Machinery's Handbook 27th Edition
A REFERENCE BOOK FOR THE MECHANICAL ENGINEER, DESIGNER,
MANUFACTURING ENGINEER, DRAF...
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Machinery's Handbook 27th Edition
A REFERENCE BOOK FOR THE MECHANICAL ENGINEER, DESIGNER,
MANUFACTURING ENGINEER, DRAFTSMAN, TOOLMAKER, AND MACHINIST
27th Edition
Machinery’s Handbook BY ERIK OBERG, FRANKLIN D. JONES, HOLBROOK L. HORTON, AND HENRY H. RYFFEL
CHRISTOPHER J. MCCAULEY, EDITOR RICCARDO M. HEALD, ASSOCIATE EDITOR MUHAMMED IQBAL HUSSAIN, ASSOCIATE EDITOR
2004 INDUSTRIAL PRESS INC. NEW YORK
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition COPYRIGHT COPYRIGHT 1914, 1924, 1928, 1930, 1931, 1934, 1936, 1937, 1939, 1940, 1941, 1942, 1943, 1944, 1945, 1946, 1948, 1950, 1951, 1952, 1953, 1954, 1955, 1956, 1957,© 1959, © 1962, © 1964, © 1966, © 1968, © 1971, © 1974, © 1975, © 1977, © 1979, © 1984, © 1988, © 1992, © 1996, © 1997, © 1998, © 2000, © 2004 by Industrial Press Inc., New York, NY. Library of Congress Cataloging-in-Publication Data Oberg, Erik, 1881—1951 Machinery's Handbook. 2640 p. Includes index. I. Mechanical engineering—Handbook, manuals, etc. I. Jones, Franklin Day, 1879-1967 II. Horton, Holbrook Lynedon, 1907-2001 III. Ryffel, Henry H. I920- IV. Title. TJ151.0245 2000 621.8'0212 72-622276 ISBN 0-8311-2700-7 (Toolbox Thumb Indexed 11.7 x 17.8 cm) ISBN 0-8311-2711-2 (Large Print Thumb Indexed 17.8 x 25.4 cm) ISBN 0-8311-2777-5 (CD-ROM) ISBN 0-8311-2727-9 (Toolbox Thumb Indexed / CD-ROM Combo 11.7 x 17.8 cm) ISBN 0-8311-2737-6 (Large Print Thumb Indexed / CD-ROM Combo 17.8 x 25.4 cm) LC card number 72-622276
INDUSTRIAL PRESS, INC. 200 Madison Avenue New York, New York 10016-4078 MACHINERY'S HANDBOOK 27th Edition First Printing
Printed and bound in the United States of America by National Publishing Company, Philadelphia, Pa. All rights reserved. This book or parts thereof may not be reproduced, stored in a retrieval system, or transmitted in any form without permission of the publishers.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition PREFACE Machinery's Handbook has served as the principal reference work in metalworking, design and manufacturing facilities, and in technical schools and colleges throughout the world, for more than 90 years of continuous publication. Throughout this period, the intention of the Handbook editors has always been to create a comprehensive and practical tool, combining the most basic and essential aspects of sophisticated manufacturing practice. A tool to be used in much the same way that other tools are used, to make and repair products of high quality, at the lowest cost, and in the shortest time possible. The essential basics, material that is of proven and everlasting worth, must always be included if the Handbook is to continue to provide for the needs of the manufacturing community. But, it remains a difficult task to select suitable material from the almost unlimited supply of data pertaining to the manufacturing and mechanical engineering fields, and to provide for the needs of design and production departments in all sizes of manufacturing plants and workshops, as well as those of job shops, the hobbyist, and students of trade and technical schools. The editors rely to a great extent on conversations and written communications with users of the Handbook for guidance on topics to be introduced, revised, lengthened, shortened, or omitted. In response to such suggestions, in recent years material on logarithms, trigonometry, and sine-bar constants have been restored after numerous requests for these topics. Also at the request of users, in 1997 the first ever large-print or “desktop” edition of the Handbook was published, followed in 1998 by the publication of Machinery's Handbook CD-ROM including hundreds of additional pages of material restored from earlier editions. The large-print and CD-ROM editions have since become permanent additions to the growing family of Machinery's Handbook products. Regular users of the Handbook will quickly discover some of the many changes embodied in the present edition. One is the combined Mechanics and Strength of Materials section, arising out of the two former sections of similar name; another is the Index of Standards, intended to assist in locating standards information. “Old style” numerals, in continuous use in the first through twenty-fifth editions, are now used only in the index for page references, and in cross reference throughout the text. The entire text of this edition, including all the tables and equations, has been reset, and a great many of the numerous figures have been redrawn. This edition contains more information than ever before, and sixty-four additional pages brings the total length of the book to 2704 pages, the longest Handbook ever. The 27th edition of the Handbook contains significant format changes and major revisions of existing content, as well as new material on a variety of topics. The detailed tables of contents located at the beginning of each section have been expanded and fine tuned to simplify locating your topic; numerous major sections have been extensively reworked and renovated throughout, including Mathematics, Mechanics and Strength of Materials, Properties of Materials, Fasteners, Threads and Threading, and Unit Conversions. New material includes fundamentals of basic math operations, engineering economic analysis, matrix operations, disc springs, constants for metric sine-bars, additional screw thread data and information on obscure and historical threads, aerodynamic lubrication, high speed machining, grinding feeds and speeds, machining econometrics, metalworking fluids, ISO surface texture, pipe welding, geometric dimensioning and tolerancing, gearing, and EDM. Other subjects in the Handbook that are new or have been revised, expanded, or updated are: analytical geometry, formulas for circular segments, construction of four-arc ellipse, geometry of rollers on a shaft, mechanisms, additional constants for measuring weight of piles, Ohm’s law, binary multiples, force on inclined planes, and measurement over pins. The large-print edition is identical to the traditional toolbox edition, but the size is increased by a comfortable 140% for easier reading, making it ideal as a desktop reference. Other than size, there are no differences between the toolbox and large-print editions.
v
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition PREFACE The Machinery's Handbook 27 CD-ROM contains the complete contents of the printed edition, presented in Adobe Acrobat PDF format. This popular and well known format enables viewing and printing of pages, identical to those of the printed book, rapid searching, and the ability to magnify the view of any page. Navigation aids in the form of thousands of clickable bookmarks, page cross references, and index entries take you instantly to any page referenced. The CD contains additional material that is not included in the toolbox or large print editions, including an extensive index of materials referenced in the Handbook, numerous useful mathematical tables, sine-bar constants for sine-bars of various lengths, material on cement and concrete, adhesives and sealants, recipes for coloring and etching metals, forge shop equipment, silent chain, worm gearing and other material on gears, and other topics. Also new on the CD are numerous interactive math problems. Solutions are accessed from the CD by clicking an icon, located in the page margin adjacent to a covered problem, (see figure shown here). An internet connection is required to use these problems. The list of interactive math solutions currently available can be found in the Index of Interactive Equations, starting on page 2689. Additional interactive solutions will be added from time to time as the need becomes clear. Those users involved in aspects of machining and grinding will be interested in the topics Machining Econometrics and Grinding Feeds and Speeds, presented in the Machining section. The core of all manufacturing methods start with the cutting edge and the metal removal process. Improving the control of the machining process is a major component necessary to achieve a Lean chain of manufacturing events. These sections describe the means that are necessary to get metal cutting processes under control and how to properly evaluate the decision making. A major goal of the editors is to make the Handbook easier to use. The 27th edition of the Handbook continues to incorporate the timesaving thumb tabs, much requested by users in the past. The table of contents pages beginning each major section, first introduced for the 25th edition, have proven very useful to readers. Consequently, the number of contents pages has been increased to several pages each for many of the larger sections, to more thoroughly reflect the contents of these sections. In the present edition, the Plastics section, formerly a separate thumb tab, has been incorporated into the Properties of Materials section. A major task in assembling this edition has been the expansion and reorganization of the index. For the first time, most of the many Standards referenced in the Handbook are now included in a separate Index Of Standards starting on page 2677. The editors are greatly indebted to readers who call attention to possible errors and defects in the Handbook, who offer suggestions concerning the omission of some matter that is considered to be of general value, or who have technical questions concerning the solution of difficult or troublesome Handbook problems. Such dialog is often invaluable and helps to identify topics that require additional clarification or are the source of reader confusion. Queries involving Handbook material usually entail an in depth review of the topic in question, and may result in the addition of new material to the Handbook intended to resolve or clarify the issue. The new material on the mass moment of inertia of hollow circular rings, page 248, and on the effect of temperature on the radius of thin circular rings, page 405, are good examples. Our goal is to increase the usefulness of the Handbook to the greatest extent possible. All criticisms and suggestions about revisions, omissions, or inclusion of new material, and requests for assistance with manufacturing problems encountered in the shop are always welcome. Christopher J. McCauley, Senior Editor
vi
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition ACKNOWLEDGMENTS The editors would like to acknowledge all those who contributed ideas, suggestions, and criticisms concerning the Handbook. Most importantly, we thank the readers who have contacted us with suggestions for new topics to present in this edition of the Handbook. We are grateful for your continuing constructive suggestions and criticisms with regard to Handbook topics and presentation. Your comments for this edition, as well as past and future ones are invaluable, and well appreciated. Special thanks are also extended to current and former members of our staff, the talented engineers, recent-graduates, who performed much of the fact checking, calculations, artwork, and standards verification involved in preparing the printed and CD-ROM editions of the Handbook. Many thanks to Janet Romano for her great Handbook cover designs. Her printing, packaging, and production expertise are irreplacable, continuing the long tradition of Handbook quality and ruggedness. Many of the American National Standards Institute (ANSI) Standards that deal with mechanical engineering, extracts from which are included in the Handbook, are published by the American Society of Mechanical Engineers (ASME), and we are grateful for their permission to quote extracts and to update the information contained in the standards, based on the revisions regularly carried out by the ASME. ANSI Standards are copyrighted by the publisher. Information regarding current editions of any of these Standards can be obtained from ASME International, Three Park Avenue, New York, NY 10016, or by contacting the American National Standards Institute, West 42nd Street, New York, NY 10017, from whom current copies may be purchased. Additional information concerning Standards nomenclature and other Standards bodies that may be of interest is located on page 2079. Several individuals in particular, contributed substantial amounts of time and information to this edition. Mr. David Belforte, for his thorough contribution on lasers. Manfred K. Brueckner, for his excellent presentation of formulas for circular segments, and for the material on construction of the four-arc oval. Dr. Bertil Colding, provided extensive material on grinding speeds, feeds, depths of cut, and tool life for a wide range of materials. He also provided practical information on machining econometrics, including tool wear and tool life and machining cost relationships. Mr. Edward Craig contributed information on welding. Dr. Edmund Isakov, contributed material on coned disc springs as well as numerous other suggestions related to hardness scales, material properties, and other topics. Mr. Sidney Kravitz, a frequent contributor, provided additional data on weight of piles, excellent proof reading assistance, and many useful comments and suggestions concerning many topics throughout the book. Mr. Richard Kuzmack, for his contributions on the subject of dividing heads, and additions to the tables of dividing head indexing movements. Mr. Robert E. Green, as editor emeritus, contributed much useful, well organized material to this edition. He also provided invaluable practical guidance to the editorial staff during the Handbook’s compilation. Finally, Industrial Press is extremely fortunate that Mr. Henry H. Ryffel, author and editor of Machinery’s Handbook, continues to be deeply involved with the Handbook. Henry’s ideas, suggestions, and vision are deeply appreciated by everyone who worked on this book.
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Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
Guide to the Use of Tables and Formulas in Machinery’s Handbook 27th Edition BY JOHN M. AMISS, FRANKLIN D. JONES, AND HENRY H. RYFFEL
CHRISTOPHER J. MCCAULEY, EDITOR RICCARDO HEALD, ASSOCIATE EDITOR MUHAMMED IQBAL HUSSAIN, ASSOCIATE EDITOR
2004 INDUSTRIAL PRESS INC. NEW YORK
Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
COPYRIGHT 1931, 1939, 1951, 1954, © 1959, © 1964, © 1968, © 1971,© 1975, © 1980, © 1984, © 1988, © 1992, © 1996, © 2000, © 2004 by Industrial Press Inc., New York, NY. Library of Congress Cataloging-in-Publication Data Amiss, John Milton, 1887-1968 Guide to the use of tables and formulas in Machinery’s Handbook, 27th edition by John M. Amiss, Franklin D. Jones, and Henry H. Ryffel; Christopher J. McCauley, editor; Riccardo Heald, associate editor; Muhammed Iqbal Hussain, associate editor. 264 p. 12.1 × 17.8 cm. Cover title: Machinery’s handbook 27th guide. Cover title: Machinery’s handbook twenty seventh guide. This book should be used in conjunction with the twenty-seventh edition of Machinery’s Handbook. ISBN 0-8311-2799-6 ISBN 0-8311-2788-0 (electronic edition with math) 1. Mechanical engineering—Handbook, manuals, etc. I. Title: Machinery’s handbook 27 guide. II. Machinery’s handbook twenty seventh guide. III Jones, Franklin Day, 1879-1967 IV. Ryffel, Henry H. I920- V. McCauley, Christopher J. VI. Heald, Riccardo VII. Hussain, Muhammed Iqbal VIII. Machinery’s Handbook. 27th edition. IX. Title.
TJ151.A445 2000 621.8'0212–dc 21
00-038881
INDUSTRIAL PRESS, INC. 200 Madison Avenue New York, New York 10016-4078
MACHINERY'S HANDBOOK GUIDE 27th Edition First Printing
Printed and bound in the United States of America by National Publishing Company, Philadelphia, Pa. All rights reserved. This book or parts thereof may not be reproduced, stored in a retrieval system, or transmitted in any form without permission of the publishers.
Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
THE PURPOSE OF THIS BOOK An engineering handbook is an essential part of the equipment of practically all engineers, machine designers, draftsmen, tool engineers and skilled mechanics in machine shops and toolrooms. The daily use of such a book, with its various tables and general data, saves a lot of time and labor. To obtain the full value of any handbook, however, the user must know enough about the contents to apply the tables, formulas, and other data, whenever they can be used to advantage. One purpose of this Guide, which is based on MACHINERY’S HANDBOOK, is to show by examples, solutions, and test questions typical applications of handbook information in both drafting rooms and machine shops. Another function is to familiarize engineering students or other users with the HANDBOOK’S contents. A third objective is to provide test questions and drill work that will enable the H ANDBOOK user, through practice, to obtain the required information quickly and easily. MACHINERY’S HANDBOOK, as with all other handbooks, presents information in condensed form so that a large variety of subjects can be covered in a single volume. Because of this condensed treatment, any engineering handbook must be primarily a work of reference rather than a textbook, and the practical application of some parts will not always be apparent, especially to those who have had little experience in engineering work. The questions and examples in this book are intended not only to supplement some of the HANDBOOK material, but also to stimulate interest both in those parts that are used frequently and in the more special sections that may be very valuable even though seldom required.
vii Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
THE METRIC SYSTEM MACHINERY’S HANDBOOK contains a considerable amount of metric material in terms of texts, tables, and formulas. This material is included because much of the world now uses the metric system, also known as the Système International (SI), and the movement in that direction continues in all countries that intend to compete in the international marketplace, including the United States. An explanation of the SI metric system is found on Handbook pages 142 to 144 and 2544 to 2548. A brief history is given of the development of this system, and a description is provided for each of its seven basic units. Factors and prefixes for forming decimal multiples and submultiples of the SI units also are shown. Another table lists SI units with complex names and provides symbols for them. Tables of SI units and conversion factors appear on pages 2549 through 2587. Factors are provided for converting English units to metric units, or vice versa, and cover units of length, area, volume (including capacity), velocity, acceleration, flow, mass, density, force, force per unit length, bending moment or torque, moment of inertia, section modulus, momentum, pressure, stress, energy, work, power, and viscosity. By using the factors in these tables, it is a simple matter of multiplication to convert from one system of units to the other. Where the conversion factors are exact, they are given to only 3 or 4 significant figures, but where they are not exact they are given to 7 significant figures to permit the maximum degree of accuracy to be obtained that is ordinarily required in the metalworking field. To avoid the need to use some of the conversion factors, various conversion tables are given on pages 2550 through 2579. The tables for length conversion on pages 2550 to 2562 will probably be the most frequently used. Two different types of tables are shown. The two tables on page 2553 facilitate converting lengths viii Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
ix up to 100 inches into millimeters, in steps of one ten-thousandth of an inch; and up to 1000 millimeters to inches, in steps of a thousandth of a millimeter. The table starting on page 2554 enables converting fractions and mixed number lengths up to 41 inches into millimeters, in steps of one sixty-fourth of an inch. To make possible such a wide range in a compact table, the reader often must take two or more numbers from the table and add them together, as is explained in the accompanying text. The tables starting on page 2556 and 2558 have a much more limited range of conversion for inches to millimeters and millimeters to inches. However, these table have the advantage of being direct-reading; that is, only a single value is taken from the table, and no addition is required. For those who are engaged in design work where it is necessary to do computations in the fields of mechanics and strength of materials, a considerable amount of guidance will be found for the use of metric units. Thus, beginning on Handbook page 141, the use of the metric SI system in mechanics calculations is explained in detail. In succeeding pages, boldface type is used to highlight references to metric units in the combined Mechanics and Strength of Materials section. Metric formulas are provided also, to parallel the formulas for English units. As another example, on page 213, it is explained in boldface type that SI metric units can be applied in the calculations in place of the English units of measurement without changes to the formulas for simple stresses. The reader also should be aware that certain tables in the Handbook, such as that on page 71, which gives values for segments of circles for a radius = 1, can be used for either English or metric units, as is indicated directly under the table heading. There are other instances, however, where separate tables are needed, such as are shown on pages 1018 to 1021 for the conversion of revolutions per minute, into cutting speed in feet per minute on pages 1018 and 1019, and into cutting speed in meters per minute on pages 1020 and 1021.
Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
x The metric material in the Handbook will provide considerable useful data and assistance to engineers and technicians who are required to use metric units of measurements. It is strongly suggested that all readers, whether or not they are using metric units at the present time, become familiar with the SI System by reading the explanatory material in the Handbook and by studying the SI units and the ways of converting English units to them.
Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
Machinery's Handbook Guide 27th Edition CONTENTS SECTION
1
PAGE
The Purpose Of This Book
vii
The Metric System
viii
Dimensions And Areas Of Circles
1
2
Chordal Dimensions, Segments, And Spheres
4
3
Formulas And Their Rearrangement
4
Spreadsheet Calculations
22
5
Calculations Involving Logarithms Of Numbers
32
6
Dimensions, Areas, And Volumes Of Geometrical Figures
42
7
Geometrical Propositions And Constructions
46
8
Functions Of Angles
50
9
Solution Of Right-angle Triangles
58
8
10
Solution of Oblique Triangles
78
11
Figuring Tapers
88
12
Tolerances And Allowances For Machine Parts
94
13
Using Standards Data And Information
108
14
Standard Screw And Pipe Threads
113
15
Problems In Mechanics
122
16
Strength Of Materials
138
17
Design Of Shafts And Keys For Power Transmission
150
18
Splines
159
19
Problems In Designing And Cutting Gears
169
20
Cutting Speeds, Feeds, And Machining Power
196
21
Numerical Control
205
22
General Review Questions
212
23
Answers To Practice Exercises INDEX
221 254
vi Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TABLE OF CONTENTS
COPYRIGHT
iv
PREFACE
v
ACKNOWLEDGMENTS
ix
MATHEMATICS
1
• NUMBERS, FRACTIONS, AND DECIMALS • ALGEBRA AND EQUATIONS • GEOMETRY • SOLUTION OF TRIANGLES • LOGARITHMS • MATRICES • ENGINEERING ECONOMICS
MECHANICS AND STRENGTH OF MATERIALS
138
• MECHANICS • VELOCITY, ACCELERATION, WORK, AND ENERGY • FLYWHEELS • STRENGTH OF MATERIALS • PROPERTIES OF BODIES • BEAMS • COLUMNS • PLATES, SHELLS, AND CYLINDERS • SHAFTS • SPRINGS • DISC SPRINGS • WIRE ROPE, CHAIN, ROPE, AND HOOKS
PROPERTIES, TREATMENT, AND TESTING OF MATERIALS
396
• THE ELEMENTS, HEAT, MASS, AND WEIGHT • PROPERTIES OF WOOD, CERAMICS, PLASTICS, METALS, WATER, AND AIR • STANDARD STEELS • TOOL STEELS • HARDENING, TEMPERING, AND ANNEALING • NONFERROUS ALLOYS • PLASTICS
DIMENSIONING, GAGING, AND MEASURING
629
• DRAFTING PRACTICES • ALLOWANCES AND TOLERANCES FOR FITS • MEASURING INSTRUMENTS AND INSPECTION METHODS • SURFACE TEXTURE
TOOLING AND TOOLMAKING
746
• CUTTING TOOLS • CEMENTED CARBIDES • FORMING TOOLS • MILLING CUTTERS • REAMERS • TWIST DRILLS AND COUNTERBORES • TAPS AND THREADING DIES • STANDARD TAPERS • ARBORS, CHUCKS, AND SPINDLES • BROACHES AND BROACHING • FILES AND BURS • TOOL WEAR AND SHARPENING • JIGS AND FIXTURES
MACHINING OPERATIONS
1005
• CUTTING SPEEDS AND FEEDS • SPEED AND FEED TABLES • ESTIMATING SPEEDS AND MACHINING POWER • MACHINING ECONOMETRICS • SCREW MACHINE FEEDS AND SPEEDS • CUTTING FLUIDS • MACHINING NONFERROUS METALS AND NONMETALLIC MATERIALS • GRINDING FEEDS AND SPEEDS • GRINDING AND OTHER ABRASIVE PROCESSES • KNURLS AND KNURLING • MACHINE TOOL ACCURACY • NUMERICAL CONTROL • NUMERICAL CONTROL PROGRAMMING • CAD/CAM
MANUFACTURING PROCESSES
1326
• PUNCHES, DIES, AND PRESS WORK • ELECTRICAL DISCHARGE MACHINING • IRON AND STEEL CASTINGS • SOLDERING AND BRAZING • WELDING • LASERS • FINISHING OPERATIONS
Each section has a detailed Table of Contents or Index located on the page indicated
vii
TABLE OF CONTENTS
FASTENERS
1473
• NAILS, SPIKES, AND WOOD SCREWS • RIVETS AND RIVETED JOINTS • TORQUE AND TENSION IN FASTENERS • INCH THREADED FASTENERS • METRIC THREADED FASTENERS • BRITISH FASTENERS • MACHINE SCREWS AND NUTS • CAP AND SET SCREWS • SELF-THREADING SCREWS • T-SLOTS, BOLTS, AND NUTS • PINS AND STUDS • RETAINING RINGS • WING NUTS, WING SCREWS, AND THUMB SCREWS
THREADS AND THREADING
1721
• SCREW THREAD SYSTEMS • UNIFIED SCREW THREADS • METRIC SCREW THREADS • ACME SCREW THREADS • BUTTRESS THREADS • WHITWORTH THREADS • PIPE AND HOSE THREADS • OTHER THREADS • MEASURING SCREW THREADS • TAPPING AND THREAD CUTTING • THREAD ROLLING • THREAD GRINDING • THREAD MILLING • SIMPLE, COMPOUND, DIFFERENTIAL, AND BLOCK INDEXING
GEARS, SPLINES, AND CAMS
2026
• GEARS AND GEARING • HYPOID AND BEVEL GEARING • WORM GEARING • HELICAL GEARING • OTHER GEAR TYPES • CHECKING GEAR SIZES • GEAR MATERIALS • SPLINES AND SERRATIONS • CAMS AND CAM DESIGN
MACHINE ELEMENTS
2214
• PLAIN BEARINGS • BALL, ROLLER, AND NEEDLE BEARINGS • STANDARD METAL BALLS • LUBRICANTS AND LUBRICATION • COUPLINGS AND CLUTCHES • FRICTION BRAKES • KEYS AND KEYSEATS • FLEXIBLE BELTS AND SHEAVES • TRANSMISSION CHAINS • STANDARDS FOR ELECTRIC MOTORS • ADHESIVES AND SEALANTS • MOTION CONTROL • O-RINGS • ROLLED STEEL SECTIONS, WIRE, AND SHEET-METAL GAGES • PIPE AND PIPE FITTINGS
MEASURING UNITS
2539
• SYMBOLS AND ABBREVIATIONS • MEASURING UNITS • U.S. SYSTEM AND METRIC SYSTEM CONVERSIONS
INDEX
2588
INDEX OF STANDARDS
2677
INDEX OF INTERACTIVE EQUATIONS
2689
INDEX OF MATERIALS
2694
ADDITIONAL INFORMATION FROM THE CD
2741
• MATHEMATICS • CEMENT, CONCRETE, LUTES, ADHESIVES, AND SEALANTS • SURFACE TREATMENTS FOR METALS • MANUFACTURING • SYMBOLS FOR DRAFTING • FORGE SHOP EQUIPMENT • SILENT OR INVERTED TOOTH CHAIN • GEARS AND GEARING • MISCELLANEOUS TOPICS
Each section has a detailed Table of Contents or Index located on the page indicated
viii
Guide to Machinery's Handbook 27th Edition
SECTION 1 DIMENSIONS AND AREAS OF CIRCLES HANDBOOK Pages 66 and 76 Circumferences of circles are used in calculating speeds of rotating machine parts, including drills, reamers, milling cutters, grinding wheels, gears, and pulleys. These speeds are variously referred to as surface speed, circumferential speed, and peripheral speed; meaning for each, the distance that a point on the surface or circumference would travel in one minute. This distance usually is expressed as feet per minute. Circumferences are also required in calculating the circular pitch of gears, laying out involute curves, finding the lengths of arcs, and in solving many geometrical problems. Letters from the Greek alphabet frequently are used to designate angles, and the Greek letter π (pi) always is used to indicate the ratio between the circumference and the diameter of a circle: of circle π = 3.14159265… = circumference ------------------------------------------------------diameter of circle For most practical purposes the value of π = 3.1416 may be used. Example 1:Find the circumference and area of a circle whose diameter is 8 inches. On Handbook page 66, the circumference C of a circle is given as 3.1416d. Therefore, 3.1416 × 8 = 25.1328 inches. On the same page, the area is given as 0.7854d2. Therefore, A (area) = 0.7854 × 82 = 0.7854 × 64 = 50.2656 square inches. Example 2: From page 76 of the Handbook, the area of a cylindrical surface equals S = 3.1416 × d × h. For a diameter of 8 inches and a height of 10 inches, the area is 3.1416 × 8 × 10 = 251.328 square inches. Example 3: For the cylinder in Example 2 but with the area of both ends included, the total area is the sum of the area found in Example 2 plus two times the area found in Example 1. Thus, 1 Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
2
DIMENSIONS AND AREAS OF CIRCLES
251.328 + 2 × 50.2656 = 351.8592 square inches. The same result could have been obtained by using the formula for total area given on Handbook page 76: A = 3.1416 × d × (1⁄2 d + h) = 3.1416 × 8 × (1⁄2 × 8 + 10) = 351.8592 square inches. Example 4:If the circumference of a tree is 96 inches, what is its diameter? Since the circumference of a circle C = 3.1416 × d, 96 = 3.1416 × d so that d = 96 ÷ 3.1416 = 30.558 inches. Example 5:The tables starting on page 1018 of the Handbook provides values of revolutions per minute required producing various cutting speeds for workpieces of selected diameters. How are these speeds calculated? Cutting speed in feet per minute is calculated by multiplying the circumference in feet of a workpiece by the rpm of the spindle: cutting speed in fpm = circumference in feet × rpm. By transposing this formula as explained in Formulas And Their Rearrangement starting on page 8, cutting speed, fpm rpm = --------------------------------------------------circumference in feet For a 3-inch diameter workpiece ( 1⁄4-foot diameter) and for a cutting speed of 40 fpm, rpm = 40 ÷ (3.1416 × 1⁄4) = 50.92 = 51 rpm, approximately, which is the same as the value given on page 1018 of the Handbook. PRACTICE EXERCISES FOR SECTION 1 (See Answers to Practice Exercises For Section 1 on page 221) 1) Find the area and circumference of a circle 10 mm in diameter. 2) On Handbook page 1020, for a 5-mm diameter tool or workpiece rotating at 318 rpm, the corresponding cutting speed is given as 5 meters per minute. Check this value. 3) For a cylinder 100 mm in diameter and 10 mm high, what is the surface area not including the top or bottom? 4) A steel column carrying a load of 10,000 pounds has a diameter of 10 inches. What is the pressure on the floor in pounds per square inch? 5) What is the ratio of the area of a square of any size to the area of a circle having the same diameter as one side of the square?
Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
DIMENSIONS AND AREAS OF CIRCLES
3
6) What is the ratio of the area of a square of any size to the area of a circle having the same diameter as one side of the square? 7) The drilling speed for cast iron is assumed to be 70 feet per minute. Find the time required to drill two holes in each of 500 castings if each hole has a diameter of 3⁄4 inch and is 1 inch deep. Use 0.010 inch feed and allow one-fourth minute per hole for setup. 8) Find the weight of a cast-iron column 10 inches in diameter and 10 feet high. Cast iron weighs 0.26 pound per cubic inch. 9) If machine steel has a tensile strength of 55,000 pounds per square inch, what should be the diameter of a rod to support 36,000 pounds if the safe working stress is assumed to be one-fifth of the tensile strength? 10) Moving the circumference of a 16-inch automobile flywheel 2 inches moves the camshaft through how many degrees? (The camshaft rotates at one-half the flywheel speed.) 11) The tables beginning on Handbook page 990 give lengths of chords for spacing off circumferences of circles into equal parts. Is another method available?
Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
SECTION 2 CHORDAL DIMENSIONS, SEGMENTS, AND SPHERES HANDBOOK Pages 78, 71, and 989— 991 A chord of a circle is the distance along a straight line from one point to any other point on the circumference. A segment of a circle is that part or area between a chord and the arc it intercepts. The lengths of chords and the dimensions and areas of segments are often required in mechanical work. Lengths of Chords.—The table of chords, Handbook page 990, can be applied to a circle of any diameter as explained and illustrated by examples on that page. This table is given to six decimal places so that it can be used in connection with precision tool work. Example 1:A circle has 56 equal divisions and the chordal distance from one division to the next is 2.156 inches. What is the diameter of the circle? The chordal length in the table for 56 divisions and a diameter of 1 equals 0.05607; therefore, in this example, 2.156 = 0.05607 × diameter 2.156 Diameter = ------------------- = 38.452 inches 0.05607 Example 2:A drill jig is to have eight holes equally spaced around a circle 6 inches in diameter. How can the chordal distance between adjacent holes be determined when the table, Handbook page 990, is not available? One-half the angle between the radial center lines of adjacent holes = 180 ÷ number of holes. If the sine of this angle is multiplied by the diameter of the circle, the product equals the chordal distance. In this example, we have 180 ÷ 8 = 22.5 degrees. The sine of 22.5 degrees from a calculator is 0.38268; hence, the 4 Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
CHORDS AND SEGMENTS
5
chordal distance = 0.38268 × 6 = 2.296 inches. The result is the same as would be obtained with the table on Handbook page 990 because the figures in the column “Length of the Chord” represent the sines of angles equivalent to 180 divided by the different numbers of spaces. Use of the Table of Segments of Circles—Handbook page 71 .—This table is of the unit type in that the values all apply to a radius of 1. As explained above the table, the value for any other radius can be obtained by multiplying the figures in the table by the given radius. For areas, the square of the given radius is used. Thus, the unit type of table is universal in its application. Example 3:Find the area of a segment of a circle, the center angle of which is 57 degrees, and the radius 21⁄2 inches. First locate 57 degrees in the center angle column; opposite this figure in the area column will be found 0.0781. Since the area is required, this number is multiplied by the square of 21⁄2. Thus, 0.0781 × (21⁄2)2 = 0.488 square inch Example 4:A cylindrical oil tank is 41⁄2 feet in diameter, 10 feet long, and is in a horizontal position. When the depth of the oil is 3 feet, 8 inches, what is the number of gallons of oil? The total capacity of the tank equals 0.7854 × (41⁄2)2 × 10 = 159 cubic feet. One U.S. gallon equals 0.1337 cubic foot (see Handbook page 2566); hence, the total capacity of the tank equals 159 ÷ 0.1337 = 1190 gallons. The unfilled area at the top of the tank is a segment having a height of 10 inches or 10⁄27 (0.37037) of the tank radius. The nearest decimal equivalent to 10⁄27 in Column h of the table starting on page 71 is 0.3707; hence, the number of cubic feet in the segmentshaped space = (272 × 0.401 × 120) ÷ 1728 = 20.3 cubic feet and 20.3 ÷ 0.1337 = 152 gallons. Therefore, when the depth of oil is 3 feet, 8 inches, there are 1190 − 152 = 1038 gallons. (See also Handbook page 61 for additional information on the capacity of cylindrical tanks.) Spheres.—Handbook page 78 gives formulas for calculating spherical volumes.
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CHORDS AND SEGMENTS
Example 5:If the diameter of a sphere is 245⁄8 inches, what is the volume, given the formula: Volume = 0.5236d3 The cube of 245⁄8 = 14,932.369; hence, the volume of this sphere = 0.5236 × 14,932.369 = 7818.5 cubic inches PRACTICE EXERCISES FOR SECTION 2 (See Answers to Practice Exercises For Section 2 on page 221) 1) Find the lengths of chords when the number of divisions of a circumference and the radii are as follows: 30 and 4; 14 and 21⁄2; 18 and 31⁄2. 2) Find the chordal distance between the graduations for thousandths on the following dial indicators: (a) Starrett has 100 divisions and 13⁄8-inch dial. (b) Brown & Sharpe has 100 divisions and 13⁄4 inch dial. (c) Ames has 50 divisions and 15⁄8 - inch dial. 3) The teeth of gears are evenly spaced on the pitch circumference. In making a drawing of a gear, how wide should the dividers be set to space 28 teeth on a 3-inch diameter pitch circle? 4) In a drill jig, 8 holes, each 1⁄2 inch diameter, were spaced evenly on a 6-inch diameter circle. To test the accuracy of the jig, plugs were placed in adjacent holes, and the distance over the plugs was measured with a micrometer. What should be the micrometer reading? 5) In the preceding problem, what should be the distance over plugs placed in alternate holes? 6) What is the length of the arc of contact of a belt over a pulley 2 feet, 3 inches in diameter if the arc of contact is 215 degrees? 7) Find the areas, lengths, and heights of chords of the following segments: (a) radius 2 inches, angle 45 degrees; (b) radius 6 inches, angle 27 degrees.
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CHORDS AND SEGMENTS
7
8) Find the number of gallons of oil in a tank 6 feet in diameter and 12 feet long if the tank is in a horizontal position, and the oil measures 2 feet deep. 9) Find the surface area of the following spheres, the diameters of which are: 11⁄2; 33⁄8; 65; 203⁄4. 10) Find the volume of each sphere in the above exercise. 11) The volume of a sphere is 1,802,725 cubic inches. What are its surface area and diameter?
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Guide to Machinery's Handbook 27th Edition
SECTION 3 FORMULAS AND THEIR REARRANGEMENT HANDBOOK Page 29 A formula may be defined as a mathematical rule expressed by signs and symbols instead of in actual words. In formulas, letters are used to represent numbers or quantities, the term “quantity” being used to designate any number involved in a mathematical process. The use of letters in formulas, in place of the actual numbers, simplifies the solution of problems and makes it possible to condense into small space the information that otherwise would be imparted by long and cumbersome rules. The figures or values for a given problem are inserted in the formula according to the requirements in each specific case. When the values are thus inserted, in place of the letters, the result or answer is obtained by ordinary arithmetical methods. There are two reasons why a formula is preferable to a rule expressed in words. 1.) The formula is more concise, it occupies less space, and it is possible to see at a glance the whole meaning of the rule laid down. 2.) It is easier to remember a brief formula than a long rule, and it is, therefore, of greater value and convenience. Example 1:In spur gears, the outside diameter of the gear can be found by adding 2 to the number of teeth and dividing the sum obtained by the diametral pitch of the gear. This rule can be expressed very simply by a formula. Assume that we write D for the outside diameter of the gear, N for the number of teeth, and P for the diametral pitch. Then the formula would be: + 2D = N -----------P This formula reads exactly as the rule given above. It says that the outside diameter (D) of the gear equals 2 added to the number of teeth (N), and this sum is divided by the pitch (P). 8 Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
FORMULAS
9
If the number of teeth in a gear is 16 and the diametral pitch 6, then simply put these figures in the place of N and P in the formula, and the outside diameter as in ordinary arithmetic. + 2- = 18 D = 16 ------------------- = 3 inches 6 6 Example 2:The formula for the horsepower generated by a steam engine is as follows: × L × A × NH = P -------------------------------33, 000 in which H = indicated horsepower of engine; P = mean effective pressure on piston in pounds per square inch; L =length of piston stroke in feet; A =area of piston in square inches; N =number of strokes of piston per minute. Assume that P = 90, L = 2, A = 320, and N = 110; what would be the horsepower? If we insert the given values in the formula, we have: 90 × 2 × 320 × 110 = 192 H = --------------------------------------------33, 000 From the examples given, we may formulate the following general rule: In formulas, each letter stands for a certain dimension or quantity; when using a formula for solving a problem, replace the letters in the formula by the figures given for a certain problem, and find the required answer as in ordinary arithmetic. Omitting Multiplication Signs in Formulas.—In formulas, the sign for multiplication (×) is often left out between letters the values of which are to be multiplied. Thus AB means A × B, and the P×L×A×N PLAN formula H = --------------------------------- can also be written H = ------------------ . 33, 000 33, 000 If A = 3, and B = 5, then: AB = A × B = 3 × 5 = 15. It is only the multiplication sign (×) that can be thus left out between the symbols or letters in a formula. All other signs must be indicated the same as in arithmetic. The multiplication sign can never be left out between two figures: 35 always means thirty-five, and “three times five” must be written 3 × 5 but “three times A”
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FORMULAS
may be written 3A. As a general rule, the figure in an expression such as “3A” is written first and is known as the coefficient of A. If the letter is written first, the multiplication sign is not left out, but the expression is written "A × 3." Rearrangement of Formulas.—A formula can be rearranged or“transposed” to determine the values represented by different letters of the formula. To illustrate by a simple example, the formula for determining the speed (s) of a driven pulley when its diameter (d), and the diameter (D) and speed (S) of the driving pulley are known is as follows: s = (S × D) /d . If the speed of the driven pulley is known, and the problem is to find its diameter or the value of d instead of s, this formula can be rearranged or changed. Thus: d = (S × D) ⁄ s Rearranging a formula in this way is governed by four general rules. Rule 1. An independent term preceded by a plus sign (+) may be transposed to the other side of the equals sign (=) if the plus sign is changed to a minus sign (−). Rule 2. An independent term preceded by a minus sign may be transposed to the other side of the equals sign if the minus sign is changed to a plus sign. As an illustration of these rules, if A = B − C, then C = B − A, and if A = C + D − B, then B = C + D − A. That the foregoing are correct may be proved by substituting numerical values for the different letters and then transposing them as shown. Rule 3. A term that multiplies all the other terms on one side of the equals sign may be moved to the other side if it is made to divide all the terms on that side. As an illustration of this rule, if A = BCD, then A/(BC) = D or according to the common arrangement D = A/(BC). Suppose, in the preceding formula, that B = 10, C = 5, and D = 3; then A = 10 × 5 × 3 = 150 and 150/(10 × 5) = 3. Rule 4. A term that divides all the other terms on one side of the equals sign may be moved to the other side if it is made to multiply all the terms on that side.
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Guide to Machinery's Handbook 27th Edition
FORMULAS
11
To illustrate, if s = SD/d, then sd = SD, and, according to Rule 3., d = SD/s. This formula may also be rearranged for determining the values of S and D; thus ds/D = S, and ds/S = D. If, in the rearrangement of formulas, minus signs precede quantities, the signs may be changed to obtain positive rather than minus quantities. All the signs on both sides of the equals sign or on both sides of the equation may be changed. For example, if −2A = −B + C, then 2A = B − C. The same result would be obtained by placing all the terms on the opposite side of the equals sign, which involves changing signs. For instance, if −2A = −B + C, then B − C = 2A. Fundamental Laws Governing Rearrangement.—After a few fundamental laws that govern any formula or equation are understood, its solution usually is very simple. An equation states that one quantity equals another quantity. So long as both parts of the equation are treated exactly alike, the values remain equal. Thus, in the equation A = 1⁄2 ab, which states that the area A of a triangle equals one-half the product of the base a times the altitude b, each side of the equation would remain equal if we added the same amount: A + 6 = 1⁄2 ab + 6; or we could subtract an equal amount from both sides: A − 8 = 1⁄2 ab − 8; or multiply both parts by the same number: 7A = 7(1⁄2 ab); or we could divide both parts by the same number, and we would still have a true equation. One formula for the total area T of a cylinder is: T = 2πr2 + 2πrh, where r = radius and h = height of the cylinder. Suppose we want to solve this equation for h. Transposing the part that does not contain h to the other side by changing its sign, we get: 2πrh = T − 2πr2. To obtain h, we can divide both sides of the equation by any quantity that will leave h on the left-hand side; thus: 2
2πrh – 2πr ------------ = T -------------------2πr 2πr It is clear that, in the left-hand member, the 2πr will cancel out, leaving: h = (T − 2πr2)/(2πr). The expression 2πr in the right-hand member cannot be cancelled because it is not an independent factor, since the numerator equals the difference between T and 2πr2.
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FORMULAS
Example 3:Rearrange the formula for a trapezoid (Handbook page 64) to obtain h. a + b )hA = (------------------2 2A = (a + b)h (a + b)h = 2A
(multiply both members by 2) (transpose both members so as to get the multiple of h on the left-hand side)
(------------------a + b )h- = ----------2A a+b a+b
(divide both members by a + b)
2A h = ----------a+b
(cancel a + b from the left-hand member)
Example 4:The formula for determining the radius of a sphere (Handbook page 78) is as follows: r = 3 3V ------4π Rearrange to obtain a formula for finding the volume V. 3 r = 3V ------4π
(cube each side)
3
4πr = 3V
(multiply each side by 4π)
3
(transpose both members)
3V = 4πr
3
3V 4πr ------- = -----------3 3
(divide each side by 3)
3
(cancel 3 from left-hand member) V = 4πr -----------3 The procedure has been shown in detail to indicate the underlying principles involved. The rearrangement could be simplified somewhat by direct application of the rules previously given.To illustrate: 3 3V r = ------4π
(cube each side)
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FORMULAS
13
3 4πr = 3V (applying Rule 4. move 4π to left-hand side) 3
4πr ------------ = V (move 3 to left-hand side—Rule 3.) 3 This final equation would, of course, be reversed to locate V at the left of the equals sign as this is the usual position for whatever letter represents the quantity or value to be determined. Example 5:It is required to determine the diameter of cylinder and length of stroke of a steam engine to deliver 150 horsepower. The mean effective steam pressure is 75 pounds, and the number of strokes per minute is 120. The length of the stroke is to be 1.4 times the diameter of the cylinder. First, insert the known values into the horsepower formula (Example 2): × L × A × 120 3×L×A 150 = 75 ---------------------------------------- = ---------------------33, 000 11 The last expression is found by cancellation. Assume now that the diameter of the cylinder in inches equals D. Then, L = 1.4D/12 = 0.117D according to the requirements in the problem; the divisor 12 is introduced to change the inches to feet, L being in feet in the horsepower formula. The area A = D2 × 0.7854. If we insert these values in the last expression in our formula, we have: 2
3
3 × 0.117D × 0.7854D = 0.2757D -----------------------150 = --------------------------------------------------------11 11 3
0.2757D = 150 × 11 = 1650 3 1650 1650 D = --------------- D = 3 ---------------- = 3 5984.8 = 18.15 0.2757 0.2757
Hence, the diameter of the cylinder should be about 181⁄4 inches, and the length of the stroke 18.15 × 1.4 = 25.41, or, say, 251⁄2 inches.
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14
FORMULAS
Solving Equations or Formulas by Trial.—One of the equations used for spiral gear calculations, when the shafts are at right angles, the ratios are unequal, and the center distance must be exact, is as follows: 2CP R sec α + csc α = -------------nn In this equation R = ratio of number of teeth in large gear to number in small gear C = exact center distance Pn =normal diametral pitch n = number of teeth in small gear The exact spiral angle α of the large gear is found by trial using the equation just given. Equations of this form are solved by trial by selecting an angle assumed to be approximately correct and inserting the secant and cosecant of this angle in the equation, adding the values thus obtained, and comparing the sum with the known value to the right of the equals sign in the equation. An example will show this more clearly. By using the problem given in Machinery’s Handbook (bottom of page 2104) as an example, R = 3; C = 10; Pn= 8; n = 28. 2CP 2 × 10 × 8- = 5.714 Hence, the whole expression -------------n- = ----------------------n 28 from which it follows that: R sec α + csc α = 5.714 In the problem given, the spiral angle required is 45 degrees. The spiral gears, however, would not meet all the conditions given in the problem if the angle could not be slightly modified. To determine whether the angle should be greater or smaller than 45 degrees, insert the values of the secant and cosecant of 45 degrees in the formula. The secant of 45 degrees is 1.4142, and the cosecant is 1.4142. Then, 3 × 1.4142 + 1.4142 = 5.6568 The value 5.6568 is too small, as it is less than 5.714 which is the required value. Hence, try 46 degrees. The secant of 46 degrees is 1.4395, and the cosecant, 1.3902. Then,
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Guide to Machinery's Handbook 27th Edition
FORMULAS
15
3 × 1.4395 + 1.3902 = 5.7087 Obviously, an angle of 46 degrees is too small. Proceed, therefore, to try an angle of 46 degrees, 30 minutes. This angle will be found too great. Similarly 46 degrees, 15 minutes, if tried, will be found too great, and by repeated trials it will finally be found that an angle of 46 degrees, 6 minutes, the secant of which is 1.4422, and the cosecant, 1.3878, meets the requirements. Then, 3 × 1.4422 + 1.3878 = 5.7144 which is as close to the required value as necessary. In general, when an equation must be solved by the trial-anderror method, all the known quantities may be written on the righthand side of the equal sign, and all the unknown quantities on the left-hand side. A value is assumed for the unknown quantity. This value is substituted in the equation, and all the values thus obtained on the left-hand side are added. In general, if the result is greater than the values on the right-hand side, the assumed value of the unknown quantity is too great. If the result obtained is smaller than the sum of the known values, the assumed value for the unknown quantity is too small. By thus adjusting the value of the unknown quantity until the left-hand member of the equation with the assumed value of the unknown quantity will just equal the known quantities on the right-hand side of the equal sign, the correct value of the unknown quantity may be determined. Derivation of Formulas.—Most formulas in engineering handbooks are given without showing how they have been derived or originated, because engineers and designers usually want only the final results; moreover, such derivations would require considerable additional space, and they belong in textbooks rather than in handbooks, which are primarily works of reference. Although Machinery’s Handbook contains thousands of standard and special formulas, it is apparent that no handbook can include every kind of formula, because a great many formulas apply only to local designing or manufacturing problems. Such special formulas are derived by engineers and designers for their own use. The exact methods of deriving formulas are based upon mathematical principles as they are related to the particular factors that apply. A few examples will be given to show how several different types of special formulas have been derived.
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FORMULAS
Example 6:The problem is to deduce the general formula for finding the point of intersection of two tapers with reference to measured diameters on those tapers. In the diagram, Fig. 1, L =the distance between the two measured diameters, D and d; X =the required distance from one measured diameter to the intersection of tapers; a = angle of long taper as measured from center line; a1 =angle of short taper as measured from center line. Then, – d- = Z + Y E = D -----------2 Z = ( L – X ) tan a 1 Y = X tan a
Fig. 1. To find Dimension X from a Given Diameter D to the Intersection of Two Conical Surfaces Therefore: D–d = ( L – X ) tan a 1 + X tan a ------------2 and
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Guide to Machinery's Handbook 27th Edition
FORMULAS D – d = 2 tan a 1 ( L – X ) + 2X tan a
17 (1)
But and 2 tan a = T 2 tan a 1 = T 1 in which T and T1 represent the long and short tapers per inch, respectively. Therefore, from Equation (1), D – d = T 1 ( L – X ) + TX D – d = T 1 L – T 1 X + TX X ( T1 – T ) = T1 L – ( D – d ) T1 L – ( D – d ) X = --------------------------------T1 – T Example 7:A flywheel is 16 feet in diameter (outside measurement), and the center of its shaft is 3 feet above the floor. Derive a formula for determining how long the hole in the floor must be to permit the flywheel to turn.
Fig. 2. To Find Length of Hole in Floor for Flywheel The conditions are as represented in Fig. 2. The line AB is the floor level and is a chord of the arc ABD; it is parallel to the horizontal diameter through the center O. CD is the vertical diameter and is perpendicular to AB. It is shown in geometry that the diameter CD bisects the chord AB at the point of intersection E. One of the most useful theorems of geometry is that when a diameter bisects a chord, the product of the two parts of the diameter is equal to the square of one half the chord; in other words, (AE)2 =
Copyright 2004, Industrial Press, Inc., New York, NY
Guide to Machinery's Handbook 27th Edition
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FORMULAS
ED × EC. If AB is represented by L and OE by a, ED = r − a and EC = r + a, in which r = the radius OC; hence, ⎛L ⎞ ⎝ --2-⎠
2
2
= (r – a)(r + a) = r – a
2
2 2 2 2 L --- = r – a and L = 2 r – a 2 By substituting the values given, 2
2
L = 2 8 – 3 = 14.8324 feet = 14 feet, 10 inches. The length of the hole, therefore, should be at least 15 feet, to allow sufficient clearance. Empirical Formulas.—Many formulas used in engineering calculations cannot be established fully by mathematical derivation but must be based upon actual tests instead of relying upon mere theories or assumptions that might introduce excessive errors. These formulas are known as “empirical formulas.” Usually such a formula contains a constant (or constants) that represents the result of the tests; consequently, the value obtained by the formula is consistent with these tests or with actual practice. A simple example of an empirical formula will be found on Handbook page 386. This particular formula contains the constant 54,000, which was established by tests, and the formula is used to obtain the breaking load of wrought-iron crane chains to which a factor of safety of 3, 4, or 5 is then applied to obtain the working load. Other examples of empirical formulas will be found on Handbook page 281. Handbook page 299 contains an example of an empirical formula based upon experiments made with power-transmitting shafts. This formula gives the diameter of shaft required to prevent excessive twisting during transmission of power. Parentheses.—Two important rules relating to the use of parentheses are based upon the principles of positive and negative numbers: 1) If a parenthesis is preceded by a + sign, it may be removed, if the terms within the parentheses retain their signs. a + (b − c) = a + b − c
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FORMULAS
19
2) If a parenthesis is preceded by a − sign, it may be removed, if the signs preceding each of the terms inside of the parentheses are changed (+ changed to −, and − to +). Multiplication and division signs are not affected. a − (b − c) = a − b + c a − (−b + c) = a + b − c Knowledge of algebra is not necessary to make successful use of formulas of the general type such as are found in engineering handbooks; it is only necessary to understand thoroughly the use of letters or symbols in place of numbers, and to be well versed in the methods, rules, and processes of ordinary arithmetic. Knowledge of algebra becomes necessary only where a general rule or formula that gives the answer to a problem directly is not available. In other words, algebra is useful in developing or originating a general rule or formula, but the formula can be used without recourse to algebraic processes. Constants.—A constant is a value that does not change or is not variable. Constants at one stage of a mathematical investigation may be variables at another stage, but an absolute constant has the same value under all circumstances. The ratio of the circumference to the diameter of a circle, or 3.1416, is a simple example of an absolute constant. In a common formula used for determining the indicated horsepower of a reciprocating steam engine, the product of the mean effective pressure in psi, the length of the stroke in feet, the area of the piston in square inches, and the number of piston strokes per minute is divided by the constant 33,000, which represents the number of foot-pounds of work per minute equivalent to 1 horsepower. Constants occur in many mathematical formulas. Mathematical Signs and Abbreviations.—E v e r y d i v i s i o n o f mathematics has its traditions, customs, and signs that are frequently of ancient origin. Hence, we encounter Greek letters in many problems where it would seem that English letters would do as well or better. Most of the signs on Handbook page 2542 will be used frequently. They should, therefore, be understood.
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FORMULAS
Conversion Tables.—It may sometimes be necessity to convert English units of measurement into metric units and vice versa. The tables provided at the back of the Handbook will be found useful in this connection. PRACTICE EXERCISES FOR SECTION 3 (See Answers to Practice Exercises For Section 3 on page 222) 1) An approximate formula for determining the horsepower H of automobile engines is: H = D2SN/3, where D = diameter of bore, inches; S = length of stroke, inches; and N = number of cylinders. Find the horsepower of the following automobile engine: a) bore, 31⁄2 inches; stroke, 41⁄4 inches. b) By using the reciprocal of 3, how could this formula be stated? 2
2
2) Using the right-angle triangle formula: C = a + b , where a = one side, b = the other side, and C = the hypotenuse, find the hypotenuse of a right triangle whose sides are 16 inches and 63 inches. 3) The formula for finding the blank diameter of a cylindrical shell is: D = d × ( d + 4h ) , where D = blank diameter; d = diameter of the shell; h = height of the shell. Find the diameter of the blank to form a cylindrical shell of 3 inches diameter and 2 inches high. 4) If D = diagonal of a cube; d = diagonal of face of a cube; s = side of a cube; and V = volume of a cube; then d =
2
2D ⁄ 3 ;
2
s = D ⁄ 3 ; and V = s3. Find the side, volume of a cube, and diagonal of the face of a cube if the diagonal of the cube is 10. 5) The area of an equilateral triangle equals one fourth of the square of the side times the square root of 3, or 2
2
A = ( S ⁄ 4 ) 3 = 0.43301S . Find the area of an equilateral triangle the side of which is 14.5 inches. 6) The formula for the volume of a sphere is: 4πr3/3 or πd3 /6. What constants may be used in place of 4π/3 and π/6?
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Guide to Machinery's Handbook 27th Edition
FORMULAS
21
7) The formula for the volume of a solid ring is 2π2Rr2, where r = radius of cross section and R = radius from the center of the ring to the center of the cross section. Find the volume of a solid ring made from 2-inch round stock if the mean diameter of the ring is 6 inches. 8) Explain these signs: ±, >, 0.038)
3
T
2
2
V, S
15
T
2
8
V, (S, H/D < 0.038)
4
R
2
2
V, S
16
R
4
4
V, S
5
T
3
2
V, S
17
T
3
6
V, S
6
R
2
3
V, S
18
T
5
4
V, S
19
T
2
10
V, S
R
4
5
(S, H/D > 1.196)
7 8 9 10
T
2
4
V, S
R
4
2
V, (S, H/D < 0.732)
T
3
3
(S, H/D > 0.732)
R
3
3
V, S
R
5
2
V, (S, H/D > 1.976)
T
4
3
(S, H/D > 1.976)
11 T
3
4
V, S
12 R
3
4
V, S
T
5
3
(S, H/D > 0.236)
T
2
7
V, (S, H/D < 0.236)
T
4
4
(S, H/D > 5.464)
14 T
3
5
V, (S, H/D < 5.464)
13
20
21 22 23 24 25
T
3
7
V, (S, H/D < 1.196)
R
3
7
(S, 0.165 < H/D < 0.479)
T
6
4
(S, H/D > 0.479)
T
2
11
V, (S, H/D < 0.165)
T
4
6
V, S
T
5
5
(S, H/D > 0.366) V, (S, H/D < 0.366)
T
3
8
R
4
6
V, S
R
5
5
(S, H/D > 1.10)
T
7
4
(S, 0.113 < H/D < 1.10)
T
2
13
V, (S, H/D < 0.133)
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CIRCLES IN A RECTANGLE
87
Rollers on a Shaft*.—The following formulas illustrate the geometry of rollers on a shaft. In Fig. 31, D is the diameter of the center line of the roller circle, d is the diameter of a roller, DS = D − d is the shaft diameter, and C is the clearance along the center line of the roller circle. In the equations that follow, N is the number of rollers, and N > 3. Equation (1a) applies when the clearance C = 0 d D = --------------------⎛ sin 180 -⎞ ⎝ -------N ⎠
(1a)
Equation (1b) applies when clearance C > 0 then d-⎞ ⎞ – d C = D sin ⎛ 180° – ( N – 1 ) asin ⎛ --⎝ ⎝ D⎠ ⎠
(1b)
d
DS
C
D
Fig. 31.
Example:Forty bearings are to be placed around a 3-inch diameter shaft with no clearance. What diameter bearings are needed? Solution: Rearrange Equation (1a), and substitute in the value of N. Use the result to eliminate d, using DS = D − d . Finally, solve for D and d. d = D sin ⎛ 180 ---------⎞ = D sin ⎛ 180 ---------⎞ = 0.078459D ⎝ N ⎠ ⎝ 40 ⎠ D = D S + d = 3 + 0.078459D 3 - = 3.2554 D = -----------------0.92154 d = D – D S = 0.2554 * Rollers on a Shaft contributed by Manfred K. Brueckner.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 88
SOLUTION OF TRIANGLES
SOLUTION OF TRIANGLES Any figure bounded by three straight lines is called a triangle. Any one of the three lines may be called the base, and the line drawn from the angle opposite the base at right angles to it is called the height or altitude of the triangle. If all three sides of a triangle are of equal length, the triangle is called equilateral. Each of the three angles in an equilateral triangle equals 60 degrees. If two sides are of equal length, the triangle is an isosceles triangle. If one angle is a right or 90-degree angle, the triangle is a right or right-angled triangle. The side opposite the right angle is called the hypotenuse. If all the angles are less than 90 degrees, the triangle is called an acute or acute-angled triangle. If one of the angles is larger than 90 degrees, the triangle is called an obtuseangled triangle. Both acute and obtuse-angled triangles are known under the common name of oblique-angled triangles. The sum of the three angles in every triangle is 180 degrees. The sides and angles of any triangle that are not known can be found when: 1 ) a l l t h e three sides; 2) two sides and one angle; and 3) one side and two angles are given. In other words, if a triangle is considered as consisting of six parts, three angles and three sides, the unknown parts can be determined when any three parts are given, provided at least one of the given parts is a side. Functions of Angles For every right triangle, a set of six ratios is defined; each is the length of one side of the triangle divided by the length of another side. The six ratios are the trigonometric (trig) functions sine, cosine, tangent, cosecant, secant, and cotangent (abbreviated sin, cos, tan, csc, sec, and cot). Trig functions are usually expressed in terms of an angle in degree or radian measure, as in cos 60° = 0.5. “Arc” in front of a trig function name, as in arcsin or arccos, means find the angle whose function value is given. For example, arcsin 0.5 = 30° means that 30° is the angle whose sin is equal to 0.5. Electronic calculators frequently use sin−1, cos−1, and tan−1 to represent the arc functions. Example:tan 53.1° = 1.332; arctan 1.332 = tan−1 1.332 = 53.1° = 53° 6′ The sine of an angle equals the opposite side divided by the hypotenuse. Hence, sin B = b ÷ c, and sin A = a ÷ c. The cosine of an angle equals the adjacent side divided by the hypotenuse. Hence, cos B = a ÷ c, and c B cos A = b ÷ c. a The tangent of an angle equals the opposite side C = 90˚ A divided by the adjacent side. Hence, tan B = b ÷ a, and tan A = a ÷ b. b The cotangent of an angle equals the adjacent side divided by the opposite side. Hence, cot B = a ÷ b, and cot A = b ÷ a. The secant of an angle equals the hypotenuse divided by the adjacent side. Hence, sec B = c ÷ a, and sec A = c ÷ b. The cosecant of an angle equals the hypotenuse divided by the opposite side. Hence, csc B = c ÷ b, and csc A = c ÷ a. It should be noted that the functions of the angles can be found in this manner only when the triangle is right-angled. If in a right-angled triangle (see preceding illustration), the lengths of the three sides are represented by a, b, and c, and the angles opposite each of these sides by A, B, and C, then the side c opposite the right angle is the hypotenuse; side b is called the side adjacent to angle A and is also the side opposite to angle B; side a is the side adjacent to angle B and the
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TRIGONOMETRIC IDENTITIES
89
side opposite to angle A. The meanings of the various functions of angles can be explained with the aid of a right-angled triangle. Note that the cosecant, secant, and cotangent are the reciprocals of, respectively, the sine, cosine, and tangent. The following relation exists between the angular functions of the two acute angles in a right-angled triangle: The sine of angle B equals the cosine of angle A; the tangent of angle B equals the cotangent of angle A, and vice versa. The sum of the two acute angles in a right-angled triangle always equals 90 degrees; hence, when one angle is known, the other can easily be found. When any two angles together make 90 degrees, one is called the complement of the other, and the sine of the one angle equals the cosine of the other, and the tangent of the one equals the cotangent of the other. The Law of Sines.—In any triangle, any side is to the sine of the angle opposite that side as any other side is to the sine of the angle opposite that side. If a, b, and c are the sides, and A, B, and C their opposite angles, respectively, then: a - = ---------b- = c , --------------------sin A sin B sin C b sin A a = --------------sin B a sin B b = --------------sin A a sin C c = --------------sin A
or or or
so that: c sin A a = -------------sin C c sin B b = -------------sin C b sin C c = --------------sin B
The Law of Cosines.—In any triangle, the square of any side is equal to the sum of the squares of the other two sides minus twice their product times the cosine of the included angle; or if a, b and c are the sides and A, B, and C are the opposite angles, respectively, then: a 2 = b 2 + c 2 – 2bc cos A b 2 = a 2 + c 2 – 2ac cos B c 2 = a 2 + b 2 – 2ab cos C These two laws, together with the proposition that the sum of the three angles equals 180 degrees, are the basis of all formulas relating to the solution of triangles. Formulas for the solution of right-angled and oblique-angled triangles, arranged in tabular form, are given on the following pages. Signs of Trigonometric Functions.—The diagram, Fig. 1 on page 98, shows the proper sign (+ or −) for the trigonometric functions of angles in each of the four quadrants, 0 to 90, 90 to 180, 180 to 270, and 270 to 360 degrees. Thus, the cosine of an angle between 90 and 180 degrees is negative; the sine of the same angle is positive. Trigonometric Identities.—Trigonometric identities are formulas that show the relationship between different trigonometric functions. They may be used to change the form of some trigonometric expressions to simplify calculations. For example, if a formula has a term, 2sinAcosA, the equivalent but simpler term sin2A may be substituted. The identities that follow may themselves be combined or rearranged in various ways to form new identities.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 90
TRIGONOMETRIC IDENTITIES
Basic sin A- = ----------1 tan A = ----------cos A cot A
1 sec A = ----------cos A
1csc A = ---------sin A
Negative Angle sin ( – A ) = – sin A
cos ( – A ) = cos A
tan ( – A ) = – tan A
Pythagorean sin2 A + cos2 A = 1
1 + tan2 A = sec2 A
1 + cot2 A = csc2 A
Sum and Difference of Angles tan A + tan Btan ( A + B ) = -------------------------------1 – tan A tan B
tan A – tan Btan ( A – B ) = --------------------------------1 + tan A tan B
cot A cot B – 1cot ( A + B ) = -------------------------------cot B + cot A
cot A cot B + 1cot ( A – B ) = --------------------------------cot B – cot A
sin ( A + B ) = sin A cos B + cos A sin B
sin ( A – B ) = sin A cos B – cos A sin B
cos ( A + B ) = cos A cos B – sin A sin B
cos ( A – B ) = cos A cos B + sin A sin B
Double-Angle cos 2A = cos2 A – sin2 A = 2 cos2 A – 1 = 1 – 2 sin2 A 2 tan A - = ----------------------------2 tan 2A = ---------------------sin 2A = 2 sin A cos A cot A – tan A 1 – tan2 A Half-Angle sin 1⁄2 A =
1⁄ ( 1 2
– cos A )
tan 1⁄2 A =
sin A 1 – cos A 1 – cos A ---------------------- = --------------------- = ---------------------1 + cos A sin A 1 + cos A
cos 1⁄2 A =
1⁄ ( 1 2
+ cos A )
Product-to-Sum sin A cos B = 1⁄2 [ sin ( A + B ) + sin ( A – B ) ] cos A cos B = 1⁄2 [ cos ( A + B ) + cos ( A – B ) ] sin A sin B = 1⁄2 [ cos ( A – B ) – cos ( A + B ) ] tan A + tan Btan A tan B = ----------------------------cot A + cot B Sum and Difference of Functions sin A + sin B = 2 [ sin 1⁄2 ( A + B ) cos 1⁄2 ( A – B ) ] sin A – sin B = 2 [ sin 1⁄2 ( A – B ) cos 1⁄2 ( A + B ) ] cos A + cos B = 2 [ cos 1⁄2 ( A + B ) cos 1⁄2 ( A – B ) ] cos A – cos B = – 2 [ sin 1⁄2 ( A + B ) sin 1⁄2 ( A – B ) ] sin ( A + B ) tan A + tan B = -------------------------cos A cos B
sin ( A – B ) tan A – tan B = -------------------------cos A cos B
sin ( B + A ) cot A + cot B = -------------------------sin A sin B
sin ( B – A ) cot A – cot B = -------------------------sin A sin B
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RIGHT-ANGLE TRIANGLES
91
Solution of Right-Angled Triangles As shown in the illustration, the sides of the rightangled triangle are designated a and b and the hypotenuse, c. The angles opposite each of these sides are designated A and B, respectively. Angle C, opposite the hypotenuse c is the right angle, and is therefore always one of the known quantities. Sides and Angles Known
Formulas for Sides and Angles to be Found
Side a; side b
c =
a2 + b2
tan A = a--b
B = 90° − A
Side a; hypotenuse c
b =
c2 – a2
sin A = a--c
B = 90° − A
Side b; hypotenuse c
a =
c2 – b2
b sin B = --c
A = 90° − B
Hypotenuse c; angle B
b = c × sin B
a = c × cos B
A = 90° − B
Hypotenuse c; angle A
b = c × cos A
a = c × sin A
B = 90° − A
Side b; angle B
bc = ---------sin B
a = b × cot B
A = 90° − B
Side b; angle A
b c = ----------cos A
a = b × tan A
B = 90° − A
Side a; angle B
a c = ----------cos B
b = a × tan B
A = 90° − B
Side a; angle A
ac = ---------sin A
b = a × cot A
B = 90° − A
Trig Functions Values for Common Angles sin 0° = 0 πsin 30° = sin -6 πsin 45° = sin -4 πsin 60° = sin -3 sin 90° = sin π --2
cos 0° = 1 = 0.5 = 0.70710678 = 0.8660254 = 1
cos 30° = cos --π6 cos 45° = cos --π4 cos 60° = cos --π3 ° cos 90 = cos π --2
tan 0° = 0 = 0.8660254 = 0.70710678 = 0.5 = 0
πtan 30° = tan -6 πtan 45° = tan -4 πtan 60° = tan -3 tan 90° = tan π --2
Copyright 2004, Industrial Press, Inc., New York, NY
= 0.57735027 = 1 = 1.7320508 = ∞
Machinery's Handbook 27th Edition 92
RIGHT-ANGLE TRIANGLES Examples of the Solution of Right-Angled Triangles (English and metric units) c = 22 inches; B = 41° 36′. a = c × cos B = 22 × cos 41 ° 36′ = 22 × 0.74780 = 16.4516 inches b = c × sin B = 22 × sin 41 ° 36′ = 22 × 0.66393 = 14.6065 inches A = 90 ° – B = 90 ° – 41 ° 36′ = 48 ° 24′
Hypotenuse and One Angle Known
c = 25 centimeters; a = 20 centimeters. b =
c2 – a2 = =
25 2 – 20 2 =
625 – 400
225 = 15 centimeters
sin A = a--- = 20 ------ = 0.8 c 25 Hypotenuse and One Side Known
Hence,
A = 53°8′ B = 90° – A = 90° – 53°8′ = 36°52′
a = 36 inches; b = 15 inches. c =
a2 + b2 = =
36 2 + 15 2 =
1296 + 225
1521 = 39 inches
tan A = a--- = 36 ------ = 2.4 b 15 Hence,
A = 67 ° 23′ B = 90 ° – A = 90 ° – 67 ° 23′ = 22 ° 37′
Two Sides Known
a = 12 meters; A = 65°. a12 12 - = 13.2405 meters c = ---------= ---------------- = -----------------sin A 0.90631 sin 65 ° b = a × cot A = 12 × cot 65 ° = 12 × 0.46631 = 5.5957 meters B = 90 ° – A = 90 ° – 65 ° = 25 °
One Side and One Angle Known
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RIGHT- AND OBLIQUE-ANGLE TRIANGLES Chart For The Rapid Solution of Right-Angle and Oblique-Angle Triangles
Copyright 2004, Industrial Press, Inc., New York, NY
93
Machinery's Handbook 27th Edition 94
OBLIQUE-ANGLE TRIANGLES Solution of Oblique-Angled Triangles
One Side and Two Angles Known (Law of Sines): Call the known side a, the angle opposite it A, and the other known angle B. Then, C = 180° − (A + B). If angles B and C are given, but not A, then A = 180° − (B + C). C = 180 ° – ( A + B ) a × sin B b = --------------------sin A
One Side and Two Angles Known
Side and Angles Known
a × sin C c = --------------------sin A
× b × sin CArea = a----------------------------2 a = 5 centimeters; A = 80°; B = 62° C = 180° – ( 80° + 62° ) = 180° – 142° = 38° × sin B- = 5------------------------× sin 62 °- = 5---------------------------× 0.88295 b = a-------------------sin A sin 80 ° 0.98481 = 4.483 centimeters a × sin C- = 5------------------------× sin 38 °- = 5---------------------------× 0.61566 c = -------------------sin A sin 80 ° 0.98481 = 3.126 centimeters
Two Sides and the Angle Between Them Known: Call the known sides a and b, and the known angle between them C. Then, a × sin C tan A = ----------------------------------b – ( a × cos C ) × sin Cc = a-------------------sin A Side c may also be found directly as below: B = 180 ° – ( A + C )
c = Two Sides and the Angle Between Them Known
Sides and Angle Known
a 2 + b 2 – ( 2ab × cos C )
a × b × sin C Area = -----------------------------2 a = 9 inches; b = 8 inches; C = 35°. a × sin C - = ---------------------------------------9 × sin 35 ° tan A = ----------------------------------b – ( a × cos C ) 8 – ( 9 × cos 35 ° ) 9 × 0.57358 5.16222 = ------------------------------------------ = ------------------- = 8.22468 8 – ( 9 × 0.81915 ) 0.62765 Hence, A = 83°4′ B = 180° – ( A + C ) = 180° – 118°4′ = 61°56′ × sin C- = 9---------------------------× 0.57358 = 5.2 inches c = a-------------------sin A 0.99269
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition OBLIQUE-ANGLE TRIANGLES
95
Two Sides and the Angle Opposite One of the Sides Known: Call the known angle A, the side opposite it a, and the other known side b. Then, b × sin A sin B = --------------------C = 180° – ( A + B ) a a × sin C a × b × sin C c = --------------------Area = -----------------------------sin A 2 If, in the above, angle B > angle A but ± ------------5.83Z
If a < 0.5858l, maximum deflection is
located between load and support, at
nx = --m
b v = l ------------2l + b If a = 0.5858l, maximum deflec-
tion is at load and is
0.5858l, the second is the maximum stress. Stress is zero at
2 Wa b -------------b- ------------and 6EI 2l + b
Wl 3 -------------------101.9EI
If a > 0.5858l, maximum deflection is
Wbn 3 -------------------and located 3EIm 2 l 3
between load and point of fixture, at
Copyright 2004, Industrial Press, Inc., New York, NY
x = 2n -----m
BEAM STRESS AND DEFLECTION TABLES
W ( 3l – 11x ) s = --------16Z
Deflections at Critical Pointsa
Machinery's Handbook 27th Edition
Table 1. (Continued) Stresses and Deflections in Beams Type of Beam
Stresses Deflections General Formula for Stress at any Point Stresses at Critical Points General Formula for Deflection at any Pointa Case 15. — Fixed at One End, Supported at the Other, Uniform Load
( l – x )- ( 1⁄ l – x ) s = W ------------------4 2Zl
Maximum stress at point
Wl-----8Z
Wx 2 ( l – x -) ( 3l – 2x ) y = ------------------------48EIl
Stress is zero at x = 1⁄4l. Greatest negative stress is
Maximum deflection is at x = 0.5785l, and is
Wl 3 -------------185EI
Deflection at center,
9 Wl at x = 5⁄8l and is – --------- ------128 Z
Wl 3 -------------192EI
Deflection at point of greatest negative stress, at x = 5⁄8l is
Wl 3 -------------187EI Case 16. — Fixed at One End, Free but Guided at the Other, Uniform Load 2⎫ ⎧ s = Wl ------- ⎨ 1⁄3 – x-- + 1⁄2 ⎛ x--⎞ ⎬ ⎝ l⎠ Z ⎩ l ⎭
Maximum stress, at support,
Wl-----3Z
Wx 2- ( 2l – x ) 2 y = ------------24EIl
Maximum deflection, at free end,
Wl 3----------24EI
Stress is zero at x = 0.4227l Greatest negative stress, at free end,
– Wl ------6Z
Case 17. — Fixed at One End, Free but Guided at the Other, with Load
W s = ----- ( 1⁄2 l – x ) Z
Stress at support,
Wl ------2Z
Stress at free end
Wl – ------2Z
Wx 2- ( 3l – 2x ) y = ----------12EI
Copyright 2004, Industrial Press, Inc., New York, NY
Wl 3----------12EI
267
These are the maximum stresses and are equal and opposite. Stress is zero at center.
Maximum deflection, at free end,
BEAM STRESS AND DEFLECTION TABLES
of fixture,
Deflections at Critical Pointsa
Machinery's Handbook 27th Edition
Type of Beam
Stresses Deflections General Formula for Stress at any Point Stresses at Critical Points General Formula for Deflection at any Pointa Case 18. — Fixed at Both Ends, Load at Center Between each end and load,
Wl ------8Z
Stress at load
Wl– -----8Z
Deflections at Critical Pointsa Maximum deflection, at load,
Wl 3 -------------192EI
These are the maximum stresses and are equal and opposite. Stress is zero at x = 1⁄4l Case 19. — Fixed at Both Ends, Load at any Point For segment of length a,
Wb 2 s = ----------- [ al – x ( l + 2a ) ] Zl 3 For segment of length b, 2
s = Wa ---------- [ bl – v ( l + 2b ) ] 3 Zl
Stress at end next to segment of length a,
Wab 2 -------------Zl 2
Stress at end next to
Wa 2 b segment of length b, -------------Zl 2
For segment of length a,
Wx 2 b 2 y = ---------------- [ 2a ( l – x ) + l ( a – x ) ] 6EIl 3 For segment of length b,
Wv 2 a 2
y = ---------------- [ 2b ( l – v ) + l ( b – v ) ] 6EIl 3
Maximum stress is at end next to shorter segment. Stress is zero at
al x = ------------l + 2a and
bl v = ------------l + 2b Greatest negative stress, at 2 2
load,
2Wa b – ------------------Zl 3
Copyright 2004, Industrial Press, Inc., New York, NY
Deflection at load,
Wa 3 b 3---------------3EIl 3
Let b be the length of the longer segment and a of the shorter one. The maximum deflection is in the longer segment, at
2bl - and is v = ------------l + 2b 2 3
2Wa b ------------------------------2 3EI ( l + 2b )
BEAM STRESS AND DEFLECTION TABLES
Wx 2- ( 3l – 4x ) y = ----------48EI
Stress at ends
W ( 1⁄ l – x ) s = -----2Z 4
268
Table 1. (Continued) Stresses and Deflections in Beams
Machinery's Handbook 27th Edition
Table 1. (Continued) Stresses and Deflections in Beams Type of Beam
Stresses Deflections General Formula for Stress at any Point Stresses at Critical Points General Formula for Deflection at any Pointa Case 20. — Fixed at Both Ends, Uniform Load Maximum stress, at ends,
Wl --------12Z
Wx 2- ( l – x ) 2 y = ------------24EIl
Maximum deflection, at center,
Wl 3 -------------384EI
Stress is zero at x = 0.7887l and at x = 0.2113l Greatest negative stress, at center,
Wl– -------24Z
Case 21. — Continuous Beam, with Two Unequal Spans, Unequal, Uniform Loads Between R1 and R,
l 1 – x ⎧ ( l 1 – x )W 1 ⎫ s = -----------⎨ ------------------------- – R 1 ⎬ Z ⎩ 2l 1 ⎭ Between R2 and R,
l 2 – u ⎧ ( l 2 – u )W 2 ⎫ s = ------------ ⎨ ------------------------- – R 2 ⎬ 2l 2 Z ⎩ ⎭
Stress at support R,
W 1 l 12 + W 2 l 22 ------------------------------8Z ( l 1 + l 2 ) Greatest stress in the first span is at
l1 x = ------ ( W – R1 ) W1 1 2
R1 l1 and is – -------------2ZW 1
Between R1 and R,
x ( l1 – x ) ⎧ y = ------------------- ⎨ ( 2l – x ) ( 4R 1 – W 1 ) 24EI ⎩ 1 W1 ( l1 – x )2 ⎫ – ---------------------------⎬ l1 ⎭ Between R2 and R,
u ( l2 – u ) ⎧ y = -------------------- ⎨ ( 2l – u ) ( 4R 2 – W 2 ) 24EI ⎩ 2
Greatest stress in the second span is at
l2 u = ------ ( W – R2 ) W2 2 and is,
W2 ( l2 – u ) 2 ⎫ – ---------------------------⎬ l2 ⎭
This case is so complicated that convenient general expressions for the critical deflections cannot be obtained.
BEAM STRESS AND DEFLECTION TABLES
2⎫ ⎧ s = Wl ------- ⎨ 1⁄6 – x-- + ⎛⎝ x--⎞⎠ ⎬ 2Z ⎩ l l ⎭
Deflections at Critical Pointsa
R 22 l 2 – ------------2ZW 2
269
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Type of Beam
Stresses Deflections General Formula for Stress at any Point Stresses at Critical Points General Formula for Deflection at any Pointa Case 22. — Continuous Beam, with Two Equal Spans, Uniform Load
( l – x )- ( 1⁄ l – x ) s = W ------------------4 2Zl
Maximum stress at
Wl-----8Z
Wx 2 ( l – x -) ( 3l – 2x ) y = ------------------------48EIl
Stress is zero at x = 1⁄4l Greatest negative stress is at x = 5⁄8l and is,
Deflections at Critical Pointsa Maximum deflection is at x = 0.5785l, and is
Wl 3 -------------185EI
Deflection at center of span,
Wl 3 --------------192EI
9 - Wl – -------------128 Z
Deflection at point of greatest negative stress, at x = 5⁄8l is
Wl 3 -------------187EI
Case 23. — Continuous Beam, with Two Equal Spans, Equal Loads at Center of Each Between point A and load,
W ( 3l – 11x ) s = --------16Z Between point B and load,
5- Wv s = – -----------16 Z
Maximum stress at point A,
3- Wl ----------16 Z
Stress is zero at
3- l x = ----11
Between point A and load,
Wx 2- ( 9l – 11x ) y = ----------96EI
Maximum deflection is at v = 0.4472l, and is
Wl 3 ---------------------107.33EI
Between point B and load,
Wv - 3l 2 y = ----------( – 5v 2 ) 96EI
Greatest negative stress at center of span,
5- -----Wl– ----32 Z
Copyright 2004, Industrial Press, Inc., New York, NY
Deflection at load,
7 - -------Wl 3-------768 EI
BEAM STRESS AND DEFLECTION TABLES
point A,
270
Table 1. (Continued) Stresses and Deflections in Beams
Machinery's Handbook 27th Edition
Table 1. (Continued) Stresses and Deflections in Beams Stresses Deflections General Formula for Stress at any Point Stresses at Critical Points General Formula for Deflection at any Pointa Case 24. — Continuous Beam, with Two Unequal Spans, Unequal Loads at any Point of Each
Type of Beam
Between R1 and W1,
Between R and W1, s =
1 m= 2(l1 + l 2)
W1a1b1 Wab (l1 + a1) + 2 2 2 (l2 + a2) l1 l2 W1
R1 w a1
W2
R u b1
x b2
a2
v
R2
Between R and W2, s =
1 ------- [ m ( l 2 – x ) – W 2 a 2 x ] l2 Z Between R2 and W2,
l2
l1
1 ------- [ m ( l 1 – u ) – W 1 a 1 u ] l1 Z
W1b1 – m W1a1 + m W2a2 + m W2b2 – m + l1 l1 l2 l2
vr s = – -------2 Z
Stress at load W1,
a1 r1 – --------Z Stress at support R,
m ---Z Stress at load W2,
a2 r2 – --------Z
Between R1 and W1,
W 1 b 13 ⎫ w -⎧ l y = -------⎨ ( – w ) ( l 1 + w )r 1 – ------------- ⎬ 6EI ⎩ 1 l1 ⎭ Between R and W1,
u - [W a b (l + a ) y = ------------1 6EIl 1 1 1 1 1 – W 1 a 1 u 2 – m ( 2l 1 – u ) ( l 1 – u ) ] Between R and W2
The greatest of these is the maximum stress.
x - [W a b (l + a ) y = ------------2 6EIl 2 2 2 2 2 – W 2 a 2 x 2 – m ( 2l 2 – x ) ( l 2 – x ) ]
Deflection at load W1,
a1 b1 ------------- [ 2a 1 b 1 W 1 6EIl 1 – m ( l1 + a1 ) ] Deflection at load W2,
a2 b2 ------------- [ 2a 2 b 2 W 2 6EIl 2 – m ( l2 + a2 ) ] This case is so complicated that convenient general expressions for the maximum deflections cannot be obtained.
Between R2 and W2,
= r1
=r
= r2
3 v - ⎧ ( l – v ) ( l + v )r – W 2 b2 ⎫ y = -------⎨ 2 2 ------------- ⎬ 6EI ⎩ 2 l2 ⎭
a The deflections apply only to cases where the cross section of the beam is constant for its entire length.
In the diagrammatical illustrations of the beams and their loading, the values indicated near, but below, the supports are the “reactions” or upward forces at the supports. For Cases 1 to 12, inclusive, the reactions, as well as the formulas for the stresses, are the same whether the beam is of constant or variable cross-section. For the other cases, the reactions and the stresses given are for constant cross-section beams only.
Copyright 2004, Industrial Press, Inc., New York, NY
271
The bending moment at any point in inch-pounds is s × Z and can be found by omitting the divisor Z in the formula for the stress given in the tables. A positive value of the bending moment denotes tension in the upper fibers and compression in the lower ones. A negative value denotes the reverse, The value of W corresponding to a given stress is found by transposition of the formula. For example, in Case 1, the stress at the critical point is s = − Wl ÷ 8Z. From this formula we find W = − 8Zs ÷ l. Of course, the negative sign of W may be ignored.
BEAM STRESS AND DEFLECTION TABLES
wr s = – --------1Z
Deflections at Critical Pointsa
Machinery's Handbook 27th Edition 272
RECTANGULAR AND ROUND SOLID BEAMS
In Table 1, if there are several kinds of loads, as, for instance, a uniform load and a load at any point, or separate loads at different points, the total stress and the total deflection at any point is found by adding together the various stresses or deflections at the point considered due to each load acting by itself. If the stress or deflection due to any one of the loads is negative, it must be subtracted instead of added. Tables 2a and 2b give expressions for determining dimensions of rectangular and round beams in terms of beam stresses and load. Table 2a. Rectangular Solid Beams Style of Loading and Support
Breadth of Beam, b inch (mm)
6lW ---------- = b fh 2
Stress in Extreme Fibers, f Beam Height, h Beam Length, l inch (mm) lb/in2 (N/mm2) inch (mm) Beam fixed at one end, loaded at the other
6lW ---------- = h bf
6lW ---------- = f bh 2
Total Load, W lb (N)
bfh 2 ----------- = l 6W
2 bfh ----------- = W 6l
Beam fixed at one end, uniformly loaded
3lW ---------- = b fh 2
3lW ---------- = h bf
3lW ---------- = f bh 2
bfh 2- = l ---------3W
2 bfh ----------- = W 3l
Beam supported at both ends, single load in middle
3lW- = b ---------2fh 2
3lW ---------- = h 2bf
3lW- = f ----------2bh 2
2bfh 2- = l ------------3W
2 2bfh -------------- = W 3l
Beam supported at both ends, uniformly loaded
3lW- = b ---------4fh 2
3lW ---------- = h 4bf
3lW- = f ----------4bh 2
4bfh 2 -------------- = l 3W
4bfh 2 -------------- = W 3l
Beam supported at both ends, single unsymmetrical load
6Wac- = b -------------fh 2 l
6Wac --------------- = h bfl
6Wac --------------- = f bh 2 l
a+c=l
bh 2 fl ------------ = W 6ac
Beam supported at both ends, two symmetrical loads
3Wa ----------- = b fh 2
3Wa ----------- = h bf
3Wa ----------- = f bh 2
l, any length 2 bh -----------f = a 3W
2 bh -----------f = W 3a
Deflection of Beam Uniformly Loaded for Part of Its Length.—In the following formulas, lengths are in inches, weights in pounds. W = total load; L = total length between supports; E = modulus of elasticity; I = moment of inertia of beam section; a = fraction of length of beam at each end, that is not loaded = b ÷ L; and f = deflection. WL 3 f = ------------------------------------ ( 5 – 24a 2 + 16a 4 ) 384EI ( 1 – 2a ) The expression for maximum bending moment is: Mmax = 1⁄8WL (1 + 2a).
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Machinery's Handbook 27th Edition UNIFORMLY LOADED BEAMS
273
Table 2b. Round Solid Beams Style of Loading and Support
Diameter of Beam, d inch (mm)
3
10.18lW --------------------- = d f
Stress in Extreme Fibers, f Beam Length, l inch (mm) lb/in2 (N/mm2) Beam fixed at one end, loaded at the other
10.18lW --------------------- = f d3
Total Load, W lb (N)
d3 f = l -----------------10.18W
d3 f - = W -------------10.18l
Beam fixed at one end, uniformly loaded
3
5.092Wl --------------------- = d f
5.092Wl- = f -------------------d3
d3 f = l -----------------5.092W
d3 f - = W -------------5.092l
Beam supported at both ends, single load in middle
3
2.546Wl --------------------- = d f
2.546Wl --------------------- = f d3
d3 f = l -----------------2.546W
d3 f - = W -------------2.546l
Beam supported at both ends, uniformly loaded
3
1.273Wl --------------------- = d f
1.273Wl --------------------- = f d3
d3 f = l -----------------1.273W
d3 f - = W -------------1.273l
Beam supported at both ends, single unsymmetrical load
3
10.18Wac ------------------------- = d fl
10.18Wac ------------------------- = f d3 l
a+c=l
d 3 fl ------------------- = W 10.18ac
Beam supported at both ends, two symmetrical loads
3
5.092Wa ---------------------- = d f
5.092Wa ---------------------- = f d3
l, any length
d3 f = a -----------------5.092W
d3 f = W ---------------5.092a
These formulas apply to simple beams resting on supports at the ends.
If the formulas are used with metric SI units, W = total load in newtons; L = total length between supports in millimeters; E = modulus of elasticity in newtons per millimeter2; I = moment of inertia of beam section in millimeters4; a = fraction of length of beam at each end, that is not loaded = b ÷ L; and f = deflection in millimeters. The bending moment Mmax is in newton-millimeters (N · mm). Note: A load due to the weight of a mass of M kilograms is Mg newtons, where g = approximately 9.81 meters per second 2.
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Machinery's Handbook 27th Edition 274
BEAMS OF UNIFORM STRENGTH
Bending Stress Due to an Oblique Transverse Force.—The following illustration shows a beam and a channel being subjected to a transverse force acting at an angle φ to the center of gravity. To find the bending stress, the moments of inertia I around axes 3-3 and 4-4 are computed from the following equations: I3 = Ixsin2φ + Iycos2φ, and I4 = Ixcos2φ + Iysin2φ. y- sin φ + --x- cos φ⎞ where M The computed bending stress fb is then found from f b = M ⎛ --⎝I ⎠ I x
y
is the bending moment due to force F.
Beams of Uniform Strength Throughout Their Length.—The bending moment in a beam is generally not uniform throughout its length, but varies. Therefore, a beam of uniform cross-section which is made strong enough at its most strained section, will have an excess of material at every other section. Sometimes it may be desirable to have the crosssection uniform, but at other times the metal can be more advantageously distributed if the beam is so designed that its cross-section varies from point to point, so that it is at every point just great enough to take care of the bending stresses at that point. Tables 3a and 3b are given showing beams in which the load is applied in different ways and which are supported by different methods, and the shape of the beam required for uniform strength is indicated. It should be noted that the shape given is the theoretical shape required to resist bending only. It is apparent that sufficient cross-section of beam must also be added either at the points of support (in beams supported at both ends), or at the point of application of the load (in beams loaded at one end), to take care of the vertical shear. It should be noted that the theoretical shapes of the beams given in the two tables that follow are based on the stated assumptions of uniformity of width or depth of cross-section, and unless these are observed in the design, the theoretical outlines do not apply without modifications. For example, in a cantilever with the load at one end, the outline is a parabola only when the width of the beam is uniform. It is not correct to use a strictly parabolic shape when the thickness is not uniform, as, for instance, when the beam is made of an I- or T-section. In such cases, some modification may be necessary; but it is evident that whatever the shape adopted, the correct depth of the section can be obtained by an investigation of the bending moment and the shearing load at a number of points, and then a line can be drawn through the points thus ascertained, which will provide for a beam of practically uniform strength whether the cross-section be of uniform width or not.
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Machinery's Handbook 27th Edition BEAMS OF UNIFORM STRENGTH
275
Table 3a. Beams of Uniform Strength Throughout Their Length Type of Beam
Formulaa
Description
Load at one end. Width of beam uniform. Depth of beam decreasing towards loaded end. Outline of beam-shape, parabola with vertex at loaded end.
2 P = Sbh -----------6l
Load at one end. Width of beam uniform. Depth of beam decreasing towards loaded end. Outline of beam, one-half of a parabola with vertex at loaded end. Beam may be reversed so that upper edge is parabolic.
Sbh 2 P = -----------6l
Load at one end. Depth of beam uniform. Width of beam decreasing towards loaded end. Outline of beam triangular, with apex at loaded end.
Sbh 2 P = -----------6l
Beam of approximately uniform strength. Load at one end. Width of beam uniform. Depth of beam decreasing towards loaded end, but not tapering to a sharp point.
2 -----------P = Sbh 6l
Uniformly distributed load. Width of beam uniform. Depth of beam decreasing towards outer end. Outline of beam, right-angled triangle.
Sbh 2 P = -----------3l
Uniformly distributed load. Depth of beam uniform. Width of beam gradually decreasing towards outer end. Outline of beam is formed by two parabolas which tangent each other at their vertexes at the outer end of the beam.
Sbh 2 P = -----------3l
a In the formulas, P = load in pounds; S = safe stress in pounds per square inch; and a, b, c, h, and l are in inches. If metric SI units are used, P is in newtons; S = safe stress in N/mm2; and a, b, c, h, and l are in millimeters.
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Machinery's Handbook 27th Edition 276
BEAMS OF UNIFORM STRENGTH Table 3b. Beams of Uniform Strength Throughout Their Length Type of Beam
Description
Formulaa
Beam supported at both ends. Load concentrated at any point. Depth of beam uniform. Width of beam maximum at point of loading. Outline of beam, two triangles with apexes at points of support.
Sbh 2 l P = ------------6ac
Beam supported at both ends. Load concentrated at any point. Width of beam uniform. Depth of beam maximum at point of loading. Outline of beam is formed by two parabolas with their vertexes at points of support.
Sbh 2-l P = ------------6ac
Beam supported at both ends. Load concentrated in the middle. Depth of beam uniform. Width of beam maximum at point of loading. Outline of beam, two triangles with apexes at points of support.
2 P = 2Sbh ---------------3l
Beam supported at both ends. Load concentrated at center. Width of beam uniform. Depth of beam maximum at point of loading. Outline of beam, two parabolas with vertices at points of support.
2Sbh 2 P = ---------------3l
Beam supported at both ends. Load uniformly distributed. Depth of beam uniform. Width of beam maximum at center. Outline of beam, two parabolas with vertexes at middle of beam.
4Sbh 2 P = ---------------3l
Beam supported at both ends. Load uniformly distributed. Width of beam uniform. Depth of beam maximum at center. Outline of beam onehalf of an ellipse.
2 P = 4Sbh ---------------3l
a For details of English and metric SI units used in the formulas, see footnote on page
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275.
Machinery's Handbook 27th Edition DEFLECTION IN BEAM DESIGN
277
Deflection as a Limiting Factor in Beam Design.—For some applications, a beam must be stronger than required by the maximum load it is to support, in order to prevent excessive deflection. Maximum allowable deflections vary widely for different classes of service, so a general formula for determining them cannot be given. When exceptionally stiff girders are required, one rule is to limit the deflection to 1 inch per 100 feet of span; hence, if l = length of span in inches, deflection = l ÷ 1200. According to another formula, deflection limit = l ÷ 360 where beams are adjacent to materials like plaster which would be broken by excessive beam deflection. Some machine parts of the beam type must be very rigid to maintain alignment under load. For example, the deflection of a punch press column may be limited to 0.010 inch or less. These examples merely illustrate variations in practice. It is impracticable to give general formulas for determining the allowable deflection in any specific application, because the allowable amount depends on the conditions governing each class of work. Procedure in Designing for Deflection: Assume that a deflection equal to l ÷ 1200 is to be the limiting factor in selecting a wide-flange (W-shape) beam having a span length of 144 inches. Supports are at both ends and load at center is 15,000 pounds. Deflection y is to be limited to 144 ÷ 1200 = 0.12 inch. According to the formula on page 261 (Case 2), in which W = load on beam in pounds, l = length of span in inches, E = modulus of elasticity of material, I = moment of inertia of cross section: Wl 3- hence, I = -----------Wl 3- = -------------------------------------------------------15 ,000 × 144 3 Deflection y = ----------- = 268.1 48EI 48yE 48 × 0.12 × 29 ,000 ,000 A structural wide-flange beam, see Steel Wide-Flange Sections on page 2511, having a depth of 12 inches and weighing 35 pounds per foot has a moment of inertia I of 285 and a section modulus (Z or S) of 45.6. Checking now for maximum stress s (Case 2, page 261): Wl 15 ,000 × 144 s = ------- = -------------------------------- = 11 ,842 lbs/in2 4Z 4 × 46.0 Although deflection is the limiting factor in this case, the maximum stress is checked to make sure that it is within the allowable limit. As the limiting deflection is decreased, for a given load and length of span, the beam strength and rigidity must be increased, and, consequently, the maximum stress is decreased. Thus, in the preceding example, if the maximum deflection is 0.08 inch instead of 0.12 inch, then the calculated value for the moment of inertia I will be 402; hence a W 12 × 53 beam having an I value of 426 could be used (nearest value above 402). The maximum stress then would be reduced to 7640 pounds per square inch and the calculated deflection is 0.076 inch. A similar example using metric SI units is as follows. Assume that a deflection equal to l ÷ 1000 millimeters is to be the limiting factor in selecting a W-beam having a span length of 5 meters. Supports are at both ends and the load at the center is 30 kilonewtons. Deflection y is to be limited to 5000 ÷ 1000 = 5 millimeters. The formula on page 261 (Case 2) is applied, and W = load on beam in newtons; l = length of span in mm; E = modulus of elasticity (assume 200,000 N/mm2 in this example); and I = moment of inertia of cross-section in millimeters4. Thus, Wl 3 Deflection y = ------------48EI hence
Wl 3 30 ,000 × 5000 3 I = ------------- = ----------------------------------------- = 78 ,125 ,000 mm 4 48yE 48 × 5 × 200 ,000 Although deflection is the limiting factor in this case, the maximum stress is checked to make sure that it is within the allowable limit, using the formula from page 261 (Case 2):
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Machinery's Handbook 27th Edition 278
CURVED BEAMS Wl s = ------4Z
The units of s are newtons per square millimeter; W is the load in newtons; l is the length in mm; and Z = section modulus of the cross-section of the beam = I ÷ distance in mm from neutral axis to extreme fiber. Curved Beams.—The formula S = Mc/I used to compute stresses due to bending of beams is based on the assumption that the beams are straight before any loads are applied. In beams having initial curvature, however, the stresses may be considerably higher than predicted by the ordinary straight-beam formula because the effect of initial curvature is to shift the neutral axis of a curved member in from the gravity axis toward the center of curvature (the concave side of the beam). This shift in the position of the neutral axis causes an increase in the stress on the concave side of the beam and decreases the stress at the outside fibers. Hooks, press frames, and other machine members which as a rule have a rather pronounced initial curvature may have a maximum stress at the inside fibers of up to about 31⁄2 times that predicted by the ordinary straight-beam formula. Stress Correction Factors for Curved Beams: A simple method for determining the maximum fiber stress due to bending of curved members consists of 1) calculating the maximum stress using the straight-beam formula S = Mc/I; and; and 2) multiplying the calculated stress by a stress correction factor. Table 4 on page 279 gives stress correction factors for some of the common cross-sections and proportions used in the design of curved members. An example in the application of the method using English units of measurement is given at the bottom of the table. A similar example using metric SI units is as follows: The fiber stresses of a curved rectangular beam are calculated as 40 newtons per millimeter2, using the straight beam formula, S = Mc/I. If the beam is 150 mm deep and its radius of curvature is 300 mm, what are the true stresses? R/c = 300⁄75 = 4. From Table 4 on page 279, the K factors corresponding to R/c = 4 are 1.20 and 0.85. Thus, the inside fiber stress is 40 × 1.20 = 48 N/mm2 = 48 megapascals; and the outside fiber stress is 40 × 0.85 = 34 N/mm2 = 34 megapascals. Approximate Formula for Stress Correction Factor: The stress correction factors given in Table 4 on page 279 were determined by Wilson and Quereau and published in the University of Illinois Engineering Experiment Station Circular No. 16, “A Simple Method of Determining Stress in Curved Flexural Members.” In this same publication the authors indicate that the following empirical formula may be used to calculate the value of the stress correction factor for the inside fibers of sections not covered by the tabular data to within 5 per cent accuracy except in triangular sections where up to 10 per cent deviation may be expected. However, for most engineering calculations, this formula should prove satisfactory for general use in determining the factor for the inside fibers. 1 - --1I - ----------+ K = 1.00 + 0.5 ------bc 2 R – c R (Use 1.05 instead of 0.5 in this formula for circular and elliptical sections.) I =Moment of inertia of section about centroidal axis b =maximum width of section c =distance from centroidal axis to inside fiber, i.e., to the extreme fiber nearest the center of curvature R =radius of curvature of centroidal axis of beam
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Machinery's Handbook 27th Edition CURVED BEAMS
279
Table 4. Values of Stress Correction Factor K for Various Curved Beam Sections Section
R⁄ c
1.2 1.4 1.6 1.8 2.0 3.0 4.0 6.0 8.0 10.0 1.2 1.4 1.6 1.8 2.0 3.0 4.0 6.0 8.0 10.0 1.2 1.4 1.6 1.8 2.0 3.0 4.0 6.0 8.0 10.0 1.2 1.4 1.6 1.8 2.0 3.0 4.0 6.0 8.0 10.0 1.2 1.4 1.6 1.8 2.0 3.0 4.0 6.0 8.0 10.0 1.2 1.4 1.6 1.8 2.0 3.0 4.0 6.0 8.0 10.0
Factor K Inside Outside Fiber Fiber 3.41 .54 2.40 .60 1.96 .65 1.75 .68 1.62 .71 1.33 .79 1.23 .84 1.14 .89 1.10 .91 1.08 .93 2.89 .57 2.13 .63 1.79 .67 1.63 .70 1.52 .73 1.30 .81 1.20 .85 1.12 .90 1.09 .92 1.07 .94 3.01 .54 2.18 .60 1.87 .65 1.69 .68 1.58 .71 1.33 .80 1.23 .84 1.13 .88 1.10 .91 1.08 .93 3.09 .56 2.25 .62 1.91 .66 1.73 .70 1.61 .73 1.37 .81 1.26 .86 1.17 .91 1.13 .94 1.11 .95 3.14 .52 2.29 .54 1.93 .62 1.74 .65 1.61 .68 1.34 .76 1.24 .82 1.15 .87 1.12 .91 1.10 .93 3.26 .44 2.39 .50 1.99 .54 1.78 .57 1.66 .60 1.37 .70 1.27 .75 1.16 .82 1.12 .86 1.09 .88
a
y0
.224R .151R .108R .084R .069R .030R .016R .0070R .0039R .0025R .305R .204R .149R .112R .090R .041R .021R .0093R .0052R .0033R .336R .229R .168R .128R .102R .046R .024R .011R .0060R .0039R .336R .229R .168R .128R .102R .046R .024R .011R .0060R .0039R .352R .243R .179R .138R .110R .050R .028R .012R .0060R .0039R .361R .251R .186R .144R .116R .052R .029R .013R .0060R .0039R
Section
R⁄ c
1.2 1.4 1.6 1.8 2.0 3.0 4.0 6.0 8.0 10.0 1.2 1.4 1.6 1.8 2.0 3.0 4.0 6.0 8.0 10.0 1.2 1.4 1.6 1.8 2.0 3.0 4.0 6.0 8.0 10.0 1.2 1.4 1.6 1.8 2.0 3.0 4.0 6.0 8.0 10.0 1.2 1.4 1.6 1.8 2.0 3.0 4.0 6.0 8.0 10.0
Factor K Inside Outside Fiber Fiber 3.63 .58 2.54 .63 2.14 .67 1.89 .70 1.73 .72 1.41 .79 1.29 .83 1.18 .88 1.13 .91 1.10 .92 3.55 .67 2.48 .72 2.07 .76 1.83 .78 1.69 .80 1.38 .86 1.26 .89 1.15 .92 1.10 .94 1.08 .95 2.52 .67 1.90 .71 1.63 .75 1.50 .77 1.41 .79 1.23 .86 1.16 .89 1.10 .92 1.07 .94 1.05 .95 3.28 .58 2.31 .64 1.89 .68 1.70 .71 1.57 .73 1.31 .81 1.21 .85 1.13 .90 1.10 .92 1.07 .93 2.63 .68 1.97 .73 1.66 .76 1.51 .78 1.43 .80 1.23 .86 1.15 .89 1.09 .92 1.07 .94 1.06 .95
y0a .418R .299R .229R .183R .149R .069R .040R .018R .010R .0065R .409R .292R .224R .178R .144R .067R .038R .018R .010R .0065R .408R .285R .208R .160R .127R .058R .030R .013R .0076R .0048R .269R .182R .134R .104R .083R .038R .020R .0087R .0049R .0031R .399R .280R .205R .159R .127R .058R .031R .014R .0076R .0048R
Example: The fiber stresses of a curved rectangular beam are calculated as 5000 psi using the straight beam formula, S = Mc/I. If the beam is 8 inches deep and its radius of curvature is 12 inches, what are the true stresses? R/c = 12⁄4 = 3. The factors in the table corresponding to R/c = 3 are 0.81 and 1.30. Outside fiber stress = 5000 × 0.81 = 4050 psi; inside fiber stress = 5000 × 1.30 = 6500 psi.
a y is the distance from the centroidal axis to the neutral axis of curved beams subjected to pure 0 bending and is measured from the centroidal axis toward the center of curvature.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 280
CURVED BEAMS
Example:The accompanying diagram shows the dimensions of a clamp frame of rectangular cross-section. Determine the maximum stress at points A and B due to a clamping force of 1000 pounds.
The cross-sectional area = 2 × 4 = 8 square inches; the bending moment at section AB is 1000 (24 + 6 + 2) = 32,000 inch pounds; the distance from the center of gravity of the section at AB to point B is c = 2 inches; and using the formula on page 239, the moment of inertia of the section is 2 × (4)3 ÷ 12 = 10.667 inches4. Using the straight-beam formula, page 278, the stress at points A and B due to the bending moment is: ,000 × 2- = 6000 psi S = Mc -------- = 32 ------------------------I 10.667 The stress at A is a compressive stress of 6000 psi and that at B is a tensile stress of 6000 psi. These values must be corrected to account for the curvature effect. In Table 4 on page 279 for R/c = (6 + 2)/(2) = 4, the value of K is found to be 1.20 and 0.85 for points B and A respectively. Thus, the actual stress due to bending at point B is 1.20 × 6000 = 7200 psi in tension and the stress at point A is 0.85 × 6000 = 5100 psi in compression. To these stresses at A and B must be added, algebraically, the direct stress at section AB due to the 1000-pound clamping force. The direct stress on section AB will be a tensile stress equal to the clamping force divided by the section area. Thus 1000 ÷ 8 = 125 psi in tension. The maximum unit stress at A is, therefore, 5100 − 125 = 4975 psi in compression and the maximum unit stress at B is 7200 + 125 = 7325 psi in tension. The following is a similar calculation using metric SI units, assuming that it is required to determine the maximum stress at points A and B due to clamping force of 4 kilonewtons acting on the frame. The frame cross-section is 50 by 100 millimeters, the radius R = 200 mm, and the length of the straight portions is 600 mm. Thus, the cross-sectional area = 50 × 100 = 5000 mm2; the bending moment at AB is 4000(600 + 200) = 3,200,000 newton-millimeters; the distance from the center of gravity of the section at AB to point B is c = 50 mm; and the moment of inertia of the section is, using the formula on page 239, 50 × (100)3 = 4,170,000 mm4. Using the straight-beam formula, page 278, the stress at points A and B due to the bending moment is: Mc 3 ,200 ,000 × 50 s = -------- = ------------------------------------I 4 ,170 ,000 = 38.4 newtons per millimeter 2 = 38.4 megapascals The stress at A is a compressive stress of 38.4 N/mm2, while that at B is a tensile stress of 38.4 N/mm2. These values must be corrected to account for the curvature
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SIZE OF RAIL TO CARRY LOAD
281
effect. From the table on page 279, the K factors are 1.20 and 0.85 for points A and B respectively, derived from R/c = 200⁄50 = 4. Thus, the actual stress due to bending at point B is 1.20 × 38.4 = 46.1 N/mm2 (46.1 megapascals) in tension; and the stress at point A is 0.85 × 38.4 = 32.6 N/mm2 (32.6 megapascals) in compression. To these stresses at A and B must be added, algebraically, the direct stress at section AB due to the 4 kN clamping force. The direct stress on section AB will be a tensile stress equal to the clamping force divided by the section area. Thus, 4000⁄5000 = 0.8 N/mm 2. The maximum unit stress at A is, therefore, 32.61 − 0.8 = 31.8 N/mm 2 (31.8 megapascals) in compression, and the maximum unit stress at B is 46.1 + 0.8 = 46.9 N/mm 2 (46.9 megapascals) in tension. Size of Rail Necessary to Carry a Given Load.—The following formulas may be employed for determining the size of rail and wheel suitable for carrying a given load. Let, A = the width of the head of the rail in inches; B = width of the tread of the rail in inches; C = the wheel-load in pounds; D = the diameter of the wheel in inches.
Then the width of the tread of the rail in inches is found from the formula: C B = ---------------1250D
(1)
The width A of the head equals B + 5⁄8 inch. The diameter D of the smallest track wheel that will safely carry the load is found from the formula: C D = ------------(2) A×K in which K = 600 to 800 for steel castings; K = 300 to 400 for cast iron. As an example, assume that the wheel-load is 10,000 pounds; the diameter of the wheel is 20 inches; and the material is cast steel. Determine the size of rail necessary to carry this load. From Formula (1): 10,000 B = ------------------------ = 0.4 inch 1250 × 20 The width of the rail required equals 0.4 + 5⁄8 inch = 1.025 inch. Determine also whether a wheel 20 inches in diameter is large enough to safely carry the load. From Formula (2): 10,000 D = ---------------------------= 16 1⁄4 inches 1.025 × 600 This is the smallest diameter of track wheel that will safely carry the load; hence a 20inch wheel is ample. American Railway Engineering Association Formulas.—The American Railway Engineering Association recommends for safe operation of steel cylinders rolling on steel plates that the allowable load p in pounds per inch of length of the cylinder should not exceed the value calculated from the formula
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Machinery's Handbook 27th Edition 282
STRESSES PRODUCED BY SHOCKS – 13,000- 600d for diameterd less than 25 inches p = y.s. ------------------------------20,000
This formula is based on steel having a yield strength, y.s., of 32,000 pounds per square inch. For roller or wheel diameters of up to 25 inches, the Hertz stress (contact stress) resulting from the calculated load p will be approximately 76,000 pounds per square inch. For a 10-inch diameter roller the safe load per inch of roller length is 32,000 – 13,000 p = ------------------------------------------ 600 × 10 = 5700 lbs per inch of length 20,000 Therefore, to support a 10,000 pound load the roller or wheel would need to be 10,000⁄5700 = 1.75 inches wide. Stresses Produced by Shocks Stresses in Beams Produced by Shocks.—Any elastic structure subjected to a shock will deflect until the product of the average resistance, developed by the deflection, and the distance through which it has been overcome, has reached a value equal to the energy of the shock. It follows that for a given shock, the average resisting stresses are inversely proportional to the deflection. If the structure were perfectly rigid, the deflection would be zero, and the stress infinite. The effect of a shock is, therefore, to a great extent dependent upon the elastic property (the springiness) of the structure subjected to the impact. The energy of a body in motion, such as a falling body, may be spent in each of four ways: 1) In deforming the body struck as a whole. 2) In deforming the falling body as a whole. 3) In partial deformation of both bodies on the surface of contact (most of this energy will be transformed into heat). 4) Part of the energy will be taken up by the supports, if these are not perfectly rigid and inelastic. How much energy is spent in the last three ways it is usually difficult to determine, and for this reason it is safest to figure as if the whole amount were spent as in Case 1. If a reliable judgment is possible as to what percentage of the energy is spent in other ways than the first, a corresponding fraction of the total energy can be assumed as developing stresses in the body subjected to shocks. One investigation into the stresses produced by shocks led to the following conclusions: 1) A suddenly applied load will produce the same deflection, and, therefore, the same stress as a static load twice as great; and 2) The unit stress p (see formulas in Table 1, "Stresses Produced in Beams by Shocks") for a given load producing a shock, varies directly as the square root of the modulus of elasticity E, and inversely as the square root of the length L of the beam and the area of the section. Thus, for instance, if the sectional area of a beam is increased by four times, the unit stress will diminish only by half. This result is entirely different from those produced by static loads where the stress would vary inversely with the area, and within certain limits be practically independent of the modulus of elasticity. In Table 1, the expression for the approximate value of p, which is applicable whenever the deflection of the beam is small as compared with the total height h through which the body producing the shock is dropped, is always the same for beams supported at both ends and subjected to shock at any point between the supports. In the formulas all dimensions are in inches and weights in pounds.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STRESSES PRODUCED BY SHOCKS
283
Table 1. Stresses Produced in Beams by Shocks Method of Support and Point Struck by Falling Body
Fiber (Unit) Stress p produced by Weight Q Dropped Through a Distance h
Approximate Value of p
Supported at both ends; struck in center.
96hEI p = QaL ----------- ⎛ 1 + 1 + ----------------⎞ 4I ⎝ QL 3 ⎠
p = a 6QhE --------------LI
Fixed at one end; struck at the other.
p = QaL ----------- ⎛ 1 + 1 + 6hEI -------------⎞ I ⎝ QL 3 ⎠
p = a 6QhE --------------LI
Fixed at both ends; struck in center.
p = QaL ----------- ⎛ 1 + 1 + 384hEI -------------------⎞ 8I ⎝ QL 3 ⎠
p = a 6QhE --------------LI
I = moment of inertia of section; a = distance of extreme fiber from neutral axis; L = length of beam; E = modulus of elasticity.
If metric SI units are used, p is in newtons per square millimeter; Q is in newtons; E = modulus of elasticity in N/mm2; I = moment of inertia of section in millimeters4; and h, a, and L in millimeters. Note: If Q is given in kilograms, the value referred to is mass. The weight Q of a mass M kilograms is Mg newtons, where g = approximately 9.81 meters per second2. Examples of How Formulas for Stresses Produced by Shocks are Derived: The general formula from which specific formulas for shock stresses in beams, springs, and other machine and structural members are derived is: p = p s ⎛ 1 + 1 + 2h ------⎞ ⎝ y⎠
(1)
In this formula, p = stress in pounds per square inch due to shock caused by impact of a moving load; ps = stress in pounds per square inch resulting when moving load is applied statically; h = distance in inches that load falls before striking beam, spring, or other member; y = deflection, in inches, resulting from static load. As an example of how Formula (1) may be used to obtain a formula for a specific application, suppose that the load W shown applied to the beam in Case 2 on page 261 were dropped on the beam from a height of h inches instead of being gradually applied (static loading). The maximum stress ps due to load W for Case 2 is given as Wl ÷ 4 Z and the maximum deflection y is given as Wl3 ÷ 48 EI. Substituting these values in Formula (1), 96hEI 2h Wl p = Wl ------- ⎛ 1 + 1 + ----------------------------⎞ = ------- ⎛ 1 + 1 + ----------------⎞ 4Z ⎝ 4Z ⎝ Wl 3 ⎠ Wl 3 ÷ 48EI⎠
(2)
If in Formula (2) the letter Q is used in place of W and if Z, the section modulus, is replaced by its equivalent, I ÷ distance a from neutral axis to extreme fiber of beam, then Formula (2) becomes the first formula given in the accompanying Table 1, Stresses Produced in Beams by Shocks Stresses in Helical Springs Produced by Shocks.—A load suddenly applied on a spring will produce the same deflection, and, therefore, also the same unit stress, as a static load twice as great. When the load drops from a height h, the stresses are as given in the accompanying Table 2. The approximate values are applicable when the deflection is small as compared with the height h. The formulas show that the fiber stress for a given shock will be greater in a spring made from a square bar than in one made from a round bar, if the diameter of coil be the same and the side of the square bar equals the diameter of the round
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 284
STRESSES PRODUCED BY SHOCKS
bar. It is, therefore, more economical to use round stock for springs which must withstand shocks, due to the fact that the deflection for the same fiber stress for a square bar spring is smaller than that for a round bar spring, the ratio being as 4 to 5. The round bar spring is therefore capable of storing more energy than a square bar spring for the same stress. Table 2. Stresses Produced in Springs by Shocks Form of Bar from Which Spring is Made
Fiber (Unit) Stress f Produced by Weight Q Dropped a Height h on a Helical Spring
Approximate Value of f
Round
Ghd 4 8QD f = ------------ ⎛ 1 + 1 + ------------------⎞ πd 3 ⎝ 4QD 3 n⎠
QhG f = 1.27 ------------Dd 2 n
Square
Ghd 4 f = 9QD ------------ ⎛ 1 + 1 + --------------------------⎞ 0.9πQD 3 n⎠ 4d 3 ⎝
QhG f = 1.34 ------------Dd 2 n
G = modulus of elasticity for torsion; d = diameter or side of bar; D = mean diameter of spring; n = number of coils in spring.
Shocks from Bodies in Motion.—The formulas given can be applied, in general, to shocks from bodies in motion. A body of weight W moving horizontally with the velocity of v feet per second, has a stored-up energy: 2 E K = 1--- × Wv ---------- foot-pounds 2 g
or
2 6Wv -------------- inch-pounds g
This expression may be substituted for Qh in the tables in the equations for unit stresses containing this quantity, and the stresses produced by the energy of the moving body thereby determined. The formulas in the tables give the maximum value of the stresses, providing the designer with some definitive guidance even where there may be justification for assuming that only a part of the energy of the shock is taken up by the member under stress. The formulas can also be applied using metric SI units. The stored-up energy of a body of mass M kilograms moving horizontally with the velocity of v meters per second is: E K = 1⁄2 Mv 2 newton-meters This expression may be substituted for Qh in the appropriate equations in the tables. For calculation in millimeters, Qh = 1000 EK newton-millimeters. Fatigue Stresses.—So-called "fatigue ruptures" occur in parts that are subjected to continually repeated shocks or stresses of small magnitude. Machine parts that are subjected to continual stresses in varying directions, or to repeated shocks, even if of comparatively small magnitude, may fail ultimately if designed, from a mere knowledge of the behavior of the material under a steady stress, such as is imposed upon it by ordinary tensile stress testing machines. Examinations of numerous cases of machine parts, broken under actual working conditions, indicate that at least 80 per cent of these ruptures are caused by fatigue stresses. Most fatigue ruptures are caused by bending stresses, and frequently by a revolving bending stress. Hence, to test materials for this class of stress, the tests should be made to stress the material in a manner similar to that in which it will be stressed under actual working conditions. See Fatigue Properties on page 205 for more on this topic.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STRENGTH OF COLUMNS
285
COLUMNS Strength of Columns or Struts Structural members which are subject to compression may be so long in proportion to the diameter or lateral dimensions that failure may be the result 1) of both compression and bending; and 2) of bending or buckling to such a degree that compression stress may be ignored. In such cases, the slenderness ratio is important. This ratio equals the length l of the column in inches divided by the least radius of gyration r of the cross-section. Various formulas have been used for designing columns which are too slender to be designed for compression only. Rankine or Gordon Formula.—This formula is generally applied when slenderness ratios range between 20 and 100, and sometimes for ratios up to 120. The notation, in English and metric SI units of measurement, is given on page 287. S p = ------------------------ = ultimate load, lbs. per sq. in. 2 1 + K ⎛ -l ⎞ ⎝ r⎠ Factor K may be established by tests with a given material and end condition, and for the probable range of l/r. If determined by calculation, K = S/Cπ2E. Factor C equals 1 for either rounded or pivoted column ends, 4 for fixed ends, and 1 to 4 for square flat ends. The factors 25,000, 12,500, etc., in the Rankine formulas, arranged as on page 287, equal 1/K, and have been used extensively. Straight-line Formula.—This general type of formula is often used in designing compression members for buildings, bridges, or similar structural work. It is convenient especially in designing a number of columns that are made of the same material but vary in size, assuming that factor B is known. This factor is determined by tests. l p = S y – B ⎛ - ⎞ = ultimate load, lbs. per sq. in. ⎝ r⎠ Sy equals yield point, lbs. per square inch, and factor B ranges from 50 to 100. Safe unit stress = p ÷ factor of safety. Formulas of American Railway Engineering Association.—The formulas that follow apply to structural steel having an ultimate strength of 60,000 to 72,000 pounds per square inch. For building columns having l/r ratios not greater than 120, allowable unit stress = 17,000 − 0.485 l2/r2. For columns having l/r ratios greater than 120, allowable unit stress 18 ,000 allowable unit stress = --------------------------------------1 + l 2 ⁄ 18 ,000r 2 For bridge compression members centrally loaded and with values of l/r not greater than 140: 1 l2 Allowable unit stress, riveted ends = 15 ,000 – --- ---4 r2 1 l2 Allowable unit stress, pin ends = 15 ,000 – --- ---3 r2
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Machinery's Handbook 27th Edition 286
STRENGTH OF COLUMNS
Euler Formula.—This formula is for columns that are so slender that bending or buckling action predominates and compressive stresses are not taken into account. 2 IE P = Cπ ---------------= total ultimate load, in pounds l2 The notation, in English and metric SI units of measurement, is given in the table Rankine' s and Euler' s Formulas for Columns on page 287. Factors C for different end conditions are included in the Euler formulas at the bottom of the table. According to a series of experiments, Euler formulas should be used if the values of l/r exceed the following ratios: Structural steel and flat ends, 195; hinged ends, 155; round ends, 120; cast iron with flat ends, 120; hinged ends, 100; round ends, 75; oak with flat ends, 130. The critical slenderness ratio, which marks the dividing line between the shorter columns and those slender enough to warrant using the Euler formula, depends upon the column material and its end conditions. If the Euler formula is applied when the slenderness ratio is too small, the calculated ultimate strength will exceed the yield point of the material and, obviously, will be incorrect. Eccentrically Loaded Columns.—In the application of the column formulas previously referred to, it is assumed that the action of the load coincides with the axis of the column. If the load is offset relative to the column axis, the column is said to be eccentrically loaded, and its strength is then calculated by using a modification of the Rankine formula, the quantity cz/r2 being added to the denominator, as shown in the table on the next page. This modified formula is applicable to columns having a slenderness ratio varying from 20 or 30 to about 100. Machine Elements Subjected to Compressive Loads.—As in structural compression members, an unbraced machine member that is relatively slender (i.e., its length is more than, say, six times the least dimension perpendicular to its longitudinal axis) is usually designed as a column, because failure due to overloading (assuming a compressive load centrally applied in an axial direction) may occur by buckling or a combination of buckling and compression rather than by direct compression alone. In the design of unbraced steel machine “columns” which are to carry compressive loads applied along their longitudinal axes, two formulas are in general use:
(Euler)
S y Ar 2 P cr = -------------Q
(1)
Sy l 2 Q = ------------ (3) nπ 2 E In these formulas, Pcr = critical load in pounds that would result in failure of the column; A = cross-sectional area, square inches; Sy = yield point of material, pounds per square inch; r = least radius of gyration of cross-section, inches; E = modulus of elasticity, pounds per square inch; l = column length, inches; and n = coefficient for end conditions. For both ends fixed, n = 4; for one end fixed, one end free, n = 0.25; for one end fixed and the other end free but guided, n = 2; for round or pinned ends, free but guided, n = 1; and for flat ends, n = 1 to 4. It should be noted that these values of n represent ideal conditions that are seldom attained in practice; for example, for both ends fixed, a value of n = 3 to 3.5 may be more realistic than n = 4. If metric SI units are used in these formulas, Pcr = critical load in newtons that would result in failure of the column; A = cross-sectional area, square millimeters; Sy = yield point of the material, newtons per square mm; r = least radius of gyration of cross-section, mm; E = modulus of elasticity, newtons per square mm; l = column length, mm; and n = a coefficient for end conditions. The coefficients given are valid for calculations in metric units. (J. B. Johnson)
Q P cr = AS y ⎛ 1 – --------⎞ ⎝ 4r 2⎠
(2)
where
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RANKINE AND EULER FORMULAS
287
Rankine's and Euler's Formulas for Columns Symbol p P S l r I r2 E c z
Quantity Ultimate unit load Total ultimate load Ultimate compressive strength of material Length of column or strut Least radius of gyration Least moment of inertia Moment of inertia/area of section Modulus of elasticity of material Distance from neutral axis of cross-section to side under compression Distance from axis of load to axis coinciding with center of gravity of cross-section
English Unit Lbs./sq. in. Pounds Lbs./sq. in. Inches Inches Inches4 Inches2 Lbs./sq. in.
Metric SI Units Newtons/sq. mm. Newtons Newtons/sq. mm. Millimeters Millimeters Millimeters4 Millimeters2 Newtons/sq. mm.
Inches
Millimeters
Inches
Millimeters
Rankine's Formulas Both Ends of One End Fixed and Column Fixed One End Rounded
Material
Both Ends Rounded
Steel
S p = -------------------------------l2 1 + ---------------------25 ,000r 2
S p = -------------------------------l2 1 + ---------------------12 ,500r 2
S p = --------------------------l2 1 + ----------------6250r 2
Cast Iron
S p = -------------------------l2 1 + ----------------5000r 2
S p = -------------------------l2 1 + ----------------2500r 2
S p = -------------------------l2 1 + ----------------1250r 2
Wrought Iron
S p = ------------------------------l2 1 + --------------------35 ,000r 2
S p = ------------------------------l2 1 + --------------------17 ,500r 2
S p = -------------------------l2 1 + ---------------8750r 2
Timber
S p = --------------------------l2 1 + ----------------3000r 2
S p = --------------------------l2 1 + ----------------1500r 2
S p = -----------------------l2 1 + -------------750r 2
Formulas Modified for Eccentrically Loaded Columns Material
Steel
Both Ends of Column Fixed
One End Fixed and One End Rounded
Both Ends Rounded
S p = ------------------------------------------l2 cz 1 + ---------------------- + ----25 ,000r 2 r 2
S p = ------------------------------------------l2 cz 1 + ---------------------- + ----12 ,500r 2 r 2
S p = -------------------------------------2 l cz 1 + ----------------- + ----6250r 2 r 2
For materials other than steel, such as cast iron, use the Rankine formulas given in the upper table and add to the denominator the quantity cz ⁄ r 2 Both Ends of Column Fixed 2 IE P = 4π --------------l2
Euler's Formulas for Slender Columns One End Fixed and Both Ends One End Rounded Rounded 2 IE P = 2π --------------l2
2 IE P = π ----------l2
One End Fixed and One End Free 2 IE P = π ----------4l 2
Allowable Working Loads for Columns: To find the total allowable working load for a given section, divide the total ultimate load P (or p × area), as found by the appropriate formula above, by a suitable factor of safety.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 288
COLUMNS
Factor of Safety for Machine Columns: When the conditions of loading and the physical qualities of the material used are accurately known, a factor of safety as low as 1.25 is sometimes used when minimum weight is important. Usually, however, a factor of safety of 2 to 2.5 is applied for steady loads. The factor of safety represents the ratio of the critical load Pcr to the working load. Application of Euler and Johnson Formulas: To determine whether the Euler or Johnson formula is applicable in any particular case, it is necessary to determine the value of the quantity Q ÷ r2. If Q ÷ r2 is greater than 2, then the Euler Formula (1) should be used; if Q ÷ r2 is less than 2, then the J. B. Johnson formula is applicable. Most compression members in machine design are in the range of proportions covered by the Johnson formula. For this reason a good procedure is to design machine elements on the basis of the Johnson formula and then as a check calculate Q ÷ r2 to determine whether the Johnson formula applies or the Euler formula should have been used. Example 1, Compression Member Design:A rectangular machine member 24 inches long and 1⁄2 × 1 inch in cross-section is to carry a compressive load of 4000 pounds along its axis. What is the factor of safety for this load if the material is machinery steel having a yield point of 40,000 pounds per square inch, the load is steady, and each end of the rod has a ball connection so that n = 1? From Formula (3) 40 ,000 × 24 × 24 Q = ---------------------------------------------------------------------------------- = 0.0778 1 × 3.1416 × 3.1416 × 30 ,000 ,000 (The values 40,000 and 30,000,000 were obtained from the table Strength Data for Iron and Steel on page 474.) The radius of gyration r for a rectangular section (page 239) is 0.289 × the dimension in the direction of bending. In columns, bending is most apt to occur in the direction in which the section is the weakest, the 1⁄2-inch dimension in this example. Hence, least radius of gyration r = 0.289 × 1⁄2 = 0.145 inch. Q 0.0778 = 3.70 ---- = -------------------r2 ( 0.145 ) 2 which is more than 2 so that the Euler formula will be used. s y Ar 2 40 ,000 × 1⁄2 × 1 P cr = ------------- = ----------------------------------3.70 Q = 5400 pounds so that the factor of safety is 5400 ÷ 4000 = 1.35 Example 2, Compression Member Design:In the preceding example, the column formulas were used to check the adequacy of a column of known dimensions. The more usual problem involves determining what the dimensions should be to resist a specified load. For example,: A 24-inch long bar of rectangular cross-section with width w twice its depth d is to carry a load of 4000 pounds. What must the width and depth be if a factor of safety of 1.35 is to be used? First determine the critical load Pcr: P cr = working load × factor of safety = 4000 × 1.35 = 5400 pounds
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Machinery's Handbook 27th Edition COLUMNS
289
Next determine Q which, as in Example 1, will be 0.0778. Assume Formula (2) applies: Q-⎞ P cr = As y ⎛ 1 – ------⎝ 4r 2⎠ 0.0778 5400 = w × d × 40 ,000 ⎛ 1 – ----------------⎞ ⎝ 4r 2 ⎠ 0.01945 = 2d 2 × 40 ,000 ⎛⎝ 1 – -------------------⎞⎠ r2 5400 0.01945 -------------------------- = d 2 ⎛ 1 – -------------------⎞ ⎝ 40 ,000 × 2 r2 ⎠ As mentioned in Example 1 the least radius of gyration r of a rectangle is equal to 0.289 times the least dimension, d, in this case. Therefore, substituting for d the value r ÷ 0.289, 5400 r -⎞ 2 ⎛ 1 – 0.01945 -------------------------------------------⎞ = ⎛ -----------⎝ 0.289⎠ ⎝ 40 ,000 × 2 r2 ⎠ 5400 × 0.289 × 0.289-------------------------------------------------= r 2 – 0.01945 40 ,000 × 2 0.005638 = r 2 – 0.01945 r 2 = 0.0251 Checking to determine if Q ÷ r2 is greater or less than 2, Q = 0.0778 ------------------- = 3.1 0.0251 r2 therefore Formula (1) should have been used to determine r and dimensions w and d. Using Formula (1), 2
r -⎞ r 2 40 ,000 × 2 × ⎛ -----------⎝ 0.289⎠ × - = ----------------------------------------------------------,000 × -----------------------------------------5400 = 40 Q 0.0778 2d 2
r2
× 0.0778 × 0.289 × 0.289- = 0.0004386 r 4 = 5400 ------------------------------------------------------------------------40 ,000 × 2 0.145 d = ------------- = 0.50 inch 0.289 and w = 2d = 1 inch as in the previous example. American Institute of Steel Construction.—For main or secondary compression members with l/r ratios up to 120, safe unit stress = 17,000 − 0.485l2/r2. For columns and bracing or other secondary members with l/r ratios above 120, 18 ,000 Safe unit stress, psi = --------------------------------------- for bracing and secondary members. For main 1 + l 2 ⁄ 18 ,000r 2 18 ,000 l ⁄ r-⎞ members, safe unit stress, psi = --------------------------------------- × ⎛ 1.6 – -------200⎠ 1 + l 2 ⁄ 18 ,000r 2 ⎝ Pipe Columns: Allowable concentric loads for steel pipe columns based on the above formulas are given in the table on page 290.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 290
ALLOWABLE LOADS FOR STEEL PIPE COLUMNS Allowable Concentric Loads for Steel Pipe Columns STANDARD STEEL PIPE 12
10
8
6
5
4
31⁄2
3
Wall Thickness, Inch
0.375
0.365
0.322
0.280
0.258
0.237
0.226
0.216
Weight per Foot, Pounds
49.56
40.48
28.55
18.97
14.62
10.79
9.11
7.58
Nominal Diameter, Inches
Effective Length (KL), Feeta 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 22 24 25 26
Allowable Concentric Loads in Thousands of Pounds 303 301 299 296 293 291 288 285 282 278 275 272 268 265 261 254 246 242 238
246 243 241 238 235 232 229 226 223 220 216 213 209 205 201 193 185 180 176
171 168 166 163 161 158 155 152 149 145 142 138 135 131 127 119 111 106 102
110 108 106 103 101 98 95 92 89 86 82 79 75 71 67 59 51 47 43
83 81 78 76 73 71 68 65 61 58 55 51 47 43 39 32 27 25 23
59 57 54 52 49 46 43 40 36 33 29 26 23 21 19 15 13 12
48 46 44 41 38 35 32 29 25 22 19 17 15 14 12 10
38 36 34 31 28 25 22 19 16 14 12 11 10 9
EXTRA STRONG STEEL PIPE Nominal Diameter, Inches Wall Thickness, Inch Weight per Foot, Pounds Effective Length (KL), Feeta 6 7 8 9 10 11 12 13 14 15 16 18 19 20 21 22 24 26 28
12 0.500 65.42 400 397 394 390 387 383 379 375 371 367 363 353 349 344 337 334 323 312 301
31⁄2 10 8 6 5 4 0.500 0.500 0.432 0.375 0.337 0.318 54.74 43.39 28.57 20.78 14.98 12.50 Allowable Concentric Loads in Thousands of Pounds 332 259 166 118 81 66 328 255 162 114 78 63 325 251 159 111 75 59 321 247 155 107 71 55 318 243 151 103 67 51 314 239 146 99 63 47 309 234 142 95 59 43 305 229 137 91 54 38 301 224 132 86 49 33 296 219 127 81 44 29 291 214 122 76 39 25 281 203 111 65 31 20 276 197 105 59 28 18 271 191 99 54 25 16 265 185 92 48 22 14 260 179 86 44 21 248 166 73 37 17 236 152 62 32 224 137 54 27
3 0.300 10.25 52 48 45 41 37 33 28 24 21 18 16 12 11
a With respect to radius of gyration. The effective length (KL) is the actual unbraced length, L, in feet, multiplied by the effective length factor (K) which is dependent upon the restraint at the ends of the unbraced length and the means available to resist lateral movements. K may be determined by referring to the last portion of this table.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition ALLOWABLE LOADS FOR STEEL PIPE COLUMNS
291
Allowable Concentric Loads for Steel Pipe Columns (Continued) DOUBLE-EXTRA STRONG STEEL PIPE Nominal Diameter, Inches
8
6
5
4
3
Wall Thickness, Inch
0.875
0.864
0.750
0.674
0.600
Weight per Foot, Pounds
72.42
53.16
38.55
27.54
18.58
Effective Length (KL), Feeta
Allowable Concentric Loads in Thousands of Pounds
6
431
306
216
147
91
7
424
299
209
140
84
8
417
292
202
133
77
9
410
284
195
126
69
10
403
275
187
118
60
11
395
266
178
109
51
12
387
257
170
100
43
13
378
247
160
91
37
14
369
237
151
81
32
15
360
227
141
70
28
16
351
216
130
62
24
17
341
205
119
55
22
18
331
193
108
49
19
321
181
97
44
20
310
168
87
40
22
288
142
72
33
24
264
119
61
26
240
102
52
28
213
88
44
EFFECTIVE LENGTH FACTORS (K) FOR VARIOUS COLUMN CONFIGURATIONS (a)
(b)
(c)
(d)
(e)
(f)
Buckled shape of column is shown by dashed line
Theoretical K value
0.5
0.7
1.0
1.0
2.0
2.0
Recommended design value when ideal conditions are approximated
0.65
0.80
1.2
1.0
2.10
2.0
Rotation fixed and translation fixed Rotation free and translation fixed End condition code Rotation fixed and translation free Rotation free and translation free
Load tables are given for 36 ksi yield stress steel. No load values are given below the heavy horizontal lines, because the Kl/r ratios (where l is the actual unbraced length in inches and r is the governing radius of gyration in inches) would exceed 200. Data from “Manual of Steel Construction,” 8th ed., 1980, with permission of the American Institute of Steel Construction.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 292
PLATES, SHELLS, AND CYLINDERS
PLATES, SHELLS, AND CYLINDERS Flat Stayed Surfaces.—Large flat areas are often held against pressure by stays distributed at regular intervals over the surface. In boiler work, these stays are usually screwed into the plate and the projecting end riveted over to insure steam tightness. The U.S. Board of Supervising Inspectors and the American Boiler Makers Association rules give the following formula for flat stayed surfaces: C × t 2P = ------------S2 in which P =pressure in pounds per square inch C =a constant, which equals 112 for plates 7⁄16 inch and under 120, for plates over 7⁄16 inch thick 140, for plates with stays having a nut and bolt on the inside and outside 160, for plates with stays having washers of at least one-half the thickness of the plate, and with a diameter at least one-half of the greatest pitch t =thickness of plate in 16ths of an inch (thickness = 7⁄16, t = 7) S =greatest pitch of stays in inches Strength and Deflection of Flat Plates.—Generally, the formulas used to determine stresses and deflections in flat plates are based on certain assumptions that can be closely approximated in practice. These assumptions are: 1) the thickness of the plate is not greater than one-quarter the least width of the plate; 2) the greatest deflection when the plate is loaded is less than one-half the plate thickness; 3) the maximum tensile stress resulting from the load does not exceed the elastic limit of the material; and 4) all loads are perpendicular to the plane of the plate. Plates of ductile materials fail when the maximum stress resulting from deflection under load exceeds the yield strength; for brittle materials, failure occurs when the maximum stress reaches the ultimate tensile strength of the material involved. Square and Rectangular Flat Plates.—The formulas that follow give the maximum stress and deflection of flat steel plates supported in various ways and subjected to the loading indicated. These formulas are based upon a modulus of elasticity for steel of 30,000,000 pounds per square inch and a value of Poisson's ratio of 0.3. If the formulas for maximum stress, S, are applied without modification to other materials such as cast iron, aluminum, and brass for which the range of Poisson's ratio is about 0.26 to 0.34, the maximum stress calculations will be in error by not more than about 3 per cent. The deflection formulas may also be applied to materials other than steel by substituting in these formulas the appropriate value for E, the modulus of elasticity of the material (see pages 474 and 554). The deflections thus obtained will not be in error by more than about 3 per cent. In the stress and deflection formulas that follow, p =uniformly distributed load acting on plate, pounds per square inch W =total load on plate, pounds; W = p × area of plate L =distance between supports (length of plate), inches. For rectangular plates, L = long side, l = short side t =thickness of plate, inches S =maximum tensile stress in plate, pounds per square inch d =maximum deflection of plate, inches E =modulus of elasticity in tension. E = 30,000,000 pounds per square inch for steel
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition PLATES, SHELLS, AND CYLINDERS
293
If metric SI units are used in the formulas, then, W =total load on plate, newtons L =distance between supports (length of plate), millimeters. For rectangular plates, L = long side, l = short side t =thickness of plate, millimeters S =maximum tensile stress in plate, newtons per mm squared d =maximum deflection of plate, mm E =modulus of elasticity, newtons per mm squared a) Square flat plate supported at top and bottom of all four edges and a uniformly distributed load over the surface of the plate. 0.0443WL 2S = 0.29W --------------(1) (2) d = --------------------------t2 Et 3 b) Square flat plate supported at the bottom only of all four edges and a uniformly distributed load over the surface of the plate. 0.0443WL 2 S = 0.28W --------------(3) d = --------------------------(4) t2 Et 3 c) Square flat plate with all edges firmly fixed and a uniformly distributed load over the surface of the plate. 0.0138WL 2 S = 0.31W --------------(5) d = --------------------------(6) t2 Et 3 d) Square flat plate with all edges firmly fixed and a uniform load over small circular area at the center. In Equations (7) and (9), r0 = radius of area to which load is applied. If r0 < 1.7t, use rs where r s =
1.6r 0 2 + t 2 – 0.675t .
L -⎞ S = 0.62W --------------- log ⎛ ------e⎝ 2r ⎠ t2 0
0.0568WL 2d = --------------------------(8) Et 3 e) Square flat plate with all edges supported above and below, or below only, and a concentrated load at the center. (See Case 4, above, for definition of r0). (7)
L -⎞ + 0.577 S = 0.62W --------------- log ⎛ ------e⎝ 2r ⎠ t2 0
2 (10) d = 0.1266WL ---------------------------Et 3 f) Rectangular plate with all edges supported at top and bottom and a uniformly distributed load over the surface of the plate.
(9)
0.75W 0.1422W (11) (12) S = -----------------------------------d = ----------------------------------L 2.21 l2 ⎞ Et 3 ⎛⎝ ---- + ----------⎞⎠ t2 ⎛ L --- + 1.61 ----3 2 ⎝l ⎠ 2 l L L g) Rectangular plate with all edges fixed and a uniformly distributed load over the surface of the plate. 0.5W S = -------------------------------------5 t2 ⎛ L --- + 0.623l ------------------⎞ ⎝l L5 ⎠
(13)
0.0284W d = ------------------------------------------L- + ----------------1.056l 2-⎞ Et 3 ⎛ --⎝ l3 L4 ⎠
Copyright 2004, Industrial Press, Inc., New York, NY
(14)
Machinery's Handbook 27th Edition 294
PLATES, SHELLS, AND CYLINDERS
Circular Flat Plates.—In the following formulas, R = radius of plate to supporting edge in inches; W = total load in pounds; and other symbols are the same as used for square and rectangular plates. If metric SI units are used, R = radius of plate to supporting edge in millimeters, and the values of other symbols are the same as those used for square and rectangular plates. a) Edge supported around the circumference and a uniformly distributed load over the surface of the plate. 0.221WR 2S = 0.39W --------------(15) (16) d = -----------------------t2 Et 3 b) Edge fixed around circumference and a uniformly distributed load over the surface of the plate. 0.0543WR 2 (17) S = 0.24W --------------(18) d = --------------------------t2 Et 3 c) Edge supported around the circumference and a concentrated load at the center. 0.55WR 2 R - – 0.0185 ----t 2d = ------------------------------------ 1 + 1.3 loge -------------(19) S = 0.48W 0.325t Et 3 R2 t2 d) Edge fixed around circumference and a concentrated load at the center. R t 2S = 0.62W --------------- loge --------------- + 0.0264 ----0.325t t2 R2
(21)
0.22WR 2 d = ---------------------Et 3
(20)
(22)
Strength of Cylinders Subjected to Internal Pressure.—In designing a cylinder to withstand internal pressure, the choice of formula to be used depends on 1) the kind of material of which the cylinder is made (whether brittle or ductile); 2) the construction of the cylinder ends (whether open or closed); and 3) whether the cylinder is classed as a thin- or a thick-walled cylinder. A cylinder is considered to be thin-walled when the ratio of wall thickness to inside diameter is 0.1 or less and thick-walled when this ratio is greater than 0.1. Materials such as cast iron, hard steel, cast aluminum are considered to be brittle materials; low-carbon steel, brass, bronze, etc. are considered to be ductile. In the formulas that follow, p = internal pressure, pounds per square inch; D = inside diameter of cylinder, inches; t = wall thickness of cylinder, inches; µ = Poisson's ratio, = 0.3 for steel, 0.26 for cast iron, 0.34 for aluminum and brass; and S = allowable tensile stress, pounds per square inch. Metric SI units can be used in Formulas (23), (25), (26), and (27), where p = internal pressure in newtons per square millimeter; D = inside diameter of cylinder, millimeters; t = wall thickness, mm; µ = Poisson's ratio, = 0.3 for steel, 0.26 for cast iron, and 0.34 for aluminum and brass; and S = allowable tensile stress, N/mm2. For the use of metric SI units in Formula (24), see below. Dp Thin-walled Cylinders: (23) t = ------2S For low-pressure cylinders of cast iron such as are used for certain engine and press applications, a formula in common use is Dp t = ------------ + 0.3 2500
Copyright 2004, Industrial Press, Inc., New York, NY
(24)
Machinery's Handbook 27th Edition PLATES, SHELLS, AND CYLINDERS
295
This formula is based on allowable stress of 1250 pounds per square inch and will give a wall thickness 0.3 inch greater than Formula (23) to allow for variations in metal thickness that may result from the casting process. If metric SI units are used in Formula (24), t = cylinder wall thickness in millimeters; D = inside diameter of cylinder, mm; and the allowable stress is in newtons per square millimeter. The value of 0.3 inches additional wall thickness is 7.62 mm, and the next highest number in preferred metric basic sizes is 8 mm. Thick-walled Cylinders of Brittle Material, Ends Open or Closed: Lamé's equation is used when cylinders of this type are subjected to internal pressure. + p- – 1⎞ t = D ---- ⎛ S----------⎠ 2⎝ S–p
(25)
The table Ratio of Outside Radius to Inside Radius, Thick Cylinders on page 296 is for convenience in calculating the dimensions of cylinders under high internal pressure without the use of Formula (25). Example, Use of the Table:Assume that a cylinder of 10 inches inside diameter is to withstand a pressure of 2500 pounds per square inch; the material is cast iron and the allowable stress is 6000 pounds per square inch. To solve the problem, locate the allowable stress per square inch in the left-hand column of the table and the working pressure at the top of the columns. Then find the ratio between the outside and inside radii in the body of the table. In this example, the ratio is 1.558, and hence the outside diameter of the cylinder should be 10 × 1.558, or about 155⁄8 inches. The thickness of the cylinder wall will therefore be (15.558 − 10)/2 = 2.779 inches. Unless very high-grade material is used and sound castings assured, cast iron should not be used for pressures exceeding 2000 pounds per square inch. It is well to leave more metal in the bottom of a hydraulic cylinder than is indicated by the results of calculations, because a hole of some size must be cored in the bottom to permit the entrance of a boring bar when finishing the cylinder, and when this hole is subsequently tapped and plugged it often gives trouble if there is too little thickness. For steady or gradually applied stresses, the maximum allowable fiber stress S may be assumed to be from 3500 to 4000 pounds per square inch for cast iron; from 6000 to 7000 pounds per square inch for brass; and 12,000 pounds per square inch for steel castings. For intermittent stresses, such as in cylinders for steam and hydraulic work, 3000 pounds per square inch for cast iron; 5000 pounds per square inch for brass; and 10,000 pounds per square inch for steel castings, is ordinarily used. These values give ample factors of safety. Note: In metric SI units, 1000 pounds per square inch equals 6.895 newtons per square millimeter. Thick-walled Cylinders of Ductile Material, Closed Ends: Clavarino's equation is used: D t = ---2
S + ( 1 – 2µ )p --------------------------------- – 1 S – ( 1 + µ )p
(26)
Thick-walled Cylinders of Ductile Material, Open Ends: Birnie's equation is used: t = D ---2
S----------------------------+ ( 1 – µ )p- – 1 S – ( 1 + µ )p
Spherical Shells Subjected to Internal Pressure.—Let: D =internal diameter of shell in inches p =internal pressure in pounds per square inch S =safe tensile stress per square inch t =thickness of metal in the shell, in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
(27)
Machinery's Handbook 27th Edition 296
PLATES, SHELLS, AND CYLINDERS Ratio of Outside Radius to Inside Radius, Thick Cylinders Working Pressure in Cylinder, Pounds per Square Inch
Allowable Stress in Metal per Sq. In. of Section 2,000 2,500 3,000 3,500 4,000 4,500 5000 5,500 6,000 6,500 7,000 7,500 8,000 8,500 9,000 9,500 10,000 10,500 11,000 11,500 12,000 12,500 13,000 13,500 14,000 14,500 15,000 16,000
1000
2000
3000
4000
5000
6000
7000
1.732 1.527 1.414 1.341 1.291 1.253 1.224 1.201 1.183 … … … … … … … … … … … … … … … … … … …
… … 2.236 1.915 1.732 1.612 1.527 1.464 1.414 1.374 1.341 1.314 1.291 1.271 1.253 1.235 1.224 1.212 1.201 1.193 1.183 … … … … … … …
… … … … 2.645 2.236 2.000 1.844 1.732 1.647 1.581 1.527 1.483 1.446 1.414 1.386 1.362 1.341 1.322 1.306 1.291 1.277 1.264 1.253 1.243 1.233 1.224 1.209
… … … … … … 3.000 2.516 2.236 2.049 1.914 1.813 1.732 1.666 1.612 1.566 1.527 1.493 1.464 1.437 1.414 1.393 1.374 1.357 1.341 1.327 1.314 1.291
… … … … … … … … 3.316 2.768 2.449 2.236 2.081 1.963 1.871 1.795 1.732 1.678 1.633 1.593 1.558 1.527 1.500 1.475 1.453 1.432 1.414 1.381
… … … … … … … … … … 3.605 3.000 2.645 2.408 2.236 2.104 2.000 1.915 1.844 1.784 1.732 1.687 1.647 1.612 1.581 1.553 1.527 1.483
… … … … … … … … … … … … 3.872 3.214 2.828 2.569 2.380 2.236 2.121 2.027 1.949 1.878 1.825 1.775 1.732 1.693 1.658 1.599
pD Then, t = ------4S This formula also applies to hemi-spherical shells, such as the hemi-spherical head of a cylindrical container subjected to internal pressure, etc. If metric SI units are used, then: D =internal diameter of shell in millimeters p =internal pressure in newtons per square millimeter S =safe tensile stress in newtons per square millimeter t =thickness of metal in the shell in millimeters Meters can be used in the formula in place of millimeters, providing the treatment is consistent throughout.
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Machinery's Handbook 27th Edition PLATES, SHELLS, AND CYLINDERS
297
Example:Find the thickness of metal required in the hemi-spherical end of a cylindrical vessel, 2 feet in diameter, subjected to an internal pressure of 500 pounds per square inch. The material is mild steel and a tensile stress of 10,000 pounds per square inch is allowable. × 2 × 12- = 0.3 inch t = 500 ----------------------------4 × 10 ,000 A similar example using metric SI units is as follows: find the thickness of metal required in the hemi-spherical end of a cylindrical vessel, 750 mm in diameter, subjected to an internal pressure of 3 newtons/mm2. The material is mild steel and a tensile stress of 70 newtons/mm2 is allowable. 3 × 750 t = ------------------ = 8.04 mm 4 × 70 If the radius of curvature of the domed head of a boiler or container subjected to internal pressure is made equal to the diameter of the boiler, the thickness of the cylindrical shell and of the spherical head should be made the same. For example, if a boiler is 3 feet in diameter, the radius of curvature of its head should also be 3 feet, if material of the same thickness is to be used and the stresses are to be equal in both the head and cylindrical portion. Collapsing Pressure of Cylinders and Tubes Subjected to External Pressures.—The following formulas may be used for finding the collapsing pressures of lap-welded Bessemer steel tubes: (28) P = 86 ,670 ---t- – 1386 D 3 P = 50 ,210 ,000 ⎛ ---t-⎞ ⎝ D⎠
(29)
in which P = collapsing pressure in pounds per square inch; D = outside diameter of tube or cylinder in inches; t = thickness of wall in inches. Formula (28) is for values of P greater than 580 pounds per square inch, and Formula (29) is for values of P less than 580 pounds per square inch. These formulas are substantially correct for all lengths of pipe greater than six diameters between transverse joints that tend to hold the pipe to a circular form. The pressure P found is the actual collapsing pressure, and a suitable factor of safety must be used. Ordinarily, a factor of safety of 5 is sufficient. In cases where there are repeated fluctuations of the pressure, vibration, shocks and other stresses, a factor of safety of from 6 to 12 should be used. If metric SI units are used the formulas are: (30) P = 597.6 ---t- – 9.556 D 3 P = 346 ,200 ⎛ ---t-⎞ ⎝ D⎠
(31)
where P = collapsing pressure in newtons per square millimeter; D = outside diameter of tube or cylinder in millimeters; and t = thickness of wall in millimeters. Formula (30) is for values of P greater than 4 N/mm2, and Formula (31) is for values of P less than 4 N/mm2. The table Tubes Subjected to External Pressure is based upon the requirements of the Steam Boat Inspection Service of the Department of Commerce and Labor and gives the permissible working pressures and corresponding minimum wall thickness for long, plain, lap-welded and seamless steel flues subjected to external pressure only. The table thicknesses have been calculated from the formula:
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 298
PLATES, SHELLS, AND CYLINDERS
( F × p ) + 1386 ]D t = [--------------------------------------------86 ,670 in which D = outside diameter of flue or tube in inches; t = thickness of wall in inches; p = working pressure in pounds per square inch; F = factor of safety. The formula is applicable to working pressures greater than 100 pounds per square inch, to outside diameters from 7 to 18 inches, and to temperatures less than 650°F. The preceding Formulas (28) and (29) were determined by Prof. R. T. Stewart, Dean of the Mechanical Engineering Department of the University of Pittsburgh, in a series of experiments carried out at the plant of the National Tube Co., McKeesport, Pa. The apparent fiber stress under which the different tubes failed varied from about 7000 pounds per square inch for the relatively thinnest to 35,000 pounds per square inch for the relatively thickest walls. The average yield point of the material tested was 37,000 pounds and the tensile strength 58,000 pounds per square inch, so it is evident that the strength of a tube subjected to external fluid collapsing pressure is not dependent alone upon the elastic limit or ultimate strength of the material from which it is made. Tubes Subjected to External Pressure Outside Diameter of Tube, Inches
100
Working Pressure in Pounds per Square Inch
7 8 9 10 11 12 13 14 15 16 16 18
0.152 0.174 0.196 0.218 0.239 0.261 0.283 0.301 0.323 0.344 0.366 0.387
120
140
160
180
200
220
Thickness of Tube in Inches. Safety Factor, 5 0.160 0.183 0.206 0.229 0.252 0.275 0.298 0.320 0.343 0.366 0.389 0.412
0.168 0.193 0.217 0.241 0.265 0.289 0.313 0.337 0.361 0.385 0.409 0.433
0.177 0.202 0.227 0.252 0.277 0.303 0.328 0.353 0.378 0.404 0.429 0.454
0.185 0.211 0.237 0.264 0.290 0.317 0.343 0.369 0.396 0.422 0.448 0.475
0.193 0.220 0.248 0.275 0.303 0.330 0.358 0.385 0.413 0.440 0.468 0.496
0.201 0.229 0.258 0.287 0.316 0.344 0.373 0.402 0.430 0.459 0.488 0.516
Dimensions and Maximum Allowable Pressure of Tubes Subjected to External Pressure
Outside Dia., Inches
ThickMax. ness Pressure of Allowed, Material, psi Inches
Outside Dia., Inches
ThickMax. ness Pressure of Allowed, Material, psi Inches
Outside Dia., Inches
ThickMax. ness Pressure of Allowed, Material, psi Inches
2
0.095
427
3
0.109
327
4
0.134
21⁄4
0.095
380
31⁄4
0.120
332
41⁄2
0.134
238
21⁄2
0.109
392
31⁄2
0.120
308
5
0.148
235
23⁄4
0.109
356
33⁄4
0.120
282
6
0.165
199
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303
Machinery's Handbook 27th Edition SHAFTS
299
SHAFTS Shaft Calculations Torsional Strength of Shafting.—In the formulas that follow, α =angular deflection of shaft in degrees c =distance from center of gravity to extreme fiber D =diameter of shaft in inches G =torsional modulus of elasticity = 11,500,000 pounds per square inch for steel J =polar moment of inertia of shaft cross-section (see table) l =length of shaft in inches N =angular velocity of shaft in revolutions per minute P =power transmitted in horsepower Ss =allowable torsional shearing stress in pounds per square inch T =torsional or twisting moment in inch-pounds Zp =polar section modulus (see table page 249) The allowable twisting moment for a shaft of any cross-section such as circular, square, etc., is: T = Ss × Zp
(1)
For a shaft delivering P horsepower at N revolutions per minute the twisting moment T being transmitted is: ,000PT = 63 -------------------N
(2)
The twisting moment T as determined by this formula should be less than the value determined by using Formula (7) if the maximum allowable stress Ss is not to be exceeded. The diameter of a solid circular shaft required to transmit a given torque T is: D =
3
5.1T ----------Ss
(3a)
or
D =
3
321 ,000 P----------------------NS s
(3b)
The allowable stresses that are generally used in practice are: 4000 pounds per square inch for main power-transmitting shafts; 6000 pounds per square inch for lineshafts carrying pulleys; and 8500 pounds per square inch for small, short shafts, countershafts, etc. Using these allowable stresses, the horsepower P transmitted by a shaft of diameter D, or the diameter D of a shaft to transmit a given horsepower P may be determined from the following formulas: For main power-transmitting shafts: 3
D NP = ---------80
(4a)
or
D =
3
80P ---------N
(4b)
53.5P -------------N
(5b)
For lineshafts carrying pulleys: 3
D N P = ----------53.5
(5a)
or
D =
3
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Machinery's Handbook 27th Edition 300
SHAFTS
For small, short shafts: 3 38PD ND = 3 --------(6b) or P = ---------(6a) N 38 Shafts that are subjected to shocks, such as sudden starting and stopping, should be given a greater factor of safety resulting in the use of lower allowable stresses than those just mentioned. Example:What should be the diameter of a lineshaft to transmit 10 horsepower if the shaft is to make 150 revolutions per minute? Using Formula (5b),
D =
3
53.5 × 10 = 1.53 or, say, 1 9⁄ inches ---------------------16 150
Example:What horsepower would be transmitted by a short shaft, 2 inches in diameter, carrying two pulleys close to the bearings, if the shaft makes 300 revolutions per minute? Using Formula (6a), 3
2 × 300 = 63 horsepower P = -------------------38 Torsional Strength of Shafting, Calculations in Metric SI Units.—T h e a l l o w a b l e twisting moment for a shaft of any cross-section such as circular, square, etc., can be calculated from: T = Ss × Zp (7) where T = torsional or twisting moment in newton-millimeters; Ss = allowable torsional shearing stress in newtons per square millimeter; and Zp = polar section modulus in millimeters3. For a shaft delivering power of P kilowatts at N revolutions per minute, the twisting moment T being transmitted is: 6
6
10 P 9.55 × 10 P or T = -----------T = ----------------------------(8a) (8) N ω where T is in newton-millimeters, and ω = angular velocity in radians per second. The diameter D of a solid circular shaft required to transmit a given torque T is: D =
3
5.1T ----------Ss
(9a)
6
or
D =
3
48.7 × 10 P ----------------------------NS s
or
D =
3
5.1 × 10 P -------------------------ωS s
(9b)
6
(9c)
where D is in millimeters; T is in newton-millimeters; P is power in kilowatts; N = revolutions per minute; Ss = allowable torsional shearing stress in newtons per square millimeter, and ω = angular velocity in radians per second. If 28 newtons/mm2 and 59 newtons/mm2 are taken as the generally allowed stresses for main power-transmitting shafts and small short shafts, respectively, then using these allowable stresses, the power P transmitted by a shaft of diameter D, or the diameter D of a shaft to transmit a given power P may be determined from the following formulas:
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Machinery's Handbook 27th Edition SHAFTS
301
For main power-transmitting shafts: 3
6
D N P = ------------------------(10a) 6 1.77 × 10 For small, short shafts:
or
D =
3
1.77 × 10 P ----------------------------N
(10b)
3
6 D N × 10 P P = ------------------------(11a) or D = 3 0.83 (11b) ----------------------------6 N 0.83 × 10 where P is in kilowatts, D is in millimeters, and N = revolutions per minute. Example:What should be the diameter of a power-transmitting shaft to transmit 150 kW at 500 rpm? 6
D =
3
1.77 × 10 × 150 ---------------------------------------- = 81 millimeters 500
Example:What power would a short shaft, 50 millimeters in diameter, transmit at 400 rpm? 3
50 × 400 P = ------------------------- = 60 kilowatts 6 0.83 × 10 Torsional Deflection of Circular Shafts.—Shafting must often be proportioned not only to provide the strength required to transmit a given torque, but also to prevent torsional deflection (twisting) through a greater angle than has been found satisfactory for a given type of service. For a solid circular shaft the torsional deflection in degrees is given by: α = 584Tl -------------(12) 4 D G Example:Find the torsional deflection for a solid steel shaft 4 inches in diameter and 48 inches long, subjected to a twisting moment of 24,000 inch-pounds. By Formula (12), 584 × 24 ,000 × 48 α = -------------------------------------------- = 0.23 degree 4 4 × 11 ,500 ,000 Formula (12) can be used with metric SI units, where α = angular deflection of shaft in degrees; T = torsional moment in newton-millimeters; l = length of shaft in millimeters; D = diameter of shaft in millimeters; and G = torsional modulus of elasticity in newtons per square millimeter. Example:Find the torsional deflection of a solid steel shaft, 100 mm in diameter and 1300 mm long, subjected to a twisting moment of 3 × 10 6 newton-millimeters. The torsional modulus of elasticity is 80,000 newtons/mm 2. By Formula (12) 6
584 × 3 × 10 × 1300 α = --------------------------------------------------- = 0.285 degree 4 100 × 80 ,000 The diameter of a shaft that is to have a maximum torsional deflection α is given by: TlD = 4.9 × 4 ------(13) Gα Formula (13) can be used with metric SI units, where D = diameter of shaft in millimeters; T = torsional moment in newton-millimeters; l = length of shaft in millime-
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Machinery's Handbook 27th Edition 302
SHAFTS
ters; G = torsional modulus of elasticity in newtons per square millimeter; and α = angular deflection of shaft in degrees. According to some authorities, the allowable twist in steel transmission shafting should not exceed 0.08 degree per foot length of the shaft. The diameter D of a shaft that will permit a maximum angular deflection of 0.08 degree per foot of length for a given torque T or for a given horsepower P can be determined from the formulas: D = 0.29 4 T
PD = 4.6 × 4 --(14b) N Using metric SI units and assuming an allowable twist in steel transmission shafting of 0.26 degree per meter length, Formulas (14a) and (14b) become: (14a)
D = 2.26 4 T
or
P D = 125.7 × 4 --N where D = diameter of shaft in millimeters; T = torsional moment in newton-millimeters; P = power in kilowatts; and N = revolutions per minute. Another rule that has been generally used in mill practice limits the deflection to 1 degree in a length equal to 20 times the shaft diameter. For a given torque or horsepower, the diameter of a shaft having this maximum deflection is given by: D = 0.1 3 T
or
PD = 4.0 × 3 --(15b) N Example:Find the diameter of a steel lineshaft to transmit 10 horsepower at 150 revolutions per minute with a torsional deflection not exceeding 0.08 degree per foot of length. By Formula (14b), (15a)
or
10- = 2.35 inches D = 4.6 × 4 -------150 This diameter is larger than that obtained for the same horsepower and rpm in the example given for Formula (5b) in which the diameter was calculated for strength considerations only. The usual procedure in the design of shafting which is to have a specified maximum angular deflection is to compute the diameter first by means of Formulas (13), (14a), (14b), (15a), or (15b) and then by means of Formulas (3a), (3b), (4b), (5b), or (6b), using the larger of the two diameters thus found. Linear Deflection of Shafting.—For steel line shafting, it is considered good practice to limit the linear deflection to a maximum of 0.010 inch per foot of length. The maximum distance in feet between bearings, for average conditions, in order to avoid excessive linear deflection, is determined by the formulas: 2
L = 8.95 3 D for shafting subject to no bending action except it’s own weight 3
2
L = 5.2 D for shafting subject to bending action of pulleys, etc. in which D = diameter of shaft in inches and L = maximum distance between bearings in feet. Pulleys should be placed as close to the bearings as possible. In general, shafting up to three inches in diameter is almost always made from cold-rolled steel. This shafting is true and straight and needs no turning, but if keyways are cut in the shaft, it must usually be straightened afterwards, as the cutting of the keyways relieves the tension on the surface of the shaft produced by the cold-rolling process. Sizes of shafting from three to five inches in diameter may be either cold-rolled or turned, more frequently the latter, and all larger sizes of shafting must be turned because cold-rolled shafting is not available in diameters larger than 5 in.
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Machinery's Handbook 27th Edition SHAFTS
303
Diameters of Finished Shafting (former American Standard ASA B17.1) Diameters, Inches TransmisMachinery sion Shafting Shafting 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
15⁄ 16
1
13⁄16
17⁄16
111⁄16
11⁄16 11⁄8 13⁄16 11⁄4 15⁄16 13⁄8 17⁄16 11⁄2 19⁄16 15⁄8 111⁄16 13⁄4
Minus Tolerances, Inchesa 0.002 0.002 0.002 0.002 0.002 0.002 0.002 0.002 0.002 0.003 0.003 0.003 0.003 0.003 0.003 0.003 0.003 0.003 0.003 0.003 0.003
Diameters, Inches TransmisMachinery sion Shafting Shafting
1 15⁄16
23⁄16
27⁄16
215⁄16
37⁄16
113⁄16 17⁄8 115⁄16 2 21⁄16 21⁄8 23⁄16 21⁄4 25⁄16 23⁄8 27⁄16 21⁄2 25⁄8 23⁄4 27⁄8 3 31⁄8 31⁄4 33⁄8 31⁄2 35⁄8
Minus Tolerances Inchesa 0.003 0.003 0.003 0.003 0.004 0.004 0.004 0.004 0.004 0.004 0.004 0.004 0.004 0.004 0.004 0.004 0.004 0.004 0.004 0.004 0.004
Diameters, Inches TransmisMachinery sion Shafting Shafting
3 15⁄16 47⁄16 415⁄16 57⁄16 515⁄16 61⁄2 7 71⁄2 8 … …
33⁄4 37⁄8 4 41⁄4 41⁄2 43⁄4 5 51⁄4 51⁄2 53⁄4 6 61⁄4 61⁄2 63⁄4 7 71⁄4 71⁄2 73⁄4 8 … …
Minus Tolerances, Inchesa 0.004 0.004 0.004 0.005 0.005 0.005 0.005 0.005 0.005 0.005 0.005 0.006 0.006 0.006 0.006 0.006 0.006 0.006 0.006 … …
a Note:—These tolerances are negative or minus and represent the maximum allowable variation below the exact nominal size. For instance the maximum diameter of the 115⁄16 inch shaft is 1.938 inch and its minimum allowable diameter is 1.935 inch. Stock lengths of finished transmission shafting shall be: 16, 20 and 24 feet.
Design of Transmission Shafting.—The following guidelines for the design of shafting for transmitting a given amount of power under various conditions of loading are based upon formulas given in the former American Standard ASA B17c Code for the Design of Transmission Shafting. These formulas are based on the maximum-shear theory of failure which assumes that the elastic limit of a ductile ferrous material in shear is practically onehalf its elastic limit in tension. This theory agrees, very nearly, with the results of tests on ductile materials and has gained wide acceptance in practice. The formulas given apply in all shaft designs including shafts for special machinery. The limitation of these formulas is that they provide only for the strength of shafting and are not concerned with the torsional or lineal deformations which may, in shafts used in machine design, be the controlling factor (see Torsional Deflection of Circular Shafts on page 301 and Linear Deflection of Shafting on page 302 for deflection considerations). In the formulas that follow, 4
B = 3 1 ÷ ( 1 – K ) (see Table 3) D =outside diameter of shaft in inches D1 =inside diameter of a hollow shaft in inches Km =shock and fatigue factor to be applied in every case to the computed bending moment (see Table 1) Kt =combined shock and fatigue factor to be applied in every case to the computed torsional moment (see Table 1) M =maximum bending moment in inch-pounds N =revolutions per minute P =maximum power to be transmitted by the shaft in horsepower
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 304
SHAFTS
pt =maximum allowable shearing stress under combined loading conditions in pounds per square inch (see Table 2) S =maximum allowable flexural (bending) stress, in either tension or compression in pounds per square inch (see Table 2) Ss =maximum allowable torsional shearing stress in pounds per square inch (see Table 2) T =maximum torsional moment in inch-pounds V =maximum transverse shearing load in pounds For shafts subjected to pure torsional loads only, 5.1K t T D = B 3 ---------------Ss
(16a)
or
321 ,000K t P D = B 3 ----------------------------Ss N
(16b)
For stationary shafts subjected to bending only, 10.2K m M D = B 3 ----------------------S For shafts subjected to combined torsion and bending,
or
(17)
5.1- ( K M ) 2 + ( K T ) 2 D = B 3 -----m t pt
(18a)
,000K t P⎞ 2 5.1- ( K M ) 2 + ⎛ 63 -------------------------D = B 3 -----m ⎝ ⎠ N pt
(18b)
Formulas (16a) to (18b) may be used for solid shafts or for hollow shafts. For solid shafts the factor B is equal to 1, whereas for hollow shafts the value of B depends on the value of K which, in turn, depends on the ratio of the inside diameter of the shaft to the outside diameter (D1 ÷ D = K). Table 3 gives values of B corresponding to various values of K. For short solid shafts subjected only to heavy transverse shear, the diameter of shaft required is: D =
1.7V---------Ss
(19)
Formulas (16a), (17), (18a) and (19), can be used unchanged with metric SI units. Formula (16b) becomes: 48.7K t P D = B 3 ------------------- and Formula (18b) becomes: Ss N 5.1 ( M ) 2 + ⎛ 9.55K t P⎞ 2 D = B 3 ------ Km ⎝ ------------------pt N ⎠ Throughout the formulas, D = outside diameter of shaft in millimeters; T = maximum torsional moment in newton-millimeters; Ss = maximum allowable torsional shearing stress in newtons per millimeter squared (see Table 2); P = maximum power to be transmitted in milliwatts; N = revolutions per minute; M = maximum bending moment in newton-millimeters; S = maximum allowable flexural (bending) stress, either in tension or compression in newtons per millimeter squared (see Table 2); pt = maximum allowable shearing stress under combined loading conditions in newtons
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per millimeter squared; and V = maximum transverse shearing load in kilograms. The factors Km, Kt, and B are unchanged, and D1 = the inside diameter of a hollow shaft in millimeters. Table 1. Recommended Values of the Combined Shock and Fatigue Factors for Various Types of Load Stationary Shafts Kt Km
Type of Load Gradually applied and steady Suddenly applied, minor shocks only Suddenly applied, heavy shocks
1.0 1.5–2.0 …
Rotating Shafts Km Kt
1.0 1.5–2.0 …
1.5 1.5–2.0 2.0–3.0
1.0 1.0–1.5 1.5–3.0
Table 2. Recommended Maximum Allowable Working Stresses for Shafts Under Various Types of Load Type of Load Material “Commercial Steel” shafting without keyways “Commercial Steel” shafting with keyways Steel purchased under definite physical specs.
Simple Bending S = 16,000 S = 12,000 (See note a)
Pure Torsion Ss = 8000 Ss = 6000 (See note b)
Combined Stress pt = 8000 pt = 6000 (See note b)
a S = 60 per cent of the elastic limit in tension but not more than 36 per cent of the ultimate tensile strength. b S and p = 30 per cent of the elastic limit in tension but not more than 18 per cent of the ultimate s t tensile strength.
If the values in the Table are converted to metric SI units, note that 1000 pounds per square inch = 6.895 newtons per square millimeter.
Table 3. Values of the Factor B Corresponding to Various Values of K for Hollow Shafts D K = ------1 = D B =
3
4
1 ÷ (1 – K )
0.95
0.90
0.85
0.80
0.75
0.70
0.65
0.60
0.55
0.50
1.75
1.43
1.28
1.19
1.14
1.10
1.07
1.05
1.03
1.02
For solid shafts, B = 1 because K = 0, as follows: B =
3
4
1 ÷ (1 – K ) =
3
1 ÷ (1 – 0) = 1
Effect of Keyways on Shaft Strength.—Keyways cut into a shaft reduce its load carrying ability, particularly when impact loads or stress reversals are involved. To ensure an adequate factor of safety in the design of a shaft with standard keyway (width, one-quarter, and depth, one-eighth of shaft diameter), the former Code for Transmission Shafting tentatively recommended that shafts with keyways be designed on the basis of a solid circular shaft using not more than 75 per cent of the working stress recommended for the solid shaft. See also page 2363. Formula for Shafts of Brittle Materials.—The preceding formulas are applicable to ductile materials and are based on the maximum-shear theory of failure which assumes that the elastic limit of a ductile material in shear is one-half its elastic limit in tension. Brittle materials are generally stronger in shear than in tension; therefore, the maximumshear theory is not applicable. The maximum-normal-stress theory of failure is now generally accepted for the design of shafts made from brittle materials. A material may be considered to be brittle if its elongation in a 2-inch gage length is less than 5 per cent. Materials such as cast iron, hardened tool steel, hard bronze, etc., conform to this rule. The diameter of a shaft made of a brittle material may be determined from the following formula which is based on the maximum-normal-stress theory of failure:
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Machinery's Handbook 27th Edition 306
SHAFTS 2 2 D = B 3 5.1 ------- ( K m M ) + ( K m M ) + ( K t T ) St
where St is the maximum allowable tensile stress in pounds per square inch and the other quantities are as previously defined. The formula can be used unchanged with metric SI units, where D = outside diameter of shaft in millimeters; St = the maximum allowable tensile stress in newtons per millimeter squared; M = maximum bending moment in newton-millimeters; and T = maximum torsional moment in newton-millimeters. The factors Km, Kt, and B are unchanged. Critical Speed of Rotating Shafts.—At certain speeds, a rotating shaft will become dynamically unstable and the resulting vibrations and deflections can result in damage not only to the shaft but to the machine of which it is a part. The speeds at which such dynamic instability occurs are called the critical speeds of the shaft. On page 196 are given formulas for the critical speeds of shafts subject to various conditions of loading and support. A shaft may be safely operated either above or below its critical speed, good practice indicating that the operating speed be at least 20 per cent above or below the critical. The formulas commonly used to determine critical speeds are sufficiently accurate for general purposes. However, the torque applied to a shaft has an important effect on its critical speed. Investigations have shown that the critical speeds of a uniform shaft are decreased as the applied torque is increased, and that there exist critical torques which will reduce the corresponding critical speed of the shaft to zero. A detailed analysis of the effects of applied torques on critical speeds may be found in a paper. “Critical Speeds of Uniform Shafts under Axial Torque,” by Golomb and Rosenberg presented at the First U.S. National Congress of Applied Mechanics in 1951. Shaft Couplings.—A shaft coupling is a device for fastening together the ends of two shafts, so that the rotary motion of one causes rotary motion of the other. One of the most simple and common forms of coupling is the flange coupling Figs. 1a and 1b. It consists of two flanged sleeves or hubs, each of which is keyed to the end of one of the two shafts to be connected. The sleeves are held together and prevented from rotating relative to each other by bolts through the flanges as indicated. Flange Coupling
Fig. 1a.
Fig. 1b.
Flexible Couplings: Flexible couplings are the most common mechanical means of compensating for unavoidable errors in alignment of shafts and shafting. When correctly applied, they are highly efficient for joining lengths of shafting without causing loss of power from bearing friction due to misalignment, and for use in direct motor drives for all kinds of machinery. Flexible couplings are not intended to be used for connecting a driven shaft and a driving shaft that are purposely placed in different planes or at an angle but are intended simply to overcome slight unavoidable errors in alignment that develop in service. There is a wide variety of flexible coupling designs; most of them consist essentially
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of two flanged members or hubs, fastened to the shafts and connected by some yielding arrangement. Balance is an important factor in coupling selection or design; it is not sufficient that the coupling be perfectly balanced when installed, but it must remain in balance after wear has taken place. Comparison of Hollow and Solid Shafting with Same Outside Diameter.—T a b l e 4 that follows gives the per cent decrease in strength and weight of a hollow shaft relative to the strength and weight of a solid shaft of the same diameter. The upper figures in each line give the per cent decrease in strength and the lower figures give the per cent decrease in weight. Example:A 4-inch shaft, with a 2-inch hole through it, has a weight 25 per cent less than a solid 4-inch shaft, but its strength is decreased only 6.25 per cent. Table 4. Comparative Torsional Strengths and Weights of Hollow and Solid Shafting with Same Outside Diameter Dia. of Solid and Hollow Shaft, Inches 11⁄2 13⁄4 2 21⁄4 21⁄2 23⁄4 3 31⁄4 31⁄2 33⁄4 4 41⁄4 41⁄2 43⁄4 5 51⁄2 6 61⁄2 7 71⁄2 8
Diameter of Axial Hole in Hollow Shaft, Inches 1
11⁄4
11⁄2
13⁄4
2
21⁄2
3
31⁄2
4
41⁄2
19.76 44.44 10.67 32.66 6.25 25.00 3.91 19.75 2.56 16.00 1.75 13.22 1.24 11.11 0.87 9.46 0.67 8.16 0.51 7.11 0.40 6.25 0.31 5.54 0.25 4.94 0.20 4.43 0.16 4.00 0.11 3.30 0.09 2.77 0.06 2.36 0.05 2.04 0.04 1.77 0.03 1.56
48.23 69.44 26.04 51.02 15.26 39.07 9.53 30.87 6.25 25.00 4.28 20.66 3.01 17.36 2.19 14.80 1.63 12.76 1.24 11.11 0.96 9.77 0.74 8.65 0.70 7.72 0.50 6.93 0.40 6.25 0.27 5.17 0.19 4.34 0.14 3.70 0.11 3.19 0.08 2.77 0.06 2.44
… … 53.98 73.49 31.65 56.25 19.76 44.44 12.96 36.00 8.86 29.74 6.25 25.00 4.54 21.30 3.38 18.36 2.56 16.00 1.98 14.06 1.56 12.45 1.24 11.11 1.00 9.97 0.81 8.10 0.55 7.43 0.40 6.25 0.29 5.32 0.22 4.59 0.16 4.00 0.13 3.51
… … … … 58.62 76.54 36.60 60.49 24.01 49.00 16.40 40.48 11.58 34.01 8.41 29.00 6.25 25.00 4.75 21.77 3.68 19.14 2.89 16.95 2.29 15.12 1.85 13.57 1.51 12.25 1.03 10.12 0.73 8.50 0.59 7.24 0.40 6.25 0.30 5.44 0.23 4.78
… … … … … … 62.43 79.00 40.96 64.00 27.98 52.89 19.76 44.44 14.35 37.87 10.67 32.66 8.09 28.45 6.25 25.00 4.91 22.15 3.91 19.75 3.15 17.73 2.56 16.00 1.75 13.22 1.24 11.11 0.90 9.47 0.67 8.16 0.51 7.11 0.40 6.25
… … … … … … … … … … 68.30 82.63 48.23 69.44 35.02 59.17 26.04 51.02 19.76 44.44 15.26 39.07 11.99 34.61 9.53 30.87 7.68 27.70 6.25 25.00 4.27 20.66 3.02 17.36 2.19 14.79 1.63 12.76 1.24 11.11 0.96 9.77
… … … … … … … … … … … … … … 72.61 85.22 53.98 73.49 40.96 64.00 31.65 56.25 24.83 49.85 19.76 44.44 15.92 39.90 12.96 36.00 8.86 29.76 6.25 25.00 4.54 21.30 3.38 18.36 2.56 16.00 1.98 14.06
… … … … … … … … … … … … … … … … … … 75.89 87.10 58.62 76.56 46.00 67.83 36.60 60.49 29.48 54.29 24.01 49.00 16.40 40.48 11.58 34.02 8.41 28.99 6.25 25.00 4.75 21.77 3.68 19.14
… … … … … … … … … … … … … … … … … … … … … … 78.47 88.59 62.43 79.00 50.29 70.91 40.96 64.00 27.98 52.89 19.76 44.44 14.35 37.87 10.67 32.66 8.09 28.45 6.25 25.00
… … … … … … … … … … … … … … … … … … … … … … … … … … 80.56 89.75 65.61 81.00 44.82 66.94 31.65 56.25 23.98 47.93 17.08 41.33 12.96 36.00 10.02 31.64
The upper figures in each line give number of per cent decrease in strength; the lower figures give per cent decrease in weight.
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Machinery's Handbook 27th Edition 308
SPRINGS
SPRINGS Introduction to Spring Design Many advances have been made in the spring industry in recent years. For example: developments in materials permit longer fatigue life at higher stresses; simplified design procedures reduce the complexities of design, and improved methods of manufacture help to speed up some of the complicated fabricating procedures and increase production. New types of testing instruments and revised tolerances also permit higher standards of accuracy. Designers should also consider the possibility of using standard springs now available from stock. They can be obtained from spring manufacturing companies located in different areas, and small shipments usually can be made quickly. Designers of springs require information in the following order of precedence to simplify design procedures. 1) Spring materials and their applications 2) Allowable spring stresses 3) Spring design data with tables of spring characteristics, tables of formulas, and tolerances. Only the more commonly used types of springs are covered in detail here. Special types and designs rarely used such as torsion bars, volute springs, Belleville washers, constant force, ring and spiral springs and those made from rectangular wire are only described briefly. Belleville and disc springs are discussed in the section DISC SPRINGS starting on page 354 Notation.—The following symbols are used in spring equations: AC = Active coils b =Widest width of rectangular wire, inches CL = Compressed length, inches D =Mean coil diameter, inches = OD − d d =Diameter of wire or side of square, inches E =Modulus of elasticity in tension, pounds per square inch F =Deflection, for N coils, inches F° =Deflection, for N coils, rotary, degrees f =Deflection, for one active coil FL = Free length, unloaded spring, inches G =Modulus of elasticity in torsion, pounds per square inch IT = Initial tension, pounds K =Curvature stress correction factor L =Active length subject to deflection, inches N =Number of active coils, total P =Load, pounds p =pitch, inches R =Distance from load to central axis, inches S or St = Stress, torsional, pounds per square inch Sb =Stress, bending, pounds per square inch SH = Solid height Sit = Stress, torsional, due to initial tension, pounds per square inch T =Torque = P × R, pound-inches TC = Total coils t =Thickness, inches U =Number of revolutions = F °/360°
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Spring Materials The spring materials most commonly used include high-carbon spring steels, alloy spring steels, stainless spring steels, copper-base spring alloys, and nickel-base spring alloys. High-Carbon Spring Steels in Wire Form.—These spring steels are the most commonly used of all spring materials because they are the least expensive, are easily worked, and are readily available. However, they are not satisfactory for springs operating at high or low temperatures or for shock or impact loading. The following wire forms are available: Music Wire, ASTM A228 (0.80–0.95 per cent carbon): This is the most widely used of all spring materials for small springs operating at temperatures up to about 250 degrees F. It is tough, has a high tensile strength, and can withstand high stresses under repeated loading. The material is readily available in round form in diameters ranging from 0.005 to 0.125 inch and in some larger sizes up to 3⁄16 inch. It is not available with high tensile strengths in square or rectangular sections. Music wire can be plated easily and is obtainable pretinned or preplated with cadmium, but plating after spring manufacture is usually preferred for maximum corrosion resistance. Oil-Tempered MB Grade, ASTM A229 (0.60–0.70 per cent carbon): This general-purpose spring steel is commonly used for many types of coil springs where the cost of music wire is prohibitive and in sizes larger than are available in music wire. It is readily available in diameters ranging from 0.125 to 0.500 inch, but both smaller and larger sizes may be obtained. The material should not be used under shock and impact loading conditions, at temperatures above 350 degrees F., or at temperatures in the sub-zero range. Square and rectangular sections of wire are obtainable in fractional sizes. Annealed stock also can be obtained for hardening and tempering after coiling. This material has a heat-treating scale that must be removed before plating. Oil-Tempered HB Grade, SAE 1080 (0.75–0.85 per cent carbon): This material is similar to the MB Grade except that it has a higher carbon content and a higher tensile strength. It is obtainable in the same sizes and is used for more accurate requirements than the MB Grade, but is not so readily available. In lieu of using this material it may be better to use an alloy spring steel, particularly if a long fatigue life or high endurance properties are needed. Round and square sections are obtainable in the oil-tempered or annealed conditions. Hard-Drawn MB Grade, ASTM A227 (0.60–0.70 per cent carbon): This grade is used for general-purpose springs where cost is the most important factor. Although increased use in recent years has resulted in improved quality, it is best not to use it where long life and accuracy of loads and deflections are important. It is available in diameters ranging from 0.031 to 0.500 inch and in some smaller and larger sizes also. The material is available in square sections but at reduced tensile strengths. It is readily plated. Applications should be limited to those in the temperature range of 0 to 250 degrees F. High-Carbon Spring Steels in Flat Strip Form.—Two types of thin, flat, high-carbon spring steel strip are most widely used although several other types are obtainable for specific applications in watches, clocks, and certain instruments. These two compositions are used for over 95 per cent of all such applications. Thin sections of these materials under 0.015 inch having a carbon content of over 0.85 per cent and a hardness of over 47 on the Rockwell C scale are susceptible to hydrogen-embrittlement even though special plating and heating operations are employed. The two types are described as follows: Cold-Rolled Spring Steel, Blue-Tempered or Annealed, SAE 1074, also 1064, and 1070 (0.60 to 0.80 per cent carbon): This very popular spring steel is available in thicknesses ranging from 0.005 to 0.062 inch and in some thinner and thicker sections. The material is available in the annealed condition for forming in 4-slide machines and in presses, and can
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readily be hardened and tempered after forming. It is also available in the heat-treated or blue-tempered condition. The steel is obtainable in several finishes such as straw color, blue color, black, or plain. Hardnesses ranging from 42 to 46 Rockwell C are recommended for spring applications. Uses include spring clips, flat springs, clock springs, and motor, power, and spiral springs. Cold-Rolled Spring Steel, Blue-Tempered Clock Steel, SAE 1095 (0.90 to 1.05 per cent carbon): This popular type should be used principally in the blue-tempered condition. Although obtainable in the annealed condition, it does not always harden properly during heat-treatment as it is a “shallow” hardening type. It is used principally in clocks and motor springs. End sections of springs made from this steel are annealed for bending or piercing operations. Hardnesses usually range from 47 to 51 Rockwell C. Other materials available in strip form and used for flat springs are brass, phosphorbronze, beryllium-copper, stainless steels, and nickel alloys. Alloy Spring Steels.—These spring steels are used for conditions of high stress, and shock or impact loadings. They can withstand both higher and lower temperatures than the high-carbon steels and are obtainable in either the annealed or pretempered conditions. Chromium Vanadium, ASTM A231: This very popular spring steel is used under conditions involving higher stresses than those for which the high-carbon spring steels are recommended and is also used where good fatigue strength and endurance are needed. It behaves well under shock and impact loading. The material is available in diameters ranging from 0.031 to 0.500 inch and in some larger sizes also. In square sections it is available in fractional sizes. Both the annealed and pretempered types are available in round, square, and rectangular sections. It is used extensively in aircraft-engine valve springs and for springs operating at temperatures up to 425 degrees F. Silicon Manganese: This alloy steel is quite popular in Great Britain. It is less expensive than chromium-vanadium steel and is available in round, square, and rectangular sections in both annealed and pretempered conditions in sizes ranging from 0.031 to 0.500 inch. It was formerly used for knee-action springs in automobiles. It is used in flat leaf springs for trucks and as a substitute for more expensive spring steels. Chromium Silicon, ASTM A401: This alloy is used for highly stressed springs that require long life and are subjected to shock loading. It can be heat-treated to higher hardnesses than other spring steels so that high tensile strengths are obtainable. The most popular sizes range from 0.031 to 0.500 inch in diameter. Very rarely are square, flat, or rectangular sections used. Hardnesses ranging from 50 to 53 Rockwell C are quite common and the alloy may be used at temperatures up to 475 degrees F. This material is usually ordered specially for each job. Stainless Spring Steels.—The use of stainless spring steels has increased and several compositions are available all of which may be used for temperatures up to 550 degrees F. They are all corrosion resistant. Only the stainless 18-8 compositions should be used at sub-zero temperatures. Stainless Type 302, ASTM A313 (18 per cent chromium, 8 per cent nickel): This stainless spring steel is very popular because it has the highest tensile strength and quite uniform properties. It is cold-drawn to obtain its mechanical properties and cannot be hardened by heat treatment. This material is nonmagnetic only when fully annealed and becomes slightly magnetic due to the cold-working performed to produce spring properties. It is suitable for use at temperatures up to 550 degrees F. and for sub-zero temperatures. It is very corrosion resistant. The material best exhibits its desirable mechanical properties in diameters ranging from 0.005 to 0.1875 inch although some larger diameters are available. It is also available as hard-rolled flat strip. Square and rectangular sections are available but are infrequently used.
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Stainless Type 304, ASTM A313 (18 per cent chromium, 8 per cent nickel): This material is quite similar to Type 302, but has better bending properties and about 5 per cent lower tensile strength. It is a little easier to draw, due to the slightly lower carbon content. Stainless Type 316, ASTM A313 (18 per cent chromium, 12 per cent nickel, 2 per cent molybdenum): This material is quite similar to Type 302 but is slightly more corrosion resistant because of its higher nickel content. Its tensile strength is 10 to 15 per cent lower than Type 302. It is used for aircraft springs. Stainless Type 17-7 PH ASTM A313 (17 per cent chromium, 7 per cent nickel): T h i s alloy, which also contains small amounts of aluminum and titanium, is formed in a moderately hard state and then precipitation hardened at relatively low temperatures for several hours to produce tensile strengths nearly comparable to music wire. This material is not readily available in all sizes, and has limited applications due to its high manufacturing cost. Stainless Type 414, SAE 51414 (12 per cent chromium, 2 per cent nickel): This alloy has tensile strengths about 15 per cent lower than Type 302 and can be hardened by heat-treatment. For best corrosion resistance it should be highly polished or kept clean. It can be obtained hard drawn in diameters up to 0.1875 inch and is commonly used in flat coldrolled strip for stampings. The material is not satisfactory for use at low temperatures. Stainless Type 420, SAE 51420 (13 per cent chromium): This is the best stainless steel for use in large diameters above 0.1875 inch and is frequently used in smaller sizes. It is formed in the annealed condition and then hardened and tempered. It does not exhibit its stainless properties until after it is hardened. Clean bright surfaces provide the best corrosion resistance, therefore the heat-treating scale must be removed. Bright hardening methods are preferred. Stainless Type 431, SAE 51431 (16 per cent chromium, 2 per cent nickel): This spring alloy acquires high tensile properties (nearly the same as music wire) by a combination of heat-treatment to harden the wire plus cold-drawing after heat-treatment. Its corrosion resistance is not equal to Type 302. Copper-Base Spring Alloys.—Copper-base alloys are important spring materials because of their good electrical properties combined with their good resistance to corrosion. Although these materials are more expensive than the high-carbon and the alloy steels, they nevertheless are frequently used in electrical components and in sub-zero temperatures. Spring Brass, ASTM B 134 (70 per cent copper, 30 per cent zinc): This material is the least expensive and has the highest electrical conductivity of the copper-base alloys. It has a low tensile strength and poor spring qualities, but is extensively used in flat stampings and where sharp bends are needed. It cannot be hardened by heat-treatment and should not be used at temperatures above 150 degrees F., but is especially good at sub-zero temperatures. Available in round sections and flat strips, this hard-drawn material is usually used in the “spring hard” temper. Phosphor Bronze, ASTM B 159 (95 per cent copper, 5 per cent tin): This alloy is the most popular of this group because it combines the best qualities of tensile strength, hardness, electrical conductivity, and corrosion resistance with the least cost. It is more expensive than brass, but can withstand stresses 50 per cent higher.The material cannot be hardened by heat-treatment. It can be used at temperatures up to 212 degrees F. and at subzero temperatures. It is available in round sections and flat strip, usually in the “extra-hard” or “spring hard” tempers. It is frequently used for contact fingers in switches because of its low arcing properties. An 8 per cent tin composition is used for flat springs and a superfine grain composition called “Duraflex,” has good endurance properties. Beryllium Copper, ASTM B 197 (98 per cent copper, 2 per cent beryllium): T h i s a l l o y can be formed in the annealed condition and then precipitation hardened after forming at
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temperatures around 600 degrees F, for 2 to 3 hours. This treatment produces a high hardness combined with a high tensile strength. After hardening, the material becomes quite brittle and can withstand very little or no forming. It is the most expensive alloy in the group and heat-treating is expensive due to the need for holding the parts in fixtures to prevent distortion. The principal use of this alloy is for carrying electric current in switches and in electrical components. Flat strip is frequently used for contact fingers. Nickel-Base Spring Alloys.—Nickel-base alloys are corrosion resistant, withstand both elevated and sub-zero temperatures, and their non-magnetic characteristic makes them useful for such applications as gyroscopes, chronoscopes, and indicating instruments. These materials have a high electrical resistance and therefore should not be used for conductors of electrical current. Monel* (67 per cent nickel, 30 per cent copper): This material is the least expensive of the nickel-base alloys. It also has the lowest tensile strength but is useful due to its resistance to the corrosive effects of sea water and because it is nearly non-magnetic. The alloy can be subjected to stresses slightly higher than phosphor bronze and nearly as high as beryllium copper. Its high tensile strength and hardness are obtained as a result of colddrawing and cold-rolling only, since it can not be hardened by heat-treatment. It can be used at temperatures ranging from −100 to +425 degrees F. at normal operating stresses and is available in round wires up to 3⁄16 inch in diameter with quite high tensile strengths. Larger diameters and flat strip are available with lower tensile strengths. “K” Monel * (66 per cent nickel, 29 per cent copper, 3 per cent aluminum): This material is quite similar to Monel except that the addition of the aluminum makes it a precipitation-hardening alloy. It may be formed in the soft or fairly hard condition and then hardened by a long-time age-hardening heat-treatment to obtain a tensile strength and hardness above Monel and nearly as high as stainless steel. It is used in sizes larger than those usually used with Monel, is non-magnetic and can be used in temperatures ranging from − 100 to + 450 degrees F. at normal working stresses under 45,000 pounds per square inch. Inconel*(78 per cent nickel, 14 per cent chromium, 7 per cent iron): This is one of the most popular of the non-magnetic nickel-base alloys because of its corrosion resistance and because it can be used at temperatures up to 700 degrees F. It is more expensive than stainless steel but less expensive than beryllium copper. Its hardness and tensile strength is higher than that of “K” Monel and is obtained as a result of cold-drawing and cold-rolling only. It cannot be hardened by heat treatment. Wire diameters up to 1⁄4 inch have the best tensile properties. It is often used in steam valves, regulating valves, and for springs in boilers, compressors, turbines, and jet engines. Inconel “X”*(70 per cent nickel, 16 per cent chromium, 7 per cent iron): This material is quite similar to Inconel but the small amounts of titanium, columbium and aluminum in its composition make it a precipitation-hardening alloy. It can be formed in the soft or partially hard condition and then hardened by holding it at 1200 degrees F. for 4 hours. It is non-magnetic and is used in larger sections than Inconel. This alloy is used at temperatures up to 850 degrees F. and at stresses up to 55,000 pounds per square inch. Duranickel* (“Z” Nickel) (98 per cent nickel): This alloy is non-magnetic, corrosion resistant, has a high tensile strength and is hardenable by precipitation hardening at 900 degrees F. for 6 hours. It may be used at the same stresses as Inconel but should not be used at temperatures above 500 degrees F. Nickel-Base Spring Alloys with Constant Moduli of Elasticity.—Some special nickel alloys have a constant modulus of elasticity over a wide temperature range. These materials are especially useful where springs undergo temperature changes and must exhibit uniform spring characteristics. These materials have a low or zero thermo-elastic coefficient * Trade name of the International Nickel Company.
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Machinery's Handbook 27th Edition STRESSES IN SPRINGS
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and therefore do not undergo variations in spring stiffness because of modulus changes due to temperature differentials. They also have low hysteresis and creep values which makes them preferred for use in food-weighing scales, precision instruments, gyroscopes, measuring devices, recording instruments and computing scales where the temperature ranges from − 50 to + 150 degrees F. These materials are expensive, none being regularly stocked in a wide variety of sizes. They should not be specified without prior discussion with spring manufacturers because some suppliers may not fabricate springs from these alloys due to the special manufacturing processes required. All of these alloys are used in small wire diameters and in thin strip only and are covered by U.S. patents. They are more specifically described as follows: Elinvar* (nickel, iron, chromium): This alloy, the first constant-modulus alloy used for hairsprings in watches, is an austenitic alloy hardened only by cold-drawing and cold-rolling. Additions of titanium, tungsten, molybdenum and other alloying elements have brought about improved characteristics and precipitation-hardening abilities. These improved alloys are known by the following trade names: Elinvar Extra, Durinval, Modulvar and Nivarox. Ni-Span C* (nickel, iron, chromium, titanium): This very popular constant-modulus alloy is usually formed in the 50 per cent cold-worked condition and precipitation-hardened at 900 degrees F. for 8 hours, although heating up to 1250 degrees F. for 3 hours produces hardnesses of 40 to 44 Rockwell C, permitting safe torsional stresses of 60,000 to 80,000 pounds per square inch. This material is ferromagnetic up to 400 degrees F; above that temperature it becomes non-magnetic. Iso-Elastic† (nickel, iron, chromium, molybdenum): This popular alloy is relatively easy to fabricate and is used at safe torsional stresses of 40,000 to 60,000 pounds per square inch and hardnesses of 30 to 36 Rockwell C. It is used principally in dynamometers, instruments, and food-weighing scales. Elgiloy‡ (nickel, iron, chromium, cobalt): This alloy, also known by the trade names 8J Alloy, Durapower, and Cobenium, is a non-magnetic alloy suitable for sub-zero temperatures and temperatures up to about 1000 degrees F., provided that torsional stresses are kept under 75,000 pounds per square inch. It is precipitation-hardened at 900 degrees F. for 8 hours to produce hardnesses of 48 to 50 Rockwell C. The alloy is used in watch and instrument springs. Dynavar** (nickel, iron, chromium, cobalt): This alloy is a non-magnetic, corrosionresistant material suitable for sub-zero temperatures and temperatures up to about 750 degrees F., provided that torsional stresses are kept below 75,000 pounds per square inch. It is precipitation-hardened to produce hardnesses of 48 to 50 Rockwell C and is used in watch and instrument springs. Spring Stresses Allowable Working Stresses for Springs.—The safe working stress for any particular spring depends to a large extent on the following items: 1) Type of spring — whether compression, extension, torsion, etc. 2) Size of spring — small or large, long or short 3) Spring material 4) Size of spring material 5) Type of service — light, average, or severe 6) Stress range — low, average, or high * Trade name of Soc. Anon. de Commentry Fourchambault et Decazeville, Paris, France. † Trade name of John Chatillon & Sons. ‡ Trade name of Elgin National Watch Company. ** Trade name of Hamilton Watch Company.
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STRESSES IN SPRINGS
7) Loading — static, dynamic, or shock 8) Operating temperature 9) Design of spring — spring index, sharp bends, hooks. Consideration should also be given to other factors that affect spring life: corrosion, buckling, friction, and hydrogen embrittlement decrease spring life; manufacturing operations such as high-heat stress-equalizing, presetting, and shot-peening increase spring life. Item 5, the type of service to which a spring is subjected, is a major factor in determining a safe working stress once consideration has been given to type of spring, kind and size of material, temperature, type of loading, and so on. The types of service are: Light Service: This includes springs subjected to static loads or small deflections and seldom-used springs such as those in bomb fuses, projectiles, and safety devices. This service is for 1,000 to 10,000 deflections. Average Service: This includes springs in general use in machine tools, mechanical products, and electrical components. Normal frequency of deflections not exceeding 18,000 per hour permit such springs to withstand 100,000 to 1,000,000 deflections. Severe Service: This includes springs subjected to rapid deflections over long periods of time and to shock loading such as in pneumatic hammers, hydraulic controls and valves. This service is for 1,000,000 deflections, and above. Lowering the values 10 per cent permits 10,000,000 deflections. Figs. 1 through 6 show curves that relate the three types of service conditions to allowable working stresses and wire sizes for compression and extension springs, and safe values are provided. Figs. 7 through 10 provide similar information for helical torsion springs. In each chart, the values obtained from the curves may be increased by 20 per cent (but not beyond the top curves on the charts if permanent set is to be avoided) for springs that are baked, and shot-peened, and compression springs that are pressed. Springs stressed slightly above the Light Service curves will take a permanent set. A curvature correction factor is included in all curves, and is used in spring design calculations (see examples beginning page 321). The curves may be used for materials other than those designated in Figs. 1 through 10, by applying multiplication factors as given in Table 1. LIVE GRAPH Click here to view
160
Torsional Stress (corrected) Pounds per Square Inch (thousands)
150
Hard Drawn Steel Wire QQ-W-428, Type II; ASTM A227, Class II
140 130 120
Light Service
Average Service
110
Severe Service 100 90 80
0 .020 .040 .060 .080 .100 .120 .140 .160 .180 .200 .220 .240 .260 .280 .300 .320 .340 .360 .380 .400 .420 .440 .460 .480 .500
70
Wire Diameter (inch)
Fig. 1. Allowable Working Stresses for Compression Springs — Hard Drawn Steel Wirea
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LIVE GRAPH 220 210 200 190 180 170 160 150 140 130 120 110 100 90 80
MUSIC WIRE QQ-Q-470, ASTM A228
Light Service Average Service Severe Service
0 .010 .020 .030 .040 .050 .060 .070 .080 .090 .100 .110 .120 .130 .140 .150 .160 .170 .180 .190 .200 .210 .220 .230 .240 .250
Torsional Stress (Corrected) Pounds per Square Inch (thousands)
Click here to view
Wire Diameter (inch)
Fig. 2. Allowable Working Stresses for Compression Springs — Music Wirea LIVE GRAPH Click here to view
160
Torsional Stress (corrected) Pounds per Square Inch (thousands)
150
Oil-tempered Steel Wire QQ-W-428, Type I; ASTM A229, Class II
140
Light Service
130
Average Service
120
Severe Service
110 100 90 80
0 .020 .040 .060 .080 .100 .120 .140 .160 .180 .200 .220 .240 .260 .280 .300 .320 .340 .360 .380 .400 .420 .440 .460 .480 .500
70
Wire Diameter (inch)
Fig. 3. Allowable Working Stresses for Compression Springs — Oil-Tempereda LIVE GRAPH
Torsional Stress (corrected) Pounds per Square Inch (thousands)
190 180 170
Click here to view
Chrome-silicon Alloy Steel Wire QQ-W-412, comp 2, Type II; ASTM A401 Light Service Average Service Severe Service
160 150 140 130 120
0 .020 .040 .060 .080 .100 .120 .140 .160 .180 .200 .220 .240 .260 .280 .300 .320 .340 .360 .380 .400 .420 .440 .460 .480 .500
110
Wire Diameter (inch)
Fig. 4. Allowable Working Stresses for Compression Springs — Chrome-Silicon Alloy Steel Wirea
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Machinery's Handbook 27th Edition 316
STRESSES IN SPRINGS LIVE GRAPH Click here to view
160
Corrosion-resisting Steel Wire QQ-W-423, ASTM A313
Torsional Stress (corrected) Pounds per Square Inch (thousands)
150 140
Light service Average service
130 120
Severe service 110 100 90
70
0 .020 .040 .060 .080 .100 .120 .140 .160 .180 .200 .220 .240 .260 .280 .300 .320 .340 .360 .380 .400 .420 .440 .460 .480 .500
80
Wire Diameter (inch)
Fig. 5. Allowable Working Stresses for Compression Springs — Corrosion-Resisting Steel Wirea LIVE GRAPH Chrome-vanadium Alloy Steel Wire, ASTM A231 Light service Average service
Severe service
0 .020 .040 .060 .080 .100 .120 .140 .160 .180 .200 .220 .240 .260 .280 .300 .320 .340 .360 .380 .400 .420 .440 .460 .480 .500
Torsional Stress (corrected) Pounds per Square Inch (thousands)
Click here to view
190 180 170 160 150 140 130 120 110 100 90 80
Wire Diameter (inch)
Fig. 6. Allowable Working Stresses for Compression Springs — Chrome-Vanadium Alloy Steel Wirea Click here to view
Music Wire, ASTM A228
Light service Average service Severe service
0 .010 .020 .030 .040 .050 .060 .070 .080 .090 .100 .110 .120 .130 .140 .150 .160 .170 .180 .190 .200 .210 .220 .230 .240 .250
Stress, Pounds per Square Inch (thousands)
LIVE GRAPH
270 260 250 240 230 220 210 200 190 180 170 160 150 140 130 120
Wire Diameter (inch)
Fig. 7. Recommended Design Stresses in Bending for Helical Torsion Springs — Round Music Wire
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260 250 240 230 220 210 200 190 180 170 160 150 140 130 120 110
Click here to view
Oil-tempered MB Grade, ASTM A229 Type I
Light service Average service Severe service
0 .020 .040 .060 .080 .100 .120 .140 .160 .180 .200 .220 .240 .260 .280 .300 .320 .340 .360 .380 .400 .420 .440 .460 .480 .500
Stress, Pounds per Square Inch (thousands)
LIVE GRAPH
Wire Diameter (inch)
Fig. 8. Recommended Design Stresses in Bending for Helical Torsion Springs — Oil-Tempered MB Round Wire Click here to view
Stainless Steel, “18-8,” Types 302 & 304 ASTM A313 Light Service Average Service Severe Service
0 .020 .040 .060 .080 .100 .120 .140 .160 .180 .200 .220 .240 .260 .280 .300 .320 .340 .360 .380 .400 .420 .440 .460 .480 .500
Stress, Pounds per Square Inch (thousands)
LIVE GRAPH
220 210 200 190 180 170 160 150 140 130 120 110 100 90 80 70
Wire Diameter (inch)
Fig. 9. Recommended Design Stresses in Bending for Helical Torsion Springs — Stainless Steel Round Wire Click here to view
Chrome-silicon, ASTM A401 Light service Average service Severe service
0 .020 .040 .060 .080 .100 .120 .140 .160 .180 .200 .220 .240 .260 .280 .300 .320 .340 .360 .380 .400 .420 .440 .460 .480 .500
Stress, Pounds per Square Inch (thousands)
LIVE GRAPH
290 280 270 260 250 240 230 220 210 200 190 180 170 160 150 140
Wire Diameter (inch)
Fig. 10. Recommended Design Stresses in Bending for Helical Torsion Springs — Chrome-Silicon Round Wire a Although Figs. 1 through 6 are for compression springs, they may also be used for extension springs; for extension springs, reduce the values obtained from the curves by 10 to 15 per cent.
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Machinery's Handbook 27th Edition 318
STRESSES IN SPRINGS Table 1. Correction Factors for Other Materials Compression and Tension Springs Material
Factor
Material
Factor
Silicon-manganese
Multiply the values in the chromium-vanadium curves (Fig. 6) by 0.90
Stainless Steel, 316
Valve-spring quality wire
Use the values in the chromiumvanadium curves (Fig. 6)
Multiply the values in the corrosion-resisting steel curves (Fig. 5) by 0.90
Stainless Steel, 304 and 420
Multiply the values in the corrosion-resisting steel curves (Fig. 5) by 0.95
Stainless Steel, 431 and 17-7PH
Multiply the values in the music wire curves (Fig. 2) by 0.90
Helical Torsion Springs Material
Factora
Material
Hard Drawn MB
0.70
Stainless Steel, 431
Factora
Up to 1⁄32 inch diameter
0.80
Up to 1⁄32 inch diameter
0.75
Over 1⁄32 to 1⁄16 inch
0.85
Over 1⁄32 to 3⁄16 inch
0.70
Over 1⁄16 to 1⁄8 inch
0.95
Over 3⁄16 to 1⁄4 inch
0.65
Over 1⁄8 inch
1.00
Over 1⁄4 inch
0.50
Chromium-Vanadium
Stainless Steel, 316
Up to 1⁄16 inch diameter
1.05
Up to 1⁄8 inch diameter
1.00
Over 1⁄16 inch
1.10
Over 1⁄8 to 3⁄16 inch
1.07
Phosphor Bronze
Over 3⁄16 inch
1.12
Stainless Steel, 17-7 PH
Stainless Steel, 420 Up to 1⁄32 inch diameter
0.70
Up to 1⁄8 inch diameter
0.45
Over 1⁄8 inch
0.55
Beryllium Copperb
Over 1⁄32 to 1⁄16 inch
0.75
Up to 1⁄32 inch diameter
0.55
Over 1⁄16 to 1⁄8 inch
0.80
Over 1⁄32 to 1⁄16 inch
0.60
Over 1⁄8 to 3⁄16 inch
0.90
Over 1⁄16 to 1⁄8 inch
0.70
Over 3⁄16 inch
1.00
Over 1⁄8 inch
0.80
a Multiply the values in the curves for oil-tempered MB grade ASTM A229 Type 1 steel (Fig. 8) by
these factors to obtain required values. b Hard drawn and heat treated after coiling. For use with design stress curves shown in Figs. 2, 5, 6, and 8.
Endurance Limit for Spring Materials.—When a spring is deflected continually it will become “tired” and fail at a stress far below its elastic limit. This type of failure is called fatigue failure and usually occurs without warning. Endurance limit is the highest stress, or range of stress, in pounds per square inch that can be repeated indefinitely without failure of the spring. Usually ten million cycles of deflection is called “infinite life” and is satisfactory for determining this limit. For severely worked springs of long life, such as those used in automobile or aircraft engines and in similar applications, it is best to determine the allowable working stresses by referring to the endurance limit curves seen in Fig. 11. These curves are based principally upon the range or difference between the stress caused by the first or initial load and the stress caused by the final load. Experience with springs designed to stresses within the limits of these curves indicates that they should have infinite or unlimited fatigue life. All values include Wahl curvature correction factor. The stress ranges shown may be increased 20 to 30 per cent for springs that have been properly heated, pressed to remove set, and then shot peened, provided that the increased values are lower than the torsional elastic limit by at least 10 per cent.
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Machinery's Handbook 27th Edition STRESSES IN SPRINGS
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120
Final Stress, Including Curvature Correction, 1000 psi
110 ′′ .030 der 0 5′′ e un 0.12 o Wir t ic ′′ s .031 Mu ire 0 m W ic adiu Mus Van %C 0.80 ome e teel Chr S g grad in B r p M el OT S g Ste 0.08%c in r p el e OT S ring Ste grad Sp l mb Stee *HD g in Spr e 302 *HD 8 typ l 18e e t sS H.T. inles ard *Sta ull h per f p o ard mC ng h ylliu spri % *Ber 5 e ronz ur B osph s *Ph s Bra ring *Sp and st L Fir o t ue ss D
100 90 80 70 60 50 40 30 20 10 0 0
tial
Ini
e
Str
5 10 15 20 25 30 35 40 45 50 55 Initial Stress, Due to First Load, Corrected for Curvature, 1000 psi
60
Fig. 11. Endurance Limit Curves for Compression Springs Notes: For commercial spring materials with wire diameters up to 1⁄4 inch except as noted. Stress ranges may be increased by approximately 30 per cent for properly heated, preset, shot-peened springs. Materials preceeded by * are not ordinarily recommended for long continued service under severe operating conditions.
Working Stresses at Elevated Temperatures.—Since modulus of elasticity decreases with increase in temperature, springs used at high temperatures exert less load and have larger deflections under load than at room temperature. The torsional modulus of elasticity for steel may be 11,200,000 pounds per square inch at room temperature, but it will drop to 10,600,000 pounds per square inch at 400°F. and will be only 10,000,000 pounds per square inch at 600°F. Also, the elastic limit is reduced, thereby lowering the permissible working stress. Design stresses should be as low as possible for all springs used at elevated temperatures. In addition, corrosive conditions that usually exist at high temperatures, especially with steam, may require the use of corrosion-resistant material. Table 2 shows the permissible elevated temperatures at which various spring materials may be operated, together with the maximum recommended working stresses at these temperatures. The loss in load at the temperatures shown is less than 5 per cent in 48 hours; however, if the temperatures listed are increased by 20 to 40 degrees, the loss of load may be nearer 10 per cent. Maximum stresses shown in the table are for compression and extension springs and may be increased
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Machinery's Handbook 27th Edition 320
SPRING DESIGN
by 75 per cent for torsion and flat springs. In using the data in Table 2 it should be noted that the values given are for materials in the heat-treated or spring temper condition. Table 2. Recommended Maximum Working Temperatures and Corresponding Maximum Working Stresses for Springs Spring Material
Max. Working Temp., °F
Max. Working Stress, psi
Brass Spring Wire
150
30,000
Phosphor Bronze Music Wire Beryllium-Copper Hard Drawn Steel Wire Carbon Spring Steels
225 250 300 325 375
35,000 75,000 40,000 50,000 55,000
Alloy Spring Steels
400
65,000
Monel K-Monel
425 450
40,000 45,000
Spring Material Permanickela Stainless Steel 18-8 Stainless Chromium 431 Inconel High Speed Steel Inconel X Chromium-MolybdenumVanadium Cobenium, Elgiloy
Max. Working Temp, °F
Max. Working Stress, psi
500
50,000
550 600 700 775 850
55,000 50,000 50,000 70,000 55,000
900
55,000
1000
75,000
a Formerly called Z-Nickel, Type B.
Loss of load at temperatures shown is less than 5 per cent in 48 hours.
Spring Design Data Spring Characteristics.—This section provides tables of spring characteristics, tables of principal formulas, and other information of a practical nature for designing the more commonly used types of springs. Standard wire gages for springs: Information on wire gages is given in the section beginning on page 2519, and gages in decimals of an inch are given in the table on page 2520. It should be noted that the range in this table extends from Number 7⁄0 through Number 80. However, in spring design, the range most commonly used extends only from Gage Number 4⁄0 through Number 40. When selecting wire use Steel Wire Gage or Washburn and Moen gage for all carbon steels and alloy steels except music wire; use Brown & Sharpe gage for brass and phosphor bronze wire; use Birmingham gage for flat spring steels, and cold rolled strip; and use piano or music wire gage for music wire. Spring index: The spring index is the ratio of the mean coil diameter of a spring to the wire diameter (D/d). This ratio is one of the most important considerations in spring design because the deflection, stress, number of coils, and selection of either annealed or tempered material depend to a considerable extent on this ratio. The best proportioned springs have an index of 7 through 9. Indexes of 4 through 7, and 9 through 16 are often used. Springs with values larger than 16 require tolerances wider than standard for manufacturing; those with values less than 5 are difficult to coil on automatic coiling machines. Direction of helix: Unless functional requirements call for a definite hand, the helix of compression and extension springs should be specified as optional. When springs are designed to operate, one inside the other, the helices should be opposite hand to prevent intermeshing. For the same reason, a spring that is to operate freely over a threaded member should have a helix of opposite hand to that of the thread. When a spring is to engage with a screw or bolt, it should, of course, have the same helix as that of the thread. Helical Compression Spring Design.—After selecting a suitable material and a safe stress value for a given spring, designers should next determine the type of end coil formation best suited for the particular application. Springs with unground ends are less expensive but they do not stand perfectly upright; if this requirement has to be met, closed ground ends are used. Helical compression springs with different types of ends are shown in Fig. 12.
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Machinery's Handbook 27th Edition SPRING DESIGN
321
Fig. 12. Types of Helical Compression Spring Ends
Spring design formulas: Table 3 gives formulas for compression spring dimensional characteristics, and Table 4 gives design formulas for compression and extension springs. Curvature correction: In addition to the stress obtained from the formulas for load or deflection, there is a direct shearing stress and an increased stress on the inside of the section due to curvature. Therefore, the stress obtained by the usual formulas should be multiplied by a factor K taken from the curve in Fig. 13. The corrected stress thus obtained is used only for comparison with the allowable working stress (fatigue strength) curves to determine if it is a safe stress and should not be used in formulas for deflection. The curvature correction factor K is for compression and extension springs made from round wire. For square wire reduce the K value by approximately 4 per cent. Design procedure: The limiting dimensions of a spring are often determined by the available space in the product or assembly in which it is to be used. The loads and deflections on a spring may also be known or can be estimated, but the wire size and number of coils are usually unknown. Design can be carried out with the aid of the tabular data that appears later in this section (see Table 5, which is a simple method, or by calculation alone using the formulas in Tables 3 and 4. Example:A compression spring with closed and ground ends is to be made from ASTM A229 high carbon steel wire, as shown in Fig. 14. Determine the wire size and number of coils. Method 1, using table: Referring to Table 5, starting on page 325, locate the spring outside diameter (13⁄16 inches, from Fig. 14) in the left-hand column. Note from the drawing that the spring load is 36 pounds. Move to the right in the table to the figure nearest this value, which is 41.7 pounds. This is somewhat above the required value but safe. Immediately above the load value, the deflection f is given, which in this instance is 0.1594 inch. This is the deflection of one coil under a load of 41.7 pounds with an uncorrected torsional stress S of 100,000 pounds per square inch for ASTM A229 oil-tempered MB steel. For other spring materials, see the footnotes to Table 5 on page 325. Moving vertically in Table 5 from the load entry, the wire diameter is found to be 0.0915 inch. The remaining spring design calculations are completed as follows: Step 1: The stress with a load of 36 pounds is obtained by proportion, as follows: The 36 pound load is 86.3 per cent of the 41.7 pound load; therefore, the stress S at 36 pounds = 0.863 × 100,000 = 86,300 pounds per square inch.
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Machinery's Handbook 27th Edition 322
SPRING DESIGN Table 3. Formulas for Compression Springs Type of End Open or Plain (not ground)
Open or Plain (with ends ground)
Squared or Closed (not ground)
Closed and Ground
Pitch (p)
FL – d--------------N
FL ------TC
FL – 3d ------------------N
FL – 2d ------------------N
Solid Height (SH)
(TC + 1)d
TC × d
(TC + I)d
TC × d
Number of Active Coils (N)
N = TC – d= FL --------------p
N = TC – 1 = FL ------- – 1 p
N = TC – 2 – 3d = FL ------------------p
N = TC – 2 – 2d = FL ------------------p
Total Coils (TC)
FL – d--------------p
FL ------p
FL – 3d + 2 ------------------p
FL – 2d + 2 ------------------p
Free Length (FL)
(p × TC) + d
p × TC
(p × N) + 3d
(p × N) + 2d
Formulaa
Feature
a The symbol notation is given on page
308.
Table 4. Formulas for Compression and Extension Springs Formulaa, b Feature
Springs made from round wire
Load, P Pounds
0.393Sd 3 = -------------Gd 4 F P = ---------------------D 8ND 3
0.416Sd 3 = --------------------Gd 4 F P = ---------------------D 5.58ND 3
GdF PD S = --------------- = ------------------0.393d 3 πND 2
GdF D S = ---------------------- = P ------------------2.32ND 2 0.416d 3
3 πSND 2F = 8PND ------------------ = ----------------Gd Gd 4
3 2 F = 5.58PND -------------------------------------------------- = 2.32SND Gd Gd 4
Gd 4 F GdFN = ------------- = ------------8PD 3 πSD 2
Gd 4 F = -------------------GdF N = --------------------5.58PD 3 2.32SD 2
Wire Diameter, d Inch
2 d = πSND ------------------ = GF
2 d = 2.32SND ------------------------- = GF
Stress due to Initial Tension, Sit
S it = --S- × IT P
Stress, Torsional, S Pounds per square inch Deflection, F Inch Number of Active Coils, N
a The symbol notation is given on page
3
2.55PD ------------------S
Springs made from square wire
3
PD ---------------0.416S
S it = --S- × IT P
308.
b Two formulas are given for each feature, and designers can use the one found to be appropriate for
a given design. The end result from either of any two formulas is the same.
Step 2: The 86.3 per cent figure is also used to determine the deflection per coil f at 36 pounds load: 0.863 × 0.1594 = 0.1375 inch. 1.25 - = 9.1 Step 3: The number of active coils AC = F --- = --------------f 0.1375
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Machinery's Handbook 27th Edition SPRING DESIGN
323
LIVE GRAPH Click here to view
2.1 2.0 1.9
Correction Factor, K
1.8 1.7 1.6 1.5 1.4 1.3 1.2 1.1 1.0
1
2
3
4
5 6 7 Spring Index
8
9
10
11
12
Fig. 13. Compression and Extension Spring-Stress Correction for Curvaturea a For springs made from round wire. For springs made from square wire, reduce the K factor
values by approximately 4 per cent.
Fig. 14. Compression Spring Design Example
Step 4: Total Coils TC = AC + 2 (Table 3) = 9 + 2 = 11 Therefore, a quick answer is: 11 coils of 0.0915 inch diameter wire. However, the design procedure should be completed by carrying out these remaining steps: Step 5: From Table 3, Solid Height = SH = TC × d = 11 × 0.0915 ≅ 1 inch Therefore, Total Deflection = FL − SH = 1.5 inches
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Machinery's Handbook 27th Edition 324
SPRING DESIGN
,300 × 1.5 = 103 ,500 pounds per square inch Step 6: Stress Solid = 86 ---------------1.25 Step 7: Spring Index = O.D. ------------- – 1 = 0.8125 ---------------- – 1 = 7.9 d 0.0915 Step 8: From Fig. 13, the curvature correction factor K = 1.185 Step 9: Total Stress at 36 pounds load = S × K = 86,300 × 1.185 = 102,300 pounds per square inch. This stress is below the 117,000 pounds per square inch permitted for 0.0915 inch wire shown on the middle curve in Fig. 3, so it is a safe working stress. Step 10: Total Stress at Solid = 103,500 × 1.185 = 122,800 pounds per square inch. This stress is also safe, as it is below the 131,000 pounds per square inch shown on the top curve Fig. 3, and therefore the spring will not set. Method 2, using formulas: The procedure for design using formulas is as follows (the design example is the same as in Method 1, and the spring is shown in Fig. 14): Step 1: Select a safe stress S below the middle fatigue strength curve Fig. 8 for ASTM A229 steel wire, say 90,000 pounds per square inch. Assume a mean diameter D slightly below the 13⁄16-inch O.D., say 0.7 inch. Note that the value of G is 11,200,000 pounds per square inch (Table 20). Step 2: A trial wire diameter d and other values are found by formulas from Table 4 as follows: 2.55 × 36 × 0.7----------------------------------90 ,000
d =
3
2.55PD ------------------- = S
=
3
0.000714 = 0.0894 inch
3
Note: Table 21 can be used to avoid solving the cube root. Step 3: From the table on page 2520, select the nearest wire gauge size, which is 0.0915 inch diameter. Using this value, the mean diameter D = 13⁄16 inch − 0.0915 = 0.721 inch. PD - = -------------------------------------36 × 0.721 Step 4: The stress S = -----------------= 86 ,300 lb/in 2 0.393d 3 0.393 × 0.0915 3 Step 5: The number of active coils is GdF- = 11 ,200 ,000 × 0.0915 × 1.25- = 9.1 (say 9) N = -----------------------------------------------------------------------------πSD 2 3.1416 × 86 ,300 × 0.721 2 The answer is the same as before, which is to use 11 total coils of 0.0915-inch diameter wire. The total coils, solid height, etc., are determined in the same manner as in Method 1. Table of Spring Characteristics.—Table 5 gives characteristics for compression and extension springs made from ASTM A229 oil-tempered MB spring steel having a torsional modulus of elasticity G of 11,200,000 pounds per square inch, and an uncorrected torsional stress S of 100,000 pounds per square inch. The deflection f for one coil under a load P is shown in the body of the table. The method of using these data is explained in the problems for compression and extension spring design. The table may be used for other materials by applying factors to f. The factors are given in a footnote to the table.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 5. Compression and Extension Spring Deflections a Spring Outside Dia. Nom.
Dec.
7⁄ 64
.1094
1⁄ 8
.125
9⁄ 64
.1406 .1563 .1719
3⁄ 16
.1875
13⁄ 64
.2031
7⁄ 32
.2188
15⁄ 64
.2344
1⁄ 4
.250
9⁄ 32
.2813
5⁄ 16
.3125
11⁄ 32
.3438
3⁄ 8
.375
.012
.014
.016
.018
.020
.022
.024
.026
.028
.030
.032
.034
.036
.038
19 .041
18 .0475
17 .054
16 .0625
… … .00683 16.95 .00937 14.47 .01234 12.62 .01569 11.19 .01944 10.05 .0236 9.13 .0282 8.35 .0331 7.70 .0385 7.14 .0505 6.24 .0640 5.54 .0792 4.98 .0960 4.53
… … .00617 20.6 .00852 17.51 .01128 15.23 .01439 13.48 .01788 12.09 .0218 10.96 .0260 10.02 .0307 9.23 .0357 8.56 .0469 7.47 .0596 6.63 .0733 5.95 .0895 5.40
… … … … .00777 21.0 .01033 18.22 .01324 16.09 .01650 14.41 .0201 13.05 .0241 11.92 .0285 10.97 .0332 10.17 .0437 8.86 .0556 7.85 .0690 7.05 .0839 6.40
… … … … … … .00909 23.5 .01172 21.8 .01468 18.47 .01798 16.69 .0216 15.22 .0256 13.99 .0299 12.95 .0395 11.26 .0504 9.97 .0627 8.94 .0764 8.10
… … … … … … … … .00914 33.8 .01157 30.07 .01430 27.1 .01733 24.6 .0206 22.5 .0242 20.8 .0323 18.01 .0415 15.89 .0518 14.21 .0634 12.85
… … … … … … … … … … .00926 46.3 .01155 41.5 .01411 37.5 .01690 34.3 .01996 31.6 .0268 27.2 .0347 23.9 .0436 21.3 .0535 19.27
… … … … … … … … … … … … … … .01096 61.3 .01326 55.8 .01578 51.1 .0215 43.8 .0281 38.3 .0355 34.1 .0438 30.7
Deflection f (inch) per coil, at Load P (pounds) c .0277 .395 .0371 .342 .0478 .301 .0600 .268 .0735 .243 .0884 .221 .1046 .203 … … … … … … … … … … … … … …
.0222 .697 .0299 .600 .0387 .528 .0487 .470 .0598 .424 .0720 .387 .0854 .355 .1000 .328 .1156 .305 … … … … … … … … … …
.01824 1.130 .0247 .971 .0321 .852 .0406 .758 .0500 .683 .0603 .621 .0717 .570 .0841 .526 .0974 .489 .1116 .457 .1432 .403 … … … … … …
.01529 1.722 .0208 1.475 .0272 1.291 .0345 1.146 .0426 1.031 .0516 .938 .0614 .859 .0721 .793 .0836 .736 .0960 .687 .1234 .606 .1541 .542 … … … …
.01302 2.51 .01784 2.14 .0234 1.868 .0298 1.656 .0369 1.488 .0448 1.351 .0534 1.237 .0628 1.140 .0730 1.058 .0839 .987 .1080 .870 .1351 .778 .1633 .703 … …
.01121 3.52 .01548 2.99 .0204 2.61 .0261 2.31 .0324 2.07 .0394 1.876 .0470 1.716 .0555 1.580 .0645 1.465 .0742 1.366 .0958 1.202 .1200 1.074 .1470 .970 .1768 .885
.00974 4.79 .01353 4.06 .01794 3.53 .0230 3.11 .0287 2.79 .0349 2.53 .0418 2.31 .0494 2.13 .0575 1.969 .0663 1.834 .0857 1.613 .1076 1.440 .1321 1.300 .1589 1.185
.00853 6.36 .01192 5.37 .01590 4.65 .0205 4.10 .0256 3.67 .0313 3.32 .0375 3.03 .0444 2.79 .0518 2.58 .0597 2.40 .0774 2.11 .0973 1.881 .1196 1.697 .1440 1.546
.00751 8.28 .01058 6.97 .01417 6.02 .01832 5.30 .0230 4.73 .0281 4.27 .0338 3.90 .0401 3.58 .0469 3.21 .0541 3.08 .0703 2.70 .0886 2.41 .1090 2.17 .1314 1.978
.00664 10.59 .00943 8.89 .01271 7.66 0.1649 6.72 .0208 5.99 .0255 5.40 .0307 4.92 .0365 4.52 .0427 4.18 .0494 3.88 .0643 3.40 .0811 3.03 .0999 2.73 .1206 2.48
.00589 13.35 .00844 11.16 .01144 9.58 .01491 8.39 .01883 7.47 .0232 6.73 .0280 6.12 .0333 5.61 .0391 5.19 .0453 4.82 .0591 4.22 .0746 3.75 .0921 3.38 .1113 3.07
… … .00758 13.83 .01034 11.84 .01354 10.35 .01716 9.19 .0212 8.27 .0257 7.52 .0306 6.88 .0359 6.35 .0417 5.90 .0545 5.16 .0690 4.58 .0852 4.12 .1031 3.75
SPRING DESIGN
5⁄ 32 11⁄ 64
Wire Size or Washburn and Moen Gauge, and Decimal Equivalent b .010
a This
Copyright 2004, Industrial Press, Inc., New York, NY
325
table is for ASTM A229 oil tempered spring steel with a torsional modulus G of 11,200,000 psi, and an uncorrected torsional stress of 100,000 psi. For other materials use the following factors: stainless steel, multiply f by 1.067; spring brass, multiply f by 2.24; phosphor bronze, multiply f by 1.867; Monel metal, multiply f by 1.244; beryllium copper, multiply f by 1.725; Inconel (non-magnetic), multiply f by 1.045. b Round wire. For square wire, multiply f by 0.707, and p, by 1.2 c The upper figure is the deflection and the lower figure the load as read against each spring size. Note: Intermediate values can be obtained within reasonable accuracy by interpolation.
Machinery's Handbook 27th Edition
326
Table 5. (Continued) Compression and Extension Spring Deflections a Wire Size or Washburn and Moen Gauge, and Decimal Equivalent Spring Outside Dia. Nom.
Dec.
13⁄ 32
.4063
7⁄ 16
.4375
15⁄ 32
.4688 .500
17⁄ 32
.5313
9⁄ 16
.5625
19⁄ 32
.5938
5⁄ 8
.625
21⁄ 32
.6563
11⁄ 16
.6875
23⁄ 32
.7188
3⁄ 4
.750
25⁄ 32
.7813
13⁄ 16
.8125
.028
.030
.032
.034
.036
.038
.1560 1.815 .1827 1.678 .212 1.559 .243 1.456 .276 1.366 … … … … … … … … … … … … … … … … … …
.1434 2.28 .1680 2.11 .1947 1.956 .223 1.826 .254 1.713 .286 1.613 … … … … … … … … … … … … … … … …
.1324 2.82 .1553 2.60 .1800 2.42 .207 2.26 .235 2.12 .265 1.991 .297 1.880 .331 1.782 … … … … … … … … … … … …
.1228 3.44 .1441 3.17 .1673 2.94 .1920 2.75 .219 2.58 .247 2.42 .277 2.29 .308 2.17 .342 2.06 … … … … … … … … … …
.1143 4.15 .1343 3.82 .1560 3.55 .1792 3.31 .204 3.10 .230 2.92 .259 2.76 .288 2.61 .320 2.48 .352 2.36 … … … … … … … …
.1068 4.95 .1256 4.56 .1459 4.23 .1678 3.95 .1911 3.70 .216 3.48 .242 3.28 .270 3.11 .300 2.95 .331 2.81 .363 2.68 … … … … … …
.1001 5.85 .1178 5.39 .1370 5.00 .1575 4.67 .1796 4.37 .203 4.11 .228 3.88 .254 3.67 .282 3.49 .311 3.32 .342 3.17 .374 3.03 … … … …
19
18
17
16
15
14
13
3⁄ 32
12
11
1⁄ 8
.041
.0475
.054
.0625
.072
.080
.0915
.0938
.1055
.1205
.125
.0436 43.9 .0521 40.1 .0614 37.0 .0714 34.3 .0822 31.9 .0937 29.9 .1061 28.1 .1191 26.5 .1330 25.1 .1476 23.8 .1630 22.7 .1791 21.6 .1960 20.7 .214 19.80
.0373 61.6 .0448 56.3 .0530 51.7 .0619 47.9 .0714 44.6 .0816 41.7 .0926 39.1 .1041 36.9 .1164 34.9 .1294 33.1 .1431 31.5 .1574 30.0 .1724 28.7 .1881 27.5
.0304 95.6 .0367 86.9 .0437 79.7 .0512 73.6 .0593 68.4 .0680 63.9 .0774 60.0 .0873 56.4 .0978 53.3 .1089 50.5 .1206 48.0 .1329 45.7 .1459 43.6 .1594 41.7
.0292 103.7 .0353 94.3 .0420 86.4 .0494 80.0 .0572 74.1 .0657 69.1 .0748 64.8 .0844 61.0 .0946 57.6 .1054 54.6 .1168 51.9 .1288 49.4 .1413 47.1 .1545 45.1
.0241 153.3 .0293 138.9 .0351 126.9 .0414 116.9 .0482 108.3 .0555 100.9 .0634 94.4 .0718 88.7 .0807 83.7 .0901 79.2 .1000 75.2 .1105 71.5 .1214 68.2 .1329 65.2
… … .0234 217. .0282 197.3 .0335 181.1 .0393 167.3 .0455 155.5 .0522 145.2 .0593 136.2 .0668 128.3 .0748 121.2 .0833 114.9 .0923 109.2 .1017 104.0 .1115 99.3
… … .0219 245. .0265 223. .0316 205. .0371 188.8 .0430 175.3 .0493 163.6 .0561 153.4 .0634 144.3 .0710 136.3 .0791 129.2 .0877 122.7 .0967 116.9 .1061 111.5
Deflection f (inch) per coil, at Load P (pounds) .0913 7.41 .1075 6.82 .1252 6.33 .1441 5.90 .1645 5.52 .1861 5.19 .209 4.90 .233 4.63 .259 4.40 .286 4.19 .314 3.99 .344 3.82 .375 3.66 .407 3.51
.0760 11.73 .0898 10.79 .1048 9.99 .1209 9.30 .1382 8.70 .1566 8.18 .1762 7.71 .1969 7.29 .219 6.92 .242 6.58 .266 6.27 .291 5.99 .318 5.74 .346 5.50
.0645 17.56 .0764 16.13 .0894 14.91 .1033 13.87 .1183 12.96 .1343 12.16 .1514 11.46 .1693 10.83 .1884 10.27 .208 9.76 .230 9.31 .252 8.89 .275 8.50 .299 8.15
.0531 27.9 .0631 25.6 .0741 23.6 .0859 21.9 .0987 20.5 .1122 19.17 .1267 18.04 .1420 17.04 .1582 16.14 .1753 15.34 .1933 14.61 .212 13.94 .232 13.34 .253 12.78
a This
table is for ASTM A229 oil tempered spring steel with a torsional modulus G of 11,200,000 psi, and an uncorrected torsional stress of 100,000 psi. For other materials, and other important footnotes, see page 325.
Copyright 2004, Industrial Press, Inc., New York, NY
SPRING DESIGN
1⁄ 2
.026
Machinery's Handbook 27th Edition
Table 5. (Continued) Compression and Extension Spring Deflections a Wire Size or Washburn and Moen Gauge, and Decimal Equivalent Spring Outside Dia. Nom. 7⁄ 8
14
13
3⁄ 32
12
11
1⁄ 8
10
9
5⁄ 32
8
7
3⁄ 16
6
5
7⁄ 32
4
.072
.080
.0915
.0938
.1055
.1205
.125
.135
.1483
.1563
.162
.177
.1875
.192
.207
.2188
.2253
.251 18.26 .271 17.57 .292 16.94 .313 16.35 .336 15.80 .359 15.28 .382 14.80 .407 14.34 .432 13.92 .485 13.14 .541 12.44 .600 11.81 .662 11.25 .727 10.73
.222 25.3 .239 24.3 .258 23.5 .277 22.6 .297 21.9 .317 21.1 .338 20.5 .360 19.83 .383 19.24 .431 18.15 .480 17.19 .533 16.31 .588 15.53 .647 14.81
.1882 39.4 .204 36.9 .219 35.6 .236 34.3 .253 33.1 .271 32.0 .289 31.0 .308 30.0 .328 29.1 .368 27.5 .412 26.0 .457 24.6 .506 23.4 .556 22.3
.1825 41.5 .1974 39.9 .213 38.4 .229 37.0 .246 35.8 .263 34.6 .281 33.5 .299 32.4 .318 31.4 .358 29.6 .400 28.0 .444 26.6 .491 25.3 .540 24.1
.1574 59.9 .1705 57.6 .1841 55.4 .1982 53.4 .213 51.5 .228 49.8 .244 48.2 .260 46.7 .277 45.2 .311 42.6 .349 40.3 .387 38.2 .429 36.3 .472 34.6
.1325 91.1 .1438 87.5 .1554 84.1 .1675 81.0 .1801 78.1 .1931 75.5 .207 73.0 .221 70.6 .235 68.4 .265 64.4 .297 60.8 .331 57.7 .367 54.8 .404 52.2
.1262 102.3 .1370 98.2 .1479 94.4 .1598 90.9 .1718 87.6 .1843 84.6 .1972 81.8 .211 79.2 .224 76.7 .254 72.1 .284 68.2 .317 64.6 .351 61.4 .387 58.4
.0772 312. .0843 299. .0917 286. .0994 275. .1074 264. .1157 255. .1243 246. .1332 238. .1424 230. .1620 215. .1824 203. .205 191.6 .227 181.7 .252 172.6
.0707 377. .0772 360. .0842 345. .0913 332. .0986 319. .1065 307. .1145 296. .1229 286. .1315 276. .1496 259. .1690 244. .1894 230. .211 218. .234 207.
.0682 407. .0746 389. .0812 373. .0882 358. .0954 344. .1029 331. .1107 319. .1188 308. .1272 298. .1448 279. .1635 263. .1836 248. .204 235. .227 223.
.0605 521. .0663 498. .0723 477. .0786 457. .0852 439. .0921 423. .0993 407. .1066 393. .1142 379. .1303 355. .1474 334. .1657 315. .1848 298. .205 283.
.0552 626. .0606 598. .0662 572. .0721 548. .0783 526. .0845 506. .0913 487. .0982 470. .1053 454. .1203 424. .1363 399. .1535 376. .1713 356. .1905 337.
.0526 691. .0577 660. .0632 631. .0688 604. .0747 580. .0809 557. .0873 537. .0939 517. .1008 499. .1153 467. .1308 438. .1472 413. .1650 391 .1829 371.
Dec. .875
29⁄ 32
.9063
15⁄ 16
.9375
31⁄ 32
15
.9688 1.000
11⁄32
1.031
11⁄16
1.063
11⁄32
1.094
11⁄8
1.125
13⁄16
1.188
11⁄4
1.250
15⁄16
1.313
13⁄8
1.375
17⁄16
1.438
.1138 130.5 .1236 125.2 .1338 120.4 .1445 115.9 .1555 111.7 .1669 107.8 .1788 104.2 .1910 100.8 .204 97.6 .231 91.7 .258 86.6 .288 82.0 .320 77.9 .353 74.1
.0999 176.3 .1087 169.0 .1178 162.3 .1273 156.1 .1372 150.4 .1474 145.1 .1580 140.1 .1691 135.5 .1804 131.2 .204 123.3 .230 116.2 .256 110.1 .285 104.4 .314 99.4
.0928 209. .1010 199.9 .1096 191.9 .1183 184.5 .1278 177.6 .1374 171.3 .1474 165.4 .1578 159.9 .1685 154.7 .1908 145.4 .215 137.0 .240 129.7 .267 123.0 .295 117.0
.0880 234. .0959 224. .1041 215. .1127 207. .1216 198.8 .1308 191.6 .1404 185.0 .1503 178.8 .1604 173.0 .1812 162.4 .205 153.1 .229 144.7 .255 137.3 .282 130.6
SPRING DESIGN
1
Deflection f (inch) per coil, at Load P (pounds)
a This
Copyright 2004, Industrial Press, Inc., New York, NY
327
table is for ASTM A229 oil tempered spring steel with a torsional modulus G of 11,200,000 psi, and an uncorrected torsional stress of 100,000 psi. For other materials, and other important footnotes, see page 325.
Machinery's Handbook 27th Edition
328
Table 5. (Continued) Compression and Extension Spring Deflections a Wire Size or Washburn and Moen Gauge, and Decimal Equivalent Spring Outside Dia. Dec.
11⁄2
1.500
15⁄8
1.625
13⁄4
1.750
17⁄8
1.875
115⁄16
1.938
2
2.000
21⁄16
2.063
21⁄8
2.125
23⁄16
2.188
21⁄4
2.250
25⁄16
2.313
23⁄8
2.375
27⁄16
2.438
21⁄2
2.500
1⁄ 8
10
9
5⁄ 32
8
7
3⁄ 16
6
5
7⁄ 32
4
3
1⁄ 4
2
9⁄ 32
0
5⁄ 16
.1205
.125
.135
.1483
.1563
.162
.177
.1875
.192
.207
.2188
.2253
.2437
.250
.2625
.2813
.3065
.3125
.443 49.8 .527 45.7 .619 42.2 .717 39.2 .769 37.8 .823 36.6 .878 35.4 .936 34.3 .995 33.3 1.056 32.3 1.119 31.4 1.184 30.5 … … … …
.424 55.8 .505 51.1 .593 47.2 .687 43.8 .738 42.3 .789 40.9 .843 39.6 .898 38.3 .955 37.2 1.013 36.1 1.074 35.1 1.136 34.1 1.201 33.2 1.266 32.3
.387 70.8 .461 64.8 .542 59.8 .629 55.5 .676 53.6 .723 51.8 .768 50.1 .823 48.5 .876 47.1 .930 45.7 .986 44.4 1.043 43.1 1.102 42.0 1.162 40.9
.350 94.8 .413 86.7 .485 80.0 .564 74.2 .605 71.6 .649 69.2 .693 66.9 .739 64.8 .786 62.8 .835 60.9 .886 59.2 .938 57.5 .991 56.0 1.046 54.5
.324 111.5 .387 102.0 .456 94.0 .530 87.2 .569 84.2 .610 81.3 .652 78.7 .696 76.1 .740 73.8 .787 71.6 .834 69.5 .884 67.6 .934 65.7 .986 64.0
.310 124.5 .370 113.9 .437 104.9 .508 97.3 .546 93.8 .585 90.6 .626 87.6 .667 84.9 .711 82.2 .755 79.8 .801 77.5 .848 75.3 .897 73.2 .946 71.3
.277 164.6 .332 150.3 .392 138.5 .457 128.2 .492 123.6 .527 119.4 .564 115.4 .602 111.8 .641 108.3 .681 105.7 .723 101.9 .763 99.1 .810 96.3 .855 93.7
.202 352. .244 321. .290 295. .339 272. .365 262. .392 253. .421 245. .449 236. .479 229. .511 222. .542 215. .576 209. .609 203. .644 197.5
.1815 452. .220 411. .261 377. .306 348. .331 335. .355 324. .381 312. .407 302. .435 292. .463 283. .493 275. .523 267. .554 259. .586 252.
.1754 499. .212 446. .253 409. .296 378. .320 364. .344 351. .369 339. .395 327. .421 317. .449 307. .478 298. .507 289. .537 281. .568 273.
.1612 574. .1986 521. .237 477. .278 440. .300 425. .323 409. .346 395. .371 381. .396 369. .423 357. .449 347. .477 336. .506 327. .536 317.
.1482 717. .1801 650. .215 595. .253 548. .273 528. .295 509. .316 491. .339 474. .362 459. .387 444. .411 430. .437 417. .464 405. .491 394.
.1305 947. .1592 858. .1908 783. .225 721. .243 693. .263 668. .282 644. .303 622. .324 601. .346 582. .368 564. .392 547. .416 531. .441 516.
.1267 1008. .1547 912. .1856 833. .219 767. .237 737. .256 710. .275 685. .295 661. .316 639. .337 618. .359 599. .382 581. .405 564. .430 548.
Deflection f (inch) per coil, at Load P (pounds) .258 197.1 .309 180.0 .366 165.6 .426 153.4 .458 147.9 .492 142.8 .526 138.1 .562 133.6 .598 129.5 .637 125.5 .676 121.8 .716 118.3 .757 115.1 .800 111.6
.250 213. .300 193.9 .355 178.4 .414 165.1 .446 159.2 .478 153.7 .512 148.5 .546 143.8 .582 139.2 .619 135.0 .657 131.0 .696 127.3 .737 123.7 .778 120.4
.227 269. .273 246. .323 226. .377 209. .405 201. .436 194.3 .467 187.7 .499 181.6 .532 175.8 .566 170.5 .601 165.4 .637 160.7 .674 156.1 .713 151.9
.210 321. .254 292. .301 269. .351 248. .379 239. .407 231. .436 223. .466 216. .497 209. .529 202. .562 196.3 .596 190.7 .631 185.3 .667 180.2
a This
table is for ASTM A229 oil tempered spring steel with a torsional modulus G of 11,200,000 psi, and an uncorrected torsional stress of 100,000 psi. For other materials, and other important footnotes, see page 325.
Copyright 2004, Industrial Press, Inc., New York, NY
SPRING DESIGN
Nom.
11
Machinery's Handbook 27th Edition SPRING DESIGN
329
Extension Springs.—About 10 per cent of all springs made by many companies are of this type, and they frequently cause trouble because insufficient consideration is given to stress due to initial tension, stress and deflection of hooks, special manufacturing methods, secondary operations and overstretching at assembly. Fig. 15 shows types of ends used on these springs.
Machine loop and machine hook shown in line
Machine loop and machine hook shown at right angles
Hand loop and hook at right angles
Full loop on side and small eye from center
Double twisted full loop over center
Single full loop centered
Full loop at side
Small off-set hook at side
Machine half-hook over center
Small eye at side
Small eye over center
Reduced loop to center
Hand half-loop over center
Plain squarecut ends
All the Above Ends are Standard Types for Which No Special Tools are Required
Long round-end hook over center
Long square-end hook over center
Extended eye from either center or side
V-hook over center
Straight end annealed to allow forming
Coned end with short swivel eye
Coned end to hold long swivel eye
Coned end with swivel bolt
Coned end with swivel hook
This Group of Special Ends Requires Special Tools Fig. 15. Types of Helical Extension Spring Ends
Initial tension: In the spring industry, the term “Initial tension” is used to define a force or load, measurable in pounds or ounces, which presses the coils of a close wound extension spring against one another. This force must be overcome before the coils of a spring begin to open up. Initial tension is wound into extension springs by bending each coil as it is wound away from its normal plane, thereby producing a slight twist in the wire which causes the coil to spring back tightly against the adjacent coil. Initial tension can be wound into cold-coiled
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 330
SPRING DESIGN LIVE GRAPH Click here to view
44 42
The values in the curves in the chart are for springs made from spring steel. They should be reduced 15 per cent for stainless steel. 20 per cent for copper-nickel alloys and 50 per cent for phosphor bronze.
40 Torsional Stress, Pounds per Square Inch (thousands)
38 36 34 32 30 28
Initial tension in this area is readily obtainable. Use whenever possible.
26 24 22
Maximum initial tension
20 18 Pe
rm
16
iss
ibl
14 12 10
et
ors
ion
al
str
ess
8 Inital tension in this area is difficult to maintain with accurate and uniform results.
6 4
3
4
5
6
7
8 9 10 11 12 13 14 15 16 Spring Index
Fig. 16. Permissible Torsional Stress Caused by Initial Tension in Coiled Extension Springs for Different Spring Indexes
extension springs only. Hot-wound springs and springs made from annealed steel are hardened and tempered after coiling, and therefore initial tension cannot be produced. It is possible to make a spring having initial tension only when a high tensile strength, obtained by cold drawing or by heat-treatment, is possessed by the material as it is being wound into springs. Materials that possess the required characteristics for the manufacture of such springs include hard-drawn wire, music wire, pre-tempered wire, 18-8 stainless steel, phosphor-bronze, and many of the hard-drawn copper-nickel, and nonferrous alloys. Permissible torsional stresses resulting from initial tension for different spring indexes are shown in Fig. 16. Hook failure: The great majority of breakages in extension springs occurs in the hooks. Hooks are subjected to both bending and torsional stresses and have higher stresses than the coils in the spring. Stresses in regular hooks: The calculations for the stresses in hooks are quite complicated and lengthy. Also, the radii of the bends are difficult to determine and frequently vary between specifications and actual production samples. However, regular hooks are more
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPRING DESIGN
331
highly stressed than the coils in the body and are subjected to a bending stress at section B (see Table 6.) The bending stress Sb at section B should be compared with allowable stresses for torsion springs and with the elastic limit of the material in tension (See Figs. 7 through 10.) Stresses in cross over hooks: Results of tests on springs having a normal average index show that the cross over hooks last longer than regular hooks. These results may not occur on springs of small index or if the cross over bend is made too sharply. In as much as both types of hooks have the same bending stress, it would appear that the fatigue life would be the same. However, the large bend radius of the regular hooks causes some torsional stresses to coincide with the bending stresses, thus explaining the earlier breakages. If sharper bends were made on the regular hooks, the life should then be the same as for cross over hooks. Table 6. Formula for Bending Stress at Section B Type of Hook
Stress in Bending
5PD 2 S b = --------------I.D.d 3 Regular Hook
Cross-over Hook
Stresses in half hooks: The formulas for regular hooks can also be used for half hooks, because the smaller bend radius allows for the increase in stress. It will therefore be observed that half hooks have the same stress in bending as regular hooks. Frequently overlooked facts by many designers are that one full hook deflects an amount equal to one half a coil and each half hook deflects an amount equal to one tenth of a coil. Allowances for these deflections should be made when designing springs. Thus, an extension spring, with regular full hooks and having 10 coils, will have a deflection equal to 11 coils, or 10 per cent more than the calculated deflection. Extension Spring Design.—The available space in a product or assembly usually determines the limiting dimensions of a spring, but the wire size, number of coils, and initial tension are often unknown. Example:An extension spring is to be made from spring steel ASTM A229, with regular hooks as shown in Fig. 17. Calculate the wire size, number of coils and initial tension. Note: Allow about 20 to 25 per cent of the 9 pound load for initial tension, say 2 pounds, and then design for a 7 pound load (not 9 pounds) at 5⁄8 inch deflection. Also use lower stresses than for a compression spring to allow for overstretching during assembly and to obtain a safe stress on the hooks. Proceed as for compression springs, but locate a load in the tables somewhat higher than the 9 pound load. Method 1, using table: From Table 5 locate 3⁄4 inch outside diameter in the left column and move to the right to locate a load P of 13.94 pounds. A deflection f of 0.212 inch appears above this figure. Moving vertically from this position to the top of the column a suitable wire diameter of 0.0625 inch is found. The remaining design calculations are completed as follows: Step 1: The stress with a load of 7 pounds is obtained as follows: The 7 pound load is 50.2 per cent of the 13.94 pound load. Therefore, the stress S at 7 pounds = 0.502 per cent × 100,000 = 50,200 pounds per square inch.
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Machinery's Handbook 27th Edition 332
SPRING DESIGN
Fig. 17. Extension Spring Design Example
Step 2: The 50.2 per cent figure is also used to determine the deflection per coil f: 0.502 per cent × 0.212 = 0.1062 inch. Step 3: The number of active coils. (say 6) 0.625- = 5.86 AC = F --- = --------------f 0.1062 This result should be reduced by 1 to allow for deflection of 2 hooks (see notes 1 and 2 that follow these calculations.) Therefore, a quick answer is: 5 coils of 0.0625 inch diameter wire. However, the design procedure should be completed by carrying out the following steps: Step 4: The body length = (TC + 1) × d = (5 + 1) × 0.0625 = 3⁄8 inch. Step 5: The length from the body to inside hook – Body- = 1.4375 – 0.375- = 0.531 inch = FL ----------------------------------------------------------2 2 Percentage of I.D. = 0.531 ------------- = 0.531 ------------- = 85 per cent I.D. 0.625 This length is satisfactory, see Note 3 following this proceedure. Step 6: 0.75 - – 1 = 11 The spring index = O.D. ----------- – 1 = --------------d 0.0625 Step 7: The initial tension stress is S × IT 50 ,200 × 2 S it = --------------- = -------------------------- = 14 ,340 pounds per square inch P 7 This stress is satisfactory, as checked against curve in Fig. 16. Step 8: The curvature correction factor K = 1.12 (Fig. 13). Step 9: The total stress = (50,200 + 14,340) × 1.12 = 72.285 pounds per square inch This result is less than 106,250 pounds per square inch permitted by the middle curve for 0.0625 inch wire in Fig. 3 and therefore is a safe working stress that permits some additional deflection that is usually necessary for assembly purposes.
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Machinery's Handbook 27th Edition SPRING DESIGN
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Step 10: The large majority of hook breakage is due to high stress in bending and should be checked as follows: From Table 6, stress on hook in bending is: 5 × 9 × 0.6875 2 = 139 ,200 pounds per square inch 5PD 2- = -------------------------------------S b = -------------I.D.d 3 0.625 × 0.0625 3 This result is less than the top curve value, Fig. 8, for 0.0625 inch diameter wire, and is therefore safe. Also see Note 5 that follows. Notes: The following points should be noted when designing extension springs: 1) All coils are active and thus AC = TC. 2) Each full hook deflection is approximately equal to 1⁄2 coil. Therefore for 2 hooks, reduce the total coils by 1. (Each half hook deflection is nearly equal to 1⁄10 of a coil.) 3) The distance from the body to the inside of a regular full hook equals 75 to 85 per cent (90 per cent maximum) of the I.D. For a cross over center hook, this distance equals the I.D. 4) Some initial tension should usually be used to hold the spring together. Try not to exceed the maximum curve shown on Fig. 16. Without initial tension, a long spring with many coils will have a different length in the horizontal position than it will when hung vertically. 5) The hooks are stressed in bending, therefore their stress should be less than the maximum bending stress as used for torsion springs — use top fatigue strength curves Figs. 7 through 10. Method 2, using formulas: The sequence of steps for designing extension springs by formulas is similar to that for compression springs. The formulas for this method are given in Table 3. Tolerances for Compression and Extension Springs.—Tolerances for coil diameter, free length, squareness, load, and the angle between loop planes for compression and extension springs are given in Tables 7 through 12. To meet the requirements of load, rate, free length, and solid height, it is necessary to vary the number of coils for compression springs by ± 5 per cent. For extension springs, the tolerances on the numbers of coils are: for 3 to 5 coils, ± 20 per cent; for 6 to 8 coils, ± 30 per cent; for 9 to 12 coils, ± 40 per cent. For each additional coil, a further 11⁄2 per cent tolerance is added to the extension spring values. Closer tolerances on the number of coils for either type of spring lead to the need for trimming after coiling, and manufacturing time and cost are increased. Fig. 18 shows deviations allowed on the ends of extension springs, and variations in end alignments. Table 7. Compression and Extension Spring Coil Diameter Tolerances Spring Index Wire Diameter, Inch 0.015 0.023 0.035 0.051 0.076 0.114 0.171 0.250 0.375 0.500
4
6
8
10
12
14
16
0.005 0.007 0.009 0.012 0.016 0.021 0.028 0.035 0.046 0.080
0.006 0.008 0.011 0.015 0.019 0.025 0.033 0.042 0.054 0.100
0.007 0.010 0.013 0.017 0.022 0.029 0.038 0.049 0.064 0.125
Tolerance, ± inch 0.002 0.002 0.002 0.003 0.004 0.006 0.008 0.011 0.016 0.021
0.002 0.003 0.004 0.005 0.007 0.009 0.012 0.015 0.020 0.030
0.003 0.004 0.006 0.007 0.010 0.013 0.017 0.021 0.026 0.040
0.004 0.006 0.007 0.010 0.013 0.018 0.023 0.028 0.037 0.062
Courtesy of the Spring Manufacturers Institute
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 334
SPRING DESIGN .05 inch × Outside diameter
± .05 inch × Outside diameter
5 degrees
.05 inch × Outside diameter
d 2
or
1 64
inch.
Whichever is greater
45 degrees
Maximum Opening for Closed Loop
Maximum Overlap for Closed Loop
Fig. 18. Maximum Deviations Allowed on Ends and Variation in Alignment of Ends (Loops) for Extension Springs
Table 8. Compression Spring Normal Free-Length Tolerances, Squared and Ground Ends Spring Index
Number of Active Coils per Inch
4
0.5 1 2 4 8 12 16 20
0.010 0.011 0.013 0.016 0.019 0.021 0.022 0.023
6
8
10
12
14
16
0.016 0.018 0.022 0.026 0.030 0.034 0.036 0.038
0.016 0.019 0.023 0.027 0.032 0.036 0.038 0.040
Tolerance, ± Inch per Inch of Free Lengtha 0.011 0.013 0.015 0.018 0.022 0.024 0.026 0.027
0.012 0.015 0.017 0.021 0.024 0.027 0.029 0.031
0.013 0.016 0.019 0.023 0.026 0.030 0.032 0.034
0.015 0.017 0.020 0.024 0.028 0.032 0.034 0.036
a For springs less than 0.5 inch long, use the tolerances for 0.5 inch long springs. For springs with unground closed ends, multiply the tolerances by 1.7. Courtesy of the Spring Manufacturers Institute
Table 9. Extension Spring Normal Free-Length and End Tolerances Free-Length Tolerances Spring Free Length (inch) Up to 0.5 Over 0.5 to 1.0 Over 1.0 to 2.0 Over 2.0 to 4.0
End Tolerances
Tolerance (inch)
Total Number of Coils
Angle Between Loop Planes
±0.020 ±0.030 ±0.040 ±0.060
3 to 6 7 to 9 10 to 12
±25° ±35° ±45°
Free-Length Tolerances Spring Free Length (inch)
Tolerance (inch)
Over 4.0 to 8.0 Over 8.0 to 16.0 Over 16.0 to 24.0
±0.093 ±0.156 ±0.218
End Tolerances Total Number of Coils
Angle Between Loop Planes
13 to 16 Over 16
±60° Random
Courtesy of the Spring Manufacturers Institute
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Machinery's Handbook 27th Edition SPRING DESIGN
335
Table 10. Compression Spring Squareness Tolerances Slenderness Ratio FL/Da 0.5 1.0 1.5 2.0 3.0 4.0 6.0 8.0 10.0 12.0
4
6
3.0 2.5 2.5 2.5 2.0 2.0 2.0 2.0 2.0 2.0
3.0 3.0 2.5 2.5 2.5 2.0 2.0 2.0 2.0 2.0
Spring Index 8 10 12 Squareness Tolerances (± degrees) 3.5 3.5 3.5 3.0 3.0 3.0 2.5 3.0 3.0 2.5 2.5 3.0 2.5 2.5 2.5 2.5 2.5 2.5 2.0 2.5 2.5 2.0 2.0 2.5 2.0 2.0 2.0 2.0 2.0 2.0
14
16
3.5 3.5 3.0 3.0 2.5 2.5 2.5 2.5 2.5 2.0
4.0 3.5 3.0 3.0 3.0 2.5 2.5 2.5 2.5 2.5
a Slenderness Ratio = FL÷D
Springs with closed and ground ends, in the free position. Squareness tolerances closer than those shown require special process techniques which increase cost. Springs made from fine wire sizes, and with high spring indices, irregular shapes or long free lengths, require special attention in determining appropriate tolerance and feasibility of grinding ends.
Table 11. Compression Spring Normal Load Tolerances Deflection (inch)a
Length Tolerance, ± inch
0.05
0.005 0.010 0.020 0.030 0.040 0.050 0.060 0.070 0.080 0.090 0.100 0.200 0.300 0.400 0.500
12 … … … … … … … … … … … … … …
0.10
0.15
0.20
0.25
0.30
0.40
0.50
0.75
1.00
1.50
2.00
3.00
4.00
6.00
… … … … 5 5.5 6 6.5 7.5 8 8.5 15.5 22 … …
… … … … … … 5 5.5 6 6 7 12 17 21 25
… … … … … … … … 5 5 5.5 8.5 12 15 18.5
… … … … … … … … … … … 7 9.5 12 14.5
… … … … … … … … … … … 5.5 7 8.5 10.5
Tolerance, ± Per Cent of Load 7 12 22 … … … … … … … … … … … …
6 8.5 15.5 22 … … … … … … … … … … …
5 7 12 17 22 … … … … … … … … … …
… 6.5 10 14 18 22 25 … … … … … … … …
… 5.5 8.5 12 15.5 19 22 25 … … … … … … …
… 5 7 9.5 12 14.5 17 19.5 22 25 … … … … …
… … 6 8 10 12 14 16 18 20 22 … … … …
… … 5 6 7.5 9 10 11 12.5 14 15.5 … … … …
… … … 5 6 7 8 9 10 11 12 22 … … …
a From free length to loaded position.
Torsion Spring Design.—Fig. 19 shows the types of ends most commonly used on torsion springs. To produce them requires only limited tooling. The straight torsion end is the least expensive and should be used whenever possible. After determining the spring load or torque required and selecting the end formations, the designer usually estimates suitable space or size limitations. However, the space should be considered approximate until the wire size and number of coils have been determined. The wire size is dependent principally upon the torque. Design data can be devoloped with the aid of the tabular data, which is a simple method, or by calculation alone, as shown in the following sections. Many other factors affecting the design and operation of torsion springs are also covered in the section, Torsion Spring Design Recommendations on page 341. Design formulas are shown in Table 13. Curvature correction: In addition to the stress obtained from the formulas for load or deflection, there is a direct shearing stress on the inside of the section due to curvature. Therefore, the stress obtained by the usual formulas should be multiplied by the factor K
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 336
SPRING DESIGN Table 12. Extension Spring Normal Load Tolerances Wire Diameter (inch)
Spring Index
4
6
8
10
12
14
16
FL ------F
0.015
12 8 6 4.5 2.5 1.5 0.5 12 8 6 4.5 2.5 1.5 0.5 12 8 6 4.5 2.5 1.5 0.5 12 8 6 4.5 2.5 1.5 0.5 12 8 6 4.5 2.5 1.5 0.5 12 8 6 4.5 2.5 1.5 0.5 12 8 6 4.5 2.5 1.5 0.5
20.0 18.5 16.8 15.0 13.1 10.2 6.2 17.0 16.2 15.2 13.7 11.9 9.9 6.3 15.8 15.0 14.2 12.8 11.2 9.5 6.3 14.8 14.2 13.4 12.3 10.8 9.2 6.4 14.0 13.2 12.6 11.7 10.5 8.9 6.5 13.1 12.4 11.8 11.1 10.1 8.6 6.6 12.3 11.7 11.0 10.5 9.7 8.3 6.7
0.022
0.032
0.044
0.062
0.092
0.125
0.187
0.250
0.375
0.437
14.3 13.2 11.8 10.3 8.5 6.5 3.8 12.0 11.0 10.0 9.0 7.9 6.4 4.0 10.8 10.1 9.3 8.3 7.4 6.2 4.1 9.9 9.2 8.6 7.8 7.0 6.0 4.2 9.0 8.4 7.9 7.2 6.6 5.7 4.3 8.1 7.6 7.2 6.7 6.2 5.5 4.4 7.2 6.8 6.5 6.2 5.7 5.3 4.6
13.8 12.5 11.2 9.7 8.0 6.1 3.6 11.5 10.5 9.4 8.3 7.2 6.0 3.7 10.2 9.4 8.6 7.8 6.9 5.8 3.9 9.3 8.6 8.0 7.3 6.5 5.6 4.0 8.5 7.9 7.4 6.8 6.1 5.4 4.2 7.6 7.2 6.8 6.3 5.7 5.2 4.3 6.8 6.5 6.2 5.8 5.4 5.1 4.5
13.0 11.5 9.9 8.4 6.8 5.3 3.3 11.2 10.0 8.8 7.6 6.2 4.9 3.5 10.0 9.0 8.1 7.2 6.1 4.9 3.6 9.2 8.3 7.6 6.8 5.9 5.0 3.8 8.2 7.5 6.9 6.3 5.6 4.8 4.0 7.2 6.8 6.3 5.8 5.2 4.7 4.2 6.3 6.0 5.7 5.3 4.9 4.6 4.3
12.6 11.0 9.4 7.9 6.2 4.8 3.2 10.7 9.5 8.3 7.1 6.0 4.7 3.4 9.5 8.6 7.6 6.6 5.6 4.5 3.5 8.8 8.0 7.2 6.4 5.5 4.6 3.7 7.9 7.2 6.4 5.8 5.2 4.5 3.3 7.0 6.4 5.9 5.4 5.0 4.5 4.0 6.1 5.7 5.4 5.1 4.7 4.4 4.1
Tolerance, ± Per Cent of Load 18.5 17.5 16.1 14.7 12.4 9.9 5.4 15.5 14.7 14.0 12.4 10.8 9.0 5.5 14.3 13.7 13.0 11.7 10.2 8.6 5.6 13.3 12.8 12.1 10.8 9.6 8.3 5.7 12.3 11.8 11.2 10.2 9.2 8.0 5.8 11.3 10.9 10.4 9.7 8.8 7.7 5.9 10.3 10.0 9.6 9.1 8.4 7.4 5.9
17.6 16.7 15.5 14.1 12.1 9.3 4.8 14.6 13.9 12.9 11.5 10.2 8.3 4.9 13.1 12.5 11.7 10.7 9.5 7.8 5.0 12.0 11.6 10.8 10.0 9.0 7.5 5.1 11.1 10.7 10.2 9.4 8.5 7.2 5.3 10.2 9.8 9.3 8.7 8.1 7.0 5.4 9.2 8.9 8.5 8.1 7.6 6.6 5.5
16.9 15.8 14.7 13.5 11.8 8.9 4.6 14.1 13.4 12.3 11.0 9.8 7.7 4.7 13.0 12.1 11.2 10.1 8.8 7.1 4.8 11.9 11.2 10.5 9.5 8.4 6.9 4.9 10.8 10.2 9.7 9.0 8.0 6.8 5.1 9.7 9.2 8.8 8.2 7.6 6.7 5.2 8.6 8.3 8.0 7.5 7.0 6.2 5.3
16.2 15.0 13.8 12.6 10.6 8.0 4.3 13.5 12.6 11.6 10.5 9.4 7.3 4.5 12.1 11.4 10.6 9.7 8.3 6.9 4.5 11.1 10.5 9.8 9.0 8.0 6.7 4.7 10.1 9.6 9.0 8.4 7.8 6.5 4.9 9.1 8.7 8.3 7.8 7.1 6.3 5.0 8.1 7.8 7.5 7.2 6.7 6.0 5.1
15.5 14.5 13.2 12.0 10.0 7.5 4.1 13.1 12.2 10.9 10.0 9.0 7.0 4.3 12.0 11.0 10.0 9.0 7.9 6.7 4.4 10.9 10.2 9.3 8.5 7.7 6.5 4.5 9.8 9.3 8.5 8.0 7.4 6.3 4.7 8.8 8.3 7.7 7.2 6.7 6.0 4.8 7.7 7.4 7.1 6.8 6.3 5.8 5.0
15.0 14.0 12.7 11.5 9.1 7.0 4.0 12.7 11.7 10.7 9.6 8.5 6.7 4.1 11.5 10.6 9.7 8.7 7.7 6.5 4.2 10.5 9.7 8.9 8.1 7.3 6.3 4.3 9.5 8.9 8.2 7.6 7.0 6.1 4.5 8.4 8.0 7.5 7.0 6.5 5.8 4.6 7.4 7.2 6.9 6.5 6.1 5.6 4.8
FL ⁄ F = the ratio of the spring free length FL to the deflection F.
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Machinery's Handbook 27th Edition SPRING DESIGN
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Fig. 19. The Most Commonly Used Types of Ends for Torsion Springs
LIVE GRAPH Click here to view
Correction Factor, K
1.3
1.2
Round Wire Square Wire and Rectangular Wire K × S = Total Stress
1.1
1.0 3
4
5
6
7
8 9 10 Spring Index
11
12
13
14
15
16
Fig. 20. Torsion Spring Stress Correction for Curvature
obtained from the curve in Fig. 20. The corrected stress thus obtained is used only for comparison with the allowable working stress (fatigue strength) curves to determine if it is a safe value, and should not be used in the formulas for deflection. Torque: Torque is a force applied to a moment arm and tends to produce rotation. Torsion springs exert torque in a circular arc and the arms are rotated about the central axis. It should be noted that the stress produced is in bending, not in torsion. In the spring industry it is customary to specify torque in conjunction with the deflection or with the arms of a spring at a definite position. Formulas for torque are expressed in pound-inches. If ounceinches are specified, it is necessary to divide this value by 16 in order to use the formulas. When a load is specified at a distance from a centerline, the torque is, of course, equal to the load multiplied by the distance. The load can be in pounds or ounces with the distances in inches or the load can be in grams or kilograms with the distance in centimeters or millimeters, but to use the design formulas, all values must be converted to pounds and inches. Design formulas for torque are based on the tangent to the arc of rotation and presume that a rod is used to support the spring. The stress in bending caused by the moment P × R is identical in magnitude to the torque T, provided a rod is used. Theoretically, it makes no difference how or where the load is applied to the arms of torsion springs. Thus, in Fig. 21, the loads shown multiplied by their respective distances pro-
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 338
SPRING DESIGN Table 13. Formulas for Torsion Springs Springs made from round wire Feature
d= Wire diameter, Inches
Sb = Stress, bending pounds per square inch
N= Active Coils
F° = Deflection
T= Torque Inch lbs. (Also = P × R) I D1 = Inside Diameter After Deflection, Inches
Springs made from square wire Formula a,b
3
10.18T ----------------Sb
3
6T -----Sb
4
4000TND ------------------------EF °
4
2375TND ------------------------EF °
10.18T ----------------d3
6T -----d3
EdF ° -----------------392ND
EdF ° -----------------392ND
EdF ° ------------------392S b D
EdF ° ------------------392S b D
Ed 4 F ° ------------------4000TD
Ed 4 F ° ------------------2375TD
392S b ND ----------------------Ed
392S b ND -----------------------Ed
4000TND ------------------------Ed 4
2375TND ------------------------Ed 4
0.0982S b d 3
0.1666S b d 3
Ed 4 F ° -------------------4000ND
Ed 4 F ° -------------------2375ND
N ( ID free ) --------------------------F °N + -------360
N ( ID free ) --------------------------F °N + -------360
a Where two formulas are given for one feature, the designer should use the one found to be appropriate for the given design. The end result from either of any two formulas is the same. b The symbol notation is given on page 308.
duce the same torque; i.e., 20 × 0.5 = 10 pound-inches; 10 × 1 = 10 pound-inches; and 5 × 2 = 10 pound-inches. To further simplify the understanding of torsion spring torque, observe in both Fig. 22 and Fig. 23 that although the turning force is in a circular arc the torque is not equal to P times the radius. The torque in both designs equals P × R because the spring rests against the support rod at point a. Design Procedure: Torsion spring designs require more effort than other kinds because consideration has to be given to more details such as the proper size of a supporting rod, reduction of the inside diameter, increase in length, deflection of arms, allowance for friction, and method of testing.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPRING DESIGN
Fig. 21. Right-Hand Torsion Spring
Fig. 22. Left-Hand Torsion Spring The Torque is T = P × R, Not P × Radius, because the Spring is Resting Against the Support Rod at Point a
Fig. 23. Left-Hand Torsion Spring As with the Spring in Fig. 22, the Torque is T = P × R, Not P × Radius, Because the Support Point Is at a
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339
Machinery's Handbook 27th Edition 340
SPRING DESIGN
Example: What music wire diameter and how many coils are required for the torsion spring shown in Fig. 24, which is to withstand at least 1000 cycles? Determine the corrected stress and the reduced inside diameter after deflection.
Fig. 24. Torsion Spring Design Example. The Spring Is to be Assembled on a 7⁄16-Inch Support Rod
Method 1, using table: From Table 14, page 343, locate the 1⁄2 inch inside diameter for the spring in the left-hand column. Move to the right and then vertically to locate a torque value nearest to the required 10 pound-inches, which is 10.07 pound-inches. At the top of the same column, the music wire diameter is found, which is Number 31 gauge (0.085 inch). At the bottom of the same column the deflection for one coil is found, which is 15.81 degrees. As a 90-degree deflection is required, the number of coils needed is 90⁄15.81 = 5.69 (say 53⁄4 coils). D 0.500 + 0.085 The spring index ---- = --------------------------------- = 6.88 and thus the curvature correction factor d 0.085 K from Fig. 20 = 1.13. Therefore the corrected stress equals 167,000 × 1.13 = 188,700 pounds per square inch which is below the Light Service curve (Fig. 7) and therefore should provide a fatigue life of over 1,000 cycles. The reduced inside diameter due to deflection is found from the formula in Table 13: N ( ID free ) 5.75 × 0.500 ID 1 = --------------------------- = ------------------------------ = 0.479 in. F 90N + --------5.75 + -------360 360 This reduced diameter easily clears a suggested 7⁄16 inch diameter supporting rod: 0.479 − 0.4375 = 0.041 inch clearance, and it also allows for the standard tolerance. The overall length of the spring equals the total number of coils plus one, times the wire diameter. Thus, 63⁄4 × 0.085 = 0.574 inch. If a small space of about 1⁄64 in. is allowed between the coils to eliminate coil friction, an overall length of 21⁄32 inch results. Although this completes the design calculations, other tolerances should be applied in accordance with the Torsion Spring Tolerance Tables 16 through 17 shown at the end of this section.
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Machinery's Handbook 27th Edition SPRING DESIGN
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Longer fatigue life: If a longer fatigue life is desired, use a slightly larger wire diameter. Usually the next larger gage size is satisfactory. The larger wire will reduce the stress and still exert the same torque, but will require more coils and a longer overall length. Percentage method for calculating longer life: The spring design can be easily adjusted for longer life as follows: 1) Select the next larger gage size, which is Number 32 (0.090 inch) from Table 14. The torque is 11.88 pound-inches, the design stress is 166,000 pounds per square inch, and the deflection is 14.9 degrees per coil. As a percentage the torque is 10⁄11.88 × 100 = 84 per cent. 2) The new stress is 0.84 × 166,000 = 139,440 pounds per square inch. This value is under the bottom or Severe Service curve, Fig. 7, and thus assures longer life. 3) The new deflection per coil is 0.84 × 14.97 = 12.57 degrees. Therefore, the total number of coils required = 90⁄12.57 = 7.16 (say 7 1⁄8). The new overall length = 8 1⁄8 × 0.090 = 0.73 inch (say 3⁄4 inch). A slight increase in the overall length and new arm location are thus necessary. Method 2, using formulas: When using this method, it is often necessary to solve the formulas several times because assumptions must be made initially either for the stress or for a wire size. The procedure for design using formulas is as follows (the design example is the same as in Method 1, and the spring is shown in Fig. 24): Step 1: Note from Table 13, page 338 that the wire diameter formula is: d =
3
10.18T ----------------Sb
Step 2: Referring to Fig. 7, select a trial stress, say 150,000 pounds per square inch. Step 3: Apply the trial stress, and the 10 pound-inches torque value in the wire diameter formula: d =
3
10.18T ----------------- = Sb
3
10.18 × 10 = ------------------------150 ,000
3
0.000679 = 0.0879 inch
The nearest gauge sizes are 0.085 and 0.090 inch diameter. Note: Table 21, page 351, can be used to avoid solving the cube root. Step 4: Select 0.085 inch wire diameter and solve the equation for the actual stress: 10.18T 10.18 × 10 S b = ----------------- = ------------------------- = 165 ,764 pounds per square inch d3 0.085 3 Step 5: Calculate the number of coils from the equation, Table 13: 28 ,500 ,000 × 0.085 × 90EdF ° = ----------------------------------------------------------= 5.73 (say 5 3⁄4 ) N = ------------------392S b D 392 × 165 ,764 × 0.585 Step 6: Calculate the total stress. The spring index is 6.88, and the correction factor K is 1.13, therefore total stress = 165,764 × 1.13 = 187,313 pounds per square inch. Note: The corrected stress should not be used in any of the formulas as it does not determine the torque or the deflection. Torsion Spring Design Recommendations.—The following recommendations should be taken into account when designing torsion springs: Hand: The hand or direction of coiling should be specified and the spring designed so deflection causes the spring to wind up and to have more coils. This increase in coils and overall length should be allowed for during design. Deflecting the spring in an unwinding direction produces higher stresses and may cause early failure. When a spring is sighted down the longitudinal axis, it is “right hand” when the direction of the wire into the spring takes a clockwise direction or if the angle of the coils follows an angle similar to the threads
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 342
SPRING DESIGN
of a standard bolt or screw, otherwise it is “left hand.” A spring must be coiled right-handed to engage the threads of a standard machine screw. Rods: Torsion springs should be supported by a rod running through the center whenever possible. If unsupported, or if held by clamps or lugs, the spring will buckle and the torque will be reduced or unusual stresses may occur. Diameter Reduction: The inside diameter reduces during deflection. This reduction should be computed and proper clearance provided over the supporting rod. Also, allowances should be considered for normal spring diameter tolerances. Winding: The coils of a spring may be closely or loosely wound, but they seldom should be wound with the coils pressed tightly together. Tightly wound springs with initial tension on the coils do not deflect uniformly and are difficult to test accurately. A small space between the coils of about 20 to 25 per cent of the wire thickness is desirable. Square and rectangular wire sections should be avoided whenever possible as they are difficult to wind, expensive, and are not always readily available. Arm Length: All the wire in a torsion spring is active between the points where the loads are applied. Deflection of long extended arms can be calculated by allowing one third of the arm length, from the point of load contact to the body of the spring, to be converted into coils. However, if the length of arm is equal to or less than one-half the length of one coil, it can be safely neglected in most applications. Total Coils: Torsion springs having less than three coils frequently buckle and are difficult to test accurately. When thirty or more coils are used, light loads will not deflect all the coils simultaneously due to friction with the supporting rod. To facilitate manufacturing it is usually preferable to specify the total number of coils to the nearest fraction in eighths or quarters such as 5 1⁄8, 5 1⁄4, 5 1⁄2, etc. Double Torsion: This design consists of one left-hand-wound series of coils and one series of right-hand-wound coils connected at the center. These springs are difficult to manufacture and are expensive, so it often is better to use two separate springs. For torque and stress calculations, each series is calculated separately as individual springs; then the torque values are added together, but the deflections are not added. Bends: Arms should be kept as straight as possible. Bends are difficult to produce and often are made by secondary operations, so they are therefore expensive. Sharp bends raise stresses that cause early failure. Bend radii should be as large as practicable. Hooks tend to open during deflection; their stresses can be calculated by the same procedure as that for tension springs. Spring Index: The spring index must be used with caution. In design formulas it is D/d. For shop measurement it is O.D./d. For arbor design it is I.D./d. Conversions are easily performed by either adding or subtracting 1 from D/d. Proportions: A spring index between 4 and 14 provides the best proportions. Larger ratios may require more than average tolerances. Ratios of 3 or less, often cannot be coiled on automatic spring coiling machines because of arbor breakage. Also, springs with smaller or larger spring indexes often do not give the same results as are obtained using the design formulas. Table of Torsion Spring Characteristics.—Table 14 shows design characteristics for the most commonly used torsion springs made from wire of standard gauge sizes. The deflection for one coil at a specified torque and stress is shown in the body of the table. The figures are based on music wire (ASTM A228) and oil-tempered MB grade (ASTM A229), and can be used for several other materials which have similar values for the modulus of elasticity E. However, the design stress may be too high or too low, and the design stress, torque, and deflection per coil should each be multiplied by the appropriate correction factor in Table 15 when using any of the materials given in that table.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 14. Torsion Spring Deflections AMW Wire Gauge Decimal Equivalenta
1 .010
2 .011
3 .012
4 .013
5 .014
6 .016
7 .018
8 .020
9 .022
10 .024
11 .026
12 .029
13 .031
14 .033
15 .035
16 .037
Design Stress, kpsi
232
229
226
224
221
217
214
210
207
205
202
199
197
196
194
192
Torque, pound-inch
.0228
.0299
.0383
.0483
.0596
.0873
.1226
.1650
.2164
.2783
.3486
.4766
.5763
.6917
.8168
.9550 …
Inside Diameter, inch
Deflection, degrees per coil
0.0625
22.35
20.33
18.64
17.29
16.05
14.15
18.72
11.51
10.56
9.818
9.137
8.343
7.896
…
…
5⁄ 64
0.078125
27.17
24.66
22.55
20.86
19.32
16.96
15.19
13.69
12.52
11.59
10.75
9.768
9.215
…
…
…
3⁄ 32
0.09375
31.98
28.98
26.47
24.44
22.60
19.78
17.65
15.87
14.47
13.36
12.36
11.19
10.53
10.18
9.646
9.171
7⁄ 64
0.109375
36.80
33.30
30.38
28.02
25.88
22.60
20.12
18.05
16.43
15.14
13.98
12.62
11.85
11.43
10.82
10.27
1⁄ 8
0.125
41.62
37.62
34.29
31.60
29.16
25.41
22.59
20.23
18.38
16.91
15.59
14.04
13.17
12.68
11.99
11.36
9⁄ 64
0.140625
46.44
41.94
38.20
35.17
32.43
28.23
25.06
22.41
20.33
18.69
17.20
15.47
14.49
13.94
13.16
12.46
5⁄ 32
0.15625
51.25
46.27
42.11
38.75
35.71
31.04
27.53
24.59
22.29
20.46
18.82
16.89
15.81
15.19
14.33
13.56
3⁄ 16
0.1875
60.89
54.91
49.93
45.91
42.27
36.67
32.47
28.95
26.19
24.01
22.04
19.74
18.45
17.70
16.67
15.75
7⁄ 32
0.21875
70.52
63.56
57.75
53.06
48.82
42.31
37.40
33.31
30.10
27.55
25.27
22.59
21.09
20.21
19.01
17.94
1⁄ 4
0.250
80.15
72.20
65.57
60.22
55.38
47.94
42.34
37.67
34.01
31.10
28.49
25.44
23.73
22.72
21.35
20.13
AMW Wire Gauge Decimal Equivalenta
17 .039
18 .041
19 .043
20 .045
21 .047
22 .049
23 .051
24 .055
25 .059
26 .063
27 .067
28 .071
29 .075
30 .080
31 .085
Design Stress, kpsi
190
188
187
185
184
183
182
180
178
176
174
173
171
169
167
Torque, pound-inch
1.107
1.272
1.460
1.655
1.876
2.114
2.371
2.941
3.590
4.322
5.139
6.080
7.084
8.497
10.07
Inside Diameter, inch
SPRING DESIGN
1⁄ 16
Deflection, degrees per coil
1⁄ 8
0.125
10.80
10.29
9.876
9.447
9.102
8.784
…
…
…
…
…
…
…
…
…
9⁄ 64
0.140625
11.83
11.26
10.79
10.32
9.929
9.572
9.244
8.654
8.141
…
…
…
…
…
…
5⁄ 32
0.15625
12.86
12.23
11.71
11.18
10.76
10.36
9.997
9.345
8.778
8.279
7.975
…
…
…
…
3⁄ 16
0.1875
14.92
14.16
13.55
12.92
12.41
11.94
11.50
10.73
10.05
9.459
9.091
8.663
8.232
7.772
7.364
7⁄ 32
0.21875
16.97
16.10
15.39
14.66
14.06
13.52
13.01
12.11
11.33
10.64
10.21
9.711
9.212
8.680
8.208
1⁄ 4
0.250
19.03
18.04
17.22
16.39
15.72
15.09
14.52
13.49
12.60
11.82
11.32
10.76
10.19
9.588
9.053
with a modulus of 28,500,000 psi.
Copyright 2004, Industrial Press, Inc., New York, NY
343
a For sizes up to 13 gauge, the table values are for music wire with a modulus E of 29,000,000 psi; and for sizes from 27 to 31 guage, the values are for oil-tempered MB
Machinery's Handbook 27th Edition
8 .020
9 .022
10 .024
11 .026
12 .029
13 .031
14 .033
15 .035
16 .037
17 .039
344
Table 14. (Continued) Torsion Spring Deflections AMW Wire Gauge Decimal Equivalenta
18 .041
19 .043
20 .045
21 .047
22 .049
23 .051
Design Stress, kpsi
210
207
205
202
199
197
196
194
192
190
188
187
185
184
183
182
Torque, pound-inch
.1650
.2164
.2783
.3486
.4766
.5763
.6917
.8168
.9550
1.107
1.272
1.460
1.655
1.876
2.114
2.371
Inside Diameter, inch
Deflection, degrees per coil
0.28125
42.03
37.92
34.65
31.72
28.29
26.37
25.23
23.69
22.32
21.09
19.97
19.06
18.13
17.37
16.67
16.03
5⁄ 16
0.3125
46.39
41.82
38.19
34.95
31.14
29.01
27.74
26.04
24.51
23.15
21.91
20.90
19.87
19.02
18.25
17.53
11⁄ 32
0.34375
50.75
45.73
41.74
38.17
33.99
31.65
30.25
28.38
26.71
25.21
23.85
22.73
21.60
20.68
19.83
19.04
0.375
55.11
49.64
45.29
41.40
36.84
34.28
32.76
30.72
28.90
27.26
25.78
24.57
23.34
22.33
21.40
20.55
13⁄ 32
0.40625
59.47
53.54
48.85
44.63
39.69
36.92
35.26
33.06
31.09
29.32
27.72
26.41
25.08
23.99
22.98
22.06
7⁄ 16
0.4375
63.83
57.45
52.38
47.85
42.54
39.56
37.77
35.40
33.28
31.38
29.66
28.25
26.81
25.64
24.56
23.56
15⁄ 32
0.46875
68.19
61.36
55.93
51.00
45.39
42.20
40.28
37.74
35.47
33.44
31.59
30.08
28.55
27.29
26.14
25.07
0.500
72.55
65.27
59.48
54.30
48.24
44.84
42.79
40.08
37.67
35.49
33.53
31.92
30.29
28.95
27.71
26.58
3⁄ 8
1⁄ 2
AMW Wire Gauge Decimal Equivalenta
24 .055
25 .059
26 .063
27 .067
28 .071
29 .075
30 .080
31 .085
32 .090
33 .095
34 .100
35 .106
36 .112
37 .118
1⁄ 8 125
Design Stress, kpsi
180
178
176
174
173
171
169
167
166
164
163
161
160
158
156
Torque, pound-inch
2.941
3.590
4.322
5.139
6.080
7.084
8.497
10.07
11.88
13.81
16.00
18.83
22.07
25.49
29.92
Inside Diameter, inch
Deflection, degrees per coil
9⁄ 32
0.28125
14.88
13.88
13.00
12.44
11.81
11.17
10.50
9.897
9.418
8.934
8.547
8.090
7.727
7.353
6.973
5⁄ 16
0.3125
16.26
15.15
14.18
13.56
12.85
12.15
11.40
10.74
10.21
9.676
9.248
8.743
8.341
7.929
7.510
11⁄ 32
0.34375
17.64
16.42
15.36
14.67
13.90
13.13
12.31
11.59
11.00
10.42
9.948
9.396
8.955
8.504
8.046
0.375
19.02
17.70
16.54
15.79
14.95
14.11
13.22
12.43
11.80
11.16
10.65
10.05
9.569
9.080
8.583
13⁄ 32
0.40625
20.40
18.97
17.72
16.90
15.99
15.09
14.13
13.28
12.59
11.90
11.35
10.70
10.18
9.655
9.119
7⁄ 16
0.4375
21.79
20.25
18.90
18.02
17.04
16.07
15.04
14.12
13.38
12.64
12.05
11.35
10.80
10.23
9.655
15⁄ 32
0.46875
23.17
21.52
20.08
19.14
18.09
17.05
15.94
14.96
14.17
13.39
12.75
12.01
11.41
10.81
10.19
0.500
24.55
22.80
21.26
20.25
19.14
18.03
16.85
15.81
14.97
14.13
13.45
12.66
12.03
11.38
10.73
3⁄ 8
1⁄ 2
a For sizes up to 13 gauge, the table values are for music wire with a modulus E of 29,000,000 psi; and for sizes from 27 to 31 guage, the values are for oil-tempered MB
with a modulus of 28,500,000 psi.
Copyright 2004, Industrial Press, Inc., New York, NY
SPRING DESIGN
9⁄ 32
Machinery's Handbook 27th Edition
Table 14. (Continued) Torsion Spring Deflections AMW Wire Gauge Decimal Equivalenta
16 .037
17 .039
18 .041
19 .043
20 .045
21 .047
22 .049
23 .051
24 .055
25 .059
26 .063
27 .067
28 .071
29 .075
Design Stress, kpsi
192
190
188
187
185
184
183
182
180
178
176
174
173
171
169
Torque, pound-inch
.9550
1.107
1.272
1.460
1.655
1.876
2.114
2.371
2.941
3.590
4.322
5.139
6.080
7.084
8.497
Inside Diameter, inch
30 .080
Deflection, degrees per coil
0.53125
39.86
37.55
35.47
33.76
32.02
30.60
29.29
28.09
25.93
24.07
22.44
21.37
20.18
19.01
17.76
9⁄ 16
0.5625
42.05
39.61
37.40
35.59
33.76
32.25
30.87
29.59
27.32
25.35
23.62
22.49
21.23
19.99
18.67
19⁄ 32
0.59375
44.24
41.67
39.34
37.43
35.50
33.91
32.45
31.10
28.70
26.62
24.80
23.60
22.28
20.97
19.58
0.625
46.43
43.73
41.28
39.27
37.23
35.56
34.02
32.61
30.08
27.89
25.98
24.72
23.33
21.95
20.48
21⁄ 32
0.65625
48.63
45.78
43.22
41.10
38.97
37.22
35.60
34.12
31.46
29.17
27.16
25.83
24.37
22.93
21.39
11⁄ 16
0.6875
50.82
47.84
45.15
42.94
40.71
38.87
37.18
35.62
32.85
30.44
28.34
26.95
25.42
23.91
22.30
23⁄ 32
0.71875
53.01
49.90
47.09
44.78
42.44
40.52
38.76
37.13
34.23
31.72
29.52
28.07
26.47
24.89
23.21
0.750
55.20
51.96
49.03
46.62
44.18
42.18
40.33
38.64
35.61
32.99
30.70
29.18
27.52
25.87
24.12 5 .207
5⁄ 8
3⁄ 4
Gaugeab
1⁄ 8
5⁄ 32
3⁄ 16
Wire or Size and Decimal Equivalent
31 .085
32 .090
33 .095
34 .100
35 .106
36 .112
37 .118
.125
10 .135
9 .1483
.1563
8 .162
7 .177
.1875
6 .192
Design Stress, kpsi
167
166
164
163
161
160
158
156
161
158
156
154
150
149
146
143
Torque, pound-inch
10.07
11.88
13.81
16.00
18.83
22.07
25.49
29.92
38.90
50.60
58.44
64.30
81.68
96.45
101.5
124.6 7.015
Inside Diameter, inch
Deflection, degrees per coil
17⁄ 32
0.53125
16.65
15.76
14.87
14.15
13.31
12.64
11.96
11.26
10.93
9.958
9.441
9.064
8.256
7.856
7.565
9⁄ 16
0.5625
17.50
16.55
15.61
14.85
13.97
13.25
12.53
11.80
11.44
10.42
9.870
9.473
8.620
8.198
7.891
7.312
19⁄ 32
0.59375
18.34
17.35
16.35
15.55
14.62
13.87
13.11
12.34
11.95
10.87
10.30
9.882
8.984
8.539
8.218
7.609
5⁄ 8
0.625
19.19
18.14
17.10
16.25
15.27
14.48
13.68
12.87
12.47
11.33
10.73
10.29
9.348
8.881
8.545
7.906
21⁄ 32
0.65625
20.03
18.93
17.84
16.95
15.92
15.10
14.26
13.41
12.98
11.79
11.16
10.70
9.713
9.222
8.872
8.202
11⁄ 16
0.6875
20.88
19.72
18.58
17.65
16.58
15.71
14.83
13.95
13.49
12.25
11.59
11.11
10.08
9.564
9.199
8.499
23⁄ 32
0.71875
21.72
20.52
19.32
18.36
17.23
16.32
15.41
14.48
14.00
12.71
12.02
11.52
10.44
9.905
9.526
8.796
0.750
22.56
21.31
20.06
19.06
17.88
16.94
15.99
15.02
14.52
13.16
12.44
11.92
10.81
10.25
9.852
9.093
3⁄ 4
sizes up to 26 gauge, the table values are for music wire with a modulus E of 29,500,000 psi; for sizes from 27 to 1⁄8 inch diameter the table values are for music wire with a modulus of 28,500,000 psi; for sizes from 10 gauge to 1⁄8 inch diameter, the values are for oil-tempered MB with a modulus of 28,500,000 psi. b Gauges 31 through 37 are AMW gauges. Gauges 10 through 5 are Washburn and Moen.
SPRING DESIGN
17⁄ 32
a For
345
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
24 .055
25 .059
26 .063
27 .067
28 .071
29 .075
30 .080
31 .085
32 .090
33 .095
34 .100
35 .106
36 .112
37 .118
1⁄ 8 .125
Design Stress, kpsi
180
178
176
174
173
171
169
167
166
164
163
161
160
158
156
Torque, pound-inch
2.941
3.590
4.322
5.139
6.080
7.084
8.497
10.07
11.88
13.81
16.00
18.83
22.07
25.49
29.92
0.8125
38.38
35.54
33.06
31.42
29.61
27.83
25.93
24.25
22.90
21.55
20.46
19.19
18.17
17.14
16.09
0.875
41.14
38.09
35.42
33.65
31.70
29.79
27.75
25.94
24.58
23.03
21.86
20.49
19.39
18.29
17.17
0.9375
43.91
40.64
37.78
35.88
33.80
31.75
29.56
27.63
26.07
24.52
23.26
21.80
20.62
19.44
18.24
1
1.000
46.67
43.19
40.14
38.11
35.89
33.71
31.38
29.32
27.65
26.00
24.66
23.11
21.85
20.59
19.31
11⁄16
1.0625
49.44
45.74
42.50
40.35
37.99
35.67
33.20
31.01
29.24
27.48
26.06
24.41
23.08
21.74
20.38
11⁄8
1.125
52.20
48.28
44.86
42.58
40.08
37.63
35.01
32.70
30.82
28.97
27.46
25.72
24.31
22.89
21.46
13⁄16
1.1875
54.97
50.83
47.22
44.81
42.18
39.59
36.83
34.39
32.41
30.45
28.86
27.02
25.53
24.04
22.53
11⁄4
1.250
57.73
53.38
49.58
47.04
44.27
41.55
38.64
36.08
33.99
31.94
30.27
28.33
26.76
25.19
23.60 3⁄ 8 .375
Inside Diameter, inch 13⁄ 16 7⁄ 8 15⁄ 16
Deflection, degrees per coil
10 .135
9 .1483
5⁄ 32
.1563
8 .162
7 .177
3⁄ 16
.1875
6 .192
5 .207
7⁄ 32
.2188
4 .2253
3 .2437
1⁄ 4
9⁄ 32
5⁄ 16
11⁄ 32
.250
.2813
.3125
.3438
Design Stress, kpsi
161
158
156
154
150
149
146
143
142
141
140
139
138
137
136
135
Torque, pound-inch
38.90
50.60
58.44
64.30
81.68
96.45
101.5
124.6
146.0
158.3
199.0
213.3
301.5
410.6
542.5
700.0
0.8125
15.54
14.08
13.30
12.74
11.53
10.93
10.51
9.687
9.208
8.933
8.346
8.125
7.382
6.784
6.292
5.880
0.875
16.57
15.00
14.16
13.56
12.26
11.61
11.16
10.28
9.766
9.471
8.840
8.603
7.803
7.161
6.632
6.189
15⁄ 16
0.9375
17.59
15.91
15.02
14.38
12.99
12.30
11.81
10.87
10.32
10.01
9.333
9.081
8.225
7.537
6.972
6.499
1 11⁄16
1.000 1.0625
18.62 19.64
16.83 17.74
15.88 16.74
15.19 16.01
13.72 14.45
12.98 13.66
12.47 13.12
11.47 12.06
10.88 11.44
10.55 11.09
9.827 10.32
9.559 10.04
8.647 9.069
7.914 8.291
7.312 7.652
6.808 7.118
Inside Diameter, inch 13⁄ 16 7⁄ 8
Deflection, degrees per coil
11⁄8
1.125
20.67
18.66
17.59
16.83
15.18
14.35
13.77
12.66
12.00
11.62
10.81
10.52
9.491
8.668
7.993
7.427
13⁄16
1.1875
21.69
19.57
18.45
17.64
15.90
15.03
14.43
13.25
12.56
12.16
11.31
10.99
9.912
9.045
8.333
7.737
11⁄4
1.250
22.72
20.49
19.31
18.46
16.63
15.71
15.08
13.84
13.11
12.70
11.80
11.47
10.33
9.422
8.673
8.046
sizes up to 26 gauge, the table values are for music wire with a modulus E of 29,500,000 psi; for sizes from 27 to 1⁄8 inch diameter the table values are for music wire with a modulus of 28,500,000 psi; for sizes from 10 gauge to 1⁄8 inch diameter, the values are for oil-tempered MB with a modulus of 28,500,000 psi. For an example in the use of the table, see the example starting on page 340. Note: Intermediate values may be interpolated within reasonable accuracy. a For
Copyright 2004, Industrial Press, Inc., New York, NY
SPRING DESIGN
Washburn and Moen Gauge or Size and Decimal Equivalent a
346
Table 14. (Continued) Torsion Spring Deflections AMW Wire Gauge Decimal Equivalenta
Machinery's Handbook 27th Edition SPRING DESIGN
347
Table 15. Correction Factors for Other Materials Materiala
Material a
Factor
Hard Drawn MB Chrome-vanadium
0.75 1.10
Chrome-silicon
1.20
Stainless 302 and 304 Up to 1⁄8 inch diameter
0.85
Over 1⁄8 to 1⁄4 inch diameter
Factor
Stainless 316 Up to 1⁄8 inch diameter
0.75
Over 1⁄8 to 1⁄4 inch diameter
0.65
Over 1⁄4 inch diameter
0.65
Stainless 17–7 PH
0.75
Up to 1⁄8 inch diameter
1.00
0.65
Over 1⁄8 to 3⁄16 inch diameter
1.07
Stainless 431
0.80
Over 3⁄16 inch diameter
Stainless 420
0.85
Over
1⁄ inch 4
diameter
1.12
…
…
a For use with values in Table 14. Note: The figures in Table 14 are for music wire (ASTM A228) and oil-tempered MB grade (ASTM A229) and can be used for several other materials that have a similar modulus of elasticity E. However, the design stress may be too high or too low, and therefore the design stress, torque, and deflection per coil should each be multiplied by the appropriate correction factor when using any of the materials given in this table (Table 15).
Torsion Spring Tolerances.—Torsion springs are coiled in a different manner from other types of coiled springs and therefore different tolerances apply. The commercial tolerance on loads is ± 10 per cent and is specified with reference to the angular deflection. For example: 100 pound-inches ± 10 per cent at 45 degrees deflection. One load specified usually suffices. If two loads and two deflections are specified, the manufacturing and testing times are increased. Tolerances smaller than ± 10 per cent require each spring to be individually tested and adjusted, which adds considerably to manufacturing time and cost. Tables 16, 17, and 18 give, respectively, free angle tolerances, tolerances on the number of coils, and coil diameter tolerances. Table 16. Torsion Spring Tolerances for Angular Relationship of Ends Spring Index
Number of Coils (N) 1 2 3 4 5 6 8 10 15 20 25 30 50
4
6
8
10
12
14
16
18
5.5 9 12 16 20 21 27 31.5 38 47 56 65 90
5.5 9.5 13 16.5 20.5 22.5 28 32.5 40 49 60 68 95
20
Free Angle Tolerance, ± degrees 2 4 5.5 7 8 9.5 12 14 20 25 29 32 45
3 5 7 9 10 12 15 19 25 30 35 38 55
3.5 6 8 10 12 14.5 18 21 28 34 40 44 63
4 7 9.5 12 14 16 20.5 24 31 37 44 50 70
4.5 8 10.5 14 16 19 23 27 34 41 48 55 77
5 8.5 11 15 18 20.5 25 29 36 44 52 60 84
6 10 14 17 21 24 29 34 42 51 63 70 100
Table 17. Torsion Spring Tolerance on Number of Coils Number of Coils
Tolerance
Number of Coils
up to 5
±5°
over 10 to 20
±15°
over 5 to 10
±10°
over 20 to 40
±30°
Copyright 2004, Industrial Press, Inc., New York, NY
Tolerance
Machinery's Handbook 27th Edition 348
SPRING DESIGN Table 18. Torsion Spring Coil Diameter Tolerances Spring Index
Wire Diameter, Inch
4
0.015 0.023 0.035 0.051 0.076 0.114 0.172 0.250
0.002 0.002 0.002 0.002 0.003 0.004 0.006 0.008
6
8
10
12
14
16
0.003 0.005 0.007 0.010 0.015 0.022 0.034 0.050
0.004 0.006 0.009 0.012 0.018 0.028 0.042 0.060
Coil Diameter Tolerance, ± inch 0.002 0.002 0.002 0.003 0.005 0.007 0.010 0.014
0.002 0.002 0.003 0.005 0.007 0.010 0.013 0.022
0.002 0.003 0.004 0.007 0.009 0.013 0.020 0.030
0.003 0.004 0.006 0.008 0.012 0.018 0.027 0.040
Miscellaneous Springs.—This section provides information on various springs, some in common use, some less commonly used. Conical compression: These springs taper from top to bottom and are useful where an increasing (instead of a constant) load rate is needed, where solid height must be small, and where vibration must be damped. Conical springs with a uniform pitch are easiest to coil. Load and deflection formulas for compression springs can be used – using the average mean coil diameter, and providing the deflection does not cause the largest active coil to lie against the bottom coil. When this happens, each coil must be calculated separately, using the standard formulas for compression springs. Constant force springs: Those springs are made from flat spring steel and are finding more applications each year. Complicated design procedures can be eliminated by selecting a standard design from thousands now available from several spring manufacturers. Spiral, clock, and motor springs: Although often used in wind-up type motors for toys and other products, these springs are difficult to design and results cannot be calculated with precise accuracy. However, many useful designs have been developed and are available from spring manufacturing companies. Flat springs: These springs are often used to overcome operating space limitations in various products such as electric switches and relays. Table 19 lists formulas for designing flat springs. The formulas are based on standard beam formulas where the deflection is small. Table 19. Formulas for Flat Springs
Feature
Deflect., f Inches
Load, P Pounds
PL 3 f = -------------4Ebt 3 Sb L2 = ----------6Et 2S b bt 2 P = ---------------3L 3F = 4Ebt -----------------L3
3 f = 4PL ------------Ebt 3
2S b L 2 = -------------3Et S b bt 2 P = -----------6L 3F = Ebt --------------4L 3
3 f = 6PL ------------Ebt 3
Sb L2 = ----------Et S b bt 2 P = -----------6L 3F = Ebt --------------6L 3
3 f = 5.22PL -------------------Ebt 3
0.87S b L 2 = ---------------------Et S b bt 2 P = -----------6L Ebt 3 F = ---------------5.22L 3
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPRING DESIGN
349
Table 19. (Continued) Formulas for Flat Springs
Feature
Stress, Sb Bending psi
Thickness, t Inches
3PL S b = ----------2bt 2
6PL S b = ---------bt 2
= 6EtF ------------L2 Sb L2 t = ----------6EF =
3
PL 3 -------------4EbF
6PL S b = ---------bt 2
= 3EtF ------------2L 2 2S b L 2 t = -------------3EF =
3
4PL 3 ------------EbF
6PL S b = ---------bt 2
= EtF --------L2 Sb L2 t = ----------EF =
3
6PL 3 ------------EbF
EtF = ---------------0.87L 2 0.87S b L 2 t = ---------------------EF =
3
5.22PL 3 -------------------EbF
Based on standard beam formulas where the deflection is small. See page 308 for notation. Note: Where two formulas are given for one feature, the designer should use the one found to be appropriate for the given design. The result from either of any two formulas is the same.
Belleville washers or disc springs: These washer type springs can sustain relatively large loads with small deflections, and the loads and deflections can be increased by stacking the springs. Information on springs of this type is given in the section DISC SPRINGS starting on page 354. Volute springs: These springs are often used on army tanks and heavy field artillery, and seldom find additional uses because of their high cost, long production time, difficulties in manufacture, and unavailability of a wide range of materials and sizes. Small volute springs are often replaced with standard compression springs. Torsion bars: Although the more simple types are often used on motor cars, the more complicated types with specially forged ends are finding fewer applications as time goes. Moduli of Elasticity of Spring Materials.—The modulus of elasticity in tension, denoted by the letter E, and the modulus of elasticity in torsion, denoted by the letter G, are used in formulas relating to spring design. Values of these moduli for various ferrous and nonferrous spring materials are given in Table 20. General Heat Treating Information for Springs.—The following is general information on the heat treatment of springs, and is applicable to pre-tempered or hard-drawn spring materials only. Compression springs are baked after coiling (before setting) to relieve residual stresses and thus permit larger deflections before taking a permanent set. Extension springs also are baked, but heat removes some of the initial tension. Allowance should be made for this loss. Baking at 500 degrees F for 30 minutes removes approximately 50 per cent of the initial tension. The shrinkage in diameter however, will slightly increase the load and rate. Outside diameters shrink when springs of music wire, pretempered MB, and other carbon or alloy steels are baked. Baking also slightly increases the free length and these changes produce a little stronger load and increase the rate. Outside diameters expand when springs of stainless steel (18-8) are baked. The free length is also reduced slightly and these changes result in a little lighter load and a decrease the spring rate. Inconel, Monel, and nickel alloys do not change much when baked.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 350
SPRING DESIGN
Beryllium-copper shrinks and deforms when heated. Such springs usually are baked in fixtures or supported on arbors or rods during heating. Brass and phosphor bronze springs should be given a light heat only. Baking above 450 degrees F will soften the material. Do not heat in salt pots. Torsion springs do not require baking because coiling causes residual stresses in a direction that is helpful, but such springs frequently are baked so that jarring or handling will not cause them to lose the position of their ends. Table 20. Moduli of Elasticity in Torsion and Tension of Spring Materials Ferrous Materials Material (Commercial Name) Hard Drawn MB Up to 0.032 inch 0.033 to 0.063 inch 0.064 to 0.125 inch 0.126 to 0.625 inch Music Wire Up to 0.032 inch 0.033 to 0.063 inch 0.064 to 0.125 inch 0.126 to 0.250 inch Oil-Tempered MB Chrome-Vanadium Chrome-Silicon Silicon-Manganese Stainless Steel Types 302, 304, 316 Type 17–7 PH Type 420 Type 431
Nonferrous Materials
Modulus of Elasticity a, psi In Torsion, G
In Tension, E
11,700,000 11,600,000 11,500,000 11,400,000
28,800,000 28,700,000 28,600,000 28,500,000
12,000,000 11,850,000 11,750,000 11,600,000 11,200,000 11,200,000 11,200,000 10,750,000
29,500,000 29,000,000 28,500,000 28,000,000 28,500,000 28,500,000 29,500,000 29,000,000
10,000,000 10,500,000 11,000,000 11,400,000
28,000,000c 29,500,000 29,000,000 29,500,000
Material (Commercial Name) Spring Brass Type 70–30 Phosphor Bronze 5 per cent tin Beryllium-Copper Cold Drawn 4 Nos. Pretempered, fully hard Inconelb 600 Inconelb X 750 Monelb 400 Monelb K 500 Duranickelb 300 Permanickelb Ni Spanb C 902 Elgiloyd Iso-Elastice
Modulus of Elasticity a, psi In Torsion, G
In Tension, E
5,000,000
15,000,000
6,000,000
15,000,000
7,000,000 7,250,000 10,500,000 10,500,000 9,500,000 9,500,000 11,000,000 11,000,000 10,000,000 12,000,000 9,200,000
17,000,000 19,000,000 31,000,000c 31,000,000c 26,000,000 26,000,000 30,000,000 30,000,000 27,500,000 29,500,000 26,000,000
a Note: Modulus G (shear modulus) is used for compression and extension springs; modulus E (Young's modulus) is used for torsion, flat, and spiral springs. b Trade name of International Nickel Company. c May be 2,000,000 pounds per square inch less if material is not fully hard. d Trade name of Hamilton Watch Company. e Trade name of John Chatillon & Sons.
Spring brass and phosphor bronze springs that are not very highly stressed and are not subject to severe operating use may be stress relieved after coiling by immersing them in boiling water for a period of 1 hour. Positions of loops will change with heat. Parallel hooks may change as much as 45 degrees during baking. Torsion spring arms will alter position considerably. These changes should be allowed for during looping or forming. Quick heating after coiling either in a high-temperature salt pot or by passing a spring through a gas flame is not good practice. Samples heated in this way will not conform with production runs that are properly baked. A small, controlled-temperature oven should be used for samples and for small lot orders. Plated springs should always be baked before plating to relieve coiling stresses and again after plating to relieve hydrogen embrittlement. Hardness values fall with high heat—but music wire, hard drawn, and stainless steel will increase 2 to 4 points Rockwell C.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPRING DESIGN
351
Table 21. Squares, Cubes, and Fourth Powers of Wire Diameters Steel Wire Gage (U.S.)
Music or Piano Wire Gage
7-0 6-0 5-0 4-0 3-0 2-0 1-0 1 2 3 4 5 6 … 7 … 8 … 9 … … 10 … … 11 … … … 12 … … 13 … … 14 … 15 … … … 16 … … 17 … … 18 … … … 19 … … … 20 … 21 … … 22 … 23 … 24 …
… … … … … … … … … … … … … 45 … 44 43 42 … 41 40 … 39 38 … 37 36 35 … 34 33 … 32 31 30 29 … 28 27 26 … 25 24 … 23 22 … 21 20 19 18 17 16 15 … 14 … 13 12 … 11 … 10 … 9
Diameter Inch 0.4900 0.4615 0.4305 0.3938 0.3625 0.331 0.3065 0.283 0.2625 0.2437 0.2253 0.207 0.192 0.180 0.177 0.170 0.162 0.154 0.1483 0.146 0.138 0.135 0.130 0.124 0.1205 0.118 0.112 0.106 0.1055 0.100 0.095 0.0915 0.090 0.085 0.080 0.075 0.072 0.071 0.067 0.063 0.0625 0.059 0.055 0.054 0.051 0.049 0.0475 0.047 0.045 0.043 0.041 0.039 0.037 0.035 0.0348 0.033 0.0317 0.031 0.029 0.0286 0.026 0.0258 0.024 0.023 0.022
Section Area
Square
Cube
0.1886 0.1673 0.1456 0.1218 0.1032 0.0860 0.0738 0.0629 0.0541 0.0466 0.0399 0.0337 0.0290 0.0254 0.0246 0.0227 0.0206 0.0186 0.0173 0.0167 0.0150 0.0143 0.0133 0.0121 0.0114 0.0109 0.0099 0.0088 0.0087 0.0078 0.0071 0.0066 0.0064 0.0057 0.0050 0.0044 0.0041 0.0040 0.0035 0.0031 0.0031 0.0027 0.0024 0.0023 0.0020 0.00189 0.00177 0.00173 0.00159 0.00145 0.00132 0.00119 0.00108 0.00096 0.00095 0.00086 0.00079 0.00075 0.00066 0.00064 0.00053 0.00052 0.00045 0.00042 0.00038
0.24010 0.21298 0.18533 0.15508 0.13141 0.10956 0.09394 0.08009 0.06891 0.05939 0.05076 0.04285 0.03686 0.03240 0.03133 0.02890 0.02624 0.02372 0.02199 0.02132 0.01904 0.01822 0.01690 0.01538 0.01452 0.01392 0.01254 0.01124 0.01113 0.0100 0.00902 0.00837 0.00810 0.00722 0.0064 0.00562 0.00518 0.00504 0.00449 0.00397 0.00391 0.00348 0.00302 0.00292 0.00260 0.00240 0.00226 0.00221 0.00202 0.00185 0.00168 0.00152 0.00137 0.00122 0.00121 0.00109 0.00100 0.00096 0.00084 0.00082 0.00068 0.00067 0.00058 0.00053 0.00048
0.11765 0.09829 0.07978 0.06107 0.04763 0.03626 0.02879 0.02267 0.01809 0.01447 0.01144 0.00887 0.00708 0.00583 0.00555 0.00491 0.00425 0.00365 0.00326 0.00311 0.00263 0.00246 0.00220 0.00191 0.00175 0.00164 0.00140 0.00119 0.001174 0.001000 0.000857 0.000766 0.000729 0.000614 0.000512 0.000422 0.000373 0.000358 0.000301 0.000250 0.000244 0.000205 0.000166 0.000157 0.000133 0.000118 0.000107 0.000104 0.000091 0.0000795 0.0000689 0.0000593 0.0000507 0.0000429 0.0000421 0.0000359 0.0000319 0.0000298 0.0000244 0.0000234 0.0000176 0.0000172 0.0000138 0.0000122 0.0000106
Copyright 2004, Industrial Press, Inc., New York, NY
Fourth Power 0.05765 0.04536 0.03435 0.02405 0.01727 0.01200 0.008825 0.006414 0.004748 0.003527 0.002577 0.001836 0.001359 0.001050 0.000982 0.000835 0.000689 0.000563 0.000484 0.000455 0.000363 0.000332 0.000286 0.000237 0.000211 0.000194 0.000157 0.000126 0.0001239 0.0001000 0.0000815 0.0000701 0.0000656 0.0000522 0.0000410 0.0000316 0.0000269 0.0000254 0.0000202 0.0000158 0.0000153 0.0000121 0.00000915 0.00000850 0.00000677 0.00000576 0.00000509 0.00000488 0.00000410 0.00000342 0.00000283 0.00000231 0.00000187 0.00000150 0.00000147 0.00000119 0.00000101 0.000000924 0.000000707 0.000000669 0.000000457 0.000000443 0.000000332 0.000000280 0.000000234
Machinery's Handbook 27th Edition 352
SPRING DESIGN
Spring Failure.—Spring failure may be breakage, high permanent set, or loss of load. The causes are listed in groups in Table 22. Group 1 covers causes that occur most frequently; Group 2 covers causes that are less frequent; and Group 3 lists causes that occur occasionally. Table 22. Causes of Spring Failure
Group 1
Group 2
Cause
Comments and Recommendations
High stress
The majority of spring failures are due to high stresses caused by large deflections and high loads. High stresses should be used only for statically loaded springs. Low stresses lengthen fatigue life.
Improper electroplating methods and acid cleaning of springs, without Hydrogen proper baking treatment, cause spring steels to become brittle, and are a embrittlement frequent cause of failure. Nonferrous springs are immune. Sharp bends and holes
Sharp bends on extension, torsion, and flat springs, and holes or notches in flat springs, cause high concentrations of stress, resulting in failure. Bend radii should be as large as possible, and tool marks avoided.
Fatigue
Repeated deflections of springs, especially above 1,000,000 cycles, even with medium stresses, may cause failure. Low stresses should be used if a spring is to be subjected to a very high number of operating cycles.
Shock loading
Impact, shock, and rapid loading cause far higher stresses than those computed by the regular spring formulas. High-carbon spring steels do not withstand shock loading as well as do alloy steels.
Corrosion
Slight rusting or pitting caused by acids, alkalis, galvanic corrosion, stress corrosion cracking, or corrosive atmosphere weakens the material and causes higher stresses in the corroded area.
Faulty heat treatment
Keeping spring materials at the hardening temperature for longer periods than necessary causes an undesirable growth in grain structure, resulting in brittleness, even though the hardness may be correct.
Faulty material
Poor material containing inclusions, seams, slivers, and flat material with rough, slit, or torn edges is a cause of early failure. Overdrawn wire, improper hardness, and poor grain structure also cause early failure.
High temperature
High operating temperatures reduce spring temper (or hardness) and lower the modulus of elasticity, thereby causing lower loads, reducing the elastic limit, and increasing corrosion. Corrosion-resisting or nickel alloys should be used.
Low temperature Group 3
Temperatures below −40 degrees F reduce the ability of carbon steels to withstand shock loads. Carbon steels become brittle at −70 degrees F. Corrosion-resisting, nickel, or nonferrous alloys should be used.
Friction
Close fits on rods or in holes result in a wearing away of material and occasional failure. The outside diameters of compression springs expand during deflection but they become smaller on torsion springs.
Other causes
Enlarged hooks on extension springs increase the stress at the bends. Carrying too much electrical current will cause failure. Welding and soldering frequently destroy the spring temper. Tool marks, nicks, and cuts often raise stresses. Deflecting torsion springs outwardly causes high stresses and winding them tightly causes binding on supporting rods. High speed of deflection, vibration, and surging due to operation near natural periods of vibration or their harmonics cause increased stresses.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPRING DESIGN
353
Table 23. Arbor Diameters for Springs Made from Music Wire Spring Outside Diameter (inch)
Wire Dia. (inch)
1⁄ 16
0.008
0.039
0.060
0.078
0.093
0.107
0.119
0.129
0.010
0.037
0.060
0.080
0.099
0.115
0.129
0.142
0.012
0.034
0.059
0.081
0.101
0.119
0.135
0.150
0.014
0.031
0.057
0.081
0.102
0.121
0.140
0.016
0.028
0.055
0.079
0.102
0.123
0.018
…
0.053
0.077
0.101
0.124
0.020
…
0.049
0.075
0.096
0.022
…
0.046
0.072
0.097
0.024
…
0.043
0.070
0.026
…
…
0.028
…
0.030
…
0.032
3⁄ 32
1⁄ 8
5⁄ 32
3⁄ 16
7⁄ 32
1⁄ 4
9⁄ 32
5⁄ 16
11⁄ 32
3⁄ 8
7⁄ 16
1⁄ 2
…
…
…
…
…
…
0.154
0.164
…
…
…
…
0.163
0.177
0.189
0.200
…
…
0.156
0.172
0.187
0.200
0.213
0.234
…
0.142
0.161
0.178
0.194
0.209
0.224
0.250
0.271
0.144
0.161
0.182
0.200
0.215
0.231
0.259
0.284
0.123
0.144
0.165
0.184
0.203
0.220
0.237
0.268
0.296
0.122
0.145
0.165
0.186
0.206
0.224
0.242
0.275
0.305
0.095
0.120
0.144
0.166
0.187
0.207
0.226
0.245
0.280
0.312
0.067
0.093
0.118
0.143
0.166
0.187
0.208
0.228
0.248
0.285
0.318
…
0.064
0.091
0.115
0.141
0.165
0.187
0.208
0.229
0.250
0.288
0.323
…
0.061
0.088
0.113
0.138
0.163
0.187
0.209
0.229
0.251
0.291
0.328
…
…
0.057
0.085
0.111
0.136
0.161
0.185
0.209
0.229
0.251
0.292
0.331
0.034
…
…
…
0.082
0.109
0.134
0.159
0.184
0.208
0.229
0.251
0.292
0.333
0.036
…
…
…
0.078
0.106
0.131
0.156
0.182
0.206
0.229
0.250
0.294
0.333
0.038
…
…
…
0.075
0.103
0.129
0.154
0.179
0.205
0.227
0.251
0.293
0.335
0.041
…
…
…
…
0.098
0.125
0.151
0.176
0.201
0.226
0.250
0.294
0.336
0.0475
…
…
…
…
0.087
0.115
0.142
0.168
0.194
0.220
0.244
0.293
0.337
0.054
…
…
…
…
…
0.103
0.132
0.160
0.187
0.212
0.245
0.287
0.336
0.0625
…
…
…
…
…
…
0.108
0.146
0.169
0.201
0.228
0.280
0.330
0.072
…
…
…
…
…
…
…
0.129
0.158
0.186
0.214
0.268
0.319
0.080
…
…
…
…
…
…
…
…
0.144
0.173
0.201
0.256
0.308
0.0915
…
…
…
…
…
…
…
…
…
…
0.181
0.238
0.293
0.1055
…
…
…
…
…
…
…
…
…
…
…
0.215
0.271
0.1205
…
…
…
…
…
…
…
…
…
…
…
…
0.215
0.125
…
…
…
…
…
…
…
…
…
…
…
…
0.239
Arbor Diameter (inch)
Spring Outside Diameter (inches)
Wire Dia. (inch)
9⁄ 16
0.022
0.332
0.357
0.380
…
…
…
…
…
…
…
…
…
…
…
0.024
0.341
0.367
0.393
0.415
…
…
…
…
…
…
…
…
…
… …
5⁄ 8
11⁄ 16
3⁄ 4
13⁄ 16
7⁄ 8
15⁄ 16
1
11⁄8
11⁄4
13⁄8
11⁄2
13⁄4
2
Arbor Diameter (inches)
0.026
0.350
0.380
0.406
0.430
…
…
…
…
…
…
…
…
…
0.028
0.356
0.387
0.416
0.442
0.467
…
…
…
…
…
…
…
…
…
0.030
0.362
0.395
0.426
0.453
0.481
0.506
…
…
…
…
…
…
…
…
0.032
0.367
0.400
0.432
0.462
0.490
0.516
0.540
…
…
…
…
…
…
…
0.034
0.370
0.404
0.437
0.469
0.498
0.526
0.552
0.557
…
…
…
…
…
…
0.036
0.372
0.407
0.442
0.474
0.506
0.536
0.562
0.589
…
…
…
…
…
…
0.038
0.375
0.412
0.448
0.481
0.512
0.543
0.572
0.600
0.650
…
…
…
…
… …
0.041
0.378
0.416
0.456
0.489
0.522
0.554
0.586
0.615
0.670
0.718
…
…
…
0.0475
0.380
0.422
0.464
0.504
0.541
0.576
0.610
0.643
0.706
0.763
0.812
…
…
…
0.054
0.381
0.425
0.467
0.509
0.550
0.589
0.625
0.661
0.727
0.792
0.850
0.906
…
…
0.0625
0.379
0.426
0.468
0.512
0.556
0.597
0.639
0.678
0.753
0.822
0.889
0.951
1.06
1.17
0.072
0.370
0.418
0.466
0.512
0.555
0.599
0.641
0.682
0.765
0.840
0.911
0.980
1.11
1.22
0.080
0.360
0.411
0.461
0.509
0.554
0.599
0.641
0.685
0.772
0.851
0.930
1.00
1.13
1.26
0.0915
0.347
0.398
0.448
0.500
0.547
0.597
0.640
0.685
0.776
0.860
0.942
1.02
1.16
1.30
0.1055
0.327
0.381
0.433
0.485
0.535
0.586
0.630
0.683
0.775
0.865
0.952
1.04
1.20
1.35
0.1205
0.303
0.358
0.414
0.468
0.520
0.571
0.622
0.673
0.772
0.864
0.955
1.04
1.22
1.38
0.125
0.295
0.351
0.406
0.461
0.515
0.567
0.617
0.671
0.770
0.864
0.955
1.05
1.23
1.39
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 354
DISC SPRINGS
DISC SPRINGS Performance of Disc Springs Introduction.—Disc springs, also known as Belleville springs, are conically formed from washers and have rectangular cross section. The disc spring concept was invented by a Frenchman Louis Belleville in 1865. His springs were relatively thick and had a small amount of cone height or “dish”, which determined axial deflection. At that time, these springs were used in the buffer parts of railway rolling stock, for recoil mechanisms of guns, and some other applications. The use of disc springs will be advantageous when space is limited and high force is required, as these conditions cannot be satisfied by using coil springs. Load-deflection characteristics of disc springs are linear and regressive depending on their dimensions and the type of stacking. A large number of standard sizes are available from disc spring manufacturers and distributors, so that custom sizes may not be required. Therefore, disc springs are widely used today in virtually all branches of engineering with possibilities of new applications. Disc Spring Nomenclature.—Disc spring manufacturers assign their own part number for each disc spring, but the catalog numbers for disc springs are similar, so each item can often be identified regardless of the manufacturer. The disc spring identification number is a numerical code that provides basic dimensions in millimeters. Identification numbers representing the primary dimensions of the disc spring and consist of one, two, or three numbers separated from each other by dash marks or spaces. Disc spring manufacturers in the United States also provide dimensions in inches. Dimensions of several typical disc springs are shown in the following table. Basic nomenclature is illustrated in Fig. 1. Catalog Number (mm)
Outside Diameter D (mm)
Inside Diameter d (mm)
Thickness t (mm)
Equivalent Catalog Number (inch)
8–4.2–0.4 50–25.4–2 200–102–12
8 50 200
4.2 25.4 102
0.4 2 12
0.315–0.165– 0.0157 1.97–1.00–0.0787 7.87–4.02–0.472
Additional dimensions shown in catalogs are cone (dish) height h at unloaded condition, and overall height H = h + t, that combines the cone height and the thickness of a disc spring. d
H t
h D Fig. 1. Disc Spring Nomenclature
Disc Spring Group Classification.—Forces and stresses generated by compression depend on disc spring thickness much more than on any other dimensions. Standard DIN 2093 divides all disc springs into three groups in accordance with their thickness: Group 1 includes all disc springs with thickness less than 1.25 mm (0.0492 inch). Group 2 includes all disc springs with thickness between 1.25 mm and 6.0 mm (0.0492 inch and 0.2362 inch). Group 3 includes disc springs with thickness greater than 6.0 mm (0.2362 inch). There are 87 standard disc spring items, which are manufactured in accordance with Standard DIN 2093 specifications for dimensions and quality requirements. There are 30 standard disc spring items in Group 1. The smallest and the largest disc springs in this
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Machinery's Handbook 27th Edition DISC SPRING MATERIALS
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group are 8–4.2–0.2 and 40–20.4–1 respectively. Group 2 has 45 standard disc spring items. The smallest and the largest disc springs are 22.5–11.2–1.25 and 200–102–5.5 respectfully. Group 3 includes 12 standard disc spring items. The smallest and the largest disc springs of this group are 125–64–8 and 250–127–14 respectively. Summary of Disc Spring Sizes Specified in DIN 2093 OD Classification Group 1 Group 2 Group 3
ID
Thickness
Min.
Max
Min.
Max
Min.
Max
6 mm (0.236 in) 20 mm (0.787 in) 125 mm (4.921 in)
40 mm (1.575 in) 225 mm (8.858 in) 250 mm (9.843 in)
3.2 mm (0.126 in) 10.2 mm (0.402 in) 61 mm (2.402 in)
20.4 mm (0.803 in) 112 mm (4.409 in) 127 mm (5.000 in)
0.2 mm (0.008 in) 1.25 mm (0.049 in) 6.5 mm (0.256 in)
1.2 mm (0.047 in) 6 mm (0.236 in) 16 mm (0.630 in)
The number of catalog items by disc spring dimensions depends on the manufacturer. Currently, the smallest disc spring is 6–3.2–0.3 and the largest is 250–127–16. One of the U.S. disc spring manufacturers, Key Bellevilles, Inc. offers 190 catalog items. The greatest number of disc spring items can be found in Christian Bauer GmbH + Co. catalog. There are 291 disc spring catalog items in all three groups. Disc Spring Contact Surfaces.—Disc springs are manufactured with and without contact (also called load-bearing) surfaces. Contact surfaces are small flats at points 1 and 3 in Fig. 2, adjacent to the corner radii of the spring. The width of the contact surfaces w depends on the outside diameter D of the spring, and its value is approximately w = D⁄150. F
w
d
1
H t' 3
w F
D Fig. 2. Disc Spring with Contact Surfaces
Disc springs of Group 1 and Group 2, that are contained in the DIN 2093 Standard, do not have contact surfaces, although some Group 2 disc springs not included in DIN 2093 are manufactured with contact surfaces. All disc springs of Group 3 (standard and nonstandard) are manufactured with contact surfaces. Almost all disc springs with contact surfaces are manufactured with reduced thickness. Disc springs without contact surfaces have a corner radii r whose value depends on the spring thickness, t. One disc spring manufacturers recommends the following relationship: r=t ⁄ 6 Disc Spring Materials .—A wide variety of materials are available for disc springs, but selection of the material depends mainly on application. High-carbon steels are used only for Group 1 disc springs. AISI 1070 and AISI 1095 carbon steels are used in the U.S. Similar high-carbon steels such as DIN 1.1231 and DIN 1.1238 (Germany), and BS 060 A67 and BS 060 A78 (Great Britain) are used in other countries. The most common materials for Groups 2 and 3 springs operating under normal conditions are chromium-vanadium alloy steels such as AISI 6150 used in the U.S. Similar alloys such as DIN 1.8159 and DIN
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Machinery's Handbook 27th Edition 356
DISC SPRING STACKING
1.7701 (Germany) and BS 735 A50 (Great Britain) are used in foreign countries. Some disc spring manufacturers in the U.S. also use chromium alloy steel AISI 5160. The hardness of disc springs in Groups 2 and 3 should be 42 to 52 HRC. The hardness of disc springs in Group 1 tested by the Vickers method should be 412 to 544 HV. If disc springs must withstand corrosion and high temperatures, stainless steels and heatresistant alloys are used. Most commonly used stainless steels in the United States are AISI types 301, 316, and 631, which are similar to foreign material numbers DIN 1.4310, DIN 1.4401, and DIN 1.4568, respectively. The operating temperature range for 631 stainless steel is −330 to 660ºF (−200 to 350ºC). Among heat-resistant alloys, Inconel 718 and Inconel X750 (similar to DIN 2.4668 and DIN 2.4669, respectively) are the most popular. Operating temperature range for Inconel 718 is −440 to 1290ºF (−260 to 700ºC). When disc springs are stacked in large numbers and their total weight becomes a major concern, titanium α-β alloys can be used to reduce weight. In such cases, Ti-6Al-4V alloy is used. If nonmagnetic and corrosion resistant properties are required and material strength is not an issue, phosphor bronzes and beryllium-coppers are the most popular copper alloys for disc springs. Phosphor bronze C52100, which is similar to DIN material number 2.1030, is used at the ordinary temperature range. Beryllium-coppers C17000 and C17200, similar to material numbers DIN 2.1245 and DIN 2.1247 respectively, works well at very low temperatures. Strength properties of disc spring materials are characterized by moduli of elasticity and Poisson’s ratios. These are summarized in Table 1. Table 1. Strength Characteristics of Disc Spring Materials Modulus of Elasticity Material All Steels Heat-resistant Alloys α-β Titanium Alloys (Ti-6Al-4V) Phosphor Bronze (C52100) Beryllium-copper (C17000) Beryllium-copper (C17200)
106 psi
N⁄mm2
28–31
193,000–213,700
17 16 17 18
117,200 110,300 117,200 124,100
Poisson’s Ratio 0.30 0.28–0.29 0.32 0.35 0.30 0.30
Stacking of Disc Springs.—Individual disc springs can be arranged in series and parallel stacks. Disc springs in series stacking, Fig. 3, provide larger deflection Stotal under the same load F as a single disc spring would generate. Disc springs in parallel stacking, Fig. 4, generate higher loads Ftotal with the same deflection s, that a single disc spring would have. n =number of disc springs in stack s =deflection of single spring Stotal = total deflection of stack of n springs F =load generated by a single spring Ftotal = total load generated by springs in stack L0 =length of unloaded spring stack Series: For n disc springs arranged in series as in Fig. 3, the following equations are applied: F total = F S total = s × n L0 = H × n = ( t ÷ h ) × n
Copyright 2004, Industrial Press, Inc., New York, NY
(1)
Machinery's Handbook 27th Edition DISC SPRING STACKING
357
F
L0
L1,2
t
H
h F
d D
Fig. 3. Disc Springs in Series Stacking L1, 2 indices indicate length of spring stack under minimum and maximum load
Parallel: Parallel stacking generates a force that is directly proportional to number of springs arranged in parallel. Two springs in parallel will double the force, three springs in parallel will triple the force, and so on. However, it is a common practice to use two springs in parallel in order to keep the frictional forces between the springs as low as possible. Otherwise, the actual spring force cannot be accurately determined due to deviation from its theoretical value. For n disc springs arranged in parallel as in Fig. 4, the following equations are applied: F total = F × n S total = s L 0 = H + t ( n – 1 ) = ( h + t ) + tn – t = h + tn
(2)
d
L0
t h
D
H
Fig. 4. Disc Springs in Parallel Stacking
Parallel-Series: When both higher force and greater deflection are required, disc springs must be arranged in a combined parallel-series stacking as illustrated in Fig. 5. F
L0
L 1,2 H t
h d D
F
Fig. 5. Disc Springs in Parallel-Series Stacking
Normally, two springs in parallel are nested in series stacking. Two springs in parallel, called a pair, double the force, and the number of pairs, np, determines the total deflection, Stotal.
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Machinery's Handbook 27th Edition 358
DISC SPRING FORCES AND STRESSES
For np disc spring pairs arranged in series, the following equations are applied: F total = 2 × F S total = s × n p L 0 = H × n p = ( 2t + h ) × n p
(3)
Disc Spring Forces and Stresses Several methods of calculating forces and stresses for given disc spring configurations exist, some very complicated, others of limited accuracy. The theory which is widely used today for force and stress calculations was developed more than 65 years ago by Almen and Laszlo. The theory is based on the following assumptions: cross sections are rectangular without radii, over the entire range of spring deflection; no stresses occur in the radial direction; disc springs are always under elastic deformation during deflection; and d u e t o s m a l l cone angles of unloaded disc springs (between 3.5° and 8.6°), mathematical simplifications are applied. The theory provides accurate results for disc springs with the following ratios: outsideto-inside diameter, D ⁄ d = 1.3 to 2.5; and cone height-to-thickness, h ⁄ t is up to 1.5. Force Generated by Disc Springs Without Contact Surfaces.—Disc springs in Group 1 and most of disc springs in Group 2 are manufactured without contact (load-bearing) surfaces, but have corner radii. A single disc spring force applied to points 1 and 3 in Fig. 6 can be found from Equation (4) in which corner radii are not considered: 3 4⋅E⋅s s F = ------------------------------------------ ⎛⎝ h – ---⎞⎠ ⋅ ( h – s ) ⋅ t + t 2 2 2 ( 1 – µ ) ⋅ K1 ⋅ D
(4)
where F = disc spring force; E = modulus of elasticity of spring material; µ = Poisson’s ratio of spring material; K1 = constant depending on outside-to-inside diameter ratio; D = disc spring nominal outside diameter; h = cone (dish) height; s = disc spring deflection; and, t = disc spring thickness. D F 1
H
2
t
3
F
h d Fig. 6. Schematic of Applied Forces
It has been found that the theoretical forces calculated using Equation (4) are lower than the actual (measured) spring forces, as illustrated in Fig. 7. The difference between theoretical (trace 1) and measured force values (trace 3) was significantly reduced (trace 2) when the actual outside diameter of the spring in loaded condition was used in the calculations.
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Machinery's Handbook 27th Edition DISC SPRING FORCES AND STRESSES
359
LIVE GRAPH Click here to view
6000
3
2
5500
1
5000 4500
Force (pounds)
4000 3500 3000 2500 2000 1500 1000 500 0 0
0.01
0.03
0.02
0.04
0.05
0.06
0.07
0.08
0.09
0.10
Deflection (inch)
Fig. 7. Force–Deflection Relationships (80–36–3.6 Disc Springs) 1 – Theoretical Force Calculated by Equation (4) 2 – Theoretical Force Calculated by Equation (10) 3 – Measured Force
The actual outside diameter Da of a disc spring contact circle is smaller than the nominal outside diameter D due to cone angle α and corner radius r, as shown in Fig. 8. Diameter Da cannot be measured, but can be calculated by Equation (9) developed by the author. D/2 d/2
t r r h Da / 2 D/2
t
r
r
a b Da / 2 Fig. 8. Conventional Shape of Disc Spring
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Machinery's Handbook 27th Edition 360
DISC SPRING FORCES AND STRESSES
From Fig. 8, Da D (5) ------ = ---- – ( a + b ) 2 2 where a = t × sinα and b = r × cosα. Substitution of a and b values into Equation (5) gives: Da (6) ------ = D ---- – ( t sin α + r cos α ) 2 2 The cone angle α is found from: h = -----------2h tan α = ------------D d D –d ---- – --2 2
2h -⎞ α = atan ⎛ -----------⎝ D – d⎠
(7)
Substituting α from Equation (7) and r = t ⁄ 6 into Equation (6) gives: D ⎧ 2h -⎞ + 1--- cos atan ⎛ -----------2h -⎞ ⎫ ------a = D ---- – t ⎨ sin atan ⎛ -----------⎝ D – d⎠ ⎬ ⎝ D – d⎠ 2 2 ⎩ 6 ⎭
(8)
⎧ 2h -⎞ + 1--- cos atan ⎛ -----------2h -⎞ ⎫ D a = D – 2t ⎨ sin atan ⎛ -----------⎝ D – d⎠ ⎝ D – d⎠ ⎬ 6 ⎩ ⎭
(9)
Finally,
Substituting Da from Equation (9) for D in Equation (4) yields Equation (10), that provides better accuracy for calculating disc spring forces. 4⋅E⋅s s F = ------------------------------------------ ⎛ h – ---⎞ ⋅ ( h – s ) ⋅ t + t 3 2⎠ ( 1 – µ 2 ) ⋅ K 1 ⋅ D a2 ⎝
(10)
The constant K1 depends on disc spring outside diameter D, inside diameter d, and their ratio δ = D⁄d : – 1⎞ 2 ⎛ δ----------⎝ δ ⎠ K 1 = ---------------------------------------δ + 1- – ------2 -⎞ π ⋅ ⎛ ----------⎝ δ – 1 ln δ⎠
(11)
Table 2 compares the spring force of a series of disc springs deflected by 75% of their cone height, i.e., s = 0.75h, as determined from manufacturers catalogs calculated in accordance with Equation (4), calculated forces by use of Equation (10), and measured forces. Table 2. Comparison Between Calculated and Measured Disc Spring Forces Disc Spring Catalog Item 50 – 22.4 – 2.5 S = 1.05 mm 60 – 30.5 – 2.5 S = 1.35 mm 60 – 30.5 – 3 S = 1.275 mm 70 – 35.5 – 3 S = 1.575 mm 70 – 35.5 – 3.5 S = 1.35 mm
Schnorr Handbook for Disc Springs 8510 N 1913 lbf 8340 N 1875 lbf 13200 N 2967 lbf 12300 N 2765 lbf
Christian Bauer Disc Spring Handbook 8510 N 1913 lbf 8342 N 1875 lbf 13270 N 2983 lbf 12320 N 2770 lbf 16180 N 3637 lbf
Key Bellevilles Disc Spring Catalog 8616 N 1937 lbf 8465 N 1903 lbf 13416 N 3016 lbf 12397 N 2787 lbf
Spring Force Calculated by Equation (10)
Measured Disc Spring Force
9020 N 2028 lbf 8794 N 1977 lbf 14052 N 3159 lbf 12971 N 2916 lbf 17170 N 3860 lbf
9563 N 2150 lbf 8896 N 2000 lbf 13985 N 3144 lbf 13287 N 2987 lbf 17304 N 3890 lbf
Comparison made at 75% deflection, in Newtons (N) and pounds (lbf)
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Machinery's Handbook 27th Edition DISC SPRING FORCES AND STRESSES
361
The difference between disc spring forces calculated by Equation (10) and the measured forces varies from −5.7% (maximum) to +0.5% (minimum). Disc spring forces calculated by Equation (4) and shown in manufacturers catalogs are less than measured forces by − 11% (maximum) to −6% (minimum). Force Generated by Disc Spring with Contact Surfaces.—Some of disc springs in Group 2 and all disc springs in Group 3 are manufactured with small contact (load-bearing) surfaces or flats in addition to the corner radii. These flats provide better contact between disc springs, but, at the same time, they reduce the springs outside diameter and generate higher spring force because in Equation (4) force F is inversely proportional to the square of outside diameter D2. To compensate for the undesired force increase, the disc spring thickness is reduced from t to t′. Thickness reduction factors t′⁄t are approximately 0.94 for disc spring series A and B, and approximately 0.96 for series C springs. With such reduction factors, the disc spring force at 75% deflection is the same as for equivalent disc spring without contact surfaces. Equation (12), which is similar to Equation (10), has an additional constant K4 that correlates the increase in spring force due to contact surfaces. If disc springs do not have contact surfaces, then K42 = K4 = 1. 2
4 ⋅ E ⋅ K4 ⋅ s 2 3 s F = ----------------------------------------- K 4 ⋅ ⎛ h′ – ---⎞ ⋅ ( h′ – s ) ⋅ t′ + ( t′ ) ⎝ ⎠ 2 2 2 ( 1 – µ ) ⋅ K1 ⋅ Da
(12)
where t′ = reduced thickness of a disc spring h′ = cone height adjusted to reduced thickness: h′= H − t′ (h′ > h) K4 = constant applied to disc springs with contact surfaces. K42 can be calculated as follows: 2
2 – b + b – 4acK 4 = -------------------------------------(13) 2a where a = t′(H − 4t′ + 3t) (5H − 8 t′ + 3t); b = 32(t′)3 ; and, c = −t [5(H – t)2 + 32t2]. Disc Spring Functional Stresses.—Disc springs are designed for both static and dynamic load applications. In static load applications, disc springs may be under constant or fluctuating load conditions that change up to 5,000 or 10,000 cycles over long time intervals. Dynamic loads occur when disc springs are under continuously changing deflection between pre-load (approximately 15% to 20% of the cone height) and the maximum deflection values over short time intervals. Both static and dynamic loads cause compressive and tensile stresses. The position of critical stress points on a disc spring cross section are shown in Fig. 9.
Do
F
F 0
t
1
1
0
2
2
3
3
F
h s
H
F d D
Fig. 9. Critical Stress Points s is deflection of spring by force F; h − s is a cone height of loaded disc spring
Compressive stresses are acting at points 0 and 1, that are located on the top surface of the disc spring. Point 0 is located on the cross-sectional mid-point diameter, and point 1 is located on the top inside diameter. Tensile stresses are acting at points 2 and 3, which are located on the bottom surface of the disc spring. Point 2 is on the bottom inside diameter, and point 3 is on the bottom outside diameter. The following equations are used to calcu-
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Machinery's Handbook 27th Edition 362
DISC SPRING FATIGUE LIFE
late stresses. The minus sign “−” indicates that compressive stresses are acting in a direction opposite to the tensile stresses. 4E ⋅ t ⋅ s ⋅ K 4 3 σ 0 = – --- ⋅ ----------------------------------------π ( 1 – µ2 ) ⋅ K ⋅ D2 1 a
Point 0:
(14)
Point 1:
4E ⋅ K 4 ⋅ s ⋅ K 4 ⋅ K 2 ⋅ ⎛ h – --s-⎞ + K 3 ⋅ t ⎝ 2⎠ σ 1 = – --------------------------------------------------------------------------------------------2 2 ( 1 – µ ) ⋅ K1 ⋅ Da
(15)
Point 2:
s 4E ⋅ K 4 ⋅ s ⋅ K 3 ⋅ t – K 2 ⋅ K 4 ⋅ ⎛ h – ---⎞ ⎝ 2⎠ σ 2 = --------------------------------------------------------------------------------------------2 2 ( 1 – µ ) ⋅ K1 ⋅ Da
(16)
Point 3:
4E ⋅ K 4 ⋅ s ⋅ K 4 ⋅ ( 2K 3 – K 2 ) ⋅ ⎛ h – --s-⎞ + K 3 ⋅ t ⎝ 2⎠ σ 3 = -----------------------------------------------------------------------------------------------------------------2 2 ( 1 – µ ) ⋅ K1 ⋅ Da ⋅ δ
(17)
K2 and K3 are disc spring dimensional constants, defined as follows: δ–1 6 ⎛⎝ ----------- – 1⎞⎠ ln δ K 2 = -----------------------------π ⋅ ln δ
(18)
⋅ ( δ – 1 )K 3 = 3----------------------π ⋅ ln δ
(19)
where δ = D ⁄d is the outside-to-inside diameter ratio. In static application, if disc springs are fully flattened (100% deflection), compressive stress at point 0 should not exceed the tensile strength of disc spring materials. For most spring steels, the permissible value is σ0 ≤ 1600 N⁄mm2 or 232,000 psi. In dynamic applications, certain limitations on tensile stress values are recommended to obtain controlled fatigue life of disc springs utilized in various stacking. Maximum tensile stresses at points 2 and 3 depend on the Group number of the disc springs. Stresses σ2 and σ3 should not exceed the following values: Maximum allowable tensile stresses at points 2 and 3
Group 1
Group 2
Group 3
1300 N ⁄ mm2 (188,000 psi)
1250 N ⁄ mm2 (181,000 psi)
1200 N ⁄ mm2 (174,000 psi)
Fatigue Life of Disc Springs.—Fatigue life is measured in terms of the maximum number of cycles that dynamically loaded disc springs can sustain prior to failure. Dynamically loaded disc springs are divided into two groups: disc springs with unlimited fatigue life, which exceeds 2 × 106 cycles without failure, and disc springs with limited fatigue life between 104 cycles and less then 2 × 106 cycles. Typically, fatigue life is estimated from three diagrams, each representing one of the three Groups of disc springs (Figs. 10, 11, and 12). Fatigue life is found at the intersection of the vertical line representing minimum tensile stress σmin with the horizontal line, which represents maximum tensile stress σmax. The point of intersection of these two lines defines fatigue life expressed in number of cycles N that can be sustained prior to failure. Example: For Group 2 springs in Fig. 11, the intersection point of the σmin = 500 N⁄mm2 line with the σmax = 1200 N⁄mm2 line, is located on the N = 105 cycles line. The estimated fatigue life is 105 cycles.
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Machinery's Handbook 27th Edition DISC SPRING FATIGUE LIFE
363
LIVE GRAPH Click here to view
1400
A
B
C
Maximun Tensile Stress (N /mm2)
1200
1000
800
600
Number of Loading Cycles 400
A B C
200
100,000 500,000 2,000,000
0 0
200
400
600
800
1000
1200
1400
Minimum Tensile Stress (N / mm2)
Fig. 10. Group 1 Diagram for Estimating Fatigue Life of Disc Springs (0.2 ≤ t < 1.25 mm) LIVE GRAPH Click here to view
1400
A
B
C
Maximun Tensile Stress (N /mm2)
1200
1000
800
600
Number of Loading Cycles 400
A B C
200
100,000 500,000 2,000,000
0 0
200
400
600
800
1000
1200
1400
Minimum Tensile Stress (N / mm2)
Fig. 11. Group 2 Diagram for Estimating Fatigue Life of Disc Springs (1.25 ≤ t ≤ 6 mm) LIVE GRAPH Click here to view
1400
A
Maximun Tensile Stress (N /mm2)
1200
B
C
1000
800
600
Number of Loading Cycles 400
A B C
200
100,000 500,000 2,000,000
0 0
200
400
600
800
1000
1200
1400
Minimum Tensile Stress (N / mm2)
Fig. 12. Group 3 Diagram for Estimating Fatigue Life of Disc Springs (6 < t ≤ 16 mm)
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Machinery's Handbook 27th Edition 364
DISC SPRING FATIGUE LIFE
When the intersection points of the minimum and maximum stress lines fall inside the areas of each cycle line, only the approximate fatigue life can be estimated by extrapolating the distance from the point of intersection to the nearest cycle line. The extrapolation cannot provide accurate values of fatigue life, because the distance between the cycle lines is expressed in logarithmic scale, and the distance between tensile strength values is expressed in linear scale (Figs. 10, 11, and 12), therefore linear-to-logarithmic scales ratio is not applicable. When intersection points of minimum and maximum stress lines fall outside the cycle lines area, especially outside the N = 105 cycles line, the fatigue life cannot be estimated. Thus, the use of the fatigue life diagrams should be limited to such cases when the minimum and maximum tensile stress lines intersect exactly with each of the cycle lines. To calculate fatigue life of disc springs without the diagrams, the following equations developed by the author can be used. Disc Springs in Group 1 Disc Springs in Group 2 Disc Springs in Group 3
N = 10
10.29085532 – 0.00542096 ( σ max – 0.5σ min )
(20)
N = 10
10.10734911 – 0.00537616 ( σ max – 0.5σ min )
(21)
N = 10
13.23985664 – 0.01084192 ( σ max – 0.5σ min )
(22)
As can be seen from Equations (20), (21), and (22), the maximum and minimum tensile stress range affects the fatigue life of disc springs. Since tensile stresses at Points 2 and 3 have different values, see Equations (16) and (17), it is necessary to determine at which critical point the minimum and maximum stresses should be used for calculating fatigue life. The general method is based on the diagram, Fig. 9, from which Point 2 or Point 3 can be found in relationship with disc spring outside-to-inside diameters ratio D⁄d and disc spring cone height-to-thickness ratio h/r. This method requires intermediate calculations of D⁄d and h/t ratios and is applicable only to disc springs without contact surfaces. The method is not valid for Group 3 disc springs or for disc springs in Group 2 that have contact surfaces and reduced thickness. A simple and accurate method, that is valid for all disc springs, is based on the following statements: if (σ2 max – 0.5 σ2 min) > (σ3 max – 0.5 σ3 min), then Point 2 is used, otherwise if (σ3 max – 0.5 σ3 min) > (σ2 max – 0.5 σ2 min), then Point 3 is used The maximum and minimum tensile stress range for disc springs in Groups 1, 2, and 3 is found from the following equations. For disc springs in Group 1: 10.29085532 – log N σ max – 0.5σ min = ------------------------------------------------0.00542096 For disc springs in Group 2: – log N σ max – 0.5σ min = 10.10734911 ------------------------------------------------0.00537616 For disc springs in Group 3:
(23)
(24)
– log N σ max – 0.5σ min = 13.23985664 ------------------------------------------------(25) 0.01084192 Thus, Equations (23), (24), and (25) can be used to design any spring stack that provides required fatigue life. The following example illustrates how a maximum-minimum stress range is calculated in relationship with fatigue life of a given disc spring stack.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition DISC SPRING RECOMMENDED DIMENSION RATIOS
365
Example:A dynamically loaded stack, which utilizes disc springs in Group 2, must have the fatigue life of 5 × 105 cycles. The maximum allowable tensile stress at Points 2 or 3 is 1250 N⁄mm2. Find the minimum tensile stress value to sustain N = 5 × 105 cycles. Solution: Substitution of σmax = 1250 and N = 5 × 105 in Equation (24) gives: 5
10.10734911 – log ( 5 × 10 ) – 5.69897- = 820 1250 – 0.5σ min = -------------------------------------------------------------------- = 10.10734911 -------------------------------------------------------0.00537616 0.00537616 1250 – 820 from which σ min = --------------------------- = 860 N/mm 2 (124,700 psi) 0.5 Recommended Dimensional Characteristics of Disc Springs.—Dimensions of disc springs play a very important role in their performance. It is imperative to check selected disc springs for dimensional ratios, that should fall within the following ranges: 1) Diameters ratio, δ = D⁄d = 1.7 to 2.5. 2) Cone height-to-thickness ratio, h⁄t = 0.4 to 1.3. 3) Outside diameter-to-thickness ratio, D⁄t = 18 to 40. Small values of δ correspond with small values of the other two ratios. The h⁄t ratio determines the shape of force-deflection characteristic graphs, that may be nearly linear or strongly curved. If h⁄t = 0.4 the graph is almost linear during deflection of a disc spring up to its flat position. If h⁄t = 1.6 the graph is strongly curved and its maximum point is at 75% deflection. Disc spring deflection from 75% to 100% slightly reduces spring force. Within the h⁄t = 0.4 – 1.3 range, disc spring forces increase with the increase in deflection and reach maximum values at 100% deflection. In a stack of disc springs with a ratio h⁄t > 1.3 deflection of individual springs may be unequal, and only one disc spring should be used if possible. Example Applications of Disc Springs Example 1, Disc Springs in Group 2 (no contact surfaces): A mechanical device that works under dynamic loads must sustain a minimum of 1,000,000 cycles. The applied load varies from its minimum to maximum value every 30 seconds. The maximum load is approximately 20,000N (4,500 lbf). A 40-mm diameter guide rod is a receptacle for the disc springs. The rod is located inside a hollow cylinder. Deflection of the disc springs under minimum load should not exceed 5.5 mm (0.217 inch) including a 20 per cent preload deflection. Under maximum load, the deflection is limited to 8 mm (0.315 inch) maximum. Available space for the disc spring stack inside the cylinder is 35 to 40 mm (1.38 to 1.57 inch) in length and 80 to 85 mm (3.15 to 3.54 inch) in diameter. Select the disc spring catalog item, determine the number of springs in the stack, the spring forces, the stresses at minimum and maximum deflection, and actual disc spring fatigue life. Solution: 1) Disc spring standard inside diameter is 41 mm (1.61 inch) to fit the guide rod. The outside standard diameter is 80 mm (3.15 in) to fit the cylinder inside diameter. Disc springs with such diameters are available in various thickness: 2.25, 3.0, 4.0, and 5.0 mm (0.089, 0.118, 0.157, and 0.197 inch). The 2.25- and 3.0-mm thick springs do not fit the applied loads, since the maximum force values for disc springs with such thickness are 7,200N and 13,400N (1,600 lbf and 3,000 lbf) respectively. A 5.0-mm thick disc spring should not be used because its D⁄t ratio, 80⁄5 = 16, is less than 18 and is considered as unfavorable. Disc spring selection is narrowed to an 80–41–4 catalog item. 2) Checking 80 – 41 – 4 disc spring for dimensional ratios: h⁄ = 2.2⁄ = 0.55 D⁄ = 80⁄ = 20 δ = D⁄d = 80⁄41 = 1.95 t 4 t 4 Because the dimensional ratios are favorable, the 80–41–4 disc springs are selected.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 366
DISC SPRING EXAMPLE
3) The number of springs in the stack is found from Equation (1): n = Lo ⁄ (t + h) = 40 ⁄ (4 + 2.2) = 40⁄6.2 = 6.45. Rounding n to the nearest integer gives n = 6. The actual length of unloaded spring stack is Lo = 6.2 × 6 = 37.2 mm (1.465 inch) and it satisfies the Lo< 40 mm condition. 4) Calculating the cone angle α from Equation (7) and actual outside diameter Da from Equation (9) gives: 2 × 2.2-⎞ = atan ( 0.11282 ) = 6.4° α = atan ⎛ ----------------⎝ 80 – 41⎠ D a = 80 – 2 × 4 ⎛ sin [ atan ( 0.11282 ) ] + 1--- cos [ atan ( 0.11282 ) ]⎞ ⎝ ⎠ 6 D a = 77.78 mm (3.062 in) 5) Calculating constant K1 from Equation (11): D- = 1.95122 δ = --d 2
– 1-⎞ ⎛ 1.95122 --------------------------⎝ 1.95122 ⎠ K 1 = ------------------------------------------------------------------------------ = 0.6841 + 1 – ----------------------------2 π ⋅ 1.95122 ---------------------------1.95122 – 1 ln ( 1.95122 ) 6) Calculating minimum and maximum forces, Fmin and Fmax from Equation (10): Based on the design requirements, the disc spring stack is deflecting by 5.5 mm (0.217 in) under minimum load, and each individual disc spring is deflecting by 5.5 ⁄ 6 ≅ 0.92 mm (0.036 in). A single disc spring deflection smin = 0.9 mm (0.035 in) is used to calculate Fmin. Under maximum load, the disc spring stack is permitted maximum deflection of 8 mm (0.315 in), and each individual disc spring deflects by 8 ⁄ 6 ≅ 1.33 mm (0.0524 in). A disc spring deflection smax = 1.32 mm (0.052 in) will be used to calculate Fmax. If disc springs are made of AISI 6150 alloy steel, then modulus of elasticity E = 206,000 N⁄mm2 (30 × 106 psi) and Poisson’s ratio µ = 0.3. 4 ⋅ 206000 F min = ------------------------------------------------------------------- ⎛ 2.2 – 0.9 -------⎞ ⋅ ( 2.2 – 0.9 ) ⋅ 4 + 4 3 0.9 2⎠ ( 1 – 0.3 2 ) ( 0.6841 ) ( 77.78 ) 2 ⎝ F min = 14390N (3235 lbf) 1.32 4 ⋅ 206000 - ⎛ 2.2 – ----------⎞ ⋅ ( 2.2 – 1.32 ) ⋅ 4 + 4 3 1.32 F max = -----------------------------------------------------------------2 ⎠ ( 1 – 0.3 2 ) ( 0.6841 ) ( 77.78 ) 2 ⎝ F max = 20050N (4510 lbf) 7) Calculating constant K2, Equation (18): D 80 δ = ---- = ------ = 1.95122 d 41 – 1 – 1⎞ 1.95122 – 1- – 1⎞ 6 ⎛ δ----------6 ⎛ ----------------------------⎝ ln δ ⎠ ⎝ ln ( 1.95122 ) ⎠ K 2 = ------------------------------ = ------------------------------------------------ = 1.2086 π ⋅ ln δ π ⋅ ln ( 1.95122 ) 8) Calculating constant K3 (Equation (19)): 3 ⋅ (δ – 1) 3 ⋅ ( 1.95122 – 1 ) K 3 = ------------------------ = ---------------------------------------- = 1.3589 π ⋅ ln δ π ⋅ ln ( 1.95122 )
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition DISC SPRING EXAMPLE
367
9) Compressive stress σ0 at point 0 due to maximum deflection, Equation (14): 4E ⋅ t ⋅ s ⋅ K 4 4 ⋅ 206000 ⋅ 4 ⋅ 1.32 ⋅ 1 σ 0 = – --3- ⋅ ----------------------------------------- = – --3- ⋅ ---------------------------------------------------------------π ( 1 – µ2 ) ⋅ K ⋅ D2 π ( 1 – 0.3 2 ) ⋅ 0.6841 ⋅ 77.78 2 1 a σ 0 = 1103N/mm2 = 160000psi Because the compressive stress at point 0 does not exceed 1600 N⁄mm2, its current value satisfies the design requirement. 10) Tensile stress σ2 at point 2 due to minimum deflection s = 0.9 mm, Equation (16): σ 2min
s 4E ⋅ K 4 ⋅ s ⋅ K 3 ⋅ t – K 2 ⋅ K 4 ⋅ ⎛ h – ---⎞ ⎝ 2⎠ = --------------------------------------------------------------------------------------------- = 2 2 ( 1 – µ ) ⋅ K1 ⋅ Da
4 ⋅ 206000 ⋅ 1 ⋅ 0.9 ⋅ 1.3589 ⋅ 4 – 1.2086 ⋅ 1 ⋅ ⎛ 2.2 – 0.9 -------⎞ ⎝ 2⎠ -------------------------------------------------------------------------------------------------------------------------------------------- = 654 N/mm2 2 2 ( 1 – 0.3 ) ⋅ 0.6841 ⋅ 77.78 11) Tensile stress σ2 at point 2 due to maximum deflection s = 1.32 mm, Equation (16): σ 2max
4E ⋅ K 4 ⋅ s ⋅ K 3 ⋅ t – K 2 ⋅ K 4 ⋅ ⎛ h – --s-⎞ ⎝ 2⎠ = --------------------------------------------------------------------------------------------- = 2 2 ( 1 – µ ) ⋅ K1 ⋅ Da
1.32 4 ⋅ 206000 ⋅ 1 ⋅ 1.32 ⋅ 1.3589 ⋅ 4 – 1.2086 ⋅ 1 ⋅ ⎛⎝ 2.2 – ----------⎞⎠ 2 -------------------------------------------------------------------------------------------------------------------------------------------------- = 1032 N/mm2 2 2 ( 1 – 0.3 ) ⋅ 0.6841 ⋅ 77.78 Thus, σ2 min = 654 N⁄mm2 (94,850 psi) and σ2 max = 1032 N⁄mm2 (149,700 psi). 12) Tensile stress σ3 at point 3 due to minimum deflection s = 0.9 mm, Equation (17): 4E ⋅ K 4 ⋅ s ⋅ K 4 ⋅ ( 2K 3 – K 2 ) ⋅ ⎛ h – --s-⎞ + K 3 ⋅ t ⎝ 2⎠ σ 3min = ------------------------------------------------------------------------------------------------------------------ = 2 2 ( 1 – µ ) ⋅ K1 ⋅ Da ⋅ δ 4 ⋅ 206000 ⋅ 1 ⋅ 0.9 ⋅ 1 ⋅ ( 2 ⋅ 1.3589 – 1.2086 ) ⋅ ⎛ 2.2 – 0.9 -------⎞ + 1.3589 ⋅ 4 ⎝ 2⎠ 2 ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- = 815N/mm 2 2 ( 1 – 0.3 ) ⋅ 0.6841 ⋅ 77.78 ⋅ 1.95122
13) Tensile stress σ3 at point 3 due to maximum deflection s = 1.32 mm, Equation (17): 4E ⋅ K 4 ⋅ s ⋅ K 4 ⋅ ( 2K 3 – K 2 ) ⋅ ⎛ h – --s-⎞ + K 3 ⋅ t ⎝ 2⎠ σ 3max = ------------------------------------------------------------------------------------------------------------------ = 2 2 ( 1 – µ ) ⋅ K1 ⋅ Da ⋅ δ 1.32-⎞ + 1.3589 ⋅ 4 4 ⋅ 206000 ⋅ 1 ⋅ 1.32 ⋅ 1 ⋅ ( 2 ⋅ 1.3589 – 1.2086 ) ⋅ ⎛⎝ 2.2 – --------2 ⎠ 2 ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- = 1149 N/mm 2 2 ( 1 – 0.3 ) ⋅ 0.6841 ⋅ 77.78 ⋅ 1.95122
Thus, σ3 min = 815 N⁄mm2 (118,200 psi) and σ3 max = 1149 N⁄mm2 (166,600 psi). 14) Functional tensile stress range at critical points 2 and 3. Point 2: σ2 max – 0.5σ2 min = 1032 – 0.5 × 654 = 705 N⁄mm2 Point 3: σ3 max – 0.5σ3 min = 1149 – 0.5 × 815 = 741.5 N⁄mm2 Because σ3 max – 0.5σ3 min > σ2 max – 0.5 σ2 min, the tensile stresses at point 3 are used for fatigue life calculations.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 368
DISC SPRING EXAMPLE
15) Fatigue life of selected disc springs, Equation (21): N = 10[10.10734911 – 0.00537616 (1149 – 0.5 × 815)] = 1010.10734911 – 3.98642264 = 10 6.12092647 N = 1,321,000 cycles. Thus, the calculated actual fatigue life exceeds required minimum number of cycles by 32%. In conclusion, the six 80–41–4 disc springs arranged in series stacking, satisfy the requirements and will provide a 32 % longer fatigue life than required by the design criteria. Example 2:A company wishes to use Group 3 disc springs with contact surfaces on couplings to absorb bumping impacts between railway cars. Given: D =200 mm, disc spring outside diameter d =102 mm, disc spring inside diameter t =14 mm, spring standard thickness t′ =13.1 mm, spring reduced thickness h =4.2 mm, cone height of unloaded spring n =22, number of springs in series stacking Si =33.9 mm, initial deflection of the pack Sa =36.0 mm, additional deflection of the pack Find the fatigue life in cycles and determine if the selected springs are suitable for the application. The calculations are performed in the following sequence: 1) Determine the minimum smin and maximum smax deflections of a single disc spring: ( Si + Sa ) 33.9 + 36 )- = 3.18mm s max = -------------------- = (-------------------------n 22 Si 33.9- = 1.54mm s min = ---- = --------n 22 2) Use Equations (16) and (17) to calculate tensile stresses σ2 and σ3 at smin and smax deflections: σ2min= 674 N⁄mm2, σ2max= 1513 N⁄mm2, σ3min= 707 N⁄mm2, σ3max= 1379 N⁄mm2 3) Determine critical stress points: σ2max − 0.5σ2min = 1513 − 0.5 × 674 = 1176 N⁄mm2 σ3max − 0.5σ3min = 1379 − 0.5 × 707 = 1025.5 N⁄mm2 Because (σ2max − 0.5σ2min) > (σ3max − 0.5σ3min), then tensile stresses at Point 2 are used to calculate fatigue life. 4) Fatigue life N is calculated using Equation (22): N = 10 [13.23985664 − (0.01084192 × 1176)] = 10 0.49 = 3 cycles The selected disc springs at the above-mentioned minimum and maximum deflection values will not sustain any number of cycles. It is imperative to check the selected disc springs for dimensional ratios: Outside-to-inside diameters ratio, 200⁄102 = 1.96; within recommended range. Cone height-to-thickness ratio is 4.2⁄13.1 = 0.3; out of range, the minimum ratio is 0.4. Outside diameter-to-thickness ratio is 200 ⁄13.1 = 15; out of range, the minimum ratio is 18. Thus, only one of the dimensional ratios satisfies the requirements for the best disc spring performance.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition WIRE ROPE
369
WIRE ROPE, CHAIN, ROPE, AND HOOKS Strength and Properties of Wire Rope Wire Rope Construction.—Essentially, a wire rope is made up of a number of strands laid helically about a metallic or non-metallic core. Each strand consists of a number of wires also laid helically about a metallic or non-metallic center. Various types of wire rope have been developed to meet a wide range of uses and operating conditions. These types are distinguished by the kind of core; the number of strands; the number, sizes, and arrangement of the wires in each strand; and the way in which the wires and strands are wound or laid about each other. The following descriptive material is based largely on information supplied by the Bethlehem Steel Co. Rope Wire Materials: Materials used in the manufacture of rope wire are, in order of increasing strength: iron, phosphor bronze, traction steel, plow steel, improved plow steel, and bridge rope steel. Iron wire rope is largely used for low-strength applications such as elevator ropes not used for hoisting, and for stationary guy ropes. Phosphor bronze wire rope is used occasionally for elevator governor-cable rope and for certain marine applications as life lines, clearing lines, wheel ropes and rigging. Traction steel wire rope is used primarily as hoist rope for passenger and freight elevators of the traction drive type, an application for which it was specifically designed. Ropes made of galvanized wire or wire coated with zinc by the electro-deposition process are used in certain applications where additional protection against rusting is required. As will be noted from the tables of wire-rope sizes and strengths, the breaking strength of galvanized wire rope is 10 per cent less than that of ungalvanized (bright) wire rope. Bethanized (zinc-coated) wire rope can be furnished to bright wire rope strength when so specified. Galvanized carbon steel, tinned carbon steel, and stainless steel are used for small cords and strands ranging in diameter from 1⁄64 to 3⁄8 inch and larger. Marline clad wire rope has each strand wrapped with a layer of tarred marline. The cladding provides hand protection for workers and wear protection for the rope. Rope Cores: Wire-rope cores are made of fiber, cotton, asbestos, polyvinyl plastic, a small wire rope (independent wire-rope core), a multiple-wire strand (wire-strand core) or a cold-drawn wire-wound spring. Fiber (manila or sisal) is the type of core most widely used when loads are not too great. It supports the strands in their relative positions and acts as a cushion to prevent nicking of the wires lying next to the core. Cotton is used for small ropes such as sash cord and aircraft cord. Asbestos cores can be furnished for certain special operations where the rope is used in oven operations. Polyvinyl plastics cores are offered for use where exposure to moisture, acids, or caustics is excessive. A wire-strand core often referred to as WSC, consists of a multiple-wire strand that may be the same as one of the strands of the rope. It is smoother and more solid than the independent wire rope core and provides a better support for the rope strands. The independent wire rope core, often referred to as IWRC, is a small 6 × 7 wire rope with a wire-strand core and is used to provide greater resistance to crushing and distortion of the wire rope. For certain applications it has the advantage over a wire-strand core in that it stretches at a rate closer to that of the rope itself. Wire ropes with wire-strand cores are, in general, less flexible than wire ropes with independent wire-rope or non-metallic cores.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 370
WIRE ROPE
Ropes with metallic cores are rated 71⁄2 per cent stronger than those with non-metallic cores. Wire-Rope Lay: The lay of a wire rope is the direction of the helical path in which the strands are laid and, similarly, the lay of a strand is the direction of the helical path in which the wires are laid. If the wires in the strand or the strands in the rope form a helix similar to the threads of a right-hand screw, i.e., they wind around to the right, the lay is called right hand and, conversely, if they wind around to the left, the lay is called left hand. In the regular lay, the wires in the strands are laid in the opposite direction to the lay of the strands in the rope. In right-regular lay, the strands are laid to the right and the wires to the left. In leftregular lay, the strands are laid to the left, the wires to the right. In Lang lay, the wires and strands are laid in the same direction, i.e., in right Lang lay, both the wires and strands are laid to the right and in left Lang they are laid to the left. Alternate lay ropes having alternate right and left laid strands are used to resist distortion and prevent clamp slippage, but because other advantages are missing, have limited use. The regular lay wire rope is most widely used and right regular lay rope is customarily furnished. Regular lay rope has less tendency to spin or untwist when placed under load and is generally selected where long ropes are employed and the loads handled are frequently removed. Lang lay ropes have greater flexibility than regular lay ropes and are more resistant to abrasion and fatigue. In preformed wire ropes the wires and strands are preshaped into a helical form so that when laid to form the rope they tend to remain in place. In a non-preformed rope, broken wires tend to “wicker out” or protrude from the rope and strands that are not seized tend to spring apart. Preforming also tends to remove locked-in stresses, lengthen service life, and make the rope easier to handle and to spool. Strand Construction: Various arrangements of wire are used in the construction of wire rope strands. In the simplest arrangement six wires are grouped around a central wire thus making seven wires, all of the same size. Other types of construction known as “fillerwire,” Warrington, Seale, etc. make use of wires of different sizes. Their respective patterns of arrangement are shown diagrammatically in the table of wire weights and strengths. Specifying Wire Rope.—In specifying wire rope the following information will be required: length, diameter, number of strands, number of wires in each strand, type of rope construction, grade of steel used in rope, whether preformed or not preformed, type of center, and type of lay. The manufacturer should be consulted in selecting the best type of wire rope for a new application. Properties of Wire Rope.—Important properties of wire rope are strength, wear resistance, flexibility, and resistance to crushing and distortion. Strength: The strength of wire rope depends upon its size, kind of material of which the wires are made and their number, the type of core, and whether the wire is galvanized or not. Strengths of various types and sizes of wire ropes are given in the accompanying tables together with appropriate factors to apply for ropes with steel cores and for galvanized wire ropes. Wear Resistance: When wire rope must pass back and forth over surfaces that subject it to unusual wear or abrasion, it must be specially constructed to give satisfactory service. Such construction may make use of 1) relatively large outer wires; 2) Lang lay in which wires in each strand are laid in the same direction as the strand; and 3) flattened strands. The object in each type is to provide a greater outside surface area to take the wear or abrasion. From the standpoint of material, improved plow steel has not only the highest tensile strength but also the greatest resistance to abrasion in regularly stocked wire rope.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition WIRE ROPE
371
Flexibility: Wire rope that undergoes repeated and severe bending, such as in passing around small sheaves and drums, must have a high degree of flexibility to prevent premature breakage and failure due to fatigue. Greater flexibility in wire rope is obtained by 1) using small wires in larger numbers; 2) using Lang lay; and 3) preforming, that is, the wires and strands of the rope are shaped during manufacture to fit the position they will assume in the finished rope. Resistance to Crushing and Distortion: Where wire rope is to be subjected to transverse loads that may crush or distort it, care should be taken to select a type of construction that will stand up under such treatment. Wire rope designed for such conditions may have 1) large outer wires to spread the load per wire over a greater area; and 2) an independent wire core or a high-carbon cold-drawn wound spring core. Standard Classes of Wire Rope.—Wire rope is commonly designated by two figures, the first indicating the number of strands and the second, the number of wires per strand, as: 6 × 7, a six-strand rope having seven wires per strand, or 8 × 19, an eight-strand rope having 19 wires per strand. When such numbers are used as designations of standard wire rope classes, the second figure in the designation may be purely nominal in that the number of wires per strand for various ropes in the class may be slightly less or slightly more than the nominal as will be seen from the following brief descriptions. (For ropes with a wire strand core, a second group of two numbers may be used to indicate the construction of the wire core, as 1 × 21, 1 × 43, and so on.) 6 × 7 Class (Standard Coarse Laid Rope): Wire ropes in this class are for use where resistance to wear, as in dragging over the ground or across rollers, is an important requirement. Heavy hauling, rope transmissions, and well drilling are common applications. These wire ropes are furnished in right regular lay and occasionally in Lang lay. The cores may be of fiber, independent wire rope, or wire strand. Since this class is a relatively stiff type of construction, these ropes should be used with large sheaves and drums. Because of the small number of wires, a larger factor of safety may be called for.
Fig. 1a. 6 × 7 with fiber core
Fig. 1b. 6 × 7 with 1 × 7 WSC
Fig. 1c. 6 × 7 with 1 × 19 WSC
Fig. 1d. 6 × 7 with IWRC
As shown in Figs. 1a through Figs. 1d, this class includes a 6 × 7 construction with fiber core: a 6 × 7 construction with 1 × 7 wire strand core (sometimes called 7 × 7); a 6 × 7 construction with 1 × 19 wire strand core; and a 6 × 7 construction with independent wire rope core. Table 1 provides strength and weight data for this class. Two special types of wire rope in this class are: aircraft cord, a 6 × 6 or 7 × 7 Bethanized wire rope of high tensile strength and sash cord, a 6 × 7 iron rope used for a variety of purposes where strength is not an important factor.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 372
WIRE ROPE Table 1. Weights and Strengths of 6 × 7 (Standard Coarse Laid) Wire Ropes, Preformed and Not Preformed
Dia., Inches 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8
Approx. Weight per Ft., Pounds
Breaking Strength, Tons of 2000 Lbs. Impr. Mild Plow Plow Plow Steel Steel Steel
Dia., Inches
Approx. Weight per Ft., Pounds
3⁄ 4 7⁄ 8
0.84 1.15
Breaking Strength, Tons of 2000 Lbs. Impr. Mild Plow Plow Plow Steel Steel Steel
0.094 0.15
2.64 4.10
2.30 3.56
2.00 3.10
22.7 30.7
19.8 26.7
17.2 23.2
0.21
5.86
5.10
4.43
1
1.50
39.7
34.5
30.0
0.29
7.93
6.90
6.00
11⁄8
1.90
49.8
43.3
37.7
0.38
10.3
8.96
7.79
11⁄4
2.34
61.0
53.0
46.1
0.48
13.0
11.3
9.82
13⁄8
2.84
73.1
63.6
55.3
0.59
15.9
13.9
12.0
11⁄2
3.38
86.2
75.0
65.2
For ropes with steel cores, add 71⁄2 per cent to above strengths. For galvanized ropes, deduct 10 per cent from above strengths. Source: Rope diagrams, Bethlehem Steel Co. All data, U.S. Simplified Practice Recommendation 198–50.
6 × 19 Class (Standard Hoisting Rope): This rope is the most popular and widely used class. Ropes in this class are furnished in regular or Lang lay and may be obtained preformed or not preformed. Cores may be of fiber, independent wire rope, or wire strand. As can be seen from Table 2 and Figs. 2a through 2h, there are four common types: 6 × 25 filler wire construction with fiber core (not illustrated), independent wire core, or wire strand core (1 × 25 or 1 × 43); 6 × 19 Warrington construction with fiber core; 6 × 21 filler wire construction with fiber core; and 6 × 19, 6 × 21, and 6 × 17 Seale construction with fiber core. Table 2. Weights and Strengths of 6 × 19 (Standard Hoisting) Wire Ropes, Preformed and Not Preformed Approx. Weight per Ft., Pounds
Breaking Strength, Tons of 2000 Lbs. Impr. Mild Plow Plow Plow Steel Steel Steel
Breaking Strength, Tons of 2000 Lbs. Impr. Mild Plow Plow Plow Steel Steel Steel
Dia., Inches
Approx. Weight per Ft., Pounds
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 7⁄ 8
0.10 0.16
2.74
2.39
2.07
11⁄4
2.50
64.6
56.2
48.8
4.26
3.71
3.22
13⁄8
3.03
77.7
67.5
58.8
0.23
6.10
5.31
4.62
11⁄2
3.60
92.0
80.0
69.6
15⁄8 13⁄4 17⁄8
4.23
107
4.90
124
108
5.63
141
6.40
160
123 139
107 121 …
1 11⁄8
Dia., Inches
0.31
8.27
7.19
6.25
0.40
10.7
9.35
8.13
93.4
81.2 93.6
0.51
13.5
11.8
10.2
0.63
16.7
14.5
12.6
0.90
23.8
20.7
18.0
2 21⁄8
7.23
179
156
1.23
32.2
28.0
24.3
21⁄4
8.10
200
174
…
1.60
41.8
36.4
31.6
21⁄2
10.00
244
212
…
2.03
52.6
45.7
39.8
23⁄4
12.10
292
254
…
The 6 × 25 filler wire with fiber core not illustrated. For ropes with steel cores, add 71⁄2 per cent to above strengths. For galvanized ropes, deduct 10 per cent from above strengths. Source: Rope diagrams, Bethlehem Steel Co. All data, U.S. Simplified Practice Recommendation 198–50.
6 × 37 Class (Extra Flexible Hoisting Rope): For a given size of rope, the component wires are of smaller diameter than those in the two classes previously described and hence have less resistance to abrasion. Ropes in this class are furnished in regular and Lang lay with fiber core or independent wire rope core, preformed or not preformed.
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Machinery's Handbook 27th Edition WIRE ROPE
373
Fig. 2a. 6 × 25 filler wire with WSC (1 × 25)
Fig. 2b. 6 × 25 filler wire with IWRC
Fig. 2c. 6 × 19 Seale with fiber core
Fig. 2d. 6 × 21 Seale with fiber core
Fig. 2e. 6 × 25 filler wire with WSC (1 × 43)
Fig. 2f. 6 × 19 Warrington with fiber core
Fig. 2g. 6 × 17 Seale with fiber core
Fig. 2h. 6 × 21 filler wire with fiber core
Table 3. Weights and Strengths of 6 × 37 (Extra Flexible Hoisting) Wire Ropes, Preformed and Not Preformed
Dia., Inches
Approx. Weight per Ft., Pounds
1⁄ 4 5⁄ 16
Breaking Strength, Tons of 2000 Lbs.
Breaking Strength, Tons of 2000 Lbs.
Impr. Plow Steel
Plow Steel
Dia., Inches
Approx. Weight per Ft., Pounds
0.10
2.59
2.25
11⁄2
3.49
0.16
4.03
3.50
15⁄8
4.09
103
3⁄ 8
0.22
5.77
5.02
13⁄4
4.75
119
7⁄ 16
0.30
7.82
6.80
17⁄8
5.45
136
118
1⁄ 2
0.39
10.2
8.85
2
6.20
154
134
9⁄ 16
0.49
12.9
11.2
21⁄8
7.00
173
150
5⁄ 8
0.61
15.8
13.7
21⁄4
7.85
193
168
3⁄ 4
0.87
22.6
19.6
21⁄2
9.69
236
205
7⁄ 8
1.19
30.6
26.6
23⁄4
11.72
284
247
1 11⁄8
1.55 1.96
39.8 50.1
34.6 43.5
3 31⁄4
14.0 16.4
335 390
291 339
11⁄4
2.42
61.5
53.5
31⁄2
19.0
449
390
13⁄8
2.93
74.1
64.5
…
…
…
…
Impr. Plow Steel 87.9
Plow Steel 76.4 89.3 103
For ropes with steel cores, add 71⁄2 per cent to above strengths. For galvanized ropes, deduct 10 per cent from above strengths. Source: Rope diagrams, Bethlehem Steel Co. All data, U. S. Simplified Practice Recommendation 198-50.
As shown in Table 3 and Figs. 3a through 3h, there are four common types: 6 × 29 filler wire construction with fiber core and 6 × 36 filler wire construction with independent wire rope core, a special rope for construction equipment; 6 × 35 (two operations) construction with fiber core and 6 × 41 Warrington Seale construction with fiber core, a standard crane rope in this class of rope construction; 6 × 41 filler wire construction with fiber core or independent wire core, a special large shovel rope usually furnished in Lang lay; and 6 × 46
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Fig. 3a. 6 × 29 filler wire with fiber core
Fig. 3b. 6 × 36 filler wire with IWRC
Fig. 3c. 6 × 35 with fiber core
Fig. 3d. 6 × 41 Warrington-Seale with fiber core
Fig. 3e. 6 × 41 filler wire with fiber core
Fig. 3f. 6 × 41 filler wire with IWRC
Fig. 3g. 6 × 46 filler wire with fiber core
Fig. 3h. 6 × 46 filler wire with IWRC
filler wire construction with fiber core or independent wire rope core, a special large shovel and dredge rope. 8 × 19 Class (Special Flexible Hoisting Rope): This rope is stable and smooth-running, and is especially suitable, because of its flexibility, for high speed operation with reverse bends. Ropes in this class are available in regular lay with fiber core. As shown in Table 4 and Figs. 4a through 4d, there are four common types: 8 × 25 filler wire construction, the most flexible but the least wear resistant rope of the four types; Warrington type in 8 × 19 construction, less flexible than the 8 × 25; 8 × 21 filler wire construction, less flexible than the Warrington; and Seale type in 8 × 19 construction, which has the greatest wear resistance of the four types but is also the least flexible. Table 4. Weights and Strengths of 8 × 19 (Special Flexible Hoisting) Wire Ropes, Preformed and Not Preformed
Dia., Inches
Approx. Weight per Ft., Pounds
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8
0.09 0.14 0.20 0.28 0.36 0.46 0.57
Breaking Strength, Tons of 2000 Lbs. Impr. Plow Plow Steel Steel 2.35 3.65 5.24 7.09 9.23 11.6 14.3
2.04 3.18 4.55 6.17 8.02 10.1 12.4
Dia., Inches
Approx. Weight per Ft., Pounds
3⁄ 4 7⁄ 8
1 11⁄8 11⁄4 13⁄8 11⁄2
0.82 1.11 1.45 1.84 2.27 2.74 3.26
Breaking Strength, Tons of 2000 Lbs. Impr. Plow Plow Steel Steel 20.5 27.7 36.0 45.3 55.7 67.1 79.4
17.8 24.1 31.3 39.4 48.4 58.3 69.1
For ropes with steel cores, add 71⁄2 per cent to above strengths. For galvanized ropes, deduct 10 per cent from above strengths. Source: Rope diagrams, Bethlehem Steel Co. All data, U. S. Simplified Practice Recommendation 198-50.
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Machinery's Handbook 27th Edition WIRE ROPE
Fig. 4a. 8 × 25 filler wire with fiber core
Fig. 4b. 8 × 19 Warrington with fiber core
375
Fig. 4c. 8 × 21 filler wire with fiber core
Fig. 4d. 8 × 19 Seale with fiber core
Also in this class, but not shown in Table 4 are elevator ropes made of traction steel and iron. 18 × 7 Non-rotating Wire Rope: This rope is specially designed for use where a minimum of rotating or spinning is called for, especially in the lifting or lowering of free loads with a single-part line. It has an inner layer composed of 6 strands of 7 wires each laid in left Lang lay over a fiber core and an outer layer of 12 strands of 7 wires each laid in right regular lay. The combination of opposing lays tends to prevent rotation when the rope is stretched. However, to avoid any tendency to rotate or spin, loads should be kept to at least one-eighth and preferably one-tenth of the breaking strength of the rope. Weights and strengths are shown in Table 5. Table 5. Weights and Strengths of Standard 18 × 7 Nonrotating Wire Rope, Preformed and Not Preformed
Recommended Sheave and Drum Diameters Single layer on drum Multiple layers on drum Mine service
36 rope diameters 48 rope diameters 60 rope diameters
Fig. 5.
Dia., Inches 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
Approx. Weight per Ft., Pounds 0.061 0.108 0.169 0.24 0.33 0.43 0.55 0.68 0.97
Breaking Strength, Tons of 2000 Lbs. Impr. Plow Plow Steel Steel 1.42 1.24 2.51 2.18 3.90 3.39 5.59 4.86 7.58 6.59 9.85 8.57 12.4 10.8 15.3 13.3 21.8 19.0
Dia., Inches 7⁄ 8
1 11⁄8 11⁄4 13⁄8 11⁄2 15⁄8 13⁄4 …
Approx. Weight per Ft., Pounds 1.32 1.73 2.19 2.70 3.27 3.89 4.57 5.30 …
Breaking Strength, Tons of 2000 Lbs. Impr. Plow Plow Steel Steel 29.5 25.7 38.3 33.3 48.2 41.9 59.2 51.5 71.3 62.0 84.4 73.4 98.4 85.6 114 98.8 … …
For galvanized ropes, deduct 10 per cent from above strengths. Source: Rope diagrams, sheave and drum diameters, and data for 3⁄16, 1⁄4 and 5⁄16-inch sizes, Bethlehem Steel Co. All other data, U. S. Simplified Practice Recommendation 198-50.
Flattened Strand Wire Rope: The wires forming the strands of this type of rope are wound around triangular centers so that a flattened outer surface is provided with a greater area than in the regular round rope to withstand severe conditions of abrasion. The triangu-
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lar shape of the strands also provides superior resistance to crushing. Flattened strand wire rope is usually furnished in Lang lay and may be obtained with fiber core or independent wire rope core. The three types shown in Table 6 and Figs. 6a through 6c are flexible and are designed for hoisting work.
Fig. 6a. 6 × 25 with fiber core
Fig. 6b. 6 × 30 with fiber core
Fig. 6c. 6 × 27 with fiber core
Table 6. Weights and Strengths of Flattened Strand Wire Rope, Preformed and Not Preformed
Dia., Inches 3⁄ a 8 1⁄ a 2 9⁄ a 16 5⁄ 8 3⁄ 4 7⁄ 8
1 11⁄8 11⁄4
Approx. Weight per Ft., Pounds 0.25 0.45 0.57 0.70 1.01 1.39 1.80 2.28 2.81
Breaking Strength, Tons of 2000 Lbs. Impr. Mild Plow Plow Steel Steel 6.71 … 11.8 8.94 14.9 11.2 18.3 13.9 26.2 19.8 35.4 26.8 46.0 34.8 57.9 43.8 71.0 53.7
Dia., Inches 13⁄8 11⁄2 15⁄8 13⁄4 2 21⁄4 21⁄2 23⁄4 …
Approx. Weight per Ft., Pounds 3.40 4.05 4.75 5.51 7.20 9.10 11.2 13.6 …
Breaking Strength, Tons of 2000 Lbs. Impr. Mild Plow Plow Steel Steel 85.5 … 101 … 118 … 136 … 176 … 220 … 269 … 321 … … …
a These sizes in Type B only.
Type H is not in U.S. Simplified Practice Recommendation. Source: Rope diagrams, Bethlehem Steel Co. All other data, U.S. Simplified Practice Recommendation 198-50.
Flat Wire Rope: This type of wire rope is made up of a number of four-strand rope units placed side by side and stitched together with soft steel sewing wire. These four-strand units are alternately right and left lay to resist warping, curling, or rotating in service. Weights and strengths are shown in Table 7. Simplified Practice Recommendations.—Because the total number of wire rope types is large, manufacturers and users have agreed upon and adopted a U.S. Simplified Practice Recommendation to provide a simplified listing of those kinds and sizes of wire rope which are most commonly used and stocked. These, then, are the types and sizes which are most generally available. Other types and sizes for special or limited uses also may be found in individual manufacturer's catalogs. Sizes and Strengths of Wire Rope.—The data shown in Tables 1 through 7 have been taken from U.S. Simplified Practice Recommendation 198-50 but do not include those wire ropes shown in that Simplified Practice Recommendation which are intended primarily for marine use. Wire Rope Diameter: The diameter of a wire rope is the diameter of the circle that will just enclose it, hence when measuring the diameter with calipers, care must be taken to obtain the largest outside dimension, taken across the opposite strands, rather than the smallest dimension across opposite “valleys” or “flats.” It is standard practice for the nominal diameter to be the minimum with all tolerances taken on the plus side. Limits for diam-
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eter as well as for minimum breaking strength and maximum pitch are given in Federal Specification for Wire Rope, RR-R—571a. Wire Rope Strengths: The strength figures shown in the accompanying tables have been obtained by a mathematical derivation based on actual breakage tests of wire rope and represent from 80 to 95 per cent of the total strengths of the individual wires, depending upon the type of rope construction. Table 7. Weights and Strengths of Standard Flat Wire Rope, Not Preformed This rope consists of a number of 4-strand rope units placed side by side and stitched together with soft steel sewing wire.
Flat Wire Rope Width and Thickness, Inches
No. of Ropes
Approx. Weight per Ft., Pounds
Breaking Strength, Tons of 2000 Lbs. Mild PlowPlow Steel Steel
1⁄ × 4 1⁄ × 4 1⁄ × 4 1⁄ × 4
11⁄2
7
0.69
16.8
14.6
2
9
0.88
21.7
18.8
21⁄2
11
1.15
26.5
23.0
3
13
1.34
31.3
27.2
5⁄ × 16 5⁄ × 16 5⁄ × 16 5⁄ × 16 5⁄ × 16 5⁄ × 16
11⁄2
5
0.77
18.5
16.0
2
7
1.05
25.8
22.4
21⁄2
9
1.33
33.2
28.8
3
11
1.61
40.5
35.3
31⁄2
13
1.89
47.9
41.7
4
15
2.17
55.3
48.1
3⁄ × 8 3⁄ × 8 3⁄ × 8 3⁄ × 8 3⁄ × 8 3⁄ × 8 3⁄ × 8 3⁄ × 8 3⁄ × 8
2
6
1.25
31.4
27.3
21⁄2
8
1.64
41.8
36.4
3
9
1.84
47.1
40.9
11
2.23
57.5
50.0
1⁄ × 2 1⁄ × 2 1⁄ × 2
31⁄2 4
12
2.44
62.7
54.6
41⁄2
14
2.83
73.2
63.7
5
15
3.03
78.4
68.2
51⁄2
17
3.42
88.9
77.3
6
18
3.63
94.1
81.9
21⁄2
6
2.13
54.5
47.4
3
7
2.47
63.6
55.4
31⁄2
8
2.82
72.7
63.3
Width and Thickness, Inches
No. of Ropes
Approx. Weight per Ft., Pounds
Breaking Strength, Tons of 2000 Lbs. Mild Plow Plow Steel Steel
1⁄ × 2 1⁄ × 2 1⁄ × 2 1⁄ × 2 1⁄ × 2 1⁄ × 2
4
5⁄ × 8 5⁄ × 8 5⁄ × 8 5⁄ × 8 5⁄ × 8 5⁄ × 8 5⁄ × 8 5⁄ × 8
31⁄2
6
3.40
4
7
3.95
41⁄2
8
4.50
114
5
9
5.04
129
112
51⁄2
10
5.59
143
124
6
11
6.14
157
137
7
13
7.23
186
162
8
15
8.32
214
186
3⁄ × 4 3⁄ × 4 3⁄ × 4 3⁄ × 4
5
8
6.50
165
143
6
9
7.31
185
161
7
10
8.13
206
179
8
11
9.70
227
197
7⁄ × 8 7⁄ × 8 7⁄ × 8 7⁄ × 8
5
7
7.50
190
165
6
8
8.56
217
188
7
9
9.63
244
212
8
10
271
236
9
3.16
81.8
71.2
41⁄2
10
3.82
90.9
79.1
5
12
4.16
109
51⁄2
13
4.50
118
103
6
14
4.85
127
111
7
16
5.85
145
126
10.7
85.8 100
94.9
74.6 87.1 99.5
Source: Rope diagram, Bethlehem Steel Co.; all data, U.S. Simplified Practice Recommendation 198–50.
Safe Working Loads and Factors of Safety.—The maximum load for which a wire rope is to be used should take into account such associated factors as friction, load caused by bending around each sheave, acceleration and deceleration, and, if a long length of rope is to be used for hoisting, the weight of the rope at its maximum extension. The condition of the rope — whether new or old, worn or corroded — and type of attachments should also be considered. Factors of safety for standing rope usually range from 3 to 4; for operating rope, from 5 to 12. Where there is the element of hazard to life or property, higher values are used.
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Machinery's Handbook 27th Edition 378
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Installing Wire Rope.—The main precaution to be taken in removing and installing wire rope is to avoid kinking which greatly lessens the strength and useful life. Thus, it is preferable when removing wire rope from the reel to have the reel with its axis in a horizontal position and, if possible, mounted so that it will revolve and the wire rope can be taken off straight. If the rope is in a coil, it should be unwound with the coil in a vertical position as by rolling the coil along the ground. Where a drum is to be used, the rope should be run directly onto it from the reel, taking care to see that it is not bent around the drum in a direction opposite to that on the reel, thus causing it to be subject to reverse bending. On flat or smooth-faced drums it is important that the rope be started from the proper end of the drum. A right lay rope that is being overwound on the drum, that is, it passes over the top of the drum as it is wound on, should be started from the right flange of the drum (looking at the drum from the side that the rope is to come) and a left lay rope from the left flange. When the rope is under wound on the drum, a right lay rope should be started from the left flange and a left lay rope from the right flange, so that the rope will spool evenly and the turns will lie snugly together.
Sheaves and drums should be properly aligned to prevent undue wear. The proper position of the main or lead sheave for the rope as it comes off the drum is governed by what is called the fleet angle or angle between the rope as it stretches from drum to sheave and an imaginary center-line passing through the center of the sheave groove and a point halfway between the ends of the drum. When the rope is at one end of the drum, this angle should not exceed one and a half to two degrees. With the lead sheave mounted with its groove on this center-line, a safe fleet angle is obtained by allowing 30 feet of lead for each two feet of drum width. Sheave and Drum Dimensions: Sheaves and drums should be as large as possible to obtain maximum rope life. However, factors such as the need for lightweight equipment for easy transport and use at high speeds, may call for relatively small sheaves with consequent sacrifice in rope life in the interest of overall economy. No hard and fast rules can be laid down for any particular rope if the utmost in economical performance is to be obtained. Where maximum rope life is of prime importance, the following recommendations of Federal Specification RR-R-571a for minimum sheave or drum diameters D in terms of rope diameter d will be of interest. For 6 × 7 rope (six strands of 7 wires each) D = 72d; for 6 × 19 rope, D = 45d; for 6 × 25 rope, D = 45d; for 6 × 29 rope, D = 30d; for 6 × 37 rope, D = 27d; and for 8 × 19 rope, D = 31d. Too small a groove for the rope it is to carry will prevent proper seating of the rope in the bottom of the groove and result in uneven distribution of load on the rope. Too large a groove will not give the rope sufficient side support. Federal Specification RR-R-571a recommends that sheave groove diameters be larger than the nominal rope diameters by the following minimum amounts: For ropes of 1⁄4- to 5⁄16-inch diameters, 1⁄64 inch larger; for 3⁄8- to 3⁄ -inch diameter ropes, 1⁄ inch larger; for 13⁄ - to 11⁄ -inch diameter ropes, 3⁄ inch larger; for 4 32 16 8 64 13⁄16- to 11⁄2-inch ropes, 1⁄16 inch larger; for 19⁄16- to 21⁄4-inch ropes, 3⁄32 inch larger; and for 25⁄16 and larger diameter ropes, 1⁄8 inch larger. For new or regrooved sheaves these values should be doubled; in other words for 1⁄4- to 5⁄16-inch diameter ropes, the groove diameter should be 1⁄ inch larger, and so on. 32
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Drum or Reel Capacity: The length of wire rope, in feet, that can be spooled onto a drum or reel, is computed by the following formula, where A =depth of rope space on drum, inches: A = (H − D − 2Y) ÷ 2 B =width between drum flanges, inches D =diameter of drum barrel, inches H =diameter of drum flanges, inches K =factor from Table 8 for size of line selected Y =depth not filled on drum or reel where winding is to be less than full capacity L =length of wire rope on drum or reel, feet: L = ( A + D ) × A × B × K Table 8. Factors K Used in Calculating Wire Rope Drum and Reel Capacities Rope Dia., In. 3⁄ 32 1⁄ 8 9⁄ 64 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16
Factor K 23.4 13.6 10.8 8.72 6.14 4.59 3.29
Rope Dia., In.
Factor K
Rope Dia., In.
Factor K
1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8
0.925
13⁄8
0.127
0.741
11⁄2
0.107
0.607
15⁄8
0.0886
0.506
0.0770
0.428
13⁄4 17⁄8
0.354
2
0.0597
0.308
21⁄8
0.0532
0.0675
2.21
1
0.239
21⁄4
0.0476
1.58
11⁄8
0.191
23⁄8
0.0419
1.19
11⁄4
0.152
21⁄2
0.0380
Note: The values of “K” allow for normal oversize of ropes, and the fact that it is practically impossible to “thread-wind” ropes of small diameter. However, the formula is based on uniform rope winding and will not give correct figures if rope is wound non-uniformly on the reel. The amount of tension applied when spooling the rope will also affect the length. The formula is based on the same number of wraps of rope in each layer, which is not strictly correct, but does not result in appreciable error unless the width (B) of the reel is quite small compared with the flange diameter (H).
Example:Find the length in feet of 9⁄16-inch diameter rope required to fill a drum having the following dimensions: B = 24 inches, D = 18 inches, H = 30 inches, A = ( 30 – 18 – 0 ) ÷ 2 = 6 inches L = ( 6 + 18 ) × 6 × 24 × 0.741 = 2560.0 or 2560 feet The above formula and factors K allow for normal oversize of ropes but will not give correct figures if rope is wound non-uniformly on the reel. Load Capacity of Sheave or Drum: To avoid excessive wear and groove corrugation, the radial pressure exerted by the wire rope on the sheave or drum must be kept within certain maximum limits. The radial pressure of the rope is a function of rope tension, rope diameter, and tread diameter of the sheave and can be determined by the following equation: 2T P = -----------D×d where P =Radial pressure in pounds per square inch (see Table 9) T =Rope tension in pounds D =Tread diameter of sheave or drum in inches d =Rope diameter in inches According to the Bethlehem Steel Co. the radial pressures shown in Table 9 are recommended as maximums according to the material of which the sheave or drum is made.
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Machinery's Handbook 27th Edition 380
WIRE ROPE Table 9. Maximum Radial Pressures for Drums and Sheaves
Type of Wire Rope 6×7 6 × 19 6 × 37
Drum or Sheave Material Manganese Cast Cast Iron Steel Steela Recommended Maximum Radial Pressures, psi 300b
550b
1500b
500b 600
900b 1075
2500b 3000
Drum or Sheave Material Manganese Cast Cast Iron Steel Steela Recommended Maximum Radial Pressures, psi
Type of Wire Rope 6 × 8 Flattened Strand 6 × 25 Flattened Strand 6 × 30 Flattened Strand
450 800 800
850 1450 1450
2200 4000 4000
a 11 to 13 per cent manganese. b These values are for regular lay rope. Lang lay rope values may be increased by 15 per cent.
Minimum Sheave- and Drum-Groove Dimensions for Wire Rope Applications Nominal Rope Diameter 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 7⁄ 8
1 11⁄8 11⁄4 13⁄8 11⁄2
Groove Radius New 0.135 0.167 0.201 0.234 0.271 0.303 0.334 0.401 0.468 0.543 0.605 0.669 0.736 0.803
Worn 0.129 0.160 0.190 0.220 0.256 0.288 0.320 0.380 0.440 0.513 0.577 0.639 0.699 0.759
Nominal Rope Diameter 15⁄8 13⁄4 17⁄8 2 21⁄8 21⁄4 23⁄8 21⁄2 25⁄8 23⁄4 27⁄8 3 31⁄8 31⁄4
Groove Radius New 0.876 0.939 1.003 1.085 1.137 1.210 1.271 1.338 1.404 1.481 1.544 1.607 1.664 1.731
Worn 0.833 0.897 0.959 1.025 1.079 1.153 1.199 1.279 1.339 1.409 1.473 1.538 1.598 1.658
Nominal Rope Diameter 33⁄8 31⁄2 33⁄4 4 41⁄4 41⁄2 43⁄4 5 51⁄4 51⁄2 53⁄4 6
Groove Radius New 1.807 1.869 1.997 2.139 2.264 2.396 2.534 2.663 2.804 2.929 3.074 3.198
Worn 1.730 1.794 1.918 2.050 2.178 2.298 2.434 2.557 2.691 2.817 2.947 3.075
All dimensions in inches. Data taken from Wire Rope Users Manual, 2nd ed., American Iron and Steel Institute, Washington, D. C. The values given in this table are applicable to grooves in sheaves and drums but are not generally suitable for pitch design, since other factors may be involved.
Rope Loads due to Bending: When a wire rope is bent around a sheave, the resulting bending stress sb in the outer wire, and equivalent bending load Pb (amount that direct tension load on rope is increased by bending) may be computed by the following formulas: sb = Edw ÷ D; Pb = sbA, where A = d2Q. E is the modulus of elasticity of the wire rope (varies with the type and condition of rope from 10,000,000 to 14,000,000. An average value of 12,000,000 is frequently used), d is the diameter of the wire rope, dw is the diameter of the component wire (for 6 × 7 rope, dw = 0.106d; for 6 × 19 rope, 0.063d; for 6 × 37 rope, 0.045d; and for 8 × 19 rope, dw = 0.050d). D is the pitch diameter of the sheave in inches, A is the metal cross-sectional area of the rope, and Q is a constant, values for which are: 6 × 7 (Fiber Core) rope, 0.380; 6 × 7 (IWRC or WSC), 0.437; 6 × 19 (Fiber Core), 0.405; 6 × 19 (IWRC or WSC), 0.475; 6 × 37 (Fiber Core), 0.400; 6 × 37 (IWRC), 0.470; 8 × 19 (Fiber Core), 0.370; and Flattened Strand Rope, 0.440. Example:Find the bending stress and equivalent bending load due to the bending of a 6 × 19 (Fiber Core) wire rope of 1⁄2-inch diameter around a 24-inch pitch diameter sheave. 2
d w = 0.063 × 0.5 = 0.0315 in. A = 0.5 × 0.405 = 0.101 sq. in. s b = 12 ,000 ,000 × 0.0315 ÷ 24 = 15 ,750 lbs. per sq. in. P b = 15 ,750 × 0.101 = 1590 lbs.
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Machinery's Handbook 27th Edition WIRE ROPE
381
Cutting and Seizing of Wire Rope.—Wire rope can be cut with mechanical wire rope shears, an abrasive wheel, an electric resistance cutter (used for ropes of smaller diameter only), or an acetylene torch. This last method fuses the ends of the wires in the strands. It is important that the rope be seized on either side of where the cut is to be made. Any annealed low carbon steel wire may be used for seizing, the recommended sizes being as follows: For a wire rope of 1⁄4- to 15⁄16-inch diameter, use a seizing wire of 0.054-inch (No. 17 Steel Wire Gage); for a rope of 1- to 15⁄8-inch diameter, use a 0.105-inch wire (No. 12); and for rope of 13⁄4- to 31⁄2-inch diameter, use a 0.135-inch wire (No. 10). Except for preformed wire ropes, a minimum of two seizings on either side of a cut is recommended. Four seizings should be used on either side of a cut for Lang lay rope, a rope with a steel core, or a nonspinning type of rope. The following method of seizing is given in Federal Specification for wire rope, RR-R571a. Lay one end of the seizing wire in the groove between two strands of wire rope and wrap the other end tightly in a close helix over the portion in the groove. A seizing iron (round bar 1⁄2 to 5⁄8 inch diameter by 18 inches long) should be used to wrap the seizing tightly. This bar is placed at right angles to the rope next to the first turn or two of the seizing wire. The seizing wire is brought around the back of the seizing iron and wrapped loosely around the wire rope in the opposite direction to that of the seizing coil. As the seizing iron is now rotated around the rope it will carry the seizing wire snugly and tightly into place. When completed, both ends of the seizing should be twisted together tightly. Maintenance of Wire Rope.—Heavy abrasion, overloading, and bending around sheaves or drums that are too small in diameter are the principal reasons for the rapid deterioration of wire rope. Wire rope in use should be inspected periodically for evidence of wear and damage by corrosion. Such inspections should take place at progressively shorter intervals over the useful life of the rope as wear tends to accelerate with use. Where wear is rapid, the outside of a wire rope will show flattened surfaces in a short time. If there is any hazard involved in the use of the rope, it may be prudent to estimate the remaining strength and service life. This assessment should be done for the weakest point where the most wear or largest number of broken wires are in evidence. One way to arrive at a conclusion is to set an arbitrary number of broken wires in a given strand as an indication that the rope should be removed from service and an ultimate strength test run on the worn sample. The arbitrary figure can then be revised and rechecked until a practical working formula is arrived at. A piece of waste rubbed along the wire rope will help to reveal broken wires. The effects of corrosion are not easy to detect because the exterior wires may appear to be only slightly rusty, and the damaging effects of corrosion may be confined to the hidden inner wires where it cannot be seen. To prevent damage by corrosion, the rope should be kept well lubricated. Use of zinc coated wire rope may be indicated for some applications. Periodic cleaning of wire rope by using a stiff brush and kerosene or with compressed air or live steam and relubricating will help to lengthen rope life and reduce abrasion and wear on sheaves and drums. Before storing after use, wire rope should be cleaned and lubricated. Lubrication of Wire Rope.—Although wire rope is thoroughly lubricated during manufacture to protect it against corrosion and to reduce friction and wear, this lubrication should be supplemented from time to time. Special lubricants are supplied by wire rope manufacturers. These lubricants vary somewhat with the type of rope application and operating condition. Where the preferred lubricant can not be obtained from the wire rope manufacturer, an adhesive type of lubricant similar to that used for open gearing will often be found suitable. At normal temperatures, some wire rope lubricants may be practically solid and will require thinning before application. Thinning may be done by heating to 160 to 200 degrees F. or by diluting with gasoline or some other fluid that will allow the lubricant to penetrate the rope. The lubricant may be painted on the rope or the rope may be passed through a box or tank filled with the lubricant.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 382
WIRE ROPE
Replacement of Wire Rope.—When an old wire rope is to be replaced, all drums and sheaves should be examined for wear. All evidence of scoring or imprinting of grooves from previous use should be removed and sheaves with flat spots, defective bearings, and broken flanges, should be repaired or replaced. It will frequently be found that the area of maximum wear is located relatively near one end of the rope. By cutting off that portion, the remainder of the rope may be salvaged for continued use. Sometimes the life of a rope can be increased by simply changing it end for end at about one-half the estimated normal life. The worn sections will then no longer come at the points that cause the greatest wear. Wire Rope Slings and Fittings Slings.—A few of the simpler sling arrangements or hitches as they are called, are shown in the accompanying illustration. Normally 6 × 19 Class wire rope is recommended where a diameter in the 1⁄4-inch to 11⁄8-inch range is to be used and 6 × 37 Class wire rope where a diameter in the 11⁄4-inch and larger range is to be used. However, the 6 × 19 Class may be used even in the larger sizes if resistance to abrasion is of primary importance and the 6 × 37 Class in the smaller sizes if greater flexibility is desired. The straight lift hitch, Fig. 7a, is a straight connector between crane hook and load. The basket hitch may be used with two hooks so that the sides are vertical as shown at Fig. 7b or with a single hook with sides at various angles with the vertical as shown at Fig. 7c, Fig. 7d, and Fig. 7e. As the angle with the vertical increases, a greater tension is placed on the rope so that for any given load, a sling of greater lifting capacity must be used. The choker hitch, shown at Fig. 7f, is widely used for lifting bundles of items such as bars, poles, pipe, and similar objects. The choker hitch holds these items firmly, but the load must be balanced so that it rides safely. Since additional stress is imposed on the rope due to the choking action, the capacity of this type of hitch is 25 per cent less than that of the comparable straight lift. If two choker hitches are used at an angle, these angles must also be taken into consideration as with the basket hitches. Wire Rope Fittings.—Many varieties of swaged fittings are available for use with wire rope and several industrial and aircraft types are shown in the accompanying illustration. Swaged fittings on wire rope have an efficiency (ability to hold the wire rope) of approximately 100 per cent of the catalogue rope strength. These fittings are attached to the end or body of the wire rope by the application of high pressure through special dies that cause the material of the fitting to “flow” around the wires and strands of the rope to form a union that is as strong as the rope itself. The more commonly used types, of swaged fittings range from 1⁄8- to 5⁄8-inch diameter sizes in industrial types and from the 1⁄16- to 5⁄8-inch sizes in aircraft types. These fittings are furnished attached to the wire strand, rope, or cable. Applying Clips and Attaching Sockets.—In attaching U-bolt clips for fastening the end of a wire rope to form a loop, it is essential that the saddle or base of the clip bears against the longer or “live” end of the rope loop and the U-bolt against the shorter or “dead” end. The “U” of the clips should never bear against the live end of the rope because the rope may be cut or kinked. A wire-rope thimble should be used in the loop eye of the rope to prevent kinking when rope clips are used. The strength of a clip fastening is usually less than 80 percent of the strength of the rope. Table 10 gives the proper size, number, and spacing for each size of wire rope. In attaching commercial sockets of forged steel to wire rope ends, the following procedure is recommended. The wire rope is seized at the end and another seizing is applied at a distance from the end equal to the length of the basket of the socket. As explained in a previous section, soft iron wire is used and particularly for the larger sizes of wire rope, it is important to use a seizing iron to secure a tight winding. For large ropes, the seizing should be several inches long.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition WIRE ROPE
383
Wire Rope Slings and Fittings
Fig. 7a. Straight Lift One leg vertical Load capacity is 100% of a single rope.
Fig. 7b. Basket Hitch Two legs vertical Load capacity is 200% of the single rope in Fig. 7a.
Fig. 7d. Basket Hitch Fig. 7e. Basket Hitch Two legs at 45° with the vertical Two legs at 60° with the vertical Load capacity is 141% of Load capacity is 100% of the single rope in Fig. 7a. the single rope in Fig. 7a.
Fig. 7c. Basket Hitch Two legs at 30° with the vertical Load capacity is 174% of the single rope in Fig. 7a.
Fig. 7f. Choker Hitch One leg vertical, with slipthrough loop Rated capacity is 75% of the single rope in Fig. 7a.
The end seizing is now removed and the strands are separated so that the fiber core can be cut back to the next seizing. The individual wires are then untwisted and “broomed out” and for the distance they are to be inserted in the socket are carefully cleaned with benzine, naphtha, or unleaded gasoline. The wires are then dipped into commercial muriatic (hydrochloric) acid and left (usually one to three minutes) until the wires are bright and clean or, if zinc coated, until the zinc is removed. After cleaning, the wires are dipped into a hot soda solution (1 pound of soda to 4 gallons of water at 175 degrees F. minimum) to neutralize the acid. The rope is now placed in a vise. A temporary seizing is used to hold the wire ends
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
A
Vertical B C
A
Independent Wire Rope Core Choker 60° Bridle 45°Bridle B C A B C A B C
Copyright 2004, Industrial Press, Inc., New York, NY
WIRE ROPE
Fiber Core 30°Bridle Vertical Choker 60° Bridle 45° Bridle 30° Bridle A B C A B C A B C A B C A B C A B C Single Leg, 6 × 19 Wire Rope 1⁄ 0.59 0.56 0.53 0.44 0.42 0.40 … … … … … … … … … 0.55 0.51 0.49 0.41 0.38 0.37 … … … … … … … … … 4 3⁄ 1.3 1.2 1.1 0.98 0.93 0.86 … … … … … … … … … 1.2 1.1 1.1 0.91 0.85 0.80 … … … … … … … … … 8 1⁄ 2.3 2.2 2.0 1.7 1.6 1.5 … … … … … … … … … 2.1 2.0 1.8 1.6 1.5 1.4 … … … … … … … … … 2 5⁄ 3.6 3.4 3.0 2.7 2.5 2.2 … … … … … … … … … 3.3 3.1 2.8 2.5 2.3 2.1 … … … … … … … … … 8 3⁄ 5.1 4.9 4.2 3.8 3.6 3.1 … … … … … … … … … 4.8 4.4 3.9 3.6 3.3 2.9 … … … … … … … … … 4 7⁄ 6.9 6.6 5.5 5.2 4.9 4.1 … … … … … … … … … 6.4 5.9 5.1 4.8 4.5 3.9 … … … … … … … … … 8 1 9.0 8.5 7.2 6.7 6.4 5.4 … … … … … … … … … 8.4 7.7 6.7 6.3 5.8 5.0 … … … … … … … … … 1 1 ⁄8 11 10 9.0 8.5 7.8 6.8 … … … … … … … … … 10 9.5 8.4 7.9 7.1 6.3 … … … … … … … … … Single Leg, 6 × 37 Wire Rope 11⁄4 13 12 10 9.9 9.2 7.9 … … … … … … … … … 12 11 9.8 9.2 8.3 7.4 … … … … … … … … … 13⁄8 16 15 13 12 11 9.6 … … … … … … … … … 15 13 12 11 10 8.9 … … … … … … … … … 11⁄2 19 17 15 14 13 11 … … … … … … … … … 17 16 14 13 12 10 … … … … … … … … … 3 1 ⁄4 26 24 20 19 18 15 … … … … … … … … … 24 21 19 18 16 14 … … … … … … … … … 2 33 30 26 25 23 20 … … … … … … … … … 31 28 25 23 21 18 … … … … … … … … … 21⁄4 41 38 33 31 29 25 … … … … … … … … … … … … … … … … … … … … … … … … Two-Leg Bridle or Basket Hitch, 6 × 19 Wire Rope Sling 1⁄ 1.2 1.1 1.0 … … … 1.0 0.97 0.92 0.83 0.79 0.75 0.59 0.56 0.53 1.1 1.0 0.99 … … … 0.95 0.88 0.85 0.77 0.72 0.70 0.55 0.51 0.49 4 3⁄ 2.0 2.5 2.3 … … … 2.3 2.1 2.0 1.8 1.8 1.8 1.3 1.2 1.1 2.4 2.2 2.1 … … … 2.1 1.9 1.8 1.7 1.6 1.5 1.2 1.1 1.1 8 1⁄ 4.0 4.4 3.9 … … … 4.0 3.6 3.4 3.2 3.1 2.8 2.3 2.2 2.0 4.3 3.9 3.7 … … … 3.7 3.4 3.2 3.0 2.8 2.6 2.1 2.0 1.8 2 5⁄ 7.2 6.6 6.0 … … … 6.2 5.9 5.2 5.1 4.8 4.2 3.6 3.4 3.0 6.7 6.2 5.6 … … … 6.2 5.3 4.8 4.7 4.4 4.0 3.3 3.1 2.8 8 3⁄ 10 9.7 8.4 … … … 8.9 8.4 7.3 7.2 6.9 5.9 5.1 4.9 4.2 9.5 8.8 7.8 … … … 8.2 7.6 6.8 6.7 6.2 5.5 4.8 4.4 3.9 4 7⁄ 14 13 11 … … … 12 11 9.6 9.8 9.3 7.8 6.9 6.6 5.5 13 12 10 … … … 11 10 8.9 9.1 8.4 7.3 6.4 5.9 5.1 8 1 18 17 14 … … … 15 15 12 13 12 10 9.0 8.5 7.2 17 15 13 … … … 14 13 11 12 11 9.4 8.4 7.7 6.7 1 1 ⁄8 23 21 18 … … … 19 18 16 16 15 13 11 10 9.0 21 19 17 … … … 18 16 14 15 13 12 10 9.5 8.4 Two-Leg Bridle or Basket Hitch, 6 × 37 Wire Rope Sling 11⁄4 26 24 21 … … … 23 21 18 19 17 15 13 12 10 25 22 20 … … … 21 19 17 17 16 14 12 11 9.8 13⁄8 32 29 25 … … … 28 25 22 22 21 18 16 15 13 30 27 24 … … … 26 23 20 21 19 17 15 13 12 1 1 ⁄2 38 35 30 … … … 33 30 26 27 25 21 19 17 15 35 32 28 … … … 30 27 24 25 22 20 17 16 14 3 1 ⁄4 51 47 41 … … … 44 41 35 36 33 29 26 24 20 46 43 39 … … … 41 37 33 34 30 27 24 21 19 2 66 61 53 … … … 57 53 46 47 43 37 33 30 26 62 55 49 … … … 53 43 43 43 39 35 31 26 25 21⁄4 83 76 66 … … … 72 66 67 58 54 47 41 38 33 … … … … … … … … … … … … … … … A–socket or swaged terminal attachment; B–mechanical sleeve attachment; C–hand-tucked splice attachment. Data from Longshoring Industry, OSHA Safety and Health Standards Digest, OSHA 2232, 1985.
Dia. (in.)
384
Rated Capacities for Improved Plow Steel Wire Rope and Wire Rope Slings (in tons of 2,000 lbs)
Machinery's Handbook 27th Edition WIRE ROPE
385
Industrial Types
Round Eye
Rod Eye
Clevis
Hoist-Hook
Button-Stop
Threaded Stud
Swaged Closed Socket Swaged Open Socket Aircraft Types
Double-Shank Ball
Single-Shank Ball
Fork
Eye
Strap-Fork
Strap-Eye
Wire Rope Fittings
together until the socket is placed over the rope end. The temporary seizing is then removed and the socket located so that the ends of the wires are about even with the upper end of the basket. The opening around the rope at the bottom of the socket is now sealed with putty. Table 10. Clips Required for Fastening Wire Rope End Rope Dia., In.
U-Bolt Dia., In.
3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8
11⁄ 32 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4
Min. No. of Clips 2 2 2 2 2 3 3
Clip Spacing, In. 3 31⁄4 31⁄4 4 41⁄2 5 53⁄4
Rope Dia., In.
U-Bolt Dia., In.
3⁄ 4 7⁄ 8
7⁄ 8
1
11⁄8 11⁄4 17⁄16 11⁄2 123⁄32
11⁄8 11⁄4 13⁄8 11⁄2
1
Min. No. of Clips 4 4 4 5 5 6 6
Clip Spacing, In.
Rope Dia., In.
U-Bolt Dia., In.
63⁄4 8
15⁄8 13⁄4 2
13⁄4 115⁄16 21⁄8 25⁄8 27⁄8 … …
83⁄4 93⁄4 103⁄4 111⁄2 121⁄2
21⁄4 21⁄2 … …
Min. No. of Clips 6 7 8 8 8 … …
Clip Spacing, In. 131⁄4 141⁄2 161⁄2 161⁄2 173⁄4 … …
A special high grade pure zinc is used to fill the socket. Babbit metal should not be used as it will not hold properly. For proper fluidity and penetration, the zinc is heated to a tem-
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 386
CRANE CHAIN AND HOOKS
perature in the 830- to 900-degree F. range. If a pyrometer is not available to measure the temperature of the molten zinc, a dry soft pine stick dipped into the zinc and quickly withdrawn will show only a slight discoloration and no zinc will adhere to it. If the wood chars, the zinc is too hot. The socket is now permitted to cool and the resulting joint is ready for use. When properly prepared, the strength of the joint should be approximately equal to that of the rope itself. Crane Chain and Hooks Material for Crane Chains.—The best material for crane and hoisting chains is a good grade of wrought iron, in which the percentage of phosphorus, sulfur, silicon, and other impurities is comparatively low. The tensile strength of the best grades of wrought iron does not exceed 46,000 pounds per square inch, whereas mild steel with about 0.15 per cent carbon has a tensile strength nearly double this amount. The ductility and toughness of wrought iron, however, is greater than that of ordinary commercial steel, and for this reason it is preferable for chains subjected to heavy intermittent strains, because wrought iron will always give warning by bending or stretching, before breaking. Another important reason for using wrought iron in preference to steel is that a perfect weld can be effected more easily. Heat-treated alloy steel is also widely used for chains. This steel contains carbon, 0.30 per cent, max; phosphorus, 0.045 per cent, max; and sulfur, 0.045 per cent, max. The selection and amounts of alloying elements are left to the individual manufacturers. Strength of Chains.—When calculating the strength of chains it should be observed that the strength of a link subjected to tensile stresses is not equal to twice the strength of an iron bar of the same diameter as the link stock, but is a certain amount less, owing to the bending action caused by the manner in which the load is applied to the link. The strength is also reduced somewhat by the weld. The following empirical formula is commonly used for calculating the breaking load, in pounds, of wrought-iron crane chains: W = 54 ,000D 2 in which W = breaking load in pounds and D = diameter of bar (in inches) from which links are made. The working load for chains should not exceed one-third the value of W, and, it is often one-fourth or one-fifth of the breaking load. When a chain is wound around a casting and severe bending stresses are introduced, a greater factor of safety should be used. Care of Hoisting and Crane Chains.—Chains used for hoisting heavy loads are subject to deterioration, both apparent and invisible. The links wear, and repeated loading causes localized deformations to form cracks that spread until the links fail. Chain wear can be reduced by occasional lubrication. The life of a wrought-iron chain can be prolonged by frequent annealing or normalizing unless it has been so highly or frequently stressed that small cracks have formed. If this condition is present, annealing or normalizing will not “heal” the material, and the links will eventually fracture. To anneal a wrought-iron chain, heat it to cherry-red and allow it to cool slowly. Annealing should be done every six months, and oftener if the chain is subjected to unusually severe service. Maximum Allowable Wear at Any Point of Link Chain Size (in.) 1⁄ (9⁄ ) 4 32 3⁄ 8 1⁄ 2 5⁄ 8
Maximum Allowable Wear (in.) 3⁄ 64 5⁄ 64 7⁄ 64 9⁄ 64
Chain Size (in.)
Maximum Allowable Wear (in.)
3⁄ 4 7⁄ 8
1 11⁄8
5⁄ 32 11⁄ 64 3⁄ 16 7⁄ 32
Chain Size (in.) 11⁄4 13⁄8 11⁄2 13⁄4
Maximum Allowable Wear (in.) 1⁄ 4 3⁄ 32 5⁄ 16 11⁄ 32
Source: Longshoring Industry, OSHA 2232, 1985.
Chains should be examined periodically for twists, as a twisted chain will wear rapidly. Any links that have worn excessively should be replaced with new ones, so that every link will do its full share of work during the life of the chain, without exceeding the limit of
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SAFE WORKING LOAD FOR ROPE AND CHAIN
387
safety. Chains for hoisting purposes should be made with short links, so that they will wrap closely around the sheaves or drums without bending. The diameter of the winding drums should be not less than 25 or 30 times the diameter of the iron used for the links. The accompanying table lists the maximum allowable wear for various sizes of chains. Safe Loads for Ropes and Chains.—Safe loads recommended for wire rope or chain slings depend not only upon the strength of the sling but also upon the method of applying it to the load, as shown by the accompanying table giving safe loads as prepared by OSHA. The loads recommended in this table are more conservative than those usually specified, in order to provide ample allowance for some unobserved weakness in the sling, or the possibility of excessive strains due to misjudgment or accident. Safe Working Loads in Pounds for Manila Rope and Chains
1 11⁄16 11⁄8 11⁄4 15⁄16 13⁄8 11⁄2 15⁄8 13⁄4 17⁄8 2 21⁄8
3240 204 1835 … 346 2865 6600 467 4200 … 605 5600 … 775 … 11,240 915 7400 … 1190 9200 16,500 1520 11,400 23,000 1870 16,600 … 2250 … 28,600 2660 22,400 38,600 3120 29,400 … 3400 … 44,400 4200 34,600 57,400 4600 42,600 … 5200 … 67,000 … 51,800 79,400 6200 61,600 85,000 7800 72,400 95,800 9000 84,000 … … 95,800 … 10,800 109,600 … 12,400 …
Sling at 30°
5640 170 … 282 11,400 380 … 493 … 635 19,500 798 … 973 28,500 1240 39,800 1520 … 1830 49,800 2170 67,000 2540 … 2800 77,000 3400 99,400 3800 … 4200 116,000 … 137,000 5000 147,000 6400 163,000 7400 … … … 8800 … 10,200
1500 4540 120 1060 2340 … 200 1655 3370 9300 270 2385 4600 … 350 3250 … … 450 … 6000 15,800 530 4200 7600 … 690 5400 9400 23,300 880 6600 13,400 32,400 1080 9600 … … 1300 … 18,400 40,600 1540 13,000 24,000 54,600 1800 17,000 … … 2000 … 28,400 63,000 2400 20,000 35,000 81,000 2700 24,800 … … 3000 … 42,200 94,000 … 30,000 50,400 112,000 3600 35,600 59,000 119,000 4500 41,800 68,600 124,000 5200 48,400 78,200 … … 55,200 89,600 … 6200 63,200 … … 7200 …
Alloy Steel
Crane Chain Manila Rope
Alloy Steel
Wrought Iron
Crane Chain Manila Rope
Alloy Steel
Wrought Iron
Manila Rope
1060 1655 2385 3250 … 4200 5400 6600 9600 … 13,000 17,000 … 20,000 24,800 … 30,000 35,600 41,800 48,400 55,200 63,200 …
Alloy Steel
120 200 270 350 450 530 690 880 1080 1300 1540 1800 2000 2400 2700 3000 … 3600 4500 5200 … 6200 7200
Sling at 45°
Crane Chain
Wrought Iron
Sling at 60°
Crane Chain Wrought Iron
1⁄ a 4 5⁄ a 16 3⁄ 8 7⁄ a 16 15⁄ 32 1⁄ 2 9⁄ a 16 5⁄ 8 3⁄ 4 13⁄ 16 7⁄ 8
Rope or Chain Vertical
Manila Rope
Diameter of Rope, or Chain Link, Inch
3240 … 6600 … … 11,240 … 16,500 23,000 … 28,600 38,600 … 44,400 57,400 … 67,000 79,400 85,000 95,800 … … …
a These sizes of wrought chain are no longer manufactured in the United States.
Data from Longshoring Industry, OSHA Safety and Health Standards Digest, OSHA 2232, 1985.
The working load limit is defined as the maximum load in pounds that should ever be applied to chain, when the chain is new or in “as new” condition, and when the load is uniformly applied in direct tension to a straight length of chain. This limit is also affected by the number of chains used and their configuration. The accompanying table shows the working load limit for various configurations of heat-treated alloy steel chain using a 4 to 1 design factor, which conforms to ISO practice.
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Machinery's Handbook 27th Edition 388
STRENGTH OF ROPE Working Load Limit for Heat-Treated Alloy Steel Chain, pounds Single Leg
Double Leg
Triple and Quad Leg
Chain Size (in.) 1⁄ 4 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
3,600
6,200
5,050
3,600
9,300
7,600
5,400
6,400
11,000
9,000
6,400
16,550
13,500
9,500
11,400
19,700
16,100
11,400
29,600
24,200
17,100
17,800
30,800
25,150
17,800
46,250
37,750
26,700
25,650
44,400
36,250
25,650
66,650
54,400
38,450
34,900
60,400
49,300
34,900
90,650
74,000
52,350
Source: The Crosby Group.
Protection from Sharp Corners: When the load to be lifted has sharp corners or edges, as are often encountered with castings, and with structural steel and other similar objects, pads or wooden protective pieces should be applied at the corners, to prevent the slings from being abraded or otherwise damaged where they come in contact with the load. These precautions are especially important when the slings consist of wire cable or fiber rope, although they should also be used even when slings are made of chain. Wooden cornerpieces are often provided for use in hoisting loads with sharp angles. If pads of burlap or other soft material are used, they should be thick and heavy enough to sustain the pressure, and distribute it over a considerable area, instead of allowing it to be concentrated directly at the edges of the part to be lifted. Strength of Manila Rope
Dia. (in.) 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 13⁄ 16 7⁄ 8
1 11⁄16 11⁄8 11⁄4
Circumference (in.) 5⁄ 8 3⁄ 4
1 11⁄8 11⁄4 11⁄2 13⁄4 2 21⁄4 21⁄2 23⁄4 3 31⁄4 31⁄2 33⁄4
Weight of 100 feet of Ropea (lb)
New Rope Tensile Strengthb (lb)
Working Loadc (lb)
1.50 2.00 2.90 4.10 5.25 7.50 10.4 13.3 16.7 19.5 22.4 27.0 31.2 36.0 41.6
406 540 900 1220 1580 2380 3100 3960 4860 5850 6950 8100 9450 10,800 12,200
41 54 90 122 176 264 388 496 695 835 995 1160 1350 1540 1740
Dia. (in.)
Circumference (in.)
Weight of 100 feet of Ropea (lb)
New Rope Tensile Strengthb (lb)
Working Loadc (lb)
15⁄16 11⁄2 15⁄8 13⁄4 2 21⁄8 21⁄4 21⁄2 25⁄8 27⁄8 3 31⁄4 31⁄2 4 …
4 41⁄2 5 51⁄2 6 61⁄2 7 71⁄2 8 81⁄2 9 10 11 12 …
47.8 60.0 74.5 89.5 108 125 146 167 191 215 242 298 366 434 …
13,500 16,700 20,200 23,800 28,000 32,400 37,000 41,800 46,800 52,000 57,500 69,500 82,000 94,500 …
1930 2380 2880 3400 4000 4620 5300 5950 6700 7450 8200 9950 11,700 13,500 …
a Average value is shown; maximum is 5 per cent higher. b Based on tests of new and unused rope of standard construction in accordance with Cordage Institute Standard Test Methods. c These values are for rope in good condition with appropriate splices, in noncritical applications, and under normal service conditions. These values should be reduced where life, limb, or valuable propety are involved, or for exceptional service conditions such as shock loads or sustained loads.
Data from Cordage Institute Rope Specifications for three-strand laid and eight-strand plaited manila rope (standard construction).
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STRENGTH OF ROPE
389
Strength of Nylon and Double Braided Nylon Rope
Dia. (in.) 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 13⁄ 16 7⁄ 8
Circumference (in.) 5⁄ 8 3⁄ 4
Weight of 100 feet of Ropea (lb)
New Rope Tensile Strengthb (lb)
Working Loadc (lb)
Dia. (in.)
Nylon Rope 75 15⁄16
Weight of 100 feet of Ropea (lb)
New Rope Tensile Strengtha (lb)
Working Loadc (lb)
4
45.0
38,800
4,320
55.0
47,800
5,320
66.5
58,500
6,500
83.0
70,000
7,800
95.0
83,000
9,200
Circumference (in.)
1.00
900
1.50
1,490
124
11⁄2
1
2.50
2,300
192
15⁄8
41⁄2 5
11⁄8
3.50
3,340
278
11⁄4
5.00
4,500
410
13⁄4 2
51⁄2 6
11⁄2
6.50
5,750
525
21⁄8
95,500
10,600
8.15
7,200
720
21⁄4
61⁄2 7
109
13⁄4 2
129
113,000
12,600
10.5
9,350
935
21⁄2
126,000
14,000
14.5
12,800
1,420
25⁄8
71⁄2 8
149
21⁄4
168
146,000
16,200
21⁄2
17.0
15,300
1,700
18,000
18,000
2,000
81⁄2 9
162,000
20.0
27⁄8 3
189 210
180,000
20,000
1
23⁄4 3
26.4
22,600
2,520
25,200
11⁄16
31⁄4
29.0
26,000
11⁄8
31⁄2
34.0
11⁄4
33⁄4
40.0
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 13⁄ 16 7⁄ 8
3⁄ 4 1
10
264
226,000
2,880
31⁄4 31⁄2
11
312
270,000
30,000
29,800
3,320
4
12
380
324,000
36,000
33,800
3,760
…
…
…
…
…
Double Braided Nylon Rope (Nylon Cover—Nylon Core) 1.56 1,650 150 4 43.1 15⁄16
44,700
5,590
2.44
2,570
234
13⁄8
41⁄4
47.3
49,000
6,130
11⁄8
3.52
3,700
336
11⁄2
56.3
58,300
7,290
15⁄16
4.79
5,020
502
15⁄8
41⁄2 5
66.0
68,300
8,540
51⁄2
11⁄2 13⁄4
6.25
6,550
655
13⁄4
79,200
9,900
7.91
8,270
919
2
6
100
103,000
12,900
9.77
61⁄2 7
113
117,000
14,600
127
131,000
18,700
71⁄2 8
156
161,000
23,000
172
177,000
25,300
225 264
231,000 271,000
33,000 38,700
76.6
10,200
1,130
21⁄8
21⁄4
14.1
14,700
1,840
21⁄4
21⁄2
16.5
17,200
2,150
21⁄2
19.1
19,900
2,490
1 11⁄16
23⁄4 3 31⁄4
25.0 28.2
26,000 29,300
3,250 3,660
25⁄8 3 31⁄4
9 10
11⁄8
31⁄2
31.6
32,800
4,100
329
338,000
48,300
33⁄4
39.1
40,600
5,080
31⁄2 4
11
11⁄4
12
400
410,000
58,600
2
a Average value is shown. Maximum for nylon rope is 5 per cent higher; tolerance for double braided nylon rope is ± 5 per cent. b Based on tests of new and unused rope of standard construction in accordance with Cordage Institute Standard Test Methods. For double braided nylon rope these values are minimums and are based on a large number of tests by various manufacturers; these values represent results two standard deviations below the mean. The minimum tensile strength is determined by the formula 1057 × (linear density)0.995. c These values are for rope in good condition with appropriate splices, in noncritical applications, and under normal service conditions. These values should be reduced where life, limb, or valuable property are involved, or for exceptional service conditions such as shock loads or sustained loads. Data from Cordage Institute Specifications for nylon rope (three-strand laid and eight-strand plaited, standard construction) and double braided nylon rope.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 390
CRANE CHAIN
Loads Lifted by Crane Chains.—To find the approximate weight a chain will lift when rove as a tackle, multiply the safe load given in the table Close-link Hoisting, Sling and Crane Chain by the number of parts or chains at the movable block, and subtract one-quarter for frictional resistance. To find the size of chain required for lifting a given weight, divide the weight by the number of chains at the movable block, and add one-third for friction; next find in the column headed “Average Safe Working Load” the corresponding load, and then the corresponding size of chain in the column headed “Size.” With the heavy chain or where the chain is unusually long, the weight of the chain itself should also be considered.
Close-link Hoisting, Sling and Crane Chain
Size 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
1 11⁄16 11⁄8 13⁄16 11⁄4 15⁄16 13⁄8 17⁄16 11⁄2 19⁄16 15⁄8 111⁄16 13⁄4 113⁄16 17⁄8 115⁄16 2 21⁄16 21⁄8 23⁄16 21⁄4 23⁄8 21⁄2 25⁄8 23⁄4 27⁄8 3
Standard Pitch, P Inches 25⁄ 32 27⁄ 32 31⁄ 32 15⁄32 111⁄32 115⁄32 123⁄32 113⁄16 115⁄16 21⁄16 23⁄16 27⁄16 21⁄2 25⁄8 23⁄4 31⁄16 31⁄8 33⁄8 39⁄16 311⁄16 37⁄8
Average Weight per Foot, Pounds
4 41⁄4 41⁄2 43⁄4
3⁄ 4 1 11⁄2 2 21⁄2 31⁄4 4 5 61⁄4 7 8 9 10 12 13 141⁄2 16 171⁄2 19 211⁄2 23 25 28 30 31
5 51⁄4 51⁄2 53⁄4 6 61⁄4 61⁄2 63⁄4 67⁄8 7 71⁄8 71⁄4 71⁄2 73⁄4
33 35 38 40 43 47 50 53 581⁄2 65 70 73 76 86
Outside Length, L Inches 15⁄16 11⁄2 13⁄4 21⁄16 23⁄8 25⁄8 3 31⁄4 31⁄2 33⁄4 4 43⁄8 45⁄8 47⁄8 51⁄8 59⁄16 53⁄4 61⁄8 67⁄16 611⁄16 7 73⁄8 73⁄4 81⁄8 81⁄2 87⁄8 91⁄4 95⁄8 10 103⁄8 103⁄4 111⁄8 111⁄2 117⁄8 121⁄4 125⁄8 13 131⁄2 14
Outside Width, W Inches 7⁄ 8 11⁄16 11⁄4 13⁄8 111⁄16 17⁄8 21⁄16 21⁄4 21⁄2 211⁄16 27⁄8 31⁄16 31⁄4 35⁄16 33⁄4 37⁄8 41⁄8 41⁄4 49⁄16 43⁄4 5 55⁄16 51⁄2 511⁄16 57⁄8 61⁄16 63⁄8 69⁄16 63⁄4 615⁄16 71⁄8 75⁄16 75⁄8 8 83⁄8 83⁄4 91⁄8 91⁄2 97⁄8
Average Safe Working Load, Pounds 1,200 1,700 2,500 3,500 4,500 5,500 6,700 8,100 10,000 10,500 12,000 13,500 15,200 17,200 19,500 22,000 23,700 26,000 28,500 30,500 33,500 35,500 38,500 39,500 41,500
Proof Test, Poundsa 2,500 3,500 5,000 7,000 9,000 11,000 14,000 17,000 20,000 23,000 26,000 29,000 32,000 35,000 40,000 46,000 51,000 54,000 58,000 62,000 67,000 70,500 77,000 79,000 83,000
44,500 47,500 50,500 54,000 57,500 61,000 64,500 68,200 76,000 84,200 90,500 96,700 103,000 109,000
89,000 95,000 101,000 108,000 115,000 122,000 129,000 136,500 152,000 168,500 181,000 193,500 206,000 218,000
a Chains tested to U.S. Government and American Bureau of Shipping requirements.
Copyright 2004, Industrial Press, Inc., New York, NY
Approximate Breaking Load, Pounds 5,000 7,000 10,000 14,000 18,000 22,000 27,000 32,500 40,000 42,000 48,000 54,000 61,000 69,000 78,000 88,000 95,000 104,000 114,000 122,000 134,000 142,000 154,000 158,000 166,000 178,000 190,000 202,000 216,000 230,000 244,000 258,000 273,000 304,000 337,000 362,000 387,000 412,000 436,000
Machinery's Handbook 27th Edition SPROCKET WHEELS AND WINDING DRUMS FOR CHAIN
391
Winding Drum Scores for Chain
Chain Size
A
3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
11⁄2 111⁄16 17⁄8 21⁄16 25⁄16 21⁄2 211⁄16 27⁄8 31⁄8 35⁄16 31⁄2
1
Chain Size
B
C
D
3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2
9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
3⁄ 16 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2 17⁄ 32 9⁄ 16
1 11⁄16 11⁄8 13⁄16
A
3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
11⁄4 17⁄16 19⁄16 13⁄4 17⁄8 21⁄16 23⁄16 23⁄8 21⁄2 211⁄16 213⁄16
1
B
C
11⁄ 32 3⁄ 8 7⁄ 16 15⁄ 32 17⁄ 32 9⁄ 16 5⁄ 8 21⁄ 32 23⁄ 32 3⁄ 4 13⁄ 16
3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2
D 1 11⁄8 11⁄4 13⁄8 11⁄2 15⁄8 13⁄4 17⁄8 2 21⁄8 21⁄4
All dimensions are in inches.
Sprocket Wheels for Ordinary Link Chains Size of Chain
3⁄ 16
1⁄ 4
5⁄ 16
3⁄ 8
7⁄
Length of Link
13⁄8
11⁄2
13⁄4
2
21⁄4
1
16
1⁄ 2
9⁄ 16
5⁄
8
11⁄ 16
3⁄ 4
13⁄ 16
7⁄ 8
21⁄2
27⁄8
31⁄4
31⁄2
33⁄4
4
41⁄4
15⁄
41⁄2
43⁄4 31⁄2
16
1
Width of Link
13⁄
13⁄16
13⁄8
19⁄16
13⁄4
115⁄16
21⁄8
25⁄16
21⁄2
211⁄16
3
31⁄4
X
1⁄
16
3⁄
32
3⁄
32
3⁄
32
3⁄
32
3⁄ 32
1⁄ 16
1⁄ 16
1⁄ 16
1⁄ 16
1⁄ 16
1⁄ 16
1⁄ 16
1⁄ 16
y
3⁄
32
3⁄
32
3⁄
32
3⁄
32
3⁄
32
1⁄ 16
1⁄ 16
1⁄ 16
1⁄ 16
1⁄ 16
1⁄ 16
1⁄ 16
1⁄ 16
…
10.14 11.56 12.98 14.40 15.83 17.26 18.68 20.06 21.54 22.97 24.40 25.83 27.26 28.69 30.12 31.55 32.97 34.41 35.84 37.27 38.70 40.04
10.71 12.20 13.72 15.21 16.71 18.20 19.72 21.23 22.74 24.24 25.75 27.26 28.77 30.28 31.79 33.30 34.81 36.32 37.83 39.34 40.85 …
11.27 12.85 14.43 16.01 17.55 19.17 20.76 22.35 23.93 25.52 27.11 28.70 30.29 31.88 33.46 35.04 36.63 38.23 39.82 41.41 … …
11.84 13.50 15.15 16.81 18.47 20.13 21.80 23.46 25.13 26.80 28.47 30.14 31.80 33.46 35.13 36.83 38.48 40.15 … … … …
12.40 14.13 15.87 17.61 19.35 21.09 22.84 24.58 26.33 28.08 29.83 31.57 33.31 35.06 36.81 38.56 40.30 … … … … …
No. of Angle α Teeth 7 12°51′ 8 11°15′ 9 10°0′ 10 9°0′ 11 8°11′ 12 7°30′ 13 6°55′ 14 6°25′ 15 6°0′ 16 5°37′ 17 5°17′ 18 5°0′ 19 4°44′ 20 4°30′ 21 4°17′ 22 4°6′ 23 3°55′ 24 3°45′ 25 3°36′ 26 3°28′ 27 3°20′ 28 3°13′
16
D = Pitch Diameter in Inches 4.50 5.13 5.76 6.40 7.03 7.66 8.29 8.93 9.57 10.20 10.84 11.47 12.11 12.75 13.38 14.02 14.66 15.29 15.93 16.56 17.20 17.84
4.50 5.13 5.76 6.40 7.03 7.66 8.29 8.93 9.57 10.20 10.84 11.47 12.11 12.75 13.38 14.02 14.66 15.29 15.93 16.56 17.20 17.84
5.06 5.77 6.48 7.18 7.91 8.62 9.33 10.05 10.76 11.47 12.19 12.91 13.62 14.34 15.05 15.77 16.49 17.20 17.92 18.62 19.34 20.06
5.63 6.42 7.21 8.00 8.79 9.59 10.38 11.17 11.96 12.76 13.56 14.36 15.16 15.96 16.74 17.53 18.32 19.11 19.90 20.70 21.50 22.29
6.18 7.06 7.74 8.79 9.67 10.53 11.41 12.28 13.16 14.03 14.90 15.78 16.65 17.53 18.40 19.27 20.15 21.02 21.90 22.77 23.65 24.52
6.76 7.71 8.65 9.61 10.55 11.49 12.45 13.40 14.35 15.30 16.26 17.21 18.16 19.12 20.07 21.03 21.98 22.94 23.89 24.85 25.80 26.75
7.88 8.97 10.08 11.19 12.30 13.41 14.52 15.63 16.74 17.85 18.97 20.08 21.19 22.30 23.42 24.53 25.64 26.76 27.87 28.98 30.10 31.21
9.01 10.27 11.53 12.80 14.07 15.33 16.60 17.90 19.14 20.41 21.68 22.95 24.22 25.50 26.77 28.03 29.31 30.58 31.85 33.13 34.40 35.67
9.58 10.91 12.26 13.61 14.95 16.29 17.65 18.99 20.34 21.69 23.04 24.34 25.73 27.09 28.44 29.79 31.14 32.49 33.84 35.20 36.55 37.90
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 392
HOOKS, SHACKLES, AND EYES Sprocket Wheels for Ordinary Link Chains (Continued)
Additional Tables Dimensions of Forged Round Pin, Screw Pin, and Bolt Type Chain Shackles and Bolt Type Anchor Shackles
Working Load Nominal Limit (tons) Shackle Size 1⁄ 2 3⁄ 4
1 11⁄2 2 31⁄4 43⁄4 61⁄2 81⁄2 91⁄2 12 131⁄2 17 25 35
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
1 11⁄8 11⁄4 13⁄8 11⁄2 13⁄4 2
A
B
C
D
7⁄ 8 11⁄32 11⁄4 17⁄16 15⁄8 2 23⁄8 213⁄16 33⁄16 39⁄16 315⁄16 43⁄8 413⁄16 53⁄4 63⁄4
15⁄ 16 17⁄ 32 21⁄ 32 23⁄ 32 13⁄ 16 11⁄16 11⁄4 17⁄16 111⁄16 113⁄16 21⁄32 21⁄4 23⁄8 27⁄8 31⁄4
5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
11⁄ 16 13⁄ 16 31⁄ 32 11⁄16 13⁄16 19⁄16 17⁄8 21⁄8 23⁄8 25⁄8
1 11⁄8 11⁄4 13⁄8 11⁄2 15⁄8 2 21⁄4
3 35⁄16 35⁄8 41⁄8 5
E … … … … 17⁄8 23⁄8 213⁄16 35⁄16 33⁄4 41⁄4 411⁄16 53⁄16 53⁄4 7 73⁄4
F … … … … 15⁄8 2 23⁄8 213⁄16 33⁄16 39⁄16 315⁄16 43⁄8 413⁄16 53⁄4 63⁄4
G … … … … 13⁄ 16 11⁄16 11⁄4 17⁄16 111⁄16 113⁄16 21⁄32 21⁄4 23⁄8 27⁄8 31⁄4
All dimensions are in inches. Load limits are in tons of 2000 pounds. Source:The Crosby Group.
Copyright 2004, Industrial Press, Inc., New York, NY
H … … … … 5⁄ 8 3⁄ 4 7⁄ 8 1 11⁄8 11⁄4 13⁄8 11⁄2 15⁄8 2 21⁄4
I … … … … 13⁄16 19⁄16 17⁄8 21⁄8 23⁄8 25⁄8 3 35⁄16 35⁄8 41⁄8 5
Machinery's Handbook 27th Edition HOOKS, SHACKLES, AND EYES
Eye Hook With Latch Assembled
Eye Hook
393
Swivel Hook With Latch Assembled
Swivel Hook
Dimensions of Crane Hooks Feature
Capacity of Hook in Tons (tons of 2000 lbs) 1.1
A B D E G H K L R T O
1.47 0.75 2.88 0.94 0.75 0.81 0.56 4.34 3.22 0.81 0.88
1.75 0.91 3.19 1.03 0.84 0.94 0.62 4.94 3.66 0.81 0.97
2.03 1.12 3.62 1.06 1.00 1.16 0.75 5.56 4.09 0.84 1.00
2.41 1.25 4.09 1.22 1.12 1.31 0.84 6.40 4.69 1.19 1.12
2.94 1.56 4.94 1.50 1.44 1.62 1.12 7.91 5.75 1.38 1.34
A B C D E L R S T O
2 0.94 1.25 2.88 0.94 5.56 4.47 0.38 0.81 0.88
2.50 1.31 1.50 3.19 1.03 6.63 5.28 0.50 0.81 0.97
3 1.63 1.75 3.63 1.06 7.63 6.02 0.63 0.84 1
3 1.56 1.75 4.09 1.22 8.13 6.38 0.63 1.19 1.13
3.50 1.75 2 4.94 1.5 9.59 7.41 0.75 1.38 1.34
1.65
2.2
3.3
4.95
7.7
12.1
16.5
24.2
33
40.7
49.5
6.62 3.50 11.00 3.38 3.00 3.50 2.38 17.09 12.50 2.88 3.00
7.00 3.50 13.62 4.00 3.66 4.62 3.00 19.47 14.06 3.44 3.62
8.50 4.50 14.06 4.25 4.56 5.00 3.75 24.75 18.19 3.88 3.75
9.31 4.94 15.44 4.75 5.06 5.50 4.12 27.38 20.12 4.75 4.25
7 4.19 4 11 3.38 21.06 16.56 1.5 2.88 3
7 4.19 4 13.63 4 23.22 18.06 1.5 3.44 3.63
… … … … … … … … … …
… … … … … … … … … …
Dimensions for Eye Hooks 3.81 4.69 5.38 2.00 2.44 2.84 6.50 7.56 8.69 1.88 2.25 2.50 1.81 2.25 2.59 2.06 2.62 2.94 1.38 1.62 1.94 10.09 12.44 13.94 7.38 9.06 10.06 1.78 2.12 2.56 1.69 2.06 2.25 Dimensions for Swivel Hooks 4.50 5 5.63 2.31 2.38 2.69 2.50 2.75 3.13 6.5 7.56 8.69 1.88 2.25 2.5 12.41 14.50 15.88 9.59 11.13 12.03 1 1.13 1.25 1.78 2.13 2.56 1.69 2.06 2.25
Source: The Crosby Group. All dimensions are in inches. Hooks are made of alloy steel, quenched and tempered. For swivel hooks, the data are for a bail of carbon steel. The ultimate load is four times the working load limit (capacity). The swivel hook is a positioning device and is not intended to rotate under load; special load swiveling hooks must be used in such applications. Method of Making an Eye-splice.— When a loop is formed at the end of a rope by splicing the free end to the main or standing part of the rope, this is known as an eye-splice. The end of the rope is first unlaid about as far as it would be for making a short splice. After bending the end around to form a loop of the required size, the middle strand a, Fig. 8a, is tucked under a strand on the main part of the rope. The strand b is next inserted from the rear side under the strand on the main part which is just above the strand under which a was inserted. Since strand b is pushed under the strand on the main part from the rear side, it will come out at the point where strand a went in, as Fig. 8b. The third strand c is now passed over the strand under which strand a was inserted, and then under the next successive one, as Fig. 8c. These three strands are next pulled taut and then about one-third of the fiber should be cut from them; they are next tucked away by passing a strand over its adjoining one and under the next successive strand. The reason for cutting away part of the fiber or yarns is to reduce the size of the splice and give it a neater appearance. By gradually thinning out the fiber, the over-lapping strands may be given a gradual taper, as Fig. 8d which shows the completed eye-splice.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 394
HOOKS, SHACKLES, AND EYES
Hot Dip Galvanized, Forged Steel Eye-bolts Shank
Eye Dia.
D
C
1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8
2 4 21⁄4 41⁄4 21⁄2 41⁄2
A
6 31⁄4 6 8 10 12 4 6 8 10 12
B
1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4
1 1 11⁄4 11⁄4 11⁄2 11⁄2 11⁄2
1 1 1 1 1 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4
2 2 2 2 2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2
Safe Shank Loada (tons) D C Regular Pattern 0.25 0.25 0.4 0.4 0.6 0.6 0.6 1.1 1.1 1.1 1.1 1.1 1.75 1.75 1.75 1.75 1.75
3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 7⁄ 8 7⁄ 8 7⁄ 8
1 1 1 1 11⁄4 11⁄4 11⁄4 …
41⁄2 6 8 10 10 10 5 8 10 6 9 10 10 8 10 10 …
Eye Dia.
Safe Loada (tons)
A
B
11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 13⁄4 13⁄4 13⁄4
3 3 3 3 3 3 31⁄2 31⁄2 31⁄2
2 2 2 2 21⁄2 21⁄2 21⁄2
4 4 4 4 5 5 5 …
2.6 2.6 2.6 2.6 2.6 2.6 3.6 3.6 3.6 5 5 5 5 7.6 7.6 7.6 …
21⁄4 23⁄4 23⁄4 31⁄4 33⁄4 33⁄4 41⁄2 41⁄2 51⁄2
1.75 2.6 2.6 3.6 5 5 7.6 7.6 10.7
…
Shoulder Pattern 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 5⁄ 8
1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4
2 4 21⁄4 41⁄4 21⁄2 41⁄2 31⁄4
1 1 11⁄4
6 4
7⁄ 8 7⁄ 8 11⁄8 11⁄8 13⁄8 13⁄8 13⁄4 13⁄4 21⁄4
0.25 0.25 0.4 0.4 0.6 0.6 1.1 1.1 1.75
5⁄ 8 3⁄ 4 3⁄ 4 7⁄ 8
1 1 11⁄4 11⁄4 11⁄2
6 41⁄2 6 5 6 9 8 12 15
11⁄4 11⁄2 11⁄2 13⁄4 2 2 21⁄2 21⁄2 3
a The ultimate or breaking load is 5 times the safe working load.
All dimensions are in inches. Safe loads are in tons of 2000 pounds. Source:The Crosby Group.
Fig. 8a. Eye -Splice
Fig. 8b. Eye -Splice
Fig. 8c. Eye -Splice
Fig. 8d. Eye -Splice
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition HOOKS, SHACKLES, AND EYES
395
Eye Nuts and Lift Eyes
Eye Nut
Lifting Eye
Eye Nuts The general function of eye nuts is similar to that of eye-bolts. Eye nuts are utilized for a variety of applications in either the swivel or tapped design. Working Load M A C D E F S T Limit (lbs)a 3 21 1 1 1⁄ 1 1 11 520 1 ⁄4 ⁄4 1 ⁄16 ⁄32 ⁄2 ⁄4 1 ⁄16 4 3⁄ 21⁄ 1⁄ 1⁄ 5⁄ 850 11⁄4 11⁄16 111⁄16 16 4 32 2 4 3⁄ 9⁄ 5⁄ 3⁄ 1 1,250 15⁄8 21⁄16 11⁄4 8 4 16 16 3⁄ 7⁄ 13⁄ 2 1 1,700 11⁄4 11⁄2 21⁄2 16 16 8 3⁄ 1⁄ 13⁄ 2 1 2,250 11⁄2 21⁄2 11⁄4 2 16 8 5⁄ 1⁄ 2 1 3,600 13⁄16 21⁄2 11⁄2 33⁄16 8 2 5⁄ 3⁄ 3 5,200 23⁄8 13⁄8 11⁄8 37⁄8 13⁄4 4 8 3⁄ 7⁄ 2 7,200 25⁄8 31⁄2 15⁄8 15⁄16 45⁄16 8 4 7⁄ 5 10,000 1 4 31⁄16 17⁄8 19⁄16 21⁄4 8 7⁄ 4 5 12,300 21⁄4 11⁄8 31⁄16 17⁄8 19⁄16 8 1 15,500 11⁄4 41⁄2 21⁄2 31⁄2 115⁄16 17⁄8 53⁄4 5 2 2 18,500 23⁄4 11⁄8 13⁄8 33⁄4 61⁄4 4 22,500 11⁄2 55⁄8 31⁄8 21⁄4 11⁄4 63⁄4 23⁄8 4 10 40,000 2 7 4 33⁄8 61⁄4 11⁄2 a Data for eye nuts are for hot dip galvanized, quenched, and tempered forged steel.
Lifting Eyes A
C
11⁄4 15⁄8 2
1
21⁄2 3 31⁄2 4 41⁄2 55⁄8
3⁄ 4
11⁄4 11⁄2 13⁄4 2 21⁄4 21⁄2 31⁄8
D
E
F
G
H
L
S
T
11⁄16 11⁄4 11⁄2 2
19⁄ 32 3⁄ 4
1⁄ 2 9⁄ 16 13⁄ 16
3⁄ 8 1⁄ 2 5⁄ 8 11⁄ 16 7⁄ 8 15⁄ 16 11⁄16 11⁄4 11⁄2
5⁄ 16 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
11⁄ 16 15⁄ 16 11⁄4 11⁄2 13⁄4
1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
23⁄8 3
23⁄8 25⁄8 31⁄16 31⁄2 4
1 13⁄16 13⁄8 15⁄8 17⁄8 115⁄16 23⁄8
1 11⁄8 15⁄16 19⁄16 17⁄8 23⁄8
1 11⁄8 13⁄8
2 21⁄16 21⁄2 215⁄16
1 11⁄4
33⁄4 411⁄16 55⁄8 65⁄16 71⁄16 81⁄4 911⁄16
a Data for lifting eyes are for quenched and tempered forged steel.
All dimensions are in inches. Source:The Crosby Group.
Copyright 2004, Industrial Press, Inc., New York, NY
Working Load Limit Threaded (lbs)a 850 1,250 2,250 3,600 5,200 7,200 10,000 12,500 18,000
Machinery's Handbook 27th Edition TABLE OF CONTENTS PROPERTIES, TREATMENT, AND TESTING OF MATERIALS THE ELEMENTS, HEAT, MASS, AND WEIGHT 398 399 399 402 403 403 405 405 407 409 409 410 410 410
STANDARD STEELS
The Elements Latent Heat Specific Heat Coefficient of Thermal Expansion Ignition Temperatures Thermal Properties of Metals Adjusting Length for Temperature Length and Radius Change Due to Temperature Specific Gravity Weights and Volumes of Fuels Weight of Natural Piles Earth or Soil Weight Molecular Weight Mol
PROPERTIES OF WOOD, CERAMICS, PLASTICS, METALS, WATER, AND AIR 411 Properties of Wood 411 Mechanical Properties 412 Weight of Wood 413 Density of Wood 413 Machinability of Wood Properties of 415 Ceramics 416 Plastics 417 Investment Casting Alloys 419 Powdered Metals 420 Elastic Properties of Materials 421 Tensile Strength of Spring Wire 421 Temperature Effects on Strength 422 Pressure and Flow of Water 422 Water Pressure 423 Flow of Water in Pipes 424 Buoyancy 425 Flow through Nozzle 427 Friction Loss 428 Properties of Air 428 Volumes and Weights 429 Density of Air 430 Expansion and Compression 432 Horsepower Required to Compress Air 432 Continuity Equation 436 Flow of Air in Pipes 436 Flow of Compressed Air in Pipes
438 Properties, Compositions, and Applications 438 Standard Steel Classification 440 Numbering Systems 440 Unified Numbering System 441 Standard Steel Numbering System 441 Binary, Ternary and Quarternary 441 Damascus Steel 442 AISI-SAE Numbers for Steels 443 AISI-SAE Designation System 444 Composition of Carbon Steels 446 Composition of Alloy Steels 448 Composition of Stainless Steels 449 Thermal Treatments of Steel 450 Applications of Steels 452 Carbon Steels 455 Carburizing Grade Alloy Steels 456 Hardenable Grade Alloy Steels 457 Characteristics of Stainless Steels 460 Chromium-Nickel Austenitic Steels 462 High-Strength, Low-Alloy Steels 464 Mechanical Properties of Steels
TOOL STEELS 475 475 478 479 481 482 488 488 490 491 493 493 494 494 495 497 497 499 499 501 502 502 502
Overview Properties of Tool Steels Tool Faults, Failures and Cures Tool Steel Properties Classification Tool Steel Selection High-Speed Tool Steels Molybdenum-Type Tungsten-Type Hot-Work Tool Steels Tungsten-Types Molybdenum-Types Cold-Work Tool Steels Oil-Hardening Types Air-Hardening Types Shock-Resisting Tool Steels Mold Steels Special-Purpose Tool Steels Water-Hardening Tool Steels Forms of Tool Steel Tolerances of Dimensions Allowances for Machining Decarburization Limits
396
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TABLE OF CONTENTS PROPERTIES, TREATMENT, AND TESTING OF MATERIALS HARDENING, TEMPERING, AND ANNEALING 503 503 507 509 511 511 512 513 513 515 516 516 517 517 518 518 519 521 522 526 526 527 527 527 529 529 532 533 534 536 537 538 538 541 543 544 547 547 548 548 548 549 549 549 550
NONFERROUS ALLOYS 554 Strength of Nonferrous Metals 555 Copper and Copper Alloys 555 Cast Copper Alloys 560 Wrought Copper Alloys 569 Copper–Silicon and Copper– Beryllium Alloys 569 Everdur 571 Aluminum and Aluminum Alloys 571 Characteristics 572 Temper Designations 575 Alloy Designation Systems 575 Composition of Casting Alloys 576 Properties of Casting Alloys 578 Composition of Wrought Alloys 580 Properties of Wrought Alloys 584 Clad Aluminum Alloys 584 Principal Alloy Groups 585 Type Metal 586 Magnesium Alloys 586 Alloy and Temper Designation 589 Nickel and Nickel Alloys 589 Characteristics 589 Properties of Nickel Alloys 589 Titanium and Titanium Alloys 591 Mechanical Properties Table
Heat Treatment Of Standard Steels Heat-Treating Definitions Hardness and Hardenability Case Hardening Slow Cooling Rapid Cooling or Quenching Heat-Treating Furnaces Physical Properties Hardening Hardening Temperatures Heating Steel in Liquid Baths Salt Baths Quenching Baths Hardening or Quenching Baths Quenching in Water Quenching in Molten Salt Bath Tanks for Quenching Baths Tempering Color as Temperature Indicator Case Hardening Carburization Pack-Hardening Cyanide Hardening Nitriding Process Flame Hardening Induction Hardening SAE Carbon Steels SAE Alloy Steels Metallography Chromium-Ni Austenitic Steels Stainless Chromium Steels Heat Treating High-Speed Steels Tungsten High-Speed Steels Molybdenum High-Speed Steels Nitriding High-Speed Steel Subzero Treatment of Steel Testing the Hardness of Metals Brinell Hardness Test Rockwell Hardness Test Shore’s Scleroscope Vickers Hardness Test Knoop Hardness Numbers Monotron Hardness Indicator Keep’s Test Comparative Hardness Scales
PLASTICS 592 Properties of Plastics 592 Characteristics of Plastics 593 Plastics Materials 593 Structures 593 Mixtures 594 Physical Properties 596 Mechanical Properties 601 Strength and Modulus 602 Time Related Properties 603 Thermal Properties 605 Electrical Properties 607 Chemical Resistance 607 Design Analysis 607 Structural Analysis 609 Design Stresses 610 Thermal Stresses 611 Design for Injection Moldings 615 Design for Assembly 620 Assembly with Fasteners 621 Machining Plastics 624 Development of Prototypes 625 Plastics Gearing
397
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 398
PROPERTIES, TREATMENT, AND TESTING OF MATERIALS
THE ELEMENTS, HEAT, MASS, AND WEIGHT Table 1. The Elements — Symbols, Atomic Numbers and Weights, Melting Points Name of Element
Sym bol
Actinium Aluminum Americium Antimony Argon Arsenic Astatine Barium Berkelium Beryllium Bismuth Boron Bromine Cadmium Calcium Californium Carbon Cerium Cesium Chlorine Chromium Cobalt Copper Curium Dysprosium Einsteinium Erbium Europium Fermium Fluorine Francium Gadolinium Gallium Germanium Gold Hafnium Helium Holmium Hydrogen Indium Iodine Iridium Iron Krypton Lanthanum Lawrencium Lead Lithium Lutetium Magnesium Manganese Mendelevium Mercury Molybdenum Neodymium
Ac Al Am Sb A As At Ba Bk Be Bi B Br Cd Ca Cf C Ce Cs Cl Cr Co Cu Cm Dy Es Er Eu Fm F Fr Gd Ga Ge Au Hf He Ho H In I Ir Fe Kr La Lw Pb Li Lu Mg Mn Md Hg Mo Nd
Atomic Num. Weight 89 13 95 51 18 33 85 56 97 4 83 5 35 48 20 98 6 58 55 17 24 27 29 96 66 99 68 63 100 9 87 64 31 32 79 72 2 67 1 49 53 77 26 36 57 103 82 3 71 12 25 101 80 42 60
227.028 26.9815 (243) 121.75 39.948 74.9216 (210) 137.33 (247) 9.01218 208.980 10.81 79.904 112.41 40.08 (251) 12.011 140.12 132.9054 35.453 51.996 58.9332 63.546 (247) 162.5 (252) 167.26 151.96 (257) 18.9984 (223) 157.25 69.72 72.59 196.967 178.49 4.00260 164.930 1.00794 114.82 126.905 192.22 55.847 83.80 138.906 (260) 207.2 6.941 174.967 24.305 54.9380 (258) 200.59 95.94 144.24
Melting Point, °C
Name of Element
Sym bol
Atomic Num. Weight
1050 660.37 994 ± 4 630.74 −189.2 817a 302 725 … 1278 ± 5 271.3 2079 −7.2 320.9 839 ± 2 … 3652c 798 ± 2 28.4 ± 0.01 −100.98 1857 ± 20 1495 1083.4 ± 0.2 1340 ± 40 1409 … 1522 822 ± 5 … −219.62 27b 1311 ± 1 29.78 937.4 1064.434 2227 ± 20 −272.2d 1470 −259.14 156.61 113.5 2410 1535 −156.6 920 ± 5 … 327.502 180.54 1656 ± 5 648.8 ± 0.5 1244 ± 2 … −38.87 2617 1010
Neon Neptunium Nickel Niobium Nitrogen Nobelium Osmium Oxygen Palladium Phosphorus Platinum Plutonium Polonium Potassium Praseodymium Promethium Protactinium Radium Radon Rhenium Rhodium Rubidium Ruthenium Samarium Scandium Selenium Silicon Silver Sodium Strontium Sulfur Tantalum Technetium Tellurium Terbium Thallium Thorium Thulium Tin Titanium Tungsten Unnilhexium Unnilnonium Unniloctium Unnilpentium Unnilquadium Unnilseptium Uranium Vanadium Xenon Ytterbium Yttrium Zinc Zirconium
Ne Np Ni Nb N No Os O Pd P Pt Pu Po K Pr Pm Pa Ra Rn Re Rh Rb Ru Sm Sc Se Si Ag Na Sr S Ta Tc Te Tb Tl Th Tm Sn Ti W Unh Unn Uno Unp Unq Uns U V Xe Yb Y Zn Zr
10 93 28 41 7 102 76 8 46 15 78 94 84 19 59 61 91 88 86 75 45 37 44 62 21 34 14 47 11 38 16 73 43 52 65 81 90 69 50 22 74 106 109 108 105 104 107 92 23 54 70 39 30 40
20.1179 237.048 58.69 92.9064 14.0067 (259) 190.2 15.9994 106.42 30.9738 195.08 (244) (209) 39.0938 140.908 (145) 231.0359 226.025 (222) 186.207 102.906 85.4678 101.07 150.36 44.9559 78.96 28.0855 107.868 22.9898 87.62 32.06 180.9479 (98) 127.60 158.925 204.383 232.038 168.934 118.71 47.88 183.85 (266) (266) (265) (262) (261) (261) 238.029 50.9415 131.29 173.04 88.9059 65.39 91.224
Melting Point, °C −248.67 640 ± 1 1453 2468 ± 10 −209.86 … 3045 ± 30 −218.4 1554 44.1 1772 641 254 63.25 931 ± 4 1080b 1600 700 −71 3180 1965 ± 3 38.89 2310 1072 ± 5 1539 217 1410 961.93 97.81 ± 0.03 769 112.8 2996 2172 449.5 ± 0.3 1360 ± 4 303.5 1750 1545 ± 15 231.9681 1660 ± 10 3410 ± 20 … … … … … … 1132 ± 0.8 1890 ± 10 −111.9 824 ± 5 1523 ± 8 419.58 1852 ± 2
a At 28 atm. b Approximate. c Sublimates. d At 26 atm.
Notes: Values in parentheses are atomic weights of the most stable known isotopes. Melting points at standard pressure except as noted.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition HEAT
399
Heat and Combustion Related Properties Latent Heat.—When a body changes from the solid to the liquid state or from the liquid to the gaseous state, a certain amount of heat is used to accomplish this change. This heat does not raise the temperature of the body and is called latent heat. When the body changes again from the gaseous to the liquid, or from the liquid to the solid state, it gives out this quantity of heat. The latent heat of fusion is the heat supplied to a solid body at the melting point; this heat is absorbed by the body although its temperature remains nearly stationary during the whole operation of melting. The latent heat of evaporation is the heat that must be supplied to a liquid at the boiling point to transform the liquid into a vapor. The latent heat is generally given in British thermal units per pound. When it is said that the latent heat of evaporation of water is 966.6, this means that it takes 966.6 heat units to evaporate 1 pound of water after it has been raised to the boiling point, 212°F. When a body changes from the solid to the gaseous state without passing through the liquid stage, as solid carbon dioxide does, the process is called sublimation. Table 2. Latent Heat of Fusion Substance Bismuth Beeswax Cast iron, gray Cast iron, white
Btu per Pound 22.75 76.14 41.40 59.40
Substance Paraffine Phosphorus Lead Silver
Btu per Pound 63.27 9.06 10.00 37.92
Substance Sulfur Tin Zinc Ice
Btu per Pound 16.86 25.65 50.63 144.00
Table 3. Latent Heat of Evaporation Liquid Alcohol, ethyl Alcohol, methyl Ammonia
Btu per Pound 371.0 481.0 529.0
Liquid Carbon bisulfide Ether Sulfur dioxide
Btu per Pound 160.0 162.8 164.0
Liquid Turpentine Water
Btu per Pound 133.0 966.6
Table 4. Boiling Points of Various Substances at Atmospheric Pressure Substance Aniline Alcohol Ammonia Benzine Bromine Carbon bisulfide
Boiling Point, °F 363 173 −28 176 145 118
Substance Chloroform Ether Linseed oil Mercury Napthaline Nitric acid Oil of turpentine
Boiling Point, °F 140 100 597 676 428 248 315
Substance Saturated brine Sulfur Sulfuric acid Water, pure Water, sea Wood alcohol
Boiling Point, °F 226 833 590 212 213.2 150
Specific Heat.—The specific heat of a substance is the ratio of the heat required to raise the temperature of a certain weight of the given substance 1°F, to the heat required to raise the temperature of the same weight of water 1°F. As the specific heat is not constant at all temperatures, it is generally assumed that it is determined by raising the temperature from 62 to 63°F. For most substances, however, specific heat is practically constant for temperatures up to 212°F. In metric units, specific heat is defined as the ratio of the heat needed to raise the temperature of a mass by 1°C, to the heat needed to raise the temperature of the same mass of water by 1°C. In the metic system, heat is measued in calories (cal), mass is in grams (g), and measurements usually taken at 15°C. Because specific heat is a dimensionless ratio, the values given in the table that follows are valid in both the US system and the metric system.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 400
HEAT Table 5. Average Specific Heats (Btu/lb-°F) of Various Substances
Substance Alcohol (absolute) Alcohol (density 0.8) Aluminum Antimony Benzine Brass Brickwork Cadmium Carbon Charcoal Chalk Coal Coke Copper, 32° to 212° F Copper, 32° to 572° F Corundum Ether Fusel oil Glass Gold Graphite Ice Iron, cast Iron, wrought, 32° to 212° F 32° to 392° F 32° to 572° F 32° to 662° F Iron, at high temperatures: 1382° to 1832° F 1750° to 1840° F 1920° to 2190° F Kerosene
Specific Heat 0.700 0.622 0.214 0.051 0.450 0.094 0.200 0.057 0.204 0.200 0.215 0.240 0.203 0.094 0.101 0.198 0.503 0.564 0.194 0.031 0.201 0.504 0.130 0.110 0.115 0.122 0.126 0.213 0.218 0.199 0.500
Specific Heat 0.031 0.037 0.217 0.222 0.210 0.200 0.033 0.310 0.109 0.400 0.350 0.32 0.189 0.032 0.188 0.195 0.191 0.056 0.231 0.117 0.116 0.200 0.178 0.330 0.056 0.064 0.472 1.000 0.650 0.570 0.467 0.095
Substance Lead Lead (fluid) Limestone Magnesia Marble Masonry, brick Mercury Naphtha Nickel Oil, machine Oil, olive Paper Phosphorus Platinum Quartz Sand Silica Silver Soda Steel, high carbon Steel, mild Stone (generally) Sulfur Sulfuric acid Tin (solid) Tin (fluid) Turpentine Water Wood, fir Wood, oak Wood, pine Zinc
Table 6. Specific Heat of Gases (Btu/lb-°F) Gas Acetic acid Air Alcohol Ammonia Carbonic acid Carbonic oxide Chlorine
Constant Pressure 0.412 0.238 0.453 0.508 0.217 0.245 0.121
Constant Volume … 0.168 0.399 0.399 0.171 0.176 …
Gas Chloroform Ethylene Hydrogen Nitrogen Oxygen Steam
Constant Pressure 0.157 0.404 3.409 0.244 0.217 0.480
Constant Volume … 0.332 2.412 0.173 0.155 0.346
Heat Loss from Uncovered Steam Pipes.—The loss of heat from a bare steam or hotwater pipe varies with the temperature difference of the inside the pipe and that of the surrounding air. The loss is 2.15 Btu per hour, per square foot of pipe surface, per degree F of temperature difference when the latter is 100 degrees; for a difference of 200 degrees, the loss is 2.66 Btu; for 300 degrees, 3.26 Btu; for 400 degrees, 4.03 Btu; for 500 degrees, 5.18 Btu. Thus, if the pipe area is 1.18 square feet per foot of length, and the temperature difference 300°F, the loss per hour per foot of length = 1.18 × 300 × 3.26 = 1154 Btu.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition THERMAL PROPERTIES OF MATERIALS
401
Table 7. Values of Thermal Conductivity (k) and of Conductance (C) of Common Building and Insulating Materials Thickness, in.
Type of Material BUILDING Batt: Mineral Fiber Mineral Fiber Mineral Fiber Mineral Fiber Block: Cinder Cinder Cinder Block: Concrete Concrete Concrete Board: Asbestos Cement Plywood
Hardwood Finish Tile Glass: Architectural Mortar: Cement Plaster: Sand Sand and Gypsum Stucco Roofing: Asphalt Roll Shingle, asb. cem. Shingle, asphalt Shingle, wood
k or Ca
Max. Temp.,° F
Density, lb per cu. ft.
ka
… Avg.
… 1.61
… …
… …
… …
7⁄ 16
0.09
1.49
…
…
…
0.05
Stone:
…
…
…
…
…
6–7 81⁄2 … 4 8 12 … 4 8 12 … 1⁄ 4
0.04 0.03
Lime or Sand Wall Tile:
1 …
12.50 …
… …
… …
… …
4 8 12 Avg.
0.9 0.54 0.40 0.7
… … … …
… … … …
… … … …
… 1 1 1 …
Brick: Common Face Concrete (poured) Floor: Wood Subfloor
Thickness, in.
3–31⁄2 31⁄2–61⁄2
1⁄ 2 3⁄ 4
Plaster
Type of Material BUILDING (Continued) Siding: Metalb Wood, Med. Density
… 2–23⁄4
Mineral Fiber
k or Ca
3⁄ 4 3⁄ 4
… 0.14
… 0.90 0.58 0.53 … 1.40 0.90 0.78 … 16.5
Hollow Clay, 1-Cell Hollow Clay, 2-Cell Hollow Clay, 3-Cell Hollow Gypsum INSULATING Blanket, Mineral Fiber: Felt Rock or Slag Glass Textile
… … … … …
… … … … …
… 400 1200 350 350
… 3 to 8 6 to 12 0.65 0.65
… 0.26 0.26c 0.33 0.31
2.22
Blanket, Hairfelt
…
…
180
10
0.29
1.07
Board, Block and Pipe
…
…
…
…
…
Insulation: Amosite Asbestos Paper Glass or Slag (for Pipe) Glass or Slag (for Pipe) Glass, Cellular
… … … … … …
… … … … … …
… 1500 700 350 1000 800
… 15 to 18 30 3 to 4 10 to 15 9
… 0.32c 0.40c 0.23 0.33c 0.40 0.35c 0.29 0.28 0.25 0.22 0.31 … 0.27
… 5.0 9.0 12.0 … 1.06 1.47
Magnesia (85%)
…
…
600
11 to 12
Avg. … … … 1 … 3⁄ 8
20.0 … 10.00 … 5.0 … 13.30
Mineral Fiber Polystyrene, Beaded Polystyrene, Rigid Rubber, Rigid Foam Wood Felt Loose Fill: Cellulose
… … … … … … …
… … … … … … …
100 170 170 150 180 … …
15 1 1.8 4.5 20 … 2.5 to 3
1⁄ 2
11.10
1 … Avg. Avg. Avg. Avg.
5.0 … 6.50 4.76 2.27 1.06
Mineral Fiber Perlite Silica Aerogel Vermiculite Mineral Fiber Cement: Clay Binder Hydraulic Binder
…
…
…
2 to 5
0.28
… … … … … …
… … … … … …
… … … … 1800 1200
5 to 8 7.6 7 to 8.2 … 24 to 30 30 to 40
0.37 0.17 0.47 … 0.49c 0.75c
a Units are in Btu/hr-ft2-°F. Where thickness is given as 1 inch, the value given is thermal conductivity (k); for other thicknesses the value given is thermal conductance (C). All values are for a test mean temperature of 75°F, except those designated with c, which are for 100°F. b Over hollowback sheathing. c Test mean temperature 100°F, see footnote a . Source: American Society of Heating, Refrigerating and Air-Conditioning Engineers, Inc.: Handbook of Fundamentals.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 402
THERMAL PROPERTIES OF MATERIALS Table 8. Typical Values of Coefficient of Linear Thermal Expansion for Thermoplastics and Other Commonly Used Materials Materiala
in/in/deg F × 10−5
cm/cm/deg C × 10−5
Liquid Crystal—GR Glass Steel Concrete
0.3 0.4 0.6 0.8
0.6 0.7 1.1 1.4
Copper Bronze Brass Aluminum Polycarbonate—GR Nylon—GR TP polyester—GR Magnesium Zinc ABS—GR
0.9 1.0 1.0 1.2 1.2 1.3 1.4 1.4 1.7 1.7
1.6 1.8 1.8 2.2 2.2 2.3 2.5 2.5 3.1 3.1
Materiala
in/in/deg F × 10−5
cm/cm/deg C × 10−5
1.7 1.8 2.0 2.0
3.1 3.2 3.6 3.6
2.2 3.0 3.6 3.8 4.0 4.5 4.8 4.8 6.9 7.2
4.0 5.4 6.5 6.8 7.2 8.1 8.5 8.6 12.4 13.0
ABS—GR Polypropylene—GR Epoxy—GR Polyphenylene sulfide—GR Acetal—GR Epoxy Polycarbonate Acrylic ABS Nylon Acetal Polypropylene TP Polyester Polyethylene
a GR = Typical glass fiber-reinforced material. Other plastics materials shown are unfilled.
Table 9. Linear Expansion of Various Substances between 32 and 212°F Expansion of Volume = 3 × Linear Expansion Linear Expansion for 1°F
Substance Brick Cement, Portland Concrete Ebonite Glass, thermometer Glass, hard Granite Marble, from to
0.0000030 0.0000060 0.0000080 0.0000428 0.0000050 0.0000040 0.0000044 0.0000031 0.0000079
Linear Expansion for 1°F
Substance Masonry, brick from to Plaster Porcelain Quartz, from to Slate Sandstone Wood, pine
0.0000026 0.0000050 0.0000092 0.0000020 0.0000043 0.0000079 0.0000058 0.0000065 0.0000028
Table 10. Coefficients of Heat Transmission Metal
Btu per Second
Metal
Btu per Second
Aluminum Antimony Brass, yellow Brass, red Copper
0.00203 0.00022 0.00142 0.00157 0.00404
German silver Iron Lead Mercury Steel, hard
0.00050 0.00089 0.00045 0.00011 0.00034
Metal Steel, soft Silver Tin Zinc …
Btu per Second 0.00062 0.00610 0.00084 0.00170 …
Heat transmitted, in British thermal units, per second, through metal 1 inch thick, per square inch of surface, for a temperature difference of 1°F
Table 11. Coefficients of Heat Radiation Surface Cast-iron, new Cast-iron, rusted Copper, polished Glass Iron, ordinary Iron, sheet-, polished Oil
Btu per Hour 0.6480 0.6868 0.0327 0.5948 0.5662 0.0920 1.4800
Surface Sawdust Sand, fine Silver, polished Tin, polished Tinned iron, polished Water …
Btu per Hour 0.7215 0.7400 0.0266 0.0439 0.0858 1.0853 …
Heat radiated, in British thermal units, per square foot of surface per hour, for a temperature difference of 1° F
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition PROPERTIES OF MATERIALS
403
Table 12. Freezing Mixtures Temperature Change,°F Mixture
From
To
Common salt (NaCl), 1 part; snow, 3 parts Common salt (NaCl), 1 part; snow, 1 part Calcium chloride (CaCl2), 3 parts; snow, 2 parts
32 32 32
±0 −0.4 −27
Calcium chloride (CaCl2), 2 parts; snow, 1 part
32
−44
Sal ammoniac (NH4Cl), 5 parts; saltpeter (KNO3), 5 parts; water,16 parts
50
+10
Sal ammoniac (NH4Cl), 1 part; saltpeter (KNO3), 1 part; water,1 part
46
−11
Ammonium nitrate (NH4NO3), 1 part; water, 1 part
50
+3
Potassium hydrate (KOH), 4 parts; snow, 3 parts
32
−35
Ignition Temperatures.—The following temperatures are required to ignite the different substances specified: Phosphorus, transparent, 120°F; bisulfide of carbon, 300°F; gun cotton, 430°F; nitro-glycerine, 490°F; phosphorus, amorphous, 500°F; rifle powder, 550°F; charcoal, 660°F; dry pine wood, 800°F; dry oak wood, 900°F. Table 13. Typical Thermal Properties of Various Metals Material and Alloy Designation a
Density, ρ lb/in3
Melting Point, °F solidus
liquidus
Coeff. of Expansion, α µin/in-°F
Conductivity, k, Btu/hr-ft-°F
Specific Heat, C, Btu/lb/°F
82.5 99.4 109.2 111 80 73 104 70
0.23 0.22 0.22 0.22 0.22 0.23 0.23 0.23
12.8 13.1 12.9 12.9 13.2 13.2 13.0 13.1
61 226 205 62 187 218 109 92 70 67 71 67 67 67 67 71 67 40 50 31.4 33.9 21.8 17
0.09 0.09 0.09 0.10 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09 0.09
11.8 9.8 9.9 9.9 9.8 9.8 10.2 10.4 11.1 11.3 11.6 11.2 11.3 11.4 11.4 11.6 11.8 9.9 9.6 9.0 9.2 9.0 9.0
Aluminum Alloys 2011 2017 2024 3003 5052 5086 6061 7075
0.102 0.101 0.100 0.099 0.097 0.096 0.098 0.101
Manganese Bronze C11000 (Electrolytic tough pitch) C14500 (Free machining Cu) C17200, C17300 (Beryllium Cu) C18200 (Chromium Cu) C18700 (Leaded Cu) C22000 (Commercial bronze, 90%) C23000 (Red brass, 85%) C26000 (Cartridge brass, 70%) C27000 (Yellow brass) C28000 (Muntz metal, 60%) C33000 (Low-leaded brass tube) C35300 (High-leaded brass) C35600 (Extra-high-leaded brass) C36000 (Free machining brass) C36500 (Leaded Muntz metal) C46400 (Naval brass) C51000 (Phosphor bronze, 5% A) C54400 (Free cutting phos. bronze) C62300 (Aluminum bronze, 9%) C62400 (Aluminum bronze, 11%) C63000 (Ni-Al bronze) Nickel-Silver
0.302 0.321 0.323 0.298 0.321 0.323 0.318 0.316 0.313 0.306 0.303 0.310 0.306 0.307 0.307 0.304 0.304 0.320 0.321 0.276 0.269 0.274 0.314
995 995 995 1190 1100 1085 1080 890
1190 1185 1180 1210 1200 1185 1200 1180
Copper-Base Alloys 1590 1941 1924 1590 1958 1750 1870 1810 1680 1660 1650 1660 1630 1630 1630 1630 1630 1750 1700 1905 1880 1895 1870
1630 1981 1967 1800 1967 1975 1910 1880 1750 1710 1660 1720 1670 1660 1650 1650 1650 1920 1830 1915 1900 1930 2030
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 404
PROPERTIES OF MATERIALS Table 13. Typical Thermal Properties of Various Metals (Continued)
Material and Alloy Designation a
Density, ρ lb/in3
Melting Point, °F
Coeff. of Expansion, α µin/in-°F
Conductivity, k, Btu/hr-ft-°F
Specific Heat, C, Btu/lb/°F
43.3 7.5 7.5 6.5 10 12.6 10.1 10.1
0.11 0.10 0.10 0.10 0.10 0.10 0.10 0.10
8.5 6.9 6.2 7.2 8.7 7.7 7.6 7.6
9.4 9.4 9.2 9.4 6.5 8.8 9.0 8.2 9.4 8.3 9.3 9.3 9.3 9.4 14.4 15.6 14.4 14.4 13.8 14.8 15.1 13.8 14.0 14.0 12.1 21.2
0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.12 0.11 0.12 0.11 0.11 0.11 0.11 0.11 0.11 0.11 0.11 0.12 0.11
9.4 9.6 9.0 9.6 9.6 9.6 8.3 8.8 8.8 9.2 9.2 9.2 9.3 9.6 5.5 6.0 5.8 5.7 6.2 5.7 5.8 5.2 5.7 5.6 5.8 6.2
0.265
29.5
0.12
7.5
0.25 0.25 0.25 0.25 0.25 0.25 0.25
28.0
28.0
0.25 0.16 0.16 0.15 0.15 0.12 0.12
9.0 4.5 6.3
0.12 0.13 0.19
solidus
liquidus
Nickel-Base Alloys Nickel 200, 201, 205 Hastelloy C-22 Hastelloy C-276 Inconel 718 Monel Monel 400 Monel K500 Monel R405
0.321 0.314 0.321 0.296 0.305 0.319 0.306 0.319
S30100 S30200, S30300, S30323 S30215 S30400, S30500 S30430 S30800 S30900, S30908 S31000, S31008 S31600, S31700 S31703 S32100 S34700 S34800 S38400 S40300, S41000, S41600, S41623 S40500 S41400 S42000, S42020 S42200 S42900 S43000, S43020, S43023 S43600 S44002, S44004 S44003 S44600 S50100, S50200
0.290 0.290 0.290 0.290 0.290 0.290 0.290 0.290 0.290 0.290 0.290 0.290 0.290 0.290 0.280 0.280 0.280 0.280 0.280 0.280 0.280 0.280 0.280 0.280 0.270 0.280
2615 2475 2415 2300 2370 2370 2400 2370
2635 2550 2500 2437 2460 2460 2460 2460
Stainless Steels 2550 2550 2500 2550 2550 2550 2550 2550 2500 2500 2550 2550 2550 2550 2700 2700 2600 2650 2675 2650 2600 2600 2500 2500 2600 2700
2590 2590 2550 2650 2650 2650 2650 2650 2550 2550 2600 2650 2650 2650 2790 2790 2700 2750 2700 2750 2750 2750 2700 2750 2750 2800
Cast Iron and Steel Malleable Iron, A220 (50005, 60004, 80002) Grey Cast Iron Ductile Iron, A536 (120–90–02) Ductile Iron, A536 (100–70–03) Ductile Iron, A536 (80–55–06) Ductile Iron, A536 (65–45–120) Ductile Iron, A536 (60–40–18) Cast Steel, 3%C
liquidus approximately, 2100 to 2200, depending on composition
liquidus, 2640
20.0 18.0 20.8
5.8 5.9–6.2 5.9–6.2 5.9–6.2 5.9–6.2 5.9–6.2 7.0
Titanium Alloys Commercially Pure Ti-5Al-2.5Sn Ti-8Mn
0.163 0.162 0.171
3000 2820 2730
3040 3000 2970
5.1 5.3 6.0
a Alloy designations correspond to the AluminumAssociation numbers for aluminum alloys and to the unified numbering system (UNS) for copper and stainless steel alloys. A220 and A536 are ASTM specified irons.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition LENGTH/TEMPERATURE CHANGES
405
Adjusting Lengths for Reference Temperature.—The standard reference temperature for industrial length measurements is 20 degrees Celsius (68 degrees Fahrenheit). For other temperatures, corrections should be made in accordance with the difference in thermal expansion for the two parts, especially when the gage is made of a different material than the part to be inspected. Example:An aluminum part is to be measured with a steel gage when the room temperature is 30 °C. The aluminum part has a coefficient of linear thermal expansion, αPart = 24.7 × 10−6 mm/mm-°C, and for the steel gage, αGage = 10.8 × 10−6 mm/mm-°C. At the reference temperature, the specified length of the aluminum part is 20.021 mm. What is the length of the part at the measuring (room) temperature? ∆L, the change in the measured length due to temperature, is given by: ∆L = L ( T R – T 0 ) ( α Part – α Gage ) = 20.021 ( 30 – 20 ) ( 24.7 – 10.8 ) × 10 = 2782.919 × 10
–6
–6
mm
≈ 0.003 mm
where L = length of part at reference temperature; TR = room temperature (temperature of part and gage); and, T0 = reference temperature. Thus, the temperature corrected length at 30°C is L + ∆L = 20.021 + 0.003 = 20.024 mm. Length Change Due to Temperature.—Table 14 gives changes in length for variations from the standard reference temperature of 68°F (20°C) for materials of known coefficients of expansion, α. Coefficients of expansion are given in tables on pages 402, 403, 415, 416, 427, and elsewhere. Example:In Table 14, for coefficients between those listed, add appropriate listed values. For example, a length change for a coefficient of 7 is the sum of values in the 5 and 2 columns. Fractional interpolation also is possible. Thus, in a steel bar with a coefficient of thermal expansion of 6.3 × 10−6 = 0.0000063 in/in = 6.3 µin/in of length/°F, the increase in length at 73°F is 25 + 5 + 1.5 = 31.5 µin/in of length. For a steel with the same coefficient of expansion, the change in length, measured in degrees C, is expressed in microns (micrometers)/meter (µm/m) of length. Alternatively, and for temperatures beyond the scope of the table, the length difference due to a temperature change is equal to the coefficient of expansion multiplied by the change in temperature, i.e., 䉭L = α䉭T. Thus, for the previous example, 䉭L = 6.3 × (73 − 68) = 6.3 × 5 = 31.5 µin/in. Change in Radius of Thin Circular Ring with Temperature.—Consider a circular ring of initial radius r, that undergoes a temperature change 䉭T. Initially, the circumference of the ring is c = 2πr. If the coefficient of expansion of the ring material is α, the change in circumference due to the temperature change is 䉭c = 2πr α䉭T The new circumference of the ring will be: cn = c + 䉭c = 2πr + 2πrα䉭T = 2πr(1 + α䉭T) Note: An increase in temperature causes 䉭c to be positive, and a decrease in temperature causes 䉭c to be negative. As the circumference increases, the radius of the circle also increases. If the new radius is R, the new circumference 2πR. For a given change in temperature, 䉭T, the change in radius of the ring is found as follows: c n = 2πR = 2πr ( 1 + α ∆T )
R = r + rα ∆T
∆r = R – r = rα ∆T
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 406
LENGTH/TEMPERATURE CHANGES Table 14. Differences in Length in Inches/Inch (Microns/Meter) for Changes from the Standard Temperature of 68°F (20°C)
Temperature Deg. F C 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98
−10 −9 −8 −7 −6 −5 −4 −3 −2 −1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50
Coefficient of Thermal Expansion of Material per Degree F (C) × 106 3 4 5 10 15 20 25 for °F in microinches/inch of length (µin/in) Total Change in Length from Standard Temperature { for °C or °K in microns/meter of length (µm/m) 1
2
−30 −29 −28 −27 −26 −25 −24 −23 −22 −21 −20 −19 −18 −17 −16 −15 −14 −13 −12 −11 −10 −9 −8 −7 −6 −5 −4 −3 −2 −1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30
−60 −58 −56 −54 −52 −50 −48 −46 −44 −42 −40 −38 −36 −34 −32 −30 −28 −26 −24 −22 −20 −18 −16 −14 −12 −10 −8 −6 −4 −2 0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 54 56 58 60
−90 −87 −84 −81 −78 −75 −72 −69 −66 −63 −60 −57 −54 −51 −48 −45 −42 −39 −36 −33 −30 −27 −24 −21 −18 −15 −12 −9 −6 −3 0 3 6 9 12 15 18 21 24 27 30 33 36 39 42 45 48 51 54 57 60 63 66 69 72 75 78 81 84 87 90
−120 −116 −112 −108 −104 −100 −96 −92 −88 −84 −80 −76 −72 −68 −64 −60 −56 −52 −48 −44 −40 −36 −32 −28 −24 −20 −16 −12 −8 −4 0 4 8 12 16 20 24 28 32 36 40 44 48 52 56 60 64 68 72 76 80 84 88 92 96 100 104 108 112 116 120
−150 −145 −140 −135 −130 −125 −120 −115 −110 −105 −100 −95 −90 −85 −80 −75 −70 −65 −60 −55 −50 −45 −40 −35 −30 −25 −20 −15 −10 −5 0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90 95 100 105 110 115 120 125 130 135 140 145 150
−300 −290 −280 −270 −260 −250 −240 −230 −220 −210 −200 −190 −180 −170 −160 −150 −140 −130 −120 −110 −100 −90 −80 −70 −60 −50 −40 −30 −20 −10 0 10 20 30 40 50 60 70 80 90 100 110 120 130 140 150 160 170 180 190 200 210 220 230 240 250 260 270 280 290 300
−450 −435 −420 −405 −390 −375 −360 −345 −330 −315 −300 −285 −270 −255 −240 −225 −210 −195 −180 −165 −150 −135 −120 −105 −90 −75 −60 −45 −30 −15 0 15 30 45 60 75 90 105 120 135 150 165 180 195 210 225 240 255 270 285 300 315 330 345 360 375 390 405 420 435 450
−600 −580 −560 −540 −520 −500 −480 −460 −440 −420 −400 −380 −360 −340 −320 −300 −280 −260 −240 −220 −200 −180 −160 −140 −120 −100 −80 −60 −40 −20 0 20 40 60 80 100 120 140 160 180 200 220 240 260 280 300 320 340 360 380 400 420 440 460 480 500 520 540 560 580 600
Copyright 2004, Industrial Press, Inc., New York, NY
−750 −725 −700 −675 −650 −625 −600 −575 −550 −525 −500 −475 −450 −425 −400 −375 −350 −325 −300 −275 −250 −225 −200 −175 −150 −125 −100 −75 −50 −25 0 25 50 75 100 125 150 175 200 225 250 275 300 325 350 375 400 425 450 475 500 525 550 575 600 625 650 675 700 725 750
30
−900 −870 −840 −810 −780 −750 −720 −690 −660 −630 −600 −570 −540 −510 −480 −450 −420 −390 −360 −330 −300 −270 −240 −210 −180 −150 −120 −90 −60 −30 0 30 60 90 120 150 180 210 240 270 300 330 360 390 420 450 480 510 540 570 600 630 660 690 720 750 780 810 840 870 900
Machinery's Handbook 27th Edition SPECIFIC GRAVITY
407
Properties of Mass and Weight Specific Gravity.—Specific gravity is a number indicating how many times a certain volume of a material is heavier than an equal volume of water. The density of water differs slightly at different temperatures, so the usual custom is to make comparisons on the basis that the water has a temperature of 62°F. The weight of 1 cubic inch of pure water at 62°F is 0.0361 pound. If the specific gravity of any material is known, the weight of a cubic inch of the material, therefore, can be found by multiplying its specific gravity by 0.0361. To find the weight per cubic foot of a material, multiply the specific gravity by 62.355. If the weight of a cubic inch of a material is known, the specific gravity is found by dividing the weight per cubic inch by 0.0361. Example:Given the specific gravity of cast iron is 7.2. Then, the weight of 5 cubic inches of cast iron = 7.2 × 0.0361 × 5 = 1.2996 pounds. Example:Given the weight of a cubic inch of gold is 0.697 pound. Then, the specific gravity of gold = 0.697 ÷ 0.0361 = 19.31 If the weight per cubic foot of a material is known, the specific gravity is found by multiplying this weight by 0.01604. Table 15. Average Specific Gravity of Various Substances Specific Gravity
a Weight
Substance
lb/ft3
Substance
Specific Gravity
aWeight
lb/ft3
Specific Gravity
aWeight
Substance ABS Acrylic Aluminum bronze Aluminum, cast Aluminum, wrought Asbestos Asphaltum Borax Brick, common Brick, fire Brick, hard Brick, pressed Brickwork, in cement Brickwork, in mortar CPVC Cement, Portland (set) Chalk Charcoal Coal, anthracite Coal, bituminous Concrete Earth, loose Earth, rammed Emery
1.05 1.19 7.8 2.6 2.7 2.4 1.4 1.8 1.8 2.3 2.0 2.2 1.8 1.6 1.55 3.1 2.3 0.4 1.5 1.3 2.2 … … 4.0
66 74 486 160 167 150 87 112 112 143 125 137 112 100 97 193 143 25 94 81 137 75 100 249
Glass Glass, crushed Gold, 22 carat fine Gold, pure Granite Gravel Gypsum Ice Iron, cast Iron, wrought Iron slag Lead Limestone Marble Masonry Mercury Mica Mortar Nickel, cast Nickel, rolled Nylon 6, Cast PTFE Phosphorus Plaster of Paris
2.6 … 17.5 19.3 2.7 … 2.4 0.9 7.2 7.7 2.7 11.4 2.6 2.7 2.4 13.56 2.8 1.5 8.3 8.7 1.16 2.19 1.8 1.8
162 74 1091 1204 168 109 150 56 447 479 168 711 162 168 150 845.3 175 94 517 542 73 137 112 112
Platinum Polycarbonate Polyethylene Polypropylene Polyurethane Quartz Salt, common Sand, dry Sand, wet Sandstone Silver Slate Soapstone Steel Sulfur Tar, bituminous Tile Trap rock Water at 62°F White metal Zinc, cast Zinc, sheet … …
21.5 1.19 0.97 0.91 1.05 2.6 … … … 2.3 10.5 2.8 2.7 7.9 2.0 1.2 1.8 3.0 1.0 7.3 6.9 7.2 … …
1342 74 60 57 66 162 48 100 125 143 656 175 168 491 125 75 112 187 62.355 457 429 450 … …
lb/ft3
a The weight per cubic foot is calculated on the basis of the specific gravity except for those substances that occur in bulk, heaped, or loose form. In these instances, only the weights per cubic foot are given because the voids present in representative samples make the values of the specific gravities inaccurate.
Specific Gravity of Gases.—The specific gravity of gases is the number that indicates their weight in comparison with that of an equal volume of air. The specific gravity of air is 1, and the comparison is made at 32°F. Values are given in Table 16. Specific Gravity of Liquids.—The specific gravity of liquids is the number that indicates how much a certain volume of the liquid weighs compared with an equal volume of water, the same as with solid bodies. Specific gravity of various liquids is given in Table 17. The density of liquid is often expressed in degrees on the hydrometer, an instrument for determining the density of liquids, provided with graduations made to an arbitrary scale. The hydrometer consists of a glass tube with a bulb at one end containing air, and arranged with a weight at the bottom so as to float in an upright position in the liquid, the density of
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 408
SPECIFIC GRAVITY Table 16. Specific Gravity of Gases At 32°F Gas
Sp. Gr. 1.000 0.920 1.601 0.592 1.520 0.967 2.423
Aira Acetylene Alcohol vapor Ammonia Carbon dioxide Carbon monoxide Chlorine
Gas Ether vapor Ethylene Hydrofluoric acid Hydrochloric acid Hydrogen Illuminating gas Mercury vapor
Sp. Gr. 2.586 0.967 2.370 1.261 0.069 0.400 6.940
Gas Marsh gas Nitrogen Nitric oxide Nitrous oxide Oxygen Sulfur dioxide Water vapor
Sp. Gr. 0.555 0.971 1.039 1.527 1.106 2.250 0.623
a 1 cubic foot of air at 32°F and atmospheric pressure weighs 0.0807 pound.
which is to be measured. The depth to which the hydrometer sinks in the liquid is read off on the graduated scale. The most commonly used hydrometer is the Baumé, see Table 18. The value of the degrees of the Baumé scale differs according to whether the liquid is heavier or lighter than water. The specific gravity for liquids heavier than water equals 145 ÷ (145 − degrees Baumé). For liquids lighter than water, the specific gravity equals 140 ÷ (130 + degrees Baumé). Table 17. Specific Gravity of Liquids Liquid Acetic acid Alcohol, commercial Alcohol, pure Ammonia Benzine Bromine Carbolic acid Carbon disulfide Cotton-seed oil Ether, sulfuric
Sp. Gr. 1.06 0.83 0.79 0.89 0.69 2.97 0.96 1.26 0.93 0.72
Liquid Fluoric acid Gasoline Kerosene Linseed oil Mineral oil Muriatic acid Naphtha Nitric acid Olive oil Palm oil
Sp. Gr. 1.50 0.70 0.80 0.94 0.92 1.20 0.76 1.50 0.92 0.97
Liquid Petroleum oil Phosphoric acid Rape oil Sulfuric acid Tar Turpentine oil Vinegar Water Water, sea Whale oil
Sp. Gr. 0.82 1.78 0.92 1.84 1.00 0.87 1.08 1.00 1.03 0.92
Table 18. Degrees on Baumé’s Hydrometer Converted to Specific Gravity Deg. Baumé 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26
Specific Gravity for Liquids Heavier than Lighter than Water Water 1.000 1.007 1.014 1.021 1.028 1.036 1.043 1.051 1.058 1.066 1.074 1.082 1.090 1.099 1.107 1.115 1.124 1.133 1.142 1.151 1.160 1.169 1.179 1.189 1.198 1.208 1.219
… … … … … … … … … … 1.000 0.993 0.986 0.979 0.972 0.966 0.959 0.952 0.946 0.940 0.933 0.927 0.921 0.915 0.909 0.903 0.897
Deg. Baumé 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53
Specific Gravity for Liquids Heavier than Lighter Water than Water 1.229 1.239 1.250 1.261 1.272 1.283 1.295 1.306 1.318 1.330 1.343 1.355 1.368 1.381 1.394 1.408 1.422 1.436 1.450 1.465 1.480 1.495 1.510 1.526 1.542 1.559 1.576
0.892 0.886 0.881 0.875 0.870 0.864 0.859 0.854 0.849 0.843 0.838 0.833 0.828 0.824 0.819 0.814 0.809 0.805 0.800 0.796 0.791 0.787 0.782 0.778 0.773 0.769 0.765
Deg. Baumé 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80
Specific Gravity for Liquids Heavier Lighter than Water than Water 1.593 1.611 1.629 1.648 1.667 1.686 1.706 1.726 1.747 1.768 1.790 1.813 1.836 1.859 1.883 1.908 1.933 1.959 1.986 2.014 2.042 2.071 2.101 2.132 2.164 2.197 2.230
Copyright 2004, Industrial Press, Inc., New York, NY
0.761 0.757 0.753 0.749 0.745 0.741 0.737 0.733 0.729 0.725 0.721 0.718 0.714 0.710 0.707 0.704 0.700 0.696 0.693 0.689 0.686 0.683 0.679 0.676 0.673 0.669 0.666
Machinery's Handbook 27th Edition WEIGHT OF PILES
409 lb/ft3;
Average Weights and Volumes of Solid Fuels.—Anthracite coal, 55–65 34–41 ft3/ton (2240 lb); 67 lb/bushel. Bituminous coal, 50–55 lb/ft3; 41–45 ft3/ton (2240 lb); 60 lb/bushel.Charcoal, 8–18.5 lb/ft3; 120–124 ft3/ton (2240 lb); 20 lb/bushel. Coke, 28 lb/ft3; 80 ft3/ton (2240 lb); 40 lb/bushel. How to Estimate the Weight of Natural Piles.—To calculate the upper and lower limits of the weight of a substance piled naturally on a circular plate, so as to form a cone of material, use the equation: W = MD 3 (1) where W = weight, lb; D = diameter of plate, ft. (Fig. 1a); and, M = materials factor, whose upper and lower limits are given in Table 19b. For a rectangular plate, calculate the weight of material piled naturally by means of the following equation: W = MRA 3 (2) where A and B = the length and width in ft., respectively, of the rectangular plate in Fig. 1b, with B ≤ A; and, R = is a factor given in Table 19a as a function of the ratio B/A. Example:Find the upper and lower limits of the weight of dry ashes piled naturally on a plate 10 ft. in diameter. Using Equation (1), M = 4.58 from Table 19b, the lower limit W = 4.58 × 103 = 4,580 lb. For M = 5.89, the upper limit W = 5.89 × 103 = 5,890 lb. Example:What weight of dry ashes rests on a rectangular plate 10 ft. by 5 ft.? For B/A = 5/10 = 0.5, R = 0.39789 from Table 19a. Using Equation (2), for M = 4.58, the lower limit W = 4.58 × 0.39789 × 103 = 1,822 lb. For M = 5.89, the upper limit W = 5.89 × 0.39789 × 103 = 2,344lb.
B
A D
Fig. 1a. Conical Pile
Fig. 1b. Rectangular Pile
Table 19a. Factor R as a function of B/A (B ≤ A) B/A
R
B/A
R
B/A
R
B/A
R
B/A
R
B/A
R
0.01 0.02 0.03 0.04 0.05 0.06 0.07 0.08 0.09 0.10 0.11 0.12 0.13 0.14 0.15 0.16 0.17
0.00019 0.00076 0.00170 0.00302 0.00470 0.00674 0.00914 0.01190 0.01501 0.01846 0.02226 0.02640 0.03088 0.03569 0.04082 0.04628 0.05207
0.18 0.19 0.20 0.21 0.22 0.23 0.24 0.25 0.26 0.27 0.28 0.29 0.30 0.31 0.32 0.33 0.34
0.05817 0.06458 0.07130 0.07833 0.08566 0.09329 0.10121 0.10942 0.11792 0.12670 0.13576 0.14509 0.15470 0.16457 0.17471 0.18511 0.19576
0.35 0.36 0.37 0.38 0.39 0.40 0.41 0.42 0.43 0.44 0.45 0.46 0.47 0.48 0.49 0.50 0.51
0.20666 0.21782 0.22921 0.24085 0.25273 0.26483 0.27717 0.28973 0.30252 0.31552 0.32873 0.34216 0.35579 0.36963 0.38366 0.39789 0.41231
0.52 0.53 0.54 0.55 0.56 0.57 0.58 0.59 0.60 0.61 0.62 0.63 0.64 0.65 0.66 0.67 0.68
0.42691 0.44170 0.45667 0.47182 0.48713 0.50262 0.51826 0.53407 0.55004 0.56616 0.58243 0.59884 0.61539 0.63208 0.64891 0.66586 0.68295
0.69 0.70 0.71 0.72 0.73 0.74 0.75 0.76 0.77 0.78 0.79 0.80 0.81 0.82 0.83 0.84 0.85
0.70015 0.71747 0.73491 0.75245 0.77011 0.78787 0.80572 0.82367 0.84172 0.85985 0.87807 0.89636 0.91473 0.93318 0.95169 0.97027 0.98891
0.86 0.87 0.88 0.89 0.90 0.91 0.92 0.93 0.94 0.95 0.96 0.97 0.98 0.99 1.00 … …
1.00761 1.02636 1.04516 1.06400 1.08289 1.10182 1.12078 1.13977 1.15879 1.17783 1.19689 1.21596 1.23505 1.25414 1.27324 … …
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 410
WEIGHT OF PILES Table 19b. Limits of Factor M for Various Materials Material
Factor M
Material
Factor M
Material
Factor M
Almonds, whole Aluminum chips Aluminum silicate Ammonium chloride Asbestos, shred Ashes, dry Ashes, damp Asphalt, crushed Bakelite, powdered Baking powder Barium carbonate Bauxite, mine run Beans, navy, dry Beets, sugar, shredded Bicarbonate of soda Borax Boric acid Bronze chips Buckwheat Calcium lactate Calcium oxide (lime) Carbon, ground Casein Cashew nuts Cast iron chips Cement, Portland Cinders, coal Clay, blended for tile Coal, anthracite, chestnut Coal, bituminous, sized Coal, ground Cocoa, powdered Coconut, shredded Coffee beans
2.12–3.93 0.92–1.96 3.7–6.41 3.93–6.81 2.62–3.27 4.58–5.89 6.24–7.80 3.4–5.89 3.93–5.24 3.1–5.37 9.42 5.9–6.69 3.63 0.47–0.55 3.10 3.78–9.16 4.16–7.20 3.93–6.54 2.8–3.17 3.4–3.8 3.30 2.51 2.72–4.71 4.19–4.84 17.02–26.18 6.8–13.09 3.02–5.24 5.89 2.43 2.64–4.48 2.90 3.93–4.58 2.62–2.88 2.42–5.89
Coffee, ground Coke, pulverized Copper oxide, powdered Cork, granulated Corn on cob Corn sugar Cottonseed, dry, de–linted Diatoinaceous earth Dicalcium phosphate Ebonite, crushed Epsoin salts Feldspar, ground Fish scrap Flour Flue dust Flourspar (Flourite) Graphite, flake Gravel Gypsum, calcined Hominy Hops, dry Kaolin clay Lead silicate, granulated Lead sulphate, pulverized Lime ground Limestone, crushed Magnesium chloride Malt, dry, ground Manganese sulphate Marble, crushed Mica, ground Milk, whole, powdered Oats Orange peel, dry
1.89–3.27 2.21 20.87 1.57–1.96 1.29–1.33 2.34–4.06 1.66–5.24 0.83–1.83 5.63 4.91–9.16 3.02–6.54 8.51–9.16 5.24–6.54 5.61–10.43 2.65–3.40 10.73–14.40 3.02–5.24 6.8–13.18 6.04–6.59 2.8–6.54 4.58 12.32–21.34 25.26 24.09 7.85 6.42–11.78 4.32 1.66–2.88 5.29–9.16 6.8–12.44 1.24–1.43 2.62 1.74–2.86 1.96
Peanuts, unshelled Peanuts, shelled Peas, dry Potassium carbonate Potasiuin sulphate Pumice Rice, bran Rubber, scrap, ground Salt, dry, coarse Salt, dry, fine Saltpeter Salt rock, crushed Sand, very fine Sawdust, dry Sesame seed Shellac, powdered Slag, furnace, granular Soap powder Sodium nitrate Sodium sulphite Sodium sulphate Soybeans Steel chips, crushed Sugar, refined Sulphur Talcum powder Tin oxide, ground Tobacco stems Trisodium phosphate Walnut shells, crushed Wood chips, fir Zinc sulphate … …
1.13–3.14 2.65–5.89 2.75–3.05 3.85–6.68 5.5–6.28 5.24–5.89 1.51–2.75 2.11–4.58 3.02–8.38 5.29–10.47 6.05–10.47 4.58 7.36–9 0.95–2.85 2.04–4.84 2.34–4.06 4.53–8.51 1.51–3.27 3.96–4.66 10.54 6.92 3.48–6.28 7.56–19.63 3.78–7.2 4.5–6.95 4.37–5.9 9.17 1.96–3.27 4.53–7.85 2.65–5.24 2.49–2.88 8.85–11.12 … …
Earth or Soil Weight.—Loose earth has a weight of approximately 75 pounds per cubic foot and rammed earth, 100 pounds per cubic foot. The solid crust of the earth, according to an estimate, is composed approximately of the following elements: Oxygen, 44.0 to 48.7 per cent; silicon, 22.8 to 36.2 per cent; aluminum, 6.1 to 9.9 per cent; iron, 2.4 to 9.9 per cent; calcium, 0.9 to 6.6 per cent; magnesium, 0.1 to 2.7 per cent; sodium, 2.4 to 2.5 per cent; potassium, 1.7 to 3.1 per cent. Molecular Weight.—The smallest mass of a chemical combination which can be conceived of as existing and yet preserving its chemical properties is known as a molecule. The molecular weight of a chemical compound is equal to the sum of the atomic weights of the atoms contained in the molecule, and are calculated from the atomic weights, when the symbol of the compound is known. The atomic weight of silver is 107.88; of nitrogen, 14.01; and of oxygen, 16; hence, the molecular weight of silver-nitrate, the chemical formula of which is AgNO3 equals 107.88 + 14.01 + (3 × 16) = 169.89. Mol.—The term “mol” is used as a designation of quantity in electro-chemistry, and indicates the number of grams of a substance equal to its molecular weight. For example, one mol of siliver-nitrate equals 169.89 grams, the molecular weight of silver-nitrate being 169.89.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition WOOD
411
PROPERTIES OF WOOD, CERAMICS, PLASTICS, METALS, WATER, AND AIR Properties of Wood Mechanical Properties of Wood.—Wood is composed of cellulose, lignin, ash-forming minerals, and extractives formed into a cellular structure. (Extractives are substances that can be removed from wood by extraction with such solvents as water, alcohol, acetone, benzene, and ether.) Variations in the characteristics and volumes of the four components and differences in the cellular structure result in some woods being heavy and some light, some stiff and some flexible, and some hard and some soft. For a single species, the properties are relatively constant within limits; therefore, selection of wood by species alone may sometimes be adequate. However, to use wood most effectively in engineering applications, the effects of physical properties or specific characteristics must be considered. The mechanical properties listed in the accompanying Table 1 were obtained from tests on small pieces of wood termed “clear” and “straight grained” because they did not contain such characteristics as knots, cross grain, checks, and splits. However, these test pieces did contain such characteristics as growth rings that occur in consistent patterns within the piece. Since wood products may contain knots, cross grain, etc., these characteristics must be taken into account when assessing actual properties or when estimating actual performance. In addition, the methods of data collection and analysis have changed over the years during which the data in Table 1 have been collected; therefore, the appropriateness of the data should be reviewed when used for critical applications such as stress grades of lumber. Wood is an orthotropic material; that is, its mechanical properties are unique and independent in three mutually perpendicular directions—longitudinal, radial, and tangential. These directions are illustrated in the following figure.
Modulus of Rupture: The modulus of rupture in bending reflects the maximum load-carrying capacity of a member and is proportional to the maximum moment borne by the member. The modulus is an accepted criterion of strength, although it is not a true stress because the formula used to calculate it is valid only to the proportional limit. Work to Maximum Load in Bending: The work to maximum load in bending represents the ability to absorb shock with some permanent deformation and more or less injury to a specimen; it is a measure of the combined strength and toughness of the wood under bending stress. Maximum Crushing Strength: The maximum crushing strength is the maximum stress sustained by a compression parallel-to-grain specimen having a ratio of length to least diameter of less than 11. Compression Perpendicular to Grain: Strength in compression perpendicular to grain is reported as the stress at the proportional limit because there is no clearly defined ultimate stress for this property.
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Shear Strength Parallel to Grain: Shear strength is a measure of the ability to resist internal slipping of one part upon another along the grain. The values listed in the table are averages of the radial and tangential shears. Tensile Strength Perpendicular to Grain: The tensile strength perpendicular to the grain is a measure of the resistance of wood to forces acting across the grain that tend to split the material. Averages of radial and tangential measurements are listed. Table 1. Mechanical Properties of Commercially Important U.S. Grown Woods Static Bending
Use the first number in each column for GREEN wood; use the second number for DRY wood.
Modulus of Rupture (103 psi)
Basswood, American Cedar, N. white Cedar, W. red Douglas Fir, coasta Douglas Fir, interior W. Douglas Fir, interior N. Douglas Fir, interior S. Fir, balsam Hemlock, Eastern Hemlock, Mountain Hemlock, Western Pine, E. white Pine, Virginia Pine, W. white Redwood, old-growth Redwood, young-growth Spruce, Engelmann Spruce, red Spruce, white
5.0 4.2 5.2 7.7 7.7 7.4 6.8 5.5 6.4 6.3 6.6 4.9 7.3 4.7 7.5 5.9 4.7 6.0 5.0
Work to Max Load (in.-lb/in.3)
8.7 5.3 6.5 5.7 7.5 5.0 12.4 7.6 12.6 7.2 13.1 8.1 11.9 8.0 9.2 4.7 8.9 6.7 11.5 11.0 11.3 6.9 9.9 5.2 13.0 10.9 9.7 5.0 10.0 7.4 7.9 5.7 9.3 5.1 10.8 6.9 9.4 6.0
7.2 4.8 5.8 9.9 10.6 10.5 9.0 5.1 6.8 10.4 8.3 8.3 13.7 8.8 6.9 5.2 6.4 8.4 7.7
Maximum Crushing Strength (103 psi)
Compression Strength Perpendicular to Grain (psi)
2.22 1.90 2.77 3.78 3.87 3.47 3.11 2.63 3.08 2.88 3.36 2.44 3.42 2.43 4.20 3.11 2.18 2.72 2.35
170 230 240 380 420 360 340 190 360 370 280 220 390 190 420 270 200 260 210
4.73 3.96 4.56 7.23 7.43 6.90 6.23 5.28 5.41 6.44 7.20 5.66 6.71 5.04 6.15 5.22 4.48 5.54 5.18
370 310 460 800 760 770 740 404 650 860 550 580 910 470 700 520 410 550 430
Shear Strength Parallel to Grain (psi) 600 620 770 900 940 950 950 662 850 930 860 680 890 680 800 890 640 750 640
990 850 990 1,130 1,290 1,400 1,510 944 1,060 1,540 1,290 1,170 1,350 1,040 940 1,110 1,200 1,290 970
Tensile Strength Perp. to Grain (psi) 280 240 230 300 290 340 250 180 230 330 290 250 400 260 260 300 240 220 220
350 240 220 340 350 390 330 180 … … 340 420 380 … 240 250 350 350 360
a Coast: grows west of the summit of the Cascade Mountains in OR and WA. Interior west: grows in CA and all counties in OR and WA east of but adjacent to the Cascade summit. Interior north: grows in remainder of OR and WA and ID, MT, and WY. Interior south: grows in UT, CO, AZ, and NM.
Results of tests on small, clear, straight-grained specimens. Data for dry specimens are from tests of seasoned material adjusted to a moisture content of 12%. Source:U.S. Department of Agriculture:Wood Handbook.
Weight of Wood.—The weight of seasoned wood per cord is approximately as follows, assuming about 70 cubic feet of solid wood per cord: beech, 3300 pounds; chestnut, 2600 pounds; elm, 2900 pounds; maple, 3100 pounds; poplar, 2200 pounds; white pine, 2200 pounds; red oak, 3300 pounds; white oak, 3500 pounds. For additional weights of green and dry woods, see Table 2. Weight per Foot of Wood, Board Measure.—The following is the weight in pounds of various kinds of woods, commercially known as dry timber, per foot board measure: white oak, 4.16; white pine, 1.98; Douglas fir, 2.65; short-leaf yellow pine, 2.65; red pine, 2.60; hemlock, 2.08; spruce, 2.08; cypress, 2.39; cedar, 1.93; chestnut, 3.43; Georgia yellow pine, 3.17; California spruce, 2.08. For other woods, divide the weight/ft3 from Table 2 by 12 to obtain the approximate weight per board foot. Effect of Pressure Treatment on Mechanical Properties of Wood.—The strength of wood preserved with creosote, coal-tar, creosote-coal-tar mixtures, creosote-petroleum mixtures, or pentachlorophenol dissolved in petroleum oil is not reduced. However, waterborne salt preservatives contain chemicals such as copper, arsenic, chromium, and ammonia, which have the potential of affecting mechanical properties of treated wood and
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causing mechanical fasteners to corrode. Preservative salt-retention levels required for marine protection may reduce bending strength by 10 per cent or more. Density of Wood.—The following formula can be used to find the density of wood in lb/ft3 as a function of its moisture content. M⎞ G ⎞ ⎛ 1 + -------ρ = 62.4 ⎛ -------------------------------------------⎝ 1 + G × 0.009 × M⎠ ⎝ 100⎠ where ρ is the density, G is the specific gravity of wood, and M is the moisture content expressed in per cent.
35 54 53 56 45 46 45 50 50 41 62 63 61 48 58 47 54 50 45 56
30 35 44 37 25 27 35 34 28 29 45 51 … 36 48 34 40 38 33 44
Species Oak, red Oak, white Pine, lodgepole Pine, northern white Pine, Norway Pine, ponderosa Pines, southern yellow: Pine, loblolly Pine, longleaf Pine, shortleaf Pine, sugar Pine, western white Poplar, yellow Redwood Spruce, eastern Spruce, Engelmann Spruce, Sitka Sycamore Tamarack Walnut, black
Green
Species Douglas fir, Rocky Mt. region Elm, American Elm, rock Elm, slippery Fir, balsam Fir, commercial white Gum, black Gum, red Hemlock, eastern Hemlock, western Hickory, pecan Hickory, true Honeylocust Larch, western Locust, black Maple, bigleaf Maple, black Maple, red Maple, silver Maple, sugar
Airdry
28 34 41 38 26 26 45 44 38 31 33 22 23 23 35 30 28 24 32 34
Green
46 52 48 46 43 42 54 57 50 36 37 28 26 27 45 55 49 46 51 38
Airdry
Green
Species Alder, red Ash, black Ash, commercial white Ash, Oregon Aspen Basswood Beech Birch Birch, paper Cedar, Alaska Cedar, eastern red Cedar, northern white Cedar, southern white Cedar, western red Cherry, black Chestnut Cottonwood, eastern Cottonwood, northern black Cypress, southern Douglas fir, coast region
Airdry
Table 2. Weights of American Woods, in Pounds per Cubic Foot
64 63 39 36 42 45
44 47 29 25 34 28
53 55 52 52 35 38 50 34 39 33 52 47 58
36 41 36 25 27 28 28 28 23 28 34 37 38
Source: United States Department of Agriculture
Machinability of Wood.—The ease of working wood with hand tools generally varies directly with the specific gravity of the wood; the lower the specific gravity, the easier the wood is to cut with a sharp tool. A rough idea of the specific gravity of various woods can be obtained from the preceding table by dividing the weight of wood in lb/ft3 by 62.355. A wood species that is easy to cut does not necessarily develop a smooth surface when it is machined. Three major factors, other than specific gravity, influence the smoothness of the surface obtained by machining: interlocked and variable grain, hard deposits in the grain, and reaction wood. Interlocked and variable grain is a characteristic of many tropical and some domestic species; this type of grain structure causes difficulty in planing quarter sawn boards unless careful attention is paid to feed rates, cutting angles, and sharpness of the knives. Hard deposits of calcium carbonate, silica, and other minerals in the grain tend to dull cutting edges quickly, especially in wood that has been dried to the usual in service moisture content. Reaction wood results from growth under some physical stress such as occurs in leaning trunks and crooked branches. Generally, reaction wood occurs as tension wood in hardwoods and as compression wood in softwoods. Tension wood is particularly troublesome, often resulting in fibrous and fuzzy surfaces, especially in woods of lower density. Reaction wood may also be responsible for pinching saw blades, resulting in burning and dulling of teeth. The Table 3 rates the suitability of various domestic hardwoods for machining. The data for each species represent the percentage of pieces machined that successfully met the listed quality requirement for the processes. For example, 62 per cent of the black walnut
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pieces planed came out perfect, but only 34 per cent of the pieces run on the shaper achieved good to excellent results. Table 3. Machinability and Related Properties of Various Domestic Hardwoods Planing
Shaping
Type of Wood
Perfect
Good to Excellent
Alder, red Ash Aspen Basswood Beech Birch Birch, paper Cherry, black Chestnut Cottonwood Elm, soft Hackberry Hickory Magnolia Maple, bigleaf Maple, hard Maple, soft Oak, red Oak, white Pecan Sweetgum Sycamore Tanoak Tupelo, black Tupelo, water Walnut, black Willow Yellow-poplar
61 75 26 64 83 63 47 80 74 21 33 74 76 65 52 54 41 91 87 88 51 22 80 48 55 62 52 70
20 55 7 10 24 57 22 80 28 3 13 10 20 27 56 72 25 28 35 40 28 12 39 32 52 34 5 13
Turning Boring Quality Required Fair to Good to Excellent Excellent 88 79 65 68 90 80 … 88 87 70 65 77 84 79 8 82 76 84 85 89 86 85 81 75 79 91 58 81
Mortising
Sanding
Fair to Excellent
Good to Excellent
52 58 60 51 92 97 … 100 70 52 75 72 98 32 80 95 34 95 99 98 53 96 100 24 33 98 24 63
… 75 … 17 49 34 … … 64 19 66 … 80 37 … 38 37 81 83 … 23 21 … 21 34 … 24 19
64 94 78 76 99 97 … 100 91 70 94 99 100 71 100 99 80 99 95 100 92 98 100 82 62 100 71 87
The data above represent the percentage of pieces attempted that meet the quality requirement listed.
Nominal and Minimum Sizes of Sawn Lumber Type of Lumber
Thickness (inches) Nominal, Tn
3⁄ 4
Face Widths (inches) Green
Nominal, Wn
Dry
Green
2 to 4
Wn − 1⁄2
Wn − 7⁄16
5 to 7
Wn − 1⁄2
Wn − 3⁄8
8 to 16
Wn − 3⁄4
Wn − 1⁄2
2 to 4
Wn − 1⁄2
Wn − 7⁄16
11⁄4
1
11⁄2
11⁄4
25⁄ 32 11⁄32 19⁄32
2
11⁄2
19⁄16
1 Boards
Dry
21⁄2
2
21⁄16
5 to 6
Wn − 1⁄2
Wn − 3⁄8
Dimension
3
21⁄2
29⁄16
8 to 16
Wn − 3⁄4
Wn − 1⁄2
Lumber
31⁄2
3
31⁄16
…
…
…
4
31⁄2
39⁄16
…
…
…
41⁄2
4
41⁄16
…
…
…
…
Tn − 1⁄2
5 and up
…
Wn − 1⁄2
Timbers
5 and up
Source: National Forest Products Association: Design Values for Wood Construction. Moisture content: dry lumber ≤ 19%; green lumber > 19%. Dimension lumber refers to lumber 2 to 4 inches thick (nominal) and 2 inches or greater in width. Timbers refers to lumber of approximately square cross-section, 5 × 5 inches or larger, and a width no more than 2 inches greater than the thickness.
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Machinery's Handbook 27th Edition
Tabulated Properties of Ceramics, Plastics, and Metals Typical Properties of Ceramics Materials Material Machinable Glass Ceramic
Glass-Mica
Machining Grades
Aluminum Silicate Alumina Silicate Silica Foam TiO2 (Titania) Lava (Grade A) Zirconium Phosphate ZrO2 ZrO2·SiO2 (Zircon)
2MgO·2Al2O3·5SiO2 (Cordierite)
(Alumina)
Flexural Strength (103 psi)
Mohs’s Hardnessc
Operating Temperature (°F)
Tensile Strength (103 psi)
Compressive Strength (103 psi)
Thermal Conductivityd (Btu-ft-hr-ft2-°F)
0.09 0.11 0.10 0.09–0.10 0.10 0.13–0.17 0.14 0.10 0.08 0.08 0.03 0.14
1000 400 380 400 380 300–325 350 80 100 70 80 100
4.1–7.0 6 5.2 10.5–11.2 9.4 11–11.5 10.3 2.5 2.9 … 0.3 4.61
15 14 12.5–13 11 9–10 9 4.5 10 … 0.4 20
48 Ra 5.5 5.0 90 Rh 90 Rh 90 Rh 90 Rh 1–2 6.0 … NA 8
1472 700 1100 750 1100 700–750 1300 1000 2100 2370 2000 1800
… … … 6 5 6–6.5 6 … … … … 7.5
50 40 32 40–45 32 33–35 30 12 25 … 1.4 100
0.85 0.24 0.34 0.24–0.29 0.34 0.29–0.31 0.3 0.92 0.75 0.38 0.10 …
0.08 0.11 0.21
80 NA …
1.83 0.5 6.1
9 7.5 102
6 NA 1300 V
2000 2800 …
2.5 … …
40 30 261
0.92 0.4 (approx.) 1.69
0.11
2MgO·SiO2 (Forsterite) MgO·SiO2 (Steatite)
Al2O3
Coeff. of Expansionb (10−6 in./in.-°F)
94% 96% 99.5% 99.9%
220
1.94
16
7.5
1825
10
90
…
0.11
240
5.56
20
7.5
1825
10
85
4.58
0.09–0.10
210–240
3.83–5.44
18–21
7.5
1825
8.5–10
80–90
3.17–3.42
0.06 0.08 0.09 0.13
60 100–172 200 210
0.33 1.22–1.28 1.33 3.33
3.4 8–12 15 44
6.5 7–7.5 8 9
2000 2000 2000 2700
2.5 3.5–3.7 4 20
18.5 30–40 50 315
1.00 1.00 1.83 16.00
0.13–0.14 0.14 0.14
210 200 …
3.5–3.7 3.72 3.75
48–60 70 72
9 9 9
2600–2800 2700 2900
25 28 …
375 380 400
20.3–20.7 21.25 …
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a Obtain specific gravity by dividing density in lb/in.3 by 0.0361; for density in lb/ft3, multiply lb/in.3 by 1728; for g/cm3, multiply density in lb/in.3 by 27.68; for kg/m3, multiply density in lb/in.3 by 27,679.9. b To convert coefficient of expansion to 10−6 in./in.-°C, multiply table value by 1.8. c Mohs’s Hardness scale is used unless otherwise indicated as follows: Ra and Rh for Rockwell A and H scales, respectively; V for Vickers hardness. d To convert conductivity from Btu-ft/hr-ft2-°F to cal-cm/sec-cm2-°C, divide by 241.9.
PROPERTIES OF CERAMICS
Molding Grades
Densitya (lb/in.3)
Dielectric Strength (V/mil)
Machinery's Handbook 27th Edition
Material
Specific Gravity
0.038 0.037 0.056 0.051 0.051 0.043 0.043 0.056 0.067 0.050 0.042 0.047 0.041 0.042 0.049 0.079 0.050 0.064 0.050 0.043 0.046 0.035 0.034 0.030 0.051 0.047 0.033 0.045 0.038
1.05 1.03 1.55 1.41 1.41 1.19 1.19 1.55 1.87 1.39 1.16 1.30 1.14 1.16 1.36 2.19 1.39 1.77 1.38 1.19 1.27 0.97 0.94 0.83 1.41 1.30 0.91 1.25 1.05
… … … 380 … 500 500 … … … 295 … 600 … 1300 480 500 260 … 380 480 475 710 … 560 380 600 425 …
Coeff. of Expansionb (10−6 in/in-°F)
Tensile Modulus (103 psi)
Izod Impact (ft-lb/in of notch)
Flexural Modulus (ksi at 73°F)
% Elongation
Hardnessc
Max. Operating Temp. (°F)
53.0 … … 47.0 58.0 35.0 15.0 34.0 11.1 … 45.0 … 45.0 … 39.0 50.0 29.5 60.0 11.1 37.5 … 20.0 19.0 … … … 96.0 31.0 …
275 200 1000 437 310 400 750 400 … 1350 380 … 390 … 500 225 550 320 … 345 430 156 110 220 300 … 155 360 …
7 … 0.9 2 … 0.5 14 3 8 2.8 1.4 … 1 2.2 0.5 3 0.8 3 2.4 14 1.1 6 No Break 2.5 1.5 0.5 0.75 1.2 …
300 330 715 400 320 400 800 400 1 1400 450 … … … 400 80 400 200 1000 340 480 160 130 … … 550 200 390 …
… … … 13 … 2.7 2.1 4 … … 20 … 240 … 70 350 31–40 80 … 110 … 900 450 … … … 120 50 465–520
105 Rr 105 Rr 94 Rm 94 Rm 94 Rm 94 Rm 94 Rm … 101 Rm 119 Rr 100 Rr … 118 Rr … … … 110 Rr 100 Rr 100 Rm 74 Rm … … 64 Rr … … … 92 Rr 120 Rr …
200 … … … 200 180 311 212 260 … 210 … 230 … 230 … 170 180 248 290 … 180 176 … … … 150 325 …
a To obtain specific gravity, divide density in lb/in3 by 0.0361; for density in lb/ft3, multiply lb/in3 by 1728; for g/cm3, multiply density in lb/in3 by 27.68; for kg/m3, multiply density in lb/in3 by 27,679.9. b To convert coefficient of expansion to 10−6 in/in-°C, multiply table value by 1.8. c Hardness value scales are as follows: Rm for Rockwell M scale; Rr for Rockwell R scale.
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PROPERTIES OF PLASTICS
ABS, Extrusion Grade ABS, High Impact Acetal, 20% Glass Acetal, Copolymer Acetyl, Homopolymer Acrylic Azdel CPVC Fiber Glass Sheet Nylon 6, 30% Glass Nylon 6, Cast Nylon 6⁄6, Cast Nylon 6⁄6, Extruded Nylon 60L, Cast PET, unfilled PTFE (Teflon) PVC PVDF Phenolics Polycarbonate Polyetherimide Polyethylene, HD Polyethylene, UHMW Polymethylpentene Polymid, unfilled Polyphenylene Sulfide Polypropylene Polysulfone Polyurethane
Densitya (lb/in3)
416
Typical Properties of Plastics Materials Dielectric Strength (V/mil)
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Mechanical Properties of Various Investment Casting Alloys Alloy Designation
Material Condition
Tensile Strength (103 psi)
0.2% Yield Strengtha (103 psi)
% Elongation
Hardness
22–30 28–36 27–40 28–39 25–32 36–45 24–38 25–45 48–55
3–7 3–10 3–9 1–8 4–8 2–5 1.5–5 2–5 3–5
… … … … … … … … …
30–40 45–55 40–50 60–70 25–40 60–70 18 18–30 11–20 14–25 32 … 40–45 90–130 40–140 50–55 … … 20–40
10–20 6–10 6–10 5–8 16–24 8–16 20 20–35 15–25 20–30 24 4–50 15–20 3–8 1–15 18–23 1–4 15–20 20–30
80–85 Rb 91–96 Rb 91–96 Rb 93–98 Rb 60–65 Rb 95–100 Rb … 40–50 Rb … 30–35 Rb … 35–42 Rb 50–55 Rb 90–95 Rb 60 Rb–38 Rc 75–80 Rb 25–44 Rc 80–85 Rb 70–78 Rb
30–35 25–40 20–30 0–15 20–30 0–15 20–25 0–10 20–25 0–10 5–10 0–3 12–20 0–3 5–10 5–20 5–20 5–10 5–20 5–20 10–20 5–10 10–20 7–20 5–20
50–55 Rb 80 Rb 75 Rb 20–50 Rc 80 Rb 25–52 Rc 100 Rb 25–57 Rc 100 Rb 30–60 Rc 25 Rc 30–60 Rc 30 Rc 37–50 Rc 30–58 Rc 23–49 Rc 29–57 Rc 25–58 Rc 25–48 Rc 20–55 Rc 20–32 Rc 30–60 Rc 20–45 Rc 25–50 Rc 30–60 Rc
Aluminum 356 A356 A357 355, C355 D712 (40E) A354 RR-350 Precedent 71 KO-1
As Cast As Cast As Cast As Cast As Cast As Cast As Cast As Cast As Cast
32–40 38–40 33–50 35–50 34–40 47–55 32–45 35–55 56–60
Copper-Base Alloysa Al Bronze C (954) Al Bronze D (955) Manganese Bronze, A Manganese Bronze, C Silicon Bronze Tin Bronze Lead. Yellow Brass (854) Red Brass Silicon Brass Pure Copper Beryllium Cu 10C (820) Beryllium Cu 165C (824) Beryllium Cu 20C (825) Beryllium Cu 275C (828) Chrome Copper
As Cast Heat-Treated As Cast Heat-Treated … … … … … … … … As Cast Hardened … As Cast Hardened As Cast …
75–85 90–105 90–100 110–120 65–75 110–120 45 40–50 30–50 30–40 70 20–30 45–50 90–100 70–155 70–80 110–160 80–90 33–50
Carbon and Low-Alloy Steels and Iron IC 1010 IC 1020 IC 1030 IC 1035 IC 1045 IC 1050 IC 1060 IC 1090 IC 2345 IC 4130 IC 4140 IC 4150 IC 4330 IC 4340 IC 4620 IC 6150, IC 8740 IC 8620 IC 8630 IC 8640
Annealed Annealed Annealed Hardened Annealed Hardened Annealed Hardened Annealed Hardened Annealed Hardened Annealed Hardened Hardened Hardened Hardened Hardened Hardened Hardened Hardened Hardened Hardened Hardened Hardened
50–60 60–70 65–75 85–150 70–80 90–150 80–90 100–180 90–110 125–180 100–120 120–200 110–150 130–180 130–200 130–170 130–200 140–200 130–190 130–200 110–150 140–200 100–130 120–170 130–200
30–35 40–45 45–50 60–150 45–55 85–150 50–60 90–180 50–65 100–180 55–70 100–180 70–80 130–180 110–180 100–130 100–155 120–180 100–175 100–180 90–130 120–180 80–110 100–130 100–180
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Machinery's Handbook 27th Edition 418
PROPERTIES OF INVESTMENT CASTING ALLOYS Mechanical Properties of Various Investment Casting Alloys (Continued) Material Condition
Alloy Designation
Tensile Strength (103 psi)
0.2% Yield Strengtha (103 psi)
% Elongation
Hardness
140–200 110–150 140–180 100–140 37–43 40–50 70–80
0–10 7–20 1–7 6–12 30–35 18–24 3–10
… … 30–65 Rc 25–48 Rc 55 Rb 143–200 Bhn 243–303 Bhn
75–160 75–160 130–210 75–105 140–160 150–165 110–145 75–85 100–120
5–12 3–8 0–5 5–20 6–20 6–12 5–15 20–30 10–25
94 Rb–45 Rc 94 Rb–45 Rc 30–52 Rc 20–40 Rc 34–44 Rc … 26–38 Rc 94–100 Rb 28–32 Rc
40–50 32–36 30–35 30–45 30–40 25–35 30–40
35–50 30–40 35–45 35–60 30–45 35–45 35–45
90 Rb (max) 90 Rb (max) 90 Rb (max) 90 Rb (max) 90 Rb (max) 90 Rb (max) 90 Rb (max)
50–60 45–55 45–55 41–45 … 25–30 35–40 40–55 32–38 55–65 85–100 60–80 33–40 25–35
8–12 8–12 8–12 10–15 12–20 30–40 10–20 15–30 25–35 5–10 0 10–20 25–35 25–40
90–100 Rb 90–100 Rb 90 Rb–25 Rc 85–96 Rb … 50–60 Rb 80–90 Rb 10–20 Rc 65–75 Rb 20–28 Rc 32–38 Rc 20–30 Rc 67–78 Rb 65–85 Rb
65–95 60–75 75–90 60–70 70–80 50–60
8–20 15–25 6–10 15–20 8–15 15–30
24–32 Rc 20–25 Rc 20–30 Rc 30–36 Rc 25–34 Rc 90–100 Rb
Carbon and Low-Alloy Steels and Iron (Continued) IC 8665 IC 8730 IC 52100 IC 1722AS 1.2% Si Iron Ductile Iron, Ferritic Ductile Iron, Pearlitic
Hardened Hardened Hardened Hardened … Annealed Normalized
170–220 120–170 180–230 130–170 50–60 60–80 100–120
Hardenable Stainless Steel CA-15 IC 416 CA-40 IC 431 IC 17–4 Am-355 IC 15–5 CD-4M Cu
Hardened Hardened Hardened Hardened Hardened Hardened Hardened Annealed Hardened
CF-3, CF-3M, CF-8, CF-8M, IC 316F CF-8C CF-16F CF-20 CH-20 CN-7M IC 321, CK-20
Annealed Annealed Annealed Annealed Annealed Annealed Annealed
95–200 95–200 200–225 110–160 150–190 200–220 135–170 100–115 135–145
Austenitic Stainless Steels 70–85 70–85 65–75 65–75 70–80 65–75 65–75
Nickel-Base Alloys Alloy B Alloy C
RH Monel Monel E M-35 Monel
Annealed As Cast Annealed AC to 24°C AC to 816°C As Cast As Cast Annealed As Cast Annealed Hardened As Cast As Cast As Cast
Cobalt 21 Cobalt 25 Cobalt 31 Cobalt 36 F75 N-155
As Cast As Cast As Cast As Cast As Cast Sol. Anneal
Alloy Xb Invar (Fe–Ni alloy) In 600 (Inconel) In 625 (Inconel) Monel 410 S Monel
75–85 80–95 75–95 63–70 35–45 50–60 65–75 80–100 65–75 100–110 120–140 100–110 65–80 65–80
Cobalt-Base Alloys 95–130 90–120 105–130 90–105 95–110 90–100
a For copper alloys, yield strength is determined by 0.5% extension under load or 0.2% offset method. A number in parentheses following a copper alloy indicates the UNS designation of that alloy (for example, Al Bronze C (954) identifies the alloy as UNS C95400). b AC = air cooled to temperature indicated. Source: Investment Casting Institute. Mechanical properties are average values of separately cast test bars, and are for reference only. Items marked … indicates data are not available. Alloys identified by IC followed by an SAE designation number (IC 1010 steel, for example) are generally similar to the SAE material although properties and chemical composition may be different.
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Machinery's Handbook 27th Edition PROPERTIES OF POWDER METAL ALLOYS
419
Typical Properties of Compressed and Sintered Powdered Metal Alloys Strength (103 psi) Alloy Number a and Nominal Composition (%)
Density (g/cc)
Hardness
Transverse Rupture
Ultimate Tensile
Yield
% Elongation
Copper Base … CZP-3002
100Cu 70Cu, 1.5Pb, Bal. Zn
CNZ-1818 63Cu, 17.5Ni, Bal. Zn CTG-1004 10Sn, 4.4C, Bal. Cu CTG-1001 10Sn, 1C, Bal. Cu
7.7–7.9
81–82 Rh
54–68
24–34
…
10–26
8
75 Rh
…
33.9
…
24
7.9
90 Rh
73
34
20
11
7
67 Rh
20
9.4
6.5
6
6.5
45 Rh
25.8
15.1
9.6
9.7
Iron Base (Balance of composition, Fe) FC-2015
23.5Cu, 1.5C
FC-0800
8Cu, 0.4C
6.5
65 Rb
80
52.4
48.5
0
6.3–6.8
39–55 Rb
75–100
38–54
32–47
1 or less
FX-2008
20Cu, 1C
FN-0408
4Ni, 1–2Cu, 0.75C
7.3
93 Rb
164.2
72.3
57.7
2
6.3–7
64–84 Rb
70–107
37–63
30–47
1–1.6
F-0000
100Fe
6.5
FN-0005
0.45C, 0.50 MnS
6.4–6.8
26 Rf
37.7
15.7
11
5.7
66–78 Rf
44–61
…
…
F-0000
0.02C, 0.45P
6.6–7.2
35–50 Rb
…
90–125
…
29–38
3.9–5.5
F-0008
0.6–0.9C
6.2–7
FC-0508
0.6–0.9C, 4–6Cu
5.9–6.8
50–70 Rb
61–100
35–57
30–40
3
>3
1200–1800
2500–3000
Milling of Plastics: Peripheral cutting with end mills is used for edge preparation, slotting and similar milling operations, and end cutting can also be used for facing operations. Speeds for milling range from 800 to 1400 ft/min for peripheral end milling of many thermoplastics and from 400 to 800 ft/min for many thermosets. However, slower speeds are generally used for other milling operations, with some thermoplastics being machined at 300–500 ft/min, and some thermosets at 150–300 ft/min. Adequate support and suitable feed rates are very important. A table feed that is too low will generate excessive heat and cause surface cracks, loss of dimensional accuracy, and poor surface finish. Too high a feed rate will produce a rough surface. High-speed steel tools (M2, M3, M7, or T15) are generally used, but for glass-reinforced nylon, silicone, polyimide, and allyl, carbide (C2) is recommended. New Techniques: Lasers can be used for machining plastics, especially sheet laminates, although their use may generate internal stresses. Ultrasonic machining has no thermal, chemical, or electrical reaction with the workpiece and can produce holes down to 0.003 in. diameter, tight tolerances (0.0005 in.), and very smooth finishes (0.15 µin. with No. 600 boron carbide abrasive powder). Water-jet cutting using pressures up to 60,000 lb/in.2 is widely used for plastics and does not introduce stresses into the material. Tolerances of ± 0.004 in. can be held, depending on the equipment available. Process variables, pressures, feed rates, and the nozzle diameter depend on the material being cut. This method does not work with hollow parts unless they can be filled with a solid core. Development of Prototypes.—Prototypes are made for testing of properties such as stress and fatigue resistance, to find ways to improve quality and reliability, to improve tooling, and to reduce time to market. Prototyping may answer questions about finish, sink marks that result from contraction, witness lines from mold joints, ejector pin marks, knit or weld lines, texturing, moldability, shrinkage, mechanical strength, pull-out resistance of inserts, electrical properties, and problems of mating with other parts. Prototypes of moldings are made in five major steps including design; refining the design; making a model (physical or computer); making a mold; and producing parts. The model may be made from wood, plaster, plastics (by machining), or a metal. Some 90 per cent of prototypes are made by modern CAD/CAM methods that allow holding of dimensional tolerances of 2–3 per cent of drawing specifications. Prototypes can also be made by a process called stereo lithography that uses a tank of photosensitive liquid polymer, an x-y scanning, ultraviolet laser with a beam diameter of 0.010 in., a z-axis elevator platform, and a controlling computer. The platform height is adjusted so that a suitable thickness of liquid polymer covers its surface. The laser beam is focused on the liquid surface and hardens the polymer at this point by heating. The CAD representation of the prototype is described by a model in which thin (0.005– 0.020 in.) cross sections can be isolated. Data representing the lowest level of the prototype are used to move the platform so that a layer of the polymer corresponding to the lowest “slice” is hardened. The platform is then lowered, the liquid polymer flows over the hard-
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Machinery's Handbook 27th Edition PLASTICS GEAR DESIGN
625
ened layer, and the platform is again raised, less an amount equal to the next “slice.” The process is repeated for successive “slices” of the prototype, which is thus built up gradually to form a hollow, three-dimensional shape corresponding to the model in the CAD program. The part thus produced is fairly brittle but can be used for visual examination, design verification, and marketing evaluation, and can be replicated from other materials such as plastics or metals by casting or other methods. Finishing and decorating methods used for plastics parts include spray painting, vacuum metallizing, hot stamping, silk screening, and plating. Conductive coatings may be applied to inside surfaces, usually by flame- or arc-spraying, to dissipate static electricity and provide electromagnetic shielding. Thorough cleaning is essential. Materials such as polyethylene, polypropylene, and acetal have waxlike surfaces that may not be painted easily or may need pretreatment or special primers. Many amorphous plastics are easy to paint. Suitable coatings include polyurethane-, epoxy-, acrylic-, alkyd-, and vinyl-based paints. Oven curing may distort parts made from non-heat-resistant materials. Vacuum metallizing and sputter-plating require application of a special base coat and a protective clear top coat before and after treatment. Resistance heating or an electron beam can be used to melt the metallizing materials such as aluminum, silver, copper, and gold, which usually are pure elements. Sputter plating uses a plasma to produce the metallic vapor and can use brass as well as the metals mentioned. Chromium plating requires etched surfaces to ensure good adhesion. Plastics may be polished by buffing methods similar to those used on metals, but experiments to determine the effect of frictional heat are recommended. Surfaces can be heated to 300–400 deg. F by buffing, and some plastics soften and melt at these temperatures. Heating sometimes causes plastics to give off toxic gases, so masks should be worn to filter out such gases and dust. Parting lines, imperfections, scratches, saw lines, and scars resulting from fabrication can be treated with abrasives prior to buffing. Wet or dry abrasives such as silicon carbide or aluminum oxide are generally used, in grain sizes of 60 to as fine as 320. Some buffing compounds are ineffective on plastics. Scratch lines should be presented at a slight angle to the buff surface for best results. Light, tallow-free grease will help keep the abrasive surface free from buildup, and speeds of 5,000 to 6,000 surface feet per minute are recommended. For low-melting point plastics, soft cotton buffs are best, with surface speeds of 4,000 to 5,000 feet per minute, using a wet or greasy tripoli or silica compound. For finishing, only rouge may be needed for a satisfactory finish. If a cleaning solvent is used it should be checked to see that it does not dissolve the plastics, and it should be used only in a wellventilated area. Acrylics such as Acrylite or Plexiglass may also be ‘flame polished,’ under advice from the materials supplier. Plastics Gearing.—Plastics gears may be cut from blanks, as with metal gears, or molded to shape in an injection-molding machine, for lower production costs, though tooling may cost more. Cut plastics gears may be of similar design to their metal counterparts, but molded gears are usually of modified form to suit the material characteristics. Plastics materials also may be preferred for gears because of superior sliding properties with reduced noise and need for lubrication, chemical or electrical properties, or resistance to wear. However, plastics gear teeth slide more smoothly and easily against metal teeth than do plastics against plastics, and wear is less. For power transmission, plastics gear teeth are usually of involute form. See also Non-metallic Gearing on page 2149. Most plastics gears are made from nylons and acetals, although acrylonitrile-butadienestyrenes (ABS), polycarbonates, polysulfones, phenylene oxides, poly-urethanes, and thermoplastic polyesters can also be used. Additives used in plastics gears include glass fiber for added strength, and fibers, beads, and powders for reduced thermal expansion and improved dimensional stability. Other materials, such as molybdenum disulfide, tetrafluoroethylene (TFE), and silicones, may be added as lubricants to improve wear resistance.
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Machinery's Handbook 27th Edition 626
PLASTICS GEAR DESIGN
Choice of plastics gear material depends on requirements for size and nature of loads to be transmitted, speeds, required life, working environment, type of cooling, lubrication, and operating precision. Because of cost, plastics gears are sometimes not enclosed in sealed housings, so are often given only a single coating of lubricant grease. Overloading of lubricated plastics gear teeth will usually cause tooth fracture, and unlubricated teeth often suffer excessive wear. Thermoplastics strength varies with temperature, with higher temperatures reducing root stress and permitting tooth deformation. In calculating power to be transmitted by spur, helical, and straight bevel gearing, the following formulas should be used with the factors given in Tables 7, 8, and 9. For internal and external spur gears, S s FYV HP = ---------------------------------------(28) 55 ( 600 + V )PC s For internal and external helical gears, S s FYV HP = ---------------------------------------------423 ( 78 + V )P n C s
(29)
S s FYV ( C – F ) HP = -------------------------------------------55 ( 600 + V )PCC s
(30)
For straight bevel gears,
where Ss = safe stress in bending (from Table 8); F = face width in inches; Y = tooth form factor (from Table 7); C = pitch cone distance in inches; Cs = service factor (from Table 9); P = diametral pitch; Pn = normal diametral pitch; and V = velocity at pitch circle diameter in ft/min. Table 7. Tooth Form Factors Y for Plastics Gears 20-deg Internal Full Depth
Number of Teeth
141⁄2-deg Involute or Cycloidal
20-deg Full Depth Involute
20-deg Stub Tooth Involute
Pinion
Gear
12 13 14 15 16 17 18 19 20 21 22 24 26 28 30 34 38 43
0.210 0.220 0.226 0.236 0.242 0.251 0.261 0.273 0.283 0.289 0.292 0.298 0.307 0.314 0.320 0.327 0.336 0.346
0.245 0.261 0.276 0.289 0.259 0.302 0.308 0.314 0.320 0.327 0.330 0.336 0.346 0.352 0.358 0.371 0.383 0.396
0.311 0.324 0.339 0.348 0.361 0.367 0.377 0.386 0.393 0.399 0.405 0.415 0.424 0.430 0.437 0.446 0.456 0.462
0.327 0.327 0.330 0.330 0.333 0.342 0.349 0.358 0.364 0.371 0.374 0.383 0.393 0.399 0.405 0.415 0.424 0.430
… … … … … … … … … … … … … 0.691 0.679 0.660 0.644 0.628
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Machinery's Handbook 27th Edition PLASTICS GEAR DESIGN
627
Table 7. (Continued) Tooth Form Factors Y for Plastics Gears 141⁄2-deg Involute or Cycloidal 0.352 0.358 0.364 0.371 0.377 0.383 0.390
Number of Teeth 50 60 75 100 150 300 Rack
20-deg Full Depth Involute 0.480 0.421 0.434 0.446 0.459 0.471 0.484
20-deg Stub Tooth Involute 0.474 0.484 0.496 0.506 0.518 0.534 0.550
20-deg Internal Full Depth Pinion 0.437 0.446 0.452 0.462 0.468 0.478 …
Gear 0.613 0.597 0.581 0.565 0.550 0.534 …
These values assume a moderate temperature increase and some initial lubrication. With bevel gearing, divide the number of teeth by the cosine of the pitch angle and use the data in the table. For example, if a 20-deg PA bevel gear has 40 teeth and a pitch angle of 58 deg, 40 divided by the cosine of 58 deg = 40 ÷ 0.529919 ∼ 75, and Y = 0.434.
Table 8. Safe Bending Stress (lb/in2) Values for Plastics Gears Safe Stress Plastics Type
Unfilled
Glass-filled
ABS
3,000
6,000
Acetal
5,000
7,000
Nylon
6,000
12,000
Polycarbonate
6,000
9,000
Polyester
3,500
8,000
Polyurethane
2,500
…
Table 9. Service Factors for Plastics Gears Type of Load
8–10 Hr/Day
24 Hr/Day
Intermittent, 3 Hr/Day
Occasional, 1⁄ Hr/Day 2
Steady
1.00
1.25
0.80
Light shock
1.25
1.5
1.00
0.50 0.80
Medium shock
1.5
1.75
1.25
1.00
Heavy shock
1.75
2.00
1.5
1.25
Example:As an example, assume that a material is to be selected for a spur gear that must transmit 1⁄8 hp at 350 rpm, for 8 hrs/day under a steady load. The gear is to have 75 teeth, 32 diametral pitch, 20 deg pressure angle, 0.375 in. face width, and a pitch diameter of 2.3438 in. Using Equation (28), S s FYV 55 ( 600 + V )PC s HP HP = ---------------------------------------- or S s = ------------------------------------------------55 ( 600 + V )PC s FYV hp = 0.125, Y = 0.434 and rpm × π × D = ----------------------------------------------------350 × 3.1416 × 2.3438- = 215 ft ⁄ min V = -----------------------------12 12
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Machinery's Handbook 27th Edition 628
PLASTICS GEAR DESIGN
therefore, ( 600 + 215 )32 × 1.00 × 0.125 = 5,124 lb ⁄ in. 2 S s = 55 -----------------------------------------------------------------------------0.375 × 0.434 × 215 From Table 8 it is apparent that the gear could be molded from several materials. Available physical and chemical characteristics must now be considered in relation to the operating environment for the gear. Strengths of plastics materials decrease with increasing temperatures and not all plastics resist the effects of some liquids, including some lubricants. Some plastics deteriorate when in sunlight for long periods; some are more dimensionally stable than others; and wear resistance varies from one to another. Manufacturers’ data sheets will answer some of these questions. Backlash: Plastics gears should be so dimensioned that they will provide sufficient backlash at the highest temperatures likely to be encountered in service. Dimensional allowances must also be made for gears made of hygroscopic plastics that may be exposed to damp service conditions. Teeth of heavily loaded gears usually have tip relief to reduce effects of deflection, and have full fillet radii to reduce stress concentrations. Such modifications to tooth form are also desirable in plastics gears. If the pinion in a pair of gears has a small number of teeth, undercutting may result. Undercutting weakens teeth, causes undue wear, and may affect continuity of action. The undercutting can be reduced by using the long-short addendum system, which involves increasing the addendum of the pinion teeth and reducing that of the gear teeth. The modified addendum method will also reduce the amount of initial wear that takes place during the initial stages of contact between the teeth. Accuracy: The Gear Handbook, AGMA 390-03a-1980, Part 2, Gear Classification, provides a system whereby results of gear accuracy measurements are expressed in terms of maximum tooth-to-tooth and composite tolerances. This system uses AGMA quality numbers related to maximum tolerances, by pitch and diameter, and is equally applicable to plastics gears as to metal gears. AGMA quality numbers must be chosen for a pair of mating gears early in the design process, and the finished gears must be inspected by being run in close mesh with a master gear in a center-distance measuring instrument to make sure that the errors do not exceed the specified tolerances. To prevent failure from fatigue and wear caused by excessive flexing of the teeth, plastics gears must be made to the same standards of acccuracy as metal gears. Solidification shrinkage of plastics requires that dimensions of molds for gears be larger than the dimensions of the parts to be produced from them. The amount of the shrinkage is usually added to the mold dimension (with the mold at operating temperature). However, this procedure cannot be followed for the tooth profile as it would introduce large errors in the pressure angle. Increases in pressure angle cause gear teeth to become wider at the root and more pointed. Sliding conditions are improved and the teeth are stronger, so that higher loading values can be used. Shrinkage allowances have the greatest effect on the accuracy of the molded gears, so tooth profiles must be calculated extremely carefully in terms of mold profile. If a tooth is merely made larger by using a standard hobbing cutter to cut the tool whereby the teeth in the mold are electroeroded, differential shrinkage caused by the molded tooth being thicker at the root than at the tip will distort the shape of the molded tooth, making it thinner at the tip and thicker at the root. With two mating gears, these faulty shapes will affect the pressure angle resulting in binding, wear, and general malfunction. If the tooth thickness limits for a molded gear are to be held to +0.000 in., −0.001 in., the outside diameter must be permitted to vary up to 0.0027 in. for 20-deg, and 0.0039 in. for 141⁄2-deg pressure angle gears. All high-accuracy gears should be specified with AGMA quality numbers and inspected with center-distance measuring machines if the required accuracy is to be achieved.
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Machinery's Handbook 27th Edition TABLE OF CONTENTS TOOLING AND TOOLMAKING CUTTING TOOLS
FORMING TOOLS (Continued)
749 Terms and Definitions 749 Tool Contour 752 Relief Angles 753 Rake Angles 754 Nose Radius 755 Chipbreakers 756 Planing Tools 756 Indexable Inserts 757 Identification System 758 Indexable Insert Tool Holders 759 Standard Shank Sizes 760 Letter Symbols 761 Indexable Insert Holders 764 Sintered Carbide Tools 764 Sintered Carbide Blanks 764 Single Point Tools 764 Single-Point, Sintered-CarbideTipped Tools 767 Tool Nose Radii 767 Tool Angle Tolerances 767 Carbide Tipped Tools 767 Style A 768 Style B 769 Style C 769 Style D 770 Style E 770 Styles ER and EL 771 Style F 772 Style G
Constants for Diameters Corrected Diameters Arrangement of Circular Tools Circular Cut-Off Tools
796 796 797 798 799 800
Selection of Milling Cutters Number of Teeth Hand of Milling Cutters Plain Milling Cutters Side Milling Cutters Staggered Teeth,T-Slot Milling Cutters Metal Slitting Saws Milling Cutter Terms Shell Mills Multiple- and Two-Flute SingleEnd Helical End Mills Regular-, Long-, and Extra LongLength, Mills Two-Flute, High Helix, Regular-, Long-, and Extra Long-Length, Mills Roughing, Single-End End Mills Concave, Convex, and CornerRounding Arbor-Type Cutters Roller Chain Sprocket Keys and Keyways Woodruff Keyseat Cutters Spline-Shaft Milling Cutter Cutter Grinding Wheel Speeds and Feeds Clearance Angles Rake Angles for Milling Cutters Eccentric Type Radial Relief Indicator Drop Method Relieving Attachments Distance to Set Tooth
MILLING CUTTERS
801 801 803 804 805 806 807 815
CEMENTED CARBIDES 773 Cemented Carbide 773 Carbides and Carbonitrides 774 Properties of Tungsten-CarbideBased Cutting-Tool 778 ISO Classifications of Hardmetals 778 Ceramics 781 Superhard Materials 782 Machining Data 783 Hardmetal Tooling 783 Cutting Blades
FORMING TOOLS 784 784 787 788 789
789 789 794 795
Dovetail Forming Tools Straight Forming Tools Circular Forming Tools Circular Forming Tools Formula Top Rake
817 819 820 824 824 825 825 826 826 829 830 831
REAMERS 832 833 833 833 835 835
Hand Reamers Irregular Tooth Spacing in Reamers Threaded-end Hand Reamers Fluted and Rose Chucking Reamers Vertical Adjustment of Tooth-rest Reamer Terms and Definitions
746
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Machinery's Handbook 27th Edition TABLE OF CONTENTS TOOLING AND TOOLMAKING REAMERS
TAPS AND THREADING DIES
(Continued)
839 839 840 842 843 844 845 846 849 851 852
Direction of Rotation and Helix Dimensions of Centers Reamer Difficulties Expansion Chucking Reamers Hand Reamers Expansion Hand Reamers Driving Slots and Lugs Chucking Reamers Shell Reamers Center Reamers Taper Pipe Reamers
892 Taps 892 Types of Taps 892 Definitions of Tap Terms 896 Fraction-Size Taps 898 Machine Screw Taps 899 Ground Thread Limits 900 Taper Pipe Taps 901 Straight Pipe Taps 903 Straight Fluted Taps 905 Spiral-Pointed Taps 910 ANSI Standard Taps 911 Pulley Taps 911 Spark Plug Taps 913 Spiral Pointed Ground Thread Taps 914 Taper and Straight Pipe Taps 916 Thread Series Designations 917 Pitch Diameter Tolerance 917 Eccentricity Tolerances 919 Acme and Square-Threaded Taps 919 Acme Threads Taps 921 Proportions 921 Drill Hole Sizes for Acme Threads 922 Screwing Taps for ISO Metric Threads 925 Tapping Square Threads
TWIST DRILLS AND COUNTERBORES 854 855 875 876 877 878 878 878 879 880 881 882 884 884 884 885 886 886 887 887 889 890 891 891
Definitions of Twist Drill Terms Types of Drills Split-Sleeve, Collet Type Drill Drivers Three- and Four-Flute Straight Shank Core Drills Twist Drills and Centering Tools British Standard Combined Drills Drill Drivers British Standard Metric Twist Drills Gauge and Letter Sizes Morse Taper Shank Twist Drills Tolerance on Diameter Parallel Shank Jobber Series Twist Drills Stub Drills Steels for Twist Drills Accuracy of Drilled Holes Counterboring Interchangeable Cutters Three Piece Counterbores Sintered Carbide Boring Tools Style Designations Square Boring Tools Carbide-Tipped Square Boring Tools Solid Carbide Round Boring Tools Boring Machines, Origin
STANDARD TAPERS 926 Standard Tapers 926 Morse Taper 926 Brown & Sharpe Taper 926 Jarno Taper 934 British Standard Tapers 935 Morse Taper Sleeves 936 Brown & Sharpe Taper Shank 937 Jarno Taper Shanks 937 Machine Tool Spindles 938 Plug and Ring Gages 939 Jacobs Tapers and Threads 940 Spindle Noses 942 Tool Shanks 943 Draw-in Bolt Ends 944 Spindle Nose 945 Collets 945 Collets for Lathes, Mills, Grinders, and Fixtures
747
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Machinery's Handbook 27th Edition TABLE OF CONTENTS TOOLING AND TOOLMAKING ARBORS, CHUCKS, AND SPINDLES
TOOL WEAR AND SHARPENING
948 Portable Tool Spindles 948 Circular Saw Arbors 948 Spindles for Geared Chucks 948 Spindle Sizes 948 Straight Grinding Wheel Spindles 949 Square Drives for Portable Air 950 Threaded and Tapered Spindles 950 Abrasion Tool Spindles 951 Hexagonal Chucks for Portable Air 952 Mounted Wheels and Points 954 Shapes of Mounted Wheels and Points
BROACHES AND BROACHING
973
Sharpening Twist Drills Relief Grinding of the Tool Flanks Drill Point Thinning Sharpening Carbide Tools Silicon Carbide Wheels Diamond Wheels Diamond Wheel Grit Sizes Diamond Wheel Grades Diamond Concentration Dry Versus Wet Grinding of Carbide Tools Coolants for Carbide Tool Grinding Peripheral Versus Flat Side Grinding Lapping Carbide Tools Chip Breaker Grinding Summary of Miscellaneous Points
JIGS AND FIXTURES 975 Jig Bushings 975 Materials 975 American National Standard 976 Head Type Press Fit Wearing Bushings 979 Specifications for Press Fit Wearing Bushings 979 Slip Type Renewable Wearing Bushings 981 Fixed Type Renewable Wearing Bushings 982 Headless Type Liner Bushings 984 Locking Mechanisms 985 Jig Bushing Definitions 985 Jig Plate Thickness 985 Jig Bushing Designation System 985 Jig Boring 985 Definition of Jig and Fixture 985 Jig Borers 986 Jig-Boring Practice 987 Transfer of Tolerances 989 Determining Hole Coordinates 989 Hole Coordinate Dimension Factors 991 Spacing Off the Circumferences of Circles 993 Hole Coordinate Tables
FILES AND BURS
966
973
974 974 974
955 The Broaching Process 955 Types of Broaches 956 Pitch of Broach Teeth 957 Designing Data for Surface Broaches 957 Broaching Pressure 958 Depth of Cut per Tooth 959 Face Angle or Rake 959 Clearance Angle 959 Land Width 959 Depth of Broach Teeth 959 Radius of Tooth Fillet 959 Total Length of Broach 959 Chip Breakers 960 Shear Angle 960 Types of Broaching Machines 960 Ball-Broaching 961 Broaching Difficulties
962 963 963 965
969 969 970 971 971 972 972 972 972 973
Definitions of File Terms File Characteristics Classes of Files Effectiveness of Rotary Files and Burs Speeds of Rotary Files and Burs
748
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Machinery's Handbook 27th Edition TOOLING AND TOOLMAKING
749
CUTTING TOOLS Terms and Definitions Tool Contour.—Tools for turning, planing, etc., are made in straight, bent, offset, and other forms to place the cutting edges in convenient positions for operating on differently located surfaces. The contour or shape of the cutting edge may also be varied to suit different classes of work. Tool shapes, however, are not only related to the kind of operation, but, in roughing tools particularly, the contour may have a decided effect upon the cutting efficiency of the tool. To illustrate, an increase in the side cutting-edge angle of a roughing tool, or in the nose radius, tends to permit higher cutting speeds because the chip will be thinner for a given feed rate. Such changes, however, may result in chattering or vibrations unless the work and the machine are rigid; hence, the most desirable contour may be a compromise between the ideal form and one that is needed to meet practical requirements. Terms and Definitions.—The terms and definitions relating to single-point tools vary somewhat in different plants, but the following are in general use.
Fig. 1. Terms Applied to Single-point Turning Tools
Single-point Tool: This term is applied to tools for turning, planing, boring, etc., which have a cutting edge at one end. This cutting edge may be formed on one end of a solid piece of steel, or the cutting part of the tool may consist of an insert or tip which is held to the body of the tool by brazing, welding, or mechanical means. Shank: The shank is the main body of the tool. If the tool is an inserted cutter type, the shank supports the cutter or bit. (See diagram, Fig. 1.) Nose: A general term sometimes used to designate the cutting end but usually relating more particularly to the rounded tip of the cutting end. Face: The surface against which the chips bear, as they are severed in turning or planing operations, is called the face. Flank: The flank is that end surface adjacent to the cutting edge and below it when the tool is in a horizontal position as for turning. Base: The base is the surface of the tool shank that bears against the supporting toolholder or block. Side Cutting Edge: The side cutting edge is the cutting edge on the side of the tool. Tools such as shown in Fig. 1 do the bulk of the cutting with this cutting edge and are, therefore, sometimes called side cutting edge tools. End Cutting Edge: The end cutting edge is the cutting edge at the end of the tool. On side cutting edge tools, the end cutting edge can be used for light plunging and facing cuts. Cutoff tools and similar tools have only one cutting edge located on the end. These
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Machinery's Handbook 27th Edition 750
CUTTING TOOLS
tools and other tools that are intended to cut primarily with the end cutting edge are sometimes called end cutting edge tools. Rake: A metal-cutting tool is said to have rake when the tool face or surface against which the chips bear as they are being severed, is inclined for the purpose of either increasing or diminishing the keenness or bluntness of the edge. The magnitude of the rake is most conveniently measured by two angles called the back rake angle and the side rake angle. The tool shown in Fig. 1 has rake. If the face of the tool did not incline but was parallel to the base, there would be no rake; the rake angles would be zero. Positive Rake: If the inclination of the tool face is such as to make the cutting edge keener or more acute than when the rake angle is zero, the rake angle is defined as positive. Negative Rake: If the inclination of the tool face makes the cutting edge less keen or more blunt than when the rake angle is zero, the rake is defined as negative. Back Rake: The back rake is the inclination of the face toward or away from the end or the end cutting edge of the tool. When the inclination is away from the end cutting edge, as shown in Fig. 1, the back rake is positive. If the inclination is downward toward the end cutting edge the back rake is negative. Side Rake: The side rake is the inclination of the face toward or away from the side cutting edge. When the inclination is away from the side cutting edge, as shown in Fig. 1, the side rake is positive. If the inclination is toward the side cutting edge the side rake is negative. Relief: The flanks below the side cutting edge and the end cutting edge must be relieved to allow these cutting edges to penetrate into the workpiece when taking a cut. If the flanks are not provided with relief, the cutting edges will rub against the workpiece and be unable to penetrate in order to form the chip. Relief is also provided below the nose of the tool to allow it to penetrate into the workpiece. The relief at the nose is usually a blend of the side relief and the end relief. End Relief Angle: The end relief angle is a measure of the relief below the end cutting edge. Side Relief Angle: The side relief angle is a measure of the relief below the side cutting edge. Back Rake Angle: The back rake angle is a measure of the back rake. It is measured in a plane that passes through the side cutting edge and is perpendicular to the base. Thus, the back rake angle can be defined by measuring the inclination of the side cutting edge with respect to a line or plane that is parallel to the base. The back rake angle may be positive, negative, or zero depending upon the magnitude and direction of the back rake. Side Rake Angle: The side rake angle is a measure of the side rake. This angle is always measured in a plane that is perpendicular to the side cutting edge and perpendicular to the base. Thus, the side rake angle is the angle of inclination of the face perpendicular to the side cutting edge with reference to a line or a plane that is parallel to the base. End Cutting Edge Angle: The end cutting edge angle is the angle made by the end cutting edge with respect to a plane perpendicular to the axis of the tool shank. It is provided to allow the end cutting edge to clear the finish machined surface on the workpiece. Side Cutting Edge Angle: The side cutting edge angle is the angle made by the side cutting edge and a plane that is parallel to the side of the shank. Nose Radius: The nose radius is the radius of the nose of the tool. The performance of the tool, in part, is influenced by nose radius so that it must be carefully controlled. Lead Angle: The lead angle, shown in Fig. 2, is not ground on the tool. It is a tool setting angle which has a great influence on the performance of the tool. The lead angle is bounded by the side cutting edge and a plane perpendicular to the workpiece surface when the tool is in position to cut; or, more exactly, the lead angle is the angle between the side cutting edge and a plane perpendicular to the direction of the feed travel.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CUTTING TOOLS
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Fig. 2. Lead Angle on Single-point Turning Tool
Solid Tool: A solid tool is a cutting tool made from one piece of tool material. Brazed Tool: A brazed tool is a cutting tool having a blank of cutting-tool material permanently brazed to a steel shank. Blank: A blank is an unground piece of cutting-tool material from which a brazed tool is made. Tool Bit: A tool bit is a relatively small cutting tool that is clamped in a holder in such a way that it can readily be removed and replaced. It is intended primarily to be reground when dull and not indexed. Tool-bit Blank: The tool-bit blank is an unground piece of cutting-tool material from which a tool bit can be made by grinding. It is available in standard sizes and shapes. Tool-bit Holder: Usually made from forged steel, the tool-bit holder is used to hold the tool bit, to act as an extended shank for the tool bit, and to provide a means for clamping in the tool post. Straight-shank Tool-bit Holder: A straight-shank tool-bit holder has a straight shank when viewed from the top. The axis of the tool bit is held parallel to the axis of the shank. Offset-shank Tool-bit Holder: An offset-shank tool-bit holder has the shank bent to the right or left, as seen in Fig. 3. The axis of the tool bit is held at an angle with respect to the axis of the shank. Side cutting Tool: A side cutting tool has its major cutting edge on the side of the cutting part of the tool. The major cutting edge may be parallel or at an angle with respect to the axis of the tool. Indexable Inserts: An indexable insert is a relatively small piece of cutting-tool material that is geometrically shaped to have two or several cutting edges that are used until dull. The insert is then indexed on the holder to apply a sharp cutting edge. When all the cutting edges have been dulled, the insert is discarded. The insert is held in a pocket or against other locating surfaces on an indexable insert holder by means of a mechanical clamping device that can be tightened or loosened easily. Indexable Insert Holder: Made of steel, an indexable insert holder is used to hold indexable inserts. It is equipped with a mechanical clamping device that holds the inserts firmly in a pocket or against other seating surfaces. Straight-shank Indexable Insert Holder: A straight-shank indexable insert tool-holder is essentially straight when viewed from the top, although the cutting edge of the insert may be oriented parallel, or at an angle to, the axis of the holder. Offset-shank Indexable Insert Holder: An offset-shank indexable insert holder has the head end, or the end containing the insert pocket, offset to the right or left, as shown in Fig. 3.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 752
CUTTING TOOLS
Fig. 3. Top: Right-hand Offset-shank, Indexable Insert Holder Bottom: Right-hand Offset-shank Tool-bit Holder
End cutting Tool: An end cutting tool has its major cutting edge on the end of the cutting part of the tool. The major cutting edge may be perpendicular or at an angle, with respect to the axis of the tool. Curved Cutting-edge Tool: A curved cutting-edge tool has a continuously variable side cutting edge angle. The cutting edge is usually in the form of a smooth, continuous curve along its entire length, or along a large portion of its length. Right-hand Tool: A right-hand tool has the major, or working, cutting edge on the righthand side when viewed from the cutting end with the face up. As used in a lathe, such a tool is usually fed into the work from right to left, when viewed from the shank end. Left-hand Tool: A left-hand tool has the major or working cutting edge on the left-hand side when viewed from the cutting end with the face up. As used in a lathe, the tool is usually fed into the work from left to right, when viewed from the shank end. Neutral-hand Tool: A neutral-hand tool is a tool to cut either left to right or right to left; or the cut may be parallel to the axis of the shank as when plunge cutting. Chipbreaker: A groove formed in or on a shoulder on the face of a turning tool back of the cutting edge to break up the chips and prevent the formation of long,continuous chips which would be dangerous to the operator and also bulky and cumbersome to handle. A chipbreaker of the shoulder type may be formed directly on the tool face or it may consist of a separate piece that is held either by brazing or by clamping. Relief Angles.—The end relief angle and the side relief angle on single-point cutting tools are usually, though not invariably, made equal to each other. The relief angle under the nose of the tool is a blend of the side and end relief angles. The size of the relief angles has a pronounced effect on the performance of the cutting tool. If the relief angles are too large, the cutting edge will be weakened and in danger of breaking when a heavy cutting load is placed on it by a hard and tough material. On finish cuts, rapid wear of the cutting edge may cause problems with size control on the part. Relief angles that are too small will cause the rate of wear on the flank of the tool below the cutting edge to increase, thereby significantly reducing the tool life. In general, when cutting hard and tough materials, the relief angles should be 6 to 8 degrees for high-speed steel tools and 5 to 7 degrees for carbide tools. For medium steels, mild steels, cast iron, and other average work the recommended values of the relief angles are 8 to 12 degrees for high-speed steel tools and 5 to 10 degrees for carbides. Ductile materials having a relatively low modulus of elasticity should be cut using larger relief angles. For example, the relief angles recommended for turning copper, brass, bronze, aluminum, ferritic malleable
Copyright 2004, Industrial Press, Inc., New York, NY
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iron, and similar metals are 12 to 16 degrees for high-speed steel tools and 8 to 14 degrees for carbides. Larger relief angles generally tend to produce a better finish on the finish machined surface because less surface of the worn flank of the tool rubs against the workpiece. For this reason, single-point thread-cutting tools should be provided with relief angles that are as large as circumstances will permit. Problems encountered when machining stainless steel may be overcome by increasing the size of the relief angle. The relief angles used should never be smaller than necessary. Rake Angles.—Machinability tests have confirmed that when the rake angle along which the chip slides, called the true rake angle, is made larger in the positive direction, the cutting force and the cutting temperature will decrease. Also, the tool life for a given cutting speed will increase with increases in the true rake angle up to an optimum value, after which it will decrease again. For turning tools which cut primarily with the side cutting edge, the true rake angle corresponds rather closely with the side rake angle except when taking shallow cuts. Increasing the side rake angle in the positive direction lowers the cutting force and the cutting temperature, while at the same time it results in a longer tool life or a higher permissible cutting speed up to an optimum value of the side rake angle. After the optimum value is exceeded, the cutting force and the cutting temperature will continue to drop; however, the tool life and the permissible cutting speed will decrease. As an approximation, the magnitude of the cutting force will decrease about one per cent per degree increase in the side rake angle. While not exact, this rule of thumb does correspond approximately to test results and can be used to make rough estimates. Of course, the cutting force also increases about one per cent per degree decrease in the side rake angle. The limiting value of the side rake angle for optimum tool life or cutting speed depends upon the work material and the cutting tool material. In general, lower values can be used for hard and tough work materials. Cemented carbides are harder and more brittle than high-speed steel; therefore, the rake angles usually used for cemented carbides are less positive than for high-speed steel. Negative rake angles cause the face of the tool to slope in the opposite direction from positive rake angles and, as might be expected, they have an opposite effect. For side cutting edge tools, increasing the side rake angle in a negative direction will result in an increase in the cutting force and an increase in the cutting temperature of approximately one per cent per degree change in rake angle. For example, if the side rake angle is changed from 5 degrees positive to 5 degrees negative, the cutting force will be about 10 per cent larger. Usually the tool life will also decrease when negative side rake angles are used, although the tool life will sometimes increase when the negative rake angle is not too large and when a fast cutting speed is used. Negative side rake angles are usually used in combination with negative back rake angles on single-point cutting tools. The negative rake angles strengthen the cutting edges enabling them to sustain heavier cutting loads and shock loads. They are recommended for turning very hard materials and for heavy interrupted cuts. There is also an economic advantage in favor of using negative rake indexable inserts and tool holders inasmuch as the cutting edges provided on both the top and bottom of the insert can be used. On turning tools that cut primarily with the side cutting edge, the effect of the back rake angle alone is much less than the effect of the side rake angle although the direction of the change in cutting force, cutting temperature, and tool life is the same. The effect that the back rake angle has can be ignored unless, of course, extremely large changes in this angle are made. A positive back rake angle does improve the performance of the nose of the tool somewhat and is helpful in taking light finishing cuts. A negative back rake angle strengthens the nose of the tool and is helpful when interrupted cuts are taken. The back rake angle has a very significant effect on the performance of end cutting edge tools, such as cut-off tools. For these tools, the effect of the back rake angle is very similar to the effect of the side rake angle on side cutting edge tools.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 754
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Side Cutting Edge and Lead Angles.—These angles are considered together because the side cutting edge angle is usually designed to provide the desired lead angle when the tool is being used. The side cutting edge angle and the lead angle will be equal when the shank of the cutting tool is positioned perpendicular to the workpiece, or, more correctly, perpendicular to the direction of the feed. When the shank is not perpendicular, the lead angle is determined by the side cutting edge and an imaginary line perpendicular to the feed direction. The flow of the chips over the face of the tool is approximately perpendicular to the side cutting edge except when shallow cuts are taken. The thickness of the undeformed chip is measured perpendicular to the side cutting edge. As the lead angle is increased, the length of chip in contact with the side cutting edge is increased, and the chip will become longer and thinner. This effect is the same as increasing the depth of cut and decreasing the feed, although the actual depth of cut and feed remain the same and the same amount of metal is removed. The effect of lengthening and thinning the chip by increasing the lead angle is very beneficial as it increases the tool life for a given cutting speed or that speed can be increased. Increasing the cutting speed while the feed and the tool life remain the same leads to faster production. However, an adverse effect must be considered. Chatter can be caused by a cutting edge that is oriented at a high lead angle when turning and sometimes, when turning long and slender shafts, even a small lead angle can cause chatter. In fact, an unsuitable lead angle of the side cutting edge is one of the principal causes of chatter. When chatter occurs, often simply reducing the lead angle will cure it. Sometimes, very long and slender shafts can be turned successfully with a tool having a zero degree lead angle (and having a small nose radius). Boring bars, being usually somewhat long and slender, are also susceptible to chatter if a large lead angle is used. The lead angle for boring bars should be kept small, and for very long and slender boring bars a zero degree lead angle is recommended. It is impossible to provide a rule that will determine when chatter caused by a lead angle will occur and when it will not. In making a judgment, the first consideration is the length to diameter ratio of the part to be turned, or of the boring bar. Then the method of holding the workpiece must be considered — a part that is firmly held is less apt to chatter. Finally, the overall condition and rigidity of the machine must be considered because they may be the real cause of chatter. Although chatter can be a problem, the advantages gained from high lead angles are such that the lead angle should be as large as possible at all times. End Cutting Edge Angle.—The size of the end cutting edge angle is important when tool wear by cratering occurs. Frequently, the crater will enlarge until it breaks through the end cutting edge just behind the nose, and tool failure follows shortly. Reducing the size of the end cutting edge angle tends to delay the time of crater breakthrough. When cratering takes place, the recommended end cutting edge angle is 8 to 15 degrees. If there is no cratering, the angle can be made larger. Larger end cutting edge angles may be required to enable profile turning tools to plunge into the work without interference from the end cutting edge. Nose Radius.—The tool nose is a very critical part of the cutting edge since it cuts the finished surface on the workpiece. If the nose is made to a sharp point, the finish machined surface will usually be unacceptable and the life of the tool will be short. Thus, a nose radius is required to obtain an acceptable surface finish and tool life. The surface finish obtained is determined by the feed rate and by the nose radius if other factors such as the work material, the cutting speed, and cutting fluids are not considered. A large nose radius will give a better surface finish and will permit a faster feed rate to be used. Machinability tests have demonstrated that increasing the nose radius will also improve the tool life or allow a faster cutting speed to be used. For example, high-speed steel tools were used to turn an alloy steel in one series of tests where complete or catastrophic tool failure was used as a criterion for the end of tool life. The cutting speed for a 60-minute tool
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CUTTING TOOLS
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life was found to be 125 fpm when the nose radius was 1⁄16 inch and 160 fpm when the nose radius was 1⁄4 inch. A very large nose radius can often be used but a limit is sometimes imposed because the tendency for chatter to occur is increased as the nose radius is made larger. A nose radius that is too large can cause chatter and when it does, a smaller nose radius must be used on the tool. It is always good practice to make the nose radius as large as is compatible with the operation being performed. Chipbreakers.—Many steel turning tools are equipped with chipbreaking devices to prevent the formation of long continuous chips in connection with the turning of steel at the high speeds made possible by high-speed steel and especially cemented carbide tools. Long steel chips are dangerous to the operator, and cumbersome to handle, and they may twist around the tool and cause damage. Broken chips not only occupy less space, but permit a better flow of coolant to the cutting edge. Several different forms of chipbreakers are illustrated in Fig. 4. Angular Shoulder Type: The angular shoulder type shown at A is one of the commonly used forms. As the enlarged sectional view shows, the chipbreaking shoulder is located back of the cutting edge. The angle a between the shoulder and cutting edge may vary from 6 to 15 degrees or more, 8 degrees being a fair average. The ideal angle, width W and depth G, depend upon the speed and feed, the depth of cut, and the material. As a general rule, width W, at the end of the tool, varies from 3⁄32 to 7⁄32 inch, and the depth G may range from 1⁄ to 1⁄ inch. The shoulder radius equals depth G. If the tool has a large nose radius, the 64 16 corner of the shoulder at the nose end may be beveled off, as illustrated at B, to prevent it from coming into contact with the work. The width K for type B should equal approximately 1.5 times the nose radius. Parallel Shoulder Type: Diagram C shows a design with a chipbreaking shoulder that is parallel with the cutting edge. With this form, the chips are likely to come off in short curled sections. The parallel form may also be applied to straight tools which do not have a side cutting-edge angle. The tendency with this parallel shoulder form is to force the chips against the work and damage it.
Fig. 4. Different Forms of Chipbreakers for Turning Tools
Groove Type: This type (diagram D) has a groove in the face of the tool produced by grinding. Between the groove and the cutting edge, there is a land L. Under ideal conditions, this width L, the groove width W, and the groove depth G, would be varied to suit the feed, depth of cut and material. For average use, L is about 1⁄32 inch; G, 1⁄32 inch; and W, 1⁄16 inch. There are differences of opinion concerning the relative merits of the groove type and
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 756
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the shoulder type. Both types have proved satisfactory when properly proportioned for a given class of work. Chipbreaker for Light Cuts: Diagram E illustrates a form of chipbreaker that is sometimes used on tools for finishing cuts having a maximum depth of about 1⁄32 inch. This chipbreaker is a shoulder type having an angle of 45 degrees and a maximum width of about 1⁄16 inch. It is important in grinding all chipbreakers to give the chip-bearing surfaces a fine finish, such as would be obtained by honing. This finish greatly increases the life of the tool. Planing Tools.—Many of the principles which govern the shape of turning tools also apply in the grinding of tools for planing. The amount of rake depends upon the hardness of the material, and the direction of the rake should be away from the working part of the cutting edge. The angle of clearance should be about 4 or 5 degrees for planer tools, which is less than for lathe tools. This small clearance is allowable because a planer tool is held about square with the platen, whereas a lathe tool, the height and inclination of which can be varied, may not always be clamped in the same position. Carbide Tools: Carbide tools for planing usually have negative rake. Round-nose and square-nose end-cutting tools should have a “negative back rake” (or front rake) of 2 or 3 degrees. Side cutting tools may have a negative back rake of 10 degrees, a negative side rake of 5 degrees, and a side cutting-edge angle of 8 degrees. Indexable Inserts Introduction.—A large proportion of the cemented carbide, single-point cutting tools are indexable inserts and indexable insert tool holders. Dimensional specifications for solid sintered carbide indexable inserts are given in American National Standard ANSI B212.12-1991 (R2002). Samples of the many insert shapes are shown in Table 3. Most modern, cemented carbide, face milling cutters are of the indexable insert type. Larger size end milling cutters, side milling or slotting cutters, boring tools, and a wide variety of special tools are made to use indexable inserts. These inserts are primarily made from cemented carbide, although most of the cemented oxide cutting tools are also indexable inserts. The objective of this type of tooling is to provide an insert with several cutting edges. When an edge is worn, the insert is indexed in the tool holder until all the cutting edges are used up, after which it is discarded. The insert is not intended to be reground. The advantages are that the cutting edges on the tool can be rapidly changed without removing the tool holder from the machine, tool-grinding costs are eliminated, and the cost of the insert is less than the cost of a similar, brazed carbide tool. Of course, the cost of the tool holder must be added to the cost of the insert; however, one tool holder will usually last for a long time before it, too, must be replaced. Indexable inserts and tool holders are made with a negative rake or with a positive rake. Negative rake inserts have the advantage of having twice as many cutting edges available as comparable positive rake inserts, because the cutting edges on both the top and bottom of negative rake inserts can be used, while only the top cutting edges can be used on positive rake inserts. Positive rake inserts have a distinct advantage when machining long and slender parts, thin-walled parts, or other parts that are subject to bending or chatter when the cutting load is applied to them, because the cutting force is significantly lower as compared to that for negative rake inserts. Indexable inserts can be obtained in the following forms: utility ground, or ground on top and bottom only; precision ground, or ground on all surfaces; prehoned to produce a slight rounding of the cutting edge; and precision molded, which are unground. Positive-negative rake inserts also are available. These inserts are held on a negative-rake tool holder and have a chipbreaker groove that is formed to produce an effective positive-rake angle while cutting. Cutting edges may be available on the top surface only, or on both top and bottom surfaces. The positive-rake chipbreaker surface may be ground or precision molded on the insert.
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Many materials, such as gray cast iron, form a discontinuous chip. For these materials an insert that has plain faces without chipbreaker grooves should always be used. Steels and other ductile materials form a continuous chip that must be broken into small segments when machined on lathes and planers having single-point, cemented-carbide and cemented-oxide cutting tools; otherwise, the chips can cause injury to the operator. In this case a chipbreaker must be used. Some inserts are made with chipbreaker grooves molded or ground directly on the insert. When inserts with plain faces are used, a cemented-carbide plate-type chipbreaker is clamped on top of the insert. Identification System for Indexable Inserts.—The size of indexable inserts is determined by the diameter of an inscribed circle (I.C.), except for rectangular and parallelogram inserts where the length and width dimensions are used. To describe an insert in its entirety, a standard ANSI B212.4-2002 identification system is used where each position number designates a feature of the insert. The ANSI Standard includes items now commonly used and facilitates identification of items not in common use. Identification consists of up to ten positions; each position defines a characteristic of the insert as shown below: 1 T
2 N
3 M
4 G
5 5
6 4
7 3
8a
9a
10a A
a Eighth, Ninth, and Tenth Positions are used only when required.
1) Shape: The shape of an insert is designated by a letter: R for round; S, square; T, triangle; A, 85° parallelogram; B, 82° parallelogram; C, 80° diamond; D, 55° diamond; E, 75° diamond; H, hexagon; K, 55° parallelogram; L, rectangle; M, 86° diamond; O, octagon; P, pentagon; V, 35° diamond; and W, 80° trigon. 2) Relief Angle (Clearances): The second position is a letter denoting the relief angles; N for 0°; A, 3°; B, 5°; C, 7°; P, 11°; D, 15°; E, 20°; F, 25°; G, 30°; H, 0° & 11°*; J, 0° & 14°*; K, 0° & 17°*; L, 0° & 20°*; M, 11° & 14°*; R, 11° & 17°*; S, 11° & 20°*. When mounted on a holder, the actual relief angle may be different from that on the insert. 3) Tolerances: The third position is a letter and indicates the tolerances which control the indexability of the insert. Tolerances specified do not imply the method of manufacture.
Symbol A B C D E F G
Tolerance (± from nominal) Inscribed Thicknes, Circle, Inch Inch 0.001 0.001 0.001 0.005 0.001 0.001 0.001 0.005 0.001 0.001 0.0005 0.001 0.001 0.005
Symbol H J K L M U N
Tolerance (± from nominal) Inscribed Thickness, Circle, Inch Inch 0.0005 0.001 0.002–0.005 0.001 0.002–0.005 0.001 0.002–0.005 0.001 0.005 0.002–0.004a 0.005 0.005–0.010a 0.001 0.002–0.004a
a Exact tolerance is determined by size of insert. See ANSI B212.12.
4) Type: The type of insert is designated by a letter. A, with hole; B, with hole and countersink; C, with hole and two countersinks; F, chip grooves both surfaces, no hole; G, same as F but with hole; H, with hole, one countersink, and chip groove on one rake surface; J, with hole, two countersinks and chip grooves on two rake surfaces; M, with hole and chip groove on one rake surface; N, without hole; Q, with hole and two countersinks; R, without hole but with chip groove on one rake surface; T, with hole, one countersink, and chip * Second angle is secondary facet angle, which may vary by ± 1°.
Copyright 2004, Industrial Press, Inc., New York, NY
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groove on one rake face; U, with hole, two countersinks, and chip grooves on two rake faces; and W, with hole and one countersink. Note: a dash may be used after position 4 to separate the shape-describing portion from the following dimensional description of the insert and is not to be considered a position in the standard description. 5) Size: The size of the insert is designated by a one- or a two-digit number. For regular polygons and diamonds, it is the number of eighths of an inch in the nominal size of the inscribed circle, and will be a one- or two-digit number when the number of eighths is a whole number. It will be a two-digit number, including one decimal place, when it is not a whole number. Rectangular and parallelogram inserts require two digits: the first digit indicates the number of eighths of an inch width and the second digit, the number of quarters of an inch length. 6) Thickness: The thickness is designated by a one- or two-digit number, which indicates the number of sixteenths of an inch in the thickness of the insert. It is a one-digit number when the number of sixteenths is a whole number; it is a two-digit number carried to one decimal place when the number of sixteenths of an inch is not a whole number. 7) Cutting Point Configuration: The cutting point, or nose radius, is designated by a number representing 1⁄64ths of an inch; a flat at the cutting point or nose, is designated by a letter: 0 for sharp corner; 1, 1⁄64 inch radius; 2, 1⁄32 inch radius; 3, 3⁄64inch radius; 4, 1⁄16 inch radius; 5, 5⁄64 inch radius; 6, 3⁄32 inch radius; 7, 7⁄64 inch radius; 8, 1⁄8 inch radius; A, square insert with 45° chamfer; D, square insert with 30° chamfer; E, square insert with 15° chamfer; F, square insert with 3° chamfer; K, square insert with 30° double chamfer; L, square insert with 15° double chamfer; M, square insert with 3° double chamfer; N, truncated triangle insert; and P, flatted corner triangle insert. 8) Special Cutting Point Definition: The eighth position, if it follows a letter in the 7th position, is a number indicating the number of 1⁄64ths of an inch measured parallel to the edge of the facet. 9) Hand: R, right; L, left; to be used when required in ninth position. 10) Other Conditions: The tenth position defines special conditions (such as edge treatment, surface finish) as follows: A, honed, 0.0005 inch to less than 0.003 inch; B, honed, 0.003 inch to less than 0.005 inch; C, honed, 0.005 inch to less than 0.007 inch; J, polished, 4 microinch arithmetic average (AA) on rake surfaces only; T, chamfered, manufacturer's standard negative land, rake face only. Indexable Insert Tool Holders.—Indexable insert tool holders are made from a good grade of steel which is heat treated to a hardness of 44 to 48 Rc for most normal applications. Accurate pockets that serve to locate the insert in position and to provide surfaces against which the insert can be clamped are machined in the ends of tool holders. A cemented carbide seat usually is provided, and is held in the bottom of the pocket by a screw or by the clamping pin, if one is used. The seat is necessary to provide a flat bearing surface upon which the insert can rest and, in so doing, it adds materially to the ability of the insert to withstand the cutting load. The seating surface of the holder may provide a positive-, negative-, or a neutral-rake orientation to the insert when it is in position on the holder. Holders, therefore, are classified as positive, negative, or neutral rake. Four basic methods are used to clamp the insert on the holder: 1) Clamping, usually top clamping; 2) Pin-lock clamping; 3) Multiple clamping using a clamp, usually a top clamp, and a pin lock; and 4) Clamping the insert with a machine screw. All top clamps are actuated by a screw that forces the clamp directly against the insert. When required, a cemented-carbide, plate-type chipbreaker is placed between the clamp and the insert. Pin-lock clamps require an insert having a hole: the pin acts against the walls of the hole to clamp the insert firmly against the seating surfaces of the holder. Multiple or combination clamping, simultaneously using both a pin-lock and a top clamp, is recommended when taking heavier or interrupted cuts. Holders are available on which all the above-mentioned methods of clamping may be used. Other holders are made with only a
Copyright 2004, Industrial Press, Inc., New York, NY
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top clamp or a pin lock. Screw-on type holders use a machine screw to hold the insert in the pocket. Most standard indexable insert holders are either straight-shank or offset-shank, although special holders are made having a wide variety of configurations. The common shank sizes of indexable insert tool holders are shown in Table 1. Not all styles are available in every shank size. Positive- and negative-rake tools are also not available in every style or shank size. Some manufacturers provide additional shank sizes for certain tool holder styles. For more complete details the manufacturers' catalogs must be consulted. Table 1. Standard Shank Sizes for Indexable Insert Holders
Basic Shank Size 1⁄ × 1⁄ × 41⁄ 2 2 2 5⁄ × 5⁄ × 41⁄ 8 8 2 5⁄ × 11⁄ × 6 8 4 3⁄ × 3⁄ × 41⁄ 4 4 2 3⁄ × 1 × 6 4 3⁄ × 11⁄ × 6 4 4
Shank Dimensions for Indexable Insert Holders A In. 0.500
Ca
B mm 12.70
In. 0.500
mm
In.
mm
12.70
4.500
114.30
0.625
15.87
0.625
15.87
4.500
114.30
0.625
15.87
1.250
31.75
6.000
152.40
0.750
19.05
0.750
19.05
4.500
114.30
0.750
19.05
1.000
25.40
6.000
152.40
0.750
19.05
1.250
31.75
6.000
152.40
1×1×6 1 × 11⁄4 × 6
1.000 1.000
25.40 25.40
1.000 1.250
25.40 31.75
6.000 6.000
152.40 152.40
1 × 11⁄2 × 6
1.000
25.40
1.500
38.10
6.000
152.40
11⁄4 × 11⁄4 × 7
1.250
31.75
1.250
31.75
7.000
177.80
11⁄4 × 11⁄2 × 8
1.250
31.75
1.500
38.10
8.000
203.20
13⁄8 × 21⁄16 × 63⁄8
1.375
34.92
2.062
52.37
6.380
162.05
11⁄2 × 11⁄2 × 7
1.500
38.10
1.500
38.10
7.000
177.80
13⁄4 × 13⁄4 × 91⁄2 2×2×8
1.750
44.45
1.750
44.45
9.500
241.30
2.000
50.80
2.000
50.80
8.000
203.20
a Holder length; may vary by manufacturer. Actual shank length depends on holder style.
Identification System for Indexable Insert Holders.—The following identification system conforms to the American National Standard, ANSI B212.5-2002, Metric Holders for Indexable Inserts. Each position in the system designates a feature of the holder in the following sequence: 1 2 3 4 5 — 6 — 7 — 8a — 9 — 10a C T N A R — 85 — 25 — D — 16 — Q 1) Method of Holding Horizontally Mounted Insert: The method of holding or clamping is designated by a letter: C, top clamping, insert without hole; M, top and hole clamping, insert with hole; P, hole clamping, insert with hole; S, screw clamping through hole, insert with hole; W, wedge clamping. 2) Insert Shape: The insert shape is identified by a letter: H, hexagonal; O, octagonal; P, pentagonal; S, square; T, triangular; C, rhombic, 80° included angle; D, rhombic, 55° included angle; E, rhombic, 75° included angle; M, rhombic, 86° included angle; V, rhombic, 35° included angle; W, hexagonal, 80° included angle; L, rectangular; A, parallelogram, 85° included angle; B, parallelogram, 82° included angle; K, parallelogram, 55° included angle; R, round. The included angle is always the smaller angle.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 760
CUTTING TOOLS
3) Holder Style: The holder style designates the shank style and the side cutting edge angle, or end cutting edge angle, or the purpose for which the holder is used. It is designated by a letter: A, for straight shank with 0° side cutting edge angle; B, straight shank with 15° side cutting edge angle; C, straight-shank end cutting tool with 0° end cutting edge angle; D, straight shank with 45° side cutting edge angle; E, straight shank with 30° side cutting edge angle; F, offset shank with 0° end cutting edge angle; G, offset shank with 0° side cutting edge angle; J, offset shank with negative 3° side cutting edge angle; K, offset shank with 15° end cutting edge angle; L, offset shank with negative 5° side cutting edge angle and 5° end cutting edge angle; M, straight shank with 40° side cutting edge angle; N, straight shank with 27° side cutting edge angle; R, offset shank with 15° side cutting edge angle; S, offset shank with 45° side cutting edge angle; T, offset shank with 30° side cutting edge angle; U, offset shank with negative 3° end cutting edge angle; V, straight shank with 171⁄2° side cutting edge angle; W, offset shank with 30° end cutting edge angle; Y, offset shank with 5° end cutting edge angle. 4) Normal Clearances: The normal clearances of inserts are identified by letters: A, 3°; B, 5°; C, 7°; D, 15°; E, 20°; F, 25°; G, 30°; N, 0°; P, 11°. 5) Hand of tool: The hand of the tool is designated by a letter: R for right-hand; L, lefthand; and N, neutral, or either hand. 6) Tool Height for Rectangular Shank Cross Sections: The tool height for tool holders with a rectangular shank cross section and the height of cutting edge equal to shank height is given as a two-digit number representing this value in millimeters. For example, a height of 32 mm would be encoded as 32; 8 mm would be encoded as 08, where the one-digit value is preceded by a zero. 7) Tool Width for Rectangular Shank Cross Sections: The tool width for tool holders with a rectangular shank cross section is given as a two-digit number representing this value in millimeters. For example, a width of 25 mm would be encoded as 25; 8 mm would be encoded as 08, where the one-digit value is preceded by a zero. 8) Tool Length: The tool length is designated by a letter: A, 32 mm; B, 40 mm; C, 50 mm; D, 60 mm; E, 70 mm; F, 80 mm; G, 90 mm; H, 100 mm; J, 110 mm; K, 125 mm; L, 140 mm; M, 150 mm; N, 160 mm; P, 170 mm; Q, 180 mm; R, 200 mm; S, 250 mm; T, 300 mm; U, 350 mm; V, 400 mm; W, 450 mm; X, special length to be specified; Y, 500 mm. 9) Indexable Insert Size: The size of indexable inserts is encoded as follows: For insert shapes C, D, E, H. M, O, P, R, S, T, V, the side length (the diameter for R inserts) in millimeters is used as a two-digit number, with decimals being disregarded. For example, the symbol for a side length of 16.5 mm is 16. For insert shapes A, B, K, L, the length of the main cutting edge or of the longer cutting edge in millimeters is encoded as a two-digit number, disregarding decimals. If the symbol obtained has only one digit, then it should be preceded by a zero. For example, the symbol for a main cutting edge of 19.5 mm is 19; for an edge of 9.5 mm, the symbol is 09. 10) Special Tolerances: Special tolerances are indicated by a letter: Q, back and end qualified tool; F, front and end qualified tool; B, back, front, and end qualified tool. A qualified tool is one that has tolerances of ± 0.08 mm for dimensions F, G, and C. (See Table 2.) Table 2. Letter Symbols for Qualification of Tool Holders Position 10 ANSI B212.5-2002
Qualification of Tool Holder
Q
Back and end qualified tool
Letter Symbol F
Front and end qualified tool
B
Back, front, and end qualified tool
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CUTTING TOOLS
761
Selecting Indexable Insert Holders.—A guide for selecting indexable insert holders is provided by Table 3b. Some operations such as deep grooving, cut-off, and threading are not given in this table. However, tool holders designed specifically for these operations are available. The boring operations listed in Table 3b refer primarily to larger holes, into which the holders will fit. Smaller holes are bored using boring bars. An examination of this table shows that several tool-holder styles can be used and frequently are used for each operation. Selection of the best holder for a given job depends largely on the job and there are certain basic facts that should be considered in making the selection. Rake Angle: A negative-rake insert has twice as many cutting edges available as a comparable positive-rake insert. Sometimes the tool life obtained when using the second face may be less than that obtained on the first face because the tool wear on the cutting edges of the first face may reduce the insert strength. Nevertheless, the advantage of negative-rake inserts and holders is such that they should be considered first in making any choice. Positive-rake holders should be used where lower cutting forces are required, as when machining slender or small-diameter parts, when chatter may occur, and for machining some materials, such as aluminum, copper, and certain grades of stainless steel, when positivenegative rake inserts can sometimes be used to advantage. These inserts are held on negative-rake holders that have their rake surfaces ground or molded to form a positive-rake angle. Insert Shape: The configuration of the workpiece, the operation to be performed, and the lead angle required often determine the insert shape. When these factors need not be considered, the insert shape should be selected on the basis of insert strength and the maximum number of cutting edges available. Thus, a round insert is the strongest and has a maximum number of available cutting edges. It can be used with heavier feeds while producing a good surface finish. Round inserts are limited by their tendency to cause chatter, which may preclude their use. The square insert is the next most effective shape, providing good corner strength and more cutting edges than all other inserts except the round insert. The only limitation of this insert shape is that it must be used with a lead angle. Therefore, the square insert cannot be used for turning square shoulders or for back-facing. Triangle inserts are the most versatile and can be used to perform more operations than any other insert shape. The 80-degree diamond insert is designed primarily for heavy turning and facing operations, using the 100-degree corners, and for turning and back-facing square shoulders using the 80-degree corners. The 55- and 35-degree diamond inserts are intended primarily for tracing. Lead Angle: Tool holders should be selected to provide the largest possible lead angle, although limitations are sometimes imposed by the nature of the job. For example, when tuning and back-facing a shoulder, a negative lead angle must be used. Slender or smalldiameter parts may deflect, causing difficulties in holding size, or chatter when the lead angle is too large. End Cutting Edge Angle: When tracing or contour turning, the plunge angle is determined by the end cutting edge angle. A 2-deg minimum clearance angle should be provided between the workpiece surface and the end cutting edge of the insert. Table 3a provides the maximum plunge angle for holders commonly used to plunge when tracing where insert shape identifiers are S = square, T = triangle, D = 55-deg diamond, V = 35-deg diamond. When severe cratering cannot be avoided, an insert having a small, end cutting edge angle is desirable to delay the crater breakthrough behind the nose. For very heavy cuts a small, end cutting edge angle will strengthen the corner of the tool. Tool holders for numerical control machines are discussed in the NC section, beginning page 1309.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 762
CUTTING TOOLS Table 3a. Maximum Plunge Angle for Tracing or Contour Turning
Tool Holder Style E D and S H J
Maximum Plunge Angle 58° 43° 71° 25°
Insert Shape T S D T
Tool Holder Style J J N N
Maximum Plunge Angle 30° 50° 55° 58°–60°
Insert Shape D V T D
R
A
R
B
T
B
䊉
䊉
P
䊉
䊉
䊉
N
䊉
䊉
䊉
P
䊉
䊉
䊉
N
䊉
䊉
䊉
N
䊉
䊉
䊉
N
䊉
䊉
Bore
䊉
Plane
Chamfer
Groove
Trace
Turn and Backface
Turn and Face
N
T
A
B
Face
A
Turn
T
N-Negative P-Positive
A
Application
Rake
Insert Shape
Tool
Tool Holder Style
Table 3b. Indexable Insert Holder Application Guide
䊉
䊉
䊉
䊉
P
䊉
䊉
N
䊉
䊉
䊉
䊉
P
䊉
䊉
䊉
䊉
N
䊉
䊉
䊉
P
䊉
䊉
䊉
N
䊉
䊉
N
䊉
䊉
䊉
䊉
P
䊉
䊉
䊉
䊉
T
䊉
S
B
C
C
T
䊉
䊉
Copyright 2004, Industrial Press, Inc., New York, NY
䊉
Machinery's Handbook 27th Edition CUTTING TOOLS
763
Bore
Plane
䊉
䊉
䊉
䊉
䊉
䊉
P
䊉
䊉
䊉
䊉
䊉
䊉
䊉
N
䊉
䊉
䊉
䊉
䊉
P
䊉
䊉
䊉
䊉
䊉
N
䊉
䊉
䊉
P
䊉
䊉
䊉
N
䊉
䊉
䊉
P
䊉
䊉
䊉
N
䊉
䊉
䊉
N
䊉
䊉
䊉
P
䊉
䊉
䊉
N
䊉
䊉
Groove
䊉
Trace
N
Turn and Backface
Chamfer
G
Turn and Face
F
Face
E
Turn
S
N-Negative P-Positive
D
Application
Rake
Insert Shape
Tool
Tool Holder Style
Table 3b. (Continued) Indexable Insert Holder Application Guide
T
T
T
G
R
G
C
H
D
J
T
J
D
J
V
K
S
䊉
N
䊉
䊉
P
䊉
䊉
N
䊉
䊉
N
䊉
䊉
N
䊉
䊉
䊉
P
䊉
䊉
䊉
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 764
CARBIDE TIPS AND TOOLS
N
D
S
S
W
Plane
Bore
Chamfer
䊉
䊉
N
Groove
䊉
Trace
T
䊉
Turn and Backface
N
N
Turn and Face
C
Face
L
Turn
C
N-Negative P-Positive
K
Application
Rake
Insert Shape
Tool
Tool Holder Style
Table 3b. (Continued) Indexable Insert Holder Application Guide
䊉
N
䊉
䊉
䊉
P
䊉
䊉
䊉
N
䊉
䊉
䊉
N
䊉
䊉
䊉
䊉
䊉
䊉
䊉
P
䊉
䊉
䊉
䊉
䊉
䊉
䊉
N
䊉
䊉
S
Sintered Carbide Blanks and Cutting Tools Sintered Carbide Blanks.—As shown in Table 4, American National Standard ANSI B212.1-2002 provides standard sizes and designations for eight styles of sintered carbide blanks. These blanks are the unground solid carbide from which either solid or tipped cutting tools are made. Tipped cutting tools are made by brazing a blank onto a shank to produce the cutting tool; these tools differ from carbide insert cutting tools which consist of a carbide insert held mechanically in a tool holder. A typical single-point carbide-tipped cutting tool is shown in Fig. 1 on page 766. Single-Point, Sintered-Carbide-Tipped Tools.—American National Standard ANSI B212.1-2002 covers eight different styles of single-point, carbide-tipped general purpose tools. These styles are designated by the letters A to G inclusive. Styles A, B, F, G, and E with offset point are either right- or left-hand cutting as indicated by the letters R or L. Dimensions of tips and shanks are given in Tables 5 to 12. For dimensions and tolerances not shown, and for the identification system, dimensions, and tolerances of sintered carbide boring tools, see the Standard. A number follows the letters of the tool style and hand designation and for square shank tools, represents the number of sixteenths of an inch of width, W, and height, H. With rectangular shanks, the first digit of the number indicates the number of eighths of an inch in the shank width, W, and the second digit the number of quarters of an inch in the shank
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CARBIDE TIPS AND TOOLS
765
Table 4. American National Standard Sizes and Designations for Carbide Blanks ANSI B212.1-2002 Styleb Blank Dimensionsa T
W
L
1⁄ 16 1⁄ 16 1⁄ 16 1⁄ 16 1⁄ 16 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 5⁄ 32 5⁄ 32 5⁄ 32 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16
1⁄ 8 5⁄ 32 3⁄ 16 1⁄ 4 1⁄ 4 1⁄ 8 3⁄ 16 3⁄ 16 1⁄ 4 1⁄ 4 5⁄ 16 3⁄ 8 3⁄ 8 7⁄ 16 5⁄ 16 3⁄ 16 1⁄ 4 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 3⁄ 4 3⁄ 8 3⁄ 8 5⁄ 8 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 3⁄ 8 7⁄ 16 7⁄ 16 1⁄ 2 1⁄ 2 3⁄ 4
5⁄ 8 1⁄ 4 1⁄ 4 1⁄ 4 5⁄ 16 3⁄ 4 5⁄ 16 1⁄ 2 3⁄ 8 1⁄ 2 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 3⁄ 8 3⁄ 4 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 16 1⁄ 2 3⁄ 4 5⁄ 8 1⁄ 2 3⁄ 4 1⁄ 2 3⁄ 4 3⁄ 4 9⁄ 16 3⁄ 4 5⁄ 8 7⁄ 16 5⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 5⁄ 8 13⁄ 16 1⁄ 2 3⁄ 4 3⁄ 4
1000
Styleb 2000
Blank Designation 1010
2010
1015
2015
1020
2020
1025
2025
1030
2030
1035
2035
1040
2040
1050
2050
1060
2060
1070
2070
1080
2080
1090
2090
1100
2100
1105
2105
1080
2080
1110
2110
1120
2120
1130
2130
1140
2140
1150
2150
1160
2160
1110
2110
1170
2170
1180
2180
1190
2190
1200
2200
1210
2210
1215
2215
1220
2220
1230
2230
1240
2240
1250
2250
1260
2260
1270
2270
1280
2280
1290
2290
1300
2300
1310
2310
1320
2320
1330
2330
1340
2340
Blank Dimensionsa T
W
L
1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 3⁄ 8 1⁄ 2
3⁄ 8 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 3⁄ 4
9⁄ 16 3⁄ 4 5⁄ 8 3⁄ 4
1
1000
3000
4000
Blank Designation 0350
1350
3350
4350
0360
1360
3360
4360
0370
1370
3370
4370
0380
1380
3380
4380
0390
1390
3390
4390
0400
1400
3400
4400
0405
1405
3405
4405
0410
1410
3410
4410
0415
1415
3415
4415
0420
1420
3420
4420
0430
1430
3430
4430
0440
1440
3440
4440
1
0450
1450
3450
4450
1
0460
1460
3460
4460
3⁄ 4
0470
1470
3470
4470
0475
1475
3475
4475
11⁄4
0480
1480
3480
4480
3⁄ 4
1 5⁄ 8 3⁄ 4
1 1
7⁄ 16 7⁄ 16 1⁄ 2 1⁄ 2 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 1⁄ 2 3⁄ 4
0000
5⁄ 8 15⁄ 16 3⁄ 4
1
0490
1490
3490
4490
1
0500
1500
3500
4500
1
0510
1510
3510
4510
11⁄4
0515
1515
3515
4515
11⁄4
0520
1520
3520
4520
11⁄2
0525
1525
3525
4525
0530
1530
3530
4530
0540
1540
3540
4540
0490
1490
3490
4490
0550
1550
3550
4550
1 11⁄4 3⁄ 4 11⁄2
Styleb T 1⁄ 16 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 1⁄ 8 3⁄ 32 1⁄ 8 5⁄ 32 5⁄ 32 3⁄ 16 1⁄ 4
W 1⁄ 4 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 5⁄ 16 1⁄ 4 1⁄ 2 3⁄ 8 5⁄ 8 3⁄ 4
1
L 5⁄ 16 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 5⁄ 8 3⁄ 8 1⁄ 2 3⁄ 4 5⁄ 8 3⁄ 4 3⁄ 4
F …
5000 5030
6000 …
70000 …
…
…
7060
5080
6080
…
6100
…
1⁄ 16
… …
5100
…
5105
…
…
3⁄ 32 1⁄ 16
…
…
7170
…
…
7060
…
5200
6200
…
1⁄ 8
…
…
7230
…
5240
6240
…
…
5340
6340
…
…
5410
…
…
a All dimensions are in inches. b See Fig. 1 on page
766 for a description of styles.
height, H. One exception is the 11⁄2 × 2-inch size which has been arbitrarily assigned the number 90. A typical single-point carbide tipped cutting tool is shown in Fig. 2. The side rake, side relief, and the clearance angles are normal to the side-cutting edge, rather than the shank, to facilitate its being ground on a tilting-table grinder. The end-relief and clearance angles are
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 766
CARBIDE TIPS AND TOOLS
Fig. 1. Eight styles of sintered carbide blanks (see Table 4.)
Side Rake
Side Relief Angle
Side Clearance Angle
Tip Width
Tip Overhang Nose Radius
End Cutting Edge Angle (ECEA) Shank Width Side Cutting Edge Angle (SCEA) Overall length Tip length
Tip Thickness
Back Rake
Cutting Height Tip Overhang End Relief Angle End Clearance Angle
Shank Height
Fig. 2. A typical single-point carbide tipped cutting tool.
normal to the end-cutting edge. The back-rake angle is parallel to the side-cutting edge. The tip of the brazed carbide blank overhangs the shank of the tool by either 1⁄32 or 1⁄16 inch, depending on the size of the tool. For tools in Tables 5, 6, 7, 8, 11 and , the maximum overhang is 1⁄32 inch for shank sizes 4, 5, 6, 7, 8, 10, 12 and 44; for other shank sizes in these tables, the maximum overhang is 1⁄16 inch. In Tables 9 and 10 all tools have maximum overhang of 1⁄32 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CARBIDE TIPS AND TOOLS
767
Single-point Tool Nose Radii: The tool nose radii recommended in the American National Standard are as follows: For square-shank tools up to and including 3⁄8-inch square tools, 1⁄64 inch; for those over 3⁄8-inch square through 11⁄4-inches square, 1⁄32 inch; and for those above 11⁄4-inches square, 1⁄16 inch. For rectangular-shank tools with shank section of 1⁄2 × 1 inch through 1 × 11⁄2 inches, the nose radii are 1⁄32 inch, and for 1 × 2 and 11⁄2 × 2 inch shanks, the nose radius is 1⁄16 inch. Single-point Tool Angle Tolerances: The tool angles shown on the diagrams in the Tables 5 through 12 are general recommendations. Tolerances applicable to these angles are ± 1 degree on all angles except end and side clearance angles; for these the tolerance is ± 2 degrees. Table 5. American National Standard Style A Carbide Tipped Tools ANSI B212.1-2002
Designation Style ARa
Shank Dimensions
Style ALa
Width A
Height B
1⁄ 4
Tip Dimensions Tip Designationa
Length C
Thickness T
Width W
Length L
Square Shank AR 4
AL 4
1⁄ 4
2
AR 5
AL 5
5⁄ 16
2040
3⁄ 32
3⁄ 16
5⁄ 16
5⁄ 16
21⁄4
2070
3⁄ 32
1⁄ 4
1⁄ 2
AR 6
AL 6
3⁄ 8
AR 7
AL 7
7⁄ 16
3⁄ 8
21⁄2
2070
3⁄ 32
1⁄ 4
1⁄ 2
3
2070
3⁄ 32
1⁄ 4
AR 8
AL 8
1⁄ 2
1⁄ 2
1⁄ 2
31⁄2
2170
1⁄ 8
5⁄ 16
AR 10
AL 10
5⁄ 8
5⁄ 8
5⁄ 8
4
2230
5⁄ 32
3⁄ 8
3⁄ 4
AR 12
AL 12
AR 16
AL 16
1
3⁄ 4
3⁄ 4
41⁄2
2310
3⁄ 16
7⁄ 16
1
6
{
P3390, P4390
1⁄ 4
9⁄ 16
1
AR 20
AL 20
AR 24
AL 24
11⁄4
11⁄4
7
{
P3460, P4460
5⁄ 16
5⁄ 8
1
11⁄2
11⁄2
8
{
P3510, P4510
3⁄ 8
5⁄ 8
1
7⁄ 16
13⁄ 16
Rectangular Shank AR 44
AL 44
1⁄ 2
1
6
AR 54
AL 54
5⁄ 8
1
6
AR 55
AL 55
5⁄ 8
11⁄4
7
AR 64
AL 64
3⁄ 4
1
6
AR 66
AL 66
3⁄ 4
11⁄2
8
AR 85
AL 85
1
11⁄4
7
AR 86
AL 86
1
11⁄2
AR 88
AL 88
1
2
AL 90
11⁄2
AR 90
2
P2260
3⁄ 16
5⁄ 16
5⁄ 8
P3360, P4360
1⁄ 4
3⁄ 8
3⁄ 4
{
P3360, P4360
1⁄ 4
3⁄ 8
3⁄ 4
{
P3380, P4380
1⁄ 4
1⁄ 2
3⁄ 4
{
P3430, P4430
5⁄ 16
7⁄ 16
{
P3460, P4460
5⁄ 16
5⁄ 8
1
{
15⁄ 16
8
{
P3510, P4510
3⁄ 8
5⁄ 8
1
10
{
P3510, P4510
3⁄ 8
5⁄ 8
1
P3540, P4540
1⁄ 2
3⁄ 4
11⁄4
10
{
a
“A” is straight shank, 0 deg., SCEA (side-cutting-edge angle). “R” is right-cut. “L” is left-cut. Where a pair of tip numbers is shown, the upper number applies to AR tools, the lower to AL tools. All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 768
CARBIDE TIPS AND TOOLS Table 6. American National Standard Style B Carbide Tipped Tools with 15-degree Side-cutting-edge Angle ANSI B212.1-2002 7° ±1°
6° ± 1° To sharp corner
10° ± 2°
15° ± 1°
W
Overhang
F Ref
T
A L
R
15° ± 1° C
0° ± 1° H
Tool designation and carbide grade
Overhang 7° ±1°
10° ± 2°
B
Style GR right hand (shown) Style GE left hand (not shown) Designation Style BR Style BL
Width A
Shank Dimensions Height Length B C
Tip Designationa
Tip Dimensions Thickness Width T W
Length L
Square Shank BR 4 BR 5 BR 6 BR 7 BR 8 BR 10 BR 12 BR 16 BR 20 BR 24
BL 4 BL 5 BL 6 BL 7 BL 8 BL 10 BL 12 BL 16 BL 20 BL 24
BR 44 BR 54 BR 55 BR 64 BR 66 BR 85 BR 86 BR 88 BR 90
BL 44 BL 54 BL 55 BL 64 BL 66 BL 85 BL 86 BL 88 BL 90
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
1 11⁄4 11⁄2
1 11⁄4 11⁄2
1⁄ 2 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4
1 1 11⁄4 1 11⁄2 11⁄4 11⁄2 2 2
2 21⁄4 21⁄2 3 31⁄2 4 41⁄2 6 7 8
{ { {
2015 2040 2070 2070 2170 2230 2310 3390, 4390 3460, 4460 3510, 4510
1⁄ 16 3⁄ 32 3⁄ 32 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8
5⁄ 32 3⁄ 16 1⁄ 4 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 9⁄ 16 5⁄ 8 5⁄ 8
3⁄ 16 1⁄ 4 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 1⁄ 2
5⁄ 16 3⁄ 8 3⁄ 8 1⁄ 2 7⁄ 16 5⁄ 8 5⁄ 8 5⁄ 8 3⁄ 4
1⁄ 4 5⁄ 16 1⁄ 2 1⁄ 2 5⁄ 8 3⁄ 4 13⁄ 16
1 1 1
Rectangular Shank
1 1 1 11⁄2
6 6 7 6 8 7 8 10 10
{ { { { { { { {
2260 3360, 4360 3360, 4360 3380, 4380 3430, 4430 3460, 4460 3510, 4510 3510, 4510 3540, 4540
5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4 15⁄ 16
1 1 1 11⁄4
a Where a pair of tip numbers is shown, the upper number applies to BR tools, the lower to BL tools. All dimensions are in inches.
Brazing Carbide Tips to Steel Shanks.—Sintered carbide tips or blanks are attached to steel shanks by brazing. Shanks usually are made of low-alloy steels having carbon contents ranging from 0.40 to 0.60 per cent. Shank Preparation: The carbide tip usually is inserted into a milled recess or seat. When a recess is used, the bottom should be flat to provide a firm even support for the tip. The corner radius of the seat should be somewhat smaller than the radius on the tip to avoid contact and insure support along each side of the recess. Cleaning: All surfaces to be brazed must be absolutely clean. Surfaces of the tip may be cleaned by grinding lightly or by sand-blasting. Brazing Materials and Equipment: The brazing metal may be copper, naval brass such as Tobin bronze, or silver solder. A flux such as borax is used to protect the clean surfaces and prevent oxidation. Heating may be done in a furnace or by oxy-acetylene torch or an oxy-hydrogen torch. Copper brazing usually is done in a furnace, although an oxy-hydrogen torch with excess hydrogen is sometimes used. Brazing Procedure: One method using a torch is to place a thin sheet material, such as copper foil, around and beneath the carbide tip, the top of which is covered with flux. The flame is applied to the under side of the tool shank, and, when the materials melt, the tip is pressed firmly into its seat with tongs or with the end of a rod. Brazing material in the form of wire or rod may be used to coat or tin the surfaces of the recess after the flux melts and runs freely. The tip is then inserted, flux is applied to the top, and heating continued until the coatings melt and run freely. The tip, after coating with flux, is placed in the recess and the shank end is heated. Then a small piece of silver solder, having a melting point of 1325 degrees F., is placed on top of the tip. When this solder melts, it runs over the nickel-coated surfaces while the tip is held firmly into its seat. The brazed tool should be cooled slowly to avoid cracking due to unequal contraction between the steel and carbide.
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Machinery's Handbook 27th Edition CARBIDE TIPS AND TOOLS
769
Table 7. American National Standard Style C Carbide Tipped Tools ANSI B212.1-2002 3°I2° 0.015 × 45° Maximum permissible
Overhang W 5° ± 2° Both sides 0° ± 1°
A
F
C Tool designation and carbide grade
90° ± 1° 0° ± 1°
T
L
B
H Overhang
7° ± 1°
Note – Tool must pass thru slot of nominal width “A”
10° ± 2° Designation
Width, A
Shank Dimensions Height, B Length, C
Tip Designnation
Thickness, T
1 11⁄4
2 21⁄4 21⁄2 3 31⁄2 4 41⁄2 6 7
1030 1080 1090 1105 1200 1240 1340 1410 1480
1⁄ 16 3⁄ 32 3⁄ 32 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16 1⁄ 4 5⁄ 16
1 1 11⁄4 1 11⁄2 11⁄2
6 6 7 6 8 8
1320 1400 1400 1405 1470 1475
3⁄ 16 1⁄ 4 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
C4 C5 C6 C7 C8 C 10 C 12 C 16 C 20
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
1 11⁄4 1⁄ 2 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4
C 44 C 54 C 55 C 64 C 66 C 86
1
Tip Dimensions Width, W
Length, L
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
5⁄ 16 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4
1 11⁄4 1⁄ 2 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4
1⁄ 2 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4
1
All dimensions are in inches. Square shanks above horizontal line; rectangular below.
Table 8. American National Standard Style D, 80-degree Nose-angle Carbide Tipped Tools ANSI B212.1-2002 10° ± 2° Both sides 7° ± 1° Overhang
Note – Tool must pass thru slot of nominal width “A” R
W 0° ± 1°
40° ± 1° A
F
40° ± 1° C±
To sharp corner 0° ± 1°
T
L
1 8
Tool designation and carbide grade
H Designation D4 D5 D6 D7 D8 D 10 D 12 D 16
Width, A
1
B
Shank Dimensions Height, B Length, C
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
1
2 21⁄4 21⁄2 3 31⁄2 4 41⁄2 6
+0.000 –0.010
+0.000 –0.010
Tip Designation
Thickness, T
5030 5080 5100 5105 5200 5240 5340 5410
1⁄ 16 3⁄ 32 3⁄ 32 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16 1⁄ 4
Tip Dimensions Width, W 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
1
All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Length, L 5⁄ 16 3⁄ 8 1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 3⁄ 4 3⁄ 4
Machinery's Handbook 27th Edition 770
CARBIDE TIPS AND TOOLS
Table 9. American National Standard Style E, 60-degree Nose-angle, Carbide Tipped Tools ANSI B212.1-2002
Designation
Width A
Shank Dimensions Height B
1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4
1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4
E4 E5 E6 E8 E 10 E 12
Tip Designation
Thickness T
Tip Dimensions Width W
Length L
2
6030
21⁄4
6080
21⁄2
6100
1⁄ 16 3⁄ 32 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16
1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4
5⁄ 16 3⁄ 8 1⁄ 2 1⁄ 2 5⁄ 8 3⁄ 4
Length C
31⁄2
6200
4
6240
41⁄2
6340
All dimensions are in inches.
Table 10. American National Standard Styles ER and EL, 60-degree Nose-angle, Carbide Tipped Tools with Offset Point ANSI B212.1-2002
Designation Style Style ER EL ER 4
EL 4
ER 5
EL 5
ER 6
EL 6
ER 8
EL 8
ER 10
EL 10
ER 12
EL 12
Width A
Shank Dimensions Height Length B C
1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4
1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4
Tip Designation
2
1020
21⁄4
7060
21⁄2
7060
31⁄2
7170
4
7170
41⁄2
7230
Thick. T
Tip Dimensions Width Length W L
1⁄ 16 3⁄ 32 3⁄ 32 1⁄ 8 1⁄ 8 5⁄ 32
All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
3⁄ 16 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8
1⁄ 4 3⁄ 8 3⁄ 8 5⁄ 8 5⁄ 8 3⁄ 4
Machinery's Handbook 27th Edition CARBIDE TIPS AND TOOLS
771
Table 11. American National Standard Style F, Offset, End-cutting Carbide Tipped Tools ANSI B212.1-2002
Designation
Style FR
Style FL
Shank Dimensions
Width A
Height B
Length C
Tip Dimensions
Offset G
Length of Offset E
Tip Designation
Thickness T
Width W
Length L
1⁄ 8 5⁄ 32 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8
5⁄ 16 3⁄ 8 7⁄ 16 9⁄ 16 5⁄ 8 5⁄ 8
5⁄ 8 3⁄ 4 13⁄ 16
3⁄ 16 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8 1⁄ 2
5⁄ 16 3⁄ 8 1⁄ 2 7⁄ 16 5⁄ 8 5⁄ 8 3⁄ 4
5⁄ 8 3⁄ 4 3⁄ 4 15⁄ 16
Square Shank 1⁄ 2 5⁄ 8 3⁄ 4
31⁄2
FL 12
1⁄ 2 5⁄ 8 3⁄ 4
FL 16
1
1
6
FR 20
FL 20
11⁄4
11⁄4
7
FR 24
FL 24
11⁄2
11⁄2
8
FR 8
FL 8
FR 10
FL 10
FR 12 FR 16
4 41⁄2
1⁄ 4 3⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4
3⁄ 4
{
P4170, P3170
1
{
P1230, P3230
11⁄8
{
P4310, P3310
13⁄8
{
P4390, P3390
11⁄2
{
P4460, P3460
11⁄2
{
P4510, P3510
1 1 1
Rectangular Shank FR 44
FL 44
FR 55
FL 55
FR 64
FL 64
FR 66
FL 66
1⁄ 2 5⁄ 8 3⁄ 4 3⁄ 4
FR 85
FL 85
FR 86 FR 90
1
6
11⁄4
7
1
6
11⁄2
8
1
11⁄4
7
FL 86
1
11⁄2
8
FL 90
11⁄2
2
10
1⁄ 2 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4
7⁄ 8
{
P4260, P1260
11⁄8
{
P4360, P3360
13⁄16
{
P4380, P3380
11⁄4
{
P4430, P3430
11⁄2
{
P4460, P3460
11⁄2
{
P4510, P3510
15⁄8
{
P4540, P3540
1 1 11⁄4
All dimensions are in inches. Where a pair of tip numbers is shown, the upper number applies to FR tools, the lower number to FL tools.
Carbide Tools.—Cemented or sintered carbides are used in the machine building and various other industries, chiefly for cutting tools but also for certain other tools or parts subject to considerable abrasion or wear. Carbide cutting tools, when properly selected to obtain the right combination of strength and hardness, are very effective in machining all classes of iron and steel, non-ferrous alloys, non-metallic materials, hard rubber, synthetic resins, slate, marble, and other materials which would quickly dull steel tools either because of hardness or abrasive action. Carbide cutting tools are not only durable, but capable of exceptionally high cutting speeds. See CEMENTED CARBIDES starting on page 773 for more on these materials. Tungsten carbide is used extensively in cutting cast iron, nonferrous metals which form short chips in cutting; plastics and various other non-metallic materials. A grade having a hardness of 87.5 Rockwell A might be used where a strong grade is required, as for roughing cuts, whereas for light high-speed finishing or other cuts, a hardness of about 92 might be preferable. When tungsten carbide is applied to steel, craters or chip cavities are formed
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 772
CARBIDE TIPS AND TOOLS Table 12. American National Standard Style G, Offset, Side-cutting, Carbide Tipped Tools ANSI B212.1-2002
Designation
Tip Dimensions
Shank Dimensions
Style GR
Style GL
Width A
Height B
Length C
Offset G
GR 8
GL 8 GL 10
GR 12
GL 12
1⁄ 2 5⁄ 8 3⁄ 4
31⁄2
GR 10
1⁄ 2 5⁄ 8 3⁄ 4
GR 16
GL 16
1
1
6
GR 20
GL 20
11⁄4
11⁄4
7
GR 24
GL 24
11⁄2
11⁄2
8
1⁄ 4 3⁄ 8 3⁄ 8 1⁄ 2 3⁄ 4 3⁄ 4
Length of Offset E
Tip Designation
Thickness T
Width W
Length L
1⁄ 8 5⁄ 32 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8
5⁄ 16 3⁄ 8 7⁄ 16 9⁄ 16 5⁄ 8 5⁄ 8
5⁄ 8 3⁄ 4 13⁄ 16
3⁄ 16 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8 1⁄ 2
5⁄ 16 3⁄ 8 1⁄ 2 7⁄ 16 5⁄ 8 5⁄ 8 3⁄ 4
Square Shank 4 41⁄2
11⁄16
{
P3170, P4170
13⁄8
{
P3230, P4230
11⁄2
{
P3310, P2310
111⁄16
{
P3390, P4390
113⁄16
{
P3460, P4460
113⁄16
{
P3510, P4510
1 1 1
Rectangular Shank 1
6
11⁄4
7
GL 66
1⁄ 2 5⁄ 8 3⁄ 4 3⁄ 4
GR 85
GL 85
GR 86 GR 90
GR 44
GL 44
GR 55
GL 55
GR 64
GL 64
GR 66
1
6
11⁄2
8
1
11⁄4
7
GL 86
1
11⁄2
8
GL 90
11⁄2
2
10
1⁄ 4 3⁄ 8 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 3⁄ 4
11⁄16
{
P3260, P4260
13⁄8
{
P3360, P4360
17⁄16
{
P3380, P4380
15⁄8
{
P3430, P4430
111⁄16
{
P3460, P4460
111⁄16
{
P3510, P4510
21⁄16
{
P3540, P4540
5⁄ 8 3⁄ 4 3⁄ 4 15⁄ 16
1 1 11⁄4
All dimensions are in inches. Where a pair of tip numbers is shown, the upper number applies to GR tools, the lower number to GL tools.
back of the cutting edge; hence other carbides have been developed which offer greater resistance to abrasion. Tungsten-titanium carbide (often called “titanium carbide”) is adapted to cutting either heat-treated or unheattreated steels, cast steel, or any tough material which might form chip cavities. It is also applicable to bronzes, monel metal, aluminum alloys, etc. Tungsten-tantalum carbide or “tantalum carbide” cutting tools are also applicable to steels, bronzes or other tough materials. A hardness of 86.8 Rockwell A is recommended by one manufacturer for roughing steel, whereas a grade for finishing might have a hardness ranging from 88.8 to 91.5 Rockwell A.
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Machinery's Handbook 27th Edition CEMENTED CARBIDES AND OTHER HARD MATERIALS
773
CEMENTED CARBIDES Cemented Carbides and Other Hard Materials Carbides and Carbonitrides.—Though high-speed steel retains its importance for such applications as drilling and broaching, most metal cutting is carried out with carbide tools. For materials that are very difficult to machine, carbide is now being replaced by carbonitrides, ceramics, and superhard materials. Cemented (or sintered) carbides and carbonitrides, known collectively in most parts of the world as hard metals, are a range of very hard, refractory, wear-resistant alloys made by powder metallurgy techniques. The minute carbide or nitride particles are “cemented” by a binder metal that is liquid at the sintering temperature. Compositions and properties of individual hardmetals can be as different as those of brass and high-speed steel. All hardmetals are cermets, combining ceramic particles with a metallic binder. It is unfortunate that (owing to a mistranslation) the term cermet has come to mean either all hardmetals with a titanium carbide (TiC) base or simply cemented titanium carbonitrides. Although no single element other than carbon is present in all hard-metals, it is no accident that the generic term is “tungsten carbide.” The earliest successful grades were based on carbon, as are the majority of those made today, as listed in Table 1. The outstanding machining capabilities of high-speed steel are due to the presence of very hard carbide particles, notably tungsten carbide, in the iron-rich matrix. Modern methods of making cutting tools from pure tungsten carbide were based on this knowledge. Early pieces of cemented carbide were much too brittle for industrial use, but it was soon found that mixing tungsten carbide powder with up to 10 per cent of metals such as iron, nickel, or cobalt, allowed pressed compacts to be sintered at about 1500°C to give a product with low porosity, very high hardness, and considerable strength. This combination of properties made the materials ideally suitable for use as tools for cutting metal. Cemented carbides for cutting tools were introduced commercially in 1927, and although the key discoveries were made in Germany, many of the later developments have taken place in the United States, Austria, Sweden, and other countries. Recent years have seen two “revolutions” in carbide cutting tools, one led by the United States and the other by Europe. These were the change from brazed to clamped carbide inserts and the rapid development of coating technology. When indexable tips were first introduced, it was found that so little carbide was worn away before they were discarded that a minor industry began to develop, regrinding the socalled “throwaway” tips and selling them for reuse in adapted toolholders. Hardmetal consumption, which had grown dramatically when indexable inserts were introduced, leveled off and began to decline. This situation was changed by the advent and rapid acceptance of carbide, nitride, and oxide coatings. Application of an even harder, more wear-resistant surface to a tougher, more shock-resistant substrate allowed production of new generations of longer-lasting inserts. Regrinding destroyed the enhanced properties of the coatings, so was abandoned for coated tooling. Brazed tools have the advantage that they can be reground over and over again, until almost no carbide is left, but the tools must always be reset after grinding to maintain machining accuracy. However, all brazed tools suffer to some extent from the stresses left by the brazing process, which in unskilled hands or with poor design can shatter the carbide even before it has been used to cut metal. In present conditions it is cheaper to use indexable inserts, which are tool tips of precise size, clamped in similarly precise holders, needing no time-consuming and costly resetting but usable only until each cutting edge or corner has lost its initial sharpness (see Introduction and related topics starting on page 756 and Indexable Insert Holders for NC on page 1309. The absence of brazing stresses and the “one-use” concept also means that harder, longer-lasting grades can be used.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 774
CEMENTED CARBIDES AND OTHER HARD MATERIALS
Table 1. Typical Properties of Tungsten-Carbide-Based Cutting-Tool Hardmetals Density (g/cm3)
Hardness (Vickers)
Transverse Rupture Strength (N/mm2)
8.5 11.4 11.5 11.7 12.1 12.9 13.3 13.4 13.1 13.4 13.3 13.6 14.0 15.2 15.0 14.9 14.8 14.4 14.1
1900 1820 1740 1660 1580 1530 1490 1420 1250 1590 1540 1440 1380 1850 1790 1730 1650 1400 1320
1100 1300 1400 1500 1600 1700 1850 1950 2300 1800 1900 2000 2100 1450 1550 1700 1950 2250 2500
Composition (%) ISO Application Code
WC
P01 P05 P10 P15 P20 P25 P30 P40 P50 M10 M20 M30 M40 K01 K05 K10 K20 K30 K40
50 78 69 78 79 82 84 85 78 85 82 86 84 97 95 92 94 91 89
TiC 35 16 15 12 8 6 5 5 3 5 5 4 4
TaC 7 8 3 5 4 2 3 4 5 2 1 2
Co 6 6 8 7 8 8 9 10 16 6 8 10 10 3 4 6 6 9 11
A complementary development was the introduction of ever-more complex chip-breakers, derived from computer-aided design and pressed and sintered to precise shapes and dimensions. Another advance was the application of hot isostatic pressing (HIP), which has moved hardmetals into applications that were formerly uneconomic. This method allows virtually all residual porosity to be squeezed out of the carbide by means of inert gas at high pressure, applied at about the sintering temperature. Toughness, rupture strength, and shock resistance can be doubled or tripled by this method, and the reject rates of very large sintered components are reduced to a fraction of their previous levels. Further research has produced a substantial number of excellent cutting-tool materials based on titanium carbonitride. Generally called “cermets,” as noted previously, carbonitride-based cutting inserts offer excellent performance and considerable prospects for the future. Compositions and Structures: Properties of hardmetals are profoundly influenced by microstructure. The microstructure in turn depends on many factors including basic chemical composition of the carbide and matrix phases; size, shape, and distribution of carbide particles; relative proportions of carbide and matrix phases; degree of intersolubility of carbides; excess or deficiency of carbon; variations in composition and structure caused by diffusion or segregation; production methods generally, but especially milling, carburizing, and sintering methods, and the types of raw materials; post sintering treatments such as hot isostatic pressing; and coatings or diffusion layers applied after initial sintering. Tungsten Carbide/Cobalt (WC/Co): The first commercially available cemented carbides consisted of fine angular particles of tungsten carbide bonded with metallic cobalt. Intended initially for wire-drawing dies, this composition type is still considered to have the greatest resistance to simple abrasive wear and therefore to have many applications in machining. For maximum hardness to be obtained from closeness of packing, the tungsten carbide grains should be as small as possible, preferably below 1 µm swaging 0.00004 in.) and considerably less for special purposes. Hardness and abrasion resistance increase as the cobalt content is lowered, provided that a minimum of cobalt is present (2 per cent can be
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Machinery's Handbook 27th Edition CEMENTED CARBIDES AND OTHER HARD MATERIALS
775
enough, although 3 per cent is the realistic minimum) to ensure complete sintering. In general, as carbide grain size or cobalt content or both are increased—frequently in unison— tougher and less hard grades are obtained. No porosity should be visible, even under the highest optical magnification. WC/Co compositions used for cutting tools range from about 2 to 13 per cent cobalt, and from less than 0.5 to more than 5 µm (0.00002–0.0002 in.) in grain size. For stamping tools, swaying dies, and other wear applications for parts subjected to moderate or severe shock, cobalt content can be as much as 30 per cent, and grain size a maximum of about 10 µm (0.0004 in.). In recent years, “micrograin” carbides, combining submicron (less than 0.00004 in.) carbide grains with relatively high cobalt content have found increasing use for machining at low speeds and high feed rates. An early use was in high-speed woodworking cutters such as are used for planing. For optimum properties, porosity should be at a minimum, carbide grain size as regular as possible, and carbon content of the tungsten carbide phase close to the theoretical (stoichiometric) value. Many tungsten carbide/cobalt compositions are modified by small but important additions—from 0.5 to perhaps 3 per cent of tantalum, niobium, chromium, vanadium, titanium, hafnium, or other carbides. The basic purpose of these additions is generally inhibition of grain growth, so that a consistently fine structure is maintained. Tungsten – Titanium Carbide/Cobalt (WC/TiC/Co): These grades are used for tools to cut steels and other ferrous alloys, the purpose of the TiC content being to resist the hightemperature diffusive attack that causes chemical breakdown and cratering. Tungsten carbide diffuses readily into the chip surface, but titanium carbide is extremely resistant to such diffusion. A solid solution or “mixed crystal” of WC in TiC retains the anticratering property to a great extent. Unfortunately, titanium carbide and TiC-based solid solutions are considerably more brittle and less abrasion resistant than tungsten carbide. TiC content, therefore, is kept as low as possible, only sufficient TiC being provided to avoid severe cratering wear. Even 2 or 3 per cent of titanium carbide has a noticeable effect, and as the relative content is substantially increased, the cratering tendency becomes more severe. In the limiting formulation the carbide is tungsten-free and based entirely on TiC, but generally TiC content extends to no more than about 18 per cent. Above this figure the carbide becomes excessively brittle and is very difficult to braze, although this drawback is not a problem with throwaway inserts. WC/TiC/Co grades generally have two distinct carbide phases, angular crystals of almost pure WC and rounded TiC/WC mixed crystals. Among progressive manufacturers, although WC/TiC/Co hardmetals are very widely used, in certain important respects they are obsolescent, having been superseded by the WC/TiC/Ta(Nb)C/Co series in the many applications where higher strength combined with crater resistance is an advantage. TiC, TiN, and other coatings on tough substrates have also diminished the attractions of highTiC grades for high-speed machining of steels and ferrous alloys. Tungsten-Titanium-Tantalum (-Niobium) Carbide/Cobalt: Except for coated carbides, tungsten-titanium-tantalum (-niobium) grades could be the most popular class of hardmetals. Used mainly for cutting steel, they combine and improve upon most of the best features of the longer-established WC/TiC/Co compositions. These carbides compete directly with carbonitrides and silicon nitride ceramics, and the best cemented carbides of this class can undertake very heavy cuts at high speeds on all types of steels, including austenitic stainless varieties. These tools also operate well on ductile cast irons and nickel-base superalloys, where great heat and high pressures are generated at the cutting edge. However, they do not have the resistance to abrasive wear possessed by micrograin straight tungsten carbide grades nor the good resistance to cratering of coated grades and titanium carbidebased cermets.
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Machinery's Handbook 27th Edition 776
CEMENTED CARBIDES AND OTHER HARD MATERIALS
Titanium Carbide/Molybdenum/Nickel (TiC/Mo/Ni): The extreme indentation hardness and crater resistance of titanium carbide, allied to the cheapness and availability of its main raw material (titanium dioxide, TiO2), provide a strong inducement to use grades based on this carbide alone. Although developed early in the history of hardmetals, these carbides were difficult to braze satisfactorily and consequently were little used until the advent of clamped, throwaway inserts. Moreover, the carbides were notoriously brittle and could take only fine cuts in minimal-shock conditions. Titanium-carbide-based grades again came into prominence about 1960, when nickelmolybdenum began to be used as a binder instead of nickel. The new grades were able to perform a wider range of tasks including interrupted cutting and cutting under shock conditions. The very high indentation hardness values recorded for titanium carbide grades are not accompanied by correspondingly greater resistance to abrasive wear, the apparently less hard tungsten carbide being considerably superior in this property. Moreover, carbonitrides, advanced tantalum-containing multicarbides, and coated variants generally provide better all-round cutting performances. Titanium-Base Carbonitrides: Development of titanium-carbonitride-based cuttingtool materials predates the use of coatings of this type on more conventional hardmetals by many years. Appreciable, though uncontrolled, amounts of carbonitride were often present, if only by accident, when cracked ammonia was used as a less expensive substitute for hydrogen in some stages of the production process in the 1950's and perhaps for two decades earlier. Much of the recent, more scientific development of this class of materials has taken place in the United States, particularly by Teledyne Firth Sterling with its SD3 grade and in Japan by several companies. Many of the compositions currently in use are extremely complex, and their structures—even with apparently similar compositions—can vary enormously. For instance, Mitsubishi characterizes its Himet NX series of cermets as TiC/WC/Ta(Nb)C/Mo2C/TiN/Ni/Co/Al, with a structure comprising both large and medium-size carbide particles (mainly TiC according to the quoted density) in a superalloy-type matrix containing an aluminum-bearing intermetallic compound. Steel- and Alloy-Bonded Titanium Carbide: The class of material exemplified by FerroTic, as it is known, consists primarily of titanium carbide bonded with heat-treatable steel, but some grades also contain tungsten carbide or are bonded with nickel- or copper-base alloys. These cemented carbides are characterized by high binder contents (typically 50– 60 per cent by volume) and lower hardnesses, compared with the more usual hardmetals, and by the great variation in properties obtained by heat treatment. In the annealed condition, steel-bonded carbides have a relatively soft matrix and can be machined with little difficulty, especially by CBN (superhard cubic boron nitride) tools. After heat treatment, the degree of hardness and wear resistance achieved is considerably greater than that of normal tool steels, although understandably much less than that of traditional sintered carbides. Microstructures are extremely varied, being composed of 40–50 per cent TiC by volume and a matrix appropriate to the alloy composition and the stage of heat treatment. Applications include stamping, blanking and drawing dies, machine components, and similar items where the ability to machine before hardening reduces production costs substantially. Coating: As a final stage in carbide manufacture, coatings of various kinds are applied mainly to cutting tools, where for cutting steel in particular it is advantageous to give the rank and clearance surfaces characteristics that are quite different from those of the body of the insert. Coatings of titanium carbide, nitride, or carbonitride; of aluminum oxide; and of other refractory compounds are applied to a variety of hardmetal substrates by chemical or physical vapor deposition (CVD or PVD) or by newer plasma methods.
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Machinery's Handbook 27th Edition CEMENTED CARBIDES AND OTHER HARD MATERIALS
777
The most recent types of coatings include hafnium, tantalum, and zirconium carbides and nitrides; alumina/titanium oxide; and multiple carbide/carbonitride/nitride/oxide, oxynitride or oxycarbonitride combinations. Greatly improved properties have been claimed for variants with as many as 13 distinct CVD coatings. A markedly sharper cutting edge compared with other CVD-coated hardmetals is claimed, permitting finer cuts and the successful machining of soft but abrasive alloys. The keenest edges on coated carbides are achieved by the techniques of physical vapor deposition. In this process, ions are deposited directionally from the electrodes, rather than evenly on all surfaces, so the sharpness of cutting edges is maintained and may even be enhanced. PVD coatings currently available include titanium nitride and carbonitride, their distinctive gold color having become familiar throughout the world on high-speed steel tooling. The high temperatures required for normal CVD tends to soften heat-treated high-speed steel. PVD-coated hardmetals have been produced commercially for several years, especially for precision milling inserts. Recent developments in extremely hard coatings, generally involving exotic techniques, include boron carbide, cubic boron nitride, and pure diamond. Almost the ultimate in wear resistance, the commercial applications of thin plasma-generated diamond surfaces at present are mainly in manufacture of semiconductors, where other special properties are important. For cutting tools the substrate is of equal importance to the coating in many respects, its critical properties including fracture toughness (resistance to crack propagation), elastic modulus, resistance to heat and abrasion, and expansion coefficient. Some manufacturers are now producing inserts with graded composition, so that structures and properties are optimized at both surface and interior, and coatings are less likely to crack or break away. Specifications: Compared with other standardized materials, the world of sintered hardmetals is peculiar. For instance, an engineer who seeks a carbide grade for the finishmachining of a steel component may be told to use ISO Standard Grade P10 or Industry Code C7. If the composition and nominal properties of the designated tool material are then requested, the surprising answer is that, in basic composition alone, the tungsten carbide content of P10 (or of the now superseded C7) can vary from zero to about 75, titanium carbide from 8 to 80, cobalt 0 to 10, and nickel 0 to 15 per cent. There are other possible constituents, also, in this so-called standard alloy, and many basic properties can vary as much as the composition. All that these dissimilar materials have in common, and all that the so-called standards mean, is that their suppliers—and sometimes their suppliers alone—consider them suitable for one particular and ill-defined machining application (which for P10 or C7 is the finish machining of steel). This peculiar situation arose because the production of cemented carbides in occupied Europe during World War II was controlled by the German Hartmetallzentrale, and no factory other than Krupp was permitted to produce more than one grade. By the end of the war, all German-controlled producers were equipped to make the G, S, H, and F series to German standards. In the postwar years, this series of carbides formed the basis of unofficial European standardization. With the advent of the newer multicarbides, the previous identities of grades were gradually lost. The applications relating to the old grades were retained, however, as a new German DIN standard, eventually being adopted, in somewhat modified form, by the International Standards Organization (ISO) and by ANSI in the United States. The American cemented carbides industry developed under diverse ownership and solid competition. The major companies actively and independently developed new varieties of hardmetals, and there was little or no standardization, although there were many attempts to compile equivalent charts as a substitute for true standardization. Around 1942, the Buick division of GMC produced a simple classification code that arranged nearly 100 grades derived from 10 manufacturers under only 14 symbols (TC-1 to TC-14). In spite of serious deficiencies, this system remained in use for many years as an American industry
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standard; that is, Buick TC-1 was equivalent to industry code C1. Buick itself went much further, using the tremendous influence, research facilities, and purchasing potential of its parent company to standardize the products of each carbide manufacturer by properties that could be tested, rather than by the indeterminate recommended applications. Many large-scale carbide users have developed similar systems in attempts to exert some degree of in-house standardization and quality control. Small and medium-sized users, however, still suffer from so-called industry standards, which only provide a starting point for grade selection. ISO standard 513, summarized in Table 2, divides all machining grades into three colorcoded groups: straight tungsten carbide grades (letter K, color red) for cutting gray cast iron, nonferrous metals, and nonmetallics; highly alloyed grades (letter, P. color blue) for machining steel; and less alloyed grades (letter M, color yellow, generally with less TiC than the corresponding P series), which are multipurpose and may be used on steels, nickel-base superalloys, ductile cast irons, and so on. Each grade within a group is also given a number to represent its position in a range from maximum hardness to maximum toughness (shock resistance). Typical applications are described for grades at more or less regular numerical intervals. Although coated grades scarcely existed when the ISO standard was prepared, it is easy to classify coated as uncoated carbides—or carbonitrides, ceramics, and superhard materials—according to this system. In this situation, it is easy to see how one plant will prefer one manufacturer's carbide and a second plant will prefer that of another. Each has found the carbide most nearly ideal for the particular conditions involved. In these circumstances it pays each manufacturer to make grades that differ in hardness, toughness, and crater resistance, so that they can provide a product that is near the optimum for a specific customer's application. Although not classified as a hard metal, new particle or powder metallurgical methods of manufacture, coupled with new coating technology have led in recent years to something of an upsurge in the use of high speed steel. Lower cost is a big factor, and the development of such coatings as titanium nitride, cubic boron nitride, and pure diamond, has enabled some high speed steel tools to rival tools made from tungsten and other carbides in their ability to maintain cutting accuracy and prolong tool life. Multiple layers may be used to produce optimum properties in the coating, with adhesive strength where there is contact with the substrate, combined with hardness at the cutting surface to resist abrasion. Total thickness of such coating, even with multiple layers, is seldom more than 15 microns (0.000060 in.). Importance of Correct Grades: A great diversity of hardmetal types is required to cope with all possible combinations of metals and alloys, machining operations, and working conditions. Tough, shock-resistant grades are needed for slow speeds and interrupted cutting, harder grades for high-speed finishing, heat-resisting alloyed grades for machining superalloys, and crater-resistant compositions, including most of the many coated varieties, for machining steels and ductile iron. Ceramics.—Moving up the hardness scale, ceramics provide increasing competition for cemented carbides, both in performance and in cost-effectiveness, though not yet in reliability. Hardmetals themselves consist of ceramics—nonmetallic refractory compounds, usually carbides or carbonitrides—with a metallic binder of much lower melting point. In such systems, densification generally takes place by liquid-phase sintering. Pure ceramics have no metallic binder, but may contain lower-melting-point compounds or ceramic mixtures that permit liquid-phase sintering to take place. Where this condition is not possible, hot pressing or hot isostatic pressing can often be used to make a strong, relatively porefree component or cutting insert. This section is restricted to those ceramics that compete directly with hardmetals, mainly in the cutting-tool category as shown in Table 3. Ceramics are hard, completely nonmetallic substances that resist heat and abrasive wear. Increasingly used as clamped indexable tool inserts, ceramics differ significantly from tool
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Machinery's Handbook 27th Edition
Table 2. ISO Classifications of Hardmetals (Cemented Carbides and Carbonitrides) by Application Main Types of Chip Removal Symbol and Color
Ferrous with long chips
Steel, steel castings
P10
Steel, steel casting
P20
Steel, steel castings, ductile cast iron with long chips Steel, steel castings, ductile cast iron with long chips Steel, steel castings with sand inclusions and cavities
P40
Ferrous metals with long or short chips, and non ferrous metals
Steel, steel castings of medium or low tensile strength, with sand inclusions and cavities
M10
Steel, steel castings, manganese steel, gray cast iron, alloy cast iron Steel, steel castings, austenitic or manganese steel, gray cast iron Steel, steel castings, austenitic steel, gray cast iron, high-temperature-resistant alloys Mild, free-cutting steel, low-tensile steel, nonferrous metals and light alloys Very hard gray cast iron, chilled castings over 85 Shore, high-silicon aluminum alloys, hardened steel, highly abrasive plastics, hard cardboard, ceramics Gray cast iron over 220 Brinell, malleable cast iron with short chips, hardened steel, siliconaluminum and copper alloys, plastics, glass, hard rubber, hard cardboard, porcelain, stone Gray cast iron up to 220 Brinell, nonferrous metals, copper, brass, aluminum Low-hardness gray cast iron, low-tensile steel, compressed wood Softwood or hard wood, nonferrous metals
M20
M40 Ferrous metals with short chips, non-ferrous metals and non-metallic materials
K01
K10
K20 K30 K40
Use and Working Conditions Finish turning and boring; high cutting speeds, small chip sections, accurate dimensions, fine finish, vibration-free operations Turning, copying, threading, milling; high cutting speeds; small or medium chip sections Turning, copying, milling; medium cutting speeds and chip sections, planing with small chip sections Turning, milling, planing; medium or large chip sections, unfavorable machining conditions Turning, planing, slotting; low cutting speeds, large chip sections, with possible large cutting angles, unfavorable cutting conditions, and work on automatic machines Operations demanding very tough carbides; turning, planing, slotting; low cutting speeds, large chip sections, with possible large cutting angles, unfavorable conditions and work on automatic machines Turning; medium or high cutting speeds, small or medium chip sections
of cut
of carbide ↑ speed ↑ wear
Turning, milling; medium cutting speeds and chip sections Turning, milling, planing; medium cutting speeds, medium or large chip sections Turning, parting off; particularly on automatic machines Turning, finish turning, boring, milling, scraping
Turning, milling, drilling, boring, broaching, scraping
Turning, milling, planing, boring, broaching, demanding very tough carbide Turning, milling, planing, slotting, unfavorable conditions, and possibility of large cutting angles Turning, milling, planing, slotting, unfavorable conditions, and possibility of large cutting angles
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↓ feed ↓ toughness
779
P50
M30
K Red
Specific Material to be Machined
P01
P30
M Yellow
Direction of Decrease in Characteristic
Groups of Applications Designation (Grade)
CEMENTED CARBIDES AND OTHER HARD MATERI-
P Blue
Broad Categories of Materials to be Machined
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steels, which are completely metallic. Ceramics also differ from cermets such as cemented carbides and carbonitrides, which comprise minute ceramic particles held together by metallic binders. Table 3. Typical Properties of Cutting Tool Ceramics Group Typical composition types Density (g/cm3) Transverse rupture strength (N/mm2) Compressive strength (kN/mm2) Hardness (HV)
Alumina
Alumina/TiC
Silicon Nitride
Al2O3 or Al2O3/ZrO2
70⁄30 Al2O3/TiC
Si3N4/Y2O3 plus
4.0 700 4.0
4.25 750 4.5
3.27
PCD
3.4
800 4.0
PCBN
3.1 800
4.7
3.8
1750
1800
1600 50
28
Young's modulus (kN/mm2)
380
370
300
925
680
Modulus of rigidity (kN/mm2) Poisson's ratio
150
160
150
430
280
Hardness HK
(kN/mm2)
Thermal expansion coefficient (10−6/K) Thermal conductivity (W/m K) Fracture toughness (K1cMN/m3⁄2)
0.24 8.5 23 2.3
0.22 7.8 17 3.3
0.20 3.2 22 5.0
0.09 3.8 120 7.9
0.22 4.9 100 10
Alumina-based ceramics were introduced as cutting inserts during World War II, and were for many years considered too brittle for regular machine-shop use. Improved machine tools and finer-grain, tougher compositions incorporating zirconia or silicon carbide “whiskers” now permit their use in a wide range of applications. Silicon nitride, often combined with alumina (aluminum oxide), yttria (yttrium oxide), and other oxides and nitrides, is used for much of the high-speed machining of superalloys, and newer grades have been formulated specifically for cast iron—potentially a far larger market. In addition to improvements in toolholders, great advances have been made in machine tools, many of which now feature the higher powers and speeds required for the efficient use of ceramic tooling. Brittleness at the cutting edge is no longer a disadvantage, with the improvements made to the ceramics themselves, mainly in toughness, but also in other critical properties. Although very large numbers of useful ceramic materials are now available, only a few combinations have been found to combine such properties as minimum porosity, hardness, wear resistance, chemical stability, and resistance to shock to the extent necessary for cutting-tool inserts. Most ceramics used for machining are still based on high-purity, finegrained alumina (aluminum oxide), but embody property-enhancing additions of other ceramics such as zirconia (zirconium oxide), titania (titanium oxide), titanium carbide, tungsten carbide, and titanium nitride. For commercial purposes, those more commonly used are often termed “white” (alumina with or without zirconia) or “black” (roughly 70⁄30 alumina/titanium carbide). More recent developments are the distinctively green alumina ceramics strengthened with silicon carbide whiskers and the brown-tinged silicon nitride types. Ceramics benefit from hot isostatic pressing, used to remove the last vestiges of porosity and raise substantially the material's shock resistance, even more than carbide-based hardmetals. Significant improvements are derived by even small parts such as tool inserts, although, in principle, they should not need such treatment if raw materials and manufacturing methods are properly controlled. Oxide Ceramics: Alumina cutting tips have extreme hardness—more than HV 2000 or HRA 94—and give excellent service in their limited but important range of uses such as the machining of chilled iron rolls and brake drums. A substantial family of alumina-based materials has been developed, and fine-grained alumina-based composites now have suf-
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Machinery's Handbook 27th Edition CEMENTED CARBIDES AND OTHER HARD MATERIALS
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ficient strength for milling cast iron at speeds up to 2500 ft/min (800 m/min). Resistance to cratering when machining steel is exceptional. Oxide/Carbide Ceramics: A second important class of alumina-based cutting ceramics combines aluminum oxide or alumina-zirconia with a refractory carbide or carbides, nearly always 30 per cent TiC. The compound is black and normally is hot pressed or hot isostatically pressed (HIPed). As shown in Table 3, the physical and mechanical properties of this material are generally similar to those of the pure alumina ceramics, but strength and shock resistance are generally higher, being comparable with those of higher-toughness simple alumina-zirconia grades. Current commercial grades are even more complex, combining alumina, zirconia, and titanium carbide with the further addition of titanium nitride. Silicon Nitride Base: One of the most effective ceramic cutting-tool materials developed in the UK is Syalon (from SiAlON or silicon-aluminum-oxynitride) though it incorporates a substantial amount of yttria for efficient liquid-phase sintering). The material combines high strength with hot hardness, shock resistance, and other vital properties. Syalon cutting inserts are made by Kennametal and Sandvik and sold as Kyon 2000 and CC680, respectively. The brown Kyon 200 is suitable for machining high-nickel alloys and cast iron, but a later development, Kyon 3000 has good potential for machining cast iron. Resistance to thermal stress and thermal shock of Kyon 2000 are comparable to those of sintered carbides. Toughness is substantially less than that of carbides, but roughly twice that of oxide-based cutting-tool materials at temperatures up to 850°C. Syon 200 can cut at high edge temperatures and is harder than carbide and some other ceramics at over 700°C, although softer than most at room temperature. Whisker-Reinforced Ceramics: To improve toughness, Greenleaf Corp. has reinforced alumina ceramics with silicon carbide single-crystal “whiskers” that impart a distinctive green color to the material, marketed as WG300. Typically as thin as human hairs, the immensely strong whiskers improve tool life under arduous conditions. Whisker-reinforced ceramics and perhaps hardmetals are likely to become increasingly important as cutting and wear-resistant materials. Their only drawback seems to be the carcinogenic nature of the included fibers, which requires stringent precautions during manufacture. Superhard Materials.—Polycrystalline synthetic diamond (PCD) and cubic boron nitride (PCBN), in the two columns at the right in Table 3, are almost the only cuttinginsert materials in the “superhard” category. Both PCD and PCBN are usually made with the highest practicable concentration of the hard constituent, although ceramic or metallic binders can be almost equally important in providing overall strength and optimizing other properties. Variations in grain size are another critical factor in determining cutting characteristics and edge stability. Some manufacturers treat CBN in similar fashion to tungsten carbide, varying the composition and amount of binder within exceptionally wide limits to influence the physical and mechanical properties of the sintered compact. In comparing these materials, users should note that some inserts comprise solid polycrystalline diamond or CBN and are double-sized to provide twice the number of cutting edges. Others consist of a layer, from 0.020 to 0.040 in. (0.5 to 1 mm) thick, on a tough carbide backing. A third type is produced with a solid superhard material almost surrounded by sintered carbide. A fourth type, used mainly for cutting inserts, comprises solid hard metal with a tiny superhard insert at one or more (usually only one) cutting corners or edges. Superhard cutting inserts are expensive—up to 30 times the cost of equivalent shapes or sizes in ceramic or cemented carbide—but their outstanding properties, exceptional performance and extremely long life can make them by far the most cost-effective for certain applications. Diamond: Diamond is the hardest material found or made. As harder, more abrasive ceramics and other materials came into widespread use, diamond began to be used for grinding-wheel grits. Cemented carbide tools virtually demanded diamond grinding wheels for fine edge finishing. Solid single-crystal diamond tools were and are used to a
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small extent for special purposes, such as microtomes, for machining of hard materials, and for exceptionally fine finishes. These diamonds are made from comparatively large, high-quality gem-type diamonds, have isotropic properties, and are very expensive. By comparison, diamond abrasive grits cost only a few dollars a carat. Synthetic diamonds are produced from graphite using high temperatures and extremely high pressures. The fine diamond particles produced are sintered together in the presence of a metal “catalyst” to produce high-efficiency anisotropic cutting tool inserts. These tools comprise either a solid diamond compact or a layer of sintered diamond on a carbide backing, and are made under conditions similar to, though less severe than, those used in diamond synthesis. Both natural and synthetic diamond can be sintered in this way, although the latter method is the most frequently used. Polycrystalline diamond (PCD) compacts are immensely hard and can be used to machine many substances, from highly abrasive hardwoods and glass fiber to nonferrous metals, hardmetals, and tough ceramics. Important classes of tools that are also available with cubic boron nitride inserts include brazed-tip drills, single-point turning tools, and face-milling cutters. Boron Nitride: Polycrystalline diamond has one big limitation: it cannot be used to machine steel or any other ferrous material without rapid chemical breakdown. Boron nitride does not have this limitation. Normally soft and slippery like graphite, the soft hexagonal crystals (HBN) become cubic boron nitride (CBN) when subjected to ultrahigh pressures and temperatures, with a structure similar to and hardness second only to diamond. As a solid insert of polycrystalline cubic boron nitride (PCBN), the compound machines even the hardest steel with relative immunity from chemical breakdown or cratering. Backed by sintered carbide, inserts of PCBN can readily be brazed, increasing the usefulness of the material and the range of tooling in which it can be used. With great hardness and abrasion resistance, coupled with extreme chemical stability when in contact with ferrous alloys at high temperatures, PCBN has the ability to machine both steels and cast irons at high speeds for long operating cycles. Only its currently high cost in relation to hardmetals prevents its wider use in mass-production machining. Similar in general properties to PCBN, the recently developed “Wurbon” consists of a mixture of ultrafine (0.02 µm grain size) hexagonal and cubic boron nitride with a “wurtzite” structure, and is produced from soft hexagonal boron nitride in a microsecond by an explosive shock-wave. Basic Machining Data: Most mass-production metalcutting operations are carried out with carbide-tipped tools but their correct application is not simple. Even apparently similar batches of the same material vary greatly in their machining characteristics and may require different tool settings to attain optimum performance. Depth of cut, feed, surface speed, cutting rate, desired surface finish, and target tool life often need to be modified to suit the requirements of a particular component. For the same downtime, the life of an insert between indexings can be less than that of an equivalent brazed tool between regrinds, so a much higher rate of metal removal is possible with the indexable or throwaway insert. It is commonplace for the claims for a new coating to include increases in surface-speed rates of 200–300 per cent, and for a new insert design to offer similar improvements. Many operations are run at metal removal rates that are far from optimum for tool life because the rates used maximize productivity and cost-effectiveness. Thus any recommendations for cutting speeds and feeds must be oversimplified or extremely complex, and must be hedged with many provisos, dependent on the technical and economic conditions in the manufacturing plant concerned. A preliminary grade selection should be made from the ISO-based tables and manufacturers' literature consulted for recommendations on the chosen grades and tool designs. If tool life is much
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greater than that desired under the suggested conditions, speeds, feeds, or depths of cut may be increased. If tools fail by edge breakage, a tougher (more shock-resistant) grade should be selected, with a numerically higher ISO code. Alternatively, increasing the surface speed and decreasing the feed may be tried. If tools fail prematurely from what appears to be abrasive wear, a harder grade with numerically lower ISO designation should be tried. If cratering is severe, use a grade with higher titanium carbide content; that is, switch from an ISO K to M or M to P grade, use a P grade with lower numerical value, change to a coated grade, or use a coated grade with a (claimed) more-resistant surface layer. Built-Up Edge and Cratering: The big problem in cutting steel with carbide tools is associated with the built-up edge and the familar phenomenon called cratering. Research has shown that the built-up edge is continuous with the chip itself during normal cutting. Additions of titanium, tantalum, and niobium to the basic carbide mixture have a remarkable effect on the nature and degree of cratering, which is related to adhesion between the tool and the chip. Hardmetal Tooling for Wood and Nonmetallics.—Carbide-tipped circular saws are now conventional for cutting wood, wood products such as chipboard, and plastics, and tipped bandsaws of large size are also gaining in popularity. Tipped handsaws and mechanical equivalents are seldom needed for wood, but they are extremely useful for cutting abrasive building boards, glass-reinforced plastics, and similar material. Like the hardmetal tips used on most other woodworking tools, saw tips generally make use of straight (unalloyed) tungsten carbide/cobalt grades. However, where excessive heat is generated as with the cutting of high-silica hardwoods and particularly abrasive chipboards, the very hard but tough tungsten-titanium-tantalum-niobium carbide solid-solution grades, normally reserved for steel finishing, may be preferred. Saw tips are usually brazed and reground a number of times during service, so coated grades appear to have little immediate potential in this field. Cutting Blades and Plane Irons: These tools comprise long, thin, comparatively wide slabs of carbide on a minimal-thickness steel backing. Compositions are straight tungsten carbide, preferably micrograin (to maintain a keen cutting edge with an included angle of 30° or less), but with relatively high amounts of cobalt, 11–13 per cent, for toughness. Considerable expertise is necessary to braze and grind these cutters without inducing or failing to relieve the excessive stresses that cause distortion or cracking. Other Woodworking Cutters: Routers and other cutters are generally similar to those used on metals and include many indexable-insert designs. The main difference with wood is that rotational and surface speeds can be the maximum available on the machine. Highspeed routing of aluminum and magnesium alloys was developed largely from machines and techniques originally designed for work on wood. Cutting Other Materials: The machining of plastics, fiber-reinforced plastics, graphite, asbestos, and other hard and abrasive constructional materials mainly requires abrasion resistance. Cutting pressures and power requirements are generally low. With thermoplastics and some other materials, particular attention must be given to cooling because of softening or degradation of the work material that might be caused by the heat generated in cutting. An important application of cemented carbides is the drilling and routing of printed circuit boards. Solid tungsten carbide drills of extremely small sizes are used for this work.
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Machinery's Handbook 27th Edition 784
FORMING TOOLS
FORMING TOOLS When curved surfaces or those of stepped, angular or irregular shape are required in connection with turning operations, especially on turret lathes and “automatics,” forming tools are used. These tools are so made that the contour of the cutting edge corresponds to the shape required and usually they may be ground repeatedly without changing the shape of the cutting edge. There are two general classes of forming tools—the straight type and the circular type. The circular forming tool is generally used on small narrow forms, whereas the straight type is more suitable for wide forming operations. Some straight forming tools are clamped in a horizontal position upon the cut-off slide, whereas the others are held in a vertical position in a special holder. A common form of holder for these vertical tools is one having a dovetail slot in which the forming tool is clamped; hence they are often called “dovetail forming tools.” In many cases, two forming tools are used, especially when a very smooth surface is required, one being employed for roughing and the other for finishing. There was an American standard for forming tool blanks which covered both straight or dovetailed, and circular forms. The formed part of the finished blanks must be shaped to suit whatever job the tool is to be used for. This former standard includes the important dimensions of holders for both straight and circular forms. Dimensions of Steps on Straight or Dovetail Forming Tools.—The diagrams at the top of the accompanying Table 1 illustrate a straight or “dovetail” forming tool. The upper or cutting face lies in the same plane as the center of the work and there is no rake. (Many forming tools have rake to increase the cutting efficiency, and this type will be referred to later.) In making a forming tool, the various steps measured perpendicular to the front face (as at d) must be proportioned so as to obtain the required radial dimensions on the work. For example, if D equals the difference between two radial dimensions on the work, then: Step d = D × cosine front clearance angle Angles on Straight Forming Tools.—In making forming tools to the required shape or contour, any angular surfaces (like the steps referred to in the previous paragraph) are affected by the clearance angle. For example, assume that angle A on the work (see diagram at top of accompanying table) is 20 degrees. The angle on the tool in plane x-x, in that case, will be slightly less than 20 degrees. In making the tool, this modified or reduced angle is required because of the convenience in machining and measuring the angle square to the front face of the tool or in the plane x–x. If the angle on the work is measured from a line parallel to the axis (as at A in diagram), then the reduced angle on the tool as measured square to the front face (or in plane x–x) is found as follows: tan reduced angle on tool = tan A × cos front clearance angle If angle A on the work is larger than, say, 45 degrees, it may be given on the drawing as indicated at B. In this case, the angle is measured from a plane perpendicular to the axis of the work. When the angle is so specified, the angle on the tool in plane x–x may be found as follows: tan B tan reduced angle on tool = ---------------------------------------------cos clearance angle Table Giving Step Dimensions and Angles on Straight or Dovetailed Forming Tools.—The accompanying table gives the required dimensions and angles within its range, direct or without calculation.
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Table 1. Dimensions of Steps and Angles on Straight Forming Tools
D
x A
d
C B
x
C Radial Depth of Step D
When C = 10°
Depth d of step on tool When C = 15°
When C = 20°
Radial Depth of Step D
When C = 10°
Depth d of step on tool When C = 15°
When C = 20°
0.001 0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010 0.020 0.030
0.00098 0.00197 0.00295 0.00393 0.00492 0.00590 0.00689 0.00787 0.00886 0.00984 0.01969 0.02954
0.00096 0.00193 0.00289 0.00386 0.00483 0.00579 0.00676 0.00772 0.00869 0.00965 0.01931 0.02897
0.00094 0.00187 0.00281 0.00375 0.00469 0.00563 0.00657 0.00751 0.00845 0.00939 0.01879 0.02819
0.040 0.050 0.060 0.070 0.080 0.090 0.100 0.200 0.300 0.400 0.500 …
0.03939 0.04924 0.05908 0.06893 0.07878 0.08863 0.09848 0.19696 0.29544 0.39392 0.49240 …
0.03863 0.04829 0.05795 0.06761 0.07727 0.08693 0.09659 0.19318 0.28977 0.38637 0.48296 …
0.03758 0.04698 0.05638 0.06577 0.07517 0.08457 0.09396 0.18793 0.28190 0.37587 0.46984 …
Upper section of table gives depth d of step on forming tool for a given dimension D that equals the actual depth of the step on the work, measured radially and along the cutting face of the tool (see diagram at left). First, locate depth D required on work; then find depth d on tool under tool clearance angle C. Depth d is measured perpendicular to front face of tool. Angle A in Plane of Tool Cutting Face 5° 10 15 20 25 30 35 40 45
Angle on tool in plane x–x When C = 10° 4° 9 14 19 24 29 34 39 44
55′ 51 47 43 40 37 35 34 34
When C = 15° 4° 9 14 19 24 29 34 39 44
50′ 40 31 22 15 9 4 1 0
When C = 20° 4° 9 14 18 23 28 33 38 43
42′ 24 8 53 40 29 20 15 13
Angle A in Plane of Tool Cutting Face 50° 55 60 65 70 75 80 85 …
Angle on tool in plane x–x When C = 10° 49° 54 59 64 69 74 79 84
34′ 35 37 40 43 47 51 55 …
When C = 15° 49° 54 59 64 69 74 79 84
1′ 4 8 14 21 30 39 49 …
When C = 20° 48° 53 58 63 68 74 79 84
14′ 18 26 36 50 5 22 41 …
Lower section of table gives angles as measured in plane x–x perpendicular to front face of forming tool (see diagram on right). Find in first column the angle A required on work; then find reduced angle in plane x–x under given clearance angle C.
To Find Dimensions of Steps: The upper section of Table 1 is used in determining the dimensions of steps. The radial depth of the step or the actual cutting depth D (see left-hand diagram) is given in the first column of the table. The columns that follow give the corresponding depths d for a front clearance angle of 10, 15, or 20 degrees. To illustrate the use of the table, suppose a tool is required for turning the part shown in Fig. 1, which has diameters of 0.75, 1.25, and 1.75 inches, respectively. The difference between the largest and the smallest radius is 0.5 inch, which is the depth of one step. Assume that the clearance angle is 15 degrees. First, locate 0.5 in the column headed “Radial Depth of Step D”; then find depth d in the column headed “when C = 15°.” As will be seen, this depth is 0.48296
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Machinery's Handbook 27th Edition 786
FORMING TOOLS
inch. Practically the same procedure is followed in determining the depth of the second step on the tool. The difference in the radii in this case equals0.25. This value is not given directly in the table, so first find the depth equivalent to 0.200 and add to it the depth equivalent to 0.050. Thus, we have 0.19318 + 0.04829 = 0.24147. In using Table 1, it is assumed that the top face of the tool is set at the height of the work axis. To Find Angle: The lower section of Table 1 applies to angles when they are measured relative to the axis of the work. The application of the table will again be illustrated by using the part shown in Fig. 1. The angle used here is 40 degrees (which is also the angle in the plane of the cutting face of the tool). If the clearance angle is 15 degrees, the angle measured in plane x–x square to the face of the tool is shown by the table to be 39° 1′- a reduction of practically 1 degree.
y R
13 4"
3 4"
11 4"
r F
x D
40˚ Fig. 1.
E Fig. 2.
If a straight forming tool has rake, the depth x of each step (see Fig. 2), measured perpendicular to the front or clearance face, is affected not only by the clearance angle, but by the rake angle F and the radii R and r of the steps on the work. First, it is necessary to find three angles, designated A, B, and C, that are not shown on the drawing. Angle A = 180° – rake angle F r sin A sin B = -------------R Angle C = 180° – ( A + B ) R sin C y = ---------------sin A Angle D of tool = 90° – ( E + F ) Depth x = y sin D If the work has two or more shoulders, the depth x for other steps on the tool may be determined for each radius r. If the work has curved or angular forms, it is more practical to use a tool without rake because its profile, in the plane of the cutting face, duplicates that of the work. Example:Assume that radius R equals 0.625 inch and radius r equals 0.375 inch, so that the step on the work has a radial depth of 0.25 inch. The tool has a rake angle F of 10 degrees and a clearance angle E of 15 degrees. Then angle A = 180 − 10 = 170 degrees.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition FORMING TOOLS
787
0.375 × 0.17365 sin B = --------------------------------------- = 0.10419 Angle B = 5°59′ nearly. 0.625 Angle C = 180 – ( 170° + 5°59′ ) = 4°1′ 0.625 × 0.07005 Dimension y = --------------------------------------- = 0.25212 0.17365 Angle D = 90° – ( 15 + 10 ) = 65 degrees Depth x of step = 0.25212 × 0.90631 = 0.2285 inch Circular Forming Tools.—To provide sufficient peripheral clearance on circular forming tools, the cutting face is offset with relation to the center of the tool a distance C, as shown in Fig. 3. Whenever a circular tool has two or more diameters, the difference in the radii of the steps on the tool will not correspond exactly to the difference in the steps on the work. The form produced with the tool also changes, although the change is very slight, unless the amount of offset C is considerable. Assume that a circular tool is required to produce the piece A having two diameters as shown. A
C
r
R
D1
D
Fig. 3.
If the difference D1 between the large and small radii of the tool were made equal to dimension D required on the work, D would be a certain amount oversize, depending upon the offset C of the cutting edge. The following formulas can be used to determine the radii of circular forming tools for turning parts to different diameters: Let R = largest radius of tool in inches; D = difference in radii of steps on work; C = amount cutting edge is offset from center of tool; r = required radius in inches; then 2
⎛ R 2 – C 2 – D⎞ + C 2 ⎝ ⎠ If the small radius r is given and the large radius R is required, then r =
(1)
2
⎛ r 2 – C 2 + D⎞ + C 2 (2) ⎝ ⎠ To illustrate, if D (Fig. 3) is to be 1⁄8 inch, the large radius R is 11⁄8 inches, and C is 5⁄32 inch, what radius r would be required to compensate for the offset C of the cutting edge? Inserting these values in Formula (1): R =
r =
2
2
2
2
( 1 1⁄8 ) – ( 5⁄32 ) – ( 1⁄8 ) + ( 5⁄32 ) = 1.0014 inches
The value of r is thus found to be 1.0014 inches; hence, the diameter = 2 × 1.0014 = 2.0028 inches instead of 2 inches, as it would have been if the cutting edge had been exactly on the center line. Formulas for circular tools used on different makes of screw machines can be simplified when the values R and C are constant for each size of machine. The accompanying Table 2, Formulas for Circular Forming Tools, gives the standard values of R and C for circular tools used on different automatics. The formulas for determining the
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 788
FORMING TOOLS Table 2. Formulas for Circular Forming Tools a
Make of Machine
Brown & Sharpe
Acme
Size of Machine
Radius R, Inches
Offset C, Inches
No. 00
0.875
0.125
r =
( 0.8660 – D ) 2 + 0.0156
No. 0
1.125
0.15625
r =
( 1.1141 – D ) + 0.0244
No. 2
1.50
0.250
r =
( 1.4790 – D ) + 0.0625
No. 6
2.00
0.3125
r =
( 1.975 – D ) + 0.0976
No. 51
0.75
0.09375
r =
( 1.7441 – D ) + 0.0088
No. 515
0.75
0.09375
r =
( 0.7441 – D ) + 0.0088
No. 52
1.0
0.09375
r =
( 0.9956 – D ) + 0.0088
No. 53
1.1875
0.125
r =
( 1.1809 – D ) + 0.0156
No. 54
1.250
0.15625
r =
( 1.2402 – D ) + 0.0244
No. 55
1.250
0.15625
r =
( 1.2402 – D ) + 0.0244
No. 56
1.50
0.1875
r =
( 1.4882 – D ) + 0.0352
1⁄ ″ 4
0.625
0.03125
r =
( 0.6242 – D ) + 0.0010
3⁄ ″ 8
0.084375
0.0625
r =
( 0.8414 – D ) + 0.0039
1.15625
0.0625
r =
( 1.1546 – D ) + 0.0039
1.1875
0.0625
r =
( 1.1859 – D ) + 0.0039
2″
1.375 1.375
0.0625 0.0625
r =
( 1.3736 – D ) + 0.0039
21⁄4″
1.625
0.125
r =
( 1.6202 – D ) + 0.0156
23⁄4″
1.875
0.15625
31⁄4″
1.875
0.15625
r =
( 1.8685 – D ) + 0.0244
41⁄4″
2.50
0.250
r =
( 2.4875 – D ) + 0.0625
2.625
0.250
r =
( 2.6131 – D ) + 0.0625
5⁄ ″ 8 7⁄ ″ 8
Cleveland
11⁄4″
6″
Radius r, Inches
2 2
2
2 2 2 2 2 2 2 2 2 2 2
2
2
2
2 2
a For notation, see Fig. 3
radius r (see column at right-hand side of table) contain a constant that represents the value 2
2
of the expression R – C in Formula (1). Table 3, Constant for Determining Diameters of Circular Forming Tools has been compiled to facilitate proportioning tools of this type and gives constants for computing the various diameters of forming tools, when the cutting face of the tool is 1⁄8, 3⁄16, 1⁄4, or 5⁄16 inch below the horizontal center line. As there is no standard distance for the location of the cutting face, the table has been prepared to correspond with distances commonly used. As an example, suppose the tool is required for a part having three diameters of 1.75, 0.75, and 1.25 inches, respectively, as shown in Fig. 1, and that the largest diameter of the tool is 3 inches and the cutting face is 1⁄4 inch below the horizontal center line. The first step would
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition FORMING TOOLS
789
be to determine approximately the respective diameters of the forming tool and then correct the diameters by the use of the table. To produce the three diameters shown in Fig. 1, with a 3-inch forming tool, the tool diameters would be approximately 2, 3, and 2.5 inches, respectively. The first dimension (2 inches) is 1 inch less in diameter than that of the tool, and the necessary correction should be given in the column “Correction for Difference in Diameter”; but as the table is only extended to half-inch differences, it will be necessary to obtain this particular correction in two steps. On the line for 3-inch diameter and under corrections for 1⁄2 inch, we find 0.0085; then in line with 21⁄2 and under the same heading, we find 0.0129, hence the total correction would be 0.0085 + 0.0129 = 0.0214 inch. This correction is added to the approximate diameter, making the exact diameter of the first step 2 + 0.0214 = 2.0214 inches. The next step would be computed in the same way, by noting on the 3-inch line the correction for 1⁄2 inch and adding it to the approximate diameter of the second step, giving an exact diameter of 2.5 + 0.0085 + 2.5085 inches. Therefore, to produce the part shown in Fig. 1, the tool should have three steps of 3, 2.0214, and 2.5085 inches, respectively, provided the cutting face is 1⁄4 inch below the center. All diameters are computed in this way, from the largest diameter of the tool. Tables 4a, 4b, and 4c, Corrected Diameters of Circular Forming Tools, are especially applicable to tools used on Brown & Sharpe automatic screw machines. Directions for using these tables are given on page 789. Circular Tools Having Top Rake.—Circular forming tools without top rake are satisfactory for brass, but tools for steel or other tough metals cut better when there is a rake angle of 10 or 12 degrees. For such tools, the small radius r (see Fig. 3) for an outside radius R may be found by the formula r =
2
2
P + R – 2PR cos θ
To find the value of P, proceed as follows: sin φ = small radius on work × sin rake angle ÷ large radius on work. Angle β = rake angle − φ. P = large radius on work × sin β ÷ sin rake angle. Angle θ = rake angle + δ. Sin δ = vertical height C from center of tool to center of work ÷ R. It is assumed that the tool point is to be set at the same height as the work center.
Using Tables for “Corrected Diameters of Circular Forming Tools”.—Tables 4a, 4b, and 4c are especially applicable to Brown & Sharpe automatic screw machines. The maximum diameter D of forming tools for these machines should be as follows: For No. 00 machine, 13⁄4 inches; for No. 0 machine, 21⁄4 inches; for No. 2 machine, 3 inches. To find the other diameters of the tool for any piece to be formed, proceed as follows: Subtract the smallest diameter of the work from the diameter of the work that is to be formed by the required tool diameter; divide the remainder by 2; locate the quotient obtained in the column headed “Length c on Tool,” and opposite the figure thus located and in the column headed by the number of the machine used, read off directly the diameter to which the tool is to be made. The quotient obtained, which is located in the column headed “Length c on Tool,” is the length c, as shown in Fig. 4. Example:A piece of work is to be formed on a No. 0 machine to two diameters, one being
1⁄ inch and one 0.550 inch; find the diameters of the tool. The maximum tool diameter is 21⁄ 4 4 inches, or the diameter that will cut the 1⁄4-inch diameter of the work. To find the other diameter, proceed according to the rule given: 0.550 − 1⁄4 = 0.300; 0.300 ÷ 2 = 0.150. In
Table 4b, opposite 0.150, we find that the required tool diameter is 1.9534 inches. These tables are for tools without rakes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Cutting Face 3⁄16 Inch Below Center
Cutting Face 1⁄4 Inch Below Center
Cutting Face 5⁄16 Inch Below Center
Correction for Difference in Diameter
Correction for Difference in Diameter
Correction for Difference in Diameter
Correction for Difference in Diameter
Radius of Tool
1⁄ Inch 8
1⁄ Inch 4
1⁄ Inch 2
1⁄ Inch 8
1⁄ Inch 4
1⁄ Inch 2
1⁄ Inch 8
1⁄ Inch 4
1⁄ Inch 2
1⁄ Inch 8
1⁄ Inch 4
1⁄ Inch 2
1
0.500
…
…
…
…
…
…
…
…
…
…
…
…
11⁄8
0.5625
0.0036
…
…
0.0086
…
…
0.0167
…
…
0.0298
…
…
11⁄4
0.625
0.0028
0.0065
…
0.0067
0.0154
…
0.0128
0.0296
…
0.0221
0.0519
…
13⁄8
0.6875
0.0023
…
…
0.0054
…
…
0.0102
…
…
0.0172
…
…
11⁄2
0.750
0.0019
0.0042
0.0107
0.0045
0.0099
0.0253
0.0083
0.0185
0.0481
0.0138
0.0310
0.0829
15⁄8
0.8125
0.0016
…
…
0.0037
…
…
0.0069
…
…
0.0114
…
…
13⁄4
0.875
0.0014
0.0030
…
0.0032
0.0069
…
0.0058
0.0128
…
0.0095
0.0210
…
17⁄8
0.9375
0.0012
…
…
0.0027
…
…
0.0050
…
…
0.0081
…
…
2
1.000
0.0010
0.0022
0.0052
0.0024
0.0051
0.0121
0.0044
0.0094
0.0223
0.0070
0.0152
0.0362
21⁄8
1.0625
0.0009
…
…
0.0021
…
…
0.0038
…
…
0.0061
…
…
21⁄4
1.125
0.0008
0.0017
…
0.0018
0.0040
…
0.0034
0.0072
…
0.0054
0.0116
…
23⁄8
1.1875
0.0007
…
…
0.0016
…
…
0.0029
…
…
0.0048
…
…
21⁄2
1.250
0.0006
0.0014
0.0031
0.0015
0.0031
0.0071
0.0027
0.0057
0.0129
0.0043
0.0092
0.0208
25⁄8
1.3125
0.0006
…
…
0.0013
…
…
0.0024
…
…
0.0038
…
…
23⁄4
1.375
0.0005
0.0011
…
0.0012
0.0026
…
0.0022
0.0046
…
0.0035
0.0073
…
27⁄8
1.4375
0.0005
…
…
0.0011
…
…
0.0020
…
…
0.0032
…
…
3
1.500
0.0004
0.0009
0.0021
0.0010
0.0021
0.0047
0.0018
0.0038
0.0085
0.0029
0.0061
0.0135
31⁄8
1.5625
0.00004
…
…
0.0009
…
…
0.0017
…
…
0.0027
…
…
31⁄4
1.625
0.0003
0.0008
…
0.0008
0.0018
…
0.0015
0.0032
…
0.0024
0.0051
…
33⁄8
1.6875
0.0003
…
…
0.0008
…
…
0.0014
…
…
0.0023
…
…
31⁄2
1.750
0.0003
0.0007
0.0015
0.0007
0.0015
0.0033
0.0013
0.0028
0.0060
0.0021
0.0044
0.0095
35⁄8
1.8125
0.0003
…
…
0.0007
…
…
0.0012
…
…
0.0019
…
…
33⁄4
1.875
0.0002
0.0006
…
0.0.0006
0.0013
…
0.0011
0.0024
…
0.0018
0.0038
…
Copyright 2004, Industrial Press, Inc., New York, NY
FORMING TOOLS
Dia. of Tool
790
Table 3. Constant for Determining Diameters of Circular Forming Tools Cutting Face 1⁄8 Inch Below Center
Machinery's Handbook 27th Edition FORMING TOOLS
791
Table 4a. Corrected Diameters of Circular Forming Tools Length c on Tool
Number of B. & S. Automatic Screw Machine No. 00 No. 0 No. 2
0.001 0.002 0.003 0.004 0.005 0.006
1.7480 1.7460 1.7441 1.7421 1.7401 1.7381
2.2480 2.2460 2.2441 2.2421 2.2401 2.2381
2.9980 2.9961 2.9941 2.9921 2.9901 2.9882
0.007 0.008 0.009 0.010 0.011 0.012 0.013 0.014 0.015 1⁄ 64 0.016 0.017 0.018 0.019 0.020 0.021 0.022
1.7362 1.7342 1.7322 1.7302 1.7282 1.7263 1.7243 1.7223 1.7203 1.7191
2.2361 2.2341 2.2321 2.2302 2.2282 2.2262 2.2243 2.2222 2.2203 2.2191
2.9862 2.9842 2.9823 2.9803 2.9783 2.9763 2.9744 2.9724 2.9704 2.9692
1.7184 1.7164 1.7144 1.7124 1.7104 1.7085 1.7065
2.2183 2.2163 2.2143 2.2123 2.2104 2.2084 2.2064
2.9685 2.9665 2.9645 2.9625 2.9606 2.9586 2.9566
0.023 0.024 0.025 0.026 0.027 0.028 0.029 0.030 0.031 1⁄ 32 0.032 0.033 0.034 0.035 0.036 0.037
1.7045 1.7025 1.7005 1.6986 1.6966 1.6946 1.6926 1.6907 1.6887 1.6882
2.2045 2.2025 2.2005 2.1985 2.1965 2.1945 2.1925 2.1906 2.1886 2.1881
2.9547 2.9527 2.9507 2.9488 2.9468 2.9448 2.9428 2.9409 2.9389 2.9384
1.6867 1.6847 1.6827 1.6808 1.6788 1.6768
2.1866 2.1847 2.1827 2.1807 2.1787 2.1767
2.9369 2.9350 2.9330 2.9310 2.9290 2.9271
0.038 0.039 0.040 0.041 0.042 0.043 0.044 0.045 0.046 3⁄ 64 0.047 0.048 0.049 0.050 0.051 0.052 0.053
1.6748 1.6729 1.6709 1.6689 1.6669 1.6649 1.6630 1.6610 1.6590 1.6573
2.1747 2.1727 2.1708 2.1688 2.1668 2.1649 2.1629 2.1609 2.1589 2.1572
2.9251 2.9231 2.9211 2.9192 2.9172 2.9152 2.9133 2.9113 2.9093 2.9076
1.6570 1.6550 1.6531 1.6511 1.6491 1.6471 1.6452
2.1569 2.1549 2.1529 2.1510 2.1490 2.1470 2.1451
2.9073 2.9054 2.9034 2.9014 2.8995 2.8975 2.8955
0.054 0.055 0.056
1.6432 1.6412 1.6392
2.1431 2.1411 2.1391
0.057
1.6373
2.1372
Length c on Tool 0.058 0.059 0.060 0.061 0.062 1⁄ 16 0.063 0.064 0.065 0.066 0.067 0.068 0.069 0.070 0.071 0.072
Number of B. & S. Automatic Screw Machine No. 00 No. 0 No. 2 1.6353 1.6333 1.6313 1.6294 1.6274 1.6264
2.1352 2.1332 2.1312 2.1293 2.1273 2.1263
2.8857 2.8837 2.8818 2.8798 2.8778 2.8768
1.6254 1.6234 1.6215 1.6195 1.6175 1.6155 1.6136 1.6116 1.6096 1.6076
2.1253 2.1233 2.1213 2.1194 2.1174 2.1154 2.1134 2.1115 2.1095 2.1075
2.8759 2.8739 2.8719 2.8699 2.8680 2.8660 2.8640 2.8621 2.8601 2.8581
1.6057 1.6037 1.6017 1.5997 1.5978 1.5958 1.5955
2.1055 2.1035 2.1016 2.0996 2.0976 2.0956 2.0954
2.8561 2.8542 2.8522 2.8503 2.8483 2.8463 2.8461
1.5938 1.5918 1.5899 1.5879 1.5859 1.5839 1.5820 1.5800 1.5780 1.5760
2.0937 2.0917 2.0897 2.0877 2.0857 2.0838 2.0818 2.0798 2.0778 2.0759
2.8443 2.8424 2.8404 2.8384 2.8365 2.8345 2.8325 2.8306 2.8286 2.8266
1.5740 1.5721 1.5701 1.5681 1.5661 1.5647
2.0739 2.0719 2.0699 2.0679 2.0660 2.0645
2.8247 2.8227 2.8207 2.8187 2.8168 2.8153
1.5642 1.5622 1.5602 1.5582 1.5563 1.5543 1.5523 1.5503 1.5484 1.5464
2.0640 2.0620 2.0600 2.0581 2.0561 2.0541 2.0521 2.0502 2.0482 2.0462
2.8148 2.8128 2.8109 2.8089 2.8069 2.8050 2.8030 2.8010 2.7991 2.7971
1.5444 1.5425 1.5405 1.5385 1.5365 1.5346 1.5338
2.0442 2.0422 2.0403 2.0383 2.0363 2.0343 2.0336
2.7951 2.7932 2.7912 2.7892 2.7873 2.7853 2.7846
2.8936 2.8916 2.8896
0.104 0.105 0.106 0.107 0.108 0.109 7⁄ 64 0.110 0.111 0.112
1.5326 1.5306 1.5287
2.0324 2.0304 2.0284
2.7833 2.7814 2.7794
2.8877
0.113
1.5267
2.0264
2.7774
0.073 0.074 0.075 0.076 0.077 0.078 5⁄ 64 0.079 0.080 0.081 0.082 0.083 0.084 0.085 0.086 0.087 0.088 0.089 0.090 0.091 0.092 0.093 3⁄ 32 0.094 0.095 0.096 0.097 0.098 0.099 0.100 0.101 0.102 0.103
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 792
FORMING TOOLS Table 4a. Corrected Diameters of Circular Forming Tools (Continued)
Length c on Tool 0.113 0.114
Number of B. & S. Automatic Screw Machine No. 00 No. 0 No. 2 1.5267 2.0264 2.7774 1.5247 2.0245 2.7755
0.115 0.116 0.117 0.118 0.119 0.120 0.121 0.122 0.123 0.124 0.125 0.126 0.127 0.128 0.129 0.130 0.131
1.5227 1.5208 1.5188 1.5168 1.5148 1.5129 1.5109 1.5089 1.5070 1.5050 1.5030 1.5010 1.4991 1.4971 1.4951 1.4932 1.4912
2.0225 2.0205 2.0185 2.0166 2.0146 2.0126 2.0106 2.0087 2.0067 2.0047 2.0027 2.0008 1.9988 1.9968 1.9948 1.9929 1.9909
2.7735 2.7715 2.7696 2.7676 2.7656 2.7637 2.7617 2.7597 2.7578 2.7558 2.7538 2.7519 2.7499 2.7479 2.7460 2.7440 2.7420
0.132 0.133 0.134 0.135 0.136 0.137 0.138 0.139 0.140 9⁄ 64 0.141 0.142 0.143 0.144 0.145 0.146 0.147
1.4892 1.4872 1.4853 1.4833 1.4813 1.4794 1.4774 1.4754 1.4734 1.4722
1.9889 1.9869 1.9850 1.9830 1.9810 1.9790 1.9771 1.9751 1.9731 1.9719
2.7401 2.7381 2.7361 2.7342 2.7322 2.7302 2.7282 2.7263 2.7243 2.7231
1.4715 1.4695 1.4675 1.4655 1.4636 1.4616 1.4596
1.9711 1.9692 1.9672 1.9652 1.9632 1.9613 1.9593
2.7224 2.7204 2.7184 2.7165 2.7145 2.7125 2.7106
0.148 0.149 0.150 0.151 0.152 0.153 0.154 0.155 0.156 5⁄ 32 0.157 0.158 0.159 0.160 0.161 0.162
1.4577 1.4557 1.4537 1.4517 1.4498 1.4478 1.4458 1.4439 1.4419 1.4414
1.9573 1.9553 1.9534 1.9514 1.9494 1.9474 1.9455 1.9435 1.9415 1.9410
2.7086 2.7066 2.7047 2.7027 2.7007 2.6988 2.6968 2.6948 2.6929 2.6924
1.4399 1.4380 1.4360 1.4340 1.4321 1.4301
1.9395 1.9376 1.9356 1.9336 1.9317 1.9297
2.6909 2.6889 2.6870 2.6850 2.6830 2.6811
0.163 0.164 0.165 0.166 0.167 0.168 0.169 0.170
1.4281 1.4262 1.4242 1.4222 1.4203 1.4183 1.4163 1.4144
1.9277 1.9257 1.9238 1.9218 1.9198 1.9178 1.9159 1.9139
2.6791 2.6772 2.6752 2.6732 2.6713 2.6693 2.6673 2.6654
Length c on Tool 0.171 11⁄ 64 0.172 0.173 0.174 0.175 0.176 0.177 0.178 0.179 0.180 0.181 0.182 0.183 0.184 0.185 0.186 0.187 3⁄ 16 0.188 0.189 0.190 0.191 0.192 0.193 0.194 0.195 0.196 0.197
Number of B. & S. Automatic Screw Machine No. 00 No. 0 No. 2 1.4124 1.9119 2.6634 1.4107 1.9103 2.6617 1.4104 1.4084 1.4065 1.4045 1.4025 1.4006 1.3986 1.3966 1.3947 1.3927 1.3907 1.3888 1.3868 1.3848 1.3829 1.3809 1.3799
1.9099 1.9080 1.9060 1.9040 1.9021 1.9001 1.8981 1.8961 1.8942 1.8922 1.8902 1.8882 1.8863 1.8843 1.8823 1.8804 1.8794
2.6614 2.6595 2.6575 2.6556 2.6536 2.6516 2.6497 2.6477 2.6457 2.6438 2.6418 2.6398 2.6379 2.6359 2.6339 2.6320 2.6310
1.3789 1.3770 1.3750 1.3730 1.3711 1.3691 1.3671 1.3652 1.3632 1.3612
1.8784 1.8764 1.8744 1.8725 1.8705 1.8685 1.8665 1.8646 1.8626 1.8606
2.6300 2.6281 2.6261 2.6241 2.6222 2.6202 2.6182 2.6163 2.6143 2.6123
0.198 0.199 0.200 0.201 0.202 0.203 13⁄ 64 0.204 0.205 0.206 0.207 0.208 0.209 0.210 0.211 0.212 0.213
1.3592 1.3573 1.3553 … … … …
1.8587 1.8567 1.8547 1.8527 1.8508 1.8488 1.8486
2.6104 2.6084 2.6064 2.6045 2.6025 2.6006 2.6003
… … … … … … … … … …
1.8468 1.8449 1.8429 1.8409 1.8390 1.8370 1.8350 1.8330 1.8311 1.8291
2.5986 2.5966 2.5947 2.5927 2.5908 2.5888 2.5868 2.5849 2.5829 2.5809
0.214 0.215 0.216 0.217 0.218 7⁄ 32 0.219 0.220 0.221 0.222 0.223 0.224 0.225 0.226
… … … … … …
1.8271 1.8252 1.8232 1.8212 1.8193 1.8178
2.5790 2.5770 2.5751 2.5731 2.5711 2.5697
… … … … … … … …
1.8173 1.8153 1.8133 1.8114 1.8094 1.8074 1.8055 1.8035
2.5692 2.5672 2.5653 2.5633 2.5613 2.5594 2.5574 2.5555
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition FORMING TOOLS
793
Table 4b. Corrected Diameters of Circular Forming Tools Number of B. & S. Screw Machine
Number of B. & S. Screw Machine
Length c on Tool
No. 0
No. 2
Length c on Tool
No. 0
No. 2
0.227 0.228 0.229 0.230
1.8015 1.7996 1.7976 1.7956
2.5535 2.5515 2.5496 2.5476
0.284 0.285 0.286 0.287
1.6894 1.6874 1.6854 1.6835
2.4418 2.4398 2.4378 2.4359
0.231 0.232 0.233 0.234 15⁄ 64 0.235 0.236 0.237 0.238 0.239
1.7936 1.7917 1.7897 1.7877 1.7870
2.5456 2.5437 2.5417 2.5398 2.5390
0.288 0.289 0.290 0.291 0.292
1.6815 1.6795 1.6776 1.6756 1.6736
1.7858 1.7838 1.7818 1.7799 1.7779
2.5378 2.5358 2.5339 2.5319 2.5300
0.240 0.241 0.242 0.243 0.244 0.245 0.246
1.7759 1.7739 1.7720 1.7700 1.7680 1.7661 1.7641
2.5280 2.5260 2.5241 2.5221 2.5201 2.5182 2.5162
0.293 0.294 0.295 0.296 19⁄ 64 0.297 0.298 0.299 0.300 0.301 0.302 0.303
0.247 0.248 0.249 0.250 0.251 0.252 0.253 0.254 0.255 0.256
1.7621 1.7602 1.7582 1.7562 1.7543 1.7523 1.7503 1.7484 1.7464 1.7444
2.5143 2.5123 2.5104 2.5084 2.5064 2.5045 2.5025 2.5005 2.4986 2.4966
0.257 0.258 0.259 0.260 0.261 0.262 0.263 0.264 0.265 17⁄ 64 0.266 0.267 0.268 0.269 0.270 0.271 0.272
1.7425 1.7405 1.7385 1.7366 1.7346 1.7326 1.7306 1.7287 1.7267 1.7255
2.4947 2.4927 2.4908 2.4888 2.4868 2.4849 2.4829 2.4810 2.4790 2.4778
1.7248 1.7228 1.7208 1.7189 1.7169 1.7149 1.7130
2.4770 2.4751 2.4731 2.4712 2.4692 2.4673 2.4653
0.273 0.274 0.275 0.276 0.277
1.7110 1.7090 1.7071 1.7051 1.7031
0.278 0.279 0.280 0.281 9⁄ 32 0.282 0.283
Length c on Tool
Number 2 B. & S. Machine
2.4340 2.4320 2.4300 2.4281 2.4261
0.341 0.342 0.343 11⁄ 32 0.344 0.345 0.346 0.347 0.348
2.3245 2.3225 2.3206 2.3186 2.3166
1.6717 1.6697 1.6677 1.6658 1.6641
2.4242 2.4222 2.4203 2.4183 2.4166
0.349 0.350 0.351 0.352 0.353
2.3147 2.3127 2.3108 2.3088 2.3069
1.6638 1.6618 1.6599 1.6579 … … …
2.4163 2.4144 2.4124 2.4105 2.4085 2.4066 2.4046
2.3049 2.3030 2.3010 2.2991 2.2971 2.2952 2.2945
0.304 0.305 0.306 0.307 0.308 0.309 0.310 0.311 0.312 5⁄ 16 0.313 0.314 0.315 0.316 0.317 0.318 0.319 0.320 0.321 0.322
… … … … … … … … … …
2.4026 2.4007 2.3987 2.3968 2.3948 2.3929 2.3909 2.3890 2.3870 2.3860
0.354 0.355 0.356 0.357 0.358 0.359 23⁄ 64 0.360 0.361 0.362 0.363 0.364 0.365 0.366 0.367 0.368 0.369
… … … … … … … … … …
2.3851 2.3831 2.3811 2.3792 2.3772 2.3753 2.3733 2.3714 2.3694 2.3675
0.370 0.371 0.372 0.373 0.374 0.375 0.376 0.377 0.378 0.379
2.2737 2.2718 2.2698 2.2679 2.2659 2.2640 2.2620 2.2601 2.2581 2.2562
… … … … … … …
2.3655 2.3636 2.3616 2.3596 2.3577 2.3557 2.3555
0.380 0.381 0.382 0.383 0.384 0.385 0.386
2.2542 2.2523 2.2503 2.2484 2.2464 2.2445 2.2425
2.4633 2.4614 2.4594 2.4575 2.4555
0.323 0.324 0.325 0.326 0.327 0.328 21⁄ 64 0.329 0.330 0.331 0.332 0.333
… … … … …
2.3538 2.3518 2.3499 2.3479 2.3460
2.2406 2.2386 2.2367 2.2347 2.2335
1.7012 1.6992 1.6972 1.6953 1.6948
2.4535 2.4516 2.4496 2.4477 2.4472
0.334 0.335 0.336 0.337 0.338
… … … … …
2.3440 2.3421 2.3401 2.3381 2.3362
0.387 0.388 0.389 0.390 25⁄ 64 0.391 0.392 0.393 0.394 0.395
1.6933
2.4457
0.339
0.396
2.2230
2.4438
0.340
… …
2.3342
1.6913
2.3323
0.397
2.2211
Copyright 2004, Industrial Press, Inc., New York, NY
2.3303 2.3284 2.3264 2.3250
2.2932 2.2913 2.2893 2.2874 2.2854 2.2835 2.2815 2.2796 2.2776 2.2757
2.2328 2.2308 2.2289 2.2269 2.2250
Machinery's Handbook 27th Edition 794
FORMING TOOLS Table 4c. Corrected Diameters of Circular Forming Tools
Length c on Tool
Number 2 B. & S. Machine
Length c on Tool
Number 2 B. & S. Machine
0.398 0.399 0.400 0.401 0.402 0.403
2.2191 2.2172 2.2152 2.2133 2.2113 2.2094
0.423 0.424 0.425 0.426 0.427 0.428
2.1704 2.1685 2.1666 2.1646 2.1627 2.1607
0.404 0.405 0.406 13⁄ 32 0.407 0.408 0.409 0.410 0.411 0.412
2.2074 2.2055 2.2035 2.2030
0.429 0.430 0.431 0.432
2.2016 2.1996 2.1977 2.1957 2.1938 2.1919
0.413 0.414 0.415 0.416 0.417 0.418 0.419 0.420 0.421 27⁄ 64 0.422
Length c on Tool
Number 2 B. & S. Machine
Length c on Tool
Number 2 B. & S. Machine
2.1199 2.1179 2.1160 2.1140 2.1121 2.1118
0.474 0.475 0.476 0.477 0.478 0.479
2.0713 2.0694 2.0674 2.0655 2.0636 2.0616
2.1588 2.1568 2.1549 2.1529
0.449 0.450 0.451 0.452 0.453 29⁄ 64 0.454 0.455 0.456 0.457
2.1101 2.1082 2.1063 2.1043
0.480 0.481 0.482 0.483
2.0597 2.0577 2.0558 2.0538
2.1510 2.1490 2.1471 2.1452 2.1432 2.1422
0.458 0.459 0.460 0.461 0.462 0.463
2.1024 2.1004 2.0985 2.0966 2.0946 2.0927
0.484 0.485 0.486 0.487 0.488 0.489
2.0519 2.0500 2.0480 2.0461 2.0441 2.0422
2.1899 2.1880 2.1860 2.1841 2.1821 2.1802
0.433 0.434 0.435 0.436 0.437 7⁄ 16 0.438 0.439 0.440 0.441 0.442 0.443
2.1413 2.1393 2.1374 2.1354 2.1335 2.1315
2.0907 2.0888 2.0868 2.0849 2.0830 2.0815
0.490 0.491 0.492 0.493 0.494 0.495
2.0403 2.0383 2.0364 2.0344 2.0325 2.0306
2.1782 2.1763 2.1743 2.1726
0.444 0.445 0.446 0.447
2.1296 2.1276 2.1257 2.1237
0.464 0.465 0.466 0.467 0.468 15⁄ 32 0.469 0.470 0.471 0.472
2.0810 2.0791 2.0771 2.0752
0.496 0.497 0.498 0.499
2.0286 2.0267 2.0247 2.0228
2.1724
0.448
2.1218
0.473
2.0733
0.500
2.0209
Dimensions of Forming Tools for B. & S. Automatic Screw Machines
W D T h
No. of Machine
Max. Dia., D
h
T
W
00
13⁄4
1⁄ 8
3⁄ –16 8
1⁄ 4
0
21⁄4
5⁄ 32
1⁄ –14 2
5⁄ 16
2
3
1⁄ 4
5⁄ –12 8
3⁄ 8
6
4
5⁄ 16
3⁄ –12 4
3⁄ 8
c Fig. 4.
Arrangement of Circular Tools.—When applying circular tools to automatic screw machines, their arrangement has an important bearing on the results obtained. The various ways of arranging the circular tools, with relation to the rotation of the spindle, are shown at A, B, C, and D in Fig. 5. These diagrams represent the view obtained when looking toward the chuck. The arrangement shown at A gives good results on long forming operations on brass and steel because the pressure of the cut on the front tool is downward; the support is more rigid than when the forming tool is turned upside down on the front slide, as shown at B; here the stock, turning up toward the tool, has a tendency to lift the crossslide, causing chattering; therefore, the arrangement shown at A is recommended when a high-quality finish is desired. The arrangement at B works satisfactorily for short steel pieces that do not require a high finish; it allows the chips to drop clear of the work, and is especially advantageous when making screws, when the forming and cut-off tools operate after the die, as no time is lost in reversing the spindle. The arrangement at C is recommended for heavy cutting on large work, when both tools are used for forming the piece; a
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition FORMING TOOLS
795
rigid support is then necessary for both tools and a good supply of oil is also required. The arrangement at D is objectionable and should be avoided; it is used only when a left-hand thread is cut on the piece and when the cut-off tool is used on the front slide, leaving the heavy cutting to be performed from the rear slide. In all “cross-forming” work, it is essential that the spindle bearings be kept in good condition, and that the collet or chuck has a parallel contact upon the bar that is being formed.
Front
Back Back
A
Front
B
Form
Cut-Off Cut-Off
Front
Form
Front
Back C
Form
Back D
Cut-Off
Form and Cut-Off
Form
Fig. 5.
Feeds and Speeds for Forming Tools.—Approximate feeds and speeds for forming tools are given in the table beginning on page 1132. The feeds and speeds are average values, and if the job at hand has any features out of the ordinary, the figures given should be altered accordingly. Dimensions for Circular Cut-Off Tools x a
T
1" 32
r r
D
1⁄ 16
T 0.031
x 0.013
Norway Iron, Machine Steel a = 15 Deg. T x 0.039 0.010
1⁄ 8
0.044
0.019
0.055
0.015
0.062
0.013
3⁄ 16
0.052
0.022
0.068
0.018
0.076
0.016
1⁄ 4
0.062
0.026
0.078
0.021
0.088
0.019
Dia. of Stock
R
Soft Brass, Copper a = 23 Deg.
Drill Rod, Tool Steel a = 12 Deg. T x 0.043 0.009
5⁄ 16
0.069
0.029
0.087
0.023
0.098
0.021
3⁄ 8
0.076
0.032
0.095
0.025
0.107
0.023
7⁄ 16
0.082
0.035
0.103
0.028
0.116
0.025
1⁄ 2
0.088
0.037
0.110
0.029
0.124
0.026
9⁄ 16
0.093
0.039
0.117
0.031
0.131
0.028
5⁄ 8
0.098
0.042
0.123
0.033
0.137
0.029
11⁄ 16
0.103
0.044
0.129
0.035
0.145
0.031
3⁄ 4
0.107
0.045
0.134
0.036
0.152
0.032
13⁄ 16
0.112
0.047
0.141
0.038
0.158
0.033
7⁄ 8
0.116
0.049
0.146
0.039
0.164
0.035
15⁄ 16
0.120
0.051
0.151
0.040
0.170
0.036
1
0.124
0.053
0.156
0.042
0.175
0.037
The length of the blade equals radius of stock R + x + r + 1⁄32 inch (for notation, see illustration above); r = 1⁄16 inch for 3⁄8- to 3⁄4-inch stock, and 3⁄32 inch for 3⁄4- to 1-inch stock.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 796
MILLING CUTTERS
MILLING CUTTERS Selection of Milling Cutters The most suitable type of milling cutter for a particular milling operation depends on such factors as the kind of cut to be made, the material to be cut, the number of parts to be machined, and the type of milling machine available. Solid cutters of small size will usually cost less, initially, than inserted blade types; for long-run production, inserted-blade cutters will probably have a lower overall cost. Depending on either the material to be cut or the amount of production involved, the use of carbide-tipped cutters in preference to high-speed steel or other cutting tool materials may be justified. Rake angles depend on both the cutter material and the work material. Carbide and cast alloy cutting tool materials generally have smaller rake angles than high-speed steel tool materials because of their lower edge strength and greater abrasion resistance. Soft work materials permit higher radial rake angles than hard materials; thin cutters permit zero or practically zero axial rake angles; and wide cutters operate smoother with high axial rake angles. See Rake Angles for Milling Cutters on page 826. Cutting edge relief or clearance angles are usually from 3 to 6 degrees for hard or tough materials, 4 to 7 degrees for average materials, and 6 to 12 degrees for easily machined materials. See Clearance Angles for Milling Cutter Teeth on page 825. The number of teeth in the milling cutter is also a factor that should be given consideration, as explained in the next paragraph. Number of Teeth in Milling Cutters.—In determining the number of teeth a milling cutter should have for optimum performance, there is no universal rule. There are, however, two factors that should be considered in making a choice: 1 ) T h e number of teeth should never be so great as to reduce the chip space between the teeth to a point where a free flow of chips is prevented; and 2) The chip space should be smooth and without sharp corners that would cause clogging of the chips in the space. For milling ductile materials that produce a continuous and curled chip, a cutter with large chip spaces is preferable. Such coarse tooth cutters permit an easier flow of the chips through the chip space than would be obtained with fine tooth cutters, and help to eliminate cutter “chatter.” For cutting operations in thin materials, fine tooth cutters reduce cutter and workpiece vibration and the tendency for the cutter teeth to “straddle” the workpiece and dig in. For slitting copper and other soft nonferrous materials, teeth that are either chamfered or alternately flat and V-shaped are best. As a general rule, to give satisfactory performance the number of teeth in milling cutters should be such that no more than two teeth at a time are engaged in the cut. Based on this rule, the following formulas are recommended: For face milling cutters, T = 6.3D -----------W
(1)
cos AT = 12.6D --------------------------D + 4d
(2)
For peripheral milling cutters,
where T = number of teeth in cutter; D = cutter diameter in inches; W = width of cut in inches; d = depth of cut in inches; and A = helix angle of cutter. To find the number of teeth that a cutter should have when other than two teeth in the cut at the same time is desired, Formulas (1) and (2) should be divided by 2 and the result multiplied by the number of teeth desired in the cut.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
797
Example:Determine the required number of teeth in a face mill where D = 6 inches and W = 4 inches. Using Formula (1), 6.3 × 6 T = ---------------- = 10 teeth, approximately 4 Example:Determine the required number of teeth in a plain milling cutter where D = 4 inches and d = 1⁄4 inch. Using Formula (2), 12.6 × 4 × cos 0 ° T = ---------------------------------------- = 10 teeth, approximately 4 + ( 4 × 1⁄4 ) In high speed milling with sintered carbide, high-speed steel, and cast non-ferrous cutting tool materials, a formula that permits full use of the power available at the cutter but prevents overloading of the motor driving the milling machine is: K×H T = ---------------------------------F×N×d×W
(3)
where T = number of cutter teeth; H = horsepower available at the cutter; F = feed per tooth in inches; N = revolutions per minute of cutter; d = depth of cut in inches; W = width of cut in inches; and K = a constant which may be taken as 0.65 for average steel, 1.5 for cast iron, and 2.5 for aluminum. These values are conservative and take into account dulling of the cutter in service. Example:Determine the required number of teeth in a sintered carbide tipped face mill for high speed milling of 200 Brinell hardness alloy steel if H = 10 horsepower; F = 0.008 inch; N = 272 rpm; d = 0.125 inch; W = 6 inches; and K for alloy steel is 0.65. Using Formula (3), 0.65 × 10 T = --------------------------------------------------------= 4 teeth, approximately 0.008 × 272 × 0.125 × 6 American National Standard Milling Cutters.—According to American National Standard ANSI/ASME B94.19-1997 milling cutters may be classified in two general ways, which are given as follows: By Type of Relief on Cutting Edges: Milling cutters may be described on the basis of one of two methods of providing relief for the cutting edges. Profile sharpened cutters are those on which relief is obtained and which are resharpened by grinding a narrow land back of the cutting edges. Profile sharpened cutters may produce flat, curved, or irregular surfaces. Form relieved cutters are those which are so relieved that by grinding only the faces of the teeth the original form is maintained throughout the life of the cutters. Form relieved cutters may produce flat, curved or irregular surfaces. By Method of Mounting: Milling cutters may be described by one of two methods used to mount the cutter. Arbor type cutters are those which have a hole for mounting on an arbor and usually have a keyway to receive a driving key. These are sometimes called Shell type. Shank type cutters are those which have a straight or tapered shank to fit the machine tool spindle or adapter. Explanation of the “Hand” of Milling Cutters.—In the ANSI Standard the terms “right hand” and “left hand” are used to describe hand of rotation, hand of cutter and hand of flute helix. Hand of Rotation or Hand of Cut: is described as either “right hand” if the cutter revolves counterclockwise as it cuts when viewed from a position in front of a horizontal milling machine and facing the spindle or “left hand” if the cutter revolves clockwise as it cuts when viewed from the same position.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 798
MILLING CUTTERS
American National Standard Plain Milling Cutters ANSI/ASME B94.19-1997 Cutter Diameter Nom.
Max.
Min.
Range of Face Widths, Nom.a
Hole Diameter Nom.
Max.
Min.
1
1.00075
1.0000
1
1.00075
1.0000
Light-duty Cuttersb 3⁄ , 1⁄ , 5⁄ , 3⁄ , 16 4 16 8
21⁄2
2.515
2.485
1⁄ , 5⁄ , 3⁄ , 2 8 4
1, 11⁄2 ,
2 and 3 3⁄ , 1⁄ , 5⁄ , 3⁄ , 16 4 16 8
3
3.015
2.985
3
3.015
2.985
1, 11⁄4 , 11⁄2 , 2
11⁄4
1.2510
1.2500
3.985
and 3 1⁄ , 5⁄ and 3⁄ 4 16 8
1
1.00075
1.0000 1.2500
5⁄ , 3⁄ , 8 4
and 11⁄2
1⁄ , 5⁄ , 3⁄ , 2 8 4
4
4.015
3⁄ , 1⁄ , 5⁄ , 3⁄ , 8 2 8 4
4
4.015
3.985
1, 11⁄2 , 2, 3
11⁄4
1.2510
1
1.00075
1.0000
1
1.0010
1.0000
21⁄2
2.515
2.485
and 4 Heavy-duty Cuttersc 2
21⁄2
2.515
2.485
4
3
3.015
2.985
2, 21⁄2 , 3, 4 and 6
11⁄4
1.2510
1.2500
4
4.015
3.985
2, 3, 4 and 6
11⁄2
1.5010
1.5000
11⁄4
1.2510
1.2500
11⁄2
1.5010
1.5000
3
3.015
2.985
High-helix Cuttersd 4 and 6
4
4.015
3.985
8
on Face Widths: Up to 1 inch, inclusive, ± 0.001 inch; over 1 to 2 inches, inclusive, +0.010, −0.000 inch; over 2 inches, +0.020, −0.000 inch. b Light-duty plain milling cutters with face widths under 3⁄ inch have straight teeth. Cutters with 3⁄ 4 4 inch face and wider have helix angles of not less than 15 degrees nor greater than 25 degrees. c Heavy-duty plain milling cutters have a helix angle of not less than 25 degrees nor greater than 45 degrees. d High-helix plain milling cutters have a helix angle of not less than 45 degrees nor greater than 52 degrees. a Tolerances
All dimensions are in inches. All cutters are high-speed steel. Plain milling cutters are of cylindrical shape, having teeth on the peripheral surface only.
Hand of Cutter: Some types of cutters require special consideration when referring to their hand. These are principally cutters with unsymmetrical forms, face type cutters, or cutters with threaded holes. Symmetrical cutters may be reversed on the arbor in the same axial position and rotated in the cutting direction without altering the contour produced on the work-piece, and may be considered as either right or left hand. Unsymmetrical cutters reverse the contour produced on the work-piece when reversed on the arbor in the same axial position and rotated in the cutting direction. A single-angle cutter is considered to be a right-hand cutter if it revolves counterclockwise, or a left-hand cutter if it revolves clockwise, when cutting as viewed from the side of the larger diameter. The hand of rotation of a single angle milling cutter need not necessarily be the same as its hand of cutter. A single corner rounding cutter is considered to be a right-hand cutter if it revolves counterclockwise, or a left-hand cutter if it revolves clockwise, when cutting as viewed from the side of the smaller diameter.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
799
American National Standard Side Milling Cutters ANSI/ASME B94.19-1997 Cutter Diameter Nom.
Max.
Min.
Range of Face Widths Nom.a
Hole Diameter Nom.
Max.
Min.
Side Cuttersb 2
2.015
1.985
3⁄ , 1⁄ , 3⁄ 16 4 8
5⁄ 8
0.62575
0.6250
21⁄2
2.515
2.485
1⁄ , 3⁄ , 1⁄ 4 8 2
7⁄ 8
0.87575
0.8750
3
3.015
2.985
1⁄ , 5⁄ , 3⁄ , 7⁄ , 1⁄ 4 16 8 16 2
1
1.00075
1.0000
4
4.015
3.985
1⁄ , 3⁄ , 1⁄ , 5⁄ , 3⁄ , 7⁄ 4 8 2 8 4 8
1
1.00075
1.0000
4
4.015
3.985
1⁄ , 5⁄ , 3⁄ 2 8 4
11⁄4
1.2510
1.2500
5
5.015
4.985
1⁄ , 5⁄ , 3⁄ 2 8 4
5
5.015
4.985
1⁄ , 5⁄ , 3⁄ , 2 8 4
6
6.015
5.985
6
6.015
5.985
7
7.015
6.985
7
7.015
6.985
8
8.015
7.985
3⁄ , 4
8.015
7.985
3⁄ , 4
8
1
1⁄ 2
1.00075
1.0000
11⁄4
1.2510
1.2500
1
1.00075
1.0000
11⁄4
1.2510
1.2500
3⁄ 4
11⁄4
1.2510
1.2500
3⁄ 4
11⁄2
1.5010
1.5000
1
11⁄4
1.2510
1.2500
1
11⁄2
1.5010
1.5000
0.87575
0.8750
1⁄ , 5⁄ , 3⁄ , 2 8 4
1
21⁄2
2.515
2.485
Staggered-tooth Side Cuttersc 1⁄ , 5⁄ , 3⁄ , 1⁄ 4 16 8 2
3
3.015
2.985
3⁄ , 1⁄ , 5⁄ , 3⁄ 16 4 16 8
3
3.015
2.985
1⁄ , 5⁄ , 3⁄ 2 8 4
4
4.015
3.985
5
5.015
4.985
6
6.015
5.985
3⁄ , 1⁄ , 5⁄ , 3⁄ , 7⁄ , 8 2 8 4 8
8
8.015
7.985
3⁄ , 1⁄ , 5⁄ , 3⁄ , 8 2 8 4
1⁄ , 5⁄ , 3⁄ , 7⁄ , 1⁄ , 4 16 8 16 2 5⁄ , 3⁄ 8 4
1
and 7⁄8
1⁄ , 5⁄ , 3⁄ 2 8 4
1
1
7⁄ 8
1
1.00075
1.0000
11⁄4
1.2510
1.2500
11⁄4
1.2510
1.2500
11⁄4
1.2510
1.2500
11⁄4
1.2510
1.2500
11⁄2
1.5010
1.5000
11⁄4
4
4.015
3.985
Half Side Cuttersd 3⁄ 4
1.2510
1.2500
5
5.015
4.985
3⁄ 4
11⁄4
1.2510
1.2500
6
6.015
5.985
3⁄ 4
11⁄4
1.2510
1.2500
a Tolerances on Face Widths: For side cutters, +0.002, −0.001 inch; for staggered-tooth side cutters
up to 3⁄4 inch face width, inclusive, +0.000 −0.0005 inch, and over 3⁄4 to 1 inch, inclusive, +0.000 − 0.0010 inch; and for half side cutters, +0.015, −0.000 inch. b Side milling cutters have straight peripheral teeth and side teeth on both sides. c Staggered-tooth side milling cutters have peripheral teeth of alternate right- and left-hand helix and alternate side teeth. d Half side milling cutters have side teeth on one side only. The peripheral teeth are helical of the same hand as the cut. Made either with right-hand or left-hand cut. All dimensions are in inches. All cutters are high-speed steel. Side milling cutters are of cylindrical shape, having teeth on the periphery and on one or both sides.
Hand of Flute Helix: Milling cutters may have straight flutes which means that their cutting edges are in planes parallel to the cutter axis. Milling cutters with flute helix in one direction only are described as having a right-hand helix if the flutes twist away from the observer in a clockwise direction when viewed from either end of the cutter or as having a left-hand helix if the flutes twist away from the observer in a counterclockwise direction when viewed from either end of the cutter. Staggered tooth cutters are milling cutters with every other flute of opposite (right and left hand) helix. An illustration describing the various milling cutter elements of both a profile cutter and a form-relieved cutter is given on page 801.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 800
MILLING CUTTERS American National Standard Staggered Teeth, T-Slot Milling Cutters with Brown & Sharpe Taper and Weldon Shanks ANSI/ASME B94.19-1997
Cutter Dia., D
Bolt Size 1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4
1
Face Width, W
9⁄ 16 21⁄ 32 25⁄ 32 31⁄ 32 11⁄4 115⁄32 127⁄32
Neck Dia., N
15⁄ 64 17⁄ 64 21⁄ 64 25⁄ 64 31⁄ 64 5⁄ 8 53⁄ 64
17⁄ 64 21⁄ 64 13⁄ 32 17⁄ 32 21⁄ 32 25⁄ 32 11⁄32
With B. & S. Tapera,b Length, Taper L No.
With Weldon Shank Length, Dia., L S
…
…
219⁄32
…
…
211⁄16
…
…
5 51⁄4
7
67⁄8
9
71⁄4
9
31⁄4 37⁄16 315⁄16 47⁄16 413⁄16
7
a For dimensions of Brown & Sharpe taper shanks, see information given on page
1⁄ 2 1⁄ 2 3⁄ 4 3⁄ 4
1 1 11⁄4
936.
b Brown & Sharpe taper shanks have been removed from ANSI/ASME B94.19 they are included for
reference only. All dimensions are in inches. All cutters are high-speed steel and only right-hand cutters are standard. Tolerances: On D, +0.000, −0.010 inch; on W, +0.000, −0.005 inch; on N, +0.000, −0.005 inch; on L, ± 1⁄16 inch; on S, −00001 to −0.0005 inch.
American National Standard Form Relieved Corner Rounding Cutters with Weldon Shanks ANSI/ASME B94.19-1997
Rad., R
Dia., D
Dia., d
S
L
1⁄ 16 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16 1⁄ 4 5⁄ 16
7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
1⁄ 4 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8
3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2
21⁄2
1 11⁄8
21⁄2 3 3 3 3 31⁄4
Rad., R 3⁄ 8 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2
Dia., D 11⁄4 7⁄ 8
1 11⁄8 11⁄4 13⁄8 11⁄2
Dia., d 3⁄ 8 5⁄ 16 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8
S
L
1⁄ 2 3⁄ 4 3⁄ 4 7⁄ 8 7⁄ 8
31⁄2
1
4 41⁄8
1
31⁄8 31⁄4 31⁄2 33⁄4
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters are standard. Tolerances: On D, ±0.010 inch; on diameter of circle, 2R, ±0.001 inch for cutters up to and including 1⁄8 -inch radius, +0.002, −0.001 inch for cutters over 1⁄8 -inch radius; on S, −0.0001 to −0.0005 inch; and on L, ± 1⁄16 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
801
American National Standard Metal Slitting Saws ANSI/ASME B94.19-1997 Cutter Diameter Nom.
Max.
21⁄2
2.515
3
3.015
4
4.015
5 5 6 6 8 8
5.015 5.015 6.015 6.015 8.015 8.015
21⁄2 3 4 5 5 6 6 8 8
2.515 3.015 4.015 5.015 5.015 6.015 6.015 8.015 8.015
3 4 5 6
3.015 4.015 5.015 6.015
6 8 10 12
6.015 8.015 10.015 12.015
Min.
Range of Face Widths Nom.a
Hole Diameter Nom.
Plain Metal Slitting Sawsb 1⁄ , 3⁄ , 1⁄ , 3⁄ , 1⁄ 7⁄ 2.485 32 64 16 32 8 8 1⁄ , 3⁄ , 1⁄ , 3⁄ , 32 64 16 32 2.985 1 1⁄ and 5⁄ 8 32 1⁄ , 3⁄ , 1⁄ , 3⁄ , 1⁄ , 32 64 16 32 8 3.985 1 5⁄ and 3⁄ 32 16 1⁄ , 3⁄ , 1⁄ 1 4.985 16 32 8 1⁄ 11⁄4 4.985 8 1 3 1 ⁄16 , ⁄32 , ⁄8 1 5.985 1⁄ , 3⁄ 11⁄4 5.985 8 16 1⁄ 1 7.985 8 1⁄ 11⁄4 7.985 8 Metal Slitting Saws with Side Teethc 1 3 1 7⁄ ⁄16 , ⁄32 , ⁄8 2.485 8 1⁄ , 3⁄ , 1⁄ , 5⁄ 2.985 1 16 32 8 32 1 3 1 5 3 ⁄16 , ⁄32 , ⁄8 , ⁄32 , ⁄16 1 3.985 1⁄ , 3⁄ , 1⁄ , 5⁄ , 3⁄ 4.985 1 16 32 8 32 16 1⁄ 1⁄ 1 4.985 8 4 1⁄ , 3⁄ , 1⁄ , 3⁄ 5.985 1 16 32 8 16 1⁄ , 3⁄ 1⁄ 1 5.985 8 16 4 1⁄ 1 7.985 8 1⁄ , 3⁄ 11⁄4 7.985 8 16 Metal Slitting Saws with Staggered Peripheral and Side Teethd 3⁄ 2.985 1 16 3⁄ 1 3.985 16 3⁄ , 1⁄ 4.985 1 16 4 3⁄ , 1⁄ 1 5.985 16 4 3⁄ , 1⁄ 11⁄4 5.985 16 4 3⁄ , 1⁄ 11⁄4 7.985 16 4 3⁄ , 1⁄ 11⁄4 9.985 16 4 1 5 ⁄4 , ⁄16 11⁄2 11.985
Max.
Min.
0.87575
0.8750
1.00075
1.0000
1.00075
1.0000
1.00075 1.2510 1.00075 1.2510 1.00075 1.2510
1.0000 1.2500 1.0000 1.2500 1.0000 1.2500
0.87575 1.00075 1.00075 1.00075 1.2510 1.00075 1.2510 1.00075 1.2510
0.8750 1.0000 1.0000 1.0000 1.2500 1.0000 1.2500 1.0000 1.2500
1.00075 1.00075 1.00075 1.00075
1.0000 1.0000 1.0000 1.0000
1.2510 1.2510 1.2510 1.5010
1.2500 1.2500 1.2500 1.5000
a Tolerances on face widths are plus or minus 0.001 inch. b Plain metal slitting saws are relatively thin plain milling cutters having peripheral teeth only. They are furnished with or without hub and their sides are concaved to the arbor hole or hub. c Metal slitting saws with side teeth are relatively thin side milling cutters having both peripheral and side teeth. d Metal slitting saws with staggered peripheral and side teeth are relatively thin staggered tooth milling cutters having peripheral teeth of alternate right- and left-hand helix and alternate side teeth.
All dimensions are in inches. All saws are high-speed steel. Metal slitting saws are similar to plain or side milling cutters but are relatively thin.
Milling Cutter Terms
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 802
MILLING CUTTERS Milling Cutter Terms (Continued)
American National Standard Single- and Double-Angle Milling Cutters ANSI/ASME B94.19-1997 Cutter Diameter Nom.
Max.
Hole Diameter Min.
Nominal Face Widtha
Nom.
Max.
Min.
Single-angle Cuttersb 3⁄ -24 8
UNF-2B RH
3⁄ -24 8
UNF-2B LH
c11⁄ 4
1.265
1.235
7⁄ 16
c15⁄ 8
1.640
1.610
9⁄ 16
23⁄4
2.765
2.735
1⁄ 2
1
1.00075
1.0000
3
3.015
2.985
1⁄ 2
11⁄4
1.2510
1.2500
23⁄4
2.765
2.735
1
1.00075
1.0000
1⁄ -20 2
UNF-2B RH
Double-angle Cuttersd 1⁄ 2
a Face width tolerances are plus or minus 0.015 inch. b Single-angle milling cutters have peripheral teeth, one cutting edge of which lies in a conical surface and the other in the plane perpendicular to the cutter axis. There are two types: one has a plain keywayed hole and has an included tooth angle of either 45 or 60 degrees plus or minus 10 minutes; the other has a threaded hole and has an included tooth angle of 60 degrees plus or minus 10 minutes. Cutters with a right-hand threaded hole have a right-hand hand of rotation and a right-hand hand of cutter. Cutters with a left-hand threaded hole have a left-hand hand of rotation and a left-hand hand of cutter. Cutters with plain keywayed holes are standard as either right-hand or left-hand cutters. c These cutters have threaded holes, the sizes of which are given under “Hole Diameter.” d Double-angle milling cutters have symmetrical peripheral teeth both sides of which lie in conical surfaces. They are designated by the included angle, which may be 45, 60 or 90 degrees. Tolerances are plus or minus 10 minutes for the half angle on each side of the center.
All dimensions are in inches. All cutters are high-speed steel.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
803
American National Standard Shell Mills ANSI/ASME B94.19-1997
Dia., D inches
Width, W inches
Dia., H inches
11⁄4
1
11⁄2
11⁄8
13⁄4
11⁄4
2
13⁄8
1⁄ 2 1⁄ 2 3⁄ 4 3⁄ 4
21⁄4
11⁄2
1
21⁄2
15⁄8
1
23⁄4
15⁄8
1
3
13⁄4
11⁄4
31⁄2
17⁄8 21⁄4 21⁄4 21⁄4 21⁄4
11⁄4 11⁄2 11⁄2 11⁄2
4 41⁄2 5 6
2
Length, B inches 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4
1 1 1 1
Width, C inches
Depth, E inches
Radius, F inches
Dia., J inches
1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 5⁄ 8 3⁄ 4
5⁄ 32 5⁄ 32 3⁄ 16 3⁄ 16 7⁄ 32 7⁄ 32 7⁄ 32 9⁄ 32 9⁄ 32 3⁄ 8 3⁄ 8 3⁄ 8 7⁄ 16
1⁄ 64 1⁄ 64 1⁄ 32 1⁄ 32 1⁄ 32 1⁄ 32 1⁄ 32 1⁄ 32 1⁄ 32 1⁄ 16 1⁄ 16 1⁄ 16 1⁄ 16
11⁄ 16 11⁄ 16 15⁄ 16 15⁄ 16 11⁄4 13⁄8 11⁄2 121⁄32 111⁄16 21⁄32 21⁄16 29⁄16 213⁄16
Dia., K degrees 5⁄ 8 5⁄ 8 7⁄ 8 7⁄ 8 13⁄16 13⁄16 13⁄16 11⁄2 11⁄2 17⁄8 17⁄8 17⁄8 21⁄2
Angle, L inches 0 0 0 0 0 0 5 5 5 5 10 10 15
All cutters are high-speed steel. Right-hand cutters with right-hand helix and square corners are standard. Tolerances: On D, +1⁄64 inch; on W, ±1⁄64 inch; on H, +0.0005 inch; on B, +1⁄64 inch; on C, at least +0.008 but not more than +0.012 inch; on E, +1⁄64 inch; on J, ±1⁄64 inch; on K, ±1⁄64 inch.
End Mill Terms
Enlarged Section of End Mill Tooth
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 804
MILLING CUTTERS End Mill Terms (Continued)
Enlarged Section of End Mill
American National Standard Multiple- and Two-Flute Single-End Helical End Mills with Plain Straight and Weldon Shanks ANSI/ASME B94.19-1997
Cutter Diameter, D Nom. 1⁄ 8 3⁄ 16 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4
Max. .130
Shank Diameter, S Min.
Max.
Min.
Multiple-flute with Plain Straight Shanks .125 .125 .1245
.1925
.1875
.1875
.1870
.255
.250
.250
.2495
.380
.375
.375
.3745
.505
.500
.500
.4995
.755
.750
.750
.7495
Length of Cut, W 5⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 15⁄ 16 1 1 ⁄4
Length Overall, L 11⁄4 13⁄8 111⁄16 113⁄16 21⁄4 25⁄8
Two-flute for Keyway Cutting with Weldon Shanks 1⁄ 8 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
.125
.1235
.375
.3745
.1875
.1860
.375
.3745
.250
.2485
.375
.3745
3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 9⁄ 16
25⁄16 25⁄16 25⁄16 25⁄16
.3125
.3110
.375
.3745
.375
.3735
.375
.3745
.500
.4985
.500
.4995
1
3
.625
.6235
.625
.6245
15⁄16
37⁄16
.750
.7485
.750
.7495
15⁄16
39⁄16
.875
.8735
.875
.8745
11⁄2
33⁄4
25⁄16
1
1.000
.9985
1.000
.9995
15⁄8
41⁄8
11⁄4
1.250
1.2485
1.250
1.2495
15⁄8
41⁄8
11⁄2
1.500
1.4985
1.250
1.2495
15⁄8
41⁄8
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters with right-hand helix are standard. The helix angle is not less than 10 degrees for multiple-flute cutters with plain straight shanks; the helix angle is optional with the manufacturer for two-flute cutters with Weldon shanks. Tolerances: On W, ±1⁄32 inch; on L, ±1⁄16 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
805
ANSI Regular-, Long-, and Extra Long-Length, Multiple-Flute Medium Helix Single-End End Mills with Weldon Shanks ANSI/ASME B94.19-1997
As Indicated By The Dimensions Given Below, Shank Diameter S May Be Larger, Smaller, Or The Same As The Cutter Diameter D Cutter Dia., D 1⁄ b 8 3⁄ b 16 1⁄ b 4 5⁄ b 16 3⁄ b 8 7⁄ 16 1⁄ 2 1⁄ b 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 5⁄ b 8 11⁄ 16 3⁄ b 4 13⁄ 16 7⁄ 8
1 7⁄ 8
1 11⁄8 11⁄4
Regular Mills S 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8
Long Mills
L
Na
25⁄16
4
…
23⁄8
4
…
27⁄16
4
21⁄2
4
21⁄2
4
1
211⁄16
4
1
211⁄16
11⁄4
31⁄4
13⁄8 13⁄8 15⁄8 15⁄8 15⁄8 15⁄8 15⁄8 17⁄8 17⁄8 17⁄8 17⁄8 17⁄8 2 2
W 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 3⁄ 4
S
W …
L …
…
…
Extra Long Mills Na
S
…
…
…
…
…
…
W
Na
L …
…
…
…
11⁄4
31⁄16
4
13⁄8
31⁄8
4
11⁄2
31⁄4
13⁄4
33⁄4
4
3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2
13⁄4
39⁄16
4
2
33⁄4
4
4
3⁄ 8 3⁄ 8 3⁄ 8
21⁄2
41⁄4
4
4
…
…
…
…
2
4
4
1⁄ 2
3
5
4
4
…
…
…
…
…
…
…
…
33⁄8 33⁄8 35⁄8 35⁄8 33⁄4 33⁄4 33⁄4
4
…
…
…
…
…
…
…
…
4
5⁄ 8
21⁄2
45⁄8
4
5⁄ 8
4
61⁄8
4
4
…
…
…
…
…
…
…
…
4
4
3⁄ 4
3
51⁄4
4
3⁄ 4
4
61⁄4
4
4
…
…
…
…
…
…
…
…
4
…
…
…
…
…
…
…
…
4
…
…
…
…
…
…
…
…
6
…
…
…
…
…
…
…
…
4
6
7⁄ 8
31⁄2
4
7⁄ 8
5
6
1
4
4
1
6
71⁄4 81⁄2
4
4
53⁄4 61⁄2
41⁄8
4
…
…
…
…
…
…
…
…
41⁄8
4
…
…
…
…
…
…
…
…
41⁄4
6
1
4
61⁄2
6
…
…
…
…
41⁄4
6
1
4
61⁄2
6
11⁄4
6
81⁄2
6
4
1
1
2
41⁄2
4
…
…
…
…
…
…
…
…
11⁄8
1
2
41⁄2
6
…
…
…
…
…
…
…
…
11⁄4
1
2
41⁄2
6
…
…
…
…
…
…
…
…
2
41⁄2 41⁄2 41⁄2 41⁄2 41⁄2 41⁄2
6
…
…
…
…
…
…
…
…
61⁄2 61⁄2 61⁄2 61⁄2 61⁄2
6
…
…
…
…
6
…
…
…
…
6
11⁄4
8
101⁄2
6
6
…
…
…
…
8
…
…
…
…
13⁄8 11⁄2 11⁄4 11⁄2 13⁄4
1
2
1
2
11⁄4
2
11⁄4
2
11⁄4
2
11⁄4
2
6
1
4
6
11⁄4
4
6
11⁄4
4
6
11⁄4
4
8
11⁄4
4
a N = Number of flutes. b In this size of regular mill a left-hand cutter with left-hand helix is also standard.
All dimensions are in inches. All cutters are high-speed steel. Helix angle is greater than 19 degrees but not more than 39 degrees. Right-hand cutters with right-hand helix are standard. Tolerances: On D, +0.003 inch; on S, −0.0001 to −0.0005 inch; on W, ±1⁄32 inch; on L, ±1⁄16 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 806
MILLING CUTTERS ANSI Two-Flute, High Helix, Regular-, Long-, and Extra Long-Length, Single-End End Mills with Weldon Shanks ANSI/ASME B94.19-1997
Regular Mill
Cutter Dia., D 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
S
W
3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
5⁄ 8 3⁄ 4 3⁄ 4
11⁄4 15⁄8 15⁄8 17⁄8
1
2
11⁄4
11⁄4
2
11⁄2
11⁄4 11⁄4
2 2
Extra Long Mill
S
W
L
S
W
27⁄16
3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 5⁄ 8 3⁄ 4
11⁄4
31⁄16
39⁄16
31⁄8 31⁄4 33⁄4
3⁄ 8 3⁄ 8 3⁄ 8
13⁄4
13⁄8 11⁄2 13⁄4
2 21⁄2
33⁄4 41⁄4
…
…
…
2
4
3
5
21⁄2
45⁄8
4
61⁄8
3
51⁄4
…
…
21⁄2 21⁄2 211⁄16 31⁄4 33⁄4 37⁄8 41⁄8 41⁄2 41⁄2 41⁄2 41⁄2
1
1
2
Long Mill L
1⁄ 2 5⁄ 8 3⁄ 4
4
61⁄4
…
… 81⁄2
1
4
… 61⁄2
1
6
11⁄4
4
61⁄2
11⁄4
6
81⁄2
4
61⁄2 61⁄2
11⁄4
8
101⁄2
…
…
11⁄4 11⁄4
4
…
L
…
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters with right-hand helix are standard. Helix angle is greater than 39 degrees. Tolerances: On D, +0.003 inch; on S, −0.0001 to −0.0005 inch; on W, ±1⁄32 inch; and on L, ±1⁄16 inch.
Combination Shanks for End Mills ANSI/ASME B94.19-1997 Right-hand Cut
Left-hand Cut
G K 1/2 K 90° H
E B
F C
12°
45° D
A J
Dia. A
45°
L
.015
Central With “K”
M
La
B
C
D
E
F
G
H
J
K
M
11⁄2
211⁄16
13⁄16
.515
1.406
11⁄2
.515
1.371
1.302
.377
2 21⁄2
31⁄4
123⁄32
.700
1.900
13⁄4
.700
1.809
1.772
.440
31⁄2
115⁄16
.700
2.400
2
.700
2.312
9⁄ 16 5⁄ 8 3⁄ 4
2.245
.503
7⁄ 16 1⁄ 2 9⁄ 16
a Length of shank.
All dimensions are in inches. Modified for use as Weldon or Pin Drive shank.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
807
ANSI Roughing, Single-End End Mills with Weldon Shanks, High-Speed Steel ANSI/ASME B94.19-1997
Diameter Cutter D
Length Shank S
1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4
1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4
1 1 11⁄4 11⁄4 11⁄2 11⁄2 13⁄4 13⁄4
1 1 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4
Cut W 1 11⁄4 2 11⁄4 15⁄8 21⁄2 11⁄2 15⁄8 3 2 4 2 4 2 4 2 4
Diameter Overall L 3 31⁄4 4 33⁄8 33⁄4 45⁄8 33⁄4 37⁄8 51⁄4 41⁄2 61⁄2 41⁄2 61⁄2 41⁄2 61⁄2 41⁄2 61⁄2
Length
Cutter D
Shank S
Cut W
Overall L
2 2 2 2 2 2 2 2 2 21⁄2 21⁄2 21⁄2 21⁄2 3 3 3 3
2 2 2 2 2 2 2 2 2 2 2 2 2 21⁄2 21⁄2 21⁄2 21⁄2
2 3 4 5 6 7 8 10 12 4 6 8 10 4 6 8 10
53⁄4 63⁄4 73⁄4 83⁄4 93⁄4 103⁄4 113⁄4 133⁄4 153⁄4 73⁄4 93⁄4 113⁄4 133⁄4 73⁄4 93⁄4 113⁄4 133⁄4
All dimensions are in inches. Right-hand cutters with right-hand helix are standard. Tolerances: Outside diameter, +0.025, −0.005 inch; length of cut, +1⁄8 , −1⁄32 inch.
American National Standard Heavy Duty, Medium Helix Single-End End Mills, 21⁄2 -inch Combination Shank, High-Speed Steel ANSI/ASME B94.19-1997
Dia. of Cutter, D 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 3 3
No. of Flutes 3 3 6 6 6 6 6 2 2
Length of Cut, W 8 10 4 6 8 10 12 4 6
Length Overall, L 12 14 8 10 12 14 16 73⁄4 93⁄4
Dia. of Cutter, D
No. of Flutes
3 3 3 3 3 3 3 3 …
3 3 3 8 8 8 8 8 …
Length of Cut, W 4 6 8 4 6 8 10 12 …
Length Overall, L 73⁄4 93⁄4 113⁄4 73⁄4 93⁄4 113⁄4 133⁄4 153⁄4 …
All dimensions are in inches. For shank dimensions see page 806. Right-hand cutters with righthand helix are standard. Helix angle is greater than 19 degrees but not more than 39 degrees. Tolerances: On D, +0.005 inch; on W, ±1⁄32 inch; on L, ±1⁄16 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 808
MILLING CUTTERS
ANSI Stub-, Regular-, and Long-Length, Four-Flute, Medium Helix, Plain-End, Double-End Miniature End Mills with 3⁄16 -Inch Diameter Straight Shanks ANSI/ASME B94.19-1997
Stub Length
Regular Length
Dia. D
W
L
W
L
1⁄ 16 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16
3⁄ 32 9⁄ 64 3⁄ 16 15⁄ 64 9⁄ 32
2 2 2 2 2
3⁄ 16 9⁄ 32 3⁄ 8 7⁄ 16 1⁄ 2
21⁄4 21⁄4 21⁄4 21⁄4 21⁄4
Dia. D
Long Length W
B
1⁄ 16 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16
3⁄ 8 1⁄ 2 3⁄ 4 7⁄ 8
L
7⁄ 32 9⁄ 32 3⁄ 4 7⁄ 8
1
21⁄2 25⁄8 31⁄8 31⁄4 33⁄8
1
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters with right-hand helix are standard. Helix angle is greater than 19 degrees but not more than 39 degrees. Tolerances: On D, + 0.003 inch (if the shank is the same diameter as the cutting portion, however, then the tolerance on the cutting diameter is − 0.0025 inch.); on W, + 1⁄32 , − 1⁄64 inch; and on L, ±1⁄16 inch.
American National Standard 60-Degree Single-Angle Milling Cutters with Weldon Shanks ANSI/ASME B94.19-1997
Dia., D
S
W
L
Dia., D
S
W
L
3⁄ 4 13⁄8
3⁄ 8 5⁄ 8
5⁄ 16 9⁄ 16
21⁄8
17⁄8
7⁄ 8
31⁄4
27⁄8
21⁄4
13⁄ 16 11⁄16
1
33⁄4
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters are standard. Tolerances: On D, ± 0.015 inch; on S, − 0.0001 to − 0.0005 inch; on W, ± 0.015 inch; and on L, ±1⁄16 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
809
American National Standard Stub-, Regular-, and Long-Length, Two-Flute, Medium Helix, Plain- and Ball-End, Double-End Miniature End Mills with 3⁄16 -Inch Diameter Straight Shanks ANSI/ASME B94.19-1997
Stub Length
Regular Length
Dia., C and D
W
L
W
L
W
L
W
L
1⁄ 32 3⁄ 64 1⁄ 16 5⁄ 64 3⁄ 32 7⁄ 64 1⁄ 8 9⁄ 64 5⁄ 32 11⁄ 64 3⁄ 16
3⁄ 64 1⁄ 16 3⁄ 32 1⁄ 8 9⁄ 64 5⁄ 32 3⁄ 16 7⁄ 32 15⁄ 64 1⁄ 4 9⁄ 32
2
…
…
21⁄4
…
…
2
…
…
21⁄4
…
…
2
3⁄ 32
2
21⁄4
3⁄ 16
2
…
…
…
9⁄ 64 …
…
9⁄ 32 …
21⁄4 …
2
3⁄ 16 …
…
21⁄4 21⁄4 21⁄4 21⁄4 21⁄4 21⁄4 21⁄4 21⁄4
21⁄4 …
2
3⁄ 32 9⁄ 64 3⁄ 16 15⁄ 64 9⁄ 32 21⁄ 64 3⁄ 8 13⁄ 32 7⁄ 16 1⁄ 2 1⁄ 2
3⁄ 8 …
21⁄4 …
7⁄ 16 …
21⁄4 …
1⁄ 2
21⁄4
Plain End
Ball End
2 2
Plain End
2 2
2
15⁄ 64
2
2
…
…
2
9⁄ 32
Long Length, Plain End
Dia., D
Ba
W
L
1⁄ 16 3⁄ 32 1⁄ 8
3⁄ 8 1⁄ 2 3⁄ 4
7⁄ 32 9⁄ 32 3⁄ 4
21⁄2 25⁄8 31⁄8
2 Dia., D 5⁄ 32 3⁄ 16
Ball End
Long Length, Plain End Ba
W
L
7⁄ 8
7⁄ 8
1
1
31⁄4 33⁄8
a B is the length below the shank.
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters with right-hand helix are standard. Helix angle is greater than 19 degrees but not more than 39 degrees. Tolerances: On C and D, − 0.0015 inch for stub and regular length; + 0.003 inch for long length (if the shank is the same diameter as the cutting portion, however, then the tolerance on the cutting diameter is − 0.0025 inch.); on W, + 1⁄32 , − 1⁄64 inch; and on L, ± 1⁄16 inch.
American National Standard Multiple Flute, Helical Series End Mills with Brown & Sharpe Taper Shanks
Dia., D
W
L
Taper No.
Dia., D
W
L
Taper No.
1⁄ 2 3⁄ 4
15⁄ 16 11⁄4 5 1 ⁄8
415⁄16 51⁄4 55⁄8
7 7 7
11⁄4 11⁄2 2
2
71⁄4 71⁄2 8
9 9 9
1
21⁄4 23⁄4
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters with right-hand helix are standard. Helix angle is not less than 10 degrees. No. 5 taper is standard without tang; Nos. 7 and 9 are standard with tang only. Tolerances: On D, +0.005 inch; on W, ±1⁄32 inch; and on L ±1⁄16 inch. For dimensions of B & S taper shanks, see information given on page 936.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 810
MILLING CUTTERS
American National Standard Stub- and Regular-Length, Two-Flute, Medium Helix, Plain- and Ball-End, Single-End End Mills with Weldon Shanks ANSI/ASME B94.19-1997
Regular Length — Plain End Dia., D 1⁄ 8 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8
1 7⁄ 8 1 11⁄8 11⁄4 1 11⁄8 11⁄4 13⁄8 11⁄2 11⁄4 11⁄2 13⁄4 2
S 3⁄ 8 3⁄8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 1 1 1 1 1 11⁄4 11⁄4 11⁄4 11⁄4
W 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 9⁄ 16 13⁄ 16 13⁄ 16
1 11⁄8 11⁄8 15⁄16 15⁄16 15⁄16 15⁄16 15⁄16 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 15⁄8 15⁄8 15⁄8 15⁄8 15⁄8 15⁄8 15⁄8 15⁄8 15⁄8 15⁄8 15⁄8
Stub Length — Plain End
L 25⁄16 25⁄16 25⁄16 25⁄16 25⁄16 21⁄2 21⁄2 3 31⁄8 31⁄8 35⁄16 35⁄16 37⁄16 37⁄16 37⁄16 35⁄8 35⁄8 35⁄8 33⁄4 33⁄4 37⁄8 37⁄8 41⁄8 41⁄8 41⁄8 41⁄8 41⁄8 41⁄8 41⁄8 41⁄8 41⁄8
Cutter Dia., D
Shank Dia., S
1⁄ 8 3⁄ 16 1⁄ 4
Length of Cut. W
3⁄ 8 3⁄ 8 3⁄ 8
3⁄ 16 9⁄ 32 3⁄ 8
Length Overall. L 21⁄8 23⁄16 21⁄4
Regular Length — Ball End
Dia., C and D 1⁄ 8 3⁄ 16 1⁄ 4
Shank Dia., S 3⁄ 8 3⁄ 8 3⁄ 8
Length of Cut. W 3⁄ 8 1⁄ 2 5⁄ 8
Length Overall. L 25⁄16 3 2 ⁄8 27⁄16
5⁄ 16 3⁄ 8 7⁄ 16
3⁄ 8 3⁄ 8 1⁄ 2
3⁄ 4 3⁄ 4
1
21⁄2 21⁄2 3
1⁄ 2 9⁄ 16 5⁄ 8
1⁄ 2 1⁄ 2 1⁄ 2
1 11⁄8 11⁄8
3 31⁄8 31⁄8
5⁄ 8 3⁄ 4 3⁄ 4
5⁄ 8 1⁄ 2 3⁄ 4
13⁄8 15⁄16 15⁄8
31⁄2 35⁄16 37⁄8
7⁄ 8 1 1 1 ⁄8
7⁄ 8
1 1
2 21⁄4 21⁄4
41⁄4 43⁄4 43⁄4
11⁄4 11⁄2
11⁄4 11⁄4
21⁄2 21⁄2
5 5
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters with right-hand helix are standard. Helix angle is greater than 19 degrees but not more than 39 degrees. Tolerances: On C and D, −0.0015 inch for stub-length mills, + 0.003 inch for regular-length mills; on S, −0.0001 to −0.0005 inch; on W, ± 1⁄32 inch; and on L, ± 1⁄16 inch. The following single-end end mills are available in premium high speed steel: ball end, two flute, with D ranging from 1⁄8 to 11⁄2 inches; ball end, multiple flute, with D ranging from 1⁄8 to 1 inch; and plain end, two flute, with D ranging from 1⁄8 to 11⁄2 inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
811
American National Standard Long-Length Single-End and Stub-, and Regular Length, Double-End, Plain- and Ball-End, Medium Helix, Two-Flute End Mills with Weldon Shanks ANSI/ASME B94.19-1997
Dia., C and D 1⁄ 8 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
1 11⁄4
Single End Long Length — Plain End S
Ba
W
… … 3⁄ 8 3⁄ 8 3⁄ 8 … 1⁄ 2 5⁄ 8 3⁄ 4 1 11⁄4
… … 11⁄2 13⁄4 13⁄4 … 27⁄32 223⁄32 311⁄32 431⁄32 431⁄32
… … 5⁄ 8 3⁄ 4 3⁄ 4 … 1 13⁄8 15⁄8 21⁄2 3
Long Length — Ball End
L
Ba
S 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 5⁄ 8 3⁄ 4
… … 31⁄16 35⁄16 35⁄16 … 4 45⁄8 53⁄8 71⁄4 71⁄4
W
13⁄ 16 11⁄8 1 1 ⁄2 13⁄4 13⁄4 17⁄8 21⁄4 23⁄4 33⁄8
1 …
3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 3⁄ 4
1 1 13⁄8 15⁄8 21⁄2 …
5 …
L 23⁄8 211⁄16 31⁄16 35⁄16 35⁄16 311⁄16 4 45⁄8 53⁄8 71⁄4 …
a B is the length below the shank.
Dia., C and D 1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 7⁄ 8
1
S
Stub Length — Plain End W
3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8
3⁄ 16 15⁄ 64 9⁄ 32 21⁄ 64 3⁄ 8
… … … … … … … … … … … … … …
… … … … … … … … … … … … … …
L 23⁄4 23⁄4 23⁄4 27⁄8 27⁄8 … … … … … … … … … … … … … …
Double End Regular Length — Plain End S W 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 7⁄ 8
1
3⁄ 8 7⁄ 16 7⁄ 16 1⁄ 2 1⁄ 2 9⁄ 16 9⁄ 16 9⁄ 16 9⁄ 16 13⁄ 16 13⁄ 16 13⁄ 16 13⁄ 16 11⁄8 11⁄8 15⁄16 15⁄16 19⁄16 15⁄8
L 31⁄16 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 33⁄4 33⁄4 33⁄4 33⁄4 41⁄2 41⁄2 5 5 51⁄2 57⁄8
S
Regular Length — Ball End W L
3⁄ 8 … 3⁄ 8 … 3⁄ 8 … 3⁄ 8 … 3⁄ 8 … 1⁄ 2 … 1⁄ 2 … 5⁄ 8 … 3⁄ 4 … 1
3⁄ 8 … 7⁄ 16 … 1⁄ 2 … 9⁄ 16 … 9⁄ 16 … 13⁄ 16 … 13⁄ 16 … 11⁄8 … 15⁄16 … 15⁄8
31⁄16 … 31⁄8 … 31⁄8 … 31⁄8 … 31⁄8 … 33⁄4 … 33⁄4 … 41⁄2 … 5 … 57⁄8
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters with right-hand helix are standard. Helix angle is greater than 19 degrees but not more than 39 degrees. Tolerances: On C and D, + 0.003 inch for single-end mills, −0.0015 inch for double-end mills; on S, −0.0001 to −0.0005 inch; on W, ±1⁄32 inch; and on L, ±1⁄16 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 812
MILLING CUTTERS American National Standard Regular-, Long-, and Extra Long-Length, Three-and Four-Flute, Medium Helix, Center Cutting, Single-End End Mills with Weldon Shanks ANSI/ASME B94.19-1997
Dia., D 1⁄ 8 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 5⁄ 8 11⁄ 16 3⁄ 4 7⁄ 8
1 11⁄8 11⁄4 11⁄2
Regular Length W
S 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 5⁄ 8 5⁄ 8 3⁄ 4 7⁄ 8
3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 3⁄ 4 11⁄4 15⁄8 15⁄8 15⁄8 17⁄8
1 1 11⁄4 11⁄4
25⁄16 23⁄8 27⁄16 21⁄2 21⁄2 31⁄4 33⁄4 33⁄4 37⁄8 41⁄8 41⁄2 41⁄2 41⁄2 41⁄2
2 2 2 2
Four Flute Long Length S W
L … …
… … 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 5⁄ 8
… 3⁄ 4 7⁄ 8 1 … 11⁄4 …
L
… …
S
Extra Long Length W L
… …
11⁄4 13⁄8 11⁄2
33⁄16 31⁄8 31⁄4
2 21⁄2 … 3 31⁄2 4 … 4 …
4 45⁄8 … 51⁄4 53⁄4 61⁄2 … 61⁄2 …
… … 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 5⁄ 8
… … 13⁄4 2 21⁄2 3 4 … 4 5 6 … 6 …
… 3⁄ 4 7⁄ 8 1 … 11⁄4 …
39⁄16 33⁄4 41⁄4 5 61⁄8 … 61⁄4 71⁄4 81⁄2 … 81⁄2 …
Three Flute Dia., D 1⁄ 8 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 1⁄ 2 9⁄ 16 9⁄ 16 5⁄ 8 3⁄ 4 5⁄ 8 3⁄ 4 7⁄ 8
1 3⁄ 4 7⁄ 8
1 1 1
S W Regular Length 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4 7⁄ 8
1
3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 3⁄ 4
1 1 11⁄4 13⁄8 13⁄8 13⁄8 15⁄8 15⁄8 15⁄8 17⁄8 17⁄8 15⁄8 17⁄8 17⁄8 17⁄8 2
L 25⁄16 23⁄8 27⁄16 21⁄2 21⁄2 211⁄16 211⁄16 31⁄4 33⁄8 33⁄8 33⁄8 35⁄8 33⁄4 33⁄4 4 4 37⁄8 41⁄8 41⁄8 41⁄8 41⁄2
Dia., D 11⁄8 11⁄4 11⁄2 11⁄4 11⁄2 13⁄4 2
S W Regular Length (cont.) 1 1 1 11⁄4 11⁄4 11⁄4 11⁄4
L
2 2 2 2 2 2 2
41⁄2 41⁄2 41⁄2 41⁄2 41⁄2 41⁄2 41⁄2
11⁄4 13⁄8 11⁄2 13⁄4 2 21⁄2 3 4 4 4 4 4
311⁄16 31⁄8 31⁄4 33⁄4 4 45⁄8 51⁄4 61⁄2 61⁄2 61⁄2 61⁄2 61⁄2
Long Length 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 5⁄ 8 3⁄ 4
1 11⁄4 11⁄2 13⁄4 2
1 11⁄4 11⁄4 11⁄4 11⁄4
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters with right-hand helix are standard. Helix angle is greater than 19 degrees but not more than 39 degrees. Tolerances: On D, +0.003 inch; on S, −0.0001 to −0.0005 inch; on W, ±1⁄32 inch; and on L, ±1⁄16 inch. The following center-cutting, single-end end mills are available in premium high speed steel: regular length, multiple flute, with D ranging from 1⁄8 to 11⁄2 inches; long length, multiple flute, with D ranging from 3⁄8 to 11⁄4 inches; and extra long-length, multiple flute, with D ranging from 3⁄8 to 11⁄4 inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
813
American National Standard Stub- and Regular-length, Four-flute, Medium Helix, Double-end End Mills with Weldon Shanks ANSI/ASME B94.19-1997
Dia., D
S
W
Dia., D
L
S
W
Dia., D
L
S
W
L
Stub Length 1⁄ 8
3⁄ 8
3⁄ 16
23⁄4
3⁄ 16
3⁄ 8
5⁄ 32
3⁄ 8
15⁄ 64
23⁄4
7⁄ 32
3⁄ 8
9⁄ 32 21⁄ 64
23⁄4
1⁄ 4
3⁄ 8
3⁄ 8
27⁄8
27⁄8
…
…
…
…
Regular Length 1⁄ a 8
3⁄ 8
3⁄ 8
31⁄16
11⁄ 32
3⁄ 8
3⁄ 4
31⁄2
5⁄ a 8
5⁄ 8
13⁄8
5
5⁄ a 32
3⁄ 8
7⁄ 16
31⁄8
3⁄ a 8
3⁄ 8
3⁄ 4
31⁄2
11⁄ 16
3⁄ 4
15⁄8
55⁄8
3⁄ a 16
3⁄ 8
1⁄ 2
31⁄4
13⁄ 32
1⁄ 2
1
41⁄8
3⁄ a 4
3⁄ 4
15⁄8
55⁄8
7⁄ 32
3⁄ 8
9⁄ 16
31⁄4
7⁄ 16
1⁄ 2
1
41⁄8
13⁄ 16
7⁄ 8
17⁄8
61⁄8
1⁄ a 4
3⁄ 8
5⁄ 8
33⁄8
15⁄ 32
1⁄ 2
1
41⁄8
7⁄ 8
7⁄ 8
17⁄8
61⁄8
9⁄ 32
3⁄ 8
11⁄ 16
33⁄8
1⁄ a 2
1⁄ 2
1
41⁄8
1
17⁄8
63⁄8
5⁄ a 16
3⁄ 8
3⁄ 4
31⁄2
9⁄ 16
5⁄ 8
13⁄8
5
…
…
…
1 …
a In this size of regular mill a left-hand cutter with a left-hand helix is also standard.
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters with right-hand helix are standard. Helix angle is greater than 19 degrees but not more than 39 degrees. Tolerances: On D, +0.003 inch (if the shank is the same diameter as the cutting portion, however, then the tolerance on the cutting diameter is −0.0025 inch); on S, −0.0001 to −0.0005 inch; on W, ±1⁄32 inch; and on L, ±1⁄16 inch.
American National Standard Stub- and Regular-Length, Four-Flute, Medium Helix, Double-End End Mills with Weldon Shanks ANSI/ASME B94.19-1997
Dia., D
S
W
L
Dia., D
S
Three Flute
W
L
Four Flute
1⁄ 8
3⁄ 8
3⁄ 8
31⁄16
1⁄ 8
3⁄ 8
3⁄ 8
31⁄16
3⁄ 16
3⁄ 8
1⁄ 2
31⁄4
3⁄ 16
3⁄ 8
1⁄ 2
31⁄4
1⁄ 4
3⁄ 8
5⁄ 8
33⁄8
1⁄ 4
3⁄ 8
5⁄ 8
33⁄8
5⁄ 16
3⁄ 8
3⁄ 4
31⁄2
5⁄ 16
3⁄ 8
3⁄ 4
31⁄2
3⁄ 8
3⁄ 8
3⁄ 4
31⁄2
3⁄ 8
3⁄ 8
3⁄ 4
7⁄ 16
1⁄ 2
1
41⁄8
1⁄ 2
1⁄ 2
1
41⁄8
1⁄ 2
1⁄ 2
1
41⁄8
5⁄ 8
5⁄ 8
13⁄8
5
9⁄ 16
5⁄ 8
13⁄8
5
3⁄ 4
3⁄ 4
15⁄8
55⁄8
5⁄ 8
5⁄ 8
13⁄8
5
7⁄ 8
7⁄ 8
17⁄8
61⁄8
3⁄ 4
3⁄ 4
15⁄8
55⁄8
1
1
17⁄8
63⁄8
1
1
17⁄8
63⁄8
…
…
…
…
31⁄2
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters with right-hand helix are standard. Helix angle is greater than 19 degrees but not more than 39 degrees. Tolerances: On D, +0.0015 inch; on S, −0.0001 to −0.0005 inch; on W, ±1⁄32 inch; and on L, ±1⁄16 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 814
MILLING CUTTERS
American National Standard Plain- and Ball-End, Heavy Duty, Medium Helix, Single-End End Mills with 2-Inch Diameter Shanks ANSI/ASME B94.19-1997
W
Plain End L
2
2
53⁄4
2
3
2
4
2
…
…
…
2
6
93⁄4
2, 3, 4, 6
8
6
8
4
113⁄4 73⁄4
2, 3, 4, 6
…
…
…
…
…
…
5
83⁄4
4
6
93⁄4 113⁄4
2, 4, 6
…
…
…
6
…
…
…
Dia., C and D
2 21⁄2 21⁄2 21⁄2 21⁄2
8
W
Ball End L
2, 4, 6
…
…
63⁄4
2, 3
…
…
73⁄4
2, 3, 4, 6
4
73⁄4
6
5
83⁄4
2, 4
6
93⁄4
6
113⁄4
6
No. of Flutes
No. of Flutes … …
All dimensions are in inches. All cutters are high-speed steel. Right-hand cutters with right-hand helix are standard. Helix angle is greater than 19 degrees but not more than 39 degrees. Tolerances: On C and D, + 0.005 inch for 2, 3, 4 and 6 flutes: on W, ± 1⁄16 inch; and on L, ± 1⁄16 inch.
Dimensions of American National Standard Weldon Shanks ANSI/ASME B94.19-1997 Shank Dia.
Flat Length
Shank
Xa
Lengthb
Dia.
Flat Length
Xa
Lengthb
3⁄ 8
19⁄16
0.325
0.280
1
29⁄32
0.925
0.515
1⁄ 2
125⁄32
0.440
0.330
11⁄4
29⁄32
1.156
0.515
5⁄ 8
129⁄32
0.560
0.400
11⁄2
211⁄16
1.406
0.515
3⁄ 4
21⁄32
0.675
0.455
2
31⁄4
1.900
0.700
7⁄ 8
21⁄32
0.810
0.455
21⁄2
31⁄2
2.400
0.700
a X is distance from bottom of flat to opposite side of shank. b Minimum.
All dimensions are in inches. Centerline of flat is at half-length of shank except for 11⁄2 -, 2- and 21⁄2 -inch shanks where it is 13⁄16 , 127⁄32 and 115⁄16 from shank end, respectively. Tolerance on shank diameter, − 0.0001 to − 0.0005 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
815
Amerian National Standard Form Relieved, Concave, Convex, and Corner-Rounding Arbor-Type Cutters ANSI/ASME B94.19-1997
Concave
Convex
Diameter C or Radius R Nom.
Max.
Min.
Cutter Dia. Da
Corner-rounding
Width W ± .010b
Diameter of Hole H Nom.
Max.
Min.
Concave Cuttersc 1⁄ 8
0.1270
0.1240
21⁄4
1⁄ 4
1
1.00075
1.00000
3⁄ 16
0.1895
0.1865
21⁄4
3⁄ 8
1
1.00075
1.00000
1⁄ 4
0.2520
0.2490
21⁄2
7⁄ 16
1
1.00075
1.00000
5⁄ 16
0.3145
0.3115
23⁄4
9⁄ 16
1
1.00075
1.00000
3⁄ 8
0.3770
0.3740
23⁄4
5⁄ 8
1
1.00075
1.00000
7⁄ 16
0.4395
0.4365
3
3⁄ 4
1
1.00075
1.00000
1⁄ 2
0.5040
0.4980
3
13⁄ 16
1
1.00075
1.00000
5⁄ 8
0.6290
0.6230
31⁄2
1
11⁄4
1.251
1.250
3⁄ 4
0.7540
0.7480
33⁄4
13⁄16
11⁄4
1.251
1.250
0.8730
4
13⁄8
11⁄4
1.251
1.250
0.9980
41⁄4
19⁄16
11⁄4
1.251
1.250
1.00000
7⁄ 8
1
0.8790 1.0040
Convex Cuttersc 1⁄ 8
0.1270
0.1230
21⁄4
1⁄ 8
1
1.00075
3⁄ 16
0.1895
0.1855
21⁄4
3⁄ 16
1
1.00075
1.00000
1⁄ 4
0.2520
0.2480
21⁄2
1⁄ 4
1
1.00075
1.00000
5⁄ 16
0.3145
0.3105
23⁄4
5⁄ 16
1
1.00075
1.00000
3⁄ 8
0.3770
0.3730
23⁄4
3⁄ 8
1
1.00075
1.00000
7⁄ 16
0.4395
0.4355
3
7⁄ 16
1
1.00075
1.00000
1⁄ 2
0.5020
0.4980
3
1⁄ 2
1
1.00075
1.00000
5⁄ 8
0.6270
0.6230
31⁄2
5⁄ 8
11⁄4
1.251
1.250
3⁄ 4
0.7520
0.7480
33⁄4
3⁄ 4
11⁄4
1.251
1.250
0.8730
4
7⁄ 8
11⁄4
1.251
1.250
0.9980
41⁄4
11⁄4
1.251
1.250
7⁄ 8
1
0.8770 1.0020
1
Corner-rounding Cuttersd 1⁄ 8
0.1260
0.1240
21⁄2
1
1.00075
1.00000
1⁄ 4
0.2520
0.2490
3
13⁄ 32
1
1.00075
1.00000
3⁄ 8
0.3770
0.3740
33⁄4
9⁄ 16
11⁄4
1.251
1.250
1⁄ 2
0.5020
0.4990
41⁄4
3⁄ 4
11⁄4
1.251
1.250
5⁄ 8
0.6270
0.6240
41⁄4
15⁄ 16
11⁄4
1.251
1.250
a Tolerances on cutter diameter are + 1⁄ , − 1⁄ 16 16 b Tolerance does not apply to convex cutters.
1⁄ 4
inch for all sizes.
c Size of cutter is designated by specifying diameter C of circular form. d Size of cutter is designated by specifying radius R of circular form.
All dimensions in inches. All cutters are high-speed steel and are form relieved. Right-hand corner rounding cutters are standard, but left-hand cutter for 1⁄4 -inch size is also standard. For key and keyway dimensions for these cutters, see page 819.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 816
MILLING CUTTERS
American National Standard Roughing and Finishing Gear Milling Cutters for Gears with 141⁄2 -Degree Pressure Angles ANSI/ASME B94.19-1997
ROUGHING Diametral Pitch
FINISHING
Dia. of Cutter, D
Dia. of Hole, H
81⁄2
2
3
51⁄4
11⁄2
73⁄4
2 13⁄4
3
43⁄4
11⁄4
4
43⁄4
13⁄4
4
Diametral Pitch
Dia. of Cutter, D
Dia. of Hole, H
Dia. of Cutter, D
Dia. of Hole, H
5
33⁄8
6
37⁄8
1 11⁄2
13⁄4
6
31⁄2
11⁄4
41⁄2
11⁄2
6
31⁄8 33⁄8
1 11⁄4
Diametral Pitch
Roughing Gear Milling Cutters 1 11⁄4 11⁄2 13⁄4
7 61⁄2
2
61⁄2
13⁄4
4
41⁄4
11⁄4
7
2 21⁄2
53⁄4
11⁄2
4
35⁄8
27⁄8
13⁄4
5
43⁄8
1 13⁄4
7
61⁄8
8
31⁄4
1 11⁄4
21⁄2
11⁄2 13⁄4
5
41⁄4 33⁄4
11⁄2 11⁄4
8
27⁄8
1
3
53⁄4 55⁄8
…
…
…
1 11⁄4
81⁄2 73⁄4
14
11⁄2 13⁄4
7 61⁄2
21⁄8 21⁄2 21⁄8 23⁄8
2 2 21⁄2 21⁄2 3
5
Finishing Gear Milling Cutters
3 3 4 4 4 4 5 5 5 5 6
2
6
2 13⁄4
6 6
13⁄4
7
61⁄2
13⁄4
7
53⁄4
11⁄2
7
61⁄8
13⁄4
8
53⁄4
11⁄2
8
55⁄8 51⁄4 43⁄4 43⁄4 41⁄2 41⁄4 35⁄8 43⁄8 41⁄4 33⁄4 33⁄8 41⁄4
13⁄4 11⁄2 11⁄4 13⁄4 11⁄2 11⁄4
8 9
37⁄8 31⁄2 31⁄8 35⁄8 33⁄8 27⁄8 31⁄2 31⁄4 27⁄8 31⁄8 23⁄4
11⁄2 11⁄4
16
1 11⁄2
18
16
11⁄4
18
1 11⁄2
20 20
11⁄4
22
1 11⁄4
24
1 11⁄4
24
13⁄4
26
13⁄4
22
7⁄ 8
1 7⁄ 8
1 7⁄ 8
2 23⁄8
1
2 21⁄4
1
2 21⁄4
1
7⁄ 8 7⁄ 8
11
25⁄8
1
32
13⁄4
11
23⁄8
13⁄4
12
40
13⁄4
1
48
13⁄4
1 13⁄4
12
27⁄8 25⁄8 21⁄4 21⁄2
7⁄ 8 11⁄4
36
11⁄2 11⁄4
7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8
…
…
…
…
…
…
1 13⁄4
9 10 10
3 23⁄4
10
23⁄8
12 14
28
13⁄4
7⁄ 8
30
13⁄4
1
7⁄ 8
1
All dimensions are in inches. All gear milling cutters are high-speed steel and are form relieved. For keyway dimensions see page 819. Tolerances: On outside diameter, + 1⁄16 , −1⁄16 inch; on hole diameter, through 1-inch hole diameter, +0.00075 inch, over 1-inch and through 2-inch hole diameter, +0.0010 inch. For cutter number relative to numbers of gear teeth, see page 2052. Roughing cutters are made with No. 1 cutter form only.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
817
American National Standard Gear Milling Cutters for Mitre and Bevel Gears with 141⁄2 -Degree Pressure Angles ANSI/ASME B94.19-1997 Diametral Pitch 3 4 5 6 7 8
Diameter of Cutter, D 4 35⁄8 33⁄8 31⁄8 27⁄8 27⁄8
Diameter of Hole, H 11⁄4 11⁄4 11⁄4 1 1 1
Diameter of Cutter, D
Diametral Pitch
23⁄8 21⁄4 21⁄8 21⁄8 2 13⁄4
10 12 14 16 20 24
Diameter of Hole, H 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8
All dimensions are in inches. All cutters are high-speed steel and are form relieved. For keyway dimensions see page 819. For cutter selection see page 2091. Tolerances: On outside diameter, +1⁄16 , −1⁄16 inch; on hole diameter, through 1-inch hole diameter, +0.00075 inch, for 11⁄4 -inch hole diameter, +0.0010 inch. To select the cutter number for bevel gears with the axis at any angle, double the back cone radius and multiply the result by the diametral pitch. This procedure gives the number of equivalent spur gear teeth and is the basis for selecting the cutter number from the table on page 2054.
American National Standard Roller Chain Sprocket Milling Cutters
American National Standard Roller Chain Sprocket Milling Cutters ANSI/ASME B94.19-1997 Chain Pitch
Dia. of Roll
No. of Teeth in Sprocket
1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8
0.130 0.130 0.130 0.130 0.130 0.130 0.200 0.200 0.200 0.200 0.200 0.200 0.313 0.313 0.313 0.313 0.313 0.313 0.400 0.400 0.400 0.400 0.400 0.400
6 7–8 9–11 12–17 18–34 35 and over 6 7–8 9–11 12–17 18–34 35 and over 6 7–8 9–11 12–17 18–34 35 and over 6 7–8 9–11 12–17 18–34 35 and over
Dia. of Cutter, D 23⁄4 23⁄4 23⁄4 23⁄4 23⁄4 23⁄4 23⁄4 23⁄4 23⁄4 23⁄4 23⁄4 23⁄4 3 3 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄4 31⁄4 31⁄4 31⁄4
Width of Cutter, W 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 9⁄ 32 9⁄ 32 15⁄ 32 15⁄ 32 15⁄ 32 7⁄ 16 7⁄ 16 13⁄ 32 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 23⁄ 32 11⁄ 16 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 23⁄ 32 11⁄ 16
Copyright 2004, Industrial Press, Inc., New York, NY
Dia. of Hole, H 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
Machinery's Handbook 27th Edition 818
MILLING CUTTERS American National Standard Roller Chain Sprocket Milling Cutters ANSI/ASME B94.19-1997(Continued) Chain Pitch 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 1 1 1 1 1 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 2 2 2 2 2 2 21⁄4 21⁄4 21⁄4 21⁄4 21⁄4 21⁄4 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 3 3 3 3 3 3
Dia. of Roll 0.469 0.469 0.469 0.469 0.469 0.469 0.625 0.625 0.625 0.625 0.625 0.750 0.750 0.750 0.750 0.750 0.875 0.875 0.875 0.875 0.875 0.875 1.000 1.000 1.000 1.000 1.000 1.000 1.125 1.125 1.125 1.125 1.125 1.125 1.406 1.406 1.406 1.406 1.406 1.406 1.563 1.563 1.563 1.563 1.563 1.563 1.875 1.875 1.875 1.875 1.875 1.875
No. of Teeth in Sprocket 6 7–8 9–11 12–17 18–34 35 and over 6 7–8 9–11 18–34 35 and over 6 7–8 9–11 18–34 35 and over 6 7–8 9–11 12–17 18–34 35 and over 6 7–8 9–11 12–17 18–34 35 and over 6 7–8 9–11 12–17 18–34 35 and over 6 7–8 9–11 12–17 18–34 35 and over 6 7–8 9–11 12–17 18–34 35 and over 6 7–8 9–11 12–17 18–34 35 and over
Dia. of Cutter, D 31⁄4 31⁄4 33⁄8 33⁄8 33⁄8 33⁄8 37⁄8 4 41⁄8 41⁄4 41⁄4 41⁄4 43⁄8 41⁄2 45⁄8 45⁄8 43⁄8 41⁄2 45⁄8 45⁄8 43⁄4 43⁄4 5 51⁄8 51⁄4 53⁄8 51⁄2 51⁄2 53⁄8 51⁄2 55⁄8 53⁄4 57⁄8 57⁄8 57⁄8 6 61⁄4 63⁄8 61⁄2 61⁄2 63⁄8 65⁄8 63⁄4 67⁄8 7 71⁄8 71⁄2 73⁄4 77⁄8 8 8 81⁄4
Width of Cutter, W 29⁄ 32 29⁄ 32 29⁄ 32 7⁄ 8 27⁄ 32 13⁄ 16 11⁄2 11⁄2 115⁄32 113⁄32 111⁄32 113⁄16 113⁄16 125⁄32 111⁄16 15⁄8 113⁄16 113⁄16 125⁄32 13⁄4 111⁄16 15⁄8 23⁄32 23⁄32 21⁄16 21⁄32 131⁄32 17⁄8 213⁄32 213⁄32 23⁄8 25⁄16 21⁄4 25⁄32 211⁄16 211⁄16 221⁄32 219⁄32 215⁄32 213⁄32 3 3 215⁄16 229⁄32 23⁄4 211⁄16 319⁄32 319⁄32 317⁄32 315⁄32 311⁄32 37⁄32
Dia. of Hole, H 1 1 1 1 1 1 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄4 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 2 2 2 2 2 2
All dimensions are in inches. All cutters are high-speed steel and are form relieved. For keyway dimensions see page 819. Tolerances: Outside diameter, +1⁄16 , −1⁄16 inch; hole diameter, through 1-inch diameter, + 0.00075 inch, above 1-inch diameter and through 2-inch diameter, + 0.0010 inch. For tooth form, see ANSI sprocket tooth form table on page 2458.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
American National Standard Keys and Keyways for Milling Cutters and Arbors ANSI/ASME B94.19-1997
Nom. Size Key (Square)
CUTTER HOLE AND KEYWAY
Arbor and Keyseat A Max.
A Min.
B Max.
ARBOR AND KEY
Hole and Keyway B Min.
C Max.
C Min.
Arbor and Key
Da Min.
H Nom.
Corner Radius
E Max.
E Min.
F Max.
F Min.
1⁄ 2
3⁄ 32
0.0947
0.0937
0.4531
0.4481
0.106
0.099
0.5578
3⁄ 64
0.020
0.0932
0.0927
0.5468
0.5408
5⁄ 8
1⁄ 8
0.1260
0.1250
0.5625
0.5575
0.137
0.130
0.6985
1⁄ 16
1⁄ 32
0.1245
0.1240
0.6875
0.6815
3⁄ 4
1⁄ 8
0.1260
0.1250
0.6875
0.6825
0.137
0.130
0.8225
1⁄ 16
1⁄ 32
0.1245
0.1240
0.8125
0.8065
7⁄ 8
1⁄ 8
0.1260
0.1250
0.8125
0.8075
0.137
0.130
0.9475
1⁄ 16
1⁄ 32
0.1245
0.1240
0.9375
0.9315
1⁄ 4
0.2510
0.2500
0.8438
0.8388
0.262
0.255
1.1040
3⁄ 32
3⁄ 64
0.2495
0.2490
1.0940
1.0880
11⁄4
5⁄ 16
0.3135
0.3125
1.0630
1.0580
0.343
0.318
1.3850
1⁄ 8
1⁄ 16
0.3120
0.3115
1.3750
1.3690
11⁄2
3⁄ 8
0.3760
0.3750
1.2810
1.2760
0.410
0.385
1.6660
5⁄ 32
1⁄ 16
0.3745
0.3740
1.6560
1.6500
13⁄4
7⁄ 16
0.4385
0.4375
1.5000
1.4950
0.473
0.448
1.9480
3⁄ 16
1⁄ 16
0.4370
0.4365
1.9380
1.9320
2
1⁄ 2
0.5010
0.5000
1.6870
1.6820
0.535
0.510
2.1980
3⁄ 16
1⁄ 16
0.4995
0.4990
2.1880
2.1820
21⁄2
5⁄ 8
0.6260
0.6250
2.0940
2.0890
0.660
0.635
2.7330
7⁄ 32
1⁄ 16
0.6245
0.6240
2.7180
2.7120
3
3⁄ 4
0.7510
0.7500
2.5000
2.4950
0.785
0.760
3.2650
1⁄ 4
3⁄ 32
0.7495
0.7490
3.2500
3.2440
31⁄2
7⁄ 8
0.8760
0.8750
3.0000
2.9950
0.910
0.885
3.8900
3⁄ 8
3⁄ 32
0.8745
0.8740
3.8750
3.8690
1
4
1
1.0010
1.0000
3.3750
3.3700
1.035
1.010
4.3900
3⁄ 8
3⁄ 32
0.9995
0.9990
4.3750
4.3690
41⁄2
11⁄8
1.1260
1.1250
3.8130
3.8080
1.160
1.135
4.9530
7⁄ 16
1⁄ 8
1.1245
1.1240
4.9380
4.9320
5
11⁄4
1.2510
1.2500
4.2500
4.2450
1.285
1.260
5.5150
1⁄ 2
1⁄ 8
1.2495
1.2490
5.5000
5.4940
819
a D max. is 0.010 inch larger than D min.
MILLING CUTTERS
ARBOR AND KEYSEAT Nom.Arbor and Cutter Hole Dia.
All dimensions given in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 820
MILLING CUTTERS
American National Standard Woodruff Keyseat Cutters—Shank-Type StraightTeeth and Arbor-Type Staggered-Teeth ANSI/ASME B94.19-1997
Shank-type Cutters
Cutter Number
Nom. Dia.of Cutter, D
Width of Face, W
Length Overall, Cutter L Number
Nom. Dia. of Cutter, D
Width of Face, W
Length Overall, Cutter L Number
Nom. Dia.of Cutter, D
Width of Face, W
Length Overall, L
202
1⁄ 4
1⁄ 16
21⁄16
506
3⁄ 4
5⁄ 32
25⁄32
809
1 1⁄8
1⁄ 4
2 1⁄4
202 1⁄2
5⁄ 16
1⁄ 16
21⁄16
606
3⁄ 4
3⁄ 16
23⁄16
1009
1 1⁄8
5⁄ 16
2 5⁄16
302 1⁄2
5⁄ 16
3⁄ 32
23⁄32
806
3⁄ 4
1⁄ 4
21⁄4
610
11⁄4
3⁄ 16
23⁄16
203
3⁄ 8
1⁄ 16
21⁄16
507
7⁄ 8
5⁄ 32
25⁄32
710
11⁄4
7⁄ 32
27⁄32
303
3⁄ 8
3⁄ 32
23⁄32
607
7⁄ 8
3⁄ 16
23⁄16
810
11⁄4
1⁄ 4
21⁄4
403
3⁄ 8
1⁄ 8
21⁄8
707
7⁄ 8
7⁄ 32
27⁄32
1010
11⁄4
5⁄ 16
25⁄16
204
1⁄ 2
1⁄ 16
21⁄16
807
7⁄ 8
1⁄ 4
21⁄4
1210
11⁄4
3⁄ 8
23⁄8
304
1⁄ 2
3⁄ 32
23⁄32
608
1
3⁄ 16
23⁄16
811
13⁄8
1⁄ 4
21⁄4
404
1⁄ 2
1⁄ 8
21⁄8
708
1
7⁄ 32
27⁄32
1011
13⁄8
5⁄ 16
25⁄16
305
5⁄ 8
3⁄ 32
23⁄32
808
1
1⁄ 4
21⁄4
1211
13⁄8
3⁄ 8
23⁄8
405
5⁄ 8
1⁄ 8
21⁄8
1008
1
5⁄ 16
25⁄16
812
11⁄2
1⁄ 4
21⁄4
505
5⁄ 8
5⁄ 32
25⁄32
1208
1
3⁄ 8
23⁄8
1012
11⁄2
5⁄ 16
25⁄16
605
5⁄ 8
3⁄ 16
23⁄16
609
11⁄8
3⁄ 16
23⁄16
1212
11⁄2
3⁄ 8
23⁄8
406
3⁄ 4
1⁄ 8
21⁄8
709
11⁄8
7⁄ 32
27⁄32
…
…
…
…
Width of Face, W
Dia. of Hole, H 1
Arbor-type Cutters
Cutter Number
Nom. Dia.of Cutter, D
Width of Face, W
617
21⁄8
3⁄ 16
3⁄ 4
1022
23⁄4
5⁄ 16
1
1628
31⁄2
1⁄ 2
817
21⁄8
1⁄ 4
3⁄ 4
1222
23⁄4
3⁄ 8
1
1828
31⁄2
9⁄ 16
1
1017
21⁄8
5⁄ 16
3⁄ 4
1422
23⁄4
7⁄ 16
1
2028
31⁄2
5⁄ 8
1
1217
21⁄8
3⁄ 8
3⁄ 4
1622
23⁄4
1⁄ 2
1
2428
31⁄2
3⁄ 4
1
822
23⁄4
1⁄ 4
1228
31⁄2
3⁄ 8
1
…
…
…
…
Dia. of Hole, Cutter H Number
1
Nom. Dia.of Cutter, D
Width of Face, W
Dia. of Hole, Cutter H Number
Nom. Dia.of Cutter, D
All dimensions are given in inches. All cutters are high-speed steel. Shank type cutters are standard with right-hand cut and straight teeth. All sizes have 1⁄2 -inch diameter straight shank. Arbor type cutters have staggered teeth. For Woodruff key and key-slot dimensions, see pages 2369 through 2371. Tolerances: Face with W for shank type cutters: 1⁄16 - to 5⁄32 -inch face, + 0.0000, −0.0005; 3⁄16 to 7⁄32 , − 0.0002, − 0.0007; 1⁄4 , −0.0003, −0.0008; 5⁄16 , −0.0004, −0.0009; 3⁄8 , − 0.0005, −0.0010 inch. Face width W for arbor type cutters; 3⁄16 inch face, −0.0002, −0.0007; 1⁄4 , −0.0003, −0.0008; 5⁄16 , −0.0004, −0.0009; 3⁄8 and over, −0.0005, −0.0010 inch. Hole size H: +0.00075, −0.0000 inch. Diameter D for shank type cutters: 1⁄4 - through 3⁄4 -inch diameter, +0.010, +0.015, 7⁄8 through 11⁄8 , +0.012, +0.017; 11⁄4
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
821
through 11⁄2 , +0.015, +0.020 inch. These tolerances include an allowance for sharpening. For arbor type cutters diameter D is furnished 1⁄32 inch larger than listed and a tolerance of ±0.002 inch applies to the oversize diameter.
Setting Angles for Milling Straight Teeth of Uniform Land Width in End Mills, Angular Cutters, and Taper Reamers.—The accompanying tables give setting angles for the dividing head when straight teeth, having a land of uniform width throughout their length, are to be milled using single-angle fluting cutters. These setting angles depend upon three factors: the number of teeth to be cut; the angle of the blank in which the teeth are to be cut; and the angle of the fluting cutter. Setting angles for various combinations of these three factors are given in the tables. For example, assume that 12 teeth are to be cut on the end of an end mill using a 60-degree cutter. By following the horizontal line from 12 teeth, read in the column under 60 degrees that the dividing head should be set to an angle of 70 degrees and 32 minutes.
The following formulas, which were used to compile these tables, may be used to calculate the setting-angles for combinations of number of teeth, blank angle, and cutter angle not covered by the tables. In these formulas, A = setting-angle for dividing head, B = angle of blank in which teeth are to be cut, C = angle of fluting cutter, N = number of teeth to be cut, and D and E are angles not shown on the accompanying diagram and which are used only to simplify calculations. (1) tan D = cos ( 360° ⁄ N ) × cot B sin E = tan ( 360° ⁄ N ) × cot C × sin D
(2)
Setting-angle A = D – E
(3)
Example:Suppose 9 teeth are to be cut in a 35-degree blank using a 55-degree singleangle fluting cutter. Then, N = 9, B = 35°, and C = 55°. tan D = cos ( 360° ⁄ 9 ) × cot 35° = 0.76604 × 1.4281 = 1.0940; and D = 47°34′ sin E = tan ( 360° ⁄ 9 ) × cot 55° × sin 47°34′ = 0.83910 × 0.70021 × 0.73806 = 0.43365; and E = 25°42′ Setting angle A = 47°34′ – 25°42′ = 21°52′ For end mills and side mills the angle of the blank B is 0 degrees and the following simplified formula may be used to find the setting angle A (4) cos A = tan ( 360° ⁄ N ) × cot C Example:If in the previous example the blank angle was 0 degrees, cos A = tan (360°/9) × cot 55° = 0.83910 × 0.70021 = 0.58755, and setting-angle A = 54°1′
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 822
MILLING CUTTERS Angles of Elevation for Milling Straight Teeth in 0-, 5-, 10-, 15-, 20-, 25-, 30-, and 35-degree Blanks Using Single-Angle Fluting Cutters
No. of Teeth
Angle of Fluting Cutter 90°
80°
70°
60°
50°
90°
80°
70°
0° Blank (End Mill)
60°
50°
5° Blank
6
…
72° 13′
50° 55′
…
…
80°
4′
62° 34′
41° 41′
8
…
79
51
68
39
54° 44′
32° 57′
82
57
72
52
61
47
48°
… 0′
25°
…
10
…
82
38
74
40
65
12
52
26
83
50
76
31
68
35
59
11
46
4
12
…
84
9
77
52
70
32
61
2
84
14
78
25
72
10
64
52
55
5 28
40′
14
…
85
8
79
54
73
51
66
10
84
27
79
36
74
24
68
23
60
16
…
85
49
81
20
76
10
69
40
84
35
80
25
75
57
70
49
64
7
18
…
86
19
82
23
77
52
72
13
84
41
81
1
77
6
72
36
66
47
20
…
86
43
83
13
79
11
74
11
84
45
81
29
77
59
73
59
68
50
22
…
87
2
83
52
80
14
75
44
84
47
81
50
78
40
75
4
70
26
24
…
87
18
84
24
81
6
77
0
84
49
82
7
79
15
75
57
71
44
10° Blank
15° Blank
6
70° 34′
53° 50′
34° 5′
…
…
61° 49′
46° 12′
28 ° 4′
8
76
0
66
9
55
19
41° 56′
20° 39′
69
15
59
46
49
21
36°
10
77
42
70
31
62
44
53
30
40
71
40
64
41
57
8
48
12
78
30
72
46
66
37
59
26
49
50
72
48
67
13
61
13
54
14
45
13
14
78
56
74
9
69
2
63
6
55
19
73
26
68
46
63
46
57
59
50
38
16
79
12
75
5
70 41
65
37
59
1
73
50
69 49
65 30
60
33
54 20
18
79
22
75
45
71
53
67
27
61
43
74
5
70
33
66
46
62
26
57
20
79
30
76
16
72
44
68
52
63
47
74
16
71
6
67
44
63
52
59
3
22
79
35
76
40
73
33
69
59
65
25
74
24
71
32
68
29
65
0
60
40
24
79
39
76
59
74
9
70
54
66
44
74
30
71
53
69
6
65
56
61
59
42
20° Blank
…
… 34′ 17°
34′
12
18
36
0
25° Blank
6
53° 57′
39° 39′
23° 18′
47° 0′
34° 6′
19° 33′
…
…
8
62
46
53
45
43
53
31°
… 53′
14° 31′
…
56
36
48
8
38
55
27° 47′
11° 33′
10
65
47
59
4
51
50
43
18
32
1
60
2
53
40
46
47
38
43
27
47
12
67
12
61
49
56
2
49
18
40
40
61
42
56
33
51
2
44
38
36
10
14
68
0
63
29
58 39
53
4
46
0
62
38
58 19
53 41
48
20
41 22
16
68
30
64
36
60
26
55
39
49
38
63
13
59
29
55
29
50
53
44
18
68
50
65
24
61
44
57
32
52
17
63
37
60
19
56
48
52
46
47
34
20
69
3
65
59
62
43
58
58
54
18
63
53
60
56
57
47
54
11
49
33
22
69
14
66
28
63
30
60
7
55
55
64
5
61
25
58
34
55
19
51
9
24
69
21
66
49
64
7
61
2
57
12
64
14
61
47
59
12
56
13
52
26
6
40° 54′
29° 22′
16° 32′
8
50
46
42
55
34
24
24°
10
54
29
48
30
42
3
12
56
18
51
26
46
14
57
21
53
15
16
58
0
54
18
58
26
20
58
44
22
58
24
59
30° Blank
57
35° Blank …
…
35° 32′
25° 19′
…
…
14°
3′
12′ 10°
14′
45
17
38
5
30
18
21°
4′
8°
41′
34
31
24
44
49
7
43
33
37
35
30
38
21
40
14
40
12
32
32
51
3
46
30
41
39
36
2
28
55
48
52
43
49
37
27
52
9
48
19
44
12
39
28
33
33
27
50
39
46
19
40
52
52
50
49
20
45
56
41
51
36
45
55
18
51
57
48
7
43
20
53
18
50
21
47
12
43
36
39 8
55
55
52
56
49
30
45
15
53
38
50
59
48
10
44
57
40
57
57
56
24
53
42
50
36
46
46
53
53
51
29
48
56
46
1
42
24
8
56
48
54
20
51
30
48
0
54
4
51
53
49
32
46
52
43
35
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MILLING CUTTERS
823
Angles of Elevation for Milling Straight Teeth in 40-, 45-, 50-, 55-, 60-, 65-, 70-, and 75-degree Blanks Using Single-Angle Fluting Cutters No. of Teeth
Angle of Fluting Cutter 90°
80°
70°
60°
50°
90°
80°
70°
40° Blank
60°
50°
45° Blank …
…
6
30° 48′
21° 48′
11° 58′
26° 34′
18° 43′
10° 11′
8
40
7
33
36
26
33
18°
16′
7°
23′
35
16
29
25
23
8
10
43
57
38
51
33
32
27
3
18
55
38
58
34
21
29
12
45
54
41
43
37
14
32
3
25
33
40
54
37
5
14
47
3
43
29
39
41
35
19
29
51
42
1
38
16
47
45
44
39
41
21
37
33
32
50
42
44
18
48
14
45
29
42
34
39
13
35
5
43
20
48
35
46
7
43
30
40
30
36
47
43
22
48
50
46
36
44
13
41
30
38
8
24
49
1
46
58
44
48
42
19
39
15
…
…
15° 48′
5°
58′
24
23
40
16
10
33
0
28
18
22
13
46
35
17
31
18
26
9
39
54
36
52
33
24
28
57
13
40
42
38
1
34
56
30
1
34
41
18
38
53
36
8
32
37
43
49
41
46
39
34
37
5
34
53
44
0
42
7
40
7
37
50
35
55
50° Blank
55° Blank
6
22° 45′
15° 58′
8°
38′
19° 17′
13° 30′
7°
15′
…
8
30
41
25
31
19
59
13°
33′
5°
20′
26
21
21
52
17
3
11° 30′
4°
17′
10
34
10
30
2
25
39
20
32
14
9
29
32
25
55
22
3
17
36
11
52
12
36
0
32
34
28
53
24
42
19
27
31
14
28
12
24
59
21
17
16
32
14
37
5
34
9
31
1
27
26
22
58
32
15
29
39
26
53
23
43
19
40
16
37
47
35
13
32
29
29
22
25
30
32
54
30
38
28
12
25
26
21
54
18
38
15
35
58
33
33
30
46
27
21
33
21
31
20
29
10
26
43
23
35
20
38
35
36
32
34
21
31
52
28
47
33
40
31
51
29
54
27
42
24
53
22
38
50
36
58
34
59
32
44
29
57
33
54
32
15
30
29
28
28
25
55
24
39
1
37
19
35
30
33
25
30
52
34
5
32
34
30
57
29
7
26
46
…
…
60° Blank
…
65° Blank …
…
…
…
6
16°
6′
11°
12′
6°
2′
13°
7′
9°
8′
4°
53′
8
22
13
18
24
14
19
9°
37′
3°
44′
18
15
15
6
11
42
7°
50′
3°
1′
10
25
2
21
56
18
37
14
49
10
5
20
40
18
4
15
19
12
9
8
15
12
26
34
23
57
21
10
17
59
14
13
21
59
19
48
17
28
14
49
11
32
14
27
29
25
14
22
51
20
6
16
44
22
48
20
55
18
54
16
37
13
48
16
28
5
26
7
24
1
21
37
18
40
23
18
21
39
19
53
17
53
15
24
18
28
29
26
44
24
52
22
44
20
6
23
40
22
11
20
37
18
50
16
37
20
28
46
27
11
25
30
23
35
21
14
23
55
22
35
21
10
19
33
17
34
22
29
0
27
34
26
2
24
17
22
8
24
6
22
53
21
36
20
8
18
20
24
29
9
27
50
26
26
24
50
22
52
24
15
23
8
21
57
20
36
18
57
34′
1° 45′
70° Blank 6
10° 18′
7°
9′
3°
48′
8
14
26
11
55
9
14
10
16
25
14
21
12
12
17
30
15
45
13
14
18
9
16
38
15
16
18
35
17
15
15
18
18
53
17
42
16
20
19
6
18
1
22
19
15
18
16
24
19
22
18
29
75° Blank …
…
…
…
7°
38′
5°
19′
2°
50′
10
44
8
51
6
51
30
12
14
10
40
9
1
7
8
4
49
8
13
4
11
45
10
21
8
45
6
47
10
55
13
34
12
26
11
13
9
50
8
7
12
13
13
54
12
54
11
50
10
37
9
7
59
13
13
14
8
13
14
12
17
11
12
9
51
15
35
13
59
14
18
13
29
12
38
11
39
10
27
16
3
14
35
14
25
13
41
12
53
12
0
10
54
16
25
15
5
14
31
13
50
13
7
12
18
11
18
6°
9′
2°
21′
8
9
53
11
37
6
45
9
1 50
13
11
14
13
26
14
16
53
17
15
17
33
Copyright 2004, Industrial Press, Inc., New York, NY
4°
Machinery's Handbook 27th Edition 824
CUTTER GRINDING Angles of Elevation for Milling Straight Teeth in 80- and 85-degree Blanks Using Single-Angle Fluting Cutters
No.of Teeth
Angle of Fluting Cutter 90°
80°
70°
60°
50°
90°
80°
80° Blank 6 8 10 12 14 16 18 20 22 24
5° 7 8 8 9 9 9 9 9 9
2′ 6 7 41 2 15 24 31 36 40
3° 5 7 7 8 8 8 8 9 9
30′ 51 5 48 16 35 48 58 6 13
1° 4 5 6 7 7 8 8 8 8
52′ 31 59 52 28 51 10 24 35 43
70°
60°
50°
… 1° 29′ 2 21 2 53 3 15 3 30 3 43 3 52 3 59 4 5
… 0° 34′ 1 35 2 15 2 42 3 1 3 16 3 28 3 37 3 45
85° Blank … 3° 2′ 4 44 5 48 6 32 7 3 7 26 7 44 7 59 8 11
… 1° 8′ 3 11 4 29 5 24 6 3 6 33 6 56 7 15 7 30
2° 3 4 4 4 4 4 4 4 4
30′ 32 3 20 30 37 42 46 48 50
1° 2 3 3 4 4 4 4 4 4
44′ 55 32 53 7 17 24 29 33 36
0° 2 2 3 3 3 4 4 4 4
55′ 15 59 25 43 56 5 12 18 22
Spline-Shaft Milling Cutter.—The most efficient method of forming splines on shafts is by hobbing, but special milling cutters may also be used. Since the cutter forms the space between adjacent splines, it must be made to suit the number of splines and the root diameter of the shaft. The cutter angle B equals 360 degrees divided by the number of splines. The following formulas are for determining the chordal width C at the root of the splines or the chordal width across the concave edge of the cutter. In these formulas, A = angle between center line of spline and a radial line passing through the intersection of the root circle and one side of the spline; W = width of spline; d = root diameter of splined shaft; C = chordal width at root circle between adjacent splines; N = number of splines.
sin A = W ----d
C = d × sin ⎛ 180 --------- – A⎞ ⎝ N ⎠
Splines of involute form are often used in preference to the straight-sided type. Dimensions of the American Standard involute splines and hobs are given in the section on splines. Cutter Grinding Wheels for Sharpening Milling Cutters.—Milling cutters may be sharpened either by using the periphery of a disk wheel or the face of a cup wheel. The latter grinds the lands of the teeth flat, whereas the periphery of a disk wheel leaves the teeth slightly concave back of the cutting edges. The concavity produced by disk wheels reduces the effective clearance angle on the teeth, the effect being more pronounced for wheels of small diameter than for wheels of large diameter. For this reason, large diameter wheels are preferred when sharpening milling cutters with disk type wheels. Irrespective of what type of wheel is used to sharpen a milling cutter, any burrs resulting from grinding should be carefully
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CUTTER GRINDING
825
removed by a hand stoning operation. Stoning also helps to reduce the roughness of grinding marks and improves the quality of the finish produced on the surface being machined. Unless done very carefully, hand stoning may dull the cutting edge. Stoning may be avoided and a sharper cutting edge produced if the wheel rotates toward the cutting edge, which requires that the operator maintain contact between the tool and the rest while the wheel rotation is trying to move the tool away from the rest. Though slightly more difficult, this method will eliminate the burr. Specifications of Grinding Wheels for Sharpening Milling Cutters Cutter Material Carbon Tool Steel
Operation Roughing Finishing
Abrasive Material
Grinding Wheel Grain Size 46–60 100
Grade K H
Bond Vitrified Vitrified
60 100 80 100 46 100–120
K,H H F,G,H H H,K,L,N H
Vitrified Vitrified Vitrified Vitrified Vitrified Vitrified
60
G
Vitrified
Diamond Diamond
100 Up to 500
a a
Resinoid Resinoid
Cubic Boron Nitride
80–100 100–120
R,P S,T
Resinoid Resinoid
Aluminum Oxide
High-speed Steel: 18-4-1
{
18-4-2
{
Cast Non-Ferrous Tool Material
Sintered Carbide
Carbon Tool Steel and High-Speed Steelb
Roughing Finishing Roughing Finishing Roughing Finishing Roughing after Brazing Roughing Finishing Roughing Finishing
Aluminum Oxide
Aluminum Oxide Silicon Carbide
a Not indicated in diamond wheel markings. b For hardnesses above Rockwell C 56.
Wheel Speeds and Feeds for Sharpening Milling Cutters.—Relatively low cutting speeds should be used when sharpening milling cutters to avoid tempering and heat checking. Dry grinding is recommended in all cases except when diamond wheels are employed. The surface speed of grinding wheels should be in the range of 4500 to 6500 feet per minute for grinding milling cutters of high-speed steel or cast non-ferrous tool material. For sintered carbide cutters, 5000 to 5500 feet per minute should be used. The maximum stock removed per pass of the grinding wheel should not exceed about 0.0004 inch for sintered carbide cutters; 0.003 inch for large high-speed steel and cast nonferrous tool material cutters; and 0.0015 inch for narrow saws and slotting cutters of highspeed steel or cast non-ferrous tool material. The stock removed per pass of the wheel may be increased for backing-off operations such as the grinding of secondary clearance behind the teeth since there is usually a sufficient body of metal to carry off the heat. Clearance Angles for Milling Cutter Teeth.—The clearance angle provided on the cutting edges of milling cutters has an important bearing on cutter performance, cutting efficiency, and cutter life between sharpenings. It is desirable in all cases to use a clearance angle as small as possible so as to leave more metal back of the cutting edges for better heat dissipation and to provide maximum support. Excessive clearance angles not only weaken the cutting edges, but also increase the likelihood of “chatter” which will result in poor finish on the machined surface and reduce the life of the cutter. According to The Cincinnati Milling Machine Co., milling cutters used for general purpose work and having diameters from 1⁄8 to 3 inches should have clearance angles from 13 to 5 degrees, respectively, decreasing proportionately as the diameter increases. General purpose cutters over 3
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 826
CUTTER GRINDING
inches in diameter should be provided with a clearance angle of 4 to 5 degrees. The land width is usually 1⁄64 , 1⁄32 , and 1⁄16 inch, respectively, for small, medium, and large cutters. The primary clearance or relief angle for best results varies according to the material being milled about as follows: low carbon, high carbon, and alloy steels, 3 to 5 degrees; cast iron and medium and hard bronze, 4 to 7 degrees; brass, soft bronze, aluminum, magnesium, plastics, etc., 10 to 12 degrees. When milling cutters are resharpened, it is customary to grind a secondary clearance angle of 3 to 5 degrees behind the primary clearance angle to reduce the land width to its original value and thus avoid interference with the surface to be milled. A general formula for plain milling cutters, face mills, and form relieved cutters which gives the clearance angle C, in degrees, necessitated by the feed per revolution F, in inches, the width of land L, in inches, the depth of cut d, in inches, the cutter diameter D, in inches, and the Brinell hardness number B of the work being cut is: F - d ( D – d )⎞ C = 45860 --------------- ⎛ 1.5L + ------⎠ DB ⎝ πD Rake Angles for Milling Cutters.—In peripheral milling cutters, the rake angle is generally defined as the angle in degrees that the tooth face deviates from a radial line to the cutting edge. In face milling cutters, the teeth are inclined with respect to both the radial and axial lines. These angles are called radial and axial rake, respectively. The radial and axial rake angles may be positive, zero, or negative. Positive rake angles should be used whenever possible for all types of high-speed steel milling cutters. For sintered carbide tipped cutters, zero and negative rake angles are frequently employed to provide more material back of the cutting edge to resist shock loads. Rake Angles for High-speed Steel Cutters: Positive rake angles of 10 to 15 degrees are satisfactory for milling steels of various compositions with plain milling cutters. For softer materials such as magnesium and aluminum alloys, the rake angle may be 25 degrees or more. Metal slitting saws for cutting alloy steel usually have rake angles from 5 to 10 degrees, whereas zero and sometimes negative rake angles are used for saws to cut copper and other soft non-ferrous metals to reduce the tendency to “hog in.” Form relieved cutters usually have rake angles of 0, 5, or 10 degrees. Commercial face milling cutters usually have 10 degrees positive radial and axial rake angles for general use in milling cast iron, forged and alloy steel, brass, and bronze; for milling castings and forgings of magnesium and free-cutting aluminum and their alloys, the rake angles may be increased to 25 degrees positive or more, depending on the operating conditions; a smaller rake angle is used for abrasive or difficult to machine aluminum alloys. Cast Non-ferrous Tool Material Milling Cutters: Positive rake angles are generally provided on milling cutters using cast non-ferrous tool materials although negative rake angles may be used advantageously for some operations such as those where shock loads are encountered or where it is necessary to eliminate vibration when milling thin sections. Sintered Carbide Milling Cutters: Peripheral milling cutters such as slab mills, slotting cutters, saws, etc., tipped with sintered carbide, generally have negative radial rake angles of 5 degrees for soft low carbon steel and 10 degrees or more for alloy steels. Positive axial rake angles of 5 and 10 degrees, respectively, may be provided, and for slotting saws and cutters, 0 degree axial rake may be used. On soft materials such as free-cutting aluminum alloys, positive rake angles of 10 to so degrees are used. For milling abrasive or difficult to machine aluminum alloys, small positive or even negative rake angles are used. Eccentric Type Radial Relief.—When the radial relief angles on peripheral teeth of milling cutters are ground with a disc type grinding wheel in the conventional manner the ground surfaces on the lands are slightly concave, conforming approximately to the radius of the wheel. A flat land is produced when the radial relief angle is ground with a cup wheel. Another entirely different method of grinding the radial angle is by the eccentric method, which produces a slightly convex surface on the land. If the radial relief angle at
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CUTTER GRINDING
827
the cutting edge is equal for all of the three types of land mentioned, it will be found that the land with the eccentric relief will drop away from the cutting edge a somewhat greater distance for a given distance around the land than will the others. This is evident from a study of Table 1 entitled, Indicator Drops for Checking the Radial Relief Angle on Peripheral Teeth. This feature is an advantage of the eccentric type relief which also produces an excellent finish. Table 1. Indicator Drops for Checking the Radial Relief Angle on Peripheral Teeth Cutter Diameter, Inch 1⁄ 16 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
Indicator Drops, Inches For Flat and Concave Relief For Eccentric Relief Min. Max. Min. Max.
Rec. Range of Radial Relief Angles, Degrees
Checking Distance, Inch
Rec. Max. Primary Land Width, Inch
20–25
.005
.0014
.0019
.0020
.0026
.007
16–20
.005
.0012
.0015
.0015
.0019
.007
15–19
.010
.0018
.0026
.0028
.0037
.015
13–17
.010
.0017
.0024
.0024
.0032
.015
12–16
.010
.0016
.0023
.0022
.0030
.015
11–15
.010
.0015
.0022
.0020
.0028
.015
10–14
.015
.0017
.0028
.0027
.0039
.020
10–14
.015
.0018
.0029
.0027
.0039
.020
10–13
.015
.0019
.0027
.0027
.0035
.020
10–13
.015
.0020
.0028
.0027
.0035
.020
10–13
.015
.0020
.0029
.0027
.0035
.020
9–12
.020
.0022
.0032
.0032
.0044
.025
9–12
.020
.0022
.0033
.0032
.0043
.025
9–12
.020
.0023
.0034
.0032
.0043
.025
9–12
.020
.0024
.0034
.0032
.0043
.025
9–12
.020
.0024
.0035
.0032
.0043
.025
8–11
.020
.0022
.0032
.0028
.0039
.025
8–11
.030
.0029
.0045
.0043
.0059
.035
8–11
.030
.0030
.0046
.0043
.0059
.035
8–11
.030
.0031
.0047
.0043
.0059
.035
8–11
.030
.0032
.0048
.0043
.0059
.035
1 11⁄8
7–10 7–10 7–10
.030 .030 .030
.0027 .0028 .0029
.0043 .0044 .0045
.0037 .0037 .0037
.0054 .0054 .0053
.035 .035 .035
11⁄4
6–9
.030
.0024
.0040
.0032
.0048
.035
13⁄8
6–9
.030
.0025
.0041
.0032
.0048
.035
11⁄2
6–9
.030
.0026
.0041
.0032
.0048
.035
15⁄8
6–9
.030
.0026
.0042
.0032
.0048
.035
13⁄4
6–9
.030
.0026
.0042
.0032
.0048
.035
17⁄8 2 21⁄4
6–9 6–9 5–8
.030 .030 .030
.0027 .0027 .0022
.0043 .0043 .0038
.0032 .0032 .0026
.0048 .0048 .0042
.035 .035 .040
21⁄2
5–8
.030
.0023
.0039
.0026
.0042
.040
23⁄4 3 31⁄2 4 5 6 7 8 10 12
5–8 5–8 5–8 5–8 4–7 4–7 4–7 4–7 4–7 4–7
.030 .030 .030 .030 .030 .030 .030 .030 .030 .030
.0023 .0023 .0024 .0024 .0019 .0019 .0020 .0020 .0020 .0020
.0039 .0039 .0040 .0040 .0035 .0035 .0036 .0036 .0036 .0036
.0026 .0026 .0026 .0026 .0021 .0021 .0021 .0021 .0021 .0021
.0042 .0042 .0042 .0042 .0037 .0037 .0037 .0037 .0037 .0037
.040 .040 .047 .047 .047 .047 .060 .060 .060 .060
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 828
CUTTER GRINDING
The setup for grinding an eccentric relief is shown in Fig. 1. In this setup the point of contact between the cutter and the tooth rest must be in the same plane as the centers, or axes, of the grinding wheel and the cutter. A wide face is used on the grinding wheel, which is trued and dressed at an angle with respect to the axis of the cutter. An alternate method is to tilt the wheel at this angle. Then as the cutter is traversed and rotated past the grinding wheel while in contact with the tooth rest, an eccentric relief will be generated by the angular face of the wheel. This type of relief can only be ground on the peripheral teeth on milling cutters having helical flutes because the combination of the angular wheel face and the twisting motion of the cutter is required to generate the eccentric relief. Therefore, an eccentric relief cannot be ground on the peripheral teeth of straight fluted cutters. Table 2 is a table of wheel angles for grinding an eccentric relief for different combinations of relief angles and helix angles. When angles are required that cannot be found in this table, the wheel angle, W, can be calculated by using the following formula, in which R is the radial relief angle and H is the helix angle of the flutes on the cutter. tan W = tan R × tan H Table 2. Grinding Wheel Angles for Grinding Eccentric Type Radial Relief Angle Radial Relief Angle, R, Degrees
Helix Angle of Cutter Flutes, H, Degrees 12
18
20
30
40
45
50
52
Wheel Angle, W, Degrees
1
0°13′
0°19′
0°22′
0°35′
0°50′
1°00′
1°12′
1°17′
2
0°26′
0°39′
0°44′
1°09′
1°41′
2°00′
2°23′
2°34′
3
0°38′
0°59′
1°06′
1°44′
2°31′
3°00′
3°34′
3°50′
4
0°51′
1°18′
1°27′
2°19′
3°21′
4°00′
4°46′
5°07′
5
1°04′
1°38′
1°49′
2°53′
4°12′
5°00′
5°57′
6°23′
6
1°17′
1°57′
2°11′
3°28′
5°02′
6°00′
7°08′
7°40′
7
1°30′
2°17′
2°34′
4°03′
5°53′
7°00′
8°19′
8°56′
8
1°43′
2°37′
2°56′
4°38′
6°44′
8°00′
9°30′
10°12′
9
1°56′
2°57′
3°18′
5°13′
7°34′
9°00′
10°41′
11°28′
10
2°09′
3°17′
3°40′
5°49′
8°25′
10°00′
11°52′
12°43′
11
2°22′
3°37′
4°03′
6°24′
9°16′
11°00′
13°03′
13°58′
12
2°35′
3°57′
4°25′
7°00′
10°07′
12°00′
14°13′
15°13′
13
2°49′
4°17′
4°48′
7°36′
10°58′
13°00′
15°23′
16°28′
14
3°02′
4°38′
5°11′
8°11′
11°49′
14°00′
16°33′
17°42′
15
3°16′
4°59′
5°34′
8°48′
12°40′
15°00′
17°43′
18°56′
16
3°29′
5°19′
5°57′
9°24′
13°32′
16°00′
18°52′
20°09′
17
3°43′
5°40′
6°21′
10°01′
14°23′
17°00′
20°01′
21°22′
18
3°57′
6°02′
6°45′
10°37′
15°15′
18°00′
21°10′
22°35′
19
4°11′
6°23′
7°09′
11°15′
16°07′
19°00′
22°19′
23°47′ 24°59′
20
4°25′
6°45′
7°33′
11°52′
16°59′
20°00′
23°27′
21
4°40′
7°07′
7°57′
12°30′
17°51′
21°00′
24°35′
26°10′
22
4°55′
7°29′
8°22′
13°08′
18°44′
22°00′
25°43′
27°21′
23
5°09′
7°51′
8°47′
13°46′
19°36′
23°00′
26°50′
28°31′
24
5°24′
8°14′
9°12′
14°25′
20°29′
24°00′
27°57′
29°41′
25
5°40′
8°37′
9°38′
15°04′
21°22′
25°00′
29°04′
30°50′
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CUTTER GRINDING
829
Indicator Drop Method of Checking Relief and Rake Angles.—The most convenient and inexpensive method of checking the relief and rake angles on milling cutters is by the indicator drop method. Three tables, Tables 1, 3 and 4, of indicator drops are provided in this section, for checking radial relief angles on the peripheral teeth, relief angles on side and end teeth, and rake angles on the tooth faces.
Fig. 1. Setup for Grinding Eccentric Type Radial Relief Angle
Table 3. Indicator Drops for Checking Relief Angles on Side Teeth and End Teeth Given Relief Angle Checking Distance, Inch
1°
.005
.00009
.00017
.00026
.00035
.010
.00017
.00035
.00052
.0007
.015
.00026
.0005
.00079
.031
.00054
.0011
.047
.00082
.0016
.062
.00108
.0022
2°
3°
4°
5°
6°
7°
8°
9°
.0004
.0005
.0006
.0007
.0008
.0009
.0011
.0012
.0014
.0016
.0010
.0013
.0016
.0018
.0021
.0024
.0016
.0022
.0027
.0033
.0038
.0044
.0049
.0025
.0033
.0041
.0049
.0058
.0066
.0074
.0032
.0043
.0054
.0065
.0076
.0087
.0098
Indicator Drop, inch
Fig. 2. Setup for Checking the Radial Relief Angle by Indicator Drop Method
The setup for checking the radial relief angle is illustrated in Fig. 2. Two dial test indicators are required, one of which should have a sharp pointed contact point. This indicator is positioned so that the axis of its spindle is vertical, passing through the axis of the cutter. The cutter may be held by its shank in the spindle of a tool and cutter grinder workhead, or
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 830
CUTTER GRINDING
between centers while mounted on a mandrel. The cutter is rotated to the position where the vertical indicator contacts a cutting edge. The second indicator is positioned with its spindle axis horizontal and with the contact point touching the tool face just below the cutting edge. With both indicators adjusted to read zero, the cutter is rotated a distance equal to the checking distance, as determined by the reading on the second indicator. Then the indicator drop is read on the vertical indicator and checked against the values in the tables. The indicator drops for radial relief angles ground by a disc type grinding wheel and those ground with a cup wheel are so nearly equal that the values are listed together; values for the eccentric type relief are listed separately, since they are larger. A similar procedure is used to check the relief angles on the side and end teeth of milling cutters; however, only one indicator is used. Also, instead of rotating the cutter, the indicator or the cutter must be moved a distance equal to the checking distance in a straight line. Table 4. Indicator Drops for Checking Rake Angles on Milling Cutter Face
Set indicator to read zero on horizontal plane passing through cutter axis. Zero cutting edge against indicator. Rate Angle, Deg. 1 2 3 4 5 6 7 8 9 10
Measuring Distance, inch .031
.062
.094
.125
Indicator Drop, inch .0005 .0011 .0016 .0022 .0027 .0033 .0038 .0044 .0049 .0055
.0011 .0022 .0032 .0043 .0054 .0065 .0076 .0087 .0098 .0109
.0016 .0033 .0049 .0066 .0082 .0099 .0115 .0132 .0149 .0166
.0022 .0044 .0066 .0087 .0109 .0131 .0153 .0176 .0198 .0220
Move cutter or indicator measuring distance. Measuring Distance, inch
Rate Angle, Deg.
.031
11 12 13 14 15 16 17 18 19 20
.0060 .0066 .0072 .0077 .0083 .0089 .0095 .0101 .0107 .0113
.062
.094
.125
Indicator Drop, inch .0121 .0132 .0143 .0155 .0166 .0178 .0190 .0201 .0213 .0226
.0183 .0200 .0217 .0234 .0252 .0270 .0287 .0305 .0324 .0342
.0243 .0266 .0289 .0312 .0335 .0358 .0382 .0406 .0430 .0455
Relieving Attachments.—A relieving attachment is a device applied to lathes (especially those used in tool-rooms) for imparting a reciprocating motion to the tool-slide and tool, in order to provide relief or clearance for the cutting edges of milling cutters, taps, hobs, etc. For example, in making a milling cutter of the formed type, such as is used for cutting gears, it is essential to provide clearance for the teeth and so form them that they may he ground repeatedly without changing the contour or shape of the cutting edge. This may be accomplished by using a relieving attachment. The tool for “backing off” or giving clearance to the teeth corresponds to the shape required, and it is given a certain amount of reciprocating movement, so that it forms a surface back of each cutting edge, which is of uniform cross-section on a radial plane but eccentric to the axis of the cutter sufficiently to provide the necessary clearance for the cutting edges.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CUTTER GRINDING
831
Various Set-ups Used in Grinding the Clearance Angle on Milling Cutter Teeth
Wheel Above Center
In-Line Centers
Wheel Below Center
Cup Wheel
Distance to Set Center of Wheel Above the Cutter Center (Disk Wheel) Desired Clearance Angle, Degrees
Dia. of Wheel, Inches
1
3
.026
.052
.079
.105
.131
.157
.183
.209
4
.035
.070
.105
.140
.174
.209
.244
.278
5
.044
.087
.131
.174
.218
.261
.305
6
.052
.105
.157
.209
.261
.314
7
.061
.122
.183
.244
.305
8
.070
.140
.209
.279
9
.079
.157
.236
10
.087
.175
.262
2
3
4
10
11
12
.235
.260
.286
.312
.313
.347
.382
.416
.348
.391
.434
.477
.520
.366
.417
.469
.521
.572
.624
.366
.427
.487
.547
.608
.668
.728
.349
.418
.488
.557
.626
.695
.763
.832
.314
.392
.470
.548
.626
.704
.781
.859
.936
.349
.436
.523
.609
.696
.782
.868
.954
1.040
aDistance
5
6
7
8
9
to Offset Wheel Center Above Cutter Center, Inches
a Calculated from the formula: Offset = Wheel Diameter × 1⁄ 2
× Sine of Clearance Angle.
Distance to Set Center of Wheel Below the Cutter Center (Disk Wheel) Dia. of Cutter, Inches
Desired Clearance Angle, Degrees 1
2
3
4 aDistance
5
6
7
8
9
10
11
12
to Offset Wheel Center Below Cutter Center, Inches
2
.017
.035
.052
.070
.087
.105
.122
.139
.156
.174
.191
.208
3
.026
.052
.079
.105
.131
.157
.183
.209
.235
.260
.286
.312
4
.035
.070
.105
.140
.174
.209
.244
.278
.313
.347
.382
.416
5
.044
.087
.131
.174
.218
.261
.305
.348
.391
.434
.477
.520
6
.052
.105
.157
.209
.261
.314
.366
.417
.469
.521
.572
.624
7
.061
.122
.183
.244
.305
.366
.427
.487
.547
.608
.668
.728
8
.070
.140
.209
.279
.349
.418
.488
.557
.626
.695
.763
.832
9
.079
.157
.236
.314
.392
.470
.548
.626
.704
.781
.859
.936
10
.087
.175
.262
.349
.436
.523
.609
.696
.782
.868
.954
1.040
a Calculated from the formula: Offset = Cutter Diameter × 1⁄ 2
× Sine of Clearance Angle.
Distance to Set Tooth Rest Below Center Line of Wheel and Cutter.—W h e n the clearance angle is ground with a disk type wheel by keeping the center line of the wheel in line with the center line of the cutter, the tooth rest should be lowered by an amount given by the following formula: Wheel Diam. × Cutter Dia. × Sine of One-half the Clearance Angle Offset = ----------------------------------------------------------------------------------------------------------------------------------------------------------------Wheel Dia. + Cutter Dia. Distance to Set Tooth Rest Below Cutter Center When Cup Wheel is Used.—W h e n the clearance is ground with a cup wheel, the tooth rest is set below the center of the cutter the same amount as given in the table for Distance to Set Center of Wheel Below the Cutter Center (Disk Wheel).
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 832
REAMERS
REAMERS Hand Reamers.—Hand reamers are made with both straight and helical flutes. Helical flutes provide a shearing cut and are especially useful in reaming holes having keyways or grooves, as these are bridged over by the helical flutes, thus preventing binding or chattering. Hand reamers are made in both solid and expansion forms. The American standard dimensions for solid forms are given in the accompanying table. The expansion type is useful whenever, in connection with repair or other work, it is necessary to enlarge a reamed hole by a few thousandths of an inch. The expansion form is split through the fluted section and a slight amount of expansion is obtained by screwing in a tapering plug. The diameter increase may vary from 0.005 to 0.008 inch for reamers up to about 1 inch diameter and from 0.010 to 0.012 inch for diameters between 1 and 2 inches. Hand reamers are tapered slightly on the end to facilitate starting them properly. The actual diameter of the shanks of commercial reamers may be from 0.002 to 0.005 inch under the reamer size. That part of the shank that is squared should be turned smaller in diameter than the shank itself, so that, when applying a wrench, no burr may be raised that may mar the reamed hole if the reamer is passed clear through it. When fluting reamers, the cutter is so set with relation to the center of the reamer blank that the tooth gets a slight negative rake; that is, the cutter should be set ahead of the center, as shown in the illustration accompanying the table giving the amount to set the cutter ahead of the radial line. The amount is so selected that a tangent to the circumference of the reamer at the cutting point makes an angle of approximately 95 degrees with the front face of the cutting edge. Amount to Set Cutter Ahead of Radial Line to Obtain Negative Front Rake Fluting Cutter a B C 95
A Reamer Blank
Size of Reamer
a, Inches
1⁄ 4
0.011
3⁄ 8
Size of Reamer 7⁄ 8
a, Inches
Size of Reamer
a, Inches
0.038
2
0.087 0.098
0.016
1
0.044
21⁄4
1⁄ 2
0.022
11⁄4
0.055
21⁄2
0.109
5⁄ 8
0.027
11⁄2
0.066
23⁄4
0.120
3⁄ 4
0.033
13⁄4
0.076
3
0.131
When fluting reamers, it is necessary to “break up the flutes”; that is, to space the cutting edges unevenly around the reamer. The difference in spacing should be very slight and need not exceed two degrees one way or the other. The manner in which the breaking up of the flutes is usually done is to move the index head to which the reamer is fixed a certain amount more or less than it would be moved if the spacing were regular. A table is given showing the amount of this additional movement of the index crank for reamers with different numbers of flutes. When a reamer is provided with helical flutes, the angle of spiral should be such that the cutting edges make an angle of about 10 or at most 15 degrees with the axis of the reamer. The relief of the cutting edges should be comparatively slight. An eccentric relief, that is, one where the land back of the cutting edge is convex, rather than flat, is used by one or two manufacturers, and is preferable for finishing reamers, as the reamer will hold its size longer. When hand reamers are used merely for removing stock, or simply for enlarging holes, the flat relief is better, because the reamer has a keener cutting edge. The width of the land of the cutting edges should be about 1⁄32 inch for a 1⁄4-inch, 1⁄16 inch for a 1-inch, and 3⁄32 inch for a 3-inch reamer.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition REAMERS
833
Irregular Spacing of Teeth in Reamers Number of flutes in reamer Index circle to use
4
6
39
39
Before cutting 2d flute 3d flute 4th flute 5th flute 6th flute 7th flute 8th flute 9th flute 10th flute 11th flute 12th flute 13th flute 14th flute 15th flute 16th flute
8 less 4 more 6 less … … … … … … … … … … … …
8
10
12
14
39 39 39 49 Move Spindle the Number of Holes below More or Less than for Regular Spacing 4 less 3 less 2 less 4 less 3 less 5 more 5 more 3 more 4 more 2 more 7 less 2 less 5 less 1 less 2 less 6 more 4 more 2 more 3 more 4 more 5 less 6 less 2 less 4 less 1 less … 2 more 3 more 4 more 3 more … 3 less 2 less 3 less 2 less … … 5 more 2 more 1 more … … 1 less 2 less 3 less … … … 3 more 3 more … … … 4 less 2 less … … … … 2 more … … … … 3 less … … … … … … … … … …
16 20
2 less 2 more 1 less 2 more 2 less 1 more 2 less 2 more 2 less 1 more 2 less 2 more 1 less 2 more 2 less
Threaded-end Hand Reamers.—Hand reamers are sometimes provided with a thread at the extreme point in order to give them a uniform feed when reaming. The diameter on the top of this thread at the point of the reamer is slightly smaller than the reamer itself, and the thread tapers upward until it reaches a dimension of from 0.003 to 0.008 inch, according to size, below the size of the reamer; at this point, the thread stops and a short neck about 1⁄16inch wide separates the threaded portion from the actual reamer, which is provided with a short taper from 3⁄16 to 7⁄16 inch long up to where the standard diameter is reached. The length of the threaded portion and the number of threads per inch for reamers of this kind are given in the accompanying table. The thread employed is a sharp V-thread. Dimensions for Threaded-End Hand Reamers Dia. of Thread at Point of Reamer
Sizes of Reamers
Length of Threaded Part
No. of Threads per Inch
1⁄ –5⁄ 8 16
3⁄ 8
32
Full diameter −0.006
11⁄ –1⁄ 32 2
7⁄ 16
28
−0.006
17⁄ –3⁄ 32 4
1⁄ 2
24
−0.008
25⁄ –1 32
9⁄ 16
18
−0.008
217⁄32–3
Dia. of Thread at Point of Reamer
Sizes of Reamers
Length of Threaded Part
No. of Threads per Inch
11⁄32–11⁄2
9⁄ 16
18
Full diameter −0.010
117⁄32–2
9⁄ 16
18
−0.012
21⁄32–21⁄2
9⁄ 16
18
−0.015
9⁄ 16
18
−0.020
Fluted Chucking Reamers.—Reamers of this type are used in turret lathes, screw machines, etc., for enlarging holes and finishing them smooth and to the required size. The best results are obtained with a floating type of holder that permits a reamer to align itself with the hole being reamed. These reamers are intended for removing a small amount of metal, 0.005 to 0.010 inch being common allowances. Fluted chucking reamers are provided either with a straight shank or a standard taper shank. (See table for standard dimensions.)
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 834
REAMERS Fluting Cutters for Reamers 55
D
30
85
85
A
A
C
B
C
B 15 70
D
Reamer Dia. 1⁄ 8 3⁄ 16 1⁄ 4 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4
1
Fluting Cutter Dia. A 13⁄4 13⁄4 13⁄4 2 2 2 2 21⁄4
Fluting Cutter Thickness B
Hole Dia. in Cutter C
3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2
3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4
1
Radius between Cutting Faces D
Reamer Dia. 11⁄4
nonea nonea 1⁄ 64 1⁄ 64 1⁄ 32 1⁄ 32 3⁄ 64 3⁄ 64
11⁄2 13⁄4
Fluting Cutter Dia. A
Fluting Cutter Thickness B
Hole Dia. in Cutter C
21⁄4
9⁄ 16 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 7⁄ 8 7⁄ 8
1
21⁄4 21⁄4
2
21⁄2
21⁄4
21⁄2
21⁄2
21⁄2
23⁄4 3
21⁄2 21⁄2
1
1 1 1 1 1 1 1
Radius between Cutting Faces D 1⁄ 16 1⁄ 16 5⁄ 64 5⁄ 64 5⁄ 64 3⁄ 16 3⁄ 16 3⁄ 16
a Sharp corner, no radius
Rose Chucking Reamers.—The rose type of reamer is used for enlarging cored or other holes. The cutting edges at the end are ground to a 45-degree bevel. This type of reamer will remove considerable metal in one cut. The cylindrical part of the reamer has no cutting edges, but merely grooves cut for the full length of the reamer body, providing a way for the chips to escape and a channel for lubricant to reach the cutting edges. There is no relief on the cylindrical surface of the body part, but it is slightly back-tapered so that the diameter at the point with the beveled cutting edges is slightly larger than the diameter farther back. The back-taper should not exceed 0.001 inch per inch. This form of reamer usually produces holes slightly larger than its size and it is, therefore, always made from 0.005 to 0.010 inch smaller than its nominal size, so that it may be followed by a fluted reamer for finishing. The grooves on the cylindrical portion are cut by a convex cutter having a width equal to from one-fifth to one-fourth the diameter of the rose reamer itself. The depth of the groove should be from one-eighth to one-sixth the diameter of the reamer. The teeth at the end of the reamer are milled with a 75-degree angular cutter; the width of the land of the cutting edge should be about one-fifth the distance from tooth to tooth. If an angular cutter is preferred to a convex cutter for milling the grooves on the cylindrical portion, because of the higher cutting speed possible when milling, an 80-degree angular cutter slightly rounded at the point may be used. Cutters for Fluting Rose Chucking Reamers.—The cutters used for fluting rose chucking reamers on the end are 80-degree angular cutters for 1⁄4- and 5⁄16-inch diameter reamers; 75-degree angular cutters for 3⁄8- and 7⁄16-inch reamers; and 70-degree angular cutters for all larger sizes. The grooves on the cylindrical portion are milled with convex cutters of approximately the following sizes for given diameters of reamers: 5⁄32-inch convex cutter
Copyright 2004, Industrial Press, Inc., New York, NY
;; ;
Machinery's Handbook 27th Edition REAMERS
835
Dimensions of Formed Reamer Fluting Cutters
A
B Dia. = D
C
C
The making and maintenance of cutters of the formed type involves greater expense than the use of angular cutters of which dimensions are given on the previous page; but the form of flute produced by the formed type of cutter is preferred by many reamer users. The claims made for the formed type of flute are that the chips can be more readily removed from the reamer, and that the reamer has greater strength and is less likely to crack or spring out of shape in hardening.
G
E
H
F
6
Reamer Size 1⁄ –3⁄ 8 16 1⁄ –5⁄ 4 16 3⁄ –7⁄ 8 16 1⁄ –11⁄ 2 16 3⁄ –1 4 11⁄16–11⁄2 19⁄16–21⁄8 21⁄4–3
1⁄ -inch 2
No. of Teeth in Reamer
Cutter Dia. D
6
13⁄4
6
13⁄4
6
17⁄8 2
6–8 8 10 12 14
21⁄8 21⁄4 23⁄8 25⁄8
Cutter Width A
Hole Dia. B
Bearing Width C
Bevel Length E
Radius F
Radius F
3⁄ 16 1⁄ 4 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16
7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8
…
0.125
0.016
…
0.152
0.022
1⁄ 8 1⁄ 8 5⁄ 32 5⁄ 32 3⁄ 16 3⁄ 16
0.178
0.029
0.205
0.036
0.232
0.042
0.258
0.049
0.285
0.056
0.312
0.062
7⁄ 32 9⁄ 32 1⁄ 2 9⁄ 16 11⁄ 16 3⁄ 4 27⁄ 32 7⁄ 8
Tooth Depth H
No. of Cutter Teeth
0.21
14
0.25
13
0.28
12
0.30
12
0.32
12
0.38
11
0.40
11
0.44
10
5⁄ -inch 16
for reamers; cutter for 1-inch reamers; 3⁄8-inch cutter for 11⁄2-inch reamers; 13⁄ -inch cutters for 2-inch reamers; and 15⁄ -inch cutters for 21⁄ -inch reamers. The smaller 32 32 2 sizes of reamers, from 1⁄4 to 3⁄8 inch in diameter, are often milled with regular double-angle reamer fluting cutters having a radius of 1⁄64 inch for 1⁄4-inch reamer, and 1⁄32 inch for 5⁄16- and 3⁄ -inch sizes. 8 Reamer Terms and Definitions.—Reamer: A rotary cutting tool with one or more cutting elements used for enlarging to size and contour a previously formed hole. Its principal support during the cutting action is obtained from the workpiece. (See Fig. 1.) Actual Size: The actual measured diameter of a reamer, usually slightly larger than the nominal size to allow for wear. Angle Of Taper: The included angle of taper on a taper tool or taper shank. Arbor Hole: The central mounting hole in a shell reamer. Axis: the imaginary straight line which forms the longitudinal centerline of a reamer, usually established by rotating the reamer between centers. Back Taper: A slight decrease in diameter, from front to back, in the flute length of reamers. Bevel: An unrelieved angular surface of revolution (not to be confused with chamfer). Body: The fluted full diameter portion of a reamer, inclusive of the chamfer, starting taper, and bevel. Chamfer: The angular cutting portion at the entering end of a reamer (see also Secondary Chamfer).
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 836
REAMERS Vertical Adjustment of Tooth-rest for Grinding Clearance on Reamers Hand Reamer for Steel. Cutting Clearance Land 0.006 inch Wide
Size of Reamer 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
1 11⁄8 11⁄4 13⁄8 11⁄2 15⁄8 13⁄4 17⁄8 2 21⁄8 21⁄4 23⁄8 21⁄2 25⁄8 23⁄4 27⁄8 3 31⁄8 31⁄4 33⁄8 31⁄2 35⁄8 33⁄4 37⁄8 4 41⁄8 41⁄4 43⁄8 41⁄2 45⁄8 43⁄4 47⁄8 5
Hand Reamer for Cast Iron and Bronze. Cutting Clearance Land 0.025 inch Wide
Chucking Reamer for Cast Iron and Bronze. Cutting Clearance Land 0.025 inch Wide
For Cutting Clearance
For Second Clearance
For Cutting Clearance
For Second Clearance
For Cutting Clearance
For Second Clearance
0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012 0.012
0.052 0.062 0.072 0.082 0.092 0.102 0.112 0.122 0.132 0.142 0.152 0.162 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172 0.172
0.032 0.032 0.035 0.040 0.040 0.040 0.045 0.045 0.048 0.050 0.052 0.056 0.056 0.059 0.063 0.063 0.065 0.065 0.065 0.070 0.072 0.075 0.078 0.081 0.084 0.087 0.090 0.093 0.096 0.096 0.096 0.096 0.100 0.100 0.104 0.106 0.110
0.072 0.072 0.095 0.120 0.120 0.120 0.145 0.145 0.168 0.170 0.192 0.196 0.216 0.219 0.223 0.223 0.225 0.225 0.225 0.230 0.232 0.235 0.238 0.241 0.244 0.247 0.250 0.253 0.256 0.256 0.256 0.256 0.260 0.260 0.264 0.266 0.270
0.040 0.040 0.040 0.045 0.045 0.045 0.050 0.050 0.055 0.060 0.060 0.060 0.064 0.064 0.064 0.068 0.072 0.075 0.077 0.080 0.080 0.083 0.083 0.087 0.090 0.093 0.097 0.100 0.104 0.104 0.106 0.108 0.108 0.110 0.114 0.116 0.118
0.080 0.090 0.100 0.125 0.125 0.125 0.160 0.160 0.175 0.200 0.200 0.200 0.224 0.224 0.224 0.228 0.232 0.235 0.237 0.240 0.240 0.240 0.243 0.247 0.250 0.253 0.257 0.260 0.264 0.264 0.266 0.268 0.268 0.270 0.274 0.276 0.278
Rose Chucking Reamers for Steel For Cutting Clearance on Angular Edge at End 0.080 0.090 0.100 0.125 0.125 0.125 0.160 0.175 0.175 0.200 0.200 0.200 0.225 0.225 0.225 0.230 0.230 0.235 0.240 0.240 0.240 0.240 0.245 0.245 0.250 0.250 0.255 0.255 0.260 0.260 0.265 0.265 0.265 0.270 0.275 0.275 0.275
Chamfer Angle: The angle between the axis and the cutting edge of the chamfer measured in an axial plane at the cutting edge. Chamfer Length: The length of the chamfer measured parallel to the axis at the cutting edge. Chamfer Relief Angle: See under Relief. Chamfer Relief: See under Relief. Chip Breakers: Notches or grooves in the cutting edges of some taper reamers designed. to break the continuity of the chips. Circular Land: See preferred term Margin.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition REAMERS
837
Illustration of Terms Applying to Reamers
Machine Reamer
Hand Reamer
Hand Reamer, Pilot and Guide
Chucking Reamer, Straight and Taper Shank
Clearance: The space created by the relief behind the cutting edge or margin of a reamer. Core: The central portion of a reamer below the flutes which joins the lands. Core Diameter: The diameter at a given point along the axis of the largest circle which does not project into the flutes. Cutter Sweep: The section removed by the milling cutter or grinding wheel in entering or leaving a flute. Cutting Edge: The leading edge of the relieved land in the direction of rotation for cutting. Cutting Face: The leading side of the relieved land in the direction of rotation for cutting on which the chip impinges. External Center: The pointed end of a reamer. The included angle varies with manufacturing practice. Flutes: Longitudinal channels formed in the body of the reamer to provide cutting edges, permit passage of chips, and allow cutting fluid to reach the cutting edges. Angular Flute: A flute which forms a cutting face lying in a plane intersecting the reamer axis at an angle. It is unlike a helical flute in that it forms a cutting face which lies in a single plane. Helical Flute: Sometimes called spiral flute, a flute which is formed in a helical path around the axis of a reamer. Spiral flute: 1) On a taper reamer, a flute of constant lead; or, 2) in reference to a straight reamer, see preferred term helical flute. Straight Flute: A flute which forms a cutting edge lying in an axial plane. Flute Length: The length of the flutes not including the cutter sweep.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 838
REAMERS
Guide: A cylindrical portion following the flutes of a reamer to maintain alignment. Heel: The trailing edge of the land in the direction of rotation for cutting. Helix Angle: The angle which a helical cutting edge at a given point makes with an axial plane through the same point. Hook: A concave condition of a cutting face. The rake of a hooked cutting face must be determined at a given point. Internal Center: A 60 degree countersink with clearance at the bottom, in one or both ends of a tool, which establishes the tool axis. Irregular Spacing: A deliberate variation from uniform spacing of the reamer cutting edges. Land: The section of the reamer between adjacent flutes. Land Width: The distance between the leading edge of the land and the heel measured at a right angle to the leading edge. Lead of Flute: The axial advance of a helical or spiral cutting edge in one turn around the reamer axis. Length: The dimension of any reamer element measured parallel to the reamer axis. Limits: The maximum and minimum values designated for a specific element. Margin: The unrelieved part of the periphery of the land adjacent to the cutting edge. Margin Width: The distance between the cutting edge and the primary relief measured at a right angle to the cutting edge. Neck: The section of reduced diameter connecting shank to body, or connecting other portions of the reamer. Nominal Size: The designated basic size of a reamer overall length–the extreme length of the complete reamer from end to end, but not including external centers or expansion screws. Periphery: The outside circumference of a reamer. Pilot: A cylindrical portion preceding the entering end of the reamer body to maintain alignment. Rake: The angular relationship between the cutting face, or a tangent to the cutting face at a given point and a given reference plane or line. Axial Rake: Applies to angular (not helical or spiral) cutting faces. It is the angle between a plane containing the cutting face, or tangent to the cutting face at a given point, and the reamer axis. Helical Rake: Applies only to helical and spiral cutting faces (not angular). It is the angle between a plane, tangent to the cutting face at a given point on the cutting edge, and the reamer axis. Negative Rake: Describes a cutting face in rotation whose cutting edge lags the surface of the cutting face. Positive Rake: Describes a cutting face in rotation whose cutting edge leads the surface of the cutting face. Radial Rake Angle: The angle in a transverse plane between a straight cutting face and a radial line passing through the cutting edge. Relief: The result of the removal of tool material behind or adjacent to the cutting edge to provide clearance and prevent rubbing (heel drag). Axial Relief: The relief measured in the axial direction between a plane perpendicular to the axis and the relieved surface. It can be measured by the amount of indicator drop at a given radius in a given amount of angular rotation. Cam Relief : The relief from the cutting edge to the heel of the land produced by a cam action. Chamfer Relief Angle: The axial relief angle at the outer corner of the chamfer. It is measured by projection into a plane tangent to the periphery at the outer corner of the chamfer. Chamfer Relief: The axial relief on the chamfer of the reamer. Eccentric Relief: A convex relieved surface behind the cutting edge.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition REAMERS
839
Flat Relief: A relieved surface behind the cutting edge which is essentially flat. Radial Relief: Relief in a radial direction measured in the plane of rotation. It can be measured by the amount of indicator drop at a given radius in a given amount of angular rotation. Primary Relief: The relief immediately behind the cutting edge or margin. Properly called relief. Secondary Relief: An additional relief behind the primary relief. Relief Angle: The angle, measured in a transverse plane, between the relieved surface and a plane tangent to the periphery at the cutting edge. Secondary Chamfer: A slight relieved chamfer adjacent to and following the initial chamfer on a reamer. Shank: The portion of the reamer by which it is held and driven. Squared Shank: A cylindrical shank having a driving square on the back end. Starting Radius: A relieved radius at the entering end of a reamer in place of a chamfer. Starting Taper: A slight relieved taper on the front end of a reamer. Straight Shank: A cylindrical shank. Tang: The flatted end of a taper shank which fits a slot in the socket. Taper per Foot: The difference in diameter between two points 12 in. apart measured along the axis. Taper Shank: A shank made to fit a specific (conical) taper socket. Direction of Rotation and Helix.—The terms “right hand” and “left hand” are used to describe both direction of rotation and direction of flute helix or reamers. Hand of Rotation (or Hand of Cut): Right-hand Rotation (or Right-hand Cut): W h e n viewed from the cutting end, the reamer must revolve counterclockwise to cut Left-hand Rotation (or Left-hand Cut): When viewed from the cutting end, the reamer must revolve clockwise to cut Hand of Flute Helix: Right-hand Helix: When the flutes twist away from the observer in a clockwise direction when viewed from either end of the reamer. Left-hand helix: When the flutes twist away from the observer in a counterclockwise direction when viewed from either end of the reamer. The standard reamers on the tables that follow are all right-hand rotation.
;; ; ; ;;
Dimensions of Centers for Reamers and Arbors
A
B 60
C
D
Arbor. Dia. A 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16
Large Center Dia. B 1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32
Drill No. C 55 52 48 43 39 33 30 29
Hole Depth D 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32
Arbor Dia. A 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
1 11⁄8 11⁄4 13⁄8 11⁄2 … 15⁄8 13⁄4 17⁄8 2 21⁄8 21⁄4 23⁄8
Large Center Dia. B 3⁄ 8 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2 33⁄ 64 17⁄ 32 35⁄ 64 9⁄ 16
Drill No. C 25 20 17 12 8 5 3 2 1
Hole Depth D 7⁄ 16 1⁄ 2 17⁄ 32 9⁄ 16 19⁄ 32 5⁄ 8 21⁄ 32 21⁄ 32 11⁄ 16
Arbor Dia. A 21⁄2 25⁄8 23⁄4 27⁄8 3 31⁄8 31⁄4 33⁄8 31⁄2
…
Letter
…
35⁄8
37⁄ 64 19⁄ 32 39⁄ 64 5⁄ 8 41⁄ 64 21⁄ 32 43⁄ 64
A
23⁄ 32 23⁄ 32 3⁄ 4 3⁄ 4 25⁄ 32 13⁄ 16 27⁄ 32
33⁄4
B C E F G H
37⁄8 4 41⁄4 41⁄2 43⁄4 5
Large Center Dia. B 11⁄ 16 45⁄ 64 23⁄ 32 47⁄ 64 3⁄ 4 49⁄ 64 25⁄ 32 51⁄ 64 13⁄ 16 53⁄ 64 27⁄ 32 55⁄ 64 7⁄ 8 29⁄ 32 15⁄ 16 31⁄ 32
1
Copyright 2004, Industrial Press, Inc., New York, NY
Drill No. C J
Hole Depth D 27⁄ 32
K
7⁄ 8 29⁄ 32 29⁄ 32 15⁄ 16 31⁄ 32 31⁄ 32
L M N N O O
1
P
1
Q
11⁄16
R
11⁄16
R
11⁄16
S
11⁄8
T
11⁄8
V
13⁄16
W
11⁄4
X
11⁄4
Machinery's Handbook 27th Edition 840
REAMERS Straight Shank Center Reamers and Machine Countersinks ANSI B94.2-1983 (R1988) D
D S
S A
A
Center Reamers (Short Countersinks) Dia. of Cut
Approx. Length Overall, A
Length of Shank, S
Machine Countersinks
Dia. of Shank, D
Dia. of Cut
Approx. Length Overall, A
Length of Shank, S
Dia. of Shank, D
1⁄ 4
11⁄2
3⁄ 4
3⁄ 16
1⁄ 2
37⁄8
21⁄4
1⁄ 2
3⁄ 8
13⁄4
7⁄ 8
1⁄ 4
5⁄ 8
4
21⁄4
1⁄ 2
1⁄ 2
2
1
3⁄ 8
3⁄ 4
41⁄8
21⁄4
1⁄ 2
5⁄ 8
21⁄4
1
3⁄ 8
7⁄ 8
41⁄4
21⁄4
1⁄ 2
3⁄ 4
25⁄8
11⁄4
1⁄ 2
1
43⁄8
21⁄4
1⁄ 2
All dimensions are given in inches. Material is high-speed steel. Reamers and countersinks have 3 or 4 flutes. Center reamers are standard with 60, 82, 90, or 100 degrees included angle. Machine countersinks are standard with either 60 or 82 degrees included angle. Tolerances: On overall length A, the tolerance is ±1⁄8 inch for center reamers in a size range of from 1⁄ to 3⁄ inch, incl., and machine countersinks in a size range of from 1⁄ to 5⁄ inch. incl.; ± 3⁄ inch for 4 8 2 8 16 center reamers, 1⁄2 to 3⁄4 inch, incl.; and machine countersinks, 3⁄4 to 1 inch, incl. On shank diameter D, the tolerance is −0.0005 to −0.002 inch. On shank length S, the tolerance is ±1⁄16 inch.
Reamer Difficulties.—Certain frequently occurring problems in reaming require remedial measures. These difficulties include the production of oversize holes, bellmouth holes, and holes with a poor finish. The following is taken from suggestions for correction of these difficulties by the National Twist Drill and Tool Co. and Winter Brothers Co.* Oversize Holes: The cutting of a hole oversize from the start of the reaming operations usually indicates a mechanical defect in the setup or reamer. Thus, the wrong reamer for the workpiece material may have been used or there may be inadequate workpiece support, inadequate or worn guide bushings, or misalignment of the spindles, bushings, or workpiece or runout of the spindle or reamer holder. The reamer itself may be defective due to chamfer runout or runout of the cutting end due to a bent or nonconcentric shank. When reamers gradually start to cut oversize, it is due to pickup or galling, principally on the reamer margins. This condition is partly due to the workpiece material. Mild steels, certain cast irons, and some aluminum alloys are particularly troublesome in this respect. Corrective measures include reducing the reamer margin widths to about 0.005 to 0.010 inch, use of hard case surface treatments on high-speed-steel reamers, either alone or in combination with black oxide treatments, and the use of a high-grade finish on the reamer faces, margins, and chamfer relief surfaces. Bellmouth Holes: The cutting of a hole that becomes oversize at the entry end with the oversize decreasing gradually along its length always reflects misalignment of the cutting portion of the reamer with respect to the hole. The obvious solution is to provide improved guiding of the reamer by the use of accurate bushings and pilot surfaces. If this solution is not feasible, and the reamer is cutting in a vertical position, a flexible element may be employed to hold the reamer in such a way that it has both radial and axial float, with the hope that the reamer will follow the original hole and prevent the bellmouth condition. In horizontal setups where the reamer is held fixed and the workpiece rotated, any misalignment exerts a sideways force on the reamer as it is fed to depth, resulting in the forma* “Some Aspects of Reamer Design and Operation,” Metal Cuttings, April 1963.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition REAMERS
841
tion of a tapered hole. This type of bellmouthing can frequently be reduced by shortening the bearing length of the cutting portion of the reamer. One way to do this is to reduce the reamer diameter by 0.010 to 0.030 inch, depending on size and length, behind a short fulldiameter section, 1⁄8 to 1⁄2 inch long according to length and size, following the chamfer. The second method is to grind a high back taper, 0.008 to 0.015 inch per inch, behind the short full-diameter section. Either of these modifications reduces the length of the reamer tooth that can cause the bellmouth condition. Poor Finish: The most obvious step toward producing a good finish is to reduce the reamer feed per revolution. Feeds as low as 0.0002 to 0.0005 inch per tooth have been used successfully. However, reamer life will be better if the maximum feasible feed is used. The minimum practical amount of reaming stock allowance will often improve finish by reducing the volume of chips and the resulting heat generated on the cutting portion of the chamfer. Too little reamer stock, however, can be troublesome in that the reamer teeth may not cut freely but will deflect or push the work material out of the way. When this happens, excessive heat, poor finish, and rapid reamer wear can occur. Because of their superior abrasion resistance, carbide reamers are often used when fine finishes are required. When properly conditioned, carbide reamers can produce a large number of good-quality holes. Careful honing of the carbide reamer edges is very important. American National Standard Fluted Taper Shank Chucking Reamers— Straight and Helical Flutes, Fractional Sizes ANSI B94.2-1983 (R1988)
No. of Morse Taper Shanka
No. of Flutes
21⁄2
2
8 to 10
25⁄8
2
8 to 10
10
25⁄8
2
8 to 10
10
25⁄8
3
8 to 10
10
25⁄8
3
8 to 10
Length Overall A
Flute Length B
No. of Morse Taper Shanka
No. of Flutes
Reamer Dia.
1⁄ 4
6
11⁄2
1
4 to 6
27⁄ 32
91⁄2
5⁄ 16
6
11⁄2
1
4 to 6
7⁄ 8
10
3⁄ 8
7
13⁄4
1
4 to 6
29⁄ 32
7
13⁄4
6 to 8
15⁄ 16 31⁄ 32
Reamer Dia.
7⁄ 16
1
Length Overall A
Flute Length B
1⁄ 2
8
2
1
6 to 8
17⁄ 32
8
2
1
6 to 8
1
101⁄2
23⁄4
3
8 to 12
9⁄ 16
8
2
1
6 to 8
11⁄16
101⁄2
23⁄4
3
8 to 12
19⁄ 32
8
2
1
6 to 8
11⁄8
11
27⁄8
3
8 to 12
5⁄ 8
9
21⁄4
2
6 to 8
13⁄16
11
27⁄8
3
8 to 12
21⁄ 32
9
21⁄4
2
6 to 8
1 1⁄4
11 1⁄2
3
4
8 to 12
11⁄ 16
9
21⁄4
2
6 to 8
15⁄16
111⁄2
3
4
8 to 12
23⁄ 32
9
21⁄4
2
6 to 8
13⁄8
12
31⁄4
4
10 to 12
3⁄ 4
91⁄2
21⁄2
2
6 to 8
17⁄16
12
31⁄4
4
10 to 12
25⁄ 32
91⁄2
21⁄2
2
8 to 10
11⁄2
121⁄2
31⁄2
4
10 to 12
13⁄ 16
91⁄2
21⁄2
2
8 to 10
…
…
…
…
…
a American National Standard self-holding tapers (see Table 7a on page 933.)
All dimensions are given in inches. Material is high-speed steel. Helical flute reamers with right-hand helical flutes are standard. Tolerances: On reamer diameter, 1⁄4-inch size, +.0001 to +.0004 inch; over 1⁄4- to 1-inch size, + .0001 to +.0005 inch; over 1-inch size, +.0002 to +.0006 inch. On length overall A and flute length B, 1⁄ - to 1-inch size, incl., ±1⁄ inch; 11⁄ -to 11⁄ -inch size, incl., 3⁄ inch. 4 16 16 2 32
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 842
REAMERS Expansion Chucking Reamers—Straight and Taper Shanks ANSI B94.2-1983 (R1988) D
B A Dia of Reamer 3⁄ 8
Length, A
Flute Length,B
7
3⁄ 4
13⁄ 32
7
3⁄ 4
7⁄ 16
7
7⁄ 8
15⁄ 32
7
7⁄ 8
1⁄ 2
8
17⁄ 32
Shank Dia., D Max.
Min.
Dia.of Reamer
Length, A
Shank Dia.,D
Flute Length,B
Max.
Min.
101⁄2
15⁄8
0.8745
0.8730
0.3095
13⁄32
0.3105
0.3095
11⁄8
11
13⁄4
0.8745
0.8730
0.3730
0.3720
15⁄32
11
13⁄4
0.8745
0.8730
0.3730
0.3720
13⁄16
11
13⁄4
0.9995
0.9980
1
0.4355
0.4345
17⁄32
11
13⁄4
0.9995
0.9980
8
1
0.4355
0.4345
11⁄4
111⁄2
17⁄8
0.9995
0.9980
9⁄ 16
8
11⁄8
0.4355
0.4345
15⁄16
111⁄2
17⁄8
0.9995
0.9980
19⁄ 32
8
11⁄8
0.4355
0.4345
13⁄8
12
2
0.9995
0.9980
5⁄ 8
9
11⁄4
0.5620
0.5605
17⁄16
12
2
1.2495
1.2480
21⁄ 32
9
11⁄4
0.5620
0.5605
11⁄2
121⁄2
21⁄8
1.2495
1.2480
11⁄ 16
9
11⁄4
0.5620
0.5605
19⁄16a
121⁄2
21⁄8
1.2495
1.2480
23⁄ 32
9
11⁄4
0.5620
0.5605
15⁄8
13
21⁄4
1.2495
1.2480
3⁄ 4
91⁄2
13⁄8
0.6245
0.6230
111⁄16a
13
21⁄4
1.2495
1.2480
25⁄ 32
91⁄2
13⁄8
0.6245
0.6230
13⁄4
131⁄2
23⁄8
1.2495
1.2480
13⁄ 16
91⁄2
13⁄8
0.6245
0.6230
113⁄16a
131⁄2
23⁄8
1.4995
1.4980
27⁄ 32
91⁄2
13⁄8
0.6245
0.6230
17⁄8
14
21⁄2
1.4995
1.4980
0.7480
115⁄16a
14
21⁄2
1.4995
1.4980
1.4995
1.4980
7⁄ 8
0.3105
10
11⁄2
29⁄ 32
10
11⁄2
0.7495
0.7480
2
14
21⁄2
15⁄ 16
10
11⁄2
0.7495
0.7480
21⁄8b
141⁄2
23⁄4
…
…
31⁄ 32
10
11⁄2
0.7495
0.7480
21⁄4b
141⁄2
23⁄4
…
…
1
101⁄2
15⁄8
0.8745
0.8730
23⁄8b
15
3
…
…
11⁄32
101⁄2
15⁄8
0.8745
0.8730
21⁄2b
15
3
…
…
11⁄16
101⁄2
15⁄8
0.8745
0.8730
…
…
…
…
…
0.7495
a Straight shank only. b Taper shank only.
All dimensions in inches. Material is high-speed steel. The number of flutes is as follows: 3⁄8- to 15⁄32inch sizes, 4 to 6; 1⁄2- to 31⁄32-inch sizes, 6 to 8; 1- to 111⁄16-inch sizes, 8 to 10; 13⁄4- to 115⁄16-inch sizes, 8 to 12; 2 - to 21⁄4-inch sizes, 10 to 12; 23⁄8- and 21⁄2-inch sizes, 10 to 14. The expansion feature of these reamers provides a means of adjustment that is important in reaming holes to close tolerances. When worn undersize, they may be expanded and reground to the original size. Tolerances: On reamer diameter, 8⁄8- to 1-inch sizes, incl., +0.0001 to +0.0005 inch; over 1-inch size, + 0.0002 to + 0.0006 inch. On length A and flute length B, 3⁄8- to 1-inch sizes, incl., ±1⁄16 inch; 11⁄32to 2-inch sizes, incl., ±3⁄32 inch; over 2-inch sizes, ±1⁄8 inch. Taper is Morse taper: No. 1 for sizes 3⁄8 to 19⁄32 inch, incl.; No. 2 for sizes 5⁄8 to 29⁄32 incl.; No. 3 for sizes 15⁄ to 17⁄ , incl.; No. 4 for sizes 11⁄ to 15⁄ , incl.; and No. 5 for sizes 13⁄ to 21⁄ , incl. For amount of taper, 16 32 4 8 4 2 see Table 1b on page 928.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition REAMERS
843
Hand Reamers—Straight and Helical Flutes ANSI B94.2-1983 (R1988)
Straight Flutes 1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2 17⁄ 32 9⁄ 16 19⁄ 32 5⁄ 8 21⁄ 32 11⁄ 16 23⁄ 32 3⁄ 4
… 7⁄ 8 … 1
11⁄8 11⁄4 13⁄8 11⁄2
Reamer Diameter Helical Decimal Flutes Equivalent … 0.1250 … 0.1562 … 0.1875 … 0.2188 1⁄ 0.2500 4 … 0.2812 5⁄ 0.3125 16 … 0.3438 3⁄ 0.3750 8 … 0.4062 7⁄ 0.4375 16 … 0.4688 1⁄ 0.5000 2 … 0.5312 9⁄ 0.5625 16 … 0.5938 5⁄ 0.6250 8 … 0.6562 11⁄ 0.6875 16 … 0.7188 3⁄ 0.7500 4 13⁄ 0.8125 16 7⁄ 0.8750 8 15⁄ 0.9375 16 1 1.0000 1.1250 11⁄8 1.2500 11⁄4 3 1.3750 1 ⁄8 1 1.5000 1 ⁄2
Length Overall A 3 31⁄4 31⁄2 33⁄4 4 41⁄4 41⁄2 43⁄4 5 51⁄4 51⁄2 53⁄4 6 61⁄4 61⁄2 63⁄4 7 73⁄8 73⁄4 81⁄8 83⁄8 91⁄8 93⁄4 101⁄4 107⁄8 115⁄8 121⁄4 125⁄8 13
Flute Length B
Square Length C
11⁄2 15⁄8 13⁄4 17⁄8
5⁄ 32 7⁄ 32 7⁄ 32 1⁄ 4 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 7⁄ 16 7⁄ 16 1⁄ 2 1⁄ 2 9⁄ 16 9⁄ 16 5⁄ 8 5⁄ 8 11⁄ 16 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
2 21⁄8 21⁄4 23⁄8 21⁄2 25⁄8 23⁄4 27⁄8 3 31⁄8 31⁄4 33⁄8 31⁄2 311⁄16 37⁄8 41⁄16 43⁄16 49⁄16 47⁄8 51⁄8 57⁄16 513⁄16 61⁄8 65⁄16 61⁄2
1 1 1 1 11⁄8
Size of Square 0.095 0.115 0.140 0.165 0.185 0.210 0.235 0.255 0.280 0.305 0.330 0.350 0.375 0.400 0.420 0.445 0.470 0.490 0.515 0.540 0.560 0.610 0.655 0.705 0.750 0.845 0.935 1.030 1.125
No. of Flutes 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 8 to 10 8 to 10 8 to 10 8 to 10 8 to 10 8 to 12 10 to 12 10 to 14
All dimensions in inches. Material is high-speed steel. The nominal shank diameter D is the same as the reamer diameter. Helical-flute hand reamers with left-hand helical flutes are standard. Reamers are tapered slightly on the end to facilitate proper starting. Tolerances: On diameter of reamer, up to 1⁄4-inch size, incl., + .0001 to + .0004 inch; over 1⁄4-to 1inch size, incl., +.0001 to + .0005 inch; over 1-inch size, +.0002 to +.0006 inch. On length overall A and flute length B, 1⁄8- to 1-inch size, incl., ± 1⁄16 inch; 11⁄8- to 11⁄2-inch size, incl., ±3⁄32 inch. On length of square C, 1⁄8- to 1 inch size, incl., ±1⁄32 inch; 11⁄8-to 11⁄2-inch size, incl., ±1⁄16 inch. On shank diameter D, 1⁄ - to 1-inch size, incl., −.001 to −.005 inch; 11⁄ - to 11⁄ -inch size, incl., −.0015 to − .006 inch. On size 8 8 2 of square, 1⁄8- to 1⁄2-inch size, incl., −.004 inch; 17⁄32- to 1-inch size, incl., −.006 inch; 11⁄8- to 11⁄2-inch size, incl., −.008 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 844
REAMERS American National Standard Expansion Hand Reamers—Straight and Helical Flutes, Squared Shank ANSI B94.2-1983 (R1988)
Reamer Dia. 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 7⁄ 8
Length Overall A Max Min 43⁄8 43⁄8 53⁄8 53⁄8 61⁄2 61⁄2 7
1
75⁄8 8 9 10
11⁄8 11⁄4
101⁄2 11
33⁄4 4 41⁄4 41⁄2 5 53⁄8 53⁄4 61⁄4 61⁄2 71⁄2 83⁄8 9 93⁄4
Flute Length Length of B Square Max Min C Straight Flutes 13⁄4 17⁄8 2 2 21⁄2 21⁄2 3 3 31⁄2 4 41⁄2 43⁄4 5
11⁄2 11⁄2 13⁄4 13⁄4 13⁄4 17⁄8 21⁄4 21⁄2 25⁄8 31⁄8 31⁄8 31⁄2 41⁄4
Shank Dia. D
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 7⁄ 8
1 1 1
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 7⁄ 8
1 11⁄8 11⁄4
Size of Square
Number of Flutes
0.185 0.235 0.280 0.330 0.375 0.420 0.470 0.515 0.560 0.655 0.750 0.845 0.935
6 to 8 6 to 8 6 to 9 6 to 9 6 to 9 6 to 9 6 to 9 6 to 10 6 to 10 8 to 10 8 to 10 8 to 12 8 to 12
0.185 0.235 0.280 0.330 0.375 0.470 0.560 0.655 0.750 0.935
6 to 8 6 to 8 6 to 9 6 to 9 6 to 9 6 to 9 6 to 10 6 to 10 6 to 10 8 to 12
Helical Flutes 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
1 11⁄4
43⁄8 43⁄8 61⁄8 61⁄4 61⁄2 8
37⁄8 4
85⁄8 93⁄8 101⁄4 113⁄8
61⁄2 71⁄2 83⁄8 93⁄4
41⁄4 41⁄2 5 6
13⁄4 13⁄4 2 2 21⁄2 3 31⁄2 4 41⁄2 5
11⁄2 11⁄2 13⁄4 13⁄4 13⁄4 21⁄4 25⁄8 31⁄8 31⁄8 41⁄4
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
1 1
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
1 11⁄4
All dimensions are given in inches. Material is carbon steel. Reamers with helical flutes that are left hand are standard. Expansion hand reamers are primarily designed for work where it is necessary to enlarge reamed holes by a few thousandths. The pilots and guides on these reamers are ground undersize for clearance. The maximum expansion on these reamers is as follows: .006 inch for the 1⁄4- to 7⁄16inch sizes. .010 inch for the 1⁄2- to 7⁄8-inch sizes and .012 inch for the 1- to 11⁄4-inch sizes. Tolerances: On length overall A and flute length B, ±1⁄16 inch for 1⁄4- to 1-inch sizes, ± 3⁄32 inch for 11⁄8to 11⁄4-inch sizes; on length of square C, ±1⁄32 inch for 1⁄4- to 1-inch sizes, ± 1⁄16 inch for 11⁄8-to 11⁄4-inch sizes; on shank diameter D −.001 to −.005 inch for 1⁄4- to 1-inch sizes, −.0015 to −.006 inch for 11⁄8- to 11⁄4-inch sizes; on size of square, −.004 inch for 1⁄4- to 1⁄2-inch sizes. −.006 inch for 9⁄16- to 1-inch sizes, and −.008 inch for 11⁄8- to 11⁄4-inch sizes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition REAMERS
845
Taper Shank Jobbers Reamers—Straight Flutes ANSI B94.2-1983 (R1988)
Reamer Diameter Fractional Dec. Equiv. 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
1 11⁄16 11⁄8 13⁄16 11⁄4 13⁄8 11⁄2
0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.6875 0.7500 0.8125 0.8750 0.9375 1.0000 1.0625 1.1250 1.1875 1.2500 1.3750 1.5000
Length Overall A 53⁄16 51⁄2 513⁄16 61⁄8 67⁄16 63⁄4 79⁄16 8 83⁄8 813⁄16 93⁄16 10 103⁄8 105⁄8 107⁄8 111⁄8 129⁄16 1213⁄16 131⁄8
Length of Flute B
No. of Morse Taper Shanka
No. of Flutes
1 1 1 1 1 1 2 2 2 2 2 3 3 3 3 3 4 4 4
6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 8 to 10 8 to 10 8 to 10 8 to 10 8 to 10 8 to 10 8 to 10 8 to 10 8 to 12 8 to 12 10 to 12 10 to 12
2 21⁄4 21⁄2 23⁄4 3 31⁄4 31⁄2 37⁄8 43⁄16 49⁄16 47⁄8 51⁄8 57⁄16 55⁄8 513⁄16 6 61⁄8 65⁄16 61⁄2
a American National Standard self-holding tapers (Table 7a on page 933.)
All dimensions in inches. Material is high-speed steel. Tolerances: On reamer diameter, 1⁄4-inch size, +.0001 to +.0004 inch; over 1⁄4- to 1-inch size, incl., +.0001 to +.0005 inch; over 1-inch size, +.0002 to +.0006 inch. On overall length A and length of flute B, 1⁄4- to 1-inch size, incl., ±1⁄16 inch; and 11⁄16- to 11⁄2-inch size, incl., ±3⁄32 inch.
American National Standard Driving Slots and Lugs for Shell Reamers or Shell Reamer Arbors ANSI B94.2-1983 (R1988)
Arbor Size No. 4 5 6 7 8 9
Fitting Reamer Sizes 3⁄ 4 13⁄ to 1 16 11⁄16 to 11⁄4 15⁄16 to 15⁄8 111⁄16 to 2 21⁄16 to 21⁄2
Driving Slot Width Depth W J 5⁄ 3⁄ 32 16 1⁄ 3⁄ 16 4 3⁄ 1⁄ 16 4 1⁄ 5⁄ 4 16 1⁄ 5⁄ 4 16 5⁄ 3⁄ 16 8
Lug on Arbor Width Depth L M 9⁄ 5⁄ 64 32 11⁄ 7⁄ 64 32 11⁄ 7⁄ 64 32 15⁄ 9⁄ 64 32 15⁄ 9⁄ 64 32 19⁄ 11⁄ 64 32
Reamer Hole Dia. at Large End 0.375 0.500 0.625 0.750 1.000 1.250
All dimension are given in inches. The hole in shell reamers has a taper of 1⁄8 inch per foot, with arbors tapered to correspond. Shell reamer arbor tapers are made to permit a driving fit with the reamer.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 846
REAMERS Straight Shank Chucking Reamers—Straight Flutes, Wire Gage Sizes ANSI B94.2-1983 (R1988)
Reamer Diameter Wire Gage
Inch
Lgth. Overall A
Shank Dia. D
Lgth. of Flute B
Max
Min
No. of Flutes
Reamer Diameter Wire Gage
Inch
Lgth. Overall A
Shank Dia. D
Lgth. of Flute B
Max
Min
No. of Flutes
60
.0400
21⁄2
1⁄ 2
.0390
.0380
4
49
.0730
3
3⁄ 4
.0660
.0650
4
59
.0410
21⁄2
1⁄ 2
.0390
.0380
4
48
.0760
3
3⁄ 4
.0720
.0710
4
58
.0420
21⁄2
1⁄ 2
.0390
.0380
4
47
.0785
3
3⁄ 4
.0720
.0710
4
57
.0430
21⁄2
1⁄ 2
.0390
.0380
4
46
.0810
3
3⁄ 4
.0771
.0701
4
56
.0465
21⁄2
1⁄ 2
.0455
.0445
4
45
.0820
3
3⁄ 4
.0771
.0761
4
55
.0520
21⁄2
1⁄ 2
.0510
.0500
4
44
.0860
3
3⁄ 4
.0810
.0800
4
54
.0550
21⁄2
1⁄ 2
.0510
.0500
4
43
.0890
3
3⁄ 4
.0810
.0800
4
53
.0595
21⁄2
1⁄ 2
.0585
.0575
4
42
.0935
3
3⁄ 4
.0880
.0870
4
52
.0635
21⁄2
1⁄ 2
.0585
.0575
4
41
.0960
31⁄2
7⁄ 8
.0928
.0918
4 to 6
51
.0670
3
3⁄ 4
.0660
.0650
4
40
.0980
31⁄2
7⁄ 8
.0928
.0918
4 to 6
50
.0700
3
3⁄ 4
.0660
.0650
4
39
.0995
31⁄2
7⁄ 8
.0928
.0918
4 to 6
38
.1015
31⁄2
7⁄ 8
.0950
.0940
4 to 6
19
.1660
41⁄2
11⁄8
.1595
.1585
4 to 6
37
.1040
31⁄2
7⁄ 8
.0950
.0940
4 to 6
18
.1695
41⁄2
11⁄8
.1595
.1585
4 to 6
36
.1065
31⁄2
7⁄ 8
.1030
.1020
4 to 6
17
.1730
41⁄2
11⁄8
.1645
.1635
4 to 6
35
.1100
31⁄2
7⁄ 8
.1030
.1020
4 to 6
16
.1770
41⁄2
11⁄8
.1704
.1694
4 to 6
34
.1110
31⁄2
7⁄ 8
.1055
.1045
4 to 6
15
.1800
41⁄2
11⁄8
.1755
.1745
4 to 6
33
.1130
31⁄2
7⁄ 8
.1055
.1045
4 to 6
14
.1820
41⁄2
11⁄8
.1755
.1745
4 to 6
32
.1160
31⁄2
7⁄ 8
.1120
.1110
4 to 6
13
.1850
41⁄2
11⁄8
.1805
.1795
4 to 6
31
.1200
31⁄2
7⁄ 8
.1120
.1110
4 to 6
12
.1890
41⁄2
11⁄8
.1805
.1795
4 to 6
30
.1285
31⁄2
7⁄ 8
.1190
.1180
4 to 6
11
.1910
5
11⁄4
.1860
.1850
4 to 6
29
.1360
4
1
.1275
.1265
4 to 6
10
.1935
5
11⁄4
.1860
.1850
4 to 6
28
.1405
4
1
.1350
.1340
4 to 6
9
.1960
5
11⁄4
.1895
.1885
4 to 6
27
.1440
4
1
.1350
.1340
4 to 6
8
.1990
5
11⁄4
.1895
.1885
4 to 6
26
.1470
4
1
.1430
.1420
4 to 6
7
.2010
5
11⁄4
.1945
.1935
4 to 6
25
.1495
4
1
.1430
.1420
4 to 6
6
.2040
5
11⁄4
.1945
.1935
4 to 6
24
.1520
4
1
.1460
.1450
4 to 6
5
.2055
5
11⁄4
.2016
.2006
4 to 6
23
.1540
4
1
.1460
.1450
4 to 6
4
.2090
5
11⁄4
.2016
.2006
4 to 6
22
.1570
4
1
.1510
.1500
4 to 6
3
.2130
5
11⁄4
.2075
.2065
4 to 6
21
.1590
41⁄2
11⁄8
.1530
.1520
4 to 6
2
2210
6
11⁄2
.2173
.2163
4 to 6
20
.1610
41⁄2
11⁄8
.1530
.1520
4 to 6
1
.2280
6
11⁄2
.2173
.2163
4 to 6
All dimensions in inches. Material is high-speed steel. Tolerances: On diameter of reamer, plus .0001 to plus .0004 inch. On overall length A, plus or minus 1⁄16 inch. On length of flute B, plus or minus 1⁄16 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition REAMERS
847
Straight Shank Chucking Reamers—Straight Flutes, Letter Sizes ANSI B94.2-1983 (R1988)
Reamer Diameter Letter Inch A B C D E F G H I J K L M
Lgth. Overall A
Lgth. of Flute B
6 6 6 6 6 6 6 6 6 6 6 6 6
11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2
0.2340 0.2380 0.2420 0.2460 0.2500 0.2570 0.2610 0.2660 0.2720 0.2770 0.2810 0.2900 0.2950
Shank Dia. D Max Min 0.2265 0.2329 0.2329 0.2329 0.2405 0.2485 0.2485 0.2485 0.2485 0.2485 0.2485 0.2792 0.2792
.2255 .2319 .2319 .2319 .2395 .2475 .2475 .2475 .2475 .2475 .2475 .2782 .2782
No. of Flutes 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6
Reamer Diameter Letter Inch N O P Q R S T U V W X Y Z
Lgth. Overall A
Lgth. of Flute B
6 6 6 6 6 7 7 7 7 7 7 7 7
11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4
0.3020 0.3160 0.3230 0.3320 0.3390 0.3480 0.3580 0.3680 0.3770 0.3860 0.3970 0.4040 0.4130
Shank Dia. D Max Min 0.2792 0.2792 0.2792 0.2792 0.2792 0.3105 0.3105 0.3105 0.3105 0.3105 0.3105 0.3105 0.3730
0.2782 0.2782 0.2782 0.2782 0.2782 0.3095 0.3095 0.3095 0.3095 0.3095 0.3095 0.3095 0.3720
No. of Flutes 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 6 to 8
All dimensions in inches. Material is high-speed steel. Tolerances: On diameter of reamer, for sizes A to E, incl., plus .0001 to plus .0004 inch and for sizes F to Z, incl., plus .0001 to plus .0005 inch. On overall length A, plus or minus 1⁄16 inch. On length of flute B, plus or minus 1⁄16 inch.
Straight Shank Chucking Reamers— Straight Flutes, Decimal Sizes ANSI B94.2-1983 (R1988)
Lgth. Reamer Overall Dia. A 0.1240 0.1260 0.1865 0.1885 0.2490 0.2510 0.3115
31⁄2 31⁄2 41⁄2 41⁄2 6 6 6
Lgth. of Flute B 7⁄ 8 7⁄ 8 11⁄8 11⁄8 11⁄2 11⁄2 11⁄2
Shank Diameter D Max. 0.1190 0.1190 0.1805 0.1805 0.2405 0.2405 0.2792
Min. 0.1180 0.1180 0.1795 0.1795 0.2395 0.2395 0.2782
No. of Flutes
Lgth. Reamer Overall Dia. A
4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6
0.3135 0.3740 0.3760 0.4365 0.4385 0.4990 0.5010
6 7 7 7 7 8 8
Lgth. of Flute B 11⁄2 13⁄4 13⁄4 13⁄4 13⁄4 2 2
Shank Diameter D Max. 0.2792 0.3105 0.3105 0.3730 0.3730 0.4355 0.4355
Min. 0.2782 0.3095 0.3095 0.3720 0.3720 0.4345 0.4345
No. of Flutes 4 to 6 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8
All dimensions in inches. Material is high-speed steel. Tolerances: On diameter of reamer, for 0.124 to 0.249-inch sizes, plus .0001 to plus .0004 inch and for 0.251 to 0.501-inch sizes, plus .0001 to plus .0005 inch. On overall length A, plus or minus 1⁄16 inch. On length of flute B, plus or minus 1⁄16 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 848
REAMERS
American National Standard Straight Shank Rose Chucking and Chucking Reamers—Straight and Helical Flutes, Fractional Sizes ANSI B94.2-1983 (R1988)
Reamer Diameter Chucking Rose Chucking 3⁄ a … 64 1⁄ … 16 5⁄ … 64 3⁄ … 32 7⁄ … 64 1⁄ a 1⁄ 8 8 9⁄ … 64 5⁄ … 32 11⁄ … 64 3⁄ a 3⁄ 16 16 13⁄ … 64 7⁄ … 32 15⁄ … 64 1⁄ a 1⁄ 4 4 17⁄ … 64 9⁄ … 32 19⁄ … 64 5⁄ a 5⁄ 16 16 21⁄ … 64 11⁄ … 32 23⁄ … 64 3⁄ a 3⁄ 8 8 25⁄ … 64 13⁄ … 32 27⁄ … 64 7⁄ a 7⁄ 16 16 29⁄ … 64 15⁄ … 32 31⁄ … 64 1⁄ a 1⁄ 2 2 17⁄ … 32 9⁄ … 16 19⁄ … 32 5⁄ … 8 21⁄ … 32 11⁄ … 16 23⁄ … 32 3⁄ … 4 25⁄ … 32 13⁄ … 16 27⁄ … 32 7⁄ … 8 29⁄ … 32 15⁄ … 16 31⁄ … 32 1 … 1 … 1 ⁄16 … 11⁄8 … 13⁄16 … 11⁄4 … 15⁄16b … 13⁄8 … 17⁄16b 1 … 1 ⁄2
Length Overall A 21⁄2 21⁄2 3 3 31⁄2 31⁄2 4 4 41⁄2 41⁄2 5 5 6 6 6 6 6 6 6 6 7 7 7 7 7 7 7 7 8 8 8 8 8 9 9 9 9 91⁄2 91⁄2 91⁄2 91⁄2 10 10 10 10 101⁄2 101⁄2 11 11 111⁄2 111⁄2 12 12 121⁄2
Flute Length B 1⁄ 2 1⁄ 2 3⁄ 4 3⁄ 4 7⁄ 8 7⁄ 8
1 1 11⁄8 11⁄8 11⁄4 11⁄4 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 2 2 2 2 2 21⁄4 21⁄4 21⁄4 21⁄4 21⁄2 21⁄2 21⁄2 21⁄2 25⁄8 25⁄8 25⁄8 25⁄8 23⁄4 23⁄4 27⁄8 27⁄8 3 3 31⁄4 31⁄4 31⁄2
Shank Dia. D Max Min 0.0455 0.0445 0.0585 0.0575 0.0720 0.0710 0.0880 0.0870 0.1030 0.1020 0.1190 0.1180 0.1350 0.1340 0.1510 0.1500 0.1645 0.1635 0.1805 0.1795 0.1945 0.1935 0.2075 0.2065 0.2265 0.2255 0.2405 0.2395 0.2485 0.2475 0.2485 0.2475 0.2792 0.2782 0.2792 0.2782 0.2792 0.2782 0.2792 0.2782 0.3105 0.3095 0.3105 0.3095 0.3105 0.3095 0.3105 0.3095 0.3730 0.3720 0.3730 0.3720 0.3730 0.3720 0.3730 0.3720 0.4355 0.4345 0.4355 0.4345 0.4355 0.4345 0.4355 0.4345 0.4355 0.4345 0.5620 0.5605 0.5620 0.5605 0.5620 0.5605 0.5620 0.5605 0.6245 0.6230 0.6245 0.6230 0.6245 0.6230 0.6245 0.6230 0.7495 0.7480 0.7495 0.7480 0.7495 0.7480 0.7495 0.7480 0.8745 0.8730 0.8745 0.8730 0.8745 0.8730 0.9995 0.9980 0.9995 0.9980 0.9995 0.9980 0.9995 0.9980 1.2495 1.2480 1.2495 1.2480
a Reamer with straight flutes is standard only.
Copyright 2004, Industrial Press, Inc., New York, NY
No. of Flutes 4 4 4 4 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 6 to 8 8 to 10 8 to 10 8 to 10 8 to 10 8 to 10 8 to 10 8 to 10 8 to 12 8 to 12 8 to 12 8 to 12 8 to 12 10 to 12 10 to 12 10 to 12 10 to 12
Machinery's Handbook 27th Edition REAMERS
849
b Reamer with helical flutes is standard only.
All dimensions are given in inches. Material is high-speed steel. Chucking reamers are end cutting on the chamfer and the relief for the outside diameter is ground in back of the margin for the full length of land. Lands of rose chucking reamers are not relieved on the periphery but have a relatively large amount of back taper. Tolerances: On reamer diameter, up to 1⁄4-inch size, incl., + .0001 to + .0004 inch; over 1⁄4-to 1-inch size, incl., + .0001 to + .0005 inch; over 1-inch size, + .0002 to + .0006 inch. On length overall A and flute length B, up to 1-inch size, incl., ±1⁄16 inch; 11⁄16- to 11⁄2-inch size, incl., ±3⁄32 inch. Helical flutes are right- or left-hand helix, right-hand cut, except sizes 11⁄16 through 11⁄2 inches, which are right-hand helix only.
Shell Reamers—Straight and Helical Flutes ANSI B94.2-1983 (R1988)
Diameter of Reamer
Length Overall A
3⁄ 4 7⁄ 8 15⁄ a 16
1 11⁄16 11⁄8 13⁄16 11⁄4 15⁄16 13⁄8 17⁄16 11⁄2 19⁄16 15⁄8 111⁄16 13⁄4 113⁄16 17⁄8 115⁄16 2
21⁄4 21⁄2 21⁄2 21⁄2 23⁄4 23⁄4 23⁄4 23⁄4
11⁄2 13⁄4 13⁄4 13⁄4
3 3 3 3 3 3
21⁄4 21⁄4 21⁄4 21⁄4 21⁄4 21⁄4 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 23⁄4 23⁄4 23⁄4 23⁄4 23⁄4 23⁄4
31⁄2 31⁄2 31⁄2 31⁄2 31⁄2 31⁄2 33⁄4 33⁄4 33⁄4 33⁄4 33⁄4 33⁄4
21⁄16a 21⁄8 23⁄16a 21⁄4 23⁄8a 21⁄2a
Flute Length B
2 2 2 2
Hole Diameter Large End H
Fitting Arbor No.
Number of Flutes
0.375 0.500 0.500 0.500 0.625 0.625 0.625 0.625 0.750 0.750 0.750 0.750 0.750 0.750 1.000 1.000 1.000 1.000 1.000 1.000 1.250 1.250 1.250 1.250 1.250 1.250
4 5 5 5 6 6 6 6 7 7 7 7 7 7 8 8 8 8 8 8 9 9 9 9 9 9
8 to 10 8 to 10 8 to 10 8 to 10 8 to 12 8 to 12 8 to 12 8 to 12 8 to 12 8 to 12 8 to 12 10 to 14 10 to 14 10 to 14 10 to 14 12 to 14 12 to 14 12 to 14 12 to 14 12 to 14 12 to 16 12 to 16 12 to 16 12 to 16 14 to 16 14 to 16
a Helical flutes only.
All dimensions are given in inches. Material is high-speed steel. Helical flute shell reamers with left-hand helical flutes are standard. Shell reamers are designed as a sizing or finishing reamer and are held on an arbor provided with driving lugs. The holes in these reamers are ground with a taper of 1⁄ inch per foot. 8 Tolerances: On diameter of reamer, 3⁄4- to 1-inch size, incl., + .0001 to + .0005 inch; over 1-inch size, + .0002 to + .0006 inch. On length overall A and flute length B, 3⁄4- to 1-inch size, incl., ± 1⁄16 inch; 11⁄16- to 2-inch size, incl., ± 3⁄32 inch; 21⁄16- to 21⁄2-inch size, incl., ± 1⁄8 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 850
REAMERS American National Standard Arbors for Shell Reamers— Straight and Taper Shanks ANSI B94.2-1983 (R1988)
Arbor Size No. 4 5 6
Overall Length A 9 91⁄2 10
Approx. Length of Taper L
Reamer Size
Taper Shank No.a
21⁄4 21⁄2 23⁄4
3⁄ 4 13⁄ to 1 16 1 1 ⁄16 to 11⁄4
2 2 3
Straight Shank Dia. D 1⁄ 2 5⁄ 8 3⁄ 4
Arbor Size No. 7 8 9
Overall Length A
Approx. Length of Taper L
11 12 13
3 31⁄2 33⁄4
Reamer Size
Taper Shank No.a
Straight Shank Dia. D
15⁄16 to 15⁄8 111⁄16 to 2 21⁄16 to 21⁄2
3 4 4
7⁄ 8 11⁄8 3 1 ⁄8
a American National Standard self-holding tapers (see Table 7a on page 933.)
All dimensions are given in inches. These arbors are designed to fit standard shell reamers (see table). End which fits reamer has taper of 1⁄8 inch per foot.
Stub Screw Machine Reamers—Helical Flutes ANSI B94.2-1983 (R1988)
Series No.
Diameter Range
Length Length Dia. Overof of all Flute Shank A
B
Size of Hole
Flute No.
Series No.
D
H
1⁄ 2
1⁄ 8
1⁄ 16
4
12
4
13
Length Length Dia. Overof of all Flute Shank
Size of Hole
A
B
D
H
Flute No.
.3761- .407
21⁄2
11⁄4
1⁄ 2
3⁄ 16
6
.4071- .439
21⁄2
11⁄4
1⁄ 2
3⁄ 16
6
.4391- .470
21⁄2
11⁄4
1⁄ 2
3⁄ 16
6
11⁄4
1⁄ 2
3⁄ 16
6
Diameter Range
00
.0600-.066
13⁄4
0
.0661-.074
13⁄4
1⁄ 2
1⁄ 8
1⁄ 16
.0741-.084
13⁄4
1⁄ 2
1⁄ 8
1⁄ 16
2
.0841-.096
13⁄4
1⁄ 2
1⁄ 8
1⁄ 16
4
15
.4701- .505
21⁄2
3
.0961-.126
2
3⁄ 4
1⁄ 8
1⁄ 16
4
16
.5051- .567
3
11⁄2
5⁄ 8
1⁄ 4
6
4
.1261-.158
21⁄4
1
1⁄ 4
3⁄ 32
4
17
.5671- .630
3
11⁄2
5⁄ 8
1⁄ 4
6
5
.1581-.188
21⁄4
1
1⁄ 4
3⁄ 32
4
18
.6301- .692
3
11⁄2
5⁄ 8
1⁄ 4
6
6
.1881-.219
21⁄4
1
1⁄ 4
3⁄ 32
6
19
.6921- .755
3
11⁄2
3⁄ 4
5⁄ 16
8
7
.2191-.251
21⁄4
1
1⁄ 4
3⁄ 32
6
20
.7551- .817
3
11⁄2
3⁄ 4
5⁄ 16
8
8
.2511-.282
21⁄4
1
3⁄ 8
1⁄ 8
6
21
.8171- .880
3
11⁄2
3⁄ 4
5⁄ 16
8
9
.2821-.313
21⁄4
1
3⁄ 8
1⁄ 8
6
22
.8801- .942
3
11⁄2
3⁄ 4
5⁄ 16
8
10
.3131-.344
21⁄2
11⁄4
3⁄ 8
1⁄ 8
6
23
.9421-1.010
3
11⁄2
3⁄ 4
5⁄ 16
8
11
.3441-.376
21⁄2
11⁄4
3⁄ 8
1⁄ 8
6
…
…
…
…
…
…
…
1
4
14
All dimensions in inches. Material is high-speed steel. These reamers are standard with right-hand cut and left-hand helical flutes within the size ranges shown. Tolerances: On diameter of reamer, for sizes 00 to 7, incl., plus .0001 to plus .0004 inch and for sizes 8 to 23, incl., plus .0001 to plus .0005 inch. On overall length A, plus or minus 1⁄16 inch. On length of flute B, plus or minus 1⁄16 inch. On diameter of shank D, minus .0005 to minus .002 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition REAMERS
851
American National Standard Morse Taper Finishing Reamers ANSI B94.2-1983 (R1988)
Taper No.a 0
Small End Dia. (Ref.) 0.2503
Large End Dia. (Ref.) 0.3674
1
0.3674
2
0.5696
3 4 5
Taper No.a 0 1
Straight Flutes and Squared Shank Length Flute Square Overall Length Length A B C 33⁄4
21⁄4
0.5170
5
3
0.7444
6
31⁄2
0.7748
0.9881
71⁄4
41⁄4
1.0167
1.2893
81⁄2
51⁄4
61⁄4 93⁄4 Straight and Spiral Flutes and Taper Shank Small Large Length Flute End Dia. End Dia. Overall Length (Ref.) (Ref.) A B 0.2503 0.3674 511⁄32 21⁄4 5 3 0.3674 0.5170 6 ⁄16 1.4717
1.8005
5⁄ 16 7⁄ 16 5⁄ 8 7⁄ 8
1 11⁄8 Taper Shank No.a 0
Shank Dia. D
Square Size 0.235
5⁄ 16 7⁄ 16 5⁄ 8 7⁄ 8 11⁄8 11⁄2
0.330 0.470 0.655 0.845 1.125
Squared and Taper Shank Number of Flutes 4 to 6 incl.
1
6 to 8 incl.
2
0.5696
0.7444
73⁄8
31⁄2
2
6 to 8 incl.
3
0.7748
0.9881
87⁄8
41⁄4
3
8 to 10 incl.
4
1.0167
1.2893
107⁄8
51⁄4
4
8 to 10 incl.
5
1.4717
1.8005
131⁄8
61⁄4
5
10 to 12 incl.
a Morse. For amount of taper see Table 1b on page 928.
All dimension are given in inches. Material is high-speed steel. The chamfer on the cutting end of the reamer is optional. Squared shank reamers are standard with straight flutes. Tapered shank reamers are standard with straight or spiral flutes. Spiral flute reamers are standard with left-had spiral flutes. Tolerances: On overall length A and flute length B, in taper numbers 0 to 3, incl., ±1⁄16 inch, in taper numbers 4 and 5, ±3⁄32 inch. On length of square C, in taper numbers 0 to 3, incl., ±1⁄32 inch; in taper numbers 4 and 5, ±1⁄16 inch. On shank diameter D, − .0005 to − .002 inch. On size of square, in taper numbers 0 and 1, − .004 inch; in taper numbers 2 and 3, − .006 inch; in taper numbers 4 and 5, − .008 inch.
Center Reamers.—A “center reamer” is a reamer the teeth of which meet in a point. By their use small conical holes may be reamed in the ends of parts to be machined as on lathe centers. When large holes—usually cored—must be center-reamed, a large reamer is ordinarily used in which the teeth do not meet in a point, the reamer forming the frustum of a cone. Center reamers for such work are called “bull” or “pipe” center reamers. Bull Center Reamer: A conical reamer used for reaming the ends of large holes—usually cored—so that they will fit on a lathe center. The cutting part of the reamer is generally in the shape of a frustum of a cone. It is also known as a pipe center reamer.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 852
REAMERS Taper Pipe Reamers—Spiral Flutes ANSI B94.2-1983 (R1988)
Nom. Size 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4
1 11⁄4 11⁄2 2
Diameter Large Small End End 0.362 0.316 0.472 0.406 0.606 0.540 0.751 0.665 0.962 0.876 1.212 1.103 1.553 1.444 1.793 1.684 2.268 2.159
Length Overall A
Flute Length B
21⁄8 27⁄16 29⁄16 31⁄8 31⁄4 33⁄4 4
3⁄ 4 11⁄16 11⁄16 13⁄8 13⁄8 13⁄4 13⁄4 13⁄4 13⁄4
41⁄4 41⁄2
Square Length C
Shank Diaeter D 0.4375 0.5625 0.7000 0.6875 0.9063 1.1250 1.3125 1.5000 1.8750
3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 11⁄ 16 13⁄ 16 15⁄ 16
1 11⁄8
Size of Square 0.328 0.421 0.531 0.515 0.679 0.843 0.984 1.125 1.406
No. of Flutes 4 to 6 4 to 6 4 to 6 4 to 6 6 to 10 6 to 10 6 to 10 6 to 10 8 to 12
All dimensions are given in inches. These reamers are tapered3⁄4 inch per foot and are intended for reaming holes to be tapped with American National Standard Taper Pipe Thread taps. Material is high-speed steel. Reamers are standard with left-hand spiral flutes. Tolerances: On length overall A and flute length B, 1⁄8- to 3⁄4-inch size, incl., ±1⁄16 inch; 1- to 11⁄2-inch size, incl., ±3⁄32 inch; 2-inch size, ±1⁄8 inch. On length of square C, 1⁄8- to 3⁄4-inch size, incl., ±1⁄32 inch; 1to 2-inch size, incl., ±1⁄16 inch. On shank diameter D, 1⁄8-inch size, − .0015 inch; 1⁄4- to 1-inch size, incl., − .002 inch; 11⁄4- to 2-inch size, incl., − .003 inch. On size of square, 1⁄8-inch size, − .004 inch; 1⁄4- to 3⁄4inch size, incl., − .006 inch; 1- to 2-inch size, incl., − .008 inch.
B & S Taper Reamers—Straight and Spiral Flutes, Squared Shank Taper No.a 1 2 3 4 5 6 7 8 9 10
Dia., Small End 0.1974 0.2474 0.3099 0.3474 0.4474 0.4974 0.5974 0.7474 0.8974 1.0420
Dia., Large End 0.3176 0.3781 0.4510 0.5017 0.6145 0.6808 0.8011 0.9770 1.1530 1.3376
Overall Length
Square Length
43⁄4 51⁄8 51⁄2 57⁄8 63⁄8 67⁄8 71⁄2 81⁄8 87⁄8 93⁄4
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 13⁄ 16 7⁄ 8
1
Flute Length
Dia. of Shank
27⁄8 31⁄8 33⁄8 311⁄16 4 43⁄8 47⁄8 51⁄2 61⁄8 67⁄8
9⁄ 32 11⁄ 32 13⁄ 32 7⁄ 16 9⁄ 16 5⁄ 8 3⁄ 4 13⁄ 16
1 11⁄8
Size of Square 0.210 0.255 0.305 0.330 0.420 0.470 0.560 0.610 0.750 0.845
No. of Flutes 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 4 to 6 6 to 8 6 to 8 6 to 8 6 to 8
a For taper per foot, see Table 10 on page 936.
These reamers are no longer ANSI Standard. All dimensions are given in inches. Material is high-speed steel. The chamfer on the cutting end of the reamer is optional. All reamers are finishing reamers. Spiral flute reamers are standard with lefthand spiral flutes. (Tapered reamers, especially those with left-hand spirals, should not have circular lands because cutting must take place on the outer diameter of the tool.) B & S taper reamers are designed for use in reaming out Brown & Sharpe standard taper sockets. Tolerances: On length overall A and flute length B, taper nos. 1 to 7, incl., ±1⁄16 inch; taper nos. 8 to 10, incl., ±3⁄32 inch. On length of square C, taper nos. 1 to 9, incl., ±1⁄32 inch; taper no. 10, ±1⁄16 inch. On shank diameter D, − .0005 to − .002 inch. On size of square, taper nos. 1 to 3, incl., − .004 inch; taper nos. 4 to 9, incl., − .006 inch; taper no. 10, − .008 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition REAMERS
853
American National Standard Die-Maker's Reamers ANSI B94.2-1983 (R1988)
Letter Size AAA AA A B C D E F
Diameter Small Large End End 0.055 0.070 0.065 0.080 0.075 0.090 0.085 0.103 0.095 0.113 0.105 0.126 0.115 0.136 0.125 0.148
Length A
B
Letter Size
21⁄4 21⁄4 21⁄4 23⁄8 21⁄2 25⁄8 23⁄4 3
11⁄8 11⁄8 11⁄8 13⁄8 13⁄8 15⁄8 15⁄8 13⁄4
G H I J K L M N
Diameter Small Large End End 0.135 0.158 0.145 0.169 0.160 0.184 0.175 0.199 0.190 0.219 0.205 0.234 0.220 0.252 0.235 0.274
Length A
B
Letter Size
3 31⁄4 31⁄4 31⁄4 31⁄2 31⁄2 4 41⁄2
13⁄4 17⁄8 17⁄8 17⁄8 21⁄4 21⁄4 21⁄2 3
O P Q R S T U …
Diameter Small Large End End 0.250 0.296 0.275 0.327 0.300 0.358 0.335 0.397 0.370 0.435 0.405 0.473 0.440 0.511 … …
Length A
B
5 51⁄2 6 61⁄2 63⁄4 7 71⁄4 …
31⁄2 4 41⁄2 43⁄4 5 51⁄4 51⁄2 …
All dimensions in inches. Material is high-speed steel. These reamers are designed for use in diemaking, have a taper of 3⁄4 degree included angle or 0.013 inch per inch, and have 2 or 3 flutes. Reamers are standard with left-hand spiral flutes. Tip of reamer may have conical end. Tolerances: On length overall A and flute length B, ±1⁄16 inch.
Taper Pin Reamers — Straight and Left-Hand Spiral Flutes, Squared Shank; and Left-Hand High-Spiral Flutes, Round Shank ANSI B94.2-1983 (R1988)
No. of Taper Pin Reamer 8⁄0b 7⁄0 6⁄0 5⁄0 4⁄0 3⁄0 2⁄0 0 1 2 3 4 5 6 7 8 9 10
Diameter at Large End of Reamer (Ref.) 0.0514 0.0666 0.0806 0.0966 0.1142 0.1302 0.1462 0.1638 0.1798 0.2008 0.2294 0.2604 0.2994 0.3540 0.4220 0.5050 0.6066 0.7216
Diameter at Small End of Reamer (Ref.) 0.0351 0.0497 0.0611 0.0719 0.0869 0.1029 0.1137 0.1287 0.1447 0.1605 0.1813 0.2071 0.2409 0.2773 0.3297 0.3971 0.4805 0.5799
Overall Lengthof Reamer A
Length of Flute B
15⁄8 113⁄16 115⁄16 23⁄16 25⁄16 25⁄16 29⁄16 215⁄16 215⁄16 33⁄16 311⁄16 41⁄16 45⁄16 57⁄16 65⁄16 73⁄16 85⁄16 95⁄16
25⁄ 32 13⁄ 16 15⁄ 16 13⁄16 15⁄16 15⁄16 19⁄16 111⁄16 111⁄16 115⁄16 25⁄16 29⁄16 213⁄16 311⁄16 47⁄16 53⁄16 61⁄16 613⁄16
Length of Square Ca … 5⁄ 32 5⁄ 32 5⁄ 32 5⁄ 32 5⁄ 32 7⁄ 32 7⁄ 32 7⁄ 32 1⁄ 4 1⁄ 4 1⁄ 4 5⁄ 16 3⁄ 8 3⁄ 8 7⁄ 16 9⁄ 16 5⁄ 8
Diameter of Shank D
Size of Squarea
1⁄ 16 5⁄ 64 3⁄ 32 7⁄ 64 1⁄ 8 9⁄ 64 5⁄ 32 11⁄ 64 3⁄ 16 13⁄ 64 15⁄ 64 17⁄ 64 5⁄ 16 23⁄ 64 13⁄ 32 7⁄ 16 9⁄ 16 5⁄ 8
… 0.060 0.070 0.080 0.095 0.105 0.115 0.130 0.140 0.150 0.175 0.200 0.235 0.270 0.305 0.330 0.420 0.470
a Not applicable to high-spiral flute reamers. b Not applicable to straight and left-hand spiral fluted, squared shank reamers.
All dimensions in inches. Reamers have a taper of1⁄4 inch per foot and are made of high-speed steel. Straight flute reamers of carbon steel are also standard. The number of flutes is as follows; 3 or 4, for 7⁄0 to 4⁄0 sizes; 4 to 6, for 3⁄0 to 0 sizes; 5 or 6, for 1 to 5 sizes; 6 to 8, for 6 to 9 sizes; 7 or 8, for the 10 size in the case of straight- and spiral-flute reamers; and 2 or 3, for 8⁄0 to 8 sizes; 2 to 4, for the 9 and 10 sizes in the case of high-spiral flute reamers. Tolerances: On length overall A and flute length B, ±1⁄16 inch. On length of square C, ±1⁄32 inch. On shank diameter D, −.001 to −.005 inch for straight- and spiral-flute reamers and −.0005 to −.002 inch for high-spiral flute reamers. On size of square, −.004 inch for 7⁄0 to 7 sizes and −.006 inch for 8 to 10 sizes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 854
TWIST DRILLS
TWIST DRILLS AND COUNTERBORES Twist drills are rotary end-cutting tools having one or more cutting lips and one or more straight or helical flutes for the passage of chips and cutting fluids. Twist drills are made with straight or tapered shanks, but most have straight shanks. All but the smaller sizes are ground with “back taper,” reducing the diameter from the point toward the shank, to prevent binding in the hole when the drill is worn. Straight Shank Drills: Straight shank drills have cylindrical shanks which may be of the same or of a different diameter than the body diameter of the drill and may be made with or without driving flats, tang, or grooves. Taper Shank Drills: Taper shank drills are preferable to the straight shank type for drilling medium and large size holes. The taper on the shank conforms to one of the tapers in the American Standard (Morse) Series. American National Standard.—American National Standard B94.11M-1993 covers nomenclature, definitions, sizes and tolerances for High Speed Steel Straight and Taper Shank Drills and Combined Drills and Countersinks, Plain and Bell types. It covers both inch and metric sizes. Dimensional tables from the Standard will be found on the following pages. Definitions of Twist Drill Terms.—The following definitions are included in the Standard. Axis: The imaginary straight line which forms the longitudinal center of the drill. Back Taper: A slight decrease in diameter from point to back in the body of the drill. Body: The portion of the drill extending from the shank or neck to the outer corners of the cutting lips. Body Diameter Clearance: That portion of the land that has been cut away so it will not rub against the wall of the hole. Chisel Edge: The edge at the ends of the web that connects the cutting lips. Chisel Edge Angle: The angle included between the chisel edge and the cutting lip as viewed from the end of the drill. Clearance Diameter: The diameter over the cutaway portion of the drill lands. Drill Diameter: The diameter over the margins of the drill measured at the point. Flutes: Helical or straight grooves cut or formed in the body of the drill to provide cutting lips, to permit removal of chips, and to allow cutting fluid to reach the cutting lips. Helix Angle: The angle made by the leading edge of the land with a plane containing the axis of the drill. Land: The peripheral portion of the drill body between adjacent flutes. Land Width: The distance between the leading edge and the heel of the land measured at a right angle to the leading edge. Lips—Two Flute Drill: The cutting edges extending from the chisel edge to the periphery. Lips—Three or Four Flute Drill (Core Drill): The cutting edges extending from the bottom of the chamfer to the periphery. Lip Relief: The axial relief on the drill point. Lip Relief Angle: The axial relief angle at the outer corner of the lip. It is measured by projection into a plane tangent to the periphery at the outer corner of the lip. (Lip relief angle is usually measured across the margin of the twist drill.) Margin: The cylindrical portion of the land which is not cut away to provide clearance. Neck: The section of reduced diameter between the body and the shank of a drill. Overall Length: The length from the extreme end of the shank to the outer corners of the cutting lips. It does not include the conical shank end often used on straight shank drills, nor does it include the conical cutting point used on both straight and taper shank drills. (For core drills with an external center on the cutting end it is the same as for two-flute
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TWIST DRILLS
855
drills. For core drills with an internal center on the cutting end, the overall length is to the extreme ends of the tool.) Point: The cutting end of a drill made up of the ends of the lands, the web, and the lips. In form, it resembles a cone, but departs from a true cone to furnish clearance behind the cutting lips. Point Angle: The angle included between the lips projected upon a plane parallel to the drill axis and parallel to the cutting lips. Shank: The part of the drill by which it is held and driven. Tang: The flattened end of a taper shank, intended to fit into a driving slot in the socket. Tang Drive: Two opposite parallel driving flats on the end of a straight shank. Web: The central portion of the body that joins the end of the lands. The end of the web forms the chisel edge on a two-flute drill. Web Thickness: The thickness of the web at the point unless another specific location is indicated. Web Thinning: The operation of reducing the web thickness at the point to reduce drilling thrust. Point Angle
Neck Dia. Taper Shank Tang Straight Shank Axis
Neck Length
Lip Relief Angle Rake or Helix Angle
Straight Shank Shank Dia.
Shank Length
Shank Length
Drill Dia.
Clearance Dia. Body Dia. Clearance Chisel Edge Angle
Flutes Body Length Over-All Length
Flute Length
Flute Length
Margin Lip Web Chisel Edge
Land
ANSI Standard Twist Drill Nomenclature
Types of Drills.—Drills may be classified based on the type of shank, number of flutes or hand of cut. Straight Shank Drills: Those having cylindrical shanks which may be the same or different diameter than the body of the drill. The shank may be with or without driving flats, tang, grooves, or threads. Taper Shank Drills: Those having conical shanks suitable for direct fitting into tapered holes in machine spindles, driving sleeves, or sockets. Tapered shanks generally have a driving tang. Two-Flute Drills: The conventional type of drill used for originating holes. Three-Flute Drills (Core Drills): Drill commonly used for enlarging and finishing drilled, cast or punched holes. They will not produce original holes. Four-Flute Drills (Core Drills): Used interchangeably with three-flute drills. They are of similar construction except for the number of flutes. Right-Hand Cut: When viewed from the cutting point, the counterclockwise rotation of a drill in order to cut. Left-Hand Cut: When viewed from the cutting point, the clockwise rotation of a drill in order to cut. Teat Drill: The cutting edges of a teat drill are at right angles to the axis, and in the center there is a small teat of pyramid shape which leads the drill and holds it in position. This form is used for squaring the bottoms of holes made by ordinary twist drills or for drilling the entire hole, especially if it is not very deep and a square bottom is required. For instance, when drilling holes to form clearance spaces at the end of a keyseat, preparatory to cutting it out by planing or chipping, the teat drill is commonly used.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 856
TWIST DRILLS
Table 1. ANSI Straight Shank Twist Drills — Jobbers Length through 17.5 mm, Taper Length through 12.7 mm, and Screw Machine Length through 25.4 mm Diameter ANSI/ASME B94.11M-1993 Drill Diameter, Da Fraction No. or Ltr.
Jobbers Length
Equivalent mm
Decimal In.
mm
Screw Machine Length
Taper Length
Flute
Overall
Flute
Overall
Flute
F
L
F
L
F
Overall L
Inch
mm
Inch
mm
Inch
mm
Inch
mm
Inch
mm
Inch
mm
97
0.15
0.0059
0.150
1⁄ 16
1.6
3⁄ 4
19
…
…
…
…
…
…
…
…
96
0.16
0.0063
0.160
1⁄ 16
1.6
3⁄ 4
19
…
…
…
…
…
…
…
…
95
0.17
0.0067
0.170
1⁄ 16
1.6
3⁄ 4
19
…
…
…
…
…
…
…
…
94
0.18
0.0071
0.180
1⁄ 16
1.6
3⁄ 4
19
…
…
…
…
…
…
…
…
93
0.19
0.0075
0.190
1⁄ 16
1.6
3⁄ 4
19
…
…
…
…
…
…
…
…
92
0.20
0.0079
0.200
1⁄ 16
1.6
3⁄ 4
19
…
…
…
…
…
…
…
…
0.0083
0.211
5⁄ 64
2.0
3⁄ 4
19
…
…
…
…
…
…
…
…
0.0087
0.221
5⁄ 64
2.0
3⁄ 4
19
…
…
…
…
…
…
…
…
89
0.0091
0.231
5⁄ 64
2.0
3⁄ 4
19
…
…
…
…
…
…
…
…
88
0.0095
0.241
5⁄ 64
2.0
3⁄ 4
19
…
…
…
…
…
…
…
…
0.0098
0.250
5⁄ 64
2.0
3⁄ 4
19
…
…
…
…
…
…
…
…
0.0100
0.254
5⁄ 64
2.0
3⁄ 4
19
…
…
…
…
…
…
…
…
0.267
3⁄ 32
2.4
3⁄ 4
19
…
…
…
…
…
…
…
…
0.280
3⁄ 32
2.4
3⁄ 4
19
…
…
…
…
…
…
…
…
0.292
3⁄ 32
2.4
3⁄ 4
19
…
…
…
…
…
…
…
…
0.300
3⁄ 32
2.4
3⁄ 4
19
…
…
…
…
…
…
…
…
0.305
3⁄ 32
2.4
3⁄ 4
19
…
…
…
…
…
…
…
…
0.318
3⁄ 32
2.4
3⁄ 4
19
…
…
…
…
…
…
…
…
0.320
3⁄ 32
2.4
3⁄ 4
19
…
…
…
…
…
…
…
…
0.330
3⁄ 32
2.4
3⁄ 4
19
…
…
…
…
…
…
…
…
0.343
1⁄ 8
3
3⁄ 4
19
…
…
…
…
…
…
…
…
0.350
1⁄ 8
3
3⁄ 4
19
…
…
…
…
…
…
…
…
0.368
1⁄ 8
3
3⁄ 4
19
…
…
…
…
…
…
…
…
0.380
3⁄ 16
5
3⁄ 4
19
…
…
…
…
…
…
…
…
0.396
3⁄ 16
5
3⁄ 4
19
…
…
…
…
…
…
…
…
0.400
3⁄ 16
5
3⁄ 4
19
…
…
…
…
…
…
…
…
0.406
3⁄ 16
5
7⁄ 8
22
…
…
…
…
…
…
…
…
0.420
3⁄ 16
5
7⁄ 8
22
…
…
…
…
…
…
…
…
0.450
3⁄ 16
5
7⁄ 8
22
…
…
…
…
…
…
…
…
0.0180
0.457
3⁄ 16
5
7⁄ 8
22
…
…
…
…
…
…
…
…
0.48
0.0189
0.480
3⁄ 16
5
7⁄ 8
22
…
…
…
…
…
…
…
…
0.50
0.0197
0.500
3⁄ 16
5
7⁄ 8
22
…
…
…
…
…
…
…
…
76
0.0200
0.508
3⁄ 16
5
7⁄ 8
22
…
…
…
…
…
…
…
…
75
0.0210
0.533
1⁄ 4
6
1
25
…
…
…
…
…
…
…
…
0.0217
0.550
1⁄ 4
6
1
25
…
…
…
…
…
…
…
…
0.0225
0.572
1⁄ 4
6
1
25
…
…
…
…
…
…
…
…
0.0236
0.600
5⁄ 16
8
11⁄8
29
…
…
…
…
…
…
…
…
91 90
0.22
0.25 87 86 85
0.0105 0.28
84
0.0110 0.0115
0.30 83
0.0118 0.0120
82
0.0125 0.32
81
0.0126 0.0130
80
0.0135 0.35
79
0.0138 0.0145
0.38 1⁄ 64
0.0150 0.0156
0.40 78
0.0157 0.0160
0.42 0.45 77
0.55 74 0.60
0.0165 0.0177
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TWIST DRILLS
857
Table 1. (Continued) ANSI Straight Shank Twist Drills — Jobbers Length through 17.5 mm, Taper Length through 12.7 mm, and Screw Machine Length through 25.4 mm Diameter ANSI/ASME B94.11M-1993 Drill Diameter, Da Fraction No. or Ltr.
Jobbers Length
Equivalent Decimal In.
Screw Machine Length
Taper Length
Flute
Overall
Flute
Overall
Flute
F
L
F
L
F
Overall L
Inch
mm
Inch
mm
Inch
mm
Inch
mm
Inch
mm
Inch
mm
0.610
5⁄ 16
8
11⁄8
29
…
…
…
…
…
…
…
…
0.635
5⁄ 16
8
11⁄8
29
…
…
…
…
…
…
…
…
0.650
3⁄ 8
10
11⁄4
32
…
…
…
…
…
…
…
…
0.660
3⁄ 8
10
11⁄4
32
…
…
…
…
…
…
…
…
0.700
3⁄ 8
10
11⁄4
32
…
…
…
…
…
…
…
…
0.711
3⁄ 8
10
11⁄4
32
…
…
…
…
…
…
…
…
0.742
1⁄ 2
13
13⁄8
35
…
…
…
…
…
…
…
…
0.750
1⁄ 2
13
13⁄8
35
…
…
…
…
…
…
…
…
0.787
1⁄ 2
13
13⁄8
35
…
…
…
…
…
…
…
…
0.0312
0.792
1⁄ 2
13
13⁄8
35
…
…
…
…
…
…
…
…
0.0315
0.800
1⁄ 2
13
13⁄8
35
…
…
…
…
…
…
…
…
67
0.0320
0.813
1⁄ 2
13
13⁄8
35
…
…
…
…
…
…
…
…
66
0.0330
0.838
1⁄ 2
13
13⁄8
35
…
…
…
…
…
…
…
…
0.0335
0.850
5⁄ 8
16
11⁄2
38
…
…
…
…
…
…
…
…
0.0350
0.889
5⁄ 8
16
11⁄2
38
…
…
…
…
…
…
…
…
0.0354
0.899
5⁄ 8
16
11⁄2
38
…
…
…
…
…
…
…
…
64
0.0360
0.914
5⁄ 8
16
11⁄2
38
…
…
…
…
…
…
…
…
63
0.0370
0.940
5⁄ 8
16
11⁄2
38
…
…
…
…
…
…
…
…
0.0374
0.950
5⁄ 8
16
11⁄2
38
…
…
…
…
…
…
…
…
62
0.0380
0.965
5⁄ 8
16
11⁄2
38
…
…
…
…
…
…
…
…
61
0.0390
0.991
11⁄ 16
17
15⁄8
41
…
…
…
…
…
…
…
…
0.0394
1.000
11⁄ 16
17
15⁄8
41
11⁄8
29
21⁄4
57
1⁄ 2
13
13⁄8
35
60
0.0400
1.016
11⁄ 16
17
15⁄8
41
11⁄8
29
21⁄4
57
1⁄ 2
13
13⁄8
35
59
0.0410
1.041
11⁄ 16
17
15⁄8
41
11⁄8
29
21⁄4
57
1⁄ 2
13
13⁄8
35
0.0413
1.050
11⁄ 16
17
15⁄8
41
11⁄8
29
21⁄4
57
1⁄ 2
13
13⁄8
35
58
0.0420
1.067
11⁄ 16
17
15⁄8
41
11⁄8
29
21⁄4
57
1⁄ 2
13
13⁄8
35
57
0.0430
1.092
3⁄ 4
19
13⁄4
44
11⁄8
29
21⁄4
57
1⁄ 2
13
13⁄8
35
1.10
0.0433
1.100
3⁄ 4
19
13⁄4
44
11⁄8
29
21⁄4
57
1⁄ 2
13
13⁄8
35
1.15
0.0453
1.150
3⁄ 4
19
13⁄4
44
11⁄8
29
21⁄4
57
1⁄ 2
13
13⁄8
35
56
0.0465
1.181
3⁄ 4
19
13⁄4
44
11⁄8
29
21⁄4
57
1⁄ 2
13
13⁄8
35
3⁄ 64
0.0469
1.191
3⁄ 4
19
13⁄4
44
11⁄8
29
21⁄4
57
1⁄ 2
13
13⁄8
35
1.20
0.0472
1.200
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
1.25
0.0492
1.250
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
1.30
0.0512
1.300
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
0.0520
1.321
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
0.0531
1.350
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
0.0550
1.397
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
1.40
0.0551
1.400
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
1.45
0.0571
1.450
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
1.50
0.0591
1.500
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
0.0595
1.511
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
0.0610
1.550
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
0.0625
1.588
7⁄ 8
22
17⁄8
48
13⁄4
44
3
76
5⁄ 8
16
15⁄8
41
0.0630
1.600
7⁄ 8
22
17⁄8
48
2
51
33⁄4
95
11⁄ 16
17
111⁄16
43
0.0635
1.613
7⁄ 8
22
17⁄8
48
2
51
33⁄4
95
11⁄ 16
17
111⁄16
43
0.0650
1.650
1
25
2
51
2
51
33⁄4
95
11⁄ 16
17
111⁄16
43
mm
73
0.0240
72
0.0250 0.65
71
0.0256 0.0260
0.70 70
0.0276 0.0280
69
0.0292 0.75
68
0.0295 0.0310
1⁄ 32
0.80
0.85 65 0.90
0.95
1.00
1.05
55 1.35 54
53 1.55 1⁄ 16
1.60 52 1.65
mm
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 858
TWIST DRILLS
Table 1. (Continued) ANSI Straight Shank Twist Drills — Jobbers Length through 17.5 mm, Taper Length through 12.7 mm, and Screw Machine Length through 25.4 mm Diameter ANSI/ASME B94.11M-1993 Drill Diameter, Da Fraction No. or Ltr.
Jobbers Length
Equivalent mm 1.70
51
Decimal In. 0.0669 0.0670
1.75 50
0.0689 0.0700
1.80 1.85 49
0.0709 0.0728 0.0730
1.90 48
0.0748 0.0760
mm 1.700 1.702 1.750 1.778 1.800 1.850 1.854 1.900 1.930
Screw Machine Length
Taper Length
Flute
Overall
Flute
Overall
Flute
F
L
F
L
F
Inch
mm
Inch
mm
Inch
mm
Inch
mm
1
25
2
51
2
51
33⁄4
95
11⁄ 16
51
33⁄4
95
11⁄ 16
51
33⁄4
95
11⁄ 16
51
33⁄4
95
11⁄ 16
51
33⁄4
95
11⁄ 16
51
33⁄4
95
11⁄ 16
51
33⁄4
95
11⁄ 16
51
33⁄4
95
11⁄ 16
51
33⁄4
95
11⁄ 16
95
11⁄ 16
1 1 1 1 1 1 1 1
25 25 25 25 25 25 25 25
2 2 2 2 2 2 2 2
51 51 51 51 51 51 51 51
2 2 2 2 2 2 2 2
Inch
Overall L
mm
Inch
mm
17
111⁄16
43
17
111⁄16
43
17
111⁄16
43
17
111⁄16
43
17
111⁄16
43
17
111⁄16
43
17
111⁄16
43
17
111⁄16
43
17
111⁄16
43
17
111⁄16
43
0.0768
1.950
1
25
2
51
2
51
33⁄4
5⁄ 64
0.0781
1.984
1
25
2
51
2
51
33⁄4
95
11⁄ 16
17
111⁄16
43
47
0.0785
1.994
1
25
2
51
21⁄4
57
41⁄4
108
11⁄ 16
17
111⁄16
43
2.00
0.0787
2.000
1
25
2
51
21⁄4
57
41⁄4
108
11⁄ 16
17
111⁄16
43
2.05
0.0807
2.050
11⁄8
29
21⁄8
54
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
46
0.0810
2.057
11⁄8
29
21⁄8
54
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
45
0.0820
2.083
11⁄8
29
21⁄8
54
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
2.10
0.0827
2.100
11⁄8
29
21⁄8
54
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
2.15
0.0846
2.150
11⁄8
29
21⁄8
54
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
0.0860
2.184
11⁄8
29
21⁄8
54
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
2.20
0.0866
2.200
11⁄4
32
21⁄4
57
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
2.25
0.0886
2.250
11⁄4
32
21⁄4
57
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
0.0890
2.261
11⁄4
32
21⁄4
57
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
2.30
0.0906
2.300
11⁄4
32
21⁄4
57
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
2.35
0.0925
2.350
11⁄4
32
21⁄4
57
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
42
0.0935
2.375
11⁄4
32
21⁄4
57
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
3⁄ 32
0.0938
2.383
11⁄4
32
21⁄4
57
21⁄4
57
41⁄4
108
3⁄ 4
19
13⁄4
44
0.0945
2.400
13⁄8
35
23⁄8
60
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
0.0960
2.438
13⁄8
35
23⁄8
60
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
0.0965
2.450
13⁄8
35
23⁄8
60
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
0.0980
2.489
13⁄8
35
23⁄8
60
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
0.0984
2.500
13⁄8
35
23⁄8
60
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
39
0.0995
2.527
13⁄8
35
23⁄8
60
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
38
0.1015
2.578
17⁄16
37
21⁄2
64
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
0.1024
2.600
17⁄16
37
21⁄2
64
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
0.1040
2.642
17⁄16
37
21⁄2
64
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
0.1063
2.700
17⁄16
37
21⁄2
64
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
36
0.1065
2.705
17⁄16
37
21⁄2
64
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
7⁄ 64
0.1094
2.779
11⁄2
38
25⁄8
67
21⁄2
64
45⁄8
117
13⁄ 16
21
113⁄16
46
35
0.1100
2.794
11⁄2
38
25⁄8
67
23⁄4
70
51⁄8
130
7⁄ 8
22
17⁄8
48
0.1102
2.800
11⁄2
38
25⁄8
67
23⁄4
70
51⁄8
130
7⁄ 8
22
17⁄8
48
34
0.1110
2.819
11⁄2
38
25⁄8
67
23⁄4
70
51⁄8
130
7⁄ 8
22
17⁄8
48
33
0.1130
2.870
11⁄2
38
25⁄8
67
23⁄4
70
51⁄8
130
7⁄ 8
22
17⁄8
48
0.1142
2.900
15⁄8
41
23⁄4
70
23⁄4
70
51⁄8
130
7⁄ 8
22
17⁄8
48
0.1160
2.946
15⁄8
41
23⁄4
70
23⁄4
70
51⁄8
130
7⁄ 8
22
17⁄8
48
0.1181
3.000
15⁄8
41
23⁄4
70
23⁄4
70
51⁄8
130
7⁄ 8
22
17⁄8
48
0.1200
3.048
15⁄8
41
23⁄4
70
23⁄4
70
51⁄8
130
7⁄ 8
22
17⁄8
48
1.95
44
43
2.40 41 2.46 40 2.50
2.60 37 2.70
2.80
2.90 32 3.00 31
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TWIST DRILLS
859
Table 1. (Continued) ANSI Straight Shank Twist Drills — Jobbers Length through 17.5 mm, Taper Length through 12.7 mm, and Screw Machine Length through 25.4 mm Diameter ANSI/ASME B94.11M-1993 Drill Diameter, Da Fraction No. or Ltr.
Jobbers Length
Equivalent Decimal In.
Screw Machine Length
Taper Length
Flute
Overall
Flute
Overall
Flute
F
L
F
L
F
Inch
mm
Inch
mm
Inch
mm
Inch
mm
Inch
3.100
15⁄8
41
23⁄4
70
23⁄4
70
51⁄8
130
7⁄ 8
3.175
15⁄8
41
23⁄4
70
23⁄4
70
51⁄8
130
7⁄ 8
3.200
15⁄8
41
23⁄4
76
53⁄8
137
15⁄ 16
3.264
15⁄8
41
23⁄4
76
53⁄8
137
15⁄ 16
3.300
13⁄4
44
27⁄8
76
53⁄8
137
15⁄ 16
3.400
13⁄4
44
27⁄8
76
53⁄8
137
15⁄ 16
3.454
13⁄4
44
27⁄8
76
53⁄8
137
15⁄ 16
3.500
13⁄4
44
27⁄8
76
53⁄8
137
15⁄ 16
3.569
13⁄4
44
27⁄8
76
53⁄8
137
15⁄ 16
0.1406
3.571
13⁄4
44
27⁄8
73
3
76
53⁄8
137
15⁄ 16
0.1417
3.600
17⁄8
48
3
76
3
76
53⁄8
137
0.1440
3.658
17⁄8
48
3
76
3
76
53⁄8
0.1457
3.700
17⁄8
48
3
76
3
76
26
0.1470
3.734
17⁄8
48
3
76
3
25
0.1495
3.797
17⁄8
48
3
76
0.1496
3.800
17⁄8
48
3
0.1520
3.861
2
51
0.1535
3.900
2
23
0.1540
3.912
5⁄ 32
0.1562
22
mm
mm
Overall L
mm
Inch
mm
22
17⁄8
48
22
17⁄8
48
24
115⁄16
49
24
115⁄16
49
24
115⁄16
49
24
115⁄16
49
24
115⁄16
49
24
115⁄16
49
24
115⁄16
49
24
115⁄16
49
1
25
21⁄16
52
137
1
25
21⁄16
52
53⁄8
137
1
25
21⁄16
52
76
53⁄8
137
1
25
21⁄16
52
3
76
53⁄8
137
1
25
21⁄16
52
76
3
76
53⁄8
137
1
25
21⁄16
52
31⁄8
79
3
76
53⁄8
137
1
25
21⁄16
52
51
31⁄8
79
3
76
53⁄8
137
1
25
21⁄16
52
2
51
31⁄8
79
3
76
53⁄8
137
1
25
21⁄16
52
3.967
2
51
31⁄8
79
3
76
53⁄8
137
1
25
21⁄16
52
0.1570
3.988
2
51
31⁄8
79
33⁄8
86
53⁄4
146
11⁄16
27
21⁄8
54
0.1575
4.000
21⁄8
54
31⁄4
83
33⁄8
86
53⁄4
146
11⁄16
27
21⁄8
54
21
0.1590
4.039
21⁄8
54
31⁄4
83
33⁄8
86
53⁄4
146
11⁄16
27
21⁄8
54
20
0.1610
4.089
21⁄8
54
31⁄4
83
33⁄8
86
53⁄4
146
11⁄16
27
21⁄8
54
4.10
0.1614
4.100
21⁄8
54
31⁄4
83
33⁄8
86
53⁄4
146
11⁄16
27
21⁄8
54
4.20
0.1654
4.200
21⁄8
54
31⁄4
83
33⁄8
86
53⁄4
146
11⁄16
27
21⁄8
54
0.1660
4.216
21⁄8
54
31⁄4
83
33⁄8
86
53⁄4
146
11⁄16
27
21⁄8
54
0.1693
4.300
21⁄8
54
31⁄4
83
33⁄8
86
53⁄4
146
11⁄16
27
21⁄8
54
18
0.1695
4.305
21⁄8
54
31⁄4
83
33⁄8
86
53⁄4
146
11⁄16
27
21⁄8
54
11⁄ 64
0.1719
4.366
21⁄8
54
31⁄4
83
33⁄8
86
53⁄4
146
11⁄16
27
21⁄8
54
17
0.1730
4.394
23⁄16
56
33⁄8
86
33⁄8
86
53⁄4
146
11⁄8
29
23⁄16
56
0.1732
4.400
23⁄16
56
33⁄8
86
33⁄8
86
53⁄4
146
11⁄8
29
23⁄16
56
0.1770
4.496
23⁄16
56
33⁄8
86
33⁄8
86
53⁄4
146
11⁄8
29
23⁄16
56
0.1772
4.500
23⁄16
56
33⁄8
86
33⁄8
86
53⁄4
146
11⁄8
29
23⁄16
56
0.1800
4.572
23⁄16
56
33⁄8
86
33⁄8
86
53⁄4
146
11⁄8
29
23⁄16
56
0.1811
4.600
23⁄16
56
33⁄8
86
33⁄8
86
53⁄4
146
11⁄8
29
23⁄16
56
0.1820
4.623
23⁄16
56
33⁄8
86
33⁄8
86
53⁄4
146
11⁄8
29
23⁄16
56
0.1850
4.700
25⁄16
59
31⁄2
89
33⁄8
86
53⁄4
146
11⁄8
29
23⁄16
56
0.1875
4.762
25⁄16
59
31⁄2
89
33⁄8
86
53⁄4
146
11⁄8
29
23⁄16
56
0.1890
4.800
25⁄16
59
31⁄2
89
35⁄8
92
6
152
13⁄16
30
21⁄4
57
0.1910
4.851
25⁄16
59
31⁄2
89
35⁄8
92
6
152
13⁄16
30
21⁄4
57
0.1929
4.900
27⁄16
62
35⁄8
92
35⁄8
92
6
152
13⁄16
30
21⁄4
57
10
0.1935
4.915
27⁄16
62
35⁄8
92
35⁄8
92
6
152
13⁄16
30
21⁄4
57
9
0.1960
4.978
27⁄16
62
35⁄8
92
35⁄8
92
6
152
13⁄16
30
21⁄4
57
0.1969
5.000
27⁄16
62
35⁄8
92
35⁄8
92
6
152
13⁄16
30
21⁄4
57
0.1990
5.054
27⁄16
62
35⁄8
92
35⁄8
92
6
152
13⁄16
30
21⁄4
57
3.10 1⁄ 8
0.1250 3.20
30 3.40 29 28
0.1339 0.1378 0.1405
9⁄ 64
3.60 27 3.70
3.80 24 3.90
4.00
19 4.30
4.40 16 4.50 15 4.60 14 4.70
3⁄ 16
4.80
11 4.90
5.00 8
0.1299 0.1360
3.50
12
0.1260 0.1285
3.30
13
0.1220
70 70 73 73 73 73 73
3 3 3 3 3 3 3
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 860
TWIST DRILLS
Table 1. (Continued) ANSI Straight Shank Twist Drills — Jobbers Length through 17.5 mm, Taper Length through 12.7 mm, and Screw Machine Length through 25.4 mm Diameter ANSI/ASME B94.11M-1993 Drill Diameter, Da Fraction No. or Ltr.
Jobbers Length
Equivalent Decimal In.
Screw Machine Length
Taper Length
Flute
Overall
Flute
Overall
Flute
F
L
F
L
F
Overall L
mm
Inch
mm
Inch
mm
Inch
mm
Inch
mm
Inch
mm
5.100
27⁄16
62
35⁄8
92
35⁄8
92
6
152
13⁄16
30
21⁄4
57
5.105
27⁄16
62
35⁄8
92
35⁄8
152
13⁄16
30
21⁄4
57
5.159
27⁄16
62
35⁄8
92
35⁄8
152
13⁄16
30
21⁄4
57
5.182
21⁄2
64
33⁄4
95
35⁄8
152
11⁄4
32
23⁄8
60
5.200
21⁄2
64
33⁄4
95
35⁄8
152
11⁄4
32
23⁄8
60
5.220
21⁄2
64
33⁄4
95
35⁄8
152
11⁄4
32
23⁄8
60
5.300
21⁄2
64
33⁄4
95
35⁄8
152
11⁄4
32
23⁄8
60
5.309
21⁄2
64
33⁄4
95
35⁄8
152
11⁄4
32
23⁄8
60
5.400
21⁄2
64
33⁄4
95
35⁄8
152
11⁄4
32
23⁄8
60
0.2130
5.410
21⁄2
64
33⁄4
95
35⁄8
92
6
152
11⁄4
32
23⁄8
60
0.2165
5.500
21⁄2
64
33⁄4
95
35⁄8
92
6
152
11⁄4
32
23⁄8
60
0.2188
5.558
21⁄2
64
33⁄4
95
35⁄8
92
6
152
11⁄4
32
23⁄8
60
0.2205
5.600
25⁄8
67
37⁄8
98
33⁄4
95
61⁄8
156
15⁄16
33
27⁄16
62
0.2210
5.613
25⁄8
67
37⁄8
98
33⁄4
95
61⁄8
156
15⁄16
33
27⁄16
62
0.2244
5.700
25⁄8
67
37⁄8
98
33⁄4
95
61⁄8
156
15⁄16
33
27⁄16
62
0.2280
5.791
25⁄8
67
37⁄8
98
33⁄4
95
61⁄8
156
15⁄16
33
27⁄16
62
5.80
0.2283
5.800
25⁄8
67
37⁄8
98
33⁄4
95
61⁄8
156
15⁄16
33
27⁄16
62
5.90
0.2323
5.900
25⁄8
67
37⁄8
98
33⁄4
95
61⁄8
156
15⁄16
33
27⁄16
62
A
0.2340
5.944
25⁄8
67
37⁄8
98
…
…
…
…
15⁄16
33
27⁄16
62
15⁄ 64
0.2344
5.954
25⁄8
67
37⁄8
98
33⁄4
95
61⁄8
156
15⁄16
33
27⁄16
62
0.2362
6.000
23⁄4
70
4
102
33⁄4
95
61⁄8
156
13⁄8
35
21⁄2
64
0.2380
6.045
23⁄4
70
4
102
…
…
…
…
13⁄8
35
21⁄2
64
0.2402
6.100
23⁄4
70
4
102
33⁄4
95
61⁄8
156
13⁄8
35
21⁄2
64
0.2420
6.147
23⁄4
70
4
102
…
…
…
…
13⁄8
35
21⁄2
64
0.2441
6.200
23⁄4
70
4
102
33⁄4
95
61⁄8
156
13⁄8
35
21⁄2
64
0.2460
6.248
23⁄4
70
4
102
…
…
…
…
13⁄8
35
21⁄2
64
0.2480
6.300
23⁄4
70
4
102
33⁄4
95
61⁄8
156
13⁄8
35
21⁄2
64
0.2500
6.350
23⁄4
70
4
102
33⁄4
95
61⁄8
156
13⁄8
35
21⁄2
64
6.40
0.2520
6.400
27⁄8
73
41⁄8
105
37⁄8
98
61⁄4
159
17⁄16
37
25⁄8
67
6.50
0.2559
6.500
27⁄8
73
41⁄8
105
37⁄8
98
61⁄4
159
17⁄16
37
25⁄8
67
0.2570
6.528
27⁄8
73
41⁄8
105
…
…
…
…
17⁄16
37
25⁄8
67
0.2598
6.600
27⁄8
73
41⁄8
105
…
…
…
…
17⁄16
37
25⁄8
67
0.2610
6.629
27⁄8
73
41⁄8
105
…
…
…
…
17⁄16
37
25⁄8
67
0.2638
6.700
27⁄8
73
41⁄8
105
…
…
…
…
17⁄16
37
25⁄8
67
17⁄ 64
0.2656
6.746
27⁄8
73
41⁄8
105
37⁄8
98
61⁄4
159
17⁄16
37
25⁄8
67
H
0.2660
6.756
27⁄8
73
41⁄8
105
…
…
…
…
11⁄2
38
211⁄16
68
6.80
0.2677
6.800
27⁄8
73
41⁄8
105
37⁄8
98
61⁄4
159
11⁄2
38
211⁄16
68
6.90
0.2717
6.900
27⁄8
73
41⁄8
105
…
…
…
…
11⁄2
38
211⁄16
68
0.2720
6.909
27⁄8
73
41⁄8
105
…
…
…
…
11⁄2
38
211⁄16
68
0.2756
7.000
27⁄8
73
41⁄8
105
37⁄8
98
61⁄4
159
11⁄2
38
211⁄16
68
0.2770
7.036
27⁄8
73
41⁄8
105
…
…
…
…
11⁄2
38
211⁄16
68
0.2795
7.100
215⁄16
75
41⁄4
108
…
…
…
…
11⁄2
38
211⁄16
68
K
0.2810
7.137
215⁄16
75
41⁄4
108
…
…
…
…
11⁄2
38
211⁄16
68
9⁄ 32
0.2812
7.142
215⁄16
75
41⁄4
108
37⁄8
98
61⁄4
159
11⁄2
38
211⁄16
68
7.20
0.2835
7.200
215⁄16
75
41⁄4
108
4
102
63⁄8
162
19⁄16
40
23⁄4
70
7.30
0.2874
7.300
215⁄16
75
41⁄4
108
…
…
…
19⁄16
40
23⁄4
70
mm 5.10
7
0.2008 0.2010
13⁄ 64
0.2031
6
0.2040 5.20
5
0.2047 0.2055
5.30 4
0.2087 0.2090
5.40 3 5.50 7⁄ 32
5.60 2 5.70 1
6.00 B 6.10 C 6.20 D 6.30 E, 1⁄4
F 6.60 G 6.70
I 7.00 J 7.10
0.2126
…
92 92 92 92 92 92 92 92
6 6 6 6 6 6 6 6
Copyright 2004, Industrial Press, Inc., New York, NY
Inch
mm
Machinery's Handbook 27th Edition TWIST DRILLS
861
Table 1. (Continued) ANSI Straight Shank Twist Drills — Jobbers Length through 17.5 mm, Taper Length through 12.7 mm, and Screw Machine Length through 25.4 mm Diameter ANSI/ASME B94.11M-1993 Drill Diameter, Da Fraction No. or Ltr.
Jobbers Length
Equivalent Decimal In.
Screw Machine Length
Taper Length
Flute
Overall
Flute
Overall
Flute
F
L
F
L
F
Overall L
mm
Inch
mm
Inch
mm
Inch
mm
Inch
mm
Inch
mm
7.366
215⁄16
75
41⁄4
108
…
…
…
…
19⁄16
40
23⁄4
70
7.400
31⁄16
78
43⁄8
111
…
…
…
…
19⁄16
40
23⁄4
70
7.493
31⁄16
78
43⁄8
111
…
…
…
…
19⁄16
40
23⁄4
70
7.500
31⁄16
78
43⁄8
102
63⁄8
162
19⁄16
40
23⁄4
70
7.541
31⁄16
78
43⁄8
102
63⁄8
162
19⁄16
40
23⁄4
70
7.600
31⁄16
78
43⁄8
41
213⁄16
71
7.671
31⁄16
78
43⁄8
41
213⁄16
71
7.700
33⁄16
81
41⁄2
41
213⁄16
71
7.800
33⁄16
81
41⁄2
71
0.3110
7.900
33⁄16
81
41⁄2
114
0.3125
7.938
33⁄16
81
41⁄2
114
0.3150
8.000
33⁄16
81
41⁄2
0.3160
8.026
33⁄16
81
8.10
0.3189
8.100
35⁄16
8.20
0.3228
8.200
0.3230
mm
L
0.2900 7.40
M
0.2913 0.2950
7.50 19⁄ 64
0.2953 0.2969
111 111
4 4
Inch
mm
111
…
…
…
…
15⁄8
111
…
…
…
…
15⁄8
114
…
…
…
…
15⁄8
102
63⁄8
162
15⁄8
41
213⁄16
…
…
…
15⁄8
41
213⁄16
71
4
102
63⁄8
162
15⁄8
41
213⁄16
71
114
41⁄8
105
61⁄2
165
111⁄16
43
215⁄16
75
41⁄2
114
…
…
…
…
111⁄16
43
215⁄16
75
84
45⁄8
117
…
…
…
…
111⁄16
43
215⁄16
75
35⁄16
84
45⁄8
117
41⁄8
105
61⁄2
165
111⁄16
43
215⁄16
75
8.204
35⁄16
84
45⁄8
117
…
…
…
…
111⁄16
43
215⁄16
75
0.3268
8.300
35⁄16
84
45⁄8
117
…
…
…
…
111⁄16
43
215⁄16
75
0.3281
8.334
35⁄16
84
45⁄8
117
41⁄8
105
61⁄2
165
111⁄16
43
215⁄16
75
0.3307
8.400
37⁄16
87
43⁄4
121
…
…
…
…
111⁄16
43
3
76
0.3320
8.433
37⁄16
87
43⁄4
121
…
…
…
…
111⁄16
43
3
76
8.50
0.3346
8.500
37⁄16
87
43⁄4
121
41⁄8
105
61⁄2
165
111⁄16
43
3
76
8.60
0.3386
8.600
37⁄16
87
43⁄4
121
…
…
…
…
111⁄16
43
3
76
0.3390
8.611
37⁄16
87
43⁄4
121
…
…
…
…
111⁄16
43
3
76
0.3425
8.700
37⁄16
87
43⁄4
121
…
…
…
…
111⁄16
43
3
76
0.3438
8.733
37⁄16
87
43⁄4
121
41⁄8
105
61⁄2
165
111⁄16
43
3
76
8.80
0.3465
8.800
31⁄2
89
47⁄8
124
41⁄4
108
63⁄4
171
13⁄4
44
31⁄16
78
0.3480
8.839
31⁄2
89
47⁄8
124
…
…
…
…
13⁄4
44
31⁄16
78
8.90
0.3504
8.900
31⁄2
89
47⁄8
124
…
…
…
…
13⁄4
44
31⁄16
78
9.00
0.3543
9.000
31⁄2
89
47⁄8
124
41⁄4
108
63⁄4
171
13⁄4
44
31⁄16
78
0.3580
9.093
31⁄2
89
47⁄8
124
…
…
…
…
13⁄4
44
31⁄16
78
0.3583
9.100
31⁄2
89
47⁄8
124
…
…
…
…
13⁄4
44
31⁄16
78
0.3594
9.129
31⁄2
89
47⁄8
124
41⁄4
108
63⁄4
171
13⁄4
44
31⁄16
78
9.20
0.3622
9.200
35⁄8
92
5
127
41⁄4
108
63⁄4
171
113⁄16
46
31⁄8
79
9.30
0.3661
9.300
35⁄8
92
5
127
…
…
…
…
113⁄16
46
31⁄8
79
0.3680
9.347
35⁄8
92
5
127
…
…
…
…
113⁄16
46
31⁄8
79
9.40
0.3701
9.400
35⁄8
92
5
127
…
…
…
…
113⁄16
46
31⁄8
79
9.50
0.3740
9.500
35⁄8
92
5
127
41⁄4
108
63⁄4
171
113⁄16
46
31⁄8
79
3⁄ 8
0.3750
9.525
35⁄8
92
5
127
41⁄4
108
63⁄4
171
113⁄16
46
31⁄8
79
V
0.3770
9.576
35⁄8
92
5
127
…
…
…
…
17⁄8
48
31⁄4
83
9.60
0.3780
9.600
33⁄4
95
51⁄8
130
…
…
…
…
17⁄8
48
31⁄4
83
9.70
0.3819
9.700
33⁄4
95
51⁄8
130
…
…
…
…
17⁄8
48
31⁄4
83
9.80
0.3858
9.800
33⁄4
95
51⁄8
130
43⁄8
111
178
17⁄8
48
31⁄4
83
0.3860
9.804
33⁄4
95
51⁄8
130
…
…
…
…
17⁄8
48
31⁄4
83
0.3898
9.900
33⁄4
95
51⁄8
130
…
…
…
…
17⁄8
48
31⁄4
83
0.3906
9.921
33⁄4
95
51⁄8
130
43⁄8
111
7
178
17⁄8
48
31⁄4
83
0.3937
10.000
33⁄4
95
51⁄8
130
43⁄8
111
7
178
115⁄16
49
35⁄16
84
7.60 N
0.2992 0.3020
7.70 7.80 7.90 5⁄ 16
8.00 O
P 8.30 21⁄ 64
8.40 Q
R 8.70 11⁄ 32
S
T 9.10 23⁄ 64
U
W 9.90 25⁄ 64
10.00
0.3031 0.3071
114
4 …
7
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 862
TWIST DRILLS
Table 1. (Continued) ANSI Straight Shank Twist Drills — Jobbers Length through 17.5 mm, Taper Length through 12.7 mm, and Screw Machine Length through 25.4 mm Diameter ANSI/ASME B94.11M-1993 Drill Diameter, Da Fraction No. or Ltr.
Decimal In.
Screw Machine Length
Taper Length
Flute
Overall
Flute
Overall
Flute
F
L
F
L
F
Overall L
Inch
mm
Inch
mm
Inch
mm
Inch
mm
Inch
mm
10.084
33⁄4
95
51⁄8
130
…
…
…
…
115⁄16
49
35⁄16
84
10.200
37⁄8
98
51⁄4
133
43⁄8
111
178
115⁄16
49
35⁄16
84
10.262
37⁄8
98
51⁄4
133
…
…
…
115⁄16
49
35⁄16
84
10.317
37⁄8
98
51⁄4
133
43⁄8
111
178
115⁄16
49
35⁄16
84
10.490
37⁄8
98
51⁄4
133
…
…
…
51
33⁄8
86
10.500
37⁄8
98
51⁄4
133
45⁄8
117
71⁄4
51
33⁄8
86
10.716
315⁄16
100
53⁄8
137
45⁄8
117
71⁄4
51
33⁄8
86
10.800
41⁄16
103
51⁄2
140
45⁄8
117
71⁄4
52
37⁄16
87
11.000
41⁄16
103
51⁄2
140
45⁄8
117
71⁄4
87
0.4375
11.112
41⁄16
103
51⁄2
140
45⁄8
117
71⁄4
11.20
0.4409
11.200
43⁄16
106
55⁄8
143
43⁄4
121
11.50
0.4528
11.500
43⁄16
106
55⁄8
143
43⁄4
0.4531
11.509
43⁄16
106
55⁄8
143
0.4646
11.800
45⁄16
110
53⁄4
0.4688
11.908
45⁄16
110
12.00
0.4724
12.000
43⁄8
12.20
0.4803
12.200
0.4844
mm
X
0.3970 10.20
Y
0.4016 0.4040
13⁄ 32
0.4062
Z
0.4130 10.50
27⁄ 64
0.4134 0.4219
mm
7 … 7
… 184
2 2
Inch
mm
184
2
184
21⁄16
184
21⁄16
52
37⁄16
184
21⁄16
52
37⁄16
87
71⁄2
190
21⁄8
54
39⁄16
90
121
71⁄2
190
21⁄8
54
39⁄16
90
43⁄4
121
71⁄2
190
21⁄8
54
39⁄16
90
146
43⁄4
121
71⁄2
190
21⁄8
54
35⁄8
92
53⁄4
146
43⁄4
121
71⁄2
190
21⁄8
54
35⁄8
92
111
57⁄8
149
43⁄4
121
73⁄4
197
23⁄16
56
311⁄16
94
43⁄8
111
57⁄8
149
43⁄4
121
73⁄4
197
23⁄16
56
311⁄16
94
12.304
43⁄8
111
57⁄8
149
43⁄4
121
73⁄4
197
23⁄16
56
311⁄16
94
0.4921
12.500
41⁄2
114
6
152
43⁄4
121
73⁄4
197
21⁄4
57
33⁄4
95
0.5000
12.700
41⁄2
114
6
152
43⁄4
121
73⁄4
197
21⁄4
57
33⁄4
95
12.80
0.5039
12.800
41⁄2
114
6
152
…
…
…
…
23⁄8
60
37⁄8
98
13.00
0.5118
13.000
41⁄2
114
6
152
…
…
…
…
23⁄8
60
37⁄8
98
0.5156
13.096
413⁄16
122
65⁄8
168
…
…
…
…
23⁄8
60
37⁄8
98
0.5197
13.200
413⁄16
122
65⁄8
168
…
…
…
…
23⁄8
60
37⁄8
98
0.5312
13.492
413⁄16
122
65⁄8
168
…
…
…
…
23⁄8
60
37⁄8
98
13.50
0.5315
13.500
413⁄16
122
65⁄8
168
…
…
…
…
23⁄8
60
37⁄8
98
13.80
0.5433
13.800
413⁄16
122
65⁄8
168
…
…
…
…
21⁄2
64
4
102
0.5469
13.891
413⁄16
122
65⁄8
168
…
…
…
…
21⁄2
64
4
102
14.00
0.5512
14.000
413⁄16
122
65⁄8
168
…
…
…
…
21⁄2
64
4
102
14.25
0.5610
14.250
413⁄16
122
65⁄8
168
…
…
…
…
21⁄2
64
4
102
0.5625
14.288
413⁄16
122
65⁄8
168
…
…
…
…
21⁄2
64
4
102
14.50
0.5709
14.500
413⁄16
122
65⁄8
168
…
…
…
…
25⁄8
67
41⁄8
105
0.5781
14.684
413⁄16
122
65⁄8
168
…
…
…
…
25⁄8
67
41⁄8
105
14.75
0.5807
14.750
53⁄16
132
71⁄8
181
…
…
…
…
25⁄8
67
41⁄8
105
15.00
0.5906
15.000
53⁄16
132
71⁄8
181
…
…
…
…
25⁄8
67
41⁄8
105
0.5938
15.083
53⁄16
132
71⁄8
181
…
…
…
…
25⁄8
67
41⁄8
105
0.6004
15.250
53⁄16
132
71⁄8
181
…
…
…
…
23⁄4
70
41⁄4
108
0.6094
15.479
53⁄16
132
71⁄8
181
…
…
…
…
23⁄4
70
41⁄4
108
15.50
0.6102
15.500
53⁄16
132
71⁄8
181
…
…
…
…
23⁄4
70
41⁄4
108
15.75
0.6201
15.750
53⁄16
132
71⁄8
181
…
…
…
…
23⁄4
70
41⁄4
108
0.6250
15.875
53⁄16
132
71⁄8
181
…
…
…
…
23⁄4
70
41⁄4
108
16.00
0.6299
16.000
53⁄16
132
71⁄8
181
…
…
…
…
27⁄8
73
41⁄2
114
16.25
0.6398
16.250
53⁄16
132
71⁄8
181
…
…
…
…
27⁄8
73
41⁄2
114
0.6406
16.271
53⁄16
132
71⁄8
181
…
…
…
…
27⁄8
73
41⁄2
144
0.6496
16.500
53⁄16
132
71⁄8
181
…
…
…
…
27⁄8
73
41⁄2
114
0.6562
16.669
53⁄16
132
71⁄8
181
…
…
…
…
27⁄8
73
41⁄2
114
10.80 11.00 7⁄ 16
29⁄ 64
11.80 15⁄ 32
31⁄ 64
12.50 1⁄ 2
33⁄ 64
13.20 17⁄ 32
35⁄ 64
9⁄ 16
37⁄ 64
19⁄ 32
15.25 39⁄ 64
5⁄ 8
41⁄ 64
16.50 21⁄ 32
Jobbers Length
Equivalent
0.4252 0.4331
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TWIST DRILLS
863
Table 1. (Continued) ANSI Straight Shank Twist Drills — Jobbers Length through 17.5 mm, Taper Length through 12.7 mm, and Screw Machine Length through 25.4 mm Diameter ANSI/ASME B94.11M-1993 Drill Diameter, Da Fraction No. or Ltr.
Jobbers Length
Equivalent mm
Decimal In.
16.75
0.6594
Screw Machine Length
Taper Length
Flute
Overall
Flute
Overall
Flute
F
L
F
L
F
Overall L
Inch
mm
Inch
mm
Inch
mm
Inch
mm
Inch
mm
16.750
55⁄8
143
75⁄8
194
…
…
…
…
27⁄8
73
41⁄2
114
0.6693
17.000
55⁄8
143
75⁄8
194
…
…
…
…
27⁄8
73
41⁄2
114
0.6719
17.066
55⁄8
143
75⁄8
194
…
…
…
…
27⁄8
73
41⁄2
114
0.6791
17.250
55⁄8
143
75⁄8
194
…
…
…
…
27⁄8
73
41⁄2
114
0.6875
17.462
55⁄8
143
75⁄8
194
…
…
…
…
27⁄8
73
41⁄2
114
0.6890
17.500
55⁄8
143
75⁄8
194
…
…
…
…
3
76
43⁄4
121
0.7031
17.859
…
…
…
…
…
…
…
…
3
76
43⁄4
121
0.7087
18.000
…
…
…
…
…
…
…
…
3
76
43⁄4
121
0.7188
18.258
…
…
…
…
…
…
…
…
3
76
43⁄4
121
0.7283
18.500
…
…
…
…
…
…
…
…
31⁄8
79
5
127
0.7344
18.654
…
…
…
…
…
…
…
…
31⁄8
79
5
127
0.7480
19.000
…
…
…
…
…
…
…
…
31⁄8
79
5
127
3⁄ 4
0.7500
19.050
…
…
…
…
…
…
…
…
31⁄8
79
5
127
49⁄ 64
0.7656
19.446
…
…
…
…
…
…
…
…
31⁄4
83
51⁄8
130
0.7677
19.500
…
…
…
…
…
…
…
…
31⁄4
83
51⁄8
130
0.7812
19.845
…
…
…
…
…
…
…
…
31⁄4
83
51⁄8
130
0.7879
20.000
…
…
…
…
…
…
…
…
33⁄8
86
51⁄4
133
0.7969
20.241
…
…
…
…
…
…
…
…
33⁄8
86
51⁄4
133
0.8071
20.500
…
…
…
…
…
…
…
…
33⁄8
86
51⁄4
133
0.8125
20.638
…
…
…
…
…
…
…
…
33⁄8
86
51⁄4
133
0.8268
21.000
…
…
…
…
…
…
…
…
31⁄2
89
53⁄8
137
53⁄ 64
0.8281
21.034
…
…
…
…
…
…
…
…
31⁄2
89
53⁄8
137
27⁄ 32
0.8438
21.433
…
…
…
…
…
…
…
…
31⁄2
89
53⁄8
137
0.8465
21.500
…
…
…
…
…
…
…
…
31⁄2
89
53⁄8
137
0.8594
21.829
…
…
…
…
…
…
…
…
31⁄2
89
53⁄8
137
0.8661
22.000
…
…
…
…
…
…
…
…
31⁄2
89
53⁄8
137
0.8750
22.225
…
…
…
…
…
…
…
…
31⁄2
89
53⁄8
137
0.8858
22.500
…
…
…
…
…
…
…
…
35⁄8
92
55⁄8
143
0.8906
22.621
…
…
…
…
…
…
…
…
35⁄8
92
55⁄8
143
0.9055
23.000
…
…
…
…
…
…
…
…
35⁄8
92
55⁄8
143
29⁄ 32
0.9062
23.017
…
…
…
…
…
…
…
…
35⁄8
92
55⁄8
143
59⁄ 64
0.9219
23.416
…
…
…
…
…
…
…
…
33⁄4
95
53⁄4
146
0.9252
23.500
…
…
…
…
…
…
…
…
33⁄4
95
53⁄4
146
0.9375
23.812
…
…
…
…
…
…
…
…
33⁄4
95
53⁄4
146
0.9449
24.000
…
…
…
…
…
…
…
…
37⁄8
98
57⁄8
149
0.9531
24.209
…
…
…
…
…
…
…
…
37⁄8
98
57⁄8
149
0.9646
24.500
…
…
…
…
…
…
…
…
37⁄8
98
57⁄8
149
0.9688
24.608
…
…
…
…
…
…
…
…
37⁄8
98
57⁄8
149
0.9843
25.000
…
…
…
…
…
…
…
…
4
102
6
152
63⁄ 64
0.9844
25.004
…
…
…
…
…
…
…
…
4
102
6
152
1
1.0000
25.400
…
…
…
…
…
…
…
…
4
102
6
152
17.00 43⁄ 64
17.25 11⁄ 16
17.50 45⁄ 64
18.00 23⁄ 32
18.50 47⁄ 64
19.00
19.50 25⁄ 32
20.00 51⁄ 64
20.50 13⁄ 16
21.00
21.50 55⁄ 64
22.00 7⁄ 8
22.50 57⁄ 64
23.00
23.50 15⁄ 16
24.00 61⁄ 64
24.50 31⁄ 32
25.00
mm
a Fractional inch, number, letter, and metric sizes.
Copyright 2004, Industrial Press, Inc., New York, NY
Inch
mm
Machinery's Handbook 27th Edition 864
TWIST DRILLS
Nominal Shank Size is Same as Nominal Drill Size
Table 2. ANSI Straight Shank Twist Drills — Taper Length — Over 1⁄2 in. (12.7 mm) Dia., Fractional and Metric Sizes ANSI/ASME B94.11M-1993 Diameter of Drill D Frac.
mm 12.80 13.00
33⁄ 64
13.20 17⁄ 32
13.50 13.80 35⁄ 64
14.00 14.25 9⁄ 16
14.50 37⁄ 64
14.75 15.00 19⁄ 32
15.25 39⁄ 64
15.50 15.75 5⁄ 8
16.00 16.25 41⁄ 64
16.50 21⁄ 32
16.75 17.00 43⁄ 64
17.25 11⁄ 16
17.50 45⁄ 64
18.00 23⁄ 32
18.50 47⁄ 64
19.00 3⁄ 4 49⁄ 64
19.50 25⁄ 32
Decimal Inch Equiv.
Millimeter Equiv.
0.5039 0.5117 0.5156 0.5197 0.5312 0.5315 0.5433 0.5419 0.5512 0.5610 0.5625 0.5709 0.5781 0.5807 0.5906 0.5938 0.6004 0.6094 0.6102 0.6201 0.6250 0.6299 0.6398 0.6406 0.6496 0.6562 0.6594 0.6693 0.6719 0.6791 0.6875 0.6890 0.7031 0.7087 0.7188 0.7283 0.7344 0.7480 0.7500 0.7656 0.7677 0.7812
12.800 13.000 13.096 13.200 13.492 13.500 13.800 13.891 14.000 14.250 14.288 14.500 14.684 14.750 15.000 15.083 15.250 15.479 15.500 15.750 15.875 16.000 16.250 16.271 16.500 16.667 16.750 17.000 17.066 17.250 17.462 17.500 17.859 18.000 18.258 18.500 18.654 19.000 19.050 19.446 19.500 19.842
Flute Length F Inch mm 43⁄4 43⁄4 43⁄4 43⁄4 43⁄4 43⁄4 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 51⁄8 51⁄8 51⁄8 51⁄8 51⁄8 53⁄8 53⁄8 53⁄8 53⁄8 53⁄8 55⁄8 55⁄8 55⁄8 55⁄8 57⁄8 57⁄8 57⁄8 57⁄8 6 6 6
121 121 121 121 121 121 124 124 124 124 124 124 124 124 124 124 124 124 124 124 124 130 130 130 130 130 137 137 137 137 137 143 143 143 143 149 149 149 149 152 152 152
Overall Length L Inch mm 8 8 8 8 8 8 81⁄4 81⁄4 81⁄4 81⁄4 81⁄4 83⁄4 83⁄4 83⁄4 83⁄4 83⁄4 83⁄4 83⁄4 83⁄4 83⁄4 83⁄4 9 9 9 9 9 91⁄4 91⁄4 91⁄4 91⁄4 91⁄4 91⁄2 91⁄2 91⁄2 91⁄2 93⁄4 93⁄4 93⁄4 93⁄4 97⁄8 97⁄8 97⁄8
203 203 203 203 203 203 210 210 210 210 210 222 222 222 222 222 222 222 222 222 222 228 228 228 228 228 235 235 235 235 235 241 241 241 241 247 247 247 247 251 251 251
Length of Body B Inch mm 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 51⁄4 51⁄4 51⁄4 51⁄4 51⁄4 51⁄2 51⁄2 51⁄2 51⁄2 51⁄2 53⁄4 53⁄4 53⁄4 53⁄4 6 6 6 6 61⁄8 61⁄8 61⁄8
124 124 124 124 124 124 127 127 127 127 127 127 127 127 127 127 127 127 127 127 127 133 133 133 133 133 140 140 140 140 140 146 146 146 146 152 152 152 152 156 156 156
Minimum Length of Shk. S Inch mm 25⁄8 25⁄8 25⁄8 25⁄8 25⁄8 25⁄8 23⁄4 23⁄4 23⁄4 23⁄4 23⁄4 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8
66 66 66 66 66 66 70 70 70 70 70 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 79
Copyright 2004, Industrial Press, Inc., New York, NY
Maximum Length ofNeck N Inch mm 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8
13 13 13 13 13 13 13 13 13 13 13 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16
Machinery's Handbook 27th Edition TWIST DRILLS
865
Table 2. (Continued) ANSI Straight Shank Twist Drills — Taper Length — Over 1⁄2 in. (12.7 mm) Dia., Fractional and Metric Sizes ANSI/ASME B94.11M-1993 Diameter of Drill D Frac.
mm 20.00
51⁄ 64
20.50 13⁄ 16
21.00 53⁄ 64 27⁄ 32
21.50 55⁄ 64
22.00 7⁄ 8
22.50 57⁄ 64
23.00 29⁄ 32 59⁄ 64
23.50 15⁄ 16
24.00 61⁄ 64
24.50 31⁄ 32
25.00 63⁄ 64
1 25.50 11⁄64 26.00 11⁄32 26.50 13⁄64 11⁄16 27.00 15⁄64 27.50 13⁄32 28.00 17⁄64 28.50 11⁄8 19⁄64 29.00 15⁄32 29.50 111⁄64 30.00 13⁄16 30.50 113⁄64 17⁄32 31.00 115⁄64 31.50
Decimal Inch Equiv.
Millimeter Equiv.
0.7874 0.7969 0.8071 0.8125 0.8268 0.8281 0.8438 0.8465 0.8594 0.8661 0.8750 0.8858 0.8906 0.9055 0.9062 0.9219 0.9252 0.9375 0.9449 0.9531 0.9646 0.9688 0.9843 0.9844 1.0000 1.0039 1.0156 1.0236 1.0312 1.0433 1.0469 1.0625 1.0630 1.0781 1.0827 1.0938 1.1024 1.1094 1.1220 1.1250 1.1406 1.1417 1.1562 1.1614 1.1719 1.1811 1.1875 1.2008 1.2031 1.2188 1.2205 1.2344 1.2402
20.000 20.241 20.500 20.638 21.000 21.034 21.433 21.500 21.829 22.000 22.225 22.500 22.621 23.000 23.017 23.416 23.500 23.812 24.000 24.209 24.500 24.608 25.000 25.004 25.400 25.500 25.796 26.000 26.192 26.560 26.591 26.988 27.000 27.384 27.500 27.783 28.000 28.179 28.500 28.575 28.971 29.000 29.367 29.500 29.766 30.000 30.162 30.500 30.559 30.958 31.000 31.354 31.500
Flute Length F Inch mm 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 63⁄8 63⁄8 63⁄8 63⁄8 63⁄8 63⁄8 63⁄8 61⁄2 61⁄2 61⁄2 61⁄2 65⁄8 65⁄8 65⁄8 65⁄8 67⁄8 67⁄8 67⁄8 71⁄8 71⁄8 71⁄8 71⁄8 71⁄4 71⁄4 71⁄4 73⁄8 73⁄8 73⁄8 73⁄8 71⁄2 71⁄2 71⁄2 77⁄8 77⁄8 77⁄8
156 156 156 156 156 156 156 156 156 156 156 156 156 156 156 156 156 156 162 162 162 162 162 162 162 165 165 165 165 168 168 168 168 175 175 175 181 181 181 181 184 184 184 187 187 187 187 190 190 190 200 200 200
Overall Length L Inch mm 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 103⁄4 103⁄4 103⁄4 11 11 11 11 11 11 11 111⁄8 111⁄8 111⁄8 111⁄8 111⁄4 111⁄4 111⁄4 111⁄4 111⁄2 111⁄2 111⁄2 113⁄4 113⁄4 113⁄4 113⁄4 117⁄8 117⁄8 117⁄8 12 12 12 12 121⁄8 121⁄8 121⁄8 121⁄2 121⁄2 121⁄2
254 254 254 254 254 254 254 254 254 254 254 254 254 254 254 273 273 273 279 279 279 279 279 279 279 282 282 282 282 286 286 286 286 292 292 292 298 298 298 298 301 301 301 305 305 305 305 308 308 308 317 317 317
Length of Body B Inch mm 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄4 61⁄2 61⁄2 61⁄2 61⁄2 61⁄2 61⁄2 61⁄2 65⁄8 65⁄8 65⁄8 65⁄8 63⁄4 63⁄4 63⁄4 63⁄4 7 7 7 71⁄4 71⁄4 71⁄4 71⁄4 73⁄8 73⁄8 73⁄8 71⁄2 71⁄2 71⁄2 71⁄2 75⁄8 75⁄8 75⁄8 8 8 8
159 159 159 159 159 159 159 159 159 159 159 159 159 159 159 159 159 159 165 165 165 165 165 165 165 168 168 168 168 172 172 172 172 178 178 178 184 184 184 184 187 187 187 191 191 191 191 194 194 194 203 203 203
Minimum Length of Shk. S Inch mm 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 31⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8 37⁄8
79 79 79 79 79 79 79 79 79 79 79 79 79 79 79 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98 98
Copyright 2004, Industrial Press, Inc., New York, NY
Maximum Length ofNeck N Inch mm 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8
16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16
Machinery's Handbook 27th Edition 866
TWIST DRILLS
Table 2. (Continued) ANSI Straight Shank Twist Drills — Taper Length — Over 1⁄2 in. (12.7 mm) Dia., Fractional and Metric Sizes ANSI/ASME B94.11M-1993 Diameter of Drill D Frac.
mm
11⁄4 32.00 32.50 19⁄32 33.00 15⁄16 33.50 34.00 111⁄32 34.50 13⁄8 35.00 35.50 113⁄32 36.00 36.50 17⁄16 37.00 115⁄32 37.50 38.00 11⁄2 19⁄16 15⁄8 13⁄4
Decimal Inch Equiv.
Millimeter Equiv.
1.2500 1.2598 1.2795 1.2812 1.2992 1.3125 1.3189 1.3386 1.3438 1.3583 1.3750 1.3780 1.3976 1.4062 1.4173 1.4370 1.4375 1.4567 1.4688 1.4764 1.4961 1.5000 1.5625 1.6250 1.7500
31.750 32.000 32.500 32.542 33.000 33.338 33.500 34.000 34.133 34.500 34.925 35.000 35.500 35.717 36.000 36.500 36.512 37.000 37.308 37.500 38.000 38.100 39.688 41.275 44.450
Flute Length F Inch mm 77⁄8 81⁄2 81⁄2 81⁄2 85⁄8 85⁄8 83⁄4 83⁄4 83⁄4 87⁄8 87⁄8 9 9 9 91⁄8 91⁄8 91⁄8 91⁄4 91⁄4 93⁄8 93⁄8 93⁄8 95⁄8 97⁄8 101⁄2
200 216 216 216 219 219 222 222 222 225 225 229 229 229 232 232 232 235 235 238 238 238 244 251 267
Overall Length L Inch mm 121⁄2 141⁄8 141⁄8 141⁄8 141⁄4 141⁄4 143⁄8 143⁄8 143⁄8 141⁄2 141⁄2 145⁄8 145⁄8 145⁄8 143⁄4 143⁄4 143⁄4 147⁄8 147⁄8 15 15 15
317 359 359 359 362 362 365 365 365 368 368 372 372 372 375 375 375 378 378 381 381 381 387 397 413
151⁄4 155⁄8 161⁄4
Length of Body B Inch mm 8 85⁄8 85⁄8 85⁄8 83⁄4 83⁄4 87⁄8 87⁄8 87⁄8 9 9 91⁄8 91⁄8 91⁄8 91⁄4 91⁄4 91⁄4 93⁄8 93⁄8 91⁄2 91⁄2 91⁄2 93⁄4 10 105⁄8
203 219 219 219 222 222 225 225 225 229 229 232 232 232 235 235 235 238 238 241 241 241 247 254 270
Minimum Length of Shk. S Inch mm 37⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8 47⁄8
Maximum Length ofNeck N Inch mm 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4
98 124 124 124 124 124 124 124 124 124 124 124 124 124 124 124 124 124 124 124 124 124 124 124 124
16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 19 19
Table 3. American National Standard Tangs for Straight Shank Drills ANSI/ASME B94.11M-1993 Nominal Diameter of Drill Shank, A Inches 1⁄ thru 3⁄ 8 16 over 3⁄16 thru 1⁄4 over 1⁄4 thru 5⁄16 over 5⁄16 thru 3⁄8 over 3⁄8 thru 15⁄32 over 15⁄32 thru 9⁄16 over 9⁄16 thru 21⁄32 over 21⁄32 thru 3⁄4 over 3⁄4 thru 7⁄8 over 7⁄8 thru 1 over 1 thru 13⁄16 over 13⁄16 thru 13⁄8
Thickness of Tang, J Inches Millimeters Min. Max. Min.
Millimeters
Max.
3.18 thru 4.76
0.094
0.090
2.39
2.29
over 4.76 thru 6.35
0.122
0.118
3.10
3.00
over 6.35 thru 7.94
0.162
0.158
4.11
4.01
over 7.94 thru 9.53
0.203
0.199
5.16
5.06
over 9.53 thru 11.91
0.243
0.239
6.17
6.07
over 11.91 thru 14.29
0.303
0.297
7.70
7.55
over 14.29 thru 16.67
0.373
0.367
9.47
9.32
over 16.67 thru 19.05
0.443
0.437
11.25
11.10
over 19.05 thru 22.23
0.514
0.508
13.05
12.90
over 22.23 thru 25.40
0.609
0.601
15.47
15.27
over 25.40 thru 30.16
0.700
0.692
17.78
17.58
over 30.16 thru 34.93
0.817
0.809
20.75
20.55
To fit split sleeve collet type drill drivers. See page 878.
Copyright 2004, Industrial Press, Inc., New York, NY
Length of Tang, K Inches 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8
Millimeters 7.0 8.0 8.5 9.5 11.0 12.5 14.5 16.0 17.5 19.0 20.5 22.0
Machinery's Handbook 27th Edition TWIST DRILLS
867
Table 4. American National Standard Straight Shank Twist Drills — Screw Machine Length — Over 1 in. (25.4 mm) Dia. ANSI/ASME B94.11M-1993
Diameter of Drill D Frac.
mm
Decimal Inch Equivalent
Millimeter Equivalent
25.50
1.0039
26.00 11⁄16 28.00 11⁄8
Flute Length
Overall Length
F
L
Shank Diameter A
Inch
mm
Inch
mm
Inch
mm
25.500
4
102
6
152
0.9843
25.00
1.0236
26.000
4
102
6
152
0.9843
25.00
1.0625
26.988
4
102
6
152
1.0000
25.40
1.1024
28.000
4
102
6
152
0.9843
25.00
1.1250
28.575
4
102
6
152
1.0000
25.40
1.1811
30.000
41⁄4
108
65⁄8
168
0.9843
25.00
13⁄16
1.1875
30.162
41⁄4
108
65⁄8
168
1.0000
25.40
11⁄4
1.2500
31.750
43⁄8
111
63⁄4
171
1.0000
25.40
32.00
1.2598
32.000
43⁄8
111
7
178
1.2402
31.50
1.3125
33.338
43⁄8
111
7
178
1.2500
31.75
34.00
1.3386
34.000
41⁄2
114
71⁄8
181
1.2402
31.50
1.3750
34.925
41⁄2
114
71⁄8
181
1.2500
31.75
1.4173
36.000
43⁄4
121
73⁄8
187
1.2402
31.50
1.4375
36.512
43⁄4
121
73⁄8
187
1.2500
31.75
1.4961
38.000
47⁄8
124
71⁄2
190
1.2402
31.50
11⁄2
1.5000
38.100
47⁄8
124
71⁄2
190
1.2500
31.75
19⁄16
1.5625
39.688
47⁄8
124
73⁄4
197
1.5000
38.10
1.5748
40.000
47⁄8
124
73⁄4
197
1.4961
38.00
1.6250
41.275
47⁄8
124
73⁄4
197
1.5000
38.10
42.00
1.6535
42.000
51⁄8
130
8
203
1.4961
38.00
1.6875
42.862
51⁄8
130
8
203
1.5000
38.10
44.00
1.7323
44.000
51⁄8
130
8
203
1.4961
38.00
1.7500
44.450
51⁄8
130
8
203
1.5000
38.10
1.8110
46.000
53⁄8
137
81⁄4
210
1.4961
38.00
113⁄16
1.8125
46.038
53⁄8
137
81⁄4
210
1.5000
38.10
17⁄8
1.8750
47.625
53⁄8
137
81⁄4
210
1.5000
38.10
1.8898
48.000
55⁄8
143
81⁄2
216
1.4961
38.00
1.9375
49.212
55⁄8
143
81⁄2
216
1.5000
38.10
1.9685
50.000
55⁄8
143
81⁄2
216
1.4961
38.00
2.0000
50.800
55⁄8
143
81⁄2
216
1.5000
38.10
30.00
15⁄16
13⁄8 36.00 17⁄16 38.00
40.00 15⁄8
111⁄16
13⁄4 46.00
48.00 115⁄16 50.00 2
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 868
TWIST DRILLS
Table 5. American National Taper Shank Twist Drills Fractional and Metric Sizes ANSI/ASME B94.11M-1993 Drill Diameter, D Equivalent Fraction
mm 3.00
1⁄ 8
3.20 3.50 9⁄ 64
3.80 5⁄ 32
4.00 4.20 11⁄ 64
4.50 3⁄ 16
4.80 5.00 13⁄ 64
5.20 5.50 7⁄ 32
5.80 15⁄ 64
6.00 6.20 1⁄ 4
6.50 17⁄ 64
6.80 7.00 9⁄ 32
7.20 7.50 19⁄ 64
7.80 5⁄ 16
8.00 8.20 21⁄ 64
8.50 11⁄ 32
8.80 9.00 23⁄ 64
9.20 9.50 3⁄ 8
9.80 25⁄ 64
10.00
Decimal Inch 0.1181 0.1250 0.1260 0.1378 0.1406 0.1496 0.1562 0.1575 0.1654 0.1719 0.1772 0.1875 0.1890 0.1969 0.2031 0.2047 0.2165 0.2183 0.2223 0.2344 0.2362 0.2441 0.2500 0.2559 0.2656 0.2677 0.2756 0.2812 0.2835 0.2953 0.2969 0.3071 0.3125 0.3150 0.3228 0.3281 0.3346 0.3438 0.3465 0.3543 0.3594 0.3622 0.3740 0.3750 0.3858 0.3906 0.3937
mm 3.000 3.175 3.200 3.500 3.571 3.800 3.967 4.000 4.200 4.366 4.500 4.762 4.800 5.000 5.159 5.200 5.500 5.558 5.800 5.954 6.000 6.200 6.350 6.500 6.746 6.800 7.000 7.142 7.200 7.500 7.541 7.800 7.938 8.000 8.200 8.334 8.500 8.733 8.800 9.000 9.129 9.200 9.500 9.525 9.800 9.921 10.000
Morse Taper No. 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
Regular Shank Flute Length Overall Length F L Inch mm Inch mm 7 1 48 130 1 ⁄8 5 ⁄8 48 130 17⁄8 51⁄8 54 137 53⁄8 21⁄8 54 137 21⁄8 53⁄8 1 3 54 137 2 ⁄8 5 ⁄8 54 137 53⁄8 21⁄8 54 137 21⁄8 53⁄8 64 146 21⁄2 53⁄4 1 3 64 146 5 ⁄4 2 ⁄2 1 3 64 146 2 ⁄2 5 ⁄4 64 146 53⁄4 21⁄2 64 146 21⁄2 53⁄4 70 6 152 23⁄4 3 70 6 152 2 ⁄4 70 6 152 23⁄4 70 6 152 23⁄4 70 6 152 23⁄4 70 6 152 23⁄4 7 1 73 156 2 ⁄8 6 ⁄8 73 156 27⁄8 61⁄8 73 156 27⁄8 61⁄8 73 156 27⁄8 61⁄8 7 1 73 156 2 ⁄8 6 ⁄8 1 3 76 159 6 ⁄4 3 76 159 61⁄4 159 3 76 61⁄4 3 76 159 61⁄4 1 3 76 159 6 ⁄4 1 3 79 162 6 ⁄8 3 ⁄8 79 162 31⁄8 63⁄8 79 162 31⁄8 63⁄8 79 162 63⁄8 31⁄8 1 3 79 162 3 ⁄8 6 ⁄8 1 1 83 165 3 ⁄4 6 ⁄2 83 165 61⁄2 31⁄4 83 165 31⁄4 61⁄2 83 165 31⁄4 61⁄2 1 1 83 165 3 ⁄4 6 ⁄2 89 171 31⁄2 63⁄4 89 171 31⁄2 63⁄4 89 171 31⁄2 63⁄4 1 3 89 171 3 ⁄2 6 ⁄4 1 3 89 171 3 ⁄2 6 ⁄4 89 171 31⁄2 63⁄4 92 7 178 35⁄8 92 7 178 35⁄8 92 7 178 35⁄8
Morse Taper No. … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … 2 … 2 …
Larger or Smaller Shanka Flute Length Overall Length F L Inch mm Inch mm … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … 89 187 31⁄2 73⁄8 … … … … 92 190 35⁄8 71⁄2 … … … …
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TWIST DRILLS
869
Table 5. (Continued) American National Taper Shank Twist Drills Fractional and Metric Sizes ANSI/ASME B94.11M-1993 Drill Diameter, D Equivalent Fraction
mm 10.20
13⁄ 32
10.50 27⁄ 64
10.80 11.00 7⁄ 16
11.20 11.50 29⁄ 64
11.80 15⁄ 32
12.00 12.20 31⁄ 64
12.50 1⁄ 2
12.80 13.00 33⁄ 64
13.20 17⁄ 32
13.50 13.80 35⁄ 64
14.00 14.25 9⁄ 16
14.50 37⁄ 64
14.75 15.00 19⁄ 32
15.25 39⁄ 64
15.50 15.75 5⁄ 8
16.00 16.25 41⁄ 64
16.50 21⁄ 32
16.75 17.00 43⁄ 64
17.25 11⁄ 16
17.50 45⁄ 64
18.00 23⁄ 32
18.50 47⁄ 64
Decimal Inch 0.4016 0.4062 0.4134 0.4219 0.4252 0.4331 0.4375 0.4409 0.4528 0.4531 0.4646 0.4688 0.4724 0.4803 0.4844 0.4921 0.5000 0.5034 0.5118 0.5156 0.5197 0.5312 0.5315 0.5433 0.5469 0.5572 0.5610 0.5625 0.5709 0.5781 0.5807 0.5906 0.5938 0.6004 0.6094 0.6102 0.6201 0.6250 0.6299 0.6398 0.6406 0.6496 0.6562 0.6594 0.6693 0.6719 0.6791 0.6875 0.6880 0.7031 0.7087 0.7188 0.7283 0.7344
mm 10.200 10.320 10.500 10.716 10.800 11.000 11.112 11.200 11.500 11.509 11.800 11.906 12.000 12.200 12.304 12.500 12.700 12.800 13.000 13.096 13.200 13.492 13.500 13.800 13.891 14.000 14.250 14.288 14.500 14.684 14.750 15.000 15.083 15.250 15.479 15.500 15.750 15.875 16.000 16.250 16.271 16.500 16.667 16.750 17.000 17.066 17.250 17.462 17.500 17.859 18.000 18.258 18.500 18.654
Morse Taper No. 1 1 1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
Regular Shank Flute Length Overall Length F L Inch mm Inch mm 35⁄8 92 7 178 92 7 178 35⁄8 7 1 98 184 3 ⁄8 7 ⁄4 7 1 98 184 3 ⁄8 7 ⁄4 98 184 71⁄4 37⁄8 98 184 37⁄8 71⁄4 98 184 37⁄8 71⁄4 1 1 105 190 7 ⁄2 4 ⁄8 1 1 105 190 4 ⁄8 7 ⁄2 105 190 41⁄8 71⁄2 105 190 71⁄2 41⁄8 105 190 41⁄8 71⁄2 3 1 111 210 4 ⁄8 8 ⁄4 111 210 81⁄4 43⁄8 111 210 43⁄8 81⁄4 111 210 43⁄8 81⁄4 3 1 111 210 4 ⁄8 8 ⁄4 5 1 117 216 4 ⁄8 8 ⁄2 117 216 45⁄8 81⁄2 117 216 45⁄8 81⁄2 117 216 45⁄8 81⁄2 5 1 117 216 4 ⁄8 8 ⁄2 5 1 117 216 4 ⁄8 8 ⁄2 124 222 47⁄8 83⁄4 124 222 47⁄8 83⁄4 124 222 47⁄8 83⁄4 7 3 124 222 4 ⁄8 8 ⁄4 7 3 124 222 4 ⁄8 8 ⁄4 124 222 47⁄8 83⁄4 124 222 47⁄8 83⁄4 124 222 83⁄4 47⁄8 7 3 124 222 4 ⁄8 8 ⁄4 124 222 47⁄8 83⁄4 124 222 83⁄4 47⁄8 124 222 47⁄8 83⁄4 7 3 124 222 4 ⁄8 8 ⁄4 7 3 124 222 8 ⁄4 4 ⁄8 124 222 47⁄8 83⁄4 130 9 229 51⁄8 130 9 229 51⁄8 1 130 9 229 5 ⁄8 1 130 9 229 5 ⁄8 130 9 229 51⁄8 137 235 53⁄8 91⁄4 137 235 53⁄8 91⁄4 137 235 53⁄8 91⁄4 137 235 53⁄8 91⁄4 137 235 53⁄8 91⁄4 143 241 91⁄2 55⁄8 5 1 143 241 5 ⁄8 9 ⁄2 5 1 143 241 5 ⁄8 9 ⁄2 143 241 55⁄8 91⁄2 149 248 57⁄8 93⁄4 149 248 57⁄8 93⁄4
Morse Taper No. … 2 … 2 … … 2 … … 2 … 2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 … … … … … … … … … … … … 3 … 3 … … 3 … 3 … 3 … 3 … 3
Larger or Smaller Shanka Flute Length Overall Length F L Inch mm Inch mm … … … … 92 190 35⁄8 71⁄2 … … … … 98 197 37⁄8 73⁄4 … … … … … … … … 98 197 37⁄8 73⁄4 … … … … … … … … 105 8 203 41⁄8 … … … … 105 8 203 41⁄8 3 3 111 197 4 ⁄8 7 ⁄4 111 197 43⁄8 73⁄4 111 197 43⁄8 73⁄4 111 197 43⁄8 73⁄4 3 3 111 197 4 ⁄8 7 ⁄4 5 117 8 203 4 ⁄8 117 8 203 45⁄8 117 8 203 45⁄8 117 8 203 45⁄8 5 117 8 203 4 ⁄8 5 117 8 203 4 ⁄8 124 210 47⁄8 81⁄4 124 210 47⁄8 81⁄4 124 210 47⁄8 81⁄4 7 1 124 210 4 ⁄8 8 ⁄4 7 1 124 210 4 ⁄8 8 ⁄4 … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … 130 248 51⁄8 93⁄4 … … … … 130 248 51⁄8 93⁄4 … … … … … … … … 3 137 10 254 5 ⁄8 … … … … 137 10 254 53⁄8 … … … … 143 260 55⁄8 101⁄4 … … … … 143 260 55⁄8 101⁄4 … … … … 149 267 57⁄8 101⁄2
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 870
TWIST DRILLS Table 5. (Continued) American National Taper Shank Twist Drills Fractional and Metric Sizes ANSI/ASME B94.11M-1993 Drill Diameter, D Equivalent
Fraction
mm 19.00
3⁄ 4 49⁄ 64
19.50 25⁄ 32
20.00 51⁄ 64
20.50 13⁄ 16
21.00 53⁄ 64 27⁄ 32
21.50 55⁄ 64
22.00 7⁄ 8
22.50 57⁄ 64
23.00 29⁄ 32 59⁄ 64
23.50 15⁄ 16
24.00 61⁄ 64
24.50 31⁄ 32
25.00 63⁄ 64
1 25.50 11⁄64 26.00 11⁄32 26.50 13⁄64 11⁄16 27.00 15⁄64 27.50 13⁄32 28.00 17⁄64 28.50 11⁄8 19⁄64 29.00 15⁄32 29.50 111⁄64 30.00 13⁄16 30.50 113⁄64
Decimal Inch 0.7480 0.7500 0.7656 0.7677 0.7812 0.7821 0.7969 0.8071 0.8125 0.8268 0.8281 0.8438 0.8465 0.8594 0.8661 0.8750 0.8858 0.8906 0.9055 0.9062 0.9219 0.9252 0.9375 0.9449 0.9531 0.9646 0.9688 0.9843 0.9844 1.0000 1.0039 1.0156 1.0236 1.0312 1.0433 1.0469 1.0625 1.0630 1.0781 1.0827 1.0938 1.1024 1.1094 1.1220 1.1250 1.1406 1.1417 1.1562 1.1614 1.1719 1.1811 1.1875 1.2008 1.2031
mm 19.000 19.050 19.446 19.500 19.843 20.000 20.241 20.500 20.638 21.000 21.034 21.433 21.500 21.829 22.000 22.225 22.500 22.621 23.000 23.017 23.416 23.500 23.813 24.000 24.209 24.500 24.608 25.000 25.004 25.400 25.500 25.796 26.000 26.192 26.500 26.591 26.988 27.000 27.384 27.500 27.783 28.000 28.179 28.500 28.575 28.971 29.000 29.367 29.500 29.797 30.000 30.162 30.500 30.559
Morse Taper No. 2 2 2 2 2 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4
Regular Shank Flute Length Overall Length F L Inch mm Inch mm 57⁄8 93⁄4 149 248 149 248 57⁄8 93⁄4 7 6 152 251 9 ⁄8 7 6 152 251 9 ⁄8 6 152 251 97⁄8 156 273 61⁄8 103⁄4 156 273 61⁄8 103⁄4 1 3 156 273 10 ⁄4 6 ⁄8 1 3 156 273 6 ⁄8 10 ⁄4 156 273 61⁄8 103⁄4 156 273 61⁄8 103⁄4 156 273 61⁄8 103⁄4 1 3 156 273 6 ⁄8 10 ⁄4 156 273 61⁄8 103⁄4 156 273 61⁄8 103⁄4 156 273 61⁄8 103⁄4 1 3 156 273 10 ⁄4 6 ⁄8 1 3 156 273 6 ⁄8 10 ⁄4 156 273 61⁄8 103⁄4 156 273 61⁄8 103⁄4 156 273 61⁄8 103⁄4 1 3 156 273 10 ⁄4 6 ⁄8 1 3 156 273 6 ⁄8 10 ⁄4 162 11 279 63⁄8 162 11 279 63⁄8 162 11 279 63⁄8 3 162 11 279 6 ⁄8 3 162 11 279 6 ⁄8 162 11 279 63⁄8 162 11 279 63⁄8 165 283 111⁄8 61⁄2 1 1 165 283 6 ⁄2 11 ⁄8 165 283 61⁄2 111⁄8 165 283 61⁄2 111⁄8 168 286 65⁄8 111⁄4 5 1 168 286 6 ⁄8 11 ⁄4 5 1 168 286 6 ⁄8 11 ⁄4 168 286 65⁄8 111⁄4 175 318 67⁄8 121⁄2 175 318 121⁄2 67⁄8 7 1 175 318 6 ⁄8 12 ⁄2 1 3 181 324 7 ⁄8 12 ⁄4 181 324 71⁄8 123⁄4 181 324 71⁄8 123⁄4 181 324 71⁄8 123⁄4 1 7 184 327 7 ⁄4 12 ⁄8 184 327 71⁄4 127⁄8 184 327 71⁄4 127⁄8 187 13 330 73⁄8 3 187 13 330 7 ⁄8 187 13 330 73⁄8 187 13 330 73⁄8 190 333 71⁄2 131⁄8 190 333 71⁄2 131⁄8
Morse Taper No. … 3 3 … 3 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 … … … … … … … … … 4 … … … 4 … … 4 … 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3
Larger or Smaller Shanka Flute Length Overall Length F L Inch mm Inch mm … … … … 149 267 57⁄8 101⁄2 5 6 152 270 10 ⁄8 … … … … 6 152 270 105⁄8 156 10 254 61⁄8 156 10 254 61⁄8 1 156 10 254 6 ⁄8 1 156 10 254 6 ⁄8 156 10 254 61⁄8 156 10 254 61⁄8 156 10 254 61⁄8 1 156 10 254 6 ⁄8 156 10 254 61⁄8 156 10 254 61⁄8 156 10 254 61⁄8 1 156 10 254 6 ⁄8 1 156 10 254 6 ⁄8 156 10 254 61⁄8 156 10 254 61⁄8 … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … 162 12 305 63⁄8 … … … … … … … … … … … … 165 308 61⁄2 121⁄8 … … … … … … … … 5 1 168 311 6 ⁄8 12 ⁄4 … … … … 175 292 67⁄8 111⁄2 175 292 67⁄8 111⁄2 175 292 67⁄8 111⁄2 1 3 181 298 7 ⁄8 11 ⁄4 181 298 71⁄8 113⁄4 181 298 71⁄8 113⁄4 181 298 71⁄8 113⁄4 1 7 184 302 7 ⁄4 11 ⁄8 184 302 71⁄4 117⁄8 184 302 71⁄4 117⁄8 187 12 305 73⁄8 3 187 12 305 7 ⁄8 187 12 305 73⁄8 187 12 305 73⁄8 190 308 71⁄2 121⁄8 190 308 71⁄2 121⁄8
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TWIST DRILLS
871
Table 5. (Continued) American National Taper Shank Twist Drills Fractional and Metric Sizes ANSI/ASME B94.11M-1993 Drill Diameter, D Equivalent Fraction 17⁄32
mm 31.00
115⁄64 31.50 11⁄4 32.00 117⁄64 32.50 19⁄32 119⁄64 33.00 15⁄16 33.50 121⁄64 34.00 111⁄32 34.50 123⁄64 13⁄8 35.00 125⁄64 35.50 113⁄32 36.00 127⁄64 36.50 17⁄16 129⁄64 37.00 115⁄32 37.50 131⁄64 38.00 11⁄2 133⁄64 117⁄32 39.00 135⁄64 19⁄16 40.00 137⁄64 119⁄32 139⁄64 41.00 15⁄8 141⁄64 42.00 121⁄32 143⁄64 111⁄16 43.00 145⁄64 123⁄32 44.00
Decimal Inch 1.2188 1.2205 1.2344 1.2402 1.2500 1.2598 1.2656 1.2795 1.2812 1.2969 1.2992 1.3125 1.3189 1.3281 1.3386 1.3438 1.3583 1.3594 1.3750 1.3780 1.3906 1.3976 1.4062 1.4173 1.4219 1.4370 1.4375 1.4531 1.4567 1.4688 1.4764 1.4844 1.4961 1.5000 1.5156 1.5312 1.5354 1.5469 1.5625 1.5748 1.5781 1.5938 1.6094 1.6142 1.6250 1.6406 1.6535 1.6562 1.6719 1.6875 1.6929 1.7031 1.7188 1.7323
mm 30.958 31.000 31.354 31.500 31.750 32.000 32.146 32.500 32.542 32.941 33.000 33.338 33.500 33.734 34.000 34.133 34.500 34.529 34.925 35.000 35.321 35.500 35.717 36.000 36.116 36.500 36.512 36.909 37.000 37.308 37.500 37.704 38.000 38.100 38.496 38.892 39.000 39.291 39.688 40.000 40.084 40.483 40.879 41.000 41.275 41.671 42.000 42.067 42.466 42.862 43.000 43.259 43.658 44.000
Morse Taper No. 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 … 5 5 … 5 5 … 5 … 5 5 … 5 5 … 5 5 … 5 5
Regular Shank Flute Length Overall Length F L Inch mm Inch mm 71⁄2 131⁄8 190 333 200 343 77⁄8 131⁄2 7 1 200 343 7 ⁄8 13 ⁄2 7 1 200 343 7 ⁄8 13 ⁄2 200 343 77⁄8 131⁄2 216 359 81⁄2 141⁄8 216 359 81⁄2 141⁄8 1 1 216 359 14 ⁄8 8 ⁄2 1 1 216 359 8 ⁄2 14 ⁄8 219 362 85⁄8 141⁄4 219 362 141⁄4 85⁄8 219 362 85⁄8 141⁄4 3 3 222 365 8 ⁄4 14 ⁄8 222 365 83⁄4 143⁄8 222 365 83⁄4 143⁄8 222 365 83⁄4 143⁄8 7 1 225 368 14 ⁄2 8 ⁄8 7 1 225 368 8 ⁄8 14 ⁄2 225 368 87⁄8 141⁄2 371 9 229 145⁄8 9 229 371 145⁄8 5 371 9 229 14 ⁄8 5 9 229 371 14 ⁄8 232 375 91⁄8 143⁄4 232 375 91⁄8 143⁄4 232 375 91⁄8 143⁄4 1 3 232 375 9 ⁄8 14 ⁄4 1 7 235 378 9 ⁄4 14 ⁄8 235 378 91⁄4 147⁄8 235 378 91⁄4 147⁄8 238 15 381 93⁄8 3 238 15 381 9 ⁄8 238 15 381 93⁄8 238 15 381 93⁄8 … … … … 3 3 238 416 9 ⁄8 16 ⁄8 5 5 244 422 16 ⁄8 9 ⁄8 … … … … 244 422 95⁄8 165⁄8 251 429 167⁄8 97⁄8 … … … … 7 7 251 429 9 ⁄8 16 ⁄8 … … … … 10 254 17 432 10 254 17 432 … … … … 257 435 101⁄8 171⁄8 257 435 101⁄8 171⁄8 … … … … 257 435 101⁄8 171⁄8 1 1 257 435 10 ⁄8 17 ⁄8 … … … … 257 435 101⁄8 171⁄8 257 435 101⁄8 171⁄8
Morse Taper No. 3 3 3 3 3 … … … … … … … … … … … … … … … … … … … … … … … … … … … … … 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4
Larger or Smaller Shanka Flute Length Overall Length F L Inch mm Inch mm 71⁄2 121⁄8 190 308 200 318 77⁄8 121⁄2 7 1 200 318 7 ⁄8 12 ⁄2 7 1 200 318 7 ⁄8 12 ⁄2 200 318 77⁄8 121⁄2 … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … 238 15 381 93⁄4 3 238 15 381 9 ⁄8 244 387 95⁄8 151⁄4 244 387 95⁄8 151⁄4 244 387 95⁄8 151⁄4 251 394 97⁄8 151⁄2 7 1 251 394 9 ⁄8 15 ⁄2 7 1 251 394 9 ⁄8 15 ⁄2 10 254 397 155⁄8 10 254 397 155⁄8 10 254 397 155⁄8 1 3 257 400 10 ⁄8 15 ⁄4 257 400 101⁄8 153⁄4 257 400 101⁄8 153⁄4 257 400 101⁄8 153⁄4 1 3 257 400 10 ⁄8 15 ⁄4 1 3 257 400 10 ⁄8 15 ⁄4 257 400 101⁄8 153⁄4 257 400 101⁄8 153⁄4 264 413 103⁄8 161⁄4
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 872
TWIST DRILLS Table 5. (Continued) American National Taper Shank Twist Drills Fractional and Metric Sizes ANSI/ASME B94.11M-1993 Drill Diameter, D Equivalent
Fraction 147⁄64 13⁄4
mm
45.00 125⁄32 46.00 113⁄16 127⁄32 47.00 17⁄8 48.00 129⁄32 49.00 115⁄16 50.00 131⁄32 2 51.00 21⁄32 52.00 21⁄16 53.00 23⁄32 21⁄8 54.00 25⁄32 55.00 23⁄16 56.00 27⁄32 57.00 21⁄4 58.00 25⁄16 59.00 60.00 23⁄8 61.00 27⁄16 62.00 63.00 21⁄2 64.00 65.00 29⁄16 66.00 25⁄8 67.00 68.00 211⁄16 69.00 23⁄4 70.00 71.00 213⁄16
Decimal Inch 1.7344 1.7500 1.7717 1.7812 1.8110 1.8125 1.8438 1.8504 1.8750 1.8898 1.9062 1.9291 1.9375 1.9625 1.9688 2.0000 2.0079 2.0312 2.0472 2.0625 2.0866 2.0938 2.1250 2.1260 2.1562 2.1654 2.1875 2.2000 2.2188 2.2441 2.2500 2.2835 2.3125 2.3228 2.3622 2.3750 2.4016 2.4375 2.4409 2.4803 2.5000 2.5197 2.5591 2.5625 2.5984 2.6250 2.6378 2.6772 2.6875 2.7165 2.7500 2.7559 2.7953 2.8125
mm 44.054 44.450 45.000 45.242 46.000 46.038 46.833 47.000 47.625 48.000 48.417 49.000 49.212 50.000 50.008 50.800 51.000 51.592 52.000 52.388 53.000 53.183 53.975 54.000 54.767 55.000 55.563 56.000 56.358 57.000 57.150 58.000 58.738 59.000 60.000 60.325 61.000 61.912 62.000 63.000 63.500 64.000 65.000 65.088 66.000 66.675 67.000 68.000 68.262 69.000 69.850 70.000 71.000 71.438
Morse Taper No. … 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5
Regular Shank Flute Length Overall Length F L Inch mm Inch mm … … … … 257 435 101⁄8 171⁄8 1 1 257 435 10 ⁄8 17 ⁄8 257 435 101⁄8 171⁄8 257 435 171⁄8 101⁄8 257 435 101⁄8 171⁄8 257 435 101⁄8 171⁄8 3 3 264 441 17 ⁄8 10 ⁄8 3 3 264 441 10 ⁄8 17 ⁄8 264 441 103⁄8 173⁄8 264 441 103⁄8 173⁄8 264 441 103⁄8 173⁄8 3 3 264 441 10 ⁄8 17 ⁄8 264 441 173⁄8 103⁄8 264 441 103⁄8 173⁄8 264 441 103⁄8 173⁄8 3 3 264 441 17 ⁄8 10 ⁄8 3 3 264 441 10 ⁄8 17 ⁄8 260 441 101⁄4 173⁄8 260 441 101⁄4 173⁄8 260 441 101⁄4 173⁄8 1 3 260 441 10 ⁄4 17 ⁄8 1 3 260 441 10 ⁄4 17 ⁄8 260 441 101⁄4 173⁄8 260 441 101⁄4 173⁄8 260 441 101⁄4 173⁄8 1 3 260 441 10 ⁄4 17 ⁄4 1 3 257 441 17 ⁄8 10 ⁄8 257 441 101⁄8 173⁄8 257 441 101⁄8 173⁄8 257 441 101⁄8 173⁄8 1 3 257 441 10 ⁄8 17 ⁄8 257 441 101⁄8 173⁄8 257 441 173⁄8 101⁄8 257 441 101⁄8 173⁄8 1 3 257 441 10 ⁄8 17 ⁄8 1 3 286 476 18 ⁄4 11 ⁄4 286 476 111⁄4 183⁄4 286 476 111⁄4 183⁄4 286 476 183⁄4 111⁄4 1 3 286 476 11 ⁄4 18 ⁄4 7 1 302 495 11 ⁄8 19 ⁄2 302 495 191⁄2 117⁄8 302 495 117⁄8 191⁄2 302 495 117⁄8 191⁄2 7 1 302 495 11 ⁄8 19 ⁄2 324 518 123⁄4 203⁄8 324 518 123⁄4 203⁄8 324 518 123⁄4 203⁄8 3 3 324 518 12 ⁄4 20 ⁄8 3 3 324 518 12 ⁄4 20 ⁄8 340 537 211⁄8 133⁄8 340 537 133⁄8 211⁄8 340 537 133⁄8 211⁄8
Morse Taper No. 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … …
Larger or Smaller Shanka Flute Length Overall Length F L Inch mm Inch mm 103⁄8 161⁄4 264 413 264 413 103⁄4 161⁄4 3 1 264 413 10 ⁄8 16 ⁄4 3 1 264 413 10 ⁄8 16 ⁄4 264 413 103⁄8 161⁄4 264 413 103⁄8 161⁄4 264 413 103⁄8 161⁄4 1 1 267 419 10 ⁄2 16 ⁄2 1 1 267 419 10 ⁄2 16 ⁄2 267 419 101⁄2 161⁄2 267 419 101⁄2 161⁄2 270 422 105⁄8 165⁄8 5 5 270 422 10 ⁄8 16 ⁄8 270 422 105⁄8 165⁄8 270 422 105⁄8 165⁄8 270 422 105⁄8 165⁄8 … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … … …
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TWIST DRILLS
873
Table 5. (Continued) American National Taper Shank Twist Drills Fractional and Metric Sizes ANSI/ASME B94.11M-1993 Drill Diameter, D Equivalent Fraction
mm 72.00 73.00
27⁄8 74.00 215⁄16 75.00 76.00 3 77.00 78.00 31⁄8 31⁄4 31⁄2
Decimal Inch
mm
2.8346 2.8740 2.8750 2.9134 2.9375 2.9528 2.9921 3.0000 3.0315 3.0709 3.1250 3.2500 3.5000
72.000 73.000 73.025 74.000 74.612 75.000 76.000 76.200 77.000 78.000 79.375 82.550 88.900
Morse Taper No. 5 5 5 5 5 5 5 5 6 6 6 6 …
Regular Shank Flute Length Overall Length F L Inch mm Inch mm 133⁄8 133⁄8 133⁄8 14 14 14 14 14 145⁄8 145⁄8 145⁄8 151⁄2 …
340 211⁄8 340 211⁄8 340 211⁄8 356 213⁄4 356 213⁄4 356 213⁄4 356 213⁄4 356 213⁄4 371 241⁄2 371 241⁄2 371 241⁄2 394 251⁄2 … …
Morse Taper No. … … … … … … … … 5 5 5 5 5
537 537 537 552 552 552 552 552 622 622 622 648 …
Larger or Smaller Shanka Flute Length Overall Length F L Inch mm Inch mm … … … … … … … … 141⁄4 141⁄4 141⁄4 151⁄4 161⁄4
… … … … … … … … 362 362 362 387 413
… … … … … … … … 22 22 22 23 24
… … … … … … … … 559 559 559 584 610
a Larger or smaller than regular shank.
Table 6. American National Standard Combined Drills and Countersinks — Plain and Bell Types ANSI/ASME B94.11M-1993 BELL TYPE
PLAIN TYPE
Size Designation
Body Diameter A Inches Millimeters 1⁄ 8 1⁄ 8 1⁄ 8 3⁄ 16 1⁄ 4 5⁄ 16 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
00 0 1 2 3 4 5 6 7 8
Plain Type Drill Diameter D Inches Millimeters
3.18 3.18 3.18 4.76 6.35 7.94 11.11 12.70 15.88 19.05
.025 1⁄ 32 3⁄ 64 5⁄ 64 7⁄ 64 1⁄ 8 3⁄ 16 7⁄ 32 1⁄ 4 5⁄ 16
Drill Length C Millimeters
Inches
0.64 0.79 1.19 1.98 2.78 3.18 4.76 5.56 6.35 7.94
.030 .038
11⁄8 11⁄8 11⁄4 17⁄8 2
0.76 0.97 1.19 1.98 2.78 3.18 4.76 5.56 6.35 7.94
3⁄ 64 5⁄ 64 7⁄ 64 1⁄ 8 3⁄ 16 7⁄ 32 1⁄ 4 5⁄ 16
Overall Length L Millimeters
Inches
29 29 32 48 51 54 70 76 83 89
21⁄8 23⁄4 3 31⁄4 31⁄2
Bell Type
Size Designation 11 12 13 14 15 16 17 18
Body Diameter
Drill Diameter
Bell Diameter
Drill Length
A
D
E
C
Inches 1⁄ 8 3⁄ 16 1⁄ 4 5⁄ 16 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
mm 3.18 4.76 6.35 7.94 11.11 12.70 15.88 19.05
Overall Length L
Inches
mm
Inches
mm
Inches
mm
Inches
mm
3⁄ 64 1⁄ 16 3⁄ 32 7⁄ 64 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4
1.19
0.10
2.5
1.19
11⁄4
32
1.59
0.15
3.8
1.59
0.20
5.1
2.38
17⁄8 2
48
2.38 2.78
0.25
6.4
3⁄ 64 1⁄ 16 3⁄ 32 7⁄ 64 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4
2.78
21⁄8
54
3.97
23⁄4 3
70
4.76 5.56
31⁄4
83
6.35
31⁄2
89
3.97
0.35
8.9
4.76
0.40
10.2
5.56
0.50
12.7
6.35
0.60
15.2
Copyright 2004, Industrial Press, Inc., New York, NY
51
76
Machinery's Handbook 27th Edition 874
TWIST DRILLS
Table 7. American National Standard Three- and Four-Flute Taper Shank Core Drills — Fractional Sizes Only ANSI/ASME B94.11M-1993 Drill Diameter, D Equivalent Inch 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2 17⁄ 32 9⁄ 16 19⁄ 32 5⁄ 8 21⁄ 32 11⁄ 16 23⁄ 32 3⁄ 4 25⁄ 32 13⁄ 16 27⁄ 32 7⁄ 8 29⁄ 32 15⁄ 16 31⁄ 32
Three-Flute Drills Morse Taper No.
Overall Length
F
L
Decimal Inch
mm
A
Inch
0.2500
6.350
1
0.2812
7.142
1
0.3175
7.938
1
0.3438
8.733
1
0.3750
9.525
1
0.4062
10.319
1
0.4375
11.112
1
0.4688
11.908
1
0.5000
12.700
2
0.5312
13.492
2
0.5625
14.288
2
0.5938
15.083
2
0.6250
15.815
2
0.6562
16.668
2
0.6875
17.462
2
0.7188
18.258
2
0.7500
19.050
2
0.7812
19.842
Four-Flute Drills
Flute Length
Morse Taper No.
Flute Length
Overall Length
F
L
mm
Inch
mm
A
Inch
mm
Inch
mm
27⁄8 3
73
61⁄8
156
…
…
…
…
…
76
159
…
…
…
…
…
31⁄8 31⁄4 31⁄2 35⁄8 37⁄8 41⁄8 43⁄8 45⁄8 47⁄8 47⁄8 47⁄8 51⁄8 53⁄8 55⁄8 57⁄8
79
162
…
…
…
…
…
165
…
…
…
…
…
89
61⁄4 63⁄8 61⁄2 63⁄4
171
…
…
…
…
…
92
7
178
…
…
…
…
…
98
184
…
…
…
…
…
190
…
…
…
…
…
210
2
43⁄8
111
81⁄4
210
216
2
45⁄8
117
81⁄2
216
222
2
47⁄8
124
83⁄4
222
222
2
47⁄8
124
83⁄4
222
124
71⁄4 71⁄2 81⁄4 81⁄2 83⁄4 83⁄4 83⁄4
222
2
47⁄8
124
222
130
9
229
2
51⁄8
130
83⁄4 9
137
91⁄4
235
2
53⁄8
137
91⁄4
235
143
91⁄2
241
2
55⁄8
143
91⁄2
241
149
93⁄4
248
2
93⁄4
248
152
251
57⁄8 6
149 152
156
97⁄8 103⁄4 103⁄4 103⁄4 103⁄4 103⁄4
251
156
97⁄8 103⁄4 103⁄4 103⁄4 103⁄4 103⁄4
162
162
11
279
162
11
279
165
111⁄8
283
168
111⁄4
286
175
121⁄2
318
181
123⁄4
324
184
327
187
127⁄8 13
190
131⁄8
333
200
131⁄2
343
216
141⁄8
359
2
6
0.8125
20.638
3
0.8438
21.433
3
0.8750
22.225
3
0.9062
23.019
3
0.9375
23.812
3
0.9688
24.608
3
1
1.0000
25.400
3
11⁄32
1.0312
26.192
3
11⁄16
1.0625
26.988
3
13⁄32
1.0938
27.783
4
11⁄8
1.1250
28.575
4
15⁄32
1.1562
29.367
4
13⁄16
1.1875
30.162
4
17⁄32
1.2188
30.958
4
11⁄4
1.2500
31.750
4
61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 63⁄8 63⁄8 61⁄2 65⁄8 67⁄8 71⁄8 71⁄4 73⁄8 71⁄2 77⁄8
19⁄32
1.2812
32.542
…
…
83
105 111 117 124 124
156
2
273
3
273
3
273
3
273
3
273
3
11
279
3
162
11
279
3
165
111⁄8
283
3
168
111⁄4
286
3
175
121⁄2
318
4
181
123⁄4
324
4
184
327
4
187
127⁄8 13
330
4
190
131⁄8
333
4
200
131⁄2 …
343
4
…
4
156 156 156
…
61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 63⁄8 63⁄8 61⁄2 65⁄8 67⁄8 71⁄8 71⁄4 73⁄8 71⁄2 77⁄8 81⁄2
156 156 156 156
Copyright 2004, Industrial Press, Inc., New York, NY
229
273 273 273 273 273
330
Machinery's Handbook 27th Edition TWIST DRILLS
875
Table 7. American National Standard Three- and Four-Flute Taper Shank Core Drills — Fractional Sizes Only ANSI/ASME B94.11M-1993 Drill Diameter, D
Three-Flute Drills
Equivalent Inch 15⁄16
Decimal Inch 1.3125
Morse Taper No.
Four-Flute Drills
Flute Length
Overall Length
F
L
mm 33.338
A …
Inch …
mm …
Inch …
mm …
Morse Taper No.
Flute Length
Overall Length
F
A 4
Inch 85⁄8
111⁄32 13⁄8
1.3438
34.133
…
…
…
…
…
4
1.3750
34.925
…
…
…
…
…
4
83⁄4 87⁄8
113⁄32
1.4062
35.717
…
…
…
…
…
4
9 91⁄8 91⁄4 93⁄8 93⁄8 95⁄8 97⁄8
L mm 219
Inch 141⁄4
mm 362
222
365
225
143⁄8 141⁄2
229
145⁄8
371
232
375
235
143⁄4 147⁄8
238
15
381
238
416
368
17⁄16 115⁄32 11⁄2 117⁄32 19⁄16 119⁄32 15⁄8 121⁄32 111⁄16 123⁄32 13⁄4 125⁄32 113⁄16 127⁄32 17⁄8 129⁄32 115⁄16 131⁄32
1.4375
36.512
…
…
…
…
…
4
1.4688
37.306
…
…
…
…
…
4
1.5000
38.100
…
…
…
…
…
4
1.5312
38.892
…
…
…
…
…
5
1.5675
39.688
…
…
…
…
…
5
1.5938
40.483
…
…
…
…
…
5
251
163⁄8 165⁄8 167⁄8
1.6250
41.275
…
…
…
…
…
5
10
254
17
432
1.6562
42.067
…
…
…
…
…
5
101⁄8
257
171⁄8
435
1.6875
42.862
…
…
…
…
…
5
101⁄8
257
171⁄8
435
1.7188
43.658
…
…
…
…
…
5
101⁄8
257
171⁄8
435
1.7500
44.450
…
…
…
…
…
5
101⁄8
257
171⁄8
435
1.7812
45.244
…
…
…
…
…
5
101⁄8
257
171⁄8
435
1.8125
46.038
…
…
…
…
…
5
101⁄8
257
171⁄8
435
1.8438
46.833
…
…
…
…
…
5
101⁄8
257
171⁄8
435
1.8750
47.625
…
…
…
…
…
5
103⁄8
264
173⁄8
441
1.9062
48.417
…
…
…
…
…
5
103⁄8
264
173⁄8
441
1.9375
49.212
…
…
…
…
…
5
264
50.008
…
…
…
…
…
5
2
2.0000
50.800
…
…
…
…
…
5
21⁄8 21⁄4 23⁄8 21⁄2
2.1250
53.975
…
…
…
…
…
5
2.2500
57.150
…
…
…
…
…
5
2.3750
60.325
…
…
…
…
…
5
2.5000
63.500
…
…
…
…
…
5
173⁄8 173⁄8 173⁄8 173⁄8 173⁄8 173⁄8 183⁄4
441
1.9688
103⁄8 103⁄8 103⁄8 101⁄4 101⁄8 101⁄8 111⁄4
244
264 264 260 257 257 286
378
422 429
441 441 441 441 441 476
Table 8. American National Standard Drill Drivers — Split-Sleeve, Collet Type ANSI B94.35-1972 (R1995)
Taper Number
G Overall Length
H Diameter at Gage Line
J Taper per Foota
0b
2.38
0.356
0.62460
2.22
0.16
1
2.62
0.475
0.59858
2.44
0.19
2
3.19
0.700
0.59941
2.94
0.25
K Length to Gage Line
L Driver Projection
a Taper rate in accordance with ANSI/ASME B5.10-1994 (R2002), Machine Tapers. b Size 0 is not an American National Standard but is included here to meet special needs.
All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 876
TWIST DRILLS Table 9. ANSI Three- and Four-Flute Straight Shank Core Drills — Fractional Sizes Only ANSI/ASME B94.11M-1993
Drill Diameter, D
Three-Flute Drills
Equivalent Inch 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2 17⁄ 32 9⁄ 16 19⁄ 32 5⁄ 8 21⁄ 32 11⁄ 16 23⁄ 32 3⁄ 4 25⁄ 32 13⁄ 16 27⁄ 32 7⁄ 8 29⁄ 32 15⁄ 16 31⁄ 32
Four-Flute Drills
Flute Length
Overall Length
Flute Length
F
L
F
Overall Length L
Decimal Inch
mm
Inch
mm
Inch
mm
Inch
mm
Inch
mm
0.2500
6.350
33⁄4
95
61⁄8
156
…
…
…
…
0.2812
7.142
98
61⁄4
159
…
…
…
…
0.3125
7.938
37⁄8 4
102
63⁄8
162
…
…
…
…
0.3438
8.733
41⁄8
105
61⁄2
165
…
…
…
…
0.3750
9.525
41⁄8
105
171
…
…
…
…
0.4062
10.317
43⁄8
111
63⁄4 7
178
…
…
…
…
0.4375
11.112
45⁄8
117
71⁄4
184
…
…
…
…
0.4688
11.908
43⁄4
121
71⁄2
190
…
…
…
…
0.5000
12.700
43⁄4
121
197
43⁄4
121
13.492
43⁄4
121
203
43⁄4
121
73⁄4 8
197
0.5312
73⁄4 8
203
0.5625
14.288
47⁄8
124
81⁄4
210
47⁄8
124
81⁄4
210
0.5938
15.083
124
222
124
15.875
124
124
83⁄4 83⁄4
222
0.6250
83⁄4 83⁄4
0.6562
16.667
130
9
229
130
9
229
137
91⁄4
235
137
91⁄4 91⁄2 93⁄4 97⁄8
235
0.6875
17.462
47⁄8 47⁄8 51⁄8 53⁄8
0.7188
18.258
…
…
…
…
0.7500
19.050
57⁄8
149
93⁄4
248
47⁄8 47⁄8 51⁄8 53⁄8 55⁄8 57⁄8
0.7812
19.842
…
…
…
…
6
152
0.8125
20.638
…
…
…
…
156
10
254
0.8438
21.433
…
…
…
…
156
10
254
0.8750
22.225
…
…
…
…
156
10
254
0.9062
23.017
…
…
…
…
156
10
254
0.9375
23.812
…
…
…
…
156
0.9688
24.608
…
…
…
…
61⁄8 61⁄8 61⁄8 61⁄8 61⁄8 63⁄8 63⁄8 61⁄2 65⁄8 67⁄8 71⁄8 77⁄8
162
103⁄4 11
279
162
11
279
165
111⁄8
283
168
111⁄4
286
175
111⁄2
292
181
113⁄4
298
200
121⁄2
318
222
1
1.0000
25.400
…
…
…
…
11⁄32
1.0312
26.192
…
…
…
…
11⁄16
1.0625
26.988
…
…
…
…
13⁄32
1.0938
27.783
…
…
…
…
11⁄8
1.1250
28.575
…
…
…
…
11⁄4
1.2500
31.750
…
…
…
…
143 149
Copyright 2004, Industrial Press, Inc., New York, NY
222
241 248 251
273
Machinery's Handbook 27th Edition
Table 10. Length of Point on Twist Drills and Centering Tools
Decimal Equivalent
Length of Point when Included Angle = 90°
Length of Point when Included Angle = 118°
Dia. of Drill
Length of Point when Included Angle = 118°
Decimal Equivalent
60
0.0400
0.020
0.012
37
0.1040
0.052
0.031
14
0.1820
0.091
0.055
3⁄ 8
0.3750
0.188
0.113
59
0.0410
0.021
0.012
36
0.1065
0.054
0.032
13
0.1850
0.093
0.056
25⁄ 64
0.3906
0.195
0.117
58
0.0420
0.021
0.013
35
0.1100
0.055
0.033
12
0.1890
0.095
0.057
13⁄ 32
0.4063
0.203
0.122
57
0.0430
0.022
0.013
34
0.1110
0.056
0.033
11
0.1910
0.096
0.057
27⁄ 64
0.4219
0.211
0.127
56
0.0465
0.023
0.014
33
0.1130
0.057
0.034
10
0.1935
0.097
0.058
7⁄ 16
0.4375
0.219
0.131
55
0.0520
0.026
0.016
32
0.1160
0.058
0.035
9
0.1960
0.098
0.059
29⁄ 64
0.4531
0.227
0.136
54
0.0550
0.028
0.017
31
0.1200
0.060
0.036
8
0.1990
0.100
0.060
15⁄ 32
0.4688
0.234
0.141
53
0.0595
0.030
0.018
30
0.1285
0.065
0.039
7
0.2010
0.101
0.060
31⁄ 64
0.4844
0.242
0.145
52
0.0635
0.032
0.019
29
0.1360
0.068
0.041
6
0.2040
0.102
0.061
1⁄ 2
0.5000
0.250
0.150
51
0.0670
0.034
0.020
28
0.1405
0.070
0.042
5
0.2055
0.103
0.062
33⁄ 64
0.5156
0.258
0.155
50
0.0700
0.035
0.021
27
0.1440
0.072
0.043
4
0.2090
0.105
0.063
17⁄ 32
0.5313
0.266
0.159
49
0.0730
0.037
0.022
26
0.1470
0.074
0.044
3
0.2130
0.107
0.064
35⁄ 64
0.5469
0.273
0.164
48
0.0760
0.038
0.023
25
0.1495
0.075
0.045
2
0.2210
0.111
0.067
9⁄ 16
0.5625
0.281
0.169
47
0.0785
0.040
0.024
24
0.1520
0.076
0.046
1
0.2280
0.114
0.068
37⁄ 64
0.5781
0.289
0.173
46
0.0810
0.041
0.024
23
0.1540
0.077
0.046
15⁄ 64
0.2344
0.117
0.070
19⁄ 32
0.5938
0.297
0.178
45
0.0820
0.041
0.025
22
0.1570
0.079
0.047
1⁄ 4
0.2500
0.125
0.075
39⁄ 64
0.6094
0.305
0.183
44
0.0860
0.043
0.026
21
0.1590
0.080
0.048
17⁄ 64
0.2656
0.133
0.080
5⁄ 8
0.6250
0.313
0.188
43
0.0890
0.045
0.027
20
0.1610
0.081
0.048
9⁄ 32
0.2813
0.141
0.084
41⁄ 64
0.6406
0.320
0.192
42
0.0935
0.047
0.028
19
0.1660
0.083
0.050
19⁄ 64
0.2969
0.148
0.089
21⁄ 32
0.6563
0.328
0.197
41
0.0960
0.048
0.029
18
0.1695
0.085
0.051
5⁄ 16
0.3125
0.156
0.094
43⁄ 64
0.6719
0.336
0.202
40
0.0980
0.049
0.029
17
0.1730
0.087
0.052
21⁄ 64
0.3281
0.164
0.098
11⁄ 16
0.6875
0.344
0.206
39
0.0995
0.050
0.030
16
0.1770
0.089
0.053
11⁄ 32
0.3438
0.171
0.103
23⁄ 32
0.7188
0.359
0.216
38
0.1015
0.051
0.030
15
0.1800
0.090
0.054
23⁄ 64
0.3594
0.180
0.108
3⁄ 4
0.7500
0.375
0.225
Size of Drill
Decimal Equivalent
Length of Point when Included Angle = 90°
Length of Point when Included Angle = 118°
Size or Dia. of Drill
Copyright 2004, Industrial Press, Inc., New York, NY
877
Decimal Equivalent
Length of Point when Included Angle = 90°
Length of Point when Included Angle = 118°
TWIST DRILLS
Size of Drill
Length of Point when Included Angle = 90°
Machinery's Handbook 27th Edition 878
DRILL DRIVERS
British Standard Combined Drills and Countersinks (Center Drills).—BS 328: Part 2: 1972 (1990) provides dimensions of combined drills and countersinks for center holes. Three types of drill and countersink combinations are shown in this standard but are not given here. These three types will produce center holes without protecting chamfers, with protecting chamfers, and with protecting chamfers of radius form. Drill Drivers—Split-Sleeve, Collet Type.—American National Standard ANSI B94.351972 (R1995) covers split-sleeve, collet-type drivers for driving straight shank drills, reamers, and similar tools, without tangs from 0.0390-inch through 0.1220-inch diameter, and with tangs from 0.1250-inch through 0.7500-inch diameter, including metric sizes. For sizes 0.0390 through 0.0595 inch, the standard taper number is 1 and the optional taper number is 0. For sizes 0.0610 through 0.1875 inch, the standard taper number is 1, first optional taper number is 0, and second optional taper number is 2. For sizes 0.1890 through 0.2520 inch, the standard taper number is 1, first optional taper number is 2, and second optional taper number is 0. For sizes 0.2570 through 0.3750 inch, the standard taper number is 1 and the optional taper number is 2. For sizes 0.3860 through 0.5625 inch, the standard taper number is 2 and the optional taper number is 3. For sizes 0.5781 through 0.7500 inch, the standard taper number is 3 and the optional taper number is 4. The depth B that the drill enters the driver is 0.44 inch for sizes 0.0390 through 0.0781 inch; 0.50 inch for sizes 0.0785 through 0.0938 inch; 0.56 inch for sizes 0.0960 through 0.1094 inch; 0.62 inch for sizes 0.1100 through 0.1220 inch; 0.75 inch for sizes 0.1250 through 0.1875 inch; 0.88 inch for sizes 0.1890 through 0.2500 inch; 1.00 inch for sizes 0.2520 through 0.3125 inch; 1.12 inches for sizes 0.3160 through 0.3750 inch; 1.25 inches for sizes 0.3860 through 0.4688 inch; 1.31 inches for sizes 0.4844 through 0.5625 inch; 1.47 inches for sizes 0.5781 through 0.6562 inch; and 1.62 inches for sizes 0.6719 through 0.7500 inch. British Standard Metric Twist Drills.—BS 328: Part 1:1959 (incorporating amendments issued March 1960 and March 1964) covers twist drills made to inch and metric dimensions that are intended for general engineering purposes. ISO recommendations are taken into account. The accompanying tables give the standard metric sizes of Morse taper shank twist drills and core drills, parallel shank jobbing and long series drills, and stub drills. All drills are right-hand cutting unless otherwise specified, and normal, slow, or quick helix angles may be provided. A “back-taper” is ground on the diameter from point to shank to provide longitudinal clearance. Core drills may have three or four flutes, and are intended for opening up cast holes or enlarging machined holes, for example. The parallel shank jobber, and long series drills, and stub drills are made without driving tenons. Morse taper shank drills with oversize dimensions are also listed, and Table 11 shows metric drill sizes superseding gage and letter size drills, which are now obsolete in Britain. To meet special requirements, the Standard lists nonstandard sizes for the various types of drills. The limits of tolerance on cutting diameters, as measured across the lands at the outer corners of a drill, shall be h8, in accordance with BS 1916, Limits and Fits for Engineering (Part I, Limits and Tolerances), and Table 14 shows the values common to the different types of drills mentioned before. The drills shall be permanently and legibly marked whenever possible, preferably by rolling, showing the size, and the manufacturer's name or trademark. If they are made from high-speed steel, they shall be marked with the letters H.S. where practicable. Drill Elements: The following definitions of drill elements are given. Axis: The longitudinal center line. Body: That portion of the drill extending from the extreme cutting end to the commencement of the shank.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TWIST DRILLS
879
Shank: That portion of the drill by which it is held and driven. Flutes: The grooves in the body of the drill that provide lips and permit the removal of chips and allow cutting fluid to reach the lips. Web (Core): The central portion of the drill situated between the roots of the flutes and extending from the point end toward the shank; the point end of the web or core forms the chisel edge. Lands: The cylindrical-ground surfaces on the leading edges of the drill flutes. The width of the land is measured at right angles to the flute helix. Body Clearance: The portion of the body surface that is reduced in diameter to provide diametral clearance. Heel: The edge formed by the intersection of the flute surface and the body clearance. Point: The sharpened end of the drill, consisting of all that part of the drill that is shaped to produce lips, faces, flanks, and chisel edge. Face: That portion of the flute surface adjacent to the lip on which the chip impinges as it is cut from the work. Flank: The surface on a drill point that extends behind the lip to the following flute. Lip (Cutting Edge): The edge formed by the intersection of the flank and face. Relative Lip Height: The relative position of the lips measured at the outer corners in a direction parallel to the drill axis. Outer Corner: The corner formed by the intersection of the lip and the leading edge of the land. Chisel Edge: The edge formed by the intersection of the flanks. Chisel Edge Corner: The corner formed by the intersection of a lip and the chisel edge. Table 11. British Standard Drills — Metric Sizes Superseding Gauge and Letter Sizes BS 328: Part 1:1959, Appendix B Obsolete Drill Size
Recommended MetricSize (mm)
Obsolete Drill Size
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59
0.35 0.38 0.40 0.45 0.50 0.52 0.58 0.60 0.65 0.65 0.70 0.75 1⁄ in. 32 0.82 0.85 0.90 0.92 0.95 0.98 1.00 1.00 1.05
58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37
Recommended Metric Size (mm) 1.05 1.10 3⁄ in. 64 1.30 1.40 1.50 1.60 1.70 1.80 1.85 1.95 2.00 2.05 2.10 2.20 2.25 3⁄ in. 32 2.45 2.50 2.55 2.60 2.65
Obsolete Drill Size
Recommended Metric Size (mm)
Obsolete Drill Size
36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15
2.70 2.80 2.80 2.85 2.95 3.00 3.30 3.50 9⁄ in. 64 3.70 3.70 3.80 3.90 3.90 4.00 4.00 4.10 4.20 4.30 4.40 4.50 4.60
14 13 12 11 10 9 8 7 6 5 4 3 2 1 A B C D E F G H
Recommended Metric Size (mm)
Obsolete Drill Size
4.60 4.70 4.80 4.90 4.90 5.00 5.10 5.10 5.20 5.20 5.30 5.40 5.60 5.80 15⁄ in. 64
6.00 6.10 6.20 1⁄ in. 4 6.50 6.60 17⁄ in. 64
I J K L M N O P Q R S T U V W X Y Z … … … …
Recommended Metric Size (mm) 6.90 7.00 9⁄ in. 32
7.40 7.50 7.70 8.00 8.20 8.40 8.60 8.80 9.10 9.30 3⁄ in. 8 9.80 10.10 10.30 10.50 … … … …
Gauge and letter size drills are now obsolete in the United Kingdom and should not be used in the production of new designs. The table is given to assist users in changing over to the recommended standard sizes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 880
TWIST DRILLS Table 12. British Standard Morse Taper Shank Twist Drills and Core Drills — Standard Metric Sizes BS 328: Part 1:1959
Diameter 3.00 3.20 3.50 3.80 4.00 4.20 4.50 4.80 5.00 5.20 5.50 5.80 6.00 6.20 6.50 6.80 7.00 7.20 7.50 7.80 8.00 8.20 8.50 8.80 9.00 9.20 9.50 9.80 10.00 10.20 10.50 10.80 11.00 11.20 11.50 11.80 12.00 12.20 12.50 12.80 13.00 13.20 13.50 13.80 14.00 14.25 14.50 14.75 15.00 15.25 15.50 15.75 16.00 16.25 16.50
Flute Length
Overall Length
33 36 39
114 117 120
43
123
47
128
52
133
57
138
63
144
69
150
75
156
81
87
94
162
168
175
101
182
108
189
114
212
120
218
125
223
Diameter 16.75 17.00 17.25 17.50 17.75 18.00 18.25 18.50 18.75 19.00 19.25 19.50 19.75 20.00 20.25 20.50 20.75 21.00 21.25 21.50 21.75 22.00 22.25 22.50 22.75 23.00 23.25 23.50 23.75 24.00 24.25 24.50 24.75 25.00 25.25 25.50 25.75 26.00 26.25 26.50 26.75 27.00 27.25 27.50 27.75 28.00 28.25 28.50 28.75 29.00 29.25 29.50 29.75 30.00
Flute Length
Overall Length
125
223
130
228
135
233
140
145
150
238
243
248
155
253
155
276
160
281
165
286
170
291
175
175
296
296
Diameter 30.25 30.50 30.75 31.00 31.25 31.50 31.75 32.00 32.50 33.00 33.50 34.00 34.50 35.00 35.50 36.00 36.50 37.00 37.50 38.00 38.50 39.00 39.50 40.00 40.50 41.00 41.50 42.00 42.50 43.00 43.50 44.00 44.50 45.00 45.50 46.00 46.50 47.00 47.50 48.00 48.50 49.00 49.50 50.00 50.50 51.00 52.00 53.00 54.00 55.00 56.00 57.00 58.00 59.00 60.00
Copyright 2004, Industrial Press, Inc., New York, NY
Flute Length
Overall Length
180
301
185
306
185
334
190
339
195
344
200
349
205
354
210
359
215
364
220
369
225
374
225
412
230
417
235
422
Machinery's Handbook 27th Edition TWIST DRILLS
881
Table 12. (Continued) British Standard Morse Taper Shank Twist Drills and Core Drills — Standard Metric Sizes BS 328: Part 1:1959 Diameter 61.00 62.00 63.00 64.00 65.00 66.00 67.00 68.00 69.00 70.00 71.00 72.00 73.00 74.00 75.00
Flute Length
Overall Length
240
427
245
432
250
437
250
437
255
442
Diameter 76.00 77.00 78.00 79.00 80.00 81.00 82.00 83.00 84.00 85.00 86.00 87.00 88.00 89.00 90.00
Flute Length 260
Overall Length 477
260
514
265
519
270
524
Diameter 91.00 92.00 93.00 94.00 95.00 96.00 97.00 98.00 99.00 100.00
Flute Length
Overall Length
275
529
280
534
All dimensions are in millimeters. Tolerances on diameters are given in the table below. Table 13, shows twist drills that may be supplied with the shank and length oversize, but they should be regarded as nonpreferred. The Morse taper shanks of these twist and core drills are as follows: 3.00 to 14.00 mm diameter, M.T. No. 1; 14.25 to 23.00 mm diameter, M.T. No. 2; 23.25 to 31.50 mm diameter, M.T. No. 3; 31.75 to 50.50 mm diameter, M.T. No. 4; 51.00 to 76.00 mm diameter, M.T. No. 5; 77.00 to 100.00 mm diameter, M.T. No. 6.
Table 13. British Standard Morse Taper Shank Twist Drills — Metric Oversize Shank and Length Series BS 328: Part 1:1959 Dia. Range
Overall Length
M. T. No.
Dia. Range
Overall Length
M. T. No.
Dia. Range
Overall Length
M. T. No.
12.00 to 13.20
199
2
22.50 to 23.00
276
3
45.50 to 47.50
402
5
13.50 to 14.00
206
2
26.75 to 28.00
319
4
48.00 to 50.00
407
5
18.25 to 19.00
256
3
29.00 to 30.00
324
4
50.50
412
5
19.25 to 20.00
251
3
30.25 to 31.50
329
4
64.00 to 67.00
499
6
20.25 to 21.00
266
3
40.50 to 42.50
392
5
68.00 to 71.00
504
6
21.25 to 22.25
271
3
43.00 to 45.00
397
5
72.00 to 75.00
509
6
Diameters and lengths are given in millimeters. For the individual sizes within the diameter ranges given, see Table 12. This series of drills should be regarded as non-preferred.
Table 14. British Standard Limits of Tolerance on Diameter for Twist Drills and Core Drills — Metric Series BS 328: Part 1:1959 Drill Size (Diameter measured across lands at outer corners)
Tolerance (h8)
0 to 1 inclusive
Plus 0.000 to Minus 0.014
Over 1 to 3 inclusive
Plus 0.000 to Minus 0.014
Over 3 to 6 inclusive
Plus 0.000 to Minus 0.018
Over 6 to 10 inclusive
Plus 0.000 to Minus 0.022
Over 10 to 18 inclusive
Plus 0.000 to Minus 0.027
Over 18 to 30 inclusive
Plus 0.000 to Minus 0.033
Over 30 to 50 inclusive
Plus 0.000 to Minus 0.039
Over 50 to 80 inclusive
Plus 0.000 to Minus 0.046
Over 80 to 120 inclusive
Plus 0.000 to Minus 0.054
All dimensions are given in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 882
TWIST DRILLS
4
19
5
20
6
22
7
24
8
26
9
28
10
30
11
32
12
34
14
36
16
38
1.35 1.40 1.45 1.50
18
40
1.55 1.60 1.65 1.70
20
43
24
49
27
53
30
57
33
61
36
65
39
70
43
75
47
52
80
86
5.40 5.50 5.60 5.70 5.80 5.90 6.00 6.10 6.20 6.30 6.40 6.50 6.60 6.70 6.80 6.90 7.00 7.10 7.20 7.30 7.40 7.50 7.60 7.70 7.80 7.90 8.00 8.10 8.20 8.30 8.40 8.50 8.60 8.70 8.80 8.90 9.00 9.10 9.20 9.30 9.40 9.50 9.60 9.70 9.80 9.90 10.00 10.10
57
93
63
101
69
109
75
81
87
117
125
133
Diameter
Overall Length
Flute Length
Diameter
46
Overall Length
19
22
Flute Length
3.0
1.75 1.80 1.85 1.90 1.95 2.00 2.05 2.10 2.15 2.20 2.25 2.30 2.35 2.40 2.45 2.50 2.55 2.60 2.65 2.70 2.75 2.80 2.85 2.90 2.95 3.00 3.10 3.20 3.30 3.40 3.50 3.60 3.70 3.80 3.90 4.00 4.10 4.20 4.30 4.40 4.50 4.60 4.70 4.80 4.90 5.00 5.10 5.20 5.30
Overall Length
19
Flute Length
2.5
Diameter
Overall Length
0.20 0.22 0.25 0.28 0.30 0.32 0.35 0.38 0.40 0.42 0.45 0.48 0.50 0.52 0.55 0.58 0.60 0.62 0.65 0.68 0.70 0.72 0.75 0.78 0.80 0.82 0.85 0.88 0.90 0.92 0.95 0.98 1.00 1.05 1.10 1.15 1.20 1.25 1.30
Flute Length
Diameter
Table 15. British Standard Parallel Shank Jobber Series Twist Drills — Standard Metric Sizes BS 328: Part 1:1959
87
133
94
142
101
151
108
160
14.25 14.50 14.75 15.00
114
169
15.25 15.50 15.75 16.00
120
178
10.20 10.30 10.40 10.50 10.60 10.70 10.80 10.90 11.00 11.10 11.20 11.30 11.40 11.50 11.60 11.70 11.80 11.90 12.00 12.10 12.20 12.30 12.40 12.50 12.60 12.70 12.80 12.90 13.00 13.10 13.20 13.30 13.40 13.50 13.60 13.70 13.80 13.90 14.00
All dimensions are in millimeters. Tolerances on diameters are given in Table 14.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TWIST DRILLS
883
Table 16. British Standard Parallel Shank Long Series Twist Drills — Standard Metric Sizes BS 328: Part 1:1959 Diameter 2.00 2.05 2.10 2.15 2.20 2.25 2.30 2.35 2.40 2.45 2.50 2.55 2.60 2.65 2.70 2.75 2.80 2.85 2.90 2.95 3.00 3.10 3.20 3.30 3.40 3.50 3.60 3.70 3.80 3.90 4.00 4.10 4.20 4.30 4.40 4.50 4.60 4.70 4.80 4.90 5.00 5.10 5.20 5.30 5.40 5.50 5.60 5.70 5.80 5.90 6.00 6.10 6.20 6.30 6.40 6.50 6.60 6.70
Flute Length
Overall Length
56
85
59
90
62
95
66
100
69
106
73
112
78
119
82
126
87
132
91
97
139
148
Diameter 6.80 6.90 7.00 7.10 7.20 7.30 7.40 7.50 7.60 7.70 7.80 7.90 8.00 8.10 8.20 8.30 8.40 8.50 8.60 8.70 8.80 8.90 9.00 9.10 9.20 9.30 9.40 9.50 9.60 9.70 9.80 9.90 10.00 10.10 10.20 10.30 10.40 10.50 10.60 10.70 10.80 10.90 11.00 11.10 11.20 11.30 11.40 11.50 11.60 11.70 11.80 11.90 12.00 12.10 12.20 12.30 12.40 12.50 12.60
Flute Length
102
109
115
121
128
134
Overall Length
156
165
175
184
195
205
Diameter 12.70 12.80 12.90 13.00 13.10 13.20 13.30 13.40 13.50 13.60 13.70 13.80 13.90 14.00 14.25 14.50 14.75 15.00 15.25 15.50 15.75 16.00 16.25 16.50 16.75 17.00 17.25 17.50 17.75 18.00 18.25 18.50 18.75 19.00 19.25 19.50 19.75 20.00 20.25 20.50 20.75 21.00 21.25 21.50 21.75 22.00 22.25 22.50 22.75 23.00 23.25 23.50 23.75 24.00 24.25 24.50 24.75 25.00
All dimensions are in millimeters. Tolerances on diameters are given in Table 14.
Copyright 2004, Industrial Press, Inc., New York, NY
Flute Length
Overall Length
134
205
140
214
144
220
149
227
154
235
158
241
162
247
166
254
171
261
176
268
180
275
185
282
Machinery's Handbook 27th Edition 884
TWIST DRILLS
49 52
3.80 4.00 4.20 4.50 4.80
22
55
24 26
58 62
66
31
70
34
74
37
79
40
84
Overall Length
18 20
28
Flute Length
46
62
Diameter
16
6.20 6.50 6.80 7.00 7.20 7.50 7.80 8.00 8.20 8.50 8.80 9.00 9.20
26
Overall Length
5.00 5.20 5.50 5.80 6.00
Flute Length
Diameter
20 24 26 30 32 36 38 40 43
Diameter
Overall Length
3 5 6 8 9 11 12 13 14
Overall Length
Flute Length
0.50 0.80 1.00 1.20 1.50 1.80 2.00 2.20 2.50 2.80 3.00 3.20 3.50
Flute Length
Diameter
Table 17. British Standard Stub Drills — Metric Sizes BS 328: Part 1:1959
9.50 9.80 10.00 10.20 10.50
40
84
14.00 14.50 15.00 15.50 16.00
54
107
10.80 11.00 11.20 11.50 11.80 12.00 12.20 12.50 12.80 13.00 13.20 13.50 13.80
43
47
89
95
51
102
54
107
16.50 17.00 17.50 18.00 18.50 19.00 19.50 20.00 21.00 22.00 23.00 24.00 25.00
56
111
58
115
60
119
62
123
64
127
66
131
68 70 72
136 141 146
75
151
All dimensions are given in millimeters. Tolerances on diameters are given in Table 14.
Steels for Twist Drills.—Twist drill steels need good toughness, abrasion resistance, and ability to resist softening due to heat generated by cutting. The amount of heat generated indicates the type of steel that should be used. Carbon Tool Steel may be used where little heat is generated during drilling. High-Speed Steel is preferred because of its combination of red hardness and wear resistance, which permit higher operating speeds and increased productivity. Optimum properties can be obtained by selection of alloy analysis and heat treatment. Cobalt High-Speed Steel alloys have higher red hardness than standard high-speed steels, permitting drilling of materials such as heat-resistant alloys and materials with hardness greater than Rockwell 38 C. These high-speed drills can withstand cutting speeds beyond the range of conventional high-speed-steel drills and have superior resistance to abrasion but are not equal to tungsten-carbide tipped tools. Accuracy of Drilled Holes.—Normally the diameter of drilled holes is not given a tolerance; the size of the hole is expected to be as close to the drill size as can be obtained. The accuracy of holes drilled with a two-fluted twist drill is influenced by many factors, which include: the accuracy of the drill point; the size of the drill; length and shape of the chisel edge; whether or not a bushing is used to guide the drill; the work material; length of the drill; runout of the spindle and the chuck; rigidity of the machine tool, workpiece, and the setup; and also the cutting fluid used, if any. The diameter of the drilled holes will be oversize in most materials. The table Oversize Diameters in Drilling on page 885 provides the results of tests reported by The United States Cutting Tool Institute in which the diameters of over 2800 holes drilled in steel and cast iron were measured. The values in this table indicate what might be expected under average shop conditions; however, when the drill point is accurately ground and the other machining conditions are correct, the resulting hole size is more likely to be between the mean and average minimum values given in this table. If the drill is ground and used incorrectly, holes that are even larger than the average maximum values can result.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition COUNTERBORES
885
Oversize Diameters in Drilling Drill Dia., Inch 1⁄ 16 1⁄ 8 1⁄ 4
Amount Oversize, Inch Average Max. Mean Average Min. 0.002 0.0045 0.0065
0.0015 0.003 0.004
Drill Dia., Inch
0.001 0.001 0.0025
1⁄ 2 3⁄ 4
1
Amount Oversize, Inch Average Max. Mean Average Min. 0.008 0.008 0.009
0.005 0.005 0.007
0.003 0.003 0.004
Courtesy of The United States Cutting Tool Institute
Some conditions will cause the drilled hole to be undersize. For example, holes drilled in light metals and in other materials having a high coefficient of thermal expansion such as plastics, may contract to a size that is smaller than the diameter of the drill as the material surrounding the hole is cooled after having been heated by the drilling. The elastic action of the material surrounding the hole may also cause the drilled hole to be undersize when drilling high strength materials with a drill that is dull at its outer corner. The accuracy of the drill point has a great effect on the accuracy of the drilled hole. An inaccurately ground twist drill will produce holes that are excessively over-size. The drill point must be symmetrical; i.e., the point angles must be equal, as well as the lip lengths and the axial height of the lips. Any alterations to the lips or to the chisel edge, such as thinning the web, must be done carefully to preserve the symmetry of the drill point. Adequate relief should be provided behind the chisel edge to prevent heel drag. On conventionally ground drill points this relief can be estimated by the chisel edge angle. When drilling a hole, as the drill point starts to enter the workpiece, the drill will be unstable and will tend to wander. Then as the body of the drill enters the hole the drill will tend to stabilize. The result of this action is a tendency to drill a bellmouth shape in the hole at the entrance and perhaps beyond. Factors contributing to bellmouthing are: an unsymmetrically ground drill point; a large chisel edge length; inadequate relief behind the chisel edge; runout of the spindle and the chuck; using a slender drill that will bend easily; and lack of rigidity of the machine tool, workpiece, or the setup. Correcting these conditions as required will reduce the tendency for bellmouthing to occur and improve the accuracy of the hole diameter and its straightness. Starting the hole with a short stiff drill, such as a center drill, will quickly stabilize the drill that follows and reduce or eliminate bellmouthing; this procedure should always be used when drilling in a lathe, where the work is rotating. Bellmouthing can also be eliminated almost entirely and the accuracy of the hole improved by using a close fitting drill jig bushing placed close to the workpiece. Although specific recommendations cannot be made, many cutting fluids will help to increase the accuracy of the diameters of drilled holes. Double margin twist drills, available in the smaller sizes, will drill a more accurate hole than conventional twist drills having only a single margin at the leading edge of the land. The second land, located on the trailing edge of each land, provides greater stability in the drill bushing and in the hole. These drills are especially useful in drilling intersecting off-center holes. Single and double margin step drills, also available in the smaller sizes, will produce very accurate drilled holes, which are usually less than 0.002 inch larger than the drill size. Counterboring.—Counterboring (called spot-facing if the depth is shallow) is the enlargement of a previously formed hole. Counterbores for screw holes are generally made in sets. Each set contains three counterbores: one with the body of the size of the screw head and the pilot the size of the hole to admit the body of the screw; one with the body the size of the head of the screw and the pilot the size of the tap drill; and the third with the body the size of the body of the screw and the pilot the size of the tap drill. Counterbores are usually provided with helical flutes to provide positive effective rake on the cutting edges. The four flutes are so positioned that the end teeth cut ahead of center to provide a shearing action and eliminate chatter in the cut. Three designs are most common: solid, two-piece, and three-piece. Solid designs have the body, cutter, and pilot all in one piece. Two-piece designs have an integral shank and counterbore cutter, with an interchangeable pilot, and provide true concentricity of the cutter diameter with the shank, but allowing use of various
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 886
COUNTERBORES
pilot diameters. Three-piece counterbores have separate holder, counterbore cutter, and pilot, so that a holder will take any size of counterbore cutter. Each counterbore cutter, in turn, can be fitted with any suitable size diameter of pilot. Counterbores for brass are fluted straight. Counterbores with Interchangeable Cutters and Guides
Range of Cutter Diameters, A
Range of Pilot Diameters, B
Total Length, C
Length of Cutter Body, D
Length of Pilot, E
Dia. of Shank, F
No. of Holder
No. of Morse Taper Shank
1
1 or 2
3⁄ -11⁄ 4 16
1⁄ -3⁄ 2 4
71⁄4
1
5⁄ 8
3⁄ 4
2
2 or 3
11⁄8-19⁄16
11⁄16-11⁄8
91⁄2
13⁄8
7⁄ 8
11⁄8
3
3 or 4
15⁄8-21⁄16
7⁄ -15⁄ 8 8
121⁄2
13⁄4
11⁄8
15⁄8
4
4 or 5
21⁄8-31⁄2
1-21⁄8
15
21⁄4
13⁄8
21⁄8
Solid Counterbores with Integral Pilot Pilot Diameters
Overall Length
Counterbore Diameters
Nominal
+1⁄64
+1⁄32
Straight Shank Diameter
Short
Long
13⁄ 32
1⁄ 4
17⁄ 64
9⁄ 32
3⁄ 8
31⁄2
51⁄2
1⁄ 2
5⁄ 16
21⁄ 64
11⁄ 32
3⁄ 8
31⁄2
51⁄2
19⁄ 32
3⁄ 8
25⁄ 64
13⁄ 32
1⁄ 2
4
6
11⁄ 16
7⁄ 16
29⁄ 64
15⁄ 32
1⁄ 2
4
6
25⁄ 32
1⁄ 2
33⁄ 64
17⁄ 32
1⁄ 2
5
7
0.110
0.060
0.076
…
7⁄ 64
21⁄2
…
0.133
0.073
0.089
…
1⁄ 8
21⁄2
…
0.155
0.086
0.102
…
5⁄ 32
21⁄2
…
0.176
0.099
0.115
…
11⁄ 64
21⁄2
…
0.198
0.112
0.128
…
3⁄ 16
21⁄2
…
0.220
0.125
0.141
…
3⁄ 16
21⁄2
…
0.241
0.138
0.154
…
7⁄ 32
21⁄2
…
0.285
0.164
0.180
…
1⁄ 4
21⁄2
…
0.327
0.190
0.206
…
9⁄ 32
23⁄4
…
0.372
0.216
0.232
…
5⁄ 16
23⁄4
…
All dimensions are in inches.
Small counterbores are often made with three flutes, but should then have the size plainly stamped on them before fluting, as they cannot afterwards be conveniently measured. The flutes should be deep enough to come below the surface of the pilot. The counterbore should be relieved on the end of the body only, and not on the cylindrical surface. To facilitate the relieving process, a small neck is turned between the guide and the body for clearance. The amount of clearance on the cutting edges is, for general work, from 4 to 5 degrees. The accompanying table gives dimensions for straight shank counterbores. Three Piece Counterbores.—Data shown for the first two styles of counterbores are for straight shank designs. These tools are also available with taper shanks in most sizes. Sizes of taper shanks for cutter diameters of 1⁄4 to 9⁄16 in. are No. 1, for 19⁄32 to 7⁄8 in., No. 2; for 15⁄16 to 13⁄8 in., No. 3; for 11⁄2 to 2 in., No. 4; and for 21⁄8 to 21⁄2 in., No. 5.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STANDARD CARBIDE BORING TOOLS
887
Counterbore Sizes for Hex-head Bolts and Nuts.—Table 2, page 1531, shows the maximum socket wrench dimensions for standard 1⁄4-, 1⁄2- and 3⁄4-inch drive socket sets. For a given socket size (nominal size equals the maximum width across the flats of nut or bolt head), the dimension K given in the table is the minimum counterbore diameter required to provide socket wrench clearance for access to the bolt or nut. Sintered Carbide Boring Tools.—Industrial experience has shown that the shapes of tools used for boring operations need to be different from those of single-point tools ordinarily used for general applications such as lathe work. Accordingly, Section 5 of American National Standard ANSI B212.1-2002 gives standard sizes, styles and designations for four basic types of sintered carbide boring tools, namely: solid carbide square; carbidetipped square; solid carbide round; and carbide-tipped round boring tools. In addition to these ready-to-use standard boring tools, solid carbide round and square unsharpened boring tool bits are provided. Style Designations for Carbide Boring Tools: Table 1 shows designations used to specify the styles of American Standard sintered carbide boring tools. The first letter denotes solid (S) or tipped (T). The second letter denotes square (S) or round (R). The side cutting edge angle is denoted by a third letter (A through H) to complete the style designation. Solid square and round bits with the mounting surfaces ground but the cutting edges unsharpened (Table 3) are designated using the same system except that the third letter indicating the side cutting edge angle is omitted. Table 1. American National Standard Sintered Carbide Boring Tools — Style Designations ANSI B212.1-2002 Side Cutting Edge Angle E Degrees
Designation
0 10 30 40 45 55 90 (0° Rake) 90 (10° Rake)
A B C D E F G H
Boring Tool Styles Solid Square (SS)
SSC SSE
Tipped Square (TS) TSA TSB TSC TSD TSE TSF
Solid Round (SR)
Tipped Round (TR)
SRC
TRC
SRE
TRE TRG TRH
Size Designation of Carbide Boring Tools: Specific sizes of boring tools are identified by the addition of numbers after the style designation. The first number denotes the diameter or square size in number of 1⁄32nds for types SS and SR and in number of 1⁄16ths for types TS and TR. The second number denotes length in number of 1⁄8ths for types SS and SR. For styles TRG and TRH, a letter “U” after the number denotes a semi-finished tool (cutting edges unsharpened). Complete designations for the various standard sizes of carbide boring tools are given in Tables 2 through 7. In the diagrams in the tables, angles shown without tolerance are ± 1°. Examples of Tool Designation:The designation TSC-8 indicates: a carbide-tipped tool (T); square cross-section (S); 30-degree side cutting edge angle (C); and 8⁄16 or 1⁄2 inch square size (8). The designation SRE-66 indicates: a solid carbide tool (S); round cross-section (R); 45 degree side cutting edge angle (E); 6⁄32 or 3⁄16 inch diameter (6); and 6⁄8 or 3⁄4 inch long (6). The designation SS-610 indicates: a solid carbide tool (S); square cross-section (S); 6⁄32 or 3⁄ inch square size (6); 10⁄ or 11⁄ inches long (10). 16 8 4 It should be noted in this last example that the absence of a third letter (from A to H) indicates that the tool has its mounting surfaces ground but that the cutting edges are unsharpened.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 888
STANDARD CARBIDE BORING TOOLS
Table 2. ANSI Carbide-Tipped Round General-Purpose Square-End Boring Tools Style TRG with 0° Rake and Style TRH with 10° Rake ANSI B212.1-2002
Tool Designation
Finished
Semifinisheda
TRG-5
TRG-5U
TRH-5
TRH-5U
TRG-6
TRG-6U
TRH-6
TRH-6U
TRG-7
TRG-7U
TRH-7
TRH-7U
TRG-8
TRG-8U
TRH-8
TRH-8U
Shank Dimensions, Inches Dia. D
Length C
5⁄ 16
11⁄2
3⁄ 8
13⁄4
7⁄ 16
21⁄2
1⁄ 2
Tip Dimensions, Inches Rake Angle Deg.
Dim.Over Flat B
Nose Height H
Setback M (Min)
19⁄ 64
3⁄ 16
3⁄ 16
0
±.005
7⁄ 32
3⁄ 16
10
11⁄ 32
7⁄ 32
±.010
1⁄ 4
21⁄2
13⁄ 32
1⁄ 4
±.010
5⁄ 16
15⁄ 32
9⁄ 32
±.010
11⁄ 32
Tip No.
T
W
L
1025
1⁄ 16
1⁄ 4
1⁄ 4
1030
1⁄ 16
5⁄ 16
1⁄ 4
1080
3⁄ 32
5⁄ 16
3⁄ 8
1090
3⁄ 32
3⁄ 8
3⁄ 8
0
3⁄ 16
10 0
3⁄ 16
10 0
1⁄ 4
10
a Semifinished tool will be without Flat (B) and carbide unground on the end.
Table 3. Solid Carbide Square and Round Boring Tool Bits
Square Bits Tool Designation
Round Bits
A
B
SS-58
5⁄ 32
5⁄ 32
C 1
SS-610
3⁄ 16
3⁄ 16
SS-810
1⁄ 4
1⁄ 4
SS-1012
5⁄ 16
SS-1214
3⁄ 8
Tool Designation
Tool Designation
D
C
D
C
5⁄ 8
Tool Designation SR-88
1⁄ 4
1 11⁄4
D
C
SR-33
3⁄ 32
3⁄ 8
SR-55
5⁄ 32
11⁄4
SR-34
3⁄ 32
1⁄ 2
SR-64
3⁄ 16
1⁄ 2
SR-810
1⁄ 4
11⁄4
SR-44
1⁄ 8
1⁄ 2
SR-66
3⁄ 16
3⁄ 4
SR-1010
5⁄ 16
11⁄4
5⁄ 16
11⁄2
SR-46
1⁄ 8
3⁄ 4
SR-69
3⁄ 16
11⁄8
…
…
…
3⁄ 8
13⁄4
SR-48
1⁄ 8
1
SR-77
7⁄ 32
7⁄ 8
…
…
…
All dimensions are in inches. Tolerance on Length: Through 1 inch, + 1⁄32, − 0; over 1 inch, +1⁄16, −0.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 4. ANSI Solid Carbide Square Boring Tools Style SSC for 60° Boring Bar and Style SSE for 45° Boring Bar ANSI B212.1-2002
Table 5. ANSI Carbide-Tipped Round Boring Tools Style TRC for 60° Boring Bar and Style TRE for 45° Boring Bar ANSI B212.1-2002 6° ± 1° Tool Designation and Carbide Grade
6° ± 1°
G ± 1°
F Ref
W
G ± 1°
F Ref A +0.000 –0.002
1 C ± 16
A ±0.005 to sharp corner 2
E ± 1°
H ± 0.010 6° ± 1° Along angle “G” Optional Design
12° ± 1°
5⁄ 32
5⁄ 32
1
3⁄ 16
3⁄ 16
11⁄4
1⁄ 4
1⁄ 4
11⁄4
5⁄ 16
5⁄ 16
11⁄2
End Cutting Edge Angle G ,Deg.
Shoulder Angle F ,Deg.
30 45 30 45 30 45 30 45
38 53 38 53 38 53 38 53
60 45 60 45 60 45 60 45
TRC-5
60
TRE-5
45
TRC-6
60
TRE-6
45
TRC-7
60
TRE-7
45
TRC-8
60
TRE-8
45
D
C
5⁄ 16
11⁄2
3⁄ 8
13⁄4
7⁄ 16
21⁄2
1⁄ 2
21⁄2
B 19⁄ 64
±.005 11⁄ 32
±.010 13⁄ 32
±.010 15⁄ 32
±.010
H 7⁄ 32
9⁄ 32
5⁄ 16
3⁄ 8
Shoulder Angle F, Deg.
60 45 60 45 60 45 60 45
Side Cutting Edge Angle E,Deg.
Shank Dimensions, Inches
End Cut. Edge Angle G, Deg.
SSC-58 SSE-58 SSC-610 SSE-610 SSC-810 SSE-810 SSC-1012 SSE-1012
+0.000 –0.002
Bor. Bar Angle from Axis, Deg.
R
Shank Dimensions, Inches Width Height Length A B C
Tool Designation
6° ± 1° Along angle “G”
Side Cut. Edge Angle E, Deg.
12° ± 2° Along angle “G”
Tool Designation and Carbide Grade
Tool Designation
6° ± 1° L
1 C ± 64
Boring Bar Angle, Deg. from Axis
D/2 ± 1 to sharp corner 64
F ± 1°
B
0.010 R ± 0.003
T
30
38
60
R 1⁄ 64
Tip Dimensions, Inches Tip No.
T
W
L
2020
1⁄ 16
3⁄ 16
1⁄ 4
±.005
45
53
45
1⁄ 64
30
38
60
2040
3⁄ 32
3⁄ 16
5⁄ 16
±.005
45
53
45
2020
1⁄ 16
3⁄ 16
1⁄ 4
1⁄ 32
30
38
60
±.010
45
53
45
2060
3⁄ 32
1⁄ 4
3⁄ 8
1⁄ 4
3⁄ 8
5⁄ 16
3⁄ 8
1⁄ 32
30
38
60
2060
3⁄ 32
±.010
45
53
45
2080
3⁄ 32
STANDARD CARBIDE BORING TOOLS
8° ± 2° 6° ± 1°
R D +0.0005 –0.0015
889
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 890
STANDARD CARBIDE BORING TOOLS
Table 6. ANSI Carbide-Tipped Square Boring Tools — ANSI B212.1-2002 Styles TSA and TSB for 90° Boring Bar, Styles TSC and TSD for 60° Boring Bar, and Styles TSE and TSF for 45° Boring Bar
G ± 1° Shoulder angle Ref F
10° ± 1° 7° ± 1° 6° ± 1°
W
R Ref to Sharp Corner
A +0.000 –0.010
T 1 C ± 16
E ± 1° L
A
B
5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4
5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4
C 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 13⁄4 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 21⁄2 3 3 3 3 3 3 31⁄2 31⁄2 31⁄2 31⁄2 31⁄2 31⁄2
R
⎛ 1⁄64 ⎞ ⎜ ± ⎟ ⎜ ⎟ ⎝ 0.005⎠
⎛ 1⁄32 ⎞ ⎜ ± ⎟ ⎜ ⎟ ⎝ 0.010⎠
⎛ 1⁄32 ⎞ ⎜ ± ⎟ ⎜ ⎟ ⎝ 0.010⎠
Shoulder Angle F, Deg.
90 90 60 60 45 45 90 90 60 60 45 45 90 90 60 60 45 45 90 90 60 60 45 45 90 90 60 60 45 45 90 90 60 60 45 45
B +0.000 –0.010 End Cut. Edge Angle G, Deg.
Bor. Bar Angle from Axis, Deg.
TSA-5 TSB-5 TSC-5 TSD-5 TSE-5 TSF-5 TSA-6 TSB-6 TSC-6 TSD-6 TSE-6 TSF-6 TSA-7 TSB-7 TSC-7 TSD-7 TSE-7 TSF-7 TSA-8 TSB-8 TSC-8 TSD-8 TSE-8 TSF-8 TSA-10 TSB-10 TSC-10 TSD-10 TSE-10 TSF-10 TSA-12 TSB-12 TSC-12 TSD-12 TSE-12 TSF-12
Shank Dimensions, Inches
0° ± 1° Along angle “G” 10° ± 2° Along angle “G”
SideCut. Edge Angle E, Deg.
Tool Designation
12° ± 1° Tool Designation and Carbide Grade
0 10 30 40 45 55 0 10 30 40 45 55 0 10 30 40 45 55 0 10 30 40 45 55 0 10 30 40 45 55 0 10 30 40 45 55
8 8 38 38 53 53 8 8 38 38 53 53 8 8 38 38 53 53 8 8 38 38 53 53 8 8 38 38 53 53 8 8 38 38 53 53
90 90 60 60 45 45 90 90 60 60 45 45 90 90 60 60 45 45 90 90 60 60 45 45 90 90 60 60 45 45 90 90 60 60 45 45
Tip Dimensions, Inches Tip No. 2040 2040 2040 2040 2040 2040 2040 2040 2040 2040 2040 2040 2060 2060 2060 2060 2060 2060 2150 2150 2150 2150 2150 2150 2220 2220 2220 2220 2220 2220 2300 2300 2300 2300 2300 2300
Copyright 2004, Industrial Press, Inc., New York, NY
T
W
L
3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 3⁄ 32 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 5⁄ 32 5⁄ 32 5⁄ 32 5⁄ 32 5⁄ 32 5⁄ 32 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16
3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16
5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16 7⁄ 16 9⁄ 16 9⁄ 16 9⁄ 16 9⁄ 16 9⁄ 16 9⁄ 16 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8 5⁄ 8
Machinery's Handbook 27th Edition STANDARD CARBIDE BORING TOOLS
891
Table 7. ANSI Solid Carbide Round Boring Tools — ANSI B212.1-2002 Style SRC for 60° Boring Bar and Style SRE for 45° Boring Bar
6° ± 1°
Tool Designation and Carbide Grade
G ± 1°
F Ref
6° ± 1°
0.010 R ± 0.003
D +0.0005 –0.0015 B +0.000 –0.005
D ±0.005 to sharp corner 2
E ± 1° 1
C ± 64
H 6° ± 1° Along angle “G”
Bor. Bar Angle Tool from Axis, Designation Deg.
Dia. D
Shank Dimensions, Inches Nose Dim. Height Over H Flat B
Length C
Side Cut. Edge Angle E ,Deg.
End Cut. Edge Angle G ,Deg.
Shoulder Angle F ,Deg.
30
38
60
45
53
45
30
38
60
45
53
45
SRC-33
60
3⁄ 32
3⁄ 8
0.088
0.070
SRE-33
45
3⁄ 32
3⁄ 8
0.088
0.070
SRC-44
60
1⁄ 8
1⁄ 2
0.118
0.094
SRE-44
45
1⁄ 8
1⁄ 2
0.118
0.094
+0.000 – 0.005
SRC-55
60
5⁄ 32 5⁄ 32 3⁄ 16 3⁄ 16 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16
5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4
0.149
0.117
±0.005
30
38
60
0.149
0.117
±0.005
45
53
45
0.177
0.140
±0.005
30
38
60
0.177
0.140
±0.005
45
53
45
0.240
0.187
±0.005
30
38
60
SRE-55
45
SRC-66
60
SRE-66
45
SRC-88
60
SRE-88
45
SRC-1010
60
SRE-1010
45
1
+0.000 – 0.005
1
0.240
0.187
±0.005
45
53
45
11⁄4
0.300
0.235
±0.005
30
38
60
11⁄4
0.300
0.235
±0.005
45
53
45
Boring Machines, Origin.—The first boring machine was built by John Wilkinson, in 1775. Smeaton had built one in 1769 which had a large rotary head, with inserted cutters, carried on the end of a light, overhanging shaft. The cylinder to be bored was fed forward against the cutter on a rude carriage, running on a track laid in the floor. The cutter head followed the inaccuracies of the bore, doing little more than to smooth out local roughness of the surface. Watt’s first steam cylinders were bored on this machine and he complained that one, 18 inches in diameter, was 3⁄8 inch out of true. Wilkinson thought of the expedient, which had escaped both Smeaton and Watt, of extending the boring-bar completely through the cylinder and giving it an out-board bearing, at the same time making it much larger and stiffer. With this machine cylinders 57 inches in diameter were bored which were within 1⁄16 inch of true. Its importance can hardly be overestimated as it insured the commercial success of Watt’s steam engine which, up to that time, had not passed the experimental stage.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 892
TAPS AND THREADING DIES
TAPS AND THREADING DIES Taps General dimensions and tap markings given in the ASME B94.9 Standard for straight fluted taps, spiral pointed taps, spiral pointed only taps, spiral fluted taps, fast spiral fluted taps, thread forming taps, pulley taps, nut taps, and pipe taps are shown in the tables on the pages that follow. This Standard also gives the thread limits for taps with cut threads and ground threads. The thread limits for cut thread and ground thread taps for screw threads are given in Tables 1 through 5 and Tables 4a and 4b; thread limits for cut thread and ground thread taps for pipe threads are given in Tables 6a through 7c. Taps recommended for various classes of Unified screw threads are given in Tables 8a through 11 in numbered sizes and Table 9 for nuts in fractional sizes. Types of Taps.—Taps included in ASME B94.9 are categorized either by the style of fluting or by the specific application for which the taps are designed. The following types 1 through 6 are generally short in length, and were originally called “Hand Taps” but this design is generally used in machine applications. The remaining types have special lengths, which are detailed in the tables. The thread size specifications for these types may be fractional or machine screw inch sizes, or metric sizes. The thread form may be ground or cut (unground) as further defined in each table. Additionally, the cutting chamfer on the thread may be Bottoming (B), Plug (P), or Taper (T). (1) Straight Flute Taps: These taps have straight flutes of a number specified as either standard or optional, and are for general purpose applications. (2) Spiral Pointed Taps: These taps have straight flutes and the cutting face of the first few threads is ground at an angle to force the chips ahead and prevent clogging in the flutes. (3) Spiral Pointed Only Taps: These taps are made with the spiral point feature only without longitudinal flutes. These taps are especially suitable for tapping thin materials. (4) Spiral Fluted Taps: These taps have right-hand helical flutes with a helix angle of 25 to 35 deg. These features are designed to help draw chips from the hole or to bridge a keyway. (5) Fast Spiral Fluted Taps: These taps are similar to spiral fluted taps, except the helix angle is from 45 to 60 deg. (6) Thread Forming Taps: These taps are fluteless except as optionally designed with one or more lubricating grooves. The thread form on the tap is lobed, so that there are a finite number of points contacting the work thread form. The tap does not cut, but forms the thread by extrusion. (7) Pulley Taps: These taps have shanks that are extended in length by a standard amount for use where added reach is required. The shank is the same nominal diameter as the thread. (8) Nut Taps: These taps are designed for tapping nuts on a low-production basis. Approximately one-half to three-quarters of the threaded portion has a chamfered section, which distributes the cutting over many teeth and facilitates entering the hole to be tapped. The length overall, the length of the thread, and the length of the shank are appreciably longer than on a regular straight fluted tap. Nut taps have been removed from ASME B94.9 but are retained for reference. (9) Pipe Taps: These taps are used to produce standard straight or tapered pipe threads. Definitions of Tap Terms.—The definitions that follow are taken from ASME B94.9 but include only the more important terms. Some tap terms are the same as screw thread terms; therefore, see Definitions of Screw Threads starting on page 1727. Back Taper: A gradual decrease in the diameter of the thread form on a tap from the chamfered end of the land toward the back, which creates a slight radial relief in the threads.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
893
Base of Thread: Coincides with the cylindrical or conical surface from which the thread projects. Chamfer: Tapering of the threads at the front end of each land or chaser of a tap by cutting away and relieving the crest of the first few teeth to distribute the cutting action over several teeth. Chamfer Angle: Angle formed between the chamfer and the axis of the tap measured in an axial plane at the cutting edge. Chamfer Relief Angle: Complement of the angle formed between a tangent to the relieved surface at the cutting edge and a radial line to the same point on the cutting edge. Core Diameter: Diameter of a circle which is tangent to the bottom of the flutes at a given point on the axis. First Full Thread: First full thread on the cutting edge back of the chamfer. It is at this point that rake, hook, and thread elements are measured. Crest Clearance: Radial distance between the root of the internal thread and the crest of the external thread of the coaxially assembled design forms of mating threads. Class of Thread: Designation of the class that determines the specification of the size, allowance, and tolerance to which a given threaded product is to be manufactured. It is not applicable to the tools used for threading. Tap Terms Overall Length Shank Thread Length Length Chamfer Axis Length
Length of Sq.
Size of Square
Core Dia. Land Flute
;;; ;;;;;; ;;;;;;; Point Dia.
Style 1
2
3 Shank Dia.
90°
Thread Lead Angle
Pitch
Max. Tap Major Dia.
Min. Tap Major Dia.
Internal Center
Tap Crest Basic Crest
Basic Height of Thread
Basic Major Dia.
Angle of Thread Flank
Basic Pitch Dia.
Basic Minor Dia. Base of Thread Basic Root
Relieved to Cutting Edge
No Relief
Cutting Edge Cutting Face
External Center
Chamfer Angle
Concentric Margin Eccentric Relief
Heel
Concentric
Eccentric
Con-Eccentric Relief
Land
Negative Rake Angle
Zero Rake
Positive Rake Angle
Negative Rake
Radial
Positive Rake
Tangential Measurement Hook Angle (Chordal Measurement)
Hook
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 894
TAPS AND THREADING DIES
Flank Angle: Angle between the individual flank and the perpendicular to the axis of the thread, measured in an axial plane. A flank angle of a symmetrical thread is commonly termed the “half angle of thread.” Flank—Leading: 1) Flank of a thread facing toward the chamfered end of a threading tool; and 2) The leading flank of a thread is the one which, when the thread is about to be assembled with a mating thread, faces the mating thread. Flank—Trailing: The trailing flank of a thread is the one opposite the leading flank. Flutes: Longitudinal channels formed in a tap to create cutting edges on the thread profile and to provide chip spaces and cutting fluid passages. On a parallel or straight thread tap they may be straight, angular or helical; on a taper thread tap they may be straight, angular or spiral. Flute-Angular: A flute lying in a plane intersecting the tool axis at an angle. Flute-Helical: A flute with uniform axial lead and constant helix in a helical path around the axis of a cylindrical tap. Flute-Spiral: A flute with uniform axial lead in a spiral path around the axis of a conical tap. Flute Lead Angle: Angle at which a helical or spiral cutting edge at a given point makes with an axial plane through the same point. Flute-Straight: A flute which forms a cutting edge lying in an axial plane. Front Taper: A gradual increase in the diameter of the thread form on a tap from the leading end of the tool toward the back. Heel: Edge of the land opposite the cutting edge. Hook Angle: Inclination of a concave cutting face, usually specified either as Chordal Hook or Tangential Hook. Hook-Chordal Angle: Angle between the chord passing through the root and crest of a thread form at the cutting face, and a radial line through the crest at the cutting edge. Hook-Tangential Angle: Angle between a line tangent to a hook cutting face at the cutting edge and a radial line to the same point. Interrupted Thread Tap: A tap having an odd number of lands with alternate teeth in the thread helix removed. In some designs alternate teeth are removed only for a portion of the thread length. Land: One of the threaded sections between the flutes of a tap. Lead: Distance a screw thread advances axially in one complete turn. Lead Error: Deviation from prescribed limits. Lead Deviation: Deviation from the basic nominal lead. Progressive Lead Deviation: (1) On a straight thread the deviation from a true helix where the thread helix advances uniformly. (2) On a taper thread the deviation from a true spiral where the thread spiral advances uniformly. Length of Thread: The length of the thread of the tap includes the chamfered threads and the full threads but does not include an external center. It is indicated by the letter “B” in the illustrations at the heads of the tables. Limits: The limits of size are the applicable maximum and minimum sizes. Major Diameter: On a straight thread the major diameter is that of the major cylinder. On a taper thread the major diameter at a given position on the thread axis is that of the major cone at that position. Minor Diameter: On a straight thread the minor diameter is that of the minor cylinder. On a taper thread the minor diameter at a given position on the thread axis is that of the minor cone at that position. Pitch Diameter (Simple Effective Diameter): On a straight thread, the pitch diameter is the diameter of the imaginary coaxial cylinder, the surface of which would pass through the thread profiles at such points as to make the width of the groove equal to one-half the basic pitch. On a perfect thread this coincidence occurs at the point where the widths of the thread and groove are equal. On a taper thread, the pitch diameter at a given position on the thread axis is the diameter of the pitch cone at that position.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
895
Point Diameter: Diameter at the cutting edge of the leading end of the chamfered section. Rake: Angular relationship of the straight cutting face of a tooth with respect to a radial line through the crest of the tooth at the cutting edge. Positive rake means that the crest of the cutting face is angularly ahead of the balance of the cutting face of the tooth. Negative rake means that the crest of the cutting face is angularly behind the balance of the cutting face of the tooth. Zero rake means that the cutting face is directly on a radial line. Relief: Removal of metal behind the cutting edge to provide clearance between the part being threaded and the threaded land. Relief-Center: Clearance produced on a portion of the tap land by reducing the diameter of the entire thread form between cutting edge and heel. Relief-Chamfer: Gradual decrease in land height from cutting edge to heel on the chamfered portion of the land on a tap to provide radial clearance for the cutting edge. Relief-Con-eccentric Thread: Radial relief in the thread form starting back of a concentric margin. Relief-Double Eccentric Thread: Combination of a slight radial relief in the thread form starting at the cutting edge and continuing for a portion of the land width, and a greater radial relief for the balance of the land. Relief-Eccentric Thread: Radial relief in the thread form starting at the cutting edge and continuing to the heel. Relief-Flatted Land: Clearance produced on a portion of the tap land by truncating the thread between cutting edge and heel. Relief-Grooved Land: Clearance produced on a tap land by forming a longitudinal groove in the center of the land. Relief-Radial: Clearance produced by removal of metal from behind the cutting edge. Taps should have the chamfer relieved and should have back taper, but may or may not have relief in the angle and on the major diameter of the threads. When the thread angle is relieved, starting at the cutting edge and continuing to the heel, the tap is said to have “eccentric” relief. If the thread angle is relieved back of a concentric margin (usually onethird of land width), the tap is said to have “con-eccentric” relief. Size-Actual: Measured size of an element on an individual part. Size-Basic: That size from which the limits of size are derived by the application of allowances and tolerances. Size-Functional: The functional diameter of an external or internal thread is the pitch diameter of the enveloping thread of perfect pitch, lead and flank angles, having full depth of engagement but clear at crests and roots, and of a specified length of engagement. It may be derived by adding to the pitch diameter in an external thread, or subtracting from the pitch diameter in an internal thread, the cumulative effects of deviations from specified profile, including variations in lead and flank angle over a specified length of engagement. The effects of taper, out-of-roundness, and surface defects may be positive or negative on either external or internal threads. Size-Nominal: Designation used for the purpose of general identification. Spiral Flute: See Flutes. Spiral Point: Angular fluting in the cutting face of the land at the chamfered end. It is formed at an angle with respect to the tap axis of opposite hand to that of rotation. Its length is usually greater than the chamfer length and its angle with respect to the tap axis is usually made great enough to direct the chips ahead of the tap. The tap may or may not have longitudinal flutes. Thread Lead Angle: On a straight thread, the lead angle is the angle made by the helix of the thread at the pitch line with a plane perpendicular to the axis. On a taper thread, the lead angle at a given axial position is the angle made by the conical spiral of the thread, with the plane perpendicular to the axis, at the pitch line.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 896
TAPS AND THREADING DIES Table 1. ANSI Standard Fraction-Size Taps — Cut Thread Limits ASME B94.9-1999 Threads per Inch
Major Diameter
Pitch Diameter
NC UNC
NF UNF
NS UNS
Basic
Min.
Max.
Basic
Min.
Max.
1⁄ 8
…
…
40
0.1250
0.1266
0.1286
0.1088
0.1090
0.1105
5⁄ 32
…
…
32
0.1563
0.1585
0.1605
0.1360
0.1365
0.1380
3⁄ 16
…
…
24
0.1875
0.1903
0.1923
0.1604
0.1609
0.1624
3⁄ 16
…
…
32
0.1875
0.1897
0.1917
0.1672
0.1677
0.1692
1⁄ 4
20
…
…
0.2500
0.2532
0.2557
0.2175
0.2180
0.2200
1⁄ 4
…
28
…
0.2500
0.2524
0.2549
0.2268
0.2273
0.2288
5⁄ 16
18
…
…
0.3125
0.3160
0.3185
0.2764
0.2769
0.2789
5⁄ 16
…
24
…
0.3125
0.3153
0.3178
0.2854
0.2859
0.2874
3⁄ 8
16
…
…
0.3750
0.3789
0.3814
0.3344
0.3349
0.3369
3⁄ 8
…
24
…
0.3750
0.3778
0.3803
0.3479
0.3484
0.3499
7⁄ 16
14
…
…
0.4375
0.4419
0.4449
0.3911
0.3916
0.3941
7⁄ 16
…
20
…
0.4375
0.4407
0.4437
0.4050
0.4055
0.4075
1⁄ 2
13
…
…
0.5000
0.5047
0.5077
0.4500
0.4505
0.4530
1⁄ 2
…
20
…
0.5000
0.5032
0.5062
0.4675
0.4680
0.4700
9⁄ 16
12
…
…
0.5625
0.5675
0.5705
0.5084
0.5089
0.5114
9⁄ 16
…
18
…
0.5625
0.5660
0.5690
0.5264
0.5269
0.5289
5⁄ 8
11
…
…
0.6250
0.6304
0.6334
0.5660
0.5665
0.5690
5⁄ 8
…
18
…
0.6250
0.6285
0.6315
0.5889
0.5894
0.5914
3⁄ 4
10
…
…
0.7500
0.7559
0.7599
0.6850
0.6855
0.6885
3⁄ 4
…
16
…
0.7500
0.7539
0.7579
0.7094
0.7099
0.7124
7⁄ 8
9
…
…
0.8750
0.8820
0.8860
0.8028
0.8038
0.8068
7⁄ 8
…
14
…
0.8750
0.8799
0.8839
0.8286
0.8296
0.8321
Tap Size
1
8
…
…
1.0000
1.0078
1.0118
0.9188
0.9198
0.9228
1
…
12
…
1.0000
1.0055
1.0095
0.9459
0.9469
0.9494
1
…
…
14
1.0000
1.0049
1.0089
0.9536
0.9546
0.9571
11⁄8
7
…
…
1.1250
1.1337
1.1382
1.0322
1.0332
1.0367
11⁄8
…
12
…
1.1250
1.1305
1.1350
1.0709
1.0719
1.0749
11⁄4
7
…
…
1.2500
1.2587
1.2632
1.1572
1.1582
1.1617
11⁄4
…
12
…
1.2500
1.2555
1.2600
1.1959
1.1969
1.1999
13⁄8
6
…
…
1.3750
1.3850
1.3895
1.2667
1.2677
1.2712
13⁄8
…
12
…
1.3750
1.3805
1.3850
1.3209
1.3219
1.3249
11⁄2
6
…
…
1.5000
1.5100
1.5145
1.3917
1.3927
1.3962
11⁄2
…
12
…
1.5000
1.5055
1.5100
1.4459
1.4469
1.4499
13⁄4
5
…
…
1.7500
1.7602
1.7657
1.6201
1.6216
1.6256
2
41⁄2
…
…
2.0000
2.0111
2.0166
1.8557
1.8572
1.8612
All dimensions are given in inches. Lead Tolerance: Plus or minus 0.003 inch max. per inch of thread. Angle Tolerance: Plus or minus 35 min. in half angle or 53 min. in full angle for 41⁄2 to 51⁄2 thds. per in.; 40 min. half angle and 60 min. full angle for 6 to 9 thds.; 45 min. half angle and 68 min. full angle for 10 to 28 thds.; 60 min. half angle and 90 min. full angle for 30 to 64 thds. per in.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 2. ANSI Standard Fractional-Size Taps — Ground Thread Limits ASME B94.9-1999 Threads per Inch Size in.
1 1 1 11⁄8 11⁄8 11⁄4 11⁄4 13⁄8 13⁄8 11⁄2 11⁄2 13⁄4 2
NF UNF
NS UNS
20 … 18 … 16 … 14 … 13 … 12 … 11 … … … 10 … 9 … 8 … … 7 … 7 … 6 … 6 … … …
… 28 … 24 … 24 … 20 … 20 … 18 … 18 … … … 16 … 14 … 12 … … 12 … 12 … 12 … 12 5 4.5
… … … … … … … … … … … … … … 11 16 … … … … … … 14 … … … … … … … … … …
Major Diameter Basic 0.2500 0.2500 0.3125 0.3125 0.3750 0.3750 0.4375 0.4375 0.5000 0.5000 0.5625 0.5625 0.6250 0.6250 0.6875 0.6875 0.7500 0.7500 0.8750 0.8750 1.0000 1.0000 1.0000 1.1250 1.1250 1.2500 1.2500 1.3750 1.3750 1.5000 1.5000 1.7500 2.0000
Min. 0.2532 0.2523 0.3161 0.3152 0.3790 0.3777 0.4422 0.4407 0.5050 0.5032 0.5679 0.5661 0.6309 0.6286 0.6934 0.6915 0.7565 0.7540 0.8822 0.8797 1.0082 1.0054 1.0047 1.1343 1.1304 1.2593 1.2554 1.3859 1.3804 1.5109 1.5054 1.7630 2.0145
Basic Pitch Dia.
Max. 0.2565 0.2546 0.3197 0.3179 0.3831 0.3804 0.4468 0.4440 0.5100 0.5065 0.5733 0.5697 0.6368 0.6322 0.6993 0.6956 0.7630 0.7581 0.8894 0.8843 1.0163 1.0108 1.0093 1.1436 1.1358 1.2686 1.2608 1.3967 1.3858 1.5217 1.5108 1.7760 2.0289
0.2175 0.2268 0.2764 0.2854 0.3344 0.3479 0.3911 0.4050 0.4500 0.4675 0.5084 0.5264 0.5660 0.5889 0.6285 0.6469 0.6850 0.7094 0.8028 0.8286 0.9188 0.9459 0.9536 1.0322 1.0709 1.1572 1.1959 1.2667 1.3209 1.3917 1.4459 1.6201 1.8557
H1 Limit Min. Max. 0.2175 0.2268 0.2764 0.2854 0.3344 0.3479 … … 0.4500 0.4675 … … … … … … … 0.7094 … …
0.2180 0.2273 0.2769 0.2859 0.3349 0.3484 … … 0.4505 0.4680 … … … … … … … 0.7099 … …
H2 Limit Min. Max. 0.2180 0.2273 0.2769 0.2859 0.3349 0.3484 0.3916 … 0.4505 0.4680 … 0.5269 0.5665 0.5894 … … 0.6855 0.7099 … 0.8291
0.2185 0.2278 0.2774 0.2864 0.3354 0.3489 0.3921 … 0.4510 0.4685 … 0.5274 0.5670 0.5899 … … 0.6860 0.7104 … 0.8296
Notes: a H4
limit value; b H5 limit value; c H6 limit value; e H7 limit value; f H8 limit value. Minimum and maximum major diameters are: d 0.0010 larger than shown; g 0.0035 larger than shown; h 0.0020 larger than shown; i 0.0015 larger than shown.
Pitch Diameter H3 & H4 a Limits Min. Max. 0.2185 0.2278 0.2774 0.2864 0.3354 0.3489 0.3921 0.4060 0.4510 0.4685 0.5094 0.5274 0.5670 0.5899 0.6295 0.6479 0.6860 0.7104 0.8043 a 0.8301 a 0.9203 a 0.9474 a 0.9551 a 1.0337 a 1.0724 a 1.1587 a 1.1974 a 1.2682 a 1.3224 a 1.3932 a 1.4474 a 1.6216 a 1.8572 a
0.2190 0.2283 0.2779 0.2869 0.3359 0.3494 0.3926 0.4065 0.4515 0.4690 0.5099 0.5279 0.5675 0.5904 0.6300 0.6484 0.6865 0.7109 0.8048 a 0.8306 a 0.9208 a 0.9479 a 0.9556 a 1.0342 a 1.0729 a 1.1592 a 1.1979 a 1.2687 a 1.3229 a 1.3937 a 1.4479 a 1.6221 a 1.8577 a
H4 a, H5 b, H6 c Limits Min. Max. b, d
0.2195 0.2283 a 0.2784 b, d 0.2869 a 0.3364 b, d 0.3494 a 0.3931b, d 0.4070 b, d 0.4520 b, d 0.4695 b, d 0.5104 b, d 0.5284 b, d 0.5680 b, d 0.5909 b, d … … 0.6870 b, d 0.7114 b, d 0.8053 c … 0.9213 c … … … … … … … … … … … …
b, d
0.2200 0.2288 a 0.2789 b, d 0.2874 a 0.3369 b, d 0.3499 a 0.3936 b, d 0.4075 b, d 0.4525 b, d 0.4700 b, d 0.5109 b, d 0.5289 b, d 0.5685 b, d 0.5914 b, d … … 0.6875 b, d 0.7119 b, d 0.8058 c … 0.9218 c … … … … … … … … … … … …
H7 e, H8 f Limits Min. Max. … … 0.2794 e, h 0.2884 e, h 0.3374 e, h 0.3509 e, h 0.3946 f 0.4085 f 0.4536 f 0.4710 f 0.5114 e, h 0.5294 e, h 0.5690 e, h 0.5919 e, h … … 0.6880 e, i 0.7124 e, i … … … … … … … … … … … … … … …
… … 0.2799 e, h 0.2889 e, h 0.3379 e, h 0.3514 e, h 0.3951 f 0.4090 f 0.4240 f 0.4715 f 0.5119 e, h 0.5299 e, h 0.5695 e, h 0.5924 e, h … … 0.6885 e, i 0.7129 e, i … … … … … … … … … … … … … … …
Copyright 2004, Industrial Press, Inc., New York, NY
897
All dimensions are given in inches. Limits listed in the above table are the most commonly used in industry. Not all styles of taps are available with all limits listed. For calculation of limits not listed see ASME B94.9-1999
TAPS AND THREADING DIES
1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 7⁄ 16 7⁄ 16 1⁄ 2 1⁄ 2 9⁄ 16 9⁄ 16 5⁄ 8 5⁄ 8 11⁄ 16 11⁄ 16 3⁄ 4 3⁄ 4 7⁄ 8 7⁄ 8
NC UNC
Machinery's Handbook 27th Edition
Major Diameter
898
Table 3. ANSI Standard Machine Screw Taps — Ground Thread Limits ASME B94.9-1999 Threads per Inch
Pitch Diameter Limits H1 Limit
H3 a, H4 b, H5 c Limits
H2 Limit
Max.
Basic Pitch Dia.
Min.
Max.
Min.
Max.
Min.
0.0616
0.0519
0.0519
0.0524
0.0524
0.0529
Notes:
Size
NC UNC
NF UNF
NS UNS
Basic
Min.
0
…
80
…
0.0600
0.0605
1
64
…
…
0.0730
0.0736
0.0750
0.0629
0.0629
0.0634
0.0634
0.0639
1
…
72
…
0.0730
0.0736
0.0748
0.0640
0.0640
0.0645
0.0645
0.0650
2
56
…
…
0.0860
0.0867
0.0883
0.0744
0.0744
0.0749
0.0749
0.0754
…
64
…
0.0860
0.0866
0.0880
0.0759
…
…
0.0764
0.0769
48
…
…
0.0990
0.0999
0.1017
0.0855
…
…
0.0860
0.0865 0.0884
H6 d, H7 e, H10 f Limits Min.
Max.
a H3 d H6
limit value; b H4 limit value; c H5 limit value; limit value; e H7 limit value; f H10 limit value.
Minimum and maximum major diameters are: g 0.0010 larger than shown; h 0.0020 larger than shown;i 0.0035 larger than shown; j 0.0015 larger than shown.
3
…
56
…
0.0990
0.0997
0.1013
0.0874
0.0874
0.0879
0.0879
4
40
…
…
0.1120
0.1134
0.1152
0.0958
0.0958
0.0963
0.0963
0.0968
0.0978 c, j
0.0983 c, j
…
…
4
…
48
…
0.1120
0.1129
0.1147
0.0985
0.0985
0.0990
0.0990
0.0995
0.1005 c, j
0.1010 c, j
…
…
4
…
…
36
0.1120
0.1135
0.1156
0.0940
0.0940
0.0945
0.0945
0.0950
0.0960 c, j
0.0965 c, j
…
…
5
40
…
…
0.1250
0.1264
0.1283
0.1088
0.1088
0.1093
0.1093
0.1098
0.1108 c, j
0.1113 c, j
…
…
5
…
44
…
0.1250
0.1263
0.1280
0.1102
…
…
0.1107
0.1112
0.1122 c, j
0.1127 c, j
…
6
32
…
…
0.1380
0.1401
0.1421
0.1177
0.1177
0.1182
0.1182
0.1187
0.1187 a 0.1197 c, g
0.1192 a 0.1202 g
0.1207 e, h 0.1222 f, i
6
…
40
…
0.1380
0.1394
0.1413
0.1218
0.1218
0.1223
0.1223
0.1228
0.1238 c
0.1243 c
…
…
8
32
…
…
0.1640
0.1661
0.1681
0.1437
0.1437
0.1442
0.1442
0.1447
0.1447 a 0.1457 g
0.1452 a 0.1462 g
0.1467 e, h 0.1482 f, i
0.1472 e, h 0.1487 f, i
…
… 0.1212 e, h 0.1227 f, i
8
…
36
…
0.1640
0.1655
0.1676
0.1460
…
…
0.1465
0.1470
0.1480 g
0.1485 g
10
24
…
…
0.1900
0.1927
0.1954
0.1629
0.1629
0.1634
0.1634
0.1639
0.1639 a 0.1644 b
0.1644 a 0.1649 b
0.1654 d, g 0.1659 e, h
0.1659 d, g 0.1664 e, h
10
…
32
…
0.1900
0.1921
0.1941
0.1697
0.1697
0.1702
0.1702
0.1707
0.1707 a 0.1712 b
0.1712 a 0.1717 b
0.1722 d, g 0.1727 e, h 0.1742 f, i
0.1727 d, g 0.1732 e, h 0.1747 f, i
12
24
…
…
0.2160
0.2187
0.2214
0.1889
…
…
…
…
0.1899 a 0.0914 b
0.1904 a 0.1919 b
0.1914 d, g
0.1919 d, g
12
…
28
…
0.2160
0.2183
0.2206
0.1928
…
…
…
…
0.1938 a 0.1953 b
0.1943 a 0.1958 b
0.1953 d, g
0.1958 d, g
All dimensions are given in inches. Limits listed in table are most commonly used in industry. Not all style of taps are available with all limits listed.
Copyright 2004, Industrial Press, Inc., New York, NY
…
TAPS AND THREADING DIES
2 3
Max.
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
899
Table 4a. ANSI Standard Metric Tap Ground Thread Limits in Inches — M Profile ASME B94.9-1999 Nominal Diam, mm 1.6 2 2.5 3 3.5 4 4.5 5 6 7 8 10 12 14 16 20 24 30 36 42 48
Pitch, mm 0.35 0.4 0.45 0.5 0.6 0.7 0.75 0.8 1 1 1.25 1.5 1.75 2 2 2.5 3 3.5 4 4.5 5
Basic 0.06299 0.07874 0.09843 0.11811 0.13780 0.15748 0.17717 0.19685 0.23622 0.27559 0.31496 0.39370 0.47244 0.55118 0.62992 0.78740 0.94488 1.18110 1.41732 1.65354 1.88976
Major Diameter (Inches) Min 0.06409 0.08000 0.09984 0.11969 0.13969 0.15969 0.17953 0.19937 0.23937 0.27874 0.31890 0.39843 0.47795 0.55748 0.63622 0.79538 0.95433 1.19213 1.42992 1.66772 1.90551
Max 0.06508 0.08098 0.10083 0.12067 0.14067 0.16130 0.18114 0.20098 0.24098 0.28035 0.32142 0.40094 0.48047 0.56000 0.63874 0.79780 0.95827 1.19606 1.43386 1.71102 1.98819
Basic 0.05406 0.06850 0.08693 0.10531 0.12244 0.13957 0.15799 0.17638 0.21063 0.25000 0.28299 0.35535 0.42768 0.50004 0.57878 0.72346 0.86815 1.09161 1.31504 1.53846 1.76189
Pitch Diameter (Inches) Min 0.05500 0.06945 0.08787 0.10626 0.12370 0.14083 0.15925 0.17764 0.21220 0.25157 0.28433 0.35720 0.42953 0.50201 0.58075 0.72543 0.87063 1.09417 1.31760 1.54154 1.76496
Max 0.05559 0.07004 0.08846 0.10685 0.12449 0.14161 0.16004 0.17843 0.21319 0.25256 0.28555 0.35843 0.43075 0.50362 0.58236 0.72705 0.87224 1.09622 1.31965 1.54358 1.76701
Basic pitch diameter is the same as minimum pitch diameter of internal thread, Class 6H as shown in table starting on page 1798. Pitch diameter limits are designated in the Standard as D3 for 1.6 to 3 mm diameter sizes, incl.: D4 for 3.5 to 5 mm sizes, incl.; D5 for 6 and 8 mm sizes; D6 for 10 and 12 mm sizes; D7 for 14 to 20 mm sizes, incl.; D8 for 24 mm size; and D9 for 30 and 36 mm sizes. Angle tolerances are plus or minus 30 minutes in half angle for pitches ranging from 0.35 through 2.5 mm, incl. and plus or minus 25 minutes in half angle for pitches ranging from 3 to 4 mm, incl. A maximum deviation of plus or minus 0.0005 inch within any two threads not farther apart than one inch is permitted.
Table 4b. ANSI Standard Metric Tap Ground Thread Limits in Millimeters— M Profile ASME B94.9-1999 Nominal Diam, mm 1.6 2 2.5 3 3.5 4 4.5 5 6 7 8 10 12 14 16 20 24 30 36 42 48
Pitch, mm 0.35 0.4 0.45 0.5 0.6 0.7 0.75 0.8 1 1 1.25 1.5 1.75 2 2 2.5 3 3.5 4 4.5 5
Basic 1.600 2.000 2.500 3.000 3.500 4.000 4.500 5.000 6.000 7.000 8.000 10.000 12.000 14.000 16.000 20.000 24.000 30.000 36.000 42.000 48.000
Major Diameter (mm) Min 1.628 2.032 2.536 3.040 3.548 4.056 4.560 5.064 6.080 7.080 8.100 10.120 12.140 14.160 16.160 20.200 24.240 30.280 36.320 42.360 48.400
Max
Basic
Pitch Diameter (mm) Min
Max
1.653 2.057 2.561 3.065 3.573 4.097 4.601 5.105 6.121 7.121 8.164 10.184 12.204 14.224 16.224 20.264 24.340 30.380 36.420 43.460 50.500
1.373 1.740 2.208 2.675 3.110 3.545 4.013 4.480 5.350 6.350 7.188 9.026 10.863 12.701 14.701 18.376 22.051 27.727 33.402 39.077 44.752
1.397 1.764 2.232 2.699 3.142 3.577 4.045 4.512 5.390 6.390 7.222 9.073 10.910 12.751 14.751 18.426 22.114 27.792 33.467 39.155 44.830
1.412 1.779 2.247 2.714 3.162 3.597 4.065 4.532 5.415 6.415 7.253 9.104 10.941 12.792 14.792 18.467 22.155 27.844 33.519 36.207 44.882
Basic pitch diameter is the same as minimum pitch diameter of internal thread, Class 6H as shown in table starting on page 1798. Pitch diameter limits are designated in the Standard as D3 for 1.6 to 3 mm diameter sizes, incl.: D4 for 3.5 to 5 mm sizes, incl.; D5 for 6 and 8 mm sizes; D6 for 10 and 12 mm sizes; D7 for 14 to 20 mm sizes, incl.; D8 for 24 mm size; D9 for 30 and 36 mm sizes; D10 for 42 and 48 mm sizes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 900
TAPS AND THREADING DIES Table 5. ANSI Standard Machine Screw Taps — Cut Threads Limits ASME B94.9-1999
Size
NC UNC
Threads per Inch NF NS UNF UNS
… 64 … 56 … 48 … … 40 … 40 32 … … 32 … … 24 … 24 … …
0 1 1 2 2 3 3 4 4 4 5 6 6 6 8 8 8 10 10 12 12 14
80 … 72 … 64 … 56 … … 48 … … … 40 … 36 … … 32 … 28 …
… … … … … … … 36 … … … … 36 … … … 40 … … … … 24
Major Diameter
Pitch Diameter
Basic
Min.
Max.
Basic
Min.
Max.
0.0600 0.0730 0.0730 0.0860 0.0860 0.0990 0.0990 0.1120 0.1120 0.1120 0.1250 0.1380 0.1380 0.1380 0.1640 0.1640 0.1640 0.1900 0.1900 0.2160 0.2160 0.2420
0.0609 0.0740 0.0740 0.0872 0.0870 0.1003 0.1002 0.1137 0.1136 0.1133 0.1266 0.1402 0.1397 0.1396 0.1662 0.1657 0.1656 0.1928 0.1922 0.2188 0.2184 0.2448
0.0624 0.0755 0.0755 0.0887 0.0885 0.1018 0.1017 0.1157 0.1156 0.1153 0.1286 0.1422 0.1417 0.1416 0.1682 0.1677 0.1676 0.1948 0.1942 0.2208 0.2204 0.2473
0.0519 0.0629 0.0640 0.0744 0.0759 0.0855 0.0874 0.0940 0.0958 0.0985 0.1088 0.1177 0.1200 0.1218 0.1437 0.1460 0.1478 0.1629 0.1697 0.1889 0.1928 0.2149
0.0521 0.0631 0.0642 0.0746 0.0761 0.0857 0.0876 0.0942 0.0960 0.0987 0.1090 0.1182 0.1202 0.1220 0.1442 0.1462 0.1480 0.1634 0.1702 0.1894 0.1933 0.2154
0.0531 0.0641 0.0652 0.0756 0.0771 0.0867 0.0886 0.0957 0.0975 0.1002 0.1105 0.1197 0.1217 0.1235 0.1457 0.1477 0.1495 0.1649 0.1717 0.1909 0.1948 0.2174
All dimensions are given in inches. Lead Tolerance: Plus or minus 0.003 inch per inch of thread. Angle Tolerance: Plus or minus 45 min. in half angle and 65 min. in full angle for 20 to 28 threads per inch; plus or minus 60 min. in half angle and 90 min. in full angle for 30 or more threads per inch.
Table 6a. ANSI Standard Taper Pipe Taps — Cut Thread Tolerances for NPT and Ground Thread Tolerances for NPT, NPTF, and ANPT ASME B94.9-1999
Nominal Size 1⁄ 16 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4
1 11⁄4 11⁄2 2 21⁄2 3 31⁄2 b 4b
Threads per Inch NPT, NPTF, or ANPT 27 27 18 18 14 14 111⁄2 111⁄2 111⁄2 111⁄2 8 8 8 8
Gage Measurementa Tolerance Plus or Minus Cut Ground Projection Thread Thread Inches 0.312 0.312 0.459 0.454 0.579 0.565 0.678 0.686 0.699 0.667 0.925 0.925 0.938 0.950
0.0625 0.0625 0.0625 0.0625 0.0625 0.0625 0.0937 0.0937 0.0937 0.0937 0.0937 0.0937 1⁄ 8 1⁄ 8
0.0625 0.0625 0.0625 0.0625 0.0625 0.0625 0.0937 0.0937 0.0937 0.0937 0.0937 0.0937 1⁄ 8 1⁄ 8
Taper per Inch on Diameter, Inches Cut Thread Ground Thread Min.
Max.
Min.
Max.
0.0599 0.0599 0.0599 0.0599 0.0599 0.0599 0.0599 0.0599 0.0599 0.0599 0.0612 0.0612 47⁄ c 64 47⁄ c 64
0.0703 0.0703 0.0703 0.0703 0.0677 0.0677 0.0677 0.0677 0.0677 0.0677 0.0664 0.0664 51⁄ c 64 51⁄ c 64
0.0599 0.0599 0.0599 0.0599 0.0599 0.0599 0.0599 0.0599 0.0599 0.0599 0.0612 0.0612 47⁄ c 64 47⁄ c 64
0.0651 0.0651 0.0651 0.0651 0.0651 0.0651 0.0651 0.0651 0.0651 0.0651 0.0651 0.0651 25⁄ c 32 25⁄ c 32
a Distance that small end of tap projects through L1 taper ring gage (see ANSI B1.20.3). b
No longer included in ASME B94.9-1999 shown for reference only.
c Taper per foot, inches.
All dimensions are given in inches. Lead Tolerance: Plus or minus 0.003 inch per inch of cut thread and plus or minus 0.0005 inch per inch of ground thread. Angle Tolerance: Plus or minus 40 min. in half angle and 60 min. in full angle for 8 cut threads per inch; plus or minus 45 min. in half angle and 60 min. in full angle for 111⁄2 to 27 cut threads per inch; plus or minus 25 min. in half angle for 8 ground threads per inch; and plus and minus 30 min. in half angle for 111⁄2 to 27 ground threads per inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
901
Table 6b. ANSI Taper Pipe Thread — Widths of Flats at Tap Crests and Roots for Cut Thread NPT and Ground Thread NPT, ANPT, and NPTF ASME B94.9-1999 Threads per Inch 27 18 14 111⁄2 8
{ Major Diameter { Minor Diameter { Major Diameter { Minor Diameter { Major Diameter { Minor Diameter { Major Diameter { Minor Diameter { Major Diameter { Minor Diameter
a Minimum minor diameter
Column II NPTF—Cut and Ground Thread
Column I NPT—Cut and Ground Thread ANPT—Ground Thread
Tap Flat Width at
Minimuma
Maximum
Minimuma
Maximum
0.0014 … 0.0021 … 0.0027 … 0.0033 … 0.0048 …
0.0041 0.0041 0.0057 0.0057 0.0064 0.0064 0.0073 0.0073 0.0090 0.0090
0.0040 … 0.0050 … 0.0050 … 0.0060 … 0.0080 …
0.0055 0.0040 0.0065 0.0050 0.0065 0.0050 0.0083 0.0060 0.0103 0.0080
falts are not specified. May be sharp as practicable.
All dimensions are given in inches. Note: Cut Thread taps made to Column I are marked NPT but are not recommended for ANPT applications. Ground Thread taps made to Column I are marked NPT and may be used for NPT and ANPT applications. Ground Thread taps made to Column II are marked NPTF and used for Dryseal application.
Table 7a. ANSI Standard Straight Pipe Taps (NPSF—Dryseal) Ground Thread Limits ASME B94.9-1999 Major Diameter Nominal Size, Inches 1⁄ 16 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4
Threads per Inch 27 27 18 18 14 14
Min. G 0.3008 0.3932 0.5239 0.6593 0.8230 1.0335
Max. H 0.3018 0.3942 0.5249 0.6603 0.8240 1.0345
Pitch Diameter Plug at Gaging Notch E 0.2812 0.3736 0.4916 0.6270 0.7784 0.9889
Min. K 0.2772 0.3696 0.4859 0.6213 0.7712 0.9817
Max. L 0.2777 0.3701 0.4864 0.6218 0.7717 0.9822
Minora Dia. Flat, Max. 0.004 0.004 0.005 0.005 0.005 0.005
a As specified or sharper.
Formulas For American Dryseal (NPSF) Ground Thread Taps Major Diameter Pitch Diameter Min. Max. Min. Max. G H K L H − 0.0010 K + Q − 0.0005 L − 0.0005 E−F H − 0.0010 K + Q − 0.0005 L − 0.0005 E−F H − 0.0010 K + Q − 0.0005 L − 0.0005 E−F H − 0.0010 K + Q − 0.0005 L − 0.0005 E−F H − 0.0010 K + Q − 0.0005 L − 0.0005 E−F H − 0.0010 K + Q − 0.0005 L − 0.0005 E−F
Nominal Size, Inches 1⁄ 16 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4
Threads per Inch 27 18 14
Values to Use in Formulas F 0.0035 Pitch diameter of plug 0.0052 at gaging notch 0.0067 E
M Actual measured pitch diameter
Max. Minor Dia. M−Q M−Q M−Q M−Q M−Q M−Q Q 0.0251 0.0395 0.0533
All dimensions are given in inches. Lead Tolerance: Plus or minus 0.0005 inch within any two threads not farther apart than one inch. Angle Tolerance: Plus or minus 30 min. in half angle for 14 to 27 threads per inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 902
TAPS AND THREADING DIES Table 7b. ANSI Standard Straight Pipe Taps (NPS) Cut Thread Limits ASME B94.9-1999 Pitch Diameter
Values to Use in Formulas
Threads per Inch, NPS, NPSC
Size at Gaging Notch
Min.
Max.
A
B
C
1⁄ 8
27
0.3736
0.3721
0.3751
0.0267
0.0296
0.0257
1⁄ 4
18
0.4916
0.4908
0.4938
3⁄ 8
18
0.6270
0.6257
0.6292
} 0.0408
0.0444
0.0401
1⁄ 2
14
0.7784
0.7776
0.7811
3⁄ 4
14
0.9889
0.9876
0.9916
111⁄2
1.2386
1.2372
1.2412
Nominal Size
1
} 0.0535
0.0571
0.0525
0.0658
0.0696
0.0647
The following are approximate formulas, in which M = measured pitch diameter in inches: Major dia., min. = M + A Major dia., max. = M + B Minor dia., max. = M − C
All dimensions are given in inches. Lead Tolerance: Plus or minus 0.003 inch per inch of thread. Angle Tolerance: All pitches, plus or minus 45 min. in half angle and 68 min. in full angle. Taps made to these specifications are to be marked NPS and used for NPSC thread form.
Table 7c. ANSI Standard Straight Pipe Taps (NPS) Ground Thread Limits ASME B94.9-1999
Nominal Size, Inches
Major Diameter Plug at Gaging Notch 0.3983 0.5286 0.6640 0.8260 1.0364 1.2966
Pitch Diameter Plug at Gaging Notch E 0.3736 0.4916 0.6270 0.7784 0.9889 1.2386
Min. K 0.3746 0.4933 0.6287 0.7806 0.9906 1.2402
Max. L 0.3751 0.4938 0.6292 0.7811 0.9916 1.2412
1⁄ 8
Formulas for NPS Ground Thread Tapsa Minor Threads Major Diameter Dia. per Inch Min. G Max. H Max. 27 H − 0.0010 (K + A) − 0.0010 M−B 18
A 0.0296 0.0444
B 0.0257 0.0401
to 3⁄4 1
H − 0.0010
(K + A) − 0.0020
M−B
0.0571
0.0525
H − 0.0015
(K + A) − 0.0021
M−B
1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4
111⁄2
1
Nominal Size 1⁄ 4
Threads per Inch, NPS, NPSC, NPSM 27 18 18 14 14
Min. G 0.4022 0.5347 0.6701 0.8347 1.0447 1.3062
Max. H 0.4032 0.5357 0.6711 0.8357 1.0457 1.3077
14
0.0696 0.0647 111⁄2 The maximum Pitch Diameter of tap is based upon an allowance deducted from the maximum product pitch diameter of NPSC or NPSM, whichever is smaller. The minimum Pitch Diameter of tap is derived by subtracting the ground thread pitch diameter tolerance for actual equivalent size. a In the formulas, M equals the actual measured pitch diameter.
All dimensions are given in inches. Lead tolerance: Plus or minus 0.0005 inch within any two threads not farther apart than one inch. Angle Tolerance: All pitches, plus or minus 30 min. in half angle. Taps made to these specifications are to be marked NPS and used for NPSC and NPSM.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
903
0 1 1 2 2 2 3 3 3 4 4 4 4 5 5 5 6 6 6 6 8 8 8 8 10 10 10 10 10 12 12
0.060 0.073 0.073 0.086 0.086 0.086 0.099 0.099 0.099 0.112 0.112 0.112 0.112 0.125 0.125 0.125 0.138 0.138 0.138 0.138 0.164 0.164 0.164 0.164 0.190 0.190 0.190 0.190 0.190 0.216 0.216
NC NF NS UNC UNF UNS … 64 … 56 56 … 48 48 … … 40 40 … 40 40 … 32 32 … … 32 32 32 … 24 24 … … 24 24 …
80 … 72 … … 64 … … 56 … … … 48 … … 44 … … 40 40 … … … 36 … … 32 32 32 … 28
… … … … … … … … … 36 … … … … … … … … … … … … … … … … … … … … …
No. of Flutes 2 2 2 2b 3 3 2b 3 3 3 2b 3 3 2b 3 3 2b 3 2b 3 2b 3b 4 4 2* 3b 2b 3b 4 4 4
H1
H2
H3
H7
TPB TPB TPB … TPB … … P … … P … … … P … P TPB … P P … TPB … … … P … TPB … …
PB P PB PB TPB TPB PB TPB TPB TPB PB TPB TPB PB TPB TPB PB TPB P TPB PB PB TPB TPB PB P PB PB TPB … …
… … … … … … … … … … … … … … … … PB TPB … … PB PB TPB … PB PB PB PB TPB TPB TPB
… … … … … … … … … … … … … … … … … PB … … … PB PB … … … … PB PB … …
Length Overall A 15⁄8 111⁄16 111⁄16 13⁄4 13⁄4 13⁄4 113⁄16 113⁄16 113⁄16 17⁄8 17⁄8 17⁄8 17⁄8 115⁄16 115⁄16 115⁄16 2 2 2 2 21⁄8 21⁄8 21⁄8 21⁄8 23⁄8 23⁄8 23⁄8 23⁄8 23⁄8 23⁄8 23⁄8
Diameter of Shank D
Basic Major Diameter
Length of Square C
Pitch Dia.Limits and Chamfersa
Threads per Inch Size
Length of Thread B
Table 8a. ANSI Standard Ground Thread Straight Fluted Taps Machine Screw Sizes ASME B94.9-1999
E
5⁄ 16 3⁄ 16 3⁄ 8 7⁄ 16 7⁄ 16 7⁄ 16 1⁄ 2 1⁄ 2 1⁄ 2 9⁄ 16 9⁄ 16 9⁄ 16 9⁄ 16 5⁄ 8 5⁄ 8 5⁄ 8 11⁄ 16 11⁄ 16 11⁄ 16 11⁄ 16 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 7⁄ 8 15⁄ 16 15⁄ 16
3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 9⁄ 32 9⁄ 32
0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.168 0.168 0.168 0.168 0.194 0.194 0.194 0.194 0.194 0.220 0.220
0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.131 0.131 0.131 0.131 0.152 0.152 0.152 0.152 0.152 0.165 0.165
a Chamfer designations are: T = taper, P = plug, and B = bottoming. b Optional number of flutes.
All dimensions are given in inches. These taps are standard as high-speed steel taps with ground threads, with standard and optional number of flutes and pitch diameter limits and chamfers as given in the table. These are style 1 taps and have external centers on thread and shank ends (may be removed on thread end of bottoming taps). For standard thread limits see Table 3. For eccentricity tolerances see Table 22. Tolerances: Numbers 0 to 12 size range — A, ± 1⁄32 ; B, ± 3⁄64 ; C, ± 1⁄32 ; D, − 0.0015; E, − 0.004.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 904
TAPS AND THREADING DIES Table 8b. ANSI Standard Cut Thread Straight Fluted Taps Machine Screw Sizes ASME B94.9-1999
Size
Basic Major Diameter
0 1 2 3 4 5 6 8 10 12 14
0.060 0.073 0.086 0.099 0.112 0.125 0.138 0.164 0.190 0.216 0.242
Threads per Inch Carbon Steel HS Steel NC UNC
NF UNF
NS UNS
NC UNC
NF UNF
Number of Flutes
…
80a 72a 64a 56a 48a …
… … … …
… … … …
36a …
40a 40a 32 32 24 24 …
… … … … … … … … 32 … …
2 2 3 3 3 3 3 4 4 4 4
64a 56 48a 40 40 32 32 24 24 …
40a 36a 32
36a 40a … …
28a …
24a
Length of Thread, B
Length Overall, A 15⁄8 111⁄16 13⁄4 113⁄16 17⁄8 115⁄16 2
Dimensions Length of Diameter Square, of Shank, C D
5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 7⁄ 8 15⁄ 16
21⁄8 23⁄8 23⁄8 21⁄2
3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 1⁄ 4 9⁄ 32 5⁄ 16
1
Size of Square, E
0.141 0.141 0.141 0.141 0.141 0.141 0.141 0.168 0.194 0.220 0.255
0.110 0.110 0.110 0.110 0.110 0.110 0.110 0.131 0.152 0.165 0.191
a These taps are standard with plug chamfer only. All others are standard with taper, plug or bottom-
ing chamfer. Tolerances for General Dimensions Element
Range
Length Overall, A Length of Thread, B
Tolerance
0 to 14 incl
±1⁄32
0 to 12 incl
±3⁄64 ±1⁄16
14
Length of Square, C
Element
Tolerance −0.004 −0.005
14
Size of Square, E
±1⁄32
0 to 14 incl
Range 0 to 12 incl
Diameter of Shank, D
−0.004
0 to 14 incl
All dimensions are given in inches. Styles 1 and 2 cut thread taps have optional style centers on thread and shank ends. For standard thread limits see Table 5. For eccentricity tolerances see Table 22.
Table 9. ANSI Standard Nut Taps (formerly ANSI/ASME B94.9-1987)
Dia. of Tap
Threads per Inch NC,UNC
Number of Flutes
1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2
20 18 16 13
4 4 4 4
Element Overall Length, A Thread Length, B Square Length, C
Diameter Range 1⁄ 4 1⁄ 4 1⁄ 4
to 1⁄2 to 1⁄2 to 1⁄2
Length Overall, A 5 51⁄2 6 7
Length of Thread, B
Length of Square, C
15⁄8 113⁄16 2 21⁄2
9⁄ 16 5⁄ 8 11⁄ 16 7⁄ 8
Tolerances for General Dimensions Tolerance Element ±1⁄16 ±1⁄16 ±1⁄32
Shank Diameter,D Size of Square,E
Diameter of Shank, D
Size of Square, E
0.185 0.240 0.294 0.400
0.139 0.180 0.220 0.300
Diameter Range 1⁄ 4 1⁄ 4
to 1⁄2 to 1⁄2
Tolerance −0.005 −0.004
All dimensions are given in inches. These ground thread high-speed steel taps are standard in H3 limit only. All taps have an internal center in thread end. For standard limits see Table 2. Chamfer J is made 1⁄2 ro 3⁄4 the thread length of B.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
905
Table 10. ANSI Standard Spiral-Pointed Taps Machine Screw Sizes ASME B94.9-1999
High-Speed Steel Taps with Ground Threads Threads per Basic Inch Major NF NS Diam- NC UNC UNF UNS eter
Size
Pitch Dia. Limits and Chamfers†
No. of Flute s
H1
H2
H3
H7
Length Overall A
0
0.060
…
80
…
2
PB
PB
…
…
15⁄8
1
0.073
64
72
…
2
P
P
…
…
111⁄16
2
0.086
56
…
…
2
PB
PB
…
…
2
0.086
…
64
…
2
…
P
…
…
3
0.099
48
…
…
2
…
PB
…
…
3
0.099
…
56
…
2
P
P
…
…
4
0.112
…
…
36
2
…
P
…
…
4
0.112
40
…
…
2
P
PB
…
…
4
0.112
…
48
…
2
P
PB
…
…
5
0.125
40
…
…
2
P
PB
…
…
5
0.125
…
44
…
2
…
P
…
…
13⁄4 13⁄4 113⁄16 113⁄16 17⁄8 17⁄8 17⁄8 115⁄16 115⁄16
6
0.138
32
…
…
2
P
PB
PB
PB
2
6
0.138
…
40
…
2
…
PB
…
…
2 21⁄8 21⁄8 23⁄8 23⁄8 23⁄8 23⁄8
8
0.164
32
…
…
2
P
PB
PB
PB
8
0.164
…
36
…
2
…
P
…
…
10
0.190
24
…
…
2
P
PB
PB
P
10
0.190
…
32
…
2
PB
PB
PB
P
12
0.216
24
…
…
2
…
…
PB
…
12
0.216
…
28
…
2
…
…
P
…
Length of Thread B
Length of Square C
Diameter of Shank D
Size of Square E
5⁄ 16 3⁄ 8 7⁄ 16 7⁄ 16 1⁄ 2 1⁄ 2 9⁄ 16 9⁄ 16 9⁄ 16 5⁄ 8 5⁄ 8 11⁄ 16 11⁄ 16 3⁄ 4 3⁄ 4 7⁄ 8 7⁄ 8 15⁄ 16 15⁄ 16
3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 9⁄ 32 9⁄ 32
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.168
0.131
0.168
0.131
0.194
0.152
0.194
0.152
0.220
0.165
0.220
0.165
High-Speed and Carbon Steel Taps with Cut Threads Threads per Inch Carbon Steel
HS Steel
Size
Basic Major Diameter
NC UNC
NF UNF
NC UNC
NF UNF
No. of Flutes
Length Overall, A
4
0.112
…
…
40
…
2
17⁄8
5
0.125
…
…
40
…
2
6
0.138
32
…
32
…
2
115⁄16 2
8
0.164
32
…
32
…
2
21⁄8
10
0.190
24
32
24
32
2
23⁄8
12
0.216
…
…
24
…
2
23⁄8
Length of Thread, B
Length of Square, C
Diameter of Shank, D
Size of Square, E
9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 7⁄ 8 15⁄ 16
3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 1⁄ 4 9⁄ 32
0.141
0.110
0.141
0.110
0.141
0.110
0.168
0.131
0.194
0.152
0.220
0.165
Tolerances for General Dimensions Tolerance
Tolerance
Size Range
Ground Thread
Cut Thread
Overall Length, A
0 to 12
Thread Length, B
0 to 12
Square Length, C
0 to 12
±1⁄32 ±3⁄64 ±1⁄32
±1⁄32 ±3⁄64 ±1⁄32
Element
Element
Size Range
Ground Thread
Cut Thread
Shank Diameter, D
0 to 12
−0.0015
−0.004
Size of Square, E
0 to 12
−0.004
−0.004
All dimensions are in inches. Chamfer designations are: P = plug and B = bottoming. Cut thread taps are standard with plug chamfer only. Style 1 ground thread taps have external centers on thread and shank ends (may be removed on thread end of bottoming taps). Style 1 cut thread taps have optional style centers on thread and shank ends. Standard thread limits for ground threads are given in Table 3 and for cut threads in Table 5. For eccentricity tolerances see Table 22.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 906
TAPS AND THREADING DIES Table 11. ANSI Standard Spiral Pointed Only and Regular and Fast Spiral-Fluted Taps — Machine Screw Sizes ASME B94.9-1999 STYLE 1
Pitch Dia. Limits & Chamfersa
Length of Thread, B
Length of Square, C
Diameter of Shank, D
Size of Square, E
Size
Basic Major Diameter
H2
H3
Length Overall, A
3b
0.099
48
…
2
PB
…
113⁄16
1⁄ 2
3⁄ 16
0.141
0.110
4
0.112
40
…
2
PB
…
17⁄8
9⁄ 16
3⁄ 16
0.141
0.110
5
0.125
40
…
2
PB
…
115⁄16
5⁄ 8
3⁄ 16
0.141
0.110
6
0.138
32
…
2
…
PB
2
11⁄ 16
3⁄ 16
0.141
0.110
8
0.164
32
…
2c, 3b
…
PB
21⁄8
3⁄ 4
1⁄ 4
0.168
0.131
10
0.190
24
32
2c, 3b
…
PB
23⁄8
7⁄ 8
1⁄ 4
0.194
0.152
12d
0.216
24
…
2c, 3b
…
PB
23⁄8
15⁄ 16
9⁄ 32
0.220
0.165
Threads per Inch NC UNC
NF UNF
No. of Flutes
a Bottom chamfer applies only to regular and fast spiral-fluted machine screw taps. b Applies only to fast spiral-fluted machine screw taps. c Does not apply to fast spiral-fluted machine screw taps. d Does not apply to regular spiral-fluted machine screw taps.
Tolerances for General Dimensions Element
Size Range
Tolerance
Element
Size Range
Tolerance
Overall Length, A
3 to 12
±1⁄32
Shank Diameter, D
3 to 12
−0.0015
Thread Length, B
3 to 12
±3⁄64
Square Length, C
3 to 12
±1⁄32
Size of Square, E
3 to 12
−0.004
All dimensions are given in inches. These standard taps are made of high-speed steel with ground threads. For standard thread limits see Table 3. For eccentricity tolerances see Table 22. Spiral Pointed Only Taps: These taps are standard with plug chamfer only. They are provided with a spiral point only; the balance of the threaded section is left unfluted. These Style 1 taps have external centers on thread and shank ends. Regular Spiral Fluted Taps: These taps have right-hand spiral flutes with a helix angle of from 25 to 35 degrees. Fast Spiral Fluted Taps: These taps have right-hand spiral flutes with a helix angle of from 45 to 60 degrees. Both regular and fast spiral-fluted Style 1 taps have external centers on thread and shank ends (may be removed on thread end of bottoming taps). Chamfer designations: P = plug and B = bottoming.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
907
Table 12a. ANSI Standard Ground Thread Straight Fluted Taps Fractional Sizes ASME B94.9-1999
Threads per Inch
Dia. of Tap 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 7⁄ 16 1⁄ 2 1⁄ 2 9⁄ 16 9⁄ 16 5⁄ 8 5⁄ 8 11⁄ a 16 3⁄ 4 3⁄ 4 7⁄ b 8 7⁄ 8 1b
1 1c 11⁄8 11⁄4 13⁄8 11⁄2
No. of NC NF Flute s UNC UNF 20 … 4 … 28 4 18 … 4 … 24 4 16 … 4 … 24 4 14 20 4 13 … 4 … 20 4 12 … 4 … 18 4 11 … 4 … 18 4 … … 4 10 … 4 … 16 4 9 … 4 … 14 4 8 … 4 … 12 4 … … 4 7 12 4 4 7 12d 4 6 12d 6 4 12d
Pitch Diameter Limits and Chamfers
H1 TPB PB PB PB PB PB … P PB … … … … … … P … … … … … … … … …
H2 TPB PB PB P PB PB … … … … P P P … P P … P … … … … … … …
H3 TPB TBP TPB TPB TPB TPB TPB TPB TPB TPB TPB TPB TPB TPB TPB TPB … … … … … … … … …
H4 … PB … PB … PB … … … … … … … … … … TPB TPB TPB TPB TPB TPB TPB TPB TPB
H5 PB … PB … PB … PB PB P P P PB PB … PB PB … … … … … … … … …
Length Overall, A 2 1⁄2 2 1⁄2 223⁄32 223⁄32 215⁄16 215⁄16 35⁄32 3 3⁄8 33⁄8 319⁄32 319⁄32 313⁄16 313⁄16 41⁄32 41⁄4 41⁄4 411⁄16 411⁄16 51⁄8 51⁄8 51⁄8 57⁄16 53⁄4 61⁄16 63⁄8
Dimensions Length Length ofThread, of Square, B C 5⁄ 1 16 5 1 ⁄16 3⁄ 1 1⁄8 8 3⁄ 11⁄8 8 7⁄ 11⁄4 16 1 7 1 ⁄4 ⁄16 13⁄ 17⁄16 32 7⁄ 1 21⁄32 16 7⁄ 121⁄32 16 1⁄ 1 21⁄32 2 1⁄ 121⁄32 2 13 9⁄ 1 ⁄16 16 13 9 1 ⁄16 ⁄16 5⁄ 113⁄16 8 11⁄ 2 16 11⁄ 2 16 3⁄ 27⁄32 4 3⁄ 27⁄32 4 13⁄ 21⁄2 16 13⁄ 21⁄2 16 13⁄ 21⁄2 16 7⁄ 29⁄16 8 1 29⁄16 3 11⁄16 3 11⁄8
Dia.of Shank, D 0.255 0.255 0.318 0.318 0.381 0.381 0.323 0.367 0.367 0.429 0.429 0.480 0.480 0.542 0.590 0.590 0.697 0.697 0.800 0.800 0.800 0.896 1.021 1.108 1.233
Sizeof Square, E 0.191 0.191 0.238 0.238 0.286 0.286 0.242 0.275 0.275 0.322 0.322 0.360 0.360 0.406 0.442 0.442 0.523 0.523 0.600 0.600 0.600 0.672 0.766 0.831 0.925
a This size has 11 or 16 threads per
inch NS-UNS. are also available with plug chamfer in H6 pitch diameter limits. threads per inch NS-UNS. d In these sizes NF-UNF thread taps have six flutes. b These sizes
c This size has 14
Element
Diameter Range
Length Overall, A Length of Thread, B Length of Square, C
1⁄ to 1 incl 4 11⁄8 to 11⁄2 incl 1⁄ to 1⁄ incl 4 2 9⁄ to 11⁄ incl 16 2 1⁄ to 1 incl 4 11⁄8 to 11⁄2 incl
Tolerances for General Dimensions Tolerance Element ±1⁄32 ±1⁄16 ±1⁄16 ±3⁄32 ±1⁄32 ±1⁄16
Diameter Range
Tolerance
Diameter of Shank, D
1⁄ to 5⁄ incl 4 8 11⁄ to 11⁄ incl 16 2
−0.0015 −0.002
Size of Square, E
1⁄ to 1⁄ incl 4 2 9⁄ to 1 incl 16 11⁄8 to 11⁄2 incl
−0.004 −0.006 −0.008
All dimensions are given in inches. These taps are standard in high-speed steel. Chamfer designations are: T = taper, P = plug, and B = bottoming. Style 2 taps, 3⁄8 inch and smaller, have external center on thread end (may be removed on bottoming taps) and external partial cone center on shank end with length of come approximately one-quarter of diameter of shank. Style 3 taps, larger than 3⁄8 inch, have internal center in thread and shank ends. For standared thread limits see Table 2. For eccentricity tolerances see Table 22.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 908
TAPS AND THREADING DIES Table 12b. ANSI Standard Cut Thread Straight Fluted Taps Fractional Sizes ASME B94.9-1999
Threads Per Inch
Dimensions
Carbon Steel Dia. of Tap 1⁄ 8 5⁄ 32 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 7⁄ 8
NC UNC
NF UNF
HS Steel NS UNS
NC UNC
NF UNF
No. of Flutes
…
…
40
…
…
3
115⁄16
…
32
…
…
4
2 1⁄8
…
…
24, 32
…
…
4
23⁄8
20
28
…
20
28
4
21⁄2
1
18
24
…
18
24
4
223⁄32
11⁄8
5⁄ 8 3⁄ 4 7⁄ 8
Length of Square, C 3⁄ 16 1⁄ 4 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 13⁄ 32 7⁄ 16 1⁄ 2 9⁄ 16 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8
Dia. of Shank, D
Size of Square, E
0.141
0.110
0.168
0.131
0.194
0.152
0.255
0.191
0.318
0.238
16
24
…
16
24
4
215⁄16
11⁄4
14
20
…
14
20
4
35⁄32
17⁄16 121⁄32 121⁄32 113⁄16
3
11⁄16
1.108
0.831
3
11⁄8
1.233
0.925
13
20
…
13
20
4
12
18
…
12
…
4
11
18
…
11
18
4
10
16
…
10
16
4
9
14
…
9
14
4
0.381
0.286
0.323
0.242
12ba
…
…
…
4
…
…
…
4
5a
12ba …
33⁄8 319⁄32 313⁄16 41⁄4 411⁄16 51⁄8 57⁄16 53⁄4 61⁄16 63⁄8
…
…
…
6
7
33⁄16
11⁄4
1.430
1.072
41⁄2 a
…
…
…
…
6
75⁄8
39⁄16
13⁄8
1.644
1.233
1
8
…
…
4
12
14a …
8
7
…
…
4
11⁄4
7
12b
…
…
…
4
13⁄8
6a 6
13⁄4 2
Length of Thread, B
…
11⁄8
11⁄2
Length Overall, A
2 27⁄32 21⁄2 29⁄16 29⁄16
1
0.367
0.275
0.429
0.322
0.480
0.360
0.590
0.442
0.697
0.523
0.800
0.600
0.896
0.672
1.021
0.766
a Standard in plug chamfer only. b In these sizes NF-UNF thread taps have six flutes.
Elements
Range
Length Overall, A
Length of Thread, B
Length of Square, C
1⁄ to 1 16 11⁄8 to 2 1⁄ to 3⁄ 16 16 1⁄ to 1⁄ 4 2 9⁄ to 11⁄ 16 2 15⁄8 to 2 1⁄ to 1 16 11⁄8 to 2
Tolerances for General Dimensions Tolerance Elements ±1⁄32 ±1⁄16 ±3⁄64 ±1⁄16 ±3⁄32 ±1⁄8 ±1⁄32 ±1⁄16
Range
Tolerance
Diameter of Shank, D
1⁄ to 3⁄ 16 16 1⁄ to 1 4 11⁄8 to 2
−0.004 −0.005 −0.007
Size of Square, E
1⁄ to 1⁄ 16 2 9⁄ to 1 16 1⁄ to 2 8
−0.004 −0.006 −0.008
All dimensions are given in inches. These taps are standard in carbon steel and high-speed steel. Except where indicated, these taps are standard with taper, plug, or bottoming chamfer. Cut thread taps, sizes 3⁄8 inch and smaller have optional style center on thread and shank ends; sizes larger than 3⁄8 inch have internal centers in thread and shank ends. For standard thread limits see Table 1. For eccentricity tolerances see Table 22.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
909
Table 13. ANSI Standard Straight Fluted (Optional Number of Flutes) and Spiral Pointed Taps—Fractional Sizes ASME B94.9-1999
Dia. of Tap
Threads per Inch NC, UNC NF, UNF
1⁄ 4 1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 7⁄ 16 7⁄ 16 1⁄ 2 1⁄ 2
20 20 … 18 18 … 16 … 14 … 13 …
1⁄ 4 1⁄ a 4 1⁄ 4 1⁄ a 4 5⁄ 16 5⁄ a 16 5⁄ 16 5⁄ a 16 3⁄ 8 3⁄ 8 7⁄ a 16 1⁄ 2 5⁄ a 8 3⁄ a 4
20 20 … … 18 18 … … 16 … 14 13 11 10
Pitch Diameter Length Length Limits and Chamfersab No. of Overall, of Thread, Flutes H1 H2 H3 H4 H5 A B Ground Thread High-Speed-Steel Straight Fluted Taps
Length of Square, C
Dia. of Shank, D
Size of Square, E
0.255 0.255 0.255 0.318 0.318 0.318 0.381 0.381 0.323 0.323 0.367 0.367
0.191 0.191 0.191 0.238 0.238 0.238 0.286 0.286 0.242 0.242 0.275 0.275
0.255 0.255 0.255 0.255 0.318 0.318 0.318 0.318 0.381 0.381 0.323 0.367 0.480 0.590
0.191 0.191 0.191 0.191 0.238 0.238 0.238 0.238 0.286 0.286 0.242 0.275 0.360 0.442
5⁄ 21⁄2 … 2 … … PB … … 1 16 5⁄ 21⁄2 … 3 P P PB … P 1 16 1 5⁄ 2 ⁄2 28 2, 3 … … PB … … 1 16 3⁄ 223⁄32 11⁄8 … 2 … … PB … … 8 3⁄ 223⁄32 11⁄8 … 3 … … PB … … 8 3⁄ 223⁄32 11⁄8 24 3 … … PB … … 8 7⁄ 215⁄16 11⁄4 … 3 … … PB … … 16 7⁄ 215⁄16 11⁄4 24 3 … … PB … … 16 13⁄ 35⁄32 17⁄16 … 3 … … P … … 32 13⁄ 35⁄32 17⁄16 20 3 … … P … … 32 7⁄ 33⁄8 121⁄32 … 3 … … PB … … 16 7⁄ 33⁄8 121⁄32 20 3 … … P … … 16 Ground Thread High-Speed-Steel and Cut Thread High-Speed-Steel Spiral Pointed Taps 5⁄ 21⁄2 … 2 P P PB … P 1 16 5⁄ 21⁄2 1 … 3 … … P … P 16 1 5⁄ 2 ⁄2 28 2 P P PB P … 1 16 5⁄ 21⁄2 1 28 3 … P … P … 16 3⁄ 223⁄32 11⁄8 … 2 P P PB … P 8 3⁄ 11⁄8 223⁄32 … 3 … … P … P 8 3⁄ 223⁄32 11⁄8 24 2 P P PB P … 8 3⁄ 11⁄8 223⁄32 24 3 … P P P … 8 7⁄ 215⁄16 11⁄4 … 3 P P P … P 16 7⁄ 215⁄16 11⁄4 24 3 P P P P … 16 13⁄ 17⁄16 35⁄32 20 3 … Pc P … P 32 7⁄ 121⁄32 33⁄8 3 P P P … P 20a 16 9⁄ 313⁄16 113⁄16 18 3 … … P … Pd 16 11⁄ 41⁄4 2 16 3 … … P … Pe 16
a Applies only to ground thread high-speed-steel taps. b Cut thread high-speed-steel taps are standard with plug chamfer only. c Applies only to 7⁄ -14 tap. 16 d Applies only to 5⁄ -11 tap. 8 e Applies ony to 3⁄ -10 tap. For eccentricity tolerances see Table 22. 4
Element Overall Length, A Thread Length, B Square Length, C
Diameter Range
Tolerances for General Dimensions Tolerance Ground Thread Cut Thread Element
1⁄ 4
to 3⁄4
±1⁄32
1⁄ 4 5⁄ 8 1⁄ 4
to 1⁄2 to 3⁄4 to 3⁄4
±1⁄16 ±1⁄32 ±1⁄32
±1⁄32 ±1⁄16
ShankDiameter,D Size of Square,E
Diameter Range 1⁄ 4 1⁄ 4 5⁄ 8
Tolerance Ground Thread CutThread
5⁄ 8
−0.0015 −0.0020
−0.005 …
to 1⁄2 to 3⁄4
−0.0040 −0.0060
−0.004 …
to 3⁄ 4
All dimensions are given in inches. P = plug and B = bottoming. Ground thread taps — Style 2, 3⁄8 inch and smaller, have external center on thread end (may be removed on bottoming taps) and external partial cone center on shank end, with length of cone approximately 1⁄4 of shank diameter. Ground thread taps—Style 3, larger than 3⁄8 inch, have internal center in thread and shank ends. Cut threadtaps, 3⁄8 inch and smaller have optional style center on thread and shank ends; sizes larger than 3⁄8 inch have internal centers in thread and shank ends. For standard thread limits see Tables 1 and 2.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 910
TAPS AND THREADING DIES Table 14. Other Types of ANSI Standard Taps ASME B94.9-1999
Threads per Inch
Dia. of Tap 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ e 16 1⁄ 2
Length Overall, A
Length of Thread, B
NC UNC
NF UNF
Number of Flutes
20
28a
2 b,c , 3 a
21⁄2
1
18
24a
223⁄32
11⁄8
16
24a
2d, 3a 3
14
20
3
13
20a
3
215⁄16 35⁄32 33⁄8
11⁄4 17⁄16 121⁄32
Dia. of Shank, D
Length of Square, C 5⁄ 16 3⁄ 8 7⁄ 16 13⁄ 32 7⁄ 16
Size of Square, E
0.255
0.191
0.318
0.238
0.381
0.286
0.323
0.242
0.367
0.275
a Does not apply to spiral pointed only taps. b Does not apply to spiral fluted taps with 28 threads per inch. c Does not apply to fast spiral fluted taps. d Applies only to spiral pointed only taps. e Applies only to fast spiral fluted taps.
Tolerances for General Dimensions Diameter Range
Element Overall Length, A Thread Length, B Square Length, C
1⁄ 4 1⁄ 4 1⁄ 4
to to to
1⁄ 2 1⁄ 2 1⁄ 2
Diameter Range
Tolerance
Element
±1⁄32 ±1⁄16 ±1⁄32
Shank Diameter, D
1⁄ 4
to 1⁄2
Tolerance −0.0015
Size of Square, E
1⁄ 4
to 1⁄2
−0.004
All dimensions are given in inches. These standard taps are made of high-speed steel with ground threads. For standard thread limits see Table 2. Spiral Pointed Only Taps: These taps are standard with plulg chamfer only in H3 limit. They are provided with spiral point only. The balance of the threaded section is left unfluted. Spiral Fluted Taps: These taps are standard with plug or bottoming chamfer in H3 limit and have right-hand spiral flutes with a helix angle of from 25 to 35 degrees. Fast Spiral Fluted Taps: These taps are standard with plug or bottoming chamfer in H3 limit and have right-hand spiral flutes with a helix angle of from 45 to 60 degrees. Style 2 taps, 3⁄8 inch and smaller, have external center on thread end (may be removed on bottoming taps) and external partial cone center on shank end with cone length approximately 1⁄4 shank diameter. Style 3 taps larger than 3⁄8 inch have internal center in thread and shank ends. For standard thread limits see Table 2. For eccentricity tolerances see Table 22.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
911
Table 15. ANSI Standard Pulley Taps ASME B94.9-1999
Threads per Dia. Inch Number of NC of Tap UNC Flutes
Length of Size Shank Length Length Length Dia. of Close of of of of Thread, Square, Shank, Tolerance, Square, Neck, Eb Ta B C D Kc
Length Overall, A
1⁄ 4
20
4
6, 8
1.00
0.31
0.2550
1.50
0.191
0.38
5⁄ 16
18
4
6, 8
1.13
0.38
0.3180
1.56
0.238
0.38
0.44
0.3810
1.63
0.286
0.38
3⁄ 8
16
4
6, 8, 10
1.25
7⁄ 16
14
4
6, 8
1.44
0.50
0.4440
1.69
0.333
0.44
1⁄ 2
13
4
6, 8, 10, 12
1.66
0.56
0.5070
1.69
0.380
0.50
5⁄ 8
11
4
6,8,10,12
1.81
0.69
0.6330
2.00
0.475
0.63
3⁄ 4
10
4
10, 12
2.00
0.75
0.7590
2.25
0.569
0.75
a T is minimum length of shank which is held to eccentricity tolerances. b Size of square is equal to 0.75D to the nearest 0.001 inch. c K neck optional with manufacturer.
Tolerances for General Dimensions Diameter Range
Element
Diameter Range
Tolerance
Element Shank Diameter, D
1⁄ 4
to 3⁄4
Size of Square, E
1⁄ 4 5⁄ 8
1⁄ 2 3⁄ 4
Overall Length, A
1⁄ 4
to 3⁄4
±0.06
Thread Length, B
1⁄ 4
to 3⁄4
±0.06
Square Length, C
1⁄ 4
to 3⁄4
±0.03
to to
Tolerance −0.0050 −0.004 −0.006
All dimensions are given in inches. These ground thread high-speed steel taps are standard with plug chamfer in H3 limit only. All taps have an internal center in thread end. For standard thread limits see Table 2. For eccentricity tolerances see Table 22.
Table 16. ANSI Standard Ground Thread Spark Plug Taps Metric Sizes ASME B94.9-1999 Tap Diameter, mm 14 18
Pitch, mm
Number of Flutes
1.25
4 4
1.50
Overall Length, In. A
Thread Length, In. B
Square Length, In. C
Shank Dia., In. D
Square Size, In. E
319⁄32
121⁄32
1⁄ 2
0.429
0.322
41⁄32
113⁄16
5⁄ 8
0.542
0.406
These are high-speed steel Style 3 taps and have internal center in thread and shank ends. They are standard with plug chamfer only, right-hand threads with 60-degree form of thread. Tolerances: Overall length, ± 1⁄32 inch; thread length, ± 3⁄32 inch; square length, ± 1⁄32 inch; shank diameter, 14 mm, −0.0015 inch, 18 mm, −0.0020 inch; and size of square, −0.0040 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 912
TAPS AND THREADING DIES Table 17a. ANSI Standard Ground Thread Straight Fluted Taps M Profile — Metric Sizes ASME B94.9-1999
D3
Pitch Diameter Limits and Chamfers D4 D5 D6 D7 D8
D9
Length Overall A
PB
…
…
…
…
…
…
15⁄8
3
PB
…
…
…
…
…
…
13⁄4
0.45
3
PB
…
…
…
…
…
…
113⁄16
3
0.5
3
PB
…
…
…
…
…
…
3.5
0.6
3
…
PB
…
…
…
…
…
115⁄16 2
Nom. Dia. mm.
Pitch mm
No. of Flutes
1.6
0.35
2
2
0.4
2.5
4
0.7
4
…
PB
…
…
…
…
…
4.5
0.75
4
…
PB
…
…
…
…
…
5
0.8
4
…
PB
…
…
…
…
…
6
1
4
…
…
PB
…
…
…
…
7
1
4
…
…
PB
…
…
…
…
8
1.25
4
…
…
PB
…
…
…
…
10
1.5
4
…
…
…
PB
…
…
…
12
1.75
4
…
…
…
PB
…
…
…
4
…
…
…
…
PB
…
…
14
2
16
2
…
PB
20
2.5
4
…
…
…
…
PB
…
…
24
3
4
…
…
…
…
…
PB
…
3.5
4
…
…
…
…
…
…
PB
4
4
…
…
…
…
…
…
PB
30 36
Element Overall Length, A
Thread Length, B
Square Length, C
4
…
…
…
Nom. Dia. Range, mm M1.6 to M24, incl. M30 and M36 M1.6 to M5, incl. M6 to M12 incl. M14 to M36 M1.6 to M24, incl. M30 and M36
…
…
21⁄8 23⁄8 23⁄8 21⁄2 223⁄32 223⁄32 215⁄16 33⁄8 319⁄32 313⁄16 415⁄32 429⁄32 57⁄16 61⁄16
Tolerances Toler., Inch Element ±1⁄32 ±1⁄16 ±3⁄64 ±1⁄16 ±3⁄32 ±1⁄32 ±1⁄16
Length of Thread B 5⁄ 16 7⁄ 16 1⁄ 2 5⁄ 8 11⁄ 16 3⁄ 4 7⁄ 8 7⁄ 8
1 11⁄8 11⁄8 11⁄4 121⁄32 121⁄32 113⁄16 2 27⁄32 29⁄16 3
Length of Square C 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 1⁄ 4 1⁄ 4 5⁄ 16 3⁄ 8 3⁄ 8 7⁄ 16 7⁄ 16 1⁄ 2 9⁄ 16 11⁄ 16 3⁄ 4
Dia. of Square D
Size of Square E
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.141
0.110
0.168
0.131
0.194
0.152
0.194
0.152
0.255
0.191
0.318
0.238
0.318
0.238
0.381
0.286
0.367
0.275
0.429
0.322
0.480
0.360
0.652
0.489
0.760
0.570
1
1.021
0.766
11⁄8
1.233
0.925
Nom. Dia. Range, mm
Toler., Inch
Shank Diameter, D
M1.6 to M14, incl. M16 to M36
−0.0015 −0.002
Size of Square, E
M1.6 to M12, incl. M14 to M24, incl. M30 and M36
−0.004 −0.006 −0.008
All dimensions are in inches except where otherwise stated. Chamfer Designation: P — Plug, B — Bottoming. These taps are high-speed steel. Style 1 taps, sizes M1.6 through M5, have external center on thread and shank ends (may be removed on thread end of bottoming taps). Style 2 taps, sizes M6, M7, M8, and M10, have external center on thread end (may be removed on bottoming taps) and external partial cone center on shank end with length of cone approximately 1⁄4 of diameter of shank. Style 3 taps, sizes larger than M10 have external center on thread and shank ends. For standard thread limits see Tables 4a and 4b. For eccentricity tolerances of tap elements see Table 22.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
913
Table 17b. ANSI Standard Spiral Pointed Ground Thread Taps M Profile — Metric Sizes ASME B94.9-1999
Nom. Dia. mm.
Pitch mm
No. of Flutes
Length Overall
Length of Thread
Length of Square
Dia. of Square
D3
Pitch Diameter Limits and Styles D4
D5
D6
D7
A
B
C
D
Size of Square E
1.6
0.35
2
P
…
…
…
…
15⁄8
5⁄ 16
3⁄ 16
0.141
0.110
2
0.4
2
P
…
…
…
…
13⁄4
7⁄ 16
3⁄ 16
0.141
0.110
2.5
0.45
2
P
…
…
…
…
113⁄16
1⁄ 2
3⁄ 16
0.141
0.110
3
0.5
2
P
…
…
…
…
115⁄16
5⁄ 8
3⁄ 16
0.141
0.110
3.5
0.6
2
…
P
…
…
…
2
11⁄ 16
3⁄ 16
0.141
0.110
4
0.7
2
…
P
…
…
…
21⁄8
3⁄ 4
1⁄ 4
0.168
0.131
5
0.8
2
…
P
…
…
…
23⁄8
7⁄ 8
1⁄ 4
0.194
0.152
6
1
2
…
…
P
…
…
21⁄2
1
5⁄ 16
0.255
0.191
8
1.25
2
…
…
P
…
…
223⁄32
11⁄8
3⁄ 8
0.318
0.238
10
1.5
3
…
…
…
P
…
215⁄16
11⁄4
7⁄ 16
0.381
0.286
12
1.75
3
…
…
…
P
…
33⁄8
121⁄32
7⁄ 16
0.367
0.275
14
2
3
…
…
…
…
P
319⁄32
121⁄32
1⁄ 2
0.429
0.322
16
2
3
…
…
…
…
P
313⁄16
113⁄16
9⁄ 16
0.480
0.360
20
2.5
3
…
…
…
…
P
415⁄32
2
11⁄ 16
0.652
0.489
Tolerances Element
Nom. Dia. Range, mm
Toler., Inch
Overall Length, A
M1.6 to M20, incl.
±1⁄32
M1.6 to M5, incl.
±3⁄64
Thread Length, B
M16 to M12 incl.
±1⁄16
M14 to M20
±3⁄32
M1.6 to M20
±1⁄32
Square Length, C
Nom. Dia. Range, mm Element
Toler., Inch
Shank Diameter, D
M1.6 to M14, incl. M16 to M20
−0.0015 −0.002
Size of Square, E
M1.6 to M12, incl. M14 to M20, incl.
−0.004 −0.006
All dimensions are in inches except where otherwise stated. Chamfer Designation: P — Plug. These taps are high-speed steel. Style 1 taps, sizes M1.6 through M5, have external center on thread and shank ends. Style 2 taps, sizes M6, M8 and M10, have external center on thread end and external partial cone center on shank end with length of cone approximately 1⁄4 of diameter of shank. Style 3 taps, sizes larger than M10 have external center on thread and shank ends. For standards thread limits see Table 4a and 4b. For eccentricity tolerances of tap elements see Table 22.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 914
TAPS AND THREADING DIES Table 18. ANSI Standard Taper and Straight Pipe Taps ASME B94.9-1999
Nominal Size
Threads per Inch Carbon High-Speed Steel Steel
1⁄ a 16 1⁄ 8 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4
… 27 27 18 18 14 14
27 27 27 18 18 14 14
1
111⁄2 111⁄2 111⁄2 111⁄2 8 8
111⁄2 111⁄2 111⁄2 111⁄2 … …
… … … … … … …
27 27 18 18 14 14
11⁄4 11⁄2 2 21⁄2 c 3c 1⁄ a 8 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4
1
Number of Flutes Regular 4 4 4 4 4 4 5 5 5 7 7 8 8
Length Interrupted Overall, A Taper Pipe Taps … 21⁄8 5 21⁄8 5 21⁄8 5 27⁄16 5 29⁄16 5 31⁄8 5 31⁄4 5 33⁄4 5 4
4 4 4 4 4 5 5
111⁄2
7 ba 7ba … …
41⁄4 41⁄2 51⁄2 6
Straight Pipe Taps … 21⁄8 … 21⁄8 … 27⁄16 … 29⁄16 … 31⁄8 … 31⁄4 … 33⁄4
Length of Thread, B
Dimensions Length of Diameter Square, C of Shank, D
11⁄ 16 3⁄ 4 3⁄ 4 11⁄16 11⁄16 13⁄8 13⁄8 13⁄4 13⁄4 13⁄4 13⁄4 29⁄16 25⁄8
3⁄ 8 3⁄ 8 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 11⁄ 16 13⁄ 16 15⁄ 16
3⁄ 4 3⁄ 4 11⁄16 11⁄16 13⁄8 13⁄8 13⁄4
Size of Square, E
11⁄8 11⁄4 13⁄8
0.3125 0.3125 0.4375 0.5625 0.7000 0.6875 0.9063 1.1250 1.3125 1.5000 1.8750 2.2500 2.6250
0.234 0.234 0.328 0.421 0.531 0.515 0.679 0.843 0.984 1.125 1.406 1.687 1.968
3⁄ 8 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 11⁄ 16 13⁄ 16
0.3125 0.4375 0.5625 0.7000 0.6875 0.9063 1.1250
0.234 0.328 0.421 0.531 0.515 0.679 0.843
1
a Ground thread taps only. b Standard in NPT form of thread only. c Cut thread taps only.
Element Overall Length, A
Diameter Range 1⁄ 16
to 1 to 3
3⁄ 4
1⁄ 16
Thread Length, B
Square Length, C
to 3⁄4 1 to 11⁄4 1 1 ⁄2 to 3
1⁄ to 3⁄ 16 4 1 to 3
Tolerances for General Dimensions Tolerance Cut Thread Ground Thread Element ±1⁄32 ±1⁄16 ±1⁄16 ±3⁄32 ±1⁄8 ±1⁄32 ±1⁄16
±1⁄32 ± 1⁄16 ±1⁄16 ±3⁄32 ±1⁄8 ±1⁄32 ±1⁄16
Shank Diameter, D
Size of Square, E
Diameter Range 1⁄ to ⁄ 16 8 1⁄ to 1⁄ 8 2 1⁄ to 1 4 3⁄ to 3 4 11⁄4 to 2 1⁄ to 1⁄ 16 8 1⁄ to 3⁄ 4 4
1 to 3
Tolerance Cut Thread Ground Thread … −0.0015 −0.007 … … −0.002 −0.009 … −0.004 −0.006 −0.008
… −0.003 −0.004 −0.006 −0.008
All dimensions are given in inches. These taps have an internal center in the thread end. Taper Pipe Threads: The 1⁄8 -inch pipe tap is furnished with large size shank unless the small shank is specified. These taps have 2 to 31⁄2 threads chamfer. The first few threads on interrupted thread pipe taps are left full. The following styles and sizes are standard: 1⁄16 to 2 inches regular ground thread, NPT, NPTF, and ANPT: 1⁄8 to 2 inches interrupted ground thread, NPT, NPTF and ANPT: 1⁄8 to 3 inches carbon steel regular cut thread, NPT; 1⁄8 to 2 inches high-speed steel, regular cut thread, NPT; 1⁄8 to 11⁄4 inches high-speed steel interrupted cut thread, NPT. For standard thread limits see Tables 6a and 6b. Straight Pipe Threads: The 1⁄8 -inch pipe tap is furnished with large size shank unless the small size is specified. These taps are standard with plug chamfer only. The following styles and sizes are standard: ground threads — 1⁄8 to 1 inch, NPSC and NPSM; 1⁄8 to 3⁄4 inch, NPSF; cut threads — 1⁄8 to 1 inch, NPSC and NPSM. For standard thread limits see Tables 7a, 7b, and 7c. For eccentricity tolerances see Table 22.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
915
Table 19. Taps Recommended for Classes 2B and 3B Unified Screw Threads Numbered and Fractional Sizes ASME B94.9-1999 Size
Threads per Inch NC NF UNC UNF
Recommended Tap For Class of Thread Class 2Ba
Class 3B
Pitch Diameter Limits For Class of Thread Min, All Max Max Classes (Basic) Class 2B Class 3B
Machine Screw Numbered Size Taps 0 1 1 2 2 3 3 4 4 5 5 6 6 8 8 10 10 12 12
… 64 … 56 … 48 … 40 … 40 … 32 … 32 … 24 … 24 …
80 … 72 … 64 … 56 … 48 … 44 … 40 … 36 … 32 … 28
G H2 G H2 G H2 G H2 G H2 G H2 G H2 G H2 G H2 G H2 G H2 G H3 G H2 G H3 G H2 G H3 G H3 G H3 G H3
1⁄ 4 1⁄ 4 5⁄ 16 5⁄ 16 3⁄ 8 3⁄ 8 7⁄ 16 7⁄ 16 1⁄ 2 1⁄ 2 9⁄ 16 9⁄ 16 5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 7⁄ 8 7⁄ 8
20 … 18 … 16 … 14 … 13 … 12 … 11 … 10 … 9 … 8 …
… 28 … 24 … 24 … 20 … 20 … 18 … 18 … 16 … 14 … 12
G H5 G H4 G H5 G H4 G H5 G H4 G H5 G H5 G H5 G H5 G H5 G H5 G H5 G H5 G H5 G H5
1 1 1 11⁄8 11⁄8 11⁄4 11⁄4 13⁄8 13⁄8 11⁄2 11⁄2
14NS 7 … 7 … 6 … 6 …
… 12 … 12 … 12 … 12
G H6b G H6b G H6b G H6b G H6b G H8b G H6b G H8b G H6b G H8b G H6b G H8b G H6b
G H1 G H1 G H1 G H1 G H1 G H1 G H1 G H2 G H1 G H2 G H1 G H2 G H2 G H2 G H2 G H3 G H2 G H3 G H3 Fractional Size Taps G H3 G H3 G H3 G H3 G H3 G H3 G H3 G H3 G H3 G H3 G H3 G H3 G H3 G H3 G H5 G H3 G H4 G H4 G H4 G H4 G H4 G H4 G H4 G H4 G H4 G H4 G H4 G H4 G H4
0.0519 0.0629 0.0640 0.0744 0.0759 0.0855 0.0874 0.0958 0.0985 0.1088 0.1102 0.1177 0.1218 0.1437 0.1460 0.1629 0.1697 0.1889 0.1928
0.0542 0.0655 0.0665 0.0772 0.0786 0.0885 0.0902 0.0991 0.1016 0.1121 0.1134 0.1214 0.1252 0.1475 0.1496 0.1672 0.1736 0.1933 0.1970
0.0536 0.0648 0.0659 0.0765 0.0779 0.0877 0.0895 0.0982 0.1008 0.1113 0.1126 0.1204 0.1243 0.1465 0.1487 0.1661 0.1726 0.1922 0.1959
0.2175 0.2268 0.2764 0.2854 0.3344 0.3479 0.3911 0.4050 0.4500 0.4675 0.5084 0.5264 0.5660 0.5889 0.6850 0.7094 0.8028 0.8286 0.9188 0.9459 0.9536 1.0322 1.0709 1.1572 1.1959 1.2667 1.3209 1.3917 1.4459
0.2224 0.2311 0.2817 0.2902 0.3401 0.3528 0.3972 0.4104 0.4565 0.4731 0.5152 0.5323 0.5732 0.5949 0.6927 0.7159 0.8110 0.8356 0.9276 0.9535 0.9609 1.0416 1.0787 1.1668 1.2039 1.2771 1.3291 1.4022 1.4542
0.2211 0.2300 0.2803 0.2890 0.3387 0.3516 0.3957 0.4091 0.4548 0.4717 0.5135 0.5308 0.5714 0.5934 0.6907 0.7143 0.8089 0.8339 0.9254 0.9516 0.9590 1.0393 1.0768 1.1644 1.2019 1.2745 1.3270 1.3996 1.4522
a Cut thread taps in all fractional sizes and in numbered sizes 3 to 12 NC and NF may be used under normal conditions and in average materials to produce tapped holes in this classification. b Standard G H4 taps are also suitable for this class of thread.
All dimensions are given in inches. The above recommended taps normally produce the class of thread indicated in average materials when used with reasonable care. However, if the tap specified does not give a satisfactory gage fit in the work, a choice of some other limit tap will be necessary.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 916
TAPS AND THREADING DIES
Standard System of Tap Marking.—Ground thread taps, inch screw threads, are marked with the nominal size, number of threads per inch, the proper symbol to identify the thread form, “HS” for high-speed steel, “G” for ground thread, and designators for tap pitch diameter and special features, such as left-hand and multi-start threads. Cut thread taps, inch screw threads, are marked with the nominal size, number of threads per inch, and the proper symbol to identify the thread form. High-speed steel taps are marked “HS,” but carbon steel taps need not be marked. Ground thread taps made with metric screw threads, M profile, are marked with “M,” followed by the nominal size and pitch in millimeters, separated by “x.” Marking also includes “HS” for high-speed steel, “G” for ground thread, designators for tap pitch diameter and special features, such as left-hand and multi-start threads. Thread symbol designators are listed in the accompanying table. Tap pitch diameter designators, systems of limits, special features, and examples for ground threads are given in the following section. Standard System Tap Thread Limits and Identification for Unified Inch Screw Threads, Ground Thread.—H or L Limits: For Unified inch screw threads, when the maximum tap pitch diameter is over basic pitch diameter by an even multiple of 0.0005 in. or the minimum tap pitch diameter limit is under basic pitch diameter by an even multiple of 0.0005 in., the taps are marked “H” or “L,” respectively, followed by a limit number, determined as follows: H limit number =Amount maximum tap PD limit is over basic PD divided by 0.0005 L limit number =Amount minimum tap PD limit is under basic PD divided by 0.0005 Table 20. Thread Series Designations Standard Tap Marking
Product Thread Designation
M M
M MJ
NC NC NPS NPSF NPSH
NC5IF NC5INF NPSC NPSF NPSH
NPSI NPSL NPS NPT NPTF NPTR
NPSI NPSL NPSM NPT NPTF NPTR
N NC NF NEF N NC NF NEF N NC NF NEF NS
UN UNC UNF UNEF UNJ UNJC UNJF UNJEF UNR UNRC UNRF UNREF UNS
Third Series Metric Screw Threads—M Profile, with basic ISO 68 profile Metric Screw Threads—M Profile, with rounded root of radius 0.15011P to 0.18042P Class 5 interference-fit thread Entire ferrous material range Entire nonferrous material range American Standard straight pipe threads in pipe couplings Dry seal American Standard fuel internal straight pipe threads American Standard straight hose coupling threads for joining to American Standard taper pipe threads Dryseal American Standard intermediate internal straight pipe threads American Standard straight pipe threads for loose-fitting mechanical joints with locknuts American Standard straight pipe threads for free-fitting mechanical joints for fixtures American Standard taper pipe threads for general use Dryseal American Standard taper pipe threads American Standard taper pipe threads for railing joints Unified Inch Screw Thread Constant-pitch series Coarse pitch series Fine pitch series Extra-fine pitch series Constant-pitch series, with rounded root of radius 0.15011P to 0.18042P (ext. thd. only) Coarse pitch series, with rounded root of radius 0.15011P to 0.18042 P (ext. thd. only) Fine pitch series, with rounded root of radius 0.15011P to 0.18042P (ext. thd. only) Extra-fine pitch series, with rounded root of radius 0.15011P to 0.18042P (ext. thd. only) Constant-pitch series, with rounded root of radius not less than 0.108P (ext. thd. only) Coarse thread series, with rounded root of radius not less than 0.108P (ext. thd. only) Fine pitch series, with rounded root of radius not less than 0.108P (ext. thd. only) Extra-fine pitch series, with rounded root of radius not less than 0.108P (ext. thd. only) Special diameter pitch, or length of engagement
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
917
The PD limits for various H limit numbers are given in Table 2. The PD limits for L limit numbers are determined as follows. The minimum tap PD equals the basic PD minus the number of half-thousandths (0.0005 in.) represented by the limit number. The maximum tap PD equals the minimum PD plus the PD tolerance given in Table 21. Table 21. PD Tolerance for Unified Inch Screw Threads Ground Thread ASME B94.9-1999 Threads per Inch
To 1 in., incl.
Over 1 in. to 11⁄2 in., incl.
Over 11⁄2 to 21⁄2 in., incl.
Over 2 1⁄2 in.
80-28 24-18 16-18 7-6 51⁄2 -4
0.0005 0.0005 0.0005 0.0010 0.0010
0.0010 0.0010 0.0010 0.0010 0.0015
0.0010 0.0015 0.0015 0.0020 0.0020
0.0015 0.0015 0.0020 0.0025 0.0025
Example: 3⁄8 -16 NC HS H1 Max. tap PD = 0.3349 Min. tap PD = 0.3344 Example: 3⁄8 -16 NC HS G L2 Min. tap PD = Basic PD − 0.0010 in. = 0.3344 − 0.0010 = 0.3334 Max. tap PD = Min. Tap PD + 0.0005 = 0.3334 + 0.0005 = 0.3339 Oversize or Undersize: When the maximum tap PD over basic PD or the minimum tap PD under basic PD is not an even multiple of 0.0005, the tap PD is usually designated as an amount oversize or undersize. The amount oversize is added to the basic PD to establish the minimum tap PD. The amount undersize is subtracted from the basic PD to establish the minimum tap PD. The PD tolerance in Table 21 is added to the minimum tap PD to establish the maximum tap PD for both. Example : 7⁄16 -14 NC plus 0.0017 HS G Min. tap PD = Basic PD + 0.0017 in. Max. tap PD = Min. tap PD + 0.0005 in. Whenever possible for oversize or other special tap PD requirements, the maximum and minimum tap PD requirements should be specified. Special Tap Pitch Diameter: Taps not made to H or L limit numbers, to Table 22, or to the formula for oversize or undersize taps, may be marked with the letter “S” enclosed by a circle or by some other special identifier. Example: 1⁄2 -16 NC HS G . Table 22. ANSI Standard Runout and Location Tolerance of Tap Elements ASME B94.9-1999 Range Sizes are Inclusive Hand, Mch. Screw Metric Pipe
Element Square (at central point) Shank Major Diameter Pitch Diameter (at first full thread) Chamferb
#0–1⁄2 ″
M1.6–M12
17⁄ –4″ 32 #0–5⁄16 ″ 11⁄ –4″ 32 #0–5⁄16 ″ 11⁄ –4″ 32 #0–5⁄16 ″ 11⁄ –4″ 32 #0–1⁄2 ″ 17⁄ –4″ 32
M14–M100 M1.6–M8 M10–M100 M1.6–M8 M10–M100 M1.6–M8 M10–M100 M1.6–M12 M14–M100
1⁄ –1⁄ ″ 16 8 1⁄ –4″ 4 1⁄ ″ 16 1⁄ –4″ 8 1⁄ ″ 16 1⁄ –4″ 8 1⁄ ″ 16 1⁄ –4″ 8 1⁄ –1⁄ ″ 16 8 1⁄ –4″ 4
Cut Thread
Ground Thread Location, inch
Eccentricity
tiva
Eccentricity
tiva
…
…
…
…
0.0060
…
…
…
…
0.0030
0.0060
0.0005
0.0010
0.0080 …
0.0040
0.0080
0.0008
0.0016
…
0.0025
0.0050
0.0005
0.0010
…
0.0040
0.0080
0.0008
0.0016
…
0.0025
0.0050
0.0005
0.0010
…
0.0040
0.0080
0.0008
0.0016
…
0.0020
0.0040
0.0010
0.0020
…
0.0030
0.0060
0.0015
0.0030
…
a tiv = total indicator variation. This data no longer included in Standard, but for reference figures are given for both eccentricity and total indicator variation to avoid misunderstanding. b Chamfer should preferably be inspected by light projection to avoid errors due to indicator contact points dropping into the thread groove. All dimensions are given in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 918
TAPS AND THREADING DIES
Left-Hand Taps: Taps with left-hand threads are marked “LEFT HAND” or “LH.” Example:3⁄8 -16 NC LH HS G H3. Multiple-Start Threads: Taps with multiple-start threads are marked with the lead designated as a fraction, also “Double,” “Triple,” etc. The Unified Screw Thread form symbol is always designated as “NS” for multiple-start threads. Example:3⁄8 -16 NS Double 1⁄8 Lead HS G H5. Standard System of Ground Thread Tap Limits and Identification for Metric Screw Threads, M Profile.—All calculations for metric taps use millimeter values. When U.S. customary values are needed, they are translated from the three-place millimeter tap diameters only after the calculations are completed. Table 23. PD Tolerance for Metric Screw Threads M Profile—Ground Threads ASME B94.9-1999 M1.6 to M6.3, inclusive.
Over M6.3 to M25, inclusive
Over M25 to M90, inclusive
Over M90
0.3
0.015
0.015
0.020
0.020
0.35
0.015
0.015
0.020
0.020
0.4
0.015
0.015
0.020
0.025
Pitch, P (mm)
0.45
0.015
0.020
0.020
0.025
0.5
0.015
0.020
0.025
0.025
0.6
0.020
0.020
0.025
0.025
0.7
0.020
0.020
0.025
0.025
0.75
0.020
0.025
0.025
0.031
0.8
0.020
0.025
0.025
0.031
0.9
0.020
0.025
0.025
0.031
1
0.025
0.025
0.031
0.031
1.25
0.025
0.031
0.031
0.041
1.5
0.025
0.031
0.031
0.041
1.75
…
0.031
0.041
0.041
2
…
0.041
0.041
0.041
2.5
…
0.041
0.041
0.052
3
…
0.041
0.052
0.052
3.5
…
0.041
0.052
0.052
4
…
0.052
0.052
0.064
4.5
…
0.052
0.052
0.064
5
…
…
0.064
0.064
5.5
…
…
0.064
0.064
6
…
…
0.064
0.064
D or DU Limits: When the maximum tap pitch diameter is over basic pitch diameter by an even multiple of 0.013 mm (0.000512 in. reference), or the minimum tap pitch diameter limit is under basic pitch diameter by an even multiple of 0.013 mm, the taps are marked with the letters “D” or “DU,” respectively, followed by a limit number. The limit number is determined as follows: D limit number = Amount maximum tap PD limit is over basic PD divided by 0.013 DU limit number = Amount minimum tap PD limit is under basic PD divided by 0.013
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
919
The PD limits for various D limit numbers are given in Table 4b. The PD limits for DU limit numbers are determined as follows. The minimum tap PD equals the basic PD minus the number of millimeters represented by the limit number (multiples of 0.013 mm). The maximum tap PD equals the minimum tap PD plus the PD tolerance given in Table 23. Example:M1.6 × 0.35 HS G D3 Max. tap PD = 1.412 Min. tap PD = 1.397 M6 × 1 HS G DU4 Min. tap PD = Basic PD − 0.052 mm = 5.350 − 0.052 = 5.298 Max. tap PD = Min. tap PD + 0.025 mm = 5.323 Metric oversize or undersize taps, taps with special pitch diameters, and left-hand taps follow the marking system given for inch taps. Examples:M12 × 1.75 + 0.044 HS G M10 × 1.5 HS G M10 × 1.5 LH HS G D6 Multiple-Start Threads: Metric taps with multiple-start threads are marked with the lead designated in millimeters preceded by the letter “L,” the pitch in millimeters preceded by the letter “P,” and the words “(2 starts),” “(3 starts),” etc. Examples:M16 × L4-P2 (2 starts) HS G D8 M14 × L6-P2 (3 starts) HS G D7 Acme and Square-Threaded Taps These taps are usually made in sets, three taps in a set being the most common. For very fine pitches, two taps in a set will be found sufficient, whereas as many as five taps in a set are used for coarse pitches. The table on the next page gives dimensions for proportioning both Acme and square-threaded taps when made in sets. In cutting the threads of squarethreaded taps, one leading tap maker uses the following rules: The width of the groove between two threads is made equal to one-half the pitch of the thread, less 0.004 inch, making the width of the thread itself equal to one-half of the pitch, plus 0.004 inch. The depth of the thread is made equal to 0.45 times the pitch, plus 0.0025 inch. This latter rule produces a thread that for all the ordinarily used pitches for square-threaded taps has a depth less than the generally accepted standard depth, this latter depth being equal to one-half the pitch. The object of this shallow thread is to ensure that if the hole to be threaded by the tap is not bored out so as to provide clearance at the bottom of the thread, the tap will cut its own clearance. The hole should, however, always be drilled out large enough so that the cutting of the clearance is not required of the tap. The table, Dimensions of Acme Threads Taps in Sets of Three Taps, may also be used for the length dimensions for Acme taps. The dimensions in this table apply to single-threaded taps. For multiple-threaded taps or taps with very coarse pitch, relative to the diameter, the length of the chamfered part of the thread may be increased. Square-threaded taps are made to the same table as Acme taps, with the exception of the figures in column K, which for square-threaded taps should be equal to the nominal diameter of the tap, no oversize allowance being customary in these taps. The first tap in a set of Acme taps (not square-threaded taps) should be turned to a taper at the bottom of the thread for a distance of about one-quarter of the length of the threaded part. The taper should be so selected that the root diameter is about 1⁄32 inch smaller at the point than the proper root diameter of the tap. The first tap should preferably be provided with a short pilot at the point. For very coarse pitches, the first tap may be provided with spiral flutes at right angles to the angle of the thread. Acme and square-threaded taps should be relieved or backed off on the top of the thread of the chamfered portion on all the taps in the set. When the taps are used as machine taps, rather than as hand taps, they should be relieved in the angle of the thread, as well as on the top,
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 920
TAPS AND THREADING DIES Table 24. Dimensions of Acme Threads Taps in Sets of Three Taps A C
B
1ST TAP IN SET
D
E
ROOT DIA. – 0.010"
2ND TAP IN SET
F
G
ROOT DIA. – 0.010" K FINISHING TAP Nominal Dia.
H
A
B
C
G
H
I
K
1⁄ 2
41⁄4
17⁄8
23⁄8
1⁄ 2
17⁄8
5⁄ 8
13⁄4
7⁄ 8
11⁄2
0.520
9⁄ 16
47⁄8
21⁄8
23⁄4
9⁄ 16
23⁄16
3⁄ 4
2
1
13⁄4
0.582
5⁄ 8
51⁄2
23⁄8
31⁄8
5⁄ 8
21⁄2
7⁄ 8
21⁄4
11⁄8
2
0.645
11⁄ 16
6
21⁄2
31⁄2
313⁄16
213⁄16
15⁄ 16
29⁄16
11⁄4
21⁄4
0.707
3⁄ 4
61⁄2
211⁄16
313⁄16
11⁄ 16
31⁄8
1
213⁄16
13⁄8
27⁄16
0.770
13⁄ 16
67⁄8
213⁄16
41⁄16
3⁄ 4
35⁄16
11⁄16
3
17⁄16
2 5⁄8
0.832
7⁄ 8
71⁄4
3
41⁄4
3⁄ 4
31⁄2
11⁄8
31⁄8
11⁄2
23⁄4
0.895
15⁄ 16
D
I
E
F
79⁄16
31⁄8
47⁄16
13⁄ 16
35⁄8
13⁄16
31⁄4
19⁄16
27⁄8
0.957
1
77⁄8
31⁄4
45⁄8
13⁄ 16
313⁄16
11⁄4
33⁄8
15⁄8
3
1.020
11⁄8
81⁄2
39⁄16
415⁄16
7⁄ 8
41⁄16
15⁄16
35⁄8
13⁄4
33⁄16
1.145
11⁄4
9
33⁄4
51⁄4
15⁄ 16
45⁄16
13⁄8
37⁄8
17⁄8
33⁄8
1.270
13⁄8
91⁄2
4
51⁄2
1
41⁄2
17⁄16
41⁄16
2
31⁄2
1.395 1.520
11⁄2
10
41⁄4
53⁄4
1
43⁄4
11⁄2
41⁄4
21⁄8
35⁄8
15⁄8
101⁄2
41⁄2
6
1
5
11⁄2
41⁄2
21⁄8
37⁄8
1.645
13⁄4
11
43⁄4
61⁄4
11⁄16
53⁄16
19⁄16
411⁄16
21⁄4
4
1.770
17⁄8
113⁄8
47⁄8
61⁄2
11⁄16
57⁄16
19⁄16
415⁄16
21⁄4
41⁄4
1.895
2
113⁄4
5
63⁄4
11⁄8
55⁄8
15⁄8
51⁄8
23⁄8
43⁄8
2.020
21⁄4
121⁄2
51⁄4
71⁄4
11⁄8
61⁄8
13⁄16
51⁄2
21⁄2
43⁄4
2.270
21⁄2
131⁄4
51⁄2
73⁄4
13⁄4
69⁄16
17⁄8
57⁄8
25⁄8
51⁄8
2.520
23⁄4
14
53⁄4
81⁄4
11⁄4
7
2
61⁄4
23⁄4
51⁄2
2.770
3
15
61⁄4
83⁄4
11⁄4
71⁄2
2
63⁄4
3
53⁄4
3.020
for the whole length of the chamfered portion. Acme taps should also always be relieved on the front side of the thread to within 1⁄32 inch of the cutting edge. Adjustable Taps: Many adjustable taps are now used, especially for accurate work. Some taps of this class are made of a solid piece of tool steel that is split and provided with means of expanding sufficiently to compensate for wear. Most of the larger adjustable taps have inserted blades or chasers that are held rigidly, but are capable of radial adjustment. The use of taps of this general class enables standard sizes to be maintained readily.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
921
Table 25. Proportions of Acme and Square-Threaded Taps Made in Sets R – 0.010"
B
A C L
R = root diameter of thread. T = double depth of full thread.
Kind of Tap
No. of Taps in Set
Order of Tap in Set
A
B
R + 0.65T
R + 0.010
1⁄ L 8
to 1⁄6 L
2d
D
A on 1st tap − 0.005
1⁄ L 4
to 1⁄3 L
1st
R + 0.45T
R + 0.010
1⁄ L 8
to 1⁄6 L
2d
R + 0.80T
A on 1st tap − 0.005
1⁄ L 6
to 1⁄4 L
3d
D
A on 2d tap − 0.005
1⁄ L 4
to 1⁄3 L
1st
R + 0.40T
R + 0.010
1⁄ L 8
2d
R + 0.70T
A on 1st tap − 0.005
1⁄ L 6
3d
R + 0.90T
A on 2d tap − 0.005
1⁄ L 5
4th
D
A on 3d tap − 0.005
1⁄ L 4
1st
R + 0.37T
R + 0.010
1⁄ L 8
2d
R + 0.63T
A on 1st tap − 0.005
1⁄ L 6
3d
R + 0.82T
A on 2d tap − 0.005
1⁄ L 5
4th
R + 0.94T
A on 3d tap − 0.005
1⁄ L 5
to 1⁄4 L
5th
D
A on 4th tap − 0.005
1⁄ L 4
to 1⁄3 L
1st
R + 0.67T
R
1⁄ L 8
to 1⁄6 L
2d
D
A on 1st tap − 0.005
1⁄ L 4
to 1⁄3 L
1st
R + 0.41T
R
1⁄ L 8
to 1⁄6 L
2d
R + 0.080T
A on 1st tap − 0.005
1⁄ L 6
to 1⁄4 L
3d
D
A on 2d tap − 0.005
1⁄ L 4
to 1⁄3 L
1st
R + 0.32T
R
1⁄ L 8
2d
R + 0.62T
A on 1st tap − 0.005
1⁄ L 6
3d
R + 0.90T
A on 2d tap − 0.005
1⁄ L 5
4th
D
A on 3d tap − 0.005
1⁄ L 4
1st
R + 0.26T
R
1⁄ L 8
2d
R + 0.50T
A on 1st tap − 0.005
1⁄ L 6
3d
R + 0.72T
A on 2d tap − 0.005
1⁄ L 5
4th
R + 0.92T
A on 3d tap − 0.005
1⁄ L 5
to 1⁄4 L
5th
D
A on 4th tap − 0.005
1⁄ L 4
to 1⁄3 L
1st 2
3
Acme Thread Taps
4
5
2
3
SquareThreaded Taps
4
5
D = full diameter of tap.
C
to 1⁄3 L
to 1⁄3 L
Drill Hole Sizes for Acme Threads.—Many tap and die manufacturers and vendors make available to their customers computer programs designed to calculate drill hole sizes for all the Acme threads in their ranges from the basic dimensions. The large variety and combination of dimensions for such tools prevent inclusion of a complete set of tables of tap drills for Acme taps in this Handbook. The following formulas (dimensions in inches) for calculating drill hole sizes for Acme threads are derived from the American National Standard, ANSI/ASME B1.5-1997, Acme Screw Threads.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 922
TAPS AND THREADING DIES
To select a tap drill size for an Acme thread, first calculate the maximum and minimum internal product minor diameters for the thread to be produced. (Dimensions for general purpose, centralizing, and stub Acme screw threads are given in the Threads and Threading section, starting on page 1825.) Then select a drill that will yield a finished hole somewhere between the established maximum and minimum product minor diameters. Consider staying close to the maximum product limit in selecting the hole size, to reduce the amount of material to be removed when cutting the thread. If there is no standard drill size that matches the hole diameter selected, it may be necessary to drill and ream, or bore the hole to size, to achieve the required hole diameter. Diameters of General-Purpose Acme Screw Threads of Classes 2G, 3G, and 4G may be calculated from: minimum diameter = basic major diameter − pitch maximum diameter = minimum minor diameter + 0.05 × pitch pitch = 1/number of threads per inch Example: 1⁄2 -10 Acme 2G, pitch = 1⁄10 = 0.1 minimum diameter = 0.5 − 0.1 = 0.4 maximum diameter = 0.4 + (0.05 × 0.1) = 0.405 drill selected = letter X or 0.3970 + 0.0046 (probable oversize) = 0.4016 Diameters of Acme Centralizing Screw Threads of Classes 2C, 3C, and 4C may be calculated from: minimum diameter = basic major diameter − 0.9 × pitch maximum diameter = minimum minor diameter + 0.05 × pitch pitch = 1/number of threads per inch Example: 1⁄2 -10 Acme 2C, pitch = 1⁄10 = 0.1 minimum diameter = 0.5 − (0.9 × 0.1) = 0.41 maximum diameter = 0.41 + (0.05 × 0.1) = 0.415 drill selected = 13⁄32 or 0.4062 + 0.0046 (probable oversize) = 0.4108. Diameters for Acme Centralizing Screw Threads of Classes 5C and 6C: These classes are not recommended for new designs, but may be calculated from: minimum diameter = [basic major diameter − (0.025 √ basic major diameter)] − 0.9 × pitch maximum diameter = minimum minor diameter + 0.05 × pitch pitch = 1/number of threads per inch Example: 1⁄2 -10 Acme 5C, pitch = 1⁄10 = 0.1 minimum diameter = [0.5 − (0.025 √ 0.5)] − (0.9 × 0.1) = 0.3923 maximum diameter = 0.3923 + (0.05 × 0.1) = 0.3973 drill selected = 25⁄64 or 0.3906 + 0.0046 (probable oversize) = 0.3952 British Standard Screwing Taps for ISO Metric Threads.—BS 949: Part 1:1976 provides dimensions and tolerances for screwing taps for ISO metric coarse-pitch series threads in accordance with BS 3643: Part 2; and for metric fine-pitch series threads in accordance with BS 3643: Part 3. Table 26 provides dimensional data for the cutting portion of cut-thread taps for coarseseries threads of ISO metric sizes. The sizes shown were selected from the first-choice combinations of diameter and pitch listed in BS 3643:Part 1:1981 (1998). Table 13 provides similar data for ground-thread taps for both coarse- and fine-pitch series threads of ISO metric sizes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
923
Table 26. British Standard Screwing Taps for ISO Metric Threads Dimensional Limits for the Threaded Portion of Cut Taps— Coarse Pitch Series BS 949: Part 1:1976 Major Diameter Designation
Pitch
Pitch Diameter
Minimuma
Basic
Max.
Tolerance on Thread Angle, Degrees
Min.
M1
0.25
1.030
0.838
0.875
0.848
4.0
M1.2
0.25
1.230
1.038
1.077
1.048
4.0
M1.6
0.35
1.636
1.373
1.417
1.385
3.4
M2
0.40
2.036
1.740
1.786
1.752
3.2
M2.5
0.45
2.539
2.208
2.259
2.221
3.0
M3
0.50
3.042
2.675
2.730
2.689
2.9
M4
0.70
4.051
3.545
3.608
3.562
2.4
M5
0.80
5.054
4.480
4.547
4.498
2.3
M6
1.00
6.060
5.350
5.424
5.370
2.0
M8
1.25
8.066
7.188
7.270
7.210
1.8
M10
1.50
10.072
9.026
9.116
9.050
1.6
M12
1.75
12.078
10.863
10.961
10.889
1.5
M16
2.00
16.084
14.701
14.811
14.729
1.4
M20
2.50
20.093
18.376
18.497
18.407
1.3
M24
3.00
24.102
22.051
22.183
22.085
1.2
M30
3.50
30.111
27.727
27.874
27.764
1.1
M36
4.00
36.117
33.402
33.563
33.441
1.0
a See notes under Table 27.
Table 27. British Standard Screwing Taps for ISO Metric Threads Dimensional Limits for the Threaded Portion of Ground Taps— Coarse-and Fine-Pitch BS 949: Part 1:1976 All Classes of Taps
Thread
Designation
Nominal Major Dia. (basic) d
Pitch p
Min. Major Dia. dmina
Basic Pitch Dia. d2
Class 1 Taps
Class 2 Taps
Class 3 Taps
d2min
d2max
Tolerance on 1⁄2 Thd Angle
Pitch Diameter d2min
d2max
d2min
d2max
COARSE-PITCH THREAD SERIES M1
1
0.25
1.022
0.838
0.844
0.855
…
…
…
…
±60′
M1.2
1.2
0.25
1.222
1.038
1.044
1.055
…
…
…
…
±60′
M1.6
1.6
0.35
1.627
1.373
1.380
1.393
1.393
1.407
…
…
±50′
M2
2
0.40
2.028
1.740
1.747
1.761
1.761
1.776
…
…
±40′
M2.5
2.5
0.45
2.530
2.208
2.216
2.231
2.231
2.246
…
…
±38′
M3
3
0.50
3.032
2.675
2.683
2.699
2.699
2.715
2.715
2.731
±36′
M4
4
0.70
4.038
3.545
3.555
3.574
3.574
3.593
3.593
3.612
±30′
M5
5
0.80
5.040
4.480
4.490
4.510
4.510
4.530
4.530
4.550
±26′
M6
6
1.00
6.047
5.350
5.362
5.385
5.385
5.409
5.409
5.433
±24′
M8
8
1.25
8.050
7.188
7.201
7.226
7.226
7.251
7.251
7.276
±22′
M10
10
1.50
10.056
9.026
9.040
9.068
9.068
9.096
9.096
9.124
±20′
M12
12
1.75
12.064
10.863
10.879
10.911
10.911
10.943
10.943
10.975
±19′
M16
16
2.00
16.068
14.701
14.718
14.752
14.752
14.786
14.786
14.820
±18′
M20
20
2.50
20.072
18.376
18.394
18.430
18.430
18.466
18.466
18.502
±16′
M24
24
3.00
24.085
22.051
22.072
22.115
22.115
22.157
22.157
22.199
±14′
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 924
TAPS AND THREADING DIES
Table 27. (Continued) British Standard Screwing Taps for ISO Metric Threads Dimensional Limits for the Threaded Portion of Ground Taps— Coarse-and Fine-Pitch BS 949: Part 1:1976 All Classes of Taps
Thread
Class 1 Taps
Class 2 Taps
Class 3 Taps
d2max
d2min
d2max
Tolerance on 1⁄2 Thd Angle
M30
30
3.50
30.090
27.727
27.749
27.794
27.794
27.839
27.839
27.884
±13′
M36
36
4.00
36.094
33.402
33.426
33.473
33.473
33.520
33.520
33.567
±12′
Designation
Nominal Major Dia. (basic) d
Pitch p
Min. Major Dia. dmina
Basic Pitch Dia. d2
d2min
Pitch Diameter d2max
d2min
FINE-PITCH THREAD SIZES M1 × 0.2
1
0.20
1.020
0.870
0.875
0.885
…
…
…
…
±70′
M1.2 × 0.2
1.2
0.20
1.220
1.070
1.075
1.085
…
…
…
…
±70′
M1.6 × 0.2
1.6
0.20
1.621
1.470
1.475
1.485
…
…
…
…
±70′
M2 × 0.25
2
0.25
2.024
1.838
1.844
1.856
…
…
…
…
±60′
M2.5 × 0.35
2.5
0.35
2.527
2.273
2.280
2.293
2.293
2.307
…
…
±50′
M3 × 0.35
3
0.35
3.028
2.773
2.780
2.794
2.794
2.809
…
…
±50′
M4 × 0.5
4
0.50
4.032
3.675
3.683
3.699
3.699
3.715
3.715
3.731
±36′
M5 × 0.5
5
0.50
5.032
4.675
4.683
4.699
4.699
4.715
4.715
4.731
±36′
M6 × 0.75
6
0.75
6.042
5.513
5.524
5.545
5.545
5.566
5.566
5.587
±28′
M8 × 1
8
1.00
8.047
7.350
7.362
7.385
7.385
7.409
7.409
7.433
±24′
M10 × 1.25
10
1.25
10.050
9.188
9.201
9.226
9.226
9.251
9.251
9.276
±22′
M12 × 1.25
12
1.25
12.056
11.188
11.202
11.230
11.230
11.258
11.258
11.286
±22′
M16 × 1.5
16
1.50
16.060
15.026
15.041
15.071
15.071
15.101
15.101
15.131
±20′
M20 × 1.5
20
1.50
20.060
19.026
19.041
19.071
19.071
19.101
19.101
19.131
±20′
M24 × 2
24
2.00
24.072
22.701
22.719
22.755
22.755
22.791
22.791
22.827
±18′
M30 × 2
30
2.00
30.072
28.701
28.719
28.755
28.755
28.791
28.791
28.827
±18′
a The maximum tap major diameter, d max, is not specified and is left to the manufacturer's discretion. All dimension are in millimeters. The thread sizes in the table have been selected from the preferred series shown in BS 3643:Part 1:1981 (1998). For other sizes, and for second and third choice combinations of diameters and pitches, see the Standard.
Tolerance Classes of Taps: Three tolerance classes (class 1, class 2, and class 3) are used for the designation of taps used for the production of nuts of the following classes: nut classes 4H, 5H, 6H, 7H, and 8H, all having zero minimum clearance; nut classes 4G, 5G, and 6G, all having positive minimum clearance. The tolerances for the three classes of taps are stated in terms of a tolerance unit t, the value of which is equal to the pitch diameter tolerance, TD2, grade 5, of the nut. Thus, t = TD2, grade 5, of the nut. Taps of the different classes vary in the limits of size of the tap pitch diameter. The tolerance on the tap pitch diameter, Td2, is the same for all three classes of taps (20 percent of t), but the position of the tolerance zone with respect to the basic pitch diameter depends upon the lower deviation value Em which is: for tap class 1, Em = +0.1t; for tap class 2, Em = + 0.3t; and for tap class 3, Em = +0.5t.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPS AND THREADING DIES
925
Nuts 8H
6G
7H
5G
6H
4G
5H
Taps Class 3
4H Class 2
t Class 1
0.7t 0.5t E1
0.3t Pitch diameter of basic profile 0.1t
The disposition of the tolerances described is shown in the accompanying illustration of nut class tolerances compared against tap class tolerances. The distance EI shown in this illustration is the minumum clearance, which is zero for H classes and positive for G classes of nuts. Choice of Tap Tolerance Class: Unless otherwise specified, class 1 taps are used for nuts of classes 4H and 5H; class 2 taps for nuts of classes 6H, 4G, and 5G; and class 3 taps for nuts of classes 7H, 8H, and 6G. This relationship of tap and nut classes is a general one, since the accuracy of tapping varies with a number of factors such as the material being tapped, the condition of the machine tool used, the tapping attachment used, the tapping speed, and the lubricant. Tap Major Diameter: Except when a screwed connection has to be tight against gaseous or liquid pressure, it is undesirable for the mating threads to bear on the roots and crests. By avoiding contact in these regions of the threads, the opposite flanks of the two threads are allowed to make proper load bearing contact when the connection is tightened. In general, the desired clearance between crests and roots of mating threads is obtained by increasing the major and minor diameters of the internal thread. Such an increase in the minor diameter is already provided on threads such as the ISO metric thread, in which there is a basic clearance between the crests of minimum size nuts and the roots of maximum size bolts. For this reason, and the fact that taps are susceptible to wear on the crests of their threads, a minimum size is specified for the major diameter of new taps which provides a reasonable margin for the wear of their crests and at the same time provides the desired clearance at the major diameter of the hole. These minimum major diameters for taps are shown in Tables 26 and 13. The maximum tap major diameter is not specified and is left to the manufacturer to take advantage of this concession to produce taps with as liberal a margin possible for wear on the major diameter. Tapping Square Threads.—If it is necessary to tap square threads, this should be done by using a set of taps that will form the thread by a progressive cutting action, the taps varying in size in order to distribute the work, especially for threads of comparatively coarse pitch. From three to five taps may be required in a set, depending upon the pitch. Each tap should have a pilot to steady it. The pilot of the first tap has a smooth cylindrical end from 0.003 to 0.005 inch smaller than the hole, and the pilots of following taps should have teeth.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 926
STANDARD TAPERS
STANDARD TAPERS Standard Tapers Certain types of small tools and machine parts, such as twist drills, end mills, arbors, lathe centers, etc., are provided with taper shanks which fit into spindles or sockets of corresponding taper, thus providing not only accurate alignment between the tool or other part and its supporting member, but also more or less frictional resistance for driving the tool. There are several standards for “self-holding” tapers, but the American National, Morse, and the Brown & Sharpe are the standards most widely used by American manufacturers. The name self-holding has been applied to the smaller tapers—like the Morse and the Brown & Sharpe—because, where the angle of the taper is only 2 or 3 degrees, the shank of a tool is so firmly seated in its socket that there is considerable frictional resistance to any force tending to turn or rotate the tool relative to the socket. The term “self-holding” is used to distinguish relatively small tapers from the larger or self-releasing type. A milling machine spindle having a taper of 31⁄2 inches per foot is an example of a self-releasing taper. The included angle in this case is over 16 degrees and the tool or arbor requires a positive locking device to prevent slipping, but the shank may be released or removed more readily than one having a smaller taper of the self-holding type. Morse Taper.—Dimensions relating to Morse standard taper shanks and sockets may be found in an accompanying table. The taper for different numbers of Morse tapers is slightly different, but it is approximately 5⁄8 inch per foot in most cases. The table gives the actual tapers, accurate to five decimal places. Morse taper shanks are used on a variety of tools, and exclusively on the shanks of twist drills. Dimensions for Morse Stub Taper Shanks are given in Table 1a, and for Morse Standard Taper Shanks in Table 1b. Brown & Sharpe Taper.—This standard taper is used for taper shanks on tools such as end mills and reamers, the taper being approximately 1⁄2 inch per foot for all sizes except for taper No. 10, where the taper is 0.5161 inch per foot. Brown & Sharpe taper sockets are used for many arbors, collets, and machine tool spindles, especially milling machines and grinding machines. In many cases there are a number of different lengths of sockets corresponding to the same number of taper; all these tapers, however, are of the same diameter at the small end. Jarno Taper.—The Jarno taper was originally proposed by Oscar J. Beale of the Brown & Sharpe Mfg. Co. This taper is based on such simple formulas that practically no calculations are required when the number of taper is known. The taper per foot of all Jarno taper sizes is 0.600 inch on the diameter. The diameter at the large end is as many eighths, the diameter at the small end is as many tenths, and the length as many half inches as are indicated by the number of the taper. For example, a No. 7 Jarno taper is 7⁄8 inch in diameter at the large end; 7⁄10 , or 0.700 inch at the small end; and 7⁄2 , or 31⁄2 inches long; hence, diameter at large end = No. of taper ÷ 8; diameter at small end = No. of taper ÷ 10; length of taper = No. of taper ÷ 2. The Jarno taper is used on various machine tools, especially profiling machines and die-sinking machines. It has also been used for the headstock and tailstock spindles of some lathes. American National Standard Machine Tapers: This standard includes a self-holding series (Tables 2, 3, 4, 5 and 7a) and a steep taper series, Table 6. The self-holding taper series consists of 22 sizes which are listed in Table 7a. The reference gage for the self-holding tapers is a plug gage. Table 7b gives the dimensions and tolerances for both plug and ring gages applying to this series. Tables 2 through 5 inclusive give the dimensions for selfholding taper shanks and sockets which are classified as to (1) means of transmitting torque from spindle to the tool shank, and (2) means of retaining the shank in the socket. The steep machine tapers consist of a preferred series (bold-face type, Table 6) and an intermediate series (light-face type). A self-holding taper is defined as “a taper with an
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STANDARD TAPERS
927
angle small enough to hold a shank in place ordinarily by friction without holding means. (Sometimes referred to as slow taper.)” A steep taper is defined as “a taper having an angle sufficiently large to insure the easy or self-releasing feature.” The term “gage line” indicates the basic diameter at or near the large end of the taper. Table 1a. Morse Stub Taper Shanks
Small End of Plug, b D
Shank Dia. End of Socket, a A
No. of Taper
Taper per Foota
Taper per Inchb
1
0.59858
0.049882
0.4314
0.475
15⁄16
2
0.59941
0.049951
0.6469
0.700
Total Length, B
Tang
Depth, C
Thickness, E
Length, F
11⁄8
13⁄ 64
5⁄ 16
111⁄16
17⁄16
19⁄ 64
7⁄ 16
25⁄ 64
9⁄ 16
3
0.60235
0.050196
0.8753
0.938
2
13⁄4
4
0.62326
0.051938
1.1563
1.231
23⁄8
21⁄16
33⁄ 64
11⁄ 16
3
211⁄16
3⁄ 4
15⁄ 16
5
0.63151
0.052626
1.6526
1.748
Tang
Socket
Tang Slot
Min. Depth of Tapered Hole
Socket End to Tang Slot, M
No. of Taper
Radius of Mill, G
Diameter, H
1
3⁄ 16
13⁄ 32
7⁄ 8
2
7⁄ 32
39⁄ 64
11⁄16
15⁄32
17⁄64
3
9⁄ 32
13⁄ 16
11⁄4
13⁄8
15⁄16
11⁄16
13⁄ 32
11⁄8
4
3⁄ 8
13⁄32
17⁄16
19⁄16
11⁄2
13⁄16
17⁄ 32
13⁄8
5
9⁄ 16
119⁄32
113⁄16
115⁄16
17⁄8
17⁄16
25⁄ 32
13⁄4
Plug Depth, P
Drilled X 5⁄ 16
Reamed Y 29⁄ 32
Width, N
Length, O
25⁄ 32
7⁄ 32
23⁄ 32
15⁄ 16
5⁄ 16
15⁄ 16
a These are basic dimensions. b These dimensions are calculated for reference only.
All dimensions in inches. Radius J is 3⁄64 , 1⁄16 , 5⁄64 , 3⁄32 , and 1⁄8 inch respectively for Nos. 1, 2, 3, 4, and 5 tapers.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 928
STANDARD TAPERS Table 1b. Morse Standard Taper Shanks
No. of Taper
Taper per Foot
Taper per Inch
Small End of Plug D
0
0.62460
0.05205
0.252
1 2
0.59858 0.59941
0.04988 0.04995
0.369 0.572
Shank
Diameter End of Socket A
Length B
0.3561
Depth S
Depth of Hole H
211⁄32
27⁄32
21⁄32
0.475
29⁄16
27⁄16
25⁄32
0.700
31⁄8
215⁄16
239⁄64
311⁄16
31⁄4
3
0.60235
0.05019
0.778
0.938
37⁄8
4
0.62326
0.05193
1.020
1.231
47⁄8
45⁄8
41⁄8
5
0.63151
0.05262
1.475
1.748
61⁄8
57⁄8
51⁄4
6
0.62565
0.05213
2.116
2.494
89⁄16
81⁄4
721⁄64
3.270
115⁄8
111⁄4
105⁄64
Dia.
Width W
Length L
Keyway to End K
11⁄ 64
9⁄ 16
115⁄16
7
0.62400
0.05200
2.750
Plug Depth P
Thickness t
Length T
Radius R
2
0.1562
1⁄ 4
5⁄ 32
0.235
Tang or Tongue
Keyway
21⁄8
0.2031
3⁄ 8
3⁄ 16
0.343
0.218
3⁄ 4
21⁄16
29⁄16
0.2500
7⁄ 16
1⁄ 4
17⁄ 32
0.266
7⁄ 8
21⁄2
33⁄16
0.3125
9⁄ 16
9⁄ 32
23⁄ 32
0.328
13⁄16
31⁄16
0.4687
5⁄ 8
5⁄ 16
31⁄ 32
0.484
11⁄4
37⁄8
0.6250
3⁄ 4
3⁄ 8
113⁄32
0.656
11⁄2
415⁄16
0.7500
11⁄8
1⁄ 2
2
0.781
13⁄4
7
1.1250
13⁄8
3⁄ 4
25⁄8
1.156
25⁄8
91⁄2
41⁄16 53⁄16 71⁄4 10
Tolerances on rate of taper: all sizes 0.002 in. per foot. This tolerance may be applied on shanks only in the direction that increases the rate of taper, and on sockets only in the direction that decreases the rate of taper.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STANDARD TAPERS
929
Table 2. American National Standard Taper Drive with Tang, Self-Holding Tapers ANSI/ASME B5.10-1994 (R2002)
No. of Taper 0.239 0.299 0.375 1 2 3 4 41⁄2 5 6
Diameter at Gage Line (1) A 0.23922 0.29968 0.37525 0.47500 0.70000 0.93800 1.23100 1.50000 1.74800 2.49400
No. of Taper 0.239 0.299 0.375 1 2 3 4 41⁄2 5 6
Radius J 0.03 0.03 0.05 0.05 0.06 0.08 0.09 0.13 0.13 0.16
Shank Gage Line Total Length to End of Shank of Shank C B 1.28 1.19 1.59 1.50 1.97 1.88 2.56 2.44 3.13 2.94 3.88 3.69 4.88 4.63 5.38 5.13 6.12 5.88 8.25 8.25 Socket Min. Depth of Hole K Drilled 1.06 1.31 1.63 2.19 2.66 3.31 4.19 4.62 5.31 7.41
Reamed 1.00 1.25 1.56 2.16 2.61 3.25 4.13 4.56 5.25 7.33
Tang
Thickness E 0.125 0.156 0.188 0.203 0.250 0.312 0.469 0.562 0.625 0.750
Length F 0.19 0.25 0.31 0.38 0.44 0.56 0.63 0.69 0.75 1.13
Radius of Mill Diameter G H 0.19 0.18 0.19 0.22 0.19 0.28 0.19 0.34 0.25 0.53 0.22 0.72 0.31 0.97 0.38 1.20 0.38 1.41 0.50 2.00 Tang Slot
Gage Line to Tang Slot M 0.94 1.17 1.47 2.06 2.50 3.06 3.88 4.31 4.94 7.00
Width N 0.141 0.172 0.203 0.218 0.266 0.328 0.484 0.578 0.656 0.781
Length O 0.38 0.50 0.63 0.75 0.88 1.19 1.25 1.38 1.50 1.75
Shank End to Back of Tang Slot P 0.13 0.17 0.22 0.38 0.44 0.56 0.50 0.56 0.56 0.50
All dimensions are in inches. (1) See Table 7b for plug and ring gage dimensions. Tolerances: For shank diameter A at gage line, + 0.002 − 0.000; for hole diameter A, + 0.000 − 0.002. For tang thickness E up to No. 5 inclusive, + 0.000 − 0.006; No. 6, + 0.000 − 0.008. For width N of tang slot up to No. 5 inclusive, + 0.006; − 0.000; No. 6, + 0.008 − 0.000. For centrality of tang E with center line of taper, 0.0025 (0.005 total indicator variation). These centrality tolerances also apply to the tang slot N. On rate of taper, all sizes 0.002 per foot. This tolerance may be applied on shanks only in the direction which increases the rate of taper and on sockets only in the direction which decreases the rate of taper. Tolerances for two-decimal dimensions are plus or minus 0.010, unless otherwise specified.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 930
STANDARD TAPERS Table 3. American National Standard Taper Drive with Keeper Key Slot, Self-Holding Tapers ANSI/ASME B5.10-1994 (R2002)
Shank
Tang
No. of Taper
Dia. at Gage Line (1) A
Total Length B
Gage Line to End C
3
0.938
3.88
4
1.231
41⁄2 5
Socket Min. Depth of Hole K
Gage Line to Tang Slot M
Thickness E
Length F
Radius of Mill G
Drill
Ream
3.69
0.312
0.56
0.28
0.78
0.08
3.31
3.25
3.06
4.88
4.63
0.469
0.63
0.31
0.97
0.09
4.19
4.13
3.88
1.500
5.38
5.13
0.562
0.69
0.38
1.20
0.13
4.63
4.56
4.32
1.748
6.13
5.88
0.625
0.75
0.38
1.41
0.13
5.31
5.25
4.94
Diameter H
Radius J
6
2.494
8.56
8.25
0.750
1.13
0.50
2.00
0.16
7.41
7.33
7.00
7
3.270
11.63
11.25
1.125
1.38
0.75
2.63
0.19
10.16
10.08
9.50
Tang Slot
Keeper Slot in Shank
Keeper Slot in Socket
No. of Taper
Width N
Length O
Shank End to Back of Slot P
Gage Line to Bottom of Slot Y′
Length X
Width N′
Gage Line to Front of Slot Y
3
0.328
1.19
0.56
1.03
1.13
0.266
1.13
1.19
4
0.484
1.25
0.50
1.41
1.19
0.391
1.50
1.25
0.391
41⁄2
0.578
1.38
0.56
1.72
1.25
0.453
1.81
1.38
0.453
5
0.656
1.50
0.56
2.00
1.38
0.516
2.13
1.50
0.516
6
0.781
1.75
0.50
2.13
1.63
0.641
2.25
1.75
0.641
7
1.156
2.63
0.88
2.50
1.69
0.766
2.63
1.81
0.766
Length Z
Width N′ 0.266
All dimensions are in inches. (1) See Table 7b for plug and ring gage dimensions. Tolerances: For shank diameter A at gage line, +0.002, −0; for hole diameter A, +0, −0.002. For tang thickness E up to No. 5 inclusive, +0, −0.006; larger than No. 5, +0, −0.008. For width of slots N and N′ up to No. 5 inclusive, +0.006, −0; larger than No. 5, +0.008, −0. For centrality of tang E with center line of taper 0.0025 (0.005 total indicator variation). These centrality tolerances also apply to slots N and N′. On rate of taper, see footnote in Table 2. Tolerances for two-decimal dimensions are ±0.010 unless otherwise specified.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STANDARD TAPERS
931
Table 4. American National Standard Nose Key Drive with Keeper Key Slot, Self-Holding Tapers ANSI/ASME B5.10-1994 (R2002)
Taper
A(1)
200 250 300 350 400 450 500 600 800 1000 1200
2.000 2.500 3.000 3.500 4.000 4.500 5.000 6.000 8.000 10.000 12.000
Taper 200 250 300 350 400 450 500 600 800 1000 1200 Taper 200 250 300 350 400 450 500 600 800 1000 1200
D 1.41 1.66 2.25 2.50 2.75 3.00 3.25 3.75 4.75 … … U 1.81 2.25 2.75 3.19 3.63 4.19 4.63 5.50 7.38 9.19 11.00
C
Q
I′
I
R
S
5.13 5.88 6.63 7.44 8.19 9.00 9.75 11.31 14.38 17.44 20.50
B′
Min 0.003 Max 0.035 for all sizes
0.25 0.25 0.25 0.31 0.31 0.38 0.38 0.44 0.50 0.63 0.75
1.38 1.38 1.63 2.00 2.13 2.38 2.50 3.00 3.50 4.50 5.38
1.63 2.06 2.50 2.94 3.31 3.81 4.25 5.19 7.00 8.75 10.50
1.010 1.010 2.010 2.010 2.010 3.010 3.010 3.010 4.010 4.010 4.010
0.562 0.562 0.562 0.562 0.562 0.812 0.812 0.812 1.062 1.062 1.062
D′a 0.375 0.375 0.375 0.375 0.375 0.500 0.500 0.500 0.500 … … V 1.00 1.00 1.00 1.25 1.25 1.50 1.50 1.75 2.00 2.50 3.00
W 3.44 3.69 4.06 4.88 5.31 5.88 6.44 7.44 9.56 11.50 13.75 M 4.50 5.19 5.94 6.75 7.50 8.00 8.75 10.13 12.88 15.75 18.50
X 1.56 1.56 1.56 2.00 2.25 2.44 2.63 3.00 4.00 4.75 5.75 N 0.656 0.781 1.031 1.031 1.031 1.031 1.031 1.281 1.781 2.031 2.531
N′ 0.656 0.781 1.031 1.031 1.031 1.031 1.031 1.281 1.781 2.031 2.031 O 1.56 1.94 2.19 2.19 2.19 2.75 2.75 3.25 4.25 5.00 6.00
R′ 1.000 1.000 2.000 2.000 2.000 3.000 3.000 3.000 4.000 4.000 4.000 P 0.94 1.25 1.50 1.50 1.50 1.75 1.75 2.06 2.75 3.31 4.00
S′ 0.50 0.50 0.50 0.50 0.50 0.75 0.75 0.75 1.00 1.00 1.00 Y 2.00 2.25 2.63 3.00 3.25 3.63 4.00 4.63 5.75 7.00 8.25
T 4.75 5.50 6.25 6.94 7.69 8.38 9.13 10.56 13.50 16.31 19.00 Z 1.69 1.69 1.69 2.13 2.38 2.56 2.75 3.25 4.25 5.00 6.00
a Thread is UNF-2B for hole; UNF-2A for screw. (1) See Table 7b for plug and ring gage dimensions. All dimensions are in inches. AE is 0.005 greater than one-half of A. Width of drive key R″ is 0.001 less than width R″ of keyway. Tolerances: For diameter A of hole at gage line, +0, −0.002; for diameter A of shank at gage line, +0.002, −0; for width of slots N and N′, +0.008, −0; for width of drive keyway R′ in socket, +0, − 0.001; for width of drive keyway R in shank, 0.010, −0; for centrality of slots N and N′ with center line of spindle, 0.007; for centrality of keyway with spindle center line: for R, 0.004 and for R′, 0.002 T.I.V. On rate of taper, see footnote in Table 2. Two-decimal dimensions, ±0.010 unless otherwise specified.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 932
STANDARD TAPERS Table 5. American National Standard Nose Key Drive with Drawbolt, Self-Holding Tapers ANSI/ASME B5.10-1994 (R2002)
No. of Taper
Dia. at Gage Line Aa
200 250 300 350 400 450 500 600 800 1000 1200
2.000 2.500 3.000 3.500 4.000 4.500 5.000 6.000 8.000 10.000 12.000
Drive Key Screw Holes UNF 2B Center Line Hole UNF to Center 2A Screw of Screw D′ D 1.41 1.66 2.25 2.50 2.75 3.00 3.25 3.75 4.75 … …
0.38 0.38 0.38 0.38 0.38 0.50 0.50 0.50 0.50 … …
Sockets Drive Keyway
Width R″
Width R′
Depth S′
Gage Line to Front of Relief T
0.999 0.999 1.999 1.999 1.999 2.999 2.999 2.999 3.999 3.999 3.999
1.000 1.000 2.000 2.000 2.000 3.000 3.000 3.000 4.000 4.000 4.000
0.50 0.50 0.50 0.50 0.50 0.75 0.75 0.75 1.00 1.00 1.00
4.75 5.50 6.25 6.94 7.69 8.38 9.13 10.56 13.50 16.31 19.00
Dia. of Relief U
Depth of Relief V
Dia. of Draw Bolt Hole d
1.81 2.25 2.75 3.19 3.63 4.19 4.63 5.50 7.38 9.19 11.00
1.00 1.00 1.00 1.25 1.25 1.50 1.50 1.75 2.00 2.50 3.00
1.00 1.00 1.13 1.13 1.63 1.63 1.63 2.25 2.25 2.25 2.25
a See Table 7b for plug and ring gage dimensions.
Shanks Drawbar Hole
No. of Taper
Length from Gage Line B′
Dia. UNC-2B AL 7⁄ –9 8 7⁄ –9 8
Depth of Drilled Hole E
Depth of Thread AP
Dia. of Counter Bore G
2.44
1.75
0.91
1.75 2.00 2.00 3.00
0.91 1.03 1.03 1.53
Drive Keyway
Depth of 60° Chamfer J
Width R
Depth S
Center Line to Bottom of Keyway AE
4.78
0.13
1.010
0.562
1.005
5.53 6.19 7.00 7.50
0.13 0.19 0.19 0.31
1.010 2.010 2.010 2.010
0.562 0.562 0.562 0.562
1.255 1.505 1.755 2.005
Gage Line to First Thread AO
200
5.13
250 300 350 400
5.88 6.63 7.44 8.19
1–8 1–8 11⁄2 –6
2.44 2.75 2.75 4.00
450
9.00
11⁄2 –6
4.00
3.00
1.53
8.31
0.31
3.010
0.812
2.255
500
9.75
11⁄2 –6
4.00
3.00
1.53
9.06
0.31
3.010
0.812
2.505
600
11.31
5.31
4.00
2.03
10.38
0.50
3.010
0.812
3.005
800
14.38
5.31
4.00
2.03
13.44
0.50
4.010
1.062
4.005
1000
17.44
5.31
4.00
2.03
16.50
0.50
4.010
1.062
5.005
1200
20.50
2–41⁄2 2–41⁄2 2–41⁄2 2–41⁄2
5.31
4.00
2.03
19.56
0.50
4.010
1.062
6.005
All dimensions in inches. Exposed length C is 0.003 minimum and 0.035 maximum for all sizes. Drive Key D′ screw sizes are 3⁄8 –24 UNF-2A up to taper No. 400 inclusive and 1⁄2 –20 UNF-2A for larger tapers. Tolerances: For diameter A of hole at gage line, +0.000, −0.002 for all sizes; for diameter A of shank at gage line, +0.002, −0.000; for all sizes; for width of drive keyway R′ in socket, +0.000, − 0.001; for width of drive keyway R in shank, +0.010, −0.000; for centrality of drive keyway R′, with center line of shank, 0.004 total indicator variation, and for drive keyway R′, with center line of spindle, 0.002. On rate of taper, see footnote in Table 2. Tolerances for two-decimal dimensions are ±0.010 unless otherwise specified.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STANDARD TAPERS
933
Table 6. ANSI Standard Steep Machine Tapers ANSI/ASME B5.10-1994 (R2002)
No. of Taper 5 10 15 20 25 30
Taper per Foota 3.500 3.500 3.500 3.500 3.500 3.500
Dia. at Gage Lineb 0.500 0.625 0.750 0.875 1.000 1.250
Length Along Axis 0.6875 0.8750 1.0625 1.3125 1.5625 1.8750
No. of Taper 35 40 45 50 55 60
Taper per Foota 3.500 3.500 3.500 3.500 3.500 3.500
Dia.at Gage Lineb 1.500 1.750 2.250 2.750 3.500 4.250
Length Along Axis 2.2500 2.5625 3.3125 4.0000 5.1875 6.3750
a This taper corresponds to an included angle of 16°, 35′, 39.4″. b The basic diameter at gage line is at large end of taper.
All dimensions given in inches. The tapers numbered 10, 20, 30, 40, 50, and 60 that are printed in heavy-faced type are designated as the “Preferred Series.” The tapers numbered 5, 15, 25, 35, 45, and 55 that are printed in light-faced type are designated as the “Intermediate Series.”
Table 7a. American National Standard Self-holding Tapers — Basic Dimensions ANSI/ASME B5.10-1994 (R2002) No. of Taper
Taper per Foot
Dia. at Gage Line a A
.239 .299 .375 1 2 3 4
0.50200 0.50200 0.50200 0.59858 0.59941 0.60235 0.62326
0.23922 0.29968 0.37525 0.47500 0.70000 0.93800 1.23100
41⁄2
0.62400
1.50000
5 6 7 200 250 300 350 400 450 500 600 800 1000 1200
0.63151 1.74800 0.62565 2.49400 0.62400 3.27000 0.750 2.000 0.750 2.500 0.750 3.000 0.750 3.500 0.750 4.000 0.750 4.500 0.750 5.000 0.750 6.000 0.750 8.000 0.750 10.000 0.750 12.000
Means of Driving and Holdinga
} Tang Drive With Shank Held in by Friction (See Table 2)
} Tang Drive With Shank Held in by Key (See Table 3)
} Key Drive With Shank Held in by Key (See Table 4) } Key Drive With Shank Held in by Draw-bolt (See Table 5)
a See illustrations above Tables 2 through 5.
All dimensions given in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Origin of Series Brown & Sharpe Taper Series
Morse Taper Series
3⁄ 4
Inch per Foot Taper Series
Machinery's Handbook 27th Edition 934
STANDARD TAPERS Table 7b. American National Standard Plug and Ring Gages for the Self-Holding Taper Series ANSI/ASME B5.10-1994 (R2002)
Length Gage Line to End L
Depth of GagingNotch, Plug Gage L′
0.94 1.19 1.50 2.13 2.56 3.19 4.06 4.50 5.19 7.25 10.00 4.75 5.50 6.25 7.00 7.75 8.50 9.25 10.75 13.75 16.75 19.75
0.048 0.048 0.048 0.040 0.040 0.040 0.038 0.038 0.038 0.038 0.038 0.032 0.032 0.032 0.032 0.032 0.032 0.032 0.032 0.032 0.032 0.032
Tolerances for Diameter Ab
No. of Taper
Tapera per Foot
Diametera at Gage Line A
Class X Gage
Class Y Gage
Class Z Gage
Diameter at Small End A′
0.239 0.299 0.375 1 2 3 4 41⁄2 5 6 7 200 250 300 350 400 450 500 600 800 1000 1200
0.50200 0.50200 0.50200 0.59858 0.59941 0.60235 0.62326 0.62400 0.63151 0.62565 0.62400 0.75000 0.75000 0.75000 0.75000 0.75000 0.75000 0.75000 0.75000 0.75000 0.75000 0.75000
0.23922 0.29968 0.37525 0.47500 0.70000 0.93800 1.23100 1.50000 1.74800 2.49400 3.27000 2.00000 2.50000 3.00000 3.50000 4.00000 4.50000 5.00000 6.00000 8.00000 10.00000 12.00000
0.00004 0.00004 0.00004 0.00004 0.00004 0.00006 0.00006 0.00006 0.00008 0.00008 0.00010 0.00008 0.00008 0.00010 0.00010 0.00010 0.00010 0.00013 0.00013 0.00016 0.00020 0.00020
0.00007 0.00007 0.00007 0.00007 0.00007 0.00009 0.00009 0.00009 0.00012 0.00012 0.00015 0.00012 0.00012 0.00015 0.00015 0.00015 0.00015 0.00019 0.00019 0.00024 0.00030 0.00030
0.00010 0.00010 0.00010 0.00010 0.00010 0.00012 0.00012 0.00012 0.00016 0.00016 0.00020 0.00016 0.00016 0.00020 0.00020 0.00020 0.00020 0.00025 0.00025 0.00032 0.00040 0.00040
0.20000 0.25000 0.31250 0.36900 0.57200 0.77800 1.02000 1.26600 1.47500 2.11600 2.75000 1.703 2.156 2.609 3.063 3.516 3.969 4.422 5.328 7.141 8.953 10.766
a The taper per foot and diameter A at gage line are basic dimensions. Dimensions in Column A′ are calculated for reference only. b Tolerances for diameter A are plus for plug gages and minus for ring gages.
All dimensions are in inches. The amount of taper deviation for Class X, Class Y, and Class Z gages are the same, respectively, as the amounts shown for tolerances on diameter A. Taper deviation is the permissible allowance from true taper at any point of diameter in the length of the gage. On taper plug gages, this deviation may be applied only in the direction which decreases the rate of taper. On taper ring gages, this deviation may be applied only in the direction which increases the rate of taper. Tolerances on two-decimal dimensions are ±0.010.
British Standard Tapers.—British Standard 1660: 1972, “Machine Tapers, Reduction Sleeves, and Extension Sockets,” contains dimensions for self-holding and self-releasing tapers, reduction sleeves, extension sockets, and turret sockets for tools having Morse and metric 5 per cent taper shanks. Adapters for use with 7⁄24 tapers and dimensions for spindle noses and tool shanks with self-release tapers and cotter slots are included in this Standard.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STANDARD TAPERS
935
Table 8. Dimensions of Morse Taper Sleeves
A
B
C
D
H
I
K
L
M
2
1
39⁄16
0.700
5⁄ 8
E
1⁄ 4
F
7⁄ 16
G
23⁄16
0.475
21⁄16
3⁄ 4
0.213
3
1
315⁄16
0.938
1⁄ 4
5⁄ 16
9⁄ 16
23⁄16
0.475
21⁄16
3⁄ 4
0.213
3
2
47⁄16
0.938
3⁄ 4
5⁄ 16
9⁄ 16
25⁄8
0.700
21⁄2
7⁄ 8
0.260
4
1
47⁄8
1.231
1⁄ 4
15⁄ 32
5⁄ 8
23⁄16
0.475
21⁄16
3⁄ 4
0.213
4
2
47⁄8
1.231
1⁄ 4
15⁄ 32
5⁄ 8
25⁄8
0.700
21⁄2
7⁄ 8
0.260
4
3
53⁄8
1.231
3⁄ 4
15⁄ 32
5⁄ 8
31⁄4
0.938
31⁄16
13⁄16
0.322
5
1
61⁄8
1.748
1⁄ 4
5⁄ 8
3⁄ 4
23⁄16
0.475
21⁄16
3⁄ 4
0.213
5
2
61⁄8
1.748
1⁄ 4
5⁄ 8
3⁄ 4
25⁄8
0.700
21⁄2
7⁄ 8
0.260
5
3
61⁄8
1.748
1⁄ 4
5⁄ 8
3⁄ 4
31⁄4
0.938
31⁄16
13⁄16
0.322
5
4
65⁄8
1.748
3⁄ 4
5⁄ 8
3⁄ 4
41⁄8
1.231
37⁄8
11⁄4
0.478
6
1
85⁄8
2.494
3⁄ 8
3⁄ 4
11⁄8
23⁄16
0.475
21⁄16
3⁄ 4
0.213
6
2
85⁄8
2.494
3⁄ 8
3⁄ 4
11⁄8
25⁄8
0.700
21⁄2
7⁄ 8
0.260
6
3
85⁄8
2.494
3⁄ 8
3⁄ 4
11⁄8
31⁄4
0.938
31⁄16
13⁄16
0.322
6
4
85⁄8
2.494
3⁄ 8
3⁄ 4
11⁄8
41⁄8
1.231
37⁄8
11⁄4
0.478
6
5
85⁄8
2.494
3⁄ 8
3⁄ 4
11⁄8
51⁄4
1.748
415⁄16
11⁄2
0.635
7
3
115⁄8
3.270
3⁄ 8
11⁄8
13⁄8
31⁄4
0.938
31⁄16
13⁄16
0.322
7
4
115⁄8
3.270
3⁄ 8
11⁄8
13⁄8
41⁄8
1.231
37⁄8
11⁄4
0.478
7
5
115⁄8
3.270
3⁄ 8
11⁄8
13⁄8
51⁄4
1.748
415⁄16
11⁄2
0.635
7
6
121⁄2
3.270
11⁄4
11⁄8
13⁄8
73⁄8
2.494
7
13⁄4
0.760
Table 9. Morse Taper Sockets — Hole and Shank Sizes
Morse Taper
Morse Taper
Morse Taper
Size
Hole
Shank
Size
Hole
Shank
Size
Hole
Shank
1 by 2
No. 1
No. 2
2 by 5
No. 2
No. 5
4 by 4
No. 4
No. 4
1 by 3
No. 1
No. 3
3 by 2
No. 3
No. 2
4 by 5
No. 4
No. 5
1 by 4
No. 1
No. 4
3 by 3
No. 3
No. 3
4 by 6
No. 4
No. 6
1 by 5
No. 1
No. 5
3 by 4
No. 3
No. 4
5 by 4
No. 5
No. 4
2 by 3
No. 2
No. 3
3 by 5
No. 3
No. 5
5 by 5
No. 5
No. 5
2 by 4
No. 2
No. 4
4 by 3
No. 4
No. 3
5 by 6
No. 5
No. 6
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 936
STANDARD TAPERS Table 10. Brown & Sharpe Taper Shanks
Dia. of Plug at Small End
Number of Taper
Taper per Foot (inch)
1c
.50200
.20000
2c
.50200
.25000
3c
4
5
.50200
.50240
.50160
D
.31250
.35000
.45000
Plug Depth, P
Keyway from End of Spindle
Length of Keywaya
Width of Keyway
Length Diame- Thickter of ness of of Arbor Arbor Arbor Tongue Tongue Tongue
Mill. Mach. Standard
Miscell.
K
S
W
T
d
t
15⁄ 16
…
…
15⁄ 16
13⁄16
3⁄ 8
.135
3⁄ 16
.170
1⁄ 8
13⁄16
…
…
111⁄64
11⁄2
1⁄ 2
.166
1⁄ 4
.220
5⁄ 32
11⁄2
…
…
115⁄32
17⁄8
5⁄ 8
.197
5⁄ 16
.282
3⁄ 16
…
…
13⁄4
123⁄32
21⁄8
5⁄ 8
.197
5⁄ 16
.282
3⁄ 16
…
…
2
131⁄32
23⁄8
5⁄ 8
.197
5⁄ 16
.282
3⁄ 16
…
11⁄4
…
113⁄64
121⁄32
11⁄ 16
.228
11⁄ 32
.320
7⁄ 32
111⁄16
…
…
141⁄64
23⁄32
11⁄ 16
.228
11⁄ 32
.320
7⁄ 32
…
13⁄4
…
111⁄16
23⁄16
3⁄ 4
.260
3⁄ 8
.420
1⁄ 4
…
…
2
115⁄16
27⁄16
3⁄ 4
.260
3⁄ 8
.420
1⁄ 4
21⁄8
…
…
21⁄16
29⁄16
3⁄ 4
.260
3⁄ 8
.420
1⁄ 4
B & Sb Standard
Shank Depth
L
6
.50329
.50000
23⁄8
…
…
219⁄64
27⁄8
7⁄ 8
.291
7⁄ 16
.460
9⁄ 32
…
…
21⁄2
213⁄32
31⁄32
15⁄ 16
.322
15⁄ 32
.560
5⁄ 16
7
.50147
.60000
27⁄8
…
…
225⁄32
313⁄32
15⁄ 16
.322
15⁄ 32
.560
5⁄ 16
…
3
…
229⁄32
317⁄32
15⁄ 16
.322
15⁄ 32
.560
5⁄ 16
39⁄16
…
…
329⁄64
41⁄8
1
.353
1⁄ 2
.710
11⁄ 32
…
4
…
37⁄8
45⁄8
11⁄8
.385
9⁄ 16
.860
3⁄ 8
41⁄4
…
…
41⁄8
47⁄8
11⁄8
.385
9⁄ 16
.860
3⁄ 8
5
…
…
427⁄32
523⁄32
15⁄16
.447
21⁄ 32
1.010
7⁄ 16
…
511⁄16
…
517⁄32
613⁄32
15⁄16
.447
21⁄ 32
1.010
7⁄ 16
…
…
67⁄32
61⁄16
615⁄16
15⁄16
.447
21⁄ 32
1.010
7⁄ 16
515⁄16
…
…
525⁄32
621⁄32
15⁄16
.447
21⁄ 32
1.210
7⁄ 16
…
63⁄4
…
619⁄32
715⁄32
15⁄16
.447
21⁄ 32
1.210
7⁄ 16
71⁄8
71⁄8
…
615⁄16
715⁄16
11⁄2
.510
3⁄ 4
1.460
1⁄ 2
…
…
61⁄4
…
…
…
…
…
…
…
8
.50100
.75000
9
.50085
.90010
10
11 12
.51612
.50100 .49973
1.04465
1.24995 1.50010
13
.50020
1.75005
73⁄4
…
…
79⁄16
89⁄16
11⁄2
.510
3⁄ 4
1.710
1⁄ 2
14
.50000
2.00000
81⁄4
81⁄4
…
81⁄32
95⁄32
111⁄16
.572
27⁄ 32
1.960
9⁄ 16
921⁄32
111⁄16
.572
27⁄ 32
2.210
9⁄ 16
17⁄8
.635
15⁄ 16
2.450
5⁄ 8
15
.5000
2.25000
83⁄4
…
…
817⁄32
16
.50000
2.50000
91⁄4
…
…
9
17
.50000
2.75000
93⁄4
…
…
…
…
…
…
…
…
…
.50000
3.00000
101⁄4
…
…
…
…
…
…
…
…
…
18
101⁄4
a Special
lengths of keyway are used instead of standard lengths in some places. Standard lengths need not be used when keyway is for driving only and not for admitting key to force out tool. b “B & S Standard” Plug Depths are not used in all cases. c Adopted by American Standards Association.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STANDARD TAPERS
937
Table 11. Jarno Taper Shanks
Number of Taper
Length A
Length B
Diameter D
Taper per foot
0.20
0.250
0.600
0.30
0.375
0.600
0.40
0.500
0.600
21⁄2
0.50
0.625
0.600
3
0.60
0.750
0.600
31⁄2
0.70
0.875
0.600
4
0.80
1.000
0.600
41⁄2
0.90
1.125
0.600
5
1.00
1.250
0.600
51⁄2
1.10
1.375
0.600
6
1.20
1.500
0.600
61⁄2
1.30
1.625
0.600
7
1.40
1.750
0.600
2
11⁄8
1
3
15⁄8
11⁄2
4
23⁄16
2
5
211⁄16
6
33⁄16
7
311⁄16
8
43⁄16
9
411⁄16
10
51⁄4
11
53⁄4
12
61⁄4
13
63⁄4
14
71⁄4
Diameter C
15
73⁄4
71⁄2
1.50
1.875
0.600
16
85⁄16
8
1.60
2.000
0.600
17
813⁄16
81⁄2
1.70
2.125
0.600
18
95⁄16
9
1.80
2.250
0.600
91⁄2
1.90
2.375
0.600
2.00
2.500
0.600
19 20
913⁄16 105⁄16
10
Tapers for Machine Tool Spindles.—Most lathe spindles have Morse tapers, most milling machine spindles have American Standard tapers, almost all smaller milling machine spindles have R8 tapers, and large vertical milling machine spindles have American Standard tapers. The spindles of drilling machines and the taper shanks of twist drills are made to fit the Morse taper. For lathes, the Morse taper is generally used, but lathes may have the Jarno, Brown & Sharpe, or a special taper. Of 33 lathe manufacturers, 20 use the Morse taper; 5, the Jarno; 3 use special tapers of their own; 2 use modified Morse (longer than the standard but the same taper); 2 use Reed (which is a short Jarno); 1 uses the Brown & Sharpe standard. For grinding machine centers, Jarno, Morse, and Brown & Sharpe tapers are used. Of ten grinding machine manufacturers, 3 use Brown & Sharpe; 3 use Morse; and 4 use Jarno. The Brown & Sharpe taper is used extensively for milling machine and dividing head spindles. The standard milling machine spindle adopted in 1927 by the milling machine manufacturers of the National Machine Tool Builders' Association (now The Association for Manufacturing Technology [AMT]), has a taper of 31⁄2 inches per foot. This comparatively steep taper was adopted to ensure easy release of arbors.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 938
STANDARD TAPERS
Table 12. American National Standard Plug and Ring Gages for Steep Machine Tapers ANSI/ASME B5.10-1994 (R2002)
Tolerances for Diameter Ab No. of Taper
Taper per Foota (Basic)
Diameter at Gage Linea A
Class X Gage
Class Y Gage
Class Z Gage
Diameter at Small Enda A′
Length Gage Line to Small End L
Overall Length Dia. of Gage of Body Opening B C
5
3.500
0.500
0.00004
0.00007
0.00010
0.2995
0.6875
0.81
0.30
10
3.500
0.625
0.00004
0.00007
0.00010
0.3698
0.8750
1.00
0.36
15
3.500
0.750
0.00004
0.00007
0.00010
0.4401
1.0625
1.25
0.44
20
3.500
0.875
0.00006
0.00009
0.00012
0.4922
1.3125
1.50
0.48
25
3.500
1.000
0.00006
0.00009
0.00012
0.5443
1.5625
1.75
0.53
30
3.500
1.250
0.00006
0.00009
0.00012
0.7031
1.8750
2.06
0.70
35
3.500
1.500
0.00006
0.00009
0.00012
0.8438
2.2500
2.44
0.84
40
3.500
1.750
0.00008
0.00012
0.00016
1.0026
2.5625
2.75
1.00
45
3.500
2.250
0.00008
0.00012
0.00016
1.2839
3.3125
3.50
1.00
50
3.500
2.750
0.00010
0.00015
0.00020
1.5833
4.0000
4.25
1.00
55
3.500
3.500
0.00010
0.00015
0.00020
1.9870
5.1875
5.50
1.00
60
3.500
4.250
0.00010
0.00015
0.00020
2.3906
6.3750
6.75
2.00
a The taper per foot and diameter A at gage line are basic dimensions. Dimensions in Column A′ are
calculated for reference only. b Tolerances for diameter A are plus for plug gages and minus for ring gages. All dimensions are in inches. The amounts of taper deviation for Class X, Class Y, and Class Z gages are the same, respectively, as the amounts shown for tolerances on diameter A. Taper deviation is the permissible allowance from true taper at any point of diameter in the length of the gage. On taper plug gages, this deviation may be applied only in the direction which decreases the rate of taper. On taper ring gages, this deviation may be applied only in the direction which increases the rate of taper. Tolerances on two-decimal dimensions are ±0.010.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STANDARD TAPERS
939
Table 13. Jacobs Tapers and Threads for Drill Chucks and Spindles
Taper Series No. 0 No. 1 No. 2 No. 2a No. 3
A 0.2500 0.3840 0.5590 0.5488 0.8110
B 0.22844 0.33341 0.48764 0.48764 0.74610
C 0.43750 0.65625 0.87500 0.75000 1.21875
Taper per Ft. 0.59145 0.92508 0.97861 0.97861 0.63898
Taper Series No. 4 No. 5 No. 6 No. 33 …
A 1.1240 1.4130 0.6760 0.6240 …
B 1.0372 1.3161 0.6241 0.5605 …
Taper per Ft. 0.62886 0.62010 0.62292 0.76194 …
C 1.6563 1.8750 1.0000 1.0000 …
a These dimensions are for the No. 2 “short” taper.
Thread Size 5⁄ –24 16 5⁄ –24 16 3⁄ –24 8 1⁄ –20 2 5⁄ –11 8 5⁄ –16 8 45⁄ –16 64 3⁄ –16 4
1–8 1–10 11⁄2 –8 Threada Size 5⁄ –24 16 3⁄ –24 8 1⁄ –20 2 5⁄ –11 8 5⁄ –16 8 45⁄ –16 64 3⁄ –16 4
1–8 1–10 11⁄2 –8
Diameter D
Diameter E
Dimension F
Max.
Min.
Max.
Min.
Max.
Min.
0.531 0.633 0.633 0.860 1.125 1.125 1.250 1.250 1.437 1.437 1.871
0.516 0.618 0.618 0.845 1.110 1.110 1.235 1.235 1.422 1.422 1.851
0.3245 0.3245 0.385 0.510 0.635 0.635 0.713 0.760 1.036 1.036 1.536
0.3195 0.3195 0.380 0.505 0.630 0.630 0.708 0.755 1.026 1.026 1.526
0.135 0.135 0.135 0.135 0.166 0.166 0.166 0.166 0.281 0.281 0.343
0.115 0.115 0.115 0.115 0.146 0.146 0.146 0.146 0.250 0.250 0.312
G Max
Min
Hb
0.3114 0.3739 0.4987 0.6234 0.6236 0.7016 0.7485 1.000 1.000 1.500
0.3042 0.3667 0.4906 0.6113 0.6142 0.6922 0.7391 0.9848 0.9872 1.4848
0.437c 0.562d 0.562 0.687 0.687 0.687 0.687 1.000 1.000 1.000
Plug Gage Pitch Dia. Go Not Go 0.2854 0.3479 0.4675 0.5660 0.5844 0.6625 0.7094 0.9188 0.9350 1.4188
0.2902 0.3528 0.4731 0.5732 0.5906 0.6687 0.7159 0.9242 0.9395 1.4242
Ring Gage Pitch Dia. Go Not Go 0.2843 0.3468 0.4662 0.5644 0.5830 0.6610 0.7079 0.9188 0.9350 1.4188
0.2806 0.3430 0.4619 0.5589 0.5782 0.6561 0.7029 0.9134 0.9305 1.4134
a Except for 1–8, 1–10, 11⁄ –8 all threads are now manufactured to the American National Standard 2 Unified Screw Thread System, Internal Class 2B, External Class 2A. Effective date 1976. b Tolerances for dimension H are as follows: 0.030 inch for thread sizes 5⁄ –24 to 3⁄ –16, inclusive 16 4 and 0.125 inch for thread sizes 1–8 to 11⁄2 –8, inclusive. c Length for Jacobs 0B5⁄16 chuck is 0.375 inch, length for 1B5⁄16 chuck is 0.437 inch. d Length for Jacobs No. 1BS chuck is 0.437 inch.
Usual Chuck Capacities for Different Taper Series Numbers: No. 0 taper, drill diameters, 0–5⁄32 inch; No. 1, 0–1⁄4 inch; No. 2, 0–1⁄2 inch; No. 2 “Short,” 0–5⁄16 inch; No. 3, 0–1⁄2 , 1⁄8 –5⁄8 , 3⁄16 –3⁄4 , or 1⁄4 – 13⁄ inch; No. 4, 1⁄ –3⁄ inch; No. 5, 3⁄ –1; No. 6, 0–1⁄ inch; No. 33, 0–1⁄ inch. 16 8 4 8 2 2 Usual Chuck Capacities for Different Thread Sizes: Size 5⁄16 –24, drill diameters 0–1⁄4 inch; size 3⁄8 – 3 1 3 5 1 1 24, drill diameters 0– ⁄8 , ⁄16 – ⁄8 , or ⁄64 – ⁄2 inch; size ⁄2 –20, drill diameters 0–1⁄2 , 1⁄16 –3⁄8 , or 5⁄64 –1⁄2 inch; size 5⁄8 –11, drill diameters 0–1⁄2 inch; size 5⁄8 –16, drill diameters 0–1⁄2 , 1⁄8– –5⁄8 , or 3⁄16 –3⁄4 inch; size 45⁄64 –16, drill diameters 0–1⁄2 inch; size 3⁄4 –16, drill diameters 0–1⁄2 or 3⁄16 –3⁄4 .
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
;; ;;
Face of column
E min M
Standard steep machine taper 3.500 inch per ft
X See Note 3
C
;;
D min
Slot and key location X .002 total M
Usable threads
45°
G
Optional Key Construction
Z
K
.015
H
J
.015
B
A gage
H
–X–
X .0004 See note 4
;;; ;;; ;;; Z
L min section Z-Z
F
45°
F′ F
G
Keyseat Key tight fit in slot when insert key is used
Preferred Key Construction
Copyright 2004, Industrial Press, Inc., New York, NY
G′
STANDARD TAPERS
Max variation from gage line
940
;;;;;;;;; ;;;;;;;;; ;;;;;;;;; ;;;;;;;; ;;;;;;;; ;;;;;;;; ;;;;;;;; ;;;; ;;;; ;;;;
Table 1. Essential Dimensions of American National Standard Spindle Noses for Milling Machines ANSI B5.18-1972 (R1998)
Machinery's Handbook 27th Edition
Table 1. (Continued) Essential Dimensions of American National Standard Spindle Noses for Milling Machines ANSI B5.18-1972 (R1998)
Size No.
Gage Dia.of Taper A
30
Clearance Hole for Draw-in Bolt Min. D
Minimum Dimension Spindle End to Column E
Width of Driving Key F
Width of Keyseat F′
Maximum Height of Driving Key G
Minimum Depth of Keyseat G′
Distance fromCenter to Driving Keys H
Radius of Bolt Hole Circle J
Size of Threads for Bolt Holes UNC-2B K
Full Depth of Arbor Hole in Spindle Min. L
Depth of Usable Thread for Bolt Hole M
Pilot Dia. C
1.250
2.7493 2.7488
0.692 0.685
0.66
0.50
0.6255 0.6252
0.624 0.625
0.31
0.31
0.660 0.654
1.0625 (Note 1)
0.375–16
2.88
0.62
40
1.750
3.4993 3.4988
1.005 0.997
0.66
0.62
0.6255 0.6252
0.624 0.625
0.31
0.31
0.910 0.904
1.3125 (Note 1)
0.500–13
3.88
0.81
45
2.250
3.9993 3.9988
1.286 1.278
0.78
0.62
0.7505 0.7502
0.749 0.750
0.38
0.38
1.160 1.154
1.500 (Note 1)
0.500–13
4.75
0.81
50
2.750
5.0618 5.0613
1.568 1.559
1.06
0.75
1.0006 1.0002
0.999 1.000
0.50
0.50
1.410 1.404
2.000(Note 2)
0.625–11
5.50
1.00
60
4.250
8.7180 8.7175
2.381 2.371
1.38
1.50
1.0006 1.0002
0.999 1.000
0.50
0.50
2.420 2.414
3.500 (Note 2)
0.750–10
8.62
1.25
Copyright 2004, Industrial Press, Inc., New York, NY
941
All dimensions are given in inches. Tolerances: Two-digit decimal dimensions ± 0.010 unless otherwise specified. A—Taper: Tolerance on rate of taper to be 0.001 inch per foot applied only in direction which decreases rate of taper. F′—Centrality of keyway with axis of taper 0.002 total at maximum material condition. (0.002 Total indicator variation) F—Centrality of solid key with axis of taper 0.002 total at maximum material condition. (0.002 Total indicator variation) Note 1: Holes spaced as shown and located within 0.006 inch diameter of true position. Note 2: Holes spaced as shown and located within 0.010 inch diameter of true position. Note 3: Maximum turnout on test plug: 0.0004 at 1 inch projection from gage line. 0.0010 at 12 inch projection from gage line. Note 4: Squareness of mounting face measured near mounting bolt hole circle.
STANDARD TAPERS
Dia.of Spindle B
Machinery's Handbook 27th Edition 942
STANDARD TAPERS
Table 2. Essential Dimensions of American National Standard Tool Shanks for Milling Machines ANSI B5.18-1972 (R1998)
Size of Thread for Draw-in Bolt UNC-2B M
Pilot Dia. R
Length of Pilot S
Minimum Length of Usable Thread T
Minimum Depth of Clearance Hole U
0.500–13
0.675 0.670
0.81
1.00
2.00
0.94 0.93
0.625–11
0.987 0.980
1.00
1.12
2.25
0.656 0.666
1.19 1.18
0.750–10
1.268 1.260
1.00
1.50
2.75
2.750
0.875 0.885
1.50 1.49
1.000–8
1.550 1.540
1.00
1.75
3.50
60
4.250
1.109 1.119
2.28 2.27
1.250–7
2.360 2.350
1.75
2.25
4.25
Size. No.
Distance from Rear of Flange to End of Arbor V
30
Tap Drill Size for Draw-in Thread O
Dia.of Neck P
1.250
0.422 0.432
0.66 0.65
40
1.750
0.531 0.541
45
2.250
Size No.
Gage Dia.of Taper N
30
50
Clearance of Flange from Gage Diameter W
Tool Shank Centerline to Driving Slot X
Width of Driving Slot Y
2.75
0.045 0.075
0.640 0.625
0.635 0.645
40
3.75
0.045 0.075
0.890 0.875
0.635 0.645
45
4.38
0.105 0.135
1.140 1.125
0.760 0.770
50
5.12
0.105 0.135
1.390 1.375
1.010 1.020
60
8.25
0.105 0.135
2.400 2.385
1.010 1.020
Distance from Gage Line to Bottom of C'bore Z
Depth of 60° Center K
Diameter of C'bore L
2.50
0.05 0.07
0.525 0.530
3.50
0.05 0.07
0.650 0.655
4.06
0.05 0.07
0.775 0.780
4.75
0.05 0.12
1.025 1.030
7.81
0.05 0.12
1.307 1.312
All dimensions are given in inches. Tolerances: Two digit decimal dimensions ± 0.010 inch unless otherwise specified. M—Permissible for Class 2B “NoGo” gage to enter five threads before interference. N—Taper tolerance on rate of taper to be 0.001 inch per foot applied only in direction which increases rate of taper. Y—Centrality of drive slot with axis of taper shank 0.004 inch at maximum material condition. (0.004 inch total indicator variation)
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STANDARD TAPERS
943
Table 3. American National Standard Draw-in Bolt Ends ANSI B5.18-1972 (R1998)
Length of Usable Thread Size of Thread on Large Diam- for Large End eter UNC-2A C M
Length of Small End A
Length of Usable Thread at Small End B
30
1.06
0.75
0.75
0.500–13
0.375–16
40
1.25
1.00
1.12
0.625–11
0.500–13
45
1.50
1.12
1.25
0.750–10
0.625–11
50
1.50
1.25
1.38
1.000–8
0.625–11
60
1.75
1.37
2.00
1.250–7
1.000–8
Size No.
Size of Thread for Small End UNC-2A D
All dimensions are given in inches.
Table 4. American National Standard Pilot Lead on Centering Plugs for Flatback Milling Cutters ANSI B5.18-1972 (R1998)
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 944
STANDARD TAPERS
Table 5. Essential Dimensions for American National Standard Spindle Nose with Large Flange ANSI B5.18-1972 (R1998)
;;;;; ;;;;; ;;;;; ;;;;; ;;;;; ;; ;; ;; ;; M2
American Standard Taper 3.500 Inch Per Ft X See Note 1 D min
Usable threads
;; E min
H2
.015 .015
F1 F
Dia. of Spindle Flange B
Pilot Dia. C
50A
2.750
8.7180 8.7175
1.568 1.559
Size No.
Distance from Center to Driving Keys Second Position
H1
H2
1st Position
Z
B
Keyseat Key tight fit in slot G′
Drive Key
Clearance Hole for Draw-in Bolt Min. D
Min. Dim. Spindle End to Column E
1.06
0.75
Radius of Bolt Hole Circles (See Note 3)
Width of Driving Key F 1.0006 1.0002
H2
J1
J2
K1
K2
Full Depth of Arbor Hole in Spindle Min. L
2.420 2.410
2.000
3.500
0.625–11
0.750–10
5.50
Inner
H1
J
J1
X .0004 See note 2 Face of Column
G1
50A
2nd Position
K
L min section Z-Z
Gage Diam. of Taper A
45° Z
A gage
Max variation from Gage Line
Size No.
X .002 Total M
45°
K Usable threads
M1
C
Slot and key location
-X-
Size of Threads for Bolt Holes UNC-2B
Outer
Height of Driving Key Max. G
Depth of Keyseat Min. G1
0.50
0.50 Depth of Usable Thread for Bolt Holes
M1
M2
1.00
1.25
Distance from Center to Driving Keys First Position H1 1.410 1.404
Width of Keyseat F1 0.999 1.000
All dimensions are given in inches. Tolerances: Two-digit decimal dimensions ± 0.010 unless otherwise specified. A—Tolerance on rate of taper to be 0.001 inch per foot applied only in direction which decreases rate of taper. F—Centrality of solid key with axis of taper 0.002 inch total at maximum material condition. (0.002 inch Total indicator variation) F1—Centrality of keyseat with axis of taper 0.002 inch total at maximum material condition. (0.002 inch Total indicator variation) Note 1: Maximum runout on test plug: 0.0004 at 1 inch projection from gage line. 0.0010 at 12 inch projection from gage line. Note 2: Squareness of mounting face measured near mounting bolt hole circle. Note 3: Holes located as shown and within 0.010 inch diameter of true position.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition COLLETS
945
Collets Collets for Lathes, Mills, Grinders, and Fixtures AC
A C
A C B
1
B
2
B
3
A C
A
AC B
B
4
5 6
A D
C
A D
A C
B
7
B
8
A
B
C B
9
A C
A C B
B
B
11
10
12
Collet Styles
Collets for Lathes, Mills, Grinders, and Fixtures Dimensions Collet
Max. Capacity (inches)
Style
Bearing Diam., A
Length, B
Thread, C
Round
Hex
1A
1
0.650
2.563
0.640 × 26 RH
0.500
0.438
Square 0.344
1AM
1
1.125
3.906
1.118 × 24 RH
1.000
0.875
0.719
1B
2
0.437
1.750
0.312 × 30 RH
0.313
0.219
0.188
1C
1
0.335
1.438
0.322 × 40 RH
0.250
0.219
0.172
1J
1
1.250
3.000
1.238 × 20 RH
1.063
0.875
0.750
1K
3
1.250
2.813
None
1.000
0.875
0.719
2A
1
0.860
3.313
0.850 × 20 RH
0.688
0.594
0.469
2AB
2
0.750
2.563
0.500 × 20 RH
0.625
0.484
0.391
2AM
1
0.629
3.188
0.622 × 24 RH
0.500
0.438
0.344
2B
2
0.590
2.031
0.437 × 26 RH
0.500
0.438
0.344
2C
1
0.450
1.812
0.442 × 30 RH
0.344
0.594
0.234
2H
1
0.826
4.250
0.799 × 20 RH
0.625
0.531
1.000
2J
1
1.625
3.250
1.611 × 18 RH
1.375
1.188
0.438
2L
1
0.950
3.000
0.938 × 20 RH
0.750
0.656
1.000
2M
4
2 Morse
2.875
0.375 × 16 RH
0.500
0.438
0.344
2NS
1
0.324
1.562
0.318 × 40 RH
0.250
0.203
0.172
2OS
1
0.299
1.250
0.263 × 40 RH
0.188
0.156
0.125
2S
1
0.750
3.234
0.745 × 18 RH
0.563
0.484
0.391
2VB
2
0.595
2.438
0.437 × 26 RH
0.500
0.438
0.344
3AM
1
0.750
3.188
0.742 × 24 RH
0.625
0.531
0.438
3AT
1
0.687
2.313
0.637 × 26 RH
0.500
0.438
0.344
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 946
COLLETS Collets for Lathes, Mills, Grinders, and Fixtures (Continued) Dimensions
Collet
Max. Capacity (inches)
Style
Bearing Diam., A
Length, B
Thread, C
Round
Hex
3B
2
0.875
3.438
0.625 × 16 RH
0.750
0.641
Square 0.531
3C
1
0.650
2.688
0.640 × 26 RH
0.500
0.438
0.344
3H
1
1.125
4.438
1.050 × 20 RH
0.875
0.750
0.625
3J
1
2.000
3.750
1.988 × 20 RH
1.750
1.500
1.250
3NS
1
0.687
2.875
0.647 × 20 RH
0.500
0.438
0.344
3OS
1
0.589
2.094
0.518 × 26 RH
0.375
0.313
0.266
3PN
1
0.650
2.063
0.645 × 24 RH
0.500
0.438
0.344
3PO
1
0.599
2.063
0.500 × 24 RH
0.375
0.313
0.266
3S
1
1.000
4.594
0.995 × 20 RH
0.750
0.656
0.531
3SC
1
0.350
1.578
0.293 × 36 RH
0.188
0.156
0.125
3SS
1
0.589
2.125
0.515 × 26 RH
0.375
0.313
0.266
4C
1
0.950
3.000
0.938 × 20 RH
0.750
0.656
0.531
4NS
1
0.826
3.500
0.800 × 20 RH
0.625
0.531
0.438
4OS
1
0.750
2.781
0.660 × 20 RH
0.500
0.438
0.344
4PN
1
1.000
2.906
0.995 × 16 RH
0.750
0.656
0.531
4S
1
0.998
3.250
0.982 × 20 RH
0.750
0.656
0.531
5C
1
1.250
3.281
1.238 × 20 RHa
1.063
0.906
0.750
5M
5
1.438
3.438
1.238 × 20 RH
0.875
0.750
0.625
5NS
1
1.062
4.219
1.050 × 20 RH
0.875
0.750
0.625
5OS
1
3.500
3.406
0.937 × 18 RH
0.750
0.641
0.516
5P
1
0.812
3.687
0.807 × 24 RH
0.625
0.531
0.438
5PN
1
1.312
3.406
1.307 × 16 RH
1.000
0.875
0.719
5SC
1
0.600
2.438
0.500 × 26 RH
0.375
0.328
0.266
5ST
1
1.250
3.281
1.238 × 20 RH
1.063
0.906
0.750
5V
1
0.850
3.875
0.775 × 18 RH
0.563
0.484
0.391
6H
1
1.375
4.750
1.300 × 10 RH
1.125
0.969
0.797
6K
1
0.842
3.000
0.762 × 26 RH
0.625
0.531
0.438
6L
1
1.250
4.438
1.178 × 20 RH
1.000
0.875
0.719
6NS
1
1.312
5.906
1.234 × 14 RH
1.000
0.859
0.703
6R
1
1.375
4.938
1.300 × 20 RH
1.125
0.969
0.781
7B
4
7 B&S
3.125
0.375 × 16 RH
0.500
0.406
0.344
7 B&S
4
7 B&S
2.875
0.375 × 16 RH
0.500
0.406
0.344
7P
1
1.125
4.750
1.120 × 20 RH
0.875
0.750
0.625
7R
6
1.062
3.500
None
0.875
0.750
0.625
8H
1
1.500
4.750
1.425 × 20 RH
1.250
1.063
0.875
8ST
1
2.375
5.906
2.354 × 12 RH
2.125
1.844
1.500
8WN
1
1.250
3.875
1.245 × 16 RH
1.000
0.875
0.719
9B
4
9 B&S
4.125
0.500 × 13 RH
0.750
0.641
0.531
10L
1
1.562
5.500
1.490 × 18 RH
1.250
1.063
0.875
10P
1
1.500
4.750
1.495 × 20 RH
1.250
1.063
0.875
16C
1
1.889
4.516
1.875 × 1.75 mm RHb
1.625
1.406
1.141
20W
1
0.787
2.719
0.775 × 6–1 cm
0.563
0.484
0.391
22J
1
2.562
4.000
2.550 × 18 RH
2.250
1.938
1.563
32S
1
0.703
2.563
0.690 × 24 RH
0.500
0.438
0.344
35J
1
3.875
5.000
3.861 × 18 RH
3.500
3.000
2.438
42S
1
1.250
3.688
1.236 × 20 RH
1.000
0.875
0.719
50V
8
1.250
4.000
1.125 × 24 RH
0.938
0.813
0.656
52SC
1
0.800
3.688
0.795 × 20 RH
0.625
0.531
0.438
115
1
1.344
3.500
1.307 × 20 LH
1.125
0.969
0.797
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition COLLETS
947
Collets for Lathes, Mills, Grinders, and Fixtures (Continued) Dimensions Collet
Max. Capacity (inches)
Style
Bearing Diam., A
Length, B
Thread, C
Round
Hex
215
1
2.030
4.750
1.990 × 18 LH
1.750
1.500
Square 1.219
315
1
3.687
5.500
3.622 × 16 LH
3.250
2.813
2.250
B3
7
0.650
3.031
0.437 × 20 RH
0.500
0.438
0.344
D5
7
0.780
3.031
0.500 × 20 RH
0.625
0.531
0.438
GTM
7
0.625
2.437
0.437 × 20 RH
0.500
0.438
0.344
J&L
9
0.999
4.375
None
0.750
0.641
0.516
JC
8
1.360
4.000
None
1.188
1.000
0.813
LB
10
0.687
2.000
None
0.500
0.438
0.344
RO
11
1.250
2.938
0.875 × 16 RH
1.125
0.969
0.781
RO
12
1.250
4.437
0.875 × 16 RH
0.800
0.688
0.563
RO
12
1.250
4.437
0.875 × 16 RH
1.125
0.969
0.781
RO
11
1.250
2.938
0.875 × 16 RH
0.800
0.688
0.563
R8
7
0.950
4.000
0.437 × 20 RH
0.750
0.641
0.531
a Internal stop thread is 1.041 × 24 RH.
b Internal stop thread is 1.687 × 20 RH.
Dimensions in inches unless otherwise noted. Courtesy of Hardinge Brothers, Inc.
DIN 6388, Type B, and DIN 6499, ER Type Collets 30 C A B
Collet Standard Type B, DIN 6388
ER Type, DIN 6499
A B
L
L
ER Type
Type B Dimensions
Type
B (mm)
A (mm)
C
16
25.50
40
4.5–16
…
20
29.80
45
5.5–20
…
25
35.05
52
5.5–25
…
32
43.70
60
9.5–32
…
13.5
0.5–5
8°
ERA8
8.50
L (mm)
ERA11
11.50
18
0.5–7
8°
ERA16
17
27
0.5–10
8°
ERA20
21
31
0.5–13
8°
ERA25
26
35
0.5–16
8°
ERA32
33
40
2–20
8°
41
46
3–26
8°
41
39
26–30
8°
52
60
5–34
8°
ERA40 ERA50
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 948
PORTABLE GRINDING TOOLS
ARBORS, CHUCKS, AND SPINDLES Portable Tool Spindles Circular Saw Arbors.—ANSI Standard B107.4-1982 “Driving and Spindle Ends for Portable Hand, Air, and Air Electric Tools” calls for a round arbor of 5⁄8-inch diameter for nominal saw blade diameters of 6 to 8.5 inches, inclusive, and a 3⁄4-inch diameter round arbor for saw blade diameters of 9 to 12 inches, inclusive. Spindles for Geared Chucks.—Recommended threaded and tapered spindles for portable tool geared chucks of various sizes are as given in the following table: Recommended Spindle Sizes Recommended Spindles
Chuck Sizes, Inch 3⁄ and 1⁄ Light 16 4 1⁄ and 5⁄ Medium 4 16 3⁄ Light 8 3⁄ Medium 8 1⁄ Light 2 1⁄ Medium 2 5⁄ and 3⁄ Medium 8 4
3⁄ –24 8 3⁄ –24 8 3⁄ –24 8 1⁄ –20 2 1⁄ –20 2 5⁄ –16 8 5⁄ –16 8
Threaded
Tapera
or 1⁄2–20
2 Short
or 1⁄2 –20
2
1
or 5⁄8 –16
2
or 5⁄8 –16
33
or 3⁄4 –16
6
or 3⁄4 –16
3
a Jacobs number.
Vertical and Angle Portable Tool Grinder Spindles.—The 5⁄8–11 spindle with a length of 11⁄8 inches shown on page 950 is designed to permit the use of a jam nut with threaded cup wheels. When a revolving guard is used, the length of the spindle is measured from the wheel bearing surface of the guard. For unthreaded wheels with a 7⁄8-inch hole, a safety sleeve nut is recommended. The unthreaded wheel with 5⁄8-inch hole is not recommended because a jam nut alone may not resist the inertia effect when motor power is cut off. Straight Grinding Wheel Spindles for Portable Tools.—Portable grinders with pneumatic or induction electric motors should be designed for the use of organic bond wheels rated 9500 feet per minute. Light-duty electric grinders may be designed for vitrified wheels rated 6500 feet per minute. Recommended maximum sizes of wheels of both types are as given in the following table: Recommended Maximum Grinding Wheel Sizes for Portable Tools Maximum Wheel Dimensions 9500 fpm 6500 fpm Diameter Thickness Diameter Thickness D T D T
Spindle Size 3⁄ -24 × 11⁄ 8 8 1⁄ –13 × 13⁄ 2 4 5⁄ –11 × 21⁄ 8 8 5⁄ –11 × 31⁄ 8 8 5⁄ –11 × 31⁄ 8 8 3⁄ –10 × 31⁄ 4 4
21⁄2 4
1⁄ 2 3⁄ 4
8
1
8
1
6
2
…
…
8
11⁄2
…
…
8
2
…
…
4 5
1⁄ 2 3⁄ 4
Minimum T with the first three spindles is about 1⁄8 inch to accommodate cutting off wheels. Flanges are assumed to be according to ANSI B7.1 and threads to ANSI B1.1.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition PORTABLE TOOL SPINDLES
949
American Standard Square Drives for Portable Air and Electric Tools ASA B5.38-1958
DESIGN A
DESIGN B Male End
AM
CM
DM
Drive Size
Desig n.
Max.
Min.
BM Max.
Max.
Min.
Max.
Min.
EM Min.
FM Max.
RM Max.
1⁄ 4
A
0.252
0.247
0.330
0.312
0.265
0.165
0.153
…
0.078
0.015
3⁄ 8
A
0.377
0.372
0.500
0.438
0.406
0.227
0.215
…
0.156
0.031
1⁄ 2
A
0.502
0.497
0.665
0.625
0.531
0.321
0.309
…
0.187
0.031
5⁄ 8
A
0.627
0.622
0.834
0.656
0.594
0.321
0.309
…
0.187
0.047
3⁄ 4
B B B
0.752 1.002 1.503
0.747 0.997 1.498
1.000 1.340 1.968
0.938 1.125 1.625
0.750 1.000 1.562
0.415 0.602 0.653
0.403 0.590 0.641
0.216 0.234 0.310
… … …
0.047 0.063 0.094
1 11⁄2
DESIGN A
DESIGN B Female End
Drive Size 1⁄ 4 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4
1 11⁄2
AF
DF
Design
Max.
Min.
BF Min.
Max.
Min.
EF Min.
RF Max.
A
0.258
0.253
0.335
0.159
0.147
0.090
…
A
0.383
0.378
0.505
0.221
0.209
0.170
…
A
0.508
0.503
0.670
0.315
0.303
0.201
…
A
0.633
0.628
0.839
0.315
0.303
0.201
…
B B B
0.758 1.009 1.510
0.753 1.004 1.505
1.005 1.350 1.983
0.409 0.596 0.647
0.397 0.584 0.635
0.216 0.234 0.310
0.047 0.062 0.125
All dimensions in inches. Incorporating fillet radius (RM) at shoulder of male tang precludes use of minimum diameter crosshole in socket (EF), unless female drive end is chamfered (shown as optional). If female drive end is not chamfered, socket cross-hole diameter (EF) is increased to compensate for fillet radius RM, max. Minimum clearance across flats male to female is 0.001 inch through 3⁄4-inch size; 0.002 inch in 1and 11⁄2-inch sizes. For impact wrenches AM should be held as close to maximum as practical. CF, min. for both designs A and B should be equal to CM, max.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 950
PORTABLE TOOL SPINDLES American Standard Threaded and Tapered Spindles for Portable Air and Electric Tools ASA B5.38-1958
Taper Spindle (Jacobs)
Threaded Spindle Nom. Dia. and Thd.
Max.
Min.
R
L
3⁄ –24 8
0.3479
0.3455
1⁄ 16
9⁄ c 16 9⁄ 16
1⁄ –20 2
0.4675
0.4649
1⁄ 16
5⁄ –16 8
0.5844
0.5812
3⁄ 32
11⁄ 16
0.7062
3⁄ 32
11⁄ 16
3⁄ –16 4
Master Plug Gage
Pitch Dia.
0.7094
EG
DG
DM
LM
1
0.335-0.333
0.656
0.38400 0.33341 0.65625
0.92508
2Sd 2 33 6 3
0.490-0.488 0.490-0.488 0.563-0.561 0.626-0.624 0.748-0.746
0.750 0.875 1.000 1.000 1.219
0.54880 0.55900 0.62401 0.67600 0.81100
0.97861 0.97861 0.76194 0.62292 0.63898
0.48764 0.48764 0.56051 0.62409 0.74610
LG
Taper per Footb
No.a
0.7500 0.87500 1.000 1.000 1.21875
a Jacobs taper number. b Calculated from E
G, DG, LG for the master plug gage. c Also 7⁄ inch. 16 d 2S stands for 2 Short.
All dimensions in inches. Threads are per inch and right-hand. Tolerances: On R, plus or minus 1⁄64 inch; on L, plus 0.000, minus 0.030 inch.
American Standard Abrasion Tool Spindles for Portable Air and Electric Tools ASA B5.38-1958 Sanders and Polishers
Vertical and Angle Grinders
With Revolving Cup Guard
Stationary Guard
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition PORTABLE TOOL SPINDLES
951
American Standard Abrasion Tool Spindles for Portable Air and Electric Tools ASA B5.38-1958 (Continued) Straight Wheel Grinders
Cone Wheel Grinders
H
R
3⁄ –24 UNF-2A 8 1⁄ –13 UNC-2A 2 5⁄ –11 UNC-2A 8 5⁄ –11 UNC-2A 8 3⁄ –10 UNC-2A 4
1⁄ 4 3⁄ 8 1⁄ 2
L 11⁄8 13⁄4 21⁄8
1
31⁄8
1
31⁄4
D
L
3⁄ –24 UNF-2A 8 1⁄ –13 UNC-2A 2 5⁄ –11 UNC-2A 8
9⁄ 16 11⁄ 16 15⁄ 16
All dimensions in inches. Threads are right-hand.
American Standard Hexagonal Chucks and Shanks for Portable Air and Electric Tools ASA B5.38-1958
H
H
Nominal Hexagon
Min.
Max.
B
L Max.
Nominal Hexagon
Min.
Max.
B
L Max.
1⁄ 4
0.253
0.255
3⁄ 8
15⁄ 16
5⁄ 8
0.630
0.632
11⁄ 32
15⁄8
5⁄ 16
0.314
0.316
13⁄ 64
1
3⁄ 4
0.755
0.758
11⁄ 32
17⁄8
7⁄ 16
0.442
0.444
17⁄ 64
11⁄8
…
…
…
…
…
Shanks
All dimensions in inches. Tolerances on B is plus or minus 0.005 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 952
MOUNTED WHEELS AND POINTS Mounted Wheels and Mounted Points
These wheels and points are used in hard-to-get-at places and are available with a vitrified bond. The wheels are available with aluminum oxide or silicon carbide abrasive grains. The aluminum oxide wheels are used to grind tough and tempered die steels and the silicon carbide wheels, cast iron, chilled iron, bronze, and other non-ferrous metals. The illustrations on pages 952 and 953 give the standard shapes of mounted wheels and points as published by the Grinding Wheel Institute. A note about the maximum operating speed for these wheels is given at the bottom of the first page of illustrations. Metric sizes are given on page 954.
5′′ 8
1′′ 4
1′′ 2
B 41 1′′ 8
B 43
B 44
B 71
B 81
B 52 1′′ 4
B 91
11′′ 16
B 53
5′′ 16
3′′ 4
B 97 3′′ 8
1′′ 2
5′′ 8 11′′ 16
1′′ 8
B 96 1′′ 2
B 61
3′′ 8
1′′ 4
1′′ 8
B 92 3′′ 8
5′′ 16
B 101 1′′ 8
3′′ 16
3′′ 8
3′′ 16
B 103
B 104 3′′ 8
B 111
B 112
1′′ 4
3′′ 8
B 121 B 122 B 123 B 124 D
D
1′′ 2
1′′ 2
B 132
3′′ 8
B 133
T
1′′ 2
B 135
D
D T
B 131
5′′ 8
5′′ 16
1′′ 2 1′′ 4
7′′ 16
1′′ 2
B 51
5′′ 8 3′′ 16
5′′ 8
3′′ 8
3′′ 4
5′′ 8
3′′ 4
7′′ 32
1′′ 2
B 62
3′′ 4
7′′ 16
B 42 3′′ 8
3′′ 8
5′′ 16
3′′ 4
5′′ 8
T T
Group W
Fig. 1a. Standard Shapes and Sizes of Mounted Wheels and Points ANSI B74.2-1982 See Table 1 for inch sizes of Group W shapes, and for metric sizes for all shapes
The maximum speeds of mounted vitrified wheels and points of average grade range from about 38,000 to 152,000 rpm for diameters of 1 inch down to 1⁄4 inch. However, the safe operating speed usually is limited by the critical speed (speed at which vibration or whip tends to become excessive) which varies according to wheel or point dimensions, spindle diameter, and overhang.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 953
3′′ 4
1′′ A4
A5
A 12
A 13
1 1′′ 8
11′′ 16
1′′
1′′ 4
A 14
A 11 3′′ 4
7′′ 8
1 1′′ 8
2 1′′ 2 11′′ 16
7′′ 8
3′′ 4
A3
1′′ 116
A1
1 1′′ 4
1′′
3′′ 4
1 1′′ 8
1 1′′ 4
2′′
2 1′′ 2
2 3′′ 4
MOUNTED WHEELS AND POINTS
1′′ 4
1′′ A 15
A 21
A 23
A 24
1 3′′ 8 3′′ 8 5′′ 8
1′′
1′′
5′′ 8
1 1′′ 2
1′′ A 32
A 31
A 34
1′′ 4
3′′ 4
1′′ 3′′ 8
3′′ 8
1′′ 1 5′′ 8
3′′ 4
A 26
A 25
1 3′′ 8
1′′ A 35
A 36
A 37
A 38
A 39
Fig. 1b. Standard Shapes and Sizes of Mounted Wheels and Points ANSI B74.2-1982
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 954
MOUNTED WHEELS AND POINTS Table 1. Shapes and Sizes of Mounted Wheels and Points ANSI B74.2-1982 Abrasive Shape
Abrasive Shape Size Diameter Thickness mm mm
No.a
A1 A3 A4 A5 A 11 A 12 A 13 A 14 A 15 A 21 A 23 B 41 B 42 B 43 B 44 B 51 B 52 B 53 B 61 B 62 B 71 B 81 B 91 B 92 B 96
20 22 30 20 21 18 25 18 6 25 20 16 13 6 5.6 11 10 8 20 13 16 20 13 6 3
65 70 30 28 45 30 25 22 25 25 25 16 20 8 10 20 20 16 8 10 3 5 16 6 6
Abrasive Shape Size T D mm inch
Abrasive Shape No.a
D mm
W 144
3
6
W 145
3
10
W 146
3
13
W 152
5
6
W 153
5
10
W 154
5
13
W 158
6
3
W 160
6
6
W 162
6
10
W 163
6
13
W 164
6
20
W 174
10
6
W 175
10
10
W 176
10
13
W 177
10
20
W 178
10
25
W 179
10
30
W 181
13
1.5
W 182
13
3
W 183
13
6
W 184
13
10
W 185
13
13
W 186
13
20
W 187
13
25
W 188
13
40
W 189
13
50
W 195
16
20
a See shape diagrams in Figs. 1a
1⁄ 8 1⁄ 8 1⁄ 8 3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 3⁄ 8 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 1⁄ 2 5⁄ 8
Abrasive Shape
Abrasive Shape Size Diameter Thickness mm mm
No.a
A 24 A 25 A 26 A 31 A 32 A 34 A 35 A 36 A 37 A 38 A 39 B 97 B 101 B 103 B 104 B 111 B 112 B 121 B 122 B 123 B 124 B 131 B 132 B 133 B 135
6 25 16 35 25 38 25 40 30 25 20 3 16 16 8 11 10 13 10 5 3 13 10 10 6
20 … … 26 20 10 10 10 6 25 20 10 18 5 10 18 13 … … … … 13 13 10 13
Abrasive Shape Size T D mm inch
T inch
Abrasive Shape No.a
D mm
1⁄ 4 3⁄ 8 1⁄ 2 1⁄ 4 3⁄ 8 1⁄ 2 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4
W 196
16
26
W 197
16
50
W 200
20
3
W 201
20
6
W 202
20
10
W 203
20
13
W 204
20
20
W 205
20
25
W 207
20
40
W 208
20
50
5⁄ 8 5⁄ 8 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4 3⁄ 4
W 215
25
3
1
W 216
25
6
1
W 217
25
10
1
W 218
25
13
1
W 220
25
25
1
1
1
W 221
25
40
1
11⁄2
11⁄4
W 222
25
50
1
2
1⁄ 16 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4
W 225
30
6
11⁄4
W 226
30
10
11⁄4
W 228
30
20
11⁄4
W 230
30
30
11⁄4
1⁄ 4 3⁄ 8 3⁄ 4 1 1 ⁄4
W 232
30
50
11⁄4
2
W 235
40
6
11⁄2
1
W 236
40
13
1⁄ 4 1⁄ 2
11⁄2
W 237
40
25
2
W 238
40
40
11⁄2 11⁄2 11⁄2
11⁄2
3⁄ 4
W 242
50
25
2
1
and 1b on pages 952 and 953.
Copyright 2004, Industrial Press, Inc., New York, NY
T inch 1 2 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 3⁄ 4
1 11⁄2 2 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2
1
Machinery's Handbook 27th Edition BROACHES AND BROACHING
955
BROACHES AND BROACHING The Broaching Process The broaching process may be applied in machining holes or other internal surfaces and also to many flat or other external surfaces. Internal broaching is applied in forming either symmetrical or irregular holes, grooves, or slots in machine parts, especially when the size or shape of the opening, or its length in proportion to diameter or width, make other machining processes impracticable. Broaching originally was utilized for such work as cutting keyways, machining round holes into square, hexagonal, or other shapes, forming splined holes, and for a large variety of other internal operations. The development of broaching machines and broaches finally resulted in extensive application of the process to external, flat, and other surfaces. Most external or surface broaching is done on machines of vertical design, but horizontal machines are also used for some classes of work. The broaching process is very rapid, accurate, and it leaves a finish of good quality. It is employed extensively in automotive and other plants where duplicate parts must be produced in large quantities and for dimensions within small tolerances. Types of Broaches.—A number of typical broaches and the operations for which they are intended are shown by the diagrams, Fig. 1. Broach A produces a round-cornered, square hole. Prior to broaching square holes, it is usually the practice to drill a round hole having a diameter d somewhat larger than the width of the square. Hence, the sides are not completely finished, but this unfinished part is not objectionable in most cases. In fact, this clearance space is an advantage during the broaching operation in that it serves as a channel for the broaching lubricant; moreover, the broach has less metal to remove. Broach B is for finishing round holes. Broaching is superior to reaming for some classes of work, because the broach will hold its size for a much longer period, thus insuring greater accuracy. Broaches C and D are for cutting single and double keyways, respectively. Broach C is of rectangular section and, when in use, slides through a guiding bushing which is inserted in the hole. Broach E is for forming four integral splines in a hub. The broach at F is for producing hexagonal holes. Rectangular holes are finished by broach G. The teeth on the sides of this broach are inclined in opposite directions, which has the following advantages: The broach is stronger than it would be if the teeth were opposite and parallel to each other; thin work cannot drop between the inclined teeth, as it tends to do when the teeth are at right angles, because at least two teeth are always cutting; the inclination in opposite directions neutralizes the lateral thrust. The teeth on the edges are staggered, the teeth on one side being midway between the teeth on the other edge, as shown by the dotted line. A double cut broach is shown at H. This type is for finishing, simultaneously, both sides f of a slot, and for similar work. Broach I is the style used for forming the teeth in internal gears. It is practically a series of gear-shaped cutters, the outside diameters of which gradually increase toward the finishing end of the broach, Broach J is for round holes but differs from style B in that it has a continuous helical cutting edge. Some prefer this form because it gives a shearing cut. Broach K is for cutting a series of helical grooves in a hub or bushing. In helical broaching, either the work or the broach is rotated to form the helical grooves as the broach is pulled through. In addition to the typical broaches shown in Fig. 1, many special designs are now in use for performing more complex operations. Two surfaces on opposite sides of a casting or forging are sometimes machined simultaneously by twin broaches and, in other cases, three or four broaches are drawn through a part at the same time, for finishing as many duplicate holes or surfaces. Notable developments have been made in the design of broaches for external or “surface” broaching. Burnishing Broach: This is a broach having teeth or projections which are rounded on the top instead of being provided with a cutting edge, as in the ordinary type of broach. The teeth are highly polished, the tool being used for broaching bearings and for operations on
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 956
BROACHING
Fig. 1. Types of Broaches
other classes of work where the metal is relatively soft. The tool compresses the metal, thus making the surface hard and smooth. The amount of metal that can be displaced by a smooth-toothed burnishing broach is about the same as that removed by reaming. Such broaches are primarily intended for use on babbitt, white metal, and brass, but may also be satisfactorily used for producing a glazed surface on cast iron. This type of broach is also used when it is only required to accurately size a hole. Pitch of Broach Teeth.—The pitch of broach teeth depends upon the depth of cut or chip thickness, length of cut, the cutting force required and power of the broaching machine. In the pitch formulas which follow L =length, in inches, of layer to be removed by broaching d =depth of cut per tooth as shown by Table 1 (For internal broaches, d = depth of cut as measured on one side of broach or one-half difference in diameters of successive teeth in case of a round broach) F =a factor. (For brittle types of material, F = 3 or 4 for roughing teeth, and 6 for finishing teeth. For ductile types of material, F = 4 to 7 for roughing teeth and 8 for finishing teeth.) b =width of inches, of layer to be removed by broaching P =pressure required in tons per square inch, of an area equal to depth of cut times width of cut, in inches (Table 2) T =usable capacity, in tons, of broaching machine = 70% of maximum tonnage
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition BROACHING
957
Table 1. Designing Data for Surface Broaches Depth of Cut per Tooth, Inch Material to be Broached Steel, High Tensile Strength Steel, Medium Tensile Strength Cast Steel Malleable Iron Cast Iron, Soft Cast Iron, Hard Zinc Die Castings Cast Bronze Wrought Aluminum Alloys Cast Aluminum Alloys Magnesium Die Castings
Roughinga 0.0015–0.002 0.0025–0.005 0.0025–0.005 0.0025–0.005 0.006 –0.010 0.003 –0.005 0.005 –0.010 0.010 –0.025
Finishing 0.0005 0.0005 0.0005 0.0005 0.0005 0.0005 0.0010 0.0005
Face Angle or Rake, Degrees 10–12 14–18 10 7 10–15 5 12b 8
0.005 –0.010 0.005 –0.010 0.010 –0.015
0.0010 0.0010 0.0010
15b 12b 20b
Clearance Angle, Degrees Roughing Finishing 1.5–3 0.5–1 1.5–3 0.5–1 1.53 0.5 1.5–3 0.5 1.5–3 0.5 1.5–3 0.5 5 2 0 0 3 3 3
1 1 1
a The lower depth-of-cut values for roughing are recommended when work is not very rigid, the tolerance is small, a good finish is required, or length of cut is comparatively short. b In broaching these materials, smooth surfaces for tooth and chip spaces are especially recommended.
Table 2. Broaching Pressure P for Use in Pitch Formula (2)
Material to be Broached Steel, High Ten. Strength Steel, Med. Ten. Strength Cast Steel Malleable Iron Cast Iron Cast Brass Brass, Hot Pressed Zinc Die Castings Cast Bronze Wrought Aluminum Cast Aluminum Magnesium Alloy
Depth d of Cut per Tooth, Inch 0.024 0.010 0.004 0.002 0.001 Pressure P in Tons per Square Inch … … … 250 312 … … 158 185 243 … … 128 158 … … … 108 128 … … 115 115 143 … … 50 50 … … … 85 85 … … … 70 70 … … 35 35 … … … … 70 70 … … … 85 85 … … 35 35 … … …
Pressure P, Side-cutting Broaches 200-.004″cut 143-.006″cut 115-.006″ cut 100-.006″ cut 115-.020″ cut ............ ............ ............ ............ ............ ............ ............
The minimum pitch shown by Formula (1) is based upon the receiving capacity of the chip space. The minimum, however, should not be less than 0.2 inch unless a smaller pitch is required for exceptionally short cuts to provide at least two teeth in contact simultaneously, with the part being broached. A reduction below 0.2 inch is seldom required in surface broaching but it may be necessary in connection with internal broaching. Minimum pitch = 3 LdF
(1)
Whether the minimum pitch may be used or not depends upon the power of the available machine. The factor F in the formula provides for the increase in volume as the material is broached into chips. If a broach has adjustable inserts for the finishing teeth, the pitch of the finishing teeth may be smaller than the pitch of the roughing teeth because of the smaller depth d of the cut. The higher value of F for finishing teeth prevents the pitch from becoming too small, so that the spirally curled chips will not be crowded into too small a space.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 958
BROACHING
The pitch of the roughing and finishing teeth should be equal for broaches without separate inserts (notwithstanding the different values of d and F) so that some of the finishing teeth may be ground into roughing teeth after wear makes this necessary. Allowable pitch = dLbP -------------T
(2)
If the pitch obtained by Formula (2) is larger than the minimum obtained by Formula (1), this larger value should be used because it is based upon the usable power of the machine. As the notation indicates, 70 per cent of the maximum tonnage T is taken as the usable capacity. The 30 per cent reduction is to provide a margin for the increase in broaching load resulting from the gradual dulling of the cutting edges. The procedure in calculating both minimum and allowable pitches will be illustrated by an example. Example:Determine pitch of broach for cast iron when L = 9 inches; d = 0.004; and F = 4. Minimum pitch = 3 9 × 0.004 × 4 = 1.14 Next, apply Formula (2). Assume that b = 3 and T = 10; for cast iron and depth d of 0.004, P = 115 (Table 2). Then, 0.004 × 9 × 3 × 115 Allowable pitch = ----------------------------------------------- = 1.24 10 This pitch is safely above the minimum. If in this case the usable tonnage of an available machine were, say, 8 tons instead of 10 tons, the pitch as shown by Formula (2) might be increased to about 1.5 inches, thus reducing the number of teeth cutting simultaneously and, consequently, the load on the machine; or the cut per tooth might be reduced instead of increasing the pitch, especially if only a few teeth are in cutting contact, as might be the case with a short length of cut. If the usable tonnage in the preceding example were, say, 15, then a pitch of 0.84 would be obtained by Formula (2); hence the pitch in this case should not be less than the minimum of approximately 1.14 inches. Depth of Cut per Tooth.—The term “depth of cut” as applied to surface or external broaches means the difference in the heights of successive teeth. This term, as applied to internal broaches for round, hexagonal or other holes, may indicate the total increase in the diameter of successive teeth; however, to avoid confusion, the term as here used means in all cases and regardless of the type of broach, the depth of cut as measured on one side. In broaching free cutting steel, the Broaching Tool Institute recommends 0.003 to 0.006 inch depth of cut for surface broaching; 0.002 to 0.003 inch for multispline broaching; and 0.0007 to 0.0015 inch for round hole broaching. The accompanying table contains data from a German source and applies specifically to surface broaches. All data relating to depth of cut are intended as a general guide only. While depth of cut is based primarily upon the machinability of the material, some reduction from the depth thus established may be required particularly when the work supporting fixture in surface broaching is not sufficiently rigid to resist the thrust from the broaching operation. In some cases, the pitch and cutting length may be increased to reduce the thrust force. Another possible remedy in surface broaching certain classes of work is to use a side-cutting broach instead of the ordinary depth cutting type. A broach designed for side cutting takes relatively deep narrow cuts which extend nearly to the full depth required. The side cutting section is followed by teeth arranged for depth cutting to obtain the required size and surface finish on the work. In general, small tolerances in surface broaching require a reduced cut per tooth to minimize work deflection resulting from the pressure of the cut. See Cutting Speed for Broaching starting on page 1074 for broaching speeds.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition BROACHING
959
Terms Commonly Used in Broach Design
Face Angle or Rake.—The face angle (see diagram) of broach teeth affects the chip flow and varies considerably for different materials. While there are some variations in practice, even for the same material, the angles given in the accompanying table are believed to represent commonly used values. Some broach designers increase the rake angle for finishing teeth in order to improve the finish on the work. Clearance Angle.—The clearance angle (see illustration) for roughing steel varies from 1.5 to 3 degrees and for finishing steel from 0.5 to 1 degree. Some recommend the same clearance angles for cast iron and others, larger clearance angles varying from 2 to 4 or 5 degrees. Additional data will be found in Table 1. Land Width.—The width of the land usually is about 0.25 × pitch. It varies, however, from about one-fourth to one-third of the pitch. The land width is selected so as to obtain the proper balance between tooth strength and chip space. Depth of Broach Teeth.—The tooth depth as established experimentally and on the basis of experience, usually varies from about 0.37 to 0.40 of the pitch. This depth is measured radially from the cutting edge to the bottom of the tooth fillet. Radius of Tooth Fillet.—The “gullet” or bottom of the chip space between the teeth should have a rounded fillet to strengthen the broach, facilitate curling of the chips, and safeguard against cracking in connection with the hardening operation. One rule is to make the radius equal to one-fourth the pitch. Another is to make it equal 0.4 to 0.6 the tooth depth. A third method preferred by some broach designers is to make the radius equal onethird of the sum obtained by adding together the land width, one-half the tooth depth, and one-fourth of the pitch. Total Length of Broach.—After the depth of cut per tooth has been determined, the total amount of material to be removed by a broach is divided by this decimal to ascertain the number of cutting teeth required. This number of teeth multiplied by the pitch gives the length of the active portion of the broach. By adding to this dimension the distance over three or four straight teeth, the length of a pilot to be provided at the finishing end of the broach, and the length of a shank which must project through the work and the faceplate of the machine to the draw-head, the overall length of the broach is found. This calculated length is often greater than the stroke of the machine, or greater than is practical for a broach of the diameter required. In such cases, a set of broaches must be used. Chip Breakers.—The teeth of broaches frequently have rounded chip-breaking grooves located at intervals along the cutting edges. These grooves break up wide curling chips and prevent them from clogging the chip spaces, thus reducing the cutting pressure and strain on the broach. These chip-breaking grooves are on the roughing teeth only. They are staggered and applied to both round and flat or surface broaches. The grooves are formed by a round edged grinding wheel and usually vary in width from about 1⁄32 to 3⁄32 inch depending upon the size of broach. The more ductile the material, the wider the chip breaker grooves should be and the smaller the distance between them. Narrow slotting broaches may have the right- and left-hand corners of alternate teeth beveled to obtain chip-breaking action.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 960
BROACHING
Shear Angle.—The teeth of surface broaches ordinarily are inclined so they are not at right angles to the broaching movement. The object of this inclination is to obtain a shearing cut which results in smoother cutting action and an improvement in surface finish. The shearing cut also tends to eliminate troublesome vibration. Shear angles for surface broaches are not suitable for broaching slots or any profiles that resist the outward movement of the chips. When the teeth are inclined, the fixture should be designed to resist the resulting thrusts unless it is practicable to incline the teeth of right- and left-hand sections in opposite directions to neutralize the thrust. The shear angle usually varies from 10 to 25 degrees. Types of Broaching Machines.—Broaching machines may be divided into horizontal and vertical designs, and they may be classified further according to the method of operation, as, for example, whether a broach in a vertical machine is pulled up or pulled down in forcing it through the work. Horizontal machines usually pull the broach through the work in internal broaching but short rigid broaches may be pushed through. External surface broaching is also done on some machines of horizontal design, but usually vertical machines are employed for flat or other external broaching. Although parts usually are broached by traversing the broach itself, some machines are designed to hold the broach or broaches stationary during the actual broaching operation. This principle has been applied both to internal and surface broaching. Vertical Duplex Type: The vertical duplex type of surface broaching machine has two slides or rams which move in opposite directions and operate alternately. While the broach connected to one slide is moving downward on the cutting stroke, the other broach and slide is returning to the starting position, and this returning time is utilized for reloading the fixture on that side; consequently, the broaching operation is practically continuous. Each ram or slide may be equipped to perform a separate operation on the same part when two operations are required. Pull-up Type: Vertical hydraulically operated machines which pull the broach or broaches up through the work are used for internal broaching of holes of various shapes, for broaching bushings, splined holes, small internal gears, etc. A typical machine of this kind is so designed that all broach handling is done automatically. Pull-down Type: The various movements in the operating cycle of a hydraulic pulldown type of machine equipped with an automatic broach-handling slide, are the reverse of the pull-up type. The broaches for a pull-down type of machine have shanks on each end, there being an upper one for the broach-handling slide and a lower one for pulling through the work. Hydraulic Operation: Modern broaching machines, as a general rule, are operated hydraulically rather than by mechanical means. Hydraulic operation is efficient, flexible in the matter of speed adjustments, low in maintenance cost, and the “smooth” action required for fine precision finishing may be obtained. The hydraulic pressures required, which frequently are 800 to 1000 pounds per square inch, are obtained from a motor-driven pump forming part of the machine. The cutting speeds of broaching machines frequently are between 20 and 30 feet per minute, and the return speeds often are double the cutting speed, or higher, to reduce the idle period. Ball-Broaching.—Ball-broaching is a method of securing bushings, gears, or other components without the need for keys, pins, or splines. A series of axial grooves, separated by ridges, is formed in the bore of the workpiece by cold plastic deformation of the metal when a tool, having a row of three rotating balls around its periphery, is pressed through the parts. When the bushing is pressed into a broached bore, the ridges displace the softer material of the bushing into the grooves—thus securing the assembly. The balls can be made of high-carbon chromium steel or carbide, depending on the hardness of the component.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition BROACHING
961
Broaching Difficulties.—The accompanying table has been compiled from information supplied by the National Broach and Machine Co. and presents some of the common broaching difficulties, their causes and means of correction. Causes of Broaching Difficulties Broaching Difficulty
Possible Causes
Stuck broach
Insufficient machine capacity; dulled teeth; clogged chip gullets; failure of power during cutting stroke. To remove a stuck broach, workpiece and broach are removed from the machine as a unit; never try to back out broach by reversing machine. If broach does not loosen by tapping workpiece lightly and trying to slide it off its starting end, mount workpiece and broach in a lathe and turn down workpiece to the tool surface. Workpiece may be sawed longitudinally into several sections in order to free the broach. Check broach design, perhaps tooth relief (back off) angle is too small or depth of cut per tooth is too great.
Galling and pickup
Lack of homogeneity of material being broached—uneven hardness, porosity; improper or insufficient coolant; poor broach design, mutilated broach; dull broach; improperly sharpened broach; improperly designed or outworn fixtures. Good broach design will do away with possible chip build-up on tooth faces and excessive heating. Grinding of teeth should be accurate so that the correct gullet contour is maintained. Contour should be fair and smooth.
Broach breakage
Overloading; broach dullness; improper sharpening; interrupted cutting stroke; backing up broach with workpiece in fixture; allowing broach to pass entirely through guide hole; ill fitting and/or sharp edged key; crooked holes; untrue locating surface; excessive hardness of workpiece; insufficient clearance angle; sharp corners on pull end of broach. When grinding bevels on pull end of broach use wheel that is not too pointed.
Chatter
Too few teeth in cutting contact simultaneously; excessive hardness of material being broached; loose or poorly constructed tooling; surging of ram due to load variations. Chatter can be alleviated by changing the broaching speed, by using shear cutting teeth instead of right angle teeth, and by changing the coolant and the face and relief angles of the teeth.
Drifting or misalignment of tool during cutting stroke
Lack of proper alignment when broach is sharpened in grinding machine, which may be caused by dirt in the female center of the broach; inadequate support of broach during the cutting stroke, on a horizontal machine especially; body diameter too small; cutting resistance variable around I.D. of hole due to lack of symmetry of surfaces to be cut; variations in hardness around I.D. of hole; too few teeth in cutting contact.
Streaks in broached surface
Lands too wide; presence of forging, casting or annealing scale; metal pickup; presence of grinding burrs and grinding and cleaning abrasives.
Rings in the broached hole
Due to surging resulting from uniform pitch of teeth; presence of sharpening burrs on broach; tooth clearance angle too large; locating face not smooth or square; broach not supported for all cutting teeth passing through the work. The use of differential tooth spacing or shear cutting teeth helps in preventing surging. Sharpening burrs on a broach may be removed with a wood block.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 962
FILES AND BURS
FILES AND BURS Files Definitions of File Terms.—The following file terms apply to hand files but not to rotary files and burs. Axis: Imaginary line extending the entire length of a file equidistant from faces and edges. Back: The convex side of a file having the same or similar cross-section as a half-round file. Bastard Cut: A grade of file coarseness between coarse and second cut of American pattern files and rasps. Blank: A file in any process of manufacture before being cut. Blunt: A file whose cross-sectional dimensions from point to tang remain unchanged. Coarse Cut: The coarsest of all American pattern file and rasp cuts. Coarseness: Term describing the relative number of teeth per unit length, the coarsest having the least number of file teeth per unit length; the smoothest, the most. American pattern files and rasps have four degrees of coarseness: coarse, bastard, second and smooth. Swiss pattern files usually have seven degrees of coarseness: 00, 0, 1, 2, 3, 4, 6 (from coarsest to smoothest). Curved tooth files have three degrees of coarseness: standard, fine and smooth. Curved Cut: File teeth which are made in curved contour across the file blank. Cut: Term used to describe file teeth with respect to their coarseness or their character (single, double, rasp, curved, special). Double Cut: A file tooth arrangement formed by two series of cuts, namely the overcut followed, at an angle, by the upcut. Edge: Surface joining faces of a file. May have teeth or be smooth. Face: Widest cutting surface or surfaces that are used for filing. Heel or Shoulder: That portion of a file that abuts the tang. Hopped: A term used among file makers to represent a very wide skip or spacing between file teeth. Length: The distance from the heel to the point. Overcut: The first series of teeth put on a double-cut file. Point: The front end of a file; the end opposite the tang. Rasp Cut: A file tooth arrangement of round-topped teeth, usually not connected, that are formed individually by means of a narrow, punch-like tool. Re-cut: A worn-out file which has been re-cut and re-hardened after annealing and grinding off the old teeth. Safe Edge: An edge of a file that is made smooth or uncut, so that it will not injure that portion or surface of the workplace with which it may come in contact during filing. Second Cut: A grade of file coarseness between bastard and smooth of American pattern files and rasps. Set: To blunt the sharp edges or corners of file blanks before and after the overcut is made, in order to prevent weakness and breakage of the teeth along such edges or corners when the file is put to use. Shoulder or Heel: See Heel or Shoulder. Single Cut: A file tooth arrangement where the file teeth are composed of single unbroken rows of parallel teeth formed by a single series of cuts. Smooth Cut: An American pattern file and rasp cut that is smoother than second cut. Tang: The narrowed portion of a file which engages the handle. Upcut: The series of teeth superimposed on the overcut, and at an angle to it, on a doublecut file.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition FILES AND BURS
963
File Characteristics.—Files are classified according to their shape or cross-section and according to the pitch or spacing of their teeth and the nature of the cut. Cross-section and Outline: The cross-section may be quadrangular, circular, triangular, or some special shape. The outline or contour may be tapered or blunt. In the former, the point is more or less reduced in width and thickness by a gradually narrowing section that extends for one-half to two-thirds of the length. In the latter the cross-section remains uniform from tang to point. Cut: The character of the teeth is designated as single, double, rasp or curved. The single cut file (or float as the coarser cuts are sometimes called) has a single series of parallel teeth extending across the face of the file at an angle of from 45 to 85 degrees with the axis of the file. This angle depends upon the form of the file and the nature of the work for which it is intended. The single cut file is customarily used with a light pressure to produce a smooth finish. The double cut file has a multiplicity of small pointed teeth inclining toward the point of the file arranged in two series of diagonal rows that cross each other. For general work, the angle of the first series of rows is from 40 to 45 degrees and of the second from 70 to 80 degrees. For double cut finishing files the first series has an angle of about 30 degrees and the second, from 80 to 87 degrees. The second, or upcut, is almost always deeper than the first or overcut. Double cut files are usually employed, under heavier pressure, for fast metal removal and where a rougher finish is permissible. The rasp is formed by raising a series of individual rounded teeth from the surface of the file blank with a sharp narrow, punch-like cutting tool and is used with a relatively heavy pressure on soft substances for fast removal of material. The curved tooth file has teeth that are in the form of parallel arcs extending across the face of the file, the middle portion of each arc being closest to the point of the file. The teeth are usually single cut and are relatively coarse. They may be formed by steel displacement but are more commonly formed by milling. With reference to coarseness of cut the terms coarse, bastard, second and smooth cuts are used, the coarse or bastard files being used on the heavier classes of work and the second or smooth cut files for the finishing or more exacting work. These degrees of coarseness are only comparable when files of the same length are compared, as the number or teeth per inch of length decreases as the length of the file increases. The number of teeth per inch varies considerably for different sizes and shapes and for files of different makes. The coarseness range for the curved tooth files is given as standard, fine and smooth. In the case of Swiss pattern files, a series of numbers is used to designate coarseness instead of names; Nos. 00, 0, 1, 2, 3, 4 and 6 being the most common with No. 00 the coarsest and No. 6 the finest. Classes of Files.—There are five main classes of files: mill or saw files; machinists' files; curved tooth files; Swiss pattern files; and rasps. The first two classes are commonly referred to as American pattern files. Mill or Saw Files: These are used for sharpening mill or circular saws, large crosscut saws; for lathe work; for draw filing; for filing brass and bronze; and for smooth filing generally. The number identifying the following files refers to the illustration in Fig. 1 1) Cantsaw files have an obtuse isosceles triangular section, a blunt outline, are single cut and are used for sharpening saws having “M”-shaped teeth and teeth of less than 60-degree angle; 2) Crosscut files have a narrow triangular section with short side rounded, a blunt outline, are single cut and are used to sharpen crosscut saws. The rounded portion is used to deepen the gullets of saw teeth and the sides are used to sharpen the teeth themselves. ; 3) Double ender fileshave a triangular section, are tapered from the middle to both ends, are tangless are single cut and are used reversibly for sharpening saws; 4) The mill file itself, is usually single cut, tapered in width, and often has two square cutting edges in addition to the cutting sides. Either or both edges may be rounded, however, for filing the gul-
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 964
FILES AND BURS
lets of saw teeth. The blunt mill file has a uniform rectangular cross-section from tip to tang; 5) The The triangular saw files or taper saw files have an equilateral triangular section, are tapered, are single cut and are used for filing saws with 60-degree angle teeth. They come in taper, slim taper, extra slim taper and double extra slim taper thicknesses Blunt triangular and blunt hand saw files are without taper; and 6) Web saw files have a diamond-shaped section, a blunt outline, are single cut and are used for sharpening pulpwood or web saws. . Machinists' Files: These files are used throughout industry where metal must be removed rapidly and finish is of secondary importance. Except for certain exceptions in the round and half-round shapes, all are double cut. 7) Flat files have a rectangular section, are tapered in width and thickness, are cut on both sides and edges and are used for general utility work; 8) Half round files have a circular segmental section, are tapered in width and thickness, have their flat side double cut, their rounded side mostly double but sometimes single cut, and are used to file rounded holes, concave corners, etc. in general filing work; 9) Hand files are similar to flat files but taper in thickness only. One edge is uncut or “safe.”; and 10) Knife files have a “knife-blade” section, are tapered in width only, are double cut, and are used by tool and die makers on work having acute angles. Machinist's general purpose files have a rectangular section, are tapered and have single cut teeth divided by angular serrations which produce short cutting edges. These edges help stock removal but still leave a smooth finish and are suitable for use on various materials including aluminum, bronze, cast iron, malleable iron, mild steels and annealed tool steels. 11) Pillar files are similar to hand files but are thicker and not as wide; 12) Round files have a circular section, are tapered, single cut, and are generally used to file circular openings or curved surfaces; 13) Square files have a square section, are tapered, and are used for filing slots, keyways and for general surface filing where a heavier section is preferred; 14) Three square files have an equilateral triangular section and are tapered on all sides. They are double cut and have sharp corners as contrasted with taper triangular files which are single cut and have somewhat rounded corners. They are used for filing accurate internal angles, for clearing out square corners, and for filing taps and cutters; and 15) Warding files have a rectangular section, and taper in width to a narrow point. They are used for general narrow space filing. . Wood files are made in the same sections as flat and half round files but with coarser teeth especially suited for working on wood.
1
2
9
4
3
10
11
6
5
12
13
7
14
8
15
Fig. 1. Styles of Mill or Saw Files
Curved Tooth Files: Regular curved tooth files are made in both rigid and flexible forms. The rigid type has either a tang for a conventional handle or is made plain with a hole at each end for mounting in a special holder. The flexible type is furnished for use in special holders only. The curved tooth files come in standard fine and smooth cuts and in parallel
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition FILES AND BURS
965
flat, square, pillar, pillar narrow, half round and shell types. A special curved tooth file is available with teeth divided by long angular serrations. The teeth are cut in an “off center” arc. When moved across the work toward one edge of the file a fast cutting action is provided; when moved toward the other edge, a smoothing action; thus the file is made to serve a dual purpose. Swiss Pattern Files: These are used by tool and die makers, model makers and delicate instrument parts finishers. They are made to closer tolerances than the conventional American pattern files although with similar cross-sections. The points of the Swiss pattern files are smaller, the tapers are longer and they are available in much finer cuts. They are primarily finishing tools for removing burrs left from previous finishing operations truing up narrow grooves, notches and keyways, cleaning out corners and smoothing small parts. For very fine work, round and square handled needle files, available in numerous crosssectional shapes in overall lengths from 4 to 7 3⁄4 inches, are used. Die sinkers use die sinkers files and die sinkers rifflers. The files, also made in many different cross-sectional shapes, are 31⁄2 inches in length and are available in the cut Nos. 0, 1, 2, and 4. The rifflers are from 51⁄2 to 63⁄4 inches long, have cutting surfaces on either end, and come in numerous cross-sectional shapes in cut Nos. 0, 2, 3, 4 and 6. These rifflers are used by die makers for getting into corners, crevices, holes and contours of intricate dies and molds. Used in the same fashion as die sinkers rifflers, silversmiths rifflers, that have a much heavier crosssection, are available in lengths from 6 7⁄8 to 8 inches and in cuts Nos. 0, 1, 2, and 3. Blunt machine files in Cut Nos. 00, 0, and 2 for use in ordinary and bench filing machines are available in many different cross-sectional shapes, in lengths from 3 to 8 inches. Rasps: Rasps are employed for work on relatively soft substances such as wood, leather, and lead where fast removal or material is required. They come in rectangular and half round cross-sections, the latter with and without a sharp edge. Special Purpose Files: Falling under one of the preceding five classes of files, but modified to meet the requirements of some particular function, are a number of special purpose files. The long angle lathe file is used for filing work that is rotating in a lathe. The long tooth angle provides a clean shear, eliminates drag or tear and is self-clearing. This file has safe or uncut edges to protect shoulders of the work which are not to be filed. The foundry file has especially sturdy teeth with heavy set edges for the snagging of castings—the removing of fins, sprues, and other projections. The die casting file has extra strong teeth on corners and edges as well as sides for working on die castings of magnesium, zinc, or aluminum alloys. A special file for stainless steel is designed to stand up under the abrasive action of stainless steel alloys. Aluminum rasps and files are designed to eliminate clogging. A special tooth construction is used in one type of aluminum tile which breaks up the filings, allows the file to clear itself and overcomes chatter. A brass file is designed so that with a little pressure the sharp, high-cut teeth bite deep while with less pressure, their short uncut angle produces a smoothing effect. The lead float has coarse, single cut teeth at almost right angles to the file axis. These shear away the metal under ordinary pressure and produce a smoothing effect under light pressure. The shear tooth file has a coarse single cut with a long angle for soft metals or alloys, plastics, hard rubber and wood. Chain saw files are designed to sharpen all types of chain saw teeth. These files come in round, rectangular, square and diamond-shaped sections. The round and square sectioned files have either double or single cut teeth, the rectangular files have single cut teeth and the diamondshaped files have double cut teeth. Effectiveness of Rotary Files and Burs.—There it very little difference in the efficiency of rotary files or burs when used in electric tools and when used in air tools, provided the speeds have been reasonably well selected. Flexible-shaft and other machines used as a source of power for these tools have a limited number of speeds which govern the revolutions per minute at which the tools can be operated.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 966
FILES AND BURS
The carbide bur may be used on hard or soft materials with equally good results. The principle difference in construction of the carbide bur is that its teeth or flutes are provided with a negative rather than a radial rake. Carbide burs are relatively brittle, and must be treated more carefully than ordinary burs. They should be kept cutting freely, in order to prevent too much pressure, which might result in crumbling of the cutting epics. At the same speeds, both high-speed steel and carbide burs remove approximately the same amount of metal. However, when carbide burs are used at their most efficient speeds, the rate of stock removal may be as much as four times that of ordinary burs. In certain cases, speeds much higher than those shown in the table can be used. It has been demonstrated that a carbide bur will last up to 100 times as long as a high-speed steel bur of corresponding size and shape. Approximate Speeds of Rotary Files and Burs Medium Cut, High-Speed Steel Bur or File Tool Diam., Inches
Mild Steel
1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
4600
Cast Iron Bronze Aluminum Speed, Revolutions per Minute 7000 15,000 20,000
Magnesium 30,000
Carbide Bur Medium Fine Cut Cut Any Material 45,000 30,000
3450
5250
11,250
15,000
22,500
30,000
20,000
2750
4200
9000
12,000
18,000
24,000
16,000
2300
3500
7500
10,000
15,000
20,000
13,350
2000
3100
6650
8900
13,350
18,000
12,000
1900
2900
6200
8300
12,400
16,000
10,650
1700
2600
5600
7500
11,250
14,500
9650
1 11⁄8
1600 1500
2400 2300
5150 4850
6850 6500
10,300 9750
13,000 …
8650 …
11⁄4
1400
2100
4500
6000
9000
…
…
As recommended by the Nicholson File Company.
Steel Wool.—Steel wool is made by shaving thin layers of steel from wire. The wire is pulled, by special machinery built for the purpose, past cutting tools or through cutting dies which shave off chips from the outside. Steel wool consists of long, relatively strong, and resilient steel shavings having sharp edges. This characteristic renders it an excellent abrasive. The fact that the cutting characteristics of steel wool vary with the size of the fiber, which is readily controlled in manufacture, has adapted it to many applications. Metals other than steel have been made into wool by the same processes as steel, and when so manufactured have the same general characteristics. Thus wool has been made from copper, lead, aluminum, bronze, brass, monel metal, and nickel. The wire from which steel wool is made may be produced by either the Bessemer, or the basic or acid openhearth processes. It should contain from 0.10 to 0.20 per cent carbon; from 0.50 to 1.00 per cent manganese; from 0.020 to 0.090 per cent sulphur; from 0.050 to 0.120 per cent phosphorus; and from 0.001 to 0.010 per cent silicon. When drawn on a standard tensilestrength testing machine, a sample of the steel should show an ultimate strength of not less than 120,000 pounds per square inch. Steel Wool Grades Description Super Fine Extra Fine Very Fine Fine
Grade 0000 000 00 0
Fiber Thickness Inch Millimeter 0.001 0.025 0.0015 0.035 0.0018 0.04 0.002 0.05
Description Medium Medium Coarse Coarse Extra Coarse
Grade 1 2 3 4
Fiber Thickness Inch Millimeter 0.0025 0.06 0.003 0.075 0.0035 0.09 0.004 0.10
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TOOL WEAR
967
TOOL WEAR AND SHARPENING Metal cutting tools wear constantly when they are being used. A normal amount of wear should not be a cause for concern until the size of the worn region has reached the point where the tool should be replaced. Normal wear cannot be avoided and should be differentiated from abnormal tool breakage or excessively fast wear. Tool breakage and an excessive rate of wear indicate that the tool is not operating correctly and steps should be taken to correct this situation. There are several basic mechanisms that cause tool wear. It is generally understood that tools wear as a result of abrasion which is caused by hard particles of work material plowing over the surface of the tool. Wear is also caused by diffusion or alloying between the work material and the tool material. In regions where the conditions of contact are favorable, the work material reacts with the tool material causing an attrition of the tool material. The rate of this attrition is dependent upon the temperature in the region of contact and the reactivity of the tool and the work materials with each other. Diffusion or alloying also occurs where particles of the work material are welded to the surface of the tool. These welded deposits are often quite visible in the form of a built-up edge, as particles or a layer of work material inside a crater or as small mounds attached to the face of the tool. The diffusion or alloying occurring between these deposits and the tool weakens the tool material below the weld. Frequently these deposits are again rejoined to the chip by welding or they are simply broken away by the force of collision with the passing chip. When this happens, a small amount of the tool material may remain attached to the deposit and be plucked from the surface of the tool, to be carried away with the chip. This mechanism can cause chips to be broken from the cutting edge and the formation of small craters on the tool face called pull-outs. It can also contribute to the enlargement of the larger crater that sometimes forms behind the cutting edge. Among the other mechanisms that can cause tool wear are severe thermal gradients and thermal shocks, which cause cracks to form near the cutting edge, ultimately leading to tool failure. This condition can be caused by improper tool grinding procedures, heavy interrupted cuts, or by the improper application of cutting fluids when machining at high cutting speeds. Chemical reactions between the active constituents in some cutting fluids sometimes accelerate the rate of tool wear. Oxidation of the heated metal near the cutting edge also contributes to tool wear, particularly when fast cutting speeds and high cutting temperatures are encountered. Breakage of the cutting edge caused by overloading, heavy shock loads, or improper tool design is not normal wear and should be corrected. The wear mechanisms described bring about visible manifestations of wear on the tool which should be understood so that the proper corrective measures can be taken, when required. These visible signs of wear are described in the following paragraphs and the corrective measures that might be required are given in the accompanying Tool TroubleShooting Check List. The best procedure when trouble shooting is to try to correct only one condition at a time. When a correction has been made it should be checked. After one condition has been corrected, work can then start to correct the next condition. Flank Wear: Tool wear occurring on the flank of the tool below the cutting edge is called flank wear. Flank wear always takes place and cannot be avoided. It should not give rise to concern unless the rate of flank wear is too fast or the flank wear land becomes too large in size. The size of the flank wear can be measured as the distance between the top of the cutting edge and the bottom of the flank wear land. In practice, a visual estimate is usually made instead of a precise measurement, although in many instances flank wear is ignored and the tool wear is “measured” by the loss of size on the part. The best measure of tool wear, however, is flank wear. When it becomes too large, the rubbing action of the wear land against the workpiece increases and the cutting edge must be replaced. Because conditions vary, it is not possible to give an exact amount of flank wear at which the tool should be replaced. Although there are many exceptions, as a rough estimate, high-speed steel
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 968
TOOL SHARPENING
tools should be replaced when the width of the flank wear land reaches 0.005 to 0.010 inch for finish turning and 0.030 to 0.060 inch for rough turning; and for cemented carbides 0.005 to 0.010 inch for finish turning and 0.020 to 0.040 inch for rough turning. Under ideal conditions which, surprisingly, occur quite frequently, the width of the flank wear land will be very uniform along its entire length. When the depth of cut is uneven, such as when turning out-of-round stock, the bottom edge of the wear land may become somewhat slanted, the wear land being wider toward the nose. A jagged-appearing wear land usually is evidence of chipping at the cutting edge. Sometimes, only one or two sharp depressions of the lower edge of the wear land will appear, to indicate that the cutting edge has chipped above these depressions. A deep notch will sometimes occur at the “depth of cut line,” or that part of the cutting opposite the original surface of the work. This can be caused by a hard surface scale on the work, by a work-hardened surface layer on the work, or when machining high-temperature alloys. Often the size of the wear land is enlarged at the nose of the tool. This can be a sign of crater breakthrough near the nose or of chipping in this region. Under certain conditions, when machining with carbides, it can be an indication of deformation of the cutting edge in the region of the nose. When a sharp tool is first used, the initial amount of flank wear is quite large in relation to the subsequent total amount. Under normal operating conditions, the width of the flank wear land will increase at a uniform rate until it reaches a critical size after which the cutting edge breaks down completely. This is called catastrophic failure and the cutting edge should be replaced before this occurs. When cutting at slow speeds with high-speed steel tools, there may be long periods when no increase in the flank wear can be observed. For a given work material and tool material, the rate of flank wear is primarily dependent on the cutting speed and then the feed rate. Cratering: A deep crater will sometimes form on the face of the tool which is easily recognizable. The crater forms at a short distance behind the side cutting edge leaving a small shelf between the cutting edge and the edge of the crater. This shelf is sometimes covered with the built-up edge and at other times it is uncovered. Often the bottom of the crater is obscured with work material that is welded to the tool in this region. Under normal operating conditions, the crater will gradually enlarge until it breaks through a part of the cutting edge. Usually this occurs on the end cutting edge just behind the nose. When this takes place, the flank wear at the nose increases rapidly and complete tool failure follows shortly. Sometimes cratering cannot be avoided and a slow increase in the size of the crater is considered normal. However, if the rate of crater growth is rapid, leading to a short tool life, corrective measures must be taken. Cutting Edge Chipping: Small chips are sometimes broken from the cutting edge which accelerates tool wear but does not necessarily cause immediate tool failure. Chipping can be recognized by the appearance of the cutting edge and the flank wear land. A sharp depression in the lower edge of the wear land is a sign of chipping and if this edge of the wear land has a jagged appearance it indicates that a large amount of chipping has taken place. Often the vacancy or cleft in the cutting edge that results from chipping is filled up with work material that is tightly welded in place. This occurs very rapidly when chipping is caused by a built-up edge on the face of the tool. In this manner the damage to the cutting edge is healed; however, the width of the wear land below the chip is usually increased and the tool life is shortened. Deformation: Deformation occurs on carbide cutting tools when taking a very heavy cut using a slow cutting speed and a high feed rate. A large section of the cutting edge then becomes very hot and the heavy cutting pressure compresses the nose of the cutting edge, thereby lowering the face of the tool in the area of the nose. This reduces the relief under the nose, increases the width of the wear land in this region, and shortens the tool life. Surface Finish: The finish on the machined surface does not necessarily indicate poor cutting tool performance unless there is a rapid deterioration. A good surface finish is,
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Machinery's Handbook 27th Edition TOOL SHARPENING
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however, sometimes a requirement. The principal cause of a poor surface finish is the built-up edge which forms along the edge of the cutting tool. The elimination of the builtup edge will always result in an improvement of the surface finish. The most effective way to eliminate the built-up edge is to increase the cutting speed. When the cutting speed is increased beyond a certain critical cutting speed, there will be a rather sudden and large improvement in the surface finish. Cemented carbide tools can operate successfully at higher cutting speeds, where the built-up edge does not occur and where a good surface finish is obtained. Whenever possible, cemented carbide tools should be operated at cutting speeds where a good surface finish will result. There are times when such speeds are not possible. Also, high-speed tools cannot be operated at the speed where the built-up edge does not form. In these conditions the most effective method of obtaining a good surface finish is to employ a cutting fluid that has active sulphur or chlorine additives. Cutting tool materials that do not alloy readily with the work material are also effective in obtaining an improved surface finish. Straight titanium carbide and diamond are the two principal tool materials that fall into this category. The presence of feed marks can mar an otherwise good surface finish and attention must be paid to the feed rate and the nose radius of the tool if a good surface finish is desired. Changes in the tool geometry can also be helpful. A small “flat,” or secondary cutting edge, ground on the end cutting edge behind the nose will sometimes provide the desired surface finish. When the tool is in operation, the flank wear should not be allowed to become too large, particularly in the region of the nose where the finished surface is produced. Sharpening Twist Drills.—Twist drills are cutting tools designed to perform concurrently several functions, such as penetrating directly into solid material, ejecting the removed chips outside the cutting area, maintaining the essentially straight direction of the advance movement and controlling the size of the drilled hole. The geometry needed for these multiple functions is incorporated into the design of the twist drill in such a manner that it can be retained even after repeated sharpening operations. Twist drills are resharpened many times during their service life, with the practically complete restitution of their original operational characteristics. However, in order to assure all the benefits which the design of the twist drill is capable of providing, the surfaces generated in the sharpening process must agree with the original form of the tool's operating surfaces, unless a change of shape is required for use on a different work material. The principal elements of the tool geometry which are essential for the adequate cutting performance of twist drills are shown in Fig. 1. The generally used values for these dimensions are the following: Point angle: Commonly 118°, except for high strength steels, 118° to 135°; aluminum alloys, 90° to 140°; and magnesium alloys, 70° to 118°. Helix angle: Commonly 24° to 32°, except for magnesium and copper alloys, 10° to 30°. Lip relief angle: Commonly 10° to 15°, except for high strength or tough steels, 7° to 12°. The lower values of these angle ranges are used for drills of larger diameter, the higher values for the smaller diameters. For drills of diameters less than 1⁄4 inch, the lip relief angles are increased beyond the listed maximum values up to 24°. For soft and free machining materials, 12° to 18° except for diameters less than 1⁄4 inch, 20° to 26°. Relief Grinding of the Tool Flanks.—In sharpening twist drills the tool flanks containing the two cutting edges are ground. Each flank consists of a curved surface which provides the relief needed for the easy penetration and free cutting of the tool edges. In grinding the flanks, Fig. 2, the drill is swung around the axis A of an imaginary cone while resting in a support which holds the drill at one-half the point angle B with respect to the face of the grinding wheel. Feed f for stock removal is in the direction of the drill axis. The relief angle is usually measured at the periphery of the twist drill and is also specified by that value. It is not a constant but should increase toward the center of the drill.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 970
TOOL SHARPENING
The relief grinding of the flank surfaces will generate the chisel angle on the web of the twist drill. The value of that angle, typically 55°, which can be measured, for example, with the protractor of an optical projector, is indicative of the correctness of the relief grinding.
Fig. 1. The principal elements of tool geometry on twist drills.
Fig. 3. The chisel edge C after thinning the web by grinding off area T.
Fig. 2. In grinding the face of the twist drill the tool is swung around the axis A of an imaginary cone, while resting in a support tilted by half of the point angle β with respect to the face of the grinding wheel. Feed f for stock removal is in the direction of the drill axis.
Fig. 4. Split point or “crankshaft” type web thinning.
Drill Point Thinning.—The chisel edge is the least efficient operating surface element of the twist drill because it does not cut, but actually squeezes or extrudes the work material. To improve the inefficient cutting conditions caused by the chisel edge, the point width is often reduced in a drill-point thinning operation, resulting in a condition such as that shown in Fig. 3. Point thinning is particularly desirable on larger size drills and also on those which become shorter in usage, because the thickness of the web increases toward the shaft of the twist drill, thereby adding to the length of the chisel edge. The extent of point thinning is limited by the minimum strength of the web needed to avoid splitting of the drill point under the influence of cutting forces. Both sharpening operations—the relieved face grinding and the point thinning—should be carried out in special drill grinding machines or with twist drill grinding fixtures mounted on general-purpose tool grinding machines, designed to assure the essential accu-
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Machinery's Handbook 27th Edition TOOL SHARPENING
971
racy of the required tool geometry. Off-hand grinding may be used for the important web thinning when a special machine is not available; however, such operation requires skill and experience. Improperly sharpened twist drills, e.g. those with unequal edge length or asymmetrical point angle, will tend to produce holes with poor diameter and directional control. For deep holes and also drilling into stainless steel, titanium alloys, high temperature alloys, nickel alloys, very high strength materials and in some cases tool steels, split point grinding, resulting in a “crankshaft” type drill point, is recommended. In this type of pointing, see Fig. 4, the chisel edge is entirely eliminated, extending the positive rake cutting edges to the center of the drill, thereby greatly reducing the required thrust in drilling. Points on modified-point drills must be restored after sharpening to maintain their increased drilling efficiency. Sharpening Carbide Tools.—Cemented carbide indexable inserts are usually not resharpened but sometimes they require a special grind in order to form a contour on the cutting edge to suit a special purpose. Brazed type carbide cutting tools are resharpened after the cutting edge has become worn. On brazed carbide tools the cutting-edge wear should not be allowed to become excessive before the tool is re-sharpened. One method of determining when brazed carbide tools need resharpening is by periodic inspection of the flank wear and the condition of the face. Another method is to determine the amount of production which is normally obtained before excessive wear has taken place, or to determine the equivalent period of time. One disadvantage of this method is that slight variations in the work material will often cause the wear rate not to be uniform and the number of parts machined before regrinding will not be the same each time. Usually, sharpening should not require the removal of more than 0.005 to 0.010 inch of carbide. General Procedure in Carbide Tool Grinding: The general procedure depends upon the kind of grinding operation required. If the operation is to resharpen a dull tool, a diamond wheel of 100 to 120 grain size is recommended although a finer wheel—up to 150 grain size—is sometimes used to obtain a better finish. If the tool is new or is a “standard” design and changes in shape are necessary, a 100-grit diamond wheel is recommended for roughing and a finer grit diamond wheel can be used for finishing. Some shops prefer to rough grind the carbide with a vitrified silicon carbide wheel, the finish grinding being done with a diamond wheel. A final operation commonly designated as lapping may or may not be employed for obtaining an extra-fine finish. Wheel Speeds: The speed of silicon carbide wheels usually is about 5000 feet per minute. The speeds of diamond wheels generally range from 5000 to 6000 feet per minute; yet lower speeds (550 to 3000 fpm) can be effective. Offhand Grinding: In grinding single-point tools (excepting chip breakers) the common practice is to hold the tool by hand, press it against the wheel face and traverse it continuously across the wheel face while the tool is supported on the machine rest or table which is adjusted to the required angle. This is known as “offhand grinding” to distinguish it from the machine grinding of cutters as in regular cutter grinding practice. The selection of wheels adapted to carbide tool grinding is very important. Silicon Carbide Wheels.—The green colored silicon carbide wheels generally are preferred to the dark gray or gray-black variety, although the latter are sometimes used. Grain or Grit Sizes: For roughing, a grain size of 60 is very generally used. For finish grinding with silicon carbide wheels, a finer grain size of 100 or 120 is common. A silicon carbide wheel such as C60-I-7V may be used for grinding both the steel shank and carbide tip. However, for under-cutting steel shanks up to the carbide tip, it may be advantageous to use an aluminum oxide wheel suitable for grinding softer, carbon steel. Grade: According to the standard system of marking, different grades from soft to hard are indicated by letters from A to Z. For carbide tool grinding fairly soft grades such as G, H, I, and J are used. The usual grades for roughing are I or J and for finishing H, I, and J. The
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 972
TOOL SHARPENING
grade should be such that a sharp free-cutting wheel will be maintained without excessive grinding pressure. Harder grades than those indicated tend to overheat and crack the carbide. Structure: The common structure numbers for carbide tool grinding are 7 and 8. The larger cup-wheels (10 to 14 inches) may be of the porous type and be designated as 12P. The standard structure numbers range from 1 to 15 with progressively higher numbers indicating less density and more open wheel structure. Diamond Wheels.—Wheels with diamond-impregnated grinding faces are fast and cool cutting and have a very low rate of wear. They are used extensively both for resharpening and for finish grinding of carbide tools when preliminary roughing is required. Diamond wheels are also adapted for sharpening multi-tooth cutters such as milling cutters, reamers, etc., which are ground in a cutter grinding machine. Resinoid bonded wheels are commonly used for grinding chip breakers, milling cutters, reamers or other multi-tooth cutters. They are also applicable to precision grinding of carbide dies, gages, and various external, internal and surface grinding operations. Fast, cool cutting action is characteristic of these wheels. Metal bonded wheels are often used for offhand grinding of single-point tools especially when durability or long life and resistance to grooving of the cutting face, are considered more important than the rate of cutting. Vitrified bonded wheels are used both for roughing of chipped or very dull tools and for ordinary resharpening and finishing. They provide rigidity for precision grinding, a porous structure for fast cool cutting, sharp cutting action and durability. Diamond Wheel Grit Sizes.—For roughing with diamond wheels a grit size of 100 is the most common both for offhand and machine grinding. Grit sizes of 120 and 150 are frequently used in offhand grinding of single point tools 1) for resharpening; 2) for a combination roughing and finishing wheel; and 3) for chipbreaker grinding. Grit sizes of 220 or 240 are used for ordinary finish grinding all types of tools (offhand and machine) and also for cylindrical, internal and surface finish grinding. Grits of 320 and 400 are used for “lapping” to obtain very fine finishes, and for hand hones. A grit of 500 is for lapping to a mirror finish on such work as carbide gages and boring or other tools for exceptionally fine finishes. Diamond Wheel Grades.—Diamond wheels are made in several different grades to better adapt them to different classes of work. The grades vary for different types and shapes of wheels. Standard Norton grades are H, J, and L, for resinoid bonded wheels, grade N for metal bonded wheels and grades J, L, N, and P, for vitrified wheels. Harder and softer grades than standard may at times be used to advantage. Diamond Concentration.—The relative amount (by carat weight) of diamond in the diamond section of the wheel is known as the “diamond concentration.” Concentrations of 100 (high), 50 (medium) and 25 (low) ordinarily are supplied. A concentration of 50 represents one-half the diamond content of 100 (if the depth of the diamond is the same in each case) and 25 equals one-fourth the content of 100 or one-half the content of 50 concentration. 100 Concentration: Generally interpreted to mean 72 carats of diamond/in.3 of abrasive section. (A 75 concentration indicates 54 carats/in.3.) Recommended (especially in grit sizes up to about 220) for general machine grinding of carbides, and for grinding cutters and chip breakers. Vitrified and metal bonded wheels usually have 100 concentration. 50 Concentration: In the finer grit sizes of 220, 240, 320, 400, and 500, a 50 concentration is recommended for offhand grinding with resinoid bonded cup-wheels.
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Machinery's Handbook 27th Edition TOOL SHARPENING
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25 Concentration: A low concentration of 25 is recommended for offhand grinding with resinoid bonded cup-wheels with grit sizes of 100, 120 and 150. Depth of Diamond Section: The radial depth of the diamond section usually varies from 1⁄ to 1⁄ inch. The depth varies somewhat according to the wheel size and type of bond. 16 4
Dry Versus Wet Grinding of Carbide Tools.—In using silicon carbide wheels, grinding should be done either absolutely dry or with enough coolant to flood the wheel and tool. Satisfactory results may be obtained either by the wet or dry method. However, dry grinding is the most prevalent usually because, in wet grinding, operators tend to use an inadequate supply of coolant to obtain better visibility of the grinding operation and avoid getting wet; hence checking or cracking in many cases is more likely to occur in wet grinding than in dry grinding. Wet Grinding with Silicon Carbide Wheels: One advantage commonly cited in connection with wet grinding is that an ample supply of coolant permits using wheels about one grade harder than in dry grinding thus increasing the wheel life. Plenty of coolant also prevents thermal stresses and the resulting cracks, and there is less tendency for the wheel to load. A dust exhaust system also is unnecessary. Wet Grinding with Diamond Wheels: In grinding with diamond wheels the general practice is to use a coolant to keep the wheel face clean and promote free cutting. The amount of coolant may vary from a small stream to a coating applied to the wheel face by a felt pad. Coolants for Carbide Tool Grinding.—In grinding either with silicon carbide or diamond wheels a coolant that is used extensively consists of water plus a small amount either of soluble oil, sal soda, or soda ash to prevent corrosion. One prominent manufacturer recommends for silicon carbide wheels about 1 ounce of soda ash per gallon of water and for diamond wheels kerosene. The use of kerosene is quite general for diamond wheels and usually it is applied to the wheel face by a felt pad. Another coolant recommended for diamond wheels consists of 80 per cent water and 20 per cent soluble oil. Peripheral Versus Flat Side Grinding.—In grinding single point carbide tools with silicon carbide wheels, the roughing preparatory to finishing with diamond wheels may be done either by using the flat face of a cup-shaped wheel (side grinding) or the periphery of a “straight” or disk-shaped wheel. Even where side grinding is preferred, the periphery of a straight wheel may be used for heavy roughing as in grinding back chipped or broken tools (see left-hand diagram). Reasons for preferring peripheral grinding include faster cutting with less danger of localized heating and checking especially in grinding broad surfaces. The advantages usually claimed for side grinding are that proper rake or relief angles are easier to obtain and the relief or land is ground flat. The diamond wheels used for tool sharpening are designed for side grinding. (See right-hand diagram.)
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 974
TOOL SHARPENING
Lapping Carbide Tools.—Carbide tools may be finished by lapping, especially if an exceptionally fine finish is required on the work as, for example, tools used for precision boring or turning non-ferrous metals. If the finishing is done by using a diamond wheel of very fine grit (such as 240, 320, or 400), the operation is often called “lapping.” A second lapping method is by means of a power-driven lapping disk charged with diamond dust, Norbide powder, or silicon carbide finishing compound. A third method is by using a hand lap or hone usually of 320 or 400 grit. In many plants the finishes obtained with carbide tools meet requirements without a special lapping operation. In all cases any feather edge which may be left on tools should be removed and it is good practice to bevel the edges of roughing tools at 45 degrees to leave a chamfer 0.005 to 0.010 inch wide. This is done by hand honing and the object is to prevent crumbling or flaking off at the edges when hard scale or heavy chip pressure is encountered. Hand Honing: The cutting edge of carbide tools, and tools made from other tool materials, is sometimes hand honed before it is used in order to strengthen the cutting edge. When interrupted cuts or heavy roughing cuts are to be taken, or when the grade of carbide is slightly too hard, hand honing is beneficial because it will prevent chipping, or even possibly, breakage of the cutting edge. Whenever chipping is encountered, hand honing the cutting edge before use will be helpful. It is important, however, to hone the edge lightly and only when necessary. Heavy honing will always cause a reduction in tool life. Normally, removing 0.002 to 0.004 inch from the cutting edge is sufficient. When indexable inserts are used, the use of pre-honed inserts is preferred to hand honing although sometimes an additional amount of honing is required. Hand honing of carbide tools in between cuts is sometimes done to defer grinding or to increase the life of a cutting edge on an indexable insert. If correctly done, so as not to change the relief angle, this procedure is sometimes helpful. If improperly done, it can result in a reduction in tool life. Chip Breaker Grinding.—For this operation a straight diamond wheel is used on a universal tool and cutter grinder, a small surface grinder, or a special chipbreaker grinder. A resinoid bonded wheel of the grade J or N commonly is used and the tool is held rigidly in an adjustable holder or vise. The width of the diamond wheel usually varies from 1⁄8 to 1⁄4 inch. A vitrified bond may be used for wheels as thick as 1⁄4 inch, and a resinoid bond for relatively narrow wheels. Summary of Miscellaneous Points.—In grinding a single-point carbide tool, traverse it across the wheel face continuously to avoid localized heating. This traverse movement should be quite rapid in using silicon carbide wheels and comparatively slow with diamond wheels. A hand traversing and feeding movement, whenever practicable, is generally recommended because of greater sensitivity. In grinding, maintain a constant, moderate pressure. Manipulating the tool so as to keep the contact area with the wheel as small as possible will reduce heating and increase the rate of stock removal. Never cool a hot tool by dipping it in a liquid, as this may crack the tip. Wheel rotation should preferably be against the cutting edge or from the front face toward the back. If the grinder is driven by a reversing motor, opposite sides of a cup wheel can be used for grinding right-and lefthand tools and with rotation against the cutting edge. If it is necessary to grind the top face of a single-point tool, this should precede the grinding of the side and front relief, and topface grinding should be minimized to maintain the tip thickness. In machine grinding with a diamond wheel, limit the feed per traverse to 0.001 inch for 100 to 120 grit; 0.0005 inch for 150 to 240 grit; and 0.0002 inch for 320 grit and finer.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition JIGS AND FIXTURES
975
JIGS AND FIXTURES Jig Bushings Material for Jig Bushings.—Bushings are generally made of a good grade of tool steel to ensure hardening at a fairly low temperature and to lessen the danger of fire cracking. They can also be made from machine steel, which will answer all practical purposes, provided the bushings are properly casehardened to a depth of about 1⁄16 inch. Sometimes, bushings for guiding tools may be made of cast iron, but only when the cutting tool is of such a design that no cutting edges come within the bushing itself. For example, bushings used simply to support the smooth surface of a boring-bar or the shank of a reamer might, in some instances, be made of cast iron, but hardened steel bushings should always be used for guiding drills, reamers, taps, etc., when the cutting edges come in direct contact with the guiding surfaces. If the outside diameter of the bushing is very large, as compared with the diameter of the cutting tool, the cost of the bushing can sometimes be reduced by using an outer cast-iron body and inserting a hardened tool steel bushing. When tool steel bushings are made and hardened, it is recommended that A-2 steel be used. The furnace should be set to 1750°F and the bushing placed in the furnace and held there approximately 20 minutes after the furnace reaches temperature. Remove the bushing and cool in still air. After the part cools to 100–150°F, immediately place in a tempering furnace that has been heated to 300°F. Remove the bushing after one hour and cool in still air. If an atmospherically controlled furnace is unavailable, the part should be wrapped in stainless foil to prevent scaling and oxidation at the 1750°F temperature. American National Standard Jig Bushings.—Specifications for the following types of jig bushings are given in American National Standard B94.33-1974 (R1986). Head Type Press Fit Wearing Bushings, Type H (Fig. 1 and Tables 1 and 3); Headless Type Press Fit Wearing Bushings, Type P (Fig. 2 and Tables 1 and 3); Slip Type Renewable Wearing Bushings, Type S (Fig. 3 and Tables 4 and 5); Fixed Type Renewable Wearing Bushings, Type F (Fig. 4 and Tables 5 and 6); Headless Type Liner Bushings, Type L (Fig. 5 and Table 7); and Head Type Liner Bushings, Type HL (Fig. 6 and Table 8). Specifications for locking mechanisms are also given in Table 9.
Fig. 1. Head Type Press FitWearing Bushings — Type H
Fig. 2. Headless Type Press Fit Wearing Bushings — Type P
Fig. 3. Slip Type Renewable Wearing Bushings—Type S
Fig. 4. Fixed Type Renewable Wearing Bushings — Type F
Fig. 5. Headless Type Liner Bushings — Type L
Fig. 6. Head Type Liner Bushings — Type HL
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 976
JIGS AND FIXTURES Table 1. American National Standard Head Type Press Fit Wearing Bushings — Type H ANSI B94.33-1974 (R1986)
Range of Hole Sizes A
Body Diameter B Unfinished Nom
Max
Min
Finished Max
Min
0.0135 up to and including 0.0625
0.156
0.166
0.161
0.1578
0.1575
0.0630 to 0.0995
0.203
0.213
0.208
0.2046
0.2043
0.1015 to 0.1405
0.250
0.260
0.255
0.2516
0.2513
0.1406 to 0.1875
0.312
0.327
0.322
0.3141
0.3138
0.189 to 0.2500
0.406
0.421
0.416
0.4078
0.4075
0.2570 to 0.3125
0.500
0.520
0.515
0.5017
0.5014
0.3160 to 0.4219
0.625
0.645
0.640
0.6267
0.6264
0.4375 to 0.5000
0.750
0.770
0.765
0.7518
0.7515
0.5156 to 0.6250
0.875
0.895
0.890
0.8768
0.8765
Body Length C 0.250 0.312 0.375 0.500 0.250 0.312 0.375 0.500 0.750 0.250 0.312 0.375 0.500 0.750 0.250 0.312 0.375 0.500 0.750 1.000 0.250 0.312 0.375 0.500 0.750 1.000 1.375 1.750 0.312 0.375 0.500 0.750 1.000 1.375 1.750 0.312 0.375 0.500 0.750 1.000 1.375 1.750 2.125 0.500 0.750 1.000 1.375 1.750 2.125 0.500 0.750 1.000 1.375 1.750 2.125 2.500
Radius D
Head Diam. E Max
Head Thickness F Max
0.016
0.250
0.094
0.016
0.312
0.094
0.016
0.375
0.094
0.031
0.438
0.125
0.031
0.531
0.156
0.047
0.625
0.219
0.047
0.812
0.219
0.062
0.938
0.219
0.062
0.125
0.250
Copyright 2004, Industrial Press, Inc., New York, NY
Number H-10-4 H-10-5 H-10-6 H-10-8 H-13-4 H-13-5 H-13-6 H-13-8 H-13-12 H-16-4 H-16-5 H-16-6 H-16-8 H-16-12 H-20-4 H-20-5 H-20-6 H-20-8 H-20-12 H-20-16 H-26-4 H-26-5 H-26-6 H-26-8 H-26-12 H-26-16 H-26-22 H-26-28 H-32-5 H-32-6 H-32-8 H-32-12 H-32-16 H-32-22 H-32-28 H-40-5 H-40-6 H-40-8 H-40-12 H-40-16 H-40-22 H-40-28 H-40-34 H-48-8 H-48-12 H-48-16 H-48-22 H-29-28 H-48-34 H-56-8 H-56-12 H-56-16 H-56-22 H-56-28 H-56-34 H-56-40
Machinery's Handbook 27th Edition JIGS AND FIXTURES
977
Table 1. (Continued) American National Standard Head Type Press Fit Wearing Bushings — Type H ANSI B94.33-1974 (R1986) Range of Hole Sizes A
Body Diameter B Unfinished
Finished
Nom
Max
Min
Max
Min
0.6406 to 0.7500
1.000
1.020
1.015
1.0018
1.0015
0.7656 to 1.0000
1.375
1.395
1.390
1.3772
1.3768
1.0156 to 1.3750
1.750
1.770
1.765
1.7523
1.7519
1.3906 to 1.7500
2.250
2.270
2.265
2.2525
2.2521
Body Length C 0.500 0.750 1.000 1.375 1.750 2.125 2.500 0.750 1.000 1.375 1.750 2.125 2.500 1.000 1.375 1.750 2.125 2.500 3.000 1.000 1.375 1.750 2.125 2.500 3.000
Radius D
Head Diam. E Max
Head Thickness F Max
0.094
1.250
0.312
0.094
1.625
0.375
0.094
2.000
0.375
0.094
2.500
0.375
Number H-64-8 H-64-12 H-64-16 H-64-22 H-64-28 H-64-34 H-64-40 H-88-12 H-88-16 H-88-22 H-88-28 H-88-34 H-88-40 H-112-16 H-112-22 H-112-28 H-112-34 H-112-40 H-112-48 H-144-16 H-144-22 H-144-28 H-144-34 H-144-40 H-144-48
All dimensions are in inches. See also Table 3 for additional specifications.
Table 2. American National Standard Headless Type Press Fit Wearing Bushings — Type P ANSI B94.33-1974 (R1986) Range of Hole Sizes A
Nom
Body Diameter B Unfinished Finished Max Min Max Min
0.0135 up to and including 0.0625
0.156
0.166
0.161
0.1578
0.1575
0.0630 to 0.0995
0.203
0.213
0.208
0.2046
0.2043
0.1015 to 0.1405
0.250
0.260
0.255
0.2516
0.2513
0.1406 to 0.1875
0.312
0.327
0.322
0.3141
0.3138
Body Length C 0.250 0.312 0.375 0.500 0.250 0.312 0.375 0.500 0.750 0.250 0.312 0.375 0.500 0.750 0.250 0.312 0.375 0.500 0.750 1.000
Radius D
0.016
0.016
0.016
0.031
Copyright 2004, Industrial Press, Inc., New York, NY
Number P-10-4 P-10-5 P-10-6 P-10-8 P-13-4 P-13-5 P-13-6 P-13-8 P-13-12 P-16-4 P-16-5 P-16-6 P-16-8 P-16-12 P-20-4 P-20-5 P-20-6 P-20-8 P-20-12 P-20-16
Machinery's Handbook 27th Edition 978
JIGS AND FIXTURES Table 2. (Continued) American National Standard Headless Type Press Fit Wearing Bushings — Type P ANSI B94.33-1974 (R1986)
Nom
Body Diameter B Unfinished Finished Max Min Max Min
0.1890 to 0.2500
0.406
0.421
0.416
0.4078
0.4075
0.2570 to 0.3125
0.500
0.520
0.515
0.5017
0.5014
0.3160 to 0.4219
0.625
0.645
0.640
0.6267
0.6264
0.4375 to 0.5000
0.750
0.770
0.765
0.7518
0.7515
0.5156 to 0.6250
0.875
0.895
0.890
0.8768
0.8765
0.6406 to 0.7500
1.000
1.020
1.015
1.0018
1.0015
0.7656 to 1.0000
1.375
1.395
1.390
1.3772
1.3768
1.0156 to 1.3750
1.750
1.770
1.765
1.7523
1.7519
1.3906 to 1.7500
2.250
2.270
2.265
2.2525
2.2521
Range of Hole Sizes A
Body Length C 0.250 0.312 0.375 0.500 0.750 1.000 1.375 1.750 0.312 0.375 0.500 0.750 1.000 1.375 1.750 0.312 0.375 0.500 0.750 1.000 1.375 1.750 2.125 0.500 0.750 1.000 1.375 1.750 2.125 0.500 0.750 1.000 1.375 1.750 2.125 2.500 0.500 0.750 1.000 1.375 1.750 2.125 2.500 0.750 1.000 1.375 1.750 2.125 2.500 1.000 1.375 1.750 2.125 2.500 3.000 1.000 1.375 1.750 2.125 2.500 3.000
Radius D
0.031
0.047
0.047
0.062
0.062
0.062
0.094
0.094
0.094
All dimensions are in inches. See Table 3 for additional specifications.
Copyright 2004, Industrial Press, Inc., New York, NY
Number P-26-4 P-26-5 P-26-6 P-26-8 P-26-12 P-26-16 P-26-22 P-26-28 P-32-5 P-32-6 P-32-8 P-32-12 P-32-16 P-32-22 P-32-28 P-40-5 P-40-6 P-40-8 P-40-12 P-40-16 P-40-22 P-40-28 P-40-34 P-48-8 P-48-12 P-48-16 P-48-22 P-48-28 P-48-34 P-56-8 P-56-12 P-56-16 P-56-22 P-56-28 P-56-34 P-56-40 P-64-8 P-64-12 P-64-16 P-64-22 P-64-28 P-64-34 P-64-40 P-88-12 P-88-16 P-88-22 P-88-28 P-88-34 P-88-40 P-112-16 P-112-22 P-112-28 P-112-34 P-112-40 P-112-48 P-144-16 P-144-22 P-144-28 P-144-34 P-144-40 P-144-48
Machinery's Handbook 27th Edition JIGS AND FIXTURES
979
Table 3. Specifications for Head Type H and Headless Type P Press Fit Wearing Bushings ANSI B94.33-1974 (R1986) All dimensions given in inches. Tolerance on dimensions where not otherwise specified shall be ±0.010 inch. Size and type of chamfer on lead end to be manufacturer's option. The length, C, is the overall length for the headless type and length underhead for the head type. The head design shall be in accordance with the manufacturer's practice. Diameter A must be concentric to diameter B within 0.0005 T.I.V. on finish ground bushings. The body diameter, B, for unfinished bushings is larger than the nominal diameter in order to provide grinding stock for fitting to jig plate holes. The grinding allowance is: 0.005 to 0.010 in. for sizes 0.156, 0.203 and 0.250 in. 0.010 to 0.015 in. for sizes 0.312 and 0.406 in. 0.015 to 0.020 in. for sizes 0.500 in. and up. Hole sizes are in accordance with American National Standard Twist Drill Sizes. The maximum and minimum values of the hole size, A, shall be as follows: Nominal Size of Hole Maximum Minimum Above 0.0135 to 0.2500 in., incl. Nominal + 0.0004 in. Nominal + 0.0001 in. Above 0.2500 to 0.7500 in., incl. Nominal + 0.0005 in. Nominal + 0.0001 in. Above 0.7500 to 1.5000 in., incl. Nominal + 0.0006 in. Nominal + 0.0002 in. Above 1.5000 in. Nominal + 0.0007 in. Nominal + 0.0003 in. Bushings in the size range from 0.0135 through 0.3125 will be counterbored to provide for lubrication and chip clearance. Bushings without counterbore are optional and will be furnished upon request. The size of the counterbore shall be inside diameter of the bushing + 0.031 inch. The included angle at the bottom of the counterbore shall be 118 deg, ± 2 deg. The depth of the counterbore shall be in accordance with the table below to provide adequate drill bearing. Drill Bushing Hole Size 0.0135 to 0.0630 to 0.1015 to 0.1406 to 0.1890 to 0.2570 to 0.0625 0.0995 0.1405 0.1875 0.2500 0.3125 P H P H P H P H P H P H Body Length Minimum Drill Bearing Length—Inch 0.250 X 0.250 X X X X X X X X X X 0.312 X 0.250 X X X X X X X X X X 0.375 0.250 0.250 X X X X X X X X X X 0.500 0.250 0.250 X 0.312 X 0.312 X 0.375 X X X X 0.750 + + 0.375 0.375 0.375 0.375 X 0.375 X X X X 1.000 + + + + + + 0.625 0.625 0.625 0.625 0.625 0.625 1.375 + + + + + + + + 0.625 0.625 0.625 0.625 1.750 + + + + + + + + 0.625 0.625 0.625 0.625
All dimensions are in inches. X indicates no counterbore. + indicates not American National Standard
Table 4. American National Standard Slip Type Renewable Wearing Bushings — Type S ANSI B94.33-1974 (R1986) Range of Hole Sizes A
Body Diameter B Nom
Max
Min
0.0135 up to and including 0.0469
0.188
0.1875
0.1873
0.0492 to 0.1562
0.312
0.3125
0.3123
0.1570 to 0.3125
0.500
0.5000
0.4998
0.3160 to 0.5000
0.750
0.7500
0.7498
Length UnderHead C 0.250 0.312 0.375 0.500 0.312 0.500 0.750 1.000 0.312 0.500 0.750 1.000 1.375 1.750 0.500 0.750 1.000 1.375 1.750 2.125
Radius D
Head Diam. E Max
Head Thickness F Max
0.031
0.312
0.188
0.047
0.562
0.375
0.047
0.812
0.438
0.094
1.062
0.438
Copyright 2004, Industrial Press, Inc., New York, NY
Number S-12-4 S-12-5 S-12-6 S-12-8 S-20-5 S-20-8 S-20-12 S-20-16 S-32-5 S-32-8 S-32-12 S-32-16 S-32-22 S-32-28 S-48-8 S-48-12 S-48-16 S-48-22 S-48-28 S-48-34
Machinery's Handbook 27th Edition 980
JIGS AND FIXTURES Table 4. (Continued) American National Standard Slip Type Renewable Wearing Bushings — Type S ANSI B94.33-1974 (R1986)
Range of Hole Sizes A
Body Diameter B Nom
Max
Min
0.5156 to 0.7500
1.000
1.0000
0.9998
0.7656 to 1.0000
1.375
1.3750
1.3747
1.0156 to 1.3750
1.750
1.7500
1.7497
1.3906 to 1.7500
2.250
2.2500
2.2496
Length UnderHead C 0.500 0.750 1.000 1.375 1.750 2.125 2.500 0.750 1.000 1.375 1.750 2.125 2.500 1.000 1.375 1.750 2.125 2.500 3.000 1.000 1.375 1.750 2.125 2.500 3.000
Radius D
Head Diam. E Max
Head Thickness F Max
0.094
1.438
0.438
0.094
1.812
0.438
0.125
2.312
0.625
0.125
2.812
0.625
Number S-64-8 S-64-12 S-64-16 S-64-22 S-64-28 S-64-34 S-64-40 S-88-12 S-88-16 S-88-22 S-88-28 S-88-34 S-88-40 S-112-16 S-112-22 S-112-28 S-112-34 S-112-40 S-112-48 S-144-16 S-144-22 S-144-28 S-144-34 S-144-40 S-144-48
All dimensions are in inches. See also Table 5 for additional specifications.
Table 5. Specifications for Slip Type S and Fixed Type F Renewable Wearing Bushings ANSI B94.33-1974 (R1986) Tolerance on dimensions where not otherwise specified shall be plus or minus 0.010 inch. Hole sizes are in accordance with the American Standard Twist Drill Sizes. The maximum and minimum values of hole size, A, shall be as follows: Nominal Size of Hole Maximum Minimum Above 0.0135 to 0.2500 in. incl. Nominal + 0.0004 in. Nominal + 0.0001 in. Above 0.2500 to 0.7500 in. incl. Nominal + 0.0005 in. Nominal + 0.0001 in. Above 0.7500 to 1.5000 in. incl. Nominal + 0.0006 in. Nominal + 0.0002 in. Above 1.5000 Nominal + 0.0007 in. Nominal + 0.0003 in. The head design shall be in accordance with the manufacturer's practice. Head of slip type is usually knurled. When renewable wearing bushings are used with liner bushings of the head type, the length under the head will still be equal to the thickness of the jig plate, because the head of the liner bushing will be countersunk into the jig plate. Diameter A must be concentric to diameter B within 0.0005 T.I.R. on finish ground bushings. Size and type of chamfer on lead end to be manufacturer's option. Bushings in the size range from 0.0135 through 0.3125 will be counterbored to provide for lubrication and chip clearance. Bushings without counterbore are optional and will be furnished upon request. The size of the counterbore shall be inside diameter of the bushings plus 0.031 inch. The included angle at the bottom of the counterbore shall be 118 deg., plus or minus 2 deg. The depth of the counterbore shall be in accordance with the table below to provide adequate drill bearing. Drill Bearing Hole Size
Body Length 0.250 0.312 0.375 0.500 0.750 1.000 1.375 1.750
0.0135 to 0.0625 S F
0.0630 to 0.0995 S F
0.1015 to 0.1405 S F
0.1406 to 0.1875 S F
0.1890 to 0.2500 S F
0.2500 to 0.3125 S F
X 0.375 0.375 0.375 0.625 0.625 0.625 0.625
X X X X 0.625 0.625 0.625 0.625
Minimum Drill Bearing Length 0.250 0.250 0.250 0.250 0.250 0.312 + +
0.250 0.250 0.250 0.250 0.250 0.312 + +
0.375 0.375 0.375 0.375 0.375 0.375 + +
0.375 0.375 0.375 0.375 0.375 0.375 + +
X 0.375 0.375 0.375 0.375 0.375 + +
X 0.375 0.375 0.375 0.375 0.375 + +
X 0.375 0.375 0.375 0.375 0.625 0.625 0.625
X 0.375 0.375 0.375 0.375 0.625 0.625 0.625
X 0.375 0.375 0.375 0.625 0.625 0.625 0.625
All dimensions are in inches. X indicates no counterbore, + indicates not American National Standard length.
Copyright 2004, Industrial Press, Inc., New York, NY
X X X X 0.625 0.625 0.625 0.625
Machinery's Handbook 27th Edition JIGS AND FIXTURES
981
Table 6. American National Standard Fixed Type Renewable Wearing Bushings — Type F ANSI B94.33-1974 (R1986) Range of Hole Sizes A 0.0135 up to and including 0.0469
0.0492 to 0.1562
Body Diameter B Nom
Max
Min
Length Under Head C
Radius D
Head Diam. E Max
Head Thickness F Max
0.250 0.188
0.312
0.1875
0.3125
0.1873
0.3123
0.312 0.375
0.031
0.312
0.188
0.500
0.5000
0.4998
F-12-8 F-20-5
0.500 0.750
0.047
0.562
0.250
0.7500
0.7498
F-20-16 F-32-5
0.750 1.000
F-32-8 0.047
0.812
0.250
1.0000
0.9998
1.375
1.3750
1.3747
F-32-28
0.500
F-48-8
1.000 1.375
F-48-12 0.094
1.062
0.250
1.7500
1.7497
F-48-34
0.500
F-64-8
0.750
F-64-12
1.375
F-64-16 0.094
1.438
0.375
F-64-28
2.125
F-64-34
2.500
F-64-40
0.750
F-88-12
1.375 1.750
F-88-16 0.094
1.812
0.375
2.2500
2.2496
F-88-22 F-88-28 F-88-34
2.500
F-88-40
1.000
F-112-16
1.750 2.125
F-112-22 0.125
2.312
0.375
F-112-28 F-112-34 F-112-40
3.000
F-112-48
1.000
F-144-16
1.375 2.250
F-64-22
1.750
2.500
1.3906 to 1.7500
F-48-22 F-48-28
1.375 1.750
F-48-16
2.125
2.125
1.0156 to 1.3750
F-32-16 F-32-22
1.000 0.7656 to 1.0000
F-32-12
1.750
1.000 1.000
F-20-12
0.312
1.750
0.5156 to 0.7500
F-20-8
1.000
0.750 0.750
F-12-6
0.312
1.375
0.3160 to 0.5000
F-12-5
0.500
0.500 0.1570 to 0.3125
Number F-12-4
1.750 2.125
F-144-22 0.125
2.812
0.375
F-144-28 F-144-34
2.500
F-144-40
3.000
F-144-48
All dimensions are in inches. See also Table 5 for additional specifications.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 982
JIGS AND FIXTURES Table 7. American National Standard Headless Type Liner Bushings — Type L ANSI B94.33-1974 (R1986)
Range of Hole Sizes in Renewable Bushings
Body Diameter B Unfinished
Inside Diameter A
Finished
Nom
Max
Min
Nom
Max
Min
Max
Min
0.0135 up to and including 0.0469
0.188
0.1879
0.1876
0.312
0.3341
0.3288
0.3141
0.3138
0.0492 to 0.1562
0.312
0.3129
0.3126
0.500
0.520
0.515
0.5017
0.5014
0.1570 to 0.3125
0.500
0.5005
0.5002
0.750
0.770
0.765
0.7518
0.7515
0.3160 to 0.5000
0.750
0.7506
0.7503
1.000
1.020
1.015
1.0018
1.0015
0.5156 to 0.7500
1.000
1.0007
1.0004
1.375
1.395
1.390
1.3772
1.3768
0.7656 to 1.0000
1.375
1.3760
1.3756
1.750
1.770
1.765
1.7523
1.7519
1.0156 to 1.3750
1.750
1.7512
1.7508
2.250
2.270
2.265
2.2525
2.2521
1.3906 to 1.7500
2.250
2.2515
2.2510
2.750
2.770
2.765
2.7526
2.7522
Overall Length C 0.250 0.312 0.375 0.500 0.312 0.500 0.750 1.000 0.312 0.500 0.750 1.000 1.375 1.750 0.500 0.750 1.000 1.375 1.750 2.125 0.500 1.750 1.000 1.375 1.750 2.125 2.500 0.750 1.000 1.375 1.750 2.125 2.500 1.000 1.375 1.750 2.125 2.500 3.000 1.000 1.375 1.750 2.125 2.500 3.000
Radius D
0.031
0.047
0.062
0.062
0.094
0.094
0.094
0.125
Number L-20-4 L-20-5 L-20-6 L-20-8 L-32-5 L-32-8 L-32-12 L-32-16 L-48-5 L-48-8 L-48-12 L-48-16 L-48-22 L-48-28 L-64-8 L-64-12 L-64-16 L-64-22 L-64-28 L-64-34 L-88-8 L-88-12 L-88-16 L-88-22 L-88-28 L-88-34 L-88-40 L-112-12 L-112-16 L-112-22 L-112-28 L-112-34 L-112-40 L-144-16 L-144-22 L-144-28 L-144-34 L-144-40 L-144-48 L-176-16 L-176-22 L-176-28 L-176-34 L-176-40 L-176-48
All dimensions are in inches. Tolerances on dimensions where otherwise not specified are ± 0.010 in. The body diameter, B, for unfinished bushings is 0.015 to 0.020 in. larger than the nominal diameter in order to provide grinding stock for fitting to jig plate holes. Diameter A must be concentric to diameter B within 0.0005 T.I.R. on finish ground bushings.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition JIGS AND FIXTURES
983
Nom
Max
Unfinished
Min
Nom
Max
Min
Finished
Max
Min
Overall Length C
Head Dia. E
Head Thickness F Max
Body Diameter B
Inside Diameter A
Radius D
Range of Hole Sizes in Renewable Bushings
Table 8. American National Standard Head Type Liner Bushing — Type HL ANSI B94.33-1974 (R1986)
0.312 0.0135 to 0.1562
0.312
0.3129
0.3126
0.500 0.520 0.515
0.5017
0.5014
0.500 0.750
0.047 0.625 0.094
0.3160 to 0.5000
0.5156 to 0.7500
0.500
0.750
0.5005
0.7506
0.5002
0.7503
0.750 0.770 0.765
1.000 1.020 1.015
0.7518
1.0018
0.7515
1.0015
1.000
HL-32-16 HL-48-5
0.750 1.000
HL-48-8 0.062 0.875 0.094
1.0007
1.0004
1.375 1.395 1.390
1.3772
1.3768
1.375
1.3760
1.3756
1.750 1.770 1.765
1.7523
1.7519
HL-48-22 HL-48-28
0.500
HL-64-8
0.750
HL-64-12
1.000 1.375
0.062 1.125 0.125
1.7512
1.7508
2.250
2.27
2.265
2.2525
2.2521
HL-64-28 HL-64-34
0.500
HL-88-8
0.750
HL-88-12
1.375
HL-88-16 0.094 1.500 0.125
HL-88-28
2.125
HL-88-34
2.500
HL-88-40
0.750
HL-112-12
1.375 1.750
HL-112-16 0.094 1.875 0.188
2.2515
2.2510
2.750 2.770 2.765
2.7526
2.7522
HL-112-22 HL-112-28 HL-112-34
2.500
HL-112-40
1.000
HL-144-16
1.750 2.125
HL-144-22 0.094 2.375 0.188
HL-144-28 HL-144-34 HL-144-40
3.000
HL-144-48
1.000
HL-176-16
1.375 2.250
HL-88-22
1.750
2.500
1.3906 to 1.7500
HL-64-22
2.125
1.375 1.750
HL-64-16
1.750
2.125
1.0156 to 1.3750
HL-48-16
1.750
1.000 0.7656 to 1.0000
HL-48-12
1.375
1.000 1.000
HL-32-8 HL-32-12
0.312 0.500 0.1570 to 0.3125
Number HL-32-5
1.750 2.125
HL-176-22 0.125 2.875 0.188
HL-176-28 HL-176-34
2.500
HL-176-40
3.000
HL-176-48
All dimensions are in inches. See also footnotes to Table 7.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 984
JIGS AND FIXTURES
Table 9. American National Standard Locking Mechanisms for Jig Bushings ANSI B94.33-1974 (R1986) Lock Screw for Use with Slip or Fixed Renewable Bushings
No.
A
B
C
D
E
F
LS-0 LS-1
0.438 0.625
0.188 0.375
0.312 0.625
0.188 0.250
0.105-0.100 0.138-0.132
LS-2
0.875
0.375
0.625
Per Manufacturer's Standard
0.375
0.200-0.194
LS-3
1.000
0.438
0.750
0.375
0.200-0.194
UNC Thread 8–32 5⁄ –18 16 5⁄ –18 16 3⁄ –16 8
Round Clamp Optional Only for Use with Fixed Renewable Bushing
Number
A
B
C
D
E
F
G
H
RC-1
0.625
0.312
0.484
0.150
0.203
0.125
0.531
0.328
RC-2
0.625
0.438
0.484
0.219
0.187
0.188
0.906
0.328
RC-3
0.750
0.500
0.578
0.281
0.219
0.188
1.406
0.391
Use With Socket Head Screw 5⁄ –18 16 5⁄ –18 16 3⁄ –16 8
Locking Mechanism Dimensions of Slip and Fixed Renewable Bushings
R
Locking Dim. of Lock Screw (Slip or Fixed)
Locking Dim. of Clamp (Fixed Only)
Max Head Diam. of Mating Liner Used to Clear Locking Device
0.266 0.500 0.625 0.750 0.922 1.109 1.391 1.641
0.105-0.100 0.138-0.132 0.138-0.132 0.138-0.132 0.200-0.194 0.200-0.194 0.200-0.194 0.200-0.194
… 0.125-0.115 0.125-0.115 0.125-0.115 0.187-0.177 0.187-0.177 0.187-0.177 0.187-0.177
… 0.625 0.875 1.125 1.500 1.875 2.375 2.875
G Head Thickness
Body OD
Max Diam. F When Used With Locking Device
Slip
Fixed
H ± 0.005
0.188 0.312 0.500 0.750 1.000 1.375 1.750 2.250
0.312 0.562 0.812 1.062 1.438 1.812 2.312 2.812
0.188 0.375 0.438 0.438 0.438 0.438 0.625 0.625
0.188 0.250 0.250 0.250 0.375 0.375 0.375 0.375
0.094 0.125 0.125 0.125 0.188 0.188 0.188 0.188
J
L Ma x
0.094 0.172 0.297 0.422 0.594 0.781 1.000 1.250
55° 65° 65° 50° 35° 30° 30° 25°
All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Clam p or Screw LS or RC 0 1 1 1 2 2 3 3
Machinery's Handbook 27th Edition JIG BUSHINGS
985
Jig Bushing Definitions.— Renewable Bushings: Renewable wearing bushings to guide the tool are for use in liners which in turn are installed in the jig. They are used where the bushing will wear out or become obsolete before the jig or where several bushings are to be interchangeable in one hole. Renewable wearing bushings are divided into two classes, “Fixed” and “Slip.” Fixed renewable bushings are installed in the liner with the intention of leaving them in place until worn out. Slip renewable bushings are interchangeable in a given size of liner and, to facilitate removal, they are usually made with a knurled head. They are most frequently used where two or more operations requiring different inside diameters are performed in a single jig, such as where drilling is followed by reaming, tapping, spot facing, counterboring, or some other secondary operation. Press Fit Bushings: Press fit wearing bushings to guide the tool are for installation directly in the jig without the use of a liner and are employed principally where the bushings are used for short production runs and will not require replacement. They are intended also for short center distances. Liner Bushings: Liner bushings are provided with and without heads and are permanently installed in a jig to receive the renewable wearing bushings. They are sometimes called master bushings. Jig Plate Thickness.—The standard length of the press fit portion of jig bushings as established are based on standardized uniform jig plate thicknesses of 5⁄16, 3⁄8, 1⁄2, 3⁄4, 1, 13⁄8, 13⁄4, 21⁄8, 21⁄2, and 3 inches. Jig Bushing Designation System.—Inside Diameter: The inside diameter of the hole is specified by a decimal dimension. Type Bushing: The type of bushing is specified by a letter: S for Slip Renewable, F for Fixed Renewable, L for Headless Liner, HL for Head Liner, P for Headless Press Fit, and H for Head Press Fit. Body Diameter: The body diameter is specified in multiples of 0.0156 inch. For example, a 0.500-inch body diameter = 0.500/0.0156 = 32. Body Length: The effective or body length is specified in multiples of 0.0625 inch. For example, a 0.500-inch length = 0.500/0.0625 = 8. Unfinished Bushings: All bushings with grinding stock on the body diameter are designated by the letter U following the number. Example:A slip renewable bushing having a hole diameter of 0.5000 inch, a body diameter of 0.750 inch, and a body length of 1.000 inch would be designated as .5000-S-48-16. Jig Boring Definition of Jig and Fixture.—The distinction between a jig and fixture is not easy to define, but, as a general rule, it is as follows: A jig either holds or is held on the work, and, at the same time, contains guides for the various cutting tools, whereas a fixture holds the work while the cutting tools are in operation, but does not contain any special arrangements for guiding the tools. A fixture, therefore, must be securely held or fixed to the machine on which the operation is performed—hence the name. A fixture is sometimes provided with a number of gages and stops, but not with bushings or other devices for guiding and supporting the cutting tools. Jig Borers.—Jig borers are used for precision hole-location work. For this reason, the coordinate measuring systems on these machines are designed to provide longitudinal and transverse movements that are accurate to 0.0001 in. One widely used method of obtaining this accuracy utilizes ultraprecision lead screws. Another measuring system employs precision end measuring rods and a micrometer head that are placed in a trough which is parallel to the table movement. However, the purpose of all coordinate measuring systems used is the same: to provide a method of aligning the spindle at the precise location where a hole is to be produced. Since the work table of a jig borer moves in two directions, the
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 986
JIG BORING
coordinate system of dimensioning is used, where dimensions are given from two perpendicular reference axes, usually the sides of the workpiece, frequently its upper left-hand corner. See Fig. 1C. Jig-Boring Practice.—The four basic steps to follow to locate and machine a hole on a jig borer are: Align and Clamp the Workpiece: The first consideration in placing the workpiece on the jig-borer table should be the relation of the coordinate measuring system of the jig borer to the coordinate dimensions on the drawing. Therefore, the coordinate measuring system is designed so that the readings of the coordinate measurements are direct when the table is moved toward the left and when it is moved toward the column of the jig borer. The result would be the same if the spindle were moved toward the right and away from the column, with the workpiece situated in such a position that one reference axis is located at the left and the other axis at the back, toward the column. If the holes to be bored are to pass through the bottom of the workpiece, then the workpiece must be placed on precision parallel bars. In order to prevent the force exerted by the clamps from bending the workpiece the parallel bars are placed directly under the clamps, which hold the workpiece on the table. The reference axes of the workpiece must also be aligned with respect to the transverse and longitudinal table movements before it is firmly clamped. This alignment can be done with a dial-test indicator held in the spindle of the jig borer and bearing against the longitudinal reference edge. As the table is traversed in the longitudinal direction, the workpiece is adjusted until the dial-test indicator readings are the same for all positions. Locate the Two Reference Axes of the Workpiece with Respect to the Spindle: T h e j i g borer table is now moved to position the workpiece in a precise and known location from where it can be moved again to the location of the holes to be machined. Since all the holes are dimensioned from the two reference axes, the most convenient position to start from is where the axis of the jig-borer spindle and the intersection of the two workpiece reference axes are aligned. This is called the starting position, which is similar to a zero reference position. When so positioned, the longitudinal and transverse measuring systems of the jig borer are set to read zero. Occasionally, the reference axes are located outside the body of the workpiece: a convenient edge or hole on the workpiece is picked up as the starting position, and the dimensions from this point to the reference axes are set on the positioning measuring system. Locate the Hole: Precise coordinate table movements are used to position the workpiece so that the spindle axis is located exactly where the hole is to be machined. When the measuring system has been set to zero at the starting position, the coordinate readings at the hole location will be the same as the coordinate dimensions of the hole center. The movements to each hole must be made in one direction for both the transverse and longitudinal directions, to eliminate the effect of any backlash in the lead screw. The usual table movements are toward the left and toward the column. The most convenient sequence on machines using micrometer dials as position indicators (machines with lead screws) is to machine the hole closest to the starting position first and then the next closest, and so on. On jig borers using end measuring rods, the opposite sequence is followed: The farthest hole is machined first and then the next farthest, and so on, since it is easier to remove end rods and replace them with shorter rods. Drill and Bore Hole to Size: The sequence of operations used to produce a hole on a jig borer is as follows: 1) a short, stiff drill, such as a center drill, that will not deflect when cutting should be used to spot a hole when the work and the axis of the machine tool spindle are located at the exact position where the hole is wanted; 2) the initial hole is made by a twist drill; and 3) a single-point boring tool that is set to rotate about the axis of the machine tool spindle is then used to generate a cut surface that is concentric to the axis of rotation.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition JIG BORING
987
Heat will be generated by the drilling operation, so it is good practice to drill all the holes first, and then allow the workpiece to cool before the holes are bored to size. Transfer of Tolerances.—All of the dimensions that must be accurately held on precision machines and engine parts are usually given a tolerance. And when such dimensions are changed from the conventional to the coordinate system of dimensioning, the tolerances must also be included. Because of their importance, the transfer of the tolerances must be done with great care, keeping in mind that the sum of the tolerances of any pair of dimensions in the coordinate system must not be larger than the tolerance of the dimension that they replaced in the conventional system. An example is given in Fig. 1. The first step in the procedure is to change the tolerances given in Fig. 1A to equal, bilateral tolerances given in Fig. 1B. For example, the dimension 2.125+.003−.001 has a total tolerance of 0.004. The equal, bilateral tolerance would be plus or minus one-half of this value, or ±.002. Then to keep the limiting dimensions the same, the basic dimension must be changed to 2.126, in order to give the required values of 2.128 and 2.124. When changing to equal, bilateral tolerances, if the upper tolerance is decreased (as in this example), the basic dimension must be increased by a like amount. The upper tolerance was decreased by 0.003 − 0.002 = 0.001; therefore, the basic dimension was increased by 0.001 to 2.126. Conversely, if the upper tolerance is increased, the basic dimension is decreased. The next step is to transfer the revised basic dimension to the coordinate dimensioning system. To transfer the 2.126 dimension, the distance of the applicable holes from the left reference axis must be determined. The first holes to the right are 0.8750 from the reference axis. The second hole is 2.126 to the right of the first holes. Therefore, the second hole is 0.8750 + 2.126 = 3.0010 to the right of the reference axis. This value is then the coordinate dimension for the second hole, while the 0.8750 value is the coordinate dimension of the first two, vertically aligned holes. This procedure is followed for all the holes to find their distances from the two reference axes. These values are given in Fig. 1C. The final step is to transfer the tolerances. The 2.126 value in Fig. 1B has been replaced by the 0.8750 and 3.0010 values in Fig. 1C. The 2.126 value has an available tolerance of ±0.002. Dividing this amount equally between the two replacement values gives 0.8750 ± 0.001 and 3.0010 ± 0.001. The sum of these tolerances is .002, and as required, does not exceed the tolerance that was replaced. Next transfer the tolerance of the 0.502 dimension. Divide the available tolerance, ±0.002, equally between the two replacement values to yield 3.0010 ±0.001 and 3.5030 ±0.001. The sum of these two tolerances equals the replaced tolerance, as required. However, the 1.125 value of the last hole to the right (coordinate dimension 4.6280 in.) has a tolerance of only ±0.001. Therefore, the sum of the tolerances on the 3.5030 and 4.6280 values cannot be larger than 0.001. Dividing this tolerance equally would give 3.5030 ± .0005 and 4.6280 ±0.0005. This new, smaller tolerance replaces the ± 0.001 tolerance on the 3.5030 value in order to satisfy all tolerance sum requirements. This example shows how the tolerance of a coordinate value is affected by more than one other dimensional requirement. The following discussion will summarize the various tolerances listed in Fig. 1C. For the 0.8750 ± 0.0010 dimension, the ± 0.0010 tolerance together with the ± 0.0010 tolerance on the 3.0010 dimension is required to maintain the ± 0.002 tolerance of the 2.126 dimension. The ± .0005 tolerances on the 3.5030 and 4.2680 dimensions are required to maintain the ± 0.001 tolerance of the 1.125 dimension, at the same time as the sum of the ± .0005 tolerance on the 3.5030 dimension and the ± 0.001 tolerance on the 3.0010 dimension does not exceed the ± 0.002 tolerance on the replaced 0.503 dimension. The ± 0.0005 tolerances on the 1.0000 and 2.0000 values maintain the ± 0.001 tolerance on the 1.0000 value given at the right in Fig. 1A. The ± 0.0045 tolerance on the 3.0000 dimension together with the ± 0.0005 tolerance on the 1.0000 value maintains the ± .005 tolerance on the 2.0000 dimension of Fig. 1A. It should be noted that the 2.000 ± .005 dimension in Fig. 1A was replaced by the 1.0000 and 3.0000 dimensions in Fig. 1C. Each of these values could have had a tol-
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 988
JIG BORING ±.005
1.000 ±.001
1.000
±.005
2.000
±.005
2.125
.875
+.003 –.001
1.125 +.004
.500 –.000
A
±.005
1.000 ±.001
1.000
±.005
2.000
±.002
±.005
±.001
2.126
.875
1.125 ±.002
B
Ref.
Ref.
.502
±.0005
1.000 ±.001
1.000
±.0005
2.000 ±.0045
±.0005
4.6280
±.0005
3.5030
±.0010
3.0010
.8750
±.0010
3.000
C
Fig. 1. (A) Conventional Dimensions, Mixed Tolerances; (B) Conventional Dimensions, All Equal, Bilateral Tolerances; and (C) Coordinate Dimensions
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition JIG BORING
989
erance of ± 0.0025, except that the tolerance on the 1.0000 dimension on the left in Fig. 1A is also bound by the ± 0.001 tolerance on the 1.0000 dimension on the right, thus the ± 0.0005 tolerance value is used. This procedure requires the tolerance on the 3.0000 value to be increased to ± 0.0045. Determining Hole Coordinates On the following pages are given tables of the lengths of chords for spacing off the circumferences of circles. The object of these tables is to make possible the division of the periphery into a number of equal parts without trials with the dividers. The first table, Table 10, is calculated for circles having a diameter equal to 1. For circles of other diameters, the length of chord given in the table should be multiplied by the diameter of the circle. Table 10 may be used by toolmakers when setting “buttons” in circular formation. Assume that it is required to divide the periphery of a circle of 20 inches diameter into thirty-two equal parts. From the table the length of the chord is found to be 0.098017 inch, if the diameter of the circle were 1 inch. With a diameter of 20 inches the length of the chord for one division would be 20 × 0.098017 = 1.9603 inches. Another example in metric units: For a 100 millimeter diameter requiring 5 equal divisions, the length of the chord for one division would be 100 × 0.587785 = 58.7785 millimeters. Tables 11a and 11b starting on page 991 are additional tables for the spacing off of circles; the tables, in this case, being worked out for diameters from 1⁄16 inch to 14 inches. As an example, assume that it is required to divide a circle having a diameter of 61⁄2 inches into seven equal parts. Find first, in the column headed “6” and in line with 7 divisions, the length of the chord for a 6-inch circle, which is 2.603 inches. Then find the length of the chord for a 1⁄2-inch diameter circle, 7 divisions, which is 0.217. The sum of these two values, 2.603 + 0.217 = 2.820 inches, is the length of the chord required for spacing off the circumference of a 61⁄2-inch circle into seven equal divisions. As another example, assume that it is required to divide a circle having a diameter of 923⁄32 inches into 15 equal divisions. First find the length of the chord for a 9-inch circle, which is 1.871 inch. The length of the chord for a 23⁄32-inch circle can easily be estimated from the table by taking the value that is exactly between those given for 11⁄16 and 3⁄4 inch. The value for 11⁄16 inch is 0.143, and for 3⁄4 inch, 0.156. For 23⁄32, the value would be 0.150. Then, 1.871 + 0.150 = 2.021 inches. Hole Coordinate Dimension Factors for Jig Boring.—Tables of hole coordinate dimension factors for use in jig boring are given in Tables 12 through 15 starting on page 993. The coordinate axes shown in the figure accompanying each table are used to reference the tool path; the values listed in each table are for the end points of the tool path. In this machine coordinate system, a positive Y value indicates that the effective motion of the tool with reference to the work is toward the front of the jig borer (the actual motion of the jig borer table is toward the column). Similarly, a positive X value indicates that the effective motion of the tool with respect to the work is toward the right (the actual motion of the jig borer table is toward the left). When entering data into most computer-controlled jig borers, current practice is to use the more familiar Cartesian coordinate axis system in which the positive Y direction is “up” (i.e., pointing toward the column of the jig borer). The computer will automatically change the signs of the entered Y values to the signs that they would have in the machine coordinate system. Therefore, before applying the coordinate dimension factors given in the tables, it is important to determine the coordinate system to be used. If a Cartesian coordinate system is to be used for the tool path, then the sign of the Y values in the tables must be changed, from positive to negative and from negative to positive. For example, when programming for a three-hole type A circle using Cartesian coordinates, the Y values from Table 14 would be y1 = + 0.50000, y2 = −0.25000, and y3 = −0.25000.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 990
JIG BORING Table 10. Lengths of Chords for Spacing Off the Circumferences of Circles with a Diameter Equal to 1 (English or metric units)
No. of Spaces 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
Length of Chord 0.866025 0.707107 0.587785 0.500000 0.433884 0.382683 0.342020 0.309017 0.281733 0.258819 0.239316 0.222521 0.207912 0.195090 0.183750 0.173648 0.164595 0.156434 0.149042 0.142315 0.136167 0.130526 0.125333 0.120537 0.116093 0.111964 0.108119 0.104528 0.101168 0.098017 0.095056 0.092268 0.089639 0.087156 0.084806 0.082579 0.080467 0.078459
No. of Spaces 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78
Length of Chord 0.076549 0.074730 0.072995 0.071339 0.069756 0.068242 0.066793 0.065403 0.064070 0.062791 0.061561 0.060378 0.059241 0.058145 0.057089 0.056070 0.055088 0.054139 0.053222 0.052336 0.051479 0.050649 0.049846 0.049068 0.048313 0.047582 0.046872 0.046183 0.045515 0.044865 0.044233 0.043619 0.043022 0.042441 0.041876 0.041325 0.040789 0.040266
No. of Spaces 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116
Length of Chord 0.039757 0.039260 0.038775 0.038303 0.037841 0.037391 0.036951 0.036522 0.036102 0.035692 0.035291 0.034899 0.034516 0.034141 0.033774 0.033415 0.033063 0.032719 0.032382 0.032052 0.031728 0.031411 0.031100 0.030795 0.030496 0.030203 0.029915 0.029633 0.029356 0.029085 0.028818 0.028556 0.028299 0.028046 0.027798 0.027554 0.027315 0.027079
No. of Spaces 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154
Length of Chord 0.026848 0.026621 0.026397 0.026177 0.025961 0.025748 0.025539 0.025333 0.025130 0.024931 0.024734 0.024541 0.024351 0.024164 0.023979 0.023798 0.023619 0.023443 0.023269 0.023098 0.022929 0.022763 0.022599 0.022438 0.022279 0.022122 0.021967 0.021815 0.021664 0.021516 0.021370 0.021225 0.021083 0.020942 0.020804 0.020667 0.020532 0.020399
For circles of other diameters, multiply length given in table by diameter of circle. Example:In a drill jig, 8 holes, each 1⁄2 inch diameter, were spaced evenly on a 6-inch diameter circle. To test the accuracy of the jig, plugs were placed in adjacent holes, and the distance over the plugs was measured with a micrometer. What should be the micrometer reading? Solution: The micrometer reading equals the diameter of one plug plus 6 times the chordal distance between adjacent hole centers given in the table above. Thus, the reading should be 1⁄2 + (6 × 0382683) = 2.796098 inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 11a. Table for Spacing Off the Circumferences of Circles Diameter of Circle to be Spaced Off No. of Divisions
Degrees in Arc
1⁄ 16
1⁄ 8
3⁄ 16
1⁄ 4
5⁄ 16
3⁄ 8
7⁄ 16
1⁄ 2
9⁄ 16
5⁄ 8
11⁄ 16
3⁄ 4
13⁄ 16
7⁄ 8
15⁄ 16
Length of Chord 3 4 5 6 7
120 90 72 60 51 3⁄7 45 40 36
12 13
30
32 8⁄11 27 9⁄13
0.108 0.088 0.073 0.063 0.054
0.162 0.133 0.110 0.094 0.081
0.217 0.177 0.147 0.125 0.108
0.271 0.221 0.184 0.156 0.136
0.325 0.265 0.220 0.188 0.163
0.379 0.309 0.257 0.219 0.190
0.433 0.354 0.294 0.250 0.217
0.487 0.398 0.331 0.281 0.244
0.541 0.442 0.367 0.313 0.271
0.595 0.486 0.404 0.344 0.298
0.650 0.530 0.441 0.375 0.325
0.704 0.575 0.478 0.406 0.353
0.758 0.619 0.514 0.438 0.380
0.812 0.663 0.551 0.469 0.407
0.024 0.021 0.019 0.018
0.048 0.043 0.039 0.035
0.072 0.064 0.058 0.053
0.096 0.086 0.077 0.070
0.120 0.107 0.097 0.088
0.144 0.128 0.116 0.106
0.167 0.150 0.135 0.123
0.191 0.171 0.155 0.141
0.215 0.192 0.174 0.158
0.239 0.214 0.193 0.176
0.263 0.235 0.212 0.194
0.287 0.257 0.232 0.211
0.311 0.278 0.251 0.229
0.335 0.299 0.270 0.247
0.359 0.321 0.290 0.264
0.016 0.015
0.032 0.030
0.049 0.045
0.065 0.060
0.081 0.075
0.097 0.090
0.113 0.105
0.129 0.120
0.146 0.135
0.162 0.150
0.178 0.165
0.194 0.179
0.210 0.194
0.226 0.209
0.243 0.224
14
25 5⁄7
0.014
0.028
0.042
0.056
0.069
0.083
0.097
0.111
0.125
0.139
0.153
0.167
0.181
0.195
0.209
15 16
24
0.013 0.012
0.026 0.024
0.039 0.037
0.052 0.049
0.065 0.061
0.078 0.073
0.091 0.085
0.104 0.098
0.117 0.110
0.130 0.122
0.143 0.134
0.156 0.146
0.169 0.159
0.182 0.171
0.195 0.183
22 1⁄2
17
21 3⁄17
0.011
0.023
0.034
0.046
0.057
0.069
0.080
0.092
0.103
0.115
0.126
0.138
0.149
0.161
0.172
18 19
20
0.011 0.010
0.022 0.021
0.033 0.031
0.043 0.041
0.054 0.051
0.065 0.062
0.076 0.072
0.087 0.082
0.098 0.093
0.109 0.103
0.119 0.113
0.130 0.123
0.141 0.134
0.152 0.144
0.163 0.154
20 21
18 17 1⁄7
0.010 0.009
0.020 0.019
0.029 0.028
0.039 0.037
0.049 0.047
0.059 0.056
0.068 0.065
0.078 0.075
0.088 0.084
0.098 0.093
0.108 0.102
0.117 0.112
0.127 0.121
0.137 0.130
0.147 0.140
22
16 4⁄11
0.009
0.018
0.027
0.036
0.044
0.053
0.062
0.071
0.080
0.089
0.098
0.107
0.116
0.125
0.133
23
15 15⁄23
0.009
0.017
0.026
0.034
0.043
0.051
0.060
0.068
0.077
0.085
0.094
0.102
0.111
0.119
0.128
24 25
15
0.008 0.008
0.016 0.016
0.024 0.023
0.033 0.031
0.041 0.039
0.049 0.047
0.057 0.055
0.065 0.063
0.073 0.070
0.082 0.078
0.090 0.086
0.098 0.094
0.106 0.102
0.114 0.110
0.122 0.117
26
13 11⁄13
0.008
0.015
0.023
0.030
0.038
0.045
0.053
0.060
0.068
0.075
0.083
0.090
0.098
0.105
0.113
28
12 6⁄7
0.007
0.014
0.021
0.028
0.035
0.042
0.049
0.056
0.063
0.070
0.077
0.084
0.091
0.098
0.105
30 32
12
0.007 0.006
0.013 0.012
0.020 0.018
0.026 0.025
0.033 0.031
0.039 0.037
0.046 0.043
0.052 0.049
0.059 0.055
0.065 0.061
0.072 0.067
0.078 0.074
0.085 0.080
0.091 0.086
0.098 0.092
18 18⁄19
14
11
2⁄ 5
1⁄ 4
JIG BORING
8 9 10 11
0.054 0.044 0.037 0.031 0.027
991
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
992
Table 11b. Table for Spacing Off the Circumferences of Circles Diameter of Circle to be Spaced Off No. of Divisions
Degrees in Arc
1
2
3
4
5
6
7
8
9
10
11
12
13
14
Length of Chord 120 90 72 60
8 9 10 11
45 40 36
12 13
30
518⁄7
328⁄11 279⁄13
0.866 0.707 0.588 0.500 0.434
1.732 1.414 1.176 1.000 0.868
2.598 2.121 1.763 1.500 1.302
3.464 2.828 2.351 2.000 1.736
4.330 3.536 2.939 2.500 2.169
5.196 4.243 3.527 3.000 2.603
6.062 4.950 4.114 3.500 3.037
6.928 5.657 4.702 4.000 3.471
7.794 6.364 5.290 4.500 3.905
8.660 7.071 5.878 5.000 4.339
9.526 7.778 6.466 5.500 4.773
10.392 8.485 7.053 6.000 5.207
11.258 9.192 7.641 6.500 5.640
12.124 9.899 8.229 7.000 6.074
0.383 0.342 0.309 0.282
0.765 0.684 0.618 0.563
1.148 1.026 0.927 0.845
1.531 1.368 1.236 1.127
1.913 1.710 1.545 1.409
2.296 2.052 1.854 1.690
2.679 2.394 2.163 1.972
3.061 2.736 2.472 2.254
3.444 3.078 2.781 2.536
3.827 3.420 3.090 2.817
4.210 3.762 3.399 3.099
4.592 4.104 3.708 3.381
4.975 4.446 4.017 3.663
5.358 4.788 4.326 3.944
0.259 0.239
0.518 0.479
0.776 0.718
1.035 0.957
1.294 1.197
1.553 1.436
1.812 1.675
2.071 1.915
2.329 2.154
2.588 2.393
2.847 2.632
3.106 2.872
3.365 3.111
3.623 3.350
14
255⁄7
0.223
0.445
0.668
0.890
1.113
1.335
1.558
1.780
2.003
2.225
2.448
2.670
2.893
3.115
15 16
24
0.208 0.195
0.416 0.390
0.624 0.585
0.832 0.780
1.040 0.975
1.247 1.171
1.455 1.366
1.663 1.561
1.871 1.756
2.079 1.951
2.287 2.146
2.495 2.341
2.703 2.536
2.911 2.731
221⁄2
17
213⁄17
0.184
0.367
0.551
0.735
0.919
1.102
1.286
1.470
1.654
1.837
2.021
2.205
2.389
2.572
18 19
20
0.174 0.165
0.347 0.329
0.521 0.494
0.695 0.658
0.868 0.823
1.042 0.988
1.216 1.152
1.389 1.317
1.563 1.481
1.736 1.646
1.910 1.811
2.084 1.975
2.257 2.140
2.431 2.304
20 21
18 171⁄7
0.156 0.149
0.313 0.298
0.469 0.447
0.626 0.596
0.782 0.745
0.939 0.894
1.095 1.043
1.251 1.192
1.408 1.341
1.564 1.490
1.721 1.639
1.877 1.789
2.034 1.938
2.190 2.087
22
164⁄11
0.142
0.285
0.427
0.569
0.712
0.854
0.996
1.139
1.281
1.423
1.565
1.708
1.850
1.992
23
1515⁄23
0.136
0.272
0.408
0.545
0.681
0.817
0.953
1.089
1.225
1.362
1.498
1.634
1.770
1.906
24 25
15 142⁄5
0.131 0.125
0.261 0.251
0.392 0.376
0.522 0.501
0.653 0.627
0.783 0.752
0.914 0.877
1.044 1.003
1.175 1.128
1.305 1.253
1.436 1.379
1.566 1.504
1.697 1.629
1.827 1.755
26
1311⁄13
0.121
0.241
0.362
0.482
0.603
0.723
0.844
0.964
1.085
1.205
1.326
1.446
1.567
1.688
28
126⁄7
0.112
0.224
0.336
0.448
0.560
0.672
0.784
0.896
1.008
1.120
1.232
1.344
1.456
1.568
30 32
12
0.105 0.098
0.209 0.196
0.314 0.294
0.418 0.392
0.523 0.490
0.627 0.588
0.732 0.686
0.836 0.784
0.941 0.882
1.045 0.980
1.150 1.078
1.254 1.176
1.359 1.274
1.463 1.372
1818⁄19
111⁄4
See Determining Hole Coordinates on page 989 for explanatory matter.
Copyright 2004, Industrial Press, Inc., New York, NY
JIG BORING
3 4 5 6 7
Machinery's Handbook 27th Edition JIG BORING
993
Table 12. Hole Coordinate Dimension Factors for Jig Boring — Type “A” Hole Circles (English or Metric Units)
The diagram shows a type “A” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
3 Holes x1 y1 x2 y2 x3 y3
0.50000 0.00000 0.06699 0.75000 0.93301 0.75000
4 Holes x1 y1 x2 y2 x3 y3 x4 y4
0.50000 0.00000 0.00000 0.50000 0.50000 1.00000 1.00000 0.50000
10 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10
0.50000 0.00000 0.20611 0.09549 0.02447 0.34549 0.02447 0.65451 0.20611 0.90451 0.50000 1.00000 0.79389 0.90451 0.97553 0.65451 0.97553 0.34549 0.79389 0.09549
5 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5
11 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11
0.50000 0.00000 0.22968 0.07937 0.04518 0.29229 0.00509 0.57116 0.12213 0.82743 0.35913 0.97975 0.64087 0.97975 0.87787 0.82743 0.99491 0.57116 0.95482 0.29229 0.77032 0.07937
0.50000 0.00000 0.02447 0.34549 0.20611 0.90451 0.79389 0.90451 0.97553 0.34549
6 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6
12 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12
0.50000 0.00000 0.25000 0.06699 0.06699 0.25000 0.00000 0.50000 0.06699 0.75000 0.25000 0.93301 0.50000 1.00000 0.75000 0.93301 0.93301 0.75000 1.00000 0.50000 0.93801 0.25000 0.75000 0.06699
0.50000 0.00000 0.06699 0.25000 0.06699 0.75000 0.50000 1.00000 0.93301 0.75000 0.93301 0.25000
7 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7
13 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13
0.50000 0.00000 0.26764 0.05727 0.08851 0.21597 0.00365 0.43973 0.03249 0.67730 0.16844 0.87426 0.38034 0.98547 0.61966 0.98547 0.83156 0.87426 0.96751 0.67730 0.99635 0.43973 0.91149 0.21597 0.73236 0.05727
0.50000 0.00000 0.10908 0.18826 0.01254 0.61126 0.28306 0.95048 0.71694 0.95048 0.98746 0.61126 0.89092 0.18826
8 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8
14 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14
0.50000 0.00000 0.28306 0.04952 0.10908 0.18826 0.01254 0.38874 0.01254 0.61126 0.10908 0.81174 0.28306 0.95048 0.50000 1.00000 0.71694 0.95048 0.89092 0.81174 0.98746 0.61126 0.98746 0.38874 0.89092 0.18826 0.71694 0.04952
0.50000 0.00000 0.14645 0.14645 0.00000 0.50000 0.14645 0.85355 0.50000 1.00000 0.85355 0.85355 1.00000 0.50000 0.85355 0.14645
9 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9
15 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15
0.50000 0.00000 0.29663 0.04323 0.12843 0.16543 0.02447 0.34549 0.00274 0.55226 0.06699 0.75000 0.20611 0.90451 0.39604 0.98907 0.60396 0.98907 0.79389 0.90451 0.93301 0.75000 0.99726 0.55226 0.97553 0.34549 0.87157 0.16543 0.70337 0.04323
Copyright 2004, Industrial Press, Inc., New York, NY
x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16
0.50000 0.00000 0.17861 0.11698 0.00760 0.41318 0.06699 0.75000 0.32899 0.96985 0.67101 0.96985 0.93301 0.75000 0.99240 0.41318 0.82139 0.11698 16 Holes 0.50000 0.00000 0.30866 0.03806 0.14645 0.14645 0.03806 0.30866 0.00000 0.50000 0.03806 0.69134 0.14645 0.85355 0.30866 0.96194 0.50000 1.00000 0.69134 0.96194 0.85355 0.85355 0.96194 0.69134 1.00000 0.50000 0.96194 0.30866 0.85355 0.14645 0.69134 0.03806
Machinery's Handbook 27th Edition 994
JIG BORING Table 12. (Continued) Hole Coordinate Dimension Factors for Jig Boring — Type “A” Hole Circles (English or Metric Units)
The diagram shows a type “A” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
17 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17
0.50000 0.00000 0.31938 0.03376 0.16315 0.13050 0.05242 0.27713 0.00213 0.45387 0.01909 0.63683 0.10099 0.80132 0.23678 0.92511 0.40813 0.99149 0.59187 0.99149 0.76322 0.92511 0.89901 0.80132 0.98091 0.63683 0.99787 0.45387 0.94758 0.27713 0.83685 0.13050 0.68062 0.03376
18 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18
24Holes x1 y1 x2 y2 x3
0.50000 0.00000 0.37059 0.01704 0.25000
0.50000 0.00000 0.32899 0.03015 0.17861 0.11698 0.06699 0.25000 0.00760 0.41318 0.00760 0.58682 0.06699 0.75000 0.17861 0.88302 0.32899 0.96985 0.50000 1.00000 0.67101 0.96985 0.82139 0.88302 0.93301 0.75000 0.99240 0.58682 0.99240 0.41318 0.93301 0.25000 0.82139 0.11698 0.67101 0.03015
19 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19
25 Holes x1 y1 x2 y2 x3
0.50000 0.00000 0.37566 0.01571 0.25912
0.50000 0.00000 0.33765 0.02709 0.19289 0.10543 0.08142 0.22653 0.01530 0.37726 0.00171 0.54129 0.04211 0.70085 0.13214 0.83864 0.26203 0.93974 0.41770 0.99318 0.58230 0.99318 0.73797 0.93974 0.86786 0.83864 0.95789 0.70085 0.99829 0.54129 0.98470 0.37726 0.91858 0.22658 0.80711 0.10543 0.66235 0.02709
20 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20
26 Holes x1 y1 x2 y2 x3
0.50000 0.00000 0.38034 0.01453 0.26764
0.50000 0.00000 0.34549 0.02447 0.20611 0.09549 0.09549 0.20611 0.02447 0.34549 0.00000 0.50000 0.02447 0.65451 0.09549 0.79389 0.20611 0.90451 0.34549 0.97553 0.50000 1.00000 0.65451 0.97553 0.79389 0.90451 0.90451 0.79389 0.97553 0.65451 1.00000 0.50000 0.97553 0.34549 0.90451 0.20611 0.79389 0.09549 0.65451 0.02447
21 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21
27 Holes x1 y1 x2 y2 x3
0.50000 0.00000 0.38469 0.01348 0.27560
0.50000 0.00000 0.35262 0.02221 0.21834 0.08688 0.10908 0.18826 0.03456 0.31733 0.00140 0.46263 0.01254 0.61126 0.06699 0.75000 0.15991 0.86653 0.28306 0.95048 0.42548 0.99442 0.57452 0.99442 0.71694 0.95048 0.84009 0.86653 0.93301 0.75000 0.98746 0.61126 0.99860 0.46263 0.96544 0.31733 0.89092 0.18826 0.78166 0.08688 0.64738 0.02221
22 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22
0.50000 0.00000 0.35913 0.02025 0.22968 0.07937 0.12213 0.17257 0.04518 0.29229 0.00509 0.42884 0.00509 0.57116 0.04518 0.70771 0.12213 0.82743 0.22968 0.92063 0.35913 0.97975 0.50000 1.00000 0.64087 0.97975 0.77032 0.92063 0.87787 0.82743 0.95482 0.70771 0.99491 0.57116 0.99491 0.42884 0.95482 0.29229 0.87787 0.17257 0.77032 0.07937 0.64087 0.02025
28 Holes x1 y1 x2 y2 x3
0.50000 0.00000 0.38874 0.01254 0.28306
Copyright 2004, Industrial Press, Inc., New York, NY
23 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23
0.50000 0.00000 0.36510 0.01854 0.24021 0.07279 0.13458 0.15872 0.05606 0.26997 0.01046 0.39827 0.00117 0.53412 0.02887 0.66744 0.09152 0.78834 0.18446 0.88786 0.30080 0.95861 0.43192 0.99534 0.56808 0.99534 0.69920 0.95861 0.81554 0.88786 0.90848 0.78834 0.97113 0.66744 0.99883 0.53412 0.98954 0.39827 0.94394 0.26997 0.86542 0.15872 0.75979 0.07279 0.63490 0.01854
Machinery's Handbook 27th Edition JIG BORING
995
Table 12. (Continued) Hole Coordinate Dimension Factors for Jig Boring — Type “A” Hole Circles (English or Metric Units)
The diagram shows a type “A” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
24Holes y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24
0.06699 0.14645 0.14645 0.06699 0.25000 0.01704 0.37059 0.00000 0.50000 0.01704 0.62941 0.06699 0.75000 0.14645 0.85355 0.25000 0.93301 0.37059 0.98296 0.50000 1.00000 0.62941 0.98296 0.75000 0.93301 0.85355 0.85355 0.93301 0.75000 0.98296 0.62941 1.00000 0.50000 0.98296 0.37059 0.93301 0.25000 0.85355 0.14645 0.75000 0.6699 0.62941 0.01704
25 Holes y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25
0.06185 0.15773 0.13552 0.07784 0.23209 0.02447 0.34549 0.00099 0.46860 0.00886 0.59369 0.04759 0.71289 0.11474 0.81871 0.20611 0.90451 0.31594 0.96489 0.43733 0.99606 0.56267 0.99606 0.68406 0.96489 0.79389 0.90451 0.88526 0.81871 0.95241 0.71289 0.99114 0.59369 0.99901 0.46860 0.97553 0.34549 0.92216 0.23209 0.84227 0.13552 0.74088 0.06185 0.62434 0.01571
26 Holes y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25 x26 y26
0.05727 0.16844 0.12574 0.08851 0.21597 0.03249 0.32270 0.00365 0.43973 0.00365 0.56027 0.03249 0.67730 0.08851 0.78403 0.16844 0.87426 0.26764 0.94273 0.38034 0.98547 0.50000 1.00000 0.61966 0.98547 0.73236 0.94273 0.83156 0.87426 0.91149 0.78403 0.96751 0.67730 0.99635 0.56027 0.99635 0.43973 0.96751 0.32270 0.91149 0.21597 0.83156 0.12574 0.73236 0.05727 0.61966 0.01453
27 Holes y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25 x26 y26 x27 y27
0.05318 0.17861 0.11698 0.09894 0.20142 0.04089 0.30196 0.00760 0.41318 0.00085 0.52907 0.02101 0.64340 0.06699 0.75000 0.13631 0.84312 0.22525 0.91774 0.32899 0.96985 0.44195 0.99662 0.55805 0.99662 0.67101 0.96985 0.77475 0.91774 0.86369 0.84312 0.93301 0.75000 0.97899 0.64340 0.99915 0.52907 0.99240 0.41318 0.95911 0.30196 0.90106 0.20142 0.82139 0.11698 0.72440 0.05318 0.61531 0.01348
28 Holes y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25 x26 y26 x27 y27 x28 y28
0.04952 0.18826 0.10908 0.10908 0.18826 0.04952 0.28306 0.01254 0.38874 0.00000 0.50000 0.01254 0.61126 0.04952 0.71694 0.10908 0.81174 0.18826 0.89092 0.28306 0.95048 0.38874 0.98746 0.50000 1.00000 0.61126 0.98746 0.71694 0.95048 0.81174 0.89092 0.89092 0.81174 0.95048 0.71694 0.98746 0.61126 1.00000 0.50000 0.98746 0.38874 0.95048 0.28306 0.89092 0.18826 0.81174 0.10908 0.71694 0.04952 0.61126 0.01254
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 996
JIG BORING Table 13. Hole Coordinate Dimension Factors for Jig Boring — Type “B” Hole Circles (English or Metric Units)
The diagram shows a type “B” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
3 Holes x1 y1 x2 y2 x3 y3
0.06699 0.25000 0.50000 1.00000 0.93301 0.25000
4 Holes x1 y1 x2 y2 x3 y3 x4 y4
0.14645 0.14645 0.14645 0.85355 0.85355 0.85355 0.85355 0.14645
10 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10
0.34549 0.02447 0.09549 0.20611 0.00000 0.50000 0.09549 0.79389 0.34549 0.97553 0.65451 0.97553 0.90451 0.79389 1.00000 0.50000 0.90451 0.20611 0.65451 0.02447
5 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5
11 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11
0.35913 0.02025 0.12213 0.17257 0.00509 0.42884 0.04518 0.70771 0.22968 0.92063 0.50000 1.00000 0.77032 0.92063 0.95482 0.70771 0.99491 0.42884 0.87787 0.17257 0.64087 0.02025
0.20611 0.09549 0.02447 0.65451 0.50000 1.00000 0.97553 0.65451 0.79389 0.09549
6 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6
12 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12
0.37059 0.01704 0.14645 0.14645 0.01704 0.37059 0.01704 0.62941 0.14645 0.85355 0.37059 0.98296 0.62941 0.98296 0.85355 0.85355 0.98296 0.62941 0.98296 0.37059 0.85355 0.14645 0.62941 0.01704
0.25000 0.06699 0.00000 0.50000 0.25000 0.93301 0.75000 0.93301 1.00000 0.50000 0.75000 0.06699
7 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7
13 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13
0.38034 0.01453 0.16844 0.12574 0.03249 0.32270 0.00365 0.56027 0.08851 0.78403 0.26764 0.94273 0.50000 1.00000 0.73236 0.94273 0.91149 0.78403 0.99635 0.56027 0.96751 0.32270 0.83156 0.12574 0.61966 0.01453
0.28306 0.04952 0.01254 0.38874 0.10908 0.81174 0.50000 1.00000 0.89092 0.81174 0.98746 0.38874 0.71694 0.04952
8 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8
14 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14
0.38874 0.01254 0.18826 0.10908 0.04952 0.28306 0.00000 0.50000 0.04952 0.71694 0.18826 0.89092 0.38874 0.98746 0.61126 0.98746 0.81174 0.89092 0.95048 0.71694 1.00000 0.50000 0.95048 0.28306 0.81174 0.10908 0.61126 0.01254
0.30866 0.03806 0.03806 0.30866 0.03806 0.69134 0.30866 0.96194 0.69134 0.96194 0.96194 0.69134 0.96194 0.30866 0.69134 0.03806
9 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9
15 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15
0.39604 0.01093 0.20611 0.09549 0.06699 0.25000 0.00274 0.44774 0.02447 0.65451 0.12843 0.83457 0.29663 0.95677 0.50000 1.00000 0.70337 0.95677 0.87157 0.83457 0.97553 0.65451 0.99726 0.44774 0.93301 0.25000 0.79389 0.09549 0.60396 0.01093
Copyright 2004, Industrial Press, Inc., New York, NY
x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16
0.32899 0.03015 0.06699 0.25000 0.00760 0.58682 0.17861 0.88302 0.50000 1.00000 0.82139 0.88302 0.99240 0.58682 0.93301 0.25000 0.67101 0.03015 16 Holes 0.40245 0.00961 0.22221 0.08427 0.08427 0.22221 0.00961 0.40245 0.00961 0.59755 0.08427 0.77779 0.22221 0.91573 0.40245 0.99039 0.59755 0.99039 0.77779 0.91573 0.91573 0.77779 0.99039 0.59755 0.99039 0.40245 0.91573 0.22221 0.77779 0.08427 0.59755 0.00961
Machinery's Handbook 27th Edition JIG BORING
997
Table 13. (Continued) Hole Coordinate Dimension Factors for Jig Boring — Type “B” Hole Circles (English or Metric Units)
The diagram shows a type “B” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
17 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17
0.40813 0.00851 0.23678 0.07489 0.10099 0.19868 0.01909 0.36317 0.00213 0.54613 0.05242 0.72287 0.16315 0.86950 0.31938 0.96624 0.50000 1.00000 0.68062 0.96624 0.83685 0.86950 0.94758 0.72287 0.99787 0.54613 0.98091 0.36317 0.89901 0.19868 0.76322 0.07489 0.59187 0.00851
18 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18
24 Holes
0.41318 0.00760 0.25000 0.06699 0.11698 0.17861 0.03015 0.32899 0.00000 0.50000 0.03015 0.67101 0.11698 0.82139 0.25000 0.93301 0.41318 0.99240 0.58682 0.99240 0.75000 0.93301 0.88302 0.82139 0.96985 0.67101 1.00000 0.50000 0.96985 0.32899 0.88302 0.17861 0.75000 0.06699 0.58682 0.00760
19 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19
25 Holes
0.41770 0.00682 0.26203 0.06026 0.13214 0.16136 0.04211 0.29915 0.00171 0.45871 0.01530 0.62274 0.08142 0.77347 0.19289 0.89457 0.33765 0.97291 0.50000 1.00000 0.66235 0.97291 0.80711 0.89457 0.91858 0.77347 0.98470 0.62274 0.99829 0.45871 0.95789 0.29915 0.86786 0.16136 0.73797 0.06026 0.58230 0.00682
20 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20
26 Holes
0.42178 0.00616 0.27300 0.05450 0.14645 0.14645 0.05450 0.27300 0.00616 0.42178 0.00616 0.57822 0.05450 0.72700 0.14645 0.85355 0.27300 0.94550 0.42178 0.99384 0.57822 0.99384 0.72700 0.94550 0.85355 0.85355 0.94550 0.72700 0.99384 0.57822 0.99384 0.42178 0.94550 0.27300 0.85355 0.14645 0.72700 0.05450 0.57822 0.00616
21 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21
27 Holes
0.42548 0.00558 0.28306 0.04952 0.15991 0.13347 0.06699 0.25000 0.01254 0.38874 0.00140 0.53737 0.03456 0.68267 0.10908 0.81174 0.21834 0.91312 0.35262 0.97779 0.50000 1.00000 0.64738 0.97779 0.78166 0.91312 0.89092 0.81174 0.96544 0.68267 0.99860 0.53737 0.98746 0.38874 0.93301 0.25000 0.84009 0.13347 0.71694 0.04952 0.57452 0.00558
22 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22
0.42884 0.00509 0.29229 0.04518 0.17257 0.12213 0.07937 0.22968 0.02025 0.35913 0.00000 0.50000 0.02025 0.64087 0.07937 0.77032 0.17257 0.87787 0.29229 0.95482 0.42884 0.99491 0.57116 0.99491 0.70771 0.95482 0.82743 0.87787 0.92063 0.77032 0.97975 0.64087 1.00000 0.50000 0.97975 0.35913 0.92063 0.22968 0.82743 0.12213 0.70771 0.04518 0.57116 0.00509
28 Holes
x1 y1 x2 y2 x3
0.43474 0.00428 0.30866 0.03806 0.19562
x1 y1 x2 y2 x3
0.43733 0.00394 0.31594 0.03511 0.20611
x1 y1 x2 y2 x3
0.43973 0.00365 0.32270 0.03249 0.21597
x1 y1 x2 y2 x3
0.44195 0.00338 0.32899 0.03015 0.22525
x1 y1 x2 y2 x3
0.44402 0.00314 0.33486 0.02806 0.23398
y3
0.10332
y3
0.09549
y3
0.08851
y3
0.08226
y3
0.07664
Copyright 2004, Industrial Press, Inc., New York, NY
23 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23
0.43192 0.00466 0.30080 0.04139 0.18446 0.11214 0.09152 0.21166 0.02887 0.33256 0.00117 0.46588 0.01046 0.60173 0.05606 0.73003 0.13458 0.84128 0.24021 0.92721 0.36510 0.98146 0.50000 1.00000 0.63490 0.98146 0.75979 0.92721 0.86542 0.84128 0.94394 0.73003 0.98954 0.60173 0.99883 0.46588 0.97113 0.33256 0.90848 0.21166 0.81554 0.11214 0.69920 0.04139 0.56808 0.00466
Machinery's Handbook 27th Edition 998
JIG BORING Table 13. (Continued) Hole Coordinate Dimension Factors for Jig Boring — Type “B” Hole Circles (English or Metric Units)
The diagram shows a type “B” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24
24 Holes 0.10332 0.19562 0.03806 0.30866 0.00428 0.43474 0.00428 0.56526 0.03806 0.69134 0.10332 0.80438 0.19562 0.89668 0.30866 0.96194 0.43474 0.99572 0.56526 0.99572 0.69134 0.96194 0.80438 0.89668 0.89668 0.80438 0.96194 0.69134 0.99572 0.56526 0.99572 0.43474 0.96194 0.30866 0.89668 0.19562 0.80438 0.10332 0.69134 0.03806 0.56526 0.00428
x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25
25 Holes 0.11474 0.18129 0.04759 0.28711 0.00886 0.40631 0.00099 0.53140 0.02447 0.65451 0.07784 0.76791 0.15773 0.86448 0.25912 0.93815 0.37566 0.98429 0.50000 1.00000 0.62434 0.98429 0.74088 0.93815 0.84227 0.86448 0.92216 0.76791 0.97553 0.65451 0.99901 0.53140 0.99114 0.40631 0.95241 0.28711 0.88526 0.18129 0.79389 0.09549 0.68406 0.03511 0.56267 0.00394
x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25 x26 y26
26 Holes 0.12574 0.16844 0.05727 0.26764 0.01453 0.38034 0.00000 0.50000 0.01453 0.61966 0.05727 0.73236 0.12574 0.83156 0.21597 0.91149 0.32270 0.96751 0.43973 0.99635 0.56027 0.99635 0.67730 0.96751 0.78403 0.91149 0.87426 0.83156 0.94273 0.73236 0.98547 0.61966 1.00000 0.50000 0.98547 0.38034 0.94273 0.26764 0.87426 0.16844 0.78403 0.08851 0.67730 0.03249 0.56027 0.00365
x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25 x26 y26 x27 y27
27 Holes 0.13631 0.15688 0.06699 0.25000 0.02101 0.35660 0.00085 0.47093 0.00760 0.58682 0.04089 0.69804 0.09894 0.79858 0.17861 0.88302 0.27560 0.94682 0.38469 0.98652 0.50000 1.00000 0.61531 0.98652 0.72440 0.94682 0.82139 0.88302 0.90106 0.79858 0.95911 0.69804 0.99240 0.58682 0.99915 0.47093 0.97899 0.35660 0.93301 0.25000 0.86369 0.15688 0.77475 0.08226 0.67101 0.03015 0.55805 0.00338
x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25 x26 y26 x27 y27 x28 y28
28 Holes 0.14645 0.14645 0.07664 0.23398 0.02806 0.33486 0.00314 0.44402 0.00314 0.55598 0.02806 0.66514 0.07664 0.76602 0.14645 0.85355 0.23398 0.92336 0.33486 0.97194 0.44402 0.99686 0.55598 0.99686 0.66514 0.97194 0.76602 0.92336 0.85355 0.85355 0.92336 0.76602 0.97194 0.66514 0.99686 0.55598 0.99686 0.44402 0.97194 0.33486 0.92336 0.23398 0.85355 0.14645 0.76602 0.07664 0.66514 0.02806 0.55598 0.00314
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition JIG BORING
999
Table 14. Hole Coordinate Dimension Factors for Jig Boring — Type “A” Hole Circles, Central Coordinates (English or Metric Units)
The diagram shows a type “A” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
3 Holes x1 y1 x2 y2 x3 y3
0.00000 −0.50000 −0.43301 +0.25000 +0.43301 +0.25000
4 Holes x1 y1 x2 y2 x3 y3 x4 y4
0.00000 −0.50000 −0.50000 0.00000 0.00000 +0.50000 +0.50000 0.00000
10 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10
0.00000 −0.50000 −0.29389 −0.40451 −0.47553 −0.15451 −0.47553 +0.15451 −0.29389 +0.40451 0.00000 +0.50000 +0.29389 +0.40451 +0.47553 +0.15451 +0.47553 −0.15451 +0.29389 −0.40451
5 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5
11 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11
0.00000 −0.5000 −0.27032 −0.42063 −0.45482 −0.20771 −0.49491 +0.07116 −0.37787 +0.32743 −0.14087 +0.47975 +0.14087 +0.47975 +0.37787 +0.32743 +0.49491 +0.07116 +0.45482 −0.20771 +0.27032 −0.42063
0.00000 −0.50000 −0.47553 −0.15451 −0.29389 +0.40451 +0.29389 +0.40451 +0.47553 −0.15451
6 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6
12 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12
0.00000 −0.50000 −0.25000 −0.43301 −0.43301 −0.25000 −0.50000 0.00000 −0.43301 +0.25000 −0.25000 +0.43301 0.00000 +0.50000 +0.25000 +0.43301 +0.43301 +0.25000 +0.50000 0.00000 +0.43301 −0.25000 +0.25000 −0.43301
0.00000 −0.50000 −0.43301 −0.25000 −0.43301 +0.25000 0.00000 +0.50000 +0.43301 +0.25000 +0.43301 −0.25000
7 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7
13 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13
0.00000 −0.50000 −0.23236 −0.44273 −0.41149 −2.28403 −0.49635 −0.06027 −0.46751 +0.17730 − 0.33156 +0.37426 −0.11966 +0.48547 +0.11966 +0.48547 +0.33156 +0.37426 +0.46751 +0.17730 +0.49635 −0.06027 +0.41149 −0.28403 +0.23236 −0.44273
0.00000 −0.50000 −0.39092 −0.31174 −0.48746 +0.11126 −0.21694 +0.45048 +0.21694 +0.45048 +0.48746 +0.11126 +0.39092 −0.31174
8 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8
14 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14
0.00000 −0.50000 −0.21694 −0.45048 −0.39092 −0.31174 −0.48746 −0.11126 −0.48746 +0.11126 −0.39092 +0.31174 −0.21694 +0.45048 0.00000 +0.50000 +0.21694 +0.45048 +0.39092 +0.31174 +0.48746 +0.11126 +0.48746 −0.11126 +0.39092 −0.31174 +0.21694 −0.45048
0.00000 −0.50000 −0.35355 −0.35355 −0.50000 0.00000 −0.35355 +0.35355 0.00000 +0.50000 +0.35355 +0.35355 +0.50000 0.00000 +0.35355 −0.35355
9 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9
15 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5
0.00000 −0.50000 −0.20337 −0.45677 −0.37157 −0.33457 −0.47553 −0.15451 −0.49726 y5 +0.05226 x6 −0.43301 y6 +0.25000 x7 −0.29389 y7 +0.40451 x8 −0.10396 y8 +0.48907 x9 +0.10396 y9 +0.48907 x10 +0.29389 y10 +0.40451 x11 +0.43301 y11 +0.25000 x12 +0.49726 y12 +0.05226 x13 +0.47553 y13 −0.15451 x14 +0.37157 y14 −0.33457 x15 +0.20337 y15 −0.45677
Copyright 2004, Industrial Press, Inc., New York, NY
x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16
0.00000 −0.50000 −0.32139 −0.38302 −0.49240 −0.08682 −0.43301 +0.25000 −0.17101 +0.46985 +0.17101 +0.46985 +0.43301 +0.25000 +0.49240 −0.08682 +0.32139 −0.38302 16 Holes 0.00000 −0.50000 −0.19134 −0.46194 −0.35355 −0.35355 −0.46194 −0.19134 −0.50000 0.00000 −0.46194 +0.19134 −0.35355 +0.35355 −0.19134 +0.46194 0.00000 +0.50000 +0.19134 +0.46194 +0.35355 +0.35355 +0.46194 +0.19134 +0.50000 0.00000 +0.46194 −0.19134 +0.35355 −0.35355 +0.19134 −0.46194
Machinery's Handbook 27th Edition 1000
JIG BORING
Table 14. (Continued) Hole Coordinate Dimension Factors for Jig Boring — Type “A” Hole Circles, Central Coordinates (English or Metric Units)
The diagram shows a type “A” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
17 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17
0.00000 −0.50000 −0.18062 −0.46624 −0.33685 −0.36950 −0.44758 −0.22287 −0.49787 −0.04613 −0.48091 +0.13683 −0.39901 +0.30132 −0.26322 +0.42511 −0.09187 +0.49149 +0.09187 +0.49149 +0.26322 +0.42511 +0.39901 +0.30132 +0.48091 +0.13683 +0.49787 −0.04613 +0.44758 −0.22287 +0.33685 −0.36950 +0.18062 −0.46624
18 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18
24 Holes
0.00000 −0.50000 −0.17101 −0.46985 +0.32139 −0.38302 −0.43301 −0.25000 −0.49240 −0.08682 −0.49420 +0.08682 −0.43301 +0.25000 −0.32139 +0.38302 −0.17101 +0.46985 0.00000 +0.50000 +0.17101 +0.46985 +0.32139 +0.38302 +0.43301 +0.25000 +0.49240 +0.08682 +0.49240 −0.08682 +0.43301 −0.25000 +0.32139 −0.38302 +0.17101 −0.46985
19 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19
25 Holes
x1 y1 x2 y2 x3
0.00000 −0.50000 −0.12941 −0.48296 −0.25000
x1 y1 x2 y2 x3
y3
− 0.43301 y3
0.00000 −0.50000 −0.12434 −0.48429 −0.24088
0.00000 −0.50000 −0.16235 −0.47291 −0.30711 −0.39457 −0.41858 −0.27347 −0.48470 −0.12274 −0.49829 +0.04129 −0.45789 +0.20085 −0.36786 +0.33864 −0.23797 +0.43974 −0.08230 +0.49318 +0.08230 +0.49318 +0.23797 +0.43974 +0.36786 +0.33864 +0.45789 +0.20085 +0.49829 +0.04129 +0.48470 −0.12274 +0.41858 −0.27347 +0.30711 −0.39457 + 0.16235 −0.47291
20 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20
26 Holes x1 y1 x2 y2 x3
−0.43815 y3
0.00000 −0.50000 −0.11966 −0.48547 −0.23236
0.000000 −0.50000 −0.15451 −0.47553 −0.29389 −0.40451 −0.40451 −0.29389 −0.47553 −0.15451 −0.50000 0.00000 −0.47553 +0.15451 −0.40451 +0.29389 −0.29389 +0.40451 −0.15451 +0.47553 0.00000 +0.50000 +0.15451 +0.47553 +0.29389 +0.40451 +0.40451 +0.29389 +0.47553 +0.15451 +0.50000 0.00000 +0.47553 −0.15451 +0.40451 −0.29389 +0.29389 −0.40451 +0.15451 −0.47553
21 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21
27 Holes x1 y1 x2 y2 x3
−0.44273 y3
0.00000 −0.50000 −0.11531 −0.48652 −0.22440
0.00000 −0.50000 −0.14738 −0.47779 −0.28166 −0.41312 −0.39092 −0.31174 −.046544 −0.18267 −0.49860 −0.03737 −0.48746 +0.11126 −0.43301 +0.25000 −0.34009 +0.36653 −0.21694 +0.45048 −0.07452 +0.49442 +0.07452 +0.49442 +0.21694 +0.45048 +0.34009 +0.36653 +0.43301 +0.25000 +0.48746 +0.11126 +0.49860 −0.03737 +0.46544 −0.18267 +0.39092 −0.31174 +0.28166 −0.41312 +0.14738 −0.47779
22 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22
0.00000 −0.50000 −0.14087 −0.47975 −0.27032 −0.42063 −0.37787 −0.32743 −0.45482 −0.20771 −0.49491 −0.07116 −0.49491 +0.07116 −0.45482 +0.20771 −0.37787 +0.32743 −0.27032 +0.42063 −0.14087 +0.47975 0.00000 +0.50000 +0.14087 +0.47975 +0.27032 +0.42063 +0.37787 +0.32743 +0.45482 +0.20771 +0.49491 +0.07116 +0.49491 −0.07116 +0.45482 −0.20771 +0.37787 −0.32743 +0.27032 −0.42063 +0.14087 −0.47975
28 Holes x1 y1 x2 y2 x3
0.00000 −0.50000 −0.11126 −0.48746 −0.21694
−0.44682 y3
−0.45048
Copyright 2004, Industrial Press, Inc., New York, NY
23 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23
0.00000 −0.50000 −0.13490 −0.48146 −0.25979 −0.42721 −0.36542 −0.34128 −0.44394 −0.23003 −0.48954 −0.10173 −0.49883 +0.03412 −0.47113 +0.16744 −0.40848 +0.28834 −0.31554 +0.38786 −0.19920 +0.45861 −0.06808 +0.49534 +0.06808 +0.49534 +0.19920 +0.45861 +0.31554 +0.38786 +0.40848 +0.28834 +0.47113 +0.16744 +0.49883 +0.03412 +0.48954 −0.10173 +0.44394 −0.23003 +0.36542 −0.34128 +0.25979 −0.42721 +0.13490 −0.48146
Machinery's Handbook 27th Edition JIG BORING
1001
Table 14. (Continued) Hole Coordinate Dimension Factors for Jig Boring — Type “A” Hole Circles, Central Coordinates (English or Metric Units)
The diagram shows a type “A” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24
24 Holes −0.35355 −0.35355 −0.43301 −0.25000 −0.48296 −0.12941 −0.50000 0.00000 −0.48296 +0.12941 −0.43301 +0.25000 −0.35355 +0.35355 −0.25000 +0.43301 −0.12941 +0.48296 0.00000 +0.50000 +0.12941 +0.48296 +0.25000 +0.43301 +0.35355 +0.35355 +0.43301 +0.25000 +0.48296 +0.12941 +0.50000 0.00000 +0.48296 −0.12941 +0.43301 −0.25000 +0.35355 −0.35355 +0.25000 −0.43301 +0.12941 −0.48296
x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25
25 Holes −0.34227 −0.36448 −0.42216 −0.26791 −0.47553 −0.15451 −0.49901 −0.03140 −0.49114 +0.09369 −0.45241 +0.21289 −0.38526 +0.31871 −0.29389 +0.40451 −0.18406 +0.46489 −0.06267 +0.49606 +0.06267 +0.49606 +0.18406 +0.46489 +0.29389 +0.40451 + 0.38526 +0.31871 +0.45241 +0.21289 +0.49114 +0.09369 +0.49901 −0.03140 +0.47553 −0.15451 +0.42216 −0.26791 +0.34227 −0.36448 +0.24088 −0.43815 +0.12434 −0.48429
x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25 x26 y26
26 Holes −0.33156 −0.37426 −0.41149 −0.28403 −0.46751 −0.17730 −0.49635 −0.06027 −0.49635 +0.06027 −0.46751 +0.17730 −0.41149 +0.28403 −0.33156 +0.37426 −0.23236 +0.44273 −0.11966 +0.48547 0.00000 +0.50000 +0.11966 +0.48547 +0.23236 +0.44273 +0.33156 +0.37426 +0.41149 +0.28403 +0.46751 +0.17730 +0.49635 +0.06027 +0.49635 −0.06027 +0.46751 −0.17730 +0.41149 −0.28403 +0.33156 −0.37426 +0.23236 −0.44273 +0.11966 −0.48547
x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25 x26 y26 x27 y27
27 Holes −0.32139 −0.38302 −0.40106 −0.29858 −0.45911 −0.19804 −0.49240 −0.08682 −0.49915 +0.02907 −0.47899 +0.14340 −0.43301 +0.25000 −0.36369 +0.34312 −0.27475 +0.41774 −0.17101 +0.46985 −0.05805 +0.49662 +0.05805 +0.49662 +0.17101 +0.46985 +0.27475 +0.41774 +0.36369 +0.34312 +0.43301 +0.25000 +0.47899 +0.14340 +0.49915 +0.02907 +0.49240 −0.08682 +0.45911 −0.19804 +0.40106 −0.29858 +0.32139 −0.38302 +0.22440 −0.44682 +0.11531 −0.48652
x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9 x10 y10 x11 y11 x12 y12 x13 y13 x14 y14 x15 y15 x16 y16 x17 y17 x18 y18 x19 y19 x20 y20 x21 y21 x22 y22 x23 y23 x24 y24 x25 y25 x26 y26 x27 y27 x28 y28
28 Holes −0.31174 −0.39092 −0.39092 −0.31174 −0.45048 −0.21694 −0.48746 −0.11126 −0.50000 0.00000 −0.48746 +0.11126 −0.45048 +0.21694 −0.39092 +0.31174 −0.31174 +0.39092 −0.21694 +0.45048 −0.11126 +0.48746 0.00000 +0.50000 +0.11126 +0.48746 +0.21694 +0.45048 +0.31174 +0.39092 +0.39092 +0.31174 +0.45048 +0.21694 +0.48746 +0.11126 +0.50000 0.00000 +0.48746 −0.11126 +0.45048 −0.21694 +0.39092 −0.31174 +0.31174 −0.39092 +0.21694 −0.45048 +0.11126 −0.48746
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1002
JIG BORING Table 15. Hole Coordinate Dimension Factors for Jig Boring — Type “B” Hole Circles Central Coordinates (English or Metric units)
The diagram shows a type “B” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
3 Holes x1 y1 x2 y2 x3 y3
−0.43301 −0.25000 0.00000 +0.50000 +0.43301 −0.25000
10 Holes x1 −0.15451 y1 −0.47553 x2 −0.40451 y2 −0.29389 x3 −0.50000 y3 0.00000 x4 −0.40451 y4 +0.29389 x5 −0.15451 y5 +0.47553 x6 +0.15451 y6 +0.47553 x7 +0.40451 y7 +0.29389 x8 +0.50000 y8 0.00000 x9 +0.40451 y9 −0.29389 x10 +0.15451 y10 −0.47553
4 Holes x1 y1 x2 y2 x3 y3 x4 y4
−0.35355 −0.35355 −0.35355 +0.35355 +0.35355 +0.35355 +0.35355 −0.35355
11 Holes x1 −0.14087 y1 −0.47975 x2 −0.37787 y2 −0.32743 x3 −0.49491 y3 −0.07116 x4 −0.45482 y4 +0.20771 x5 −0.27032 y5 +0.42063 x6 0.00000 y6 +0.50000 x7 +0.27032 y7 +0.42063 x8 +0.45482 y8 +0.20771 x9 +0.49491 y9 −0.07116 x10 +0.37787 y10 −0.32743 x11 +0.14087 y11 −0.47975
5 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5
−0.29389 −0.40451 −0.47553 +0.15451 0.00000 +0.50000 +0.47553 +0.15451 +0.29389 −0.40451
12 Holes x1 −0.12941 y1 −0.48296 x2 −0.35355 y2 −0.35355 x3 −0.48296 y3 −0.12941 x4 −0.48296 y4 +0.12941 x5 −0.35355 y5 +0.35355 x6 −0.12941 y6 +0.48296 x7 +0.12941 y7 +0.48296 x8 +0.35355 y8 +0.35355 x9 +0.48296 y9 +0.12941 x10 +0.48296 y10 −0.12941 x11 +0.35355 y11 −0.35355 x12 +0.12941 y12 −0.48296
6 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6
−0.25000 −0.43301 −0.50000 0.00000 −0.25000 +0.43301 +0.25000 +0.43301 +0.50000 0.00000 +0.25000 −0.43301
13 Holes x1 −0.11966 y1 −0.48547 x2 −0.33156 y2 −0.37426 x3 −0.46751 y3 −0.17730 x4 −0.49635 y4 +0.06027 x5 −0.41149 y5 +0.28403 x6 −0.23236 y6 +0.44273 x7 0.00000 y7 + 0.50000 x8 +0.23236 y8 +0.44273 x9 +0.41149 y9 +0.28403 x10 +0.49635 y10 +0.06027 x11 +0.46751 y11 −0.17730 x12 +0.33156 y12 −0.37426 x13 +0.11966 y13 −0.48547
7 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7
−0.21694 −0.45048 −0.48746 −0.11126 −0.39092 +0.31174 0.00000 +0.50000 +0.39092 +0.31174 +0.48746 −0.11126 +0.21694 −0.45048
14 Holes x1 −0.11126 y1 −0.48746 x2 −0.31174 y2 −0.39092 x3 −0.45048 y3 −0.21694 x4 −0.50000 y4 0.00000 x5 −0.45048 y5 +0.21694 x6 −0.31174 y6 +0.39092 x7 −0.11126 y7 +0.48746 x8 +0.11126 y8 +0.48746 x9 +0.31174 y9 +0.39092 x10 +0.45048 y10 +0.21694 x11 +0.50000 y11 0.00000 x12 +0.45048 y12 −0.21694 x13 +0.31174 y13 −0.39092 x14 +0.11126 y14 − 0.48746
8 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8
−0.19134 −0.46194 −0.46194 −0.19134 −0.46194 +0.19134 −0.19134 +0.46194 +0.19134 +0.46194 +0.46194 +0.19134 +0.46194 −0.19134 +0.19134 −0.46194
15 Holes x1 −0.10396 y1 −0.48907 x2 −0.29389 y2 −0.40451 x3 −0.43301 y3 −0.25000 x4 −0.49726 y4 −0.05226 x5 −0.47553 y5 +0.15451 x6 −0.37157 y6 +0.33457 x7 −0.20337 y7 +0.45677 x8 0.00000 y8 +0.50000 x9 +0.20337 y9 +0.45677 x10 +0.37157 y10 +0.33457 x11 +0.47553 y11 +0.15451 x12 +0.49726 y12 −0.05226 x13 +0.43301 y13 −0.25000 x14 +0.29389 y14 −0.40451 x15 +0.10396 y15 −0.48907
Copyright 2004, Industrial Press, Inc., New York, NY
9 Holes x1 y1 x2 y2 x3 y3 x4 y4 x5 y5 x6 y6 x7 y7 x8 y8 x9 y9
−0.17101 −0.46985 −0.43301 −0.25000 −0.49240 +0.08682 −0.32139 +0.38302 0.00000 +0.50000 +0.32139 +0.38302 +0.49240 +0.08682 +0.43301 −0.25000 +0.17101 −0.46985 16 Holes
x1 −0.09755 y1 −0.49039 x2 −0.27779 y2 −0.41573 x3 −0.41573 y3 −0.27779 x4 −0.49039 y4 −0.09755 x5 −0.49039 y5 +0.09755 x6 −0.41573 y6 +0.27779 x7 −0.27779 y7 +0.41573 x8 −0.09755 y8 +0.49039 x9 +0.09755 y9 +0.49039 x10 +0.27779 y10 +0.41573 x11 +0.41573 y11 +0.27779 x12 +0.49039 y12 +0.09755 x13 +0.49039 y13 −0.09755 x14 +0.41573 y14 −0.27779 x15 +0.27779 y15 −0.41573 x16 +0.09755 y16 −0.49039
Machinery's Handbook 27th Edition JIG BORING
1003
Table 15. (Continued) Hole Coordinate Dimension Factors for Jig Boring — Type “B” Hole Circles Central Coordinates (English or Metric units)
The diagram shows a type “B” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
17 Holes x1 −0.09187 y1 − 0.49149 x2 −0.26322 y2 −0.42511 x3 − 0.39901 y3 −0.30132 x4 −0.48091 y4 −0.13683 x5 −0.49787 y5 +0.04613 x6 −0.44758 y6 +0.22287 x7 −0.33685 y7 +0.36950 x8 −0.18062 y8 +0.46624 x9 0.00000 y9 +0.50000 x10 +0.18062 y10 +0.46624 x11 +0.33685 y11 +0.36950 x12 +0.44758 y12 +0.22287 x13 +0.49787 y13 +0.04613 x14 +0.48091 y14 −0.13683 x15 +0.39901 y15 −0.30132 x16 +0.26322 y16 −0.42511 x17 +0.09187 y17 − 0.49149
18 Holes x1 −0.08682 y1 −0.49240 x2 −0.25000 y2 −0.43301 x3 −0.38302 y3 −0.32139 x4 −0.46985 y4 −0.17101 x5 −0.50000 y5 0.00000 x6 −0.46985 y6 +0.17101 x7 −0.38302 y7 +0.32139 x8 −0.25000 y8 +0.43301 x9 −0.08682 y9 +0.49240 x10 +0.08682 y10 +0.49240 x11 +0.25000 y11 +0.43301 x12 +0.38302 y12 +0.32139 x13 +0.46985 y13 +0.17101 x14 +0.50000 y14 0.00000 x15 +0.46985 y15 −0.17101 x16 +0.38302 y16 −0.32139 x17 +0.25000 y17 −0.43301 x18 +0.08682 y18 −0.49240
24 Holes
19 Holes x1 −0.08230 y1 −0.49318 x2 −0.23797 y2 −0.43974 x3 −0.36786 y3 −0.33864 x4 −0.45789 y4 −0.20085 x5 −0.49829 y5 −0.04129 x6 −0.48470 y6 +0.12274 x7 −0.41858 y7 +0.27347 x8 −0.30711 y8 +0.39457 x9 −0.16235 y9 +0.47291 x10 0.00000 y10 +0.50000 x11 +0.16235 y11 +0.47291 x12 +0.30711 y12 +0.39457 x13 +0.41858 y13 +0.27347 x14 +0.48470 y14 +0.12274 x15 +0.49829 y15 −0.04129 x16 +0.45789 y16 −0.20085 x17 +0.36786 y17 −0.33864 x18 +0.23797 y18 −0.43974 x19 +0.08230 y19 −0.49318
25 Holes
20 Holes x1 −0.07822 y1 −0.49384 x2 −0.22700 y2 −0.44550 x3 −0.35355 y3 −0.35355 x4 −0.44550 y4 −0.22700 x5 −0.49384 y5 −0.07822 x6 −0.49384 y6 +0.07822 x7 −0.44550 y7 +0.22700 x8 −0.35355 y8 +0.35355 x9 −0.22700 y9 +0.44550 x10 −0.07822 y10 +0.49384 x11 +0.07822 y11 +0.49384 x12 +0.22700 y12 +0.44550 x13 +0.35355 y13 +0.35355 x14 +0.44550 y14 +0.22700 x15 +0.49384 y15 +0.07822 x16 +0.49384 y16 −0.07822 x17 +0.44550 y17 −0.22700 x18 +0.35355 y18 −0.35355 x19 +0.22700 y19 −0.44550 x20 +0.07822 y20 −0.49384
26 Holes
21 Holes x1 −0.07452 y1 −0.49442 x2 −0.21694 y2 −0.45048 x3 −0.34009 y3 −0.36653 x4 −0.43301 y4 −0.25000 x5 −0.48746 y5 −0.11126 x6 −0.49860 y6 +0.03737 x7 −0.46544 y7 +0.18267 x8 −0.39092 y8 +0.31174 x9 −0.28166 y9 +0.41312 x10 −0.14738 y10 +0.47779 x11 0.00000 y11 +0.50000 x12 +0.14738 y12 +0.47779 x13 +0.28166 y13 +0.41312 x14 +0.39092 y14 +0.31174 x15 +0.46544 y15 +0.18267 x16 +0.49860 y16 +0.03737 x17 +0.48746 y17 −0.11126 x18 +0.43301 y18 −0.25000 x19 +0.34009 y19 −0.36653 x20 +0.21694 y20 −0.45048 x21 +0.07452 y21 −0.49442
27 Holes
22 Holes x1 −0.07116 y1 −0.49491 x2 −0.20771 y2 −0.45482 x3 −0.32743 y3 −0.37787 x4 −0.42063 y4 −0.27032 x5 −0.47975 y5 −0.14087 x6 −0.50000 y6 0.00000 x7 −0.47975 y7 +0.14087 x8 −0.42063 y8 +0.27032 x9 −0.32743 y9 +0.37787 x10 −0.20771 y10 +0.45482 x11 −0.07116 y11 +0.49491 x12 + 0.07116 y12 +0.49491 x13 +0.20771 y13 +0.45482 x14 +0.32743 y14 +0.37787 x15 +0.42063 y15 +0.27032 x16 +0.47975 y16 +0.14087 x17 +0.50000 y17 0.00000 x18 +0.47975 y18 −0.14087 x19 +0.42063 y19 −0.27032 x20 +0.32743 y20 −0.37787 x21 +0.20771 y21 −0.45482 x22 +0.07116 y22 −0.49491
28 Holes
x1 y1 x2 y2 x3
−0.06526 −0.49572 −0.19134 −0.46194 −0.30438
x1 y1 x2 y2 x3
−0.06267 −0.49606 −0.18406 −0.46489 −0.29389
x1 y1 x2 y2 x3
−0.06027 −0.49635 −0.17730 −0.46751 −0.28403
x1 y1 x2 y2 x3
−0.05805 −0.49662 −0.17101 −0.46985 −0.27475
x1 y1 x2 y2 x3
−0.05598 −0.49686 −0.16514 −0.47194 −0.26602
y3
−0.39668
y3 −0.40451
y3
−0.41149
y3 −0.41774
y3
−0.42336
Copyright 2004, Industrial Press, Inc., New York, NY
23 Holes x1 −0.06808 y1 −0.49534 x2 −0.19920 y2 −0.45861 x3 −0.31554 y3 −0.38786 x4 −0.40848 y4 −0.28834 x5 −0.47113 y5 −0.16744 x6 −0.49883 y6 −0.03412 x7 −0.48954 y7 +0.10173 x8 −0.44394 y8 +0.23003 x9 −0.36542 y9 +0.34128 x10 −0.25979 y10 +0.42721 x11 −0.13490 y11 +0.48146 x12 0.00000 y12 +0.50000 x13 +0.13490 y13 +0.48146 x14 +0.25979 y14 +0.42721 x15 +0.36542 y15 +0.34128 x16 +0.44394 y16 +0.23003 x17 +0.48954 y17 +0.10173 x18 +0.49883 y18 −0.03412 x19 +0.47113 y19 −0.16744 x20 +0.40848 y20 −0.28834 x21 +0.31554 y21 −0.38786 x22 +0.19920 y22 −0.45861 x23 +0.06808 y23 −0.49534
Machinery's Handbook 27th Edition 1004
JIG BORING
Table 15. (Continued) Hole Coordinate Dimension Factors for Jig Boring — Type “B” Hole Circles Central Coordinates (English or Metric units)
The diagram shows a type “B” circle for a 5-hole circle. Coordinates x, y are given in the table for hole circles of from 3 to 28 holes. Dimensions are for holes numbered in a counterclockwise direction (as shown). Dimensions given are based upon a hole circle of unit diameter. For a hole circle of, say, 3-inch or 3-centimeter diameter, multiply table values by 3.
24 Holes x4 −0.39668 y4 −0.30438 x5 −0.46194 y5 −0.19134 x6 −0.49572 y6 −0.06526 x7 −0.49572 y7 +0.06526 x8 −0.46194 y8 +0.19134 x9 −0.39668 y9 +0.30438 x10 −0.30438 y10 +0.39668 x11 −0.19134 y11 +0.46194 x12 −0.06526 y12 +0.49572 x13 +0.06526 y13 +0.49572 x14 +0.19134 y14 +0.46194 x15 +0.30438 y15 +0.39668 x16 +0.39668 y16 +0.30438 x17 +0.46194 y17 +0.19134 x18 +0.49572 y18 +0.06526 x19 +0.49572 y19 −0.06526 x20 +0.46194 y20 −0.19134 x21 +0.39668 y21 −0.30438 x22 +0.30438 y22 −0.39668 x23 +0.19134 y23 −0.46194 x24 +0.06526 y24 −0.49572
25 Holes x4 −0.38526 y4 −0.31871 x5 −0.45241 y5 −0.21289 x6 −0.49114 y6 −0.09369 x7 −0.49901 y7 +0.03140 x8 −0.47553 y8 +0.15451 x9 −0.42216 y9 +0.26791 x10 −0.34227 y10 + 0.36448 x11 −0.24088 y11 +0.43815 x12 −0.12434 y12 +0.48429 x13 0.00000 y13 +0.50000 x14 +0.12434 y14 +0.48429 x15 +0.24088 y15 +0.43815 x16 +0.34227 y16 +0.36448 x17 +0.42216 y17 +0.26791 x18 +0.47553 y18 +0.15451 x19 +0.49901 y19 +0.03140 x20 +0.49114 y20 −0.09369 x21 +0.45241 y21 −0.21289 x22 +0.38526 y22 −0.31871 x23 +0.29389 y23 −0.40451 x24 +0.18406 y24 −0.46489 x25 +0.06267 y25 −0.49606
26 Holes x4 −0.37426 y4 −0.33156 x5 −0.44273 y5 −0.23236 x6 −0.48547 y6 −0.11966 x7 −0.50000 y7 0.00000 x8 −0.48547 y8 +0.11966 x9 −0.44273 y9 +0.23236 x10 −0.37426 y10 +0.33156 x11 −0.28403 y11 +0.41149 x12 −0.17730 y12 +0.46751 x13 −0.06027 y13 +0.49635 x14 +0.06027 y14 +0.49635 x15 +0.17730 y15 +0.46751 x16 +0.28403 y16 +0.41149 x17 +0.37426 y17 +0.33156 x18 +0.44273 y18 +0.23236 x19 +0.48547 y19 +0.11966 x20 +0.50000 y20 0.00000 x21 + 0.48547 y21 −0.11966 x22 +0.44273 y22 −0.23236 x23 +0.37426 y23 −0.33156 x24 +0.28403 y24 −0.41149 x25 +0.17730 y25 −0.46751 x26 +0.06027 y26 −0.49635
27 Holes x4 −0.36369 y4 −0.34312 x5 −0.43301 y5 − 0.25000 x6 −0.47899 y6 −0.14340 x7 −0.49915 y7 − 0.02907 x8 −0.49240 y8 +0.08682 x9 −0.45911 y9 +0.19804 x10 −0.40106 y10 +0.29858 x11 −0.32139 y11 +0.38302 x12 −0.22440 y12 +0.44682 x13 −0.11531 y13 +0.48652 x14 0.00000 y14 +0.50000 x15 +0.11531 y15 +0.48652 x16 +0.22440 y16 +0.44682 x17 +0.32139 y17 +0.38302 x18 +0.40106 y18 + 0.29858 x19 +0.45911 y19 +0.19804 x20 +0.49240 y20 +0.08682 x21 +0.49915 y21 −0.02907 x22 +0.47899 y22 − 0.14340 x23 +0.43301 y23 −0.25000 x24 +0.36369 y24 −0.34312 x25 +0.27475 y25 −0.41774 x26 +0.17101 y26 −0.46985 x27 +0.05805 y27 −0.49662
28 Holes x4 −0.35355 y4 −0.35355 x5 −0.42336 y5 −0.26602 x6 −0.47194 y6 −0.16514 x7 −0.49686 y7 −0.05598 x8 −0.49686 y8 +0.05598 x9 −0.47194 y9 +0.16514 x10 −0.42336 y10 +0.26602 x11 −0.35355 y11 +0.35355 x12 −0.26602 y12 +0.42336 x13 −0.16514 y13 +0.47194 x14 −0.05598 y14 +0.49686 x15 +0.05598 y15 +0.49686 x16 +0.16514 y16 +0.47194 x17 +0.26602 y17 +0.42336 x18 +0.35355 y18 +0.35355 x19 +0.42336 y19 +0.26602 x20 +0.47194 y20 +0.16514 x21 +0.49686 y21 +0.05598 x22 +0.49686 y22 −0.05598 x23 +0.47194 y23 −0.16514 x24 +0.42336 y24 −0.26602 x25 +0.35355 y25 −0.35355 x26 +0.26602 y26 −0.42336 x27 +0.16514 y27 −0.47194 x28 +0.05598 y28 −0.49686
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TABLE OF CONTENTS DIMENSIONING, GAGING, AND MEASURING DRAFTING PRACTICES 630 630 630 630 633 634 638 640 642
MEASURING INSTRUMENTS AND INSPECTION METHODS
ANSI Drafting Practices Sizes of Drawing Sheets Symbols for Section Lining Geometric Dimensioning ANSI and ISO Symbols Definitions Datum Referencing Positional Tolerance Checking Drawings
ALLOWANCES AND TOLERANCES FOR FITS 645 645 647 648 649 651 651 652 652 652 656 658 660 662 665 665 666 667 670 670 672 674 674 676 678 679 680 680 682 682 683 685 687 689 689 690
Basic Dimensions Tolerances Force fits Expansion and Shrinkage Fits Temperatures for Shrinkage Fits ANSI Standard Limits and Fits Definitions Preferred Basic Sizes Standard Tolerances ANSI Standard Fits Modified Standard Fits Running and Sliding Fits Clearance Locational Fits Transition Locational Fits ANSI Metric Limits and Fits Definitions Tolerances Designation Preferred Metric Fits Hole Basis Fits Clearance Fits Transition and Interference Fits Shaft Basis Fits Clearance Fits Transition and Interference Fits Gagemakers Tolerances ISO Metric Limits and Fits Definitions Calculated Limits of Tolerance Tolerance for Selected Holes Tolerance for Selected Shafts Clearances Deviations for Shafts Deviations for Holes Preferred Numbers ANSI Preferred Numbers Preferred Metric Sizes
692 693 695 695 695 696 697 698 698 699 706 713 713 714 715 717 717 717 718 719 721 723
Verniers and Micrometers Dual Metric-Inch Vernier Metric Micrometer Sine-bar Types of Sine-bars Setting a Sine-bar Using Sine-bar Tables Measuring Tapers with V-block Dimensioning Tapers Constants for 5-inch Sine-bar Constants for 100-mm Sine-bar Angles and Tapers Measuring Dovetail Slides Tapers per Foot Figuring Tapers Measurement over Pins and Rolls Measurement over Pins Checking a V-shaped Groove Checking Radius of Arc Checking Shaft Conditions Out-of-Roundness and Lobing Measurements Using Light
SURFACE TEXTURE 724 ANSI Surface Texture 726 Definitions 727 Sampling Lengths 728 Roughness Parameters 729 Waviness Parameters 729 Surface Roughness to Tolerances 730 Instruments for Measurement 731 Roughness Measurements 731 Surface Texture Symbols 734 Roughness Average Values 735 Lay Symbols 735 Surface Texture of Castings 735 Metric Dimensions on Drawings 738 ISO Surface Finish 738 Surface Finish Symbology 740 Roughness Lengths 743 Gage Blocks 743 Precision Gage Blocks 744 Gage Block Sets
629
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Machinery's Handbook 27th Edition 630
DIMENSIONING, GAGING, AND MEASURING
DRAFTING PRACTICES American National Standard Drafting Practices Several American National Standards for use in preparing engineering drawings and related documents are referred to for use. Sizes of Drawing Sheets.—Recommended trimmed sheet sizes, based on ANSI Y14.11980 (R1987), are shown in the following table. Size, inches
Metric Size, mm
A
81⁄2 × 11
D
22 × 34
A0
841 × 1189
A3
297 × 420
B
11 × 17
E
34 × 44
A1
594 × 841
A4
210 × 297
C
17 × 22
F
28 × 40
A2
420 × 594
The standard sizes shown by the left-hand section of the table are based on the dimensions of the commercial letter head, 81⁄2 × 11 inches, in general use in the United States. The use of the basic sheet size 81⁄2 × 11 inches and its multiples permits filing of small tracings and folded blueprints in commercial standard letter files with or without correspondence. These sheet sizes also cut without unnecessary waste from the present 36-inch rolls of paper and cloth. For drawings made in the metric system of units or for foreign correspondence, it is recommended that the metric standard trimmed sheet sizes be used. (Right-hand section of table.) These sizes are based on the width-to-length ratio of 1 to
2.
Line Conventions and Drawings.—American National Standard Y14.2M-1979 (R1987) establishes line and lettering practices for engineering drawings. The line conventions and the symbols for section lining are as shown on Tables 1 and 2. Approximate width of THICK lines for metric drawings are 0.6 mm, and for inch drawings, 0.032 inch. Approximate width of THIN lines for metric drawings are 0.3 mm, and for inch drawings, 0.016 inch. These approximate line widths are intended to differentiate between THICK and THIN lines and are not values for control of acceptance or rejection of the drawings. Surface-Texture Symbols.—A detailed explanation of the use of surface-texture symbols from American National Standard Y14.36M-1996 begins on page 731. Geometric Dimensioning and Tolerancing.—ANSI/ASME Y14.5M-1994, “Dimensioning and Tolerancing,” covers dimensioning, tolerancing, and similar practices for engineering drawings and related documentation. The mathematical definitions of dimensioning and tolerancing principles are given in the standard ANSI/ASME Y14.5.1M-1994. ISO standards ISO 8015 and ISO 26921 contain a detailed explanation of ISO geometric dimensioning and tolerancing practices. Geometric dimensioning and tolerancing provides a comprehensive system for symbolically defining the geometrical tolerance zone within which features must be contained. It provides an accurate transmission of design specifications among the three primary users of engineering drawings; design, manufacturing and quality assurance. Some techniques introduced in ANSI/ASME Y14.5M-1994 have been accepted by ISO. These techniques include projected tolerance zone, three-plane datum concept, total runout tolerance, multiple datums, and datum targets. Although this Standard follows ISO practice closely, there are still differences between ISO and U.S. practice. (A comparison of the symbols used in ISO standards and Y14.5M is given on page 633.)
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Machinery's Handbook 27th Edition DRAFTING PRACTICES
631
Table 1. American National Standard for Engineering Drawings ANSI/ASME Y14.2M-1992 Visible Line
THICK
Hidden Line
THIN
Section Line
THIN
Center Line
THIN THIN
Symmetry Line
Leader Extension Line Dimension Line Extension Line And Leader
Dimension Line THIN 3.50
THICK Cutting-Plane Line or Viewing-Plane Line
THICK
THICK Short Breaks Break Line
THIN Long Breaks
Phantom Line
THIN THIN
Stitch Line
THIN ................................................... Chain Line
THICK
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Machinery's Handbook 27th Edition 632
DRAFTING PRACTICES Table 2. American National Standard Symbols for Section Lining ANSI Y14.2M-1979 (R1987) Cast and Malleable iron (Also for general use of all materials)
Titanium and refractory material
Steel
Electric windings, electro magnets, resistance, etc.
Bronze, brass, copper, and compositions
Concrete
White metal, zinc, lead, babbitt, and alloys
Marble, slate, glass, porcelain, etc.
Magnesium, aluminum, and aluminum alloys
Earth
Rubber, plastic electrical insulation
Rock
Cork, felt, fabric, leather, fiber
Sand
Sound insulation
Water and other liquids
Thermal insulation
Wood-across grain Wood-with grain
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Machinery's Handbook 27th Edition
Table 3. Comparison of ANSI and ISO Geometric Symbols ASME Y14.5M-1994 Symbol for
ANSI Y14.5M
ISO
Symbol for
ANSI Y14.5
ISO
Symbol for
ANSI Y14.5M
ISO
Circular Runouta
Feature Control Frame
Flatness
Total Runouta
Datum Featurea
Circularity
At Maximum Material Condition
All Around - Profile
Cylindricity
At Least Material Condition
Conical Taper
Profile of a Line
Regardless of Feature Size
Profile of a Surface
Projected Tolerance Zone
Counterbore/Spotface
Angularity
Diameter
Countersink
Perpendicularity
Basic Dimension
Parallelism
Reference Dimension
Position
Datum Target
Dimension Not to Scale
15
15
Concentricity/Coaxiality
Target Point
Number of Times/Places
8X
8X
Symmetry
Dimension Origin
Arc Length
Radius
R
Betweena
NONE
NONE
GEOMETRIC SYMBOLS
Straightness
Slope
Depth/Deep (50)
(50)
Square (Shape)
R
Spherical Radius
SR
SR
Sperical Diameter
None
Controlled Radius
CR
None
Statical Tolerance
None
633
a Arrowheads may be filled in.
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Machinery's Handbook 27th Edition 634
GEOMETRIC DIMENSIONING
One major area of disagreement is the ISO “principle of independency” versus the “Taylor principle.” Y14.5M and standard U.S. practice both follow the Taylor principle, in which a geometric tolerancing zone may not extend beyond the boundary (or envelope) of perfect form at MMC (maximum material condition). This boundary is prescribed to control variations as well as the size of individual features. The U.S. definition of independency further defines features of size as being independent and not required to maintain a perfect relationship with other features. The envelope principle is optional in treatment of these principles. A summary of the application of ANSI/ASME geometric control symbols and their use with basic dimensions and modifiers is given in Table 1. Table 1. Application of Geometric Control Symbols Type Geometric Characteristics
Pertains To
Basic Dimensions
Feature Modifier
Datum Modifier
Form
Circularity
Runout Location Orientation Profile
Straightness
Profile (Line)
Flatness
ONLY individual feature
NO datum Modifier not applicable
Cylindricity Profile (Surface)
Individual or related
Angularity
Yes if related Yes RFS implied unless MMC or LMC is stated
Perpendicularity Parallelism Position Concentricity Symmetry Circular Runout
ALWAYS related feature(s)
RFS implied unless MMC or LMC is stated
Yes
Only RFS
Only RFS
Total Runout
Five types of geometric control, when datums are indicated, when basic dimensions are required, and when MMC and LMC modifiers may be used.
ANSI/ASME Y14.5M features metric SI units (the International System of Units), but customary units may be used without violating any principles. On drawings where all dimensions are either in millimeters or in inches, individual identification of linear units is not required. However, the drawing should contain a note stating UNLESS OTHERWISE SPECIFIED, ALL DIMENSIONS ARE IN MILLIMETERS (or IN INCHES, as applicable). According to this Standard, all dimensions are applicable at a temperature of 20 C (68 F) unless otherwise specified. Compensation may be made for measurements taken at other temperatures. Angular units are expressed in degrees and decimals of a degree (35.4) or in degrees (°), minutes (′), and seconds (″), as in 35° 25′ 10″. A 90-degree angle is implied where center lines and depicting features are shown on a drawing at right angles and no angle is specified. A 90-degree BASIC angle applies where center lines of features in a pattern or surface shown at right angles on a drawing are located or defined by basic dimensions and no angle is specified. Definitions.—The following terms are defined as their use applies to ANSI/ASME Y14.5M. Datum Feature: The feature of a part that is used to establish a datum. Datum Identifier: The graphic symbol on a drawing used to indicate the datum feature.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition GEOMETRIC DIMENSIONING Leader may be appropriately directed to a feature.
Datum letter
A
A
0.25 Datum triangle may be filled or not filled.
A
635
M
Combined feature control frame and datum identifier
A B C A
A
Fig. 1. Datum Feature Symbol
Datum Plane: The individual theoretical planes of the reference frame derived from a specified datum feature. A datum is the origin from which the location or other geometric characteristics of features of a part are established. Datum Reference Frame: Sufficient features on a part are chosen to position the part in relationship to three planes. The three planes are mutually perpendicular and together called the datum reference frame. The planes follow an order of precedence and allow the part to be immobilized. This immobilization in turn creates measurable relationships among features. Datum Simulator: Formed by the datum feature contacting a precision surface such as a surface plate, gage surface or by a mandrel contacting the datum. Thus, the plane formed by contact restricts motion and constitutes the specific reference surface from which measurements are taken and dimensions verified. The datum simulator is the practical embodiment of the datum feature during manufacturing and quality assurance. Datum Target: A specified point, line, or area on a part, used to establish a datum. Degrees of Freedom: The six directions of movement or translation are called degrees of freedom in a three-dimensional environment. They are up-down, left-right, fore-aft, roll, pitch and yaw. Up Right Aft
Yaw
Pitch
Fore Roll
Left Down
Fig. 2. Degrees of Freedom (Movement) That Must be Controlled, Depending on the Design Requirements.
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GEOMETRIC DIMENSIONING
Dimension, Basic: A numerical value used to describe the theoretically exact size, orientation, location, or optionally, profile, of a feature or datum or datum target. Basic dimensions are indicated by a rectangle around the dimension and are not toleranced directly or by default. The specific dimensional limits are determined by the permissible variations as established by the tolerance zone specified in the feature control frame. A dimension is only considered basic for the geometric control to which it is related. 38
Fig. 3. Basic Dimensions
Dimension Origin: Symbol used to indicate the origin and direction of a dimension between two features. The dimension originates from the symbol with the dimension tolerance zone being applied at the other feature. 20
0.3 4.2 4.1 8
0.3 20
30
0.3
0.1˚ Dimension origin symbol Fig. 4. Dimension Origin Symbol
Dimension, Reference: A dimension, usually without tolerance, used for information purposes only. Considered to be auxiliary information and not governing production or inspection operations. A reference dimension is a repeat of a dimension or is derived from a calculation or combination of other values shown on the drawing or on related drawings. Feature Control Frame: Specification on a drawing that indicates the type of geometric control for the feature, the tolerance for the control, and the related datums, if applicable. Geometric control symbol
0.25 A-B Co-datum (both primary)
Primary datum reference
Tolerance
Tolerance modifier
M
A
B
C Tertiary datum reference Secondary datum reference
Fig. 5. Feature Control Frame and Datum Order of Precedence
Feature: The general term applied to a physical portion of a part, such as a surface, hole, pin, tab, or slot. Least Material Condition (LMC): The condition in which a feature of size contains the least amount of material within the stated limits of size, for example, upper limit or maximum hole diameter and lower limit or minimum shaft diameter.
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Machinery's Handbook 27th Edition GEOMETRIC DIMENSIONING
637
Limits, Upper and Lower (UL and LL): The arithmetic values representing the maximum and minimum size allowable for a dimension or tolerance. The upper limit represents the maximum size allowable. The lower limit represents the minimum size allowable. Maximum Material Condition (MMC): The condition in which a feature of size contains the maximum amount of material within the stated limits of size. For example, the lower limit of a hole is the minimum hole diameter. The upper limit of a shaft is the maximum shaft diameter. Position: Formerly called true position, position is the theoretically exact location of a feature established by basic dimensions. Regardless of Feature Size (RFS): The term used to indicate that a geometric tolerance or datum reference applies at any increment of size of the feature within its tolerance limits. RFS is the default condition unless MMC or LMC is specified. The concept is now the default in ANSI/ASME Y14.5M-1994, unless specifically stated otherwise. Thus the symbol for RFS is no longer supported in ANSI/ASME Y14.5M-1994. Size, Actual: The term indicating the size of a feature as produced. Size, Feature of: A feature that can be described dimensionally. May include a cylindrical or spherical surface, or a set of two opposed parallel surfaces associated with a size dimension. Tolerance Zone Symmetry: In geometric tolerancing, the tolerance value stated in the feature control frame is always a single value. Unless otherwise specified, it is assumed that the boundaries created by the stated tolerance are bilateral and equidistant about the perfect form control specified. However, if desired, the tolerance may be specified as unilateral or unequally bilateral. (See Figs. 6 through 8) Tolerance, Bilateral: A tolerance where variation is permitted in both directions from the specified dimension. Bilateral tolerances may be equal or unequal. Tolerance, Geometric: The general term applied to the category of tolerances used to control form, profile, orientation, location, and runout. Tolerance, Unilateral: A tolerance where variation is permitted in only one direction from the specified dimension. True Geometric Counterpart: The theoretically perfect plane of a specified datum feature. Virtual Condition: A constant boundary generated by the collective effects of the feature size, its specified MMC or LMC material condition, and the geometric tolerance for that condition. 0.1
0.25
M
A
10 R75 38
A
Bilateral zone with 0.1 of the 0.25 tolerance outside perfect form. Fig. 6. Application of a bilateral geometric tolerance
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GEOMETRIC TOLERANCING
0.25
M
A
10 R75 38
A
Unilateral zone with all of the 0.25 tolerance outside perfect form. Fig. 7. Application of a unilateral geometric tolerance zone outside perfect form
0.25
M
A
10 R75 38
A
Unilateral zone with all of the 0.25 tolerance inside perfect form. Fig. 8. Application of a unilateral geometric tolerance zone inside a perfect form
Datum Referencing.—A datum indicates the origin of a dimensional relationship between a toleranced feature and a designated feature or features on a part. The designated feature serves as a datum feature, whereas its true geometric counterpart establishes the datum plane. Because measurements cannot be made from a true geometric counterpart, which is theoretical, a datum is assumed to exist in, and be simulated by the associated processing equipment. For example, machine tables and surface plates, although not true planes, are of such quality that they are used to simulate the datums from which measurements are taken and dimensions are verified. When magnified, flat surfaces of manufactured parts are seen to have irregularities, so that contact is made with a datum plane formed at a number of surface extremities or high points. Sufficient datum features, those most important to the design of the part, are chosen to position the part in relation to a set of three mutually perpendicular planes, the datum reference frame. This reference frame exists only in theory and not on the part. Therefore, it is necessary to establish a method for simulating the theoretical reference frame from existing features of the part. This simulation is accomplished by positioning the part on appropriate datum features to adequately relate the part to the reference frame and to restrict the degrees of freedom of the part in relation to it. These reference frame planes are simulated in a mutually perpendicular relationship to provide direction as well as the origin for related dimensions and measurements. Thus, when the part is positioned on the datum reference frame (by physical contact between each datum feature and its counterpart in the associated processing equipment), dimensions related to the datum reference frame by a feature control frame are thereby mutually perpendicular. This theoretical reference frame constitutes the three-plane dimensioning system used for datum referencing.
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Machinery's Handbook 27th Edition GEOMETRIC TOLERANCING
639
Target area (where applicable)
12 P1 Datum reference letter 18
18 12
12 P1
or
P1 Target number
18
18 Target C2 is on the hidden or far side of the part.
12 C2 18 18
Fig. 9. Datum target symbols
Depending on the degrees of freedom that must be controlled, a simple reference frame may suffice. At other times, additional datum reference frames may be necessary where physical separation occurs or the functional relationship. Depending on the degrees of freedom that must be controlled, a single datum of features require that datum reference frames be applied at specific locations on the part. Each feature control frame must contain the datum feature references that are applicable. Datum Targets: Datum targets are used to establish a datum plane. They may be points, lines or surface areas. Datum targets are used when the datum feature contains irregularities, the surface is blocked by other features or the entire surface cannot be used. Examples where datum targets may be indicated include uneven surfaces, forgings and castings, weldments, non-planar surfaces or surfaces subject to warping or distortion. The datum target symbol is located outside the part outline with a leader directed to the target point, area or line. The targets are dimensionally located on the part using basic or toleranced dimensions. If basic dimensions are used, established tooling or gaging tolerances apply. A solid leader line from the symbol to the target is used for visible or near side locations with a dashed leader line used for hidden or far side locations. The datum target symbol is divided horizontally into two halves. The top half contains the target point area if applicable; the bottom half contains a datum feature identifying letter and target number. Target
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GEOMETRIC TOLERANCING
numbers indicate the quantity required to define a primary, secondary, or tertiary datum. If indicating a target point or target line, the top half is left blank. Datum targets and datum features may be combined to form the datum reference frame, Fig. 9. Datum Target points: A datum target point is indicated by the symbol “X,” which is dimensionally located on a direct view of the surface. Where there is no direct view, the point location is dimensioned on multiple views. Datum Target Lines: A datum target line is dimensionally located on an edge view of the surface using a phantom line on the direct view. Where there is no direct view, the location is dimensioned on multiple views. Where the length of the datum target line must be controlled, its length and location are dimensioned. Datum Target Areas: Where it is determined that an area or areas of flat contact are necessary to ensure establishment of the datum, and where spherical or pointed pins would be inadequate, a target area of the desired shape is specified. Examples include the need to span holes, finishing irregularities, or rough surface conditions. The datum target area may be indicated with the “X” symbol as with a datum point, but the area of contact is specified in the upper half of the datum target symbol. Datum target areas may additionally be specified by defining controlling dimensions and drawing the contact area on the feature with section lines inside a phantom outline of the desired shape. Positional Tolerance.—A positional tolerance defines a zone within which the center, axis, or center plane of a feature of size is permitted to vary from true (theoretically exact) position. Basic dimensions establish the true position from specified datum features and between interrelated features. A positional tolerance is indicated by the position symbol, a tolerance, and appropriate datum references placed in a feature control frame. Modifiers: In certain geometric tolerances, modifiers in the form of additional symbols may be used to further refine the level of control. The use of the MMC and LMC modifiers has been common practice for many years. However, several new modifiers were introduced with the 1994 U.S. national standard. Some of the new modifiers include free state, tangent plane and statistical tolerancing, Fig. 10.
F
M
L
T
P
ST
Free State
MMC
LMC
Tangent Plane
Projected Tolerance Zone
Statistical Tolerance
Fig. 10. Tolerance modifiers
Projected Tolerance Zone: Application of this concept is recommended where any variation in perpendicularity of the threaded or press-fit holes could cause fasteners such as screws, studs, or pins to interfere with mating parts. An interference with subsequent parts can occur even though the hole axes are inclined within allowable limits. This interference occurs because, without a projected tolerance zone, a positional tolerance is applied only to the depth of threaded or press-fit holes. Unlike the floating fastener application involving clearance holes only, the attitude of a fixed fastener is restrained by the inclination of the produced hole into which it assembles. Projected tolerance zone symbol
0.25 M P 14 A
B
C
Minimum height of projected tolerance zone Fig. 11. Projected tolerance zone callout
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Machinery's Handbook 27th Edition GEOMETRIC TOLERANCING
641
With a projected tolerance zone equal to the thickness of the mating part, the inclinational error is accounted for in both parts. The minimum extent and direction of the projected tolerance zone is shown as a value in the feature control frame. The zone may be shown in a drawing view as a dimensioned value with a heavy chain line drawn closely adjacent to an extension of the center line of the hole. 4x M6x1-6H
A
0.25
M P
14 A
B
C
This on the drawing
0.25 positional True position tolerance zone axis
Axis of threaded hole projected tolerance 14 minimum zone height
Means this
True position axis Axis of threaded hole Fig. 12. Projected tolerance zone application
Statistical Tolerance: The statistical tolerancing symbol is a modifier that may be used to indicate that a tolerance is controlled statistically as opposed to being controlled arithmetically. With arithmetic control, assembly tolerances are typically divided arithmetically among the individual components of the assembly. This division results in the assumption that assemblies based on “worst case” conditions would be guaranteed to fit because the worst case set of parts fit — so that anything better would fit as well. When this technique is restrictive, statistical tolerancing, via the symbol, may be specified in the feature control frame as a method of increasing tolerances for individual parts. This procedure may reduce manufacturing costs because its use changes the assumption that statistical process control may make a statistically significant quantity of parts fit, but not absolutely all. The technique should only be used when sound statistical methods are employed.
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CHECKING DRAWINGS
Tangent Plane: When it is desirable to control the surface of a feature by the contacting or high points of the surface, a tangent plane symbol is added as a modifier to the tolerance in the feature control frame, Fig. 13. This on the drawing 0.1 T A
A
Means this 0.1 Tolerance zone
Controlled surface
Tangent plane generated by high points Fig. 13. Tangent plane modifier
Free State: The free state modifier symbol is used when the geometric tolerance applies to the feature in its “free state,” or after removal of any forces used in the manufacturing process. With removal of forces the part may distort due to gravity, flexibility, spring back, or other release of internal stresses developed during fabrication. Typical applications include parts with extremely thin walls and non-rigid parts made of rubber or plastics. The modifier is placed in the tolerance portion of the feature control frame and follows any other modifier. The above examples are just a few of the numerous concepts and related symbols covered by ANSI/ASME Y14.5M-1994. Refer to the standard for a complete discussion with further examples of the application of geometric dimensioning and tolerancing principles. Checking Drawings.—In order that the drawings may have a high standard of excellence, a set of instructions, as given in the following, has been issued to the checkers, and also to the draftsmen and tracers in the engineering department of a well-known machine-building company. Inspecting a New Design: When a new design is involved, first inspect the layouts carefully to see that the parts function correctly under all conditions, that they have the proper relative proportions, that the general design is correct in the matters of strength, rigidity, bearing areas, appearance, convenience of assembly, and direction of motion of the parts, and that there are no interferences. Consider the design as a whole to see if any improvements can be made. If the design appears to be unsatisfactory in any particular, or improvements appear to be possible, call the matter to the attention of the chief engineer. Checking for Strength: Inspect the design of the part being checked for strength, rigidity, and appearance by comparing it with other parts for similar service whenever possible, giving preference to the later designs in such comparison, unless the later designs are known to be unsatisfactory. If there is any question regarding the matter, compute the stresses and deformations or find out whether the chief engineer has approved the stresses or deformations that will result from the forces applied to the part in service. In checking parts that are to go on a machine of increased size, be sure that standard parts used in similar machines and proposed for use on the larger machine, have ample strength and rigidity under the new and more severe service to which they will be put. Materials Specified: Consider the kind of material required for the part and the various possibilities of molding, forging, welding, or otherwise forming the rough part from this material. Then consider the machining operations to see whether changes in form or design will reduce the number of operations or the cost of machining. See that parts are designed with reference to the economical use of material, and whenever possible, utilize standard sizes of stock and material readily obtainable from local
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CHECKING DRAWINGS
643
dealers. In the case of alloy steel, special bronze, and similar materials, be sure that the material can be obtained in the size required. Method of Making Drawing: Inspect the drawing to see that the projections and sections are made in such a way as to show most clearly the form of the piece and the work to be done on it. Make sure that any worker looking at the drawing will understand what the shape of the piece is and how it is to be molded or machined. Make sure that the delineation is correct in every particular, and that the information conveyed by the drawing as to the form of the piece is complete. Checking Dimensions: Check all dimensions to see that they are correct. Scale all dimensions and see that the drawing is to scale. See that the dimensions on the drawing agree with the dimensions scaled from the lay-out. Wherever any dimension is out of scale, see that the dimension is so marked. Investigate any case where the dimension, the scale of the drawing, and the scale of the lay-out do not agree. All dimensions not to scale must be underlined on the tracing. In checking dimensions, note particularly the following points: See that all figures are correctly formed and that they will print clearly, so that the workers can easily read them correctly. See that the overall dimensions are given. See that all witness lines go to the correct part of the drawing. See that all arrow points go to the correct witness lines. See that proper allowance is made for all fits. See that the tolerances are correctly given where necessary. See that all dimensions given agree with the corresponding dimensions of adjacent parts. Be sure that the dimensions given on a drawing are those that the machinist will use, and that the worker will not be obliged to do addition or subtraction to obtain the necessary measurements for machining or checking his work. Avoid strings of dimensions where errors can accumulate. It is generally better to give a number of dimensions from the same reference surface or center line. When holes are to be located by boring on a horizontal spindle boring machine or other similar machine, give dimensions to centers of bored holes in rectangular coordinates and from the center lines of the first hole to be bored, so that the operator will not be obliged to add measurements or transfer gages. Checking Assembly: See that the part can readily be assembled with the adjacent parts. If necessary, provide tapped holes for eyebolts and cored holes for tongs, lugs, or other methods of handling. Make sure that, in being assembled, the piece will not interfere with other pieces already in place and that the assembly can be taken apart without difficulty. Check the sum of a number of tolerances; this sum must not be great enough to permit two pieces that should not be in contact to come together. Checking Castings: In checking castings, study the form of the pattern, the methods of molding, the method of supporting and venting the cores, and the effect of draft and rough molding on clearances. Avoid undue metal thickness, and especially avoid thick and thin sections in the same casting. Indicate all metal thicknesses, so that the molder will know what chaplets to use for supporting the cores. See that ample fillets are provided, and that they are properly dimensioned. See that the cores can be assembled in the mold without crushing or interference. See that swelling, shrinkage, or misalignment of cores will not make trouble in machining. See that the amount of extra material allowed for finishing is indicated.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 644
CHECKING DRAWINGS
See that there is sufficient extra material for finishing on large castings to permit them to be “cleaned up,” even though they warp. In such castings, make sure that the metal thickness will be sufficient after finishing, even though the castings do warp. Make sure that sufficient sections are shown so that the pattern makers and molders will not be compelled to make assumptions about the form of any part of the casting. These details are particularly important when a number of sections of the casting are similar in form, while others differ slightly. Checking Machined Parts: Study the sequences of operations in machining and see that all finish marks are indicated. See that the finish marks are placed on the lines to which dimensions are given. See that methods of machining are indicated where necessary. Give all drill, reamer, tap, and rose bit sizes. See that jig and gage numbers are indicated at the proper places. See that all necessary bosses, lugs, and openings are provided for lifting, handling, clamping, and machining the piece. See that adequate wrench room is provided for all nuts and bolt heads. Avoid special tools, such as taps, drills, reamers, etc., unless such tools are specifically authorized. Where parts are right- and left-hand, be sure that the hand is correctly designated. When possible, mark parts as symmetrical, so as to avoid having them right- and left-hand, but do not sacrifice correct design or satisfactory operation on this account. When heat-treatment is required, the heat-treatment should be specified. Check the title, size of machine, the scale, and the drawing number on both the drawing and the drawing record card. Tapers for Machine Tool Spindles.—Various standard tapers have been used for the taper holes in the spindles of machine tools, such as drilling machines, lathes, milling machines, or other types requiring a taper hole for receiving either the shank of a cutter, an arbor, a center, or any tool or accessory requiring a tapering seat. The Morse taper represents a generally accepted standard for drilling machines. Morse Tapers Morse Taper 0 1
Taper per Foot 0.62460 0.59858
Morse Taper 2 3
Taper per Foot 0.59941 0.60235
Morse Taper 4 5
Taper per Foot 0.62326 0.63151
The headstock and tailstock spindles of lathes also have the Morse taper in most cases; but the Jarno, the Reed (which is the short Jarno), and the Brown & Sharpe have also been used. Milling machine spindles formerly had Brown & Sharpe tapers in most cases. In 1927, the milling machine manufacturers of the National Machine Tool Builders’ Association adopted a standard taper of 31⁄2 inches per foot. This comparatively steep taper has the advantage of insuring instant release of arbors or adapters. National Machine Tool Builders’ Association Tapers Taper Numbera
Large End Diameter
Taper Numbera
Large End Diameter
30
11⁄4
50
23⁄4
40
13⁄4
60
41⁄4
a Standard taper of 31⁄ inches per foot 2
The British Standard for milling machine spindles is also 31⁄2 inches taper per foot and includes these large end diameters: 13⁄8 inches, 13⁄4 inches, 23⁄4 inches, and 31⁄4 inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition ALLOWANCES AND TOLERANCES
645
ALLOWANCES AND TOLERANCES FOR FITS Limits and Fits Fits between cylindrical parts, i.e., cylindrical fits, govern the proper assembly and performance of many mechanisms. Clearance fits permit relative freedom of motion between a shaft and a hole—axially, radially, or both. Interference fits secure a certain amount of tightness between parts, whether these are meant to remain permanently assembled or to be taken apart from time to time. Or again, two parts may be required to fit together snugly—without apparent tightness or looseness. The designer's problem is to specify these different types of fits in such a way that the shop can produce them. Establishing the specifications requires the adoption of two manufacturing limits for the hole and two for the shaft, and, hence, the adoption of a manufacturing tolerance on each part. In selecting and specifying limits and fits for various applications, it is essential in the interests of interchangeable manufacturing that 1) standard definitions of terms relating to limits and fits be used; 2) preferred basic sizes be selected wherever possible to reduce material and tooling costs; 3) limits be based upon a series of preferred tolerances and allowances; and 4) a uniform system of applying tolerances (preferably unilateral) be used. These principles have been incorporated in both the American and British standards for limits and fits. Information about these standards is given beginning on page 651. Basic Dimensions.—The basic size of a screw thread or machine part is the theoretical or nominal standard size from which variations are made. For example, a shaft may have a basic diameter of 2 inches, but a maximum variation of minus 0.010 inch may be permitted. The minimum hole should be of basic size wherever the use of standard tools represents the greatest economy. The maximum shaft should be of basic size wherever the use of standard purchased material, without further machining, represents the greatest economy, even though special tools are required to machine the mating part. Tolerances.—Tolerance is the amount of variation permitted on dimensions or surfaces of machine parts. The tolerance is equal to the difference between the maximum and minimum limits of any specified dimension. For example, if the maximum limit for the diameter of a shaft is 2.000 inches and its minimum limit 1.990 inches, the tolerance for this diameter is 0.010 inch. The extent of these tolerances is established by determining the maximum and minimum clearances required on operating surfaces. As applied to the fitting of machine parts, the word tolerance means the amount that duplicate parts are allowed to vary in size in connection with manufacturing operations, owing to unavoidable imperfections of workmanship. Tolerance may also be defined as the amount that duplicate parts are permitted to vary in size to secure sufficient accuracy without unnecessary refinement. The terms “tolerance” and “allowance” are often used interchangeably, but, according to common usage, allowance is a difference in dimensions prescribed to secure various classes of fits between different parts. Unilateral and Bilateral Tolerances.—The term “unilateral tolerance” means that the total tolerance, as related to a basic dimension, is in one direction only. For example, if the basic dimension were 1 inch and the tolerance were expressed as 1.000 − 0.002, or as 1.000 + 0.002, these would be unilateral tolerances because the total tolerance in each is in one direction. On the contrary, if the tolerance were divided, so as to be partly plus and partly minus, it would be classed as “bilateral.” +0.001 Thus, 1.000 −0.001 is an example of bilateral tolerance, because the total tolerance of 0.002 is given in two directions—plus and minus. When unilateral tolerances are used, one of the three following methods should be used to express them:
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 646
ALLOWANCES AND TOLERANCES
1) Specify, limiting dimensions only as Diameter of hole: 2.250, 2.252 Diameter of shaft: 2.249, 2.247 2) One limiting size may be specified with its tolerances as Diameter of hole: 2.250 + 0.002, −0.000 Diameter of shaft: 2.249 + 0.000, −0.002 3) The nominal size may be specified for both parts, with a notation showing both allowance and tolerance, as Diameter of hole: 21⁄4 + 0.002, −0.000 Diameter of shaft: 21⁄4 − 0.001, −0.003 Bilateral tolerances should be specified as such, usually with plus and minus tolerances of equal amount. An example of the expression of bilateral tolerances is +0.001 −0.001 Application of Tolerances.—According to common practice, tolerances are applied in such a way as to show the permissible amount of dimensional variation in the direction that is less dangerous. When a variation in either direction is equally dangerous, a bilateral tolerance should be given. When a variation in one direction is more dangerous than a variation in another, a unilateral tolerance should be given in the less dangerous direction. For nonmating surfaces, or atmospheric fits, the tolerances may be bilateral, or unilateral, depending entirely upon the nature of the variations that develop in manufacture. On mating surfaces, with few exceptions, the tolerances should be unilateral. Where tolerances are required on the distances between holes, usually they should be bilateral, as variation in either direction is normally equally dangerous. The variation in the distance between shafts carrying gears, however, should always be unilateral and plus; otherwise, the gears might run too tight. A slight increase in the backlash between gears is seldom of much importance. One exception to the use of unilateral tolerances on mating surfaces occurs when tapers are involved; either bilateral or unilateral tolerances may then prove advisable, depending upon conditions. These tolerances should be determined in the same manner as the tolerances on the distances between holes. When a variation either in or out of the position of the mating taper surfaces is equally dangerous, the tolerances should be bilateral. When a variation in one direction is of less danger than a variation in the opposite direction, the tolerance should be unilateral and in the less dangerous direction. Locating Tolerance Dimensions.—Only one dimension in the same straight line can be controlled within fixed limits. That dimension is the distance between the cutting surface of the tool and the locating or registering surface of the part being machined. Therefore, it is incorrect to locate any point or surface with tolerances from more than one point in the same straight line. Every part of a mechanism must be located in each plane. Every operating part must be located with proper operating allowances. After such requirements of location are met, all other surfaces should have liberal clearances. Dimensions should be given between those points or surfaces that it is essential to hold in a specific relation to each other. This restriction applies particularly to those surfaces in each plane that control the location of other component parts. Many dimensions are relatively unimportant in this respect. It is good practice to establish a common locating point in each plane and give, as far as possible, all such dimensions from these common locating points. The locating points on the drawing, the locatingor registering points used for machining the surfaces and the locating points for measuring should all be identical. The initial dimensions placed on component drawings should be the exact dimensions that would be used if it were possible to work without tolerances. Tolerances should be 2 ± 0.001 or
2
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition FITS
647
given in that direction in which variations will cause the least harm or danger. When a variation in either direction is equally dangerous, the tolerances should be of equal amount in both directions, or bilateral. The initial clearance, or allowance, between operating parts should be as small as the operation of the mechanism will permit. The maximum clearance should be as great as the proper functioning of the mechanism will permit. Direction of Tolerances on Gages.—The extreme sizes for all plain limit gages shall not exceed the extreme limits of the part to be gaged. All variations in the gages, whatever their cause or purpose, shall bring these gages within these extreme limits. The data for gage tolerances on page 678 cover gages to inspect workpieces held to tolerances in the American National Standard ANSI B4.4M-1981. Allowance for Forced Fits.—The allowance per inch of diameter usually ranges from 0.001 inch to 0.0025 inch, 0.0015 being a fair average. Ordinarily the allowance per inch decreases as the diameter increases; thus the total allowance for a diameter of 2 inches might be 0.004 inch, whereas for a diameter of 8 inches the total allowance might not be over 0.009 or 0.010 inch. The parts to be assembled by forced fits are usually made cylindrical, although sometimes they are slightly tapered. The advantages of the taper form are that the possibility of abrasion of the fitted surfaces is reduced; that less pressure is required in assembling; and that the parts are more readily separated when renewal is required. On the other hand, the taper fit is less reliable, because if it loosens, the entire fit is free with but little axial movement. Some lubricant, such as white lead and lard oil mixed to the consistency of paint, should be applied to the pin and bore before assembling, to reduce the tendency toward abrasion. Pressure for Forced Fits.—The pressure required for assembling cylindrical parts depends not only upon the allowance for the fit, but also upon the area of the fitted surfaces, the pressure increasing in proportion to the distance that the inner member is forced in. The approximate ultimate pressure in tons can be determined by the use of the following formula in conjunction with the accompanying table of Pressure Factors for Forced Fits. Assuming that A = area of surface in contact in “fit”; a = total allowance in inches; P = ultimate pressure required, in tons; F = pressure factor based upon assumption that the diameter of the hub is twice the diameter of the bore, that the shaft is of machine steel, and that the hub is of cast iron: ×a×F P = A ---------------------2 Pressure Factors for Forced Fits Diameter, Inches
Pressure Factor
Diameter, Inches
Pressure Factor
1 11⁄4
500
31⁄2
395
33⁄4
123
11⁄2
325
13⁄4
276
4 41⁄4
2 21⁄4
240
41⁄2
212
43⁄4
21⁄2
189
132
Diameter, Inches
Pressure Factor
6 61⁄4
75
115
61⁄2
69
108
63⁄4
66
101
64
96
7 71⁄4
91
71⁄2
59
72
61
23⁄4
171
5 51⁄4
86
73⁄4
57
3 31⁄4
156
51⁄2
82
55
143
53⁄4
78
8 81⁄2
52
Diameter, Inches
Pressure Factor
9 91⁄2
48.7
10 101⁄2
43.5
11 111⁄2
39.3
12 121⁄2
35.9
13 131⁄2
46.0
Diameter, Inches 14 141⁄2
Pressure Factor 30.5 29.4
15 151⁄2
28.3
16 161⁄2
26.5 24.8
34.4
17 171⁄2
33.0
18
23.4
31.7
…
…
41.3 37.5
27.4 25.6 24.1
Allowance for Given Pressure.—By transposing the preceding formula, the approxi2P mate allowance for a required ultimate tonnage can be determined. Thus, a = ------- . The AF
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 648
FITS
average ultimate pressure in tons commonly used ranges from 7 to 10 times the diameter in inches. Expansion Fits.—In assembling certain classes of work requiring a very tight fit, the inner member is contracted by sub-zero cooling to permit insertion into the outer member and a tight fit is obtained as the temperature rises and the inner part expands. To obtain the sub-zero temperature, solid carbon dioxide or “dry ice” has been used but its temperature of about 109 degrees F. below zero will not contract some parts sufficiently to permit insertion in holes or recesses. Greater contraction may be obtained by using high purity liquid nitrogen which has a temperature of about 320 degrees F. below zero. During a temperature reduction from 75 degrees F. to −321 degrees F., the shrinkage per inch of diameter varies from about 0.002 to 0.003 inch for steel; 0.0042 inch for aluminum alloys; 0.0046 inch for magnesium alloys; 0.0033 inch for copper alloys; 0.0023 inch for monel metal; and 0.0017 inch for cast iron (not alloyed). The cooling equipment may vary from an insulated bucket to a special automatic unit, depending upon the kind and quantity of work. One type of unit is so arranged that parts are precooled by vapors from the liquid nitrogen before immersion. With another type, cooling is entirely by the vapor method. Shrinkage Fits.—General practice seems to favor a smaller allowance for shrinkage fits than for forced fits, although in many shops the allowances are practically the same for each, and for some classes of work, shrinkage allowances exceed those for forced fits. The shrinkage allowance also varies to a great extent with the form and construction of the part that has to be shrunk into place. The thickness or amount of metal around the hole is the most important factor. The way in which the metal is distributed also has an influence on the results. Shrinkage allowances for locomotive driving wheel tires adopted by the American Railway Master Mechanics Association are as follows: Center diameter, inches Allowances, inches
38
44
50
56
62
66
0.040
0.047
0.053
0.060
0.066
0.070
Whether parts are to be assembled by forced or shrinkage fits depends upon conditions. For example, to press a tire over its wheel center, without heating, would ordinarily be a rather awkward and difficult job. On the other hand, pins, etc., are easily and quickly forced into place with a hydraulic press and there is the additional advantage of knowing the exact pressure required in assembling, whereas there is more or less uncertainty connected with a shrinkage fit, unless the stresses are calculated. Tests to determine the difference in the quality of shrinkage and forced fits showed that the resistance of a shrinkage fit to slippage for an axial pull was 3.66 times greater than that of a forced fit, and in rotation or torsion, 3.2 times greater. In each comparative test, the dimensions and allowances were the same. Allowances for Shrinkage Fits.—The most important point to consider when calculating shrinkage fits is the stress in the hub at the bore, which depends chiefly upon the shrinkage allowance. If the allowance is excessive, the elastic limit of the material will be exceeded and permanent set will occur, or, in extreme conditions, the ultimate strength of the metal will be exceeded and the hub will burst. The intensity of the grip of the fit and the resistance to slippage depends mainly upon the thickness of the hub; the greater the thickness, the stronger the grip, and vice versa. Assuming the modulus of elasticity for steel to be 30,000,000, and for cast iron, 15,000,000, the shrinkage allowance per inch of nominal diameter can be determined by the following formula, in which A = allowance per inch of diameter; T = true tangential tensile stress at inner surface of outer member; C = factor taken from one of the accompanying Tables 1, 2, and 3. For a cast-iron hub and steel shaft: T(2 + C) A = --------------------------30 ,000 ,000
Copyright 2004, Industrial Press, Inc., New York, NY
(1)
Machinery's Handbook 27th Edition SHRINKAGE FIT
649
When both hub and shaft are of steel: T(1 + C) A = --------------------------(2) 30 ,000 ,000 If the shaft is solid, the factor C is taken from Table 1; if it is hollow and the hub is of steel, factor C is taken from Table 2; if it is hollow and the hub is of cast iron, the factor is taken from Table 3. Table 1. Factors for Calculating Shrinkage Fit Allowances for Steel Shafts and Steel or Cast Iron Hubs Ratio of Diameters D2 -----D1
1.5 1.6 1.8 2.0 2.2 2.4 2.6
Steel Hub
Cast-iron Hub
Ratio of Diameters
0.234 0.263 0.311 0.348 0.377 0.399 0.417
2.8 3.0 3.2 3.4 3.6 3.8 4.0
C 0.227 0.255 0.299 0.333 0.359 0.380 0.397
D2 -----D1
Steel Hub
Cast-iron Hub C
0.410 0.421 0.430 0.438 0.444 0.450 0.455
0.432 0.444 0.455 0.463 0.471 0.477 0.482
Values of factor C for solid steel shafts of nominal diameter D1, and hubs of steel or cast iron of nominal external and internal diameters D2 and D1, respectively.
Example 1:A steel crank web 15 inches outside diameter is to be shrunk on a 10-inch solid steel shaft. Required the allowance per inch of shaft diameter to produce a maximum tensile stress in the crank of 25,000 pounds per square inch, assuming the stresses in the crank to be equivalent to those in a ring of the diameter given. The ratio of the external to the internal diameters equals 15 ÷ 10 = 1.5; T = 25,000 pounds; from Table 1, C = 0.227. Substituting in Formula (2): ,000 × ( 1 + 0.227 -) = 0.001 inch A = 25 -------------------------------------------------30 ,000 ,000 Example 2:Find the allowance per inch of diameter for a 10-inch shaft having a 5-inch axial through hole, other conditions being the same as in Example 1. The ratio of external to internal diameters of the hub equals 15 ÷ 10 = 1.5, as before, and the ratio of external to internal diameters of the shaft equals 10 ÷ 5 = 2. From Table 2, we find that factor C = 0.455; T = 25,000 pounds. Substituting these values in Formula (2): 25 ,000 ( 1 + 0.455 ) A = --------------------------------------------- = 0.0012 inch 30 ,000 ,000 The allowance is increased, as compared with Example 1, because the hollow shaft is more compressible. Example 3:If the crank web in Example 1 is of cast iron and 4000 pounds per square inch is the maximum tensile stress in the hub, what is the allowance per inch of diameter? D2 ------ = 1.5 T = 4000 D1 In Table 1, we find that C = 0.234. Substituting in Formula (1), for cast-iron hubs, A = 0.0003 inch, which, owing to the lower tensile strength of cast iron, is about one-third the shrinkage allowance in Example 1, although the stress is two-thirds of the elastic limit. Temperatures for Shrinkage Fits.—The temperature to which the outer member in a shrinkage fit should be heated for clearance in assembling the parts depends on the total
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 650
SHRINKAGE FIT Table 2. Factors for Calculating Shrinkage Fit Allowances for Hollow Steel Shafts and Steel Hubs
D2 -----D1
D1 -----D0
Ca
D ------2 D1
D1 -----D0
Ca
D2 -----D1
D ------1 D0
Ca
1.5
2.0 2.5 3.0 3.5
0.455 0.357 0.313 0.288
2.4
2.0 2.5 3.0 3.5
0.760 0.597 0.523 0.481
3.4
2.0 2.5 3.0 3.5
0.876 0.689 0.602 0.555
1.6
2.0 2.5 3.0 3.5
0.509 0.400 0.350 0.322
2.6
2.0 2.5 3.0 3.5
0.793 0.624 0.546 0.502
3.6
2.0 2.5 3.0 3.5
0.888 0.698 0.611 0.562
1.8
2.0 2.5 3.0 3.5
0.599 0.471 0.412 0.379
2.8
2.0 2.5 3.0 3.5
0.820 0.645 0.564 0.519
3.8
2.0 2.5 3.0 3.5
0.900 0.707 0.619 0.570
2.0
2.0 2.5 3.0 3.5
0.667 0.524 0.459 0.422
3.0
2.0 2.5 3.0 3.5
0.842 0.662 0.580 0.533
4.0
2.0 2.5 3.0 3.5
0.909 0.715 0.625 0.576
2.2
2.0 2.5 3.0 3.5
0.718 0.565 0.494 0.455
3.2
2.0 2.5 3.0 3.5
0.860 0.676 0.591 0.544
…
… … … …
… … … …
a Values of factor C for hollow steel shafts of external and internal diameters D and D , respectively, 1 0 and steel hubs of nominal external diameter D2.
Table 3. Factors for Calculating Shrinkage Fit Allowances for Hollow Steel Shafts and Cast-iron Hubs D2 -----D1
D1 -----D0
Ca
D ------2 D1
D1 -----D0
Ca
D2 -----D1
D ------1 D0
Ca
1.5
2.0 2.5 3.0 3.5
0.468 0.368 0.322 0.296
2.4
2.0 2.5 3.0 3.5
0.798 0.628 0.549 0.506
3.4
2.0 2.5 3.0 3.5
0.926 0.728 0.637 0.587
1.6
2.0 2.5 3.0 3.5
0.527 0.414 0.362 0.333
2.6
2.0 2.5 3.0 3.5
0.834 0.656 0.574 0.528
3.6
2.0 2.5 3.0 3.5
0.941 0.740 0.647 0.596
1.8
2.0 2.5 3.0 3.5
0.621 0.488 0.427 0.393
2.8
2.0 2.5 3.0 3.5
0.864 0.679 0.594 0.547
3.8
2.0 2.5 3.0 3.5
0.953 0.749 0.656 0.603
2.0
2.0 2.5 3.0 3.5
0.696 0.547 0.479 0.441
3.0
2.0 2.5 3.0 3.5
0.888 0.698 0.611 0.562
4.0
2.0 2.5 3.0 3.5
0.964 0.758 0.663 0.610
2.2
2.0 2.5 3.0 3.5
0.753 0.592 0.518 0.477
3.2
2.0 2.5 3.0 3.5
0.909 0.715 0.625 0.576
…
… … … …
… … … …
a Values of factor C for hollow steel shafts and cast-iron hubs.
Notation as in Table 2.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition ANSI STANDARD LIMITS AND FITS
651
expansion required and on the coefficient α of linear expansion of the metal (i.e., the increase in length of any section of the metal in any direction for an increase in temperature of 1 degree F). The total expansion in diameter that is required consists of the total allowance for shrinkage and an added amount for clearance. The value of the coefficient α is, for nickel-steel, 0.000007; for steel in general, 0.0000065; for cast iron, 0.0000062. As an example, take an outer member of steel to be expanded 0.005 inch per inch of internal diameter, 0.001 being the shrinkage allowance and the remainder for clearance. Then α × t ° = 0.005 0.005 - = 769 degrees F t = -----------------------0.0000065 The value t is the number of degrees F that the temperature of the member must be raised above that of the room temperature. ANSI Standard Limits and Fits This American National Standard for Preferred Limits and Fits for Cylindrical Parts, ANSI B4.1-1967 (R1999), presents definitions of terms applying to fits between plain (non threaded) cylindrical parts and makes recommendations on preferred sizes, allowances, tolerances, and fits for use wherever they are applicable. This standard is in accord with the recommendations of American-British-Canadian (ABC) conferences up to a diameter of 20 inches. Experimental work is being carried on with the objective of reaching agreement in the range above 20 inches. The recommendations in the standard are presented for guidance and for use where they might serve to improve and simplify products, practices, and facilities. They should have application for a wide range of products. As revised in 1967, and reaffirmed in 1999, the definitions in ANSI B4.1 have been expanded and some of the limits in certain classes have been changed. Factors Affecting Selection of Fits.—Many factors, such as length of engagement, bearing load, speed, lubrication, temperature, humidity, and materials must be taken into consideration in the selection of fits for a particular application, and modifications in the ANSI recommendations may be required to satisfy extreme conditions. Subsequent adjustments may also be found desirable as a result of experience in a particular application to suit critical functional requirements or to permit optimum manufacturing economy. Definitions.—The following terms are defined in this standard: Nominal Size: The nominal size is the designation used for the purpose of general identification. Dimension: A dimension is a geometrical characteristic such as diameter, length, angle, or center distance. Size: Size is a designation of magnitude. When a value is assigned to a dimension, it is referred to as the size of that dimension. (It is recognized that the words “dimension” and “size” are both used at times to convey the meaning of magnitude.) Allowance: An allowance is a prescribed difference between the maximum material limits of mating parts. (See definition of Fit). It is a minimum clearance (positive allowance) or maximum interference (negative allowance) between such parts. Tolerance: A tolerance is the total permissible variation of a size. The tolerance is the difference between the limits of size. Basic Size: The basic size is that size from which the limits of size are derived by the application of allowances and tolerances. Design Size: The design size is the basic size with allowance applied, from which the limits of size are derived by the application of tolerances. Where there is no allowance, the design size is the same as the basic size. Actual Size: An actual size is a measured size. Limits of Size: The limits of size are the applicable maximum and minimum sizes.
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Machinery's Handbook 27th Edition 652
PREFERRED BASIC SIZES
Maximum Material Limit: A maximum material limit is that limit of size that provides the maximum amount of material for the part. Normally it is the maximum limit of size of an external dimension or the minimum limit of size of an internal dimension.* Minimum Material Limit: A minimum material limit is that limit of size that provides the minimum amount of material for the part. Normally it is the minimum limit of size of an external dimension or the maximum limit of size of an internal dimension.* Tolerance Limit: A tolerance limit is the variation, positive or negative, by which a size is permitted to depart from the design size. Unilateral Tolerance: A unilateral tolerance is a tolerance in which variation is permitted in only one direction from the design size. Bilateral Tolerance: A bilateral tolerance is a tolerance in which variation is permitted in both directions from the design size. Unilateral Tolerance System: A design plan that uses only unilateral tolerances is known as a Unilateral Tolerance System. Bilateral Tolerance System: A design plan that uses only bilateral tolerances is known as a Bilateral Tolerance System. Fits.— Fit: Fit is the general term used to signify the range of tightness that may result from the application of a specific combination of allowances and tolerances in the design of mating parts. Actual Fit: The actual fit between two mating parts is the relation existing between them with respect to the amount of clearance or interference that is present when they are assembled. (Fits are of three general types: clearance, transition, and interference.) Clearance Fit: A clearance fit is one having limits of size so specified that a clearance always results when mating parts are assembled. Interference Fit: An interference fit is one having limits of size so specified that an interference always results when mating parts are assembled. Transition Fit: A transition fit is one having limits of size so specified that either a clearance or an interference may result when mating parts are assembled. Basic Hole System: A basic hole system is a system of fits in which the design size of the hole is the basic size and the allowance, if any, is applied to the shaft. Basic Shaft System: A basic shaft system is a system of fits in which the design size of the shaft is the basic size and the allowance, if any, is applied to the hole. Preferred Basic Sizes.—In specifying fits, the basic size of mating parts shall be chosen from the decimal series or the fractional series in Table 4. Prefered Series for Tolerances and Allowances.—All fundamental tolerances and allowances of all shafts and holes have been taken from the series given in Table 5. Standard Tolerances.—The series of standard tolerances shown in Table 6 are so arranged that for any one grade they represent approximately similar production difficulties throughout the range of sizes. This table provides a suitable range from which appropriate tolerances for holes and shafts can be selected and enables standard gages to be used. The tolerances shown in Table 6 have been used in the succeeding tables for different classes of fits. Table 7 graphically illustrates the range of tolearance grades that various machining processes may produce under normal conditions. ANSI Standard Fits.—Tables 8a through 12 inclusive show a series of standard types and classes of fits on a unilateral hole basis, such that the fit produced by mating parts in any one class will produce approximately similar performance throughout the range of sizes. These tables prescribe the fit for any given size, or type of fit; they also prescribe the * An example of exceptions: an exterior corner radius where the maximum radius is the minimum mate-
rial limit and the minimum radius is the maximum material limit.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STANDARD FITS
653
Table 4. Preferred Basic Sizes ANSI B4.1-1967 (R1999) Decimala
Fractionala
0.010
2.00
8.50
1⁄ 64
0.015625
21⁄4
2.2500
91⁄2
9.5000
0.012
2.20
9.00
1⁄ 32
0.03125
21⁄2
2.5000
10
10.0000 10.5000
0.016
2.40
9.50
1⁄ 16
0.0625
23⁄4
2.7500
101⁄2
0.020
2.60
10.00
3⁄ 32
0.09375
3
3.0000
11
11.0000
0.025
2.80
10.50
1⁄ 8
0.1250
31⁄4
3.2500
111⁄2
11.5000
0.032
3.00
11.00
5⁄ 32
0.15625
31⁄2
3.5000
12
12.0000
0.040
3.20
11.50
3⁄ 16
0.1875
33⁄4
3.7500
121⁄2
12.5000
0.05
3.40
12.00
1⁄ 4
0.2500
4
4.0000
13
13.0000
0.06
3.60
12.50
5⁄ 16
0.3125
41⁄4
4.2500
131⁄2
13.5000
0.08
3.80
13.00
3⁄ 8
0.3750
41⁄2
4.5000
14
14.0000
0.10
4.00
13.50
7⁄ 16
0.4375
43⁄4
4.7500
141⁄2
14.5000
0.12
4.20
14.00
1⁄ 2
0.5000
5
5.0000
15
15.0000
0.16
4.40
14.50
9⁄ 16
0.5625
51⁄4
5.2500
151⁄2
15.5000
0.20
4.60
15.00
5⁄ 8
0.6250
51⁄2
5.5000
16
16.0000
0.24
4.80
15.50
11⁄ 16
0.6875
53⁄4
5.7500
161⁄2
16.5000 17.0000
0.30
5.00
16.00
3⁄ 4
0.7500
6
6.0000
17
0.40
5.20
16.50
7⁄ 8
0.8750
61⁄2
6.5000
171⁄2
17.5000
0.50 0.60
5.40 5.60
17.00 17.50
1
1.0000 1.2500
7 71⁄2
7.0000 7.5000
18
11⁄4
181⁄2
18.0000 18.5000 19.0000
0.80
5.80
18.00
11⁄2
1.5000
8
8.0000
19
1.00
6.00
18.50
13⁄4
1.7500
81⁄2
8.5000
191⁄2
19.5000
1.20 1.40 1.60 1.80
6.50 7.00 7.50 8.00
19.00 19.50 20.00 …
2 … … …
2.0000 … … …
9 … … …
9.0000 … … …
20 … … …
20.0000 … … …
a All dimensions are in inches.
Table 5. Preferred Series of Tolerances and Allowances a ANSI B4.1-1967 (R1999) 0.1 … 0.15 … … 0.2 … 0.25 …
1 1.2 1.4 1.6 1.8 2 2.2 2.5 2.8
10 12 14 16 18 20 22 25 28
100 125 … 160 … 200 … 250 …
0.3 … 0.4 … 0.5 0.6 0.7 0.8 0.9
3 3.5 4 4.5 5 6 7 8 9
30 35 40 45 50 60 70 80 …
… … … … … … … … …
a All values in thousandths of an inch
standard limits for the mating parts that will produce the fit. The fits listed in these tables contain all those that appear in the approved American-British-Canadian proposal. Selection of Fits: In selecting limits of size for any application, the type of fit is determined first, based on the use or service required from the equipment being designed; then the limits of size of the mating parts are established, to insure that the desired fit will be produced. Theoretically, an infinite number of fits could be chosen, but the number of standard fits shown in the accompanying tables should cover most applications. Designation of Standard Fits: Standard fits are designated by means of the following symbols which, facilitate reference to classes of fit for educational purposes. The symbols are not intended to be shown on manufacturing drawings; instead, sizes should be specified on drawings.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 654
STANDARD FITS Table 6. ANSI Standard Tolerances ANSI B4.1-1967 (R1999) Nominal Size, Inches
Over
To
0 0.12 0.24 0.40 0.71 1.19 1.97 3.15 4.73 7.09 9.85 12.41 15.75 19.69 30.09 41.49 56.19 76.39 100.9 131.9 171.9
0.12 0.24 0.40 0.71 1.19 1.97 3.15 4.73 7.09 9.85 12.41 15.75 19.69 30.09 41.49 56.19 76.39 100.9 131.9 171.9 200
Grade 4
5
6
7
8
9
10
11
12
13
Tolerances in thousandths of an incha 0.12 0.15 0.15 0.2 0.25 0.3 0.3 0.4 0.5 0.6 0.6 0.7 0.8 0.9 1.0 1.2 1.6 2.0 2.5 3 4
0.15 0.20 0.25 0.3 0.4 0.4 0.5 0.6 0.7 0.8 0.9 1.0 1.0 1.2 1.6 2.0 2.5 3 4 5 6
0.25 0.3 0.4 0.4 0.5 0.6 0.7 0.9 1.0 1.2 1.2 1.4 1.6 2.0 2.5 3 4 5 6 8 10
0.4 0.5 0.6 0.7 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.5 3 4 5 6 8 10 12 16
0.6 0.7 0.9 1.0 1.2 1.6 1.8 2.2 2.5 2.8 3.0 3.5 4 5 6 8 10 12 16 20 25
1.0 1.2 1.4 1.6 2.0 2.5 3.0 3.5 4.0 4.5 5.0 6 6 8 10 12 16 20 25 30 40
1.6 1.8 2.2 2.8 3.5 4.0 4.5 5 6 7 8 9 10 12 16 20 25 30 40 50 60
2.5 3.0 3.5 4.0 5.0 6 7 9 10 12 12 14 16 20 25 30 40 50 60 80 100
4 5 6 7 8 10 12 14 16 18 20 22 25 30 40 50 60 80 100 125 160
6 7 9 10 12 16 18 22 25 28 30 35 40 50 60 80 100 125 160 200 250
a All tolerances above heavy line are in accordance with American-British-Canadian (ABC) agreements.
Table 7. Relation of Machining Processes to Tolerance Grades ANSI B4.1-1967 (R1999) MACHINING OPERATION
TOLERANCE GRADES 4
5
6
7
8
9
10
Lapping & Honing Cylindrical Grinding Surface Grinding This chart may be used as a general guide to determine the machining processes that will under normal conditions, produce work withen the tolerance grades indicated. (See also Relation of Surface Roughness to Tolerances starting on page 729.
Diamond Turning Diamond Boring Broaching Reaming Turning Boring Milling Planing & Shaping Drilling
The letter symbols used to designate standard fits are as follows: RC = Running or Sliding Clearance Fit LC = Locational Clearance Fit LT = Transition Clearance or Interference Fit LN = Locational Interference Fit FN = Force or Shrink Fit
Copyright 2004, Industrial Press, Inc., New York, NY
11
12
13
Machinery's Handbook 27th Edition STANDARD FITS
655
These letter symbols are used in conjunction with numbers representing the class of fit; thus FN 4 represents a Class 4, force fit. Each of these symbols (two letters and a number) represents a complete fit for which the minimum and maximum clearance or interference and the limits of size for the mating parts are given directly in the tables. Description of Fits.—The classes of fits are arranged in three general groups: running and sliding fits, locational fits, and force fits. Running and Sliding Fits (RC): Running and sliding fits, for which limits of clearance are given in Table 8a, are intended to provide a similar running performance, with suitable lubrication allowance, throughout the range of sizes. The clearances for the first two classes, used chiefly as slide fits, increase more slowly with the diameter than for the other classes, so that accurate location is maintained even at the expense of free relative motion. These fits may be described as follows: RC 1 Close sliding fits are intended for the accurate location of parts that must assemble without perceptible play. RC 2 Sliding fits are intended for accurate location, but with greater maximum clearance than class RC 1. Parts made to this fit move and turn easily but are not intended to run freely, and in the larger sizes may seize with small temperature changes. RC 3 Precision running fits are about the closest fits that can be expected to run freely, and are intended for precision work at slow speeds and light journal pressures, but are not suitable where appreciable temperature differences are likely to be encountered. RC 4 Close running fits are intended chiefly for running fits on accurate machinery with moderate surface speeds and journal pressures, where accurate location and minimum play are desired. RC 5 and RC 6 Medium running fits are intended for higher running speeds, or heavy journal pressures, or both. RC 7 Free running fits are intended for use where accuracy is not essential, or where large temperature variations are likely to be encountered, or under both these conditions. RC 8 and RC 9 Loose running fits are intended for use where wide commercial tolerances may be necessary, together with an allowance, on the external member. Locational Fits (LC, LT, and LN): Locational fits are fits intended to determine only the location of the mating parts; they may provide rigid or accurate location, as with interference fits, or provide some freedom of location, as with clearance fits. Accordingly, they are divided into three groups: clearance fits (LC), transition fits (LT), and interference fits (LN). These are described as follows: LC Locational clearance fits are intended for parts which are normally stationary, but that can be freely assembled or disassembled. They range from snug fits for parts requiring accuracy of location, through the medium clearance fits for parts such as spigots, to the looser fastener fits where freedom of assembly is of prime importance. LT Locational transition fits are a compromise between clearance and interference fits, for applications where accuracy of location is important, but either a small amount of clearance or interference is permissible. LN Locational interference fits are used where accuracy of location is of prime importance, and for parts requiring rigidity and alignment with no special requirements for bore pressure. Such fits are not intended for parts designed to transmit frictional loads from one part to another by virtue of the tightness of fit. These conditions are covered by force fits. Force Fits: (FN): Force or shrink fits constitute a special type of interference fit, normally characterized by maintenance of constant bore pressures throughout the range of sizes. The interference therefore varies almost directly with diameter, and the difference
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 656
MODIFIED STANDARD FITS
between its minimum and maximum value is small, to maintain the resulting pressures within reasonable limits. These fits are described as follows: FN 1 Light drive fits are those requiring light assembly pressures, and produce more or less permanent assemblies. They are suitable for thin sections or long fits, or in cast-iron external members. FN 2 Medium drive fits are suitable for ordinary steel parts, or for shrink fits on light sections. They are about the tightest fits that can be used with high-grade cast-iron external members. FN 3 Heavy drive fits are suitable for heavier steel parts or for shrink fits in medium sections. FN 4 and FN 5 Force fits are suitable for parts that can be highly stressed, or for shrink fits where the heavy pressing forces required are impractical. Graphical Representation of Limits and Fits.—A visual comparison of the hole and shaft tolerances and the clearances or interferences provided by the various types and classes of fits can be obtained from the diagrams on page 657. These diagrams have been drawn to scale for a nominal diameter of 1 inch. Use of Standard Fit Tables.—Example 1:A Class RC 1 fit is to be used in assembling a mating hole and shaft of 2-inch nominal diameter. This class of fit was selected because the application required accurate location of the parts with no perceptible play (see Description of Fits, RC 1 close sliding fits). From the data in Table 8a, establish the limits of size and clearance of the hole and shaft. Maximum hole = 2 + 0.0005 = 2.0005; minimum hole = 2 inches Maximum shaft = 2 − 0.0004 = 1.9996; minimum shaft = 2 − 0.0007 = 1.9993 inches Minimum clearance = 0.0004; maximum clearance = 0.0012 inch Modified Standard Fits.—Fits having the same limits of clearance or interference as those shown in Tables 8a to 12 may sometimes have to be produced by using holes or shafts having limits of size other than those shown in these tables. These modifications may be accomplished by using either a Bilateral Hole System (Symbol B) or a Basic Shaft System (Symbol S). Both methods will result in nonstandard holes and shafts. Bilateral Hole Fits (Symbol B): The common situation is where holes are produced with fixed tools such as drills or reamers; to provide a longer wear life for such tools, a bilateral tolerance is desired. The symbols used for these fits are identical with those used for standard fits except that they are followed by the letter B. Thus, LC 4B is a clearance locational fit, Class 4, except that it is produced with a bilateral hole. The limits of clearance or interference are identical with those shown in Tables 8a to 12 for the corresponding fits. The hole tolerance, however, is changed so that the plus limit is that for one grade finer than the value shown in the tables and the minus limit equals the amount by which the plus limit was lowered. The shaft limits are both lowered by the same amount as the lower limit of size of the hole. The finer grade of tolerance required to make these modifications may be obtained from Table 6. For example, an LC 4B fit for a 6-inch diameter hole would have tolerance limits of +4.0, −2.0 ( + 0.0040 inch, − 0.0020 inch); the shaft would have tolerance limits of −2.0, −6.0 ( −0.0020 inch, −0.0060 inch). Basic Shaft Fits (Symbol S): For these fits, the maximum size of the shaft is basic. The limits of clearance or interference are identical with those shown in Tables 8a to 12 for the corresponding fits and the symbols used for these fits are identical with those used for standard fits except that they are followed by the letter S. Thus, LC 4S is a clearance locational fit, Class 4, except that it is produced on a basic shaft basis.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
; ; ;;; ;;; ;;; ;;; ;; ;;;;;;; MODIFIED STANDARD FITS
657
The limits for hole and shaft as given in Tables 8a to 12 are increased for clearance fits (decreased for transition or interference fits) by the value of the upper shaft limit; that is, by the amount required to change the maximum shaft to the basic size. Graphical Representation of ANSI Standard Limits and Fits ANSI B4.1-1967 (R1999)
Hole Tolerance
6 4 2 0 –2 –4 –6 –8 –10 12 10 8 6 4 2 0 –2 –4 –6 –8 –10 –12 –14 –16 –18 –20 –22
Shaft Tolerance
RC9
RC8
RC2
RC1
RC3
RC4
RC6
RC5
RC7
Running or Sliding Fits
LC11
LC10
LC9
LC7
LC4
LC1
LC2
LC3
LC5
LC8
LC6
;; ;; ; ; ; ;; ;;;;;;;; ;; ;;;; ;;
2 1 0 –1
Clearance Locational Fits
LT1
LT2
LT3
LT4
LT6
LT5
Transition Fits
FN3
LN3
LN2 2 LN1 1 0 Interference Locational Fits
2 1 0 –1
FN1
FN2
FN3
FN3
Force or Shrink Fits
Diagrams show disposition of hole and shaft tolerances (in thousandths of an inch) with respect to basic size (0) for a diameter of 1 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
658
Table 8a. American National Standard Running and Sliding Fits ANSI B4.1-1967 (R1999) Nominal Size Range, Inches Over
Class RC 1
Class RC 2
Class RC 3
Class RC 4
Standard Tolerance Limits
Standard Tolerance Limits
Standard Tolerance Limits
Standard Tolerance Limits
Clearancea
Hole H5
Shaft g4
Clearancea
Hole H6
0.1
+0.2
−0.1
0.1
+0.25
0.45
−0.1
0.3
+0.4
0
−0.25
0.55
0
−0.3
0.95
0
0.15
+0.2
−0.15
0.15
+0.3
−0.15
0.4
+0.5
To
0 – 0.12
0.24 – 0.40 0.40 – 0.71 0.71 – 1.19 1.19 – 1.97 1.97 – 3.15 3.15 – 4.73 4.73 – 7.09 7.09 – 9.85 9.85 – 12.41 12.41 – 15.75 15.75 – 19.69
Clearancea
Hole H7
Shaft f6
Clearancea
Hole H8
Shaft f7
−0.3
0.3
+0.6
−0.3
−0.55
1.3
0
−0.7
−0.4
0.4
+0.7
−0.4
Values shown below are in thousandths of an inch
0.5
0
−0.3
0.65
0
−0.35
1.12
0
−0.7
1.6
0
−0.9
0.2
+0.25
−0.2
0.2
+0.4
−0.2
0.5
+0.6
−0.5
0.5
+0.9
−0.5
0.6
0
−0.35
0.85
0
−0.45
1.5
0
−0.9
2.0
0
−1.1
0.25
+0.3
−0.25
0.25
+0.4
−0.25
0.6
+0.7
−0.6
0.6
+1.0
−0.6
0.75
0
−0.45
0.95
0
−0.55
1.7
0
−1.0
2.3
0
−1.3
0.3
+0.4
−0.3
0.3
+0.5
−0.3
0.8
+0.8
−0.8
0.8
+1.2
−0.8
0.95
0
−0.55
1.2
0
−0.7
2.1
0
−1.3
2.8
0
−1.6
0.4
+0.4
−0.4
0.4
+0.6
−0.4
1.0
+1.0
−1.0
1.0
+1.6
−1.0
1.1
0
−0.7
1.4
0
−0.8
2.6
0
−1.6
3.6
0
−2.0
0.4
+0.5
−0.4
0.4
+0.7
−0.4
1.2
+1.2
−1.2
1.2
+1.8
−1.2
1.2
0
−0.7
1.6
0
−0.9
3.1
0
−1.9
4.2
0
−2.4
0.5
+0.6
−0.5
0.5
+0.9
−0.5
1.4
+1.4
−1.4
1.4
+2.2
−1.4
1.5
0
−0.9
2.0
0
−1.1
3.7
0
−2.3
5.0
0
−2.8
0.6
+0.7
−0.6
0.6
+1.0
−0.6
1.6
+1.6
−1.6
1.6
+2.5
−1.6
1.8
0
−1.1
2.3
0
−1.3
4.2
0
−2.6
5.7
0
−3.2
0.6
+0.8
−0.6
0.6
+1.2
−0.6
2.0
+1.8
−2.0
2.0
+2.8
−2.0
2.0
0
−1.2
2.6
0
−1.4
5.0
0
−3.2
6.6
0
−3.8
0.8
+0.9
−0.8
0.8
+1.2
−0.8
2.5
+2.0
−2.5
2.5
+3.0
−2.5
2.3
0
−1.4
2.9
0
−1.7
5.7
0
−3.7
7.5
0
−4.5
1.0
+1.0
−1.0
1.0
+1.4
−1.0
3.0
+2.2
−3.0
3.0
+3.5
−3.0
2.7
0
−1.7
3.4
0
−2.0
6.6
0
−4.4
8.7
0
−5.2
1.2
+1.0
−1.2
1.2
+1.6
−1.2
4.0
+2.5
−4.0
4.0
+4.0
−4.0
3.0
0
−2.0
3.8
0
−2.2
8.1
0
−5.6
10.5
0
−6.5
Copyright 2004, Industrial Press, Inc., New York, NY
RUNNING AND SLIDING FITS
0.12 – 0.24
Shaft g5
Machinery's Handbook 27th Edition
Table 8b. American National Standard Running and Sliding Fits ANSI B4.1-1967 (R1999) Class RC 5 Nominal Size Range, Inches Over
Class RC 6
Standard Tolerance Limits Clearancea
Hole H8
Shaft e7
Clearancea
Hole H9
To
0 – 0.12 0.12 – 0.24
0.71 – 1.19 1.19 – 1.97 1.97 – 3.15 3.15 – 4.73 4.73 – 7.09 7.09 – 9.85 9.85 – 12.41 12.41 – 15.75 15.75 – 19.69
Shaft e8
Class RC 8
Standard Tolerance Limits Clearancea
Hole H9
Shaft d8
Class RC 9
Standard Tolerance Limits Clearancea
Standard Tolerance Limits
Hole H10
Shaft c9
Clearancea
Hole H11
Shaft
+1.6 0 +1.8 0 +2.2 0 +2.8 0 +3.5 0 +4.0 0 +4.5 0 +5.0 0 +6.0 0 +7.0 0 +8.0 0 +9.0 0 +10.0 0
− 2.5 − 3.5 − 2.8 − 4.0 − 3.0 − 4.4 − 3.5 − 5.1 − 4.5 − 6.5 − 5.0 − 7.5 − 6.0 − 9.0 − 7.0 −10.5 − 8.0 −12.0 −10.0 −14.5 −12.0 −17.0 −14.0 −20.0 −16.0 −22.0
4.0 8.1 4.5 9.0 5.0 10.7 6.0 12.8 7.0 15.5 8.0 18.0 9.0 20.5 10.0 24.0 12.0 28.0 15.0 34.0 18.0 38.0 22.0 45.0 25.0 51.0
+2.5 0 +3.0 0 +3.5 0 +4.0 0 +5.0 0 +6.0 0 +7.0 0 +9.0 0 +10.0 0 +12.0 0 +12.0 0 +14.0 0 +16.0 0
− 4.0 − 5.6 − 4.5 − 6.0 − 5.0 − 7.2 − 6.0 − 8.8 − 7.0 −10.5 − 8.0 −12.0 − 9.0 −13.5 −10.0 −15.0 −12.0 −18.0 −15.0 −22.0 −18.0 −26.0 −22.0 −31.0 −25.0 −35.0
Values shown below are in thousandths of an inch 0.6 1.6 0.8 2.0 1.0 2.5 1.2 2.9 1.6 3.6 2.0 4.6 2.5 5.5 3.0 6.6 3.5 7.6 4.0 8.6 5.0 10.0 6.0 11.7 8.0 14.5
+0.6 0 +0.7 0 +0.9 0 +1.0 0 +1.2 0 +1.6 0 +1.8 0 +2.2 0 +2.5 0 +2.8 0 +3.0 0 +3.5 0 +4.0 0
− 0.6 − 1.0 − 0.8 − 1.3 − 1.0 − 1.6 − 1.2 − 1.9 − 1.6 − 2.4 − 2.0 − 3.0 − 2.5 − 3.7 − 3.0 − 4.4 − 3.5 − 5.1 − 4.0 − 5.8 − 5.0 − 7.0 − 6.0 − 8.2 − 8.0 −10.5
0.6 2.2 0.8 2.7 1.0 3.3 1.2 3.8 1.6 4.8 2.0 6.1 2.5 7.3 3.0 8.7 3.5 10.0 4.0 11.3 5.0 13.0 6.0 15.5 8.0 18.0
+1.0 0 +1.2 0 +1.4 0 +1.6 0 +2.0 0 +2.5 0 +3.0 0 +3.5 0 +4.0 0 +4.5 0 +5.0 0 +6.0 0 +6.0 0
− 0.6 − 1.2 − 0.8 − 1.5 − 1.0 − 1.9 − 1.2 − 2.2 − 1.6 − 2.8 − 2.0 − 3.6 − 2.5 − 4.3 − 3.0 − 5.2 − 3.5 − 6.0 − 4.0 − 6.8 − 5.0 − 8.0 − 6.0 − 9.5 − 8.0 −12.0
1.0 2.6 1.2 3.1 1.6 3.9 2.0 4.6 2.5 5.7 3.0 7.1 4.0 8.8 5.0 10.7 6.0 12.5 7.0 14.3 8.0 16.0 10.0 19.5 12.0 22.0
+1.0 0 +1.2 0 +1.4 0 +1.6 0 +2.0 0 +2.5 0 +3.0 0 +3.5 0 +4.0 0 +4.5 0 +5.0 0 +6.0 0 +6.0 0
− 1.0 − 1.6 − 1.2 − 1.9 − 1.6 − 2.5 − 2.0 − 3.0 − 2.5 − 3.7 − 3.0 − 4.6 − 4.0 − 5.8 − 5.0 − 7.2 − 6.0 − 8.5 − 7.0 − 9.8 − 8.0 −11.0 −10.0 −13.5 −12.0 −16.0
2.5 5.1 2.8 5.8 3.0 6.6 3.5 7.9 4.5 10.0 5.0 11.5 6.0 13.5 7.0 15.5 8.0 18.0 10.0 21.5 12.0 25.0 14.0 29.0 16.0 32.0
RUNNING AND SLIDING FITS
0.24 – 0.40 0.40 – 0.71
Class RC 7
Standard Tolerance Limits
a Pairs of values shown represent minimum and maximum amounts of clearance resulting from application of standard tolerance limits.
Copyright 2004, Industrial Press, Inc., New York, NY
659
Tolerance limits given in body of table are added to or subtracted from basic size (as indicated by + or − sign) to obtain maximum and minimum sizes of mating parts. All data above heavy lines are in accord with ABC agreements. Symbols H5, g4, etc. are hole and shaft designations in ABC system. Limits for sizes above 19.69 inches are also given in the ANSI Standard.
Machinery's Handbook 27th Edition
660
Table 9a. American National Standard Clearance Locational Fits ANSI B4.1-1967 (R1999) Class LC 1 Nominal Size Range, Inches Over
Class LC 2
Standard Tolerance Limits Clearancea
Hole H6
Shaft h5
0
+0.25
0
Clearancea
Hole H7
Shaft h6
0
+0.4
0
To
0– 0.12
0.24– 0.40 0.40– 0.71 0.71– 1.19 1.19– 1.97 1.97– 3.15 3.15– 4.73 4.73– 7.09 7.09– 9.85 9.85– 12.41 12.41– 15.75 15.75– 19.69
Class LC 4
Standard Tolerance Limits Clearancea
Hole H8
Shaft h7
Class LC 5
Standard Tolerance Limits Clearancea
Hole H10
Shaft h9
Standard Tolerance Limits Clearancea
Hole H7
Shaft g6
Values shown below are in thousandths of an inch 0.45 0 0.5 0 0.65 0 0.7 0 0.9 0 1.0 0 1.2 0 1.5 0 1.7 0 2.0 0 2.1 0 2.4 0 2.6
0
−0.2
+0.3
0
0
−0.2
+0.4
0
0
−0.25
+0.4
0
0
−0.3
+0.5
0
0
−0.4
+0.6
0
0
−0.4
+0.7
0
0
−0.5
+0.9
0
0
−0.6
+1.0
0
0
−0.7
+1.2
0
0
−0.8
+1.2
0
0
−0.9
+1.4
0
0
−1.0
+1.6
0
0
−1.0
0.65 0 0.8 0 1.0 0 1.1 0 1.3 0 1.6 0 1.9 0 2.3 0 2.6 0 3.0 0 3.2 0 3.6 0 4.1
0
−0.25
0
+0.6
0
1
0
−0.4
0
+0.7
0
0
−0.5
+0.9
0
0
−0.6
+1.0
0
0
−0.7
+0.5
0
0
−0.3
+0.6
0
0
−0.4
+0.7
0
0
−0.4
+0.8
0
0
+1.2
0
0
−0.5
2
0
−0.8
+1.0
0
0
+1.6
0
0
−0.6
0
−1
+1.2
0
0
+1.8
0
0
−0.7
3
0
−1.2
+1.4
0
0
+2.2
0
0
−0.9
+1.6
0
0
−1.0
+1.8
0
0
−1.2
+2.0
0
0
1.2 0 1.5 0 1.7
2.6
0 2.6 0 3.0 0 3.6 0 4.4 0 5.5 0 6.5 0 7.5 0
+1.6
0
0.1
+0.4
−0.1
0
−1.0
0.75
0
−0.35
+1.8
0
0.15
+0.5
−0.15
0
−1.2
0.95
0
−0.45
+2.2
0
0.2
+0.6
−0.2
0
−1.4
1.2
0
−0.6
+2.8
0
0.25
+0.7
−0.25
0
−1.6
1.35
0
−0.65
+3.5
0
0.3
+0.8
−0.3
0
−2.0
1.6
0
−0.8
+4.0
0
0.4
+1.0
−0.4
0
−2.5
2.0
0
−1.0
+4.5
0
0.4
+1.2
−0.4
0
−3
2.3
0
−1.1
+5.0
0
0.5
+1.4
−0.5
0
−1.4
0
−3.5
2.8
0
−1.4
+2.5
0
0
+6.0
0
0.6
+1.6
−0.6
0
−1.6
10.0
0
−4
3.2
0
−1.6
+2.8
0
0
+7.0
0
0.6
+1.8
−0.6
0
−1.8
11.5
0
−4.5
3.6
0
−1.8
0
+3.0
0
0
+8.0
0
0.7
+2.0
−0.7
−1.2
5
0
−2.0
13.0
0
−5
3.9
0
−1.9
+2.2
0
0
+3.5
0
0
+9.0
0
0.7
+2.2
−0.7
0
−1.4
+2.5
0
0
−1.6
3.6 0 4.1 0 4.6
5.7 0 6.5
8.5
0
−2.2
15.0
0
−6
4.3
0
−2.1
+4
0
0
+10.0
0
0.8
+2.5
−0.8
0
−2.5
16.0
0
−6
4.9
0
−2.4
Copyright 2004, Industrial Press, Inc., New York, NY
CLEARANCE LOCATIONAL FITS
0.12– 0.24
Class LC 3
Standard Tolerance Limits
Machinery's Handbook 27th Edition
Table 9b. American National Standard Clearance Locational Fits ANSI B4.1-1967 (R1999) Class LC 6 Nominal Size Range, Inches Over
Class LC 7
Std. Tolerance Limits Clearancea
Hole H9
Shaft f8
Class LC 8
Std. Tolerance Limits Clearancea
Hole H10
Shaft e9
Clearancea
To
0 – 0.12 0.12 − 0.24
0.40 – 0.71 0.71 – 1.19 1.19 – 1.97 1.97 – 3.15 3.15 – 4.73 4.73 – 7.09 7.09 − 9.85 9.85 – 12.41 12.41 – 15.75 15.75– 19.69
Hole H10
Shaft d9
Std. Tolerance Limits Clearancea
Hole H11
Shaft c10
Clearancea
Class LC 10
Class LC 11
Std. Tolerance Limits
Std. Tolerance Limits
Hole H12
Shaft
Clearancea
Hole H13
5 17 6 20 7 25 8 28 10 34 12 44 14 50 16 60 18 68 22 78 28 88 30 100 35 115
+6 0 +7 0 +9 0 +10 0 +12 0 +16 0 +18 0 +22 0 +25 0 +28 0 +30 0 +35 0 +40 0
Shaft
Values shown below are in thousandths of an inch 0.3 1.9 0.4 2.3 0.5 2.8 0.6 3.2 0.8 4.0 1.0 5.1 1.2 6.0 1.4 7.1 1.6 8.1 2.0 9.3 2.2 10.2 2.5 12.0 2.8 12.8
+1.0 0 +1.2 0 +1.4 0 +1.6 0 +2.0 0 +2.5 0 +3.0 0 +3.5 0 +4.0 0 +4.5 0 +5.0 0 +6.0 0 +6.0 0
−0.3 −0.9 −0.4 −1.1 −0.5 −1.4 −0.6 −1.6 −0.8 −2.0 −1.0 −2.6 −1.0 −3.0 −1.4 −3.6 −1.6 −4.1 −2.0 −4.8 −2.2 −5.2 −2.5 −6.0 −2.8 −6.8
0.6 3.2 0.8 3.8 1.0 4.6 1.2 5.6 1.6 7.1 2.0 8.5 2.5 10.0 3.0 11.5 3.5 13.5 4.0 15.5 4.5 17.5 5.0 20.0 5.0 21.0
+1.6 0 +1.8 0 +2.2 0 +2.8 0 +3.5 0 +4.0 0 +4.5 0 +5.0 0 +6.0 0 +7.0 0 +8.0 0 +9.0 0 +10.0 0
− 0.6 − 1.6 − 0.8 − 2.0 − 1.0 − 2.4 − 1.2 − 2.8 − 1.6 − 3.6 − 2.0 − 4.5 − 2.5 − 5.5 − 3.0 − 6.5 − 3.5 − 7.5 − 4.0 − 8.5 − 4.5 − 9.5 − 5 −11 − 5 −11
1.0 2.0 1.2 4.2 1.6 5.2 2.0 6.4 2.5 8.0 3.6 9.5 4.0 11.5 5.0 13.5 6 16 7 18.5 7 20 8 23 9 25
+1.6 0 +1.8 0 +2.2 0 +2.8 0 +3.5 0 +4.0 0 +4.5 0 +5.0 0 +6 0 +7 0 +8 0 +9 0 +10 0
− 1.0 − 2.0 − 1.2 − 2.4 − 1.6 − 3.0 − 2.0 − 3.6 − 2.5 − 4.5 − 3.0 − 5.5 − 4.0 − 7.0 − 5.0 − 8.5 − 6 −10 − 7 −11.5 − 7 −12 − 8 −14 − 9 −15
2.5 6.6 2.8 7.6 3.0 8.7 3.5 10.3 4.5 13.0 5.0 15.0 6.0 17.5 7 21 8 24 10 29 12 32 14 37 16 42
+2.5 0 +3.0 0 +3.5 0 +4.0 0 +5.0 0 +6 0 +7 0 +9 0 +10 0 +12 0 +12 0 +14 0 +16 0
− 2.5 − 4.1 − 2.8 − 4.6 − 3.0 − 5.2 − 3.5 − 6.3 − 4.5 − 8.0 − 5.0 − 9.0 − 6.0 −10.5 − 7 −12 − 8 −14 −10 −17 −12 −20 −14 −23 −16 −26
4 12 4.5 14.5 5 17 6 20 7 23 8 28 10 34 11 39 12 44 16 52 20 60 22 66 25 75
+4 0 +5 0 +6 0 +7 0 +8 0 +10 0 +12 0 +14 0 +16 0 +18 0 +20 0 +22 0 +25 0
− 4 − 8 − 4.5 − 9.5 − 5 −11 − 6 −13 − 7 −15 − 8 −18 −10 −22 −11 −25 −12 −28 −16 −34 −20 −40 −22 −44 −25 −50
− 5 − 11 − 6 −13 − 7 −16 − 8 −18 −10 −22 −12 −28 −14 −32 −16 −38 −18 −43 −22 −50 −28 −58 −30 −65 −35 −75
CLEARANCE LOCATIONAL FITS
0.24 − 0.40
Class LC 9
Std. Tolerance Limits
a Pairs of values shown represent minimum and maximum amounts of interference resulting from application of standard tolerance limits.
Copyright 2004, Industrial Press, Inc., New York, NY
661
Tolerance limits given in body of table are added or subtracted to basic size (as indicated by + or − sign) to obtain maximum and minimum sizes of mating parts. All data above heavy lines are in accordance with American-British-Canadian (ABC) agreements. Symbols H6, H7, s6, etc. are hole and shaft designations in ABC system. Limits for sizes above 19.69 inches are not covered by ABC agreements but are given in the ANSI Standard.
Machinery's Handbook 27th Edition
Nominal Size Range, Inches Over
Class LT 2
Std. Tolerance Limits Fita
Hole H7
Shaft js6
Class LT 3
Std. Tolerance Limits Fita
Hole H8
Shaft js7
Fita
To
0 – 0.12
0.40 – 0.71 0.71 – 1.19 1.19 – 1.97 1.97 – 3.15 3.15 – 4.73 4.73 – 7.09 7.09 – 9.85 9.85 – 12.41 12.41 – 15.75 15.75 – 19.69
Hole H7
Shaft k6
Class LT 5
Std. Tolerance Limits Fita
Hole H8
Shaft k7
Class LT 6
Std. Tolerance Limits
Std. Tolerance Limits
Fita
Hole H7
Shaft n6
Fita
Hole H7
Shaft n7
−0.5 +0.15 −0.6 +0.2 −0.8 +0.2 −0.9 +0.2 −1.1 +0.2 −1.3 +0.3 −1.5 +0.4 −1.9 +0.4 −2.2 +0.4 −2.6 +0.4 −2.6 +0.6 −3.0 +0.6 −3.4 +0.7
+0.4 0 +0.5 0 +0.6 0 +0.7 0 +0.8 0 +1.0 0 +1.2 0 +1.4 0 +1.6 0 +1.8 0 +2.0 0 +2.2 0 +2.5 0
+0.5 +0.25 +0.6 +0.3 +0.8 +0.4 +0.9 +0.5 +1.1 +0.6 +1.3 +0.7 +1.5 +0.8 +1.9 +1.0 +2.2 +1.2 +2.6 +1.4 +2.6 +1.4 +3.0 +1.6 +3.4 +1.8
−0.65 +0.15 −0.8 +0.2 −1.0 +0.2 −1.2 +0.2 −1.4 +0.2 −1.7 +0.3 −2.0 +0.4 −2.4 +0.4 −2.8 +0.4 −3.2 +0.4 −3.4 +0.6 −3.8 +0.6 −4.3 +0.7
+0.4 0 +0.5 0 +0.6 0 +0.7 0 +0.8 0 +1.0 0 +1.2 0 +1.4 0 +1.6 0 +1.8 0 +2.0 0 +2.2 0 +2.5 0
+0.65 +0.25 +0.8 +0.3 +1.0 +0.4 +1.2 +0.5 +1.4 +0.6 +1.7 +0.7 +2.0 +0.8 +2.4 +1.0 +2.8 +1.2 +3.2 +1.4 +3.4 +1.4 +3.8 +1.6 +4.3 +1.8
Values shown below are in thousandths of an inch −0.12 +0.52 −0.15 +0.65 −0.2 +0.8 −0.2 +0.9 −0.25 +1.05 −0.3 +1.3 −0.3 +1.5 −0.4 +1.8 −0.5 +2.1 −0.6 +2.4 −0.6 +2.6 −0.7 +2.9 −0.8 +3.3
+0.4 0 +0.5 0 +0.6 0 +0.7 0 +0.8 0 +1.0 0 +1.2 0 +1.4 0 +1.6 0 +1.8 0 +2.0 0 +2.2 0 +2.5 0
+0.12 −0.12 +0.15 −0.15 +0.2 −0.2 +0.2 −0.2 +0.25 −0.25 +0.3 −0.3 +0.3 −0.3 +0.4 −0.4 +0.5 −0.5 +0.6 −0.6 +0.6 −6.6 +0.7 −0.7 +0.8 −0.8
−0.2 +0.8 −0.25 +0.95 −0.3 +1.2 −0.35 +1.35 −0.4 +1.6 −0.5 +2.1 −0.6 +2.4 −0.7 +2.9 −0.8 +3.3 −0.9 +3.7 −1.0 +4.0 −1.0 +4.5 −1.2 +5.2
+0.6 0 +0.7 0 +0.9 0 +1.0 0 +1.2 0 +1.6 0 +1.8 0 +2.2 0 +2.5 0 +2.8 0 +3.0 0 +3.5 0 +4.0 0
+0.2 −0.2 +0.25 −0.25 +0.3 −0.3 +0.35 −0.35 +0.4 −0.4 +0.5 −0.5 +0.6 −0.6 +0.7 −0.7 +0.8 −0.8 +0.9 −0.9 +1.0 −1.0 +1.0 −1.0 +1.2 −1.2
−0.5 +0.5 −0.5 +0.6 −0.6 +0.7 −0.7 +0.9 −0.8 +1.1 −1.0 +1.3 −1.1 +1.5 −1.4 +1.6 −1.4 +1.8 −1.6 +2.0 −1.8 +2.3
+0.6 0 +0.7 0 +0.8 0 +1.0 0 +1.2 0 +1.4 0 +1.6 0 +1.8 0 +2.0 0 +2.2 0 +2.5 0
+0.5 +0.1 +0.5 +0.1 +0.6 +0.1 +0.7 +0.1 +0.8 +0.1 +1.0 +0.1 +1.1 +0.1 +1.4 +0.2 +1.4 +0.2 +1.6 +0.2 +1.8 +0.2
−0.7 +0.8 −0.8 +0.9 −0.9 +1.1 −1.1 +1.5 −1.3 +1.7 −1.5 +2.1 −1.7 +2.4 −2.0 +2.6 −2.2 +2.8 −2.4 +3.3 −2.7 +3.8
+0.9 0 +1.0 0 +1.2 0 +1.6 0 +1.8 0 +2.2 0 +2.5 0 +2.8 0 +3.0 0 +3.5 0 +4.0 0
+0.7 +0.1 +0.8 +0.1 +0.9 +0.1 +1.1 +0.1 +1.3 +0.1 +1.5 +0.1 +1.7 +0.1 +2.0 +0.2 +2.2 +0.2 +2.4 +0.2 +2.7 +0.2
a Pairs of values shown represent maximum amount of interference (−) and maximum amount of clearance (+) resulting from application of standard tolerance limits. All data above heavy lines are in accord with ABC agreements. Symbols H7, js6, etc., are hole and shaft designations in the ABC system.
Copyright 2004, Industrial Press, Inc., New York, NY
TRANSITION LOCATIONAL FITS
0.12 – 0.24 0.24 – 0.40
Class LT 4
Std. Tolerance Limits
662
Table 10. ANSI Standard Transition Locational Fits ANSI B4.1-1967 (R1999) Class LT 1
Machinery's Handbook 27th Edition
Table 11. ANSI Standard Force and Shrink Fits ANSI B4.1-1967 (R1999) Class FN 1 Nominal Size Range, Inches Over
Interferencea
Hole H6
0.12– 0.24
Shaft
Interferencea
Hole H7
Shaft s6
+0.5
0.2
+0.4
+0.85
0.40– 0.56 0.56– 0.71 0.71– 0.95 0.95– 1.19 1.58
1.58– 1.97 1.97– 2.56 2.56– 3.15 3.15– 3.94 3.94– 4.73
Class FN 4
Standard Tolerance Limits Interferencea
Hole H7
Shaft t6
Class FN 5
Standard Tolerance Limits Interferencea
Hole H7
Shaft u6
Standard Tolerance Limits Interferencea
Hole H8
Shaft x7
Values shown below are in thousandths of an inch 0.3
+0.4
+0.95
0.3
+0.6
+1.3
0.5
0
+0.3
0.85
0
+0.6
0.95
0
+0.7
1.3
0
+0.9
0.1
+0.3
+0.6
0.2
+0.5
+1.0
0.4
+0.5
+1.2
0.5
+0.7
+1.7
0.6
0
+0.4
1.0
0
+0.7
1.2
0
+0.9
1.7
0
+1.2
0.1
+0.4
+0.75
0.4
+0.6
+1.4
0.6
+0.6
+1.6
0.5
+0.9
+2.0
0.75
0
+0.5
1.4
0
+1.0
1.6
0
+1.2
2.0
0
+1.4
0.1
+0.4
+0.8
0.5
+0.7
+1.6
0.7
+0.7
+1.8
0.6
+1.0
+2.3
0.8
0
+0.5
1.6
0
+1.2
1.8
0
+1.4
2.3
0
+1.6
0.2
+0.4
+0.9
0.5
+0.7
+1.6
0.7
+0.7
+1.8
0.8
+1.0
+2.5
0.9
0
+0.6
1.6
0
+1.2
1.8
0
+1.4
2.5
0
+1.8
0.2
+0.5
+1.1
0.6
+0.8
+1.9
0.8
+0.8
+2.1
1.0
+1.2
+3.0
1.1
0
+0.7
1.9
0
+1.4
2.1
0
+1.6
3.0
0
+2.2
0.3
+0.5
+1.2
0.6
+0.8
+1.9
0.8
+0.8
+2.3
1.3
+1.2
+3.3
1.2
0
+0.8
1.9
0
+1.4
0.3
+0.6
+1.3
0.8
+1.0
+2.4
1.3
0
+0.9
2.4
0
0.4
+0.6
+1.4
0.8
1.4
0
+1.0
0.6
+0.7
1.8 0.7 1.9
0.05
+0.25
+2.1
+1.0
2.1
0
+1.6
2.3
0
+1.8
3.3
0
+2.5
1.0
+1.0
+2.6
1.5
+1.0
+3.1
1.4
+1.6
+4.0
+1.8
2.6
0
+2.0
3.1
0
+2.5
4.0
0
+3.0
+1.0
+2.4
1.2
+1.0
+2.8
1.8
+1.0
+3.4
2.4
+1.6
+5.0
2.4
0
+1.8
2.8
0
+2.2
3.4
0
+2.8
5.0
0
+4.0
+1.8
0.8
+1.2
+2.7
1.3
+1.2
+3.2
2.3
+1.2
+4.2
3.2
+1.8
+6.2
0
+1.3
2.7
0
+2.0
3.2
0
+2.5
4.2
0
+3.5
6.2
0
+5.0
+0.7
+1.9
1.0
+1.2
+2.9
1.8
+1.2
+3.7
2.8
+1.2
+4.7
4.2
+1.8
+7.2
0
+1.4
2.9
0
+2.2
3.7
0
+3.0
4.7
0
+4.0
7.2
0
+6.0
0.9
+0.9
+2.4
1.4
+1.4
+3.7
2.1
+1.4
+4.4
3.6
+1.4
+5.9
4.8
+2.2
+8.4
2.4
0
+1.8
3.7
0
+2.8
4.4
0
+3.5
5.9
0
+5.0
8.4
0
+7.0
1.1
+0.9
+2.6
1.6
+1.4
+3.9
2.6
+1.4
+4.9
4.6
+1.4
+6.9
5.8
+2.2
+9.4
2.6
0
+2.0
3.9
0
+3.0
4.9
0
+4.0
6.9
0
+6.0
9.4
0
+8.0
Copyright 2004, Industrial Press, Inc., New York, NY
663
+0.8
FORCE AND SHRINK FITS
0.24– 0.40
Class FN 3
Standard Tolerance Limits
To
0– 0.12
1.19–
Class FN 2
Standard Tolerance Limits
Machinery's Handbook 27th Edition
Nominal Size Range, Inches Over
Class FN 2
Standard Tolerance Limits Interferencea
Hole H6
Shaft
Interferencea
Hole H7
Shaft s6
+2.9
1.9
+1.6
+4.5
To 5.52
5.52–
6.30
6.30–
7.09
7.09–
7.88
7.88–
8.86
8.86–
9.85
9.85– 11.03 11.03– 12.41 12.41– 13.98 13.98– 15.75 15.75– 17.72 17.72– 19.69
Class FN 4
Standard Tolerance Limits Interferencea
Hole H7
Shaft t6
Class FN 5
Standard Tolerance Limits Interferencea
Hole H7
Shaft u6
Standard Tolerance Limits Interferencea
Hole H8
Shaft x7
Values shown below are in thousandths of an inch 3.4
+1.6
+6.0
5.4
+1.6
+8.0
7.5
+2.5
+11.6
2.9
0
+2.2
4.5
0
+3.5
6.0
0
+5.0
8.0
0
+7.0
11.6
0
+10.0
1.5
+1.0
+3.2
2.4
+1.6
+5.0
3.4
+1.6
+6.0
5.4
+1.6
+8.0
9.5
+2.5
+13.6
3.2
0
+2.5
5.0
0
+4.0
6.0
0
+5.0
8.0
0
+7.0
13.6
0
+12.0
1.8
+1.0
+3.5
2.9
+1.6
+5.5
4.4
+1.6
+7.0
6.4
+1.6
+9.0
9.5
+2.5
3.5
0
+2.8
5.5
0
+4.5
7.0
0
+6.0
9.0
0
+8.0
13.6
0
+12.0
1.8
+1.2
+3.8
3.2
+1.8
+6.2
5.2
+1.8
+8.2
7.2
+1.8
+10.2
11.2
+2.8
+15.8
3.8
0
+3.0
6.2
0
+5.0
8.2
0
+7.0
10.2
0
+9.0
15.8
0
+14.0
2.3
+1.2
+4.3
3.2
+1.8
+6.2
5.2
+1.8
+8.2
8.2
+1.8
+11.2
13.2
+2.8
+17.8
4.3
0
+3.5
6.2
0
+5.0
8.2
0
+7.0
11.2
0
+10.0
17.8
0
+16.0
2.3
+1.2
+4.3
4.2
+1.8
+7.2
6.2
+1.8
+9.2
10.2
+1.8
+13.2
13.2
+2.8
+17.8
4.3
0
+3.5
7.2
0
+6.0
9.2
0
+8.0
13.2
0
+12.0
17.8
0
+16.0
2.8
+1.2
+4.9
4.0
+2.0
+7.2
7.0
+2.0
+10.2
10.0
+2.0
+13.2
15.0
+3.0
+20.0
4.9
0
+4.0
7.2
0
+6.0
10.2
0
+9.0
13.2
0
+12.0
20.0
0
+18.0
2.8
+1.2
+4.9
5.0
+2.0
+8.2
7.0
+2.0
+10.2
12.0
+2.0
+15.2
17.0
+3.0
+22.0
4.9
0
+4.0
8.2
0
+7.0
10.2
0
+9.0
15.2
0
+14.0
22.0
0
+20.0
3.1
+1.4
+5.5
5.8
+2.2
+9.4
7.8
+2.2
+11.4
13.8
+2.2
+17.4
18.5
+3.5
+24.2
5.5
0
+4.5
9.4
0
+8.0
11.4
0
+10.0
17.4
0
+16.0
24.2
0
+22.0
3.6
+1.4
+6.1
5.8
+2.2
+9.4
9.8
+2.2
+13.4
15.8
+2.2
+19.4
21.5
+3.5
+27.2
6.1
0
+5.0
9.4
0
+8.0
13.4
0
+12.0
19.4
0
+18.0
27.2
0
+25.0
4.4
+1.6
+7.0
6.5
+2.5
+10.6
+9.5
+2.5
+13.6
17.5
+2.5
+21.6
24.0
+4.0
+30.5
7.0
0
+6.0
10.6
0
+9.0
13.6
0
+12.0
21.6
0
+20.0
30.5
0
+28.0
4.4
+1.6
+7.0
7.5
+2.5
+11.6
11.5
+2.5
+15.6
19.5
+2.5
+23.6
26.0
+4.0
+32.5
7.0
0
+6.0
11.6
0
+10.0
15.6
0
+14.0
23.6
0
+22.0
32.5
0
+30.0
1.2
+1.0
+13.6
a Pairs of values shown represent minimum and maximum amounts of interference resulting from application of standard tolerance limits.
All data above heavy lines are in accordance with American-British-Canadian (ABC) agreements. Symbols H6, H7, s6, etc., are hole and shaft designations in the ABC system. Limits for sizes above 19.69 inches are not covered by ABC agreements but are given in the ANSI standard.
Copyright 2004, Industrial Press, Inc., New York, NY
FORCE AND SHRINK FITS
4.73–
Class FN 3
Standard Tolerance Limits
664
Table 11. (Continued) ANSI Standard Force and Shrink Fits ANSI B4.1-1967 (R1999) Class FN 1
Machinery's Handbook 27th Edition INTERFERENCE LOCATIONAL FITS
665
Table 12. ANSI Standard Interference Location Fits ANSI B4.1-1967 (R1999) Class LN 1 Nominal Size Range, Inches Over
Limits of Interference
Hole H6
To 0– 0.12
0.12– 0.24 0.24– 0.40 0.40– 0.71 0.71– 1.19 1.19– 1.97 1.97– 3.15 3.15– 4.73 4.73– 7.09 7.09– 9.85 9.85– 12.41 12.41– 15.75 15.75– 19.69
Class LN 2
Standard Limits Shaft n5
Limits of Interference
Class LN 3
Standard Limits Hole H7
Shaft p6
Limits of Interference
Standard Limits Hole H7
Shaft r6
+0.4 0 +0.5 0 +0.6 0 +0.7 0 +0.8 0 +1.0 0 +1.2 0 +1.4 0 +1.6 0 +1.8 0 +2.0 0 +2.2 0 +2.5 0
+0.75 +0.5 +0.9 +0.6 +1.2 +0.8 +1.4 +1.0 +1.7 +1.2 +2.0 +1.4 +2.3 +1.6 +2.9 +2.0 +3.5 +2.5 +4.2 +3.0 +4.7 +3.5 +5.9 +4.5 +6.6 +5.0
Values shown below are given in thousandths of an inch 0 0.45 0 0.5 0 0.65 0 0.8 0 1.0 0 1.1 0.1 1.3 0.1 1.6 0.2 1.9 0.2 2.2 0.2 2.3 0.2 2.6 0.2 2.8
+0.25 0 +0.3 0 +0.4 0 +0.4 0 +0.5 0 +0.6 0 +0.7 0 +0.9 0 +1.0 0 +1.2 0 +1.2 0 +1.4 0 +1.6 0
+0.45 +0.25 +0.5 +0.3 +0.65 +0.4 +0.8 +0.4 +1.0 +0.5 +1.1 +0.6 +1.3 +0.8 +1.6 +1.0 +1.9 +1.2 +2.2 +1.4 +2.3 +1.4 +2.6 +1.6 +2.8 +1.8
0 0.65 0 0.8 0 1.0 0 1.1 0 1.3 0 1.6 0.2 2.1 0.2 2.5 0.2 2.8 0.2 3.2 0.2 3.4 0.3 3.9 0.3 4.4
+0.4 0 +0.5 0 +0.6 0 +0.7 0 +0.8 0 +1.0 0 +1.2 0 +1.4 0 +1.6 0 +1.8 0 +2.0 0 +2.2 0 +2.5 0
+0.65 +0.4 +0.8 +0.5 +1.0 +0.6 +1.1 +0.7 +1.3 +0.8 +1.6 +1.0 +2.1 +1.4 +2.5 +1.6 +2.8 +1.8 +3.2 +2.0 +3.4 +2.2 +3.9 +2.5 +4.4 +2.8
0.1 0.75 0.1 0.9 0.2 1.2 0.3 1.4 0.4 1.7 0.4 2.0 0.4 2.3 0.6 2.9 0.9 3.5 1.2 4.2 1.5 4.7 2.3 5.9 2.5 6.6
All data in this table are in accordance with American-British-Canadian (ABC) agreements. Limits for sizes above 19.69 inches are not covered by ABC agreements but are given in the ANSI Standard. Symbols H7, p6, etc., are hole and shaft designations in the ABC system. Tolerance limits given in body of table are added or subtracted to basic size (as indicated by + or − sign) to obtain maximum and minimum sizes of mating parts.
American National Standard Preferred Metric Limits and Fits This standard ANSI B4.2-1978 (R1999) describes the ISO system of metric limits and fits for mating parts as approved for general engineering usage in the United States. It establishes: 1) the designation symbols used to define dimensional limits on drawings, material stock, related tools, gages, etc.; 2) the preferred basic sizes (first and second choices); 3) the preferred tolerance zones (first, second, and third choices); 4 ) t h e p r e ferred limits and fits for sizes (first choice only) up to and including 500 millimeters; and 5) the definitions of related terms. The general terms “hole” and “shaft” can also be taken to refer to the space containing or contained by two parallel faces of any part, such as the width of a slot, or the thickness of a key. Definitions.—The most important terms relating to limits and fits are shown in Fig. 1 and are defined as follows: Basic Size: The size to which limits of deviation are assigned. The basic size is the same for both members of a fit. For example, it is designated by the numbers 40 in 40H7. Deviation: The algebraic difference between a size and the corresponding basic size.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 666
ANSI STANDARD PREFERRED METRIC LIMITS AND FITS
Upper Deviation: The algebraic difference between the maximum limit of size and the corresponding basic size. Lower Deviation: The algebraic difference between the minimum limit of size and the corresponding basic size. Fundamental Deviation: That one of the two deviations closest to the basic size. For example, it is designated by the letter H in 40H7. Tolerance: The difference between the maximum and minimum size limits on a part. Tolerance Zone: A zone representing the tolerance and its position in relation to the basic size.
Fig. 1. Illustration of Definitions
International Tolerance Grade: (IT): A group of tolerances that vary depending on the basic size, but that provide the same relative level of accuracy within a given grade. For example, it is designated by the number 7 in 40H7 or as IT7. Hole Basis: The system of fits where the minimum hole size is basic. The fundamental deviation for a hole basis system is H. Shaft Basis: The system of fits where the maximum shaft size is basic. The fundamental deviation for a shaft basis system is h. Clearance Fit: The relationship between assembled parts when clearance occurs under all tolerance conditions. Interference Fit: The relationship between assembled parts when interference occurs under all tolerance conditions. Transition Fit: The relationship between assembled parts when either a clearance or an interference fit can result, depending on the tolerance conditions of the mating parts. Tolerances Designation.—An “International Tolerance grade” establishes the magnitude of the tolerance zone or the amount of part size variation allowed for external and internal dimensions alike (see Fig. 1). Tolerances are expressed in grade numbers that are consistent with International Tolerance grades identified by the prefix IT, such as IT6, IT11, etc. A smaller grade number provides a smaller tolerance zone.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition PREFERRED METRIC FITS
667
A fundamental deviation establishes the position of the tolerance zone with respect to the basic size (see Fig. 1). Fundamental deviations are expressed by tolerance position letters. Capital letters are used for internal dimensions and lowercase or small letters for external dimensions. Symbols.—By combining the IT grade number and the tolerance position letter, the tolerance symbol is established that identifies the actual maximum and minimum limits of the part. The toleranced size is thus defined by the basic size of the part followed by a symbol composed of a letter and a number, such as 40H7, 40f7, etc. A fit is indicated by the basic size common to both components, followed by a symbol corresponding to each component, the internal part symbol preceding the external part symbol, such as 40H8/f7. Some methods of designating tolerances on drawings are: 40.039⎞ 40H8 ⎛
40H8
⎛ 40.039⎞ 40H8 ⎝ 40.000⎠
⎝ 40.000⎠
The values in parentheses indicate reference only.
Preferred Metric Fits.—First-choice tolerance zones are used to establish preferred fits in ANSI B4.2, Preferred Metric Limits and Fits, as shown in Figs. 2 and 3. A complete listing of first-, second-, and third- choice tolerance zones is given in the Standard. Hole basis fits have a fundamental deviation of H on the hole, and shaft basis fits have a fundamental deviation of h on the shaft and are shown in Fig. 2 for hole basis and Fig. 3 for shaft basis fits. A description of both types of fits, that have the same relative fit condition, is given in Table 1. Normally, the hole basis system is preferred; however, when a common shaft mates with several holes, the shaft basis system should be used. The hole basis and shaft basis fits shown in the table Description of Preferred Fits on page 669 are combined with the first-choice preferred metric sizes from Table 1 on page 690, to form Tables 2, 3, 4, and 5, in which specific limits as well as the resultant fits are tabulated. If the required size is not found tabulated in Tables 2 through 5 then the preferred fit can be calculated from numerical values given in an appendix of ANSI B4.2-1978 (R1999). It is anticipated that other fit conditions may be necessary to meet special requirements, and a preferred fit can be loosened or tightened simply by selecting a standard tolerance zone as given in the Standard. Information on how to calculate limit dimensions, clearances, and interferences, for nonpreferred fits and sizes can be found in an appendix of this Standard. Conversion of Fits: It may sometimes be neccessary or desirable to modify the tolereance zone on one or both of two mating parts, yet still keep the total tolerance and fit condition the same. Examples of this appear in Table 1 on page 669 when converting from a hole basis fit to a shaft basis fit. The corresponding fits are identical yet the individual tolerance zones are different. To convert from one type of fit to another, reverse the fundamental devations between the shaft and hole keeping the IT grade the same on each individual part. The examples below represent preferred fits from Table 1 for a 60-mm basic size. These fits have the same maximum clearance (0.520) and the same minimum clearance (0.140). Hole basis, loose running fit, values from Table 2 Hole 60H11
⎛ 60.190⎞ ⎝ 60.000⎠
Hole 60C11
⎛ 60.330⎞ ⎝ 60.140⎠
Shaft 60c11
⎛ 59.860⎞ ⎝ 59.670⎠
Fit 60H11/c11
⎛ 0.520⎞ ⎝ 0.140⎠
Hole basis, loose running fit, values from Table 4 Shaft 60h11
⎛ 60.000⎞ ⎝ 59.810⎠
Fit 60C11/h11
Copyright 2004, Industrial Press, Inc., New York, NY
⎛ 0.520⎞ ⎝ 0.140⎠
Machinery's Handbook 27th Edition PREFERRED METRIC FITS
Shaft Tolerance u6
H11
s6 p6
n6
H9
Maximum Interference
K6
H8
H7 g6
Minimum Tolerance Shaft Tolerance
Maximum Clearance
Hole Tolerance
668
H7 h6
H7
H7
H7
H7
Basic Size
H7
Minimum Interference Hole Tolerance
f7
d9
c11
Transition
Clearance
Interference
Minimum tolerance
C11
D9
F8 G7 h7
Shaft tolerance
Maximum clearance
Hole tolerance
Fig. 2. Preferred Hole Basis Fits
h6
H7 h6
h6 h6
h9
Shaft tolerance
K7 h6
Basic size
h6
h6 N7
Maximum interference
P7 S7
h11
U7
Minimum interference Hole tolerance
Clearance
Transition
Interference
Fig. 3. Preferred Shaft Basis Fits
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 1. Description of Preferred Fits
Transition Fits Interference Fits
DESCRIPTION
Shaft Basis
H11/c11
C11/h11
H9/d9
D9/h9
Free running fit not for use where accuracy is essential, but good for large temperature variations, high running speeds, or heavy journal pressures.
H8/f7
F8/h7
Close Running fit for running on accurate machines and for accurate moderate speeds and journal pressures.
H7/g6
G7/h6
H7/h6
H7/h6
H7/k6
K7/h6
Locational transition fit for accurate location, a compromise between clearance and interferance.
H7/n6
N7/h6
Locational transition fit for more accurate location where greater interferance is permissible.
H7/p6a
P7/h6
Locational interference fit for parts requiring rigidity and alignment with prime accuracy of location but without special bore pressure requirements.
H7/s6
S7/h6
Medium drive fit for ordinary steel parts or shrink fits on light sections, the tightest fit usable with cast iron.
H7/u6
U7/h6
Force fit suitable for parts which can be highly stressed or for shrink fits where the heavy pressing forces required are impractical.
Loose running fit for wide commercial tolerances or allowances on external members.
↑ More Clearance
Sliding fit not intended to run freely, but to move and turn freely and locate accurately. Locational clearance fit provides snug fit for locating stationary parts; but can be freely assembled and disassembled.
Copyright 2004, Industrial Press, Inc., New York, NY
More Interferance ↓
669
a Transition fit for basic sizes in range from 0 through 3 mm.
PREFERRED METRIC FITS
Clearance Fits
ISO SYMBOL Hole Basis
Machinery's Handbook 27th Edition
670
Table 2. American National Standard Preferred Hole Basis Metric Clearance Fits ANSI B4.2-1978 (R1999) Loose Running Basic Sizea 1
1.6 2 2.5 3 4 5 6 8 10 12 16 20 25
Shaft C11
1.060 1.000 1.260 1.200 1.660 1.600 2.060 2.000 2.560 2.500 3.060 3.000 4.075 4.000 5.075 5.000 6.075 6.000 8.090 8.000 10.090 10.000 12.110 12.000 16.110 16.000 20.130 20.000 25.130 25.000
0.940 0.880 1.140 1.080 1.540 1.480 1.940 1.880 2.440 2.380 2.940 2.880 3.930 3.855 4.930 4.855 5.930 5.855 7.920 7.830 9.920 9.830 11.905 11.795 15.905 15.795 19.890 19.760 24.890 24.760
Free Running
Close Running
Sliding
Locational Clearance
Fitb
Hole H9
Shaft d9
Fitb
Hole H8
Shaft f7
Fitb
Hole H7
Shaft g6
Fitb
Hole H7
Shaft h6
Fitb
0.180 0.060 0.180 0.060 0.180 0.060 0.180 0.060 0.180 0.060 0.180 0.060 0.220 0.070 0.220 0.070 0.220 0.070 0.260 0.080 0.260 0.080 0.315 0.095 0.315 0.095 0.370 0.110 0.370 0.110
1.025 1.000 1.225 1.200 1.625 1.600 2.025 2.000 2.525 2.500 3.025 3.000 4.030 4.000 5.030 5.000 6.030 6.000 8.036 8.000 10.036 10.000 12.043 12.000 16.043 16.000 20.052 20.000 25.052 25.000
0.980 0.995 1.180 1.155 1.580 1.555 1.980 1.955 2.480 2.455 2.980 2.955 3.970 3.940 4.970 4.940 5.970 5.940 7.960 7.924 9.960 9.924 11.956 11.907 15.950 15.907 19.935 19.883 24.935 24.883
0.070 0.020 0.070 0.020 0.070 0.020 0.070 0.020 0.070 0.020 0.070 0.020 0.090 0.030 0.090 0.030 0.090 0.030 0.112 0.040 0.112 0.040 0.136 0.050 0.136 0.050 0.169 0.065 0.169 0.065
1.014 1.000 1.214 1.200 1.614 1.600 2.014 2.000 2.514 2.500 3.014 3.000 4.018 4.000 5.018 5.000 6.018 6.000 8.022 8.000 10.022 10.000 12.027 12.000 16.027 16.000 20.033 20.000 25.033 25.000
0.994 0.984 1.194 1.184 1.594 1.584 1.994 1.984 2.494 2.484 2.994 2.984 3.990 3.978 4.990 4.978 5.990 5.978 7.987 7.972 9.987 9.972 11.984 11.966 15.984 15.966 19.980 19.959 24.980 24.959
0.030 0.006 0.030 0.006 0.030 0.006 0.030 0.006 0.030 0.006 0.030 0.006 0.040 0.010 0.040 0.010 0.040 0.010 0.050 0.013 0.050 0.013 0.061 0.016 0.061 0.016 0.074 0.020 0.074 0.020
1.010 1.000 1.210 1.200 1.610 1.600 2.010 2.000 2.510 2.500 3.010 3.000 4.012 4.000 5.012 5.000 6.012 6.000 8.015 8.000 10.015 10.000 12.018 12.000 16.018 16.000 20.021 20.000 25.021 25.000
0.998 0.992 1.198 1.192 1.598 1.592 1.998 1.992 2.498 2.492 2.998 2.992 3.996 3.988 4.996 4.988 5.996 5.988 7.995 7.986 9.995 9.986 11.994 11.983 15.994 15.983 19.993 19.980 24.993 24.980
0.018 0.002 0.018 0.002 0.018 0.002 0.018 0.002 0.018 0.002 0.018 0.002 0.024 0.004 0.024 0.004 0.024 0.004 0.029 0.005 0.029 0.005 0.035 0.006 0.035 0.006 0.041 0.007 0.041 0.007
1.010 1.000 1.210 1.200 1.610 1.600 2.010 2.000 2.510 2.500 3.010 3.000 4.012 4.000 5.012 5.000 6.012 6.000 8.015 8.000 10.015 10.000 12.018 12.000 16.018 16.000 20.021 20.000 25.021 25.000
1.000 0.994 1.200 1.194 1.600 1.594 2.000 1.994 2.500 2.494 3.000 2.994 4.000 3.992 5.000 4.992 6.000 5.992 8.000 7.991 10.000 9.991 12.000 11.989 16.000 15.989 20.000 19.987 25.000 24.987
0.016 0.000 0.016 0.000 0.016 0.000 0.016 0.000 0.016 0.000 0.016 0.000 0.020 0.000 0.020 0.000 0.020 0.000 0.024 0.000 0.024 0.000 0.029 0.000 0.029 0.000 0.034 0.000 0.034 0.000
Copyright 2004, Industrial Press, Inc., New York, NY
HOLE BASIS METRIC CLEARANCE FITS
1.2
Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min
Hole H11
Machinery's Handbook 27th Edition
Table 2. (Continued) American National Standard Preferred Hole Basis Metric Clearance Fits ANSI B4.2-1978 (R1999) Loose Running Basic Sizea 30 40
60 80 100 120 160 200 250 300 400 500
Shaft C11 29.890 29.760 39.880 39.720 49.870 49.710 59.860 59.670 79.850 79.660 99.830 99.610 119.820 119.600 159.790 159.540 199.760 199.470 249.720 249.430 299.670 299.350 399.600 399.240 499.520 499.120
Free Running Fitb 0.370 0.110 0.440 0.120 0.450 0.130 0.520 0.140 0.530 0.150 0.610 0.170 0.620 0.180 0.710 0.210 0.820 0.240 0.860 0.280 0.970 0.330 1.120 0.400 1.280 0.480
Hole H9 30.052 30.000 40.062 40.000 50.062 50.000 60.074 60.000 80.074 80.000 100.087 100.000 120.087 120.000 160.100 160.000 200.115 200.000 250.115 250.000 300.130 300.000 400.140 400.000 500.155 500.000
Shaft d9 29.935 29.883 39.920 39.858 49.920 49.858 59.900 59.826 79.900 79.826 99.880 99.793 119.880 119.793 159.855 159.755 199.830 199.715 249.830 249.715 299.810 299.680 399.790 399.650 499.770 499.615
Close Running Fitb 0.169 0.065 0.204 0.080 0.204 0.080 0.248 0.100 0.248 0.100 0.294 0.120 0.294 0.120 0.345 0.145 0.400 0.170 0.400 0.170 0.450 0.190 0.490 0.210 0.540 0.230
Hole H8 30.033 30.000 40.039 40.000 50.039 50.000 60.046 60.000 80.046 80.000 100.054 100.000 120.054 120.000 160.063 160.000 200.072 200.000 250.072 250.000 300.081 300.000 400.089 400.000 500.097 500.000
Shaft f7 29.980 29.959 39.975 39.950 49.975 49.950 59.970 59.940 79.970 79.940 99.964 99.929 119.964 119.929 159.957 159.917 199.950 199.904 249.950 249.904 299.944 299.892 399.938 399.881 499.932 499.869
Sliding Fitb 0.074 0.020 0.089 0.025 0.089 0.025 0.106 0.030 0.106 0.030 0.125 0.036 0.125 0.036 0.146 0.043 0.168 0.050 0.168 0.050 0.189 0.056 0.208 0.062 0.228 0.068
Hole H7 30.021 30.000 40.025 40.000 50.025 50.000 60.030 60.000 80.030 80.000 100.035 100.000 120.035 120.000 160.040 160.000 200.046 200.000 250.046 250.000 300.052 300.000 400.057 400.000 500.063 500.000
Shaft g6 29.993 29.980 39.991 39.975 49.991 49.975 59.990 59.971 79.990 79.971 99.988 99.966 119.988 119.966 159.986 159.961 199.985 199.956 249.985 249.956 299.983 299.951 399.982 399.946 499.980 499.940
Locational Clearance Fitb 0.041 0.007 0.050 0.009 0.050 0.009 0.059 0.010 0.059 0.010 0.069 0.012 0.069 0.012 0.079 0.014 0.090 0.015 0.090 0.015 0.101 0.017 0.111 0.018 0.123 0.020
Hole H7 30.021 30.000 40.025 40.000 50.025 50.000 60.030 60.000 80.030 80.000 100.035 100.000 120.035 120.000 160.040 160.000 200.046 200.000 250.046 250.000 300.052 300.000 400.057 400.000 500.063 500.000
Shaft h6 30.000 29.987 40.000 39.984 50.000 49.984 60.000 59.981 80.000 79.981 100.000 99.978 120.000 119.978 160.000 159.975 200.000 199.971 250.000 249.971 300.000 299.968 400.000 399.964 500.000 499.960
Fitb 0.034 0.000 0.041 0.000 0.041 0.000 0.049 0.000 0.049 0.000 0.057 0.000 0.057 0.000 0.065 0.000 0.075 0.000 0.075 0.000 0.084 0.000 0.093 0.000 0.103 0.000
HOLE BASIS METRIC CLEARANCE FITS
50
Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min
Hole H11 30.130 30.000 40.160 40.000 50.160 50.000 60.190 60.000 80.190 80.000 100.220 100.000 120.220 120.000 160.250 160.000 200.290 200.000 250.290 250.000 300.320 300.000 400.360 400.000 500.400 500.000
a The sizes shown are first-choice basic sizes (see Table 1). Preferred fits for other sizes can be calculated from data given in ANSI B4.2-1978 (R1999). b All fits shown in this table have clearance.
All dimensions are in millimeters.
671
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
672
Table 3. American National Standard Preferred Hole Basis Metric Transition and Interference Fits ANSI B4.2-1978 (R1999) Locational Transition Basic Sizea 1 1.2
2 2.5 3 4 5 6 8 10 12 16 20 25
Locational Interference
Medium Drive
Force
Shaft k6
Fitb
Hole H7
Shaft n6
Fitb
Hole H7
Shaft p6
Fitb
Hole H7
Shaft s6
Fitb
Hole H7
Shaft u6
Fitb
1.010 1.000 1.210 1.200 1.610 1.600 2.010 2.000 2.510 2.500 3.010 3.000 4.012 4.000 5.012 5.000 6.012 6.000 8.015 8.000 10.015 10.000 12.018 12.000 16.018 16.000 20.021 20.000 25.021 25.000
1.006 1.000 1.206 1.200 1.606 1.600 2.006 2.000 2.506 2.500 3.006 3.000 4.009 4.001 5.009 5.001 6.009 6.001 8.010 8.001 10.010 10.001 12.012 12.001 16.012 16.001 20.015 20.002 25.015 25.002
+0.010 −0.006 +0.010 −0.006 +0.010 −0.006 +0.010 −0.006 +0.010 −0.006 +0.010 −0.006 +0.011 −0.009 +0.011 −0.009 +0.011 −0.009 +0.014 −0.010 +0.014 −0.010 +0.017 −0.012 +0.017 −0.012 +0.019 −0.015 +0.019 −0.015
1.010 1.000 1.210 1.200 1.610 1.600 2.010 2.000 2.510 2.500 3.010 3.000 4.012 4.000 5.012 5.000 6.012 6.000 8.015 8.000 10.015 10.000 12.018 12.000 16.018 16.000 20.021 20.000 25.021 25.000
1.010 1.004 1.210 1.204 1.610 1.604 2.010 2.004 2.510 2.504 3.010 3.004 4.016 4.008 5.016 5.008 6.016 6.008 8.019 8.010 10.019 10.010 12.023 12.012 16.023 16.012 20.028 20.015 25.028 25.015
+0.006 −0.010 +0.006 −0.010 +0.006 −0.010 +0.006 −0.010 +0.006 −0.010 +0.006 −0.010 +0.004 −0.016 +0.004 −0.016 +0.004 −0.016 +0.005 −0.019 +0.005 −0.019 +0.006 −0.023 +0.006 −0.023 +0.006 −0.028 +0.006 −0.028
1.010 1.000 1.210 1.200 1.610 1.600 2.010 2.000 2.510 2.500 3.010 3.000 4.012 4.000 5.012 5.000 6.012 6.000 8.015 8.000 10.015 10.000 12.018 12.000 16.018 16.000 20.021 20.000 25.021 25.000
1.012 1.006 1.212 1.206 1.612 1.606 2.012 2.006 2.512 2.506 3.012 3.006 4.020 4.012 5.020 5.012 6.020 6.012 8.024 8.015 10.024 10.015 12.029 12.018 16.029 16.018 20.035 20.022 25.035 25.022
+0.004 −0.012 +0.004 −0.012 +0.004 −0.012 +0.004 −0.012 +0.004 −0.012 +0.004 −0.012 0.000 −0.020 0.000 −0.020 0.000 −0.020 0.000 −0.024 0.000 −0.024 0.000 −0.029 0.000 −0.029 −0.001 −0.035 −0.001 −0.035
1.010 1.000 1.210 1.200 1.610 1.600 2.010 2.000 2.510 2.500 3.010 3.000 4.012 4.000 5.012 5.000 6.012 6.000 8.015 8.000 10.015 10.000 12.018 12.000 16.018 16.000 20.021 20.000 25.021 25.000
1.020 1.014 1.220 1.214 1.620 1.614 2.020 2.014 2.520 2.514 3.020 3.014 4.027 4.019 5.027 5.019 6.027 6.019 8.032 8.023 10.032 10.023 12.039 12.028 16.039 16.028 20.048 20.035 25.048 25.035
−0.004 −0.020 −0.004 −0.020 −0.004 −0.020 −0.004 −0.020 −0.004 −0.020 −0.004 −0.020 −0.007 −0.027 −0.007 −0.027 −0.007 −0.027 −0.008 −0.032 −0.008 −0.032 −0.010 −0.039 −0.010 −0.039 −0.014 −0.048 −0.014 −0.048
1.010 1.000 1.210 1.200 1.610 1.600 2.010 2.000 2.510 2.500 3.010 3.000 4.012 4.000 5.012 5.000 6.012 6.000 8.015 8.000 10.015 10.000 12.018 12.000 16.018 16.000 20.021 20.000 25.021 25.000
1.024 1.018 1.224 1.218 1.624 1.618 2.024 2.018 2.524 2.518 3.024 3.018 4.031 4.023 5.031 5.023 6.031 6.023 8.037 8.028 10.034 10.028 12.044 12.033 16.044 16.033 20.054 20.041 25.061 25.048
−0.008 −0.024 −0.008 −0.024 −0.008 −0.024 −0.008 −0.024 −0.008 −0.024 −0.008 −0.024 −0.011 −0.031 −0.011 −0.031 −0.011 −0.031 −0.013 −0.037 −0.013 −0.037 −0.015 −0.044 −0.015 −0.044 −0.020 −0.054 −0.027 −0.061
Copyright 2004, Industrial Press, Inc., New York, NY
HOLE BASIS METRIC TRANSITION FITS
1.6
Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min
Locational Transition
Hole H7
Machinery's Handbook 27th Edition
Table 3. (Continued) American National Standard Preferred Hole Basis Metric Transition and Interference Fits ANSI B4.2-1978 (R1999) Locational Transition Basic Sizea 30 40
60 80 100 120 160 200 250 300 400 500
Shaft k6 30.015 30.002 40.018 40.002 50.018 50.002 60.021 60.002 80.021 80.002 100.025 100.003 120.025 120.003 160.028 160.003 200.033 200.004 250.033 250.004 300.036 300.004 400.040 400.004 500.045 500.005
Fitb +0.019 −0.015 +0.023 −0.018 +0.023 −0.018 +0.028 −0.021 +0.028 −0.021 +0.032 −0.025 +0.032 −0.025 +0.037 −0.028 +0.042 −0.033 +0.042 −0.033 +0.048 −0.036 +0.053 −0.040 +0.058 −0.045
Locational Transition Hole H7 30.021 30.000 40.025 40.000 50.025 50.000 60.030 60.000 80.030 80.000 100.035 100.000 120.035 120.000 160.040 160.000 200.046 200.000 250.046 250.000 300.052 300.000 400.057 400.000 500.063 500.000
Shaft n6 30.028 30.015 40.033 40.017 50.033 50.017 60.039 60.020 80.039 80.020 100.045 100.023 120.045 120.023 160.052 160.027 200.060 200.031 250.060 250.031 300.066 300.034 400.073 400.037 500.080 500.040
Fitb +0.006 −0.028 +0.008 −0.033 +0.008 −0.033 +0.010 −0.039 +0.010 −0.039 +0.012 −0.045 +0.012 −0.045 +0.013 −0.052 +0.015 −0.060 +0.015 −0.060 +0.018 −0.066 +0.020 −0.073 +0.023 −0.080
Locational Interference Hole H7 30.021 30.000 40.025 40.000 50.025 50.000 60.030 60.000 80.030 80.000 100.035 100.000 120.035 120.000 160.040 160.000 200.046 200.000 250.046 250.000 300.052 300.000 400.057 400.000 500.063 500.000
Shaft p6 30.035 30.022 40.042 40.026 50.042 50.026 60.051 60.032 80.051 80.032 100.059 100.037 120.059 120.037 160.068 160.043 200.079 200.050 250.079 250.050 300.088 300.056 400.098 400.062 500.108 500.068
Fitb −0.001 −0.035 −0.001 −0.042 −0.001 −0.042 −0.002 −0.051 −0.002 −0.051 −0.002 −0.059 −0.002 −0.059 −0.003 −0.068 −0.004 −0.079 −0.004 −0.079 −0.004 −0.088 −0.005 −0.098 −0.005 −0.108
Medium Drive Hole H7 30.021 30.000 40.025 40.000 50.025 50.000 60.030 60.000 80.030 80.000 100.035 100.000 120.035 120.000 160.040 160.000 200.046 200.000 250.046 250.000 300.052 300.000 400.057 400.000 500.063 500.000
Shaft s6 30.048 30.035 40.059 40.043 50.059 50.043 60.072 60.053 80.078 80.059 100.093 100.071 120.101 120.079 160.125 160.100 200.151 200.122 250.169 250.140 300.202 300.170 400.244 400.208 500.292 500.252
Force Fitb −0.014 −0.048 −0.018 −0.059 −0.018 −0.059 −0.023 −0.072 −0.029 −0.078 −0.036 −0.093 −0.044 −0.101 −0.060 −0.125 −0.076 −0.151 −0.094 −0.169 −0.118 −0.202 −0.151 −0.244 −0.189 −0.292
Hole H7 30.021 30.000 40.025 40.000 50.025 50.000 60.030 60.000 80.030 80.000 100.035 100.000 120.035 120.000 160.040 160.000 200.046 200.000 250.046 250.000 300.052 300.000 400.057 400.000 500.063 500.000
Shaft u6 30.061 30.048 40.076 40.060 50.086 50.070 60.106 60.087 80.121 80.102 100.146 100.124 120.166 120.144 160.215 160.190 200.265 200.236 250.313 250.284 300.382 300.350 400.471 400.435 500.580 500.540
Fitb −0.027 −0.061 −0.035 −0.076 −0.045 −0.086 −0.057 −0.106 −0.072 −0.121 −0.089 −0.146 −0.109 −0.166 −0.150 −0.215 −0.190 −0.265 −0.238 −0.313 −0.298 −0.382 −0.378 −0.471 −0.477 −0.580
HOLE BASIS METRIC TRANSITION FITS
50
Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min
Hole H7 30.021 30.000 40.025 40.000 50.025 50.000 60.030 60.000 80.030 80.000 100.035 100.000 120.035 120.000 160.040 160.000 200.046 200.000 250.046 250.000 300.052 300.000 400.057 400.000 500.063 500.000
a The sizes shown are first-choice basic sizes (see Table 1). Preferred fits for other sizes can be calculated from data given in ANSI B4.2-1978 (R1999). b A plus sign indicates clearance; a minus sign indicates interference.
All dimensions are in millimeters.
673
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
674
Table 4. American National Standard Preferred Shaft Basis Metric Clearance Fits ANSI B4.2-1978 (R1999) Loose Running Basic Sizea 1
1.6 2 2.5 3 4 5 6 8 10 12 16 20 25
Close Running
Sliding
Locational Clearance
Shaft h11
Fitb
Hole D9
Shaft h9
Fitb
Hole F8
Shaft h7
Fitb
Hole G7
Shaft h6
Fitb
Hole H7
Shaft h6
Fitb
1.120 1.060 1.320 1.260 1.720 1.660 2.120 2.060 2.620 2.560 3.120 3.060 4.145 4.070 5.145 5.070 6.145 6.070 8.170 8.080 10.170 10.080 12.205 12.095 16.205 16.095 20.240 20.110 25.240 25.110
1.000 0.940 1.200 1.140 1.600 1.540 2.000 1.940 2.500 2.440 3.000 2.940 4.000 3.925 5.000 4.925 6.000 5.925 8.000 7.910 10.000 9.910 12.000 11.890 16.000 15.890 20.000 19.870 25.000 24.870
0.180 0.060 0.180 0.060 0.180 0.060 0.180 0.060 0.180 0.060 0.180 0.060 0.220 0.070 0.220 0.070 0.220 0.070 0.260 0.080 0.260 0.080 0.315 0.095 0.315 0.095 0.370 0.110 0.370 0.110
1.045 1.020 1.245 1.220 1.645 1.620 2.045 2.020 2.545 2.520 3.045 3.020 4.060 4.030 5.060 5.030 6.060 6.030 8.076 8.040 10.076 10.040 12.093 12.050 16.093 16.050 20.117 20.065 25.117 25.065
1.000 0.975 1.200 1.175 1.600 1.575 2.000 1.975 2.500 2.475 3.000 2.975 4.000 3.970 5.000 4.970 6.000 5.970 8.000 7.964 10.000 9.964 12.000 11.957 16.000 15.957 20.000 19.948 25.000 24.948
0.070 0.020 0.070 0.020 0.070 0.020 0.070 0.020 0.070 0.020 0.070 0.020 0.090 0.030 0.090 0.030 0.090 0.030 0.112 0.040 0.112 0.040 0.136 0.050 0.136 0.050 0.169 0.065 0.169 0.065
1.020 1.006 1.220 1.206 1.620 1.606 2.020 2.006 2.520 2.506 3.020 3.006 4.028 4.010 5.028 5.010 6.028 6.010 8.035 8.013 10.035 10.013 12.043 12.016 16.043 16.016 20.053 20.020 25.053 25.020
1.000 0.990 1.200 1.190 1.600 1.590 2.000 1.990 2.500 2.490 3.000 2.990 4.000 3.988 5.000 4.988 6.000 5.988 8.000 7.985 10.000 9.985 12.000 11.982 16.000 15.982 20.000 19.979 25.000 24.979
0.030 0.006 0.030 0.006 0.030 0.006 0.030 0.006 0.030 0.006 0.030 0.006 0.040 0.010 0.040 0.010 0.040 0.010 0.050 0.013 0.050 0.013 0.061 0.016 0.061 0.016 0.074 0.020 0.074 0.020
1.012 1.002 1.212 1.202 1.612 1.602 2.012 2.002 2.512 2.502 3.012 3.002 4.016 4.004 5.016 5.004 6.016 6.004 8.020 8.005 10.020 10.005 12.024 12.006 16.024 16.006 20.028 20.007 25.028 25.007
1.000 0.994 1.200 1.194 1.600 1.594 2.000 1.994 2.500 2.494 3.000 2.994 4.000 3.992 5.000 4.992 6.000 5.992 8.000 7.991 10.000 9.991 12.000 11.989 16.000 15.989 20.000 19.987 25.000 24.987
0.018 0.002 0.018 0.002 0.018 0.002 0.018 0.002 0.018 0.002 0.018 0.002 0.024 0.004 0.024 0.004 0.024 0.004 0.029 0.005 0.029 0.005 0.035 0.006 0.035 0.006 0.041 0.007 0.041 0.007
1.010 1.000 1.210 1.200 1.610 1.600 2.010 2.000 2.510 2.500 3.010 3.000 4.012 4.000 5.012 5.000 6.012 6.000 8.015 8.000 10.015 10.000 12.018 12.000 16.018 16.000 20.021 20.000 25.021 25.000
1.000 0.994 1.200 1.194 1.600 1.594 2.000 1.994 2.500 2.494 3.000 2.994 4.000 3.992 5.000 4.992 6.000 5.992 8.000 7.991 10.000 9.991 12.000 11.989 16.000 15.989 20.000 19.987 25.000 24.987
0.016 0.000 0.016 0.000 0.016 0.000 0.016 0.000 0.016 0.000 0.016 0.000 0.020 0.000 0.020 0.000 0.020 0.000 0.024 0.000 0.024 0.000 0.029 0.000 0.029 0.000 0.034 0.000 0.034 0.000
Copyright 2004, Industrial Press, Inc., New York, NY
SHAFT BASIS METRIC CLEARANCE FITS
1.2
Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min
Free Running
Hole C11
Machinery's Handbook 27th Edition
Table 4. (Continued) American National Standard Preferred Shaft Basis Metric Clearance Fits ANSI B4.2-1978 (R1999) Loose Running Basic Sizea 30 40
60 80 100 120 160 200 250 300 400 500
Shaft h11 30.000 29.870 40.000 39.840 50.000 49.840 60.000 59.810 80.000 79.810 100.000 99.780 120.000 119.780 160.000 159.750 200.000 199.710 250.000 249.710 300.000 299.680 400.000 399.640 500.000 499.600
Free Running Fitb 0.370 0.110 0.440 0.120 0.450 0.130 0.520 0.140 0.530 0.150 0.610 0.170 0.620 0.180 0.710 0.210 0.820 0.240 0.860 0.280 0.970 0.330 1.120 0.400 1.280 0.480
Hole D9 30.117 30.065 40.142 40.080 50.142 50.080 60.174 60.100 80.174 80.100 100.207 100.120 120.207 120.120 160.245 160.145 200.285 200.170 250.285 250.170 300.320 300.190 400.350 400.210 500.385 500.230
Shaft h9 30.000 29.948 40.000 39.938 50.000 49.938 60.000 59.926 80.000 79.926 100.000 99.913 120.000 119.913 160.000 159.900 200.000 199.885 250.000 249.885 300.000 299.870 400.000 399.860 500.000 499.845
Close Running Fitb 0.169 0.065 0.204 0.080 0.204 0.080 0.248 0.100 0.248 0.100 0.294 0.120 0.294 0.120 0.345 0.145 0.400 0.170 0.400 0.170 0.450 0.190 0.490 0.210 0.540 0.230
Hole F8 30.053 30.020 40.064 40.025 50.064 50.025 60.076 60.030 80.076 80.030 100.090 100.036 120.090 120.036 160.106 160.043 200.122 200.050 250.122 250.050 300.137 300.056 400.151 400.062 500.165 500.068
Shaft h7 30.000 29.979 40.000 39.975 50.000 49.975 60.000 59.970 80.000 79.970 100.000 99.965 120.000 119.965 160.000 159.960 200.000 199.954 250.000 249.954 300.000 299.948 400.000 399.943 500.000 499.937
Sliding Fitb 0.074 0.020 0.089 0.025 0.089 0.025 0.106 0.030 0.106 0.030 0.125 0.036 0.125 0.036 0.146 0.043 0.168 0.050 0.168 0.050 0.189 0.056 0.208 0.062 0.228 0.068
Hole G7 30.028 30.007 40.034 40.009 50.034 50.009 60.040 60.010 80.040 80.010 100.047 100.012 120.047 120.012 160.054 160.014 200.061 200.015 250.061 250.015 300.069 300.017 400.075 400.018 500.083 500.020
Shaft h6 30.000 29.987 40.000 39.984 50.000 49.984 60.000 59.981 80.000 79.981 100.000 99.978 120.000 119.978 160.000 159.975 200.000 199.971 250.000 249.971 300.000 299.968 400.000 399.964 500.000 499.960
Locational Clearance Fitb 0.041 0.007 0.050 0.009 0.050 0.009 0.059 0.010 0.059 0.010 0.069 0.012 0.069 0.012 0.079 0.014 0.090 0.015 0.090 0.015 0.101 0.017 0.111 0.018 0.123 0.020
Hole H7 30.021 30.000 40.025 40.000 50.025 50.000 60.030 60.000 80.030 80.000 100.035 100.000 120.035 120.000 160.040 160.000 200.046 200.000 250.046 250.000 300.052 300.000 400.057 400.000 500.063 500.000
Shaft h6 30.000 29.987 40.000 39.984 50.000 49.984 60.000 59.981 80.000 79.981 100.000 99.978 120.000 119.978 160.000 159.975 200.000 199.971 250.000 249.971 300.000 299.968 400.000 399.964 500.000 499.960
Fitb 0.034 0.000 0.041 0.000 0.041 0.000 0.049 0.000 0.049 0.000 0.057 0.000 0.057 0.000 0.065 0.000 0.075 0.000 0.075 0.000 0.084 0.000 0.093 0.000 0.103 0.000
SHAFT BASIS METRIC CLEARANCE FITS
50
Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min
Hole C11 30.240 30.110 40.280 40.120 50.290 50.130 60.330 60.140 80.340 80.150 100.390 100.170 120.400 120.180 160.460 160.210 200.530 200.240 250.570 250.280 300.650 300.330 400.760 400.400 500.880 500.480
a The sizes shown are first-choice basic sizes (see Table 1). Preferred fits for other sizes can be calculated from data given in ANSI B4.2-1978 (R1999). b All fits shown in this table have clearance.
All dimensions are in millimeters.
675
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
676
Table 5. American National Standard Preferred Shaft Basis Metric Transition and Interference Fits ANSI B4.2-1978 (R1999) Locational Transition Basic Sizea 1
1.6 2 2.5 3 4 5 6 8 10 12 16 20 25
Locational Interference
Medium Drive
Force
Shaft h6
Fitb
Hole N7
Shaft h6
Fitb
Hole P7
Shaft h6
Fitb
Hole S7
Shaft h6
Fitb
Hole U7
Shaft h6
Fitb
1.000 0.990 1.200 1.190 1.600 1.590 2.000 1.990 2.500 2.490 3.000 2.990 4.003 3.991 5.003 4.991 6.003 5.991 8.005 7.990 10.005 9.990 12.006 11.988 16.006 15.988 20.006 19.985 25.006 24.985
1.000 0.994 1.200 1.194 1.600 1.594 2.000 1.994 2.500 2.494 3.000 2.994 4.000 3.992 5.000 4.992 6.000 5.992 8.000 7.991 10.000 9.991 12.000 11.989 16.000 15.989 20.000 19.987 25.000 24.987
+0.006 −0.010 +0.006 −0.010 +0.006 −0.010 +0.006 −0.010 +0.006 −0.010 +0.006 −0.010 +0.011 −0.009 +0.011 −0.009 +0.011 −0.009 +0.014 −0.010 +0.014 −0.010 +0.017 −0.012 +0.017 −0.012 +0.019 −0.015 +0.019 −0.015
0.996 0.986 1.196 1.186 1.596 1.586 1.996 1.986 2.496 2.486 2.996 2.986 3.996 3.984 4.996 4.984 5.996 5.984 7.996 7.981 9.996 9.981 11.995 11.977 15.995 15.977 19.993 19.972 24.993 24.972
1.000 0.994 1.200 1.194 1.600 1.594 2.000 1.994 2.500 2.494 3.000 2.994 4.000 3.992 5.000 4.992 6.000 5.992 8.000 7.991 10.000 9.991 12.000 11.989 16.000 15.989 20.000 19.987 25.000 24.987
+0.002 −0.014 +0.002 −0.014 +0.002 −0.014 +0.002 −0.014 +0.002 −0.014 +0.002 −0.014 +0.004 −0.016 +0.004 −0.016 +0.004 −0.016 +0.005 −0.019 +0.005 −0.019 +0.006 −0.023 +0.006 −0.023 +0.006 −0.028 +0.006 −0.028
0.994 0.984 1.194 1.184 1.594 1.584 1.994 1.984 2.494 2.484 2.994 2.984 3.992 3.980 4.992 4.980 5.992 5.980 7.991 7.976 9.991 9.976 11.989 11.971 15.989 15.971 19.986 19.965 24.986 24.965
1.000 0.994 1.200 1.194 1.600 1.594 2.000 1.994 2.500 2.494 3.000 2.994 4.000 3.992 5.000 4.992 6.000 5.992 8.000 7.991 10.000 9.991 12.000 11.989 16.000 15.989 20.000 19.987 25.000 24.987
0.000 −0.016 0.000 −0.016 0.000 −0.016 0.000 −0.016 0.000 −0.016 0.000 −0.016 0.000 −0.020 0.000 −0.020 0.000 −0.020 0.000 −0.024 0.000 −0.024 0.000 −0.029 0.000 −0.029 −0.001 −0.035 −0.001 −0.035
0.986 0.976 1.186 1.176 1.586 1.576 1.986 1.976 2.486 2.476 2.986 2.976 3.985 3.973 4.985 4.973 5.985 5.973 7.983 7.968 9.983 9.968 11.979 11.961 15.979 15.961 19.973 19.952 24.973 24.952
1.000 0.994 1.200 1.194 1.600 1.594 2.000 1.994 2.500 2.494 3.000 2.994 4.000 3.992 5.000 4.992 6.000 5.992 8.000 7.991 10.000 9.991 12.000 11.989 16.000 15.989 20.000 19.987 25.000 24.987
−0.008 −0.024 −0.008 −0.024 −0.008 −0.024 −0.008 −0.024 −0.008 −0.024 −0.008 −0.024 −0.007 −0.027 −0.007 −0.027 −0.007 −0.027 −0.008 −0.032 −0.008 −0.032 −0.010 −0.039 −0.010 −0.039 −0.014 −0.048 −0.014 −0.048
0.982 0.972 1.182 1.172 1.582 1.572 1.982 1.972 2.482 2.472 2.982 2.972 3.981 3.969 4.981 4.969 5.981 5.969 7.978 7.963 9.978 9.963 11.974 11.956 15.974 15.956 19.967 19.946 24.960 24.939
1.000 0.994 1.200 1.194 1.600 1.594 2.000 1.994 2.500 2.494 3.000 2.994 4.000 3.992 5.000 4.992 6.000 5.992 8.000 7.991 10.000 9.991 12.000 11.989 16.000 15.989 20.000 19.987 25.000 24.987
−0.012 −0.028 −0.012 −0.028 −0.012 −0.028 −0.012 −0.028 −0.012 −0.028 −0.012 −0.028 −0.011 −0.031 −0.011 −0.031 −0.011 −0.031 −0.013 −0.037 −0.013 −0.037 −0.015 −0.044 −0.015 −0.044 −0.020 −0.054 −0.027 −0.061
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SHAFT BASIS METRIC TRANSITION FITS
1.2
Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min
Locational Transition
Hole K7
Machinery's Handbook 27th Edition
Table 5. (Continued) American National Standard Preferred Shaft Basis Metric Transition and Interference Fits ANSI B4.2-1978 (R1999) Locational Transition Basic Sizea 30 40
60 80 100 120 160 200 250 300 400 500
Shaft h6 30.000 29.987 40.000 39.984 50.000 49.984 60.000 59.981 80.000 79.981 100.000 99.978 120.000 119.978 160.000 159.975 200.00 199.971 250.000 249.971 300.000 299.968 400.000 399.964 500.000 499.960
Fitb +0.019 −0.015 +0.023 −0.018 +0.023 −0.018 +0.028 −0.021 +0.028 −0.021 +0.032 −0.025 +0.032 −0.025 +0.037 −0.028 +0.042 −0.033 +0.042 −0.033 +0.048 −0.036 +0.053 −0.040 +0.058 −0.045
Locational Transition Hole N7 29.993 29.972 39.992 39.967 49.992 49.967 59.991 59.961 79.991 79.961 99.990 99.955 119.990 119.955 159.988 159.948 199.986 199.940 249.986 249.940 299.986 299.934 399.984 399.927 499.983 499.920
Shaft h6 30.000 29.987 40.000 39.984 50.000 49.984 60.000 59.981 80.000 79.981 100.000 99.978 120.000 119.978 160.000 159.975 200.000 199.971 250.000 249.971 300.000 299.968 400.000 399.964 500.000 499.960
Fitb +0.006 −0.028 +0.008 −0.033 +0.008 −0.033 +0.010 −0.039 +0.010 −0.039 +0.012 −0.045 +0.012 −0.045 +0.013 −0.052 +0.015 −0.060 +0.015 −0.060 +0.018 −0.066 +0.020 −0.073 +0.023 −0.080
Locational Interference Hole P7 29.986 29.965 39.983 39.958 49.983 49.958 59.979 59.949 79.979 79.949 99.976 99.941 119.976 119.941 159.972 159.932 199.967 199.921 249.967 249.921 299.964 299.912 399.959 399.902 499.955 499.892
Shaft h6 30.000 29.987 40.000 39.984 50.000 49.984 60.000 59.981 80.000 79.981 100.000 99.978 120.000 119.978 160.000 159.975 200.000 199.971 250.000 249.971 300.000 299.968 400.000 399.964 500.000 499.960
Fitb −0.001 −0.035 −0.001 −0.042 −0.001 −0.042 −0.002 −0.051 −0.002 −0.051 −0.002 −0.059 −0.002 −0.059 −0.003 −0.068 −0.004 −0.079 −0.004 −0.079 −0.004 −0.088 −0.005 −0.098 −0.005 −0.108
Medium Drive Hole S7 29.973 29.952 39.966 39.941 49.966 49.941 59.958 59.928 79.952 79.922 99.942 99.907 119.934 119.899 159.915 159.875 199.895 199.849 249.877 249.831 299.850 299.798 399.813 399.756 499.771 499.708
Shaft h6 30.000 29.987 40.000 39.984 50.000 49.984 60.000 59.981 80.000 79.981 100.000 99.978 120.000 119.978 160.000 159.975 200.000 199.971 250.000 249.971 300.000 299.968 400.000 399.964 500.000 499.960
Force Fitb −0.014 −0.048 −0.018 −0.059 −0.018 −0.059 −0.023 −0.072 −0.029 −0.078 −0.036 −0.093 −0.044 −0.101 −0.060 −0.125 −0.076 −0.151 −0.094 −0.169 −0.118 −0.202 −0.151 −0.244 −0.189 −0.292
Hole U7 29.960 29.939 39.949 39.924 49.939 49.914 59.924 59.894 79.909 79.879 99.889 99.854 119.869 119.834 159.825 159.785 199.781 199.735 249.733 249.687 299.670 299.618 399.586 399.529 499.483 499.420
Shaft h6 30.000 29.987 40.000 39.984 50.000 49.984 60.000 59.981 80.000 79.981 100.000 99.978 120.000 119.978 160.000 159.975 200.000 199.971 250.000 249.971 300.000 299.968 400.000 399.964 500.000 499.960
Fitb −0.027 −0.061 −0.035 −0.076 −0.045 −0.086 −0.087 −0.106 −0.072 −0.121 −0.089 −0.146 −0.109 −0.166 −0.150 −0.215 −0.190 −0.265 −0.238 −0.313 −0.298 −0.382 −0.378 −0.471 −0.477 −0.580
SHAFT BASIS METRIC TRANSITION FITS
50
Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min Max Min
Hole K7 30.006 29.985 40.007 39.982 50.007 49.982 60.009 59.979 80.009 79.979 100.010 99.975 120.010 119.975 160.012 159.972 200.013 199.967 250.013 249.967 300.016 299.964 400.017 399.960 500.018 499.955
a The sizes shown are first-choice basic sizes (see Table 1). Preferred fits for other sizes can be calculated from data given in ANSI B4.2-1978 (R1999). b A plus sign indicates clearance; a minus sign indicates interference.
All dimensions are in millimeters.
677
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Machinery's Handbook 27th Edition 678
GAGEMAKERS TOLERANCES Table 6. American National Standard Gagemakers Tolerances ANSI B4.4M-1981 (R1987)
Gagemakers Tolerance ISO SymClass bola ZM 0.05 IT11 YM
0.05 IT9
XM
0.05 IT8
XXM
0.05 IT7
XXX M
0.05 IT6
Workpiece Tolerance IT Grade Recommended Gage Usage IT11 Low-precision gages recommended to be used to inspect workpieces held to internal (hole) tolerances C11 and H11 and to external (shaft) tolerances c11 and h11. IT9 Gages recommended to be used to inspect workpieces held to internal (hole) tolerances D9 and H9 and to external (shaft) tolerances d9 and h9. IT8 Precision gages recommended to be used to inspect workpieces held to internal (hole) tolerances F8 and H8. IT7 Recommended to be used for gages to inspect workpieces held to internal (hole) tolerances G7, H7, K7, N7, P7, S7, and U7, and to external (shaft) tolerances f7 and h7. IT6 High-precision gages recommended to be used to inspect workpieces held to external (shaft) tolerances g6, h6, k6, n6, p6, s6, and u6.
a Gagemakers tolerance is equal to 5 per cent of workpiece tolerance or 5 per cent of applicable IT grade value. See Table 7.
For workpiece tolerance class values, see previous Tables 2 through 5, incl.
Table 7. American National Standard Gagemakers Tolerances ANSI B4.4M-1981 (R1987) Basic Size Over 0 3 6 10 18 30 50 80 120 180 250 315 400
To 3 6 10 18 30 50 80 120 180 250 315 400 500
Class ZM
Class YM
Class XM
Class XXM
Clas XXXM
(0.05 IT11) 0.0030 0.0037 0.0045 0.0055 0.0065 0.0080 0.0095 0.0110 0.0125 0.0145 0.0160 0.0180 0.0200
(0.05 IT9) 0.0012 0.0015 0.0018 0.0021 0.0026 0.0031 0.0037 0.0043 0.0050 0.0057 0.0065 0.0070 0.0077
(0.05 IT8) 0.0007 0.0009 0.0011 0.0013 0.0016 0.0019 0.0023 0.0027 0.0031 0.0036 0.0040 0.0044 0.0048
(0.05 IT7) 0.0005 0.0006 0.0007 0.0009 0.0010 0.0012 0.0015 0.0017 0.0020 0.0023 0.0026 0.0028 0.0031
(0.05 IT6) 0.0003 0.0004 0.0005 0.0006 0.0007 0.0008 0.0010 0.0011 0.0013 0.0015 0.0016 0.0018 0.0020
All dimensions are in millimeters. For closer gagemakers tolerance classes than Class XXXM, specify 5 per cent of IT5, IT4, or IT3 and use the designation 0.05 IT5, 0.05 IT4, etc.
Fig. 4. Relationship between Gagemakers Tolerance, Wear Allowance and Workpiece Tolerance
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Machinery's Handbook 27th Edition TOLERANCE APPLICATION
679
Applications.—Many factors such as length of engagement, bearing load, speed, lubrication, operating temperatures, humidity, surface texture, and materials must be taken into account in fit selections for a particular application. Choice of other than the preferred fits might be considered necessary to satisfy extreme conditions. Subsequent adjustments might also be desired as the result of experience in a particular application to suit critical functional requirements or to permit optimum manufacturing economy. Selection of a departure from these recommendations will depend upon consideration of the engineering and economic factors that might be involved; however, the benefits to be derived from the use of preferred fits should not be overlooked. A general guide to machining processes that may normally be expected to produce work within the tolerances indicated by the IT grades given in ANSI B4.2-1978 (R1999) is shown in Table 8. Practical usage of the various IT tolerance grades is shown in Table 9. Table 8. Relation of Machining Processes to IT Tolerance Grades IT Grades 4
5
6
7
8
9
10
11
Lapping & Honing Cylindrical Grinding Surface Grinding Diamond Turning Diamond Boring Broaching Powder Metal sizes Reaming Turning Powder Metal sintered Boring Milling Planing & Shaping Drilling Punching Die Casting
Table 9. Practical Use of International Tolerance Grades For Measurig Tools For Material IT Grades 01 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 For Fits For Large Manufacturing Tolerances
British Standard for Metric ISO Limits and Fits Based on ISO Recommendation R286, this British Standard BS 4500:1969 is intended to provide a comprehensive range of metric limits and fits for engineering purposes, and meets the requirements of metrication in the United Kingdom. Sizes up to 3,150 mm are covered by the Standard, but the condensed information presented here embraces dimensions up to 500 mm only. The system is based on a series of tolerances graded to suit all classes of work from the finest to the most coarse, and the different types of fits that can be obtained range from coarse clearance to heavy interference. In the Standard, only cylindrical parts, designated holes and shafts are referred to explicitly, but it is emphasized that the recommendations apply equally well to other sections, and the general term hole or shaft
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Machinery's Handbook 27th Edition 680
BRITISH STANDARD METRIC ISO LIMITS AND FITS
can be taken to mean the space contained by or containing two parallel faces or tangent planes of any part, such as the width of a slot, or the thickness of a key. It is also strongly emphasized that the grades series of tolerances are intended for the most general application, and should be used wherever possible whether the features of the component involved are members of a fit or not. Definitions.—The definitions given in the Standard include the following: Limits of Size: The maximum and minimum sizes permitted for a feature. Basic Size: The reference size to which the limits of size are fixed. The basic size is the same for both members of a fit. Upper Deviation: The algebraical difference between the maximum limit of size and the corresponding basic size. It is designated as ES for a hole, and as es for a shaft, which stands for the French term écart supérieur. Lower Deviation: The algebraical difference between the minimum limit of size and the corresponding basic size. It is designated as EI for a hole, and as ei for a shaft, which stands for the French term écart inférieur. Zero Line: In a graphical representation of limits and fits, the straight line to which the deviations are referred. The zero line is the line of zero deviation and represents the basic size. Tolerance: The difference between the maximum limit of size and the minimum limit of size. It is an absolute value without sign. Tolerance Zone: In a graphical representation of tolerances, the zone comprised between the two lines representing the limits of tolerance and defined by its magnitude (tolerance) and by its position in relation to the zero line. Fundamental Deviation: That one of the two deviations, being the one nearest to the zero line, which is conventionally chosen to define the position of the tolerance zone in relation to the zero line. Shaft-Basis System of Fits: A system of fits in which the different clearances and interferences are obtained by associating various holes with a single shaft. In the ISO system, the basic shaft is the shaft the upper deviation of which is zero. Hole-Basis System of Fits: A system of fits in which the different clearances and interferences are obtained by associating various shafts with a single hole. In the ISO system, the basic hole is the hole the lower deviation of which is zero. Selected Limits of Tolerance, and Fits.—The number of fit combinations that can be built up with the ISO system is very large. However, experience shows that the majority of fits required for usual engineering products can be provided by a limited selection of tolerances. Limits of tolerance for selected holes are shown in Table 1, and for shafts, in Table 2. Selected fits, based on combinations of the selected hole and shaft tolerances, are given in Table 3. Tolerances and Fundamental Deviations.—There are 18 tolerance grades intended to meet the requirements of different classes of work, and they are designated IT01, IT0, and IT1 to IT16. (IT stands for ISO series of tolerances.) Table 4 shows the standardized numerical values for the 18 tolerance grades, which are known as standard tolerances. The system provides 27 fundamental deviations for sizes up to and including 500 mm, and Tables 5a and 5b contain the values for shafts and Tables 6a and 6b for holes. Uppercase (capital) letters designate hole deviations, and the same letters in lower case designate shaft deviations. The deviation js (Js for holes) is provided to meet the need for symmetrical bilateral tolerances. In this instance, there is no fundamental deviation, and the tolerance zone, of whatever magnitude, is equally disposed about the zero line. Calculated Limits of Tolerance.—The deviations and fundamental tolerances provided by the ISO system can be combined in any way that appears necessary to give a required fit. Thus, for example, the deviations H (basic hole) and f (clearance shaft) could be associated, and with each of these deviations any one of the tolerance grades IT01 to IT16 could
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Machinery's Handbook 27th Edition BRITISH STANDARD METRIC ISO LIMITS AND FITS
681
be used. All the limits of tolerance that the system is capable of providing for sizes up to and including 500 mm can be calculated from the standard tolerances given in Table 4, and the fundamental deviations given in Tables 5a, 5b, 6a and 6b. The range includes limits of tolerance for shafts and holes used in small high-precision work and horology. The system provides for the use of either hole-basis or shaft-basis fits, and the Standard includes details of procedures for converting from one type of fit to the other. The limits of tolerance for a shaft or hole are designated by the appropriate letter indicating the fundamental deviation, followed by a suffix number denoting the tolerance grade. This suffix number is the numerical part of the tolerance grade designation. Thus, a hole tolerance with deviation H and tolerance grade IT7 is designated H7. Likewise, a shaft with deviation p and tolerance grade IT6 is designated p6. The limits of size of a component feature are defined by the basic size, say, 45 mm, followed by the appropriate tolerance designation, for example, 45 H7 or 45 p6. A fit is indicated by combining the basic size common to both features with the designation appropriate to each of them, for example, 45 H7-p6 or 45 H7/p6. When calculating the limits of size for a shaft, the upper deviation es, or the lower deviation ei, is first obtained from Tables 5a or 5b, depending on the particular letter designation, and nominal dimension. If an upper deviation has been determined, the lower deviation ei = es − IT. The IT value is obtained from Table 4 for the particular tolerance grade being applied. If a lower deviation has been obtained from Tables 5a or 5b, the upper deviation es = ei + IT. When the upper deviation ES has been determined for a hole from Tables 6a or 6b, the lower deviation EI = ES − IT. If a lower deviation EI has been obtained from Table 6a, then the upper deviation ES = EI + IT. The upper deviations for holes K, M, and N with tolerance grades up to and including IT8, and for holes P to ZC with tolerance grades up to and including IT7 must be calculated by adding the delta (∆) values given in Table 6b as indicated. Example 1:The limits of size for a part of 133 mm basic size with a tolerance designation g9 are derived as follows: From Table 5a, the upper deviation (es) is − 0.014 mm. From Table 4, the tolerance grade (IT9) is 0.100 mm. The lower deviation (ei) = es − IT = 0.114 mm, and the limits of size are thus 132.986 and 132.886 mm. Example 2:The limits of size for a part 20 mm in size, with tolerance designation D3, are derived as follows: From Table 6a, the lower deviation (EI) is + 0.065 mm. From Table 4, the tolerance grade (IT3) is 0.004 mm. The upper deviation (ES) = EI + IT = 0.069 mm, and thus the limits of size for the part are 20.069 and 20.065 mm. Example 3:The limits of size for a part 32 mm in size, with tolerance designation M5, which involves a delta value, are obtained as follows: From Table 6a, the upper deviation ES is − 0.009 mm + ∆ = −0.005 mm. (The delta value given at the end of Table 6b for this size and grade IT5 is 0.004 mm.) From Table 4, the tolerance grade (IT5) is 0.011 mm. The lower deviation (EI) = ES − IT = − 0.016 mm, and thus the limits of size for the part are 31.995 and 31.984 mm. Where the designations h and H or js and Js are used, it is only necessary to refer to Table 4. For h and H, the fundamental deviation is always zero, and the disposition of the tolerance is always negative ( − ) for a shaft, and positive ( + ) for a hole. Example 4:The limits for a part 40 mm in size, designated h8 are derived as follows: From Table 4, the tolerance grade (IT8) is 0.039 mm, and the limits are therefore 40.000 and 39.961 mm. Example 5:The limits for a part 60 mm in size, designated js7 or Js7 are derived as follows: From Table 4, the tolerance grade (IT7) is 0.030 mm, and this value is divided equally about the basic size to give limits of 60.015 and 59.985 mm.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 682
BRITISH STANDARD METRIC ISO LIMITS AND FITS Table 1. British Standard Limits of Tolerance for Selected Holes (Upper and Lower Deviations) BS 4500:1969
Nominal Sizes, mm
H7
H8
H9
H11
Over
Up to and Including
ES +
EI
ES +
EI
ES +
EI
ES +
EI
…
3
10
0
14
0
25
0
60
0
3
6
12
0
18
0
30
0
75
0
6
10
15
0
22
0
36
0
90
0
10
18
18
0
27
0
43
0
110
0
18
30
21
0
33
0
52
0
130
0
30
50
25
0
39
0
62
0
160
0
50
80
30
0
46
0
74
0
190
0
80
120
35
0
54
0
87
0
220
0
120
180
40
0
63
0
100
0
250
0
180
250
46
0
72
0
115
0
290
0
250
315
52
0
81
0
130
0
320
0
315
400
57
0
89
0
140
0
360
0
400
500
63
0
97
0
155
0
400
0
ES = Upper deviation, EI = Lower deviation. The dimensions are given in 0.001 mm, except for the nominal sizes, which are in millimeters.
Table 2. British Standard Limits of Tolerance for Selected Shafts (Upper and Lower Deviations) BS 4500:1969 Nominal Sizes, mm
d10
e9
f7
g6
h6
k6
n6
p6
s6
es −
…
3
60
120
20
60
14
39
6
16
2
8
0
6
6
0
10
4
12
6
20
14
3
6
70
145
30
78
20
50
10
22
4
12
0
8
9
1
16
8
20
12
27
19
6
10
80
170
40
98
25
61
13
28
5
14
0
9
10
1
19
10
24
15
32
23
10
18
95
205
50
120
32
75
16
34
6
17
0
11
12
1
23
12
29
18
39
28
18
30
110
240
65
149
40
92
20
41
7
20
0
13
15
2
28
15
35
22
48
35
30
40
120
280
80
180
50
112
25
50
9
25
0
16
18
2
33
17
42
26
59
43
40
50
130
290
80
180
50
112
25
50
9
25
0
16
18
2
33
17
42
26
59
43
50
65
140
330
100
220
60
134
30
60
10
29
0
19
21
2
39
20
51
32
72
53
65
80
150
340
100
220
60
134
30
60
10
29
0
19
21
2
39
20
51
32
78
59
80
100
170
390
120
260
72
159
36
71
12
34
0
22
25
3
45
23
59
37
93
71
100
120
180
400
120
260
72
159
36
71
12
34
0
22
25
3
45
23
59
37
101
79
120
140
200
450
145
305
85
185
43
83
14
39
0
25
28
3
52
27
68
43
117
92
140
160
210
460
145
305
85
185
43
83
14
39
0
25
28
3
52
27
68
43
125
100
160
180
230
480
145
305
85
185
43
83
14
39
0
25
28
3
52
27
68
43
133
108
180
200
240
530
170
355
100
215
50
96
15
44
0
29
33
4
60
31
79
50
151
122
200
225
260
550
170
355
100
215
50
96
15
44
0
29
33
4
60
31
79
50
159
130
225
250
280
570
170
355
100
215
50
96
15
44
0
29
33
4
60
31
79
50
169
140
250
280
300
620
190
400
110
240
56
108
17
49
0
32
36
4
66
34
88
56
190
158
280
315
330
650
190
400
110
240
56
108
17
49
0
32
36
4
66
34
88
56
202
170
315
355
360
720
210
440
125
265
62
119
18
54
0
36
40
4
73
37
98
62
226
190
355
400
400
760
210
440
125
265
62
119
18
54
0
36
40
4
73
37
98
62
244
208
400
450
440
840
230
480
135
290
68
131
20
60
0
40
45
5
80
40
108
68
272
232
450
500
480
880
230
480
135
290
68
131
20
60
0
40
45
5
80
40
108
68
292
252
Over
Up to and Incl.
c11 ei −
es −
ei −
es −
ei −
es −
ei −
es −
ei −
es −
ei −
es +
ei +
es +
ei +
es +
ei +
es +
ei +
es = Upper deviation, ei = Lower deviation. The dimensions are given in 0.001 mm, except for the nominal sizes, which are in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 3. British Standard Selected Fits, Minimum and Maximum Clearances BS 4500:1969 Nominal Sizes, mm
H11—c11
H9—d10
H9—e9
H8—f7
H7—g6
H7—h6
H7—k6
H7—n6
H7—p6
H7—s6
Up to and Incl.
Min
Max
Min
Max
Min
Max
Min
Max
Min
Max
Min
Max
Min
Max
Min
Max
Min
Max
Min
Max
…
3
60
180
20
85
14
64
6
30
2
18
0
16
−6
+10
−10
+6
−12
+4
−20
−4
3
6
70
220
30
108
20
80
10
40
4
24
0
20
−9
+11
−16
+4
−20
0
−27
−7
6
10
80
260
40
134
25
97
13
50
5
29
0
24
−10
+14
−19
+5
−24
0
−32
−8
10
18
95
315
50
163
32
118
16
61
6
35
0
29
−12
+17
−23
+6
−29
0
−39
−10
18
30
110
370
65
201
40
144
20
74
7
41
0
34
−15
+19
−28
+6
−35
−1
−48
−14
30
40
120
440
80
242
50
174
25
89
9
50
0
41
−18
+23
−33
+8
−42
−1
−59
−18
40
50
130
450
80
242
50
174
25
89
9
50
0
41
−18
+23
−33
+8
−42
−1
−59
−18
50
65
140
520
100
294
60
208
30
106
10
59
0
49
−21
+28
−39
+10
−51
−2
−72
−23
65
80
150
530
100
294
60
208
30
106
10
59
0
49
−21
+28
−39
+10
−51
−2
−78
−29
80
100
170
610
120
347
72
246
36
125
12
69
0
57
−25
+32
−45
+12
−59
−2
−93
−36
100
120
180
620
120
347
72
246
36
125
12
69
0
57
−25
+32
−45
+12
−59
−2
−101
−44
120
140
200
700
145
405
85
285
43
146
14
79
0
65
−28
+37
−52
+13
−68
−3
−117
−52
140
160
210
710
145
405
85
285
43
146
14
79
0
65
−28
+37
−52
+13
−68
−3
−125
−60
160
180
230
730
145
405
85
285
43
146
14
79
0
65
−28
+37
−52
+13
−68
−3
−133
−68
180
200
240
820
170
470
100
330
50
168
15
90
0
75
−33
+42
−60
+15
−79
−4
−151
−76
200
225
260
840
170
470
100
330
50
168
15
90
0
75
−33
+42
−60
+15
−79
−4
−159
−84
225
250
280
860
170
470
100
330
50
168
15
90
0
75
−33
+42
−60
+15
−79
−4
−169
−94
250
280
300
940
190
530
110
370
56
189
17
101
0
84
−36
+48
−66
+18
−88
−4
−190
−126
280
315
330
970
190
530
110
370
56
189
17
101
0
84
−36
+48
−66
+18
−88
−4
−202
−112
315
355
360
1080
210
580
125
405
62
208
18
111
0
93
−40
−53
−73
+20
−98
−5
−226
−133
355
400
400
1120
210
580
125
405
62
208
18
111
0
93
−40
−53
−73
+20
−98
−5
−244
−151
400
450
440
1240
230
635
135
445
68
228
20
123
0
103
−45
+58
−80
+23
−108
−5
−272
−169
450
500
480
1280
230
635
135
445
68
228
20
123
0
103
−45
+58
−80
+23
−108
−5
−292
−189
Minus (−) sign indicates negative clearance, i.e., interference.
Copyright 2004, Industrial Press, Inc., New York, NY
683
The dimensions are given in 0.001 mm, except for the nominal sizes, which are in millimeters.
BRITISH STANDARD METRIC ISO LIMITS AND FITS
Over
Machinery's Handbook 27th Edition
Nominal Sizes, mm
684
Table 4. British Standard Limits and Fits BS 4500:1969 Tolerance Grades
To
IT 01
IT 0
IT 1
IT 2
IT 3
IT 4
IT 5
IT 6
IT 7
IT 8
IT 9
IT 10
IT 11
IT 12
IT 13
IT 14 a
IT 15 a
IT 16 a
…
3
0.3
0.5
0.8
1.2
2
3
4
6
10
14
25
40
60
100
140
250
400
600
3
6
0.4
0.6
1
1.5
2.5
4
5
8
12
18
30
48
75
120
180
300
480
750
6
10
0.4
0.6
1
1.5
2.5
4
6
9
15
22
36
58
90
150
220
360
580
900
10
18
0.5
0.8
1.2
2
3
5
8
11
18
27
43
70
110
180
270
430
700
1100
18
30
0.6
1
1.5
2.5
4
6
9
13
21
33
52
84
130
210
330
520
840
1300
30
50
0.6
1
1.5
2.5
4
7
11
16
25
39
62
100
160
250
390
620
1000
1600
50
80
0.8
1.2
2
3
5
8
13
19
30
46
74
120
190
300
460
740
1200
1900
80
120
1
1.5
2.5
4
6
10
15
22
35
54
87
140
220
350
540
870
1400
2200
120
180
1.2
2
3.5
5
8
12
18
25
40
63
100
160
250
400
630
1000
1600
2500
180
250
2
3
4.5
7
10
14
20
29
46
72
115
185
290
460
720
1150
1850
2900
250
315
2.5
4
6
8
12
16
23
32
52
81
130
210
320
520
810
1300
2100
3200
315
400
3
5
7
9
13
18
25
36
57
89
140
230
360
570
890
1400
2300
3600
400
500
4
6
8
10
15
20
27
40
63
97
155
250
400
630
970
1550
2500
4000
a Not applicable to sizes below 1 mm.
The dimensions are given in 0.001 mm, except for the nominal sizes which are in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
BRITISH STANDARD METRIC ISO LIMITS AND FITS
Over
Machinery's Handbook 27th Edition
Table 5a. British Standard Fundamental Deviations for Shafts BS 4500:1969 Grade Nominal Sizes, mm
01 to 16
5–6
Fundamental (Upper) Deviation es
7
8
≤3 >7
4–7
Fundamental (Lower) Deviation ei
To
aa
ba
c
cd
d
e
ef
f
fg
g
h
… 3 6 10 14 18 24 30 40 50 65 80 100 120 140 160 180 200 225 250 280 315 355 400 450
3 6 10 14 18 24 30 40 50 65 80 100 120 140 160 180 200 225 250 280 315 355 400 450 500
−270 −270 −280 −290 −290 −300 −300 −310 −320 −340 −360 −380 −410 −460 −520 −580 −660 −740 −820 −920 −1050 −1200 −1350 −1500 −1650
−140 −140 −150 −150 −150 −160 −160 −170 −180 −190 −200 −220 −240 −260 −280 −310 −340 −380 −420 −480 −540 −600 −680 −760 −840
−60 −70 −80 −95 −95 −110 −110 −120 −130 −140 −150 −170 −180 −200 −210 −230 −240 −260 −280 −300 −330 −360 −400 −440 −480
−34 −46 −56 … … … … … … … … … … … … … … … … … … … … … …
−20 −30 −40 −50 −50 −65 −65 −80 −80 −100 −100 −120 −120 −145 −145 −145 −170 −170 −170 −190 −190 −210 −210 −230 −230
−14 −20 −25 −32 −32 −40 −40 −50 −50 −60 −60 −72 −72 −85 −85 −85 −100 −100 −100 −110 −110 −125 −125 −135 −135
−10 −14 −18 … … … … … … … … … … … … … … … … … … … … … …
−6 −10 −13 −16 −16 −20 −20 −25 −25 −30 −30 −36 −36 −43 −43 −43 −50 −50 −50 −56 −56 −62 −62 −68 −68
−4 −6 −8 … … … … … … … … … … … … … … … … … … … … … …
−2 −4 −5 −6 −6 −7 −7 −9 −9 −10 −10 −12 −12 −14 −14 −14 −15 −15 −15 −17 −17 −18 −18 −20 −20
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
js b
±IT/2
j −2 −2 −2 −3 −3 −4 −4 −5 −5 −7 −7 −9 −9 −11 −11 −11 −13 −13 −13 −16 −16 −18 −18 −20 −20
−4 −4 −5 −6 −6 −8 −8 −10 −10 −12 −12 −15 −15 −18 −18 −18 −21 −21 −21 −26 −26 −28 −28 −32 −32
k −6 … … … … … … … … … … … … … … … … … … … … … … … …
0 +1 +1 +1 +1 +2 +2 +2 +2 +2 +2 +3 +3 +3 +3 +3 +4 +4 +4 +4 +4 +4 +4 +5 +5
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
BRITISH STANDARD METRIC ISO LIMITS AND FITS
Over
a Not applicable to sizes up to 1 mm.
Copyright 2004, Industrial Press, Inc., New York, NY
685
b In grades 7 to 11, the two symmetrical deviations ±IT/2 should be rounded if the IT value in micrometers is an odd value by replacing it with the even value immediately below. For example, if IT = 175, replace it by 174.
Machinery's Handbook 27th Edition
686
Table 5b. British Standard Fundamental Deviations for Shafts BS 4500:1969 Grade Nominal Sizes, mm
01 to 16 Fundamental (Lower) Deviation ei To
m
n
p
r
s
t
u
v
x
y
z
za
zb
zc
…
3
+2
+4
+6
+10
+14
…
+18
…
+20
…
+26
+32
+40
+60
3
6
+4
+8
+12
+15
+19
…
+23
…
+28
…
+35
+42
+50
+80
6
10
+6
+10
+15
+19
+23
…
+28
…
+34
…
+42
+52
+67
+97
10
14
+7
+12
+18
+23
+28
…
+33
…
+40
…
+50
+64
+90
+130 +150
14
18
+7
+12
+18
+23
+28
…
+33
+39
+45
…
+60
+77
+108
18
24
+8
+15
+22
+28
+35
…
+41
+47
+54
+63
+73
+98
+136
+188
24
30
+8
+15
+22
+28
+35
+41
+48
+55
+64
+75
+88
+118
+160
+218
30
40
+9
+17
+26
+34
+43
+48
+60
+68
+80
+94
+112
+148
+200
+274
40
50
+9
+17
+26
+34
+43
+54
+70
+81
+97
+114
+136
+180
+242
+325
50
65
+11
+20
+32
+41
+53
+66
+87
+102
+122
+144
+172
+226
+300
+405
65
80
+11
+20
+32
+43
+59
+75
+102
+120
+146
+174
+210
+274
+360
+480
80
100
+13
+23
+37
+51
+71
+91
+124
+146
+178
+214
+258
+335
+445
+585
100
120
+13
+23
+37
+54
+79
+104
+144
+172
+210
+254
+310
+400
+525
+690
120
140
+15
+27
+43
+63
+92
+122
+170
+202
+248
+300
+365
+470
+620
+800
140
160
+15
+27
+43
+65
+100
+134
+190
+228
+280
+340
+415
+535
+700
+900
160
180
+15
+27
+43
+68
+108
+146
+210
+252
+310
+380
+465
+600
+780
+1000
180
200
+17
+31
+50
+77
+122
+166
+236
+284
+350
+425
+520
+670
+880
+1150
200
225
+17
+31
+50
+80
+130
+180
+258
+310
+385
+470
+575
+740
+960
+1250
225
250
+17
+31
+50
+84
+140
+196
+284
+340
+425
+520
+640
+820
+1050
+1350
250
280
+20
+34
+56
+94
+158
+218
+315
+385
+475
+580
+710
+920
+1200
+1550
280
315
+20
+34
+56
+98
+170
+240
+350
+425
+525
+650
+790
+1000
+1300
+1700
315
355
+21
+37
+62
+108
+190
+268
+390
+475
+590
+730
+900
+1150
+1500
+1900
355
400
+21
+37
+62
+114
+208
+294
+435
+530
+660
+820
+1000
+1300
+1650
+2100
400
450
+23
+40
+68
+126
+232
+330
+490
+595
+740
+920
+1100
+1450
+1850
+2400
450
500
+23
+40
+68
+132
+252
+360
+540
+660
+820
+1000
+1250
+1600
+2100
+2600
The dimensions are in 0.001 mm, except the nominal sizes, which are in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
BRITISH STANDARD METRIC ISO LIMITS AND FITS
Over
Machinery's Handbook 27th Edition
Table 6a. British Standard Fundamental Deviations for Holes BS 4500:1969 Grade Nominal Sizes, mm
01 to 16
6
7
8
Fundamental (Lower) Deviation EI
≤8
>8
≤8a
>8
≤8
>8b
Fundamental (Upper) Deviation ES
To
Ab
Bb
C
CD
D
E
EF
F
FG
G
H
… 3 6 10 14 18 24 30 40 50 65 80 100 120 140 160 180 200 225 250 280 315 355 400 450
3 6 10 14 18 24 30 40 50 65 80 100 120 140 160 180 200 225 250 280 315 355 400 450 500
+270 +270 +280 +290 +290 +300 +300 +310 +320 +340 +360 +380 +410 +460 +520 +580 +660 +740 +820 +920 +1050 +1200 +1350 +1500 +1650
+140 +140 +150 +150 +150 +160 +160 +170 +180 +190 +200 +220 +240 +260 +280 +310 +340 +380 +420 +480 +540 +600 +680 +760 +840
+60 +70 +80 +95 +95 +110 +110 +120 +130 +140 +150 +170 +180 +200 +210 +230 +240 +260 +280 +300 +330 +360 +400 +440 +480
+34 +46 +56 … … … … … … … … … … … … … … … … … … … … … …
+20 +30 +40 +50 +50 +65 +65 +80 +80 +100 +100 +120 +120 +145 +145 +145 +170 +170 +170 +190 +190 +210 +210 +230 +230
+14 +20 +25 +32 +32 +40 +40 +50 +50 +60 +60 +72 +72 +85 +85 +85 +100 +100 +100 +110 +110 +125 +125 +135 +135
+10 +14 +18 … … … … … … … … … … … … … … … … … … … … … …
+6 +10 +13 +16 +16 +20 +20 +25 +25 +30 +30 +36 +36 +43 +43 +43 +50 +50 +50 +56 +56 +62 +62 +68 +68
+4 +6 +8 … … … … … … … … … … … … … … … … … … … … … …
+2 +4 +5 +6 +6 +7 +7 +9 +9 +10 +10 +12 +12 +14 +14 +14 +15 +15 +15 +17 +17 +18 +18 +20 +20
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
Jsc
±IT/2
Kd
J +2 +5 +5 +6 +6 +8 +8 +10 +10 +13 +13 +16 +16 +18 +18 +18 +22 +22 +22 +25 +25 +29 +29 +33 +33
+4 +6 +8 +10 +10 +12 +12 +14 +14 +18 +18 +22 +22 +26 +26 +26 +30 +30 +30 +36 +36 +39 +39 +43 +43
+6 +10 +12 +15 +15 +20 +20 +24 +24 +28 +28 +34 +34 +41 +41 +41 +47 +47 +47 +55 +55 +60 +60 +66 +66
0 −1+∆ −1+∆ −1+∆ −1+∆ −2+∆ −2+∆ −2+∆ −2+∆ −2+∆ −2+∆ −3+∆ −3+∆ −3+∆ −3+∆ −3+∆ −4+∆ −4+∆ −4+∆ −4+∆ −4+∆ −4+∆ −4+∆ −5+4 −5+4
Md 0 … … … … … … … … … … … … … … … … … … … … … … … …
−2 −4+∆ −6+∆ −7+∆ −7+∆ −8+∆ −8+∆ −9+∆ −9+∆ −11+∆ −11+∆ −13+∆ −13+∆ −15+∆ −15+∆ −15+∆ −17+∆ −17−∆ −17+∆ −20+∆ −20+∆ −21+∆ −21+∆ −23+∆ −23+∆
Nd −2 −4 −6 −7 −7 −8 −8 −9 −9 −11 −11 −13 −13 −15 −15 −15 −17 −17 −17 −20 −20 −21 −21 −23 −23
−4 −8+∆ −10+∆ −12+∆ −12+∆ −15+∆ −15+∆ −17+∆ −17+∆ −20+∆ −20+∆ −23+∆ −23+∆ −27+∆ −27+∆ −27+∆ −31+∆ −31+∆ −31+∆ −34+∆ −34+∆ −37+∆ −37+∆ −40+∆ −40+∆
−4 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
a Special case: for M6, ES = −9 for sizes from 250 to 315 mm, instead of −11. b Not applicable to sizes up to 1 mm.
Copyright 2004, Industrial Press, Inc., New York, NY
687
c In grades 7 to 11, the two symmetrical deviations ±IT/2 should be rounded if the IT value in micrometers is an odd value, by replacing it with the even value below. For example, if IT = 175, replace it by 174. d When calculating deviations for holes K, M, and N with tolerance grades up to and including IT8, and holes F to ZC with tolerance grades up to and including IT7, the delta (∆) values are added to the upper deviation ES. For example, for 25 P7, ES = −0.022 + 0.008 = −0.014 mm.
BRITISH STANDARD METRIC ISO LIMITS AND FITS
Over
Machinery's Handbook 27th Edition
688
Table 6b. British Standard Fundamental Deviations for Holes BS 4500:1969 Grade Nominal Sizes, mm
≤7
Values for delta (∆)d
>7 Fundamental (Upper) Deviation ES
To
…
3
P to ZC
Grade
P
R
S
T
U
V
X
Y
Z
− 6
−10
−14
…
−18
…
−20
…
−26
ZA −32
ZB −40
ZC −60
3
4
5
6
7
8
0
0
0
0
0
0
3
6
−12
−15
−19
…
−23
…
−28
…
−35
−42
−50
−80
1
1.5
1
3
4
6
6
10
−15
−19
−23
…
−28
…
−34
…
−42
−52
−67
−97
1
1.5
2
3
6
7 9
10
14
−18
−23
−28
…
−33
…
−40
…
−50
−64
−90
−130
1
2
3
3
7
14
18
−18
−23
−28
…
−33
−39
−45
…
−60
−77
−108
−150
1
2
3
3
7
9
18
24
−22
−28
−35
…
−41
−47
−54
−63
−73
−98
−136
−188
1.5
2
3
4
8
12
24
30
−22
−28
−35
−41
−48
−55
−64
−75
−88
−118
−160
−218
1.5
2
3
4
8
12
30
40
−26
−34
−43
−48
−60
−68
−80
−94
−112
−148
−200
−274
1.5
3
4
5
9
14
40
50
−26
−34
−43
−54
−70
−81
−97
−114
−136
−180
−242
−325
1.5
3
4
5
9
14
50
65
−32
−41
−53
−66
−87
−102
−122
−144
−172
−226
−300
−405
2
3
5
6
11
16
65
80
80
100
100
120
120
140
Same deviation as for grades above 7 increased by ∆
−32
−43
−59
−75
−102
−120
−146
−174
−210
−274
−360
−480
2
3
5
6
11
16
−37
−51
−71
−91
−124
−146
−178
−214
−258
−335
−445
−585
2
4
5
7
13
19
−37
−54
−79
−104
−144
−172
−210
−254
−310
−400
−525
−690
2
4
5
7
13
19
−43
−63
−92
−122
−170
−202
−248
−300
−365
−470
−620
−800
3
4
6
7
15
23
140
160
−43
−65
−100
−134
−190
−228
−280
−340
−415
−535
−700
−900
3
4
6
7
15
23
160
180
−43
−68
−108
−146
−210
−252
−310
−380
−465
−600
−780
−1000
3
4
6
7
15
23
180
200
−50
−77
−122
−166
−226
−284
−350
−425
−520
−670
−880
−1150
3
4
6
9
17
26
200
225
−50
−80
−130
−180
−258
−310
−385
−470
−575
−740
−960
−1250
3
4
6
9
17
26
225
250
−50
−84
−140
−196
−284
−340
−425
−520
−640
−820
−1050
−1350
3
4
6
9
17
26
250
280
−56
−94
−158
−218
−315
−385
−475
−580
−710
−920
−1200
−1550
4
4
7
9
20
29
280
315
−56
−98
−170
−240
−350
−425
−525
−650
−790
−1000
−1300
−1700
4
4
7
9
20
29
315
355
−62
−108
−190
−268
−390
−475
−590
−730
−900
−1150
−1500
−1800
4
5
7
11
21
32
355
400
−62
−114
−208
−294
−435
−530
−660
−820
−1000
−1300
−1650
−2100
4
5
7
11
21
32
400
450
−68
−126
−232
−330
−490
−595
−740
−920
−1100
−1450
−1850
−2400
5
5
7
13
23
34
450
500
−68
−132
−252
−360
−540
−660
−820
−1000
−1250
−1600
−2100
−2600
5
5
7
13
23
34
The dimensions are given in 0.001 mm, except the nominal sizes, which are in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
BRITISH STANDARD METRIC ISO LIMITS AND FITS
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Machinery's Handbook 27th Edition PREFERRED NUMBERS
689
Preferred Numbers Preferred numbers are series of numbers selected to be used for standardization purposes in preference to any other numbers. Their use will lead to simplified practice and they should be employed whenever possible for individual standard sizes and ratings, or for a series, in applications similar to the following: 1) Important or characteristic linear dimensions, such as diameters and lengths, areas, volume, weights, capacities. 2) Ratings of machinery and apparatus in horsepower, kilowatts, kilovolt-amperes, voltages, currents, speeds, power-factors, pressures, heat units, temperatures, gas or liquidflow units, weight-handling capacities, etc. 3) Characteristic ratios of figures for all kinds of units. American National Standard for Preferred Numbers.—This ANSI Standard Z17.11973 covers basic series of preferred numbers which are independent of any measurement system and therefore can be used with metric or customary units. The numbers are rounded values of the following five geometric series of numbers: 10N/5, 10N/10, 10N/20, 10N/40, and 10N/80, where N is an integer in the series 0, 1, 2, 3, etc. The designations used for the five series are respectively R5, R10, R20, R40, and R80, where R stands for Renard (Charles Renard, originator of the first preferred number system) and the number indicates the root of 10 on which the particular series is based. The R5 series gives 5 numbers approximately 60 per cent apart, the R10 series gives 10 numbers approximately 25 per cent apart, the R20 series gives 20 numbers approximately 12 per cent apart, the R40 series gives 40 numbers approximately 6 per cent apart, and the R80 series gives 80 numbers approximately 3 per cent apart. The number of sizes for a given purpose can be minimized by using first the R5 series and adding sizes from the R10 and R20 series as needed. The R40 and R80 series are used principally for expressing tolerances in sizes based on preferred numbers. Preferred numbers below 1 are formed by dividing the given numbers by 10, 100, etc., and numbers above 10 are obtained by multiplying the given numbers by 10, 100, etc. Sizes graded according to the system may not be exactly proportional to one another due to the fact that preferred numbers may differ from calculated values by +1.26 per cent to −1.01 per cent. Deviations from preferred numbers are used in some instances — for example, where whole numbers are needed, such as 32 instead of 31.5 for the number of teeth in a gear. Basic Series of Preferred Numbers ANSI Z17.1-1973 Series Designation R5
R10
R20
R40
R40
R80
R80
R80
R80
1.00 1.03 1.06 1.09 1.12 1.15 1.18 1.22 1.25 1.28 1.32 1.36 1.40 1.45 1.50 1.55 1.60 1.65 1.70 1.75
1.80 1.85 1.90 1.95 2.00 2.06 2.12 2.18 2.24 2.30 2.36 2.43 2.50 2.58 2.65 2.72 2.80 2.90 3.00 3.07
3.15 3.25 3.35 3.45 3.55 3.65 3.75 3.87 4.00 4.12 4.25 4.37 4.50 4.62 4.75 4.87 5.00 5.15 5.20 5.45
5.60 5.80 6.00 6.15 6.30 6.50 6.70 6.90 7.10 7.30 7.50 7.75 8.00 8.25 8.50 8.75 9.00 9.25 9.50 9.75
Preferred Numbers 1.00 1.60 2.50 4.00 6.30 … … … … … … … … … … … … … … …
1.00 1.25 1.60 2.00 2.50 3.15 4.00 5.00 6.30 8.00 … … … … … … … … … …
1.00 1.12 1.25 1.40 1.60 1.80 2.00 2.24 2.50 2.80 3.15 3.55 4.00 4.50 5.00 5.60 6.30 7.10 8.00 9.00
1.00 1.06 1.12 1.18 1.25 1.32 1.40 1.50 1.60 1.70 1.80 1.90 2.00 2.12 2.24 2.36 2.50 2.65 2.80 3.00
3.15 3.35 3.55 3.75 4.00 4.25 4.50 4.75 5.00 5.30 5.60 6.00 6.30 6.70 7.10 7.50 8.00 8.50 9.00 9.50
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 690
PREFERRED METRIC SIZES
Preferred Metric Sizes.—American National Standard ANSI B32.4M-1980 (R1994), presents series of preferred metric sizes for round, square, rectangular, and hexagonal metal products. Table 1 gives preferred metric diameters from 1 to 320 millimeters for round metal products. Wherever possible, sizes should be selected from the Preferred Series shown in the table. A Second Preference series is also shown. A Third Preference Series not shown in the table is: 1.3, 2.1, 2.4, 2.6, 3.2, 3.8, 4.2, 4.8, 7.5, 8.5, 9.5, 36, 85, and 95. Most of the Preferred Series of sizes are derived from the American National Standard “10 series” of preferred numbers (see American National Standard for Preferred Numbers on page 689). Most of the Second Preference Series are derived from the “20 series” of preferred numbers. Third Preference sizes are generally from the “40 series” of preferred numbers. For preferred metric diameters less than 1 millimeter, preferred across flat metric sizes of square and hexagon metal products, preferred across flat metric sizes of rectangular metal products, and preferred metric lengths of metal products, reference should be made to the Standard. Table 1. American National Standard Preferred Metric Sizes ANSI B4.2-1978 (R1999) Basic Size, mm
Basic Size, mm
Basic Size, mm
Basic Size, mm
1st Choice
2nd Choice
1st Choice
2nd Choice
1st Choice
2nd Choice
1st Choice
2nd Choice
1 … 1.2 … 1.6 … 2 … 2.5 … 3 … 4 … 5 …
… 1.1 … 1.4 … 1.8 … 2.2 … 2.8 … 3.5 … 4.5 … 5.5
6 … 8 … 10 … 12 … 16 … 20 … 25 … 30 …
… 7 … 9 … 11 … 14 … 18 … 22 … 28 … 35
40 … 50 … 60 … 80 … 100 … 120 … 160 … 200 …
… 45 … 55 … 70 … 90 … 110 … 140 … 180 … 220
250 … 300 … 400 … 500 … 600 … 800 … 1000 … … …
… 280 … 350 … 450 … 550 … 700 … 900 … … … …
British Standard Preferred Numbers and Preferred Sizes.—This British Standard, PD 6481:1977 1983, gives recommendations for the use of preferred numbers and preferred sizes for functional characteristics and dimensions of various products. The preferred number system is internationally standardized in ISO 3. It is also referred to as the Renard, or R, series (see American National Standard for Preferred Numbers, on page 689). The series in the preferred number system are geometric series, that is, there is a constant ratio between each figure and the succeeding one, within a decimal framework. Thus, the R5 series has five steps between 1 and 10, the R10 series has 10 steps between 1 and 10, the R20 series, 20 steps, and the R40 series, 40 steps, giving increases between steps of approximately 60, 25, 12, and 6 per cent, respectively. The preferred size series have been developed from the preferred number series by rounding off the inconvenient numbers in the basic series and adjusting for linear measurement in millimeters. These series are shown in Table 2. After taking all normal considerations into account, it is recommended that (a) for ranges of values of the primary functional characteristics (outputs and capacities) of a series of
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition BRITISH STANDARD PREFERRED SIZES
691
products, the preferred number series R5 to R40 (see page 689) should be used, and (b) whenever linear sizes are concerned, the preferred sizes as given in the following table should be used. The presentation of preferred sizes gives designers and users a logical selection and the benefits of rational variety reduction. The second-choice size given should only be used when it is not possible to use the first choice, and the third choice should be applied only if a size from the second choice cannot be selected. With this procedure, common usage will tend to be concentrated on a limited range of sizes, and a contribution is thus made to variety reduction. However, the decision to use a particular size cannot be taken on the basis that one is first choice and the other not. Account must be taken of the effect on the design, the availability of tools, and other relevant factors. Table 2. British Standard Preferred Sizes, PD 6481: 1977 (1983) Choice 1st
2nd
Choice 3rd
1st
2nd
1
1st
2nd
5.2 1.1
5.5
1.2
5.8 1.3 1.4
6.2 1.5
6.5
9
2.2
2.6
14 3.2 3.5
15
3.8
17
4 4.5
20
95
56
110
21 22
250 165 168 172 175
112 115
275 280
178
285
180
290
118 120
265 270
108
64
255 260
170
58 62
245
162
102 105
235 240
160
100
60
4.8
152 158
98
54
225 230
155
55
19
148
88
52
215 220
150
92
18 4.2
142
90
48
205 210
145
42
16
198 200
140
82
50
192 195
135
80
46
188
132
76
3rd
190
138
45 13
2nd
128
85 44
1st
130
38
12
2.8 3
125
78
10
Choice 3rd 122
74
35
9.5
2nd
75
40
11
1st
72
32
8.5
2.4
70
36
2
2.5
26
Choice 3rd 66
28
8
2.1
65
34 7.5
1.9
23 24
2nd
68
7
1.8
1st
30 6.8
1.7
Choice 3rd
25
6
1.6
5
Choice 3rd
182 185
295 300
For dimensions above 300, each series continues in a similar manner, i.e., the intervals between each series number are the same as between 200 and 300.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 692
MEASURING INSTRUMENTS
MEASURING INSTRUMENTS AND INSPECTION METHODS Verniers and Micrometers Reading a Vernier.—A general rule for taking readings with a vernier scale is as follows: Note the number of inches and sub-divisions of an inch that the zero mark of the vernier scale has moved along the true scale, and then add to this reading as many thousandths, or hundredths, or whatever fractional part of an inch the vernier reads to, as there are spaces between the vernier zero and that line on the vernier which coincides with one on the true scale. For example, if the zero line of a vernier which reads to thousandths is slightly beyond the 0.5 inch division on the main or true scale, as shown in Fig. 1, and graduation line 10 on the vernier exactly coincides with one on the true scale, the reading is 0.5 + 0.010 or 0.510 inch. In order to determine the reading or fractional part of an inch that can be obtained by a vernier, multiply the denominator of the finest sub-division given on the true scale by the total number of divisions on the vernier. For example, if one inch on the true scale is divided into 40 parts or fortieths (as in Fig. 1), and the vernier into twenty-five parts, the vernier will read to thousandths of an inch, as 25 × 40 = 1000. Similarly, if there are sixteen divisions to the inch on the true scale and a total of eight on the vernier, the latter will enable readings to be taken within one-hundred-twenty-eighths of an inch, as 8 × 16 = 128.
Fig. 1.
Fig. 2.
If the vernier is on a protractor, note the whole number of degrees passed by the vernier zero mark and then count the spaces between the vernier zero and that line which coincides with a graduation on the protractor scale. If the vernier indicates angles within five minutes or one-twelfth degree (as in Fig. 2), the number of spaces multiplied by 5 will, of course, give the number of minutes to be added to the whole number of degrees. The reading of the protractor set as illustrated would be 14 whole degrees (the number passed by the zero mark on the vernier) plus 30 minutes, as the graduation 30 on the vernier is the only one to
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MEASURING INSTRUMENTS
693
the right of the vernier zero which exactly coincides with a line on the protractor scale. It will be noted that there are duplicate scales on the vernier, one being to the right and the other to the left of zero. The left-hand scale is used when the vernier zero is moved to the left of the zero of the protractor scale, whereas the right-hand graduations are used when the movement is to the right. Reading a Metric Vernier.—The smallest graduation on the bar (true or main scale) of the metric vernier gage shown in Fig. 1, is 0.5 millimeter. The scale is numbered at each twentieth division, and thus increments of 10, 20, 30, 40 millimeters, etc., are indicated. There are 25 divisions on the vernier scale, occupying the same length as 24 divisions on the bar, which is 12 millimeters. Therefore, one division on the vernier scale equals one twenty-fifth of 12 millimeters = 0.04 × 12 = 0.48 millimeter. Thus, the difference between one bar division (0.50 mm) and one vernier division (2.48 mm) is 0.50 − 0.48 = 0.02 millimeter, which is the minimum measuring increment that the gage provides. To permit direct readings, the vernier scale has graduations to represent tenths of a millimeter (0.1 mm) and fiftieths of a millimeter (0.02 mm).
Fig. 1.
To read a vernier gage, first note how many millimeters the zero line on the vernier is from the zero line on the bar. Next, find the graduation on the vernier scale which exactly coincides with a graduation line on the bar, and note the value of the vernier scale graduation. This value is added to the value obtained from the bar, and the result is the total reading. In the example shown in Fig. 1, the vernier zero is just past the 40.5 millimeters graduation on the bar. The 0.18 millimeter line on the vernier coincides with a line on the bar, and the total reading is therefore 40.5 + 0.18 = 40.68 mm. Dual Metric-Inch Vernier.—The vernier gage shown in Fig. 2 has separate metric and inch 50-division vernier scales to permit measurements in either system. A 50-division vernier has more widely spaced graduations than the 25-division vernier shown on the previous pages, and is thus easier to read. On the bar, the smallest metric graduation is 1 millimeter, and the 50 divisions of the vernier occupy the same length as 49 divisions on the bar, which is 49 mm. Therefore, one division on the vernier scale equals one-fiftieth of 49 millimeters = 0.02 × 49 = 0.98 mm. Thus, the difference between one bar division (1.0 mm) and one vernier division (0.98 mm) is 0.02 mm, which is the minimum measuring increment the gage provides. The vernier scale is graduated for direct reading to 0.02 mm. In the figure, the vernier zero is just past the 27 mm graduation on the bar, and the 0.42 mm graduation on the vernier coincides with a line on the bar. The total reading is therefore 27.42 mm. The smallest inch graduation on the bar is 0.05 inch, and the 50 vernier divisions occupy the same length as 49 bar divisions, which is 2.45 inches. Therefore, one vernier division
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Machinery's Handbook 27th Edition 694
MEASURING INSTRUMENTS
equals one-fiftieth of 2.45 inches = 0.02 × 2.45 = 0.049 inch. Thus, the difference between the length of a bar division and a vernier division is 0.050-0.049 = 0.001 inch. The vernier scale is graduated for direct reading to 0.001 inch. In the example, the vernier zero is past the 1.05 graduation on the bar, and the 0.029 graduation on the vernier coincides with a line on the bar. Thus, the total reading is 1.079 inches.
Fig. 2.
Reading a Micrometer.—The spindle of an inch-system micrometer has 40 threads per inch, so that one turn moves the spindle axially 0.025 inch (1 ÷ 40 = 0.025), equal to the distance between two graduations on the frame. The 25 graduations on the thimble allow the 0.025 inch to be further divided, so that turning the thimble through one division moves the spindle axially 0.001 inch (0.025 ÷ 25 = 0.001). To read a micrometer, count the number of whole divisions that are visible on the scale of the frame, multiply this number by 25 (the number of thousandths of an inch that each division represents) and add to the product the number of that division on the thimble which coincides with the axial zero line on the frame. The result will be the diameter expressed in thousandths of an inch. As the numbers 1, 2, 3, etc., opposite every fourth sub-division on the frame, indicate hundreds of thousandths, the reading can easily be taken mentally. Suppose the thimble were screwed out so that graduation 2, and three additional sub-divisions, were visible (as shown in Fig. 3), and that graduation 10 on the thimble coincided with the axial line on the frame. The reading then would be 0.200 + 0.075 + 0.010, or 0.285 inch.
Fig. 3. Inch Micrometer
Fig. 4. Inch Micrometer with Vernier
Some micrometers have a vernier scale on the frame in addition to the regular graduations, so that measurements within 0.0001 part of an inch can be taken. Micrometers of this type are read as follows: First determine the number of thousandths, as with an ordinary micrometer, and then find a line on the vernier scale that exactly coincides with one on the thimble; the number of this line represents the number of ten-thousandths to be added to the number of thousandths obtained by the regular graduations. The reading shown in the illustration, Fig. 4, is 0.270 + 0.0003 = 0.2703 inch.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SINE-BAR
695
Micrometers graduated according to the English system of measurement ordinarily have a table of decimal equivalents stamped on the sides of the frame, so that fractions such as sixty-fourths, thirty-seconds, etc., can readily be converted into decimals. Reading a Metric Micrometer.—The spindle of an ordinary metric micrometer has 2 threads per millimeter, and thus one complete revolution moves the spindle through a distance of 0.5 millimeter. The longitudinal line on the frame is graduated with 1 millimeter divisions and 0.5 millimeter sub-divisions. The thimble has 50 graduations, each being 0.01 millimeter (one-hundredth of a millimeter). To read a metric micrometer, note the number of millimeter divisions visible on the scale of the sleeve, and add the total to the particular division on the thimble which coincides with the axial line on the sleeve. Suppose that the thimble were screwed out so that graduation 5, and one additional 0.5 sub-division were visible (as shown in Fig. 5), and that graduation 28 on the thimble coincided with the axial line on the sleeve. The reading then would be 5.00 + 0.5 + 0.28 = 5.78 mm. Some micrometers are provided with a vernier scale on the sleeve in addition to the regular graduations to permit measurements within 0.002 millimeter to be made. Micrometers of this type are read as follows: First determine the number of whole millimeters (if any) and the number of hundredths of a millimeter, as with an ordinary micrometer, and then find a line on the sleeve vernier scale which exactly coincides
Fig. 5. Metric Micrometer
with one on the thimble. The number of this coinciding vernier line represents the number of two-thousandths of a millimeter to be added to the reading already obtained. Thus, for example, a measurement of 2.958 millimeters would be obtained by reading 2.5 millimeters on the sleeve, adding 0.45 millimeter read from the thimble, and then adding 0.008 millimeter as determined by the vernier. Note: 0.01 millimeter = 0.000393 inch, and 0.002 millimeter = 0.000078 inch (78 millionths). Therefore, metric micrometers provide smaller measuring increments than comparable inch unit micrometers—the smallest graduation of an ordinary inch reading micrometer is 0.001 inch; the vernier type has graduations down to 0.0001 inch. When using either a metric or inch micrometer, without a vernier, smaller readings than those graduated may of course be obtained by visual interpolation between graduations. Sine-bar The sine-bar is used either for very accurate angular measurements or for locating work at a given angle as, for example, in surface grinding templets, gages, etc. The sine-bar is especially useful in measuring or checking angles when the limit of accuracy is 5 minutes or less. Some bevel protractors are equipped with verniers which read to 5 minutes but the setting depends upon the alignment of graduations whereas a sine-bar usually is located by positive contact with precision gage-blocks selected for whatever dimension is required for obtaining a given angle. Types of Sine-bars.—A sine-bar consists of a hardened, ground and lapped steel bar with very accurate cylindrical plugs of equal diameter attached to or near each end. The form illustrated by Fig. 3 has notched ends for receiving the cylindrical plugs so that they are held firmly against both faces of the notch. The standard center-to-center distance C between the plugs is either 5 or 10 inches. The upper and lower sides of sine-bars are parallel to the center line of the plugs within very close limits. The body of the sine-bar ordi-
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 696
SINE-BAR
narily has several through holes to reduce the weight. In the making of the sine-bar shown in Fig. 4, if too much material is removed from one locating notch, regrinding the shoulder at the opposite end would make it possible to obtain the correct center distance. That is the reason for this change in form. The type of sine-bar illustrated by Fig. 5 has the cylindrical disks or plugs attached to one side. These differences in form or arrangement do not, of course, affect the principle governing the use of the sine-bar. An accurate surface plate or master flat is always used in conjunction with a sine-bar in order to form the base from which the vertical measurements are made.
Fig. 1.
Fig. 2.
Fig. 3.
Fig. 4.
Setting a Sine-bar to a Given Angle.—To find the vertical distance H, for setting a sinebar to the required angle, convert the angle to decimal form on a pocket calculator, take the sine of that angle, and multiply by the distance between the cylinders. For example, if an angle of 31 degrees, 30 minutes is required, the equivalent angle is 31 degrees plus 30⁄60 = 31 + 0.5, or 31.5 degrees. (For conversions from minutes and seconds to decimals of degrees and vice versa, see page 96). The sine of 31.5 degrees is 0.5225 and multiplying this value by the sine-bar length gives 2.613 in. for the height H, Fig. 1 and 3, of the gage blocks. Finding Angle when Height H of Sine-bar is Known.—To find the angle equivalent to a given height H, reverse the above procedure. Thus, if the height H is 1.4061 in., dividing by 5 gives a sine of 0.28122, which corresponds to an angle of 16.333 degrees, or 16 degrees 20 minutes. Checking Angle of Templet or Gage by Using Sine-bar.—Place templet or gage on sine-bar as indicated by dotted lines, Fig. 1. Clamps may be used to hold work in place. Place upper end of sine-bar on gage blocks having total height H corresponding to the required angle. If upper edge D of work is parallel with surface plate E, then angle A of work equals angle A to which sine-bar is set. Parallelism between edge D and surface plate may be tested by checking the height at each end with a dial gage or some type of indicating comparator. Measuring Angle of Templet or Gage with Sine-bar.—To measure such an angle, adjust height of gage blocks and sine-bar until edge D, Fig. 1, is parallel with surface plate E; then find angle corresponding to height H, of gage blocks. For example, if height H is
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SINE-BAR
697
2.5939 inches when D and E are parallel, the calculator will show that the angle A of the work is 31 degrees, 15 minutes. Checking Taper per Foot with Sine-bar.—As an example, assume that the plug gage in Fig. 2 is supposed to have a taper of 61⁄8 inches per foot and taper is to be checked by using a 5-inch sine-bar. The table of Tapers per Foot and Corresponding Angles on page 714 shows that the included angle for a taper of 6 1⁄8 inches per foot is 28 degrees 38 minutes 1 second, or 28.6336 degrees from the calculator. For a 5-inch sine-bar, the calculator gives a value of 2.396 inch for the height H of the gage blocks. Using this height, if the upper surface F of the plug gage is parallel to the surface plate the angle corresponds to a taper of 6 1⁄8 inches per foot. Setting Sine-bar having Plugs Attached to Side.—If the lower plug does not rest directly on the surface plate, as in Fig. 3, the height H for the sine-bar is the difference between heights x and y, or the difference between the heights of the plugs; otherwise, the procedure in setting the sine-bar and checking angles is the same as previously described. Checking Templets Having Two Angles.—Assume that angle a of templet, Fig. 4, is 9 degrees, angle b 12 degrees, and that edge G is parallel to the surface plate. For an angle b of 12 degrees, the calculator shows that the height H is 1.03956 inches. For an angle a of 9 degrees, the difference between measurements x and y when the sine-bar is in contact with the upper edge of the templet is 0.78217 inch. Using Sine-bar Tables to Set 5-inch and 100-mm Sine-bars to Given Angle.—T h e table starting on page page 699 gives constants for a 5-inch sine-bar, and starting on page 706 are given constants for a 100-mm sine-bar. These constants represent the vertical height H for setting a sine-bar of the corresponding length to the required angle. Using Sine-bar Tables with Sine-bars of Other Lengths.—A sine-bar may sometimes be preferred that is longer (or shorter) than that given in available tables because of its longer working surface or because the longer center distance is conducive to greater precision. To use the sine-bar tables with a sine-bar of another length to obtain the vertical distances H, multiply the value obtained from the table by the fraction (length of sine-bar used ÷ length of sine-bar specified in table). Example: Use the 5-inch sine-bar table to obtain the vertical height H for setting a 10inch sine-bar to an angle of 39°. The sine of 39 degrees is 0.62932, hence the vertical height H for setting a 10-inch sine-bar is 6.2932 inches. Solution: The height H given for 39° in the 5-inch sine-bar table (page 703) is 3.14660. The corresponding height for a 10-inch sine-bar is 10⁄5 × 3.14660 = 6.2932 inches. Using a Calculator to Determine Sine-bar Constants for a Given Angle.—T h e c o n stant required to set a given angle for a sine-bar of any length can be quickly determined by using a scientific calculator. The required formaulas are as follows: a) angle A given in degrees and calculator is set to measure angles in radian
π ⎞ H = L × sin ⎛ A × -------⎝ 180⎠
or
a) angle A is given in radian, or b) angle A is given in degrees and calculator is set to measure angles in degrees
H = L × sin ( A )
where L =length of the sine-bar A =angle to which the sine-bar is to be set H = vertical height to which one end of sine-bar must be set to obtain angle A π = 3.141592654 In the previous formulas, the height H and length L must be given in the same units, but may be in either metric or US units. Thus, if L is given in mm, then H is in mm; and, if L is given in inches, then H is in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 698
TAPERS
Measuring Tapers with Vee-block and Sine-bar.—The taper on a conical part may be checked or found by placing the part in a vee-block which rests on the surface of a sineplate or sine-bar as shown in the accompanying diagram. The advantage of this method is that the axis of the vee-block may be aligned with the sides of the sine-bar. Thus when the tapered part is placed in the vee-block it will be aligned perpendicular to the transverse axis of the sine-bar.
The sine-bar is set to angle B = (C + A/2) where A/2 is one-half the included angle of the tapered part. If D is the included angle of the precision vee-block, the angle C is calculated from the formula: sin ( A ⁄ 2 )sin C = ----------------------sin ( D ⁄ 2 ) If dial indicator readings show no change across all points along the top of the taper surface, then this checks that the angle A of the taper is correct. If the indicator readings vary, proceed as follows to find the actual angle of taper: 1) Adjust the angle of the sine-bar until the indicator reading is constant. Then find the new angle B′ as explained in the paragraph Measuring Angle of Templet or Gage with Sine-bar on page 696; and 2) Using the angle B′ calculate the actual half-angle A′/2 of the taper from the formula:. ′ sin B ′ tan A ----- = --------------------------------2 D csc ---- + cos B ′ 2 The taper per foot corresponding to certain half-angles of taper may be found in the table on page 714. Dimensioning Tapers.—At least three methods of dimensioning tapers are in use. Standard Tapers: Give one diameter or width, the length, and insert note on drawing designating the taper by number. Special Tapers: In dimensioning a taper when the slope is specified, the length and only one diameter should be given or the diameters at both ends of the taper should be given and length omitted. Precision Work: In certain cases where very precise measurements are necessary the taper surface, either external or internal, is specified by giving a diameter at a certain distance from a surface and the slope of the taper.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 5-INCH SINE-BAR CONSTANTS
699
Constants for 5-inch Sine-bar Constants for Setting a 5-inch Sine-bar for 1° to 7° Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
0° 0.00000 0.00145 0.00291 0.00436 0.00582 0.00727 0.00873 0.01018 0.01164 0.01309 0.01454 0.01600 0.01745 0.01891 0.02036 0.02182 0.02327 0.02473 0.02618 0.02763 0.02909 0.03054 0.03200 0.03345 0.03491 0.03636 0.03782 0.03927 0.04072 0.04218 0.04363 0.04509 0.04654 0.04800 0.04945 0.05090 0.05236 0.05381 0.05527 0.05672 0.05818 0.05963 0.06109 0.06254 0.06399 0.06545 0.06690 0.06836 0.06981 0.07127 0.07272 0.07417 0.07563 0.07708 0.07854 0.07999 0.08145 0.08290 0.08435 0.08581 0.08726
1° 0.08726 0.08872 0.09017 0.09162 0.09308 0.09453 0.09599 0.09744 0.09890 0.10035 0.10180 0.10326 0.10471 0.10617 0.10762 0.10907 0.11053 0.11198 0.11344 0.11489 0.11634 0.11780 0.11925 0.12071 0.12216 0.12361 0.12507 0.12652 0.12798 0.12943 0.13088 0.13234 0.13379 0.13525 0.13670 0.13815 0.13961 0.14106 0.14252 0.14397 0.14542 0.14688 0.14833 0.14979 0.15124 0.15269 0.15415 0.15560 0.15705 0.15851 0.15996 0.16141 0.16287 0.16432 0.16578 0.16723 0.16868 0.17014 0.17159 0.17304 0.17450
2° 0.17450 0.17595 0.17740 0.17886 0.18031 0.18177 0.18322 0.18467 0.18613 0.18758 0.18903 0.19049 0.19194 0.19339 0.19485 0.19630 0.19775 0.19921 0.20066 0.20211 0.20357 0.20502 0.20647 0.20793 0.20938 0.21083 0.21228 0.21374 0.21519 0.21664 0.21810 0.21955 0.22100 0.22246 0.22391 0.22536 0.22681 0.22827 0.22972 0.23117 0.23263 0.23408 0.23553 0.23699 0.23844 0.23989 0.24134 0.24280 0.24425 0.24570 0.24715 0.24861 0.25006 0.25151 0.25296 0.25442 0.25587 0.25732 0.25877 0.26023 0.26168
3° 0.26168 0.26313 0.26458 0.26604 0.26749 0.26894 0.27039 0.27185 0.27330 0.27475 0.27620 0.27766 0.27911 0.28056 0.28201 0.28346 0.28492 0.28637 0.28782 0.28927 0.29072 0.29218 0.29363 0.29508 0.29653 0.29798 0.29944 0.30089 0.30234 0.30379 0.30524 0.30669 0.30815 0.30960 0.31105 0.31250 0.31395 0.31540 0.31686 0.31831 0.31976 0.32121 0.32266 0.32411 0.32556 0.32702 0.32847 0.32992 0.33137 0.33282 0.33427 0.33572 0.33717 0.33863 0.34008 0.34153 0.34298 0.34443 0.34588 0.34733 0.34878
4° 0.34878 0.35023 0.35168 0.35313 0.35459 0.35604 0.35749 0.35894 0.36039 0.36184 0.36329 0.36474 0.36619 0.36764 0.36909 0.37054 0.37199 0.37344 0.37489 0.37634 0.37779 0.37924 0.38069 0.38214 0.38360 0.38505 0.38650 0.38795 0.38940 0.39085 0.39230 0.39375 0.39520 0.39665 0.39810 0.39954 0.40099 0.40244 0.40389 0.40534 0.40679 0.40824 0.40969 0.41114 0.41259 0.41404 0.41549 0.41694 0.41839 0.41984 0.42129 0.42274 0.42419 0.42564 0.42708 0.42853 0.42998 0.43143 0.43288 0.43433 0.43578
5° 0.43578 0.43723 0.43868 0.44013 0.44157 0.44302 0.44447 0.44592 0.44737 0.44882 0.45027 0.45171 0.45316 0.45461 0.45606 0.45751 0.45896 0.46040 0.46185 0.46330 0.46475 0.46620 0.46765 0.46909 0.47054 0.47199 0.47344 0.47489 0.47633 0.47778 0.47923 0.48068 0.48212 0.48357 0.48502 0.48647 0.48791 0.48936 0.49081 0.49226 0.49370 0.49515 0.49660 0.49805 0.49949 0.50094 0.50239 0.50383 0.50528 0.50673 0.50818 0.50962 0.51107 0.51252 0.51396 0.51541 0.51686 0.51830 0.51975 0.52120 0.52264
6° 0.52264 0.52409 0.52554 0.52698 0.52843 0.52987 0.53132 0.53277 0.53421 0.53566 0.53710 0.53855 0.54000 0.54144 0.54289 0.54433 0.54578 0.54723 0.54867 0.55012 0.55156 0.55301 0.55445 0.55590 0.55734 0.55879 0.56024 0.56168 0.56313 0.56457 0.56602 0.56746 0.56891 0.57035 0.57180 0.57324 0.57469 0.57613 0.57758 0.57902 0.58046 0.58191 0.58335 0.58480 0.58624 0.58769 0.58913 0.59058 0.59202 0.59346 0.59491 0.59635 0.59780 0.59924 0.60068 0.60213 0.60357 0.60502 0.60646 0.60790 0.60935
Copyright 2004, Industrial Press, Inc., New York, NY
7° 0.60935 0.61079 0.61223 0.61368 0.61512 0.61656 0.61801 0.61945 0.62089 0.62234 0.62378 0.62522 0.62667 0.62811 0.62955 0.63099 0.63244 0.63388 0.63532 0.63677 0.63821 0.63965 0.64109 0.64254 0.64398 0.64542 0.64686 0.64830 0.64975 0.65119 0.65263 0.65407 0.65551 0.65696 0.65840 0.65984 0.66128 0.66272 0.66417 0.66561 0.66705 0.66849 0.66993 0.67137 0.67281 0.67425 0.67570 0.67714 0.67858 0.68002 0.68146 0.68290 0.68434 0.68578 0.68722 0.68866 0.69010 0.69154 0.69298 0.69443 0.69587
Machinery's Handbook 27th Edition 700
5-INCH SINE-BAR CONSTANTS Constants for Setting a 5-inch Sine-bar for 8° to 15°
Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
8° 0.69587 0.69731 0.69875 0.70019 0.70163 0.70307 0.70451 0.70595 0.70739 0.70883 0.71027 0.71171 0.71314 0.71458 0.71602 0.71746 0.71890 0.72034 0.72178 0.72322 0.72466 0.72610 0.72754 0.72898 0.73042 0.73185 0.73329 0.73473 0.73617 0.73761 0.73905 0.74049 0.74192 0.74336 0.74480 0.74624 0.74768 0.74911 0.75055 0.75199 0.75343 0.75487 0.75630 0.75774 0.75918 0.76062 0.76205 0.76349 0.76493 0.76637 0.76780 0.76924 0.77068 0.77211 0.77355 0.77499 0.77643 0.77786 0.77930 0.78074 0.78217
9° 0.78217 0.78361 0.78505 0.78648 0.78792 0.78935 0.79079 0.79223 0.79366 0.79510 0.79653 0.79797 0.79941 0.80084 0.80228 0.80371 0.80515 0.80658 0.80802 0.80945 0.81089 0.81232 0.81376 0.81519 0.81663 0.81806 0.81950 0.82093 0.82237 0.82380 0.82524 0.82667 0.82811 0.82954 0.83098 0.83241 0.83384 0.83528 0.83671 0.83815 0.83958 0.84101 0.84245 0.84388 0.84531 0.84675 0.84818 0.84961 0.85105 0.85248 0.85391 0.85535 0.85678 0.85821 0.85965 0.86108 0.86251 0.86394 0.86538 0.86681 0.86824
10° 0.86824 0.86967 0.87111 0.87254 0.87397 0.87540 0.87683 0.87827 0.87970 0.88113 0.88256 0.88399 0.88542 0.88686 0.88829 0.88972 0.89115 0.89258 0.89401 0.89544 0.89687 0.89830 0.89973 0.90117 0.90260 0.90403 0.90546 0.90689 0.90832 0.90975 0.91118 0.91261 0.91404 0.91547 0.91690 0.91833 0.91976 0.92119 0.92262 0.92405 0.92547 0.92690 0.92833 0.92976 0.93119 0.93262 0.93405 0.93548 0.93691 0.93834 0.93976 0.94119 0.94262 0.94405 0.94548 0.94691 0.94833 0.94976 0.95119 0.95262 0.95404
11° 0.95404 0.95547 0.95690 0.95833 0.95976 0.96118 0.96261 0.96404 0.96546 0.96689 0.96832 0.96974 0.97117 0.97260 0.97403 0.97545 0.97688 0.97830 0.97973 0.98116 0.98258 0.98401 0.98544 0.98686 0.98829 0.98971 0.99114 0.99256 0.99399 0.99541 0.99684 0.99826 0.99969 1.00112 1.00254 1.00396 1.00539 1.00681 1.00824 1.00966 1.01109 1.01251 1.01394 1.01536 1.01678 1.01821 1.01963 1.02106 1.02248 1.02390 1.02533 1.02675 1.02817 1.02960 1.03102 1.03244 1.03387 1.03529 1.03671 1.03814 1.03956
12° 1.03956 1.04098 1.04240 1.04383 1.04525 1.04667 1.04809 1.04951 1.05094 1.05236 1.05378 1.05520 1.05662 1.05805 1.05947 1.06089 1.06231 1.06373 1.06515 1.06657 1.06799 1.06941 1.07084 1.07226 1.07368 1.07510 1.07652 1.07794 1.07936 1.08078 1.08220 1.08362 1.08504 1.08646 1.08788 1.08930 1.09072 1.09214 1.09355 1.09497 1.09639 1.09781 1.09923 1.10065 1.10207 1.10349 1.10491 1.10632 1.10774 1.10916 1.11058 1.11200 1.11342 1.11483 1.11625 1.11767 1.11909 1.12050 1.12192 1.12334 1.12476
13° 1.12476 1.12617 1.12759 1.12901 1.13042 1.13184 1.13326 1.13467 1.13609 1.13751 1.13892 1.14034 1.14175 1.14317 1.14459 1.14600 1.14742 1.14883 1.15025 1.15166 1.15308 1.15449 1.15591 1.15732 1.15874 1.16015 1.16157 1.16298 1.16440 1.16581 1.16723 1.16864 1.17006 1.17147 1.17288 1.17430 1.17571 1.17712 1.17854 1.17995 1.18136 1.18278 1.18419 1.18560 1.18702 1.18843 1.18984 1.19125 1.19267 1.19408 1.19549 1.19690 1.19832 1.19973 1.20114 1.20255 1.20396 1.20538 1.20679 1.20820 1.20961
14° 1.20961 1.21102 1.21243 1.21384 1.21525 1.21666 1.21808 1.21949 1.22090 1.22231 1.22372 1.22513 1.22654 1.22795 1.22936 1.23077 1.23218 1.23359 1.23500 1.23640 1.23781 1.23922 1.24063 1.24204 1.24345 1.24486 1.24627 1.24768 1.24908 1.25049 1.25190 1.25331 1.25472 1.25612 1.25753 1.25894 1.26035 1.26175 1.26316 1.26457 1.26598 1.26738 1.26879 1.27020 1.27160 1.27301 1.27442 1.27582 1.27723 1.27863 1.28004 1.28145 1.28285 1.28426 1.28566 1.28707 1.28847 1.28988 1.29129 1.29269 1.29410
Copyright 2004, Industrial Press, Inc., New York, NY
15° 1.29410 1.29550 1.29690 1.29831 1.29971 1.30112 1.30252 1.30393 1.30533 1.30673 1.30814 1.30954 1.31095 1.31235 1.31375 1.31516 1.31656 1.31796 1.31937 1.32077 1.32217 1.32357 1.32498 1.32638 1.32778 1.32918 1.33058 1.33199 1.33339 1.33479 1.33619 1.33759 1.33899 1.34040 1.34180 1.34320 1.34460 1.34600 1.34740 1.34880 1.35020 1.35160 1.35300 1.35440 1.35580 1.35720 1.35860 1.36000 1.36140 1.36280 1.36420 1.36560 1.36700 1.36840 1.36980 1.37119 1.37259 1.37399 1.37539 1.37679 1.37819
Machinery's Handbook 27th Edition 5-INCH SINE-BAR CONSTANTS
701
Constants for Setting a 5-inch Sine-bar for 16° to 23° Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
16° 1.37819 1.37958 1.38098 1.38238 1.38378 1.38518 1.38657 1.38797 1.38937 1.39076 1.39216 1.39356 1.39496 1.39635 1.39775 1.39915 1.40054 1.40194 1.40333 1.40473 1.40613 1.40752 1.40892 1.41031 1.41171 1.41310 1.41450 1.41589 1.41729 1.41868 1.42008 1.42147 1.42287 1.42426 1.42565 1.42705 1.42844 1.42984 1.43123 1.43262 1.43402 1.43541 1.43680 1.43820 1.43959 1.44098 1.44237 1.44377 1.44516 1.44655 1.44794 1.44934 1.45073 1.45212 1.45351 1.45490 1.45629 1.45769 1.45908 1.46047 1.46186
17° 1.46186 1.46325 1.46464 1.46603 1.46742 1.46881 1.47020 1.47159 1.47298 1.47437 1.47576 1.47715 1.47854 1.47993 1.48132 1.48271 1.48410 1.48549 1.48687 1.48826 1.48965 1.49104 1.49243 1.49382 1.49520 1.49659 1.49798 1.49937 1.50075 1.50214 1.50353 1.50492 1.50630 1.50769 1.50908 1.51046 1.51185 1.51324 1.51462 1.51601 1.51739 1.51878 1.52017 1.52155 1.52294 1.52432 1.52571 1.52709 1.52848 1.52986 1.53125 1.53263 1.53401 1.53540 1.53678 1.53817 1.53955 1.54093 1.54232 1.54370 1.54509
18° 1.54509 1.54647 1.54785 1.54923 1.55062 1.55200 1.55338 1.55476 1.55615 1.55753 1.55891 1.56029 1.56167 1.56306 1.56444 1.56582 1.56720 1.56858 1.56996 1.57134 1.57272 1.57410 1.57548 1.57687 1.57825 1.57963 1.58101 1.58238 1.58376 1.58514 1.58652 1.58790 1.58928 1.59066 1.59204 1.59342 1.59480 1.59617 1.59755 1.59893 1.60031 1.60169 1.60307 1.60444 1.60582 1.60720 1.60857 1.60995 1.61133 1.61271 1.61408 1.61546 1.61683 1.61821 1.61959 1.62096 1.62234 1.62371 1.62509 1.62647 1.62784
19° 1.62784 1.62922 1.63059 1.63197 1.63334 1.63472 1.63609 1.63746 1.63884 1.64021 1.64159 1.64296 1.64433 1.64571 1.64708 1.64845 1.64983 1.65120 1.65257 1.65394 1.65532 1.65669 1.65806 1.65943 1.66081 1.66218 1.66355 1.66492 1.66629 1.66766 1.66903 1.67041 1.67178 1.67315 1.67452 1.67589 1.67726 1.67863 1.68000 1.68137 1.68274 1.68411 1.68548 1.68685 1.68821 1.68958 1.69095 1.69232 1.69369 1.69506 1.69643 1.69779 1.69916 1.70053 1.70190 1.70327 1.70463 1.70600 1.70737 1.70873 1.71010
20° 1.71010 1.71147 1.71283 1.71420 1.71557 1.71693 1.71830 1.71966 1.72103 1.72240 1.72376 1.72513 1.72649 1.72786 1.72922 1.73059 1.73195 1.73331 1.73468 1.73604 1.73741 1.73877 1.74013 1.74150 1.74286 1.74422 1.74559 1.74695 1.74831 1.74967 1.75104 1.75240 1.75376 1.75512 1.75649 1.75785 1.75921 1.76057 1.76193 1.76329 1.76465 1.76601 1.76737 1.76873 1.77010 1.77146 1.77282 1.77418 1.77553 1.77689 1.77825 1.77961 1.78097 1.78233 1.78369 1.78505 1.78641 1.78777 1.78912 1.79048 1.79184
21° 1.79184 1.79320 1.79456 1.79591 1.79727 1.79863 1.79998 1.80134 1.80270 1.80405 1.80541 1.80677 1.80812 1.80948 1.81083 1.81219 1.81355 1.81490 1.81626 1.81761 1.81897 1.82032 1.82168 1.82303 1.82438 1.82574 1.82709 1.82845 1.82980 1.83115 1.83251 1.83386 1.83521 1.83657 1.83792 1.83927 1.84062 1.84198 1.84333 1.84468 1.84603 1.84738 1.84873 1.85009 1.85144 1.85279 1.85414 1.85549 1.85684 1.85819 1.85954 1.86089 1.86224 1.86359 1.86494 1.86629 1.86764 1.86899 1.87034 1.87168 1.87303
22° 1.87303 1.87438 1.87573 1.87708 1.87843 1.87977 1.88112 1.88247 1.88382 1.88516 1.88651 1.88786 1.88920 1.89055 1.89190 1.89324 1.89459 1.89594 1.89728 1.89863 1.89997 1.90132 1.90266 1.90401 1.90535 1.90670 1.90804 1.90939 1.91073 1.91207 1.91342 1.91476 1.91610 1.91745 1.91879 1.92013 1.92148 1.92282 1.92416 1.92550 1.92685 1.92819 1.92953 1.93087 1.93221 1.93355 1.93490 1.93624 1.93758 1.93892 1.94026 1.94160 1.94294 1.94428 1.94562 1.94696 1.94830 1.94964 1.95098 1.95232 1.95366
Copyright 2004, Industrial Press, Inc., New York, NY
23° 1.95366 1.95499 1.95633 1.95767 1.95901 1.96035 1.96169 1.96302 1.96436 1.96570 1.96704 1.96837 1.96971 1.97105 1.97238 1.97372 1.97506 1.97639 1.97773 1.97906 1.98040 1.98173 1.98307 1.98440 1.98574 1.98707 1.98841 1.98974 1.99108 1.99241 1.99375 1.99508 1.99641 1.99775 1.99908 2.00041 2.00175 2.00308 2.00441 2.00574 2.00708 2.00841 2.00974 2.01107 2.01240 2.01373 2.01506 2.01640 2.01773 2.01906 2.02039 2.02172 2.02305 2.02438 2.02571 2.02704 2.02837 2.02970 2.03103 2.03235 2.03368
Machinery's Handbook 27th Edition 702
5-INCH SINE-BAR CONSTANTS Constants for Setting a 5-inch Sine-bar for 24° to 31°
Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
24° 2.03368 2.03501 2.03634 2.03767 2.03900 2.04032 2.04165 2.04298 2.04431 2.04563 2.04696 2.04829 2.04962 2.05094 2.05227 2.05359 2.05492 2.05625 2.05757 2.05890 2.06022 2.06155 2.06287 2.06420 2.06552 2.06685 2.06817 2.06950 2.07082 2.07214 2.07347 2.07479 2.07611 2.07744 2.07876 2.08008 2.08140 2.08273 2.08405 2.08537 2.08669 2.08801 2.08934 2.09066 2.09198 2.09330 2.09462 2.09594 2.09726 2.09858 2.09990 2.10122 2.10254 2.10386 2.10518 2.10650 2.10782 2.10914 2.11045 2.11177 2.11309
25° 2.11309 2.11441 2.11573 2.11704 2.11836 2.11968 2.12100 2.12231 2.12363 2.12495 2.12626 2.12758 2.12890 2.13021 2.13153 2.13284 2.13416 2.13547 2.13679 2.13810 2.13942 2.14073 2.14205 2.14336 2.14468 2.14599 2.14730 2.14862 2.14993 2.15124 2.15256 2.15387 2.15518 2.15649 2.15781 2.15912 2.16043 2.16174 2.16305 2.16436 2.16567 2.16698 2.16830 2.16961 2.17092 2.17223 2.17354 2.17485 2.17616 2.17746 2.17877 2.18008 2.18139 2.18270 2.18401 2.18532 2.18663 2.18793 2.18924 2.19055 2.19186
26° 2.19186 2.19316 2.19447 2.19578 2.19708 2.19839 2.19970 2.20100 2.20231 2.20361 2.20492 2.20622 2.20753 2.20883 2.21014 2.21144 2.21275 2.21405 2.21536 2.21666 2.21796 2.21927 2.22057 2.22187 2.22318 2.22448 2.22578 2.22708 2.22839 2.22969 2.23099 2.23229 2.23359 2.23489 2.23619 2.23749 2.23880 2.24010 2.24140 2.24270 2.24400 2.24530 2.24660 2.24789 2.24919 2.25049 2.25179 2.25309 2.25439 2.25569 2.25698 2.25828 2.25958 2.26088 2.26217 2.26347 2.26477 2.26606 2.26736 2.26866 2.26995
27° 2.26995 2.27125 2.27254 2.27384 2.27513 2.27643 2.27772 2.27902 2.28031 2.28161 2.28290 2.28420 2.28549 2.28678 2.28808 2.28937 2.29066 2.29196 2.29325 2.29454 2.29583 2.29712 2.29842 2.29971 2.30100 2.30229 2.30358 2.30487 2.30616 2.30745 2.30874 2.31003 2.31132 2.31261 2.31390 2.31519 2.31648 2.31777 2.31906 2.32035 2.32163 2.32292 2.32421 2.32550 2.32679 2.32807 2.32936 2.33065 2.33193 2.33322 2.33451 2.33579 2.33708 2.33836 2.33965 2.34093 2.34222 2.34350 2.34479 2.34607 2.34736
28° 2.34736 2.34864 2.34993 2.35121 2.35249 2.35378 2.35506 2.35634 2.35763 2.35891 2.36019 2.36147 2.36275 2.36404 2.36532 2.36660 2.36788 2.36916 2.37044 2.37172 2.37300 2.37428 2.37556 2.37684 2.37812 2.37940 2.38068 2.38196 2.38324 2.38452 2.38579 2.38707 2.38835 2.38963 2.39091 2.39218 2.39346 2.39474 2.39601 2.39729 2.39857 2.39984 2.40112 2.40239 2.40367 2.40494 2.40622 2.40749 2.40877 2.41004 2.41132 2.41259 2.41386 2.41514 2.41641 2.41769 2.41896 2.42023 2.42150 2.42278 2.42405
29° 2.42405 2.42532 2.42659 2.42786 2.42913 2.43041 2.43168 2.43295 2.43422 2.43549 2.43676 2.43803 2.43930 2.44057 2.44184 2.44311 2.44438 2.44564 2.44691 2.44818 2.44945 2.45072 2.45198 2.45325 2.45452 2.45579 2.45705 2.45832 2.45959 2.46085 2.46212 2.46338 2.46465 2.46591 2.46718 2.46844 2.46971 2.47097 2.47224 2.47350 2.47477 2.47603 2.47729 2.47856 2.47982 2.48108 2.48235 2.48361 2.48487 2.48613 2.48739 2.48866 2.48992 2.49118 2.49244 2.49370 2.49496 2.49622 2.49748 2.49874 2.50000
30° 2.50000 2.50126 2.50252 2.50378 2.50504 2.50630 2.50755 2.50881 2.51007 2.51133 2.51259 2.51384 2.51510 2.51636 2.51761 2.51887 2.52013 2.52138 2.52264 2.52389 2.52515 2.52640 2.52766 2.52891 2.53017 2.53142 2.53268 2.53393 2.53519 2.53644 2.53769 2.53894 2.54020 2.54145 2.54270 2.54396 2.54521 2.54646 2.54771 2.54896 2.55021 2.55146 2.55271 2.55397 2.55522 2.55647 2.55772 2.55896 2.56021 2.56146 2.56271 2.56396 2.56521 2.56646 2.56771 2.56895 2.57020 2.57145 2.57270 2.57394 2.57519
Copyright 2004, Industrial Press, Inc., New York, NY
31° 2.57519 2.57644 2.57768 2.57893 2.58018 2.58142 2.58267 2.58391 2.58516 2.58640 2.58765 2.58889 2.59014 2.59138 2.59262 2.59387 2.59511 2.59635 2.59760 2.59884 2.60008 2.60132 2.60256 2.60381 2.60505 2.60629 2.60753 2.60877 2.61001 2.61125 2.61249 2.61373 2.61497 2.61621 2.61745 2.61869 2.61993 2.62117 2.62241 2.62364 2.62488 2.62612 2.62736 2.62860 2.62983 2.63107 2.63231 2.63354 2.63478 2.63602 2.63725 2.63849 2.63972 2.64096 2.64219 2.64343 2.64466 2.64590 2.64713 2.64836 2.64960
Machinery's Handbook 27th Edition 5-INCH SINE-BAR CONSTANTS
703
Constants for Setting a 5-inch Sine-bar for 32° to 39° Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
32° 2.64960 2.65083 2.65206 2.65330 2.65453 2.65576 2.65699 2.65822 2.65946 2.66069 2.66192 2.66315 2.66438 2.66561 2.66684 2.66807 2.66930 2.67053 2.67176 2.67299 2.67422 2.67545 2.67668 2.67791 2.67913 2.68036 2.68159 2.68282 2.68404 2.68527 2.68650 2.68772 2.68895 2.69018 2.69140 2.69263 2.69385 2.69508 2.69630 2.69753 2.69875 2.69998 2.70120 2.70243 2.70365 2.70487 2.70610 2.70732 2.70854 2.70976 2.71099 2.71221 2.71343 2.71465 2.71587 2.71709 2.71831 2.71953 2.72076 2.72198 2.72320
33° 2.72320 2.72441 2.72563 2.72685 2.72807 2.72929 2.73051 2.73173 2.73295 2.73416 2.73538 2.73660 2.73782 2.73903 2.74025 2.74147 2.74268 2.74390 2.74511 2.74633 2.74754 2.74876 2.74997 2.75119 2.75240 2.75362 2.75483 2.75605 2.75726 2.75847 2.75969 2.76090 2.76211 2.76332 2.76453 2.76575 2.76696 2.76817 2.76938 2.77059 2.77180 2.77301 2.77422 2.77543 2.77664 2.77785 2.77906 2.78027 2.78148 2.78269 2.78389 2.78510 2.78631 2.78752 2.78873 2.78993 2.79114 2.79235 2.79355 2.79476 2.79596
34° 2.79596 2.79717 2.79838 2.79958 2.80079 2.80199 2.80319 2.80440 2.80560 2.80681 2.80801 2.80921 2.81042 2.81162 2.81282 2.81402 2.81523 2.81643 2.81763 2.81883 2.82003 2.82123 2.82243 2.82364 2.82484 2.82604 2.82723 2.82843 2.82963 2.83083 2.83203 2.83323 2.83443 2.83563 2.83682 2.83802 2.83922 2.84042 2.84161 2.84281 2.84401 2.84520 2.84640 2.84759 2.84879 2.84998 2.85118 2.85237 2.85357 2.85476 2.85596 2.85715 2.85834 2.85954 2.86073 2.86192 2.86311 2.86431 2.86550 2.86669 2.86788
35° 2.86788 2.86907 2.87026 2.87146 2.87265 2.87384 2.87503 2.87622 2.87741 2.87860 2.87978 2.88097 2.88216 2.88335 2.88454 2.88573 2.88691 2.88810 2.88929 2.89048 2.89166 2.89285 2.89403 2.89522 2.89641 2.89759 2.89878 2.89996 2.90115 2.90233 2.90351 2.90470 2.90588 2.90707 2.90825 2.90943 2.91061 2.91180 2.91298 2.91416 2.91534 2.91652 2.91771 2.91889 2.92007 2.92125 2.92243 2.92361 2.92479 2.92597 2.92715 2.92833 2.92950 2.93068 2.93186 2.93304 2.93422 2.93540 2.93657 2.93775 2.93893
36° 2.93893 2.94010 2.94128 2.94246 2.94363 2.94481 2.94598 2.94716 2.94833 2.94951 2.95068 2.95185 2.95303 2.95420 2.95538 2.95655 2.95772 2.95889 2.96007 2.96124 2.96241 2.96358 2.96475 2.96592 2.96709 2.96827 2.96944 2.97061 2.97178 2.97294 2.97411 2.97528 2.97645 2.97762 2.97879 2.97996 2.98112 2.98229 2.98346 2.98463 2.98579 2.98696 2.98813 2.98929 2.99046 2.99162 2.99279 2.99395 2.99512 2.99628 2.99745 2.99861 2.99977 3.00094 3.00210 3.00326 3.00443 3.00559 3.00675 3.00791 3.00908
37° 3.00908 3.01024 3.01140 3.01256 3.01372 3.01488 3.01604 3.01720 3.01836 3.01952 3.02068 3.02184 3.02300 3.02415 3.02531 3.02647 3.02763 3.02878 3.02994 3.03110 3.03226 3.03341 3.03457 3.03572 3.03688 3.03803 3.03919 3.04034 3.04150 3.04265 3.04381 3.04496 3.04611 3.04727 3.04842 3.04957 3.05073 3.05188 3.05303 3.05418 3.05533 3.05648 3.05764 3.05879 3.05994 3.06109 3.06224 3.06339 3.06454 3.06568 3.06683 3.06798 3.06913 3.07028 3.07143 3.07257 3.07372 3.07487 3.07601 3.07716 3.07831
38° 3.07831 3.07945 3.08060 3.08174 3.08289 3.08403 3.08518 3.08632 3.08747 3.08861 3.08976 3.09090 3.09204 3.09318 3.09433 3.09547 3.09661 3.09775 3.09890 3.10004 3.10118 3.10232 3.10346 3.10460 3.10574 3.10688 3.10802 3.10916 3.11030 3.11143 3.11257 3.11371 3.11485 3.11599 3.11712 3.11826 3.11940 3.12053 3.12167 3.12281 3.12394 3.12508 3.12621 3.12735 3.12848 3.12962 3.13075 3.13189 3.13302 3.13415 3.13529 3.13642 3.13755 3.13868 3.13982 3.14095 3.14208 3.14321 3.14434 3.14547 3.14660
Copyright 2004, Industrial Press, Inc., New York, NY
39° 3.14660 3.14773 3.14886 3.14999 3.15112 3.15225 3.15338 3.15451 3.15564 3.15676 3.15789 3.15902 3.16015 3.16127 3.16240 3.16353 3.16465 3.16578 3.16690 3.16803 3.16915 3.17028 3.17140 3.17253 3.17365 3.17478 3.17590 3.17702 3.17815 3.17927 3.18039 3.18151 3.18264 3.18376 3.18488 3.18600 3.18712 3.18824 3.18936 3.19048 3.19160 3.19272 3.19384 3.19496 3.19608 3.19720 3.19831 3.19943 3.20055 3.20167 3.20278 3.20390 3.20502 3.20613 3.20725 3.20836 3.20948 3.21059 3.21171 3.21282 3.21394
Machinery's Handbook 27th Edition 704
5-INCH SINE-BAR CONSTANTS Constants for Setting a 5-inch Sine-bar for 40° to 47°
Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
40° 3.21394 3.21505 3.21617 3.21728 3.21839 3.21951 3.22062 3.22173 3.22284 3.22395 3.22507 3.22618 3.22729 3.22840 3.22951 3.23062 3.23173 3.23284 3.23395 3.23506 3.23617 3.23728 3.23838 3.23949 3.24060 3.24171 3.24281 3.24392 3.24503 3.24613 3.24724 3.24835 3.24945 3.25056 3.25166 3.25277 3.25387 3.25498 3.25608 3.25718 3.25829 3.25939 3.26049 3.26159 3.26270 3.26380 3.26490 3.26600 3.26710 3.26820 3.26930 3.27040 3.27150 3.27260 3.27370 3.27480 3.27590 3.27700 3.27810 3.27920 3.28030
41° 3.28030 3.28139 3.28249 3.28359 3.28468 3.28578 3.28688 3.28797 3.28907 3.29016 3.29126 3.29235 3.29345 3.29454 3.29564 3.29673 3.29782 3.29892 3.30001 3.30110 3.30219 3.30329 3.30438 3.30547 3.30656 3.30765 3.30874 3.30983 3.31092 3.31201 3.31310 3.31419 3.31528 3.31637 3.31746 3.31854 3.31963 3.32072 3.32181 3.32289 3.32398 3.32507 3.32615 3.32724 3.32832 3.32941 3.33049 3.33158 3.33266 3.33375 3.33483 3.33591 3.33700 3.33808 3.33916 3.34025 3.34133 3.34241 3.34349 3.34457 3.34565
42° 3.34565 3.34673 3.34781 3.34889 3.34997 3.35105 3.35213 3.35321 3.35429 3.35537 3.35645 3.35753 3.35860 3.35968 3.36076 3.36183 3.36291 3.36399 3.36506 3.36614 3.36721 3.36829 3.36936 3.37044 3.37151 3.37259 3.37366 3.37473 3.37581 3.37688 3.37795 3.37902 3.38010 3.38117 3.38224 3.38331 3.38438 3.38545 3.38652 3.38759 3.38866 3.38973 3.39080 3.39187 3.39294 3.39400 3.39507 3.39614 3.39721 3.39827 3.39934 3.40041 3.40147 3.40254 3.40360 3.40467 3.40573 3.40680 3.40786 3.40893 3.40999
43° 3.40999 3.41106 3.41212 3.41318 3.41424 3.41531 3.41637 3.41743 3.41849 3.41955 3.42061 3.42168 3.42274 3.42380 3.42486 3.42592 3.42697 3.42803 3.42909 3.43015 3.43121 3.43227 3.43332 3.43438 3.43544 3.43649 3.43755 3.43861 3.43966 3.44072 3.44177 3.44283 3.44388 3.44494 3.44599 3.44704 3.44810 3.44915 3.45020 3.45126 3.45231 3.45336 3.45441 3.45546 3.45651 3.45757 3.45862 3.45967 3.46072 3.46177 3.46281 3.46386 3.46491 3.46596 3.46701 3.46806 3.46910 3.47015 3.47120 3.47225 3.47329
44° 3.47329 3.47434 3.47538 3.47643 3.47747 3.47852 3.47956 3.48061 3.48165 3.48270 3.48374 3.48478 3.48583 3.48687 3.48791 3.48895 3.48999 3.49104 3.49208 3.49312 3.49416 3.49520 3.49624 3.49728 3.49832 3.49936 3.50039 3.50143 3.50247 3.50351 3.50455 3.50558 3.50662 3.50766 3.50869 3.50973 3.51077 3.51180 3.51284 3.51387 3.51491 3.51594 3.51697 3.51801 3.51904 3.52007 3.52111 3.52214 3.52317 3.52420 3.52523 3.52627 3.52730 3.52833 3.52936 3.53039 3.53142 3.53245 3.53348 3.53451 3.53553
45° 3.53553 3.53656 3.53759 3.53862 3.53965 3.54067 3.54170 3.54273 3.54375 3.54478 3.54580 3.54683 3.54785 3.54888 3.54990 3.55093 3.55195 3.55297 3.55400 3.55502 3.55604 3.55707 3.55809 3.55911 3.56013 3.56115 3.56217 3.56319 3.56421 3.56523 3.56625 3.56727 3.56829 3.56931 3.57033 3.57135 3.57236 3.57338 3.57440 3.57542 3.57643 3.57745 3.57846 3.57948 3.58049 3.58151 3.58252 3.58354 3.58455 3.58557 3.58658 3.58759 3.58861 3.58962 3.59063 3.59164 3.59266 3.59367 3.59468 3.59569 3.59670
46° 3.59670 3.59771 3.59872 3.59973 3.60074 3.60175 3.60276 3.60376 3.60477 3.60578 3.60679 3.60779 3.60880 3.60981 3.61081 3.61182 3.61283 3.61383 3.61484 3.61584 3.61684 3.61785 3.61885 3.61986 3.62086 3.62186 3.62286 3.62387 3.62487 3.62587 3.62687 3.62787 3.62887 3.62987 3.63087 3.63187 3.63287 3.63387 3.63487 3.63587 3.63687 3.63787 3.63886 3.63986 3.64086 3.64186 3.64285 3.64385 3.64484 3.64584 3.64683 3.64783 3.64882 3.64982 3.65081 3.65181 3.65280 3.65379 3.65478 3.65578 3.65677
Copyright 2004, Industrial Press, Inc., New York, NY
47° 3.65677 3.65776 3.65875 3.65974 3.66073 3.66172 3.66271 3.66370 3.66469 3.66568 3.66667 3.66766 3.66865 3.66964 3.67063 3.67161 3.67260 3.67359 3.67457 3.67556 3.67655 3.67753 3.67852 3.67950 3.68049 3.68147 3.68245 3.68344 3.68442 3.68540 3.68639 3.68737 3.68835 3.68933 3.69031 3.69130 3.69228 3.69326 3.69424 3.69522 3.69620 3.69718 3.69816 3.69913 3.70011 3.70109 3.70207 3.70305 3.70402 3.70500 3.70598 3.70695 3.70793 3.70890 3.70988 3.71085 3.71183 3.71280 3.71378 3.71475 3.71572
Machinery's Handbook 27th Edition 5-INCH SINE-BAR CONSTANTS
705
Constants for Setting a 5-inch Sine-bar for 48° to 55° Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
48° 3.71572 3.71670 3.71767 3.71864 3.71961 3.72059 3.72156 3.72253 3.72350 3.72447 3.72544 3.72641 3.72738 3.72835 3.72932 3.73029 3.73126 3.73222 3.73319 3.73416 3.73513 3.73609 3.73706 3.73802 3.73899 3.73996 3.74092 3.74189 3.74285 3.74381 3.74478 3.74574 3.74671 3.74767 3.74863 3.74959 3.75056 3.75152 3.75248 3.75344 3.75440 3.75536 3.75632 3.75728 3.75824 3.75920 3.76016 3.76112 3.76207 3.76303 3.76399 3.76495 3.76590 3.76686 3.76782 3.76877 3.76973 3.77068 3.77164 3.77259 3.77355
49° 3.77355 3.77450 3.77546 3.77641 3.77736 3.77831 3.77927 3.78022 3.78117 3.78212 3.78307 3.78402 3.78498 3.78593 3.78688 3.78783 3.78877 3.78972 3.79067 3.79162 3.79257 3.79352 3.79446 3.79541 3.79636 3.79730 3.79825 3.79919 3.80014 3.80109 3.80203 3.80297 3.80392 3.80486 3.80581 3.80675 3.80769 3.80863 3.80958 3.81052 3.81146 3.81240 3.81334 3.81428 3.81522 3.81616 3.81710 3.81804 3.81898 3.81992 3.82086 3.82179 3.82273 3.82367 3.82461 3.82554 3.82648 3.82742 3.82835 3.82929 3.83022
50° 3.83022 3.83116 3.83209 3.83303 3.83396 3.83489 3.83583 3.83676 3.83769 3.83862 3.83956 3.84049 3.84142 3.84235 3.84328 3.84421 3.84514 3.84607 3.84700 3.84793 3.84886 3.84978 3.85071 3.85164 3.85257 3.85349 3.85442 3.85535 3.85627 3.85720 3.85812 3.85905 3.85997 3.86090 3.86182 3.86274 3.86367 3.86459 3.86551 3.86644 3.86736 3.86828 3.86920 3.87012 3.87104 3.87196 3.87288 3.87380 3.87472 3.87564 3.87656 3.87748 3.87840 3.87931 3.88023 3.88115 3.88207 3.88298 3.88390 3.88481 3.88573
51° 3.88573 3.88665 3.88756 3.88847 3.88939 3.89030 3.89122 3.89213 3.89304 3.89395 3.89487 3.89578 3.89669 3.89760 3.89851 3.89942 3.90033 3.90124 3.90215 3.90306 3.90397 3.90488 3.90579 3.90669 3.90760 3.90851 3.90942 3.91032 3.91123 3.91214 3.91304 3.91395 3.91485 3.91576 3.91666 3.91756 3.91847 3.91937 3.92027 3.92118 3.92208 3.92298 3.92388 3.92478 3.92568 3.92658 3.92748 3.92839 3.92928 3.93018 3.93108 3.93198 3.93288 3.93378 3.93468 3.93557 3.93647 3.93737 3.93826 3.93916 3.94005
52° 3.94005 3.94095 3.94184 3.94274 3.94363 3.94453 3.94542 3.94631 3.94721 3.94810 3.94899 3.94988 3.95078 3.95167 3.95256 3.95345 3.95434 3.95523 3.95612 3.95701 3.95790 3.95878 3.95967 3.96056 3.96145 3.96234 3.96322 3.96411 3.96500 3.96588 3.96677 3.96765 3.96854 3.96942 3.97031 3.97119 3.97207 3.97296 3.97384 3.97472 3.97560 3.97649 3.97737 3.97825 3.97913 3.98001 3.98089 3.98177 3.98265 3.98353 3.98441 3.98529 3.98616 3.98704 3.98792 3.98880 3.98967 3.99055 3.99143 3.99230 3.99318
53° 3.99318 3.99405 3.99493 3.99580 3.99668 3.99755 3.99842 3.99930 4.00017 4.00104 4.00191 4.00279 4.00366 4.00453 4.00540 4.00627 4.00714 4.00801 4.00888 4.00975 4.01062 4.01148 4.01235 4.01322 4.01409 4.01495 4.01582 4.01669 4.01755 4.01842 4.01928 4.02015 4.02101 4.02188 4.02274 4.02361 4.02447 4.02533 4.02619 4.02706 4.02792 4.02878 4.02964 4.03050 4.03136 4.03222 4.03308 4.03394 4.03480 4.03566 4.03652 4.03738 4.03823 4.03909 4.03995 4.04081 4.04166 4.04252 4.04337 4.04423 4.04508
54° 4.04508 4.04594 4.04679 4.04765 4.04850 4.04936 4.05021 4.05106 4.05191 4.05277 4.05362 4.05447 4.05532 4.05617 4.05702 4.05787 4.05872 4.05957 4.06042 4.06127 4.06211 4.06296 4.06381 4.06466 4.06550 4.06635 4.06720 4.06804 4.06889 4.06973 4.07058 4.07142 4.07227 4.07311 4.07395 4.07480 4.07564 4.07648 4.07732 4.07817 4.07901 4.07985 4.08069 4.08153 4.08237 4.08321 4.08405 4.08489 4.08572 4.08656 4.08740 4.08824 4.08908 4.08991 4.09075 4.09158 4.09242 4.09326 4.09409 4.09493 4.09576
Copyright 2004, Industrial Press, Inc., New York, NY
55° 4.09576 4.09659 4.09743 4.09826 4.09909 4.09993 4.10076 4.10159 4.10242 4.10325 4.10409 4.10492 4.10575 4.10658 4.10741 4.10823 4.10906 4.10989 4.11072 4.11155 4.11238 4.11320 4.11403 4.11486 4.11568 4.11651 4.11733 4.11816 4.11898 4.11981 4.12063 4.12145 4.12228 4.12310 4.12392 4.12475 4.12557 4.12639 4.12721 4.12803 4.12885 4.12967 4.13049 4.13131 4.13213 4.13295 4.13377 4.13459 4.13540 4.13622 4.13704 4.13785 4.13867 4.13949 4.14030 4.14112 4.14193 4.14275 4.14356 4.14437 4.14519
Machinery's Handbook 27th Edition 706
100-MILLIMETER SINE-BAR CONSTANTS Constants for 100-millimeter Sine-bar Constants for Setting a 100-mm Sine-bar for 0° to 7°
Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
0° 0.000000 0.029089 0.058178 0.087266 0.116355 0.145444 0.174533 0.203622 0.232710 0.261799 0.290888 0.319977 0.349065 0.378154 0.407242 0.436331 0.465420 0.494508 0.523596 0.552685 0.581773 0.610861 0.639950 0.669038 0.698126 0.727214 0.756302 0.785390 0.814478 0.843566 0.872654 0.901741 0.930829 0.959916 0.989004 1.018091 1.047179 1.076266 1.105353 1.134440 1.163527 1.192613 1.221700 1.250787 1.279873 1.308960 1.338046 1.367132 1.396218 1.425304 1.454390 1.483476 1.512561 1.541646 1.570732 1.599817 1.628902 1.657987 1.687072 1.716156 1.745241
1° 1.745241 1.774325 1.803409 1.832493 1.861577 1.890661 1.919744 1.948828 1.977911 2.006994 2.036077 2.065159 2.094242 2.123324 2.152407 2.181489 2.210570 2.239652 2.268733 2.297815 2.326896 2.355977 2.385057 2.414138 2.443218 2.472298 2.501378 2.530457 2.559537 2.588616 2.617695 2.646774 2.675852 2.704930 2.734009 2.763086 2.792164 2.821241 2.850318 2.879395 2.908472 2.937548 2.966624 2.995700 3.024776 3.053851 3.082927 3.112001 3.141076 3.170151 3.199224 3.228298 3.257372 3.286445 3.315518 3.344591 3.373663 3.402735 3.431807 3.460879 3.489950
2° 3.489950 3.519021 3.548091 3.577162 3.606232 3.635301 3.664371 3.693440 3.722509 3.751578 3.780646 3.809714 3.838781 3.867848 3.896915 3.925982 3.955048 3.984114 4.013179 4.042244 4.071309 4.100374 4.129438 4.158502 4.187566 4.216629 4.245691 4.274754 4.303816 4.332878 4.361939 4.391000 4.420060 4.449121 4.478180 4.507240 4.536299 4.565357 4.594416 4.623474 4.652532 4.681589 4.710645 4.739702 4.768757 4.797813 4.826868 4.855923 4.884977 4.914031 4.943084 4.972137 5.001190 5.030242 5.059294 5.088346 5.117396 5.146447 5.175497 5.204546 5.233596
3° 5.233596 5.262644 5.291693 5.320741 5.349788 5.378835 5.407881 5.436927 5.465973 5.495018 5.524063 5.553107 5.582151 5.611194 5.640237 5.669279 5.698321 5.727362 5.756403 5.785443 5.814483 5.843522 5.872561 5.901600 5.930638 5.959675 5.988712 6.017748 6.046784 6.075819 6.104854 6.133888 6.162922 6.191956 6.220988 6.250021 6.279052 6.308083 6.337114 6.366144 6.395174 6.424202 6.453231 6.482259 6.511286 6.540313 6.569339 6.598365 6.627390 6.656415 6.685439 6.714462 6.743485 6.772508 6.801529 6.830551 6.859571 6.888591 6.917611 6.946630 6.975647
4° 6.975647 7.004666 7.033682 7.062699 7.091714 7.120730 7.149745 7.178759 7.207772 7.236785 7.265797 7.294809 7.323820 7.352830 7.381840 7.410849 7.439858 7.468865 7.497873 7.526879 7.555886 7.584891 7.613896 7.642900 7.671903 7.700905 7.729908 7.758909 7.787910 7.816910 7.845910 7.874909 7.903907 7.932905 7.961901 7.990898 8.019893 8.048887 8.077881 8.106875 8.135867 8.164860 8.193851 8.222842 8.251831 8.280821 8.309810 8.338798 8.367785 8.396770 8.425757 8.454741 8.483727 8.512710 8.541693 8.570675 8.599656 8.628636 8.657617 8.686596 8.715574
5° 8.715574 8.744553 8.773529 8.802505 8.831481 8.860456 8.889430 8.918404 8.947375 8.976348 9.005319 9.034289 9.063258 9.092227 9.121195 9.150162 9.179129 9.208094 9.237060 9.266023 9.294987 9.323949 9.352911 9.381871 9.410831 9.439791 9.468750 9.497706 9.526664 9.555620 9.584576 9.613530 9.642484 9.671437 9.700389 9.729341 9.758290 9.787240 9.816189 9.845137 9.874084 9.903030 9.931975 9.960920 9.989863 10.018806 10.047749 10.076690 10.105630 10.134569 10.163508 10.192446 10.221383 10.250319 10.279254 10.308188 10.337122 10.366054 10.394986 10.423916 10.452847
6° 10.452847 10.481776 10.510704 10.539631 10.568558 10.597483 10.626408 10.655332 10.684254 10.713176 10.742096 10.771017 10.799935 10.828855 10.857771 10.886688 10.915604 10.944518 10.973432 11.002344 11.031256 11.060166 11.089077 11.117986 11.146894 11.175800 11.204707 11.233611 11.262516 11.291419 11.320322 11.349223 11.378123 11.407023 11.435922 11.464819 11.493715 11.522612 11.551505 11.580400 11.609291 11.638184 11.667073 11.695964 11.724852 11.753740 11.782627 11.811512 11.840398 11.869281 11.898164 11.927045 11.955926 11.984805 12.013684 12.042562 12.071439 12.100314 12.129189 12.158062 12.186934
Copyright 2004, Industrial Press, Inc., New York, NY
7° 12.186934 12.215807 12.244677 12.273546 12.302414 12.331282 12.360147 12.389013 12.417877 12.446741 12.475602 12.504464 12.533323 12.562182 12.591040 12.619897 12.648753 12.677608 12.706462 12.735313 12.764166 12.793015 12.821865 12.850713 12.879560 12.908405 12.937251 12.966094 12.994938 13.023779 13.052620 13.081459 13.110297 13.139134 13.167971 13.196806 13.225639 13.254473 13.283303 13.312135 13.340963 13.369792 13.398619 13.427444 13.456269 13.485093 13.513916 13.542737 13.571558 13.600377 13.629195 13.658011 13.686828 13.715641 13.744455 13.773267 13.802078 13.830888 13.859696 13.888504 13.917311
Machinery's Handbook 27th Edition 100-MILLIMETER SINE-BAR CONSTANTS
707
Constants for Setting a 100-mm Sine-bar for 8° to 15° Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
8° 13.917311 13.946115 13.974920 14.003723 14.032524 14.061324 14.090124 14.118922 14.147718 14.176514 14.205309 14.234102 14.262894 14.291684 14.320475 14.349262 14.378049 14.406837 14.435621 14.464404 14.493186 14.521968 14.550748 14.579526 14.608303 14.637080 14.665854 14.694628 14.723400 14.752172 14.780942 14.809710 14.838478 14.867244 14.896008 14.924772 14.953535 14.982296 15.011056 15.039814 15.068572 15.097328 15.126082 15.154835 15.183589 15.212339 15.241088 15.269837 15.298584 15.327330 15.356073 15.384818 15.413560 15.442300 15.471039 15.499778 15.528514 15.557248 15.585982 15.614716 15.643447
9° 15.643447 15.672176 15.700907 15.729633 15.758359 15.787084 15.815807 15.844529 15.873250 15.901969 15.930688 15.959404 15.988119 16.016832 16.045546 16.074257 16.102966 16.131676 16.160383 16.189089 16.217793 16.246496 16.275198 16.303898 16.332596 16.361296 16.389990 16.418684 16.447378 16.476070 16.504761 16.533449 16.562140 16.590824 16.619509 16.648193 16.676876 16.705557 16.734236 16.762913 16.791590 16.820265 16.848938 16.877609 16.906282 16.934952 16.963619 16.992287 17.020950 17.049614 17.078276 17.106937 17.135597 17.164253 17.192909 17.221565 17.250219 17.278872 17.307520 17.336170 17.364819
10° 17.364819 17.393463 17.422110 17.450752 17.479393 17.508034 17.536674 17.565311 17.593946 17.622580 17.651215 17.679844 17.708475 17.737103 17.765730 17.794355 17.822979 17.851603 17.880222 17.908842 17.937458 17.966076 17.994690 18.023304 18.051914 18.080526 18.109135 18.137741 18.166346 18.194950 18.223553 18.252153 18.280754 18.309351 18.337948 18.366541 18.395136 18.423727 18.452316 18.480906 18.509493 18.538078 18.566662 18.595243 18.623825 18.652405 18.680981 18.709558 18.738132 18.766705 18.795275 18.823847 18.852413 18.880980 18.909544 18.938108 18.966669 18.995230 19.023787 19.052345 19.080900
11° 19.080900 19.109453 19.138006 19.166555 19.195105 19.223652 19.252197 19.280741 19.309282 19.337824 19.366364 19.394899 19.423435 19.451969 19.480503 19.509033 19.537561 19.566090 19.594616 19.623138 19.651661 19.680183 19.708702 19.737219 19.765734 19.794249 19.822762 19.851271 19.879780 19.908289 19.936794 19.965298 19.993801 20.022301 20.050800 20.079296 20.107794 20.136286 20.164778 20.193268 20.221758 20.250244 20.278730 20.307213 20.335695 20.364176 20.392654 20.421131 20.449606 20.478079 20.506550 20.535021 20.563488 20.591955 20.620419 20.648882 20.677343 20.705801 20.734259 20.762716 20.791170
12° 20.791170 20.819622 20.848074 20.876522 20.904968 20.933413 20.961857 20.990299 21.018738 21.047176 21.075613 21.104048 21.132481 21.160910 21.189341 21.217768 21.246193 21.274618 21.303040 21.331459 21.359877 21.388294 21.416710 21.445122 21.473532 21.501944 21.530350 21.558756 21.587158 21.615562 21.643963 21.672359 21.700758 21.729153 21.757544 21.785934 21.814325 21.842712 21.871098 21.899481 21.927864 21.956244 21.984621 22.012997 22.041372 22.069744 22.098114 22.126484 22.154850 22.183216 22.211578 22.239941 22.268299 22.296656 22.325012 22.353367 22.381718 22.410067 22.438416 22.466763 22.495106
13° 22.495106 22.523447 22.551790 22.580128 22.608463 22.636799 22.665133 22.693462 22.721790 22.750118 22.778444 22.806767 22.835087 22.863405 22.891726 22.920040 22.948353 22.976665 23.004974 23.033281 23.061586 23.089891 23.118193 23.146492 23.174789 23.203087 23.231380 23.259672 23.287962 23.316252 23.344538 23.372820 23.401104 23.429384 23.457661 23.485937 23.514212 23.542484 23.570755 23.599022 23.627289 23.655554 23.683815 23.712074 23.740334 23.768589 23.796844 23.825096 23.853346 23.881594 23.909840 23.938086 23.966328 23.994566 24.022804 24.051041 24.079275 24.107506 24.135736 24.163965 24.192190
14° 24.192190 24.220413 24.248636 24.276855 24.305073 24.333288 24.361502 24.389713 24.417923 24.446129 24.474335 24.502539 24.530739 24.558937 24.587135 24.615330 24.643522 24.671715 24.699902 24.728088 24.756271 24.784456 24.812635 24.840813 24.868988 24.897163 24.925335 24.953505 24.981672 25.009838 25.038002 25.066162 25.094322 25.122478 25.150633 25.178785 25.206938 25.235085 25.263231 25.291374 25.319517 25.347658 25.375795 25.403931 25.432064 25.460196 25.488325 25.516453 25.544577 25.572699 25.600819 25.628939 25.657055 25.685167 25.713280 25.741390 25.769497 25.797602 25.825705 25.853807 25.881905
Copyright 2004, Industrial Press, Inc., New York, NY
15° 25.881905 25.910002 25.938097 25.966188 25.994278 26.022366 26.050451 26.078535 26.106615 26.134695 26.162773 26.190845 26.218918 26.246988 26.275057 26.303122 26.331184 26.359247 26.387306 26.415361 26.443417 26.471470 26.499519 26.527567 26.555613 26.583656 26.611696 26.639736 26.667770 26.695807 26.723839 26.751867 26.779896 26.807920 26.835943 26.863964 26.891983 26.920000 26.948013 26.976025 27.004034 27.032042 27.060045 27.088047 27.116049 27.144045 27.172041 27.200035 27.228025 27.256014 27.284000 27.311985 27.339966 27.367945 27.395922 27.423899 27.451870 27.479839 27.507807 27.535774 27.563736
Machinery's Handbook 27th Edition 708
100-MILLIMETER SINE-BAR CONSTANTS Constants for Setting a 100-mm Sine-bar for 16° to 23°
Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
16° 27.563736 27.591696 27.619656 27.647610 27.675568 27.703518 27.731466 27.759413 27.787357 27.815298 27.843239 27.871176 27.899113 27.927044 27.954975 27.982903 28.010828 28.038750 28.066669 28.094591 28.122507 28.150421 28.178331 28.206240 28.234146 28.262049 28.289951 28.317852 28.345749 28.373644 28.401535 28.429424 28.457312 28.485195 28.513081 28.540960 28.568838 28.596712 28.624586 28.652456 28.680323 28.708189 28.736053 28.763914 28.791773 28.819628 28.847481 28.875332 28.903179 28.931028 28.958872 28.986712 29.014551 29.042387 29.070219 29.098051 29.125879 29.153708 29.181532 29.209352 29.237171
17° 29.237171 29.264988 29.292801 29.320612 29.348425 29.376230 29.404034 29.431835 29.459635 29.487431 29.515224 29.543015 29.570807 29.598593 29.626377 29.654158 29.681936 29.709713 29.737488 29.765261 29.793030 29.820797 29.848560 29.876320 29.904079 29.931835 29.959589 29.987343 30.015091 30.042837 30.070581 30.098322 30.126060 30.153795 30.181532 30.209263 30.236990 30.264715 30.292439 30.320160 30.347878 30.375593 30.403309 30.431019 30.458725 30.486431 30.514133 30.541832 30.569530 30.597227 30.624920 30.652609 30.680296 30.707981 30.735662 30.763342 30.791018 30.818695 30.846365 30.874035 30.901701
18° 30.901701 30.929363 30.957024 30.984682 31.012341 31.039993 31.067644 31.095291 31.122936 31.150579 31.178219 31.205856 31.233494 31.261126 31.288755 31.316381 31.344006 31.371626 31.399244 31.426865 31.454477 31.482088 31.509697 31.537302 31.564903 31.592505 31.620102 31.647699 31.675291 31.702881 31.730467 31.758051 31.785631 31.813210 31.840790 31.868362 31.895933 31.923500 31.951065 31.978628 32.006187 32.033745 32.061302 32.088852 32.116402 32.143948 32.171490 32.199032 32.226570 32.254108 32.281639 32.309170 32.336697 32.364220 32.391743 32.419262 32.446777 32.474293 32.501804 32.529312 32.556816
19° 32.556816 32.584320 32.611816 32.639317 32.666813 32.694302 32.721790 32.749275 32.776760 32.804241 32.831718 32.859192 32.886665 32.914135 32.941601 32.969067 32.996525 33.023983 33.051437 33.078896 33.106342 33.133789 33.161236 33.188675 33.216114 33.243549 33.270981 33.298416 33.325840 33.353264 33.380688 33.408104 33.435520 33.462933 33.490349 33.517754 33.545158 33.572559 33.599960 33.627354 33.654747 33.682137 33.709530 33.736912 33.764294 33.791672 33.819050 33.846420 33.873791 33.901161 33.928528 33.955887 33.983246 34.010601 34.037956 34.065304 34.092651 34.119999 34.147343 34.174679 34.202015
20° 34.202015 34.229347 34.256680 34.284004 34.311333 34.338654 34.365971 34.393288 34.420597 34.447906 34.475216 34.502518 34.529823 34.557121 34.584415 34.611706 34.638996 34.666283 34.693565 34.720848 34.748127 34.775398 34.802670 34.829941 34.857204 34.884468 34.911728 34.938988 34.966240 34.993492 35.020741 35.047985 35.075226 35.102463 35.129704 35.156937 35.184166 35.211395 35.238617 35.265839 35.293056 35.320271 35.347488 35.374695 35.401901 35.429104 35.456306 35.483501 35.510696 35.537891 35.565079 35.592262 35.619446 35.646626 35.673801 35.700974 35.728142 35.755314 35.782478 35.809639 35.836796
21° 35.836796 35.863953 35.891102 35.918251 35.945400 35.972542 35.999683 36.026817 36.053951 36.081081 36.108212 36.135334 36.162460 36.189579 36.216694 36.243805 36.270912 36.298019 36.325123 36.352226 36.379322 36.406418 36.433506 36.460594 36.487679 36.514759 36.541840 36.568916 36.595989 36.623058 36.650124 36.677185 36.704247 36.731304 36.758358 36.785408 36.812458 36.839500 36.866543 36.893581 36.920616 36.947647 36.974678 37.001705 37.028725 37.055744 37.082760 37.109772 37.136784 37.163792 37.190796 37.217796 37.244793 37.271790 37.298779 37.325768 37.352753 37.379734 37.406712 37.433689 37.460659
22° 37.460659 37.487629 37.514595 37.541557 37.568520 37.595474 37.622429 37.649376 37.676323 37.703266 37.730206 37.757145 37.784081 37.811012 37.837940 37.864864 37.891785 37.918701 37.945614 37.972530 37.999439 38.026344 38.053246 38.080143 38.107037 38.133930 38.160820 38.187706 38.214588 38.241470 38.268345 38.295216 38.322086 38.348953 38.375816 38.402679 38.429535 38.456387 38.483238 38.510082 38.536926 38.563766 38.590607 38.617439 38.644272 38.671097 38.697922 38.724743 38.751560 38.778374 38.805187 38.831993 38.858799 38.885597 38.912395 38.939190 38.965981 38.992771 39.019554 39.046337 39.073112
Copyright 2004, Industrial Press, Inc., New York, NY
23° 39.073112 39.099888 39.126659 39.153427 39.180195 39.206955 39.233715 39.260468 39.287220 39.313965 39.340710 39.367451 39.394192 39.420929 39.447659 39.474388 39.501110 39.527832 39.554550 39.581268 39.607979 39.634686 39.661392 39.688091 39.714790 39.741486 39.768173 39.794865 39.821548 39.848232 39.874908 39.901581 39.928253 39.954922 39.981586 40.008247 40.034904 40.061558 40.088207 40.114857 40.141499 40.168140 40.194778 40.221413 40.248043 40.274670 40.301292 40.327911 40.354530 40.381145 40.407757 40.434361 40.460964 40.487564 40.514160 40.540752 40.567341 40.593929 40.620510 40.647091 40.673664
Machinery's Handbook 27th Edition 100-MILLIMETER SINE-BAR CONSTANTS
709
Constants for Setting a 100-mm Sine-bar for 24° to 31° Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
24° 40.673664 40.700237 40.726807 40.753372 40.779934 40.806492 40.833046 40.859600 40.886147 40.912689 40.939232 40.965767 40.992306 41.018837 41.045364 41.071888 41.098408 41.124924 41.151436 41.177948 41.204453 41.230957 41.257458 41.283951 41.310444 41.336933 41.363419 41.389900 41.416378 41.442856 41.469326 41.495792 41.522259 41.548717 41.575176 41.601631 41.628082 41.654526 41.680969 41.707409 41.733845 41.760277 41.786709 41.813133 41.839558 41.865974 41.892391 41.918800 41.945210 41.971615 41.998016 42.024414 42.050804 42.077194 42.103580 42.129963 42.156345 42.182724 42.209095 42.235462 42.261826
25° 42.261826 42.288189 42.314545 42.340900 42.367252 42.393600 42.419945 42.446285 42.472618 42.498951 42.525280 42.551605 42.577930 42.604248 42.630566 42.656876 42.683182 42.709488 42.735786 42.762085 42.788380 42.814667 42.840954 42.867237 42.893513 42.919788 42.946060 42.972332 42.998592 43.024853 43.051109 43.077362 43.103615 43.129860 43.156105 43.182343 43.208576 43.234806 43.261036 43.287258 43.313480 43.339695 43.365910 43.392120 43.418324 43.444527 43.470726 43.496918 43.523109 43.549301 43.575481 43.601662 43.627838 43.654011 43.680180 43.706345 43.732506 43.758667 43.784821 43.810970 43.837116
26° 43.837116 43.863258 43.889397 43.915531 43.941666 43.967796 43.993919 44.020039 44.046154 44.072269 44.098377 44.124481 44.150589 44.176685 44.202778 44.228870 44.254955 44.281040 44.307117 44.333199 44.359268 44.385338 44.411400 44.437462 44.463520 44.489571 44.515621 44.541668 44.567711 44.593750 44.619781 44.645813 44.671841 44.697861 44.723885 44.749901 44.775909 44.801918 44.827923 44.853924 44.879917 44.905910 44.931904 44.957886 44.983868 45.009846 45.035820 45.061787 45.087753 45.113720 45.139679 45.165630 45.191582 45.217529 45.243473 45.269409 45.295345 45.321281 45.347206 45.373131 45.399052
27° 45.399052 45.424969 45.450878 45.476788 45.502697 45.528595 45.554493 45.580387 45.606274 45.632160 45.658043 45.683918 45.709797 45.735664 45.761532 45.787392 45.813251 45.839104 45.864956 45.890804 45.916649 45.942486 45.968323 45.994152 46.019978 46.045803 46.071621 46.097439 46.123253 46.149059 46.174862 46.200661 46.226460 46.252251 46.278042 46.303825 46.329605 46.355381 46.381153 46.406921 46.432686 46.458447 46.484207 46.509960 46.535709 46.561455 46.587193 46.612930 46.638664 46.664394 46.690121 46.715843 46.741558 46.767273 46.792980 46.818687 46.844387 46.870090 46.895782 46.921471 46.947159
28° 46.947159 46.972839 46.998516 47.024189 47.049862 47.075527 47.101189 47.126846 47.152500 47.178150 47.203796 47.229439 47.255077 47.280712 47.306343 47.331966 47.357590 47.383205 47.408821 47.434433 47.460041 47.485641 47.511238 47.536831 47.562420 47.588009 47.613590 47.639168 47.664742 47.690311 47.715878 47.741440 47.766994 47.792549 47.818100 47.843647 47.869186 47.894726 47.920258 47.945786 47.971313 47.996834 48.022350 48.047863 48.073372 48.098877 48.124378 48.149876 48.175369 48.200859 48.226341 48.251823 48.277298 48.302773 48.328239 48.353703 48.379162 48.404621 48.430073 48.455521 48.480965
29° 48.480965 48.506401 48.531837 48.557270 48.582699 48.608120 48.633541 48.658955 48.684364 48.709770 48.735172 48.760571 48.785969 48.811359 48.836742 48.862125 48.887505 48.912876 48.938244 48.963612 48.988976 49.014332 49.039684 49.065033 49.090378 49.115715 49.141052 49.166386 49.191715 49.217037 49.242359 49.267673 49.292984 49.318291 49.343597 49.368893 49.394188 49.419479 49.444763 49.470047 49.495323 49.520596 49.545868 49.571133 49.596394 49.621651 49.646904 49.672153 49.697395 49.722637 49.747875 49.773106 49.798332 49.823555 49.848774 49.873989 49.899200 49.924408 49.949612 49.974808 50.000000
30° 50.000000 50.025192 50.050377 50.075558 50.100735 50.125908 50.151077 50.176239 50.201397 50.226555 50.251705 50.276852 50.301998 50.327137 50.352268 50.377399 50.402523 50.427647 50.452763 50.477879 50.502987 50.528091 50.553192 50.578285 50.603378 50.628464 50.653545 50.678627 50.703701 50.728771 50.753838 50.778900 50.803955 50.829010 50.854061 50.879105 50.904144 50.929180 50.954208 50.979237 51.004261 51.029278 51.054295 51.079304 51.104309 51.129311 51.154308 51.179298 51.204288 51.229275 51.254253 51.279228 51.304199 51.329163 51.354126 51.379082 51.404037 51.428989 51.453934 51.478874 51.503807
Copyright 2004, Industrial Press, Inc., New York, NY
31° 51.503807 51.528740 51.553669 51.578590 51.603512 51.628426 51.653336 51.678242 51.703140 51.728039 51.752930 51.777817 51.802704 51.827583 51.852455 51.877327 51.902191 51.927055 51.951912 51.976768 52.001614 52.026459 52.051300 52.076134 52.100964 52.125790 52.150612 52.175430 52.200245 52.225052 52.249859 52.274658 52.299454 52.324245 52.349033 52.373814 52.398594 52.423367 52.448135 52.472900 52.497658 52.522415 52.547169 52.571915 52.596657 52.621395 52.646126 52.670856 52.695580 52.720303 52.745018 52.769730 52.794434 52.819138 52.843834 52.868526 52.893215 52.917904 52.942581 52.967258 52.991928
Machinery's Handbook 27th Edition 710
100-MILLIMETER SINE-BAR CONSTANTS Constants for Setting a 100-mm Sine-bar for 32° to 39°
Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
32° 52.991928 53.016594 53.041256 53.065914 53.090565 53.115211 53.139858 53.164497 53.189137 53.213768 53.238392 53.263012 53.287628 53.312241 53.336849 53.361454 53.386051 53.410645 53.435234 53.459820 53.484402 53.508976 53.533546 53.558121 53.582684 53.607243 53.631794 53.656342 53.680889 53.705425 53.729961 53.754494 53.779018 53.803539 53.828056 53.852570 53.877079 53.901581 53.926086 53.950581 53.975067 53.999554 54.024036 54.048512 54.072983 54.097450 54.121910 54.146370 54.170822 54.195271 54.219715 54.244152 54.268589 54.293022 54.317448 54.341869 54.366287 54.390697 54.415104 54.439507 54.463905
33° 54.463905 54.488297 54.512688 54.537071 54.561451 54.585827 54.610195 54.634560 54.658928 54.683285 54.707634 54.731983 54.756325 54.780663 54.804996 54.829323 54.853649 54.877968 54.902283 54.926594 54.950897 54.975197 54.999493 55.023792 55.048077 55.072361 55.096638 55.120911 55.145176 55.169441 55.193699 55.217953 55.242203 55.266449 55.290688 55.314922 55.339153 55.363380 55.387608 55.411823 55.436035 55.460243 55.484444 55.508644 55.532837 55.557026 55.581207 55.605389 55.629562 55.653732 55.677895 55.702057 55.726212 55.750370 55.774513 55.798656 55.822792 55.846924 55.871052 55.895172 55.919292
34° 55.919292 55.943405 55.967514 55.991615 56.015717 56.039810 56.063900 56.087982 56.112068 56.136143 56.160213 56.184280 56.208340 56.232395 56.256447 56.280495 56.304535 56.328571 56.352604 56.376633 56.400654 56.424675 56.448685 56.472702 56.496704 56.520702 56.544697 56.568687 56.592670 56.616650 56.640625 56.664597 56.688560 56.712521 56.736477 56.760429 56.784374 56.808315 56.832256 56.856190 56.880116 56.904037 56.927956 56.951866 56.975777 56.999676 57.023575 57.047470 57.071358 57.095242 57.119118 57.142994 57.166862 57.190731 57.214592 57.238445 57.262295 57.286140 57.309978 57.333817 57.357643
35° 57.357643 57.381470 57.405293 57.429108 57.452919 57.476723 57.500523 57.524323 57.548119 57.571903 57.595684 57.619461 57.643234 57.667000 57.690762 57.714520 57.738274 57.762020 57.785763 57.809502 57.833233 57.856960 57.880684 57.904408 57.928120 57.951828 57.975533 57.999229 58.022926 58.046612 58.070297 58.093975 58.117649 58.141319 58.164982 58.188641 58.212296 58.235947 58.259594 58.283234 58.306870 58.330498 58.354122 58.377743 58.401360 58.424969 58.448574 58.472172 58.495770 58.519360 58.542942 58.566525 58.590099 58.613674 58.637238 58.660801 58.684357 58.707905 58.731449 58.754990 58.778526
36° 58.778526 58.802055 58.825584 58.849102 58.872620 58.896130 58.919636 58.943134 58.966637 58.990128 59.013615 59.037094 59.060570 59.084042 59.107506 59.130966 59.154423 59.177872 59.201317 59.224758 59.248196 59.271626 59.295052 59.318478 59.341892 59.365303 59.388710 59.412109 59.435505 59.458893 59.482281 59.505661 59.529037 59.552406 59.575771 59.599133 59.622486 59.645836 59.669186 59.692528 59.715862 59.739193 59.762516 59.785835 59.809151 59.832462 59.855766 59.879066 59.902359 59.925652 59.948933 59.972214 59.995487 60.018761 60.042027 60.065285 60.088539 60.111790 60.135033 60.158272 60.181503
37° 60.181503 60.204731 60.227955 60.251175 60.274387 60.297596 60.320797 60.343994 60.367195 60.390381 60.413563 60.436741 60.459915 60.483082 60.506245 60.529400 60.552551 60.575699 60.598839 60.621979 60.645107 60.668236 60.691357 60.714478 60.737587 60.760693 60.783794 60.806889 60.829979 60.853065 60.876144 60.899220 60.922287 60.945354 60.968414 60.991467 61.014515 61.037560 61.060604 61.083637 61.106667 61.129688 61.152706 61.175720 61.198727 61.221729 61.244728 61.267719 61.290707 61.313686 61.336662 61.359634 61.382603 61.405567 61.428524 61.451473 61.474419 61.497360 61.520294 61.543224 61.566151
38° 61.566151 61.589069 61.611984 61.634892 61.657795 61.680695 61.703587 61.726475 61.749363 61.772240 61.795113 61.817982 61.840843 61.863697 61.886551 61.909397 61.932236 61.955074 61.977905 62.000729 62.023548 62.046364 62.069172 62.091984 62.114780 62.137577 62.160362 62.183147 62.205925 62.228699 62.251465 62.274227 62.296986 62.319736 62.342484 62.365223 62.387959 62.410690 62.433418 62.456139 62.478855 62.501564 62.524269 62.546967 62.569660 62.592350 62.615032 62.637711 62.660381 62.683048 62.705711 62.728367 62.751019 62.773670 62.796310 62.818943 62.841576 62.864201 62.886818 62.909431 62.932041
Copyright 2004, Industrial Press, Inc., New York, NY
39° 62.932041 62.954643 62.977242 62.999836 63.022423 63.045002 63.067581 63.090153 63.112724 63.135284 63.157837 63.180389 63.202934 63.225471 63.248005 63.270535 63.293056 63.315575 63.338089 63.360596 63.383095 63.405594 63.428085 63.450573 63.473053 63.495529 63.517998 63.540462 63.562923 63.585377 63.607822 63.630264 63.652702 63.675137 63.697563 63.719982 63.742397 63.764809 63.787220 63.809620 63.832012 63.854401 63.876785 63.899162 63.921535 63.943901 63.966263 63.988621 64.010971 64.033318 64.055656 64.077988 64.100319 64.122650 64.144966 64.167282 64.189590 64.211891 64.234184 64.256477 64.278763
Machinery's Handbook 27th Edition 100-MILLIMETER SINE-BAR CONSTANTS
711
Constants for Setting a 100-mm Sine-bar for 40° to 47° Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
40° 64.278763 64.301041 64.323318 64.345589 64.367851 64.390106 64.412361 64.434608 64.456856 64.479095 64.501328 64.523552 64.545769 64.567986 64.590195 64.612396 64.634598 64.656792 64.678978 64.701164 64.723335 64.745506 64.767677 64.789841 64.811996 64.834145 64.856285 64.878426 64.900558 64.922684 64.944809 64.966919 64.989037 65.011139 65.033241 65.055336 65.077423 65.099503 65.121590 65.143661 65.165726 65.187790 65.209846 65.231895 65.253937 65.275978 65.298012 65.320038 65.342064 65.364075 65.386093 65.408096 65.430099 65.452095 65.474083 65.496071 65.518044 65.540016 65.561989 65.583946 65.605904
41° 65.605904 65.627853 65.649803 65.671738 65.693672 65.715599 65.737526 65.759438 65.781357 65.803261 65.825165 65.847061 65.868950 65.890831 65.912712 65.934586 65.956451 65.978310 66.000168 66.022018 66.043861 66.065704 66.087532 66.109367 66.131187 66.153008 66.174820 66.196625 66.218422 66.240219 66.262009 66.283791 66.305565 66.327339 66.349106 66.370865 66.392624 66.414368 66.436119 66.457855 66.479591 66.501320 66.523041 66.544754 66.566467 66.588165 66.609863 66.631561 66.653244 66.674927 66.696602 66.718277 66.739944 66.761604 66.783257 66.804909 66.826546 66.848183 66.869820 66.891441 66.913063
42° 66.913063 66.934677 66.956284 66.977890 66.999481 67.021072 67.042664 67.064240 67.085823 67.107391 67.128952 67.150513 67.172058 67.193611 67.215149 67.236679 67.258209 67.279732 67.301254 67.322762 67.344269 67.365768 67.387268 67.408760 67.430244 67.451721 67.473190 67.494659 67.516121 67.537575 67.559021 67.580467 67.601906 67.623337 67.644760 67.666183 67.687599 67.709007 67.730415 67.751808 67.773201 67.794586 67.815971 67.837341 67.858711 67.880074 67.901436 67.922783 67.944130 67.965469 67.986809 68.008133 68.029457 68.050781 68.072090 68.093399 68.114693 68.135986 68.157280 68.178558 68.199837
43° 68.199837 68.221107 68.242371 68.263634 68.284889 68.306137 68.327377 68.348610 68.369850 68.391075 68.412292 68.433502 68.454712 68.475914 68.497108 68.518303 68.539482 68.560661 68.581833 68.603004 68.624161 68.645317 68.666466 68.687614 68.708755 68.729889 68.751015 68.772133 68.793251 68.814354 68.835457 68.856560 68.877647 68.898735 68.919815 68.940887 68.961952 68.983017 69.004074 69.025131 69.046173 69.067207 69.088242 69.109268 69.130295 69.151306 69.172318 69.193321 69.214317 69.235313 69.256294 69.277275 69.298248 69.319221 69.340187 69.361145 69.382095 69.403038 69.423981 69.444908 69.465836
44° 69.465836 69.486763 69.507675 69.528587 69.549492 69.570389 69.591278 69.612167 69.633049 69.653923 69.674797 69.695656 69.716515 69.737366 69.758209 69.779045 69.799881 69.820709 69.841530 69.862343 69.883156 69.903961 69.924759 69.945549 69.966339 69.987114 70.007889 70.028656 70.049423 70.070175 70.090927 70.111671 70.132408 70.153145 70.173866 70.194588 70.215302 70.236015 70.256721 70.277420 70.298111 70.318794 70.339470 70.360146 70.380814 70.401474 70.422127 70.442780 70.463425 70.484062 70.504692 70.525314 70.545937 70.566551 70.587158 70.607765 70.628357 70.648949 70.669533 70.690109 70.710678
45° 70.710678 70.731247 70.751808 70.772362 70.792908 70.813446 70.833984 70.854515 70.875038 70.895561 70.916069 70.936577 70.957077 70.977570 70.998055 71.018539 71.039017 71.059486 71.079948 71.100403 71.120857 71.141304 71.161743 71.182182 71.202606 71.223030 71.243446 71.263855 71.284256 71.304657 71.325043 71.345428 71.365814 71.386185 71.406555 71.426910 71.447266 71.467613 71.487961 71.508301 71.528633 71.548958 71.569275 71.589592 71.609894 71.630196 71.650490 71.670776 71.691063 71.711334 71.731606 71.751869 71.772133 71.792389 71.812630 71.832870 71.853104 71.873337 71.893555 71.913773 71.933983
46° 71.933983 71.954185 71.974380 71.994576 72.014755 72.034935 72.055107 72.075279 72.095444 72.115601 72.135750 72.155891 72.176025 72.196159 72.216278 72.236397 72.256508 72.276619 72.296715 72.316811 72.336899 72.356979 72.377052 72.397125 72.417191 72.437248 72.457298 72.477341 72.497383 72.517410 72.537437 72.557457 72.577469 72.597481 72.617485 72.637474 72.657463 72.677452 72.697433 72.717400 72.737366 72.757324 72.777275 72.797226 72.817162 72.837097 72.857025 72.876945 72.896866 72.916771 72.936676 72.956573 72.976463 72.996353 73.016228 73.036102 73.055969 73.075829 73.095680 73.115532 73.135368
Copyright 2004, Industrial Press, Inc., New York, NY
47° 73.135368 73.155205 73.175034 73.194855 73.214676 73.234482 73.254288 73.274086 73.293884 73.313667 73.333450 73.353226 73.372986 73.392746 73.412506 73.432251 73.451996 73.471733 73.491463 73.511185 73.530899 73.550613 73.570320 73.590019 73.609711 73.629395 73.649078 73.668755 73.688416 73.708084 73.727737 73.747383 73.767029 73.786659 73.806290 73.825920 73.845535 73.865143 73.884758 73.904350 73.923943 73.943535 73.963112 73.982689 74.002251 74.021812 74.041367 74.060921 74.080460 74.099998 74.119530 74.139053 74.158569 74.178085 74.197586 74.217087 74.236580 74.256065 74.275543 74.295013 74.314484
Machinery's Handbook 27th Edition 712
100-MILLIMETER SINE-BAR CONSTANTS Constants for Setting a 100-mm Sine-bar for 48° to 55°
Min. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
48° 74.314484 74.333946 74.353401 74.372849 74.392288 74.411728 74.431152 74.450577 74.470001 74.489410 74.508812 74.528214 74.547600 74.566986 74.586365 74.605736 74.625107 74.644463 74.663818 74.683167 74.702507 74.721840 74.741173 74.760498 74.779816 74.799118 74.818428 74.837723 74.857010 74.876297 74.895576 74.914848 74.934113 74.953369 74.972618 74.991867 75.011108 75.030342 75.049568 75.068794 75.088005 75.107216 75.126419 75.145615 75.164803 75.183983 75.203156 75.222328 75.241493 75.260651 75.279800 75.298943 75.318085 75.337219 75.356346 75.375458 75.394577 75.413681 75.432777 75.451874 75.470963
49° 75.470963 75.490044 75.509117 75.528183 75.547241 75.566299 75.585350 75.604385 75.623428 75.642456 75.661484 75.680496 75.699509 75.718513 75.737511 75.756500 75.775482 75.794464 75.813431 75.832397 75.851357 75.870308 75.889259 75.908203 75.927132 75.946060 75.964981 75.983894 76.002800 76.021706 76.040596 76.059486 76.078369 76.097244 76.116112 76.134972 76.153831 76.172684 76.191528 76.210365 76.229195 76.248016 76.266838 76.285645 76.304451 76.323250 76.342041 76.360825 76.379601 76.398376 76.417145 76.435898 76.454651 76.473404 76.492142 76.510880 76.529602 76.548325 76.567039 76.585747 76.604446
50° 76.604446 76.623138 76.641830 76.660507 76.679184 76.697853 76.716515 76.735168 76.753822 76.772469 76.791100 76.809731 76.828354 76.846970 76.865578 76.884186 76.902779 76.921371 76.939957 76.958534 76.977104 76.995667 77.014229 77.032784 77.051331 77.069862 77.088394 77.106926 77.125443 77.143951 77.162460 77.180962 77.199455 77.217941 77.236420 77.254890 77.273354 77.291817 77.310272 77.328720 77.347160 77.365593 77.384026 77.402443 77.420860 77.439262 77.457664 77.476059 77.494446 77.512833 77.531204 77.549576 77.567932 77.586296 77.604645 77.622986 77.641319 77.659653 77.677971 77.696289 77.714600
51° 77.714600 77.732903 77.751198 77.769485 77.787766 77.806046 77.824318 77.842575 77.860840 77.879089 77.897331 77.915565 77.933800 77.952019 77.970238 77.988449 78.006653 78.024849 78.043045 78.061226 78.079399 78.097572 78.115738 78.133896 78.152054 78.170197 78.188332 78.206467 78.224586 78.242706 78.260818 78.278923 78.297020 78.315109 78.333199 78.351273 78.369347 78.387413 78.405472 78.423523 78.441566 78.459610 78.477638 78.495667 78.513680 78.531693 78.549698 78.567696 78.585693 78.603676 78.621651 78.639626 78.657593 78.675552 78.693504 78.711449 78.729393 78.747322 78.765244 78.783165 78.801079
52° 78.801079 78.818985 78.836884 78.854774 78.872658 78.890533 78.908409 78.926277 78.944138 78.961990 78.979836 78.997673 79.015503 79.033325 79.051147 79.068962 79.086761 79.104561 79.122353 79.140137 79.157921 79.175690 79.193451 79.211220 79.228966 79.246712 79.264450 79.282181 79.299904 79.317627 79.335335 79.353043 79.370735 79.388428 79.406113 79.423790 79.441460 79.459129 79.476791 79.494438 79.512085 79.529716 79.547348 79.564972 79.582588 79.600204 79.617805 79.635399 79.652992 79.670578 79.688156 79.705719 79.723289 79.740845 79.758392 79.775940 79.793472 79.811005 79.828529 79.846046 79.863556
53° 79.863556 79.881058 79.898552 79.916039 79.933525 79.950996 79.968468 79.985931 80.003387 80.020836 80.038277 80.055710 80.073143 80.090561 80.107979 80.125381 80.142784 80.160179 80.177567 80.194946 80.212318 80.229683 80.247047 80.264404 80.281754 80.299088 80.316422 80.333748 80.351067 80.368385 80.385689 80.402985 80.420280 80.437561 80.454842 80.472115 80.489380 80.506638 80.523895 80.541138 80.558372 80.575607 80.592827 80.610046 80.627258 80.644463 80.661659 80.678848 80.696030 80.713211 80.730377 80.747543 80.764694 80.781853 80.798988 80.816124 80.833252 80.850380 80.867493 80.884598 80.901703
54° 80.901703 80.918793 80.935883 80.952965 80.970039 80.987106 81.004166 81.021217 81.038269 81.055305 81.072342 81.089363 81.106384 81.123398 81.140404 81.157402 81.174393 81.191376 81.208351 81.225327 81.242287 81.259247 81.276199 81.293144 81.310081 81.327011 81.343933 81.360847 81.377754 81.394661 81.411552 81.428444 81.445320 81.462196 81.479065 81.495926 81.512779 81.529625 81.546471 81.563301 81.580132 81.596947 81.613762 81.630569 81.647362 81.664154 81.680939 81.697723 81.714493 81.731255 81.748009 81.764763 81.781502 81.798248 81.814972 81.831696 81.848412 81.865120 81.881821 81.898521 81.915207
Copyright 2004, Industrial Press, Inc., New York, NY
55° 81.915207 81.931885 81.948563 81.965225 81.981888 81.998543 82.015190 82.031830 82.048462 82.065086 82.081711 82.098320 82.114922 82.131523 82.148109 82.164696 82.181274 82.197845 82.214401 82.230957 82.247513 82.264053 82.280586 82.297119 82.313637 82.330154 82.346664 82.363159 82.379654 82.396141 82.412621 82.429092 82.445557 82.462013 82.478470 82.494911 82.511353 82.527779 82.544205 82.560623 82.577034 82.593437 82.609833 82.626221 82.642601 82.658974 82.675346 82.691704 82.708061 82.724403 82.740746 82.757080 82.773399 82.789726 82.806038 82.822342 82.838638 82.854927 82.871216 82.887489 82.903755
Machinery's Handbook 27th Edition ANGLES AND TAPERS
713
Accurate Measurement of Angles and Tapers When great accuracy is required in the measurement of angles, or when originating tapers, disks are commonly used. The principle of the disk method of taper measurement is that if two disks of unequal diameters are placed either in contact or a certain distance apart, lines tangent to their peripheries will represent an angle or taper, the degree of which depends upon the diameters of the two disks and the distance between them.
The gage shown in the accompanying illustration, which is a form commonly used for originating tapers or measuring angles accurately, is set by means of disks. This gage consists of two adjustable straight edges A and A1, which are in contact with disks B and B1. The angle α or the taper between the straight edges depends, of course, upon the diameters of the disks and the center distance C, and as these three dimensions can be measured accurately, it is possible to set the gage to a given angle within very close limits. Moreover, if a record of the three dimensions is kept, the exact setting of the gage can be reproduced quickly at any time. The following rules may be used for adjusting a gage of this type, and cover all problems likely to arise in practice. Disks are also occasionally used for the setting of parts in angular positions when they are to be machined accurately to a given angle: the rules are applicable to these conditions also. Measuring Dovetail Slides.—Dovetail slides that must be machined accurately to a given width are commonly gaged by using pieces of cylindrical rod or wire and measuring as indicated by the dimensions x and y of the accompanying illustrations.
The rod or wire used should be small enough so that the point of contact e is somewhat below the corner or edge of the dovetail. To obtain dimension x for measuring male dovetails, add 1 to the cotangent of one-half the dovetail angle α, multiply by diameter D of the rods used, and add the product to dimension α. x = D ( 1 + cot 1⁄2 α ) + a
c = h × cot α
To obtain dimension y for measuring a female dovetail, add 1 to the cotangent of one-half the dovetail angle α, multiply by diameter D of the rod used, and subtract the result from dimension b. Expressing these rules as formulas: y = b – D ( 1 + cot 1⁄2 α )
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 714
ANGLES AND TAPERS Tapers per Foot and Corresponding Angles
Taper per Foot 1⁄ 64 1⁄ 32 1⁄ 16 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2 17⁄ 32 9⁄ 16 19⁄ 32 5⁄ 8 21⁄ 32 11⁄ 16 23⁄ 32 3⁄ 4 25⁄ 32 13⁄ 16 27⁄ 32 7⁄ 8 29⁄ 32 15⁄ 16 31⁄ 32
Included Angle
Angle with Center Line
Taper per Foot
0.149208°
0°
4′
29″ 0°
2′
14″
0.298415
0
8
57
4
29
17⁄8 115⁄16
0
Included Angle
Angle with Center Line
9.230863°
8°
56′
9.527283
9
13 51
4″
4°
28′
4
36
2″ 56
0.447621
0
17
54
0
8
57
2
10.119738
9
31 38
4
45
49
0.596826
0
26
51
0
13
26
21⁄8
10.711650
10
7 11
5
3
36
0.746028
0
35
49
0
17
54
21⁄4
11.302990
10
42 42
5
21
21
0.895228
0
44
46
0
22
23
23⁄8
11.893726
11
18 11
5
39
5
1.044425
0
53
43
0
26
51
21⁄2
12.483829
11
53 37
5
56
49
1.193619
1
2
40
0
31
20
25⁄8
13.073267
12
29
2
6
14
31
1.342808
1
11
37
0
35
49
23⁄4
13.662012
13
4 24
6
32
12
1.491993
1
20
34
0
40
17
14.250033
13
39 43
6
49
52
1.641173
1
29
31
0
44
46
27⁄8 3
30
1.790347
1
38
28
0
49
14
1.939516
1
47
25
0
53
43
2.088677
1
56
22
0
58
11
2.237832
2
5
19
1
2
40
2.386979
2
14
16
1
7
8
2.536118
2
23
13
1
11
37
2.685248
2
32
10
1
16
5
2.834369
2
41
7
1
20
33
14.837300
14
15
0
7
7
31⁄8 31⁄4 33⁄8 31⁄2 35⁄8 33⁄4 37⁄8
15.423785
14
50 14
7
25
7
16.009458
15
25 26
7
42
43
16.594290
16
0 34
8
0
17
17.178253
16
35 39
8
17
50
17.761318
17
10 42
8
35
21
18.343458
17
45 41
8
52
50
18.924644
18
20 36
9
10
18
4
19.504850
18
55 29
9
27
44
30 17
2.983481
2
50
4
1
25
2
41⁄8
20.084047
19
3.132582
2
59
1
1
29
30
41⁄4
20.662210
20
21.239311 21.815324
9
45
9
3
10
2
31
20
39 44
10
19
52
21
14 22
10
37
11
22.390223
21
48 55
10
54
28
22.963983
22
23 25
11
11
42
23.536578
22
57 50
11
28
55
5
3.281673
3
7
57
1
33
59
3.430753
3
16
54
1
38
27
3.579821
3
25
51
1
42
55
3.728877
3
34
47
1
47
24
3.877921
3
43
44
1
51
52
43⁄8 41⁄2 45⁄8 43⁄4 47⁄8
4.026951
3
52
41
1
56
20
5
24.107983
23
32 12
11
46
6
4.175968
4
1
37
2
0
49
51⁄8
24.678175
24
6 29
12
3
14
4.324970
4
10
33
2
5
17
51⁄4
25.247127
24
40 41
12
20
21
4.473958
4
19
30
2
9
45
53⁄8
25.814817
25
14 50
12
37
25
4.622931
4
28
26
2
14
13
51⁄2
26.381221
25
48 53
12
54
27
4.771888
4
37
23
2
18
41
55⁄8
26.946316
26
22 52
13
11
26
27.510079
26
56 47
13
28
23
28.072487
27
30 36
13
45
18
4 21
14
2
10
1
5.069753
4
46
19
2
23
9
11⁄16 11⁄8 13⁄16 11⁄4 15⁄16 13⁄8 17⁄16 11⁄2 19⁄16 15⁄8 111⁄16 13⁄4 113⁄16
5.367550
5
4
11
2
32
6
53⁄4 57⁄8
5.665275
5
22
3
2
41
2
6
28.633518
28
5.962922
5
39
55
2
49
57
61⁄8
29.193151
28
38
1
14
19
0
6.260490
5
57
47
2
58
53
61⁄4
29.751364
29
11 35
14
35
48
6.557973
6
15
38
3
7
49
63⁄8
30.308136
29
45
5
14
52
32
6.855367
6
33
29
3
16
44
61⁄2
30.863447
30
18 29
15
9
15
7.152669
6
51
19
3
25
40
65⁄8
31.417276
30
51 48
15
25
54
7.449874
7
9
10
3
34
35
63⁄4
31.969603
31
25
15
42
31
7.746979
7
27
0
3
43
30
31
58 11
15
59
5
7
44
49
3
52
25
67⁄8 7
32.520409
8.043980
33.069676
32
31 13
16
15
37
33.617383
33
34.163514
33
9.230863
34
8.340873
8
2
38
4
1
19
8.637654
8
20
27
4
10
14
0.149208
8
38
16
4
19
8
71⁄8 71⁄4 73⁄8
2
4 11
16
32
5
3
16
48
31
9 49
17
4
54
37
Taper per foot represents inches of taper per foot of length. For conversions into decimal degrees and radians see Conversion Tables of Angular Measure on page 96.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition ANGLES AND TAPERS
715
Rules for Figuring Tapers Given To Find The taper per foot. The taper per inch. The taper per inch. The taper per foot. End diameters and length The taper per foot. of taper in inches. Large diameter and Diameter at small end in length of taper in inches inches, and taper per foot. Small diameter and Diameter at large end in length of taper in inches. inches, and taper per foot. The taper per foot and Distance between two two diameters in inches. given diameters in inches. The taper per foot. Amount of taper in a certain length in inches.
Rule Divide the taper per foot by 12. Multiply the taper per inch by 12. Subtract small diameter from large; divide by length of taper; and multiply quotient by 12. Divide taper per foot by 12; multiply by length of taper; and subtract result from large diameter. Divide taper per foot by 12; multiply by length of taper; and add result to small diameter. Subtract small diameter from large; divide remainder by taper per foot; and multiply quotient by 12. Divide taper per foot by 12; multiply by given length of tapered part.
To find angle α for given taper T in inches per foot.—
d
D C
α = 2 arctan ( T ⁄ 24 )
Example:What angle α is equivalent to a taper of 1.5 inches per foot? α = 2 × arctan ( 1.5 ⁄ 24 ) = 7.153° To find taper per foot T given angle α in degrees.— T = 24 tan ( α ⁄ 2 ) inches per foot Example:What taper T is equivalent to an angle of 7.153°? T = 24 tan ( 7.153 ⁄ 2 ) = 1.5 inches per foot To find angle α given dimensions D, d, and C.— Let K be the difference in the disk diameters divided by twice the center distance. K = (D − d)/(2C), then α = 2 arcsin K Example:If the disk diameters d and D are 1 and 1.5 inches, respectively, and the center distance C is 5 inches, find the included angle α. K = ( 1.5 – 1 ) ⁄ ( 2 × 5 ) = 0.05
α = 2 × arcsin 0.05 = 5.732°
To find taper T measured at right angles to a line through the disk centers given dimensions D, d, and distance C.— Find K using the formula in the previous example, then T = 24K ⁄ 1 – K 2 inches per foot Example:If disk diameters d and D are 1 and 1.5 inches, respectively, and the center distance C is 5 inches, find the taper per foot. K = ( 1.5 – 1 ) ⁄ ( 2 × 5 ) = 0.05
24 × 0.05 T = ------------------------------- = 1.2015 inches per foot 1 – ( 0.05 ) 2
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 716
ANGLES AND TAPERS
To find center distance C for a given taper T in inches per foot.— D–d 1 + ( T ⁄ 24 ) 2 C = ------------- × ---------------------------------- inches 2 T ⁄ 24 Example:Gage is to be set to 3⁄4 inch per foot, and disk diameters are 1.25 and 1.5 inches, respectively. Find the required center distance for the disks. – 1.25- × ---------------------------------------1 + ( 0.75 ⁄ 24 ) 2- = 4.002 inches C = 1.5 ----------------------0.75 ⁄ 24 2 To find center distance C for a given angle α and dimensions D and d.— C = ( D – d ) ⁄ 2 sin ( α ⁄ 2 ) inches Example:If an angle α of 20° is required, and the disks are 1 and 3 inches in diameter, respectively, find the required center distance C. C = ( 3 – 1 ) ⁄ ( 2 × sin 10 ° ) = 5.759 inches To find taper T measured at right angles to one side .—When one side is taken as a base line and the taper is measured at right angles to that side, calculate K as explained above and use the following formula for determining the taper T:
D d
C
1 – K 2 inches per foot T = 24K ------------------1 – 2K 2
Example:If the disk diameters are 2 and 3 inches, respectively, and the center I distance is 5 inches, what is the taper per foot measured at right angles to one side? 3 – 2- = 0.1 K = ----------2×5
1 – ( 0.1 ) 2 T = 24 × 0.1 × ------------------------------------- = 2.4367 in. per ft. 1 – [ 2 × ( 0.1 ) 2 ]
To find center distance C when taper T is measured from one side.— D–d C = ----------------------------------------------------- inches 2 – 2 ⁄ 1 + ( T ⁄ 12 ) 2 Example:If the taper measured at right angles to one side is 6.9 inches per foot, and the disks are 2 and 5 inches in diameter, respectively, what is center distance C? 5–2 C = ---------------------------------------------------------- = 5.815 inches. 2 – 2 ⁄ 1 + ( 6.9 ⁄ 12 ) 2 To find diameter D of a large disk in contact with a small disk of diameter d given angle α.—
d
D
+ sin ( α ⁄ 2 )- inches D = d×1 -------------------------------1 – sin ( α ⁄ 2 )
Example:The required angle α is 15°. Find diameter D of a large disk that is in contact with a standard 1-inch reference disk.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MEASUREMENT OVER PINS
717
+ sin 7.5° = 1.3002 inches D = 1 × 1--------------------------1 – sin 7.5° Measurement over Pins and Rolls Measurement over Pins.—When the distance across a bolt circle is too large to measure using ordinary measuring tools, then the required distance may be found from the distance across adacent or alternate holes using one of the methods that follow: c θ
θ
= 3 ---- 60 n -----
y
x
d
c
= 3 ---- 60 n -----
x
d
θ = 3 ------6---0 n
x
Fig. 1a.
Fig. 1b.
d
Fig. 1c.
Even Number of Holes in Circle: To measure the unknown distance x over opposite plugs in a bolt circle of n holes (n is even and greater than 4), as shown in Fig. 1a, where y is the distance over alternate plugs, d is the diameter of the holes, and θ = 360°/n is the angle between adjacent holes, use the following general equation for obtaining x: – d- + d x = y---------sin θ Example:In a die that has six 3/4-inch diameter holes equally spaced on a circle, where the distance y over alternate holes is 41⁄2 inches, and the angle θ between adjacent holes is 60°, then 4.500 – 0.7500 x = ------------------------------------ + 0.7500 = 5.0801 sin 60° In a similar problem, the distance c over adjacent plugs is given, as shown in Fig. 1b. If the number of holes is even and greater than 4, the distance x over opposite plugs is given in the following formula: –θ ⎛ sin ⎛ 180 ------------------⎞ ⎞ ⎜ ⎝ 2 ⎠⎟ x = 2 ( c – d ) ⎜ -------------------------------⎟ + d sin θ ⎜ ⎟ ⎝ ⎠ where d and θ are as defined above. Odd Number of Holes in Circle: In a circle as shown in Fig. 1c, where the number of holes n is odd and greater than 3, and the distance c over adjacent holes is given, then θ equals 360/n and the distance x across the most widely spaced holes is given by: c---------– d2 +d x = ----------θ sin --4 Checking a V-shaped Groove by Measurement Over Pins.—In checking a groove of the shape shown in Fig. 2, it is necessary to measure the dimension X over the pins of radius R. If values for the radius R, dimension Z, and the angles α and β are known, the problem is
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 718
MEASUREMENT WITH ROLLS
to determine the distance Y, to arrive at the required overall dimension for X. If a line AC is drawn from the bottom of the V to the center of the pin at the left in Fig. 2, and a line CB from the center of this pin to its point of tangency with the side of the V, a right-angled triangle is formed in which one side, CB, is known and one angle CAB, can be determined. A line drawn from the center of a circle to the point of intersection of two tangents to the circle bisects the angle made by the tangent lines, and angle CAB therefore equals 1⁄2 (α + β). The length AC and the angle DAC can now be found, and with AC known in the rightangled triangle ADC, AD, which is equal to Y can be found.
Fig. 2.
The value for X can be obtained from the formula + β- cos α – β- + 1⎞ X = Z + 2R ⎛ csc α ----------------------⎝ ⎠ 2 2 For example, if R = 0.500, Z = 1.824, α = 45 degrees, and β = 35 degrees, 45° + 35° 45° – 35° X = 1.824 + ( 2 × 0.5 ) ⎛⎝ csc ------------------------ cos ----------------------- + 1⎞⎠ 2 2 X = 1.824 + csc 40° cos 5° + 1 X = 1.824 + 1.5557 × 0.99619 + 1 X = 1.824 + 1.550 + 1 = 4.374 Checking Radius of Arc by Measurement Over Rolls.—The radius R of large-radius concave and convex gages of the type shown in Figs. 3a, 3b and 3c can be checked by measurement L over two rolls with the gage resting on the rolls as shown. If the diameter of the rolls D, the length L, and the height H of the top of the arc above the surface plate (for the concave gage, Fig. 3a) are known or can be measured, the radius R of the workpiece to be checked can be calculated trigonometrically, as follows. Referring to Fig. 3a for the concave gage, if L and D are known, cb can be found, and if H and D are known, ce can be found. With cb and ce known, ab can be found by means of a diagram as shown in Fig. 3c. In diagram Fig. 3c, cb and ce are shown at right angles as in Fig. 3a. A line is drawn connecting points b and e and line ce is extended to the right. A line is now drawn from point b perpendicular to be and intersecting the extension of ce at point f. A semicircle can now be drawn through points b, e, and f with point a as the center. Triangles bce and bcf are similar and have a common side. Thus ce:bc::bc:cf. With ce and bc known, cf can be found from this proportion and hence ef which is the diameter of the semicircle and radius ab. Then R = ab + D/2.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CHECKING SHAFT CONDITIONS
Fig. 3a.
719
Fig. 3b.
Fig. 3c.
The procedure for the convex gage is similar. The distances cb and ce are readily found and from these two distances ab is computed on the basis of similar triangles as before. Radius R is then readily found. The derived formulas for concave and convex gages are as follows: Formulas:
( L – D )2 + H ---R = ---------------------8(H – D) 2
(Concave gage Fig. 3a)
( L – D )2 R = --------------------(Convex gage Fig. 3b) 8D For example: For Fig. 3a, let L = 17.8, D = 3.20, and H = 5.72, then ( 17.8 – 3.20 ) 2 5.72 ( 14.60 ) 2 R = ----------------------------------- + ---------- = -------------------- + 2.86 8 ( 5.72 – 3.20 ) 2 8 × 2.52 213.16 R = ---------------- + 2.86 = 13.43 20.16 For Fig. 3b, let L = 22.28 and D = 3.40, then 22.28 – 3.40 ) 2- = 356.45 R = (--------------------------------------------------- = 13.1 8 × 3.40 27.20 Checking Shaft Conditions Checking for Various Shaft Conditions.—An indicating height gage, together with Vblocks can be used to check shafts for ovality, taper, straightness (bending or curving), and concentricity of features (as shown exaggerated in Fig. 4). If a shaft on which work has
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 720
CHECKING SHAFT CONDITIONS
been completed shows lack of concentricity. it may be due to the shaft having become bent or bowed because of mishandling or oval or tapered due to poor machine conditions. In checking for concentricity, the first step is to check for ovality, or out-of-roundness, as in Fig. 4a. The shaft is supported in a suitable V-block on a surface table and the dial indicator plunger is placed over the workpiece, which is then rotated beneath the plunger to obtain readings of the amount of eccentricity. This procedure (sometimes called clocking, owing to the resemblance of the dial indicator to a clock face) is repeated for other shaft diameters as necessary, and, in addition to making a written record of the measurements, the positions of extreme conditions should be marked on the workpiece for later reference.
Fig. 4.
To check for taper, the shaft is supported in the V-block and the dial indicator is used to measure the maximum height over the shaft at various positions along its length, as shown in Fig. 4b, without turning the workpiece. Again, the shaft should be marked with the reading positions and values, also the direction of the taper, and a written record should be made of the amount and direction of any taper discovered. Checking for a bent shaft requires that the shaft be clocked at the shoulder and at the farther end, as shown in Fig. 4c. For a second check the shaft is rotated only 90° or a quarter turn. When the recorded readings are compared with those from the ovality and taper checks, the three conditions can be distinguished.
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Machinery's Handbook 27th Edition OUT OF ROUNDNESS, LOBING
721
To detect a curved or bowed condition, the shaft should be suspended in two V-blocks with only about 1⁄8 inch of each end in each vee. Alternatively, the shaft can be placed between centers. The shaft is then clocked at several points, as shown in Fig. 4d, but preferably not at those locations used for the ovality, taper, or crookedness checks. If the single element due to curvature is to be distinguished from the effects of ovality, taper, and crookedness, and its value assessed, great care must be taken to differentiate between the conditions detected by the measurements. Finally, the amount of eccentricity between one shaft diameter and another may be tested by the setup shown in Fig. 4e. With the indicator plunger in contact with the smaller diameter, close to the shoulder, the shaft is rotated in the V-block and the indicator needle position is monitored to find the maximum and minimum readings. Curvature, ovality, or crookedness conditions may tend to cancel each other, as shown in Fig. 5, and one or more of these degrees of defectiveness may add themselves to the true eccentricity readings, depending on their angular positions. Fig. 5a shows, for instance, how crookedness and ovality tend to cancel each other, and also shows their effect in falsifying the reading for eccentricity. As the same shaft is turned in the V-block to the position shown in Fig. 5b, the maximum curvature reading could tend to cancel or reduce the maximum eccentricity reading. Where maximum readings for ovality, curvature, or crookedness occur at the same angular position, their values should be subtracted from the eccentricity reading to arrive at a true picture of the shaft condition. Confirmation of eccentricity readings may be obtained by reversing the shaft in the V-block, as shown in Fig. 5c, and clocking the larger diameter of the shaft.
Fig. 5.
Out-of-Roundness—Lobing.—With the imposition of finer tolerances and the development of improved measurement methods, it has become apparent that no hole,' cylinder, or sphere can be produced with a perfectly symmetrical round shape. Some of the conditions are diagrammed in Fig. 6, where Fig. 6a shows simple ovality and Fig. 6b shows ovality occurring in two directions. From the observation of such conditions have come the terms lobe and lobing. Fig. 6c shows the three-lobed shape common with centerless-ground components, and Fig. 6d is typical of multi-lobed shapes. In Fig. 6e are shown surface waviness, surface roughness, and out-of-roundness, which often are combined with lobing.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 722
OUT OF ROUNDNESS, LOBING
Fig. 6.
In Figs. 6a through 6d, the cylinder (or hole) diameters are shown at full size but the lobes are magnified some 10,000 times to make them visible. In precision parts, the deviation from the round condition is usually only in the range of millionths of an inch, although it occasionally can be 0.0001 inch, 0.0002 inch, or more. For instance, a 3-inch-diameter part may have a lobing condition amounting to an inaccuracy of only 30 millionths (0.000030 inch). Even if the distortion (ovality, waviness, roughness) is small, it may cause hum, vibration, heat buildup, and wear, possibly leading to eventual failure of the component or assembly. Plain elliptical out-of-roundness (two lobes), or any even number of lobes, can be detected by rotating the part on a surface plate under a dial indicator of adequate resolution, or by using an indicating caliper or snap gage. However, supporting such a part in a Vblock during measurement will tend to conceal roundness errors. Ovality in a hole can be detected by a dial-type bore gage or internal measuring machine. Parts with odd numbers of lobes require an instrument that can measure the envelope or complete circumference. Plug and ring gages will tell whether a shaft can be assembled into a bearing, but not whether there will be a good fit, as illustrated in Fig. 6e. A standard, 90-degree included-angle V-block can be used to detect and count the number of lobes, but to measure the exact amount of lobing indicated by R-r in Fig. 7 requires a V-block with an angle α, which is related to the number of lobes. This angle α can be calculated from the formula 2α = 180° − 360°/N, where N is the number of lobes. Thus, for a three-lobe form, α becomes 30 degrees, and the V-block used should have a 60-degree included angle. The distance M, which is obtained by rotating the part under the comparator plunger, is converted to a value for the radial variation in cylinder contour by the formula M = (R − r) (1 + csc α).
Fig. 7.
Using a V-block (even of appropriate angle) for parts with odd numbers of lobes will give exaggerated readings when the distance R − r (Fig. 7) is used as the measure of the amount of out-of-roundness. The accompanying table shows the appropriate V-block angles for various odd numbers of lobes, and the factors (1 + csc α) by which the readings are increased over the actual out-of-roundness values.
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Machinery's Handbook 27th Edition MEASUREMENTS USING LIGHT
723
Table of Lobes, V-block Angles and Exaggeration Factors in Measuring Out-of-round Conditions in Shafts Number of Lobes 3 5 7 9
Included Angle of V-block (deg) 60 108 128.57 140
Exaggeration Factor (1 + csc α) 3.00 2.24 2.11 2.06
Measurement of a complete circumference requires special equipment, often incorporating a precision spindle running true within two millionths (0.000002) inch. A stylus attached to the spindle is caused to traverse the internal or external cylinder being inspected, and its divergences are processed electronically to produce a polar chart similar to the wavy outline in Fig. 6e. The electronic circuits provide for the variations due to surface effects to be separated from those of lobing and other departures from the “true” cylinder traced out by the spindle. Measurements Using Light Measuring by Light-wave Interference Bands.—Surface variations as small as two millionths (0.000002) inch can be detected by light-wave interference methods, using an optical flat. An optical flat is a transparent block, usually of plate glass, clear fused quartz, or borosilicate glass, the faces of which are finished to extremely fine limits (of the order of 1 to 8 millionths [0.000001 to 0.000008] inch, depending on the application) for flatness. When an optical flat is placed on a “flat” surface, as shown in Fig. 8, any small departure from flatness will result in formation of a wedge-shaped layer of air between the work surface and the underside of the flat. Light rays reflected from the work surface and the underside of the flat either interfere with or reinforce each other. Interference of two reflections results when the air gap measures exactly half the wavelength of the light used, and produces a dark band across the work surface when viewed perpendicularly, under monochromatic helium light. A light band is produced halfway between the dark bands when the rays reinforce each other. With the 0.0000232-inch-wavelength helium light used, the dark bands occur where the optical flat and the work surface are separated by 11.6 millionths (0.0000116) inch, or multiples thereof.
;; ;;
7 fringes × .0000116 = .0000812′′
.0000812′′
.0000116′′
Fig. 8.
For instance, at a distance of seven dark bands from the point of contact, as shown in Fig. 8, the underface of the optical flat is separated from the work surface by a distance of 7 × 0.0000116 inch or 0.0000812 inch. The bands are separated more widely and the indications become increasingly distorted as the viewing angle departs from the perpendicular. If the bands appear straight, equally spaced and parallel with each other, the work surface is flat. Convex or concave surfaces cause the bands to curve correspondingly, and a cylindrical tendency in the work surface will produce unevenly spaced, straight bands.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 724
SURFACE TEXTURE
SURFACE TEXTURE American National Standard Surface Texture (Surface Roughness, Waviness, and Lay) American National Standard ANSI/ASME B46.1-1995 is concerned with the geometric irregularities of surfaces of solid materials, physical specimens for gaging roughness, and the characteristics of stylus instrumentation for measuring roughness. The standard defines surface texture and its constituents: roughness, waviness, lay, and flaws. A set of symbols for drawings, specifications, and reports is established. To ensure a uniform basis for measurements the standard also provides specifications for Precision Reference Specimens, and Roughness Comparison Specimens, and establishes requirements for stylustype instruments. The standard is not concerned with luster, appearance, color, corrosion resistance, wear resistance, hardness, subsurface microstructure, surface integrity, and many other characteristics that may be governing considerations in specific applications. The standard is expressed in SI metric units but U.S. customary units may be used without prejudice. The standard does not define the degrees of surface roughness and waviness or type of lay suitable for specific purposes, nor does it specify the means by which any degree of such irregularities may be obtained or produced. However, criteria for selection of surface qualities and information on instrument techniques and methods of producing, controlling and inspecting surfaces are included in Appendixes attached to the standard. The Appendix sections are not considered a part of the standard: they are included for clarification or information purposes only. Surfaces, in general, are very complex in character. The standard deals only with the height, width, and direction of surface irregularities because these characteristics are of practical importance in specific applications. Surface texture designations as delineated in this standard may not be a sufficient index to performance. Other part characteristics such as dimensional and geometrical relationships, material, metallurgy, and stress must also be controlled. Definitions of Terms Relating to the Surfaces of Solid Materials.—The terms and ratings in the standard relate to surfaces produced by such means as abrading, casting, coating, cutting, etching, plastic deformation, sintering, wear, and erosion. Error of form is considered to be that deviation from the nominal surface caused by errors in machine tool ways, guides, insecure clamping or incorrect alignment of the workpiece or wear, all of which are not included in surface texture. Out-of-roundness and outof-flatness are examples of errors of form. See ANSI/ASME B46.3.1-1988 for measurement of out-of-roundness. Flaws are unintentional, unexpected, and unwanted interruptions in the topography typical of a part surface and are defined as such only when agreed upon by buyer and seller. If flaws are defined, the surface should be inspected specifically to determine whether flaws are present, and rejected or accepted prior to performing final surface roughness measurements. If defined flaws are not present, or if flaws are not defined, then interruptions in the part surface may be included in roughness measurements. Lay is the direction of the predominant surface pattern, ordinarily determined by the production method used. Roughness consists of the finer irregularities of the surface texture, usually including those irregularities that result from the inherent action of the production process. These irregularities are considered to include traverse feed marks and other irregularities within the limits of the roughness sampling length. Surface is the boundary of an object that separates that object from another object, substance or space. Surface, measured is the real surface obtained by instrumental or other means.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SURFACE TEXTURE
725
Flaw
Lay
Waviness Spacing
Waviness Height
Valleys Roughness Average — Ra
Peaks
Mean Line
Roughness Spacing
Fig. 1. Pictorial Display of Surface Characteristics
Surface, nominal is the intended surface contour (exclusive of any intended surface roughness), the shape and extent of which is usually shown and dimensioned on a drawing or descriptive specification. Surface, real is the actual boundary of the object. Manufacturing processes determine its deviation from the nominal surface. Surface texture is repetitive or random deviations from the real surface that forms the three-dimensional topography of the surface. Surface texture includes roughness, waviness, lay and flaws. Fig. 1 is an example of a unidirectional lay surface. Roughness and waviness parallel to the lay are not represented in the expanded views. Waviness is the more widely spaced component of surface texture. Unless otherwise noted, waviness includes all irregularities whose spacing is greater than the roughness sampling length and less than the waviness sampling length. Waviness may result from
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 726
SURFACE TEXTURE
such factors as machine or work deflections, vibration, chatter, heat-treatment or warping strains. Roughness may be considered as being superposed on a ‘wavy’ surface. Definitions of Terms Relating to the Measurement of Surface Texture.—T e r m s regarding surface texture pertain to the geometric irregularities of surfaces and include roughness, waviness and lay. Profile is the contour of the surface in a plane measured normal, or perpendicular, to the surface, unless another other angle is specified. Graphical centerline. See Mean Line. Height (z) is considered to be those measurements of the profile in a direction normal, or perpendicular, to the nominal profile. For digital instruments, the profile Z(x) is approximated by a set of digitized values. Height parameters are expressed in micrometers (µm). Height range (z) is the maximum peak-to-valley surface height that can be detected accurately with the instrument. It is measurement normal, or perpendicular, to the nominal profile and is another key specification. Mean line (M) is the line about which deviations are measured and is a line parallel to the general direction of the profile within the limits of the sampling length. See Fig. 2. The mean line may be determined in one of two ways. The filtered mean line is the centerline established by the selected cutoff and its associated circuitry in an electronic roughness average measuring instrument. The least squares mean line is formed by the nominal profile but by dividing into selected lengths the sum of the squares of the deviations minimizes the deviation from the nominal form. The form of the nominal profile could be a curve or a straight line. Peak is the point of maximum height on that portion of a profile that lies above the mean line and between two intersections of the profile with the mean line. Profile measured is a representation of the real profile obtained by instrumental or other means. When the measured profile is a graphical representation, it will usually be distorted through the use of different vertical and horizontal magnifications but shall otherwise be as faithful to the profile as technically possible. Profile, modified is the measured profile where filter mechanisms (including the instrument datum) are used to minimize certain surface texture characteristics and emphasize others. Instrument users apply profile modifications typically to differentiate surface roughness from surface waviness. Profile, nominal is the profile of the nominal surface; it is the intended profile (exclusive of any intended roughness profile). Profile is usually drawn in an x-z coordinate system. See Fig. 2. Measure profile
Z
X Nominal profile Fig. 2. Nominal and Measured Profiles
Profile, real is the profile of the real surface. Profile, total is the measured profile where the heights and spacing may be amplified differently but otherwise no filtering takes place. Roughness profile is obtained by filtering out the longer wavelengths characteristic of waviness. Roughness spacing is the average spacing between adjacent peaks of the measured profile within the roughness sampling length.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SURFACE TEXTURE
727
Roughness topography is the modified topography obtained by filtering out the longer wavelengths of waviness and form error. Sampling length is the nominal spacing within which a surface characteristic is determined. The range of sampling lengths is a key specification of a measuring instrument. Spacing is the distance between specified points on the profile measured parallel to the nominal profile. Spatial (x) resolution is the smallest wavelength which can be resolved to 50% of the actual amplitude. This also is a key specification of a measuring instrument. System height resolution is the minimum height that can be distinguished from background noise of the measurement instrument. Background noise values can be determined by measuring approximate rms roughness of a sample surface where actual roughness is significantly less than the background noise of the measuring instrument. It is a key instrumentation specification. Topography is the three-dimensional representation of geometric surface irregularities. Topography, measured is the three-dimensional representation of geometric surface irregularities obtained by measurement. Topography, modified is the three-dimensional representation of geometric surface irregularities obtained by measurement but filtered to minimize certain surface characteristics and accentuate others. Valley is the point of maximum depth on that portion of a profile that lies below the mean line and between two intersections of the profile with the mean line. Waviness, evaluation length (L), is the length within which waviness parameters are determined. Waviness, long-wavelength cutoff (lcw) the spatial wavelength above which the undulations of waviness profile are removed to identify form parameters. A digital Gaussian filter can be used to separate form error from waviness but its use must be specified. Waviness profile is obtained by filtering out the shorter roughness wavelengths characteristic of roughness and the longer wavelengths associated with the part form parameters. Waviness sampling length is a concept no longer used. See waviness long-wavelength cutoff and waviness evaluation length. Waviness short-wavelength cutoff (lsw) is the spatial wavelength below which roughness parameters are removed by electrical or digital filters. Waviness topography is the modified topography obtained by filtering out the shorter wavelengths of roughness and the longer wavelengths associated with form error. Waviness spacing is the average spacing between adjacent peaks of the measured profile within the waviness sampling length. Sampling Lengths.—Sampling length is the normal interval for a single value of a surface parameter. Generally it is the longest spatial wavelength to be included in the profile measurement. Range of sampling lengths is an important specification for a measuring instrument.
Sampling Length
l
l
l
l
l
Evaluation length, L
Traverse Length Fig. 3. Traverse Length
Roughness sampling length (l) is the sampling length within which the roughness average is determined. This length is chosen to separate the profile irregularities which are des-
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 728
SURFACE TEXTURE
ignated as roughness from those irregularities designated as waviness. It is different from evaluation length (L) and the traversing length. See Fig. 3. Evaluation length (L) is the length the surface characteristics are evaluated. The evaluation length is a key specification of a measuring instrument. Traversing length is profile length traversed to establish a representative evaluation length. It is always longer than the evaluation length. See Section 4.4.4 of ANSI/ASME B46.1-1995 for values which should be used for different type measurements. Cutoff is the electrical response characteristic of the measuring instrument which is selected to limit the spacing of the surface irregularities to be included in the assessment of surface texture. Cutoff is rated in millimeters. In most electrical averaging instruments, the cutoff can be user selected and is a characteristic of the instrument rather than of the surface being measured. In specifying the cutoff, care must be taken to choose a value which will include all the surface irregularities to be assessed. Waviness sampling length (l) is a concept no longer used. See waviness long-wavelength cutoff and waviness evaluation length. Roughness Parameters.—Roughness is the fine irregularities of the surface texture resulting from the production process or material condition. Roughness average (Ra), also known as arithmetic average (AA) is the arithmetic average of the absolute values of the measured profile height deviations divided by the evaluation length, L. This is shown as the shaded area of Fig. 4 and generally includes sampling lengths or cutoffs. For graphical determinations of roughness average, the height deviations are measured normal, or perpendicular, to the chart center line. Y'
Mean line
X
f a b
c
d
e
g
h
i
j
p k
l
m n
q
r
s
t u
o
v
w
X'
Y
Fig. 4.
Roughness average is expressed in micrometers (µm). A micrometer is one millionth of a meter (0.000001 meter). A microinch (µin) is one millionth of an inch (0.000001 inch). One microinch equals 0.0254 micrometer (1 µin. = 0.0254 µm). Roughness Average Value (Ra) From Continuously Averaging Meter Reading m a y b e made of readings from stylus-type instruments of the continuously averaging type. To ensure uniform interpretation, it should be understood that the reading that is considered significant is the mean reading around which the needle tends to dwell or fluctuate with a small amplitude. Roughness is also indicated by the root-mean-square (rms) average, which is the square root of the average value squared, within the evaluation length and measured from the mean line shown in Fig. 4, expressed in micrometers. A roughness-measuring instrument calibrated for rms average usually reads about 11 per cent higher than an instrument calibrated for arithmetical average. Such instruments usually can be recalibrated to read arithmetical average. Some manufacturers consider the difference between rms and AA to be small enough that rms on a drawing may be read as AA for many purposes. Roughness evaluation length (L), for statistical purposes should, whenever possible, consist of five sampling lengths (l). Use of other than five sampling lengths must be clearly indicated.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SURFACE TEXTURE
729
Waviness Parameters.—Waviness is the more widely spaced component of surface texture. Roughness may be thought of as superimposed on waviness. Waviness height (Wt) is the peak-to-valley height of the modified profile with roughness and part form errors removed by filtering, smoothing or other means. This value is typically three or more times the roughness average. The measurement is taken normal, or perpendicular, to the nominal profile within the limits of the waviness sampling length. Waviness evaluation length (Lw) is the evaluation length required to determine waviness parameters. For waviness, the sampling length concept is no longer used. Rather, only waviness evaluation length (Lw) and waviness long-wavelength cutoff (lew) are defined. For better statistics, the waviness evaluation length should be several times the waviness long-wavelength cutoff. Relation of Surface Roughness to Tolerances.—Because the measurement of surface roughness involves the determination of the average linear deviation of the measured surface from the nominal surface, there is a direct relationship between the dimensional tolerance on a part and the permissible surface roughness. It is evident that a requirement for the accurate measurement of a dimension is that the variations introduced by surface roughness should not exceed the dimensional tolerances. If this is not the case, the measurement of the dimension will be subject to an uncertainty greater than the required tolerance, as illustrated in Fig. 5. Roughness Height
Roughness Mean Line
Profile Height
Uncertainty In Measurement
Roughness Mean Line
Roughness Height
Profile Height
Fig. 5.
The standard method of measuring surface roughness involves the determination of the average deviation from the mean surface. On most surfaces the total profile height of the surface roughness (peak-to-valley height) will be approximately four times (4×) the measured average surface roughness. This factor will vary somewhat with the character of the surface under consideration, but the value of four may be used to establish approximate profile heights. From these considerations it follows that if the arithmetical average value of surface roughness specified on a part exceeds one eighth of the dimensional tolerance, the whole tolerance will be taken up by the roughness height. In most cases, a smaller roughness specification than this will be found; but on parts where very small dimensional tolerances are given, it is necessary to specify a suitably small surface roughness so useful dimensional measurements can be made. The tables on pages pages 652 and 679 show the relations between machining processes and working tolerances. Values for surface roughness produced by common processing methods are shown in Table 1. The ability of a processing operation to produce a specific surface roughness depends on many factors. For example, in surface grinding, the final surface depends on the peripheral speed of the wheel, the speed of the traverse, the rate of feed, the grit size, bonding material and state of dress of the wheel, the amount and type of lubrication at the
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 730
SURFACE TEXTURE Table 1. Surface Roughness Produced by Common Production Methods
Process
Roughness Average, Ra – Micrometers µm (Microinches µin.) 50 25 12.5 6.3 3.2 1.6 0.80 0.40 0.20 (2000) (1000) (500) (250) (125) (63) (32) (16) (8)
Flame Cutting Snagging Sawing Planing, Shaping Drilling Chemical Milling Elect. Discharge Mach. Milling Broaching Reaming Electron Beam Laser Electro-Chemical Boring, Turning Barrel Finishing Electrolytic Grinding Roller Burnishing Grinding Honing Electro-Polish Polishing Lapping Superfinishing Sand Casting Hot Rolling Forging Perm. Mold Casting Investment Casting Extruding Cold Rolling, Drawing Die Casting The ranges shown above are typical of the processes listed Higher or lower values may be obtained under special conditions
KEY
0.10 (4)
0.05 (2)
0.025 (1)
0.012 (0.5)
Average Application Less Frequent Application
point of cutting, and the mechanical properties of the piece being ground. A small change in any of the above factors can have a marked effect on the surface produced. Instrumentation for Surface Texture Measurement.—Instrumentation used for measurement of surface texture, including roughness and waviness generally falls into six types. These include: Type I, Profiling Contact Skidless Instruments: Used for very smooth to very rough surfaces. Used for roughness and may measure waviness. Can generate filtered or unfiltered profiles and may have a selection of filters and parameters for data analysis. Examples include: 1) skidless stylus-type with LVDT (linear variable differential transformer) vertical transducers; 2) skidless-type using an interferometric transducer; 3)skidless stylustype using capacitance transducer. Type II, Profiling Non-contact Instruments: Capable of full profiling or topographical analysis. Non-contact operation may be advantageous for softness but may vary with sample type and reflectivity. Can generate filtered or unfiltered profiles but may have difficulty with steeply inclined surfaces. Examples include: 1) interferometric microscope; 2) optical focus sending; 3) Nomarski differential profiling; 4) laser triangulation; 5) scanning electron microscope (SEM) stereoscopy; 6) confocal optical microscope. Type III, Scanned Probe Microscope: Feature high spatial resolution (at or near the atomic scale) but area of measurement may be limited. Examples include: 1) scanning tunneling microscope (STM) and 2) atomic force microscope (AFM).
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SURFACE TEXTURE
731
Type IV, Profiling Contact Skidded Instruments: Uses a skid as a datum to eliminate longer wavelengths; thus cannot be used for waviness or errors of form. May have a selection of filters and parameters and generates an output recording of filtered and skid-modified profiles. Examples include: 1) skidded, stylus-type with LVDT vertical measuring transducer and 2) fringe-field capacitance (FFC) transducer. Type V, Skidded Instruments with Parameters Only: Uses a skid as a datum to eliminate longer wavelengths; thus cannot be used for waviness or errors of form. Does not generate a profile. Filters are typically 2RC type and generate Ra but other parameters may be available. Examples include: 1) skidded, stylus-type with piezoelectric measuring transducer and 2) skidded, stylus-type with moving coil measuring transducer. Type VI, Area Averaging Methods: Used to measure averaged parameters over defined areas but do not generate profiles. Examples include: 1) parallel plate capacitance (PPC) method; 2) total integrated scatter (TIS); 3) angle resolved scatter (ARS)/bi-directional reflectance distribution function (BRDF). Selecting Cutoff for Roughness Measurements.—In general, surfaces will contain irregularities with a large range of widths. Surface texture instruments are designed to respond only to irregularity spacings less than a given value, called cutoff. In some cases, such as surfaces in which actual contact area with a mating surface is important, the largest convenient cutoff will be used. In other cases, such as surfaces subject to fatigue failure only the irregularities of small width will be important, and more significant values will be obtained when a short cutoff is used. In still other cases, such as identifying chatter marks on machined surfaces, information is needed on only the widely space irregularities. For such measurements, a large cutoff value and a larger radius stylus should be used. The effect of variation in cutoff can be understood better by reference to Fig. 6. The profile at the top is the true movement of a stylus on a surface having a roughness spacing of about 1 mm and the profiles below are interpretations of the same surface with cutoff value settings of 0.8 mm, 0.25 mm and 0.08 mm, respectively. It can be seen that the trace based on 0.8 mm cutoff includes most of the coarse irregularities and all of the fine irregularities of the surface. The trace based on 0.25 mm excludes the coarser irregularities but includes the fine and medium fine. The trace based on 0.08 mm cutoff includes only the very fine irregularities. In this example the effect of reducing the cutoff has been to reduce the roughness average indication. However, had the surface been made up only of irregularities as fine as those of the bottom trace, the roughness average values would have been the same for all three cutoff settings. In other words, all irregularities having a spacing less than the value of the cutoff used are included in a measurement. Obviously, if the cutoff value is too small to include coarser irregularities of a surface, the measurements will not agree with those taken with a larger cutoff. For this reason, care must be taken to choose a cutoff value which will include all of the surface irregularities it is desired to assess. To become proficient in the use of continuously averaging stylus-type instruments the inspector or machine operator must realize that for uniform interpretation, the reading which is considered significant is the mean reading around which the needle tends to dwell or fluctuate under small amplitude. Drawing Practices for Surface Texture Symbols.—American National Standard ANSI/ASME Y14.36M-1996 establishes the method to designate symbolic controls for surface texture of solid materials. It includes methods for controlling roughness, waviness, and lay, and provides a set of symbols for use on drawings, specifications, or other documents. The standard is expressed in SI metric units but U.S. customary units may be used without prejudice. Units used (metric or non-metric) should be consistent with the other units used on the drawing or documents. Approximate non-metric equivalents are shown for reference.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 732
SURFACE TEXTURE
Fig. 6. Effects of Various Cutoff Values
Surface Texture Symbol.—The symbol used to designate control of surface irregularities is shown in Fig. 7b and Fig. 7d. Where surface texture values other than roughness average are specified, the symbol must be drawn with the horizontal extension as shown in Fig. 7f. Use of Surface Texture Symbols: When required from a functional standpoint, the desired surface characteristics should be specified. Where no surface texture control is specified, the surface produced by normal manufacturing methods is satisfactory provided it is within the limits of size (and form) specified in accordance with ANSI/ASME Y14.5M-1994, Dimensioning and Tolerancing. It is considered good practice to always specify some maximum value, either specifically or by default (for example, in the manner of the note shown in Fig. 2). Material Removal Required or Prohibited: The surface texture symbol is modified when necessary to require or prohibit removal of material. When it is necessary to indicate that a surface must be produced by removal of material by machining, specify the symbol shown in Fig. 7b. When required, the amount of material to be removed is specified as shown in Fig. 7c, in millimeters for metric drawings and in inches for non-metric drawings. Tolerance for material removal may be added to the basic value shown or specified in a general note. When it is necessary to indicate that a surface must be produced without material removal, specify the machining prohibited symbol as shown in Fig. 7d. Proportions of Surface Texture Symbols: The recommended proportions for drawing the surface texture symbol are shown in Fig. 7f. The letter height and line width should be the same as that for dimensions and dimension lines.
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Machinery's Handbook 27th Edition SURFACE TEXTURE
733
Surface Texture Symbols and Construction Symbol
Meaning Basic Surface Texture Symbol. Surface may be produced by any method except when the bar or circle (Fig. 7b or 7d) is specified.
Fig. 7a.
Fig. 7b.
Fig. 7c.
Material Removal By Machining Is Required. The horizontal bar indicates that material removal by machining is required to produce the surface and that material must be provided for that purpose. Material Removal Allowance. The number indicates the amount of stock to be removed by machining in millimeters (or inches). Tolerances may be added to the basic value shown or in general note.
Fig. 7d.
Material Removal Prohibited. The circle in the vee indicates that the surface must be produced by processes such as casting, forging, hot finishing, cold finishing, die casting, powder metallurgy or injection molding without subsequent removal of material.
Fig. 7e.
Surface Texture Symbol. To be used when any surface characteristics are specified above the horizontal line or the right of the symbol. Surface may be produced by any method except when the bar or circle (Fig. 7b and 7d) is specified.
Fig. 7f.
Applying Surface Texture Symbols.—The point of the symbol should be on a line representing the surface, an extension line of the surface, or a leader line directed to the surface, or to an extension line. The symbol may be specified following a diameter dimension. Although ANSI/ASME Y14.5M-1994, “Dimensioning and Tolerancing” specifies that normally all textual dimensions and notes should be read from the bottom of the drawing, the surface texture symbol itself with its textual values may be rotated as required. Regardless, the long leg (and extension) must be to the right as the symbol is read. For parts requiring extensive and uniform surface roughness control, a general note may be added to the drawing which applies to each surface texture symbol specified without values as shown in Fig. 8. When the symbol is used with a dimension, it affects the entire surface defined by the dimension. Areas of transition, such as chamfers and fillets, shall conform with the roughest adjacent finished area unless otherwise indicated. Surface texture values, unless otherwise specified, apply to the complete surface. Drawings or specifications for plated or coated parts shall indicate whether the surface texture values apply before plating, after plating, or both before and after plating. Only those values required to specify and verify the required texture characteristics should be included in the symbol. Values should be in metric units for metric drawing and non-metric units for non-metric drawings. Minority units on dual dimensioned drawings are enclosed in brackets.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 734
SURFACE TEXTURE
Fig. 8. Application of Surface Texture Symbols
Roughness and waviness measurements, unless otherwise specified, apply in a direction which gives the maximum reading; generally across the lay. Cutoff or Roughness Sampling Length, (l): Standard values are listed in Table 2. When no value is specified, the value 0.8 mm (0.030 in.) applies. Table 2. Standard Roughness Sampling Length (Cutoff) Values mm 0.08 0.25 0.80
in. 0.003 0.010 0.030
mm 2.5 8.0 25.0
in. 0.1 0.3 1.0
Roughness Average (Ra): The preferred series of specified roughness average values is given in Table 3. Table 3. Preferred Series Roughness Average Values (Ra) µm
µin
µm
µin
µm
µin
0.012
0.5
0.025a
1a
160 200
2a 3
16a 20 25
4.0 5.0
0.050a 0.075a 0.10a 0.125 0.15
0.40a 0.50 0.63 0.80a 1.00 1.25
32a 40 50
6.3a 8.0 10.0
250a 320 400
0.20a 0.25 0.32
8a 10 13
1.60a 2.0 2.5
63a 80 100
12.5a 15 20
500a 600 800
3.2a
125a
25a …
1000a …
4a 5 6
a Recommended
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SURFACE TEXTURE
735
Waviness Height (Wt): The preferred series of maximum waviness height values is listed in Table 3. Waviness height is not currently shown in U.S. or ISO Standards. It is included here to follow present industry practice in the United States. Table 4. Preferred Series Maximum Waviness Height Values mm
in.
mm
in.
mm
in.
0.0005 0.0008 0.0012 0.0020 0.0025 0.005
0.00002 0.00003 0.00005 0.00008 0.0001 0.0002
0.008 0.012 0.020 0.025 0.05 0.08
0.0003 0.0005 0.0008 0.001 0.002 0.003
0.12 0.20 0.25 0.38 0.50 0.80
0.005 0.008 0.010 0.015 0.020 0.030
Lay: Symbols for designating the direction of lay are shown and interpreted in Table 5. Example Designations.—Table 6 illustrates examples of designations of roughness, waviness, and lay by insertion of values in appropriate positions relative to the symbol. Where surface roughness control of several operations is required within a given area, or on a given surface, surface qualities may be designated, as in Fig. 9a. If a surface must be produced by one particular process or a series of processes, they should be specified as shown in Fig. 9b. Where special requirements are needed on a designated surface, a note should be added at the symbol giving the requirements and the area involved. An example is illustrated in Fig. 9c. Surface Texture of Castings.—Surface characteristics should not be controlled on a drawing or specification unless such control is essential to functional performance or appearance of the product. Imposition of such restrictions when unnecessary may increase production costs and in any event will serve to lessen the emphasis on the control specified for important surfaces. Surface characteristics of castings should never be considered on the same basis as machined surfaces. Castings are characterized by random distribution of non-directional deviations from the nominal surface. Surfaces of castings rarely need control beyond that provided by the production method necessary to meet dimensional requirements. Comparison specimens are frequently used for evaluating surfaces having specific functional requirements. Surface texture control should not be specified unless required for appearance or function of the surface. Specification of such requirements may increase cost to the user. Engineers should recognize that different areas of the same castings may have different surface textures. It is recommended that specifications of the surface be limited to defined areas of the casting. Practicality of and methods of determining that a casting’s surface texture meets the specification shall be coordinated with the producer. The Society of Automotive Engineers standard J435 “Automotive Steel Castings” describes methods of evaluating steel casting surface texture used in the automotive and related industries. Metric Dimensions on Drawings.—The length units of the metric system that are most generally used in connection with any work relating to mechanical engineering are the meter (39.37 inches) and the millimeter (0.03937 inch). One meter equals 1000 millimeters. On mechanical drawings, all dimensions are generally given in millimeters, no matter how large the dimensions may be. In fact, dimensions of such machines as locomotives and large electrical apparatus are given exclusively in millimeters. This practice is adopted to avoid mistakes due to misplacing decimal points, or misreading dimensions as when other units are used as well. When dimensions are given in millimeters, many of them can be given without resorting to decimal points, as a millimeter is only a little more than 1⁄32 inch. Only dimensions of precision need be given in decimals of a millimeter; such dimensions are generally given in hundredths of a millimeter—for example, 0.02 millimeter,
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Machinery's Handbook 27th Edition 736
SURFACE TEXTURE Table 5. Lay Symbols Lay Symbol
Meaning
Example Showing Direction of Tool Marks
Lay approximately parallel to the line representing the surface to which the symbol is applied.
Lay approximately perpendicular to the line representing the surface to which the symbol is applied.
X
Lay angular in both directions to line representing the surface to which the symbol is applied.
M
Lay multidirectional
C
Lay approximately circular relative to the center of the surface to which the symbol is applied.
R
Lay approximately radial relative to the center of the surface to which the symbol is applied.
P
Lay particulate, non-directional, or protuberant
which is equal to 0.0008 inch. As 0.01 millimeter is equal to 0.0004 inch, dimensions are seldom given with greater accuracy than to hundredths of a millimeter. Scales of Metric Drawings: Drawings made to the metric system are not made to scales of 1⁄2, 1⁄4, 1⁄8, etc., as with drawings made to the English system. If the object cannot be drawn full size, it may be drawn 1⁄2, 1⁄5, 1⁄10 , 1⁄20, 1⁄50 , 1⁄100 , 1⁄200 , 1⁄500 , or 1⁄1000 size. If the object is too small and has to be drawn larger, it is drawn 2, 5, or 10 times its actual size.
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Machinery's Handbook 27th Edition SURFACE TEXTURE
737
Table 6. Application of Surface Texture Values to Symbol Roughness average rating is placed at the left of the long leg. The specification of only one rating shall indicate the maximum value and any lesser value shall be acceptable. Specify in micrometers (microinch).
Material removal by machining is required to produce the surface. The basic amount of stock provided forf material removal is specified at the left of the short leg of the symbol. Specify in millimeters (inch).
The specification of maximum and minimum roughness average values indicates permissible range of roughness. Specify in micrometers (microinch).
Removal of material is prohibited.
Maximum waviness height rating is the first rating place above the horizontal extension. Any lesser rating shall be acceptable. Specify in millimeters (inch). Maximum waviness spacing rating is the second rating placed above the horizontal extension and to the right of the waviness height rating. Any lesser rating shall be acceptable. Specify in millimeters (inch).
Lay designation is indicated by the lay symbol placed at the right of the long leg. Roughness sampling length or cutoff rating is placed below the horizontal extension. When no value is shown, 0.80 mm (0.030 inch) applies. Specify in millimeters (inch). Where required maximum roughness spacing shall be placed at the right of the lay symbol. Any lesser rating shall be acceptable. Specify in millimeters (inch).
Table 7. Examples of Special Designations
Fig. 9a.
Fig. 9b.
Fig. 9c.
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Machinery's Handbook 27th Edition 738
ISO SURFACE FINISH ISO Surface Finish
Differences Between ISO and ANSI Surface Finish Symbology.—ISO surface finish standards are comprised of numerous individual standards that taken as a whole form a set of standards roughly comparable in scope to American National Standard ANSI/ASME Y14.36M. The primary standard dealing with surface finish, ISO 1302:1992, is concerned with the methods of specifying surface texture symbology and additional indications on engineering drawings. The parameters in ISO surface finish standards relate to surfaces produced by abrading, casting, coating, cutting, etching, plastic deformation, sintering, wear, erosion, and some other methods. ISO 1302 defines how surface texture and its constituents, roughness, waviness, and lay, are specified on the symbology. Surface defects are specifically excluded from consideration during inspection of surface texture, but definitions of flaws and imperfections are discussed in ISO 8785. As with American National Standard ASME Y14.36M, ISO 1302 is not concerned with luster, appearance, color, corrosion resistance, wear resistance, hardness, sub-surface microstructure, surface integrity, and many other characteristics that may govern considerations in specific applications. Visually, the ISO surface finish symbol is similar to the ANSI symbol, but the proportions of the symbol in relationship to text height differs from ANSI, as do some of the parameters as described in Fig. 10. Examples of the application of the ISO surface finish symbol are illustrated in Table 10. The ISO 1302 standard does not define the degrees of surface roughness and waviness or type of lay for specific purposes, nor does it specify the means by which any degree of such irregularities may be obtained or produced. Also, errors of form such as out-of-roundness and out-of-flatness are not addressed in the ISO surface finish standards. Other ISO Standards Related To Surface Finish ISO 468:1982
“Surface roughness — parameters. Their values and general rules for specifying requirements.” ISO 4287:1997 “Surface texture: Profile method — Terms, definitions and surface texture parameters.” ISO 4288:1996 “Surface texture: Profile method — Rules and procedures for the assessment of surface texture.” Includes specifications for precision reference specimens, and roughness comparison specimens, and establishes requirements for stylus-type instruments.” ISO 8785:1998 “Surface imperfections — Terms, definitions and parameters.” ISO 10135-1:CD “Representation of parts produced by shaping processes — Part 1: Molded parts.”
Rules for Comparing Measured Values to Specified Limits.—Max rule: When a maximum requirement is specified for a surface finish parameter on a drawing (e.g. Rz1.5max), none of the inspected values may extend beyond the upper limit over the entire surface. MAX must be added to the parametric symbol in the surface finish symbology on the drawing. 16% rule: When upper and lower limits are specified, no more than 16% of all measured values of the selected parameter within the evaluation length may exceed the upper limit. No more than 16% of all measured values of the selected parameter within the evaluation length may be less than the lower limit.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition ISO SURFACE FINISH Production method
Roughness value in micrometers preceded by parameter symbol
Basic symbol for surface under consideration or to a specification explained elsewhere in a note
a
Machine allowance
Roughness value other than Ra (micrometers)
b c/f
e Basic symbol for a surface to be machined
739
d Surface pattern
Basic symbol for material removal prohibited and left in the state from a previous manufacturing process
In future versions of 1302, all roughness values will be allowed at location 'a' only Waviness height preceded by parametric symbol or sampling length (millimeters)
a2 x'
c / f1
a1
x
Basic symbol with all round circle added to indicate the surface specification applies to all surfaces in that view
e
Text height h (ISO 3098-1)
d'
b
f2
d
h
2.5
3.5
5
7
10
14
Line width for symbols
d and d'
0.25
0.35
0.5
0.7
1
1.2
2
Height for segment
x
3.5
5
7
10
14
20
28
8
11
15
21
30
42
60
Height for symbol segment
x'
20
Fig. 10. ISO Surface Finish Symbol
ISO Surface Parameter Symbols Rp = max height profile Rv = max profile valley depth Rz* = max height of the profile Rc = mean height of profile Rt = total height of the profile Ra = arithmetic mean deviation of the profile Rq = root mean square deviation of the profile Rsk = skewness of the profile Rku = kurtosis of the profile RSm = mean width of the profile R∆q = root mean square slope of the profile Rmr = material ration of the profile
Rδc = profile section height difference Ip = sampling length – primary profile lw = sampling length – waviness profile lr = sampling length – roughness profile ln = evaluation length Z(x) = ordinate value dZ /dX = local slope Zp = profile peak height Zv = profile valley depth Zt = profile element height Xs = profile element width Ml = material length of profile
Exceptions to the 16% rule: Where the measured values of roughness profiles being inspected follow a normal distribution, the 16% rule may be overridden. This is allowed when greater than 16% of the measured values exceed the upper limit, but the total roughness profile conforms with the sum of the arithmetic mean and standard deviation (µ + σ). Effectively this means that the greater the value of σ, the further µ must be from the upper limit (see Fig. 11). Basic rules for determining cut-off wavelength: When the sampling length is specified on the drawing or in documentation, the cut-off wavelength λc is equal to the sample length. When no sampling length is specified, the cut-off wavelength is estimated using Table 8.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 740
ISO SURFACE FINISH
Upper limit of surface texture parameter
Fig. 11.
Basic rules for measurement of roughness parameters: For non-periodic roughness the parameter Ra, Rz, Rz1max or RSm are first estimated using visual inspection, comparison to specimens, graphic analysis, etc. The sampling length is then selected from Table 8, based on the use of Ra, Rz, Rz1max or RSm. Then with instrumentation, a representative sample is taken using the sampling length chosen above.
Ra, µm
Rz, Rz1max, µm
RSm, µm
Sampling length, lr (mm)
Curves for Periodic and Non-periodic Profiles
Evaluation length, ln (mm)
Table 8. Sampling Lengths Curves for Non-periodic Profiles such as Ground Surfaces
(0.006) < Ra ≤ 0.02
(0.025) < Rz, Rz1max ≤ 0.1
0.013 < RSm ≤ 0.04
0.08
0.4
0.02 < Ra ≤ 0.1
0.1 < Rz, Rz1max ≤ 0.5
0.04 < RSm ≤ 0.13
0.25
1.25
0.1 < Ra ≤ 2
0.5 < Rz, Rz1max ≤ 10
0.13 < RSm ≤ 0.4
0.8
4
2 < Ra ≤ 10
10 < Rz, Rz1max ≤ 50
0.4 < RSm ≤ 1.3
2.5
12.5
10 < Ra ≤ 80
50 < Rz, Rz1max ≤ 200
1.3 < RSm ≤ 4
8
40
For Ra, Rq, Rsk, Rku, R∆q
For Rz, Rv, Rp, Rc, Rt
For R-parameters and RSm
The measured values are then compared to the ranges of values in Table 8 for the particular parameter. If the value is outside the range of values for the estimated sampling length, the measuring instrument is adjusted for the next higher or lower sampling length and the measurement repeated. If the final setting corresponds to Table 8, then both the sampling length setting and Ra, Rz, Rz1max or RSm values are correct and a representative measurement of the parameter can be taken. For periodic roughness, the parameter RSm is estimated graphically and the recommended cut-off values selected using Table 8. If the value is outside the range of values for the estimated sampling length, the measuring instrument is adjusted for the next higher or lower sampling length and the measurement repeated. If the final setting corresponds to Table 8, then both the sampling length setting and RSm values are correct and a representative measurement of the parameter can be taken. Table 9. Preferred Roughness Values and Roughness Grades Roughness values, Ra µm µin 50 25 12.5 6.3 3.2 1.6
2000 1000 500 250 125 63
Previous Grade Number from ISO 1302 N12 N11 N10 N9 N8 N7
Roughness values, Ra µm µin 0.8 0.4 0.2 0.1 0.05 0.025
Previous Grade Number from ISO 1302
32 16 8 4 2 1
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N6 N5 N4 N3 N2 N1
Machinery's Handbook 27th Edition ISO SURFACE FINISH
741
Table 10. Examples of ISO Applications of Surface Texture Symbology Interpretation
Example
Surface roughness is produced by milling and between upper limit of Ra = 50 µm and Ra = 6.3 µm; direction of lay is crossed in oblique directions relative to plane of projection; sampling length is 5 mm. Surface roughness of Rz = 6.3 µm is the default for all surfaces as indicated by the Rz = 6.3 specification, plus basic symbol within parentheses. Any deviating specification is called out with local notes such as the Ra = 0.8 µm specification. Surface roughness is produced by grinding to Ra = 1.2 µm and limited to Ry = 6.3 µm max; direction of lay is perpendicular relative to the plane of projection; sampling length is 2.4 mm.
Ra 50 Ra 6.3
5 X
Rz 6.3
( )
Ra 0.8
ground Ra 1.2
2.4/Ry 6.3 MAX
Fe/Ni20pCr
Surface treatment without any machining; nickel-chrome plated to Rz = 1 µm on all surfaces.
Rz 1
Fe/Ni10bCr 0,8 2,5/Rz 16 2,5/Rz 6.3
Ra 3.2
R3
Surface is nickel-chrome plated to roughness of Ra = 3.2 µm with a sampling length of 0.8 mm; limited to Rz = 16 µm to Rz = 6.3 µm with a sampling length of 2.5 mm.
milled
Ra 1.6
Ra 0.8
Surface roughness of Rz = 6.3 µm is the default for all surfaces except the inside diameter which is Ra = 0.8 mm.
Surface texture symbology may be combined with dimension leaders and witness (extension) lines.
Ra 0.8 2x45˚
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Machinery's Handbook 27th Edition 742
ISO SURFACE FINISH
Table 10. (Continued) Examples of ISO Applications of Surface Texture Symbology Interpretation
Example
Ra 1. 6
Ra
Rz 4.0
R3
43
45
Surface texture symbology may be applied to extended extension lines or on extended projection lines.
0.8
Rz 40
Surface roughness is produced by milling and between upper limit of Ra = 50 µm and Ra = 6.3 µm; direction of lay is crossed in oblique directions relative to plane of projection; sampling length is 5 mm.
3x Ø5
Ground Fe/Cr 50 Ry 6.2 Ry 1.6
Ø45
Surface treatment without any machining; nickel-chrome plated to Rz = 1 µm on all surfaces.
30 Chromium plated
a2 Surface texture characteristics may be specified both before and after surface treatment.
Ø
Built-up surface The symbol may be expanded with additional lines for textual information where there is insufficient room on the drawing.
a1
Ground
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition PRECISION GAGE BLOCKS
743
Gage Blocks Precision Gage Blocks.—Precision gage blocks are usually purchased in sets comprising a specific number of blocks of different sizes. The nominal gage lengths of individual blocks in a set are determined mathematically so that particular desired lengths can be obtained by combining selected blocks. They are made to several different tolerance grades which categorize them as master blocks, calibration blocks, inspection blocks, and workshop blocks. Master blocks are employed as basic reference standards; calibration blocks are used for high precision gaging work and calibrating inspection blocks; inspection blocks are used as toolroom standards and for checking and setting limit and comparator gages, for example. The workshop blocks are working gages used as shop standards for a variety of direct precision measurements and gaging applications, including sine-bar settings. Federal Specification GGG-G-15C, Gage Blocks (see below), lists typical sets, and gives details of materials, design, and manufacturing requirements, and tolerance grades. When there is in a set no single block of the exact size that is wanted, two or more blocks are combined by “wringing” them together. Wringing is achieved by first placing one block crosswise on the other and applying some pressure. Then a swiveling motion is used to twist the blocks to a parallel position, causing them to adhere firmly to one another. When combining blocks for a given dimension, the object is to use as few blocks as possible to obtain the dimension. The procedure for selecting blocks is based on successively eliminating the right-hand figure of the desired dimension. Example:Referring to gage block set number 1 in Table 1, determine the blocks required to obtain 3.6742 inches. Step 1: Eliminate 0.0002 by selecting a 0.1002 block. Subtract 0.1002 from 3.6743 = 3.5740. Step 2: Eliminate 0.004 by selecting a 0.124 block. Subtract 0.124 from 3.5740 = 3.450. Step 3: Eliminate 0.450 with a block this size. Subtract 0.450 from 3.450 = 3.000. Step 4: Select a 3.000 inch block. The combined blocks are 0.1002 + 0.124 + 0.450 + 3.000 = 3.6742 inches. Federal Specification for Gage Blocks, Inch and Metric Sizes.—This Specification, GGG-G-15C, March 20, 1975, which supersedes GGG-G-15B, November 6, 1970, covers design, manufacturing, and purchasing details for precision gage blocks in inch and metric sizes up to and including 20 inches and 500 millimeters gage lengths. The shapes of blocks are designated Style 1, which is rectangular; Style 2, which is square with a center accessory hole, and Style 3, which defines other shapes as may be specified by the purchaser. Blocks may be made from steel, chromium-plated steel, chromium carbide, or tungsten carbide. There are four tolerance grades, which are designated Grade 0.5 (formerly Grade AAA in the GGG-G-15A issue of the Specification); Grade 1 (formerly Grade AA); Grade 2 (formerly Grade A +); and Grade 3 (a compromise between former Grades A and B). Grade 0.5 blocks are special reference gages used for extremely high precision gaging work, and are not recommended for general use. Grade 1 blocks are laboratory reference standards used for calibrating inspection gage blocks and high precision gaging work. Grade 2 blocks are used as inspection and toolroom standards, and Grade 3 blocks are used as shop standards. Inch and metric sizes of blocks in specific sets are given in Tables 1 and 2, which is not a complete list of available sizes. It should be noted that some gage blocks must be ordered as specials, some may not be available in all materials, and some may not be available from all manufacturers. Gage block set number 4 (88 blocks), listed in the Specification, is not given in Table 1. It is the same as set number 1 (81 blocks) but contains seven additional blocks measuring 0.0625, 0.078125, 0.093750, 0.100025, 0.100050, 0.100075, and 0.109375 inch. In Table 2, gage block set number 3M (112 blocks) is not given. It is similar to set number 2M (88 blocks), and the chief difference is the inclusion of a larger number of blocks in the 0.5 millimeter increment series up to 24.5 mm. Set numbers 5M (88 blocks), 6M (112 blocks), and 7M (17 blocks) also are not listed.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 744
PRECISION GAGE BLOCKS Table 1. Gage Block Sets—Inch Sizes Federal Specification GGG-G-15C Set Number 1 (81 Blocks)
.1001
First Series: 0.0001 Inch Increments (9 Blocks) .1003 .1004 .1005 .1006 .1007
.1002
.101 .111 .121 .131 .141
.102 .112 .122 .132 .142
.103 .113 .123 .133 .143
.050 .550
.100 .600
.150 .650
Second Series: 0.001 Inch Increments (49 Blocks) .104 .105 .106 .107 .114 .115 .116 .117 .124 .125 .126 .127 .134 .135 .136 .137 .144 .145 .146 .147 Third Series: 0.050 Inch Increments (19 Blocks) .200 .250 .300 .350 .700 .750 .800 .850
.1008
.1009
.108 .118 .128 .138 .148
.109 .119 .129 .139 .149
.110 .120 .130 .140
.400 .900
.450 .950
.500
Fourth Series: 1.000 Inch Increments (4 Blocks) 2.000 3.000
1.000
4.000
Set Number 5 (21 Blocks) .0101
First Series: 0.0001 Inch Increments (9 Blocks) .0103 .0104 .0105 .0106 .0107
.0102
.010
.011
Second Series: 0.001 Inch Increments (11 Blocks) .013 .014 .015 .016 .017 One Block 0.01005 Inch
.012
.0108 .018
.0109
.019
.020
Set Number 6 (28 Blocks) .0201
.0202
.021
.022
.010
.020
First Series: 0.0001 Inch Increments (9 Blocks) .0203 .0204 .0205 .0206 .0207 Second Series: 0.001 Inch Increments (9 Blocks) .023 .024 .025 .026 .027 Third Series: 0.010 Inch Increments (9 Blocks) .030 .040 .050 .060 .070 One Block 0.02005 Inch
.0208
.0209
.028
.029
.080
.090
Long Gage Block Set Number 7 (8 Blocks) 5
6
7
Whole Inch Series (8 Blocks) 8 10 12
16
20
Set Number 8 (36 Blocks) .1001 .100 .120
First Series: 0.0001 Inch Increments (9 Blocks) .1003 .1004 .1005 .1006 .1007
.1002 .101
.102 .130
Second Series: 0.001 Inch Increments (11 Blocks) .103 .104 .105 .106 .107
.1008 .108
Third Series: 0.010 Inch Increments (8 Blocks) .140 .150 .160 .170
.109
.180
Fourth Series: 0.100 Inch Increments (4 Blocks) .300 .400
.200 1
Whole Inch Series (3 Blocks) 2 One Block 0.050 Inch
.1009 .110 .190
.500 4
Set Number 9 (20 Blocks) .0501 .050
.0502 .051
First Series: 0.0001 Inch Increments (9 Blocks) .0503 .0504 .0505 .0506 .0507 Second Series: 0.001 Inch Increments (10 Blocks) .052 .053 .054 .055 .056 .057 One Block 0.05005 Inch
.0508
.0509
.058
.059
Set number 4 is not shown, and the Specification does not list a set 2 or 3. Arranged here in incremental series for convenience of use.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition PRECISION GAGE BLOCKS
745
Table 2. Gage Block Sets—Metric Sizes Federal Specification GGG-G-15C Set Number 1M (45 Blocks) First Series: 0.001 Millimeter Increments (9 Blocks) 1.001
1.002
1.003
1.004
1.005
1.006
1.007
1.008
1.009
1.08
1.09
1.80
1.90
7.0
8.0
9.0
70
80
90
1.008
1.009
Second Series: 0.01 Millimeter Increments (9 Blocks) 1.01
1.02
1.03
1.04
1.05
1.06
1.07
Third Series: 0.10 Millimeter Increments (9 Blocks) 1.10
1.20
1.30
1.40
1.50
1.60
1.70
Fourth Series: 1.0 Millimeter Increments (9 Blocks) 1.0
2.0
3.0
4.0
5.0
6.0
Fifth Series: 10 Millimeter Increments (9 Blocks) 10
20
30
40
50
60
Set Number 2M (88 Blocks) First Series: 0.001 Millimeter Increments (9 Blocks) 1.001
1.002
1.003
1.004
1.005
1.006
1.007
Second Series: 0.01 Millimeter Increments (49 Blocks) 1.01
1.02
1.03
1.04
1.05
1.06
1.07
1.08
1.09
1.10
1.11
1.12
1.13
1.14
1.15
1.16
1.17
1.18
1.19
1.20
1.21
1.22
1.23
1.24
1.25
1.26
1.27
1.28
1.29
1.30
1.31
1.32
1.33
1.34
1.35
1.36
1.37
1.38
1.39
1.40
1.41
1.42
1.43
1.44
1.45
1.46
1.47
1.48
1.49
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.5
6.0
6.5
7.0
7.5
8.0
8.5
9.0
9.5
10
20
30
80
90
Third Series: 0.50 Millimeter Increments (19 Blocks) 5.0
Fourth Series: 10 Millimeter Increments (10 Blocks) 40
50
60
70
100
One Block 1.0005 mm Set Number 4M (45 Blocks) First Series: 0.001 Millimeter Increments (9 Blocks) 2.001
2.002
2.003
2.004
2.005
2.006
2.007
2.008
2.009
2.08
2.09
2.7
2.8
2.9
7.0
8.0
9.0
70
80
90
Second Series: 0.01 Millimeter Increments (9 Blocks) 2.01
2.02
2.03
2.04
2.05
2.06
2.07
Third Series: 0.10 Millimeter Increments (9 Blocks) 2.1
2.2
2.3
2.4
2.5
2.6
Fourth Series: 1 Millimeter Increments (9 Blocks) 1.0
2.0
3.0
4.0
5.0
6.0
Fifth Series: 10 Millimeter Increments (9 Blocks) 10
20
30
40
50
60
Long Gage Block Set Number 8M (8 Blocks) Whole Millimeter Series (8 Blocks) 125
150
175
200
250
300
400
500
Set numbers 3M, 5M, 6M, and 7M are not listed. Arranged here in incremental series for convenience of use. Note: Gage blocks measuring 1.09 millimeters and under in set number 1M, blocks measuring 1.5 millimeters and under in set number 2M, and block measuring 1.0 millimeter in set number 4M are not available in tolerance grade 0.5.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TABLE OF CONTENTS MACHINING OPERATIONS CUTTING SPEEDS AND FEEDS 1009 Indroduction to Speeds and Feeds 1009 Cutting Tool Materials 1013 Cutting Speeds 1014 Cutting Conditions 1014 Selecting Cutting Conditions 1014 Tool Troubleshooting 1016 Cutting Speed Formulas 1018 RPM for Various Cutting Speeds and Diameter
SPEED AND FEED TABLES 1022 1022 1026 1027 1031 1032 1033 1035 1037 1038 1039 1040 1043 1044 1045 1049 1050 1052 1054 1056 1057 1059 1060 1061 1066 1067 1068 1070 1071 1072 1072 1074 1075 1075 1077 1079 1080 1081
How to Use the Tables Principal Speed andFeed Tables Speed and Feed Tables for Turning Plain Carbon and Alloy Steels Tool Steels Stainless Steels Ferrous Cast Metals Speed and Tool Life Adjustments Copper Alloys Titanium and Titanium Alloys Superalloys Speed and Feed Tables for Milling Slit Milling Aluminium Alloys Plain Carbon and Alloy Steels Tool Steels Stainless Steels Ferrous Cast Metals High Speed Steel Cutters Speed Adjustment Factors Radial Depth of Cut Adjustments Tool Life Adjustments Drilling, Reaming, and Threading Plain Carbon and Alloy Steels Tool Steels Stainless Steels Ferrous Cast Metals Light Metals Adjustment Factors for HSS Copper Alloys Tapping and Threading Cutting Speed for Broaching Spade Drills Spade Drill Geometry Spade Drilling Feed Rates Power Consumption Trepanning
ESTIMATING SPEEDS AND MACHINING POWER 1082 1082 1082 1082 1082 1084 1084 1085 1085 1088 1090 1090 1091 1091 1091
Planer Cutting Speeds Cutting Speed and Time Planing Time Speeds for Metal-Cutting Saws Turning Unusual Material Estimating Machining Power Power Constants Feed Factors Tool Wear Factors Metal Removal Rates Estimating Drilling Thrust, Torque, and Power Work Material Factor Chisel Edge Factors Feed Factors Drill Diameter Factors
MACHINING ECONOMETRICS 1093 Tool Wear And Tool Life Relationships 1093 Equivalent Chip Thickness (ECT) 1094 Tool-life Relationships 1098 The G- and H-curves 1099 Tool-life Envelope 1102 Forces and Tool-life 1104 Surface Finish and Tool-life 1106 Shape of Tool-life Relationships 1107 Minimum Cost 1108 Production Rate 1108 The Cost Function 1109 Global Optimum 1110 Economic Tool-life 1113 Machine Settings and Cost Calculations 1113 Nomenclature 1114 Cutting Formulas 1118 Tooling And Total Cost 1119 Optimized Data 1122 High-speed Machining Econometrics 1123 Chip Geometry in Milling 1125 Chip Thickness 1127 Forces and Tool-life 1128 High-speed Milling 1129 Econometrics Comparison
1005
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TABLE OF CONTENTS MACHINING OPERATIONS SCREW MACHINE FEEDS AND SPEEDS 1131 Automatic Screw Machine Tools 1131 Knurling 1131 Revolution for Knurling 1131 Cams for Threading 1132 Cutting Speeds and Feeds 1134 Spindle Revolutions 1135 Practical Points on Cam 1136 Stock for Screw Machine Products 1138 Band Saw Blade Selection 1139 Tooth Forms 1139 Types of Blades 1140 Band Saw Speed and Feed Rate 1141 Bimetal Band Saw Speeds 1142 Band Saw Blade Break-In
GRINDING FEEDS AND SPEEDS 1158 Basic Rules 1158 Wheel life T and Grinding Ratio 1159 ECT in Grinding 1160 Optimum Grinding Data 1162 Surface Finish, Ra 1163 Spark-out Time 1164 Grinding Cutting Forces 1165 Grinding Data 1166 Grindability Groups 1166 Side Feed, Roughing and Finishing 1167 Relative Grindability 1168 Grindability Overview 1168 Procedure to Determine Data 1174 Calibration of Recommendations 1176 Optimization
GRINDING AND OTHER ABRASIVE PROCESSES
CUTTING FLUIDS 1144 Types of Fluids 1144 Cutting Oils 1144 Water-Miscible Fluids 1145 Selection of Cutting Fluids 1146 Turning, Milling, Drilling and Tapping 1147 Machining 1148 Machining Magnesium 1149 Metalworking Fluids 1149 Classes of Metalworking Fluids 1149 Occupational Exposures 1150 Fluid Selection, Use, and Application 1151 Fluid Maintenance 1152 Respiratory Protection
MACHINING NONFERROUS METALS AND NON-METALLIC MATERIALS 1153 Machining Nonferrous Metals 1153 Aluminium 1154 Magnesium 1155 Zinc Alloy Die-Castings 1155 Monel and Nickel Alloys 1156 Copper Alloys 1156 Machining Non-metals 1156 Hard Rubber 1156 Formica Machining 1157 Micarta Machining 1157 Ultrasonic Machining
1177 Grinding Wheels 1177 Abrasive Materials 1178 Bond Properties 1178 Structure 1179 ANSI Markings 1179 Sequence of Markings 1180 ANSI Shapes and Sizes 1180 Selection of Grinding Wheel 1181 Standard Shapes Ranges 1188 Grinding Wheel Faces 1189 Classification of Tool Steels 1190 Hardened Tool Steels 1194 Constructional Steels 1195 Cubic Boron Nitride 1196 Dressing and Truing 1196 Tools and Methods for Dressing and Truing 1198 Guidelines for Truing and Dressing 1199 Diamond Truing and Crossfeeds 1200 Size Selection Guide 1200 Minimum Sizes for Single-Point Truing Diamonds
1006
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TABLE OF CONTENTS MACHINING OPERATIONS GRINDING AND OTHER ABRASIVE PROCESSES
GRINDING AND OTHER ABRASIVE PROCESSES
(Continued)
(Continued)
1201 Diamond Wheels 1201 Shapes 1202 Core Shapes and Designations 1202 Cross-sections and Designations 1203 Designations for Location 1204 Composition 1205 Designation Letters 1206 Selection of Diamond Wheels 1206 Abrasive Specification 1207 Handling and Operation 1207 Speeds and Feeds 1207 Grinding Wheel Safety 1207 Safety in Operating 1208 Handling, Storage and Inspection 1208 Machine Conditions 1208 Grinding Wheel Mounting 1209 Safe Operating Speeds 1210 Portable Grinders 1212 Cylindrical Grinding 1212 Plain, Universal, and LimitedPurpose Machines 1212 Traverse or Plunge Grinding 1212 Work Holding on Machines 1213 Work-Holding Methods 1213 Selection of Grinding Wheels 1214 Wheel Recommendations 1214 Operational Data 1215 Basic Process Data 1215 High-Speed 1216 Areas and Degrees of Automation 1216 Troubles and Their Correction 1220 Centerless Grinding 1221 Through-feed Method of Grinding 1221 In-feed Method 1221 End-feed Method 1221 Automatic Centerless Method 1221 Centerless Grinding 1222 Surface Grinding 1223 Principal Systems 1225 Grinding Wheel Recommendations 1226 Process Data for Surface Grinding 1226 Basic Process Data 1227 Faults and Possible Causes
1229 1229 1229 1229 1230 1230 1230 1230 1233 1233 1233 1234 1234 1235 1235 1235 1235 1236 1236 1237 1237 1237 1238 1238 1238 1238 1238 1239 1239 1239
Offhand Grinding Floor- and Bench-Stand Grinding Portable Grinding Swing-Frame Grinding Abrasive Belt Grinding Application of Abrasive Belts Selection Contact Wheels Abrasive Cutting Cutting-Off Difficulties Honing Process Rate of Stock Removal Formula for Rotative Speeds Factors in Rotative Speed Formulas Eliminating Undesirable Honing Conditions Tolerances Laps and Lapping Material for Laps Laps for Flat Surfaces Grading Abrasives Charging Laps Rotary Diamond Lap Grading Diamond Dust Cutting Properties Cutting Qualities Wear of Laps Lapping Abrasives Effect on Lapping Lubricants Lapping Pressures Wet and Dry Lapping Lapping Tests
KNURLS AND KNURLING 1240 Knurls and Knurling 1240 ANSI Standard 1240 Preferred Sizes 1240 Specifications 1241 Cylindrical Tools 1242 Flat Tools 1242 Specifications for Flat Dies 1242 Formulas to Knurled Work 1243 Tolerances 1244 Marking on Knurls and Dies 1244 Concave Knurls
1007
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TABLE OF CONTENTS MACHINING OPERATIONS MACHINE TOOL ACCURACY 1248 1249
Degrees of Accuracy Expected with NC Machine Tool Part Tolerances
NUMERICAL CONTROL 1254 1254 1254 1255 1258 1262 1262 1262 1263 1264 1264 1264 1267
Introduction CNC Technology Numerical Control vs. Manual Operations Numerical Control Standards Programmable Controller Closed-Loop System Open-Loop System Adaptive Control Flexible Manufacturing Systems Flexible Manufacturing Cell Flexible Manufacturing Module Axis Nomenclature Total Indicator Reading
NUMERICAL CONTROL PROGRAMMING 1269 Programming 1272 Postprocessors 1272 G-Code Programming 1272 Format Classification 1272 Letter Addresses 1274 Sequence Number (N-Word) 1274 Preparatory Word (G-Word) 1278 Miscellaneous Functions 1279 Feed Function (F-Word) 1280 Spindle Function (S-Word) 1280 Tool Function (T-Word) 1282 Linear Interpolation 1283 Circular Interpolation 1284 Helical and Parabolic Interpolation 1285 Subroutine 1287 Conditional Expressions 1287 Fixed (Canned) Cycles 1291 Turning Cycles 1291 Thread Cutting
NUMERICAL CONTROL PROGRAMMING (Continued)
1292 APT Programming 1294 APT Computational Statements 1294 APT Geometry Statements 1295 Points, Lines and Circles 1299 APT Motion Statements 1300 Contouring Cutter Movements 1301 Circles and Planes 1303 3-D Geometry 1304 APT Postprocessor Statements 1306 APT Example Program 1307 APT for Turning 1309 Indexable Insert Holders for NC 1310 Insert Radius Compensation 1312 Threading Tool Insert Radius 1313 V-Flange Tool Shanks 1314 Retention Knobs
CAD/CAM 1315 1317 1318 1322 1322 1324 1324 1325 1325
CAD/CAM Drawing Projections Drawing Tips and Traps Sizes of Lettering on Drawing Drawing Exchange Standards Rapid Automated Prototyping DNC Machinery Noise Measuring Machinery Noise
1008
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINING OPERATIONS
1009
CUTTING SPEEDS AND FEEDS Indroduction to Speeds and Feeds Work Materials.—The large number of work materials that are commonly machined vary greatly in their basic structure and the ease with which they can be machined. Yet it is possible to group together certain materials having similar machining characteristics, for the purpose of recommending the cutting speed at which they can be cut. Most materials that are machined are metals and it has been found that the most important single factor influencing the ease with which a metal can be cut is its microstructure, followed by any cold work that may have been done to the metal, which increases its hardness. Metals that have a similar, but not necessarily the same microstructure, will tend to have similar machining characteristics. Thus, the grouping of the metals in the accompanying tables has been done on the basis of their microstructure. With the exception of a few soft and gummy metals, experience has shown that harder metals are more difficult to cut than softer metals. Furthermore, any given metal is more difficult to cut when it is in a harder form than when it is softer. It is more difficult to penetrate the harder metal and more power is required to cut it. These factors in turn will generate a higher cutting temperature at any given cutting speed, thereby making it necessary to use a slower speed, for the cutting temperature must always be kept within the limits that can be sustained by the cutting tool without failure. Hardness, then, is an important property that must be considered when machining a given metal. Hardness alone, however, cannot be used as a measure of cutting speed. For example, if pieces of AISI 11L17 and AISI 1117 steel both have a hardness of 150 Bhn, their recommended cutting speeds for high-speed steel tools will be 140 fpm and 130 fpm, respectively. In some metals, two entirely different microstructures can produce the same hardness. As an example, a fine pearlite microstructure and a tempered martensite microstructure can result in the same hardness in a steel. These microstructures will not machine alike. For practical purposes, however, information on hardness is usually easier to obtain than information on microstructure; thus, hardness alone is usually used to differentiate between different cutting speeds for machining a metal. In some situations, the hardness of a metal to be machined is not known. When the hardness is not known, the material condition can be used as a guide. The surface of ferrous metal castings has a scale that is more difficult to machine than the metal below. Some scale is more difficult to machine than others, depending on the foundry sand used, the casting process, the method of cleaning the casting, and the type of metal cast. Special electrochemical treatments sometimes can be used that almost entirely eliminate the effect of the scale on machining, although castings so treated are not frequently encountered. Usually, when casting scale is encountered, the cutting speed is reduced approximately 5 or 10 per cent. Difficult-to-machine surface scale can also be encountered when machining hot-rolled or forged steel bars. Metallurgical differences that affect machining characteristics are often found within a single piece of metal. The occurrence of hard spots in castings is an example. Different microstructures and hardness levels may occur within a casting as a result of variations in the cooling rate in different parts of the casting. Such variations are less severe in castings that have been heat treated. Steel bar stock is usually harder toward the outside than toward the center of the bar. Sometimes there are slight metallurgical differences along the length of a bar that can affect its cutting characteristics. Cutting Tool Materials.—The recommended cutting feeds and speeds in the accompanying tables are given for high-speed steel, coated and uncoated carbides, ceramics, cermets, and polycrystalline diamonds. More data are available for HSS and carbides because these materials are the most commonly used. Other materials that are used to make cutting tools are cemented oxides or ceramics, cermets, cast nonferrous alloys (Stellite), singlecrystal diamonds, polycrystalline diamonds, and cubic boron nitride.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1010
SPEEDS AND FEEDS
Carbon Tool Steel: It is used primarily to make the less expensive drills, taps, and reamers. It is seldom used to make single-point cutting tools. Hardening in carbon steels is very shallow, although some have a small amount of vanadium and chromium added to improve their hardening quality. The cutting speed to use for plain carbon tool steel should be approximately one-half of the recommended speed for high-speed steel. High-Speed Steel: This designates a number of steels having several properties that enhance their value as cutting tool material. They can be hardened to a high initial or roomtemperature hardness ranging from 63 Rc to 65 Rc for ordinary high-speed steels and up to 70 Rc for the so-called superhigh-speed steels. They can retain sufficient hardness at temperatures up to 1,000 to 1,100°F to enable them to cut at cutting speeds that will generate these tool temperatures, and they will return to their original hardness when cooled to room temperature. They harden very deeply, enabling high-speed steels to be ground to the tool shape from solid stock and to be reground many times without sacrificing hardness at the cutting edge. High-speed steels can be made soft by annealing so that they can be machined into complex cutting tools such as drills, reamers, and milling cutters and then hardened. The principal alloying elements of high-speed steels are tungsten (W), molybdenum (Mo), chromium (Cr), vanadium (V), together with carbon (C). There are a number of grades of high-speed steel that are divided into two types: tungsten high-speed steels and molybdenum high-speed steels. Tungsten high-speed steels are designated by the prefix T before the number that designates the grade. Molybdenum high-speed steels are designated by the prefix letter M. There is little performance difference between comparable grades of tungsten or molybdenum high-speed steel. The addition of 5 to 12 per cent cobalt to high-speed steel increases its hardness at the temperatures encountered in cutting, thereby improving its wear resistance and cutting efficiency. Cobalt slightly increases the brittleness of high-speed steel, making it susceptible to chipping at the cutting edge. For this reason, cobalt high-speed steels are primarily made into single-point cutting tools that are used to take heavy roughing cuts in abrasive materials and through rough abrasive surface scales. The M40 series and T15 are a group of high-hardness or so-called super high-speed steels that can be hardened to 70 Rc; however, they tend to be brittle and difficult to grind. For cutting applications, they are usually heat treated to 67–68 Rc to reduce their brittleness and tendency to chip. The M40 series is appreciably easier to grind than T15. They are recommended for machining tough die steels and other difficult-to-cut materials; they are not recommended for applications where conventional high-speed steels perform well. Highspeed steels made by the powder-metallurgy process are tougher and have an improved grindability when compared with similar grades made by the customary process. Tools made of these steels can be hardened about 1 Rc higher than comparable high-speed steels made by the customary process without a sacrifice in toughness. They are particularly useful in applications involving intermittent cutting and where tool life is limited by chipping. All these steels augment rather than replace the conventional high-speed steels. Cemented Carbides: They are also called sintered carbides or simply carbides. They are harder than high-speed steels and have excellent wear resistance. Information on cemented carbides and other hard metal tools is included in the section CEMENTED CARBIDES starting on page 773. Cemented carbides retain a very high degree of hardness at temperatures up to 1400°F and even higher; therefore, very fast cutting speeds can be used. When used at fast cutting speeds, they produce good surface finishes on the workpiece. Carbides are more brittle than high-speed steel and, therefore, must be used with more care. Hundreds of grades of carbides are available and attempts to classify these grades by area of application have not been entirely successful. There are four distinct types of carbides: 1) straight tungsten carbides; 2) crater-resistant carbides; 3) titanium carbides; and 4) coated carbides.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPEEDS AND FEEDS
1011
Straight Tungsten Carbide: This is the most abrasion-resistant cemented carbide and is used to machine gray cast iron, most nonferrous metals, and nonmetallic materials, where abrasion resistance is the primary criterion. Straight tungsten carbide will rapidly form a crater on the tool face when used to machine steel, which reduces the life of the tool. Titanium carbide is added to tungsten carbide in order to counteract the rapid formation of the crater. In addition, tantalum carbide is usually added to prevent the cutting edge from deforming when subjected to the intense heat and pressure generated in taking heavy cuts. Crater-Resistant Carbides: These carbides, containing titanium and tantalum carbides in addition to tungsten carbide, are used to cut steels, alloy cast irons, and other materials that have a strong tendency to form a crater. Titanium Carbides: These carbides are made entirely from titanium carbide and small amounts of nickel and molybdenum. They have an excellent resistance to cratering and to heat. Their high hot hardness enables them to operate at higher cutting speeds, but they are more brittle and less resistant to mechanical and thermal shock. Therefore, they are not recommended for taking heavy or interrupted cuts. Titanium carbides are less abrasion-resistant and not recommended for cutting through scale or oxide films on steel. Although the resistance to cratering of titanium carbides is excellent, failure caused by crater formation can sometimes occur because the chip tends to curl very close to the cutting edge, thereby forming a small crater in this region that may break through. Coated Carbides: These are available only as indexable inserts because the coating would be removed by grinding. The principal coating materials are titanium carbide (TiC), titanium nitride (TiN), and aluminum oxide (Al2O3). A very thin layer (approximately 0.0002 in.) of coating material is deposited over a cemented carbide insert; the material below the coating is called the substrate. The overall performance of the coated carbide is limited by the substrate, which provides the required toughness and resistance to deformation and thermal shock. With an equal tool life, coated carbides can operate at higher cutting speeds than uncoated carbides. The increase may be 20 to 30 per cent and sometimes up to 50 per cent faster. Titanium carbide and titanium nitride coated carbides usually operate in the medium (200–800 fpm) cutting speed range, and aluminum oxide coated carbides are used in the higher (800–1600 fpm) cutting speed range. Carbide Grade Selection: The selection of the best grade of carbide for a particular application is very important. An improper grade of carbide will result in a poor performance—it may even cause the cutting edge to fail before any significant amount of cutting has been done. Because of the many grades and the many variables that are involved, the carbide producers should be consulted to obtain recommendations for the application of their grades of carbide. A few general guidelines can be given that are useful to form an orientation. Metal cutting carbides usually range in hardness from about 89.5 Ra (Rockwell A Scale) to 93.0 Ra with the exception of titanium carbide, which has a hardness range of 90.5 Ra to 93.5 Ra. Generally, the harder carbides are more wear-resistant and more brittle, whereas the softer carbides are less wear-resistant but tougher. A choice of hardness must be made to suit the given application. The very hard carbides are generally used for taking light finishing cuts. For other applications, select the carbide that has the highest hardness with sufficient strength to prevent chipping or breaking. Straight tungsten carbide grades should always be used unless cratering is encountered. Straight tungsten carbides are used to machine gray cast iron, ferritic malleable iron, austenitic stainless steel, high-temperature alloys, copper, brass, bronze, aluminum alloys, zinc alloy die castings, and plastics. Crater-resistant carbides should be used to machine plain carbon steel, alloy steel, tool steel, pearlitic malleable iron, nodular iron, other highly alloyed cast irons, ferritic stainless steel, martensitic stainless steel, and certain high-temperature alloys. Titanium carbides are recommended for taking high-speed finishing and semifinishing cuts on steel, especially the low-carbon, low-alloy steels, which are less abrasive and have a strong tendency to form a crater. They are also used to take light cuts on alloy cast iron and on
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Machinery's Handbook 27th Edition 1012
SPEEDS AND FEEDS
some high-nickel alloys. Nonferrous materials, such as some aluminum alloys and brass, that are essentially nonabrasive may also be machined with titanium carbides. Abrasive materials and others that should not be machined with titanium carbides include gray cast iron, titanium alloys, cobalt- and nickel-base superalloys, stainless steel, bronze, many aluminum alloys, fiberglass, plastics, and graphite. The feed used should not exceed about 0.020 inch per revolution. Coated carbides can be used to take cuts ranging from light finishing to heavy roughing on most materials that can be cut with these carbides. The coated carbides are recommended for machining all free-machining steels, all plain carbon and alloy steels, tool steels, martensitic and ferritic stainless steels, precipitation-hardening stainless steels, alloy cast iron, pearlitic and martensitic malleable iron, and nodular iron. They are also recommended for taking light finishing and roughing cuts on austenitic stainless steels. Coated carbides should not be used to machine nickel- and cobalt-base superalloys, titanium and titanium alloys, brass, bronze, aluminum alloys, pure metals, refractory metals, and nonmetals such as fiberglass, graphite, and plastics. Ceramic Cutting Tool Materials: These are made from finely powdered aluminum oxide particles sintered into a hard dense structure without a binder material. Aluminum oxide is also combined with titanium carbide to form a composite, which is called a cermet. These materials have a very high hot hardness enabling very high cutting speeds to be used. For example, ceramic cutting tools have been used to cut AISI 1040 steel at a cutting speed of 18,000 fpm with a satisfactory tool life. However, much lower cutting speeds, in the range of 1000 to 4000 fpm and lower, are more common because of limitations placed by the machine tool, cutters, and chucks. Although most applications of ceramic and cermet cutting tool materials are for turning, they have also been used successfully for milling. Ceramics and cermets are relatively brittle and a special cutting edge preparation is required to prevent chipping or edge breakage. This preparation consists of honing or grinding a narrow flat land, 0.002 to 0.006 inch wide, on the cutting edge that is made about 30 degrees with respect to the tool face. For some heavy-duty applications, a wider land is used. The setup should be as rigid as possible and the feed rate should not normally exceed 0.020 inch, although 0.030 inch has been used successfully. Ceramics and cermets are recommended for roughing and finishing operations on all cast irons, plain carbon and alloy steels, and stainless steels. Materials up to a hardness of 60 Rockwell C Scale can be cut with ceramic and cermet cutting tools. These tools should not be used to machine aluminum and aluminum alloys, magnesium alloys, titanium, and titanium alloys. Cast Nonferrous Alloy: Cutting tools of this alloy are made from tungsten, tantalum, chromium, and cobalt plus carbon. Other alloying elements are also used to produce materials with high temperature and wear resistance. These alloys cannot be softened by heat treatment and must be cast and ground to shape. The room-temperature hardness of cast nonferrous alloys is lower than for high-speed steel, but the hardness and wear resistance is retained to a higher temperature. The alloys are generally marketed under trade names such as Stellite, Crobalt, and Tantung. The initial cutting speed for cast nonferrous tools can be 20 to 50 per cent greater than the recommended cutting speed for high-speed steel as given in the accompanying tables. Diamond Cutting Tools: These are available in three forms: single-crystal natural diamonds shaped to a cutting edge and mounted on a tool holder on a boring bar; polycrystalline diamond indexable inserts made from synthetic or natural diamond powders that have been compacted and sintered into a solid mass, and chemically vapor-deposited diamond. Single-crystal and polycrystalline diamond cutting tools are very wear-resistant, and are recommended for machining abrasive materials that cause other cutting tool materials to wear rapidly. Typical of the abrasive materials machined with single-crystal and polycrystalline diamond tools and cutting speeds used are the following: fiberglass, 300 to 1000 fpm; fused silica, 900 to 950 fpm; reinforced melamine plastics, 350 to 1000 fpm; reinforced phenolic plastics, 350 to 1000 fpm; thermosetting plastics, 300 to 2000 fpm; Teflon,
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPEEDS AND FEEDS
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600 fpm; nylon, 200 to 300 fpm; mica, 300 to 1000 fpm; graphite, 200 to 2000 fpm; babbitt bearing metal, 700 fpm; and aluminum-silicon alloys, 1000 to 2000 fpm. Another important application of diamond cutting tools is to produce fine surface finishes on soft nonferrous metals that are difficult to finish by other methods. Surface finishes of 1 to 2 microinches can be readily obtained with single-crystal diamond tools, and finishes down to 10 microinches can be obtained with polycrystalline diamond tools. In addition to babbitt and the aluminum-silicon alloys, other metals finished with diamond tools include: soft aluminum, 1000 to 2000 fpm; all wrought and cast aluminum alloys, 600 to 1500 fpm; copper, 1000 fpm; brass, 500 to 1000 fpm; bronze, 300 to 600 fpm; oilite bearing metal, 500 fpm; silver, gold, and platinum, 300 to 2500 fpm; and zinc, 1000 fpm. Ferrous alloys, such as cast iron and steel, should not be machined with diamond cutting tools because the high cutting temperatures generated will cause the diamond to transform into carbon. Chemically Vapor-Deposited (CVD) Diamond: This is a new tool material offering performance characteristics well suited to highly abrasive or corrosive materials, and hard-tomachine composites. CVD diamond is available in two forms: thick-film tools, which are fabricated by brazing CVD diamond tips, approximately 0.020 inch (0.5 mm) thick, to carbide substrates; and thin-film tools, having a pure diamond coating over the rake and flank surfaces of a ceramic or carbide substrate. CVD is pure diamond, made at low temperatures and pressures, with no metallic binder phase. This diamond purity gives CVD diamond tools extreme hardness, high abrasion resistance, low friction, high thermal conductivity, and chemical inertness. CVD tools are generally used as direct replacements for PCD (polycrystalline diamond) tools, primarily in finishing, semifinishing, and continuous turning applications of extremely wear-intensive materials. The small grain size of CVD diamond (ranging from less than 1 µm to 50 µm) yields superior surface finishes compared with PCD, and the higher thermal conductivity and better thermal and chemical stability of pure diamond allow CVD tools to operate at faster speeds without generating harmful levels of heat. The extreme hardness of CVD tools may also result in significantly longer tool life. CVD diamond cutting tools are recommended for the following materials: a l u m i n u m and other ductile; nonferrous alloys such as copper, brass, and bronze; and highly abrasive composite materials such as graphite, carbon-carbon, carbon-filled phenolic, fiberglass, and honeycomb materials. Cubic Boron Nitride (CBN): Next to diamond, CBN is the hardest known material. It will retain its hardness at a temperature of 1800°F and higher, making it an ideal cutting tool material for machining very hard and tough materials at cutting speeds beyond those possible with other cutting tool materials. Indexable inserts and cutting tool blanks made from this material consist of a layer, approximately 0.020 inch thick, of polycrystalline cubic boron nitride firmly bonded to the top of a cemented carbide substrate. Cubic boron nitride is recommended for rough and finish turning hardened plain carbon and alloy steels, hardened tool steels, hard cast irons, all hardness grades of gray cast iron, and superalloys. As a class, the superalloys are not as hard as hardened steel; however, their combination of high strength and tendency to deform plastically under the pressure of the cut, or gumminess, places them in the class of hard-to-machine materials. Conventional materials that can be readily machined with other cutting tool materials should not be machined with cubic boron nitride. Round indexable CBN inserts are recommended when taking severe cuts in order to provide maximum strength to the insert. When using square or triangular inserts, a large lead angle should be used, normally 15°, and whenever possible, 45°. A negative rake angle should always be used, which for most applications is negative 5°. The relief angle should be 5° to 9°. Although cubic boron nitride cutting tools can be used without a coolant, flooding the tool with a water-soluble type coolant is recommended. Cutting Speed, Feed, Depth of Cut, Tool Wear, and Tool Life.—The cutting conditions that determine the rate of metal removal are the cutting speed, the feed rate, and the depth of cut. These cutting conditions and the nature of the material to be cut determine the
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Machinery's Handbook 27th Edition 1014
SPEEDS AND FEEDS
power required to take the cut. The cutting conditions must be adjusted to stay within the power available on the machine tool to be used. Power requirements are discussed in Estimating Machining Power later in this section. The cutting conditions must also be considered in relation to the tool life. Tool life is defined as the cutting time to reach a predetermined amount of wear, usually flank wear. Tool life is determined by assessing the time—the tool life—at which a given predetermined flank wear is reached (0.01, 0.015, 0.025, 0.03 inch, for example). This amount of wear is called the tool wear criterion, and its size depends on the tool grade used. Usually, a tougher grade can be used with a bigger flank wear, but for finishing operations, where close tolerances are required, the wear criterion is relatively small. Other wear criteria are a predetermined value of the machined surface roughness and the depth of the crater that develops on the rake face of the tool. The ANSI standard, Specification For Tool Life Testing With Single-Point Tools (ANSI B94.55M-1985), defines the end of tool life as a given amount of wear on the flank of a tool. This standard is followed when making scientific machinability tests with singlepoint cutting tools in order to achieve uniformity in testing procedures so that results from different machinability laboratories can be readily compared. It is not practicable or necessary to follow this standard in the shop; however, it should be understood that the cutting conditions and tool life are related. Tool life is influenced most by cutting speed, then by the feed rate, and least by the depth of cut. When the depth of cut is increased to about 10 times greater than the feed, a further increase in the depth of cut will have no significant effect on the tool life. This characteristic of the cutting tool performance is very important in determining the operating or cutting conditions for machining metals. Conversely, if the cutting speed or the feed is decreased, the increase in the tool life will be proportionately greater than the decrease in the cutting speed or the feed. Tool life is reduced when either feed or cutting speed is increased. For example, the cutting speed and the feed may be increased if a shorter tool life is accepted; furthermore, the reduction in the tool life will be proportionately greater than the increase in the cutting speed or the feed. However, it is less well understood that a higher feed rate (feed/rev × speed) may result in a longer tool life if a higher feed/rev is used in combination with a lower cutting speed. This principle is well illustrated in the speed tables of this section, where two sets of feed and speed data are given (labeled optimum and average) that result in the same tool life. The optimum set results in a greater feed rate (i.e., increased productivity) although the feed/rev is higher and cutting speed lower than the average set. Complete instructions for using the speed tables and for estimating tool life are given in How to Use the Feeds and Speeds Tables starting on page 1022. Selecting Cutting Conditions.—The first step in establishing the cutting conditions is to select the depth of cut. The depth of cut will be limited by the amount of metal that is to be machined from the workpiece, by the power available on the machine tool, by the rigidity of the workpiece and the cutting tool, and by the rigidity of the setup. The depth of cut has the least effect upon the tool life, so the heaviest possible depth of cut should always be used. The second step is to select the feed (feed/rev for turning, drilling, and reaming, or feed/tooth for milling). The available power must be sufficient to make the required depth of cut at the selected feed. The maximum feed possible that will produce an acceptable surface finish should be selected. The third step is to select the cutting speed. Although the accompanying tables provide recommended cutting speeds and feeds for many materials, experience in machining a certain material may form the best basis for adjusting the given cutting speeds to a particular job. However, in general, the depth of cut should be selected first, followed by the feed, and last the cutting speed.
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Machinery's Handbook 27th Edition SPEEDS AND FEEDS
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Table 16. Tool Troubleshooting Check List Tool Material Carbide
Problem Excessive flank wear—Tool life too short
HSS
Excessive cratering
Carbide
HSS
Cutting edge chipping
Carbide
Remedy 1. Change to harder, more wear-resistant grade 2. Reduce the cutting speed 3. Reduce the cutting speed and increase the feed to maintain production 4. Reduce the feed 5. For work-hardenable materials—increase the feed 6. Increase the lead angle 7. Increase the relief angles 1. Use a coolant 2. Reduce the cutting speed 3. Reduce the cutting speed and increase the feed to maintain production 4. Reduce the feed 5. For work-hardenable materials—increase the feed 6. Increase the lead angle 7. Increase the relief angle 1. Use a crater-resistant grade 2. Use a harder, more wear-resistant grade 3. Reduce the cutting speed 4. Reduce the feed 5. Widen the chip breaker groove 1. Use a coolant 2. Reduce the cutting speed 3. Reduce the feed 4. Widen the chip breaker groove 1. Increase the cutting speed 2. Lightly hone the cutting edge 3. Change to a tougher grade 4. Use negative-rake tools 5. Increase the lead angle 6. Reduce the feed 7. Reduce the depth of cut 8. Reduce the relief angles 9. If low cutting speed must be used, use a high-additive EP cutting fluid
HSS
1. Use a high additive EP cutting fluid 2. Lightly hone the cutting edge before using 3. Increase the lead angle 4. Reduce the feed 5. Reduce the depth of cut 6. Use a negative rake angle 7. Reduce the relief angles
Carbide and HSS
1. Check the setup for cause if chatter occurs 2. Check the grinding procedure for tool overheating 3. Reduce the tool overhang 1. Change to a grade containing more tantalum 2. Reduce the cutting speed 3. Reduce the feed 1. Increase the cutting speed 2. If low cutting speed must be used, use a high additive EP cutting fluid 4. For light cuts, use straight titanium carbide grade 5. Increase the nose radius 6. Reduce the feed 7. Increase the relief angles 8. Use positive rake tools
Cutting edge deformation
Carbide
Poor surface finish
Carbide
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Machinery's Handbook 27th Edition 1016
SPEEDS AND FEEDS Table 16. (Continued) Tool Troubleshooting Check List Tool Material HSS
Problem Poor surface finish (Continued)
Notching at the depth of cut line
Remedy 1. Use a high additive EP cutting fluid 2. Increase the nose radius 3. Reduce the feed 4. Increase the relief angles 5. Increase the rake angles
Diamond Carbide and HSS
1. Use diamond tool for soft materials 1. Increase the lead angle 2. Reduce the feed
Cutting Speed Formulas Most machining operations are conducted on machine tools having a rotating spindle. Cutting speeds are usually given in feet or meters per minute and these speeds must be converted to spindle speeds, in revolutions per minute, to operate the machine. Conversion is accomplished by use of the following formulas: For U.S. units:
For metric units:
V- rpm N = 12V ---------- = 3.82 --πD D
V- rpm N = 1000V ---------------- = 318.3 --πD D
where N is the spindle speed in revolutions per minute (rpm); V is the cutting speed in feet per minute (fpm) for U.S. units and meters per minute (m/min) for metric units. In turning, D is the diameter of the workpiece; in milling, drilling, reaming, and other operations that use a rotating tool, D is the cutter diameter in inches for U.S. units and in millimeters for metric units. π = 3.1416. Example:The cutting speed for turning a 4-inch (101.6-mm) diameter bar has been found to be 575 fpm (175.3 m/min). Using both the inch and metric formulas, calculate the lathe spindle speed. 12 × 575 = 549 rpm N = 12V ---------- = ------------------------πD 3.1416 × 4
1000 × 175.3 - = 549 rpm N = 1000V ---------------- = ----------------------------------πD 3.1416 × 101.6
When the cutting tool or workpiece diameter and the spindle speed in rpm are known, it is often necessary to calculate the cutting speed in feet or meters per minute. In this event, the following formulas are used. For U.S. units:
For metric units:
V = πDN ------------ fpm 12
πDN- m/min V = ----------1000
As in the previous formulas, N is the rpm and D is the diameter in inches for the U.S. unit formula and in millimeters for the metric formula. Example:Calculate the cutting speed in feet per minute and in meters per minute if the spindle speed of a 3⁄4-inch (19.05-mm) drill is 400 rpm. × 0.75 × 400- = 78.5 fpm V = πDN ------------ = π ---------------------------------12 12 πDN- = ------------------------------------π × 19.05 × 400- = 24.9 m/min V = ----------1000 1000
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Machinery's Handbook 27th Edition SPEEDS AND FEEDS
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Cutting Speeds and Equivalent RPM for Drills of Number and Letter Sizes Size No. 1 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 54 Size A B C D E F G H I J K L M N O P Q R S T U V W X Y Z
30′
40′
50′
503 518 548 562 576 592 606 630 647 678 712 730 754 779 816 892 988 1032 1076 1129 1169 1226 1333 1415 1508 1637 1805 2084
670 691 731 749 768 790 808 840 863 904 949 973 1005 1039 1088 1189 1317 1376 1435 1505 1559 1634 1777 1886 2010 2183 2406 2778
838 864 914 936 960 987 1010 1050 1079 1130 1186 1217 1257 1299 1360 1487 1647 1721 1794 1882 1949 2043 2221 2358 2513 2729 3008 3473
491 482 473 467 458 446 440 430 421 414 408 395 389 380 363 355 345 338 329 320 311 304 297 289 284 277
654 642 631 622 611 594 585 574 562 552 544 527 518 506 484 473 460 451 439 426 415 405 396 385 378 370
818 803 789 778 764 743 732 718 702 690 680 659 648 633 605 592 575 564 549 533 519 507 495 481 473 462
Cutting Speed, Feet per Minute 60′ 70′ 80′ 90′ 100′ Revolutions per Minute for Number Sizes 1005 1173 1340 1508 1675 1037 1210 1382 1555 1728 1097 1280 1462 1645 1828 1123 1310 1498 1685 1872 1151 1343 1535 1727 1919 1184 1382 1579 1777 1974 1213 1415 1617 1819 2021 1259 1469 1679 1889 2099 1295 1511 1726 1942 2158 1356 1582 1808 2034 2260 1423 1660 1898 2135 2372 1460 1703 1946 2190 2433 1508 1759 2010 2262 2513 1559 1819 2078 2338 2598 1631 1903 2175 2447 2719 1784 2081 2378 2676 2973 1976 2305 2634 2964 3293 2065 2409 2753 3097 3442 2152 2511 2870 3228 3587 2258 2634 3010 3387 3763 2339 2729 3118 3508 3898 2451 2860 3268 3677 4085 2665 3109 3554 3999 4442 2830 3301 3773 4244 4716 3016 3518 4021 4523 5026 3274 3820 4366 4911 5457 3609 4211 4812 5414 6015 4167 4862 5556 6251 6945 Revolutions per Minute for Letter Sizes 982 1145 1309 1472 1636 963 1124 1284 1445 1605 947 1105 1262 1420 1578 934 1089 1245 1400 1556 917 1070 1222 1375 1528 892 1040 1189 1337 1486 878 1024 1170 1317 1463 862 1005 1149 1292 1436 842 983 1123 1264 1404 827 965 1103 1241 1379 815 951 1087 1223 1359 790 922 1054 1185 1317 777 907 1036 1166 1295 759 886 1012 1139 1265 725 846 967 1088 1209 710 828 946 1065 1183 690 805 920 1035 1150 676 789 902 1014 1127 659 769 878 988 1098 640 746 853 959 1066 623 727 830 934 1038 608 709 810 912 1013 594 693 792 891 989 576 672 769 865 962 567 662 756 851 945 555 647 740 832 925
110′
130′
150′
1843 1901 2010 2060 2111 2171 2223 2309 2374 2479 2610 2676 2764 2858 2990 3270 3622 3785 3945 4140 4287 4494 4886 5187 5528 6002 6619 7639
2179 2247 2376 2434 2495 2566 2627 2728 2806 2930 3084 3164 3267 3378 3534 3864 4281 4474 4663 4892 5067 5311 5774 6130 6534 7094 7820 9028
2513 2593 2741 2809 2879 2961 3032 3148 3237 3380 3559 3649 3769 3898 4078 4459 4939 5162 5380 5645 5846 6128 6662 7074 7539 8185 9023 10417
1796 1765 1736 1708 1681 1635 1610 1580 1545 1517 1495 1449 1424 1391 1330 1301 1266 1239 1207 1173 1142 1114 1088 1058 1040 1017
2122 2086 2052 2018 1968 1932 1903 1867 1826 1793 1767 1712 1683 1644 1571 1537 1496 1465 1427 1387 1349 1317 1286 1251 1229 1202
2448 2407 2368 2329 2292 2229 2195 2154 2106 2068 2039 1976 1942 1897 1813 1774 1726 1690 1646 1600 1557 1520 1484 1443 1418 1387
For fractional drill sizes, use the following table.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1018
RPM FOR VARIOUS SPEEDS Revolutions per Minute for Various Cutting Speeds and Diameters
Dia., Inches 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
1 11⁄16 11⁄8 13⁄16 11⁄4 15⁄16 13⁄8 17⁄16 11⁄2 19⁄16 15⁄8 111⁄16 13⁄4 17⁄8 2 21⁄8 21⁄4 23⁄8 21⁄2 25⁄8 23⁄4 27⁄8 3 31⁄8 31⁄4 33⁄8 31⁄2 35⁄8 33⁄4 37⁄8 4 41⁄4 41⁄2 43⁄4 5 51⁄4 51⁄2 53⁄4 6 61⁄4 61⁄2 63⁄4 7 71⁄4 71⁄2 73⁄4 8
40
50
60
70
611 489 408 349 306 272 245 222 203 190 175 163 153 144 136 129 123 116 111 106 102 97.6 93.9 90.4 87.3 81.5 76.4 72.0 68.0 64.4 61.2 58.0 55.6 52.8 51.0 48.8 46.8 45.2 43.6 42.0 40.8 39.4 38.2 35.9 34.0 32.2 30.6 29.1 27.8 26.6 25.5 24.4 23.5 22.6 21.8 21.1 20.4 19.7 19.1
764 611 509 437 382 340 306 273 254 237 219 204 191 180 170 161 153 146 139 133 127 122 117 113 109 102 95.5 90.0 85.5 80.5 76.3 72.5 69.5 66.0 63.7 61.0 58.5 56.5 54.5 52.5 51.0 49.3 47.8 44.9 42.4 40.2 38.2 36.4 34.7 33.2 31.8 30.6 29.4 28.3 27.3 26.4 25.4 24.6 23.9
917 733 611 524 459 407 367 333 306 284 262 244 229 215 204 193 183 175 167 159 153 146 141 136 131 122 115 108 102 96.6 91.7 87.0 83.4 79.2 76.4 73.2 70.2 67.8 65.5 63.0 61.2 59.1 57.3 53.9 51.0 48.2 45.9 43.6 41.7 39.8 38.2 36.7 35.2 34.0 32.7 31.6 30.5 29.5 28.7
1070 856 713 611 535 475 428 389 357 332 306 285 267 251 238 225 214 204 195 186 178 171 165 158 153 143 134 126 119 113 107 102 97.2 92.4 89.1 85.4 81.9 79.1 76.4 73.5 71.4 69.0 66.9 62.9 59.4 56.3 53.5 50.9 48.6 46.5 44.6 42.8 41.1 39.6 38.2 36.9 35.6 34.4 33.4
Cutting Speed, Feet per Minute 80 90 100 120 Revolutions per Minute 1222 1376 1528 1834 978 1100 1222 1466 815 916 1018 1222 699 786 874 1049 611 688 764 917 543 611 679 813 489 552 612 736 444 500 555 666 408 458 508 610 379 427 474 569 349 392 438 526 326 366 407 488 306 344 382 458 287 323 359 431 272 306 340 408 258 290 322 386 245 274 306 367 233 262 291 349 222 250 278 334 212 239 265 318 204 230 254 305 195 220 244 293 188 212 234 281 181 203 226 271 175 196 218 262 163 184 204 244 153 172 191 229 144 162 180 216 136 153 170 204 129 145 161 193 122 138 153 184 116 131 145 174 111 125 139 167 106 119 132 158 102 114 127 152 97.6 110 122 146 93.6 105 117 140 90.4 102 113 136 87.4 98.1 109 131 84.0 94.5 105 126 81.6 91.8 102 122 78.8 88.6 98.5 118 76.4 86.0 95.6 115 71.8 80.8 89.8 108 67.9 76.3 84.8 102 64.3 72.4 80.4 96.9 61.1 68.8 76.4 91.7 58.2 65.4 72.7 87.2 55.6 62.5 69.4 83.3 53.1 59.8 66.4 80.0 51.0 57.2 63.6 76.3 48.9 55.0 61.1 73.3 47.0 52.8 58.7 70.4 45.3 50.9 56.6 67.9 43.7 49.1 54.6 65.5 42.2 47.4 52.7 63.2 40.7 45.8 50.9 61.1 39.4 44.3 49.2 59.0 38.2 43.0 47.8 57.4
140
160
180
200
2139 1711 1425 1224 1070 951 857 770 711 664 613 570 535 503 476 451 428 407 389 371 356 342 328 316 305 286 267 252 238 225 213 203 195 185 178 171 164 158 153 147 143 138 134 126 119 113 107 102 97.2 93.0 89.0 85.5 82.2 79.2 76.4 73.8 71.0 68.9 66.9
2445 1955 1629 1398 1222 1086 979 888 813 758 701 651 611 575 544 515 490 466 445 424 406 390 374 362 349 326 306 288 272 258 245 232 222 211 203 195 188 181 174 168 163 158 153 144 136 129 122 116 111 106 102 97.7 93.9 90.6 87.4 84.3 81.4 78.7 76.5
2750 2200 1832 1573 1375 1222 1102 999 914 853 788 733 688 646 612 580 551 524 500 477 457 439 421 407 392 367 344 324 306 290 275 261 250 238 228 219 211 203 196 189 184 177 172 162 153 145 138 131 125 120 114 110 106 102 98.3 94.9 91.6 88.6 86.0
3056 2444 2036 1748 1528 1358 1224 1101 1016 948 876 814 764 718 680 644 612 582 556 530 508 488 468 452 436 408 382 360 340 322 306 290 278 264 254 244 234 226 218 210 205 197 191 180 170 161 153 145 139 133 127 122 117 113 109 105 102 98.4 95.6
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Machinery's Handbook 27th Edition RPM FOR VARIOUS SPEEDS
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Revolutions per Minute for Various Cutting Speeds and Diameters Dia., Inches 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
1 11⁄16 11⁄8 13⁄16 11⁄4 15⁄16 13⁄8 17⁄16 11⁄2 19⁄16 15⁄8 111⁄16 13⁄4 113⁄16 17⁄8 115⁄16 2 21⁄8 21⁄4 23⁄8 21⁄2 25⁄8 23⁄4 27⁄8 3 31⁄8 31⁄4 33⁄8 31⁄2 35⁄8 33⁄4 37⁄8 4 41⁄4 41⁄2 43⁄4 5 51⁄4 51⁄2 53⁄4 6 61⁄4 61⁄2 63⁄4 7 71⁄4 71⁄2 73⁄4 8
225
250
275
300
3438 2750 2292 1964 1719 1528 1375 1250 1146 1058 982 917 859 809 764 724 687 654 625 598 573 550 528 509 491 474 458 443 429 404 382 362 343 327 312 299 286 274 264 254 245 237 229 221 214 202 191 180 171 163 156 149 143 137 132 127 122 118 114 111 107
3820 3056 2546 2182 1910 1698 1528 1389 1273 1175 1091 1019 955 899 849 804 764 727 694 664 636 611 587 566 545 527 509 493 477 449 424 402 382 363 347 332 318 305 293 283 272 263 254 246 238 224 212 201 191 181 173 166 159 152 146 141 136 131 127 123 119
4202 3362 2801 2401 2101 1868 1681 1528 1401 1293 1200 1120 1050 988 933 884 840 800 764 730 700 672 646 622 600 579 560 542 525 494 468 442 420 400 381 365 350 336 323 311 300 289 280 271 262 247 233 221 210 199 190 182 174 168 161 155 149 144 139 135 131
4584 3667 3056 2619 2292 2037 1834 1667 1528 1410 1310 1222 1146 1078 1018 965 917 873 833 797 764 733 705 679 654 632 611 591 573 539 509 482 458 436 416 398 381 366 352 339 327 316 305 295 286 269 254 241 229 218 208 199 190 183 176 169 163 158 152 148 143
Cutting Speed, Feet per Minute 325 350 375 400 Revolutions per Minute 4966 5348 5730 6112 3973 4278 4584 4889 3310 3565 3820 4074 2837 3056 3274 3492 2483 2675 2866 3057 2207 2377 2547 2717 1987 2139 2292 2445 1806 1941 2084 2223 1655 1783 1910 2038 1528 1646 1763 1881 1419 1528 1637 1746 1324 1426 1528 1630 1241 1337 1432 1528 1168 1258 1348 1438 1103 1188 1273 1358 1045 1126 1206 1287 993 1069 1146 1222 946 1018 1091 1164 903 972 1042 1111 863 930 996 1063 827 891 955 1018 794 855 916 978 764 822 881 940 735 792 849 905 709 764 818 873 685 737 790 843 662 713 764 815 640 690 739 788 620 668 716 764 584 629 674 719 551 594 636 679 522 563 603 643 496 534 573 611 472 509 545 582 451 486 520 555 431 465 498 531 413 445 477 509 397 427 458 488 381 411 440 470 367 396 424 452 354 381 409 436 342 368 395 421 331 356 382 407 320 345 369 394 310 334 358 382 292 314 337 359 275 297 318 339 261 281 301 321 248 267 286 305 236 254 272 290 225 242 260 277 215 232 249 265 206 222 238 254 198 213 229 244 190 205 220 234 183 198 212 226 177 190 204 218 171 184 197 210 165 178 190 203 160 172 185 197 155 167 179 191
425
450
500
550
6493 5195 4329 3710 3248 2887 2598 2362 2165 1998 1855 1732 1623 1528 1443 1367 1299 1237 1181 1129 1082 1039 999 962 927 895 866 838 811 764 721 683 649 618 590 564 541 519 499 481 463 447 433 419 405 383 360 341 324 308 294 282 270 259 249 240 231 223 216 209 203
6875 5501 4584 3929 3439 3056 2751 2501 2292 2116 1965 1834 1719 1618 1528 1448 1375 1309 1250 1196 1146 1100 1057 1018 982 948 917 887 859 809 764 724 687 654 625 598 572 549 528 509 490 474 458 443 429 404 382 361 343 327 312 298 286 274 264 254 245 237 229 222 215
7639 6112 5093 4365 3821 3396 3057 2779 2547 2351 2183 2038 1910 1798 1698 1609 1528 1455 1389 1329 1273 1222 1175 1132 1091 1054 1019 986 955 899 849 804 764 727 694 664 636 611 587 566 545 527 509 493 477 449 424 402 382 363 347 332 318 305 293 283 272 263 254 246 238
8403 6723 5602 4802 4203 3736 3362 3056 2802 2586 2401 2241 2101 1977 1867 1769 1681 1601 1528 1461 1400 1344 1293 1245 1200 1159 1120 1084 1050 988 933 884 840 800 763 730 700 672 646 622 600 579 560 542 525 494 466 442 420 399 381 365 349 336 322 311 299 289 279 271 262
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1020
RPM FOR VARIOUS SPEEDS
Revolutions per Minute for Various Cutting Speeds and Diameters (Metric Units) Cutting Speed, Meters per Minute Dia., mm
5
6
8
10
12
16
20
25
30
35
40
45
Revolutions per Minute 5
318
382
509
637
764
1019
1273
1592
1910
2228
2546
2865
6
265
318
424
530
637
849
1061
1326
1592
1857
2122
2387
8
199
239
318
398
477
637
796
995
1194
1393
1592
1790
10
159
191
255
318
382
509
637
796
955
1114
1273
1432
12
133
159
212
265
318
424
531
663
796
928
1061
1194
119
159
199
239
318
398
497
597
696
796
895
95.5
127
159
191
255
318
398
477
557
637
716
102
16
99.5
20
79.6
25
63.7
76.4
30
53.1
63.7
84.9
127
153
204
255
318
382
446
509
573
106
127
170
212
265
318
371
424
477
35
45.5
54.6
72.8
90.9
145
182
227
273
318
364
409
40
39.8
47.7
63.7
79.6
95.5
127
159
199
239
279
318
358 318
109
45
35.4
42.4
56.6
70.7
84.9
113
141
177
212
248
283
50
31.8
38.2
51
63.7
76.4
102
127
159
191
223
255
286
55
28.9
34.7
46.3
57.9
69.4
92.6
116
145
174
203
231
260
60
26.6
31.8
42.4
53.1
63.7
84.9
106
133
159
186
212
239
65
24.5
29.4
39.2
49
58.8
78.4
98
122
147
171
196
220
70
22.7
27.3
36.4
45.5
54.6
72.8
90.9
114
136
159
182
205
75
21.2
25.5
34
42.4
51
68
84.9
106
127
149
170
191
80
19.9
23.9
31.8
39.8
47.7
63.7
79.6
99.5
119
139
159
179
106
90
17.7
21.2
28.3
35.4
42.4
56.6
70.7
88.4
124
141
159
100
15.9
19.1
25.5
31.8
38.2
51
63.7
79.6
95.5
111
127
143
110
14.5
17.4
23.1
28.9
34.7
46.2
57.9
72.3
86.8
101
116
130
120
13.3
15.9
21.2
26.5
31.8
42.4
53.1
66.3
79.6
92.8
106
119
130
12.2
14.7
19.6
24.5
29.4
39.2
49
61.2
73.4
85.7
97.9
110
140
11.4
13.6
18.2
22.7
27.3
36.4
45.5
56.8
68.2
79.6
90.9
102
150
10.6
12.7
17
21.2
25.5
34
42.4
53.1
63.7
74.3
84.9
95.5
160
9.9
11.9
15.9
19.9
23.9
31.8
39.8
49.7
59.7
69.6
79.6
89.5
170
9.4
11.2
15
18.7
22.5
30
37.4
46.8
56.2
65.5
74.9
84.2
180
8.8
10.6
14.1
17.7
21.2
28.3
35.4
44.2
53.1
61.9
70.7
79.6
190
8.3
10
13.4
16.8
20.1
26.8
33.5
41.9
50.3
58.6
67
75.4
200
8
39.5
12.7
15.9
19.1
25.5
31.8
39.8
47.7
55.7
63.7
71.6
220
7.2
8.7
11.6
14.5
17.4
23.1
28.9
36.2
43.4
50.6
57.9
65.1
240
6.6
8
10.6
13.3
15.9
21.2
26.5
33.2
39.8
46.4
53.1
59.7
260
6.1
7.3
9.8
12.2
14.7
19.6
24.5
30.6
36.7
42.8
49
55.1
280
5.7
6.8
9.1
11.4
13.6
18.2
22.7
28.4
34.1
39.8
45.5
51.1
300
5.3
6.4
8.5
10.6
12.7
17
21.2
26.5
31.8
37.1
42.4
47.7
350
4.5
5.4
7.3
9.1
10.9
14.6
18.2
22.7
27.3
31.8
36.4
40.9
400
4
4.8
6.4
8
9.5
12.7
15.9
19.9
23.9
27.9
31.8
35.8
450
3.5
4.2
5.7
7.1
8.5
11.3
14.1
17.7
21.2
24.8
28.3
31.8
500
3.2
3.8
5.1
6.4
7.6
10.2
12.7
15.9
19.1
22.3
25.5
28.6
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RPM FOR VARIOUS SPEEDS
1021
Revolutions per Minute for Various Cutting Speeds and Diameters (Metric Units) Cutting Speed, Meters per Minute Dia., mm
50
55
60
65
70
75
80
85
90
95
100
200
Revolutions per Minute 5
3183
3501
3820
4138
4456
4775
5093
5411
5730
6048
6366
12,732
6
2653
2918
3183
3448
3714
3979
4244
4509
4775
5039
5305
10,610
8
1989
2188
2387
2586
2785
2984
3183
3382
3581
3780
3979
7958
10
1592
1751
1910
2069
2228
2387
2546
2706
2865
3024
3183
6366
12
1326
1459
1592
1724
1857
1989
2122
2255
2387
2520
2653
5305
16
995
1094
1194
1293
1393
1492
1591
1691
1790
1890
1989
3979
20
796
875
955
1034
1114
1194
1273
1353
1432
1512
1592
3183
25
637
700
764
828
891
955
1019
1082
1146
1210
1273
2546
30
530
584
637
690
743
796
849
902
955
1008
1061
2122
35
455
500
546
591
637
682
728
773
819
864
909
1818
40
398
438
477
517
557
597
637
676
716
756
796
1592
45
354
389
424
460
495
531
566
601
637
672
707
1415
50
318
350
382
414
446
477
509
541
573
605
637
1273
55
289
318
347
376
405
434
463
492
521
550
579
1157
60
265
292
318
345
371
398
424
451
477
504
530
1061
65
245
269
294
318
343
367
392
416
441
465
490
979
70
227
250
273
296
318
341
364
387
409
432
455
909
75
212
233
255
276
297
318
340
361
382
403
424
849
80
199
219
239
259
279
298
318
338
358
378
398
796
90
177
195
212
230
248
265
283
301
318
336
354
707
100
159
175
191
207
223
239
255
271
286
302
318
637
110
145
159
174
188
203
217
231
246
260
275
289
579
120
133
146
159
172
186
199
212
225
239
252
265
530
130
122
135
147
159
171
184
196
208
220
233
245
490
140
114
125
136
148
159
171
182
193
205
216
227
455
150
106
117
127
138
149
159
170
180
191
202
212
424
160
99.5
109
119
129
139
149
159
169
179
189
199
398
170
93.6
103
112
122
131
140
150
159
169
178
187
374
180
88.4
97.3
106
115
124
133
141
150
159
168
177
354
190
83.8
92.1
101
109
117
126
134
142
151
159
167
335
200
79.6
87.5
95.5
103
111
119
127
135
143
151
159
318
220
72.3
79.6
86.8
94
101
109
116
123
130
137
145
289
240
66.3
72.9
79.6
86.2
92.8
99.5
106
113
119
126
132
265
260
61.2
67.3
73.4
79.6
85.7
91.8
97.9
104
110
116
122
245
280
56.8
62.5
68.2
73.9
79.6
85.3
90.9
96.6
102
108
114
227
300
53.1
58.3
63.7
69
74.3
79.6
84.9
90.2
95.5
101
106
212
350
45.5
50
54.6
59.1
63.7
68.2
72.8
77.3
81.8
99.1
91
182
400
39.8
43.8
47.7
51.7
55.7
59.7
63.7
67.6
71.6
75.6
79.6
159
450
35.4
38.9
42.4
46
49.5
53.1
56.6
60.1
63.6
67.2
70.7
141
500
31.8
35
38.2
41.4
44.6
47.7
50.9
54.1
57.3
60.5
63.6
127
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1022
SPEEDS AND FEEDS
SPEED AND FEED TABLES How to Use the Feeds and Speeds Tables Introduction to the Feed and Speed Tables.—The principal tables of feed and speed values are listed in the table below. In this section, Tables 1 through 9 give data for turning, Tables 10 through 15e give data for milling, and Tables 17 through 23 give data for reaming, drilling, threading. The materials in these tables are categorized by description, and Brinell hardness number (Bhn) range or material condition. So far as possible, work materials are grouped by similar machining characteristics. The types of cutting tools (HSS end mill, for example) are identified in one or more rows across the tops of the tables. Other important details concerning the use of the tables are contained in the footnotes to Tables 1, 10 and 17. Information concerning specific cutting tool grades is given in notes at the end of each table. Principal Speed andFeed Tables Feeds and Speeds for Turning Table 1. Cutting Feeds and Speeds for Turning Plain Carbon and Alloy Steels Table 2. Cutting Feeds and Speeds for Turning Tool Steels Table 3. Cutting Feeds and Speeds for Turning Stainless Steels Table 4a. Cutting Feeds and Speeds for Turning Ferrous Cast Metals Table 4b. Cutting Feeds and Speeds for Turning Ferrous Cast Metals Table 5c. Cutting-Speed Adjustment Factors for Turning with HSS Tools Table 5a. Turning-Speed Adjustment Factors for Feed, Depth of Cut, and Lead Angle Table 5b. Tool Life Factors for Turning with Carbides, Ceramics, Cermets, CBN, and Polycrystalline Diamond Table 6. Cutting Feeds and Speeds for Turning Copper Alloys Table 7. Cutting Feeds and Speeds for Turning Titanium and Titanium Alloys Table 8. Cutting Feeds and Speeds for Turning Light Metals Table 9. Cutting Feeds and Speeds for Turning Superalloys Feeds and Speeds for Milling Table 10. Cutting Feeds and Speeds for Milling Aluminum Alloys Table 11. Cutting Feeds and Speeds for Milling Plain Carbon and Alloy Steels Table 12. Cutting Feeds and Speeds for Milling Tool Steels Table 13. Cutting Feeds and Speeds for Milling Stainless Steels Table 14. Cutting Feeds and Speeds for Milling Ferrous Cast Metals Table 15a. Recommended Feed in Inches per Tooth (ft) for Milling with High Speed Steel Cutters Table 15b. End Milling (Full Slot) Speed Adjustment Factors for Feed, Depth of Cut, and Lead Angle Table 15c. End, Slit, and Side Milling Speed Adjustment Factors for Radial Depth of Cut Table 15d. Face Milling Speed Adjustment Factors for Feed, Depth of Cut, and Lead Angle Table 15e. Tool Life Adjustment Factors for Face Milling, End Milling, Drilling, and Reaming Table 16. Cutting Tool Grade Descriptions and Common Vendor Equivalents Feeds and Speeds for Drilling, Reaming, and Threading Table 17. Feeds and Speeds for Drilling, Reaming, and Threading Plain Carbon and Alloy Steels Table 18. Feeds and Speeds for Drilling, Reaming, and Threading Tool Steels Table 19. Feeds and Speeds for Drilling, Reaming, and Threading Stainless Steels Table 20. Feeds and Speeds for Drilling, Reaming, and Threading Ferrous Cast Metals Table 21. Feeds and Speeds for Drilling, Reaming, and Threading Light Metals Table 22. Feed and Diameter Speed Adjustment Factors for HSS Twist Drills and Reamers Table 23. Feeds and Speeds for Drilling and Reaming Copper Alloys
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPEEDS AND FEEDS
1023
Each of the cutting speed tables in this section contains two distinct types of cutting speed data. The speed columns at the left of each table contain traditional Handbook cutting speeds for use with high-speed steel (HSS) tools. For many years, this extensive collection of cutting data has been used successfully as starting speed values for turning, milling, drilling, and reaming operations. Instructions and adjustment factors for use with these speeds are given in Table 5c (feed and depth-of-cut factors) for turning, and in Table 15a (feed, depth of cut, and cutter diameter) for milling. Feeds for drilling and reaming are discussed in Using the Feed and Speed Tables for Drilling, Reaming, and Threading. With traditional speeds and feeds, tool life may vary greatly from material to material, making it very difficult to plan efficient cutting operations, in particular for setting up unattended jobs on CNC equipment where the tool life must exceed cutting time, or at least be predictable so that tool changes can be scheduled. This limitation is reduced by using the combined feed/speed data contained in the remaining columns of the speed tables. The combined feed/speed portion of the speed tables gives two sets of feed and speed data for each material represented. These feed/speed pairs are the optimum and average data (identified by Opt. and Avg.); the optimum set is always on the left side of the column and the average set is on the right. The optimum feed/speed data are approximate values of feed and speed that achieve minimum-cost machining by combining a high productivity rate with low tooling cost at a fixed tool life. The average feed/speed data are expected to achieve approximately the same tool life and tooling costs, but productivity is usually lower, so machining costs are higher. The data in this portion of the tables are given in the form of two numbers, of which the first is the feed in thousandths of an inch per revolution (or per tooth, for milling) and the second is the cutting speed in feet per minute. For example, the feed/speed set 15⁄215 represents a feed of 0.015 in./rev at a speed of 215 fpm. Blank cells in the data tables indicate that feed/speed data for these materials were not available at the time of publication. Generally, the feed given in the optimum set should be interpreted as the maximum safe feed for the given work material and cutting tool grade, and the use of a greater feed may result in premature tool wear or tool failure before the end of the expected tool life. The primary exception to this rule occurs in milling, where the feed may be greater than the optimum feed if the radial depth of cut is less than the value established in the table footnote; this topic is covered later in the milling examples. Thus, except for milling, the speed and tool life adjustment tables, to be discussed later, do not permit feeds that are greater than the optimum feed. On the other hand, the speed and tool life adjustment factors often result in cutting speeds that are well outside the given optimum to average speed range. The combined feed/speed data in this section were contributed by Dr. Colding of Colding International Corp., Ann Arbor, MI. The speed, feed, and tool life calculations were made by means of a special computer program and a large database of cutting speed and tool life testing data. The COMP computer program uses tool life equations that are extensions of the F. W. Taylor tool life equation, first proposed in the early 1900s. The Colding tool life equations use a concept called equivalent chip thickness (ECT), which simplifies cutting speed and tool life predictions, and the calculation of cutting forces, torque, and power requirements. ECT is a basic metal cutting parameter that combines the four basic turning variables (depth of cut, lead angle, nose radius, and feed per revolution) into one basic parameter. For other metal cutting operations (milling, drilling, and grinding, for example), ECT also includes additional variables such as the number of teeth, width of cut, and cutter diameter. The ECT concept was first presented in 1931 by Prof. R. Woxen, who showed that equivalent chip thickness is a basic metal cutting parameter for high-speed cutting tools. Dr. Colding later extended the theory to include other tool materials and metal cutting operations, including grinding. The equivalent chip thickness is defined by ECT = A/CEL, where A is the cross-sectional area of the cut (approximately equal to the feed times the depth of cut), and CEL is the cutting edge length or tool contact rubbing length. ECT and several other terms related to tool
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1024
SPEEDS AND FEEDS
geometry are illustrated in Figs. 1 and 2. Many combinations of feed, lead angle, nose radius and cutter diameter, axial and radial depth of cut, and numbers of teeth can give the same value of ECT. However, for a constant cutting speed, no matter how the depth of cut, feed, or lead angle, etc., are varied, if a constant value of ECT is maintained, the tool life will also remain constant. A constant value of ECT means that a constant cutting speed gives a constant tool life and an increase in speed results in a reduced tool life. Likewise, if ECT were increased and cutting speed were held constant, as illustrated in the generalized cutting speed vs. ECT graph that follows, tool life would be reduced.
; ;; ; ;; ;;;;;;;;;;;;;;;;;;; ;;;;;;;;;;;; ; ; ; ; ; ; ; ; ; EC
CE
L
T
a
CELe
A'
r
A
f
a =depth of cut A = A′ = chip cross-sectional area CEL = CELe = engaged cutting edge length ECT = equivalent chip thickness =A′/CEL f =feed/rev r =nose radius LA = lead angle (U.S.) LA(ISO) = 90−LA
LA (ISO)
LA (U.S.) Fig. 1. Cutting Geometry, Equivalent Chip Thickness, and Cutting Edge Length
;;;;; ;;;;; ;;;;; ;;;;; ;;;;; ;;;;; ;;;;; ;;;;; ;;;;; ;;; ;;;;; ;;;;; ;;; ;;;;; ;;;;; ;;; ;;;;; ;;; ;;; ;;; ;;; CEL
;;; ;;; ;;; ;;; ;;; ;;;
A
A– A
LA (ISO)
A
LA (U.S.)
Rake Angle
Fig. 2. Cutting Geometry for Turning
In the tables, the optimum feed/speed data have been calculated by COMP to achieve a fixed tool life based on the maximum ECT that will result in successful cutting, without premature tool wear or early tool failure. The same tool life is used to calculate the average feed/speed data, but these values are based on one-half of the maximum ECT. Because the data are not linear except over a small range of values, both optimum and average sets are required to adjust speeds for feed, lead angle, depth of cut, and other factors.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPEEDS AND FEEDS
1025
Tool life is the most important factor in a machining system, so feeds and speeds cannot be selected as simple numbers, but must be considered with respect to the many parameters that influence tool life. The accuracy of the combined feed/speed data presented is believed to be very high. However, machining is a variable and complicated process and use of the feed and speed tables requires the user to follow the instructions carefully to achieve good predictability. The results achieved, therefore, may vary due to material condition, tool material, machine setup, and other factors, and cannot be guaranteed. The feed values given in the tables are valid for the standard tool geometries and fixed depths of cut that are identified in the table footnotes. If the cutting parameters and tool geometry established in the table footnotes are maintained, turning operations using either the optimum or average feed/speed data (Tables 1 through 9) should achieve a constant tool life of approximately 15 minutes; tool life for milling, drilling, reaming, and threading data (Tables 10 through 14 and Tables 17 through 22) should be approximately 45 minutes. The reason for the different economic tool lives is the higher tooling cost associated with milling-drilling operations than for turning. If the cutting parameters or tool geometry are different from those established in the table footnotes, the same tool life (15 or 45 minutes) still may be maintained by applying the appropriate speed adjustment factors, or tool life may be increased or decreased using tool life adjustment factors. The use of the speed and tool life adjustment factors is described in the examples that follow. Both the optimum and average feed/speed data given are reasonable values for effective cutting. However, the optimum set with its higher feed and lower speed (always the left entry in each table cell) will usually achieve greater productivity. In Table 1, for example, the two entries for turning 1212 free-machining plain carbon steel with uncoated carbide are 17⁄805 and 8⁄1075. These values indicate that a feed of 0.017 in./rev and a speed of 805 ft/min, or a feed of 0.008 in./rev and a speed of 1075 ft/min can be used for this material. The tool life, in each case, will be approximately 15 minutes. If one of these feed and speed pairs is assigned an arbitrary cutting time of 1 minute, then the relative cutting time of the second pair to the first is equal to the ratio of their respective feed × speed products. Here, the same amount of material that can be cut in 1 minute, at the higher feed and lower speed (17⁄805), will require 1.6 minutes at the lower feed and higher speed (8⁄1075) because 17 × 805/(8 × 1075) = 1.6 minutes. LIVE GRAPH
1000
Click here to view
V = Cutting Speed (m/min)
Tool Life, T (min)
100
T=5 T = 15 T = 45 T = 120
10 0.01
0.1
1
Equivalent Chip Thickness, ECT (mm) Cutting Speed versus Equivalent Chip Thickness with Tool Life as a Parameter
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1026
SPEEDS AND FEEDS
Speed and Feed Tables for Turning.—Speeds for HSS (high-speed steel) tools are based on a feed of 0.012 inch/rev and a depth of cut of 0.125 inch; use Table 5c to adjust the given speeds for other feeds and depths of cut. The combined feed/speed data in the remaining columns are based on a depth of cut of 0.1 inch, lead angle of 15 degrees, and nose radius of 3⁄64 inch. Use Table 5a to adjust given speeds for other feeds, depths of cut, and lead angles; use Table 5b to adjust given speeds for increased tool life up to 180 minutes. Examples are given in the text. Examples Using the Feed and Speed Tables for Turning: The examples that follow give instructions for determining cutting speeds for turning. In general, the same methods are also used to find cutting speeds for milling, drilling, reaming, and threading, so reading through these examples may bring some additional insight to those other metalworking processes as well. The first step in determining cutting speeds is to locate the work material in the left column of the appropriate table for turning, milling, or drilling, reaming, and threading. Example 1, Turning:Find the cutting speed for turning SAE 1074 plain carbon steel of 225 to 275 Brinell hardness, using an uncoated carbide insert, a feed of 0.015 in./rev, and a depth of cut of 0.1 inch. In Table 1, feed and speed data for two types of uncoated carbide tools are given, one for hard tool grades, the other for tough tool grades. In general, use the speed data from the tool category that most closely matches the tool to be used because there are often significant differences in the speeds and feeds for different tool grades. From the uncoated carbide hard grade values, the optimum and average feed/speed data given in Table 1 are 17⁄615 and 8⁄815, or 0.017 in./rev at 615 ft/min and 0.008 in./rev at 815 ft/min. Because the selected feed (0.015 in./rev) is different from either of the feeds given in the table, the cutting speed must be adjusted to match the feed. The other cutting parameters to be used must also be compared with the general tool and cutting parameters given in the speed tables to determine if adjustments need to be made for these parameters as well. The general tool and cutting parameters for turning, given in the footnote to Table 1, are depth of cut = 0.1 inch, lead angle = 15°, and tool nose radius = 3⁄64 inch. Table 5a is used to adjust the cutting speeds for turning (from Tables 1 through 9) for changes in feed, depth of cut, and lead angle. The new cutting speed V is found from V = Vopt × Ff × Fd, where Vopt is the optimum speed from the table (always the lower of the two speeds given), and Ff and Fd are the adjustment factors from Table 5a for feed and depth of cut, respectively. To determine the two factors Ff and Fd, calculate the ratio of the selected feed to the optimum feed, 0.015⁄0.017 = 0.9, and the ratio of the two given speeds Vavg and Vopt, 815⁄615 = 1.35 (approximately). The feed factor Fd = 1.07 is found in Table 5a at the intersection of the feed ratio row and the speed ratio column. The depth-of-cut factor Fd = 1.0 is found in the same row as the feed factor in the column for depth of cut = 0.1 inch and lead angle = 15°, or for a tool with a 45° lead angle, Fd = 1.18. The final cutting speed for a 15° lead angle is V = Vopt × Ff × Fd = 615 × 1.07 × 1.0 = 658 fpm. Notice that increasing the lead angle tends to permit higher cutting speeds; such an increase is also the general effect of increasing the tool nose radius, although nose radius correction factors are not included in this table. Increasing lead angle also increases the radial pressure exerted by the cutting tool on the workpiece, which may cause unfavorable results on long, slender workpieces. Example 2, Turning:For the same material and feed as the previous example, what is the cutting speed for a 0.4-inch depth of cut and a 45° lead angle? As before, the feed is 0.015 in./rev, so Ff is 1.07, but Fd = 1.03 for depth of cut equal to 0.4 inch and a 45° lead angle. Therefore, V = 615 × 1.07 × 1.03 = 676 fpm. Increasing the lead angle from 15° to 45° permits a much greater (four times) depth of cut, at the same feed and nearly constant speed. Tool life remains constant at 15 minutes. (Continued on page 1036)
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 1. Cutting Feeds and Speeds for Turning Plain Carbon and Alloy Steels
Opt.
Avg.
Opt.
Avg.
Tool Material Coated Carbide Ceramic Hard Tough Hard Tough f = feed (0.001 in./rev), s = speed (ft/min) Opt. Avg. Opt. Avg. Opt. Avg. Opt. Avg.
Opt.
Avg.
f s f s
17 805 17 745
8 1075 8 935
36 405 36 345
17 555 17 470
17 1165 28 915
8 1295 13 1130
28 850 28 785
13 1200 13 1110
15 3340 15 1795
8 4985 8 2680
15 1670 15 1485
8 2500 8 2215
7 1610 7 1490
3 2055 3 1815
f s
17 730
8 990
36 300
17 430
17 1090
8 1410
28 780
13 1105
15 1610
8 2780
15 1345
8 2005
7 1355
3 1695
f s
17 615
8 815
36 300
17 405
17 865
8 960
28 755
13 960
13 1400
7 1965
13 1170
7 1640
f s
17 515
8 685
36 235
17 340
17 720
8 805
28 650
13 810
10 1430
5 1745
10 1070
5 1305
f s
17 745
8 935
36 345
17 470
28 915
13 1130
28 785
13 1110
15 1795
8 2680
15 1485
8 2215
7 1490
3 1815
f s f s f s
17 615 17 805 17 745 17 615
8 815 8 1075 8 935 8 815
36 300 36 405 36 345 36 300
17 405 17 555 17 470 17 405
17 865 17 1165 28 915 17 865
8 960 8 1295 13 1130 8 960
28 755 28 850 28 785 28 755
13 960 13 1200 13 1110 13 960
13 1400 15 3340 15 1795 13 1400
7 1965 8 4985 8 2680 7 1965
13 1170 15 1670 15 1485 13 1170
7 1640 8 2500 8 2215 7 1640
7 1610 7 1490
3 2055 3 1815
Uncoated Carbide Hard Tough
HSS Material AISI/SAE Designation Free-machining plain carbon steels (resulfurized): 1212, 1213, 1215
100–150
150
150–200
160
100–150
130
150–200
120
175–225
120
{
275–325
75
325–375
50
{
Plain carbon steels: 1006, 1008, 1009, 1010, 1012, 1015, 1016, 1017, 1018, 1019, 1020, 1021, 1022, 1023, 1024, 1025, 1026, 1513, 1514
40
100–150
140
150–200
145
200–250
110
100–125
120
125–175
110
175–225
90
225–275
70
f s
Copyright 2004, Industrial Press, Inc., New York, NY
1027
375–425
Cermet
SPEEDS AND FEEDS
(Leaded): 11L17, 11L18, 12L13, 12L14
Speed (fpm)
{
1108, 1109, 1115, 1117, 1118, 1120, 1126, 1211 {
1132, 1137, 1139, 1140, 1144, 1146, 1151
Brinell Hardness
Machinery's Handbook 27th Edition
f s
Opt. 17 745
Avg. 8 935
Opt. 36 345
Avg. 17 470
Tool Material Coated Carbide Ceramic Hard Tough Hard Tough f = feed (0.001 in./rev), s = speed (ft/min) Opt. Avg. Opt. Avg. Opt. Avg. Opt. Avg. 28 13 28 13 15 8 15 8 915 1130 785 1110 1795 2680 1485 2215
f s
17 615
8 815
36 300
17 405
17 865
8 960
28 755
13 960
13 1400
7 1965
13 1170
7 1640
f s
17 515
8 685
36 235
17 340
17 720
8 805
28 650
13 810
10 1430
5 1745
10 1070
5 1305
f s
17 730
8 990
36 300
17 430
17 8 1090 1410
28 780
13 1105
15 1610
8 2780
15 1345
8 2005
7 1355
3 1695
f s
17 615
8 815
36 300
17 405
17 865
8 960
28 755
13 960
13 1400
7 1965
13 1170
7 1640
7 1365
3 1695
f s
17 515
8 685
36 235
17 340
17 720
8 805
28 650
13 810
10 1430
5 1745
10 1070
5 1305
17 525
8 705
36 235
17 320
17 505
8 525
28 685
13 960
15 1490
8 2220
15 1190
8 1780
7 1040
3 1310
17 355
8 445
36 140
17 200
17 630
8 850
28 455
13 650
10 1230
5 1510
10 990
5 1210
7 715
3 915
17 330
8 440
36 125
17 175
17 585
8 790
28 125
13 220
8 1200
4 1320
8 960
4 1060
7 575
3 740
Uncoated Carbide Hard Tough
HSS Material AISI/SAE Designation
Plain carbon steels (continued): 1055, 1060, 1064, 1065, 1070, 1074, 1078, 1080, 1084, 1086, 1090, 1095, 1548, 1551, 1552, 1561, 1566
Free-machining alloy steels, (resulfurized): 4140, 4150
Speed (fpm)
125–175
100
175–225
85
225–275
70
275–325
60
325–375
40
375–425
30
125–175
100
175–225
80
225–275
65
275–325
50
325–375
35
375–425
30
175–200
110
200–250
90
250–300
65
300–375
50
375–425
40
f s f s f s
Copyright 2004, Industrial Press, Inc., New York, NY
Cermet Opt. 7 1490
Avg. 3 1815
SPEEDS AND FEEDS
Plain carbon steels (continued): 1027, 1030, 1033, 1035, 1036, 1037, 1038, 1039, 1040, 1041, 1042, 1043, 1045, 1046, 1048, 1049, 1050, 1052, 1524, 1526, 1527, 1541
Brinell Hardness
1028
Table 1. (Continued) Cutting Feeds and Speeds for Turning Plain Carbon and Alloy Steels
Machinery's Handbook 27th Edition
Table 1. (Continued) Cutting Feeds and Speeds for Turning Plain Carbon and Alloy Steels
Opt. 17 730 17 615
Avg. 8 990 8 815
Opt. 36 300 36 300
Avg. 17 430 17 405
f s
17 515
8 685
36 235
17 340
17 720
8 805
28 650
13 810
10 1430
5 1745
10 1070
5 1305
HSS Material AISI/SAE Designation
Free-machining alloy steels: (leaded): 41L30, 41L40, 41L47, 41L50, 43L47, 51L32, 52L100, 86L20, 86L40
Alloy steels: 4012, 4023, 4024, 4028, 4118, 4320, 4419, 4422, 4427, 4615, 4620, 4621, 4626, 4718, 4720, 4815, 4817, 4820, 5015, 5117, 5120, 6118, 8115, 8615, 8617, 8620, 8622, 8625, 8627, 8720, 8822, 94B17
Alloy steels: 1330, 1335, 1340, 1345, 4032, 4037, 4042, 4047, 4130, 4135, 4137, 4140, 4142, 4145, 4147, 4150, 4161, 4337, 4340, 50B44, 50B46, 50B50, 50B60, 5130, 5132, 5140, 5145, 5147, 5150, 5160, 51B60, 6150, 81B45, 8630, 8635, 8637, 8640, 8642, 8645, 8650, 8655, 8660, 8740, 9254, 9255, 9260, 9262, 94B30 E51100, E52100 use (HSS Speeds)
Brinell Hardness
Speed (fpm)
150–200
120
200–250
100
250–300
75
300–375
55
375–425
50
125–175
100
175–225
90
225–275
70
275–325
60 50 30 (20)
175–225
85 (70)
225–275
70 (65)
275–325
60 (50)
325–375
40 (30)
375–425
30 (20)
Opt. 7 1355 7 1355
Avg. 3 1695 3 1695
f s f s f s
17 525
8 705
36 235
17 320
17 505
8 525
28 685
13 960
15 1490
8 2220
15 1190
8 1780
7 1040
3 1310
17 355
8 445
36 140
1 200
17 630
8 850
28 455
13 650
10 1230
5 1510
10 990
5 1210
7 715
3 915
17 330
8 440
36 135
17 190
17 585
8 790
28 240
13 350
9 1230
5 1430
8 990
5 1150
7 655
3 840
f s
17 330
8 440
36 125
17 175
17 585
8 790
28 125
13 220
8 1200
4 1320
8 960
4 1060
7 575
3 740
f s f s f s
17 525 17 355
8 705 8 445
36 235 36 140
17 320 17 200
17 505 17 630
8 525 8 850
28 685 28 455
13 960 13 650
15 1490 10 1230
8 2220 5 1510
15 1190 10 990
8 1780 5 1210
7 1020 7 715
3 1310 3 915
17 330
8 440
36 135
17 190
17 585
8 790
28 240
13 350
9 1230
5 1430
8 990
5 1150
7 655
3 840
f s
17 330
8 440
36 125
17 175
17 585
8 790
28 125
13 220
8 1200
4 1320
8 960
4 1060
7 575
3 740
Copyright 2004, Industrial Press, Inc., New York, NY
1029
325–35 375–425
Cermet
SPEEDS AND FEEDS
f s f s
Tool Material Coated Carbide Ceramic Hard Tough Hard Tough f = feed (0.001 in./rev), s = speed (ft/min) Opt. Avg. Opt. Avg. Opt. Avg. Opt. Avg. 17 8 28 13 15 8 15 8 1090 1410 780 1105 1610 2780 1345 2005 17 8 28 13 13 7 13 7 865 960 755 960 1400 1965 1170 1640
Uncoated Carbide Hard Tough
Machinery's Handbook 27th Edition
Opt.
Avg.
Opt.
Avg.
Tool Material Coated Carbide Ceramic Hard Tough Hard Tough f = feed (0.001 in./rev), s = speed (ft/min) Opt. Avg. Opt. Avg. Opt. Avg. Opt. Avg.
f s
17 220
8 295
36 100
17 150
20 355
10 525
28 600
13 865
10 660
5 810
7 570
3 740
f s
17 165
8 185
36 55
17 105
17 325
8 350
28 175
13 260
8 660
4 730
7 445
3 560
17 55†
8 90
36 100
17 150
7
3
17 55†
8 90
8 705
36 235
17 320
17 505
8 525
28 685
8 440
36 125
17 175
17 585
8 790
28 125
Uncoated Carbide Hard Tough
HSS Material AISI/SAE Designation
Brinell Hardness 220–300
Speed (fpm) 65
300–350
50
350–400
35
43–48 Rc
25
48–52 Rc
10
250–325
60
f s
50–52 Rc
10
f s
200–250
70
f s
17 525
300–350
30
f s
17 330
Maraging steels (not AISI): 18% Ni, Grades 200, 250, 300, and 350
Nitriding steels (not AISI): Nitralloy 125, 135, 135 Mod., 225, and 230, Nitralloy N, Nitralloy EZ, Nitrex 1
f s
17 220
8 295
20 355
10 525
28 600
Cermet Opt.
Avg.
7 385
3 645
10 270
5 500
660
810
10 570
5 740
7 385‡
3 645
10 270
5 500
13 960
15 1490
8 2220
15 1190
8 1780
7 1040
3 1310
13 220
8 1200
4 1320
8 960
4 1060
7 575
3 740
13 865
Speeds for HSS (high-speed steel) tools are based on a feed of 0.012 inch/rev and a depth of cut of 0.125 inch; use Table 5c to adjust the given speeds for other feeds and depths of cut. The combined feed/speed data in the remaining columns are based on a depth of cut of 0.1 inch, lead angle of 15 degrees, and nose radius of 3⁄64 inch. Use Table 5a to adjust given speeds for other feeds, depths of cut, and lead angles; use Table 5b to adjust given speeds for increased tool life up to 180 minutes. Examples are given in the text. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbides, hard = 17, tough = 19, † = 15; coated carbides, hard = 11, tough = 14; ceramics, hard = 2, tough = 3, ‡ = 4; cermet = 7 .
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
Ultra-high-strength steels (not ASI): AMS alloys 6421 (98B37 Mod.), 6422 (98BV40), 6424, 6427, 6428, 6430, 6432, 6433, 6434, 6436, and 6442; 300M and D6ac
1030
Table 1. (Continued) Cutting Feeds and Speeds for Turning Plain Carbon and Alloy Steels
Machinery's Handbook 27th Edition
Table 2. Cutting Feeds and Speeds for Turning Tool Steels Uncoated HSS Material AISI Designation
Hot work, chromium type: H10, H11, H12, H13, H14, H19
Hot work, tungsten type: H21, H22, H23, H24, H25, H26 Hot work, molybdenum type: H41, H42, H43
Speed (fpm)
150–200 175–225 175–225
100 70 70
200–250
45
200–250
70
200–250 225–275 150–200 200–250
55 45 80 65
325–375
50
48–50 Rc 50–52 Rc 52–56 Rc 150–200 200–250 150–200 200–250
20 10 — 60 50 55 45
Opt.
Avg.
Opt.
Avg.
Tool Material Coated Carbide Ceramic Hard Tough Hard Tough f = feed (0.001 in./rev), s = speed (ft/min) Opt. Avg. Opt. Avg. Opt. Avg. Opt. Avg.
Cermet Opt.
Avg.
f s
17 455
8 610
36 210
17 270
17 830
8 1110
28 575
13 805
13 935
7 1310
13 790
7 1110
7 915
3 1150
f s
17 445
8 490
36 170
17 235
17 705
8 940
28 515
13 770
13 660
7 925
13 750
7 1210
7 1150
3 1510
f s
17 165
8 185
36 55
17 105
17 325
8 350
28 175
13 260
8 660
4 730
7 445
3 560
17 55†
8 90
36 170
17 235
7 1150
3 1510
f s f s
17 445
8 490
17 705
8 940
28 515
13 770
7 385‡
3 645
10 270
5 500
13 660
7 925
13 750
7 1210
Special purpose, low alloy: L2, L3, L6
150–200
75
f s
17 445
8 610
36 210
17 270
17 830
8 1110
28 575
13 805
13 935
7 1310
13 790
7 1110
7 915
3 1150
Mold: P2, P3, P4, P5, P6, P26, P21
100–150 150–200
90 80
f s
17 445
8 610
36 210
17 270
17 830
8 1110
28 575
13 805
13 935
7 1310
13 790
7 1110
7 915
3 1150
200–250
65 f s
17 445
8 490
36 170
17 235
17 705
8 940
28 515
13 770
13 660
7 925
13 750
7 1210
7 1150
3 1510
High-speed steel: M1, M2, M6, M10, T1, T2,T6 M3-1, M4 M7, M30, M33, M34, M36, M41, M42, M43, M44, M46, M47, T5, T8 T15, M3-2
225–275
55
225–275
45
Copyright 2004, Industrial Press, Inc., New York, NY
1031
Speeds for HSS (high-speed steel) tools are based on a feed of 0.012 inch/rev and a depth of cut of 0.125 inch; use Table 5c to adjust the given speeds for other feeds and depths of cut. The combined feed/speed data in the remaining columns are based on a depth of cut of 0.1 inch, lead angle of 15 degrees, and nose radius of 3⁄64 inch. Use Table 5a to adjust given speeds for other feeds, depths of cut, and lead angles; use Table 5b to adjust given speeds for increased tool life up to 180 minutes. Examples are given in the text.The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbides, hard = 17, tough = 19, † = 15; coated carbides, hard = 11, tough = 14; ceramics, hard = 2, tough = 3, ‡ = 4; cermet = 7.
SPEEDS AND FEEDS
Water hardening: W1, W2, W5 Shock resisting: S1, S2, S5, S6, S7 Cold work, oil hardening: O1, O2, O6, O7 Cold work, high carbon, high chromium: D2, D3, D4, D5, D7 Cold work, air hardening: A2, A3, A8, A9, A10 A4, A6 A7
Brinell Hardness
Uncoated Carbide Hard Tough
Machinery's Handbook 27th Edition
1032
Table 3. Cutting Feeds and Speeds for Turning Stainless Steels Tool Material Uncoated
Uncoated Carbide
HSS Material Free-machining stainless steel (Ferritic): 430F, 430FSe (Austenitic): 203EZ, 303, 303Se, 303MA, 303Pb, 303Cu, 303 Plus X
Stainless steels (Ferritic): 405, 409 429, 430, 434, 436, 442, 446, 502 (Austenitic): 201, 202, 301, 302, 304, 304L, 305, 308, 321, 347, 348 (Austenitic): 302B, 309, 309S, 310, 310S, 314, 316, 316L, 317, 330
(Martensitic): 403, 410, 420, 501
(Martensitic): 414, 431, Greek Ascoloy, 440A, 440B, 440C (Precipitation hardening):15-5PH, 17-4PH, 17-7PH, AF-71, 17-14CuMo, AFC-77, AM-350, AM-355, AM-362, Custom 455, HNM, PH13-8, PH14-8Mo, PH15-7Mo, Stainless W
Speed (fpm)
135–185
110
135–185 225–275 135–185 185–240 275–325 375–425
100 80 110 100 60 30
135–185
90
135–185 225–275
75 65
135–185
70
135–175 175–225 275–325 375–425 225–275 275–325 375–425 150–200 275–325 325–375 375–450
95 85 55 35 55–60 45–50 30 60 50 40 25
Coated Carbide Tough
Hard
Cermet
Tough
f = feed (0.001 in./rev), s = speed (ft/min) Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
f s
20 480
10 660
36 370
17 395
17 755
8 945
28 640
13 810
7 790
3 995
f s
13 520
7 640
36 310
17 345
28 625
13 815
7 695
3 875
f s
13 520
7 640
36 310
28 625
13 815
7 695
3 875
f s f s
13 210
7 260
36 85
17 135
28 130
13 165
20 480
10 660
36 370
17 395
28 640
13 810
7 790
3 995
f s
13 520
7 640
36 310
17 345
28 625
13 165
7 695
3 875
f s
13 210
7 260
36 85
17 135
28 130
13 165
13 200†
7 230
f s
13 520
7 640
36 310
17 345
28 625
13 815
13 695
7 875
f s
13 195
7 240
36 85
17 155
17 755
8 945
See footnote to Table 1 for more information. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbides, hard = 17, tough = 19; coated carbides, hard = 11, tough = 14; cermet = 7, † = 18.
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
(Martensitic): 416, 416Se, 416 Plus X, 420F, 420FSe, 440F, 440FSe
Brinell Hardness
Hard
Machinery's Handbook 27th Edition
Table 4a. Cutting Feeds and Speeds for Turning Ferrous Cast Metals Tool Material Uncoated Carbide HSS
Material
Brinell Hardness
Coated Carbide
Tough
Hard
Ceramic
Tough
Hard
Tough
Cermet
CBN
f = feed (0.001 in./rev), s = speed (ft/min)
Speed (fpm)
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Gray Cast Iron ASTM Class 20
120–150
ASTM Class 25
160–200
120 90
ASTM Class 30, 35, and 40
190–220
80
220–260
60
250–320
35
ASTM Type 1, 1b, 5 (Ni resist)
100–215
70
ASTM Type 2, 3, 6 (Ni resist)
120–175
65
ASTM Type 2b, 4 (Ni resist)
150–250
50
(Ferritic): 32510, 35018
110–160
130
(Pearlitic): 40010, 43010, 45006, 45008, 48005, 50005
160–200
95
200–240
75
(Martensitic): 53004, 60003, 60004
200–255
70
(Martensitic): 70002, 70003
220–260
60
(Martensitic): 80002
240–280
50
(Martensitic): 90001
250–320
30
28 240
13 365
28 665
13 1040
28 585
13 945
15 1490
8 2220
15 1180
8 1880
8 395
4 510
24 8490
11 36380
f s
28 160
13 245
28 400
13 630
28 360
13 580
11 1440
6 1880
11 1200
6 1570
8 335
4 420
24 1590
11 2200
f s
28 110
13 175
28 410
13 575
15 1060
8 1590
15 885
8 1320
8 260
4 325
f s
28 180
13 280
28 730
13 940
28 660
13 885
15 1640
8 2450
15 1410
8 2110
f s
28 125
13 200
28 335
13 505
28 340
13 510
13 1640
7 2310
13 1400
7 1970
f s
28 100
13 120
28 205
13 250
11 1720
6 2240
11 1460
6 1910
Malleable Iron
SPEEDS AND FEEDS
ASTM Class 45 and 50 ASTM Class 55 and 60
f s
Speeds for HSS (high-speed steel) tools are based on a feed of 0.012 inch/rev and a depth of cut of 0.125 inch; use Table 5c to adjust the given speeds for other feeds and depths of cut. The combined feed/speed data in the remaining columns are based on a depth of cut of 0.1 inch, lead angle of 15 degrees, and nose radius of 3⁄64 inch. Use Table 5a to adjust the given speeds for other feeds, depths of cut, and lead angles; use Table 5b to adjust given speeds for increased tool life up to 180 minutes. Examples are given in the text.
Copyright 2004, Industrial Press, Inc., New York, NY
1033
The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbides, tough = 15; Coated carbides, hard = 11, tough = 14; ceramics, hard = 2, tough = 3; cermet = 7; CBN = 1.
Machinery's Handbook 27th Edition
1034
Table 4b. Cutting Feeds and Speeds for Turning Ferrous Cast Metals Tool Material Uncoated Carbide
Uncoated HSS Brinell Hardness
Material
Hard
Coated Carbide
Tough
Hard
Ceramic
Tough
Hard
Tough
Cermet
f = feed (0.001 in./rev), s = speed (ft/min) Speed (fpm)
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Nodular (Ductile) Iron (Ferritic): 60-40-18, 65-45-12 (Ferritic-Pearlitic): 80-55-06
{
(Martensitic): 120-90-02
{
100 80
225–260
65
240–300
45
270–330
30
300–400
15
100–150
110
125–175
100
175–225 225–300
90 70
150–200
90
200–250
80
250–300
60
f s
28 200
13 325
28 490
13 700
28 435
13 665
15 970
8 1450
15 845
8 1260
8 365
4 480
f s
28 130
13 210
28 355
13 510
28 310
13 460
11 765
6 995
11 1260
6 1640
8 355
4 445
f s
28 40
13 65
28 145
13 175
10 615
5 750
10 500
5 615
8 120
4 145
Cast Steels (Low-carbon): 1010, 1020 (Medium-carbon): 1030, 1040, 1050
{
(Low-carbon alloy): 1320, 2315, 2320, 4110, 4120, 4320, 8020, 8620
{
(Medium-carbon alloy): 1330, 1340, 2325, 2330, 4125, 4130, 4140, 4330, 4340, 8030, 80B30, 8040, 8430, 8440, 8630, 8640, 9525, 9530, 9535
{
175–225
80
225–250
70
250–300
55
300–350
45
350–400
30
f s
17 370
8 490
36 230
17 285
17 665
8 815
28 495
13 675
15 2090
8 3120
7 625
3 790
f s
17 370
8 490
36 150
17 200
17 595
8 815
28 410
13 590
15 1460
8 2170
7 625
3 790
f s
17 310
8 415
36 115
17 150
17 555
8 760
15 830
8 1240
f s
28 70†
13 145
15 445
8 665
f s
28 115†
13 355
28 335
13 345
15 955
8 1430
The combined feed/speed data in this table are based on tool grades (identified in Table 16) as shown: uncoated carbides, hard = 17; tough = 19, † = 15; coated carbides, hard = 11; tough = 14; ceramics, hard = 2; tough = 3; cermet = 7. Also, see footnote to Table 4a.
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
(Pearlitic-Martensitic): 100-70-03
140–190 190–225
Machinery's Handbook 27th Edition
Table 5a. Turning-Speed Adjustment Factors for Feed, Depth of Cut, and Lead Angle Ratio of the two cutting speeds given in the tables 1.00
1.00 0.90 0.80 0.70 0.60 0.50 0.40 0.30 0.20 0.10
1.0 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00
Depth of Cut and Lead Angle
Vavg/Vopt 1.10
1.25
1.35
1.50
1.75
2.00
1 in. (25.4 mm)
0.4 in. (10.2 mm)
0.2 in. (5.1 mm)
0.1 in. (2.5 mm)
15°
15°
15°
15°
45°
45°
1.0 1.05 1.09 1.13 1.20 1.25 1.28 1.32 1.34 1.20
1.0 1.07 1.10 1.22 1.25 1.35 1.44 1.52 1.60 1.55
1.0 1.09 1.15 1.22 1.35 1.50 1.66 1.85 2.07 2.24
0.04 in. (1.0 mm)
45°
15°
45°
1.18 1.17 1.15 1.15 1.14 1.14 1.13 1.12 1.10 1.06
1.29 1.27 1.25 1.24 1.23 1.23 1.21 1.18 1.15 1.10
1.35 1.34 1.31 1.30 1.29 1.28 1.26 1.23 1.19 1.12
Depth of Cut and Lead Angle Factor, Fd
Feed Factor, Ff 1.0 1.02 1.03 1.05 1.08 1.10 1.09 1.06 1.00 0.80
45°
1.0 1.10 1.20 1.32 1.50 1.75 2.03 2.42 2.96 3.74
1.0 1.12 1.25 1.43 1.66 2.00 2.43 3.05 4.03 5.84
0.74 0.75 0.77 0.77 0.78 0.78 0.78 0.81 0.84 0.88
1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0
0.79 0.80 0.81 0.82 0.82 0.82 0.84 0.85 0.89 0.91
1.03 1.03 1.03 1.03 1.03 1.03 1.03 1.02 1.02 1.01
0.85 0.86 0.87 0.87 0.88 0.88 0.89 0.90 0.91 0.92
1.08 1.08 1.07 1.08 1.07 1.07 1.06 1.06 1.05 1.03
1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0
Use with Tables 1 through 9. Not for HSS tools. Tables 1 through 9 data, except for HSS tools, are based on depth of cut = 0.1 inch, lead angle = 15 degrees, and tool life = 15 minutes. For other depths of cut, lead angles, or feeds, use the two feed/speed pairs from the tables and calculate the ratio of desired (new) feed to optimum feed (largest of the two feeds given in the tables), and the ratio of the two cutting speeds (Vavg/Vopt). Use the value of these ratios to find the feed factor Ff at the intersection of the feed ratio row and the speed ratio column in the left half of the table. The depth-of-cut factor Fd is found in the same row as the feed factor in the right half of the table under the column corresponding to the depth of cut and lead angle. The adjusted cutting speed can be calculated from V = Vopt × Ff × Fd, where Vopt is the smaller (optimum) of the two speeds from the speed table (from the left side of the column containing the two feed/speed pairs). See the text for examples.
Table 5b. Tool Life Factors for Turning with Carbides, Ceramics, Cermets, CBN, and Polycrystalline Diamond Tool Life, T (minutes) 15 45 90 180
Turning with Carbides: Workpiece < 300 Bhn
Turning with Carbides: Workpiece > 300 Bhn; Turning with Ceramics: Any Hardness
Turning with Mixed Ceramics: Any Workpiece Hardness
fs
fm
fl
fs
fm
fl
fs
fm
fl
1.0 0.86 0.78 0.71
1.0 0.81 0.71 0.63
1.0 0.76 0.64 0.54
1.0 0.80 0.70 0.61
1.0 0.75 0.63 0.53
1.0 0.70 0.56 0.45
1.0 0.89 0.82 0.76
1.0 0.87 0.79 0.72
1.0 0.84 0.75 0.67
1035
Except for HSS speed tools, feeds and speeds given in Tables 1 through 9 are based on 15-minute tool life. To adjust speeds for another tool life, multiply the cutting speed for 15-minute tool life V15 by the tool life factor from this table according to the following rules: for small feeds where feed ≤ 1⁄2 fopt, the cutting speed for desired tool life is VT = fs × V15; for medium feeds where 1⁄2 fopt < feed < 3⁄4 fopt, VT = fm × V15; and for larger feeds where 3⁄4 fopt ≤ feed ≤ fopt, VT = fl × V15. Here, fopt is the largest (optimum) feed of the two feed/speed values given in the speed tables.
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
Ratio of Chosen Feed to Optimum Feed
Machinery's Handbook 27th Edition 1036
SPEEDS AND FEEDS Table 5c. Cutting-Speed Adjustment Factors for Turning with HSS Tools Feed
Feed Factor
Depth-of-Cut Factor
Depth of Cut
in.
mm
Ff
in.
mm
Fd
0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010 0.011 0.012 0.013 0.014 0.015 0.016 0.018 0.020 0.022 0.025 0.028 0.030 0.032 0.035 0.040 0.045 0.050 0.060
0.05 0.08 0.10 0.13 0.15 0.18 0.20 0.23 0.25 0.28 0.30 0.33 0.36 0.38 0.41 0.46 0.51 0.56 0.64 0.71 0.76 0.81 0.89 1.02 1.14 1.27 1.52
1.50 1.50 1.50 1.44 1.34 1.25 1.18 1.12 1.08 1.04 1.00 0.97 0.94 0.91 0.88 0.84 0.80 0.77 0.73 0.70 0.68 0.66 0.64 0.60 0.57 0.55 0.50
0.005 0.010 0.016 0.031 0.047 0.062 0.078 0.094 0.100 0.125 0.150 0.188 0.200 0.250 0.312 0.375 0.438 0.500 0.625 0.688 0.750 0.812 0.938 1.000 1.250 1.250 1.375
0.13 0.25 0.41 0.79 1.19 1.57 1.98 2.39 2.54 3.18 3.81 4.78 5.08 6.35 7.92 9.53 11.13 12.70 15.88 17.48 19.05 20.62 23.83 25.40 31.75 31.75 34.93
1.50 1.42 1.33 1.21 1.15 1.10 1.07 1.04 1.03 1.00 0.97 0.94 0.93 0.91 0.88 0.86 0.84 0.82 0.80 0.78 0.77 0.76 0.75 0.74 0.73 0.72 0.71
For use with HSS tool data only from Tables 1 through 9. Adjusted cutting speed V = VHSS × Ff × Fd, where VHSS is the tabular speed for turning with high-speed tools.
Example 3, Turning:Determine the cutting speed for turning 1055 steel of 175 to 225 Brinell hardness using a hard ceramic insert, a 15° lead angle, a 0.04-inch depth of cut and 0.0075 in./rev feed. The two feed/speed combinations given in Table 5a for 1055 steel are 15⁄1610 and 8⁄2780, corresponding to 0.015 in./rev at 1610 fpm and 0.008 in./rev at 2780 fpm, respectively. In Table 5a, the feed factor Ff = 1.75 is found at the intersection of the row corresponding to feed/fopt = 7.5⁄15 = 0.5 and the column corresponding to Vavg/Vopt = 2780⁄1610 = 1.75 (approximately). The depth-of-cut factor Fd = 1.23 is found in the same row, under the column heading for a depth of cut = 0.04 inch and lead angle = 15°. The adjusted cutting speed is V = 1610 × 1.75 × 1.23 = 3466 fpm. Example 4, Turning:The cutting speed for 1055 steel calculated in Example 3 represents the speed required to obtain a 15-minute tool life. Estimate the cutting speed needed to obtain a tool life of 45, 90, and 180 minutes using the results of Example 3. To estimate the cutting speed corresponding to another tool life, multiply the cutting speed for 15-minute tool life V15 by the adjustment factor from the Table 5b, Tool Life Factors for Turning. This table gives three factors for adjusting tool life based on the feed used, fs for feeds less than or equal to 1⁄2 fopt, 3⁄4 fm for midrange feeds between 1⁄2 and 3⁄4 fopt and fl for large feeds greater than or equal to 3⁄4 fopt and less than fopt. In Example 3, fopt is 0.015 in./rev and the selected feed is 0.0075 in./rev = 1⁄2 fopt. The new cutting speeds for the various tool lives are obtained by multiplying the cutting speed for 15-minute tool life V15 by the factor
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPEEDS AND FEEDS
1037
for small feeds fs from the column for turning with ceramics in Table 5b. These calculations, using the cutting speed obtained in Example 3, follow. Tool Life 15 min 45 min 90 min 180 min
Cutting Speed V15 = 3466 fpm V45 = V15 × 0.80 = 2773 fpm V90 = V15 × 0.70 = 2426 fpm V180 = V15 × 0.61 = 2114 fpm
Depth of cut, feed, and lead angle remain the same as in Example 3. Notice, increasing the tool life from 15 to 180 minutes, a factor of 12, reduces the cutting speed by only about one-third of the V15 speed. Table 6. Cutting Feeds and Speeds for Turning Copper Alloys Group 1 Architectural bronze (C38500); Extra-high-headed brass (C35600); Forging brass (C37700); Freecutting phosphor bronze, B2 (C54400); Free-cutting brass (C36000); Free-cutting Muntz metal (C37000); High-leaded brass (C33200; C34200); High-leaded brass tube (C35300); Leaded commercial bronze (C31400); Leaded naval brass (C48500); Medium-leaded brass (C34000) Group 2 Aluminum brass, arsenical (C68700); Cartridge brass, 70% (C26000); High-silicon bronze, B (C65500); Admiralty brass (inhibited) (C44300, C44500); Jewelry bronze, 87.5% (C22600); Leaded Muntz metal (C36500, C36800); Leaded nickel silver (C79600); Low brass, 80% (C24000); Low-leaded brass (C33500); Low-silicon bronze, B (C65100); Manganese bronze, A (C67500); Muntz metal, 60% (C28000); Nickel silver, 55-18 (C77000); Red brass, 85% (C23000); Yellow brass (C26800) Group 3 Aluminum bronze, D (C61400); Beryllium copper (C17000, C17200, C17500); Commercialbronze, 90% (C22000); Copper nickel, 10% (C70600); Copper nickel, 30% (C71500); Electrolytic tough pitch copper (C11000); Guilding, 95% (C21000); Nickel silver, 65-10 (C74500); Nickel silver, 65-12 (C75700); Nickel silver, 65-15 (C75400); Nickel silver, 65-18 (C75200); Oxygen-free copper (C10200) ; Phosphor bronze, 1.25% (C50200); Phosphor bronze, 10% D (C52400) Phosphor bronze, 5% A (C51000); Phosphor bronze, 8% C (C52100); Phosphorus deoxidized copper (C12200) Uncoated Carbide
HSS Wrought Alloys Description and UNS Alloy Numbers
Polycrystalline Diamond
f = feed (0.001 in./rev), s = speed (ft/min)
Material Speed Condition (fpm)
Opt. Avg.
Group 1
A CD
300 350
f s
28 13 1170 1680
Group 2
A CD
200 250
f s
28 715
13 900
Group 3
A CD
100 110
f s
28 440
13 610
Opt.
Avg.
7 1780
13 2080
Abbreviations designate: A, annealed; CD, cold drawn. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbide, 15; diamond, 9. See the footnote to Table 7.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1038
SPEEDS AND FEEDS
Table 7. Cutting Feeds and Speeds for Turning Titanium and Titanium Alloys Tool Material HSS
Uncoated Carbide (Tough)
Material Brinell Hardness
f = feed (0.001 in./rev), s = speed (ft/min) Speed (fpm)
Opt.
Avg.
Commercially Pure and Low Alloyed 99.5Ti, 99.5Ti-0.15Pd
110–150
100–105
99.1Ti, 99.2Ti, 99.2Ti-0.15Pd, 98.9Ti-0.8Ni-0.3Mo
180–240
85–90
250–275
70
99.0 Ti
f s f s f s
28 55 28 50 20 75
13 190 13 170 10 210
f s
17 95
8 250
f s
17 55
8 150
Alpha Alloys and Alpha-Beta Alloys 5Al-2.5Sn, 8Mn, 2Al-11Sn-5Zr1Mo, 4Al-3Mo-1V, 5Al-6Sn-2Zr1Mo, 6Al-2Sn-4Zr-2Mo, 6Al-2Sn4Zr-6Mo, 6Al-2Sn-4Zr-2Mo-0.25Si
300–350
50
6Al-4V 6Al-6V-2Sn, Al-4Mo, 8V-5Fe-IAl
310–350 320–370 320–380
40 30 20
6Al-4V, 6Al-2Sn-4Zr-2Mo, 6Al-2Sn-4Zr-6Mo, 6Al-2Sn-4Zr-2Mo-0.25Si
320–380
40
4Al-3Mo-1V, 6Al-6V-2Sn, 7Al-4Mo
375–420
20
I Al-8V-5Fe
375–440
20
Beta Alloys 13V-11Cr-3Al, 8Mo-8V-2Fe-3Al, 3Al-8V-6Cr-4Mo-4Zr, 11.5Mo-6Zr-4.5Sn
{
275–350
25
375–440
20
The speed recommendations for turning with HSS (high-speed steel) tools may be used as starting speeds for milling titanium alloys, using Table 15a to estimate the feed required. Speeds for HSS (high-speed steel) tools are based on a feed of 0.012 inch/rev and a depth of cut of 0.125 inch; use Table 5c to adjust the given speeds for other feeds and depths of cut. The combined feed/speed data in the remaining columns are based on a depth of cut of 0.1 inch, lead angle of 15 degrees, and nose radius of 3⁄64 inch. Use Table 5a to adjust given speeds for other feeds, depths of cut, and lead angles; use Table 5b to adjust given speeds for increased tool life up to 180 minutes. Examples are given in the text. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbide, 15.
Table 8. Cutting Feeds and Speeds for Turning Light Metals Tool Material Uncoated Carbide (Tough)
HSS Material Description All wrought and cast magnesium alloys All wrought aluminum alloys, including 6061T651, 5000, 6000, and 7000 series All aluminum sand and permanent mold casting alloys
Material Condition
Speed (fpm)
A, CD, ST, and A CD ST and A AC ST and A
800 600 500 750 600
Polycrystalline Diamond
f = feed (0.001 in./rev), s = speed (ft/min) Opt.
Avg.
Opt.
Avg.
f s
36 2820
17 4570
f s
36 865
17 1280
11 5890a
f s
24 2010
11 2760
8 4765
4 5755
f s
32 430
15 720
10 5085
5 6570
f s
36 630
17 1060
11 7560
6 9930
Aluminum Die-Casting Alloys Alloys 308.0 and 319.0 Alloys 390.0 and 392.0 Alloy 413 All other aluminum die-casting alloys including alloys 360.0 and 380.0
—
—
AC ST and A — ST and A
80 60 — 100
AC
125
Copyright 2004, Industrial Press, Inc., New York, NY
8 8270
Machinery's Handbook 27th Edition SPEEDS AND FEEDS
1039
a The feeds and speeds for turning Al alloys 308.0 and 319.0 with (polycrystalline) diamond tooling represent an expected tool life T = 960 minutes = 16 hours; corresponding feeds and speeds for 15minute tool life are 11⁄28600 and 6⁄37500. Abbreviations for material condition: A, annealed; AC, as cast; CD, cold drawn; and ST and A, solution treated and aged, respectively. Speeds for HSS (high-speed steel) tools are based on a feed of 0.012 inch/rev and a depth of cut of 0.125 inch; use Table 5c to adjust the HSS speeds for other feeds and depths of cut. The combined feed/speed data are based on a depth of cut of 0.1 inch, lead angle of 15 degrees, and nose radius of 3⁄64 inch. Use Table 5a to adjust given speeds for other feeds, depths of cut, and lead angles; use Table 5b to adjust given speeds for increased tool life up to 180 minutes. The data are based on tool grades (identified in Table 16) as follows: uncoated carbide, 15; diamond, 9.
Table 9. Cutting Feeds and Speeds for Turning Superalloys Tool Material Uncoated Carbide
HSS Turning Rough
Finish
Ceramic
Tough
Hard
Tough
CBN
f = feed (0.001 in./rev), s = speed (ft/min) Material Description
Speed (fpm)
T-D Nickel Discalloy 19-9DL, W-545 16-25-6, A-286, Incoloy 800, 801, { and 802, V-57 Refractaloy 26 J1300 Inconel 700 and 702, Nimonic 90 and { 95 S-816, V-36 S-590 Udimet 630 N-155 { Air Resist 213; Hastelloy B, C, G and X (wrought); Haynes 25 and 188; J1570; M252 (wrought); Mar{ M905 and M918; Nimonic 75 and 80 CW-12M; Hastelloy B and C (cast); { N-12M Rene 95 (Hot Isostatic Pressed) HS 6, 21, 2, 31 (X 40), 36, and 151; Haynes 36 and 151; Mar-M302, { M322, and M509, WI-52 Rene 41 Incoloy 901 Waspaloy Inconel 625, 702, 706, 718 (wrought), 721, 722, X750, 751, 901, 600, and { 604 AF2-1DA, Unitemp 1753 Colmonoy, Inconel 600, 718, K{ Monel, Stellite Air Resist 13 and 215, FSH-H14, Nasa CW-Re, X-45 Udimet 500, 700, and 710 Astroloy Mar-M200, M246, M421, and Rene 77, 80, and 95 (forged) B-1900, GMR-235 and 235D, IN 100 and 738, Inconel 713C and 718 (cast), M252 (cast)
70–80 15–35 25–35
80–100 35–40 30–40
30–35
35–40
15–20 15–25
20–25 20–30
10–12
12–15
10–15
15–20 15–30 20–25 15–25
10–20
15–20
20–25
8–12
10–15
—
—
10–12
10–15
10–15 10–20 10–30
12–20 20–35 25–35
15–20
20–35
8–10
10–15
—
—
10–12
10–15
10–15 5–10
12–20 5–15 10–12 10–15
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
f s
24 90
11 170
20 365
10 630
f s
20 75
10 135
20 245
10 420
f s
20 75
10 125
11 1170
6 2590
11 405
6 900
20 230
10 400
f s
28 20
13 40
11 895
6 2230
10 345
5 815
20 185
10 315
f s
28 15
13 15
11 615
6 1720
10 290
5 700
20 165
10 280
8–10 {
8–10
The speed recommendations for rough turning may be used as starting values for milling and drilling with HSS tools. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbide = 15; ceramic, hard = 4, tough = 3; CBN = 1.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1040
SPEEDS AND FEEDS
Speeds for HSS (high-speed steel) tools are based on a feed of 0.012 inch/rev and a depth of cut of 0.125 inch; use Table 5c to adjust the given speeds for other feeds and depths of cut. The combined feed/speed data in the remaining columns are based on a depth of cut of 0.1 inch, lead angle of 15 degrees, and nose radius of 3⁄64 inch. Use Table 5a to adjust given speeds for other feeds, depths of cut, and lead angles; use Table 5b to adjust given speeds for increased tool life up to 180 minutes. Examples are given in the text.
Speed and Feed Tables for Milling.—Tables 10 through 14 give feeds and speeds for milling. The data in the first speed column can be used with high-speed steel tools using the feeds given in Table 15a; these are the same speeds contained in previous editions of the Handbook. The remaining data in Tables 10 through 14 are combined feeds and speeds for end, face, and slit, slot, and side milling that use the speed adjustment factors given in Tables 15b, 15c, and 15d. Tool life for the combined feed/speed data can also be adjusted using the factors in Table 15e. Table 16 lists cutting tool grades and vendor equivalents. End Milling: Table data for end milling are based on a 3-tooth, 20-degree helix angle tool with a diameter of 1.0 inch, an axial depth of cut of 0.2 inch, and a radial depth of cut of 1 inch (full slot). Use Table 15b to adjust speeds for other feeds and axial depths of cut, and Table 15c to adjust speeds if the radial depth of cut is less than the tool diameter. Speeds are valid for all tool diameters. Face Milling: Table data for face milling are based on a 10-tooth, 8-inch diameter face mill, operating with a 15-degree lead angle, 3⁄64-inch nose radius, axial depth of cut = 0.1 inch, and radial depth (width) of cut = 6 inches (i.e., width of cut to cutter diameter ratio = 3⁄ ). These speeds are valid if the cutter axis is above or close to the center line of the work4 piece (eccentricity is small). Under these conditions, use Table 15d to adjust speeds for other feeds and axial and radial depths of cut. For larger eccentricity (i.e., when the cutter axis to workpiece center line offset is one half the cutter diameter or more), use the end and side milling adjustment factors (Tables 15b and 15c) instead of the face milling factors. Slit and Slot Milling: Table data for slit milling are based on an 8-tooth, 10-degree helix angle tool with a cutter width of 0.4 inch, diameter D of 4.0 inch, and a depth of cut of 0.6 inch. Speeds are valid for all tool diameters and widths. See the examples in the text for adjustments to the given speeds for other feeds and depths of cut. Tool life for all tabulated values is approximately 45 minutes; use Table 15e to adjust tool life from 15 to 180 minutes. Using the Feed and Speed Tables for Milling: The basic feed for milling cutters is the feed per tooth (f), which is expressed in inches per tooth. There are many factors to consider in selecting the feed per tooth and no formula is available to resolve these factors. Among the factors to consider are the cutting tool material; the work material and its hardness; the width and the depth of the cut to be taken; the type of milling cutter to be used and its size; the surface finish to be produced; the power available on the milling machine; and the rigidity of the milling machine, the workpiece, the workpiece setup, the milling cutter, and the cutter mounting. The cardinal principle is to always use the maximum feed that conditions will permit. Avoid, if possible, using a feed that is less than 0.001 inch per tooth because such low feeds reduce the tool life of the cutter. When milling hard materials with small-diameter end mills, such small feeds may be necessary, but otherwise use as much feed as possible. Harder materials in general will require lower feeds than softer materials. The width and the depth of cut also affect the feeds. Wider and deeper cuts must be fed somewhat more slowly than narrow and shallow cuts. A slower feed rate will result in a better surface finish; however, always use the heaviest feed that will produce the surface finish desired. Fine chips produced by fine feeds are dangerous when milling magnesium because spontaneous combustion can occur. Thus, when milling magnesium, a fast feed that will produce a relatively thick chip should be used. Cutting stainless steel produces a work-hardened layer on the surface that has been cut. Thus, when milling this material, the feed should be large enough to allow each cutting edge on the cutter to penetrate below the work-hardened
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPEEDS AND FEEDS
1041
layer produced by the previous cutting edge. The heavy feeds recommended for face milling cutters are to be used primarily with larger cutters on milling machines having an adequate amount of power. For smaller face milling cutters, start with smaller feeds and increase as indicated by the performance of the cutter and the machine. When planning a milling operation that requires a high cutting speed and a fast feed, always check to determine if the power required to take the cut is within the capacity of the milling machine. Excessive power requirements are often encountered when milling with cemented carbide cutters. The large metal removal rates that can be attained require a high horsepower output. An example of this type of calculation is given in the section on Machining Power that follows this section. If the size of the cut must be reduced in order to stay within the power capacity of the machine, start by reducing the cutting speed rather than the feed in inches per tooth. The formula for calculating the table feed rate, when the feed in inches per tooth is known, is as follows: fm = ft nt N where fm =milling machine table feed rate in inches per minute (ipm) ft =feed in inch per tooth (ipt) nt =number of teeth in the milling cutter N =spindle speed of the milling machine in revolutions per minute (rpm) Example:Calculate the feed rate for milling a piece of AISI 1040 steel having a hardness of 180 Bhn. The cutter is a 3-inch diameter high-speed steel plain or slab milling cutter with 8 teeth. The width of the cut is 2 inches, the depth of cut is 0.062 inch, and the cutting speed from Table 11 is 85 fpm. From Table 15a, the feed rate selected is 0.008 inch per tooth. 12V 12 × 85 N = ---------- = ------------------- = 108 rpm πD 3.14 × 3 f m = f t n t N = 0.008 × 8 × 108 = 7 ipm (approximately) Example 1, Face Milling:Determine the cutting speed and machine operating speed for face milling an aluminum die casting (alloy 413) using a 4-inch polycrystalline diamond cutter, a 3-inch width of cut, a 0.10-inch depth of cut, and a feed of 0.006 inch/tooth. Table 10 gives the feeds and speeds for milling aluminum alloys. The feed/speed pairs for face milling die cast alloy 413 with polycrystalline diamond (PCD) are 8⁄2320 (0.008 in./tooth feed at 2320 fpm) and 4⁄4755 (0.004 in./tooth feed at 4755 fpm). These speeds are based on an axial depth of cut of 0.10 inch, an 8-inch cutter diameter D, a 6-inch radial depth (width) of cut ar, with the cutter approximately centered above the workpiece, i.e., eccentricity is low, as shown in Fig. 3. If the preceding conditions apply, the given feeds and speeds can be used without adjustment for a 45-minute tool life. The given speeds are valid for all cutter diameters if a radial depth of cut to cutter diameter ratio (ar/D) of 3⁄4 is maintained (i.e., 6⁄8 = 3⁄4). However, if a different feed or axial depth of cut is required, or if the ar/D ratio is not equal to 3⁄4, the cutting speed must be adjusted for the conditions. The adjusted cutting speed V is calculated from V = Vopt × Ff × Fd × Far, where Vopt is the lower of the two speeds given in the speed table, and Ff, Fd, and Far are adjustment factors for feed, axial depth of cut, and radial depth of cut, respectively, obtained from Table 15d (face milling); except, when cutting near the end or edge of the workpiece as in Fig. 4, Table 15c (side milling) is used to obtain Ff.
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Machinery's Handbook 27th Edition 1042
SPEEDS AND FEEDS
Work ar
Work Feed ar
Feed
D
Cutter
D Cutter e Fig. 3.
Fig. 4.
In this example, the cutting conditions match the standard conditions specified in the speed table for radial depth of cut to cutter diameter (3 in./4 in.), and depth of cut (0.01 in), but the desired feed of 0.006 in./tooth does not match either of the feeds given in the speed table (0.004 or 0.008). Therefore, the cutting speed must be adjusted for this feed. As with turning, the feed factor Ff is determined by calculating the ratio of the desired feed f to maximum feed fopt from the speed table, and from the ratio Vavg/Vopt of the two speeds given in the speed table. The feed factor is found at the intersection of the feed ratio row and the speed ratio column in Table 15d. The speed is then obtained using the following equation: Chosen feed - = ------f - = 0.006 ------------- = 0.75 -----------------------------------0.008 Optimum feed f opt
Average speed- = V avg ------------------------------------------------ = 4755 ------------ ≈ 2.0 Optimum speed V opt 2320
F f = ( 1.25 + 1.43 ) ⁄ 2 = 1.34
F d = 1.0
F ar = 1.0
V = 2320 × 1.34 × 1.0 × 1.0 = 3109 fpm, and 3.82 × 3109 ⁄ 4 = 2970 rpm Example 2, End Milling:What cutting speed should be used for cutting a full slot (i.e., a slot cut from the solid, in one pass, that is the same width as the cutter) in 5140 steel with hardness of 300 Bhn using a 1-inch diameter coated carbide (insert) 0° lead angle end mill, a feed of 0.003 in./tooth, and a 0.2-inch axial depth of cut? The feed and speed data for end milling 5140 steel, Brinell hardness = 275–325, with a coated carbide tool are given in Table 11 as 15⁄80 and 8⁄240 for optimum and average sets, respectively. The speed adjustment factors for feed and depth of cut for full slot (end milling) are obtained from Table 15b. The calculations are the same as in the previous examples: f/fopt = 3⁄15 = 0.2 and Vavg/Vopt = 240⁄80 = 3.0, therefore, Ff = 6.86 and Fd = 1.0. The cutting speed for a 45-minute tool life is V = 80 × 6.86 × 1.0 = 548.8, approximately 550 ft/min. Example 3, End Milling:What cutting speed should be used in Example 2 if the radial depth of cut ar is 0.02 inch and axial depth of cut is 1 inch? In end milling, when the radial depth of cut is less than the cutter diameter (as in Fig. 4), first obtain the feed factor Ff from Table 15c, then the axial depth of cut and lead angle factor Fd from Table 15b. The radial depth of cut to cutter diameter ratio ar/D is used in Table 15c to determine the maximum and minimum feeds that guard against tool failure at high feeds and against premature tool wear caused by the tool rubbing against the work at very low feeds. The feed used should be selected so that it falls within the minimum to maximum feed range, and then the feed factor Ff can be determined from the feed factors at minimum and maximum feeds, Ff1 and Ff2 as explained below.
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Machinery's Handbook 27th Edition SPEEDS AND FEEDS
1043
The maximum feed fmax is found in Table 15c by multiplying the optimum feed from the speed table by the maximum feed factor that corresponds to the ar/D ratio, which in this instance is 0.02⁄1 = 0.02; the minimum feed fmin is found by multiplying the optimum feed by the minimum feed factor. Thus, fmax = 4.5 × 0.015 = 0.0675 in./tooth and fmin = 3.1 × 0.015 = 0.0465 in./tooth. If a feed between these maximum and minimum values is selected, 0.050 in./tooth for example, then for ar/D = 0.02 and Vavg/Vopt = 3.0, the feed factors at maximum and minimum feeds are Ff1 = 7.90 and Ff2 = 7.01, respectively, and by interpolation, Ff = 7.01 + (0.050 − 0.0465)(0.0675 − 0.0465) × (7.90 − 7.01) = 7.16, approximately 7.2. The depth of cut factor Fd is obtained from Table 15b, using fmax from Table 15c instead of the optimum feed fopt for calculating the feed ratio (chosen feed/optimum feed). In this example, the feed ratio = chosen feed/fmax = 0.050⁄0.0675 = 0.74, so the feed factor is Fd = 0.93 for a depth of cut = 1.0 inch and 0° lead angle. Therefore, the final cutting speed is 80 × 7.2 × 0.93 = 587 ft/min. Notice that fmax obtained from Table 15c was used instead of the optimum feed from the speed table, in determining the feed ratio needed to find Fd. Slit Milling.—The tabular data for slit milling is based on an 8-tooth, 10-degree helix angle cutter with a width of 0.4 inch, a diameter D of 4.0 inch, and a depth of cut of 0.6 inch. The given feeds and speeds are valid for any diameters and tool widths, as long as sufficient machine power is available. Adjustments to cutting speeds for other feeds and depths of cut are made using Table 15c or 15d, depending on the orientation of the cutter to the work, as illustrated in Case 1 and Case 2 of Fig. 5. The situation illustrated in Case 1 is approximately equivalent to that illustrated in Fig. 3, and Case 2 is approximately equivalent to that shown in Fig. 4. Case 1: If the cutter is fed directly into the workpiece, i.e., the feed is perpendicular to the surface of the workpiece, as in cutting off, then Table 15d (face milling) is used to adjust speeds for other feeds. The depth of cut portion of Table 15d is not used in this case (Fd = 1.0), so the adjusted cutting speed V = Vopt × Ff × Far. In determining the factor Far from Table 15d, the radial depth of cut ar is the length of cut created by the portion of the cutter engaged in the work. Case 2: If the cutter feed is parallel to the surface of the workpiece, as in slotting or side milling, then Table 15c (side milling) is used to adjust the given speeds for other feeds. In Table 15c, the cutting depth (slot depth, for example) is the radial depth of cut ar that is used to determine maximum and minimum allowable feed/tooth and the feed factor Ff. These minimum and maximum feeds are determined in the manner described previously, however, the axial depth of cut factor Fd is not required. The adjusted cutting speed, valid for cutters of any thickness (width), is given by V = Vopt × Ff. Slit Mill
f Case 1 ar Chip Thickness
Work
ar Case 2 f feed/rev, f Fig. 5. Determination of Radial Depth of Cut or in Slit Milling
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Machinery's Handbook 27th Edition
End Milling
HSS Material Condition*
Material All wrought aluminum alloys, 6061-T651, 5000, 6000, 7000 series All aluminum sand and permanent mold casting alloys
Alloys 360.0 and 380.0
—
Alloys 390.0 and 392.0
—
Alloy 413 All other aluminum die-casting alloys
{
Slit Milling
Polycrystalline Diamond
Indexable Insert Uncoated Carbide
HSS
Opt.
Avg. Opt.
Avg. Opt.
Avg. Opt.
Avg. Opt.
Avg. Opt.
Avg.
f s
15 165
8 15 850 620
8 39 2020 755
20 8 1720 3750
4 16 8430 1600
8 39 4680 840
20 2390
f s f s f s
15 30 15 30
Aluminum Die-Casting Alloys 8 15 8 39 100 620 2020 755 8 15 8 39 90 485 1905 555 39 220
20 1720 20 8 1380 3105 20 370
16 160 4 16 7845 145
8 375 8 355
39 840 39 690
20 2390 20 2320
4 4755
39 500
20 1680
39 690
20 2320
— ST and A
f s
AC
f s
15 30
8 90
15 355
8 39 1385 405
20 665
15 485
8 39 1905 555
20 8 1380 3105
8 2320
4 16 7845 145
8 335
Abbreviations designate: A, annealed; AC, as cast; CD, cold drawn; and ST and A, solution treated and aged, respectively. End Milling: Table data for end milling are based on a 3-tooth, 20-degree helix angle tool with a diameter of 1.0 inch, an axial depth of cut of 0.2 inch, and a radial depth of cut of 1 inch (full slot). Use Table 15b to adjust speeds for other feeds and axial depths of cut, and Table 15c to adjust speeds if the radial depth of cut is less than the tool diameter. Speeds are valid for all tool diameters. Face Milling: Table data for face milling are based on a 10-tooth, 8-inch diameter face mill, operating with a 15-degree lead angle, 3⁄64-inch nose radius, axial depth of cut = 0.1 inch, and radial depth (width) of cut = 6 inches (i.e., width of cut to cutter diameter ratio = 3⁄4). These speeds are valid if the cutter axis is above or close to the center line of the workpiece (eccentricity is small). Under these conditions, use Table 15d to adjust speeds for other feeds and axial and radial depths of cut. For larger eccentricity (i.e., when the cutter axis to workpiece center line offset is one half the cutter diameter or more), use the end and side milling adjustment factors (Tables 15b and 15c) instead of the face milling factors. Slit and Slot Milling: Table data for slit milling are based on an 8-tooth, 10-degree helix angle tool with a cutter width of 0.4 inch, diameter D of 4.0 inch, and a depth of cut of 0.6 inch. Speeds are valid for all tool diameters and widths. See the examples in the text for adjustments to the given speeds for other feeds and depths of cut. Tool life for all tabulated values is approximately 45 minutes; use Table 15e to adjust tool life from 15 to 180 minutes. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbide = 15; diamond = 9.
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
—
Indexable Insert Uncoated Carbide
f = feed (0.001 in./tooth), s = speed (ft/min)
CD ST and A CD ST and A
Alloys 308.0 and 319.0
Face Milling
Indexable Insert Uncoated Carbide
1044
Table 10. Cutting Feeds and Speeds for Milling Aluminum Alloys
Machinery's Handbook 27th Edition
Table 11. Cutting Feeds and Speeds for Milling Plain Carbon and Alloy Steels End Milling HSS Brinell Hardness
Material
{
(Resulfurized): 1108, 1109, 1115, 1117, 1118, 1120, 1126, 1211
{
(Resulfurized): 1132, 1137, 1139, 1140, 1144, 1146, 1151
(Leaded): 11L17, 11L18, 12L13, 12L14
Plain carbon steels: 1006, 1008, 1009, 1010, 1012, 1015, 1016, 1017, 1018, 1019, 1020, 1021, 1022, 1023, 1024, 1025, 1026, 1513, 1514
{
{
Uncoated Carbide
Opt.
Avg. Opt.
7 45
4 125 4 100
100–150
140
f s
150–200
130
f s
7 35
100–150
130
150–200
115
f s
7 30
175–225
115
f s
7 30
4 85
f s
7 25
4 70
f s
7 35
275–325
70 45
Slit Milling
f = feed (0.001 in./tooth), s = speed (ft/min)
Speed (fpm)
325–375
Face Milling
Coated Carbide Uncoated Carbide Coated Carbide Uncoated Carbide Coated Carbide
7 465
Avg. Opt. 4 735
7 800
Avg. Opt. 4 39 1050 225
Avg. Opt. 20 335
Avg. Opt.
39 415
20 685
39 215
20 405
4
7
4
39
20
39
20
39
20
39
20
325
565
465
720
140
220
195
365
170
350
245
495
39 185
20 350
39 90
20 235
39 135
20 325
39 265
20 495
39 525
20 830
39 175
20 330
4 100
39 215
20 405
39 185
20 350
39 415
20 685
7 210
4 435
7 300
4 560
39 90
20 170
150–200
130
200–250
110
f s
7 30
4 85
100–125
110
f s
7 45
4 125
125–175
110
f s
7 35
4 100
39 215
20 405
f s
7 30
4 85
39 185
20 350
7 465
4 735
7 800
4 39 1050 225
20 335
Copyright 2004, Industrial Press, Inc., New York, NY
1045
35
90
20 830
7
140
65
39 525
85
100–150
175–225
Avg.
20 495
4
375–425
225–275
Avg. Opt.
39 265
SPEEDS AND FEEDS
Free-machining plain carbon steels (resulfurized): 1212, 1213, 1215
HSS
Machinery's Handbook 27th Edition
End Milling HSS
Material
Plain carbon steels: 1055, 1060, 1064, 1065, 1070, 1074, 1078, 1080, 1084, 1086, 1090, 1095, 1548, 1551, 1552, 1561, 1566
Free-machining alloy steels (Resulfurized): 4140, 4150
Brinell Hardness
Speed (fpm)
125–175
100
175–225
85
225–275
70
275–325
55
325–375
35
375–425
25
125–175
90
175–225
75
225–275
60
275–325
45
325–375
30
375–425
15
175–200
100
200–250
90
250–300
60
300–375
45
375–425
35
Uncoated Carbide
Face Milling
Slit Milling
Coated Carbide Uncoated Carbide Coated Carbide Uncoated Carbide Coated Carbide f = feed (0.001 in./tooth), s = speed (ft/min)
Opt.
Avg. Opt.
Avg. Opt.
f s
7 35
4 100
Avg. Opt.
39 215
20 405
f s
7 30
4 85
39 185
20 350
f s
7 25
4 70
7 210
4 435
7 300
4 560
39 90
20 170
39 175
20 330
39 90
20 235
39 135
20 325
f s
7 30
4 85
7 325
4 565
7 465
4 720
39 140
20 220
39 195
20 365
39 170
20 350
39 245
20 495
f s
7 30
4 85
39 185
20 350
f s
7 25
4 70
7 210
4 435
7 300
4 560
39 175
20 330
39 90
20 235
39 135
20 325
f s
15 7
8 30
15 105
8 270
15 270
8 450
39 295
20 475
39 135
20 305
7 25
4 70
f s
15 6
8 25
15 50
8 175
15 85
8 255
39 200
20 320
39 70
20 210
7 25
4 70
f s
15 5
8 20
15 40
8 155
15 75
8 225
39 175
20 280
39 90
Avg. Opt.
20 170
Copyright 2004, Industrial Press, Inc., New York, NY
Avg. Opt.
Avg. Opt.
Avg.
SPEEDS AND FEEDS
Plain carbon steels: 1027, 1030, 1033, 1035, 1036, 1037, 1038, 1039, 1040, 1041, 1042, 1043, 1045, 1046, 1048, 1049, 1050, 1052, 1524, 1526, 1527, 1541
HSS
1046
Table 11. (Continued) Cutting Feeds and Speeds for Milling Plain Carbon and Alloy Steels
Machinery's Handbook 27th Edition
Table 11. (Continued) Cutting Feeds and Speeds for Milling Plain Carbon and Alloy Steels End Milling HSS
Material
Free-machining alloy steels (Leaded): 41L30, 41L40, 41L47, 41L50, 43L47, 51L32, 52L100, 86L20, 86L40
Speed (fpm)
150–200
115
200–250
95
Face Milling
Slit Milling
Coated Carbide Uncoated Carbide Coated Carbide Uncoated Carbide Coated Carbide f = feed (0.001 in./tooth), s = speed (ft/min)
Opt.
Avg. Opt.
f s
7 30
4 85
f s
7 30
4 85
f s
7 25
4 70
7 210
4 435
7 300
4 560
f s
15 7
8 30
15 105
8 270
15 220
7 325
Avg. Opt. 4 565
7 465
Avg. Opt. 4 720
39 140
Avg. Opt. 20 220
Avg. Opt.
39 195
20 365
39 185
20 350
39 175
8 450
Avg. Opt.
Avg.
39 170
20 350
39 245
20 495
20 330
39 90
20 235
39 135
20 325
39 295
20 475
39 135
20 305
39 265
20 495
39 70
20 210
39 115
20 290
250–300
70
300–375
50
375–425
40
125–175
100
175–225
90
225–275
60
f s
15 6
8 25
15 50
8 175
15 85
8 255
39 200
20 320
275–325
50
f s
15 5
8 20
15 45
8 170
15 80
8 240
39 190
20 305
325–375
40
375–425
25
f s
15 5
8 20
15 40
8 155
15 75
8 225
39 175
20 280
175–225
75 (65)
f s
15 5
8 30
15 105
8 270
15 220
8 450
39 295
20 475
39 135
20 305
39 265
20 495
225–275
60
f s
15 5
8 25
15 50
8 175
15 85
8 255
39 200
20 320
39 70
20 210
39 115
20 290
275–325
50 (40)
f s
15 5
8 25
15 45
8 170
15 80
8 240
39 190
20 305
325–375
35 (30)
375–425
20
f s
15 5
8 20
15 40
8 155
15 75
8 225
39 175
20 280
39 90
20 170
1047
Alloy steels: 1330, 1335, 1340, 1345, 4032, 4037, 4042, 4047, 4130, 4135, 4137, 4140, 4142, 4145, 4147, 4150, 4161, 4337, 4340, 50B44, 50B46, 50B50, 50B60, 5130, 5132, 5140, 5145, 5147, 5150, 5160, 51B60, 6150, 81B45, 8630, 8635, 8637, 8640, 8642, 8645, 8650, 8655, 8660, 8740, 9254, 9255, 9260, 9262, 94B30 E51100, E52100: use (HSS speeds)
Brinell Hardness
Uncoated Carbide
SPEEDS AND FEEDS
Alloy steels: 4012, 4023, 4024, 4028, 4118, 4320, 4419, 4422, 4427, 4615, 4620, 4621, 4626, 4718, 4720, 4815, 4817, 4820, 5015, 5117, 5120, 6118, 8115, 8615, 8617, 8620, 8622, 8625, 8627, 8720, 8822, 94B17
HSS
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Machinery's Handbook 27th Edition
End Milling HSS
Material Ultra-high-strength steels (not AISI): AMS 6421 (98B37 Mod.), 6422 (98BV40), 6424, 6427, 6428, 6430, 6432, 6433, 6434, 6436, and 6442; 300M, D6ac
Nitriding steels (not AISI): Nitralloy 125, 135, 135 Mod., 225, and 230, Nitralloy N, Nitralloy EZ, Nitrex 1
Uncoated Carbide
Face Milling
Slit Milling
Coated Carbide Uncoated Carbide Coated Carbide Uncoated Carbide Coated Carbide f = feed (0.001 in./tooth), s = speed (ft/min)
Brinell Hardness
Speed (fpm)
220–300
60
300–350
45
350–400
20
f s
43–52 Rc
—
250–325
Opt.
Avg. Opt.
f s
Avg. Opt.
Avg. Opt.
4 355
8 150
4 320
f s
5 20†
3 55
50
f s
8 165
4 355
50–52 Rc
—
f s
5 20†
3 55
200–250
60
f s
15 7
8 30
15 105
8 270
15 220
8 450
39 295
300–350
25
f s
15 5
8 20
15 40
8 155
15 75
8 225
39 175
8 15
4 45
8 300
Avg. Opt.
8 165
39 130
8 300
Avg. Opt.
Avg. Opt.
Avg.
4 480 20 235
39 75
20 175
39 5
20 15
39 5
20 15
39 135
20 305
4 480
20 475
39 265
20 495
20 280
For HSS (high-speed steel) tools in the first speed column only, use Table 15a for recommended feed in inches per tooth and depth of cut. End Milling: Table data for end milling are based on a 3-tooth, 20-degree helix angle tool with a diameter of 1.0 inch, an axial depth of cut of 0.2 inch, and a radial depth of cut of 1 inch (full slot). Use Table 15b to adjust speeds for other feeds and axial depths of cut, and Table 15c to adjust speeds if the radial depth of cut is less than the tool diameter. Speeds are valid for all tool diameters. Face Milling: Table data for face milling are based on a 10-tooth, 8-inch diameter face mill, operating with a 15-degree lead angle, 3⁄64-inch nose radius, axial depth of cut = 0.1 inch, and radial depth (width) of cut = 6 inches (i.e., width of cut to cutter diameter ratio = 3⁄4). These speeds are valid if the cutter axis is above or close to the center line of the workpiece (eccentricity is small). Under these conditions, use Table 15d to adjust speeds for other feeds and axial and radial depths of cut. For larger eccentricity (i.e., when the cutter axis to workpiece center line offset is one half the cutter diameter or more), use the end and side milling adjustment factors (Tables 15b and 15c) instead of the face milling factors. Slit and Slot Milling: Table data for slit milling are based on an 8-tooth, 10-degree helix angle tool with a cutter width of 0.4 inch, diameter D of 4.0 inches, and a depth of cut of 0.6 inch. Speeds are valid for all tool diameters and widths. See the examples in the text for adjustments to the given speeds for other feeds and depths of cut. Tool life for all tabulated values is approximately 45 minutes; use Table 15e to adjust tool life from 15 to 180 minutes. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: end and slit milling uncoated carbide = 20 except † = 15; face milling uncoated carbide = 19; end, face, and slit milling coated carbide = 10.
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
Maraging steels (not AISI): 18% Ni Grades 200, 250, 300, and 350
HSS
1048
Table 11. (Continued) Cutting Feeds and Speeds for Milling Plain Carbon and Alloy Steels
Machinery's Handbook 27th Edition
Table 12. Cutting Feeds and Speeds for Milling Tool Steels End Milling HSS Material
Hot work, chromium type: H10, H11, H12, H13, H14, H19
Hot work, tungsten and molybdenum types: H21, H22, H23, H24, H25, H26, H41, H42, H43 Special-purpose, low alloy: L2, L3, L6 Mold: P2, P3, P4, P5, P6 P20, P21
{
150–200 175–225
85 55
175–225
50
200–250
40
200–250
50
200–250 225–275 150–200 200–250
45 40 60 50
325–375
30
48–50 Rc 50–52 Rc 52–56 Rc 150–200
— — — 55
200–250
45
150–200
65
100–150 150–200
75 60
200–250
50
225–275
40
225–275
30
Uncoated Carbide
Slit Milling Uncoated Carbide
CBN
Coated Carbide
f = feed (0.001 in./tooth), s = speed (ft/min) Opt.
f s
8 25
Avg.
4 70
Opt.
8 235
Avg.
Opt.
4 8 455 405
f s
f s
8 15
4 45
f s
8 150
4 320
5 20†
3 55
f s f s
f s
8 25
4 70
8 235
4 8 455 405
Avg.
Opt.
Avg.
4 39 635 235
20 385
39 255
20 385
39 130
20 235
Opt.
39 50 39 255
20 385
4 39 635 235
20 385
39 255
20 385
Copyright 2004, Industrial Press, Inc., New York, NY
Avg.
Opt.
Avg.
Opt.
39 115
20 39 265 245
39 75
20 175
20 39 135 5†
39 115
Avg.
20 445
20 15
20 39 265 245
20 445
1049
High-speed steel: M1, M2, M6, M10, T1, T2, T6 M3-1, M4, M7, M30, M33, M34, M36, M41, M42, M43, M44, M46, M47, T5, T8 T15, M3-2
Speed (fpm)
Coated Carbide
SPEEDS AND FEEDS
Water hardening: W1, W2, W5 Shock resisting: S1, S2, S5, S6, S7 Cold work, oil hardening: O1, O2, O6, O7 Cold work, high carbon, high chromium: D2, D3, D4, D5, D7 Cold work, air hardening: A2, { A3, A8, A9, A10 A4, A6 A7
Brinell Hardness
Face Milling
Uncoated Carbide
HSS
Machinery's Handbook 27th Edition
End Milling HSS Material Free-machining stainless steels (Ferritic): 430F, 430FSe (Austenitic): 203EZ, 303, 303Se, 303MA, { 303Pb, 303Cu, 303 Plus X (Martensitic): 416, 416Se, 416 Plus X, 420F, 420FSe, 440F, 440FSe
{
Stainless steels (Ferritic): 405, 409, 429, 430, 434, 436, 442, 446, 502 (Austenitic): 201, 202, 301, 302, 304, 304L, { 305, 308, 321, 347, 348 (Austenitic): 302B, 309, 309S, 310, 310S, 314, 316, 316L, 317, 330 (Martensitic): 403, 410, 420, 501
{
Face Milling
Uncoated Carbide
HSS
Coated Carbide
Coated Carbide
Slit Milling Uncoated Carbide
Coated Carbide
f = feed (0.001 in./tooth), s = speed (ft/min)
Brinell Hardness
Speed (fpm)
135–185
110
f s
135–185 225–275 135–185 185–240 275–325 375–425
100 80 110 100 60 30
f s
135–185
90
135–185 225–275
75 65
135–185
70
135–175 175–225 275–325 375–425
95 85 55 35
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
7 30
4 80
7 305
4 780
7 420
4 1240
39 210
20 385
39 120
20 345
39 155
20 475
7 20
4 55
7 210
4 585
39 75
20 240
f s
7 30
4 80
7 305
4 780
39 120
20 345
39 155
20 475
f s
7 20
4 55
7 210
4 585
39 75
20 240
7 420
4 1240
Copyright 2004, Industrial Press, Inc., New York, NY
39 210
20 385
SPEEDS AND FEEDS
Table 13. Cutting Feeds and Speeds for Milling Stainless Steels
1050
For HSS (high-speed steel) tools in the first speed column only, use Table 15a for recommended feed in inches per tooth and depth of cut. End Milling: Table data for end milling are based on a 3-tooth, 20-degree helix angle tool with a diameter of 1.0 inch, an axial depth of cut of 0.2 inch, and a radial depth of cut of 1 inch (full slot). Use Table 15b to adjust speeds for other feeds and axial depths of cut, and Table 15c to adjust speeds if the radial depth of cut is less than the tool diameter. Speeds are valid for all tool diameters. Face Milling: Table data for face milling are based on a 10-tooth, 8-inch diameter face mill, operating with a 15-degree lead angle, 3⁄64-inch nose radius, axial depth of cut = 0.1 inch, and radial depth (width) of cut = 6 inches (i.e., width of cut to cutter diameter ratio = 3⁄4). These speeds are valid if the cutter axis is above or close to the center line of the workpiece (eccentricity is small). Under these conditions, use Table 15d to adjust speeds for other feeds and axial and radial depths of cut. For larger eccentricity (i.e., when the cutter axis to workpiece center line offset is one half the cutter diameter or more), use the end and side milling adjustment factors (Tables 15b and 15c) instead of the face milling factors. Slit and Slot Milling: Table data for slit milling are based on an 8-tooth, 10-degree helix angle tool with a cutter width of 0.4 inch, diameter D of 4.0 inches, and a depth of cut of 0.6 inch. Speeds are valid for all tool diameters and widths. See the examples in the text for adjustments to the given speeds for other feeds and depths of cut. Tool life for all tabulated values is approximately 45 minutes; use Table 15e to adjust tool life from 15 to 180 minutes. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbide = 20, † = 15; coated carbide = 10; CBN = 1.
Machinery's Handbook 27th Edition
Table 13. (Continued) Cutting Feeds and Speeds for Milling Stainless Steels End Milling HSS Material Stainless Steels (Martensitic): 414, 431, Greek Ascoloy, 440A, 440B, 440C
{
Speed (fpm)
225–275
55–60
275–325
45–50
375–425
30
150–200
60
275–325
50
325–375
40
375–450
25
Coated Carbide
Slit Milling
Coated Carbide
Uncoated Carbide
Coated Carbide
f = feed (0.001 in./tooth), s = speed (ft/min) Opt.
f s
7 20
Avg.
Opt.
Avg.
4 55
7 210
4 585
Opt.
Avg.
Opt.
Avg.
Opt.
39 75
Avg.
Opt.
Avg.
20 240
For HSS (high-speed steel) tools in the first speed column only, use Table 15a for recommended feed in inches per tooth and depth of cut. End Milling: Table data for end milling are based on a 3-tooth, 20-degree helix angle tool with a diameter of 1.0 inch, an axial depth of cut of 0.2 inch, and a radial depth of cut of 1 inch (full slot). Use Table 15b to adjust speeds for other feeds and axial depths of cut, and Table 15c to adjust speeds if the radial depth of cut is less than the tool diameter. Speeds are valid for all tool diameters.
SPEEDS AND FEEDS
(Precipitation hardening): 15-5PH, 17-4PH, 177PH, AF-71, 17-14CuMo, AFC-77, AM-350, AM-355, AM-362, Custom 455, HNM, PH138, PH14-8Mo, PH15-7Mo, Stainless W
Brinell Hardness
Face Milling
Uncoated Carbide
HSS
Face Milling: Table data for face milling are based on a 10-tooth, 8-inch diameter face mill, operating with a 15-degree lead angle, 3⁄64-inch nose radius, axial depth of cut = 0.1 inch, and radial depth (width) of cut = 6 inches (i.e., width of cut to cutter diameter ratio = 3⁄4). These speeds are valid if the cutter axis is above or close to the center line of the workpiece (eccentricity is small). Under these conditions, use Table 15d to adjust speeds for other feeds and axial and radial depths of cut. For larger eccentricity (i.e., when the cutter axis to workpiece center line offset is one half the cutter diameter or more), use the end and side milling adjustment factors (Tables 15b and 15c) instead of the face milling factors. Slit and Slot Milling: Table data for slit milling are based on an 8-tooth, 10-degree helix angle tool with a cutter width of 0.4 inch, diameter D of 4.0 inch, and a depth of cut of 0.6 inch. Speeds are valid for all tool diameters and widths. See the examples in the text for adjustments to the given speeds for other feeds and depths of cut.
Copyright 2004, Industrial Press, Inc., New York, NY
1051
Tool life for all tabulated values is approximately 45 minutes; use Table 15e to adjust tool life from 15 to 180 minutes. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbide = 20; coated carbide = 10.
Machinery's Handbook 27th Edition
1052
Table 14. Cutting Feeds and Speeds for Milling Ferrous Cast Metals End Milling HSS Brinell Speed Hardness (fpm)
Material
Uncoated Carbide
HSS
Face Milling Coated Carbide
Uncoated Carbide
Coated Carbide
Slit Milling
Ceramic
CBN
Uncoated Carbide
Coated Carbide
f = feed (0.001 in./tooth), s = speed (ft/min) Opt. Avg. Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
39 140
20 225
39 285
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
39 1130
20 39 1630 200
20 39 530 205 20 39 400 145
Avg.
Opt.
Avg.
Gray Cast Iron ASTM Class 20
120–150
100
ASTM Class 25
160–200
80
ASTM Class 30, 35, and 40
190–220
70
220–260
50
250–320
30
ASTM Type 1, 1b, 5 (Ni resist)
100–215
50
ASTM Type 2, 3, 6 (Ni resist)
120–175
40
ASTM Type 2b, 4 (Ni resist)
150–250
30
(Ferritic): 32510, 35018
110–160
110
(Pearlitic): 40010, 43010, 45006, 45008, 48005, 50005
160–200
80
200–240
65
3 90
5 520
3 855
f 5 s 30
3 70
5 515
3 1100
f 5 s 30
3 70
5 180
f 5 s 25
3 65
5 150
f 7 s 15
4 35
7 125
f 7 s 10
4 30
7 90
20 535
20 420
39 95
20 39 160 185
20 395
39 845
20 39 1220 150
20 380
3 250
39 120
20 39 195 225
20 520
39 490
20 925
39 85
20 150
3 215
39 90
20 39 150 210
20 400
39 295
20 645
39 70
20 125
4 240
39 100
20 39 155 120
20 255
39 580
20 920
39 60
20 135
4 210
39 95
20 39 145 150
20 275
39 170
20 415
39 40
20 100
Malleable Iron
(Martensitic): 53004, 60003, 60004
200–255
55
(Martensitic): 70002, 70003
220–260
50
(Martensitic): 80002
240–280
45
(Martensitic): 90001
250–320
25
(Ferritic): 60-40-18, 65-45-12
140–190
75
190–225
60
Nodular (Ductile) Iron
(Ferritic-Pearlitic): 80-55-06
{
225–260
50
(Pearlitic-Martensitic): 100-70-03
240–300
40
(Martensitic): 120-90-02
270–330
25
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
ASTM Class 45 and 50 ASTM Class 55 and 60
f 5 s 35
Machinery's Handbook 27th Edition
Table 14. (Continued) Cutting Feeds and Speeds for Milling Ferrous Cast Metals End Milling HSS
HSS
Face Milling Coated Carbide
Uncoated Carbide
Coated Carbide
Slit Milling
Ceramic
CBN
Uncoated Carbide
Coated Carbide
f = feed (0.001 in./tooth), s = speed (ft/min)
Brinell Speed Hardness (fpm)
Material
Uncoated Carbide
Opt. Avg. Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Opt.
Avg.
Cast Steels (Low carbon): 1010, 1020
100–150
100
125–175
95 80 60
150–200
85
200–250
75
250–300
50
175–225
70
(Medium-carbon alloy): 1330, 1340, 225–250 2325, 2330, 4125, 4130, 4140, 4330, { 250–300 4340, 8030, 80B30, 8040, 8430, 8440, 300–350 8630, 8640, 9525, 9530, 9535
65
(Low-carbon alloy): 1320, 2315, 2320, 4110, 4120, 4320, 8020, 8620
{
{
50 30
4 7 70 245†
4 410
7 420
4 650
39 265‡
20 430
39 135†
20 39 260 245
20 450
f 7 s 20
4 7 55 160†
4 400
7 345
4 560
39 205‡
20 340
39 65†
20 39 180 180
20 370
f 7 s 15
4 7 45 120†
4 310
39 45†
20 135
f s
39 25
20 40
Copyright 2004, Industrial Press, Inc., New York, NY
1053
For HSS (high-speed steel) tools in the first speed column only, use Table 15a for recommended feed in inches per tooth and depth of cut. End Milling: Table data for end milling are based on a 3-tooth, 20-degree helix angle tool with a diameter of 1.0 inch, an axial depth of cut of 0.2 inch, and a radial depth of cut of 1 inch (full slot). Use Table 15b to adjust speeds for other feeds and axial depths of cut, and Table 15c to adjust speeds if the radial depth of cut is less than the tool diameter. Speeds are valid for all tool diameters. Face Milling: Table data for face milling are based on a 10-tooth, 8-inch diameter face mill, operating with a 15-degree lead angle, 3⁄64-inch nose radius, axial depth of cut = 0.1 inch, and radial depth (width) of cut = 6 inches (i.e., width of cut to cutter diameter ratio = 3⁄4). These speeds are valid if the cutter axis is above or close to the center line of the workpiece (eccentricity is small). Under these conditions, use Table 15d to adjust speeds for other feeds and axial and radial depths of cut. For larger eccentricity (i.e., when the cutter axis to workpiece center line offset is one half the cutter diameter or more), use the end and side milling adjustment factors (Tables 15b and 15c) instead of the face milling factors. Slit and Slot Milling: Table data for slit milling are based on an 8-tooth, 10-degree helix angle tool with a cutter width of 0.4 inch, diameter D of 4.0 inches, and a depth of cut of 0.6 inch. Speeds are valid for all tool diameters and widths. See the examples in the text for adjustments to the given speeds for other feeds and depths of cut. Tool life for all tabulated values is approximately 45 minutes; use Table 15e to adjust tool life from 15 to 180 minutes. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbide = 15 except † = 20; end and slit milling coated carbide = 10; face milling coated carbide = 11 except ‡ = 10. ceramic = 6; CBN = 1.
SPEEDS AND FEEDS
175–225 225–300
(Medium carbon): 1030, 1040 1050
f 7 s 25
Machinery's Handbook 27th Edition
1054
Table 15a. Recommended Feed in Inches per Tooth (ft) for Milling with High Speed Steel Cutters End Mills Depth of Cut, .250 in
Depth of Cut, .050 in
Cutter Diam., in 1⁄ 2
Hardness, HB
Material
3⁄ 4
1 and up
Cutter Diam., in 1⁄ 4
1⁄ 2
3⁄ 4
1 and up
Plain or Slab Mills
Form Relieved Cutters
Face Mills and Shell End Mills
Slotting and Side Mills
Feed per Tooth, inch
Free-machining plain carbon steels
100–185
.001
.003
.004
.001
.002
.003
.004
.003–.008
.005
.004–.012
.002–.008
Plain carbon steels, AISI 1006 to 1030; 1513 to 1522
100–150
.001
.003
.003
.001
.002
.003
.004
.003–.008
.004
.004–.012
.002–.008
{
.001
.002
.003
.001
.002
.002
.003
.003–.008
.004
.003–.012
.002–.008
.001
.003
.003
.001
.002
.003
.004
.003–.008
.004
.004–.012
.002–.008
{ 180–220
.001
.002
.003
.001
.002
.002
.003
.003–.008
.004
.003–.012
.002–.008
220–300
.001
.002
.002
.001
.001
.002
.003
.002–.006
.003
.002–.008
.002–.006
Alloy steels having less than 3% carbon. Typical examples: AISI 4012, 4023, 4027, 4118, 4320 4422, 4427, 4615, 4620, 4626, 4720, 4820, 5015, 5120, 6118, 8115, 8620 8627, 8720, 8820, 8822, 9310, 93B17
125–175
.001
.003
.003
.001
.002
.003
.004
.003–.008
.004
.004–.012
.002–.008
175–225
.001
.002
.003
.001
.002
.003
.003
.003–.008
.004
.003–.012
.002–.008
225–275
.001
.002
.003
.001
.001
.002
.003
.002–.006
.003
.003–.008
.002–.006
275–325
.001
.002
.002
.001
.001
.002
.002
.002–.005
.003
.002–.008
.002–.005
Alloy steels having 3% carbon or more. Typical examples: AISI 1330, 1340, 4032, 4037, 4130, 4140, 4150, 4340, 50B40, 50B60, 5130, 51B60, 6150, 81B45, 8630, 8640, 86B45, 8660, 8740, 94B30
175–225
.001
.002
.003
.001
.002
.003
.004
.003–.008
.004
.003–.012
.002–.008
225–275
.001
.002
.003
.001
.001
.002
.003
.002–.006
.003
.003–.010
.002–.006
275–325
.001
.002
.002
.001
.001
.002
.003
.002–.005
.003
.002–.008
.002–.005
325–375
.001
.002
.002
.001
.001
.002
.002
.002–.004
.002
.002–.008
.002–.005
150–200
.001
.002
.002
.001
.002
.003
.003
.003–.008
.004
.003–.010
.002–.006
200–250
.001
.002
.002
.001
.002
.002
.003
.002–.006
.003
.003–.008
.002–.005
120–180
.001
.003
.004
.002
.003
.004
.004
.004–.012
.005
.005–.016
.002–.010
180–225
.001
.002
.003
.001
.002
.003
.003
.003–.010
.004
.004–.012
.002–.008
225–300
.001
.002
.002
.001
.001
.002
.002
.002–.006
.003
.002–.008
.002–.005
110–160
.001
.003
.004
.002
.003
.004
.004
.003–.010
.005
.005–.016
.002–.010
AISI 1033 to 1095; 1524 to 1566
Tool steel
Gray cast iron
Free malleable iron
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
150–200 120–180
Machinery's Handbook 27th Edition
Table 15a. (Continued) Recommended Feed in Inches per Tooth (ft) for Milling with High Speed Steel Cutters End Mills Depth of Cut, .250 in
Depth of Cut, .050 in
Cutter Diam., in
Material(Continued) Pearlitic-Martensitic malleable iron
Zinc alloys (die castings) Copper alloys (brasses & bronzes)
1⁄ 2
3⁄ 4
Plain or Slab Mills
Form Relieved Cutters
Face Mills and Shell End Mills
Slotting and Side Mills
Hardness, HB 160–200
.001
.003
.004
.001
.002
.003
.004
.003–.010
.004
.004–.012
.002–.018
200–240
.001
.002
.003
.001
.002
.003
.003
.003–.007
.004
.003–.010
.002–.006
240–300
.001
.002
.002
.001
.001
.002
.002
.002–.006
.003
.002–.008
.002–.005
100–180
.001
.003
.003
.001
.002
.003
.004
.003–.008
.004
.003–.012
.002–.008
180–240
.001
.002
.003
.001
.002
.003
.003
.003–.008
.004
.003–.010
.002–.006
240–300
.001
.002
.002
.005
.002
.002
.002
.002–.006
.003
.003–.008
.002–.005
…
.002
.003
.004
.001
.003
.004
.006
.003–.010
.005
.004–.015
.002–.012
100–150
.002
.004
.005
.002
.003
.005
.006
.003–.015
.004
.004–.020
.002–.010
1 and up
1⁄ 4
1 and up
Feed per Tooth, inch
150–250
.002
.003
.004
.001
.003
.004
.005
.003–.015
.004
.003–.012
.002–.008
Free cutting brasses & bronzes
80–100
.002
.004
.005
.002
.003
.005
.006
.003–.015
.004
.004–.015
.002–.010
Cast aluminum alloys—as cast
…
.003
.004
.005
.002
.004
.005
.006
.005–.016
.006
.005–.020
.004–.012
Cast aluminum alloys—hardened
…
.003
.004
.005
.002
.003
.004
.005
.004–.012
.005
.005–.020
.004–.012
Wrought aluminum alloys— cold drawn
…
.003
.004
.005
.002
.003
.004
.005
.004–.014
.005
.005–.020
.004–.012
Wrought aluminum alloys—hardened
…
.002
.003
.004
.001
.002
.003
.004
.003–.012
.004
.005–.020
.004–.012
Magnesium alloys Ferritic stainless steel Austenitic stainless steel
Martensitic stainless steel
.003
.004
.005
.003
.004
.005
.007
.005–.016
.006
.008–.020
.005–.012
.001
.002
.003
.001
.002
.003
.003
.002–.006
.004
.004–.008
.002–.007
135–185
.001
.002
.003
.001
.002
.003
.003
.003–.007
.004
.005–.008
.002–.007
185–275
.001
.002
.003
.001
.002
.002
.002
.003–.006
.003
.004–.006
.002–.007
135–185
.001
.002
.002
.001
.002
.003
.003
.003–.006
.004
.004–.010
.002–.007
185–225
.001
.002
.002
.001
.002
.002
.003
.003–.006
.004
.003–.008
.002–.007
225–300
.0005
.002
.002
.0005
.001
.002
.002
.002–.005
.003
.002–.006
.002–.005
100–160
.001
.003
.004
.001
.002
.003
.004
.002–.006
.004
.002–.008
.002–.006
Copyright 2004, Industrial Press, Inc., New York, NY
1055
Monel
… 135–185
SPEEDS AND FEEDS
Cast steel
3⁄ 4
Cutter Diam., in
1⁄ 2
Machinery's Handbook 27th Edition
1056
Table 15b. End Milling (Full Slot) Speed Adjustment Factors for Feed, Depth of Cut, and Lead Angle Cutting Speed, V = Vopt × Ff × Fd Ratio of the two cutting speeds Ratio of Chosen Feed to Optimum Feed
Depth of Cut and Lead Angle
(average/optimum) given in the tables Vavg/Vopt 1.00
1.25
1.50
2.00
2.50
3.00
4.00
1 in
(25.4 mm)
0.4 in
(10.2 mm)
0.2 in
(5.1 mm)
0.1 in
(2.4 mm)
0.04 in
(1.0 mm)
0°
45°
0°
45°
0°
45°
0°
45°
0°
45°
Feed Factor, Ff
Depth of Cut and Lead Angle Factor, Fd
1.0
1.0
1.0
1.0
1.0
1.0
1.0
0.91
1.36
0.94
1.38
1.00
0.71
1.29
1.48
1.44
1.66
0.90
1.00
1.06
1.09
1.14
1.18
1.21
1.27
0.91
1.33
0.94
1.35
1.00
0.72
1.26
1.43
1.40
1.59
0.80
1.00
1.12
1.19
1.31
1.40
1.49
1.63
0.92
1.30
0.95
1.32
1.00
0.74
1.24
1.39
1.35
1.53
0.70
1.00
1.18
1.30
1.50
1.69
1.85
2.15
0.93
1.26
0.95
1.27
1.00
0.76
1.21
1.35
1.31
1.44
0.60
1.00
1.20
1.40
1.73
2.04
2.34
2.89
0.94
1.22
0.96
1.25
1.00
0.79
1.18
1.28
1.26
1.26
0.50
1.00
1.25
1.50
2.00
2.50
3.00
4.00
0.95
1.17
0.97
1.18
1.00
0.82
1.14
1.21
1.20
1.21
0.40
1.00
1.23
1.57
2.29
3.08
3.92
5.70
0.96
1.11
0.97
1.12
1.00
0.86
1.09
1.14
1.13
1.16
0.30
1.00
1.14
1.56
2.57
3.78
5.19
8.56
0.98
1.04
0.99
1.04
1.00
0.91
1.04
1.07
1.05
1.09
0.20
1.00
0.90
1.37
2.68
4.49
6.86
17.60
1.00
0.85
1.00
0.95
1.00
0.99
0.97
0.93
0.94
0.88
0.10
1.00
0.44
0.80
2.08
4.26
8.00
20.80
1.05
0.82
1.00
0.81
1.00
1.50
0.85
0.76
0.78
0.67
For HSS (high-speed steel) tool speeds in the first speed column of Tables 10 through 14, use Table 15a to determine appropriate feeds and depths of cut. Cutting feeds and speeds for end milling given in Tables 11 through 14 (except those for high-speed steel in the first speed column) are based on milling a 0.20-inch deep full slot (i.e., radial depth of cut = end mill diameter) with a 1-inch diameter, 20-degree helix angle, 0-degree lead angle end mill. For other depths of cut (axial), lead angles, or feed, use the two feed/speed pairs from the tables and calculate the ratio of desired (new) feed to optimum feed (largest of the two feeds are given in the tables), and the ratio of the two cutting speeds (Vavg/Vopt). Find the feed factor Ff at the intersection of the feed ratio row and the speed ratio column in the left half of the Table. The depth of cut factor Fd is found in the same row as the feed factor, in the right half of the table under the column corresponding to the depth of cut and lead angle. The adjusted cutting speed can be calculated from V = Vopt × Ff × Fd, where Vopt is the smaller (optimum) of the two speeds from the speed table (from the left side of the column containing the two feed/speed pairs). See the text for examples. If the radial depth of cut is less than the cutter diameter (i.e., for cutting less than a full slot), the feed factor Ff in the previous equation and the maximum feed fmax must be obtained from Table 15c. The axial depth of cut factor Fd can then be obtained from this table using fmax in place of the optimum feed in the feed ratio. Also see the footnote to Table 15c.
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
1.00
Machinery's Handbook 27th Edition
Table 15c. End, Slit, and Side Milling Speed Adjustment Factors for Radial Depth of Cut Cutting Speed, V = Vopt × Ff × Fd Vavg/Vopt
Vavg/Vopt
Maximum Feed/Tooth Factor
1.25
1.00
1.00
1.00
1.00
1.00
1.00
1.00
0.75
1.00
1.15
1.24
1.46
1.54
1.66
0.60
1.00
1.23
1.40
1.73
2.04
0.50
1.00
1.25
1.50
2.00
0.40
1.10
1.25
1.55
0.30
1.35
1.20
0.20
1.50
0.10
2.05
0.05 0.02
Maximum Feed/Tooth Factor
1.25
1.00
0.70
1.18
1.30
1.50
1.69
1.85
2.15
1.87
0.70
1.24
1.48
1.93
2.38
2.81
3.68
2.34
2.89
0.70
1.24
1.56
2.23
2.95
3.71
5.32
2.50
3.00
4.00
0.70
1.20
1.58
2.44
3.42
4.51
6.96
2.17
2.83
3.51
4.94
0.77
1.25
1.55
2.55
3.72
5.08
8.30
1.57
2.28
3.05
3.86
5.62
0.88
1.23
1.57
2.64
4.06
5.76
10.00
1.14
1.56
2.57
3.78
5.19
8.56
1.05
1.40
1.56
2.68
4.43
6.37
11.80
0.92
1.39
2.68
4.46
6.77
13.10
1.44
0.92
1.29
2.50
4.66
7.76
17.40
2.90
0.68
1.12
2.50
4.66
7.75
17.30
2.00
0.68
1.12
2.08
4.36
8.00
20.80
4.50
0.38
0.71
1.93
4.19
7.90
21.50
3.10
0.38
0.70
1.38
3.37
7.01
22.20
1.50
2.00
2.50
3.00
4.00
Feed Factor Ff at Maximum Feed per Tooth, Ff1
1.50
2.00
2.50
3.00
4.00
Feed Factor Ff at Minimum Feed per Tooth, Ff2
This table is for side milling, end milling when the radial depth of cut (width of cut) is less than the tool diameter (i.e., less than full slot milling), and slit milling when the feed is parallel to the work surface (slotting). The radial depth of cut to diameter ratio is used to determine the recommended maximum and minimum values of feed/tooth, which are found by multiplying the feed/tooth factor from the appropriate column above (maximum or minimum) by feedopt from the speed tables. For example, given two feed/speed pairs 7⁄15 and 4⁄45 for end milling cast, medium-carbon, alloy steel, and a radial depth of cut to diameter ratio ar/D of 0.10 (a 0.05-inch width of cut for a 1⁄2-inch diameter end mill, for example), the maximum feed fmax = 2.05 × 0.007 = 0.014 in./tooth and the minimum feed fmin = 1.44 × 0.007 = 0.010 in./tooth. The feed selected should fall in the range between fmin and fmax. The feed factor Fd is determined by interpolating between the feed factors Ff1 and Ff2 corresponding to the maximum and minimum feed per tooth, at the appropriate ar/D and speed ratio. In the example given, ar/D = 0.10 and Vavg/Vopt = 45⁄15 = 3, so the feed factor Ff1 at the maximum feed per tooth is 6.77, and the feed factor Ff2 at the minimum feed per tooth is 7.76. If a working feed of 0.012 in./tooth is chosen, the feed factor Ff is half way between 6.77 and 7.76 or by formula, Ff = Ff1 + (feed − fmin)/(fmax − fmin) × (ff2 − ff1 ) = 6.77 + (0.012 − 0.010)/(0.014 − 0.010) × (7.76 − 6.77) = 7.27. The cutting speed is V = Vopt × Ff × Fd, where Fd is the depth of cut and lead angle factor from Table 15b that corresponds to the feed ratio (chosen feed)/fmax, not the ratio (chosen feed)/optimum feed. For a feed ratio = 0.012⁄0.014 = 0.86 (chosen feed/fmax), depth of cut = 0.2 inch and lead angle = 45°, the depth of cut factor Fd in Table 15b is between 0.72 and 0.74. Therefore, the final cutting speed for this example is V = Vopt × Ff × Fd = 15 × 7.27 × 0.73 = 80 ft/min.
Copyright 2004, Industrial Press, Inc., New York, NY
1057
Slit and Side Milling: This table only applies when feed is parallel to the work surface, as in slotting. If feed is perpendicular to the work surface, as in cutting off, obtain the required speed-correction factor from Table 15d (face milling). The minimum and maximum feeds/tooth for slit and side milling are determined in the manner described above, however, the axial depth of cut factor Fd is not required. The adjusted cutting speed, valid for cutters of any thickness (width), is given by V = Vopt × Ff. Examples are given in the text.
SPEEDS AND FEEDS
Ratio of Radial Depth of Cut to Diameter
Machinery's Handbook 27th Edition
Ratio of Chosen Feed to Optimum Feed
1.00
2.00
1 in (25.4 mm) 15° 45°
1.0 1.10 1.20 1.32 1.50 1.75 2.03 2.42 2.96 3.74
1.0 1.12 1.25 1.43 1.66 2.00 2.43 3.05 4.03 5.84
0.78 0.78 0.80 0.81 0.81 0.81 0.82 0.84 0.86 0.90
Vavg/Vopt 1.10
1.0 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00 1.00
1.0 1.02 1.03 1.05 1.08 1.10 1.09 1.06 1.00 0.80
1.25 1.35 1.50 Feed Factor, Ff 1.0 1.0 1.0 1.05 1.07 1.09 1.09 1.10 1.15 1.13 1.22 1.22 1.20 1.25 1.35 1.25 1.35 1.50 1.28 1.44 1.66 1.32 1.52 1.85 1.34 1.60 2.07 1.20 1.55 2.24
1.11 1.10 1.10 1.09 1.09 1.09 1.08 1.07 1.06 1.04
0.4 in 0.2 in 0.1 in (10.2 mm) (5.1 mm) (2.4 mm) 15° 45° 15° 45° 15° 45° Depth of Cut Factor, Fd 0.94 1.16 0.90 1.10 1.00 1.29 0.94 1.16 0.90 1.09 1.00 1.27 0.94 1.14 0.91 1.08 1.00 1.25 0.95 1.14 0.91 1.08 1.00 1.24 0.95 1.13 0.92 1.08 1.00 1.23 0.95 1.13 0.92 1.08 1.00 1.23 0.95 1.12 0.92 1.07 1.00 1.21 0.96 1.11 0.93 1.06 1.00 1.18 0.96 1.09 0.94 1.05 1.00 1.15 0.97 1.06 0.96 1.04 1.00 1.10
0.04 in (1.0 mm) 15° 45° 1.47 1.45 1.40 1.39 1.38 1.37 1.34 1.30 1.24 1.15
1.66 1.58 1.52 1.50 1.48 1.47 1.43 1.37 1.29 1.18
Ratio of Radial Depth of Cut/Cutter Diameter, ar/D 1.00 0.72 0.73 0.75 0.75 0.76 0.76 0.78 0.80 0.82 0.87
0.75 0.50 0.40 0.30 0.20 Radial Depth of Cut Factor, Far 1.00 1.53 1.89 2.43 3.32 1.00 1.50 1.84 2.24 3.16 1.00 1.45 1.73 2.15 2.79 1.00 1.44 1.72 2.12 2.73 1.00 1.42 1.68 2.05 2.61 1.00 1.41 1.66 2.02 2.54 1.00 1.37 1.60 1.90 2.34 1.00 1.32 1.51 1.76 2.10 1.00 1.26 1.40 1.58 1.79 1.00 1.16 1.24 1.31 1.37
0.10 5.09 4.69 3.89 3.77 3.52 3.39 2.99 2.52 1.98 1.32
For HSS (high-speed steel) tool speeds in the first speed column, use Table 15a to determine appropriate feeds and depths of cut. Tabular feeds and speeds data for face milling in Tables 11 through 14 are based on a 10-tooth, 8-inch diameter face mill, operating with a 15-degree lead angle, 3⁄64inch cutter insert nose radius, axial depth of cut = 0.1 inch, and radial depth (width) of cut = 6 inches (i.e., width of cut to cutter diameter ratio = 3⁄4). For other depths of cut (radial or axial), lead angles, or feed, calculate the ratio of desired (new) feed to optimum feed (largest of the two feeds given in the speed table), and the ratio of the two cutting speeds (Vavg/Vopt). Use these ratios to find the feed factor Ff at the intersection of the feed ratio row and the speed ratio column in the left third of the table. The depth of cut factor Fd is found in the same row as the feed factor, in the center third of the table, in the column corresponding to the depth of cut and lead angle. The radial depth of cut factor Far is found in the same row as the feed factor, in the right third of the table, in the column corresponding to the radial depth of cut to cutter diameter ratio ar/D. The adjusted cutting speed can be calculated from V = Vopt × Ff × Fd × Far, where Vopt is the smaller (optimum) of the two speeds from the speed table (from the left side of the column containing the two feed/speed pairs). The cutting speeds as calculated above are valid if the cutter axis is centered above or close to the center line of the workpiece (eccentricity is small). For larger eccentricity (i.e., the cutter axis is offset from the center line of the workpiece by about one-half the cutter diameter or more), use the adjustment factors from Tables 15b and 15c (end and side milling) instead of the factors from this table. Use Table 15e to adjust end and face milling speeds for increased tool life up to 180 minutes. Slit and Slot Milling: Tabular speeds are valid for all tool diameters and widths. Adjustments to the given speeds for other feeds and depths of cut depend on the circumstances of the cut. Case 1: If the cutter is fed directly into the workpiece, i.e., the feed is perpendicular to the surface of the workpiece, as in cutting off, then this table (face milling) is used to adjust speeds for other feeds. The depth of cut factor is not used for slit milling (Fd = 1.0), so the adjusted cutting speed V = Vopt × Ff × Far. For determining the factor Far, the radial depth of cut ar is the length of cut created by the portion of the cutter engaged in the work. Case 2: If the cutter is fed parallel to the surface of the workpiece, as in slotting, then Tables 15b and 15c are used to adjust the given speeds for other feeds. See Fig. 5.
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
1.00 0.90 0.80 0.70 0.60 0.50 0.40 0.30 0.20 0.10
Cutting Speed V = Vopt × Ff × Fd × Far Depth of Cut, inch (mm), and Lead Angle
Ratio of the two cutting speeds (average/optimum) given in the tables
1.00
1058
Table 15d. Face Milling Speed Adjustment Factors for Feed, Depth of Cut, and Lead Angle
Machinery's Handbook 27th Edition SPEEDS AND FEEDS
1059
Table 15e. Tool Life Adjustment Factors for Face Milling, End Milling, Drilling, and Reaming Tool Life, T (minutes) 15 45 90 180
Face Milling with Carbides and Mixed Ceramics fs fm fl 1.69 1.00 0.72 0.51
1.78 1.00 0.70 0.48
1.87 1.00 0.67 0.45
End Milling with Carbides and HSS fs fm fl 1.10 1.00 0.94 0.69
1.23 1.00 0.89 0.69
1.35 1.00 0.83 0.69
Twist Drilling and Reaming with HSS fs fm fl 1.11 1.00 0.93 0.87
1.21 1.00 0.89 0.80
1.30 1.00 0.85 0.72
The feeds and speeds given in Tables 11 through 14 and Tables 17 through 23 (except for HSS speeds in the first speed column) are based on a 45-minute tool life. To adjust the given speeds to obtain another tool life, multiply the adjusted cutting speed for the 45-minute tool life V45 by the tool life factor from this table according to the following rules: for small feeds, where feed ≤ 1⁄2 fopt, the cutting speed for the desired tool life T is VT = fs × V15; for medium feeds, where 1⁄2 fopt < feed < 3⁄4 fopt, VT = fm × V15; and for larger feeds, where 3⁄4 fopt ≤ feed ≤ fopt, VT = fl × V15. Here, fopt is the largest (optimum) feed of the two feed/speed values given in the speed tables or the maximum feed fmax obtained from Table 15c, if that table was used in calculating speed adjustment factors.
Table 16. Cutting Tool Grade Descriptions and Common Vendor Equivalents Grade Description Cubic boron nitride Ceramics
Cermets Polycrystalline Coated carbides
Uncoated carbides
Tool Identification Code 1 2 3 4 (Whiskers) 5 (Sialon) 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
Approximate Vendor Equivalents Sandvik Coromant
Kennametal
CB50
KD050
CC620 CC650 CC670 CC680 CC690 CT515 CT525 CD10 GC-A GC3015 GC235 GC4025 GC415 H13A S10T S1P S30T S6 SM30
K060 K090 KYON2500 KYON2000 KYON3000 KT125 KT150 KD100 — KC910 KC9045 KC9025 KC950 K8, K4H K420, K28 K45 — K21, K25 KC710
Seco CBN2 0 480 480 — 480 — CM CR PAX20 — TP100 TP300 TP200 TP100 883 CP20 CP20 CP25 CP50 CP25
Valenite VC721 — Q32 — — Q6 VC605 VC610 VC727 — SV310 SV235 SV325 SV315 VC2 VC7 VC7 VC5 VC56 VC35M
See Table 2 on page 779 and the section Cemented Carbides and Other Hard Materials for more detailed information on cutting tool grades. The identification codes in column two correspond to the grade numbers given in the footnotes to Tables 1 to 4b, 6 to 14, and 17 to 23.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1060
SPEEDS AND FEEDS
Using the Feed and Speed Tables for Drilling, Reaming, and Threading.—The first two speed columns in Tables 17 through 23 give traditional Handbook speeds for drilling and reaming. The following material can be used for selecting feeds for use with the traditional speeds. The remaining columns in Tables 17 through 23 contain combined feed/speed data for drilling, reaming, and threading, organized in the same manner as in the turning and milling tables. Operating at the given feeds and speeds is expected to result in a tool life of approximately 45 minutes, except for indexable insert drills, which have an expected tool life of approximately 15 minutes per edge. Examples of using this data follow. Adjustments to HSS drilling speeds for feed and diameter are made using Table 22; Table 5a is used for adjustments to indexable insert drilling speeds, where one-half the drill diameter D is used for the depth of cut. Tool life for HSS drills, reamers, and thread chasers and taps may be adjusted using Table 15e and for indexable insert drills using Table 5b. The feed for drilling is governed primarily by the size of the drill and by the material to be drilled. Other factors that also affect selection of the feed are the workpiece configuration, the rigidity of the machine tool and the workpiece setup, and the length of the chisel edge. A chisel edge that is too long will result in a very significant increase in the thrust force, which may cause large deflections to occur on the machine tool and drill breakage. For ordinary twist drills, the feed rate used is 0.001 to 0.003 in /rev for drills smaller than 1⁄ in, 0.002 to 0.006 in./rev for 1⁄ - to 1⁄ -in drills; 0.004 to 0.010 in./rev for 1⁄ - to 1⁄ -in drills; 8 8 4 4 2 0.007 to 0.015 in./rev for 1⁄2- to 1-in drills; and, 0.010 to 0.025 in./rev for drills larger than 1
inch. The lower values in the feed ranges should be used for hard materials such as tool steels, superalloys, and work-hardening stainless steels; the higher values in the feed ranges should be used to drill soft materials such as aluminum and brass. Example 1, Drilling:Determine the cutting speed and feed for use with HSS drills in drilling 1120 steel. Table 15a gives two sets of feed and speed parameters for drilling 1120 steel with HSS drills. These sets are 16⁄50 and 8⁄95, i.e., 0.016 in./rev feed at 50 ft/min and 0.008 in./rev at 95 fpm, respectively. These feed/speed sets are based on a 0.6-inch diameter drill. Tool life for either of the given feed/speed settings is expected to be approximately 45 minutes. For different feeds or drill diameters, the cutting speeds must be adjusted and can be determined from V = Vopt × Ff × Fd, where Vopt is the minimum speed for this material given in the speed table (50 fpm in this example) and Ff and Fd are the adjustment factors for feed and diameter, respectively, found in Table 22.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 17. Feeds and Speeds for Drilling, Reaming, and Threading Plain Carbon and Alloy Steels Drilling
Reaming
Drilling
HSS Brinell Hardness
Material Free-machining plain carbon steels (Resulfurized): 1212, 1213, 1215
{
(Resulfurized): 1108, 1109, 1115, 1117, 1118, 1120, 1126, 1211
{
{
(Leaded): 11L17, 11L18, 12L13, 12L14
{
Plain carbon steels: 1006, 1008, 1009, 1010, 1012, 1015, 1016, 1017, 1018, 1019, 1020, 1021, 1022, 1023, 1024, 1025, 1026, 1513, 1514
Plain carbon steels: 1027, 1030, 1033, 1035, 1036, 1037, 1038, 1039, 1040, 1041, 1042, 1043, 1045, 1046, 1048, 1049, 1050, 1052, 1524, 1526, 1527, 1541
{
{
Reaming
Threading
HSS
HSS
f = feed (0.001 in./rev), s = speed (ft/min)
Speed (fpm)
Avg. Opt.
Avg. Opt.
Avg. Opt.
Avg.
f 21 s 55
Opt.
11 125
8 310
4 620
36 140
18 83 185 140
20 185
f 16 s 50
8 95
8 370
4 740
27 105
14 83 115 90
20 115
f s
8 365
4 735
60
f s
8 365
4 735
100
65
f 21 s 55
8 310
4 620
36 140
18 83 185 140
20 185
90 70 60 90 75 60 50 35 25
60 45 40 60 50 40 30 20 15
f s
8 365
4 735
f s
8 365
4 735
100–150
120
80
150–200 100–150 150–200
125 110 120
80 75 80
175–225
100
65
275–325 325–375 375–425 100–150 150–200
70 45 35 130 120
45 30 20 85 80
200–250
90
100–125 125–175 175–225 225–275 125–175 175–225 225–275 275–325 325–375 375–425
11 125
SPEEDS AND FEEDS
(Resulfurized): 1132, 1137, 1139, 1140, 1144, 1146, 1151
Indexable Insert Coated Carbide
HSS
1061
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Drilling
Reaming
Drilling
HSS Material
Plain carbon steels (Continued): 1055, 1060, 1064, 1065, 1070, 1074, 1078, 1080, 1084, 1086, 1090, 1095, 1548, 1551, 1552, 1561, 1566
(Leaded): 41L30, 41L40, 41L47, 41L50, 43L47, 51L32, 52L100, 86L20, 86L40
Alloy steels: 4012, 4023, 4024, 4028, 4118, 4320, 4419, 4422, 4427, 4615, 4620, 4621, 4626, 4718, 4720, 4815, 4817, 4820, 5015, 5117, 5120, 6118, 8115, 8615, 8617, 8620, 8622, 8625, 8627, 8720, 8822, 94B17
{
{
Reaming
Threading
HSS
HSS
f = feed (0.001 in./rev), s = speed (ft/min)
Brinell Hardness 125–175 175–225
85 70
55 45
f 16 s 50
225–275
50
30
f s
275–325 325–375 375–425 175–200 200–250
40 30 15 90 80
25 20 10 60 50
Speed (fpm)
Opt.
250–300
55
30
300–375 375–425
40 30
25 15
f 16 s 75
Avg. Opt.
Avg. Opt.
Avg.
8 370
4 740
27 105
14 83 115 90
20 115
8 365
4 735
8 410
4 685
26 150
13 83 160 125
20 160
8 355
4 600
8 140
f s f s f 16 s 50 f s
8 310
4 525
8 95
8 370 8 365
4 740 4 735
27 105
14 83 115 90
20 115
f 16 s 75
8 140
8 410
4 685
26 150
13 83 160 125
20 160
8 355
4 600
8 335
4 570
19 95
10 83 135 60
20 95
8 310
4 525
150–200
100
65
200–250
90
60
250–300 300–375 375–425 125–175 175–225
65 45 30 85 70
40 30 15 55 45
225–275
55
35
f s
{
Avg. Opt. 8 95
275–325
50
30
f 11 s 50
325–375 375–425
35 25
25 15
f s
6 85
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
Free-machining alloy steels (Resulfurized): 4140, 4150
{
Indexable Insert Coated Carbide
HSS
1062
Table 17. (Continued) Feeds and Speeds for Drilling, Reaming, and Threading Plain Carbon and Alloy Steels
Machinery's Handbook 27th Edition
Table 17. (Continued) Feeds and Speeds for Drilling, Reaming, and Threading Plain Carbon and Alloy Steels Drilling
Reaming
Drilling
HSS Material
Ultra-high-strength steels (not AISI): AMS 6421 (98B37 Mod.), 6422 (98BV40), 6424, 6427, 6428, 6430, 6432, 6433, 6434, 6436, and 6442; 300M, D6ac Maraging steels (not AISI): 18% Ni Grade 200, 250, 300, and 350 Nitriding steels (not AISI): Nitralloy 125, 135, 135 Mod., 225, and 230, Nitralloy N, Nitralloy EZ, Nitrex I
Opt.
Avg. Opt.
Avg. Opt.
Avg. Opt.
Avg.
8 410
4 685
26 150
13 83 160 125
20 160
8 355
4 600
8 335
4 570
19 95
10 83 135 60
20 95
f s
8 310
4 525
f s
8 325
4 545
26 150
13 83 160 125
20 160
50 (40)
f 16 s 75
225–275
60 (50)
40 (30)
f s f 11 s 50
6 85
275–325
45 (35)
30 (25)
325–375 375–425 220–300 300–350
30 (30) 20 (20) 50 35
15 (20) 15 (10) 30 20
350–400
20
10
f s
8 270
4 450
250–325
50
30
f s
8 325
4 545
40
f 16 s 75
8 410
4 685
20
f s
8 310
4 525
300–350
35
HSS
8 140
75 (60)
60
Threading
HSS
f = feed (0.001 in./rev), s = speed (ft/min)
Speed (fpm)
175–225
200–250
Reaming
8 140
SPEEDS AND FEEDS
Alloy steels: 1330, 1335, 1340, 1345, 4032, 4037, 4042, 4047, 4130, 4135, 4137, 4140, 4142, 4145, 4147, 4150, 4161, 4337, 4340, 50B44, 50B46, 50B50, 50B60, 5130, 5132, 5140, 5145, 5147, 5150, { 5160, 51B60, 6150, 81B45, 8630, 8635, 8637, 8640, 8642, 8645, 8650, 8655, 8660, 8740, 9254, 9255, 9260, 9262, 94B30 E51100, E52100: use (HSS speeds)
Brinell Hardness
Indexable Insert Coated Carbide
HSS
The two leftmost speed columns in this table contain traditional Handbook speeds for drilling and reaming with HSS steel tools. The section Feed Rates for Drilling and Reaming contains useful information concerning feeds to use in conjunction with these speeds.
Copyright 2004, Industrial Press, Inc., New York, NY
1063
HSS Drilling and Reaming: The combined feed/speed data for drilling are based on a 0.60-inch diameter HSS drill with standard drill point geometry (2-flute with 118° tip angle). Speed adjustment factors in Table 22 are used to adjust drilling speeds for other feeds and drill diameters. Examples of using this data are given in the text. The given feeds and speeds for reaming are based on an 8-tooth, 25⁄32-inch diameter, 30° lead angle reamer, and a 0.008-inch radial depth of cut. For other feeds, the correct speed can be obtained by interpolation using the given speeds if the desired feed lies in the recommended range (between the given values of optimum and average feed). If a feed lower than the given average value is chosen, the speed should be maintained at the corresponding average speed (i.e., the highest of the two speed values given). The cutting speeds for reaming do not require adjustment for tool diameters for standard ratios of radical depth of cut to reamer diameter (i.e., fd = 1.00). Speed adjustment factors to modify tool life are found in Table 15e.
Machinery's Handbook 27th Edition 1064
SPEEDS AND FEEDS
Indexable Insert Drilling: The feed/speed data for indexable insert drilling are based on a tool with two cutting edges, an insert nose radius of 3⁄64 inch, a 10-degree lead angle, and diameter D = 1 inch. Adjustments to cutting speed for feed and depth of cut are made using Table 5aAdjustment Factors) using a depth of cut of D/2, or one-half the drill diameter. Expected tool life at the given feeds and speeds is approximately 15 minutes for short hole drilling (i.e., where maximum hole depth is about 2D or less). Speed adjustment factors to increase tool life are found in Table 5b. Tapping and Threading: The data in this column are intended for use with thread chasers and for tapping. The feed used for tapping and threading must be equal to the lead (feed = lead = pitch) of the thread being cut. The two feed/speed pairs given for each material, therefore, are representative speeds for two thread pitches, 12 and 50 threads per inch (1⁄0.083 = 12, and 1⁄0.020 = 50). Tool life is expected to be approximately 45 minutes at the given feeds and speeds. When cutting fewer than 12 threads per inch (pitch ≥ 0.08 inch), use the lower (optimum) speed; for cutting more than 50 threads per inch (pitch ≤ 0.02 inch), use the larger (average) speed; and, in the intermediate range between 12 and 50 threads per inch, interpolate between the given average and optimum speeds. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: coated carbide = 10.
Example 2, Drilling:If the 1120 steel of Example 1 is to be drilled with a 0.60-inch drill at a feed of 0.012 in./rev, what is the cutting speed in ft/min? Also, what spindle rpm of the drilling machine is required to obtain this cutting speed? To find the feed factor Fd in Table 22, calculate the ratio of the desired feed to the optimum feed and the ratio of the two cutting speeds given in the speed tables. The desired feed is 0.012 in./rev and the optimum feed, as explained above is 0.016 in./rev, therefore, feed/fopt = 0.012⁄0.016 = 0.75 and Vavg/Vopt = 95⁄50 = 1.9, approximately 2. The feed factor Ff is found at the intersection of the feed ratio row and the speed ratio column. Ff = 1.40 corresponds to about halfway between 1.31 and 1.50, which are the feed factors that correspond to Vavg/Vopt = 2.0 and feed/fopt ratios of 0.7 and 0.8, respectively. Fd, the diameter factor, is found on the same row as the feed factor (halfway between the 0.7 and 0.8 rows, for this example) under the column for drill diameter = 0.60 inch. Because the speed table values are based on a 0.60-inch drill diameter, Fd = 1.0 for this example, and the cutting speed is V = Vopt × Ff × Fd = 50 × 1.4 × 1.0 = 70 ft/min. The spindle speed in rpm is N = 12 × V/(π × D) = 12 × 70/(3.14 × 0.6) = 445 rpm. Example 3, Drilling:Using the same material and feed as in the previous example, what cutting speeds are required for 0.079-inch and 4-inch diameter drills? What machine rpm is required for each? Because the feed is the same as in the previous example, the feed factor is Ff = 1.40 and does not need to be recalculated. The diameter factors are found in Table 22 on the same row as the feed factor for the previous example (about halfway between the diameter factors corresponding to feed/fopt values of 0.7 and 0.8) in the column corresponding to drill diameters 0.079 and 4.0 inches, respectively. Results of the calculations are summarized below. Drill diameter = 0.079 inch
Drill diameter = 4.0 inches
Ff = 1.40
Ff = 1.40
Fd = (0.34 + 0.38)/2 = 0.36
Fd = (1.95 + 1.73)/2 = 1.85
V = 50 × 1.4 × 0.36 = 25.2 fpm
V = 50 × 1.4 × 1.85 = 129.5 fpm
12 × 25.2/(3.14 × 0.079) = 1219 rpm
12 × 129.5/(3.14 × 4) = 124 rpm
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SPEEDS AND FEEDS
1065
Drilling Difficulties: A drill split at the web is evidence of too much feed or insufficient lip clearance at the center due to improper grinding. Rapid wearing away of the extreme outer corners of the cutting edges indicates that the speed is too high. A drill chipping or breaking out at the cutting edges indicates that either the feed is too heavy or the drill has been ground with too much lip clearance. Nothing will “check” a high-speed steel drill quicker than to turn a stream of cold water on it after it has been heated while in use. It is equally bad to plunge it in cold water after the point has been heated in grinding. The small checks or cracks resulting from this practice will eventually chip out and cause rapid wear or breakage. Insufficient speed in drilling small holes with hand feed greatly increases the risk of breakage, especially at the moment the drill is breaking through the farther side of the work, due to the operator's inability to gage the feed when the drill is running too slowly. Small drills have heavier webs and smaller flutes in proportion to their size than do larger drills, so breakage due to clogging of chips in the flutes is more likely to occur. When drilling holes deeper than three times the diameter of the drill, it is advisable to withdraw the drill (peck feed) at intervals to remove the chips and permit coolant to reach the tip of the drill. Drilling Holes in Glass: The simplest method of drilling holes in glass is to use a standard, tungsten-carbide-tipped masonry drill of the appropriate diameter, in a gun-drill. The edges of the carbide in contact with the glass should be sharp. Kerosene or other liquid may be used as a lubricant, and a light force is maintained on the drill until just before the point breaks through. The hole should then be started from the other side if possible, or a very light force applied for the remainder of the operation, to prevent excessive breaking of material from the sides of the hole. As the hard particles of glass are abraded, they accumulate and act to abrade the hole, so it may be advisable to use a slightly smaller drill than the required diameter of the finished hole. Alternatively, for holes of medium and large size, use brass or copper tubing, having an outside diameter equal to the size of hole required. Revolve the tube at a peripheral speed of about 100 feet per minute, and use carborundum (80 to 100 grit) and light machine oil between the end of the pipe and the glass. Insert the abrasive under the drill with a thin piece of soft wood, to avoid scratching the glass. The glass should be supported by a felt or rubber cushion, not much larger than the hole to be drilled. If practicable, it is advisable to drill about halfway through, then turn the glass over, and drill down to meet the first cut. Any fin that may be left in the hole can be removed with a round second-cut file wetted with turpentine. Smaller-diameter holes may also be drilled with triangular-shaped cemented carbide drills that can be purchased in standard sizes. The end of the drill is shaped into a long tapering triangular point. The other end of the cemented carbide bit is brazed onto a steel shank. A glass drill can be made to the same shape from hardened drill rod or an old threecornered file. The location at which the hole is to be drilled is marked on the workpiece. A dam of putty or glazing compound is built up on the work surface to contain the cutting fluid, which can be either kerosene or turpentine mixed with camphor. Chipping on the back edge of the hole can be prevented by placing a scrap plate of glass behind the area to be drilled and drilling into the backup glass. This procedure also provides additional support to the workpiece and is essential for drilling very thin plates. The hole is usually drilled with an electric hand drill. When the hole is being produced, the drill should be given a small circular motion using the point as a fulcrum, thereby providing a clearance for the drill in the hole. Very small round or intricately shaped holes and narrow slots can be cut in glass by the ultrasonic machining process or by the abrasive jet cutting process.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Drilling
Reaming
Drilling
HSS Brinell Hardness
Material
HSS
Opt.
85
55
Shock resisting: S1, S2, S5, S6, S7
175–225
50
35
Cold work (oil hardening): O1, O2, O6, O7
175–225
45
30
200–250
30
20
(Air hardening): A2, A3, A8, A9, A10
200–250
50
35
A4, A6
200–250
45
30
A7
225–275
30
20
150–200
60
40
200–250
50
30
325–375
30
20
150–200
55
35
200–250
40
25
150–200
45
30
200–250
35
20
150–200
60
40
100–150
75
50
150–200
60
40
200–250
45
30
225–275
35
20
225–275
25
15
Hot work (chromium type): H10, H11, H12, H13, H14, H19
(Tungsten type): H21, H22, H23, H24, H25, H26 (Molybdenum type): H41, H42, H43
{
{ {
Special-purpose, low alloy: L2, L3, L6 Mold steel: P2, P3, P4, P5, P6P20, P21 High-speed steel: M1, M2, M6, M10, T1, T2, T6 M3-1, M4, M7, M30, M33, M34, M36, M41, M42, M43, M44, M46, M47, T5, T8 T15, M3-2
{
Threading
HSS
HSS
f 15 s 45
Avg. Opt.
Avg. Opt.
Avg. Opt.
Avg.
7 85
8 360
4 24 605 90
12 95
83 75
20 95
8 270
4 450
8 360
4 24 605 90
12 95
83 75
20 95
f s
f 15 s 45
7 85
See the footnote to Table 17 for instructions concerning the use of this table. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: coated carbide = 10.
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
150–200
{
Reaming
f = feed (0.001 in./rev), s = speed (ft/min)
Speed (fpm)
Water hardening: W1, W2, W5
(High carbon, high chromium): D2, D3, D4, D5, D7
Indexable Insert Uncoated Carbide
1066
Table 18. Feeds and Speeds for Drilling, Reaming, and Threading Tool Steels
Machinery's Handbook 27th Edition
Table 19. Feeds and Speeds for Drilling, Reaming, and Threading Stainless Steels Drilling
Reaming
Drilling
HSS Brinell Hardness
Material Free-machining stainless steels (Ferritic): 430F, 430FSe
HSS
Speed (fpm) 90
60
135–185 225–275 135–185 185–240 275–325 375–425
85 70 90 70 40 20
55 45 60 45 25 10
Stainless steels (Ferritic): 405, 409, 429, 430, 434
135–185
65
45
(Austenitic): 201, 202, 301, 302, 304, 304L, 305, 308, { 321, 347, 348 (Austenitic): 302B, 309, 309S, 310, 310S, 314, 316
135–185 225–275 135–185 135–175 175–225 275–325 375–425 225–275 275–325 375–425 225–275 275–325 375–425
55 50 50 75 65 40 25 50 40 25 45 40 20
35 30 30 50 45 25 15 30 25 15 30 25 10
150–200
50
30
275–325 325–375 375–450
45 35 20
25 20 10
(Austenitic): 203EZ, 303, 303Se, 303MA, 303Pb, 303Cu, 303 Plus X
{
(Martensitic): 416, 416Se, 416 Plus X, 420F, 420FSe, { 440F, 440FSe
(Martensitic): 403, 410, 420, 501
{
(Martensitic): 414, 431, Greek Ascoloy
{
(Martensitic): 440A, 440B, 440C
{
(Precipitation hardening): 15–5PH, 17–4PH, 17–7PH, AF–71, 17–14CuMo, AFC–77, AM–350, AM–355, { AM–362, Custom 455, HNM, PH13–8, PH14–8Mo, PH15–7Mo, Stainless W
Opt. f 15 s 25
7 45
8 320
4 24 540 50
12 50
83 40
20 51
f 15 s 20
7 40
8 250
4 24 425 40
12 40
83 35
20 45
f 15 s 25
7 45
8 320
4 24 540 50
12 50
83 40
20 51
f 15 s 20
7 40
8 250
4 24 425 40
12 40
83 35
20 45
f 15 s 20
7 40
8 250
4 24 425 40
12 40
83 35
20 45
Copyright 2004, Industrial Press, Inc., New York, NY
1067
See the footnote to Table 17 for instructions concerning the use of this table. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: coated carbide = 10.
SPEEDS AND FEEDS
135–185
Reaming Threading Indexable Insert Coated Carbide HSS HSS f = feed (0.001 in./rev), s = speed (ft/min) Avg. Opt. Avg. Opt. Avg. Opt. Avg.
Machinery's Handbook 27th Edition
1068
Table 20. Feeds and Speeds for Drilling, Reaming, and Threading Ferrous Cast Metals Drilling
Reaming
Drilling
Reaming
Threading
HSS
HSS
Indexable Carbide Insert HSS
Material
HSS
Coated
f = feed (0.001 in./rev), s = speed (ft/min)
Speed (fpm)
Brinell Hardness
Uncoated
Opt.
120–150
100
65
ASTM Class 25
160–200
90
60
ASTM Class 30, 35, and 40
190–220
80
55
ASTM Class 45 and 50
220–260
60
40
ASTM Class 55 and 60
250–320
30
20
ASTM Type 1, 1b, 5 (Ni resist)
100–215
50
30
ASTM Type 2, 3, 6 (Ni resist)
120–175
40
25
ASTM Type 2b, 4 (Ni resist)
150–250
30
20
(Ferritic): 32510, 35018
110–160
110
75
f s f s
Avg. Opt.
Avg. Opt.
Avg. Opt.
Avg. Opt.
6 26 485 85
13 83 65 90
20 80
21 50
10 83 30 55
20 45
30 95
16 83 80 100
20 85
22 65
11 83 45 70
20 60
28 80
14 83 60 80
20 70
16 80
8 90
11 85
6 180
11 235
13 50
6 50
11 70
6 150
11 195
6 405
Avg.
Malleable Iron
(Pearlitic): 40010, 43010, 45006, 45008, 48005, 50005
160–200
80
55
200–240
70
45
(Martensitic): 53004, 60003, 60004
200–255
55
35
(Martensitic): 70002, 70003
220–260
50
30
(Martensitic): 80002
240–280
45
30
(Martensitic): 90001
250–320
25
15
(Ferritic): 60-40-18, 65-45-12
140–190
100
65
f s
19 80
10 100
f s
14 65
7 65
11 85
6 180
11 270 11 235
6 555 6 485
Nodular (Ductile) Iron f s
17 70
9 80
11 85
6 180
11 235
Copyright 2004, Industrial Press, Inc., New York, NY
6 485
SPEEDS AND FEEDS
ASTM Class 20
Machinery's Handbook 27th Edition
Table 20. (Continued) Feeds and Speeds for Drilling, Reaming, and Threading Ferrous Cast Metals Drilling
Reaming
Drilling
Reaming
Threading
HSS
HSS
Indexable Carbide Insert HSS
(Martensitic): 120-90-02
{
(Ferritic-Pearlitic): 80-55-06
Uncoated
Coated
f = feed (0.001 in./rev), s = speed (ft/min)
Speed (fpm)
Brinell Hardness
Material
HSS
Opt.
270–330
25
330–400
10
5
190–225
70
45
Avg. Opt.
Avg. Opt.
Avg. Opt.
6 150
6 405
Avg. Opt.
Avg.
15
50
30
240–300
40
25
(Low carbon): 1010, 1020
100–150
100
65
125–175
90
60
175–225
70
45
225–300
55
35
150–200
75
50
200–250
65
40
250–300
50
30
175–225
70
45
225–250
60
35
250–300
45
30
300–350
30
20
350–400
20
10
f s
13 60
6 60
f s
18 35
9 70
f s
15 35
7 60
11 70
11 195
21 55
11 83 40 60
20 55
29 75
15 83 85 65
20 85
24 65
12 83 70 55
20 70
Cast Steels
(Medium carbon): 1030, 1040, 1050
(Low-carbon alloy): 1320, 2315, 2320, 4110, 4120, 4320, 8020, 8620
{
{
(Medium-carbon alloy): 1330, 1340, 2325, 2330, 4125, 4130, 4140, 4330, 4340, { 8030, 80B30, 8040, 8430, 8440, 8630, 8640, 9525, 9530, 9535
f s
8 195†
4 475
8 130†
4 315
Copyright 2004, Industrial Press, Inc., New York, NY
1069
See the footnote to Table 17 for instructions concerning the use of this table. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated = 15; coated carbide = 11, † = 10.
SPEEDS AND FEEDS
225–260
(Pearlitic-Martensitic): 100-70-03
Machinery's Handbook 27th Edition
Drilling
Reaming
Drilling
HSS Brinell Hardness
Material
CD
All wrought aluminum alloys, 6061-T651, 5000, 6000, 7000 series All aluminum sand and permanent mold casting alloys
HSS
Reaming
Threading
HSS
HSS
f = feed (0.001 in./rev), s = speed (ft/min)
Speed (fpm) 400
Indexable Insert Uncoated Carbide
1070
Table 21. Feeds and Speeds for Drilling, Reaming, and Threading Light Metals
Opt.
Avg. Opt.
Avg. Opt.
Avg. Opt.
Avg.
400
ST and A
350
350
AC
500
500
ST and A
350
f 31 s 390
16 580
11 3235
6 11370
52 610
26 615
83 635
20 565
350
Alloys 308.0 and 319.0
—
—
—
f 23 s 110
11 145
11 945
6 3325
38 145
19 130
83 145
20 130
Alloys 360.0 and 380.0
—
—
—
f 27 s 90
14 125
11 855
6 3000
45 130
23 125
83 130
20 115
AC
300
300
ST and A
70
70
—
—
ST and A
45
40
f 24 s 65
12 85
11 555
6 1955
40 85
20 80
83 85
20 80
AC
125
100
f 27 s 90
14 125
11 855
6 3000
45 130
23 125
83 130
20 115
All wrought magnesium alloys
A,CD,ST and A
500
500
All cast magnesium alloys
A,AC, ST and A
450
450
Alloys 390.0 and 392.0
{
Alloys 413 All other aluminum die-casting alloys
{
Magnesium Alloys
Abbreviations designate: A, annealed; AC, as cast; CD, cold drawn; and ST and A, solution treated and aged, respectively. See the footnote to Table 17 for instructions concerning the use of this table. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows; uncoated carbide = 15.
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
Aluminum Die-Casting Alloys
Machinery's Handbook 27th Edition
Table 22. Feed and Diameter Speed Adjustment Factors for HSS Twist Drills and Reamers Cutting Speed, V = Vopt × Ff × Fd Ratio of the two cutting speeds (average/optimum) given in the tables Vavg/Vopt
Tool Diameter
Ratio of Chosen Feed to Optimum Feed
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
1.00
0.30
0.44
0.56
0.78
1.00
0.90
1.00
1.06
1.09
1.14
1.18
1.21
1.27
0.32
0.46
0.59
0.79
1.00
0.80
1.00
1.12
1.19
1.31
1.40
1.49
1.63
0.34
0.48
0.61
0.80
0.70
1.00
1.15
1.30
1.50
1.69
1.85
2.15
0.38
0.52
0.64
0.60
1.00
1.23
1.40
1.73
2.04
2.34
2.89
0.42
0.55
0.50
1.00
1.25
1.50
2.00
2.50
3.00
5.00
0.47
0.40
1.00
1.23
1.57
2.29
3.08
3.92
5.70
0.30
1.00
1.14
1.56
2.57
3.78
5.19
0.20
1.00
0.90
1.37
2.68
4.49
0.10
1.00
1.44
0.80
2.08
4.36
1.25
1.50
2.00
2.50
0.60 in
1.00 in
2.00 in
3.00 in
4.00 in
(15 mm)
(25 mm)
(50 mm)
(75 mm)
(100 mm)
1.32
1.81
2.11
2.29
1.30
1.72
1.97
2.10
1.00
1.27
1.64
1.89
1.95
0.82
1.00
1.25
1.52
1.67
1.73
0.67
0.84
1.00
1.20
1.46
1.51
1.54
0.60
0.71
0.87
1.00
1.15
1.30
1.34
1.94
0.53
0.67
0.77
0.90
1.00
1.10
1.17
1.16
1.12
8.56
0.64
0.76
0.84
0.94
1.00
1.04
1.02
0.96
0.90
6.86
17.60
0.83
0.92
0.96
1.00
1.00
0.96
0.81
0.73
0.66
8.00
20.80
1.29
1.26
1.21
1.11
1.00
0.84
0.60
0.46
0.38
3.00
4.00
0.08 in
0.15 in
0.25 in
0.40 in
(2 mm)
(4 mm)
(6 mm)
(10 mm)
Feed Factor, Ff
Diameter Factor, Fd
1071
Copyright 2004, Industrial Press, Inc., New York, NY
SPEEDS AND FEEDS
This table is specifically for use with the combined feed/speed data for HSS twist drills in Tables 17 through 23; use Tables 5a and 5b to adjust speed and tool life for indexable insert drilling with carbides. The combined feed/speed data for HSS twist drilling are based on a 0.60-inch diameter HSS drill with standard drill point geometry (2-flute with 118° tip angle). To adjust the given speeds for different feeds and drill diameters, use the two feed/speed pairs from the tables and calculate the ratio of desired (new) feed to optimum feed (largest of the two feeds from the speed table), and the ratio of the two cutting speeds Vavg/Vopt. Use the values of these ratios to find the feed factor Ff at the intersection of the feed ratio row and the speed ratio column in the left half of the table. The diameter factor Fd is found in the same row as the feed factor, in the right half of the table, under the column corresponding to the drill diameter. For diameters not given, interpolate between the nearest available sizes. The adjusted cutting speed can be calculated from V = Vopt × Ff × Fd, where Vopt is the smaller (optimum) of the two speeds from the speed table (from the left side of the column containing the two feed/speed pairs). Tool life using the selected feed and the adjusted speed should be approximately 45 minutes. Speed adjustment factors to modify tool life are found in Table 15e.
Machinery's Handbook 27th Edition 1072
SPEEDS AND FEEDS Table 23. Feeds and Speeds for Drilling and Reaming Copper Alloys Group 1
Architectural bronze(C38500); Extra-high-leaded brass (C35600); Forging brass (C37700); Freecutting phosphor bronze (B-2) (C54400); Free-cutting brass (C36000); Free-cutting Muntz metal (C37000); High-leaded brass (C33200, C34200); High-leaded brass tube (C35300); Leaded commercial bronze (C31400); Leaded naval brass (C48500); Medium-leaded brass (C34000) Group 2 Aluminum brass, arsenical (C68700); Cartridge brass, 70% (C26000); High-silicon bronze, B (C65500); Admiralty brass (inhibited) (C44300, C44500); Jewelry bronze, 87.5% (C22600); Leaded Muntz metal (C36500, C36800); Leaded nickel silver (C79600); Low brass, 80% (C24000); Low-leaded brass (C33500); Low-silicon bronze, B (C65100); Manganese bronze, A (C67500); Muntz metal, 60% (C28000); Nickel silver, 55–18 (C77000); Red brass, 85% (C23000); Yellow brass (C26800) Group 3 Aluminum bronze, D (C61400); Beryllium copper (C17000, C17200, C17500); Commercial bronze, 90% (C22000); Copper nickel, 10% (C70600); Copper nickel, 30% (C71500);Electrolytic tough-pitch copper (C11000); Gilding, 95% (C21000); Nickel silver, 65–10 (C74500); Nickel silver, 65–12 (C75700); Nickel silver, 65–15 (C75400); Nickel silver, 65–18 (C75200); Oxygen-free copper (C10200); Phosphor bronze, 1.25% (C50200); Phosphor bronze, 10% D (C52400); Phosphor bronze, 5% A (C51000); Phosphor bronze, 8% C (C52100); Phosphorus deoxidized copper (C12200) Drilling Alloy Description and UNS Alloy Numbers
Group 1 Group 2 Group 3
Material Condition A CD A CD A CD
Reaming
HSS Speed (fpm) 160 175 120 140 60 65
160 175 110 120 50 60
Drilling Reaming Indexable Insert HSS Uncoated Carbide HSS f = feed (0.001 in./rev), s = speed (ft/min) Opt. Avg. Opt. Avg. Opt. Avg. Wrought Alloys f 21 11 11 6 36 18 s 210 265 405 915 265 230 f 24 12 11 6 40 20 s 100 130 205 455 130 120 f 23 11 11 6 38 19 s 155 195 150 340 100 175
Abbreviations designate: A, annealed; CD, cold drawn. The two leftmost speed columns in this table contain traditional Handbook speeds for HSS steel tools. The text contains information concerning feeds to use in conjunction with these speeds. HSS Drilling and Reaming: The combined feed/speed data for drilling and Table 22 are used to adjust drilling speeds for other feeds and drill diameters. Examples are given in the text. The given feeds and speeds for reaming are based on an 8-tooth, 25⁄32-inch diameter, 30° lead angle reamer, and a 0.008-inch radial depth of cut. For other feeds, the correct speed can be obtained by interpolation using the given speeds if the desired feed lies in the recommended range (between the given values of optimum and average feed). The cutting speeds for reaming do not require adjustment for tool diameter as long as the radial depth of cut does not become too large. Speed adjustment factors to modify tool life are found in Table 15e. Indexable Insert Drilling: The feed/speed data for indexable insert drilling are based on a tool with two cutting edges, an insert nose radius of 3⁄64 inch, a 10-degree lead angle, and diameter D of 1 inch. Adjustments for feed and depth of cut are made using Table 5a (Turning Speed Adjustment Factors) using a depth of cut of D/2, or one-half the drill diameter. Expected tool life at the given feeds and speeds is 15 minutes for short hole drilling (i.e., where hole depth is about 2D or less). Speed adjustment factors to increase tool life are found in Table 5b. The combined feed/speed data in this table are based on tool grades (identified in Table 16) as follows: uncoated carbide = 15.
Using the Feed and Speed Tables for Tapping and Threading.—The feed used in tapping and threading is always equal to the pitch of the screw thread being formed. The
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Machinery's Handbook 27th Edition SPEEDS AND FEEDS
1073
threading data contained in the tables for drilling, reaming, and threading (Tables 17 through 23) are primarily for tapping and thread chasing, and do not apply to thread cutting with single-point tools. The threading data in Tables 17 through 23 give two sets of feed (pitch) and speed values, for 12 and 50 threads/inch, but these values can be used to obtain the cutting speed for any other thread pitches. If the desired pitch falls between the values given in the tables, i.e., between 0.020 inch (50 tpi) and 0.083 inch (12 tpi), the required cutting speed is obtained by interpolation between the given speeds. If the pitch is less than 0.020 inch (more than 50 tpi), use the average speed, i.e., the largest of the two given speeds. For pitches greater than 0.083 inch (fewer than 12 tpi), the optimum speed should be used. Tool life using the given feed/speed data is intended to be approximately 45 minutes, and should be about the same for threads between 12 and 50 threads per inch. Example:Determine the cutting speed required for tapping 303 stainless steel with a 1⁄2– 20 coated HSS tap. The two feed/speed pairs for 303 stainless steel, in Table 19, are 83⁄35 (0.083 in./rev at 35 fpm) and 20⁄45 (0.020 in./rev at 45 fpm). The pitch of a 1⁄2–20 thread is 1⁄20 = 0.05 inch, so the required feed is 0.05 in./rev. Because 0.05 is between the two given feeds (Table 19), the cutting speed can be obtained by interpolation between the two given speeds as follows: 0.05 – 0.02- ( 45 – 35 ) = 40 fpm V = 35 + ----------------------------0.083 – 0.02 The cutting speed for coarse-pitch taps must be lower than for fine-pitch taps with the same diameter. Usually, the difference in pitch becomes more pronounced as the diameter of the tap becomes larger and slight differences in the pitch of smaller-diameter taps have little significant effect on the cutting speed. Unlike all other cutting tools, the feed per revolution of a tap cannot be independently adjusted—it is always equal to the lead of the thread and is always greater for coarse pitches than for fine pitches. Furthermore, the thread form of a coarse-pitch thread is larger than that of a fine-pitch thread; therefore, it is necessary to remove more metal when cutting a coarse-pitch thread. Taps with a long chamfer, such as starting or tapper taps, can cut faster in a short hole than short chamfer taps, such as plug taps. In deep holes, however, short chamfer or plug taps can run faster than long chamfer taps. Bottoming taps must be run more slowly than either starting or plug taps. The chamfer helps to start the tap in the hole. It also functions to involve more threads, or thread form cutting edges, on the tap in cutting the thread in the hole, thus reducing the cutting load on any one set of thread form cutting edges. In so doing, more chips and thinner chips are produced that are difficult to remove from deeper holes. Shortening the chamfer length causes fewer thread form cutting edges to cut, thereby producing fewer and thicker chips that can easily be disposed of. Only one or two sets of thread form cutting edges are cut on bottoming taps, causing these cutting edges to assume a heavy cutting load and produce very thick chips. Spiral-pointed taps can operate at a faster cutting speed than taps with normal flutes. These taps are made with supplementary angular flutes on the end that push the chips ahead of the tap and prevent the tapped hole from becoming clogged with chips. They are used primarily to tap open or through holes although some are made with shorter supplementary flutes for tapping blind holes. The tapping speed must be reduced as the percentage of full thread to be cut is increased. Experiments have shown that the torque required to cut a 100 per cent thread form is more than twice that required to cut a 50 per cent thread form. An increase in the percentage of full thread will also produce a greater volume of chips. The tapping speed must be lowered as the length of the hole to be tapped is increased. More friction must be overcome in turning the tap and more chips accumulate in the hole.
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Machinery's Handbook 27th Edition 1074
SPEEDS AND FEEDS
It will be more difficult to apply the cutting fluid at the cutting edges and to lubricate the tap to reduce friction. This problem becomes greater when the hole is being tapped in a horizontal position. Cutting fluids have a very great effect on the cutting speed for tapping. Although other operating conditions when tapping frequently cannot be changed, a free selection of the cutting fluid usually can be made. When planning the tapping operation, the selection of a cutting fluid warrants a very careful consideration and perhaps an investigation. Taper threaded taps, such as pipe taps, must be operated at a slower speed than straight thread taps with a comparable diameter. All the thread form cutting edges of a taper threaded tap that are engaged in the work cut and produce a chip, but only those cutting edges along the chamfer length cut on straight thread taps. Pipe taps often are required to cut the tapered thread from a straight hole, adding to the cutting burden. The machine tool used for the tapping operation must be considered in selecting the tapping speed. Tapping machines and other machines that are able to feed the tap at a rate of advance equal to the lead of the tap, and that have provisions for quickly reversing the spindle, can be operated at high cutting speeds. On machines where the feed of the tap is controlled manually—such as on drill presses and turret lathes—the tapping speed must be reduced to allow the operator to maintain safe control of the operation. There are other special considerations in selecting the tapping speed. Very accurate threads are usually tapped more slowly than threads with a commercial grade of accuracy. Thread forms that require deep threads for which a large amount of metal must be removed, producing a large volume of chips, require special techniques and slower cutting speeds. Acme, buttress, and square threads, therefore, are generally cut at lower speeds. Cutting Speed for Broaching.—Broaching offers many advantages in manufacturing metal parts, including high production rates, excellent surface finishes, and close dimensional tolerances. These advantages are not derived from the use of high cutting speeds; they are derived from the large number of cutting teeth that can be applied consecutively in a given period of time, from their configuration and precise dimensions, and from the width or diameter of the surface that can be machined in a single stroke. Most broaching cutters are expensive in their initial cost and are expensive to sharpen. For these reasons, a long tool life is desirable, and to obtain a long tool life, relatively slow cutting speeds are used. In many instances, slower cutting speeds are used because of the limitations of the machine in accelerating and stopping heavy broaching cutters. At other times, the available power on the machine places a limit on the cutting speed that can be used; i.e., the cubic inches of metal removed per minute must be within the power capacity of the machine. The cutting speeds for high-speed steel broaches range from 3 to 50 feet per minute, although faster speeds have been used. In general, the harder and more difficult to machine materials are cut at a slower cutting speed and those that are easier to machine are cut at a faster speed. Some typical recommendations for high-speed steel broaches are: AISI 1040, 10 to 30 fpm; AISI 1060, 10 to 25 fpm; AISI 4140, 10 to 25 fpm; AISI 41L40, 20 to 30 fpm; 201 austenitic stainless steel, 10 to 20 fpm; Class 20 gray cast iron, 20 to 30 fpm; Class 40 gray cast iron, 15 to 25 fpm; aluminum and magnesium alloys, 30 to 50 fpm; copper alloys, 20 to 30 fpm; commercially pure titanium, 20 to 25 fpm; alpha and beta titanium alloys, 5 fpm; and the superalloys, 3 to 10 fpm. Surface broaching operations on gray iron castings have been conducted at a cutting speed of 150 fpm, using indexable insert cemented carbide broaching cutters. In selecting the speed for broaching, the cardinal principle of the performance of all metal cutting tools should be kept in mind; i.e., increasing the cutting speed may result in a proportionately larger reduction in tool life, and reducing the cutting speed may result in a proportionately larger increase in the tool life. When broaching most materials, a suitable cutting fluid should be used to obtain a good surface finish and a better tool life. Gray cast iron can be broached without using a cutting fluid although some shops prefer to use a soluble oil.
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Machinery's Handbook 27th Edition SPADE DRILLS
1075
Spade Drills Spade drills are used to produce holes ranging in size from about 1 inch to 6 inches diameter, and even larger. Very deep holes can be drilled and blades are available for core drilling, counterboring, and for bottoming to a flat or contoured shape. There are two principal parts to a spade drill, the blade and the holder. The holder has a slot into which the blade fits; a wide slot at the back of the blade engages with a tongue in the holder slot to locate the blade accurately. A retaining screw holds the two parts together. The blade is usually made from high-speed steel, although cast nonferrous metal and cemented carbide-tipped blades are also available. Spade drill holders are classified by a letter symbol designating the range of blade sizes that can be held and by their length. Standard stub, short, long, and extra long holders are available; for very deep holes, special holders having wear strips to support and guide the drill are often used. Long, extra long, and many short length holders have coolant holes to direct cutting fluid, under pressure, to the cutting edges. In addition to its function in cooling and lubricating the tool, the cutting fluid also flushes the chips out of the hole. The shank of the holder may be straight or tapered; special automotive shanks are also used. A holder and different shank designs are shown in Fig. 1; Figs. 2a through Fig. 2f show some typical blades. Milling machine taper shank
Body diameter Blade retaining screw
Coolant holes
Locating flats Body
Flute Blade slot
Seating surface Flute length
Morse taper shank
Straight shank
Coolant inductor
Automotive shank (special) Fig. 1. Spade Drill Blade Holder
Spade Drill Geometry.—Metal separation from the work is accomplished in a like manner by both twist drills and spade drills, and the same mechanisms are involved for each. The two cutting lips separate the metal by a shearing action that is identical to that of chip formation by a single-point cutting tool. At the chisel edge, a much more complex condition exists. Here the metal is extruded sideways and at the same time is sheared by the rotation of the blunt wedge-formed chisel edge. This combination accounts for the very high thrust force required to penetrate the work. The chisel edge of a twist drill is slightly rounded, but on spade drills, it is a straight edge. Thus, it is likely that it is more difficult for the extruded metal to escape from the region of the chisel edge with spade drills. However, the chisel edge is shorter in length than on twist drills and the thrust for spade drilling is less.
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Machinery's Handbook 27th Edition 1076
SPADE DRILLS Typical Spade Drill Blades
Fig. 2a. Standard blade
Fig. 2b. Standard blade with corner chamfer
Fig. 2d. Center cutting facing or Fig. 2e. Standard blade with split bottoming blade point or crankshaft point
Fig. 2c. Core drilling blade
Fig. 2f. Center cutting radius blade
Basic spade drill geometry is shown in Fig. 3. Normally, the point angle of a standard tool is 130 degrees and the lip clearance angle is 18 degrees, resulting in a chisel edge angle of 108 degrees. The web thickness is usually about 1⁄4 to 5⁄16 as thick as the blade thickness. Usually, the cutting edge angle is selected to provide this web thickness and to provide the necessary strength along the entire length of the cutting lip. A further reduction of the chisel edge length is sometimes desirable to reduce the thrust force in drilling. This reduction can be accomplished by grinding a secondary rake surface at the center or by grinding a split point, or crankshaft point, on the point of the drill. The larger point angle of a standard spade drill—130 degrees as compared with 118 degrees on a twist drill—causes the chips to flow more toward the periphery of the drill, thereby allowing the chips to enter the flutes of the holder more readily. The rake angle facilitates the formation of the chip along the cutting lips. For drilling materials of average hardness, the rake angle should be 10 to 12 degrees; for hard or tough steels, it should be 5 to 7 degrees; and for soft and ductile materials, it can be increased to 15 to 20 degrees. The rake surface may be flat or rounded, and the latter design is called radial rake. Radial rake is usually ground so that the rake angle is maximum at the periphery and decreases uniformly toward the center to provide greater cutting edge strength at the center. A flat rake surface is recommended for drilling hard and tough materials in order to reduce the tendency to chipping and to reduce heat damage. A most important feature of the cutting edge is the chip splitters, which are also called chip breaker grooves. Functionally, these grooves are chip dividers; instead of forming a single wide chip along the entire length of the cutting edge, these grooves cause formation of several chips that can be readily disposed of through the flutes of the holder. Chip splitters must be carefully ground to prevent the chips from packing in the grooves, which greatly reduces their effectiveness. Splitters should be ground perpendicular to the cutting lip and parallel to the surface formed by the clearance angle. The grooves on the two cut-
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Machinery's Handbook 27th Edition SPADE DRILLING
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ting lips must not overlap when measured radially along the cutting lip. Fig. 4 and the accompanying table show the groove form and dimensions.
Rake angle
R Radial rake Front lip clearance angle Chip splitters
O.D. clearance angle Flat rake
O.D. land (circular)
Seating pad Locating ears
Blade diameter
Web
Chisel edge angle
Locating slot
Rake surface Cutting lip
Chisel edge Blade thickness
Cutting edge angle
0.031 Typ.
Back taper Point angle
Stepped O.D. clearance 0.031 R. Typ. O.D. clearance angle
Wedge angle (optional)
Fig. 3. Spade Drill Blade
On spade drills, the front lip clearance angle provides the relief. It may be ground on a drill grinding machine but usually it is ground flat. The normal front lip clearance angle is 8 degrees; in some instances, a secondary relief angle of about 14 degrees is ground below the primary clearance. The wedge angle on the blade is optional. It is generally ground on thicker blades having a larger diameter to prevent heel dragging below the cutting lip and to reduce the chisel edge length. The outside-diameter land is circular, serving to support and guide the blade in the hole. Usually it is ground to have a back taper of 0.001 to 0.002 inch per inch per side. The width of the land is approximately 20 to 25 per cent of the blade thickness. Normally, the outside-diameter clearance angle behind the land is 7 to 10 degrees. On many spade drill blades, the outside-diameter clearance surface is stepped about 0.030 inch below the land.
Fig. 4. Spade Drill Chip Splitter Dimensions
Spade Drilling.—Spade drills are used on drilling machines and other machine tools where the cutting tool rotates; they are also used on turning machines where the work
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Machinery's Handbook 27th Edition 1078
SPADE DRILLING
rotates and the tool is stationary. Although there are some slight operational differences, the methods of using spade drills are basically the same. An adequate supply of cutting fluid must be used, which serves to cool and lubricate the cutting edges; to cool the chips, thus making them brittle and more easily broken; and to flush chips out of the hole. Flood cooling from outside the hole can be used for drilling relatively shallow holes, of about one to two and one-half times the diameter in depth. For deeper holes, the cutting fluid should be injected through the holes in the drill. When drilling very deep holes, it is often helpful to blow compressed air through the drill in addition to the cutting fluid to facilitate ejection of the chips. Air at full shop pressure is throttled down to a pressure that provides the most efficient ejection. The cutting fluids used are light and medium cutting oils, water-soluble oils, and synthetics, and the type selected depends on the work material. Starting a spade drill in the workpiece needs special attention. The straight chisel edge on the spade drill has a tendency to wander as it starts to enter the work, especially if the feed is too light. This wander can result in a mispositioned hole and possible breakage of the drill point. The best method of starting the hole is to use a stub or short-length spade drill holder and a blade of full size that should penetrate at least 1⁄8 inch at full diameter. The holder is then changed for a longer one as required to complete the hole to depth. Difficulties can be encountered if spotting with a center drill or starting drill is employed because the angles on these drills do not match the 130-degree point angle of the spade drill. Longer spade drills can be started without this starting procedure if the drill is guided by a jig bushing and if the holder is provided with wear strips. Chip formation warrants the most careful attention as success in spade drilling is dependent on producing short, well-broken chips that can be easily ejected from the hole. Straight, stringy chips or chips that are wound like a clock spring cannot be ejected properly; they tend to pack around the blade, which may result in blade failure. The chip splitters must be functioning to produce a series of narrow chips along each cutting edge. Each chip must be broken, and for drilling ductile materials they should be formed into a “C” or “figure 9” shape. Such chips will readily enter the flutes on the holder and flow out of the hole. Proper chip formation is dependent on the work material, the spade drill geometry, and the cutting conditions. Brittle materials such as gray cast iron seldom pose a problem because they produce a discontinuous chip, but austenitic stainless steels and very soft and ductile materials require much attention to obtain satisfactory chip control. Thinning the web or grinding a split point on the blade will sometimes be helpful in obtaining better chip control, as these modifications allow use of a heavier feed. Reducing the rake angle to obtain a tighter curl on the chip and grinding a corner chamfer on the tool will sometimes help to produce more manageable chips. In most instances, it is not necessary to experiment with the spade drill blade geometry to obtain satisfactory chip control. Control usually can be accomplished by adjusting the cutting conditions; i.e., the cutting speed and the feed rate. Normally, the cutting speed for spade drilling should be 10 to 15 per cent lower than that for an equivalent twist drill, although the same speed can be used if a lower tool life is acceptable. The recommended cutting speeds for twist drills on Tables 17 through 23, starting on page 1061, can be used as a starting point; however, they should be decreased by the percentage just given. It is essential to use a heavy feed rate when spade drilling to produce a thick chip. and to force the chisel edge into the work. In ductile materials, a light feed will produce a thin chip that is very difficult to break. The thick chip on the other hand, which often contains many rupture planes, will curl and break readily. Table 1 gives suggested feed rates for different spade drill sizes and materials. These rates should be used as a starting point and some adjustments may be necessary as experience is gained.
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Machinery's Handbook 27th Edition SPADE DRILLING
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Table 1. Feed Rates for Spade Drilling Feed—Inches per Revolution Spade Drill Diameter—Inches Material Free Machining Steel
Plain Carbon Steels
Free Machining Alloy Steels
Alloy Steels
Hardness, Bhn
1–11⁄4
11⁄4–2
2–3
3–4
4–5
5–8
100–240
0.014
0.016
0.018
0.022
0.025
0.030
240–325
0.010
0.014
0.016
0.020
0.022
0.025
100–225
0.012
0.015
0.018
0.022
0.025
0.030
225–275
0.010
0.013
0.015
0.018
0.020
0.025
275–325
0.008
0.010
0.013
0.015
0.018
0.020
150–250
0.014
0.016
0.018
0.022
0.025
0.030
250–325
0.012
0.014
0.016
0.018
0.020
0.025
325–375
0.010
0.010
0.014
0.016
0.018
0.020
125–180
0.012
0.015
0.018
0.022
0.025
0.030
180–225
0.010
0.012
0.016
0.018
0.022
0.025
225–325
0.009
0.010
0.013
0.015
0.018
0.020
325–400
0.006
0.008
0.010
0.012
0.014
0.016
Tool Steels Water Hardening
150–250
0.012
0.014
0.016
0.018
0.020
0.022
Shock Resisting
175–225
0.012
0.014
0.015
0.016
0.017
0.018
Cold Work
200–250
0.007
0.008
0.009
0.010
0.011
0.012
Hot Work
150–250
0.012
0.013
0.015
0.016
0.018
0.020
Mold
150–200
0.010
0.012
0.014
0.016
0.018
0.018
Special-Purpose
150–225
0.010
0.012
0.014
0.016
0.016
0.018
200–240
0.010
0.012
0.013
0.015
0.017
0.018
110–160
0.020
0.022
0.026
0.028
0.030
0.034
160–190
0.015
0.018
0.020
0.024
0.026
0.028
190–240
0.012
0.014
0.016
0.018
0.020
0.022
240–320
0.010
0.012
0.016
0.018
0.018
0.018
140–190
0.014
0.016
0.018
0.020
0.022
0.024
190–250
0.012
0.014
0.016
0.018
0.018
0.020
250–300
0.010
0.012
0.016
0.018
0.018
0.018
110–160
0.014
0.016
0.018
0.020
0.022
0.024
160–220
0.012
0.014
0.016
0.018
0.020
0.020
220–280
0.010
0.012
0.014
0.016
0.018
0.018
High-Speed
Gray Cast Iron
Ductile or Nodular Iron
Malleable Iron Ferritic Pearlitic Free Machining Stainless Steel Ferritic
…
0.016
0.018
0.020
0.024
0.026
0.028
Austenitic
…
0.016
0.018
0.020
0.022
0.024
0.026
Martensitic
…
0.012
0.014
0.016
0.016
0.018
0.020
Stainless Steel Ferritic
…
0.012
0.014
0.018
0.020
0.020
0.022
Austenitic
…
0.012
0.014
0.016
0.018
0.020
0.020
Martensitic Aluminum Alloys Copper Alloys
…
0.010
0.012
0.012
0.014
0.016
0.018
…
0.020
0.022
0.024
0.028
0.030
0.040
(Soft)
0.016
0.018
0.020
0.026
0.028
0.030
(Hard)
0.010
0.012
0.014
0.016
0.018
0.018
Titanium Alloys
…
0.008
0.010
0.012
0.014
0.014
0.016
High-Temperature Alloys
…
0.008
0.010
0.012
0.012
0.014
0.014
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Machinery's Handbook 27th Edition 1080
SPADE DRILLING
Power Consumption and Thrust for Spade Drilling.—In each individual setup, there are factors and conditions influencing power consumption that cannot be accounted for in a simple equation; however, those given below will enable the user to estimate power consumption and thrust accurately enough for most practical purposes. They are based on experimentally derived values of unit horsepower, as given in Table 2. As a word of caution, these values are for sharp tools. In spade drilling, it is reasonable to estimate that a dull tool will increase the power consumption and the thrust by 25 to 50 per cent. The unit horsepower values in the table are for the power consumed at the cutting edge, to which must be added the power required to drive the machine tool itself, in order to obtain the horsepower required by the machine tool motor. An allowance for power to drive the machine is provided by dividing the horsepower at the cutter by a mechanical efficiency factor, em. This factor can be estimated to be 0.90 for a direct spindle drive with a belt, 0.75 for a back gear drive, and 0.70 to 0.80 for geared head drives. Thus, for spade drilling the formulas are πD -⎞ fN hp c = uhp ⎛ --------⎝ 4 ⎠ 2
B s = 148,500 uhp fD hp hp m = -------cem fm f = ---N where hpc = horsepower at the cutter hpm = horsepower at the motor Bs =thrust for spade drilling in pounds uhp = unit horsepower D =drill diameter in inches f =feed in inches per revolution fm =feed in inches per minute N =spindle speed in revolutions per minute em =mechanical efficiency factor Table 2. Unit Horsepower for Spade Drilling Material
Hardness
Plain Carbon and Alloy Steel
Cast Irons Stainless Steels
85–200 Bhn 200–275 275–375 375–425 45–52 Rc 110–200 Bhn 200–300 135–275 Bhn 30–45 Rc
uhp 0.79 0.94 1.00 1.15 1.44 0.5 1.08 0.94 1.08
Material Titanium Alloys High-Temp Alloys Aluminum Alloys Magnesium Alloys Copper Alloys
Hardness 250–375 Bhn 200–360 Bhn … … 20–80 Rb 80–100 Rb
uhp 0.72 1.44 0.22 0.16 0.43 0.72
Example:Estimate the horsepower and thrust required to drive a 2-inch diameter spade drill in AISI 1045 steel that is quenched and tempered to a hardness of 275 Bhn. From Table 17 on page 1061, the cutting speed, V, for drilling this material with a twist drill is 50 feet per minute. This value is reduced by 10 per cent for spade drilling and the speed selected is thus 0.9 × 50 = 45 feet per minute. The feed rate (from Table 1, page 1079) is 0.015 in/rev. and the unit horsepower from Table 2 above is 0.94. The machine efficiency factor is estimated to be 0.80 and it will be assumed that a 50 per cent increase in the unit horsepower must be allowed for dull tools.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TREPANNING
1081
Step 1. Calculate the spindle speed from the following formula: 12VN = --------πD where: N =spindle speed in revolutions per minute V =cutting speed in feet per minute D =drill diameter in inches 12 × 45 Thus, N = ------------------ = 86 revolutions per minute π×2 Step 2. Calculate the horsepower at the cutter: 2 π × 2 2-⎞ 0.015 × 86 = 3.8 hp c = uhp ⎛ πD ----------⎞ fN = 0.94 ⎛ -------------⎝ 4 ⎠ ⎝ 4 ⎠
Step 3. Calculate the horsepower at the motor and provide for a 50 per cent power increase for the dull tool: hp 3.8- = 4.75 horsepower hp m = -------c- = --------em 0.80 hp m (with dull tool) = 1.5 × 4.75 = 7.125 horsepower Step 4. Estimate the spade drill thrust: B s = 148,500 × uhp × fD = 148,500 × 0.94 × 0.015 × 2 = 4188 lb (for sharp tool) B s = 1.5 × 4188 = 6282 lb (for dull tool) Trepanning.—Cutting a groove in the form of a circle or boring or cutting a hole by removing the center or core in one piece is called trepanning. Shallow trepanning, also called face grooving, can be performed on a lathe using a single-point tool that is similar to a grooving tool but has a curved blade. Generally, the minimum outside diameter that can be cut by this method is about 3 inches and the maximum groove depth is about 2 inches. Trepanning is probably the most economical method of producing deep holes that are 2 inches, and larger, in diameter. Fast production rates can be achieved. The tool consists of a hollow bar, or stem, and a hollow cylindrical head to which a carbide or high-speed steel, single-point cutting tool is attached. Usually, only one cutting tool is used although for some applications a multiple cutter head must be used; e.g., heads used to start the hole have multiple tools. In operation, the cutting tool produces a circular groove and a residue core that enters the hollow stem after passing through the head. On outside-diameter exhaust trepanning tools, the cutting fluid is applied through the stem and the chips are flushed around the outside of the tool; inside-diameter exhaust tools flush the chips out through the stem with the cutting fluid applied from the outside. For starting the cut, a tool that cuts a starting groove in the work must be used, or the trepanning tool must be guided by a bushing. For holes less than about five diameters deep, a machine that rotates the trepanning tool can be used. Often, an ordinary drill press is satisfactory; deeper holes should be machined on a lathe with the work rotating. A hole diameter tolerance of ±0.010 inch can be obtained easily by trepanning and a tolerance of ±0.001 inch has sometimes been held. Hole runout can be held to ±0.003 inch per foot and, at times, to ±0.001 inch per foot. On heat-treated metal, a surface finish of 125 to 150 µm AA can be obtained and on annealed metals 100 to 250 µm AA is common.
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Machinery's Handbook 27th Edition 1082
SPEEDS AND FEEDS
ESTIMATING SPEEDS AND MACHINING POWER Estimating Planer Cutting Speeds.—Whereas most planers of modern design have a means of indicating the speed at which the table is traveling, or cutting, many older planers do not. Thus, the following formulas are useful for planers that do not have a means of indicating the table or cutting speed. It is not practicable to provide a formula for calculating the exact cutting speed at which a planer is operating because the time to stop and start the table when reversing varies greatly. The formulas below will, however, provide a reasonable estimate. Vc ≅ Sc L V S c ≅ -----c L where Vc =cutting speed; fpm or m/min Sc =number of cutting strokes per minute of planer table L =length of table cutting stroke; ft or m Cutting Speed for Planing and Shaping.—The traditional HSS cutting tool speeds in Tables 1 through 4b and Tables 6 through 9 can be used for planing and shaping. The feed and depth of cut factors in Tables 5c should also be used, as explained previously. Very often, other factors relating to the machine or the setup will require a reduction in the cutting speed used on a specific job. Cutting Time for Turning, Boring, and Facing.—The time required to turn a length of metal can be determined by the following formula in which T = time in minutes, L = length of cut in inches, f = feed in inches per revolution, and N = lathe spindle speed in revolutions per minute. L T = -----fN When making job estimates, the time required to load and to unload the workpiece on the machine, and the machine handling time, must be added to the cutting time for each length cut to obtain the floor-to-floor time. Planing Time.—The approximate time required to plane a surface can be determined from the following formula in which T = time in minutes, L = length of stroke in feet, Vc = cutting speed in feet per minute, Vr = return speed in feet per minute; W = width of surface to be planed in inches, F = feed in inches, and 0.025 = approximate reversal time factor per stroke in minutes for most planers: W 1 1 T = ----- L × ⎛⎝ ----- + -----⎞⎠ + 0.025 Vc Vr F Speeds for Metal-Cutting Saws.—The following speeds and feeds for solid-tooth, highspeed-steel, circular, metal-cutting saws are recommended by Saws International, Inc. (sfpm = surface feet per minute = 3.142 × blade diameter in inches × rpm of saw shaft ÷ 12). Speeds for Turning Unusual Materials.—Slate, on account of its peculiarly stratified formation, is rather difficult to turn, but if handled carefully, can be machined in an ordinary lathe. The cutting speed should be about the same as for cast iron. A sheet of fiber or pressed paper should be interposed between the chuck or steadyrest jaws and the slate, to protect the latter. Slate rolls must not be centered and run on the tailstock. A satisfactory method of supporting a slate roll having journals at the ends is to bore a piece of lignum vitae to receive the turned end of the roll, and center it for the tailstock spindle. Rubber can be turned at a peripheral speed of 200 feet per minute, although it is much easier to grind it with an abrasive wheel that is porous and soft. For cutting a rubber roll in
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINING POWER
1083
Speeds, Feeds, and Tooth Angles for Sawing Various Materials 
α =Cutting angle β =Relief angle
␣
Materials
Front Rake Angle α (deg)
Back Rake Angle β (deg)
Aluminum
24
Light Alloys with Cu, Mg, and Zn
Stock Diameters (inches)
1⁄ –3⁄ 4 4
3⁄ –11⁄ 4 2
11⁄2–21⁄2
21⁄2–31⁄2
12
6500 sfpm 100 in/min
6200 sfpm 85 in/min
6000 sfpm 80 in/min
5000 sfpm 75 in/min
22
10
3600 sfpm 70 in/min
3300 sfpm 65 in/min
3000 sfpm 63 in/min
2600 sfpm 60 in/min
Light Alloys with High Si
20
8
650 sfpm 16 in/min
600 sfpm 16 in/min
550 sfpm 14 in/min
550 sfpm 12 in/min
Copper
20
10
1300 sfpm 24 in/min
1150 sfpm 24 in/min
1000 sfpm 22 in/min
800 sfpm 22 in/min
Bronze
15
8
1300 sfpm 24 in/min
1150 sfpm 24 in/min
1000 sfpm 22 in/min
800 sfpm 20 in/min
Hard Bronze
10
8
400 sfpm 6.3 in/min
360 sfpm 6 in/min
325 sfpm 5.5 in/min
300 sfpm 5.1 in/min
Cu-Zn Brass
16
8
2000 sfpm 43 in/min
2000 sfpm 43 in/min
1800 sfpm 39 in/min
1800 sfpm 35 in/min
Gray Cast Iron
12
8
82 sfpm 4 in/min
75 sfpm 4 in/min
72 sfpm 3.5 in/min
66 sfpm 3 in/min
Carbon Steel
20
8
160 sfpm 6.3 in/min
150 sfpm 5.9 in/min
150 sfpm 5.5 in/min
130 sfpm 5.1 in/min
Medium Hard Steel
18
8
100 sfpm 5.1 in/min
100 sfpm 4.7 in/min
80 sfpm 4.3 in/min
80 sfpm 4.3 in/min
Hard Steel
15
8
66 sfpm 4.3 in/min
66 sfpm 4.3 in/min
60 sfpm 4 in/min
57 sfpm 3.5 in/min
Stainless Steel
15
8
66 sfpm 2 in/min
63 sfpm 1.75 in/min
60 sfpm 1.75 in/min
57 sfpm 1.5 in/min
two, the ordinary parting tool should not be used, but a tool shaped like a knife; such a tool severs the rubber without removing any material. Gutta percha can be turned as easily as wood, but the tools must be sharp and a good soap-and-water lubricant used. Copper can be turned easily at 200 feet per minute. Limestone such as is used in the construction of pillars for balconies, etc., can be turned at 150 feet per minute, and the formation of ornamental contours is quite easy. Marble is a treacherous material to turn. It should be cut with a tool such as would be used for brass, but
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1084
MACHINING POWER
at a speed suitable for cast iron. It must be handled very carefully to prevent flaws in the surface. The foregoing speeds are for high-speed steel tools. Tools tipped with tungsten carbide are adapted for cutting various non-metallic products which cannot be machined readily with steel tools, such as slate, marble, synthetic plastic materials, etc. In drilling slate and marble, use flat drills; and for plastic materials, tungsten-carbide-tipped twist drills. Cutting speeds ranging from 75 to 150 feet per minute have been used for drilling slate (without coolant) and a feed of 0.025 inch per revolution for drills 3⁄4 and 1 inch in diameter. Estimating Machining Power.—Knowledge of the power required to perform machining operations is useful when planning new machining operations, for optimizing existing machining operations, and to develop specifications for new machine tools that are to be acquired. The available power on any machine tool places a limit on the size of the cut that it can take. When much metal must be removed from the workpiece it is advisable to estimate the cutting conditions that will utilize the maximum power on the machine. Many machining operations require only light cuts to be taken for which the machine obviously has ample power; in this event, estimating the power required is a wasteful effort. Conditions in different shops may vary and machine tools are not all designed alike, so some variations between the estimated results and those obtained on the job are to be expected. However, by using the methods provided in this section a reasonable estimate of the power required can be made, which will suffice in most practical situations. The measure of power in customary inch units is the horsepower; in SI metric units it is the kilowatt, which is used for both mechanical and electrical power. The power required to cut a material depends upon the rate at which the material is being cut and upon an experimentally determined power constant, Kp, which is also called the unit horsepower, unit power, or specific power consumption. The power constant is equal to the horsepower required to cut a material at a rate of one cubic inch per minute; in SI metric units the power constant is equal to the power in kilowatts required to cut a material at a rate of one cubic centimeter per second, or 1000 cubic millimeters per second (1 cm3 = 1000 mm3). Different values of the power constant are required for inch and for metric units, which are related as follows: to obtain the SI metric power constant, multiply the inch power constant by 2.73; to obtain the inch power constant, divide the SI metric power constant by 2.73. Values of the power constant in Tables 3a, and 3b can be used for all machining operations except drilling and grinding. Values given are for sharp tools. Table 3a. Power Constants, Kp, Using Sharp Cutting Tools Material
Kp Kp Brinell Inch Metric Hardness Units Units
Material
Brinell Hardness
Kp Kp Inch Metric Units Units
150–175
0.42
1.15
175–200 200–250 250–300
0.57 0.82 1.18
1.56 2.24 3.22
150–175 175–200 200–250 …
0.62 0.78 0.86 …
1.69 2.13 2.35 …
Ferrous Cast Metals
Gray Cast Iron
Alloy Cast Iron
100–120 120–140 140–160 { 160–180 180–200 200–220 220–240
0.28 0.35 0.38 0.52 0.60 0.71 0.91
0.76 0.96 1.04 1.42 1.64 1.94 2.48
Malleable Iron Ferritic
150–175 { 175–200 200–250
0.30 0.63 0.92
0.82 1.72 2.51
Cast Steel
Pearlitic
…
{
{
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Machinery's Handbook 27th Edition MACHINING POWER
1085
Table 3a. (Continued) Power Constants, Kp, Using Sharp Cutting Tools Material
Kp Kp Brinell Inch Metric Hardness Units Units
Material
Brinell Hardness
Kp Kp Inch Metric Units Units
High-Temperature Alloys, Tool Steel, Stainless Steel, and Nonferrous Metals High-Temperature Alloys A286 165 A286 285 Chromoloy 200 Chromoloy 310 Inco 700 330 Inco 702 230 Hastelloy-B 230 M-252 230 M-252 310 Ti-150A 340 U-500 375
0.82 0.93 0.78 1.18 1.12 1.10 1.10 1.10 1.20 0.65 1.10
2.24 2.54 3.22 3.00 3.06 3.00 3.00 3.00 3.28 1.77 3.00
…
1.00
2.73
0.75 0.88 0.98 1.20 1.30
2.05 2.40 2.68 3.28 3.55
Monel Metal
Tool Steel
175-200 200-250 { 250-300 300-350 350-400
150-175 175-200 200-250 … …
0.60 0.72 0.88 0.25 0.91
1.64 1.97 2.40 0.68 2.48
… … … …
0.83 0.50 0.25 0.30
2.27 1.36 0.68 0.82
Bronze Hard Medium
… …
0.91 0.50
2.48 1.36
Aluminum Cast Rolled (hard)
… …
0.25 0.33
0.68 0.90
Magnesium Alloys
…
0.10
0.27
Stainless Steel Zinc Die Cast Alloys Copper (pure) Brass Hard Medium Soft Leaded
{
The value of the power constant is essentially unaffected by the cutting speed, the depth of cut, and the cutting tool material. Factors that do affect the value of the power constant, and thereby the power required to cut a material, include the hardness and microstructure of the work material, the feed rate, the rake angle of the cutting tool, and whether the cutting edge of the tool is sharp or dull. Values are given in the power constant tables for different material hardness levels, whenever this information is available. Feed factors for the power constant are given in Table 4. All metal cutting tools wear but a worn cutting edge requires more power to cut than a sharp cutting edge. Factors to provide for tool wear are given in Table 5. In this table, the extra-heavy-duty category for milling and turning occurs only on operations where the tool is allowed to wear more than a normal amount before it is replaced, such as roll turning. The effect of the rake angle usually can be disregarded. The rake angle for which most of the data in the power constant tables are given is positive 14 degrees. Only when the deviation from this angle is large is it necessary to make an adjustment. Using a rake angle that is more positive reduces the power required approximately 1 per cent per degree; using a rake angle that is more negative increases the power required; again approximately 1 per cent per degree. Many indexable insert cutting tools are formed with an integral chip breaker or other cutting edge modifications, which have the effect of reducing the power required to cut a material. The extent of this effect cannot be predicted without a test of each design. Cutting fluids will also usually reduce the power required, when operating in the lower range of cutting speeds. Again, the extent of this effect cannot be predicted because each cutting fluid exhibits its own characteristics.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1086
MACHINING POWER Table 3b. Power Constants, Kp, Using Sharp Cutting Tools
Material
Brinell Hardness
Kp Kp Inch Metric Units Units
Material
Brinell Hardness
Kp Inch Units
Kp SI Metric Units
220–240 240–260 260–280 280–300 300–320 320–340 340–360
0.89 0.92 0.95 1.00 1.03 1.06 1.14
2.43 2.51 2.59 2.73 2.81 2.89 3.11
180–200 200–220 220–240 240–260 …
0.51 0.55 0.57 0.62 …
1.39 1.50 1.56 1.69 …
140–160 160–180 180–200 200–220 220–240 240–260 260–280 280–300 300–320 320–340 … … … …
0.56 0.59 0.62 0.65 0.70 0.74 0.77 0.80 0.83 0.89 … … … …
1.53 1.61 1.69 1.77 1.91 2.02 2.10 2.18 2.27 2.43 … … … …
Wrought Steels Plain Carbon Steels 80–100 100–120 120–140 140–160 160–180 180–200 200–220
All Plain Carbon Steels
0.63 0.66 0.69 0.74 0.78 0.82 0.85
1.72 1.80 1.88 2.02 2.13 2.24 2.32
All Plain Carbon Steels
Free Machining Steels AISI 1108, 1109, 1110, 1115, 1116, 1117, 1118, 1119, 1120, 1125, 1126, 1132
100–120 120–140 140–160 160–180 180–200
0.41 0.42 0.44 0.48 0.50
1.12 1.15 1.20 1.31 1.36
140–160 160–180 180–200 200–220 220–240 240–260 260–280 280–300 300–320 320–340 340–360 160–180 180–200 200–220
0.62 0.65 0.69 0.72 0.76 0.80 0.84 0.87 0.91 0.96 1.00 0.79 0.83 0.87
1.69 1.77 1.88 1.97 2.07 2.18 2.29 2.38 2.48 2.62 2.73 2.16 2.27 2.38
AISI 1137, 1138, 1139, 1140, 1141, 1144, 1145, 1146, 1148, 1151
Alloy Steels AISI 4023, 4024, 4027, 4028, 4032, 4037, 4042, 4047, 4137, 4140, 4142, 4145, 4147, 4150, 4340, 4640, 4815, 4817, 4820, 5130, 5132, 5135, 5140, 5145, 5150, 6118, 6150, 8637, 8640, 8642, 8645, 8650, 8740
AISI 1330, 1335, 1340, E52100
AISI 4130, 4320, 4615, 4620, 4626, 5120, 8615, 8617, 8620, 8622, 8625, 8630, 8720
The machine tool transmits the power from the driving motor to the workpiece, where it is used to cut the material. The effectiveness of this transmission is measured by the machine tool efficiency factor, E. Average values of this factor are given in Table 6. Formulas for calculating the metal removal rate, Q, for different machining operations are given in Table 7. These formulas are used together with others given below. The following formulas can be used with either customary inch or with SI metric units. Pc = K p CQW P K p CQW Pm = -----c = -------------------E E where Pc =power at the cutting tool; hp, or kW
Copyright 2004, Industrial Press, Inc., New York, NY
(1) (2)
Machinery's Handbook 27th Edition MACHINING POWER
1087
Table 4. Feed Factors, C, for Power Constants Inch Units Feed in.a 0.001 0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010 0.011 0.012 0.013
SI Metric Units
C
Feed in.a
1.60 1.40 1.30 1.25 1.19 1.15 1.11 1.08 1.06 1.04 1.02 1.00 0.98
0.014 0.015 0.016 0.018 0.020 0.022 0.025 0.028 0.030 0.032 0.035 0.040 0.060
a Turning, in/rev;
C
Feed mmb
C
Feed mmb
C
0.97 0.96 0.94 0.92 0.90 0.88 0.86 0.84 0.83 0.82 0.80 0.78 0.72
0.02 0.05 0.07 0.10 0.12 0.15 0.18 0.20 0.22 0.25 0.28 0.30 0.33
1.70 1.40 1.30 1.25 1.20 1.15 1.11 1.08 1.06 1.04 1.01 1.00 0.98
0.35 0.38 0.40 0.45 0.50 0.55 0.60 0.70 0.75 0.80 0.90 1.00 1.50
0.97 0.95 0.94 0.92 0.90 0.88 0.87 0.84 0.83 0.82 0.80 0.78 0.72
milling, in/tooth; planing and shaping, in/stroke; broaching, in/tooth. milling, mm/tooth; planing and shaping, mm/stroke; broaching, mm/tooth.
b Turning, mm/rev;
Table 5. Tool Wear Factors, W Type of Operation For all operations with sharp cutting tools Turning: Finish turning (light cuts) Normal rough and semifinish turning Extra-heavy-duty rough turning Milling: Slab milling End milling Light and medium face milling Extra-heavy-duty face milling Drilling: Normal drilling Drilling hard-to-machine materials and drilling with a very dull drill Broaching: Normal broaching Heavy-duty surface broaching Planing and Use values given for turning Shaping
Pm =power at the motor; hp, or kW Kp =power constant (see Tables 3a and 3b) Q =metal removal rate; in 3/min or cm3/s (see Table 7) C =feed factor for power constant (see Table 4) W =tool wear factor (see Table 5) E =machine tool efficiency factor (see Table 6) V =cutting speed, fpm, or m/min N =cutting speed, rpm f =feed rate for turning; in/rev or mm/rev
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W 1.00 1.10 1.30 1.60–2.00 1.10 1.10 1.10–1.25 1.30–1.60 1.30 1.50 1.05–1.10 1.20–1.30
Machinery's Handbook 27th Edition 1088
MACHINING POWER f =feed rate for planing and shaping; in/stroke, or mm/stroke ft =feed per tooth; in/tooth, or mm/tooth fm =feed rate; in/min or mm/min dt =maximum depth of cut per tooth: inch, or mm d =depth of cut; inch, or mm nt =number of teeth on milling cutter nc =number of teeth engaged in work w =width of cut; inch, or mm Table 6. Machine Tool Efficiency Factors, E Type of Drive
E
Type of Drive
E
Direct Belt Drive
0.90
Geared Head Drive
0.70–0.80
Back Gear Drive
0.75
Oil-Hydraulic Drive
0.60–0.90
Table 7. Formulas for Calculating the Metal Removal Rate, Q
Operation
Metal Removal Rate For SI Metric Units Only For Inch Units Only Q = cm3/s Q = in3/min
Single-Point Tools (Turning, Planing, and Shaping)
12Vfd
V- fd ----60
Milling
fmwd
f m wd ----------------60, 000
Surface Broaching
12Vwncdt
V- un d ----60 c t
Example:A 180–200 Bhn AISI 4130 shaft is to be turned on a geared head lathe using a cutting speed of 350 fpm (107 m/min), a feed rate of 0.016 in/rev (0.40 mm/rev), and a depth of cut of 0.100 inch (2.54 mm). Estimate the power at the cutting tool and at the motor, using both the inch and metric data. Inch units: Kp =0.62 (from Table 3b) C =0.94 (from Table 4) W =1.30 (from Table 5) E =0.80 (from Table 6) Q =12 Vfd = 12 × 350 × 0.016 × 0.100 (from Table 7) Q =6.72 in3/min Pc = K p CQW = 0.62 × 0.94 × 6.72 × 1.30 = 5.1 hp P 5 - = 6.4 hp Pm = -----c = --------E 0.80 SI metric units: Kp =1.69 (from Table 3b) C =0.94 (from Table 4) W =1.30 (from Table 5) E =0.80 (from Table 6)
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Machinery's Handbook 27th Edition MACHINING POWER
1089
3 V- fd = 107 Q = ------------- × 0.40 × 2.54 = 1.81 cm /s (from Table 7) 60 60
Pc = K p CQW = 1.69 × 0.94 × 1.81 × 1.30 = 3.74 kW P Pm = -----c = 3.74 ---------- = 4.677 kW E 0.80 Whenever possible the maximum power available on a machine tool should be used when heavy cuts must be taken. The cutting conditions for utilizing the maximum power should be selected in the following order: 1) select the maximum depth of cut that can be used; 2) select the maximum feed rate that can be used; and 3) estimate the cutting speed that will utilize the maximum power available on the machine. This sequence is based on obtaining the longest tool life of the cutting tool and at the same time obtaining as much production as possible from the machine. The life of a cutting tool is most affected by the cutting speed, then by the feed rate, and least of all by the depth of cut. The maximum metal removal rate that a given machine is capable of machining from a given material is used as the basis for estimating the cutting speed that will utilize all the power available on the machine. Example:A 0.125 inch deep cut is to be taken on a 200–210 Bhn AISI 1050 steel part using a 10 hp geared head lathe. The feed rate selected for this job is 018 in./rev. Estimate the cutting speed that will utilize the maximum power available on the lathe. Kp =0.85 (From Table 3b) C =0.92 (From Table 4) W =1.30 (From Table 5) E =0.80 (From Table 6) Pm E 10 × 0.80 Q max = --------------- = ------------------------------------------0.85 × 0.92 × 1.30 K p CW
K p CQW⎞ ⎛ P = -------------------⎝ m E ⎠
3
= 7.87 in /min Q max 7.87 V = ------------ = -------------------------------------------12fd 12 × 0.018 × 0.125 = 291 fpm
( Q = 12Vfd )
Example:A 160-180 Bhn gray iron casting that is 6 inches wide is to have 1⁄8 inch stock removed on a 10 hp milling machine, using an 8 inch diameter, 10 tooth, indexable insert cemented carbide face milling cutter. The feed rate selected for this cutter is 0.012 in/tooth, and all the stock (0.125 inch) will be removed in one cut. Estimate the cutting speed that will utilize the maximum power available on the machine. Kp =0.52 (From Table 3a) C =1.00 (From Table 4) W =1.20 (From Table 5) E =0.80 (From Table 6)
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Machinery's Handbook 27th Edition 1090
MACHINING POWER
Pm E 3 10 × 0.80 Q max = --------------- = -------------------------------------------- = 12.82 in /min 0.52 × 1.00 × 1.20 K p CW Q max 12.82 = 17.1 in/min f m = ------------ = ---------------------wd 6 × 0.125 f max 17 - = ------------------------N = --------= 142.4 rpm ft nt 0.012 × 10 × 8 × 142 = 298.3 fpm V = πDN ------------ = π --------------------------12 12
p CQW⎞ ⎛P = K -------------------⎝ m E ⎠
( Q = f m wd ) ( fm = ft nt N ) ⎛ N = 12V ----------⎞ ⎝ πD ⎠
Estimating Drilling Thrust, Torque, and Power.—Although the lips of a drill cut metal and produce a chip in the same manner as the cutting edges of other metal cutting tools, the chisel edge removes the metal by means of a very complex combination of extrusion and cutting. For this reason a separate method must be used to estimate the power required for drilling. Also, it is often desirable to know the magnitude of the thrust and the torque required to drill a hole. The formulas and tabular data provided in this section are based on information supplied by the National Twist Drill Division of Regal-Beloit Corp. The values in Tables 8 through 11 are for sharp drills, and tool wear factors are given in Table 5. For most ordinary drilling operations 1.30 can be used as the tool wear factor. When drilling most difficult-to-machine materials and when the drill is allowed to become very dull, 1.50 should be used as the value of this factor. It is usually more convenient to measure the web thickness at the drill point than the length of the chisel edge; for this reason, the approximate w/d ratio corresponding to each c/d ratio for a correctly ground drill is provided in Table 9. For most standard twist drills the c/d ratio is 0.18, unless the drill has been ground short or the web has been thinned. The c/d ratio of split point drills is 0.03. The formulas given below can be used for spade drills, as well as for twist drills. Separate formulas are required for use with customary inch units and for SI metric units. Table 8. Work Material Factor, Kd, for Drilling with a Sharp Drill Work Material AISI 1117 (Resulfurized free machining mild steel) Steel, 200 Bhn Steel, 300 Bhn Steel, 400 Bhn Cast Iron, 150 Bhn Most Aluminum Alloys Most Magnesium Alloys Most Brasses Leaded Brass Austenitic Stainless Steel (Type 316) Titanium Alloy Ti6Al4V René 41
40Rc 40Rc
Hastelloy-C
Material Constant, Kd 12,000 24,000 31,000 34,000 14,000 7,000 4,000 14,000 7,000 24,000a for Torque 35,000a for Thrust 18,000a for Torque 29,000a for Thrust 40,000ab min. 30,000a for Torque 37,000a for Thrust
a Values based upon a limited number of tests. b Will increase with rapid wear.
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Machinery's Handbook 27th Edition MACHINING POWER
1091
Table 9. Chisel Edge Factors for Torque and Thrust c/d
Approx. w/d
Torque Factor A
Thrust Factor B
Thrust Factor J
c/d
Approx. w/d
Torque Factor A
Thrust Factor B
Thrust Factor J
0.03 0.05 0.08 0.10 0.13 0.15
0.025 0.045 0.070 0.085 0.110 0.130
1.000 1.005 1.015 1.020 1.040 1.080
1.100 1.140 1.200 1.235 1.270 1.310
0.001 0.003 0.006 0.010 0.017 0.022
0.18 0.20 0.25 0.30 0.35 0.40
0.155 0.175 0.220 0.260 0.300 0.350
1.085 1.105 1.155 1.235 1.310 1.395
1.355 1.380 1.445 1.500 1.575 1.620
0.030 0.040 0.065 0.090 0.120 0.160
For drills of standard design, use c/d = 0.18; for split point drills, use c/d = 0.03 c/d = Length of Chisel Edge ÷ Drill Diameter. w/d = Web Thickness at Drill Point ÷ Drill Diameter.
For inch units only: T =2Kd Ff FT BW + KdD 2JW M =KdFf FM AW Pc =MN⁄ 63.025 For SI metric units only: T =0.05 Kd Ff FT BW + 0.007 Kd D2JW K d F f F M AW M = ----------------------------- = 0.000025 Kd Ff FM AW 40 ,000 Pc =MN⁄ 9550 Use with either inch or metric units: P P m = -----c E where Pc =Power at the cutter; hp, or kW Pm =Power at the motor; hp, or kW M =Torque; in. lb, or N.m T =Thrust; lb, or N Kd =Work material factor (See Table 8) Ff =Feed factor (See Table 10) FT =Thrust factor for drill diameter (See Table 11) FM =Torque factor for drill diameter (See Table 11) A =Chisel edge factor for torque (See Table 9) B =Chisel edge factor for thrust (See Table 9) J =Chisel edge factor for thrust (See Table 9) W =Tool wear factor (See Table 5) N =Spindle speed; rpm E =Machine tool efficiency factor (See Table 6) D =Drill diameter; in., or mm c =Chisel edge length; in., or mm (See Table 9) w =Web thickness at drill point; in., or mm (See Table 9)
(1) (2) (3) (4) (5) (6) (7)
Example:A standard 7⁄8 inch drill is to drill steel parts having a hardness of 200 Bhn on a drilling machine having an efficiency of 0.80. The spindle speed to be used is 350 rpm and the feed rate will be 0.008 in./rev. Calculate the thrust, torque, and power required to drill these holes: Kd =24,000 (From Table 8) Ff =0.021 (From Table 10) FT =0.899 (From Table 11) FM =0.786 (From Table 11) A =1.085 (From Table 9) B =1.355 (From Table 9) J =0.030 (From Table 9)
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Machinery's Handbook 27th Edition 1092
MACHINING POWER Table 10. Feed Factors Ff for Drilling Inch Units
SI Metric Units
Feed, in./rev
Ff
Feed, in./rev
Ff
Feed, mm/rev
Ff
Feed, mm/rev
0.0005 0.001 0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010
0.0023 0.004 0.007 0.010 0.012 0.014 0.017 0.019 0.021 0.023 0.025
0.012 0.013 0.015 0.018 0.020 0.022 0.025 0.030 0.035 0.040 0.050
0.029 0.031 0.035 0.040 0.044 0.047 0.052 0.060 0.068 0.076 0.091
0.01 0.03 0.05 0.08 0.10 0.12 0.15 0.18 0.20 0.22 0.25
0.025 0.060 0.091 0.133 0.158 0.183 0.219 0.254 0.276 0.298 0.330
0.30 0.35 0.40 0.45 0.50 0.55 0.65 0.75 0.90 1.00 1.25
Ff 0.382 0.432 0.480 0.528 0.574 0.620 0.708 0.794 0.919 1.000 1.195
Table 11. Drill Diameter Factors: FT for Thrust, FM for Torque Inch Units
SI Metric Units
Drill Dia., in.
FT
FM
Drill Dia., in.
FT
FM
Drill Dia., mm
FT
FM
Drill Dia., mm
FT
FM
0.063 0.094 0.125 0.156 0.188 0.219 0.250 0.281 0.313 0.344 0.375 0.438 0.500 0.563 0.625 0.688 0.750 0.813
0.110 0.151 0.189 0.226 0.263 0.297 0.330 0.362 0.395 0.426 0.456 0.517 0.574 0.632 0.687 0.741 0.794 0.847
0.007 0.014 0.024 0.035 0.049 0.065 0.082 0.102 0.124 0.146 0.171 0.226 0.287 0.355 0.429 0.510 0.596 0.689
0.875 0.938 1.000 1.063 1.125 1.250 1.375 1.500 1.625 1.750 1.875 2.000 2.250 2.500 2.750 3.000 3.500 4.000
0.899 0.950 1.000 1.050 1.099 1.195 1.290 1.383 1.475 1.565 1.653 1.741 1.913 2.081 2.246 2.408 2.724 3.031
0.786 0.891 1.000 1.116 1.236 1.494 1.774 2.075 2.396 2.738 3.100 3.482 4.305 5.203 6.177 7.225 9.535 12.13
1.60 2.40 3.20 4.00 4.80 5.60 6.40 7.20 8.00 8.80 9.50 11.00 12.50 14.50 16.00 17.50 19.00 20.00
1.46 2.02 2.54 3.03 3.51 3.97 4.42 4.85 5.28 5.96 6.06 6.81 7.54 8.49 9.19 9.87 10.54 10.98
2.33 4.84 8.12 12.12 16.84 22.22 28.26 34.93 42.22 50.13 57.53 74.90 94.28 123.1 147.0 172.8 200.3 219.7
22.00 24.00 25.50 27.00 28.50 32.00 35.00 38.00 42.00 45.00 48.00 50.00 58.00 64.00 70.00 76.00 90.00 100.00
11.86 12.71 13.34 13.97 14.58 16.00 17.19 18.36 19.89 21.02 22.13 22.86 25.75 27.86 29.93 31.96 36.53 39.81
260.8 305.1 340.2 377.1 415.6 512.0 601.6 697.6 835.3 945.8 1062 1143 1493 1783 2095 2429 3293 3981
W =1.30 (From Table 5) T =2KdFf FT BW + Kd d2JW = 2 × 24,000 × 0.21 × 0.899 × 1.355 × 1.30 + 24,000 × 0.8752 × 0.030 × 1.30 = 2313 lb M =Kd Ff FMAW = 24,000 × 0.021 × 0.786 × 1.085 × 1.30 = 559 in. lb MN 559 × 350 P c = ---------------- = ------------------------ = 3.1 hp 63 ,025 63 ,025
P 3.1 P m = -----c = ---------- = 3.9 hp E 0.80
Twist drills are generally the most highly stressed of all metal cutting tools. They must not only resist the cutting forces on the lips, but also the drill torque resulting from these forces and the very large thrust force required to push the drill through the hole. Therefore, often when drilling smaller holes, the twist drill places a limit on the power used and for very large holes, the machine may limit the power.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1093
MACHINING ECONOMETRICS Tool Wear And Tool Life Relationships Tool wear.—Tool-life is defined as the cutting time to reach a predetermined wear, called the tool wear criterion. The size of tool wear criterion depends on the grade used, usually a tougher grade can be used at bigger flank wear. For finishing operations, where close tolerances are required, the wear criterion is relatively small. Other alternative wear criteria are a predetermined value of the surface roughness, or a given depth of the crater which develops on the rake face of the tool. The most appropriate wear criteria depends on cutting geometry, grade, and materials. Tool-life is determined by assessing the time — the tool-life — at which a given predetermined flank wear is reached, 0.25, 0.4, 0.6, 0.8 mm etc. Fig. 1 depicts how flank wear varies with cutting time (approximately straight lines in a semi-logarithmic graph) for three combinations of cutting speeds and feeds. Alternatively, these curves may represent how variations of machinability impact on tool-life, when cutting speed and feed are constant. All tool wear curves will sooner or later bend upwards abruptly and the cutting edge will break, i.e., catastrophic failure as indicated by the white arrows in Fig. 1. LIVE GRAPH Click here to view
1
Wear, mm
Average
0.1
Low Average High
0.01 0
10
20
30
40
50
60
70
80
90
100 110 120 130 140 150
Cutting Time, minutes
Fig. 1. Flank Wear as a Function of Cutting Time
The maximum deviation from the average tool-life 60 minutes in Fig. 1 is assumed to range between 40 and 95 minutes, i.e. −33% and +58% variation. The positive deviation from the average (longer than expected tool-life) is not important, but the negative one (shorter life) is, as the edge may break before the scheduled tool change after 60 minutes, when the flank wear is 0.6 mm. It is therefore important to set the wear criterion at a safe level such that tool failures due to “normal” wear become negligible. This is the way machinability variations are mastered. Equivalent Chip Thickness (ECT).—ECT combines the four basic turning variables, depth of cut, lead angle, nose radius and feed per revolution into one basic parameter. For all other metal cutting operations such as drilling, milling and grinding, additional variables such as number of teeth, width of cut, and cutter diameter are included in the parameter ECT. In turning, milling, and drilling, according to the ECT principle, when the product of feed times depth of cut is constant the tool-life is constant no matter how the depth of cut or feed is selected, provided that the cutting speed and cutting edge length are maintained constant. By replacing the geometric parameters with ECT, the number of toollife tests to evaluate cutting parameters can be reduced considerably, by a factor of 4 in turning, and in milling by a factor of 7 because radial depth of cut, cutter diameter and number of teeth are additional parameters.
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Machinery's Handbook 27th Edition 1094
MACHINING ECONOMETRICS
The introduction of the ECT concept constitutes a major simplification when predicting tool-life and calculating cutting forces, torque, and power. ECT was first presented in 1931 by Professor R. Woxen, who both theoretically and experimentally proved that ECT is a basic metal cutting parameter for high-speed cutting tools. Dr. Colding later proved that the concept also holds for carbide tools, and extended the calculation of ECT to be valid for cutting conditions when the depth of cut is smaller than the tool nose radius, or for round inserts. Colding later extended the concept to all other metal cutting operations, including the grinding process. The definition of ECT is: ECT = Area ------------- (mm or inch) CEL A = cross sectional area of cut (approximately = feed × depth of cut), (mm2 or inch2) CEL = cutting edge length (tool contact rubbing length), (mm or inch), see Fig.9. An exact value of A is obtained by the product of ECT and CEL. In turning, milling, and drilling, ECT varies between 0.05 and 1 mm, and is always less than the feed/rev or feed/tooth; its value is usually about 0.7 to 0.9 times the feed.
where
Example 1:For a feed of 0.8 mm/rev, depth of cut a = 3 mm, and a cutting edge length CEL = 4 mm2, the value of ECT is approximately ECT = 0.8 × 3 ÷ 4 = 0.6 mm. The product of ECT, CEL, and cutting speed V (m/min or ft/min) is equal to the metal removal rate, MRR, which is measured in terms of the volume of chips removed per minute: MRR = 1000V × Area = 1000V × ECT × CEL mm 3 /min = V × Area cm 3 /min or inch 3 /min The specific metal removal rate SMRR is the metal removal rate per mm cutting edge length CEL, thus: SMMR = 1000V × ECT mm 3 /min/mm = V × ECT cm 3 /min/mm or inch 3 /min/inch Example 2:Using above data and a cutting speed of V = 250 m/min specific metal removal rate becomes SMRR = 0.6 × 250 = 150 (cm3/min/mm). ECT in Grinding: In grinding ECT is defined as in the other metal cutting processes, and is approximately equal to ECT = Vw × ar ÷ V, where Vw is the work speed, ar is the depth of cut, and A = Vw × ar. Wheel life is constant no matter how depth ar, or work speed Vw, is selected at V = constant (usually the influence of grinding contact width can be neglected). This translates into the same wheel life as long as the specific metal removal rate is constant, thus: SMMR = 1000Vw × ar mm 3 /min/mm In grinding, ECT is much smaller than in the other cutting processes, ranging from about 0.0001 to 0.001 mm (0.000004 to 0.00004 inch). The grinding process is described in a separate chapter GRINDING FEEDS AND SPEEDS starting on page 1158. Tool-life Relationships.—Plotting the cutting times to reach predetermined values of wear typically results in curves similar to those shown in Fig. 2 (cutting time versus cutting speed at constant feed per tooth) and Fig. 3 (cutting time versus feed per tooth at constant cutting speed). These tests were run in 1993 with mixed ceramics turn-milling hard steel, 82 RC, at the Technische Hochschule Darmstadt.
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS LIVE GRAPH
1095
LIVE GRAPH
Click here to view
Click here to view
40
40
VB = 0.15 mm VB = 0.2 mm VB = 0.1 mm VB = 0.05 mm 30
LF (tool life travel ), mm
LF (tool life travel ), mm
30
20
20
10
10 VB 0.05 mm VB 0.1 mm VB 0.15 mm
0
0 0
0.05
0.1
0.15
0.2
Fz (feed per tooth), mm
Fig. 2. Influence of feed per tooth on cutting time
200
250
300
350
400
450
500
VC (cutting speed), m/min
Fig. 3. Influence of cutting speed on tool-life
Tool-life has a maximum value at a particular setting of feed and speed. Economic and productive cutting speeds always occur on the right side of the curves in Figs. 2 and 4, which are called Taylor curves, represented by the so called Taylor’s equation. The variation of tool-life with feed and speed constitute complicated relationships, illustrated in Figs. 6a, 6b, and 6c. Taylor’s Equation.—Taylor’s equation is the most commonly used relationship between tool-life T, and cutting speed V. It constitutes a straight line in a log-log plot, one line for each feed, nose radius, lead angle, or depth of cut, mathematically represented by: V × Tn = C (1a) where n = is the slope of the line C =is a constant equal to the cutting speed for T = 1 minute By transforming the equation to logarithmic axes, the Taylor lines become straight lines with slope = n. The constant C is the cutting speed on the horizontal (V) axis at tool-life T = 1 minute, expressed as follows lnV + n × lnT = lnC (1b) For different values of feed or ECT, log-log plots of Equation (1a) form approximately straight lines in which the slope decreases slightly with a larger value of feed or ECT. In practice, the Taylor lines are usually drawn parallel to each other, i.e., the slope n is assumed to be constant. Fig. 4 illustrates the Taylor equation, tool-life T versus cutting speed V, plotted in log-log coordinates, for four values of ECT = 0.1, 0.25, 0.5 and 0.7 mm. In Fig. 4, starting from the right, each T–V line forms a generally straight line that bends off and reaches its maximum tool-life, then drops off with decreasing speed (see also Figs. 2 and 3. When operating at short tool-lives, approximately when T is less than 5 minutes, each line bends a little so that the cutting speed for 1 minute life becomes less than the value calculated by constant C. The Taylor equation is a very good approximation of the right hand side of the real toollife curve (slightly bent). The portion of the curve to the left of the maximum tool-life gives shorter and shorter tool-lives when decreasing the cutting speed starting from the point of maximum tool-life. Operating at the maximum point of maximum tool-life, or to the left of it, causes poor surface finish, high cutting forces, and sometimes vibrations.
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Machinery's Handbook 27th Edition 1096
MACHINING ECONOMETRICS LIVE GRAPH Click here to view
100
Tmax
ECT = 0.1 ECT = 0.25 ECT = 0.5 ECT = 0.7
T minutes
T2,V2 b
10
n = a/b a
T1,V1
1 10
100
C
1000
V m/min
Fig. 4. Definition of slope n and constant C in Taylor’s equation
Evaluation of Slope n, and Constant C.—When evaluating the value of the Taylor slope based on wear tests, care must be taken in selecting the tool-life range over which the slope is measured, as the lines are slightly curved. The slope n can be found in three ways: • Calculate n from the formula n = (ln C - ln V)/ln T, reading the values of C and V for any value of T in the graph. • Alternatively, using two points on the line, (V1, T1) and (V2, T2), calculate n using the relationship V1 × T1n = V2 × T2n. Then, solving for n, ln ( V 1 ⁄ V 2 ) n = ------------------------ln ( T 2 ⁄ T 1 )
•
Graphically, n may be determined from the graph by measuring the distances “a” and “b” using a mm scale, and n is the ratio of a and b, thus, n = a/b
Example:Using Fig. 4, and a given value of ECT= 0.7 mm, calculate the slope and constant of the Taylor line. On the Taylor line for ECT= 0.7, locate points corresponding to tool-lives T1 = 15 minutes and T2 = 60 minutes. Read off the associated cutting speeds as, approximately, V1 = 110 m/min and V2 = 65 m/min. The slope n is then found to be n = ln (110/65)/ln (60/15) = 0.38 The constant C can be then determined using the Taylor equation and either point (T1, V1) or point (T2, V2), with equivalent results, as follows: C = V × Tn = 110 × 150.38 = 65 × 600.38 = 308 m/min (1027 fpm) The Generalized Taylor Equation.—The above calculated slope and constant C define tool-life at one particular value of feed f, depth of cut a, lead angle LA, nose radius r, and other relevant factors. The generalized Taylor equation includes these parameters and is written T n = A × f m × a p × LA q × r s
(2)
where A = area; and, n, m, p, q, and s = constants. There are two problems with the generalized equation: 1) a great number of tests have to be run in order to establish the constants n, m, p, q, s, etc.; and 2) the accuracy is not very good because Equation (2) yields straight lines when plotted versus f, a, LA, and r, when in reality, they are parabolic curves..
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1097
The Generalized Taylor Equation using Equivalent Chip Thickness (ECT): Due to the compression of the aforementioned geometrical variables (f, a, LA, r, etc.) into ECT, Equation (2) can now be rewritten: V × T n = A × ECT m (3) Experimental data confirms that the Equation (3) holds, approximately, within the range of the test data, but as soon as the equation is extended beyond the test results, the error can become very great because the V–ECT curves are represented as straight lines by Equation (3)and the real curves have a parabolic shape. The Colding Tool-life Relationship.—This relationship contains 5 constants H, K, L, M, and N0, which attain different values depending on tool grade, work material, and the type of operation, such as longitudinal turning versus grooving, face milling versus end milling, etc. This tool-life relationship is proven to describe, with reasonable accuracy, how tool-life varies with ECT and cutting speed for any metal cutting and grinding operation. It is expressed mathematically as follows either as a generalized Taylor equation (4a), or, in logarithmic coordinates (4b): V×T
( N 0 – L × lnECT )
× ECT
H- + lnECT ⎛ – -----------------------⎞ ⎝ 2M 4M ⎠
= e
H-⎞ ⎛ K – ------⎝ 4M⎠
(4a)
– H- – z ( N – L ) y = K – x-----------(4b) 0 x 4M where x =ln ECT y =ln V z =ln T M = the vertical distance between the maximum point of cutting speed (ECTH, VH) for T = 1 minute and the speed VG at point (ECTG, VG), as shown in Fig. 5. 2M = the horizontal distance between point (ECTH, VG) and point (VG, ECTG) H and K = the logarithms of the coordinates of the maximum speed point (ECTH, VH) at tool-life T = 1 minute, thus H = ln(ECTH) and K = ln (VH) N0 and L = the variation of the Taylor slope n with ECT: n = N0 − L × ln (ECT) LIVE GRAPH Click here to view
1000 H-CURVE
VH
G-CURVE
K = ln(VH) M 2M
V, m/min
VG
100
Constants N0 and L define the change in the Taylor slope, n, with ECT
10 0.01
T=1 T = 100 T = 300
H = ln(ECTH)
ECTH 0.1
ECTG
1
ECT, mm
Fig. 5. Definitions of the constants H, K, L, M, and N0 for tool-life equation in the V-ECT plane with tool-life constant
The constants L and N0 are determined from the slopes n1 and n2 of two Taylor lines at ECT1 and ECT2, and the constant M from 3 V–ECT values at any constant tool-life. Constants H and K are then solved using the tool-life equation with the above-calculated values of L, N0 and M.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1098
MACHINING ECONOMETRICS
The G- and H-curves.—The G-curve defines the longest possible tool-life for any given metal removal rate, MRR, or specific metal removal rate, SMRR. It also defines the point where the total machining cost is minimum, after the economic tool-life TE, or optimal tool-life TO, has been calculated, see Optimization Models, Economic Tool-life when Feed is Constant starting on page 1110. The tool-life relationship is depicted in the 3 planes: T–V, where ECT is the plotted parameter (the Taylor plane); T–ECT, where V is plotted; and, V–ECT, where T is a parameter. The latter plane is the most useful because the optimal cutting conditions are more readily understood when viewing in the V–ECT plane. Figs. 6a, 6b, and 6c show how the tool-life curves look in these 3 planes in log-log coordinates. LIVE GRAPH Click here to view
T minutes
100
10
ECT = 0.1 ECT = 0.25 ECT = 0.5 ECT = 0.7
1 10
100
1000
V m/min
Fig. 6a. Tool-life vs. cutting sped T–V, ECT plotted
Fig. 6a shows the Taylor lines, and Fig. 6b illustrates how tool-life varies with ECT at different values of cutting speed, and shows the H-curve. Fig. 6c illustrates how cutting speed varies with ECT at different values of tool-life. The H- and G-curves are also drawn in Fig. 6c. LIVE GRAPH Click here to view
10000 V = 100 V = 150 V = 225 V = 250 V = 300
T minutes
1000
100
10
1 0.01
H-CURVE
0.1
1
ECT, mm
Fig. 6b. Tool-life vs. ECT, T–ECT, cutting speed plotted
A simple and practical method to ascertain that machining is not done to the left of the Hcurve is to examine the chips. When ECT is too small, about 0.03-0.05 mm, the chips tend to become irregular and show up more or less as dust.
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1099
LIVE GRAPH Click here to view
1000
H-CURVE
V, m/min
G-CURVE
100
T=1 T=5 T = 15 T = 30 T = 60 T = 100 T = 300 10 0.01
0.1
1
ECT, mm
Fig. 6c. Cutting speed vs. ECT, V–ECT, tool-life plotted
The V–ECT–T Graph and the Tool-life Envelope.— The tool-life envelope, in Fig. 7, is an area laid over the V–ECT–T graph, bounded by the points A, B, C, D, and E, within which successful cutting can be realized. The H- and G-curves represent two borders, lines AE and BC. The border curve, line AB, shows a lower limit of tool-life, TMIN = 5 minutes, and border curve, line DE, represents a maximum tool-life, TMAX = 300 minutes. TMIN is usually 5 minutes due to the fact that tool-life versus cutting speed does not follow a straight line for short tool-lives; it decreases sharply towards one minute tool-life. TMAX varies with tool grade, material, speed and ECT from 300 minutes for some carbide tools to 10000 minutes for diamond tools or diamond grinding wheels, although systematic studies of maximum tool-lives have not been conducted. Sometimes the metal cutting system cannot utilize the maximum values of the V–ECT–T envelope, that is, cutting at optimum V–ECT values along the G-curve, due to machine power or fixture constraints, or vibrations. Maximum ECT values, ECTMAX, are related to the strength of the tool material and the tool geometry, and depend on the tool grade and material selection, and require a relatively large nose radius. LIVE GRAPH Click here to view
V, m/min
1000
T=1 T=5 T = 15 T = 30 T = 60 T = 100 T = 300
H-curve
Big Radius To Avoid Breakage
A
A'
G-curve OF
Tool Breaks
B E'
100 0.01
E OR
Tmax
0.1
D
C
1
ECT, mm Fig. 7. Cutting speed vs. ECT, V–ECT, tool-life plotted
Minimum ECT values, ECTMIN, are defined by the conditions at which surface finish suddenly deteriorates and the cutting edge begins rubbing rather than cutting. These conditions begin left of the H-curve, and are often accompanied by vibrations and built-up edges on the tool. If feed or ECT is reduced still further, excessive tool wear with sparks and tool breakage, or melting of the edge occurs. For this reason, values of ECT lower than approx-
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1100
MACHINING ECONOMETRICS
imately 0.03 mm should not be allowed. In Fig. 7, the ECTMIN boundary is indicated by contour line A′E′. In milling the minimum feed/tooth depends on the ratio ar/D, of radial depth of cut ar, and cutter diameter D. For small ar/D ratios, the chip thickness becomes so small that it is necessary to compensate by increasing the feed/tooth. See High-speed Machining Econometrics starting on page 1122 for more on this topic. Fig. 7 demonstrates, in principle, minimum cost conditions for roughing at point OR, and for finishing at point OF, where surface finish or tolerances have set a limit. Maintaining the speed at OR, 125 m/min, and decreasing feed reaches a maximum tool-life = 300 minutes at ECT = 0.2, and a further decrease of feed will result in shorter lives. Similarly, starting at point X (V = 150, ECT = 0.5, T = 15) and reducing feed, the H-curve will be reached at point E (ECT = 0.075, T = 300). Continuing to the left, tool-life will decrease and serious troubles occur at point E′ (ECT = 0.03). Starting at point OF (V = 300, ECT = 0.2, T = 15) and reducing feed the H-curve will be reached at point E (ECT = 0.08, T = 15). Continuing to the left, life will decrease and serious troubles occur at ECT = 0.03. Starting at point X (V = 400, ECT = 0.2, T = 5) and reducing feed the H-curve will be reached at point E (ECT = 0.09, T = 7). Continuing to the left, life will decrease and serious troubles occur at point A′ (ECT =0.03), where T = 1 minute. Cutting Forces and Chip Flow Angle.—There are three cutting forces, illustrated in Fig. 8, that are associated with the cutting edge with its nose radius r, depth of cut a, lead angle LA, and feed per revolution f, or in milling feed per tooth fz. There is one drawing for roughing and one for finishing operations.
Roughing: f -2 S
a ≥ r (1 – sin (LA)) feed x
Finishing: ECT
a–x
CEL LA(U.S.)
O
b F R FH FA
CFA
–x⎞ CFA = 90 – atan ⎛⎝-a------FR b⎠ Axial Force = FA = FH cos(CFA) Radial Force = FR = FH sin(CFA)
s
x a–x
u r–a
r CFA
LA(U.S.) z = 90 – CFA f b = --- + r cos (LA) + 2 tan (LA)(a – r sin(LA))
z
f/ 2
r(1 – sin(LA)) a O
r a
c
a < r (1 – sin(LA))
FH FA
u= 90 – CFA
2 x = r – r2 – ---f4 f c = --- + r – (r – a)2 2 –x⎞ CFA = 90 – atan ⎛⎝-a---c---⎠
ISO LA = 90 – LA (U.S.)
Fig. 8. Definitions of equivalent chip thickness, ECT, and chip flow angle, CFA.
The cutting force FC, or tangential force, is perpendicular to the paper plane. The other two forces are the feed or axial force FA, and the radial force FR directed towards the work piece. The resultant of FA and FR is called FH. When finishing, FR is bigger than FA, while in roughing FA is usually bigger than FR. The direction of FH, measured by the chip flow angle CFA, is perpendicular to the rectangle formed by the cutting edge length CEL and ECT (the product of ECT and CEL constitutes the cross sectional area of cut, A). The important task of determining the direction of FH, and calculation of FA and FR, are shown in the formulas given in the Fig. 8. The method for calculating the magnitudes of FH, FA, and FR is described in the following. The first thing is to determine the value of the cutting force FC. Approximate formulas
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1101
to calculate the tangential cutting force, torque and required machining power are found in the section ESTIMATING SPEEDS AND MACHINING POWER starting on page 1082. Specific Cutting Force, Kc: The specific cutting force, or the specific energy to cut, Kc, is defined as the ratio between the cutting force FC and the chip cross sectional area, A. thus, Kc = FC ÷ A N/mm2. The value of Kc decreases when ECT increases, and when the cutting speed V increases. Usually, Kc is written in terms of its value at ECT = 1, called Kc1, and neglecting the effect of cutting speed, thus Kc = Kc1 × ECT B, where B = slope in log-log coordinates LIVE GRAPH Click here to view
10000
V = 300 V = 250
Kc N/mm2
V = 200
1000 0.01
0.1
1
ECT, mm
Fig. 9. Kc vs. ECT, cutting speed plotted
A more accurate relationship is illustrated in Fig. 9, where Kc is plotted versus ECT at 3 different cutting speeds. In Fig. 9, the two dashed lines represent the aforementioned equation, which each have different slopes, B. For the middle value of cutting speed, Kc varies with ECT from about 1900 to 1300 N/mm2 when ECT increases from 0.1 to 0.7 mm. Generally the speed effect on the magnitude of Kc is approximately 5 to 15 percent when using economic speeds. LIVE GRAPH Click here to view
FH/FC
1
V=300
V=250 V=200
0.1 0.01
0.1
1
ECT, mm
Fig. 10. FH /FC vs. ECT, cutting speed plotted
Determination of Axial, FA, and Radial, FR, Forces: This is done by first determining the resultant force FH and then calculating FA and FR using the Fig. 8 formulas. FH is derived
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1102
MACHINING ECONOMETRICS
from the ratio FH /FC, which varies with ECT and speed in a fashion similar to Kc. Fig. 10 shows how this relationship may vary. As seen in Fig. 10, FH/FC is in the range 0.3 to 0.6 when ECT varies from 0.1 to 1 mm, and speed varies from 200 to 250 m/min using modern insert designs and grades. Hence, using reasonable large feeds FH/FC is around 0.3 – 0.4 and when finishing about 0.5 – 0.6. Example:Determine FA and FR, based on the chip flow angle CFA and the cutting force FC, in turning. Using a value of Kc = 1500 N/mm2 for roughing, when ECT = 0.4, and the cutting edge length CEL = 5 mm, first calculate the area A = 0.4 × 5 = 2 mm2. Then, determine the cutting force FC = 2 × 1500 = 3000 Newton, and an approximate value of FH = 0.5 × 3000 = 1500 Newton. Using a value of Kc = 1700 N/mm2 for finishing, when ECT = 0.2, and the cutting edge length CEL = 2 mm, calculate the area A = 0.2 × 2 = 0.4 mm2. The cutting force FC = 0.4 × 1700 = 680 Newton and an approximate value of FH = 0.35 × 680 = 238 Newton. Fig. 8 can be used to estimate CFA for rough and finish turning. When the lead angle LA is 15 degrees and the nose radius is relatively large, an estimated value of the chip flow angle becomes about 30 degrees when roughing, and about 60 degrees in finishing. Using the formulas for FA and FR relative to FH gives: Roughing: FA = FH × cos (CFA) = 1500 × cos 30 = 1299 Newton FR = FH × sin (CFA) = 1500 × sin 30 = 750 Newton Finishing: FA = FH × cos (CFA) = 238 × cos 60 = 119 Newton FR = FH × sin (CFA) = 238 × sin 60 = 206 Newton The force ratio FH/FC also varies with the tool rake angle and increases with negative rakes. In grinding, FH is much larger than the grinding cutting force FC; generally FH/FC is approximately 2 to 4, because grinding grits have negative rakes of the order –35 to –45 degrees. Forces and Tool-life.—Forces and tool life are closely linked. The ratio FH/FC is of particular interest because of the unique relationship of FH/FC with tool-life. LIVE GRAPH Click here to view
1.8 1.6
H-CURVE
1.4
FH/FC
1.2 1 0.8 0.6 0.4 0.2 0 0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
ECT, mm
Fig. 11a. FH /FC vs. ECT
The results of extensive tests at Ford Motor Company are shown in Figs. 11a and 11b, where FH/FC and tool-life T are plotted versus ECT at different values of cutting speed V.
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1103
For any constant speed, tool-life has a maximum at approximately the same values of ECT as has the function FH/FC. LIVE GRAPH Click here to view
1000
H-CURVE
T, min
100
10
1
0.1 0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
ECT, mm
Fig. 11b. Tool-life vs. ECT
The Force Relationship: Similar tests performed elsewhere confirm that the FH/FC function can be determined using the 5 tool-life constants (H, K, M, L, N0) introduced previously, and a new constant (LF/L). ( x – H )2 K – y – -------------------1- ⋅ F 4M H⎞ ln ⎛ ------- = -------------------------------------⎝a F ⎠ LF C ------ ( N 0 – Lx ) L
(5)
The constant a depends on the rake angle; in turning a is approximately 0.25 to 0.5 and LF/L is 10 to 20. FC attains it maximum values versus ECT along the H-curve, when the tool-life equation has maxima, and the relationships in the three force ratio planes look very similar to the tool-life functions shown in the tool-life planes in Figs. 6a, 6b, and 6c. LIVE GRAPH Click here to view
1000 LF/L = 5
LF/L = 10
T , minutes
LF/L = 20 100
10
1 0.1
1
FH/FC
Fig. 12. Tool-life vs. FH/FC
Tool-life varies with FH/FC with a simple formula according to Equation (5) as follows:
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1104
MACHINING ECONOMETRICS LF
F H ⎞ ----T = ⎛ --------- L ⎝ aF ⎠ C
where L is the constant in the tool-life equation, Equation (4a) or (4b), and LF is the corresponding constant in the force ratio equation, Equation (5). In Fig. 12 this function is plotted for a = 0.5 and for LF/L = 5, 10, and 20. Accurate calculations of aforementioned relationships require elaborate laboratory tests, or better, the design of a special test and follow-up program for parts running in the ordinary production. A software machining program, such as Colding International Corp. COMP program can be used to generate the values of all 3 forces, torque and power requirements both for sharp and worn tools Surface Finish Ra and Tool-life.—It is well known that the surface finish in turning decreases with a bigger tool nose radius and increases with feed; usually it is assumed that Ra increases with the square of the feed per revolution, and decreases inversely with increasing size of the nose radius. This formula, derived from simple geometry, gives rise to great errors. In reality, the relationship is more complicated because the tool geometry must taken into account, and the work material and the cutting conditions also have a significant influence. LIVE GRAPH Click here to view
Ra, mm
10
V = 475 V = 320 V = 234 V = 171 V = 168 V = 144 V = 120
1
0.1 0.001
0.01
0.1
1
ECT, mm
Fig. 13. Ra vs. ECT, nose radius r constant
Fig. 13 shows surface finish Ra versus ECT at various cutting speeds for turning cast iron with carbide tools and a nose radius r = 1.2 mm. Increasing the cutting speed leads to a smaller Ra value. Fig. 14 shows how the finish improves when the tool nose radius, r, increases at a constant cutting speed (168 m/min) in cutting nodular cast iron. In Fig. 15, Ra is plotted versus ECT with cutting speed V for turning a 4310 steel with carbide tools, for a nose radius r = 1.2 mm, illustrating that increasing the speed also leads to a smaller Ra value for steel machining. A simple rule of thumb for the effect of increasing nose radius r on decreasing surface finish Ra, regardless of the ranges of ECT or speeds used, albeit within common practical values, is as follows. In finishing, R a1 r 0.5 (6) -------- = ⎛ ----2⎞ ⎝r ⎠ R a2
1
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS LIVE GRAPH
1105
LIVE GRAPH
Click here to view
Click here to view
10
5 4.5 4 3.5
Ra
Ra
3 2.5
1 V = 260
2 1.5
V = 215
V = 170, r = 0.8 V = 170, r = 1.2 V = 170, r = 1.6
1
V = 175
0.5 0.1
0 0
0.05
0.1
0.15
0.2
0.01
0.25
0.1
1
ECT, mm
ECT
Fig. 14. Ra vs. ECT cutting speed constant, nose radius r varies
Fig. 15. Ra vs. ECT, cutting speed and nose radius r constant
In roughing, multiply the finishing values found using Equation (6) by 1.5, thus, Ra (Rough) = 1.5 × Ra (Finish) for each ECT and speed. Example 1:Find the decrease in surface roughness resulting from a tool nose radius change from r = 0.8 mm to r =1.6 mm in finishing. Also, find the comparable effect in roughing. For finishing, using r2 =1.6 and r1 = 0.8, Ra1/Ra2 = (1.6/0.8) 0.5 = 1.414, thus, the surface roughness using the larger tool radius is Ra2 = Ra1 ÷ 1.414 = 0.7Ra1 In roughing, at the same ECT and speed, Ra = 1.5 × Ra2 =1.5 × 0.7Ra1 = 1.05Ra1 Example 2:Find the decrease in surface roughness resulting from a tool nose radius change from r = 0.8 mm to r =1.2 mm For finishing, using r2 =1.2 and r1 = 0.8, Ra1/Ra2 = (1.2/0.8) 0.5 = 1.224, thus, the surface roughness using the larger tool radius is Ra2 = Ra1 ÷ 1.224 = 0.82Ra1 In roughing, at the same ECT and speed, Ra = 1.5 × Ra2 =1.5 × 0.82Ra1 = 1.23Ra1 It is interesting to note that, at a given ECT, the Ra curves have a minimum, see Figs. 13 and 15, while tool-life shows a maximum, see Figs. 6b and 6c. As illustrated in Fig. 16, Ra increases with tool-life T when ECT is constant, in principle in the same way as does the force ratio. LIVE GRAPH Click here to view
Ra
10
1
ECT = 0.03 ECT = 0.08 ECT = 0.12 ECT = 0.18 ECT = 0.30 0.1 1
10
100
1000
T, min.
Fig. 16. Ra vs. T, holding ECT constant
The Surface Finish Relationship: Ra is determined using the same type of mathematical relationship as for tool-life and force calculations: x – H Ra 2 y = K Ra – -------------------- – ( N 0Ra – L Ra )ln ( R a ) 4M Ra
where KRA, HRA, MRA, NORA, and LRA are the 5 surface finish constants.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1106
MACHINING ECONOMETRICS
Shape of Tool-life Relationships for Turning, Milling, Drilling and Grinding Operations—Overview.—A summary of the general shapes of tool-life curves (V–ECT–T graphs) for the most common machining processes, including grinding, is shown in double logarithmic coordinates in Fig. 17a through Fig. 17h. LIVE GRAPH
LIVE GRAPH
Click here to view
Click here to view
1000
V, m/min
V, m/min.
1000
100
100
Tool-life, T (minutes) T = 15
Tool-life (minutes)
T = 45
T = 15 T = 45
T =120
T = 120 10 0.01
0.1
10 0.01
1
0.1
1
ECT, mm
ECT, mm
Fig. 17a. Tool-life for turning cast iron using coated carbide
Fig. 17b. Tool-life for turning low-alloy steel using coated carbide
LIVE GRAPH
LIVE GRAPH
Click here to view
Click here to view
1000
1000
T = 15
Tool-life (minutes) T = 15
T = 45 T = 120
T = 45 T = 120
100
V, m/min
V, m/min.
100
10
10
1 1 0.01
0.1
ECT, mm
1
0.01
0.1
1
ECT, mm
Fig. 17c. Tool-life for end-milling AISI 4140 steel Fig. 17d. Tool-life for end-milling low-allow steel using high-speed steel using uncoated carbide
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS LIVE GRAPH
1107
LIVE GRAPH
Click here to view
Click here to view
1000
1000
V,m/min.
V, m/min
100
10
T = 45 T = 15
T = 120
T = 45
T = 15
T = 120 100
1 0.01
0.1
1
ECT, mm
Fig. 17e. Tool-life for end-milling low-alloy steel using coated carbide
0.1
0.01
1
Fig. 17f. Tool-life for face-milling SAE 1045 steel using coated carbide
LIVE GRAPH
LIVE GRAPH
Click here to view
Click here to view
1000
10000
T = 15 T = 45 T = 120
V, m/min.
V m/min
100
1000
10
T = 30 T = 10 T=1 100
1
0.00001 0.01
0.1
ECT, mm
Fig. 17g. Tool-life for solid carbide drill
1
0.0001
0.001
ECT, mm
Fig. 17h. Wheel-life in grinding M4 tool-steel
Calculation Of Optimized Values Of Tool-life, Feed And Cutting Speed Minimum Cost.—Global optimum is defined as the absolute minimum cost considering all alternative speeds, feeds and tool-lives, and refers to the determination of optimum tool-life TO, feed fO, and cutting speed VO, for either minimum cost or maximum production rate. When using the tool-life equation, T = f (V, ECT), determine the corresponding feed, for given values of depth of cut and operation geometry, from optimum equivalent chip thickness, ECTO. Mathematically the task is to determine minimum cost, employing the cost function CTOT = cost of machining time + tool changing cost + tooling cost. Minimum cost optima occur along the so-called G-curve, identified in Fig. 6c. Another important factor when optimizing cutting conditions involves choosing the proper cost values for cost per edge CE, replacement time per edge TRPL, and not least, the hourly rate HR that should be applied. HR is defined as the portion of the hourly shop rate that is applied to the operations and machines in question. If optimizing all operations in the portion of the shop for which HR is calculated, use the full rate; if only one machine is involved, apply a lower rate, as only a portion of the general overhead rate should be used, otherwise the optimum, and anticipated savings, are erroneous.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1108
MACHINING ECONOMETRICS
Production Rate.—The production rate is defined as the cutting time or the metal removal rate, corrected for the time required for tool changes, but neglecting the cost of tools. The result of optimizing production rate is a shorter tool-life, higher cutting speed, and a higher feed compared to minimum cost optimization, and the tooling cost is considerably higher. Production rates optima also occur along the G-curve. The Cost Function.—There are a number of ways the total machining cost CTOT can be plotted, for example, versus feed, ECT, tool-life, cutting speed or other parameter. In Fig. 18a, cost for a face milling operation is plotted versus cutting time, holding feed constant, and using a range of tool-lives, T, varying from 1 to 240 minutes. LIVE GRAPH
CTOOL
CTOT
5.85 6.91 7.47 8.30 8.83
0.487 0.192 0.125 0.069 0.049
9.81 10.91 11.60 12.12 13.47
Click here to view
0.569 0.288 0.228 0.185 0.172
T 1 3 5 10 15
V 598 506 468 421 396
0.027
0.164
30
356
0.015 0.011 0.008 0.005
0.167 60 321 0.172 90 302 0.177 120 289 0.192 240 260
0.3 CTOT
T varies
CTOOL T varies 0.25
Total Cost
Cost of Face Milling Operation, $
Minimum cost
tc
0.2
Cost of Cutting Time
0.15
Hourly Rate = 60$/hour
0.1
0.05
Tooling Cost 0 5
7
9
11
13
15
Cutting Time, secsonds
Fig. 18a. Variation of tooling cost CTOOL, and total cost CC, with cutting time tc, including minimum cost cutting time
The tabulated values show the corresponding cutting speeds determined from the toollife equation, and the influence of tooling on total cost. Tooling cost, CTOOL = sum of tool cost + cost of replacing worn tools, decreases the longer the cutting time, while the total cost, CTOT, has a minimum at around 10 seconds of cutting time. The dashed line in the graph represents the cost of machining time: the product of hourly rate HR, and the cutting time tc divided by 60. The slope of the line defines the value of HR. 0.5 CTOT 1 Tool CTOT 2 Tools
0.45 0.4
CTOT 4 Tools
Cost, $
0.35 0.3 0.25 0.2 0.15 0.1 0.05 0 5
6
7
8
9
10
11
12
13
14
15
Cutting time, seconds
Fig. 18b. Total cost vs. cutting time for simultaneously cutting with 1, 2, and 4 tools
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1109
The cutting time for minimum cost varies with the ratio of tooling cost and HR. Minimum cost moves towards a longer cutting time (longer tool-life) when either the price of the tooling increases, or when several tools cut simultaneously on the same part. In Fig. 18b, this is exemplified by running 2 and 4 cutters simultaneously on the same work piece, at the same feed and depth of cut, and with a similar tool as in Fig. 18a. As the tooling cost goes up 2 and 4 times, respectively, and HR is the same, the total costs curves move up, but also moves to the right, as do the points of minimum cost and optimal cutting times. This means that going somewhat slower, with more simultaneously cutting tools, is advantageous. Global Optimum.—Usually, global optimum occurs for large values of feed, heavy roughing, and in many cases the cutting edge will break trying to apply the large feeds required. Therefore, true optima cannot generally be achieved when roughing, in particular when using coated and wear resistant grades; instead, use the maximum values of feed, ECTmax, along the tool-life envelope, see Fig. 7. As will be shown in the following, the first step is to determine the optimal tool-life TO, and then determine the optimum values of feeds and speeds. Optimum Tool-life TO = 22 minutes V22
tc, sec.
CTOOL
CTOT
0.03 0.08 0.10 0.17 0.20 0.40 0.60 0.70
416 397 374 301 276 171 119 91
28.067 11.017 9.357 6.831 6.334 5.117 4.903 4.924
0.1067 0.0419 0.0356 0.0260 0.0241 0.0194 0.0186 0.0187
0.4965 0.1949 0.1655 0.1208 0.1120 0.0905 0.0867 0.0871
Maximum Production Rate, T = 5 minutes V5 tc CTOOL CTOT fz 0.7
163
3.569
0.059
0.109
T Varies between 1 and 240 minutes fz = 0.10
Minimum Cost
ECT= 0.26
CTOOL T = 22 CTOT T = 22
CTOOL T varies CTOT T varies
0.5
0.45
0.4
0.35
0.3
0.25
0.2
0.15
0.1
0.05
tc secs. CTOOL
CTOT
T
V
0.487 0.192 0.125 0.069 0.049 0.027 0.015 0.011 0.008 0.005
0.569 0.288 0.228 0.185 0.172 0.164 0.167 0.172 0.177 0.192
1 3 5 10 15 30 60 90 120 240
598 506 468 421 396 357 321 302 289 260
5.850 6.914 7.473 8.304 8.832 9.815 10.906 11.600 12.119 13.467
0.6
0.55
Cost, $
Minimum Cost
fz
0 0
5
10
15
20
25
30
Cutting Time, seconds
Fig. 19. Variation of tooling and total cost with cutting time, comparing global optimum with minimum cost at fz = 0.1 mm
The example in Fig. 19 assumes that TO = 22 minutes and the feed and speed optima were calculated as fO = 0.6 mm/tooth, VO = 119 m/min, and cutting time tcO = 4.9 secs. The point of maximum production rate corresponds to fO = 0.7 mm/tooth, VO = 163 m/min, at tool-life TO =5 minutes, and cutting time tcO = 3.6 secs. The tooling cost is approximately 3 times higher than at minimum cost (0.059 versus 0.0186), while the piece cost is only slightly higher: $0.109 versus $0.087. When comparing the global optimum cost with the minimum at feed = 0.1 mm/tooth the graph shows it to be less than half (0.087 versus 0.164), but also the tooling cost is about 1/3 lower (0.0186 versus 0.027). The reason why tooling cost is lower depends on the tooling cost term tc × CE /T (see Calculation of Cost of Cutting and Grinding Operations on page
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Machinery's Handbook 27th Edition 1110
MACHINING ECONOMETRICS
1115). In this example, cutting times tc= 4.9 and 9.81 seconds, at T = 22 and 30 minutes respectively, and the ratios are proportional to 4.9/22 = 0.222 and 9.81/30 = 0.327 respectively. The portions of the total cost curve for shorter cutting times than at minimum corresponds to using feeds and speeds right of the G-curve, and those on the other side are left of this curve. Optimization Models, Economic Tool-life when Feed is Constant.—Usually, optimization is performed versus the parameters tool-life and cutting speed, keeping feed at a constant value. The cost of cutting as function of cutting time is a straight line with the slope = HR = hourly rate. This cost is independent of the values of tool change and tooling. Adding the cost of tool change and tooling, gives the variation of total cutting cost which shows a minimum with cutting time that corresponds to an economic tool-life, TE. Economic tool-life represents a local optima (minimum cost) at a given constant value of feed, feed/tooth, or ECT. Using the Taylor Equation: V × T = C and differentiating CTOT with respect to T yields: Economic tool-life: TE = TV × (1/n − 1), minutes Economic cutting speed: VE = C/TEn, m/min, or sfm In these equations, n and C are constants in the Taylor equation for the given value of feed. Values of Taylor slopes, n, are estimated using the speed and feed Tables 1 through 23 starting on page 1027 and handbook Table 5b on page 1035 for turning, and Table 15e on page 1059 for milling and drilling; and TV is the equivalent tooling-cost time. TV = TRPL + 60 × CE ÷ HR, minutes, where TRPL = time for replacing a worn insert, or a set of inserts in a milling cutter or inserted drill, or a twist drill, reamer, thread chaser, or tap. TV is described in detail, later; CE = cost per edge, or set of edges, or cost per regrind including amortized price of tool; and HR = hourly shop rate, or that rate that is impacted by the changes of cutting conditions . In two dimensions, Fig. 20a shows how economic tool-life varies with feed per tooth. In this figure, the equivalent tooling-cost time TV is constant, however the Taylor constant n varies with the feed per tooth. LIVE GRAPH Click here to view
60
TE
TE , minutes
50
40
30
20
10
0 0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
fz , mm
Fig. 20a. Economic tool-life, TE vs. feed per tooth, fz
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1111
Economic tool-life increases with greater values of TV, either when TRPL is longer, or when cost per edge CE is larger for constant HR, or when HR is smaller and TRPL and CE are unchanged. For example, when using an expensive machine (which makes HR bigger) the value of TV gets smaller, as does the economic tool-life, TE = TV × (1/n - 1). Reducing TE results in an increase in the economic cutting speed, VE. This means raising the cutting speed, and illustrates the importance, in an expensive system, of utilizing the equipment better by using more aggressive machining data. LIVE GRAPH Click here to view
T, minutes
1000
100
10 ECT = 1.54
ECT = 0.51
ECT = 0.8 1 10
100
1000
V, m/min
Fig. 20b. Tool-life vs. cutting speed, constant ECT
As shown in Fig. 20a for a face milling operation, economic tool-life TE varies considerably with feed/tooth fz, in spite of the fact that the Taylor lines have only slightly different slopes (ECT = 0.51, 0.6, 1.54), as shown in Fig. 20b. The calculation is based on the following cost data: TV = 6, hourly shop rate HR = $60/hour, cutter diameter D = 125 mm with number of teeth z = 10, and radial depth of cut ar = 40 mm. The conclusion relating to the determination of economic tool-life is that both hourly rate HR and slope n must be evaluated with reasonable accuracy in order to arrive at good values. However, the method shown will aid in setting the trend for general machining economics evaluations. Global Optimum, Graphical Method.—There are several ways to demonstrate in graphs how cost varies with the production parameters including optimal conditions. In all cases, tool-life is a crucial parameter. Cutting time tc is inversely proportional to the specific metal removal rate, SMRR = V × ECT, thus, 1/tc = V × ECT. Taking the log of both sides,
lnV = – lnECT – lnt c + C
(7)
where C is a constant. Equation (7) is a straight line with slope (– 1) in the V–ECT graph when plotted in a loglog graph. This means that a constant cutting time is a straight 45-degree line in the V–ECT graph, when plotted in log-log coordinates with the same scale on both axis (a square graph). The points at which the constant cutting time lines (at 45 degrees slope) are tangent to the tool-life curves define the G-curve, along which global optimum cutting occurs. Note: If the ratio a/CEL is not constant when ECT varies, the constant cutting time lines are not straight, but the cutting time deviation is quite small in most cases.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1112
MACHINING ECONOMETRICS
In the V–ECT graph, Fig. 21, 45-degree lines have been drawn tangent to each tool-life curve: T=1, 5, 15, 30, 60, 100 and 300 minutes. The tangential points define the G-curve, and the 45-degree lines represent different constant cutting times: 1, 2, 3, 10 minutes, etc. Following one of these lines and noting the intersection points with the tool-life curves T = 1, 5, etc., many different speed and feed combinations can be found that will give the same cutting time. As tool-life gets longer (tooling cost is reduced), ECT (feed) increases but the cutting speed has to be reduced. LIVE GRAPH Click here to view
1000
Constant cutting time increasing going down 45 Degrees
V, m/min
G-CURVE
T=1 T=5 T=15 T=30 T=60 100 0.1
ECT, mm
1
Fig. 21. Constant cutting time in the V-ECT plane, tool-life constant
Global Optimum, Mathematical Method.—Global optimization is the search for extremum of CTOT for the three parameters: T, ECT, and V. The results, in terms of the tool-life equation constants, are: Optimum tool-life: 1- – 1⎞ T O = T V × ⎛ ----⎝n ⎠ O n O = 2M × ( L × lnT O ) 2 + 1 – N 0 + L × ( 2M + H ) where nO = slope at optimum ECT. The same approach is used when searching for maximum production rate, but without the term containing tooling cost. Optimum cutting speed: VO = e
– M + K + ( H × L – N 0 ) × lnT O + M × L 2 × ( lnT O ) 2
Optimum ECT: ECT O = e
H + 2M × ( L × ln ( T O ) + 1 )
Global optimum is not reached when face milling for very large feeds, and CTOT decreases continually with increasing feed/tooth, but can be reached for a cutter with many teeth, say 20 to 30. In end milling, global optimum can often be achieved for big feeds and for 3 to 8 teeth.
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1113
Determination Of Machine Settings And Calculation Of Costs Based on the rules and knowledge presented in Chapters 1 and 2, this chapter demonstrates, with examples, how machining times and costs are calculated. Additional formulas are given, and the speed and feed tables given in SPEED AND FEED TABLES starting on page 1022 should be used. Finally the selection of feeds, speeds and tool-lives for optimized conditions are described with examples related to turning, end milling, and face milling. There are an infinite number of machine settings available in the machine tool power train producing widely different results. In practice only a limited number of available settings are utilized. Often, feed is generally selected independently of the material being cut, however, the influence of material is critical in the choice of cutting speed. The tool-life is normally not known or directly determined, but the number of pieces produced before the change of worn tools is better known, and tool-life can be calculated using the formula for piece cutting time tc given in this chapter. It is well known that increasing feeds or speeds reduces the number of pieces cut between tool changes, but not how big are the changes in the basic parameter tool-life. Therefore, there is a tendency to select “safe” data in order to get a long tool-life. Another common practice is to search for a tool grade yielding a longer life using the current speeds and feeds, or a 10–20% increase in cutting speed while maintaining the current tool-life. The reason for this old-fashioned approach is the lack of knowledge about the opportunities the metal cutting process offers for increased productivity. For example, when somebody wants to calculate the cutting time, he/she can select a value of the feed rate (product of feed and rpm), and easily find the cutting time by dividing cutting distance by the feed rate. The number of pieces obtained out of a tool is a guesswork, however. This problem is very common and usually the engineers find desired toollives after a number of trial and error runs using a variety of feeds and speeds. If the user is not well familiar with the material cut, the tool-life obtained could be any number of seconds or minutes, or the cutting edge might break. There are an infinite number of feeds and speeds, giving the same feed rate, producing equal cutting time. The same cutting time per piece tc is obtained independent of the selection of feed/rev f and cutting speed V, (or rpm), as long as the feed rate FR remains the same: FR = f1 × rpm1 = f2 × rpm2 = f3 × rpm3 …, etc. However, the number of parts before tool change Nch will vary considerably including the tooling cost ctool and the total cutting cost ctot. The dilemma confronting the machining-tool engineer or the process planner is how to set feeds and speeds for either desired cycle time, or number of parts between tool changes, while balancing the process versus other operations or balancing the total times in one cell with another. These problems are addressed in this section. Nomenclature f = feed/rev or tooth, mm fE =economic feed fO =optimum feed T =tool-life, minutes TE =economic tool-life TO =optimum tool-life V =cutting speed, m/min VE =economic cutting speed VO =optimum cutting speed, m/min Similarly, economic and optimum values of: ctool = piece cost of tooling, $ CTOOL = cost of tooling per batch, $ ctot = piece total cost of cutting, $ CTOT =total cost of cutting per batch, $ FR =feed rate measured in the feeding direction, mm/rev N =batch size Nch = number of parts before tool change tc = piece cutting time, minutes TC =cutting time per batch, minutes tcyc = piece cycle time, minutes TCYC = cycle time before tool change, minutes
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Machinery's Handbook 27th Edition 1114
MACHINING ECONOMETRICS
ti = idle time (tool “air” motions during cycle), minutes z = cutter number of teeth The following variables are used for calculating the per batch cost of cutting: CC =cost of cutting time per batch, $ CCH = cost of tool changes per batch, $ CE =cost per edge, for replacing or regrinding, $ HR =hourly rate, $ TV =equivalent tooling-cost time, minutes TRPL = time for replacing worn edge(s), or tool for regrinding, minutes Note: In the list above, when two variables use the same name, one in capital letters and one lower case, TC and tc for example, the variable name in capital letters refers to batch processing and lowercase letters to per piece processing, such as TC = Nch × tc, CTOT = Nch × ctot, etc. Formulas Valid For All Operation Types Including Grinding Calculation of Cutting Time and Feed Rate Feed Rate: FR = f × rpm (mm/min), where f is the feed in mm/rev along the feeding direction, rpm is defined in terms of work piece or cutter diameter D in mm, and cutting speed V in m/min, as follows: 1000V 318V rpm = ---------------- = ------------πD D Cutting time per piece: Note: Constant cutting time is a straight 45-degree line in the V–ECT graph, along which tool-life varies considerably, as is shown in Chapter 2. Dist - = -----------------------Dist × πDt c = Dist ----------- = ---------------FR f × rpm 1000V × f where the units of distance cut Dist, diameter D, and feed f are mm, and V is in m/min. In terms of ECT, cutting time per piece, tc, is as follows: × πD- × ----------------------------a t c = Dist -----------------------1000V CEL × ECT where a = depth of cut, because feed × cross sectional chip area = f × a = CEL × ECT. Example 3, Cutting Time:Given Dist =105 mm, D =100 mm, f = 0.3 mm, V = 300 m/min, rpm = 700, FR = 210 mm/min, find the cutting time. Cutting time = tc = 105 × 3.1416 × 100 ÷ (1000 × 300 × 0.3) = 0.366 minutes = 22 seconds Scheduling of Tool Changes Number of parts before tool change: Nch = T÷ tc Cycle time before tool change: TCYC = Nch × (tc + ti), where tcyc = tc + ti, where tc = cutting time per piece, ti = idle time per piece Tool-life: T = Nch × tc Example 4: Given tool-life T = 90 minutes, cutting time tc = 3 minutes, and idle time ti = 3 minutes, find the number of parts produced before a tool change is required and the time until a tool change is required.
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1115
Number of parts before tool change = Nch = 90/3 = 30 parts. Cycle time before tool change = TCYC = 30 × (3 + 3) = 180 minutes Example 5: Given cutting time, tc = 1 minute, idle time ti = 1 minute, Nch = 100 parts, calculate the tool-life T required to complete the job without a tool change, and the cycle time before a tool change is required. Tool-life = T = Nch × tc = 100 × 1 = 100 minutes. Cycle time before tool change = TCYC = 100 × (1 + 1) = 200 minutes. Calculation of Cost of Cutting and Grinding Operations.—When machining data varies, the cost of cutting, tool changing, and tooling will change, but the costs of idle and slack time are considered constant. Cost of Cutting per Batch: CC = HR × TC/60 TC = cutting time per batch = (number of parts) × tc, minutes, or when determining time for tool change TCch = Nch × tc minutes = cutting time before tool change. tc = Cutting time/part, minutes HR = Hourly Rate Cost of Tool Changes per Batch: H T RPL $ ⋅ min = $ --------C CH = ------R- × T C × ----------60 T min where T = tool-life, minutes, and TRPL = time for replacing a worn edge(s), or tool for regrinding, minutes Cost of Tooling per Batch: Including cutting tools and holders, but without tool changing costs, 60C E min --------------------- ⋅ $ ⋅ hr ----HR HR $ ⋅ min ⋅ --------------------------hr $- = $ C TOOL = ------- × T C × -------------------60 T min min Cost of Tooling + Tool Changes per Batch: Including cutting tools, holders, and tool changing costs, 60C T RPL + ------------EHR HR ( C TOOL + C CH ) = ------- × T C × ------------------------------60 T Total Cost of Cutting per Batch: 60C ⎛ T RPL + ------------E-⎞ ⎜ HR HR ⎟ -⎟ C TOT = ------- × T C ⎜ 1 + ------------------------------60 T ⎜ ⎟ ⎝ ⎠ Equivalent Tooling-cost Time, TV: 60C The two previous expressions can be simplified by using T V = T RPL + ------------EHR thus: H T ( C TOOL + C CH ) = ------R- × T C × -----V60 T
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Machinery's Handbook 27th Edition 1116
MACHINING ECONOMETRICS
T H C TOT = ------R- × T C ⎛ 1 + -----V-⎞ ⎝ T⎠ 60 CE = cost per edge(s) is determined using two alternate formulas, depending on whether tools are reground or inserts are replaced: Cost per Edge, Tools for Regrinding cost of tool + ( number of regrinds × cost/regrind ) C E = ----------------------------------------------------------------------------------------------------------------------1 + number of regrinds Cost per Edge, Tools with Inserts: cost of insert(s) cost of cutter body C E = --------------------------------------------------------------- + ----------------------------------------------------------------------------------number of edges per insert cutter body life in number of edges Note: In practice allow for insert failures by multiplying the insert cost by 4/3, that is, assuming only 3 out of 4 edges can be effectively used. Example 6, Cost per Edge–Tools for Regrinding:Use the data in the table below to calculate the cost per edge(s) CE, and the equivalent tooling-cost time TV, for a drill. Time for cutter replacement TRPL, minute
Cutter Price, $
Cost per regrind, $
Number of regrinds
Hourly shop rate, $
Batch size
Taylor slope, n
Economic cutting time, tcE minute
1
40
6
5
50
1000
0.25
1.5
Using the cost per edge formula for reground tools, CE = (40 + 5 × 6) ÷ (1 + 5) = $6.80 60C 60 ( 6.8 ) When the hourly rate is $50/hr, T V = T RPL + ------------E- = 1 + ------------------ = 9.16minutes HR 50 1 Calculate economic tool-life using T E = T V × ⎛ --- – 1⎞ thus, TE = 9.17 × (1/0.25 – 1) = ⎝n ⎠ 9.16 × 3 = 27.48 minutes. Having determined, elsewhere, the economic cutting time per piece to be tcE = 1.5 minutes, for a batch size = 1000 calculate: Cost of Tooling + Tool Change per Batch: H T 50 9.16 ( C TOOL + C CH ) = ------R- × T C × -----V- = ------ × 1000 × 1.5 × ------------- = $ 417 60 T 60 27.48 Total Cost of Cutting per Batch: T H 9.16 C TOT = ------R- × T C ⎛ 1 + -----V-⎞ = 50 ------ × 1000 × 1.5 × ⎛ 1 + -------------⎞ = $ 1617 ⎝ ⎝ T⎠ 27.48⎠ 60 60 Example 7, Cost per Edge–Tools with Inserts: Use data from the table below to calculate the cost of tooling and tool changes, and the total cost of cutting. For face milling, multiply insert price by safety factor 4/3 then calculate the cost per edge: CE =10 × (5/3) × (4/3) + 750/500 = 23.72 per set of edges When the hourly rate is $50, equivalent tooling-cost time is TV = 2 + 23.72 × 60/50 = 30.466 minutes (first line in table below). The economic tool-life for Taylor slope n = 0.333 would be TE = 30.466 × (1/0.333 –1) = 30.466 × 2 = 61 minutes. When the hourly rate is $25, equivalent tooling-cost time is TV = 2 + 23.72 × 60/25 = 58.928 minutes (second line in table below). The economic tool-life for Taylor slope n = 0.333 would be TE = 58.928 × (1/0.333 –1) =58.928 × 2 = 118 minutes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINING ECONOMETRICS Time for replacement of inserts TRPL, minutes
Number of inserts
Price per insert
2 2
10 10
5 5
1
3
6
1
1
5
Edges per insert
Cutter Price
Face mill 750 750 End mill 2 75 Turning 3 50 3 3
1117
Edges per cutter
Cost per set of edges, CE
Hourly shop rate
TV minutes
500 500
23.72 23.72
50 25
30.466 58.928
200
4.375
50
6.25
100
2.72
30
6.44
With above data for the face mill, and after having determined the economic cutting time as tcE = 1.5 minutes, calculate for a batch size = 1000 and $50 per hour rate: Cost of Tooling + Tool Change per Batch: H T 50 30.466 ( C TOOL + C CH ) = ------R- × T C × -----V- = ------ × 1000 × 1.5 × ---------------- = $ 624 60 T 60 61 Total Cost of Cutting per Batch: T H 30.466 50 C TOT = ------R- × T C ⎛ 1 + -----V-⎞ = ------ × 1000 × 1.5 × ⎛ 1 + ----------------⎞ = $ 1874 ⎝ ⎝ 60 T⎠ 60 61 ⎠ Similarly, at the $25/hour shop rate, (CTOOL + CCH) and CTOT are $312 and $937, respectively. Example 8, Turning: Production parts were run in the shop at feed/rev = 0.25 mm. One series was run with speed V1 = 200 m/min and tool-life was T1 = 45 minutes. Another was run with speed V2 = 263 m/min and tool-life was T2 = 15 minutes. Given idle time ti = 1 minute, cutting distance Dist =1000 mm, work diameter D = 50 mm. First, calculate Taylor slope, n, using Taylor’s equation V1 × T1n = V2 × T2n, as follows: V T 200- ÷ ln ----15- = 0.25 n = ln -----1- ÷ ln -----2 = ln -------V2 T1 263 45 Economic tool-life TE is next calculated using the equivalent tooling-cost time TV, as described previously. Assuming a calculated value of TV = 4 minutes, then TE can be calculated from 1 - – 1⎞ T E = T V × ⎛ 1--- – 1⎞ = 4 × ⎛ --------= 12 minutes ⎝n ⎠ ⎝ 0.25 ⎠ Economic cutting speed, VE can be found using Taylor’s equation again, this time using the economic tool-life, as follows, V E1 × ( T E ) n = V 2 × ( T 2 ) n 0.25 T n V E1 = V 2 × ⎛ -----2-⎞ = 263 × ⎛ 15 ------⎞ = 278 m/min ⎝T ⎠ ⎝ 12⎠ E
Using the process data, the remaining economic parameters can be calculated as follows: Economic spindle rpm, rpmE = (1000VE)/(πD) = (1000 × 278)/(3.1416 × 50) = 1770 rpm Economic feed rate, FRE = f × rpmE = 0.25 × 1770 = 443 mm/min Economic cutting time, tcE = Dist/ FRE =1000/ 443 = 2.259 minutes Economic number of parts before tool change, NchE = TE ÷ tcE =12 ÷ 2.259 = 5.31 parts Economic cycle time before tool change, TCYCE = NchE × (tc + ti) = 5.31 × (2.259 + 1) = 17.3 minutes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1118
MACHINING ECONOMETRICS
Variation Of Tooling And Total Cost With The Selection Of Feeds And Speeds It is a well-known fact that tool-life is reduced when either feed or cutting speed is increased. When a higher feed/rev is selected, the cutting speed must be decreased in order to maintain tool-life. However, a higher feed rate (feed rate = feed/rev × rpm, mm/min) can result in a longer tool-life if proper cutting data are applied. Optimized cutting data require accurate machinability databases and a computer program to analyze the options. Reasonably accurate optimized results can be obtained by selecting a large feed/rev or tooth, and then calculating the economic tool-life TE. Because the cost versus feed or ECT curve is shallow around the true minimum point, i.e., the global optimum, the error in applying a large feed is small compared with the exact solution. Once a feed has been determined, the economic cutting speed VE can be found by calculating the Taylor slope, and the time/cost calculations can be completed using the formulas described in last section. The remainder of this section contains examples useful for demonstrating the required procedures. Global optimum may or may not be reached, and tooling cost may or may not be reduced, compared to currently used data. However, the following examples prove that significant time and cost reductions are achievable in today’s industry. Note: Starting values of reasonable feeds in mm/rev can be found in the Handbook speed and feed tables, see Principal Speed andFeed Tables on page 1022, by using the favg values converted to mm as follows: feed (mm/rev) = feed (inch/rev) × 25.4 (mm/inch), thus 0.001 inch/rev = 0.001× 25.4 = 0.0254 mm/rev. When using speed and feed Tables 1 through 23, where feed values are given in thousandths of inch per revolution, simply multiply the given feed by 25.4/1000 = 0.0254, thus feed (mm/rev) = feed (0.001 inch/rev) × 0.0254 (mm/ 0.001inch). Example 9, Converting Handbook Feed Values From Inches to Millimeters: Handbook tables give feed values fopt and favg for 4140 steel as 17 and 8 × (0.001 inch/rev) = 0.017 and 0.009 inch/rev, respectively. Convert the given feeds to mm/rev. feed = 0.017 × 25.4 = 17 × 0.0254 = 0.4318 mm/rev feed = 0.008 × 25.4 = 8 × 0.0254 = 0.2032 mm/rev Example 10, Using Handbook Tables to Find the Taylor Slope and Constant:Calculate the Taylor slope and constant, using cutting speed data for 4140 steel in Table 1 starting on page 1027, and for ASTM Class 20 grey cast iron using data from Table 4a on page 1033, as follows: For the 175–250 Brinell hardness range, and the hard tool grade, ln ( V 1 ⁄ V 2 ) ( 525 ⁄ 705 )- = ln ------------------------------n = ------------------------= 0.27 C = V 1 × ( T 1 ) n = 1458 ln ( 15 ⁄ 45 ) ln ( T 2 ⁄ T 1 ) For the 175–250 Brinell hardness range, and the tough tool grade, ln ( V 1 ⁄ V 2 ) ( 235 ⁄ 320 )- = ln ------------------------------n = ------------------------= 0.28 C = V 1 × ( T 1 ) n = 685 ln ( T 2 ⁄ T 1 ) ln ( 15 ⁄ 45 ) For the 300–425 Brinell hardness range, and the hard tool grade, ln ( V 1 ⁄ V 2 ) ( 330 ⁄ 440 )- = 0.26 n = ------------------------- = ln ------------------------------C = V 1 × ( T 1 ) n = 894 ln ( T 2 ⁄ T 1 ) ln ( 15 ⁄ 45 ) For the 300–425 Brinell hardness range, and the tough tool grade, ln ( V 1 ⁄ V 2 ) ( 125 ⁄ 175 )- = 0.31 n = ------------------------- = ln ------------------------------C = V 1 × ( T 1 ) n = 401 ln ( T 2 ⁄ T 1 ) ln ( 15 ⁄ 45 ) For ASTM Class 20 grey cast iron, using hard ceramic,
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINING ECONOMETRICS ln ( V 1 ⁄ V 2 ) ( 1490 ⁄ 2220 -) = 0.36 n = ------------------------- = ln ------------------------------------ln ( T 2 ⁄ T 1 ) ln ( 15 ⁄ 45 )
1119
C = V 1 × ( T 1 ) n = 5932
Selection of Optimized Data.—Fig. 22 illustrates cutting time, cycle time, number of parts before a tool change, tooling cost, and total cost, each plotted versus feed for a constant tool-life. Approximate minimum cost conditions can be determined using the formulas previously given in this section. First, select a large feed/rev or tooth, and then calculate economic tool-life TE, and the economic cutting speed VE, and do all calculations using the time/cost formulas as described previously. 1000 tc
100
tcyc # parts
10
CTOT
CTOOL
1
0.1
0.01
0.001 0.01
0.1
1
10
f, mm/rev
Fig. 22. Cutting time, cycle time, number of parts before tool change, tooling cost, and total cost vs. feed for tool-life = 15 minutes, idle time = 10 s, and batch size = 1000 parts
Example 11, Step by Step Procedure: Turning – Facing out:1) Select a big feed/rev, in this case f = 0.9 mm/rev (0.035 inch/rev). A Taylor slope n is first determined using the Handbook tables and the method described in Example 10. In this example, use n = 0.35 and C = 280. 2) Calculate TV from the tooling cost parameters: If cost of insert = $7.50; edges per insert = 2; cost of tool holder = $100; life of holder = 100 insert sets; and for tools with inserts, allowance for insert failures = cost per insert by 4/3, assuming only 3 out of 4 edges can be effectively used. Then, cost per edge = CE is calculated as follows: cost of insert(s) cost of cutter body C E = --------------------------------------------------------------- + ----------------------------------------------------------------------------------number of edges per insert cutter body life in number of edges × 4 ⁄ 3 + 100 = 7.50 ---------------------------------- = $6.00 2 100 The time for replacing a worn edge of the facing insert =TRPL = 2.24 minutes. Assuming an hourly rate HR = $50/hour, calculate the equivalent tooling-cost time TV TV = TRPL + 60 × CE/HR =2.24 +60 × 6/50 = 9.44 minutes 3) Determine economic tool-life TE TE = TV × (1/n − 1) = 9.44 × (1/ 0.35 − 1) = 17.5 minutes 4) Determine economic cutting speed using the Handbook tables using the method shown in Example 10, V E = C ⁄ TEn m/min = 280 / 17.50.35 = 103 m/min
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Machinery's Handbook 27th Edition 1120
MACHINING ECONOMETRICS
5) Determine cost of tooling per batch (cutting tools, holders and tool changing) then total cost of cutting per batch: CTOOL = HR × TC × (CE/T)/60 (CTOOL+CCH) = HR × TC × ((TRPL+CE/T)/60 CTOT = HR × TC (1 + (TRPL+CE)/T) Example 12, Face Milling – Minimum Cost : This example demonstrates how a modern firm, using the formulas previously described, can determine optimal data. It is here applied to a face mill with 10 teeth, milling a 1045 type steel, and the radial depth versus the cutter diameter is 0.8. The V–ECT–T curves for tool-lives 5, 22, and 120 minutes for this operation are shown in Fig. 23a. LIVE GRAPH Click here to view
1000
V, m/min
G-CURVE
100
T=5
T = 22
T = 120 10 0.1
1
10
ECT, mm
Fig. 23a. Cutting speed vs. ECT, tool-life constant
The global cost minimum occurs along the G-curve, see Fig. 6c and Fig. 23a, where the 45-degree lines defines this curve. Optimum ECT is in the range 1.5 to 2 mm. For face and end milling operations, ECT = z × fz × ar/D × aa/CEL ÷ π. The ratio aa/CEL = 0.95 for lead angle LA = 0, and for ar/D = 0.8 and 10 teeth, using the formula to calculate the feed/tooth range gives for ECT = 1.5, fz = 0.62 mm and for ECT = 2, fz = 0.83 mm. LIVE GRAPH Click here to view
0.6
T=5 T = 22 T = 120
0.5
0.4
tc
0.3
0.2 0.1
0 0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
fz
Fig. 23b. Cutting time per part vs. feed per tooth
Using computer simulation, the minimum cost occurs approximately where Fig. 23a indicates it should be. Total cost has a global minimum at fz around 0.6 to 0.7 mm and a speed of around 110 m/min. ECT is about 1.9 mm and the optimal cutter life is TO = 22 minutes. Because it may be impossible to reach the optimum feed value due to tool breakage,
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1121
the maximum practical feed fmax is used as the optimal value. The difference in costs between a global optimum and a practical minimum cost condition is negligible, as shown in Figs. 23c and 23e. A summary of the results are shown in Figs. 23a through 23e, and Table 1. 0.31 T = 120 T = 22
0.26
T=5
CTOT, $
0.21
0.16
0.11
0.06
0.01 0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
fz, mm
Fig. 23c. Total cost vs. feed/tooth
When plotting cutting time/part, tc, versus feed/tooth, fz, at T = 5, 22, 120 in Figs. 23b, tool-life T = 5 minutes yields the shortest cutting time, but total cost is the highest; the minimum occurs for fz about 0.75 mm, see Figs. 23c. The minimum for T = 120 minutes is about 0.6 mm and for TO = 22 minutes around 0.7 mm. 0.1 T=5
0.09 T = 22
0.08 T =120
Unit Tooling Cost, $
0.07 0.06 0.05 0.04 0.03 0.02 0.01 0 0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
fz, mm
Fig. 23d. Tooling cost versus feed/tooth
Fig. 23d shows that tooling cost drop off quickly when increasing feed from 0.1 to 0.3 to 0.4 mm, and then diminishes slowly and is almost constant up to 0.7 to 0.8 mm/tooth. It is generally very high at the short tool-life 5 minutes, while tooling cost of optimal tool-life 22 minutes is about 3 times higher than when going slow at T =120 minutes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1122
MACHINING ECONOMETRICS 0.3
CTOT, $
0.25
0.2
0.15
0.1
0.05
T = 120 T = 22 T=5
0 0
50
100
150
200
250
300
350
400
450
500
V, m/min
Fig. 23e. Total cost vs. cutting speed at 3 constant tool-lives, feed varies
The total cost curves in Fig. 23e. were obtained by varying feed and cutting speed in order to maintain constant tool-lives at 5, 22 and 120 minutes. Cost is plotted as a function of speed V instead of feed/tooth. Approximate optimum speeds are V = 150 m/min at T = 5 minutes, V = 180 m/min at T = 120 minutes, and the global optimum speed is VO = 110 m/min for TO = 22 minutes. Table 1 displays the exact numerical values of cutting speed, tooling cost and total cost for the selected tool-lives of 5, 22, and 120 minutes, obtained from the software program. Table 1. Face Milling, Total and Tooling Cost versus ECT, Feed/tooth fz, and Cutting Speed V, at Tool-lives 5, 22, and 120 minutes T = 5 minutes
T = 22 minutes
T = 120 minutes
fz
ECT
V
CTOT
CTOOL
V
CTOT
CTOOL
V
CTOT
CTOOL
0.03
0.08
489
0.72891
0.39759
416
0.49650
0.10667
344
0.49378
0.02351
0.08
0.21
492
0.27196
0.14834
397
0.19489
0.04187
311
0.20534
0.00978
0.10
0.26
469
0.22834
0.12455
374
0.16553
0.03556
289
0.17674
0.00842
0.17
0.44
388
0.16218
0.08846
301
0.12084
0.02596
225
0.13316
0.00634
0.20
0.51
359
0.14911
0.08133
276
0.11204
0.02407
205
0.12466
0.00594
0.40
1.03
230
0.11622
0.06339
171
0.09051
0.01945
122
0.10495
0.00500
0.60
1.54
164
0.10904
0.05948
119
0.08672
0.01863
83
0.10301
0.00491
0.70
1.80
141
0.10802
0.05892
102
0.08665
0.01862
70
0.10393
0.00495
0.80
2.06
124
0.10800
0.05891
89
0.08723
0.01874
60
0.10547
0.00502
1.00
2.57
98
0.10968
0.05982
69
0.08957
0.01924
47
0.10967
0.00522
High-speed Machining Econometrics High-speed Machining – No Mystery.—This section describes the theory and gives the basic formulas for any milling operation and high-speed milling in particular, followed by several examples on high-speed milling econometrics. These rules constitute the basis on which selection of milling feed factors is done. Selection of cutting speeds for general milling is done using the Handbook Table 10 through 14, starting on page 1044. High-speed machining is no mystery to those having a good knowledge of metal cutting. Machining materials with very good machinability, such as low-alloyed aluminum, have for ages been performed at cutting speeds well below the speed values at which these materials should be cut. Operating at these low speeds often results in built-up edges and poor surface finish, because the operating conditions selected are on the wrong side of the Taylor curve, i.e. to the left of the H-curve representing maximum tool-life values (see Fig. 4 on page 1096).
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1123
In the 1950’s it was discovered that cutting speed could be raised by a factor of 5 to 10 when hobbing steel with HSS cutters. This is another example of being on the wrong side of the Taylor curve. One of the first reports on high-speed end milling using high-speed steel (HSS) and carbide cutters for milling 6061-T651 and A356-T6 aluminum was reported in a study funded by Defense Advanced Research Project Agency (DARPA). Cutting speeds of up to 4400 m/min (14140 fpm) were used. Maximum tool-lives of 20 through 40 minutes were obtained when the feed/tooth was 0.2 through 0.25 mm (0.008 to 0.01 inch), or measured in terms of ECT around 0.07 to 0.09 mm. Lower or higher feed/tooth resulted in shorter cutter lives. The same types of previously described curves, namely T–ECT curves with maximum tool-life along the H-curve, were produced. When examining the influence of ECT, or feed/rev, or feed/tooth, it is found that too small values cause chipping, vibrations, and poor surface finish. This is caused by inadequate (too small) chip thickness, and as a result the material is not cut but plowed away or scratched, due to the fact that operating conditions are on the wrong (left) side of the toollife versus ECT curve (T-ECT with constant speed plotted). There is a great difference in the thickness of chips produced by a tooth traveling through the cutting arc in the milling process, depending on how the center of the cutter is placed in relation to the workpiece centerline, in the feed direction. Although end and face milling cut in the same way, from a geometry and kinematics standpoint they are in practice distinguished by the cutter center placement away from, or close to, the work centerline, respectively, because of the effect of cutter placement on chip thickness. This is the criteria used to distinguishing between the end and face milling processes in the following. Depth of Cut/Cutter Diameter, ar/D is the ratio of the radial depth of cut ar and the cutter diameter D. In face milling when the cutter axis points approximately to the middle of the work piece axis, eccentricity is close to zero, as illustrated in Figs. 3 and 4, page 1042, and Fig. 5 on page 1043. In end milling, ar/D = 1 for full slot milling. Mean Chip Thickness, hm is a key parameter that is used to calculate forces and power requirements in high-speed milling. If the mean chip thickness hm is too small, which may occur when feed/tooth is too small (this holds for all milling operations), or when ar/D decreases (this holds for ball nose as well as for straight end mills), then cutting occurs on the left (wrong side) of the tool-life versus ECT curve, as illustrated in Figs. 6b and 6c. In order to maintain a given chip thickness in end milling, the feed/tooth has to be increased, up to 10 times for very small ar/D values in an extreme case with no run out and otherwise perfect conditions. A 10 times increase in feed/tooth results in 10 times bigger feed rates (FR) compared to data for full slot milling (valid for ar/D = 1), yet maintain a given chip thickness. The cutter life at any given cutting speed will not be the same, however. Increasing the number of teeth from say 2 to 6 increases equivalent chip thickness ECT by a factor of 3 while the mean chip thickness hm remains the same, but does not increase the feed rate to 30 (3 × 10) times bigger, because the cutting speed must be reduced. However, when the ar/D ratio matches the number of teeth, such that one tooth enters when the second tooth leaves the cutting arc, then ECT = hm. Hence, ECT is proportional to the number of teeth. Under ideal conditions, an increase in number of teeth z from 2 to 6 increases the feed rate by, say, 20 times, maintaining tool-life at a reduced speed. In practice about 5 times greater feed rates can be expected for small ar/D ratios (0.01 to 0.02), and up to 10 times with 3 times as many teeth. So, high-speed end milling is no mystery. Chip Geometry in End and Face Milling.—Fig. 24 illustrates how the chip forming process develops differently in face and end milling, and how mean chip thickness hm varies with the angle of engagement AE, which depends on the ar/D ratio. The pertinent chip geometry formulas are given in the text that follows.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1124
MACHINING ECONOMETRICS Face Milling
End Milling
AE
hmax
ar hmax ar
hm
hm
AE
fz ar ---⎞⎠ cos AE = 1 – 2 × ⎛⎝---D
fz 2 ar ---⎞⎠ cos AE = 1 – 2 × ⎛⎝---D
Fig. 24.
Comparison of face milling and end milling geometry High-speed end milling refers to values of ar/D that are less than 0.5, in particular to ar/D ratios which are considerably smaller. When ar/D = 0.5 (AE = 90 degrees) and diminishing in end milling, the chip thickness gets so small that poor cutting action develops, including plowing or scratching. This situation is remedied by increasing the feed/tooth, as shown in Table 2a as an increasing fz/fz0 ratio with decreasing ar/D. For end milling, the fz/fz0 feed ratio is 1.0 for ar/D = 1 and also for ar/D = 0.5. In order to maintain the same hm as at ar/D = 1, the feed/tooth should be increased, by a factor of 6.38 when ar/D is 0.01 and by more than 10 when ar/D is less than 0.01. Hence high-speed end milling could be said to begin when ar/D is less than 0.5 In end milling, the ratio fz/fz0 = 1 is set at ar/D = 1.0 (full slot), a common value in vendor catalogs and handbooks, for hm = 0.108 mm. The face milling chip making process is exactly the same as end milling when face milling the side of a work piece and ar/D = 0.5 or less. However, when face milling close to and along the work centerline (eccentricity is close to zero) chip making is quite different, as shown in Fig. 24. When ar/D = 0.74 (AE = 95 degrees) in face milling, the fz/fz0 ratio = 1 and increases up to 1.4 when the work width is equal to the cutter diameter (ar/D = 1). The face milling fz/fz0 ratio continues to diminish when the ar/D ratio decreases below ar/D = 0.74, but very insignificantly, only about 11 percent when ar/D = 0.01. In face milling fz/fz0 = 1 is set at ar/D = 0.74, a common value recommended in vendor catalogs and handbooks, for hm = 0.151 mm. Fig. 25 shows the variation of the feed/tooth-ratio in a graph for end and face milling. LIVE GRAPH Click here to view
6.5 6
fz/fz0 , Face Milling
5.5
fz/fz0 , End Milling
5 4.5
fz/fz0
4 3.5 3 2.5 2 1.5 1 0.5 0 0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
ar/D
Fig. 25. Feed/tooth versus ar/D for face and end milling
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1125
Table 2a. Variation of Chip Thickness and fz/fz0 with ar/D Face Milling
End Milling (straight)
ecentricitye = 0 z =8 fz0 = 0.017 cosAE = 1 − 2 × (ar/D)2
z =2 fz0 = 0.017 cosAE = 1 − 2 × (ar/D)
ar/D
AE
hm/fz
hm
ECT/hm
fz/fz0
AE
hm/fz
hm
ECT/hm
fz/fz0
1.0000 0.9000 0.8000 0.7355 0.6137 0.5000 0.3930 0.2170 0.1250 0.0625 0.0300 0.0100 0.0010
180.000 128.316 106.260 94.702 75.715 60.000 46.282 25.066 14.361 7.167 3.438 1.146 0.115
0.637 0.804 0.863 0.890 0.929 0.162 0.973 0.992 0.997 0.999 1.000 1.000 1.000
0.108 0.137 0.147 0.151 0.158 0.932 0.165 0.169 0.170 0.170 0.170 0.170 0.000
5.000 3.564 2.952 2.631 1.683 0.216 1.028 0.557 0.319 0.159 0.076 0.025 0.000
1.398 1.107 1.032 1.000 0.958 0.202 0.915 0.897 0.892 0.891 0.890 0.890 0.890
180.000 143.130 126.870 118.102 103.144 90.000 77.643 55.528 41.410 28.955 19.948 11.478 3.624
0.637 0.721 0.723 0.714 0.682 0.674 0.580 0.448 0.346 0.247 0.172 0.100 0.000
0.108 0.122 0.123 0.122 0.116 0.115 0.099 0.076 0.059 0.042 0.029 0.017 0.000
1.000 0.795 0.711 0.667 0.573 0.558 0.431 0.308 0.230 0.161 0.111 0.064 0.000
1.000 0.884 0.881 0.892 0.934 1.000 1.098 1.422 1.840 2.574 3.694 6.377 20.135
In Table 2a, a standard value fz0 = 0.17 mm/tooth (commonly recommended average feed) was used, but the fz/fz0 values are independent of the value of feed/tooth, and the previously mentioned relationships are valid whether fz0 = 0.17 or any other value. In both end and face milling, hm = 0.108 mm for fz0 = 0.17mm when ar/D =1. When the fz/fz0 ratio = 1, hm = 0.15 for face milling, and 0.108 in end milling both at ar/D = 1 and 0.5. The tabulated data hold for perfect milling conditions, such as, zero run-out and accurate sharpening of all teeth and edges. Mean Chip Thickness hm and Equivalent Chip Thickness ECT.—The basic formula for equivalent chip thickness ECT for any milling process is: ECT = fz × z/π × (ar/D) × aa/CEL, where fz = feed/tooth, z = number of teeth, D = cutter diameter, ar = radial depth of cut, aa = axial depth of cut, and CEL = cutting edge length. As a function of mean chip thickness hm: ECT = hm × (z/2) × (AE/180), where AE = angle of engagement. Both terms are exactly equal when one tooth engages as soon as the preceding tooth leaves the cutting section. Mathematically, hm = ECT when z = 360/AE; thus: for face milling, AE = arccos (1 – 2 × (ar/D)2) for end milling, AE = arccos (1 – 2 × (ar/D)) Calculation of Equivalent Chip Thickness (ECT) versus Feed/tooth and Number of teeth.: Table 2b is a continuation of Table 2a, showing the values of ECT for face and end milling for decreasing values ar/D, and the resulting ECT when multiplied by the fz/fz0 ratio fz0 = 0.17 (based on hm = 0.108). Small ar/D ratios produce too small mean chip thickness for cutting chips. In practice, minimum values of hm are approximately 0.02 through 0.04 mm for both end and face milling. Formulas.— Equivalent chip thickness can be calculated for other values of fz and z by means of the following formulas: Face milling: ECTF = ECT0F × (z/8) × (fz/0.17) × (aa/CEL) or, if ECTF is known calculate fz using: fz = 0.17 × (ECTF/ECT0F) × (8/z) × (CEL/aa)
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1126
MACHINING ECONOMETRICS Table 2b. Variation of ECT, Chip Thickness and fz/fz0 with ar/D Face Milling
ar/D 1.0000 0.9000 0.8080 0.7360 0.6137 0.5900 0.5000 0.2170 0.1250 0.0625 0.0300 0.0100 0.0010
hm 0.108 0.137 0.146 0.151 0.158 0.159 0.162 0.169 0.170 0.170 0.170 0.170 0.170
fz/fz0 1.398 1.107 1.036 1.000 0.958 0.952 0.932 0.897 0.892 0.891 0.890 0.890 0.890
ECT 0.411 0.370 0.332 0.303 0.252 0.243 0.206 0.089 0.051 0.026 0.012 0.004 0.002
End Milling (straight) ECT0 corrected for fz/fz0 0.575 0.410 0.344 0.303 0.242 0.231 0.192 0.080 0.046 0.023 0.011 0.004 0.002
hm 0.108 0.122 0.123 0.121 0.116 0.115 0.108 0.076 0.059 0.042 0.029 0.017 0.005
fz/fz0 1.000 0.884 0.880 0.892 0.934 0.945 1.000 1.422 1.840 2.574 3.694 6.377 20.135
ECT 0.103 0.093 0.083 0.076 0.063 0.061 0.051 0.022 0.013 0.006 0.003 0.001 0.001
ECT0 corrected for fz/fz0 0.103 0.082 0.073 0.067 0.059 0.057 0.051 0.032 0.024 0.017 0.011 0.007 0.005
In face milling, the approximate values of aa/CEL = 0.95 for lead angle LA = 0° (90° in the metric system); for other values of LA, aa/CEL = 0.95 × sin (LA), and 0.95 × cos (LA) in the metric system. Example, Face Milling: For a cutter with D = 250 mm and ar = 125 mm, calculate ECTF for fz = 0.1, z = 12, and LA = 30 degrees. First calculate ar/D = 0.5, and then use Table 2b and find ECT0F = 0.2. Calculate ECTF with above formula: ECTF = 0.2 × (12/8) × (0.1/0.17) × 0.95 × sin 30 = 0.084 mm. End milling: ECTE = ECT0E × (z/2) × (fz/0.17) × (aa/CEL), or if ECTE is known calculate fz from: fz = 0.17 × (ECTE/ECT0E) × (2/z)) × (CEL/aa) The approximate values of aa/CEL = 0.95 for lead angle LA = 0° (90° in the metric system). Example, High-speed End Milling:For a cutter with D = 25 mm and ar = 3.125 mm, calculate ECTE for fz = 0.1 and z = 6. First calculate ar/D = 0.125, and then use Table 2b and find ECT0E = 0.0249. Calculate ECTE with above formula: ECTE = 0.0249 × (6/2) × (0.1/0.17) × 0.95 × 1 = 0.042 mm. Example, High-speed End Milling: For a cutter with D = 25 mm and ar = 0.75 mm, calculate ECTE for fz = 0.17 and z = 2 and 6. First calculate ar/D = 0.03, and then use Table 2b and find fz/fz0 = 3.694 Then, fz = 3.694 × 0.17 = 0.58 mm/tooth and ECTE = 0.0119 × 0.95 = 0.0113 mm and 0.0357 × 0.95 = 0.0339 mm for 2 and 6 teeth respectively. These cutters are marked HS2 and HS6 in Figs. 26a, 26d, and 26e. Example, High-speed End Milling: For a cutter with D = 25 mm and ar = 0.25 mm, calculate ECTE for fz = 0.17 and z = 2 and 6. First calculate ar/D = 0.01, and then use Table 2b and find ECT0E = 0.0069 and 0.0207 for 2 and 6 teeth respectively. When obtaining such small values of ECT, there is a great danger to be far on the left side of the H-curve, at least when there are only 2 teeth. Doubling the feed would be the solution if cutter design and material permit. Example, Full Slot Milling:For a cutter with D = 25 mm and ar = 25 mm, calculate ECTE for fz = 0.17 and z = 2 and 6. First calculate ar/D =1, and then use Table 2b and find ECTE =
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1127
0.108 × 0.95 = 0.103 and 3 × 0.108 × 0.95 = 0.308 for 2 and 6 teeth, respectively. These cutters are marked SL2 and SL6 in Figs. 26a, 26d, and 26e. Physics behind hm and ECT, Forces and Tool-life (T).—The ECT concept for all metal cutting and grinding operations says that the more energy put into the process, by increasing feed/rev, feed/tooth, or cutting speed, the life of the edge decreases. When increasing the number of teeth (keeping everything else constant) the work and the process are subjected to a higher energy input resulting in a higher rate of tool wear. In high-speed milling when the angle of engagement AE is small the contact time is shorter compared to slot milling (ar/D = 1) but the chip becomes shorter as well. Maintaining the same chip thickness as in slot milling has the effect that the energy consumption to remove the chip will be different. Hence, maintaining a constant chip thickness is a good measure when calculating cutting forces (keeping speed constant), but not when determining tool wear. Depending on cutting conditions the wear rate can either increase or decrease, this depends on whether cutting occurs on the left or right side of the H-curve. Fig. 26a shows an example of end milling of steel with coated carbide inserts, where cutting speed V is plotted versus ECT at 5, 15, 45 and 180 minutes tool-lives. Notice that the ECT values are independent of ar/D or number of teeth or feed/tooth, or whether fz or fz0 is used, as long as the corresponding fz/fz0-ratio is applied to determine ECTE. The result is one single curve per tool-life. Had cutting speed been plotted versus fz0, ar/D, or z values (number of teeth), several curves would be required at each constant tool-life, one for each of these parameters This illustrates the advantage of using the basic parameter ECT rather than fz, or hm, or ar/D on the horizontal axis. LIVE GRAPH Click here to view
1000
V, m/min
T=5 T=15 T=45 T=180
H-CURVE G-CURVE
HS 6
SL 2
HS 2 SL 6
100 0.001
0.01
0.1
1
ECT, mm
Fig. 26a. Cutting speed vs. ECT, tool-life plotted, for end milling
Example: The points (HS2, HS6) and (SL2, SL6) on the 45-minute curve in Fig. 26a relate to the previous high-speed and full slot milling examples for 2 and 6 teeth, respectively. Running a slot at fz0 = 0.17 mm/tooth (hm = 0.108, ECTE = 0.103 mm) with 2 teeth and for a tool-life 45 minutes, the cutting speed should be selected at V = 340 m/min at point SL2 and for six teeth (hm = 0.108 mm, ECTE = 0.308) at V = 240 m/min at point SL6. When high-speed milling for ar/D = 0.03 at fz = 3.394 × 0.17 = 0.58 mm/tooth = 0.58 mm/tooth, ECT is reduced to 0.011 mm (hm = 0.108) the cutting speed is 290 m/min to maintain T = 45 minutes, point HS2. This point is far to the left of the H-curve in Fig.26b, but if the number of teeth is increased to 6 (ECTE = 3 × 0.103 = 0.3090), the cutting speed is 360 m/min at T = 45 minutes and is close to the H-curve, point HS6. Slotting data using 6 teeth are on the right of this curve at point SL6, approaching the G-curve, but at a lower slotting speed of 240 m/min.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1128
MACHINING ECONOMETRICS
Depending on the starting fz value and on the combination of cutter grade - work material, the location of the H-curve plays an important role when selecting high-speed end milling data. Feed Rate and Tool-life in High-speed Milling, Effect of ECT and Number of Teeth.—Calculation of feed rate is done using the formulas in previously given: Feed Rate: FR = z × fz × rpm, where z × fz = f (feed/rev of cutter). Feed is measured along the feeding direction. rpm = 1000 × V/3.1416/D, where D is diameter of cutter. LIVE GRAPH
LIVE GRAPH
Click here to view
10000
Click here to view
10000
T=5 T = 15 T = 45 T = 180
FR, mm/min
FR, mm/min
T=5 T = 15 T = 45 T = 180
1000 1000
100
V, m/min
V, m/min
H-CURVE
T=5 T = 15 T = 45 T= 180 0.01
T=5 T = 15 T = 45 T = 180
100 0.01
0.1
ar/D
Fig. 26b. High speed feed rate and cutting speed versus ar/D at T = 5, 15, 45, and 180 minutes
0.1
ECT, mm
1
Fig. 26c. High speed feed rate and cutting speed versus ECT, ar/D plotted at T = 5, 15, 45, and 180 minutes
Fig. 26b shows the variation of feed rate FR plotted versus ar/D for tool-lives 5, 15, 45 and 180 minutes with a 25 mm diameter cutter and 2 teeth. Fig. 26c shows the variation of feed rate FR when plotted versus ECT. In both graphs the corresponding cutting speeds are also plotted. The values for ar/D = 0.03 in Fig. 26b correspond to ECT = 0.011 in Fig. 26c. Feed rates have minimum around values of ar/D = 0.8 and ECT=0.75 and not along the H-curve. This is due to the fact that the fz/fz0 ratio to maintain a mean chip thickness = 0.108 mm changes FR in a different proportion than the cutting speed. LIVE GRAPH Click here to view
100000 T = 45, SL
T = 45 T = 45, HS
H-CURVE
FR , mm/min.
HS6 HS4 10000 HS2 SL6 SL4 SL2 1000 0.01
0.1
1
ECT, mm
Fig. 26d. Feed rate versus ECT comparison of slot milling (ar/D = 1) and high-speed milling at (ar/D = 0.03) for 2, 4, and 6 teeth at T = 45 minutes
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Machinery's Handbook 27th Edition MACHINING ECONOMETRICS
1129
A comparison of feed rates for full slot (ar/D = 1) and high-speed end milling (ar/D = 0.03 and fz = 3.69 × fz0 = 0.628 mm) for tool-life 45 minutes is shown in Fig. 26d. The points SL2, SL4, SL6 and HS2, HS4, HS6, refer to 2, 4, and 6 teeth (2 to 6 teeth are commonly used in practice). Feed rate is also plotted versus number of teeth z in Fig. 26e, for up to 16 teeth, still at fz = 0.628 mm. Comparing the effect of using 2 versus 6 teeth in high-speed milling shows that feed rates increase from 5250 mm/min (413 ipm) up to 18000 mm/min (1417ipm) at 45 minutes toollife. The effect of using 2 versus 6 teeth in full slot milling is that feed rate increases from 1480 mm/min (58 ipm) up to 3230 mm/min (127 ipm) at tool-life 45 minutes. If 16 teeth could be used at ar/D = 0.03, the feed rate increases to FR = 44700 mm/min (1760 ipm), and for full slot milling FR = 5350 mm/min (210 ipm). LIVE GRAPH Click here to view
FR , mm/min.
100000
HS6 HS4
10000 HS2
SL6
SL4
T = 45, SL
SL2
T = 45, HS
1000 0
1
2
3
4
5
6
7
8
9
10 11 12 13 14 15 16 17
Number teeth
Fig. 26e. Feed rate versus number of teeth comparison of slot milling (ar/D = 1) and high-speed milling at (ar/D = 0.03) for 2, 4, and 6 teeth at T = 45 minutes
Comparing the feed rates that can be obtained in steel cutting with the one achieved in the earlier referred DARPA investigation, using HSS and carbide cutters milling 6061-T651 and A356-T6 aluminum, it is obvious that aluminium end milling can be run at 3 to 6 times higher feed rates. This requires 3 to 6 times higher spindle speeds (cutter diameter 25 mm, radial depth of cut ar = 12.5 mm, 2 teeth). Had these tests been run with 6 teeth, the feed rates would increase up to 150000-300000 mm/min, when feed/tooth = 3.4 × 0.25 = 0.8 mm/tooth at ar/D = 0.03. Process Econometrics Comparison of High-speed and Slot End Milling .—W h e n making a process econometrics comparison of high-speed milling and slot end milling use the formulas for total cost ctot (Determination Of Machine Settings And Calculation Of Costs starting on page 1113). Total cost is the sum of the cost of cutting, tool changing, and tooling: ctot= HR × (Dist/FR) × (1 + TV/T)/60 where TV =TRPL + 60 × CE/HR = equivalent tooling-cost time, minutes TRPL = replacement time for a set of edges or tool for regrinding CE =cost per edge(s) HR =hourly rate, $
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1130
MACHINING ECONOMETRICS
Fig. 27. compares total cost ctot, using the end milling cutters of the previous examples, for full slot milling with high-speed milling at ar/D =0.03, and versus ECT at T =45 minutes. 1 H-CURVE
minutes 2,4,6 teeth marked SL2 SL4 SL6
ctot , $
HS2 0.1 HS4 T = 45, z = 4, SL
HS6
T = 45, z = 6, SL T = 45, z = 2, HS T = 45, z = 4, H T = 45, z = 6, HS 0.01 0.01
0.1
1
ECT, mm
Fig. 27. Cost comparison of slot milling (ar/D = 1) and high-speed milling at (ar/D = 0.03) for 2, 4, and 6 teeth at T = 45 minutes
The feed/tooth for slot milling is fz0 = 0.17 and for high-speed milling at ar/D = 0.03 the feed is fz = 3.69 × fz0 = 0.628 mm. The calculations for total cost are done according to above formula using tooling cost at TV = 6, 10, and 14 minutes, for z = 2, 4, and 6 teeth respectively. The distance cut is Dist = 1000 mm. Full slot milling costs are, at feed rate FR = 3230 and z = 6 ctot = 50 × (1000/3230) × (1 + 14/45)/60 = $0.338 per part at feed rate FR =1480 and z = 2 ctot = 50 × (1000/1480) × (1 + 6/45)/60 = $0.638 per part High-speed milling costs, at FR=18000, z = 6 ctot = 50 × (1000/18000) × (1 + 14/45)/60 = $0.0606 per part at FR= 5250, z = 2 ctot = 50 × (1000/5250) × (1 + 6/45)/60 = $0.180 per part The cost reduction using high-speed milling compared to slotting is enormous. For highspeed milling with 2 teeth, the cost for high-speed milling with 2 teeth is 61 percent (0.208/0.338) of full slot milling with 6 teeth (z = 6). The cost for high-speed milling with 6 teeth is 19 percent (0.0638/0.338) of full slot for z = 6. Aluminium end milling can be run at 3 to 6 times lower costs than when cutting steel. Costs of idle (non-machining) and slack time (waste) are not considered in the example. These data hold for perfect milling conditions such as zero run-out and accurate sharpening of all teeth and edges.
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Machinery's Handbook 27th Edition SCREW MACHINE SPEEDS AND FEEDS
1131
SCREW MACHINE FEEDS AND SPEEDS Feeds and Speeds for Automatic Screw Machine Tools.—Approximate feeds and speeds for standard screw machine tools are given in the accompanying table. Knurling in Automatic Screw Machines.—When knurling is done from the cross slide, it is good practice to feed the knurl gradually to the center of the work, starting to feed when the knurl touches the work and then passing off the center of the work with a quick rise of the cam. The knurl should also dwell for a certain number of revolutions, depending on the pitch of the knurl and the kind of material being knurled. See also KNURLS AND KNURLING starting on page 1240. When two knurls are employed for spiral and diamond knurling from the turret, the knurls can be operated at a higher rate of feed for producing a spiral than they can for producing a diamond pattern. The reason for this is that in the first case the knurls work in the same groove, whereas in the latter case they work independently of each other. Revolutions Required for Top Knurling.—The depth of the teeth and the feed per revolution govern the number of revolutions required for top knurling from the cross slide. If R is the radius of the stock, d is the depth of the teeth, c is the distance the knurl travels from the point of contact to the center of the work at the feed required for knurling, and r is the radius of the knurl; then c =
2
(R + r) – (R + r – d)
2
For example, if the stock radius R is 5⁄32 inch, depth of teeth d is 0.0156 inch, and radius of knurl r is 0.3125 inch, then 2
c = ( 0.1562 + 0.3125 ) – ( 0.1562 + 0.3125 – 0.0156 ) = 0.120 inch = cam rise required
2
Assume that it is required to find the number of revolutions to knurl a piece of brass 5⁄16 inch in diameter using a 32 pitch knurl. The included angle of the teeth for brass is 90 degrees, the circular pitch is 0.03125 inch, and the calculated tooth depth is 0.0156 inch. The distance c (as determined in the previous example) is 0.120 inch. Referring to the accompanying table of feeds and speeds, the feed for top knurling brass is 0.005 inch per revolution. The number of revolutions required for knurling is, therefore, 0.120 ÷ 0.005 = 24 revolutions. If conditions permit, the higher feed of 0.008 inch per revolution given in the table may be used, and 15 revolutions are then required for knurling. Cams for Threading.—The table Spindle Revolutions and Cam Rise for Threading on page 1134 gives the revolutions required for threading various lengths and pitches and the corresponding rise for the cam lobe. To illustrate the use of this table, suppose a set of cams is required for threading a screw to the length of 3⁄8 inch in a Brown & Sharpe machine. Assume that the spindle speed is 2400 revolutions per minute; the number of revolutions to complete one piece, 400; time required to make one piece, 10 seconds; pitch of the thread, 1⁄ inch or 32 threads per inch. By referring to the table, under 32 threads per inch, and 32 opposite 3⁄8 inch (length of threaded part), the number of revolutions required is found to be 15 and the rise required for the cam, 0.413 inch.
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Machinery's Handbook 27th Edition
Cut
Tool Boring tools
Finishing Center drills Angular Circular Straight Stock diameter under 1⁄8 in. Button Dies { Chaser Cutoff tools {
Drills, twist cut
Form tools, circular
{
Dia. of Hole, Inches … … … … … … … Under 1⁄8 Over 1⁄8 … … … … … … 0.02 0.04 1⁄ 16 3⁄ 32 1⁄ 8 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ –5⁄ 8 8 … … … … … … …
Brassa Feed, Inches per Rev. … 0.012 0.010 0.008 0.008 0.006 0.010 0.003 0.006 0.0015 0.0035 0.0035 0.002 … … 0.0014 0.002 0.004 0.006 0.009 0.012 0.014 0.016 0.016 0.002 0.002 0.0015 0.0012 0.001 0.001 0.001
Feed, Inches per Rev. 0.008 0.010 0.008 0.007 0.006 0.005 0.010 0.0015 0.0035 0.0006 0.0015 0.0015 0.0008 … … 0.001 0.0014 0.002 0.0025 0.0035 0.004 0.005 0.005 0.006 0.0009 0.0008 0.0007 0.0006 0.0005 0.0005 0.0004
Material to be Machined Mild or Soft Steel Tool Steel, 0.80–1.00% C Surface Speed, Feet per Min. Surface Speed, Feet per Min. Feed, Carbon H.S.S. Carbon H.S.S. Inches Tools Tools Tools Tools per Rev. 50 110 0.004 30 60 70 150 0.005 40 75 70 150 0.004 40 75 70 150 0.003 40 75 70 150 0.002 40 75 70 150 0.0015 40 75 70 150 0.006 40 75 50 110 0.001 30 75 50 110 0.002 30 75 80 150 0.0004 50 85 80 150 0.001 50 85 80 150 0.001 50 85 80 150 0.0005 50 85 30 … … 14 … 30 40 … 16 20 40 60 0.0006 30 45 40 60 0.0008 30 45 40 60 0.0012 30 45 40 60 0.0016 30 45 40 75 0.002 30 60 40 75 0.003 30 60 40 75 0.003 30 60 40 75 0.0035 30 60 40 85 0.004 30 60 80 150 0.0006 50 85 80 150 0.0005 50 85 80 150 0.0004 50 85 80 150 0.0004 50 85 80 150 0.0003 50 85 80 150 0.0003 50 85 80 150 … … …
Copyright 2004, Industrial Press, Inc., New York, NY
SCREW MACHINE SPEEDS AND FEEDS
Box tools, roller rest Single chip finishing
Width or Depth, Inches 0.005 1⁄ 32 1⁄ 16 1⁄ 8 3⁄ 16 1⁄ 4 0.005 … … … 3⁄ –1⁄ 64 8 1⁄ –1⁄ 16 8 … … … … … … … … … … … … 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4 1
1132
Approximate Cutting Speeds and Feeds for Standard Automatic Screw Machine Tools—Brown and Sharpe
Machinery's Handbook 27th Edition
Approximate Cutting Speeds and Feeds for Standard Automatic Screw Machine Tools—Brown and Sharpe (Continued) Cut
Tool Turned diam. under 5⁄32 in. {
Turned diam. over 5⁄32 in.
{
Turret
{
Knee tools
Knurling tools {
Side or swing
{
Top
{
End cut
{
Pointing and facing tools Reamers and bits
Recessing tools { Inside cut
Swing tools, forming
Turning, straight and taperb Taps
1⁄ –1⁄ 16 8 1⁄ 8 1⁄ 4 3⁄ 8 1⁄ 2 1⁄ 32 1⁄ 16 1⁄ 8 3⁄ 16
…
Dia. of Hole, Inches … … … … … … … … … … … … … … … … 1⁄ or less 8 1⁄ or over 8 … … … … … … … … … … … … …
Brassa
{ {
Feed, Inches per Rev. 0.012 0.010 0.017 0.015 0.012 0.010 0.009 … 0.020 0.040 0.004 0.006 0.005 0.008 0.001 0.0025 0.010 – 0.007 0.010 0.001 0.005 0.0025 0.0008 0.002 0.0012 0.001 0.0008 0.008 0.006 0.005 0.004 …
Feed, Inches per Rev. 0.010 0.009 0.014 0.012 0.010 0.008 0.007 0.010 0.015 0.030 0.002 0.004 0.003 0.006 0.0008 0.002 0.008 – 0.006 0.010 0.0006 0.003 0.002 0.0006 0.0007 0.0005 0.0004 0.0003 0.006 0.004 0.003 0.0025 …
Material to be Machined Mild or Soft Steel Tool Steel, 0.80–1.00% C Surface Speed, Feet per Min. Surface Speed, Feet per Min. Feed, Carbon H.S.S. Inches Carbon H.S.S. Tools Tools per Rev. Tools Tools 70 150 0.008 40 85 70 150 0.006 40 85 70 150 0.010 40 85 70 150 0.008 40 85 70 150 0.008 40 85 70 150 0.006 40 85 70 150 0.0045 40 85 70 150 0.008 40 85 150 … 0.010 105 … 150 … 0.025 105 … 150 … 0.002 105 … 150 … 0.003 105 … 150 … 0.002 105 … 150 … 0.004 105 … 70 150 0.0005 40 80 70 150 0.0008 40 80 70 105 0.006 – 0.004 40 60 70 105 0.006 – 0.008 40 60 70 150 0.0004 40 75 70 150 0.002 40 75 70 105 0.0015 40 60 70 105 0.0004 40 60 70 150 0.0005 40 85 70 150 0.0003 40 85 70 150 0.0002 40 85 70 150 0.0002 40 85 70 150 0.0035 40 85 70 150 0.003 40 85 70 150 0.002 40 85 70 150 0.0015 40 85 25 30 … 12 15
b For taper turning use feed slow enough for greatest depth depth of cut.
Copyright 2004, Industrial Press, Inc., New York, NY
1133
a Use maximum spindle speed on machine.
SCREW MACHINE SPEEDS AND FEEDS
Hollow mills and balance turning tools {
Width or Depth, Inches 1⁄ 32 1⁄ 16 1⁄ 32 1⁄ 16 1⁄ 8 3⁄ 16 1⁄ 4 1⁄ 32 On Off … … … … … … 0.003 – 0.004 0.004 – 0.008 … …
Machinery's Handbook 27th Edition
1134
Spindle Revolutions and Cam Rise for Threading Number of Threads per Inch Length of Threaded Portion, Inch
1⁄ 8
3⁄ 16
1⁄ 4
5⁄ 16
3⁄ 8
7⁄ 16
1⁄ 2
9⁄ 16
5⁄ 8
11⁄ 16
3⁄ 4
72
64
56
48
40
36
32
30
28
24
20
18
16
9.50
9.00
8.50
8.00
6.00
5.50
5.50
5.00
5.00
5.00
3.00
…
…
…
0.107
0.113
0.120
0.129
0.110
0.121
0.134
0.138
0.147
0.157
0.106
…
…
…
9.00
8.00
7.00
7.00
7.00
6.50
4.50
14
First Line: Revolutions of Spindle for Threading. Second Line: Rise on Cam for Threading, Inch
14.50 0.163 19.50 0.219 24.50 0.276 29.50 0.332 34.50 0.388 39.50 0.444 44.50 0.501 49.50 0.559 54.50 0.613 59.50 0.679 64.50 0.726
13.50 0.169 18.00 0.225 23.508 0.294 27.00 0.338 31.50 0.394 36.00 0.450 40.50 0.506 45.00 0.563 49.50 0.619 54.00 0.675 58.50 0.731
12.50 0.176 16.50 0.232 20.50 0.288 24.50 0.345 28.50 0.401 32.50 0.457 36.50 0.513 40.50 0.570 44.50 0.626 48.50 0.682 52.50 0.738
11.50 0.185 15.00 0.241 18.50 0.297 22.00 0.354 25.50 0.410 29.00 0.466 32.50 0.522 36.00 0.579 39.50 0.635 43.00 0.691 46.50 0.747
0.165 12.00 0.220 15.00 0.275 18.00 0.340 21.00 0.385 24.00 0.440 27.00 0.495 30.00 0.550 33.00 0.605 36.00 0.660 39.00 0.715
0.176 10.50 0.231 13.00 0.286 15.50 0.341 18.00 0.396 20.50 0.451 23.00 0.506 25.50 0.561 28.00 0.616 30.50 0.671 33.00 0.726
0.171 10.00 0.244 12.00 0.293 14.50 0.354 16.50 0.403 19.00 0.464 21.00 0.513 23.50 0.574 25.50 0.623 28.00 0.684 30.00 0.733
4.00
3.50
3.50
0.193
0.205
0.204
0.159
0.170
0.165
0.186
9.00
8.50
8.50
6.00
5.50
5.00
4.50
0.248 11.00 0.303 13.00 0.358 15.00 0.413 17.00 0.468 19.00 0.523 21.00 0.578 23.00 0.633 25.00 0.688 27.00 0.743
0.249 10.50 0.308 12.50 0.367 14.50 0.425 16.00 0.469 18.00 0.528 20.00 0.587 22.00 0.645 23.50 0.689 25.50 0.748
0.267 10.00 0.314 12.00 0.377 13.50 0.424 15.50 0.487 17.00 0.534 19.00 0.597 20.50 0.644 22.50 0.707 24.00 0.754
Copyright 2004, Industrial Press, Inc., New York, NY
… … … … 4.00
0.213
0.234
0.236
0.239
0.243
7.50
6.50
6.00
5.50
5.00
0.266
0.276
0.283
0.292
0.304
9.00
8.00
7.00
6.50
6.00
0.319 10.50 0.372 12.00 0.425 13.50 0.478 15.00 0.531 16.50 0.584 18.00 0.638 19.50 0.691
0.340
0.330
0.345
0.364
9.00
8.50
7.50
7.00
0.383 10.50 0.446 11.50 0.489 13.00 0.553 14.00 0.595 15.50 0.659 16.50 0.701
0.401
0.398
0.425
9.50
8.50
7.50
0.448 10.50 0.496 11.50 0.543 13.00 0.614 14.00 0.661 15.00 0.708
0.451
0.455
9.50
8.50
0.504 10.50 0.558 11.50 0.611 12.50 0.664 13.50 0.717
0.516 9.50 0.577 10.50 0.637 11.00 0.668 12.00 0.728
CAMS THREADING ON SCREW MACHINES
1⁄ 16
80
Machinery's Handbook 27th Edition SCREW MACHINE CAM AND TOOL DESIGN
1135
Threading cams are often cut on a circular milling attachment. When this method is employed, the number of minutes the attachment should be revolved for each 0.001 inch rise, is first determined. As 15 spindle revolutions are required for threading and 400 for completing one piece, that part of the cam surface required for the actual threading operation equals 15 ÷ 400 = 0.0375, which is equivalent to 810 minutes of the circumference. The total rise, through an arc of 810 minutes is 0.413 inch, so the number of minutes for each 0.001 inch rise equals 810 ÷ 413 = 1.96 or, approximately, two minutes. If the attachment is graduated to read to five minutes, the cam will be fed laterally 0.0025 inch each time it is turned through five minutes of arc. Practical Points on Cam and Tool Design.—The following general rules are given to aid in designing cams and special tools for automatic screw machines, and apply particularly to Brown and Sharpe machines: 1) Use the highest speeds recommended for the material used that the various tools will stand. 2) Use the arrangement of circular tools best suited for the class of work. 3) Decide on the quickest and best method of arranging the operations before designing the cams. 4) Do not use turret tools for forming when the cross-slide tools can be used to better advantage. 5) Make the shoulder on the circular cutoff tool large enough so that the clamping screw will grip firmly. 6) Do not use too narrow a cutoff blade. 7) Allow 0.005 to 0.010 inch for the circular tools to approach the work and 0.003 to 0.005 inch for the cutoff tool to pass the center. 8) When cutting off work, the feed of the cutoff tool should be decreased near the end of the cut where the piece breaks off. 9) When a thread is cut up to a shoulder, the piece should be grooved or necked to make allowance for the lead on the die. An extra projection on the forming tool and an extra amount of rise on the cam will be needed. 10) Allow sufficient clearance for tools to pass one another. 11) Always make a diagram of the cross-slide tools in position on the work when difficult operations are to be performed; do the same for the tools held in the turret. 12) Do not drill a hole the depth of which is more than 3 times the diameter of the drill, but rather use two or more drills as required. If there are not enough turret positions for the extra drills needed, make provision for withdrawing the drill clear of the hole and then advancing it into the hole again. 13) Do not run drills at low speeds. Feeds and speeds recommended in the table starting on page 1132 should be followed as far as is practicable. 14) When the turret tools operate farther in than the face of the chuck, see that they will clear the chuck when the turret is revolved. 15) See that the bodies of all turret tools will clear the side of the chute when the turret is revolved. 16) Use a balance turning tool or a hollow mill for roughing cuts. 17) The rise on the thread lobe should be reduced so that the spindle will reverse when the tap or die holder is drawn out. 18) When bringing another tool into position after a threading operation, allow clearance before revolving the turret. 19) Make provision to revolve the turret rapidly, especially when pieces are being made in from three to five seconds and when only a few tools are used in the turret. It is sometimes desirable to use two sets of tools. 20) When using a belt-shifting attachment for threading, clearance should be allowed, as it requires extra time to shift the belt.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1136
SCREW MACHINE
21) When laying out a set of cams for operating on a piece that requires to be slotted, cross-drilled or burred, allowance should be made on the lead cam so that the transferring arm can descend and ascend to and from the work without coming in contact with any of the turret tools. 22) Always provide a vacant hole in the turret when it is necessary to use the transferring arm. 23) When designing special tools allow as much clearance as possible. Do not make them so that they will just clear each other, as a slight inaccuracy in the dimensions will often cause trouble. 24) When designing special tools having intricate movements, avoid springs as much as possible, and use positive actions. Stock for Screw Machine Products.—The amount of stock required for the production of 1000 pieces on the automatic screw machine can be obtained directly from the table Stock Required for Screw Machine Products. To use this table, add to the length of the work the width of the cut-off tool blade; then the number of feet of material required for 1000 pieces can be found opposite the figure thus obtained, in the column headed “Feet per 1000 Parts.” Screw machine stock usually comes in bars 10 feet long, and in compiling this table an allowance was made for chucking on each bar. The table can be extended by using the following formula, in which F =number of feet required for 1000 pieces L =length of piece in inches W =width of cut-off tool blade in inches F = ( L + W ) × 84 The amount to add to the length of the work, or the width of the cut-off tool, is given in the following, which is standard in a number of machine shops: Diameter of Stock, Inches Width of Cut-off Tool Blade, Inches 0.000–0.250 0.045 0.251–0.375 0.062 0.376–0.625 0.093 0.626–1.000 0.125 1.001–1.500 0.156
It is sometimes convenient to know the weight of a certain number of pieces, when estimating the price. The weight of round bar stock can be found by means of the following formulas, in which W =weight in pounds D =diameter of stock in inches F =length in feet For brass stock: W = D2 × 2.86 × F For steel stock: W = D2 × 2.675 × F For iron stock: W = D2 × 2.65 × F
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STOCK FOR SCREW MACHINES
1137
Stock Required for Screw Machine Products The table gives the amount of stock, in feet, required for 1000 pieces, when the length of the finished part plus the thickness of the cut-off tool blade is known. Allowance has been made for chucking. To illustrate, if length of cut-off tool and work equals 0.140 inch, 11.8 feet of stock is required for the production of 1000 parts. Length of Piece and Cut-Off Tool
Feet per 1000 Parts
Length of Piece and Cut-Off Tool
Feet per 1000 Parts
Length of Piece and Cut-Off Tool
0.050 0.060 0.070 0.080 0.090 0.100 0.110 0.120 0.130 0.140 0.150 0.160 0.170 0.180 0.190 0.200 0.210 0.220 0.230 0.240 0.250 0.260 0.270 0.280 0.290 0.300 0.310 0.320 0.330 0.340 0.350 0.360 0.370 0.380 0.390 0.400 0.410 0.420
4.2 5.0 5.9 6.7 7.6 8.4 9.2 10.1 10.9 11.8 12.6 13.4 14.3 15.1 16.0 16.8 17.6 18.5 19.3 20.2 21.0 21.8 22.7 23.5 24.4 25.2 26.1 26.9 27.7 28.6 29.4 30.3 31.1 31.9 32.8 33.6 34.5 35.3
0.430 0.440 0.450 0.460 0.470 0.480 0.490 0.500 0.510 0.520 0.530 0.540 0.550 0.560 0.570 0.580 0.590 0.600 0.610 0.620 0.630 0.640 0.650 0.660 0.670 0.680 0.690 0.700 0.710 0.720 0.730 0.740 0.750 0.760 0.770 0.780 0.790 0.800
36.1 37.0 37.8 38.7 39.5 40.3 41.2 42.0 42.9 43.7 44.5 45.4 46.2 47.1 47.9 48.7 49.6 50.4 51.3 52.1 52.9 53.8 54.6 55.5 56.3 57.1 58.0 58.8 59.7 60.5 61.3 62.2 63.0 63.9 64.7 65.5 66.4 67.2
0.810 0.820 0.830 0.840 0.850 0.860 0.870 0.880 0.890 0.900 0.910 0.920 0.930 0.940 0.950 0.960 0.970 0.980 0.990 1.000 1.020 1.040 1.060 1.080 1.100 1.120 1.140 1.160 1.180 1.200 1.220 1.240 1.260 1.280 1.300 1.320 1.340 1.360
Feet per 1000 Parts 68.1 68.9 69.7 70.6 71.4 72.3 73.1 73.9 74.8 75.6 76.5 77.3 78.2 79.0 79.8 80.7 81.5 82.4 83.2 84.0 85.7 87.4 89.1 90.8 92.4 94.1 95.8 97.5 99.2 100.8 102.5 104.2 105.9 107.6 109.2 110.9 112.6 114.3
Length of Piece and Cut-Off Tool
Feet per 1000 Parts
1.380 1.400 1.420 1.440 1.460 1.480 1.500 1.520 1.540 1.560 1.580 1.600 1.620 1.640 1.660 1.680 1.700 1.720 1.740 1.760 1.780 1.800 1.820 1.840 1.860 1.880 1.900 1.920 1.940 1.960 1.980 2.000 2.100 2.200 2.300 2.400 2.500 2.600
116.0 117.6 119.3 121.0 122.7 124.4 126.1 127.7 129.4 131.1 132.8 134.5 136.1 137.8 139.5 141.2 142.9 144.5 146.2 147.9 149.6 151.3 152.9 154.6 156.3 158.0 159.7 161.3 163.0 164.7 166.4 168.1 176.5 184.9 193.3 201.7 210.1 218.5
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1138
BAND SAW BLADES
Band Saw Blade Selection.—The primary factors to consider in choosing a saw blade are: the pitch, or the number of teeth per inch of blade; the tooth form; and the blade type (material and construction). Tooth pitch selection depends on the size and shape of the work, whereas tooth form and blade type depend on material properties of the workpiece and on economic considerations of the job.
30
26 25 24 23 28 27 22
29
21
20 19
35
.75 1.5
18 17
40
16 15 14
.75 1.5
45 .75 1.5
50 800 900 1000 1250
55 Inch 0 .1
mm
14 18 14 18
14 18
.2 .3
5 10 15 20 25
10 14 8 12
10 14
10 14
6 10
4 6
.8
4 6
.9 1
11 4
1.5 2.5
9 2 3
75
8
2 3
5 8
1
1
2
11 10
1.5 2.5
3 4
5 8
.7
12
150 100
4 6 6 10
6 10
13
1.5 2.5
500 450 400 350 300 250 200
50
5 8
8 12
8 12
.4 .5 .6
700 600
7
2 3
3 4
6 5
3 4
13 4 2 1 4 1 23 4 3 31 4 3 2 2 2
1
2
33 4
4
Courtesy of American Saw and Manufacturing Company
The tooth selection chart above is a guide to help determine the best blade pitch for a particular job. The tooth specifications in the chart are standard variable-pitch blade sizes as specified by the Hack and Band Saw Association. The variable-pitch blades listed are designated by two numbers that refer to the approximate maximum and minimum tooth pitch. A 4⁄6 blade, for example, has a maximum tooth spacing of approximately 1⁄4 inch and a minimum tooth spacing of about 1⁄6 inch. Blades are available, from most manufacturers, in sizes within about ±10 per cent of the sizes listed. To use the chart, locate the length of cut in inches on the outside circle of the table (for millimeters use the inside circle) and then find the tooth specification that aligns with the length, on the ring corresponding to the material shape. The length of cut is the distance that any tooth of the blade is in contact with the work as it passes once through the cut. For cutting solid round stock, use the diameter as the length of cut and select a blade from the ring with the solid circle. When cutting angles, channels, I-beams, tubular pieces, pipe, and hollow or irregular shapes, the length of cut is found by dividing the cross-sectional area of the cut by the distance the blade needs to travel to finish the cut. Locate the length of cut on the outer ring (inner ring for mm) and select a blade from the ring marked with the angle, Ibeam, and pipe sections. Example:A 4-inch pipe with a 3-inch inside diameter is to be cut. Select a variable pitch blade for cutting this material.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition BAND SAW BLADES
1139
The area of the pipe is π/4 × (42 − 32) = 5.5 in.2 The blade has to travel 4 inches to cut through the pipe, so the average length of cut is 5.5⁄4 = 1.4 inches. On the tooth selection wheel, estimate the location of 1.4 inches on the outer ring, and read the tooth specification from the ring marked with the pipe, angle, and I-beam symbols. The chart indicates that a 4⁄6 variable-pitch blade is the preferred blade for this cut. Tooth Forms.—Band saw teeth are characterized by a tooth form that includes the shape, spacing (pitch), rake angle, and gullet capacity of the tooth. Tooth form affects the cutting efficiency, noise level, blade life, chip-carrying capacity, and the surface finish quality of the cut. The rake angle, which is the angle between the face of the tooth and a line perpendicular to the direction of blade travel, influences the cutting speed. In general, positive rake angles cut faster. The standard tooth form has conventional shape teeth, evenly spaced with deep gullets and a 0° rake angle. Standard tooth blades are used for generalpurpose cutting on a wide variety of materials. The skip tooth form has shallow, widely spaced teeth arranged in narrow bands and a 0° rake angle. Skip tooth blades are used for cutting soft metals, wood, plastics, and composite materials. The hook tooth form is similar to the skip tooth, but has a positive rake angle and is used for faster cutting of large sections of soft metal, wood, and plastics, as well as for cutting some metals, such as cast iron, that form a discontinuous chip. The variable-tooth (variable-pitch) form has a conventional tooth shape, but the tips of the teeth are spaced a variable distance (pitch) apart. The variable pitch reduces vibration of the blade and gives smoother cutting, better surface finish, and longer blade life. The variable positive tooth form is a variable-pitch tooth with a positive rake angle that causes the blade to penetrate the work faster. The variable positive tooth blade increases production and gives the longest blade life. Set is the angle that the teeth are offset from the straight line of a blade. The set affects the blade efficiency (i.e., cutting rate), chip-carrying ability, and quality of the surface finish. Alternate set blades have adjacent teeth set alternately one to each side. Alternate set blades, which cut faster but with a poorer finish than other blades, are especially useful for rapid rough cutting. A raker set is similar to the alternate set, but every few teeth, one of the teeth is set to the center, not to the side (typically every third tooth, but sometimes every fifth or seventh tooth). The raker set pattern cuts rapidly and produces a good surface finish. The vari-raker set, or variable raker, is a variable-tooth blade with a raker set. The variraker is quieter and produces a better surface finish than a raker set standard tooth blade. Wavy set teeth are set in groups, alternately to one side, then to the other. Both wavy set and vari-raker set blades are used for cutting tubing and other interrupted cuts, but the blade efficiency and surface finish produced are better with a vari-raker set blade. Types of Blades.—The most important band saw blade types are carbon steel, bimetal, carbide tooth, and grit blades made with embedded carbide or diamond. Carbon steel blades have the lowest initial cost, but they may wear out faster. Carbon steel blades are used for cutting a wide variety of materials, including mild steels, aluminum, brass, bronze, cast iron, copper, lead, and zinc, as well as some abrasive materials such as cork, fiberglass, graphite, and plastics. Bimetal blades are made with a high-speed steel cutting edge that is welded to a spring steel blade back. Bimetal blades are stronger and last longer, and they tend to produce straighter cuts because the blade can be tensioned higher than carbon steel blades. Because bimetal blades last longer, the cost per cut is frequently lower than when using carbon steel blades. Bimetal blades are used for cutting all ferrous and nonferrous metals, a wide range of shapes of easy to moderately machinable material, and solids and heavy wall tubing with moderate to difficult machinability. Tungsten carbide blades are similar to bimetal blades but have tungsten carbide teeth welded to the blade back. The welded teeth of carbide blades have greater wear and high-temperature resistance than either carbon steel or bimetal blades and produce less tooth vibration, while giving smoother, straighter, faster, and quieter cuts requiring less feed force. Carbide blades are used on tough alloys such as cobalt, nickel- and titanium-based alloys, and for nonferrous materials such as aluminum castings, fiberglass, and graphite. The carbide grit blade
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1140
BAND SAW BLADES
has tungsten carbide grit metallurgically bonded to either a gulleted (serrated) or toothless steel band. The blades are made in several styles and grit sizes. Both carbide grit and diamond grit blades are used to cut materials that conventional (carbon and bimetal) blades are unable to cut such as: fiberglass, reinforced plastics, composite materials, carbon and graphite, aramid fibers, plastics, cast iron, stellites, high-hardness tool steels, and superalloys. Band Saw Speed and Feed Rate.—The band speed necessary to cut a particular material is measured in feet per minute (fpm) or in meters per minute (m/min), and depends on material characteristics and size of the workpiece. Typical speeds for a bimetal blade cutting 4-inch material with coolant are given in the speed selection table that follows. For other size materials or when cutting without coolant, adjust speeds according to the instructions at the bottom of the table.
Cutting Rate (in.2/min)
LIVE GRAPH Click here to view
30 28 26 24 22 20 18 16 14 12 10 8 6 4 2 0
0.75 1.5 1.5 2.5
23 34
46
58 8 12
0
50
100 150 200 250 300 350 400 450 500 550 600 Band Speed (ft/min)
Cutting Rates for Band Saws The feed or cutting rate, usually measured in square inches or square meters per minute, indicates how fast material is being removed and depends on the speed and pitch of the blade, not on the workpiece material. The graph above, based on material provided by American Saw and Mfg., gives approximate cutting rates (in.2/min) for various variablepitch blades and cutting speeds. Use the value from the graph as an initial starting value and then adjust the feed based on the performance of the saw. The size and character of the chips being produced are the best indicators of the correct feed force. Chips that are curly, silvery, and warm indicate the best feed rate and band speed. If the chips appear burned and heavy, the feed is too great, so reduce the feed rate, the band speed, or both. If the chips are thin or powdery, the feed rate is too low, so increase the feed rate or reduce the band speed. The actual cutting rate achieved during a cut is equal to the area of the cut divided by the time required to finish the cut. The time required to make a cut is equal to the area of the cut divided by the cutting rate in square inches per minute.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition BAND SAW BLADES
1141
Bimetal Band Saw Speeds for Cutting 4-Inch Material with Coolant Material Aluminum Alloys Cast Iron
Cobalt Copper
Iron Base Super Alloy Magnesium Nickel Nickel Alloy
Stainless Steel
Category (AISI/SAE) 1100, 2011, 2017, 2024, 3003, 5052, 5086, 6061, 6063, 6101, 6262, 7075 A536 (60-40-18) A47 A220 (50005), A536 (80-55-06) A48 (20 ksi) A536 (100-70-03) A48 (40 ksi) A220 (60004) A436 (1B) A220 (70003) A436 (2) A220 (80002), A436 (2B) A536 (120-90-02) A220 (90001), A48 (60 ksi) A439 (D-2) A439 (D-2B) WF-11 Astroloy M 356, 360 353 187, 1452 380, 544 173, 932, 934 330, 365 623, 624 230, 260, 272, 280, 464, 632, 655 101, 102, 110, 122, 172, 17510, 182, 220, 510, 625, 706, 715 630 811 Pyromet X-15 A286, Incoloy 800 and 801 AZ31B Nickel 200, 201, 205 Inconel 625 Incoloy 802, 804 Monel R405 20CB3 Monel 400, 401 Hastelloy B, B2, C, C4, C22, C276, F, G, G2, G3, G30, N, S, W, X, Incoloy 825, 926, Inconel 751, X750, Waspaloy Monel K500 Incoloy 901, 903, Inconel 600, 718, Ni-Span-C902, Nimonic 263, Rene 41, Udimet 500 Nimonic 75 416, 420 203EZ, 430, 430F, 4302 303, 303PB, 303SE, 410, 440F, 30323 304 414, 30403 347 316, 31603 Greek Ascoloy 18-18-2, 309, Ferralium 15-5PH, 17-4PH, 17-7PH, 2205, 310, AM350, AM355, Custom 450, Custom 455, PH13-8Mo, PH14-8Mo, PH15-7Mo 22-13-5, Nitronic 50, 60
Speed (fpm) 500
Speed (m/min) 152
360 300 240 230 185 180 170 150 145 140 125 120 100 80 60 65 60 450 400 375 350 315 285 265 245 235 230 215 120 90 900 85 100 90 85 80 75 70
110 91 73 70 56 55 52 46 44 43 38 37 30 24 18 20 18 137 122 114 107 96 87 81 75 72 70 66 37 27 274 26 30 27 26 24 23 21
65 60
20 18
50 190 150 140 120 115 110 100 95 90 80
15 58 46 43 37 35 34 30 29 27 24
60
18
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1142
BAND SAW BLADES
Bimetal Band Saw Speeds for Cutting 4-Inch Material with Coolant (Continued) Material Steel
Titanium
Category (AISI/SAE) 12L14 1213, 1215 1117 1030 1008, 1015, 1020, 1025 1035 1018, 1021, 1022, 1026, 1513, A242 Cor-Ten A 1137 1141, 1144, 1144 Hi Stress 41L40 1040, 4130, A242 Cor-Ten B, (A36 Shapes) 1042, 1541, 4140, 4142 8615, 8620, 8622 W-1 1044, 1045, 1330, 4340, E4340, 5160, 8630 1345, 4145, 6150 1060, 4150, 8640, A-6, O-1, S-1 H-11, H-12, H-13, L-6, O-6 1095 A-2 E9310 300M, A-10, E52100, HY-80, HY-100 S-5 S-7 M-1 HP 9-4-20, HP 9-4-25 M-2, M-42, T1 D-2 T-15 Pure, Ti-3Al-8V-6Cr-4Mo-4Z, Ti-8Mo-8V-2Fe-3Al Ti-2Al-11Sn-5Zr-1Mo, Ti-5Al-2.5Sn, Ti-6Al-2Sn-4Zr-2Mo Ti-6Al-4V Ti-7Al-4Mo, Ti-8Al-1Mo-1V
Speed (fpm) 425 400 340 330 320 310 300 290 280 275 270 250 240 225 220 210 200 190 185 180 175 160 140 125 110 105 100 90 70 80 75 70 65
Speed (m/min) 130 122 104 101 98 94 91 88 85 84 82 76 73 69 67 64 61 58 56 55 53 49 43 38 34 32 30 27 21 24 23 21 20
The speed figures given are for 4-in. material (length of cut) using a 3⁄4 variable-tooth bimetal blade and cutting fluid. For cutting dry, reduce speed 30–50%; for carbon steel band saw blades, reduce speed 50%. For other cutting lengths: increase speed 15% for 1⁄4-in. material (10⁄14 blade); increase speed 12% for 3⁄4-in. material (6⁄10 blade); increase speed 10% for 11⁄4-in. material (4⁄6 blade); decrease speed 12% for 8-in. material (2⁄3 blade). Table data are based on material provided by LENOX Blades, American Saw & Manufacturing Co.
Example:Find the band speed, the cutting rate, and the cutting time if the 4-inch pipe of the previous example is made of 304 stainless steel. The preceding blade speed table gives the band speed for 4-inch 304 stainless steel as 120 fpm (feet per minute). The average length of cut for this pipe (see the previous example) is 1.4 inches, so increase the band saw speed by about 10 per cent (see footnote on ) to 130 fpm to account for the size of the piece. On the cutting rate graph above, locate the point on the 4⁄6 blade line that corresponds to the band speed of 130 fpm and then read the cutting rate from the left axis of the graph. The cutting rate for this example is approximately 4 in. 2/min. The cutting time is equal to the area of the cut divided by the cutting rate, so cutting time = 5.5⁄4 = 1.375 minutes. Band Saw Blade Break-In.—A new band saw blade must be broken in gradually before it is allowed to operate at its full recommended feed rate. Break-in relieves the blade of residual stresses caused by the manufacturing process so that the blade retains its cutting ability longer. Break-in requires starting the cut at the material cutting speed with a low feed rate and then gradually increasing the feed rate over time until enough material has been cut. A blade should be broken in with the material to be cut.
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Machinery's Handbook 27th Edition CUTTING FLUIDS
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To break in a new blade, first set the band saw speed at the recommended cutting speed for the material and start the first cut at the feed indicated on the starting feed rate graph below. After the saw has penetrated the work to a distance equal to the width of the blade, increase the feed slowly. When the blade is about halfway through the cut, increase the feed again slightly and finish the cut without increasing the feed again. Start the next and each successive cut with the same feed rate that ended the previous cut, and increase the feed rate slightly again before the blade reaches the center of the cut. Repeat this procedure until the area cut by the new blade is equal to the total area required as indicated on the graph below. At the end of the break-in period, the blade should be cutting at the recommended feed rate, otherwise adjusted to that rate.
% of Normal Feed
LIVE GRAPH
100 90 80 70 60 50 40 30 20 10 0 ft/min. 40 m/min. 12
Click here to view
80 24
120 37
Starting Feed Rate
160 49
200 61
240 73
280 85
320 98
360 110
Break-In Area
Band Speed (Machinability) LIVE GRAPH Total Break-In Area Required in.2 Click here to view 100 90 80 70 60 50 40 30 20 10 0 ft/min. 40 80 120 160 200 240 280 m/min. 12 24 37 49 61 73 85
cm2 645 580 515 450 385 320 260 195 130 65 0
320 98
360 110
Band Speed (Machinability) Cutting Fluids for Machining The goal in all conventional metal-removal operations is to raise productivity and reduce costs by machining at the highest practical speed consistent with long tool life, fewest rejects, and minimum downtime, and with the production of surfaces of satisfactory accuracy and finish. Many machining operations can be performed “dry,” but the proper application of a cutting fluid generally makes possible: higher cutting speeds, higher feed rates, greater depths of cut, lengthened tool life, decreased surface roughness, increased dimensional accuracy, and reduced power consumption. Selecting the proper cutting fluid for a specific machining situation requires knowledge of fluid functions, properties, and limitations. Cutting fluid selection deserves as much attention as the choice of machine tool, tooling, speeds, and feeds. To understand the action of a cutting fluid it is important to realize that almost all the energy expended in cutting metal is transformed into heat, primarily by the deformation of the metal into the chip and, to a lesser degree, by the friction of the chip sliding against the tool face. With these factors in mind it becomes clear that the primary functions of any cut-
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1144
CUTTING FLUIDS
ting fluid are: cooling of the tool, workpiece, and chip; reducing friction at the sliding contacts; and reducing or preventing welding or adhesion at the contact surfaces, which forms the “built-up edge” on the tool. Two other functions of cutting fluids are flushing away chips from the cutting zone and protecting the workpiece and tool from corrosion. The relative importance of the functions is dependent on the material being machined, the cutting tool and conditions, and the finish and accuracy required on the part. For example, cutting fluids with greater lubricity are generally used in low-speed machining and on most difficult-to-cut materials. Cutting fluids with greater cooling ability are generally used in high-speed machining on easier-to-cut materials. Types of Cutting and Grinding Fluids.—In recent years a wide range of cutting fluids has been developed to satisfy the requirements of new materials of construction and new tool materials and coatings. There are four basic types of cutting fluids; each has distinctive features, as well as advantages and limitations. Selection of the right fluid is made more complex because the dividing line between types is not always clear. Most machine shops try to use as few different fluids as possible and prefer fluids that have long life, do not require constant changing or modifying, have reasonably pleasant odors, do not smoke or fog in use, and, most important, are neither toxic nor cause irritation to the skin. Other issues in selection are the cost and ease of disposal. The major divisions and subdivisions used in classifying cutting fluids are: Cutting Oils, including straight and compounded mineral oils plus additives. Water-Miscible Fluids , including emulsifiable oils; chemical or synthetic fluids; and semichemical fluids. Gases. Paste and Solid Lubricants. Since the cutting oils and water-miscible types are the most commonly used cutting fluids in machine shops, discussion will be limited primarily to these types. It should be noted, however, that compressed air and inert gases, such as carbon dioxide, nitrogen, and Freon, are sometimes used in machining. Paste, waxes, soaps, graphite, and molybdenum disulfide may also be used, either applied directly to the workpiece or as an impregnant in the tool, such as in a grinding wheel. Cutting Oils.—Cutting oils are generally compounds of mineral oil with the addition of animal, vegetable, or marine oils to improve the wetting and lubricating properties. Sulfur, chlorine, and phosphorous compounds, sometimes called extreme pressure (EP) additives, provide for even greater lubricity. In general, these cutting oils do not cool as well as watermiscible fluids. Water-Miscible Fluids.—Emulsions or soluble oils are a suspension of oil droplets in water. These suspensions are made by blending the oil with emulsifying agents (soap and soaplike materials) and other materials. These fluids combine the lubricating and rust-prevention properties of oil with water's excellent cooling properties. Their properties are affected by the emulsion concentration, with “lean” concentrations providing better cooling but poorer lubrication, and with “rich” concentrations having the opposite effect. Additions of sulfur, chlorine, and phosphorus, as with cutting oils, yield “extreme pressure” (EP) grades. Chemical fluids are true solutions composed of organic and inorganic materials dissolved in water. Inactive types are usually clear fluids combining high rust inhibition, high cooling, and low lubricity characteristics with high surface tension. Surface-active types include wetting agents and possess moderate rust inhibition, high cooling, and moderate lubricating properties with low surface tension. They may also contain chlorine and/or sulfur compounds for extreme pressure properties. Semichemical fluids are combinations of chemical fluids and emulsions. These fluids have a lower oil content but a higher emulsifier and surface-active-agent content than
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CUTTING FLUIDS
1145
emulsions, producing oil droplets of much smaller diameter. They possess low surface tension, moderate lubricity and cooling properties, and very good rust inhibition. Sulfur, chlorine, and phosphorus also are sometimes added. Selection of Cutting Fluids for Different Materials and Operations.—The choice of a cutting fluid depends on many complex interactions including the machinability of the metal; the severity of the operation; the cutting tool material; metallurgical, chemical, and human compatibility; fluid properties, reliability, and stability; and finally cost. Other factors affect results. Some shops standardize on a few cutting fluids which have to serve all purposes. In other shops, one cutting fluid must be used for all the operations performed on a machine. Sometimes, a very severe operating condition may be alleviated by applying the “right” cutting fluid manually while the machine supplies the cutting fluid for other operations through its coolant system. Several voluminous textbooks are available with specific recommendations for the use of particular cutting fluids for almost every combination of machining operation and workpiece and tool material. In general, when experience is lacking, it is wise to consult the material supplier and/or any of the many suppliers of different cutting fluids for advice and recommendations. Another excellent source is the Machinability Data Center, one of the many information centers supported by the U.S. Department of Defense. While the following recommendations represent good practice, they are to serve as a guide only, and it is not intended to say that other cutting fluids will not, in certain specific cases, also be effective. Steels: Caution should be used when using a cutting fluid on steel that is being turned at a high cutting speed with cemented carbide cutting tools. See Application of Cutting Fluids to Carbides later. Frequently this operation is performed dry. If a cutting fluid is used, it should be a soluble oil mixed to a consistency of about 1 part oil to 20 to 30 parts water. A sulfurized mineral oil is recommended for reaming with carbide tipped reamers although a heavy-duty soluble oil has also been used successfully. The cutting fluid recommended for machining steel with high speed cutting tools depends largely on the severity of the operation. For ordinary turning, boring, drilling, and milling on medium and low strength steels, use a soluble oil having a consistency of 1 part oil to 10 to 20 parts water. For tool steels and tough alloy steels, a heavy-duty soluble oil having a consistency of 1 part oil to 10 parts water is recommended for turning and milling. For drilling and reaming these materials, a light sulfurized mineral-fatty oil is used. For tough operations such as tapping, threading, and broaching, a sulfochlorinated mineralfatty oil is recommended for tool steels and high-strength steels, and a heavy sulfurized mineral-fatty oil or a sulfochlorinated mineral oil can be used for medium- and lowstrength steels. Straight sulfurized mineral oils are often recommended for machining tough, stringy low carbon steels to reduce tearing and produce smooth surface finishes. Stainless Steel: For ordinary turning and milling a heavy-duty soluble oil mixed to a consistency of 1 part oil to 5 parts water is recommended. Broaching, threading, drilling, and reaming produce best results using a sulfochlorinated mineral-fatty oil. Copper Alloys: Most brasses, bronzes, and copper are stained when exposed to cutting oils containing active sulfur and chlorine; thus, sulfurized and sulfochlorinated oils should not be used. For most operations a straight soluble oil, mixed to 1 part oil and 20 to 25 parts water is satisfactory. For very severe operations and for automatic screw machine work a mineral-fatty oil is used. A typical mineral-fatty oil might contain 5 to 10 per cent lard oil with the remainder mineral oil. Monel Metal: When turning this material, an emulsion gives a slightly longer tool life than a sulfurized mineral oil, but the latter aids in chip breakage, which is frequently desirable. Aluminum Alloys: Aluminum and aluminum alloys are frequently machined dry. When a cutting fluid is used it should be selected for its ability to act as a coolant. Soluble oils mixed to a consistency of 1 part oil to 20 to 30 parts water can be used. Mineral oil-base
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1146
CUTTING FLUIDS
cutting fluids, when used to machine aluminum alloys, are frequently cut back to increase their viscosity so as to obtain good cooling characteristics and to make them flow easily to cover the tool and the work. For example, a mineral-fatty oil or a mineral plus a sulfurized fatty oil can be cut back by the addition of as much as 50 per cent kerosene. Cast Iron: Ordinarily, cast iron is machined dry. Some increase in tool life can be obtained or a faster cutting speed can be used with a chemical cutting fluid or a soluble oil mixed to consistency of 1 part oil and 20 to 40 parts water. A soluble oil is sometimes used to reduce the amount of dust around the machine. Magnesium: Magnesium may be machined dry, or with an air blast for cooling. A light mineral oil of low acid content may be used on difficult cuts. Coolants containing water should not be used on magnesium because of the danger of releasing hydrogen caused by reaction of the chips with water. Proprietary water-soluble oil emulsions containing inhibitors that reduce the rate of hydrogen generation are available. Grinding: Soluble oil emulsions or emulsions made from paste compounds are used extensively in precision grinding operations. For cylindrical grinding, 1 part oil to 40 to 50 parts water is used. Solution type fluids and translucent grinding emulsions are particularly suited for many fine-finish grinding applications. Mineral oil-base grinding fluids are recommended for many applications where a fine surface finish is required on the ground surface. Mineral oils are used with vitrified wheels but are not recommended for wheels with rubber or shellac bonds. Under certain conditions the oil vapor mist caused by the action of the grinding wheel can be ignited by the grinding sparks and explode. To quench the grinding spark a secondary coolant line to direct a flow of grinding oil below the grinding wheel is recommended. Broaching: For steel, a heavy mineral oil such as sulfurized oil of 300 to 500 Saybolt viscosity at 100 degrees F can be used to provide both adequate lubricating effect and a dampening of the shock loads. Soluble oil emulsions may be used for the lighter broaching operations. Cutting Fluids for Turning, Milling, Drilling and Tapping.—The following table, Cutting Fluids Recommended for Machining Operations, gives specific cutting oil recommendations for common machining operations. Soluble Oils: Types of oils paste compounds that form emulsions when mixed with water: Soluble oils are used extensively in machining both ferrous and non-ferrous metals when the cooling quality is paramount and the chip-bearing pressure is not excessive. Care should be taken in selecting the proper soluble oil for precision grinding operations. Grinding coolants should be free from fatty materials that tend to load the wheel, thus affecting the finish on the machined part. Soluble coolants should contain rust preventive constituents to prevent corrosion. Base Oils: Various types of highly sulfurized and chlorinated oils containing inorganic, animal, or fatty materials. This “base stock” usually is “cut back” or blended with a lighter oil, unless the chip-bearing pressures are high, as when cutting alloy steel. Base oils usually have a viscosity range of from 300 to 900 seconds at 100 degrees F. Mineral Oils: This group includes all types of oils extracted from petroleum such as paraffin oil, mineral seal oil, and kerosene. Mineral oils are often blended with base stocks, but they are generally used in the original form for light machining operations on both freemachining steels and non-ferrous metals. The coolants in this class should be of a type that has a relatively high flash point. Care should be taken to see that they are nontoxic, so that they will not be injurious to the operator. The heavier mineral oils (paraffin oils) usually have a viscosity of about 100 seconds at 100 degrees F. Mineral seal oil and kerosene have a viscosity of 35 to 60 seconds at 100 degrees F.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CUTTING FLUIDS
1147
Cutting Fluids Recommended for Machining Operations Material to be Cut Aluminuma
Turning (or)
Mineral Oil with 10 Per cent Fat Soluble Oil
Milling (or) (or)
25 Per Cent Sulfur base Oilb with 75 Per Cent Mineral Oil Mineral Oil with 10 Per Cent Fat 25 Per Cent Lard Oil with 75 Per Cent Mineral Oil Soluble Oil Soluble Oil Dry Soluble Oil Soluble Oil 10 Per Cent Lard Oil with 90 Per Cent Mineral Oil
Alloy Steelsb Brass Tool Steels and Low-carbon Steels Copper Monel Metal Cast Ironc Malleable Iron Bronze Magnesiumd Material to be Cut
Soluble Oil Soluble Oil Soluble Oil Dry Soluble Oil Soluble Oil Mineral Seal Oil
Drilling Soluble Oil (75 to 90 Per Cent Water)
Aluminume (or)
10 Per Cent Lard Oil with 90 Per Cent Mineral Oil
Alloy Steelsb
Soluble Oil
Brass
Soluble Oil (75 to 90 Per Cent Water) 30 Per Cent Lard Oil with 70 Per Cent Mineral Oil
(or) Tool Steels and Low-carbon Steels
Soluble Oil
Copper
Soluble Oil
Monel Metal
Soluble Oil
Tapping (or) (or) (or)
(or) Dry
Malleable Iron
Soluble Oil
Bronze
Soluble Oil
Magnesiumd
60-second Mineral Oil
Lard Oil Sperm Oil Wool Grease 25 Per Cent Sulfur-base Oilb Mixed with Mineral Oil 30 Per Cent Lard Oil with 70 Per Cent Mineral Oil 10 to 20 Per Cent Lard Oil with Mineral Oil
(or)
Cast Ironc
Soluble Oil (96 Per Cent Water) Mineral Seal Oil Mineral Oil 10 Per Cent Lard Oil with 90 Per Cent Mineral Oil Soluble Oil (96 Per Cent Water)
(or)
25 to 40 Per Cent Lard Oil with Mineral Oil 25 Per Cent Sulfur-base Oilb with 75 Per Cent Mineral Oil Soluble Oil 25 to 40 Per Cent Lard Oil Mixed with Mineral Oil Sulfur-base Oilb Mixed with Mineral Oil Dry 25 Per Cent Lard Oil with 75 Per Cent Mineral Oil Soluble Oil 20 Per Cent Lard Oil with 80 Per Cent Mineral Oil 20 Per Cent Lard Oil with 80 Per Cent Mineral Oil
a In machining aluminum, several varieties of coolants may be used. For rough machining, where the
stock removal is sufficient to produce heat, water soluble mixtures can be used with good results to dissipate the heat. Other oils that may be recommended are straight mineral seal oil; a 50–50 mixture of mineral seal oil and kerosene; a mixture of 10 per cent lard oil with 90 per cent kerosene; and a 100second mineral oil cut back with mineral seal oil or kerosene. b The sulfur-base oil referred to contains 41⁄ per cent sulfur compound. Base oils are usually dark in 2 color. As a rule, they contain sulfur compounds resulting from a thermal or catalytic refinery process. When so processed, they are more suitable for industrial coolants than when they have had such compounds as flowers of sulfur added by hand. The adding of sulfur compounds by hand to the coolant reservoir is of temporary value only, and the non-uniformity of the solution may affect the machining operation. c A soluble oil or low-viscosity mineral oil may be used in machining cast iron to prevent excessive metal dust.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1148
CUTTING FLUIDS
d When a cutting fluid is needed for machining magnesium, low or nonacid mineral seal or lard oils are recommended. Coolants containing water should not be used because of the fire danger when magnesium chips react with water, forming hydrogen gas. e Sulfurized oils ordinarily are not recommended for tapping aluminum; however, for some tapping operations they have proved very satisfactory, although the work should be rinsed in a solvent right after machining to prevent discoloration.
Application of Cutting Fluids to Carbides.—Turning, boring, and similar operations on lathes using carbides are performed dry or with the help of soluble oil or chemical cutting fluids. The effectiveness of cutting fluids in improving tool life or by permitting higher cutting speeds to be used, is less with carbides than with high-speed steel tools. Furthermore, the effectiveness of the cutting fluid is reduced as the cutting speed is increased. Cemented carbides are very sensitive to sudden changes in temperature and to temperature gradients within the carbide. Thermal shocks to the carbide will cause thermal cracks to form near the cutting edge, which are a prelude to tool failure. An unsteady or interrupted flow of the coolant reaching the cutting edge will generally cause these thermal cracks. The flow of the chip over the face of the tool can cause an interruption to the flow of the coolant reaching the cutting edge even though a steady stream of coolant is directed at the tool. When a cutting fluid is used and frequent tool breakage is encountered, it is often best to cut dry. When a cutting fluid must be used to keep the workpiece cool for size control or to allow it to be handled by the operator, special precautions must be used. Sometimes applying the coolant from the front and the side of the tool simultaneously is helpful. On lathes equipped with overhead shields, it is very effective to apply the coolant from below the tool into the space between the shoulder of the work and the tool flank, in addition to applying the coolant from the top. Another method is not to direct the coolant stream at the cutting tool at all but to direct it at the workpiece above or behind the cutting tool. The danger of thermal cracking is great when milling with carbide cutters. The nature of the milling operation itself tends to promote thermal cracking because the cutting edge is constantly heated to a high temperature and rapidly cooled as it enters and leaves the workpiece. For this reason, carbide milling operations should be performed dry. Lower cutting-edge temperatures diminish the danger of thermal cracking. The cuttingedge temperatures usually encountered when reaming with solid carbide or carbide-tipped reamers are generally such that thermal cracking is not apt to occur except when reaming certain difficult-to-machine metals. Therefore, cutting fluids are very effective when used on carbide reamers. Practically every kind of cutting fluid has been used, depending on the job material encountered. For difficult surface-finish problems in holes, heavy duty soluble oils, sulfurized mineral-fatty oils, and sulfochlorinated mineral-fatty oils have been used successfully. On some work, the grade and the hardness of the carbide also have an effect on the surface finish of the hole. Cutting fluids should be applied where the cutting action is taking place and at the highest possible velocity without causing splashing. As a general rule, it is preferable to supply from 3 to 5 gallons per minute for each single-point tool on a machine such as a turret lathe or automatic. The temperature of the cutting fluid should be kept below 110 degrees F. If the volume of fluid used is not sufficient to maintain the proper temperature, means of cooling the fluid should be provided. Cutting Fluids for Machining Magnesium.—In machining magnesium, it is the general but not invariable practice in the United States to use a cutting fluid. In other places, magnesium usually is machined dry except where heat generated by high cutting speeds would not be dissipated rapidly enough without a cutting fluid. This condition may exist when, for example, small tools without much heat-conducting capacity are employed on automatics. The cutting fluid for magnesium should be an anhydrous oil having, at most, a very low acid content. Various mineral-oil cutting fluids are used for magnesium.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CUTTING FLUIDS
1149
Occupational Exposure To Metal working Fluids The term metalworking fluids (MWFs) describes coolants and lubricants used during the fabrication of products from metals and metal substitutes. These fluids are used to prolong the life of machine tools, carry away debris, and protect or treat the surfaces of the material being processed. MWFs reduce friction between the cutting tool and work surfaces, reduce wear and galling, protect surface characteristics, reduce surface adhesion or welding, carry away generated heat, and flush away swarf, chips, fines, and residues. Table 1 describes the four different classes of metal working fluids: Table 1. Classes of Metalworking Fluids (MWFs) MWF
Straight oil (neat oil or cutting oil)
Description
Dilution factor
Highly refined petroleum oils (lubricant-base oils) or other animal, marine, vegetable, or synthetic oils used singly or in combination with or without additives. These are lubricants, none or function to improve the finish on the metal cut, and prevent corrosion.
Combinations of 30% to 85% highly refined, high-viscos1 part concentrate ity lubricant-base oils and emulsifiers that may include other to 5 to 40 parts Soluble oil performance additives. Soluble oils are diluted with water water (emulsifiable oil) before use at ratios of parts water. Semisynthetic
Contain smaller amounts of severely refined lubricant-base 1 part concentrate oil (5 to 30% in the concentrate), a higher proportion of to 10 to 40 parts emulsifiers that may include other performance additives, water and 30 to 50% water.
Synthetica
Contain no petroleum oils and may be water soluble or water dispersible. The simplest synthetics are made with 1 part concentrate organic and inorganic salts dissolved in water. Offer good to 10 to 40 parts rust protection and heat removal but usually have poor lubriwater cating ability. May be formulated with other performance additives. Stable, can be made bioresistant.
a Over the last several decades major changes in the U.S. machine tool industry have increased the consumption of MWFs. Specifically, the use of synthetic MWFs increased as tool and cutting speeds increased.
Occupational Exposures to Metal Working Fluids (MWFs).—W o r k e r s c a n b e exposed to MWFs by inhalation of aerosols (mists) or by skin contact resulting in an increased risk of respiratory (lung) and skin disease. Health effects vary based on the type of MWF, route of exposure, concentration, and length of exposure. Skin contact usually occurs when the worker dips his/her hands into the fluid, floods the machine tool, or handling parts, tools, equipment or workpieces coated with the fluid, without the use of personal protective equipment such as gloves and apron. Skin contact can also result from fluid splashing onto worker from the machine if guarding is absent or inadequate. Inhalation exposures result from breathing MWF mist or aerosol. The amount of mist generated (and the severity of the exposure) depends on a variety of factors: the type of MWF and its application process; the MWF temperature; the specific machining or grinding operation; the presence of splash guarding; and the effectiveness of the ventilation system. In general, the exposure will be higher if the worker is in close proximity to the machine, the operation involves high tool speeds and deep cuts, the machine is not enclosed, or if ventilation equipment was improperly selected or poorly maintained. In addition, high-pressure and/or excessive fluid application, contamination of the fluid with tramp oils, and improper fluid selection and maintenance will tend to result in higher exposure.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1150
CUTTING FLUIDS
Each MWF class consists of a wide variety of chemicals used in different combinations and the risk these chemicals pose to workers may vary because of different manufacturing processes, various degrees of refining, recycling, improperly reclaimed chemicals, different degrees of chemical purity, and potential chemical reactions between components. Exposure to hazardous contaminants in MWFs may present health risks to workers. Contamination may occur from: process chemicals and ancillary lubricants inadvertently introduced; contaminants, metals, and alloys from parts being machined; water and cleaning agents used for routine housekeeping; and, contaminants from other environmental sources at the worksite. In addition, bacterial and fungal contaminants may metabolize and degrade the MWFs to hazardous end-products as well as produce endotoxins. The improper use of biocides to manage microbial growth may result in potential health risks. Attempts to manage microbial growth solely with biocides may result in the emergence of biocide-resistant strains from complex interactions that may occur among different member species or groups within the population. For example, the growth of one species, or the elimination of one group of organisms may permit the overgrowth of another. Studies also suggest that exposure to certain biocides can cause either allergic or contact dermatitis. Fluid Selection, Use, and Application.—The MWFs selected should be as nonirritating and nonsensitizing as possible while remaining consistent with operational requirements. Petroleum-containing MWFs should be evaluated for potential carcinogenicity using ASTM Standard E1687-98, “Determining Carcinogenic Potential of Virgin Base Oils in Metalworking Fluids”. If soluble oil or synthetic MWFs are used, ASTM Standard E149794, “Safe Use of Water-Miscible Metalworking Fluids” should be consulted for safe use guidelines, including those for product selection, storage, dispensing, and maintenance. To minimize the potential for nitrosamine formation, nitrate-containing materials should not be added to MWFs containing ethanolamines. Many factors influence the generation of MWF mists, which can be minimized through the proper design and operation of the MWF delivery system. ANSI Technical Report B11 TR2-1997, “Mist Control Considerations for the Design, Installation and Use of Machine Tools Using Metalworking Fluids” provides directives for minimizing mist and vapor generation. These include minimizing fluid delivery pressure, matching the fluid to the application, using MWF formulations with low oil concentrations, avoiding contamination with tramp oils, minimizing the MWF flow rate, covering fluid reservoirs and return systems where possible, and maintaining control of the MWF chemistry. Also, proper application of MWFs can minimize splashing and mist generation. Proper application includes: applying MWFs at the lowest possible pressure and flow volume consistent with provisions for adequate part cooling, chip removal, and lubrication; applying MWFs at the tool/workpiece interface to minimize contact with other rotating equipment; ceasing fluid delivery when not performing machining; not allowing MWFs to flow over the unprotected hands of workers loading or unloading parts; and using mist collectors engineered for the operation and specific machine enclosures. Properly maintained filtration and delivery systems provide cleaner MWFs, reduce mist, and minimize splashing and emissions. Proper maintenance of the filtration and delivery systems includes: the selection of appropriate filters; ancillary equipment such as chip handling operations, dissolved air-flotation devices, belt-skimmers, chillers or plate and frame heat exchangers, and decantation tanks; guard coolant return trenches to prevent dumping of floor wash water and other waste fluids; covering sumps or coolant tanks to prevent contamination with waste or garbage (e.g., cigarette butts, food, etc.); and, keeping the machine(s) clean of debris. Parts washing before machining can be an important part of maintaining cleaner MWFs. Since all additives will be depleted with time, the MWF and additives concentrations should be monitored frequently so that components and additives can be made up as needed. The MWF should be maintained within the pH and concentration ranges recom-
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Machinery's Handbook 27th Edition CUTTING FLUIDS
1151
mended by the formulator or supplier. MWF temperature should be maintained at the lowest practical level to slow the growth of microorganisms, reduce water losses and changes in viscosity, and–in the case of straight oils–reduce fire hazards. Fluid Maintenance.—Drums, tanks, or other containers of MWF concentrates should be stored appropriately to protect them from outdoor weather conditions and exposure to low or high temperatures. Extreme temperature changes may destabilize the fluid concentrates, especially in the case of concentrates mixed with water, and cause water to seep into unopened drums encouraging bacterial growth. MWFs should be maintained at as low a temperature as is practical. Low temperatures slow the growth of microorganisms, reduce water losses and change in viscosity, and in the case of straight oils, reduce the fire hazard risks. To maintain proper MWF concentrations, neither water nor concentrate should be used to top off the system. The MWF mixture should be prepared by first adding the concentrate to the clean water (in a clean container) and then adding the emulsion to that mixture in the coolant tank. MWFs should be mixed just before use; large amounts should not be stored, as they may deteriorate before use. Personal Protective Clothing: Personal protective clothing and equipment should always be worn when removing MWF concentrates from the original container, mixing and diluting concentrate, preparing additives (including biocides), and adding MWF emulsions, biocides, or other potentially hazardous ingredients to the coolant reservoir. Personal protective clothing includes eye protection or face shields, gloves, and aprons which do not react with but shed MWF ingredients and additives. System Service: Coolant systems should be regularly serviced, and the machines should be rigorously maintained to prevent contamination of the fluids by tramp oils (e.g., hydraulic oils, gear box oils, and machine lubricants leaking from the machines or total loss slideway lubrication). Tramp oils can destabilize emulsions, cause pumping problems, and clog filters. Tramp oils can also float to the top of MWFs, effectively sealing the fluids from the air, allowing metabolic products such as volatile fatty acids, mercaptols, scatols, ammonia, and hydrogen sulfide are produced by the anaerobic and facultative anaerobic species growing within the biofilm to accumulate in the reduced state. When replacing the fluids, thoroughly clean all parts of the system to inhibit the growth of microorganisms growing on surfaces. Some bacteria secrete layers of slime that may grow in stringy configurations that resemble fungal growth. Many bacteria secrete polymers of polysaccharide and/or protein, forming a glycocalyx which cements cells together much as mortar holds bricks. Fungi may grow as masses of hyphae forming mycelial mats. The attached community of microorganisms is called a biofilm and may be very difficult to remove by ordinary cleaning procedures. Biocide Treatment: Biocides are used to maintain the functionality and efficacy of MWFs by preventing microbial overgrowth. These compounds are often added to the stock fluids as they are formulated, but over time the biocides are consumed by chemical and biological demands Biocides with a wide spectrum of biocidal activity should be used to suppress the growth of the widely diverse contaminant population. Only the concentration of biocide needed to meet fluid specifications should be used since overdosing could lead to skin or respiratory irritation in workers, and under-dosing could lead to an inadequate level of microbial control. Ventilation Systems: The ventilation system should be designed and operated to prevent the accumulation or recirculation of airborne contaminants in the workplace. The ventilation system should include a positive means of bringing in at least an equal volume of air from the outside, conditioning it, and evenly distributing it throughout the exhausted area. Exhaust ventilation systems function through suction openings placed near a source of contamination. The suction opening or exhaust hood creates and air motion sufficient to overcome room air currents and any airflow generated by the process. This airflow cap-
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Machinery's Handbook 27th Edition 1152
CUTTING FLUIDS
tures the contaminants and conveys them to a point where they can either be discharged or removed from the airstream. Exhaust hoods are classified by their position relative to the process as canopy, side draft, down draft or enclosure. ANSI Technical Report B11 TR 21997 contains guidelines for exhaust ventilation of machining and grinding operations. Enclosures are the only type of exhaust hood recommended by the ANSI committee. They consist of physical barriers between the process and the worker's environment. Enclosures can be further classified by the extent of the enclosure: close capture (enclosure of the point of operation, total enclosure (enclosure of the entire machine), or tunnel enclosure (continuous enclosure over several machines). If no fresh make up air is introduced into the plant, air will enter the building through open doors and windows, potentially causing cross-contamination of all process areas. Ideally, all air exhausted from the building should be replaced by tempered air from an uncontaminated location. By providing a slight excess of make up air in relatively clean areas and s slight deficit of make up air in dirty areas, cross-contamination can be reduced. In addition, this air can be channeled directly to operator work areas, providing the cleanest possible work environment. Ideally, this fresh air should be supplied in the form of a lowvelocity air shower ( 30 N/µm). These data are then calibrated with the users own data in order to refine the estimate and optimize the grinding process, as discussed in User Calibration of Recommendations. The recommendations are valid for all grinding processes such as plunge grinding, cylindrical, and surface grinding with periphery or side of wheel, as well as for creep feed grinding. The grinding data machinability system is based on the basic parameters equivalent chip thickness ECT, and wheel speed V, and is used to determine specific metal removal rates SMRR and wheel-life T, including the work speed Vw after the grinding depths for roughing and finishing are specified. For each material group, the grinding data machinability system consists of T–V Taylor lines in log-log coordinates for 3 wheel speeds at wheel lives of 1, 10 and 100 minutes wheel-life with 4 different values of equivalent chip thickness ECT. The wheel speeds are designated V1, V10, and V100 respectively. In each table the corresponding specific metal removal rates SMRR are also tabulated and designated as SMRR1, SMRR10 and SMRR100 respectively. The user can select any value of ECT and interpolate between the Taylor lines. These curves look the same in grinding as in the other metal cutting processes and the slope is set at n = 0.26, so each Taylor line is formulated by V × T0.26 = C, where C is a constant tabulated at four ECT values, ECT = 17, 33, 50 and 75 × 10−5 mm, for each material group. Hence, for each value of ECT, V1 × 10.26 = V10 × 100.26 = V100 × 1000.26 = C. Side Feed, Roughing and Finishing.—In cylindrical grinding, the side feed, fs = C × Width, does not impact on the values in the tables, but on the feed rate FR, where the fraction of the wheel width C is usually selected for roughing and in finishing operations, as shown in the following table. Work Material Roughing, C Finishing, C Unhardened Steel 2 ⁄ 3–3⁄ 4 1⁄ 3–3⁄ 8 Stainless Steel 1⁄ 2 1⁄ 4 Cast Iron 3⁄ 4 3⁄ 8 Hardened Steel 1⁄ 2 1⁄ 4 Finishing: The depth of cut in rough grinding is determined by the allowance and usually set at ar = 0.01 to 0.025 mm. The depth of cut for finishing is usually set at ar = 0.0025 mm and accompanied by higher wheel speeds in order to improve surface finish. However, the most important criterion for critical parts is to increase the work speed in order to avoid thermal damage and surface cracks. In cylindrical grinding, a reduction of side feed fs
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Machinery's Handbook 27th Edition GRINDING FEEDS AND SPEEDS
1167
improves Ra as well. Small grit sizes are very important when very small finishes are required. See Figs. 4, 5, and 6 for reference. Terms and Definitions aa =depth of cut ar =radial depth of cut, mm C =fraction of grinding wheel width CEL = cutting edge length, mm CU =Taylor constant D =wheel diameter, mm DIST = grinding distance, mm dw =work diameter, mm ECT = equivalent chip thickness = f(ar,V,Vw,fs), mm Vw fs ( ar + 1 ) = 1 ÷ (V ÷ Vw ÷ ar + 1 ÷ fs) = -----------------------------V = approximately Vw × ar ÷ V = SMRR ÷ V ÷ 1000 = z × fz × ar × aa ÷ CEL ÷ (πD) mm FR = feed rate, mm/min = fs × RPMw for cylindrical grinding = fi × RPMw for plunge (in-feed) grinding fi = in-feed in plunge grinding, mm/rev of work fs =side feed or engaged wheel width in cylindrical grinding = C × Width = aa approximately equal to the cutting edge length CEL Grinding ratio = MRR÷W* = SMRR × T÷W* = 1000 × ECT × V × T÷W* MRR = metal removal rate = SMRR × T = 1000 × fs × ar × Vw mm3/min SMRR = specific metal removal rate obtained by dividing MRR by the engaged wheel width (C × Width) = 1000 × ar × Vw mm3/mm width/min Note: 100 mm3/mm/min = 0.155 in3/in/min, and 1 in3/in/min = 645.16 mm3/mm/min T, TU = wheel-life = Grinding ratio × W ÷ (1000 × ECT × V) minutes tc = grinding time per pass = DIST÷FR min = DIST÷FR + tsp (min) when spark-out time is included = # Strokes × (DIST÷FR + tsp) (min) when spark-out time and strokes are included tsp = spark-out time, minutes V,VU = wheel speed, m/min Vw,VwU = work speed = SMRR ÷ 1000 ÷ ar m/min W* = volume wheel wear, mm3 Width = wheel width (mm) RPM = wheel speed = 1000 × V ÷ D ÷ π rpm RPMw = work speed = 1000 × Vw ÷ Dw ÷ π rpm Relative Grindability.—An overview of grindability of the data base, which must be based on a constant wheel wear rate, or wheel-life, is demonstrated using 10 minutes wheel-life shown in Table 2.
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Machinery's Handbook 27th Edition 1168
GRINDING FEEDS AND SPEEDS Table 2. Grindability Overview Vw
Material Group
ECT × 10−5
V10
SMRR10
Roughing Depth ar = 0.025
1 Unhardened 2 Stainless 3 Cast Iron 4 Tool Steel 5 Tool Steel 6 Tool Steel 7Tool Steel 8 Heat resistant 9 Carbide with Diamond Wheel 10 Ceramics with Diamond Wheel
33 33 33 33 33 33 33 33
3827 1080 4000 3190 2870 2580 1080 1045
1263 360 1320 1050 950 850 360 345
50 15 53 42 38 35 15 14
500 150 530 420 380 350 150 140
Finishing Depth ar = 0.0025
5
V600 = 1200 SMRR600 = 50
2
20
5
V600 = 411 SMRR600 = 21
0.84
84
Procedure to Determine Data.—The following wheel-life recommendations are designed for 4 values of ECT = 0.00017, 0.00033, 0.00050 and 0.00075 mm (shown as 17, 33, 50 and 75 in the tables). Lower values of ECT than 0.00010 mm (0.000004 in.) are not recommended as these may lie to the left of the H-curve. The user selects any one of the ECT values, or interpolates between these, and selects the wheel speed for 10 or 100 minutes life, denoted by V10 and V100, respectively. For other desired wheel lives the wheel speed can be calculated from the tabulated Taylor constants C and n = 0.26 as follows: (V × T(desired)) 0.26 = C, the value of which is tabulated for each ECT value. C is the value of cutting speed V at T = 1 minute, hence is the same as for the speed V1 (V1 ×1^0.26 =C) V10 C ÷ 100.26 = C ÷ 1.82 V100 C ÷ 1000.26 = C ÷ 3.31. Example 6: A tool steel in material group 6 with ECT = 0.00033, has constant C= 4690, V10 = 2578 m/min, and V100 = 1417 m/min. From this information, find the wheel speed for desired wheel-life of T = 15 minutes and T = 45 minutes For T = 15 minutes we get V15 = 4690 ÷ 150.26 = 2319 m/min (7730 fpm) and for T = 45 minutes V45 = 4690 ÷ 450.26 = 1743 m/min (5810 fpm). The Tables are arranged in 3 sections: 1. Speeds V10 and V1 = Constant CST(standard) for 4 ECT values 0.00017, 0.00033, 0.00050 and 0.00075 mm. Values CU and V10U refer to user calibration of the standard values in each material group, explained in the following. 2. Speeds V100 (first row of 3), V10 and V1 (last in row) corresponding to wheel lives 100, 10 and 1 minutes, for 4 ECT values 0.00017, 0.00033, 0.00050 and 0.00075 mm. 3. Specific metal removal rates SMRR100, SMRR10 and SMRR1 corresponding to wheel lives 100, 10 and 1 minutes, for the 4 ECT values 0.00017, 0.00033, 0.00050, and 0.00075 mm
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Machinery's Handbook 27th Edition GRINDING FEEDS AND SPEEDS
1169
The 2 Graphs show: wheel life versus wheel speed in double logarithmic coordinates (Taylor lines); and, SMRR versus wheel speed in double logarithmic coordinates for 4 ECT values: 0.00017, 0.00033, 0.00050 and 0.00075 mm.
Tool Life T (min)
Table 1. Group 1—Unhardened Steels ECT = 0.00017 mm
ECT = 0.00033 mm
ECT = 0.00050 mm
ECT = 0.00075 mm
Constant C = 8925
Constant C = 6965
Constant C = 5385
Constant C = 3885
VT
SMRR
VT
SMRR
VT
SMRR
VT
100
2695
460
2105
695
1625
815
1175
880
10
4905
835
3830
1265
2960
1480
2135
1600
1
8925
1520
6965
2300
5385
2695
3885
2915
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100
10000
SMRR, mm3/mm/min
ECT = 17 ECT = 33 ECT = 50 ECT = 75
T, minutes
SMRR
10
1 1000
Fig. 1a. T–V
1000
T=100 ECT = 17 ECT = 33 ECT = 50 ECT = 75 100 1000
10000
V, m/min
T=1 min. T=10 min.
10000
V, m/min
Fig. 1b. SMRR vs. V, T = 100, 10, 1 minutes
Tool Life T (min)
Table 2. Group 2—Stainless Steels SAE 30201 – 30347, SAE 51409 – 51501 ECT = 0.00017 mm
ECT = 0.00033 mm
ECT = 0.00050 mm
ECT = 0.00075 mm
Constant C = 2270
Constant C = 1970
Constant C = 1505
Constant C = 1010
VT
SMRR
VT
SMRR
VT
SMRR
VT
100
685
115
595
195
455
225
305
230
10
1250
210
1080
355
825
415
555
415
1
2270
385
1970
650
1505
750
1010
760
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10000
100
SMRR, mm3/mm/min
ECT = 17 ECT = 33 ECT = 50 ECT = 75
T, minutes
SMRR
10
ECT = 17 ECT = 33 ECT = 50 ECT = 75
1000
100
1 100
1000
V, m/min
Fig. 2a. T–V
10000
100
1000
10000
V, m/min
Fig. 2b. SMRR vs. V, T = 100, 10, 1 minutes
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Machinery's Handbook 27th Edition 1170
GRINDING FEEDS AND SPEEDS
Tool Life T (min)
Table 3. Group 3—Cast Iron ECT = 0.00017 mm
ECT = 0.00033 mm
ECT = 0.00050 mm
ECT = 0.00075 mm
Constant C = 10710
Constant C = 8360
Constant C = 6465
Constant C = 4665
VT
SMRR
VT
SMRR
VT
SMRR
VT
SMRR
100
3235
550
2525
835
1950
975
1410
1055
10
5885
1000
4595
1515
3550
1775
2565
1920
1
10710
1820
8360
2760
6465
3230
4665
3500
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10000 ECT = 17 ECT = 33 ECT = 50 ECT = 75
10
T = 1 min
SMRR, mm3/mm/min
T, minutes
100
1 1000
Fig. 3a. T–V
T = 10 min T = 100 min ECT = 17 ECT = 33 ECT = 50 ECT = 75 100
10000
V, m/min
1000
1000
10000
V, m/min
Fig. 3b. SMRR vs. V, T = 100, 10, 1 minutes
Tool Life T (min)
Table 4. Group 4—Tool Steels, M1, M8, T1, H, O, L, F, 52100
100
ECT = 0.00017 mm
ECT = 0.00033 mm
ECT = 0.00050 mm
ECT = 0.00075 mm
Constant C = 7440
Constant C = 5805
Constant C = 4490
Constant C = 3240
VT
SMRR
VT
SMRR
VT
SMRR
VT
SMRR
2245
380
1755
580
1355
680
980
735
10
4090
695
3190
1055
2465
1235
1780
1335
1
7440
1265
5805
1915
4490
2245
3240
2430
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100
T, minutes
ECT = 17 ECT = 33 ECT = 50 ECT = 75
10
1
1000
10000
V, m/min
Fig. 4a. T–V
SMRR, mm3/mm/min
10000
T = 1 min T = 10 min 1000
T = 100 min
100
1000
ECT = 17 ECT = 33 ECT = 50 ECT = 75
V, m/min
10000
Fig. 4b. SMRR vs. V, T = 100, 10, 1 minutes
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Machinery's Handbook 27th Edition GRINDING FEEDS AND SPEEDS
1171
Tool Life T (min)
Table 5. Group 5—Tool Steels, M2, T2, T5, T6, D2, D5, H41, H42, H43, M50 ECT = 0.00017 mm
ECT = 0.00033 mm
ECT = 0.00050 mm
ECT = 0.00075 mm
Constant C = 6695
Constant C = 5224
Constant C = 4040
Constant C = 2915
VT
SMRR
VT
SMRR
VT
SMRR
VT
100
2020
345
1580
520
1220
610
880
660
10
3680
625
2870
945
2220
1110
1600
1200
1
6695
1140
5225
1725
4040
2020
2915
2185
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100
10
SMRR, mm3/mm/min
10000 ECT = 17 ECT = 33 ECT = 50 ECT = 75
T, minutes
SMRR
1000
ECT = 17 ECT = 33 ECT = 50 ECT = 75
1 1000
100
10000
V, m/min
Fig. 5a. T–V
1000
V, m/min
10000
Fig. 5b. SMRR vs. V, T = 100, 10, 1 minutes
Tool Life T (min)
Table 6. Group 6—Tool Steels, M3, M4, T3, D7 ECT = 0.00017 mm
ECT = 0.00033 mm
ECT = 0.00050 mm
ECT = 0.00075 mm
Constant C = 5290
Constant C = 4690
Constant C = 3585
Constant C = 2395
SMRR
VT
1600
270
10
2910
1
5290
VT
100
SMRR
VT
SMRR
VT
SMRR
1415
465
1085
540
725
540
495
2580
850
1970
985
1315
985
900
4690
1550
3585
1795
2395
1795
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10000
T, minutes
ECT = 17 ECT = 33 ECT = 50 ECT = 75 10
SMRR, mm3/mm/min
100
1000
ECT = 17 ECT = 33 ECT = 50 ECT = 75 100
1 1000
V, m/min
Fig. 6a. Group 6 Tool Steels T–V
10000
1000
10000
V, m/min
Fig. 6b. SMRR vs. V, T = 100, 10, 1 minutes
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Machinery's Handbook 27th Edition 1172
GRINDING FEEDS AND SPEEDS
Tool Life T (min)
Table 7. Group 7—Tool Steels, T15, M15 ECT = 0.00017 mm
ECT = 0.00033 mm
ECT = 0.00050 mm
ECT = 0.00075 mm
Constant C = 2270
Constant C = 1970
Constant C = 1505
Constant C = 1010
VT
SMRR
VT
SMRR
VT
SMRR
VT
100
685
115
595
195
455
225
305
230
10
1250
210
1080
355
825
415
555
415
1
2270
385
1970
650
1505
750
1010
760
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10000 ECT = 17 ECT = 33 ECT = 50 ECT = 75
10
ETC = 17 ETC = 33
SMRR, mm3/mm/min
100
T, minutes
SMRR
ETC = 50 ETC = 75
1000
100
1 100
1000
100
10000
1000
10000
V, m/min
V, m/min
Fig. 7a. T–V
Fig. 7b. SMRR vs. V, T = 100, 10, 1 minutes
Tool Life T (min)
Table 8. Group 8—Heat Resistant Alloys, Inconel, Rene, etc. ECT = 0.00017 mm
ECT = 0.00033 mm
ECT = 0.00050 mm
ECT = 0.00075 mm
Constant C = 2150
Constant C = 1900
Constant C = 1490
Constant C = 1035
VT
SMRR
VT
SMRR
VT
SMRR
VT
100
650
110
575
190
450
225
315
235
10
1185
200
1045
345
820
410
570
425
1
2150
365
1900
625
1490
745
1035
780
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100
10000
SMRR, mm3/mm/min
ECT = 17 ECT = 33 ECT = 50 ECT = 75
T, minutes
SMRR
10
1 100
1000
V, m/min
Fig. 8a. T–V
10000
ETC = 17 ETC = 33 ETC = 50 ETC = 75
1000
100 100
1000
10000
V, m/min
Fig. 8b. SMRR vs. V, T = 100, 10, 1 minutes
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Machinery's Handbook 27th Edition GRINDING FEEDS AND SPEEDS
1173
Tool Life T (min)
Table 9. Group 9—Carbide Materials, Diamond Wheel ECT = 0.00002 mm
ECT = 0.00003 mm
ECT = 0.00005 mm
ECT = 0.00008 mm
Constant C = 9030
Constant C = 8030
Constant C = 5365
Constant C = 2880
VT
SMRR
VT
SMRR
VT
SMRR
VT
SMRR
4800
1395
30
1195
35
760
40
390
30
600
2140
45
1855
55
1200
60
625
50
10
4960
100
4415
130
2950
145
1580
125
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10000
T, minutes
1000
100
10
ECT = 2 ECT = 3 ECT = 5 ECT = 8
100
10
10000
1000
100
1000
SMRR, mm3/mm/min
ECT = 2 ECT = 3 ECT = 5 ECT = 8
100
1000
10000
V, m/min
V, m/min
Fig. 9a. T–V
Fig. 9b. SMRR vs. V, T = 100, 10, 1 minutes
Tool Life T (min)
Table 10. Group 10 — Ceramic Materials Al2O3, ZrO2, SiC, Si3N4, Diamond Wheel ECT = 0.00002 mm
ECT = 0.00003 mm
ECT = 0.00005 mm
ECT = 0.00008 mm
Constant C = 2460
Constant C = 2130
Constant C = 1740
Constant C = 1420
VT
SMRR
VT
SMRR
VT
SMRR
VT
4800
395
8
335
10
265
13
210
17
600
595
12
510
15
410
20
330
25
10
1355
25
1170
35
955
50
780
60
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10000
100 ECT = 2 ECT = 3 ECT = 5 ECT = 8
SMRR, mm3/mm/min
ECT = 2 ECT = 3 ECT = 5 ECT = 8
T, minutes
1000
100
10 100
SMRR
10 1000
V, m/min
Fig. 10a. T–V
10000
100
1000
10000
V, m/min
Fig. 10b. SMRR vs. V, T = 100, 10, 1 minutes
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Machinery's Handbook 27th Edition 1174
GRINDING FEEDS AND SPEEDS User Calibration of Recommendations
It is recommended to copy or redraw the standard graph for any of the material groups before applying the data calibration method described below. The method is based on the user’s own experience and data. The procedure is described in the following and illustrated in Table 11 and Fig. 12. Only one shop data set is needed to adjust all four Taylor lines as shown below. The required shop data is the user’s wheel-life TU obtained at the user’s wheel speed VU, the user’s work speed VwU, and depth of cut ar. 1) First the user finds out which wheel-life TU was obtained in the shop, and the corresponding wheel speed VU, depth of cut ar and work speed VwU. 2) Second, calculate: a) ECT = VwU × ar ÷ VU b) the user Taylor constant CU = VU × TU0.26 V10U = CU ÷ 100.26 V100U = CU ÷ 1000.26 3) Thirdly, the user Taylor line is drawn in the pertinent graph. If the user wheel-life TU is longer than that in the standard graph the speed values will be higher, or if the user wheellife is shorter the speeds CU, V10U, V100U will be lower than the standard values C, V10 and V100. The results are a series of lines moved to the right or to the left of the standard Taylor lines for ECT = 17, 33, 50 and 75 × 10−5 mm. Each standard table contains the values C = V1, V10, V100 and empty spaces for filling out the calculated user values: CU = VU × TU0.26, V10U = CU ÷ 100.26 and V100U = CU ÷ 1000.26. Example 7: Assume the following test results on a Group 6 material: user speed is VU = 1800 m/min, wheel-life TU = 7 minutes, and ECT = 0.00017 mm. The Group 6 data is repeated below for convenience. Standard Table Data, Group 6 Material Tool Life T (min)
ECT = 0.00017 mm Constant C = 5290 VT SMRR
100 10 1
1600 2910 5290
270 495 900
ECT = 0.00033 mm Constant C = 4690 VT SMRR 1415 2580 4690
ECT = 0.00050 mm Constant C = 3585 VT SMRR
465 850 1550
1085 1970 3585
540 985 1795
725 1315 2395
540 985 1795
LIVE GRAPH
LIVE GRAPH
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10000 ECT = 17 ECT = 33 ECT = 50 ECT = 75
10
SMRR, mm3/mm/min
100
T, minutes
ECT = 0.00075 mm Constant C = 2395 VT SMRR
1000
ECT = 17 ECT = 33 ECT = 50 ECT = 75 100
1 1000
V, m/min
Fig. 11a. Group 6 Tool Steels, T–V
10000
1000
10000
V, m/min
Fig. 11b. SMRR vs. V, T = 100, 10, 1 minutes
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Machinery's Handbook 27th Edition GRINDING FEEDS AND SPEEDS
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Calculation Procedure 1) Calculate V1U, V10U, V100U and SMRR1U, SMRR10U, SMRR100U for ECT = 0.00017 mm a) V1U = the user Taylor constant CU = VU × TU0.26 = 1800 × 7 0.26 = 2985 m/min, and SMRR1U = 1000 × 2985 × 0.00017 = 507 mm3/mm width/min V10U = CU ÷ 100.26 = 2985 ÷ 10 0.26 = 1640 m/min, and SMRR10U = 1000 × 1640 × 0.00017 = 279 mm3/mm width/min V100U = CU ÷ 1000.26 = 2985 ÷ 100 0.26 = 900 m/min, and SMRR100U = 1000 × 900 × 0.00017 = 153 mm3/mm width/min 2) For ECT = 0.00017 mm, calculate the ratio of user Taylor constant to standard Taylor constant from the tables = CU ÷ CST = CU ÷ V1 = 2985 ÷ 5290 = 0.564 (see Table 6 for the value of CST = V1 at ECT = 0.00017 mm). 3) For ECT = 0.00033, 0.00050, and 0.00075 mm calculate the user Taylor constants from CU = CST × (the ratio calculated in step 2) = V1 × 0.564 = V1U. Then, calculate V10U and V100U and SMRR1U, SMRR10U, SMRR100U using the method in items 1b) and 1c) above. a) For ECT = 0.00033 mm V1U = CU = 4690 × 0.564 = 2645 m/min V10U = CU ÷ 100.26 = 2645 ÷ 10 0.26 = 1455 m/min V100U = CU ÷ 1000.26 = 2645 ÷ 100 0.26 = 800 m/min SMRR1U, SMRR10U, and SMRR100U = 876, 480, and 264 mm3/mm width/min b) For ECT = 0.00050 mm V1U = CU = 3590 × 0.564 = 2025 m/min V10U = CU ÷ 100.26 = 2025 ÷ 10 0.26 = 1110 m/min V100U = CU ÷ 1000.26 = 2025 ÷ 100 0.26 = 610 m/min SMRR1U, SMRR10U, and SMRR100U = 1013, 555, and 305 mm3/mm width/min c) For ECT = 0.00075 mm V1U = CU = 2395 × 0.564 = 1350 m/min V10U = CU ÷ 100.26 = 1350 ÷ 10 0.26 = 740 m/min V100U = CU ÷ 1000.26 = 1350 ÷ 100 0.26 = 405 m/min SMRR1U, SMRR10U, and SMRR100U = 1013, 555, and 305 mm3/mm width/min Thus, the wheel speed for any desired wheel-life at a given ECT can be calculated from V = CU ÷ T 0.26. For example, at ECT = 0.00050 mm and desired tool-life T = 9, V9 = 2025 ÷ 9 0.26 = 1144 m/min. The corresponding specific metal removal rate is SMRR = 1000 × 1144 × 0.0005 = 572 mm3/mm width/min (0.886 in3/inch width/min).
Tool Life T (min)
Table 11. User Calculated Data, Group 6 Material
100 10 1
ECT = 0.00017 mm User Constant CU = 2985 VT SMRR 900 1640 2985
153 279 507
ECT = 0.00033 mm User Constant CU = 2645 VT SMRR 800 1455 2645
264 480 876
ECT = 0.00050 mm User Constant CU = 2025 VT SMRR 610 1110 2025
305 555 1013
ECT = 0.00075 mm User Constant CU = 1350 VT SMRR 405 740 1350
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305 555 1013
Machinery's Handbook 27th Edition 1176
GRINDING FEEDS AND SPEEDS LIVE GRAPH Click here to view
T minutes
100
Standard V10 = 2910 for T = 10 minutes
ECT = 17 ECT = 33 ECT = 50 ECT = 75 ECTU = 17 ECTU = 33 ECTU = 50 ECTU = 75
10 TU = 7
1 1000
VU = 1800
V m/min
10000
Fig. 12. Calibration of user grinding data to standard Taylor Lines User Input: VU = 1800 m/min, TU = 7 minutes, ECT = 0.00017 mm
Optimization.— As shown, a global optimum occurs along the G-curve, in selected cases for values of ECT around 0.00075, i.e. at high metal removal rates as in other machining operations. It is recommended to use the simple formula for economic life: TE = 3 × TV minutes. TV = TRPL + 60 × CE ÷ HR, minutes, where TRPL is the time required to replace wheel, CE = cost per wheel dressing = wheel cost + cost per dressing, and HR is the hourly rate. In grinding, values of TV range between 2 and 5 minutes in conventional grinders, which means that the economic wheel lives range between 6 and 15 minutes indicating higher metal removal rates than are commonly used. When wheels are sharpened automatically after each stroke as in internal grinding, or when grits are continually replaced as in abrasive grinding (machining), TV may be less than one minute. This translates into wheel lives around one minute in order to achieve minimum cost grinding. Grinding Cost, Optimization and Process Planning: More accurate results are obtained when the firm collects and systemizes the information on wheel lives, wheel and work speeds, and depths of cut from production runs. A computer program can be used to plan the grinding process and apply the rules and formulas presented in this chapter. A complete grinding process planning program, such as that developed by Colding International Corporation, can be used to optimize machine settings for various feed-speed preferences corresponding wheel-life requirements, minimum cost or maximum production rate grinding, required surface finish and sparkout time; machine and fixture requirements based on the grinding forces, torque and power for sharp and worn grinding wheels; and, detailed time and cost analysis per part and per batch including wheel dressing and wheel changing schedules. Table 12 summarizes the time and cost savings per batch as it relates to tool life. The sensitivity of how grinding parameters are selected is obvious. Minimum cost conditions yield a 51% reduction of time and 44% reduction of cost, while maximum production rate reduces total time by 65% but, at the expense of heavy wheel consumption (continuous dressing), cost by only 18%. Table 12. Wheel Life vs. Cost Preferences Long Life Economic Life Minimum Cost Max Production Rate
Time per Batch, minutes 2995 2433 1465 1041
Cost per Batch, $ Tooling Total Cost 39 2412 252 2211 199 1344 1244 1980
Reduction from Long Life,% Time Cost — — 19 8 51 44 65 18
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Machinery's Handbook 27th Edition GRINDING WHEELS
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GRINDING AND OTHER ABRASIVE PROCESSES Processes and equipment discussed under this heading use abrasive grains for shaping workpieces by means of machining or related methods. Abrasive grains are hard crystals either found in nature or manufactured. The most commonly used materials are aluminum oxide, silicon carbide, cubic boron nitride and diamond. Other materials such as garnet, zirconia, glass and even walnut shells are used for some applications. Abrasive products are used in three basic forms by industry: a) Bonded to form a solid shaped tool such as disks (the basic shape of grinding wheels), cylinders, rings, cups, segments, or sticks to name a few. b) Coated on backings made of paper or cloth, in the form of sheets, strips, or belts. c) Loose, held in some liquid or solid carrier (for lapping, polishing, tumbling), or propelled by centrifugal force, air, or water pressure against the work surface (blast cleaning). The applications for abrasive processes are multiple and varied. They include: a) Cleaning of surfaces, also the coarse removal of excess material—such as rough offhand grinding in foundries to remove gates and risers. b) Shaping, such as in form grinding and tool sharpening. c) Sizing, a general objective, but of primary importance in precision grinding. d) Surface finish improvement, either primarily as in lapping, honing, and polishing or as a secondary objective in other types of abrasive processes. e) Separating, as in cut-off or slicing operations. The main field of application of abrasive processes is in metalworking, because of the capacity of abrasive grains to penetrate into even the hardest metals and alloys. However, the great hardness of the abrasive grains also makes the process preferred for working other hard materials, such as stones, glass, and certain types of plastics. Abrasive processes are also chosen for working relatively soft materials, such as wood, rubber, etc., for such reasons as high stock removal rates, long-lasting cutting ability, good form control, and fine finish of the worked surface. Grinding Wheels Abrasive Materials.—In earlier times, only natural abrasives were available. From about the beginning of this century, however, manufactured abrasives, primarily silicon carbide and aluminum oxide, have replaced the natural materials; even natural diamonds have been almost completely supplanted by synthetics. Superior and controllable properties, and dependable uniformity characterize the manufactured abrasives. Both silicon carbide and aluminum oxide abrasives are very hard and brittle. This brittleness, called friability, is controllable for different applications. Friable abrasives break easily, thus forming sharp edges. This decreases the force needed to penetrate into the work material and the heat generated during cutting. Friable abrasives are most commonly used for precision and finish grinding. Tough abrasives resist fracture and last longer. They are used for rough grinding, snagging, and off-hand grinding. As a general rule, although subject to variation: 1) Aluminum oxide abrasives are used for grinding plain and alloyed steel in a soft or hardened condition. 2) Silicon carbide abrasives are selected for cast iron, nonferrous metals, and nonmetallic materials. 3) Diamond is the best type of abrasive for grinding cemented carbides. It is also used for grinding glass, ceramics, and hardened tool steel.
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Machinery's Handbook 27th Edition 1178
GRINDING WHEELS
4) Cubic Boron Nitride (CBN) is known by several trade names including Borazon (General Electric Co.), ABN (De Beers), Sho-bon (Showa-Denko), and Elbor (USSR). CBN is a synthetic superabrasive used for grinding hardened steels and wear-resistant superalloys. (See Cubic Boron Nitride (CBN) starting on page 1013.) CBN grinding wheels have long lives and can maintain close tolerances with superior surface finishes. Bond Properties and Grinding Wheel Grades.—The four main types of bonds used for grinding wheels are the vitrified, resinoid, rubber, and metal. Vitrified bonds are used for more than half of all grinding wheels made, and are preferred because of their strength and other desirable qualities. Being inert, glass-like materials, vitrified bonds are not affected by water or by the chemical composition of different grinding fluids. Vitrified bonds also withstand the high temperatures generated during normal grinding operations. The structure of vitrified wheels can be controlled over a wide range of strength and porosity. Vitrified wheels, however, are more sensitive to impact than those made with organic bonds. Resinoid bonds are selected for wheels subjected to impact, or sudden loads, or very high operating speeds. They are preferred for snagging, portable grinder uses, or roughing operations. The higher flexibility of this type of bond—essentially a filled thermosetting plastic—helps it withstand rough treatment. Rubber bonds are even more flexible than the resinoid type, and for that reason are used for producing a high finish and for resisting sudden rises in load. Rubber bonded wheels are commonly used for wet cut-off wheels because of the nearly burr-free cuts they produce, and for centerless grinder regulating wheels to provide a stronger grip and more reliable workpiece control. Metal bonds are used in CBN and diamond wheels. In metal bonds produced by electrodeposition, a single layer of superabrasive material (diamond or CBN) is bonded to a metal core by a matrix of metal, usually nickel. The process is so controlled that about 30– 40 per cent of each abrasive particle projects above the deposited surface, giving the wheel a very aggressive and free-cutting action. With proper use, such wheels have remarkably long lives. When dulled, or worn down, the abrasive can be stripped off and the wheel renewed by a further deposit process. These wheels are also used in electrical discharge grinding and electrochemical grinding where an electrically conductive wheel is needed. In addition to the basic properties of the various bond materials, each can also be applied in different proportions, thereby controlling the grade of the grinding wheel. Grinding wheel grades commonly associated with hardness, express the amount of bond material in a grinding wheel, and hence the strength by which the bond retains the individual grains. During grinding, the forces generated when cutting the work material tend to dislodge the abrasive grains. As the grains get dull and if they don't fracture to resharpen themselves, the cutting forces will eventually tear the grains from their supporting bond. For a “soft” wheel the cutting forces will dislodge the abrasive grains before they have an opportunity to fracture. When a “hard” wheel is used, the situation is reversed. Because of the extra bond in the wheel the grains are so firmly held that they never break loose and the wheel becomes glazed. During most grinding operations it is desirable to have an intermediate wheel where there is a continual slow wearing process composed of both grain fracture and dislodgement. The grades of the grinding wheels are designated by capital letters used in alphabetical order to express increasing “hardness” from A to Z. Grinding Wheel Structure.—The individual grains, which are encased and held together by the bond material, do not fill the entire volume of the grinding wheel; the intermediate open space is needed for several functional purposes such as heat dissipation, coolant application, and particularly, for the temporary storage of chips. It follows that the
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Machinery's Handbook 27th Edition GRINDING WHEELS
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spacing of the grains must be greater for coarse grains which cut thicker chips and for large contact areas within which the chips have to be retained on the surface of the wheel before being disposed of. On the other hand, a wide spacing reduces the number of grains that contact the work surface within a given advance distance, thereby producing a coarser finish. In general, denser structures are specified for grinding hard materials, for high-speed grinding operations, when the contact area is narrow, and for producing fine finishes and/or accurate forms. Wheels with open structure are used for tough materials, high stock removal rates, and extended contact areas, such as grinding with the face of the wheel. There are, however, several exceptions to these basic rules, an important one being the grinding of parts made by powder metallurgy, such as cemented carbides; although they represent one of the hardest industrial materials, grinding carbides requires wheels with an open structure. Most kinds of general grinding operations, when carried out with the periphery of the wheel, call for medium spacing of the grains. The structure of the grinding wheels is expressed by numerals from 1 to 16, ranging from dense to open. Sometimes, “induced porosity” is used with open structure wheels. This term means that the grinding wheel manufacturer has placed filler material (which later burns out when the wheel is fired to vitrify the bond) in the grinding wheel mix. These fillers create large “pores” between grain clusters without changing the total volume of the “pores” in the grinding wheel. Thus, an A46-H12V wheel and an A46H12VP wheel will contain the same amounts of bond, abrasive, and air space. In the former, a large number of relatively small pores will be distributed throughout the wheel. The latter will have a smaller number of larger pores. American National Standard Grinding Wheel Markings.—ANSI Standard B74.131990“ Markings for Identifying Grinding Wheels and Other Bonded Abrasives,” applies to grinding wheels and other bonded abrasives, segments, bricks, sticks, hones, rubs, and other shapes that are for removing material, or producing a desired surface or dimension. It does not apply to specialities such as sharpening stones and provides only a standard system of markings. Wheels having the same standard markings but made by different wheel manufacturers may not—and probably will not—produce exactly the same grinding action. This desirable result cannot be obtained because of the impossibility of closely correlating any measurable physical properties of bonded abrasive products in terms of their grinding action. Symbols for designating diamond and cubic boron wheel compositions are given on page 1204. Sequence of Markings.—The accompanying illustration taken from ANSI B74.13-1990 shows the makeup of a typical wheel or bonded abrasive marking.
The meaning of each letter and number in this or other markings is indicated by the following complete list. 1) Abrasive Letters: The letter (A) is used for aluminum oxide, (C) for silicon carbide, and (Z) for aluminum zirconium. The manufacturer may designate some particular type in any one of these broad classes, by using his own symbol as a prefix (example, 51). 2) Grain Size: The grain sizes commonly used and varying from coarse to very fine are indicated by the following numbers: 8, 10, 12, 14, 16, 20, 24, 30, 36, 46, 54, 60,70, 80, 90, 100, 120, 150, 180, and 220. The following additional sizes are used occasionally: 240, 280, 320, 400, 500, and 600. The wheel manufacturer may add to the regular grain number an additional symbol to indicate a special grain combination.
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Machinery's Handbook 27th Edition 1180
GRINDING WHEELS
3) Grade: Grades are indicated by letters of the alphabet from A to Z in all bonds or processes. Wheel grades from A to Z range from soft to hard. 4) Structure: The use of a structure symbol is optional. The structure is indicated by Nos. 1 to 16 (or higher, if necessary) with progressively higher numbers indicating a progressively wider grain spacing (more open structure). 5) Bond or Process: Bonds are indicated by the following letters: V, vitrified; S, silicate; E, shellac or elastic; R, rubber; RF, rubber reinforced; B, resinoid (synthetic resins); BF, resinoid reinforced; O, oxychloride. 6) Manufacturer's Record: The sixth position may be used for manufacturer's private factory records; this is optional. American National Standard Shapes and Sizes of Grinding Wheels.—T h e A N S I Standard B74.2-1982 which includes shapes and sizes of grinding wheels, gives a wide variety of grinding wheel shape and size combinations. These are suitable for the majority of applications. Although grinding wheels can be manufactured to shapes and dimensions different from those listed, it is advisable, for reasons of cost and inventory control, to avoid using special shapes and sizes, unless technically warranted. Standard shapes and size ranges as given in this Standard together with typical applications are shown in Table 1a for inch dimensions and in Table 1b for metric dimensions. The operating surface of the grinding wheel is often referred to as the wheel face. In the majority of cases it is the periphery of the grinding wheel which, when not specified otherwise, has a straight profile. However, other face shapes can also be supplied by the grinding wheel manufacturers, and also reproduced during usage by appropriate truing. ANSI B74.2-1982 standard offers 13 different shapes for grinding wheel faces, which are shown in Table 2. The Selection of Grinding Wheels.—In selecting a grinding wheel, the determining factors are the composition of the work material, the type of grinding machine, the size range of the wheels used, and the expected grinding results, in this approximate order. The Norton Company has developed, as the result of extensive test series, a method of grinding wheel recommendation that is more flexible and also better adapted to taking into consideration pertinent factors of the job, than are listings based solely on workpiece categories. This approach is the basis for Tables 3 through 6, inclusive. Tool steels and constructional steels are considered in the detailed recommendations presented in these tables. Table 3 assigns most of the standardized tool steels to five different grindability groups. The AISI-SAE tool steel designations are used. After having defined the grindability group of the tool steel to be ground, the operation to be carried out is found in the first column of Table 4. The second column in this table distinguishes between different grinding wheel size ranges, because wheel size is a factor in determining the contact area between wheel and work, thus affecting the apparent hardness of the grinding wheel. Distinction is also made between wet and dry grinding. Finally, the last two columns define the essential characteristics of the recommended types of grinding wheels under the headings of first and second choice, respectively. Where letters are used preceding A, the standard designation for aluminum oxide, they indicate a degree of friability different from the regular, thus: SF = semi friable (Norton equivalent 16A) and F = friable (Norton equivalent 33A and 38A). The suffix P, where applied, expresses a degree of porosity that is more open than the regular.
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Table 1a. Standard Shapes and Inch Size Ranges of Grinding Wheels ANSI B74.2-1982 Size Ranges of Principal Dimensions, Inches Applications
D = Dia.
T = Thick.
H = Hole
Type 1. Straight Wheel For peripheral grinding.
1⁄ to 3⁄ 64 8
1⁄ to 16
12 to 48
1⁄ to 2
6
5 to 20
14 to 30
1 to 20
5 or 12
8 to 14
1 to 12
1⁄ to 4
4
1⁄ to 4
2
3⁄ to 7⁄ 32 8
General purpose
6 to 36
1⁄ to 2
4
1⁄ to 2
For wet tool grinding only
30 or 36
3 or 4
20
CUTTING OFF (Organic bonds only) CYLINDRICAL GRINDING Between centers CYLINDRICAL GRINDING Centerless grinding wheels CYLINDRICAL GRINDING Centerless regulating wheels INTERNAL GRINDING
1 to 48
6
3 to 6
OFFHAND GRINDING Grinding on the periphery
1⁄ to 4
11⁄2
1⁄ to 2
3
11⁄4
SAW GUMMING (F-type face)
6 to 12
SNAGGING Floor stand machines
12 to 24
1 to 3
11⁄4 to 21⁄2
SNAGGING Floor stand machines (Organic bond, wheel speed over 6500 sfpm)
20 to 36
2 to 4
6 or 12
SNAGGING Mechanical grinders (Organic bond, wheel speed up to 16,500 sfpm)
24
SNAGGING Portable machines SNAGGING Portable machines (Reinforced organic bond, 17,000 sfpm) SNAGGING Swing frame machines SURFACE GRINDING Horizontal spindle machines TOOL GRINDING Broaches, cutters, mills, reamers, taps, etc.
2 to 3
12
3 to 8
1⁄ to 4
1
6 or 8
3⁄ or 4
1
1
2 to 3
31⁄2 to
6 to 24
1⁄ to 2
6
11⁄4 to
6 to 10
1⁄ to 1⁄ 4 2
5⁄ to 8
12 to 24
3⁄ to 5⁄ 8 8
12 12 5
Type 2. Cylindrical Wheel Side grinding wheel — mounted on the diameter; may also be mounted in a chuck or on a plate.
W = Wall SURFACE GRINDING Vertical spindle machines
8 to 20
4 or 5
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1 to 4
Machinery's Handbook 27th Edition 1182
GRINDING WHEELS
Table 1a. (Continued) Standard Shapes and Inch Size Ranges of Grinding Wheels ANSI B74.2-1982 Size Ranges of Principal Dimensions, Inches Applications
D = Dia.
T = Thick.
H = Hole
Type 5. Wheel, recessed one side For peripheral grinding. Allows wider faced wheels than the available mounting thickness, also grinding clearance for the nut and flange.
CYLINDRICAL GRINDING Between centers
12 to 36
11⁄2 to 4
5 or 12
CYLINDRICAL GRINDING Centerless regulating wheel
8 to 14
3 to 6
3 or 5
INTERNAL GRINDING
3⁄ to 8
4
3⁄ to 8
2
1⁄ to 7⁄ 8 8
SURFACE GRINDING Horizontal spindle machines
7 to 24
3⁄ to 4
6
11⁄4 to 12
Type 6. Straight-Cup Wheel Side grinding wheel, in whose dimensioning the wall thickness (W) takes precedence over the diameter of the recess. Hole is 5⁄ -11UNC-2B threaded for the snagging wheels and 8 1⁄ or 11⁄ ″ for the tool grinding wheels. 2 4
W = Wall SNAGGING Portable machines, organic bond only.
4 to 6
2
TOOL GRINDING Broaches, cutters, mills, reamers, taps, etc.
2 to 6
1 1⁄4 to 2
3⁄ to 4
11⁄2
5⁄ or 3⁄ 16 8
Type 7. Wheel, recessed two sides Peripheral grinding. Recesses allow grinding clearance for both flanges and also narrower mounting thickness than overall thickness.
CYLINDRICAL GRINDING Between centers
12 to 36
11⁄2 to 4
5 or 12
CYLINDRICAL GRINDING Centerless regulating wheel
8 to 14
4 to 20
3 to 6
SURFACE GRINDING Horizontal spindle machines
12 to 24
2 to 6
5 to 12
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Machinery's Handbook 27th Edition GRINDING WHEELS
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Table 1a. (Continued) Standard Shapes and Inch Size Ranges of Grinding Wheels ANSI B74.2-1982 Size Ranges of Principal Dimensions, Inches Applications
D = Dia.
T = Thick.
H = Hole
Type 11. Flaring-Cup Wheel Side grinding wheel with wall tapered outward from the back; wall generally thicker in the back.
SNAGGING Portable machines, organic bonds only, threaded hole
4 to 6
2
TOOL GRINDING Broaches, cutters, mills, reamers, taps, etc.
2 to 5
1 1⁄4 to 2
5⁄ -11 8
UNC-2B
1⁄ to 2
1 1⁄4
Type 12. Dish Wheel Grinding on the side or on the Uface of the wheel, the U-face being always present in this type.
TOOL GRINDING Broaches, cutters, mills, reamers, taps, etc.
3 to 8
1⁄ or 3⁄ 2 4
1⁄ to 2
1 1⁄4
Type 13. Saucer Wheel Peripheral grinding wheel, resembling the shape of a saucer, with cross section equal throughout.
1⁄ to 2
SAW GUMMING Saw tooth shaping and sharpening
8 to 12
1 3⁄4 U&E 11⁄2
1⁄ to 4
3⁄ to 4
1 1⁄4
Type 16. Cone, Curved Side Type 17. Cone, Straight Side, Square Tip Type 17R. Cone, Straight Side, Round Tip (Tip Radius R = J/2)
SNAGGING Portable machine, threaded holes
11⁄4 to 3
2 to 31⁄2
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3⁄ -24UNF-2B 8
to 5⁄ -11UNC-2B 8
Machinery's Handbook 27th Edition 1184
GRINDING WHEELS
Table 1a. (Continued) Standard Shapes and Inch Size Ranges of Grinding Wheels ANSI B74.2-1982 Size Ranges of Principal Dimensions, Inches Applications
D = Dia.
T = Thick.
H = Hole
Type 18. Plug, Square End Type 18R. Plug, Round End R = D/2
Type 19. Plugs, Conical End, Square Tip Type 19R. Plugs, Conical End, Round Tip (Tip Radius R = J/2)
SNAGGING Portable machine, threaded holes
11⁄4 to 3
2 to 31⁄2
3⁄ -24UNF-2B 8
to 5⁄ -11UNC-2B 8
Type 20. Wheel, Relieved One Side Peripheral grinding wheel, one side flat, the other side relieved to a flat.
CYLINDRICAL GRINDING Between centers
12 to 36
3⁄ to 4
4
5 to 20
Type 21. Wheel, Relieved Two Sides Both sides relieved to a flat.
Type 22. Wheel, Relieved One Side, Recessed Other Side One side relieved to a flat.
Type 23. Wheel, Relieved and Recessed Same Side The other side is straight.
CYLINDRICAL GRINDING Between centers, with wheel periphery
20 to 36
2 to 4
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12 or 20
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Table 1a. (Continued) Standard Shapes and Inch Size Ranges of Grinding Wheels ANSI B74.2-1982 Size Ranges of Principal Dimensions, Inches Applications
D = Dia.
T = Thick.
H = Hole
Type 24. Wheel, Relieved and Recessed One Side, Recessed Other Side One side recessed, the other side is relieved to a recess.
Type 25. Wheel, Relieved and Recessed One Side, Relieved Other Side One side relieved to a flat, the other side relieved to a recess.
Type 26. Wheel, Relieved and Recessed Both Sides
CYLINDRICAL GRINDING Between centers, with the periphery of the wheel
20 to 36
2 to 4
12 or 20
TYPES 27 & 27A. Wheel, Depressed Center 27. Portable Grinding: Grinding normally done by contact with work at approx. a 15° angle with face of the wheel. 27A. Cutting-off: Using the periphery as grinding face. CUTTING OFF Reinforced organic bonds only SNAGGING Portable machine
16 to 30
U = E = 5⁄32 to 1⁄4
1 or 1 1⁄2
3 to 9
U = Uniform thick. 1⁄8 to 3⁄8
3⁄ or 7⁄ 8 8
Type 28. Wheel, Depressed Center (Saucer Shaped Grinding Face) Grinding at approx. 15° angle with wheel face.
SNAGGING Portable machine
7 or 9
U = Uniform thickness 1⁄4
Throughout table large open-head arrows indicate grinding surfaces.
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7⁄ 8
Machinery's Handbook 27th Edition 1186
GRINDING WHEELS Table 1b. Standard Shapes and Metric Size Ranges of Grinding Wheels ANSI B74.2-1982 Size Ranges of Principal Dimensions, Millimeters Applications
D = Diam.
T = Thick.
H = Hole
Type 1. Straight Wheela CUTTING OFF (nonreinforced and reinforced organic bonds only)
150 to 1250
0.8 to 10
16 to 152.4
CYLINDRICAL GRINDING Between centers
300 to 1250
20 to 160
127 to 508
CYLINDRICAL GRINDING Centerless grinding wheels
350 to 750
25 to 500
127 or 304.8
CYLINDRICAL GRINDING Centerless regulating wheels
200 to 350
25 to 315
76.2 to 152.4
6 to 100
6 to 50
2.5 to 25
General purpose
150 to 900
13 to 100
20 to 76.2
For wet tool grinding only
750 or 900
80 or 100
508
SAW GUMMING (F-type face)
150 to 300
6 to 40
32
SNAGGING Floor stand machines
300 to 600
25 to 80
32 to 76.2
SNAGGING Floor stand machines(organic bond, wheel speed over 33 meters per second)
500 to 900
50 to 100
152.4 or 304.8
SNAGGING Mechanical grinders (organic bond, wheel speed up to 84 meters per second)
600
50 to 80
304.8
SNAGGING Portable machines
80 to 200
6 to 25
10 to 16
SNAGGING Swing frame machines (organic bond)
300 to 600
50 to 80
88.9 to 304.8
SURFACE GRINDING Horizontal spindle machines
150 to 600
13 to 160
32 to 304.8
TOOL GRINDING Broaches, cutters, mills, reamers, taps, etc.
150 to 250
6 to 20
32 to 127
INTERNAL GRINDING OFFHAND GRINDING Grinding on the periphery
Type 2. Cylindrical Wheela
W = Wall SURFACE GRINDING Vertical spindle machines
200 to 500
100 or 125
Copyright 2004, Industrial Press, Inc., New York, NY
25 to 100
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Table 1b. (Continued) Standard Shapes and Metric Size Ranges of Grinding Wheels ANSI B74.2-1982 Size Ranges of Principal Dimensions, Millimeters Applications
D = Diam.
T = Thick.
H = Hole
Type 5. Wheel, recessed one sidea CYLINDRICAL GRINDING Between centers
300 to 900
40 to 100
127 or 304.8
CYLINDRICAL GRINDING Centerless regulating wheels
200 to 350
80 to 160
76.2 or 127
INTERNAL GRINDING
10 to 100
10 to 50
3.18 to 25
Type 6. Straight-Cup Wheela
W = Wall SNAGGING Portable machines, organic bond only (hole is 5⁄8-11 UNC-2B)
100 to 150
50
20 to 40
TOOL GRINDING Broaches, cutters, mills, reamers, taps, etc. (Hole is 13 to 32 mm)
50 to 150
32 to 50
8 or 10
Type 7. Wheel, recessed two sidesa CYLINDRICAL GRINDING Between centers
300 to 900
40 to 100
127 or 304.8
CYLINDRICAL GRINDING Centerless regulating wheels
200 to 350
100 to 500
76.2 to 152.4
Type 11. Flaring-Cup Wheela SNAGGING Portable machines, organic bonds only, threaded hole
100 to 150
50
TOOL GRINDING Broaches, cutters, mills, reamers, taps, etc.
50 to 125
32 to 50
13 to 32
13 or 20
13 to 32
5⁄ -11 8
UNC-2B
Type 12. Dish Wheela TOOL GRINDING Broaches, cutters, mills, reamers, taps, etc.
80 to 200
Type 27 and 27A. Wheel, depressed centera CUTTING OFF Reinforced organic bonds only
400 to 750
U=E=6
25.4 or 38.1
SNAGGING Portable machines
80 to 230
U = E = 3.2 to 10
9.53 or 22.23
a See Table 1a for diagrams and descriptions of each wheel type.
All dimensions in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1188
GRINDING WHEELS Table 2. Standard Shapes of Grinding Wheel Faces ANSI B74.2-1982
Recommendations, similar in principle, yet somewhat less discriminating have been developed by the Norton Company for constructional steels. These materials can be ground either in their original state (soft) or in their after-hardened state (directly or following carburization). Constructional steels must be distinguished from structural steels which are used primarily by the building industry in mill shapes, without or with a minimum of machining. Constructional steels are either plain carbon or alloy type steels assigned in the AISISAE specifications to different groups, according to the predominant types of alloying elements. In the following recommendations no distinction is made because of different compositions since that factor generally, has a minor effect on grinding wheel choice in constructional steels. However, separate recommendations are made for soft (Table 5) and
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition GRINDING WHEELS
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hardened (Table 6) constructional steels. For the relatively rare instance where the use of a single type of wheel for both soft and hardened steel materials is considered more important than the selection of the best suited types for each condition of the work materials, Table 5 lists “All Around” wheels in its last column. For applications where cool cutting properties of the wheel are particularly important, Table 6 lists, as a second alternative, porous-type wheels. The sequence of choices as presented in these tables does not necessarily represent a second, or third best; it can also apply to conditions where the first choice did not provide optimum results and by varying slightly the composition of the grinding wheel, as indicated in the subsequent choices, the performance experience of the first choice might be improved. Table 3. Classification of Tool Steels by their Relative Grindability Relative Grindability Group
AISI-SAE Designation of Tool Steels
GROUP 1—Any area of work surface
W1, W2, W5
High grindability tool and die steels
O1, O2, O6, O7
(Grindability index greater than 12)
H10, H11, H12, H13, H14
S1, S2, S4, S5, S6, S7
L2, L6 GROUP 2—Small area of work surface (as found in tools)
H19, H20, H21, H22, H23, H24, H26 P6, P20, P21 T1, T7, T8
Medium grindability tool and die steels
M1, M2, M8, M10, M33, M50
(Grindability index 3 to 12)
D1, D2, D3, D4, D5, D6 A2, A4, A6, A8, A9, A10
GROUP 3—Small area of work surface
T4, T5, T6, T8
(as found in tools)
M3, M6, M7, M34, M36, M41, M42, M46, M48, M52, M62
Low grindability tool and die steels
D2, D5
(Grindability index between 1.0 and 3)
A11
GROUP 4—Large area of work surface (as found in dies)
All steels found in Groups 2 and 3
Medium and low grindability tool and die steels (Grindability index between 1.0 and 12) GROUP 5—Any area of work surface
D3, D4, D7 M4
Very low grindability tool and die steels
A7
(Grindability index less than 1.0)
T15
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1190
GRINDING WHEELS Table 4. Grinding Wheel Recommendations for Hardened Tool Steels According to their Grindability Operation
Surfacing Surfacing wheels
Segments or Cylinders Cups
Wheel or Rim First-Choice Diameter, Specifications Inches Group 1 Steels 14 and smaller 14 and smaller Over 14 11⁄2 rim or less 3⁄ rim or less 4
Second-Choice Specifications
Wet FA46-I8V Dry FA46-H8V Wet FA36-I8V Wet FA30-H8V
SFA46-G12VP FA46-F12VP SFA36-I8V FA30-F12VP
Wet FA36-H8V
FA46-F12VP
(for rims wider than 11⁄2 inches, go one grade softer in available specifications) Cutter sharpening Straight wheel Dish shape Cup shape Form tool grinding
Cylindrical Centerless Internal Production grinding
Tool room grinding
… … … … … 8 and smaller 8 and smaller 10 and larger 14 and smaller 16 and larger …
Wet FA46-K8V FA60-K8V Dry FA46-J8V FA46-H12VP Dry FA60-J8V FA60-H12VP Dry FA46-L8V FA60-H12VP Wet SFA46-L5V SFA60-L5V Wet FA60-L8V to FA100-M7V Dry FA60-K8V to FA100-L8V Wet FA60-L8V to FA80-M6V Wet SFA60-L5V … Wet SFA60-M5V … Wet SFA60-M5V …
Under 1⁄2
Wet SPA80-N6V
SFA80-N7V
1⁄ to 2
Wet SFA60-M5V
SFA60-M6V
Wet SFA54-L5V Wet SFA46-L5V Dry FA80-L6V
SFA54-L6V SFA46-K5V SFA80-L7V
1 Over 1 to 3 Over 3 Under 1⁄2
1⁄ to 2
Dry FA70-K7V 1 Over 1 to 3 Dry FA60-J8V Over 3 Dry FA46-J8V Group 2 Steels
Surfacing Straight wheels
Segments or Cylinders Cups
14 and smaller 14 and smaller Over 14 11⁄2 rim or less 3⁄ rim or less 4
SFA70-K7V FA60-H12VP FA54-H12VP
Wet FA46-I8V Dry FA46-H8V Wet FA46-H8V Wet FA30-G8V
FA46-G12VP FA46-F12VP SFA46-I8V FA36-E12VP
Wet FA36-H8V
FA46-F12VP
(for rims wider than 11⁄2 inches, go one grade softer in available specifications)
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Machinery's Handbook 27th Edition GRINDING WHEELS
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Table 4. (Continued) Grinding Wheel Recommendations for Hardened Tool Steels According to their Grindability Operation Cutter sharpening Straight wheel Dish shape Cup shape Form tool grinding
Cylindrical Centerless Internal Production grinding
Tool room grinding
Wheel or Rim Diameter, Inches
First-Choice Specifications
… … … … … 8 and smaller 8 and smaller 10 and larger 14 and less 16 and larger …
Wet FA46-L5V FA60-K8V Dry FA46-J8V FA60-H12VP Dry FA60-J5V FA60-G12VP Dry FA46-K5V FA60-G12VP Wet FA46-L5V FA60-J8V Wet FA60-K8V to FA120-L8V Dry FA80-K8V to FA150-K8V Wet FA60-K8V to FA120-L8V Wet FA60-L5V SFA60-L5V Wet FA60-K5V SFA60-K5V Wet FA60-M5V SFA60-M5V
Under 1⁄2
Wet FA80-L6V
1⁄ to 2
Wet FA70-K5V
SFA70-K5V
Wet FA60-J8V Wet FA54-J8V
SFA60-J7V SFA54-J8V
Under 1⁄2
Dry FA80-I8V
Dry FA70-J8V 1 Over 1 to 3 Dry FA60-I8V Over 3 Dry FA54-I8V Group 3 Steels
Segments or Cylinders Cups
SFA80-L6V
1 Over 1 to 3 Over 3
1⁄ to 2
Surfacing Straight wheels
Second-Choice Specifications
14 and smaller 14 and smaller Over 14 11⁄2 rim or less 3⁄ rim or less 4
SFA80-K7V SFA70-J7V FA60-G12VP FA54-G12VP
Wet FA60-I8V Dry FA60-H8V Wet FA60-H8V Wet FA46-G8V
FA60-G12VP FA60-F12VP SFA60-I8V FA46-E12VP
Wet FA46-G8V
FA46-E12VP
(for rims wider than 11⁄2 inches, go one grade softer in available specifications) Cutter grinding Straight wheel Dish shape Cup shape Form tool grinding
… … … … … 8 and smaller 8 and smaller 10 and larger
Wet FA46-J8V FA60-J8V Dry FA46-I8V FA46-G12VP Dry FA60-H8V FA60-F12VP Dry FA46-I8V FA60-F12VP Wet FA46-J8V FA60-J8V Wet FA80-K8V to FA150-L9V Dry FA100-J8V to FA150-K8V Wet FA80-J8V to FA150-J8V
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1192
GRINDING WHEELS
Table 4. (Continued) Grinding Wheel Recommendations for Hardened Tool Steels According to their Grindability Operation Cylindrical Centerless Internal Production grinding
Tool room grinding
Wheel or Rim Diameter, Inches 14 and less 16 and larger …
Wet FA80-L5V Wet FA60-L6V Wet FA60-L5V
SFA80-L6V SFA60-K5V SFA60-L5V
Under 1⁄2
Wet FA90-L6V
SFA90-L6V
1⁄ to 2
Wet FA80-L6V
SFA80-L6V
Wet FA70-K5V Wet FA60-J5V Dry FA90-K8V
SFA70-K5V SFA60-J5V SFA90-K7V
1 Over 1 to 3 Over 3 Under 1⁄2
First-Choice Specifications
1⁄ to 2
Dry FA80-J8V 1 Over 1 to 3 Dry FA70-I8V Over 3 Dry FA60-I8V Group 4 Steels
Surfacing Straight wheels
Segments Cylinders Cups
Form tool grinding
Cylindrical Internal Production grinding
Tool room grinding
14 and smaller 14 and smaller Over 14 1 1⁄2 rim or less 1 1⁄2 rim or less 3⁄ rim or less 4
Second-Choice Specifications
SFA80-J7V SFA70-G12VP SFA60-G12VP
Wet FA60-I8V Wet FA60-H8V Wet FA46-H8V Wet FA46-G8V
C60-JV C60-IV C60-HV C46-HV
Wet FA46-G8V
C60-HV
Wet FA46-G6V
C60-IV
(for rims wider than 1 1⁄2 inches, go one grade softer in available specifications) 8 and smaller Wet FA60-J8V to FA150-K8V 8 and smaller Dry FA80-I8V to FA180-J8V 10 and larger Wet FA60-J8V to FA150-K8V 14 and less Wet FA80-K8V C60-KV 16 and larger Wet FA60-J8V C60-KV Under 1⁄2
Wet FA90-L8V
1⁄ to 2
Wet FA80-K5V
C80-KV
Wet FA70-J8V Wet FA60-I8V Dry FA90-K8V
C70-JV C60-IV C90-KV
1 Over 1 to 3 Over 3 Under 1⁄2
1⁄ to 2
1 Over 1 to 3 Over 3
C90-LV
Dry FA80-J8V
C80-JV
Dry FA70-I8V Dry FA60-H8V
C70-IV C60-HV
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Table 4. (Continued) Grinding Wheel Recommendations for Hardened Tool Steels According to their Grindability Wheel or Rim Diameter, Inches
Operation
FirstChoice Specifications
SecondChoice Specifications
ThirdChoice Specifications
Group 5 Steels Surfacing Straight wheels
Segments or Cylinders Cups
14 and smaller
Wet SFA60-H8V
FA60-E12VP
C60-IV
14 and smaller
Dry SFA80-H8V
FA80-E12VP
C80-HV
Over 14
Wet SFA60-H8V
FA60-E12VP
C60-HV
1 1⁄2 rim or less
Wet SFA46-G8V
FA46-E12VP
C46-GV
3⁄ rim 4
Wet SFA60-G8V
FA60-E12VP
C60-GV
or less
(for rims wider than 1 1⁄2 inches, go one grade softer in available specifications) Cutter grinding …
Wet SFA60-I8V
SFA60-G12VP
…
…
Dry SFA60-H8V
SFA80-F12VP
…
Dish shape
…
Dry SFA80-H8V
SFA80-F12VP
…
Cup shape
…
Dry SFA60-I8V
SFA60-G12VP
…
…
Wet SFA60-J8V
SFA60-H12VP
…
Straight wheels
Form tool grinding
Cylindrical
8 and smaller
Wet FA80-J8V to FA180-J9V
…
8 and smaller
Dry FA100-I8V to FA220-J9V
…
10 and larger
Wet FA80-J8V to FA180-J9V
14 and less
Wet FA80-J8V
C80-KV
FA80-H12VP
16 and larger
…
Wet FA80-I8V
C80-KV
FA80-G12VP
Wet FA80-J5V
C80-LV
…
Wet FA100-L8V
C90-MV
…
Wet FA90-K8V
C80-LV
…
Over 1 to 3
Wet FA80-J8V
C70-KV
FA80-H12VP
Over 3
Wet FA70-I8V
C60-JV
FA70-G12VP
Dry FA100-K8V
C90-KV
…
1
Dry FA90-J8V
C80-JV
…
Over 1 to 3
Dry FA80-I8V
C70-IV
FA80-G12VP
Over 3
Dry FA70-I8V
C60-IV
FA70-G12VP
…
Centerless Internal
Production grind- Under 1⁄2 ing 1⁄ to 1 2
Tool room grinding
Under 1⁄ to 2
1⁄ 2
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1194
GRINDING WHEELS
Table 5. Grinding Wheel Recommendations for Constructional Steels (Soft) Grinding Operation Surfacing Straight wheels
Wheel or Rim Diameter, Inches
First Choice
Alternate Choice (Porous type)
All-Around Wheel
14 and smaller 14 and smaller Over 14
Wet FA46-J8V Dry FA46-I8V Wet FA36-J8V
FA46-H12VP FA46-H12VP FA36-H12VP
FA46-J8V FA46-I8V FA36-J8V
Wet FA24-H8V
FA30-F12VP
FA24-H8V
FA30-G12VP
FA24-H8V
FA30-F12VP
FA30-H8V
11⁄2 rim or
Segments
less 11⁄2 rim or
Cylinders
less 3⁄ rim 4
Cups Cylindrical
Wet FA24-I8V Wet FA24-H8V
or less
(for wider rims, go one grade softer) Wet SFA60-M5V … Wet SFA54-M5V … Wet SFA54-N5V … Wet SFA60-M5V …
14 and smaller 16 and larger …
Centerless Internal
Under 1⁄2
SFA60-L5V SFA54-L5V SFA60-M5V SFA80-L6V
1
Wet SFA60-L5V
…
SFA60-K5V
Over 1 to 3 Over 3
Wet SFA54-K5V Wet SFA46-K5V
… …
SFA54-J5V SFA46-J5V
1⁄ to 2
Table 6. Grinding Wheel Recommendations for Constructional Steels (Hardened or Carburized) Grinding Operation Surfacing Straight wheels
Wheel or Rim Diameter, Inches 14 and smaller 14 and smaller Over 14
Segments or Cylinders
11⁄2 rim or less
Cups
3⁄ rim 4
Forms and Radius Grinding
or less
8 and smaller 8 and smaller 10 and larger
Cylindrical Work diameter 1 inch and smaller Over 1 inch 1 inch and smaller Over 1 inch Centerless Internal
First Choice
Alternate Choice (Porous Type)
Wet FA46-I8V Dry FA46-H8V Wet FA36-I8V Wet FA30-H8V
FA46-G12VP FA46-F12VP FA36-G12VP FA36-F12VP
Wet FA36-H8V
FA46-F12VP
(for wider rims, go one grade softer) Wet FA60-L7V to FA100-M8V Dry FA60-K8V to FA100-L8V Wet FA60-L7V to FA80-M7V
Under 1⁄2
Wet SFA80-L6V Wet SFA80-K5V Wet SFA60-L5V Wet SFA60-L5V Wet SFA80-M6V Wet SFA80-N6V
… … … … … …
1⁄ to 2
1
Wet SFA60-M5V
…
Over 1 to 3 Over 3 Under 1⁄2
Wet SFA54-L5V Wet SFA46-K5V Dry FA80-L6V
… … …
1⁄ to 2
1
Dry FA70-K8V
…
Over 1 to 3 Over 3
Dry FA60-J8V Dry FA46-J8V
FA60-H12VP FA54-H12VP
14 and smaller 14 and smaller 16 and larger 16 and larger …
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition GRINDING WHEELS
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Cubic Boron Nitride (CBN) Grinding Wheels.—Although CBN is not quite as hard, strong, and wear-resistant as a diamond, it is far harder, stronger, and more resistant to wear than aluminum oxide and silicon carbide. As with diamond, CBN materials are available in different types for grinding workpieces of 50 Rc and above, and for superalloys of 35 Rc and harder. Microcrystalline CBN grinding wheels are suitable for grinding mild steels, medium-hard alloy steels, stainless steels, cast irons, and forged steels. Wheels with larger mesh size grains (up to 20⁄30), now available, provide for higher rates of metal removal. Special types of CBN are produced for resin, vitrified, and electrodeposited bonds. Wheel standards and nomenclature generally conform to those used for diamond wheels (page 1201), except that the letter B instead of D is used to denote the type of abrasive. Grinding machines for CBN wheels are generally designed to take full advantage of the ability of CBN to operate at high surface speeds of 9,000–25,000 sfm. CBM is very responsive to changes in grinding conditions, and an increase in wheel speed from 5,000 to 10,000 sfm can increase wheel life by a factor of 6 or more. A change from a water-based coolant to a coolant such as a sulfochlorinated or sulfurized straight grinding oil can increase wheel life by a factor of 10 or more. Machines designed specifically for use with CBN grinding wheels generally use either electrodeposited wheels or have special trueing systems for other CBN bond wheels, and are totally enclosed so they can use oil as a coolant. Numerical control systems are used, often running fully automatically, including loading and unloading. Machines designed for CBN grinding with electrodeposited wheels are extensively used for form and gear grinding, special systems being used to ensure rapid mounting to exact concentricity and truth in running, no trueing or dressing being required. CBN wheels can produce workpieces having excellent accuracy and finish, with no trueing or dressing for the life of the wheel, even over many hours or days of production grinding of hardened steel components. Resin-, metal-, and vitrified-bond wheels are used extensively in production grinding, in standard and special machines. Resin-bonded wheels are used widely for dry tool and cutter resharpening on conventional hand-operated tool and cutter grinders. A typical wheel for such work would be designated 11V9 cup type, 100⁄120 mesh, 75 concentration, with a 1⁄16 or 1⁄8 in. rim section. Special shapes of resin-bonded wheels are used on dedicated machines for cutting tool manufacture. These types of wheels are usually self-dressing, and allow full machine control of the operation without the need for an operator to see, hear, or feel the action. Metal-bonded CBN wheels are usually somewhat cheaper than those using other types of bond because only a thin layer of abrasive is present. Metal bonding is also used in manufacture of CBN honing stones. Vitrified-bond CBN wheels are a recent innovation, and high-performance bonds are still being developed. These wheels are used for grinding cams, internal diameters, and bearing components, and can be easily redressed. An important aspect of grinding with CBN and diamond wheels is reduced heating of the workpiece, thought to result from their superior thermal conductivity compared with aluminum oxide, for instance. CBN and diamond grains also are harder, which means that they stay sharp longer than aluminum oxide grains. The superior ability to absorb heat from the workpiece during the grinding process reduces formation of untempered martensite in the ground surface, caused by overheating followed by rapid quenching. At the same time, a higher compressive residual stress is induced in the surface, giving increased fatigue resistance, compared with the tensile stresses found in surfaces ground with aluminum oxide abrasives. Increased fatigue resistance is of particular importance for gear grinding, especially in the root area. Variations from General Grinding Wheel Recommendations.—Recommendations for the selection of grinding wheels are usually based on average values with regard to both operational conditions and process objectives. With variations from such average values,
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1196
GRINDING WHEELS
the composition of the grinding wheels must be adjusted to obtain optimum results. Although it is impossible to list and to appraise all possible variations and to define their effects on the selection of the best suited grinding wheels, some guidance is obtained from experience. The following tabulation indicates the general directions in which the characteristics of the initially selected grinding wheel may have to be altered in order to approach optimum performance. Variations in a sense opposite to those shown will call for wheel characteristic changes in reverse. Conditions or Objectives To increase cutting rate To retain wheel size and/or form For small or narrow work surface For larger wheel diameter To improve finish on work For increased work speed or feed rate For increased wheel speed
For interrupted or coarse work surface For thin walled parts To reduce load on the machine drive motor
Direction of Change Coarser grain, softer bond, higher porosity Finer grain, harder bond Finer grain, harder bond Coarser grain Finer grain, harder bond, or resilient bond Harder bond Generally, softer bond, except for highspeed grinding, which requires a harder bond for added wheel strength Harder bond Softer bond Softer bond
Dressing and Truing Grinding Wheels.—The perfect grinding wheel operating under ideal conditions will be self sharpening, i.e., as the abrasive grains become dull, they will tend to fracture and be dislodged from the wheel by the grinding forces, thereby exposing new, sharp abrasive grains. Although in precision machine grinding this ideal sometimes may be partially attained, it is almost never attained completely. Usually, the grinding wheel must be dressed and trued after mounting on the precision grinding machine spindle and periodically thereafter. Dressing may be defined as any operation performed on the face of a grinding wheel that improves its cutting action. Truing is a dressing operation but is more precise, i.e., the face of the wheel may be made parallel to the spindle or made into a radius or special shape. Regularly applied truing is also needed for accurate size control of the work, particularly in automatic grinding. The tools and processes generally used in grinding wheel dressing and truing are listed and described in Table 1. Table 1. Tools and Methods for Grinding Wheel Dressing and Truing Designation
Description
Rotating Hand Dressers
Freely rotating discs, either star-shaped with protruding points or discs with corrugated or twisted perimeter, supported in a fork-type handle, the lugs of which can lean on the tool rest of the grinding machine.
Abrasive Sticks
Made of silicon carbide grains with a hard bond. Applied directly or supported in a handle. Less frequently abrasive sticks are also made of boron carbide.
Application Preferred for bench- or floor-type grinding machines; also for use on heavy portable grinders (snagging grinders) where free-cutting proper ties of the grinding wheel are primarily sought and the accuracy of the trued profile is not critical. Usually hand held and use limited to smaller-size wheels. Because it also shears the grains of the grinding wheel, or preshaping, prior to final dressing with, e.g., a diamond.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition GRINDING WHEELS
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Table 1. (Continued) Tools and Methods for Grinding Wheel Dressing and Truing Designation
Description
Abrasive Wheels (Rolls)
Silicon carbide grains in a hard vitrified bond are cemented on ball-bearing mounted spindles. Use either as hand tools with handles or rigidly held in a supporting member of the grinding machine. Generally freely rotating; also available with adjustable brake for diamond wheel dressing.
Single-Point Diamonds
A diamond stone of selected size is mounted in a steel nib of cylindrical shape with or without head, dimensioned to fit the truing spindle of specific grinding machines. Proper orientation and retainment of the diamond point in the setting is an important requirement.
Single-Point Form Truing Diamonds
Selected diamonds having symmetrically located natural edges with precisely lapped diamond points, controlled cone angles and vertex radius, and the axis coinciding with that of the nib.
Cluster-Type Diamond Dresser
Several, usually seven, smaller diamond stones are mounted in spaced relationship across the working surface of the nib. In some tools, more than a single layer of such clusters is set at parallel levels in the matrix, the deeper positioned layer becoming active after the preceding layer has worn away.
Impregnated Matrix-Type Diamond Dressers
The operating surface consists of a layer of small, randomly distributed, yet rather uniformly spaced diamonds that are retained in a bond holding the points in an essentially common plane. Supplied either with straight or canted shaft, the latter being used to cancel the tilt of angular truing posts.
Form- Generating Truing Devices
Swiveling diamond holder post with adjustable pivot location, arm length, and swivel arc, mounted on angularly adjustable cross slides with controlled traverse movement, permits the generation of various straight and circular profile elements, kept in specific mutual locations.
Application Preferred for large grinding wheels as a diamond saver, but also for improved control of the dressed surface characteristics. By skewing the abrasive dresser wheel by a few degrees out of parallel with the grinding wheel axis, the basic crushing action is supplemented with wiping and shearing, thus producing the desired degree of wheel surface smoothness. The most widely used tool for dressing and truing grinding wheels in precision grinding. Permits precisely controlled dressing action by regulating infeed and cross feed rate of the truing spindle when the latter is guided by cams or templates for accurate form truing. Used for truing operations requiring very accurately controlled, and often steeply inclined wheel profiles, such as are needed for thread and gear grinding, where one or more diamond points participate in generating the resulting wheel periphery form. Dependent on specially designed and made truing diamonds and nibs. Intended for straight-face dressing and permits the utilization of smaller, less expensive diamond stones. In use, the holder is canted at a 3° to 10° angle, bringing two to five points into contact with the wheel. The multiplepoint contact permits faster cross feed rates during truing than may be used with single-point diamonds for generating a specific degree of wheel-face finish. For the truing of wheel surfaces consisting of a single or several flat elements. The nib face should be held tangent to the grinding wheel periphery or parallel with a flat working surface. Offers economic advantages where technically applicable because of using less expensive diamond splinters presented in a manner permitting efficient utilization. Such devices are made in various degrees of complexity for the positionally controlled interrelation of several different profile elements. Limited to regular straight and circular sections, yet offers great flexibility of setup, very accurate adjustment, and unique versatility for handling a large variety of frequently changing profiles.
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Machinery's Handbook 27th Edition 1198
GRINDING WHEELS
Table 1. (Continued) Tools and Methods for Grinding Wheel Dressing and Truing Designation
Description
ContourDuplicating Truing Devices
The form of a master, called cam or template, shaped to match the profile to be produced on the wheel, or its magnified version, is translated into the path of the diamond point by means of mechanical linkage, a fluid actuator, or a pantograph device.
Grinding Wheel Contouring by Crush Truing
A hardened steel or carbide roll, which is free to rotate and has the desired form of the workpiece, is fed gradually into the grinding wheel, which runs at slow speed. The roll will, by crushing action, produce its reverse form in the wheel. Crushing produces a free-cutting wheel face with sharp grains.
Rotating Diamond RollType Grinding Wheel Truing
Special rolls made to agree with specific profile specifications have their periphery coated with a large number of uniformly distributed diamonds, held in a matrix into which the individual stones are set by hand (for larger diamonds) or bonded by a plating process (for smaller elements).
Diamond Dressing Blocks
Made as flat blocks for straight wheel surfaces, are also available for radius dressing and profile truing. The working surface consists of a layer of electroplated diamond grains, uniformly distributed and capable of truing even closely toleranced profiles.
Application Preferred single-point truing method for profiles to be produced in quantities warranting the making of special profile bars or templates. Used also in small- and medium-volume production when the complexity of the profile to be produced excludes alternate methods of form generation. Requires grinding machines designed for crush truing, having stiff spindle bearings, rigid construction, slow wheel speed for truing, etc. Due to the cost of crush rolls and equipment, the process is used for repetitive work only. It is one of the most efficient methods for precisely duplicating complex wheel profiles that are capable of grinding in the 8-microinch AA range. Applicable for both surface and cylindrical grinding. The diamond rolls must be rotated by an air, hydraulic, or electric motor at about one-fourth of the grinding wheel surface speed and in opposite direction to the wheel rotation. Whereas the initial costs are substantially higher than for single-point diamond truing the savings in truing time warrants the method's application in large-volume production of profile-ground components. For straight wheels, dressing blocks can reduce dressing time and offer easy installation on surface grinders, where the blocks mount on the magnetic plate. Recommended for smalland medium-volume production for truing intricate profiles on regular surface grinders, because the higher pressure developed in crush dressing is avoided.
Guidelines for Truing and Dressing with Single-Point Diamonds.—The diamond nib should be canted at an angle of 10 to 15 degrees in the direction of the wheel rotation and also, if possible, by the same amount in the direction of the cross feed traverse during the truing (see diagram). The dragging effect resulting from this “angling,” combined with the occasional rotation of the diamond nib in its holder, will prolong the diamond life by limiting the extent of wear facets and will also tend to produce a pyramid shape of the diamond tip. The diamond may also be set to contact the wheel at about 1⁄8 to 1⁄4 inch below its centerline. Depth of Cut: This amount should not exceed 0.001 inch per pass for general work, and will have to be reduced to 0.0002 to 0.0004 inch per pass for wheels with fine grains used for precise finishing work. Diamond crossfeed rate: This value may be varied to some extent depending on the required wheel surface: faster crossfeed for free cutting, and slower crossfeed for produc-
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Machinery's Handbook 27th Edition GRINDING WHEELS
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ing fine finishes. Such variations, however, must always stay within the limits set by the grain size of the wheel. Thus, the advance rate of the truing diamond per wheel revolution should not exceed the diameter of a grain or be less than half of that rate. Consequently, the diamond crossfeed must be slower for a large wheel than for a smaller wheel having the same grain size number. Typical crossfeed values for frequently used grain sizes are given in Table 2.
10 – 15 C L 10 – 15 1
CROSSFEED
8"
– 1 4"
Table 2. Typical Diamond Truing and Crossfeeds Grain Size Crossfeed per Wheel Rev., in. Grain Size Crossfeed per Wheel Rev., in.
30
36
46
50
0.014–0.024
0.012–0.019
0.008–0.014
0.007–0.012
60
80
120
…
0.006–0.010
0.004–0.007
0.0025–0.004
…
These values can be easily converted into the more conveniently used inch-per-minute units, simply by multiplying them by the rpm of the grinding wheel. Example:For a 20-inch diameter wheel, Grain No. 46, running at 1200 rpm: Crossfeed rate for roughing-cut truing—approximately 17 ipm, for finishing-cut truing—approximately 10 ipm Coolant should be applied before the diamond comes into contact with the wheel and must be continued in generous supply while truing. The speed of the grinding wheel should be at the regular grinding rate, or not much lower. For that reason, the feed wheels of centerless grinding machines usually have an additional speed rate higher than functionally needed, that speed being provided for wheel truing only. The initial approach of the diamond to the wheel surface must be carried out carefully to prevent sudden contact with the diamond, resulting in penetration in excess of the selected depth of cut. It should be noted that the highest point of a worn wheel is often in its center portion and not at the edge from which the crossfeed of the diamond starts. The general conditions of the truing device are important for best truing results and for assuring extended diamond life. A rigid truing spindle, well-seated diamond nib, and firmly set diamond point are mandatory. Sensitive infeed and smooth traverse movement at uniform speed also must be maintained. Resetting of the diamond point.: Never let the diamond point wear to a degree where the grinding wheel is in contact with the steel nib. Such contact can damage the setting of the diamond point and result in its loss. Expert resetting of a worn diamond can repeatedly add to its useful life, even when applied to lighter work because of reduced size.
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Machinery's Handbook 27th Edition 1200
GRINDING WHEELS
Size Selection Guide for Single-Point Truing Diamonds.—There are no rigid rules for determining the proper size of the diamond for any particular truing application because of the very large number of factors affecting that choice. Several of these factors are related to the condition, particularly the rigidity, of the grinding machine and truing device, as well as to such characteristics of the diamond itself as purity, crystalline structure, etc. Although these factors are difficult to evaluate in a generally applicable manner, the expected effects of several other conditions can be appraised and should be considered in the selection of the proper diamond size. The recommended sizes in Table 3 must be considered as informative only and as representing minimum values for generally favorable conditions. Factors calling for larger diamond sizes than listed are the following: Silicon carbide wheels (Table 3 refers to aluminum oxide wheels) Dry truing Grain sizes coarser than No. 46 Bonds harder than M Wheel speed substantially higher than 6500 sfm. It is advisable to consider any single or pair of these factors as justifying the selection of one size larger diamond. As an example: for truing an SiC wheel, with grain size No. 36 and hardness P, select a diamond that is two sizes larger than that shown in Table 3 for the wheel size in use. Table 3. Recommended Minimum Sizes for Single-Point Truing Diamonds Diamond Size in Caratsa 0.25 0.35 0.50 0.60 0.75 1.00 1.25 1.50 1.75 2.00 2.50 3.00 3.50 4.00
Index Number (Wheel Dia. × Width in Inches) 3 6 10 15 21 30 48 65 80 100 150 200 260 350
Examples of Max. Grinding Wheel Dimensions Diameter 4 6 8 10 12 12 14 16 20 20 24 24 30 36
Width 0.75 1 1.25 1.50 1.75 2.50 3.50 4.00 4.00 5.00 6.00 8.00 8.00 10.00
a One carat equals 0.2 gram.
Single-point diamonds are available as loose stones, but are preferably procured from specialized manufacturers supplying the diamonds set into steel nibs. Expert setting, comprising both the optimum orientation of the stone and its firm retainment, is mandatory for assuring adequate diamond life and satisfactory truing. Because the holding devices for truing diamonds are not yet standardized, the required nib dimensions vary depending on the make and type of different grinding machines. Some nibs are made with angular heads, usually hexagonal, to permit occasional rotation of the nib either manually, with a wrench, or automatically.
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Machinery's Handbook 27th Edition DIAMOND WHEELS
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Diamond Wheels Diamond Wheels.—A diamond wheel is a special type of grinding wheel in which the abrasive elements are diamond grains held in a bond and applied to form a layer on the operating face of a non-abrasive core. Diamond wheels are used for grinding very hard or highly abrasive materials. Primary applications are the grinding of cemented carbides, such as the sharpening of carbide cutting tools; the grinding of glass, ceramics, asbestos, and cement products; and the cutting and slicing of germanium and silicon. Shapes of Diamond Wheels.—The industry-wide accepted Standard (ANSI B74.31974) specifies ten basic diamond wheel core shapes which are shown in Table 1 with the applicable designation symbols. The applied diamond abrasive layer may have different cross-sectional shapes. Those standardized are shown in Table 2. The third aspect which is standardized is the location of the diamond section on the wheel as shown by the diagrams in Table 3. Finally, modifications of the general core shape together with pertinent designation letters are given in Table 4. The characteristics of the wheel shape listed in these four tables make up the components of the standard designation symbol for diamond wheel shapes. An example of that symbol with arbitrarily selected components is shown in Fig. 1.
Fig. 1. A Typical Diamond Wheel Shape Designation Symbol
An explanation of these components is as follows: Basic Core Shape: This portion of the symbol indicates the basic shape of the core on which the diamond abrasive section is mounted. The shape is actually designated by a number. The various core shapes and their designations are given in Table 1. Diamond Cross-Section Shape: This, the second component, consisting of one or two letters, denotes the cross-sectional shape of the diamond abrasive section. The various shapes and their corresponding letter designations are given in Table 2. Diamond Section Location: The third component of the symbol consists of a number which gives the location of the diamond section, i.e., periphery, side, corner, etc. An explanation of these numbers is shown in Table 3. Modification: The fourth component of the symbol is a letter designating some modification, such as drilled and counterbored holes for mounting or special relieving of diamond section or core. This modification position of the symbol is used only when required. The modifications and their designations are given in Table 4.
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Machinery's Handbook 27th Edition 1202
DIAMOND WHEELS Table 1. Diamond Wheel Core Shapes and Designations ANSI B74.3-1974 1
9
2
11
3
12
4
14
6
15
Table 2. Diamond Cross-sections and Designations ANSI B74.3-1974
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Table 3. Designations for Location of Diamond Section on Diamond Wheel ANSI B74.3-1974 Designation No. and Location
Description
1 — Periphery
The diamond section shall be placed on the periphery of the core and shall extend the full thickness of the wheel. The axial length of this section may be greater than, equal to, or less than the depth of diamond, measured radially. A hub or hubs shall not be considered as part of the wheel thickness for this definition.
2 — Side
The diamond section shall be placed on the side of the wheel and the length of the diamond section shall extend from the periphery toward the center. It may or may not include the entire side and shall be greater than the diamond depth measured axially. It shall be on that side of the wheel which is commonly used for grinding purposes.
3 — Both Sides
The diamond sections shall be placed on both sides of the wheel and shall extend from the periphery toward the center. They may or may not include the entire sides, and the radial length of the diamond section shall exceed the axial diamond depth.
4 — Inside Bevel or Arc
This designation shall apply to the general wheel types 2, 6, 11, 12, and 15 and shall locate the diamond section on the side wall. This wall shall have an angle or arc extending from a higher point at the wheel periphery to a lower point toward the wheel center.
5 — Outside Bevel or Arc
This designation shall apply to the general wheel types, 2, 6, 11, and 15 and shall locate the diamond section on the side wall. This wall shall have an angle or arc extending from a lower point at the wheel periphery to a higher point toward the wheel center.
6 — Part of Periphery
The diamond section shall be placed on the periphery of the core but shall not extend the full thickness of the wheel and shall not reach to either side.
Illustration
7 — Part of Side The diamond section shall be placed on the side of the core and shall not extend to the wheel periphery. It may or may not extend to the center.
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Machinery's Handbook 27th Edition 1204
DIAMOND WHEELS Table 3. (Continued) Designations for Location of Diamond Section on Diamond Wheel ANSI B74.3-1974
Designation No. and Location
Description
Illustration
8 — Throughout Designates wheels of solid diamond abrasive section without cores. 9 — Corner
Designates a location which would commonly be considered to be on the periphery except that the diamond section shall be on the corner but shall not extend to the other corner.
10 — Annular
Designates a location of the diamond abrasive section on the inner annular surface of the wheel.
Composition of Diamond and Cubic Boron Nitride Wheels.—According to American National Standard ANSI B74.13-1990, a series of symbols is used to designate the composition of these wheels. An example is shown below.
Fig. 2. Designation Symbols for Composition of Diamond and Cubic Boron Nitride Wheels
The meaning of each symbol is indicated by the following list: 1) Prefix: The prefix is a manufacturer's symbol indicating the exact kind of abrasive. Its use is optional. 2) Abrasive Type: The letter (B) is used for cubic boron nitride and (D) for diamond. 3) Grain Size: The grain sizes commonly used and varying from coarse to very fine are indicated by the following numbers: 8, 10, 12, 14, 16, 20, 24, 30, 36, 46, 54, 60, 70, 80, 90, 100, 120, 150, 180, and 220. The following additional sizes are used occasionally: 240, 280, 320, 400, 500, and 600. The wheel manufacturer may add to the regular grain number an additional symbol to indicate a special grain combination. 4) Grade: Grades are indicated by letters of the alphabet from A to Z in all bonds or processes. Wheel grades from A to Z range from soft to hard. 5) Concentration: The concentration symbol is a manufacturer's designation. It may be a number or a symbol. 6) Bond: Bonds are indicated by the following letters: B, resinoid; V, vitrified; M, metal. 7) Bond Modification: Within each bond type a manufacturer may have modifications to tailor the bond to a specific application. These modifications may be identified by either letters or numbers. 8) Abrasive Depth: Abrasive section depth, in inches or millimeters (inches illustrated), is indicated by a number or letter which is the amount of total dimensional wear a user may expect from the abrasive portion of the product. Most diamond and CBN wheels are made with a depth of coating on the order of 1⁄16 in., 1⁄8 in., or more as specified. In some cases the diamond is applied in thinner layers, as thin as one thickness of diamond grains. The L is included in the marking system to identify a layered type product. 9) Manufacturer's Identification Symbol: The use of this symbol is optional.
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Machinery's Handbook 27th Edition DIAMOND WHEELS
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Table 4. Designation Letters for Modifications of Diamond Wheels ANSI B74.3-1974 Designation Lettera
Description
B — Drilled and Counterbored
Holes drilled and counterbored in core.
C — Drilled and Countersunk
Holes drilled and countersunk in core.
H — Plain Hole
Straight hole drilled in core.
M — Holes Plain and Threaded
Mixed holes, some plain, some threaded, are in core.
P — Relieved One Core relieved on one side of wheel. Thickness of core Side is less than wheel thickness.
R — Relieved Two Sides
Core relieved on both sides of wheel. Thickness of core is less than wheel thickness.
S — SegmentedDiamond Section
Wheel has segmental diamond section mounted on core. (Clearance between segments has no bearing on definition.)
SS — Segmental and Slotted
Wheel has separated segments mounted on a slotted core.
T — Threaded Holes
Threaded holes are in core.
Q — Diamond Inserted
Three surfaces of the diamond section are partially or completely enclosed by the core.
V — Diamond Inverted
Any diamond cross section, which is mounted on the core so that the interior point of any angle, or the concave side of any arc, is exposed shall be considered inverted. Exception: Diamond cross section AH shall be placed on the core with the concave side of the arc exposed.
a Y — Diamond Inserted and Inverted. See definitions for Q and V.
Copyright 2004, Industrial Press, Inc., New York, NY
Illustration
Machinery's Handbook 27th Edition 1206
DIAMOND WHEELS
The Selection of Diamond Wheels.—Two general aspects must be defined: (a) The shape of the wheel, also referred to as the basic wheel type and (b) The specification of the abrasive portion. Table 5. General Diamond Wheel Recommendations for Wheel Type and Abrasive Specification Typical Applications or Operation
Basic Wheel Type
Single Point Tools (offhand grinding)
D6A2C
Single Point Tools (machine ground)
D6A2H
Chip Breakers
D1A1
Abrasive Specification Rough: MD100-N100-B1⁄8 Finish: MD220-P75-B1⁄8 Rough: MD180-J100-B1⁄8 Finish: MD320-L75-B1⁄8 MD150-R100-B1⁄8
Multitooth Tools and Cutters (face mills, end mills, reamers, broaches, etc.) Rough: MD100-R100-B1⁄8 Combination: MD150-R100-B1⁄8
Sharpening and Backing off
D11V9
Fluting
D12A2
MD180-N100-B1⁄8
Saw Sharpening
D12A2
MD180-R100-B1⁄8
Surface Grinding (horizontal spindle)
D1A1
Finish: MD220-R100-B1⁄8
Rough: MD120-N100-B1⁄8 Finish: MD240-P100-B1⁄8 MD80-R75-B1⁄8
Surface Grinding (vertical spindle)
D2A2T
Cylindrical or Centertype Grinding
D1A1
MD120-P100-B1⁄8
Internal Grinding
D1A1
MD150-N100-B1⁄8
D1A1R
MD150-R100-B1⁄4
Disc
MD400-L50-B1⁄16
Slotting and Cutoff Lapping Hand Honing
DH1, DH2
Rough: MD220-B1⁄16 Finish: MD320-B1⁄6
General recommendations for the dry grinding, with resin bond diamond wheels, of most grades of cemented carbides of average surface to ordinary finishes at normal rates of metal removal with average size wheels, as published by Cincinnati Milacron, are listed in Table 5. A further set of variables are the dimensions of the wheel, which must be adapted to the available grinding machine and, in some cases, to the configuration of the work. The general abrasive specifications in Table 5 may be modified to suit operating conditions by the following suggestions: Use softer wheel grades for harder grades of carbides, for grinding larger areas or larger or wider wheel faces. Use harder wheel grades for softer grades of carbides, for grinding smaller areas, for using smaller and narrower face wheels and for light cuts.
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Machinery's Handbook 27th Edition GRINDING WHEEL SAFETY
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Use fine grit sizes for harder grades of carbides and to obtain better finishes. Use coarser grit sizes for softer grades of carbides and for roughing cuts. Use higher diamond concentration for harder grades of carbides, for larger diameter or wider face wheels, for heavier cuts, and for obtaining better finish. Guidelines for the Handling and Operation of Diamond Wheels.—G r i n d i n g machines used for grinding with diamond wheels should be of the precision type, in good service condition, with true running spindles and smooth slide movements. Mounting of Diamond Wheels: Wheel mounts should be used which permit the precise centering of the wheel, resulting in a runout of less than 0.001 inch axially and 0.0005 inch radially. These conditions should be checked with a 0.0001-inch type dial indicator. Once mounted and centered, the diamond wheel should be retained on its mount and stored in that condition when temporarily removed from the machine. Truing and Dressing: Resinoid bonded diamond wheels seldom require dressing, but when necessary a soft silicon carbide stick may be hand-held against the wheel. Peripheral and cup type wheels may be sharpened by grinding the cutting face with a 60 to 80 grit silicon carbide wheel. This can be done with the diamond wheel mounted on the spindle of the machine, and with the silicon carbide wheel driven at a relatively slow speed by a specially designed table-mounted grinder or by a small table-mounted tool post grinder. The diamond wheel can be mounted on a special arbor and ground on a lathe with a tool post grinder; peripheral wheels can be ground on a cylindrical grinder or with a special brakecontrolled truing device with the wheel mounted on the machine on which it is used. Cup and face type wheels are often lapped on a cast iron or glass plate using a 100 grit silicon carbide abrasive. Care must be used to lap the face parallel to the back, otherwise they must be ground to restore parallelism. Peripheral diamond wheels can be trued and dressed by grinding a silicon carbide block or a special diamond impregnated bronze block in a manner similar to surface grinding. Conventional diamonds must not be used for truing and dressing diamond wheels. Speeds and Feeds in Diamond Grinding.—General recommendations are as follows: Wheel Speeds: The generally recommended wheel speeds for diamond grinding are in the range of 5000 to 6000 surface feet per minute, with this upper limit as a maximum to avoid harmful “overspeeding.” Exceptions from that general rule are diamond wheels with coarse grains and high concentration (100 per cent) where the wheel wear in dry surface grinding can be reduced by lowering the speed to 2500–3000 sfpm. However, this lower speed range can cause rapid wheel breakdown in finer grit wheels or in those with reduced diamond concentration. Work Speeds: In diamond grinding, work rotation and table traverse are usually established by experience, adjusting these values to the selected infeed so as to avoid excessive wheel wear. Infeed per Pass: Often referred to as downfeed and usually a function of the grit size of the wheel. The following are general values which may be increased for raising the productivity, or lowered to improve finish or to reduce wheel wear. Wheel Grit Size Range 100 to 120 150 to 220 250 and finer
Infeed per Pass 0.001 inch 0.0005 inch 0.00025 inch
Grinding Wheel Safety Safety in Operating Grinding Wheels.—Grinding wheels, although capable of exceptional cutting performance due to hardness and wear resistance, are prone to damage caused by improper handling and operation. Vitrified wheels, comprising the major part of grinding wheels used in industry, are held together by an inorganic bond which is actually
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Machinery's Handbook 27th Edition 1208
GRINDING WHEEL SAFETY
a type of pottery product and therefore brittle and breakable. Although most of the organic bond types are somewhat more resistant to shocks, it must be realized that all grinding wheels are conglomerates of individual grains joined by a bond material whose strength is limited by the need of releasing the dull, abrasive grains during use. It must also be understood that during the grinding process very substantial forces act on the grinding wheel, including the centrifugal force due to rotation, the grinding forces resulting from the resistance of the work material, and shocks caused by sudden contact with the work. To be able to resist these forces, the grinding wheel must have a substantial minimum strength throughout that is well beyond that needed to hold the wheel together under static conditions. Finally, a damaged grinding wheel can disintegrate during grinding, liberating dormant forces which normally are constrained by the resistance of the bond, thus presenting great hazards to both operator and equipment. To avoid breakage of the operating wheel and, should such a mishap occur, to prevent damage or injury, specific precautions must be applied. These safeguards have been formulated into rules and regulations and are set forth in the American National Standard ANSI B7.1-1988, entitled the American National Standard Safety Requirements for the Use, Care, and Protection of Abrasive Wheels. Handling, Storage and Inspection.—Grinding wheels should be hand carried, or transported, with proper support, by truck or conveyor. A grinding wheel must not be rolled around on its periphery. The storage area, positioned not far from the location of the grinding machines, should be free from excessive temperature variations and humidity. Specially built racks are recommended on which the smaller or thin wheels are stacked lying on their sides and the larger wheels in an upright position on two-point cradle supports consisting of appropriately spaced wooden bars. Partitions should separate either the individual wheels, or a small group of identical wheels. Good accessibility to the stored wheels reduces the need of undesirable handling. Inspection will primarily be directed at detecting visible damage, mostly originating from handling and shipping. Cracks which are not obvious can usually be detected by “ring testing,” which consists of suspending the wheel from its hole and tapping it with a nonmetallic implement. Heavy wheels may be allowed to rest vertically on a clean, hard floor while performing this test. A clear metallic tone, a “ring”, should be heard; a dead sound being indicative of a possible crack or cracks in the wheel. Machine Conditions.—The general design of the grinding machines must ensure safe operation under normal conditions. The bearings and grinding wheel spindle must be dimensioned to withstand the expected forces and ample driving power should be provided to ensure maintenance of the rated spindle speed. For the protection of the operator, stationary machines used for dry grinding should have a provision made for connection to an exhaust system and when used for off-hand grinding, a work support must be available. Wheel guards are particularly important protection elements and their material specifications, wall thicknesses and construction principles should agree with the Standard’s specifications. The exposure of the wheel should be just enough to avoid interference with the grinding operation. The need for access of the work to the grinding wheel will define the boundary of guard opening, particularly in the direction of the operator. Grinding Wheel Mounting.—The mass and speed of the operating grinding wheel makes it particularly sensitive to imbalance. Vibrations that result from such conditions are harmful to the machine, particularly the spindle bearings, and they also affect the ground surface, i.e., wheel imbalance causes chatter marks and interferes with size control. Grinding wheels are shipped from the manufacturer’s plant in a balanced condition, but retaining the balanced state after mounting the wheel is quite uncertain. Balancing of the mounted wheel is thus required, and is particularly important for medium and large size
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Machinery's Handbook 27th Edition GRINDING WHEEL SAFETY
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wheels, as well as for producing acccurate and smooth surfaces. The most common way of balancing mounted wheels is by using balancing flanges with adjustable weights. The wheel and balancing flanges are mounted on a short balancing arbor, the two concentric and round stub ends of which are supported in a balancing stand. Such stands are of two types: 1) the parallel straight-edged, which must be set up precisely level; and 2) the disk type having two pairs of ball bearing mounted overlapping disks, which form a V for containing the arbor ends without hindering the free rotation of the wheel mounted on that arbor. The wheel will then rotate only when it is out of balance and its heavy spot is not in the lowest position. Rotating the wheel by hand to different positions will move the heavy spot, should such exist, from the bottom to a higher location where it can reveal its presence by causing the wheel to turn. Having detected the presence and location of the heavy spot, its effect can be cancelled by displacing the weights in the circular groove of the flange until a balanced condition is accomplished. Flanges are commonly used means for holding grinding wheels on the machine spindle. For that purpose, the wheel can either be mounted directly through its hole or by means of a sleeve which slips over a tapered section of the machine spindle. Either way, the flanges must be of equal diameter, usually not less than one-third of the new wheel’s diameter. The purpose is to securely hold the wheel between the flanges without interfering with the grinding operation even when the wheel becomes worn down to the point where it is ready to be discarded. Blotters or flange facings of compressible material should cover the entire contact area of the flanges. One of the flanges is usually fixed while the other is loose and can be removed and adjusted along the machine spindle. The movable flange is held against the mounted grinding wheel by means of a nut engaging a threaded section of the machine spindle. The sense of that thread should be such that the nut will tend to tighten as the spindle revolves. In other words, to remove the nut, it must be turned in the direction that the spindle revolves when the wheel is in operation. Safe Operating Speeds.—Safe grinding processes are predicated on the proper use of the previously discussed equipment and procedures, and are greatly dependent on the application of adequate operating speeds. The Standard establishes maximum speeds at which grinding wheels can be operated, assigning the various types of wheels to several classification groups. Different values are listed according to bond type and to wheel strength, distinguishing between low, medium and high strength wheels. For the purpose of general information, the accompanying table shows an abbreviated version of the Standard’s specification. However, for the governing limits, the authoritative source is the manufacturer’s tag on the wheel which, particularly for wheels of lower strength, might specify speeds below those of the table. All grinding wheels of 6 inches or greater diameter must be test run in the wheel manufacturer’s plant at a speed that for all wheels having operating speeds in excess of 5000 sfpm is 1.5 times the maximum speed marked on the tag of the wheel. The table shows the permissible wheel speeds in surface feet per minute (sfpm) units, whereas the tags on the grinding wheels state, for the convenience of the user, the maximum operating speed in revolutions per minute (rpm). The sfpm unit has the advantage of remaining valid for worn wheels whose rotational speed may be increased to the applicable sfpm value. The conversion from either one to the other of these two kinds of units is a matter of simple calculation using the formulas: D- × π sfpm = rpm × ----12
or
sfpm × 12 rpm = -----------------------D×π
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Machinery's Handbook 27th Edition 1210
GRINDING WHEEL SAFETY
where D = maximum diameter of the grinding wheel, in inches. Table 2, showing the conversion values from surface speed into rotational speed, can be used for the direct reading of the rpm values corresponding to several different wheel diameters and surface speeds. Special Speeds: Continuing progress in grinding methods has led to the recognition of certain advantages that can result from operating grinding wheels above, sometimes even higher than twice, the speeds considered earlier as the safe limits of grinding wheel operations. Advantages from the application of high speed grinding are limited to specific processes, but the Standard admits, and offers code regulations for the use of wheels at special high speeds. These regulations define the structural requirements of the grinding machine and the responsibilities of the grinding wheel manufacturers, as well as of the users. High speed grinding should not be applied unless the machines, particularly guards, spindle assemblies, and drive motors, are suitable for such methods. Also, appropriate grinding wheels expressly made for special high speeds must be used and, of course, the maximum operating speeds indicated on the wheel’s tag must never be exceeded. Portable Grinders.—The above discussed rules and regulations, devised primarily for stationary grinding machines apply also to portable grinders. In addition, the details of various other regulations, specially applicable to different types of portable grinders are discussed in the Standard, which should be consulted, particularly for safe applications of portable grinding machines. Table 1. Maximum Peripheral Speeds for Grinding Wheels Based on ANSI B7.1–1988 Classification No.
1
2 3 4 5 6 7 8 9 10 11 12
Maximum Operating Speeds, sfpm, Depending on Strength of Bond Types of Wheelsa Straight wheels — Type 1, except classifications 6, 7, 9, 10, 11, and 12 below Taper Side Wheels — Type 4b Types 5, 7, 20, 21, 22, 23, 24, 25, 26 Dish wheels — Type 12 Saucer wheels — Type 13 Cones and plugs — Types 16, 17, 18, 19 Cylinder wheels — Type 2 Segments Cup shape tool grinding wheels — Types 6 and 11 (for fixed base machines) Cup shape snagging wheels — Types 6 and 11 (for portable machines) Abrasive disks Reinforced wheels — except cutting-off wheels (depending on diameter and thickness) Type 1 wheels for bench and pedestal grinders, Types 1 and 5 also in certain sizes for surface grinders Diamond and cubic boron nitride wheels Metal bond Steel centered cutting off Cutting-off wheels — Larger than 16-inch diameter (incl. reinforced organic) Cutting-off wheels — 16-inch diameter and smaller (incl. reinforced organic) Thread and flute grinding wheels Crankshaft and camshaft grinding wheels
Inorganic Bonds
Organic Bonds
5,500 to 6,500
6,500 to 9,500
5,000 to 6,000
5,000 to 7,000
4,500 to 6,000
6,000 to 8,500
4,500 to 6,500
6,000 to 9,500
5,500 to 6,500
5,500 to 8,500
…
9,500 to 16,000
5,500 to 7,550
6,500 to 9,500
to 6,500 to 12,000 to 16,000
to 9,500 … to 16,000
…
9,500 to 14,200
…
9,500 to 16,000
8,000 to 12,000 5,500 to 8,500
8,000 to 12,000 6,500 to 9,500
a See Tables 1a and 1b starting on page
1181. Non-standard shape. For snagging wheels, 16 inches and larger — Type 1, internal wheels — Types 1 and 5, and mounted wheels, see ANSI B7.1–1988. Under no conditions should a wheel be operated faster than the maximum operating speed established by the manufacturer. b
Values in this table are for general information only.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 2. Revolutions per Minute for Various Grinding Speeds and Wheel Diameters (Based on ANSI B7.1–1988) Peripheral (Surface) Speed, Feet per Minute Wheel Diameter, Inch
4,500
5,000
5,500
6,000
6,500
7,000
7,500
8,000
9,000
9,500
10,000
12,000
14,000
16,000
15,279 7,639 5,093 3,820 3,056 2,546 2,183 1,910 1,698 1,528 1,273 1,091 955 849 764 694 637 588 546 509 477 449 424 402 382 364 347 332 318 288 255 212
17,189 8,594 5,730 4,297 3,438 2,865 2,456 2,149 1,910 1,719 1,432 1,228 1,074 955 859 781 716 661 614 573 537 506 477 452 430 409 391 374 358 324 286 239
19,099 9,549 6,366 4,775 3,820 3,183 2,728 2,387 2,122 1,910 1,592 1,364 1,194 1,061 955 868 796 735 682 637 597 562 531 503 477 455 434 415 398 360 318 265
21,008 10,504 7,003 5,252 4,202 3,501 3,001 2,626 2,334 2,101 1,751 1,501 1,313 1,167 1,050 955 875 808 750 700 657 618 584 553 525 500 477 457 438 396 350 292
22,918 11,459 7,639 5,730 4,584 3,820 3,274 2,865 2,546 2,292 1,910 1,637 1,432 1,273 1,146 1,042 955 881 819 764 716 674 637 603 573 546 521 498 477 432 382 318
24,828 12,414 8,276 6,207 4,966 4,138 3,547 3,104 2,759 2,483 2,069 1,773 1,552 1,379 1,241 1,129 1,035 955 887 828 776 730 690 653 621 591 564 540 517 468 414 345
26,738 13,369 8,913 6,685 5,348 4,456 3,820 3,342 2,971 2,674 2,228 1,910 1,671 1,485 1,337 1,215 1,114 1,028 955 891 836 786 743 704 668 637 608 581 557 504 446 371
28,648 14,324 9,549 7,162 5,730 4,775 4,093 3,581 3,183 2,865 2,387 2,046 1,790 1,592 1,432 1,302 1,194 1,102 1,023 955 895 843 796 754 716 682 651 623 597 541 477 398
30,558 15,279 10,186 7,639 6,112 5,093 4,365 3,820 3,395 3,056 2,546 2,183 1,910 1,698 1,528 1,389 1,273 1,175 1,091 1,019 955 899 849 804 764 728 694 664 637 577 509 424
32,468 16,234 10,823 8,117 6,494 5,411 4,638 4,058 3,608 3,247 2,706 2,319 2,029 1,804 1,623 1,476 1,353 1,249 1,160 1,082 1,015 955 902 854 812 773 738 706 676 613 541 451
34,377 17,189 11,459 8,594 6,875 5,730 4,911 4,297 3,820 3,438 2,865 2,456 2,149 1,910 1,719 1,563 1,432 1,322 1,228 1,146 1,074 1,011 955 905 859 819 781 747 716 649 573 477
36,287 18,144 12,096 9,072 7,257 6,048 5,184 4,536 4,032 3,629 3,024 2,592 2,268 2,016 1,814 1,649 1,512 1,396 1,296 1,210 1,134 1,067 1,008 955 907 864 825 789 756 685 605 504
38,197 19,099 12,732 9,549 7,639 6,366 5,457 4,775 4,244 3,820 3,183 2,728 2,387 2,122 1,910 1,736 1,592 1,469 1,364 1,273 1,194 1,123 1,061 1,005 955 909 868 830 796 721 637 531
45,837 22,918 15,279 11,459 9,167 7,639 6,548 5,730 5,093 4,584 3,820 3,274 2,865 2,546 2,292 2,083 1,910 1,763 1,637 1,528 1,432 1,348 1,273 1,206 1,146 1,091 1,042 996 955 865 764 637
53,476 26,738 17,825 13,369 10,695 8,913 7,639 6,685 5,942 5,348 4,456 3,820 3,342 2,971 2,674 2,431 2,228 2,057 1,910 1,783 1,671 1,573 1,485 1,407 1,337 1,273 1,215 1,163 1,114 1,009 891 743
61,115 30,558 20,372 15,279 12,223 10,186 8,731 7,639 6,791 6,112 5,093 4,365 3,820 3,395 3,056 2,778 2,546 2,351 2,183 2,037 1,910 1,798 1,698 1,608 1,528 1,455 1,389 1,329 1,273 1,153 1,019 849
Copyright 2004, Industrial Press, Inc., New York, NY
Wheel Diameter, Inch 1 2 3 4 5 6 7 8 9 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 53 60 72
1211
8,500
Revolutions per Minute
GRINDING WHEEL SPEEDS
1 2 3 4 5 6 7 8 9 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 53 60 72
4,000
Machinery's Handbook 27th Edition 1212
CYLINDRICAL GRINDING Cylindrical Grinding
Cylindrical grinding designates a general category of various grinding methods that have the common characteristic of rotating the workpiece around a fixed axis while grinding outside surface sections in controlled relation to that axis of rotation. The form of the part or section being ground in this process is frequently cylindrical, hence the designation of the general category. However, the shape of the part may be tapered or of curvilinear profile; the position of the ground surface may also be perpendicular to the axis; and it is possible to grind concurrently several surface sections, adjacent or separated, of equal or different diameters, located in parallel or mutually inclined planes, etc., as long as the condition of a common axis of rotation is satisfied. Size Range of Workpieces and Machines: Cylindrical grinding is applied in the manufacture of miniature parts, such as instrument components and, at the opposite extreme, for grinding rolling mill rolls weighing several tons. Accordingly, there are cylindrical grinding machines of many different types, each adapted to a specific work-size range. Machine capacities are usually expressed by such factors as maximum work diameter, work length and weight, complemented, of course, by many other significant data. Plain, Universal, and Limited-Purpose Cylindrical Grinding Machines.—The plain cylindrical grinding machine is considered the basic type of this general category, and is used for grinding parts with cylindrical or slightly tapered form. The universal cylindrical grinder can be used, in addition to grinding the basic cylindrical forms, for the grinding of parts with steep tapers, of surfaces normal to the part axis, including the entire face of the workpiece, and for internal grinding independently or in conjunction with the grinding of the part’s outer surfaces. Such variety of part configurations requiring grinding is typical of work in the tool room, which constitutes the major area of application for universal cylindrical grinding machines. Limited-purpose cylindrical grinders are needed for special work configurations and for high-volume production, where productivity is more important than flexibility of adaptation. Examples of limited-purpose cylindrical grinding machines are crankshaft and camshaft grinders, polygonal grinding machines, roll grinders, etc. Traverse or Plunge Grinding.—In traverse grinding, the machine table carrying the work performs a reciprocating movement of specific travel length for transporting the rotating workpiece along the face of the grinding wheel. At each or at alternate stroke ends, the wheel slide advances for the gradual feeding of the wheel into the work. The length of the surface that can be ground by this method is generally limited only by the stroke length of the machine table. In large roll grinders, the relative movement between work and wheel is accomplished by the traverse of the wheel slide along a stationary machine table. In plunge grinding, the machine table, after having been set, is locked and, while the part is rotating, the wheel slide continually advances at a preset rate, until the finish size of the part is reached. The width of the grinding wheel is a limiting factor of the section length that can be ground in this process. Plunge grinding is required for profiled surfaces and for the simultaneous grinding of multiple surfaces of different diameters or located in different planes. When the configuration of the part does not make use of either method mandatory, the choice may be made on the basis of the following general considerations: traverse grinding usually produces a better finish, and the productivity of plunge grinding is generally higher. Work Holding on Cylindrical Grinding Machines.—The manner in which the work is located and held in the machine during the grinding process determines the configuration of the part that can be adapted for cylindrical grinding and affects the resulting accuracy of the ground surface. The method of work holding also affects the attainable production rate, because the mounting and dismounting of the part can represent a substantial portion of the total operating time.
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Machinery's Handbook 27th Edition CYLINDRICAL GRINDING
1213
Whatever method is used for holding the part on cylindrical types of grinding machines, two basic conditions must be satisfied: 1) the part should be located with respect to its correct axis of rotation; and 2) the work drive must cause the part to rotate, at a specific speed, around the established axis. The lengthwise location of the part, although controlled, is not too critical in traverse grinding; however, in plunge grinding, particularly when shoulder sections are also involved, it must be assured with great accuracy. Table 1 presents a listing, with brief discussions, of work-holding methods and devices that are most frequently used in cylindrical grinding. Table 1. Work-Holding Methods and Devices for Cylindrical Grinding Designation
Description
Discussion
Centers, nonrotating (“dead”), with drive plate
Headstock with nonrotating spindle holds The simplest method of holding the work the center. Around the spindle, an indebetween two opposite centers is also the pendently supported sleeve carries the potentially most accurate, as long as cordrive plate for rotating the work. Tailstock rectly prepared and located center holes for opposite center. are used in the work.
Centers, driving type
Word held between two centers obtains its rotation from the concurrently applied drive by the live headstock spindle and live tailstock spindle.
Eliminates the drawback of the common center-type grinding with driver plate, which requires a dog attached to the workpiece. Driven spindles permit the grinding of the work up to both ends.
Chuck, geared, or camactuated
Two, three, or four jaws moved radially through mechanical elements, hand-, or power-operated, exert concentrically acting clamping force on the workpiece.
Adaptable to workpieces of different configurations and within a generally wide capacity of the chuck. Flexible in uses that, however, do not include high-precision work.
Chuck, diaphragm
Force applied by hand or power of a flexible Rapid action and flexible adaptation to difdiaphragm causes the attached jaws to ferent work configurations by means of deflect temporarily for accepting the special jaws offer varied uses for the work, which is held when force is grinding of disk-shaped and similar parts. released.
Collets
Holding devices with externally or internally acting clamping force, easily adaptable to power actuation, assuring high centering accuracy.
Limited to parts with previously machined or ground holding surfaces, because of the small range of clamping movement of the collet jaws.
Face plate
Has four independently actuated jaws, any or several of which may be used, or entirely removed, using the base plate for supporting special clamps.
Used for holding bulky parts, or those of awkward shape, which are ground in small quantities not warranting special fixtures.
Magnetic plate
Flat plates, with pole distribution adapted to Applicable for light cuts such as are frethe work, are mounted on the spindle like quent in tool making, where the rapid chucks and may be used for work with the clamping action and easy access to both locating face normal to the axis. the O.D. and the exposed face are sometimes of advantage.
Steady rests
Two basic types are used: (a) the two-jaw type supporting the work from the back (back rest), leaving access by the wheel; (b) the three-jaw type (center rest).
Special fixtures
Single-purpose devices, designed for a par- Typical workpieces requiring special fixturing are, as examples, crankshafts where ticular workpiece, primarily for providthe holding is combined with balancing ing special locating elements. functions; or internal gears located on the pitch circle of the teeth for O.D. grinding.
A complementary work-holding device, used in conjunction with primary work holders, to provide additional support, particularly to long and/or slender parts.
Selection of Grinding Wheels for Cylindrical Grinding.—For cylindrical grinding, as for grinding in general, the primary factor to be considered in wheel selection is the work material. Other factors are the amount of excess stock and its rate of removal (speeds and feeds), the desired accuracy and surface finish, the ratio of wheel and work diameter, wet or dry grinding, etc. In view of these many variables, it is not practical to set up a complete
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1214
CYLINDRICAL GRINDING
list of grinding wheel recommendations with general validity. Instead, examples of recommendations embracing a wide range of typical applications and assuming common practices are presented in Table 2. This is intended as a guide for the starting selection of grinding-wheel specifications which, in case of a not entirely satisfactory performance, can be refined subsequently. The content of the table is a version of the grinding-wheel recommendations for cylindrical grinding by the Norton Company using, however, non-proprietary designations for the abrasive types and bonds. Table 2. Wheel Recommendations for Cylindrical Grinding Material Aluminum Armatures (laminated) Axles (auto & railway) Brass Bronze Soft Hard Bushings (hardened steel) Bushings (cast iron) Cam lobes (cast alloy) Roughing Finishing Cam lobes (hardened steel) Roughing Finishing Cast iron Chromium plating Commercial finish High finish Reflective finish Commutators (copper) Crankshafts (airplane) Pins Bearings Crankshafts (automotive pins and bearings) Finishing Roughing & finishing Regrinding Regrinding, sprayed metal Drills
Wheel Marking SFA46-18V SFA100-18V A54-M5V C36-KV C36-KV A46-M5V BFA60-L5V C36-JV BFA54-N5V A70-P6B BFA54-L5V BFA80-T8B C36-JV SFA60-J8V A150-K5E C500-I9E C60-M4E BFA46-K5V A46-L5V
A54-N5V A54-O5V A54-M5V C60-JV BFA54-N5V
Material Forgings Gages (plug) General-purpose grinding Glass Gun barrels Spotting and O.D. Nitralloy Before nitriding After nitriding Commercial finish High finish Reflective finish Pistons (aluminum) (cast iron) Plastics Rubber Soft Hard Spline shafts Sprayed metal Steel Soft 1 in. dia. and smaller over 1 in dia. Hardened 1 in. dia. and smaller over 1 in. dia. 300 series stainless Stellite Titanium Valve stems (automative) Valve tappets
Wheel Marking A46-M5V SFA80-K8V SFA54-L5V BFA220-011V BFA60-M5V A60-K5V SFA60-18V C100-1V C500-19E SFA46-18V C36-KV C46-JV SFA20-K5B C36-KB SFA60-N5V C60-JV
SFA60-M5V SFA46-L5V SFA80-L8V SFA60-K5V SFA46-K8V BFA46-M5V C60-JV BFA54-N5V BFA54-M5V
Note: Prefixes to the standard designation “A” of aluminum oxide indicate modified abrasives as follows: BFA = Blended friable (a blend of regular and friable), SFA = Semifriable.
Operational Data for Cylindrical Grinding.—In cylindrical grinding, similarly to other metalcutting processes, the applied speed and feed rates must be adjusted to the operational conditions as well as to the objectives of the process. Grinding differs, however, from other types of metalcutting methods in regard to the cutting speed of the tool which, in grinding, is generally not a variable; it should be maintained at, or close to the optimum rate, commonly 6500 feet per minute peripheral speed. In establishing the proper process values for grinding, of prime consideration are the work material, its condition (hardened or soft), and the type of operation (roughing or finishing). Other influencing factors are the characteristics of the grinding machine (stability, power), the specifications of the grinding wheel, the material allowance, the rigidity and
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Machinery's Handbook 27th Edition CYLINDRICAL GRINDING
1215
balance of the workpiece, as well as several grinding process conditions, such as wet or dry grinding, the manner of wheel truing, etc. Variables of the cylindrical grinding process, often referred to as grinding data, comprise the speed of work rotation (measured as the surface speed of the work); the infeed (in inches per pass for traverse grinding, or in inches per minute for plunge grinding); and, in the case of traverse grinding, the speed of the reciprocating table movement (expressed either in feet per minute, or as a fraction of the wheel width for each revolution of the work). For the purpose of starting values in setting up a cylindrical grinding process, a brief listing of basic data for common cylindrical grinding conditions and involving frequently used materials, is presented in Table 3. Table 3. Basic Process Data for Cylindrical Grinding Traverse Grinding Work Material Plain Carbon Steel Alloy Steel Tool Steel Copper Alloys
Aluminum Alloys
Material Condition
Work Surface Speed, fpm
Infeed, Inch/Pass
Traverse for Each Work Revolution, In Fractions of the Wheel Width
Roughing
Roughing
Finishing
Annealed
100
0.002
0.0005
1⁄ 2
1⁄ 6
Hardened
70
0.002
0.0003–0.0005
1⁄ 4
1⁄ 8
Annealed
100
0.002
0.0005
1⁄ 2
1⁄ 6
Hardened
70
0.002
0.0002–0.0005
1⁄ 4
1⁄ 8
Annealed
60
0.002
0.0005 max.
1⁄ 2
1⁄ 6
Hardened Annealed or Cold Drawn Cold Drawn or Solution Treated
50
0.002
0.0001–0.0005
1⁄ 4
1⁄ 8 1⁄ 6
1⁄ 6
Finishing
100
0.002
0.0005 max.
1⁄ 3
150
0.002
0.0005 max.
1⁄ 3
Plunge Grinding Work Material Steel, soft Plain carbon steel, hardened Alloy and tool steel, hardened
Infeed per Revolution of the Work, Inch Roughing
Finishing
0.0005 0.0002 0.0001
0.0002 0.000050 0.000025
These data, which are, in general, considered conservative, are based on average operating conditions and may be modified subsequently by: a) reducing the values in case of unsatisfactory quality of the grinding or the occurrence of failures; and b) increasing the rates for raising the productivity of the process, particularly for rigid workpieces, substantial stock allowance, etc.
High-Speed Cylindrical Grinding.—The maximum peripheral speed of the wheels in regular cylindrical grinding is generally 6500 feet per minute; the commonly used grinding wheels and machines are designed to operate efficiently at this speed. Recently, efforts were made to raise the productivity of different grinding methods, including cylindrical grinding, by increasing the peripheral speed of the grinding wheel to a substantially higher than traditional level, such as 12,000 feet per minute or more. Such methods are designated by the distinguishing term of high-speed grinding. For high-speed grinding, special grinding machines have been built with high dynamic stiffness and static rigidity, equipped with powerful drive motors, extra-strong spindles and bearings, reinforced wheel guards, etc., and using grinding wheels expressly made and tested for operating at high peripheral speeds. The higher stock-removal rate accomplished by high-speed grinding represents an advantage when the work configuration and material permit, and the removable stock allowance warrants its application.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1216
CYLINDRICAL GRINDING
CAUTION: High-speed grinding must not be applied on standard types of equipment, such as general types of grinding machines and regular grinding wheels. Operating grinding wheels, even temporarily, at higher than approved speed constitutes a grave safety hazard. Areas and Degrees of Automation in Cylindrical Grinding.—Power drive for the work rotation and for the reciprocating table traverse are fundamental machine movements that, once set for a certain rate, will function without requiring additional attention. Loading and removing the work, starting and stopping the main movements, and applying infeed by hand wheel are carried out by the operator on cylindrical grinding machines in their basic degree of mechanization. Such equipment is still frequently used in tool room and jobbing-type work. More advanced levels of automation have been developed for cylindrical grinders and are being applied in different degrees, particularly in the following principal respects: a) Infeed, in which different rates are provided for rapid approach, roughing and finishing, followed by a spark-out period, with presetting of the advance rates, the cutoff points, and the duration of time-related functions. b) Automatic cycling actuated by a single lever to start work rotation, table reciprocation, grinding-fluid supply, and infeed, followed at the end of the operation by wheel slide retraction, the successive stopping of the table movement, the work rotation, and the fluid supply. c) Table traverse dwells (tarry) in the extreme positions of the travel, over preset periods, to assure uniform exposure to the wheel contact of the entire work section. d) Mechanized work loading, clamping, and, after termination of the operation, unloading, combined with appropriate work-feeding devices such as indexing-type drums. e) Size control by in-process or post-process measurements. Signals originated by the gage will control the advance movement or cause automatic compensation of size variations by adjusting the cutoff points of the infeed. f) Automatic wheel dressing at preset frequency, combined with appropriate compensation in the infeed movement. g) Numerical control obviates the time-consuming setups for repetitive work performed on small- or medium-size lots. As an application example: shafts with several sections of different lengths and diameters can be ground automatically in a single operation, grinding the sections in consecutive order to close dimensional limits, controlled by an in-process gage, which is also automatically set by means of the program. The choice of the grinding machine functions to be automated and the extent of automation will generally be guided by economic considerations, after a thorough review of the available standard and optional equipment. Numerical control of partial or complete cycles is being applied to modern cylindrical and other grinding machines. Cylindrical Grinding Troubles and Their Correction.—Troubles that may be encountered in cylindrical grinding may be classified as work defects (chatter, checking, burning, scratching, and inaccuracies), improperly operating machines (jumpy infeed or traverse), and wheel defects (too hard or soft action, loading, glazing, and breakage). The Landis Tool Company has listed some of these troubles, their causes, and corrections as follows: Chatter: Sources of chatter include: 1) faulty coolant; 2) wheel out of balance; 3) wheel out of round; 4) wheel too hard; 5) improper dressing; 6) faulty work support or rotation; 7) improper operation; 8) faulty traverse; 9) work vibration; 10) outside vibration transmitted to machine; 11) interference; 12) wheel base; and 13) headstock. Suggested procedures for correction of these troubles are: 1) Faulty coolant: Clean tanks and lines. Replace dirty or heavy coolant with correct mixture. 2) Wheel out of balance: Rebalance on mounting before and after dressing. Run wheel without coolant to remove excess water. Store a removed wheel on its side to keep retained
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CYLINDRICAL GRINDING
1217
water from causing a false heavy side. Tighten wheel mounting flanges. Make sure wheel center fits spindle. 3) Wheel out of round: True before and after balancing. True sides to face. 4) Wheel too hard: Use coarser grit, softer grade, more open bond. See Wheel Defects on page 1219. 5) Improper dressing: Use sharp diamond and hold rigidly close to wheel. It must not overhang excessively. Check diamond in mounting. 6) Faulty work support or rotation: Use sufficient number of work rests and adjust them more carefully. Use proper angles in centers of work. Clean dirt from footstock spindle and be sure spindle is tight. Make certain that work centers fit properly in spindles. 7) Improper operation: Reduce rate of wheel feed. 8) Faulty traverse: See Uneven Traverse or Infeed of Wheel Head on page 1219. 9) Work vibration: Reduce work speed. Check workpiece for balance. 10) Outside vibration transmitted to machine: Check and make sure that machine is level and sitting solidly on foundation. Isolate machine or foundation. 11) Interference: Check all guards for clearance. 12) Wheel base: Check spindle bearing clearance. Use belts of equal lengths or uniform cross-section on motor drive. Check drive motor for unbalance. Check balance and fit of pulleys. Check wheel feed mechanism to see that all parts are tight. 13) Headstock: Put belts of same length and cross-section on motor drive; check for correct work speeds. Check drive motor for unbalance. Make certain that headstock spindle is not loose. Check work center fit in spindle. Check wear of face plate and jackshaft bearings. Spirals on Work (traverse lines with same lead on work as rate of traverse): Sources of spirals include: 1) machine parts out of line; and 2) truing. Suggested procedures for correction of these troubles are: 1) Machine parts out of line: Check wheel base, headstock, and footstock for proper alignment. 2) Truing: Point truing tool down 3 degrees at the workwheel contact line. Round off wheel edges. Check Marks on Work: Sources of check marks include: 1 ) i m p r o p e r o p e r a t i o n ; 2) improper heat treatment; 3) improper size control; 4) improper wheel; a n d 5) improper dressing. Suggested procedures for correction of these troubles are: 1) Improper operation: Make wheel act softer. See Wheel Defects. Do not force wheel into work. Use greater volume of coolant and a more even flow. Check the correct positioning of coolant nozzles to direct a copious flow of clean coolant at the proper location. 2) Improper heat treatment: Take corrective measures in heat-treating operations. 3) Improper size control: Make sure that engineering establishes reasonable size limits. See that they are maintained. 4) Improper wheel: Make wheel act softer. Use softer-grade wheel. Review the grain size and type of abrasive. A finer grit or more friable abrasive or both may be called for. 5) Improper dressing: Check that the diamond is sharp, of good quality, and well set. Increase speed of the dressing cycle. Make sure diamond is not cracked. Burning and Discoloration of Work: Sources of burning and discoloration are:improper operationand improper wheel. Suggested procedures for correction of these troubles are: 1) Improper operation: Decrease rate of infeed. Don’t stop work while in contact with wheel. 2) Improper wheel: Use softer wheel or obtain softer effect. See Wheel Defects. Use greater volume of coolant.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1218
CYLINDRICAL GRINDING
Isolated Deep Marks on Work: Source of trouble is an unsuitable wheel. Use a finer wheel and consider a change in abrasive type. Fine Spiral or Thread on Work: Sources of this trouble are: 1) improper operation; a n d 2) faulty wheel dressing. Suggested procedures for corrections of these troubles are: 1) Improper operation: Reduce wheel pressure. Use more work rests. Reduce traverse with respect to work rotation. Use different traverse rates to break up pattern when making numerous passes. Prevent edge of wheel from penetrating by dressing wheel face parallel to work. 2) Faulty wheel dressing: Use slower or more even dressing traverse. Set dressing tool at least 3 degrees down and 30 degrees to the side from time to time. Tighten holder. Don’t take too deep a cut. Round off wheel edges. Start dressing cut from wheel edge. Narrow and Deep Regular Marks on Work: Source of trouble is that the wheel is too coarse. Use finer grain size. Wide, Irregular Marks of Varying Depth on Work: Source of trouble is too soft a wheel. Use a harder grade wheel. See Wheel Defects. Widely Spaced Spots on Work: Sources of trouble are oil spots or glazed areas on wheel face. Balance and true wheel. Keep oil from wheel face. Irregular “Fish-tail” Marks of Various Lengths and Widths on Work: Source of trouble is dirty coolant. Clean tank frequently. Use filter for fine finish grinding. Flush wheel guards after dressing or when changing to finer wheel. Wavy Traverse Lines on Work: Source of trouble is wheel edges. Round off. Check for loose thrust on spindle and correct if necessary. Irregular Marks on Work: Cause is loose dirt. Keep machine clean. Deep, Irregular Marks on Work: Source of trouble is loose wheel flanges. Tighten and make sure blotters are used. Isolated Deep Marks on Work: Sources of trouble are: 1) grains pull out; coolant too strong; 2) coarse grains or foreign matter in wheel face; and 3) improper dressing. Respective suggested procedures for corrections of these troubles are: 1) decrease soda content in coolant mixture; 2) dress wheel; and 3) use sharper dressing tool. Brush wheel after dressing with stiff bristle brush. Grain Marks on Work: Sources of trouble are: 1) improper finishing cut; 2) grain sizes of roughing and finishing wheels differ too much; 3) dressing too coarse; and 4) wh eel too coarse or too soft. Respective suggested procedures for corrections of these troubles are: start with high work and traverse speeds; finish with high work speed and slow traverse, letting wheel “spark-out” completely; finish out better with roughing wheel or use finer roughing wheel; use shallower and slower cut; and use finer grain size or harder-grade wheel. Inaccuracies in Work: Work out-of-round, out-of-parallel, or tapered. Sources of trouble are: 1) misalignment of machine parts; 2) work centers; 3) improper operation; 4) coolant; 5) wheel; 6) improper dressing; 7) spindle bearings; and 8) work. Suggested procedures for corrections of these troubles are: 1) Misalignment of machine parts: Check headstock and tailstock for alignment and proper clamping. 2) Work centers: Centers in work must be deep enough to clear center point. Keep work centers clean and lubricated. Check play of footstock spindle and see that footstock spindle is clean and tightly seated. Regrind work centers if worn. Work centers must fit taper of work-center holes. Footstock must be checked for proper tension. 3) Improper operation: Don’t let wheel traverse beyond end of work. Decrease wheel pressure so work won’t spring. Use harder wheel or change feeds and speeds to make
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Machinery's Handbook 27th Edition CYLINDRICAL GRINDING
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wheel act harder. Allow work to “spark-out.” Decrease feed rate. Use proper number of work rests. Allow proper amount of tarry. Workpiece must be balanced if it is an odd shape. 4) Coolant: Use greater volume of coolant. 5) Wheel: Rebalance wheel on mounting before and after truing. 6) Improper dressing: Use same positions and machine conditions for dressing as in grinding. 7) Spindle bearings: Check clearance. 8) Work: Work must come to machine in reasonably accurate form. Inaccurate Work Sizing (when wheel is fed to same position, it grinds one piece to correct size, another oversize, and still another undersize): Sources of trouble are: 1) improper work support or rotation; 2) wheel out of balance; 3) loaded wheel; 4) improper infeed; 5) improper traverse; 6) coolant; 7) misalignment; and 8) work. Suggested procedures for corrections of these troubles are: 1) Improper work support or rotation: Keep work centers clean and lubricated. Regrind work-center tips to proper angle. Be sure footstock spindle is tight. Use sufficient work rests, properly spaced. 2) Wheel out of balance: Balance wheel on mounting before and after truing. 3) Loaded wheel: See Wheel Defects. 4) Improper infeed: Check forward stops of rapid feed and slow feed. When readjusting position of wheel base by means of the fine feed, move the wheel base back after making the adjustment and then bring it forward again to take up backlash and relieve strain in feed-up parts. Check wheel spindle bearings. Don’t let excessive lubrication of wheel base slide cause “floating.” Check and tighten wheel feed mechanism. Check parts for wear. Check pressure in hydraulic system. Set infeed cushion properly. Check to see that pistons are not sticking. 5) Improper traverse: Check traverse hydraulic system and the operating pressure. Prevent excessive lubrication of carriage ways with resultant “floating” condition. Check to see if carriage traverse piston rods are binding. Carriage rack and driving gear must not bind. Change length of tarry period. 6) Coolant: Use greater volume of clean coolant. 7) Misalignment: Check level and alignment of machine. 8) Work: Workpieces may vary too much in length, permitting uneven center pressure. Uneven Traverse or Infeed of Wheel Head: Sources of uneven traverse or infeed of wheel head are: carriage and wheel head, hydraulic system, interference, unbalanced conditions, and wheel out of balance. Suggested procedures for correction of these troubles are: 1) Carriage and wheel head: Ways may be scored. Be sure to use recommended oil for both lubrication and hydraulic system. Make sure ways are not so smooth that they press out oil film. Check lubrication of ways. Check wheel feed mechanism, traverse gear, and carriage rack clearance. Prevent binding of carriage traverse cylinder rods. 2) Hydraulic systems: Remove air and check pressure of hydraulic oil. Check pistons and valves for oil leakage and for gumminess caused by incorrect oil. Check worn valves or pistons that permit leakage. 3) Interference: Make sure guard strips do not interfere. 4) Unbalanced conditions: Eliminate loose pulleys, unbalanced wheel drive motor, uneven belts, or high spindle keys. 5) Wheel out of balance: Balance wheel on mounting before and after truing. Wheel Defects: When wheel is acting too hard, such defects as glazing, some loading, lack of cut, chatter, and burning of work result.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1220
CYLINDRICAL GRINDING
Suggested procedures for correction of these faults are: 1) Increase work and traverse speeds as well as rate of in-feed; 2) decrease wheel speed, diameter, or width; 3 ) d r e s s more sharply; 4) use thinner coolant; 5) don’t tarry at end of traverse; 6) select softer wheel grade and coarser grain size; 7) avoid gummy coolant; and 8) on hardened work select finer grit, more fragile abrasive or both to get penetration. Use softer grade. When wheel is acting too soft, such defects as wheel marks, tapered work, short wheel life, and not-holding-cut result. Suggested procedures for correction of these faults are: 1) Decrease work and traverse speeds as well as rate of in-feed; 2) increase wheel speed, diameter, or width; 3 ) d r e s s with little in-feed and slow traverse; 4) use heavier coolants; 5) don’t let wheel run off work at end of traverse; and 6) select harder wheel or less fragile grain or both. Wheel Loading and Glazing: Sources of the trouble of wheel loading or glazing are: 1) Incorrect wheel; 2) improper dress; 3) faulty operation; 4) faulty coolant; a n d 5) gummy coolant. Suggested procedures for correction of these faults are: 1) Incorrect wheel: Use coarser grain size, more open bond, or softer grade. 2) Improper dressing: Keep wheel sharp with sharp dresser, clean wheel after dressing, use faster dressing traverse, and deeper dressing cut. 3) Faulty operation: Control speeds and feeds to soften action of wheel. Use less in-feed to prevent loading; more in-feed to stop glazing. 4) Faulty coolant: Use more, cleaner and thinner coolant, and less oily coolant. 5) Gummy coolant: To stop wheel glazing, increase soda content and avoid the use of soluble oils if water is hard. In using soluble oil coolant with hard water a suitable conditioner or “softener” should be added. Wheel Breakage: Suggested procedures for the correction of a radial break with three or more pieces are: 1) Reduce wheel speed to or below rated speed; 2) mount wheel properly, use blotters, tight arbors, even flange pressure and be sure to keep out dirt between flange and wheel; 3) use plenty of coolant to prevent over-heating; 4) use less in-feed; and 5) don’t allow wheel to become jammed on work. A radial break with two pieces may be caused by excessive side strain. To prevent an irregular wheel break, don’t let wheel become jammed on work; don’t allow striking of wheel; and never use wheels that have been damaged in handling. In general, do not use a wheel that is too tight on the arbor since the wheel is apt to break when started. Prevent excessive hammering action of wheel. Follow rules of the American National Standard Safety Requirements for the Use, Care, and Protection of Abrasive Wheels (ANSI B7.11988). Centerless Grinding In centerless grinding the work is supported on a work rest blade and is between the grinding wheel and a regulating wheel. The regulating wheel generally is a rubber bonded abrasive wheel. In the normal grinding position the grinding wheel forces the work downward against the work rest blade and also against the regulating wheel. The latter imparts a uniform rotation to the work giving it its same peripheral speed which is adjustable. The higher the work center is placed above the line joining the centers of the grinding and regulating wheels the quicker the rounding action. Rounding action is also increased by a high work speed and a slow rate of traverse (if a through-feed operation). It is possible to have a higher work center when using softer wheels, as their use gives decreased contact pressures and the tendency of the workpiece to lift off the work rest blade is lessened. Long rods or bars are sometimes ground with their centers below the line-of-centers of the wheels to eliminate the whipping and chattering due to slight bends or kinks in the rods or bars, as they are held more firmly down on the blade by the wheels.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CENTERLESS GRINDING
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There are three general methods of centerless grinding which may be described as through-feed, in-feed, and end-feed methods. Through-feed Method of Grinding.—The through-feed method is applied to straight cylindrical parts. The work is given an axial movement by the regulating wheel and passes between the grinding and regulating wheels from one side to the other. The rate of feed depends upon the diameter and speed of the regulating wheel and its inclination which is adjustable. It may be necessary to pass the work between the wheels more than once, the number of passes depending upon such factors as the amount of stock to be removed, the roundness and straightness of the unground work, and the limits of accuracy required. The work rest fixture also contains adjustable guides on either side of the wheels that directs the work to and from the wheels in a straight line. In-feed Method of Centerless Grinding.—When parts have shoulders, heads or some part larger than the ground diameter, the in-feed method usually is employed. This method is similar to “plungecut” form grinding on a center type of grinder. The length or sections to be ground in any one operation are limited by the width of the wheel. As there is no axial feeding movement, the regulating wheel is set with its axis approximately parallel to that of the grinding wheel, there being a slight inclination to keep the work tight against the end stop. End-feed Method of Grinding.—The end-feed method is applied only to taper work. The grinding wheel, regulating wheel, and the work rest blade are set in a fixed relation to each other and the work is fed in from the front mechanically or manually to a fixed end stop. Either the grinding or regulating wheel, or both, are dressed to the proper taper. Automatic Centerless Grinding.—The grinding of relatively small parts may be done automatically by equipping the machine with a magazine, gravity chute, or hopper feed, provided the shape of the part will permit using these feed mechanisms. Internal Centerless Grinding.—Internal grinding machines based upon the centerless principle utilize the outside diameter of the work as a guide for grinding the bore which is concentric with the outer surface. In addition to straight and tapered bores, interrupted and “blind” holes can be ground by the centerless method. When two or more grinding operations such as roughing and finishing must be performed on the same part, the work can be rechucked in the same location as often as required. Centerless Grinding Troubles.—A number of troubles and some corrective measures compiled by a manufacturer are listed here for the through-feed and in-feed methods of centerless grinding. Chattermarks are caused by having the work center too high above the line joining the centers of the grinding and regulating wheels; using too hard or too fine a grinding wheel; using too steep an angle on the work support blade; using too thin a work support blade; “play” in the set-up due to loosely clamped members; having the grinding wheel fit loosely on the spindle; having vibration either transmitted to the machine or caused by a defective drive in the machine; having the grinding wheel out-of-balance; using too heavy a stock removal; and having the grinding wheel or the regulating wheel spindles not properly adjusted. Feed lines or spiral marks in through-feed grinding are caused by too sharp a corner on the exit side of the grinding wheel which may be alleviated by dressing the grinding wheel to a slight taper about 1⁄2 inch from the edge, dressing the edge to a slight radius, or swiveling the regulating wheel a bit. Scored work is caused by burrs, abrasive grains, or removed material being imbedded in or fused to the work support blade. This condition may be alleviated by using a coolant with increased lubricating properties and if this does not help a softer grade wheel should be used.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1222
SURFACE GRINDING
Work not ground round may be due to the work center not being high enough above the line joining the centers of the grinding and regulating wheels. Placing the work center higher and using a softer grade wheel should help to alleviate this condition. Work not ground straight in through-feed grinding may be due to an incorrect setting of the guides used in introducing and removing the work from the wheels, and the existence of convex or concave faces on the regulating wheel. For example, if the work is tapered on the front end, the work guide on the entering side is deflected toward the regulating wheel. If tapered on the back end, then the work guide on the exit side is deflected toward the regulating wheel. If both ends are tapered, then both work guides are deflected toward the regulating wheel. The same barrel-shaped pieces are also obtained if the face of the regulating wheel is convex at the line of contact with the work. Conversely, the work would be ground with hollow shapes if the work guides were deflected toward the grinding wheel or if the face of the regulating wheel were concave at the line of contact with the work. The use of a warped work rest blade may also result in the work not being ground straight and the blade should be removed and checked with a straight edge. In in-feed grinding, in order to keep the wheel faces straight which will insure straightness of the cylindrical pieces being ground, the first item to be checked is the straightness and the angle of inclination of the work rest blade. If this is satisfactory then one of three corrective measures may be taken: the first might be to swivel the regulating wheel to compensate for the taper, the second might be to true the grinding wheel to that angle that will give a perfectly straight workpiece, and the third might be to change the inclination of the regulating wheel (this is true only for correcting very slight tapers up to 0.0005 inch). Difficulties in sizing the work in in-feed grinding are generally due to a worn in-feed mechanism and may be overcome by adjusting the in-feed nut. Flat spots on the workpiece in in-feed grinding usually occur when grinding heavy work and generally when the stock removal is light. This condition is due to insufficient driving power between the work and the regulating wheel which may be alleviated by equipping the work rest with a roller that exerts a force against the workpiece; and by feeding the workpiece to the end stop using the upper slide. Surface Grinding The term surface grinding implies, in current technical usage, the grinding of surfaces which are essentially flat. Several methods of surface grinding, however, are adapted and used to produce surfaces characterized by parallel straight line elements in one direction, while normal to that direction the contour of the surface may consist of several straight line sections at different angles to each other (e.g., the guideways of a lathe bed); in other cases the contour may be curved or profiled (e.g., a thread cutting chaser). Advantages of Surface Grinding.—Alternate methods for machining work surfaces similar to those produced by surface grinding are milling and, to a much more limited degree, planing. Surface grinding, however, has several advantages over alternate methods that are carried out with metal-cutting tools. Examples of such potential advantages are as follows: 1) Grinding is applicable to very hard and/or abrasive work materials, without significant effect on the efficiency of the stock removal. 2) The desired form and dimensional accuracy of the work surface can be obtained to a much higher degree and in a more consistent manner. 3) Surface textures of very high finish and—when the appropriate system is utilized— with the required lay, are generally produced. 4) Tooling for surface grinding as a rule is substantially less expensive, particularly for producing profiled surfaces, the shapes of which may be dressed into the wheel, often with simple devices, in processes that are much more economical than the making and the maintenance of form cutters.
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Machinery's Handbook 27th Edition SURFACE GRINDING
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5) Fixturing for work holding is generally very simple in surface grinding, particularly when magnetic chucks are applicable, although the mechanical holding fixture can also be simpler, because of the smaller clamping force required than in milling or planing. 6) Parallel surfaces on opposite sides of the work are produced accurately, either in consecutive operations using the first ground surface as a dependable reference plane or, simultaneously, in double face grinding, which usually operates without the need for holding the parts by clamping. 7) Surface grinding is well adapted to process automation, particularly for size control, but also for mechanized work handling in the large volume production of a wide range of component parts. Principal Systems of Surface Grinding.—Flat surfaces can be ground with different surface portions of the wheel, by different arrangements of the work and wheel, as well as by different interrelated movements. The various systems of surface grinding, with their respective capabilities, can best be reviewed by considering two major distinguishing characteristics: 1) The operating surface of the grinding wheel, which may be the periphery or the face (the side); 2) The movement of the work during the process, which may be traverse (generally reciprocating) or rotary (continuous), depending on the design of a particular category of surface grinders. The accompanying Table 1and the text that follows provides a concise review of the principal surface grinding systems, defined by the preceding characteristics. It should be noted that many surface grinders are built for specific applications, and do not fit exactly into any one of these major categories. Operating Surface, Periphery of Wheel: Movement of Work, Reciprocating: W o r k i s mounted on the horizontal machine table that is traversed in a reciprocating movement at a speed generally selected from a steplessly variable range. The transverse movement, called cross feed of the table or of the wheel slide, operates at the end of the reciprocating stroke and assures the gradual exposure of the entire work surface, which commonly exceeds the width of the wheel. The depth of the cut is controlled by the downfeed of the wheel, applied in increments at the reversal of the transverse movement. Operating Surface, Periphery of Wheel: Movement of Work, Rotary: Work is mounted, usually on the full-diameter magnetic chuck of the circular machine table that rotates at a preset constant or automatically varying speed, the latter maintaining an approximately equal peripheral speed of the work surface area being ground. The wheelhead, installed on a cross slide, traverses over the table along a radial path, moving in alternating directions, toward and away from the center of the table. Infeed is by vertical movement of the saddle along the guideways of the vertical column, at the end of the radial wheelhead stroke. The saddle contains the guideways along which the wheelhead slide reciprocates. Operating Surface, Face of Wheel: Movement of Work,Reciprocating: O p e r a t i o n i s similar to the reciprocating table-type peripheral surface grinder, but grinding is with the face, usually with the rim of a cup-shaped wheel, or a segmental wheel for large machines. Capable of covering a much wider area of the work surface than the peripheral grinder, thus frequently no need for cross feed. Provides efficient stock removal, but is less adaptable than the reciprocating table-type peripheral grinder. Operating Surface, Face of Wheel: Movement of Work, Rotary: The grinding wheel, usually of segmental type, is set in a position to cover either an annular area near the periphery of the table or, more commonly, to reach beyond the table center. A large circular magnetic chuck generally covers the entire table surface and facilitates the mounting of workpieces, even of fixtures, when needed. The uninterrupted passage of the work in contact with the large wheel face permits a very high rate of stock removal and the machine,
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1224
SURFACE GRINDING Table 1. Principal Systems of Surface Grinding — Diagrams
Reciprocating — Periphery of Wheel
Rotary — Periphery of Wheel
Reciprocating — Face (Side) of Wheel
Traverse Along Straight Line or Arcuate Path — Face (Side) of Wheel
Rotary — Face (Side) of Wheel
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Machinery's Handbook 27th Edition SURFACE GRINDING
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with single or double wheelhead, can be adapted also to automatic operation with continuous part feed by mechanized work handling. Operating Surface, Face of Wheel: Movement of Work, Traverse Along Straight or Arcuate Path: The grinding wheel, usually of segmental type, is set in a position to cover either an annular area near the periphery of the table or, more commonly, to reach beyond the table center. A large circular magnetic chuck generally covers the entire table surface and facilitates the mounting of workpieces, even of fixtures, when needed. The uninterrupted passage of the work in contact with the large wheel face permits a very high rate of stock removal and the machine, with single or double wheelhead, can be adapted also to automatic operation with continuous part feed by mechanized work handling. Selection of Grinding Wheels for Surface Grinding.—The most practical way to select a grinding wheel for surface grinding is to base the selection on the work material. Table 2a gives the grinding wheel recommendations for Types 1, 5, and 7 straight wheels used on reciprocating and rotary table surface grinders with horizontal spindles. Table 2b gives the grinding wheel recommendations for Type 2 cylinder wheels, Type 6 cup wheels, and wheel segments used on vertical spindle surface grinders. The last letters (two or three) that may follow the bond designation V (vitrified) or B (resinoid) refer to: 1) bond modification, “BE” being especially suitable for surface grinding; 2) special structure, “P” type being distinctively porous; and 3) for segments made of 23A type abrasives, the term 12VSM implies porous structure, and the letter “P” is not needed. The wheel markings in Tables 2a and 2b are those used by the Norton Co., complementing the basic standard markings with Norton symbols. The complementary symbols used in these tables, that is, those preceding the letter designating A (aluminum oxide) or C (silicon carbide), indicate the special type of basic abrasive that has the friability best suited for particular work materials. Those preceding A (aluminum oxide) are 57—a versatile abrasive suitable for grinding steel in either a hard or soft state. 38—the most friable abrasive. 32—the abrasive suited for tool steel grinding. 23—an abrasive with intermediate grinding action, and 19—the abrasive produced for less heat-sensitive steels. Those preceding C (silicon carbide) are 37—a general application abrasive, and 39—an abrasive for grinding hard cemented carbide. Table 2a. Grinding Wheel Recommendations for Surface Grinding— Using Straight Wheel Types 1, 5, and 7 Horizontal-spindle, reciprocating-table surface grinders Wheels less than 16 inches diameter
Material Cast iron Nonferrous metal Soft steel Hardened steel, broad contact Hardened steel, narrow contact or interrupted cut General-purpose wheel Cemented carbides
37C36-K8V or 23A46-I8VBE 37C36-K8V 23A46-J8VBE 32A46-H8VBE or 32A60-F12VBEP
Wheels 16 inches diameter and over 23A36-I8VBE 37C36-K8V 23A36-J8VBE 32A36-H8VBE or 32A36-F12VBEP
Horizontal-spindle, rotary-table surface grinders Wheels of any diameter 37C36-K8V or 23A46-I8VBE 37C36-K8V 23A46-J8VBE 32A46-I8VBE
32A46-I8VBE
32A36-J8VBE
32A46-J8VBE
23A46-H8VBE Diamond wheelsa
23A36-I8VBE Diamond wheelsa
23A46-I8VBE Diamond wheelsa
a General diamond wheel recommendations are listed in Table 5 on page 1206.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1226
SURFACE GRINDING
Table 2b. Grinding Wheel Recommendations for Surface Grinding—Using Type 2 Cylinder Wheels, Type 6 Cup Wheels, and Wheel Segments Type 2 Cylinder Wheels
Material High tensile cast iron and nonferrous metals Soft steel, malleable cast iron, steel castings, boiler plate Hardened steel—broad contact
37C24-HKV
Type 6 Cup Wheels
Wheel Segments
37C24-HVK
23A24-I8VBE or 23A30-G12VBEP 32A46-G8VBE or 32A36-E12VBEP
32A46-G8VBE or 32A60-E12VBEP
Hardened steel—narrow contact or interrupt cut
32A46-H8VBE
32A60-H8VBE
General-purpose use
23A30-H8VBE or 23A30-E12VBEP
37C24-HVK 23A24-I8VSM or 23A30-H12VSM 32A36-G8VBE or 32A46-E12VBEP 32A46-G8VBE or 32A60-G12VBEP 23A30-H8VSM or 23A30-G12VSM
23A24-I8VBE
…
Process Data for Surface Grinding.—In surface grinding, similarly to other metal-cutting processes, the speed and feed rates that are applied must be adjusted to the operational conditions as well as to the objectives of the process. Grinding differs, however, from other types of metal cutting methods in regard to the cutting speed of the tool; the peripheral speed of the grinding wheel is maintained within a narrow range, generally 5500 to 6500 surface feet per minute. Speed ranges different from the common one are used in particular processes which require special wheels and equipment. Table 3. Basic Process Data for Peripheral Surface Grinding on Reciprocating Table Surface Grinders
Work Material Plain carbon steel
Hardness
Nitriding steels
Cast steels
Gray irons Ductile irons Stainless steels, martensitic Aluminum alloys
Table Speed, fpm
Downfeed, in. per pass Finish, Rough max.
Crossfeed per pass, fraction of wheel width
Annealed, cold drawn
5500–6500 50–100
0.003
0.0005
1⁄ 4
52–65 Rc
Carburized and/or quenched and tempered
5500–6500 50–100
0.003
0.0005
1⁄ 10
52 Rc max.
Annealed or quenched and tempered
5500–6500 50–100
0.003
0.001
1⁄ 4
52–65 Rc
Carburized and/or quenched and tempered
5500–6500 50–100
0.003
0.0005
1⁄ 10
5500–6500 50–100
0.002
0.0005
1⁄ 5
5500–6500 50–100
0.002
0.0005
1⁄ 10
52 Rc max.
Alloy steels
Tool steels
Material Condition
Wheel Speed, fpm
150–275 Bhn Annealed 56–65 Rc
Quenched and tempered
200–350 Bhn Normalized, annealed 60–65 Rc
Nitrided
5500–6500 50–100
0.003
0.001
1⁄ 4
5500–6500 50–100
0.003
0.0005
1⁄ 10
52 Rc max.
Normalized, annealed
5500–6500 50–100
0.003
0.001
1⁄ 4
Over 52 Rc
Carburized and/or quenched and tempered
5500–6500 50–100
0.003
0.0005
1⁄ 10
52 Rc max.
As cast, annealed, and/or quenched and tempered
5000–6500 50–100
0.003
0.001
1⁄ 3
52 Rc max.
As cast, annealed or quenched and tempered
5500–6500 50–100
0.003
0.001
1⁄ 5
135–235 Bhn Annealed or cold drawn
5500–6500 50–100
0.002
0.0005
1⁄ 4
Over 275 Bhn Quenched and tempered
5500–6500 50–100
0.001
0.0005
1⁄ 8
5500–6500 50–100
0.003
0.001
1⁄ 3
30–150 Bhn
As cast, cold drawn or treated
In establishing the proper process values for grinding, of prime consideration are the work material, its condition, and the type of operation (roughing or finishing). Table 3 gives basic process data for peripheral surface grinding on reciprocating table surface
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SURFACE GRINDING
1227
grinders. For different work materials and hardness ranges data are given regarding table speeds, downfeed (infeed) rates and cross feed, the latter as a function of the wheel width. Common Faults and Possible Causes in Surface Grinding.—Approaching the ideal performance with regard to both the quality of the ground surface and the efficiency of surface grinding, requires the monitoring of the process and the correction of conditions adverse to the attainment of that goal. Defective, or just not entirely satisfactory surface grinding may have any one or more of several causes. Exploring and determining the cause for eliminating its harmful effects is facilitated by knowing the possible sources of the experienced undesirable performance. Table 4, associating the common faults with their possible causes, is intended to aid in determining the actual cause, the correction of which should restore the desired performance level. While the table lists the more common faults in surface grinding, and points out their frequent causes, other types of improper performance and/or other causes, in addition to those indicated, are not excluded. Vitrified Grinding Wheels.—The term “vitrified” denotes the type of bond used in these grinding wheels. The bond in a grinding wheel is the material which holds the abrasive grains together and supports them while they cut. With a given type of bond, it is the amount of bond that determines the “hardness” or softness” of wheels. The abrasive itself is extremely hard in all wheels, and the terms “hard” and “soft” refer to the strength of bonding; the greater the percentage of bond with respect to the abrasive, the heavier the coating of bond around the abrasive grains and the stronger the bond posts, the “harder” the wheel. Most wheels are made with a vitrified bond composed of clays and feldspar selected for their fusibility. During the “burning” process in grinding wheel manufacture, the clays are fused into a molten glass condition. Upon cooling, a span or post of this glass connects each abrasive grain to its neighbors to make a rigid, strong, grinding wheel. These wheels are porous, free cutting and unaffected by water, acids, oils, heat, or cold. Vitrified wheels are extensively used for cylindrical grinding, surface grinding, internal grinding and cutter grinding. Silicate Bonding Process.—Silicate grinding wheels derive their name from the fact that silicate of soda or water glass is the principal ingredient used in the bond. These wheels are also sometimes referred to as semi-vitrified wheels. Ordinarily, they cut smoothly and with comparatively little heat, and for grinding operations requiring the lowest wheel wear, compatible with cool cutting, silicate wheels are often used. Their grade is also dependable and much larger wheels can be made by this bonding process than by the vitrified process. Some of the grinding operations for which silicate wheels have been found to be especially adapted are as follows: for grinding high-speed steel machine shop tools, such as reamers, milling cutters, etc.; for hand-grinding lathe and planer tools; for surface grinding with machines of the vertical ring-wheel type; and for operations requiring dish-shaped wheels and cool cutting. These wheels are unequaled for wet grinding on hardened steel and for wet tool grinding. They are easily recognized by their light gray color. Oilstones.—The natural oilstones commonly used are the Washita and Arkansas. The Washita is a coarser and more rapidly cutting stone, and is generally considered the most satisfactory for sharpening woodworkers’ tools. There are various grades of Washita rock, varying from the perfect crystallized and porous whetstone grit, to vitreous flint and hard sandstone. The best whetstones are porous and uniform in texture and are composed entirely of silica crystals. The poorer grades are less porous, making them vitreous or “glassy.” They may also have hard spots or sand holes, or contain grains of sand among the crystals. For general work, a soft, free-grit, quick-cutting stone is required, although a finegrit medium-hard stone is sometimes preferable. These are commonly furnished in three grits: fine, medium, and coarse, and in all required shapes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Wheel loading
Wheel glazing
Rapid wheel wear
Not firmly seated
Work sliding on chuck
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Poor size holding
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Work not parallel
Poor finish
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Scratches on surface
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Abrupt section changes
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Grit too fine Grit too coarse Grade too hard Grade too soft Wheel not balanced Dense structure Improper coolant Insufficient coolant Dirty coolant Diamond loose or chipped Diamond dull No or poor magnetic force Chuck surface worn or burred
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Too low work speed Too light feed Too heavy cut Chuck retained swarf Chuck loading improper Insufficient blocking of parts Wheel runs off the work Wheel dressing too fine Wheel edge not chamfered Loose dirt under guard
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Copyright 2004, Industrial Press, Inc., New York, NY
WORK RETAINMENT
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Work not flat
TOOLING AND COOLANT MACHINE AND SETUP OPERATIONAL CONDITIONS
WHEEL CONDITION
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Heat treat stresses Work too thin Work warped
FAULTS
SURFACE QUALITY
SURFACE GRINDING
GRINDING WHEEL
WORK CONDITION
CAUSES
METALLURGICAL DEFECTS Burnishing of work
WORK DIMENSION
1228
Table 4. Common Faults and Possible Causes in Surface Grinding
Machinery's Handbook 27th Edition OFFHAND GRINDING
1229
Offhand Grinding Offhand grinding consists of holding the wheel to the work or the work to the wheel and grinding to broad tolerances and includes such operations as certain types of tool sharpening, weld grinding, snagging castings and other rough grinding. Types of machines that are used for rough grinding in foundries are floor- and bench-stand machines. Wheels for these machines vary from 6 to 30 inches in diameter. Portable grinding machines (electric, flexible shaft, or air-driven) are used for cleaning and smoothing castings. Many rough grinding operations on castings can be best done with shaped wheels, such as cup wheels (including plate mounted) or cone wheels, and it is advisable to have a good assortment of such wheels on hand to do the odd jobs the best way. Floor- and Bench-Stand Grinding.—The most common method of rough grinding is on double-end floor and bench stands. In machine shops, welding shops, and automotive repair shops, these grinders are usually provided with a fairly coarse grit wheel on one end for miscellaneous rough grinding and a finer grit wheel on the other end for sharpening tools. The pressure exerted is a very important factor in selecting the proper grinding wheel. If grinding is to be done mostly on hard sharp fins, then durable, coarse and hard wheels are required, but if grinding is mostly on large gate and riser pads, then finer and softer wheels should be used for best cutting action. Portable Grinding.—Portable grinding machines are usually classified as air grinders, flexible shaft grinders, and electric grinders. The electric grinders are of two types; namely, those driven by standard 60 cycle current and so-called high-cycle grinders. Portable grinders are used for grinding down and smoothing weld seams; cleaning metal before welding; grinding out imperfections, fins and parting lines in castings and smoothing castings; grinding punch press dies and patterns to proper size and shape; and grinding manganese steel castings. Wheels used on portable grinders are of three bond types; namely, resinoid, rubber, and vitrified. By far the largest percentage is resinoid. Rubber bond is used for relatively thin wheels and where a good finish is required. Some of the smaller wheels such as cone and plug wheels are vitrified bonded. Grit sizes most generally used in wheels from 4 to 8 inches in diameter are 16, 20, and 24. In the still smaller diameters, finer sizes are used, such as 30, 36, and 46. The particular grit size to use depends chiefly on the kind of grinding to be done. If the work consists of sharp fins and the machine has ample power, a coarse grain size combined with a fairly hard grade should be used. If the job is more in the nature of smoothing or surfacing and a fairly good finish is required, then finer and softer wheels are called for. Swing-Frame Grinding.—This type of grinding is employed where a considerable amount of material is to be removed as on snagging large castings. It may be possible to remove 10 times as much material from steel castings using swing-frame grinders as with portable grinders; and 3 times as much material as with high-speed floor-stand grinders. The largest field of application for swing-frame machines is on castings which are too heavy to handle on a floor stand; but often it is found that comparatively large gates and risers on smaller castings can be ground more quickly with swing-frame grinders, even if fins and parting lines have to be ground on floor stands as a second operation. In foundries, the swing-frame machines are usually suspended from a trolley on a jib that can be swung out of the way when placing the work on the floor with the help of an overhead crane. In steel mills when grinding billets, a number of swing-frame machines are usually suspended from trolleys on a line of beams which facilitate their use as required. The grinding wheels used on swing-frame machines are made with coarser grit sizes and harder grades than wheels used on floor stands for the same work. The reason is that greater grinding pressures can be obtained on the swing-frame machines.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1230
ABRASIVE CUTTING Abrasive Belt Grinding
Abrasive belts are used in the metalworking industry for removing stock, light cleaning up of metal surfaces, grinding welds, deburring, breaking and polishing hole edges, and finish grinding of sheet steel. The types of belts that are used may be coated with aluminum oxide (the most common coating) for stock removal and finishing of all alloy steels, highcarbon steel, and tough bronzes; and silicon carbide for use on hard, brittle, and low-tensile strength metals which would include aluminum and cast irons. Table 1 is a guide to the selection of the proper abrasive belt, lubricant, and contact wheel. This table is entered on the basis of the material used and type of operation to be done and gives the abrasive belt specifications (type of bonding andabrasive grain size and material), the range of speeds at which the belt may best be operated, the type of lubricant to use, and the type and hardness of the contact wheel to use. Table 2 serves as a guide in the selection of contact wheels. This table is entered on the basis of the type of contact wheel surface and the contact wheel material. The table gives the hardness and/or density, the type of abrasive belt grinding for which the contact wheel is intended, the character of the wheel action and such comments as the uses, and hints for best use. Both tables are intended only as guides for general shop practice; selections may be altered to suit individual requirements. There are three types of abrasive belt grinding machines. One type employs a contact wheel behind the belt at the point of contact of the workpiece to the belt and facilitates a high rate of stock removal. Another type uses an accurate parallel ground platen over which the abrasive belt passes and facilitates the finishing of precision parts. A third type which has no platens or contact wheel is used for finishing parts having uneven surfaces or contours. In this type there is no support behind the belt at the point of contact of the belt with the workpiece. Some machines are so constructed that besides grinding against a platen or a contact wheel the workpiece may be moved and ground against an unsupported portion of the belt, thereby in effect making it a dual machine. Although abrasive belts at the time of their introduction were used dry, since the advent of the improved waterproof abrasive belts, they have been used with coolants, oil-mists, and greases to aid the cutting action. The application of a coolant to the area of contact retards loading, resulting in a cool, free cutting action, a good finish and a long belt life. Abrasive Cutting Abrasive cut-off wheels are used for cutting steel, brass and aluminum bars and tubes of all shapes and hardnesses, ceramics, plastics, insulating materials, glass and cemented carbides. Originally a tool or stock room procedure, this method has developed into a highspeed production operation. While the abrasive cut-off machine and cut-off wheel can be said to have revolutionized the practice of cutting-off materials, the metal saw continues to be the more economical method for cutting-off large cross-sections of certain materials. However, there are innumerable materials and shapes that can be cut with much greater speed and economy by the abrasive wheel method. On conventional chop-stroke abrasive cutting machines using 16-inch diameter wheels, 2-inch diameter bar stock is the maximum size that can be cut with satisfactory wheel efficiency, but bar stock up to 6 inches in diameter can be cut efficiently on oscillating-stroke machines. Tubing up to 31⁄2 inches in diameter can also be cut efficiently. Abrasive wheels are commonly available in four types of bonds: Resinoid, rubber, shellac and fiber or fabric reinforced. In general, resinoid bonded cut-off wheels are used for dry cutting where burrs and some burn are not objectionable and rubber bonded wheels are used for wet cutting where cuts are to be smooth, clean and free from burrs. Shellac bonded wheels have a soft, free cutting quality which makes them particularly useful in the tool room where tool steels are to be cut without discoloration. Fiber reinforced bonded wheels are able to withstand severe flexing and side pressures and fabric reinforced bonded
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 1. Guide to the Selection and Application of Abrasive Belts
Material Hot-and Cold-Rolled Steel
Belt Speed, fpm
Roughing
R/R Al2O3
24–60
4000–65000
Light-body or none
Cog-tooth, serrated rubber
70–90
Polishing
R/G or R/R Al2O3
80–150
4500–7000
Light-body or none
Plain or serrated rubber, sectional or finger-type cloth wheel, free belt
20–60
R/G or electro-coated Al2O3 cloth
180–500
4500–7000
Heavy or with abrasive compound
Smooth-faced rubber or cloth
20–40
Fine Polishing Stainless Steel
Titanium
Durometer Hardness
50–80
3500–5000
Light-body or none
Cog-tooth, serrated rubber
70–90
Polishing
R/G or R/R Al2O3
80–120
4000–5500
Light-body or none
Plain or serrated rubber, sectional or finger-type cloth wheel, free belt
30–60
Closed-coat SiC
150–280
4500–5500
Heavy or oil mist
Smooth-faced rubber or cloth
20–40
Roughing
R/R SiC or Al2O3
24–80
5000–6500
Light
Cog-tooth, serrated rubber
70–90
Polishing
R/G SiC or Al2O3
100–180
4500–6500
Light
Plain or serrated rubber, sectional or finger-type cloth wheel, free belt
30–50
Closed-coat SiC or electro-coated Al2O3
220–320
4500–6500
Heavy or with abrasive compound
Plain faced rubber, finger-type cloth or free belt
20–50
36–80
2200–4500
Light-body
Cog-tooth, serrated rubber
70–90
Roughing
R/R SiC or Al2O3
Polishing
Closed-coat SiC or electro-coated Al2O3 or R/G SiC or Al2O3
100–150
4000–6500
Light-body
Plain or serrated rubber, sectional or finger-type cloth wheel, free belt
30–50
Fine Polishing
Closed-coat SiC or electro-coated Al2O3
180–320
4000–6500
Light or with abrasive compound
Same as for polishing
20–30
Roughing
R/R SiC or Al2O3
24–80
4500–6500
Light-body
Hard wheel depending on application
50–70
Polishing
R/G SiC or Al2O3
100–180
4500–6500
Light-body
Plain rubber, cloth or free belt
30–50
Electro-coated Al2O3 or closed-coat SiC
220–320
4500–6500
Heavy or with abrasive compound
Plain or finger-type cloth wheel, or free belt
20–30
Fine Polishing Cast Iron
Type
Roughing
R/R Al2O3
24–60
2000–4000
None
Cog-tooth, serrated rubber
70–90
Polishing
R/R Al2O3
80–150
4000–5500
None
Serrated rubber
30–70
Fine Polishing
R/R Al2O3
120–240
4000–5500
Light-body
Smooth-faced rubber
30–40 70–80
Roughing
R/R SiC or Al2O3
36–50
700–1500
Sulfur-chlorinated
Small-diameter, cog-tooth serrated rubber
Polishing
R/R SiC
60–120
1200–2000
Light-body
Standard serrated rubber
Fine Polishing
R/R SiC
120–240
1200–2000
Light-body
Smooth-faced rubber or cloth
50 20–40
1231
a R/R indicates that both the making and sizing bond coats are resin. R/G indicates that the making coat is glue and the sizing coat is resin. The abbreviations Al O for 2 3 aluminum oxide and SiC for silicon carbide are used. Almost all R/R and R/G Al2O3 and SiC belts have a heavy-drill weight cloth backing. Most electro-coated Al2O3 and closed-coat SiC belts have a jeans weight cloth backing.
Copyright 2004, Industrial Press, Inc., New York, NY
ABRASIVE CUTTING
Non-ferrous Die-castings
Type of Grease Lubricant
R/R Al2O3
Fine Polishing Copper Alloys or Brass
Abrasive Belta
Roughing
Fine Polishing Aluminum, Cast or Fabricated
Contact Wheel
Grit
Type of Operation
Machinery's Handbook 27th Edition 1232
ABRASIVE CUTTING Table 2. Guide to the Selection and Application of Contact Wheels Hardness and Density
Surface
Material
Cog-tooth
Rubber
Standard serrated
Rubber
X-shaped serrations
Rubber
20 to 50 durometer
Plain face
Rubber
20 to 70 durometer
Flat flexible
Compressed canvas
About nine densities from very hard to very soft
Flat flexible
Solid sectional canvas
Soft, medium, and hard
Flat flexible
Buff section canvas
Soft
Contour polishing
Flat flexible
Sponge rubber inserts
5 to 10 durometer, soft
Polishing
Flexible
Fingers of canvas attached to hub
Soft
Polishing
Flat flexible
Rubber segments
Varies in hardness
Flat flexible
Inflated rubber
Air pressure controls hardness
70 to 90 durometer 40 to 50 durometer, medium density
Purposes
Wheel Action
Comments
Roughing
Fast cutting, allows long belt life.
For cutting down projections on castings and weld beads.
Roughing
Leaves rough- to mediumground surface.
For smoothing projections and face defects.
Flexibility of rubber allows entry into contours. Medium polishing, light removal. Plain wheel face allows conRoughing trolled penetration of abraand sive grain. Softer wheels polishing give better finishes. Hard wheels can remove Roughing metal, but not as quickly as and cog-tooth rubber wheels. polishing Softer wheels polish well. Uniform polishing. Avoids abrasive pattern on work. Polishing Adjusts to contours. Can be performed for contours. Roughing and polishing
Same as for standard serrated wheels but preferred for soft non-ferrous metals.
For large or small flat faces.
Good for medium-range grinding and polishing.
A low-cost wheel with uniform density at the face. Handles all types of polishing. Can be widened or narrowed For fine polishing and finishby adding or removing secing. tions. Low cost. Has replaceable segments. Uniform polishing and finPolishes and blends conishing. Polishes and blends tours. Segments allow dencontours. sity changes. Uniform polishing and finishing.
For polishing and finishing.
Roughing Grinds or polishes depending on density and hardness and of inserts. polishing
For portable machines. Uses replaceable segments that save on wheel costs and allow density changes.
Roughing and Uniform finishing. polishing
Adjusts to contours.
wheels which are highly resistant to breakage caused by extreme side pressures, are fast cutting and have a low rate of wear. The types of abrasives available in cut-off wheels are: Aluminum oxide, for cutting steel and most other metals; silicon carbide, for cutting non-metallic materials such as carbon, tile, slate, ceramics, etc.; and diamond, for cutting cemented carbides. The method of denoting abrasive type, grain size, grade, structure and bond type by using a system of markings is the same as for grinding wheels (see page 1179). Maximum wheel speeds given in the American National Standard “Safety Requirements for The Use, Care, and Protection of Abrasive Wheels” (ANSI B7.1-1988) range from 9500 to 14,200 surface feet per minute for organic bonded cut-off wheels larger than 16 inches in diameter and from 9500 to 16,000 surface feet per minute for organic bonded cut-off wheels 16 inches in diameter and smaller. Maximum wheel speeds specified by the manufacturer should never be exceeded even though they may be lower than those given in the B7.1 Standard. There are four basic types of abrasive cutting machines: Chop-stroke, oscillating stroke, horizontal stroke and work rotating. Each of these four types may be designed for dry cutting or for wet cutting (includes submerged cutting).
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition HONING PROCESS
1233
The accompanying table based upon information made available by The Carborundum Co. gives some of the probable causes of cutting off difficulties that might be experienced when using abrasive cut-off wheels. Probable Causes of Cutting-Off Difficulties Difficulty Angular Cuts and Wheel Breakage Burning of Stock
Excessive Wheel Wear
Excessive Burring
Probable Cause (1) Inadequate clamping which allows movement of work while the wheel is in the cut. The work should be clamped on both sides of the cut. (2) Work vise higher on one side than the other causing wheel to be pinched. (3) Wheel vibration resulting from worn spindle bearings. (4) Too fast feeding into the cut when cutting wet. (1) Insufficient power or drive allowing wheel to stall. (2) Cuts too heavy for grade of wheel being used. (3) Wheel fed through the work too slowly. This causes a heating up of the material being cut. This difficulty encountered chiefly in dry cutting. (1) Too rapid cutting when cutting wet. (2) Grade of wheel too hard for work, resulting in excessive heating and burning out of bond. (3) Inadequate coolant supply in wet cutting. (4) Grade of wheel too soft for work. (5) Worn spindle bearings allowing wheel vibration. (1) Feeding too slowly when cutting dry. (2) Grit size in wheel too coarse. (3) Grade of wheel too hard. (4) Wheel too thick for job.
Honing Process The hone-abrading process for obtaining cylindrical forms with precise dimensions and surfaces can be applied to internal cylindrical surfaces with a wide range of diameters such as engine cylinders, bearing bores, pin holes, etc. and also to some external cylindrical surfaces. The process is used to: 1) eliminate inaccuracies resulting from previous operations by generating a true cylindrical form with respect to roundness and straightness within minimum dimensional limits; 2) generate final dimensional size accuracy within low tolerances, as may be required for interchangeability of parts; 3) provide rapid and economical stock removal consistent with accomplishment of the other results; and 4) generate surface finishes of a specified degree of surface smoothness with high surface quality. Amount and Rate of Stock Removal.—Honing may be employed to increase bore diameters by as much as 0.100 inch or as little as 0.001 inch. The amount of stock removed by the honing process is entirely a question of processing economy. If other operations are performed before honing then the bulk of the stock should be taken off by the operation that can do it most economically. In large diameter bores that have been distorted in heat treating, it may be necessary to remove as much as 0.030 to 0.040 inch from the diameter to make the bore round and straight. For out-of-round or tapered bores, a good “rule of thumb” is to leave twice as much stock (on the diameter) for honing as there is error in the bore. Another general rule is: For bores over one inch in diameter, leave 0.001 to 0.0015 inch stock per inch of diameter. For example, 0.002 to 0.003 inch of stock is left in twoinch bores and 0.010 to 0.015 inch in ten-inch bores. Where parts are to be honed for finish only, the amount of metal to be left for removing tool marks may be as little as 0.0002 to 0.015 inch on the diameter. In general, the honing process can be employed to remove stock from bore diameters at the rate of 0.009 to 0.012 inch per minute on cast-iron parts and from 0.005 to 0.008 inch per minute on steel parts having a hardness of 60 to 65 Rockwell C. These rates are based on parts having a length equal to three or four times the diameter. Stock has been removed
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1234
HONING PROCESS
from long parts such as gun barrels, at the rate of 65 cubic inches per hour. Recommended honing speeds for cast iron range from 110 to 200 surface feet per minute of rotation and from 50 to 110 lineal feet per minute of reciprocation. For steel, rotating surface speeds range from 50 to 110 feet per minute and reciprocation speeds from 20 to 90 lineal feet per minute. The exact rotation and reciprocation speeds to be used depend upon the size of the work, the amount and characteristics of the material to be removed and the quality of the finish desired. In general, the harder the material to be honed, the lower the speed. Interrupted bores are usually honed at faster speeds than plain bores. Formula for Rotative Speeds.—Empirical formulas for determining rotative speeds for honing have been developed by the Micromatic Hone Corp. These formulas take into consideration the type of material being honed, its hardness and its surface characteristics; the abrasive area; and the type of surface pattern and degree of surface roughness desired. Because of the wide variations in material characteristics, abrasives available, and types of finishes specified, these formulas should be considered as a guide only in determining which of the available speeds (pulley or gear combinations) should be used for any particular application. K×D The formula for rotative speed, S, in surface feet per minute is: S = --------------W×N R The formula for rotative speed in revolutions per minute is: R.P.M = --------------W×N where, K and R are factors taken from the table on the following page, D is the diameter of the bore in inches, W is the width of the abrasive stone or stock in inches, and N is the number of stones. Although the actual speed of the abrasive is the resultant of both the rotative speed and the reciprocation speed, this latter quantity is seldom solved for or used. The reciprocation speed is not determined empirically but by testing under operating conditions. Changing the reciprocation speed affects the dressing action of the abrasive stones, therefore, the reciprocation speed is adjusted to provide for a desired surface finish which is usually a well lubricated bearing surface that will not scuff. Table of Factors for Use in Rotative Speed Formulas Hardnessb Soft Character of Surfacea Base Metal Dressing Surface Severe Dressing
Medium
Hard
Factors Material
K
R
K
R
K
R
Cast Iron Steel Cast Iron Steel Cast Iron Steel
110 80 150 110 200 150
420 300 570 420 760 570
80 60 110 80 150 110
300 230 420 300 570 420
60 50 80 60 110 80
230 190 300 230 420 300
a The character of the surface is classified according to its effect on the abrasive; Base Metal being a honed, ground or fine bored section that has little dressing action on the grit; Dressing Surface being a rough bored, reamed or broached surface or any surface broken by cross holes or ports; Severe Dressing being a surface interrupted by keyways, undercuts or burrs that dress the stones severely. If over half of the stock is to be removed after the surface is cleaned up, the speed should be computed using the Base Metal factors for K and R. b Hardness designations of soft, medium and hard cover the following ranges on the Rockwell “ C” hardness scale, respectively: 15 to 45, 45 to 60 and 60 to 70.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition LAPS AND LAPPING
1235
Possible Adjustments for Eliminating Undesirable Honing Conditions Adjustment Required to Correct Conditiona Abrasiveb Grain Size
Hardness
Structure
Feed Pressure
Reciprocation
R.P.M.
Runout Time
Stroke Length
Abrasive Glazing Abrasive Loading Too Rough Surface Finish Too Smooth Surface Finish Poor Stone Life Slow Stock Removal Taper — Large at Ends Taper — Small at Ends
Friability
Undesirable Condition
Other
+ 0 0 0 − + 0 0
−− −− ++ −− + −− 0 0
−− − ++ −− ++ − 0 0
+ − − + − + 0 0
++ ++ − + − ++ 0 0
++ + − + − ++ 0 0
−− −− ++ −− + −− 0 0
− 0 + − 0 0 0 0
0 0 0 0 0 0 − +
a The + and + + symbols generally indicate that there should be an increase or addition while the − and − − symbols indicate that there should be a reduction or elimination. In each case, the double symbol indicates that the contemplated change would have the greatest effect. The 0 symbol means that a change would have no effect. b For the abrasive adjustments the + and + + symbols indicate a more friable grain, a finer grain, a harder grade or a more open structure and the − and − − symbols just the reverse. Compiled by Micromatic Hone Corp.
Abrasive Stones for Honing.—Honing stones consist of aluminum oxide, silicon carbide, CBN or diamond abrasive grits, held together in stick form by a vitrified clay, resinoid or metal bond. CBN metal-bond stones are particularly suitable and widely used for honing. The grain and grade of abrasive to be used in any particular honing operation depend upon the quality of finish desired, the amount of stock to be removed, the material being honed and other factors. The following general rules may be followed in the application of abrasive for honing: 1) Silicon-carbide abrasive is commonly used for honing cast iron, while aluminum-oxide abrasive is generally used on steel; 2) The harder the material being honed, the softer the abrasive stick used; 3) A rapid reciprocating speed will tend to make the abrasive cut fast because the dressing action on the grits will be severe; and 4) To improve the finish, use a finer abrasive grit, incorporate more multi-direction action, allow more “run-out” time after honing to size, or increase the speed of rotation. Surface roughnesses ranging from less than 1 micro-inch r.m.s. to a relatively coarse roughness can be obtained by judicious choice of abrasive and honing time but the most common range is from 3 to 50 micro-inches r.m.s. Adjustments for Eliminating Undesirable Honing Conditions.—The accompanying table indicates adjustments that may be made to correct certain undesirable conditions encountered in honing. Only one change should be made at a time and its effect noted before making other adjustments. Tolerances.—For bore diameters above 4 inches the tolerance of honed surfaces with respect to roundness and straightness ranges from 0.0005 to 0.001 inch; for bore diameters from 1 to 4 inches, 0.0003 to 0.0005 inch; and for bore diameters below 1 inch, 0.00005 to 0.0003 inch. Laps and Lapping Material for Laps.—Laps are usually made of soft cast iron, copper, brass or lead. In general, the best material for laps to be used on very accurate work is soft, close-grained cast iron. If the grinding, prior to lapping, is of inferior quality, or an excessive allowance has been left for lapping, copper laps may be preferable. They can be charged more easily and cut more rapidly than cast iron, but do not produce as good a finish. Whatever material is
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Machinery's Handbook 27th Edition 1236
LAPS AND LAPPING
used, the lap should be softer than the work, as, otherwise, the latter will become charged with the abrasive and cut the lap, the order of the operation being reversed. A common and inexpensive form of lap for holes is made of lead which is cast around a tapering steel arbor. The arbor usually has a groove or keyway extending lengthwise, into which the lead flows, thus forming a key that prevents the lap from turning. When the lap has worn slightly smaller than the hole and ceases to cut, the lead is expanded or stretched a little by the driving in of the arbor. When this expanding operation has been repeated two or three times, the lap usually must be trued or replaced with a new one, owing to distortion. The tendency of lead laps to lose their form is an objectionable feature. They are, however, easily molded, inexpensive, and quickly charged with the cutting abrasive. A more elaborate form for holes is composed of a steel arbor and a split cast-iron or copper shell which is sometimes prevented from turning by a small dowel pin. The lap is split so that it can be expanded to accurately fit the hole being operated upon. For hardened work, some toolmakers prefer copper to either cast iron or lead. For holes varying from 1⁄4 to 1⁄2 inch in diameter, copper or brass is sometimes used; cast iron is used for holes larger than 1⁄2 inch in diameter. The arbors for these laps should have a taper of about 1⁄4 or 3⁄8 inch per foot. The length of the lap should be somewhat greater than the length of the hole, and the thickness of the shell or lap proper should be from 1⁄8 to 1⁄6 its diameter. External laps are commonly made in the form of a ring, there being an outer ring or holder and an inner shell which forms the lap proper. This inner shell is made of cast iron, copper, brass or lead. Ordinarily the lap is split and screws are provided in the holder for adjustment. The length of an external lap should at least equal the diameter of the work, and might well be longer. Large ring laps usually have a handle for moving them across the work. Laps for Flat Surfaces.—Laps for producing plane surfaces are made of cast iron. In order to secure accurate results, the lapping surface must be a true plane. A flat lap that is used for roughing or “blocking down” will cut better if the surface is scored by narrow grooves. These are usually located about 1⁄2 inch apart and extend both lengthwise and crosswise, thus forming a series of squares similar to those on a checker-board. An abrasive of No. 100 or 120 emery and lard oil can be used for charging the roughing lap. For finer work, a lap having an unscored surface is used, and the lap is charged with a finer abrasive. After a lap is charged, all loose abrasive should be washed off with gasoline, for fine work, and when lapping, the surface should be kept moist, preferably with kerosene. Gasoline will cause the lap to cut a little faster, but it evaporates so rapidly that the lap soon becomes dry and the surface caked and glossy in spots. Loose emery should not be applied while lapping, for if the lap is well charged with abrasive in the beginning, is kept well moistened and not crowded too hard, it will cut for a considerable time. The pressure upon the work should be just enough to insure constant contact. The lap can be made to cut only so fast, and if excessive pressure is applied it will become “stripped” in places. The causes of scratches are: Loose abrasive on the lap; too much pressure on the work, and poorly graded abrasive. To produce a perfectly smooth surface free from scratches, the lap should be charged with a very fine abrasive. Grading Abrasives for Lapping.—For high-grade lapping, abrasives can be evenly graded as follows: A quantity of flour-emery or other abrasive is placed in a heavy cloth bag, which is gently tapped, causing very fine particles to be sifted through. When a sufficient quantity has been obtained in this way, it is placed in a dish of lard or sperm oil. The largest particles will then sink to the bottom and in about one hour the oil should be poured into another dish, care being taken not to disturb the sediment at the bottom. The oil is then allowed to stand for several hours, after which it is poured again, and so on, until the desired grade is obtained.
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Machinery's Handbook 27th Edition LAPS AND LAPPING
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Charging Laps.—To charge a flat cast-iron lap, spread a very thin coating of the prepared abrasive over the surface and press the small cutting particles into the lap with a hard steel block. There should be as little rubbing as possible. When the entire surface is apparently charged, clean and examine for bright spots; if any are visible, continue charging until the entire surface has a uniform gray appearance. When the lap is once charged, it should be used without applying more abrasive until it ceases to cut. If a lap is over-charged and an excessive amount of abrasive is used, there is a rolling action between the work and lap which results in inaccuracy. The surface of a flat lap is usually finished true, prior to charging, by scraping and testing with a standard surface-plate, or by the well-known method of scraping-in three plates together, in order to secure a plane surface. In any case, the bearing marks or spots should be uniform and close together. These spots can be blended by covering the plates evenly with a fine abrasive and rubbing them together. While the plates are being ground in, they should be carefully tested and any high spots which may form should be reduced by rubbing them down with a smaller block. To charge cylindrical laps for internal work, spread a thin coating of prepared abrasive over the surface of a hard steel block, preferably by rubbing lightly with a cast-iron or copper block; then insert an arbor through the lap and roll the latter over the steel block, pressing it down firmly to embed the abrasive into the surface of the lap. For external cylindrical laps, the inner surface can be charged by rolling-in the abrasive with a hard steel roller that is somewhat smaller in diameter than the lap. The taper cast-iron blocks which are sometimes used for lapping taper holes can also be charged by rolling-in the abrasive, as previously described; there is usually one roughing and one finishing lap, and when charging the former, it may be necessary to vary the charge in accordance with any error which might exist in the taper. Rotary Diamond Lap.—This style of lap is used for accurately finishing very small holes, which, because of their size, cannot be ground. While the operation is referred to as lapping, it is, in reality, a grinding process, the lap being used the same as a grinding wheel. Laps employed for this work are made of mild steel, soft material being desirable because it can be charged readily. Charging is usually done by rolling the lap between two hardened steel plates. The diamond dust and a little oil is placed on the lower plate, and as the lap revolves, the diamond is forced into its surface. After charging, the lap should be washed in benzine. The rolling plates should also be cleaned before charging with dust of a finer grade. It is very important not to force the lap when in use, especially if it is a small size. The lap should just make contact with the high spots and gradually grind them off. If a diamond lap is lubricated with kerosene, it will cut freer and faster. These small laps are run at very high speeds, the rate depending upon the lap diameter. Soft work should never be ground with diamond dust because the dust will leave the lap and charge the work. When using a diamond lap, it should be remembered that such a lap will not produce sparks like a regular grinding wheel; hence, it is easy to crowd the lap and “strip” some of the diamond dust. To prevent this, a sound intensifier or “harker” should be used. This is placed against some stationary part of the grinder spindle, and indicates when the lap touches the work, the sound produced by the slightest contact being intensified. Grading Diamond Dust.—The grades of diamond dust used for charging laps are designated by numbers, the fineness of the dust increasing as the numbers increase. The diamond, after being crushed to powder in a mortar, is thoroughly mixed with high-grade olive oil. This mixture is allowed to stand five minutes and then the oil is poured into another receptacle. The coarse sediment which is left is removed and labeled No. 0, according to one system. The oil poured from No. 0 is again stirred and allowed to stand ten minutes, after which it is poured into another receptacle and the sediment remaining is labeled No. 1. This operation is repeated until practically all of the dust has been recovered from the oil, the time that the oil is allowed to stand being increased as shown by the following table. This is done in order to obtain the smaller particles that require a longer time for precipitation:
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Machinery's Handbook 27th Edition 1238
LAPS AND LAPPING To obtain No. 1 — 10 minutes
To obtain No. 4 — 2 hours
To obtain No. 2 — 30 minutes
To obtain No. 5 — 10 hours
To obtain No. 3 — 1 hour To obtain No. 6 — until oil is clear The No. 0 or coarse diamond which is obtained from the first settling is usually washed in benzine, and re-crushed unless very coarse dust is required. This No. 0 grade is sometimes known as “ungraded” dust. In some places the time for settling, in order to obtain the various numbers, is greater than that given in the table. Cutting Properties of Laps and Abrasives.—In order to determine the cutting properties of abrasives when used with different lapping materials and lubricants, a series of tests was conducted, the results of which were given in a paper by W. A. Knight and A. A. Case, presented before the American Society of Mechanical Engineers. In connection with these tests, a special machine was used, the construction being such that quantitative results could be obtained with various combinations of abrasive, lubricant, and lap material. These tests were confined to surface lapping. It was not the intention to test a large variety of abrasives, three being selected as representative; namely, Naxos emery, carborundum, and alundum. Abrasive No. 150 was used in each case, and seven different lubricants, five different pressures, and three different lap materials were employed. The lubricants were lard oil, machine oil, kerosene, gasoline, turpentine, alcohol, and soda water. These tests indicated throughout that there is, for each different combination of lap and lubricant, a definite size of grain that will give the maximum amount of cutting. With all the tests, except when using the two heavier lubricants, some reduction in the size of the grain below that used in the tests (No. 150) seemed necessary before the maximum rate of cutting was reached. This reduction, however, was continuous and soon passed below that which gave the maximum cutting rate. Cutting Qualities with Different Laps.—The surfaces of the steel and cast-iron laps were finished by grinding. The hardness of the different laps, as determined by the scleroscope was, for cast-iron, 28; steel, 18; copper, 5. The total amount ground from the testpieces with each of the three laps showed that, taking the whole number of tests as a standard, there is scarcely any difference between the steel and cast iron, but that copper has somewhat better cutting qualities, although, when comparing the laps on the basis of the highest and lowest values obtained with each lap, steel and cast iron are as good for all practical purposes as copper, when the proper abrasive and lubricant are used. Wear of Laps.—The wear of laps depends upon the material from which they are made and the abrasive used. The wear on all laps was about twice as fast with carborundum as with emery, while with alundum the wear was about one and one-fourth times that with emery. On an average, the wear of the copper lap was about three times that of the cast-iron lap. This is not absolute wear, but wear in proportion to the amount ground from the testpieces. Lapping Abrasives.—As to the qualities of the three abrasives tested, it was found that carborundum usually began at a lower rate than the other abrasives, but, when once started, its rate was better maintained. The performance gave a curve that was more nearly a straight line. The charge or residue as the grinding proceeded remained cleaner and sharper and did not tend to become pasty or mucklike, as is so frequently the case with emery. When using a copper lap, carborundum shows but little gain over the cast-iron and steel laps, whereas, with emery and alundum, the gain is considerable. Effect of Different Lapping Lubricants.—The action of the different lubricants, when tested, was found to depend upon the kind of abrasive and the lap material. Lard and Machine Oil: The test showed that lard oil, without exception, gave the higher rate of cutting, and that, in general, the initial rate of cutting is higher with the lighter lubri-
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Machinery's Handbook 27th Edition LAPS AND LAPPING
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cants, but falls off more rapidly as the test continues. The lowest results were obtained with machine oil, when using an emery-charged, cast-iron lap. When using lard oil and a carborundum-charged steel lap, the highest results were obtained. Gasoline and Kerosene: On the cast-iron lap, gasoline was superior to any of the lubricants tested. Considering all three abrasives, the relative value of gasoline, when applied to the different laps, is as follows: Cast iron, 127; copper, 115; steel, 106. Kerosene, like gasoline, gives the best results on cast iron and the poorest on steel. The values obtained by carborundum were invariably higher than those obtained with emery, except when using gasoline and kerosene on a copper lap. Turpentine and Alcohol: Turpentine was found to do good work with carborundum on any lap. With emery, turpentine did fair work on the copper lap, but, with the emery on cast-iron and steel laps, it was distinctly inferior. Alcohol gives the lowest results with emery on the cast-iron and steel laps. Soda Water: Soda water gives medium results with almost any combination of lap and abrasives, the best work being on the copper lap and the poorest on the steel lap. On the cast-iron lap, soda water is better than machine or lard oil, but not so good as gasoline or kerosene. Soda water when used with alundum on the copper lap, gave the highest results of any of the lubricants used with that particular combination. Lapping Pressures.—Within the limits of the pressures used, that is, up to 25 pounds per square inch, the rate of cutting was found to be practically proportional to the pressure. The higher pressures of 20 and 25 pounds per square inch are not so effective on the copper lap as on the other materials. Wet and Dry Lapping.—With the “wet method” of using a surface lap, there is a surplus of oil and abrasive on the surface of the lap. As the specimen being lapped is moved over it, there is more or less movement or shifting of the abrasive particles. With the “dry method,” the lap is first charged by rubbing or rolling the abrasive into its surface. All surplus oil and abrasive are then washed off, leaving a clean surface, but one that has embedded uniformly over it small particles of the abrasive. It is then like the surface of a very fine oilstone and will cut away hardened steel that is rubbed over it. While this has been termed the dry method, in practice, the lap surface is kept moistened with kerosene or gasoline. Experiments on dry lapping were carried out on the cast-iron, steel, and copper laps used in the previous tests, and also on one of tin made expressly for the purpose. Carborundum alone was used as the abrasive and a uniform pressure of 15 pounds per square inch was applied to the specimen throughout the tests. In dry lapping, much depends upon the manner of charging the lap. The rate of cutting decreased much more rapidly after the first 100 revolutions than with the wet method. Considering the amounts ground off during the first 100 revolutions, and the best result obtained with each lap taken as the basis of comparison, it was found that with a tin lap, charged by rolling No. 150 carborundum into the surface, the rate of cutting, when dry, approached that obtained with the wet method. With the other lap materials, the rate with the dry method was about one-half that of the wet method. Summary of Lapping Tests.—The initial rate of cutting does not greatly differ for different abrasives. There is no advantage in using an abrasive coarser than No. 150. The rate of cutting is practically proportional to the pressure. The wear of the laps is in the following proportions: cast iron, 1.00; steel, 1.27; copper, 2.62. In general, copper and steel cut faster than cast iron, but, where permanence of form is a consideration, cast iron is the superior metal. Gasoline and kerosene are the best lubricants to use with a cast-iron lap. Machine and lard oil are the best lubricants to use with copper or steel laps. They are, however, least effective on a cast-iron lap. In general, wet lapping is from 1.2 to 6 times as fast as dry lapping, depending upon the material of the lap and the manner of charging.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1240
KNURLS AND KNURLING
KNURLS AND KNURLING ANSI Standard Knurls and Knurling.—The ANSI/ASME Standard B94.6-1984 covers knurling tools with standardized diametral pitches and their dimensional relations with respect to the work in the production of straight, diagonal, and diamond knurling on cylindrical surfaces having teeth of uniform pitch parallel to the cylinder axis or at a helix angle not exceeding 45 degrees with the work axis. These knurling tools and the recommendations for their use are equally applicable to general purpose and precision knurling. The advantage of this ANSI Standard system is the provision by which good tracking (the ability of teeth to mesh as the tool penetrates the work blank in successive revolutions) is obtained by tools designed on the basis of diametral pitch instead of TPI (teeth per inch) when used with work blank diameters that are multiples of 1⁄64 inch for 64 and 128 diametral pitch or 1⁄32 inch for 96 and 160 diametral pitch. The use of knurls and work blank diameters which will permit good tracking should improve the uniformity and appearance of knurling, eliminate the costly trial and error methods, reduce the failure of knurling tools and production of defective work, and decrease the number of tools required. Preferred sizes for cylindrical knurls are given in Table 1 and detailed specifications appear in Table 2. Table 1. ANSI Standard Preferred Sizes for Cylindrical Type Knurls ANSI/ASME B94.6-1984 Nominal Outside Diameter Dnt
Width of Face F
Diameter of Hole A
64
1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
3⁄ 16 1⁄ 4 3⁄ 8 3⁄ 8
3⁄ 16 1⁄ 4 1⁄ 4 1⁄ 4
32 40 48 56
5⁄ 8
5⁄ 16
7⁄ 32
40
3⁄ 4
5⁄ 8 3⁄ 8
1⁄ 4 5⁄ 16
48 64
Standard Diametral Pitches, P 96 128 160 Number of Teeth, Nt, for Standard Pitches 48 60 72 84
64 80 96 112
80 100 120 140
60
80
100
72 96
96 128
120 160
Additional Sizes for Bench and Engine Lathe Tool Holders
1
The 96 diametral pitch knurl should be given preference in the interest of tool simplification. Dimensions Dnt, F, and A are in inches.
Table 2. ANSI Standard Specifications for Cylindrical Knurls with Straight or Diagonal Teeth ANSI/ASME B94.6-1984 Diametral Pitch P 64
Nominal Diameter, Dnt 1⁄ 2
5⁄ 8
3⁄ 4
7⁄ 8
1
Tracking Correction Factor Q
0.9864
0.0006676
Major Diameter of Knurl, Dot, +0.0000, −0.0015 0.4932
0.6165
0.7398
0.8631
Tooth Depth, h, + 0.0015, − 0.0000 Straight
Diagonal
0.024
0.021
96
0.4960
0.6200
0.7440
0.8680
0.9920
0.0002618
0.016
0.014
128
0.4972
0.6215
0.7458
0.8701
0.9944
0.0001374
0.012
0.010
160
0.4976
0.6220
0.7464
0.8708
0.9952
0.00009425
0.009
0.008
Radius at Root R 0.0070 0.0050 0.0060 0.0040 0.0045 0.0030 0.0040 0.0025
All dimensions except diametral pitch are in inches. Approximate angle of space between sides of adjacent teeth for both straight and diagonal teeth is 80 degrees. The permissible eccentricity of teeth for all knurls is 0.002 inch maximum (total indicator reading). Number of teeth in a knurl equals diametral pitch multiplied by nominal diameter. Diagonal teeth have 30-degree helix angle, ψ.
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Machinery's Handbook 27th Edition KNURLS AND KNURLING
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The term Diametral Pitch applies to the quotient obtained by dividing the total number of teeth in the circumference of the work by the basic blank diameter; in the case of the knurling tool it would be the total number of teeth in the circumference divided by the nominal diameter. In the Standard the diametral pitch and number of teeth are always measured in a transverse plane which is perpendicular to the axis of rotation for diagonal as well as straight knurls and knurling. Cylindrical Knurling Tools.—The cylindrical type of knurling tool comprises a tool holder and one or more knurls. The knurl has a centrally located mounting hole and is provided with straight or diagonal teeth on its periphery. The knurl is used to reproduce this tooth pattern on the work blank as the knurl and work blank rotate together. *Formulas for Cylindrical Knurls
P =diametral pitch of knurl = Nt ÷ Dnt Dnt = nominal diameter of knurl = Nt ÷ P Nt =no. of teeth on knurl = P × Dnt *P nt *P ot
(1) (2) (3)
=circular pitch on nominal diameter = π ÷ P
(4)
=circular pitch on major diameter = πDot ÷ Nt
(5)
Dot = major diameter of knurl = Dnt − (NtQ ÷ π) Q =Pnt − Pot = tracking correction factor in Formula
(6) (7)
Tracking Correction Factor Q: Use of the preferred pitches for cylindrical knurls, Table 2, results in good tracking on all fractional work-blank diameters which are multiples of 1⁄64 inch for 64 and 128 diametral pitch, and 1⁄32 inch for 96 and 160 diametral pitch; an indication of good tracking is evenness of marking on the work surface during the first revolution of the work. The many variables involved in knurling practice require that an empirical correction method be used to determine what actual circular pitch is needed at the major diameter of the knurl to produce good tracking and the required circular pitch on the workpiece. The empirical tracking correcton factor, Q, in Table 2 is used in the calculation of the major diameter of the knurl, Formula (6).
Cylindrical Knurl * Note:
For diagonal knurls, Pnt and Pot are the transverse circular pitches which are measured in the plane perpendicular to the axis of rotation.
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Machinery's Handbook 27th Edition 1242
KNURLS AND KNURLING
Flat Knurling Tools.—The flat type of tool is a knurling die, commonly used in reciprocating types of rolling machines. Dies may be made with either single or duplex faces having either straight or diagonal teeth. No preferred sizes are established for flat dies. Flat Knurling Die with Straight Teeth:
R =radius at root P =diametral pitch = Nw ÷ Dw Dw =work blank (pitch) diameter = Nw ÷ P Nw =number of teeth on work = P × Dw h =tooth depth Q =tracking correction factor (see Table 2) Pl =linear pitch on die =circular pitch on work pitch diameter = P − Q
(8) (9) (10)
(11)
Table 3. ANSI Standard Specifications for Flat Knurling Dies ANSI/ASME B94.6-1984 Diametral Pitch, P
Linear Pitch,a Pl
Tooth Depth, h Straight
Diagonal
Tooth Depth, h
Radius at Root, R
Diametral Pitch, P
Linear Pitch,a Pl
Straight
Diagonal
128
0.0244
0.012
0.010
0.0045 0.0030
160
0.0195
0.009
0.008
0.0040 0.0025
64
0.0484
0.024
0.021
0.0070 0.0050
96
0.0325
0.016
0.014
0.0060 0.0040
Radius at Root, R
a The linear pitches are theoretical. The exact linear pitch produced by a flat knurling die may vary slightly from those shown depending upon the rolling condition and the material being rolled.
All dimensions except diametral pitch are in inches.
Teeth on Knurled Work
Formulas Applicable to Knurled Work.—The following formulas are applicable to knurled work with straight, diagonal, and diamond knurling.
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Machinery's Handbook 27th Edition KNURLS AND KNURLING
1243
Formulas for Straight or Diagonal Knurling with Straight or Diagonal Tooth Cylindrical Knurling Tools Set with Knurl Axis Parallel with Work Axis: P =diametral pitch = Nw ÷ Dw Dw =work blank diameter = Nw ÷ P Nw =no. of teeth on work = P × Dw a =“addendum” of tooth on work = (Dow − Dw) ÷ 2 h =tooth depth (see Table 2) Dow = knurled diameter (outside diameter after knurling) = Dw + 2a
(12) (13) (14) (15) (16)
Formulas for Diagonal and Diamond Knurling with Straight Tooth Knurling Tools Set at an Angle to the Work Axis: ψ =angle between tool axis and work axis P =diametral pitch on tool Pψ =diametral pitch produced on work blank (as measured in the transverse plane) by setting tool axis at an angle ψ with respect to work blank axis Dw =diameter of work blank; and Nw =number of teeth produced on work blank (as measured in the transverse plane) then, Pψ =P cos ψ (17) and, N =DwP cos ψ (18) For example, if 30 degree diagonal knurling were to be produced on 1-inch diameter stock with a 160 pitch straight knurl: If,
N w = D w P cos 30 ° = 1.000 × 160 × 0.86603 = 138.56 teeth Good tracking is theoretically possible by changing the helix angle as follows to correspond to a whole number of teeth (138): cos ψ = N w ÷ D w P = 138 ÷ ( 1 × 160 ) = 0.8625 ψ = 30 1⁄2 degrees, approximately Whenever it is more practical to machine the stock, good tracking can be obtained by reducing the work blank diameter as follows to correspond to a whole number of teeth (138): Nw 138 - = ---------------------------= 0.996 inch D w = ---------------P cos ψ 160 × 0.866 Table 4. ANSI Standard Recommended Tolerances on Knurled Diameters ANSI/ASME B94.6-1984 Tolerance Class I II III
64
+ 0.005 − 0.012 + 0.000 − 0.010 + 0.000 − 0.006
96 128 Tolerance on Knurled Outside Diameter + 0.004 + 0.003 − 0.010 − 0.008 + 0.000 + 0.000 − 0.009 − 0.008 + 0.000 + 0.000 − 0.005 − 0.004
Diametral Pitch 160 64
+ 0.002 − 0.006 + 0.000 − 0.006 + 0.000 − 0.003
± 0.0015
96 128 Tolerance on Work-Blank Diameter Before Knurling ± 0.0010
± 0.0007
160
± 0.0005
± 0.0015
± 0.0010
± 0.0007
± 0.0005
+ 0.000 − 0.0015
+ 0.0000 − 0.0010
+ 0.000 − 0.0007
+ 0.0000 − 0.0005
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1244
KNURLS AND KNURLING
Recommended Tolerances on Knurled Outside Diameters.—T h e r e c o m m e n d e d applications of the tolerance classes shown in Table 4 are as follows: Class I: Tolerances in this classification may be applied to straight, diagonal and raised diamond knurling where the knurled outside diameter of the work need not be held to close dimensional tolerances. Such applications include knurling for decorative effect, grip on thumb screws, and inserts for moldings and castings. Class II: Tolerances in this classification may be applied to straight knurling only and are recommended for applications requiring closer dimensional control of the knurled outside diameter than provided for by Class I tolerances. Class III: Tolerances in this classification may be applied to straight knurling only and are recommended for applications requiring closest possible dimensional control of the knurled outside diameter. Such applications include knurling for close fits. Note: The width of the knurling should not exceed the diameter of the blank, and knurling wider than the knurling tool cannot be produced unless the knurl starts at the end of the work. Marking on Knurls and Dies.—Each knurl and die should be marked as follows: a. when straight to indicate its diametral pitch; b. when diagonal, to indicate its diametral pitch, helix angle, and hand of angle. Concave Knurls.—The radius of a concave knurl should not be the same as the radius of the piece to be knurled. If the knurl and the work are of the same radius, the material compressed by the knurl will be forced down on the shoulder D and spoil the appearance of the work. A design of concave knurl is shown in the accompanying illustration, and all the important dimensions are designated by letters. To find these dimensions, the pitch of the knurl required must be known, and also, approximately, the throat diameter B. This diameter must suit the knurl holder used, and be such that the circumference contains an even number of teeth with the required pitch. When these dimensions have been decided upon, all the other unknown factors can be found by the following formulas: Let R = radius of piece to be knurled; r = radius of concave part of knurl; C = radius of cutter or hob for cutting the teeth in the knurl; B = diameter over concave part of knurl (throat diameter); A = outside diameter of knurl; d = depth of tooth in knurl; P = pitch of knurl (number of teeth per inch circumference); p = circular pitch of knurl; then r = R + 1⁄2d; C = r + d; A = B + 2r − (3d + 0.010 inch); and d = 0.5 × p × cot α/2, where α is the included angle of the teeth. As the depth of the tooth is usually very slight, the throat diameter B will be accurate enough for all practical purposes for calculating the pitch, and it is not necessary to take into consideration the pitch circle. For example, assume that the pitch of a knurl is 32, that the throat diameter B is 0.5561 inch, that the radius R of the piece to be knurled is 1⁄16 inch, and that the angle of the teeth is 90 degrees; find the dimensions of the knurl. Using the notation given: 1- = 0.03125 inch p = --1- = ----d = 0.5 × 0.03125 × cot 45° = 0.0156 inch P 32 1- + 0.0156 r = -------------------- = 0.0703 inch C = 0.0703 + 0.0156 = 0.0859 inch 16 2 A = 0.5561 + 0.1406 – ( 0.0468 + 0.010 ) = 0.6399 inch
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Machinery's Handbook 27th Edition ACCURACY
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MACHINE TOOL ACCURACY Accuracy, Repeatability, and Resolution: In machine tools, accuracy is the maximum spread in measurements made of slide movements during successive runs at a number of target points, as discussed below. Repeatability is the spread of the normal curve at the target point that has the largest spread. A rule of thumb says that repeatability is approximately half the accuracy value, or twice as good as the accuracy, but this rule is somewhat nullified due to the introduction of error-compensation features on NC machines. Resolution refers to the smallest units of measurement that the system (controller plus servo) can recognize. Resolution is an electronic/electrical term and the unit is usually smaller than either the accuracy or the repeatability. Low values for resolution are usually, though not necessarily, applied to machines of high accuracy. In addition to high cost, a low-resolution-value design usually has a low maximum feed rate and the use of such designs is usually restricted to applications requiring high accuracy. Positioning Accuracy:The positioning accuracy of a numerically controlled machine tool refers to the ability of an NC machine to place the tip of a tool at a preprogrammed target. Although no metal cutting is involved, this test is very significant for a machine tool and the cost of an NC machine will rise almost geometrically with respect to its positioning accuracy. Care, therefore, should be taken when deciding on the purchase of such a machine, to avoid paying the premium for unneeded accuracy but instead to obtain a machine that will meet the tolerance requirements for the parts to be produced. Accuracy can be measured in many ways. A tool tip on an NC machine could be moved, for example, to a target point whose X-coordinate is 10.0000 inches. If the move is along the X-axis, and the tool tip arrives at a point that measures 10.0001 inches, does this mean that the machine has an accuracy of 0.0001 inch? What if a repetition of this move brought the tool tip to a point measuring 10.0003 inches, and another repetition moved the tool to a point that measured 9.9998 inches? In practice, it is expected that there would be a scattering or distribution of measurements and some kind of averaging is normally used. Mean Positional Deviation = 0.0003 = xj
Positional Deviation xij
Readings Normal Curve
x-Axis
Target 10.0000
Mean (Avg.) 10.0003
Distance Between Increments = 0.001"
Fig. 1. In a Normal Distribution, Plotted Points Cluster Around the Mean.
Although averaging the results of several runs is an improvement over a single run, the main problem with averaging is that it does not consider the extent or width of the spread of readings. For example, if one measurement to the 10.0000-inch target is 9.9000 inches and another is 10.1000 inches, the difference of the two readings is 0.2000 inch, and the accuracy is poor. However, the readings average a perfect 10 inches. Therefore, the average and the spread of several readings must both be considered in determining the accuracy. Plotting the results of a large number of runs generates a normal distribution curve, as shown in Fig. 1. In this example, the readings are plotted along the X-axis in increments of
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Machinery's Handbook 27th Edition 1246
ACCURACY
0.0001 inch (0.0025 mm). Usually, five to ten such readings are sufficient. The distance of any one reading from the target is called the positional deviation of the point. The distance of the mean, or average, for the normal distribution from the target is called the mean positional deviation. The spread for the normal curve is determined by a mathematical formula that calculates the distance from the mean that a certain percentage of the readings fall into. The mathematical formula used calculates one standard deviation, which represents approximately 32 per cent of the points that will fall within the normal curve, as shown in Fig. 2. One standard deviation is also called one sigma, or 1σ. Plus or minus one sigma (±1σ) represents 64 per cent of all the points under the normal curve. A wider range on the curve, ±2σ, means that 95.44 per cent of the points are within the normal curve, and ±3σ means that 99.74 per cent of the points are within the normal curve. If an infinite number of runs were made, almost all the measurements would fall within the ±3σ range.
64% of Readings 95.44% of Readings 99.74% of Readings –1 +1 –2
+2
–3
+3 Mean (Avg.)
Fig. 2. Percentages of Points Falling in the ±1σ (64%), ±2σ (95.44%), and ±3σ (99.74%) Ranges
The formula for calculating one standard deviation is 1σ =
1 ----------n–1
n
∑ ( Xij – Xj )
2
i=1
where n = number of runs to the target; i = identification for any one run; Xij = positional deviation for any one run (see Fig. 1); and, Xj = mean positional deviation (see Fig. 1). The bar over the X in the formula indicates that the value is the mean or average for the normal distribution. Example:From Fig. 3, five runs were made at a target point that is 10.0000 inches along the X-axis and the positional deviations for each run were: x1j = −0.0002, x2j = +0.0002, x3j = +0.0005, x4j = +0.0007, and x5j = +0.0008 inch. The algebraic total of these five runs is +0.0020, and the mean positional deviation = Xj = 0.0020⁄5 = 0.0004. The calculations for one standard deviation are: 1σ =
1 - [ ( X – X )2 + ( X – X )2 + ( X – X )2 + ( X – X ) 2 + ( X – X )2 ] ----------j j j j j 1j 2j 3j 4j 5j n–1
1σ =
1 - ( – 0.0002 – 0.0004 ) 2 ----------[ + ( 0.0002 – 0.0004 ) 2 + 5–1 ( 0.0005 – 0.0004 ) 2 + ( 0.0007 – 0.0004 ) 2 + ( 0.0008 – 0.0004 ) 2 ]
=
--1- ( 0.00000066 ) = 4
-6
0.17 ×10 = 0.0004
Three sigma variations or 3σ, is 3 times sigma, equal to 0.0012 for the example.
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If an infinite number of trials were made to the target position of 10.0000 inches for the ongoing example, 99.74 per cent of the points would fall between 9.9992 and 10.0016 inches, giving a spread of ± 3σ, or 0.0024 inch. This spread alone is not considered as the accuracy but rather the repeatability for the target point 10.0000.
Fig. 3. Readings for Five Runs to Target Points P1, P2, P3, P4, and P5 Result in a Mean Positional Deviation of 0.0004
To calculate the accuracy, it is not sufficient to make a number of runs to one target point along a particular axis, but rather to a number of points along the axis, the number depending on the length of axis travel provided. For example, a travel of about 3 ft requires 5, and a travel of 6 ft requires 10 target points. The standard deviation and spread for the normal curve must be determined at each target point, as shown in Fig. 4. The accuracy for the axis would then be the spread between the normal curve with the most negative position and the normal curve with the most positive position. Technically, the accuracy is a spread rather than a ± figure, but it is often referred to as a ± figure and it may be assumed that a ±0.003, for expediency, is equal to a spread of 0.006. The above description for measuring accuracy considers unidirectional approaches to target points. Bidirectional movements (additional movements to the same target point from either direction) will give different results, mostly due to backlash in the lead-screw, though backlash is small with ballnut leadscrews. Measurements made with bidirectional movements will show greater spreads and somewhat less accuracy than will unidirectional movements.
x–Axis TP1
TP2
TP3
TP4
TP5
(a)
Spread = Accuracy = 0.004⬙ (b) Fig. 4. Two Ways of Plotting Five Target Point Spreads
Rules for determining accuracy were standardized in guidelines last revised by the Association for Manufacturing Technology (AMT) in 1972. Some European machine tool builders use the VDI/DGQ 3441 (German) guidelines, which are similar to those of the
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ACCURACY
AMT in that normal distributions are used and a number of target points are selected along an axis. Japanese standards JIS B6201, JIS B6336, and JIS B6338 are somewhat simpler and consider only the spread of the readings, so that the final accuracy figure may be almost double that given by the AMT or VDI methods. The International Standards Organization (ISO), in 1988, issued ISO 230-2, which follows the procedures discussed above, but is somewhat less strict than the AMT recommendations. Table 1 lists some types of NC machines and the degree of accuracy that they normally provide. Table 1. Degrees of Accuracy Expected with NC Machine Tools Accuracy Type of NC Machine Large boring machines or boring mills Small milling machines Large machining centers Small and medium-sized machining centers Lathes, slant bed, small and medium sizes Lathes, small precision Horizontal jigmill Vertical jig boring machines Vertical jig grinding machines Cylindrical grinding machines, small to medium sizes Diamond turning lathes
inches 0.0010–0.0020 0.0006–0.0010 0.0005–0.0008 0.0003–0.0006 0.0002–0.0005 0.0002–0.0003 0.0002–0.0004 0.0001–0.0002 0.0001–0.0002
mm 0.025–0.050 0.015–0.025 0.012–0.020 0.008–0.015 0.006–0.012 0.004–0.008 0.004–0.010 0.002–0.005 0.002–0.005
0.00004–0.0003
0.001–0.007
0.00002–0.0001
0.0005–0.003
Significance of Accuracy:Numerically controlled machines are generally considered to be more accurate and more consistent in their movements than their conventional counterparts. CNC controllers have improved the accuracy by providing the ability to compensate for mechanical inaccuracies. Thus, compensation for errors in the lead-screw, parallelism and squareness of the machine ways, and for the effects of heating can be made automatically on NC machines. Some machine tool types are expected to be more accurate than others; for instance, grinding machines are more accurate than milling machines, and lathes for diamond turning are more accurate than normal slant-bed lathes. Accuracy of machine tools depends on temperature, air pressure, local vibrations, and humidity. ISO standard 230-2 requires that, where possible, the ambient temperature for conducting such tests be held between 67.1 and 68.9 degrees F (19.5 and 20.5 degrees C). Autocollimation:Checks on movements of slides and spindles, and alignment and other characteristics of machine tools are performed with great accuracy by means of an autocollimator, which is an optical, noncontact, angle-measuring instrument. Flatness, straightness, perpendicularity, and runout can also be checked by autocollimation. The instrument is designed to project a beam of light from a laser or an incandescent bulb onto an optically flat mirror. When the light beam is reflected back to the instrument, the distance traveled by the beam, also deviations from a straight line, can be detected by the projector and calculated electronically or measured by the scale. Autocollimators have a small angular measuring range and are usually calibrated in arcseconds. One arc-second is an angle of 4.85 millionths of an inch (0.00000485 in.) per inch of distance from the vertex, and is often rounded to 5 millionths of an inch per inch. Angles can also be described in terms of radians and 1 arc-second is equal to 4.85 microradians, or 0.0000573 deg. In practice, the interferometer or autocollimator is fixed to a rigid structure and the optical mirror, which should have a flatness of one-quarter wavelength of the light used (see page 723), is fixed to the workpiece to be measured. The initial reading is taken, and then
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the workpiece is moved to another position. Readings of movement can be made to within a few millionths of an inch. Angular displacements, corresponding to successive positions, of about 1 arc-second can be taken from most autocollimators, in azimuth or elevation or a combination of the two. Generally, the line width of the reticle limits the accuracy of reading such instruments. Laser interferometers are designed to allow autocollimation readings to be taken by a photodetector instead of the eye, and some designs can measure angles to 0.001 arc-second, closer than is required for most machine shop applications. Output from an electronic autocollimator is usually transferred to a computer for recording or analysis if required. The computer calculates, lists, and plots the readings for the target points automatically, under control of the inspection program. A typical plot from such a setup is seen in Fig. 5, where the central line connects the averages for the normal distributions at each target point. The upper line connects the positive outer limits and the lower line the negative outer limits for the normal distributions. The normal spread, indicating the accuracy of positioning, is 0.00065 inch (0.016 mm), for the Y-axis along which the measurements were taken.
Date Humidity Air Press. Air Temp. Mach. Temp.
1984 / 6 / 11 Percent 41.00 In. Hg 27.36 Deg. F 77.50 Deg. F 76.50
Machining Center Axis Travel From –0.30 to –15.30
Axis - Y Runs - 8 Points - 16 In Increments of 1.0000
+ 0.0010 + 0.0005
– 0.0005 – 15.30 – 0.0010 – 0.30 – 1.80
– 3.30
– 4.80
– 6.30
– 7.80
– 9.30
– 10.80
– 12.30
– 13.80
Fig. 5. Laser Interferometer Plots of Movements of Slides on a Large Horizontal Machining Center Showing an Accuracy of 0.00065 inch (0.016 mm) for the y Axis
Effect of Machine Accuracy on Part Tolerances Part tolerances are usually shown on prints, usually in a control block to ANSI Standard 14.5M-1994 (see Geometric Dimensioning and Tolerancing starting on page 630.) Table 2 shows some part tolerance symbols that relate to machine tool positioning accuracy. The accuracy of a part is affected by machine and cutting tool dynamics, alignment, fixture accuracy, operator settings, and accuracies of the cutting tools, holders, and collets, but the positioning accuracy of the machine probably has the greatest influence. Spindle rotation accuracy, or runout, also has a large influence on part accuracy. The ratio of the attainable part accuracy to the no-load positioning accuracy can vary from 1.7:1 to 8.31:1, depending on the type of cutting operation. For instance, making a hole by drilling, followed by a light boring or reaming operation, produces a quite accurate result in about the 1.7:1 range, whereas contour milling on hard material could be at the higher end of the range. A good average for part accuracy versus machine positioning accuracy is 3.3:1, which means that the part accuracy is 3.3 times the positioning accuracy.
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Table 2. Symbols and Feature Control Frames ANSI Y14.5M-1994 Symbol
Characteristic
Meaning of Characteristic
The allowable true position tolerance of a feature from a datum (assume feature to be a drilled hole). Feature control block might appear as: Position
Relationship to the Machine Tool Assume tolerance is 0.005 mm. Machine positioning accuracy would be at least 0.005 × 0.707 = 0.0035 mm even if it is assumed that the hole accuracy is the same as the positioning accuracy. Machine could be milling, drilling, or machining center.
y – axis
⭋ 0.005 A A is the datum, which can be another surface, another hole, or other feature
True Position Tolerance Zone
ACCURACY
x – axis 45
Position
Assume feature to be a turned circumference, the axis of which has to be within a tolerance to another feature. Feature control block would appear as follows if feature A were the axis of hole 1:
Center (axis) for Hole 2
⭋ 0.005 A
Center (axis) for Hole 1
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True Position Tolerance Zone 2 (0.005 mm) Hole 2
Machinery's Handbook 27th Edition
Table 2. Symbols and Feature Control Frames ANSI Y14.5M-1994 Symbol
Characteristic
Meaning of Characteristic
Relationship to the Machine Tool
The roundness tolerance establishes a band. Roundness
This tolerance would apply to turning and would be the result of radial spindle runout.
Diametral accuracy of the part would depend on the positioning accuracy of the cross-slide of lathe or grinder. PosiUsually expressed as a ± tolerance attached to the dimension. tioning accuracy would be from 1⁄2 to 1⁄4 of part accuracy, depending chiefly on the rigidity of the tool, depth of cut, and material being cut.
ACCURACY
Diameter
Tolerance band
Specifies a uniform boundary, along a true profile.
Tolerance 0.005
Profile of a surface
Datum A
Affected by positioning accuracy of machine. There would be side and/or end forces on the tool so expect part to machine positioning accuracy to be high, say, 5:1
Feature control block might appear as:
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⭋ 0.005 A
Machinery's Handbook 27th Edition
Characteristic
Meaning of Characteristic
Relationship to the Machine Tool
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Table 2. Symbols and Feature Control Frames ANSI Y14.5M-1994 Symbol
A feature (surface) parallel to a datum plane or datum axis.
Tolerance 0.010 Affected by positioning accuracy, machine alignment, and fixturing.
Parallelism
Datum A Feature control block might appear as:
ACCURACY
⭋ 0.010 A
Applies to turning. The axis of the feature must lie within the tolerance zone of another axis.
Tolerance 0.010
A
Concentricity
Affected by positioning accuracy, most likely along Z axis.
Datum A Feature control block might appear as follows:
⭋ 0.005 A
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Machinery's Handbook 27th Edition
Table 2. Symbols and Feature Control Frames ANSI Y14.5M-1994 Symbol
Characteristic
Meaning of Characteristic
Relationship to the Machine Tool
Applies to the runout (both radial and axial) of a circular feature at any one position around the circumference or flat, perpendicular to the axis.
Runout
Runout at a Point (Radial)
Radial runout on part is not affected by spindle radial runout unless whole machine is untrue. Axial runout on part is affected by axial runout on machine. Feature would normally be perpendicular to datum. Feature control block might appear as:
⭋ 0.005 A
Runout at a Point (Axial)
Would be affected by either radial or axial runout, or both, machine misalignment, or setup.
Total runout
ACCURACY
Runout at a Point (Radial)
Similar to runout but applies to total surface and therefore consider both radial and axial runout.
A feature is perpendicular to a datum plane or axis. Perpendicularity
Tolerance Zone
Affected principally by misalignment of machine or fixturing.
1253
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Machinery's Handbook 27th Edition 1254
NUMERICAL CONTROL
NUMERICAL CONTROL Introduction.—The Electronic Industries Association (EIA) defines numerical control as “a system in which actions are controlled by the direct insertion of numerical data at some point.” More specifically, numerical control, or NC as it will be called here, involves machines controlled by electronic systems designed to accept numerical data and other instructions, usually in a coded form. These instructions may come directly from some source such as a punched tape, a floppy disk, directly from a computer, or from an operator. The key to the success of numerical control lies in its flexibility. To machine a different part, it is only necessary to “play” a different tape. NC machines are more productive than conventional equipment and consequently produce parts at less cost even when the higher investment is considered. NC machines also are more accurate and produce far less scrap than their conventional counterparts. By 1985, over 110,000 NC machine tools were operating in the United States. Over 80 per cent of the dollars being spent on the most common types of machine tools, namely, drilling, milling, boring, and turning machines, are going into NC equipment. NC is a generic term for the whole field of numerical control and encompasses a complete field of endeavor. Sometimes CNC, which stands for Computer Numerical Control and applies only to the control system, is used erroneously as a replacement term for NC. Albeit a monumental development, use of the term CNC should be confined to installations where the older hardware control systems have been replaced. Metal cutting is the most popular application, but NC is being applied successfully to other equipment, including punch presses, EDM wire cutting machines, inspection machines, laser and other cutting and torching machines, tube bending machines, and sheet metal cutting and forming machines. State of the CNC Technology Today.—Early numerical control machines were ordinary machines retrofitted with controls and motors to drive tools and tables. The operations performed were the same as the operations were on the machines replaced. Over the years, NC machines began to combine additional operations such as automatically changing tools and workpieces. The structure of the machines has been strengthened to provide more rigid platforms. These changes have resulted in a class of machine that can outperform its predecessors in both speed and accuracy. Typical capabilities of a modern machining center are accuracy better than ±0.00035 inch; spindle speeds in the range up to 25,000 rpm or more, and increasing; feed rates up to 400 inches per minute and increasing; tool change times hovering between 2 and 4 seconds and decreasing. Specialized machines have been built that can achieve accuracy better than one millionth (0.000001) of an inch. Computer numerical control of machines has undergone a great deal of change in the last decade, largely as a result of rapid increases in computer capability. Development of new and improved materials for tooling and bearings, improvements in tool geometry, and the added structural stiffness of the new machines have made it possible to perform cutting operations at speeds and feeds that were formerly impossible to attain. Numerical Control vs. Manual Operations.—The initial cost of a CNC machine is generally much higher than a manual machine of the same nominal capacity, and the higher initial cost leads to a higher overall cost of the machine per hour of its useful life. However, the additional cost of a CNC machine has to be considered against potential savings that the machine may make possible. Some of the individual factors that make NC and CNC machining attractive are considered below. Labor is usually one of the highest costs in the production of a part, but the labor rate paid to a CNC machine operator may be lower than the rate paid to the operator of conventional machines. This statement is particularly true when there is a shortage of operators with specialized skills necessary for setting up and operating a manual machine. However, it should not be assumed that skilled CNC machine operators are not needed because most CNCs have manual overrides that allow the operator to adjust feeds and speeds and to manually edit or enter programs as necessary. Also, skilled setup personnel and operators are
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likely to promote better production rates and higher efficiency in the shop. In addition, the labor rate for setting up and operating a CNC machine can sometimes be divided between two or more machines, further reducing the labor costs and cost per part produced. The quantity and quality requirements for an order of parts often determines what manufacturing process will be used to produce them. CNC machines are probably most effective when the jobs call for a small to medium number of components that require a wide range of operations to be performed. For example, if a large number of parts are to be machined and the allowable tolerances are large, then manual or automatic fixed-cycle machines may be the most viable process. But, if a large quantity of high quality parts with strict tolerances are required, then a CNC machine will probably be able to produce the parts for the lowest cost per piece because of the speed and accuracy of CNC machines. Moreover, if the production run requires designing and making a lot of specialized form tools, cams, fixtures, or jigs, then the economics of CNC machining improves even more because much of the preproduction work is not required by the nature of the CNC process. CNC machines can be effective for producing one-of-a-kind jobs if the part is complicated and requires a lot of different operations that, if done manually, would require specialized setups, jigs, fixtures, etc. On the other hand, a single component requiring only one or two setups might be more practical to produce on a manual machine, depending on the tolerances required. When a job calls for a small to medium number of components that require a wide range of operations, CNC is usually preferable. CNC machines are also especially well suited for batch jobs where small numbers of components are produced from an existing part program, as inventory is needed. Once the part program has been tested, a batch of the parts can be run whenever necessary. Design changes can be incorporated by changing the part program as required. The ability to process batches also has an additional benefit of eliminating large inventories of finished components. CNC machining can help reduce machine idle time. Surveys have indicated that when machining on manual machines, the average time spent on material removal is only about 40 per cent of the time required to complete a part. On particularly complicated pieces, this ratio can drop to as low as 10 per cent or even less. The balance of the time is spent on positioning the tool or work, changing tools, and similar activities. On numerically controlled machines, the metal removal time frequently has been found to be in excess of 70 per cent of the total time spent on the part. CNC nonmachining time is lower because CNC machines perform quicker tool changes and tool or work positioning than manual machines. CNC part programs require a skilled programmer and cost additional preproduction time, but specialized jigs and fixtures that are frequently required with manual machines are not usually required with CNC machines, thereby reducing setup time and cost considerably. Additional advantages of CNC machining are reduced lead time; improved cutting efficiency and longer tool life, as a result of better control over the feeds and speeds; improved quality and consistently accurate parts, reduced scrap, and less rework; lower inspection costs after the first part is produced and proven correct; reduced handling of parts because more operations can be performed per setup; and faster response to design changes because most part changes can be made by editing the CNC program. Numerical Control Standards.—Standards for NC hardware and software have been developed by many organizations, and copies of the latest standards may be obtained from the following: Electronic Industries Association (EIA), 2001 Pennsylvania Avenue NW, Washington, DC 20006 (EIA and ANSI/EIA); American Society of Mechanical Engineers (ASME), 345 East 47th Street, New York, NY 10017 (ANSI/ASME); American National Standards Institute (ANSI), 25 West 43rd Street, New York, NY 10036 (ANSI, ANSI/EIA, ANSI/ASME, and ISO); National Standards Association, Inc. (NSA), 1200 Quince Orchard Boulevard, Gaithersburg, MD 20878; NMTBA The Association for Manufacturing Technology, 7901 Westpark Drive, McLean, VA 22102. Some of the standards and their contents are listed briefly in the accompanying table.
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Machinery's Handbook 27th Edition 1256
NUMERICAL CONTROL Numerical Control Standards
Standard Title ANSI/CAM-I 101-1990
Description Dimensional Measuring Interface Specification
ANSI/ASME B5.50 V-Flange Tool Shanks for Machining Centers with Automatic Tool Changers ANSI/ASME B5.54-1992
Methods for Performance Evaluation of Computer Numerically Controlled Machining Centers
ANSI/ASME B89.1.12M
Methods for Performance Evaluation of Coordinate Measuring Machines
ANSI/EIA 227-A
1-inch Perforated Tape
ANSI/EIA 232-D
Interface Between Data Terminal Equipment and Data Circuit-Terminating Equipment Employing Serial Binary Data Interchange
ANSI/EIA 267-B
Axis and Motion Nomenclature for Numerically Controlled Machines
ANSI/EIA 274-D
Interchangeable Variable Block Data Format for Positioning, Contouring and Contouring/Positioning Numerically Controlled Machines
ANSI/EIA 358-B
Subset of American National Standarde Code for Information Interchange for Numerical Machine Control Perforated Tape
ANSI/EIA 408
Interface Between NC Equipment and Data Terminal Equipment Employing Parallel Binary Data Interchange
ANSI/EIA 423-A
Electrical Characteristics of Unbalanced Voltage Digital Interface Circuits
ANSI/EIA 431
Electrical Interface Between Numerical Control and Machine Tools
ANSI/EIA 441
Operator Interface Function of Numerical Controls
ANSI/EIA 449
General Purpose 37-position and 9-position Interface for Data Terminal Equipment and Data Circuit-Terminating Equipment Employing Serial Binary Data Interchange
ANSI/EIA 484
Electrical and Mechanical Interface Characteristics and Line Control Protocol Using Communication Control Characters for Serial Data Link between a Direct Numerical Control System and Numerical Control Equipment Employing Asynchronous Full Duplex Transmission
ANSI/EIA 491-A -1990
Interface between a Numerical Control Unit and Peripheral Equipment Employing Asynchronous Binary Data Interchange over Circuits having EIA-423-A Electrical Characteristics
ANSI/EIA 494
32-bit Binary CL Interchange (BCL) Input Format for Numerically Controlled Machines
EIA AB3-D
Glossary of Terms for Numerically Controlled Machines
EIA Bulletin 12
Application Notes on Interconnection between Interface Circuits Using RS449 and RS-232-C
ANSI X 3.94
Programming Aid for Numerically Controlled Manufacturing
ANSI X 3.37
Programming Language APT
ANSI X 3.20
1-inch Perforated Tape Take-up Reels for Information Interchange
ANSI X 3.82
One-sided Single Density Unformatted 5.25 inch Flexible Disc Cartridges
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Numerical Control Standards (Continued) Standard Title
Description
ISO 841
Numerical Control of Machines—Axis and Motion Nomenclature
ISO 2806
Numerical Control of Machines—Bilingual Vocabulary
ISO 2972
Numerical Control of Machines—Symbols
ISO 3592
Numerical Control of Machines—Numerical Control Processor Output, Logical Structure and Major Words
ISO 4336
Numerical Control of Machines—Specification of Interface Signals between the Numerical Control Unit and the Electrical Equipment of a Numerically Controlled Machine
ISO 4343
Numerical Control of Machines—NC Processor Output— Minor Elements of 2000-type Records (Post Processor Commands)
ISO TR 6132
Numerical Control of Machines—Program Format and Definition of Address Words—Part 1: Data Format for Positioning, Line Motion and Contouring Control Systems
ISO 230-1
Geometric Accuracy of Machines Operating Under No-Load or Finishing Conditions
ISO 230-2
Determination of Accuracy and Repeatability of Positioning of Numerically Controlled Machine Tools
NAS 911
Numerically Controlled Skin/Profile Milling Machines
NAS 912
Numerically Controlled Spar Milling Machines
NAS 913
Numerically Controlled Profiling and Contouring Milling Machines
NAS 914
Numerically Controlled Horizontal Boring, Drilling and Milling Machines
NAS 960
Numerically Controlled Drilling Machines
NAS 963
Computer Numerically Controlled Vertical and Horizontal Jig Boring Machines
NAS 970
Basic Tool Holders for Numerically Controlled Machine Tools
NAS 971
Precision Numerically Controlled Measuring/Inspection Machines
NAS 978
Numerically Controlled Machining Centers
NAS 990
Numerically Controlled Composite Filament Tape Laying Machines
NAS 993
Direct Numerical Control System
NAS 994
Adaptive Control System for Numerically Controlled Milling Machines
NAS 995
Specification for Computerized Numerical Control (CNC)
NMTBA
Common Words as They Relate to Numerical Control Software
NMTBA
Definition and Evaluation of Accuracy and Repeatability of Numerically Controlled Machine Tools
NMTBA
Numerical Control Character Code Cross Reference Chart
NMTBA
Selecting an Appropriate Numerical Control Programming Method
NEMA 1A1
Industrial Cell Controller Classification Concepts and Selection Guide
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Programmable Controller.—Frequently referred to as a PC or PLC (the latter term meaning Programmable Logic Controller), a programmable controller is an electronic unit or small computer. PLCs are used to control machinery, equipment, and complete processes, and to assist CNC systems in the control of complex NC machine tools and flexible manufacturing modules and cells. In effect, PLCs are the technological replacements for electrical relay systems.
Fig. 1. Programmable Controllers' Four Basic Elements
As shown in Fig. 1, a PLC is composed of four basic elements: the equipment for handling input and output (I/O) signals, the central processing unit (CPU), the power supply, and the memory. Generally, the CPU is a microprocessor and the brain of the PLC. Early PLCs used hardwired special-purpose electronic logic circuits, but most PLCs now being offered are based on microprocessors and have far more logic and control capabilities than was possible with hardwired systems. The CPU scans the status of the input devices continuously, correlates these inputs with the control logic in the memory, and produces the appropriate output responses needed to control the machine or equipment. Input to a PLC is either discrete or continuous. Discrete inputs may come from push buttons, micro switches, limit switches, photocells, proximity switches or pressure switches, for instance. Continuous inputs may come from sources such as thermocouples, potentiometers, or voltmeters. Outputs from a PLC normally are directed to actuating hardware such as solenoids, solenoid valves, and motor starters. The function of a PLC is to examine the status of an input or set of inputs and, based on this status, actuate or regulate an output or set of outputs. Digital control logic and sensor input signals are stored in the memory as a series of binary numbers (zeros and ones). Each memory location holds only one “bit” (either 0 or 1) of binary information; however, most of the data in a PLC are used in groups of 8 bits, or bytes. A word is a group of bytes that is operated on at one time by the PLC. The word size in modern PLCs ranges from 8 to 32 bits (1 to 4 bytes), depending on the design of the PLC. In general, the larger the word size that a system is able to operate on (that is, to work on at one time), the faster the system is going to perform. New systems are now beginning to appear that can operate on 64 bits of information at a time. There are two basic categories of memory: volatile and nonvolatile. Volatile memory loses the stored information when the power is turned off, but nonvolatile memory retains its logic even when power is cut off. A backup battery must be used if the information stored in volatile memory is to be retained. There are six commonly used types of memory. Of these six, random-access memory (RAM) is the most common type because it is the easiest to program and edit. RAM is also the only one of the six common types that is vola-
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tile memory. The five nonvolatile memory types are: core memory, read-only memory (ROM), programmable read-only memory (PROM), electronically alterable programmable read-only memory (EAPROM), and electronically erasable programmable read-only memory (EEPROM). EEPROMs are becoming more popular due to their relative ease of programming and their nonvolatile characteristic. ROM is often used as a generic term to refer to the general class of read-only memory types and to indicate that this type of memory is not usually reprogrammed. More than 90 per cent of the microprocessor PLCs now in the field use RAM memory. RAM is primarily used to store data, which are collected or generated by a process, and to store programs that are likely to change frequently. For example, a part program for machining a workpiece on a CNC machining center is loaded into and stored in RAM. When a different part is to be made, a different program can be loaded in its place. The nonvolatile memory types are usually used to store programs and data that are not expected to be changed. Programs that directly control a specific piece of equipment and contain specific instructions that allow other programs (such as a part program stored in RAM) to access and operate the hardware are usually stored in nonvolatile memory or ROM. The benefit of ROM is that stored programs and data do not have to be reloaded into the memory after the power has been turned off. PLCs are used primarily with handling systems such as conveyors, automatic retrieval and storage systems, robots, and automatic guided vehicles (AGV), such as are used in flexible manufacturing cells, modules, and systems (see Flexible Manufacturing Systems (FMS), Flexible Manufacturing Cell, and Flexible Manufacturing Module). PLCs are also to be found in applications as diverse as combustion chamber control, chemical process control, and printed-circuit-board manufacturing. Types of Programmable Controllers Type
No. of I/Os
General Applications
Math Capability
Mini
32
Replaces relays, timers, and counters.
Yes
Micro
32–64
Replaces relays, timers, and counters.
Yes
Small
64–128
Replaces relays, timers, and counters. Used for materials handling, and some process control.
Yes
Medium
128–512
Replaces relays, timers, and counters. Used for materials handling, process control, and data collection.
Yes
512+
Replaces relays, timers, and counters. Master control for other PLCs and cells and for generation of reports. High-level network capability
Yes
Large
Types of PLCs may be divided into five groups consisting of micro, mini, small, medium, and large according to the number of I/Os, functional capabilities, and memory capacity. The smaller the number of I/Os and memory capacity, and the fewer the functions, the simpler the PLC. Micro and mini PLCs are usually little more than replacements for relay systems, but larger units may have the functional capabilities of a small computer and be able to handle mathematical functions, generate reports, and maintain high-level communications.
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The preceding guidelines have some gray areas because mini, micro, and small PLCs are now available with large memory sizes and functional capacities normally reserved for medium and large PLCs. The accompanying table compares the various types of PLCs and their applications. Instructions that are input to a PLC are called programs. Four major programming languages are used with PLCs, comprising ladder diagrams, Boolean mnemonics, functional blocks, and English statements. Some PLC systems even support high-level programming languages such as BASIC and PASCAL. Ladder diagrams and Boolean mnemonics are the basic control-level languages. Functional blocks and English statements are considered high-level languages. Ladder diagrams were used with electrical relay systems before these systems were replaced by PLCs and are still the most popular programming method, so they will be discussed further.
Fig. 2. One Rung on a Ladder Diagram
A ladder diagram consists of symbols, or ladder logic elements, that represent relay contacts or switches and other elements in the control system. One of the more basic symbols represents a normally open switch and is described by the symbol ü ą. Another symbol is the normally closed switch, described by the symbol ü\ą. When the normally open switch is activated, it will close, and when the normally closed switch is activated, it will open. Fig. 2 shows one rung (line) on a ladder diagram. Switch 1001 is normally open and switch 1002 is closed. A symbol for a coil (0001) is shown at the right. If switch 1001 is actuated, it will close. If switch 1002 is not activated, it will stay closed. With the two switches closed, current will flow through the line and energize coil 0001. The coil will activate some mechanism such as an electric motor, a robot, or an NC machine tool, for instance. As an example, Fig. 3 shows a flexible manufacturing module (FMM), consisting of a turning center (NC lathe), an infeed conveyor, an outfeed conveyor, a robot that moves workpieces between the infeed conveyor, the turning center, and the outfeed conveyor, and a PLC. The arrowed lines show the signals going to and coming from the PLC. Fig. 4 shows a ladder diagram for a PLC that would control the operations of the FMM by: 1) Activating the infeed conveyor to move the workpiece to a position where the robot can pick it up 2) Activating the robot to pick up the workpiece and load it into the chuck on the NC lathe 3) Activating the robot to remove the finished workpiece and place it on the outfeed conveyor 4) Activating the outfeed conveyor to move the workpiece to the next operation
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Fig. 3. Layout of a Flexible Manufacturing Module
Fig. 4. Portion of a Typical Ladder Diagram for Control of a Flexible Manufacturing Module Including a Turning Center, Conveyors, a Robot, and a Programmable Controller
In Rung 1 of Fig. 4, a request signal for a workpiece from the NC lathe closes the normally open switch 1001. Switch 1002 will remain closed if photocell 1 is not activated, i.e., if it does not detect a workpiece. The signal therefore closes the circuit, energizes the coil, and starts the conveyor motor to bring the next workpiece into position for the robot to grasp.
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In Rung 2, switch 1002 (which has been changed in the program of the PLC from a normally closed to a normally open switch) closes when it is activated as photocell 1 detects the workpiece. The signal thus produced, together with the closing of the now normally open switch 1001, energizes the coil, causing the robot to pick up the workpiece from the infeed conveyor. In Rung 3, switch 1004 on the lathe closes when processing of the part is completed and it is ready to be removed by the robot. Photocell 2 checks to see if there is a space on the conveyor to accept the completed part. If no part is seen by photocell 2, switch 1003 will remain closed, and with switch 1004 closed, the coil will be energized, activating the robot to transfer the completed part to the outfeed conveyor. Rung 4 shows activation of the output conveyor when a part is to be transferred. Normally open switch 1004 was closed when processing of the part was completed. Switch 1003 (which also was changed from a normally closed to a normally open switch by the program) closes if photocell 2 detects a workpiece. The circuit is then closed and the coil is energized, starting the conveyor motor to move the workpiece clear to make way for the succeeding workpiece. Closed-Loop System.—Also referred to as a servo or feedback system, a closed-loop system is a control system that issues commands to the drive motors of an NC machine. The system then compares the results of these commands as measured by the movement or location of the machine component, such as the table or spindlehead. The feedback devices normally used for measuring movement or location of the component are called resolvers, encoders, Inductosyns, or optical scales. The resolver, which is a rotary analog mechanism, is the least expensive, and has been the most popular since the first NC machines were developed. Resolvers are normally connected to the lead-screws of NC machines. Linear measurement is derived from monitoring the angle of rotation of the leadscrew and is quite accurate. Encoders also are normally connected to the leadscrew of the NC machine, and measurements are in digital form. Pulses, or a binary code in digital form, are generated by rotation of the encoder, and represent turns or partial turns of the leadscrew. These pulses are well suited to the digital NC system, and encoders have therefore become very popular with such systems. Encoders generally are somewhat more expensive than resolvers. The Inductosyn (a trade name of Farrand Controls, Inc.) also produces analog signals, but is attached to the slide or fixed part of a machine to measure the position of the table, spindlehead, or other component. The Inductosyn provides almost twice the measurement accuracy of the resolver, but is considerably more expensive, depending on the length of travel to be measured. Optical scales generally produce information in digital form and, like the Inductosyn, are attached to the slide or fixed part of the machine. Optical scale measurements are more accurate than either resolvers or encoders and, because of their digital nature, are well suited to the digital computer in a CNC system. Like the Inductosyn, optical scales are more costly than either resolvers or encoders. Open-Loop System.—A control system that issues commands to the drive motors of an NC machine and has no means of assessing the results of these commands is known as an open-loop system. In such a system, no provision is made for feedback of information concerning movement of the slide(s), or rotation of the leadscrew(s). Stepping motors are popular as drives for open-loop systems. Adaptive Control.—Measuring performance of a process and then adjusting the process to obtain optimum performance is called adaptive control. In the machine tool field, adaptive control is a means of adjusting the feed and/or speed of the cutting tool, based on sensor feedback information, to maintain optimum cutting conditions. A typical arrangement is seen in Fig. 5. Adaptive control is used primarily for cutting higher-strength materials
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such as titanium, although the concept is applicable to the cutting of any material. The costs of the sensors and software have restricted wider use of the feature.
Fig. 5.
The sensors used for adaptive control are generally mounted on the machine drive shafts, tools, or even built into the drive motor. Typically, sensors are used to provide information such as the temperature at the tip of the cutting tool and the cutting force exerted by the tool. The information measured by the sensors is used by the control system computer to analyze the cutting process and adjust the feeds and speeds of the machine to maximize the material removal rate or to optimize another process variable such as surface finish. For the computer to effectively evaluate the process in real time (i.e., while cutting is in progress), details such as maximum allowable tool temperature, maximum allowable cutting force, and information about the drive system need to be integrated into the computer program monitoring the cutting process. Adaptive control can be used to detect worn, broken, or dull tooling. Ordinarily, the adaptive control system monitors the cutting process to keep the process variables (cutting speed and feed rate, for example) within the proper range. Because the force required to machine a workpiece is lowest when the tool is new or recently resharpened, a steady increase in cutting force during a machining operation, assuming that the feed remains the same, is an indication that the tool is becoming dull (temperature may increase as well). Upon detecting cutting forces that are greater than a predetermined maximum allowable force, the control system causes the feed rate, the cutting speed, or both to be adjusted to maintain the cutting force within allowable limits. If the cutting force cannot be maintained without causing the speed and/or feed rate to be adjusted outside its allowable limits, the machine will be stopped, indicating that the tool is too dull and must be resharpened or replaced. On some systems, the process monitoring equipment can interface directly with the machine control system, as discussed above. On other systems, the adaptive control is implemented by a separate monitoring system that is independent of the machine control system. These systems include instrumentation to monitor the operations of the machine tool, but do not have the capability to directly change operating parameters, such as feeds and speeds. In addition, this type of control does not require any modification of the existing part programs for control of the machine. Flexible Manufacturing Systems (FMS).—A flexible manufacturing system (FMS) is a computer-controlled machining arrangement that can perform a variety of continuous metal-cutting operations on a range of components without manual intervention. The objective of such a system is to produce components at the lowest possible cost, especially components of which only small quantities are required. Flexibility, or the ability to switch from manufacture of one type of component to another, or from one type of machining to another, without interrupting production, is the prime requirement of such a system. In general, FMS are used for production of numbers of similar parts between 200 and 2000,
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although larger quantities are not uncommon. An FMS involves almost all the departments in a company, including engineering, methods, tooling and part programming, planning and scheduling, purchasing, sales and customer service, accounting, maintenance, and quality control. Initial costs of an FMS are estimated as being borne (percentages in parentheses) by machine tools (46.2), materials handling systems (7.7), tooling and fixtures (5.9), pallets (1.9), computer hardware (3.7), computer software (2.2), wash stations (2.8), automatic storage and retrieval systems (6.8), coolant and chip systems (2.4), spares (2), and others (18.4). FMS are claimed to bring reductions in direct labor (80–90), production planning and control (65), and inspection (70). Materials handling and shop supervision are reduced, and individual productivity is raised. In the materials field, savings are made in tooling (35), scrap and rework (65), and floor space (50). Inventory is reduced and many other costs are avoided. Intangible savings claimed to result from FMS include reduced tooling changeover time, ability to produce complex parts, to incorporate engineering changes more quickly and efficiently than with other approaches, and to make special designs, so that a company can adapt quickly to changing market conditions. Requirements for spare parts with good fit are easily met, and the lower costs combine with higher quality to improve market share. FMS also are claimed to improve morale among workers, leading to higher productivity, with less paper work and more orderly shop operations. Better control of costs and improved cost data help to produce more accurate forecasts of sales and manpower requirements. Response to surges in demand and more economical materials ordering are other advantages claimed with FMS. Completion of an FMS project is said to average 57 months, including 20 months from the time of starting investigations to the placing of the purchase order. A further 13 months are needed for delivery and a similar period for installation. Debugging and building of production takes about another 11 months before production is running smoothly. FMS are expensive, requiring large capital outlays and investments in management time, software, engineering, and shop support. Efficient operation of FMS also require constant workflow because gaps in the production cycle are very costly. Flexible Manufacturing Cell.—A flexible manufacturing cell usually consists of two or three NC machines with some form of pallet-changing equipment or an industrial robot. Prismatic-type parts, such as would be processed on a machining center, are usually handled on pallets. Cylindrical parts, such as would be machined on an NC lathe, usually are handled with an overhead type of robot. The cell may be controlled by a computer, but is often run by programmable controllers. The systems can be operated without attendants, but the mixture of parts usually must be less than with a flexible manufacturing system (FMS). Flexible Manufacturing Module.—A flexible manufacturing module is defined as a single machining center (or turning center) with some type of automatic materials handling equipment such as multiple pallets for machining centers, or robots for manipulating cylindrical parts and chucks for turning centers. The entire module is usually controlled by one or more programmable logic controllers. Axis Nomenclature.—To distinguish among the different motions, or axes, of a machine tool, a system of letter addresses has been developed. A letter is assigned, for example, to the table of the machine, another to the saddle, and still another to the spindle head. These letter addresses, or axis designations, are necessary for the electronic control system to assign movement instructions to the proper machine element. The assignment of these letter addresses has been standardized on a worldwide basis and is contained in three standards, all of which are in agreement. These standards are EIA RS-267-B, issued by the Electronics Industries Association; AIA NAS-938, issued by the Aerospace Industries Association; and ISO/R 841, issued by the International Organization for Standardization.
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The standards are based on a “right-hand rule,” which describes the orientation of the motions as well as whether the motions are positive or negative. If a right hand is laid palm up on the table of a vertical milling machine, as shown in Fig. 1, for example, the thumb will point in the positive X-direction, the forefinger in the positive Y-direction, and the erect middle finger in the positive Z-direction, or up. The direction signs are based on the motion of the cutter relative to the workpiece. The movement of the table shown in Fig. 2 is therefore positive, even though the table is moving to the left, because the motion of the cutter relative to the workpiece is to the right, or in the positive direction. The motions are considered from the part programmer's viewpoint, which assumes that the cutter always moves around the part, regardless of whether the cutter or the part moves. The right-hand rule also holds with a horizontal-spindle machine and a vertical table, or angle plate, as shown in Fig. 3. Here, spindle movement back and away from the angle plate, or workpiece, is a positive Z-motion, and movement toward the angle plate is a negative Z-motion. Rotary motions also are governed by a right-hand rule, but the fingers are joined and the thumb is pointed in the positive direction of the axis. Fig. 4 shows the designations of the rotary motions about the three linear axes, X, Y, and Z. Rotary motion about the X-axis is designated as A; rotary motion about the Y-axis is B; and rotary motion about the Z-axis is C. The fingers point in the positive rotary directions. Movement of the rotary table around the Y-axis shown in Fig. 4 is a B motion and is common with horizontal machining centers. Here, the view is from the spindle face looking toward the rotary table. Referring, again, to linear motions, if the spindle is withdrawn axially from the work, the motion is a positive Z. A move toward the work is a negative Z. When a second linear motion is parallel to another linear motion, as with the horizontal boring mill seen in Fig. 5, the horizontal motion of the spindle, or quill, is designated as Z and a parallel motion of the angle plate is W. A movement parallel to the X-axis is U and a movement parallel to the Y-axis is V. Corresponding motions are summarized as follows: Linear
Rotary
Linear and Parallel
X
A
U
Y
B
V
Z
C
W
Fig. 1.
Fig. 2.
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Fig. 3.
Fig. 4.
Axis designations for a lathe are shown in Fig. 6. Movement of the cross-slide away from the workpiece, or the centerline of the spindle, is noted as a plus X. Movement toward the workpiece is a minus X. The middle finger points in the positive Z-direction; therefore, movement away from the headstock is positive and movement toward the headstock is negative. Generally, there is no Y-movement. The machine shown in Fig. 6 is of conventional design, but most NC lathes look more like that shown in Fig. 7. The same right-hand rule applies to this four-axis lathe, on which each turret moves along its own two independent axes. Movement of the outside-diameter or upper turret, up and away from the workpiece, or spindle centerline, is a positive Xmotion, and movement toward the workpiece is a negative X-motion. The same rules apply to the U-movement of the inside-diameter, or boring, turret. Movement of the lower turret parallel to the Z-motion of the outside-diameter turret is called the W-motion. A popular lathe configuration is to have both turrets on one slide, giving a two-axis system rather than the four-axis system shown. X-and Z-motions may be addressed for either of the two heads. Upward movement of the boring head therefore is a positive X-motion.
Fig. 5.
Fig. 6.
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Fig. 7.
Axis nomenclature for other machine configurations is shown in Fig. 9. The letters with the prime notation (e.g., X′, Y′, Z′, W′, A′, and B′) mean that the motion shown is positive, because the movement of the cutter with respect to the work is in a positive direction. In these instances, the workpiece is moving rather than the cutter. Total Indicator Reading (TIR).—Total indicator reading is used as a measure of the range of machine tool error. TIR is particularly useful for describing the error in a machine tool spindle, referred to as runout. As shown in Fig. 8, there are two types of runout: axial and radial, which can be measured with a dial indicator. Axial runout refers to the wobble of a spindle and is measured at the spindle face. Radial runout is the range of movement of the spindle centerline and is measured on the side of the spindle or quill.
Fig. 8.
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Fig. 9.
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NUMERICAL CONTROL PROGRAMMING Programming.—A numerical control (NC) program is a list of instructions (commands) that completely describes, in sequence, every operation to be carried out by a machine. When a program is run, each instruction is interpreted by the machine controller, which causes an action such as starting or stopping of a spindle or coolant, changing of spindle speed or rotation, or moving a table or slide a specified direction, distance, or speed. The form that program instructions can take, and how programs are stored and/or loaded into the machine, depends on the individual machine/control system. However, program instructions must be in a form (language) that the machine controller can understand. A programming language is a system of symbols, codes, and rules that describes the manner in which program instructions can be written. One of the earliest and most widely recognized numerical control programming languages is based on the Standard ANSI/EIA RS-274-D-1980. The standard defines a recommended data format and codes for sending instructions to machine controllers. Although adherence to the standard is not mandatory, most controller manufacturers support it and most NC machine controllers (especially controllers on older NC machines using tape input) can accept data in a format that conforms, at least in part, with the recommended codes described in the RS-274-D standard. Most newer controllers also accept instructions written in proprietary formats offered (specified) by the controller's manufacturer. One of the primary benefits of a standardized programming format is easy transfer of programs from one machine to another, but even standardized code formats such as RS274-D are implemented differently on different machines. Consequently, a program written for one machine may not operate correctly on another machine without some modification of the program. On the other hand, proprietary formats are attractive because of features that are not available using the standardized code formats. For example, a proprietary format may make available certain codes that allow a programmer, with only a few lines of code, to program complex motions that would be difficult or even impossible to do in the standard language. The disadvantage of proprietary formats is that transferring programs to another machine may require a great deal of program modification or even complete rewriting. Generally, with programs written in a standardized format, the modifications required to get a program written for one machine to work on another machine are not extensive. In programming, before describing the movement of any machine part, it is necessary to establish a coordinate system(s) as a reference frame for identifying the type and direction of the motion. A description of accepted terminology used worldwide to indicate the types of motion and the orientation of machine axes is contained in a separate section (Axis Nomenclature). Part geometry is programmed with reference to the same axes as are used to describe motion. Manual data input (MDI) permits the machine operator to insert machining instructions directly into the NC machine control system via push buttons, pressure pads, knobs, or other arrangements. MDI has been available since the earliest NC machines were designed, but the method was less efficient than tape for machining operations and was used primarily for setting up the NC machine. Computer numerical control (CNC) systems, with their canned cycles and other computing capabilities, have now made the MDI concept more feasible and for some work MDI may be more practical than preparing a program. The choice depends very much on the complexity of the machining work to be done and, to a lesser degree, on the skill of the person who prepares the program. Conversational part programming is a form of MDI that requires the operator or programmer to answer a series of questions displayed on the control panel of the CNC. The operator replies to questions that describe the part, material, tool and machine settings, and machining operations by entering numbers that identify the material, blank size and thickness or diameter, tool definitions, and other required data. Depending on capability, some
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controls can select the required spindle speed and feed rate automatically by using a materials look-up table; other systems request the appropriate feed and speed data. Tool motions needed to machine a part are described by selecting a linear or circular motion programming mode and entering endpoint and intersection coordinates of lines and radius, diameter, tangent points, and directions of arcs and circles (with some controllers, intersection and tangent points are calculated automatically). Machined elements such as holes, slots, and bolt circles are entered by selecting the appropriate tool and describing its action, or with “canned routines” built into the CNC to perform specific machining operations. On some systems, if a feature is once described, it can be copied and/or moved by: translation (copy and/or move), rotation about a point, mirror image (copy and rotate about an axis), and scaling (copy and change size). On many systems, as each command is entered, a graphic image of the part or operation gives a visual check that the program is producing the intended results. When all the necessary data have been entered, the program is constructed and can be run immediately or saved on tape, floppy disk, or other storage media for later use. Conversational programming gives complete control of machine operations to the shop personnel, taking advantage of the experience and practical skills of the machine operator/programmer. Control systems that provide conversational programming usually include many built-in routines (fixed or canned cycles) for commonly used machining operations and may also have routines for specialized operations. Built-in routines speed programming because one command may replace many lines of program code that would take considerable time to write. Some built-in cycles allow complex machining operations to be programmed simply by specifying the final component profile and the starting stock size, handling such details as developing tool paths, depth of cut, number of roughing passes, and cutter speed automatically. On turning machines, built-in cycles for reducing diameters, chamfer and radius turning, and cutting threads automatically are common. Although many CNC machines have a conversational programming mode, the programming methods used and the features available are not standardized. Some control systems cannot be programmed from the control panel while another program is running (i.e., while a part is being machined), but those systems that can be thus programmed are more productive because programming does not require the machine to be idle. Conversational programming is especially beneficial In reducing programming time in shops that do most of their part programming from the control panel of the machine. Manual part programming describes the preparation of a part program by manually writing the part program in word addressed format. In the past, this method implied programming without using a computer to determine tool paths, speeds and feeds, or any of the calculations normally required to describe the geometry of a part. Today, however, computers are frequently used for writing and storing the program on disk, as well as for calculations required to program the part. Manual part programming consists of writing codes, in a format appropriate to the machine controller, that instruct the controller to perform a specific action. The most widely accepted form of coding the instructions for numerically controlled machines uses the codes and formats suggested in the ANSI/EIA RS-274-D-1980, standard. This type of programming is sometimes called G-code programming, referring to a commonly used word address used in the RS-274-D standard. Basic details of programming in this format, using the various codes available, are discussed in the next section (G-Code Programming). Computer-assisted part programming (CAPP) uses a computer to help in the preparation of the detailed instructions for operating an NC machine. In the past, defining a curve or complicated surface profile required a series of complex calculationsto describe the features in intimate detail. However, with the introduction of the microprocessor as an integral part of the CNC machine, the process of defining many complex shapes has been reduced to the simple task of calling up a canned cycle to calculate the path of the cutter. Most new CNC systems have some graphic programming capability, and many use
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graphic images of the part “drawn” on a computer screen. The part programmer moves a cutter about the part to generate the part program or the detailed block format instructions required by the control system. Machining instructions, such as the speed and feed rate, are entered via the keyboard. Using the computer as an assistant is faster and far more accurate than the manual part programming method. Computer-assisted part programming methods generally can be characterized as either language-based or graphics-based, the distinction between the two methods being primarily in the manner by which the tool paths are developed. Some modern-language-based programming systems, such as Compact II, use interactive alphanumeric input so that programming errors are detected as soon as they are entered. Many of these programming systems are completely integrated with computer graphics and display an image of the part or operation as soon as an instruction is entered. The language-based programming systems are usually based on, or are a variation of, the APT programming language, which is discussed separately within this section (APT Programming). The choice between computer-assisted part programming and manual part programming depends on the complexity of the part (particularly its geometry) and how many parts need to be programmed. The more complicated the part, the more benefit to be gained by CAPP, and if many parts are to be programmed, even if they are simple ones, the benefits of a computer-aided system are substantial. If the parts are not difficult to program but involve much repetition, computer-assisted part programming may also be preferred. If parts are to be programmed for several different control systems, a high-level part programming language such as APT will make writing the part programs easier. Because almost all machines have some deviations from standard practices, and few control systems use exactly the same programming format, a higher-level language allows the programmer to concentrate primarily on part geometry and machining considerations. The postprocessors (see Postprocessors below) for the individual control systems accommodate most of the variations in the programming required. The programmer only needs to write the program; the postprocessor deals with the machine specifics. Graphical programming involves building a two- or three-dimensional model of a part on a computer screen by graphically defining the geometric shapes and surfaces of the part using the facilities of a CAD program. In many cases, depending on features of the CAD software package, the same computer drawing used in the design and drafting stage of a project can also be used to generate the program to produce the part. The graphical entities, such as holes, slots, and surfaces, are linked with additional information required for the specific machining operations needed. Most of the cutter movements (path of the cutter), such as those needed for the generation of pockets and lathe roughing cuts, are handled automatically by the computer. The program may then sort the various machining operations into an efficient sequence so that all operations that can be performed with a particular tool are done together, if possible. The output of graphical part programming is generally an alphanumeric part programming language output file, in a format such as an APT or Compact II file. The part programming language file can be manually checked, and modified, as necessary before being run, and to help detect errors, many graphics programming systems also include some form of part verification software that simulates machining the part on the computer screen. Nongraphic data, such as feed rates, spindle speeds and coolant on/off, must be typed in by the part programmer or entered from acomputer data base at the appropriate points in the program, although some programs prompt for this information when needed. When the part program language file is run or compiled, the result is a center line data (CL data) file describing the part. With most computer-aided part programming output files, the CL data file needs to be processed through a postprocessor (see Postprocessors below) to tailor the final code produced to the actual machine being used. Postprocessor output is in a form that can be sent directly to the control system, or can be saved on tape or magnetic media and transferred to the machine tool when necessary. The
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graphic image of the part and the alphanumeric output files are saved in separate files so that either can be edited in the future if changes in the part become necessary. Revised files must be run and processed again for the part modifications to be included in the part program. Software for producing part programs is discussed further in the CAD/CAM section. Postprocessors.—A postprocessor is computer software that contains a set of computer instructions designed to tailor the cutter center line location data (CL data), developed by a computerized part programming language, to meet the requirements of a particular machine tool/system combination. Generally, when a machine tool is programmed in a graphical programming environment or any high-level language such as APT, a file is created that describes all movements required of a cutting tool to make the part. The file thus created is run, or compiled, and the result is a list of coordinates (CL data) that describes the successive positions of the cutter relative to the origin of the machine's coordinate system. The output of the program must be customized to fit the input requirements of the machine controller that will receive the instructions. Cutter location data must be converted into a format recognized by the control system, such as G codes and M codes, or into another language or proprietary format recognized by the controller. Generally, some instructions are also added or changed by the programmer at this point. The lack of standardization among machine tool control systems means that almost all computerized part programming languages require a postprocessor to translate the computer-generated language instructions into a form that the machine controller recognizes. Postprocessors are software and are generally prepared for a fee by the machine tool builder, the control system builder, a third party vendor, or by the user. G-Code Programming Programs written to operate numerical control (NC) machines with control systems that comply with the ANSI/EIA RS-274-D-1980, Standard consist of a series of data blocks, each of which is treated as a unit by the controller and contains enough information for a complete command to be carried out by the machine. Each block is made up of one or more words that indicate to the control system how its corresponding action is to be performed. A word is an ordered set of characters, consisting of a letter plus some numerical digits, that triggers a specific action of a machine tool. The first letter of the word is called the letter address of the word, and is used to identify the word to the control system. For example, X is the letter address of a dimension word that requires a move in the direction of the X-axis, Y is the letter address of another dimension word; and F is the letter address of the feed rate. The assigned letter addresses and their meanings, as listed in ANSI/EIA RS-274-D, are shown in Table 1. Format Classification.—The format classification sheet completely describes the format requirements of a control system and gives other important information required to program a particular control including: the type of machine, the format classification shorthand and format detail, a listing of specific letter address codes recognized by the system (for example, G-codes: G01, G02, G17, etc.) and the range of values the available codes may take (S range: 10 to 1800 rpm, for example), an explanation of any codes not specifically assigned by the Standard, and any other unique features of the system. The format classification shorthand is a nine- or ten-digit code that gives the type of system, the number of motion and other words available, the type and format of dimensional data required by the system, the number of motion control channels, and the number of numerically controlled axes of the system. The format detail verysuccinctly summarizes details of the machine and control system. This NC shorthand gives the letter address words and word lengths that can be used to make up a block. The format detail defines the basic features of the control system and the type of machine tool to which it refers. For example, the format detail
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Table 1. Letter Addresses Used in Numerical Control Letter Address
Description
Refers to
A
Angular dimension about the X-axis. Measured in decimal parts of a degree
Axis nomenclature
B
Angular dimension about the Y-axis. Measured in decimal parts of a degree
Axis nomenclature
C
Angular dimension about the Z-axis. Measured in decimal parts of a degree
Axis nomenclature
D
Angular dimension about a special axis, or third feed function, or tool function for selection of tool compensation
Axis nomenclature
E
Angular dimension about a special axis or second feed function
Axis nomenclature
F
Feed word (code)
Feed words
G
Preparatory word (code)
Preparatory words
H
Unassigned
I
Interpolation parameter or thread lead parallel to the X-axis
Circular interpolation and threading
J
Interpolation parameter or thread lead parallel to the Yaxis
Circular interpolation and threading
K
Interpolation parameter or thread lead parallel to the Zaxis
Circular interpolation and threading
L
Unassigned
M
Miscellaneous or auxilliary function
N
Sequence number
Sequence number
O
Sequence number for secondary head only
Sequence number
P
Third rapid-traverse dimension or tertiary-motion dimension parallel to X
Axis nomenclature
Q
Second rapid-traverse dimension or tertiary-motion dimension parallel to Y
Axis nomenclature
R
First rapid-traverse dimension or tertiary-motion dimension parallel to Z or radius for constant surface-speed calculation
Axis nomenclature Spindle speed
Miscellaneous functions
S
Spindle-speed function
T
Tool function
Tool function
U
Secondary-motion dimension parallel to X
Axis nomenclature
V
Secondary-motion dimension parallel to Y
Axis nomenclature
W
Secondary-motion dimension parallel to Z
Axis nomenclature
X
Primary X-motion dimension
Axis nomenclature
Y
Primary Y-motion dimension
Axis nomenclature
Z
Primary Z-motion dimension
Axis nomenclature
N4G2X + 24Y + 24Z + 24B24I24J24F31T4M2 specifies that the NC machine is a machining center (has X-, Y-, and Z-axes) and a tool changer with a four-digit tool selection code (T4); the three linear axes are programmed with two digits before the decimal point and four after the decimal point (X + 24Y + 24Z + 24) and can be positive or negative; probably has a horizontal spindle and rotary table (B24
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= rotary motion about the Y-axis); has circular interpolation (I24J24); has a feed rate range in which there are three digits before and one after the decimal point (F31); and can handle a four-digit sequence number (N4), two-digit G-words (G2), and two-digit miscellaneous words (M2). The sequence of letter addresses in the format detail is also the sequence in which words with those addresses should appear when used in a block. The information given in the format shorthand and format detail is especially useful when programs written for one machine are to be used on different machines. Programs that use the variable block data format described in RS-274-D can be used interchangeably on systems that have the same format classification, but for complete program compatibility between machines, other features of the machine and control system must also be compatible, such as the relationships of the axes and the availability of features and control functions. Control systems differ in the way that the numbers may be written. Most newer CNC machines accept numbers written in a decimal-point format, however, some systems require numbers to be in a fixed-length format that does not use an explicit decimal point. In the latter case, the control system evaluates a number based on the number of digits it has, including zeros. Zero suppression in a control system is an arrangement that allows zeros before the first significant figure to be dropped (leading zero suppression) or allows zeros after the last significant figure to be dropped (trailing zero suppression). An X-axis movement of 05.3400, for example, could be expressed as 053400 if represented in the full field format, 53400 (leading zero suppression), or 0534 (trailing zero suppression). With decimal-point programming, the above number is expressed simply as 5.34. To ensure program compatibility between machines, all leading and trailing zeros should be included in numbers unless decimal-point programming is used. Sequence Number (N-Word).—A block normally starts with a sequence number that identifies the block within the part program. Most control systems use a four-digit sequence number allowing step numbers up to N9999. The numbers are usually advanced by fives or tens in order to leave spaces for additional blocks to be inserted later if required. For example, the first block in a program would be N0000, the next block N0005; the next N0010; and so on. The slash character, /, placed in a block, before the sequence number, is called an optional stop and causes the block to be skipped over when actuated by the operator. The block that is being worked on by the machine is often displayed on a digital readout so that the operator may know the precise operation being performed. Preparatory Word (G-Word).—A preparatory word (also referred to as a preparatory function or G-code) consists of the letter address G and usually two digits. The preparatory word is placed at the beginning of a block, normally following the sequence number. Most newer CNC machines allow more than one G-code to be used in a single block, although many of the older systems do not. To ensure compatability with older machines and with the RS-274-D Standard, only one G-code per block should be used. The G-word indicates to the control system how to interpret the remainder of theblock. For example, G01 refers to linear interpolation and indicates that the words following in the block will move the cutter in a straight line. The G02 code indicates that the words following in the block will move the cutter in a clockwise circular path. A G-word can completely change the normal meaning of other words in a block. For example, X is normally a dimension word that describes a distance or position in the X-direction. However, if a block contains the G04 word, which is the code for a dwell, the X word represents the time, in seconds, that the machine is to dwell. The majority of G-codes are designated as modal, which means that once used, the code remains in effect for succeeding blocks unless it is specifically changed or canceled. Therefore, it is not necessary to include modal G-codes in succeeding blocks except to change or cancel them. Unless a G-code is modal, it is only effective within its designated block for the operation it defines. Table 2, G-Code Addresses, lists standardized G-code addresses and modality.
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Table 2. G-Code Addresses Code G00 G01
Description ab * Rapid traverse, point to point (M,L) abc Linear interpolation (M,L)
G02
abc
G03
abc
G04
ab
G05
ab
G06
abc
G07
c
G08
ab
G09
ab
G10–G12
ab
G13–G16 G13–G16
Circular interpolation — clockwise movement (M,L)
Code G34
ab*
G35
abc
G36-G39 G36
ab c
Circular interpolation—counterclockwise movement (M,L) Dwell—a programmed time delay (M,L) Unassigned
G37, G37.1, G37.2, G37.3 G37.4
Parabolic interpolation (M,L)
G38
Used for programming with cylindrical diameter values (L) Programmed acceleration (M,L). d Also for lathe programming with cylindrical diameter values Programmed deceleration (M,L). d Used to stop the axis movement at a precise location (M,L)
G38.1
Description Thread cutting, increasing lead (L) Thread cutting, decreasing lead (L) Permanently unassigned Used for automatic acceleration and deceleration when the blocks are short (M,L) Used for tool gaging (M,L)
Used for probing to measure the diameter and center of a hole (M) Used with a probe to measure the parallelness of a part with respect to an axis (M)
G39, G39.1
Generates a nonprogrammed block to improve cycle time and corner cutting quality when used with cutter compensation (M) Tool tip radius compensation used with linear generated block (L) Tool tip radius compensation used used with circular generated block (L)
G39 G39.1
ac
Unassigned. dSometimes used for machine lock and unlock devices Axis selection (M,L)
G40
abc
b
Unassigned
G41
abc
Cancel cutter compensation/ offset (M) Cutter compensation, left (M)
abc
Cutter compensation, right (M)
G14, G14.1
Used for computing lines and circle intersections (M,L) Used for scaling (M,L)
G42
c
G43
abc
Cutter offset, inside corner (M,L)
G15–G16
c
G44
abc
G15, G16.1
c
Cutter offset, outside corner (M,L) Unassigned
G13
G16.2 G17–G19
c abc
G20 G22–G32
ab
G22–G23
c
G22.1, G233.1
c
G24
c
G27–G29
G30 G31, G31.1, G31.2, G31.3, G31.4 G33
abc
Polar coordinate programming (M) Cylindrical interpolation—C axis (L) End face milling—C axis (L)
G45–G49 G50–G59
ab a
Reserved for adaptive control (M,L) Unassigned
X-Y, X-Z, Y-Z plane selection, respectively (M,L) Unassigned
G50 G50.1
c
Cancel mirror image (M,L)
Unassigned
G51.1
c
Program mirror image (M,L)
Defines safety zones in which the machine axis may not enter (M,L) Defines safety zones in which the cutting tool may not exit (M,L) Single-pass rough-facing cycle (L) Used for automatically moving to and returning from home position (M,L)
G52
b
Unassigned
Return to an alternate home position (M,L) External skip function, moves an axis on a linear path until an external signal aborts the move (M,L) Thread cutting, constant lead (L)
bb
G52 G53 G53 G54–G59 G54–G59.3 G60–G62
bc c bc c abc
Used to offset the axes with respect to the coordinate zero point (see G92) (M,L) Datum shift cancel Call for motion in the machine coordinate system (M,L) Datum shifts (M,L) Allows for presetting of work coordinate systems (M,L) Unassigned
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Code G61
G62 G63 G63 G64–G69 G64
c
c
a bc abc c
G65
c
G66
c
G66.1
c
G67
c
G68
c
G69
c
G70 G71 G72
abc
G72 G72
b
G73 G73
abc ac
c
b c
G74
ac
G74
bc
G74
c
G74 G75
ac
G75 G75
b
G76–G79
ab
Description Modal equivalent of G09 except that rapid moves are not taken to a complete stop before the next motion block is executed (M,L) Automatic corner override, reduces the feed rate on an inside corner cut (M,L) Unassigned Tapping mode (M,L) Unassigned Cutting mode, usually set by the system installer (M,L) Calls for a parametric macro (M,L) Calls for a parametric macro. Applies to motion blocks only (M,L)
Code
Description Cancel fixed cycles
G80
abc
G81
abc
Drill cycle, no dwell and rapid out (M,L)
G82
abc
Drill cycle, dwell and rapid out (M,L)
G83
abc
G84 G84.1 G85
abc
G86
abc
G87
abc
Deep hole peck drilling cycle (M,L) Right-hand tapping cycle (M,L) Left-hand tapping cycle (M,L) Boring cycle, no dwell, feed out (M,L) Boring cycle, spindle stop, rapid out (M,L) Boring cycle, manual retraction (M,L)
G88
abc
Same as G66 but applies to all blocks (M,L) Stop the modal parametric macro (see G65, G66, G66.1) (M,L) Rotates the coordinate system (i.e., the axes) (M)
G88.1
Cancel axes rotation (M)
G88.4
c abc
G88.2 G88.3
Boring cycle, spindle stop, manual retraction (M,L) Pocket milling (rectangular and circular), roughing cycle (M) Pocket milling (rectangular and circular), finish cycle (M) Post milling, roughs out material around a specified area (M) Post milling, finish cuts material around a post (M) Hemisphere milling, roughing cycle (M) Hemisphere milling, finishing cycle (M)
Inch programming (M,L) Metric programming (M,L) Circular interpolation CW (three-dimensional) (M) Unassigned Used to perform the finish cut on a turned part along the Z-axis after the roughing cuts initiated under G73, G74, or G75 codes (L) Unassigned Deep hole peck drilling cycle (M); OD and ID roughing cycle, running parallel to the Z-axis (L) Cancel multiquadrant circular interpolation (M,L) Move to home position (M,L)
G88.5
G90
abc
Absolute dimension input (M,L)
G91
abc
Left-hand tapping cycle (M)
G92
abc
Rough facing cycle (L)
G93
abc
Multiquadrant circular interpolation (M,L) Unassigned Roughing routine for castings or forgings (L) Unassigned
G94
c
G95
abc
G96
abc
G97
abc
Incremental dimension input (M,L) Preload registers, used to shift the coordinate axes relative to the current tool position (M,L) Inverse time feed rate (velocity/distance) (M,L) Feed rate in inches or millimeters per minute (ipm or mpm) (M,L) Feed rate given directly in inches or millimeters per revolution (ipr or mpr) (M,L) Maintains a constant surface speed, feet (meters) per minute (L) Spindle speed programmed in rpm (M,L) Unassigned
G88.6
G89
abc
G89.1
G89.2
G98–99
Boring cycle, dwell and feed out (M,L) Irregular pocket milling, roughing cycle (M)
Irregular pocket milling, finishing cycle (M)
ab
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a Adheres to ANSI/EIA RS-274-D; b Adheres to ISO 6983/1,2,3 Standards; where both symbols appear together, the ANSI/EIA and ISO standard codes are comparable; c This code is modal. All codes that are not identified as modal are nonmodal, when used according to the corresponding definition. d Indicates a use of the code that does not conform with the Standard. Symbols following a description: (M) indicates that the code applies to a mill or machining center; (L) indicates that the code applies to turning machines; (M,L) indicates that the code applies to both milling and turning machines. Codes that appear more than once in the table are codes that are in common use, but are not defined by the Standard or are used in a manner that is different than that designated by the Standard (e.g., see G61).
Most systems that support the RS-274-D Standard codes do not use all the codes available in the Standard. Unassigned G-words in the Standard are often used by builders of machine tool control systems for a variety of special purposes, sometimes leading to confusion as to the meanings of unassigned codes. Even more confusing, some builders of systems and machine tools use the less popular standardized codes for other than the meaning listed in the Standard. For these reasons, machine code written specifically for one machine/controller will not necessarily work correctly on another machine controller without modification. Dimension words contain numerical data that indicate either a distance or a position. The dimension units are selected by using G70 (inch programming) or G71 (metric programming) code. G71 is canceled by a G70 command, by miscellaneous functions M02 (end of program), or by M30 (end of data). The dimension words immediately follow the G-word in a block and on multiaxis machines should be placed in the following order: X, Y, Z, U, V, W, P, Q, R, A, B, C, D, and E. Absolute programming (G90) is a method of defining the coordinate locations of points to which the cutter (or workpiece) is to move based on the fixed machine zero point. In Fig. 1, the X − Y coordinates of P1 are X = 1.0, Y = 0.5 and the coordinates of P2 are X = 2.0, Y = 1.1. To indicate the movement of the cutter from one point to another when using the absolute coordinate system, only the coordinates of the destination point P2 are needed. Incremental programming (G91) is a method of identifying the coordinates of a particular location in terms of the distance of the new location from the current location. In the example shown in Fig. 2, a move from P1 to P2 is written as X + 1.0, Y + 0.6. If there is no movement along the Z-axis, Z is zero and normally is not noted. An X − Y incremental move from P2 to P3 in Fig. 2 is written as X + 1.0, Y − 0.7.
Fig. 1.
Fig. 2.
Most CNC systems offer both absolute and incremental part programming. The choice is handled by G-code G90 for absolute programming and G91 for incremental programming. G90 and G91 are both modal, so they remain in effect until canceled.
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The G92 word is used to preload the registers in the control system with desired values. A common example is the loading of the axis-position registers in the control system for a lathe. Fig. 3 shows a typical home position of the tool tip with respect to the zero point on the machine. The tool tip here is registered as being 15.0000 inches in the Z-direction and 4.5000 inches in the X-direction from machine zero. No movement of the tool is required. Although it will vary with different control system manufacturers, the block to accomplish the registration shown in Fig. 3 will be approximately: N0050 G92 X4.5 Z15.0 Miscellaneous Functions (M-Words).—Miscellaneous functions, or M-codes, also referred to as auxiliary functions, constitute on-off type commands. M functions are used to control actions such as starting and stopping of motors, turning coolant on and off, changing tools, and clamping and unclamping parts. M functions are made up of the letter M followed by a two-digit code. Table 3 lists the standardized M-codes, however, the functions available will vary from one control system to another. Most systems provide fewer M functions than the complete list and may use some of the unassigned codes to provide additional functions that are not covered by the Standard. If an M-code is used in a block, it follows the T-word and is normally the last word in the block. Table 3. Miscellaneous Function Words from ANSI/EIA RS-274-D Code
Description
M00
Automatically stops the machine. The operator must push a button to continue with the remainder of the program. An optional stop acted upon only when the operator has previously signaled for this command by pushing a button. The machine will automatically stop when the control system senses the M01 code. This end-of-program code stops the machine when all commands in the block are completed. May include rewinding of tape. Start spindle rotation in a clockwise direction—looking out from the spindle face. Start spindle rotation in a counterclockwise direction—looking out from the spindle face. Stop the spindle in a normal and efficient manner. Command to change a tool (or tools) manually or automatically. Does not cover tool selection, as is possible with the T-words. M07 (coolant 2) and M08 (coolant 1) are codes to turn on coolant. M07 may control flood coolant and M08 mist coolant. Shuts off the coolant. M10 applies to automatic clamping of the machine slides, workpiece, fixture spindle, etc. M11 is an unclamping code. An inhibiting code used to synchronize multiple sets of axes, such as a four-axis lathe having two independently operated heads (turrets). Starts CW spindle motion and coolant on in the same command. Starts CCW spindle motion and coolant on in the same command. Rapid traverse of feed motion in either the +(M15) or −(M16) direction. Unassigned. Oriented spindle stop. Causes the spindle to stop at a predetermined angular position. Permanently unassigned. An end-of-tape code similar to M02, but M30 will also rewind the tape; also may switch automatically to a second tape reader. A command known as interlock bypass for temporarily circumventing a normally provided interlock.
M01
M02 M03 M04 M05 M06 M07 to M08 M09 M10 to M11 M12 M13 M14 M15 to M16 M17 to M18 M19 M20 to M29 M30 M31
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Table 3. (Continued) Miscellaneous Function Words from ANSI/EIA RS-274-D Code M32 to M35 M36 to M39 M40 to M46 M47 M48 to M49 M50 to M57 M58 to M59 M60 to M89 M90 to M99
Description Unassigned. Permanently unassigned. Used to signal gear changes if required at the machine; otherwise, unassigned. Continues program execution from the start of the program unless inhibited by an interlock signal. M49 deactivates a manual spindle or feed override and returns the parameter to the programmed value; M48 cancels M49. Unassigned. Holds the rpm constant at the value in use when M59 is initiated; M58 cancels M59. Unassigned. Reserved for use by the machine user.
Feed Function (F-Word).—F-word stands for feed-rate word or feed rate. The meaning of the feed word depends on the system of units in use and the feed mode. For example, F15 could indicate a feed rate of 0.15 inch (or millimeter) per revolution or 15 inches (or millimeters) per minute, depending on whether G70 or G71 is used to indicate inch or metric programming and whether G94 or G95 is used to specify feed rate expressed as inches (or mm) per minute or revolution. The G94 word is used to indicate inches/minute (ipm) or millimeters/minute (mmpm) and G95 is used for inches/revolution (ipr) or millimeters/revolution (mmpr). The default system of units is selected by G70 (inch programming) or G71 (metric programming) prior to using the feed function. The feed function is modal, so it stays in effect until it is changed by setting a new feed rate. In a block, the feed function is placed immediately following the dimension word of the axis to which it applies or immediately following the last dimension word to which it applies if it is used for more than one axis.
Fig. 3.
In turning operations, when G95 is used to set a constant feed rate per revolution, the spindle speed is varied to compensate for the changing diameter of the work — the spindle speed increases as the working diameter decreases. To prevent the spindle speed from increasing beyond a maximum value, the S-word, see Spindle Function (S-Word), is used to specify the maximum allowable spindle speed before issuing the G95 command. If the spindle speed is changed after the G95 is used, the feed rate is also changed accordingly. If G94 is used to set a constant feed per unit of time (inches or millimeters per minute), changes in the spindle speed do not affect the feed rate. Feed rates expressed in inches or millimeters per revolution can be converted to feed rates in inches or millimeters per minute by multiplying the feed rate by the spindle speed in revolutions per minute: feed/minute = feed/revolution × spindle speed in rpm. Feed rates for milling cutters are sometimes given in inches or millimeters per tooth. To convert feed
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per tooth to feed per revolution, multiply the feed rate per tooth by the number of cutter teeth: feed/revolution = feed/tooth × number of teeth. For certain types of cuts, some systems require an inverse-time feed command that is the reciprocal of the time in minutes required to complete the block of instructions. The feed command is indicated by a G93 code followed by an F-word value found by dividing the feed rate, in inches (millimeters) or degrees per minute, by the distance moved in the block: feed command = feed rate/distance = (distance/time)/distance = 1/time. Feed-rate override refers to a control, usually a rotary dial on the control system panel, that allows the programmer or operator to override the programmed feed rate. Feed-rate override does not change the program; permanent changes can only be made by modifying the program. The range of override typically extends from 0 to 150 per cent of the programmed feed rate on CNC machines; older hardwired systems are more restrictive and most cannot be set to exceed 100 per cent of the preset rate. Spindle Function (S-Word).—An S-word specifies the speed of rotation of the spindle. The spindle function is programmed by the address S followed by the number of digits specified in the format detail (usually a four-digit number). Two G-codes control the selection of spindle speed input: G96 selects a constant cutting speed in surface feet per minute (sfm) or meters per minute (mpm) and G97 selects a constant spindle speed in revolutions per minute (rpm). In turning, a constant spindle speed (G97) is applied for threading cycles and for machining parts in which the diameter remains constant. Feed rate can be programmed with either G94 (inches or millimeters per minute) or G95 (inches or millimeters per revolution) because each will result in a constant cutting speed to feed relationship. G96 is used to select a constant cutting speed (i.e., a constant surface speed) for facing and other cutting operations in which the diameter of the workpiece changes. The spindle speed is set to an initial value specified by the S-word and then automatically adjusted as the diameter changes so that a constant surface speed is maintained. The control system adjusts spindle speed automatically, as the working diameter of the cutting tool changes, decreasing spindle speed as the working diameter increasesor increasing spindle speed as the working diameter decreases. When G96 is used for a constant cutting speed, G95 in a succeeding block maintains a constant feed rate per revolution. Speeds given in surface feet or meters per minute can be converted to speeds in revolutions per minute (rpm) by the formulas: sfm × 12rpm = -------------------π×d
mpm × 1000rpm = ----------------------------π×d
where d is the diameter, in inches or millimeters, of the part on a lathe or of the cutter on a milling machine; and π is equal to 3.14159. Tool Function (T-Word).—The T-word calls out the tool that is to be selected on a machining center or lathe having an automatic tool changer or indexing turret. On machines without a tool changer, this word causes the machine to stop and request a tool change. This word also specifies the proper turret face on a lathe. The word usually is accompanied by several numbers, as in T0101, where the first pair of numbers refers to the tool number (and carrier or turret if more than one) and the second pair of numbers refers to the tool offset number. Therefore, T0101 refers to tool 1, offset 1. Information about the tools and the tool setups is input to the CNC system in the form of a tool data table. Details of specific tools are transferred from the table to the part program via the T-word. The tool nose radius of a lathe tool, for example, is recorded in the tool data table so that the necessary tool path calculations can be made by the CNC system. The miscellaneous code M06 can also be used to signal a tool change, either manually or automatically.
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Compensation for variations in the tool nose radius, particularly on turning machines, allows the programmer to program the part geometry from the drawing and have the tool follow the correct path in spite of variations in the tool nose shape. Typical of the data required, as shown in Fig. 4, are the nose radius of the cutter, the X and Z distances from the gage point to some fixed reference point on the turret, and the orientation of the cutter (tool tip orientation code), as shown in Fig. 5. Details of nose radius compensation for numerical control is given in a separate section (Indexable Insert Holders for NC).
Fig. 4.
Fig. 5.
Tool offset, also called cutter offset, is the amount of cutter adjustment in a direction parallel to the axis of a tool. Tool offset allows the programmer to accommodate the varying dimensions of different tooling by assuming (for the sake of the programming) that all the tools are identical. The actual size of the tool is totally ignored by the programmer who programs the movement of the tools to exactly follow the profile of theworkpiece shape. Once tool geometry is loaded into the tool data table and the cutter compensation controls of the machine activated, the machine automatically compensates for the size of the tools in the programmed movements of the slide. In gage length programming, the tool length and tool radius or diameter are included in the program calculations. Compensation is then used only to account for minor variations in the setup dimensions and tool size.
Fig. 6.
Customarily, the tool offset is used in the beginning of a program to initialize each individual tool. Tool offset also allows the machinist to correct for conditions, such as tool wear, that would cause the location of the cutting edge to be different from the programmed location. For example, owing to wear, the tool tip in Fig. 6 is positioned a distance of 0.0065 inch from the location required for the work to be done. To compensate for this wear, the operator (or part programmer), by means of the CNC control panel, adjusts the tool tip with reference to the X- and Z-axes, moving the tool closer to the work by
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0.0065 inch throughout its traverse. The tool offset number causes the position of the cutter to be displaced by the value assigned to that offset number.
Fig. 7.
Fig. 8.
Changes to the programmed positions of cutting tool tip(s) can be made by tool length offset programs included in the control system. A dial or other means is generally provided on milling, drilling, and boring machines, and machining centers, allowing the operator or part programmer to override the programmed axial, or Z-axis, position. This feature is particularly helpful when setting the lengths of tools in their holders or setting a tool in a turret, as shown in Fig. 7, because an exact setting is not necessary. The tool can be set to an approximate length and the discrepancy eliminated by the control system. The amount of offset may be determined by noting the amount by which the cutter is moved manually to a fixed point on the fixture or on the part, from the programmed Z-axis location. For example, in Fig. 7, the programmed Z-axis motion results in the cutter being moved to position A, whereas the required location for the tool is at B. Rather than resetting the tool or changing the part program, the tool length offset amount of 0.0500 inch is keyed into the control system. The 0.0500-inch amount is measured by moving the cutter tip manually to position B and reading the distance moved on the readout panel. Thereafter, every time that cutter is brought into the machining position, the programmed Z-axis location will be overridden by 0.0500 inch. Manual adjustment of the cutter center path to correct for any variance between nominal and actual cutter radius is called cutter compensation. The net effect is to move the path of the center of the cutter closer to, or away from, the edge of the workpiece, as shown in Fig. 8. The compensation may also be handled via a tool data table. When cutter compensation is used, it is necessary to include in the program a G41 code if the cutter is to be to the left of the part and a G42 code if to the right of the part, as shown in Fig. 8. A G40 code cancels cutter compensation. Cutter compensation with earlier hardwire systems was expensive, very limited, and usually held to ±0.0999 inch. The range for cutter compensation with CNC control systems can go as high as ±999.9999 inches, although adjustments of this magnitude are unlikely to be required.
Fig. 9.
Linear Interpolation.—The ability of the control system to guide the workpiece along a straight-line path at an angle to the slide movements is called linear interpolation. Move-
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ments of the slides are controlled through simultaneous monitoring of pulses by the control system. For example, if monitoring of the pulses for the X-axis of a milling machine is at the same rate as for the Y-axis, the cutting tool will move at a 45-degree angle relative to the X-axis. However, if the pulses are monitored at twice the rate for the X-axis as for the Yaxis, the angle that the line of travel will make with the X-axis will be 26.57 degrees (tangent of 26.57 degrees = 1⁄2), as shown in Fig. 9. The data required are the distances traveled in the X- and Y-directions, and from these data, the control system will generate the straight line automatically. This monitoring concept also holds for linear motions along three axes. The required G-code for linear interpolation blocks is G01. The code is modal, which means that it will hold for succeeding blocks until it is changed. Circular Interpolation.—A simplified means of programming circular arcs in one plane, using one block of data, is called circular interpolation. This procedure eliminates the need to break the arc into straight-line segments. Circular interpolation is usually handled in one plane, or two dimensions, although three-dimensional circular interpolation is described in the Standards. The plane to be used is selected by a G or preparatory code. In Fig. 10, G17 is used if the circle is to be formed in the X−Y plane,
Fig. 10.
Fig. 11.
G18 if in the X−Z plane, and G19 if in the Y−Z plane. Often the control system is preset for the circular interpolation feature to operate in only one plane (e.g., the X−Y plane for milling machines or machining centers or the X−Z plane for lathes), and for these machines, the G-codes are not necessary. A circular arc may be described in several ways. Originally, the RS-274 Standard specified that, with incremental programming, the block should contain: 1) A G-code describing the direction of the arc, G02 for clockwise (CW), and G03 for counterclockwise (CCW). 2) Directions for the component movements around the arc parallel to the axes. In the example shown in Fig. 11, the directions are X = +1.1 inches and Y = +1.0 inch. The signs are determined by the direction in which the arc is being generated. Here, both X and Y are positive. 3) The I dimension, which is parallel to the X-axis with a value of 1.3 inches, and the J dimension, which is parallel to the Y-axis with a value of 0.3 inch. These values, which locate point A with reference to the center of the arc, are called offset dimensions. The block for this work would appear as follows: N0025 G02 X011000 Y010000 I013000 J003000 (The sequence number, N0025, is arbitrary.) The block would also contain the plane selection (i.e., G17, G18, or G19), if this selection is not preset in the system. Most of the newer control systems allow duplicate words in the
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same block, but most of the older systems do not. In these older systems, it is necessary to insert the plane selection code in a separate and prior block, for example, N0020 G17. Another stipulation in the Standard is that the arc is limited to one quadrant. Therefore, four blocks would be required to complete a circle. Four blocks would also be required to complete the arc shown in Fig. 12, which extends into all four quadrants. When utilizing absolute programming, the coordinates of the end point are described. Again from Fig. 11, the block, expressed in absolute coordinates, appears as: N0055 G02 X01800 Y019000 I013000 J003000 where the arc is continued from a previous block; the starting point for the arc in this block would be the end point of the previous block.
Fig. 12.
Fig. 13.
The Standard still contains the format discussed, but simpler alternatives have been developed. The latest version of the Standard (RS-274-D) allows multiple quadrant programming in one block, by inclusion of a G75 word. In the absolute-dimension mode (G90), the coordinates of the arc center are specified. In the incremental-dimension mode (G91), the signed (plus or minus) incremental distances from the beginning point of the arc to the arc center are given. Most system builders have introduced some variations on this format. One system builder utilizes the center and the end point of the arc when in an absolute mode, and might describe the block for going from A to B in Fig. 13 as: N0065 G75 G02 X2.5 Y0.7 I2.2 J1.6 The I and the J words are used to describe the coordinates of the arc center. Decimal-point programming is also used here. A block for the same motion when programmed incrementally might appear as: N0075 G75 G02 X1.1 Y − 1.6 I0.7 J0.7 This approach is more in conformance with the RS-274-D Standard in that the X and Y values describe the displacement between the starting and ending points (points A and B), and the I and J indicate the offsets of the starting point from the center. Another and even more convenient way of formulating a circular motion block is to note the coordinates of the ending point and the radius of the arc. Using absolute programming, the block for the motion in Fig. 13 might appear as: N0085 G75 G02 X2.5 Y0.7 R10.0 The starting point is derived from the previous motion block. Multiquadrant circular interpolation is canceled by a G74 code. Helical and Parabolic Interpolation.—Helical interpolation is used primarily for milling large threads and lubrication grooves, as shown in Fig. 14. Generally, helical interpolation involves motion in all three axes (X, Y, Z) and is accomplished by using circular
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interpolation (G02 or G03) while changing the third dimension. Parabolic interpolation (G06) is simultaneous and coordinated control of motion-such that the resulting cutter path describes part of a parabola. The RS-274-D Standard provides further details. Subroutine.—A subroutine is a set of instructions or blocks that can be inserted into a program and repeated whenever required. Parametric subroutines permit letters or symbols to be inserted into the program in place of numerical values (see Parametric Expressions and Macros). Parametric subroutines can be called during part programming and values assigned to the letters or symbols. This facility is particularly helpful when dealing with families of parts. A subprogram is similar to a subroutine except that a subprogram is not wholly contained within another program, as is a subroutine. Subprograms are used when it is necessary to perform the same task frequently, in different programs. The advantage of subprograms over subroutines is that subprograms may be called by any other program, whereas the subroutine can only be called by the program that contains the subroutine. There is no standard subroutine format; however, the example below is typical of a program that might be used for milling the three pockets shown in Fig. 15. In the example, the beginning and end of the subroutine are indicated by the codes M92 and M93, respectively, and M94 is the code that is used to call the subroutine. The codes M92, M93, and M94 are not standardized (M-codes M90 through M99 are reserved for the user) and may be different from control system to control system. The subroutine functions may use different codes or may not be available at all on other systems. N0010 G00 X.6 Y.85
Cutter is moved at a rapid traverse rate to a position over the corner of the first pocket to be cut.
N0020 M92
Tells the system that the subroutine is to start in the next block.
N0030 G01 Z−.25 F2.0
Cutter is moved axially into the workpiece 0.25 inch at 2.0 ipm.
N0040 X.8
Cutter is moved to the right 0.8 inch.
N0050 Y.2
Cutter is moved laterally up 0.2 inch.
N0060 X−.8
Cutter is moved to the left 0.8 inch.
N0070 Y.2
Cutter is moved laterally up 0.2 inch.
Fig. 14.
Fig. 15.
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N0080 X.8
Cutter is moved to the right 0.8 inch.
N0090 G00 Z.25 M93
Cutter is moved axially out of pocket at rapid traverse rate. Last block of subroutine is signaled by word M93.
N0100 X.75 Y.5
Cutter is moved to bottom left-hand corner of second pocket at rapid traverse rate.
N0110 M94 N0030
Word M94 calls for repetition of the subroutine that starts at sequence number N0030 and ends at sequence number N0090.
N0120 G00 X.2 Y−I.3
After the second pocket is cut by repetition of sequence numbers N0030 through N0090, the cutter is moved to start the third pocket.
N0130 M94 N0030
Repetition of subroutine is called for by word M94 and the third pocket is cut.
Parametric Expressions and Macros.—Parametric programming is a method whereby a variable or replaceable parameter representing a value is placed in the machining code instead of using the actual value. In this manner, a section of code can be used several or many times with different numerical values, thereby simplifying the programming and reducing the size of the program. For example, if the values of X and Y in lines N0040 to N0080 of the previous example are replaced as follows: N0040 X#1 N0050 Y#2 N0060 X#3 N0070 Y#4 then the subroutine starting at line N0030 is a parametric subroutine. That is, the numbers following the # signs are the variables or parameters that will be replaced with actual values when the program is run. In this example, the effect of the program changes is to allow the same group of code to be used for milling pockets of different sizes. If on the other hand, lines N0010, N0100, and N0120 of the original example were changed in a similar manner, the effect would be to move the starting location of each of the slots to the location specified by the replaceable parameters. Before the program is run, the values that are to be assigned to each of the parameters or variables are entered as a list at the start of the part program in this manner: #1 = .8 #2 = .2 #3 = .8 #4 = .2 All that is required to repeat the same milling process again, but this time creating a different size pocket, is to change the values assigned to each of the parameters #1, #2, #3, and #4 as necessary. Techniques for using parametric programming are not standardized and are not recognized by all control systems. For this reason, consult the programming manual of the particular system for specific details.
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As with a parametric subroutine, macro describes a type of program that can be recalled to allow insertion of finite values for letter variables. The difference between a macro and a parametric subroutine is minor. The term macro normally applies toa source program that is used with computer-assisted part programming; the parametric subroutine is a feature of the CNC system and can be input directly into that system. Conditional Expressions.—It is often useful for a program to make a choice between two or more options, depending on whether or not a certain condition exists. A program can contain one or more blocks of code that are not needed every time the program is run, but are needed some of the time. For example, refer to the previous program for milling three slots. An occasion arises that requires that the first and third slots be milled, but not the second one. If the program contained the following block of code, the machine could be easily instructed to skip the milling of the second slot: N0095 IF [#5 EQ 0] GO TO N0120 In this block, #5 is the name of a variable; EQ is a conditional expression meaning equals; and GO TO is a branch statement meaning resume execution of the program at the following line number. The block causes steps N0100 and N0110 of the program to be skipped if the value of #5 (a dummy variable) is set equal to zero. If the value assigned to #5 is any number other than zero, the expression (#5 EQ 0) is not true and the remaining instructions in block N0095 are not executed. Program execution continues with the next step, N0100, and the second pocket is milled. For the second pocket to be milled, parameter #5 is initialized at the beginning of the program with a statement such as #5 = 1 or #5 = 2. Initializing #5 = 0 guarantees that the pocket is not machined. On control systems that automatically initialize all variables to zero whenever the system is reset or a program is loaded, the second slot will not be machined unless the #5 is assigned a nonzero value each time the program is run. Other conditional expressions are: NE = not equal to; GT = greater than; LT = less than; GE = greater than or equal to; and LE = less than or equal to. As with parametric expressions, conditional expressions may not be featured on all machines and techniques and implementation will vary. Therefore, consult the control system programming manual for the specific command syntax. Fixed (Canned) Cycles.—Fixed (canned) cycles comprise sets of instructions providing for a preset sequence of events initiated by a single command or a block of data. Fixed cycles generally are offered by the builder of the control system or machine tool as part of the software package that accompanies the CNC system. Limited numbers of canned cycles began to appear on hardwire control systems shortly before their demise. The canned cycles offered generally consist of the standard G-codes covering driling, boring, and tapping operations, plus options that have been developed by the system builder such as thread cutting and turning cycles. (See Thread Cutting and Turning Cycles.) Some standard canned cycles included in RS-274-D are shown herewith. A block of data that might be used to generate the cycle functions is also shown above each illustration. Although the G-codes for the functions are standardized, the other words in the block and the block format are not, and different control system builders have different arrangements. The blocks shown are reasonable examples of fixed cycles and do not represent those of any particular system builder.
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The G81 block for a simple drilling cycle is: N_____ G81 X_____Y_____C_____D_____F_____EOB N_____X_____Y_____EOB
This G81 drilling cycle will move the drill point from position A to position B and then down to C at a rapid traverse rate; the drill point will next be fed from C to D at the programmed feed rate, then returned to C at the rapid traverse rate. If the cycle is to be repeated at a subsequent point, such as point E in the illustration, it is necessary Only to give the required X and Y coordinates. This repetition capability is typical of canned cycles. The G82 block for a spotfacing or drilling cycle with a dwell is: N_____G82 X_____Y_____C_____D_____T_____F_____EOB
This G82 code produces a cycle that is very similar to the cycle of the G81 code except for the dwell period at point D. The dwell period allows the tool to smooth out the bottom of the counterbore or spotface. The time for the dwell, in seconds, is noted as a T-word. The G83 block for a peck-drilling cyle is: N_____G83 X_____Y_____C_____D_____K_____F_____EOB
In the G83 peck-drilling cycle, the drill is moved from point A to point B and then to point C at the rapid traverse rate; the drill is then fed the incremental distance K, followed by
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rapid return to C. Down feed again at the rapid traverse rate through the distance K is next, after which the drill is fed another distance K. The drill is thenrapid traversed back to C, followed by rapid traverse for a distance of K + K; down feed to D follows before the drill is rapid traversed back to C, to end the cycle. The G84 block for a tapping cycle is: N_____G84 X_____Y_____C_____D_____F_____EOB
The G84 canned tapping cycle starts with the end of the tap being moved from point A to point B and then to point C at the rapid traverse rate. The tap is then fed to point D, reversed, and moved back to point C. The G85 block for a boring cycle with tool retraction at the feed rate is: N_____G85 X_____Y_____C_____D_____F_____EOB
In the G85 boring cycle, the tool is moved from point A to point B and then to point C at the rapid traverse rate. The tool is next fed to point D and then, while still rotating, is moved back to point C at the same feed rate. The G86 block for a boring cycle with rapid traverse retraction is: N_____G86 X_____Y_____C_____D_____F_____EOB
The G86 boring cycle is similar to the G85 cycle except that the tool is withdrawn at the rapid traverse rate.
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The G87 block for a boring cycle with manual withdrawal of the tool is: N_____G87 X_____Y_____C_____D_____F_____EOB
In the G87 canned boring cycle, the cutting tool is moved from A to B and then to C at the rapid traverse rate. The tool is then fed to D. The cycle is identical to the other boring cycles except that the tool is withdrawn manually. The G88 block for a boring cycle with dwell and manual withdrawal is: N_____G88 X_____Y_____C_____D_____T_____F_____EOB
In the G88 dwell cycle, the tool is moved from A to B to C at the rapid traverse rate and then fed at the prescribed feed rate to D. The tool dwells at D, then stops rotating and is withdrawn manually. The G89 block for a boring cycle with dwell and withdrawal at the feed rate is: N_____G89 X_____Y_____C_____D_____T_____F_____EOB
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Fig. 16.
Turning Cycles.—Canned turning cycles are available from most system builders and are designed to allow the programmer to describe a complete turning operation in one or a few blocks. There is no standard for this type of operation, so a wide variety of programs have developed. Fig. 16 shows a hypothetical sequence in which the cutter is moved from the start point to depth for the first pass. If incremental programming is in effect, this distance is specified as D1. The depths of the other cuts will also be programmed as D2, D3, and so on. The length of the cut will be set by the W-word, and will remain the same with each pass. The preparatory word that calls for the roughing cycle is G77. The roughing feed rate is 0.03 ipr (inch per revolution), and the finishing feed rate (last pass) is 0.005 ipr. The block appears as follows: N0054 G77 W = 3.1 D1 = .4 D2 = .3 D3 = .3 D4 = .1 F1 = .03 F2 = .005 Thread Cutting.—Most NC lathes can produce a variety of thread types including constant-lead threads, variable-lead threads (increasing), variable-lead threads (decreasing), multiple threads, taper threads, threads running parallel to the spindle axis, threads (spiral groove) perpendicular to the spindle axis, and threads containing a combination of the preceding. Instead of the feed rate, the lead is specified in the threading instruction block, so that the feed rate is made consistent with, and dependent upon, the selected speed (rpm) of the spindle. The thread lead is generally noted by either an I- or a K-word. The I-word is used if the thread is parallel to the X-axis and the K-word if the thread is parallel to the Z-axis, the latter being by far the most common. The G-word for a constant-lead thread is G33, for an increasing variable-lead thread is G34, and for a decreasing variable-lead thread is G35. Taper threads are obtained by noting the X- and Z-coordinates of the beginning and end points of the thread if the G90 code is in effect (absolute programming), or the incremental movement from the beginning point to the end point of the thread if the G91 code (incremental programming) is in effect. N0001 G91 (Incremental programming) N0002 G00 X−.1000 (Rapid traverse to depth) N0003 G33 Z−1.0000 K.0625 (Produce a thread with a constant lead of 0.625 inch) N0004 G00 X.1000 (Withdraw at rapid traverse) N0005 Z1.0000 (Move back to start point)
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Fig. 17.
Fig. 18.
Multiple threads are specified by a code in the block that spaces the start of the threads equally around the cylinder being threaded. For example, if a triple thread is to be cut, the threads will start 120 degrees apart. Typical single-block thread cutting utilizing a plunge cut is illustrated in Fig. 17 and shows two passes. The passes areidentical except for the distance of the plunge cut. Builders of control systems and machine tools use different codewords for threading, but those shown below can be considered typical. For clarity, both zeros and decimal points are shown. The only changes in the second pass are the depth of the plunge cut and the withdrawal. The blocks will appear as follows: N0006 X − .1050 N0007 G33 Z − 1.0000 K.0625 N0008 G00 X.1050 N0009 Z1.000 Compound thread cutting, rather than straight plunge thread cutting, is possible also, and is usually used on harder materials. As illustrated in Fig. 18, the starting point for the thread is moved laterally in the -Z direction by an amount equal to the depth of the cut times the tangent of an angle that is slightly less than 30 degrees. The program for the second pass of the example shown in Fig. 18 is as follows: N0006 X − .1050 Z − .0028 N0007 G33 Z − 1.0000 K.0625 N0008 G00 X.1050 N0009 Z1.0000 Fixed (canned), one-block cycles also have been developed for CNC systems to produce the passes needed to complete a thread. These cycles may be offered by the builder of the control system or machine tool as standard or optional features. Subroutines also can generally be prepared by the user to accomplish the same purpose (see Subroutine). A oneblock fixed threading cycle might look something like: N0048 G98 X − .2000 Z − 1.0000 D.0050 F.0010 where G98 = preparatory code for the threading cycle X − .2000 = total distance from the starting point to the bottom of the thread Z − 1.0000 = length of the thread D.0050 = depths of successive cuts F.0010 = depth(s) of the finish cut(s) APT Programming APT.—APT stands for Automatically Programmed Tool and is one of many computer languages designed for use with NC machine tools. The selection of a computer-assisted part-programming language depends on the type and complexity of the parts being machined more than on any other factor. Although some of the other languages may be easier to use, APT has been chosen to be covered in this book because it is a nonproprietary
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language in the public domain, has the broadest range of capability, and is one of the most advanced and universally accepted NC programming languages available. APT (or a variation thereof) is also one of the languages that is output by many computer programs that produce CNC part programs directly from drawings produced with CAD systems. APT is suitable for use in programming part geometry from simple to exceptionally complex shapes. APT was originally designed and used on mainframe computers, however, it is now available, in many forms, on mini- and microcomputers as well. APT has also been adopted as ANSI Standard X3.37and by the International Organization for Standardization (ISO) as a standardized language for NC programming. APT is a very dynamic program and is continually being updated. APT is being used as a processor for partprogramming graphic systems, some of which have the capability of producing an APT program from a graphic screen display or CAD drawing and of producing a graphic display on the CAD system from an APT program. APT is a high-level programming language. One difference between APT and the ANSI/EIA RS-274-D (G-codes) programming format discussed in the last section is that APT uses English like words and expressions to describe the motion of the tool or workpiece. APT has the capability of programming the machining of parts in up to five axes, and also allows computations and variables to be included in the programming statements so that a whole family of similar parts can be programmed easily. This section describes the general capabilities of the APT language and includes a ready reference guide to the basic geometry and motion statements of APT, which is suitable for use in programming the machining of the majority of cubic type parts involving two-dimensional movements. Some of the three-dimensional geometry capability of APT and a description of its fivedimensional capability are also included. Section 0 Controls the information flow PARTNO XXXX MACHIN/XXXX CUTTER/ .25 FROM/P1 (( )) )) (( FINI
Section 1 Converts English-like part program into computer language. Also checks for syntax errors in the part program.
Section 2 Heart of APT system. Performs geometry calculations. Output is center-line path of cutter or cutter location (CLC), described as coordinate points.
Section 3 Handles redundant operations and axis shifts.
Section 4 Converts to the block data and format required by the machine tool/system combination. Referred to as a postprocessor.
Tape output or direct to machine control system via DNC
As shown above, the APT system can be thought of comprising the input program, the five sections 0 through IV, and the output program. The input program shown on the left progresses through the first four sections and all four are controlled by the fifth, section 0. Section IV, the postprocessor, is the software package that is added to sections II and III to customize the output and produce the necessary program format (including the G-words, M-words, etc.) so that the coded instructions will be recognizable by the control system. The postprocessor is software that is separate from the main body of the APT program, but for purposes of discussion, it may be easier to consider it as a unit within the APT program.
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Machinery's Handbook 27th Edition 1294
NUMERICAL CONTROL
APT Computational Statements.—Algebraic and trigonometric functions and computations can be performed with the APT system as follows: Arithmetic Form 25 × 25 25 ÷ 25 25 + 25 25 − 25
APT Form 25*25 25⁄25 25 + 25 25 − 25
Arithmetic Form APT Form Arithmetic Form 25**2 cos θ 252 25**n tan θ 25n √25 SQRTF (25) arctan .5000 sin θ SINF(θ)
APT Form COSF(θ) TANF(θ) ATANF(.5)
Computations may be used in the APT system in two ways. One way is to let a factor equal the computation and then substitute the factor in a statement; the other is to put the computation directly into the statement. The following is a series of APT statements illustrating the first approach. P1 = POINT/0,0,1 T =(25*2⁄3 + (3**2 − 1)) P2 = POINT/T,0,0 The second way would be as follows; P1 = POINT/0,0,1 P2 = POINT/(25*2⁄3 + (3**2 − 1)),0,0 Note: The parentheses have been used as they would be in an algebraic formula so that the calculations will be carried out in proper sequence. The operations within the inner parentheses would be carried out first. It is important for the total number of left-hand parentheses to equal the total number of right-hand parentheses; otherwise, the program will fail. APT Geometry Statements.—Before movements around the geometry of a part can be described, the geometry must be defined. For example, in the statement GOTO/P1, the computer must know where P1 is located before the statement can be effective. P1 therefore must be described in a geometry statement, prior to its use in the motion statement GOTO/P1. The simplest and most direct geometry statement for a point is P1 = POINT/X ordinate, Y ordinate, Z ordinate If the Z ordinate is zero and the point lies on the X−Y plane, the Z location need not be noted. There are other ways of defining the position of a point, such as at the intersection of two lines or where a line is tangent to a circular arc. These alternatives are described below, together with ways to define lines and circles. Referring to the preceding statement, P1 is known as a symbol. Any combination of letters and numbers may be used as a symbol providing the total does not exceed six characters and at least one of them is a letter. MOUSE2 would be an acceptable symbol, as would CAT3 or FRISBE. However, it is sensible to use symbols that help define the geometry. For example, C1 or CIR3 would be good symbols for a circle. A good symbol for a vertical line would be VL5. Next, and after the equal sign, the particular geometry is noted. Here, it is a POINT. This word is a vocabulary word and must be spelled exactly as prescribed. Throughout, the designers of APT have tried to use words that are as close to English as possible. A slash follows the vocabulary word and is followed by a specific description of the particular geometry, such as the coordinates of the point P1. A usable statement for P1 might appear as P1 = POINT/1,5,4. The 1 would be the X ordinate; the 5, the Y ordinate; and the 4, the Z ordinate. Lines as calculated by the computer are infinitely long, and circles consist of 360 degrees. As the cutter is moved about the geometry under control of the motion statements, the lengths of the lines and the amounts of the arcs are “cut” to their proper size. (Some of the geometry statements shown in the accompanying illustrations for defining POINTS, LINES, CIRCLES, TABULATED CYLINDERS, CYLINDERS, CONES, and SPHERES, in the APT language, may not be included in some two-dimensional [ADAPT] systems.)
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Machinery's Handbook 27th Edition NUMERICAL CONTROL Points
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1295
Machinery's Handbook 27th Edition 1296
NUMERICAL CONTROL Lines
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Machinery's Handbook 27th Edition NUMERICAL CONTROL Lines (Continued)
P2 and P3 are points close to the tangent points of L1 and the intersection point of L2, therefore cannot be end points of the tabulated cylinder
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1297
Machinery's Handbook 27th Edition 1298
NUMERICAL CONTROL Circles
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Machinery's Handbook 27th Edition NUMERICAL CONTROL
1299
Circles
APT Motion Statements.—APT is based on the concept that a milling cutter is guided by two surfaces when in a contouring mode. Examples of these surfaces are shown in Fig. 1, and they are called the “part” and the “drive” surfaces. Usually, the partsurface guides the bottom of the cutter and the drive surface guides the side of the cutter. These surfaces may or may not be actual surfaces on the part, and although they may be imaginary to the part programmer, they are very real to the computer. The cutter is either stopped or redirected by a third surface called a check surface. If one were to look directly down on these surfaces, they would appear as lines, as shown in Figs. 2a through 2c.
Fig. 1. Contouring Mode Surfaces
When the cutter is moving toward the check surface, it may move to it, onto it, or past it, as illustrated in Fig. 2a. When the cutter meets the check surface, it may go right, denoted by the APT command GORGT, or go left, denoted by the command GOLFT, in Fig. 2b.
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Machinery's Handbook 27th Edition 1300
NUMERICAL CONTROL
Alternatively, the cutter may go forward, instructed by the command GOFWD, as in Fig. 2c. The command GOFWD is used when the cutter is moving either onto or off a tangent circular arc. These code instructions are part of what are called motion commands. Fig. 3 shows a cutter moving along a drive surface, L1, toward a check surface, L2. When it arrives at L2, the cutter will make a right turn and move along L2 and past the new check surface L3. Note that L2 changes from a check surface to a drive surface the moment the cutter begins to move along it. The APT motion statement for this move is: GORGT/L2,PAST,L3 Contouring Cutter Movements
Fig. 2a.
Fig. 2b.
Fig. 2c.
Fig. 3. Motion Statements for Movements Around a Workpiece
Still referring to Fig. 3, the cutter moves along L3 until it comes to L4. L3 now becomes the drive surface and L4 the check surface. The APT statement is: GORGT/L3,TO,L4 The next statement is: GOLFT/L4,TANTO,C1 Even though the cutter is moving to the right, it makes a left turn if one is looking in the direction of travel of the cutter. In writing the motion statements, the part programmers must imagine they are steering the cutter. The drive surface now becomes L4 and the check surface, C1. The next statement will therefore be: GOFWD/C1,TANTO,L5 This movement could continue indefinitely, with the cutter being guided by the drive, part, and check surfaces. Start-Up Statements: For the cutter to move along them, it must first be brought into contact with the three guiding surfaces by means of a start-up statement. There are three different start-up statements, depending on how many surfaces are involved. A three-surface start-up statement is one in which the cutter is moved to the drive, part, and check surfaces, as seen in Fig. 4a. A two-surface start-up is one in which the cutter is
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Machinery's Handbook 27th Edition NUMERICAL CONTROL
1301
moved to the drive and part surfaces, as in Fig. 4b. A one-surface start-up is one in which the cutter is moved to the drive surface and the X−Y plane, where Z = 0, as in Fig. 4c. With the two- and one-surface start-up statements, the cutter moves in the most direct path, or perpendicular to the surfaces. Referring to Fig. 4a(three-surface start-up), the move is initiated from a point P1. The two statements that will move the cutter from P1 to the three surfaces are: FROM/P1 GO/TO,DS,TO,PS,TO,CS Circles
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Machinery's Handbook 27th Edition 1302
NUMERICAL CONTROL
DS is used as the symbol for the Drive Surface; PS as the symbol for the Part Surface; and CS as the symbol for the Check Surface. The surfaces must be denoted in this sequence. The drive surface is the surface that the cutter will move along after coming in contact with the three surfaces. The two statements applicable to the two-surface start-up (Fig. 4b) are: FROM/P1 GO/TO,DS,TO,PS The one-surface start-up (Fig. 4c) is: FROM/P1 GO/TO,DS Planes
Cutter Movement Surfaces
Fig. 4a.
Fig. 4b.
Fig. 4c.
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Machinery's Handbook 27th Edition NUMERICAL CONTROL
1303
Tabulated Cylinder
3-D Geometry
A cone is defined by its vertex, its axis as a unit vector, and the half angle (refer to cylinder for an example of a vector statement) CON1 = CONE/P1,V1,45
A sphere is defined by the center and the radius SP1 = SPHERE/P1, RADIUS, 2.5 or SP1 = SPHERE/5, 5, 3, 2.5 (where 5, 5, and 3 are the X, Y, and Z coordinates or P1, and 2.5 is the radius)
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Machinery's Handbook 27th Edition 1304
NUMERICAL CONTROL
Fig. 5. A Completed Two-Surface Start-Up
Note that, in all three motion statements, the slash mark (/) lies between the GO and the TO. When the cutter is moving to a point rather than to surfaces, such as in a start-up, the statement is GOTO/ rather than GO/TO. A two-surface start-up, Fig. 3, when completed, might appear as shown in Fig. 5, which includes the motion statements needed. The motion statements, as they would appear in a part program, are shown at the left, below: FROM/P1 FROM/P1 GO/TO,L1,TO,PS GOTO/P2 GORGT/L1,TO,L2 GOTO/P3 GORGT/L2,PAST,L3 GOTO/P4 GORGT/L3,TO,L4 GOTO/P5 GOLFT/L4,TANTO,C1 GOTO/P6 GOFWD/C1,TANTO,L5 GOTO/P7 GOFWD/L5,PAST,L1 GOTO/P2 GOTO statements can move the cutter throughout the range of the machine, as shown in Fig. 6. APT statements for such movements are shown at the right in the preceding example. The cutter may also be moved incrementally, as shown in Fig. 7. Here, the cutter is to move 2 inches in the + X direction, 1 inch in the + Y direction, and 1.5 inches in the + Z direction. The incremental move statement (indicated by DLTA) is: GODLTA/2,1,1.5 The first position after the slash is the X movement; the second the Y movement, and the third, the Z movement. Five-Axis Machining: Machining on five axes is achieved by causing the APT program to generate automatically a unit vector that is normal to the surface being machined, as shown in Fig. 8. The vector would be described by its X, Y, and Z components. These components, along with the X, Y, and Z coordinate positions of the tool tip, are fed into the postprocessor, which determines the locations and angles for the machine tool head and/or table. APT Postprocessor Statements.—Statements that refer to the operation of the machine rather than to the geometry of the part or the motion of the cutter about the part are called postprocessor statements. APT postprocessor statements have been standardized internationally. Some common statements and an explanation of their meaning follow:
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Machinery's Handbook 27th Edition NUMERICAL CONTROL
1305
MACHIN/ Specifies the postprocessor that is to be used. Every postprocessor has an identity code, and this code must follow the slash mark (/). For example: MACHIN/LATH,82 FEDRATE/ Denotes the feed rate. If in inches per minute (ipm), only the number
Fig. 6. A Series of GOTO Statements
Fig. 7. Incremental Cutter Movements
Fig. 8. Five-Axis Machining
need be shown. If in inches per revolution (ipr), IPR must be shown, for example: FEDRAT/.005,IPR RAPID Means rapid traverse and applies only to the statement that immediately follows it SPINDL/ Refers to spindle speed. If in revolutions per minute (rpm), only the number need be shown. If in surface feet per minute (sfm), the letters SFM need to be shown, for example: SPINDL/ 100SFM COOLNT/ Means cutting fluid and can be subdivided into: COOLNT/ON, COOLNT/MIST, COOLNT/FLOOD, COOLNT/OFF TURRET/ Used to call for a selected tool or turret position CYCLE/ Specifies a cycle operation such as a drilling or boring cycle. An example of a drilling cycle is: CYCLE/DRILL,RAPTO,.45,FEDTO,0,IPR,.004. The next statement might be GOTO/PI and the drill will then move to P1 and perform the cycle operation. The cycle will repeat until the CYCLE/OFF statement is read
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Machinery's Handbook 27th Edition 1306
NUMERICAL CONTROL
END Stops the machine but does not turn off the control system
Fig. 9. Symbols for Geometrical Elements
APT Example Program.—A dimensioned drawing of a part and a drawing with the symbols for the geometry elements are shown in Fig. 9. A complete APT program for this part, starting with the statement PARTNO 47F36542 and ending with FINI, is shown at the left below. The numbers at the left of the statements are for reference purposes only, and are not part of the program. The cutter is set initially at a point represented by the symbol SP, having coordinates X = −0.5, Y = −0.5, Z = 0.75, and moves to L1 (extended) with a one-surface start-up so that the bottom of the cutter rests on the X−Y plane. The cutter then moves counterclockwise around the part, past L1 (extended), and returns to SP. The coordinates of P1 are X = 0, Y = 0, and Z = 1. (1) (2) (3) (4) (5) (6) (7)
(10) (11) (12)
PARTNO CUTTER/.25 FEDRAT/5 SP = POINT/−.5, −.5, .75 P1 = POINT/0, 0, 1 L1 = LINE/P1, ATANGL, 0 C1 = CIRCLE/(1.700 + 1.250), .250, .250 C2 = CIRCLE/1.700, 1.950, .5 L2 = LINE/RIGHT, TANTO, C1, RIGHT, TANTO, C2 L3 = LINE/P1, LEFT, TANTO, C2 FROM/SP GO/TO, L1
(13) (14) (15) (16) (17) (18)
GORGT/L1, TANTO, C1 GOFWD/C1, TANTO, L2 GOFWD/L2, TANTO, C2 GOFWD/C2, TANTO, L3 GOFWD/L3, PAST, L1 GOTO/SP
(8) (9)
(1) (2) (3) (4) (5) (6) (7)
PARTNO CUTTER/.25 FEDRAT/5 SP = POINT/−.5, −.5, .75 P1 = POINT/0, 0, 1 L1 = LINE/P1, ATANGL, 0 C1 = CIRCLE/(1.700 + 1.250), .250, .250
(8) C2 = CIRCLE/1.700, 1.950, .5 (9) L2 = LINE/RIGHT, TANTO, C1, RIGHT, TANTO, C2 (10) L3 = LINE/P1, LEFT, TANTO, C2 (11) FROM/SP (12) FRO −.500 −.5000 .7500 M (13) GO/TO/, L1 (14) GT −.5000 −.1250 .0000 (15) GORGT/L1, TANTO, C1 (16) GT 2.9500 −.1250 .0000 (17) GOFWD/C1, TANTO, L2 (18) CIR 2.9500 .2500 .3750 CCLW
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Machinery's Handbook 27th Edition NUMERICAL CONTROL (19) FINI
(19) (20) (21) (22) (23) (24) (25) (26) (27) (28) (29)
3.2763 .4348 GOFWD/L2, TANTO, C2 GT 2.2439 2.2580 GOFWD/C2, TANTO, L3 CIR 1.700 1.9500 1.1584 2.2619 GOFWD/L3, PAST, L1 GT −.2162 −.1250 GOTO/SP GT −.5000 −.5000 FINI
1307 .0000 .0000 .6250 CCLW .0000 .0000 .7500
Referring to the numbers at the left of the program: (1) PARTNO must begin every program. Any identification can follow. (2) The diameter of the cutter is specified. Here it is 0.25 inch. (3) The feed rate is given as 5 inches per minute, which is contained in a postprocessor statement. (4)–(10) Geometry statements. (11)–(18) Motion statements. (19) All APT programs end with FINI. A computer printout from section II of the APT program is shown at the right, above. This program was run on a desktop personal computer. Lines (1) through (10) repeat the geometry statements from the original program. The motion statements are also repeated, and below each motion statement are shown the X, Y, and Z coordinates of the end points of the center-line (CL) movements for the cutter. Two lines of data follow those for the circular movements. For example, Line (18), which follows Line (17), GOFWD/C1,TANTO,L2, describes the X coordinate of the center of the arc, 2.9500, the Y coordinate of the center of the arc, 0.2500, and the radius of the arc required to be traversed by the cutter. This radius is that of the arc shown on the part print, plus the radius of the cutter (0.2500 + 0.1250 = 0.3750). Line (18) also shows that the cutter is traveling in a counterclockwise (CCLW) motion. A circular motion is described in Lines (22), (23), and (24). Finally, the cutter is directed to return to the starting point, SP, and this command is noted in Line (27). The X, Y, and Z coordinates of SP are shown in Line (28). APT for Turning.—In its basic form, APT is not a good program for turning. Although APT is probably the most suitable program for three-, four-, and five-axis machining, it is awkward for the simple two-axis geometry required for lathe operations. To overcome this problem, preprocessors have been developed especially for lathe part programming. The statements in the lathe program are automatically converted to basic APT statements in the computer and processed by the regular APT processor. An example of a lathe program, based on the APT processor and made available by the McDonnell Douglas Automation Co., is shown below. The numbers in parentheses are not part of the program, but are used only for reference. Fig. 10 shows the general set-up for the part, and Fig. 11 shows an enlarged view of the part profile with dimensions expressed along what would be the Xand Y-axes on the part print.
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Machinery's Handbook 27th Edition 1308
NUMERICAL CONTROL
Fig. 10. Setup for APT Turning
Fig. 11.
(1) (2) (3) (4) (5)
PARTNO LATHE EXAMPLE MACHIN/MODEL LATHE T1 = TOOL/FACE, 1, XOFF, −1, YOFF, −6, RADIUS, .031 BLANK1 = SHAPE/FACE, 3.5, TURN, 2 PART1 = SHAPE/FACE, 3.5, TAPER, 3.5, .5, ATANGL, − 45, TURN, 1,$ FILLET, .25 FACE, 1.5 TURN, 2 (6) FROM/(20–1), (15–6) (7) LATHE/ROUGH, BLANK1, PART1, STEP, .1, STOCK, .05,$ SFM, 300, IPR, .01, T1 (8) LATHE/FINISH, PART1, SFM, 400, IPR, .005, T1 (9) END (10) FINI
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Machinery's Handbook 27th Edition NUMERICAL CONTROL
1309
Line (3) describes the tool. Here, the tool is located on face 1 of the turret and its tip is −1 inch “off” (offset) in the X direction and −6 inches “off” in the Y direction, when considering X−Y rather than X−Z axes. The cutting tool tip radius is also noted in this statement. Line (4) describes the dimensions of the rough material, or blank. Lines parallel to the Xaxis are noted as FACE lines, and lines parallel to the Z-axis are noted as TURN lines. The FACE line (LN1) is located 3.5 inches along the Z-axis and parallel to the X-axis. The TURN line (LN2) is located 2 inches above the Z-axis and parallel to it. Note that in Figs. 10 and 11, the X-axis is shown in a vertical position and the Z-axis in a horizontal position. Line (5) describes the shape of the finished part. The term FILLET is used in this statement to describe a circle that is tangent to the line described by TURN, 1 and the line that is described by FACE, 1.5. The $ sign means that the statement is continued on the next line. These geometry elements must be contiguous and must be described in sequence. Line (6) specifies the position of the tool tip at the start of the operation, relative to the point of origin. Line (7) describes the roughing operation and notes that the material to be roughed out lies between BLANK1 and PART1; that the STEP, or depth of roughing cuts, is to be 0.1 inch; that 0.05 inch is to be left for the finish cut; that the speed is to be 300 sfm and the feed rate is to be 0.01 ipr; and that the tool to be used is identified by the symbol T1. Line (8) describes the finish cut, which is to be along the contour described by PART1. Indexable Insert Holders for NC.—Indexable insert holders for numerical control lathes are usually made to more precise standards than ordinary holders. Where applicable, reference should be made to American National Standard B212.3-1986, Precision Holders for Indexable Inserts. This standard covers the dimensional specifications, styles, and designations of precision holders for indexable inserts, which are defined as tool holders that locate the gage insert (a combination of shim and insert thicknesses) from the back or front and end surfaces to a specified dimension with a ± 0.003 inch (± 0.08 mm) tolerance. In NC programming, the programmed path is that followed by the center of the tool tip, which is the center of the point, or nose radius, of the insert. The surfaces produced are the result of the path of the nose and the major cutting edge, so it is necessary to compensate for the nose or point radius and the lead angle when writing the program. Table 1, from B212.3, gives the compensating dimensions for different holder styles. The reference point is determined by the intersection of extensions from the major and minor cutting edges, which would be the location of the point of a sharp pointed tool. The distances from this point to the nose radius are L1 and D1; L2 and D2 are the distances from the sharp point to the center of the nose radius. Threading tools have sharp corners and do not require a radius compensation. Other dimensions of importance in programming threading tools are also given in Table 2; the data were developed by Kennametal, Inc. The C and F characters are tool holder dimensions other than the shank size. In all instances, the C dimension is parallel to the length of the shank and the F dimension is parallel to the side dimension; actual dimensions must be obtained from the manufacturer. For all K style holders, the C dimension is the distance from the end of the shank to the tangent point of the nose radius and the end cutting edge of the insert. For all other holders, the C dimension is from the end of the shank to a tangent to the nose radius of the insert. The F dimension on all B, D, E, M, P, and V style holders is measured from the back side of the shank to the tangent point of the nose radius and the side cutting edge of the insert. For all A, F, G, J, K, and L style holders, the F dimension is the distance from the back side of the shank to the tangent of the nose radius of the insert. In all these designs, the nose radius is the standard radius corresponding to those given in the paragraph Cutting Point Configuration on page 758.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1310
NUMERICAL CONTROL Table 1. Insert Radius Compensation ANSI B212.3-1986 Square Profile Turning 15° Lead Angle
B Stylea Also applies to R Style
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64 1⁄ 16
.0035
.0191
.0009
.0110
.0070
.0383
.0019
.0221
.0105
.0574
.0028
.0331
.0140
.0765
.0038
.0442
Turning 45° Lead Angle D Stylea Also applies to S Style
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64
.0065
.0221
.0065
0
.0129
.0442
.0129
0
.0194
.0663
.0194
0
1⁄ 16
.0259
.0884
.0259
0
Facing 15° Lead Angle
K Stylea
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64
.0009
.0110
.0035
.0191
.0019
.0221
.0070
.0383
.0028
.0331
.0105
.0574
1⁄ 16
.0038
.0442
.0140
.0765
Triangle Profile Turning 0° Lead Angle
G
Stylea
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64 1⁄ 16
.0114
.0271
0
.0156
.0229
.0541
0
.0312
.0343
.0812
0
.0469
.0458
.1082
0
.0625
Turning and Facing 15° Lead Angle B Stylea Also applies to R Style
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64 1⁄ 16
.0146
.0302
.0039
.0081
.0291
.0604
.0078
.0162
.0437
.0906
.0117
.0243
.0582
.1207
.0156
.0324
Facing 90° Lead Angle
F Stylea
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64
0
.0156
.0114
.0271
0
.0312
.0229
.0541
0
.0469
.0343
.0812
1⁄ 16
0
.0625
.0458
.1082
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Machinery's Handbook 27th Edition NUMERICAL CONTROL
1311
Table 1. (Continued) Insert Radius Compensation ANSI B212.3-1986 Triangle Profile (continued) Turning & Facing 3° Lead Angle
J
Stylea
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64 1⁄ 16
.0106
.0262
.0014
.0170
.0212
.0524
.0028
.0340
.0318
.0786
.0042
.0511
.0423
.1048
.0056
.0681
80° Diamond Profile Turning & Facing 0° Lead Angle
G Stylea
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64
.0030
.0186
0
.0156
.0060
.0312
0
.0312
.0090
.0559
0
.0469
1⁄ 16
.0120
.0745
0
.0625
Turning & Facing 5° Reverse Lead Angle
L Stylea
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64
.0016
.0172
.0016
.0172
.0031
.0344
.0031
.0344
.0047
.0516
.0047
.0516
1⁄ 16
.0062
.0688
.0062
.0688
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64
0
.0156
.0030
.0186
0
.0312
.0060
.0372
0
.0469
.0090
.0559
1⁄ 16
0
.0625
.0120
.0745
Facing 0° Lead Angle
F Stylea
Turning 15° Lead Angle
R Stylea
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64
.0011
.0167
.0003
.0117
.0022
.0384
.0006
.0234
.0032
.0501
.0009
.0351
1⁄ 16
.0043
.0668
.0012
.0468
Facing 15° Lead Angle
K Stylea
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64
.0003
.0117
.0011
.0167
.0006
.0234
.0022
.0334
.0009
.0351
.0032
.0501
1⁄ 16
.0012
.0468
.0043
.0668
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1312
NUMERICAL CONTROL Table 1. (Continued) Insert Radius Compensation ANSI B212.3-1986 55° Profile Profiling 3° Reverse Lead Angle
J Stylea
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64
.0135
.0292
.0015
.0172
.0271
.0583
.0031
.0343
.0406
.0875
.0046
.0519
1⁄ 16
.0541
.1166
.0062
.0687
35° Profile Profiling 3° Reverse Lead Angle J Stylea Negative rake holders have 6° back rake and 6° side rake
Rad.
L-1
L-2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64
.0330
.0487
.0026
.0182
.0661
.0973
.0051
.0364
.0991
.1460
.0077
.0546
1⁄ 16
.1322
.1947
.0103
.0728
Profiling 5° Lead Angle
L Stylea
Rad.
L-1
L -2
D-1
D-2
1⁄ 64 1⁄ 32 3⁄ 64 1⁄ 16
.0324
.0480
.0042
.0198
.0648
.0360
.0086
.0398
.0971
.1440
.0128
.0597
.1205
.1920
.0170
.0795
a L-1
and D-1 over sharp point to nose radius; and L-2 and D-2 over sharp point to center of nose radius. The D-1 dimension for the B, E, D, M, P, S, T, and V style tools are over the sharp point of insert to a sharp point at the intersection of a line on the lead angle on the cutting edge of the insert and the C dimension. The L-1 dimensions on K style tools are over the sharp point of insert to sharp point intersection of lead angle and F dimensions. All dimensions are in inches.
Table 2. Threading Tool Insert Radius Compensation for NC Programming Threading Insert Size 2 3 4 5
T 5⁄ Wide 32 3⁄ Wide 16 1⁄ Wide 4 3⁄ Wide 8
R .040 .046 .053 .099
U .075 .098 .128 .190
Y .040 .054 .054 …
X .024 .031 .049 …
All dimensions are given in inches. Courtesy of Kennametal, Inc.
Copyright 2004, Industrial Press, Inc., New York, NY
Z .140 .183 .239 …
Machinery's Handbook 27th Edition NUMERICAL CONTROL
1313
V-Flange Tool Shanks and Retention Knobs.—Dimensions of ANSI B5.18-1972 (R1998) standard tool shanks and corresponding spindle noses are detailed on pages 940 through 944, and are suitable for spindles used in milling and associated machines. Corresponding equipment for higher-precision numerically controlled machines, using retention knobs instead of drawbars, is usually made to the ANSI/ASME B5.50-1985 standard. Essential Dimensions of V-Flange Tool Shanks ANSI/ASME B5.50-1985
A
Size 30 40 45 50 60
B
C
D
E
F
G
H
J
K
Tolerance
±0.005
±0.010
Min.
+ 0.015 −0.000
UNC 2B
±0.010
±0.002
+0.000 −0.015
+0.000 −0.015
Gage Dia. 1.250 1.750 2.250 2.750 4.250
1.875 2.687 3.250 4.000 6.375
0.188 0.188 0.188 0.250 0.312
1.00 1.12 1.50 1.75 2.25
0.516 0.641 0.766 1.031 1.281
0.500-13 0.625-11 0.750-10 1.000-8 1.250-7
1.531 2.219 2.969 3.594 5.219
1.812 2.500 3.250 3.875 5.500
0.735 0.985 1.235 1.485 2.235
0.640 0.890 1.140 1.390 2.140
A
L
M
N
P
R
S
T
Z
Tolerance
±0.001
±0.005
+0.000 −0.015
Min.
±0.002
±0.010
Min. Flat
+0.000 −0.005
Size 30 40 45 50
Gage Dia. 1.250 1.750 2.250 2.750
0.645 0.645 0.770 1.020
1.250 1.750 2.250 2.750
1.38 1.38 1.38 1.38
2.176 2.863 3.613 4.238
0.590 0.720 0.850 1.125
0.650 0.860 1.090 1.380
1.250 1.750 2.250 2.750
60
4.250
1.020
4.250
1.500
5.683
1.375
2.04
4.250
0.030 0.060 0.090 0.090 0.120 0.200
Notes: Taper tolerance to be 0.001 in. in 12 in. applied in direction that increases rate of taper. Geometric dimensions symbols are to ANSI Y14.5M-1982. Dimensions are in inches. Deburr all sharp edges. Unspecified fillets and radii to be 0.03 ± 0.010R, or 0.03 ± 0.010 × 45 degrees. Data for size 60 are not part of Standard. For all sizes, the values for dimensions U (tol. ± 0.005) are 0.579: for V (tol. ± 0.010), 0.440; for W (tol. ± 0.002), 0.625; for X (tol. ± 0.005), 0.151; and for Y (tol. ± 0.002), 0.750.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1314
NUMERICAL CONTROL Essential Dimensions of V-Flange Tool Shank Retention Knobs ANSI/ASME B5.50-1985
Size
A
B
C
D
E
F
30
0.500-13
0.520
0.385
1.10
0.460
0.320
40
0.625-11
0.740
0.490
1.50
0.640
0.440
45
0.750-10
0.940
0.605
1.80
0.820
0.580
50
1.000-8
1.140
0.820
2.30
1.000
0.700
60
1.250-7
1.460
1.045
3.20
1.500
1.080
UNC- 2A
±0.005
±0.005
±0.040
±0.005
±0.005
Tolerances Size
G
H
J
K
L
M
R
30
0.04
0.10
0.187
0.65 0.64
0.53
0.19
0.094
40
0.06
0.12
0.281
0.94 0.92
0.75
0.22
0.094
0.375
1.20 1.18
1.00
0.22
0.094
0.468
1.44 1.42
1.25
0.25
0.125
2.14 2.06
45 50 60 Tolerances
0.08 0.10
0.16 0.20
0.14
0.30
0.500
±0.010
±0.010
±0.010
1.50
0.31
0.125
+0.000 −0.010
±0.040
+0.010 −0.005
Notes: Dimensions are in inches. Material: low-carbon steel. Heat treatment: carburize and harden to 0.016 to 0.028 in. effective case depth. Hardness of noted surfaces to be Rockwell 56-60; core hardness Rockwell C35-45. Hole J shall not be carburized. Surfaces C and R to be free from tool marks. Deburr all sharp edges. Geometric dimension symbols are to ANSI Y14.5M-1982. Data for size 60 are not part of Standard.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CAD/CAM
1315
CAD/CAM CAD/CAM.—CAD in engineering means computer-aided design using a computer graphics system to develop mechanical, electrical/electronic, and architectural designs. A second D (CADD) is sometimes added (computer-aided drafting and design) and simply indicates a mechanical drafting or drawing program. CAD technology is the foundation for a wide variety of engineering, design, drafting, analysis, and manufacturing activities. Often a set of drawings initially developed in the design phase of a project is also used for analyzing and optimizing the design, creating mechanical drawings of parts and assemblies and for generating NC/CNC part programs that control machining operations. Formerly, after a component had been designed with CAD, the design was passed to a part programmer who developed a program for machining the components, either manually or directly on the computer (graphic) screen, but the process often required redefining and reentering part geometry. This procedure is often regarded as the CAM part of CAD/CAM, although CAM (for computer-aided manufacturing) has a much broader meaning and involves the computer in many other manufacturing activities such as factory simulation and planning analyses. Improvements in the speed and capability of computers, operating systems, and programs (including, but not limited to CAD) have simplified the process of integrating the manufacturing process and passing drawings (revised, modified, and translated, as necessary) through the design, analysis, simulation, and manufacturing stages. A CAD drawing is a graphic representation of part geometry data stored in a drawing database file. The drawing database generally contains the complete list of entity (line, arc, etc.) and coordinate information required to build the CAD drawing, and additional information that may be required to define solid surfaces and other model characteristics. The format of data in a drawing file depends on the CAD program used to create the file. Generally, drawings are not directly interchangeable between drawing programs, however, drawings created in one system can usually be translated into an intermediate format or file type, such as DXF, that allows some of the drawing information to be exchanged between different programs. Translation frequently results in some loss of detail or loss of other drawing information because the various drawing programs do not all have the same features. The section Drawing Exchange Standards covers some of the available methods of transferring drawing data between different CAD programs.
Fig. 1. Simple Wireframe Cube with Hidden Lines Automatically Removed
The simplest CAD drawings are two-dimensional and conform to normal engineering drafting practice showing orthographic (front, top, and side views, for example), exploded, isometric, or other views of a component. Depending on the complexity of the part and machining requirements, two-dimensional drawings are often sufficient for use in developing NC/CNC part programs. If a part can be programmed within a two-dimensional
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Machinery's Handbook 27th Edition 1316
CAD/CAM
CAD framework, a significant cost saving may be realized because 3-D drawings require considerably more time, drawing skill, and experience to produce than 2-D drawings. Wireframes are the simplest two- and three-dimensional forms of drawing images and are created by defining all edges of a part and, where required, lines defining surfaces. Wireframe drawing elements consist primarily of lines and arcs that can be used in practically any combination. A wireframe drawing of a cube, as in Fig. 1, consists of 12 lines of equal length (some are hidden and thus not shown), each perpendicular to the others. Information about the interior of the cube and the character of the surfaces is not included in the drawing. With such a system, if a 1-inch cube is drawn and a 0.5-inch cylinder is required to intersect the cube's surface at the center of one of its faces, the intersection points cannot be determined because nothing is known about the area between the edges. A wireframe model of this type is ambiguous if the edges overlap or do not meet where they should. Hidden-line removal can be used to indicate the relative elevations of the drawing elements, but normally a drawing cannot be edited when hidden lines have been removed. Hidden lines can be shown dashed or can be omitted from the view. Two-dimensional drawing elements, such as lines, arcs, and circles, are constructed by directly or indirectly specifying point coordinates, usually x and y, that identify the location, size, and orientation of the entities. Three-dimensional drawings are also made up of a collection of lines, arcs, circles, and other drawing elements and are stored in a similar manner. A third point coordinate, z, indicates the elevation of a point in 3-D drawings. On the drawing screen, working in the x-y plane, the elevation is commonly thought of as the distance of a point or object into the screen (away from the observer) or out of the viewing screen (toward the observer). Coordinate axes are oriented according to the right-hand rule: If the fingers of the right hand point in the direction from the positive x-axis to the positive y-axis, the thumb of the right hand points in the direction of the positive z-axis. Assigning a thickness (or extruding) to objects drawn in two dimensions quickly gives some 3-D characteristics to an object and can be used to create simple prismatic 3-D shapes, such as cubes and cylinders. Usually, the greatest difficulty in creating 3-D drawings is in picking and visualizing the three-dimensional points in a two-dimensional workspace (the computer display screen). To assist in the selection of 3-D points, many CAD programs use a split or windowed screen drawing area that can simultaneously show different views of a drawing. Changes made in the current or active window are reflected in each of the other windows. A typical window setup might show three orthogonal (mutually perpendicular) views of the drawing and a perspective or 3-D view. Usually, the views shown can be changed as required to suit the needs of the operator. If carefully constructed, wireframe images may contain enough information to completely define the external geometry of simple plane figures. Wireframe images are especially useful for visualization of 3-D objects and are effectively used during the design process to check fits, clearances, and dimensional accuracy. Parts designed to be used together can be checked for accuracy of fit by bringing them together in a drawing, superimposing the images, and graphically measuring clearances. If the parts have been designed or drawn incorrectly, the errors will frequently be obvious and appropriate corrections can be made. A more complicated level of 3-D drawing involves solids, with sections of the part being depicted on the screen as solid geometrical structures called primitives, such as cylinders, spheres, and cubes. Primitives can be assembled on a drawing to show more complex parts. Three distinct forms of image may be generated by 3-D systems, although not all systems make use of all three. Surface Images: A surface image defines not only the edges of the part, but also the “skin” of each face or surface. For the example mentioned previously, the intersection for the 0.5-inch cylinder would be calculated and drawn in position. Surface models are necessary for designing free-form objects such as automotive body panels and plastics injection moldings used in consumer goods. For a surface model, the computer must be provided
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Machinery's Handbook 27th Edition CAD/CAM
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with much more information about the part in addition to the x, y, z coordinates defining each point, as in a wireframe. This information may include tangent vectors, surface normals, and weighting that determines how much influence one point has on another, twists, and other mathematical data that define abstract curves, for instance. Fig. 2 shows a typical 3-D surface patch. Shaded images may be constructed using simulated light sources, reflections, colors, and textures to make renderings more lifelike. Surface images are sometimes ambiguous, with surfaces that overlap or miss each other entirely. Information about the interior of the part, such as the center of gravity or the volume, also may not be available, depending on the CAD package.
z x
90˚ y 30˚ Fig. 2. A 3-D Surface Patch
30˚
Fig. 3. Isometric Drawing Showing Orientation of Principle Drawing Axes
Solid Images: A solid image is the ultimate electronic representation of a part, containing all the necessary information about edges, surfaces, and the interior. Most solid-imaging programs can calculate volume, center of mass, centroid, and moment of inertia. Several methods are available for building a solid model. One method is to perform Boolean operations on simple shapes such as cylinders, cones, cubes, and blocks. Boolean operations are used to union (join), difference (subtract one from another), and intersect (find the common volume between two objects). Thus, making a hole in a part requires subtracting a cylinder from a rectangular block. This type of program is called constructive solid geometry (CSG). The boundary representation type of imaging program uses profiles of 2-D shapes that it extrudes, rotates, and otherwise translates in 3-D space to create the required solid. Sometimes combinations of the above two programs are used to attain a blend of flexibility, accuracy, and performance. For more precision, greatly increased time is needed for calculations, so compromises sometimes are needed to maintain reasonable productivity. Solid images may be sliced or sectioned on the screen to provide a view of the interior. This type of image is also useful for checking fit and assembly of one part with another. Solid images provide complete, unambiguous representation of a part, but the programs require large amounts of computer memory. Each time a Boolean operation is performed, the list of calculations that must be done to define the model becomes longer, so that computation time increases. Drawing Projections.—Several different techniques are used to display objects on paper or a computer screen to give an accurate three-dimensional appearance. Several of these methods are commonly used in CAD drawings. Isometric drawings, as in Fig. 3, can be used to good effect for visualizing a part because they give the impression of a 3-D view and are often much faster to create. Isometric drawings are created in 2-D space, with the x- and y-axes being inclined at 30 degrees to the horizontal, as shown in Fig. 3, and the z-axis as vertical. Holes and cylinders in isometric drawings become elliptical. Because of the orientation of the x-, y-, and z-axes, the true length of lines may not be accurately represented in isometric drawings and dimensions
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1318
CAD/CAM
should not be taken directly from a print. Some CAD programs have a special set of predefined drawing axes to facilitate creating isometric drawings. In parallel projections, lines that are parallel in an object, assembly, or part being portrayed remain parallel in the drawing. Parallel projections show 3-D objects in a dimensionally correct manner, so that relative and scaled dimensions may be taken directly from a drawing. However, drawings may not appear as realistic as isometric or perspective drawings. A characteristic of perspective drawings is that parallel lines converge (see Fig. 4) so that objects that are farther away from the observer appear smaller. Perspective drawing techniques are used in some three-dimensional drawings to convey the true look of an object, or group of objects. Because objects in perspective drawings are not drawn to scale, dimensional information cannot be extracted from the drawings of a part. Some 3-D drawing packages have a true perspective drawing capability, and others use a simulation technique to portray a 3-D perspective. An axonometric projection is a 3-D perpendicular projection of an object onto a surface, such that the object is tilted relative to its normal orientation. An axonometric projection of a cube, as in Fig. 1, shows three faces of the cube. CAD systems are adept at using this type of view, making it easy to see an object from any angle.
0.01
Fig. 4. Perspective Drawing of Three EqualSize Cubes and Construction Lines
Fig. 5. A Common Positioning Error
Drawing Tips and Traps.—Images sometimes appear correct on the screen but contain errors that show up when the drawing is printed or used to produce NC/CNC part programs. In Fig. 5, the two lines within the smaller circle appear to intersect at a corner, but when the view of the intersection is magnified, as in the larger circle, it is clear that the lines actually do not touch. Although an error of this type may not be easily visible, other parts placed in the drawing relative to this part will be out of position. A common problem that shows up in plotting, but is difficult to detect on the screen, comes from placing lines in the same spot. When two or more lines occupy exactly the same location on the screen, there is usually no noticeable effect on the display. However, when the drawing is plotted, each line is plotted separately, causing the single line visible to become thicker and darker. Likewise, if a line that appears continuous on the screen is actually made up of several segments, plotting the line will frequently result in a broken, marred, or blotted appearance to the line because the individual segments are plotted separately, and at different times. To avoid these problems and to get cleaner looking plots, replace segmented lines with single lines and avoid constructions that place one line directly on top of another. Exact decimal values should be used when entering point coordinates from the keyboard, if possible; fractional sizes should be entered as fractions, not truncated decimals. For example, 5⁄16 should be entered as 0.3125 or 5⁄16, not 0.313. Accumulated rounding errors and surprises later on when parts do not fit are thus reduced. Drawing dimensions, on the
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Machinery's Handbook 27th Edition CAD/CAM
1319
other hand, should not have more significant digits or be more precise than necessary. Unnecessary precision in dimensioning leads to increased difficulty in the production stage because the part has to be made according to the accuracy indicated on the drawing. Snap and object snap commands make selecting lines, arcs, circles, or other drawing entities faster, easier, and more accurate when picking and placing objects on the screen. Snap permits only points that are even multiples of the snap increment to be selected by the pointer. A 1⁄8-inch snap setting, for example, will allow points to be picked at exactly 1⁄8-inch intervals. Set the snap increment to the smallest distance increment (1 in., 1⁄4 in., 1 ft., etc.) being used in the area of the drawing under construction and reset the snap increment frequently, if necessary. The snap feature can be turned off during a command to override the setting or to select points at a smaller interval than the snap increment allows. Some systems permit setting a different snap value for each coordinate axis. The object snap selection mode is designed to select points on a drawing entity according to predefined characteristics of the entity. For example, if end-point snap is in effect, picking a point anywhere along a line will select the end point of the line nearest the point picked. Object snap modes include point, intersection, midpoint, center and quadrants of circles, tangency point (allows picking a point on an arc or circle that creates a tangent to a line), and perpendicular point (picks a point that makes a perpendicular from the base point to the object selected). When two or more object snap modes are used together, the nearest point that meets the selection criteria will be chosen. Using object snap will greatly reduce the frequency of the type of problem shown in Fig. 5. Copy: Once drawn, avoid redrawing the same object. It is almost always faster to copy and modify a drawing than to draw it again. The basic copy commands are: copy, array, offset, and mirror. Use these, along with move and rotate and the basic editing commands, to modify existing objects. Copy and move should be the most frequently used commands. If possible, create just one instance of a drawing object and then copy and move it to create others. To create multiple copies of an object, use the copy, multiple feature to copy selected objects as many times as required simply by indicating the destination points. The array command makes multiple copies of an object according to a regular pattern. The rectangular array produces rows and columns, and the polar array puts the objects into a circular pattern, such as in a bolt circle. Offset copies an entity and places the new entity a specified distance from the original and is particularly effective at placing parallel lines and curves, and for creating concentric copies of closed shapes. Mirror creates a mirror image copy of an object, and is useful for making right- and left-hand variations of an object as well as for copying objects from one side of an assembly to the other. In some CAD programs, a system variable controls whether text is mirrored along with other objects. Many manufacturers distribute drawings of their product lines in libraries of CAD drawings, usually as DXF files, that can be incorporated into existing drawings. The suitability of such drawings depends on the CAD program and drawing format being used, the skill of the technician who created the drawings, and the accuracy of the drawings. A typical example, Fig. 6, shows a magnetically coupled actuator drawing distributed by Tol-OMatic, Inc. Libraries of frequently used drawing symbols and blocks are also available from commercial sources. Create Blocks of Frequently Used Objects: Once created, complete drawings or parts of drawings can be saved and later recalled, as needed, into another drawing. Such objects can be scaled, copied, stretched, mirrored, rotated, or otherwise modified without changing the original. When shapes are initially drawn in unit size (i.e., fitting within a 1 × 1 square) and saved, they can be inserted into any drawing and scaled very easily. One or more individual drawing elements can be saved as a group element, or block, that can be manipulated in a drawing as a single element. Block properties vary, depending on the drawing program, but are among the most powerful features of CAD. Typically, blocks are uniquely named
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Machinery's Handbook 27th Edition 1320
CAD/CAM
and, as with simple objects, may be saved in a file on the disk. Blocks are ideal for creating libraries of frequently used drawing symbols. Blocks can be copied, moved, scaled very easily, rotated, arrayed, and inserted as many times as is required in a drawing and manipulated as one object. When scaled, each object within the block is also scaled to the same degree.
Fig. 6. Manufacturer's Drawing of a Magnetically Coupled Actuator (Courtesy of Tol-O-Matic, Inc.)
When a family of parts is to be drawn, create and block a single drawing of the part that fits within a unit cube of convenient size, such as 1 × 1 × 1. When the block is inserted in a drawing, it is scaled appropriately in the x-, y-, and z-directions. For example, 3⁄8-inch bolts can be drawn 1 inch long in the x-direction and 3⁄8-inch in diameter in the y-z plane. If a 5inch bolt is needed, insert the “bolt” block with a scale of 5 in the x-direction and a scale of 1 in the y- and z-directions. Once blocked, the individual components of a block (lines, arcs, circles, surfaces, and text, for example) cannot be individually changed or edited. To edit a block, a copy (instance) of the block must be exploded (unblocked) to divide it into its original components. Once exploded, all the individual elements of the block (except other blocks) can be edited. When the required changes have been made, the block must be redefined (redeclared as a block by giving it a name and identifying its components). If the block is redefined using the same name, any previous references to the block in the drawing will be updated to match the redefined block. For example, an assembly drawing is needed that shows a mechanical frame with 24 similar control panels attached to it. Once one of the panels is drawn and defined as a block (using the name PANEL, for instance), the block can be inserted (or copied) into the drawing 24 times. Later, if changes need to be made to the panel design, one instance of the block PANEL can be exploded, modified, and redefined with the name PANEL. When PANEL is redefined, every other copy of the PANEL block in the drawing is also redefined, so every copy of PANEL in the drawing is updated. On the other hand, if the block was redefined with a different name, say, PANEL1, existing copies of PANEL remain unchanged. When redefining a block that already exists in the drawing, be sure to use the same insertion point that was used for the original definition of the block; otherwise, the positions of existing blocks with the same name will be changed. Use of Text Attributes to Request Drawing Information Automatically: Text attributes are a useful method for attaching textual information to a particular part or feature of a drawing. An attribute is basically a text variable that has a name and can be assigned a value. Attributes are created by defining attribute characteristics such as a name, location in the drawing, text size and style, and default value. The attribute value is assigned when the attribute is inserted into a drawing as part of a block. Fig. 7 shows two views of a title block for size A to C drawing sheets. The upper figure includes the title block dimensions (included only for reference) and the names and locations of the attributes (COMPANY, TITLE1, TITLE2, etc.). When a block containing text
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Machinery's Handbook 27th Edition CAD/CAM
1321
attributes is inserted in a drawing, the operator is asked to enter the value of each attribute. To create this title block, first draw the frame of the title block and define the attributes (name, location and default value for: company name and address, drawing titles [2 lines], drawing size, drawing number, revision number, scale, and sheet number). Finally, create and name a block containing the title frame and all the attribute definitions (do not include the dimensions).
0.62
1.75
0.38 0.25
0.38
1.00 1.75
0.38 1.75
4.25 6.25
Fig. 7. Title Block for A to C Size Drawing Sheets Showing the Placement of Text Attributes. The Lower Figure Shows the Completed Block
When the block is inserted into a drawing, the operator is asked to enter the attribute values (such as company name, drawing title, etc.), which are placed into the title block at the predetermined location. The lower part of Fig. 7 shows a completed title block as it might appear inserted in a drawing. A complete drawing sheet could include several additional blocks, such as a sheet frame, a revision block, a parts list block, and any other supplementary blocks needed. Some of these blocks, such as the sheet frame, title, and parts list blocks, might be combined into a single block that could be inserted into a drawing at one time. Define a Default Drawing Configuration: Drawing features that are commonly used in a particular type of drawing can be set up in a template file so that frequently used settings, such as text and dimension styles, text size, drawing limits, initial view, and other default settings, are automatically set up when a new drawing is started. Different configurations can be defined for each frequently used drawing type, such as assembly, parts, or printed circuit drawings. When creating a new drawing, use one of the template files as a pattern or open a template file and use it to create the new drawing, saving it with a new name. Scaling Drawings: Normally, for fast and accurate drawing, it is easiest to draw most objects full scale, or with a 1:1 scale. This procedure greatly simplifies creation of the initial drawing, and ensures accuracy, because scale factors do not need to be calculated. If it becomes necessary to fit a large drawing onto a small drawing sheet (for example, to fit a 15 × 30 inch assembly onto a 11 × 17 inch, B-sized, drawing sheet), the drawing sheet can be scaled larger to fit the assembly size. Likewise, large drawing sheets can be scaled down to fit small drawings. The technique takes some practice, but it permits the drawing assembly to be treated full scale. If editing is required at a later date (to move something or add a hole in a particular location, for example), changes can be made without rescaling and dimensions can be taken directly from the unscaled drawing on the computer. Scaling Text on Drawing Sheets: It is usually desirable that text, dimensions, and a few other features on drawings stay a consistent size on each sheet, even when the drawing size is very different. The following procedure ensures that text and dimensions (other features
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Machinery's Handbook 27th Edition 1322
CAD/CAM
as well, if desired) will be the same size, from drawing to drawing without resorting to scaling the drawing to fit onto the drawing sheet. Create a drawing sheet having the exact dimensions of the actual sheet to be output (A, B, C, D, or E size, for example). Use text attributes, such as the title block illustrated in Fig. 7, to include any text that needs to be entered each time the drawing sheet is used. Create a block of the drawing sheet, including the text attributes, and save the block to disk. Repeat for each size drawing sheet required. Establish the nominal text and dimension size requirements for the drawing sheet when it is plotted full size (1:1 scale). This is the size text that will appear on a completed drawing. Use Table 1 as a guide to recommended text sizes of various drawing features. Table 1. Standard Sizes of Mechanical Drawing Lettering ANSI Y14.2M–1992 Inch Use For
Min. Letter Heights, (in)
Drawing title, drawing size, CAGE Code, drawing number, and revision lettera Section and view letters Zone letters and numerals in borders Drawing block headings All other characters
0.24 0.12 0.24 0.24 0.10 0.12
Metric Drawing Size
Min. Letter Heights, (mm)
Drawing Size
D, E, F, H, J, K A, B, C, G All All All All
6 3 6 6 2.5 3
A0, A1 A2, A3, A4 All All All All
a When used within the title block.
Test the sheet by setting the text size and dimension scale variables to their nominal values (established above) and place some text and dimensions onto the drawing sheet. Plot a copy of the drawing sheet and check that text and dimensions are the expected size. To use the drawing sheet, open a drawing to be placed on the sheet and insert the sheet block into the drawing. Scale and move the sheet block to locate the sheet relative to the drawing contents. When scaling the sheet, try to use whole-number scale factors (3:1, 4:1, etc.), if possible; this will make setting text size and dimension scale easier later on. Set the text-size variable equal to the nominal text size multiplied by the drawing sheet insertion scale (for example, for 0.24 text height on a drawing sheet scaled 3:1, the text-size variable will be set to 3 × 0.24 = 0.72). Likewise, set the dimension-scale variable equal to the nominal dimension size multiplied by the drawing sheet insertion scale. Once the text size and dimensions scale variables have been set, enter all the text and dimensions into the drawing. If text of another size is needed, multiply the new nominal text size by the sheet scale to get the actual size of the text to use in the drawing. Use Appropriate Detail: Excessive detail may reduce the effectiveness of the drawing, increase the drawing time on individual commands and the overall time spent on a drawing, and reduce performance and speed of the CAD program. Whenever possible, symbolic drawing elements should be used to represent more complicated parts of a drawing unless the appearance of that particular component is essential to the drawing. Drawing everything to scale often serves no purpose but to complicate a drawing and increase drawing time. The importance of detail depends on the purpose of a drawing, but detail in one drawing is unnecessary in another. For example, the slot size of a screw head (length and width) varies with almost every size of screw. If the purpose of a drawing is to show the type and location of the hardware, a symbolic representation of a screw is usually all that is required. The same is generally true of other screw heads, bolt threads, bolt head diameters and width across the flats, wire diameters, and many other hardware features. Drawing Exchange Standards.—The ability to transfer working data between different CAD, CAD/CAM, design analysis, and NC/CNC programs is one of the most important requirements of engineering drawing programs. Once an engineer, designer, draftsman, or machinist enters relevant product data into his or her machine (computer or machine tool), the information defining the characteristics of the product should be available to the others
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CAD/CAM
1323
involved in the project without recreating or reentering it. In view of manufacturing goals of reducing lead time and increasing productivity, concurrent engineering, and improved product performance, interchangeable data are a critical component in a CAD/CAM program. Depending on the requirements of a project, it may be entirely possible to transfer most if not all of the necessary product drawings from one drawing system to another. IGES stands for Initial Graphics Exchange Specification and is a means of exchanging or converting drawings and CAD files for use in a different computer graphics system. The concept is shown diagrammatically in Fig. 8. Normally, a drawing prepared on the computer graphics system supplied by company A would have to be redrawn before it would operate on the computer graphics system supplied by company B. However, with IGES, the drawing can be passed through a software package called a preprocessor that converts it into a standardized IGES format that can be stored on a magnetic disk. A postprocessor at company B is then used to convert the standard IGES format to that required for their graphics system. Both firms would be responsible for purchasing or developing their own preprocessors and postprocessors, to suit their own machines and control systems. Almost all the major graphics systems manufacturing companies today either have or are developing IGES preprocessor and postprocessor programs to convert software from one system to another.
Fig. 8.
DXF stands for Drawing Exchange Format and is a pseudo-standard file format used for exchanging drawings and associated information between different CAD and design analysis programs. Nearly all two- and three-dimensional CAD programs support some sort of drawing exchange through the use of DXF files, and most can read and export DXF files. There are, however, differences in the drawing features supported and the manner in which the DXF files are handled by each program. For example, if a 3-D drawing is exported in the DXF format and imported into a 2-D CAD program, some loss of information results because all the 3-D features are not supported by the 2-D program, so that most attempts to make a transfer between such programs fail completely. Most common drawing entities (lines, arcs, etc.) will transfer successfully, although other problems may occur. For example, drawing entities that are treated as a single object in an original drawing (such as blocks, hatch patterns, and symbols) may be divided into hundreds of individual components when converted into a DXF file. Consequently, such a drawing may become much more difficult to edit after it is transferred to another drawing program. ASCII stands for American Standard Code for Information Interchange. ASCII is a code system that describes the manner in which character-based information is stored in a computer system. Files stored in the ASCII format can be transferred easily between computers, even those using different operating systems. Although ASCII is not a drawing file format, many CAD drawing formats (DXF and IGES, for example) are ASCII files. In these files, the drawing information is stored according to a specific format using ASCII characters. ASCII files are often referred to as pure text files because they can be read and edited by simple text editors. HPGL, for Hewlett-Packard Graphics Language, is a format that was first developed for sending vector- (line-) based drawing information to pen plotters. The format is commonly used for sending drawing files to printers and plotters for printing. Because HPGL is a character-based format (ASCII), it can be transferred between computers easily. Normally, devices that recognize the HPGL format can print the files without using the program on which the file (a drawing, for example) was created.
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Machinery's Handbook 27th Edition 1324
CAD/CAM
STL is a CAD drawing format that is primarily used to send CAD drawings to rapid automated prototyping machines. STL is a mnemonic abbreviation for stereo-lithography, the technique that is used to create three-dimensional solid models directly from computergenerated drawings and for which the drawing format was originally developed. Most prototyping machines use 3-D CAD drawing files in STL format to create a solid model of the part represented by a drawing. STEP stands for Standard for Exchange of Product Model Data and is a series of existing and proposed ISO standards written to allow access to all the data that surround a product. It extends the IGES idea of providing a geometric data transfer to include all the other data that would need to be communicated about a product over its lifetime, and facilitates the use and accessibility of the product data. Although STEP is a new standard, software tools have been developed for converting data from the IGES to STEP format and from STEP to IGES. Rapid Automated Prototyping.—Rapid automated prototyping is a method of quickly creating an accurate three-dimensional physical model directly from a computerized conception of the part. The process is accomplished without machining or the removal of any material, but rather is a method of building up the model in three-dimensional space. The process makes it possible to easily and automatically create shapes that would be difficult or impossible to produce by any other method. Currently, production methods are able to produce models with an accuracy tolerance of ± 0.005 inch. Models are typically constructed of photoreactive polymer resins, nylon, polycarbonate or other thermoplastics, and investment casting wax. The model size is limited by the capability of the modeling machines to about 1 cubic foot at the present, however, large models can be built in sections and glued or otherwise fastened together. Much of the work and a large part of the cost associated with creating a physical model by rapid prototyping are in the initial creation of the CAD model. The model needs to be a 3D design model, built using wireframe, surface, or solid CAD modeling techniques. Many full-featured CAD systems support translation of drawing files into the STL format, which is the preferred file format for downloading CAD models to rapid prototyping machines. CAD programs without STL file format capability can use the IGES or DXF file format. This process can be time-consuming and expensive because additional steps may have to be taken by the service bureau to recreate features lost in converting the IGES or DXF file into STL format. If the design file has to be edited by a service bureau to recreate surfaces lost in the translation, unwanted changes to the model may occur, unnoticed. The safest route is to create a CAD model and export it directly into the STL format, leaving little chance for unexpected errors. Reverse STL generators are also available that will display a file saved in STL format or convert it into a form that can be imported into a CAD program. DNC.—DNC stands for Direct Numerical Control and refers to a method of controlling numerical control machines from a remote location by means of a link to a computer or computer network. In its simplest form, DNC consists of one NC or CNC machine linked by its serial port to a computer. The computer may be used to develop and store CNC part programs and to transfer part programs to the machine as required. DNC links are normally two-directional, meaning that the NC/CNC can be operated from a computer terminal and the computer can be operated or ordered to supply data to the NC/CNC from the machine's control panel. The number of machines that can be connected to a DNC network depends on the network's capability; in theory, any number of machines can be attached, and controlled. The type of network depends on the individual DNC system, but most industry standard network protocols are supported, so DNC nodes can be connected to existing networks very easily. Individual NC/CNC machines on a network can be controlled locally, from a network terminal in another building, or even from a remote location miles away through phone or leased lines.
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Machinery's Handbook 27th Edition CAM/CAD
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Machinery Noise.—Noise from machinery or mechanical systems can be controlled to some degree in the design or development stage if quantified noise criteria are provided the designer. Manufacturers and consumers may also use the same information in deciding whether the noise generated by a machine will be acceptable for a specific purpose. Noise criteria for may be classified as follows: 1) relating to the degree of interference with speech communications; 2) relating to physiological damage to humans, especially hearing; and 3) those relating to psychological disturbances in people exposed to noise. Sound Level Specifications: Noise criteria generally are specified in some system of units representing sound levels. One commonly used system specifies sound levels in units called decibels on the “A” scale, written dBA. The dBA scale designates a sound level system weighted to match human hearing responses to various frequencies and loudness. For example, to permit effective speech communication, typical criteria for indoor maximum noise levels are: meeting and conference rooms, 42 dBA; private offices and small meeting rooms, 38 to 47 dBA; supervisors' offices and reception rooms, 38 to 52 dBA; large offices and cafeterias, 42 to 52 dBA; laboratories, drafting rooms, and general office areas, 47 to 56 dBA; maintenance shops, computer rooms, and washrooms, 52 to 61 dBA; control and electrical equipment rooms, 56 to 66 dBA; and manufacturing areas and foremen’s offices, 66 dBA. Similarly, there are standards and recommendations for daily permissible times of exposure at various steady sound levels to avoid hearing damage. For a working shift of 8 hours, a steady sound level of 90 dBA is the maximum generally permitted, with marked reduction in allowable exposure times for higher sound levels.* Measuring Machinery Noise.—The noise level produced by a single machine can be measured by using a standard sound level meter of the handheld type set to the dBA scale. However, when other machines are running at the same time, or when there are other background noises, the noise of the machine cannot be measured directly. In such cases, two measurements, taken as follows, can be used to calculate the noise level of the individual machine. The meter should be held at arm's length and well away from any bystanders to avoid possible significant error up to 5 dBA. Step 1. At the point of interest, measure the total noise, T, in decibels; that is, measure the noise of the shop and the machine in question when all machines are running; Step 2. Turn off the machine in question and measure B, the remaining background noise level; Step 3. Calculate M, the noise of the machine alone, M = 10log10[10(T/10) − 10(B/10)]. T-----
B-----
M = 10 log ⎛ 10 10 – 10 10⎞ ⎝ ⎠
Example 1:With a machine running, the sound level meter reads 51 decibels as the total shop noise T; and with the machine shut off the meter reads 49 decibels as the remaining background noise B. What is the noise level M of the machine alone? 51-----
49-----
M = 10 log ⎛⎝ 10 10 – 10 10⎞⎠ = 46.7 decibels dBA
Example 2:If in Example 1 the remaining background noise level B was 41 decibels instead of 49, what is the noise level of the machine alone? 51 ------
41 ------
M = 10 log ⎛ 10 10 – 10 10⎞ = 50.5 decibels dBA ⎝ ⎠
Note: From this example it is evident that when the background noise level B is approximately 10 or more decibels lower than the total noise level T measured at the machine in question, then the background noise does not contribute significantly to the sound level at the machine and, for practical purposes, M = T and no calculation is required. *
After April 1983, if employee noise exposures equal or exceed an 8-hour, time-weighted average sound level of 85 dB, OSHA requires employers to administer an effective hearing conservation program.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TABLE OF CONTENTS MANUFACTURING PROCESSES PUNCHES, DIES, AND PRESS WORK 1329 Punches and Dies 1329 Clearance 1330 Lubricants for Press Work 1330 Annealing Drawn Shells 1330 Drawing Rectangular Shapes 1330 Speeds and Pressures for Presses 1331 Pressure Required for Punching 1331 Shut Height of Press 1331 Drawn Shells 1331 Diameters of Shell Blanks 1333 Drawn Cylindrical Shells 1334 Depth and Diameter Reductions 1335 Sheet Metal 1335 Lengths of Straight Stock 1339 Other Bending Allowance Formulas 1339 Joining and Edging 1344 Fine Blanking 1346 Steel Rule Dies 1347 Making Steel Rule Dies
ELECTRICAL DISCHARGE MACHINING 1349 EDM Terms 1351 EDM Process 1354 Electrical Control Adjustments 1355 Workpiece Materials 1355 Characteristics of Materials 1355 Electrode Materials 1356 Types of Electrodes 1357 Making Electrodes 1359 Wire EDM
IRON AND STEEL CASTINGS 1360 Material Properties 1360 Gray Cast Iron 1360 White Cast Iron 1360 Chilled Cast Iron 1360 Alloy Cast Iron 1361 Malleable-iron Castings 1361 Ductile Cast Iron 1362 Steel Castings 1362 Carbon Steel Castings 1363 Mechanical Properties 1363 Alloy Steel Castings 1364 Heat-Resistant Steel Castings
IRON AND STEEL CASTINGS (Continued)
1364 1365 1367 1368 1368 1368 1368 1369 1369 1369 1369 1370 1370 1371 1371 1371 1372 1372 1372 1372 1373 1373 1373 1373 1374 1374 1374 1375 1375 1375 1375 1376 1376 1376 1376 1376 1377 1377 1377 1379 1379 1379 1379
Corrosion-Resistant Steel Castings Casting of Metals Removal of Gates and Risers Blast Cleaning of Castings Heat Treatment of Steel Castings Estimating Casting Weight Woods for Patterns Selection of Wood Pattern Varnish Shrinkage Allowances Metal Patterns Weight of Casting Die Casting Porosity Designing Die Castings Alloys Used for Die Casting Aluminum-Base Alloys Zinc-Base Alloys Copper-Base Alloys Magnesium-Base Alloys Tin-Base Alloys Lead-Base Alloys Dies for Die-Casting Machines Die-Casting Bearing Metal Injection Molding of Metal Precision Investment Casting Casting Materials Master Mold Shrinkage Allowances Casting Dimensions Investment Materials Casting Operations Investment Removal Investment Castings Casting Weights and Sizes Design for Investment Casting Casting Milling Cutters Extrusion of Metals Basic Process Powder Metallurgy Advantages of Powder Metallurgy Limiting Factors Design of Briquetting Tools
1326
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Machinery's Handbook 27th Edition TABLE OF CONTENTS MANUFACTURING PROCESSES SOLDERING AND BRAZING
WELDING (Continued)
1380 Soldering 1380 Forms Available 1380 Fluxes for Soldering 1380 Methods of Application 1382 Ultrasonic Fluxless Soldering 1382 Brazing 1382 Filler Metals 1382 Brazing Filler Metals 1382 Brazing Filler Metals 1382 Selection of Filler Metals 1386 Fluxes for Brazing 1387 Steadying Work 1387 Supplying Heat 1387 Symbol Application
WELDING 1389 Welding Electrodes and Fluxes 1389 Processes 1390 Gas Metal Arc Welding (GMAW) 1390 Electrode Diameters 1391 Maximum Deposition Rates 1391 GMAW Welding of Sheet Steel 1391 Application of Shielding Gases 1393 Welding Controls 1395 GMAW Spray Transfer 1395 Deposition Rates of Electrodes 1397 Optimum Settings for GMAW 1397 Spray Transfer Voltage 1398 Flux-Cored Arc Welding 1398 Flux-Cored Welding Electrodes 1398 Gas-Shielded Electrodes 1399 Settings for FCAW Electrodes 1399 Weld Requirements 1399 Selecting an FCAW Electrode 1400 FCAW Electrodes 1401 Contact Tip Recess 1401 Porosity and Worm Tracks 1401 Welding with Various Diameter 1402 High-Deposition Electrodes 1403 Deposition Rates for Vertical Up Welding 1403 Deposition Rates of Flat and Horizontal Welds 1403 Electrode Diameters and Deposition Rates 1404 Shielding Gases and FCAW Electrodes
1405 Shielded Metal Arc Welding 1406 ANSI/AWS Standard 1406 AWS E60XX Electrodes 1408 AWS E70XX Electrodes 1409 Gas Tungsten Arc Welding 1409 GTAW Welding Current 1411 Tungsten Electrode Type 1412 Selection of GTAW 1412 Tungsten Electrode Compositions 1412 Electrode and Current Selection 1413 Current Ranges for GTAW Electrodes 1413 Current Ranges for EWP and EWZ and GTAW Electrodes 1414 Filler Metals 1414 Shielding Gases 1414 Plasma Arc Welding (PAW) 1414 Gases for Plasma Arc Welding 1415 Shielding Gases 1415 PAW Welding Equipment 1416 Applications 1416 Welding Aluminum 1417 Plasma Arc Surface Coating 1418 Plasma Arc Cutting of Metals 1418 Precision Plasma Arc Cutting 1418 Flame Cutting of Metals 1418 Arc Cutting 1419 The Cutting Torch 1419 Adjustment of Cutting Torch 1419 Metals That Can Be Cut 1419 Cutting Stainless Steel 1419 Cutting Cast Iron 1419 Mechanically Guided Torches 1419 Cutting Steel Castings 1420 Thickness of Metal 1420 Hard Facing 1420 Hard-Facing Materials 1420 High-Speed Steels 1421 Austenitic Manganese Steels 1421 Austenitic High-Chromium Irons 1421 Cobalt-Base Alloys 1422 Copper-Base Alloys 1423 Nickel-Chromium-Boron Alloys 1424 Chromium Plating 1424 Electron-Beam (EB) Welding 1425 Pipe Welding 1428 Use of Flux-cored Electrodes 1428 Complete Weld Fusion 1429 Other Methods
1327
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TABLE OF CONTENTS MANUFACTURING PROCESSES WELDING
LASERS
(Continued)
(Continued)
1429 Pipe Welding Procedure 1429 Thick-Walled, Carbon-Steel Pipes, Root Welding 1430 Thick-Walled, Carbon-Steel Pipes, Fill and Cover Welds 1431 Thin-Walled Carbon Steel Pipes, Root, Fill and Cover Pass 1432 Weld and Welding Symbols 1432 ANSI Weld and Welding Symbols 1433 Basic Weld Symbols 1434 Supplementary Weld Symbols 1434 Welding Codes, Rules, Regulations, and Specifications 1435 Letter Designations for Welding 1436 ANSI Welding Symbols 1441 Nondestructive Testing 1441 Symbols
1454 Heat Treatment with Lasers 1454 Materials Applicability 1454 Hardening Rates 1454 Cladding with Lasers 1455 Marking with Lasers 1455 Mask Marking 1455 Scanned-Beam Marking
LASERS 1443 1443 1443 1444 1445 1445 1446 1446 1447 1447 1448 1448 1449 1450 1451 1451 1452 1452 1452 1453 1453 1453 1453 1454 1454
Introduction Laser Light Laser Beams Beam Focusing Types of Industrial Lasers Industrial Laser Systems Safety Laser Beam/Material Interaction Thermal Properties of Workpieces Cutting Metal with Lasers Beam Assistance Techniques Cut Edge Roughness Heat-Affected Zones Cutting of Nonmetals Welding with Lasers Laser Welding Theory Welded Joint Design Welding Rates Processing Gas Drilling with Lasers Laser Drilling Theory Direct Drilling Percussive Drilling Trepanning Drilling Rates
FINISHING OPERATIONS 1456 Power Brush Finishing 1456 Description of Brushes 1456 Use of Brushes 1456 Deburring and Producing a Radius 1457 Eliminating Undesirable Conditions 1457 Characteristics in Power Brush 1457 Polishing and Buffing 1457 Polishing Wheels 1460 Polishing Operations and Abrasives 1460 Buffing Wheels 1460 Speed of Polishing Wheels 1461 Grain Numbers of Emery 1461 Grades of Emery Cloth 1461 Etching and Etching Fluids 1461 Etching Fluids 1462 Conversion Coatings and the Coloring of Metals 1462 Passivation of Copper 1462 Coloring of Copper Alloys 1463 Coloring of Iron and Steel 1463 Anodizing Aluminum Alloys 1464 Magnesium Alloys 1464 Titanium Alloys 1464 Plating 1464 Surface Coatings 1472 Flame Spraying Process
1328
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Machinery's Handbook 27th Edition MANUFACTURING PROCESSES
1329
PUNCHES, DIES, AND PRESS WORK Clearance between Punches and Dies.—The amount of clearance between a punch and die for blanking and perforating is governed by the thickness and kind of stock to be operated upon. For thin material, the punch should be a close sliding fit to prevent ragged edges, but for heavier stock, there should be some clearance. The clearance between the punch and die in cutting heavy material reduces the pressure required for the punching operation and the danger of breaking the punch. Meaning of the Term “Clearance”.—There is a difference of opinion among diemakers as to the method of designating clearance. The prevailing practice of fifteen firms specializing in die work is as follows: Ten of these firms define clearance as the space between the punch and die on one side, or one-half the difference between the punch and die sizes. The remaining five firms consider clearance as the total difference between the punch and die sizes; for example, if the die is round, clearance equals die diameter minus punch diameter. The advantage of designating clearance as the space on each side is particularly evident with dies of irregular form or of angular shape. Although the practice of designating clearance as the difference between the punch and die diameters may be satisfactory for round dies, it leads to confusion when the dies are of unsymmetrical forms. The term “clearance” should not be used in specifications without indicating clearly just what it means. According to one die manufacturer, the term “cutting clearance” is used to indicate the space between the punch and die on each side, and the term “die clearance” refers to the angular clearance provided below the cutting edge so that the parts will fall easily through the die. The term “clearance” as here used means the space on one side only; hence, for round dies, clearance equals die radius minus punch radius. Clearances Generally Allowed.—For brass and soft steel, most dies are given a clearance on one side equal to the stock thickness multiplied by 0.05 or 0.06; but one-half of this clearance is preferred for some classes of work, and a clearance equal to the stock thickness multiplied by 0.10 may give the cleanest fracture for certain other operations such as punching holes in ductile steel boiler plate. Where Clearance Is Applied.—Whether clearance is deducted from the diameter of the punch or added to the diameter of the die depends upon the nature of the work. If a blank of given size is required, the die is made to that size and the punch is made smaller. Inversely, when holes of a given size are required, the punch is made to the diameter wanted and the die is made larger. Therefore, for blanking to a given size, the clearance is deducted from the size of the punch, and for perforating, the clearance is added to the size of the die. Effect of Clearance on Working Pressure.—Clearance affects not only the smoothness of the fracture, but also the pressure required for punching or blanking. This pressure is greatest when the punch diameter is small compared to the thickness of the stock. In one test, for example, a punching pressure of about 32,000 pounds was required to punch 3⁄4inch holes into 5⁄16-inch mild steel plate when the clearance was about 10 per cent. With a clearance of about 4.5 per cent, the pressure increased to 33,000 pounds and a clearance of 2.75 per cent resulted in a pressure of 34,500 pounds. Soft ductile metal requires more clearance than hard metal, although it has been common practice to increase the clearance for harder metals. In punching holes in fairly hard steel, a clean fracture was obtained with a clearance of only 0.03 times stock thickness. Angular Clearance for Dies.—The angular clearance ordinarily used in a blanking die varies from 1 to 2 degrees, although dies intended for producing a comparatively small number of blanks are sometimes given a clearance angle of 4 or 5 degrees to facilitate making the die quickly. When large numbers of blanks are required, a clearance of about 1 degree is used.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1330
PUNCHES, DIES, AND PRESS WORK
There are two methods of giving clearance to dies: In one method, the clearance extends to the top face of the die; and in the other, there is a space about 1⁄8 inch below the cutting edge that is left practically straight, or having a very small amount of clearance. For very soft metal, such as soft, thin brass, the first method is employed, but for harder material, such as hard brass, steel, etc., it is better to have a very small clearance for a short distance below the cutting edge. When a die is made in this way, thousands of blanks can be cut with little variation in their size, as grinding the die face will not enlarge the hole to any appreciable extent. Lubricants for Press Work.—Blanking dies used for carbon and low-alloy steels are often run with only residual mill lubricant, but will last longer if lightly oiled. Higher alloy and stainless steels require thicker lubricants. Kerosene is usually used with aluminum. Lubricant thickness needs to be about 0.0001 in. and can be obtained with about 1 pint of fluid to cover 500 sq. ft of material. During successive strokes, metal debris adheres to the punch and may accelerate wear, but damage may be reduced by application of the lubricant to the sheet or strip by means of rollers or spray. High-speed blanking may require heavier applications or a continuous airless spraying of oil. For sheet thicker than 1⁄8 in. and for stainless steel, high-pressure lubricants containing sulfurs and chlorines are often used. Shallow drawing and forming of steel can be done with low-viscosity oils and soap solutions, but deeper draws require light- to medium-viscosity oils containing fats and such active elements as sulfur or phosphorus, and mineral fillers such as chalk or mica. Deep drawing often involves ironing or thinning of the walls by up to 35 per cent, and thick oils containing high proportions of chemically active compounds are used. Additives used in drawing compounds are selected for their ability to maintain a physical barrier between the tool surfaces and the metal being shaped. Dry soaps and polymer films are frequently used for these purposes. Aluminum can be shallow drawn with oils of low to medium viscosity, and for deep drawing, tallow may be added, also wax or soap suspensions for very large reductions. Annealing Drawn Shells.—When drawing steel, iron, brass, or copper, annealing is necessary after two or three draws have been made, because the metal is hardened by the drawing process. For steel and brass, anneal between alternate reductions, at least. Tin plate or stock that cannot be annealed without spoiling the finish must ordinarily be drawn to size in one or two operations. Aluminum can be drawn deeper and with less annealing than the other commercial metals, provided the proper grade is used. If it is necessary to anneal aluminum, it should be heated in a muffle furnace, care being taken to see that the temperature does not exceed 700 degrees F. Drawing Brass.—When drawing brass shells or cup-shaped articles, it is usually possible to make the depth of the first draw equal to the diameter of the shell. By heating brass to a temperature just below what would show a dull red in a dark room, it is possible to draw difficult shapes, otherwise almost impossible, and to produce shapes with square corners. Drawing Rectangular Shapes.—When square or rectangular shapes are to be drawn, the radius of the corners should be as large as possible, because defects usually occur in the corners when drawing. Moreover, the smaller the radius, the less the depth that can be obtained in the first draw. The maximum depths that can be drawn with corners of a given radii are approximately as follows: With a radius of 3⁄32 to 3⁄16 inch, depth of draw, 1 inch; radius3⁄16 to 3⁄8 inch, depth 11⁄2 inches; radius3⁄8 to 1⁄2 inch, depth 2 inches; and radius1⁄2 to 3⁄4 inch, depth 3 inches. These figures are taken from actual practice and can doubtless be exceeded slightly when using metal prepared for the process. If the box needs to be quite deep and the radius is quite small, two or more drawing operations will be necessary. Speeds and Pressures for Presses.—The speeds for presses equipped with cutting dies depend largely upon the kind of material being worked, and its thickness. For punching
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Machinery's Handbook 27th Edition PUNCHES, DIES, AND PRESS WORK
1331
and shearing ordinary metals not over 1⁄4 inch thick, the speeds usually range between 50 and 200 strokes per minute, 100 strokes per minute being a fair average. For punching metal over 1⁄4 inch thick, geared presses with speeds ranging from 25 to 75 strokes per minute are commonly employed. The cutting pressures required depend upon the shearing strength of the material, and the actual area of the surface being severed. For round holes, the pressure required equals the circumference of the hole × the thickness of the stock × the shearing strength. To allow for some excess pressure, the tensile strength may be substituted for the shearing strength; the tensile strength for these calculations may be roughly assumed as follows: Mild steel, 60,000; wrought iron, 50,000; bronze, 40,000; copper, 30,000; aluminum, 20,000; zinc, 10,000; and tin and lead, 5,000 pounds per square inch. Pressure Required for Punching.—The formula for the force in tons required to punch a circular hole in sheet steel is πDST/2000, where S = the shearing strength of the material in lb/in.2, T = thickness of the steel in inches, and 2000 is the number of lb in 1 ton. An approximate formula is DT × 80, where D and T are the diameter of the hole and the thickness of the steel, respectively, both in inches, and 80 is a factor for steel. The result is the force in tons. Example:Find the pressure required to punch a hole, 2 inches in diameter, through 1⁄4-in. thick steel. By applying the approximate formula, 2 × 1⁄4 × 80 = 40 tons. If the hole is not circular, replace the hole diameter with the value of one-third of the perimeter of the hole to be punched. Example:Find the pressure required to punch a 1-inch square hole in 1⁄4-in. thick steel. The total length of the hole perimeter is 4 in. and one-third of 4 in. is 11⁄3 in., so the force is 11⁄3 × 1⁄4 × 80 = 26 2⁄3 tons. The corresponding factor for punching holes in brass is 65 instead of 80. So, to punch a hole measuring 1 by 2 inches in 1⁄4-in. thick brass sheet, the factor for hole size is the perimeter length 6 ÷ 3 = 2, and the formula is 2 × 1⁄4 × 65 = 32 1⁄2 tons. Shut Height of Press.—The term “shut height,” as applied to power presses, indicates the die space when the slide is at the bottom of its stroke and the slide connection has been adjusted upward as far as possible. The “shut height” is the distance from the lower face of the slide, either to the top of the bed or to the top of the bolster plate, there being two methods of determining it; hence, this term should always be accompanied by a definition explaining its meaning. According to one press manufacturer, the safest plan is to define “shut height” as the distance from the top of the bolster to the bottom of the slide, with the stroke down and the adjustment up, because most dies are mounted on bolster plates of standard thickness, and a misunderstanding that results in providing too much die space is less serious than having insufficient die space. It is believed that the expression “shut height” was applied first to dies rather than to presses, the shut height of a die being the distance from the bottom of the lower section to the top of the upper section or punch, excluding the shank, and measured when the punch is in the lowest working position. Diameters of Shell Blanks.—The diameters of blanks for drawing plain cylindrical shells can be obtained from Table 1 on the following pages, which gives a very close approximation for thin stock. The blank diameters given in this table are for sharp-cornered shells and are found by the following formula in which D = diameter of flat blank; d = diameter of finished shell; and h = height of finished shell. D =
2
d + 4dh
(1)
Example:If the diameter of the finished shell is to be 1.5 inches, and the height, 2 inches, the trial diameter of the blank would be found as follows:
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1332
PUNCHES, DIES, AND PRESS WORK D =
2
1.5 + 4 × 1.5 × 2 =
14.25 = 3.78 inches
For a round-cornered cup, the following formula, in which r equals the radius of the corner, will give fairly accurate diameters, provided the radius does not exceed, say, 1⁄4 the height of the shell: D =
2
d + 4dh – r
(2)
These formulas are based on the assumption that the thickness of the drawn shell is the same as the original thickness of the stock, and that the blank is so proportioned that its area will equal the area of the drawn shell. This method of calculating the blank diameter is quite accurate for thin material, when there is only a slight reduction in the thickness of the metal incident to drawing; but when heavy stock is drawn and the thickness of the finished shell is much less than the original thickness of the stock, the blank diameter obtained from Formula (1) or (2) will be too large, because when the stock is drawn thinner, there is an increase in area. When an appreciable reduction in thickness is to be made, the blank diameter can be obtained by first determining the “mean height” of the drawn shell by the following formula. This formula is only approximately correct, but will give results sufficiently accurate for most work: htM = ---T
(3)
where M = approximate mean height of drawn shell; h = height of drawn shell; t = thickness of shell; and T = thickness of metal before drawing. After determining the mean height, the blank diameter for the required shell diameter is obtained from the table previously referred to, the mean height being used instead of the actual height. Example:Suppose a shell 2 inches in diameter and 3 3⁄4 inches high is to be drawn, and that the original thickness of the stock is 0.050 inch, and the thickness of drawn shell, 0.040 inch. To what diameter should the blank be cut? Obtain the mean height from Formula (3) : × 0.040- = 3 inches M = ht ----- = 3.75 ----------------------------T 0.050 According to the table, the blank diameter for a shell 2 inches in diameter and 3 inches high is 5.29 inches. Formula (3) is accurate enough for all practical purposes, unless the reduction in the thickness of the metal is greater than about one-fifth the original thickness. When there is considerable reduction, a blank calculated by this formula produces a shell that is too long. However, the error is in the right direction, as the edges of drawn shells are ordinarily trimmed. If the shell has a rounded corner, the radius of the corner should be deducted from the figures given in the table. For example, if the shell referred to in the foregoing example had a corner of 1⁄4-inch radius, the blank diameter would equal 5.29 − 0.25 = 5.04 inches. Another formula that is sometimes used for obtaining blank diameters for shells, when there is a reduction in the thickness of the stock, is as follows: D =
2 2 2 a + ( a – b ) h--t
Copyright 2004, Industrial Press, Inc., New York, NY
(4)
Machinery's Handbook 27th Edition
Table 1. Diameters of Blanks for Drawn Cylindrical Shells Diam. of Shell
1⁄ 4
1⁄ 2
3⁄ 4
1
1 1⁄4
1 1⁄2
1 3⁄4
2
2 1⁄4
Height of Shell 2 1⁄2
2 3⁄4
3 1⁄4
3 1⁄2
3 3⁄4
1⁄ 4
0.56
0.75
0.90
1.03
1.14
1.25
1.35
1.44
1.52
1.60
1.68
1.75
1.82
1.89
1.95
2.01
2.14
2.25
2.36
2.46
1⁄ 2
0.87
1.12
1.32
1.50
1.66
1.80
1.94
2.06
2.18
2.29
2.40
2.50
2.60
2.69
2.78
2.87
3.04
3.21
3.36
3.50
3⁄ 4
1.14
1.44
1.68
1.89
2.08
2.25
2.41
2.56
2.70
2.84
2.97
3.09
3.21
3.33
3.44
3.54
3.75
3.95
4.13
4.31
1
1.41
1.73
2.00
2.24
2.45
2.65
2.83
3.00
3.16
3.32
3.46
3.61
3.74
3.87
4.00
4.12
4.36
4.58
4.80
5.00
1 1⁄4
1.68
2.01
2.30
2.56
2.79
3.01
3.21
3.40
3.58
3.75
3.91
4.07
4.22
4.37
4.51
4.64
4.91
5.15
5.39
5.62
1 1⁄2
1.94
2.29
2.60
2.87
3.12
3.36
3.57
3.78
3.97
4.15
4.33
4.50
4.66
4.82
4.98
5.12
5.41
5.68
5.94
6.18
1 3⁄4
2.19
2.56
2.88
3.17
3.44
3.68
3.91
4.13
4.34
4.53
4.72
4.91
5.08
5.26
5.41
5.58
5.88
6.17
6.45
6.71
2
2.45
2.83
3.16
3.46
3.74
4.00
4.24
4.47
4.69
4.90
5.10
5.29
5.48
5.66
5.83
6.00
6.32
6.63
6.93
7.21
2 1⁄4
2.70
3.09
3.44
3.75
4.04
4.31
4.56
4.80
5.03
5.25
5.46
5.66
5.86
6.05
6.23
6.41
6.75
7.07
7.39
7.69
2 1⁄2
2.96
3.36
3.71
4.03
4.33
4.61
4.87
5.12
5.36
5.59
5.81
6.02
6.22
6.42
6.61
6.80
7.16
7.50
7.82
8.14
2 3⁄4
3.21
3.61
3.98
4.31
4.62
4.91
5.18
5.44
5.68
5.92
6.15
6.37
6.58
6.79
6.99
7.18
7.55
7.91
8.25
8.58
3
3.46
3.87
4.24
4.58
4.90
5.20
5.48
5.74
6.00
6.25
6.48
6.71
6.93
7.14
7.35
7.55
7.94
8.31
8.66
9.00
3 1⁄4
3.71
4.13
4.51
4.85
5.18
5.48
5.77
6.04
6.31
6.56
6.80
7.04
7.27
7.49
7.70
7.91
8.31
8.69
9.06
9.41
3 1⁄2
3.97
4.39
4.77
5.12
5.45
5.77
6.06
6.34
6.61
6.87
7.12
7.36
7.60
7.83
8.05
8.26
8.67
9.07
9.45
9.81
3 3⁄4
4.22
4.64
5.03
5.39
5.73
6.05
6.35
6.64
6.91
7.18
7.44
7.69
7.92
8.16
8.38
8.61
9.03
9.44
9.83
10.20
4
4.47
4.90
5.29
5.66
6.00
6.32
6.63
6.93
7.21
7.48
7.75
8.00
8.25
8.49
8.72
8.94
9.38
9.80
10.20
10.58
4 1⁄4
4.72
5.15
5.55
5.92
6.27
6.60
6.91
7.22
7.50
7.78
8.05
8.31
8.56
8.81
9.04
9.28
9.72
10.15
10.56
10.96 11.32
3
4
4 1⁄2
5
5 1⁄2
6
4.98
5.41
5.81
6.19
6.54
6.87
7.19
7.50
7.79
8.08
8.35
8.62
8.87
9.12
9.37
9.60
10.06
10.50
10.92
5.22
5.66
6.07
6.45
6.80
7.15
7.47
7.78
8.08
8.37
8.65
8.92
9.18
9.44
9.69
9.93
10.40
10.84
11.27
11.69
5
5.48
5.92
6.32
6.71
7.07
7.42
7.75
8.06
8.37
8.66
8.94
9.22
9.49
9.75
10.00
10.25
10.72
11.18
11.62
12.04
5 1⁄4
5.73
6.17
6.58
6.97
7.33
7.68
8.02
8.34
8.65
8.95
9.24
9.52
9.79
10.05
10.31
10.56
11.05
11.51
11.96
12.39
5 1⁄2
5.98
6.42
6.84
7.23
7.60
7.95
8.29
8.62
8.93
9.23
9.53
9.81
10.08
10.36
10.62
10.87
11.37
11.84
12.30
12.74
6.23
6.68
7.09
7.49
7.86
8.22
8.56
8.89
9.21
9.52
9.81
10.10
10.38
10.66
10.92
11.18
11.69
12.17
12.63
13.08
6
6.48
6.93
7.35
7.75
8.12
8.49
8.83
9.17
9.49
9.80
10.10
10.39
10.68
10.95
11.23
11.49
12.00
12.49
12.96
13.42
Copyright 2004, Industrial Press, Inc., New York, NY
1333
5 3⁄4
PUNCHES, DIES, AND PRESS WORK
4 1⁄2 4 3⁄4
Machinery's Handbook 27th Edition 1334
PUNCHES, DIES, AND PRESS WORK
In this formula, D = blank diameter; a = outside diameter; b = inside diameter; t = thickness of shell at bottom; and h = depth of shell. This formula is based on the volume of the metal in the drawn shell. It is assumed that the shells are cylindrical, and no allowance is made for a rounded corner at the bottom, or for trimming the shell after drawing. To allow for trimming, add the required amount to depth h. When a shell is of irregular cross-section, if its weight is known, the blank diameter can be determined by the following formula: W(5) D = 1.1284 ----wt where D = blank diameter in inches; W = weight of shell; w = weight of metal per cubic inch; and t = thickness of the shell. In the construction of dies for producing shells, especially of irregular form, a common method to be used is to make the drawing tool first. The actual blank diameter then can be determined by trial. One method is to cut a trial blank as near to size and shape as can be estimated. The outline of this blank is then scribed on a flat sheet, after which the blank is drawn. If the finished shell shows that the blank is not of the right diameter or shape, a new trial blank is cut either larger or smaller than the size indicated by the line previously scribed, this line acting as a guide. If a model shell is available, the blank diameter can also be determined as follows: First, cut a blank somewhat large, and from the same material used for making the model; then, reduce the size of the blank until its weight equals the weight of the model. Depth and Diameter Reductions of Drawn Cylindrical Shells.—The depth to which metal can be drawn in one operation depends upon the quality and kind of material, its thickness, the slant or angle of the dies, and the amount that the stock is thinned or “ironed” in drawing. A general rule for determining the depth to which cylindrical shells can be drawn in one operation is as follows: The depth or length of the first draw should never be greater than the diameter of the shell. If the shell is to have a flange at the top, it may not be practicable to draw as deeply as is indicated by this rule, unless the metal is extra good, because the stock is subjected to a higher tensile stress, owing to the larger blank needed to form the flange. According to another rule, the depth given the shell on the first draw should equal one-third the diameter of the blank. Ordinarily, it is possible to draw sheet steel of any thickness up to 1⁄4 inch, so that the diameter of the first shell equals about sixtenths of the blank diameter. When drawing plain shells, the amount that the diameter is reduced for each draw must be governed by the quality of the metal and its susceptibility to drawing. The reduction for various thicknesses of metal is about as follows: Approximate thickness of sheet steel
1⁄ 16
1⁄ 8
3⁄ 16
1⁄ 4
5⁄ 16
Possible reduction in diameter for each succeeding step, per cent
20
15
12
10
8
For example, if a shell made of 1⁄16-inch stock is 3 inches in diameter after the first draw, it can be reduced 20 per cent on the next draw, and so on until the required diameter is obtained. These figures are based upon the assumption that the shell is annealed after the first drawing operation, and at least between every two of the following operations. Necking operations—that is, the drawing out of a short portion of the lower part of the cup into a long neck—may be done without such frequent annealings. In double-action presses, where the inside of the cup is supported by a bushing during drawing, the reductions possible may be increased to 30, 24, 18, 15, and 12 per cent, respectively. (The latter figures may also be used for brass in single-action presses.) When a hole is to be pierced at the bottom of a cup and the remaining metal is to be drawn after the hole has been pierced or punched, always pierce from the opposite direction to
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition PUNCHES, DIES, AND PRESS WORK
1335
that in which the stock is to be drawn after piercing. It may be necessary to machine the metal around the pierced hole to prevent the starting of cracks or flaws in the subsequent drawing operations. The foregoing figures represent conservative practice and it is often possible to make greater reductions than are indicated by these figures, especially when using a good drawing metal. Taper shells require smaller reductions than cylindrical shells, because the metal tends to wrinkle if the shell to be drawn is much larger than the punch. The amount that the stock is “ironed” or thinned out while being drawn must also be considered, because a reduction in gage or thickness means greater force will be exerted by the punch against the bottom of the shell; hence the amount that the shell diameter is reduced for each drawing operation must be smaller when much ironing is necessary. The extent to which a shell can be ironed in one drawing operation ranges between 0.002 and 0.004 inch per side, and should not exceed 0.001 inch on the final draw, if a good finish is required. Allowances for Bending Sheet Metal.—In bending steel, brass, bronze, or other metals, the problem is to find the length of straight stock required for each bend; these lengths are added to the lengths of the straight sections to obtain the total length of the material before bending. If L = length in inches, of straight stock required before bending; T = thickness in inches; and R = inside radius of bend in inches: For 90° bends in soft brass and soft copper see Table 2 or: L = ( 0.55 × T ) + ( 1.57 × R ) (1) For 90° bends in half-hard copper and brass, soft steel, and aluminum see Table 3 or: L = ( 0.64 × T ) + ( 1.57 × R ) (2) For 90° bends in bronze, hard copper, cold-rolled steel, and spring steel see Table 4 or: L = ( 0.71 × T ) + ( 1.57 × R ) (3) Angle of Bend Other Than 90 Degrees: For angles other than 90 degrees, find length L, using tables or formulas, and multiply L by angle of bend, in degrees, divided by 90 to find length of stock before bending. In using this rule, note that angle of bend is the angle through which the material has actually been bent; hence, it is not always the angle as given on a drawing. To illustrate, in Fig. 1, the angle on the drawing is 60 degrees, but the angle of bend A is 120 degrees (180 − 60 = 120); in Fig. 2, the angle of bend A is 60 degrees; in Fig. 3, angle A is 90 − 30 = 60 degrees. Formulas (1), (2), and (3) are based on extensive experiments of the Westinghouse Electric Co. They apply to parts bent with simple tools or on the bench, where limits of ± 1⁄64 inch are specified. If a part has two or more bends of the same radius, it is, of course, only necessary to obtain the length required for one of the bends and then multiply by the number of bends, to obtain the total allowance for the bent sections.
Fig. 1.
Fig. 2.
Fig. 3.
Example, Showing Application of Formulas:Find the length before bending of the part illustrated by Fig. 4. Soft steel is to be used. For bend at left-hand end (180-degree bend) L = [ ( 0.64 × 0.125 ) + ( 1.57 × 0.375 ) ] × 180 --------- = 1.338 90
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
1336
Table 2. Lengths of Straight Stock Required for 90-Degree Bends in Soft Copper and Soft Brass Radius R of Bend, Inches
Thickness T of Material, Inch 1⁄ 32
3⁄ 64
1⁄ 16
5⁄ 64
3⁄ 32
1⁄ 8
5⁄ 32
3⁄ 16
7⁄ 32
1⁄ 4
9⁄ 32
5⁄ 16
1⁄ 32
0.058
0.066
0.075
0.083
0.092
0.101
0.118
0.135
0.152
0.169
0.187
0.204
0.221
3⁄ 64
0.083
0.091
0.100
0.108
0.117
0.126
0.143
0.160
0.177
0.194
0.212
0.229
0.246
1⁄ 16
0.107
0.115
0.124
0.132
0.141
0.150
0.167
0.184
0.201
0.218
0.236
0.253
0.270
3⁄ 32
0.156
0.164
0.173
0.181
0.190
0.199
0.216
0.233
0.250
0.267
0.285
0.302
0.319
1⁄ 8
0.205
0.213
0.222
0.230
0.239
0.248
0.265
0.282
0.299
0.316
0.334
0.351
0.368
5⁄ 32
0.254
0.262
0.271
0.279
0.288
0.297
0.314
0.331
0.348
0.365
0.383
0.400
0.417
3⁄ 16
0.303
0.311
0.320
0.328
0.337
0.346
0.363
0.380
0.397
0.414
0.432
0.449
0.466
7⁄ 32
0.353
0.361
0.370
0.378
0.387
0.396
0.413
0.430
0.447
0.464
0.482
0.499
0.516
1⁄ 4
0.401
0.409
0.418
0.426
0.435
0.444
0.461
0.478
0.495
0.512
0.530
0.547
0.564
9⁄ 32
0.450
0.458
0.467
0.475
0.484
0.493
0.510
0.527
0.544
0.561
0.579
0.596
0.613
5⁄ 16
0.499
0.507
0.516
0.524
0.533
0.542
0.559
0.576
0.593
0.610
0.628
0.645
0.662
11⁄ 32
0.549
0.557
0.566
0.574
0.583
0.592
0.609
0.626
0.643
0.660
0.678
0.695
0.712
3⁄ 8
0.598
0.606
0.615
0.623
0.632
0.641
0.658
0.675
0.692
0.709
0.727
0.744
0.761
13⁄ 32
0.646
0.654
0.663
0.671
0.680
0.689
0.706
0.723
0.740
0.757
0.775
0.792
0.809
7⁄ 16
0.695
0.703
0.712
0.720
0.729
0.738
0.755
0.772
0.789
0.806
0.824
0.841
0.858
15⁄ 32
0.734
0.742
0.751
0.759
0.768
0.777
0.794
0.811
0.828
0.845
0.863
0.880
0.897
1⁄ 2
0.794
0.802
0.811
0.819
0.828
0.837
0.854
0.871
0.888
0.905
0.923
0.940
0.957
9⁄ 16
0.892
0.900
0.909
0.917
0.926
0.935
0.952
0.969
0.986
1.003
1.021
1.038
1.055
5⁄ 8
0.990
0.998
1.007
1.015
1.024
1.033
1.050
1.067
1.084
1.101
1.119
1.136
1.153
11⁄ 16
1.089
1.097
1.106
1.114
1.123
1.132
1.149
1.166
1.183
1.200
1.218
1.235
1.252
3⁄ 4
1.187
1.195
1.204
1.212
1.221
1.230
1.247
1.264
1.281
1.298
1.316
1.333
1.350
13⁄ 16
1.286
1.294
1.303
1.311
1.320
1.329
1.346
1.363
1.380
1.397
1.415
1.432
1.449
7⁄ 8
1.384
1.392
1.401
1.409
1.418
1.427
1.444
1.461
1.478
1.495
1.513
1.530
1.547
15⁄ 16
1.481
1.489
1.498
1.506
1.515
1.524
1.541
1.558
1.575
1.592
1.610
1.627
1.644
1.580 1.678
1.588 1.686
1.597 1.695
1.605 1.703
1.614 1.712
1.623 1.721
1.640 1.738
1.657 1.755
1.674 1.772
1.691 1.789
1.709 1.807
1.726 1.824
1.743 1.841
1.777
1.785
1.794
1.802
1.811
1.820
1.837
1.854
1.871
1.888
1.906
1.923
1.940
1 3⁄16
1.875
1.883
1.892
1.900
1.909
1.918
1.935
1.952
1.969
1.986
2.004
2.021
2.038
1 1⁄4
1.972
1.980
1.989
1.997
2.006
2.015
2.032
2.049
2.066
2.083
2.101
2.118
2.135
1 1 1⁄16 1
1⁄ 8
Copyright 2004, Industrial Press, Inc., New York, NY
PUNCHES, DIES, AND PRESS WORK
1⁄ 64
Machinery's Handbook 27th Edition
Table 3. Lengths of Straight Stock Required for 90-Degree Bends in Half-Hard Brass and Sheet Copper, Soft Steel, and Aluminum Radius R of Bend, Inches
Thickness T of Material, Inch 3⁄ 64
1⁄ 16
5⁄ 64
3⁄ 32
1⁄ 8
5⁄ 32
3⁄ 16
7⁄ 32
1⁄ 4
9⁄ 32
5⁄ 16
0.059
0.069
0.079
0.089
0.099
0.109
0.129
0.149
0.169
0.189
0.209
0.229
0.249
0.084
0.094
0.104
0.114
0.124
0.134
0.154
0.174
0.194
0.214
0.234
0.254
0.274
0.108
0.118
0.128
0.138
0.148
0.158
0.178
0.198
0.218
0.238
0.258
0.278
0.298
0.157
0.167
0.177
0.187
0.197
0.207
0.227
0.247
0.267
0.287
0.307
0.327
0.347
0.206
0.216
0.226
0.236
0.246
0.256
0.276
0.296
0.316
0.336
0.356
0.376
0.396
0.255
0.265
0.275
0.285
0.295
0.305
0.325
0.345
0.365
0.385
0.405
0.425
0.445
0.305
0.315
0.325
0.335
0.345
0.355
0.375
0.395
0.415
0.435
0.455
0.475
0.495
0.354
0.364
0.374
0.384
0.394
0.404
0.424
0.444
0.464
0.484
0.504
0.524
0.544
0.403
0.413
0.423
0.433
0.443
0.453
0.473
0.493
0.513
0.533
0.553
0.573
0.593
0.452
0.462
0.472
0.482
0.492
0.502
0.522
0.542
0.562
0.582
0.602
0.622
0.642
0.501
0.511
0.521
0.531
0.541
0.551
0.571
0.591
0.611
0.631
0.651
0.671
0.691
0.550
0.560
0.570
0.580
0.590
0.600
0.620
0.640
0.660
0.680
0.700
0.720
0.740
0.599
0.609
0.619
0.629
0.639
0.649
0.669
0.689
0.709
0.729
0.749
0.769
0.789
0.648
0.658
0.668
0.678
0.688
0.698
0.718
0.738
0.758
0.778
0.798
0.818
0.838
0.697
0.707
0.717
0.727
0.737
0.747
0.767
0.787
0.807
0.827
0.847
0.867
0.887
0.746
0.756
0.766
0.776
0.786
0.796
0.816
0.836
0.856
0.876
0.896
0.916
0.936
0.795
0.805
0.815
0.825
0.835
0.845
0.865
0.885
0.905
0.925
0.945
0.965
0.985
0.844
0.854
0.864
0.874
0.884
0.894
0.914
0.934
0.954
0.974
0.994
1.014
1.034
0.894
0.904
0.914
0.924
0.934
0.944
0.964
0.984
1.004
1.024
1.044
1.064
1.084
0.992
1.002
1.012
1.022
1.032
1.042
1.062
1.082
1.102
1.122
1.42
1.162
1.182
1.090
1.100
1.110
1.120
1.130
1.140
1.160
1.180
1.200
1.220
1.240
1.260
1.280
1.188
1.198
1.208
1.218
1.228
1.238
1.258
1.278
1.298
1.318
1.338
1.358
1.378
1.286
1.296
1.306
1.316
1.326
1.336
1.356
1.376
1.396
1.416
1.436
1.456
1.476
1.384
1.394
1.404
1.414
1.424
1.434
1.454
1.474
1.494
1.514
1.534
1.554
1.574
1.483
1.493
1.503
1.513
1.523
1.553
1.553
1.573
1.693
1.613
1.633
1.653
1.673
1 1 1⁄16
1.581 1.697
1.591 1.689
1.601 1.699
1.611 1.709
1.621 1.719
1.631 1.729
1.651 1.749
1.671 1.769
1.691 1.789
1.711 1.809
1.731 1.829
1.751 1.849
1.771 1.869
1 1⁄8
1.777
1.787
1.797
1.807
1.817
1.827
1.847
1.867
1.887
1.907
1.927
1.947
1.967
1 3⁄16
1.875
1.885
1.895
1.905
1.915
1.925
1.945
1.965
1.985
1.005
2.025
2.045
2.065
1 1⁄4
1.973
1.983
1.993
1.003
2.013
2.023
2.043
2.063
2.083
2.103
2.123
2.143
2.163
1⁄ 32 3⁄ 64 1⁄ 16 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2 17⁄ 32 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4 13⁄ 16 7⁄ 8 15⁄ 16
Copyright 2004, Industrial Press, Inc., New York, NY
1337
1⁄ 32
PUNCHES, DIES, AND PRESS WORK
1⁄ 64
Machinery's Handbook 27th Edition
Thickness T of Material, Inch 1⁄ 32
3⁄ 64
1⁄ 16
5⁄ 64
3⁄ 32
1⁄ 8
5⁄ 32
3⁄ 16
7⁄ 32
1⁄ 4
9⁄ 32
5⁄ 16
1⁄ 32
0.060
0.071
0.082
0.093
0.104
0.116
0.138
0.160
0.182
0.204
0.227
0.249
0.271
3⁄ 64
0.085
0.096
0.107
0.118
0.129
0.141
0.163
0.185
0.207
0.229
0.252
0.274
0.296
1⁄ 16
0.109
0.120
0.131
0.142
0.153
0.165
0.187
0.209
0.231
0.253
0.276
0.298
0.320
3⁄ 32
0.158
0.169
0.180
0.191
0.202
0.214
0.236
0.258
0.280
0.302
0.325
0.347
0.369
1⁄ 8
0.207
0.218
0.229
0.240
0.251
0.263
0.285
0.307
0.329
0.351
0.374
0.396
0.418
5⁄ 32
0.256
0.267
0.278
0.289
0.300
0.312
0.334
0.356
0.378
0.400
0.423
0.445
0.467
3⁄ 16
0.305
0.316
0.327
0.338
0.349
0.361
0.383
0.405
0.427
0.449
0.472
0.494
0.516
7⁄ 32
0.355
0.366
0.377
0.388
0.399
0.411
0.433
0.455
0.477
0.499
0.522
0.544
0.566
1⁄ 4
0.403
0.414
0.425
0.436
0.447
0.459
0.481
0.503
0.525
0.547
0.570
0.592
0.614
9⁄ 32
0.452
0.463
0.474
0.485
0.496
0.508
0.530
0.552
0.574
0.596
0.619
0.641
0.663
5⁄ 16
0.501
0.512
0.523
0.534
0.545
0.557
0.579
0.601
0.623
0.645
0.668
0.690
0.712
11⁄ 32
0.551
0.562
0.573
0.584
0.595
0.607
0.629
0.651
0.673
0.695
0.718
0.740
0.762
3⁄ 8
0.600
0.611
0.622
0.633
0.644
0.656
0.678
0.700
0.722
0.744
0.767
0.789
0.811
13⁄ 32
0.648
0.659
0.670
0.681
0.692
0.704
0.726
0.748
0.770
0.792
0.815
0.837
0.859
7⁄ 16
0.697
0.708
0.719
0.730
0.741
0.753
0.775
0.797
0.819
0.841
0.864
0.886
0.908
15⁄ 32
0.736
0.747
0.758
0.769
0.780
0.792
0.814
0.836
0.858
0.880
0.903
0.925
0.947
1⁄ 2
0.796
0.807
0.818
0.829
0.840
0.852
0.874
0.896
0.918
0.940
0.963
0.985
1.007
9⁄ 16
0.894
0.905
0.916
0.927
0.938
0.950
0.972
0.994
1.016
1.038
1.061
1.083
1.105
5⁄ 8
0.992
1.003
1.014
1.025
1.036
1.048
1.070
1.092
1.114
1.136
1.159
1.181
1.203
11⁄ 16
1.091
1.102
1.113
1.124
1.135
1.147
1.169
1.191
1.213
1.235
1.258
1.280
1.302
3⁄ 4
1.189
1.200
1.211
1.222
1.233
1.245
1.267
1.289
1.311
1.333
1.356
1.378
1.400
13⁄ 16
1.288
1.299
1.310
1.321
1.332
1.344
1.366
1.388
1.410
1.432
1.455
1.477
1.499
7⁄ 8
1.386
1.397
1.408
1.419
1.430
1.442
1.464
1.486
1.508
1.530
1.553
1.575
1.597
15⁄ 16
1.483
1.494
1.505
1.516
1.527
1.539
1.561
1.583
1.605
1.627
1.650
1.672
1.694
1.582 1.680
1.593 1.691
1.604 1.702
1.615 1.713
1.626 1.724
1.638 1.736
1.660 1.758
1.682 1.780
1.704 1.802
1.726 1.824
1.749 1.847
1.771 1.869
1.793 1.891
1.779
1.790
1.801
1.812
1.823
1.835
1.857
1.879
1.901
1.923
1.946
1.968
1.990
1 3⁄16
1.877
1.888
1.899
1.910
1.921
1.933
1.955
1.977
1.999
2.021
2.044
2.066
2.088
1 1⁄4
1.974
1.985
1.996
2.007
2.018
2.030
2.052
2.074
2.096
2.118
2.141
2.163
2.185
1 1 1⁄16 1
1⁄ 8
Copyright 2004, Industrial Press, Inc., New York, NY
PUNCHES, DIES, AND PRESS WORK
1⁄ 64
1338
Table 4. Lengths of Straight Stock Required for 90-Degree Bends in Hard Copper, Bronze, Cold-Rolled Steel, and Spring Steel Radius R of Bend, Inches
Machinery's Handbook 27th Edition PUNCHES, DIES, AND PRESS WORK
1339
For bend at right-hand end (60-degree bend) L = [ ( 0.64 × 0.125 ) + ( 1.57 × 0.625 ) ] × 60 ------ = 0.707 90 Total length before bending = 3.5 + 1.338 + 0.707 = 5.545 inches
Fig. 4.
Fig. 5.
Other Bending Allowance Formulas.—When bending sheet steel or brass, add from 1⁄3 to 1⁄2 of the thickness of the stock, for each bend, to the sum of the inside dimensions of the finished piece, to get the length of the straight blank. The harder the material the greater the allowance (1⁄3 of the thickness is added for soft stock and 1⁄2 of the thickness for hard material). The data given in the table, Allowances for Bends in Sheet Metal on page 1340, refer more particularly to the bending of sheet metal for counters, bank fittings and general office fixtures, for which purpose it is not absolutely essential to have the sections of the bends within very close limits. Absolutely accurate data for this work cannot be deduced, as the stock varies considerably as to hardness, etc. The figures given apply to sheet steel, aluminum, brass and bronze. Experience has demonstrated that for the semisquare corners, such as are formed in a V-die, the amount to be deducted from the sum of the outside bend dimensions, as shown in Fig. 5 by the sum of the letters from a to e, is as follows: X = 1.67 BG, where X = the amount to be deducted; B = the number of bends; and G = the decimal equivalent of the gage. The values of X for different gages and numbers of bends are given in the table. Its application may be illustrated by an example: A strip having two bends is to have outside dimensions of 2, 11⁄2 and 2 inches, and is made of stock 0.125 inch thick. The sum of the outside dimensions is thus 51⁄2 inches, and from the table the amount to be deducted is found to be 0.416; hence the blank will be 5.5 − 0.416 = 5.084 inches long. The lower part of the table applies to square bends which are either drawn through a block of steel made to the required shape, or else drawn through rollers in a drawbench. The pressure applied not only gives a much sharper corner, but it also elongates the material more than in the V-die process. In this case, the deduction is X = 1.33 BG. Joining and Edging A duct system is an assembly whose main function is to convey air. Elements of the duct system are sheets, transverse joints, longitudinal seams, and reinforcements.The sheets must be able to withstand deflection caused by both internal pressure and vibration due to turbulent air flow. Transverse joints must be able to withstand 1.5 times the maximum operating pressure without failure. Transverse joint designs should be consistent with the static pressure class, sealing requirements, materials involved, and support interval distances. Notching, bending, folding, and fit up tolerances shall be appropriate for the proper class. Longitudinial seams also must be able to withstand 1.5 times the operating pressure without deformation. Seams shall be formed and assembled with proper dimension and proportion for tight and secure fit up. Seams may be a butt, corner, plug, or spot weld design. Seams shall be selected based on material and pressure. A duct section between adjacent hangers must be able to carry its own weight and to resist external loads for which
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1340
PUNCHES, DIES, AND PRESS WORK Allowances for Bends in Sheet Metal
Formed in a Press by a V-die
Rolled or Drawn in a Draw-bench
Amount to be Deducted from the Sum of the Outside Bend Dimensions, Inches
Gage
Thick ness Inches
Square Bends
1 Bend
18 16 14 13 12 11 10 18 16 14 13 12 11 10
0.0500 0.0625 0.0781 0.0937 0.1093 0.1250 0.1406 0.0500 0.0625 0.0781 0.0937 0.1093 0.1250 0.1406
0.083 0.104 0.130 0.156 0.182 0.208 0.234 0.066 0.083 0.104 0.125 0.145 0.166 0.187
2 Bends
3 Bends
4 Bends
5 Bends
6 Bends
7 Bends
0.166 0.208 0.260 0.312 0.364 0.416 0.468 0.133 0.166 0.208 0.250 0.291 0.333 0.375
0.250 0.312 0.390 0.468 0.546 0.625 0.703 0.200 0.250 0.312 0.375 0.437 0.500 0.562
0.333 0.416 0.520 0.625 0.729 0.833 0.937 0.266 0.333 0.416 0.500 0.583 0.666 0.750
0.416 0.520 0.651 0.781 0.911 1.041 1.171 0.333 0.416 0.521 0.625 0.729 0.833 0.937
0.500 0.625 0.781 0.937 1.093 1.250 1.406 0.400 0.500 0.625 0.750 0.875 1.000 1.125
0.583 0.729 0.911 1.093 1.276 1.458 1.643 0.466 0.583 0.729 0.875 1.020 1.166 1.312
it is constructed. The reinforcing members must be able to resist the deflection of the sheet, and its own deflection. There is a relationship between duct width, reinforcement spacing, reinforcement size, pressure, and sheet thickness. For constant pressure and constant duct size, the thicker sheet allows more distance between reinforcements. The higher the pressure the shorter the spacing between reinforcements. Joints and intermediate reinforcements are labor intensive and may be more costly than the savings gained by a reduction in wall thickness. Thicker duct wall and stronger joints are more cost effective than using more reinforcement. The following material illustrates various joint designs, used both in duct work and other sheet metal asseblies. Sheet Metal Joints Plain Lap and Flush Lap:
Fig. 6. Plain Lap
The plain lap (Fig. 6 ) and flush lap (Fig. 7 ) are both used for various materials such as galvanized or black iron, copper, stainless steel, aluminum, or other metals, and may be soldered, and/or riveted, as well as spot, tack, or solid-welded. Lap dimensions vary with the particular application, and since it is the duty of the draftsman to specify straight joints in lengths that use full-sheet sizes, transverse lap dimensions must be known.
Fig. 7. Flush Lap
Raw and Flange Corner: The raw and flange corner (Fig. 8) is generally spot-welded, but may be riveted or soldered. For heavy gages it is tack-welded or solid-welded. Fig. 8. Raw and Flange Corner
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Machinery's Handbook 27th Edition PUNCHES, DIES, AND PRESS WORK
1341
Flange and Flange Corner: The flange and flange corner (Fig. 9) is a refinement of the raw and flange corner. It is particularly useful for heavy-gage duct sections which require flush outside corners and must be fielderected. Fig. 9. Flange and Flange Corner
Standing Seam:
Fig. 10. Standing Seam
The standing seam (Fig. 10) is often used for large plenums, or casings. Before the draftsman is able to lay out a casing drawing, one of the items of information needed is seam allowance measurements, so that panel sizes can be detailed for economical use of standard sheets. Considering velocity levels, standing seams are considered for duct interiors: 1″ seam is normally applied for duct widths up to 42″, and 11⁄2″ for bigger ducts.
Groove Seam:
Fig. 11. Groove Seam
The groove seam (Fig. 11) is often used for rectangular or round duct straight joints, or to join some sheets for fittings that are too large to be cut out from standard sheets. It is also known as the pipelock, or flat lock seam.
Corner Standing Seam: The corner standing seam (Fig. 12) has similar usage to the standing seam, and also can be used for straight-duct sections. This type of seams are mostly applied at the ends at 8″ intervals. Fig. 12. Corner Standing Seam
Double Seam:
Fig. 13. Double Corner Seam
The double corner seam (Fig. 13) at one time was the most commonly used method for duct fitting fabrication. However, although it is seldom used because of the hand operations required for assembly, the double seam can be used advantageously for duct fittings with compound curves. It is called the slide lock seam. Machines are available to automatically close this seam.
Slide-Corner:
Fig. 14. Slide Corner
The slide-corner (Fig. 14) is a large version of the double seam. It is often used for field assembly of straight joints, such as in an existing ceiling space, or other restricted working area where ducts must be built in place. To assemble the duct segments, opposite ends of each seam are merely “entered” and then pushed into position. Ducts are sent to job sites “knocked-down” for more efficient use of shipping space.
Button Punch Snap Lock:
Fig. 15. Button Punch Snap Lock
The button punch snap lock (Fig. 15) is a flush-type seam which may be soldered or caulked. This seam can be modified slightly for use as a “snap lock”. This types of seam is not applicable for aluminum or other soft metals. This seam may be used up to 4″ w.g. by using screws at the ends. The pocket depth should not be smaller than 5⁄8″ for 20, 22 and 26 gage.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1342
PUNCHES, DIES, AND PRESS WORK
Pittsburg:
The Pittsburg (Fig. 16) is the most commonly used seam for standard gage duct construction. The common pocket depths are 5⁄16″ and 5⁄8″ depending on the thickness of sheet. Fig. 16. Pittsburgh
Flange: The flange (Fig. 17) is an end edge stiffener. The draftsman must indicate size of the flange, direction of bend, degree of bend (if other than 90°) and when full corners are desired. Full corners are generally advisable for collar connections to concrete or masonry wall openings at louvers. Fig. 17. Flange
Hem: The hem edge (Fig. 18) is a flat, finished edge. As with the flange, this must be designated by the draftsman. For example, drawing should show: 3⁄4″ hem out.
Fig. 18. Hem
Flat Drive Slip:
Fig. 19. Drive Slip
This is one of the simplest transverse joints. It is applicable where pressure is less than 2″ w.g. This is a slide type connection generally used on small ducts in combination of “S” slips. Service above 2″ inches w.g. is not applicable.
Standing Drive Slip: H
This is also a slide type connection. It is made by elongating flat drive slip, fasten standing portions 2″ from each end. It is applicable for any length in 2″ w.g, 36″ for 3″ inch w.g., and 30″ inches at 4″ w.g. service.
Fig. 20. Standing Drive Slip
Flat Drive Slip Reinforced: This is the reinforcement on flat drive slip by adding a transverse angle section after a fixed interval. Fig. 21. Drive Slip Reinforced
Double “S” Slip Reinforced:
Fig. 22. Double “S” Slip
The double “S” slip is applied, to eliminate the problem of notching and bending, especially for large ducts. Apply 24 gage sheet for 30″ width or less, 22 gage sheet over 30″ width.
Flat “S” Slip:
Fig. 23. Plain “S” Slip
Normally the “S” slip is used for small ducts. However, it is also useful if the connection of a large duct is tight to a beam, column or other object, and an “S” slip is substituted for the shop standard slip. Service above 2″ inches w.g. is not applicable. Gage shall not be less than 24, and shall not 2 gage less than the duct gage. When it is applied on all four edges, fasten within 2″ of the corners and at 12″ maximum interval.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition PUNCHES, DIES, AND PRESS WORK
1343
Hemmed “S” Slip:
Fig. 24. Hemmed “S” Slip
This is the modified “S” slip, by adding hem and an angle for reinforcing. The hem edge is a flat, and finished edge. Hemmed “S” slip is mostly applied with angle. The drive is generally 16 gage, formed a 1 inch height slip pocket and screws at the end. Notching and bending operations on an “S” slip joints can be cumbersome and costly, especially for large sizes. Tied each section of the duct within 2″ from the corner at maximum 6-inch interval.
Other Types of Duct Connections Clinch-bar Slip and Flange:
Fig. 25. Clinch-bar Slip and Flange
The clinch-bar slip and flange (Fig. 25), uses the principle of the standing seam, but with a duct lap in the direction of airflow. These slips are generally assembled as a framed unit with full corners either riveted or spot-welded, which adds to the duct cross-section rigidity. Reinforcement may be accomplished by spot welding the flat-bar to the flange of the large end. Accessibility to all four sides of the duct is required because the flange of the slip must be folded over the flange on the large end after the ducts are connected.
Clinch-bar Slip and Angle :
Fig. 26. Clinch-bar Slip and Angle
The clinch bar slip and angle (Fig. 26), is similar to clinch bar slip (Fig. 25), but it has a riveted or spot-welded angle on the large end. This connection can also have a raw large end which is inserted into the space between the angle and the shop-fabricated slip. Matched angles (minimum of 16 ga) are riveted or spot welded to the smaller sides of the ducts, to pull the connection “home.”
Flanged Duct Connections Angle Frame, or Ring:
Fig. 27. Raw Ends and Matched ∠s
Any of the following flanged connections may have gaskets. The draftsman should not allow for gasket thicknesses in calculations for running length dimensions, nor should he indicate angle sizes, bolt centers, etc., as these items are established in job specifications and approved shop standards. Generally, angles are fastened to the duct sections in the shop. If conditions at the job site require consideration for length contingencies, the draftsman should specify “loose angles” such as at a connection to equipment which may be located later. The most common matched angle connection is the angle frame, or ring (Fig. 27). The angles are fastened flush to the end of the duct.
Flanged End and Angle:
Fig. 28. Flanged Ends and Matched ∠s
The flanged end and angle (Fig. 28), is often used for ducts 16 ga or lighter, as the flange provides a metal-to-metal gasket and holds the angle frame or ring on the duct without additional fastening. The draftsman may indicate in a field note that a round-duct fitting is to be ″rotated as required″.This type of angle-ring-connection is convenient for such a condition.
Formed Flanges:
Fig. 29. Formed Flanges
Double flanges (Fig. 29), are similar to Fig. 21, except that the connecting flange has a series of matched bolt holes. This connection, caulked airtight, is ideal for single-wall apparatus casings or plenums. The flanges are formed at the ends of the duct, after assembly they will form a T shape. Mating flanges shall be locked together by long clips. In order to form effective seal, gasket is used with suitable density and resiliency. At the corners 16 gage thickness steel corner are used with 3⁄8″ diameter bolts.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1344
FINE BLANKING
Double Flanges and Cleat:
Double Flanges and Cleat (Fig. 30) is identical to (Fig. 29), but has an air seal cleat. The reinforcements is attached to the duct wall on both sides of the joint. Fig. 30. Double Flanges and Cleat
Clinch-type Flanged Connections:
Fig. 31. Bead Clinch and Z Rings
Clinch-type flanged connections for round ducts, 16 ga or lighter, are shown in Fig. 31. The angles or rings can be loose, as explained in Flanged End and Angle, (Fig. 28). The draftsman should indicate flange sizes, bend direction, and type of assembly. An example such as the flange lap for a field assembly of a 10-gage casing corner would be written: 1 1⁄2″ flange out square on side with 9⁄32″∅ bolt holes 12″ CC. At the beginning and ending angles are connected by rivets or welding. The bolt will be 5⁄16″ ∅ at 6″ maximum spacing 4″ w.g..
Fine Blanking The process called fine blanking uses special presses and tooling to produce flat components from sheet metal or plate, with high dimensional accuracy. According to Hydrel A. G., Romanshorn, Switzerland, fine-blanking presses can be powered hydraulically or mechanically, or by a combination of these methods, but they must have three separate and distinct movements. These movements serve to clamp the work material, to perform the blanking operation, and to eject the finished part from the tool. Forces of 1.5–2.5 times those used in conventional stamping are needed for fine blanking, so machines and tools must be designed and constructed accordingly. In mechanical fine-blanking presses the clamping and ejection forces are exerted hydraulically. Such presses generally are of toggle-type design and are limited to total forces of up to about 280 tons. Higher forces generally require all-hydraulic designs. These presses are also suited to embossing, coining, and impact extrusion work. Cutting elements of tooling for fine blanking generally are made from 12 per cent chromium steel, although high speed steel and tungsten carbide also are used for long runs or improved quality. Cutting clearances between the intermediate punch and die are usually held between 0.0001 and 0.0003 in. The clamping elements are sharp projections of 90degree V-section that follow the outline of the workpiece and that are incorporated into each tool as part of the stripper plate with thin material and also as part of the die plate when material thicker than 0.15 in. is to be blanked. Pressure applied to the elements containing the V-projections prior to the blanking operation causes the sharp edges to enter the material surface, preventing sideways movement of the blank. The pressure applied as the projections bite into the work surface near the contour edges also squeezes the material, causing it to flow toward the cutting edges, reducing the usual rounding effect at the cut edge. When small details such as gear teeth are to be produced, V-projections are often used on both sides of the work, even with thin materials, to enhance the flow effect. With suitable tooling, workpieces can be produced with edges that are perpendicular to top and bottom surfaces within 0.004 in. on thicknesses of 0.2 in., for instance. V-projection dimensions for various material thicknesses are shown in the table Dimensions for V-projections Used in Fine-Blanking Tools. Fine-blanked edges are free from the fractures that result from conventional tooling, and can have surface finishes down to 80 µin. Ra with suitable tooling. Close tolerances can be
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition FINE BLANKING
1345
Dimensions for V-projections Used in Fine-Blanking Tools
V-Projections On Stripper Plate Only Material Thickness 0.040-0.063 0.063-0.098 0.098-0.125 0.125-0.157 0.157-0.197 0.157–0.197 0.197–0.248 0.248–0.315 0.315–0.394 0.394–0.492 0.492–0.630 All units are in inches.
V-Projections On Both Stripper and Die Plate
A h r V-Projections On Stripper Plate Only 0.040 0.012 0.008 0.055 0.015 0.008 0.083 0.024 0.012 0.098 0.028 0.012 0.110 0.032 0.012 V-Projections On Both Stripper and Die Plate 0.098 0.020 0.008 0.118 0.028 0.008 0.138 0.032 0.008 0.177 0.040 0.020 0.217 0.047 0.020 0.276 0.063 0.020
H
R
… … … … …
… … … … …
0.032 0.040 0.047 0.060 0.070 0.087
0.032 0.040 0.047 0.060 0.080 0.118
held on inner and outer forms, and on hole center distances. Flatness of fine-blanked components is better than that of parts made by conventional methods, but distortion may occur with thin materials due to release of internal stresses. Widths must be slightly greater than are required for conventional press working. Generally, the strip width must be 2–3 times the thickness, plus the width of the part measured transverse to the feed direction. Other factors to be considered are shape, material quality, size and shape of the V-projection in relation to the die outline, and spacing between adjacent blanked parts. Holes and slots can be produced with ratios of width to material thickness down to 0.7, compared with the 1:1 ratio normally specified for conventional tooling. Operations such as countersinking, coining, and bending up to 60 degrees can be incorporated in fine-blanking tooling. The cutting force in lb exerted in fine blanking is 0.9 times the length of the cut in inches times the material thickness in inches, times the tensile strength in lbf/in.2. Pressure in lb exerted by the clamping element(s) carrying the V-projections is calculated by multiplying the length of the V-projection, which depends on its shape, in inches by its height (h), times the material tensile strength in lbf/in.2, times an empirical factor f. Factor f has been determined to be 2.4–4.4 for a tensile strength of 28,000–113,000 lbf/in.2. The clamping pressure is approximately 30 per cent of the cutting force, calculated as above. Dimensions and positioning of the V-projection(s) are related to the material thickness, quality, and tensile strength. A small V-projection close to the line of cut has about the same effect as a large V-projection spaced away from the cut. However, if the V-projection is too close to the cut, it may move out of the material at the start of the cutting process, reducing its effectiveness.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1346
STEEL RULE DIES
Positioning the V-projection at a distance from the line of cut increases both material and blanking force requirements. Location of the V-projection relative to the line of cut also affects tool life. Steel Rule Dies Steel rule dies (or knife dies) were patented by Robert Gair in 1879, and, as the name implies, have cutting edges made from steel strips of about the same proportions as the steel strips used in making graduated rules for measuring purposes. According to J. A. Richards, Sr., of the J. A. Richards Co., Kalamazoo, MI, a pioneer in the field, these dies were first used in the printing and shoemaking industries for cutting out shapes in paper, cardboard, leather, rubber, cork, felt, and similar soft materials. Steel rule dies were later adopted for cutting upholstery material for the automotive and other industries, and for cutting out simple to intricate shapes in sheet metal, including copper, brass, and aluminum. A typical steel rule die, partially cut away to show the construction, is shown in Fig. 1, and is designed for cutting a simple circular shape. Such dies generally cost 25 to 35 per cent of the cost of conventional blanking dies, and can be produced in much less time. The die shown also cuts a rectangular opening in the workpiece, and pierces four holes, all in one press stroke. Upper die shoe
Fool proofing pin locations
Male punch
Lignostone die block Steel rule with land for shearing Piercing punch
Fool proofing pin locations
Die strippers may be neoprene, spring ejector, or positive knock out
Parallels for slug clearance
Lower die plate
Lower die shoe
Subdie plate
Fig. 1. Steel Rule Die for Cutting a Circular Shape, Sectioned to Show the Construction
The die blocks that hold the steel strips on edge on the press platen or in the die set may be made from plaster, hot lead or type metal, or epoxy resin, all of which can be poured to shape. However, the material most widely used for light work is 3⁄4-in. thick, five- or sevenply maple or birch wood. Narrow slots are cut in this wood with a jig saw to hold the strips vertically. Where greater forces are involved, as with operations on metal sheets, the blocks usually are made from Lignostone densified wood or from metal. In the 3⁄4-in. thickness mostly used, medium- and high-density grades of Lignostone are available. The 3⁄4-in. thickness is made from about 35 plies of highly compressed lignite wood, bonded with
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Machinery's Handbook 27th Edition STEEL RULE DIES
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phenolformaldehyde resin, which imparts great density and strength. The material is made in thicknesses up to 6 in., and in various widths and lengths. Steel rule die blocks can carry punches of various shapes to pierce holes in the stock, also projections designed to form strengthening ribs and other shapes in material such as aluminum, at the same time as the die cuts the component to shape. Several dies can be combined or nested, and operated together in a large press, to produce various shapes simultaneously from one sheet of material. As shown in Fig. 1, the die steel is held in the die block slot on its edge, usually against the flat platen of a die set attached to the moving slide of the press. The sharp, free end of the rule faces toward the workpiece, which is supported by the face of the other die half. This other die half may be flat or may have a punch attached to it, as shown, and it withstands the pressure exerted in the cutting or forming action when the press is operated. The closed height of the die is adjusted to permit the cutting edge to penetrate into the material to the extent needed, or, if there is a punch, to carry the cutting edges just past the punch edges for the cutting operation. After the sharp edge has penetrated it, the material often clings to the sides of the knife. Ejector inserts made from rubber, combinations of cork and rubber, and specially compounded plastics material, or purpose-made ejectors, either spring- or positively actuated, are installed in various positions alongside the steel rules and the punch. These ejectors are compressed as the dies close, and when the dies open, they expand, pushing the material clear of the knives or the punch. The cutting edges of the steel rules can be of several shapes, as shown in profile in Fig. 2, to suit the material to be cut, or the type of cutting operation. Shape A is used for shearing in the punch in making tools for blanking and piercing operations, the sharp edge later being modified to a flat, producing a 90° cutting edge, B. The other shapes in Fig. 2 are used for cutting various soft materials that are pressed against a flat surface for cutting. The shape at C is used for thin, and the shape at D for thicker materials.
;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;; ;;;;;;;; ;; A
B
C
D
Fig. 2. Cutting Edges for Steel Rule Dies
Steel rule die steel is supplied in lengths of 30 and 50 in., or in coils of any length, with the edges ground to the desired shape, and heat treated, ready for use. The rule material width is usually referred to as the height, and material can be obtained in heights of 0.95, 1, 11⁄8, 11⁄4, and 11⁄2 in. Rules are available in thicknesses of 0.055, 0.083, 0.11, 0.138, 0.166, and 0.25 in. (4 to 18 points in printers' measure of 72 points = 1 in.). Generally, stock thicknesses of 0.138 or 0.166 in. (10 and 12 points) are preferred, the thinner rules being used mainly for dies requiring intricate outlines. The stock can be obtained in soft or hard temper. The standard edge bevel is 46°, but bevels of 40 to 50° can be used. Thinner rule stock is easiest to form to shape and is often used for short runs of 50 pieces or thereabouts. The thickness and hardness of the material to be blanked also must be considered when choosing rule thickness. Making of Steel Rule Dies.—Die making begins with a drawing of the shape required. Saw cutting lines may be marked directly on the face of the die block in a conventional layout procedure using a height gage, or a paper drawing may be pasted to or drawn on the die
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STEEL RULE DIES
board. Because paper stretches and shrinks, Mylar or other nonshrink plastics sheets may be preferred for the drawing. A hole is drilled off the line to allow a jig saw to be inserted, and jig saw or circular saw cuts are then made under manual control along the drawing lines to produce the slots for the rules. Jig saw blades are available in a range of sizes to suit various thicknesses of rule and for sawing medium-density Lignostone, a speed of 300 strokes/min is recommended, the saw having a stroke of about 2 in. To make sure the rule thickness to be used will be a tight fit in the slot, trials are usually carried out on scrap pieces of die block before cuts are made on a new block. During slot cutting, the saw blade must always be maintained vertical to the board being cut, and magnifying lenses are often used to keep the blade close to the line. Carbide or carbide-tipped saw blades are recommended for clean cuts as well as for long life. To keep any “islands” (such as the center of a circle) in position, various places in the sawn line are cut to less than full depth for lengths of 1⁄4 to 1⁄2 in., and to heights of 5⁄8 to 3⁄4 in. to bridge the gaps. Slots of suitable proportions must be provided in the steel rules, on the sides away from the cutting edges, to accommodate these die block bridges. Rules for steel rule dies are bent to shape to fit the contours called for on the drawing by means of small, purpose-built bending machines, fitted with suitable tooling. For bends of small radius, the tooling on these machines is arranged to perform a peening or hammering action to force the steel rule into close contact with the radius-forming component of the machine so that quite small radii, as required for jig saw puzzles, for instance, can be produced with good accuracy. Some forms are best made in two or more pieces, then joined by welding or brazing. The edges to be joined are mitered for a perfect fit, and are clamped securely in place for joining. Electrical resistance or a gas heating torch is used to heat the joint. Wet rags are applied to the steel at each side of the joint to keep the material cool and the hardness at the preset level, as long as possible. When shapes are to be blanked from sheet metal, the steel rule die is arranged with flat, 90° edges (B, in Fig. 2), which cut by pushing the work past a close-fitting counter-punch. This counterpunch, shown in Fig. 1, may be simply a pad of steel or other material, and has an outline corresponding to the shape of the part to be cut. Sometimes the pad may be given a gradual, slight reduction in height to provide a shearing action as the moving tool pushes the work material past the pad edges. As shown in Fig. 1, punches can be incorporated in the die to pierce holes, cut slots, or form ribs and other details during the blanking operation. These punches are preferably made from high-carbon, high-vanadium, alloy steel, heat treated to Rc 61 to 63, with the head end tempered to Rc 45 to 50. Heat treatment of the high-carbon-steel rules is designed to produce a hardness suited to the application. Rules in dies for cutting cartons and similar purposes, with mostly straight cuts, are hardened to Rc 51 to 58. For dies requiring many intricate bends, lower-carbon material is used, and is hardened to Rc 38 to 45. And for dies to cut very intricate shapes, a steel in dead-soft condition with hardness of about Rb 95 is recommended. After the intricate bends are made, this steel must be carburized before it is hardened and tempered. For this material, heat treatment uses an automatic cycle furnace, and consists of carburizing in a liquid compound heated to 1500°F and quenching in oil, followed by “tough” tempering at 550°F and cooling in the furnace. After the hardened rule has been reinstalled in the die block, the tool is loaded into the press and the sharp die is used with care to shear the sides of the pad to match the die contours exactly. A close fit, with clearances of about half those used in conventional blanking dies, is thus ensured between the steel rule and the punch. Adjustments to the clearances can be made at this point by grinding the die steel or the punch. After the adjustment work is done, the sharp edges of the rule steel are ground flat to produce a land of about 1⁄64 in. wide (A in Fig. 2), for the working edges of the die. Clearances for piercing punches should be similar to those used on conventional piercing dies.
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Machinery's Handbook 27th Edition ELECTRICAL DISCHARGE MACHINING
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ELECTRICAL DISCHARGE MACHINING Generally called EDM, electrical discharge machining uses an electrode to remove metal from a workpiece by generating electric sparks between conducting surfaces. The two main types of EDM are termed sinker or plunge, used for making mold or die cavities, and wire, used to cut shapes such as are needed for stamping dies. For die sinking, the electrode usually is made from copper or graphite and is shaped as a positive replica of the shape to be formed on or in the workpiece. A typical EDM sinker machine, shown diagrammatically in Fig. 1, resembles a vertical milling machine, with the electrode attached to the vertical slide. The slide is moved down and up by an electronic, servo-controlled drive unit that controls the spacing between the electrode and the workpiece on the table. The table can be adjusted in three directions, often under numerical control, to positions that bring a workpiece surface to within 0.0005 to 0.030 in. from the electrode surface, where a spark is generated.
Fig. 1. Sinker or Plunge Type EDM Machines Are Used to Sink Cavities in Molds and Dies
Fig. 2. Wire Type EDM Machines Are Used to Cut Stamping Die Profiles.
Wire EDM, shown diagrammatically in Fig. 2, are numerically controlled and somewhat resemble a bandsaw with the saw blade replaced by a fine brass or copper wire, which forms the electrode. This wire is wound off one reel, passed through tensioning and guide rollers, then through the workpiece and through lower guide rollers before being wound onto another reel for storage and eventual recycling. One set of guide rollers, usually the lower, can be moved on two axes at 90 degrees apart under numerical control to adjust the angle of the wire when profiles of varying angles are to be produced. The table also is movable in two directions under numerical control to adjust the position of the workpiece relative to the wire. Provision must be made for the cut-out part to be supported when it is freed from the workpiece so that it does not pinch and break the wire. EDM applied to grinding machines is termed EDG. The process uses a graphite wheel as an electrode, and wheels can be up to 12 in. in diameter by 6 in. wide. The wheel periphery is dressed to the profile required on the workpiece and the wheel profile can then be transferred to the workpiece as it is traversed past the wheel, which rotates but does not touch the work. EDG machines are highly specialized and are mainly used for producing complex profiles on polycrystaline diamond cutting tools and for shaping carbide tooling such as form tools, thread chasers, dies, and crushing rolls. EDM Terms*.— Anode: The positive terminal of an electrolytic cell or battery. In EDM, incorrectly applied to the tool or electrode. * Source: Hansvedt Industries
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Barrel effect: In wire EDM, a condition where the center of the cut is wider than the entry and exit points of the wire, due to secondary discharges caused by particles being pushed to the center by flushing pressure from above and beneath the workpiece. Capacitor: An electrical component that stores an electric charge. In some EDM power supplies, several capacitors are connected across the machining gap and the current for the spark comes directly from the capacitors when they are discharged. Cathode: The negative terminal in an electrolytic cell or battery. In EDM incorrectly applied to the workpiece. Colloidal suspension: Particles suspended in a liquid that are too fine to settle out. In EDM, the tiny particles produced in the sparking action form a colloidal suspension in the dielectric fluid. Craters: Small cavities left on an EDM surface by the sparking action, also known as pits. Dielectric filter : A filter that removes particles from 5 µm (0.00020 in.) down to as fine as 1 µm (0.00004 in) in size, from dielectric fluid. Dielectric fluid : The non-conductive fluid that circulates between the electrode and the workpiece to provide the dielectric strength across which an arc can occur, to act as a coolant to solidify particles melted by the arc, and to flush away the solidified particles. Dielectric strength: In EDM, the electrical potential (voltage) needed to break down (ionize) the dielectric fluid in the gap between the electrode and the workpiece. Discharge channel: The conductive pathway formed by ionized dielectric and vapor between the electrode and the workpiece. Dither: A slight up and down movement of the machine ram and attached electrode, used to improve cutting stability. Duty cycle: The percentage of a pulse cycle during which the current is turned on (on time), relative to the total duration of the cycle. EDG: Electrical discharge grinding using a machine that resembles a surface grinder but has a wheel made from electrode material. Metal is removed by an EDM process rather than by grinding. Electrode growth: A plating action that occurs at certain low-power settings, whereby workpiece material builds up on the electrode, causing an increase in size. Electrode wear: Amount of material removed from the electrode during the EDM process. This removal can be end wear or corner wear, and is measured linearly or volumetrically but is most often expressed as end wear per cent, measured linearly. Electro-forming: An electro-plating process used to make metal EDM electrodes. Energy: Measured in joules, is the equivalent of volt-coulombs or volt-ampere- seconds. Farad: Unit of electrical capacitance, or the energy-storing capacity of a capacitor. Gap: The closest point between the electrode and the workpiece where an electrical discharge will occur. (See Overcut) Gap current: The average amperage flowing across the machining gap. Gap voltage: The voltage across the gap while current is flowing. The voltage across the electrode/workpiece before current flows is called the open gap voltage. Heat-affected zone. The layer below the recast layer, which has been subjected to elevated temperatures that have altered the properties of the workpiece metal. Ion: An atom or group of atoms that has lost or gained one or more electrons and is therefore carrying a positive or negative electrical charge, and is described as being ionized. Ionization: The change in the dielectric fluid that is subjected to a voltage potential whereby it becomes electrically conductive, allowing it to conduct the arc. Low-wear: An EDM process in which the volume of electrode wear is between 2 and 15 per cent of the volume of workpiece wear. Normal negative polarity wear ratios are 15 to 40 per cent. Negative electrode: The electrode voltage potential is negative relative to the workpiece. No-wear: An EDM process in which electrode wear is virtually eliminated and the wear ratio is usually less than 2 per cent by volume.
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Machinery's Handbook 27th Edition ELECTRICAL DISCHARGE MACHINING
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Orbit: A programmable motion between the electrode and the workpiece, produced by a feature built in to the machine, or an accessory, that produces a cavity or hole larger than the electrode. The path can be planetary (circular), vectorial, or polygonal (trace). These motions can often be performed in sequence, and combined with x-axis movement of the electrode. Overcut: The distance between one side of an electrode and the adjacent wall of the workpiece cavity. Overcut taper: The difference between the overcut dimensions at the top (entrance) and at the bottom of the cavity. Plasma: A superheated, highly ionized gas that forms in the discharge channel due to the applied voltage. Positive electrode: The electrode voltage potential is positive with respect to the workpiece. is the opposite of this condition. Power parameters: A set of power supply, servo, electrode material, workpiece material, and flushing settings that are selected to produce a desired metal removal rate and surface finish. Quench: The rapid cooling of the EDM surface by the dielectric fluid, which is partially responsible for metallurgical changes in the recast layer and in the heat- affected zone. Recast layer: A layer created by the solidification of molten metal on the workpiece surface after it has been melted by the EDM process. Secondary discharge: A discharge that occurs as conductive particles are carried out along the side of the electrode by the dielectric fluid. Spark in: A method of locating an electrode with respect to the workpiece, using high frequency, low amperage settings so that there is no cutting action. The electrode is advanced toward the workpiece until contact is indicated and this point is used as the basis for setting up the job. Spark out: A technique used in orbiting, which moves the electrode in the same path until sparking ceases. Square wave: An electrical wave shape generated by a solid state power supply. Stroke: The distance the ram travels under servo control. UV axis: A mechanism that provides for movement of the upper head of a wire EDM machine to allow inclined surfaces to be generated. White layer: The surface layer of an EDM cut that is affected by the heat generated during the process. The characteristics of the layer depend on the material, and may be extremely hard martensite or an annealed layer. Wire EDM: An EDM machine or process in which the electrode is a continuously unspooling, conducting wire that moves in preset patterns in relation to the workpiece. Wire guide: A replaceable precision round diamond insert, sized to match the wire, that guides the wire at the entrance and exit points of a wire cut. Wire speed: The rate at which the wire is fed axially through the workpiece (not the rate at which cutting takes place), adjusted so that clean wire is maintained in the cut but slow enough to minimize waste. The EDM Process.—During the EDM process, energy from the sparks created between the electrode and the workpiece is dissipated by the melting and vaporizing of the workpiece material preferentially, only small amounts of material being lost from the electrode. When current starts to flow between the electrode and the work, the dielectric fluid in the small area in which the gap is smallest, and in which the spark will occur, is transformed into a plasma of hydrogen, carbon, and various oxides. This plasma forms a conducting passageway, consisting of ionized or electrically charged particles, through which the spark can form between the electrode and the workpiece. After current starts to flow, to heat and vaporize a tiny area, the striking voltage is reached, the voltage drops, and the field of ionized particles loses its energy, so that the spark can no longer be sustained. As the voltage then begins to rise again with the increase in resistance, the electrical supply is
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Machinery's Handbook 27th Edition 1352
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cut off by the control, causing the plasma to implode and creating a low-pressure pulse that draws in dielectric fluid to flush away metallic debris and cool the impinged area. Such a cycle typically lasts a few microseconds (millionths of a second, or µs), and is repeated continuously in various places on the workpiece as the electrode is moved into the work by the control system. Flushing: An insulating dielectric fluid is made to flow in the space between the workpiece and the electrode to prevent premature spark discharge, cool the workpiece and the electrode, and flush away the debris. For sinker machines, this fluid is paraffin, kerosene, or a silicon-based dielectric fluid, and for wire machines, the dielectric fluid is usually deionized water. The dielectric fluid can be cooled in a heat exchanger to prevent it from rising above about 100°F, at which cooling efficiency may be reduced. The fluid must also be filtered to remove workpiece particles that would prevent efficient flushing of the spark gaps. Care must be taken to avoid the possibility of entrapment of gases generated by sparking. These gases may explode, causing danger to life, breaking a valuable electrode or workpiece, or causing a fire. Flushing away of particles generated during the process is vital to successful EDM operations. A secondary consideration is the heat transferred to the side walls of a cavity, which may cause the workpiece material to expand and close in around the electrode, leading to formation of dc arcs where conductive particles are trapped. Flushing can be done by forcing the fluid to pass through the spark gap under pressure, by sucking it through the gap, or by directing a side nozzle to move the fluid in the tank surrounding the workpiece. In pressure flushing, fluid is usually pumped through strategically placed holes in the electrode or in the workpiece. Vacuum flushing is used when side walls must be accurately formed and straight, and is seldom needed on numerically controlled machines because the table can be programmed to move the workpiece sideways. Flushing needs careful consideration because of the forces involved, especially where fluid is pumped or sucked through narrow passageways, and large hydraulic forces can easily be generated. Excessively high pressures can lead to displacement of the electrode, the workpiece, or both, causing inaccuracy in the finished product. Many low-pressure flushing holes are preferable to a few high-pressure holes. Pressure-relief valves in the system are recommended. Electronic Controls: The electrical circuit that produces the sparks between the electrode and the workpiece is controlled electronically, the length of the extremely short on and off periods being matched by the operator or the programmer to the materials of the electrode and the workpiece, the dielectric, the rate of flushing, the speed of metal removal, and the quality of surface finish required. The average current flowing between the electrode and the workpiece is shown on an ammeter on the power source, and is the determining factor in machining time for a specific operation. The average spark gap voltage is shown on a voltmeter. EDM machines can incorporate provision for orbiting the electrode so that flushing is easier, and cutting is faster and increased on one side. Numerical control can also be used to move the workpiece in relation to the electrode with the same results. Numerical control can also be used for checking dimensions and changing electrodes when necessary. The clearance on all sides between the electrode and the workpiece, after the machining operation, is called the overcut or overburn. The overcut becomes greater with increases in the on time, the spark energy, or the amperage applied, but its size is little affected by voltage changes. Allowances must be made for overcut in the dimensioning of electrodes. Sidewall encroachment and secondary discharge can take up parts of these allowances, and electrodes must always be made smaller to avoid making a cavity or hole too large. Polarity: Polarity can affect processing speed, finish, wear, and stability of the EDM operation. On sinker machines, the electrode is generally, made positive to protect the electrode from excessive wear and preserve its dimensional accuracy. This arrangement
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Machinery's Handbook 27th Edition ELECTRICAL DISCHARGE MACHINING
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removes metal at a slower rate than electrode negative, which is mostly used for highspeed metal removal with graphite electrodes. Negative polarity is also used for machining carbides, titanium, and refractory alloys using metallic electrodes. Metal removal with graphite electrodes can be as much as 50 per cent faster with electrode negative polarity than with electrode positive, but negative polarity results in much faster electrode wear, so it is generally restricted to electrode shapes that can be redressed easily. Newer generators can provide less than 1 per cent wear with either copper or graphite electrodes during roughing operations. Roughing is typically done with a positive-polarity electrode using elevated on times. Some electrodes, particularly micrograin graphites, have a high resistance to wear. Fine-grain, high-density graphites provide better wear characteristics than coarser, less dense grades, and copper-tungsten resists wear better than pure copper electrodes. Machine Settings: For vertical machines, a rule of thumb for power selection on graphite and copper electrodes is 50 to 65 amps per square inch of electrode engagement. For example, an electrode that is 1⁄2 in. square might use 0.5 × 0.5 × 50 = 12.5 amps. Although each square inch of electrode surface may be able to withstand higher currents, lower settings should be used with very large jobs or the workpiece may become overheated and it may be difficult to clean up the recast layer. Lower amperage settings are required for electrodes that are thin or have sharp details. The voltage applied across the arc gap between the electrode and the workpiece is ideally about 35 volts, but should be as small as possible to maintain stability of the process. Spark Frequency: Spark frequency is the number of times per second that the current is switched on and off. Higher frequencies are used for finishing operations and for work on cemented carbide, titanium, and copper alloys. The frequency of sparking affects the surface finish produced, low frequencies being used with large spark gaps for rapid metal removal with a rough finish, and higher frequencies with small gaps for finer finishes. High frequency usually increases, and low frequency reduces electrode wear. The Duty Cycle: Electronic units on modern EDM machines provide extremely close control of each stage in the sparking cycle, down to millionths of a second (µs). A typical EDM cycle might last 100 µs. Of this time, the current might be on for 40 µs and off for 60 µs. The relationship between the lengths of the on and off times is called the duty cycle and it indicates the degree of efficiency of the operation. The duty cycle states the on time as a percentage of the total cycle time and in the previous example it is 40 per cent. Although reducing the off time will increase the duty cycle, factors such as flushing efficiency, electrode and workpiece material, and dielectric condition control the minimum off time. Some EDM units incorporate sensors and fuzzy logic circuits that provide for adaptive control of cutting conditions for unattended operation. Efficiency is also reported as the amount of metal removed, expressed as in.3/hr. In the EDM process, work is done only during the on time, and the longer the on time, the more material is removed in each sparking cycle. Roughing operations use extended on time for high metal-removal rates, resulting in fewer cycles per second, or lower frequency. The resulting craters are broader and deeper so that the surface is rougher and the heat-affected zone (HAZ) on the workpiece is deeper. With positively charged electrodes, the spark moves from the electrode toward the workpiece and the maximum material is removed from the workpiece. However, every spark takes a minute particle from the electrode so that the electrode also is worn away. Finishing electrodes tend to wear much faster than roughing electrodes because more sparks are generated in unit time. The part of the cycle needed for reionizing the dielectric (the off time) greatly affects the operating speed. Although increasing the off time slows the process, longer off times can increase stability by providing more time for the ejected material to be swept away by the flow of the dielectric fluid, and for deionization of the fluid, so that erratic cycling of the servo-mechanisms that advance and retract the electrode is avoided. In any vertical EDM
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operation, if the overcut, wear, and finish are satisfactory, machining speed can best be adjusted by slowly decreasing the off time setting in small increments of 1 to 5 µs until machining becomes erratic, then returning to the previous stable setting. As the off time is decreased, the machining gap or gap voltage will slowly fall and the working current will rise. The gap voltage should not be allowed to drop below 35 to 40 volts. Metal Removal Rates (MRR): Amounts of metal removed in any EDM process depend largely on the length of the on time, the energy/spark, and the number of sparks/second. The following data were provided by Poco Graphite, Inc., in their EDM Technical Manual. For a typical roughing operation using electrode positive polarity on high-carbon steel, a 67 per cent duty cycle removed 0.28 in.3/hr. For the same material, a 50 per cent duty cycle removed 0.15 in.3/hr, and a 33 per cent duty cycle for finishing removed 0.075 in.3/hr. In another example, shown in the top data row in Table 1, a 40 per cent duty cycle with a frequency of 10 kHz and peak current of 50 amps was run for 5 minutes of cutting time. Metal was removed at the rate of 0.8 in.3/hr with electrode wear of 2.5 per cent and a surface finish of 400 µin. Ra. When the on and off times in this cycle were halved, as shown in the second data row in Table 1, the duty cycle remained at 40 per cent, but the frequency doubled to 20 kHz. The result was that the peak current remained unaltered, but with only half the on time the MRR was reduced to 0.7 in.3/hr, the electrode wear increased to 6.3 per cent, and the surface finish improved to 300 µin. Ra. The third and fourth rows in Table 1 show other variations in the basic cycle and the results. Table 1. Effect of Electrical Control Adjustments on EDM Operations
On Time (µs) 40 20 40 40
Off Time (µs) 60 30 10 60
Frequency (kHz) 10 20 20 10
Peak Current (Amps) 50 50 50 25
Metal Removal Rate (in.3/hr) 0.08 0.7 1.2 0.28
Electrode Wear (%) 2.5 6.3 1.4 2.5
Surface Finish (µ in. Ra) 400 300 430 350
The Recast Layer: One drawback of the EDM process when used for steel is the recast layer, which is created wherever sparking occurs. The oil used as a dielectric fluid causes the EDM operation to become a random heat-treatment process in which the metal surface is heated to a very high temperature, then quenched in oil. The heat breaks down the oil into hydrocarbons, tars, and resins, and the molten metal draws out the carbon atoms and traps them in the resolidified metal to form the very thin, hard, brittle surface called the recast layer that covers the heat-affected zone (HAZ). This recast layer has a white appearance and consists of particles of material that have been melted by the sparks, enriched with carbon, and drawn back to the surface or retained by surface tension. The recast layer is harder than the parent metal and can be as hard as glass, and must be reduced or removed by vapor blasting with glass beads, polishing, electrochemical or abrasive flow machining, after the shaping process is completed, to avoid cracking or flaking of surface layers that may cause failure of the part in service. Beneath the thin recast layer, the HAZ, in steel, consists of martensite that usually has been hardened by the heating and cooling sequences coupled with the heat-sink cooling effect of a thick steel workpiece. This martensite is hard and its rates of expansion and contraction are different from those of the parent metal. If the workpiece is subjected to heating and cooling cycles in use, the two layers are constantly stressed and these stresses may cause formation of surface cracks. The HAZ is usually much deeper in a workpiece cut on a sinker than on a wire machine, especially after roughing, because of the increased heating effect caused by the higher amounts of energy applied.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition ELECTRICAL DISCHARGE MACHINING
1355
The depth of the HAZ depends on the amperage and the length of the on time, increasing as these values increase, to about 0.012 to 0.015 in. deep. Residual stress in the HAZ can range up to 650 N/mm2. The HAZ cannot be removed easily, so it is best avoided by programming the series of cuts taken on the machine so that most of the HAZ produced by one cut is removed by the following cut. If time is available, cut depth can be reduced gradually until the finishing cuts produce an HAZ having a thickness of less than 0.0001 in. Workpiece Materials.—Most homogeneous materials used in metalworking can be shaped by the EDM process. Some data on typical workpiece materials are given in Table 2. Sintered materials present some difficulties caused by the use of a cobalt or other binder used to hold the carbide or other particles in the matrix. The binder usually melts at a lower temperature than the tungsten, molybdenum, titanium, or other carbides, so it is preferentially removed by the sparking sequence and the carbide particles are thus loosened and freed from the matrix. The structures of sintered materials based on tungsten, cobalt, and molybdenum require higher EDM frequencies with very short on times, so that there is less danger of excessive heat buildup, leading to melting. Copper-tungsten electrodes are recommended for EDM of tungsten carbides. When used with high frequencies for powdered metals, graphite electrodes often suffer from excessive wear. Workpieces of aluminum, brass, and copper should be processed with metallic electrodes of low melting points such as copper or copper-tungsten. Workpieces of carbon and stainless steel that have high melting points should be processed with graphite electrodes. The melting points and specific gravities of the electrode material and of the workpiece should preferably be similar. Table 2. Characteristics of Common Workpiece Materials for EDM
Material Aluminum Brass Cobalt Copper Graphite Inconel Magnesium Manganese Molybdenum Nickel Carbon Steel Tool Steel Stainless Steel Titanium Tungsten Zinc
Specific Gravity 2.70 8.40 8.71 8.89 2.07 … 1.83 7.30 10.20 8.80 7.80 … … 4.50 18.85 6.40
Melting Point
Vaporization Temperature
°F
°C
°F
°C
1220 1710 2696 1980
660 930 1480 1082
4442
2450
N/A 2350 1202 2300 4748 2651 2500 2730 2750 3200 6098 790
1285 650 1260 2620 1455 1371 1500 1510 1700 3370 420
… 5520 4710 6330
2900 2595 3500 …
2025 3870 10,040 4900
1110 2150 5560 2730 … … …
5900 10,670 1663
3260 5930 906
Conductivity (Silver = 100) 63.00 … 16.93 97.61 70.00 … 39.40 15.75 17.60 12.89 12.00 … … 13.73 14.00 26.00
Electrode Materials.—Most EDM electrodes are made from graphite, which provides a much superior rate of metal removal than copper because of the ability of graphite to resist thermal damage. Graphite has a density of 1.55 to 1.85 g/cm3, lower than most metals. Instead of melting when heated, graphite sublimates, that is, it changes directly from a solid to a gas without passing through the liquid stage. Sublimation of graphite occurs at a temperature of 3350°C (6062°F). EDM graphite is made by sintering a compressed mixture of fine graphite powder (1 to 100 micron particle size) and coal tar pitch in a furnace. The open structure of graphite means that it is eroded more rapidly than metal in the EDM process. The electrode surface is also reproduced on the surface of the workpiece. The sizes of individual surface recesses may be reduced during sparking when the work is moved under numerical control of workpiece table movements.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1356
ELECTRICAL DISCHARGE MACHINING
The fine grain sizes and high densities of graphite materials that are specially made for high-quality EDM finishing provide high wear resistance, better finish, and good reproduction of fine details, but these fine grades cost more than graphite of larger grain sizes and lower densities. Premium grades of graphite cost up to five times as much as the least expensive and about three times as much as copper, but the extra cost often can be justified by savings during machining or shaping of the electrode. Graphite has a high resistance to heat and wear at lower frequencies, but will wear more rapidly when used with high frequencies or with negative polarity. Infiltrated graphites for EDM electrodes are also available as a mixture of copper particles in a graphite matrix, for applications where good machinability of the electrode is required. This material presents a trade-off between lower arcing and greater wear with a slower metal-removal rate, but costs more than plain graphite. EDM electrodes are also made from copper, tungsten, silver-tungsten, brass, and zinc, which all have good electrical and thermal conductivity. However, all these metals have melting points below those encountered in the spark gap, so they wear rapidly. Copper with 5 per cent tellurium, added for better machining properties, is the most commonly used metal alloy. Tungsten resists wear better than brass or copper and is more rigid when used for thin electrodes but is expensive and difficult to machine. Metal electrodes, with their more even surfaces and slower wear rates, are often preferred for finishing operations on work that requires a smooth finish. In fine-finishing operations, the arc gap between the surfaces of the electrode and the workpiece is very small and there is a danger of dc arcs being struck, causing pitting of the surface. This pitting is caused when particles dislodged from a graphite electrode during fine-finishing cuts are not flushed from the gap. If struck by a spark, such a particle may provide a path for a continuous discharge of current that will mar the almost completed work surface. Some combinations of electrode and workpiece material, electrode polarity, and likely amounts of corner wear are listed in Table 3. Corner wear rates indicate the ability of the electrode to maintain its shape and reproduce fine detail. The column headed Capacitance refers to the use of capacitors in the control circuits to increase the impact of the spark without increasing the amperage. Such circuits can accomplish more work in a given time, at the expense of surface-finish quality and increased electrode wear. Table 3. Types of Electrodes Used for Various Workpiece Materials Electrode Copper Copper Copper Copper Copper Copper Copper Copper-tungsten Copper-tungsten Copper-tungsten Copper-tungsten Copper-tungsten Graphite Graphite Graphite Graphite Graphite Graphite Graphite Graphite
Electrode Polarity + + + − − − − + − − − − + − + − + − − −
Workpiece Material Steel Inconel Aluminum Titanium Carbide Copper Copper-tungsten Steel Copper Copper-tungsten Titanium Carbide Steel Steel Inconel Inconel Aluminum Aluminum Titanium Copper
Corner Wear (%) 2–10 2–10 200 mm
Width Across Flats, S
> 125 and < 200 mm
Body Diameter, Ds
< 125 mm
Nominal Bolt Dia., D and Thread Pitch M5 × 0.8 M6 × 1 M8 × 1.25
Wrenching Height, K1
For Bolt Lengths
Basic Thread Min Length,a B 2.4 16 22 35 2.8 18 24 37 3.7 22 28 41 4.5 26 32 45 4.5 26 32 45 5.2 30 36 49 6.2 34 40 53 7.0 38 44 57 8.8 46 52 65 10.5 54 60 73 13.1 66 72 85 15.8 78 84 97 18.2 90 96 109 21.0 102 108 121 24.5 … 124 137 28.0 … 140 153 31.5 … 156 169 35.0 … 172 185 39.2 … 192 205 43.4 … 212 225
a Basic thread length, B, is a reference dimension. b This size with width across flats of 15 mm is not standard. Unless specifically ordered, M10 hex bolts with 16 mm width across flats will be furnished. All dimensions are in millimeters. For additional manufacturing and acceptance specifications, reference should be made to the ANSI B18.2.3.5M-1979 (R1995) standard.
Materials and Mechanical Properties.—Unless otherwise specified, steel metric screws and bolts, with the exception of heavy hex structural bolts, hex lag screws, and socket head cap screws, conform to the requirements specified in SAE J1199 or ASTM F568. Steel heavy hex structural bolts conform to ASTM A325M or ASTM A490M. Alloy steel socket head cap screws conform to ASTM A574M, property class 12.9, where the numeral 12 represents approximately one-hundredth of the minimum tensile strength in megapascals and the decimal .9 approximates the ratio of the minimum yield stress to the minimum tensile stress. This is in accord with ISO designation practice. Screws and bolts
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC SCREWS AND BOLTS
1551
of other materials, and all materials for hex lag bolts, have properties as agreed upon by the purchaser and the manufacturer. Except for socket head cap screws, metric screws and bolts are furnished with a natural (as processed) finish, unplated or uncoated unless otherwise specified. Alloy steel socket head cap screws are furnished with an oiled black oxide coating (thermal or chemical) unless a protective plating or coating is specified by the purchaser. Metric Screw and Bolt Identification Symbols.—Screws and bolts are identified on the top of the head by property class symbols and manufacturer's identification symbol. Metric Screw and Bolt Designation.—Metric screws and bolts with the exception of socket head cap screws are designated by the following data, preferably in the sequence shown: product name, nominal diameter and thread pitch (except for hex lag screws), nominal length, steel property class or material identification, and protective coating, if required. Example:Hex cap screw, M10 × 1.5 × 50, class 9.8, zinc plated Heavy hex structural bolt, M24 × 3 × 80, ASTM A490M Hex lag screw, 6 × 35, silicon bronze. Socket head cap screws (metric series) are designated by the following data in the order shown: ANSI Standard number, nominal size, thread pitch, nominal screw length, name of product (may be abbreviated SHCS), material and property class (alloy steel screws are supplied to property class 12.9 as specified in ASTM A574M: corrosion-resistant steel screws are specified to the property class and material requirements in ASTM F837M), and protective finish, if required. Example:B18.3.1M—6 × 1 × 20 Hexagon Socket Head Cap Screw, Alloy Steel B18.3.1M—10 × 1.5 × 40 SHCS, Alloy Steel Zinc Plated. Metric Screw and Bolt Thread Lengths.—The length of thread on metric screws and bolts (except for metric lag screws) is controlled by the grip gaging length, Lg max. This is the distance measured parallel to the axis of the screw or bolt, from under the head bearing surface to the face of a noncounterbored or noncountersunk standard GO thread ring gage assembled by hand as far as the thread will permit. The maximum grip gaging length, as calculated and rounded to one decimal place, is equal to the nominal screw length, L, minus the basic thread length, B, or in the case of socket head cap screws, minus the minimum thread length LT. B and LT are reference dimensions intended for calculation purposes only and will be found in Tables 12 and 14, respectively. Table 13. Basic Thread Lengths for Metric Round Head Square Neck Bolts ANSI/ASME B18.5.2.2M-1982, R1993 Nom. Bolt Dia., D and Thread Pitch M5 × 0.8 M6 × 1 M8 × 1.25 M10 × 1.5 M12 × 1.75
Bolt Length, L ≤ 125
> 125 and ≤ 200
> 200
Basic Thread Length, B 16 18 22 26 30
22 24 28 32 36
35 37 41 45 49
Bolt Length, L
Nom. Bolt Dia., D and Thread Pitch
≤ 125
M14 × 2 M16 × 2 M20 × 2.5 M24 × 3 …
34 38 46 54 …
> 125 and ≤ 200
> 200
Basic Thread length, B 40 44 52 60 …
All dimensions are in millimeters Basic thread length B is a reference dimension intended for calculation purposes only.
Copyright 2004, Industrial Press, Inc., New York, NY
53 57 65 73 …
Machinery's Handbook 27th Edition 1552
METRIC SCREWS AND BOLTS
Table 14. Socket Head Cap Screws (Metric Series)—Length of Complete Thread ANSI/ASME B18.3.1M-1986 Length of Complete Thread, LT
Nominal Size
Nominal Size
Length of Complete Thread, LT
Nominal Size
Length of Complete Thread, LT
M20
52.0
M1.6
15.2
M6
24.0
M2
16.0
M8
28.0
M24
60.0
M2.5
17.0
M10
32.0
M30
72.0
M3
18.0
M12
36.0
M36
84.0
M4
20.0
M14
40.0
M42
96.0
M5
22.0
M16
44.0
M48
108.0
Grip length, LG equals screw length, L, minus LT. Total length of thread LTT equals LT plus 5 times the pitch of the coarse thread for the respective screw size. Body length LB equals L minus LTT.
The minimum thread length for hex lag screws is equal to one-half the nominal screw length plus 12 mm, or 150 mm, whichever is shorter. Screws too short for this formula to apply are threaded as close to the head as practicable. Metric Screw and Bolt Diameter-Length Combinations.—For a given diameter, the recommended range of lengths of metric cap screws, formed hex screws, heavy hex screws, hex flange screws, and heavy hex flange screws can be found in Table 16, for heavy hex structural bolts in Table 17, for hex lag screws in Table 15, for round head square neck bolts in Table 18, and for socket head cap screws in Table 19. No recommendations for diameter-length combinations are given in the Standards for hex bolts and heavy hex bolts. Hex bolts in sizes M5 through M24 and heavy hex bolts in sizes M12 through M24 are standard only in lengths longer than 150 mm or 10D, whichever is shorter. When shorter lengths of these sizes are ordered, hex cap screws are normally supplied in place of hex bolts and heavy hex screws in place of heavy hex bolts. Hex bolts in sizes M30 and larger and heavy hex bolts in sizes M30 and M36 are standard in all lengths; however, at manufacturer's option, hex cap screws may be substituted for hex bolts and heavy hex screws for heavy hex bolts for any diameter-length combination. Table 15. Recommended Diameter-Length Combinations for Metric Hex Lag Screws ANSI B18.2.3.8M-1981 (R1999) Nominal Length, L
5
6
8
10
12
16
20
24
Nominal Length, L
10
12
16
20
24
8
d
…
…
…
…
…
…
…
90
d
d
d
d
d
10
d
d
…
…
…
…
…
…
100
d
d
d
d
d
12
d
d
d
…
…
…
…
…
110
…
d
d
d
d
14
d
d
d
…
…
…
…
…
120
…
d
d
d
d
16
d
d
d
d
…
…
…
…
130
…
…
d
d
d
20
d
d
d
d
d
…
…
…
140
…
…
d
d
d
25
d
d
d
d
d
d
…
…
150
…
…
d
d
d
30
d
d
d
d
d
d
d
…
160
…
…
d
d
d
35
d
d
d
d
d
d
d
d
180
…
…
…
d
d
40
d
d
d
d
d
d
d
d
200
…
…
…
d
d
45
d
d
d
d
d
d
d
d
220
…
…
…
…
d
50
d
d
d
d
d
d
d
d
240
…
…
…
…
d
60
…
d
d
d
d
d
d
d
260
…
…
…
…
d
70
…
…
d
d
d
d
d
d
280
…
…
…
…
d
80
…
…
d
d
d
d
d
d
300
…
…
…
…
d
Nominal Screw Diameter
Nominal Screw Diameter
All dimensions are in millimeters. Recommended diameter-length combinations are indicated by the symbol d.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC SCREWS AND BOLTS
1553
Table 16. Rec’d Diameter-Length Combinations for Metric Hex Cap Screws, Formed Hex and Heavy Hex Screws, Hex Flange and Heavy Hex Flange Screws Diameter—Pitch Nominal Lengtha
M5 ×0.8
M6 ×1
M8 ×1.25
M10 ×1.5
M12 ×1.75
M14 ×2
M16 ×2
M20 ×2.5
M24 ×3
M30 ×3.5
M36 ×4
8
d
…
…
…
…
…
…
…
…
…
…
10
d
d
…
…
…
…
…
…
…
…
…
12
d
d
d
…
…
…
…
…
…
…
…
14
d
d
d
db
…
…
…
…
…
…
…
16
d
d
d
d
db
db
…
…
…
…
…
20
d
d
d
d
d
d
…
…
…
…
…
25
d
d
d
d
d
d
d
…
…
…
…
30
d
d
d
d
d
d
d
d
…
…
…
35
d
d
d
d
d
d
d
d
d
…
…
40
d
d
d
d
d
d
d
d
d
d
…
45
d
d
d
d
d
d
d
d
d
d
…
50
d
d
d
d
d
d
d
d
d
d
d
(55)
…
d
d
d
d
d
d
d
d
d
d
60
…
d
d
d
d
d
d
d
d
d
d
(65)
…
…
d
d
d
d
d
d
d
d
d
70
…
…
d
d
d
d
d
d
d
d
d
(75)
…
…
d
d
d
d
d
d
d
d
d
80
…
…
d
d
d
d
d
d
d
d
d
(85)
…
…
…
d
d
d
d
d
d
d
d d
90
…
…
…
d
d
d
d
d
d
d
100
…
…
…
d
d
d
d
d
d
d
d
110
…
…
…
…
d
d
d
d
d
d
d
120
…
…
…
…
d
d
d
d
d
d
d
130
…
…
…
…
…
d
d
d
d
d
d
140
…
…
…
…
…
d
d
d
d
d
d
150
…
…
…
…
…
…
d
d
d
d
d
160
…
…
…
…
…
…
d
d
d
d
d
(170)
…
…
…
…
…
…
…
d
d
d
d
180
…
…
…
…
…
…
…
d
d
d
d
(190)
…
…
…
…
…
…
…
d
d
d
d
200
…
…
…
…
…
…
…
d
d
d
d
220
…
…
…
…
…
…
…
…
d
d
d
240
…
…
…
…
…
…
…
…
d
d
d
260
…
…
…
…
…
…
…
…
…
d
d
280
…
…
…
…
…
…
…
…
…
d
d
300
…
…
…
…
…
…
…
…
…
d
d
a Lengths
in parentheses are not recommended. Recommended lengths of formed hex screws, hex flange screws, and heavy hex flange screws do not extend above 150 mm. Recommended lengths of heavy hex screws do not extend below 20 mm. Standard sizes for government use. Recommended diameter-length combinations are indicated by the symbol d. Screws with lengths above heavy cross lines are threaded full length. b Does not apply to hex flange screws and heavy hex flange screws.
All dimensions are in millimeters. For available diameters of each type of screw, see respective dimensional table.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1554
METRIC SCREWS AND BOLTS Table 17. Recommended Diameter-Length Combinations for Metric Heavy Hex Structural Bolts
Nominal Length, L
Nominal Diameter and Thread Pitch M16 × 2
M20 × 2.5
M22 × 2.5
M24 × 3
M27 × 3
M30 × 3.5
M36 × 4
d
…
d
d
… …
d
d
d
… … …
d
d
d
d
… … … …
d
d
d
d
d
… … … … …
d
d
d
d
d
d
d
d
d
d
d
d
… … … … … … …
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
45 50 55 60 65 70 75 80 85 90 95 100 110 120 130 140 150 160 170 180 190 200 210 220 230 240 250 260 270 280 290 300
All dimensions are in millimeters. Recommended diameter-length combinations are indicated by the symbol d. Bolts with lengths above the heavy cross lines are threaded full length.
Table 18. Recommended Diameter-Length Combinations for Metric Round Head Square Neck Bolts Nominal Length,a L 10 12 (14) 16 20 25 30 35 40 45 50 (55) 60 (65) 70 (75) 80
Nominal Diameter and Thread Pitch M5 × 0.8
M6 ×1
M8 × 1.25
M10 × 1.5
M12 × 1.75
M14 ×2
M16 ×2
M20 × 2.5
M24 ×3
d
…
d
d
d
d
… … …
d
d
d
… … … …
d
d
d
d
… … … … …
d
d
d
d
d
… … … … … …
… … … … … …
d
d
d
d
d
d
d
d
d
d
d
d
d
d
… … … … … … … …
d
d
d
d
d
d
d
d
… … … … … … … … …
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
… … … … … …
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
… … … …
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC SCREWS AND BOLTS
1555
Table 18. (Continued) Recommended Diameter-Length Combinations for Metric Round Head Square Neck Bolts Nominal Diameter and Thread Pitch
Nominal Length,a L
M5 × 0.8 … … … … … … … … … … … … … … …
(85) 90 100 110 120 130 140 150 160 (170) 180 (190) 200 220 240
M6 ×1 … … … … … … … … … … … … … … …
M8 × 1.25 … … … … … … … … … … … … … … …
M10 × 1.5
M12 × 1.75
M14 ×2
M16 ×2
M20 × 2.5
M24 ×3
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
… … … … … … … … … … … …
d
d
d
d
d
d
d
d
d
d
… … … … … … … … … …
d
d
d
d
d
d
d
d
… … … … … … … …
d
d
d
d
d
d
… … … … … …
d
d
d
d
d
d
d
d
… …
d d
a Bolts with lengths above the heavy cross lines are threaded full length. Lengths in ( ) are not recom-
mended. All dimensions are in millimeters. Recommended diameter-length combinations are indicated by the symbol d. Standard sizes for government use.
Table 19. Diameter-Length Combinations for Socket Head Cap Screws (Metric Series) Nominal Length, L 20 25 30 35 40 45 50 55 60 65 70 80 90 100 110 120 130 140 150 160 180 200 220 240 260 300
Nominal Size M1.6
M2
d
d
d
d
M2.5 d
M3
M4
M5
M6
d
M8
M10
M12
M14
M16
M20
M24
d
d
d
d
d
d
… … … … … … … … … … … … … … … … … … … … … … …
d
d
d
d
d
d
d
d
d
d
d
… … … … … … … … … … … … … … … … … … … … …
d
d
d
d
d
d
d
d
d
d
d
d
d
… … … … … … … … … … … … … … … … … … …
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
… … … … … … … … … … … … … … … …
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
… … … … … … … … … … … … … …
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
… … … … … … … … … … … …
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
… … … … … … … … … …
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
… … … … … …
d
d
d
d
d
d
d
d
d
d
d
d
… … … …
d
d
d
d
d
d
d
d
d
… …
d
d
d
d
…
d
d
d
d
d
d
d
d
All dimensions are in millimeters. Screws with lengths above heavy cross lines are threaded full length. Diameter-length combinations are indicated by the symbol d. Standard sizes for government use. In addition to the lengths shown, the following lengths are standard: 3, 4, 5, 6, 8, 10, 12, and 16 mm. No diameter-length combinations are given in the Standard for these lengths. Screws larger than M24 with lengths equal to or shorter than LTT (see Table 14 footnote) are threaded full length.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1556
METRIC SCREWS AND BOLTS
Metric Screw and Bolt Thread Series.—Unless otherwise specified, metric screws and bolts, except for hex lag screws, are furnished with metric coarse threads conforming to the dimensions for general purpose threads given in ANSI B1.13M (see American National Standard Metric Screw Threads M Profile on page 1783). Except for socket head cap screws, the tolerance class is 6g, which applies to plain finish (unplated or uncoated) screws or bolts and to plated or coated screws or bolts before plating or coating. For screws with additive finish, the 6g diameters may be exceeded by the amount of the allowance, i.e. the basic diameters apply to the screws or bolts after plating or coating. For socket head cap screws, the tolerance class is 4g6g, but for plated screws, the allowance g may be consumed by the thickness of plating so that the maximum limit of size after plating is tolerance class 4h6h. Thread limits are in accordance with ANSI B1.13M. Metric hex lag screws have a special thread which is covered in Table 5. Metric Screw and Bolt Clearance Holes.—Clearance holes for screws and bolts with the exception of hex lag screws, socket head cap screws, and round head square neck bolts are given in Table 20. Clearance holes for round head square neck bolts are given in Table 8 and drill and counterbore sizes for socket head cap screws are given in Table 21. Table 20. Recommended Clearance Holes for Metric Hex Screws and Bolts Nominal Dia., D and Thread Pitch M5 × 0.8 M6 × 1 M8 × 1.25 M10 × 1.5 M12 × 1.75 M14 × 2 M16 × 2 M20 × 2.5 M22 × 2.5a M24 × 3 M27 × 3a
Clearance Hole Dia., Basic, Dh
Clearance Hole Dia., Basic,Dh
Close
Normal, Preferred
Loose
Nominal Dia., D and Thread Pitch
Close
Normal, Preferred
Loose
5.3 6.4 8.4 10.5 13.0 15.0 17.0 21.0 23.0
5.5 6.6 9.0 11.0 13.5 15.5 17.5 22.0 24.0
5.8 7.0 10.0 12.0 14.5 16.5 18.5 24.0 26.0
M30 × 3.5 M36 × 4 M42 × 4.5 M48 × 5 M56 × 5.5 M64 × 6 M72 × 6 M80 × 6 M90 × 6
31.0 37.0 43.0 50.0 58.0 66.0 74.0 82.0 93.0
33.0 39.0 45.0 52.0 62.0 70.0 78.0 86.0 96.0
35.0 42.0 48.0 56.0 66.0 74.0 82.0 91.0 101.0
25.0 28.0
26.0 30.0
28.0 32.0
M100 × 6 …
104.0 …
107.0 …
112.0 …
a Applies only to heavy hex structural bolts.
All dimensions are in millimeters. Does not apply to hex lag screws, hex socket head cap screws, or round head square neck bolts. Normal Clearance: This is preferred for general purpose applications and should be specified unless special design considerations dictate the need for either a close or loose clearance hole. Close Clearance: This should be specified only where conditions such as critical alignment of assembled parts, wall thickness or other limitations necessitate use of a minimum hole. When close clearance holes are specified, special provision (e.g. countersinking) must be made at the screw or bolt entry side to permit proper seating of the screw or bolt head. Loose Clearance: This should be specified only for applications where maximum adjustment capability between components being assembled is necessary. Recommended Tolerances: The clearance hole diameters given in this table are minimum size. Recommended tolerances are: for screw or bolt diameter M5, +0.2 mm; for M6 through M16, +0.3 mm; for M20 through M42, +0.4 mm; for M48 through M72, +0.5 mm; and for M80 through M100, +0.6 mm.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC SCREWS AND BOLTS
1557
Table 21. Drill and Counterbore Sizes for Metric Socket Head Cap Screws
Nominal Size or Basic Screw Diameter
Nominal Drill Size, A Close Fitb
Normal Fitc
Counterbore Diameter, X
Countersink Diameter,a Y 2.0
M1.6
1.80
1.95
3.50
M2
2.20
2.40
4.40
2.6
M2.5
2.70
3.00
5.40
3.1
M3
3.40
3.70
6.50
3.6
M4
4.40
4.80
8.25
4.7
M5
5.40
5.80
9.75
5.7
M6
6.40
6.80
11.25
6.8
M8
8.40
8.80
14.25
9.2
M10
10.50
10.80
17.25
11.2
M12
12.50
12.80
19.25
14.2
M14
14.50
14.75
22.25
16.2
M16
16.50
16.75
25.50
18.2
M20
20.50
20.75
31.50
22.4
M24
24.50
24.75
37.50
26.4
M30
30.75
31.75
47.50
33.4
M36
37.00
37.50
56.50
39.4
M42
43.00
44.00
66.00
45.6
M48
49.00
50.00
75.00
52.6
a Countersink:
It is considered good practice to countersink or break the edges of holes which are smaller than B Max. (see Table 24) in parts having a hardness which approaches, equals, or exceeds the screw hardness. If such holes are not countersunk, the heads of screws may not seat properly or the sharp edges on holes may deform the fillets on screws, thereby making them susceptible to fatigue in applications involving dynamic loading. The countersink or corner relief, however, should not be larger than is necessary to ensure that the fillet on the screw is cleared. Normally, the diameter of countersink does not have to exceed B Max. Countersinks or corner reliefs in excess of this diameter reduce the effective bearing area and introduce the possibility of embedment where the parts to be fastened are softer than the screws or of brinnelling or flaring the heads of the screws where the parts to be fastened are harder than the screws. b Close Fit: The close fit is normally limited to holes for those lengths of screws which are threaded to the head in assemblies where only one screw is to be used or where two or more screws are to be used and the mating holes are to be produced either at assembly or by matched and coordinated tooling. c Normal Fit: The normal fit is intended for screws of relatively long length or for assemblies involving two or more screws where the mating holes are to be produced by conventional tolerancing methods. It provides for the maximum allowable eccentricity of the longest standard screws and for certain variations in the parts to be fastened, such as: deviations in hole straightness, angularity between the axis of the tapped hole and that of the hole for shank, differences in center distances of the mating holes, etc. All dimensions are in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1558
METRIC SCREWS AND BOLTS
Table 22. Recommended Clearance Holes for Metric Round Head Square Neck Bolts
Clearance Nom. Bolt Dia., D and Thd. Pitch M5 × 0.8 M6 × 1 M8 × 1.25 M10 × 1.5 M12 × 1.75
Closea
Normalb
Clearance Loosec
Minimum Hole Diameter or Square Width, H
Corner Radius Rh
… … 9.0 11.0 13.5
0.2 0.3 0.4 0.4 0.6
5.5 6.6 … … 13.0
5.8 7.0 10.0 12.0 14.5
Nom. Bolt Dia., D and Thd. Pitch M14 × 2 M16 × 2 M20 × 2.5 M24 × 3 …
Closea
Normalb
Loosec
Minimum Hole Diameter or Square Width, H 15.0 17.0 21.0 25.0 …
15.5 17.5 22.0 26.0 …
16.5 18.5 24.0 28.0 …
Corner Radius Rh 0.6 0.6 0.8 1.0 …
a Close Clearance: Close clearance should be specified only for square holes in very thin and/or soft material, or for slots, or where conditions such as critical alignment of assembled parts, wall thickness, or other limitations necessitate use of a minimal hole. Allowable swell or fins on the bolt body and/or fins on the corners of the square neck may interfere with close clearance round or square holes. b Normal Clearance: Normal clearance hole sizes are preferred for general purpose applications and should be specified unless special design considerations dictate the need for either a close or loose clearance hole. c Loose Clearance: Loose clearance hole sizes should be specified only for applications where maximum adjustment capability between components being assembled is necessary. Loose clearance square hole or slots may not prevent bolt turning during wrenching.
All dimensions are in millimeters.
Table 23. Drilled Head Dimensions for Metric Hex Socket Head Cap Screws
Two holes Nominal Size or Basic Screw Diameter M3 M4 M5 M6 M8 M10 M12 M16 M20 M24 M30 M36
Six holes Hole Center Location, W Max Min
Drilled Hole Diameter, X Max Min
1.20 1.60 2.00 2.30 2.70 3.30 4.00 5.00 6.30 7.30 9.00 10.50
0.95 1.35 1.35 1.35 1.35 1.65 1.65 1.65 2.15 2.15 2.15 2.15
0.80 1.20 1.50 1.80 2.20 2.80 3.50 4.50 5.80 6.80 8.50 10.00
0.80 1.20 1.20 1.20 1.20 1.50 1.50 1.50 2.00 2.00 2.00 2.00
Copyright 2004, Industrial Press, Inc., New York, NY
Hole Alignment Check Plug Diameter Basic 0.75 0.90 0.90 0.90 0.90 1.40 1.40 1.40 1.80 1.80 1.80 1.80
Machinery's Handbook 27th Edition METRIC SCREWS AND BOLTS
1559
All dimensions are in millimeters. Drilled head metric hexagon socket head cap screws normally are not available in screw sizes smaller than M3 nor larger than M36. The M3 and M4 nominal screw sizes have two drilled holes spaced 180 degrees apart. Nominal screw sizes M5 and larger have six drilled holes spaced 60 degrees apart unless the purchaser specifies two drilled holes. The positioning of holes on opposite sides of the socket should be such that the hole alignment check plug will pass completely through the head without any deflection. When so specified by the purchaser, the edges of holes on the outside surface of the head will be chamfered 45 degrees to a depth of 0.30 to 0.50 mm.
Table 24. American National Standard Socket Head Cap Screws— Metric Series ANSI/ASME B18.3.1M-1986
Body Diameter, D
Head Diameter A
Chamfer or Radius S
Hexagon Socket Sizea J
Spline TransiKey Socket Engage tion Dia. Sizea ment Ba M T
Min
Max
Nom.
Nom.
Min
Max
1.52 1.91 2.40 2.89 3.88 4.86 5.85 7.83 9.81 11.79 13.77 15.76 19.73 23.70 29.67 35.64 41.61 47.58
0.16 0.20 0.25 0.30 0.40 0.50 0.60 0.80 1.00 1.20 1.40 1.60 2.00 2.40 3.00 3.60 4.20 4.80
1.5 1.5 2.0 2.5 3.0 4.0 5.0 6.0 8.0 10.0 12.0 14.0 17.0 19.0 22.0 27.0 32.0 36.0
1.829 1.829 2.438 2.819 3.378 4.648 5.486 7.391 … … … … … … … … … …
0.80 1.00 1.25 1.50 2.00 2.50 3.00 4.00 5.00 6.00 7.00 8.00 10.00 12.00 15.00 18.00 21.00 24.00
2.0 2.6 3.1 3.6 4.7 5.7 6.8 9.2 11.2 14.2 16.2 18.2 22.4 26.4 33.4 39.4 45.6 52.6
Head Height H
Nom. Size and Thread Pitch
Max
Min
Max
Min
Max
M1.6 × 0.35 M2 × 0.4 M2.5 × 0.45 M3 × 0.5 M4 × 0.7 M5 × 0.8 M6 × 1 M8 × 1.25 M10 × 1.5 M12 × 1.75 M14 × 2b M16 × 2 M20 × 2.5 M24 × 3 M30 × 3.5 M36 × 4 M42 × 4.5 M48 × 5
1.60 2.00 2.50 3.00 4.00 5.00 6.00 8.00 10.00 12.00 14.00 16.00 20.00 24.00 30.00 36.00 42.00 48.00
1.46 1.86 2.36 2.86 3.82 4.82 5.82 7.78 9.78 11.73 13.73 15.73 19.67 23.67 29.67 35.61 41.61 47.61
3.00 3.80 4.50 5.50 7.00 8.50 10.00 13.00 16.00 18.00 21.00 24.00 30.00 36.00 45.00 54.00 63.00 72.00
2.87 3.65 4.33 5.32 6.80 8.27 9.74 12.70 15.67 17.63 20.60 23.58 29.53 35.48 44.42 53.37 62.31 71.27
1.60 2.00 2.50 3.00 4.00 5.00 6.00 8.00 10.00 12.00 14.00 16.00 20.00 24.00 30.00 36.00 42.00 48.00
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1560
METRIC NUTS
a See also Table 25. b The M14 × 2 size is not recommended for use in new designs.
All dimensions are in millimeters LG is grip length and LB is body length (see Table 14). For length of complete thread, see Table 14. For additional manufacturing and acceptance specifications, see ANSI/ASME B18.3.1M-1986.
Table 25. American National Standard Hexagon and Spline Sockets for Socket Head Cap Screws—Metric Series ANSI/ASME B18.3.1M-1986
METRIC HEXAGON SOCKETS
METRIC SPLINE SOCKET
See Table 24 Nominal Hexagon Socket Size
1.5 2 2.5 3 4 5 6 8 10
Socket Width Across Flats, J Max
Min
1.545 2.045 2.560 3.071 4.084 5.084 6.095 8.115 10.127
1.520 2.020 2.520 3.020 4.020 5.020 6.020 8.025 10.025
See Table 24 Nominal Socket Width Hexagon Across Corners, Socket C Size Metric Hexagon Sockets Min 1.73 2.30 2.87 3.44 4.58 5.72 6.86 9.15 11.50
Socket Major Diameter, M
Nominal Spline Socket Size
Max
Min
1.829 2.438 2.819 3.378 4.648 5.486 7.391
1.8796 2.4892 2.9210 3.4798 4.7752 5.6134 7.5692
1.8542 2.4638 2.8702 3.4290 4.7244 5.5626 7.5184
12 14 17 19 22 24 27 32 36
Socket Width Across Flats, J Max
Min
Min
12.146 14.159 17.216 19.243 22.319 24.319 27.319 32.461 36.461
12.032 14.032 17.050 19.065 22.065 24.065 27.065 32.080 36.080
13.80 16.09 19.56 21.87 25.31 27.60 31.04 36.80 41.38
Metric Spline Socketsa Socket Minor Diameter, N Max Min 1.6256 2.0828 2.4892 2.9972 4.1402 4.8260 6.4516
Socket Width Across Corners, C
1.6002 2.0320 2.4384 2.9464 4.0894 4.7752 6.4008
Width of Tooth, P Max
Min
0.4064 0.5588 0.6350 0.7620 0.9906 1.2700 1.7272
0.3810 0.5334 0.5842 0.7112 0.9398 1.2192 2.6764
a The tabulated dimensions represent direct metric conversions of the equivalent inch size spline sockets shown in American National Standard Socket Cap, Shoulder and Set Screws — Inch Series ANSI B18.3. Therefore, the spline keys and bits shown therein are applicable for wrenching the corresponding size metric spline sockets.
Metric Nuts The American National Standards covering metric nuts have been established in cooperation with the Department of Defense in such a way that they could be used by the Government for procurement purposes. Extensive information concerning these nuts is given in the following text and tables, but for more complete manufacturing and acceptance specifications, reference should be made to the respective Standards, which may be obtained by
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC NUTS
1561
non-governmental agencies from the American National Standards Institute, 25 West 43rd Street, New York, N.Y. 10036. Manufacturers should be consulted concerning items and sizes which are in stock production. Comparison with ISO Standards.—American National Standards for metric nuts have been coordinated to the extent possible with comparable ISO Standards or proposed Standards, thus: ANSI B18.2.4.1M Metric Hex Nuts, Style 1 with ISO 4032; B18.2.4.2M Metric Hex Nuts, Style 2 with ISO 4033; B18.2.4.4M Metric Hex Flange Nuts with ISO 4161; B18.2.4.5M Metric Hex Jam Nuts with ISO 4035; and B18.2.4.3M Metric Slotted Hex Nuts, B18.2.4.6M Metric Heavy Hex Nuts in sizes M12 through M36, and B18.16.3M Prevailing-Torque Type Steel Metric Hex Nuts and Hex Flange Nuts with comparable draft ISO Standards. The dimensional differences between each ANSI Standard and the comparable ISO Standard or draft Standard are very few, relatively minor, and none will affect the interchangeability of nuts manufactured to the requirements of either. At its meeting in Varna, May 1977, ISO/TC2 studied several technical reports analyzing design considerations influencing determination of the best series of widths across flats for hex bolts, screws, and nuts. A primary technical objective was to achieve a logical ratio between under head (nut) bearing surface area (which determines the magnitude of compressive stress on the bolted members) and the tensile stress area of the screw thread (which governs the clamping force that can be developed by tightening the fastener). The series of widths across flats in the ANSI Standards agree with those which were selected by ISO/TC2 to be ISO Standards. One exception for width across flats of metric hex nuts, styles 1 and 2, metric slotted hex nuts, metric hex jam nuts, and prevailing-torque metric hex nuts is the M10 size. These nuts in M10 size are currently being produced in the United States with a width across flats of 15 mm. This width, however, is not an ISO Standard. Unless these M10 nuts with width across flats of 15 mm are specifically ordered, the M10 size with 16 mm width across flats will be furnished. In ANSI Standards for metric nuts, letter symbols designating dimensional characteristics are in accord with those used in ISO Standards, except capitals have been used for data processing convenience instead of lower case letters used in ISO Standards. Metric Nut Tops and Bearing Surfaces.—Metric hex nuts, styles 1 and 2, slotted hex nuts, and hex jam nuts are double chamfered in sizes M16 and smaller and in sizes M20 and larger may either be double chamfered or have a washer-faced bearing surface and a chamfered top at the option of the manufacturer. Metric heavy hex nuts are optional either way in all sizes. Metric hex flange nuts have a flange bearing surface and a chamfered top and prevailing-torque type metric hex nuts have a chamfered bearing surface. Prevailingtorque type metrix hex flange nuts have a flange bearing surface. All types of metric nuts have the tapped hole countersunk on the bearing face and metric slotted hex nuts, hex flange nuts, and prevailing-torque type hex nuts and hex flange nuts may be countersunk on the top face. Materials and Mechanical Properties.—Nonheat-treated carbon steel metric hex nuts, style 1 and slotted hex nuts conform to material and property class requirements specified for property class 5 nuts; hex nuts, style 2 and hex flange nuts to property class 9 nuts; hex jam nuts to property class 04 nuts, and nonheat-treated carbon and alloy steel heavy hex nuts to property classes 5, 9, 8S, or 8S3 nuts; all as covered in ASTM A563M. Carbon steel metric hex nuts, style 1 and slotted hex nuts that have specified heat treatment conform to material and property class requirements specified for property class 10 nuts; hex nuts, style 2 to property class 12 nuts; hex jam nuts to property class 05 nuts; hex flange nuts to property classes 10 and 12 nuts; and carbon or alloy steel heavy hex nuts to property classes 10S, 10S3, or 12 nuts, all as covered in ASTM A563M. Carbon steel prevailing-torque type hex nuts and hex flange nuts conform to mechanical and property class requirements as given in ANSI B18.16.1M.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1562
METRIC NUTS Table 26. American National Standard Metric Hex Nuts, Styles 1 and 2 ANSI/ASME B18.2.4.1M and B18.2.4.2M-1979 (R1995)
Nominal Nut Dia. and Thread Pitch
Width Across Flats, S Max
Width Across Corners, E Min
Max
Min
Thickness, M Max
Bearing Face Dia., Dw
Washer Face Thickness, C
Min
Min
Max
Min
1.05 1.35 1.75 2.15 2.55 2.90 4.40 4.90 6.44 8.7 8.04 10.37 12.10 14.10 16.90 20.20 24.30 29.40
2.3 3.1 4.1 4.6 5.1 6.0 7.0 8.9 11.6 13.6 14.6 16.6 19.4 22.4 27.9 32.5 42.5 50.8
… … … … … … … … … 0.6 … … … … 0.8 0.8 0.8 0.8
… … … … … … … … … 0.3 … … … … 0.4 0.4 0.4 0.4
2.65 3.00 3.50 4.80 5.40 7.14 9.6 8.94 11.57 13.40 15.70 19.00 22.60 27.30 33.10
4.6 5.1 5.9 6.9 8.9 11.6 13.6 14.6 16.6 19.6 22.5 27.7 33.2 42.7 51.1
… … … … … … 0.6 … … … … 0.8 0.8 0.8 0.8
… … … … … … 0.3 … … … … 0.4 0.4 0.4 0.4
Metric Hex Nuts — Style 1 M1.6 × 0.35 M2 × 0.4 M2.5 × 0.45 M3 × 0.5 M3.5 × 0.6 M4 × 0.7 M5 × 0.8 M6 × 1 M8 × 1.25 aM10 × 1.5 M10 × 1.5 M12 × 1.75 M14 × 2 M16 × 2 M20 × 2.5 M24 × 3 M30 × 3.5 M36 × 4
3.20 4.00 5.00 5.50 6.00 7.00 8.00 10.00 13.00 15.00 16.00 18.00 21.00 24.00 30.00 36.00 46.00 55.00
3.02 3.82 4.82 5.32 5.82 6.78 7.78 9.78 12.73 14.73 15.73 17.73 20.67 23.67 29.16 35.00 45.00 53.80
3.70 4.62 5.77 6.35 6.93 8.08 9.24 11.55 15.01 17.32 18.48 20.78 24.25 27.71 34.64 41.57 53.12 63.51
M3 × 0.5 M3.5 × 0.6 M4 × 0.7 M5 × 0.8 M6 × 1 M8 × 1.25 aM10 × 1.5 M10 × 1.5 M12 × 1.75 M14 × 2 M16 × 2 M20 × 2.5 M24 × 3 M30 × 3.5 M36 × 4
5.50 6.00 7.00 8.00 10.00 13.00 15.00 16.00 18.00 21.00 24.00 30.00 36.00 46.00 55.00
5.32 5.82 6.78 7.78 9.78 12.73 14.73 15.73 17.73 20.67 23.67 29.16 35.00 45.00 53.80
6.35 6.93 8.08 9.24 11.55 15.01 17.32 18.48 20.78 24.25 27.71 34.64 41.57 53.12 63.51
3.41 4.32 5.45 6.01 6.58 7.66 8.79 11.05 14.38 16.64 17.77 20.03 23.36 26.75 32.95 39.55 50.85 60.79
1.30 1.60 2.00 2.40 2.80 3.20 4.70 5.20 6.80 9.1 8.40 10.80 12.80 14.80 18.00 21.50 25.60 31.00
Metric Hex Nuts — Style 2 6.01 6.58 7.66 8.79 11.05 14.38 16.64 17.77 20.03 23.35 26.75 32.95 39.55 50.85 60.79
2.90 3.30 3.80 5.10 5.70 7.50 10.0 9.30 12.00 14.10 16.40 20.30 23.90 28.60 34.70
a This size with width across flats of 15 mm is not standard. Unless specifically ordered, M10 hex nuts with 16 mm width across flats will be furnished.
All dimensions are in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC NUTS
1563
Table 27. American National Standard Metric Slotted Hex Nuts ANSI B18.2.4.4M-1982 (R1999)
Nominal Nut Dia. and Thread Pitch
Width Across Flats, S
Width Across Corners, E
Thickness, M
Bearing Face Dia., Dw
Unslotted Thickness, F
Width of Slot, N
Washer Face Thickness C
Max
Min
Max
Min
Max
Min
Min
Max
Min
Max
Min
Max
M5 × 0.8
8.00
7.78
9.24
8.79
5.10
4.80
6.9
3.2
2.9
2.0
1.4
…
…
M6 × 1
10.00
9.78
11.55 11.05
5.70
5.40
8.9
3.5
3.2
2.4
1.8
…
…
M8 × 1.25
13.00 12.73 15.01 14.38
7.50
7.14
11.6
4.4
4.1
2.9
2.3
…
…
× 1.5
15.00 14.73 17.32 16.64
10.0
9.6
13.6
5.7
5.4
3.4
2.8
0.6
0.3
M10 × 1.5
16.00 15.73 18.48 17.77
9.30
8.94
14.6
5.2
4.9
3.4
2.8
…
…
M12 × 1.75
18.00 17.73 20.78 20.03 12.00 11.57
16.6
7.3
6.9
4.0
3.2
…
…
M14 × 2
21.00 20.67 24.25 23.35 14.10 13.40
19.6
8.6
8.0
4.3
3.5
…
…
M16 × 2
24.00 23.67 27.71 26.75 16.40 15.70
22.5
9.9
9.3
5.3
4.5
…
…
M20 × 2.5
30.00 29.16 34.64 32.95 20.30 19.00
27.7
13.3
12.2
5.7
4.5
0.8
0.4
M24 × 3
36.00 35.00 41.57 39.55 23.90 22.60
33.2
15.4
14.3
6.7
5.5
0.8
0.4
M30 × 3.5
46.00 45.00 53.12 50.85 28.60 27.30
42.7
18.1
16.8
8.5
7.0
0.8
0.4
M36 × 4
55.00 53.80 63.51 60.79 34.70 33.10
51.1
23.7
22.4
8.5
7.0
0.8
0.4
aM10
Min
a This size with width across flats of 15 mm is not standard. Unless specifically ordered, M10 slotted
hex nuts with 16 mm width across flats will be furnished. All dimensions are in millimeters.
Metric nuts of other materials, such as stainless steel, brass, bronze, and aluminum alloys, have properties as agreed upon by the manufacturer and purchaser. Properties of nuts of several grades of non-ferrous materials are covered in ASTM F467M. Unless otherwise specified, metric nuts are furnished with a natural (unprocessed) finish, unplated or uncoated. Metric Nut Thread Series.—Metric nuts have metric coarse threads with class 6H tolerances in accordance with ANSI B1.13M (see Metric Screw and Bolt Diameter-Length CombinationsMetric Screw Threads in index). For prevailing-torque type metric nuts this condition applies before introduction of the prevailing torque feature. Nuts intended for use with externally threaded fasteners which are plated or coated with a plating or coating thickness (e.g., hot dip galvanized) requiring overtapping of the nut thread to permit assembly, have over-tapped threads in conformance with requirements specified in ASTM A563M.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1564
METRIC NUTS Table 28. American National Standard Metric Hex Flange Nuts ANSI B18.2.4.4M-1982 (R1999)
DETAIL X
Nominal Nut Dia. and Thread Pitch M5 × 0.8 M6 × 1 M8 × 1.25 M10 × 1.5 M12 × 1.75 M14 × 2 M16 × 2 M20 × 2.5
Width Across Flats, S
Width Across Corners, E
Flange Dia., Dc
Bearing Circle Dia., Dw
Flange Edge Thickness, C
Thickness, M
Flange Top Fillet Radius, R
Max
Min
Max
Min
Max
Min
Min
Max
Min
Max
8.00 10.00 13.00 15.00 18.00 21.00 24.00 30.00
7.78 9.78 12.73 14.73 17.73 20.67 23.67 29.16
9.24 11.55 15.01 17.32 20.78 24.25 27.71 34.64
8.79 11.05 14.38 16.64 20.03 23.35 26.75 32.95
11.8 14.2 17.9 21.8 26.0 29.9 34.5 42.8
9.8 12.2 15.8 19.6 23.8 27.6 31.9 39.9
1.0 1.1 1.2 1.5 1.8 2.1 2.4 3.0
5.00 6.00 8.00 10.00 12.00 14.00 16.00 20.00
4.70 5.70 7.60 9.60 11.60 13.30 15.30 18.90
0.3 0.4 0.5 0.6 0.7 0.9 1.0 1.2
All dimensions are in millimeters.
Types of Metric Prevailing-Torque Type Nuts.—There are three basic designs for prevailing-torque type nuts: 1) All-metal, one-piece construction nuts which derive their prevailing-torque characteristics from controlled distortion of the nut thread and/or body. 2) Metal nuts which derive their prevailing-torque characteristics from addition or fusion of a nonmetallic insert, plug. or patch in their threads. 3) Top insert, two-piece construction nuts which derive their prevailing-torque characteristics from an insert, usually a full ring of non-metallic material, located and retained in the nut at its top surface. The first two designs are designated in Tables 29 and 30 as “all-metal” type and the third design as “top-insert” type.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 29. American National Standard Prevailing-Torque Metric Hex Nuts — Property Classes 5, 9, and 10 ANSI/ASME B18.16.3M-1998
Property Classes 5 and 10 Nuts All Metala Type
Property Class 9 Nuts
Top Insert Type
All Metal Type
Top Insert Type
Property Class 5 and 10 9 Nuts Nuts Wrenching Height, M1
Bearing Face Dia., Dw
Nominal Nut Dia. and Thread Pitch
Max
Min
Max
Min
Min
Max
Thickness, M Min Max
Min
Max
Min
Min
Min
Min
M3 × 0.5 M3.5 × 0.6 M4 × 0.7 M5 × 0.8 M6 × 1 M8 × 1.25 bM10 × 1.5
5.50 6.00 7.00 8.00 10.00 13.00 15.00
5.32 5.82 6.78 7.78 9.78 12.73 14.73
6.35 6.93 8.08 9.24 11.55 15.01 17.32
6.01 6.58 7.66 8.79 11.05 14.38 16.64
3.10 3.50 4.00 5.30 5.90 7.10 9.70
2.65 3.00 3.50 4.80 5.40 6.44 8.70
4.50 5.00 6.00 6.80 8.00 9.50 12.50
3.90 4.30 5.30 6.00 7.20 8.50 11.50
3.10 3.50 4.00 5.30 6.70 8.00 11.20
2.65 3.00 3.50 4.80 5.40 7.14 9.60
4.50 5.00 6.00 7.20 8.50 10.20 13.50
3.90 4.30 5.30 6.40 7.70 9.20 12.50
1.4 1.7 1.9 2.7 3.0 3.7 5.6
1.4 1.7 1.9 2.7 3.0 4.3 6.2
M10 × 1.5 M12 × 1.75 M14 × 2 M16 × 2 M20 × 2.5 M24 × 3 M30 × 3.5 M36 × 4
16.00 18.00 21.00 24.00 30.00 36.00 46.00 55.00
15.73 17.73 20.67 23.67 29.16 35.00 45.00 53.80
18.48 20.78 24.25 27.71 34.64 41.57 53.12 63.51
17.77 20.03 23.35 26.75 32.95 39.55 50.85 60.79
9.00 11.60 13.20 15.20 19.00 23.00 26.90 32.50
8.04 10.37 12.10 14.10 16.90 20.20 24.30 29.40
11.90 14.90 17.00 19.10 22.80 27.10 32.60 38.90
10.90 13.90 15.80 17.90 21.50 25.60 30.60 36.90
10.50 13.30 15.40 17.90 21.80 26.40 31.80 38.50
8.94 11.57 13.40 15.70 19.00 22.60 27.30 33.10
12.80 16.10 18.30 20.70 25.10 29.50 35.60 42.60
11.80 15.10 17.10 19.50 23.80 28.00 33.60 40.60
4.8 6.7 7.8 9.1 10.9 13.0 15.7 19.0
5.6 7.7 8.9 10.5 12.7 15.1 18.2 22.1
4.6 5.1 5.9 6.9 8.9 11.6 13.6 14.6 16.6 19.6 22.5 27.7 33.2 42.7 51.1
Max
METRIC NUTS
Width Across Corners, E
Width Across Flats, S
a Also includes metal nuts with non-metallic inserts, plugs, or patches in their threads.
All dimensions are in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
1565
b This size with width across flats of 15 mm is not standard. Unless specifically ordered, M10 slotted hex nuts with 16 mm width across flats will be furnished.
Machinery's Handbook 27th Edition 1566
METRIC NUTS
Bearing Circle Dia., Dw
Flange Edge Thickness, C
Flange Top Fillet Radius, R
Table 30. American National Standard Prevailing-Torque Metric Hex Flange Nuts ANSI B18.16.3M-1998
Max
Min
Max
Min
Max
Min
Min
Max
M6 × 1
10.00
9.78
11.55
11.05
7.30
5.70
8.80
8.00
14.2
12.2
1.1
0.4
M8 × 1.25
13.00
12.73
15.01
14.38
9.40
7.60
10.70
9.70
17.9
15.8
1.2
0.5
Nominal Dia. and Thread Pitch
Width Across Corners, E
Width Across Flats, S
Flange Dia., Dc
Top Insert Type
All Metal Typea
Thickness, M (All Nut Property Classes) Max
Min
Max
Min
M10 × 1.5
15.00
14.73
17.32
16.64
11.40
9.60
13.50
12.50
21.8
19.6
1.5
0.6
M12 × 1.75
18.00
17.73
20.78
20.03
13.80
11.60
16.10
15.10
26.0
23.8
1.8
0.7
M14 × 2
21.00
20.67
24.25
23.35
15.90
13.30
18.20
17.00
29.9
27.6
2.1
0.9
M16 × 2
24.00
23.67
27.71
26.75
18.30
15.30
20.30
19.10
34.5
31.9
2.4
1.0
M20 × 2.5
30.00
29.16
34.64
32.95
22.40
18.90
24.80
23.50
42.8
39.9
3.0
1.2
a Also includes metal nuts with nonmetallic inserts, plugs, or patches in their threads.
All dimensions are in millimeters.
Metric Nut Identification Symbols.—Carbon steel hex nuts, styles 1 and 2, hex flange nuts, and carbon and alloy steel heavy hex nuts are marked to identify the property class and manufacturer in accordance with requirements specified in ASTM A563M. The aforementioned nuts when made of other materials, as well as slotted hex nuts and hex jam nuts, are marked to identify the property class and manufacturer as agreed upon by manufacturer and purchaser. Carbon steel prevailing-torque type hex nuts and hex flange nuts are marked to identify property class and manufacturer as specified in ANSI B18.16.1M. Prevailing-torque type nuts of other materials are identified as agreed upon by the manufacturer and purchaser. Metric Nut Designation.—Metric nuts are designated by the following data, preferably in the sequence shown: product name, nominal diameter and thread pitch, steel property class or material identification, and protective coating, if required. (Note: It is common practice in ISO Standards to omit thread pitch from the product designation when the nut threads are the metric coarse thread series, e.g., M10 stands for M10 × 1.5). Example:Hex nut, style 1, M10 × 1.5, ASTM A563M class 10, zinc plated Heavy hex nut, M20 × 2.5, silicon bronze, ASTM F467, grade 651 Slotted hex nut, M20, ASTM A563M class 10.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC NUTS
1567
Table 31. American National Standard Metric Hex Jam Nuts and Heavy Hex Nuts ANSI B18.2.4.5M and B18.2.4.6M-1979 (R1998)
HEX JAM NUTS Nominal Nut Dia. and Thread Pitch
Width Across Flats, S Max
HEAVY HEX NUTS
Width Across Corners, E Min
Max
Min
Thickness, M Max
Bearing Face Dia., Dw
Washer Face Thickness, C
Min
Min
Max
Min
Metric Hex Jam Nuts M5 × 0.8 M6 × 1 M8 × 1.25 × 1.5 M10 × 1.5 M12 × 1.75 M14 × 2 M16 × 2 M20 × 2.5 M24 × 3 M30 × 3.5 M36 × 4
aM10
8.00 10.00 13.00 15.00
7.78 9.78 12.73 14.73
9.24 11.55 15.01 17.32
8.79 11.05 14.38 16.64
2.70 3.20 4.00 5.00
2.45 2.90 3.70 4.70
6.9 8.9 11.6 13.6
… … … …
… … … …
16.00 18.00 21.00 24.00 30.00 36.00 46.00 55.00
15.73 17.73 20.67 23.67 29.16 35.00 45.00 53.80
18.48 20.78 24.25 27.71 34.64 41.57 53.12 63.51
17.77 20.03 23.35 26.75 32.95 39.55 50.85 60.79
5.00 6.00 7.00 8.00 10.00 12.00 15.00 18.00
4.70 5.70 6.42 7.42 9.10 10.90 13.90 16.90
14.6 16.6 19.6 22.5 27.7 33.2 42.7 51.1
… … … … 0.8 0.8 0.8 0.8
… … … … 0.4 0.4 0.4 0.4
21.00 24.00 27.00 34.00 36.00 41.00 46.00 50.00 60.00 70.00 80.00 90.00 100.00 110.00 120.00 135.00 150.00
20.16 23.16 26.16 33.00 35.00 40.00 45.00 49.00 58.80 67.90 77.60 87.20 96.80 106.40 116.00 130.50 145.00
24.25 27.71 31.18 39.26 41.57 47.34 53.12 57.74 69.28 80.83 92.38 103.92 115.47 127.02 138.56 155.88 173.21
11.9 13.6 16.4 19.4 22.3 22.9 26.3 29.1 35.0 40.4 46.4 54.1 62.1 70.1 78.1 87.8 97.8
19.2 22.0 24.9 31.4 33.3 38.0 42.8 46.6 55.9 64.5 73.7 82.8 92.0 101.1 110.2 124.0 137.8
0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 1.0 1.0 1.0 1.0 1.2 1.2 1.2 1.2
0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.5 0.5 0.5 0.5 0.6 0.6 0.6 0.6
Metric Heavy Hex Nuts M12 × 1.75 M14 × 2 M16 × 2 M20 × 2.5 M22 × 2.5 M24 × 3 M27 × 3 M30 × 3.5 M36 × 4 M42 × 4.5 M48 × 5 M56 × 5.5 M64 × 6 M72 × 6 M80 × 6 M90 × 6 M100 × 6
22.78 26.17 29.56 37.29 39.55 45.20 50.85 55.37 66.44 77.41 88.46 99.41 110.35 121.30 132.24 148.77 165.30
12.3 14.3 17.1 20.7 23.6 24.2 27.6 30.7 36.6 42.0 48.0 56.0 64.0 72.0 80.0 90.0 100.0
a This size with width across flats of 15 mm is not standard. Unless specifically ordered, M10 hex jam nuts with 16 mm width across flats will be furnished.
All dimensions are in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1568
METRIC WASHERS Metric Washers
Metric Plain Washers.—American National Standard ANSI B18.22M-1981 (R1990) covers general specifications and dimensions for flat, round-hole washers, both soft (as fabricated) and hardened, intended for use in general-purpose applications. Dimensions are given in the following table. Manufacturers should be consulted for current information on stock sizes. Comparison with ISO Standards.—The washers covered by this ANSI Standard are nominally similar to those covered in various ISO documents. Outside diameters were selected, where possible, from ISO/TC2/WG6/N47 “General Plan for Plain Washers for Metric Bolts, Screws, and Nuts.” The thicknesses given in the ANSI Standard are similar to the nominal ISO thicknesses, however the tolerances differ. Inside diameters also differ. ISO metric washers are currently covered in ISO 887, “Plain Washers for Metric Bolts, Screws, and Nuts – General Plan.” Types of Metric Plain Washers.—Soft (as fabricated) washers are generally available in nominal sizes 1.6 mm through 36 mm in a variety of materials. They are normally used in low-strength applications to distribute bearing load, to provide a uniform bearing surface, and to prevent marring of the work surface. Hardened steel washers are normally available in sizes 6 mm through 36 mm in the narrow and regular series. They are intended primarily for use in high-strength joints to minimize embedment, to provide a uniform bearing surface, and to bridge large clearance holes and slots. Metric Plain Washer Materials and Finish.—Soft (as fabricated) washers are made of nonhardened steel unless otherwise specified by the purchaser. Hardened washers are made of through-hardened steel tempered to a hardness of 38 to 45 Rockwell C. Unless otherwise specified, washers are furnished with a natural (as fabricated) finish, unplated or uncoated with a light film of oil or rust inhibitor. Metric Plain Washer Designation.—When specifying metric plain washers, the designation should include the following data in the sequence shown: description, nominal size, series, material type, and finish, if required. Example:Plain washer, 6 mm, narrow, soft, steel, zinc plated Plain washer, 10 mm, regular, hardened steel.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC WASHERS
1569
Table 32. American National Standard Metric Plain Washers ANSI B18.22M-1981, R1990 Nominal Washer Sizea 1.6
2
2.5
3
3.5
4
5
6
8
10
12
14
16
20
24
30
36
Washer Series Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide Narrow Regular Wide
Inside Diameter, A
Outside Diameter, B
Max 2.09 2.09 2.09 2.64 2.64 2.64 3.14 3.14 3.14 3.68 3.68 3.68 4.18 4.18 4.18 4.88 4.88 4.88 5.78 5.78 5.78 6.87 6.87 6.87 9.12 9.12 9.12 11.12 11.12 11.12 13.57 13.57 13.57 15.52 15.52 15.52 17.52 17.52 17.52 22.32 22.32 22.32 26.12 26.12 26.12 33.02 33.02 33.02 38.92 38.92 38.92
Max 4.00 5.00 6.00 5.00 6.00 8.00 6.00 8.00 10.00 7.00 10.00 12.00 9.00 10.00 15.00 10.00 12.00 16.00 11.00 15.00 20.00 13.00 18.80 25.40 18.80b 25.40b 32.00 20.00 28.00 39.00 25.40 34.00 44.00 28.00 39.00 50.00 32.00 44.00 56.00 39.00 50.00 66.00 44.00 56.00 72.00 56.00 72.00 90.00 66.00 90.00 110.00
Min 1.95 1.95 1.95 2.50 2.50 2.50 3.00 3.00 3.00 3.50 3.50 3.50 4.00 4.00 4.00 4.70 4.70 4.70 5.50 5.50 5.50 6.65 6.65 6.65 8.90 8.90 8.90 10.85 10.85 10.85 13.30 13.30 13.30 15.25 15.25 15.25 17.25 17.25 17.25 21.80 21.80 21.80 25.60 25.60 25.60 32.40 32.40 32.40 38.30 38.30 38.30
Min 3.70 4.70 5.70 4.70 5.70 7.64 5.70 7.64 9.64 6.64 9.64 11.57 8.64 9.64 14.57 9.64 11.57 15.57 10.57 14.57 19.48 12.57 18.37 24.88 18.37b 24.48b 31.38 19.48 27.48 38.38 24.88 33.38 43.38 27.48 38.38 49.38 31.38 43.38 54.80 38.38 49.38 64.80 43.38 54.80 70.80 54.80 70.80 88.60 64.80 88.60 108.60
Thickness, C Max 0.70 0.70 0.90 0.90 0.90 0.90 0.90 0.90 1.20 0.90 1.20 1.40 1.20 1.40 1.75 1.20 1.40 2.30 1.40 1.75 2.30 1.75 1.75 2.30 2.30 2.30 2.80 2.30 2.80 3.50 2.80 3.50 3.50 2.80 3.50 4.00 3.50 4.00 4.60 4.00 4.60 5.10 4.60 5.10 5.60 5.10 5.60 6.40 5.60 6.40 8.50
Min 0.50 0.50 0.60 0.60 0.60 0.60 0.60 0.60 0.80 0.60 0.80 1.00 0.80 1.00 1.20 0.80 1.00 1.60 1.00 1.20 1.60 1.20 1.20 1.60 1.60 1.60 2.00 1.60 2.00 2.50 2.00 2.50 2.50 2.00 2.50 3.00 2.50 3.00 3.50 3.00 3.50 4.00 3.50 4.00 4.50 4.00 4.50 5.00 4.50 5.00 7.00
a Nominal washer sizes are intended for use with comparable screw and bolt sizes. b The 18.80⁄18.37 and 25.40⁄24.48 mm outside diameters avoid washers which could be used in coin-operated devices. All dimensions are in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1570
BOLTS, SCREWS, AND NUTS
BRITISH FASTENERS British Standard Square and Hexagon Bolts, Screws and Nuts.—Important dimensions of precision hexagon bolts, screws and nuts (BSW and BSF threads) as covered by British Standard 1083:1965 are given in Tables 1 and 2. The use of fasteners in this standard will decrease as fasteners having Unified inch and ISO metric threads come into increasing use. Dimensions of Unified precision hexagon bolts, screws and nuts (UNC and UNF threads) are given in BS 1768:1963 (obsolescent); of Unified black hexagon bolts, screws and nuts (UNC and UNF threads) in BS 1769:1951 (obsolescent); and of Unified black square and hexagon bolts, screws and nuts (UNC and UNF threads) in BS 2708:1956 (withdrawn). Unified nominal and basic dimensions in these British Standards are the same as the comparable dimensions in the American Standards, but the tolerances applied to these basic dimensions may differ because of rounding-off practices and other factors. For Unified dimensions of square and hexagon bolts and nuts as given in ANSI/ASME B18.2.1-1996 and ANSI/ASME B18.2.2-1987 (R1999) see Tables 1 through 4 starting on page 1514, and 7 to 10 starting on page 1519. ISO metric precision hexagon bolts, screws and nuts are specified in the British Standard BS 3692:1967 (obsolescent) (see British Standard ISO Metric Precision Hexagon Bolts, Screws and Nuts starting on page 1578), and ISO metric black hexagon bolts, screws and nuts are covered by British Standard BS 4190:1967 (obsolescent). See the section MACHINE SCREWS AND NUTS starting on page 1587 for information on British Standard metric, Unified, Whitworth, and BSF machine screws and nuts. British Standard Screwed Studs.—General purpose screwed studs are covered in British Standard 2693: Part 1:1956. The aim in this standard is to provide for a stud having tolerances which would not render it expensive to manufacture and which could be used in association with standard tapped holes for most purposes. Provision has been made for the use of both Unified Fine threads, Unified Coarse threads, British Standard Fine threads, and British Standard Whitworth threads as shown in the table on page 1573. Designations: The metal end of the stud is the end which is screwed into the component. The nut end is the end of the screw of the stud which is not screwed into the component. The plain portion of the stud is the unthreaded length. Recommended Fitting Practices for Metal End of Stud: It is recommended that holes tapped to Class 3B limits (see Table 3 starting on page 1736) in accordance with B.S. 1580 “Unified Screw Threads“ or to Close Class limits in accordance with B.S. 84 “Screw Threads of Whitworth Form” as appropriate, be used in association with the metal end of the stud specified in this standard. Where fits are not critical, however, holes may be tapped to Class 2B limits (see table on page 1736) in accordance with B.S. 1580 or Normal Class limits in accordance with B.S. 84. It is recommended that the B.A. stud specified in this standard be associated with holes tapped to the limits specified for nuts in B.S. 93, 1919 edition. Where fits for these studs are not critical, holes may be tapped to limits specified for nuts in the current edition of B.S. 93. In general, it will be found that the amount of oversize specified for the studs will produce a satisfactory fit in conjunction with the standard tapping as above. Even when interference is not present, locking will take place on the thread runout which has been carefully controlled for this purpose. Where it is considered essential to assure a true interference fit, higher grade studs should be used. It is recommended that standard studs be used even under special conditions where selective assembly may be necessary.
Copyright 2004, Industrial Press, Inc., New York, NY
; ; ;; ;;
Machinery's Handbook 27th Edition
British Standard Whitworth (BSW) and Fine (BSF) Precision Hexagon Bolts, Screws, and Nuts A
R
F
C
B
G
D
R
F
45
B
G
F
R
Alternative Ends
D
D
0.015 30 Hexagon Head Bolt, Washer Faced
0.015 30 Hexagon Head Screw, Washer Faced
11/4" D Rad. Approx.
30
Alternative Full-Bearing Head
A C
E E
0.015
A
E
C
G
D
D
Rolled Thread End
H
Chamfer
Hexagon Nut, Full
30 Ordinary Bearing
30 30 Double Chamfered
30 30 Hexagon Lock-Nut
30 Washer Faced
Alternative Hexagon Slotted Nuts
A C
D
P H
A 0.015
P
C
M
G
30
30
Double Chamfered
30 Washer Faced
D
J
N
Sharp Edge Removed
J
J
K
M
L 30
Hexagon Castle Nut, Full Bearing
For dimensions, see Tables 1 and 2.
Copyright 2004, Industrial Press, Inc., New York, NY
0.015
G
L 30
30
Double Chamfered
30 Washer Faced
1571
30 Hexagon Slotted Nut, Full Bearing
Enlarged View of Nut Countersink
Alternate Hexagon Castle Nuts
P
N
120–+ 10
BOLTS, SCREWS, AND NUTS
Alternative Hexagon Ordinary Nuts
Rounded End
Machinery's Handbook 27th Edition
Bolts, Screws, and Nuts
Bolts and Screws
Width Number of Threads per Inch
Across Flats A
BSW
BSF
1⁄ 4
20
26
5⁄ 16
18
3⁄ 8
16
7⁄ 16
Diameter of Washer Face G
Radius Under Head R
Nuts Thickness Head F
Thickness Ordinary E
Lock H
Max.
Min.a
Max.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
0.445
0.438
0.51
0.428
0.418
0.025
0.015
0.2500
0.2465
0.176
0.166
0.200
0.190
0.185
0.180
22
0.525
0.518
0.61
0.508
0.498
0.025
0.015
0.3125
0.3090
0.218
0.208
0.250
0.240
0.210
0.200
20
0.600
0.592
0.69
0.582
0.572
0.025
0.015
0.3750
0.3715
0.260
0.250
0.312
0.302
0.260
0.250
14
18
0.710
0.702
0.82
0.690
0.680
0.025
0.015
0.4375
0.4335
0.302
0.292
0.375
0.365
0.275
0.265
1⁄ 2
12
16
0.820
0.812
0.95
0.800
0.790
0.025
0.015
0.5000
0.4960
0.343
0.333
0.437
0.427
0.300
0.290
9⁄ 16
12
16
0.920
0.912
1.06
0.900
0.890
0.045
0.020
0.5625
0.5585
0.375
0.365
0.500
0.490
0.333
0.323
5⁄ 8
11
14
1.010
1.000
1.17
0.985
0.975
0.045
0.020
0.6250
0.6190
0.417
0.407
0.562
0.552
0.375
0.365
3⁄ 4
10
12
1.200
1.190
1.39
1.175
1.165
0.045
0.020
0.7500
0.7440
0.500
0.480
0.687
0.677
0.458
0.448
7⁄ 8
9
11
1.300
1.288
1.50
1.273
1.263
0.065
0.040
0.8750
0.8670
0.583
0.563
0.750
0.740
0.500
0.490
1
8
10
1.480
1.468
1.71
1.453
1.443
0.095
0.060
1.0000
0.9920
0.666
0.636
0.875
0.865
0.583
0.573
11⁄8
7
9
1.670
1.640
1.93
1.620
1.610
0.095
0.060
1.1250
1.1170
0.750
0.710
1.000
0.990
0.666
0.656
11⁄4
7
9
1.860
1.815
2.15
1.795
1.785
0.095
0.060
1.2500
1.2420
0.830
0.790
1.125
1.105
0.750
0.730
13⁄8b
…
8
2.050
2.005
2.37
1.985
1.975
0.095
0.060
1.3750
1.3650
0.920
0.880
1.250
1.230
0.833
0.813
11⁄2
6
8
2.220
2.175
2.56
2.155
2.145
0.095
0.060
1.5000
1.4900
1.000
0.960
1.375
1.355
0.916
0.896
13⁄4
5
7
2.580
2.520
2.98
2.495
2.485
0.095
0.060
1.7500
1.7400
1.170
1.110
1.625
1.605
1.083
1.063
2
4.5
7
2.760
2.700
3.19
2.675
2.665
0.095
0.060
2.0000
1.9900
1.330
1.270
1.750
1.730
1.166
1.146
a When bolts from 1⁄ to 1 inch are hot forged, the tolerance on the width across flats shall be two and a half times the tolerance shown in the table and shall be unilaterally 4
minus from maximum size. For dimensional notation, see diagram on page 1571. b Noted standard with BSW thread. All dimensions in inches except where otherwise noted.
Copyright 2004, Industrial Press, Inc., New York, NY
BOLTS, SCREWS, AND NUTS
Nominal Size D
Across Corners C
Diameter of Unthreaded Portion of Shank B
1572
Table 1. British Standard Whitworth (BSW) and Fine (BSF) Precision Hexagon Slotted and Castle Nuts BS 1083:1965 (obsolescent)
Machinery's Handbook 27th Edition
Table 2. British Standard Whitworth (BSW) and Fine (BSF) Precision Hexagon Slotted and Castle Nuts BS 1083:1965 (obsolescent) Slotted Nuts Number of Threads per Inch
Castle Nuts
Lower Face to Bottom of Slot H
Thickness P
Total Thickness J
Slotted and Castle Nuts Castellated Portion
Lower Face to Bottom of Slot K
Diameter L
Slots Width M
Depth N
BSW
BSF
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Approx.
1⁄ 4
20
26
0.200
0.190
0.170
0.160
0.290
0.280
0.200
0.190
0.430
0.425
0.100
0.090
0.090
5⁄ 16
18
22
0.250
0.240
0.190
0.180
0.340
0.330
0.250
0.240
0.510
0.500
0.100
0.090
0.090
3⁄ 8
16
20
0.312
0.302
0.222
0.212
0.402
0.392
0.312
0.302
0.585
0.575
0.100
0.090
0.090
7⁄ 16
14
18
0.375
0.365
0.235
0.225
0.515
0.505
0.375
0.365
0.695
0.685
0.135
0.125
0.140
1⁄ 2
12
16
0.437
0.427
0.297
0.287
0.577
0.567
0.437
0.427
0.805
0.795
0.135
0.125
0.140
9⁄ 16
12
16
0.500
0.490
0.313
0.303
0.687
0.677
0.500
0.490
0.905
0.895
0.175
0.165
0.187
5⁄ 8
11
14
0.562
0.552
0.375
0.365
0.749
0.739
0.562
0.552
0.995
0.985
0.175
0.165
0.187
3⁄ 4
10
12
0.687
0.677
0.453
0.443
0.921
0.911
0.687
0.677
1.185
1.165
0.218
0.208
0.234
7⁄ 8
9
11
0.750
0.740
0.516
0.506
0.984
0.974
0.750
0.740
1.285
1.265
0.218
0.208
0.234
1 11⁄8
8 7
10 9
0.875 1.000
0.865 0.990
0.595 0.720
0.585 0.710
1.155 1.280
1.145 1.270
0.875 1.000
0.865 0.990
1.465 1.655
1.445 1.635
0.260 0.260
0.250 0.250
0.280 0.280
11⁄4
7
9
1.125
1.105
0.797
0.777
1.453
1.433
1.125
1.105
1.845
1.825
0.300
0.290
0.328
13⁄8a
…
8
1.250
1.230
0.922
0.902
1.578
1.558
1.250
1.230
2.035
2.015
0.300
0.290
0.328
11⁄2
6
8
1.375
1.355
1.047
1.027
1.703
1.683
1.375
1.355
2.200
2.180
0.300
0.290
0.328
13⁄4
5
7
1.625
1.605
1.250
1.230
2.000
1.980
1.625
1.605
2.555
2.535
0.343
0.333
0.375
2
4.5
7
1.750
1.730
1.282
1.262
2.218
2.198
1.750
1.730
2.735
2.715
0.426
0.416
0.468
standard with BSW thread. For widths across flats, widths across corners, and diameter of washer face see Table 1. For dimensional notation, see diagram on page 1571.
BOLTS, SCREWS, AND NUTS
Nominal Size D
a Not
Copyright 2004, Industrial Press, Inc., New York, NY
1573
All dimensions in inches except where otherwise noted.
Machinery's Handbook 27th Edition 1574
BOLTS, SCREWS, AND NUTS
Table 3. British Standard ISO Metric Precision Hexagon Bolts, Screws and Nuts BS 3692:1967 (obsolescent)
Washer-Faced Hexagon Head Bolt
Washer-Faced Hexagon Head Screw
Full Bearing Head (Alternative Permissible on Bolts and Screws)
Alternative Types of End Permissible on Bolts and Screws
Normal Thickness Nut
Thin Nut
Enlarged View of Nut Countersink
Slotted Nut (Six Slots) Sizes M4 to M39 Only
Castle Nut (Six Slots) Sizes M12 to M39 Only
Castle Nut (Eight Slots) Sizes M42 to M68 Only
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 4. British Standard ISO Metric Precision Hexagon Bolts and Screws BS 3692:1967 (obsolescent) Nom.Size and Thread Dia.a d
0.35 0.4 0.45 0.5 0.7 0.8 1 1.25 1.5 1.75 2 2 2.5 2.5 2.5 3 3 3.5 3.5 4 4 4.5 4.5 5 5 5.5 5.5 6 6
Thread Runout a Max. 0.8 1.0 1.0 1.2 1.6 2.0 2.5 3.0 3.5 4.0 5.0 5.0 6.0 6.0 6.0 7.0 7.0 8.0 8.0 10.0 10.0 11.0 11.0 12.0 12.0 19.0 19.0 21.0 21.0
Dia. of Washer Face dt
Dia. of Unthreaded Shank d Max. Min.
Width Across Flats s Max. Min.
Width Across Corners e Max. Min.
Max.
1.6 2.0 2.5 3.0 4.0 5.0 6.0 8.0 10.0 12.0 14.0 16.0 18.0 20.0 22.0 24.0 27.0 30.0 33.0 36.0 39.0 42.0 45.0 48.0 52.0 56.0 60.0 64.0 68.0
3.2 4.0 5.0 5.5 7.0 8.0 10.0 13.0 17.0 19.0 22.0 24.0 27.0 30.0 32.0 36.0 41.0 46.0 50.0 55.0 60.0 65.0 70.0 75.0 80.0 85.0 90.0 95.0 100.0
3.7 4.6 5.8 6.4 8.1 9.2 11.5 15.0 19.6 21.9 25.4 27.7 31.2 34.6 36.9 41.6 47.3 53.1 57.7 63.5 69.3 75.1 80.8 86.6 92.4 98.1 103.9 109.7 115.5
… … … 5.08 6.55 7.55 9.48 12.43 16.43 18.37 21.37 23.27 26.27 29.27 31.21 34.98 39.98 44.98 48.98 53.86 58.86 63.76 68.76 73.76 … … … … …
1.46 1.86 2.36 2.86 3.82 4.82 5.82 7.78 9.78 11.73 13.73 15.73 17.73 19.67 21.67 23.67 26.67 29.67 32.61 35.61 38.61 41.61 44.61 47.61 51.54 55.54 59.54 63.54 67.54
3.08 3.88 4.88 5.38 6.85 7.85 9.78 12.73 16.73 18.67 21.67 23.67 26.67 29.67 31.61 35.38 40.38 45.38 49.38 54.26 59.26 64.26 69.26 74.26 79.26 84.13 89.13 94.13 99.13
3.48 4.38 5.51 6.08 7.74 8.87 11.05 14.38 18.90 21.10 24.49 26.75 30.14 33.53 35.72 39.98 45.63 51.28 55.80 61.31 66.96 72.61 78.26 83.91 89.56 95.07 100.72 106.37 112.02
Transition Dia.b da
Min.
Depth of Washer Face c
Max.
Radius Under Headb r Max. Min.
… … … 4.83 6.30 7.30 9.23 12.18 16.18 18.12 21.12 23.02 26.02 28.80 30.74 34.51 39.36 44.36 48.36 53.24 58.24 63.04 68.04 73.04 … … … … …
… … … 0.1 0.1 0.2 0.3 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.5 0.5 0.5 0.5 0.5 0.6 0.6 0.6 0.6 … … … … …
2.0 2.6 3.1 3.6 4.7 5.7 6.8 9.2 11.2 14.2 16.2 18.2 20.2 22.4 24.4 26.4 30.4 33.4 36.4 39.4 42.4 45.6 48.6 52.6 56.6 63.0 67.0 71.0 75.0
0.2 0.3 0.3 0.3 0.35 0.35 0.4 0.6 0.6 1.1 1.1 1.1 1.1 1.2 1.2 1.2 1.7 1.7 1.7 1.7 1.7 1.8 1.8 2.3 2.3 3.5 3.5 3.5 3.5
0.1 0.1 0.1 0.1 0.2 0.2 0.25 0.4 0.4 0.6 0.6 0.6 0.6 0.8 0.8 0.8 1.0 1.0 1.0 1.0 1.0 1.2 1.2 1.6 1.6 2.0 2.0 2.0 2.0
Height of Head k Max. Min. 1.225 1.525 2.125 2.125 2.925 3.650 4.15 5.65 7.18 8.18 9.18 10.18 12.215 13.215 14.215 15.215 17.215 19.26 21.26 23.26 25.26 26.26 28.26 30.26 33.31 35.31 38.31 40.31 43.31
0.975 1.275 1.875 1.875 2.675 3.35 3.85 5.35 6.82 7.82 8.82 9.82 11.785 12.785 13.785 14.785 16.785 18.74 20.74 22.74 24.74 25.74 27.74 29.74 32.69 34.69 37.69 39.69 42.69
Eccentricity of Head Max.
Eccentricity of Shank and Split Pin Hole to the Thread Max.
0.18 0.18 0.18 0.18 0.22 0.22 0.22 0.27 0.27 0.33 0.33 0.33 0.33 0.33 0.39 0.39 0.39 0.39 0.39 0.46 0.46 0.46 0.46 0.46 0.46 0.54 0.54 0.54 0.54
0.14 0.14 0.14 0.14 0.18 0.18 0.18 0.22 0.22 0.27 0.27 0.27 0.27 0.33 0.33 0.33 0.33 0.33 0.39 0.39 0.39 0.39 0.39 0.39 0.46 0.46 0.46 0.46 0.46
BOLTS, SCREWS, AND NUTS
M1.6 M2 M2.5 M3 M4 M5 M6 M8 M10 M12 (M14) M16 (M18) M20 (M22) M24 (M27) M30 (M33) M36 (M39) M42 (M45) M48 (M52) M56 (M60) M64 (M68)
Pitch of Thread (Coarse PitchSeries)
a Sizes shown in parentheses are non-preferred.
All dimensions are in millimeters. For illustration of bolts and screws see Table 3.
Copyright 2004, Industrial Press, Inc., New York, NY
1575
b A true radius is not essential provided that the curve is smooth and lies wholly within the maximum radius, determined from the maximum transitional diameter, and the minimum radius specified.
Machinery's Handbook 27th Edition
Nominal Size and Thread Diametera d
0.35 0.4 0.45 0.5 0.7 0.8 1 1.25 1.5 1.75 2 2 2.5 2.5 2.5 3 3 3.5 3.5 4 4 4.5 4.5 5 5 5.5 5.5 6 6
Width Across Flats s
Width Across Corners e
Thickness of Normal Nut m
Tolerance on Squareness of Thread to Face of Nutb
Eccentricity of Hexagon
Thickness of Thin Nut t
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Max.
Max.
Min.
3.20 4.00 5.00 5.50 7.00 8.00 10.00 13.00 17.00 19.00 22.00 24.00 27.00 30.00 32.00 36.00 41.00 46.00 50.00 55.00 60.00 65.00 70.00 75.00 80.00 85.00 90.00 95.00 100.00
3.08 3.88 4.88 5.38 6.85 7.85 9.78 12.73 16.73 18.67 21.67 23.67 26.67 29.67 31.61 35.38 40.38 45.38 49.38 54.26 59.26 64.26 69.26 74.26 79.26 84.13 89.13 94.13 99.13
3.70 4.60 5.80 6.40 8.10 9.20 11.50 15.00 19.60 21.90 25.4 27.7 31.20 34.60 36.90 41.60 47.3 53.1 57.70 63.50 69.30 75.10 80.80 86.60 92.40 98.10 103.90 109.70 115.50
3.48 4.38 5.51 6.08 7.74 8.87 11.05 14.38 18.90 21.10 24.49 6.75 30.14 33.53 35.72 39.98 45.63 51.28 55.80 61.31 66.96 72.61 78.26 83.91 89.56 95.07 100.72 106.37 112.02
1.30 1.60 2.00 2.40 3.20 4.00 5.00 6.50 8.00 10.00 11.00 13.00 15.00 16.00 18.00 19.00 22.00 24.00 26.00 29.00 31.00 34.00 36.00 38.00 42.00 45.00 48.00 51.00 54.00
1.05 1.35 1.75 2.15 2.90 3.70 4.70 6.14 7.64 9.64 10.57 12.57 14.57 15.57 17.57 18.48 21.48 23.48 25.48 28.48 30.38 33.38 35.38 37.38 41.38 44.38 47.38 50.26 53.26
0.05 0.06 0.08 0.09 0.11 0.13 0.17 0.22 0.29 0.32 0.37 0.41 0.46 0.51 0.54 0.61 0.70 0.78 0.85 0.94 1.03 1.11 1.20 1.29 1.37 1.46 1.55 1.63 1.72
0.14 0.14 0.14 0.14 0.18 0.18 0.18 0.22 0.22 0.27 0.27 0.27 0.27 0.33 0.33 0.33 0.33 0.33 0.39 0.39 0.39 0.39 0.39 0.39 0.46 0.46 0.46 0.46 0.46
… … … … … … … 5.0 6.0 7.0 8.0 8.0 9.0 9.0 10.0 10.0 12.0 12.0 14.0 14.0 16.0 16.0 18.0 18.0 20.0 … … … …
… … … … … … … 4.70 5.70 6.64 7.64 7.64 8.64 8.64 9.64 9.64 11.57 11.57 13.57 13.57 15.57 15.57 17.57 17.57 19.48 … … … …
a Sizes shown in parentheses are non-preferred. b As measured with the nut squareness gage described in the text and illustrated in Appendix A of the Standard and a feeler gage.
All dimensions are in millimeters. For illustration of hexagon nuts and thin nuts see Table 3.
Copyright 2004, Industrial Press, Inc., New York, NY
BOLTS, SCREWS, AND NUTS
M1.6 M2 M2.5 M3 M4 M5 M6 M8 M10 M12 (M14) M16 (M18) M20 (M22) M24 (M27) M30 (M33) M36 (M39) M42 (M45) M48 (M52) M56 (M60) M64 (M68)
Pitch of Thread (Coarse Pitch Series)
1576
Table 5. British Standard ISO Metric Precision Hexagon Nuts and Thin Nuts BS 3692:1967 (obsolescent)
Machinery's Handbook 27th Edition
Table 6. British Standard ISO Metric Precision Hexagon Slotted Nuts and Castle Nuts BS 3692:1967 (obsolescent) Nominal Size and Thread Diametera d
Width Across Flats s
Width Across Corners e
Diameter d2
Lower Face of Nut to Bottom of Slot m
Thickness h Max.
Min.
Width of Slot n
Radius (0.25 n) r Min.
Eccentricity of the Slots
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
M4
7.00
6.85
8.10
7.74
…
…
5
4.70
3.2
2.90
1.45
1.2
0.3
Max.
M5
8.00
7.85
9.20
8.87
…
…
6
5.70
4.0
3.70
1.65
1.4
0.35
0.18
M6
10.00
9.78
11.50
11.05
…
…
7.5
7.14
5
4.70
2.25
2
0.5
0.18
9.14
0.18
13.00
12.73
15.00
14.38
…
…
6.5
6.14
2.75
2.5
0.625
0.22
17.00
16.73
19.60
18.90
…
…
12
11.57
8
7.64
3.05
2.8
0.70
0.22
M12
19.00
18.67
21.90
21.10
17
16.57
15
14.57
10
9.64
3.80
3.5
0.875
(M14)
22.00
21.67
25.4
24.49
19
18.48
16
15.57
11
10.57
3.80
3.5
0.875
0.27
M16
24.00
23.67
27.7
26.75
22
21.48
19
18.48
13
12.57
4.80
4.5
1.125
0.27
(M18)
27.00
26.67
31.20
30.14
25
24.48
21
20.48
15
14.57
4.80
4.5
1.125
0.27
M20
30.00
29.67
34.60
33.53
28
27.48
22
21.48
16
15.57
4.80
4.5
1.125
0.33
(M22)
32.00
31.61
36.90
35.72
30
29.48
26
25.48
18
17.57
5.80
5.5
1.375
0.33 0.33
9.5
0.27
M24
36.00
35.38
41.60
39.98
34
33.38
27
26.48
19
18.48
5.80
5.5
1.375
(M27)
41.00
40.38
47.3
45.63
38
37.38
30
29.48
22
21.48
5.80
5.5
1.375
0.33
M30
46.00
45.38
53.1
51.28
42
41.38
33
32.38
24
23.48
7.36
7
1.75
0.33
(M33)
50.00
49.38
57.70
55.80
46
45.38
35
34.38
26
25.48
7.36
7
1.75
0.39
M36
55.00
54.26
63.50
61.31
50
49.38
38
37.38
29
28.48
7.36
7
1.75
0.39
(M39)
60.00
59.26
69.30
66.96
55
54.26
40
39.38
31
30.38
7.36
7
1.75
0.39
M42
65.00
64.26
75.10
72.61
58
57.26
46
45.38
34
33.38
9.36
9
2.25
0.39
(M45)
70.00
69.26
80.80
78.26
62
61.26
48
47.38
36
35.38
9.36
9
2.25
0.39
M48
75.00
74.26
86.60
83.91
65
64.26
50
49.38
38
37.38
9.36
9
2.25
0.39
(M52)
80.00
79.26
92.40
89.56
70
69.26
54
53.26
42
41.38
9.36
9
2.25
0.46 0.46
M56
85.00
84.13
98.10
95.07
75
74.26
57
56.26
45
44.38
9.36
9
2.25
(M60)
90.00
89.13
103.90
100.72
80
79.26
63
62.26
48
47.38
11.43
11
2.75
0.46
M64
95.00
94.13
109.70
106.37
85
84.13
66
65.26
51
50.26
11.43
11
2.75
0.46
(M68)
100.00
99.13
115.50
112.02
90
89.13
69
68.26
54
53.26
11.43
11
2.75
0.46
BOLTS, SCREWS, AND NUTS
M8 M10
a Sizes shown in parentheses are non-preferred.
Copyright 2004, Industrial Press, Inc., New York, NY
1577
All dimensions are in millimeters. For illustration of hexagon slotted nuts and castle nuts see Table 3.
Machinery's Handbook 27th Edition 1578
BOLTS, SCREWS, AND NUTS
After several years of use of BS 2693:Part 1:1956 (obsolescent), it was recognized that it would not meet the requirements of all stud users. The thread tolerances specified could result in clearance of interference fits because locking depended on the run-out threads. Thus, some users felt that true interference fits were essential for their needs. As a result, the British Standards Committee has incorporated the Class 5 interference fit threads specified in American Standard ASA B1.12 into the BS 2693:Part 2:1964, “Recommendations for High Grade Studs.” British Standard ISO Metric Precision Hexagon Bolts, Screws and Nuts.—This British Standard BS 3692:1967 (obsolescent) gives the general dimensions and tolerances of precision hexagon bolts, screws and nuts with ISO metric threads in diameters from 1.6 to 68 mm. It is based on the following ISO recommendations and draft recommendations: R 272, R 288, DR 911, DR 947, DR 950, DR 952 and DR 987. Mechanical properties are given only with respect to carbon or alloy steel bolts, screws and nuts, which are not to be used for special applications such as those requiring weldability, corrosion resistance or ability to withstand temperatures above 300°C or below − 50°C. The dimensional requirements of this standard also apply to non-ferrous and stainless steel bolts, screws and nuts. Finish: Finishes may be dull black which results from the heat-treating operation or may be bright finish, the result of bright drawing. Other finishes are possible by mutual agreement between purchaser and producer. It is recommended that reference be made to BS 3382 “Electroplated Coatings on Threaded Components” in this respect. General Dimensions: The bolts, screws and nuts conform to the general dimensions given in Tables 3, 4, 5 and 6. Nominal Lengths of Bolts and Screws: The nominal length of a bolt or screw is the distance from the underside of the head to the extreme end of the shank including any chamfer or radius. Standard nominal lengths and tolerances thereon are given in Table 7. Table 7. British Standard ISO Metric Bolt and Screw Nominal Lengths BS 3692:1967 (obsolescent) Nominal Lengtha l 5 6 (7) 8 (9) 10 (11) 12 14 16 (18) 20 (22) 25 (28)
Tolerance ± 0.24 ± 0.24 ± 0.29 ± 0.29 ± 0.29 ± 0.29 ± 0.35 ± 0.35 ± 0.35 ± 0.35 ± 0.35 ± 0.42 ± 0.42 ± 0.42 ± 0.42
Nominal Lengtha l 30 (32) 35 (38) 40 45 50 55 60 65 70 75 80 85 …
Tolerance ± 0.42 ± 0.50 ± 0.50 ± 0.50 ± 0.50 ± 0.50 ± 0.50 ± 0.60 ± 0.60 ± 0.60 ± 0.60 ± 0.60 ± 0.60 ± 0.70 …
Nominal Lengtha l 90 (95) 100 (105) 110 (115) 120 (125) 130 140 150 160 170 180 190
Tolerance ± 0.70 ± 0.70 ± 0.70 ± 0.70 ± 0.70 ± 0.70 ± 0.70 ± 0.80 ± 0.80 ± 0.80 ± 0.80 ± 0.80 ± 0.80 ± 0.80 ± 0.925
Nominal Lengtha l 200 220 240 260 280 300 325 350 375 400 425 450 475 500 …
Tolerance ± 0.925 ± 0.925 ± 0.925 ± 1.05 ± 1.05 ± 1.05 ± 1.15 ± 1.15 ± 1.15 ± 1.15 ± 1.25 ± 1.25 ± 1.25 ± 1.25 …
a Nominal lengths shown in parentheses are non-preferred.
All dimensions are in millimeters.
Bolt and Screw Ends: The ends of bolts and screws may be finished with either a 45degree chamfer to a depth slightly exceeding the depth of thread or a radius approximately
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition BOLTS, SCREWS, AND NUTS
1579
equal to 11⁄4 times the nominal diameter of the shank. With rolled threads, the lead formed at the end of the bolt by the thread rolling operation may be regarded as providing the necesssary chamfer to the end; the end being reasonably square with the center line of the shank. Screw Thread Form: The form of thread and diameters and associated pitches of standard ISO metric bolts, screws, and nuts are in accordance with BS 3643:Part 1:1981 (1998), “Principles and Basic Data” The screw threads are made to the tolerances for the medium class of fit (6H/6g) as specified in BS 3643:Part 2:1981 (1998), “Specification for Selected Limits of Size.” Length of Thread on Bolts: The length of thread on bolts is the distance from the end of the bolt (including any chamfer or radius) to the leading face of a screw ring gage which has been screwed as far as possible onto the bolt by hand. Standard thread lengths of bolts are 2d + 6 mm for a nominal length of bolt up to and including 125 mm, 2d + 12 mm for a nominal bolt length over 125 mm up to and including 200 mm, and 2d + 25 mm for a nominal bolt length over 200 mm. Bolts that are too short for minimum thread lengths are threaded as screws and designated as screws. The tolerance on bolt thread lengths are plus two pitches for all diameters. Length of Thread on Screws: Screws are threaded to permit a screw ring gage being screwed by hand to within a distance from the underside of the head not exceeding two and a half times the pitch for diameters up to and including 52 mm and three and a half times the pitch for diameters over 52 mm. Angularity and Eccentricity of Bolts, Screws and Nuts: The axis of the thread of the nut is square to the face of the nut subject to the “squareness tolerance” given in Table 5. In gaging, the nut is screwed by hand onto a gage, having a truncated taper thread, until the thread of the nut is tight on the thread of the gage. A sleeve sliding on a parallel extension of the gage, which has a face of diameter equal to the minimum distance across the flats of the nut and exactly at 90 degrees to the axis of the gage, is brought into contact with the leading face of the nut. With the sleeve in this position, it should not be possible for a feeler gage of thickness equal to the “squareness tolerance” to enter anywhere between the leading nut face and sleeve face. The hexagon flats of bolts, screws and nuts are square to the bearing face, and the angularity of the head is within the limits of 90 degrees, plus or minus 1 degree. The eccentricity of the hexagon flats of nuts relative to the thread diameter should not exceed the values given in Table 5 and the eccentricity of the head relative to the width across flats and eccentricity between the shank and thread of bolts and screws should not exceed the values given in Table 4. Chamfering, Washer Facing and Countersinking: Bolt and screw heads have a chamfer of approximately 30 degrees on their upper faces and, at the option of the manufacturer, a washer face or full bearing face on the underside. Nuts are countersunk at an included angle of 120 degrees plus or minus 10 degrees at both ends of the thread. The diameter of the countersink should not exceed the nominal major diameter of the thread plus 0.13 mm up to and including 12 mm diameter, and plus 0.25 mm above 12 mm diameter. This stipulation does not apply to slotted, castle or thin nuts. Strength Grade Designation System for Steel Bolts and Screws: This Standard includes a strength grade designation system consisting of two figures. The first figure is one tenth of the minimum tensile strength in kgf/mm2, and the second figure is one tenth of the ratio between the minimum yield stress (or stress at permanent set limit, R0.2) and the minimum tensile strength, expressed as a percentage. For example with the strength designation grade 8.8, the first figure 8 represents 1⁄10 the minimum tensile strength of 80 kgf/mm2 and the second figure 8 represents 1⁄10 the ratio
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1580
STUDS stress at permanent set limit R 0.2 % 1 × 64 × 100 ----------------------------------------------------------------------------------- = ----- ------ --------minimum tensile strength 10 80 1
the numerical values of stress and strength being obtained from the accompanying table. Strength Grade Designations of Steel Bolts and Screws Strength Grade Designation Tensile Strength (Rm), Min.
4.6 40
4.8 40
5.6 50
5.8 50
6.6 60
6.8 60
8.8 80
10.9 12.9 14.9 100 120 140
Yield Stress (Re), Min.
24
32
30
40
36
48
…
…
…
…
Stress at Permanent Set Limit (R0.2), Min.
…
…
…
…
…
…
64
90
108
126
All stress and strength values are in kgf/mm2 units.
Strength Grade Designation System for Steel Nuts: The strength grade designation system for steel nuts is a number which is one-tenth of the specified proof load stress in kgf/mm2. The proof load stress corresponds to the minimum tensile strength of the highest grade of bolt or screw with which the nut can be used. Strength Grade Designations of Steel Nuts Strength Grade Designation Proof Load Stress (kgf/mm2)
4 40
5 50
6 60
8 80
12 120
14 140
Recommended Bolt and Nut Combinations Grade of Bolt 4.6 4.8 5.6 5.8 6.6 6.8 8.8 10.9 12.9 14.9 Recommended Grade of Nut 4 4 5 5 6 6 8 12 12 14 Note: Nuts of a higher strength grade may be substituted for nuts of a lower strength grade.
Marking: The marking and identification requirements of this Standard are only mandatory for steel bolts, screws and nuts of 6 mm diameter and larger; manufactured to strength grade designations 8.8 (for bolts or screws) and 8 (for nuts) or higher. Bolts and screws are identified as ISO metric by either of the symbols “ISO M” or “M”, embossed or indented on top of the head. Nuts may be indented or embossed by alternative methods depending on their method of manufacture. Designation: Bolts 10 mm diameter, 50 mm long manufactured from steel of strength grade 8.8, would be designated: “Bolts M10 × 50 to BS 3692 — 8.8.” Brass screws 8 mm diameter, 20 mm long would be designated: “Brass screws M8 × 20 to BS 3692.” Nuts 12 mm diameter, manufactured from steel of strength grade 6, cadmium plated could be designated: “Nuts M12 to BS 3692 — 6, plated to BS 3382: Part 1.” Miscellaneous Information: The Standard also gives mechanical properties of steel bolts, screws and nuts [i.e., tensile strengths; hardnesses (Brinell, Rockwell, Vickers); stresses (yield, proof load); etc.], material and manufacture of steel bolts, screws and nuts; and information on inspection and testing. Appendices to the Standard give information on gaging; chemical composition; testing of mechanical properties; examples of marking of bolts, screws and nuts; and a table of preferred standard sizes of bolts and screws, to name some.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition STUDS
1581
British Standard General Purpose Studs BS 2693:Part 1:1956 (obsolescent)
Min.
UN THREADS 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 7⁄ 8
0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500 0.8750 1 1.0000 11⁄8 1.1250 11⁄4 1.2500 13⁄8 1.3750 11⁄2 1.5000 BS THREADS 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 7⁄ 8
1 11⁄8 11⁄4 13⁄8 11⁄2
0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500 0.8750 1.0000 1.1250 1.2500 1.3750 1.5000
Designation No. 2 4
Max.
Minor Diameter
Min.
Max.
Min.
Major Dia.
Effective Diameter
Thds. per In.
Max.
Major Dia.
Thds. per In.
Major Dia.
Nom. Dia. D
Limits for End Screwed into Component (All threads except BA)
Min.
Effective Diameter Max.
UNF THREADS
Minor Dia.
Min.
Max.
Min.
UNC THREADS
28 24 24 20 20 18 18 16 14 12 12 12 12 12
0.2435 0.3053 0.3678 0.4294 0.4919 0.5538 0.6163 0.7406 0.8647 0.9886 1.1136 1.2386 1.3636 1.4886
0.2294 0.2265 0.2883 0.2852 0.3510 0.3478 0.4084 0.4050 0.4712 0.4675 0.5302 0.5264 0.5929 0.5889 0.7137 0.7094 0.8332 0.8286 0.9510 0.9459 1.0762 1.0709 1.2014 1.1959 1.3265 1.3209 1.4517 1.4459 BSF THREADS
0.2088 0.2643 0.3270 0.3796 0.4424 0.4981 0.5608 0.6776 0.7920 0.9029 1.0281 1.1533 1.2784 1.4036
0.2037 0.2586 0.3211 0.3729 0.4356 0.4907 0.5533 0.6693 0.7828 0.8925 1.0176 1.1427 1.2677 1.3928
20 18 16 14 13 12 11 10 9 8 7 7 6 6
0.2419 0.3038 0.3656 0.4272 0.4891 0.5511 0.6129 0.7371 0.8611 0.9850 1.1086 1.2336 1.3568 1.4818
0.2201 0.2172 0.2793 0.2762 0.3375 0.3343 0.3945 0.3911 0.4537 0.4500 0.5122 0.5084 0.5700 0.5660 0.6893 0.6850 0.8074 0.8028 0.9239 0.9188 1.0375 1.0322 1.1627 1.1572 1.2723 1.2667 1.3975 1.3917 BSW THREADS
0.1913 0.2472 0.3014 0.3533 0.4093 0.4641 0.5175 0.6316 0.7433 0.8517 0.9550 1.0802 1.1761 1.3013
0.1849 0.2402 0.2936 0.3447 0.4000 0.4542 0.5069 0.6200 0.7306 0.8376 0.9393 1.0644 1.1581 1.2832
26 22 20 18 16 16 14 12 11 10 9 9 8 8
0.2455 0.3077 0.3699 0.4320 0.4942 0.5566 0.6187 0.7432 0.8678 0.9924 1.1171 1.2419 1.3665 1.4913
0.2280 0.2863 0.3461 0.4053 0.4637 0.5263 0.5833 0.7009 0.8214 0.9411 1.0592 1.1844 1.3006 1.4258
0.2034 0.2572 0.3141 0.3697 0.4237 0.4863 0.5376 0.6475 0.7632 0.8771 0.9881 1.1133 1.2206 1.3458
0.1984 0.2517 0.3083 0.3635 0.4172 0.4797 0.5305 0.6398 0.7551 0.8686 0.9792 1.1042 1.2110 1.3360
20 18 16 14 12 12 11 10 9 8 7 7 6 …
0.2452 0.3073 0.3695 0.4316 0.4937 0.5560 0.6183 0.7428 0.8674 0.9920 1.1164 1.2413 1.4906 …
0.2206 0.2798 0.3381 0.3952 0.4503 0.5129 0.5708 0.6903 0.8085 0.9251 1.0388 1.1640 1.3991 …
0.1886 0.2442 0.0981 0.3495 0.3969 0.4595 0.5126 0.6263 0.7374 0.8451 0.9473 1.0725 1.2924 …
0.1831 0.2383 0.2919 0.3428 0.3897 0.4521 0.5050 0.6182 0.7288 0.8360 0.9376 1.0627 1.2818 …
0.2251 0.2832 0.3429 0.4019 0.4600 0.5225 0.5793 0.6966 0.8168 0.9360 1.0539 1.1789 1.2950 1.4200
0.2177 0.2767 0.3349 0.3918 0.4466 0.5091 0.5668 0.6860 0.8039 0.9200 1.0335 1.1585 1.3933 …
Limits for End Screwed into Component (BA Threads)a Major Diameter Effective Diameter Pitch 0.8100 mm 0.03189 in. 0.6600 mm 0.2598 in.
Max. 4.700 mm 0.1850 in. 3.600 mm 0.1417 in.
Min. 4.580 mm 0.1803 in. 3.500 mm 0.1378 in.
Max. 4.275 mm 0.1683 in. 3.260 mm 0.1283 in.
Min. 4.200 mm 0.1654 in. 3.190 mm 0.1256 in.
Minor Diameter Max. 3.790 mm 0.1492 in. 2.865 mm 0.1128 in.
Min. 3.620 mm 0.1425 in. 2.720 mm 0.1071 in.
a Approximate inch equivalents are shown below the dimensions given in mm.
Nom. Stud. Dia. 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2
For Thread Length (Component End) of 1D 1.5D 7⁄ 1 8 11⁄8 13⁄8 13⁄8 15⁄8 15⁄8 17⁄8 2 13⁄4
Minimum Nominal Lengths of Studsa For Thread Length Nom. (Component End) of Stud. Dia. 1D 1.5D 9⁄ 2 23⁄8 16 1⁄ 5⁄ 2 25⁄8 8 4 3⁄ 3 25⁄8 4 7⁄ 31⁄8 35⁄8 8 1 1 4 3 ⁄2
Nom. Stud Dia. 11⁄8 11⁄4 13⁄8 11⁄2 …
For Thread Length (Component End) of 1D 1.5D 4 45⁄8 43⁄4 51⁄2 5 53⁄4 1 6 5 ⁄4 … …
a The standard also gives preferred and standard lengths of studs: Preferred lengths of studs: 7⁄ , 1, 8 11⁄8, 11⁄4, 13⁄8, 11⁄2, 13⁄4, 2, 21⁄4,21⁄2, 23⁄4, 3, 31⁄4, 31⁄2 and for lengths above 31⁄2 the preferred increment is 1⁄2. 7 1 1 3 1 5 3 7 1 1 3 1 5 3 7 1 Standard lengths of studs: ⁄8, 1, 1 ⁄8, 1 ⁄4, 1 ⁄8, 1 ⁄2, 1 ⁄8, 1 ⁄4, 1 ⁄8, 2, 2 ⁄8, 2 ⁄4, 2 ⁄8, 2 ⁄2, 2 ⁄8, 2 ⁄4, 2 ⁄8, 3, 3 ⁄8, 31⁄4, 33⁄8, 31⁄2 and for lengths above 31⁄2 the standard increment is 1⁄4.
All dimensions are in inches except where otherwise noted. See page 1877 for interference-fit threads.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1582
WASHERS British Standard Single Coil Rectangular Section Spring Washers Metric Series — Types B and BP BS 4464:1969 (1998)
Nom. Size &Thread Dia., d
Max
Min
Width, b
Thickness, s
Outside Dia., d2 Max
Radius, r Max
k (Type BP Only)
M1.6 M2 (M2.2) M2.5 M3 (M3.5) M4 M5 M6 M8 M10 M12 (M14) M16 (M18) M20 (M22) M24 (M27) M30 (M33) M36 (M39) M42 (M45) M48 (M52) M56 (M60) M64 (M68)
1.9 2.3 2.5 2.8 3.3 3.8 4.35 5.35 6.4 8.55 10.6 12.6 14.7 16.9 19.0 21.1 23.3 25.3 28.5 31.5 34.6 37.6 40.8 43.8 46.8 50.0 54.1 58.1 62.3 66.3 70.5
1.7 2.1 2.3 2.6 3.1 3.6 4.1 5.1 6.1 8.2 10.2 12.2 14.2 16.3 18.3 20.3 22.4 24.4 27.5 30.5 33.5 36.5 39.6 42.6 45.6 48.8 52.8 56.8 60.9 64.9 69.0
0.7 ± 0.1 0.9 ± 0.1 1.0 ± 0.1 1.0 ± 0.1 1.3 ± 0.1 1.3 ± 0.1 1.5 ± 0.1 1.8 ± 0.1 2.5 ± 0.15 3 ± 0.15 3.5 ± 0.2 4 ± 0.2 4.5 ± 0.2 5 ± 0.2 5 ± 0.2 6 ± 0.2 6 ± 0.2 7 ± 0.25 7 ± 0.25 8 ± 0.25 10 ± 0.25 10 ± 0.25 10 ± 0.25 12 ± 0.25 12 ± 0.25 12 ± 0.25 14 ± 0.25 14 ± 0.25 14 ± 0.25 14 ± 0.25 14 ± 0.25
0.4 ± 0.1 0.5 ± 0.1 0.6 ± 0.1 0.6 ± 0.1 0.8 ± 0.1 0.8 ± 0.1 0.9 ± 0.1 1.2 ± 0.1 1.6 ± 0.1 2 ± 0.1 2.2 ± 0.15 2.5 ± 0.15 3 ± 0.15 3.5 ± 0.2 3.5 ± 0.2 4 ± 0.2 4 ± 0.2 5 ± 0.2 5 ± 0.2 6 ± 0.25 6 ± 0.25 6 ± 0.25 6 ± 0.25 7 ± 0.25 7 ± 0.25 7 ± 0.25 8 ± 0.25 8 ± 0.25 8 ± 0.25 8 ± 0.25 8 ± 0.25
3.5 4.3 4.7 5.0 6.1 6.6 7.55 9.15 11.7 14.85 18.0 21.0 24.1 27.3 29.4 33.5 35.7 39.8 43.0 48.0 55.1 58.1 61.3 68.3 71.3 74.5 82.6 86.6 90.8 93.8 99.0
0.15 0.15 0.2 0.2 0.25 0.25 0.3 0.4 0.5 0.65 0.7 0.8 1.0 1.15 1.15 1.3 1.3 1.65 1.65 2.0 2.0 2.0 2.0 2.3 2.3 2.3 2.65 2.65 2.65 2.65 2.65
… … … … … 0.15 0.15 0.15 0.2 0.3 0.3 0.4 0.4 0.4 0.4 0.4 0.4 0.5 0.5 0.8 0.8 0.8 0.8 0.8 0.8 0.8 1.0 1.0 1.0 1.0 1.0
Inside Dia.,d1
All dimensions are given in millimeters. Sizes shown in parentheses are non-preferred, and are not usually stock sizes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition WASHERS
1583
British Standard Double Coil Rectangular Section Spring Washers; Metric Series — Type D BS 4464:1969 (1998)
Inside Dia., d1
Nom. Size, d
Max
Min
Width, b
Thickness, s
O.D., d2 Max
Radius, r Max
M2 (M2.2) M2.5 M3.0 (M3.5) M4 M5 M6 M8 M10 M12 (M14) M16 (M18) M20 (M22) M24 (M27) M30 (M33) M36 (M39) M42 M48 M56 M64
2.4 2.6 2.9 3.6 4.1 4.6 5.6 6.6 8.8 10.8 12.8 15.0 17.0 19.0 21.5 23.5 26.0 29.5 33.0 36.0 40.0 43.0 46.0 52.0 60.0 70.0
2.1 2.3 2.6 3.3 3.8 4.3 5.3 6.3 8.4 10.4 12.4 14.5 16.5 18.5 20.8 22.8 25.0 28.0 31.5 34.5 38.0 41.0 44.0 50.0 58.0 67.0
0.9 ± 0.1 1.0 ± 0.1 1.2 ± 0.1 1.2 ± 0.1 1.6 ± 0.1 1.6 ± 0.1 2 ± 0.1 3 ± 0.15 3 ± 0.15 3.5 ± 0.20 3.5 ± 0.2 5 ± 0.2 5 ± 0.2 5 ± 0.2 5 ± 0.2 6 ± 0.2 6.5 ± 0.2 7 ± 0.25 8 ± 0.25 8 ± 0.25 10 ± 0.25 10 ± 0.25 10 ± 0.25 10 ± 0.25 12 ± 0.25 12 ± 0.25
0.5 ± 0.05 0.6 ± 0.05 0.7 ± 0.1 0.8 ± 0.1 0.8 ± 0.1 0.8 ± 0.1 0.9 ± 0.1 1 ± 0.1 1.2 ± 0.1 1.2 ± 0.1 1.6 ± 0.1 1.6 ± 0.1 2 ± 0.1 2 ± 0.1 2 ± 0.1 2.5 ± 0.15 3.25 ± 0.15 3.25 ± 0.15 3.25 ± 0.15 3.25 ± 0.15 3.25 ± 0.15 3.25 ± 0.15 4.5 ± 0.2 4.5 ± 0.2 4.5 ± 0.2 4.5 ± 0.2
4.4 4.8 5.5 6.2 7.5 8.0 9.8 12.9 15.1 18.2 20.2 25.4 27.4 29.4 31.9 35.9 39.4 44.0 49.5 52.5 60.5 63.5 66.5 72.5 84.5 94.5
0.15 0.2 0.23 0.25 0.25 0.25 0.3 0.33 0.4 0.4 0.5 0.5 0.65 0.65 0.65 0.8 1.1 1.1 1.1 1.1 1.1 1.1 1.5 1.5 1.5 1.5
All dimensions are given in millimeters. Sizes shown in parentheses are non-preferred, and are not usually stock sizes. The free height of double coil washers before compression is normally approximately five times the thickness but, if required, washers with other free heights may be obtained by arrangement with manufacturer.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1584
WASHERS
British Standard Single Coil Square Section Spring Washers; Metric Series — Type A-1 BS 4464:1969 (1998)
British Standard Single Coil Square Section Spring Washers; Metric Series — Type A-2 BS 4464:1969 (1998) Inside Dia., d1
Nom. Size, d
Max
Min
Thickness & Width, s
O.D., d2 Max
Radius, r Max
M3 (M3.5) M4 M5 M6 M8 M10 M12 (M14) M16 (M18) M20 (M22) M24 (M27) M30 (M33) M36 (M39) M42 (M45) M48
3.3 3.8 4.35 5.35 6.4 8.55 10.6 12.6 14.7 16.9 19.0 21.1 23.3 25.3 28.5 31.5 34.6 37.6 40.8 43.8 46.8 50.0
3.1 3.6 4.1 5.1 6.1 8.2 10.2 12.2 14.2 16.3 18.3 20.3 22.4 24.4 27.5 30.5 33.5 36.5 39.6 42.6 45.6 48.8
1 ± 0.1 1 ± 0.1 1.2 ± 0.1 1.5 ± 0.1 1.5 ± 0.1 2 ± 0.1 2.5 ± 0.15 2.5 ± 0.15 3 ± 0.2 3.5 ± 0.2 3.5 ± 0.2 4.5 ± 0.2 4.5 ± 0.2 5 ± 0.2 5 ± 0.2 6 ± 0.2 6 ± 0.2 7 ± 0.25 7 ± 0.25 8 ± 0.25 8 ± 0.25 8 ± 0.25
5.5 6.0 6.95 8.55 9.6 12.75 15.9 17.9 21.1 24.3 26.4 30.5 32.7 35.7 38.9 43.9 47.0 52.1 55.3 60.3 63.3 66.5
0.3 0.3 0.4 0.5 0.5 0.65 0.8 0.8 1.0 1.15 1.15 1.5 1.5 1.65 1.65 2.0 2.0 2.3 2.3 2.65 2.65 2.65
All dimensions are in millimeters. Sizes shown in parentheses are nonpreferred and are not usually stock sizes.
British Standard for Metric Series Metal Washers.—BS 4320:1968 (1998) specifies bright and black metal washers for general engineering purposes. Bright Metal Washers: These washers are made from either CS4 cold-rolled strip steel BS 1449:Part 3B or from CZ 108 brass strip B.S. 2870: 1980, both in the hard condition. However, by mutual agreement between purchaser and supplier, washers may be made available with the material in any other condition, or they may be made from another material, or may be coated with a protective or decorative finish to some appropriate British Standard. Washers are reasonably flat and free from burrs and are normally supplied unchamfered. They may, however, have a 30-degree chamfer on one edge of the external diameter. These washers are made available in two size categories, normal and large diameter, and in two thicknesses, normal (Form A or C) and light (Form B or D). The thickness of a light-range washer is from 1⁄2 to 2⁄3 the thickness of a normal range washer. Black Metal Washers: These washers are made from mild steel, and can be supplied in three size categories designated normal, large, and extra large diameters. The normaldiameter series is intended for bolts ranging from M5 to M68 (Form E washers), the largediameter series for bolts ranging from M8 to M39 (Form F washers), and the extra large series for bolts from M5 to M39 (Form G washers). A protective finish can be specified by the purchaser in accordance with any appropriate British Standard.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition WASHERS
1585
Washer Designations: The Standard specifies the details that should be given when ordering or placing an inquiry for washers. These details are the general description, namely, bright or black washers; the nominal size of the bolt or screw involved, for example, M5; the designated form, for example, Form A or Form E; the dimensions of any chamfer required on bright washers; the number of the Standard BS 4320:1968 (1998), and coating information if required, with the number of the appropriate British Standard and the coating thickness needed. As an example, in the use of this information, the designation for a chamfered, normal-diameter series washer of normal-range thickness to suit a 12-mm diameter bolt would be: Bright washers M12 (Form A) chamfered to B.S. 4320. British Standard Bright Metal Washers — Metric Series BS 4320:1968 (1998) NORMAL DIAMETER SIZES Nominal Size of Bolt or Screw M 1.0 M 1.2 (M 1.4) M 1.6 M 2.0 (M 2.2) M 2.5 M3 (M 3.5) M4 (M 4.5) M5 M6 (M 7) M8 M 10 M 12 (M 14) M 16 (M 18) M 20 (M 22) M24 (M 27) M30 (M 33) M 36 (M 39) Nominal Size of Bolt or Screw M4 M5 M6 M8 M 10 M 12 (M 14) M 16 (M 18) M 20 (M 22) M 24 (M 27) M 30 (M 33) M 36 (M 39)
Thickness Inside Diameter Nom 1.1 1.3 1.5 1.7 2.2 2.4 2.7 3.2 3.7 4.3 4.8 5.3 6.4 7.4 8.4 10.5 13.0 15.0 17.0 19.0 21 23 25 28 31 34 37 40
Max 1.25 1.45 1.65 1.85 2.35 2.55 2.85 3.4 3.9 4.5 5.0 5.5 6.7 7.7 8.7 10.9 13.4 15.4 17.4 19.5 21.5 23.5 25.5 28.5 31.6 34.6 37.6 40.6
Outside Diameter
Min 1.1 1.3 1.5 1.7 2.2 2.4 2.7 3.2 3.7 4.3 4.8 5.3 6.4 7.4 8.4 10.5 13.0 15.0 17.0 19.0 21 23 25 28 31 34 37 40
Form A (Normal Range) Nom Max Min Nom Max Min 2.5 2.5 2.3 0.3 0.4 0.2 3.0 3.0 2.8 0.3 0.4 0.2 3.0 3.0 2.8 0.3 0.4 0.2 4.0 4.0 3.7 0.3 0.4 0.2 5.0 5.0 4.7 0.3 0.4 0.2 5.0 5.0 4.7 0.5 0.6 0.4 6.5 6.5 6.2 0.5 0.6 0.4 7 7 6.7 0.5 0.6 0.4 7 7 6.7 0.5 0.6 0.4 9 9 8.7 0.8 0.9 0.7 9 9 8.7 0.8 0.9 0.7 10 10 9.7 1.0 1.1 0.9 12.5 12.5 12.1 1.6 1.8 1.4 14 14 13.6 1.6 1.8 1.4 17 17 16.6 1.6 1.8 1.4 21 21 20.5 2.0 2.2 1.8 24 24 23.5 2.5 2.7 2.3 28 28 27.5 2.5 2.7 2.3 30 30 29.5 3.0 3.3 2.7 34 34 33.2 3.0 3.3 2.7 37 37 36.2 3.0 3.3 2.7 39 39 38.2 3.0 3.3 2.7 44 44 43.2 4.0 4.3 3.7 50 50 49.2 4.0 4.3 3.7 56 56 55.0 4.0 4.3 3.7 60 60 59.0 5.0 5.6 4.4 66 66 65.0 5.0 5.6 4.4 72 72 71.0 6.0 6.6 5.4 LARGE DIAMETER SIZES
Nom … … … … … … … … … … … … 0.8 0.8 1.0 1.25 1.6 1.6 2.0 2.0 2.0 2.0 2.5 2.5 2.5 3.0 3.0 3.0
Form B (Light Range) Max … … … … … … … … … … … … 0.9 0.9 1.1 1.45 1.80 1.8 2.2 2.2 2.2 2.2 2.7 2.7 2.7 3.3 3.3 3.3
Min … … … … … … … … … … … … 0.7 0.7 0.9 1.05 1.40 1.4 1.8 1.8 1.8 1.8 2.3 2.3 2.3 2.7 2.7 2.7
Thickness Inside Diameter Nom 4.3 5.3 6.4 8.4 10.5 13.0 15.0 17.0 19.0 21 23 25 28 31 34 37 40
Max 4.5 5.5 6.7 8.7 10.9 13.4 15.4 17.4 19.5 21.5 23.5 25.5 28.5 31.6 34.6 37.6 40.6
Outside Diameter Min 4.3 5.3 6.4 8.4 10.5 13.0 15 17 19 21 23 25 28 31 34 37 40
Nom 10.0 12.5 14 21 24 28 30 34 37 39 44 50 56 60 66 72 77
Max 10.0 12.5 14 21 24 28 30 34 37 39 44 50 56 60 66 72 77
Min 9.7 12.1 13.6 20.5 23.5 27.5 29.5 33.2 36.2 38.2 43.2 49.2 55 59 65 71 76
Form C (Normal Range) Nom Max Min 0.8 0.9 0.7 1.0 1.1 0.9 1.6 1.8 1.4 1.6 1.8 1.4 2.0 2.2 1.8 2.5 2.7 2.3 2.5 2.7 2.3 3.0 3.3 2.7 3.0 3.3 2.7 3.0 3.3 2.7 3.0 3.3 2.7 4.0 4.3 3.7 4.0 4.3 3.7 4.0 4.3 3.7 5.0 5.6 4.4 5.0 5.6 4.4 6.0 6.6 5.4
Nom … … 0.8 1.0 1.25 1.6 1.6 2.0 2.0 2.0 2.0 2.5 2.5 2.5 3.0 3.0 3.0
All dimensions are in millimeters. Nominal bolt or screw sizes shown in parentheses are nonpreferred.
Copyright 2004, Industrial Press, Inc., New York, NY
Form D (Light Range) Max … … 0.9 1.1 1.45 1.8 1.8 2.2 2.2 2.2 2.2 2.7 2.7 2.7 3.3 3.3 3.3
Min … … 0.7 0.9 1.05 1.4 1.4 1.8 1.8 1.8 1.8 2.3 2.3 2.3 2.7 2.7 2.7
Machinery's Handbook 27th Edition 1586
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WASHERS
British Standard Black Metal Washers — Metric Series BS 4320:1968 (1998) Inside Diameter
NORMAL DIAMETER SIZES (Form E) Outside Diameter
Nom Bolt or Screw Size
Nom
Max
Min
M5 M6 (M 7) M8 M 10 M 12 (M 14) M 16 (M 18) M 20 (M 22) M 24 (M 27) M 30 (M 33) M 36 (M 39) M 42 (M 45) M 48 (M 52) M 56 (M 60) M 64 (M 68)
5.5 6.6 7.6 9.0 11.0 14 16 18 20 22 24 26 30 33 36 39 42 45 48 52 56 62 66 70 74
5.8 7.0 8.0 9.4 11.5 14.5 16.5 18.5 20.6 22.6 24.6 26.6 30.6 33.8 36.8 39.8 42.8 45.8 48.8 53 57 63 67 71 75
5.5 6.6 7.6 9.0 11.0 14 16 18 20 22 24 26 30 33 36 39 42 45 48 52 56 62 66 70 74
M8 M 10 M 12 (M 14) M 16 (M 18) M 20 (M 22) M 24 (M 27) M 30 (M 33) M 36 (M 39)
9 11 14 16 18 20 22 24 26 30 33 36 39 42
9.4 11.5 14.5 16.5 18.5 20.6 22.6 24.6 26.6 30.6 33.8 36.8 39.8 42.8
M5 M6 (M 7) M8 M 10 M 12 (M 14) M 16 (M 18) M 20 (M 22) M 24 (M 27) M 30 (M 33) M 36 (M39)
5.5 6.6 7.6 9 11 14 16 18 20 22 24 26 30 33 36 39 42
5.8 7.0 8.0 9.4 11.5 14.5 16.5 18.5 20.6 22.6 24.6 26.6 30.6 33.8 36.8 39.8 42.8
Nom
Max
Min
10.0 10.0 9.2 12.5 12.5 11.7 14.0 14.0 13.2 17 17 16.2 21 21 20.2 24 24 23.2 28 28 27.2 30 30 29.2 34 34 32.8 37 37 35.8 39 39 37.8 44 44 42.8 50 50 48.8 56 56 54.5 60 60 58.5 66 66 64.5 72 72 70.5 78 78 76.5 85 85 83 92 92 90 98 98 96 105 105 103 110 110 108 115 115 113 120 120 118 LARGE DIAMETER SIZES (Form F) 9.0 21 21 20.2 11 24 24 23.2 14 28 28 27.2 16 30 30 29.2 18 34 34 32.8 20 37 37 35.8 22 39 39 37.8 24 44 44 42.8 26 50 50 48.8 30 56 56 54.5 33 60 60 58.5 36 66 66 64.5 39 72 72 70.5 42 77 77 75.5 EXTRA LARGE DIAMETER SIZES (Form G) 5.5 15 15 14.2 6.6 18 18 17.2 7.6 21 21 20.2 9.0 24 24 23.2 11.0 30 30 29.2 14.0 36 36 34.8 16.0 42 42 40.8 18 48 48 46.8 20 54 54 52.5 22 60 60 58.5 24 66 66 64.5 26 72 72 70.5 30 81 81 79 33 90 90 88 36 99 99 97 39 108 108 106 42 117 117 115
Thickness Nom
Max
Min
1.0 1.6 1.6 1.6 2.0 2.5 2.5 3.0 3.0 3.0 3.0 4 4 4 5 5 6 7 7 8 8 9 9 9 10
1.2 1.9 1.9 1.9 2.3 2.8 2.8 3.6 3.6 3.6 3.6 4.6 4.6 4.6 6.0 6.0 7.0 8.2 8.2 9.2 9.2 10.2 10.2 10.2 11.2
0.8 1.3 1.3 1.3 1.7 2.2 2.2 2.4 2.4 2.4 2.4 3.4 3.4 3.4 4.0 4.0 5.0 5.8 5.8 6.8 6.8 7.8 7.8 7.8 8.8
1.6 2 2.5 2.5 3 3 3 3 4 4 4 5 5 6
1.9 2.3 2.8 2.8 3.6 3.6 3.6 3.6 4.6 4.6 4.6 6.0 6.0 7
1.3 1.7 2.2 2.2 2.4 2.4 2.4 2.4 3.4 3.4 3.4 4 4 5
1.6 2 2 2 2.5 3 3 4 4 5 5 6 6 8 8 10 10
1.9 2.3 2.3 2.3 2.8 3.6 3.6 4.6 4.6 6.0 6.0 7 7 9.2 9.2 11.2 11.2
1.3 1.7 1.7 1.7 2.2 2.4 2.4 3.4 3.4 4 4 5 5 6.8 6.8 8.8 8.8
All dimensions are in millimeters. Nominal bolt or screw sizes shown in parentheses are nonpreferred.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
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MACHINE SCREWS
1587
MACHINE SCREWS AND NUTS American National Standard Machine Screws and Machine Screw Nuts.—T h i s Standard ANSI B18.6.3 covers both slotted and recessed head machine screws. Dimensions of various types of slotted machine screws, machine screw nuts, and header points are given in Tables 1 through 12. The Standard also covers flat trim head, oval trim head and drilled fillister head machine screws and gives cross recess dimensions and gaging dimensions for all types of machine screw heads. Information on metric machine screws B18.6.7M is given beginning on page 1596. Threads: Except for sizes 0000, 000, and 00, machine screw threads may be either Unified Coarse (UNC) and Fine thread (UNF) Class 2A (see American Standard for Unified Screw Threads starting on page 1732) or UNRC and UNRF Series, at option of manufacturer. Thread dimensions for sizes 0000, 000, and 00 are given in Table 7 on page 1592. Threads for hexagon machine screw nuts may be either UNC or UNF, Class 2B, and for square machine screw nuts are UNC Class 2B. Length of thread: Machine screws of sizes No. 5 and smaller with nominal lengths equal to 3 diameters and shorter have full form threads extending to within 1 pitch (thread) of the bearing surface of the head, or closer, if practicable. Nominal lengths greater than 3 diameters, up to and including 11⁄8 inch, have full form threads extending to within two pitches (threads) of the bearing surface of the head, or closer, if practicable. Unless otherwise specified, screws of longer nominal length have a minimum length of full form thread of 1.00 inch.Machine screws of sizes No. 6 and larger with nominal length equal to 3 diameters and shorter have full form threads extending to within 1 pitch (thread) of the bearing surface of the head, or closer, if practicable. Nominal lengths greater than 3 diameters, up to and including 2 inches, have full form threads extending to within 2 pitches (threads) of the bearing surface of the head, or closer, if practicable. Screws of longer nominal length, unless otherwise specified, have a minimum length of full form thread of 1.50 inches. Table 1. Square and Hexagon Machine Screw Nuts ANSI B18.6.3-1972 (R1991) F
H
F
H
Optional; See Note G1
G 30
30 Nom. Size 0 1 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8
Basic Dia. 0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500 0.3125 0.3750
Basic F 5⁄ 32 5⁄ 32 3⁄ 16 3⁄ 16 1⁄ 4 5⁄ 16 5⁄ 16 11⁄ 32 3⁄ 8 7⁄ 16 7⁄ 16 9⁄ 16 5⁄ 8
Max. F 0.156 0.156 0.188 0.188 0.250 0.312 0.312 0.344 0.375 0.438 0.438 0.562 0.625
Min. F 0.150 0.150 0.180 0.180 0.241 0.302 0.302 0.332 0.362 0.423 0.423 0.545 0.607
Max. G 0.221 0.221 0.265 0.265 0.354 0.442 0.442 0.486 0.530 0.619 0.619 0.795 0.884
Min. G 0.206 0.206 0.247 0.247 0.331 0.415 0.415 0.456 0.497 0.581 0.581 0.748 0.833
Max. G1
Min. G1
0.180 0.180 0.217 0.217 0.289 0.361 0.361 0.397 0.433 0.505 0.505 0.650 0.722
0.171 0.171 0.205 0.205 0.275 0.344 0.344 0.378 0.413 0.482 0.482 0.621 0.692
Max. H 0.050 0.050 0.066 0.066 0.098 0.114 0.114 0.130 0.130 0.161 0.193 0.225 0.257
Min. H 0.043 0.043 0.057 0.057 0.087 0.102 0.102 0.117 0.117 0.148 0.178 0.208 0.239
All dimensions in inches. Hexagon machine screw nuts have tops flat and chamfered. Diameter of top circle should be the maximum width across flats within a tolerance of minus 15 per cent. Bottoms are flat but may be chamfered if so specified. Square machine screw nuts have tops and bottoms flat without chamfer.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1588
MACHINE SCREWS
Diameter of body: The diameter of machine screw bodies is not less than Class 2A thread minimum pitch diameter nor greater than the basic major diameter of the thread. Crossrecessed trim head machine screws not threaded to the head have an 0.062 in. minimum length shoulder under the head with diameter limits as specified in the dimensional tables in the standard. Designation: Machine screws are designated by the following data in the sequence shown: Nominal size (number, fraction, or decimal equivalent); threads per inch; nominal length (fraction or decimal equivalent); product name, including head type and driving provision; header point, if desired; material; and protective finish, if required. For example: 1⁄ − 20 × 11⁄ Slotted Pan Head Machine Screw, Steel, Zinc Plated 4 4 6 − 32 × 3⁄4 Type IA Cross Recessed Fillister Head Machine Screw, Brass Machine screw nuts are designated by the following data in the sequence shown: Nominal size (number, fraction, or decimal equivalent); threads per inch; product name; material; and protective finish, if required. For example: 10 − 24 Hexagon Machine Screw Nut, Steel, Zinc Plated 0.138 − 32 Square Machine Screw Nut, Brass Table 2. American National Standard Slotted 100-Degree Flat Countersunk Head Machine Screws ANSI B18.6.3-1972 (R1977) T J 99 101
A
H L Nominal Sizea or Basic Screw Dia. 0000 000 00 0 1 2 3 4 6 8 10 1⁄ 4 5⁄ 16 3⁄ 8
0.0210 0.0340 0.0470 0.0600 0.0730 0.0860 0.0990 0.1120 0.1380 0.1640 0.1900 0.2500 0.3125 0.3750
Head Dia., A Min., Max., Edge Edge Rounded Sharp or Flat 0.043 0.037 0.064 0.058 0.093 0.085 0.119 0.096 0.146 0.120 0.172 0.143 0.199 0.167 0.225 0.191 0.279 0.238 0.332 0.285 0.385 0.333 0.507 0.442 0.635 0.556 0.762 0.670
Head Height, H Ref. 0.009 0.014 0.020 0.026 0.031 0.037 0.043 0.049 0.060 0.072 0.083 0.110 0.138 0.165
Slot Width, J Max. 0.008 0.012 0.017 0.023 0.026 0.031 0.035 0.039 0.048 0.054 0.060 0.075 0.084 0.094
Min. 0.005 0.008 0.010 0.016 0.019 0.023 0.027 0.031 0.039 0.045 0.050 0.064 0.072 0.081
Slot Depth, T Max. 0.008 0.011 0.013 0.013 0.016 0.019 0.022 0.024 0.030 0.036 0.042 0.055 0.069 0.083
Min. 0.004 0.007 0.008 0.008 0.010 0.012 0.014 0.017 0.022 0.027 0.031 0.042 0.053 0.065
a When specifying nominal size in decimals, zeros preceding the decimal point and in the fourth decimal place are omitted. All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINE SCREWS
1589
Table 3. American National Standard Slotted Flat Countersunk Head and Close Tolerance 100-Degree Flat Countersunk Head Machine Screws ANSI B18.6.3-1972 (R1991)
Nominal Sizea or Basic Screw Dia. 0000 000 00 0 1 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
Max., Lb
0.0210 0.0340 0.0470 0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500
SLOTTED FLAT COUNTERSUNK HEAD TYPE Head Dia., A Head Slot Height, H Width, J Min., Max., Edge c Sharp Edge Ref. Max. Min.
.... .... .... 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 … … …
0.043 0.064 0.093 0.119 0.146 0.172 0.199 0.225 0.252 0.279 0.332 0.385 0.438 0.507 0.635 0.762 0.812 0.875 1.000 1.125 1.375
0.037 0.058 0.085 0.099 0.123 0.147 0.171 0.195 0.220 0.244 0.292 0.340 0.389 0.452 0.568 0.685 0.723 0.775 0.889 1.002 1.230
0.011 0.016 0.028 0.035 0.043 0.051 0.059 0.067 0.075 0.083 0.100 0.116 0.132 0.153 0.191 0.230 0.223 0.223 0.260 0.298 0.372
0.008 0.011 0.017 0.023 0.026 0.031 0.035 0.039 0.043 0.048 0.054 0.060 0.067 0.075 0.084 0.094 0.094 0.106 0.118 0.133 0.149
0.004 0.007 0.010 0.016 0.019 0.023 0.027 0.031 0.035 0.039 0.045 0.050 0.056 0.064 0.072 0.081 0.081 0.091 0.102 0.116 0.131
Slot Depth, T Max.
Min.
0.007 0.009 0.014 0.015 0.019 0.023 0.027 0.030 0.034 0.038 0.045 0.053 0.060 0.070 0.088 0.106 0.103 0.103 0.120 0.137 0.171
0.003 0.005 0.009 0.010 0.012 0.015 0.017 0.020 0.022 0.024 0.029 0.034 0.039 0.046 0.058 0.070 0.066 0.065 0.077 0.088 0.111
a When specifying nominal size in decimals, zeros preceding the decimal point and in the fourth decimal place are omitted. b These lengths or shorter are undercut. c May be rounded or flat.
CLOSE TOLERANCE 100-DEGREE FLAT COUNTERSUNK HEAD TYPE Head Diameter, A Head Slot Height, Width, Max., Min., H J Edge Edgec Sharp Ref. Max. Min.
Nominal Sizea or Basic Screw Dia. 4 6 8 10 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8
Slot Depth, T Max.
Min.
0.1120 0.1380 0.1640 0.1900 0.2500
0.225 0.279 0.332 0.385 0.507
0.191 0.238 0.285 0.333 0.442
0.049 0.060 0.072 0.083 0.110
0.039 0.048 0.054 0.060 0.075
0.031 0.039 0.045 0.050 0.064
0.024 0.030 0.036 0.042 0.055
0.017 0.022 0.027 0.031 0.042
0.3125
0.635
0.556
0.138
0.084
0.072
0.069
0.053
0.3750
0.762
0.670
0.165
0.094
0.081
0.083
0.065
0.4375
0.890
0.783
0.193
0.094
0.081
0.097
0.076
0.5000
1.017
0.897
0.221
0.106
0.091
0.111
0.088
0.5625
1.145
1.011
0.249
0.118
0.102
0.125
0.099
0.6250
1.272
1.124
0.276
0.133
0.116
0.139
0.111
All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1590
MACHINE SCREWS
Table 4. American National Standard Slotted Undercut Flat Countersunk Head and Plain and Slotted Hex Washer Head Machine Screws ANSI B18.6.3-1972 (R1991) SLOTTED UNDERCUT FLAT COUNTERSUNK HEAD TYPE
Nominal Sizea or Basic Screw Dia. 0 1 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2
0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500 0.3125 0.3750 0.4375 0.5000
Max., Lb 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
Head Dia., A Max., Min., Edge Edge Rnded. Sharp or Flat
Head Height, H Max. Min.
Slot Width, J Max. Min.
Slot Depth, T Max. Min.
0.119 0.146 0.172 0.199 0.225 0.252 0.279 0.332
0.099 0.123 0.147 0.171 0.195 0.220 0.244 0.292
0.025 0.031 0.036 0.042 0.047 0.053 0.059 0.070
0.018 0.023 0.028 0.033 0.038 0.043 0.048 0.058
0.023 0.026 0.031 0.035 0.039 0.043 0.048 0.054
0.016 0.019 0.023 0.027 0.031 0.035 0.039 0.045
0.011 0.014 0.016 0.019 0.022 0.024 0.027 0.032
0.007 0.009 0.011 0.012 0.014 0.016 0.017 0.021
0.385 0.438 0.507 0.635 0.762
0.340 0.389 0.452 0.568 0.685
0.081 0.092 0.107 0.134 0.161
0.068 0.078 0.092 0.116 0.140
0.060 0.067 0.075 0.084 0.094
0.050 0.056 0.064 0.072 0.081
0.037 0.043 0.050 0.062 0.075
0.024 0.028 0.032 0.041 0.049
0.812 0.875
0.723 0.775
0.156 0.156
0.133 0.130
0.094 0.106
0.081 0.091
0.072 0.072
0.045 0.046
a When specifying nominal size in decimals, zeros preceding the decimal point and in the fourth decimal place are omitted. b These lengths or shorter are undercut.
PLAIN AND SLOTTED HEX WASHER HEAD TYPES
Nominal Sizea or Basic Screw Dia. 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8
Width Across Flats, A Max. Min.
Width AcrossCorn., W Min.
Head Height, H
Washer Dia., B
Washer Thick., U
Slota Width, J
Slota Depth, T
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500
0.125 0.125 0.188 0.188 0.250 0.250 0.312 0.312 0.375
0.120 0.120 0.181 0.181 0.244 0.244 0.305 0.305 0.367
0.134 0.134 0.202 0.202 0.272 0.272 0.340 0.340 0.409
0.050 0.055 0.060 0.070 0.093 0.110 0.120 0.155 0.190
0.040 0.044 0.049 0.058 0.080 0.096 0.105 0.139 0.172
0.166 0.177 0.243 0.260 0.328 0.348 0.414 0.432 0.520
0.154 0.163 0.225 0.240 0.302 0.322 0.384 0.398 0.480
0.016 0.016 0.019 0.025 0.025 0.031 0.031 0.039 0.050
0.010 0.010 0.011 0.015 0.015 0.019 0.019 0.022 0.030
…. …. 0.039 0.043 0.048 0.054 0.060 0.067 0.075
…. …. 0.031 0.035 0.039 0.045 0.050 0.056 0.064
…. …. 0.042 0.049 0.053 0.074 0.080 0.103 0.111
…. …. 0.025 0.030 0.033 0.052 0.057 0.077 0.083
0.3125
0.500 0.489
0.545
0.230 0.208 0.676 0.624 0.055 0.035 0.084 0.072 0.134 0.100
0.3750
0.562 0.551
0.614
0.295 0.270 0.780 0.720 0.063 0.037 0.094 0.081 0.168 0.131
a Unless otherwise specified, hexagon washer head machine screws are not slotted.
All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINE SCREWS
1591
Table 5. American National Standard Slotted Truss Head and Plain and Slotted Hexagon Head Machine Screws ANSI B18.6.3-1972 (R1991) SLOTTED TRUSS HEAD TYPE
Head Dia., A Min.
Nominal Sizea or Basic Screw Dia. 0000 000 00 0 1 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
Max.
0.0210 0.0340 0.0470 0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500
0.049 0.077 0.106 0.131 0.164 0.194 0.226 0.257 0.289 0.321 0.384 0.448 0.511 0.573 0.698 0.823 0.948 1.073 1.198 1.323 1.573
0.043 0.071 0.098 0.119 0.149 0.180 0.211 0.241 0.272 0.303 0.364 0.425 0.487 0.546 0.666 0.787 0.907 1.028 1.149 1.269 1.511
Head Height, H Min.
Max.
0.014 0.022 0.030 0.037 0.045 0.053 0.061 0.069 0.078 0.086 0.102 0.118 0.134 0.150 0.183 0.215 0.248 0.280 0.312 0.345 0.410
0.010 0.018 0.024 0.029 0.037 0.044 0.051 0.059 0.066 0.074 0.088 0.103 0.118 0.133 0.162 0.191 0.221 0.250 0.279 0.309 0.368
Head Radius, R Max.
Max.
Slot Width, J Min.
0.032 0.051 0.070 0.087 0.107 0.129 0.151 0.169 0.191 0.211 0.254 0.283 0.336 0.375 0.457 0.538 0.619 0.701 0.783 0.863 1.024
0.009 0.013 0.017 0.023 0.026 0.031 0.035 0.039 0.043 0.048 0.054 0.060 0.067 0.075 0.084 0.094 0.094 0.106 0.118 0.133 0.149
Slot Depth, T Min.
Max.
0.005 0.009 0.010 0.016 0.019 0.023 0.027 0.031 0.035 0.039 0.045 0.050 0.056 0.064 0.072 0.081 0.081 0.091 0.102 0.116 0.131
0.009 0.013 0.018 0.022 0.027 0.031 0.036 0.040 0.045 0.050 0.058 0.068 0.077 0.087 0.106 0.124 0.142 0.161 0.179 0.196 0.234
0.005 0.009 0.012 0.014 0.018 0.022 0.026 0.030 0.034 0.037 0.045 0.053 0.061 0.070 0.085 0.100 0.116 0.131 0.146 0.162 0.182
a Where specifying nominal size in decimals, zeros preceding decimal points and in the fourth decimal place are omitted.
PLAIN AND SLOTTED HEXAGON HEAD TYPES
Regular Head Width Across Across Corn., W Flats, A Max. Min. Min.
Large Head Width Across Across Corn., W Flats, A Max. Min. Min.
Max.
Min.
Max.
Min.
Max.
Min.
.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500
.125 .125 .188 .188 .188 .250 .250 .312 .312 .375
.120 .120 .181 .181 .181 .244 .244 .305 .305 .367
.134 .134 .202 .202 .202 .272 .272 .340 .340 .409
.... .... .... .219 .250 .... .312 .... .375 .438
.... .... .... .213 .244 .... .305 .... .367 .428
.... .... .... .238 .272 .... .340 .... .409 .477
.044 .050 .055 .060 .070 .093 .110 .120 .155 .190
.036 .040 .044 .049 .058 .080 .096 .105 .139 .172
.... .... .... .039 .043 .048 .054 .060 .067 .075
.... .... .... .031 .035 .039 .045 .050 .056 .064
.... .... .... .036 .042 .046 .066 .072 .093 .101
… … … .02 .03 .03 .05 .057 .07 .08
0.3125
.500
.489
.545
....
....
....
.230
.208
.084
.072
.122
.10
0.3750
.562
.551
.614
....
....
....
.295
.270
.094
.081
.156
.13
Nominal Sizea or Basic Screw Dia. 1 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8
Head Height, H
Slota Width, J
a Unless otherwise specified, hexagon head machine screws are not slotted.
All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Slota Depth, T
Machinery's Handbook 27th Edition 1592
MACHINE SCREWS Table 6. American National Standard Slotted Pan Head Machine Screws ANSI B18.6.3-1972 (R1991)
Head Dia., A
Nominal Sizea or Basic Screw Dia. 0000 000 00 0 1 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
0.0210 0.0340 0.0470 0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500
Max.
Min.
Head Height, H Max. Min.
.042 .066 .090 .116 .142 .167 .193 .219 .245 .270 .322 .373 .425 .492 .615 .740 .863 .987 1.041 1.172 1.435
.036 .060 .082 .104 .130 .155 .180 .205 .231 .256 .306 .357 .407 .473 .594 .716 .837 .958 1.000 1.125 1.375
.016 .023 .032 .039 .046 .053 .060 .068 .075 .082 .096 .110 .125 .144 .178 .212 .247 .281 .315 .350 .419
.010 .017 .025 .031 .038 .045 .051 .058 .065 .072 .085 .099 .112 .130 .162 .195 .228 .260 .293 .325 .390
Head Radius, R Max. .007 .010 .015 .020 .025 .035 .037 .042 .044 .046 .052 .061 .078 .087 .099 .143 .153 .175 .197 .219 .263
Slot Width, J Max. Min.
Slot Depth, T Max. Min.
.008 .012 .017 .023 .026 .031 .035 .039 .043 .048 .054 .060 .067 .075 .084 .094 .094 .106 .118 .133 .149
.008 .012 .016 .022 .027 .031 .036 .040 .045 .050 .058 .068 .077 .087 .106 .124 .142 .161 .179 .197 .234
.004 .008 .010 .016 .019 .023 .027 .031 .035 .039 .045 .050 .056 .064 .072 .081 .081 .091 .102 .116 .131
.004 .008 .010 .014 .018 .022 .026 .030 .034 .037 .045 .053 .061 .070 .085 .100 .116 .131 .146 .162 .192
a Where specifying nominal size in decimals, zeros preceding decimal and in the fourth decimal place are omitted.
All dimensions are in inches.
Table 7. Nos. 0000, 000 and 00 Threads ANSI B18.6.3-1972 (R1991) Appendix Series Designat.
Class
Externalb
Nominal Sizea and Threads Per Inch 0000-160 or 0.0210-160
NS
2
.0210 .0195 .0169 .0158
000-120 or 0.0340-120
NS
2
00-90 or 0.0470-90
NS
00-96 or 0.0470-96
NS
Internalc
Pitch Diameter
Minor Dia.
Class
Major Diameter
.0011
.0128
.0340 .0325 .0286 0.272
.0014
2
.0470 .0450 .0398 .0382
2
.0470 .0450 .0402 .0386
Max.
Min.
Max.
Min.
Tol.
Pitch Diameter
Major Dia.
Min.
Max.
Tol.
Min.
2
.0169
.0181
.0012
.0210
.0232
2
.0286
.0300
.0014
.034
.0016
.0326
2
.0398
.0414
.0016
.047
.0016
.0334
2
.0402
.0418
.0016
.047
a Where
specifying nominal size in decimals, zeros preceding decimal and in the fourth decimal place are omitted. b There is no allowance provided on the external threads. c The minor diameter limits for internal threads are not specified, they being determined by the amount of thread engagement necessary to satisfy the strength requirements and tapping performance in the intended application. All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINE SCREWS
1593
Table 8. American National Standard Slotted Fillister and Slotted Drilled Fillister Head Machine Screws ANSI B18.6.3-1972 (R1991)
SLOTTED FILLISTER HEAD TYPE
0000 000 00 0 1 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
Head Side Height, H
Head Dia., A
Nominal Size1 or Basic Screw Dia.
Total Head Height, O
Slot Width, J
Slot Depth, T
Max.
Min.
Max.
Min.
Max.
Min.
Max
Min.
Max.
Min.
0.0210 0.0340 0.0470 0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500
.038 .059 .082 .096 .118 .140 .161 .183 .205 .226 .270 .313 .357 .414
.032 .053 .072 .083 .104 .124 .145 .166 .187 .208 .250 .292 .334 .389
.019 .029 .037 .043 .053 .062 .070 .079 .088 .096 .113 .130 .148 .170
.011 .021 .028 .038 .045 .053 .061 .069 .078 .086 .102 .118 .134 .155
.025 .035 .047 .055 .066 .083 .095 .107 .120 .132 .156 .180 .205 .237
.15 .027 .039 .047 .058 .066 .077 .088 .100 .111 .133 .156 .178 .207
.008 .012 .017 .023 .026 .031 .035 .039 .043 .048 .054 .060 .067 .075
.004 .006 .010 .016 .019 .023 .027 .031 .035 .039 .045 .050 .056 .064
.012 .017 .022 .025 .031 .037 .043 .048 .054 .060 .071 .083 .094 .109
.006 .011 .015 .015 .020 .025 .030 .035 .040 .045 .054 .064 .074 .087
0.3125
.518
.490
.211
.194
.295
.262
.084
.072
.137
.110
0.3750
.622
.590
.253
.233
.355
.315
.094
.081
.164
.133
0.4375
.625
.589
.265
.242
.368
.321
.094
.081
.170
.135
0.5000
.750
.710
.297
.273
.412
.362
.106
.091
.190
.151
0.5625
.812
.768
.336
.308
.466
.410
.118
.102
.214
.172
0.6250
.875
.827
.375
.345
.521
.461
.133
.116
.240
.193
0.7500
1.000
.945
.441
.406
.612
.542
.149
.131
.281
.226
Drilled Hole Locat., E
Drilled Hole. Dia., F
SLOTTED DRILLED FILLISTER HEAD TYPE Nominal Size1 or Basic Screw Dia. 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8
Head Dia., A
Head Side Height, H
Total Head Height, O
Slot Width, J
Slot Depth, T
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Basic
Basic
0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500
.140 .161 .183 .205 .226 .270 .313 .357 .414
.124 .145 .166 .187 .208 .250 .292 .334 .389
.062 .070 .079 .088 .096 .113 .130 .148 .170
.055 .064 .072 .081 .089 .106 .123 .139 .161
.083 .095 .107 .120 .132 .156 .180 .205 .237
.070 .082 .094 .106 .118 .141 .165 .188 .219
.031 .035 .039 .043 .048 .054 .060 .067 .075
.023 .027 .031 .035 .039 .045 .050 .056 .064
.030 .034 .038 .042 .045 .065 .075 .087 .102
.022 .026 .030 .033 .035 .054 .064 .074 .087
.026 .030 .035 .038 .043 .043 .043 .053 .062
.031 .037 .037 .046 .046 .046 .046 .046 .062
0.3125
.518
.490
.211
.201
.295
.276
.084
.072
.130
.110
.078
.070
0.3750
.622
.590
.253
.242
.355
.333
.094
.081
.154
.134
.094
.070
All dimensions are in inches. 1Where specifying nominal size in decimals, zeros preceding decimal points and in the fourth decimal place are omitted. 2Drilled hole shall be approximately perpendicular to the axis of slot and may be permitted to break through bottom of the slot. Edges of the hole shall be free from burrs. 3A slight rounding of the edges at periphery of head is permissible provided the diameter of the bearing circle is equal to no less than 90 per cent of the specified minimum head diameter.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1594
MACHINE SCREWS Table 9. American National Standard Slotted Oval Countersunk Head Machine Screws ANSI B18.6.3-1972 (R1991)
Max Lb
Nominal Sizea or Basic Screw Dia. 00 0 1 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
0.0470 0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500
… 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 … … …
Head Dia., A Min., Edge Rnded. or Flat
Head Side Height, H,
Max., Edge Sharp .093 .119 .146 .172 .199 .225 .252 .279 .332 .385 .438 .507 .635 .762 .812 .875 1.000 1.125 1.375
.085 .099 .123 .147 .171 .195 .220 .244 .292 .340 .389 .452 .568 .685 .723 .775 .889 1.002 1.230
Total Head Height, O
Slot Width, J
Slot Depth, T
Ref.
Max.
Min.
Max.
Min.
Max.
Min.
.028 .035 .043 .051 .059 .067 .075 .083 .100 .116 .132 .153 .191 .230 .223 .223 .260 .298 .372
.042 .056 .068 .080 .092 .104 .116 .128 .152 .176 .200 .232 .290 .347 .345 .354 .410 .467 .578
.034 .041 .052 .063 .073 .084 .095 .105 .126 .148 .169 .197 .249 .300 .295 .299 .350 .399 .497
.017 .023 .026 .031 .035 .039 .043 .048 .054 .060 .067 .075 .084 .094 .094 .106 .118 .133 .149
.010 .016 .019 .023 .027 .031 .035 .039 .045 .050 .056 .064 .072 .081 .081 .091 .102 .116 .131
.023 .030 .038 .045 .052 .059 .067 .074 .088 .103 .117 .136 .171 .206 .210 .216 .250 .285 .353
.016 .025 .031 .037 .043 .049 .055 .060 .072 .084 .096 .112 .141 .170 .174 .176 .207 .235 .293
a When specifying nominal size in decimals, zeros preceding decimal points and in the fourth decimal place are omitted. b These lengths or shorter are undercut. All dimensions are in inches.
Table 10. American National Standard Header Points for Machine Screws before Threading ANSI B18.6.3-1972 (R1991) Nom. Size
Threads per Inch
Max. P
Min. P
24
0.125
0.112
32
0.138
0.124
24 28 20 28 18 24 16 24 14 20 13 20
0.149 0.156 0.170 0.187 0.221 0.237 0.270 0.295 0.316 0.342 0.367 0.399
0.134 0.141 0.153 0.169 0.200 0.215 0.244 0.267 0.287 0.310 0.333 0.362
11⁄4
10 Nom. Size. 2 4 5 6 8
Threads per Inch 56 64 40 48 40 44 32 40 32 36
Max. P 0.057 0.060 0.074 0.079 0.086 0.088 0.090 0.098 0.114 0.118
Min. P 0.050 0.053 0.065 0.070 0.076 0.079 0.080 0.087 0.102 0.106
Max. L
12
1⁄ 2
1⁄ 4
1⁄ 2
5⁄ 16
1⁄ 2
3⁄ 8
3⁄ 4
7⁄ 16
1
1⁄ 2
Max. L
13⁄8 11⁄2 11⁄2 11⁄2 11⁄2 11⁄2
All dimensions in inches. Edges of point may be rounded and end of point need not be flat nor perpendicular to shank. Machine screws normally have plain sheared ends but when specified may have header points, as shown above.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINE SCREWS
1595
Table 11. American National Standard Slotted Binding Head and Slotted Undercut Oval Countersunk Head Machine Screws ANSI B18.6.3-1972 (R1991)
Nominal Sizea or Basic Screw Dia. 0000 000 00 0 1 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8
0.0210 0.0340 0.0470 0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500 0.3125 0.3750
SLOTTED BINDING HEAD TYPE Slot Head Oval Width, Height, J F Max. Min. Max. Min.
Slot Depth, T Max. Min.
Undercutb Dia., U Max. Min.
Undercutb Depth, X Max. Min.
.009 .015 .023 .026 .035 .043 .052 .061 .069 .078 .095 .112 .130 .152 .194 .235
.009 .013 .018 .018 .024 .030 .036 .042 .048 .053 .065 .077 .089 .105 .134 .163
… … … .098 .120 .141 .162 .184 .205 .226 .269 .312 .354 .410 .513 .615
… … … .007 .008 .010 .011 .012 .014 .015 .017 .020 .023 .026 .032 .039
Head Dia., A Max. Min.
Total Head Height, O Max. Min.
.046 .073 .098 .126 .153 .181 .208 .235 .263 .290 .344 .399 .454 .525 .656 .788
.014 .021 .028 .032 .041 .050 .059 .068 .078 .087 .105 .123 .141 .165 .209 .253
.040 .067 .090 .119 .145 .171 .197 .223 .249 .275 .326 .378 .430 .498 .622 .746
.006 .008 .011 .012 .015 .018 .022 .025 .029 .032 .039 .045 .052 .061 .077 .094
.003 .005 .007 .008 .011 .013 .016 .018 .021 .024 .029 .034 .039 .046 .059 .071
.008 .012 .017 .023 .026 .031 .035 .039 .043 .048 .054 .060 .067 .075 .084 .094
.004 .006 .010 .016 .019 .023 .027 .031 .035 .039 .045 .050 .056 .064 .072 .081
.005 .009 .012 .009 .014 .020 .025 .030 .035 .040 .050 .060 .070 .084 .108 .132
… … … .086 .105 .124 .143 .161 .180 .199 .236 .274 .311 .360 .450 .540
… … … .002 .003 .005 .006 .007 .009 .010 .012 .015 .018 .021 .027 .034
a Where specifying nominal size in decimals, zeros preceding decimal points and in the fourth decimal place are omitted. b Unless otherwise specified, slotted binding head machine screws are not undercut.
Nominal Sizea or Basic Screw Dia. 0
0.0600
1
0.0730
2
0.0860
3
0.0990
4
0.1120
5
0.1250
6
0.1380
8
0.1640
10
0.1900
12
0.2160
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2
0.2500 0.3125 0.3750 0.4375 0.5000
SLOTTED UNDERCUT OVAL COUNTERSUNK HEAD TYPES Total Head Dia., Head Head Slot A Side Height, Width, Height, Min., O J H Edge Max., Max. Rnded. Edge or Flat Ref. Max. Min. Max. Min. Sharp La 1⁄ 8 1⁄ 8 1⁄ 8 1⁄ 8 3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
Slot Depth, T Max.
Min.
.119
.099
.025
.046
.033
.023
.016
.028
.022
.146
.123
.031
.056
.042
.026
.019
.034
.027
.172
.147
.036
.065
.050
.031
.023
.040
.033
.199
.171
.042
.075
.059
.035
.027
.047
.038
.225
.195
.047
.084
.067
.039
.031
.053
.043
.252
.220
.053
.094
.076
.043
.035
.059
.048
.279
.244
.059
.104
.084
.048
.039
.065
.053
.332
.292
.070
.123
.101
.054
.045
.078
.064
.385
.340
.081
.142
.118
.060
.050
.090
.074
.438
.389
.092
.161
.135
.067
.056
.103
.085
.507
.452
.107
.186
.158
.075
.064
.119
.098
.635
.568
.134
.232
.198
.084
.072
.149
.124
.762
.685
.161
.278
.239
.094
.081
.179
.149
.812
.723
.156
.279
.239
.094
.081
.184
.154
.875
.775
.156
.288
.244
.106
.091
.204
.169
a These lengths or shorter are undercut.
All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1596
MACHINE SCREWS Table 12. Slotted Round Head Machine Screws ANSI B18.6.3-1972 (R1991) Appendix
Nominal Sizea or Basic Screw Dia. 0000 000 00 0 1 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
0.0210 0.0340 0.0470 0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500
Head Diameter, A Min. .035 .056 .080 .099 .122 .146 .169 .193 .217 .240 .287 .334 .382 .443 .557 .670 .707 .766 .887 .944 1.185
Max. .041 .062 .089 .113 .138 .162 .187 .211 .236 .260 .309 .359 .408 .472 .590 .708 .750 .813 .938 1.000 1.250
Head Height, H Min. .016 .025 .036 .043 .051 .059 .067 .075 .083 .091 .107 .123 .139 .160 .198 .237 .307 .332 .385 .411 .516
Max. .022 .031 .045 .053 .061 .069 .078 .086 .095 .103 .120 .137 .153 .175 .216 .256 .328 .355 .410 .438 .547
Slot Width, J Min. .004 .008 .010 .016 .019 .023 .027 .031 .035 .039 .045 .050 .056 .064 .072 .081 .081 .091 .102 .116 .131
Max. .008 .012 .017 .023 .026 .031 .035 .039 .043 .048 .054 .060 .067 .075 .084 .094 .094 .106 .118 .133 .149
Slot Depth, T Min. .013 .012 .018 .029 .033 .037 .040 .044 .047 .051 .058 .065 .073 .082 .099 .117 .148 .159 .183 .195 .242
Max. .017 .018 .026 .039 .044 .048 .053 .058 .063 .068 .077 .087 .096 .109 .132 .155 .196 .211 .242 .258 .320
a When specifying nominal size in decimals, zeros preceding decimal point and in the fourth decimal place are omitted.
All dimensions are in inches. Not recommended, use Pan Head machine screws.
ANSI Cross References for Machine Screws and Metric Machine Screw
Type I Cross Recess
Type IA Cross Recess
Type II Cross Recess
Type III Square Center
Machine Screw Cross Recesses.—Four cross recesses, Types I, IA, II, and III, may be used in lieu of slots in machine screw heads. Dimensions for recess diameter M, width N, and depth T (not shown above) together with recess penetration gaging depths are given in American National Standard ANSI B18.6.3-1972 (R1991) for machine screws, and in ANSI/ASME B18.6.7M-1985 for metric machine screws. American National Standard Metric Machine Screws.—This Standard B18.6.7M covers metric flat and oval countersunk and slotted and recessed pan head machine screws and metric hex head and hex flange head machine screws. Dimensions are given in Tables 1 through 4 and 6.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINE SCREWS
1597
Table 1. American National Standard Thread Lengths for Metric Machine Screws ANSI/ASME B18.6.7M-1985
Pan, Hex, and Hex Flange Head Screws L
LUS
Flat and Oval Countersunk Head Screws LU
LUS
L Nominal Screw Lengtha
Heat-Treated Recessed Flat Countersunk Head Screws LU L
L
Nominal Screw Size and Thread Pitch
Nominal Screw Length Equal to or Shorter thana
Maxd
Maxe
Over
To and Including
Maxd
Maxe
Nominal Screw Length Longer thana
M2 × 0.4 M2.5 × 0.45 M3 × 0.5 M3.5 × 0.6 M4 × 0.7 M5 × 0.8 M6 × 1 M8 × 1.25 M10 × 1.5 M12 × 1.75
6 8 9 10 12 15 18 24 30 36
1.0 1.1 1.2 1.5 1.8 2.0 2.5 3.1 3.8 4.4
0.4 0.5 0.5 0.6 0.7 0.8 1.0 1.2 1.5 1.8
6 8 9 10 12 15 18 24 30 36
30 30 30 50 50 50 50 50 50 50
1.0 1.1 1.2 1.5 1.8 2.0 2.5 3.1 3.8 4.4
0.8 0.9 1.0 1.2 1.4 1.6 2.0 2.5 3.0 3.5
30 30 30 50 50 50 50 50 50 50
Unthreaded Lengthb
Unthreaded Lengthb
B Full Form Thread Lengthc
Min 25.0 25.0 25.0 38.0 38.0 38.0 38.0 38.0 38.0 38.0
a The length tolerances for metric machine screws are: up to 3 mm, incl., ± 0.2 mm; over 3 to 10 mm, incl., ± 0.3 mm; over 10 to 16 mm, incl., ± 0.4 mm; over 16 to 50 mm, incl., ± 0.5 mm; over 50 mm, ± 1.0 mm. b Unthreaded lengths L and L U US represent the distance, measured parallel to the axis of screw, from the underside of the head to the face of a nonchamfered or noncounterbored standard GO thread ring gage assembled by hand as far as the thread will permit. c Refer to the illustrations for respective screw head styles. d The L US values apply only to heat treated recessed flat countersunk head screws. e The L values apply to all screws except heat treated recessed flat countersunk head screws. U All dimensions in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Slotted and Style A
Body Diameter
Body and Shoulder Diameter
LSHa
DS Shoulder Diameter
Body Diameter
DK
K
Head Diameter Shoulder Length
Theoretical Sharp
Actual
Head Height
Max
Min
Max
Min
Min
Max
Min
Max
Min
Min
Max Ref
M2 × 0.4b
2.00
1.65
2.00
1.86
1.65
0.50
0.30
4.4
4.1
3.5
1.2
M2.5 × 0.45
2.50
2.12
2.50
2.36
2.12
0.55
0.35
5.5
5.1
4.4
1.5
R
N
Underhead Fillet Radius
T
Slot Width
Slot Depth
Max
Min
Max
Min
Max
0.8
0.4
0.7
0.5
0.6
Min 0.4
1.0
0.5
0.8
0.6
0.7
0.5
M3 × 0.5
3.00
2.58
3.00
2.86
2.58
0.60
0.40
6.3
5.9
5.2
1.7
1.2
0.6
1.0
0.8
0.9
0.6
M3.5 × 0.6
3.50
3.00
3.50
3.32
3.00
0.70
0.50
8.2
7.7
6.9
2.3
1.4
0.7
1.2
1.0
1.2
0.9
M4 × 0.7
4.00
3.43
4.00
3.82
3.43
0.80
0.60
9.4
8.9
8.0
2.7
1.6
0.8
1.5
1.2
1.3
1.0
M5 × 0.8
5.00
4.36
5.00
4.82
4.36
0.90
0.70
10.4
9.8
8.9
2.7
2.0
1.0
1.5
1.2
1.4
1.1
M6 × 1
6.00
5.21
6.00
5.82
5.21
1.10
0.90
12.6
11.9
10.9
3.3
2.4
1.2
1.9
1.6
1.6
1.2
M8 × 1.25
8.00
7.04
8.00
7.78
7.04
1.40
1.10
17.3
16.5
15.4
4.6
3.2
1.6
2.3
2.0
2.3
1.8
M10 × 1.5
10.00
8.86
10.00
9.78
8.86
1.70
1.30
20.0
19.2
17.8
5.0
4.0
2.0
2.8
2.5
2.6
2.0
a All
recessed head heat-treated steel screws of property class 9.8 or higher strength have the Style B head form. Recessed head screws other than those specifically designated to be Style B have the Style A head form. The underhead shoulder on the Style B head form is mandatory and all other head dimensions are common to both the Style A and Style B head forms. b This size is not specified for Type III square recessed flat countersunk heads; Type II cross recess is not specified for any size. All dimensions in millimeters. For dimension B, see Table 1. For dimension L, see Table 7.
Copyright 2004, Industrial Press, Inc., New York, NY
MACHINE SCREWS
Nominal Screw Size and Thread Pitch
Style B DSHa
DS
1598
Table 2. American National Standard Slotted, Cross and Square Recessed Flat Countersunk Head Metric Machine Screws ANSI/ASME B18.6.7M-1985
Machinery's Handbook 27th Edition
Table 3. American National Standard Slotted, Cross and Square Recessed Oval Countersunk Head Metric Machine Screws ANSI/ASME B18.6.7M-1985
DK
K
F
RF
R
N
T
Actual
Head Side Height
Raised Head Height
Head Top Radius
Underhead Fillet Radius
Slot Width
Slot Depth
Head Diameter Theoretical Sharp
Body Diameter Min
Max
Min
Min
Max Ref
Max
Approx
Max
Min
Max
Min
Max
M2 × 0.4a
2.00
1.65
4.4
4.1
3.5
1.2
0.5
5.0
0.8
0.4
0.7
0.5
1.0
0.8
M2.5 × 0.45
2.50
2.12
5.5
4.4
1.5
0.6
6.6
1.0
0.5
0.8
0.6
1.2
1.0
Max
5.1
Min
M3 × 0.5
3.00
2.58
6.3
5.9
5.2
1.7
0.7
7.4
1.2
0.6
1.0
0.8
1.5
1.2
M3.5 × 0.6
3.50
3.00
8.2
7.7
6.9
2.3
0.8
10.9
1.4
0.7
1.2
1.0
1.7
1.4
M4 × 0.7
4.00
3.43
9.4
8.9
8.0
2.7
1.0
11.6
1.6
0.8
1.5
1.2
1.9
1.6
M5 × 0.8
5.00
4.36
10.4
9.8
8.9
2.7
1.2
11.9
2.0
1.0
1.5
1.2
2.4
2.0
M6 × 1
6.00
5.21
12.6
11.9
10.9
3.3
1.4
14.9
2.4
1.2
1.9
1.6
2.8
2.4
M8 × 1.25
8.00
7.04
17.3
16.5
15.4
4.6
2.0
19.7
3.2
1.6
2.3
2.0
3.7
3.2
M10 × 1.5
10.00
8.86
20.0
19.2
17.8
5.0
2.3
22.9
4.0
2.0
2.8
2.5
4.4
3.8
MACHINE SCREWS
DS Nominal Screw Size and Thread Pitch
a This size is not specified for Type III square recessed oval countersunk heads; Type II cross recess is not specified for any size.
1599
All dimensions in millimeters. For dimension B, see Table 1. For dimension L, see Table 7.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
M2 × 0.4a M2.5 × 0.45 M3 × 0.5 M3.5 × 0.6 M4 × 0.7 M5 × 0.8 M6 × 1 M8 × 1.25 M10 × 1.5
Ds
DK
R1
K
Body Diameter Max Min
Head Diameter Max Min
Head Height Max Min
2.00 2.50 3.00 3.50 4.00 5.00 6.00 8.00 10.00
4.0 5.0 5.6 7.0 8.0 9.5 12.0 16.0 20.0
1.3 1.5 1.8 2.1 2.4 3.0 3.6 4.8 6.0
1.65 2.12 2.58 3.00 3.43 4.36 5.21 7.04 8.86
3.7 4.7 5.3 6.6 7.6 9.1 11.5 15.5 19.4
1.1 1.3 1.6 1.9 2.2 2.7 3.3 4.5 5.7
Head Radius Max 0.8 1.0 1.2 1.4 1.6 2.0 2.5 3.2 4.0
R1
K Head Height Max Min 1.6 2.1 2.4 2.6 3.1 3.7 4.6 6.0 7.5
1.4 1.9 2.2 2.3 2.8 3.4 4.3 5.6 7.1
Head Radius Ref 3.2 4.0 5.0 6.0 6.5 8.0 10.0 13.0 16.0
DA
R Underhead Fillet Transition Dia Radius Max Min 2.6 3.1 3.6 4.1 4.7 5.7 6.8 9.2 11.2
a This size not specified for Type III square recessed pan heads; Type II cross recess is not specified for any size.
All dimensions in millimeters. For dimension B, see Table 1. For dimension L, see Table 7.
Copyright 2004, Industrial Press, Inc., New York, NY
0.1 0.1 0.1 0.1 0.2 0.2 0.3 0.4 0.4
N Slot Width Max Min 0.7 0.8 1.0 1.2 1.5 1.5 1.9 2.3 2.8
0.5 0.6 0.8 1.0 1.2 1.2 1.6 2.0 2.5
T
W
Slot Depth Min
Unslotted Head Thickness Min
0.5 0.6 0.7 0.8 1.0 1.2 1.4 1.9 2.4
0.4 0.5 0.7 0.8 0.9 1.2 1.4 1.9 2.4
MACHINE SCREWS
Cross and Square Recess
Slotted Nominal Screw Size and Thread Pitch
1600
Table 4. American National Standard Slotted and Cross and Square Recessed Pan Head Metric Machine Screws ANSI/ASME B18.6.7M-1985
Machinery's Handbook 27th Edition METRIC MACHINE SCREWS
1601
Table 5. American National Standard Header Points for Metric Machine Screws Before Threading ANSI/ASME B18.6.7M-1985
Nominal Screw Size and Thread Pitch M2 × 0.4 M2.5 × 0.45 M3 × 0.5 M3.5 × 0.6 M4 × 0.7 M5 × 0.8 M6 × 1 M8 × 1.25 M10 × 1.5 M12 × 1.75
DP Point Diameter Max 1.33 1.73 2.12 2.46 2.80 3.60 4.25 5.82 7.36 8.90
Min 1.21 1.57 1.93 2.24 2.55 3.28 3.85 5.30 6.71 8.11
La Nominal Screw Length Max 13 13 16 20 25 30 40 40 40 45
a Header points apply to these nominal lengths or shorter. The pointing of longer lengths may require machining to the dimensions specified.
All dimensions in millimeters. The edge of the point may be rounded and the end of point need not be flat nor perpendicular to the axis of screw shank.
Threads: Threads for metric machine screws are coarse M profile threads, as given in ANSI B1.13M (see page 1783), unless otherwise specified. Length of Thread: The lengths of threads on metric machine screws are given in Table 1 for the applicable screw type, size, and length. Diameter of Body: The body diameters of metric machine screws are within the limits specified in the dimensional tables (Tables 3 through 4 and 6). Designation: Metric machine screws are designated by the following data in the sequence shown: Nominal size and thread pitch; nominal length; product name, including head type and driving provision; header point if desired; material (including property class, if steel); and protective finish, if required. For example: M8 × 1.25 × 30 Slotted Pan Head Machine Screw, Class 4.8 Steel, Zinc Plated M3.5 × 0.6 × 20 Type IA Cross Recessed Oval Countersunk Head Machine Screw, Header Point, Brass It is common ISO practice to omit the thread pitch from the product size designation when screw threads are the metric coarse thread series, e.g., M10 stands for M10 × 1.5.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
1602
Table 6. American National Standard Hex and Hex Flange Head Metric Machine Screws ANSI/ASME B18.6.7M-1985 Hex Head
M2 × 0.4 M2.5 × 0.45 M3 × 0.5 M3.5 × 0.6 M4 × 0.7 M5 × 0.8 M6 × 1 M8 × 1.25 M10 × 1.5 M12 × 1.75 M10 × 1.5b
Sa
Ea
Hex Width Across Flats
Body Diameter
DA
K
R Underhead Fillet
Hex Width Across Corners
Head Height
Transition Dia
Radius
Max
Min
Max
Min
Min
Max
Min
Max
Min
2.00 2.50 3.00 3.50 4.00 5.00 6.00 8.00 10.00 12.00 10.00
1.65 2.12 2.58 3.00 3.43 4.36 5.21 7.04 8.86 10.68 8.86
3.20 4.00 5.00 5.50 7.00 8.00 10.00 13.00 16.00 18.00 15.00
3.02 3.82 4.82 5.32 6.78 7.78 9.78 12.73 15.73 17.73 14.73
3.38 4.28 5.40 5.96 7.59 8.71 10.95 14.26 17.62 19.86 16.50
1.6 2.1 2.3 2.6 3.0 3.8 4.7 6.0 7.5 9.0 7.5
1.3 1.8 2.0 2.3 2.6 3.3 4.1 5.2 6.5 7.8 6.5
2.6 3.1 3.6 4.1 4.7 5.7 6.8 9.2 11.2 13.2 11.2
0.1 0.1 0.1 0.1 0.2 0.2 0.3 0.4 0.4 0.4 0.4
a Dimensions across flats and across corners of the head are measured at the point of maximum metal. Taper of sides of head (angle between one side and the axis) shall
not exceed 2° or 0.10 mm, whichever is greater, the specified width across flats being the large dimension. b The M10 size screws having heads with 15 mm width across flats are not ISO Standard. Unless M10 size screws with 15 mm width across flats are specifically ordered, M10 size screws with 16 mm width across flats shall be furnished.
Copyright 2004, Industrial Press, Inc., New York, NY
METRIC MACHINE SCREWS
DS Nominal Screw Size and Thread Pitch
Machinery's Handbook 27th Edition
Table 6. (Continued) American National Standard Hex and Hex Flange Head Metric Machine Screws ANSI/ASME B18.6.7M-1985 Hex Flange Head
Max
Min
Max
Min
Hex Width Across Corners, Ea Min
M2 × 0.4 M2.5 × 0.45 M3 × 0.5 M3.5 × 0.6 M4 × 0.7 M5 × 0.8 M6 × 1 M8 × 1.25 M10 × 1.5 M12 × 1.75
2.00 2.50 3.00 3.50 4.00 5.00 6.00 8.00 10.00 12.00
1.65 2.12 2.58 3.00 3.43 4.36 5.21 7.04 8.86 10.68
3.00 3.20 4.00 5.00 5.50 7.00 8.00 10.00 13.00 15.00
2.84 3.04 3.84 4.82 5.32 6.78 7.78 9.78 12.72 14.72
3.16 3.39 4.27 5.36 5.92 7.55 8.66 10.89 14.16 16.38
Hex Width Across Flats, Sa
Hex Height, K1 Min,
Flange Edge Thickness, Cb Min
Flange Top Fillet Radius, R1 Max
Max Transition Dia, DA
Min Radius, R
1.3 1.6 1.9 2.4 2.8 3.5 4.2 5.6 7.0 8.4
0.3 0.3 0.4 0.5 0.6 0.7 1.0 1.2 1.4 1.8
0.1 0.2 0.2 0.2 0.2 0.3 0.4 0.5 0.6 0.7
2.6 3.1 3.6 4.1 4.7 5.7 6.8 9.2 11.2 13.2
0.1 0.1 0.1 0.1 0.2 0.2 0.3 0.4 0.4 0.4
Flange Diameter, DC
Max
Min
Overall Head Height, K
4.5 5.4 6.4 7.5 8.5 10.6 12.8 16.8 21.0 24.8
4.1 5.0 5.9 6.9 7.8 9.8 11.8 15.5 19.3 23.3
2.2 2.7 3.2 3.8 4.3 5.4 6.7 8.6 10.7 13.7
Underhead Fillet
Copyright 2004, Industrial Press, Inc., New York, NY
1603
a Dimensions across flats and across corners of the head are measured at the point of maximum metal. Taper of sides of head (angle between one side and the axis) shall not exceed 2° or 0.10 mm, whichever is greater, the specified width across flats being the large dimension. b The contour of the edge at periphery of flange is optional provided the minimum flange thickness is maintained at the minimum flange diameter. The top surface of flange may be straight or slightly rounded (convex) upward. All dimensions in millimeters. A slight rounding of all edges of the hexagon surfaces of indented hex heads is permissible provided the diameter of the bearing circle is not less than the equivalent of 90 per cent of the specified minimum width across flats dimension. Heads may be indented, trimmed, or fully upset at the option of the manufacturer. For dimension B, see Table 1. For dimension L, see Table 7.
METRIC MACHINE SCREWS
Body Diameter, DS
Nominal Screw Size and Thread Pitch
Machinery's Handbook 27th Edition 1604
MACHINE SCREWS
Table 7. Recommended Nominal Screw Lengths for Metric Machine Screws Nominal Screw Length 2.5 3 4 5 6 8 10 13 16 20 25 30 35 40 45 50 55 60 65 70 80 90
Nominal Screw Size M2 PH A A A A A A A A A
M2.5
M3
PH A A A A A A A A A
PH A A A A A A A A A
M3.5
M4
PH A A A A A A A A A
PH A A A A A A A A A A
M5
PH A A A A A A A A A A A
M6
A A A A A A A A A A A A A
M8
A A A A A A A A A A A A A A A
M10
M12
A A A A A A A A A A A A A A A
H H H H H H H H H H H H H H
All dimensions in millimeters. 1The nominal screw lengths included between the heavy lines are recommended for the respective screw sizes and screw head styles as designated by the symbols. A — Signifies screws of all head styles covered in this standard. P — Signifies pan head screws. H — Signifies hex and hex flange head screws.
Table 8. Clearance Holes for Metric Machine Screws ANSI/ASME B18.6.7M-1985 Appendix Nominal Screw Size M2 M2.5 M3 M3.5 M4 M5 M6 M8 M10 M12
Close Clearanceb 2.20 2.70 3.20 3.70 4.30 5.30 6.40 8.40 10.50 13.00
Basic Clearance Hole Diametera Normal Clearance (Preferred)b 2.40 2.90 3.40 3.90 4.50 5.50 6.60 9.00 11.00 13.50
Loose Clearanceb 2.60 3.10 3.60 4.20 4.80 5.80 7.00 10.00 12.00 14.50
a The values given in this table are minimum limits. The recommended plus tolerances are as follows: for clearance hole diameters over 1.70 to and including 5.80 mm, plus 0.12, 0.20, and 0.30 mm for close, normal, and loose clearances, respectively; for clearance hole diameters over 5.80 to 14.50 mm, plus 0.18, 0.30, and 0.45 mm for close, normal, and loose clearances, respectively. b Normal clearance hole sizes are preferred. Close clearance hole sizes are for situations such as critical alignment of assembled components, wall thickness, or other limitations which necessitate the use of a minimal hole. Countersinking or counterboring at the fastener entry side may be necessary for the proper seating of the head. Loose clearance hole sizes are for applications where maximum adjustment capability between the components being assembled is necessary.
All dimensions in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINE SCREWS
1605
British Machine Screws.—Many of these classifications of fasteners are covered in British Standards B.S. 57:1951, “B.A. Screws, Bolts and Nuts”; BS 450:1958 (obsolescent), “Machine Screws and Machine Screw Nuts (BSW and BSF Threads)”; B.S. 1981:1953, “Unified Machine Screws and Machine Screw Nuts”; BS 2827:1957 (obsolescent):1957, “Machine Screw Nuts, Pressed Type (B.A. and Whitworth Form Threads)”; B.S. 3155:1960, “American Machine Screws and Nuts in Sizes Below 1⁄4 inch Diameter”; and BS 4183:1967 (obsolescent), “Machine Screws and Machine Screw Nuts, Metric Series.” At a conference organized by the British Standards Institution in 1965 at which the major sectors of British industry were represented, a policy statement was approved that urged British firms to regard the traditional screw thread systems—Whitworth, B.A. and BSF— as obsolescent, and to make the internationally-agreed ISO metric thread their first choice (with ISO Unified thread as second choice) for all future designs. It is recognized that some sections of British industry already using ISO inch (Unified) screw threads may find it necessary, for various reasons, to continue with their use for some time: Whitworth and B.A. threads should, however, be superseded by ISO metric threads in preference to an intermediate change to ISO inch threads. Fasteners covered by B.S. 57, B.S. 450 and BS 2827:1957 (obsolescent) eventually would be superseded and replaced by fasteners specified by B.S. 4183. British Standard Whitworth (BSW) and Fine (BSF) Machine Screws.—British Standard BS 450:1958 (obsolescent) covers machine screws and nuts with British Standard Whit-worth and British Standard Fine threads. All the various heads in common use in both slotted and recessed forms are covered. Head shapes are shown on page 1614 and dimensions on page 1617. It is intended that this standard will eventually be superseded by B.S. 4183, “Machine Screws and Machine Screw Nuts, Metric Series.” British Standard Machine Screws and Machine Screw Nuts, Metric Series.—British Standard BS 4183:1967 (obsolescent) gives dimensions and tolerances for: countersunk head, raised countersunk head, and cheese head slotted head screws in a diameter range from M1 (1 mm) to M20 (20 mm); pan head slotted head screws in a diameter range from M2.5 (2.5 mm) to M10 (10 mm); countersunk head and raised countersunk head recessed head screws in a diameter range from M2.5 (2.5 mm) to M12 (12 mm); pan head recessed head screws in a diameter range from M2.5 (2.5 mm) to M10 (10 mm); and square and hexagon machine screw nuts in a diameter range from M1.6 (1.6 mm) to M10 (10 mm). Mechanical properties are also specified for steel, brass and aluminum alloy machine screws and machine screw nuts in this standard. Material: The materials from which the screws and nuts are manufactured have a tensile strength not less than the following: steel, 40 kgf/mm2 (392 N/mm2); brass, 32 kgf/mm2 (314 N/mm2); and aluminum alloy, 32 kgf/mm2 (314 N/mm2). The unit, kgf/mm2 is in accordance with ISO DR 911 and the unit in parentheses has the relationship, 1 kgf = 9.80665 Newtons. These minimum strengths are applicable to the finished products. Steel machine screws conform to the requirements for strength grade designation 4.8. The strength grade designation system for machine screws consists of two figures, the first is 1⁄10 of the minimum tensile strength in kgf/mm2, the second is 1⁄10 of the ratio between the yield stress and the minimum tensile strength expressed as a percentage: 1⁄10 minimum tensile yield stress strength of 40 kgf/mm2 gives the symbol “4”; 1⁄10 ratio ------------------------------------------------------------ % = 1⁄10 × minimum tensile strength 32⁄ × 100⁄1 = “8”; giving the strength grade designation “4.8.” Multiplication of these two 40 figures gives the minimum yield stress in kgf/mm2. Coating of Screws and Nuts: It is recommended that the coating comply with the appropriate part of BS 3382. “Electroplated Coatings on Threaded Components.”
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1606
MACHINE SCREWS
Screw Threads: Screw threads are ISO metric coarse pitch series threads in accordance with B.S. 3643. “ISO Metric Screw Threads,” Part 1, “Thread Data and Standard Thread Series.” The external threads used for screws conform to tolerance Class 6g limits (medium fit) as given in B.S. 3643, “ISO Metric Screw Threads,” Part 2, “Limits and Tolerances for Coarse Pitch Series Threads.” The internal threads used for nuts conform to tolerance Class 6H limits (medium fit) as given in B.S. 3643: Part 2. Nominal Lengths of Screws: For countersunk head screws the nominal length is the distance from the upper surface of the head to the extreme end of the shank, including any chamfer, radius, or cone point. For raised countersunk head screws the nominal length is the distance from the upper surface of the head (excluding the raised portion) to the extreme end of the shank, including any chamfer, radius, or cone point. For pan and cheese head screws the nominal length is the distance from the underside of the head to the extreme end of the shank, including any chamfer, radius, or cone point. Standard nominal lengths and tolerances are given in Table 5. Lengths of Thread on Screws: The length of thread is the distance from the end of the screw (including any chamfer, radius, or cone point) to the leading face of a nut without countersink which has been screwed as far as possible onto the screw by hand. The minimum thread length is shown in the following table: Nominal Thread Dia., da
M1
M1.2
(M1.4)
M1.6
M2
(M2.2)
M2.5
M3
(M3.5)
M4
Thread Length b (Min.)
b
b
b
15
16
17
18
19
20
22
Nominal Thread Dia., da
(M4.5)
M5
M6
M8
M10
M12
(M14)
M16
(M18)
M20
Thread Length b (Min.)
24
25
28
34
40
46
52
58
64
70
a Items shown in parentheses are non-preferred. b Threaded up to the head.
All dimensions are in millimeters.
Screws of nominal thread diameter M1, M1.2 and M1.4 and screws of larger diameters that are too short for the above thread lengths are threaded as far as possible up to the head. In these screws the length of unthreaded shank under the head does not exceed 11⁄2 pitches for lengths up to twice the diameter and 2 pitches for longer lengths, and is defined as the distance from the leading face of a nut that has been screwed as far as possible onto the screw by hand to: 1) the junction of the basic major diameter and the countersunk portion of the head on countersunk and raised countersunk heads; and 2) the underside of the head on other types of heads. Diameter of Unthreaded Shank on Screws: The diameter of the unthreaded portion of the shank on screws is not greater than the basic major diameter of the screw thread and not less than the minimum effective diameter of the screw thread. The diameter of the unthreaded portion of shank is closely associated with the method of manufacture; it will generally be nearer the major diameter of the thread for turned screws and nearer the effective diameter for those produced by cold heading. Radius Under the Head of Screws: The radius under the head of pan and cheese head screws runs smoothly into the face of the head and shank without any step or discontinuity. A true radius is not essential providing that the curve is smooth and lies wholly within the maximum radius. Any radius under the head of countersunk head screws runs smoothly into the conical bearing surface of the head and the shank without any step or discontinuity. The radius values given in Tables 1 and 2 are regarded as the maximum where the shank diameter is equal to the major diameter of the thread and minimum where the shank diameter is approximately equal to the effective diameter of the thread.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 1. British Standard Slotted Countersunk Head Machine Screws—Metric Series BS 4183:1967 (obsolescent) Nominal Size da
Head Diameter D
Head Height k
Thread Length b
Thread Run-out a
Flushness Tolerancec
Min.
Max. 2pd
Max.
Max.
Min.
Max. 0.3d
Min. 0.2d
e
0.50
....
0.45
0.31
0.30
0.20
0.1
e
0.50
....
0.50
0.36
0.36
0.24
0.63
0.1
e
0.60
....
0.50
0.36
0.42
0.28
0.72 0.90 0.99 1.12 1.35 1.57 1.80 2.03 2.25 2.70 3.60 4.50 5.40 6.30 7.20 8.10 9.00
0.1 0.1 0.1 0.1 0.1 0.2 0.2 0.2 0.2 0.25 0.4 0.4 0.6 0.6 0.6 0.6 0.8
15.0 16.0 17.0 18.0 19.0 20.0 22.0 24.0 25.0 28.0 34.0 40.0 46.0 52.0 58.0 64.0 70.0
0.70 0.80 0.90 0.90 1.00 1.20 1.40 1.50 1.60 2.00 2.50 3.00 3.50 4.00 4.00 5.00 5.00
.... .... .... 0.10 0.12 0.13 0.15 0.17 0.19 0.23 0.29 0.37 0.44 0.52 0.60 0.67 0.75
0.60 0.70 0.80 0.80 1.00 1.00 1.20 1.20 1.51 1.91 2.31 2.81 3.31 3.31 4.37 4.37 5.37
0.46 0.56 0.66 0.66 0.86 0.86 1.06 1.06 1.26 1.66 2.06 2.56 3.06 3.06 4.07 4.07 5.07
0.48 0.60 0.66 0.75 0.90 1.05 1.20 1.35 1.50 1.80 2.40 3.00 3.60 4.20 4.80 5.40 6.00
0.32 0.40 0.44 0.50 0.60 0.70 0.80 0.90 1.00 1.20 1.60 2.00 2.40 2.80 3.20 3.60 4.00
Radius rb
Min. 1.75d
Max. 0.5d
Min. 0.45d
M1
2.00
1.75
0.50
0.45
0.1
M1.2
2.40
2.10
0.60
0.54
(M1.4)
2.80
2.45
0.70
M1.6 M2.0 (M2.2) M2.5 M3 (M3.5) M4 (M4.5) M5 M6 M8 M10 M12 (M14) M16 (M18) M20
3.20 4.00 4.40 5.00 6.00 7.00 8.00 9.00 10.00 12.00 16.00 20.00 24.00 28.00 32.00 36.00 40.00
2.80 3.50 3.85 4.38 5.25 6.10 7.00 7.85 8.75 10.50 14.00 17.50 21.00 24.50 28.00 31.50 35.00
0.80 1.00 1.10 1.25 1.50 1.75 2.00 2.25 2.50 3.00 4.00 5.00 6.00 7.00 8.00 9.00 10.00
Slot Width n
Slot Depth t
MACHINE SCREWS
Max. (Theor. Sharp) 2d
a Nominal sizes shown in parentheses are non-preferred. b See Radius Under the Head of Screws description in text. c See Dimensions of 90-Degree Countersunk Head Screws description in text. d See text following table in Lengths of Thread on Screws description in text. e Threaded up to head.
Copyright 2004, Industrial Press, Inc., New York, NY
1607
All dimensions are given in millimeters. For dimensional notation, see diagram on page 1610. Recessed head screws are also standard and are available. For dimensions see British Standard.
Machinery's Handbook 27th Edition
Head Diameter D
Head Height k
Thread Length b
Thread Runout a
Height of Raised Portion f
Head Radius R
Slot Width n
1608
Table 2. British Standard Slotted Raised Countersunk Head Machine Screws—Metric Series BS 4183:1967 (obsolescent) Slot Depth t
Min. 1.75d
Max. 0.5d
Min. 0.45d
Min.
Max. 2pc
Nom. 0.25d
Nom.
Max.
Min.
Max. 0.5d
Min. 0.4d
M1
2.00
1.75
0.50
0.45
0.1
d
0.50
0.25
2.0
0.45
0.31
0.50
0.40
M1.2
2.40
2.10
0.60
0.54
0.1
d
0.50
0.30
2.5
0.50
0.36
0.60
0.48
(M1.4)
2.80
2.45
0.70
0.63
0.1
d
0.60
0.35
2.5
0.50
0.36
0.70
0.56
M1.6
3.20
2.80
0.80
0.72
0.1
15.0
0.70
0.40
3.0
0.60
0.46
0.80
0.64
M2.0
4.00
3.50
1.00
0.90
0.1
16.0
0.80
0.50
4.0
0.70
0.56
1.00
0.80
(M2.2)
4.40
3.85
1.10
0.99
0.1
17.0
0.90
0.55
4.0
0.80
0.66
1.10
0.88
M2.5
5.00
4.38
1.25
1.12
0.1
18.0
0.90
0.60
5.0
0.80
0.66
1.25
1.00
M3
6.00
5.25
1.50
1.35
0.1
19.0
1.00
0.75
6.0
1.00
0.86
1.50
1.20
(M3.5)
7.00
6.10
1.75
1.57
0.2
20.0
1.20
0.90
6.0
1.00
0.86
1.75
1.40
M4
8.00
7.00
2.00
1.80
0.2
22.0
1.40
1.00
8.0
1.20
1.06
2.00
1.60
(M4.5) M5
9.00
7.85
2.25
2.03
0.2
24.0
1.50
1.10
8.0
1.20
1.06
2.25
1.80
10.00
8.75
2.50
2.25
0.2
25.0
1.60
1.25
10.0
1.51
1.26
2.50
2.00
M6
12.00
10.50
3.00
2.70
0.25
28.0
2.00
1.50
12.0
1.91
1.66
3.00
2.40
M8
16.00
14.00
4.00
3.60
0.4
34.0
2.50
2.00
16.0
2.31
2.06
4.00
3.20
M10
20.00
17.50
5.00
4.50
0.4
40.0
3.00
2.50
20.0
2.81
2.56
5.00
4.00
M12
24.00
21.00
6.00
5.40
0.6
46.0
3.50
3.00
25.0
3.31
3.06
6.00
4.80
(M14)
28.00
24.50
7.00
6.30
0.6
52.0
4.00
3.50
25.0
3.31
3.06
7.00
5.60
M16
32.00
28.00
8.00
7.20
0.6
58.0
4.00
4.00
32.0
4.37
4.07
8.00
6.40
(M18)
36.00
31.50
9.00
8.10
0.6
64.0
5.00
4.50
32.0
4.37
4.07
9.00
7.20
M20
40.00
35.00
10.00
9.00
0.8
70.0
5.00
5.00
40.0
5.37
5.07
10.00
8.00
a Nominal sizes shown in parentheses are non-preferred. b See Radius Under the Head of Screws description in text. c See text following table in Lengths of Thread on Screws description in text. d Threaded up to head.
All dimensions are given in millimeters. For dimensional notation see diagram on page 1610. Recessed head screws are also standard and available. For dimensions see British Standard.
Copyright 2004, Industrial Press, Inc., New York, NY
MACHINE SCREWS
Max. (Theor. Sharp) 2d
Radius Under Head rb
Nominal Size da
Machinery's Handbook 27th Edition MACHINE SCREWS
1609
Ends of Screws: When screws are made with rolled threads, the “lead” formed by the thread rolling operation is normally regarded as providing the necessary chamfer and no other machining is necessary. The ends of screws with cut threads are normally finished with a chamfer conforming to the dimension in Fig. 1a through Fig. 1d. At the option of the manufacturer, the ends of screws smaller than M6 (6-mm diameter) may be finished with a radius approximately equal to 11⁄4 times the nominal diameter of the shank. When cone point ends are required, they should have the dimensions given in Fig. 1a through Fig. 1d. Nominal Length Nominal Length d
90
d
Cut Thread Chamfered End Fig. 1a. Rolled Thread End (Approximate Form as Rolled)
d
Radius Approx. 1 1/ 4 d
Nominal Length Fig. 1c. Cut Thread Radiused End (Permissible on Sizes Below M6 Dia.)
Fig. 1b. Chamfer to Extend to Slightly Below the Minor Dia.
90
d
Nominal Length Fig. 1d. Cone Pointed End (Permissible on Cut or Rolled Thread Screws, but Regarded as "Special")
Dimensions of 90-Degree Countersunk Head Screws: One of the appendices to this British Standard states that countersunk head screws should fit into the countersunk hole with as great a degree of flushness as possible. To achieve this condition, it is necessary for the dimensions of both the head of the screw and the countersunk hole to be controlled within prescribed limits. The maximum or design size of the head is controlled by a theoretical diameter to a sharp corner and the minimum head angle of 90 degrees. The minimum head size is controlled by a minimum head diameter, the maximum head angle of 92 degrees and a flushness tolerance (see Fig. 2). The edge of the head may be flat or rounded, as shown in Fig. 3.
Fig. 2. Head Configuration
Fig. 3. Edge Configuration
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1610
MACHINE SCREWS
British Standard Machine Screws and Machine Screw Nuts—Metric Series l l
k a r
b
90 +2 D D n
d Edge May Be Rounded or Flat, But Not Sharp Edges
t
Shank Dia. ≈ Effective Dia.
Shank Dia. ≈ Major Dia.
Slotted Countersunk Head Machine Screws
l
f
l
k a r 90 +2 D D n
b d
R
Edge May Be Shank Dia. ≈ Rounded or Shank Dia. ≈ Effective Major Dia. Flat, But Not Dia. Sharp Edges Slotted Raised Countersunk Head Machine Screws
t
k
l
R
l
a r
b
D n
d t
0 TO 5
da
k
Shank Dia. ≈ Effective Dia. Slotted Pan Head Machine Screws
l
R
l
a r
b
D n 0 TO 5
Shank Dia. ≈ Major Dia.
d t
da
Shank Dia. ≈ Effective Dia. Slotted Cheese Head Machine Screws
; d
s d
;
Shank Dia. ≈ Major Dia.
e
m s e Square Nut Hexagon Nut Machine Screw Nuts, Pressed Type, Square and Hexagon
m
For dimensions, see Tables 1 through 5.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINE SCREWS
1611
Table 3. British Standard Slotted Pan Head Machine Screws— Metric Series BS 4183:1967 (obsolescent) Nominal Size da M2.5 M3 (M3.5) M4 (M4.5) M5 M6 M8 M10
Head Diameter D
Head Height k
Head Radius R
Radius Under Head r
Transition Diameter da
Max. 2d
Min.
Max. 0.6d
Min.
Max 0.4d
Min.
Max.
5.00 6.00 7.00 8.00 9.00 10.00 12.00 16.00 20.00
4.70 5.70 6.64 7.64 8.64 9.64 11.57 15.57 19.48
1.50 1.80 2.10 2.40 2.70 3.00 3.60 4.80 6.00
1.36 1.66 1.96 2.26 2.56 2.86 3.42 4.62 5.82
1.00 1.20 1.40 1.60 1.80 2.00 2.50 3.20 4.00
0.10 0.10 0.20 0.20 0.20 0.20 0.25 0.40 0.40
3.10 3.60 4.30 4.70 5.20 5.70 6.80 9.20 11.20
a Nominal sizes shown in parentheses are non-preferred.
Nominal Size da M2.5 M3 (M3.5) M4 (M4.5) M5 M6 M8 M10
Thread Length b
Thread Run-out a
Min.
Max. 2pb
Max.
Min.
Max. 0.6k
Min. 0.4k
18.00 19.00 20.00 22.00 24.00 25.00 28.00 34.00 40.00
0.90 1.00 1.20 1.40 1.50 1.60 2.00 2.50 3.00
0.80 1.00 1.00 1.20 1.20 1.51 1.91 2.31 2.81
0.66 0.86 0.86 1.06 1.06 1.26 1.66 2.06 2.56
0.90 1.08 1.26 1.44 1.62 1.80 2.16 2.88 3.60
0.60 0.72 0.84 0.96 1.08 1.20 1.44 1.92 2.40
Slot Width n
Slot Depth t
a Nominal sizes shown in parentheses are non-preferred. b See Lengths of Thread on Screws on page 1606. All dimensions are in millimeters. For dimensional notation, see diagram on page 1610. Recessed head screws are also standard and available. For dimensions, see British Standard.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Head Diameter D
Nominal Size da
Head Height k
Radius rb
Transition Diameter da
Thread Length b
Thread Run-out a
Slot Width n
1612
Table 4. British Standard Slotted Cheese Head Machine Screws—Metric Series BS 4183:1967 (obsolescent) Slot Depth t
Max.
Min.
Max.
Min.
Min.
Max.
Min.
Max. c
Max.
Min.
Max.
Min.
M1
2.00
1.75
0.70
0.56
0.10
1.30
b
0.50
0.45
0.31
0.44
0.30
M1.2
2.30
2.05
0.80
0.66
0.10
1.50
b
0.50
0.50
0.36
0.49
0.35
(M1.4)
2.60
2.35
0.90
0.76
0.10
1.70
b
0.60
0.50
0.36
0.60
0.40
M1.6
3.00
2.75
1.00
0.86
0.10
2.00
15.00
0.70
0.60
0.46
0.65
0.45
3.80
3.50
1.30
1.16
0.10
2.60
16.00
0.80
0.70
0.56
0.85
0.60
4.00
3.70
1.50
1.36
0.10
2.80
17.00
0.90
0.80
0.66
1.00
0.70
M2.5
4.50
4.20
1.60
1.46
0.10
3.10
18.00
0.90
0.80
0.66
1.00
0.70
M3
5.50
5.20
2.00
1.86
0.10
3.60
19.00
1.00
1.00
0.86
1.30
0.90
(M3.5)
6.00
5.70
2.40
2.26
0.10
4.10
20.00
1.20
1.00
0.86
1.40
1.00
M4
7.00
6.64
2.60
2.46
0.20
4.70
22.00
1.40
1.20
1.06
1.60
1.20
(M4.5)
8.00
7.64
3.10
2.92
0.20
5.20
24.00
1.50
1.20
1.06
1.80
1.40
M5
8.50
8.14
3.30
3.12
0.20
5.70
25.00
1.60
1.51
1.26
2.00
1.50
M6
10.00
9.64
3.90
3.72
0.25
6.80
28.00
2.00
1.91
1.66
2.30
1.80
M8
13.00
12.57
5.00
4.82
0.40
9.20
34.00
2.50
2.31
2.06
2.80
2.30
M10
16.00
15.57
6.00
5.82
0.40
11.20
40.00
3.00
2.81
2.56
3.20
2.70
M12
18.00
17.57
7.00
6.78
0.60
14.20
46.00
3.50
3.31
3.06
3.80
3.20
(M14)
21.00
20.48
8.00
7.78
0.60
16.20
52.00
4.00
3.31
3.06
4.20
3.60
M16
24.00
23.48
9.00
8.78
0.60
18.20
58.00
4.00
4.37
4.07
4.60
4.00
(M18)
27.00
26.48
10.00
9.78
0.60
20.20
64.00
5.00
4.37
4.07
5.10
4.50
M20
30.00
29.48
11.00
10.73
0.80
22.40
70.00
5.00
5.27
5.07
5.60
5.00
a Nominal sizes shown in parentheses are non-preferred. b Threaded up to head. c See text following table in Lengths of Thread on Screws description in text.
All dimensions are given in millimeters. For dimensional notation, see diagram on page 1610.
General Dimensions: The general dimensions and tolerances for screws and nuts are given in the accompanying tables. Although slotted screw dimensions are given, recessed head screws are also standard and available. Dimensions of recessed head screws are given in BS 4183:1967 (obsolescent).
Copyright 2004, Industrial Press, Inc., New York, NY
MACHINE SCREWS
M2 (M2.2)
Machinery's Handbook 27th Edition
Table 5. British Standard Machine Screws and Nuts — Metric Series BS 4183:1967 (obsolescent) Concentricity Tolerances
IT 13
IT 13
Countersunk & Raised Countersunk Heads Pan & Cheese Heads
Nominal Size da M1, M1.2, (M1.4) M1.6 M2, (M2.2), M2.5, M3 (M3.5) M4, (M4.5), M5 M6 M8 M10, M12 (M14) M16, (M18), M20
Head to Shank
Head to Shank and Slot to Head (IT 13) Countersunk, Raised Csk., and Pan Heads
Cheese Heads
0.14 0.18 0.18 0.22 0.22 0.27 0.27 0.33 0.33 0.39
0.14 0.14 0.18 0.18 0.22 0.22 0.27 0.27 0.33 0.33
All dimensions are given in millimeters. For dimensional notation, see diagram on page 1610.
Copyright 2004, Industrial Press, Inc., New York, NY
Width Across Flats s Corners e Min. Square 3.02 4.5 3.82 5.7 4.32 6.4 4.82 7.1 5.32 7.8 5.82 8.5 6.78 9.9 7.78 11.3 9.78 14.1 12.73 18.4 16.73 24.0
Nominal Size da M1.6 M2 (M2.2) (M2.5) M3 (M3.5) M4 M5 M6 M8 M10
Max. 3.2 4.0 4.5 5.0 5.5 6.0 7.0 8.0 10.0 13.0 17.0
Nominal Size da M1.6 M2 (M2.2) M2.5 M3 (M3.5) M4 M5 M6 M8 M10 M8 M10
Width Across Corners e Hexagon 3.7 4.6 5.2 5.8 6.4 6.9 8.1 9.2 11.5 15.0 19.6 13.0 17.0
Thickness m Min 0.75 0.95 0.95 1.35 1.35 1.75 1.75 2.25 2.75 3.70 4.70 18.4 24.0
Max. 1.0 1.2 1.2 1.6 1.6 2.0 2.0 2.5 3.0 4.0 5.0 12.73 16.73
1613
a Nominal sizes and lengths shown in parentheses are non-preferred.
Dimensions of Machine Screw Nuts, Pressed Type, Square and Hexagon
MACHINE SCREWS
Slot to Head
Nominal Lengths and Tolerances on Length for Machine Screws Tolerance Nominal Lengtha Tolerance ±0.12 45 ±0.50 ±0.12 50 ±0.060 ±0.20 55 ±0.60 ±0.20 60 ±0.60 ±0.24 65 ±0.60 ±0.24 70 ±0.60 ±0.24 75 ±0.60 ±0.29 80 ±0.60 ±0.29 85 ±0.70 ±0.29 90 ±0.70 ±0.29 (95) ±0.70 ±0.35 100 ±0.70 ±0.35 (105) ±0.70 ±0.35 110 ±0.70 ±0.35 (115) ±0.70 ±0.35 120 ±0.70 ±0.42 (125) ±0.70 ±0.42 130 ±0.80 ±0.42 140 ±0.80 ±0.42 150 ±0.80 ±0.42 160 ±0.80 ±0.50 190 ±0.925 ±0.50 200 ±0.925
Nominal Lengtha 1.5 2 2.5 3 4 5 6 (7) 8 (9) 10 (11) 12 14 16 (18) 20 (22) 25 (28) 30 (38) 40
Machinery's Handbook 27th Edition 1614
MACHINE SCREWS
British Unified Machine Screws and Nuts.—British Standard B.S. 1981:1953 covers certain types of machine screws and machine screw nuts for which agreement has been reached with the United States and Canada as to general dimensions for interchangeability. These types are: countersunk, raised-countersunk, pan, and raised-cheese head screws with slotted or recessed heads; small hexagon head screws; and precision and pressed nuts. All have Unified threads. Head shapes are shown on page 1614 and dimensions are given on page 1616. Identification: As revised by Amendment No. 1 in February 1955, this standard now requires that the above-mentioned screws and nuts that conform to this standard should have a distinguishing feature applied to identify them as Unified. All recessed head screws are to be identified as Unified by a groove in the form of four arcs of a circle in the upper surface of the head. All hexagon head screws are to be identified as Unified by: 1) a circular recess in the upper surface of the head; 2) a continuous line of circles indented on one or more of the flats of the hexagon and parallel to the screw axis; and 3) at least two contiguous circles indented on the upper surface of the head. All machine screw nuts of the pressed type shall be identified as Unified by means of the application of a groove indented in one face of the nut approximately midway between the major diameter of the thread and flats of the square or hexagon. Slotted head screws shall be identified as Unified either by a circular recess or by a circular platform or raised portion on the upper surface of the head. Machine screw nuts of the precision type shall be identified as Unified by either a groove indented on one face of the front approximately midway between the major diameter of the thread and the flats of the hexagon or a continuous line of circles indented on one or more of the flats of the hexagon and parallel to the nut axis.
;; ;;;;;;;; ; ;; ;; ;; ; ;;;;;;;;;; Recessed and Hexagon Head Screws
Precision Type
Pressed Type
Hexagon Machine Screw Nuts
Slotted Head Screws Identification Markings for British Standard Unified Machine Screws
British Standard Machine Screws and Nuts ricc:1958 (obsolescent) and B.S. 1981:1953
80° Countersunk head screw (Unified) 90° Countersink head screw (BSW & BSF)
Round head screw (BSW & BSF)
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINE SCREWS
1615
British Standard Machine Screws and Nuts (Continued) ricc:1958 (obsolescent) and B.S. 1981:1953
80° Raised countersunk head screw (Unified) 90° Raised countersunk head screw (BSW & BSF)
Mushroom head screw (BSW & BSF)
Pan head screw (Unified, BSW & BSF)
Hexagon head screw (Unified)
Cheese head screw (BSW & BSF)
Hexagon head screw (Unified) alternate design
Raised cheese head screw (Unified)
Hexagon machine screw nut (Unified)
*Countersinks to suit the screws should have a maximum angle of 80° (Unified) or 90° (BSF and BSW) with a negative tolerance. †Unified countersunk and raised countersunk head screws 2 inches long and under are threaded right up to the head. Other Unified, BSW and BSF machine screws 2 inches long and under have an unthread shank equal to twice the pitch. All Unified, BSW and BSF machine screws longer than 2 inches have a minimum thread length of 13⁄4 inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1616
MACHINE SCREWS British Standard Unified Machine Screws and Nuts B.S. 1981:1953 Threads per Inch UNC UNF
Nom.Size of Screw
Basic Dia. D
4 6 8 10
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
0.112 0.138 0.164 0.190 0.250 0.3125 0.375 0.4375 0.500 0.625 0.750
40 32 32 24c 20 18 16 14 13 11 10
… … … 32 28 24 24 20 20 18 16
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
0.112 0.138 0.164 0.190 0.250 0.3125 0.375 0.4375 0.500 0.625 0.750
40 32 32 24c 20 18 16 14 13 11 10
… … … 32 28 24 24 20 20 18 16
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4
0.112 0.138 0.164 0.190 0.250 0.3125 0.375 0.4375 0.500 0.625 0.750
40 32 32 24c 20 18 16 14 13 11 10
… … … 32 28 24 24 20 20 18 16
4 6 8 10
4 6 8 10
Dia. of Head A Depth of Head B Max. Min. Max. Min. 80° Countersunk Head Screwsa,b 0.211 0.194 0.067 … 0.260 0.242 0.083 … 0.310 0.291 0.100 … 0.359 0.339 0.116 … 0.473 0.450 0.153 … 0.593 0.565 0.191 … 0.712 0.681 0.230 … 0.753 0.719 0.223 … 0.808 0.770 0.223 … 1.041 0.996 0.298 … 1.275 1.223 0.372 … Pan Head Screwsb 0.219 0.205 0.068 0.058 0.270 0.256 0.082 0.072 0.322 0.306 0.096 0.085 0.373 0.357 0.110 0.099 0.492 0.473d 0.144 0.130 0.615 0.594 0.178 0.162 0.740 0.716 0.212 0.195 0.863 0.838 0.247 0.227 0.987 0.958 0.281 0.260 1.125 1.090 0.350 0.325 1.250 1.209 0.419 0.390 Raised Cheese-Head Screwsb 0.183 0.166 0.107 0.088 0.226 0.208 0.132 0.111 0.270 0.250 0.156 0.133 0.313 0.292 0.180 0.156 0.414 0.389 0.237 0.207 0.518 0.490 0.295 0.262 0.622 0.590 0.355 0.315 0.625 0.589 0.368 0.321 0.750 0.710 0.412 0.362 0.875 0.827 0.521 0.461 1.000 0.945 0.612 0.542
Width of Slot H Max. Min.
Depth of Slot J
0.039 0.048 0.054 0.060 0.075 0.084 0.094 0.094 0.106 0.133 0.149
0.031 0.039 0.045 0.050 0.064 0.072 0.081 0.081 0.091 0.116 0.131
0.025 0.031 0.037 0.044 0.058 0.073 0.086 0.086 0.086 0.113 0.141
0.039 0.048 0.054 0.060 0.075 0.084 0.094 0.094 0.106 0.133 0.149
0.031 0.039 0.045 0.050 0.064 0.072 0.081 0.081 0.091 0.116 0.131
0.036 0.044 0.051 0.059 0.079 0.101 0.122 0.133 0.152 0.189 0.226
0.039 0.048 0.054 0.060 0.075 0.084 0.094 0.094 0.106 0.133 0.149
0.031 0.039 0.045 0.050 0.064 0.072 0.081 0.081 0.091 0.116 0.131
0.042 0.053 0.063 0.074 0.098 0.124 0.149 0.153 0.171 0.217 0.254
a All dimensions, except J, given for the No. 4 to 3⁄ -inch sizes, incl., also apply to all the 80° Raised 8 Countersunk Head Screws given in the Standard. b Also available with recessed heads. c Non-preferred. d By arrangement may also be 0.468.
Nom. Size
Basic Dia. D
Threads per Inch UNC UNF
4 6 8 10
0.112 0.138 0.164 0.190
40 32 32 24c
4 6 8 10
0.112 0.138 0.164 0.190
40 32 32 24c
4 6 8 10
0.112 0.138 0.164 0.190 0.250 0.3125 0.375
40 32 32 24c 20 18 16
Width Across Flats A Corners C Max. Min. Max.
H'd Depth B Nut Thick. E Max. Min.
Wash. Face Dia. F Min.
Max.
Hexagon Head Screws
1⁄ 4 5⁄ 16 3⁄ 8
… 0.1875 0.1835 0.216 0.060 … 0.2500 0.2450 0.289 0.080 … 0.2500 0.2450 0.289 0.110 32 0.3125 0.3075 0.361 0.120 Hexagon Machine Screw Nuts—Precision Type … 0.1875 0.1835 0.216 0.098 … 0.2500 0.2450 0.269 0.114 … 0.3125 0.3075 0.361 0.130 … 0.3125 0.3075 0.361 0.130 Hexagon Machine Screw Nuts—Pressed Type … 0.2500 0.2410 0.289 0.087 … 0.3125 0.3020 0.361 0.114 … 0.3438 0.3320 0.397 0.130 32 0.3750 0.3620 0.433 0.130 28 0.4375 0.4230 0.505 0.193 24 0.5625 0.5450 0.649 0.225 24 0.6250 0.6070 0.722 0.257
0.055 0.074 0.104 0.113
0.183 0.245 0.245 0.307
0.173 0.235 0.235 0.297
0.087 0.102 0.117 0.117
… … … …
… … … …
0.077 0.102 0.117 0.117 0.178 0.208 0.239
… … … … … … …
… … … … … … …
All dimensions in inches. See page 1614 for a pictorial representation and letter dimensions.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition MACHINE SCREWS
1617
Depth of Head B Max. Min.
… 32c 28c 26 22 20 18 16 16c 14 12
0.219 0.328 0.383 0.438 0.547 0.656 0.766 0.875 0.984 1.094 1.312
0.201 0.307 0.360 0.412 0.518 0.624 0.729 0.835 0.941 1.046 1.257
0.056 0.084 0.098 0.113 0.141 0.169 0.197 0.225 0.253 0.281 0.338
… … … … … … … … … … …
0.039 0.050 0.055 0.061 0.071 0.082 0.093 0.104 0.115 0.126 0.148
0.032 0.042 0.046 0.051 0.061 0.072 0.082 0.092 0.103 0.113 0.134
0.027 0.041 0.048 0.055 0.069 0.083 0.097 0.111 0.125 0.138 0.166
40 24 … 20 18 16 14 12 12c 11 10
… 32c 28c 26 22 20 18 16 16c 14 12
0.219 0.328 0.383 0.438 0.547 0.656 0.766 0.875 0.984 1.094 1.312
0.206 0.312d 0.365 0.417 0.524 0.629 0.735 0.840 0.946 1.051 1.262
0.087 0.131 0.153 0.175 0.219 0.262 0.306 0.350 0.394 0.437 0.525
0.082 0.124 0.145 0.165 0.207 0.249 0.291 0.333 0.375 0.417 0.500
0.039 0.050 0.055 0.061 0.071 0.082 0.093 0.104 0.115 0.126 0.148
0.032 0.042 0.046 0.051 0.061 0.072 0.082 0.092 0.103 0.113 0.134
0.048 0.072 0.084 0.096 0.120 0.144 0.168 0.192 0.217 0.240 0.288
0.1250 0.1875 0.2188 0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500
40 24 … 20 18 16 14 12 12c 11 10
… 32c 28c 26 22 20 18 16 16c 14 12
0.245 0.373 0.425 0.492 0.615 0.740 0.863 0.987 1.031 1.125 1.250
0.231 0.375 0.407 0.473e 0.594 0.716 0.838 0.958 0.999 1.090 1.209
0.075 0.110 0.125 0.144 0.178 0.212 0.247 0.281 0.315 0.350 0.419
0.065 0.099 0.112 0.130 0.162 0.195 0.227 0.260 0.293 0.325 0.390
0.039 0.050 0.055 0.061 0.071 0.082 0.093 0.104 0.115 0.126 0.148
0.032 0.042 0.046 0.051 0.061 0.072 0.082 0.092 0.103 0.113 0.134
0.040 0.061 0.069 0.078 0.095 0.112 0.129 0.145 0.162 0.179 0.213
Cheese Head Screwsb
1⁄ 8 3⁄ 16 7⁄ 32 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
0.1250 0.1875 0.2188 0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500
40 24 … 20 18 16 14 12 12c 11 10
… 32c 28c 26 22 20 18 16 16c 14 12
0.188 0.281 0.328 0.375 0.469 0.562 0.656 0.750 0.844 0.938 1.125
0.180 0.270 0.315 0.360 0.450 0.540 0.630 0.720 0.810 0.900 1.080
0.087 0.131 0.153 0.175 0.219 0.262 0.306 0.350 0.394 0.437 0.525
0.082 0.124 0.145 0.165 0.207 0.249 0.291 0.333 0.375 0.417 0.500
0.039 0.050 0.055 0.061 0.071 0.082 0.093 0.104 0.115 0.126 0.148
0.032 0.042 0.046 0.051 0.061 0.072 0.082 0.092 0.103 0.113 0.134
0.039 0.059 0.069 0.079 0.098 0.118 0.138 0.157 0.177 0.197 0.236
1⁄ 8 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8
0.1250 0.1875 0.2500 0.3125 0.3750
40 24 20 18 16
… 32c 26 22 20
0.289 0.448 0.573 0.698 0.823
0.272 0.425 0.546 0.666 0.787
0.078 0.118 0.150 0.183 0.215
0.066 0.103 0.133 0.162 0.191
0.043 0.060 0.075 0.084 0.094
0.035 0.050 0.064 0.072 0.081
0.040 0.061 0.079 0.096 0.112
Pan Head Screwsb
Round Head Screwsb
90° Countersunk Head Screwsab
Dia. of Head A Max. Min.
Mushroom Head Screwsb
British Standard Whitworth (BSW) and Fine (BSF) Machine Screws BS 450:1958 (obsolescent) Threads per Inch BSW BSF
Nom. Size of Screw
Basic Dia. D
1⁄ 8 3⁄ 16 7⁄ 32 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 1⁄ 8 3⁄ 16 7⁄ 32 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 1⁄ 8 3⁄ 16 7⁄ 32 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
0.1250 0.1875 0.2188 0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500
40 24 … 20 18 16 14 12 12c 11 10
0.1250 0.1875 0.2188 0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500
Width of Slot H Max. Min.
Depth of Slot J
a All dimensions, except J, given for the 1⁄ -through 3⁄ -inch sizes also apply to all the 90° Raised 8 8 Countersunk Head Screw dimensions given in the Standard. b These screws are also available with recessed heads; dimensions of recess are not given here but may be found in the Standard. c Non-preferred size; avoid use whenever possible. d By arrangement may also be 0.309. e By arrangement may also be 0.468. All dimensions in inches. See diagram on page 1614 for a pictorial representation of screws and letter dimensions.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1618
CAP SCREWS
CAP AND SET SCREWS Slotted Head Cap Screws.—American National Standard ANSI/ASME B18.6.2-1998 is intended to cover the complete general and dimensional data for the various styles of slotted head cap screws as well as square head and slotted headless set screws (see page 1625). Reference should be made to this Standard for information or data not found in the following text or tables. Length of Thread: The length of complete (full form) thread on cap screws is equal to twice the basic screw diameter plus 0.250 in. with a plus tolerance of 0.188 in. or an amount equal to 21⁄2 times the pitch of the thread, whichever is greater. Cap screws of lengths too short to accommodate the minimum thread length have full form threads extending to within a distance equal to 21⁄2 pitches (threads) of the head. Designation: Slotted head cap screws are designated by the following data in the sequence shown: Nominal size (fraction or decimal equivalent); threads per inch; screw length (fraction or decimal equivalent); product name; material; and protective finish, if required. Examples: 1⁄2-13 × 3 Slotted Round Head Cap Screw, SAE Grade 2 Steel, Zinc Plated. .750-16 × 2.25 Slotted Flat Countersunk Head Cap Screw, Corrosion Resistant Steel. Table 1. American National Standard Slotted Flat Countersunk Head Cap Screws ANSI/ASME B18.6.2-1998
Head Dia., A Nominal Sizea or Basic Screw Dia.
Body Dia., E
Edge Sharp
Edge Rnd'd. or Flat
Head Hgt., H
Slot Width, J
Slot Depth, T
Filet Rad., U
Max.
Min.
Max.
Min.
Ref.
Max.
Min.
Max.
Min.
Max.
1⁄ 4
0.2500
.2500
.2450
.500
.452
.140
.075
.064
.068
.045
.100
5⁄ 16
0.3125
.3125
.3070
.625
.567
.177
.084
.072
.086
.057
.125
3⁄ 8
0.3750
.3750
.3690
.750
.682
.210
.094
.081
.103
.068
.150
7⁄ 16
0.4375
.4375
.4310
.812
.736
.210
.094
.081
.103
.068
.175
1⁄ 2
0.5000
.5000
.4930
.875
.791
.210
.106
.091
.103
.068
.200
9⁄ 16
0.5625
.5625
.5550
1.000
.906
.244
.118
.102
.120
.080
.225
5⁄ 8
0.6250
.6250
.6170
1.125
1.020
.281
.133
.116
.137
.091
.250
3⁄ 4
0.7500
.7500
.7420
1.375
1.251
.352
.149
.131
.171
.115
.300
7⁄ 8
0.8750
.8750
.8660
1.625
1.480
.423
.167
.147
.206
.138
.350
1
1.0000
1.0000
.9900
1.875
1.711
.494
.188
.166
.240
.162
.400
11⁄8
1.1250
1.1250
1.1140
2.062
1.880
.529
.196
.178
.257
.173
.450
11⁄4
1.2500
1.2500
1.2390
2.312
2.110
.600
.211
.193
.291
.197
.500
13⁄8
1.3750
1.3750
1.3630
2.562
2.340
.665
.226
.208
.326
.220
.550
11⁄2
1.5000
1.5000
1.4880
2.812
2.570
.742
.258
.240
.360
.244
.600
a When
specifying a nominal size in decimals, the zero preceding the decimal point is omitted as is any zero in the fourth decimal place. All dimensions are in inches. Threads: Threads are Unified Standard Class 2A; UNC, UNF and 8 UN Series or UNRC, UNRF, and 8 UNR Series.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CAP SCREWS
1619
Table 2. American National Standard Slotted Round Head Cap Screws ANSI/ASME B18.6.2-1998
Nom. Sizea or Basic Screw Diameter 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.7500
Body Diameter, E Max. Min.
Head Diameter, A Max. Min.
Head Height, H Max. Min.
Slot Width, J Max. Min.
Slot Depth, T Max. Min.
.2500 .3125 .3750 .4375 .5000 .5625 .6250 .7500
.437 .562 .625 .750 .812 .937 1.000 1.250
.191 .245 .273 .328 .354 .409 .437 .546
.075 .084 .094 .094 .106 .118 .133 .149
.117 .151 .168 .202 .218 .252 .270 .338
.2450 .3070 .3690 .4310 .4930 .5550 .6170 .7420
.418 .540 .603 .725 .786 .909 .970 1.215
.175 .226 .252 .302 .327 .378 .405 .507
.064 .072 .081 .081 .091 .102 .116 .131
.097 .126 .138 .167 .178 .207 .220 .278
a When specifying a nominal size in decimals, the zero preceding the decimal point is omitted as is any zero in the fourth decimal place.
All dimensions are in inches. Fillet Radius, U: For fillet radius see foonote to table below. Threads: Threads are Unified Standard Class 2A; UNC, UNF and 8 UN Series or UNRC, UNRF and 8 UNR Series.
Table 3. American National Standard Slotted Fillister Head Cap Screws ANSI/ASME B18.6.2-1998
Body Dia.., E Max. Min.
Head Dia.., A Max. Min.
Head Side Height, H Max. Min.
Total Head Height, O Max. Min.
Slot Width, J Max. Min.
Slot Depth, T Max. Min.
0.2500 0.3125 0.3750 0.4375 0.5000 0.5625
.2500 .3125 .3750 .4375 .5000 .5625
.2450 .3070 .3690 .4310 .4930 .5550
.375 .437 .562 .625 .750 .812
.363 .424 .547 .608 .731 .792
.172 .203 .250 .297 .328 .375
.157 .186 .229 .274 .301 .346
.216 .253 .314 .368 .413 .467
.194 .230 .284 .336 .376 .427
.075 .084 .094 .094 .106 .118
.064 .072 .081 .081 .091 .102
.097 .115 .142 .168 .193 .213
.077 .090 .112 .133 .153 .168
0.6250 0.7500 0.8750 1.0000
.6250 .7500 .8750 1.0000
.6170 .7420 .8660 .9900
.875 1.000 1.125 1.312
.853 .976 1.098 1.282
.422 .500 .594 .656
.391 .466 .556 .612
.521 .612 .720 .803
.478 .566 .668 .743
.133 .149 .167 .188
.116 .131 .147 .166
.239 .283 .334 .371
.189 .223 .264 .291
Nom. Sizea or Basic Screw Dia. 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 7⁄ 8
1
a When specifying nominal size in decimals, the zero preceding the decimal point is omitted as is any zero in the fourth decimal place.
All dimensions are in inches. Fillet Radius, U: The fillet radius is as follows: For screw sizes 1⁄4 to 3⁄8 incl., .031 max. and .016 min.; 7⁄16 to 9⁄16, incl., .047 max., .016 min.; and for 5⁄8 to 1, incl., .062 max., .031 min. Threads: Threads are Unified Standard Class 2A; UNC, UNF and 8 UN Series or UNRC, UNRF and 8 UNR Series.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1620
CAP SCREWS Table 4. American National Standard Hexagon and Spline Socket Head Cap Screws ANSI/ASME B18.3-1998
Nominal Size 0 1 2 3 4 5 6 8 10 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8 1 11⁄8 11⁄4 13⁄8 11⁄2 13⁄4 2 21⁄4 21⁄2 23⁄4 3 31⁄4 31⁄2 33⁄4 4
Body Diameter, D Max Min 0.0600 0.0568 0.0730 0.0695 0.0860 0.0822 0.0990 0.0949 0.1120 0.1075 0.1250 0.1202 0.1380 0.1329 0.1640 0.1585 0.1900 0.1840 0.2500 0.2435 0.3125 0.3053 0.3750 0.3678 0.4375 0.4294 0.5000 0.4919 0.6250 0.6163 0.7500 0.7406 0.8750 0.8647 1.0000 0.9886 1.1250 1.1086 1.2500 1.2336 1.3750 1.3568 1.5000 1.4818 1.7500 1.7295 2.0000 1.9780 2.2500 2.2280 2.5000 2.4762 2.7500 2.7262 3.0000 2.9762 3.2500 3.2262 3.5000 3.4762 3.7500 3.7262 4.0000 3.9762
Head Diameter, A Max Min 0.096 0.091 0.118 0.112 0.140 0.134 0.161 0.154 0.183 0.176 0.205 0.198 0.226 0.218 0.270 0.262 0.312 0.303 0.375 0.365 0.469 0.457 0.562 0.550 0.656 0.642 0.750 0.735 0.938 0.921 1.125 1.107 1.312 1.293 1.500 1.479 1.688 1.665 1.875 1.852 2.062 2.038 2.250 2.224 2.625 2.597 3.000 2.970 3.375 3.344 3.750 3.717 4.125 4.090 4.500 4.464 4.875 4.837 5.250 5.211 5.625 5.584 6.000 5.958
Head Height, H Max Min 0.060 0.057 0.073 0.070 0.086 0.083 0.099 0.095 0.112 0.108 0.125 0.121 0.138 0.134 0.164 0.159 0.190 0.185 0.250 0.244 0.312 0.306 0.375 0.368 0.438 0.430 0.500 0.492 0.625 0.616 0.750 0.740 0.875 0.864 1.000 0.988 1.125 1.111 1.250 1.236 1.375 1.360 1.500 1.485 1.750 1.734 2.000 1.983 2.250 2.232 2.500 2.481 2.750 2.730 3.000 2.979 3.250 3.228 3.500 3.478 3.750 3.727 4.000 3.976
Spline Socketa Size, M 0.060 0.072 0.096 0.096 0.111 0.111 0.133 0.168 0.183 0.216 0.291 0.372 0.454 0.454 0.595 0.620 0.698 0.790 … … … … … … … … … … … … … …
Nom. Hex. Socket Size, J 0.050 1⁄ 0.062 16 5⁄ 0.078 64 5⁄ 0.078 64 3⁄ 0.094 32 3⁄ 0.094 32 7⁄ 0.109 64 9⁄ 0.141 64 5⁄ 0.156 32 3⁄ 0.188 16 1⁄ 0.250 4 5⁄ 0.312 16 3⁄ 0.375 8 3⁄ 0.375 8 1⁄ 0.500 2 5⁄ 0.625 8 3⁄ 0.750 4 3⁄ 0.750 4 7⁄ 0.875 8 7⁄ 0.875 8 1 1.000 1 1.000 11⁄4 1.250 11⁄2 1.500 13⁄4 1.750 13⁄4 1.750 2 2.000 21⁄4 2.250 1 2 ⁄4 2.250 23⁄4 2.750 23⁄4 2.750 3 3.000
Fillet Ext., F Max 0.007 0.007 0.008 0.008 0.009 0.010 0.010 0.012 0.014 0.014 0.017 0.020 0.023 0.026 0.032 0.039 0.044 0.050 0.055 0.060 0.065 0.070 0.080 0.090 0.100 0.110 0.120 0.130 0.140 0.150 0.160 0.170
Key Engagementa, T 0.025 0.031 0.038 0.044 0.051 0.057 0.064 0.077 0.090 0.120 0.151 0.182 0.213 0.245 0.307 0.370 0.432 0.495 0.557 0.620 0.682 0.745 0.870 0.995 1.120 1.245 1.370 1.495 1.620 1.745 1.870 1.995
a Key engagement depths are minimum. Spline socket sizes are nominal.
All dimensions in inches. The body length LB of the screw is the length of the unthreaded cylindrical portion of the shank. The length of thread, LT, is the distance from the extreme point to the last complete (full form) thread. Standard length increments for screw diameters up to 1 inch are 1⁄16 inch for lengths 1⁄8 through 1⁄4 inch, 1⁄8 inch for lengths 1⁄4 through 1 inch, 1⁄4 inch for lengths 1 through 3 1⁄2 inches, 1⁄2 inch for lengths 3 1⁄2 through 7 inches, 1 inch for lengths 7 through 10 inches and for diameters over 1 inch are 1⁄2 inch for lengths 1 through 7 inches, 1 inch for lengths 7 through 10 inches, and 2 inches for lengths over 10 inches. Heads may be plain or knurled, and chamfered to an angle E of 30 to 45 degrees with the surface of the flat. The thread conforms to the Unified Standard with radius root, Class 3A UNRC and UNRF for screw sizes No. 0 through 1 inch inclusive, Class 2A UNRC and UNRF for over 1 inch through 1 1⁄ inches inclusive, and Class 2A UNRC for larger sizes. Socket dimensions are given in Table 11. 2 For details not shown, including materials, see ANSI/ASME B18.3-1998.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CAP SCREWS
1621
Table 5. Drill and Counterbore Sizes For Socket Head Cap Screws (1960 Series)
Nominal Drill Size Nominal Size or Basic Screw Diameter 0 1 2 3 4 5 6 8 10 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
1 11⁄4 11⁄2 13⁄4 2
0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2500 0.3125 0.3750 0.4375 0.5000 0.6250 0.7500 0.8750 1.0000 1.2500 1.5000 1.7500 2.0000
Close Fitb Number or Fractional Decimal Size Size
Normal Fitc Number or Fractional Decimal Size Size A
51 46 3⁄ 32
36 1⁄ 8 9⁄ 64
23 15 5 17⁄ 64 21⁄ 64 25⁄ 64 29⁄ 64 33⁄ 64 41⁄ 64 49⁄ 64 57⁄ 64 1 1 ⁄64 9 1 ⁄32 117⁄32 125⁄32 21⁄32
0.067 0.081 0.094 0.106 0.125 0.141 0.154 0.180 0.206 0.266 0.328 0.391 0.453 0.516 0.641 0.766 0.891 1.016 1.281 1.531 1.781 2.031
49 43 36 31 29 23 18 10 2 9⁄ 32 11⁄ 32 13⁄ 32 15⁄ 32 17⁄ 32 21⁄ 32 25⁄ 32 29⁄ 32 1 1 ⁄32 5 1 ⁄16 19⁄16 113⁄16 21⁄16
0.073 0.089 0.106 0.120 0.136 0.154 0.170 0.194 0.221 0.281 0.344 0.406 0.469 0.531 0.656 0.781 0.906 1.031 1.312 1.562 1.812 2.062
Counterbore Diameter B 1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 7⁄ 32 1⁄ 4 9⁄ 32 5⁄ 16 3⁄ 8 7⁄ 16 17⁄ 32 5⁄ 8 23⁄ 32 13⁄ 16
1 13⁄16 13⁄8 15⁄8 2 23⁄8 23⁄4 31⁄8
Countersink Diametera C 0.074 0.087 0.102 0.115 0.130 0.145 0.158 0.188 0.218 0.278 0.346 0.415 0.483 0.552 0.689 0.828 0.963 1.100 1.370 1.640 1.910 2.180
a Countersink: It is considered good practice to countersink or break the edges of holes which are smaller than (D Max + 2F Max) in parts having a hardness which approaches, equals or exceeds the screw hardness. If such holes are not countersunk, the heads of screws may not seat properly or the sharp edges on holes may deform the fillets on screws thereby making them susceptible to fatigue in applications involving dynamic loading. The countersink or corner relief, however, should not be larger than is necessary to insure that the fillet on the screw is cleared. b Close Fit: The close fit is normally limited to holes for those lengths of screws which are threaded to the head in assemblies where only one screw is to be used or where two or more screws are to be used and the mating holes are to be produced either at assembly or by matched and coordinated tooling. c Normal Fit: The normal fit is intended for screws of relatively long length or for assemblies involving two or more screws where the mating holes are to be produced by conventional tolerancing methods. It provides for the maximum allowable eccentricity of the longest standard screws and for certain variations in the parts to be fastened, such as: deviations in hole straightness, angularity between the axis of the tapped hole and that of the hole for the shank, differences in center distances of the mating holes, etc.
All dimensions in inches. Source: Appendix to American National Standard ANSI/ASME B18.3-1998.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1622
CAP SCREWS
Table 6. American National Standard Hexagon and Spline Socket Flat Countersunk Head Cap Screws ANSI/ASME B18.3-1998
Nominal Size 0 1 2 3 4 5 6 8 10 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
1 11⁄8 11⁄4 13⁄8 11⁄2
Body Diameter Max. Min. D 0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2500 0.3125 0.3750 0.4375 0.5000 0.6250 0.7500 0.8750 1.0000 1.1250 1.2500 1.3750 1.5000
0.0568 0.0695 0.0822 0.0949 0.1075 0.1202 0.1329 0.1585 0.1840 0.2435 0.3053 0.3678 0.4294 0.4919 0.6163 0.7406 0.8647 0.9886 1.1086 1.2336 1.3568 1.4818
Head Diameter Theoretical Sharp Abs. Max. Min. A 0.138 0.168 0.197 0.226 0.255 0.281 0.307 0.359 0.411 0.531 0.656 0.781 0.844 0.938 1.188 1.438 1.688 1.938 2.188 2.438 2.688 2.938
0.117 0.143 0.168 0.193 0.218 0.240 0.263 0.311 0.359 0.480 0.600 0.720 0.781 0.872 1.112 1.355 1.604 1.841 2.079 2.316 2.553 2.791
HeadHeight
Reference H
Spline Socket Size M
Hexagon Socket Size Nom. J
Key Engagement Min. T
0.044 0.054 0.064 0.073 0.083 0.090 0.097 0.112 0.127 0.161 0.198 0.234 0.234 0.251 0.324 0.396 0.468 0.540 0.611 0.683 0.755 0.827
0.048 0.060 0.060 0.072 0.072 0.096 0.096 0.111 0.145 0.183 0.216 0.251 0.291 0.372 0.454 0.454 … … … … … …
0.035 0.050 0.050 1⁄ 16 1⁄ 16 5⁄ 64 5⁄ 64 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 7⁄ 8 7⁄ 8 1
0.025 0.031 0.038 0.044 0.055 0.061 0.066 0.076 0.087 0.111 0.135 0.159 0.159 0.172 0.220 0.220 0.248 0.297 0.325 0.358 0.402 0.435
All dimensions in inches. The body of the screw is the unthreaded cylindrical portion of the shank where not threaded to the head; the shank being the portion of the screw from the point of juncture of the conical bearing surface and the body to the flat of the point. The length of thread LT is the distance measured from the extreme point to the last complete (full form) thread. Standard length increments of No. 0 through 1-inch sizes are as follows: 1⁄16 inch for nominal screw lengths of 1⁄8 through 1⁄4 inch; 1⁄8 inch for lengths of 1⁄4 through 1 inch; 1⁄4 inch for lengths of 1 inch through 3 1⁄2 inches; 1⁄2 inch for lengths of 3 1⁄2 through 7 inches; and 1 inch for lengths of 7 through 10 inches, incl. For screw sizes over 1 inch, length increments are: 1⁄2 inch for nominal screw lengths of 1 inch through 7 inches; 1 inch for lengths of 7 through 10 inches; and 2 inches for lengths over 10 inches. Threads shall be Unified external threads with radius root; Class 3A UNRC and UNRF series for sizes No. 0 through 1 inch and Class 2A UNRC and UNRF series for sizes over 1 inch to 1 1⁄2 inches, incl. For manufacturing details not shown, including materials, see American National Standard ANSI/ASME B18.3-1998 Socket dimensions are given in Table 11.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition CAP SCREWS
1623
Table 7. American National Standard Hexagon Socket and Spline Socket Button Head Cap Screws ANSI/ASME B18.3-1998
Screw Diameter Nominal Size
Basic
Head Diameter Max.
D
Min.
Head Height Max.
A
Min. H
Head Side Height
Spline Socket Sizea
Hexagon Socket Sizea
Standard Length
Ref.
Nom.
Nom.
Max.
S
M
J
L
0
0.0600
0.114
0.104
0.032
0.026
0.010
0.048
0.035
1⁄ 2
1
0.0730
0.139
0.129
0.039
0.033
0.010
0.060
0.050
1⁄ 2
2
0.0860
0.164
0.154
0.046
0.038
0.010
0.060
0.050
1⁄ 2
3
0.0990
0.188
0.176
0.052
0.044
0.010
0.072
1⁄ 16
1⁄ 2
4
0.1120
0.213
0.201
0.059
0.051
0.015
0.072
1⁄ 16
1⁄ 2
5
0.1250
0.238
0.226
0.066
0.058
0.015
0.096
5⁄ 64
1⁄ 2
6
0.1380
0.262
0.250
0.073
0.063
0.015
0.096
5⁄ 64
5⁄ 8
8
0.1640
0.312
0.298
0.087
0.077
0.015
0.111
3⁄ 32
10
0.1900
0.361
0.347
0.101
0.091
0.020
0.145
1⁄ 8
1
3⁄ 4
1⁄ 4
0.2500
0.437
0.419
0.132
0.122
0.031
0.183
5⁄ 32
1
5⁄ 16
0.3125
0.547
0.527
0.166
0.152
0.031
0.216
3⁄ 16
1
3⁄ 8
0.3750
0.656
0.636
0.199
0.185
0.031
0.251
7⁄ 32
11⁄4
1⁄ 2
0.5000
0.875
0.851
0.265
0.245
0.046
0.372
5⁄ 16
2
5⁄ 8
0.6250
1.000
0.970
0.331
0.311
0.062
0.454
3⁄ 8
2
a Socket dimensions are given in Table 11.
All dimensions in inches. These cap screws have been designed and recommended for light fastening applications. They are not suggested for use in critical high-strength applications where socket head cap screws should normally be used. Standard length increments for socket button head cap screws are as follows: 1⁄16 inch for nominal screw lengths of 1⁄8 through 1⁄4 inch, 1⁄8 inch for nominal screw lengths of 1⁄4 through 1 inch, and 1⁄4 inch for nominal screw lengths of 1 inch through 2 inches. Tolerances on lengths are −0.03 inch for lengths up to 1 inch inclusive. For lengths from 1 through 2 inches, inclusive, length tolerances are − 0.04 inch. The thread conforms to the Unified standard, Class 3A, with radius root, UNRC and UNRF. To prevent interference, American National Standard ANSI/ASME B18.3.4M-1986 gives metric dimensional and general requirements for a lower head profile hexagon socket button head cap screw. Because of its design, wrenchability and other design factors are reduced; therefore, B18.3.4M should be reviewed carefully. Available only in metric sizes and with metric threads. For manufacturing details, including materials, not shown, see American National Standard ANSI/ASME B18.3-1998
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1624
CAP SCREWS
Table 8. American National Standard Hexagon Socket Head Shoulder Screws ANSI/ASME B18.3-1998
Nominal Size 1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 5⁄ 8 3⁄ 4
1 11⁄4 11⁄2 13⁄4 2
Shoulder Diameter Max. Min. D 0.2480 0.3105 0.3730 0.4980 0.6230 0.7480 0.9980 1.2480 1.4980 1.7480 1.9980
0.2460 0.3085 0.3710 0.4960 0.6210 0.7460 0.9960 1.2460 1.4960 1.7460 1.9960
Thread Neck Diameter Nominal Size
Max.
Min. G
Head Diameter Max. Min. A
Head Height Max. Min. H
Head Side Height Min. S
Nominal Thread Size D1
Thread Length E
0.375 0.438 0.562 0.750 0.875 1.000 1.312 1.750 2.125 2.375 2.750
0.357 0.419 0.543 0.729 0.853 0.977 1.287 1.723 2.095 2.345 2.720
0.188 0.219 0.250 0.312 0.375 0.500 0.625 0.750 1.000 1.125 1.250
0.157 0.183 0.209 0.262 0.315 0.421 0.527 0.633 0.842 0.948 1.054
10–24 1⁄ -20 4 5⁄ -18 16 3⁄ -16 8 1⁄ -13 2 5⁄ -11 8 3⁄ -10 4 7⁄ -9 8 11⁄8-7 11⁄4-7 11⁄2-6
0.375 0.438 0.500 0.625 0.750 0.875 1.000 1.125 1.500 1.750 2.000
Thread Neck Width
Shoulder Neck Dia.
Shoulder Neck Width
Max.
Min.
Max.
I
K
F
0.177 0.209 0.240 0.302 0.365 0.490 0.610 0.735 0.980 1.105 1.230
Thread Neck Fillet Max.
Min. N
Head Fillet Extension Above D
Hexagon Socket Size
Max.
Nom.
M
J
1⁄ 4
0.142
0.133
0.083
0.227
0.093
0.023
0.017
0.014
1⁄ 8
5⁄ 16
0.193
0.182
0.100
0.289
0.093
0.028
0.022
0.017
5⁄ 32
3⁄ 8
0.249
0.237
0.111
0.352
0.093
0.031
0.025
0.020
3⁄ 16
1⁄ 2
0.304
0.291
0.125
0.477
0.093
0.035
0.029
0.026
1⁄ 4
5⁄ 8
0.414
0.397
0.154
0.602
0.093
0.042
0.036
0.032
5⁄ 16
3⁄ 4
0.521
0.502
0.182
0.727
0.093
0.051
0.045
0.039
3⁄ 8
1
0.638
0.616
0.200
0.977
0.125
0.055
0.049
0.050
1⁄ 2
11⁄4
0.750
0.726
0.222
1.227
0.125
0.062
0.056
0.060
5⁄ 8
11⁄2
0.964
0.934
0.286
1.478
0.125
0.072
0.066
0.070
13⁄4
1.089
1.059
0.286
1.728
0.125
0.072
0.066
0.080
1
2
1.307
1.277
0.333
1.978
0.125
0.102
0.096
0.090
11⁄4
7⁄ 8
All dimensions are in inches. The shoulder is the enlarged, unthreaded portion of the screw. Standard length increments for shoulder screws are: 1⁄8 inch for nominal screw lengths of 1⁄4 through 3⁄4 inch; 1⁄4 inch for lengths above 3⁄4 through 5 inches; and 1⁄2 inch for lengths over 5 inches. The thread conforms to the Unified Standard Class 3A, UNC. Hexagon socket sizes for the respective shoulder screw sizes are the same as for set screws of the same nominal size (see Table 7) except for shoulder screw size 1 inch, socket size is 1⁄2 inch, for screw size 1 1⁄2 inches, socket size is 7⁄8 inch, and for screw size 2 inches, socket size is 1 1⁄4 inches. For details not shown, including materials, see ANSI/ASME B18.3-1998.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SET SCREWS
1625
Table 9. American National Standard Slotted Headless Set Screws ANSI/ASME B18.6.2-1998
FLAT POINT
DOG POINT HALF DOG POINT
CUP POINT Nominal Sizea or Basic Screw Diameter 0 1 2 3 4 5 6 8 10 12 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4
OVAL POINT
Slot Width, J
Slot Depth, T
Cup and Flat Point Dia., C
CONE POINT Dog Point Dia., P
Point Length Dog, Q
Half Dog, Q1
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500
.014 .016 .018 .020 .024 .026 .028 .032 .035 .042 .049
.010 .012 .014 .016 .018 .020 .022 .026 .029 .035 .041
.020 .020 .025 .028 .031 .036 .040 .046 .053 .061 .068
.016 .016 .019 .022 .025 .026 .030 .036 .043 .051 .058
.033 .040 .047 .054 .061 .067 .074 .087 .102 .115 .132
.027 .033 .039 .045 .051 .057 .064 .076 .088 .101 .118
.040 .049 .057 .066 .075 .083 .092 .109 .127 .144 .156
.037 .045 .053 .062 .070 .078 .087 .103 .120 .137 .149
.032 .040 .046 .052 .058 .063 .073 .083 .095 .115 .130
.028 .036 .042 .048 .054 .057 .067 .077 .085 .105 .120
.017 .021 .024 .027 .030 .033 .038 .043 .050 .060 .068
.013 .017 .020 .023 .026 .027 .032 .037 .040 .050 .058
0.3125
.055
.047
.083
.073
.172
.156
.203
.195
.161
.151
.083
.073
0.3750
.068
.060
.099
.089
.212
.194
.250
.241
.193
.183
.099
.089
0.4375
.076
.068
.114
.104
.252
.232
.297
.287
.224
.214
.114
.104
0.5000
.086
.076
.130
.120
.291
.270
.344
.334
.255
.245
.130
.120
0.5625
.096
.086
.146
.136
.332
.309
.391
.379
.287
.275
.146
.134
0.6250
.107
.097
.161
.151
.371
.347
.469
.456
.321
.305
.164
.148
0.7500
.134
.124
.193
.183
.450
.425
.562
.549
.383
.367
.196
.180
a When
specifying a nominal size in decimals a zero preceding the decimal point or any zero in the fourth decimal place is omitted. All dimensions are in inches. Crown Radius, I: The crown radius has the same value as the basic screw diameter to three decimal places. Oval Point Radius, R: Values of the oval point radius according to nominal screw size are: For a screw size of 0, a radius of .045; 1, .055; 2, .064; 3, .074; 4, .084; 5, .094; 6, .104; 8, .123; 10, .142; 12, .162; 1⁄4, .188; 5⁄16, .234; 3⁄8, .281; 7⁄16, .328; 1⁄2, .375; 9⁄16, .422; 5⁄8, .469; and for 3⁄4, .562. Cone Point Angle, Y: The cone point angle is 90° ± 2° for the following nominal lengths, or longer, shown according to screw size: For nominal size 0, a length of 5⁄64; 1, 3⁄32; 2, 7⁄64; 3, 1⁄8; 4, 5⁄32; 5, 3⁄16; 6, 3⁄16; 8, 1⁄4; 10, 1⁄4; 12, 5⁄16; 1⁄4, 5⁄16; 5⁄16, 3⁄8; 3⁄8, 7⁄16; 7⁄16, 1⁄2; 1⁄2, 9⁄16; 9⁄16, 5⁄8; 5⁄8, 3⁄4; and for 3⁄4, 7⁄8. For shorter screws, the cone point angle is 118° ± 2°. Point Angle X: The point angle is 45°, + 5°, − 0°, for screws of nominal lengths, or longer, as given just above for cone point angle, and 30°, min. for shorter screws. Threads: are Unified Standard Class 2A; UNC and UNF Series or UNRC and UNRF Series.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1626
SET SCREWS
Table 10. American National Standard Hexagon and Spline Socket Set Screw Optional Cup Points ANSI/ASME B18.3-1998
TYPE A
TYPE B
TYPE C
TYPE D
* This diameter may be counterbored.
TYPE E
TYPE F
Point Dia. Nom. Size
Max.
Min.
Max.
C 0 1 2 3 4 5 6 8 10
TYPE G
Point Dia. Min.
Point Dia. Max.
C1
Point Length
Min.
Max.
C2
Min. S
1⁄ 4
0.033 0.040 0.047 0.054 0.061 0.067 0.074 0.087 0.102 0.132
0.027 0.033 0.039 0.045 0.051 0.057 0.064 0.076 0.088 0.118
0.032 0.038 0.043 0.050 0.056 0.062 0.069 0.082 0.095 0.125
0.027 0.033 0.038 0.045 0.051 0.056 0.062 0.074 0.086 0.114
0.027 0.035 0.043 0.051 0.059 0.068 0.074 0.090 0.101 0.156
0.022 0.030 0.038 0.046 0.054 0.063 0.068 0.084 0.095 0.150
0.007 0.008 0.010 0.011 0.013 0.014 0.017 0.021 0.024 0.027
0.004 0.005 0.007 0.007 0.008 0.009 0.012 0.016 0.019 0.022
5⁄ 16
0.172
0.156
0.156
0.144
0.190
0.185
0.038
0.033
3⁄ 8
0.212
0.194
0.187
0.174
0.241
0.236
0.041
0.036
7⁄ 16
0.252
0.232
0.218
0.204
0.286
0.281
0.047
0.042
1⁄ 2
0.291
0.270
0.250
0.235
0.333
0.328
0.054
0.049
5⁄ 8
0.371
0.347
0.312
0.295
0.425
0.420
0.067
0.062
3⁄ 4
0.450
0.425
0.375
0.357
0.523
0.518
0.081
0.076
7⁄ 8
1 11⁄8
0.530 0.609 0.689
0.502 0.579 0.655
0.437 0.500 0.562
0.418 0.480 0.542
… … …
… … …
… … …
… … …
11⁄4
0.767
0.733
0.625
0.605
…
…
…
…
13⁄8
0.848
0.808
0.687
0.667
…
…
…
…
11⁄2
0.926
0.886
0.750
0.730
…
…
…
…
13⁄4
1.086 1.244
1.039 1.193
0.875 1.000
0.855 0.980
… …
… …
… …
… …
2
All dimensions are in inches. The cup point types shown are those available from various manufacturers.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SET SCREWS
1627
Table 11. American National Standard Hexagon and Spline Sockets ANSI/ASME B18.3-1998
BROACHED SOCKET
Nominal Socket Size 0.028 0.035 0.050 1⁄ 16 5⁄ 64 3⁄ 32 7⁄ 64 1⁄ 8
Socket Width Across Flats Max. Min. J 0.0285 0.0355 0.0510 0.0635 0.0791 0.0952 0.1111 0.1270
0.0280 0.0350 0.0500 0.0625 0.0781 0.0937 0.1094 0.1250
Nominal Socket Size 9⁄ 64 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 5⁄ 16 3⁄ 8
…
HEXAGON SOCKETS Socket Socket Width Width Across Flats Across Flats Nominal Max. Min. Max. Min. Socket J J Size 0.1426 0.1587 0.1900 0.2217 0.2530 0.3160 0.3790 …
0.1406 0.1562 0.1875 0.2187 0.2500 0.3125 0.3750 …
7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 7⁄ 8
0.4420 0.5050 0.5680 0.6310 0.7570 0.8850 1.0200 …
1 …
0.4375 0.5000 0.5625 0.6250 0.7500 0.8750 1.0000 …
Nominal Socket Size 11⁄4 11⁄2 13⁄4 2 21⁄4 23⁄4 3 …
Socket Width Across Flats Max. Min. J 1.2750 1.5300 1.7850 2.0400 2.2950 2.8050 3.0600 …
1.2500 1.5000 1.7500 2.0000 2.2500 2.7500 3.0000 …
SPLINE SOCKETS Nominal Socket Size
Number of Teeth
0.033 0.048 0.060 0.072 0.096 0.111 0.133 0.145 0.168 0.183 0.216 0.251 0.291 0.372 0.454 0.595 0.620 0.698 0.790
4 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6
Socket Major Diameter Max. Min. M 0.0350 0.050 0.062 0.074 0.098 0.115 0.137 0.149 0.173 0.188 0.221 0.256 0.298 0.380 0.463 0.604 0.631 0.709 0.801
0.0340 0.049 0.061 0.073 0.097 0.113 0.135 0.147 0.171 0.186 0.219 0.254 0.296 0.377 0.460 0.601 0.627 0.705 0.797
Socket Minor Diameter Min. N
Max.
0.0260 0.041 0.051 0.064 0.082 0.098 0.118 0.128 0.150 0.163 0.190 0.221 0.254 0.319 0.386 0.509 0.535 0.604 0.685
0.0255 0.040 0.050 0.063 0.080 0.096 0.116 0.126 0.147 0.161 0.188 0.219 0.252 0.316 0.383 0.506 0.531 0.600 0.681
Width of Tooth Max.
Min. P
0.0120 0.011 0.014 0.016 0.022 0.025 0.030 0.032 0.036 0.039 0.050 0.060 0.068 0.092 0.112 0.138 0.149 0.168 0.189
0.0115 0.010 0.013 0.015 0.021 0.023 0.028 0.030 0.033 0.037 0.048 0.058 0.066 0.089 0.109 0.134 0.145 0.164 0.185
All dimensions are in inches. * Socket depths, T, for various screw types are given in the standard but are not shown here. Where sockets are chamfered, the depth of chamfer shall not exceed 10 per cent of the nominal socket size for sizes up to and including 1⁄16 inch for hexagon sockets and 0.060 for spline sockets, and 7.5 per cent for larger sizes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1628
SET SCREWS Table 12. American National Standard Square Head Set Screws ANSI/ASME B18.6.2-1998
FLAT POINT
DOG POINT HALF DOG POINT
CUP POINT Nominal Size* or Basic Screw Diameter
OVAL POINT
Cup and Flat Point Diams., C
CONE POINT Point Length
Dog and Half Dog Point Diams., P
Dog, Q
Half Dog, Q1
Oval Point Rad., R
Max.
Min
Max.
Max.
Min.
Max.
Min.
+.031 −.000
0.1900
.102
.088
.127
.120
.095
.085
.050
.040
.142
1⁄ 4
0.2500
.132
.118
.156
.149
.130
.120
.068
.058
.188
5⁄ 16
0.3125
.172
.156
.203
.195
.161
.151
.083
.073
.234
3⁄ 8
0.3750
.212
.194
.250
.241
.193
.183
.099
.089
.281
7⁄ 16
0.4375
.252
.232
.297
.287
.224
.214
.114
.104
.328
1⁄ 2
0.500
.291
.270
.344
.334
.255
.245
.130
.120
.375
9⁄ 16
0.5625
.332
.309
.391
.379
.287
.275
.146
.134
.422
5⁄ 8
0.6250
.371
.347
.469
.456
.321
.305
.164
.148
.469
3⁄ 4
0.7500
.450
.425
.562
.549
.383
.367
.196
.180
.562
7⁄ 8
0.8750
.530
.502
.656
.642
.446
.430
.227
.211
.656
1
1.0000
.609
.579
.750
.734
.510
.490
.260
.240
.750
11⁄8
1.1250
.689
.655
.844
.826
.572
.552
.291
.271
.844
11⁄4
1.2500
.767
.733
.938
.920
.635
.615
.323
.303
.938
13⁄8
1.3750
.848
.808
1.031
1.011
.698
.678
.354
.334
1.031
11⁄2
1.5000
.926
.886
1.125
1.105
.760
.740
.385
.365
1.125
10
Min.
All dimensions are in inches. *Threads: Threads are Unified Standard Class 2A; UNC, UNF and 8 UN Series or UNRC, UNRF and 8 UNR Series. Length of Thread: Square head set screws have complete (full form) threads extending over that portion of the screw length which is not affected by the point. For the respective constructions, threads extend into the neck relief, to the conical underside of head, or to within one thread (as measured with a thread ring gage) from the flat underside of the head. Threads through angular or crowned portions of points have fully formed roots with partial crests. * When specifying a nominal size in decimals, the zero preceding the decimal point is omitted as is any
zero in the fourth decimal place.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SET SCREWS
1629
Table 13. American National Standard Square Head Set Screws ANSI/ASME B18.6.2-1998
OPTIONAL HEAD CONSTRUCTIONS Nominal Size or Basic Screw Diameter
Width Across Width Across Head Height, Flats,F Corners,G H
Neck Relief Diameter, K
Neck Relief Fillet Rad.,S
Neck Relief Width, U
Head Rad.,,W Min.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
Max.
Min.
10
0.1900
.188
.180
.265
.247
.148
.134
.145
.140
.027
.083
0.48
1⁄ 4
0.2500
.250
.241
.354
.331
.196
.178
.185
.170
.032
.100
0.62
5⁄ 16
0.3125
.312
.302
.442
.415
.245
.224
.240
.225
.036
.111
0.78
3⁄ 8
0.3750
.375
.362
.530
.497
.293
.270
.294
.279
.041
.125
0.94
7⁄ 16
0.4375
.438
.423
.619
.581
.341
.315
.345
.330
.046
.143
1.09
1⁄ 2
0.5000
.500
.484
.707
.665
.389
.361
.400
.385
.050
.154
1.25
9⁄ 16
0.5625
.562
.545
.795
.748
.437
.407
.454
.439
.054
.167
1.41
5⁄ 8
0.6250
.625
.606
.884
.833
.485
.452
.507
.492
.059
.182
1.56
3⁄ 4
0.7500
.750
.729 1.060 1.001
.582
.544
.620
.605
.065
.200
1.88
7⁄ 8
0.8750
.875
.852 1.237 1.170
.678
.635
.731
.716
.072
.222
2.19
1
1.0000
1.000
.974 1.414 1.337
.774
.726
.838
.823
.081
.250
2.50
11⁄8
1.1250
1.125 1.096 1.591 1.505
.870
.817
.939
.914
.092
.283
2.81
11⁄4
1.2500
1.250 1.219 1.768 1.674
.966
.908 1.064 1.039
.092
.283
3.12
13⁄8
1.3750
1.375 1.342 1.945 1.843 1.063 1.000 1.159 1.134
.109
.333
3.44
11⁄2
1.5000
1.500 1.464 2.121 2.010 1.159 1.091 1.284 1.259
.109
.333
3.75
Designation: Square head set screws are designated by the following data in the sequence shown: Nominal size (number, fraction or decimal equivalent); threads per inch; screw length (fraction or decimal equivalent); product name; point style; material; and protective finish, if required. Examples: 1⁄4 - 20 × 3⁄4 Square Head Set Screw, Flat Point, Steel, Cadmium Plated. .500 − 13 × 1.25 Square Head Set Screw, Cone Point, Corrosion Resistant Steel. Cone Point Angle, Y: For the following nominal lengths, or longer, shown according to nominal size, the cone point angle is 90° ± 2°: For size No. 10, 1⁄4; 1⁄4, 5⁄16; 5⁄16, 3⁄8; 3⁄8, 7⁄16; 7⁄16, 1⁄2; 1⁄2, 9⁄16; 9⁄16, 5⁄8; 5⁄8, 3⁄4; 3⁄ , 7⁄ ; 7⁄ , 1; 1, 11⁄ ; 11⁄ , 11⁄ ; 11⁄ , 11⁄ ; 13⁄ , 15⁄ ; and for 11⁄ , 13⁄ . For shorter screws the cone point angle is 4 8 8 8 8 4 4 2 8 8 2 4 118° ± 2°. Point Types: Unless otherwise specified, square head set screws are supplied with cup points. Cup points as furnished by some manufacturers may be externally or internally knurled. Where so specified by the purchaser, screws have cone, dog, half-dog, flat or oval points as given on the following page. Point Angle, X: The point angle is 45°, + 5°, − 0° for screws of the nominal lengths, or longer, given just above for cone point angle, and 30° min. for shorter lengths.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1630
SCREW SOCKET KEYS AND BITS Table 14. Applicability of Hexagon and Spline Keys and Bits
Nominal Key or Bit Size
Cap Screws 1960 Series
Flat Countersunk Head Cap Screws
Button Head Cap Screws
Shoulder Screws
Set Screws
0 1&2 3&4 5&6
Nominal Screw Sizes HEXAGON KEYS AND BITS
1⁄ 16
0.062
… … 0 1
5⁄ 64
0.078
2&3
5&6
5&6
…
8
3⁄ 32
0.094
4&5
8
8
…
10
7⁄ 64
…
0.028 0.035 0.050
… 0 1&2 3&4
… 0 1&2 3&4
… … … …
0.109
6
…
…
…
1⁄ 8
0.125
…
10
10
1⁄ 4
1⁄ 4
9⁄ 64
0.141
8
…
…
…
… 5⁄ 16
5⁄ 32
0.156
10
1⁄ 4
1⁄ 4
5⁄ 16
3⁄ 16
0.188
1⁄ 4
5⁄ 16
5⁄ 16
3⁄ 8
3⁄ 8
7⁄ 32
0.219
…
3⁄ 8
3⁄ 8
…
7⁄ 16
1⁄ 4
0.250
5⁄ 16
7⁄ 16
…
1⁄ 2
1⁄ 2
5⁄ 16
0.312
3⁄ 8
1⁄ 2
1⁄ 2
5⁄ 8
5⁄ 8
3⁄ 8
0.375
7⁄ & 1⁄ 16 2
5⁄ 8
5⁄ 8
3⁄ 4
3⁄ 4
7⁄ 16
0.438
…
…
…
…
…
1⁄ 2
0.500
5⁄ 8
3⁄ 4
…
1
7⁄ 8
9⁄ 16
0.562
…
7⁄ 8
…
…
1 & 11⁄8
5⁄ 8
0.625
3⁄ 4
3⁄ 4
0.750
7⁄ & 8
1
…
11⁄4
11⁄4 & 13⁄8
11⁄8
…
…
7⁄ 8
0.875
11⁄2
11⁄8 & 11⁄4
11⁄4 & 13⁄8
…
11⁄2
…
13⁄4
13⁄4 & 2 …
1
1.000
13⁄8 & 11⁄2
11⁄2
…
11⁄4
1.250
13⁄4
…
…
2
11⁄2
1.500
2
…
…
…
…
1.750
21⁄4 &
…
…
…
…
2
2.000
23⁄4
…
…
…
…
21⁄4
2.250
3 & 31⁄4
…
…
…
…
… …
… …
… …
… … 0&1 2&3 4 5&6 8 10 … 1⁄ 4
1
13⁄4
23⁄4 3
2.750 3.000
31⁄2 &
21⁄2
33⁄4
4
SPLINE KEYS AND BITS … … 0 1 2&3 4&5 6 … 8 10
… 0 1&2 3&4 5&6 8 … 10 … 1⁄ 4
… 0 1&2 3&4 5&6 8 … 10 … 1⁄ 4
… … … … … … … … … …
0.216
1⁄ 4
5⁄ 16
5⁄ 16
…
3⁄ 8
0.251
…
3⁄ 8
3⁄ 8
…
7⁄ 16
0.291
5⁄ 16
7⁄ 16
…
…
1⁄ 2
0.372
3⁄ 8
1⁄ 2
1⁄ 2
…
5⁄ 8
0.454
7⁄ & 1⁄ 16 2
5⁄ & 3⁄ 8 4
5⁄ 8
…
3⁄ 4
0.595
5⁄ 8
…
…
…
7⁄ 8
0.620
3⁄ 4
…
…
…
…
0.698 0.790
7⁄ 8
… …
… …
… …
… …
0.033 0.048 0.060 0.072 0.096 0.111 0.133 0.145 0.168 0.183
1
Source: Appendix to American National Standard ANSI/ASME B18.3-1998.
Copyright 2004, Industrial Press, Inc., New York, NY
… 5⁄ 16
Machinery's Handbook 27th Edition SCREW SOCKET KEYS AND BITS
1631
Table 15. ANSI Hexagon and Spline Socket Set Screws ANSI/ASME B18.3-1998
Flat Point
Oval Point Cone Point
0 1 2 3 4 5 6 8 10 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
1 11⁄8 11⁄4 13⁄8 11⁄2 13⁄4 2
0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2500 0.3125 0.3750 0.4375 0.5000 0.6250 0.7500 0.8750 1.0000 1.1250 1.2500 1.3750 1.5000 1.7500 2.0000
Dia. Max. P
Lgth. Max. Q
Oval Point Radius Basic R
0.040 0.049 0.057 0.066 0.075 0.083 0.092 0.109 0.127 0.156 0.203 0.250 0.297 0.344 0.469 0.562 0.656 0.750 0.844 0.938 1.031 1.125 1.312 1.500
0.017 0.021 0.024 0.027 0.030 0.033 0.038 0.043 0.049 0.067 0.082 0.099 0.114 0.130 0.164 0.196 0.227 0.260 0.291 0.323 0.354 0.385 0.448 0.510
0.045 0.055 0.064 0.074 0.084 0.094 0.104 0.123 0.142 0.188 0.234 0.281 0.328 0.375 0.469 0.562 0.656 0.750 0.844 0.938 1.031 1.125 1.321 1.500
0.050 0.060 0.060 0.070 0.070 0.080 0.080 0.090 0.100 0.125 0.156 0.188 0.219 0.250 0.312 0.375 0.500 0.562 0.562 0.625 0.625 0.750 1.000 1.000
Half Dog
Cup Point
Socket Size Nominal Size or Basic Screw Diameter
For optional cup points and their dimensions see Table 10. Min. Key Engagement Lgth. Depth Limit for Hex. Spl. Angle T Ha TSa Yb
Hex. Nom. J
Spl. Nom. M
0.028 0.035 0.035 0.050 0.050 1⁄ 16 1⁄ 16 5⁄ 64 3⁄ 32 1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 5⁄ 16 3⁄ 8 1⁄ 2 9⁄ 16 9⁄ 16 5⁄ 8 5⁄ 8 3⁄ 4 1 1
0.033 0.033 0.048 0.048 0.060 0.072 0.072 0.096 0.111 0.145 0.183 0.216 0.251 0.291 0.372 0.454 0.595 … … … … … … …
Half Dog Point Cup and Flat Point Diameters Max. Min. C 0.033 0.040 0.047 0.054 0.061 0.067 0.074 0.087 0.102 0.132 0.172 0.212 0.252 0.291 0.371 0.450 0.530 0.609 0.689 0.767 0.848 0.926 1.086 1.244
0.027 0.033 0.039 0.045 0.051 0.057 0.064 0.076 0.088 0.118 0.156 0.194 0.232 0.270 0.347 0.425 0.502 0.579 0.655 0.733 0.808 0.886 1.039 1.193
0.026 0.035 0.040 0.040 0.045 0.055 0.055 0.080 0.080 0.125 0.156 0.188 0.219 0.250 0.312 0.375 0.500 … … … … … … …
0.09 0.09 0.13 0.13 0.19 0.19 0.19 0.25 0.25 0.31 0.38 0.44 0.50 0.57 0.75 0.88 1.00 1.13 1.25 1.50 1.63 1.75 2.00 2.25
a Reference should be made to the Standard for shortest optimum nominal lengths to which the minimum key engagement depths TH and TS apply. b Cone point angle Y is 90 degrees plus or minus 2 degrees for these nominal lengths or longer and 118 degrees plus or minus 2 degrees for shorter nominal lengths. All dimensions are in inches. The thread conforms to the Unified Standard, Class 3A, UNC and UNF series. The socket depth T is included in the Standard and some are shown here. The nominal length L of all socket type set screws is the total or overall length. For nominal screw lengths of 1⁄16 through 3⁄16 inch (0 through 3 sizes incl.) the standard length increment is 0.06 inch; for lengths 1⁄8 through 1 inch the increment is 1⁄8 inch; for lengths 1 through 2 inches the increment is 1⁄4 inch; for lengths 2 through 6 inches the increment is 1⁄2 inch; for lengths 6 inches and longer the increment is 1 inch. Socket dimensions are given in Table 11. Length Tolerance: The allowable tolerance on length L for all set screws of the socket type is ± 0.01 inch for set screws up to 5⁄8 inch long; ± 0.02 inch for screws over 5⁄8 to 2 inches long; ± 0.03 inch for screws over 2 to 6 inches long and ± 0.06 inch for screws over 6 inches long. Socket dimensions are given in Table 11. For manufacturing details, including materials, not shown, see American National Standard ANSI/ASME B18.3-1998.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1632
HEXAGON SOCKET SCREWS
British Standard Hexagon Socket Screws — Metric Series.—The first five parts of British Standard BS 4168: 1981 provide specifications for hexagon socket head cap screws and hexagon socket set screws. Hexagon Socket Head Cap Screws: The dimensional data in Table 1 are based upon BS 4168: Part 1: 1981. These screws are available in stainless steel and alloy steel, the latter having class 12.9 properties as specified in BS 6104:Part 1. When ordering these screws, the designation “Hexagon socket head cap screw BS 4168 M5 × 20-12.9” would mean, as an example, a cap screw having a thread size of d = M5, nominal length l = 20 mm, and property class 12.9. Alloy steel cap screws are furnished with a black oxide finish (thermal or chemical); stainless steel cap screws with a plain finish. Combinations of thread size, nominal length, and length of thread are shown in Table 2; the screw threads in these combinations are in the ISO metric coarse pitch series specified in BS 3643 with tolerances in the 5g6g class. (See Metric Screw Threads in Index.) Hexagon Socket Set Screws: Part 2 of B.S. 4168:1981 specifies requirements for hexagon socket set screws with fiat point having ISO metric threads, and diameters from 1.6 mm up to and including 24 mm. The dimensions of these set screws along with those of cone-point, dog-point, and cup-point set screws in accord, respectively, with Parts 3, 4, and 5 of the Standard are given in Table 3 and the accompanying illustration. All of these set screws are available in either steel processed to mechanical properties class 45H B.S. 6104:Part 3; or stainless steel processed to mechanical properties described in B.S. 6105. Steel set screws are furnished with black oxide (thermal or chemical) finish; stainless steel set screws are furnished plain. The tolerances applied to the threads of these set screws are for ISO product grade A, based on ISO 4759⁄1-1978 “Tolerances for fasteners — Part 1: Bolts, screws, and nuts with thread diameters greater than or equal to 1.6 mm and less than or equal to 150 mm and product grades A, B, and C.” Hexagon socket set screws are designated by the type, the thread size, nominal length, and property class. As an example, for a flat-point set screw of thread size d = M6, nominal length l = 12 mm, and property class 45H: Hexagon socket set screw flat point BS 4168 M6 × 12-45H British Standard Hexagon Socket Countersunk and Button Head Screws — Metric Series: British Standard BS 4168:1967 provides a metric series of hexagon socket countersunk and button head screws. The dimensions of these screws are given in Table 4. The revision of this Standard will constitute Parts 6 and 8 of BS 4168. British Standards for Mechanical Properties of Fasteners: B.S. 6104: Part 1:1981 specifies mechanical properties for bolts, screws, and studs with nominal diameters up to and including 39 mm of any triangular ISO thread and made of carbon or alloy steel. It does not apply to set screws and similar threaded fasteners. Part 2 of this Standard specifies the mechanical properties of set screws and similar fasteners, not under tensile stress, in the range from M1.6 up to and including M39 and made of carbon or alloy steel. B.S. 6105:1981 provides specifications for bolts, screws, studs, and nuts made from austenitic, ferritic, and martensitic grades of corrosion-resistant steels. This Standard applies only to fastener components after completion of manufacture with nominal diameters from M1.6 up to and including M39. These Standards are not described further here. Copies may be obtained from the British Standards Institution, 2 Park Street, London W1A 2BS and also from the American National Standards Institute, 25 West 43rd Street, New York, N.Y. 10036.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 1. British Standard Hexagon Socket Head Cap Screws—Metric Series BS 4168:Part 1:1981 (obsolescent)
Body Diameter, D Max 1.6 2 2.5 3 4 5 6 8 10 12 14 16 20 24 30 36
Min 1.46 1.86 2.36 2.86 3.82 4.82 5.82 7.78 9.78 11.73 13.73 15.73 19.67 23.67 29.67 35.61
Maxc 3 3.8 4.5 5.5 7 8.5 10 13 16 18 21 24 30 36 45 54
Head Diameter, A Maxd 3.14 3.98 4.68 5.68 7.22 8.72 10.22 13.27 16.27 18.27 21.33 24.33 30.33 36.39 45.39 54.46
Head Height, H Min 2.86 3.62 4.32 5.32 6.78 8.28 9.78 12.73 15.73 17.73 20.67 23.67 29.67 35.61 44.61 53.54
Max 1.6 2 2.5 3 4 5 6 8 10 12 14 16 20 24 30 36
Min 1.46 1.86 2.36 2.86 3.82 4.82 5.70 7.64 9.64 11.57 13.57 15.57 19.48 23.48 29.48 35.38
Hexagon Socket Size, Jb Nom 1.5 1.5 2 2.5 3 4 5 6 8 10 12 14 17. 19 22 27
Key Engagement, K Min 0.7 1 1.1 1.3 2 2.5 3 4 5 6 7 8 10 12 15.5 19
Wall Thickness, W Min 0.55 0.55 0.85 1.15 1.4 1.9 2.3 3.3 4 4.8 5.8 6.8 8.6 10.4 13.1 15.3
Fillet Dia., Rad., da F Min Max 0.1 2 0.1 2.6 0.1 3.1 0.1 3.6 0.2 4.7 0.2 5.7 0.25 6.8 0.4 9.2 0.4 11.2 0.6 14.2 0.6 16.2 0.6 18.2 0.8 22.4 0.8 26.4 1 33.4 1 39.4
CAP SCREWS
Nominal Size,a d M1.6 M2 M2.5 M3 M4 M5 M6 M8 M10 M12 (M14) M16 M20 M24 M30 M36
a The size shown in ( ) is non-preferred. b See Table 2 for min/max. c For plain heads.
1633
d For knurled heads.
All dimensions are given in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1634
SCREW SOCKETS Table 2. British Standard Hexagon Socket Screws — Metric Series BS 4168:Part 1:1981 (obsolescent) Dimensions of Hexagon Sockets
Socket Width Across Flats, J
Nominal Socket Size
Socket Width Across Flats, J
Max.
Min.
Nominal Socket Size
1.5
1.545
1.52
6
6.095
2.0
2.045
2.02
8
8.115
8.025
2.5
2.56
2.52
10
10.115
10.025
3
3.08
3.02
12
12.142
12.032
4
4.095
4.02
14
14.142
14.032
5
5.095
5.02
17
17.23
17.05
…
…
19
19.275
19.065
…
Max.
Min. 6.02
15
16
17
18
20
22
24
28
M36
… …
M30
… …
M24
… …
M20
… …
M16
… …
(M14)
… …
M12
… …
Nominal Length, L
M8
M6
M5
M4
M3
M2.5
M2
… …
16 20 25 30 35 40 45 50 55 60 65 70 80 90 100 110 120 130 140 150 160 180 200 b (ref)
Nominal Thread Size, D M10
2.5 3 4 5 6 8 10 12 16 20 25 30 35 40 45 50 55 60 65 70 80 … … b (ref)
Nominal Thread Size, D M1.6
Nominal Length, L
Association of Nominal and Thread Lengths for Each Thread Size
32
36
40
44
52
60
72
84
All dimensions are in millimeters. The popular lengths are those between the stepped solid lines. Lengths above the shaded areas are threaded to the head within 3 pitch lengths (3P). Lengths within and below the shaded areas have values of Lg and Ls (see Table 1) given by the formulas: Lgmax = L nom − b ref, and Lsmin = Lgmax − 5P.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 3. British Standard Hexagon Socket Set Screws — Metric Series BS 4168:Parts 2, 3, 4, and 5:1994
Socket Size, s
Depth of Key Engagement, ta
Length of Dog on Dog Point Screwsb
Range of Popular Lengths Flat Point
Cone Point
Dog Point
Cup Point
Short Dog, z
End Diameters Cone Point dt
Dog Point, dp
Cup Point, dz
b
max
max
max
max
2.5
0.8
0
0.8
0.8
3.0
1.0
0
1.0
1.0
1.5
4
1.5
0
1.5
1.2
1.75
5
2.0
0
2.0
1.4
Pitch, P
nom
min
min
l
l
l
l
min
M1.6
0.35
0.7
0.7
1.5
2–8
2–8
2–8
2–8
0.4
0.65
0.8
1.05
M2
0.4
0.9
0.8
1.7
2–10
2–10
2.5–10
2–10
0.5
0.75
1.0
1.25
M2.5
0.45
1.3
1.2
2.0
2–12
2.5–12
3–12
2–12
0.63
0.88
1.25
M3
0.5
1.5
1.2
2.0
2–16
2.5–16
4–16
2.5–16
0.75
1.0
1.5
M4
0.7
2.0
1.5
2.5
2.5–20
3–20
5–20
3–20
1.0
1.25
2.0
2.25
6
2.5
0
2.5
2.0
M5
0.8
2.5
2.0
3.0
3–25
4–25
6–25
4–25
1.25
1.5
2.5
2.75
6
3.5
0
3.5
2.5
M6
1.0
3.0
2.0
3.5
4–30
5–30
8–30
5–30
1.5
1.75
3.0
3.25
8
4.0
1.5
4.0
3.0
M8
1.25
4.0
3.0
5.0
5–40
6–40
8–40
6–40
2.0
2.25
4.0
4.3
10
5.5
2.0
5.5
5.0
M10
1.5
5.0
4.0
6.0
6–50
8–50
10–50
8–50
2.5
2.75
5.0
5.3
12
7.0
2.5
7.0
6.0
M12
1.75
6.0
4.8
8.0
8–60
10–60
12–60
10–60
3.0
3.25
6.0
6.3
16
8.5
3.0
8.5
8.0
M16
2.0
8.0
6.4
10.0
10–60
12–60
16–60
12–60
4.0
4.3
8.0
8.36
20
12.0
4.0
12.0
10.0
M20
2.5
10.0
8.0
12.0
12–60
16–60
20–60
16–60
5.0
5.3
10.0
10.36
25
15.0
5.0
15.0
14.0
M24
3.0
12.0
10.0
15.0
16–60
20–60
25–60
20–60
6.0
6.3
12.0
12.43
30
18.0
6.0
18.0
16.0
max
min
max
SCREW SOCKETS
Flat Point, dz
Long Dog, z
Nom. Size, d
a The smaller of the two t min. values applies to certain short-length set screws. These short-length screws are those whose length is approximately equal to the diameter
All dimensions are in millimeters. For dimensional notation, see diagram, page 1637.
Copyright 2004, Industrial Press, Inc., New York, NY
1635
of the screw. The larger t min. values apply to longer-length screws. b A dog point set screw having a nominal length equal to or less than the length shown in the (*) column of the table is supplied with length z shown in the short dog column. For set screws of lengths greater than shown in the (*) column, z for long dogs applies.
Machinery's Handbook 27th Edition 1636
SCREW SOCKETS Table 4. British Standard Hexagon Socket Countersunk and Button Head Screws — Metric Series BS 4168:1967
COUNTERSUNK HEADSCREWS Body Diameter, D
Head Diameter, A
Head Height, H
Hexagon Socket Size, J
Key Engagement, K
Fillet Radius, F
Max.
Min.
Theor. Sharp Max.
Nom.
Min.
Max.
M3
3.00
2.86
6.72
5.82
1.86
0.20
2.00
1.05
0.40
M4
4.00
3.82
8.96
7.78
2.48
0.20
2.50
1.49
0.40
M5
5.00
4.82
11.20
9.78
3.10
0.20
3.00
1.86
0.40
Nom. Sizea
M6
Absolute Min.
Ref.
Flushness Tolerance
6.00
5.82
13.44
11.73
3.72
0.20
4.00
2.16
0.60
M8
8.00
7.78
17.92
15.73
4.96
0.24
5.00
2.85
0.70
M10
10.00
9.78
22.40
19.67
6.20
0.30
6.00
3.60
0.80
M12
12.00
11.73
26.88
23.67
7.44
0.36
8.00
4.35
1.10
(M14)
14.00
13.73
30.24
26.67
8.12
0.40
10.00
4.65
1.10
M16
16.00
15.73
33.60
29.67
8.80
0.45
10.00
4.89
1.10
(M18)
18.00
17.73
36.96
32.61
9.48
0.50
12.00
5.25
1.10
M20
20.00
19.67
40.32
35.61
10.16
0.54
12.00
5.45
1.10
a Sizes shown in parentheses are non-preferred.
BUTTON HEADSCREWS
Nom. Size, D
Head Diameter,
Head Height,
Head Side Height,
Hexagon Socket Size,
Key Engagement,
A
H
S
J
K
F
da
Fillet Radius
Max.
Min.
Max.
Min.
Ref.
Nom.
Min.
Min.
Max.
M3
5.50
5.32
1.60
1.40
0.38
2.00
1.04
0.10
3.60
M4
7.50
7.28
2.10
1.85
0.38
2.50
1.30
0.20
4.70
M5
9.50
9.28
2.70
2.45
0.50
3.00
1.56
0.20
5.70
M6
10.50
10.23
3.20
2.95
0.80
4.00
2.08
0.25
6.80
M8
14.00
13.73
4.30
3.95
0.80
5.00
2.60
0.40
9.20
M10
18.00
17.73
5.30
4.95
0.80
6.00
3.12
0.40
11.20
M12
21.00
20.67
6.40
5.90
0.80
8.00
4.16
0.60
14.20
All dimensions are given in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SET SCREWS
1637
British Standard Hexagon Socket Set Screws — Metric Series BS 4168:Parts 2, 3, 4, and 5:1994
FLAT POINT
CUP POINT
DOG POINT
CONE POINT
ALTERNATE CONE POINT (M6 AND LARGER)
*The 120° angle is mandatory for short-length screws shown in the Standard. Short-length screws are those whose length is, approximately, equal to the diameter of the screw. **The 45° angle applies only to that portion of the point below the root diameter, df, of the thread. ***The cone angle applies only to the portion of the point below the root diameter, df, of the thread and shall be 120° for certain short lengths listed in the Standard. All other lengths have a 90° cone angle. †The popular length ranges of these set screws are listed in Table 3. These lengths have been selected from the following nominal lengths: 2, 2.5, 3, 4, 6, 8, 10, 12, 16, 20, 25,30, 35, 40, 45, 50, 55, and 60 millimeters.
Holding Power of Set-screws.—While the amount of power a set-screw of given size will transmit without slipping (when used for holding a pulley, gear, or other part from turning relative to a shaft) varies somewhat according to the physical properties of both set-screw and shaft and other variable factors, experiments have shown that the safe holding force in pounds for different diameters of set-screws should be approximately as follows: For 1⁄4-inch diameter set-screws the safe holding force is 100 pounds, for 3⁄8-inch
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1638
COUNTERSUNK AND BUTTON HEAD SCREWS
diameter set-screws the safe holding force is 250 pounds, for 1⁄2-inch diameter set-screws the safe holding force is 500 pounds, for 3⁄4-inch diameter set-screws the safe holding force is 1300 pounds, and for 1-inch diameter set-screws the safe holding force is 2500 pounds. The power or torque that can be safely transmitted by a set-screw may be determined from the formulas, P = (DNd2.3) ÷ 50; or T = 1250Dd2.3 in which P is the horsepower transmitted; T is the torque in inch-pounds transmitted; D is the shaft diameter in inches; N is the speed of the shaft in revolutions per minute; and d is the diameter of the set-screw in inches. Example:How many 1⁄2-inch diameter set-screws would be required to transmit 3 horsepower at a shaft speed of 1000 rpm if the shaft diameter is 1 inch? Using the first formula given above, the power transmitted by a single 1⁄2-inch diameter set-screw is determined: P = [1 × 1000 × (1⁄2)2.3] ÷ 50 = 4.1 hp. Therefore a single 1⁄2-inch diameter set-screw is sufficient. Example:In the previous example, how many 3⁄8-inch diameter set-screws would be required? P = [1 × 1000 × (3⁄8)2.3] ÷ 50 = 2.1 hp. Therefore two 3⁄8-inch diameter set-screws are required. Table 5. British Standard Whitworth (BSW) and British Standard Fine (BSF) Bright Square Head Set-Screws (With Flat Chamfered Ends)
No. 1 Standard Nominal Size and Max. Dia., Inches
1
Number of Threads per Inch
No. 2 Standard
No. 3 Standard
Depth of Head B
Width Across Flats C
Depth of Head D
Width Across Flats E
Depth of Head F
BSF
Width Across Flats A
1⁄ 4
20
26
0.250
0.250
0.313
0.250
0.375
0.250
5⁄ 16
18
22
0.313
0.313
0.375
0.313
0.438
0.313
3⁄ 8
16
20
0.375
0.375
0.438
0.375
0.500
0.375
7⁄ 16
14
18
0.438
0.438
0.500
0.438
0.625
0.438
1⁄ 2
12
16
0.500
0.500
0.563
0.500
0.750
0.500
5⁄ 8
11
14
0.625
0.625
0.750
0.625
0.875
0.625
3⁄ 4
10
12
0.750
0.750
0.875
0.750
1.000
0.750
7⁄ 8
9
11
0.875
0.875
1.000
0.875
1.125
0.875
8
10
1.000
1.000
1.125
1.000
1.250
1.000
BSW
* Depth of Head B, D and F same as for Width Across Flats, No. 1 Standard. Dimensions A, B, C, D, E, and F are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SELF-THREADING SCREWS
1639
SELF-THREADING SCREWS ANSI Standard Sheet Metal, Self-Tapping, and Metallic Drive Screws.—T a b l e 1 shows the various types of “self-tapping” screw threads covered by the ANSI B18.6.41981 (R1991) standard. (Metric thread forming and thread cutting tapping screws are discussed beginning on page 1654). ANSI designations are also shown. Types A, AB, B, BP and C when turned into a hole of proper size form a thread by a displacing action. Types D, F, G, T, BF and BT when turned into a hole of proper size form a thread by a cutting action. Type U when driven into a hole of proper size forms a series of multiple threads by a displacing action. These screws have the following descriptions and applications: Type A: Spaced-thread screw with gimlet point primarily for use in light sheet metal, resin-impregnated plywood, and asbestos compositions. This type is no longer recommended. Use Type AB in new designs and whenever possible substitute for Type A in existing designs. Type AB: Spaced-thread screw with same pitches as Type B but with gimlet point, primarily for similar uses as for Type A. Type B: Spaced-thread screw with a blunt point with pitches generally somewhat finer than Type A. Used for thin metal, non-ferrous castings, plastics, resin-impregnated plywood, and asbestos compositions. Type BP: Spaced-thread screw, the same as Type B but having a conical point extending beyond incomplete entering threads. Used for piercing fabrics or in assemblies where holes are misaligned. Type C: Screws having machine screw diameter-pitch combinations with threads approximately Unified Form and with blunt tapered points. Used where a machine screw thread is preferable to the spaced-thread types of thread forming screws. Also useful when chips from machine screw thread-cutting screws are objectionable. In view of the declining use of Type C screws, which in general require high driving torques, in favor of more efficient designs of thread tapping screws, they are not recommended for new designs. Types D, F, G, and T: Thread-cutting screws with threads approximating machine screw threads, with blunt point, and with tapered entering threads having one or more cutting edges and chip cavities. The tapered threads of the Type F may be complete or incomplete at the producer's option; all other types have incomplete tapered threads. These screws can be used in materials such as aluminum, zinc, and lead die-castings; steel sheets and shapes; cast iron; brass; and plastics. Types BF and BT: Thread-cutting screws with spaced threads as in Type B, with blunt points, and one or more cutting grooves. Used in plastics, asbestos, and other similar compositions. Type U: Multiple-threaded drive screw with large helix angle, having a pilot point, for use in metal and plastics. This screw is forced into the work by pressure and is intended for making permanent fastenings. ANSI Standard Head Types for Tapping and Metallic Drive Screws: Many of the head types used with “self-tapping” screw threads are similar to the head types of American National Standard machine screws shown in the section with that heading. Round Head: The round head has a semi-elliptical top surface and a flat bearing surface. Because of the superior slot driving characteristics of pan head screws over round head screws, and the overlap in dimensions of cross recessed pan heads and round heads, it is recommended that pan head screws be used in new designs and wherever possible substituted in existing designs. Undercut Flat and Oval Countersunk Heads: For short lengths, 82-degree and oval countersunk head tapping screws have heads undercut to 70 per cent of normal side height to afford greater length of thread on the screws.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1640
SELF-THREADING SCREWS
Flat Countersunk Head: The flat countersunk head has a flat top surface and a conical bearing surface with a head angle for one design of approximately 82 degrees and for another design of approximately 100 degrees. Because of its limited usage and in the interest of curtailing product varieties, the 100-degree flat countersunk head is considered nonpreferred. Oval Countersunk Head: The oval countersunk head has a rounded top surface and a conical bearing surface with a head angle of approximately 82 degrees. Flat and Oval Countersunk Trim Heads: Flat and oval countersunk trim heads are similar to the 82-degree flat and oval countersunk heads except that the size of head for a given size screw is one (large trim head) or two (small trim head) sizes smaller than the regular flat and oval countersunk head size. Oval countersunk trim heads have a definite radius where the curved top surface meets the conical bearing surface. Trim heads are furnished only in cross recessed types. Pan Head: The slotted pan head has a flat top surface rounded into cylindrical sides and a flat bearing surface. The recessed pan head has a rounded top and a flat bearing surface. This head type is now preferred to the round head. Fillister Head: The fillister head has a rounded top surface, cylindrical sides, and a flat bearing surface. Hex Head: The hex head has a flat or indented top surface, six flat sides, and a flat bearing surface. Because the slotted hex head requires a secondary operation in manufacture which often results in burrs at the extremity of the slot that interfere with socket wrench engagement and the wrenching capability of the hex far exceeds that of the slot, it is not recommended for new designs. Hex Washer Head: The hex washer head has an indented top surface and six flat sides formed integrally with a flat washer that projects beyond the sides and provides a flat bearing surface. Because the slotted hex washer head requires a secondary operation in manufacture which often results in burrs at the extremity of the slot that often interferes with socket wrench engagement and because the wrenching capability of the hex far exceeds that of the slot in the indented head, it is not recommended for new designs. Truss Head: The truss head has a low rounded top surface with a flat bearing surface, the diameter of which for a given screw size is larger than the diameter of the corresponding round head. In the interest of product simplification and recognizing that the truss head is an inherently weak design, it is not recommended for new designs. Method of Designation.—Tapping screws are designated by the following data in the sequence shown: Nominal size (number, fraction or decimal equivalent); threads per inch; nominal length (fraction or decimal equivalent); point type; product name, including head type and driving provision; material; and protective finish, if required. Examples: 1⁄ –14 × 11⁄ Type AB Slotted Pan Head Tapping Screw, Steel, Nickel Plated 4 2
6–32 × 3⁄4 Type T, Type 1A Cross Recessed Pan Head Tapping Screw, Corrosion Resistant Steel 0.375–16 × 1.50 Type D, Washer Head Tapping Screw, Steel Metallic Drive Screws: Type U metallic drive screws are designated by the following data in the sequence shown: Nominal size (number, fraction, or decimal equivalent); nominal length (fraction or decimal equivalent); product name, including head type; material; and protective finish, if required. Examples: 10 × 5⁄16 Round Head Metallic Drive Screw, Steel 0.312 × 0.50 Round Head Metallic Drive Screw, Steel, Zinc Plated
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SELF-THREADING SCREWS
1641
Table 1. ANSI Standard Threads and Points for Thread Forming Self-Tapping Screws ANSI B18.6.4-1981 (R1991)
See Tables 3, 5, and 6 for thread data.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1642
SELF-THREADING SCREWS Table 2. ANSI Standard Threads and Points for Thread Cutting Self-Tapping Screws ANSI B18.6.4-1981 (R1991)
See Tables 5 and 7 for thread data.
Cross Recesses.—Type I cross recess has a large center opening, tapered wings, and blunt bottom, with all edges relieved or rounded. Type IA cross recess has a large center opening, wide straight wings, and blunt bottom, with all edges relieved or rounded. Type II consists of two intersecting slots with parallel sides converging to a slightly truncated apex at the bottom of the recess. Type III has a square center opening, slightly tapered side walls, and a conical bottom, with top edges relieved or rounded. Table 3. ANSI Standard Cross Recesses for Self-Tapping Screws ANSI B18.6.4-1981 (R1991) and Metric Thread Forming and Thread Cutting Tapping Screws ANSI/ASME B18.6.5M-1986
TYPE I
TYPE IA
TYPE II
Copyright 2004, Industrial Press, Inc., New York, NY
TYPE III
Machinery's Handbook 27th Edition SELF-THREADING SCREWS
1643
Table 4. ANSI Standard Thread and Point Dimensions for Types AB, A and U Thread Forming Tapping Screws ANSI B18.6.4-1981 (R1991) Nominal Size or Basic Screw Diameter 0 1 2 3 4 5 6 7 8 10 12
0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1510 0.1640 0.1900 0.2160
1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2
0.2500 0.3125 0.3750 0.4375 0.5000
Type AB (Formerly BA) D d Major Minor Diameter Diameter Max. Min. Max. Min.
Threads per inch 48 42 32 28 24 20 20 19 18 16 14 14 12 12 10 10
0.060 0.075 0.088 0.101 0.114 0.130 0.139 0.154 0.166 0.189 0.215 0.246 0.315 0.380 0.440 0.504
0.054 0.069 0.082 0.095 0.108 0.123 0.132 0.147 0.159 0.182 0.208 0.237 0.306 0.371 0.429 0.493
0.036 0.049 0.064 0.075 0.086 0.094 0.104 0.115 0.122 0.141 0.164 0.192 0.244 0.309 0.359 0.423
L Minimum Practical Screw Lengths 90° Heads Csk. Heads 1⁄ 8 5⁄ 32 3⁄ 16 3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 5⁄ 16 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
0.033 0.046 0.060 0.071 0.082 0.090 0.099 0.109 0.116 0.135 0.157 0.185 0.236 0.299 0.349 0.413
5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 3⁄ 8 7⁄ 16 21⁄ 32 19⁄ 32 3⁄ 4 29⁄ 32 11⁄32 15⁄32
1
Type A Nominal Sizea Basic Screw Diameter 0 1 2 3 4 5 6 7 8 10 12 14 16 18 20 24
Threads per inch
0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1510 0.1640 0.1900 0.2160 0.2420 0.2680 0.2940 0.3200 0.3720
40 32 32 28 24 20 18 16 15 12 11 10 10 9 9 9
D
d
Major Diameter Max. Min.
Minor Diameter Max. Min.
0.060 0.075 0.088 0.101 0.114 0.130 0.141 0.158 0.168 0.194 0.221 0.254 0.280 0.306 0.333 0.390
0.042 0.051 0.061 0.076 0.083 0.095 0.102 0.114 0.123 0.133 0.162 0.185 0.197 0.217 0.234 0.291
0.057 0.072 0.084 0.097 0.110 0.126 0.136 0.152 0.162 0.188 0.215 0.248 0.274 0.300 0.327 0.383
L These Lengths or Shorter —Use Type AB 90° Heads Csk. Heads 1⁄ 8 1⁄ 8 5⁄ 32 3⁄ 16 3⁄ 16 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 11⁄ 16 3⁄ 4
0.039 0.048 0.056 0.071 0.078 0.090 0.096 0.108 0.116 0.126 0.155 0.178 0.189 0.209 0.226 0.282
3⁄ 16 3⁄ 16 3⁄ 16 7⁄ 32 1⁄ 4 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 3⁄ 4 13⁄ 16 13⁄ 16
1
a Where specifying nominal size in decimals, zeros preceding decimal and in fourth place are omit-
ted. Type U Metallic Drive Screws Out. Dia.
Pilot Dia.
Out. Dia.
Pilot Dia.
Nom. Size
No. of Starts
Max.
Min.
Max.
Min.
Nom. Size
No. of Starts
Max.
Min.
Max.
Min.
00 0 2 4 6
6 6 8 7 7
0.060 0.075 0.100 0.116 0.140
0.057 0.072 0.097 0.112 0.136
0.049 0.063 0.083 0.096 0.116
0.046 0.060 0.080 0.092 0.112
8 10 12 14 5⁄ 16
8 8 8 9 11
0.167 0.182 0.212 0.242 0.315
0.162 0.177 0.206 0.236 0.309
0.136 0.150 0.177 0.202 0.272
0.132 0.146 0.173 0.198 0.267
7
8
0.154
0.150
0.126
0.122
3⁄ 8
12
0.378
0.371
0.334
0.329
All dimensions are in inches. See Table 1 for thread diagrams. Sizes shown in bold face type are preferred. Type A screws are no longer recommended.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1644
SELF-THREADING SCREWS
Table 5. ANSI Standard Thread and Point Dimensions for B and BP Thread Forming and BF and BT Thread Cutting Tapping Screws ANSI B18.6.4-1981 (R1991) THREAD FORMING TYPES B AND BP d P S
D Nominal Sizea or Basic Screw Diameter 0 0.0600 1 0.0730 2 0.0860 3 0.0990 4 0.1120 5 0.1250 6 0.1380 7 0.1510 8 0.1640 10 0.1900 12 0.2160 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2
0.2500 0.3125 0.3750 0.4375 0.5000
Major Diameter
Thds per Inchb 48 42 32 28 24 20 20 19 18 16 14 14 12 12 10 10
Max 0.060 0.075 0.088 0.101 0.114 0.130 0.139 0.154 0.166 0.189 0.215 0.246 0.315 0.380 0.440 0.504
Min 0.054 0.069 0.082 0.095 0.108 0.123 0.132 0.147 0.159 0.182 0.208 0.237 0.306 0.371 0.429 0.493
Max 0.036 0.049 0.064 0.075 0.086 0.094 0.104 0.115 0.122 0.141 0.164 0.192 0.244 0.309 0.359 0.423
Min 0.033 0.046 0.060 0.071 0.082 0.090 0.099 0.109 0.116 0.135 0.157 0.185 0.236 0.299 0.349 0.413
Point Taper Lengthd
Point Diameterc
Minor Diameter
Max 0.031 0.044 0.058 0.068 0.079 0.087 0.095 0.105 0.112 0.130 0.152 0.179 0.230 0.293 0.343 0.407
Min 0.027 0.040 0.054 0.063 0.074 0.082 0.089 0.099 0.106 0.123 0.145 0.171 0.222 0.285 0.335 0.399
Max 0.042 0.048 0.062 0.071 0.083 0.100 0.100 0.105 0.111 0.125 0.143 0.143 0.167 0.167 0.200 0.200
Min 0.031 0.036 0.047 0.054 0.063 0.075 0.075 0.079 0.083 0.094 0.107 0.107 0.125 0.125 0.150 0.150
L Minimum Practical Nominal Screw Lengths Type B Type BP 90° Csk 90° Csk Heads Heads Heads Heads 1⁄ 8 1⁄ 8 5⁄ 32 3⁄ 16 3⁄ 16 7⁄ 32 1⁄ 4 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 15⁄ 32 17⁄ 32 5⁄ 8 11⁄ 16
1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 7⁄ 16 1⁄ 2 19⁄ 32 11⁄ 16 25⁄ 32 27⁄ 32
5⁄ 32 3⁄ 16 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 13⁄ 32 7⁄ 16 1⁄ 2 9⁄ 16 21⁄ 32 27⁄ 32 15⁄ 16 1 1 ⁄8 11⁄4
3⁄ 16 7⁄ 32 9⁄ 32 5⁄ 16 11⁄ 32 13⁄ 32 7⁄ 16 15⁄ 32 1⁄ 2 19⁄ 32 21⁄ 32 3⁄ 4 31⁄ 32 11⁄8 1 1 ⁄4 113⁄32
a Where specifying nominal size in decimals, zeros preceding decimal and in the fourth decimal place shall be omitted. b The width of flat at crest of thread shall not exceed 0.004 inch for sizes up to No. 8, inclusive, and 0.006 inch for larger sizes. c Point diameters specified apply to screw threads before roll threading. d Points of screws are tapered and fluted or slotted. The flute on Type BT screws has an included angle of 90 to 95 degrees and the thread cutting edge is located above the axis of the screw. Flutes and slots extend through first full form thread beyond taper except for Type BF screw on which tapered threads may be complete at manufacturer's option and flutes may be one pitch short of first full form thread.
THREAD CUTTING TYPES BF AND BTd d P
D Nominal Sizea or Basic Screw Diameter 0 0.0600 1 0.0730 2 0.0860 3 0.0990 4 0.1120 5 0.1250 6 0.1380 7 0.1510 8 0.1640 10 0.1900 12 0.2160 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2
0.2500 0.3125 0.3750 0.4375 0.5000
Thds per Inchb 48 42 32 28 24 20 20 19 18 16 14 14 12 12 10 10
Major Diameter Max 0.060 0.075 0.088 0.101 0.114 0.130 0.139 0.154 0.166 0.189 0.215 0.246 0.315 0.380 0.440 0.504
Min 0.054 0.069 0.082 0.095 0.108 0.123 0.132 0.147 0.159 0.182 0.208 0.237 0.306 0.371 0.429 0.493
Minor Diameter Max 0.036 0.049 0.064 0.075 0.086 0.094 0.104 0.115 0.122 0.141 0.164 0.192 0.244 0.309 0.359 0.423
Min 0.033 0.046 0.060 0.071 0.082 0.090 0.099 0.109 0.116 0.135 0.157 0.185 0.236 0.299 0.349 0.413
S Point Taper Lengthd
Point Diameterc Max 0.031 0.044 0.058 0.068 0.079 0.087 0.095 0.105 0.112 0.130 0.152 0.179 0.230 0.293 0.343 0.407
Min 0.027 0.040 0.054 0.063 0.074 0.082 0.089 0.099 0.106 0.123 0.145 0.171 0.222 0.285 0.335 0.399
Max 0.042 0.048 0.062 0.071 0.083 0.100 0.100 0.105 0.111 0.125 0.143 0.143 0.167 0.167 0.200 0.200
Min 0.031 0.036 0.047 0.054 0.063 0.075 0.075 0.079 0.083 0.094 0.107 0.107 0.125 0.125 0.150 0.150
All dimensions are in inches. See Tables 1 and 2 for thread diagrams.
Copyright 2004, Industrial Press, Inc., New York, NY
L Minimum Practical Nominal Screw Lengths 90° Csk Heads Heads 1⁄ 8 1⁄ 8 5⁄ 32 3⁄ 16 3⁄ 16 7⁄ 32 1⁄ 4 1⁄ 4 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 15⁄ 32 17⁄ 32 5⁄ 8 11⁄ 16
1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4 9⁄ 32 9⁄ 32 5⁄ 16 11⁄ 32 3⁄ 8 7⁄ 16 1⁄ 2 19⁄ 32 11⁄ 16 25⁄ 32 27⁄ 32
Machinery's Handbook 27th Edition
Table 6. Thread and Point Dimensions for Type C Thread Forming Tapping Screws (ANSI B18.6.4–1981, R1991 Appendix) Threads per inch 56 64 48 56 40 48 40 44 32 40 32 36 24 32 24 28 20 28 18 24 16 24 14 20 13 20
D
P
Major Diameter Max Min 0.0860 0.0813 0.0860 0.0816 0.0990 0.0938 0.0990 0.0942 0.1120 0.1061 0.1120 0.1068 0.1250 0.1191 0.1250 0.1195 0.1380 0.1312 0.1380 0.1321 0.1640 0.1571 0.1640 0.1577 0.1900 0.1818 0.1900 0.1831 0.2160 0.2078 0.2160 0.2085 0.2500 0.2408 0.2500 0.2425 0.3125 0.3026 0.3125 0.3042 0.3750 0.3643 0.3750 0.3667 0.4375 0.4258 0.4375 0.4281 0.5000 0.4876 0.5000 0.4906
Point Diameterb Max Min 0.068 0.061 0.070 0.064 0.078 0.070 0.081 0.074 0.087 0.078 0.091 0.083 0.100 0.091 0.102 0.094 0.107 0.096 0.113 0.104 0.132 0.122 0.136 0.126 0.148 0.135 0.158 0.148 0.174 0.161 0.180 0.168 0.200 0.184 0.214 0.202 0.257 0.239 0.271 0.257 0.312 0.293 0.333 0.319 0.366 0.344 0.387 0.371 0.423 0.399 0.450 0.433
a Where specifying nominal size in decimals, zeros
S Point Taper Lengthc For Short Screws For Long Screws Max Min Max Min 0.062 0.045 0.080 0.062 0.055 0.039 0.070 0.055 0.073 0.052 0.094 0.073 0.062 0.045 0.080 0.062 0.088 0.062 0.112 0.088 0.073 0.052 0.094 0.073 0.088 0.062 0.112 0.088 0.080 0.057 0.102 0.080 0.109 0.078 0.141 0.109 0.088 0.062 0.112 0.088 0.109 0.078 0.141 0.109 0.097 0.069 0.125 0.097 0.146 0.104 0.188 0.146 0.109 0.078 0.141 0.109 0.146 0.104 0.188 0.146 0.125 0.089 0.161 0.125 0.175 0.125 0.225 0.175 0.125 0.089 0.161 0.125 0.194 0.139 0.250 0.194 0.146 0.104 0.188 0.146 0.219 0.156 0.281 0.219 0.146 0.104 0.188 0.146 0.250 0.179 0.321 0.250 0.175 0.125 0.225 0.175 0.269 0.192 0.346 0.269 0.175 0.125 0.225 0.175
L Determinant Lengths for Point Taperc 90° Heads Csk Heads 5⁄ 32 1⁄ 8 3⁄ 16 5⁄ 32 7⁄ 32 3⁄ 16 7⁄ 32 3⁄ 16 1⁄ 4 7⁄ 32 1⁄ 4 7⁄ 32 11⁄ 32 1⁄ 4 11⁄ 32 5⁄ 16 13⁄ 32 5⁄ 16 15⁄ 32 11⁄ 32 1⁄ 2 11⁄ 32 19⁄ 32 13⁄ 32 5⁄ 8 13⁄ 32
3⁄ 16 3⁄ 16 7⁄ 32 3⁄ 16 1⁄ 4 7⁄ 32 9⁄ 32 1⁄ 4 5⁄ 16 9⁄ 32 11⁄ 32 5⁄ 16 7⁄ 16 11⁄ 32 7⁄ 16 13⁄ 32 17⁄ 32 13⁄ 32 19⁄ 32 15⁄ 32 11⁄ 16 1⁄ 2 3⁄ 4 9⁄ 16 25⁄ 32 9⁄ 16
Minimum Practical Nominal Screw Lengths 90° Heads Csk Heads 5⁄ 32 1⁄ 8 5⁄ 32 5⁄ 32 3⁄ 16 5⁄ 32 3⁄ 16 3⁄ 16 1⁄ 4 3⁄ 16 1⁄ 4 7⁄ 32 5⁄ 16 1⁄ 4 5⁄ 16 9⁄ 32 3⁄ 8 9⁄ 32 7⁄ 16 5⁄ 16 15⁄ 32 5⁄ 16 9⁄ 16 3⁄ 8 19⁄ 32 3⁄ 8
3⁄ 16 5⁄ 32 7⁄ 32 3⁄ 16 1⁄ 4 7⁄ 32 1⁄ 4 1⁄ 4 5⁄ 16 1⁄ 4 5⁄ 16 9⁄ 32 13⁄ 32 5⁄ 16 13⁄ 32 3⁄ 8 1⁄ 2 3⁄ 8 9⁄ 16 15⁄ 32 5⁄ 8 1⁄ 2 23⁄ 32 17⁄ 32 3⁄ 4 17⁄ 32
SELF-THREADING SCREWS
Nominal Sizeaor Basic Screw Diameter 2 0.0860 2 0.0860 3 0.0990 3 0.0990 4 0.1120 4 0.1120 5 0.1250 5 0.1250 6 0.1380 6 0.1380 8 0.1640 8 0.1640 10 0.1900 10 0.1900 12 0.2160 12 0.2160 1⁄ 4 0.2500 1⁄ 4 0.2500 5⁄ 16 0.3125 5⁄ 16 0.3125 3⁄ 8 0.3750 3⁄ 8 0.3750 7⁄ 16 0.4375 7⁄ 16 0.4375 1⁄ 2 0.5000 1⁄ 2 0.5000
preceding decimal and in the fourth decimal place shall be omitted.
b The tabulated values apply to screw blanks before roll threading. c Screws of these nominal lengths and shorter shall have point taper length specified above for short screws. Longer lengths shall have point taper length specified for long screws.
Copyright 2004, Industrial Press, Inc., New York, NY
1645
All dimensions are in inches. See Table 1 for thread diagrams. Type C is not recommended for new designs. Tapered threads shall have unfinished crests.
Machinery's Handbook 27th Edition
1646
Table 7. ANSI Standard Thread and Point Dimensions for Types D, F, G, and T Thread Cutting Tapping Screws ANSI B18.6.4-1981 (R1991) Threads per inch 56 64 48 56 40 48 40 44 32 40 32 36 24 32 24 28 20 28 18 24 16 24 14 20 13 20
D Major Diameter Max 0.0860 0.0860 0.0990 0.0990 0.1120 0.1120 0.1250 0.1250 0.1380 0.1380 0.1640 0.1640 0.1900 0.1900 0.2160 0.2160 0.2500 0.2500 0.3125 0.3125 0.3750 0.3750 0.4375 0.4375 0.5000 0.5000
Min 0.0813 0.0816 0.0938 0.0942 0.1061 0.1068 0.1191 0.1195 0.1312 0.1321 0.1571 0.1577 0.1818 0.1831 0.2078 0.2085 0.2408 0.2425 0.3026 0.3042 0.3643 0.3667 0.4258 0.4281 0.4876 0.4906
P Point Diameterb Max 0.068 0.070 0.078 0.081 0.087 0.091 0.100 0.102 0.107 0.113 0.132 0.136 0.148 0.158 0.174 0.180 0.200 0.214 0.257 0.271 0.312 0.333 0.366 0.387 0.423 0.450
Min 0.061 0.064 0.070 0.074 0.078 0.083 0.091 0.094 0.096 0.104 0.122 0.126 0.135 0.148 0.161 0.168 0.184 0.202 0.239 0.257 0.293 0.319 0.344 0.371 0.399 0.433
S Point Taper Lengthc For Short Screws For Long Screws Max Min Max Min 0.062 0.045 0.080 0.062 0.055 0.039 0.070 0.055 0.073 0.052 0.094 0.073 0.062 0.045 0.080 0.062 0.088 0.062 0.112 0.088 0.073 0.052 0.094 0.073 0.088 0.062 0.112 0.088 0.080 0.057 0.102 0.080 0.109 0.078 0.141 0.109 0.088 0.062 0.112 0.088 0.109 0.078 0.141 0.109 0.097 0.069 0.125 0.097 0.146 0.104 0.188 0.146 0.109 0.078 0.141 0.109 0.146 0.104 0.188 0.146 0.125 0.089 0.161 0.125 0.175 0.125 0.225 0.175 0.125 0.089 0.161 0.125 0.194 0.139 0.250 0.194 0.146 0.104 0.188 0.146 0.219 0.156 0.281 0.219 0.146 0.104 0.188 0.146 0.250 0.179 0.321 0.250 0.175 0.125 0.225 0.175 0.269 0.192 0.346 0.269 0.175 0.125 0.225 0.175
L Determinant Lengths for Point Taperc 90° Heads Csk Heads 5⁄ 32 1⁄ 8 3⁄ 16 5⁄ 32 7⁄ 32 3⁄ 16 7⁄ 32 3⁄ 16 1⁄ 4 7⁄ 32 1⁄ 4 7⁄ 32 11⁄ 32 1⁄ 4 11⁄ 32 5⁄ 16 13⁄ 32 5⁄ 16 15⁄ 32 11⁄ 32 1⁄ 2 11⁄ 32 19⁄ 32 13⁄ 32 5⁄ 8 13⁄ 32
3⁄ 16 3⁄ 16 7⁄ 32 3⁄ 16 1⁄ 4 7⁄ 32 9⁄ 32 1⁄ 4 5⁄ 16 9⁄ 32 11⁄ 32 5⁄ 16 7⁄ 16 11⁄ 32 7⁄ 16 13⁄ 32 17⁄ 32 13⁄ 32 19⁄ 32 15⁄ 32 11⁄ 16 1⁄ 2 3⁄ 4 9⁄ 16 25⁄ 32 9⁄ 16
Minimum Practical Nominal Screw Lengths 90° Heads Csk Heads 5⁄ 32 1⁄ 8 5⁄ 32 5⁄ 32 3⁄ 16 5⁄ 32 3⁄ 16 3⁄ 16 1⁄ 4 3⁄ 16 1⁄ 4 7⁄ 32 5⁄ 16 1⁄ 4 5⁄ 16 9⁄ 32 3⁄ 8 9⁄ 32 7⁄ 16 5⁄ 16 15⁄ 32 5⁄ 16 9⁄ 16 3⁄ 8 19⁄ 32 3⁄ 8
3⁄ 16 5⁄ 32 7⁄ 32 3⁄ 16 1⁄ 4 7⁄ 32 1⁄ 4 1⁄ 4 5⁄ 16 1⁄ 4 5⁄ 16 9⁄ 32 13⁄ 32 5⁄ 16 13⁄ 32 3⁄ 8 1⁄ 2 3⁄ 8 9⁄ 16 15⁄ 32 5⁄ 8 1⁄ 2 23⁄ 32 17⁄ 32 3⁄ 4 17⁄ 32
a Where specifying nominal size in decimals, zeros preceding decimal and in the fourth decimal place shall be omitted. b The tabulated values apply to screw blanks before roll threading. c Screws of these nominal lengths and shorter shall have point taper length specified above for short screws. Longer lengths shall have point taper length specified for long screws. All dimensions are in inches. See Table 2 for thread diagrams. Type “Type D“ otherwise designated “Type 1.“ Type “Type T“ otherwise designated “Type 23.”
Copyright 2004, Industrial Press, Inc., New York, NY
SELF-THREADING SCREWS
Nominal Sizea or Basic Screw Diameter 2 0.0860 2 0.0860 3 0.0990 3 0.0990 4 0.1120 4 0.1120 5 0.1250 5 0.1250 6 0.1380 6 0.1380 8 0.1640 8 0.1640 10 0.1900 10 0.1900 12 0.2160 12 0.2160 1⁄ 4 0.2500 1⁄ 4 0.2500 5⁄ 16 0.3125 5⁄ 16 0.3125 3⁄ 8 0.3750 3⁄ 8 0.3750 7⁄ 16 0.4375 7⁄ 16 0.4375 1⁄ 2 0.5000 1⁄ 2 0.5000
Machinery's Handbook 27th Edition SELF-THREADING SCREWS
1647
Table 8. Approximate Hole Sizes for Type A Steel Thread Forming Screws
Screw Size
4
6
7
8
Metal Thickness
In Steel, Stainless Steel, Monel Metal, Brass, and Aluminum Sheet Metal Hole Size Hole Size Pierced Drilled Metal Pierced Drilled or or Clean Drill Screw Thickor or Clean Extruded Punched Size Size ness Extruded Punched
0.015
…
0.086
44
0.018 0.024 0.030 0.036 0.015 0.018 0.024 0.030 0.036 0.015 0.018 0.024 0.030 0.036 0.048 0.018
… 0.098 0.098 0.098 … … 0.111 0.111 0.111 … … 0.120 0.120 0.120 0.120 …
0.086 0.094 0.094 0.098 0.104 0.104 0.104 0.104 0.106 0.116 0.116 0.116 0.116 0.116 0.120 0.125
44 42 42 40 37 37 37 37 36 32 32 32 32 32 31 1⁄ 8
8
10
12
14
0.024
0.136
0.125
0.030 0.036 0.048 0.018 0.024 0.030 0.036 0.048 0.024 0.030 0.036 0.048 0.024 0.030 0.036 0.048
0.136 0.136 0.136 … 0.157 0.157 0.157 0.157 … 0.185 0.185 0.185 … 0.209 0.209 0.209
0.125 0.125 0.128 0.136 0.136 0.136 0.136 0.149 0.161 0.161 0.161 0.161 0.185 0.189 0.191 0.196
In Plywood (Resin Impregnated) Screw Size
Hole Size
Drill Size
Min. Mat'l Thickness
4 6 7 8 10 12 14
0.098 0.110 0.128 0.140 0.170 0.189 0.228
40 35 30 28 18 12 1
0.188 0.188 0.250 0.250 0.312 0.312 0.438
Drill Size 1⁄ 8 1⁄ 8 1⁄ 8
30 29 29 29 29 25 20 20 20 20 13 12 11 9
In Asbestos Compositions Penetration in Blind Holes Min. Max. 0.250 0.250 0.312 0.312 0.375 0.375 0.500
0.750 0.750 0.750 0.750 1.000 1.000 1.000
Screw Size
Hole Size
Drill Size
Min. Mat'l Thickness
4 6 7 8 10 12 14
0.094 0.106 0.125 0.136 0.161 0.185 0.213
42 36 1⁄ 8 29 20 13 3
0.188 0.188 0.250 0.250 0.312 0.312 0.438
Penetration in Blind Holes Min. Max. 0.250 0.250 0.312 0.312 0.375 0.375 0.500
0.750 0.750 0.750 0.750 1.000 1.000 1.000
Type A is not recommended, use Type AB. See footnote at bottom of Table 9.
Table 9. Approximate Hole Sizes for Type C Steel Thread Forming Screws Screw Size
4–40
6–32
8–32
Metal Thickness
Hole Size
Drill Size
0.037 0.048 0.062 0.075 0.105 0.134 0.037 0.048 0.062 0.075 0.105
0.094 0.094 0.096 0.100 0.102 0.102 0.113 0.116 0.116 0.122 0.125
42 42 41 39 38 38 33 32 32 3.1mm 1⁄ 8
0.134
0.125
0.037 0.048 0.062 0.075 0.105 0.134
0.136 0.144 0.144 0.147 0.150 0.150
1⁄ 8 29 27 27 26 25 25
Screw Size
10-24
10–32
12–24
In Sheet Steel Metal ThickHole ness Size
Drill Size
Screw Size
Metal Thickness
Hole Size
Drill Size
0.037 0.048 0.062 0.075 0.105 0.134 0.037 0.048 0.062 0.075 0.105
0.221 0.221 0.228 0.234 0.234 0.236 0.224 0.228 0.232 0.234 0.238
2 2 1 A A 6mm 5.7mm 1 5.9mm A B
0.037 0.048 0.062 0.075 0.105 0.134 0.037 0.048 0.062 0.075 0.105
0.154 0.161 0.166 0.170 0.173 0.177 0.170 0.170 0.170 0.173 0.177
23 20 19 18 17 16 18 18 18 17 16
0.134
0.177
16
0.134
0.238
B
0.037 0.048 0.062 0.075 0.105 0.134
0.189 0.194 0.194 0.199 0.199 0.199
12 10 10 8 8 8
0.037 0.048 0.062 0.075 0.105 0.134
0.290 0.290 0.290 0.295 0.295 0.295
L L L M M M
1⁄ –20 4
1⁄ –28 4
5⁄ –18 16
All dimensions are in inches except drill sizes. It may be necessary to vary the hole size to suit a particular application. Type C is not recommended for new designs.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1648
SELF-THREADING SCREWS Table 10. Approximate Pierced or Extruded Hole Sizes for Types AB, B, and BP Steel Thread Forming Screws
Screw Size
Metal Thickness
Pierced or Extruded Hole Size
0.015 0.018 0.024 0.030 0.036 0.015 0.018 0.024 0.030 0.036 0.018
0.086 0.086 0.098 0.098 0.098 0.111 0.111 0.111 0.111 0.111 0.120
0.024 0.030 0.036 0.048 0.024 0.030 0.036
0.086 0.086 0.086 0.086 0.111 0.111 0.111
Screw Size
Pierced or Extruded Hole Size
Metal Thickness
Screw Size
Metal Thickness
Pierced or Extruded Hole Size
0.030 0.036 0.048 0.024 0.030 0.036 0.048 0.030 0.036 0.048 …
0.157 0.157 0.157 0.185 0.185 0.185 0.185 0.209 0.209 0.209 …
0.036 0.048 0.024 0.030 0.036 0.048 …
0.136 0.136 0.157 0.157 0.157 0.157 …
In Steel, Stainless Steel, Monel Metal, and Brass Sheet Metal
4
6
7
0.024 0.030 0.036 0.048 0.018 0.024 0.030 0.036 0.048 0.018 0.024
7
8
10
0.120 0.120 0.120 0.120 0.136 0.136 0.136 0.136 0.136 0.157 0.157
10
12
1⁄ 4
…
In Aluminum Alloy Sheet Metal
4
6
6
0.048 0.024 0.030 0.036 0.048 0.024 0.030
7
8
0.111 0.120 0.120 0.120 0.120 0.136 0.136
8
10 …
All dimensions are in inches except whole number screw and drill sizes. Since conditions differ widely, it may be necessary to vary the hole size to suit a particular application.
Table 11. Drilled Hole Sizes for Types AB, B, and BP Steel Thread Forming Screws Screw Size
Hole Size
Drill Size
Min. Mat'l Thickness
Penetration in Blind Holes Min.
Max.
Screw Size
Hole Size
In Plywood (Resin Impregnated) 2 4 6
0.073 0.100 0.125
7 8 10 12 1⁄ 4
0.136 0.144 0.173 0.194 0.228
2 4 6 7 8 10 12 1⁄ 4 2 4 6 7
49 39 1⁄ 8 29 27 17 10 1
47 42 31 30
Min. Mat'l Thickness
Penetration in Blind Holes Min.
Max.
In Asbestos Compositions
0.125 0.188 0.188
0.188 0.250 0.250
0.500 0.625 0.625
2 4 6
0.076 0.101 0.120
48 38 31
0.125 0.188 0.188
0.188 0.250 0.250
0.500 0.625 0.625
0.188 0.188 0.250 0.312 0.312
0.250 0.250 0.312 0.375 0.375
0.750 0.750 1.000 1.000 1.000
7 8 10 12 1⁄ 4
0.136 0.147 0.166 0.196 0.228
29 26 19 9 1
0.250 0.312 0.312 0.312 0.438
0.312 0.375 0.375 0.375 0.500
0.750 0.750 1.000 1.000 1.000
… … … … … … … …
2 4 6 7 8 10 12 1⁄ 4
0.078 0.100 0.128 0.136 0.150 0.177 0.199 0.234
In Aluminum, Magnesium, Zinc, Brass, and Bronze Castingsa 0.078 47 … 0.125 0.104 37 … 0.188 0.128 30 … 0.250 0.144 27 … 0.250 0.152 24 … 0.250 0.177 16 … 0.250 0.199 8 … 0.281 15⁄ 0.234 … 0.312 64 0.078 0.094 0.120 0.128
Drill Size
In Phenol Formaldehyde Plasticsa 47 39 30 29 25 16 8 15⁄ 64
… … … … … … … …
0.188 0.250 0.250 0.250 0.312 0.312 0.375 0.375
… … … … … … … …
In Cellulose Acetate and Nitrate, and Acrylic and Styrene Resinsa … 0.188 … 8 0.144 27 … 0.250 … 10 0.170 18 … 0.250 … 12 0.191 11 1⁄ … 0.250 … 0.221 2 4
… … … …
0.312 0.312 0.375 0.375
… … … …
a Data below apply to Types B and BP only.
All dimensions are in inches except whole number screw and drill sizes. Since conditions differ widely, it may be necessary to vary the hole size to suit a particular application.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SELF-THREADING SCREWS
1649
Table 12a. Approximate Drilled or Clean-Punched Hole Sizes for Types AB, B, and BP Steel Thread Forming Screws Screw Size
Metal Thickness
Hole Size
0.015 0.018 0.024 0.030 0.036 0.048 0.060 0.015 0.018 0.024 0.030 0.036 0.048 0.060 0.075 0.015 0.018 0.024 0.030 0.036 0.048 0.060 0.075 0.105
0.064 0.064 0.067 0.070 0.073 0.073 0.076 0.086 0.086 0.089 0.094 0.094 0.096 0.100 0.102 0.104 0.104 0.106 0.106 0.110 0.111 0.116 0.120 0.128
52 52 51 50 49 49 48 44 44 43 42 42 41 39 38 37 37 36 36 35 34 32 31 30
0.024 0.030 0.036 0.048 0.060 0.030 0.036 0.048 0.060 0.075 0.105 0.030 0.036 0.048 0.060 0.75 0.105 0.128 to 250 0.030 0.036 0.048
0.064 0.064 0.064 0.067 0.070 0.086 0.086 0.086 0.089 0.089 0.094 0.104 0.104 0.104 0.106 0.110 0.111
52 52 52 51 50 44 44 44 43 43 42 37 37 37 36 35 34
Drill Size
Screw Size
Metal Thickness
Hole Size
Drill Size
Screw Size
Metal Thickness
Hole Size
Drill Size
0.125 0.135 0.164 0.024 0.030 0.036 0.048 0.060 0.075 0.105 0.125 0.135 0.164 0.030 0.036 0.048 0.060 0.075 0.105 0.125 0.135 0.164 0.187 0.194
0.170 0.170 0.173 0.166 0.166 0.166 0.170 0.177 0.182 0.185 0.196 0.196 0.201 0.194a 0.194a 0.194a 0.199a 0.204a 0.209 0.228 0.228 0.234 0.234 0.234
18 18 17 19 19 19 18 16 14 13 9 9 7 10a 10a 10a 8a 6a 4 1 1 15⁄ 64 15⁄ 64 15⁄ 64
0.164 0.200 to 0.375 0.048 0.060 0.075 0.105 0.125 0.135 0.164 0.200 to 0.375 0.060 0.075 0.105 0.125 0.135 0.164 0.187 0.194 0.200 to 0.375
0.159
21
0.166
19
0.161 0.166 0.173 0.180 0.182 0.182 0.189
20 19 17 15 14 14 12
0.196
9
0.199 0.201 0.204 0.209 0.209 0.213 0.213 0.221
8 7 6 4 4 3 3 2
228
1
In Steel, Stainless Steel, Monel Metal, and Brass Sheet Metal
2
4
6
2
4
6
7
120
31
0.113 0.113 0.116
33 33 32
7
8
10
0.018 0.024 0.030 0.036 0.048 0.060 0.075 0.105 0.024 0.030 0.036 0.048 0.060 0.075 0.105 0.125 0.135 0.024 0.030 0.036 0.048 0.060 0.075 0.105
0.116 0.116 0.116 0.116 0.120 0.128 0.136 0.140 0.125 0.125 0.125 0.128 0.136 0.140 0.150 0.150 0.152 0.144 0.144 0.147 0.152a 0.152a 0.157 0.161
32 32 32 32 31 30 29 28 1⁄ 8 1⁄ 8 1⁄ 8 30 29 28 25 25 24 27 27 26 24a 24a 22 20
In Aluminum Alloy Sheet Metal 0.060 0.120 31 0.075 0.128 30 0.105 0.136 29 7 0.128 to 0.136 29 0.250 0.030 0.116 32 0.036 0.120 31 0.048 0.128 30 0.060 0.136 29 0.075 0.140 28 0.105 0.147 26 8 0.125 0.147 26 0.135 0.149 25 0.162 to 0.152 24 0.375 0.036 0.144 27 0.048 0.144 27 0.060 0.144 27 0.075 0.147 26 10 0.105 0.147 26 0.125 0.154 23 0.135 0.154 23
10
12
1⁄ 4
10
12
1⁄ 4
a For Types B and BP only; for Type AB see concluded Table 12b following.
Since conditions differ widely, it may be necessary to vary the hole size to suit a particular application. Hole sizes for metal thicknesses above 0.075 inch are for Types B and BP only.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1650
SELF-THREADING SCREWS
Table 12b. Supplementary Data for Types AB Thread Forming Screws in Steel, Stainless Steel, Monel Metal, and Brass Sheet Metal Screw Size
Metal Thickness
Hole Size
10
0.018
0.144
27
10
0.048
0.149
25
10
0.060
0.154
23
…
…
…
…
Drill Size
Screw Size
Metal Thickness
Hole Size
Drill Size
Screw Size
Metal Thickness
Hole Size
Drill Size
0.048
0.205
5
0.060
0.228
1
0.075
0.232
5.9 mm
…
…
…
In Steel, Stainless Steel, Monel Metal, and Brass Sheet Metal 1⁄ 4 1⁄ 4 1⁄ 4 1⁄ 4
0.018
0.196
9
0.024
0.196
9
0.030
0.196
9
1⁄ 4 1⁄ 4 1⁄ 4
0.036
0.196
9
…
All dimensions are in inches except numbered screw and drill sizes.
Table 13. Approximate Hole Sizes for Types D, F, G, and T Steel Thread Cutting Screws in Sheet Metals Steel Screw Size
2–56
3–48
4–40
5–40
6–32
8–32
Thickness 0.050 0.060 0.083 0.109 0.125 0.140 0.050 0.060 0.083 0.109 0.125 0.140 0.187 0.050 0.060 0.083 0.109 0.125 0.140 0.187 0.050 0.060 0.083 0.109 0.125 0.140 0.187 0.250 0.050 0.060 0.083 0.109 0.125 0.140 0.187 0.250 0.050 0.060 0.083 0.109 0.125 0.140
Hole Size 0.073 0.073 0.073 0.073 0.076 0.076 0.081 0.081 0.082 0.086 0.086 0.086 0.089 0.089 0.089 0.094 0.096 0.098 0.098 0.102 0.106 0.106 0.106 0.106 0.109 0.110 0.116 0.116 0.110 0.113 0.116 0.116 0.116 0.120 0.125 0.125 0.136 0.140 0.140 0.144 0.144 0.147
Drill Size 49 49 49 49 48 48 46 46 45 44 44 44 43 43 43 42 41 40 40 38 36 36 36 36 7⁄ 64 35 32 32 35 33 32 32 32 31 1⁄ 8 1⁄ 8 29 28 28 27 27 26
Aluminum Alloy Hole Drill Size Size 0.070 50 0.073 49 0.073 49 0.073 49 0.073 49 0.073 49 5⁄ 0.078 64 0.081 46 0.082 45 0.082 45 0.082 45 0.086 44 0.086 44 0.089 43 0.089 43 0.089 43 0.094 42 0.094 42 3⁄ 0.094 32 0.098 40 0.102 38 0.102 38 0.104 37 0.104 37 0.106 36 0.106 36 0.110 35 0.113 33 7⁄ 0.109 64 7⁄ 0.109 64 0.111 34 0.113 33 0.116 32 0.116 32 0.120 31 1⁄ 0.125 8 0.136 29 0.136 29 0.136 29 0.140 28 0.140 28 0.144 27
Steel Screw Size 8–32
10–24
10–32
12–24
1⁄ –20 4
Thickness 0.187 0.250 0.312 0.050 0.060 0.083 0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.050 0.060 0.083 0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.060 0.083 0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.500 0.083 0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.500
Hole Size 0.150 0.150 0.150 0.152 0.154 0.161 0.161 0.166 0.170 0.173 0.173 0.173 0.173 0.159 0.166 0.166 0.170 0.170 0.170 0.177 0.177 0.177 0.177 0.180 0.182 0.188 0.191 0.191 0.199 0.199 0.199 0.199 0.199 0.213 0.219 0.221 0.221 0.228 0.228 0.228 0.228 0.228
Drill Size 25 25 25 24 23 20 20 19 18 17 17 17 17 21 19 19 18 18 18 16 16 16 16 15 14 3⁄ 16 11 11 8 8 8 8 8 3 7⁄ 32 2 2 1 1 1 1 1
Copyright 2004, Industrial Press, Inc., New York, NY
Aluminum Alloy Hole Drill Size Size 0.147 26 0.150 25 0.150 25 0.150 25 0.152 24 0.154 23 0.157 22 0.159 21 0.161 20 0.166 19 11⁄ 0.172 64 0.173 17 0.173 17 0.161 20 0.161 20 0.161 20 0.166 19 0.166 19 0.166 19 11⁄ 0.172 64 0.177 16 0.177 16 0.177 16 0.177 16 0.180 15 0.182 14 0.185 13 3⁄ 0.188 16 0.191 11 0.199 8 0.199 8 0.199 8 0.199 8 0.206 5 0.209 4 0.213 3 0.213 3 0.221 2 0.228 1 0.228 1 0.228 1 0.228 1
Machinery's Handbook 27th Edition SELF-THREADING SCREWS
1651
Table 13. (Continued) Approximate Hole Sizes for Types D, F, G, and T Steel Thread Cutting Screws in Sheet Metals Steel Screw Size
1⁄ –28 4
5⁄ –18 16
5⁄ –24 16
Thickness 0.083 0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.500 0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.500 0.109 0.125 0.140
Hole Size 0.221 0.228 0.228 0.234 0.234 0.234 0.234 0.234 0.234 0.277 0.277 0.281 0.290 0.290 0.290 0.290 0.290 0.290 0.290 0.290
Drill Size 2 1 1 A 15⁄ 64 15⁄ 64 15⁄ 64 15⁄ 64 15⁄ 64 J J 9⁄ 32 L L L L L L L L
Aluminum Alloy Hole Drill Size Size 7⁄ 0.219 32 0.221 2 0.221 2 0.221 2 0.228 1 15⁄ 0.234 64 15⁄ 0.234 64 15 ⁄64 0.234 15⁄ 0.234 64 0.266 H 0.272 I 0.272 I 0.281 K 0.290 L 0.290 L 0.290 L 0.290 L 0.281 K 9 ⁄32 0.281 9⁄ 0.281 32
Steel Screw Size
5⁄ –24 16
3⁄ –16 8
3⁄ –24 8
Thickness 0.187 0.250 0.312 0.375 0.500
Hole Size 0.295 0.295 0.295 0.295 0.295
Drill Size M M M M M
0.125 0.140 0.187 0.250 0.312 0.375 0.500 0.125 0.140 0.187 0.250 0.312 0.375 0.500 …
0.339 0.339 0.348 0.358 0.358 0.358 0.358 0.348 0.348 0.358 0.358 0.358 0.358 0.358 …
R R S T T T T S S T T T T T …
Aluminum Alloy Hole Drill Size Size 0.290 L 0.295 M 0.295 M 0.295 M 0.295 M 0.328 0.332 0.339 0.348 0.348 0.348 0.348 0.344 0.344 0.348 0.358 0.358 0.358 0.358 …
21⁄ 64
Q R S S S S 11⁄ 32 11⁄ 32 S T T T T …
All dimensions are in inches except numbered drill and screw sizes. It may be necessary to vary the hole size to suit a particular application.
Table 14. Approximate Hole Sizes for Types D, F, G, and T Steel Thread Cutting Screws in Cast Metals and Plastics Screw Size
2–56
3–48
4–40
5–40
Thickness
Cast Iron Hole Drill Size Size
Zinc and Aluminuma Hole Drill Size Size
0.050
0.076
48
0.073
49
0.083
0.113
33
0.106
36
0.060
0.076
48
0.073
49
0.109
0.113
33
0.110
35
0.083
0.076
48
0.076
48
0.125
0.116
32
0.110
35
0.109
0.078
5⁄ 64
0.076
48
0.140
0.116
32
0.110
35
0.125
0.078
5⁄ 64
0.076
48
0.187
0.116
32
0.111
34
0.140
0.078
5⁄ 64
0.076
48
0.250
0.116
32
0.113
33
0.050
0.089
43
0.082
45
0.050
0.120
31
0.116
32
0.060
0.089
43
0.082
45
0.060
0.120
31
0.120
31
0.083
0.089
43
0.082
45
0.083
0.125
1⁄ 8
0.120
31
0.109
0.089
43
0.086
44
0.109
0.125
1⁄ 8
0.120
31
0.125
0.089
43
0.089
43
0.125
0.125
1⁄ 8
0.120
31
0.140
0.094
42
0.089
43
0.140
0.125
1⁄ 8
0.120
31
0.187
0.094
42
0.089
43
0.187
0.128
30
0.120
31
0.050
0.100
39
0.090
41
0.250
0.128
30
0.120
31
0.060
0.100
39
0.096
41
0.050
0.147
26
0.144
27
0.083
0.102
38
0.096
41
0.060
0.150
25
0.144
27
0.109
0.102
38
0.096
41
0.083
0.150
25
0.144
27
0.125
0.102
38
0.100
39
0.109
0.150
25
0.144
27
0.140
0.102
38
0.100
39
0.125
0.150
25
0.147
26
0.187
0.104
37
0.100
39
0.140
0.150
25
0.147
26
0.050
0.111
34
0.106
36
0.187
0.154
23
0.147
26
0.060
0.111
34
0.106
36
0.250
0.154
23
0.150
25
0.312
0.154
23
0.150
25
Screw Size
5–40
6–32
8–32
Thickness
Cast Iron Hole Drill Size Size
Copyright 2004, Industrial Press, Inc., New York, NY
Zinc and Aluminuma Hole Drill Size Size
Machinery's Handbook 27th Edition 1652
SELF-THREADING SCREWS Table 14. (Continued) Approximate Hole Sizes for Types D, F, G, and T Steel Thread Cutting Screws in Cast Metals and Plastics
Screw Size
10–24
10–32
12–24
1⁄ –20 4
Thickness 0.050 0.060 0.083 0.109 0.125 0.140 0.187 0.250 0.312 0.375
Cast Iron Hole Drill Size Size 0.170 18 0.170 18 11⁄ 0.172 64 0.173 17 0.173 17 0.173 17 0.177 16 0.177 16 0.177 16 0.177 16
Zinc and Aluminuma Hole Drill Size Size 0.161 20 0.166 19 0.166 19 0.166 19 0.166 19 0.166 19 0.170 18 0.170 18 11⁄ 0.172 64 11⁄ 0.172 64
0.050 0.060 0.083 0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.060 0.083 0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.500
0.173 0.173 0.177 0.177 0.177 0.177 0.180 0.180 0.180 0.180 0.196 0.199 0.199 0.199 0.199 0.203 0.204 0.204 0.204 0.204
17 17 16 16 16 16 15 15 15 15 9 8 8 8 8 13⁄ 64 6 6 6 6
0.170 0.170 0.172 0.172 0.172 0.172 0.172 0.173 0.173 0.177 0.189 0.191 0.191 0.191 0.194 0.194 0.196 0.196 0.199 0.199
18 18 11⁄ 64 11⁄ 64 11⁄ 64 11⁄ 64 11⁄ 64 17 17 16 12 11 11 11 10 10 9 9 8 8
0.083 0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.500
0.228 0.228 0.228 0.228 0.234 0.234 0.234 0.234 0.234
1 1 1 1 15⁄ 64 15⁄ 64 15⁄ 64 15⁄ 64 15⁄ 64
0.219 0.219 0.221 0.221 0.221 0.228 0.228 0.228 0.228
7⁄ 32 7⁄ 32
Screw Size
1⁄ –28 4
5⁄ –18 16
5⁄ –24 16
3⁄ –16 8
2 2 2 1 1 1 1
3⁄ –24 8
Thickness 0.083 0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.500
Cast Iron Hole Drill Size Size 0.234 A 15⁄ 0.234 64 15⁄ 0.234 64 15⁄ 0.234 64 0.238 B 0.238 B 0.238 B 0.238 B 0.238 B
0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.500
0.290 0.290 0.290 0.295 0.295 0.295 0.295 0.295
L L L M M M M M
Zinc and Aluminuma Hole Drill Size Size 0.228 1 0.228 1 0.228 1 0.228 1 0.228 1 0.234 A 0.234 A 15⁄ 0.234 64 15⁄ 0.234 64 0.277 J 0.281 K 0.281 K 9⁄ 0.281 32 9⁄ 0.281 32 0.290 L 0.290 L 0.290 L
0.109 0.125 0.140 0.187 0.250 0.312 0.375 0.500 0.125 0.140 0.187 0.250 0.312 0.375
0.295 0.295 0.295 0.302 0.302 0.302 0.302 0.302 0.348 0.348 0.348 0.348 0.348 0.348
M M M N N N N N S S S S S S
0.290 0.290 0.290 0.290 0.290 0.295 0.295 0.295 0.339 0.339 0.339 0.344 0.344 0.348
L L L L L M M M R R R 11⁄ 32 11⁄ 32 S
0.500
0.348
S
0.348
S
0.125 0.140 0.187 0.250 0.312 0.375 0.500
0.358 0.358 0.358 0.358 0.358 0.358 0.358
T T T T T T T
0.348 0.348 0.348 0.358 0.358 0.358 0.358
S S S T T T T
a Die Castings
Phenol Formaldehydea Depth of Penetration Min Max
Screw Size
Hole Size
Drill Size
2–56 3–48 4–40 5–40 6–32 8–32 10–24 10–32 1⁄ –20 4
0.078 0.089 0.098 0.113 0.116 0.144 0.161 0.166 0.228
5⁄ 64 43 40 33 32 27 20 19 1
0.219 0.219 0.250 0.250 0.250 0.312 0.375 0.375 0.375
0.375 0.375 0.312 0.438 0.312 0.500 0.500 0.500 0.625
Hole Size 0.076 0.086 0.093 0.110 0.116 0.144 0.161 0.166 0.228
Cellulose Acetate, Cellulose Nitrate, Acrylic Resin, and Styrene Resina Depth of Penetration Drill Size Min Max 48 44 42 35 32 27 20 19 1
0.219 0.219 0.250 0.250 0.250 0.312 0.375 0.375 0.375
a Plastics
For footnotes see Table 13.
Copyright 2004, Industrial Press, Inc., New York, NY
0.375 0.375 0.312 0.438 0.312 0.500 0.500 0.500 1.000
Machinery's Handbook 27th Edition SELF-THREADING SCREWS
1653
Table 15. Approximate Hole Sizes for Types BF and BT Steel Thread Cutting Screws in Cast Metals In Die Cast Zinc and Aluminum Screw Size
2
3
4
5
6
8
Thickness
Hole Size
Drill Size
0.060 0.083 0.109 0.125 0.140
0.073 0.073 0.076 0.076 0.076
49 49 48 48 48
0.060
0.086
0.083 0.109 0.125 0.140 0.188 0.109 0.125 0.140 0.188 0.250 0.109 0.125 0.140 0.188 0.250 0.125 0.140 0.188 0.250
Screw Size
Thickness
Hole Size
Drill Size
0.125 0.140 0.188 0.250 0.312
0.166 0.166 0.166 0.170 0.172
19 19 19 18 11⁄ 64
44
0.375
0.172
11⁄ 64
0.086 0.086 0.086 0.089 0.089 0.098 0.100 0.100 0.100 0.102 0.111 0.111 0.113 0.113 0.116 0.120 0.120 0.120 0.125
44 44 44 43 43 40 39 39 39 38 34 34 33 33 32 31 31 31
0.191 0.191 0.191 0.196 0.196 0.196 0.221 0.221 0.221 0.228 0.228 0.228 0.281 0.281 0.281 0.281 0.290 0.290 0.344
11 11 11 9 9 9 2 2 2 1 1 1 K K K K L L
1⁄ 8
0.125 0.140 0.188 0.250 0.312 0.375 0.125 0.140 0.188 0.250 0.312 0.375 0.125 0.140 0.188 0.250 0.312 0.375 0.125
11⁄ 32
0.312
0.125
1⁄ 8
0.140
0.344
11⁄ 32
0.125
0.149
25
0.188
0.344
11⁄ 32
0.140
0.149
25
0.250
0.344
11⁄ 32
0.188 0.250 0.312
0.149 0.152 0.152
25 24 24
0.312 0.375 …
0.348 0.348 …
S S …
10
12
1⁄ 4
5⁄ 16
3⁄ 8
All dimensions are in inches except numbered drill and screw sizes. It may be necessary to vary the hole size to suit a particular application.
Table 16. Approximate Hole Size for Types BF and BT Steel Thread Cutting Screws in Plastics Phenol Formaldehyde Hole Size
Drill Size
2
0.078
3 4
Cellulose Acetate, Cellulose Nitrate, Acrylic Resin and Styrene Resin
Depth of Penetration
Depth of Penetration
Min
Max
Hole Size
Drill Size
Min
Max
5⁄ 64
0.094
0.250
0.076
48
0.094
0.250
0.089
43
0.125
0.312
0.089
43
0.125
0.312
0.104
37
0.125
0.312
0.100
39
0.125
0.312
5
0.116
32
0.188
0.375
0.113
33
0.188
0.375
6
0.125
1⁄ 8
0.188
0.375
0.120
31
0.188
0.375
Screw Size
8
0.147
26
0.250
0.500
0.144
27
0.250
0.500
10
0.170
18
0.312
0.625
0.166
19
0.312
0.625
12
0.194
10
0.375
0.625
0.189
12
0.375
0.625
1⁄ 4
0.228
1
0.375
0.750
0.221
2
0.375
0.750
For footnotes see above table.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1654
THREAD INSERTS
Table 17. Approximate Hole Sizes for Type U Hardened Steel Metallic Drive Screws Screw Size
Hole Size
Drill Size
In Ferrous and Non-Ferrous Castings, Sheet Metals, Plastics, Plywood (Resin-Impregnated) and Fiber Screw Hole Drill Screw Size Size Size Size
Hole Size
Drill Size
00 0 2 4
.052 .067 .086 .104
55 51 44 37
.191 .221 .295 .358
11 2 M T
6 7 8 10
.120 .136 .144 .161
31 29 27 20
12 14 5⁄ 16 3⁄ 8
All dimensions are in inches except whole number screw and drill sizes and letter drill sizes.
Table 18. ANSI Standard Torsional Strength Requirements for Tapping Screws ANSI B18.6.4-1981 (R1991) Nom. Screw Size 2 3 4 5 6 7 8 10 12 14
Type A 4 9 12 18 24 30 39 48 83 125
Types AB,B,BF, BP,andBT 4 9 13 18 24 30 39 56 88 …
Types C, D, F, G, and T Coarse Fine Thread Thread 5 6 9 10 13 15 18 20 23 27 … … 42 47 56 74 93 108 … …
NomScrew Size 1⁄ 4
16 18 5⁄ 16 20 24 3⁄ 8 7⁄ 16 1⁄ 2 …
Type A … 152 196 … 250 492 … … … …
Types AB, B, BF, BP, and BT 142 … … 290 … … 590 620 1020 …
Types C, D, F, G, and T Coarse Fine Thread Thread 140 179 … … … … 306 370 … … … … 560 710 700 820 1075 1285 … …
Torsional strength data are in pound-inches.
Self-tapping Thread Inserts.—Self-tapping screw thread inserts are essentially hard bushings with internal and external threads. The internal threads conform to Unified and American standard classes 2B and 3B, depending on the type of insert used. The external thread has cutting edges on the end that provide the self-tapping feature. These inserts may be used in magnesium, aluminum, cast iron, zinc, plastics, and other materials. Self-tapping inserts are made of case-hardened carbon steel, stainless steel, and brass, the brass type being designed specifically for installation in wood. Screw Thread Inserts.—Screw thread inserts are helically formed coils of diamondshaped stainless steel or phosphor bronze wire that screw into a threaded hole to form a mating internal thread for a screw or stud. These inserts provide a convenient means of repairing stripped-out threads and are also used to provide stronger threads in soft materials such as aluminum, zinc die castings, wood, magnesium, etc. than can be obtained by direct tapping of the base metal involved. According to the Heli-Coil Corp., conventional design practice in specifying boss diameters or edge distances can usually be applied since the major diameter of a hole tapped to receive a thread insert is not much larger than the major diameter of thread the insert provides. Screw thread inserts are available in thread sizes from 4–40 to 11⁄2–6 inch National and Unified Coarse Thread Series and in 6–40 to 11⁄2–12 sizes in the fine-thread series. When used in conjunction with appropriate taps and gages, screw thread inserts will meet requirements of 2, 2B, 3, and 3B thread classes. ANSI Standard Metric Thread Forming and Thread Cutting Tapping Screws.— Table 1 shows the various types of metric thread forming and thread cutting screw threads covered by the standard ANSI/ASME B18.6.5M-1986. The designations of the American National Standards Institute are shown.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC SELF-THREADING SCREWS
1655
Table 1. ANSI Standard Threads and Points for Metric Thread Forming and Thread Cutting Tapping Screws ANSI/ASME B18.6.5M-1986
DETAIL OF THREAD FORM
TYPE BF
DETAIL OF THREAD FORM
TYPE BT
TYPE F
TYPE D
TYPE T See Tables 3 and 4 for thread data.
Thread Forming Tapping Screws: These types are generally for application in materials where large internal stresses are permissible or desirable, to increase resistance to loosening. These screws have the following descriptions and applications:
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1656
METRIC SELF-THREADING SCREWS
Type AB: Spaced thread screw with gimlet point primarily intended for use in thin metal, resin impregnated plywood, and asbestos compositions. Type B: Spaced thread screw with a blunt point that has tapered entering threads with unfinished crests and same pitches as Type AB. Used for thin metal, nonferrous castings, resin impregnated plywood, certain resilient plastics, and asbestos compositions. Thread Cutting Tapping Screws: These screws are generally for application in materials where disruptive internal stresses are undesirable or where excessive driving torques are encountered with thread forming tapping screws. These screws have the following descriptions and applications: Types BF and BT: Spaced threads with blunt point and tapered entering threads having unfinished crests, as on Type B, with one or more cutting edges or chip cavities, intended for use in plastics, asbestos compositions, and other similar materials. Types D, F, and T: Tapping screws with threads of machine screw diameter-pitch combinations (metric coarse thread series) approximating a 60 degree basic thread form (not necessarily conforming to any standard thread profile) with a blunt point and tapered entering threads with unfinished crests and having one or more cutting edges and chip cavities, intended for use in materials such as aluminum, zinc, and lead die castings; steel sheets and shapes; cast iron; brass; and plastics. ANSI Standard Head Types for Metric Thread Forming and Cutting Tapping Screws.—The head types covered by ANSI/ASME B18.6.5M-1986 include those commonly applicable to metric tapping screws and are described as follows: Flat Countersunk Head: The flat countersunk head has a flat top surface and a conical bearing surface with a head angle of 90 to 92 degrees. Oval Countersunk Head: The oval countersunk head has a rounded top surface and a conical bearing surface with a head angle of 90 to 92 degrees. Pan Head: The slotted pan head has a flat top surface rounding into cylindrical sides and a flat bearing surface. The recessed pan head has a rounded top surface blending into cylindrical sides and a flat bearing surface. Hex Head: The hex head has a flat or indented top surface, six flat sides, and a flat bearing surface. Hex Flange Head: The hex flange head has a flat or indented top surface and six flat sides formed integrally with a frustroconical or slightly rounded (convex) flange that projects beyond the sides and provides a flat bearing surface. Method of Designation.—Metric tapping screws are designated with the following data, preferably in the sequence shown: Nominal size; thread pitch; nominal length; thread and point type; product name, including head style and driving provision; material; and protective finish, if required. Examples: 6.3 × 1.8 × 30 Type AB, Slotted Pan Head Tapping Screw, Steel, Zinc Plated 6 × 1 × 20 Type T, Type 1A Cross Recessed Pan Head Tapping Screw, Corrosion Resistant Steel 4.2 × 1.4 × 13 Type BF, Type 1 Cross Recessed Oval Countersunk Head Tapping Screw, Steel, Chromium Plated 10 × 1.5 × 40 Type D, Hex Flange Head Tapping Screw, Steel
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC SELF-THREADING SCREWS
1657
Table 2. Recommended Nominal Screw Lengths for Metric Tapping Screws ANSI/ASME B18.6.5M-1986 Nominal Screw Size for Types AB, B, BF, and BT 2.2
-
2.9
Nominal Screw Length
2
2.5
4
PH
PH
5
PH
PH
6
A
3.5
4.2
4.8
5.5
6.3
8
9.5
-
6
8
10
Nominal Screw Size for Types D, F, and T 3
3.5
4
5
A
PH
8
A
A
A
PH
PH
10
A
A
A
A
A
13
A
A
A
A
A
A
A
PH
A
A
A
A
A
A
A
PH
20
A
A
A
A
A
A
25
A
A
A
A
A
A
A
30
A
A
A
A
A
35
A
A
A
A
A
A
A
16
PH
40
PH
A
A
45
A
A
50
A
A
55
A
60
A
Table 3. ANSI Standard Thread and Point Dimensions for Types AB and B Metric Thread Forming Tapping Screws ANSI/ASME B18.6.5M-1986 D1
D2
D3
Y
L
Z
Point Taper Length Type Bc
Min. Practical Nominal Screw Lengthd
Basic Screw Diameter
Basic Thread Pitch
Refe
Refe
Max
Min
Max
Min
Max
Min
Max
2.2 × 0.8
2.184
0.79
2.24
2.10
1.63
1.52
1.47
1.37
1.6
1.2
2.0
4
6
4
5
2.9 × 1
2.845
1.06
2.90
2.76
2.18
2.08
2.01
1.88
2.1
1.6
2.6
6
7
5
7
3.5 × 1.3
3.505
1.27
3.53
3.35
2.64
2.51
2.41
2.26
2.5
1.9
3.2
7
9
6
8
4.2 × 1.4
4.166
1.41
4.22
4.04
3.10
2.95
2.84
2.69
2.8
2.1
3.7
8
10
7
10
4.8 × 1.6
4.826
1.59
4.80
4.62
3.58
3.43
3.30
3.12
3.2
2.4
4.3
9
12
8
11
5.5 × 1.8
5.486
1.81
5.46
5.28
4.17
3.99
3.86
3.68
3.6
2.7
5.0
11
14
9
12
6.3 × 1.8
6.350
1.81
6.25
6.03
4.88
4.70
4.55
4.34
3.6
2.7
6.0
12
16
10
13
8 × 2.1
7.938
2.12
8.00
7.78
6.20
5.99
5.84
5.64
4.2
3.2
7.5
16
20
12
17
9.5 × 2.1
9.525
2.12
9.65
9.43
7.85
7.59
7.44
7.24
4.2
3.2
8.0
19
24
14
19
Thread Major Diameter
Thread Minor Diameter
Point Diameterb
Min
Point Length Factor TypeAB Reff
Type AB
Type B
Note 7 Note 8 Note 7 Note 8
Nominal Screw Size and Thread Pitcha
a The
body diameter (unthreaded portion) is not less than the minimum minor diameter nor greater than the maximum major diameter of the thread. b The tabulated values shall apply to screw blanks prior to roll threading. c The tabulated maximum limits are equal to approximately two times the thread pitch. d Lengths shown are theoretical minimums and are intended to assist the user in the selection of appropriate short screw lengths. Refer to Table 2 for recommended diameter-length combinations. e Basic screw diameter and basic thread pitch shall be used for calculation purposes wherever these factors appear in formulations for dimensions. f The minimum effective grip length on Type AB tapping screws shall be determined by subtracting the point length factor from the minimum screw length. All dimensions are in millimeters. See Table 1 for thread diagrams. 7 Pan, hex, and hex flange heads. 8 Flat and oval countersunk heads.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1658
METRIC SELF-THREADING SCREWS
Table 4. ANSI Standard Thread and Point Dimensions for Types BF, BT, D, F, and T Metric Thread Cutting Tapping Screws ANSI/ASME B18.6.5M-1986 Types BF and BT D1
D2
D3
Y
L Minimal Practical Nominal Screw Lengthc
Point Diametera
Point Taper Length Type Bb
Basic Screw Diameter
Basic Thread Pitch
Refd
Refd
Max
Min
Max
Min
Max
Min
Max
2.2 × 0.8
2.184
0.79
2.24
2.10
1.63
1.52
1.47
1.37
1.6
2.9 × 1
2.845
1.06
2.90
2.76
2.18
2.08
2.01
1.88
2.1
3.5 × 1.3
3.505
1.27
3.53
3.35
2.64
2.51
2.41
2.26
4.2 × 1.4
4.166
1.41
4.22
4.04
3.10
2.95
2.84
4.8 × 1.6
4.826
1.59
4.80
4.62
3.58
3.43
3.30
5.5 × 1.8
5.486
1.81
5.46
5.28
4.17
3.99
3.86
6.3 × 1.8
6.350
1.81
6.25
6.03
4.88
4.70
8 × 2.1
7.938
2.12
8.00
7.78
6.20
9.5 × 2.1
9.525
2.12
9.65
9.43
7.85
Nominal Screw Size and Thread Pitch
Thread Major Diameter
Thread Minor Diameter
Min
Pan, Hex and Hex Flange Heads
Flat and Oval Csunk Heads
1.2
4
5
1.6
5
7
2.5
1.9
6
8
2.69
2.8
2.1
7
10
3.12
3.2
2.4
8
11
3.68
3.6
2.7
9
12
4.55
4.34
3.6
2.7
10
13
5.99
5.84
5.64
4.2
3.2
12
17
7.59
7.44
7.24
4.2
3.2
14
19
a The tabulated values apply to screw blanks prior to roll threading. b The tabulated maximum limits are equal to approximately two times the thread pitch. c Lengths shown are theoretical minimums and are intended to assist in the selection of appropriate short screw lengths. See Table 2 for recommended length-diameter combinations. For Types D, F, and T, shorter screws are available with the point length reduced to the limits tabulated for short screws. d Basic screw diameter and basic thread pitch are used for calculation purposes whenever these factors appear in formulations for dimensions.
Types D, F, T D1 Nominal Screw Size and Thread Pitch
D3
Thread Major Diameter
DS
Y
L
Point Taper Length
Minimum Practical Nominal Screw Lengthc
For Short Screws
For Long Screwsb
Flat and Oval Csunk Heads 5
Max
Min
Max
Min
Min
Max
Min
Max
Min
Pan, Hex and Hex Flange Heads
2 × 0.4
2.00
1.88
1.45
1.39
1.65
1.4
1.0
1.8
1.4
4
2.5 × 0.45
2.50
2.37
1.88
1.82
2.12
1.6
1.1
2.0
1.6
4
6
3 × 0.5
3.00
2.87
2.32
2.26
2.58
1.8
1.3
2.3
1.8
5
6
3.5 × 0.6
3.50
3.35
2.68
2.60
3.00
2.1
1.5
2.7
2.1
5
8
4 × 0.7
4.00
3.83
3.07
2.97
3.43
2.5
1.8
3.2
2.5
6
9
5 × 0.8
5.00
4.82
3.94
3.84
4.36
2.8
2.0
3.6
2.8
7
10
Point Diametera
Body Diametera
6×1
6.00
5.79
4.69
4.55
5.21
3.5
2.5
4.5
3.5
9
12
8 × 1.25
8.00
7.76
6.40
6.24
7.04
4.4
3.1
5.6
4.4
11
16
10 × 1.5
10.00
9.73
8.08
7.88
8.86
5.3
3.8
6.8
5.3
13
18
a Minimum
limits for body diameter (unthreaded portion) are tabulated for convenient reference. For Types BF and BT, the body diameter is not less than the minimum minor diameter nor greater than the maximum major diameter of the thread. b Long screws are screws of nominal lengths equal to or longer than those listed under L. All dimensions are in millimeters. See Table 1 for thread diagrams.
Material and Heat Treatment.—Tapping screws are normally fabricated from carbon steel and are suitably processed to meet the performance and test requirements outlined in the standard, B18.6.5M. Tapping screws may also be made from corrosion resistant steel, Monel, brass, and aluminum alloys. The materials, properties, and performance characteristics applicable to such screws should be mutually agreed upon between the manufacturer and the purchaser.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC SELF-THREADING SCREWS
1659
Table 5. Clearance Holes for Metric Tapping Screws ANSI/ASME B18.6.5M-1986 Appendix Nominal Screw Size and Thread Pitch 2.2 ×0.8 2.9 ×1 3.5 ×1.3 4.2 ×1.4 4.8 ×1.6 5.5 ×1.8 6.3×1.8 8 ×2.1 9.5 ×2.1
Basic Clearance Hole Diametera Normal Clearance Close Loose (Preferred)b Clearanceb Clearanceb Types AB, B, BF, and BT 2.40 2.60 2.80 3.10 3.30 3.50 3.70 3.90 4.20 4.50 4.70 5.00 5.10 5.30 5.60 5.90 6.10 6.50 6.70 6.90 7.30 8.40 9.00 10.00 10.00 10.50 11.50
Nominal Screw Size and Thread Pitch 2 ×0.4 2.5 ×0.45 3 ×0.5 3.5 ×0.6 4 ×0.7 5 ×0.8 6 ×1 8 ×1.25 10 ×1.5
Basic Clearance Hole Diametera Normal Clearance Close Loose (Preferred)b Clearanceb Clearanceb Types D, F, and T 2.20 2.40 2.60 2.70 2.90 3.10 3.20 3.40 3.60 3.70 3.90 4.20 4.30 4.50 4.80 5.30 5.50 5.80 6.40 6.60 7.00 8.40 9.00 10.00 10.50 11.00 12.00
a The values given in this table are minimum limits. The recommended plus tolerances are as follows: for clearance hole diameters over 1.70 to and including 5.80 mm, plus 0.12, 0.20, and 0.30 mm for close, normal, and loose clearances, respectively; over 5.80 to and including 14.50 mm, plus 0.18, 0.30, and 0.45 mm for close, normal, and loose clearances, respectively. b Normal clearance hole sizes are preferred. Close clearance hole sizes are for situations such as critical alignment of assembled components, wall thickness, or other limitations that necessitate the use of a minimal hole. Countersinking or counterboring at the fastener entry side may be necessary for the proper seating of the head. Loose clearance hole sizes are for applications where maximum adjustment capability between the components being assembled is necessary.
All dimensions are in millimeters.
Approximate Installation Hole Sizes for Metric Tapping Screws.—The approximate hole sizes given in Tables 7 through 9 provide general guidance in selecting holes for installing the respective types of metric thread forming and thread cutting tapping screws in various commonly used materials. Types AB, B, BF, and BT metric tapping screws are covered in these tables; hole sizes for Types D, F, and T metric thread cutting tapping screws are still under development. Table 6. Approximate Pierced or Extruded Hole Sizes for Steel Types AB and B Metric Thread Forming Tapping Screws Nominal Screw Size andThread Pitch
2.9 × 1
3.5 × 1.3
2.9 × 1 3.5 × 1.3
Metal Thickness
Nominal Nominal Screw Size Screw Size andThread andThread Metal Hole Hole Pitch Pitch Thickness Size Size In Steel, Stainless Steel, Monel, and Brass Sheet Metal
0.38 0.46 0.61 0.76 0.91 0.38 0.46 0.61 0.76 0.91
2.18 2.18 2.49 2.49 2.49 2.82 2.82 2.82 2.82 2.82
0.61 0.76 0.91 1.22 0.61 0.76
2.18 2.18 2.18 2.18 2.82 2.82
0.46 0.61 0.76 0.91 1.22 0.46 0.61 4.8 × 1.6 0.76 0.91 1.22 In Aluminum Alloy 0.91 3.5 × 1.3 1.22 0.61 0.76 4.2 × 1.4 0.91 1.22
4.2 × 1.4
3.45 3.45 3.45 3.45 3.45 3.99 3.99 3.99 3.99 3.99 2.82 2.82 3.45 3.45 3.45 3.45
Metal Thickness
Hole Size
0.61 0.76 0.91 1.22 … 0.76 0.91 1.22 … …
4.70 4.70 4.70 4.70 … 5.31 5.31 5.31 … …
0.61 0.76 0.91 1.22 … …
3.99 3.99 3.99 3.99 … …
5.5 × 1.8
6.3 × 1.8
4.8 × 1.6
All dimensions are in millimeters.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1660
METRIC SELF-THREADING SCREWS
Table 7. Approximate Drilled or Clean-Punched Hole Sizes for Steel Type AB Metric Thread Forming Tapping Screws in Sheet Metal Nominal Screw Size and Thread Pitch
Nominal Screw Size and Thread Pitch
Metal Thickness
Hole Size
0.38
1.63
52
0.61
2.69
36
0.46
1.63
52
0.76
2.69
36
0.61
1.70
51
0.91
2.79
0.76
1.78
50
1.22
0.91
1.85
49
1.22
1.85
49
1.52
1.93
48
Drill Sizea
Metal Thickness
Nominal Screw Size and Thread Pitch
Metal Thickness
Hole Size
Drill Sizea
1.22
3.78
25
1.52
3.91
23
35
1.90
3.99
22
2.82
34
0.46
…
…
1.52
2.95
32
0.61
4.22
19
1.90
3.05
31
0.76
4.22
19
0.46
…
…
0.91
4.22
19
Hole Size
Drill Sizea
In Steel, Stainless Steel, Monel, and Brass Sheet Metal
2.2 × 0.8
2.9 × 1
3.5 × 1.3
3.5 × 1.3
4.8 × 1.6
5.5 × 1.8
0.38
2.18
44
0.61
3.18
…
1.22
4.32
18
0.46
2.18
44
0.76
3.18
…
1.52
4.50
16
0.61
2.26
43
0.91
3.18
…
1.90
4.62
14
0.76
2.39
42
4.2 × 1.4
1.22
3.25
30
0.46
4.98
9
0.91
2.39
42
1.52
3.45
29
0.61
4.98
9
1.22
2.44
41
1.90
3.56
28
0.76
4.98
9
1.52
2.54
39
0.46
3.66
27
0.91
4.98
9
1.90
2.59
38
0.61
3.66
27
1.22
5.21
W
0.38
2.64
37
0.76
3.66
27
1.52
5.79
1
0.46
2.64
37
0.91
3.73
26
1.90
5.89
…
0.38
…
…
0.61
…
…
1.22
3.66
27
0.46
…
…
0.76
2.64
37
1.52
3.66
27
0.61
1.63
52
0.91
2.64
37
1.90
3.73
26
4.8 × 1.6
6.3 × 1.8
In Aluminum Alloy Sheet Metal
2.2 × 0.8
2.9 × 1
3.5 × 1.3
3.5 × 1.3
4.8 × 1.6
0.76
1.63
52
1.22
2.64
37
0.46
…
…
0.91
1.63
52
1.52
2.69
36
0.61
…
…
1.22
1.70
51
1.90
2.79
35
0.76
…
…
1.52
1.78
50
0.46
…
…
0.91
…
…
0.38
…
…
0.61
…
…
1.22
4.09
20
0.46
…
…
0.76
2.95
32
1.52
4.22
19
0.61
…
…
0.91
3.05
31
1.90
4.39
17
4.2 × 1.4
5.5 × 1.8
0.76
2.18
44
1.22
3.25
30
0.46
…
…
0.91
2.18
44
1.52
3.45
29
0.61
…
…
1.22
2.18
44
1.90
3.56
28
0.76
…
…
1.52
2.26
43
0.46
…
…
0.91
…
…
1.90
2.26
43
0.61
…
…
1.22
…
…
0.38
…
…
0.76
…
…
1.52
5.05
8
0.46
…
…
0.91
3.66
27
1.90
5.11
7
4.8 × 1.6
6.3 × 1.8
a Customary drill size references have been retained where the metric hole diameters are direct con-
versions of their decimal inch equivalents. All dimensions are in millimeters except drill sizes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC SELF-THREADING SCREWS
1661
Table 8. Approximate Hole Sizes for Steel Type AB Metric Thread Forming Tapping Screws in Plywoods and Asbestos Nominal Screw Size and Thread Pitch
Drill Sizea
Hole Size
Penetration in Blind Holes
Min Mat'l Thickness
Min
Penetration in Blind Holes Drill Sizea
Hole Size
Max
In Plywood (Resin Impregnated)
Min Mat'l Thickness
Min
Max
In Asbestors Compositions
2.2 ×0.8
1.85
49
3.18
4.78
12.70
1.93
48
3.18
4.78
2.9 ×1
2.54
39
4.78
6.35
15.88
2.57
38
4.78
6.35
15.88
3.5 ×1.3
3.18
…
4.78
6.35
15.88
3.05
31
4.78
6.35
15.88
4.2 ×1.4
3.66
27
4.78
6.35
19.05
3.73
26
7.92
9.52
19.05
4.8 ×1.6
4.39
17
6.35
7.92
25.40
4.22
19
7.92
9.52
25.40
5.5 ×1.8
4.93
10
7.92
9.52
25.40
4.98
9
7.92
9.52
25.40
6.3 ×1.8
5.79
1
7.92
9.52
25.40
5.79
1
11.13
12.70
25.40
12.70
a Customary drill size references have been retained where the metric hole diameters are direct con-
versions of their decimal inch equivalents. All dimensions are in millimeters except drill sizes.
Table 9. Approximate Hole Sizes for Steel Type B Metric Thread Forming Tapping Screws in Plywoods, Asbestos, and Plastics Nominal Screw Size and Thread Pitch
Drill Sizea
Hole Size
Min Mat'l Thickness
Penetration in Blind Holes Min
Max
Nominal Screw Size and Thread Pitch
Hole Size
Drill Sizea
Min Mat'l Thickness
Penetration in Blind Holes Min
Max
In Plywood (Resin Impregnated) 2.2 × 0.8
1.85
49
3.18
4.78
12.70
4.8 × 1.6
4.39
17
6.35
7.92
25.40
2.9 × 1
2.54
39
4.78
6.35
15.88
5.5 × 1.8
4.93
10
7.92
9.52
25.40
1
7.92
9.52
25.40
…
…
…
3.5 × 1.3
3.18
…
4.78
6.35
15.88
6.3 × 1.8
5.79
4.2 × 1.4
3.66
27
4.78
6.35
19.05
…
…
…
a Customary drill size references have been retained where the metric hole diameters are direct con-
versions of their decimal inch equivalents. Nominal Screw Size and Thread Pitch
Hole Size
Drill Sizea
Penetration in Blind Holes
Min Mat'l Thickness
Min
Max
4.78 6.35 6.35 9.52 9.52 9.52 12.70
12.70 15.88 15.88 19.05 25.40 25.40 25.40
In Asbestos Compositions 2.2 × 0.8 2.9 × 1 3.5 × 1.3 4.2 × 1.4 4.8 × 1.6 5.5 × 1.8 6.3 × 1.8 Nominal Screw Size and Thread Pitch
1.93 2.57 3.05 3.73 4.22 4.98 5.79 Hole Size
Drill Sizea
48 38 31 26 19 9 1 Min Penetration in Blind Holes
3.18 4.78 4.78 7.92 7.92 7.92 11.13 Hole Size
In Phenol Formaldehyde 2.2 × 0.8 2.9 × 1 3.5 × 1.3 4.2 × 1.4 4.8 × 1.6 5.5 × 1.8 6.3 × 1.8
1.98 2.54 3.25 3.81 4.50 5.05 5.94
47 39 30 25 16 8 …
Drill Sizea
Min Penetration in Blind Holes
In Cellulose Acetate & Nitrate, Acrylic and Styrene Resins 4.78 6.35 6.35 7.92 7.92 9.52 9.52
1.98 2.39 3.05 3.66 4.32 4.85 5.61
47 42 32 27 18 11 2
All dimensions are in millimeters except drill sizes.
Copyright 2004, Industrial Press, Inc., New York, NY
4.78 6.35 6.35 7.92 7.92 9.52 9.52
Machinery's Handbook 27th Edition 1662
METRIC SELF-THREADING SCREWS
Table 10. Approximate Drilled or Clean-Punched Hole Sizes for Steel Type B Metric Thread Forming Tapping Screws in Sheet Metal and Cast Metals Nominal Screw Size and Thread Pitch
2.2 × 0.8
2.9 × 1
3.5 × 1.3
2.2 × 0.8
2.9 × 1
3.5 × 1.3
Nominal Nominal Screw Screw Size and Metal Size and Drill Drill Thread ThickHole Thread Sizea Pitch ness Size Sizea Pitch In Steel, Stainless Steel, Monel, and Brass Sheet Metal
Metal Thickness
Hole Size
0.38 0.46 0.61 0.76 0.91 1.22 1.52 0.38 0.46 0.61 0.76 0.91 1.22 1.52 1.90 0.38 0.46 0.61 0.76 0.91 1.22 1.52
1.63 1.63 1.70 1.78 1.85 1.85 1.93 2.18 2.18 2.26 2.39 2.39 2.44 2.54 2.59 2.64 2.64 2.69 2.69 2.79 2.82 2.95
52 52 51 50 49 49 48 44 44 43 42 42 41 39 38 37 37 36 36 35 34 32
0.61 0.76 0.91 1.22 1.52 0.76 0.91 1.22 1.52 1.90 2.67 0.76 0.91 1.22 1.52 1.90 2.67 3.25 to 6.25
1.63 1.63 1.63 1.70 1.78 2.18 2.18 2.18 2.26 2.26 2.39 2.64 2.64 2.64 2.69 2.79 2.82
52 52 52 51 50 44 44 44 43 43 42 37 37 37 36 35 34
3.05
31
1.90 2.67 0.61 0.76 0.91 1.22 1.52 1.90 2.67 3.18 3.43 0.61 0.76 0.91 1.22 1.52 1.90 2.67 3.18 3.43 4.17
3.5 × 1.3
4.2 × 1.4
4.8 × 1.6
3.05 3.25 3.18 3.18 3.18 3.25 3.45 3.56 3.81 3.81 3.86 3.66 3.66 3.73 3.86 3.86 3.99 4.09 4.32 4.32 4.39
31 30 … … … 30 29 28 25 25 24 27 27 26 24 24 22 20 18 18 17
In Aluminum Alloy Sheet Metal 0.76 2.95 32 0.91 3.05 31 1.22 3.25 30 1.52 3.45 29 1.90 3.56 28 4.2 × 1.4 2.67 3.73 26 3.18 3.73 26 3.43 3.78 25 4.11 to 9.52 3.86 24 0.91 3.66 27 1.22 3.66 27 1.52 3.66 27 1.90 3.73 26 2.67 3.73 26 3.18 3.91 23 4.8 × 1.6 3.43 3.91 23 4.17 4.04 21 5.08 to 9.52 4.22 19
5.5 × 1.8
6.3 × 1.8
5.5 × 1.8
6.3 × 1.8
Metal Thickness
Hole Size
Drill Sizea
0.61 0.76 0.91 1.22 1.52 1.90 2.67 3.18 3.43 4.17 0.76 0.91 1.22 1.52 1.90 2.67 3.18 3.43 4.17 4.75 4.93
4.22 4.22 4.22 4.32 4.50 4.62 4.70 4.98 4.98 5.11 4.93 4.93 4.93 5.05 5.18 5.31 5.79 5.79 5.94 5.94 5.94
19 19 19 18 16 14 13 9 9 7 10 10 10 8 6 4 1 1 … … …
1.22 1.52 1.90 2.67 3.18 3.43 4.17 5.08 to 9.52 1.52 1.90 2.67 3.18 3.43 4.17 4.75 4.93 5.08 to 9.52
4.09 4.22 4.39 4.57 4.62 4.62 4.80
20 19 17 15 14 14 12
4.98 5.05 5.11 5.18 5.31 5.31 5.41 5.41 5.61
9 8 7 6 4 4 3 3 2
5.79
1
a Customary drill size references have been retained where the metric hole diameters are direct conversions of their decimal inch equivalents.
Nominal Screw Size and Thread Pitch
Hole Size
2.2 × 0.8 2.9 × 1 3.5 × 1.3 4.2 × 1.4
1.98 2.64 3.25 3.86
In Aluminum, Magnesium, Zinc, Brass, and Bronze Cast Metals Nominal Screw Size Min Drill and Thread Hole Penetration a Size Pitch Size in Blind Holes 47 37 30 24
3.18 4.78 6.35 6.35
4.8 × 1.6 5.5 × 1.8 6.3 × 1.8 …
4.50 5.05 5.94 …
Drill Sizea
Min Penetration in Blind Holes
16 8 4 …
6.35 7.14 7.92 …
All dimensions are in millimeters, except drill sizes.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition METRIC SELF-THREADING SCREWS
1663
Table 11. Approximate Hole Sizes for Steel Types BF and BT Metric Thread Cutting Tapping Screws for Cast Metals and Plastics Nominal Screw Size and Thread Pitch
2.2 × 0.8
2.9 × 1
4.8 × 1.6
5.5 × 1.8
6.3 × 1.8
Material Thickness
Hole Size
1.52 2.11 2.77 3.18 3.56 2.77 3.18 3.56 4.78 6.35 3.18 3.56 4.78 6.35 7.92 9.52 3.18 3.56 4.78 6.35 7.92 9.52 3.18 3.56 4.78
1.85 1.85 1.93 1.93 1.93 2.49 2.54 2.54 2.54 2.59 4.22 4.22 4.22 4.32 4.37 4.37 4.85 4.85 4.85 4.98 4.98 4.98 5.61 5.61 5.61
Nominal Screw Size and Thread Pitch 2.2 × 0.8 2.9 × 1.0 3.5 × 1.3 4.2 × 1.4 4.8 × 1.6 5.5 × 1.8 6.3 × 1.8 2.2 × 0.8 2.9 × 1.0 3.5 × 1.3 4.2 × 1.4 4.8 × 1.6 5.5 × 1.8 6.3 × 1.8
Nominal Drill Screw Size and Sizea Thread Pitch In Die Cast Zinc and Aluminum
Hole Size
49 49 48 48 48 40 39 39 39 38 19 19 19 18 … … 11 11 11 9 9 9 2 2 2
3.5 × 1.3
4.2 × 1.4
6.3 × 1.8
8 × 2.1
9.5 × 2.1
Drill Sizea In Phenol Formaldehyde
Material Thickness
Drill Sizea
Hole Size
3.18 3.05 3.56 3.05 4.78 3.05 6.35 3.18 7.92 3.18 3.18 3.78 3.56 3.78 4.78 3.78 6.35 3.86 7.92 3.86 6.35 5.79 7.92 5.79 9.52 5.79 3.18 7.14 3.56 7.14 4.78 7.14 6.35 7.14 7.92 7.37 9.52 7.37 3.18 8.74 3.56 8.74 4.78 8.74 6.35 8.74 7.92 8.84 9.52 8.84 Depth of Penetration Min Max
1.98 … 2.39 2.64 37 3.18 3.18 … 4.78 3.73 26 6.35 4.32 18 7.92 4.93 10 9.52 5.79 1 9.52 In Cellulose Acetate and Nitrate, Acrylic and Styrene Resins 1.93 48 2.39 2.54 39 3.18 3.05 31 4.78 3.66 27 6.35 4.22 19 7.92 4.80 12 9.52 5.61 2 9.52
31 31 31 … … 25 25 25 24 24 1 1 1 K K K K L L … … … … S S
6.35 7.92 9.52 12.70 15.88 15.88 19.05 6.35 7.92 9.52 12.70 15.88 15.88 19.05
a Customary drill size references have been retained where the metric hole sizes are direct conversions of their decimal inch equivalents.
All dimensions are in millimeters except drill sizes.
The finish (plating or coating) on metric tapping screws and the material composition and hardness of the mating component are factors that affect assembly torques in individual applications. Although the recommended installation hole sizes given in Tables 7 through 9 were based on the use of plain unfinished carbon steel metric tapping screws, experience has shown that the specified holes are also suitable for screws having most types of commercial finishes. However, owing to various finishes providing different degrees of lubricity, some adjustment of installation torques may be necessary to suit individual applications. Also, where exceptionally heavy finishes are involved or screws are to be assembled into materials of higher hardness, some deviation from the specified hole sizes may be required to provide optimum assembly. The necessity and extent of such deviations can best be determined by experiment in the particular assembly environment.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
1664
T-SLOTS, BOLTS, AND NUTS Table 1. American National Standard T-Slots ANSI/ASME B5.1M-1985 (R1998) T-SLOTS
Nominal T-Bolt Sizea inch
mm
0.250 0.312 0.375 0.500 0.625 0.750 1.000 1.250 1.500
4 5 6 8 10 12 16 20 24 30 36 42 48
Width of Throat A1b inch
mm
0.282 0.344 0.438 0.562 0.688 0.812 1.062 1.312 1.562
5 6 8 10 12 14 18 22 28 36 42 48 54
Width of Headspace B1
Depth of Headspace C1
inch
inch
min
0.500 0.594 0.719 0.906 1.188 1.375 1.750 2.125 2.562
mm max
min
max
0.562 0.656 0.781 0.969 1.250 1.469 1.844 2.219 2.656
10 11 14.5 16 19 23 30 37 46 56 68 80 90
11 12.5 16 18 21 25 32 40 50 60 72 85 95
min
0.203 0.234 0.297 0.359 0.453 0.594 0.781 1.031 1.281
Depth of Throat D1
mm
inch
max
min
max
0.234 0.266 0.328 0.391 0.484 0.625 0.828 1.094 1.344
3 5 7 7 8 9 12 16 20 25 32 36 40
3.5 6 8 8 9 11 14 18 22 28 35 40 44
min
0.125 0.156 0.219 0.312 0.438 0.562 0.750 1.000 1.250
Rounding or Breaking of Cornersc
mm
inch
max
min
max
0.375 0.438 0.562 0.688 0.875 1.062 1.250 1.562 1.938
4.5 5 7 9 11 12 16 20 26 33 39 44 50
7 8 11 14 17 19 24 29 36 46 53 59 66
R1 max
0.02 0.02 0.02 0.02 0.03 0.03 0.03 0.03 0.03
W1 max
0.02 0.03 0.03 0.03 0.03 0.03 0.06 0.06 0.06
mm U1 max
R1 max
W1 max
U1 max
0.03 0.03 0.03 0.03 0.05 0.05 0.05 0.05 0.05
0.5 0.5 0.5 0.5 0.5 0.5 0.8 0.8 0.8 0.8 0.8 1.5 1.5
0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 1.5 1.5 1.5 2.5 2.5
0.8 0.8 0.8 0.8 0.8 0.8 1.3 1.3 1.3 1.3 1.3 2 2
a Width of tongue (tenon) to be used with the above T-Slots will be found in the complete standard, B5.1M. b Throat dimensions are basic. When slots are intended to be used for holding only, tolerances can be 0.0 + 0.010 inch or H12 Metric (ISO/R286); when intended for location, tolerance can be 0.0 + 0.001 inch or H8 Metric (see page 670). c Corners of T-Slots may be square or may be rounded or broken to the indicated maximum dimensions at the manufacturer's option.
For the dimensions of tongue seats, inserted tongues, and solid tongues refer to the complete standard, B5.1M.
Copyright 2004, Industrial Press, Inc., New York, NY
T-BOLTS, SLOTS, NUTS, AND TONGUES
Suggested Approximate Dimensions For Rounding Or Breaking Of Corners
Basic Dimensions
Machinery's Handbook 27th Edition
Table 2. American National Standard T-Bolts ANSI/ASME B5.1M-1985 (R1998) T-BOLTS
Width Across Flats B2
inch
metric
inch
UNC-2A
ISOd
max
min
max
0.250–20 0.312–18 0.375–16 0.500–13 0.625–11 0.750–10 1.000–8 1.250–7 1.500–6
M4 M5 M6 M8 M10 M12 M16 M20 M24 M30 M36 M42 M48
0.469 0.562 0.688 0.875 1.125 1.312 1.688 2.062 2.500
0.438 0.531 0.656 0.844 1.094 1.281 1.656 2.031 2.469
9 10 13 15 18 22 28 34 43 53 64 75 85
Width Across Corners mm
mm
min
max
max
max
min
max
8.5 9.5 12 14 17 21 27 33 42 52 63 74 84
0.663 0.796 0.972 1.238 1.591 1.856 2.387 2.917 3.536
12.7 14.1 18.4 21.2 25.5 31.1 39.6 48.1 60.8 75 90.5 106.1 120.2
0.156 0.188 0.250 0.312 0.406 0.531 0.688 0.938 1.188
0.141 0.172 0.234 0.297 0.391 0.500 0.656 0.906 1.156
2.5 4 6 6 7 8 10 14 18 23 28 32 36
a For inch tolerances for thread diameters of bolts or studs and for threads see page
R2
Height C2
inch
inch
mm
W2
inch
mm
inch
mm
min
max
max
max
max
2.1 3.6 5.6 5.6 6.6 7.6 9.6 13.2 17.2 22.2 27.2 30.5 34.5
0.02 0.02 0.02 0.02 0.03 0.03 0.03 0.03 0.03
0.3 0.3 0.5 0.5 0.5 0.5 0.8 0.8 0.8 0.8 0.8 1 1
0.03 0.03 0.03 0.06 0.06 0.06 0.06 0.06 0.06
0.5 0.5 0.8 0.8 0.8 1.5 1.5 1.5 1.5 1.5 1.5 2 2
T-BOLTS, SLOTS, NUTS, AND TONGUES
Rounding of Cornersc
Bolt Head Dimensions
Nominal T-Bolt Size and Thread A2ab
1736.
b T-slots to be used with these bolts will be found in Table 1. d Metric thread grade and tolerance position is 5g 6g (see page
1790).
Copyright 2004, Industrial Press, Inc., New York, NY
1665
c Corners of T-bolts may be square or may be rounded or broken to the indicated maximum dimensions at the manufacturer's option.
Machinery's Handbook 27th Edition
1666
Table 3. American National Standard T-Nuts ANSI/ASME B5.1M-1985 (R1998) T-NUTS
0.250
inch
mm
max
mm min
max
min
inch
mm
UNC-3B
ISOd
Width of Nut B3 inch max
mm min
Rounding of Corners
Height of Nut C3
max min
inch max
mm min
max
min
Total Thickness Including Tonguec K3 inch
mm
Length of Nutc L3 inch
R3
mm
W3
inch
mm
inch
mm
max
max
max
max
4
…
…
…
…
…
…
…
…
…
…
…
5
…
…
…
…
…
…
…
…
…
…
…
…
…
6
…
…
…
…
…
…
…
…
…
…
…
…
…
…
…
…
…
…
… … …
…
0.312
8
0.330
0.320
8.7
8.5
0.250–20
M6
0.562
0.531
15
14
0.188
0.172
6
5.6
0.281
9
0.562
18
0.02
0.5
0.03
0.8
0.375
10
0.418
0.408
11
10.75
0.312–18
M8
0.688
0.656
18
17
0.250
0.234
7
6.6
0.375
10.5
0.688
20
0.02
0.5
0.03
0.8
0.500
12
0.543
0.533
13.5
13.25
0.375–1
6M10
0.875
0.844
22
21
0.312
0.297
8
7.6
0.531
12
0.875
23
0.02
0.5
0.06
1.5
0.625
16
0.668
0.658
17.25
17
0.500–13
M12
1.125
1.094
28
27
0.406
0.391
10
9.6
0.625
15
1.125
27
0.03
0.8
0.06
1.5
0.750
20
0.783
0.773
20.5
20.25
0.625–11
M16
1.312
1.281
34
33
0.531
0.500
14
13.2
0.781
21
1.312
35
0.03
0.8
0.06
1.5
1.000
24
1.033
1.018
26.5
26
0.750–10
M20
1.688
1.656
43
42
0.688
0.656
18
17.2
1.000
27
1.688
46
0.03
0.8
0.06
1.5
1.250
30
1.273
1.258
33
32.5
1.000–8
M24
2.062
2.031
53
52
0.938
0.906
23
22.2
1.312
34
2.062
53
0.03
0.8
0.06
1.5
1.500
36
1.523
1.508
39.25
38.75
1.250–7
M30
2.500
2.469
64
63
1.188
1.156
28
27.2
1.625
42
2.500
65
0.03
0.8
0.06
1.5
42
46.75
46.25
M36
75
74
32
30.5
48
75
1
2
48
52.5
51.75
M42
85
84
36
34.5
54
85
1
2
a T-slot dimensions to fit the above nuts will be found in Table 1. b For tolerances of inch threads see page
1736.
c No tolerances are given for “Total Thickness” or “Nut Length” as they need not be held to close limits. d Metric tapped thread grade and tolerance position is 5H (see page
1790).
Copyright 2004, Industrial Press, Inc., New York, NY
T-BOLTS, SLOTS, NUTS, AND TONGUES
inch
Tap for Studb E3
Width of Tongue A3
Nominal T-Bolt Sizea
Machinery's Handbook 27th Edition COTTER AND CLEVIS PINS
1667
PINS AND STUDS Dowel-Pins.—Dowel-pins are used either to retain parts in a fixed position or to preserve alignment. Under normal conditions a properly fitted dowel-pin is subjected solely to shearing strain, and this strain occurs only at the junction of the surfaces of the two parts which are being held by the dowel-pin. It is seldom necessary to use more than two dowelpins for holding two pieces together and frequently one is sufficient. For parts that have to be taken apart frequently, and where driving out of the dowel-pins would tend to wear the holes, and also for very accurately constructed tools and gages that have to be taken apart, or that require to be kept in absolute alignment, the taper dowel-pin is preferable. The taper dowel-pin is most commonly used for average machine work, but the straight type is given the preference on tool and gage work, except where extreme accuracy is required, or where the tool or gage is to be subjected to rough handling. The size of the dowel-pin is governed by its application. For locating nests, gage plates, etc., pins from 1⁄8 to 3⁄16 inch in diameter are satisfactory. For locating dies, the diameter of the dowel-pin should never be less than 1⁄4 inch; the general rule is to use dowel-pins of the same size as the screws used in fastening the work. The length of the dowel-pin should be about one and one-half to two times its diameter in each plate or part to be doweled. When hardened cylindrical dowel-pins are inserted in soft parts, ream the hole about 0.001 inch smaller than the dowel-pin. If the doweled parts are hardened, grind (or lap) the hole 0.0002 to 0.0003 inch under size. The hole should be ground or lapped straight, that is, without taper or “bell-mouth.” American National Standard Cotter Pins ANSI B18.8.1-1972 (R1994) L
C
D
C
A
B
L
A
B
Plane of Contact with Gage Dia. Aa & Width B Max.
Wire Width B Min.
Head Dia. C Min.
Prong Length D Min.
Hole Size
3⁄ 16
0.176
0.137
0.38
0.09
0.203
7⁄ 32
0.207
0.161
0.44
0.10
0.234
0.078
1⁄ 4
0.225
0.176
0.50
0.11
0.266
0.04
0.094
5⁄ 16
0.280
0.220
0.62
0.14
0.312
0.19
0.04
0.109
3⁄ 8
0.335
0.263
0.75
0.16
0.375
0.080
0.22
0.05
0.125
7⁄ 16
0.406
0.320
0.88
0.20
0.438
0.120
0.093
0.25
0.06
0.141
1⁄ 2
0.473
0.373
1.00
0.23
0.500
9⁄ 64
0.134
0.104
0.28
0.06
0.156
5⁄ 8
0.598
0.472
1.25
0.30
0.625
5⁄ 32
0.150
0.116
0.31
0.07
0.172
3⁄ 4
0.723
0.572
1.50
0.36
0.750
Nom. Size
Dia. Aa & Width B Max.
Wire Width B Min.
Head Dia. C Min.
Prong Length D Min.
Hole Size
1⁄ 32
0.032
0.022
0.06
0.01
0.047
3⁄ 64
0.048
0.035
0.09
0.02
0.062
1⁄ 16
0.060
0.044
0.12
0.03
5⁄ 64
0.076
0.057
0.16
3⁄ 32
0.090
0.069
7⁄ 64
0.104
1⁄ 8
Nom. Size
are: −0.004 inch for the 1⁄32- to 3⁄16-inch sizes, incl.; −0.005 inch for the 7⁄32- to 5⁄16-inch sizes, incl.; −0.006 inch for the 3⁄8- to 1⁄2-inch sizes, incl.; and −0.008 inch for the 5⁄8- and 3⁄4-inch sizes. Note: Tolerances for length are: up to 1 inch ± 0.030 inch, over 1 inch ±0.060 inch. All dimensions are in inches. a Tolerances
Copyright 2004, Industrial Press, Inc., New York, NY
; ;
Machinery's Handbook 27th Edition
1668
DOWEL PINS
American National Standard Clevis Pins ANSI B18.8.1-1972 (R1994)
Radius
1
G
+ 0.02 – 0.00
B A
H D F
45
L 0.005 0.015
Optional Nom.Size (Basic Pin Dia.)
C
R
E Dia. (Break Corners)
Shank Dia.A Max
Head Dia.B Max.a
Head Hgt.C Max.b
Head Chamfer D Nom.c
Hole Dia.E Max.d
Point Dia.F Max.e
Pin Lgth.G Basicf
Head to HoleCenter H Max.g
Max.
Min.
Cotter Pin Size for Hole
Point Length L
3⁄ 16
0.186
0.32
0.07
0.02
0.088
0.15
0.58
0.504
0.055
0.035
1⁄ 16
1⁄ 4
0.248
0.38
0.10
0.03
0.088
0.21
0.77
0.692
0.055
0.035
1⁄ 16
5⁄ 16
0.311
0.44
0.10
0.03
0.119
0.26
0.94
0.832
0.071
0.049
3⁄ 32
3⁄ 8
0.373
0.51
0.13
0.03
0.119
0.33
1.06
0.958
0.071
0.049
3⁄ 32
7⁄ 16
0.436
0.57
0.16
0.04
0.119
0.39
1.19
1.082
0.071
0.049
3⁄ 32
1⁄ 2
0.496
0.63
0.16
0.04
0.151
0.44
1.36
1.223
0.089
0.063
1⁄ 8
5⁄ 8
0.621
0.82
0.21
0.06
0.151
0.56
1.61
1.473
0.089
0.063
1⁄ 8
3⁄ 4
0.746
0.94
0.26
0.07
0.182
0.68
1.91
1.739
0.110
0.076
5⁄ 32
7⁄ 8
0.871
1.04
0.32
0.09
0.182
0.80
2.16
1.989
0.110
0.076
5⁄ 32
0.996
1.19
0.35
0.10
0.182
0.93
2.41
2.239
0.110
0.076
5⁄ 32
a Tolerance is −0.05 inch.
b Tolerance is −0.02 inch. c Tolerance is ±0.01 inch.
d Tolerance is −0.015 inch. e Tolerance is −0.01 inch.
f Lengths tabulated are intended for use with standard clevises, without spacers. When other lengths are required, it is recommended that they be limited wherever possible to nominal lengths in 0.06-inch increments. g Tolerance is −0.020 inch. All dimensions are in inches.
British Standard for Metric Series Dowel Pins.—Steel parallel dowel pins specified in British Standard 1804:Part 2:1968 are divided into three grades which provide different degrees of pin accuracy. Grade 1 is a precision ground pin made from En 32A or En 32B low carbon steel (BS 970) or from high carbon steel to BS 1407 or BS 1423. Pins below 4 mm diameter are unhardened. Those of 4 mm diameter and above are hardened to a minimum of 750 HV 30 in accordance with BS 427, but if they are made from steels to BS 1407 or BS 1423 then the hardness shall be within the range 600 to 700 HV 30, in accordance with BS 427. The values of other hardness scales may be used in accordance with BS 860. Grade 2 is a ground pin made from any of the steels used for Grade 1. The pins are normally supplied unhardened, unless a different condition is agreed on between the purchaser and supplier. Grade 3 pins are made from En 1A free cutting steel (BS 970) and are supplied with a machined, bright rolled or drawn finish. They are normally supplied unhardened unless a different condition is agreed on between the purchaser and supplier. Pins of any grade may be made from different steels in accordance with BS 970, by mutual agreement between the purchaser and manufacturer. If steels other than those in the
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition DOWEL PINS
1669
standard range are used, the hardness of the pins shall also be decided on by mutual agreement between purchaser and supplier. As shown in the illustration at the head of the accompanying table, one end of each pin is chamfered to provide a lead. The other end may be similarly chamfered, or domed. British Standard Parallel Steel Dowel Pins — Metric Series BS 1804: Part 2: 1968
Nom. Length L, mm 4 6 8 10 12 16 20 25 30 35 40 45 50 60 70 80 90 100 110 120
Nominal Diameter D, mm 4 5 6 8 Chamfer a max, mm 0.6 0.75 0.9 1.2 Standard Sizes
1
1.5
2
2.5
3
0.3
0.3
0.3
0.4
0.45
10
12
16
20
25
1.5
1.8
2.5
3
4
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
d
Limits of Tolerance on Diameter Gradea Tolerance Zone Nom. Dia., mm Over To & Incl. 3 3 6 10 14 18 24
6 10 14 18 24 30
1
2
3
m5
h7
h11
+7
+2
+9 +12 +15 +15 +17 +17
+4 +6 +7 +7 +8 +8
Limits of Tolerance, 0.001 mm 0 −12b 0 0 0 0 0 0
−12 −15 −18 −18 −21 −21
0
−60
0 0 0 0 0 0
−75 −90 −110 −110 −130 −130
a The limits of tolerance for grades 1 and 2 dowel pins have been chosen to provide satisfactory assembly when used in standard reamed holes (H7 and H8 tolerance zones). If the assembly is not satisfactory, refer to B.S. 1916: Part 1, Limits and Fits for Engineering, and select a different class of fit. b This tolerance is larger than that given in BS 1916, and has been included because the use of a closer tolerance would involve precision grinding by the manufacturer, which is uneconomic for a grade 2 dowel pin. The tolerance limits on the overall length of all grades of dowel pin up to and including 50 mm long are +0.5, −0.0 mm, and for pins over 50 mm long are +0.8, −0.0 mm. The Standard specifies that the roughness of the cylindrical surface of grades 1 and 2 dowel pins, when assessed in accordance with BS 1134, shall not be greater than 0.4 µm CLA (16 CLA).
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
1670
Table 1. American National Standard Hardened Ground Machine Dowel Pins ANSI/ASME B18.8.2-1995
Pin Diameter, A
3⁄ 32 1⁄ 8 5⁄ d 32 3⁄ 16 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
1
Standard Series Pins
Point Diameter, B
Oversize Series Pins
Crown Height, C
Crown Radius, R
Range of Preferred Lengths,b L 3⁄ –3⁄ 16 4 …
Single Shear Load, for Carbon or Alloy Steel, Calculated lb
Suggested Hole Diameterc
Basic
Max
Min
Basic
Max
Min
Max
Min
Max
Min
0.0627 0.0783
0.0628 0.0784
0.0626 0.0782
0.0635 0.0791
0.0636 0.0792
0.0634 0.0790
0.058 0.074
0.048 0.064
0.020 0.026
0.008 0.010
Max
Min
400 620
0.0625 0.0781
0.0620 0.0776
0.0938
0.0940
0.0941
0.0939
0.0948
0.0949
0.0947
0.089
0.079
0.031
0.012
0.1250
0.1252
0.1253
0.1251
0.1260
0.1261
0.1259
0.120
0.110
0.041
0.016
5⁄ –1 16 3⁄ –2 8
1,600
0.1250
0.1245
0.1562
0.1564
0.1565
0.1563
0.1572
0.1573
0.1571
0.150
0.140
0.052
0.020
…
2,500
900
0.0937 0.1562
0.1557
0.1875
0.1877
0.1878
0.1876
0.1885
0.1886
0.1884
0.180
0.170
0.062
0.023
0.2500
0.2502
0.2503
0.2501
0.2510
0.2511
0.2509
0.240
0.230
0.083
0.031
0.3125
0.3127
0.3128
0.3126
0.3135
0.3136
0.3134
0.302
0.290
0.104
0.039
0.3750
0.3752
0.3753
0.3751
0.3760
0.3761
0.3759
0.365
0.350
0.125
0.047
0.4375
0.4377
0.4378
0.4376
0.4385
0.4386
0.4384
0.424
0.409
0.146
0.055
0.5000
0.5002
0.5003
0.5001
0.5010
0.5011
0.5009
0.486
0.471
0.167
0.063
0.6250
0.6252
0.6253
0.6251
0.6260
0.6261
0.6259
0.611
0.595
0.208
0.078
0.7500
0.7502
0.7503
0.7501
0.7510
0.7511
0.7509
0.735
0.715
0.250
0.094
0.8750
0.8752
0.8753
0.8751
0.8760
0.8761
0.8759
0.860
0.840
0.293
0.109
1.0000
1.0002
1.0003
1.0001
1.0010
1.0011
1.0009
0.980
0.960
0.333
0.125
1⁄ –2 2 1⁄ –21⁄ 2 2 1⁄ –21⁄ 2 2 1⁄ –3 2 7⁄ –3 8 3⁄ , 1–4 4 1 1 ⁄4–5 11⁄2–6 2,21⁄2–6 2,21⁄2–5,6
0.0932
3,600
0.1875
0.1870
6,400
0.2500
0.2495
10,000
0.3125
0.3120
14,350
0.3750
0.3745
19,550
0.4375
0.4370
25,500
0.5000
0.4995
39,900
0.6250
0.6245
57,000
0.7500
0.7495
78,000
0.8750
0.8745
102,000
1.0000
0.9995
a Where specifying nominal size as basic diameter, zeros preceding decimal and in the fourth decimal place are omitted. b Lengths increase in 1⁄ -inch steps up to 3⁄ inch, in 1⁄ -inch steps from 3⁄ inch to 1 inch, in 1⁄ -inch steps from 1 inch to 21⁄ inches, and in 1⁄ -inch steps above 21⁄ inches. 16 8 8 8 4 2 2 2 Tolerance on length is ±0.010 inch. c These hole sizes have been commonly used for press fitting Standard Series machine dowel pins into materials such as mild steels and cast iron. In soft materials such as aluminum or zinc die castings, hole size limits are usually decreased by 0.0005 inch to increase the press fit. d Nonpreferred sizes, not recommended for use in new designs. All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
DOWEL PINS
Nominal Sizea or Nominal Pin Diameter 1⁄ 0.0625 16 5⁄ d 0.0781 64
Machinery's Handbook 27th Edition DOWEL PINS
1671
If a dowel pin is driven into a blind hole where no provision is made for releasing air, the worker assembling the pin may be endangered, and damage may be caused to the associated component, or stresses may be set up. The appendix of the Standard describes one method of overcoming this problem by providing a small flat surface along the length of a pin to permit the release of air. For purposes of marking, the Standard states that each package or lot of dowel pins shall bear the manufacturer's name or trademark, the BS number, and the grade of pin. American National Standard Hardened Ground Machine Dowel Pins.—H a r d e n e d ground machine dowel pins are furnished in two diameter series: Standard Series having basic diameters 0.0002 inch over the nominal diameter, intended for initial installations; and Oversize Series having basic diameters 0.001 inch over the nominal diameter, intended for replacement use. Preferred Lengths and Sizes: The preferred lengths and sizes in which these pins are normally available are given in Table 1. Other sizes and lengths are produced as required by the purchaser. Effective Length: The effective length, Le, must not be less than 75 per cent of the overall length of the pin. Shear Strength: Single shear strength values are listed in Table 1. Prior versions of ANSI/ASME B18.8.2-1995 had listed double shear load minimum values and had specified a minimum single shear strength of 130,000 psi. See ANSI/ASME B18.8.2-1995, Appendix B for a description of the double shear test. Designation: These pins are designated by the following data in the sequence shown: Product name (noun first), including pin series, nominal pin diameter (fraction or decimal equivalent), length (fraction or decimal equivalent), material, and protective finish, if required. Examples: Pins, Hardened Ground Machine Dowel — Standard Series, 3⁄8 × 11⁄2, Steel, Phosphate Coated. Pins, Hardened Ground Machine Dowel — Oversize Series, 0.625 × 2.500, Steel Installation Precaution: Pins should not be installed by striking or hammering and when installing with a press, a shield should be used and safety glasses worn. American National Standard Hardened Ground Production Dowel Pins.—H a r d ened ground production dowel pins have basic diameters that are 0.0002 inch over the nominal pin diameter. Preferred Lengths and Sizes: The preferred lengths and sizes in which these pins are available are given in Table 2. Other sizes and lengths are produced as required by the purchaser. Shear Strength: Single shear strength values are listed in Table 2. Prior versions of ANSI/ASME B18.8.2-1995 had listed double shear load minimum values and had specified a minimum single shear strength of 102,000 psi. See ANSI/ASME B18.8.2-1995, Appendix B for a description of the double shear test. Ductility: These standard pins are sufficiently ductile to withstand being pressed into holes 0.0005 inch smaller than the nominal pin diameter in hardened steel without cracking or shattering. Designation: These pins are designated by the following data in the sequence shown: Product name (noun first), nominal pin diameter (fraction or decimal equivalent), length (fraction or decimal equivalent), material, and protective finish, if required. Examples: Pins, Hardened Ground Production Dowel, 1⁄8 × 3⁄4, Steel, Phosphate Coated Pins, Hardened Ground Production Dowel, 0.375 × 1.500, Steel
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1672
DOWEL PINS
Table 2. American National Standard Hardened Ground Production Dowel Pins ANSI/ASME B18.8.2-1995
Nominal Sizea or Nominal Pin Diameter
Corner Radius, R
Suggested Hole Diameterc
Basic
Max
Min
Max
Min
Range of Preferred Lengths,b L
Max
Min
1⁄ 16
0.0625
0.0627
0.0628
0.0626
0.020
0.010
3⁄ – 16 1
395
0.0625
0.0620
3⁄ 32
0.0938
0.0939
0.0940
0.0938
0.020
0.010
3⁄ –2 16
700
0.0937
0.0932
7⁄ 64
0.1094
0.1095
0.1096
0.1094
0.020
0.010
3⁄ –2 16
950
0.1094
0.1089
1⁄ 8
0.1250
0.1252
0.1253
0.1251
0.020
0.010
3⁄ –2 16
1,300
0.1250
0.1245
5⁄ 32
0.1562
0.1564
0.1565
0.1563
0.020
0.010
3⁄ –2 16
2,050
0.1562
0.1557
3⁄ 16
0.1875
0.1877
0.1878
0.1876
0.020
0.010
3⁄ –2 16
2,950
0.1875
0.1870
7⁄ 32
0.2188
0.2189
0.2190
0.2188
0.020
0.010
1⁄ –2 4
3,800
0.2188
0.2183
1⁄ 4
0.2500
0.2502
0.2503
0.2501
0.020
0.010
1⁄ –11⁄ , 4 2
13⁄4, 2–21⁄2
5,000
0.2500
0.2495
5⁄ 16
0.3125
0.3127
0.3128
0.3126
0.020
0.010
5⁄ –11⁄ , 16 2
13⁄4, 2–21⁄2
8,000
0.3125
0.3120
3⁄ 8
0.3750
0.3752
0.3753
0.3751
0.020
0.010
3⁄ –11⁄ , 8 2
13⁄4, 2–3
11,500
0.3750
0.3745
Pin Diameter, A
Single Shear Load, Calculated,lb
a Where specifying nominal pin size in decimals, zeros preceding decimal and in the fourth decimal
place are omitted. b Lengths increase in 1⁄ -inch steps up to 1 inch, in 1⁄ -inch steps from 1 inch to 2 inches and then are 16 8 21⁄4, 21⁄2, and 3 inches. c These hole sizes have been commonly used for press fitting production dowel pins into materials such as mild steels and cast iron. In soft materials such as aluminum or zinc die castings, hole size limits are usually decreased by 0.0005 inch to increase the press fit. All dimensions are in inches.
American National Standard Unhardened Ground Dowel Pins.—U n h a r d e n e d ground dowel pins are normally produced by grinding the outside diameter of commercial wire or rod material to size. Consequently, the maximum diameters of the pins, as specified in Table 3, are below the minimum commercial stock sizes by graduated amounts from 0.0005 inch on the 1⁄16-inch nominal pin size to 0.0028 inch on the 1-inch nominal pin size. Preferred Lengths and Sizes: The preferred lengths and sizes in which unhardened ground pins are normally available are given in Table 3. Other sizes and lengths are produced as required by the purchaser. Shear Strength: These pins must have a single shear strength of 64,000 psi minimum for pins made from steel and 40,000 psi minimum for pins made from brass and must be capable of withstanding the minimum double shear loads given in Table 3 when tested in accordance with the procedure outlined in ANSI/ASME B18.8.2-1995, Appendix B. Designation: These pins are designated by the following data in the order shown: Product name (noun first), nominal pin diameter (fraction or decimal equivalent), length (fraction or decimal equivalent), material, and protective finish, if required. Examples: Pins, Unhardened Ground Dowel, 1⁄8 × 3⁄4, Steel Pins, Unhardened Ground Dowel, 0.250 × 2.500, Steel, Zinc Plated
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition DOWEL PINS
1673
Table 3. American National Standard Unhardened Ground Dowel Pins ANSI/ASME B18.8.2-1995
Nominal Sizea or Basic Pin Diameter
1
Pin Diameter, A
Chamfer Length,C
Range of Preferred Lengths,b L
Suggested Hole Diameterc
Double Shear Load Min, lb. CarbonSteel
Brass
0.0580
350
220
0.0907
0.0892
820
510
0.1062
0.1047
1,130
710
1⁄ –2 4
0.1217
0.1202
1,490
930
0.005
1⁄ –2 4
0.1528
0.1513
2,350
1,470
0.025
0.005
1⁄ –2 4
0.1840
0.1825
3,410
2,130
0.025
0.005
1⁄ –2 4
0.2151
0.2136
4,660
2,910
0.2465
0.025
0.005
1⁄ –11⁄ , 4 2
0.2462
0.2447
6,120
3,810
0.3094
0.3089
0.040
0.020
5⁄ –11⁄ , 16 2
13⁄4, 2–21⁄2
0.3085
0.3070
9,590
5,990
0.3750
0.3717
0.3712
0.040
0.020
3⁄ –11⁄ , 8 2
13⁄4, 2–21⁄2
0.3708
0.3693
13,850
8,650
7⁄ 16
0.4375
0.4341
0.4336
0.040
0.020
7⁄ –5⁄ , 3⁄ , 7⁄ –11⁄ , 16 8 4 8 2 13⁄4, 2–21⁄2
0.4331
0.4316
18,900
11,810
1⁄ 2
0.5000
0.4964
0.4959
0.040
0.020
1⁄ , 5⁄ , 3⁄ , 7⁄ , 2 8 4 8 13⁄4, 2–3
0.4954
0.4939
24,720
15,450
5⁄ 8
0.6250
0.6211
0.6206
0.055
0.035
5⁄ , 3⁄ , 7⁄ , 1–11⁄ , 13⁄ , 8 4 8 2 4 2, 21⁄2–4
0.6200
0.6185
38,710
24,190
3⁄ 4
0.7500
0.7458
0.7453
0.055
0.035
3⁄ , 7⁄ , 1, 11⁄ , 11⁄ , 4 8 4 2 13⁄4, 2, 21⁄2–4
0.7446
0.7431
55,840
34,900
7⁄ 8
0.8750
0.8705
0.8700
0.070
0.050
7⁄ , 1, 11⁄ , 11⁄ , 13⁄ , 8 4 2 4 2, 21⁄2–4
0.8692
0.8677
76,090
47,550
1.0000
0.9952
0.9947
0.070
0.050
1, 11⁄4, 11⁄2, 13⁄4, 2, 21⁄2–4
0.9938
0.9923
99,460
62,160
Max
Min
Max
Max
Min
0.005
1⁄ –1 4
0.0595
0.025
0.005
1⁄ –11⁄ 4 2
0.1063
0.025
0.005
0.1223
0.1218
0.025
0.005
0.1562
0.1535
0.1530
0.025
3⁄ 16
0.1875
0.1847
0.1842
7⁄ 32
0.2188
0.2159
0.2154
1⁄ 4
0.2500
0.2470
5⁄ 16
0.3125
3⁄ 8
1⁄ 16
0.0625
0.0600
0.0595
0.025
3⁄ 32
0.0938
0.0912
0.0907
d7⁄ 64
0.1094
0.1068
1⁄ 8
0.1250
5⁄ 32
Min
…
13⁄4, 2–21⁄2
1–11⁄2,
a Where specifying pin size in decimals, zeros preceding decimal and in the fourth decimal place are omitted. b Lengths increase in 1⁄ -inch increments from 1⁄ to 1 inch, in 1⁄ -inch increments from 1 inch to 2 16 4 8 inches, and in 1⁄4-inch increments from 2 to 21⁄2 inches, and in 1⁄2-inch increments from 21⁄2 to 4 inches. c These hole sizes have been found to be satisfactory for press fitting pins into mild steel and cast and malleable irons. In soft materials such as aluminum alloys or zinc die castings, hole size limits are usually decreased by 0.0005 inch to increase the press fit. d Nonpreferred size, not recommended for use in new designs.
All dimensions are in inches.
American National Standard Straight Pins.—The diameter of both chamfered and square end straight pins is that of the commercial wire or rod from which the pins are made. The tolerances shown in Table 4 are applicable to carbon steel and some deviations in the diameter limits may be necessary for pins made from other materials.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1674
STRAIGHT PINS
Table 4. American National Standard Chamfered and Square End Straight Pins ANSI/ASME B18.8.2-1995
CHAMFERED STRAIGHT PIN Nominal Sizea or Basic Pin Diameter 1⁄ 16 3⁄ 32 7⁄ 64 1⁄ 8 5⁄ 32 3⁄ 16 7⁄ 32 1⁄ 4
Pin Diameter, A
SQUARE END STRAIGHT PIN
Chamfer Length, C
Max
Min
Max
Min
0.062 0.094 0.109 0.125 0.156
0.0625 0.0937 0.1094 0.1250 0.1562
0.0605 0.0917 0.1074 0.1230 0.1542
0.025 0.025 0.025 0.025 0.025
0.005 0.00 0.005 0.005 0.005
0.188 0.219 0.250
0.1875 0.2187 0.2500
0.1855 0.2167 0.2480
0.025 0.025 0.025
0.005 0.005 0.005
Nominal Sizeb or Basic Pin Diameter 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 5⁄ 8 3⁄ 4 7⁄ 8
1
Pin Diameter, A
Chamfer Length, C
Max
Min
Max
Min
0.312 0.375 0.438 0.500 0.625
0.3125 0.3750 0.4375 0.5000 0.6250
0.3105 0.3730 0.4355 0.4980 0.6230
0.040 0.040 0.040 0.040 0.055
0.020 0.020 0.020 0.020 0.035
0.750 0.875 1.000
0.7500 0.8750 1.0000
0.7480 0.8730 0.9980
0.055 0.055 0.055
0.035 0.035 0.035
a Where specifying nominal size in decimals, zeros preceding decimal point are omitted. b Where specifying nominal size in decimals, zeros preceding decimal point are omitted.
All dimensions are in inches.
Length Increments: Lengths are as specified by the purchaser; however, it is recommended that nominal pin lengths be limited to increments of not less than 0.062 inch. Material: Straight pins are normally made from cold drawn steel wire or rod having a maximum carbon content of 0.28 per cent. Where required, pins may also be made from corrosion resistant steel, brass, or other metals. Designation: Straight pins are designated by the following data, in the sequence shown: Product name (noun first), nominal size (fraction or decimal equivalent), material, and protective finish, if required. Examples: Pin, Chamfered Straight, 1⁄8 × 1.500, Steel Pin, Square End Straight, 0.250 × 2.250, Steel, Zinc Plated American National Standard Taper Pins.—Taper pins have a uniform taper over the pin length with both ends crowned. Most sizes are supplied in commercial and precision classes, the latter having generally tighter tolerances and being more closely controlled in manufacture. Diameters: The major diameter of both commercial and precision classes of pins is the diameter of the large end and is the basis for pin size. The diameter at the small end is computed by multiplying the nominal length of the pin by the factor 0.02083 and subtracting the result from the basic pin diameter. See also Table 5. Taper: The taper on commercial class pins is 0.250 ± 0.006 inch per foot and on the precision class pins is 0.250 ± 0.004 inch per foot of length. Materials: Unless otherwise specified, taper pins are made from SAE 1211 steel or cold drawn SAE 1212 or 1213 steel or equivalents, and no mechanical property requirements apply. Hole Sizes: Under most circumstances, holes for taper pins require taper reaming. Sizes and lengths of taper pins for which standard reamers are available are given in Table 6. Drilling specifications for taper pins are given below.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPER PINS
1675
Designation: Taper pins are designated by the following data in the sequence shown: Product name (noun first), class, size number (or decimal equivalent), length (fraction or three-place decimal equivalent), material, and protective finish, if required. Examples: Pin, Taper (Commercial Class) No. 0 × 3⁄4, Steel Pin, Taper (Precision Class) 0.219 × 1.750, Steel, Zinc Plated Table 5. Nominal Diameter at Small Ends of Standard Taper Pins Pin Length in inches
0
1
2
3
4
5
6
7
8
9
10
3⁄ 4
0.140
0.156
0.177
0.203
0.235
0.273
0.325
0.393
0.476
0.575
0.690
11⁄4
0.135 0.130
0.151 0.146
0.172 0.167
0.198 0.192
0.230 0.224
0.268 0.263
0.320 0.315
0.388 0.382
0.471 0.466
0.570 0.565
0.685 0.680
11⁄2
0.125
0.141
0.162
0.187
0.219
0.258
0.310
0.377
0.460
0.560
0.675
13⁄4
0.120
0.136
0.157
0.182
0.214
0.252
0.305
0.372
0.455
0.554
0.669
2 21⁄4
0.114 0.109
0.130 0.125
0.151 0.146
0.177 0.172
0.209 0.204
0.247 0.242
0.299 0.294
0.367 0.362
0.450 0.445
0.549 0.544
0.664 0.659
21⁄2
0.104
0.120
0.141
0.166
0.198
0.237
0.289
0.356
0.440
0.539
0.654
23⁄4
0.099
0.115
0.136
0.161
0.193
0.232
0.284
0.351
0.434
0.534
0.649
3 31⁄4
0.094 …
0.110 …
0.131 …
0.156 0.151
0.188 0.182
0.227 0.221
0.279 0.273
0.346 0.340
0.429 0.424
0.528 0.523
0.643 0.638
31⁄2
…
…
…
0.146
0.177
0.216
0.268
0.335
0.419
0.518
0.633
33⁄4
…
…
…
0.141
0.172
0.211
0.263
0.330
0.414
0.513
0.628
4 41⁄4
… …
… …
… …
0.136 0.131
0.167 0.162
0.206 0.201
0.258 0.253
0.326 0.321
0.409 0.403
0.508 0.502
0.623 0.617
41⁄2
…
…
…
0.125
0.156
0.195
0.247
0.315
0.398
0.497
0.612
5 51⁄2
… …
… …
… …
… …
0.146 …
0.185 …
0.237 …
0.305 0.294
0.389 0.377
0.487 0.476
0.602 0.591
6
…
…
…
…
…
…
…
0.284
0.367
0.466
0.581
1
Pin Number and Small End Diameter for Given Length
Drilling Specifications for Taper Pins.—When helically fluted taper pin reamers are used, the diameter of the through hole drilled prior to reaming is equal to the diameter at the small end of the taper pin. (See Table 5.) However, when straight fluted taper reamers are to be used, it may be necessary, for long pins, to step drill the hole before reaming, the number and sizes of the drills to be used depending on the depth of the hole (pin length). To determine the number and sizes of step drills required: Find the length of pin to be used at the top of the chart on page 1676 and follow this length down to the intersection with that heavy line which represents the size of taper pin (see taper pin numbers at the right-hand end of each heavy line). If the length of pin falls between the first and second dots, counting from the left, only one drill is required. Its size is indicated by following the nearest horizontal line from the point of intersection (of the pin length) on the heavy line over to the drill diameter values at the left. If the intersection of pin length comes between the second and third dots, then two drills are required. The size of the smaller drill then corresponds to the intersection of the pin length and the heavy line and the larger is the corresponding drill diameter for the intersection of one-half this length with the heavy line. Should the pin length fall between the third and fourth dots, three drills are required. The smallest drill will have a diameter corresponding to the intersection of the total pin length with the heavy line, the next in size will have a diameter corresponding to the intersection of two-thirds of this length with the heavy line and the largest will have a diameter corresponding to the intersection of one-third of this length with the heavy line. Where the intersection falls between two drill sizes, use the smaller.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1676
TAPER-PIN REAMER DRILLS Chart to Facilitate Selection of Number and Sizes of Drills for Step-Drilling Prior to Taper Reaming
Drill dia 0.0156 0.0312 0.0469 0.0625 0.0781 0.0938 0.1094 0.1250 0.1406 0.1562 0.1719 0.1875 0.2031 0.2188 0.2344 0.2500 0.2656 0.2812 0.2969 0.3125 0.3281 0.3438 0.3594 0.3750 0.3906 0.4062 0.4219 0.4375 0.4531 0.4688 0.4844 0.5000 0.5156 0.5312 0.5469 0.5625 0.5781 0.5938 0.6094 0.6250 0.6406 0.6562 0.6719 0.6875 0.7031
Pin dia
Length of Pin in Inches 2 3 4
1
5
6
7/0
0.0625 0.0780 0.0940 0.1090 0.1250 0.1410 0.1560
6/0 5/0 4/0 3/0
2/0
0 1 2 3 4
0.1720 0.1930 0.2190
5 6
0.2500 0.2890 7
0.3410 8
0.4090
9
0.4920
10
0.5910
0.7060
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition TAPER AND GROOVED PINS
1677
Examples:For a No. 10 taper pin 6inches long, three drills would be used, of the sizes and for the depths shown in the accompanying diagram. For a No. 10 taper pin 3-inches long, two drills would be used because the 3inch length falls between the second and third dots. The first or through drill will be 0.6406 inch and the second drill, 0.6719 inch for a depth of 11⁄2 inches. Table 6. American National Standard Taper Pins ANSI/ASME B18.8.2-1995
Pin Size Number and Basic Pin Dia.a
Major Diameter (Large End), A Commercial Class Precision Class Max Min Max Min
End Crown Radius, R Max Min
Range of Lengths,b L Stand. Reamer Avail.c Other
7⁄ 0 6⁄ 0 5⁄ 0 4⁄ 0 3⁄ 0 2⁄ 0
0.0625
0.0638
0.0618
0.0635
0.0625
0.072
0.052
…
0.0780
0.0793
0.0773
0.0790
0.0780
0.088
0.068
…
0.0940
0.0953
0.0933
0.0950
0.0940
0.104
0.084
0.1090
0.1103
0.1083
0.1100
0.1090
0.119
0.099
0.1250
0.1263
0.1243
0.1260
0.1250
0.135
0.115
0.1410
0.1423
0.1403
0.1420
0.1410
0.151
0.131
0
0.1560
0.1573
0.1553
0.1570
0.1560
0.166
0.146
1
0.1720
0.1733
0.1713
0.1730
0.1720
0.182
0.162
2
0.1930
0.1943
0.1923
0.1940
0.1930
0.203
0.183
3
0.2190
0.2203
0.2183
0.2200
0.2190
0.229
0.209
4
0.2500
0.2513
0.2493
0.2510
0.2500
0.260
0.240
5
0.2890
0.2903
0.2883
0.2900
0.2890
0.299
0.279
6
0.3410
0.3423
0.3403
0.3420
0.3410
0.351
0.331
7
0.4090
0.4103
0.4083
0.4100
0.4090
0.419
0.399
8
0.4920
0.4933
0.4913
0.4930
0.4920
0.502
0.482
9
0.5910
0.5923
0.5903
0.5920
0.5910
0.601
0.581
10
0.7060
0.7073
0.7053
0.7070
0.7060
0.716
0.696
11 12 13 14
0.8600 1.0320 1.2410 1.5210
0.8613 1.0333 1.2423 1.5223
0.8593 1.0313 1.2403 1.5203
… … … …
… … … …
0.870 1.042 1.251 1.531
0.850 1.022 1.231 1.511
1⁄ –1 4 1⁄ –1 4 1⁄ –1 4 1⁄ –11⁄ 2 4 1⁄ –11⁄ 2 4 3⁄ –11⁄ 4 4 3⁄ –11⁄ 4 2 3⁄ –13⁄ 4 4 3⁄ –2 4 1 1–2 ⁄2 11⁄4–3 11⁄4–33⁄4 11⁄4–41⁄2 11⁄4–51⁄4 11⁄2–6
… … … …
1⁄ –1 4 1⁄ –1⁄ 4 2 11⁄4, 11⁄2 11⁄4–2 11⁄4–2 11⁄2–21⁄2 11⁄2–3 11⁄2–3 13⁄4–3
2–4 21⁄4–4 23⁄4–6 31⁄4–6 4–8 43⁄4–8 51⁄2–8 61⁄4–8 2–8 2–9 3–11 3–13
a When specifying nominal pin size in decimals, zeros preceding the decimal and in the fourth decimal place are omitted. b Lengths increase in 1⁄ -inch steps up to 1 inch and in 1⁄ -inch steps above 1 inch. 8 4 c Standard reamers are available for pin lengths in this column. All dimensions are in inches. For nominal diameters, B, see Table 5.
American National Standard Grooved Pins.—These pins have three equally spaced longitudinal grooves and an expanded diameter over the crests of the ridges formed by the material displaced when the grooves are produced. The grooves are aligned with the axes of the pins. There are seven types of grooved pins as shown in the illustration on page 1679. Standard Sizes and Lengths: The standard sizes and lengths in which grooved pins are normally available are given in Table 7.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1678
PINS AND STUDS
Materials: Grooved pins are normally made from cold drawn low carbon steel wire or rod. Where additional performance is required, carbon steel pins may be supplied surface hardened and heat treated to a hardness consistent with the performance requirements. Pins may also be made from alloy steel, corrosion resistant steel, brass, Monel and other non-ferrous metals having chemical properties as agreed upon between manufacturer and purchaser. Performance Requirements: Grooved pins are required to withstand the minimum double shear loads given in Table 7 for the respective materials shown, when tested in accordance with the Double Shear Testing of Pins as set forth in ANSI/ASME B18.8.2-1995, Appendix B. Hole Sizes: To obtain maximum product retention under average conditions, it is recommended that holes for the installation of grooved pins be held as close as possible to the limits shown in Table 7. The minimum limits correspond to the drill size, which is the same as the basic pin diameter. The maximum limits are generally suitable for length-diameter ratios of not less than 4 to 1 nor greater than 10 to 1. For smaller length-to-diameter ratios, the hole should be held closer to the minimum limits where retention is critical. Conversely for larger ratios where retention requirements are less important, it may be desirable to increase the hole diameters beyond the maximum limits shown. Designation: Grooved pins are designated by the following data in the sequence shown: Product name (noun first) including type designation, nominal size (number, fraction or decimal equivalent), length (fraction or decimal equivalent), material, including specification or heat treatment where necessary, protective finish, if required. Examples: Pin, Type A Grooved, 3⁄32 × 3⁄4, Steel, Zinc Plated Pin, Type F Grooved, 0.250 × 1.500, Corrosion Resistant Steel American National Standard Grooved T-Head Cotter Pins and Round Head Grooved Drive Studs.—The cotter pins have a T-head and the studs a round head. Both pins and studs have three equally spaced longitudinal grooves and an expanded diameter over the crests of the raised ridges formed by the material displaced when the grooves are formed. Standard Sizes and Lengths: The standard sizes and range of standard lengths are given in Tables 8 and 9. Material: Unless otherwise specified these pins are made from low carbon steel. Where so indicated by the purchaser they may be made from corrosion resistant steel, brass or other non-ferrous alloys. Hole Sizes: To obtain optimum product retention under average conditions, it is recommended that holes for the installation of grooved T-head cotter pins and grooved drive studs be held as close as possible to the limits tabulated. The minimum limits given correspond to the drill size, which is equivalent to the basic shank diameter. The maximum limits shown are generally suitable for length-diameter ratios of not less than 4 to 1 and not greater than 10 to 1. For smaller length-to-diameter ratios, the holes should be held closer to minimum limits where retention is critical. Conversely, for larger length-to-diameter ratios or where retention requirements are not essential, it may be desirable to increase the hole diameter beyond the maximum limits shown. Designation: Grooved T-head cotter pins and round head grooved drive studs are designated by the following data, in the order shown: Product name (noun first), nominal size (number, fraction or decimal equivalent), length (fraction or decimal equivalent), material including specification or heat treatment where necessary, and protective finish, if required. Examples: Pin, Grooved T-Head Cotter, 1⁄4 × 11⁄4, Steel, Zinc Plated Drive Stud, Round Head Grooved, No. 10 × 1⁄2, Corrosion Resistant Steel
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
L
L
See Note 3 B
E
A
F See Note 2 Type A B
See Note 3
D
D
C
C
C
A
A
F See Note 2 Type C E
L 2
E
B
L
E
L
30° – 45° Both Ends Type F
E E
L 2
L 4
L 2
L
E
PINS
A
F See Note 2 Type B
A
F
See Note 2 Type D
E See Note 3
J
A
F
See Note 2 Type E
F
E
L H
B
F
L 2 C
K A
G Type G
F Both Ends – See Note 2
Copyright 2004, Industrial Press, Inc., New York, NY
1679
Types of American National Standard Grooved Pins, ANSI/ASME B18.8.2-1995 (For notes see bottom of Table 7.)
Machinery's Handbook 27th Edition
Chamfer Pilot Length, C Length,b D Ref Min 0.015 … 0.031 … 0.031 0.016 0.031 0.016 0.031 0.016 0.031 0.016 0.031 0.016 0.062 0.031 0.062 0.031 0.062 0.031 0.062 0.031 0.094 0.047 0.094 0.047 0.094 0.047 0.094 0.047
Crown Height,b E Max Min … … … … 0.0115 0.0015 0.0137 0.0037 0.0141 0.0041 0.0160 0.0060 0.0180 0.0080 0.0220 0.0120 0.0230 0.0130 0.0270 0.0170 0.0310 0.0210 0.0390 0.0290 0.0440 0.0340 0.0520 0.0420 0.0570 0.0470
Crown Radius,b F Max Min … … … … 0.088 0.068 0.104 0.084 0.135 0.115 0.150 0.130 0.166 0.146 0.198 0.178 0.260 0.240 0.291 0.271 0.322 0.302 0.385 0.365 0.479 0.459 0.541 0.521 0.635 0.615
Neck Width, G Max Min … … … … … … … … 0.038 0.028 0.038 0.028 0.069 0.059 0.069 0.059 0.069 0.059 0.101 0.091 0.101 0.091 0.132 0.122 0.132 0.122 0.195 0.185 0.195 0.185
Shoulder Length, H Max Min … … … … … … … … 0.041 0.031 0.041 0.031 0.041 0.031 0.057 0.047 0.057 0.047 0.072 0.062 0.072 0.062 0.104 0.094 0.135 0.125 0.135 0.125 0.135 0.125
Neck Radius, J Ref … … … … 0.016 0.016 0.031 0.031 0.031 0.047 0.047 0.062 0.062 0.094 0.094
Neck Diameter, K Max Min … … … … … … … … 0.067 0.057 0.082 0.072 0.088 0.078 0.109 0.099 0.130 0.120 0.151 0.141 0.172 0.162 0.214 0.204 0.255 0.245 0.298 0.288 0.317 0.307
Range of Standard Lengthsc 1⁄ –1⁄ 8 2 1⁄ –5⁄ 8 8 1⁄ –1 8 1⁄ –1 4 1⁄ –11⁄ 4 4 1⁄ –11⁄ 4 4 1⁄ –11⁄ 4 2 3⁄ –2 8 3⁄ –21⁄ 8 4 1⁄ –3 2 1⁄ –31⁄ 2 4 5⁄ –31⁄ 8 2 3⁄ –41⁄ 4 4 7⁄ –41⁄ 8 2 1–41⁄2
a For expanded diameters, B, see ANSI/ASME B18.8.2-1995. b Pins in 1⁄ - and 3⁄ -inch sizes of any length and all sizes of 1⁄ -inch nominal length or shorter are not crowned or chamfered. 32 64 4 c Standard lengths increase in 1⁄ -inch steps from 1⁄ to 1 inch, and in 1⁄ -inch steps above 1 inch. Standard lengths for the 1⁄ -, 3⁄ -, 1⁄ -, 8 8 4 32 64 16 3 7 1 length for the ⁄32-, ⁄64-, and ⁄8-inch sizes do not apply to Type G grooved pins. d Non-stock items, not recommended for new designs.
and 5⁄64-inch sizes and the 1⁄4-inch
Nominal Pin Size Pin Material
1⁄ 32
3⁄ 64
Steels
1⁄ 16
5⁄ 64
3⁄ 32
7⁄ 64
1⁄ 8
5⁄ 32
3⁄ 16
7⁄ 32
1⁄ 4
5⁄ 16
3⁄ 8
7⁄ 16
1⁄ 2
15,000 35,200 24,800 12,100
19,600 46,000 32,400 15,800
0.4428 0.4375
0.5060 0.5000
Double Shear Load, Min, lb
Low Carbon Alloy (Rc 40 – 48 hardness) Corrosion Resistant Brass Maximum Diameter Minimum Diameter
100 180 140 60
220 400 300 140
0.0324 0.0312
0.0482 0.0469
410 620 890 1,220 1,600 2,300 3,310 4,510 5,880 7,660 11,000 720 1,120 1,600 2,180 2,820 4,520 6,440 8,770 11,500 17,900 26,000 540 860 1,240 1,680 2,200 3,310 4,760 6,480 8,460 12,700 18,200 250 390 560 760 990 1,540 2,220 3,020 3,950 6,170 9,050 Recommended Hole Sizes for Unplated Pins (The minimum drill size is the same as the pin size. See also text on page 1678.) 0.0640 0.0798 0.0956 0.1113 0.1271 0.1587 0.1903 0.2219 0.2534 0.3166 0.3797 0.0625 0.0781 0.0938 0.1094 0.1250 0.1563 0.1875 0.2188 0.2500 0.3125 0.3750
All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
PINS AND STUDS
Pin Diameter,a A Max Min 0.0312 0.0302 0.0469 0.0459 0.0625 0.0615 0.0781 0.0771 0.0938 0.0928 0.1094 0.1074 0.1250 0.1230 0.1563 0.1543 0.1875 0.1855 0.2188 0.2168 0.2500 0.2480 0.3125 0.3105 0.3750 0.3730 0.4375 0.4355 0.5000 0.4980
1680
Table 7. American National Standard Grooved Pins ANSI/ASME B18.8.2-1995 Nominal Size or Basic Pin Diameter 1⁄ d 0.0312 32 3⁄ d 0.0469 64 1⁄ 0.0625 16 5⁄ d 0.0781 64 3⁄ 0.0938 32 7⁄ d 0.1094 64 1⁄ 0.1250 8 5⁄ 0.1563 32 3⁄ 0.1875 16 7⁄ 0.2188 32 1⁄ 0.2500 4 5⁄ 0.3125 16 3⁄ 0.3750 8 7⁄ 0.4375 16 1⁄ 0.5000 2
Machinery's Handbook 27th Edition PINS AND STUDS
1681
Table 8. American National Standard Grooved T-Head Cotter Pins ANSI/ASME B18.8.2-1995
Nominal Sizea or Basic Shank Dia. 5⁄ 0.156 32 3⁄ 0.187 16 1⁄ 0.250 4 5⁄ 0.312 16 23⁄ 0.359 64 1⁄ 0.500 2
Shank Diameter, A Max 0.154 0.186 0.248 0.310 0.358 0.498
Length, N
Min 0.150 0.182 0.244 0.305 0.353 0.493
Max 0.08 0.09 0.12 0.16 0.18 0.25
Head Dia., O Max 0.26 0.30 0.40 0.51 0.57 0.79
Min 0.24 0.28 0.38 0.48 0.54 0.76
Head Height, P
Head Width, Q
Max 0.11 0.13 0.17 0.21 0.24 0.32
Max 0.18 0.22 0.28 0.34 0.38 0.54
Min 0.09 0.11 0.15 0.19 0.22 0.30
Min 0.15 0.18 0.24 0.30 0.35 0.49
Range of Standard Lengths,b L 3⁄ –11⁄ 4 8 3⁄ –11⁄ 4 4 1–11⁄2 1 1 ⁄8–2 11⁄4–2
2–3
Recommended Hole Size Max 0.161 0.193 0.257 0.319 0.366 0.508
Min 0.156 0.187 0.250 0.312 0.359 0.500
a When specifying nominal size in decimals, zeros preceding decimal point and in the fourth decimal
place are omitted. b Lengths increase in 1⁄ -inch steps from 3⁄ to 11⁄ inch and in 1⁄ -inch steps above 11⁄ inches. For groove 8 4 4 4 4 length, M, dimensions see ANSI/ASME B18.8.2-1995. All dimensions are in inches.
For expanded diameter, B, dimensions, see ANSI/ASME B18.8.2-1995.
Table 9. American National Standard Round Head Grooved Drive Studs ANSI/ASME B18.8.2-1995
Stud Size Number and Basic Shank Diametera 0 0.067 2 0.086 4 0.104 6 0.120 7 0.136 8 0.144 10 0.161 12 0.196 14 0.221 16 0.250
Shank Diameter, A Head Diameter, O Max 0.067 0.086 0.104 0.120 0.136 0.144 0.161 0.196 0.221 0.250
Min 0.065 0.084 0.102 0.118 0.134 0.142 0.159 0.194 0.219 0.248
Max 0.130 0.162 0.211 0.260 0.309 0.309 0.359 0.408 0.457 0.472
Min 0.120 0.146 0.193 0.240 0.287 0.287 0.334 0.382 0.429 0.443
Head Height, P Max 0.050 0.070 0.086 0.103 0.119 0.119 0.136 0.152 0.169 0.174
Min 0.040 0.059 0.075 0.091 0.107 0.107 0.124 0.140 0.156 0.161
Range of Standard Lengths,b L 1⁄ –1⁄ 8 4 1⁄ –1⁄ 8 4 3⁄ –5⁄ 16 16 1⁄ –3⁄ 4 8 5⁄ –1⁄ 16 2 3⁄ –5⁄ 8 8 3⁄ –5⁄ 8 8 1⁄ 3⁄ 24 1⁄ –3⁄ 2 4 1⁄ 2
Recommended Hole Size Max 0.0686 0.0877 0.1059 0.1220 0.1382 0.1463 0.1636 0.1990 0.2240 0.2534
Min 0.0670 0.0860 0.1040 0.1200 0.1360 0.1440 0.1610 0.1960 0.2210 0.2500
a Where
Drill Size 51 44 37 31 29 27 20 9 2 1⁄ 4
specifying nominal size in decimals, zeros preceding decimal point and in the fourth decimal place are omitted. b Lengths increase in 1⁄ -inch steps from 1⁄ to 3⁄ inch and in 1⁄ -inch steps above 3⁄ inch. 16 8 8 8 8 All dimensions are in inches. For pilot length, M, and expanded diameter, B, dimensions see ANSI/ASME B18.8.2-1995.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1682
PINS Table 10. American National Standard Slotted Type Spring Pins ANSI/ASME B18.8.2-1995
Nominal Sizea or Basic Pin Diameter
Average Pin Diameter, A Max Min
Cham fer Dia., B Max
Chamfer Length, C Max Min
Material Stock SAE Thick Recommended SAE 1070 – 30302 Berylness, Hole and lium 1095 and F Size SAE 51420 30304 Copper Basic Max Min Double Shear Load, Min, lb
Range of Practical Lengthsb
1⁄ 16
0.062
0.069
0.066
0.059
0.028
0.007
0.012
0.065
0.062
430
250
270
3⁄ –1 16
5⁄ 64
0.078
0.086
0.083
0.075
0.032
0.008
0.018
0.081
0.078
800
460
500
3⁄ –11⁄ 16 2
3⁄ 32
0.094
0.103
0.099
0.091
0.038
0.008
0.022
0.097
0.094
1,150
670
710
3⁄ –11⁄ 16 2
1⁄ 8
0.125
0.135
0.131
0.122
0.044
0.008
0.028
0.129
0.125
1,875
1,090
1,170
5⁄ –2 16
9⁄ 64
0.141
0.149
0.145
0.137
0.044
0.008
0.028
0.144
0.140
2,175
1,260
1,350
3⁄ –2 8
5⁄ 32
0.156
0.167
0.162
0.151
0.048
0.010
0.032
0.160
0.156
2,750
1,600
1,725
7⁄ –21⁄ 16 2
3⁄ 16
0.188
0.199
0.194
0.182
0.055
0.011
0.040
0.192
0.187
4,150
2,425
2,600
1⁄ –21⁄ 2 2
7⁄ 32
0.219
0.232
0.226
0.214
0.065
0.011
0.048
0.224
0.219
5,850
3,400
3,650
1⁄ –3 2
1⁄ 4
0.250
0.264
0.258
0.245
0.065
0.012
0.048
0.256
0.250
7,050
4,100
4,400
1⁄ –31⁄ 2 2
5⁄ 16
0.312
0.330
0.321
0.306
0.080
0.014
0.062
0.318
0.312
10,800
6,300
6,750
3⁄ –4 4
3⁄ 8
0.375
0.395
0.385
0.368
0.095
0.016
0.077
0.382
0.375
16,300
9,500
10,200
3⁄ , 7⁄ , 1,11⁄ , 4 8 4 11⁄2,13⁄4, 2–4
7⁄ 16
0.438
0.459
0.448
0.430
0.095
0.017
0.077
0.445
0.437
19,800
11,500
12,300
1, 11⁄4,11⁄2, 13⁄4, 2–4
1⁄ 2
0.500
0.524
0.513
0.485
0.110
0.025
0.094
0.510
0.500
27,100
15,800
17,000
11⁄4, 11⁄2, 13⁄4, 2–4
5⁄ 8
0.625
0.653
0.640
0.608
0.125
0.030
0.125
0.636
0.625
46,000
18,800
…
2–6
3⁄ 4
0.750
0.784
0.769
0.730
0.150
0.030
0.150
0.764
0.750
66,000
23,200
…
2–6
a Where specifying nominal size in decimals, zeros preceding decimal point are omitted. b Length increments are 1⁄ inch from 1⁄ to 1 inch; 1⁄ from 1 inch to 2 inches; and 1⁄ inch from 2 inches 16 8 8 4 to 6 inches.
All dimensions are in inches.
American National Standard Spring Pins.—These pins are made in two types: one type has a slot throughout its length; the other is shaped into a coil. Preferred Lengths and Sizes: The preferred lengths and sizes in which these pins are normally available are given in Tables 10 and 11. Materials: Spring pins are normally made from SAE 1070–1095 carbon steel, SAE 6150H alloy steel, SAE types 51410 through 51420, 30302 and 30304 corrosion resistant steels, and beryllium copper alloy, heat treated or cold worked to attain the hardness and performance characteristics set forth in ANSI/ASME B18.8.2-1995. Designation: Spring pins are designated by the following data in the sequence shown: Examples: Pin, Coiled Spring, 1⁄4 × 11⁄4, Standard Duty, Steel, Zinc Plated Pin, Slotted Spring, 1⁄2 × 3, Steel, Phosphate Coated
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Table 11. American National Standard Coiled Type Spring Pins ANSI/ASME B18.8.2-1995
Pin Diameter, A Heavy Duty Max Min … … … … … … … … 0.070 0.066 0.086 0.082 0.103 0.098 0.118 0.113 0.136 0.130 0.168 0.161 0.202 0.194 0.235 0.226 0.268 0.258 0.334 0.322 0.400 0.386 0.466 0.450 0.532 0.514 0.658 0.640 0.784 0.766
Chamfer Light Duty Max … … … … 0.073 0.089 0.106 0.121 0.139 0.172 0.207 0.240 0.273 0.339 0.405 0.471 0.537 … …
Min … … … … 0.067 0.083 0.099 0.114 0.131 0.163 0.196 0.228 0.260 0.324 0.388 0.452 0.516 … …
Dia., B Max 0.029 0.037 0.045 0.050 0.059 0.075 0.091 0.106 0.121 0.152 0.182 0.214 0.243 0.304 0.366 0.427 0.488 0.613 0.738
Length, C Ref 0.024 0.024 0.024 0.024 0.028 0.032 0.038 0.038 0.044 0.048 0.055 0.065 0.065 0.080 0.095 0.095 0.110 0.125 0.150
Recommended Hole Size Max Min 0.032 0.031 0.040 0.039 0.048 0.046 0.053 0.051 0.065 0.061 0.081 0.077 0.097 0.093 0.112 0.108 0.129 0.124 0.160 0.155 0.192 0.185 0.224 0.217 0.256 0.247 0.319 0.308 0.383 0.370 0.446 0.431 0.510 0.493 0.635 0.618 0.760 0.743
1070–1095 and 51420
30302 and 30304
Standard Duty 90a 65 100 135a 145 190a 190 250a 330 265 550 425 775 600 1,050 825 1,400 1,100 2,200 1,700 3,150 2,400 4,200 3,300 5,500 4,300 8,700 6,700 12,600 9,600 17,000 13,300 22,500 17,500 … 35,000b … 50,000b
SAE Material Number 1070–1095 30302 and and 51420 30304 Double Shear Load, Min, lb Heavy Duty … … … … … … … … 475 360 800 575 1,150 825 1,500 1,150 2,000 1,700 3,100 2,400 4,500 3,500 5,900 4,600 7,800 6,200 12,000 9,300 18,000 14,000 23,500 18,000 32,000 25,000 … 48,000b … 70,000b
1070–1095 and 51420
30302 and 30304
Light Duty … … … … … … … … 205 160 325 250 475 360 650 500 825 650 1,300 1,000 1,900 1,450 2,600 2,000 3,300 2,600 5,200 4,000 … … … … … … … … … …
All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
1683
a Sizes 1⁄ inch through 0.052 inch are not available in SAE 1070–1095 carbon steel. 32 b Sizes 5⁄ inch and larger are produced from SAE 6150H alloy steel, not SAE 1070–1095 carbon steel. Practical lengths, L, for sizes 1⁄ through 0.052 inch are 1⁄ through 8 32 8 5⁄ inch and for the 7⁄ -inch size, 1⁄ through 13⁄ inches. For lengths of other sizes see Table 10. 8 64 4 4
PINS
Nominal Size or Basic Pin Diameter 1⁄ 0.031 32 0.039 3⁄ 0.047 64 0.052 1⁄ 0.062 16 5⁄ 0.078 64 3⁄ 0.094 32 7⁄ 0.109 64 1⁄ 0.125 8 5⁄ 0.156 32 3⁄ 0.188 16 7⁄ 0.219 32 1⁄ 0.250 4 5⁄ 0.312 16 3⁄ 0.375 8 7⁄ 0.438 16 1⁄ 0.500 2 5⁄ 0.625 8 3⁄ 0.750 4
Standard Duty Max Min 0.035 0.033 0.044 0.041 0.052 0.049 0.057 0.054 0.072 0.067 0.088 0.083 0.105 0.099 0.120 0.114 0.138 0.131 0.171 0.163 0.205 0.196 0.238 0.228 0.271 0.260 0.337 0.324 0.403 0.388 0.469 0.452 0.535 0.516 0.661 0.642 0.787 0.768
Machinery's Handbook 27th Edition 1684
RETAINING RINGS
RETAINING RINGS Retaining Rings.—The purpose of a retaining ring is to act as an artificial shoulder that will retain an object in a housing (internal ring), as shown in Fig. 1, or on a shaft (external ring). Two types of retaining ring are common, the stamped ring and the spiral-wound ring. The stamped type of retaining ring, or snap ring, is stamped from tempered sheet metal and has a nonuniform cross-section. The typical spiral-wound retaining ring has a uniform cross-section and is made up of two or more turns of coiled, spring-tempered steel, although one-turn spiral-wound rings are common. Spiral-wound retaining rings provide a continuous gapless shoulder to a housing or shaft. Most stamped rings can only be installed at or near the end of a shaft or housing. The spiral-wound design generally requires installation from the end of a shaft or housing. Both types, stamped and spiral, are usually installed into grooves on the shaft or housing.
Housing
Retained Part
Max. Groove Chamfer or Radius + Max. Side Clearance + Max. Retained Part Chamfer or Radius = Maximum Total Radius or Chamfer
Fig. 1. Typical Retaining Ring Installation Showing Maximum Total Radius or Chamfer (Courtesy Spirolox Retaining Rings)
In the section that follows, Tables 1 through 6 give dimensions and data on general-purpose tapered and reduced cross-section metric retaining rings (stamped type) covered by ANSI B27.7-1977, R1993. Tables 1 and 4 cover Type 3AM1 tapered external retaining rings, Tables 2 and 5 cover Type 3BM1 tapered internal rings, and Tables 3 and 6 cover Type 3CM1 reduced cross-section external rings. Tables 7 through 10 cover inch sizes of internal and external spiral retaining rings corresponding to MIL-R-27426 Types A (external) and B (internal), Class 1 (medium duty) and Class 2 (heavy duty). Tables 11 through 17 cover stamped retaining rings in inch sizes. Table 1. American National Standard Metric Tapered Retaining Rings — Basic External Series — 3AM1 ANSI B27.7-1977, R1993
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
1685
Shaft Dia.
Table 1. (Continued) American National Standard Metric Tapered Retaining Rings — Basic External Series — 3AM1 ANSI B27.7-1977, R1993 Ring Free Dia.
Groove Thick ness
Dia.
Width Depth d ref
Ring Edge Margin Z min
Shaft Diam S
Free Dia. D
Groove Thick ness
Dia.
Width Depth W
d ref
Edge Margin
S
D
t
G
W
t
G
4
3.60
0.25
3.80
0.32
0.1
0.3
36
33.25
1.3
33.85
1.4
1.06
3.2
5
4.55
0.4
4.75
0.5
0.13
0.4
38
35.20
1.3
35.8
1.4
1.10
Z min 3.3
6
5.45
0.4
5.70
0.5
0.15
0.5
40
36.75
1.6
37.7
1.75
1.15
3.4
7
6.35
0.6
6.60
0.7
0.20
0.6
42
38.80
1.6
39.6
1.75
1.20
3.6
8
7.15
0.6
7.50
0.7
0.25
0.8
43
39.65
1.6
40.5
1.75
1.25
3.8
9
8.15
0.6
8.45
0.7
0.28
0.8
45
41.60
1.6
42.4
1.75
1.30
3.9
10
9.00
0.6
9.40
0.7
0.30
0.9
46
42.55
1.6
43.3
1.75
1.35
4.0
11
10.00
0.6
10.35
0.7
0.33
1.0
48
44.40
1.6
45.2
1.75
1.40
4.2
12
10.85
0.6
11.35
0.7
0.33
1.0
50
46.20
1.6
47.2
1.75
1.40
4.2
13
11.90
0.9
12.30
1.0
0.35
1.0
52
48.40
2.0
49.1
2.15
1.45
4.3
14
12.90
0.9
13.25
1.0
0.38
1.2
54
49.9
2.0
51.0
2.15
1.50
4.5
15
13.80
0.9
14.15
1.0
0.43
1.3
55
50.6
2.0
51.8
2.15
1.60
4.8
16
14.70
0.9
15.10
1.0
0.45
1.4
57
52.9
2.0
53.8
2.15
1.60
4.8
17
15.75
0.9
16.10
1.0
0.45
1.4
58
53.6
2.0
54.7
2.15
1.65
4.9
18
16.65
1.1
17.00
1.2
0.50
1.5
60
55.8
2.0
56.7
2.15
1.65
4.9
19
17.60
1.1
17.95
1.2
0.53
1.6
62
57.3
2.0
58.6
2.15
1.70
5.1
20
18.35
1.1
18.85
1.2
0.58
1.7
65
60.4
2.0
61.6
2.15
1.70
5.1
21
19.40
1.1
19.80
1.2
0.60
1.8
68
63.1
2.0
64.5
2.15
1.75
5.3
22
20.30
1.1
20.70
1.2
0.65
1.9
70
64.6
2.4
66.4
2.55
1.80
5.4
23
21.25
1.1
21.65
1.2
0.67
2.0
72
66.6
2.4
68.3
2.55
1.85
5.5
24
22.20
1.1
22.60
1.2
0.70
2.1
75
69.0
2.4
71.2
2.55
1.90
5.7
25
23.10
1.1
23.50
1.2
0.75
2.3
78
72.0
2.4
74.0
2.55
2.00
6.0
26
24.05
1.1
24.50
1.2
0.75
2.3
80
74.2
2.4
75.9
2.55
2.05
6.1
27
24.95
1.3
25.45
1.4
0.78
2.3
82
76.4
2.4
77.8
2.55
2.10
6.3
28
25.80
1.3
26.40
1.4
0.80
2.4
85
78.6
2.4
80.6
2.55
2.20
6.6
30
27.90
1.3
28.35
1.4
0.83
2.5
88
81.4
2.8
83.5
2.95
2.25
6.7
32
29.60
1.3
30.20
1.4
0.90
2.7
90
83.2
2.8
85.4
2.95
2.30
6.9
34
31.40
1.3
32.00
1.4
1.00
3.0
95
88.1
2.8
90.2
2.95
2.40
7.2
35
32.30
1.3
32.90
1.4
1.05
3.1
100
92.5
2.8
95.0
2.95
2.50
7.5
All dimensions are in millimeters. Sizes −4, −5, and −6 are available in beryllium copper only. These rings are designated by series symbol and shaft diameter, thus: for a 4 mm diameter shaft, 3AM1-4; for a 20 mm diameter shaft, 3AM1-20; etc. Ring Free Diameter Tolerances: For ring sizes −4 through −6, +0.05, −0.10 mm; for sizes −7 through −12, +0.05, −0.15 mm; for sizes −13 through − 26, +0.15, −0.25 mm; for sizes −27 through −38, +0.25, −0.40 mm; for sizes −40 through −50, +0.35, −0.50 mm; for sizes −52 through −62, +0.35, −0.65 mm; and for sizes −65 through −100, +0.50, −0.75 mm. Groove Diameter Tolerances: For ring sizes −4 through −6, −0.08 mm; for sizes −7 through −10, − 0.10 mm; for sizes −11 through −15, −0.12 mm; for sizes −16 through −26, −0.15 mm; for sizes −27 through − 36, −0.20 mm; for sizes −38 through −55, −0.30 mm; and for sizes −57 through −100, − 0.40 mm. Groove Diameter F.I.M. (full indicator movement) or maximum allowable deviation of concentricity between groove and shaft: For ring sizes −4 through −6, 0.03 mm; for ring sizes −7 through − 12, 0.05 mm; for sizes −13 through −28, 0.10 mm; for sizes −30 through −55, 0.15 mm; and for sizes −57 through − 00, 0.20 mm. Groove Width Tolerances: For ring size −4, +0.05 mm; for sizes −5 and −6, +0.10 mm, for sizes − 7 through −38, +0.15 mm; and for sizes −40 through − 100, +0.20 mm. Groove Maximum Bottom Radii,R: For ring sizes −4 through −6, none; for sizes −7 through −18, 0.1 mm; for sizes −19 through −30, 0.2 mm; for sizes −32 through −50, 0.3 mm; and for sizes −52 through −100, 0.4 mm. For manufacturing details not shown, including materials, see ANSI B27.71977, R1993.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1686
RETAINING RINGS
Table 2. American National Standard Metric Tapered Retaining Rings — Basic Internal Series — 3BM1 ANSI B27.7-1977, R1993
Dia.
Width
Depth
Edge Margin
Shaft Dia.
Free Dia.
Thickness
Dia.
Width
Depth
Edge Margin
Groove
Thickness
Ring
Free Dia.
Groove
Shaft Dia.
Ring
S 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 30 32 34 35 36 37 38 40 42 45 46 47 48 50 52 55 57 58 60 62 63
D 8.80 10.00 11.10 12.20 13.30 14.25 15.45 16.60 17.70 18.90 20.05 21.10 22.25 23.30 24.40 25.45 26.55 27.75 28.85 29.95 31.10 33.40 35.35 37.75 38.75 40.00 41.05 42.15 44.25 46.60 49.95 51.05 52.15 53.30 55.35 57.90 61.10 63.25 64.4 66.8 68.6 69.9
t 0.4 0.6 0.6 0.6 0.6 0.9 0.9 0.9 0.9 0.9 0.9 0.9 0.9 0.9 1.1 1.1 1.1 1.1 1.1 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.6 1.6 1.6 1.6 1.6 1.6 1.6 2.0 2.0 2.0 2.0 2.0 2.0 2.0
G 8.40 9.45 10.50 11.60 12.65 13.70 14.80 15.85 16.90 18.00 19.05 20.10 21.15 22.20 23.30 24.35 25.4 26.6 27.7 28.8 29.8 31.9 33.9 36.1 37.2 38.3 39.3 40.4 42.4 44.5 47.6 48.7 49.8 50.9 53.1 55.3 58.4 60.5 61.6 63.8 65.8 66.9
W 0.5 0.7 0.7 0.7 0.7 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.2 1.2 1.2 1.2 1.2 1.4 1.4 1.4 1.4 1.4 1.4 1.4 1.4 1.4 1.75 1.75 1.75 1.75 1.75 1.75 1.75 2.15 2.15 2.15 2.15 2.15 2.15 2.15
d ref 0.2 0.23 0.25 0.3 0.33 0.35 0.40 0.43 0.45 0.50 0.53 0.55 0.57 0.60 0.65 0.67 0.70 0.80 0.85 0.90 0.90 0.95 0.95 1.05 1.10 1.15 1.15 1.20 1.20 1.25 1.30 1.35 1.40 1.45 1.55 1.65 1.70 1.75 1.80 1.90 1.90 1.95
Z min 0.6 0.7 0.8 0.9 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.7 1.8 1.9 2.0 2.1 2.4 2.6 2.7 2.7 2.9 2.9 3.2 3.3 3.5 3.5 3.6 3.6 3.7 3.9 4.0 4.2 4.3 4.6 5.0 5.1 5.3 5.4 5.7 5.7 5.9
S 65 68 70 72 75 78 80 82 85 88 90 92 95 98 100 102 105 108 110 115 120 125 130 135 140 145 150 155 160 165 170 175 180 185 190 200 210 220 230 240 250 …
D 72.2 75.7 77.5 79.6 83.3 86.8 89.1 91.1 94.4 97.9 100.0 102.2 105.6 109.0 110.7 112.4 115.8 119.2 120.8 126.0 132.4 137.1 142.5 148.5 154.1 159.5 164.5 168.8 175.1 180.3 185.6 191.3 196.6 202.7 207.7 217.8 230.3 240.5 251.4 262.3 273.3 …
t 2.4 2.4 2.4 2.4 2.4 2.8 2.8 2.8 2.8 2.8 2.80 2.8 2.8 2.8 2.8 2.8 2.8 2.8 2.8 2.8 2.8 2.8 2.8 3.2 3.2 3.2 3.2 3.2 4.0 4.0 4.0 4.0 4.0 4.8 4.8 4.8 4.8 4.8 4.8 4.8 4.8 …
G 69.0 72.2 74.4 76.5 79.7 82.8 85.0 87.2 90.4 93.6 95.7 97.8 101.0 104.2 106.3 108.4 111.5 114.6 116.7 121.9 127.0 132.1 137.2 142.3 147.4 152.5 157.6 162.7 167.8 172.9 178.0 183.2 188.4 193.6 198.8 209.0 219.4 230.0 240.6 251.0 261.4 …
W 2.55 2.55 2.55 2.55 2.55 2.95 2.95 2.95 2.95 2.95 2.95 2.95 2.95 2.95 2.95 2.95 2.95 2.95 2.95 2.95 2.95 2.95 2.95 3.40 3.40 3.40 3.40 3.40 4.25 4.25 4.25 4.25 4.25 5.10 5.10 5.10 5.10 5.10 5.10 5.10 5.10 …
d ref 2.00 2.10 2.20 2.25 2.35 2.40 2.50 2.60 2.70 2.80 2.85 2.90 3.00 3.10 3.15 3.20 3.25 3.30 3.35 3.45 3.50 3.55 3.60 3.65 3.70 3.75 3.80 3.85 3.90 3.95 4.00 4.10 4.20 4.30 4.40 4.50 4.70 5.00 5.30 5.50 5.70 …
Z min 6.0 6.3 6.6 6.7 7.1 7.2 7.5 7.8 8.1 8.4 8.6 8.7 9.0 9.3 9.5 9.6 9.8 9.9 10.1 10.4 10.5 10.7 10.8 11.0 11.1 11.3 11.4 11.6 11.7 11.9 12.0 12.3 12.6 12.9 13.2 13.5 14.1 15.0 15.9 16.5 17.1 …
All dimensions are in millimeters. These rings are designated by series symbol and shaft diameter, thus: for a 9 mm diameter shaft, 3BM1-9; for a 22 mm diameter shaft, 3BM1-22; etc. Ring Free Diameter Tolerances: For ring sizes −8 through −20, +0.25, −0.13 mm; for sizes −21 through −26, +0.40, −0.25 mm; for sizes −27 through −38, +0.65, −0.50 mm; for sizes −40 through − 50, +0.90, −0.65 mm; for sizes −52 through −75, +1.00, −0.75 mm; for sizes −78 through −92, +1.40,
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
1687
−1.40 mm; for sizes −95 through −155, +1.65, −1.65 mm; for sizes −160 through −180, +2.05, −2.05 mm; and for sizes −185 through −250, +2.30, −2.30 mm. Groove Diameter Tolerances: For ring sizes −8 and −9, +0.06 mm; for sizes −10 through −18, +0.10 mm; for sizes −19 through − 28, +0.15 mm; for sizes −30 through −50, +0.20 mm; for sizes − 52 through −98, +0.30; for sizes −100 through −160, +0.40 mm; and for sizes −165 through −250, +0.50 mm. Groove Diameter F.I.M. (full indicator movement) or maximum allowable deviation of concentricity between groove and shaft: For ring sizes −8 through −10, 0.03 mm; for sizes −11 through −15, 0.05 mm; for sizes −16 through −25, 0.10 mm; for sizes −26 through −45, 0.15 mm; for sizes −46 through −80, 0.20 mm; for sizes −82 through −150, 0.25 mm; and for sizes −155 through −250, 0.30 mm. Groove Width Tolerances: For ring size −8, +0.10 mm; for sizes −9 through −38, +0.15 mm; for sizes −40 through −130, +0.20 mm; and for sizes −135 through −250, +0.25 mm. Groove Maximum Bottom Radii: For ring sizes −8 through −17, 0.1 mm; for sizes −18 through − 30, 0.2 mm; for sizes −32 through −55, 0.3 mm; and for sizes −56 through −250, 0.4 mm. For manufacturing details not shown, including materials, see ANSI B27.7-1977, R1993.
Table 3. American National Standard Metric Reduced Cross Section Retaining Rings — E Ring External Series —3CM1 ANSI B27.7-1977, R1993
S
D
t
Y nom
G
W
d ref
Z min
S
D
t
Y nom
1 2 3 4 5 6 7 8 9 10
0.64 1.30 2.10 2.90 3.70 4.70 5.25 6.15 6.80 7.60
0.25 0.25 0.4 0.6 0.6 0.6 0.6 0.6 0.9 0.9
2.0 4.0 5.6 7.2 8.5 11.1 13.4 14.6 15.8 16.8
0.72 1.45 2.30 3.10 3.90 4.85 5.55 6.40 7.20 8.00
0.32 0.32 0.5 0.7 0.7 0.7 0.7 0.7 1.0 1.0
0.14 0.28 0.35 0.45 0.55 0.58 0.73 0.80 0.90 1.00
0.3 0.6 0.7 0.9 1.1 1.2 1.5 1.6 1.8 2.0
11 12 13 15 16 18 20 22 25 …
8.55 9.20 9.95 11.40 12.15 13.90 15.60 17.00 19.50 …
0.9 1.1 1.1 1.1 1.1 1.3 1.3 1.3 1.3 …
17.4 18.6 20.3 22.8 23.8 27.2 30.0 33.0 37.1 …
8.90 9.60 10.30 11.80 12.50 14.30 16.00 17.40 20.00 …
Edge Margin
Depth
Dia. G
Width
Groove Outer Dia.
Thickness
Free Dia.
Shaft Dia.
Edge Margin
Ring Depth
Dia.
Width
Groove Outer Dia.
Thickness
Free Dia.
Shaft Dia.
Ring
W
d ref
Z min
1.0 1.2 1.2 1.2 1.2 1.4 1.4 1.4 1.4 …
1.05 1.20 1.35 1.60 1.75 1.85 2.00 2.30 2.50 …
2.1 2.4 2.7 3.2 3.5 3.7 4.0 4.6 5.0 …
All dimensions are in millimeters. Size −1 is available in beryllium copper only. These rings are designated by series symbol and shaft diameter, thus: for a 2 mm diameter shaft, 3CM1-2; for a 13 mm shaft, 3CMI -13; etc. Ring Free Diameter Tolerances: For ring sizes − 1 through −7, +0.03, −0.08 mm; for sizes −8 through −13, +0.05, −0.10 mm; and for sizes −15 through −25, +0.10, −0.15 mm. Groove Diameter Tolerances: For ring sizes −1 and −2, −0.05 mm; for sizes −3 through −6, −0.08; for sizes −7 through −11, −0.10 mm; for sizes −12 through −18, − 0.15 mm; and for sizes −20 through −25, − 0.20 mm. Groove Diameter F.I.M. (Full Indicator Movement) or maximum allowable deviation of concentricity between groove and shaft: For ring sizes −1 through −3, 0.04 mm; for −4 through −6, 0.05 mm; for −7 through −10, 0.08 mm; for −11 through −25, 0.10 mm. Groove Width Tolerances: For ring sizes − 1 and −2, +0.05 mm; for size −3, +0.10 mm; and for sizes −4 through − 25, +0.15 mm. Groove Maximum Bottom Radii: For ring sizes −1 and −2, 0.05 mm; for −3 through −7, 0.15 mm; for −8 through −13, 0.25 mm; and for −15 through −25, 0.4 mm. For manufacturing details not shown, including materials, see ANSI B27.7-1977, R1993.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1688
RETAINING RINGS
Ring Seated in Groove
Ring Expanded over Shaft
Table 4. American National Standard Metric Basic External Series 3AM1 Retaining Rings, Checking and Performance Data ANSI B27.7-1977, R1993 Ring Series and Size No.
Clearance Dia. Ring Over Shaft
Ring in Groove
Gaging Diametera
Allowable Thrust Loads Sharp Corner Abutment
Maximum Allowable Corner Radii and Chamfers
Allowable Assembly Speedb
3AM1
C1
C2
K max
Prc
Pgd
R max
Ch max
…
No.
mm
mm
mm
kN
kN
mm
mm
rpm
−4a
7.0
6.8
4.90
0.6
0.2
0.35
0.25
70 000
−5a
8.2
7.9
5.85
1.1
0.3
0.35
0.25
70 000
−6a
9.1
8.8
6.95
1.4
0.4
0.35
0.25
70 000
−7
12.3
11.8
8.05
2.6
0.7
0.45
0.3
60 000
−8
13.6
13.0
9.15
3.1
1.0
0.5
0.35
55 000
−9
14.5
13.8
10.35
3.5
1.2
0.6
0.35
48 000
−10
15.5
14.7
11.50
3.9
1.5
0.7
0.4
42 000
−11
16.4
15.6
12.60
4.3
1.8
0.75
0.45
38 000
−12
17.4
16.6
13.80
4.7
2.0
0.8
0.45
34 000
−13
19.7
18.8
15.05
7.5
2.2
0.8
0.5
31 000
−14
20.7
19.7
15.60
8.1
2.6
0.9
0.5
28 000
−15
21.7
20.6
17.20
8.7
3.2
1.0
0.6
27 000
−16
22.7
21.6
18.35
9.3
3.5
1.1
0.6
25 000
−17
23.7
22.6
19.35
9.9
4.0
1.1
0.6
24 000
−18
26.2
25.0
20.60
16.0
4.4
1.2
0.7
23 000
−19
27.2
25.9
21.70
16.9
4.9
1.2
0.7
21 500
−20
28.2
26.8
22.65
17.8
5.7
1.2
0.7
20 000
−21
29.2
27.7
23.80
18.6
6.2
1.3
0.7
19 000
−22
30.3
28.7
24.90
19.6
7.0
1.3
0.8
18 500
−23
31.3
29.6
26.00
20.5
7.6
1.3
0.8
18 000
−24
34.1
32.4
27.15
21.4
8.2
1.4
0.8
17 500
−25
35.1
33.3
28.10
22.3
9.2
1.4
0.8
17 000
−26
36.0
34.2
29.25
23.2
9.6
1.5
0.9
16 500
−27
37.8
35.9
30.35
28.4
10.3
1.5
0.9
16 300
−28
38.8
36.9
31.45
28.4
11.0
1.6
1.0
15 800
−30
40.8
38.8
33.6
31.6
12.3
1.6
1.0
15 000
−32
42.8
40.7
35.9
33.6
14.1
1.7
1.0
14 800
−34
44.9
42.5
37.9
36
16.7
1.7
1.1
14 000
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
1689
Table 4. (Continued) American National Standard Metric Basic External Series 3AM1 Retaining Rings, Checking and Performance Data ANSI B27.7-1977, R1993 Ring Series and Size No.
Clearance Dia. Ring Over Shaft
Ring in Groove
Gaging Diametera
Allowable Thrust Loads Sharp Corner Abutment
Maximum Allowable Corner Radii and Chamfers
Allowable Assembly Speedb
3AM1
C1
C2
K max
Prc
Pgd
R max
Ch max
…
No.
mm
mm
mm
kN
kN
mm
mm
rpm
−35
45.9
43.4
39.0
37
18.1
1.8
1.1
13 500
−36
48.6
46.1
40.2
38
18.9
1.9
1.2
13 300
−38
50.6
48.0
42.5
40
20.5
2.0
1.2
12 700
−40
54.0
51.3
44.5
52
22.6
2.1
1.2
12 000
−42
56.0
53.2
46.9
54
24.8
2.2
1.3
11 000
−43
57.0
54.0
47.9
55
26.4
2.3
1.4
10 800
−45
59.0
55.9
50.0
58
28.8
2.3
1.4
10 000
−46
60.0
56.8
50.9
59
30.4
2.4
1.4
9 500
−48
62.4
59.1
53.0
62
33
2.4
1.4
8 800
−50
64.4
61.1
55.2
64
35
2.4
1.4
8 000
−52
67.6
64.1
57.4
84
37
2.5
1.5
7 700
−54
69.6
66.1
59.5
87
40
2.5
1.5
7 500
−55
70.6
66.9
60.4
89
44
2.5
1.5
7 400
−57
72.6
68.9
62.7
91
45
2.6
1.5
7 200
−58
73.6
69.8
63.6
93
46
2.6
1.6
7 100
−60
75.6
71.8
65.8
97
49
2.6
1.6
7 000
−62
77.6
73.6
67.9
100
52
2.7
1.6
6 900
−65
80.6
76.6
71.2
105
54
2.8
1.7
6 700
−68
83.6
79.5
74.5
110
58
2.9
1.7
6 500
−70
88.1
83.9
76.4
136
62
2.9
1.7
6 400
−72
90.1
85.8
78.5
140
65
2.9
1.7
6 200
−75
93.1
88.7
81.7
147
69
3.0
1.8
5 900
−78
95.4
92.1
84.6
151
76
3.0
1.8
5 600
−80
97.9
93.1
87.0
155
80
3.1
1.9
5 400
−82
100.0
95.1
89.0
159
84
3.2
1.9
5 200
−85
103.0
97.9
92.1
165
91
3.2
1.9
5 000
−88
107.0
100.8
95.1
199
97
3.2
1.9
4 800
−90
109.0
103.6
97.1
204
101
3.2
1.9
4 500
−95
114.0
108.6
102.7
215
112
3.4
2.1
4 350
−100
119.5
113.7
108.0
227
123
3.5
2.1
4 150
a For checking when ring is seated in groove. b These values have been calculated for steel rings. c These values apply to rings made from SAE 1060–1090 steels and PH 15-7 Mo stainless steel used on shafts hardened to Rc 50 minimum, with the exception of sizes −4, −5, and −6 which are supplied in beryllium copper only. Values for other sizes made from beryllium copper can be calculated by multiplying the listed values by 0.75. The values listed include a safety factor of 4. d These values are for all standard rings used on low carbon steel shafts. They include a safety factor of 2. Maximum allowable assembly loads with R max or Ch max are: For rings sizes −4, 0.2 kN; for sizes −5 and −6, 0.5 kN; for sizes −7 through −12, 2.1 kN; for sizes −13 through −17, 4.0 kN; for sizes −18 through −26, 6.0 kN; for sizes −27 through −38, 8.6 kN; for sizes −40 through − 50, 13.2 kN; for sizes −52 through −68, 22.0 kN; for sizes −70 through −85, 32 kN; and for sizes −88 through −100, 47 kN.
Source: Appendix to American National Standard ANSI B27.7-1977, R1993.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1690
RETAINING RINGS
Table 5. American National Standard Metric Basic Internal Series 3BMI Retaining Rings — Checking and Performance Data ANSI B27.7-1977, R1993
Max Allowable Radius of Retained Part
Ring Compressed in Bore Ring Series and Size No. 3BMI No. −8 −9 −10 −11 −12 −13 −14 −15 −16 −17 −18 −19 −20 −21 −22 −23 −24 −25 −26 −27 −28 −30 −32 −34 −35 −36 −37 −38 −40 −42 −45 −46 −47 −48 −50 −52 −55 −57
Clearance Dia. Ring Ring in in Bore Groove C1
C2
mm 4.4 4.6 5.5 5.7 6.7 6.8 6.9 7.9 8.8 9.8 10.3 11.4 11.6 12.6 13.5 14.5 15.5 16.5 17.5 17.4 18.2 20.0 22.0 24.0 25.0 26.0 27.0 28.0 29.2 29.7 32.3 33.3 34.3 35.0 36.9 38.6 40.8 42.2
mm 4.8 5.0 6.0 6.3 7.3 7.5 7.7 8.7 9.7 10.8 11.3 12.5 12.7 13.8 14.8 15.9 16.9 18.1 19.2 19.2 20.0 21.9 23.9 26.1 27.2 28.3 29.3 30.4 31.6 32.2 34.9 36.0 37.1 37.9 40.0 41.9 44.2 45.7
Max Allowable Chamfer of Retained Part
Ring Seated in Groove Gaging Diametera A min mm 1.40 1.50 1.85 1.95 2.25 2.35 2.65 2.80 2.80 3.35 3.40 3.40 3.8 4.2 4.3 4.9 5.2 6.0 5.7 5.9 6.0 6.0 7.3 7.6 8.0 8.3 8.4 8.6 9.7 9.0 9.6 9.7 10.0 10.5 12.1 11.7 11.9 12.5
Allowable Thrust Loads Sharp Corner Abutment Prb
Pgc
kN 2.4 4.4 4.9 5.4 5.8 8.9 9.7 10.4 11.0 11.7 12.3 13.1 13.7 14.5 22.5 23.5 24.8 25.7 26.8 33 34 37 39 42 43 44 45 46 62 65 69 71 72 74 77 99 105 109
kN 1.0 1.2 1.5 2.0 2.4 2.6 3.2 3.7 4.2 4.9 5.5 6.0 6.6 7.3 8.3 8.9 9.7 11.6 12.7 14.0 14.6 16.5 17.6 20.6 22.3 23.9 24.6 26.4 27.7 30.2 33.8 36 38 40 45 50 54 58
Maximum Allowable Corner Radii and Chamfers R max mm 0.4 0.5 0.5 0.6 0.6 0.7 0.7 0.7 0.7 0.75 0.75 0.8 0.9 0.9 0.9 1.0 1.0 1.0 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.2 1.7 1.7 1.7 1.7 1.7 1.7 1.7 2.0 2.0 2.0
Copyright 2004, Industrial Press, Inc., New York, NY
Ch max mm 0.3 0.35 0.35 0.4 0.4 0.5 0.5 0.5 0.5 0.6 0.6 0.65 0.7 0.7 0.7 0.8 0.8 0.8 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.6 1.6 1.6
Machinery's Handbook 27th Edition RETAINING RINGS
1691
Table 5. (Continued) American National Standard Metric Basic Internal Series 3BMI −58 −60 −62 −63 −65 −68 −70 −72 −75 −78 −80 −82 −85 −88 −90 −92 −95 −98 −100 −102 −105 −108 −110 −115 −120 −125 −130 −135 −140 −145 −150 −155 −160 −165 −170 −175 −180 −185 −190 −200 −210 −220 −230 −240 −250
43.2 45.5 47.0 47.8 49.4 52.0 53.8 55.9 58.2 61.2 63.0 63.5 66.8 69.6 71.6 73.6 76.7 78.3 80.3 82.2 85.1 88.1 88.4 93.2 98.2 103.1 108.0 110.4 115.3 120.4 125.3 130.4 133.8 138.7 143.6 146.0 151.4 154.7 159.5 169.2 177.5 184.1 194.0 200.4 210.0
46.8 49.3 50.8 51.7 53.4 56.2 58.2 60.4 62.9 66.0 68.0 68.7 72.2 75.2 77.3 79.4 82.7 84.5 86.6 88.6 91.6 94.7 95.1 100.1 105.2 110.2 115.2 117.7 122.7 127.9 132.9 138.1 141.6 146.6 151.6 154.2 159.8 163.3 168.3 178.2 186.9 194.1 204.6 211.4 221.4
13.0 12.7 14.0 14.2 14.2 14.4 16.1 17.4 16.8 17.6 17.2 18.8 19.1 20.4 21.4 22.2 22.6 22.6 24.1 25.5 26.0 26.4 27.5 29.4 27.2 30.3 31.0 30.4 30.4 31.6 33.5 37.0 35.0 33.1 38.2 37.7 39.0 37.3 35.0 43.9 40.6 38.3 49.0 45.4 53.0
111 115 119 120 149 156 161 166 172 209 215 220 228 236 241 247 255 263 269 273 281 290 295 309 321 335 349 415 429 444 460 475 613 632 651 670 690 851 873 919 965 1000 1060 1090 1150
60 66 68 71 75 82 88 93 101 108 115 122 131 141 147 153 164 174 181 187 196 205 212 227 241 255 269 283 298 313 327 343 359 374 390 403 434 457 480 517 566 608 686 725 808
2.0 2.0 2.0 2.0 2.0 2.3 2.3 2.3 2.3 2.5 2.5 2.6 2.6 2.8 2.8 2.9 3.0 3.0 3.1 3.2 3.3 3.5 3.6 3.7 3.9 4.0 4.0 4.3 4.3 4.3 4.3 4.3 4.5 4.6 4.6 4.8 5.0 5.1 5.3 5.4 5.8 6.1 6.3 6.6 6.7
1.6 1.6 1.6 1.6 1.6 1.8 1.8 1.8 1.8 2.0 2.0 2.1 2.1 2.2 2.2 2.4 2.5 2.5 2.5 2.6 2.6 2.7 2.8 2.9 3.1 3.2 3.2 3.4 3.4 3.4 3.4 3.4 3.6 3.7 3.7 3.8 4.0 4.1 4.3 4.3 4.6 4.9 5.1 5.3 5.4
a For checking when ring is seated in groove. b These values apply to rings made from SAE 1060-1090 steels and PH 15-7 Mo stainless steel used in bores hardened to Rc 50 minimum. Values for rings made from beryllium copper can be calculated by multiplying the listed values by 0.75. The values listed include a safety factor of 4. c These values are for standard rings used in low carbon steel bores. They include a safety factor of 2. Maximum allowable assembly loads for R max or Ch max are: For ring size −8, 0.8 kN; for sizes − 9 through −12, 2.0 kN; for sizes −13 through −21, 4.0 kN; for sizes −22 through −26, 7.4 kN; for sizes −27 through −38, 10.8 kN; for sizes −40 through −50, 17.4 kN; for sizes −52 through −63, 27.4 kN; for size −65, 42.0 kN; for sizes −68 through −72, 39 kN; for sizes −75 through −130, 54 kN; for sizes −135 through −155, 67 kN; for sizes −160 through −180, 102 kN; and for sizes −185 through −250, 151 kN. Source: Appendix to American National Standard ANSI B27.7-1977, R1993.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1692
RETAINING RINGS
Table 6. American National Standard Metric E-Type External Series 3CM1 Retaining Rings — Checking and Performance Data ANSI B27.7-1977, R1993
Max. Allowable Radius of Retained Part
Ring Seated in Groove Ring Series and Size No. 3CM1 No. −1 −2 −3 −4 −5 −6 −7 −8 −9 −10 −11 −12 −13 −15 −16 −18 −20 −22 −25
Clearance Diameter Ring in Groove C2 mm 2.2 4.3 6.0 7.6 8.9 11.5 14.0 15.1 16.5 17.5 18.0 19.3 21.0 23.5 24.5 27.9 30.7 33.7 37.9
Max. Allowable Chamfer of Retained Part Maximum Allowable Corner Radii and Chamfers
Allowable Thrust Loads Sharp Corner Abutment Pr b Pgc kN 0.06 0.13 0.3 0.7 0.9 1.1 1.2 1.4 3.0 3.4 3.7 4.9 5.4 6.2 6.6 8.7 9.8 10.8 12.2
R max mm 0.4 0.8 1.1 1.6 1.6 1.6 1.6 1.7 1.7 1.7 1.7 1.9 2.0 2.0 2.0 2.1 2.2 2.2 2.4
kN 0.02 0.09 0.17 0.3 0.4 0.6 0.8 1.0 1.3 1.6 1.9 2.3 2.9 4.0 4.5 5.4 6.5 8.1 10.1
Allowable Assembly Speeda … rpm 40 000 40 000 34 000 31 000 27 000 25 000 23 000 21 500 19 500 18 000 16 500 15 000 13 000 11 500 10 000 9 000 8 000 7 000 5 000
Ch max mm 0.25 0.5 0.7 1.2 1.2 1.2 1.2 1.3 1.3 1.3 1.3 1.4 1.5 1.5 1.5 1.6 1.7 1.7 1.9
a These values have been calculated for steel rings. b These values apply to rings made from SAE 1060-1090 steels and PH 15-7 Mo stainless steel used on shafts hardened to Rc 50 minimum, with the exception of size −1 which is supplied in beryllium copper only. Values for other sizes made from beryllium copper can be calculated by multiplying the listed values by 0.75. The values listed include a safety factor of 4. c These values apply to all standard rings used on low carbon steel shafts. They include a safety factor of 2. Maximum allowable assembly loads with R max or Ch max are as follows:
Ring Size No.
Maximum Allowable Load,kN
Ring Size No.
Maximum AllowableLoad, kN
Ring Size No.
Maximum AllowableLoad, kN
−1 −2 −3 −4 −5 −6 −7
0.06 0.13 0.3 0.7 0.9 1.1 1.2
−8 −9 −10 −11 −12 −13 −15
1.4 3.0 3.4 3.7 4.9 5.4 6.2
−16 −18 −20 −22 −25 … …
6.6 8.7 9.8 10.8 12.2 … …
Source: Appendix to American National Standard ANSI B27.7-1977, R1993.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
;;; ;; ;;; ;; ;;; ;; ;;; ;; ;;; ;; ;;; ;;
1693
SIZE 0.500 to 1.500
G
SIZE 1.562 and UP
A
C F
E
D
Table 7. Medium Duty Internal Spiral Retaining Rings MIL-R-27426 Ring
Groove
Static Thrust Load (lb)
Bore Dia. A
Dia. G
Wall E
Dia. C
Width D
Ring
0.500 0.512 0.531 0.562 0.594 0.625 0.656 0.687 0.718 0.750 0.777 0.781 0.812 0.843 0.866 0.875 0.906 0.938 0.968 0.987 1.000 1.023 1.031 1.062 1.093 1.125 1.156 1.188 1.218 1.250 1.281 1.312 1.343 1.375 1.406 1.437 1.456 1.468 1.500 1.562 1.574 1.625 1.653 1.687 1.750 1.813
0.532 0.544 0.564 0.594 0.626 0.658 0.689 0.720 0.751 0.790 0.817 0.821 0.853 0.889 0.913 0.922 0.949 0.986 1.025 1.041 1.054 1.078 1.084 1.117 1.147 1.180 1.210 1.249 1.278 1.312 1.342 1.374 1.408 1.442 1.472 1.504 1.523 1.535 1.567 1.634 1.649 1.701 1.730 1.768 1.834 1.894
0.045 0.045 0.045 0.045 0.045 0.045 0.045 0.045 0.045 0.065 0.065 0.065 0.065 0.065 0.065 0.065 0.065 0.065 0.075 0.075 0.075 0.075 0.075 0.075 0.075 0.075 0.075 0.085 0.085 0.085 0.085 0.085 0.085 0.095 0.095 0.095 0.095 0.095 0.095 0.108 0.108 0.108 0.108 0.118 0.118 0.118
0.526 0.538 0.557 0.588 0.619 0.651 0.682 0.713 0.744 0.782 0.808 0.812 0.843 0.880 0.903 0.912 0.939 0.975 1.015 1.030 1.043 1.066 1.074 1.104 1.135 1.167 1.198 1.236 1.266 1.298 1.329 1.360 1.395 1.427 1.458 1.489 1.508 1.520 1.552 1.617 1.633 1.684 1.712 1.750 1.813 1.875
0.030 0.030 0.030 0.030 0.030 0.030 0.030 0.030 0.030 0.036 0.036 0.036 0.036 0.036 0.036 0.036 0.036 0.036 0.042 0.042 0.042 0.042 0.042 0.042 0.042 0.042 0.042 0.048 0.048 0.048 0.048 0.048 0.048 0.048 0.048 0.048 0.048 0.048 0.048 0.056 0.056 0.056 0.056 0.056 0.056 0.056
2000 2050 2130 2250 2380 2500 2630 2750 2870 3360 3480 3500 3640 3780 3880 3920 4060 4200 4340 4420 4480 5470 5510 5680 5840 6010 6180 7380 7570 7770 7960 8150 8340 8540 8740 8930 9050 9120 9320 10100 10180 10510 10690 10910 11310 11720
Ring
Groove
Static Thrust Load (lb)
Groove
Bore Dia. A
Dia. G
Wall E
Dia. C
Width D
Ring
Groove
405 420 455 495 535 610 670 725 790 800 835 840 915 1155 1250 1250 1335 1430 1950 1865 1910 1660 1650 1745 1820 1935 2020 2115 2195 2510 2425 2532 2875 3070 3180 3330 3410 3460 3605 3590 3640 3875 4020 4510 4895 5080
3.437 3.500 3.543 3.562 3.625 3.687 3.740 3.750 3.812 4.437 4.500 4.527 4.562 4.625 4.687 4.724 4.750 4.812 4.875 4.921 4.937 5.000 5.118 5.125 5.250 5.375 5.500 5.511 5.625 5.708 5.750 5.875 5.905 6.000 6.125 6.250 6.299 6.375 6.500 6.625 6.692 6.750 6.875 7.000 7.086 7.125
3.574 3.636 3.684 3.703 3.769 3.832 3.885 3.894 3.963 4.611 4.674 4.701 4.737 4.803 4.867 4.903 4.930 4.993 5.055 5.102 5.122 5.185 5.304 5.311 5.436 5.566 5.693 5.703 5.818 5.909 5.950 6.077 6.106 6.202 6.349 6.474 6.524 6.601 6.726 6.863 6.931 6.987 7.114 7.239 7.337 7.376
0.188 0.188 0.198 0.198 0.198 0.198 0.198 0.198 0.208 0.238 0.238 0.238 0.238 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.250 0.312 0.312 0.312 0.312 0.312 0.312 0.312 0.312 0.312 0.312 0.312 0.312 0.312
3.543 3.606 3.653 3.672 3.737 3.799 3.852 3.862 3.930 4.573 4.636 4.663 4.698 4.765 4.827 4.864 4.890 4.952 5.015 5.061 5.081 5.144 5.262 5.269 5.393 5.522 5.647 5.658 5.772 5.861 5.903 6.028 6.058 6.153 6.297 6.422 6.471 6.547 6.672 6.807 6.874 6.932 7.057 7.182 7.278 7.317
0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.079 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094
27660 28170 28520 28670 29180 29680 30100 30180 30680 35710 36220 36440 36720 43940 44530 44880 45130 45710 46310 46750 46900 47500 48620 48690 49880 51050 52250 52350 53440 54230 54630 55810 56100 57000 69500 70920 71480 72340 73760 75180 75940 76590 78010 79430 80410 80850
18240 18575 19515 19620 20330 20675 20975 21030 22525 30215 30645 30830 31065 32420 32855 33115 33300 33735 34175 34495 35595 36050 36905 36955 37590 39565 40485 40565 41405 43730 44050 45010 45240 45965 52750 53825 54250 54905 55980 60375 60985 61515 62655 63790 68125 68500
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1694
RETAINING RINGS
Table 7. (Continued) Medium Duty Internal Spiral Retaining Rings MIL-R-27426 Bore Dia. A 1.850 1.875 1.938 2.000 2.047 2.062 2.125 2.165 2.188 2.250 2.312 2.375 2.437 2.440 2.500 2.531 2.562 2.625 2.677 2.688 2.750 2.813 2.834 2.875 2.937 2.952 3.000 3.062 3.125 3.149 3.187 3.250 3.312 3.346 3.375
Ring Dia. G 1.937 1.960 2.025 2.091 2.138 2.154 2.217 2.260 2.284 2.347 2.413 2.476 2.543 2.546 2.606 2.641 2.673 2.736 2.789 2.803 2.865 2.929 2.954 2.995 3.058 3.073 3.122 3.186 3.251 3.276 3.311 3.379 3.446 3.479 3.509
Groove
Wall E 0.118 0.118 0.118 0.128 0.128 0.128 0.128 0.138 0.138 0.138 0.138 0.138 0.148 0.148 0.148 0.148 0.148 0.148 0.158 0.158 0.158 0.158 0.168 0.168 0.168 0.168 0.168 0.168 0.178 0.178 0.178 0.178 0.188 0.188 0.188
Dia. C 1.917 1.942 2.005 2.071 2.118 2.132 2.195 2.239 2.262 2.324 2.390 2.453 2.519 2.522 2.582 2.617 2.648 2.711 2.767 2.778 2.841 2.903 2.928 2.969 3.031 3.046 3.096 3.158 3.223 3.247 3.283 3.350 3.416 3.450 3.479
Width D 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068
Static Thrust Load (lb) Ring 11960 12120 12530 12930 13230 13330 13740 14000 14150 14550 14950 15350 15760 15780 16160 16360 16560 16970 17310 17380 17780 18190 18320 18590 18990 19090 24150 24640 25150 25340 25650 26160 26660 26930 27160
Groove 5735 5825 6250 7090 7275 7225 7450 8020 8105 8335 9030 9275 10005 10015 10625 10900 11030 11305 12065 12115 12530 12675 13340 13530 13825 13890 14420 14720 15335 15450 15640 16270 17245 17425 17575
Bore Dia. A 7.250 7.375 7.480 7.500 7.625 7.750 7.875 8.000 8.250 8.267 8.464 8.500 8.750 8.858 9.000 9.055 9.250 9.448 9.500 9.750 10.000 10.250 10.500 10.750 11.000 3.875 3.938 4.000 4.063 4.125 4.188 4.250 4.312 4.330 4.375
Ring Dia. G 7.501 7.628 7.734 7.754 7.890 8.014 8.131 8.266 8.528 8.546 8.744 8.780 9.041 9.151 9.293 9.359 9.555 9.755 9.806 10.068 10.320 10.582 10.834 11.095 11.347 4.025 4.089 4.157 4.222 4.284 4.347 4.416 4.479 4.497 4.543
Wall E 0.312 0.312 0.312 0.312 0.312 0.312 0.312 0.312 0.375 0.375 0.375 0.375 0.375 0.375 0.375 0.375 0.375 0.375 0.375 0.375 0.375 0.375 0.375 0.375 0.375 0.208 0.208 0.218 0.218 0.218 0.218 0.228 0.228 0.228 0.228
Groove Dia. C 7.442 7.567 7.672 7.692 7.827 7.952 8.077 8.202 8.462 8.479 8.676 8.712 8.972 9.080 9.222 9.287 9.482 9.680 9.732 9.992 10.242 10.502 10.752 11.012 11.262 3.993 4.056 5.124 4.187 4.249 4.311 4.380 4.442 4.460 4.505
Width D 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.094 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068
Static Thrust Load (lb) Ring 82270 83690 84880 85110 86520 87940 89360 90780 93620 93810 96040 96450 99290 100520 102130 102750 104960 107210 107800 110640 113470 116310 119150 121980 124820 30680 31700 32190 32700 33200 33710 34210 34710 34850 32210
Groove 69700 70900 71910 72105 77125 78390 79655 80920 87575 87755 89850 90230 97265 98465 100045 105190 107455 109755 110360 118145 121175 129340 132490 141030 144310 22525 23265 24835 25225 25610 25795 27665 28065 28185 28475
Source: Spirolox Retaining Rings, RR Series. All dimensions are in inches. Depth of groove d = (C − A)/2. Standard material: carbon spring steel (SAE 1070-1090). Ring Thickness, F: For shaft sizes 0.500 through 0.718, 0.025; for sizes 0.750 through 0.938, 0.031; for sizes 0.968 through 1.156, 0.037; for sizes 1.188 through 1.500, 0.043; for sizes 1.562 through 2.952, 0.049; for sizes 3.000 through 4.562, 0.061; for sizes 4.625 through 6.000, 0.072; for sizes 6.125 through 11.000, 0.086. Ring Free Diameter Tolerances: For housing sizes 0.500 through 1.031, +0.013, −0.000; for sizes 1.062 through 1.500, +0.015, −0.000; for sizes 1.562 through 2.047, +0.020, −0.000; for sizes 2.062 through 3.000, +0.025, −0.000; for sizes 3.062 through 4.063, +0.030, −0.000; for sizes 4.125 through 5.125, +0.035, −0.000; for sizes 5.250 through 6.125, +0.045, −0.000; for sizes 6.250 through 7.125, +0.055, −0.000; for sizes 7.250 through 11.000, +0.065, −0.000. Ring Thickness Tolerances: Thickness indicated is for unplated rings; add 0.002 to upper thickness tolerance for plated rings. For housing sizes 0.500 through 1.500, ±0.002; for sizes 1.562 through 4.562, ±0.003; for sizes 4.625 through 11.000, ±0.004. Groove Diameter Tolerances: For housing sizes 0.500 through 0.750, ±0.002; for sizes 0.777 through 1.031, ±0.003; for sizes 1.062 through 1.500, ±0.004; for sizes 1.562 through 2.047, ±0.005; for sizes 2.062 through 5.125, ±0.006; for sizes 5.250 through 6.000, ±0.007; for sizes 6.125 through 11.000, ±0.008. Groove Width Tolerances: For housing sizes 0.500 through 1.156, +0.003, −0.000; for sizes 1.188 through 2.952, +0.004, −0.000; for sizes 3.000 through 6.000, +0.005, −0.000; for sizes 6.125 through 11.000, +0.006, −0.000.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
1695
Table 8. Medium Duty External Spiral Retaining Rings MIL-R-27426
; ; ; ; ; ;
SIZE 0.500 to 1.500
G
SIZE 1.562 and UP
C A F
E
D
Ring
Groove
Static Thrust Load (lb)
Ring
Groove
Static Thrust Load (lb)
Groove
Shaft Dia. A
Dia. G
Wall E
Dia. C
Width D
Ring
Groove
550
3.343
3.210
0.188
3.239
0.068
26910
17410
640
3.375
3.242
0.188
3.271
0.068
27160
17570
2210
700
3.437
3.301
0.188
3.331
0.068
27660
18240
0.030
2250
730
3.500
3.363
0.188
3.394
0.068
28170
18580
0.569
0.030
2380
740
3.543
3.402
0.198
3.433
0.068
28520
19510
0.055
0.594
0.030
2500
970
3.562
3.422
0.198
3.452
0.068
28670
19620
0.617
0.055
0.625
0.030
2630
1020
3.625
3.483
0.198
3.515
0.068
29180
19970
0.669
0.629
0.055
0.638
0.030
2680
1040
3.687
3.543
0.198
3.575
0.068
29680
20680
0.687
0.647
0.055
0.656
0.030
2750
1060
3.740
3.597
0.198
3.628
0.068
30100
20970
0.718
0.679
0.055
0.687
0.030
2870
1110
3.750
3.606
0.198
3.638
0.068
30180
21030
0.750
0.710
0.065
0.719
0.036
3360
1100
3.812
3.668
0.198
3.700
0.068
30680
21380
0.781
0.741
0.065
0.750
0.036
3500
1210
3.875
3.724
0.208
3.757
0.068
31190
22890
0.812
0.771
0.065
0.781
0.036
3640
1260
3.938
3.784
0.208
3.820
0.068
31700
23270
0.843
0.803
0.065
0.812
0.036
3780
1310
4.000
3.842
0.218
3.876
0.068
32190
24840
0.875
0.828
0.065
0.838
0.036
3920
1620
4.063
3.906
0.218
3.939
0.068
32700
25230
0.906
0.860
0.065
0.869
0.036
4060
1680
4.125
3.967
0.218
4.000
0.068
33200
25820
0.937
0.889
0.065
0.900
0.036
4200
1740
4.134
3.975
0.218
4.010
0.068
33270
25670
0.968
0.916
0.075
0.925
0.042
5180
2080
4.188
4.030
0.218
4.058
0.068
33710
27260
0.984
0.930
0.075
0.941
0.042
5260
2120
4.250
4.084
0.228
4.120
0.068
34210
27660
1.000
0.946
0.075
0.957
0.042
5350
2150
4.312
4.147
0.218
4.182
0.068
34710
28070
1.023
0.968
0.075
0.980
0.042
5470
2200
4.331
4.164
0.218
4.200
0.068
34860
28410
1.031
0.978
0.075
0.988
0.042
5510
2220
4.375
4.208
0.218
4.245
0.068
35210
28480
1.062
1.007
0.075
1.020
0.042
5680
2230
4.437
4.271
0.218
4.307
0.068
35710
28880
1.093
1.040
0.075
1.051
0.042
5840
2300
4.500
4.326
0.238
4.364
0.068
36220
30640
1.125
1.070
0.075
1.083
0.042
6010
2370
4.562
4.384
0.250
4.422
0.079
43340
31980
1.156
1.102
0.075
1.114
0.042
6180
2430
4.625
4.447
0.250
4.485
0.079
43940
32420
1.188
1.127
0.085
1.140
0.048
7380
2850
4.687
4.508
0.250
4.457
0.079
44530
32860
1.218
1.159
0.085
1.170
0.048
7570
2930
4.724
4.546
0.250
4.584
0.079
44880
33120
1.250
1.188
0.085
1.202
0.048
7770
3000
4.750
4.571
0.250
4.610
0.079
45130
33300
1.281
1.221
0.085
1.233
0.048
7960
3080
4.812
4.633
0.250
4.672
0.079
45710
33730
1.312
1.251
0.095
1.264
0.048
8150
3150
4.875
4.695
0.250
4.735
0.079
46310
34170
1.343
1.282
0.095
1.295
0.048
8340
3230
4.937
4.757
0.250
4.797
0.079
46900
34610
1.375
1.308
0.095
1.323
0.048
8540
3580
5.000
4.820
0.250
4.856
0.079
47500
36050
1.406
1.340
0.095
1.354
0.048
8740
3660
5.118
4.934
0.250
4.974
0.079
48620
36900
1.437
1.370
0.095
1.385
0.048
8930
3740
5.125
4.939
0.250
4.981
0.079
48690
36950
1.468
1.402
0.095
1.416
0.048
9120
3820
5.250
5.064
0.250
5.107
0.079
49880
37590
1.500
1.433
0.095
1.448
0.048
9320
3910
5.375
5.187
0.250
5.228
0.079
51060
39560
1.562
1.490
0.108
1.507
0.056
10100
4300
5.500
5.308
0.250
5.353
0.079
52250
40480
1.575
1.503
0.108
1.520
0.056
10190
4340
5.511
5.320
0.250
5.364
0.079
52350
40560
1.625
1.549
0.108
1.566
0.056
10510
4800
5.625
5.433
0.250
5.478
0.079
53440
41400
Shaft Dia. A
Dia. G
Wall E
Dia. C
Width D
Ring
0.500
0.467
0.045
0.474
0.030
2000
0.531
0.498
0.045
0.505
0.030
2130
0.551
0.518
0.045
0.525
0.030
0.562
0.529
0.045
0.536
0.594
0.561
0.045
0.625
0.585
0.656
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1696
RETAINING RINGS
Table 8. (Continued) Medium Duty External Spiral Retaining Rings MIL-R-27426 1.687
1.610
0.118
1.628
0.056
10910
4980
5.750
5.550
0.250
5.597
0.079
54630
44050
1.750
1.673
0.118
1.691
0.056
11310
5170
5.875
5.674
0.250
5.722
0.079
55810
45010
1.771
1.690
0.118
1.708
0.056
11450
5590
5.905
5.705
0.250
5.752
0.079
56100
45240
1.813
1.730
0.118
1.749
0.056
11720
5810
6.000
5.798
0.250
5.847
0.079
57000
45970
1.875
1.789
0.128
1.808
0.056
12120
6290
6.125
5.903
0.312
5.953
0.094
69500
52750
1.938
1.844
0.128
1.861
0.056
12530
7470
6.250
6.026
0.312
6.078
0.094
70920
53830
1.969
1.882
0.128
1.902
0.056
12730
6610
6.299
6.076
0.312
6.127
0.094
71480
54250
2.000
1.909
0.128
1.992
0.056
12930
7110
6.375
6.152
0.312
6.203
0.094
72340
54900
2.062
1.971
0.128
2.051
0.056
13330
7870
6.500
6.274
0.312
6.328
0.094
73760
55980
2.125
2.029
0.128
2.082
0.056
13740
7990
6.625
6.390
0.312
6.443
0.094
75180
60380
2.156
2.060
0.138
2.091
0.056
13940
8020
6.750
6.513
0.312
6.568
0.094
76590
61515
2.188
2.070
0.138
2.113
0.056
14150
8220
6.875
6.638
0.312
6.693
0.094
78010
62650
2.250
2.092
0.138
2.176
0.056
14550
8340
7.000
6.761
0.312
6.818
0.094
79430
63790
2.312
2.153
0.138
2.234
0.056
14950
9030
7.125
6.877
0.312
6.933
0.094
80850
68500
2.362
2.211
0.138
2.284
0.056
15270
9230
7.250
6.999
0.312
7.058
0.094
82270
69700
2.375
2.273
0.138
2.297
0.056
15350
9280
7.375
7.125
0.312
7.183
0.094
83690
70900
2.437
2.331
0.148
2.355
0.056
15760
10000
7.500
7.250
0.312
7.308
0.094
85110
72100
2.500
2.394
0.148
2.418
0.056
16160
10260
7.625
7.363
0.312
7.423
0.094
86520
77120
2.559
2.449
0.148
2.473
0.056
16540
11020
7.750
7.486
0.312
7.548
0.094
87940
78390
2.562
2.452
0.148
2.476
0.056
16560
11030
7.875
7.611
0.312
7.673
0.094
89360
79650
2.625
2.514
0.148
2.539
0.056
16970
11300
8.000
7.734
0.312
7.798
0.094
90780
80920
2.688
2.572
0.158
2.597
0.056
17380
12250
8.250
7.972
0.375
8.038
0.094
93620
87580
2.750
2.635
0.158
2.660
0.056
17780
12390
8.500
8.220
0.375
8.288
0.094
96450
90230
2.813
2.696
0.168
2.722
0.056
18190
12820
8.750
8.459
0.375
8.528
0.094
99290
97270
2.875
2.755
0.168
2.781
0.056
18590
13530
9.000
8.707
0.375
8.778
0.094
102130
100050
2.937
2.817
0.168
2.843
0.056
18990
13820
9.250
8.945
0.375
9.018
0.094
104960
107560
2.952
2.831
0.168
2.858
0.056
19090
13890
9.500
9.194
0.375
9.268
0.094
107800
110360
3.000
2.877
0.168
2.904
0.068
24150
14420
9.750
9.432
0.375
9.508
0.094
110640
118150
3.062
2.938
0.168
2.966
0.068
24640
14720
10.000
9.680
0.375
9.758
0.094
113470
121180
3.125
3.000
0.178
3.027
0.068
25150
15335
10.250
9.918
0.375
9.998
0.094
116310
129340
3.149
3.023
0.178
3.051
0.068
25340
15450
10.500
10.166
0.375
10.248
0.094
119150
132490
3.187
3.061
0.178
3.089
0.068
25650
15640
10.750
10.405
0.375
10.488
0.094
121980
141030
3.250
3.121
0.178
3.150
0.068
26160
16270
11.000
10.653
0.375
10.738
0.094
124820
144310
3.312
3.180
0.188
3.208
0.068
26660
17250
Source: Spirolox Retaining Rings, RS Series. All dimensions are in inches. Depth of groove d = (A − C)/2. Standard material: carbon spring steel (SAE 1070–1090). Ring Thickness, F: For shaft sizes 0.500 through 0.718, 0.025; for sizes 0.750 through 0.937, 0.031; for sizes 0.968 through 1.156, 0.037; for sizes 1.188 through 1.500, 0.043; for sizes 1.562 through 2.952, 0.049; for sizes 3.000 through 4.500, 0.061; for sizes 4.562 through 6.000, 0.072; for sizes 6.125 through 11.000, 0.086. Ring Free Diameter Tolerances: For shaft sizes 0.500 through 1.031, +0.000, + 0.000, −0.013; for sizes 1.062 through 1.500, +0.000, −0.015; for sizes 1.562 through 2.125, +0.000, −0.020; for sizes 2.156 through 2.688, +0.000, −0.025; for sizes 2.750 through 3.437, +0.000, −0.030; for sizes 3.500 through 5.125, +0.000, −0.040; for sizes 5.250 through 6.125, +0.000, −0.050; for sizes 6.250 through 7.375, +0.000, −0.060; for sizes 7.500 through 11.000, +0.000, −0.070. Ring Thickness Tolerances: Thickness indicated is for unplated rings; add 0.002 to upper tolerance for plated rings. For shaft sizes 0.500 through 1.500, ± 0.002; for sizes 1.562 through 4.500, ± 0.003; for sizes 4.562 through 11.000, ± 0.004. Groove Diameter Tolerances: For shaft sizes 0.500 through 0.562, ±0.002; for sizes 0.594 through 1.031, ± 0.003; for sizes 1.062 through 1.500, ± 0.004; for sizes 1.562 through 2.000, ± 0.005; for sizes 2.062 through 5.125, ±0.006; for sizes 5.250 through 6.000, ± 0.007; for sizes 6.125 through 11.000, ± 0.008. Groove Width Tolerances: For shaft sizes 0.500 through 1.156, +0.003, −0.000; for sizes 1.188 through 2.952, +0.004, −0.000; for sizes 3.000 through 6.000, +0.005, −0.000; for sizes 6.125 through 11.000, +0.006, −0.000.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
;; ;; ;; ;; ;; ;;
1697
SIZE 0.500 to 0.750
G
SIZE 0.777 and UP
A
C F
E
D
Table 9. Heavy Duty Internal Spiral Retaining Rings MIL-R-27426 Ring
Groove
Static Thrust Load (lb)
Ring
Groove
Static Thrust Load (lb)
Groove
Bore Dia. A
Dia. G
Wall E
Dia. C
Width D
Ring
Groove
310
3.543
3.781
0.281
3.755
0.120
49420
28250
2590
325
3.562
3.802
0.281
3.776
0.120
49680
28815
0.039
2840
455
3.625
3.868
0.281
3.841
0.120
50560
30160
0.655
0.039
3160
655
3.750
4.002
0.312
3.974
0.120
52310
33720
0.065
0.732
0.039
3480
965
3.875
4.136
0.312
4.107
0.120
54050
37250
0.807
0.065
0.796
0.039
3790
1065
3.938
4.203
0.312
4.174
0.120
54930
39045
0.777
0.836
0.075
0.825
0.046
4720
1026
4.000
4.270
0.312
4.240
0.120
55790
41025
0.812
0.873
0.075
0.862
0.046
4930
1150
4.125
4.369
0.312
4.339
0.120
57540
38495
0.866
0.931
0.075
0.920
0.046
5260
1395
4.250
4.501
0.312
4.470
0.120
59280
41955
0.875
0.943
0.085
0.931
0.046
5310
1520
4.330
4.588
0.312
4.556
0.120
60400
44815
0.901
0.972
0.085
0.959
0.046
5470
1675
4.500
4.768
0.312
4.735
0.120
62770
50290
0.938
1.013
0.085
1.000
0.046
5690
1925
4.625
4.899
0.312
4.865
0.120
64510
54155
1.000
1.080
0.085
1.066
0.046
6070
2310
4.750
5.030
0.312
4.995
0.120
66260
58270
1.023
1.105
0.085
1.091
0.046
6210
2480
5.000
5.297
0.312
5.260
0.120
69740
65095
1.062
1.138
0.103
1.130
0.056
7010
1940
5.250
5.559
0.350
5.520
0.139
83790
68315
1.125
1.205
0.103
1.197
0.056
7420
2280
5.375
5.690
0.350
5.650
0.139
85780
72840
1.188
1.271
0.103
1.262
0.056
7840
2615
5.500
5.810
0.350
5.770
0.139
87780
74355
1.250
1.339
0.103
1.330
0.056
8250
3110
5.750
6.062
0.350
6.020
0.139
91770
77735
1.312
1.406
0.118
1.396
0.056
8650
3650
6.000
6.314
0.350
6.270
0.139
95760
81120
1.375
1.471
0.118
1.461
0.056
9070
4075
6.250
6.576
0.380
6.530
0.174
122520
80655
1.439
1.539
0.118
1.528
0.056
9490
4670
6.500
6.838
0.380
6.790
0.174
127420
90295
1.456
1.559
0.118
1.548
0.056
9600
4890
6.625
6.974
0.380
6.925
0.174
129870
92060
1.500
1.605
0.118
1.594
0.056
9900
5275
6.750
7.105
0.380
7.055
0.174
132320
102475
1.562
1.675
0.128
1.658
0.068
12780
4840
7.000
7.366
0.380
7.315
0.174
137220
110410
1.625
1.742
0.128
1.725
0.068
13290
5415
7.250
7.628
0.418
7.575
0.209
170370
103440
1.653
1.772
0.128
1.755
0.068
13520
5695
7.500
7.895
0.418
7.840
0.209
176240
115780
1.688
1.810
0.128
1.792
0.068
13810
6070
7.750
8.157
0.418
8.100
0.209
182120
127270
1.750
1.876
0.128
1.858
0.068
14320
7635
8.000
8.419
0.418
8.360
0.209
187990
139370
1.812
1.940
0.128
1.922
0.068
14820
7305
8.250
8.680
0.437
8.620
0.209
193870
152695
1.850
1.981
0.158
1.962
0.068
15130
7960
8.500
8.942
0.437
8.880
0.209
199740
161735
1.875
2.008
0.158
1.989
0.068
15340
8305
8.750
9.209
0.437
9.145
0.209
205620
173065
1.938
2.075
0.158
2.056
0.068
15850
9125
9.000
9.471
0.437
9.405
0.209
211490
182515
2.000
2.142
0.158
2.122
0.068
16360
10040
9.250
9.737
0.437
9.669
0.209
217370
194070
2.062
2.201
0.168
2.186
0.086
21220
8280
9.500
10.000
0.500
9.930
0.209
223240
204550
Bore Dia. A
Dia. G
Wall E
Dia. C
Width D
Ring
0.500
0.538
0.045
0.530
0.039
2530
0.512
0.550
0.045
0.542
0.039
0.562
0.605
0.055
0.596
0.625
0.675
0.055
0.688
0.743
0.750
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1698
RETAINING RINGS
Table 9. (Continued) Heavy Duty Internal Spiral Retaining Rings MIL-R-27426 Ring
Groove
Static Thrust Load (lb)
Ring
Groove
Static Thrust Load (lb)
Groove
Bore Dia. A
Dia. G
Wall E
Dia. C
Width D
Ring
Groove
8935
9.750
10.260
0.500
10.189
0.209
229120
214325
22520
9745
10.000
10.523
0.500
10.450
0.209
234990
225330
23160
10455
10.250
10.786
0.500
10.711
0.209
240870
236605
0.086
23790
11700
10.500
11.047
0.500
10.970
0.209
246740
247110
2.517
0.086
24440
12715
10.750
11.313
0.500
11.234
0.209
252620
260530
0.200
2.584
0.086
25110
13550
11.000
11.575
0.500
11.495
0.209
258490
272645
2.667
0.200
2.648
0.086
25730
14640
11.250
11.838
0.500
11.756
0.209
264360
285040
2.531
2.700
0.200
2.681
0.086
26050
15185
11.500
12.102
0.562
12.018
0.209
270240
298285
2.562
2.733
0.225
2.714
0.103
29940
12775
11.750
12.365
0.562
12.279
0.209
276120
311240
2.625
2.801
0.225
2.781
0.103
30680
13780
12.000
12.628
0.562
12.540
0.209
281990
324475
2.688
2.868
0.225
2.848
0.103
31410
14775
12.250
12.891
0.562
12.801
0.209
287860
337980
2.750
2.934
0.225
2.914
0.103
32140
15790
12.500
13.154
0.562
13.063
0.209
293740
352390
2.813
3.001
0.225
2.980
0.103
32870
16845
12.750
13.417
0.562
13.324
0.209
299610
366460
2.834
3.027
0.225
3.006
0.103
33120
17595
13.000
13.680
0.662
13.585
0.209
305490
380805
2.875
3.072
0.225
3.051
0.103
33600
18505
13.250
13.943
0.662
13.846
0.209
311360
395430
3.000
3.204
0.225
3.182
0.103
35060
20795
13.500
14.207
0.662
14.108
0.209
317240
411000
3.062
3.271
0.281
3.248
0.120
42710
18735
13.750
14.470
0.662
14.369
0.209
323110
426185
3.125
3.338
0.281
3.315
0.120
43590
19865
14.000
14.732
0.662
14.630
0.209
328990
441645
3.157
3.371
0.281
3.348
0.120
44020
20345
14.250
14.995
0.662
14.891
0.209
334860
457380
3.250
3.470
0.281
3.446
0.120
45330
22120
14.500
15.259
0.750
15.153
0.209
340740
474120
3.346
3.571
0.281
3.546
0.120
46670
23905
14.750
15.522
0.750
15.414
0.209
346610
490415
3.469
3.701
0.281
3.675
0.120
48390
26405
15.000
15.785
0.750
15.675
0.209
352490
506990
3.500
3.736
0.281
3.710
0.120
48820
27370
Bore Dia. A
Dia. G
Wall E
Dia. C
Width D
Ring
2.125
2.267
0.168
2.251
0.086
21870
2.188
2.334
0.168
2.318
0.086
2.250
2.399
0.168
2.382
0.086
2.312
2.467
0.200
2.450
2.357
2.535
0.200
2.440
2.602
2.500
Source: Spirolox Retaining Rings, RRN Series. All dimensions are in inches. Depth of groove d = (C − A)/2. Thickness indicated is for unplated rings; add 0.002 to upper thickness tolerance for plated rings. Standard material: carbon spring steel (SAE 1070–1090). Ring Thickness, F: For housing sizes 0.500 through 0.750, 0.035; for sizes 0.777 through 1.023, 0.042; for sizes 1.062 through 1.500, 0.050; for sizes 1.562 through 2.000, 0.062; for sizes 2.062 through 2.531, 0.078; for sizes 2.562 through 3.000, 0.093; for sizes 3.062 through 5.000, 0.111; for sizes 5.250 through 7.000, 0.156; for sizes 7.250 through 15.000, 0.187. Ring Free Diameter Tolerances: For housing sizes 0.500 through 1.500, +0.013, −0.000; for sizes 1.562 through 2.000, +0.020, −0.000; for sizes 2.062 through 2.531, + 0.025, −0.000; for sizes 2.562 through 3.000, +0.030, −0.000; for sizes 3.062 through 5.000, +0.035, −0.000; for sizes 5.250 through 6.000, +0.050, −0.000; for sizes 6.250 through 7.000, +0.055. −0.000; for sizes 7.250 through 10.500, +0.070, −0.000; for sizes 10.750 through 12.750, +0.120, −0.000; for sizes 13.000 through 15.000, +0.140, −0.000. Ring Thickness Tolerances: For housing sizes 0.500 through 1.500, ± 0.002; for sizes 1.562 through 5.000, ± 0.003; for sizes 5.250 through 6.000, ± 0.004; for sizes 6.250 through 15.000, ± 0.005. Groove Diameter Tolerances: For housing sizes 0.500 through 0.750, ± 0.002; for sizes 0.777 through 1.023, ± 0.003; for sizes 1.062 through 1.500, ± 0.004; for sizes 1.562 through 2.000, ± 0.005; for sizes 2.062 through 5.000, ± 0.006; for sizes 5.250 through 6.000, ± 0.007; for sizes 6.250 through 10.500, ± 0.008; for sizes 10.750 through 12.500, ± 0.010; for sizes 12.750 through 15.000, ± 0.012. Groove Width Tolerances: For housing sizes 0.500 through 1.023, +0.003, −0.000; for sizes 1.062 through 2.000, +0.004, −0.000; for sizes 2.062 through 5.000, +0.005, −0.000; for sizes 5.250 through 6.000, +0.006, −0.000; for sizes 6.250 through 7.000, +0.008, −0.000; for sizes 7.250 through 15.000, +0.008, −0.000.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
;; ;; ;; ;; ;; ;;
1699
SIZE 0.469 to 0.669
G
SIZE 0.688 and UP
C A F
E
D
Table 10. Heavy Duty External Spiral Retaining Rings MIL-R-27426 Ring
Groove
Static Thrust Load (lb)
Shaft Dia. A
Dia. G
Wall E
Dia. C
Width D
Ring
0.469 0.500 0.551 0.562 0.594 0.625 0.669 0.688 0.750 0.781 0.812 0.875 0.938 0.984 1.000 1.023 1.062 1.125 1.188 1.250 1.312 1.375 1.438 1.500 1.562 1.625 1.687 1.750 1.771 1.812 1.875 1.969 2.000 2.062 2.125 2.156 2.250 2.312 2.375 2.437 2.500 2.559 2.625 2.687
0.439 0.464 0.514 0.525 0.554 0.583 0.623 0.641 0.698 0.727 0.756 0.814 0.875 0.919 0.932 0.953 0.986 1.047 1.105 1.163 1.218 1.277 1.336 1.385 1.453 1.513 1.573 1.633 1.651 1.690 1.751 1.838 1.867 1.932 1.989 2.018 2.105 2.163 2.223 2.283 2.343 2.402 2.464 2.523
0.045 0.050 0.050 0.050 0.050 0.055 0.055 0.065 0.065 0.065 0.065 0.075 0.075 0.085 0.085 0.085 0.103 0.103 0.103 0.103 0.118 0.118 0.118 0.118 0.128 0.128 0.128 0.128 0.128 0.128 0.158 0.158 0.158 0.168 0.168 0.168 0.168 0.168 0.200 0.200 0.200 0.200 0.200 0.200
0.443 0.468 0.519 0.530 0.559 0.588 0.629 0.646 0.704 0.733 0.762 0.821 0.882 0.926 0.940 0.961 0.998 1.059 1.118 1.176 1.232 1.291 1.350 1.406 1.468 1.529 1.589 1.650 1.669 1.708 1.769 1.857 1.886 1.946 2.003 2.032 2.120 2.178 2.239 2.299 2.360 2.419 2.481 2.541
0.029 0.039 0.039 0.039 0.039 0.039 0.039 0.046 0.046 0.046 0.046 0.046 0.046 0.046 0.046 0.046 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.068 0.086 0.086 0.086 0.086 0.086 0.086 0.086 0.086 0.086 0.086 0.086
1880 2530 2790 2840 3000 3160 3380 4170 4550 4740 4930 5310 5690 5970 6070 6210 7010 7420 7840 8250 8650 9070 9490 9900 12780 13290 13800 14320 14490 14820 15340 16110 16360 21220 21870 22190 23160 23790 24440 25080 25730 26340 27020 27650
Ring
Groove
Static Thrust Load (lb)
Groove
Shaft Dia. A
Dia. G
Wall E
Dia. C
Width D
Ring
Groove
510 440 540 560 700 820 1070 960 1250 1430 1620 2000 2440 2790 2950 3170 2810 2890 3450 4110 4810 5650 6340 7060 6600 7330 8190 8760 9040 9440 9950 11040 11420 11820 12980 13390 14650 15510 16170 16840 17530 17940 18930 19640
3.500 3.543 3.625 3.687 3.750 3.875 3.938 4.000 4.250 4.375 4.500 4.750 5.000 5.250 5.500 5.750 6.000 6.250 6.500 6.750 7.000 7.250 7.500 7.750 8.000 8.250 8.500 8.750 9.000 9.250 9.500 9.750 10.000 10.250 10.500 10.750 11.000 11.250 11.500 11.750 12.000 12.250 12.500 12.750
3.293 3.333 3.411 3.469 3.527 3.647 3.708 3.765 4.037 4.161 4.280 4.518 4.756 4.995 5.228 5.466 5.705 5.938 6.181 6.410 6.648 6.891 7.130 7.368 7.606 7.845 8.083 8.324 8.560 8.798 9.036 9.275 9.508 9.745 9.984 10.221 10.459 10.692 10.934 11.171 11.410 11.647 11.885 12.124
0.270 0.270 0.270 0.270 0.270 0.270 0.270 0.270 0.270 0.270 0.270 0.270 0.270 0.350 0.350 0.350 0.350 0.418 0.418 0.418 0.418 0.418 0.437 0.437 0.437 0.437 0.437 0.437 0.500 0.500 0.500 0.500 0.500 0.500 0.500 0.500 0.500 0.500 0.562 0.562 0.562 0.562 0.562 0.562
3.316 3.357 3.435 3.493 3.552 3.673 3.734 3.792 4.065 4.190 4.310 4.550 4.790 5.030 5.265 5.505 5.745 5.985 6.225 6.465 6.705 6.942 7.180 7.420 7.660 7.900 8.140 8.383 8.620 8.860 9.100 9.338 9.575 9.814 10.054 10.293 10.533 10.772 11.011 11.250 11.490 11.729 11.969 12.208
0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.139 0.139 0.139 0.139 0.174 0.174 0.174 0.174 0.174 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209 0.209
48820 49420 50560 51430 52310 54050 54930 55790 59280 61020 62770 66260 69740 83790 87780 91770 95760 122520 127420 132320 137220 142130 176240 182120 187990 193870 199740 205620 211490 217370 223240 229120 234990 240870 246740 252620 258490 264360 270240 276120 281990 287860 293740 299610
32250 33000 34490 35820 37180 39190 40230 41660 39370 40530 42810 47570 52580 57830 64720 70540 76610 82930 89510 96330 103400 111810 120170 128060 136200 144590 153220 160800 171250 180640 190280 201140 212810 223780 234490 246000 257230 269270 281590 294180 306450 319580 332360 346030
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1700
RETAINING RINGS
Table 10. (Continued) Heavy Duty External Spiral Retaining Rings MIL-R-27426 Shaft Dia. A 2.750 2.875 2.937 3.000 3.062 3.125 3.156 3.250 3.344 3.437
Ring Dia. G 2.584 2.702 2.760 2.818 2.878 2.936 2.965 3.054 3.144 3.234
Groove
Wall E 0.225 0.225 0.225 0.225 0.225 0.225 0.225 0.225 0.225 0.225
Dia. C 2.602 2.721 2.779 2.838 2.898 2.957 2.986 3.076 3.166 3.257
Width D 0.103 0.103 0.103 0.103 0.103 0.103 0.103 0.103 0.103 0.103
Static Thrust Load (lb) Ring 32140 33600 34320 35060 35780 36520 36880 37980 39080 40170
Groove 20380 22170 23240 24340 25140 26290 26860 28320 29800 30980
Shaft Dia. A 13.000 13.250 13.500 13.750 14.000 14.250 14.500 14.750 15.000
Ring Dia. G 12.361 12.598 12.837 13.074 13.311 13.548 13.787 14.024 14.262
Wall E 0.662 0.662 0.662 0.662 0.662 0.662 0.750 0.750 0.750
Groove Static Thrust Load (lb) Dia. Width C D Ring Groove 12.448 0.209 305490 359330 12.687 0.209 311360 373530 12.927 0.209 317240 387340 13.166 0.209 323110 402090 13.405 0.209 328990 417110 13.644 0.209 334860 432410 13.884 0.209 340740 447250 14.123 0.209 346610 463090 14.363 0.209 352490 478450
Source: Spirolox Retaining Rings, RSN Series. All dimensions are in inches. Depth of groove d = (A − C)/2. Thickness indicated is for unplated rings; add 0.002 to upper tolerance for plated rings. Standard material: carbon spring steel (SAE 1070-1090). Ring Thickness, F: For shaft size 0.469, 0.025; for sizes 0.500 through 0.669, 0.035; for sizes 0.688 through 1.023, 0.042; for sizes 1.062 through 1.500, 0.050; for sizes 1.562 through 2.000, 0.062; for sizes 2.062 through 2.687, 0.078; for sizes 2.750 through 3.437, 0.093; for sizes 3.500 through 5.000, 0.111; for sizes 5.250 through 6.000, 0.127; for sizes 6.250 through 7.250, 0.156; for sizes 7.500 through 15.000, 0.187. Ring Free Diameter Tolerances: For shaft sizes 0.469 through 1.500, +0.000, −0.013; for sizes 1.562 through 2.000, +0.000, −0.020; for sizes 2.062 through 2.687, + 0.000, −0.025; for sizes 2.750 through 3.437, +0.000, −0.030; for sizes 3.500 through 5.000, +0.000, −0.035; for sizes 5.250 through 6.000, +0.000, −0.050; for sizes 6.250 through 7.000, +0.000, −0.060; for sizes 7.250 through 10.000, +0.000, −0.070; for sizes 10.250 through 12.500, +0.000, −0.090; for sizes 12.750 through 15.000, +0.000, −0.110. Ring Thickness Tolerances: For shaft sizes 0.469 through 1.500, ±0.002; for sizes 1.562 through 5.000, ±0.003; for sizes 5.250 through 6.000, ±0.004; for sizes 6.250 through 15.000, ±0.005. Groove Diameter Tolerances: For shaft sizes 0.469 through 0.562, ±0.002; for sizes 0.594 through 1.023, ±0.003; for sizes 1.062 through 1.500, ±0.004; for sizes 1.562 through 2.000, ±0.005; for sizes 2.062 through 5.000, ±0.006; for sizes 5.250 through 6.000, ±0.007; for sizes 6.250 through 10.000, ±0.008; for sizes 10.250 through 12.500, ±0.010; for sizes 12.750 through 15.000, ±0.012. Groove Width Tolerances: For shaft sizes 0.469 through 1.023, +0.003, −0.000; for sizes 1.062 through 2.000, +0.004, −0.000; for sizes 2.062 through 5.000, +0.005, −0.000; for sizes 5.250 through 6.000, +0.006; −0.000; for sizes 6.250 through 7.250, + 0.008, −0.000; for sizes 7.500 through 15.000, +0.008, −0.000.
Thrust Load Capacity: The most important criterion in determining which ring is best suited for a specific application is thrust load capacity. The strength of the retaining ring and groove must both be considered when analyzing the thrust load capacity of an application to determine whether the groove or the retaining ring is likely to fail first. When a retaining ring application fails, the fault will usually be with the groove, unless the groove material is of very high strength. Ring Material: The standard materials for spiral-wound retaining rings are SAE 1070 to 1090 carbon spring steels and 18-8 type 302 stainless steels. The 1070 to 1090 carbon spring steels provide high-strength retaining rings at low cost. Type 302 stainless steel withstands ordinary rusting. Other materials are used for specialized applications, such as the type 316 stainless frequently used in the food industry. For high-temperature use, superalloy A286 rings can be used at up to 900°F and Inconel X-750 at up to 1200°F. Other materials, such as 316 stainless steel, 17-7PH and Inconel stainless steels are sometimes used for special-purpose and custom-made rings. Standard ring are typically supplied uncoated, however, special finishes such as cadmium, phosphate, zinc, or black oxide coatings for carbon spring steel rings and passivation of stainless steel rings are available.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
1701
Table 11. Important Dimensions of Inch Series External Retaining Rings MS 16624 A
;; ;; ;; L
GD
S
U
H Shaft Dia. D 0.125 0.156 0.188 0.197 0.219 0.236 0.250 0.276 0.281 0.312 0.344 0.354 0.375 0.394 0.406 0.438 0.469 0.500 0.551 0.562 0.594 0.625 0.669 0.672 0.688 0.750 0.781 0.812 0.844 0.875 0.938 0.984 1.000 1.023 1.062 1.125 1.188 1.250 1.312 1.375 1.438 1.500 1.562 1.625 1.687 1.750 1.772
Ring Dia. Thick. A T 0.112 0.010 0.142 0.010 0.168 0.015 0.179 0.015 0.196 0.015 0.215 0.015 0.225 0.025 0.250 0.025 0.256 0.025 0.281 0.025 0.309 0.025 0.320 0.025 0.338 0.025 0.354 0.025 0.366 0.025 0.395 0.025 0.428 0.025 0.461 0.035 0.509 0.035 0.521 0.035 0.550 0.035 0.579 0.035 0.621 0.035 0.621 0.035 0.635 0.042 0.693 0.042 0.722 0.042 0.751 0.042 0.780 0.042 0.810 0.042 0.867 0.042 0.910 0.042 0.925 0.042 0.946 0.042 0.982 0.050 1.041 0.050 1.098 0.050 1.156 0.050 1.214 0.050 1.272 0.050 1.333 0.050 1.387 0.050 1.446 0.062 1.503 0.062 1.560 0.062 1.618 0.062 1.637 0.062
Lugs: D = 0.125 to 0.236
Dia. G 0.117 0.146 0.175 0.185 0.205 0.222 0.230 0.255 0.261 0.290 0.321 0.330 0.352 0.369 0.382 0.412 0.443 0.468 0.519 0.530 0.559 0.588 0.629 0.631 0.646 0.704 0.733 0.762 0.791 0.821 0.882 0.926 0.940 0.961 0.998 1.059 1.118 1.176 1.232 1.291 1.350 1.406 1.468 1.529 1.589 1.650 1.669
Groove Width W 0.012 0.012 0.018 0.018 0.018 0.018 0.029 0.029 0.029 0.029 0.029 0.029 0.029 0.029 0.029 0.029 0.029 0.039 0.039 0.039 0.039 0.039 0.039 0.039 0.046 0.046 0.046 0.046 0.046 0.046 0.046 0.046 0.046 0.046 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.056 0.068 0.068 0.068 0.068 0.068
;;; ;;; ;;; ;;; ;;;
W
T
Margin E 0.012 0.015 0.018 0.018 0.021 0.021 0.030 0.030 0.030 0.033 0.033 0.036 0.036 0.036 0.036 0.039 0.039 0.048 0.048 0.048 0.051 0.054 0.060 0.060 0.063 0.069 0.072 0.075 0.080 0.081 0.084 0.087 0.090 0.093 0.096 0.099 0.105 0.111 0.120 0.126 0.132 0.141 0.141 0.144 0.147 0.150 0.153
Shaft Dia. D 1.812 1.875 1.969 2.000 2.062 2.125 2.156 2.250 2.312 2.375 2.438 2.500 2.559 2.625 2.688 2.750 2.875 2.938 3.000 3.062 3.125 3.156 3.250 3.346 3.438 3.500 3.543 3.625 3.688 3.750 3.875 3.938 4.000 4.250 4.375 4.500 4.750 5.000 5.250 5.500 5.750 6.000 6.250 6.500 6.750 7.000 7.500
E
Lugs: D = 4.25 to 8.00 Ring Dia. Thick. A T 1.675 0.062 1.735 0.062 1.819 0.062 1.850 0.062 1.906 0.078 1.964 0.078 1.993 0.078 2.081 0.078 2.139 0.078 2.197 0.078 2.255 0.078 2.313 0.078 2.377 0.078 2.428 0.078 2.485 0.078 2.543 0.093 2.659 0.093 2.717 0.093 2.775 0.093 2.832 0.093 2.892 0.093 2.920 0.093 3.006 0.093 3.092 0.093 3.179 0.093 3.237 0.109 3.277 0.109 3.352 0.109 3.410 0.109 3.468 0.109 3.584 0.109 3.642 0.109 3.700 0.109 3.989 0.109 4.106 0.109 4.223 0.109 4.458 0.109 4.692 0.109 4.927 0.125 5.162 0.125 5.396 0.125 5.631 0.125 5.866 0.156 6.100 0.156 6.335 0.156 6.570 0.156 7.009 0.187
Dia. G 1.708 1.769 1.857 1.886 1.946 2.003 2.032 2.120 2.178 2.239 2.299 2.360 2.419 2.481 2.541 2.602 2.721 2.779 2.838 2.898 2.957 2.986 3.076 3.166 3.257 3.316 3.357 3.435 3.493 3.552 3.673 3.734 3.792 4.065 4.190 4.310 4.550 4.790 5.030 5.265 5.505 5.745 5.985 6.225 6.465 6.705 7.180
Copyright 2004, Industrial Press, Inc., New York, NY
Groove Width W 0.068 0.068 0.068 0.068 0.086 0.086 0.086 0.086 0.086 0.086 0.086 0.086 0.086 0.086 0.086 0.103 0.103 0.103 0.103 0.103 0.103 0.103 0.103 0.103 0.103 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.120 0.139 0.139 0.139 0.139 0.174 0.174 0.174 0.174 0.209
Margin E 0.156 0.159 0.168 0.171 0.174 0.183 0.186 0.195 0.201 0.204 0.207 0.210 0.210 0.216 0.219 0.222 0.231 0.237 0.243 0.246 0.252 0.255 0.261 0.270 0.270 0.276 0.279 0.285 0.291 0.297 0.303 0.306 0.312 0.276 0.276 0.285 0.300 0.315 0.330 0.351 0.366 0.381 0.396 0.411 0.426 0.441 0.480
Machinery's Handbook 27th Edition 1702
RETAINING RINGS
Source: Industrial Retaining Rings, 3100 Series. All dimensions are in inches. Depth of groove d = (D − G)/2. Thickness indicated is for unplated rings; for most plated rings, the maximum ring thickness will not exceed the minimum groove width (W) minus 0.0002 inch. Standard material: carbon spring steel (SAE 1060-1090). Ring Free Diameter Tolerances: For shaft sizes 0.125 through 0.250, +0.002, −0.004; for sizes 0.276 through 0.500, +0.002, −0.005; for sizes 0.551 through 1.023, +0.005, −0.010; for sizes 1.062 through 1.500, +0.010, −0.015; for sizes 1.562 through 2.000, +0.013, −0.020; for sizes 2.062 through 2.500, +0.015, −0.025; for sizes 2.559 through 5.000, +0.020, −0.030; for sizes 5.250 through 6.000, +0.020, −0.040; for sizes 6.250 through 6.750, +0.020, −0.050; for sizes 7.000 and 7.500, +0.050, −0.130. Ring Thickness Tolerances: For shaft sizes 0.125 and 0.156, ±0.001; for sizes 0.188 through 1.500, ±0.002; for sizes 1.562 through 5.000, ±0.003; for sizes 5.250 through 6.000, ±0.004; for sizes 6.250 through 7.500, ±0.005. Groove Diameter Tolerances: For shaft sizes 0.125 through 0.250, ±0.0015; for sizes 0.276 through 0.562, ±0.002; for sizes 0.594 through 1.023, ±0.003; for sizes 1.062 though 1.500, ±0.004; for sizes 1.562 through 2.000, ±0.005; for sizes 2.062 through 5.000, ±0.006; for sizes 5.250 through 6.000, ±0.007; for sizes 6.250 through 7.500, ±0.008. Groove Width Tolerances: For shaft sizes 0.125 through 0.236, +0.002, −0.000; for sizes 0.250 through 1.023, +0.003, −0.000; for sizes 1.062 through 2.000, +0.004, −0.000; for sizes 2.062 through 5.000, +0.005, −0.000; for sizes 5.250 through 6.000, +0.006, −0.000; for sizes 6.250 through 7.500, +0.008, −0.000.
A
T L
S
U
H
;;; ;;; ;;; ;;; ;;; ;;; ;;;
;; ;
W
Lugs: D = 2.062 to 2.750 D = 3.000 to 4.625
DG
E
Table 12. Important Dimensions of Inch Series Internal Retaining Rings Ring
Groove
Ring
Groove
Housing Dia. D
Dia. A
Thick. T
Dia. G
Width W
Margin E
Housing Dia. D
Dia. A
Thick. T
Dia. G
Width W
Margin E
0.250
0.280
0.015
0.268
0.018
0.027
2.500
2.775
0.078
2.648
0.086
0.222
0.312
0.346
0.015
0.330
0.018
0.027
2.531
2.775
0.078
2.681
0.086
0.225
0.375
0.415
0.025
0.397
0.029
0.033
2.562
2.844
0.093
2.714
0.103
0.228
0.438
0.482
0.025
0.461
0.029
0.036
2.625
2.910
0.093
2.781
0.103
0.234
0.453
0.498
0.025
0.477
0.029
0.036
2.677
2.980
0.093
2.837
0.103
0.240
0.500
0.548
0.035
0.530
0.039
0.045
2.688
2.980
0.093
2.848
0.103
0.240
0.512
0.560
0.035
0.542
0.039
0.045
2.750
3.050
0.093
2.914
0.103
0.246
0.562
0.620
0.035
0.596
0.039
0.051
2.812
3.121
0.093
2.980
0.103
0.252
0.625
0.694
0.035
0.665
0.039
0.060
2.835
3.121
0.093
3.006
0.103
0.255
0.688
0.763
0.035
0.732
0.039
0.066
2.875
3.191
0.093
3.051
0.103
0.264
0.750
0.831
0.035
0.796
0.039
0.069
2.953
3.325
0.093
3.135
0.103
0.273
0.777
0.859
0.042
0.825
0.046
0.072
3.000
3.325
0.093
3.182
0.103
0.273
0.812
0.901
0.042
0.862
0.046
0.075
3.062
3.418
0.109
3.248
0.120
0.279
0.866
0.961
0.042
0.920
0.046
0.081
3.125
3.488
0.109
3.315
0.120
0.285
0.875
0.971
0.042
0.931
0.046
0.084
3.149
3.523
0.109
3.341
0.120
0.288
0.901
1.000
0.042
0.959
0.046
0.087
3.156
3.523
0.109
3.348
0.120
0.288
0.938
1.041
0.042
1.000
0.046
0.093
3.250
3.623
0.109
3.446
0.120
0.294
1.000
1.111
0.042
1.066
0.046
0.099
3.346
3.734
0.109
3.546
0.120
0.300
1.023
1.136
0.042
1.091
0.046
0.102
3.469
3.857
0.109
3.675
0.120
0.309
1.062
1.180
0.050
1.130
0.056
0.102
3.500
3.890
0.109
3.710
0.120
0.315
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
1703
Table 12. (Continued) Important Dimensions of Inch Series Internal Retaining Rings Ring
Groove
Ring
Groove
Housing Dia. D
Dia. A
Thick. T
Dia. G
Width W
Margin E
Housing Dia. D
Dia. A
Thick. T
Dia. G
Width W
Margin E
1.125
1.249
0.050
1.197
0.056
0.108
3.543
3.936
0.109
3.755
0.120
0.318
1.181
1.319
0.050
1.255
0.056
0.111
3.562
3.936
0.109
3.776
0.120
0.321
1.188
1.319
0.050
1.262
0.056
0.111
3.625
4.024
0.109
3.841
0.120
0.324
1.250
1.388
0.050
1.330
0.056
0.120
3.740
4.157
0.109
3.964
0.120
0.336
1.259
1.388
0.050
1.339
0.056
0.120
3.750
4.157
0.109
3.974
0.120
0.336
1.312
1.456
0.050
1.396
0.056
0.126
3.875
4.291
0.109
4.107
0.120
0.348
1.375
1.526
0.050
1.461
0.056
0.129
3.938
4.358
0.109
4.174
0.120
0.354
1.378
1.526
0.050
1.464
0.056
0.129
4.000
4.424
0.109
4.240
0.120
0.360
1.438
1.596
0.050
1.528
0.056
0.135
4.125
4.558
0.109
4.365
0.120
0.360
1.456
1.616
0.050
1.548
0.056
0.138
4.250
4.691
0.109
4.490
0.120
0.360
1.500
1.660
0.050
1.594
0.056
0.141
4.331
4.756
0.109
4.571
0.120
0.360
1.562
1.734
0.062
1.658
0.068
0.144
4.500
4.940
0.109
4.740
0.120
0.360
1.575
1.734
0.062
1.671
0.068
0.144
4.625
5.076
0.109
4.865
0.120
0.360
1.625
1.804
0.062
1.725
0.068
0.150
4.724
5.213
0.109
4.969
0.120
0.366
1.653
1.835
0.062
1.755
0.068
0.153
4.750
5.213
0.109
4.995
0.120
0.366
1.688
1.874
0.062
1.792
0.068
0.156
5.000
5.485
0.109
5.260
0.120
0.390
1.750
1.942
0.062
1.858
0.068
0.162
5.250
5.770
0.125
5.520
0.139
0.405
1.812
2.012
0.062
1.922
0.068
0.165
5.375
5.910
0.125
5.650
0.139
0.405
1.850
2.054
0.062
1.962
0.068
0.168
5.500
6.066
0.125
5.770
0.139
0.405
1.875
2.054
0.062
1.989
0.068
0.171
5.750
6.336
0.125
6.020
0.139
0.405
1.938
2.141
0.062
2.056
0.068
0.177
6.000
6.620
0.125
6.270
0.139
0.405
2.000
2.210
0.062
2.122
0.068
0.183
6.250
6.895
0.156
6.530
0.174
0.420
2.047
2.280
0.078
2.171
0.086
0.186
6.500
7.170
0.156
6.790
0.174
0.435
2.062
2.280
0.078
2.186
0.086
0.186
6.625
7.308
0.156
6.925
0.174
0.450
2.125
2.350
0.078
2.251
0.086
0.189
6.750
7.445
0.156
7.055
0.174
0.456
2.165
2.415
0.078
2.295
0.086
0.195
7.000
7.720
0.156
7.315
0.174
0.471
2.188
2.415
0.078
2.318
0.086
0.195
7.250
7.995
0.187
7.575
0.209
0.486
2.250
2.490
0.078
2.382
0.086
0.198
7.500
8.270
0.187
7.840
0.209
0.510
2.312
2.560
0.078
2.450
0.086
0.207
7.750
8.545
0.187
8.100
0.209
0.525
2.375
2.630
0.078
2.517
0.086
0.213
8.000
8.820
0.187
8.360
0.209
0.540
2.440
2.702
0.078
2.584
0.086
0.216
8.250
9.095
0.187
8.620
0.209
0.555
Source: Industrial Retaining Rings, 3000 Series. All dimensions are in inches. Depth of groove d = (G − D)/2. Thickness indicated is for unplated rings. Standard material: carbon spring steel (SAE 1060-1090). Ring Free Diameter Tolerances: For housing sizes 0.250 through 0.777, +0.010, −0.005; for sizes 0.812 through 1.023, +0.015, − 0.010; for sizes 1.062 through 1.500, + 0.025, − 0.020; for sizes 1.562 through 2.000, +0.035, −0.025; for sizes 2.047 through 3.000, +0.040, −0.030; for sizes 3.062 through 3.625, ±0.055; for sizes 3.740 through 6.000, ±0.065; for sizes 6.250 through 7.000, ±0.080; for sizes 7.250 through 8.250, ±0.090. Ring Thickness Tolerances: For housing sizes 0.250 through 1.500, ±0.002; for sizes 1.562 through 5.000, ±0.003; for sizes 5.250 through 6.000, ±0.004; for sizes 6.250 through 8.250, ±0.005. Groove Diameter Tolerances: For housing sizes 0.250 and 0.312, ±0.001; for sizes 0.375 through 0.750, ±0.002; for sizes 0.777 through 1.023 ±0.003; for sizes 1.062 through 1.500, ±0.004; for sizes 1.562 through 2.000, ±0.005; for sizes 2.047 through 5.000 ±0.006; for sizes 5.250 through 6.000, ±0.007; for sizes 6.250 through 8.250, ±0.008. Groove Width Tolerances: For housing sizes 0.250 and 0.312, +0.002, − 0.000; for sizes 0.375 through 1.023, +0.003, −0.000; for sizes 1.062 through 2.000, +0.004, −0.000; for sizes 2.047 through 5.000, +0.005; −0.000; for sizes 5.250 through 6.000, +0.006, −0.000; for sizes 6.250 through 8.250, +0.008, −0.000.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1704
RETAINING RINGS
;; ;;
Table 13. Important Dimensions of Inch Series External Retaining Rings MS16632 L
AB
T
Shaft Diameter D 0.125 0.156 0.188 0.219 0.236 0.250 0.281 0.312 0.375 0.406 0.437 0.500 0.562 0.625 0.687 0.750 0.812 0.875 0.937 1.000 1.125 1.188 1.250 1.375 1.500 1.750 2.000
Free Dia. A 0.102 0.131 0.161 0.187 0.203 0.211 0.242 0.270 0.328 0.359 0.386 0.441 0.497 0.553 0.608 0.665 0.721 0.777 0.830 0.887 0.997 1.031 1.110 1.220 1.331 1.555 1.777
Ring Thickness T 0.015 0.015 0.015 0.025 0.025 0.025 0.025 0.025 0.025 0.025 0.025 0.035 0.035 0.035 0.042 0.042 0.042 0.042 0.042 0.042 0.050 0.050 0.050 0.050 0.050 0.062 0.062
Diameter B 0.164 0.205 0.245 0.275 0.295 0.311 0.344 0.376 0.448 0.485 0.516 0.581 0.653 0.715 0.780 0.845 0.915 0.987 1.054 1.127 1.267 1.321 1.410 1.550 1.691 1.975 2.257
Diameter G 0.106 0.135 0.165 0.193 0.208 0.220 0.247 0.276 0.335 0.364 0.393 0.450 0.507 0.563 0.619 0.676 0.732 0.789 0.843 0.900 1.013 1.047 1.126 1.237 1.350 1.576 1.800
;;; ;;; ;;; ;;; ;;;
W
GD
E
Groove Width W 0.018 0.018 0.018 0.029 0.029 0.029 0.029 0.029 0.029 0.029 0.029 0.039 0.039 0.039 0.046 0.046 0.046 0.046 0.046 0.046 0.056 0.056 0.056 0.056 0.056 0.068 0.068
aStatic
Margin E 0.020 0.020 0.022 0.026 0.028 0.030 0.034 0.036 0.040 0.042 0.044 0.050 0.056 0.062 0.068 0.074 0.080 0.086 0.094 0.100 0.112 0.140 0.124 0.138 0.150 0.174 0.200
Thrust Load (lb) Ring Groove 85 40 110 55 130 70 260 100 280 115 295 130 330 170 370 200 440 265 480 300 515 340 825 440 930 550 1030 690 1700 820 1850 985 2010 1150 2165 1320 2320 1550 2480 1770 3300 2200 3500 2900 3600 2700 4000 3300 4400 4000 6400 5300 7300 7000
a Thrust Load Safety Factors: Ring, 4; groove, 2. Groove wall thrust loads are for grooves machined in cold-rolled steel with a tensile yield strength of 45,000 psi; for other shaft materials, the thrust load varies proportionally with the yield strength. Source: Industrial Retaining Rings, 2000 Series. All dimensions are in inches. Depth of groove d = (D − G)/2. Standard material: carbon spring steel (SAE 1060-1090). Thickness indicated is for unplated rings; for most plated rings with shaft sizes less than 1.000 inch, the maximum thickness will not exceed the minimum groove width (W) minus 0.0002 inch; for larger rings, the ring thickness may increase by 0.002 inch. Groove Maximum Bottom Radii: For shaft diameters less than 0.500 inch, 0.005 inch; for shaft sizes 0.500 through 1.000 inch, 0.010 inch; all larger sizes, 0.015 inch. Ring Free Diameter Tolerances: For shaft sizes 0.125 through 0.188, +0.002, −0.004; for sizes 0.219 through 0.437, +0.003, −0.005; for sizes 0.500 through 0.625, ±0.006; for sizes 0.687 through 1.000, ±0.007; for sizes 1.125 through 1.500, ±0.008; for sizes 1.750 and 2.000, ±0.010. Ring Thickness Tolerances: For shaft sizes 0.125 through 1.500, ±0.002; for sizes 1.750 and 2.000, ±0.003. Groove Diameter Tolerances: For shaft sizes 0.125 through 0.188, ±0.0015; for sizes 0.219 through 0.437, ±0.002; for sizes 0.500 through 1.000, ±0.003; for sizes 1.125 through 1.500, ±0.004; for sizes 1.750 and 2.000, ±0.005. Groove Width Tolerances: For shaft sizes 0.125 through 0.188, +0.002, −0.000; for sizes 0.219 through 1.000, +0.003, −0.000; for sizes 1.125 through 2.000, +0.004, −0.000.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
1705
;;; ;;; ;;; ;;;
Table 14. Important Dimensions of Inch Series External Retaining Rings MS16633 W
A B
GD
E
T Shaft Diameter D 0.040 0.062 0.062a 0.062b 0.094 0.094 0.110 0.125 0.140 0.140c 0.140d 0.156 0.172 0.188 0.188 0.218 0.250 0.312 0.375 0.437 0.437 0.500 0.625 0.744 0.750 0.750 0.875 0.985 1.000 1.188 1.375
Free Dia. A 0.025 0.051 0.051 0.051 0.073 0.069 0.076 0.094 0.100 0.108 0.102 0.114 0.125 0.145 0.122 0.185 0.207 0.243 0.300 0.337 0.375 0.392 0.480 0.616 0.616 0.574 0.668 0.822 0.822 1.066 1.213
Ring Thickness T 0.010 0.010 0.010 0.020 0.015 0.015 0.015 0.015 0.015 0.015 0.025 0.025 0.025 0.025 0.025 0.025 0.025 0.025 0.035 0.035 0.035 0.042 0.042 0.050 0.050 0.050 0.050 0.050 0.050 0.062 0.062
Diameter B 0.079 0.140 0.156 0.187 0.187 0.230 0.375 0.230 0.203 0.250 0.270 0.282 0.312 0.335 0.375 0.437 0.527 0.500 0.660 0.687 0.600 0.800 0.940 1.000 1.000 1.120 1.300 1.500 1.500 1.626 1.875
Diameter G 0.026 0.052 0.052 0.052 0.074 0.074 0.079 0.095 0.102 0.110 0.105 0.116 0.127 0.147 0.125 0.188 0.210 0.250 0.303 0.343 0.380 0.396 0.485 0.625 0.625 0.580 0.675 0.835 0.835 1.079 1.230
Groove Width W 0.012 0.012 0.012 0.023 0.018 0.018 0.018 0.018 0.018 0.018 0.029 0.029 0.029 0.029 0.029 0.029 0.029 0.029 0.039 0.039 0.039 0.046 0.046 0.056 0.056 0.056 0.056 0.056 0.056 0.068 0.068
Margin E 0.014 0.010 0.010 0.010 0.020 0.020 0.030 0.030 0.038 0.030 0.034 0.040 0.044 0.040 0.062 0.030 0.040 0.062 0.072 0.094 0.058 0.104 0.140 0.118 0.124 0.170 0.200 0.148 0.164 0.108 0.144
aStatic Thrust Load (lb) Ring Groove 13 7 20 7 20 7 40 7 45 20 45 20 55 40 65 45 70 60 70 45 150 55 165 70 180 90 195 90 195 135 225 75 260 115 325 225 685 315 800 485 800 290 1100 600 1370 1040 1940 1050 1960 1100 1960 1500 2200 2050 2570 1710 2620 1900 3400 1500 4100 2300
a Thrust Load Safety Factors: Ring 3; groove, 2.
Source: Industrial Retaining Rings, 1000 Series. All dimensions are in inches. Depth of groove d = (D − G)/2. Standard material: carbon spring steel (SAE 1060 –1090). Thickness indicated is for unplated rings; for most plated rings with shaft sizes less than 0.625, the maximum ring thickness will not exceed the minimum groove width (W) minus 0.0002 inch; for larger rings, the thickness may increase by 0.002 inch. Groove Maximum Bottom Radii: For shaft sizes 0.040 and 0.062, 0.003 inch; for sizes 0.094 through 0.250, 0.005 inch; for sizes 0.312 through 0.437, 0.010 inch; for sizes 0.500 through 1.375, 0.015 inch. Ring Free Diameter Tolerances: For shaft sizes 0.040 through 0.250, +0.001, −0.003; for sizes 0.312 through 0.500, +0.002, −0.004; for sizes 0.625 through 1.000, +0.003, −0.005; for sizes 1.188 and 1.375, +0.006, −0.010. Ring Thickness Tolerances: For shaft sizes 0.040 and 0.062a, ±0.001; for sizes 0.062b through 1.000, ±0.002; for sizes 1.188 and 1.375, ±0.003. Groove Diameter Tolerances: For shaft sizes 0.040 through 0.218, +0.002, −0.000; for sizes 0.250 through 1.000, +0.003, −0.000; for sizes 1.188 and 1.375, +0.005, −0.000. Grove Width Tolerances: For shaft sizes 0.040 through 0.140c, +0.002, −0.000; for sizes 0.140d through 1.000, +0.003, −0.000; for sizes 1.188 and 1.375, +0.004, −0.000.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1706
RETAINING RINGS
;;; ;;; ;;; ;;;
Table 15. Dimensions of Inch Series External Retaining Rings MS3215 W
A B
GD
E
T Ring
Groove
a Static
Shaft Diameter D
Free Dia. A
Thickness T
Diameter B
Diameter G
Width W
Margin E
0.094 0.125 0.156 0.188 0.219 0.250 0.312 0.312 0.375 0.438 0.500 0.562
0.072 0.093 0.113 0.143 0.182 0.204 0.242 0.242 0.292 0.332 0.385 0.430
0.015 0.015 0.025 0.025 0.025 0.025 0.025 0.035 0.035 0.035 0.042 0.042
0.206 0.270 0.335 0.375 0.446 0.516 0.588 0.588 0.660 0.746 0.810 0.870
0.074 0.095 0.116 0.147 0.188 0.210 0.250 0.250 0.303 0.343 0.396 0.437
0.018 0.018 0.029 0.029 0.029 0.029 0.029 0.039 0.039 0.039 0.046 0.046
0.020 0.030 0.040 0.040 0.031 0.040 0.062 0.062 0.072 0.096 0.104 0.124
Thrust Load (lb)
Ring 55 75 150 180 215 250 300 420 520 600 820 930
Groove 13 25 40 50 50 75 135 135 190 285 360 480
a Thrust Load Safety Factors: Ring, 3; groove, 2.
Source: Industrial Retaining Rings, 1200 Series. All dimensions are in inches. Depth of groove d = (D − G)/2. Standard material: carbon spring steel (SAE 1060-1090). Thickness indicated is for unplated rings; for most plated rings the maximum thickness will not exceed the minimum groove width (W) minus 0.0002 inch. Groove Maximum Bottom Radii: For shaft sizes 0.250 and smaller, 0.005 inch; for sizes 0.312 through 0.438, 0.010 inch; for sizes 0.500 and 0.562, 0.015 inch. Ring Free Diameter Tolerances: For shaft sizes 0.094 through 0.156, +0.001, −0.003; for sizes 0.188 through 0.312, ±0.003; for sizes 0.375 through 0.562, ±0.004. Ring Thickness Tolerances: For all shaft sizes, ±0.002. Groove Diameter Tolerances: For shaft sizes 0.094 through 0.188, +0.002, −0.000; for sizes 0.219 and 0.250, ±0.002; for sizes 0.312 through 0.562, ±0.003. Groove Width Tolerances: For shaft sizes 0.094 and 0.125, +0.002, − 0.000; for sizes 0.156 through 0.562, +0.003, −0.000.
The thrust load capacities shown in the tables of this section include safety factors. Usually, a safety factor of 2 is used for groove thrust load calculations when the load is applied through a retained part and groove with both having sharp corners and where the minimum side clearance exists between the retained part and the shaft or bore. Groove thrust load values in the tables of this section are based on these conditions. A safety factor of 3 is usual for calculations of thrust load capacity based on ring shear. Ideally, the corner of a retained part in contact with a retaining ring should have square corners and contact the ring as closely as possible to the shaft or housing. The tabulated thrust capacities assume that minimum clearances exist between the retained part and shaft or housing, that the groove and retained part have square corners, and that contact between the retained part and the ring occurs close to the shaft or housing. If these conditions apply, the tabulated thrust loads apply. If the application does not meet the previous conditions but the side clearances, radii, and chamfers are less than the maximum total radius or chamfer of Fig. 1, then the thrust load capacity must be reduced by dividing the tabulated value by 2. The maximum total radius is given by 0.5(b − d) and the maximum total chamfer by 0.375(b − d), where b is the radial wall thickness, and d is the groove depth. The recommended maximum total radius or chamfer specifications are intended to be used as guidelines by the designer, and to ensure the ring application will withstand published and calculated values of static thrust loads.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
1707
In analyzing the retaining ring loading conditions, a static, uniformly applied load is usually assumed. Dynamic and eccentric loads, however, are frequently encountered. Eccentric loading occurs when the load is concentrated on a small portion of the ring, such as may be caused by incorrectly machined surfaces, cocking of the retained part, and axial misalignment of parts. Conditions leading to eccentric loading on the ring should be avoided. In addition to the factors that affect the static thrust capacity, applications in which shock or impact loading occurs must be evaluated very carefully and tested in service to assess the effect of the mass and velocity of the retained part striking the ring. Vibration caused by impact loading can also cause the ring to fail if the resonant frequency of the system (retaining ring application) coincides with the resonant frequency of the retaining ring.
;;;;; ; ; ; ; ;;; ; ; ;;; ; ; ;;; ; ;;;; ;;;;;
Table 16. Dimensions of Inch Series Self-Locking External Retaining Rings A
T L
S
U
H Shaft Diameter Min. D 0.078 0.092 0.123 0.134 0.154 0.185 0.248 0.310 0.373 0.434 0.497 0.622 0.745
Max. D 0.080 0.096 0.127 0.138 0.158 0.189 0.252 0.316 0.379 0.440 0.503 0.628 0.755
Ring
Free Dia. A 0.074 0.089 0.120 0.130 0.150 0.181 0.238 0.298 0.354 0.412 0.470 0.593 0.706
Thickness T 0.025 0.025 0.025 0.025 0.025 0.035 0.035 0.042 0.042 0.050 0.050 0.062 0.062
D
;;; ;;; ;;; ;;; ;;;
Optical Groove
Diameter G
Width W
0.041 0.048 0.048 0.056 0.056 0.069 0.069
GD
E
aStatic
Margin E
The use of grooves with these shaft sizes is not suggested.
0.240 0.303 0.361 0.419 0.478 0.599 0.718
W
0.030 0.030 0.030 0.030 0.040 0.045 0.050
Thrust Load (lb)
Ring 10 10 20 20 22 25 35 50 55 60 65 85 90
Groove 0 0 0 0 0 0 90 110 185 280 390 570 845
a Thrust Load Safety Factors: Ring, 1; groove, 2.
Source: Industrial Retaining Rings, 7100 Series. All dimensions are in inches. Depth of groove d = (D − G)/2. Standard material: carbon spring steel (SAE 1060-1090). Thickness indicated is for unplated rings; for plated, phosphate coated, and stainless steel rings, the maximum ring thickness may be exceeded by 0.002 inch. Ring Free Diameter Tolerances: For shaft sizes 0.078 through 0.138, +0.002, −0.003; for sizes 0.154 through 0.252, +0.002, −0.004; for sizes 0.310 through 0.440, +0.003, −0.005; for sizes 0.497 through 0.755, +0.004, −0.006. Ring Thickness Tolerances: For shaft sizes 0.078 through 0.158, ±0.002; for sizes 0.185 through 0.503, ±0.003; for sizes 0.622 through 0.755, ±0.004. Groove Diameter Tolerances: For shaft sizes less than 0.248, grooves are not recommended; for other sizes, grooves are optional. For shaft sizes 0.248 through 0.316, +0.005, −0.0015; for sizes 0.373 through 0.628, +0.001, −0.002; for sizes 0.745 and 0.755, +0.002, −0.003. Groove Width Tolerances: For shaft sizes 0.248 through 0.379, +0.003, −0.000; for sizes 0.434 through 0.755, +0.004, −0.000.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1708
RETAINING RINGS
;;; ;;;;;; ; ;;;; ;;; ; ;;; ;;;; ;;; ;;;; ;;; ;;;;; ; ;;; ;;;;; ; ;;; ;;;
; ; ; ;;; ; ; ;;; ;;; ;;; ;;; ; ; ;;; ; ; ;
Table 17. Inch Series Internal and External Self-Locking Retaining Rings
Internal C
T
C
D
E
Housing
Ring Dimensions
Min. D
Max. D
Thick. T
Dia. D
Margin E
Static Thrust Load
0.311 0.374 0.437 0.498 0.560 0.623 0.748 0.873 0.936 0.998 1.248 1.436 1.498
0.313 0.376 0.439 0.502 0.564 0.627 0.752 0.877 0.940 1.002 1.252 1.440 1.502
0.010 0.010 0.010 0.010 0.010 0.010 0.015 0.015 0.015 0.015 0.015 0.015 0.015
0.136 0.175 0.237 0.258 0.312 0.390 0.500 0.625 0.687 0.750 0.938 1.117 1.188
0.040 0.040 0.040 0.040 0.040 0.040 0.060 0.060 0.060 0.060 0.060 0.060 0.060
80 75 70 60 50 45 75 70 70 70 60 60 60
External T
D
E
Shaft
Ring Dimensions
Min. D
Max. D
Thick. T
Dia. D
Margin E
Static Thrust Load
0.093 0.124 0.155 0.187 0.218 0.239 0.249 0.311 0.374 0.437 0.498 0.560 0.623 0.748 0.873 0.998
0.095 0.126 0.157 0.189 0.220 0.241 0.251 0.313 0.376 0.440 0.502 0.564 0.627 0.752 0.877 1.002
0.010 0.010 0.010 0.010 0.010 0.015 0.010 0.010 0.010 0.015 0.015 0.015 0.015 0.015 0.015 0.015
0.250 0.325 0.356 0.387 0.418 0.460 0.450 0.512 0.575 0.638 0.750 0.812 0.875 1.000 1.125 1.250
0.040 0.040 0.040 0.040 0.040 0.060 0.040 0.040 0.040 0.060 0.060 0.060 0.060 0.060 0.060 0.060
15 20 25 35 35 35 40 40 40 50 50 50 50 50 55 60
Source: Industrial Retaining Rings, 6000 Series (internal) and 6100 Series (external). All dimensions are in inches, thrust loads are in pounds. Thickness indicated is for unplated rings. Standard material: carbon spring steel (SAE 1060-1090). Internal Rings: Thrust loads are for rings made of standard material inserted into cold-rolled, lowcarbon housing. Ring Thickness Tolerances: For housing sizes 0.311 through 0.627, ±0.001; for sizes 0.748 through 1.502, ±0.002. Ring Diameter Tolerances: For housing sizes 0.311 through 0.439, ±0.005; for sizes 0.498 through 1.502, ±0.010. External Rings: Thrust loads are for rings made of standard material installed onto cold-rolled, low-carbon shafts. Ring Thickness Tolerances: For shaft sizes 0.093 through 0.220, ±0.001; for size 0.239, ±0.002; for sizes 0.249 through 0.376, ±0.001; for sizes 0.437 through 1.002, ±0.002. Ring Diameter Tolerances: For shaft sizes 0.093 through 0.502, ±0.005; for sizes 0.560 through 1.002, ±0.010.
Centrifugal Capacity: Proper functioning of a retaining ring depends on the ring remaining seated on the groove bottom. External rings “cling” to the groove bottom because the ring ID is slightly smaller than the diameter at the bottom of the groove. Ring speed should be kept below the allowable steady-state speed of the ring, or self-locking rings specially designed for high-speed applications should be used, otherwise an external ring can lose its grip on the groove. Applications of large retaining rings that tend to spin in their grooves when subjected to sudden acceleration or deceleration of the retained part can benefit from a ring with more “cling” (i.e., a smaller interior diameter) as long as the stress of installation is within permissible limits. Special rings are also available that lock into a hole in the bottom of the groove, thereby preventing rotation. The following equation can be used to determine the allowable steady-state speed N of an external spiral retaining ring:
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition RETAINING RINGS
N =
1709
0.466C 1 E 3 × 10 12 --------------------------------------------------R n3 ( 1 + C 1 ) ( R o3 – R i3 )
(1)
where the speed N is in revolutions per minute, C1 is the minimum ring cling to groove bottom, E is the ring radial wall, Rn is the free neutral ring radius, Ro is the free outside ring radius, and Ri is the free inside ring radius, all in inches. For external spiral rings, the minimum ring cling is given by: C1 = (C − G)/G, where C is the mean groove diameter in inches, and G is the maximum ring free ID in inches.
; ; ;; ;; ; ; ;; ;; ; ; ;; ;; ; ; ;; ;; ; ; ;; ;; ; ; ;; ;; ; ; ;; ;; ;; ;; ;;
(a)
(b)
(c)
Fig. 2. Localized Groove Yielding under Load. (a) Groove Profile before Loading; (b) Localized Yielding of Retained Part and Groove under Load; (c) Groove Profile after Loading beyond Thrust Capacity (Courtesy Spirolox Retaining Rings)
Rotation between Parts: The use of spiral-wound rings to retain a rotating part should be limited to applications with rotation in only one direction. The ring should be matched so that the rotation tends to wind the spring into the groove. External rings should be wound in the direction of rotation of the retained part but internal rings should be wound against the direction of rotation of the rotating part. Failure to observe these precautions will cause the ring to wind out of the groove. Spiral-wound rings can be obtained with either righthand (normal rotation) or left-hand (reverse rotation) wound configurations. Stamped retaining rings do not have these limitations, and may be used for applications that require rotation of the retained part, regardless of the direction of rotation. Retaining Ring Failure.—Failure of a retaining ring application can result from failure of the ring itself, failure of the groove, or both. If a ring fails, the cause is likely to be from shearing of the ring. Shear failure occurs when a ring is installed in a groove and loaded by a retained part with both the groove and the retained part having a compressive yield strength greater than 45,000 psi; or when the load is applied through a retained part and groove, both having sharp corners and line-to-line contact; or when the ring is too thin in section compared with its diameter. To examine the possibility of ring shear, the allowable thrust Ps, based on the shear strength of the ring material, is given by πDtS P s = ---------------s (2) K where Ps is in lbf, D is the shaft or housing diameter in inches, t is the ring thickness in inches, Ss is the shear strength of the ring material in lb/in.2, and K is the factor of safety. Groove Failure: The most common type of groove failure is yielding of the groove material that occurs when the thrust load, applied through the retaining ring against the corner of the groove, exceeds the compressive yield strength of the groove. This yielding of the groove results from a low compressive yield strength of the groove material, and allows the ring to tilt and come out of the groove, as illustrated in Fig. 2(b). When dishing of a ring occurs as a result of yielding in the groove material, a bending moment across the cross-section of the ring generates a tensile stress that is highest at the
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1710
RETAINING RINGS
interior diameter of the ring. If the maximum stress is greater than the yield strength of the ring material, the ring ID will grow and the ring will become permanently dished in shape. To determine the thrust load capacity of a ring based on groove deformation, the allowable angle of ring deflection must be calculated, then the thrust load based on groove yield can be determined. However, for spiral-wound rings, the thrust load PG that initiates the onset of groove deformation can be estimated from the following: πDdS P G = ----------------yK
(3)
where PG is given in lbf, D is the shaft or housing diameter in inches, d is the groove depth in inches, Sy is the yield strength of the groove material, and K is the safety factor. For stamped rings, estimate PG by multiplying Equation (3) by the fraction of the groove circumference that contacts the ring. The thrust load capacity of a particular retaining ring application can be increased by changing the workpiece material that houses the groove. Increasing the yield strength of the groove material increases the thrust load capacity of the retaining ring application. However, increasing the strength of the groove material may cause the failure mechanism to shift from groove deformation to ring shear. Therefore, use the lower of the values obtained from Equations (2) and (3) for the allowable thrust load. Groove Design and Machining: In most applications, grooves are located near the end of a shaft or housing bore to facilitate installation and removal of the rings. The groove is normally located a distance at least two to three times the groove depth from the end of the shaft or bore. If the groove is too close to the end of the shaft or bore, the groove may shear or yield. The following equation can be used to determine the minimum safe distance Y of a groove from the end of a shaft or housing: KP t Y = ------------πDS c
(4)
where K is the factor of safety, Pt is the thrust load on the groove in pounds, Sc is the shear strength of the groove material in psi, and D is the shaft or housing diameter in inches. A properly designed and machined groove is just as important in a retaining ring application as the ring itself. The walls of grooves should be perpendicular to the shaft or bore diameter; the grooves should have square corners on the top edges, and radii at the bottom, within the tolerances specified by the manufacturers, as shown in Fig. 1 (page 1684). Test data indicate that the ultimate thrust capacity for both static and dynamic loading conditions is greatly affected if these groove requirements are not met. For spiral-wound rings, the maximum bottom groove radius is 0.005 inch for rings up to 1.000 inch free diameter and 0.010 inch for larger rings, internal or external. For stamped rings, the maximum bottom groove radius varies with ring size and style. Table 18. Retaining Ring Standards MIL-R-21248B
Military MS-16633 Open-type external uniform cross-section MS-16634 Open-type external uniform cross-section cylindrically MS-3215 Open-type external tapered cross-section MS-16632 Crescent-type external MS-16625 Internal MS-16629 Internal cylindrically bowed MS-16624 Closed-type external tapered cross-section
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Machinery's Handbook 27th Edition RETAINING RINGS
1711
Table 18. Retaining Ring Standards (Continued) Military MS-16628 Closed-type external tapered cross-section cylindrically bowed
MIL-R-21248B
MS-16627 Internal inverted MS-16626 Closed-type external tapered cross-section MS-90707 Self-locking external tapered cross-section MIL-R-27426
AS 3215 AS 3216 AS 3217 AS 3218 AS 3219
B27.6-1972, R1983 B27.7-1977, R1983 B27.8M-1977, R1983
MA4016 MA4017 MA4020 MA4021 MA4029 MA4030 MA4035 MA4036
DIN 471, 472, 6799, 984, 5417, 7993 LN 471, 472, 6799
MS-3217 External heavy-duty tapered cross-section Uniform cross-section spiral retaining rings, Type 1-External, Type 2-Internal Acrospace Standard Ring, Retaining—Spiral, Internal, Heavy Duty, Stainless Steel Ring, Retaining—Spiral, External, Heavy Duty, Stainless Steel Ring, Retaining—Spiral, Internal, Light Duty, Stainless Steel Ring, Retaining—Spiral, External, Light Duty, Stainless Steel Ring, Wound, Dimensional and Acceptance Standard for Spiral Wound Retaining Rings ANSI General Purpose Uniform Cross-Section Spiral Retaining Rings General Purpose Tapered and Reduced Cross-Section Retaining Rings (Metric) General Purpose Metric Tapered and Reduced CrossSection Retaining Rings Type 3DM1—Heavy Duty External Rings Type 3EM1—Reinforced “E” Rings Type 3FM1—“C” Type Rings ANSI/SAE Ring, Retaining—External Spiral Wound, Heavy and Medium Duty, Crescent, Metric Ring, Retaining—External Spiral Wound, Heavy and Medium Duty, Crescent, Metric Ring, Retaining—External Tapered, Type 1, Class 2, AMS 5520, Metric Ring, Retaining—Internal Tapered, Type 1, Class 1, AMS 5520, Metric Ring, Retaining—Internal, Beveled, Tapered, Type 2, Class 1, AMS 5520, Metric Ring, Retaining—External, Reinforced E-Ring, Type 1, Class 3, AMS 5520, Metric Rings, Retaining—Spiral Wound, Uniform Section, Corrosion Resistant, Procurement Specification for, Metric Ring, Retaining—Tapered Width, Uniform Thickness, Corrosion Resistant, Procurement Specification for, Metric DIN Standards for normal and heavy type, internal and external retaining rings and retaining washers Aerospace standards for internal and external retaining rings
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1712
WING NUTS, WING SCREWS AND THUMB SCREWS
WING NUTS, WING SCREWS, AND THUMB SCREWS Wing Nuts.—A wing nut is a nut having wings designed for manual turning without driver or wrench. As covered by ANSI B18.17-1968 (R1983) wing nuts are classified first, by type on the basis of the method of manufacture; and second, by style on the basis of design characteristics. They consist of: Type A: Type A wing nuts are cold forged or cold formed solid nuts having wings of moderate height. In some sizes they are produced in regular, light, and heavy series to best suit the requirements of specific applications. Dimensions are given in Table 1. Table 1. American National Standard Type A Wing Nuts ANSI B18.17-1968, R1983
Nominal Size or Basic Major Diameter of Threada
Thds. per Inch
3 4
(0.0990) (0.1120)
48, 56 40, 38
5
(0.1250)
40, 44
6
(0.1380)
32, 40
8
(0.1640)
32, 36
10
(0.1900)
24, 32
12
(0.2160)
24, 28
1⁄ 4
(0.2500)
20, 28
5⁄ 16
(0.3125)
18, 24
Seriesb
Nut Blank Size (Ref) AA AA AA A AA A A B A B B C B C D C D E D E E F E F F
A
B
C
D
E
G
Wing Spread
Wing Height
Wing Thick.
Between Wings
Boss Dia.
Boss Height
Max Min Max Min Max Min Max Min Max Min Max Min
3⁄ 8
(0.3750)
16, 24
7⁄ 16
(0.4375)
14, 20
1⁄ 2
(0.5000)
13, 20
9⁄ 16 5⁄ 8 3⁄ 4
(0.5625)
12, 18
Hvy. Hvy. Lgt. Hvy. Lgt. Hvy. Lgt. Hvy. Lgt. Hvy. Lgt. Hvy. Lgt. Reg. Hvy. Lgt. Reg. Hvy. Lgt. Reg. Lgt. Hvy. Lgt. Hvy. Hvy.
0.72 0.72 0.72 0.91 0.72 0.91 0.91 1.10 0.91 1.10 1.10 1.25 1.10 1.25 1.44 1.25 1.44 1.94 1.44 1.94 1.94 2.76 1.94 2.76 2.76
0.59 0.59 0.59 0.78 0.59 0.78 0.78 0.97 0.78 0.97 0.97 1.12 0.97 1.12 1.31 1.12 1.31 1.81 1.31 1.81 1.81 2.62 1.81 2.62 2.62
0.41 0.41 0.41 0.47 0.41 0.47 0.47 0.57 0.47 0.57 0.57 0.66 0.57 0.66 0.79 0.66 0.79 1.00 0.79 1.00 1.00 1.44 1.00 1.44 1.44
0.28 0.28 0.28 0.34 0.28 0.34 0.34 0.43 0.34 0.43 0.43 0.53 0.43 0.53 0.65 0.53 0.65 0.87 0.65 0.87 0.87 1.31 0.87 1.31 1.31
0.11 0.11 0.11 0.14 0.11 0.14 0.14 0.18 0.14 0.18 0.18 0.21 0.18 0.21 0.24 0.21 0.24 0.33 0.24 0.33 0.33 0.40 0.33 0.40 0.40
0.07 0.07 0.07 0.10 0.07 0.10 0.10 0.14 0.10 0.14 0.14 0.17 0.14 0.17 0.20 0.17 0.20 0.26 0.20 0.26 0.26 0.34 0.26 0.34 0.34
0.21 0.21 0.21 0.27 0.21 0.27 0.27 0.33 0.27 0.33 0.33 0.39 0.39 0.39 0.48 0.39 0.48 0.65 0.48 0.65 0.65 0.90 0.65 0.90 0.90
0.17 0.17 0.17 0.22 0.17 0.22 0.22 0.26 0.22 0.26 0.26 0.32 0.26 0.32 0.42 0.32 0.42 0.54 0.42 0.54 0.54 0.80 0.54 0.80 0.80
0.33 0.33 0.33 0.43 0.33 0.43 0.43 0.50 0.43 0.50 0.50 0.58 0.50 0.58 0.70 0.58 0.70 0.93 0.70 0.93 0.93 1.19 0.93 1.19 1.19
0.29 0.29 0.29 0.39 0.29 0.39 0.39 0.45 0.39 0.45 0.45 0.51 0.45 0.51 0.64 0.51 0.64 0.86 0.64 0.86 0.86 1.13 0.86 1.13 1.13
0.14 0.14 0.14 0.18 0.14 0.18 0.18 0.22 0.18 0.22 0.22 0.25 0.22 0.25 0.30 0.25 0.30 0.39 0.30 0.39 0.39 0.55 0.39 0.55 0.55
(0.6250)
11, 18
Hvy.
F
2.76 2.62 1.44 1.31 0.40 0.34 0.90 0.80 1.19 1.13 0.55 0.51
(0.7500)
10, 16
Hvy.
F
2.76 2.62 1.44 1.31 0.40 0.34 0.90 0.80 1.19 1.13 0.55 0.51
a Where specifying nominal size in decimals, zeros in the fourth decimal place are omitted. b Lgt. = Light; Hvy. = Heavy; Reg. = Regular. Sizes shown in bold face are preferred.
All dimensions in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
0.10 0.10 0.10 0.14 0.10 0.14 0.14 0.17 0.14 0.17 0.17 0.20 0.17 0.20 0.26 0.20 0.26 0.35 0.26 0.35 0.35 0.51 0.35 0.51 0.51
Machinery's Handbook 27th Edition WING NUTS, WING SCREWS AND THUMB SCREWS
1713
Type B: Type B wing nuts are hot forged solid nuts available in two wing styles: Style 1, having wings of moderate height; and Style 2, having high wings. Dimensions are given in Table 2. Table 2. American National Standard Type B Wing Nuts ANSI B18.17-1968, R1983
STYLE 1 Nominal Size or Basic Major Diameter of Threada
Thds. per Inch
STYLE 2
A
B
C
D
E
G
Wing Spread
Wing Height
Wing Thick.
Between Wings
Boss Dia.
Boss Height
Max
Min
Max
Min
Max
Min
Max
Min
Max
Min
Max
Min
Type B, Style 1 5 (0.1250)
40
0.78
0.72
0.36
0.30
0.13
0.10
0.28
0.22
0.31
0.28
0.22
0.16
10 (0.1900)
24
0.97
0.91
0.45
0.39
0.15
0.12
0.34
0.28
0.39
0.36
0.28
0.22 0.28
1⁄ (0.2500) 4
20
1.16
1.09
0.56
0.50
0.17
0.14
0.41
0.34
0.47
0.44
0.34
5⁄ (0.3125) 16
18
1.44
1.38
0.67
0.61
0.18
0.15
0.50
0.44
0.55
0.52
0.41
0.34
3⁄ (0.3750) 8
16
1.72
1.66
0.80
0.73
0.20
0.17
0.59
0.53
0.63
0.60
0.47
0.41
7⁄ (0.4375) 16
14
2.00
1.94
0.91
0.84
0.21
0.18
0.69
0.62
0.71
0.68
0.53
0.47
1⁄ (0.5000) 2
13
2.31
2.22
1.06
0.94
0.23
0.20
0.78
0.69
0.79
0.76
0.62
0.50
9⁄ (0.5625) 16
12
2.59
2.47
1.17
1.05
0.25
0.21
0.88
0.78
0.88
0.84
0.69
0.56
5⁄ (0.6250) 8
11
2.84
2.72
1.31
1.19
0.27
0.23
0.94
0.84
0.96
0.92
0.75
0.62
3⁄ (0.7500) 4
10
3.31
3.19
1.52
1.39
0.29
0.25
1.10
1.00
1.12
1.08
0.88
0.75
Type B, Style 2 5 (0.1250)
40
0.81
0.75
0.62
0.56
0.12
0.09
0.28
0.22
0.31
0.28
0.22
0.16
10 (0.1900)
24
1.01
0.95
0.78
0.72
0.14
0.11
0.35
0.29
0.39
0.36
0.28
0.22 0.28
1⁄ (0.2500) 4
20
1.22
1.16
0.94
0.88
0.16
0.13
0.41
0.35
0.47
0.44
0.34
5⁄ (0.3125) 16
18
1.43
1.37
1.09
1.03
0.17
0.14
0.48
0.42
0.55
0.52
0.41
0.34
3⁄ (0.3750) 8
16
1.63
1.57
1.25
1.19
0.18
0.15
0.55
0.49
0.63
0.60
0.47
0.41
7⁄ (0.4375) 16
14
1.90
1.84
1.42.
1.36
0.19
0.16
0.62
0.56
0.71
0.68
0.53
0.47
1⁄ (0.5000) 2
13
2.13
2.04
1.58
1.45
0.20
0.17
0.69
0.60
0.79
0.76
0.62
0.50
9⁄ (0.5625) 16
12
2.40
2.28
1.75
1.62
0.22
0.18
0.76
0.67
0.88
0.84
0.69
0.56
5⁄ (0.6250) 8
11
2.60
2.48
1.91
1.78
0.23
0.19
0.83
0.74
0.96
0.92
0.75
0.62
3⁄ (0.7500) 4
10
3.02
2.90
2.22
2.09
0.24
0.20
0.97
0.88
1.12
1.08
0.88
0.75
a Where specifying nominal size in decimals, zeros in the fourth decimal place are omitted.
All dimensions in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1714
WING NUTS, WING SCREWS AND THUMB SCREWS
Table 3. American National Standard Type C Wing Nuts ANSI B18.17-1968, R1983
STYLE 1 Nominal Size or Basic Major Diameter of Threada
Thds. per Inch
4 (0.1120) 5 (0.1250)
40 40
6 (0.1380)
32
Serie s
STYLE 2
STYLE 3
A B C D E F G Nut Blan Wing Wing Wing Between Boss Boss Boss k Spread Height Thick. Wings Dia. Dia. Height Size (Ref) Max Min Max Min Max Min Max Min Max Min Max Min Max Min Type C, Style 1
8 (0.1640) 32 10 (0.1900) 24, 32
Reg. Reg. Reg. Hvy. Reg. Reg. Reg. Hvy.
AA AA AA A A A A B
0.66 0.66 0.66 0.85 0.85 0.85 0.85 1.08
0.64 0.64 0.64 0.83 0.83 0.83 0.83 1.05
0.36 0.36 0.36 0.43 0.43 0.43 0.43 0.57
0.35 0.35 0.35 0.42 0.42 0.42 0.42 0.53
0.11 0.11 0.11 0.14 0.14 0.14 0.14 0.16
0.09 0.09 0.09 0.12 0.12 0.12 0.12 0.14
0.18 0.18 0.18 0.29 0.29 0.29 0.29 0.32
0.16 0.16 0.16 0.27 0.27 0.27 0.27 0.30
0.27 0.27 0.27 0.38 0.38 0.38 0.38 0.44
0.25 0.25 0.25 0.36 0.36 0.36 0.36 0.42
0.32 0.32 0.32 0.41 0.41 0.41 0.41 0.48
0.30 0.30 0.30 0.40 0.40 0.40 0.40 0.46
0.16 0.16 0.16 0.20 0.20 0.20 0.20 0.23
0.14 0.14 0.14 0.18 0.18 0.18 0.18 0.21
12 (0.2160)
24
1⁄ (0.2500) 4
20, 28
Reg.
B
5⁄ (0.3125) 16
18, 24
Reg.
C
1.23 1.20 0.64 0.62 0.20 0.18 0.39 0.35 0.50 0.49 0.57 0.55 0.26 0.24
3⁄ (0.3750) 8
16, 24
Reg.
D
1.45 1.42 0.74 0.72 0.23 0.21 0.46 0.42 0.62 0.60 0.69 0.67 0.29 0.27
7⁄ (0.4375) 16
14, 20
1⁄ (0.5000) 2
13, 20
Reg. Hvy. Reg. Hvy.
E EH E EH
1.89 1.89 1.89 1.89
1.86 1.86 1.86 1.86
… … … … …
… … … … …
0.82 0.82 1.01 1.01 1.20
0.80 0.80 0.99 0.99 1.18
5 (0.1250) 40 6 (0.1380) 32 8 (0.1640) 32 10 (0.1900) 24, 32 12 (0.2160) 24
1.08 1.05 0.57 0.53 0.16 0.14 0.32 0.30 0.44 0.42 0.48 0.46 0.23 0.21
0.91 0.93 0.91 0.93
0.90 0.29 0.28 0.91 0.34 0.33 0.90 0.29 0.28 0.91 0.34 0.33 Type C, Style 2 0.25 0.23 0.09 0.08 0.25 0.23 0.09 0.08 0.28 0.27 0.11 0.09 0.28 0.27 0.11 0.09 0.32 0.31 0.12 0.11
0.67 0.63 0.67 0.63
0.65 0.62 0.65 0.62
0.75 0.81 0.75 0.81
0.73 0.79 0.73 0.79
0.83 0.89 0.83 0.89
0.82 0.87 0.82 0.87
0.38 0.42 0.38 0.42
0.37 0.40 0.37 0.40
0.21 0.21 0.29 0.29 0.38
0.19 0.19 0.28 0.28 0.37
0.26 0.26 0.36 0.36 0.44
0.24 0.24 0.34 0.34 0.43
… … … … …
… … … … …
0.17 0.17 0.19 0.19 0.22
0.15 0.15 0.18 0.18 0.20
1⁄ (0.2500) 4
20
…
…
1.20 1.18 0.32 0.31 0.12 0.11 0.38 0.37 0.44 0.43
…
…
0.22 0.20
5⁄ (0.3125) 16
18
…
…
1.51 1.49 0.36 0.35 0.14 0.12 0.44 0.43 0.51 0.49
…
…
0.24 0.23
3⁄ (0.3750) 8
16
5 (0.1250) 40 6 (0.1380) 32 8 (0.1640) 32 10 (0.1900) 24, 32 12 (0.2160) 24
…
…
1.89 1.86 0.58 0.55 0.20 0.17 0.44 0.43 0.63 0.62
… … … … …
… … … … …
0.92 0.92 0.92 1.14 1.14
0.89 0.89 0.89 1.12 1.12
0.70 0.70 0.70 0.85 0.85
Type C, Style 3 0.67 0.16 0.15 0.67 0.16 0.15 0.67 0.16 0.15 0.83 0.19 0.17 0.83 0.19 0.17
0.26 0.26 0.26 0.32 0.32
0.24 0.24 0.24 0.30 0.30
0.38 0.38 0.38 0.44 0.44
0.36 0.36 0.36 0.42 0.42
…
…
0.37 0.35
… … … … …
… … … … …
0.25 0.25 0.25 0.29 0.29
0.24 0.24 0.24 0.27 0.27
1⁄ (0.2500) 4
20
…
…
1.14 1.12 0.85 0.83 0.19 0.17 0.32 0.30 0.44 0.42
…
…
0.29 0.27
5⁄ (0.3125) 16
18
…
…
1.29 1.27 1.04 1.02 0.23 0.22 0.39 0.36 0.50 0.49
…
…
0.35 0.34
3⁄ (0.3750) 8
16
…
…
1.51 1.49 1.20 1.18 0.27 0.25 0.45 0.42 0.62 0.60
…
…
0.43 0.42
a Where specifying nominal size in decimals, zeros in the fourth decimal place are omitted.
All dimensions in inches. Sizes shown in bold face are preferred.
Type C: Type C wing nuts are die cast solid nuts and are available in three wing styles: Style 1, having wings of moderate height; Style 2, having low wings; and Style 3, having high wings. In some sizes, the Style 1 nuts are produced in regular, light, and heavy series to best suit the requirements of specific applications. Dimensions are given in Table 3.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition WING NUTS, WING SCREWS AND THUMB SCREWS
1715
Table 4. American National Standard Type D Wing Nuts ANSI B18.17-1968, R1983
STYLE 1
STYLE 2 (LOW WING)
Nominal Size or Basic Major Diameter of Threada
Thds. per Inch
Seriesb
8 (0.1640) 10 (0.1900) 12 (0.2160) 1⁄ (0.2500) 4
32, 36 24, 32 24, 28 20, 28
… … … …
5⁄ (0.3125) 16 3⁄ (0.3750) 8
18, 24 16, 24
5 (0.1250) 6 (0.1380) 8 (0.1640)
40 32 32
10 (0.1900)
24, 32
12 (0.2160) 1⁄ (0.2500) 4
24 20
10 (0.1900)
24, 32
12 (0.2160)
24
1⁄ (0.2500) 4
20
5⁄ (0.3125) 16
18
A Wing Spread
E Boss Dia.
Max Min Max Min Max Min Type D, Style 1
Min
Max Min
0.78 0.91 1.09 1.11
0.14 0.17 0.17 0.21
0.25 0.34 0.34 0.34
0.41 0.53 0.53 0.62
0.35 0.47 0.47 0.56
…
1.30 1.24 0.59 0.53 0.30 0.26
0.46
0.73 0.67
…
1.41 1.34 0.67 0.61 0.34 0.30
0.69
0.83 0.77
0.30 0.30 0.30 0.32 0.60 0.60 0.60
0.40 0.40 0.40 0.53 0.61 0.61 0.61
0.47 0.50 0.59 0.59 0.70 0.66 0.70 0.66
0.65 0.75 0.73 0.73 1.03 1.03 1.03 1.03
0.40 0.47 0.47 0.50
0.34 0.41 0.41 0.44
C Wing Thick.
STYLE 3 (LARGE BASE)
D Between Wings
0.72 0.85 1.03 1.05
B Wing Height
0.18 0.21 0.21 0.25
Reg. Reg. Reg. Reg. Hvy. Reg. Reg.
1.03 1.03 1.03 1.40 1.21 1.21 1.21
0.97 0.97 0.97 1.34 1.16 1.16 1.16
Type D, Style 2 0.25 0.19 0.19 0.13 0.25 0.19 0.19 0.13 0.25 0.19 0.19 0.13 0.34 0.28 0.25 0.18 0.28 0.26 0.31 0.25 0.28 0.26 0.31 0.25 0.28 0.26 0.31 0.25
Lgt. Reg. Reg. Lgt. Reg. Hvy. Reg. Hvy.
1.31 1.40 1.28 1.28 1.78 1.47 1.78 1.47
1.25 1.34 1.22 1.22 1.72 1.40 1.72 1.40
Type D, Style 3 0.48 0.42 0.29 0.23 0.53 0.47 0.25 0.19 0.40 0.34 0.23 0.17 0.40 0.34 0.23 0.17 0.66 0.60 0.31 0.25 0.50 0.44 0.37 0.31 0.66 0.60 0.31 0.25 0.50 0.44 0.37 0.31
G Boss Hgt.
H Wall Hgt.
T Stock Thick.
Min
Min
Max Min
0.08 0.10 0.10 0.11
0.12 0.12 0.12 0.12
0.04 0.04 0.05 0.05
0.14
0.18
0.06 0.05
0.16
0.18
0.06 0.05
0.34 0.34 0.34 0.47 0.55 0.55 0.55
0.07 0.08 0.08 0.09 0.09 0.11 0.11
0.09 0.09 0.09 0.16 0.13 0.13 0.13
0.04 0.04 0.04 0.05 0.05 0.05 0.05
0.03 0.03 0.03 0.04 0.04 0.04 0.04
0.59 0.69 0.67 0.67 0.97 0.97 0.97 0.97
0.08 0.08 0.11 0.11 0.14 0.14 0.14 0.14
0.12 0.14 0.12 0.12 0.17 0.14 0.17 0.14
0.04 0.04 0.04 0.04 0.06 0.08 0.06 0.08
0.03 0.03 0.03 0.03 0.04 0.06 0.04 0.06
0.03 0.03 0.04 0.04
a Where specifying nominal size in decimals, zeros in the fourth decimal place are omitted. b Lgt. = Light; Hvy. = Heavy; Reg. = Regular.
All dimensions in inches.
Type D: Type D wing nuts are stamped sheet metal nuts and are available in three styles: Style 1, having wings of moderate height; Style 2, having low wings; and Style 3, having wings of moderate height and a larger bearing surface. In some sizes, Styles 2 and 3 are produced in regular, light, and heavy series to best suit the requirements of specific applications. Dimensions are given in Table 4. Specification of Wing Nuts.—When specifying wing nuts, the following data should be included in the designation and should appear in the following sequence: nominal size (number, fraction or decimal equivalent), threads per inch, type, style and/or series, material, and finish. Examples: 10—32 Type A Wing Nut, Regular Series, Steel, Zinc Plated. 0.250—20 Type C Wing Nut, Style 1, Zinc Alloy, Plain. Threads for Wing Nuts.—Threads are in conformance with the ANSI Standard Unified Thread, Class 2B for all types of wing nuts except type D which have a modified Class 2B thread. Because of the method of manufacture, the minor diameter of the thread in type D
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1716
WING NUTS, WING SCREWS AND THUMB SCREWS
nuts may be somewhat larger than the Unified Thread Class 2B maximum but shall in no case exceed the minimum pitch diameter. Materials and Finish for Wing Nuts.—Types A, B, and D wing nuts are normally supplied as specified by the user in carbon steel, brass or corrosion resistant steel of good quality and adaptable to the manufacturing process. Type C wing nuts are made from die cast zinc alloy. Unless otherwise specified, wing nuts are supplied with a plain (unplated or uncoated) finish. Wing Screws.—A wing screw is a screw having a wing-shaped head designed for manual turning without a driver or wrench. As covered by ANSI B18.17-1968 (R1983) wing screws are classified first, by type on the basis of the method of manufacture, and second, by style on the basis of design characteristics. They consist of the following: Type A: Type A wing screws are of two-piece construction having cold formed or cold forged wing portions of moderate height. In some sizes they are produced in regular, light, and heavy series to best suit the requirements of specific applications. Dimensions are given in Table 5. Type B: Type B wing screws are of hot forged one-piece construction available in two wing styles: Style 1, having wings of moderate height; and Style 2, having high wings. Dimensions are given in Table 5. Type C: Type C wing screws are available in two styles: Style 1, of a one-piece die cast construction having wings of moderate height; and Style 2, of a two-piece construction having a die cast wing portion of moderate height. Dimensions are given in Table 6. Type D: Type D wing screws are of two-piece welded construction having stamped sheet metal wing portions of moderate height. Dimensions are given in Table 6. Materials for Wing Screws and Thumb Screws: Type A wing screws are normally supplied in carbon steel with the shank portion case hardened. When so specified, they also may be made from corrosion resistant steel, brass or other materials as agreed upon by the manufacturer and user. Type B wing screws are normally made from carbon steel but also may be made from corrosion resistant steel, brass or other materials. Type C, Style 1, wing screws are supplied only in die cast zinc alloy. Type C, Style 2, wing screws have the wing portion made from die cast zinc alloy with the shank portion normally made from carbon steel. Where so specified, the shank portion may be made from corrosion resistant steel, brass or other materials as agreed upon by the manufacturer and user. Type D wing screws are normally supplied in carbon steel but also may be made from corrosion resistant steel, brass or other materials. Thumb screws of all types are normally made from a good commercial quality of carbon steel having a maximum ultimate tensile strength of 48,000 psi. Where so specified, carbon steel thumb screws are case hardened. They are also made from corrosion resistant steel, brass, and other materials as agreed upon by the manufacturer and user. Unless otherwise specified, wing screws and thumb screws are supplied with a plain (unplated or uncoated) finish. Thumb Screws.—A thumb screw is a screw having a flattened head designed for manual turning without a driver or wrench. As covered by ANSI B18.17-1968 (R1983) thumb screws are classified by type on the basis of design characteristics. They consist of the following: Type A: Type A thumb screws are forged one-piece screws having a shoulder under the head and are available in two series: regular and heavy. Dimensions are given in Table 7. Type B: Type B thumb screws are forged one-piece screws without a shoulder and are available in two series: regular and heavy. Dimensions are given in Table 7.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition WING NUTS, WING SCREWS AND THUMB SCREWS
1717
Table 5. American National Standard Types A and B Wing Screws ANSI B18.17-1968, R1983
TYPE A Nominal Size or Basic Major Diametera
Thds. per Inch
Seriesb
TYPE B Head Blank size (Ref)
A
B
C
E
G
L
Wing Spread
Wing Height
Wing Thick.
Boss Dia.
Boss Height.
Practical Screw Lengths
Max Min Max Min Max Min Max Min Max Min
Max
Min
Type A 4 (0.1120)
40
6 (0.1380)
32
8 (0.1640)
32
10 (0.1900) 12 (0.2160)
1⁄ (0.2500) 4
5⁄ (0.3125) 16
3⁄ (0.3750) 8
7⁄ (0.4375) 16
24, 32 24
20
18
16
14
1⁄ (0.5000) 2
13
5⁄ (0.6250) 8
11
Hvy.
AA
0.72 0.59 0.41 0.28 0.11 0.07 0.33 0.29 0.14 0.10
Lgt.
AA
0.72 0.59 0.41 0.28 0.11 0.07 0.33 0.29 0.14 0.10
Hvy.
A
0.91 0.78 0.47 0.34 0.14 0.10 0.43 0.39 0.18 0.14
Lgt.
A
0.91 0.78 0.47 0.34 0.14 0.10 0.43 0.39 0.18 0.14
Hvy.
B
1.10 0.97 0.57 0.43 0.18 0.14 0.50 0.45 0.22 0.17
Lgt.
A
0.91 0.78 0.47 0.34 0.14 0.10 0.43 0.39 0.18 0.14
Hvy.
B
1.10 0.97 0.57 0.43 0.18 0.14 0.50 0.45 0.22 0.17
Lgt.
B
1.10 0.97 0.57 0.43 0.18 0.14 0.50 0.45 0.22 0.17
0.75 0.25 } 0.75 0.25 } 0.75 0.38 } 1.00 0.38 } 1.00 0.38
Hvy.
C
1.25 1.12 0.66 0.53 0.21 0.17 0.58 0.51 0.25 0.20
Lgt.
B
1.10 0.97 0.57 0.43 0.18 0.14 0.50 0.45 0.22 0.17
C
1.25 1.12 0.66 0.53 0.21 0.17 0.58 0.51 0.25 0.20 } 1.50 0.50
Reg. Hvy.
D
1.44 1.31 0.79 0.65 0.24 0.20 0.70 0.64 0.30 0.26
Lgt.
C
1.25 1.12 0.66 0.53 0.21 0.17 0.58 0.51 0.25 0.20 1.44 1.31 0.79 0.65 0.24 0.20 0.70 0.64 0.30 0.26 } 1.50 0.50
Reg.
D
Hvy.
E
1.94 1.81 1.00 0.87 0.33 0.26 0.93 0.86 0.39 0.35
Lgt.
D
1.44 1.31 0.79 0.65 0.24 0.20 0.70 0.64 0.30 0.26 1.94 1.81 1.00 0.87 0.33 0.26 0.93 0.86 0.39 0.35 } 2.00 0.75
Reg.
E
Hvy.
F
2.76 2.62 1.44 1.31 0.40 0.34 1.19 1.13 0.55 0.51
Lgt.
E
1.94 1.81 1.00 0.87 0.33 0.26 0.93 0.86 0.39 0.35
Hvy.
F
2.76 2.62 1.44 1.31 0.40 0.34 1.19 1.13 0.55 0.51
Lgt.
E
1.94 1.81 1.00 0.87 0.33 0.26 0.93 0.86 0.39 0.35
Hvy.
F
2.76 2.62 1.44 1.31 0.40 0.34 1.19 1.13 0.55 0.51
Hvy.
F
2.76 2.62 1.44 1.31 0.40 0.34 1.19 1.13 0.55 0.51
} 4.00 1.00 } 4.00 1.00 4.00 1.25
Type B, Style 1 10 (0.1900)
24
…
…
0.97 0.91 0.45 0.39 0.15 0.12 0.39 0.36 0.28 0.22
1⁄ (0.2500) 4
20
…
…
1.16 1.09 0.56 0.50 0.17 0.14 0.47 0.44 0.34 0.28
3.00 0.50
5⁄ (0.3125) 16
18
…
…
1.44 1.38 0.67 0.61 0.18 0.15 0.55 0.52 0.41 0.34
3.00 0.50
2.00 0.50
3⁄ (0.3750) 8
16
…
…
1.72 1.66 0.80 0.73 0.20 0.17 0.63 0.60 0.47 0.41
4.00 0.50
7⁄ (0.4375) 16
14
…
…
2.00 1.94 0.91 0.84 0.21 0.18 0.71 0.68 0.53 0.47
3.00 1.00
1⁄ (0.5000) 2
13
…
…
2.31 2.22 1.06 0.94 0.23 0.20 0.79 0.76 0.62 0.50
3.00 1.00
5⁄ (0.6250) 8
11
…
…
2.84 2.72 1.31 1.19 0.27 0.23 0.96 0.92 0.75 0.62
2.50 1.00
Type B, Style 2 10 (0.1900)
24
…
…
1.01 0.95 0.78 0.72 0.14 0.11 0.39 0.36 0.28 0.22
1⁄ (0.2500) 4
20
…
…
1.22 1.16 0.94 0.88 0.16 0.13 0.47 0.44 0.34 0.28
2.00 0.50
5⁄ (0.3125) 16
18
…
…
1.43 1.37 1.09 1.03 0.17 0.14 0.55 0.52 0.41 0.34
2.00 0.50
3⁄ (0.3750) 8
16
…
…
1.63 1.57 1.25 1.19 0.18 0.15 0.63 0.60 0.47 0.41
2.00 0.50
All dimensions in inches. Sizes shown in bold face are preferred. 1Plain point, unless alternate point from styles shown in Table 8 is specified by user. a Where specifyin nominal size in decimals, zeros in the fourth decimal place are omitted. b Hvy. = Heavy; Lgt. = Light; Reg. = Regular.
Copyright 2004, Industrial Press, Inc., New York, NY
1.25 0.50
Machinery's Handbook 27th Edition 1718
WING NUTS, WING SCREWS AND THUMB SCREWS Table 6. American National Standard Types C and D Wing Screws ANSI B18.17-1968, R1983
TYPE C
TYPE D A
B
Thds. per Inch
Wing Spread Max Min
Wing Height Max Min
6 (0.1380) 8 (0.1640) 10 (0.1900) 1⁄ (0.2500) 4
32 32 24, 32 20
0.85 0.85 0.85 1.08
0.83 0.83 0.83 1.05
0.45 0.45 0.45 0.56
0.43 0.43 0.43 0.53
0.15 0.15 0.15 0.17
0.12 0.12 0.12 0.14
… … … …
5⁄ (0.3125) 16 3⁄ (0.3750) 8
18
1.23
1.20
0.64
0.62
0.22
0.19
…
16
1.45
1.42
0.74
0.72
6 (0.1380) 8 (0.1640) 10 (0.1900) 1⁄ (0.2500) 4
32 32 24, 32 20
0.85 0.85 0.85 1.08
0.83 0.83 0.83 1.05
0.43 0.43 0.43 0.57
0.42 0.42 0.42 0.53
5⁄ (0.3125) 16 3⁄ (0.3750) 8 7⁄ (0.4375) 16 1⁄ (0.5000) 2
18
1.23
1.20
0.64
0.62
Nominal Size or Basic Screw Diametera
C
E
F
G
Boss Dia. Max Min
Height Max Min
L Practical Screw Lengths Max Min
… … … …
0.41 0.41 0.41 0.46
0.39 0.39 0.39 0.44
0.12 0.12 0.12 0.12
0.07 0.07 0.07 0.07
0.75 1.00 1.25 1.50
0.25 0.38 0.38 0.50
…
0.51
0.49
0.14
0.10
1.50
0.50
…
0.63
0.62
0.15
0.12
1.50
0.50
0.36 0.36 0.36 0.42
0.41 0.41 0.41 0.48
0.40 0.40 0.40 0.46
0.20 0.20 0.20 0.23
0.18 0.18 0.18 0.21
1.00 1.00 2.00 2.50
0.25 0.38 0.38 0.50
0.49
0.57
0.55
0.26
0.24
3.00
0.50
Wing Boss Thick. Dia. Max Min Max Min Type C, Style 1
0.24 0.21 … Type C, Style 2 0.14 0.12 0.38 0.14 0.12 0.38 0.14 0.12 0.38 0.16 0.14 0.44 0.20
0.18
0.50
16
1.45
1.42
0.74
0.72
0.23
0.21
0.62
0.60
0.69
0.67
0.29
0.27
3.00
0.75
14
1.89
1.86
0.91
0.90
0.29
0.28
0.75
0.73
0.83
0.82
0.38
0.37
4.00
1.00
13
1.89
1.86
0.91
0.90
0.75
0.73
0.83
0.82
0.38
0.37
4.00
1.00
6 (0.1380) 8 (0.1640) 10 (0.1900) 12 (0.2160) 1⁄ (0.2500) 4
32 32 24 24 20
0.78 0.78 0.90 1.09 1.09
0.72 0.72 0.84 1.03 1.03
0.40 0.40 0.46 0.46 0.46
0.34 0.34 0.40 0.40 0.40
0.29 0.28 Type D 0.18 0.12 0.18 0.12 0.21 0.15 0.26 0.20 0.26 0.20
0.35 0.35 0.35 0.44 0.47
0.31 0.31 0.31 0.39 0.43
0.40 0.40 0.53 0.61 0.61
0.34 0.34 0.47 0.55 0.55
0.21 0.21 0.22 0.24 0.24
0.14 0.14 0.16 0.18 0.18
0.75 0.75 1.00 1.00 1.50
0.25 0.38 0.38 0.38 0.50
5⁄ (0.3125) 16 3⁄ (0.3750) 8
18
1.31
1.25
0.62
0.56
0.29
0.57
0.53
0.68
0.62
0.29
0.23
1.50
0.50
16 1.31 1.25 0.62 0.56 0.29 0.23 0.63 0.59 0.68 All dimensions in inches. 1Plain point, unless alternate point from styles shown in Table 8 is specified by user.
0.62
0.29
0.23
2.00
0.75
0.23
a Where specifying nominal size in decimals, zeros in the fourth decimal place are omitted.
Wing Screw and Thumb Screw Designation.—When specifying wing and thumb screws, the following data should be included in the designation and should appear in the following sequence: nominal size (number, fraction or decimal equivalent), threads per inch, length (fractions or decimal equivalents), type, style and/or series, point (if other than plain point), materials, and finish.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition WING NUTS, WING SCREWS AND THUMB SCREWS
1719
Examples:10—32 × 11⁄4, Thumb Screw, Type A, Regular, Steel, Zinc Plated.
0.375—16 × 2.00, Wing Screw, Type B, Style 2, Steel, Cadmium Plated. 0.250—20 × 1.50, Wing Screw, Type C, Style 2, Zinc Alloy Wings, Steel Shank, Brass Plated. Table 7. American National Standard Types A and B Thumb Screws ANSI B18.17-1968, R1983
TYPE A A
TYPE B B
Nominal Size or Basic Screw Diametera
Thds. per Inch
Head Width Max Min
6 (0.1380) 8 (0.1640) 10 (0.1900) 12 (0.2160) 1⁄ (0.2500) 4 5⁄ (0.3125) 16 3⁄ (0.3750) 8
32 32 24, 32 24 20 18 16
0.31 0.36 0.42 0.48 0.55 0.70 0.83
0.29 0.34 0.40 0.46 0.52 0.67 0.80
10 (0.1900) 1⁄ (0.2500) 4 5⁄ (0.3125) 16 3⁄ (0.3750) 8 7⁄ (0.4375) 16 1⁄ (0.5000) 2
24 20 18 16 14 13
0.89 1.05 1.21 1.41 1.59 1.81
0.83 0.99 1.15 1.34 1.53 1.72
6 (0.1380) 8 (0.1640) 10 (0.1900) 12 (0.2160) 1⁄ (0.2500) 4 5⁄ (0.3125) 16 3⁄ (0.3750) 8 7⁄ (0.4375) 16 1⁄ (0.5000) 2
32 32 24, 32 24 20 18 16 14 13
0.45 0.51 0.58 0.71 0.83 0.96 1.09 1.40 1.54
0.43 0.49 0.54 0.67 0.80 0.91 1.03 1.35 1.46
10 (0.1900) 1⁄ (0.2500) 4 5⁄ (0.3125) 16 3⁄ (0.3750) 8 7⁄ (0.4375) 16 1⁄ (0.5000) 2
24 20 18 16 14 13
0.89 1.05 1.21 1.41 1.59 1.81
0.83 0.99 1.15 1.34 1.53 1.72
C
Head Head Height Thick. Max Min Max Min Type A, Regular 0.33 0.31 0.05 0.04 0.38 0.36 0.06 0.05 0.48 0.46 0.06 0.05 0.54 0.52 0.06 0.05 0.64 0.61 0.07 0.05 0.78 0.75 0.09 0.07 0.95 0.92 0.11 0.09 Type A, Heavy 0.84 0.72 0.18 0.16 0.94 0.81 0.24 0.22 1.00 0.88 0.27 0.25 1.16 1.03 0.30 0.28 1.22 1.09 0.36 0.34 1.28 1.16 0.40 0.38 Type B, Regular 0.28 0.26 0.08 0.06 0.32 0.30 0.09 0.07 0.39 0.36 0.10 0.08 0.45 0.43 0.11 0.09 0.52 0.48 0.16 0.14 0.64 0.60 0.17 0.14 0.71 0.67 0.22 0.18 0.96 0.91 0.27 0.24 1.09 1.03 0.33 0.29 Type B, Heavy 0.78 0.66 0.18 0.16 0.81 0.72 0.24 0.22 0.88 0.78 0.27 0.25 0.94 0.84 0.30 0.28 1.00 0.91 0.36 0.34 1.09 0.97 0.40 0.38
C′
E
Head Thick. Max Min
Shoulder Diameter Max Min
L Practical Screw Lengths Max Min
… … … … … … …
… … … … … … …
0.25 0.31 0.35 0.40 0.47 0.59 0.76
0.23 0.29 0.32 0.38 0.44 0.56 0.71
0.75 0.75 1.00 1.00 1.50 1.50 2.00
0.25 0.38 0.38 0.38 0.50 0.50 0.75
0.10 0.10 0.11 0.11 0.13 0.14
0.08 0.08 0.09 0.09 0.11 0.12
0.33 0.40 0.46 0.55 0.71 0.83
0.31 0.38 0.44 0.53 0.69 0.81
2.00 3.00 4.00 4.00 2.50 3.00
0.50 0.50 0.50 0.50 1.00 1.00
0.03 0.04 0.05 0.05 0.06 0.09 0.11 0.14 0.15
0.02 0.02 0.03 0.03 0.03 0.06 0.08 0.11 0.11
… … … … … … … … …
… … … … … … … … …
1.00 1.00 2.00 2.00 2.50 3.00 3.00 4.00 4.00
0.25 0.38 0.38 0.38 0.50 0.50 0.75 1.00 1.00
0.08 0.11 0.11 0.14 0.14 0.18
0.06 0.09 0.09 0.12 0.12 0.16
… … … … … …
… … … … … …
2.00 3.00 4.00 4.00 3.00 3.00
0.50 0.50 0.50 0.50 1.00 1.00
a Where specifying nominal size in decimals, zeroes in fourth decimal place are omitted.
All dimensions in inches. 1Plain point, unless alternate point from styles shown in Table 8 is specified by user.
Lengths of Wing and Thumb Screws.—The length of wing or thumb screws is measured parallel to the axis of the screw from the intersection of the head or shoulder with the shank to the extreme point of the screw. Standard length increments are as follows: For
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Machinery's Handbook 27th Edition 1720
WING NUTS, WING SCREWS AND THUMB SCREWS
sizes No. 4 through 1⁄4 inch and for nominal lengths of 0.25 to 0.75 inch, 0.12-inch increments; from 0.75- to 1.50-inch lengths, 0.25-inch increments; and for 1.50- to 3.00-inch lengths, 0.50-inch increments. For sizes 5⁄16 through 1⁄2 inch and for 0.50- to 1.50-inch lengths, 0.25-inch increments; for 1.50- to 3.00-inch lengths, 0.50-inch increments; and for 3.00- to 4.00-inch lengths, 1.00-inch increments. Threads for Wing Screws and Thumb Screws.—Threads for all types of wing screws and thumb screws are in conformance with ANSI Standard Unified Thread, Class 2A. For threads with an additive finish the Class 2A maximum diameters apply to an unplated screw or to a screw before plating, whereas the basic diameters (Class 2A maximum diameters plus the allowance) apply to a screw after plating. All types of wing and thumb screws should have complete (full form) threads extending as close to the head or shoulder as practicable. Points for Wing and Thumb Screws.—Wing and thumb screws are normally supplied with plain points (sheared ends). Where so specified, these screws may be obtained with cone, cup, dog, flat or oval points as shown in Table 8. Table 8. American National Standard Alternate Points for Wing and Thumb Screws ANSI B18.17-1968, R1983
CUP POINT
CONE POINT
FLAT POINT
OVAL POINT
DOG POINT O
P
Nominal Size or Basic Screw Diamtera
Cup and Flat Point Diameter Max Min
Diameter Max Min
Max
4 (0.1120) 6 (0.1380) 8 (0.1640) 10 (0.1900) 12 (0.2160) 1⁄ (0.2500) 4 5⁄ (0.3125) 16 3⁄ (0.3750) 8 7⁄ (0.4375) 16 1⁄ (0.5000) 2 5⁄ (0.6250) 8
0.061 0.074 0.087 0.102 0.115 0.132 0.172 0.212 0.252 0.291 0.371
0.075 0.092 0.109 0.127 0.144 0.156 0.203 0.250 0.297 0.344 0.469
0.061 0.075 0.085 0.095 0.115 0.130 0.161 0.193 0.224 0.255 0.321
0.051 0.064 0.076 0.088 0.101 0.118 0.156 0.194 0.232 0.270 0.347
Q
R
Length Min
Oval Point Radius Max Min
0.051 0.065 0.075 0.085 0.105 0.120 0.151 0.183 0.214 0.245 0.305
0.099 0.140 0.156 0.172 0.188 0.219 0.256 0.312 0.359 0.406 0.500
Dog Pointb
0.070 0.087 0.103 0.120 0.137 0.149 0.195 0.241 0.287 0.334 0.456
0.084 0.109 0.125 0.141 0.156 0.188 0.234 0.281 0.328 0.375 0.469
a Where specifying nominal size in decimals, zeros in the fourth decimal place are omitted. b The axis of dog points shall not be eccentric with the axis of the screw by more than 3 per cent of the basic screw diameter or 0.005 in., whichever is the smaller.
All dimensions in inches. 1The external point angles specified shall apply to those portions of the angles which lie below the thread root diameter, it being recognized the angle within the thread profile may be varied due to the manufacturing processes.
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Machinery's Handbook 27th Edition TABLE OF CONTENTS THREADS AND THREADING SCREW THREAD SYSTEMS 1725 Screw Thread Forms 1725 V-Thread, Sharp V-thread 1725 US Standard Screw Thread 1725 Unified Screw Thread Forms 1726 International Metric Thread 1727 Definitions of Screw Threads
UNIFIED SCREW THREADS 1732 American Standard for Unified Screw Threads 1732 Revised Standard 1732 Advantages of Unified Threads 1732 Thread Form 1733 Internal and External Screw Thread Design Profile 1733 Thread Series 1734 Inch Screw Thread 1735 Diameter-Pitch Combination 1736 Standard Series Combinations 1763 Coarse-Thread Series 1764 Fine-Thread Series 1764 Extra-Fine-Thread Series 1765 Constant Pitch Series 1766 4-Thread Series 1767 6-Thread Series 1768 8-Thread Series 1769 12-Thread Series 1770 16-Thread Series 1771 20-Thread Series 1772 28-Thread Series 1773 Thread Classes 1773 Coated 60-deg. Threads 1775 Screw Thread Selection 1775 Pitch Diameter Tolerance 1775 Screw Thread Designation 1776 Designating Coated Threads 1776 Designating UNS Threads 1776 Hole Sizes for Tapping 1776 Minor Diameter Tolerance 1777 Unified Miniature Screw Thread 1777 Basic Thread Form 1778 Design Thread Form 1779 Design Form Dimensions 1779 Formulas for Basic Dimensions 1780 Limits of Size and Tolerances 1781 Minimum Root Flats 1782 British Standard Unified Screw Threads UNJ Profile
METRIC SCREW THREADS 1783 American Standard Metric Screw Threads M Profile 1783 Comparison with Inch Threads 1783 Interchangeability 1783 Definitions 1784 Basic M Profile 1784 M Crest and Root Form 1785 General Symbols 1785 M Profile Screw Thread Series 1785 Mechanical Fastener Coarse Pitch 1786 M Profile Data 1787 Limits and Fits 1793 Dimensional Effect of Coating 1793 Formulas for M Profile 1797 Tolerance Grade Comparisons 1797 M Profile Limiting Dimension 1798 Internal Metric Thread 1800 External Metric Thread 1804 American Standard Metric Screw Threads MJ Profile 1804 Diameter-Pitch Combinations 1807 Trapezoidal Metric Thread 1807 Comparison of ISO and DIN Standards 1813 Trapezoidal Metric Thread 1814 ISO Miniature Screw Threads 1814 British Standard ISO Metric Screw Threads 1814 Basic Profile Dimensions 1815 Tolerance System 1815 Fundamental Deviations 1816 Tolerance Grades 1816 Tolerance Positions 1816 Tolerance Classes 1817 Lengths of Thread Engagements 1817 Design Profiles 1817 Designation 1818 Fundamental Deviation Formulas 1819 Crest Diameter Tolerance Formulas 1819 Limits and Tolerances 1822 Diameter/Pitch Combinations 1822 Limits and Tolerances for Finished Uncoated Threads 1823 Diameter/Pitch Combinations 1824 Comparison of Various Metric Thread Systems 1824 Comparison of Maximum Metal Dimension
1721
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Machinery's Handbook 27th Edition TABLE OF CONTENTS THREADS AND THREADING ACME SCREW THREADS 1825 1825 1827 1827 1827 1827 1827 1827 1827 1827 1832 1832 1834 1836 1836 1836 1836 1837 1837 1843 1843 1843 1843 1843 1843 1846 1846 1846 1848 1848
WHITWORTH THREADS
General Purpose Acme Threads Acme Thread Form Acme Thread Abbreviations Designation Basic Dimensions Formulas for Diameters Limiting Dimensions Single-Start Screw Thread Data Pitch Diameter Allowances Multiple Start Acme Threads Pitch Diameter Tolerances Centralizing Acme Threads Basic Dimensions Formulas for Diameters Limiting Dimensions Screw Thread Data Pitch Diameter Allowances Pitch Diameter Tolerances Tolerances and Allowances Designation Acme Centralizing Thread Stub Acme Threads Basic Dimensions Formulas for Diameters Limiting Dimensions Stub Acme Thread Designations Alternative Stub Acme Threads Former 60-Degree Stub Thread Square Thread 10-Degree Square Thread
1857 British Standard Whitworth (BSW) and Fine (BSF) Threads 1857 Standard Thread Form 1857 Whitworth Standard Thread Form 1857 Tolerance Formulas 1858 Basic Dimensions
PIPE AND HOSE THREADS
BUTTRESS THREADS 1849 Threads of Buttress Form 1849 British Standard Buttress Threads 1849 Lowenherz or Löwenherz Thread 1850 Buttress Inch Screw Threads 1850 American National Standard Buttress Inch Screw Threads 1850 Pitch Combinations 1850 Basic Dimensions 1850 Buttress Thread 1850 Symbols and Form 1851 Buttress Thread Tolerances 1851 Class 2 Tolerances 1855 Allowances for Easy Assembly 1855 External Thread Allowances 1856 Buttress Thread Designations 1856 Designation Sequence
1860 American National Standard Pipe Threads 1860 Thread Designation and Notation 1860 Taper Pipe Thread 1861 Basic Dimensions 1862 Engagement 1862 Tolerances on Thread Elements 1863 Limits on Crest and Root 1864 Pipe Couplings 1864 Railing Joint 1864 Straight Pipe Threads 1864 Mechanical Joints 1866 Dryseal Pipe Thread 1866 Limits on Crest and Root 1866 Types of Dryseal Pipe Thread 1866 Limitation of Assembly 1868 Tap Drill Sizes 1868 Special Dryseal Threads 1869 Limitations for Combinations 1869 British Standard Pipe Threads 1869 Non-pressure-tight Joints 1870 Basic Sizes 1870 Pressure-tight Joints 1871 Limits of Size 1872 Hose Coupling Screw Threads 1872 ANSI Standard 1873 Hose Coupling Threads 1874 Screw Thread Length 1874 Fire Hose Connection 1875 Basic Dimensions 1876 Limits of Size
OTHER THREADS 1877 Interference-Fit Threads 1878 Design and Application Data 1879 External Thread Dimension 1879 Internal Thread Dimension 1880 Engagement Lengths 1881 Allowances for Coarse Thread 1881 Tolerances for Coarse Thread
1722
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Machinery's Handbook 27th Edition TABLE OF CONTENTS THREADS AND THREADING OTHER THREADS
MEASURING SCREW THREADS
(Continued)
(Continued)
1882 Variations in Lead and Diameter 1883 Spark Plug Threads 1883 BS Spark Plugs 1883 SAE Spark Plugs 1884 Lamp Base and Socket Threads 1885 Instrument and Microscope Threads 1885 British Association Thread 1886 Instrument Makers’ Screw Thread 1886 Microscope Objective Thread 1889 Swiss Screw Thread 1890 Historical and Miscellaneous 1890 Aero-Thread 1890 Briggs Pipe Thread 1890 Casing Thread 1891 Cordeaux Thread 1891 Dardelet Thread 1891 “Drunken” Thread 1891 Echols Thread 1891 French Thread (S.F.) 1891 Harvey Grip Thread 1892 Lloyd & Lloyd Thread 1892 Lock-Nut Pipe Thread 1892 Philadelphia Carriage Bolt Thread 1892 SAE Standard Screw Thread 1892 Sellers Screw Thread
1905 Checking Pitch Diameter 1905 Checking Thread Thickness 1906 Wire Sizes 1906 Checking Thread Angle 1907 Best Wire Diameters 1909 Taper Screw Threads 1910 Buttress Threads 1911 Thread Gages 1911 Thread Gage Classification 1911 Gages for Unified Inch Threads 1914 Thread Forms of Gages 1914 Thread Gage Tolerances 1916 Tolerances for Cylindrical Gages 1918 Formulas for Limits
MEASURING SCREW THREADS 1893 Measuring Screw Threads 1893 Pitch and Lead of Screw Threads 1893 Thread Micrometers 1894 Ball-point Micrometers 1894 Three-wire Method 1895 Classes of Formulas 1895 Screw Thread Profiles 1895 Accuracy of Formulas 1896 Best Wire Sizes 1897 Measuring Wire Accuracy 1897 Measuring or Contact Pressure 1897 Three-Wire Formulas 1898 NIST General Formula 1899 Formulas for Pitch Diameters 1899 Effect of Small Thread Angle 1901 Dimensions Over Wires 1901 Formula Including Lead Angle 1902 Measuring Whitworth Threads 1903 Buckingham Exact Formula 1904 Accuracy of Formulas Acme and Stub Acme Thread
TAPPING AND THREAD CUTTING 1919 Selection of Taps 1921 Tap Rake Angles 1921 Cutting Speed 1921 Tapping Specific Materials 1924 Diameter of Tap Drill 1925 Hole Size Limits 1933 Tap Drill Sizes 1934 Tap Drills and Clearance Drills 1934 Tolerances of Tapped Holes 1935 Hole Sizes before Tapping 1936 Miniature Screw Threads 1937 Tapping Drill Sizes 1937 ISO Metric Threads 1938 Clearance Holes 1939 Cold Form Tapping 1940 Core Hole Sizes 1941 Tap Drill Sizes 1941 Removing a Broken Tap 1941 Tap Drills for Pipe Taps 1941 Power for Pipe Taps 1942 High-Speed CNC Tapping 1943 Coolant for Tapping 1943 Combined Drilling and Tapping 1944 Relief Angles for Cutting Tools 1946 Lathe Change Gears 1946 Change Gears for Thread Cutting 1946 Compound Gearing 1946 Fractional Threads 1947 Change Gears for Metric Pitches 1947 Change Gears for Fractional Ratios
1723
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Machinery's Handbook 27th Edition TABLE OF CONTENTS THREADS AND THREADING TAPPING AND THREAD CUTTING
THREAD MILLING (Continued)
1965 1965 1965 1966 1967 1977 1980
(Continued)
1948 1950 1950 1951
Quick-Change Gearbox Output Finding Accurate Gear Ratios Lathe Change-gears Relieving Helical-Fluted Hobs
THREAD ROLLING 1952 Thread-Rolling Machine 1952 Flat-Die Type 1952 Cylindrical-Die Type 1952 Rate of Production 1953 Precision Thread Rolling 1953 Steels for Thread Rolling 1953 Diameter of Blank 1953 Automatic Screw Machines 1954 Factors Governing the Diameter 1954 Diameter of Threading Roll 1954 Kind of Thread on Roll 1955 Application of Thread Roll 1955 Thread Rolling Speeds and Feeds
THREAD GRINDING 1957 Thread Grinding 1957 Wheels for Thread Grinding 1957 Single-Edge Wheel 1958 Edges for Roughing and Finishing 1958 Multi-ribbed Wheels 1959 Ribbed Wheel for Fine Pitches 1959 Solid Grinding Threads 1959 Number of Wheel Passes 1959 Wheel and Work Rotation 1960 Wheel Speeds 1960 Work Speeds 1960 Truing Grinding Wheels 1960 Wheel Hardness or Grade 1961 Grain Size 1961 Grinding by Centerless Method
THREAD MILLING 1962 Thread Milling 1962 Single-cutter Method 1962 Multiple-cutter Method 1963 Planetary Method 1963 Classes of Work 1964 Pitches of Die-cut Threads 1964 Changing Pitch of Screw 1964 Helical Milling 1964 Lead of a Milling Machine
1981 1982 1982 1982 1982
Change Gears for Helical Milling Short-lead Milling Helix Helix Angles Change Gears for Different Leads Lead of Helix Change Gears and Angles Determining Helix Angle For Given Lead and Diameter For Given Angle For Given Lead And Lead Given DP and Teeth Lead of Tooth Given Pitch Radius and Helix Angle
SIMPLE, COMPOUND, DIFFERENTIAL, AND BLOCK INDEXING 1983 Milling Machine Indexing 1983 Hole Circles 1983 Holes in Brown & Sharpe 1983 Holes in Cincinnati 1983 Simple Indexing 1984 Compound Indexing 1985 Simple and Compound Indexing 1990 Angular Indexing 1990 Tables for Angular Indexing 1991 Angular Values of Cincinnati Index 1992 Accurate Angular Indexing 2007 Indexing for Small Angles 2008 Differential Indexing 2008 Ratio of Gearing 2009 To Find the Indexing Movement 2009 Use of Idler Gears 2009 Compound Gearing 2010 Check Number of Divisions 2011 Simple and Different Indexing 2017 Indexing Movements of Plate 2018 Indexing Movements for High Numbers 2021 Indexing Tables 2021 Block or Multiple Indexing 2023 Indexing Movements for 60Tooth 2024 Linear Indexing for Rack Cutting 2024 Linear Indexing Movements 2025 Counter Milling
1724
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Machinery's Handbook 27th Edition THREADS AND THREADING
1725
SCREW THREAD SYSTEMS Screw Thread Forms Of the various screw thread forms which have been developed, the most used are those having symmetrical sides inclined at equal angles with a vertical center line through the thread apex. Present-day examples of such threads would include the Unified, the Whitworth and the Acme forms. One of the early forms was the Sharp V which is now used only occasionally. Symmetrical threads are relatively easy to manufacture and inspect and hence are widely used on mass-produced general-purpose threaded fasteners of all types. In addition to general-purpose fastener applications, certain threads are used to repeatedly move or translate machine parts against heavy loads. For these so-called translation threads a stronger form is required. The most widely used translation thread forms are the square, the Acme, and the buttress. Of these, the square thread is the most efficient, but it is also the most difficult to cut owing to its parallel sides and it cannot be adjusted to compensate for wear. Although less efficient, the Acme form of thread has none of the disadvantages of the square form and has the advantage of being somewhat stronger. The buttress form is used for translation of loads in one direction only because of its non-symmetrical form and combines the high efficiency and strength of the square thread with the ease of cutting and adjustment of the Acme thread. V-Thread, Sharp V-thread.—The sides of the thread form an angle of 60 degrees with each other. The top and bottom or root of this thread form are theoretically sharp, but in actual practice the thread is made with a slight flat, owing to the difficulty of producing a perfectly sharp edge and because of the tendency of such an edge to wear away or become battered. This flat is usually equal to about one twenty-fifth of the pitch, although there is no generally recognized standard. Owing to the difficulties connected with the V-thread, the tap manufacturers agreed in 1909 to discontinue the making of sharp Vthread taps, except when ordered. One advantage of the V-thread is that the same cutting tool may be used for all pitches, whereas, with the American Standard form, the width of the point or the flat varies according to the pitch. The V-thread is regarded as a good form where a steam-tight joint is necessary, and many of the taps used on locomotive work have this form of thread. Some modified V-threads, for locomotive boiler taps particularly, have a depth of 0.8 × pitch. The American Standard screw thread is used largely in preference to the sharp V-thread because it has several advantages; see American Standard for Unified Screw Threads. If p = pitch of thread, and d depth of thread, then 0.866 d = p × cos 30 deg. = 0.866 × p = ------------------------------------------------------No. of threads per inch United States Standard Screw Thread.—William Sellers of Philadelphia, in a paper read before the Franklin Institute in 1864, originally proposed the screw thread system that later became known as the U. S. Standard system for screw threads. A report was made to the United States Navy in May, 1868, in which the Sellers system was recommended as a standard for the Navy Department, which accounts for the name of U. S. Standard. The American Standard Screw Thread system is a further development of the United States Standard. The thread form which is known as the American (National) form is the same as the United States Standard form. See American Standard for Unified Screw Threads. American National and Unified Screw Thread Forms.—The American National form (formerly known as the United States Standard) was used for many years for most screws, bolts, and miscellaneous threaded products produced in the United States. The American
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Machinery's Handbook 27th Edition 1726
SCREW THREAD SYSTEMS
National Standard for Unified Screw Threads now in use includes certain modifications of the former standard as is explained below and on page 1732. The basic profile is shown in Fig. 1 and is identical for both UN and UNR screw threads. In this figure H is the height of a sharp V-thread, P is the pitch, D and d are the basic major diameters, D2 and d2 are the basic pitch diameters, and D1 and d1 are the basic minor diameters. Capital letters are used to designate the internal thread dimensions (D, D2, D1), and lowercase letters to designate the external thread dimensions (d, d2, d1). Definitions of Basic Size and Basic Profile of Thread are given on page 1727.
Fig. 1. Basic Profile of UN and UNF Screw Threads
In the past, other symbols were used for some of the thread dimensions illustrated above. These symbols were changed to conform with current practice in nomenclature as defined in ANSI/ASME B1.7M, “Nomenclature, Definitions, and Letter Symbols for Screw Threads.” The symbols used above are also in accordance with termonology and symbols used for threads of the ISO metric thread system. International Metric Thread System.—The Système Internationale (S.I.) Thread was adopted at the International Congress for the standardization of screw threads held in Zurich in 1898. The thread form is similar to the American standard (formerly U.S. Standard), excepting the depth which is greater. There is a clearance between the root and mating crest fixed at a maximum of 1⁄16 the height of the fundamental triangle or 0.054 × pitch. A rounded root profile is recommended. The angle in the plane of the axis is 60 degrees and the crest has a flat like the American standard equal to 0.125 × pitch. This system formed the basis of the normal metric series (ISO threads) of many European countries, Japan, and many other countries, including metric thread standards of the United States. Depth d = 0.7035 P max.; 0.6855 P min. Flat f = 0.125 P Radius r = 0.0633 P max.; 0.054 P min. Tap drill dia = major dia.− pitch
P f 60° Nut
d
Screw r
International Metric Fine Thread: The International Metric Fine Thread form of thread is the same as the International system but the pitch for a given diameter is smaller. German Metric Thread Form: The German metric thread form is like the International Standard but the thread depth = 0.6945 P. The root radius is the same as the maximum for the International Standard or 0.0633 P.
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Machinery's Handbook 27th Edition SCREW THREADS
1727
ISO Metric Thread System.—ISO refers to the International Organization for Standardization, a worldwide federation of national standards bodies (for example, the American National Standards Institute is the ISO national body representing the United States) that develops standards on a very wide variety of subjects. The basic profile of ISO metric threads is specified in ISO 68 and shown in Fig. 2. The basic profile of this thread is very similar to that of the Unified thread, and as previously discussed, H is the height of a sharp V-thread, P is the pitch, D and d are the basic major diameters, D2 and d2 are the basic pitch diameters, and D1 and d1 are the basic minor diameters. Here also, capital letters designate the internal thread dimensions (D, D2, D1), and lowercase letters designate the external thread dimensions (d, d2, d1). This metric thread is discussed in detail in the section METRIC SCREW THREADS starting on page 1783. Internal threads
P 8
P 2
D, d
H 8
P
60°
30°
P 2
P 4
D 2, d 2 D 1, d 1
90°
3 H 8 5 H 8 H
H 4
Axis of screw thread
External threads H=
3 × P = 0.866025404P 2
0.125H = 0.108253175P 0.250H = 0.216506351P 0.375H = 0.324759526P 0.625H = 0.541265877P
Fig. 2. ISO 68 Basic Profile
Definitions of Screw Threads The following definitions are based on American National Standard ANSI/ASME B1.7M-1984 (R2001) “Nomenclature, Definitions, and Letter Symbols for Screw Threads,” and refer to both straight and taper threads. Actual Size: An actual size is a measured size. Allowance: An allowance is the prescribed difference between the design (maximum material) size and the basic size. It is numerically equal to the absolute value of the ISO term fundamental deviation. Axis of Thread: Thread axis is coincident with the axis of its pitch cylinder or cone. Basic Profile of Thread: The basic profile of a thread is the cyclical outline, in an axial plane, of the permanently established boundary between the provinces of the external and internal threads. All deviations are with respect to this boundary. Basic Size: The basic size is that size from which the limits of size are derived by the application of allowances and tolerances. Bilateral Tolerance: This is a tolerance in which variation is permitted in both directions from the specified dimension. Black Crest Thread: This is a thread whose crest displays an unfinished cast, rolled, or forged surface. Blunt Start Thread: “Blunt start” designates the removal of the incomplete thread at the starting end of the thread. This is a feature of threaded parts that are repeatedly assembled
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Machinery's Handbook 27th Edition 1728
SCREW THREADS
by hand, such as hose couplings and thread plug gages, to prevent cutting of hands and crossing of threads. It was formerly known as a Higbee cut. Chamfer: This is a conical surface at the starting end of a thread. Class of Thread: The class of a thread is an alphanumerical designation to indicate the standard grade of tolerance and allowance specified for a thread. Clearance Fit: This is a fit having limits of size so prescribed that a clearance always results when mating parts are assembled at their maximum material condition. Complete Thread: The complete thread is that thread whose profile lies within the size limits. (See also Effective Thread and Length of Complete Thread.) Note: Formerly in pipe thread terminology this was referred to as “the perfect thread” but that term is no longer considered desirable. Crest: This is that surface of a thread which joins the flanks of the thread and is farthest from the cylinder or cone from which the thread projects. Crest Truncation: This is the radial distance between the sharp crest (crest apex) and the cylinder or cone that would bound the crest. Depth of Thread Engagement: The depth (or height) of thread engagement between two coaxially assembled mating threads is the radial distance by which their thread forms overlap each other. Design Size: This is the basic size with allowance applied, from which the limits of size are derived by the application of a tolerance. If there is no allowance, the design size is the same as the basic size. Deviation: Deviation is a variation from an established dimension, position, standard, or value. In ISO usage, it is the algebraic difference between a size (actual, maximum, or minimum) and the corresponding basic size. The term deviation does not necessarily indicate an error. (See also Error.) Deviation, Fundamental (ISO term): For standard threads, the fundamental deviation is the upper or lower deviation closer to the basic size. It is the upper deviation es for an external thread and the lower deviation EI for an internal thread. (See also Allowance and Tolerance Position.) Deviation, Lower (ISO term): The algebraic difference between the minimum limit of size and the basic size. It is designated EI for internal and ei for external thread diameters. Deviation, Upper (ISO term): The algebraic difference between the maximum limit of size and the basic size. It is designated ES for internal and es for external thread diameters. Dimension: A numerical value expressed in appropriate units of measure and indicated on drawings along with lines, symbols, and notes to define the geometrical characteristic of an object. Effective Size: See Pitch Diameter, Functional Diameter. Effective Thread: The effective (or useful) thread includes the complete thread, and those portions of the incomplete thread which are fully formed at the root but not at the crest (in taper pipe threads it includes the so-called black crest threads); thus excluding the vanish thread. Error: The algebraic difference between an observed or measured value beyond tolerance limits, and the specified value. External Thread: A thread on a cylindrical or conical external surface. Fit: Fit is the relationship resulting from the designed difference, before assembly, between the sizes of two mating parts which are to be assembled. Flank: The flank of a thread is either surface connecting the crest with the root. The flank surface intersection with an axial plane is theoretically a straight line. Flank Angle: The flank angles are the angles between the individual flanks and the perpendicular to the axis of the thread, measured in an axial plane. A flank angle of a symmetrical thread is commonly termed the half-angle of thread. Flank Diametral Displacement: In a boundary profile defined system, flank diametral displacement is twice the radial distance between the straight thread flank segments of the
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Machinery's Handbook 27th Edition SCREW THREADS
1729
maximum and minimum boundary profiles. The value of flank diametral displacement is equal to pitch diameter tolerance in a pitch line reference thread system. Height of Thread: The height (or depth) of thread is the distance, measured radially, between the major and minor cylinders or cones, respectively. Helix Angle: On a straight thread, the helix angle is the angle made by the helix of the thread and its relation to the thread axis. On a taper thread, the helix angle at a given axial position is the angle made by the conical spiral of the thread with the axis of the thread. The helix angle is the complement of the lead angle. (See also page 1966 for diagram.) Higbee Cut: See Blunt Start Thread. Imperfect Thread: See Incomplete Thread. Included Angle: This is the angle between the flanks of the thread measured in an axial plane. Incomplete Thread: A threaded profile having either crests or roots or both, not fully formed, resulting from their intersection with the cylindrical or end surface of the work or the vanish cone. It may occur at either end of the thread. Interference Fit: A fit having limits of size so prescribed that an interference always results when mating parts are assembled. Internal Thread: A thread on a cylindrical or conical internal surface. Lead: Lead is the axial distance between two consecutive points of intersection of a helix by a line parallel to the axis of the cylinder on which it lies, i.e., the axial movement of a threaded part rotated one turn in its mating thread. Lead Angle: On a straight thread, the lead angle is the angle made by the helix of the thread at the pitch line with a plane perpendicular to the axis. On a taper thread, the lead angle at a given axial position is the angle made by the conical spiral of the thread with the perpendicular to the axis at the pitch line. Lead Thread: That portion of the incomplete thread that is fully formed at the root but not fully formed at the crest that occurs at the entering end of either an external or internal thread. Left-hand Thread: A thread is a left-hand thread if, when viewed axially, it winds in a counterclockwise and receding direction. Left-hand threads are designated LH. Length of Complete Thread: The axial length of a thread section having full form at both crest and root but also including a maximum of two pitches at the start of the thread which may have a chamfer or incomplete crests. Length of Thread Engagement: The length of thread engagement of two mating threads is the axial distance over which the two threads, each having full form at both crest and root, are designed to contact. (See also Length of Complete Thread.) Limits of Size: The applicable maximum and minimum sizes. Major Clearance: The radial distance between the root of the internal thread and the crest of the external thread of the coaxially assembled designed forms of mating threads. Major Cone: The imaginary cone that would bound the crests of an external taper thread or the roots of an internal taper thread. Major Cylinder: The imaginary cylinder that would bound the crests of an external straight thread or the roots of an internal straight thread. Major Diameter: On a straight thread the major diameter is that of the major cylinder. On a taper thread the major diameter at a given position on the thread axis is that of the major cone at that position. (See also Major Cylinder and Major Cone.) Maximum Material Condition: (MMC): The condition where a feature of size contains the maximum amount of material within the stated limits of size. For example, minimum internal thread size or maximum external thread size. Minimum Material Condition: (Least Material Condition (LMC)): The condition where a feature of size contains the least amount of material within the stated limits of size. For example, maximum internal thread size or minimum external thread size. Minor Clearance: The radial distance between the crest of the internal thread and the root of the external thread of the coaxially assembled design forms of mating threads.
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Machinery's Handbook 27th Edition 1730
SCREW THREADS
Minor Cone: The imaginary cone that would bound the roots of an external taper thread or the crests of an internal taper thread. Minor Cylinder: The imaginary cylinder that would bound the roots of an external straight thread or the crests of an internal straight thread. Minor Diameter: On a straight thread the minor diameter is that of the minor cylinder. On a taper thread the minor diameter at a given position on the thread axis is that of the minor cone at that position. (See also Minor Cylinder and Minor Cone.) Multiple-Start Thread: A thread in which the lead is an integral multiple, other than one, of the pitch. Nominal Size: Designation used for general identification. Parallel Thread: See Screw Thread. Partial Thread: See Vanish Thread. Pitch: The pitch of a thread having uniform spacing is the distance measured parallel with its axis between corresponding points on adjacent thread forms in the same axial plane and on the same side of the axis. Pitch is equal to the lead divided by the number of thread starts. Pitch Cone: The pitch cone is an imaginary cone of such apex angle and location of its vertex and axis that its surface would pass through a taper thread in such a manner as to make the widths of the thread ridge and the thread groove equal. It is, therefore, located equidistantly between the sharp major and minor cones of a given thread form. On a theoretically perfect taper thread, these widths are equal to one-half the basic pitch. (See also Axis of Thread and Pitch Diameter.) Pitch Cylinder: The pitch cylinder is an imaginary cylinder of such diameter and location of its axis that its surface would pass through a straight thread in such a manner as to make the widths of the thread ridge and groove equal. It is, therefore, located equidistantly between the sharp major and minor cylinders of a given thread form. On a theoretically perfect thread these widths are equal to one-half the basic pitch. (See also Axis of Thread and Pitch Diameter.) Pitch Diameter: On a straight thread the pitch diameter is the diameter of the pitch cylinder. On a taper thread the pitch diameter at a given position on the thread axis is the diameter of the pitch cone at that position. Note: When the crest of a thread is truncated beyond the pitch line, the pitch diameter and pitch cylinder or pitch cone would be based on a theoretical extension of the thread flanks. Pitch Diameter, Functional Diameter: The functional diameter is the pitch diameter of an enveloping thread with perfect pitch, lead, and flank angles and having a specified length of engagement. It includes the cumulative effect of variations in lead (pitch), flank angle, taper, straightness, and roundness. Variations at the thread crest and root are excluded. Other, nonpreferred terms are virtual diameter, effective size, virtual effective diameter, and thread assembly diameter. Pitch Line: The generator of the cylinder or cone specified in Pitch Cylinder and Pitch Cone. Right-hand Thread: A thread is a fight-hand thread if, when viewed axially, it winds in a clockwise and receding direction. A thread is considered to be right-hand unless specifically indicated otherwise. Root: That surface of the thread which joins the flanks of adjacent thread forms and is immediately adjacent to the cylinder or cone from which the thread projects. Root Truncation: The radial distance between the sharp root (root apex) and the cylinder or cone that would bound the root. See also Sharp Root (Root Apex). Runout: As applied to screw threads, unless otherwise specified, runout refers to circular runout of major and minor cylinders with respect to the pitch cylinder. Circular runout, in accordance with ANSI Y14.5M, controls cumulative variations of circularity and coaxiality. Runout includes variations due to eccentricity and out-of-roundness. The amount of runout is usually expressed in terms of full indicator movement (FIM).
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition SCREW THREADS
1731
Screw Thread: A screw thread is a continuous and projecting helical ridge usually of uniform section on a cylindrical or conical surface. Sharp Crest (Crest Apex): The apex formed by the intersection of the flanks of a thread when extended, if necessary, beyond the crest. Sharp Root (Root Apex): The apex formed by the intersection of the adjacent flanks of adjacent threads when extended, if necessary, beyond the root. Standoff: The axial distance between specified reference points on external and internal taper thread members or gages, when assembled with a specified torque or under other specified conditions. Straight Thread: A straight thread is a screw thread projecting from a cylindrical surface. Taper Thread: A taper thread is a screw thread projecting from a conical surface. Tensile Stress Area: The tensile stress area is an arbitrarily selected area for computing the tensile strength of an externally threaded fastener so that the fastener strength is consistent with the basic material strength of the fastener. It is typically defined as a function of pitch diameter and/or minor diameter to calculate a circular cross section of the fastener correcting for the notch and helix effects of the threads. Thread: A thread is a portion of a screw thread encompassed by one pitch. On a singlestart thread it is equal to one turn. (See also Threads per Inch and Turns per Inch.) Thread Angle: See Included Angle. Thread Runout: See Vanish Thread. Thread Series: Thread Series are groups of diameter/pitch combinations distinguished from each other by the number of threads per inch applied to specific diameters. Thread Shear Area: The thread shear area is the total ridge cross-sectional area intersected by a specified cylinder with diameter and length equal to the mating thread engagement. Usually the cylinder diameter for external thread shearing is the minor diameter of the internal thread and for internal thread shearing it is the major diameter of the external thread. Threads per Inch: The number of threads per inch is the reciprocal of the axial pitch in inches. Tolerance: The total amount by which a specific dimension is permitted to vary. The tolerance is the difference between the maximum and minimum limits. Tolerance Class: (metric): The tolerance class (metric) is the combination of a tolerance position with a tolerance grade. It specifies the allowance (fundamental deviation), pitch diameter tolerance (flank diametral displacement), and the crest diameter tolerance. Tolerance Grade: (metric): The tolerance grade (metric) is a numerical symbol that designates the tolerances of crest diameters and pitch diameters applied to the design profiles. Tolerance Limit: The variation, positive or negative, by which a size is permitted to depart from the design size. Tolerance Position: (metric): The tolerance position (metric) is a letter symbol that designates the position of the tolerance zone in relation to the basic size. This position provides the allowance (fundamental deviation). Total Thread: Includes the complete and all the incomplete thread, thus including the vanish thread and the lead thread. Transition Fit: A fit having limits of size so prescribed that either a clearance or an interference may result when mating parts are assembled. Turns per Inch: The number of turns per inch is the reciprocal of the lead in inches. Unilateral Tolerance: A tolerance in which variation is permitted in one direction from the specified dimension. Vanish Thread: (Partial Thread, Washout Thread, or Thread Runout): That portion of the incomplete thread which is not fully formed at the root or at crest and root. It is produced by the chamfer at the starting end of the thread forming tool. Virtual Diameter: See Pitch Diameter, Functional Diameter. Washout Thread: See Vanish Thread.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition 1732
UNIFIED SCREW THREADS
UNIFIED SCREW THREADS American Standard for Unified Screw Threads American Standard B1.1-1949 was the first American standard to cover those Unified Thread Series agreed upon by the United Kingdom, Canada, and the United States to obtain screw thread interchangeability among these three nations. These Unified threads are now the basic American standard for fastening types of screw threads. In relation to previous American practice, Unified threads have substantially the same thread form and are mechanically interchangeable with the former American National threads of the same diameter and pitch. The principal differences between the two systems lie in: 1) application of allowances; 2) variation of tolerances with size; 3) difference in amount of pitch diameter tolerance on external and internal threads; and 4) differences in thread designation. In the Unified system an allowance is provided on both the Classes 1A and 2A external threads whereas in the American National system only the Class I external thread has an allowance. Also, in the Unified system, the pitch diameter tolerance of an internal thread is 30 per cent greater than that of the external thread, whereas they are equal in the American National system. Revised Standard.—The revised screw thread standard ANSI/ASME B1.1-1989 (R2001) is much the same as that of ANSI B1.1-1982. The latest symbols in accordance with ANSI/ASME B1.7M-1984 (R2001) Nomenclature, are used. Acceptability criteria are described in ANSI/ASME B1.3M-1992 (R2001), Screw Thread Gaging Systems for Dimensional Acceptability, Inch or Metric Screw Threads (UN, UNR, UNJ, M, and MJ). Where the letters U, A or B do not appear in the thread designations, the threads conform to the outdated American National screw threads. Advantages of Unified Threads.—The Unified standard is designed to correct certain production difficulties resulting from the former standard. Often, under the old system, the tolerances of the product were practically absorbed by the combined tool and gage tolerances, leaving little for a working tolerance in manufacture. Somewhat greater tolerances are now provided for nut threads. As contrasted with the old “classes of fit” 1, 2, and 3, for each of which the pitch diameter tolerance on the external and internal threads were equal, the Classes 1B, 2B, and 3B (internal) threads in the new standard have, respectively, a 30 per cent larger pitch diameter tolerance than the 1A, 2A, and 3A (external) threads. Relatively more tolerance is provided for fine threads than for coarse threads of the same pitch. Where previous tolerances were more liberal than required, they were reduced. Thread Form.—The Design Profiles for Unified screw threads, shown on page 1733, define the maximum material condition for external and internal threads with no allowance and are derived from the Basic Profile, shown on page 1726. UN External Screw Threads: A flat root contour is specified, but it is necessary to provide for some threading tool crest wear, hence a rounded root contour cleared beyond the 0.25P flat width of the Basic Profile is optional. UNR External Screw Threads: To reduce the rate of threading tool crest wear and to improve fatigue strength of a flat root thread, the Design Profile of the UNR thread has a smooth, continuous, non-reversing contour with a radius of curvature not less than 0.108P at any point and blends tangentially into the flanks and any straight segment. At the maximum material condition, the point of tangency is specified to be at a distance not less than 0.625H (where H is the height of a sharp V-thread) below the basic major diameter. UN and UNR External Screw Threads: The Design Profiles of both UN and UNR external screw threads have flat crests. However, in practice, product threads are produced with partially or completely rounded crests. A rounded crest tangent at 0.125P flat is shown as an option on page 1733.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition UNIFIED SCREW THREADS
1733
UN Internal Screw Thread: In practice it is necessary to provide for some threading tool crest wear, therefore the root of the Design Profile is rounded and cleared beyond the 0.125P flat width of the Basic Profile.There is no internal UNR screw thread. American National Standard Unified Internal and External Screw Thread Design Profiles (Maximum Material Condition) .— 0.125H
;;;;;;;; ;;;;;;;; ;;;;;;;;
0.625H H
0.125P
Rounded crest optional 60 deg 30 deg
0.5P Pitch line
0.375H 0.25P
P
0.25H
0.25H
Nominal flat root design minor diameter Rounded root optional
Flanks to be straight beyond 0.25H from sharp apex of root
90 deg
Axis of external thread
;;;;;;;;; ;;;;;;;;; ;;;;;;;;; ;;;;;;;;; 0.125H
0.125P 60 deg
0.625H
H
0.5P Pitch line
0.375H 0.25P
30 deg
0.6875H
0.25H
P
0.0625H 0.25H
0.1875H
r = 0.108P Flanks to be straight beyond 0.25H from sharp apex of root
90 deg
Rounded crest optional
Tangency flank/root rad.
UNR design minor diameter specified in dimensional tables
Axis of external thread
;;;;;; ;;;;;;
Min major diameter specified in dimensional tables
60°
0.25H
UN Internal Thread 0.125P (Nut) 0.125H
Pitch line 0.5P
0.25P
0.125H 0.375H
0.625H 0.25H
H
0.25H
P 90 deg
Axis of external thread
(H = height of sharp V-thread = 0.86603 × pitch)
Thread Series.—Thread series are groups of diameter-pitch combinations distinguished from each other by the numbers of threads per inch applied to a specific diameter. The various diameter-pitch combinations of eleven standard series are shown in Table 2. The limits of size of threads in the eleven standard series together with certain selected combinations of diameter and pitch, as well as the symbols for designating the various threads, are given in Table 3. (Text continues on page 1763)
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Depth of UNR Ext. Thd.
Truncation of Ext. Thd. Root
Truncation of UNR Ext. Thd. Rootb
Truncation of Ext. Thd. Crest
Truncation of Int. Thd. Root
Truncation of Int. Thd. Crest
n
P
0.86603P
0.54127P
0.59539P
0.21651P
0.16238P
0.10825P
0.10825P
0.2165P
80 72 64 56 48 44 40 36 32 28 27 24 20 18 16 14 13 12 111⁄2 11 10 9 8 7 6 5 41⁄2 4
0.01250 0.01389 0.01563 0.01786 0.02083 0.02273 0.02500 0.02778 0.03125 0.03571 0.03704 0.04167 0.05000 0.05556 0.06250 0.07143 0.07692 0.08333 0.08696
0.01083 0.01203 0.01353 0.01546 0.01804 0.01968 0.02165 0.02406 0.02706 0.03093 0.03208 0.03608 0.04330 0.04811 0.05413 0.06186 0.06662 0.07217 0.07531
0.00677 0.00752 0.00846 0.00967 0.01128 0.01230 0.01353 0.01504 0.01691 0.01933 0.02005 0.02255 0.02706 0.03007 0.03383 0.03866 0.04164 0.04511 0.04707
0.00744 0.00827 0.00930 0.01063 0.01240 0.01353 0.01488 0.01654 0.01861 0.02126 0.02205 0.02481 0.02977 0.03308 0.03721 0.04253 0.04580 0.04962 0.05177
0.00271 0.00301 0.00338 0.00387 0.00451 0.00492 0.00541 0.00601 0.00677 0.00773 0.00802 0.00902 0.01083 0.01203 0.01353 0.01546 0.01655 0.01804 0.01883
0.00203 0.00226 0.00254 0.00290 0.00338 0.00369 0.00406 0.00451 0.00507 0.00580 0.00601 0.00677 0.00812 0.00902 0.01015 0.01160 0.01249 0.01353 0.01412
0.00135 0.00150 0.00169 0.00193 0.00226 0.00246 0.00271 0.00301 0.00338 0.00387 0.00401 0.00451 0.00541 0.00601 0.00677 0.00773 0.00833 0.00902 0.00941
0.00135 0.00150 0.00169 0.00193 0.00226 0.00246 0.00271 0.00301 0.00338 0.00387 0.00401 0.00451 0.00541 0.00601 0.00677 0.00773 0.00833 0.00902 0.00941
0.00271 0.00301 0.00338 0.00387 0.00451 0.00492 0.00541 0.00601 0.00677 0.00773 0.00802 0.00902 0.01083 0.01203 0.01353 0.01546 0.01665 0.01804 0.01883
0.09091 0.10000 0.11111 0.12500 0.14286 0.16667 0.20000 0.22222
0.07873 0.08660 0.09623 0.10825 0.12372 0.14434 0.17321 0.19245
0.04921 0.05413 0.06014 0.06766 0.07732 0.09021 0.10825 0.12028
0.05413 0.05954 0.06615 0.07442 0.08506 0.09923 0.11908 0.13231
0.01968 0.02165 0.02406 0.02706 0.03093 0.03608 0.04330 0.04811
0.01476 0.01624 0.01804 0.02030 0.02320 0.02706 0.03248 0.03608
0.00984 0.01083 0.01203 0.01353 0.01546 0.01804 0.02165 0.02406
0.00984 0.01083 0.01203 0.01353 0.01546 0.01804 0.02165 0.02406
0.01968 0.02165 0.02406 0.02706 0.03093 0.03608 0.04330 0.04811
0.25000
0.21651
0.13532
0.14885
0.05413
0.04059
0.02706
0.02706
0.05413
a Also depth of thread engagement. b Design profile. c Also basic flat at external UN thread root.
All dimensions are in inches.
Copyright 2004, Industrial Press, Inc., New York, NY
Basic Flat at Int. Thd. Crestc
Maximum Ext. Thd. Root Radius
Addendum of Ext. Thd.
0.125P
0.25P
0.14434P
0.32476P
0.00156 0.00174 0.00195 0.00223 0.00260 0.00284 0.00312 0.00347 0.00391 0.00446 0.00463 0.00521 0.00625 0.00694 0.00781 0.00893 0.00962 0.01042 0.01087
0.00312 0.00347 0.00391 0.00446 0.00521 0.00568 0.00625 0.00694 0.00781 0.00893 0.00926 0.01042 0.01250 0.01389 0.01562 0.01786 0.01923 0.02083 0.02174
0.00180 0.00200 0.00226 0.00258 0.00301 0.00328 0.00361 0.00401 0.00451 0.00515 0.00535 0.00601 0.00722 0.00802 0.00902 0.01031 0.01110 0.01203 0.01255
0.00406 0.00451 0.00507 0.00580 0.00677 0.00738 0.00812 0.00902 0.01015 0.01160 0.01203 0.01353 0.01624 0.01804 0.02030 0.02320 0.02498 0.02706 0.02824
0.01136 0.01250 0.01389 0.01562 0.01786 0.02083 0.02500 0.02778
0.02273 0.02500 0.02778 0.03125 0.03571 0.04167 0.05000 0.05556
0.01312 0.01443 0.01604 0.01804 0.02062 0.02406 0.02887 0.03208
0.02952 0.03248 0.03608 0.04059 0.04639 0.05413 0.06495 0.07217
0.03125
0.06250
0.03608
0.08119
Flat at Ext. Thd. Crest and Int. Thd. Root
UNIFIED SCREW THREADS
Pitch
Depth of Sharp V-Thread
Threads per Inch
1734
Table 1. American Standard Unified Inch Screw Thread Form Data Depth of Int. Thd. and UN Ext. Thd.a
Machinery's Handbook 27th Edition UNIFIED SCREW THREADS
1735
Table 2. Diameter-Pitch Combinations for Standard Series of Threads (UN/UNR) Sizesa No. or Inches 0 (1) 2 (3) 4 5 6 8 10 (12) 1⁄ 4 5⁄ 16 3⁄ 8 7⁄ 16 1⁄ 2 9⁄ 16 5⁄ 8 (11⁄16) 3⁄ 4 (13⁄16) 7⁄ 8 (15⁄16) 1 (1 1⁄16) 1 1⁄8 (1 3⁄16) 1 1⁄4 1 5⁄16 1 3⁄8 (1 7⁄16) 1 1⁄2 (1 9⁄16) 1 5⁄8 (1 11⁄16) 1 3⁄4 (1 13⁄16) 1 7⁄8 (1 15⁄16) 2 (2 1⁄8) 2 1⁄4 (2 3⁄8) 2 1⁄2 (2 5⁄8) 2 3⁄4 (2 7⁄8) 3 (3 1⁄8) 3 1⁄4 (3 3⁄8) 3 1⁄2 (3 5⁄8) 3 3⁄4 (3 7⁄8) 4
Basic Major Dia. Inches 0.0600 0.0730 0.0860 0.0990 0.1120 0.1250 0.1380 0.1640 0.1900 0.2160 0.2500 0.3125 0.3750 0.4375 0.5000 0.5625 0.6250 0.6875 0.7500 0.8125 0.8750 0.9375 1.0000 1.0625 1.1250 1.1875 1.2500 1.3125 1.3750 1.4375 1.5000 1.5625 1.6250 1.6875 1.7500 1.8125 1.8750 1.9375 2.0000 2.1250 2.2500 2.3750 2.5000 2.6250 2.7500 2.8750 3.0000 3.1250 3.2500 3.3750 3.5000 3.6250 3.7500 3.8750 4.0000
Threads per Inch Series with Graded Pitches Series with Uniform (Constant) Pitches Coarse Fineb Extra finec UNC UNF UNEF 4-UN 6-UN 8-UN 12-UN 16-UN 20-UN 28-UN 32-UN … 80 Series designation shown indicates the UN thread form; however, the UNR 64 72 56 64 thread form may be specified by substituting UNR in place of UN in all 48 56 designations for external threads. 40 48 40 44 … … … … … … … … … 32 40 … … … … … … … … UNC 32 36 … … … … … … … … UNC 24 32 … … … … … … … … UNF 24 28 32 … … … … … … UNF UNEF 20 28 32 … … … … … UNC UNF UNEF 18 24 32 … … … … … 20 28 UNEF 16 24 32 … … … … UNC 20 28 UNEF 14 20 28 … … … … 16 UNF UNEF 32 13 20 28 … … … … 16 UNF UNEF 32 12 18 24 … … … UNC 16 20 28 32 11 18 24 … … … 12 16 20 28 32 … … 24 … … … 12 16 20 28 32 10 16 20 … … … 12 UNF UNEF 28 32 … … 20 … … … 12 16 UNEF 28 32 9 14 20 … … … 12 16 UNEF 28 32 … … 20 … … … 12 16 UNEF 28 32 8 12 20 … … UNC UNF 16 UNEF 28 32 … … 18 … … 8 12 16 20 28 … 7 12 18 … … 8 UNF 16 20 28 … … … 18 … … 8 12 16 20 28 … 7 12 18 … … 8 UNF 16 20 28 … … … 18 … … 8 12 16 20 28 … 6 12 18 … UNC 8 UNF 16 20 28 … … … 18 … 6 8 12 16 20 28 … 6 12 18 … UNC 8 UNF 16 20 28 … … … 18 … 6 8 12 16 20 … … … … 18 … 6 8 12 16 20 … … … … 18 … 6 8 12 16 20 … … 5 … … … 6 8 12 16 20 … … … … … … 6 8 12 16 20 … … … … … … 6 8 12 16 20 … … … … … … 6 8 12 16 20 … … 41⁄2 … … … 6 8 12 16 20 … … … … … … 6 8 12 16 20 … … 4 1⁄2 … … … 6 8 12 16 20 … … … … … … 6 8 12 16 20 … … 4 … … UNC 6 8 12 16 20 … … … … … 4 6 8 12 16 20 … … 4 … … UNC 6 8 12 16 20 … … … … … 4 6 8 12 16 20 … … 4 … … UNC 6 8 12 16 20 … … … … … 4 6 8 12 16 … … … 4 … … UNC 6 8 12 16 … … … … … … 4 6 8 12 16 … … … 4 … … UNC 6 8 12 16 … … … … … … 4 6 8 12 16 … … … 4 … … UNC 6 8 12 16 … … … … … … 4 6 8 12 16 … … … 4 … … UNC 6 8 12 16 … … …
a Sizes shown in parentheses are secondary sizes. Primary sizes of 41⁄ , 41⁄ , 43⁄ , 5, 51⁄ , 51⁄ , 53⁄ and 6 4 2 4 4 2 4 inches also are in the 4, 6, 8, 12, and 16 thread series; secondary sizes of 41⁄8, 43⁄8, 45⁄8, 47⁄8, 51⁄8, 53⁄8, 55⁄8, and 57⁄8 also are in the 4, 6, 8, 12, and 16 thread series. b For diameters over 11⁄ inches, use 12-thread series. 2 c For diameters over 111⁄ inches, use 16-thread series. 16
For UNR thread form substitute UNR for UN for external threads only.
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
1736
Table 3. Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 0–80 UNF 1–64 UNC 1–72 UNF
2–64 UNF 3–48 UNC 3–56 UNF 4–40 UNC 4–48 UNF 5–40 UNC 5–44 UNF 6–32 UNC 6–40 UNF 8–32 UNC 8–36 UNF
Internalb
Class
Allowance
Maxd
Min
Mine
Maxd
Min
UNR Minor Dia.,c Max (Ref.)
2A 3A 2A 3A 2A 3A 2A 3A 2A 3A 2A 3A 2A 3A 2A 3A 2A 3A 2A 3A 2A 3A 2A 3A 2A 3A 2A 3A 2A 3A
0.0005 0.0000 0.0006 0.0000 0.0006 0.0000 0.0006 0.0000 0.0006 0.0000 0.0007 0.0000 0.0007 0.0000 0.0008 0.0000 0.0007 0.0000 0.0008 0.0000 0.0007 0.0000 0.0008 0.0000 0.0008 0.0000 0.0009 0.0000 0.0008 0.0000
0.0595 0.0600 0.0724 0.0730 0.0724 0.0730 0.0854 0.0860 0.0854 0.0860 0.0983 0.0990 0.0983 0.0990 0.1112 0.1120 0.1113 0.1120 0.1242 0.1250 0.1243 0.1250 0.1372 0.1380 0.1372 0.1380 0.1631 0.1640 0.1632 0.1640
0.0563 0.0568 0.0686 0.0692 0.0689 0.0695 0.0813 0.0819 0.0816 0.0822 0.0938 0.0945 0.0942 0.0949 0.1061 0.1069 0.1068 0.1075 0.1191 0.1199 0.1195 0.1202 0.1312 0.1320 0.1321 0.1329 0.1571 0.1580 0.1577 0.1585
— — — — — — — — — — — — — — — — — — — — — — — — — — — — — —
0.0514 0.0519 0.0623 0.0629 0.0634 0.0640 0.0738 0.0744 0.0753 0.0759 0.0848 0.0855 0.0867 0.0874 0.0950 0.0958 0.0978 0.0985 0.1080 0.1088 0.1095 0.1102 0.1169 0.1177 0.1210 0.1218 0.1428 0.1437 0.1452 0.1460
0.0496 0.0506 0.0603 0.0614 0.0615 0.0626 0.0717 0.0728 0.0733 0.0744 0.0825 0.0838 0.0845 0.0858 0.0925 0.0939 0.0954 0.0967 0.1054 0.1069 0.1070 0.1083 0.1141 0.1156 0.1184 0.1198 0.1399 0.1415 0.1424 0.1439
0.0446 0.0451 0.0538 0.0544 0.0559 0.0565 0.0642 0.0648 0.0668 0.0674 0.0734 0.0741 0.0771 0.0778 0.0814 0.0822 0.0864 0.0871 0.0944 0.0952 0.0972 0.0979 0.1000 0.1008 0.1074 0.1082 0.1259 0.1268 0.1301 0.1309
Major Diameter
Pitch Diameter
Minor Diameter Class 2B 3B 2B 3B 2B 3B 2B 3B 2B 3B 2B 3B 2B 3B 2B 3B 2B 3B 2B 3B 2B 3B 2B 3B 2B 3B 2B 3B 2B 3B
Min
Max
0.0465 0.0465 0.0561 0.0561 0.0580 0.0580 0.0667 0.0667 0.0691 0.0691 0.0764 0.0764 0.0797 0.0797 0.0849 0.0849 0.0894 0.0894 0.0979 0.0979 0.1004 0.1004 0.104 0.1040 0.111 0.1110 0.130 0.1300 0.134 0.1340
0.0514 0.0514 0.0623 0.0623 0.0635 0.0635 0.0737 0.0737 0.0753 0.0753 0.0845 0.0845 0.0865 0.0865 0.0939 0.0939 0.0968 0.0968 0.1062 0.1062 0.1079 0.1079 0.114 0.1140 0.119 0.1186 0.139 0.1389 0.142 0.1416
Copyright 2004, Industrial Press, Inc., New York, NY
Pitch Diameter
Major Diameter
Min
Max
Min
0.0519 0.0519 0.0629 0.0629 0.0640 0.0640 0.0744 0.0744 0.0759 0.0759 0.0855 0.0855 0.0874 0.0874 0.0958 0.0958 0.0985 0.0985 0.1088 0.1088 0.1102 0.1102 0.1177 0.1177 0.1218 0.1218 0.1437 0.1437 0.1460 0.1460
0.0542 0.0536 0.0655 0.0648 0.0665 0.0659 0.0772 0.0765 0.0786 0.0779 0.0885 0.0877 0.0902 0.0895 0.0991 0.0982 0.1016 0.1008 0.1121 0.1113 0.1134 0.1126 0.1214 0.1204 0.1252 0.1243 0.1475 0.1465 0.1496 0.1487
0.0600 0.0600 0.0730 0.0730 0.0730 0.0730 0.0860 0.0860 0.0860 0.0860 0.0990 0.0990 0.0990 0.0990 0.1120 0.1120 0.1120 0.1120 0.1250 0.1250 0.1250 0.1250 0.1380 0.1380 0.1380 0.1380 0.1640 0.1640 0.1640 0.1640
UNIFIED SCREW THREADS
2–56 UNC
Externalb
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 10–24 UNC 10–28 UNS 10–32 UNF
12–28 UNF 12–32 UNEF 12–36 UNS 12–40 UNS 12–48 UNS 12–56 UNS 1⁄ –20 UNC 4
1⁄ –24 4 1⁄ –27 4 1⁄ –28 4
Class 2A 3A 2A 2A 3A 2A 2A 2A 2A 2A 3A 2A 3A 2A 3A 2A 2A 2A 2A 1A
0.1890 0.1900 0.1890 0.1891 0.1900 0.1891 0.1891 0.1892 0.1893 0.2150 0.2160 0.2150 0.2160 0.2151 0.2160 0.2151 0.2151 0.2152 0.2153 0.2489
2A 3A 2A
0.0011 0.0000 0.0011
0.2489 0.2500 0.2489
Maxd
Maxd
— — — — — — — — — — — — — — — — — — — —
0.1619 0.1629 0.1658 0.1688 0.1697 0.1711 0.1729 0.1757 0.1777 0.1879 0.1889 0.1918 0.1928 0.1948 0.1957 0.1971 0.1989 0.2017 0.2037 0.2164
Min 0.1586 0.1604 0.1625 0.1658 0.1674 0.1681 0.1700 0.1731 0.1752 0.1845 0.1863 0.1886 0.1904 0.1917 0.1933 0.1941 0.1960 0.1991 0.2012 0.2108
0.2408 0.2419 0.2417
0.2367 — —
0.2164 0.2175 0.2218
0.2127 0.2147 0.2181
0.1894 0.1905 0.1993
Pitch Diameter
Minor Diameter
Pitch Diameter
Major Diameter
Class 2B 3B 2B 2B 3B 2B 2B 2B 2B 2B 3B 2B 3B 2B 3B 2B 2B 2B 2B 1B
Min 0.145 0.1450 0.151 0.156 0.1560 0.160 0.163 0.167 0.171 0.171 0.1710 0.177 0.1770 0.182 0.1820 0.186 0.189 0.193 0.197 0.196
Max 0.156 0.1555 0.160 0.164 0.1641 0.166 0.169 0.172 0.175 0.181 0.1807 0.186 0.1857 0.190 0.1895 0.192 0.195 0.198 0.201 0.207
Min 0.1629 0.1629 0.1668 0.1697 0.1697 0.1720 0.1738 0.1765 0.1784 0.1889 0.1889 0.1928 0.1928 0.1957 0.1957 0.1980 0.1998 0.2025 0.2044 0.2175
Max 0.1672 0.1661 0.1711 0.1736 0.1726 0.1759 0.1775 0.1799 0.1816 0.1933 0.1922 0.1970 0.1959 0.1998 0.1988 0.2019 0.2035 0.2059 0.2076 0.2248
Min 0.1900 0.1900 0.1900 0.1900 0.1900 0.1900 0.1900 0.1900 0.1900 0.2160 0.2160 0.2160 0.2160 0.2160 0.2160 0.2160 0.2160 0.2160 0.2160 0.2500
2B 3B 2B
0.196 0.1960 0.205
0.207 0.2067 0.215
0.2175 0.2175 0.2229
0.2224 0.2211 0.2277
0.2500 0.2500 0.2500
UNS
2A
0.0010
0.2490
0.2423
—
0.2249
0.2214
0.2049
2B
0.210
0.219
0.2259
0.2304
0.2500
UNF
1A
0.0010
0.2490
0.2392
—
0.2258
0.2208
0.2064
1B
0.211
0.220
0.2268
0.2333
0.2500
UNEF
2A 3A 2A
0.0010 0.0000 0.0010
0.2490 0.2500 0.2490
0.2425 0.2435 0.2430
— — —
0.2258 0.2268 0.2287
0.2225 0.2243 0.2255
0.2064 0.2074 0.2118
2B 3B 2B
0.211 0.2110 0.216
0.220 0.2190 0.224
0.2268 0.2268 0.2297
0.2311 0.2300 0.2339
0.2500 0.2500 0.2500
3A
0.0000
0.2500
0.2440
—
0.2297
0.2273
0.2128
3B
0.2160
0.2229
0.2297
0.2328
0.2500
Copyright 2004, Industrial Press, Inc., New York, NY
1737
1⁄ –32 4
UNS
Min 0.1818 0.1828 0.1825 0.1831 0.1840 0.1836 0.1840 0.1847 0.1852 0.2078 0.2088 0.2085 0.2095 0.2091 0.2100 0.2096 0.2100 0.2107 0.2112 0.2367
Mine
Major Diameter
Allowance 0.0010 0.0000 0.0010 0.0009 0.0000 0.0009 0.0009 0.0008 0.0007 0.0010 0.0000 0.0010 0.0000 0.0009 0.0000 0.0009 0.0009 0.0008 0.0007 0.0011
Internalb UNR Minor Dia.,c Max (Ref.) 0.1394 0.1404 0.1464 0.1519 0.1528 0.1560 0.1592 0.1644 0.1681 0.1654 0.1664 0.1724 0.1734 0.1779 0.1788 0.1821 0.1835 0.1904 0.1941 0.1894
UNIFIED SCREW THREADS
10–36 UNS 10–40 UNS 10–48 UNS 10–56 UNS 12–24 UNC
Externalb
Machinery's Handbook 27th Edition
Nominal Size, Threads per Inch, and Series Designationa 1⁄ –36 UNS 4
Maxd
—
0.2311
Min 0.2280
0.2491
0.2440
—
0.2329
0.2300
0.2193
0.2492
0.2447
—
0.2357
0.2330
0.2243
0.0008
0.2492
0.2451
—
0.2376
0.2350
1A
0.0012
0.3113
0.2982
—
0.2752
UN
2A 3A 2A
0.0012 0.0000 0.0012
0.3113 0.3125 0.3113
0.3026 0.3038 0.3032
0.2982 — —
UNF
3A 1A
0.0000 0.0011
0.3125 0.3114
0.3044 0.3006
2A 3A 2A
0.0011 0.0000 0.0010
0.3114 0.3125 0.3115
2A
0.0010
3A 2A
0.0000 0.0010
3A 2A
5⁄ –27 UNS 16 5⁄ –28 UN 16
UNEF
5⁄ –36 UNS 16 5⁄ –40 UNS 16 5⁄ –48 UNS 16 3⁄ –16 UNC 8
3⁄ –18 UNS 8 3⁄ –20 UN 8
Major Diameter
Class 2A
Allowance 0.0009
0.2491
2A
0.0009
2A
0.0008
2A
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Major Diameter
Min 0.220
Max 0.226
Min 0.2320
Max 0.2360
Min 0.2500
2B
0.223
0.229
0.2338
0.2376
0.2500
2B
0.227
0.232
0.2365
0.2401
0.2500
0.2280
2B
0.231
0.235
0.2384
0.2417
0.2500
0.2691
0.2452
1B
0.252
0.265
0.2764
0.2843
0.3125
0.2752 0.2764 0.2788
0.2712 0.2734 0.2748
0.2452 0.2464 0.2518
2B 3B 2B
0.252 0.2520 0.258
0.265 0.2630 0.270
0.2764 0.2764 0.2800
0.2817 0.2803 0.2852
0.3125 0.3125 0.3125
— —
0.2800 0.2843
0.2770 0.2788
0.2530 0.2618
3B 1B
0.2580 0.267
0.2680 0.277
0.2800 0.2854
0.2839 0.2925
0.3125 0.3125
0.3042 0.3053 0.3048
— — —
0.2843 0.2854 0.2874
0.2806 0.2827 0.2839
0.2618 0.2629 0.2674
2B 3B 2B
0.267 0.2670 0.272
0.277 0.2754 0.281
0.2854 0.2854 0.2884
0.2902 0.2890 0.2929
0.3125 0.3125 0.3125
0.3115
0.3050
—
0.2883
0.2849
0.2689
2B
0.274
0.282
0.2893
0.2937
0.3125
0.3125 0.3115
0.3060 0.3055
— —
0.2893 0.2912
0.2867 0.2880
0.2699 0.2743
3B 2B
0.2740 0.279
0.2807 0.286
0.2893 0.2922
0.2926 0.2964
0.3125 0.3125
0.0000 0.0009
0.3125 0.3116
0.3065 0.3061
— —
0.2922 0.2936
0.2898 0.2905
0.2753 0.2785
3B 2B
0.2790 0.282
0.2847 0.289
0.2922 0.2945
0.2953 0.2985
0.3125 0.3125
2A
0.0009
0.3116
0.3065
—
0.2954
0.2925
0.2818
2B
0.285
0.291
0.2963
0.3001
0.3125
2A
0.0008
0.3117
0.3072
—
0.2982
0.2955
0.2869
2B
0.290
0.295
0.2990
0.3026
0.3125
1A
0.0013
0.3737
0.3595
—
0.3331
0.3266
0.2992
1B
0.307
0.321
0.3344
0.3429
0.3750
2A 3A 2A
0.0013 0.0000 0.0013
0.3737 0.3750 0.3737
0.3643 0.3656 0.3650
0.3595 — —
0.3331 0.3344 0.3376
0.3287 0.3311 0.3333
0.2992 0.3005 0.3076
2B 3B 2B
0.307 0.3070 0.315
0.321 0.3182 0.328
0.3344 0.3344 0.3389
0.3401 0.3387 0.3445
0.3750 0.3750 0.3750
2A
0.0012
0.3738
0.3657
—
0.3413
0.3372
0.3143
2B
0.321
0.332
0.3425
0.3479
0.3750
3A
0.0000
0.3750
0.3669
—
0.3425
0.3394
0.3155
3B
0.3210
0.3297
0.3425
0.3465
0.3750
Class 2B
Copyright 2004, Industrial Press, Inc., New York, NY
UNIFIED SCREW THREADS
Min 0.2436
Mine
5⁄ –20 16
5⁄ –32 16
Internalb UNR Minor Dia.,c Max (Ref.) 0.2161
1⁄ –40 UNS 4 1⁄ –48 UNS 4 1⁄ –56 UNS 4 5⁄ –18 UNC 16
5⁄ –24 16
Externalb
1738
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 3⁄ –24 UNF 8 3⁄ –24 UNF 8 3⁄ –27 UNS 8 3⁄ –28 UN 8
UNEF
3⁄ –36 8 3⁄ –40 8
UNS
UNS 0.390–27 UNS 7⁄ –14 UNC 16
7⁄ –16 16
Class 1A
0.3739
2A 3A
0.0011 0.0000
0.3739 0.3750
Maxd
Maxd
—
0.3468
Min 0.3411
0.3667 0.3678
— —
0.3468 0.3479
0.3430 0.3450
0.3243 0.3254
Pitch Diameter
Minor Diameter
Pitch Diameter
Major Diameter
Class 1B
Min 0.330
Max 0.340
Min 0.3479
Max 0.3553
Min 0.3750
2B 3B
0.330 0.3300
0.340 0.3372
0.3479 0.3479
0.3528 0.3516
0.3750 0.3750
2A
0.0011
0.3739
0.3672
—
0.3498
0.3462
0.3298
2B
0.335
0.344
0.3509
0.3556
0.3750
2A
0.0011
0.3739
0.3674
—
0.3507
0.3471
0.3313
2B
0.336
0.345
0.3518
0.3564
0.3750
3A 2A
0.0000 0.0010
0.3750 0.3740
0.3685 0.3680
— —
0.3518 0.3537
0.3491 0.3503
0.3324 0.3368
3B 2B
0.3360 0.341
0.3426 0.349
0.3518 0.3547
0.3553 0.3591
0.3750 0.3750
3A 2A
0.0000 0.0010
0.3750 0.3740
0.3690 0.3685
— —
0.3547 0.3560
0.3522 0.3528
0.3378 0.3409
3B 2B
0.3410 0.345
0.3469 0.352
0.3547 0.3570
0.3580 0.3612
0.3750 0.3750
2A
0.0009
0.3741
0.3690
—
0.3579
0.3548
0.3443
2B
0.348
0.354
0.3588
0.3628
0.3750
2A 1A
0.0011 0.0014
0.3889 0.4361
0.3822 0.4206
— —
0.3648 0.3897
0.3612 0.3826
0.3448 0.3511
2B 1B
0.350 0.360
0.359 0.376
0.3659 0.3911
0.3706 0.4003
0.3900 0.4375
2A 3A 2A
0.0014 0.0000 0.0014
0.4361 0.4375 0.4361
0.4258 0.4272 0.4267
0.4206 — —
0.3897 0.3911 0.3955
0.3850 0.3876 0.3909
0.3511 0.3525 0.3616
2B 3B 2B
0.360 0.3600 0.370
0.376 0.3717 0.384
0.3911 0.3911 0.3969
0.3972 0.3957 0.4028
0.4375 0.4375 0.4375
UNS
3A 2A
0.0000 0.0013
0.4375 0.4362
0.4281 0.4275
— —
0.3969 0.4001
0.3935 0.3958
0.3630 0.3701
3B 2B
0.3700 0.377
0.3800 0.390
0.3969 0.4014
0.4014 0.4070
0.4375 0.4375
UNF
1A
0.0013
0.4362
0.4240
—
0.4037
0.3975
0.3767
1B
0.383
0.395
0.4050
0.4131
0.4375
UNS
2A 3A 2A
0.0013 0.0000 0.0011
0.4362 0.4375 0.4364
0.4281 0.4294 0.4292
— — —
0.4037 0.4050 0.4093
0.3995 0.4019 0.4055
0.3767 0.3780 0.3868
2B 3B 2B
0.383 0.3830 0.392
0.395 0.3916 0.402
0.4050 0.4050 0.4104
0.4104 0.4091 0.4153
0.4375 0.4375 0.4375
UNS
2A
0.0011
0.4364
0.4297
—
0.4123
0.4087
0.3923
2B
0.397
0.406
0.4134
0.4181
0.4375
UNEF
2A
0.0011
0.4364
0.4299
—
0.4132
0.4096
0.3938
2B
0.399
0.407
0.4143
0.4189
0.4375
3A 2A
0.0000 0.0010
0.4375 0.4365
0.4310 0.4305
— —
0.4143 0.4162
0.4116 0.4128
0.3949 0.3993
3B 2B
0.3990 0.404
0.4051 0.411
0.4143 0.4172
0.4178 0.4216
0.4375 0.4375
3A
0.0000
0.4375
0.4315
—
0.4172
0.4147
0.4003
3B
0.4040
0.4094
0.4172
0.4205
0.4375
7⁄ –18 16 7⁄ –20 16
7⁄ –24 16 7⁄ –27 16 7⁄ –28 16
UN
Min 0.3631
Mine
Major Diameter
Allowance 0.0011
Internalb UNR Minor Dia.,c Max (Ref.) 0.3243
7⁄ –32 16
UN
UNIFIED SCREW THREADS
3⁄ –32 8
Externalb
1739
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Nominal Size, Threads per Inch, and Series Designationa 1⁄ –12 UNS 2 1⁄ –13 2
1⁄ –28 2
Major Diameter
Min 0.4870
Mine
Maxd
—
0.4443
Min 0.4389
0.5000 0.4985
0.4886 0.4822
— —
0.4459 0.4485
0.4419 0.4411
0.4008 0.4069
3B 1B
0.4100 0.417
0.4223 0.434
0.4459 0.4500
0.4511 0.4597
0.5000 0.5000
0.0015 0.0000 0.0015
0.4985 0.5000 0.4985
0.4876 0.4891 0.4882
0.4822 — —
0.4485 0.4500 0.4521
0.4435 0.4463 0.4471
0.4069 0.4084 0.4135
2B 3B 2B
0.417 0.4170 0.423
0.434 0.4284 0.438
0.4500 0.4500 0.4536
0.4565 0.4548 0.4601
0.5000 0.5000 0.5000
2A
0.0014
0.4986
0.4892
—
0.4580
0.4533
0.4241
2B
0.432
0.446
0.4594
0.4655
0.5000
UNS
3A 2A
0.0000 0.0013
0.5000 0.4987
0.4906 0.4900
— —
0.4594 0.4626
0.4559 0.4582
0.4255 0.4326
3B 2B
0.4320 0.440
0.4419 0.453
0.4594 0.4639
0.4640 0.4697
0.5000 0.5000
UNF
1A
0.0013
0.4987
0.4865
—
0.4662
0.4598
0.4392
1B
0.446
0.457
0.4675
0.4759
0.5000
UNS
2A 3A 2A
0.0013 0.0000 0.0012
0.4987 0.5000 0.4988
0.4906 0.4919 0.4916
— — —
0.4662 0.4675 0.4717
0.4619 0.4643 0.4678
0.4392 0.4405 0.4492
2B 3B 2B
0.446 0.4460 0.455
0.457 0.4537 0.465
0.4675 0.4675 0.4729
0.4731 0.4717 0.4780
0.5000 0.5000 0.5000
UNC
Major Diameter
Class 2A
Allowance 0.0016
0.4984
3A 1A
0.0000 0.0015
2A 3A 2A
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 0.410
Max 0.428
Min 0.4459
Max 0.4529
Min 0.5000
UNS
2A
0.0011
0.4989
0.4922
—
0.4748
0.4711
0.4548
2B
0.460
0.469
0.4759
0.4807
0.5000
UNEF
2A
0.0011
0.4989
0.4924
—
0.4757
0.4720
0.4563
2B
0.461
0.470
0.4768
0.4816
0.5000
UN
3A 2A
0.0000 0.0010
0.5000 0.4990
0.4935 0.4930
— —
0.4768 0.4787
0.4740 0.4752
0.4574 0.4618
3B 2B
0.4610 0.466
0.4676 0.474
0.4768 0.4797
0.4804 0.4842
0.5000 0.5000
UNC
3A 1A
0.0000 0.0016
0.5000 0.5609
0.4940 0.5437
— —
0.4797 0.5068
0.4771 0.4990
0.4628 0.4617
3B 1B
0.4660 0.472
0.4719 0.490
0.4797 0.5084
0.4831 0.5186
0.5000 0.5625
2A 3A 2A
0.0016 0.0000 0.0015
0.5609 0.5625 0.5610
0.5495 0.5511 0.5507
0.5437 — —
0.5068 0.5084 0.5146
0.5016 0.5045 0.5096
0.4617 0.4633 0.4760
2B 3B 2B
0.472 0.4720 0.485
0.490 0.4843 0.501
0.5084 0.5084 0.5161
0.5152 0.5135 0.5226
0.5625 0.5625 0.5625
2A
0.0014
0.5611
0.5517
—
0.5205
0.5158
0.4866
2B
0.495
0.509
0.5219
0.5280
0.5625
3A 1A
0.0000 0.0014
0.5625 0.5611
0.5531 0.5480
— —
0.5219 0.5250
0.5184 0.5182
0.4880 0.4950
3B 1B
0.4950 0.502
0.5040 0.515
0.5219 0.5264
0.5265 0.5353
0.5625 0.5625
2A 3A
0.0014 0.0000
0.5611 0.5625
0.5524 0.5538
— —
0.5250 0.5264
0.5205 0.5230
0.4950 0.4964
2B 3B
0.502 0.5020
0.515 0.5106
0.5264 0.5264
0.5323 0.5308
0.5625 0.5625
1⁄ –32 2 9⁄ –12 16
9⁄ –14 UNS 16 9⁄ –16 UN 16 9⁄ –18 16
UNF
Copyright 2004, Industrial Press, Inc., New York, NY
UNIFIED SCREW THREADS
1⁄ –24 2 1⁄ –27 2
Internalb UNR Minor Dia.,c Max (Ref.) 0.3992
1⁄ –14 UNS 2 1⁄ –16 UN 2 1⁄ –18 2 1⁄ –20 2
Externalb
1740
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 9⁄ –20 UN 16 9⁄ –24 16
UNEF
Class 2A
0.5612
3A 2A
0.0000 0.0012
0.5625 0.5613
Maxd
Major Diameter
Min 0.5531
Mine
Maxd
—
0.5287
Min 0.5245
0.5544 0.5541
— —
0.5300 0.5342
0.5268 0.5303
0.5030 0.5117
3B 2B
0.5080 0.517
0.5162 0.527
0.5300 0.5354
0.5341 0.5405
0.5625 0.5625 0.5625 0.5625
Major Diameter
Allowance 0.0013
Internalb UNR Minor Dia.,c Max (Ref.) 0.5017
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 0.508
Max 0.520
Min 0.5300
Max 0.5355
Min 0.5625
0.0000 0.0011
0.5625 0.5614
0.5553 0.5547
— —
0.5354 0.5373
0.5325 0.5336
0.5129 0.5173
3B 2B
0.5170 0.522
0.5244 0.531
0.5354 0.5384
0.5392 0.5432
0.0011
0.5614
0.5549
—
0.5382
0.5345
0.5188
2B
0.524
0.532
0.5393
0.5441
0.5625
UN
3A 2A
0.0000 0.0010
0.5625 0.5615
0.5560 0.5555
— —
0.5393 0.5412
0.5365 0.5377
0.5199 0.5243
3B 2B
0.5240 0.529
0.5301 0.536
0.5393 0.5422
0.5429 0.5467
0.5625 0.5625
UNC
3A 1A
0.0000 0.0016
0.5625 0.6234
0.5565 0.6052
— —
0.5422 0.5644
0.5396 0.5561
0.5253 0.5152
3B 1B
0.5290 0.527
0.5344 0.546
0.5422 0.5660
0.5456 0.5767
0.5625 0.6250
2A 3A 2A
0.0016 0.0000 0.0016
0.6234 0.6250 0.6234
0.6113 0.6129 0.6120
0.6052 — —
0.5644 0.5660 0.5693
0.5589 0.5619 0.5639
0.5152 0.5168 0.5242
2B 3B 2B
0.527 0.5270 0.535
0.546 0.5391 0.553
0.5660 0.5660 0.5709
0.5732 0.5714 0.5780
0.6250 0.6250 0.6250
0.5258 0.5385
3B 2B
0.5350 0.548
0.5463 0.564
0.5709 0.5786
0.5762 0.5852
0.6250 0.6250
9⁄ –32 16
5⁄ –12 8
UN
3A 2A
0.0000 0.0015
0.6250 0.6235
0.6136 0.6132
— —
0.5709 0.5771
0.5668 0.5720
2A
0.0014
0.6236
0.6142
—
0.5830
0.5782
0.5491
2B
0.557
0.571
0.5844
0.5906
0.6250
5⁄ –18 8
3A 1A
0.0000 0.0014
0.6250 0.6236
0.6156 0.6105
— —
0.5844 0.5875
0.5808 0.5805
0.5505 0.5575
3B 1B
0.5570 0.565
0.5662 0.578
0.5844 0.5889
0.5890 0.5980
0.6250 0.6250
UN
2A 3A 2A
0.0014 0.0000 0.0013
0.6236 0.6250 0.6237
0.6149 0.6163 0.6156
— — —
0.5875 0.5889 0.5912
0.5828 0.5854 0.5869
0.5575 0.5589 0.5642
2B 3B 2B
0.565 0.5650 0.571
0.578 0.5730 0.582
0.5889 0.5889 0.5925
0.5949 0.5934 0.5981
0.6250 0.6250 0.6250
UNEF
3A 2A
0.0000 0.0012
0.6250 0.6238
0.6169 0.6166
— —
0.5925 0.5967
0.5893 0.5927
0.5655 0.5742
3B 2B
0.5710 0.580
0.5787 0.590
0.5925 0.5979
0.5967 0.6031
0.6250 0.6250
3A 2A
0.0000 0.0011
0.6250 0.6239
0.6178 0.6172
— —
0.5979 0.5998
0.5949 0.5960
0.5754 0.5798
3B 2B
0.5800 0.585
0.5869 0.594
0.5979 0.6009
0.6018 0.6059
0.6250 0.6250
2A
0.0011
0.6239
0.6174
—
0.6007
0.5969
0.5813
2B
0.586
0.595
0.6018
0.6067
0.6250
3A
0.0000
0.6250
0.6185
—
0.6018
0.5990
0.5824
3B
0.5860
0.5926
0.6018
0.6055
0.6250
UNF
5⁄ –20 8 5⁄ –24 8
5⁄ –27 UNS 8 5⁄ –28 UN 8
Copyright 2004, Industrial Press, Inc., New York, NY
1741
5⁄ –14 UNS 8 5⁄ –16 UN 8
UNIFIED SCREW THREADS
3A 2A 2A
9⁄ –27 UNS 16 9⁄ –28 UN 16
5⁄ –11 8
Externalb
Machinery's Handbook 27th Edition
Nominal Size, Threads per Inch, and Series Designationa 5⁄ –32 UN 8
Externalb
Class 2A
0.6239
Maxd
Internalb
Min 0.6179
Mine
Maxd
—
0.6036
Min 0.6000
UNR Minor Dia.,c Max (Ref.) 0.5867
Major Diameter
Allowance 0.0011
1742
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads
Pitch Diameter
Minor Diameter
Pitch Diameter
Major Diameter
Class 2B
Min 0.591
Max 0.599
Min 0.6047
Max 0.6093
Min 0.6250
UN
3A 2A
0.0000 0.0016
0.6250 0.6859
0.6190 0.6745
— —
0.6047 0.6318
0.6020 0.6264
0.5878 0.5867
3B 2B
0.5910 0.597
0.5969 0.615
0.6047 0.6334
0.6082 0.6405
0.6250 0.6875
11⁄ –16 16
UN
3A 2A
0.0000 0.0014
0.6875 0.6861
0.6761 0.6767
— —
0.6334 0.6455
0.6293 0.6407
0.5883 0.6116
3B 2B
0.5970 0.620
0.6085 0.634
0.6334 0.6469
0.6387 0.6531
0.6875 0.6875
UN
3A 2A
0.0000 0.0013
0.6875 0.6862
0.6781 0.6781
— —
0.6469 0.6537
0.6433 0.6494
0.6130 0.6267
3B 2B
0.6200 0.633
0.6284 0.645
0.6469 0.6550
0.6515 0.6606
0.6875 0.6875
UNEF
3A 2A
0.0000 0.0012
0.6875 0.6863
0.6794 0.6791
— —
0.6550 0.6592
0.6518 0.6552
0.6280 0.6367
3B 2B
0.6330 0.642
0.6412 0.652
0.6550 0.6604
0.6592 0.6656
0.6875 0.6875
11⁄ –20 16 11⁄ –24 16
11⁄ –28 16
UN
3A 2A
0.0000 0.0011
0.6875 0.6864
0.6803 0.6799
— —
0.6604 0.6632
0.6574 0.6594
0.6379 0.6438
3B 2B
0.6420 0.649
0.6494 0.657
0.6604 0.6643
0.6643 0.6692
0.6875 0.6875
11⁄ –32 16
UN
3A 2A
0.0000 0.0011
0.6875 0.6864
0.6810 0.6804
— —
0.6643 0.6661
0.6615 0.6625
0.6449 0.6492
3B 2B
0.6490 0.654
0.6551 0.661
0.6643 0.6672
0.6680 0.6718
0.6875 0.6875
UNC
3A 1A
0.0000 0.0018
0.6875 0.7482
0.6815 0.7288
— —
0.6672 0.6832
0.6645 0.6744
0.6503 0.6291
3B 1B
0.6540 0.642
0.6594 0.663
0.6672 0.6850
0.6707 0.6965
0.6875 0.7500
UN
2A 3A 2A
0.0018 0.0000 0.0017
0.7482 0.7500 0.7483
0.7353 0.7371 0.7369
0.7288 — —
0.6832 0.6850 0.6942
0.6773 0.6806 0.6887
0.6291 0.6309 0.6491
2B 3B 2B
0.642 0.6420 0.660
0.663 0.6545 0.678
0.6850 0.6850 0.6959
0.6927 0.6907 0.7031
0.7500 0.7500 0.7500
UNS
3A 2A
0.0000 0.0015
0.7500 0.7485
0.7386 0.7382
— —
0.6959 0.7021
0.6918 0.6970
0.6508 0.6635
3B 2B
0.6600 0.673
0.6707 0.688
0.6959 0.7036
0.7013 0.7103
0.7500 0.7500
UNF
1A
0.0015
0.7485
0.7343
—
0.7079
0.7004
0.6740
1B
0.682
0.696
0.7094
0.7192
0.7500
UNS
2A 3A 2A
0.0015 0.0000 0.0014
0.7485 0.7500 0.7486
0.7391 0.7406 0.7399
— — —
0.7079 0.7094 0.7125
0.7029 0.7056 0.7079
0.6740 0.6755 0.6825
2B 3B 2B
0.682 0.6820 0.690
0.696 0.6908 0.703
0.7094 0.7094 0.7139
0.7159 0.7143 0.7199
0.7500 0.7500 0.7500
UNEF
2A
0.0013
0.7487
0.7406
—
0.7162
0.7118
0.6892
2B
0.696
0.707
0.7175
0.7232
0.7500
UNS
3A 2A
0.0000 0.0012
0.7500 0.7488
0.7419 0.7416
— —
0.7175 0.7217
0.7142 0.7176
0.6905 0.6992
3B 2B
0.6960 0.705
0.7037 0.715
0.7175 0.7229
0.7218 0.7282
0.7500 0.7500
UNS
2A
0.0012
0.7488
0.7421
—
0.7247
0.7208
0.7047
2B
0.710
0.719
0.7259
0.7310
0.7500
3⁄ –10 4
3⁄ –12 4 3⁄ –14 4 3⁄ –16 4
3⁄ –18 4 3⁄ –20 4
3⁄ –24 4 3⁄ –24 4
Copyright 2004, Industrial Press, Inc., New York, NY
UNIFIED SCREW THREADS
11⁄ –12 16
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 3⁄ –28 UN 4
—
0.7256
Min 0.7218
0.7500 0.7489
0.7435 0.7429
— —
0.7268 0.7286
0.7239 0.7250
0.7074 0.7117
3B 2B
0.7110 0.716
0.7176 0.724
0.7268 0.7297
0.7305 0.7344
0.7500 0.7500
0.0000 0.0017
0.7500 0.8108
0.7440 0.7994
— —
0.7297 0.7567
0.7270 0.7512
0.7128 0.7116
3B 2B
0.7160 0.722
0.7219 0.740
0.7297 0.7584
0.7333 0.7656
0.7500 0.8125
0.0000 0.0015
0.8125 0.8110
0.8011 0.8016
— —
0.7584 0.7704
0.7543 0.7655
0.7133 0.7365
3B 2B
0.7220 0.745
0.7329 0.759
0.7584 0.7719
0.7638 0.7782
0.8125 0.8125
3A 2A
0.0000 0.0013
0.8125 0.8112
0.8031 0.8031
— —
0.7719 0.7787
0.7683 0.7743
0.7380 0.7517
3B 2B
0.7450 0.758
0.7533 0.770
0.7719 0.7800
0.7766 0.7857
0.8125 0.8125
3A 2A
0.0000 0.0011
UN
3A 2A
UN
3A 2A
UNEF
13⁄ –16 16
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 0.711
Max 0.720
Min 0.7268
Max 0.7318
Min 0.7500
UN
3A 2A
0.0000 0.0012
0.8125 0.8113
0.8044 0.8048
— —
0.7800 0.7881
0.7767 0.7843
0.7530 0.7687
3B 2B
0.7580 0.774
0.7662 0.782
0.7800 0.7893
0.7843 0.7943
0.8125 0.8125
13⁄ –32 16
UN
3A 2A
0.0000 0.0011
0.8125 0.8114
0.8060 0.8054
— —
0.7893 0.7911
0.7864 0.7875
0.7699 0.7742
3B 2B
0.7740 0.779
0.7801 0.786
0.7893 0.7922
0.7930 0.7969
0.8125 0.8125
UNC
3A 1A
0.0000 0.0019
0.8125 0.8731
0.8065 0.8523
— —
0.7922 0.8009
0.7895 0.7914
0.7753 0.7408
3B 1B
0.7790 0.755
0.7844 0.778
0.7922 0.8028
0.7958 0.8151
0.8125 0.8750
7⁄ –10 UNS 8 7⁄ –12 UN 8
2A 3A 2A
0.0019 0.0000 0.0018
0.8731 0.8750 0.8732
0.8592 0.8611 0.8603
0.8523 — —
0.8009 0.8028 0.8082
0.7946 0.7981 0.8022
0.7408 0.7427 0.7542
2B 3B 2B
0.755 0.7550 0.767
0.778 0.7681 0.788
0.8028 0.8028 0.8100
0.8110 0.8089 0.8178
0.8750 0.8750 0.8750
2A
0.0017
0.8733
0.8619
—
0.8192
0.8137
0.7741
2B
0.785
0.803
0.8209
0.8281
0.8750
7⁄ –14 8
3A 1A
0.0000 0.0016
0.8750 0.8734
0.8636 0.8579
— —
0.8209 0.8270
0.8168 0.8189
0.7758 0.7884
3B 1B
0.7850 0.798
0.7948 0.814
0.8209 0.8286
0.8263 0.8392
0.8750 0.8750
UN
2A 3A 2A
0.0016 0.0000 0.0015
0.8734 0.8750 0.8735
0.8631 0.8647 0.8641
— — —
0.8270 0.8286 0.8329
0.8216 0.8245 0.8280
0.7884 0.7900 0.7900
2B 3B 2B
0.798 0.7980 0.807
0.814 0.8068 0.821
0.8286 0.8286 0.8344
0.8356 0.8339 0.8407
0.8750 0.8750 0.8750
UNS
3A 2A
0.0000 0.0014
0.8750 0.8736
0.8656 0.8649
— —
0.8344 0.8375
0.8308 0.8329
0.8005 0.8075
3B 2B
0.8070 0.815
0.8158 0.828
0.8344 0.8389
0.8391 0.8449
0.8750 0.8750
UNEF
2A
0.0013
0.8737
0.8656
—
0.8412
0.8368
0.8142
2B
0.821
0.832
0.8425
0.8482
0.8750
3A
0.0000
0.8750
0.8669
—
0.8425
0.8392
0.8155
3B
0.8210
0.8287
0.8425
0.8468
0.8750
7⁄ –9 8
UNF
7⁄ –16 8 7⁄ –18 8 7⁄ –20 8
Copyright 2004, Industrial Press, Inc., New York, NY
1743
13⁄ –28 16
UNIFIED SCREW THREADS
Min 0.7423
Maxd
0.7488
13⁄ –12 16
Major Diameter
Mine
Major Diameter
Class 2A
UN
Internalb UNR Minor Dia.,c Max (Ref.) 0.7062
Allowance 0.0012
3⁄ –32 4
13⁄ –20 16
Externalb
Machinery's Handbook 27th Edition
Externalb
1744
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Internalb
Nominal Size, Threads per Inch, and Series Designationa 7⁄ –24 UNS 8
Class 2A
7⁄ –27 UNS 8 7⁄ –28 UN 8
2A
0.0012
0.8738
0.8671
—
0.8497
0.8458
0.8297
2B
0.835
0.844
0.8509
0.8560
0.8750
2A
0.0012
0.8738
0.8673
—
0.8506
0.8468
0.8312
2B
0.836
0.845
0.8518
0.8568
0.8750
3A 2A
0.0000 0.0011
0.8750 0.8739
0.8685 0.8679
— —
0.8518 0.8536
0.8489 0.8500
0.8324 0.8367
3B 2B
0.8360 0.841
0.8426 0.849
0.8518 0.8547
0.8555 0.8594
0.8750 0.8750
7⁄ –32 8
UN
Allowance 0.0012
Major Diameter Maxd 0.8738
Min 0.8666
Pitch Diameter Mine
Maxd
—
0.8467
Min 0.8426
UNR Minor Dia.,c Max (Ref.) 0.8242
Minor Diameter Class 2B
Min 0.830
Max 0.840
Pitch Diameter Min 0.8479
Max 0.8532
Major Diameter Min 0.8750
UN
3A 2A
0.0000 0.0017
0.8750 0.9358
0.8690 0.9244
— —
0.8547 0.8817
0.8520 0.8760
0.8378 0.8366
3B 2B
0.8410 0.847
0.8469 0.865
0.8547 0.8834
0.8583 0.8908
0.8750 0.9375
15⁄ –16 16
UN
3A 2A
0.0000 0.0015
0.9375 0.9360
0.9261 0.9266
— —
0.8834 0.8954
0.8793 0.8904
0.8383 0.8615
3B 2B
0.8470 0.870
0.8575 0.884
0.8834 0.8969
0.8889 0.9034
0.9375 0.9375
UNEF
3A 2A
0.0000 0.0014
0.9375 0.9361
0.9281 0.9280
— —
0.8969 0.9036
0.8932 0.8991
0.8630 0.8766
3B 2B
0.8700 0.883
0.8783 0.895
0.8969 0.9050
0.9018 0.9109
0.9375 0.9375
15⁄ –20 16
15⁄ –28 16
UN
3A 2A
0.0000 0.0012
0.9375 0.9363
0.9294 0.9298
— —
0.9050 0.9131
0.9016 0.9091
0.8780 0.8937
3B 2B
0.8830 0.899
0.8912 0.907
0.9050 0.9143
0.9094 0.9195
0.9375 0.9375
15⁄ –32 16
UN
3A 2A
0.0000 0.0011
0.9375 0.9364
0.9310 0.9304
— —
0.9143 0.9161
0.9113 0.9123
0.8949 0.8992
3B 2B
0.8990 0.904
0.9051 0.911
0.9143 0.9172
0.9182 0.9221
0.9375 0.9375
3A 1A 2A 3A 2A 1A 2A 3A 1A 2A 3A 2A 3A 2A
0.0000 0.0020 0.0020 0.0000 0.0018 0.0018 0.0018 0.0000 0.0017 0.0017 0.0000 0.0015 0.0000 0.0014
0.9375 0.9980 0.9980 1.0000 0.9982 0.9982 0.9982 1.0000 0.9983 0.9983 1.0000 0.9985 1.0000 0.9986
0.9315 0.9755 0.9830 0.9850 0.9853 0.9810 0.9868 0.9886 0.9828 0.9880 0.9897 0.9891 0.9906 0.9899
— — 0.9755 — — — — — — — — — — —
0.9172 0.9168 0.9168 0.9188 0.9332 0.9441 0.9441 0.9459 0.9519 0.9519 0.9536 0.9579 0.9594 0.9625
0.9144 0.9067 0.9100 0.9137 0.9270 0.9353 0.9382 0.9415 0.9435 0.9463 0.9494 0.9529 0.9557 0.9578
0.9003 0.8492 0.8492 0.8512 0.8792 0.8990 0.8990 0.9008 0.9132 0.9132 0.9149 0.9240 0.9255 0.9325
3B 1B 2B 3B 2B 1B 2B 3B 1B 2B 3B 2B 3B 2B
0.9040 0.865 0.865 0.8650 0.892 0.910 0.910 0.9100 0.923 0.923 0.9230 0.932 0.9320 0.940
0.9094 0.890 0.890 0.8797 0.913 0.928 0.928 0.9198 0.938 0.938 0.9315 0.946 0.9408 0.953
0.9172 0.9188 0.9188 0.9188 0.9350 0.9459 0.9459 0.9459 0.9536 0.9536 0.9536 0.9594 0.9594 0.9639
0.9209 0.9320 0.9276 0.9254 0.9430 0.9573 0.9535 0.9516 0.9645 0.9609 0.9590 0.9659 0.9643 0.9701
0.9375 1.0000 1.0000 1.0000 1.0000 1.0000 1.0000 1.0000 1.0000 1.0000 1.0000 1.0000 1.0000 1.0000
1–8 UNC
1–10 UNS 1–12 UNF
1–14 UNSf
1–16 UN 1–18 UNS
Copyright 2004, Industrial Press, Inc., New York, NY
UNIFIED SCREW THREADS
15⁄ –12 16
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 1–20 UNEF
Externalb
Internalb Major Diameter
— — — — — — — — —
0.9661 0.9675 0.9716 0.9747 0.9756 0.9768 0.9786 0.9797 0.9793
Min 0.9616 0.9641 0.9674 0.9707 0.9716 0.9738 0.9748 0.9769 0.9725
1.0625 1.0608
1.0475 1.0494
— —
0.9813 1.0067
0.9762 1.0010
0.9137 0.9616
3B 2B
0.9270 0.972
0.9422 0.990
0.9813 1.0084
0.9880 1.0158
1.0625 1.0625
0.0000 0.0015
1.0625 1.0610
1.0511 1.0516
— —
1.0084 1.0204
1.0042 1.0154
0.9633 0.9865
3B 2B
0.9720 0.995
0.9823 1.009
1.0084 1.0219
1.0139 1.0284
1.0625 1.0625
3A 2A
0.0000 0.0014
1.0625 1.0611
1.0531 1.0524
— —
1.0219 1.0250
1.0182 1.0203
0.9880 0.9950
3B 2B
0.9950 1.002
1.0033 1.015
1.0219 1.0264
1.0268 1.0326
1.0625 1.0625
11⁄16–20 UN
3A 2A
0.0000 0.0014
1.0625 1.0611
1.0538 1.0530
— —
1.0264 1.0286
1.0228 1.0241
0.9964 1.0016
3B 2B
1.0020 1.008
1.0105 1.020
1.0264 1.0300
1.0310 1.0359
1.0625 1.0625
11⁄16–28 UN
3A 2A
0.0000 0.0012
1.0625 1.0613
1.0544 1.0548
— —
1.0300 1.0381
1.0266 1.0341
1.0030 1.0187
3B 2B
1.0080 1.024
1.0162 1.032
1.0300 1.0393
1.0344 1.0445
1.0625 1.0625
11⁄8–7 UNC
3A 1A
0.0000 0.0022
1.0625 1.1228
1.0560 1.0982
— —
1.0393 1.0300
1.0363 1.0191
1.0199 0.9527
3B 1B
1.0240 0.970
1.0301 0.998
1.0393 1.0322
1.0432 1.0463
1.0625 1.1250
11⁄8–8 UN
2A 3A 2A
0.0022 0.0000 0.0021
1.1228 1.1250 1.1229
1.1064 1.1086 1.1079
1.0982 — 1.1004
1.0300 1.0322 1.0417
1.0228 1.0268 1.0348
0.9527 0.9549 0.9741
2B 3B 2B
0.970 0.9700 0.990
0.998 0.9875 1.015
1.0322 1.0322 1.0438
1.0416 1.0393 1.0528
1.1250 1.1250 1.1250
11⁄8–10 UNS
3A 2A
0.0000 0.0018
1.1250 1.1232
1.1100 1.1103
— —
1.0438 1.0582
1.0386 1.0520
0.9762 1.0042
3B 2B
0.9900 1.017
1.0047 1.038
1.0438 1.0600
1.0505 1.0680
1.1250 1.1250
11⁄8–12 UNF
1A
0.0018
1.1232
1.1060
—
1.0691
1.0601
1.0240
1B
1.035
1.053
1.0709
1.0826
1.1250
2A 3A
0.0018 0.0000
1.1232 1.1250
1.1118 1.1136
— —
1.0691 1.0709
1.0631 1.0664
1.0240 1.0258
2B 3B
1.035 1.0350
1.053 1.0448
1.0709 1.0709
1.0787 1.0768
1.1250 1.1250
11⁄16–8 UN
Class 2A 3A 2A 2A 2A 3A 2A 3A 2A
0.9986 1.0000 0.9987 0.9988 0.9988 1.0000 0.9989 1.0000 1.0605
11⁄16–12 UN
3A 2A
0.0000 0.0017
11⁄16–16 UN
3A 2A
11⁄16–18 UNEF
1–24 UNS 1–27 UNS 1–28 UN 1–32 UN
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B 3B 2B 2B 2B 3B 2B 3B 2B
Min 0.946 0.9460 0.955 0.960 0.961 0.9610 0.966 0.9660 0.927
Max 0.957 0.9537 0.965 0.969 0.970 0.9676 0.974 0.9719 0.952
Min 0.9675 0.9675 0.9729 0.9759 0.9768 0.9768 0.9797 0.9797 0.9813
Max 0.9734 0.9719 0.9784 0.9811 0.9820 0.9807 0.9846 0.9834 0.9902
Min 1.0000 1.0000 1.0000 1.0000 1.0000 1.0000 1.0000 1.0000 1.0625
Copyright 2004, Industrial Press, Inc., New York, NY
1745
Maxd
Major Diameter
Allowance 0.0014 0.0000 0.0013 0.0012 0.0012 0.0000 0.0011 0.0000 0.0020
UNIFIED SCREW THREADS
Min 0.9905 0.9919 0.9915 0.9921 0.9923 0.9935 0.9929 0.9940 1.0455
Mine
UNR Minor Dia.,c Max (Ref.) 0.9391 0.9405 0.9491 0.9547 0.9562 0.9574 0.9617 0.9628 0.9117
Machinery's Handbook 27th Edition
Nominal Size, Threads per Inch, and Series Designationa 11⁄8–14 UNS
Externalb Major Diameter 1.1234
UN
2A
0.0015
UNEF
3A 2A
0.0000 0.0014
UN
3A 2A
11⁄8–24 UNS
3A 2A
11⁄8–16 11⁄8–18
11⁄8–20
11⁄8–28
Maxd
Internalb Pitch Diameter
UNR Minor Dia.,c Max (Ref.) 1.0384
Minor Diameter
Pitch Diameter
Major Diameter
Min 1.1131
Mine
Maxd
—
1.0770
Min 1.0717
1.1235
1.1141
—
1.0829
1.0779
1.0490
2B
1.057
1.071
1.0844
1.0909
1.1250
1.1250 1.1236
1.1156 1.1149
— —
1.0844 1.0875
1.0807 1.0828
1.0505 1.0575
3B 2B
1.0570 1.065
1.0658 1.078
1.0844 1.0889
1.0893 1.0951
1.1250 1.1250
0.0000 0.0014
1.1250 1.1236
1.1163 1.1155
— —
1.0889 1.0911
1.0853 1.0866
1.0589 1.0641
3B 2B
1.0650 1.071
1.0730 1.082
1.0889 1.0925
1.0935 1.0984
1.1250 1.1250
0.0000 0.0013
1.1250 1.1237
1.1169 1.1165
— —
1.0925 1.0966
1.0891 1.0924
1.0655 1.0742
3B 2B
1.0710 1.080
1.0787 1.090
1.0925 1.0979
1.0969 1.1034
1.1250 1.1250
Class 2B
Min 1.048
Max 1.064
Min 1.0786
Max 1.0855
Min 1.1250
UN
2A
0.0012
1.1238
1.1173
—
1.1006
1.0966
1.0812
2B
1.086
1.095
1.1018
1.1070
1.1250
13⁄16–8
UN
3A 2A
0.0000 0.0021
1.1250 1.1854
1.1185 1.1704
— —
1.1018 1.1042
1.0988 1.0972
1.0824 1.0366
3B 2B
1.0860 1.052
1.0926 1.077
1.1018 1.1063
1.1057 1.1154
1.1250 1.1875
13⁄16–12
UN
3A 2A
0.0000 0.0017
1.1875 1.1858
1.1725 1.1744
— —
1.1063 1.1317
1.1011 1.1259
1.0387 1.0866
3B 2B
1.0520 1.097
1.0672 1.115
1.1063 1.1334
1.1131 1.1409
1.1875 1.1875
13⁄16–16 UN
3A 2A
0.0000 0.0015
1.1875 1.1860
1.1761 1.1766
— —
1.1334 1.1454
1.1291 1.1403
1.0883 1.1115
3B 2B
1.0970 1.120
1.1073 1.134
1.1334 1.1469
1.1390 1.1535
1.1875 1.1875
13⁄16–18 UNEF
3A 2A
0.0000 0.0015
1.1875 1.1860
1.1781 1.1773
— —
1.1469 1.1499
1.1431 1.1450
1.1130 1.1199
3B 2B
1.1200 1.127
1.1283 1.140
1.1469 1.1514
1.1519 1.1577
1.1875 1.1875
13⁄16–20 UN
3A 2A
0.0000 0.0014
1.1875 1.1861
1.1788 1.1780
— —
1.1514 1.1536
1.1478 1.1489
1.1214 1.1266
3B 2B
1.1270 1.133
1.1355 1.145
1.1514 1.1550
1.1561 1.1611
1.1875 1.1875
13⁄16–28 UN
3A 2A
0.0000 0.0012
1.1875 1.1863
1.1794 1.1798
— —
1.1550 1.1631
1.1515 1.1590
1.1280 1.1437
3B 2B
1.1330 1.149
1.1412 1.157
1.1550 1.1643
1.1595 1.1696
1.1875 1.1875
11⁄4–7 UNC
3A 1A
0.0000 0.0022
1.1875 1.2478
1.1810 1.2232
— —
1.1643 1.1550
1.1612 1.1439
1.1449 1.0777
3B 1B
1.1490 1.095
1.1551 1.123
1.1643 1.1572
1.1683 1.1716
1.1875 1.2500
11⁄4–8 UN
2A 3A 2A
0.0022 0.0000 0.0021
1.2478 1.2500 1.2479
1.2314 1.2336 1.2329
1.2232 — 1.2254
1.1550 1.1572 1.1667
1.1476 1.1517 1.1597
1.0777 1.0799 1.0991
2B 3B 2B
1.095 1.0950 1.115
1.123 1.1125 1.140
1.1572 1.1572 1.1688
1.1668 1.1644 1.1780
1.2500 1.2500 1.2500
11⁄4–10 UNS
3A 2A
0.0000 0.0019
1.2500 1.2481
1.2350 1.2352
— —
1.1688 1.1831
1.1635 1.1768
1.1012 1.1291
3B 2B
1.1150 1.142
1.1297 1.163
1.1688 1.1850
1.1757 1.1932
1.2500 1.2500
Copyright 2004, Industrial Press, Inc., New York, NY
UNIFIED SCREW THREADS
Class 2A
Allowance 0.0016
1746
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 11⁄4–12 UNF
Externalb
Internalb Major Diameter
—
1.1941
Min 1.1849
1.2482 1.2500 1.2484
1.2368 1.2386 1.2381
— — —
1.1941 1.1959 1.2020
1.1879 1.1913 1.1966
1.1490 1.1508 1.1634
0.0015
1.2485
1.2391
—
1.2079
1.2028
1.1740
2B
1.182
1.196
1.2094
1.2160
1.2500
0.0000 0.0015
1.2500 1.2485
1.2406 1.2398
— —
1.2094 1.2124
1.2056 1.2075
1.1755 1.1824
3B 2B
1.1820 1.190
1.1908 1.203
1.2094 1.2139
1.2144 1.2202
1.2500 1.2500
3A 2A
0.0000 0.0014
1.2500 1.2486
1.2413 1.2405
— —
1.2139 1.2161
1.2103 1.2114
1.1839 1.1891
3B 2B
1.1900 1.196
1.1980 1.207
1.2139 1.2175
1.2186 1.2236
1.2500 1.2500
11⁄4–24 UNS
3A 2A
0.0000 0.0013
1.2500 1.2487
1.2419 1.2415
— —
1.2175 1.2216
1.2140 1.2173
1.1905 1.1991
3B 2B
1.1960 1.205
1.2037 1.215
1.2175 1.2229
1.2220 1.2285
1.2500 1.2500
11⁄4–28 UN
2A
0.0012
1.2488
1.2423
—
1.2256
1.2215
1.2062
2B
1.211
1.220
1.2268
1.2321
1.2500
15⁄16–8 UN
3A 2A
0.0000 0.0021
1.2500 1.3104
1.2435 1.2954
— —
1.2268 1.2292
1.2237 1.2221
1.2074 1.1616
3B 2B
1.2110 1.177
1.2176 1.202
1.2268 1.2313
1.2308 1.2405
1.2500 1.3125
15⁄16–12 UN
3A 2A
0.0000 0.0017
1.3125 1.3108
1.2975 1.2994
— —
1.2313 1.2567
1.2260 1.2509
1.1637 1.2116
3B 2B
1.1770 1.222
1.1922 1.240
1.2313 1.2584
1.2382 1.2659
1.3125 1.3125
15⁄16–16 UN
3A 2A
0.0000 0.0015
1.3125 1.3110
1.3011 1.3016
— —
1.2584 1.2704
1.2541 1.2653
1.2133 1.2365
3B 2B
1.2220 1.245
1.2323 1.259
1.2584 1.2719
1.2640 1.2785
1.3125 1.3125
15⁄16–18 UNEF
3A 2A
0.0000 0.0015
1.3125 1.3110
1.3031 1.3023
— —
1.2719 1.2749
1.2681 1.2700
1.2380 1.2449
3B 2B
1.2450 1.252
1.2533 1.265
1.2719 1.2764
1.2769 1.2827
1.3125 1.3125
15⁄16–20 UN
3A 2A
0.0000 0.0014
1.3125 1.3111
1.3038 1.3030
— —
1.2764 1.2786
1.2728 1.2739
1.2464 1.2516
3B 2B
1.2520 1.258
1.2605 1.270
1.2764 1.2800
1.2811 1.2861
1.3125 1.3125
15⁄16–28 UN
3A 2A
0.0000 0.0012
1.3125 1.3113
1.3044 1.3048
— —
1.2800 1.2881
1.2765 1.2840
1.2530 1.2687
3B 2B
1.2580 1.274
1.2662 1.282
1.2800 1.2893
1.2845 1.2946
1.3125 1.3125
13⁄8–6 UNC
3A 1A
0.0000 0.0024
1.3125 1.3726
1.3060 1.3453
— —
1.2893 1.2643
1.2862 1.2523
1.2699 1.1742
3B 1B
1.2740 1.195
1.2801 1.225
1.2893 1.2667
1.2933 1.2822
1.3125 1.3750
2A 3A
0.0024 0.0000
1.3726 1.3750
1.3544 1.3568
1.3453 —
1.2643 1.2667
1.2563 1.2607
1.1742 1.1766
2B 3B
1.195 1.1950
1.225 1.2146
1.2667 1.2667
1.2771 1.2745
1.3750 1.3750
Class 1A
1.2482
11⁄4–14 UNS
2A 3A 2A
0.0018 0.0000 0.0016
11⁄4–16 UN
2A
11⁄4–18 UNEF
3A 2A
11⁄4–20 UN
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 1B
Min 1.160
Max 1.178
Min 1.1959
Max 1.2079
Min 1.2500
2B 3B 2B
1.160 1.1600 1.173
1.178 1.1698 1.188
1.1959 1.1959 1.2036
1.2039 1.2019 1.2106
1.2500 1.2500 1.2500
Copyright 2004, Industrial Press, Inc., New York, NY
1747
Maxd
Major Diameter
Allowance 0.0018
UNIFIED SCREW THREADS
Min 1.2310
Mine
UNR Minor Dia.,c Max (Ref.) 1.1490
Machinery's Handbook 27th Edition
Nominal Size, Threads per Inch, and Series Designationa 13⁄8–8 UN
Externalb
1748
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Internalb Major Diameter
Maxd
1.3503
1.2916
Min 1.2844
1.3750 1.3731
1.3600 1.3602
— —
1.2938 1.3081
1.2884 1.3018
1.2262 1.2541
0.0019
1.3731
1.3559
—
1.3190
1.3096
1.2739
1B
1.285
1.303
1.3209
1.3332
1.3750
0.0019 0.0000 0.0016
1.3731 1.3750 1.3734
1.3617 1.3636 1.3631
— — —
1.3190 1.3209 1.3270
1.3127 1.3162 1.3216
1.2739 1.2758 1.2884
2B 3B 2B
1.285 1.2850 1.298
1.303 1.2948 1.314
1.3209 1.3209 1.3286
1.3291 1.3270 1.3356
1.3750 1.3750 1.3750
2A
0.0015
1.3735
1.3641
—
1.3329
1.3278
1.2990
2B
1.307
1.321
1.3344
1.3410
1.3750
13⁄8–18 UNEF
3A 2A
0.0000 0.0015
1.3750 1.3735
1.3656 1.3648
— —
1.3344 1.3374
1.3306 1.3325
1.3005 1.3074
3B 2B
1.3070 1.315
1.3158 1.328
1.3344 1.3389
1.3394 1.3452
1.3750 1.3750
13⁄8–20 UN
3A 2A
0.0000 0.0014
1.3750 1.3736
1.3663 1.3655
— —
1.3389 1.3411
1.3353 1.3364
1.3089 1.3141
3B 2B
1.3150 1.321
1.3230 1.332
1.3389 1.3425
1.3436 1.3486
1.3750 1.3750
13⁄8–24 UNS
3A 2A
0.0000 0.0013
1.3750 1.3737
1.3669 1.3665
— —
1.3425 1.3466
1.3390 1.3423
1.3155 1.3241
3B 2B
1.3210 1.330
1.3287 1.340
1.3425 1.3479
1.3470 1.3535
1.3750 1.3750
13⁄8–28 UN
2A
0.0012
1.3738
1.3673
—
1.3506
1.3465
1.3312
2B
1.336
1.345
1.3518
1.3571
1.3750
17⁄16–6 UN
3A 2A
0.0000 0.0024
1.3750 1.4351
1.3685 1.4169
— —
1.3518 1.3268
1.3487 1.3188
1.3324 1.2367
3B 2B
1.3360 1.257
1.3426 1.288
1.3518 1.3292
1.3558 1.3396
1.3750 1.4375
17⁄16–8 UN
3A 2A
0.0000 0.0022
1.4375 1.4353
1.4193 1.4203
— —
1.3292 1.3541
1.3232 1.3469
1.2391 1.2865
3B 2B
1.2570 1.302
1.2771 1.327
1.3292 1.3563
1.3370 1.3657
1.4375 1.4375
17⁄16–12 UN
3A 2A
0.0000 0.0018
1.4375 1.4357
1.4225 1.4243
— —
1.3563 1.3816
1.3509 1.3757
1.2887 1.3365
3B 2B
1.3020 1.347
1.3172 1.365
1.3563 1.3834
1.3634 1.3910
1.4375 1.4375
17⁄16–16 UN
3A 2A
0.0000 0.0016
1.4375 1.4359
1.4261 1.4265
— —
1.3834 1.3953
1.3790 1.3901
1.3383 1.3614
3B 2B
1.3470 1.370
1.3573 1.384
1.3834 1.3969
1.3891 1.4037
1.4375 1.4375
17⁄16–18 UNEF
3A 2A
0.0000 0.0015
1.4375 1.4360
1.4281 1.4273
— —
1.3969 1.3999
1.3930 1.3949
1.3630 1.3699
3B 2B
1.3700 1.377
1.3783 1.390
1.3969 1.4014
1.4020 1.4079
1.4375 1.4375
17⁄16–20 UN
3A 2A
0.0000 0.0014
1.4375 1.4361
1.4288 1.4280
— —
1.4014 1.4036
1.3977 1.3988
1.3714 1.3766
3B 2B
1.3770 1.383
1.3855 1.395
1.4014 1.4050
1.4062 1.4112
1.4375 1.4375
3A
0.0000
1.4375
1.4294
—
1.4050
1.4014
1.3780
3B
1.3830
1.3912
1.4050
1.4096
1.4375
Major Diameter
Class 2A
Allowance 0.0022
1.3728
13⁄8–10 UNS
3A 2A
0.0000 0.0019
13⁄8–12
UNF
1A
13⁄8–14 UNS
2A 3A 2A
13⁄8–16 UN
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 1.240
Max 1.265
Min 1.2938
Max 1.3031
Min 1.3750
3B 2B
1.2400 1.267
1.2547 1.288
1.2938 1.3100
1.3008 1.3182
1.3750 1.3750
Copyright 2004, Industrial Press, Inc., New York, NY
UNIFIED SCREW THREADS
Min 1.3578
Mine
UNR Minor Dia.,c Max (Ref.) 1.2240
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 17⁄16–28 UN
Externalb
Internalb Major Diameter
—
1.4130
Min 1.4088
1.4375 1.4976
1.4310 1.4703
— —
1.4143 1.3893
1.4112 1.3772
1.3949 1.2992
3B 1B
1.3990 1.320
1.4051 1.350
1.4143 1.3917
1.4184 1.4075
1.4375 1.5000
0.0024 0.0000 0.0022
1.4976 1.5000 1.4978
1.4794 1.4818 1.4828
1.4703 — 1.4753
1.3893 1.3917 1.4166
1.3812 1.3856 1.4093
1.2992 1.3016 1.3490
2B 3B 2B
1.320 1.3200 1.365
1.350 1.3396 1.390
1.3917 1.3917 1.4188
1.4022 1.3996 1.4283
1.5000 1.5000 1.5000
3A 2A
0.0000 0.0019
1.5000 1.4981
1.4850 1.4852
— —
1.4188 1.4331
1.4133 1.4267
1.3512 1.3791
3B 2B
1.3650 1.392
1.3797 1.413
1.4188 1.4350
1.4259 1.4433
1.5000 1.5000
11⁄2–12 UNF
1A
0.0019
1.4981
1.4809
—
1.4440
1.4344
1.3989
1B
1.410
1.428
1.4459
1.4584
1.5000
11⁄2–14 UNS
2A 3A 2A
0.0019 0.0000 0.0017
1.4981 1.5000 1.4983
1.4867 1.4886 1.4880
— — —
1.4440 1.4459 1.4519
1.4376 1.4411 1.4464
1.3989 1.4008 1.4133
2B 3B 2B
1.410 1.4100 1.423
1.428 1.4198 1.438
1.4459 1.4459 1.4536
1.4542 1.4522 1.4608
1.5000 1.5000 1.5000
11⁄2–16 UN
2A
0.0016
1.4984
1.4890
—
1.4578
1.4526
1.4239
2B
1.432
1.446
1.4594
1.4662
1.5000
11⁄2–18 UNEF
3A 2A
0.0000 0.0015
1.5000 1.4985
1.4906 1.4898
— —
1.4594 1.4624
1.4555 1.4574
1.4255 1.4324
3B 2B
1.4320 1.440
1.4408 1.452
1.4594 1.4639
1.4645 1.4704
1.5000 1.5000
11⁄2–20 UN
3A 2A
0.0000 0.0014
1.5000 1.4986
1.4913 1.4905
— —
1.4639 1.4661
1.4602 1.4613
1.4339 1.4391
3B 2B
1.4400 1.446
1.4480 1.457
1.4639 1.4675
1.4687 1.4737
1.5000 1.5000
11⁄2–24 UNS
3A 2A
0.0000 0.0013
1.5000 1.4987
1.4919 1.4915
— —
1.4675 1.4716
1.4639 1.4672
1.4405 1.4491
3B 2B
1.4460 1.455
1.4537 1.465
1.4675 1.4729
1.4721 1.4787
1.5000 1.5000
11⁄2–28 UN
2A
0.0013
1.4987
1.4922
—
1.4755
1.4713
1.4561
2B
1.461
1.470
1.4768
1.4823
1.5000
19⁄16–6 UN
3A 2A
0.0000 0.0024
1.5000 1.5601
1.4935 1.5419
— —
1.4768 1.4518
1.4737 1.4436
1.4574 1.3617
3B 2B
1.4610 1.382
1.4676 1.413
1.4768 1.4542
1.4809 1.4648
1.5000 1.5625
19⁄16–8 UN
3A 2A
0.0000 0.0022
1.5625 1.5603
1.5443 1.5453
— —
1.4542 1.4791
1.4481 1.4717
1.3641 1.4115
3B 2B
1.3820 1.427
1.4021 1.452
1.4542 1.4813
1.4622 1.4909
1.5625 1.5625
19⁄16–12 UN
3A 2A
0.0000 0.0018
1.5625 1.5607
1.5475 1.5493
— —
1.4813 1.5066
1.4758 1.5007
1.4137 1.4615
3B 2B
1.4270 1.472
1.4422 1.490
1.4813 1.5084
1.4885 1.5160
1.5625 1.5625
3A
0.0000
1.5625
1.5511
—
1.5084
1.5040
1.4633
3B
1.4720
1.4823
1.5084
1.5141
1.5625
Class 2A
1.4362
11⁄2–6
3A 1A
0.0000 0.0024
11⁄2–8 UN
2A 3A 2A
11⁄2–10 UNS
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 1.399
Max 1.407
Min 1.4143
Max 1.4198
Min 1.4375
Copyright 2004, Industrial Press, Inc., New York, NY
1749
Maxd
Major Diameter
Allowance 0.0013
UNIFIED SCREW THREADS
Min 1.4297
Mine
UNR Minor Dia.,c Max (Ref.) 1.3936
Machinery's Handbook 27th Edition
Nominal Size, Threads per Inch, and Series Designationa 19⁄16–16 UN
Externalb
1750
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Internalb Major Diameter
Maxd
—
1.5203
Min 1.5151
1.5625 1.5610
1.5531 1.5523
— —
1.5219 1.5249
1.5180 1.5199
1.4880 1.4949
0.0000 0.0014
1.5625 1.5611
1.5538 1.5530
— —
1.5264 1.5286
1.5227 1.5238
1.4964 1.5016
3B 2B
1.5020 1.508
1.5105 1.520
1.5264 1.5300
1.5312 1.5362
1.5625 1.5625
0.0000 0.0025
1.5625 1.6225
1.5544 1.6043
— —
1.5300 1.5142
1.5264 1.5060
1.5030 1.4246
3B 2B
1.5080 1.445
1.5162 1.475
1.5300 1.5167
1.5346 1.5274
1.5625 1.6250
3A 2A
0.0000 0.0022
1.6250 1.6228
1.6068 1.6078
— 1.6003
1.5167 1.5416
1.5105 1.5342
1.4271 1.4784
3B 2B
1.4450 1.490
1.4646 1.515
1.5167 1.5438
1.5247 1.5535
1.6250 1.6250
15⁄8–10 UNS
3A 2A
0.0000 0.0019
1.6250 1.6231
1.6100 1.6102
— —
1.5438 1.5581
1.5382 1.5517
1.4806 1.5041
3B 2B
1.4900 1.517
1.5047 1.538
1.5438 1.5600
1.5510 1.5683
1.6250 1.6250
15⁄8–12 UN
2A
0.0018
1.6232
1.6118
—
1.5691
1.5632
1.5240
2B
1.535
1.553
1.5709
1.5785
1.6250
15⁄8–14 UNS
3A 2A
0.0000 0.0017
1.6250 1.6233
1.6136 1.6130
— —
1.5709 1.5769
1.5665 1.5714
1.5258 1.5383
3B 2B
1.5350 1.548
1.5448 1.564
1.5709 1.5786
1.5766 1.5858
1.6250 1.6250
15⁄8–16 UN
2A
0.0016
1.6234
1.6140
—
1.5828
1.5776
1.5489
2B
1.557
1.571
1.5844
1.5912
1.6250
15⁄8–18 UNEF
3A 2A
0.0000 0.0015
1.6250 1.6235
1.6156 1.6148
— —
1.5844 1.5874
1.5805 1.5824
1.5505 1.5574
3B 2B
1.5570 1.565
1.5658 1.578
1.5844 1.5889
1.5895 1.5954
1.6250 1.6250
15⁄8–20 UN
3A 2A
0.0000 0.0014
1.6250 1.6236
1.6163 1.6155
— —
1.5889 1.5911
1.5852 1.5863
1.5589 1.5641
3B 2B
1.5650 1.571
1.5730 1.582
1.5889 1.5925
1.5937 1.5987
1.6250 1.6250
15⁄8–24 UNS
3A 2A
0.0000 0.0013
1.6250 1.6237
1.6169 1.6165
— —
1.5925 1.5966
1.5889 1.5922
1.5655 1.5741
3B 2B
1.5710 1.580
1.5787 1.590
1.5925 1.5979
1.5971 1.6037
1.6250 1.6250
111⁄16–6 UN
2A
0.0025
1.6850
1.6668
—
1.5767
1.5684
1.4866
2B
1.507
1.538
1.5792
1.5900
1.6875
111⁄16–8 UN
3A 2A
0.0000 0.0022
1.6875 1.6853
1.6693 1.6703
— —
1.5792 1.6041
1.5730 1.5966
1.4891 1.5365
3B 2B
1.5070 1.552
1.5271 1.577
1.5792 1.6063
1.5873 1.6160
1.6875 1.6875
111⁄16–12 UN
3A 2A
0.0000 0.0018
1.6875 1.6857
1.6725 1.6743
— —
1.6063 1.6316
1.6007 1.6256
1.5387 1.5865
3B 2B
1.5520 1.597
1.5672 1.615
1.6063 1.6334
1.6136 1.6412
1.6875 1.6875
3A
0.0000
1.6875
1.6761
—
1.6334
1.6289
1.5883
3B
1.5970
1.6073
1.6334
1.6392
1.6875
Major Diameter
Class 2A
Allowance 0.0016
1.5609
19⁄16–18 UNEF
3A 2A
0.0000 0.0015
19⁄16–20 UN
3A 2A
15⁄8–6 UN
3A 2A
15⁄8–8 UN
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 1.495
Max 1.509
Min 1.5219
Max 1.5287
Min 1.5625
3B 2B
1.4950 1.502
1.5033 1.515
1.5219 1.5264
1.5270 1.5329
1.5625 1.5625
Copyright 2004, Industrial Press, Inc., New York, NY
UNIFIED SCREW THREADS
Min 1.5515
Mine
UNR Minor Dia.,c Max (Ref.) 1.4864
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 111⁄16–16 UN
Externalb
Internalb Major Diameter
—
1.6453
Min 1.6400
1.6875 1.6860
1.6781 1.6773
— —
1.6469 1.6499
1.6429 1.6448
1.6130 1.6199
0.0000 0.0015
1.6875 1.6860
1.6788 1.6779
— —
1.6514 1.6535
1.6476 1.6487
1.6214 1.6265
3B 2B
1.6270 1.633
1.6355 1.645
1.6514 1.6550
1.6563 1.6613
1.6875 1.6875
0.0000 0.0027
1.6875 1.7473
1.6794 1.7165
— —
1.6550 1.6174
1.6514 1.6040
1.6280 1.5092
3B 1B
1.6330 1.534
1.6412 1.568
1.6550 1.6201
1.6597 1.6375
1.6875 1.7500
13⁄4–6 UN
2A 3A 2A
0.0027 0.0000 0.0025
1.7473 1.7500 1.7475
1.7268 1.7295 1.7293
1.7165 — —
1.6174 1.6201 1.6392
1.6085 1.6134 1.6309
1.5092 1.5119 1.5491
2B 3B 2B
1.534 1.5340 1.570
1.568 1.5575 1.600
1.6201 1.6201 1.6417
1.6317 1.6288 1.6525
1.7500 1.7500 1.7500
13⁄4–8 UN
3A 2A
0.0000 0.0023
1.7500 1.7477
1.7318 1.7327
— 1.7252
1.6417 1.6665
1.6354 1.6590
1.5516 1.5989
3B 2B
1.5700 1.615
1.5896 1.640
1.6417 1.6688
1.6498 1.6786
1.7500 1.7500
13⁄4–10 UNS
3A 2A
0.0000 0.0019
1.7500 1.7481
1.7350 1.7352
— —
1.6688 1.6831
1.6632 1.6766
1.6012 1.6291
3B 2B
1.6150 1.642
1.6297 1.663
1.6688 1.6850
1.6762 1.6934
1.7500 1.7500
13⁄4–12 UN
2A
0.0018
1.7482
1.7368
—
1.6941
1.6881
1.6490
2B
1.660
1.678
1.6959
1.7037
1.7500
13⁄4–14 UNS
3A 2A
0.0000 0.0017
1.7500 1.7483
1.7386 1.7380
— —
1.6959 1.7019
1.6914 1.6963
1.6508 1.6632
3B 2B
1.6600 1.673
1.6698 1.688
1.6959 1.7036
1.7017 1.7109
1.7500 1.7500
13⁄4–16 UN
2A
0.0016
1.7484
1.7390
—
1.7078
1.7025
1.6739
2B
1.682
1.696
1.7094
1.7163
1.7500
13⁄4–18 UNS
3A 2A
0.0000 0.0015
1.7500 1.7485
1.7406 1.7398
— —
1.7094 1.7124
1.7054 1.7073
1.6755 1.6824
3B 2B
1.6820 1.690
1.6908 1.703
1.7094 1.7139
1.7146 1.7205
1.7500 1.7500
13⁄4–20 UN
2A
0.0015
1.7485
1.7404
—
1.7160
1.7112
1.6890
2B
1.696
1.707
1.7175
1.7238
1.7500
113⁄16–6 UN
3A 2A
0.0000 0.0025
1.7500 1.8100
1.7419 1.7918
— —
1.7175 1.7017
1.7139 1.6933
1.6905 1.6116
3B 2B
1.6960 1.632
1.7037 1.663
1.7175 1.7042
1.7222 1.7151
1.7500 1.8125
113⁄16–8 UN
3A 2A
0.0000 0.0023
1.8125 1.8102
1.7943 1.7952
— —
1.7042 1.7290
1.6979 1.7214
1.6141 1.6614
3B 2B
1.6320 1.677
1.6521 1.702
1.7042 1.7313
1.7124 1.7412
1.8125 1.8125
113⁄16–12 UN
3A 2A
0.0000 0.0018
1.8125 1.8107
1.7975 1.7993
— —
1.7313 1.7566
1.7256 1.7506
1.6637 1.7115
3B 2B
1.6770 1.722
1.6922 1.740
1.7313 1.7584
1.7387 1.7662
1.8125 1.8125
3A
0.0000
1.8125
1.8011
—
1.7584
1.7539
1.7133
3B
1.7220
1.7323
1.7584
1.7642
1.8125
Class 2A
1.6859
111⁄16–18 UNEF
3A 2A
0.0000 0.0015
111⁄16–20 UN
3A 2A
13⁄4–5 UNC
3A 1A
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 1.620
Max 1.634
Min 1.6469
Max 1.6538
Min 1.6875
3B 2B
1.6200 1.627
1.6283 1.640
1.6469 1.6514
1.6521 1.6580
1.6875 1.6875
Copyright 2004, Industrial Press, Inc., New York, NY
1751
Maxd
Major Diameter
Allowance 0.0016
UNIFIED SCREW THREADS
Min 1.6765
Mine
UNR Minor Dia.,c Max (Ref.) 1.6114
Machinery's Handbook 27th Edition
Nominal Size, Threads per Inch, and Series Designationa 113⁄16–16 UN
Externalb
1752
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Internalb Major Diameter
Maxd
—
1.7703
Min 1.7650
1.8125 1.8110
1.8031 1.8029
— —
1.7719 1.7785
1.7679 1.7737
1.7380 1.7515
3B 2B
1.7450 1.758
1.7533 1.770
1.7719 1.7800
1.7771 1.7863
1.8125 1.8125
0.0000 0.0025
1.8125 1.8725
1.8044 1.8543
— —
1.7800 1.7642
1.7764 1.7558
1.7530 1.6741
3B 2B
1.7580 1.695
1.7662 1.725
1.7800 1.7667
1.7847 1.7777
1.8125 1.8750
0.0000 0.0023
1.8750 1.8727
1.8568 1.8577
— 1.8502
1.7667 1.7915
1.7604 1.7838
1.6766 1.7239
3B 2B
1.6950 1.740
1.7146 1.765
1.7667 1.7938
1.7749 1.8038
1.8750 1.8750
3A 2A
0.0000 0.0019
1.8750 1.8731
1.8600 1.8602
— —
1.7938 1.8081
1.7881 1.8016
1.7262 1.7541
3B 2B
1.7400 1.767
1.7547 1.788
1.7938 1.8100
1.8013 1.8184
1.8750 1.8750
17⁄8–12 UN
2A
0.0018
1.8732
1.8618
—
1.8191
1.8131
1.7740
2B
1.785
1.803
1.8209
1.8287
1.8750
17⁄8–14 UNS
3A 2A
0.0000 0.0017
1.8750 1.8733
1.8636 1.8630
— —
1.8209 1.8269
1.8164 1.8213
1.7758 1.7883
3B 2B
1.7850 1.798
1.7948 1.814
1.8209 1.8286
1.8267 1.8359
1.8750 1.8750
17⁄8–16 UN
2A
0.0016
1.8734
1.8640
—
1.8328
1.8275
1.7989
2B
1.807
1.821
1.8344
1.8413
1.8750
17⁄8–18 UNS
3A 2A
0.0000 0.0015
1.8750 1.8735
1.8656 1.8648
— —
1.8344 1.8374
1.8304 1.8323
1.8005 1.8074
3B 2B
1.8070 1.815
1.8158 1.828
1.8344 1.8389
1.8396 1.8455
1.8750 1.8750
17⁄8–20 UN
2A
0.0015
1.8735
1.8654
—
1.8410
1.8362
1.8140
2B
1.821
1.832
1.8425
1.8488
1.8750
115⁄16–6
UN
3A 2A
0.0000 0.0026
1.8750 1.9349
1.8669 1.9167
— —
1.8425 1.8266
1.8389 1.8181
1.8155 1.7365
3B 2B
1.8210 1.757
1.8287 1.788
1.8425 1.8292
1.8472 1.8403
1.8750 1.9375
115⁄16–8
UN
3A 2A
0.0000 0.0023
1.9375 1.9352
1.9193 1.9202
— —
1.8292 1.8540
1.8228 1.8463
1.7391 1.7864
3B 2B
1.7570 1.802
1.7771 1.827
1.8292 1.8563
1.8375 1.8663
1.9375 1.9375
115⁄16–12 UN
3A 2A
0.0000 0.0018
1.9375 1.9357
1.9225 1.9243
— —
1.8563 1.8816
1.8505 1.8755
1.7887 1.8365
3B 2B
1.8020 1.847
1.8172 1.865
1.8563 1.8834
1.8638 1.8913
1.9375 1.9375
115⁄16–16 UN
3A 2A
0.0000 0.0016
1.9375 1.9359
1.9261 1.9265
— —
1.8834 1.8953
1.8789 1.8899
1.8383 1.8614
3B 2B
1.8470 1.870
1.8573 1.884
1.8834 1.8969
1.8893 1.9039
1.9375 1.9375
115⁄16–20 UN
3A 2A
0.0000 0.0015
1.9375 1.9360
1.9281 1.9279
— —
1.8969 1.9035
1.8929 1.8986
1.8630 1.8765
3B 2B
1.8700 1.883
1.8783 1.895
1.8969 1.9050
1.9021 1.9114
1.9375 1.9375
3A
0.0000
1.9375
1.9294
—
1.9050
1.9013
1.8780
3B
1.8830
1.8912
1.9050
1.9098
1.9375
Major Diameter
Class 2A
Allowance 0.0016
1.8109
113⁄16–20 UN
3A 2A
0.0000 0.0015
17⁄8–6 UN
3A 2A
17⁄8–8 UN
3A 2A
17⁄8–10 UNS
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 1.745
Max 1.759
Min 1.7719
Max 1.7788
Min 1.8125
Copyright 2004, Industrial Press, Inc., New York, NY
UNIFIED SCREW THREADS
Min 1.8015
Mine
UNR Minor Dia.,c Max (Ref.) 1.7364
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 2–41⁄2 UNC
Externalb
Internalb Major Diameter
—
1.8528
Min 1.8385
1.9971 2.0000 1.9974 2.0000 1.9977 2.0000 1.9980 1.9982 2.0000 1.9983 1.9984 2.0000 1.9985 1.9985 2.0000 2.0609
1.9751 1.9780 1.9792 1.9818 1.9827 1.9850 1.9851 1.9868 1.9886 1.9880 1.9890 1.9906 1.9898 1.9904 1.9919 2.0515
1.9641 — — — 1.9752 — — — — — — — — — — —
1.8528 1.8557 1.8891 1.8917 1.9165 1.9188 1.9330 1.9441 1.9459 1.9519 1.9578 1.9594 1.9624 1.9660 1.9675 2.0203
1.8433 1.8486 1.8805 1.8853 1.9087 1.9130 1.9265 1.9380 1.9414 1.9462 1.9524 1.9554 1.9573 1.9611 1.9638 2.0149
1.7324 1.7353 1.7990 1.8016 1.8489 1.8512 1.8790 1.8990 1.9008 1.9133 1.9239 1.9255 1.9324 1.9390 1.9405 1.9864
2B 3B 2B 3B 2B 3B 2B 2B 3B 2B 2B 3B 2B 2B 3B 2B
1.759 1.7590 1.820 1.8200 1.865 1.8650 1.892 1.910 1.9100 1.923 1.932 1.9320 1.940 1.946 1.9460 1.995
1.795 1.7861 1.850 1.8396 1.890 1.8797 1.913 1.928 1.9198 1.938 1.946 1.9408 1.953 1.957 1.9537 2.009
1.8557 1.8557 1.8917 1.8917 1.9188 1.9188 1.9350 1.9459 1.9459 1.9536 1.9594 1.9594 1.9639 1.9675 1.9675 2.0219
1.8681 1.8650 1.9028 1.9000 1.9289 1.9264 1.9435 1.9538 1.9518 1.9610 1.9664 1.9646 1.9706 1.9739 1.9723 2.0289
2.0000 2.0000 2.0000 2.0000 2.0000 2.0000 2.0000 2.0000 2.0000 2.0000 2.0000 2.0000 2.0000 2.0000 2.0000 2.0625
0.0000 0.0026
2.0625 2.1224
2.0531 2.1042
— —
2.0219 2.0141
2.0179 2.0054
1.9880 1.9240
3B 2B
1.9950 1.945
2.0033 1.975
2.0219 2.0167
2.0271 2.0280
2.0625 2.1250
3A 2A
0.0000 0.0024
2.1250 2.1226
2.1068 2.1076
— 2.1001
2.0167 2.0414
2.0102 2.0335
1.9266 1.9738
3B 2B
1.9450 1.990
1.9646 2.015
2.0167 2.0438
2.0251 2.0540
2.1250 2.1250
21⁄8–12 UN
3A 2A
0.0000 0.0018
2.1250 2.1232
2.1100 2.1118
— —
2.0438 2.0691
2.0379 2.0630
1.9762 2.0240
3B 2B
1.9900 2.035
2.0047 2.053
2.0438 2.0709
2.0515 2.0788
2.1250 2.1250
21⁄8–16 UN
3A 2A
0.0000 0.0016
2.1250 2.1234
2.1136 2.1140
— —
2.0709 2.0828
2.0664 2.0774
2.0258 2.0489
3B 2B
2.0350 2.057
2.0448 2.071
2.0709 2.0844
2.0768 2.0914
2.1250 2.1250
21⁄8–20 UN
3A 2A
0.0000 0.0015
2.1250 2.1235
2.1156 2.1154
— —
2.0844 2.0910
2.0803 2.0861
2.0505 2.0640
3B 2B
2.0570 2.071
2.0658 2.082
2.0844 2.0925
2.0896 2.0989
2.1250 2.1250
3A
0.0000
2.1250
2.1169
—
2.0925
2.0888
2.0655
3B
2.0710
2.0787
2.0925
2.0973
2.1250
Class 1A
1.9971
21⁄16–16 UNS
2A 3A 2A 3A 2A 3A 2A 2A 3A 2A 2A 3A 2A 2A 3A 2A
0.0029 0.0000 0.0026 0.0000 0.0023 0.0000 0.0020 0.0018 0.0000 0.0017 0.0016 0.0000 0.0015 0.0015 0.0000 0.0016
21⁄8–6 UN
3A 2A
21⁄8–8 UN
2–6 UN 2–8 UN 2–10 UNS 2–12 UN 2–14 UNS 2–16 UN 2–18 UNS 2–20 UN
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 1B
Min 1.759
Max 1.795
Min 1.8557
Max 1.8743
Min 2.0000
Copyright 2004, Industrial Press, Inc., New York, NY
1753
Maxd
Major Diameter
Allowance 0.0029
UNIFIED SCREW THREADS
Min 1.9641
Mine
UNR Minor Dia.,c Max (Ref.) 1.7324
Machinery's Handbook 27th Edition
Nominal Size, Threads per Inch, and Series Designationa 3 2 ⁄16–16 UNS
Externalb
1754
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Internalb Major Diameter
Maxd
—
2.1453
Min 2.1399
2.1875 2.2471
2.1781 2.2141
— —
2.1469 2.1028
2.1428 2.0882
2.1130 1.9824
3B 1B
2.1200 2.009
2.1283 2.045
2.1469 2.1057
2.1521 2.1247
2.1875 2.2500
0.0029 0.0000 0.0026
2.2471 2.2500 2.2474
2.2251 2.2280 2.2292
2.2141 — —
2.1028 2.1057 2.1391
2.0931 2.0984 2.1303
1.9824 1.9853 2.0490
2B 3B 2B
2.009 2.0090 2.070
2.045 2.0361 2.100
2.1057 2.1057 2.1417
2.1183 2.1152 2.1531
2.2500 2.2500 2.2500
3A 2A
0.0000 0.0024
2.2500 2.2476
2.2318 2.2326
— 2.2251
2.1417 2.1664
2.1351 2.1584
2.0516 2.0988
3B 2B
2.0700 2.115
2.0896 2.140
2.1417 2.1688
2.1502 2.1792
2.2500 2.2500
21⁄4–10 UNS
3A 2A
0.0000 0.0020
2.2500 2.2480
2.2350 2.2351
— —
2.1688 2.1830
2.1628 2.1765
2.1012 2.1290
3B 2B
2.1150 2.142
2.1297 2.163
2.1688 2.1850
2.1766 2.1935
2.2500 2.2500
21⁄4–12 UN
2A
0.0018
2.2482
2.2368
—
2.1941
2.1880
2.1490
2B
2.160
2.178
2.1959
2.2038
2.2500
21⁄4–14 UNS
3A 2A
0.0000 0.0017
2.2500 2.2483
2.2386 2.2380
— —
2.1959 2.2019
2.1914 2.1962
2.1508 2.1633
3B 2B
2.1600 2.173
2.1698 2.188
2.1959 2.2036
2.2018 2.2110
2.2500 2.2500
21⁄4–16 UN
2A
0.0016
2.2484
2.2390
—
2.2078
2.2024
2.1739
2B
2.182
2.196
2.2094
2.2164
2.2500
21⁄4–18 UNS
3A 2A
0.0000 0.0015
2.2500 2.2485
2.2406 2.2398
— —
2.2094 2.2124
2.2053 2.2073
2.1755 2.1824
3B 2B
2.1820 2.190
2.1908 2.203
2.2094 2.2139
2.2146 2.2206
2.2500 2.2500
21⁄4–20 UN
2A
0.0015
2.2485
2.2404
—
2.2160
2.2111
2.1890
2B
2.196
2.207
2.2175
2.2239
2.2500
25⁄16–16 UNS
3A 2A
0.0000 0.0017
2.2500 2.3108
2.2419 2.3014
— —
2.2175 2.2702
2.2137 2.2647
2.1905 2.2363
3B 2B
2.1960 2.245
2.2037 2.259
2.2175 2.2719
2.2223 2.2791
2.2500 2.3125
23⁄8–6 UN
3A 2A
0.0000 0.0027
2.3125 2.3723
2.3031 2.3541
— —
2.2719 2.2640
2.2678 2.2551
2.2380 2.1739
3B 2B
2.2450 2.195
2.2533 2.226
2.2719 2.2667
2.2773 2.2782
2.3125 2.3750
23⁄8–8 UN
3A 2A
0.0000 0.0024
2.3750 2.3726
2.3568 2.3576
— —
2.2667 2.2914
2.2601 2.2833
2.1766 2.2238
3B 2B
2.1950 2.240
2.2146 2.265
2.2667 2.2938
2.2753 2.3043
2.3750 2.3750
23⁄8–12 UN
3A 2A
0.0000 0.0019
2.3750 2.3731
2.3600 2.3617
— —
2.2938 2.3190
2.2878 2.3128
2.2262 2.2739
3B 2B
2.2400 2.285
2.2547 2.303
2.2938 2.3209
2.3017 2.3290
2.3750 2.3750
23⁄8–16 UN
3A 2A
0.0000 0.0017
2.3750 2.3733
2.3636 2.3639
— —
2.3209 2.3327
2.3163 2.3272
2.2758 2.2988
3B 2B
2.2850 2.307
2.2948 2.321
2.3209 2.3344
2.3269 2.3416
2.3750 2.3750
3A
0.0000
2.3750
2.3656
—
2.3344
2.3303
2.3005
3B
2.3070
2.3158
2.3344
2.3398
2.3750
Major Diameter
Class 2A
Allowance 0.0016
2.1859
21⁄4–41⁄2 UNC
3A 1A
0.0000 0.0029
21⁄4–6 UN
2A 3A 2A
21⁄4–8 UN
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 2.120
Max 2.134
Min 2.1469
Max 2.1539
Min 2.1875
Copyright 2004, Industrial Press, Inc., New York, NY
UNIFIED SCREW THREADS
Min 2.1765
Mine
UNR Minor Dia.,c Max (Ref.) 2.1114
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 23⁄8–20 UN
Externalb
Internalb Major Diameter
—
2.3410
Min 2.3359
2.3669 2.4264
— —
2.3425 2.3952
2.3387 2.3897
2.3155 2.3613
2.4281 2.4612
— —
2.3969 2.3345
2.3928 2.3190
2.3630 2.1992
3B 1B
2.3700 2.229
2.3783 2.267
2.3969 2.3376
2.4023 2.3578
2.4375 2.5000
2.4731 2.4762 2.4791
2.4612 — —
2.3345 2.3376 2.3890
2.3241 2.3298 2.3800
2.1992 2.2023 2.2989
2B 3B 2B
2.229 2.2290 2.320
2.267 2.2594 2.350
2.3376 2.3376 2.3917
2.3511 2.3477 2.4033
2.5000 2.5000 2.5000
2.4818 2.4826
— 2.4751
2.3917 2.4164
2.3850 2.4082
2.3016 2.3488
3B 2B
2.3200 2.365
2.3396 2.390
2.3917 2.4188
2.4004 2.4294
2.5000 2.5000
2.5000 2.4980
2.4850 2.4851
— —
2.4188 2.4330
2.4127 2.4263
2.3512 2.3790
3B 2B
2.3650 2.392
2.3797 2.413
2.4188 2.4350
2.4268 2.4437
2.5000 2.5000
0.0019
2.4981
2.4867
—
2.4440
2.4378
2.3989
2B
2.410
2.428
2.4459
2.4540
2.5000
0.0000 0.0017
2.5000 2.4983
2.4886 2.4880
— —
2.4459 2.4519
2.4413 2.4461
2.4008 2.4133
3B 2B
2.4100 2.423
2.4198 2.438
2.4459 2.4536
2.4519 2.4612
2.5000 2.5000
2A
0.0017
2.4983
2.4889
—
2.4577
2.4522
2.4238
2B
2.432
2.446
2.4594
2.4666
2.5000
21⁄2–18 UNS
3A 2A
0.0000 0.0016
2.5000 2.4984
2.4906 2.4897
— —
2.4594 2.4623
2.4553 2.4570
2.4255 2.4323
3B 2B
2.4320 2.440
2.4408 2.453
2.4594 2.4639
2.4648 2.4708
2.5000 2.5000
21⁄2–20 UN
2A
0.0015
2.4985
2.4904
—
2.4660
2.4609
2.4390
2B
2.446
2.457
2.4675
2.4741
2.5000
25⁄8–6 UN
3A 2A
0.0000 0.0027
2.5000 2.6223
2.4919 2.6041
— —
2.4675 2.5140
2.4637 2.5050
2.4405 2.4239
3B 2B
2.4460 2.445
2.4537 2.475
2.4675 2.5167
2.4725 2.5285
2.5000 2.6250
25⁄8–8 UN
3A 2A
0.0000 0.0025
2.6250 2.6225
2.6068 2.6075
— —
2.5167 2.5413
2.5099 2.5331
2.4266 2.4737
3B 2B
2.4450 2.490
2.4646 2.515
2.5167 2.5438
2.5255 2.5545
2.6250 2.6250
25⁄8–12 UN
3A 2A
0.0000 0.0019
2.6250 2.6231
2.6100 2.6117
— —
2.5438 2.5690
2.5376 2.5628
2.4762 2.5239
3B 2B
2.4900 2.535
2.5047 2.553
2.5438 2.5709
2.5518 2.5790
2.6250 2.6250
25⁄8–16 UN
3A 2A
0.0000 0.0017
2.6250 2.6233
2.6136 2.6139
— —
2.5709 2.5827
2.5663 2.5772
2.5258 2.5488
3B 2B
2.5350 2.557
2.5448 2.571
2.5709 2.5844
2.5769 2.5916
2.6250 2.6250
3A
0.0000
2.6250
2.6156
—
2.5844
2.5803
2.5505
3B
2.5570
2.5658
2.5844
2.5898
2.6250
Class 2A
2.3735
27⁄16–16 UNS
3A 2A
0.0000 0.0017
2.3750 2.4358
21⁄2–4 UNC
3A 1A
0.0000 0.0031
2.4375 2.4969
21⁄2–6 UN
2A 3A 2A
0.0031 0.0000 0.0027
2.4969 2.5000 2.4973
21⁄2–8 UN
3A 2A
0.0000 0.0024
2.5000 2.4976
21⁄2–10 UNS
3A 2A
0.0000 0.0020
21⁄2–12 UN
2A
21⁄2–14 UNS
3A 2A
21⁄2–16 UN
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 2.321
Max 2.332
Min 2.3425
Max 2.3491
Min 2.3750
3B 2B
2.3210 2.370
2.3287 2.384
2.3425 2.3969
2.3475 2.4041
2.3750 2.4375
Copyright 2004, Industrial Press, Inc., New York, NY
1755
Maxd
Major Diameter
Allowance 0.0015
UNIFIED SCREW THREADS
Min 2.3654
Mine
UNR Minor Dia.,c Max (Ref.) 2.3140
Machinery's Handbook 27th Edition
Nominal Size, Threads per Inch, and Series Designationa 25⁄8–20 UN
Externalb
1756
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Internalb Major Diameter
Maxd
—
2.5910
Min 2.5859
2.6250 2.7468
2.6169 2.7111
— —
2.5925 2.5844
2.5887 2.5686
2.5655 2.4491
3B 1B
2.5710 2.479
2.5787 2.517
2.5925 2.5876
2.5975 2.6082
2.6250 2.7500
0.0032 0.0000 0.0027
2.7468 2.7500 2.7473
2.7230 2.7262 2.7291
2.7111 — —
2.5844 2.5876 2.6390
2.5739 2.5797 2.6299
2.4491 2.4523 2.5489
2B 3B 2B
2.479 2.4790 2.570
2.517 2.5094 2.600
2.5876 2.5876 2.6417
2.6013 2.5979 2.6536
2.7500 2.7500 2.7500
3A 2A
0.0000 0.0025
2.7500 2.7475
2.7318 2.7325
— 2.7250
2.6417 2.6663
2.6349 2.6580
2.5516 2.5987
3B 2B
2.5700 2.615
2.5896 2.640
2.6417 2.6688
2.6506 2.6796
2.7500 2.7500
23⁄4–10 UNS
3A 2A
0.0000 0.0020
2.7500 2.7480
2.7350 2.7351
— —
2.6688 2.6830
2.6625 2.6763
2.6012 2.6290
3B 2B
2.6150 2.642
2.6297 2.663
2.6688 2.6850
2.6769 2.6937
2.7500 2.7500
23⁄4–12 UN
2A
0.0019
2.7481
2.7367
—
2.6940
2.6878
2.6489
2B
2.660
2.678
2.6959
2.7040
2.7500
23⁄4–14 UNS
3A 2A
0.0000 0.0017
2.7500 2.7483
2.7386 2.7380
— —
2.6959 2.7019
2.6913 2.6961
2.6508 2.6633
3B 2B
2.6600 2.673
2.6698 2.688
2.6959 2.7036
2.7019 2.7112
2.7500 2.7500
23⁄4–16 UN
2A
0.0017
2.7483
2.7389
—
2.7077
2.7022
2.6738
2B
2.682
2.696
2.7094
2.7166
2.7500
23⁄4–18 UNS
3A 2A
0.0000 0.0016
2.7500 2.7484
2.7406 2.7397
— —
2.7094 2.7123
2.7053 2.7070
2.6755 2.6823
3B 2B
2.6820 2.690
2.6908 2.703
2.7094 2.7139
2.7148 2.7208
2.7500 2.7500
23⁄4–20 UN
2A
0.0015
2.7485
2.7404
—
2.7160
2.7109
2.6890
2B
2.696
2.707
2.7175
2.7241
2.7500
27⁄8–6 UN
3A 2A
0.0000 0.0028
2.7500 2.8722
2.7419 2.8540
— —
2.7175 2.7639
2.7137 2.7547
2.6905 2.6738
3B 2B
2.6960 2.695
2.7037 2.725
2.7175 2.7667
2.7225 2.7787
2.7500 2.8750
27⁄8–8 UN
3A 2A
0.0000 0.0025
2.8750 2.8725
2.8568 2.8575
— —
2.7667 2.7913
2.7598 2.7829
2.6766 2.7237
3B 2B
2.6950 2.740
2.7146 2.765
2.7667 2.7938
2.7757 2.8048
2.8750 2.8750
27⁄8–12 UN
3A 2A
0.0000 0.0019
2.8750 2.8731
2.8600 2.8617
— —
2.7938 2.8190
2.7875 2.8127
2.7262 2.7739
3B 2B
2.7400 2.785
2.7547 2.803
2.7938 2.8209
2.8020 2.8291
2.8750 2.8750
27⁄8–16 UN
3A 2A
0.0000 0.0017
2.8750 2.8733
2.8636 2.8639
— —
2.8209 2.8327
2.8162 2.8271
2.7758 2.7988
3B 2B
2.7850 2.807
2.7948 2.821
2.8209 2.8344
2.8271 2.8417
2.8750 2.8750
27⁄8–20 UN
3A 2A
0.0000 0.0016
2.8750 2.8734
2.8656 2.8653
— —
2.8344 2.8409
2.8302 2.8357
2.8005 2.8139
3B 2B
2.8070 2.821
2.8158 2.832
2.8344 2.8425
2.8399 2.8493
2.8750 2.8750
3A
0.0000
2.8750
2.8669
—
2.8425
2.8386
2.8155
3B
2.8210
2.8287
2.8425
2.8476
2.8750
Major Diameter
Class 2A
Allowance 0.0015
2.6235
23⁄4–4 UNC
3A 1A
0.0000 0.0032
23⁄4–6 UN
2A 3A 2A
23⁄4–8 UN
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 2.571
Max 2.582
Min 2.5925
Max 2.5991
Min 2.6250
Copyright 2004, Industrial Press, Inc., New York, NY
UNIFIED SCREW THREADS
Min 2.6154
Mine
UNR Minor Dia.,c Max (Ref.) 2.5640
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 3–4 UNC
Externalb
2.8344 2.8344 2.8376 2.8889 2.8917 2.9162 2.9188 2.9330 2.9440 2.9459 2.9518 2.9577 2.9594 2.9623 2.9659 2.9675 3.0139
Min 2.8183 2.8237 2.8296 2.8796 2.8847 2.9077 2.9124 2.9262 2.9377 2.9412 2.9459 2.9521 2.9552 2.9569 2.9607 2.9636 3.0045
3.1250 3.1224
3.1068 3.1074
— —
3.0167 3.0412
3.0097 3.0326
2.9266 2.9736
3B 2B
2.9450 2.990
2.9646 3.015
3.0167 3.0438
3.0259 3.0550
3.1250 3.1250
0.0000 0.0019
3.1250 3.1231
3.1100 3.1117
— —
3.0438 3.0690
3.0374 3.0627
2.9762 3.0239
3B 2B
2.9900 3.035
3.0047 3.053
3.0438 3.0709
3.0522 3.0791
3.1250 3.1250
3A 2A
0.0000 0.0017
3.1250 3.1233
3.1136 3.1139
— —
3.0709 3.0827
3.0662 3.0771
3.0258 3.0488
3B 2B
3.0350 3.057
3.0448 3.071
3.0709 3.0844
3.0771 3.0917
3.1250 3.1250
3A 1A
0.0000 0.0033
3.1250 3.2467
3.1156 3.2110
— —
3.0844 3.0843
3.0802 3.0680
3.0505 2.9490
3B 1B
3.0570 2.979
3.0658 3.017
3.0844 3.0876
3.0899 3.1088
3.1250 3.2500
2A 3A 2A
0.0033 0.0000 0.0028
3.2467 3.2500 3.2472
3.2229 3.2262 3.2290
3.2110 — —
3.0843 3.0876 3.1389
3.0734 3.0794 3.1294
2.9490 2.9523 3.0488
2B 3B 2B
2.979 2.9790 3.070
3.017 3.0094 3.100
3.0876 3.0876 3.1417
3.1017 3.0982 3.1540
3.2500 3.2500 3.2500
3A
0.0000
3.2500
3.2318
—
3.1417
3.1346
3.0516
3B
3.0700
3.0896
3.1417
3.1509
3.2500
31⁄8–6 UN 31⁄8–8 UN
3A 2A
0.0000 0.0026
31⁄8–12 UN
3A 2A
31⁄8–16 UN 31⁄4–4 UNC
3–10 UNS 3–12 UN 3–14 UNS 3–16 UN 3–18 UNS 3–20 UN
31⁄4–6
UN
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 1B 2B 3B 2B 3B 2B 3B 2B 2B 3B 2B 2B 3B 2B 2B 3B 2B
Min 2.729 2.729 2.7290 2.820 2.8200 2.865 2.8650 2.892 2.910 2.9100 2.923 2.932 2.9320 2.940 2.946 2.9460 2.945
Max 2.767 2.767 2.7594 2.850 2.8396 2.890 2.8797 2.913 2.928 2.9198 2.938 2.946 2.9408 2.953 2.957 2.9537 2.975
Min 2.8376 2.8376 2.8376 2.8917 2.8917 2.9188 2.9188 2.9350 2.9459 2.9459 2.9536 2.9594 2.9594 2.9639 2.9675 2.9675 3.0167
Max 2.8585 2.8515 2.8480 2.9038 2.9008 2.9299 2.9271 2.9439 2.9541 2.9521 2.9613 2.9667 2.9649 2.9709 2.9743 2.9726 3.0289
Min 3.0000 3.0000 3.0000 3.0000 3.0000 3.0000 3.0000 3.0000 3.0000 3.0000 3.0000 3.0000 3.0000 3.0000 3.0000 3.0000 3.1250
Copyright 2004, Industrial Press, Inc., New York, NY
1757
— 2.9611 — — — 2.9749 — — — — — — — — — — —
2.9968 2.9968 3.0000 2.9972 3.0000 2.9974 3.0000 2.9980 2.9981 3.0000 2.9982 2.9983 3.0000 2.9984 2.9984 3.0000 3.1222
Maxd
UNIFIED SCREW THREADS
Min 2.9611 2.9730 2.9762 2.9790 2.9818 2.9824 2.9850 2.9851 2.9867 2.9886 2.9879 2.9889 2.9906 2.9897 2.9903 2.9919 3.1040
Maxd
Class 1A 2A 3A 2A 3A 2A 3A 2A 2A 3A 2A 2A 3A 2A 2A 3A 2A
3–8 UN
Major Diameter
Mine
Major Diameter
Allowance 0.0032 0.0032 0.0000 0.0028 0.0000 0.0026 0.0000 0.0020 0.0019 0.0000 0.0018 0.0017 0.0000 0.0016 0.0016 0.0000 0.0028
3–6 UN
Internalb UNR Minor Dia.,c Max (Ref.) 2.6991 2.6991 2.7023 2.7988 2.8016 2.8486 2.8512 2.8790 2.8989 2.9008 2.9132 2.9238 2.9255 2.9323 2.9389 2.9405 2.9238
Machinery's Handbook 27th Edition
Nominal Size, Threads per Inch, and Series Designationa 31⁄4–8 UN
Externalb
1758
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Internalb Major Diameter
Maxd
3.2249
3.1662
Min 3.1575
3.2500 3.2480
3.2350 3.2351
— —
3.1688 3.1830
3.1623 3.1762
3.1012 3.1290
0.0019
3.2481
3.2367
—
3.1940
3.1877
3.1489
2B
3.160
3.178
3.1959
3.2041
3.2500
0.0000 0.0018
3.2500 3.2482
3.2386 3.2379
— —
3.1959 3.2018
3.1912 3.1959
3.1508 3.1632
3B 2B
3.1600 3.173
3.1698 3.188
3.1959 3.2036
3.2041 3.2113
3.2500 3.2500
2A
0.0017
3.2483
3.2389
—
3.2077
3.2021
3.1738
2B
3.182
3.196
3.2094
3.2167
3.2500
UNS
3A 2A
0.0000 0.0016
3.2500 3.2484
3.2406 3.2397
— —
3.2094 3.2123
3.2052 3.2069
3.1755 3.1823
3B 2B
3.1820 3.190
3.1908 3.203
3.2094 3.2139
3.2149 3.2209
3.2500 3.2500
UN
2A
0.0029
3.3721
3.3539
—
3.2638
3.2543
3.1737
2B
3.195
3.225
3.2667
3.2791
3.3750
UN
3A 2A
0.0000 0.0026
3.3750 3.3724
3.3568 3.3574
— —
3.2667 3.2912
3.2595 3.2824
3.1766 3.2236
3B 2B
3.1950 3.240
3.2146 3.265
3.2667 3.2938
3.2760 3.3052
3.3750 3.3750
UN
3A 2A
0.0000 0.0019
3.3750 3.3731
3.3600 3.3617
— —
3.2938 3.3190
3.2872 3.3126
3.2262 3.2739
3B 2B
3.2400 3.285
3.2547 3.303
3.2938 3.3209
3.3023 3.3293
3.3750 3.3750
33⁄8–16 UN
3A 2A
0.0000 0.0017
3.3750 3.3733
3.3636 3.3639
— —
3.3209 3.3327
3.3161 3.3269
3.2758 3.2988
3B 2B
3.2850 3.307
3.2948 3.321
3.3209 3.3344
3.3272 3.3419
3.3750 3.3750
31⁄2–4 UNC
3A 1A
0.0000 0.0033
3.3750 3.4967
3.3656 3.4610
— —
3.3344 3.3343
3.3301 3.3177
3.3005 3.1990
3B 1B
3.3070 3.229
3.3158 3.267
3.3344 3.3376
3.3400 3.3591
3.3750 3.5000
31⁄2–6 UN
2A 3A 2A
0.0033 0.0000 0.0029
3.4967 3.5000 3.4971
3.4729 3.4762 3.4789
3.4610 — —
3.3343 3.3376 3.3888
3.3233 3.3293 3.3792
3.1990 3.2023 3.2987
2B 3B 2B
3.229 3.2290 3.320
3.267 3.2594 3.350
3.3376 3.3376 3.3917
3.3519 3.3484 3.4042
3.5000 3.5000 3.5000
31⁄2–8 UN
3A 2A
0.0000 0.0026
3.5000 3.4974
3.4818 3.4824
— 3.4749
3.3917 3.4162
3.3845 3.4074
3.3016 3.3486
3B 2B
3.3200 3.365
3.3396 3.390
3.3917 3.4188
3.4011 3.4303
3.5000 3.5000
31⁄2–10 UNS
3A 2A
0.0000 0.0021
3.5000 3.4979
3.4850 3.4850
— —
3.4188 3.4329
3.4122 3.4260
3.3512 3.3789
3B 2B
3.3650 3.392
3.3797 3.413
3.4188 3.4350
3.4274 3.4440
3.5000 3.5000
31⁄2–12 UN
2A
0.0019
3.4981
3.4867
—
3.4440
3.4376
3.3989
2B
3.410
3.428
3.4459
3.4543
3.5000
3A
0.0000
3.5000
3.4886
—
3.4459
3.4411
3.4008
3B
3.4100
3.4198
3.4459
3.4522
3.5000
Major Diameter
Class 2A
Allowance 0.0026
3.2474
31⁄4–10 UNS
3A 2A
0.0000 0.0020
31⁄4–12
2A 3A 2A
UN
31⁄4–14 UNS 31⁄4–16 UN 31⁄4–18 33⁄8–6 33⁄8–8
33⁄8–12
Maxd
Pitch Diameter
Minor Diameter
Pitch Diameter
Class 2B
Min 3.115
Max 3.140
Min 3.1688
Max 3.1801
Min 3.2500
3B 2B
3.1150 3.142
3.1297 3.163
3.1688 3.1850
3.1773 3.1939
3.2500 3.2500
Copyright 2004, Industrial Press, Inc., New York, NY
UNIFIED SCREW THREADS
Min 3.2324
Mine
UNR Minor Dia.,c Max (Ref.) 3.0986
Machinery's Handbook 27th Edition
Table 3. (Continued) Standard Series and Selected Combinations — Unified Screw Threads Nominal Size, Threads per Inch, and Series Designationa 31⁄2–14 UNS
Externalb Major Diameter 3.4982
UN
2A
0.0017
UNS
3A 2A
0.0000 0.0017
UN
2A
UN
3A 2A
UN
Pitch Diameter
Minor Diameter
Pitch Diameter
Major Diameter
Min 3.4879
Mine
Maxd
—
3.4518
Min 3.4457
3.4983
3.4889
—
3.4577
3.4519
3.4238
2B
3.432
3.446
3.4594
3.4669
3.5000
3.5000 3.4983
3.4906 3.4896
— —
3.4594 3.4622
3.4551 3.4567
3.4255 3.4322
3B 2B
3.4320 3.440
3.4408 3.453
3.4594 3.4639
3.4650 3.4711
3.5000 3.5000
0.0029
3.6221
3.6039
—
3.5138
3.5041
3.4237
2B
3.445
3.475
3.5167
3.5293
3.6250
0.0000 0.0027
3.6250 3.6223
3.6068 3.6073
— —
3.5167 3.5411
3.5094 3.5322
3.4266 3.4735
3B 2B
3.4450 3.490
3.4646 3.515
3.5167 3.5438
3.5262 3.5554
3.6250 3.6250
3A 2A
0.0000 0.0019
3.6250 3.6231
3.6100 3.6117
— —
3.5438 3.5690
3.5371 3.5626
3.4762 3.5239
3B 2B
3.4900 3.535
3.5047 3.553
3.5438 3.5709
3.5525 3.5793
3.6250 3.6250
35⁄8–16 UN
3A 2A
0.0000 0.0017
3.6250 3.6233
3.6136 3.6139
— —
3.5709 3.5827
3.5661 3.5769
3.5258 3.5488
3B 2B
3.5350 3.557
3.5448 3.571
3.5709 3.5844
3.5772 3.5919
3.6250 3.6250
33⁄4–4 UNC
3A 1A
0.0000 0.0034
3.6250 3.7466
3.6156 3.7109
— —
3.5844 3.5842
3.5801 3.5674
3.5505 3.4489
3B 1B
3.5570 3.479
3.5658 3.517
3.5844 3.5876
3.5900 3.6094
3.6250 3.7500
33⁄4–6 UN
2A 3A 2A
0.0034 0.0000 0.0029
3.7466 3.7500 3.7471
3.7228 3.7262 3.7289
3.7109 — —
3.5842 3.5876 3.6388
3.5730 3.5792 3.6290
3.4489 3.4523 3.5487
2B 3B 2B
3.479 3.4790 3.570
3.517 3.5094 3.600
3.5876 3.5876 3.6417
3.6021 3.5985 3.6544
3.7500 3.7500 3.7500
33⁄4–8 UN
3A 2A
0.0000 0.0027
3.7500 3.7473
3.7318 3.7323
— 3.7248
3.6417 3.6661
3.6344 3.6571
3.5516 3.5985
3B 2B
3.5700 3.615
3.5896 3.640
3.6417 3.6688
3.6512 3.6805
3.7500 3.7500
33⁄4–10 UNS
3A 2A
0.0000 0.0021
3.7500 3.7479
3.7350 3.7350
— —
3.6688 3.6829
3.6621 3.6760
3.6012 3.6289
3B 2B
3.6150 3.642
3.6297 3.663
3.6688 3.6850
3.6776 3.6940
3.7500 3.7500
33⁄4–12 UN
2A
0.0019
3.7481
3.7367
—
3.6940
3.6876
3.6489
2B
3.660
3.678
3.6959
3.7043
3.7500
33⁄4–14 UNS
3A 2A
0.0000 0.0018
3.7500 3.7482
3.7386 3.7379
— —
3.6959 3.7018
3.6911 3.6957
3.6508 3.6632
3B 2B
3.6600 3.673
3.6698 3.688
3.6959 3.7036
3.7022 3.7115
3.7500 3.7500
33⁄4–16 UN
2A
0.0017
3.7483
3.7389
—
3.7077
3.7019
3.6738
2B
3.682
3.696
3.7094
3.7169
3.7500
33⁄4–18 UNS
3A 2A
0.0000 0.0017
3.7500 3.7483
3.7406 3.7396
— —
3.7094 3.7122
3.7051 3.7067
3.6755 3.6822
3B 2B
3.6820 3.690
3.6908 3.703
3.7094 3.7139
3.7150 3.7211
3.7500 3.7500
31⁄2–16 31⁄2–18 35⁄8–6 35⁄8–8
35⁄8–12
Maxd
Class 2B
Min 3.423
Max 3.438
Min 3.4536
Max 3.4615
Min 3.5000
UNIFIED SCREW THREADS
Class 2A
Allowance 0.0018
Internalb UNR Minor Dia.,c Max (Ref.) 3.4132
1759
Copyright 2004, Industrial Press, Inc., New York, NY
Machinery's Handbook 27th Edition
Nominal Size, Threads per Inch, and Series Designationa 37⁄8–6 UN
Externalb
—
3.7637
Min 3.7538
3.8750 3.8723
3.8568 3.8573
— —
3.7667 3.7911
3.7593 3.7820
3.6766 3.7235
3B 2B
3.6950 3.740
3.7146 3.765
3.7667 3.7938
3.7763 3.8056
3.8750 3.8750
0.0000 0.0020
3.8750 3.8730
3.8600 3.8616
— —
3.7938 3.8189
3.7870 3.8124
3.7262 3.7738
3B 2B
3.7400 3.785
3.7547 3.803
3.7938 3.8209
3.8026 3.8294
3.8750 3.8750
0.0000 0.0018
3.8750 3.8732
3.8636 3.8638
— —
3.8209 3.8326
3.8160 3.8267
3.7758 3.7987
3B 2B
3.7850 3.807
3.7948 3.821
3.8209 3.8344
3.8273 3.8420
3.8750 3.8750
0.0000 0.0034 0.0034 0.0000 0.0030 0.0000 0.0027 0.0000 0.0021 0.0020 0.0000 0.0018 0.0018 0.0000 0.0021
3.8750 3.9966 3.9966 4.0000 3.9970 4.0000 3.9973 4.0000 3.9979 3.9980 4.0000 3.9982 3.9982 4.0000 4.2479
3.8656 3.9609 3.9728 3.9762 3.9788 3.9818 3.9823 3.9850 3.9850 3.9866 3.9886 3.9879 3.9888 3.9906 4.2350
— — 3.9609 — — — 3.9748 — — — — — — — —
3.8344 3.8342 3.8342 3.8376 3.8887 3.8917 3.9161 3.9188 3.9329 3.9439 3.9459 3.9518 3.9576 3.9594 4.1829
3.8300 3.8172 3.8229 3.8291 3.8788 3.8843 3.9070 3.9120 3.9259 3.9374 3.9410 3.9456 3.9517 3.9550 4.1759
3.8005 3.6989 3.6989 3.7023 3.7986 3.8016 3.8485 3.8512 3.8768 3.8988 3.9008 3.9132 3.9237 3.9255 4.1289
3B 1B 2B 3B 2B 3B 2B 3B 2B 2B 3B 2B 2B 3B 2B
3.8070 3.729 3.729 3.7290 3.820 3.8200 3.865 3.8650 3.892 3.910 3.9100 3.923 3.932 3.9320 4.142
3.8158 3.767 3.767 3.7594 3.850 3.8396 3.890 3.8797 3.913 3.928 3.9198 3.938 3.946 3.9408 4.