Structural Synthesis of Parallel Robots
SOLID MECHANICS AND ITS APPLICATIONS Volume 173
Series Editor:
G.M.L. GLADWELL Department of Civil Engineering University of Waterloo Waterloo, Ontario, Canada N2L 3GI
Aims and Scope of the Series The fundamental questions arising in mechanics are: Why?, How?, and How much? The aim of this series is to provide lucid accounts written by authoritative researchers giving vision and insight in answering these questions on the subject of mechanics as it relates to solids. The scope of the series covers the entire spectrum of solid mechanics. Thus it includes the foundation of mechanics; variational formulations; computational mechanics; statics, kinematics and dynamics of rigid and elastic bodies: vibrations of solids and structures; dynamical systems and chaos; the theories of elasticity, plasticity and viscoelasticity; composite materials; rods, beams, shells and membranes; structural control and stability; soils, rocks and geomechanics; fracture; tribology; experimental mechanics; biomechanics and machine design. The median level of presentation is the first year graduate student. Some texts are monographs defining the current state of the field; others are accessible to final year undergraduates; but essentially the emphasis is on readability and clarity.
For other titles published in this series, go to www.springer.com/series/6557
Grigore Gogu
Structural Synthesis of Parallel Robots Part 3: Topologies with planar motion of the moving platform
Grigore Gogu Clermont University IFMA, EA 3867, Mechanical Engineering Research Group F-63000 Clermont-Ferrand, France
[email protected] ISSN 0925-0042 ISBN 978-90-481-9830-6 e-ISBN 978-90-481-9831-3 DOI 10.1007/978-90-481-9831-3 Springer Dordrecht Heidelberg London New York Library of Congress Control Number: 2010935808 © Springer Science+Business Media B.V. 2010 No part of this work may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic, mechanical, photocopying, microfilming, recording or otherwise, without written permission from the Publisher, with the exception of any material supplied specifically for the purpose of being entered and executed on a computer system, for exclusive use by the purchaser of the work. Cover Design: SPI Publisher Services Printed on acid-free paper
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Contents
Preface.................................................................................................... VII Acknowledgements ............................................................................XIII List of abbreviations and notations ................................................... XIV 1 Introduction ............................................................................................ 1 1.1 Terminology..................................................................................... 1 1.1.1 Links, joints and kinematic chains ............................................ 2 1.1.2 Serial, parallel and hybrid robots .............................................. 9 1.2 Methodology of structural synthesis .............................................. 10 1.2.1 New formulae for mobility, connectivity, redundancy and overconstraint of parallel robots ...................................................... 10 1.2.2 Evolutionary morphology approach........................................ 16 1.2.3 Types of parallel robots with respect to motion coupling....... 16 1.3 Parallel robots with planar motion of the moving platform ........... 19 2 Overconstrained planar parallel robots with coupled motions........ 27 2.1 Basic solutions ............................................................................... 27 2.1.1 Fully-parallel solutions ........................................................... 27 2.1.2 Non fully-parallel solutions .................................................... 77 2.2 Derived solutions ........................................................................... 87 3 Non overconstrained planar parallel robots with coupled motions183 3.1 Fully-parallel solutions................................................................. 183 3.2 Non fully-parallel solutions.......................................................... 228 4 Planar parallel robots with uncoupled motions............................... 239 4.1 Overconstrained solutions............................................................ 239 4.1.1 Basic solutions ...................................................................... 239 4.1.2 Derived solutions .................................................................. 251 4.2 Non overconstrained solutions..................................................... 271 5 Maximally regular planar parallel robots........................................ 283 5.1 Overconstrained solutions............................................................ 283
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5.1.1 Basic solutions ...................................................................... 283 5.1.2 Derived solutions .................................................................. 289 5.2 Non overconstrained solutions..................................................... 300 6 Spatial PMs with coupled planar motion of the moving platform. 307 6.1 Overconstrained solutions............................................................ 307 6.1.1 Basic solutions ...................................................................... 307 6.1.2 Derived solutions .................................................................. 327 6.2 Non overconstrained solutions..................................................... 346 7 Spatial PMs with uncoupled planar motion of the moving platform.................................................................................................. 367 7.1 Overconstrained solutions............................................................ 367 7.1.1 Basic solutions ...................................................................... 367 7.1.2 Derived solutions .................................................................. 420 7.2 Non overconstrained solutions..................................................... 472 8 Maximally regular SPMs with planar motion of the moving platform.................................................................................................. 529 8.1 Overconstrained solutions............................................................ 529 8.1.1 Basic solutions ...................................................................... 529 8.1.2 Derived solutions .................................................................. 578 8.2 Non overconstrained solutions..................................................... 621 References .............................................................................................. 665 Index ....................................................................................................... 683
Preface
“In other words, the invention of a mechanism will be to the scientific kinematist a synthetic problem, - which he can solve by the use of systematic, if also difficult, methods.” Reuleaux, F., Theoretische Kinematik, Braunschweig: Vieweg, 1875 Reuleaux, F., The Kinematics of Machinery, London: Macmillan, 1876 and New York: Dover, 1963 (translated by A.B.W. Kennedy) This book represents the third part of a larger work dedicated to the structural synthesis of parallel robots. Part 1 (Gogu 2008a) presented the methodology of structural synthesis and the systematisation of structural solutions of simple and complex limbs with two to six degrees of connectivity systematically generated by the structural synthesis approach. Part 2 (Gogu 2009a) presented structural solutions of translational parallel robotic manipulators with two and three degrees of mobility. This book focuses on various topologies of parallel robotic manipulators with planar motion of the moving platform systematically generated by using the structural synthesis approach proposed in Part 1. The originality of this work resides in the fact that it combines the new formulae for mobility connectivity, redundancy and overconstraints, and the evolutionary morphology in a unified approach of structural synthesis giving interesting innovative solutions for parallel mechanisms. Parallel robotic manipulators can be considered a well-established option for many different applications of manipulation, machining, guiding, testing, control, tracking, haptic force feed-back, etc. A typical parallel robotic manipulator consists of a mobile platform connected to the base (fixed platform) by at least two kinematic chains called limbs. The mobile platform can achieve between one and three independent translations (T) and one to three independent rotations (R). Parallel manipulators have been the subject of study of much robotic research during the last two decades. Early research on parallel manipulators has concentrated primarily on six degrees of freedom (DoFs) Gough-
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Stewart-type PMs introduced by Gough for a tire-testing device, and by Stewart for flight simulators. In the last decade, PMs with fewer than 6DoFs attracted researchers’ attention. Lower mobility PMs are suitable for many tasks requiring less than six DoFs. The motion freedoms of the end-effector are usually coupled together due to the multi-loop kinematic structure of the parallel manipulator. Hence, motion planning and control of the end-effector for PMs usually become very complicated. With respect to serial manipulators, such mechanisms can offer advantages in terms of stiffness, accuracy, load-toweight ratio, dynamic performances. Their disadvantages include a smaller workspace, complex command and lower dexterity due to a high motion coupling, and multiplicity of singularities inside their workspace. Uncoupled, fully-isotropic and maximally regular PMs can overcome these disadvantages. Isotropy of a robotic manipulator is related to the condition number of its Jacobian matrix, which can be calculated as the ratio of the largest and the smallest singular values. A robotic manipulator is fully-isotropic if its Jacobian matrix is isotropic throughout the entire workspace, i.e., the condition number of the Jacobian matrix is equal to one. We know that the Jacobian matrix of a robotic manipulator is the matrix mapping (i) the actuated joint velocity space on the end-effector velocity space, and (ii) the static load on the end-effector and the actuated joint forces or torques. The isotropic design aims at ideal kinematic and dynamic performance of the manipulator. We distinguish five types of PMs (i) maximally regular PMs, if the Jacobian J is an identity matrix throughout the entire workspace, (ii) fullyisotropic PMs, if the Jacobian J is a diagonal matrix with identical diagonal elements throughout the entire workspace, (iii) PMs with uncoupled motions if J is a diagonal matrix with different diagonal elements, (iv) PMs with decoupled motions, if J is a triangular matrix and (v) PMs with coupled motions if J is neither a triangular nor a diagonal matrix. Maximally regular and fully-isotropic PMs give a one-to-one mapping between the actuated joint velocity space and the external velocity space. The first solution for a fully-isotropic T3-type translational parallel robot was developed at the same time and independently by Carricato and Parenti-Castelli at University of Genoa, Kim and Tsai at University of California, Kong and Gosselin at University of Laval, and the author of this work at the French Institute of Advanced Mechanics. In 2002, the four groups published the first results of their works. The general methods used for structural synthesis of parallel mechanisms can be divided into three approaches: the method based on displacement group theory, the methods based on screw algebra, and the
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method based on the theory of linear transformations. The method proposed in this work is based on the theory of linear transformations and the evolutionary morphology and allows us to obtain the structural solutions of decoupled, uncoupled, fully-isotropic and maximally regular PMs with two to six DoFs in a systematic way. The new formulae for mobility, connectivity (spatiality), redundancy and overconstraint of PMs proposed recently by the author are integrated into the synthesis approach developed in this work. Various solutions of TaRb-type PMs are known today. In this notation, a=1,2,3 indicates the number of independent translations and b=1,2,3 the number of independent rotations of the moving platform. The parallel robots actually proposed by the robot industry have coupled and decoupled motions and just some isotropic positions in their workspace. As far as we are aware, this is the first work on robotics presenting solutions of uncoupled, fully-isotropic and maximally regular PMs along with coupled solutions obtained by a systematic approach of structural synthesis. Non-redundant/redundant, overconstrained/isostatic solutions of uncoupled and fully-isotropic/maximally regular PMs with elementary/complex limbs actuated by linear/rotary actuators with/without idle mobilities and two to six DoFs are present in a systematic approach of structural synthesis. A serial kinematic chain is associated with each elementary limb and at least one closed loop is integrated in each complex limb. The synthesis methodology and the solutions of PMs presented in this work represent the outcome of some recent research developed by the author in the last years in the framework of the projects ROBEA-MAX and ROBEA-MP2 supported by the National Center for Scientific Research (CNRS). These results have been partially published by the author in the last years. In these works the author has proposed the following for the first time in the literature: a) new formulae for calculating the degree of mobility, the degree of connectivity(spatiality), the degree of redundancy and the number of overconstraints of parallel robotic manipulators that overcome the drawbacks of the classical Chebychev-Grübler-Kutzbach formulae, b) a new approach to systematic innovation in engineering design called evolutionary morphology, c) solutions of TaRb-type fully-isotropic and maximally regular PMs for any combination of a independent translations and b independent rotations of the moving platform. The various solutions of maximally regular PMs proposed by the author belong to a modular family called Isogliden-TaRb with a+b=n with 2 ≤ n ≤ 6, a=1,2,3 and b=1,2,3. The mobile platform of these robots can have any combination of n independent translations (T) and rotations (R).
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The Isogliden-TaRb modular family was developed by the author and his research team of the Mechanical Engineering Research Group (LaMI), Blaise Pascal University and French Institute of Advanced Mechanics (IFMA) in Clermont-Ferrand. Part 1 of this work (Gogu, 2008a) was organized in ten chapters. The first chapter introduced the main concepts, definitions and components of the mechanical robotic system. Chapter 2 reviewed the contributions in mobility calculation systematized in the so called Chebychev-GrüblerKutzbach mobility formulae. The drawbacks and the limitations of these formulae are discussed, and the new formulae for mobility, connectivity, redundancy and overconstraint are demonstrated via an original approach based on the theory of linear transformations. These formulae are applied in chapter 3 for the structural analysis of parallel robots with simple and complex limbs. The new formulae are also applied to calculate the mobility and other structural parameters of single and multi-loop mechanisms that do not obey the classical Chebychev-Grübler-Kutzbach formulae, such as the mechanisms proposed by De Roberval, Sarrus, Bennett, Bricard and other so called “paradoxical mechanisms”. We have shown that these mechanisms completely obey the definitions, the theorems and the formulae proposed in the previous chapter. There is no reason to continue to consider them as “paradoxical”. Chapter 4 presented the main models and performance indices used in parallel robots. We put particular emphasis on the Jacobian matrix, which is the main issue in defining robot kinematics, singularities and performance indices. New kinetostatic performance indices are introduced in this section to define the motion decoupling and inputoutput propensity in parallel robots. Structural parameters introduced in the second chapter are integrated in the structural synthesis approach founded on the evolutionary morphology (EM) presented in chapter 5. The main paradigms of EM are presented in a closed relation with the biological background of morphological approaches and the synthetic theory of evolution. The main difference between the evolutionary algorithms and the EM are also discussed. The evolutionary algorithms are methods for solving optimization-oriented problems, and are not suited to solving conceptual design-oriented problems. They always start from a given initial population of solutions and do not solve the problem of creating these solutions. The first stage in structural synthesis of parallel robots is the generation of the kinematic chains called limbs used to give some constrained or unconstrained motion to the moving platform. The constrained motion of the mobile platform is obtained by using limbs with less than six degrees of connectivity. The various solutions of simple and complex limbs with two to six degrees of connectivity are systematically generated by the structural
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synthesis approach and presented in chapters 6-10. We focused on the solutions with a unique basis of the operational velocity space that are useful for generating various topologies of decoupled, uncoupled, fully-isotropic and maximally regular parallel robots presented in Parts 2 and 3. Limbs with multiple bases of the operational velocity space and redundant limbs are also presented in these chapters. These limb solutions are systematized with respect to various combinations of independent motions of the distal link. They are defined by symbolic notations and illustrated in about 250 figures containing more than 1500 structural diagrams. The kinematic chains presented in chapters 6-10 are useful as innovative solutions of limbs in parallel, serial and hybrid robots. In fact, serial and hybrid robots may be considered as a particular case of parallel robots with only one limb which can be a simple, complex or hybrid kinematic chain. Many serial robots actually combine closed loops in their kinematic structure. The various types of kinematic chains generated in chapters 6-10 of Part 1 are combined in Parts 2 and 3 and the following parts to set up innovative solutions of parallel robots with two to six degrees of mobility and various sets of independent motions of the moving platform. Part 2 of this work (Gogu, 2009a) was organised in 7 chapters. The first chapter recalled the main concepts, the new formulae used to calculate the main structural parameters of PMs, and the original approach of structural synthesis. Chapter 2 focused on the structural synthesis of T2-type translational parallel manipulators (TPMs) with two degrees of freedom used in pick-and-place operations. Overconstrained/isostatic solutions of coupled, decoupled, uncoupled and fully-isotropic/maximally regular PMs with elementary/complex limbs actuated by linear/rotary actuators with/without idle mobilities are presented. Chapter 3 presented the structural synthesis of overconstrained T3-type translational parallel manipulators with three degrees of freedom and coupled motions. Basic and derived solutions with linear or rotating actuators are presented. The basic solutions do not combine idle mobilities. Idle mobilities are used to reduce the degree of overconstraint in the derived solutions. The structural synthesis of non-overconstrained T3-type TPMs with decoupled motions is presented in chapter 4. Basic and derived solutions with linear or rotating actuators are on hand. Chapters 5 and 6 presented the structural synthesis of overconstrained and non-overconstrained T3-type TPMs with uncoupled motions. Basic and derived solutions with rotating actuators and identical limbs are presented. Chapter 7 focused on the structural synthesis of overconstrained and nonoverconstrained maximally regular T3-type TPMs. Basic and derived solutions with linear actuators and identical limbs are on hand. About 1000 solutions of TPMs are illustrated in 550 figures. The structural parameters of these solutions are systematized in 134 tables.
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This book representing Part 3 is organised in 8 chapters. The first chapter recalls, the main concepts, the new formulae used to calculate the main structural parameters of PMs, and the original approach of structural synthesis applied to parallel robots with planar motion of the moving platform. In such a robot, the moving platform can undergo two independent translational motions T2 and one rotational motion R1 around an axis perpendicular to the plane of translations. This motion can be obtained by using planar or spatial parallel mechanisms. Chapters 2 and 3 present the structural synthesis of overconstrained and non-overconstrained planar parallel robots with coupled motions. Basic and derived fully-parallel and non fully-parallel solutions are on hand. The structural synthesis of overconstrained and non-overconstrained planar parallel robots with uncoupled motions is presented in Chapter 4. Chapter 5 focuses on the structural synthesis of overconstrained and non-overconstrained maximally regular planar parallel robots. Chapters 6 and 7 present the structural synthesis of basic and derived solutions of overconstrained and non-overconstrained spatial parallel robots with coupled and uncoupled planar motions of the moving platform. Chapter 8 focuses on the structural synthesis of overconstrained and non-overconstrained maximally regular spatial parallel robots with planar motion of the moving platform. About 750 solutions are illustrated in 400 figures. The structural parameters of these solutions are systematized in 150 tables. Special attention was paid to graphic quality of structural diagrams to ensure a clear correspondence between the symbolic and graphic notation of joints and the relative position of their axes. The graphic illustration of the various solutions is associated with the author’s conviction that a good structural diagram really “is worth a thousand words”, especially when you are trying to disseminate the result of the structural synthesis of kinematic chains. The following parts of this work will present the structural synthesis of other PMs with two and three degrees of freedom (Part 4) and PMs with four, five and six degrees of freedom (Part 5). The writing of Parts 4 and 5 is still in progress and will soon be finalized. Many solutions for parallel robots obtained through this systematic approach of structural synthesis are presented, in this work, for the first time in the literature. The author had to make a difficult and challenging choice between protecting these solutions through patents, and releasing them directly into the public domain. The second option was adopted by publishing them in various recent scientific publications and mainly in this work. In this way, the author hopes to contribute to a rapid and widespread implementation of these solutions in future industrial products.
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Acknowledgements The scientific environment of the projects ROBEA-MAX and ROBEAMP2 supported by the CNRS was the main source of encouragement and motivation to pursue the research on the structural synthesis of parallel robots and to finalize this work. Deep gratitude is expressed here to Dr. François Pierrot, Deputy Director of LIRMM and coordinator of both ROBEA projects, and also to all colleagues involved in these projects from the research laboratories LIRMM, INRIA, IRCCyN LASMEA and LaMI for the valuable scientific exchanges during the joint work on these projects. Moreover, financial support from the CNRS, FR TIMS and IFMA for developing the innovative Isoglide-family of parallel robots is duly acknowledged. Furthermore, Prof. Graham M.L. Gladwell, the series editor of Solids Mechanics and Its Applications, and Mrs. Nathalie Jacobs, Springer Dordrecht Engineering Editor are gratefully acknowledged for their availability and encouragement in pursuing this publishing project. Ms. Sarah Davey is also gratefully acknowledged for the linguistic reviewing of this manuscript. May I also acknowledge the excellent facilities and research environment provided by LaMI and IFMA which contributed actively to the completion of this project. To conclude, I cannot forget my wife Iléana and my son Christian for their love, affection and encouragement, providing the fertile ambience for this sustained work very often prolonged late into the evening and mostly during week-ends and holidays.
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List of abbreviations and notations C - cylindrical joint C* - cylindrical joint with one or two idle mobilities CNRS - Centre National de la Recherche Scientifique (National Center for Scientific Research) DoF - degree-of-freedom eA and eG1 - link of G1-limb (e=1,2,3,…,n) eB and eG2 - link of G2-limb (e=1,2,3,…,n) eC and eG3 - link of G3-limb (e=1,2,3,…,n) eD and eG4 - link of G4-limb (e=1,2,3,…,n) EM - evolutionary morphology fi - degree of mobility of the ith joint F ← G1-G2-…-Gk general notation for the kinematic chain associated to a parallel mechanism with k simple and/or complex limbs Gi (i=1, 2,…,k) FR TIMS - Fédération de Recherche Technologies de l’Information, de la Mobilité et de la Sûreté Gi (1Gi-2Gi-…nGi) - kinematic chain associated to the ith limb H - characteristic point of the distal link/end-effector IFMA - Institut Français de Mécanique Avancée (French Institute of Advanced Mechanics) IFToMM - International Federation for the Promotion of Mechanism and Machine Science INRIA - Institut National de Recherche en Informatique et en Automatique (The French National Institute for Research in Computer Science and Control) IRCCyN - Institut de Recherche en Communications et Cybernétique de Nantes I n×n - n×n identity matrix J - Jacobian matrix k - total number of limbs in the parallel manipulator k1 - number of simple limbs in the parallel manipulator k2 - number of complex limbs in the parallel manipulator LaMI - Laboratoire de Mécanique et Ingénieries (Mechanical Engineering Research Group) LASMEA - Laboratoire des Sciences et Matériaux pour l’Electronique, et d’Automatique (Laboratory of Sciences and Materials for Electronic, and of Automatic)
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LIRMM - Laboratoire d’Informatique, de Robotique et de Microélectronique de Montpellier (Montpellier Laboratory of Computer Science, Robotics, and Microelectronics) m - total number of links including the fixed base MF - mobility of parallel mechanism F MGi - mobility of the kinematic chain associated with limb Gi NF - number of overconstraints in the parallel mechanism F n nGi - moving platform in the parallel mechanism F ← G1-G2-…-Gk, O0x0y0z0 - reference frame p - total number of joints in the parallel mechanism pGi - number of joints in Gi-limb P - prismatic joint P - actuated prismatic joint P* - prismatic joint with idle mobility Pa - R||R||R||R-type planar parallelogram loop Pa - R||R||R||R-type parallelogram loop with an actuated revolute joint Pa* or Pacs - R||R||C-S-type parallelogram loop with three idle mobilities combined in a cylindrical and a spherical joint Pac - R||R||R||C-type parallelogram loop with one idle mobility combined in a cylindrical joint Pasu - parallelogram loop with three idle mobilities combined in a spherical and a revolute joint Pas - R||R||R-S-type parallelogram loop with two idle mobilities combined in a spherical joint Pass - R||R-S-S-type parallelogram loop with idle mobilities combined in two spherical joints adjacent to the same link Pat - R ⊥ P ⊥ ||R||R ⊥ P ⊥ ||R-type telescopic planar parallelogram loop Patcs - telescopic parallelogram loop with three idle mobilities combined in a cylindrical and a spherical pair Pau - parallelogram loop with one idle mobility combined in a universal joint Pauu - parallelogram loop with two idle mobilities combined in two universal joints PM - parallel manipulator Pn2 - planar close loop with two degrees of mobility Pn2* or Pn2cs - close loop with two degrees of mobility and three idle mobilities combined in a cylindrical and a spherical pair Pn3 - planar close loop with three degrees of mobility Pn3* or Pn3cs - close loop with three degrees of mobility and three idle mobilities combined in a cylindrical and a spherical pair PPM - planar parallel manipulator q - number of independent closed loops in the parallel mechanism
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&q - joint velocity vector qi - finite displacement in the ith actuated joint rF - total number of joint parameters that lose their independence in the closed loops combined in parallel mechanism F rl - total number of joint parameters that lose their independence in the closed loops combined in the k limbs rGi - number of joint parameters that lost their independence in the closed loops combined in Gi-limb, R - revolute joint R - actuated revolute joint R* - revolute joint with idle mobility Rb - rhombus loop Rb* or Rbcs - planar rhombus loop with three idle mobilities combined in a cylindrical and a spherical joint RF - the vector space of relative velocities between the mobile and the reference platforms in the parallel mechanism F ← G1-G2-…-Gk, (RF) - the basis of vector space RF RGi - the vector space of relative velocities between the mobile and the reference platforms in the kinematic chain Gi disconnected from the parallel mechanism F ← G1-G2-…-Gk, (RGi) - the basis of vector space RGi S - spherical joint S* - spherical joint with idle mobilities SF - the connectivity between the mobile and the reference platforms in the parallel mechanism F ← G1-G2-…-Gk. SGi - the connectivity between the mobile and the reference platforms in the kinematic chain Gi disconnected from the parallel mechanism F ← G1-G2-…-Gk. SPM - spatial parallel manipulator TF - degree of structural redundancy of parallel mechanism F TPM - translational parallel manipulator U - universal joint U* - universal joint with an idle mobility v , v1 , v2 , v3 - translational velocity vectors x, y, z - coordinates of characteristic point H &x,&y,z& - time derivatives of coordinates α , β ,δ - rotation angles
α& , β& ,δ& - time derivatives of the rotation angles ,
α
,
β
,
δ
- angular velocity vectors
0 - fixed base of a kinematic chain/mechanism
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1 1Gi– fixed platform in the parallel mechanism F ← G1-G2-…-Gk, 1Gi-2Gi-…-nGi - links of limb Gi 1A-2A-…-nA - links of limb G1 1B-2B-…-nB - links of limb G2 1C-2C-…-nC - links of limb G3 1D-2D-…-nD - links of limb G4 1 and 2 in the notation 2PRR-1RPaPa - the parallel mechanism has two limb of type PRR and one limb of type RPaPa || - parallel position of joint axes/directions; for example the notation Pa||Pass indicates the fact that the axes of the revolute joints of the parallelogram loops Pa and Pass are parallel ⊥ - perpendicular position of joint axes/directions; for example the notation P ⊥ Pa indicates the fact that the axes of revolute joints in the parallelogram loop are perpendicular to the direction of the prismatic joint || || ⊥ in the notation R ⊥ P ⊥ C - the axis of the cylindrical joint is perpendicular to the direction of the actuated prismatic joint and parallel to the direction of the revolute joint || || ⊥ in the notation R ⊥ Pa ⊥ Pa - the revolute axes of the second parallelogram loop are perpendicular to the revolute axes of the first parallelogram loop and parallel to the axis of the actuated revolute joint ⊥ ⊥ in the notation R ⊥ Pa ⊥ ⊥ Pa - the revolute axes of the second parallelogram loop are perpendicular to the revolute axes of the first parallelogram loop and also to the axis of the actuated prismatic joint ⊥ ⊥ in the notation Pass ⊥ R||R ⊥ ⊥ Pa - the revolute axes of parallelogram loop Pa are perpendicular to the axes of the parallel revolute joints R R and also to the axes of the revolute joints of parallelogram loop Pass
1 Introduction
This book represents Part 3 of a larger work on the structural synthesis of parallel robots. The originality of this work resides in combining new formulae for the structural parameters and the evolutionary morphology in a unified approach of structural synthesis giving interesting innovative solutions for parallel robots. Part 1 (Gogu 2008a) presented the methodology of structural synthesis and the systematisation of structural solutions of simple and complex limbs with two to six degrees of connectivity systematically generated by the structural synthesis approach. Part 2 (Gogu 2009a) presented structural solutions of translational parallel robotic manipulators (TPMs) with two and three degrees of mobility. Part 3 of this work focuses on the structural solutions of parallel robotic manipulators with planar motion of the moving platform. This section recalls the terminology, the new formulae for the main structural parameters of parallel robots (mobility, connectivity, redundancy and overconstraint) and the main features of the methodology of structural synthesis based on the evolutionary morphology presented in Part 1.
1.1 Terminology Robots can be found today in the manufacturing industry, agricultural, military and domestic applications, space exploration, medicine, education, information and communication technologies, entertainment, etc. We have presented in Part 1 various definitions of the word robot and we have seen that it is mainly used to refer to a wide range of mechanical devices or mechanisms, the common feature of which is that they are all capable of movement and can be used to perform physical tasks. Robots take on many different forms, ranging from humanoid, which mimic the human form and mode of movement, to industrial, whose appearance is dictated by the function they are to perform. Robots can be categorized as robotic manipulators, wheeled robots, legged robots swimming robots, flying robots, androids and self reconfigurable robots which can apply themselves to a given task. This book focuses on parallel robotic manipulators G. Gogu, Structural Synthesis of Parallel Robots, Solid Mechanics and Its Applications 173, DOI 10.1007/978-90-481-9831-3_1, © Springer Science + Business Media B.V. 2010
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1 Introduction
which are the counterparts to the serial robots. The various definitions of robotics converge towards the integration of the design and the end use in the studies related to robotics. This book focuses on the conceptual design of parallel robots. Although the appearance and capabilities of robots vary greatly, all robots share the features of a mechanical, movable structure under some form of control. The structure of a robot is usually mostly mechanical and takes the form of a mechanism having as constituent elements the links connected by joints. 1.1.1 Links, joints and kinematic chains Serial or parallel kinematic chains are concatenated in the robot mechanism. The serial kinematic chain is formed by links connected sequentially by joints. Links are connected in series as well as in parallel making one or more closed-loops in a parallel mechanism. The mechanical architecture of parallel robots is based on parallel mechanisms in which a member called a moving platform is connected to a reference member by at least two limbs that can be simple or complex. The robot actuators are integrated in the limbs (also called legs) usually closed to the fixed member, also called the base or the fixed platform. The moving platform positions the robot end-effector in space and may have anything between two and six degrees of freedom. Usually, the number of actuators coincides with the degrees of freedom of the mobile platform, exceeding them only in the case of redundantly-actuated parallel robots. The paradigm of parallel robots is the hexapod-type robot, which has six degrees of freedom, but recently, the machine industry has discovered the potential applications of lower-mobility parallel robots with just 2, 3, 4 or 5 degrees of freedom. Indeed, the study of this type of parallel manipulator is very important. They exhibit interesting features when compared to hexapods, such as a simpler architecture, a simpler control system, highspeed performance, low manufacturing and operating costs. Furthermore, for several parallel manipulators with decoupled or uncoupled motions, the kinematic model can be easily solved to obtain algebraic expressions, which are well suited for implementation in optimum design problems. Parallel mechanisms can be considered a well-established solution for many different applications of manipulation, machining, guiding, testing, control, etc. The terminology used in this book is mainly established in accordance with the terminology adopted by the International Federation for the Promotion of Mechanism and Machine Science (IFToMM) and published in
1.1 Terminology
3
(Ionescu 2003). The main terms used in this book concerning kinematic pairs (joints), kinematic chains and robot kinematics are defined in Tables 1.1-1.3 in Part 1 of this work. They are completed by some complementary remarks, notations and symbols used in this book. IFToMM terminology (Ionescu 2003) defines a link as a mechanism element (component) carrying kinematic pairing elements and a joint is a physical realization of a kinematic pair. The pairing element represents the assembly of surfaces, lines or points of a solid body through which it may contact with another solid body. The kinematic pair is the mechanical model of the connection of two pairing elements having relative motion of a certain type and degree of freedom. In the standard terminology, a kinematic chain is an assembly of links (mechanism elements) and joints, and a mechanism is a kinematic chain in which one of its links is taken as a “frame”. In this definition, the “frame” is a mechanism element deemed to be fixed. In this book, we use the notion of reference element to define the “frame” element. The reference element can be fixed or may merely be deemed to be fixed with respect to other mobile elements. The fixed base is denoted in this book by 0. A mobile element in a kinematic chain G is denoted by nG (n=1, 2, …). Two or more links connected together in the same link such that no relative motion can occur between them are considered as one link. The identity symbol “ ” is used between the links to indicate that they are welded together in the same link. For example, the notation 1G 0 is used to indicate that the first link 1G of the kinematic chain G is the fixed base. A kinematic chain G is denoted by the sequence of its links. The notation G (1G 0-2G-…-nG) indicates a kinematic chain in which the first link is fixed and the notation G (1G-2G-…nG) a kinematic chain with no fixed link. We will use the notion of mechanism to qualify the whole mechanical system, and the notion of kinematic chain to qualify the sub-systems of a mechanism. So, in this book, the same assembly of links and joints G will be considered to be a kinematic chain when integrated as a sub-system in another assembly of links and joints and will be considered a mechanism when G represents the whole system. The systematization, the definitions and the formulae presented in this book are valuable for mechanisms and kinematic chains. We use the term mechanism element or link to name a component (member) of a mechanism. In this book, unless otherwise stated, we consider all links to be rigid. We distinguish the following types of links: a) monary link - a mechanism element connected in the kinematic chain by only one joint (a link which carries only one kinematic pairing element),
4
1 Introduction
b) binary link - a mechanism element connected in the kinematic chain by two joints (a link connected to two other links), c) polinary link - a mechanism element connected in the kinematic chain by more than two joints (ternary link - if the link is connected by three joints, quaternary link if the link is connected by four joints). The IFToMM terminology defines open/closed kinematic chains and mechanisms, but it does not introduce the notions of simple (elementary) and complex kinematic chains and mechanisms. A closed kinematic chain is a kinematic chain in which each link is connected with at least two other links, and an open kinematic chain is a kinematic chain in which there is at least one link which is connected in the kinematic chain by just one joint. In a simple open kinematic chain (open-loop mechanism) only monary and binary links are connected. In a complex kinematic chain at least one ternary link exists. We designate in each mechanism two extreme elements called reference element and final element. They are also called distal links. In an open kinematic chain, these elements are situated at the extremities of the chain. In a single-loop kinematic chain, the final element can be any element of the chain except the reference element. In a parallel mechanism, the two distal links are the moving and the reference platform. The two platforms are connected by at least two simple or complex kinematic chains called limbs. Each limb contains at least one joint. A simple limb is composed of a simple open kinematic chain in which the final element is the mobile platform. A complex limb is composed of a complex kinematic chain in which the final element is also the mobile platform. IFToMM terminology (Ionescu 2003) uses the term kinematic pair to define the mechanical model of the connection of links having relative motion of a certain type and degree of freedom. The word joint is used as a synonym for the kinematic pair and also to define the physical realization of a kinematic pair, including connection via intermediate mechanism elements. Both synonymous terms are used in this text. Usually, in parallel robots, lower pairs are used: revolute R, prismatic P, helical H, cylindrical C, spherical S and planar pair E. The definitions of these kinematic pairs are presented in Table 1.1 – Part 1. The graphical representations used in this book for the lower pairs are presented in Fig. 1.1(a)-(f). Universal joints and homokinetic joints are also currently used in the mechanical structure of the parallel robots to transmit the rotational motion between two shafts with intersecting axes. If the instantaneous velocities of the two shafts are always the same, the kinematic joint is homokinetic (from the Greek “homos” and “kinesis” meaning “same” and “movement”). We know that the universal joint (Cardan joint or Hooke’s joint) are heterokinetic joints. Various types of homokinetic joints (HJ) are known today: Tracta, Weiss, Bendix, Dunlop, Rzeppa, Birfield, Glaenzer,
1.1 Terminology
5
Thompson, Triplan, Tripode, UF (undercut-free) ball joint, AC (angular contact) ball joint, VL plunge ball joint, DO (double offset) plunge ball joint, AAR (angular adjusted roller), helical flexure U-joints, etc. (Dudi et al. 1989, 2001a, b). The graphical representations used in this book for the universal homokinetic joints are presented in Fig. 1.1(g)-(h). Joints with idle mobilities are commonly used to reduce the number of overconstraints in a mechanism. The idle mobility is a potential mobility of a joint that is not used by the mechanism and does not influence mechanism’s mobility in the hypothesis of perfect manufacturing and assembling precision. In theoretical conditions, when no errors exist with respect to parallel, perpendicular or intersecting positions of joint axes, motion amplitude of an idle mobility is zero. Real life manufacturing and assembling processes introduce errors in the relative positions of the joint axes and, in this case, the idle mobilities become effective mobilities usually with small amplitudes, depending on the precision of the mechanism. For example, the idle mobilities which can be combined in the parallelogram loop in Fig. 1.2 are systematized in Table 1.1 along with the number r of parameters that lose their independence in the closed loop and the number of overconstraints N of the corresponding linkage. A parallel mechanism is a single or multi-loop linkage in which a moving link called characteristic link or platform is connected to a reference link (fixed base) by at least two non interconnected kinematic chains called limbs.
Fig. 1.1. Symbols used to represent the lower kinematic pairs and the kinematic joints: (a) revolute pair, (b) prismatic pair, (c) helical pair, (d) cylindrical pair, (e) spherical pair, (f) planar contact pair, (g) universal joint, (h) homokinetic joint, (i) two superposed revolute joints (1-2) and (2-3) with the same axis, (j) superposed cylindrical (1-2) and revolute (2-3) joints with the same axis, (k) superposed revolute (1-2) and cylindrical (2-3) joints with the same axis, and (l) two superposed cylindrical joints (1-2) and (2-3) with the same axis
6
1 Introduction
Fig. 1.2. Parallelogram loops of types Pa (a), Pac (b), Pau (c), Pas (d), Pauu (e), Pacu (f), Pa* (g), Pasu (h) , Pass (i) and the number of r parameters that lost their independence in the closed loop
1.1 Terminology
7
Table 1.1. Parallelogram loops with idle mobilities and their corresponding number of overconstraints N No. Parallelogram loop 1 Pa (Fig. 1.2a) 2 Pac (Fig. 1.2b)
N 3 2
3
Pau (Fig. 1.2c)
2
4
Pas (Fig. 1.2d)
1
5
Pauu (Fig. 1.2e)
1
6
Pacu (Fig. 1.2f)
1
7
Pacs, Pa* (Fig. 1.2g) 0
8
Pasu (Fig. 1.2h)
0
9
Pass (Fig. 1.2i)
0
Idle mobilities No idle mobilities One translational idle mobility combined in a cylindrical joint One rotational idle mobility combined in a universal joint Two rotational idle mobilities combined in a spherical joint Two rotational idle mobilities combined in two universal joints One translational idle mobility combined in a cylindrical joint and one rotational idle mobilities combined in a universal joint One translational idle mobility combined in a cylindrical joint and two rotational idle mobilities combined in a spherical joint Three rotational idle mobilities combined in one revolute joint and one spherical joint Three idle mobilities combined in two spherical joints adjacent to the same link with a complementary internal rotational mobility of the link adjacent to the two spherical joints.
A parallel robot can be illustrated by a physical implementation or by an abstract representation. The physical implementation is usually illustrated by robot photography and the abstract representation by a CAD model, structural diagram and structural graph. Figure 1.3 gives an example of the various representations of a Gough-Stewart type parallel robot largely used today in industrial applications. The physical implementation in Fig. 1.3a is a photograph of the parallel robot built by Deltalab (http: //www.deltalab.fr/). In a CAD model (Fig. 1.3b) the links and the joints are represented as being as close as possible to the physical implementation (Fig. 1.3a). In a structural diagram (Fig. 1.3c) they are represented by simplified symbols, such as those introduced in Fig. 1.1, respecting the geometric relations defined by the relative positions of joint axes. A structural graph (Fig. 1.3d) is a network of vertices or nodes connected by edges or arcs with no geometric relations. The links are noted in the nodes and the joints on the edges. We can see that the Gough-Stewart type parallel robot has six identical limbs denoted in Fig. 1.3c by A, B, C, D , E and F. The final link is the mobile platform 4 4A 4B 4C 4D 4E 4F
8
1 Introduction
Fig. 1.3. Various representations of a Gough-Stewart type parallel robot: physical implementation (a), CAD model (b), structural diagram (c) and its associated graph (d), A-limb (e) and its associated graph (f)
1.1 Terminology
9
and the reference member is the fixed platform 1A 1B 1C 1D 1E 1F 0. Each limb is connected to both platforms by spherical pairs. A prismatic pair is actuated in each limb. The spherical pairs are not actuated and are called passive pairs. The two platforms are polinary links, the other two links of each limb are binary links. The parallel mechanism 6-SPS-type associated with the Gough-Stewart type parallel robot is a complex mechanism with a multi-loop associated graph (Fig. 1.3d). It has six simple limbs of type SPS. The actuated pair is underlined. The simple open kinematic chain associated with A-limb is denoted by A (1A 0-2A-3A-4A 4) – Fig. 1.3e and its associated graph is tree-type (Fig. 1.3f). 1.1.2 Serial, parallel and hybrid robots We consider the general case of a robot in which the end-effector is connected to the reference link by k≥1 kinematic chains. The end-effector is a binary or polynary link called a mobile platform in the case of parallel robots, and a monary link for serial robots. The reference link may either be the fixed base or may be deemed to be fixed. The kinematic chains connecting the end-effector to the reference link can be simple or complex. They are called limbs or legs in the case of parallel robots. A serial robot can be considered to be a parallel robot with just one simple limb, and a hybrid robot a parallel robot with just one complex limb. We denote by F ← G1-G2-…-Gk the kinematic chain associated with a general serial, parallel or hybrid robot, and by Gi (1Gi-2Gi-…-nGi) the kinematic chain associated with the ith limb (i=1,2,…,k). The end effector is n nGi and the reference link 1 1Gi. If the reference link is the fixed base, it is denoted by 1 1Gi 0. The total number of robot joints is denoted by p. A serial robot F ← G1 is a robot in which the end-effector n nG1 is connected to the reference link 1 1G1 by just one simple open kinematic chain Gi (1Gi-2Gi-…nGi) called a serial kinematic chain. A parallel robot F ← G1-G2-…-Gk is a robot in which the end-effector n nGi is connected in parallel to the reference link 1 1Gi by k≥2 kinematic chains Gi (1Gi-2Gi-…-nGi) called limbs or legs. A hybrid serial-parallel robot F ← G1 is a robot in which end-effector n nG1 is connected to reference link 1 1G1 by just one complex kinematic chain Gi (1Gi-2Gi-…nGi) called complex limb or complex leg. A fully-parallel robot F ← G1-G2-…Gk is a parallel robot in which the number of limbs is equal to the robot mobility (k=M≥2), and just one actuator exist in each limb.
10
1 Introduction
A non fully-parallel robot F ← G1-G2-…Gk is a parallel robot with fewer number of limbs than the robot mobility (k<M), and at least one limb has more than one actuator.
1.2 Methodology of structural synthesis Recent advances in research on parallel robots have contributed mainly to expanding their potential use to both terrestrial and space applications including areas such as high speed manipulation, material handling, motion platforms, machine tools, medical applications, planetary and underwater exploration. Therefore, the need for methodologies devoted to the systematic design of highly performing parallel robots is continually increasing. Structural synthesis is directly related to the conceptual phase of robot design, and represents one of the highly challenging subjects in recent robotics research. One of the most important activities in the invention and the design of parallel robots is to propose the most suitable solutions to increase the performance characteristics. The challenging and difficult objective of structural synthesis is to find a method to set up the mechanical architecture to achieve the required structural parameters. The mechanical architecture or topology is defined by number, type and relative position of joint axes in the parallel robot. The structural parameters are mobility, connectivity, redundancy and the number of overconstraints. They define the number of actuators, the degrees of freedom and the motion-type of the moving platform. A systematic approach of structural synthesis founded on the theory of linear transformations and an evolutionary morphology has been proposed in Part 1 (Gogu 2008a). The approach integrates the new formulae for mobility, connectivity, redundancy and overconstraint of parallel manipulators (Gogu 2005d, 2005e) and a new method of systematic innovation (Gogu 2005a). 1.2.1 New formulae for mobility, connectivity, redundancy and overconstraint of parallel robots Mobility is the main structural parameter of a mechanism and also one of the most fundamental concepts in the kinematic and the dynamic modelling of mechanisms. IFToMM terminology defines the mobility or the degree of freedom as the number of independent coordinates required to define the configuration of a kinematic chain or mechanism.
1.2 Methodology of structural synthesis
11
We note that the mobility of a mechanism can be defined by the number of independent finite and/or infinitesimal displacements in the joints needed to define the configuration of the mechanism (Gogu 2008a). Mobility of a mechanism represents the sum of internal and external mobilities. The internal mobilities are localized to the level of a link or a group of links. They can be associated with finite or infinitesimal motions. The external mobilities are associated with the independent finite motions transmitted by the mechanism between the actuators and the end-effector. Mobility M is used to verify the existence of a mechanism (M>0), to indicate the number of independent parameters in robot modelling and to determine the number of inputs needed to drive the mechanism. Earlier works on the mobility of mechanisms go back to the second half of the nineteenth century. During the twentieth century, sustained efforts were made to find general methods for the determination of the mobility of any rigid body mechanism. Various formulae and approaches were derived and presented in the literature. Contributions have continued to emerge in the last few years. Mobility calculation still remains a central subject in the theory of mechanisms. In Part 1 (Gogu 2008a) we have shown that the various methods proposed in the literature for mobility calculation of the closed loop mechanisms fall into two basic categories: a) approaches for mobility calculation based on setting up the kinematic constraint equations and calculating their rank for a given position of the mechanism with specific joint locations, b) formulae for a quick calculation of mobility without the need to develop the set of constraint equations. The approaches used for mobility calculation based on setting up the kinematic constraint equations and their rank calculation are valid without exception. The major drawback of these approaches is that the mobility cannot be determined quickly without setting up the kinematic model of the mechanism. Usually this model is expressed by the closure equations that must be analyzed for dependency. The information about mechanism mobility is derived by performing position, velocity or static analysis by using analytical tools (screw theory, linear algebra, affine geometry, Lie algebra, etc). For this reason, the real and practical value of these approaches is very limited in spite of their valuable theoretical foundations. Moreover, the rank of the constraint equations is calculated in a given position of the mechanism with specific joint locations. The mobility calculated in relation to a given configuration of the mechanism is an instantaneous mobility which can be different from the general mobility (global mobility, full-cycle mobility). The general mobility represents the minimum value of the instantaneous mobility in a free-of-singularity
12
1 Introduction
workspace. For a given mechanism, general mobility has a unique value for a free-of-singularity workspace. It is a global parameter characterizing the mechanism in all its configurations of the workspace except its singular ones. Instantaneous mobility is a local parameter characterizing the mechanism in a given configuration including singular ones. In a singular configuration the instantaneous mobility could be different from the general mobility. In this book, unless otherwise stated, general mobility is simply called mobility. Note 1. In a kinematotropic mechanism with branching singularities, full-cycle mobility is associated with each branch. In this case, the fullcycle mobility (global mobility) is replaced by the branch mobility which represents the minimum value of the instantaneous mobility inside the same free-of-singularity branch. As each branch has its own mobility, a single value for global mobility cannot be associated with the kinematotropic mechanisms (Gogu 2008b, c, d, 2009b, c). The term kinematotropic mechanism was coined by K. Wohlhart (1996) to define the linkages that permanently change their full-cycle mobility when passing by an instantaneous singularity from one branch to another. Various single and multiloop kinematotropic mechanisms have been presented in the literature (Wohlhart 1996, Dai and Jones 1999, Galletti and Fanghella 2001, Fanghella et al. 2006). A formula for quick calculation of mobility is an explicit relationship between the following structural parameters: the number of links and joints, the motion/constraint parameters of joints and of the mechanism. Usually, these structural parameters are easily determined by inspection without any need to develop the set of constraint equations. In Part 1, we have shown that several dozen approaches proposed in the last 150 years for the calculation of mechanism mobility can be reduced to the same original formula that we have called the Chebychev-GrüblerKutzbach (CGK) formula in its original or extended forms. These formulae have been critically reviewed (Gogu 2005b) and a criterion governing mechanisms to which this formula can be applied has been set up in (Gogu 2005c). We have explained why this well-known formula does not work for some multi-loop mechanisms. New formulae for quick calculation of mobility have been proposed in (Gogu 2005d) and demonstrated via the theory of linear transformations. More details and a development of these contributions have been presented in Part 1. The connectivity between two links of a mechanism represents the number of independent finite and/or infinitesimal displacements allowed by the mechanism between the two links. The number of overconstraints of a mechanism is given by the difference between the maximum number of joint kinematic parameters that
1.2 Methodology of structural synthesis
13
could lose their independence in the closed loops, and the number of joint kinematic parameters that actually lose their independence in the closed loops. The structural redundancy of a kinematic chain represents the difference between the mobility of the kinematic chain and connectivity between its distal links. Let us consider the case of the parallel mechanism F ← G1-G2-…-Gk in which the mobile platform n nGi is connected to the reference platform 1 1Gi by k simple and/or complex kinematic chains Gi (1Gi-2Gi-…-nGi) called limbs. In Part 1, the following parameters have been associated with the parallel mechanism F ← G1-G2-…-Gk : RGi - the vector space of relative velocities between the mobile and the reference platforms, nGi and 1Gi, in the kinematic chain Gi disconnected from the parallel mechanism F, RF - the vector space of relative velocities between the mobile and the reference platforms, n nGi and 1 1Gi, in the parallel mechanism F ← G1G2-…-Gk, whose basis is (RF)=( RG1 ∩ RG 2 ∩ ... ∩ RGk ),
(1.1)
SG - the connectivity between the mobile and the reference platforms, nGi and 1Gi, in the kinematic chain Gi disconnected from the parallel mechanism F, SF - the connectivity between the mobile and the reference platforms, n nGi and 1 1Gi, in the parallel mechanism F ← G1-G2-…Gk. We recall that the connectivity is defined by the number of independent motions between the mobile and the reference platforms. The notation 1 1Gi 0 is used when the reference platform is the fixed base. The vector spaces of relative velocities between the mobile and the reference platforms are also called operational velocity spaces. The following formulae demonstrated in Chapter 2-Part 1 (Gogu 2008a) for mobility MF, connectivity SF, number of overconstraints NF and redundancy TF of the parallel mechanism F ← G1-G2-…-Gk are used in structural synthesis of parallel robotic manipulators: p
M F = ∑ f i −rF ,
(1.2)
i =1
where
NF=6q-rF ,
(1.3)
TF=MF-SF ,
(1.4)
14
1 Introduction
SGi = dim( RGi ) ,
(1.5)
S F = dim( RF ) = dim( RG1 ∩ RG 2 ∩ ... ∩ RGk ) ,
(1.6)
k
rF = ∑ SGi − S F + rl ,
(1.7)
p = ∑ pGi ,
k
(1.8)
q=p-m+1,
(1.9)
i =1
i =1
and k
rl = ∑ rGi .
(1.10)
i =1
We note that pGi represents the number of joints of Gi-limb, p the total number of joints of parallel mechanism F, m the total number of links in mechanism F including the moving and reference platforms, q the total number of independent closed loops in the sense of graph theory, fi the mobility of the ith joint, rF the total number of joint parameters that lose their independence in mechanism F, rGi the number of joint parameters that lose their independence in the closed loops of limb Gi, rl the total number of joint parameters that lose their independence in the closed loops that may exist in the limbs of mechanism F. In Eqs. (1.5) and (1.6), dim denotes the dimension of the vector spaces. We denote by k1 the number of simple limbs and by k2 the number of complex limbs (k=k1+k2). Eq. (1.8) indicates that the limbs of the parallel mechanism F ← G1-G2-…-Gk must be defined in such a way that a joint must belong to just one limb; that is the same joint cannot be combined in two or more limbs. In Chapter 5-Part 1 the following structural conditions have been established: a) for the non redundant parallel robots (TF=0) SF=MF≤MGi
(i=1,…,k),
(1.11)
MGi=SGi≤6
(i=1,…,k),
(1.12)
b) for the redundant parallel robots with TF>0
1.2 Methodology of structural synthesis
15
SF<MF≤MGi
(i=1,…,k),
(1.13)
MGi>SGi≤6
(i=1,…,k),
(1.14)
c) for the non overconstrained parallel robots (NF=0) p
MF= ∑ f i − 6q ,
(1.15)
i =1
d) for the overconstrained parallel robots with NF>0 MF> ∑ f i − 6q .
(1.16)
pGi
(1.17)
p
i =1
We recall that M Gi = ∑ f i −rGi . i =1
We note that the intersection in Eqs. (1.1) and (1.6) is consistent if the vector spaces RGi are defined by the velocities of the same point situated on the moving platform with respect to the same reference frame. This point is called the characteristic point, and denoted by H. It is the point with the most restrictive motions of the moving platform. The connectivity SF of the moving platform n nGi in the mechanism F ← G1-G2-…-Gk is less than or equal to the mobility MF of mechanism F. The basis of the vector space RF of relative velocities between the moving and reference platforms in the mechanism F ← G1-G2-…-Gk must be valid for any point of the moving platform n nGi. Note 2. When there are various ways to choose the bases of the vector spaces RGi in Eqs. (1.1) and (1.6), the bases (RGi) are selected such that the minimum value of S F is obtained by Eq. (1.6). By this choice, the result of Eq. (1.2) fits in with the definition of general mobility as the minimum value of the instantaneous mobility. The parameters used in the new formulae (1.1)-(1.17) can be easily obtained by inspection with no need to calculate the rank of the homogeneous linear set of constraint equations associated with loop closure or with the rank of the complete screw system associated to the joints of the mechanism. An analytical method to compute these parameters has also been developed in Part 1 just for verification and for a better understanding of the meaning of these parameters. These formulae have been successfully applied in Part 1 to structural analysis of various mechanisms including so called “paradoxical” mechanisms. These formulae are useful for the
16
1 Introduction
structural synthesis of various types of parallel mechanisms with 2≤MF≤6 and various combinations of independent motions of the moving platform. These solutions are obtained in a systematic approach of structural synthesis by using the limbs generated by the method of evolutionary morphology presented in Part 1. 1.2.2 Evolutionary morphology approach Evolutionary morphology (EM) is a new method of systematic innovation in engineering design proposed by the author in (Gogu 2005a). EM is formalized by a 6-tuple of design objectives, protoelements (initial components), morphological operators, evolution criteria, morphologies and a termination criterion. The design objectives are the structural solutions, also called topologies, defined by the required values of mobility, connectivity overconstrained and redundancy and the level of motion coupling. The protoelements are the revolute and prismatic joints. The morphological operators are: (re)combination, mutation, migration and selection. These operators are deterministic and are applied at each generation of EM. At least MF=SF generations are necessary to evolve by successive combinations from the first generation of protoelements to a first solution satisfying the set of design objectives. Morphological migration could introduce new constituent elements formed by new joints or combinations of joints into the evolutionary process. Evolutionary morphology is a complementary method with respect to evolutionary algorithms that starts from a given initial population to obtain an optimum solution with respect to a fitness function. EM creates this initial population to enhance the chance of obtaining a “more global optimum”. Evolutionary algorithms are optimization oriented methods; EM is a conceptual design oriented method. A detailed presentation of the evolutionary morphology can be found in chapter 5 - Part 1. 1.2.3 Types of parallel robots with respect to motion coupling Various levels of motion coupling have been introduced in Chapter 4 - Part 1 in relation with the Jacobian matrix of the robotic manipulator which is the matrix mapping (i) the actuated joint velocity space and the endeffector velocity space, and (ii) the static load on the end-effector and the actuated joint forces or torques. Five types of parallel robotic manipulators (PMs) are introduced in Part 1: (i) maximally regular PMs, if the Jacobian J is an identity matrix
1.2 Methodology of structural synthesis
17
throughout the entire workspace, (ii) fully-isotropic PMs, if J is a diagonal matrix with identical diagonal elements throughout the entire workspace, (iii) PMs with uncoupled motions if J is a diagonal matrix with different diagonal elements, (iv) PMs with decoupled motions, if J is a triangular matrix and (v) PMs with coupled motions if J is neither a triangular nor a diagonal matrix. The term maximally regular parallel robot was recently coined by Merlet (2006) to define isotropic robots. We use this term to define just the particular case of fully-isotropic PMs, when the Jacobian matrix is an identity matrix throughout the entire workspace. Isotropy of a robotic manipulator is related to the condition number of its Jacobian matrix, which can be calculated as the ratio of the largest and the smallest singular values. A robotic manipulator is fully-isotropic if its Jacobian matrix is isotropic throughout the entire workspace, i.e., the condition number of the Jacobian matrix is one. Thus, the condition number of the Jacobian matrix is an interesting performance index characterizing the distortion of a unit sphere under this linear mapping. The condition number of the Jacobian matrix was first used by Salisbury and Craig (1982) to design mechanical fingers and developed by Angeles (1997) as a kinetostatic performance index of the robotic mechanical systems. The isotropic design aims at ideal kinematic and dynamic performance of the manipulator (Fattah and Ghasemi 2002). In an isotropic configuration, the sensitivity of a manipulator is minimal with regard to both velocity and force errors and the manipulator can be controlled equally well in all directions. The concept of kinematic isotropy has been used as a criterion in the design of various parallel manipulators (Zanganeh and Angeles 1997; Tsai and Huang 2003). Fully-isotropic PMs give a one-to-one mapping between the actuated joint velocity space and the operational velocity space. The condition number and the determinant of the Jacobian matrix being equal to one, the manipulator performs very well with regard to force and motion transmission. The various kinetostatic performance indices introduced in section 4.5-Part 1 have optimal values for fully-isotropic PMs (Gogu 2007f, 2008a, j) The first solutions of maximally regular and implicitly fully-isotropic parallel robot were developed at the same time and independently by Carricato and Parenti-Castelli at University of Genoa, Kim and Tsai at University of California, Gosselin and Kong at University of Laval, and the author at the French Institute of Advanced Mechanics (IFMA). In 2002, the four groups published the first results of their works (Carricato and Parenti-Castelli 2002; Kim and Tsai 2002; Gosselin and Kong 2002; Kong and Gosselin 2002a, b; c; Gogu 2002). Each of the last three groups has
18
1 Introduction
built a prototype of this T3-type translational parallel robot in their research laboratories and has called this robot CPM (Kim and Tsai 2002), Orthogonal Tripteron (Gosselin et al. 2004) or Isoglide3-T3 (Gogu 2004a). The first physical implementation of this robot was the CPM developed at University of California by Kim and Tsai (2002). An innovative solution of fully-isotropic T3-type translational parallel robot called Pantopteron was recently proposed by Briot and Bonev (2009). In this solution based on pantograph linkages, the moving platform moves several times faster than its linear actuators. Table 1.2. Literature dedicated to maximally-regular and implicitly fully-isotropic parallel robotic manipulators No. Type of parallel robotic manipulator 1 T3-type
2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
References
Carricato and Parenti-Castelli 2002 Gogu 2002, 2004a Gosselin and Kong 2002 Kim and Tsai 2002 Kong and Gosselin 2002a,b,c Rizk et al 2006 Stan et al. 2008 Wu et al. 2007 R2-type parallel wrist Gogu 2005f R3-type parallel wrist Gogu 2007b R3-type redundantly-actuated parallel Gogu 2007e wrists Planar T2R1-type Gogu 2004c Spatial T2R1-type Gogu 2008g Zhang et al. 2009 Spatial T2R1-type with planar motion Gogu 2008i of the moving platform T1R2-type Gogu 2005i T3R1-type with Schönflies Carricato 2005 motions Gogu 2004b, 2005g, 2006c, 2007a T2R2-type Gogu 2005h T1R3-type Gogu 2008h T1R3-type redundantly-actuated Gogu 2008e T2R3-type redundantly-actuated Gogu 2007d T3R2-type Gogu 2006b, d, 2009d T3R2-type redundantly-actuated Gogu 2006a T3R3-type hexapod Gogu 2006e
1.3 Parallel robots with planar motion of the moving platform
19
Various other types of maximally regular and implicitly fully-isotropic parallel robotic manipulators have been proposed in the last years (see Table 1.2). These solutions can be applied in machining applications (Gogu 2007c) or haptic devices (Gogu 2008f).
1.3 Parallel robots with planar motion of the moving platform This book focuses on the structural synthesis of three-degrees-of-freedom parallel robots with planar motion of the moving platform T2R1-type. In such a robot, the moving platform can undergo two independent translational motions T2 and one rotational motion R1 around an axis perpendicular to the plane of translations. This motion can be obtained by using planar or spatial parallel mechanisms. Overconstrained and non overconstrained solutions of parallel manipulators with coupled, decoupled and uncoupled motions of the moving platform along with maximally regular solutions are presented in the following sections of this book. These solutions are actuated by linear and/or rotating motors situated on the fixed base or on a moving link. Planar and spatial solutions of fully-parallel and non-fully parallel mechanisms are presented in this book. Basic and derived solutions are presented in each chapter. There are no idle mobilities in the basic solutions. To reduce the number of overconstraints in the parallel robot, derived solutions are used. These are obtained from the basic solutions by combining various idle mobilities. In a planar parallel mechanism, the links have a motion parallel to the same plane (planar motion). The rotation axes of revolute joints are parallel, and the directions of the translations in prismatic joints are parallel to a plane perpendicular to the rotation axes in the basic solutions. Just planar limbs with SGi=3 and (RGi)=( v1 ,v2 ,ωδ ) are used in the basic planar parallel mechanisms. Idle mobilities with other axis directions may also exist in the joints of the derived architectures. The basic solutions of spatial parallel mechanism with planar motion of the moving platform has at least one spatial limb with no idle mobilities and SGi>3. The parallel robots with planar motion of the moving platform presented in this book give two translational velocities v1 , v2 and one rotation velocity ωδ in the basis of the operational velocity vector space (RF)= ( v1 ,v2 ,ωδ ). The motion of the moving platform is parallel to the x0y0plane. The directions of velocities v1 and v2 are parallel to the x0- and
20
1 Introduction
y0-axes and the direction of ωδ is parallel to the z0- axis. These parallel robots have mobility MF=3 and the connectivity between the moving and fixed platforms is SF=3. The direct kinematic model of the parallel robots with planar motion of the moving platform becomes ⎡ v1 ⎤ ⎡&q1 ⎤ ⎢v ⎥ = J ⎢& ⎥ ⎢ 2 ⎥ [ ]3×3 ⎢ q2 ⎥ ⎢⎣ωδ ⎥⎦ ⎢⎣&q3 ⎥⎦
(1.18)
where: v1= &x and v2= &y are the translational velocities of the characteristic point H of the moving platform, ω = δ& is the rotation velocity of the moving δ
platform, &q1 , &q2 and &q3 are the velocities of the actuated joints, J 3×3 is the design Jacobian matrix. To obtain a non redundant solution of type F ← G1-G2-G3, a basic limb presented in Figs. 7.12-7.18-Part 1 is associated with two other simple or complex limbs with 3 ≤ MGi=SGi ≤ 6 that integrate velocities v1 , v2 and ωδ in the basis of their operational velocity spaces. We recall that the basic limbs in Figs. 7.12-7.18-Part 1 give rise to one rotational and two translational independent motions. In this way, a large set of solutions with coupled, decoupled, uncoupled motions along with maximally regular solutions can be obtained by using three simple or complex limbs with 3 ≤ MGi=SGi ≤ 6 that respect the condition (RF)=( RG1 ∩ RG 2 ∩ RG 3 )= ( v1 ,v2 ,ωδ ). Parallel robots with planar motion of the moving platform are used in classical manipulation processes, machining, locomotion interfaces, compliance devices, precision positioning tables, lithographic apparatus, micro and nano manipulations (see Table 1.3). Various architectures are used in the literature to obtain three-legged parallel manipulators based on planar mechanisms (Merlet 1997). The possible combinations of revolute, R, and prismatic, P, joints which connect the moving platform to the fixed base in a three-legged PPM are: RRR, PRR, RPR, RRP, PPR, RPP and PRP. The successions of the three joints start from the fixed base to the moving platform. Since any one of the three joints in any of the seven kinematic chains may be actuated there are 21 possible limb architectures. The various combinations of these limb architectures give 1653 possible PPMs with only lower pairs possessing three DoFs (Hayes et al. 2004). We note that these architectures have coupled motions and some of them have been extensively studied in the literature.
1.3 Parallel robots with planar motion of the moving platform
21
This is the case of 3-PRR, 3-RPR and 3-RRR architectures (see Tables 1.4-1.6). Some few studies are also dedicated to the architectures of types 3-PPR (Choi 2003; Chung and Choi 2004) and 3-PRP (Chablat and Staicu 2009; Ronchi et al. 2004). As a matter of fact, the general literature dedicated to planar parallel robots is extremely rich (see Table 1.7). Spatial solutions with planar motion of the moving platform have been less thoroughly investigated. Table 1.3. Examples of practical applications of planar parallel robots No. Practical application 1 2
3
4 5 6 7
8
References
Lithographic apparatus Machining
Kwan et al. (2003) Du Plesis and Snyman (2002, 2006a) Long et al. (2003) Snyman and Smit (2002) Micro manipulation Alici and Shirinzadeh (2003) Balan et al. (2005) Bamberger et al. (2006) Movable tables Matsumoto (1992) Sakai et al. (1999) Nano manipulation Mukhopadhyay et al. (2008) Omni-directional locomotion interface Yoon and Ryu (2004) Positioning devices Bonev (2008) Burton and Burton (1996) Scheidegger and Liechti (2002) Remote centre of compliance device Kim et al. (1996a, b)
Table 1.4. Literature dedicated to the study of the 3-PRR-type planar parallel robots No. Type of study
References
1 2 3
Control Isotropy Kinematic analysis
4 5
Singularities Workspace
Sun et al. (2006) Caro et al. (2003) Gosselin et al. (1996) Staicu (2009) Staicu et al. (2007) Masouleh and Gosselin (2007) Gosselin et al. (1996)
22
1 Introduction
Table 1.5. Literature dedicated to the study of the 3-RPR-type planar parallel robots No. Type of study 1
2 3
4 5
6 7
8 9 10
References
Bonev et al. (2008) Fried et al. (2008) Husty (2009) Macho et al. (2007) Zein et al. (2008) Wenger et Chablat (2009) Cusp points Zein et al. (2006a, b, 2007a) Dimensional synthesis and Du Plessis and Snyman (2006b) Gallant and Boudreau (2002) optimization Hay and Snyman (2002) Jiang and Gosselin (2008) Lee et al. (1999) Murray and Pierrot (1998) Staicu (2008) Dynamics Collins (2002) Kinematics Kong (2008, 2009) Kong and Gosselin (2001, 2008) Merlet (1996b, 2000) Murray et al. (1997) Takeda (2005) Wenger et Chablat (2009) Wenger et al. (2007) Williams and Joshi (1999) Binaud et al. (2009a, b) Sensitivity analysis Briot et al. (2008) Singularities Chablat et al. (2006) Collins and McCarthy (1998) Husty and Gosselin (2008) Jiang and Gosselin (2008) Kong and Gosselin (2000) Sefrioui and Gosselin (1995) Wenger et Chablat (2009) Wenger et al. (2007) Yang and O'Brien (2007) Zein et al. (2007b) Static analysis Duffy (1980) Tsai (1999) Stiffness Li and Gosselin (2008a) Workspace analysis and optimization Gallant and Boudreau (2000, 2002) Jiang and Gosselin (2006, 2008) Yang and O'Brien (2007) Assembly modes
1.3 Parallel robots with planar motion of the moving platform
23
Table 1.6. Literature dedicated to the study of the 3-RRR-type planar parallel robots No. Type of study
References
1 2
Balancing Control
3
Dimensional synthesis and optimization Dynamics Kinematic performance
Arakelian and Smith (2008) Balan et al. (2005) Castillo-Castaneda et al. (2007) Yoon and Ryu (2004) Bouzgarrou et al. (2000) Geike and McPhee (2002, 2003) Guo et al. (2004) Chablat and Wenger (2001) Tsai (1999) Alba-Gomes et al. (2005) Rooney and Earl (1983) Rooney and Tanev (2002) Alba-Gomes et al. (2007) Cha et al. (2007) Binaud et al. (2009a, b) Bonev and Gosselin (2001) Chablat and Wenger (2004) Gosselin and Wang (1997) Duffy (1980) Li and Gosselin (2007) Hunt (1978, 1982, 1983) Arsenault and Boudreau (2004a, b) Liu et al. (2000)
4 5
6 7 8
Kinetostatic indices Postures and kinematic assembly configurations Redundancy
9 10
Sensitivity and dexterity Singularities
11 12 13 14
Statics Stiffness Structural kinematics Workspace analysis and optimisation
24
1 Introduction
Table 1.7. Literature dedicated to the general study of planar parallel robots No. Type of study
References
1
Accuracy and clearances
2
Balancing
3 4 5
Calibration Compliance Control and motion planning
6
Dimensional synthesis and optimization
7
Dynamics
8
Kinematics
Bamberger et al. (2006) Briot and Bonev (2008) Yu et al. (2008) Alici and Shirinzadeh (2004a, b, 2006) Briot et al. (2009) Fattah and Agrawal (2006) Foucault and Gosselin (2002, 2004) Jean and Gosselin (1996) Laliberte et al. (1999) Leblond and Gosselin (1998) Shirinzadeh and Alici (2004) Last et al. (2007) Kim et al (1996a, b) Hahn et al. (1999) Harms et al. (1991) Kang and Mills (2003, 2005) Kang et al. (2001, 2002) Li et al. (2007) Ren et al. (2004, 2005, 2006) Shao et al. (2009) Shvalb et al. (2007) Slutski (1996) Wang and Mills (2005a, b) Wu et al. (2009) Boudreau and Gosselin (1999) Du Plessis and Snyman (2002, 2006a) Gallant and Boudreau (2000, 2003) Gosselin and Angeles (1988) Hay and Snyman (2000) Du and Yu (2006) Fattah et al. (1994) Fu and Mills (2005) Kang and Mills (2002) Khan et al. (2005) Ma and Angeles (1989) Piras et al. (2005) Staicu (2008) Wang et al. (2003) Wang and Mills (2006) Wu et al. (2008) Chablat and Staicu (2009) Collins (2002)
1.3 Parallel robots with planar motion of the moving platform
25
Table 1.7. (cont.)
9
Isotropy
10
Kinetostatics
11
Optimal design and modelling
12
Reconfigurability
13
Redundancy
Gao et al. (1996) Gosselin and Merlet (1994) Gosselin et al. (1992, 1996) Hayes and Husty (2003) Hayes and Zsombor-Murray (1996, 1998) Hayes et al. (2004) Jeanneau et al. (2004) Ji (2003) Ji and Wu (2002) Kong and Gosselin (2002d) Ma and Angeles (1989) Merlet (1996a) Mohamadi Daniali et al. (1993) Mohamed and Duffy (1985) Murray and Hanchak (2000) Rolland (2006) Rooney and Tanev (2002) Staicu et al. (2007) Urizar et al. (2009) Wang et al. (2003) Wenger and Chablat (2004) Williams and Sheley (1997) Zsombor-Murray et al. (2002) Alici and Shirinzadeh (2004a) Briot and Bonev (2009) Gogu (2004c) Mohamadi-Daniali and Zsombor-Murray (1994, 1999) Mohamadi-Daniali et al. (1995c) Company et al. (2007) Rakotomanga et al. (2008) Gosselin and Angeles (1988) Long et al. (2003) Ridgeway et al. (1992) Snyman and Smit (2002) Yoon and Ryu (2004) Choi et al. (2004a, b) Fisher et al. (2001, 2004) Constantinescu et al. (2000) Cha et al (2009) Dasgupta and Mruthyunjaya (1998) Ebrahimi et al. (2007a, b, 2008) Firmani and Podhorodeski (2004, 2005, 2007)
26
1 Introduction
Table 1.7. (cont)
14 15
Sensitivity Singularities
16
Statics
17
Stiffness
18
Workspace analysis and optimization
Firmani et al. (2007) Hahn et al. (1999) Lösch (1995) Marquet et al. (2001a,b) Müller A (2005) Nokleby et al. (2007a, b) Wu et al. (2008) Yi et al. (2002) Zibil et al. (2007) Alici and Shirinzadeh (2004b, 2006) Arsenault and Boudreau (2006) Bonev et al. (2001, 2003) Cha et al. (2009) Collins and McCarthy (1998) Degani and Wolf (2006a, b) Di Gregorio (2009) Firmani and Podhorodeski (2009) Gosselin and Wang (1995, 1997) Heerah et al. (2002, 2003) Li and Gosselin (2008b) Li et al. (2006) Mohamadi-Daniali (2005) Mohamadi-Daniali et al. (1995a, b) Sefrioui and Gosselin (1992) Theingi et al. (2004) Yang et al (2002) Duffy (1980) Weiwei and Shuang (2006) Alici and Shirinzadeh (2003) Arsenault and Boudreau (2004b, 2006) Kim et al. (1997) Simaan and Shoham (2002) Arsenault and Boudreau (2004a) Gao et al. (2001) Gosselin and Jean (1996) Hay and Snyman (2005, 2006) Hayes and Husty (2000) Husty (1996) Li et al. (2006) Merlet et al. (1998) Snyman and Hay (2000) Stachera (2005) Urizar et al. (2009)
2 Overconstrained planar parallel robots with coupled motions
In the general case, in a planar parallel robotic manipulator (PPM) with coupled motions each operational velocity depends in the general case on & 2 ,q & 3 ) , v2 = v2 ( &q1 ,q & 2 ,q & 3 ) and three actuated joint velocities: v1 = v1 ( &q1 ,q & 2 ,q & 3 ) . In some specific solutions, one or two operational ωδ = ωδ ( &q1 ,q velocities depend on just one or two actuator velocities. We note that, in this particular case, the Jacobian matrix in Eq. (6.1) is not triangular and the parallel robot always has coupled motions. They have just a few partially decoupled motions. The overconstrained solutions of PPMs with coupled motions and q p independent loops meet the condition ∑ 1 f i < 3 + 6q . They may have identical limbs or limbs with different structures and could be actuated by linear or rotating motors. The limbs can be simple or complex kinematic chains and can also combine idle mobilities. The actuators can be mounted on the fixed base or on a moving link. The first solution has the advantage of reducing the moving masses and large workspace. The second solution would be more compact.
2.1 Basic solutions The basic solutions presented in this section are either fully-parallel and non fully-parallel solutions. There are no idle mobilities in the basic solutions. 2.1.1 Fully-parallel solutions In the fully-parallel solutions of PPMs with coupled motions F ← G1-G2-G3 presented in this section, the moving platform n nGi (i=1, 2, 3) is connected to the reference platform 1 1Gi 0 by three planar limbs with three G. Gogu, Structural Synthesis of Parallel Robots, Solid Mechanics and Its Applications 173, DOI 10.1007/978-90-481-9831-3_2, © Springer Science + Business Media B.V. 2010
27
28
2 Overconstrained planar parallel robots with coupled motions
degrees of connectivity. One actuator is combined in a revolute or prismatic pair of each limb. The various types of planar simple and complex limbs with three degrees of connectivity used in the basic solutions illustrated in this section are presented in Figs. 2.1-2.3. The simple limbs combine only revolute and prismatic joints. One (Fig. 2.2a, c-g) or two (Figs. 2.2b, h and 2.3a) planar parallelogram loops are combined in the complex limbs. One telescopic parallelogram loop Pat is combined in the complex limb in Fig. 2.3b. Various solutions of PPMs with coupled motions and no idle mobilities can be obtained by using three limbs with identical or different topology presented in Figs. 2.1-2.3. Only solutions with three identical limb types are illustrated in Figs. 2.4-2.9. The revolute joints in the three limbs have parallel axes and the directions of the prismatic joints are parallel to a plane perpendicular to the rotation axes of the revolute joints. The actuator is mounted on the fixed base in the solutions illustrated in Figs. 2.4-2.9 excepting the solutions in Fig.2.5a and Fig. 2.9a in which the linear actuator is mounted on a moving link. All motions are coupled in the solutions presented in Figs. 2.4-2.9 and & 2 ,q & 3 ) , v2 = v2 ( &q1 ,q & 2 ,q & 3 ) and ωδ = ωδ ( &q1 ,q & 2 ,q & 3 ) - see Table v1 = v1 ( &q1 ,q 2.1. The prismatic joints between links 4 and 5 (Fig. 2.9a) is actuated to obtain solutions with coupled motions. If a revolute joint mounted on the fixed base and combined in the parallelogram loops is actuated, solutions with one uncoupled translational motion can be obtained and v1 = v1 ( &q1 ) . The particular case with one uncoupled translation v1 = v1 ( &q1 ) can also be obtained by using the solution in Figs. 2.10. Other solutions with this partially decoupled translation can be obtained (Figs. 2.11-2.15) by combining G1-limb in Fig. 2.1f or 2.2e with other two identical or different limbs in Figs. 2.1a-e and 2.2a-d. The particular case with partially decoupled translational motions & 2 ) and v2 = v2 ( &q1 ,q & 2 ) in Figs. 2.16-2.18 are obtained from the v1 = v1 ( &q1 ,q solutions in Figs. 2.4a and 2.5a by superposing the axes of the revolute joints connecting limbs G1 and G2 to the moving platform. The axes of the three actuated revolute joints are also superposed in the solutions presented in Figs. 2.16b and 2.17b. In this way, the workspace can be significantly increased. The limb topology and connecting conditions of the solutions in Figs. 2.4-2.17 are systematized in Table 2.2, as are their structural parameters in Tables 2.4-2.6. The particular case with decoupled rotational motion ωδ = ωδ ( &q3 ) can be obtained by using three limbs with identical or different topology
2.1 Basic solutions
29
presented in Figs. 2.1g and 2.2f-h. Solutions with three identical limb types but different actuation selection are illustrated in Figs. 2.18-2.20. One actuator is mounted on the fixed base and the other two are mounted on a moving link in these solutions. The limb topology and connecting conditions of the solutions in Figs. 2.18-2.20 are systematized in Table 2.3, as are their structural parameters in Table 2.6. The first revolute joint of the three limbs have the same rotation axis. The rotation axis of the moving platform has a fixed position in these solutions. Solutions with decoupled and unlimited rotational motion of the moving platform with different limb topologies are illustrated in Figs. 2.21-2.36. These solutions use two identical limbs (Figs. 2.1a-c and 2.2a-c) for positioning the moving platform and a different limb (Figs. 2.1g, 2.2f-g and 2.3) for rotating it. Their limb topology and connecting conditions are systematized in Table 2.3. The rotation axis of the moving platform has a fixed position in the solutions in Figs. 2.21-2.30 and a variable position in the solutions in Figs. 2.31-2.36. The solutions using G3-limb can provide an unlimited angle of rotation of the moving platform with variable position of the rotation axis. The structural parameters of the solutions in Figs. 2.21-2.36 are systematized in Tables 2.6-2.10.
30
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.1. Simple limbs for PPMs with coupled motions defined by MG=SG=3, (RG)=( v1 , v2 , δ )
2.1 Basic solutions
31
Fig. 2.2. Complex limbs for PPMs with coupled motions defined by MG=SG=3, (RG)=( v1 , v2 , δ ), and combining one or two planar parallelogram loops
32
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.3. Complex limbs for PPMs with coupled motions defined by MG=SG=3, (RG)=( v1 , v2 , δ ), and combining planar parallelogram loops (a) or a telescopic parallelogram loop (b)
Table 2.1. Motion coupling in overconstrained PPM with no idle mobilities presented in Figs. 2.4-2.36 No. Motion coupling 1
2
3
4
5
Examples
Note
The two translational and one & 2 ,q & 3 ) Figs. 2.4-2.9 v1 = v1 ( &q1 ,q rotational motions are coupled & 2 ,q &3 ) v2 = v2 ( &q1 ,q & 2 ,q &3 ) ωδ = ωδ ( &q1 ,q Figs. 2.10-2.15 One decoupled translational v1 = v1 ( &q1 ) motion & 2 ,q &3 ) v2 = v2 ( &q1 ,q & 2 ,q &3 ) ωδ = ωδ ( &q1 ,q Figs. 2.16-2.17 Partially decoupled translational &2 ) v1 = v1 ( &q1 ,q motions &2 ) v2 = v2 ( &q1 ,q & 2 ,q &3 ) ωδ = ωδ ( &q1 ,q & 2 ,q & 3 ) Figs. 2.18-2.20 Decoupled rotational motion v1 = v1 ( &q1 ,q & 2 ,q &3 ) v2 = v2 ( &q1 ,q ωδ = ωδ ( &q1 ) Figs. 2.21-2.36 Uncoupled rotational motion and &2 ) v1 = v1 ( &q1 ,q partially decoupled translational &2 ) v2 = v2 ( &q1 ,q motions ωδ = ωδ ( &q3 )
2.1 Basic solutions
33
Table 2.2. Limb topology and connecting conditions of the overconstrained PPM with no idle mobilities presented in Figs. 2.4-2.17 No. PPM type
Limb topology
Connecting conditions
1
3-RRR (Fig. 2.4a) 3-RRP (Fig. 2.4b)
R||R||R (Fig. 2.1a) R||R ⊥ P (Fig. 2.1d)
3-RPR (Fig. 2.5a) 3-PRR (Fig. 2.5b) 3-PRP (Fig. 2.6) 3-PaPaR (Fig. 2.7) 3-PaRR (Fig. 2.8a) 3-PaRP (Fig. 2.8b) 3-PaPR (Fig. 2.9a) 3-PPaR (Fig. 2.9b) 3-PPR (Fig. 2.10) 1PPR-2RRR (Fig. 2.11)
R ⊥ P ⊥ ||R (Fig. 2.1b) P ⊥ R||R (Fig. 2.1c) P⊥ R⊥ P (Fig. 2.1e) Pa||Pa||R (Fig. 2.2b) Pa||R||R (Fig. 2.2a) Pa||R ⊥ P (Fig. 2.2d) Pa ⊥ P ⊥ ||R (Fig. 2.2e) P ⊥ Pa ||R (Fig. 2.2c) P ⊥ P ⊥⊥ R (Fig. 2.1f) P ⊥ P ⊥⊥ R (Fig. 2.1f) R||R||R (Fig. 2.1a) P ⊥ P ⊥⊥ R (Fig. 2.1f) R||R ⊥ P (Fig. 2.1d) P ⊥ P ⊥⊥ R (Fig. 2.1f) R ⊥ P ⊥ ||R (Fig. 2.1b)
The directions of the revolute joints of the three limbs are parallel. The directions of the revolute joints of the three limbs are parallel. The directions of the prismatic joints are parallel to a plane perpendicular to the axis of the revolute joints. Idem No. 2
2
3 4 5 6 7 8 9 10 11 12
13
1PPR-2RRP (Fig. 2.12a)
14
1PPR-2RPR (Fig. 2.12b)
Idem No. 2 Idem No. 2 Idem No. 1 Idem No. 1 Idem No. 2 Idem No. 2 Idem No. 2 Idem No. 2 Idem No. 2
Idem No. 2
Idem No. 2
34
2 Overconstrained planar parallel robots with coupled motions
Table 2.2. (cont.) 15
1PPR-2PRR (Fig. 2.13a)
16
1PPR-2PRP (Fig. 2.13b)
17
1PaPR-2PaRR (Fig. 2.14a)
18
1PaPR-2PPaR (Fig. 2.14b)
19
1PaPR-2PaPaR (Fig. 2.15a)
20
1PaPR-2PaRP (Fig. 2.15b)
21
3RRR (Fig. 2.16a)
P ⊥ P ⊥⊥ R (Fig. 2.1f) P ⊥ R||R (Fig. 2.1c) P ⊥ P ⊥⊥ R (Fig. 2.1f) P⊥ R⊥ P (Fig. 2.1e) Pa ⊥ P ⊥ ||R (Fig. 2.2e) Pa||R||R (Fig. 2.2a) Pa ⊥ P ⊥ ||R (Fig. 2.2e) P ⊥ Pa||R (Fig. 2.2c) Pa ⊥ P ⊥ ||R (Fig. 2.2e) Pa||Pa||R (Fig. 2.2b) Pa ⊥ P ⊥ ||R (Fig. 2.2e) Pa||R ⊥ P (Fig. 2.2d) R||R||R (Fig. 2.1a)
22
3RRR (Fig. 2.16b)
R||R||R (Fig. 2.1a)
23
3RPR (Fig. 2.17a)
R ⊥ P ⊥ ||R (Fig. 2.1b)
24
2RPR-1RPR (Fig. 2.17b)
R ⊥ P ⊥ ||R R ⊥ P ⊥ ||R (Fig. 2.1b)
Idem No. 2
Idem No. 2
Idem No. 2
Idem No. 2
Idem No. 2
Idem No. 2
Idem No. 1 The axes of the revolute joints connecting limbs G1 and G2 to the moving platform are superposed. Idem No. 21 The axes of the three actuated revolute joints are superposed. Idem 2 The axes of the revolute joints connecting limbs G1 and G2 to the moving platform are superposed. Idem 23 The axes of the first revolute joints of the three limbs are superposed.
2.1 Basic solutions
35
Table 2.3. Limb topology and connecting conditions of the overconstrained PPM with no idle mobilities presented in Figs. 2.18-2.36 No. PPM type
Limb topology
Connecting conditions
1
2RPP-1RPP (Fig. 2.18)
R ⊥ P ⊥⊥ P (Fig. 2.1g)
2
2RPPa-1RPPa (Fig. 2.19) 2RPaP-1RPaP (Fig. 2.20a) 2RPaPa-1RPaPa (Fig. 2.20b) 2PRR-1RPP (Fig. 2.21a)
R ⊥ P ⊥ ||Pa (Fig. 2.2f) R||Pa ⊥ P (Fig. 2.2g) R||Pa||Pa (Fig. 2.2h) P ⊥ R||R (Fig. 2.1c) R ⊥ P ⊥⊥ P (Fig. 2.1g) R||R||R (Fig. 2.1a) R ⊥ P ⊥⊥ P (Fig. 2.1g) R ⊥ P ⊥ ||R (Fig. 2.1b) R ⊥ P ⊥⊥ P (Fig. 2.1g) P ⊥ Pa||R (Fig. 2.2c) R ⊥ P ⊥⊥ P (Fig. 2.1g) Pa||R||R (Fig. 2.2a) R ⊥ P ⊥⊥ P (Fig. 2.1g) Pa||Pa||R (Fig. 2.2b) R ⊥ P ⊥⊥ P (Fig. 2.1g) P ⊥ R||R (Fig. 2.1c) R ⊥ P ⊥ ||Pa (Fig. 2.2f)
The directions of the revolute joints of the three limbs are parallel. The directions of the prismatic joints are parallel to a plane perpendicular to the axis of the revolute joints. Idem No. 1
3 4 5
6
2RRR-1RPP (Fig. 2.21b)
7
2RPR-1RPP (Fig. 2.21c)
8
2PPaR-1RPP (Fig. 2.22a)
9
2PaRR-1RPP (Fig. 2.22b)
10
2PaPaR-1RPP (Fig. 2.22c)
11
2PRR-1RPPa (Fig. 2.23a)
Idem No. 1 Idem No. 1 Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
36
2 Overconstrained planar parallel robots with coupled motions
Table 2.3. (cont.) 12
2RRR-1RPPa (Fig. 2.23b)
13
2RPR-1RPPa (Fig. 2.23c)
14
2PRR-1RPaP (Fig. 2.24a)
15
2RRR-1RPaP (Fig. 2.24b)
16
2RPR-1RPaP (Fig. 2.24c)
17
2PRR-1RPaPa (Fig. 2.25a)
18
2RRR-1RPaPa (Fig. 2.25b)
19
2RPR-1RPaPa (Fig. 2.25c)
20
2PPaR-1RPPa (Fig. 2.26a)
21
2PaRR-1RPPa (Fig. 2.26b)
22
2PPaR-1RPaP (Fig. 2.27a)
R||R||R (Fig. 2.1a) R ⊥ P ⊥ ||Pa (Fig. 2.2f) R ⊥ P ⊥ ||R (Fig. 2.1b) R ⊥ P ⊥ ||Pa (Fig. 2.2f) P ⊥ R||R (Fig. 2.1c) R||Pa ⊥ P (Fig. 2.2g) R||R||R (Fig. 2.1a) R||Pa ⊥ P (Fig. 2.2g) R ⊥ P ⊥ ||R (Fig. 2.1b) R||Pa ⊥ P (Fig. 2.2g) P ⊥ R||R (Fig. 2.1c) R||Pa||Pa (Fig. 2.2h) R||R||R (Fig. 2.1a) R||Pa||Pa (Fig. 2.2h) R ⊥ P ⊥ ||R (Fig. 2.1b) R||Pa||Pa (Fig. 2.2h) P ⊥ Pa||R (Fig. 2.2c) R ⊥ P ⊥ ||Pa (Fig. 2.2f) Pa||R||R (Fig. 2.2a) R ⊥ P ⊥ ||Pa (Fig. 2.2f) P ⊥ Pa||R (Fig. 2.2c) R||Pa ⊥ P (Fig. 2.2g)
Idem No. 1
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2.1 Basic solutions
37
Table 2.3. (cont) 23
24
25
26
27
28
29
30
31
32
33
Pa||R||R (Fig. 2.2a) R||Pa ⊥ P (Fig. 2.2g) 2PaPaR-1RPPa Pa||Pa||R (Fig. 2.28a) (Fig. 2.2b) R ⊥ P ⊥ ||Pa (Fig. 2.2f) 2PaPaR-1RPaP Pa||Pa||R (Fig. 2.28b) (Fig. 2.2b) R||Pa ⊥ P (Fig. 2.2g) 2PPaR-1RPaPa P ⊥ Pa||R (Fig. 2.29a) (Fig. 2.2c) R||Pa||Pa (Fig. 2.2h) 2PaRR-1RPaPa Pa||R||R (Fig. 2.29b) (Fig. 2.2a) R||Pa||Pa (Fig. 2.2h) 2PaPaR-1RPaPa Pa||Pa||R (Fig. 2.30) (Fig. 2.2b) R||Pa||Pa (Fig. 2.2h) 2PRR-1RPaPa P ⊥ R||R (Fig. 2.31a) (Fig. 2.1c) R||Pa||Pa (Fig. 2.3a) 2PRR-1RPaPat P ⊥ R||R (Fig. 2.1c) (Fig. 2.31b) R||Pa||Pat (Fig. 2.3b) 2RRR-1RPaPa R||R||R (Fig. 2.32a) (Fig. 2.1a) R||Pa||Pa (Fig. 2.3a) 2RRR-1RPaPat R||R||R (Fig. 2.32b) (Fig. 2.1a) R||Pa||Pat (Fig. 2.3b) 2RPR-1RPaPa R ⊥ P ⊥ ||R (Fig. 2.33a) (Fig. 2.1b) R||Pa||Pa (Fig. 2.3a) 2PaRR-1RPaP (Fig. 2.27b)
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The directions of the revolute joints of the three limbs are parallel.
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38
2 Overconstrained planar parallel robots with coupled motions
Table 2.3. (cont.) 34
35
36
37
38
39
40
R ⊥ P ⊥ ||R (Fig. 2.1b) R||Pa||Pat (Fig. 2.3b) 2PPaR-1RPaPa P ⊥ Pa||R (Fig. 2.34a) (Fig. 2.2c) R||Pa||Pa (Fig. 2.3a) 2PPaR-1RPaPat P ⊥ Pa||R (Fig. 2.2c) (Fig. 2.34b) R||Pa||Pat (Fig. 2.3b) 2PaRR-1RPaPa Pa||R||R (Fig. 2.35a) (Fig. 2.2a) R||Pa||Pa (Fig. 2.3a) 2PaRR-1RPaPat Pa||R||R (Fig. 2.35b) (Fig. 2.2a) R||Pa||Pat (Fig. 2.3b) 2PaPaR-1RPaPa Pa||Pa||R (Fig. 2.36a) (Fig. 2.2b) R||Pa||Pa (Fig. 2.3a) 2PaPaR-1RPaPat Pa||Pa||R (Fig. 2.36b) (Fig. 2.2b) R||Pa||Pat (Fig. 2.3b) 2RPR-1RPaPat (Fig. 2.33b)
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2.1 Basic solutions
39
Table 2.4. Structural parameters of planar parallel mechanisms in Figs. 2.4-2.10 No. Structural Solution parameter 3-RRR , 3-RRP (Fig. 2.4a,b) 3-RPR, 3-PRR (Fig. 2.5a,b) 3-PRP (Fig. 2.6) 3-PPR (Fig. 2.10) 1 m 8 2 p1 3 3 p2 3 4 p3 3 5 p 9 6 q 2 7 k1 3 8 k2 0 9 k 3 10 (RG1) ( v1 , v 2 , δ ) 11 (RG2) ( v1 , v2 , δ ) 12
(RG3)
13 14 15 16 17 18 19 20 21 22
SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
23 24 25 26 27 28 29
SF rl rF MF NF TF
30 31 32
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
( v1 , v2 , 3 3 3 0 0 0 3 3 3 ( v1 , v2 , 3 0 6 3 6 0 3
δ
)
δ
)
3-PaPaR (Fig. 2.7)
20 9 9 9 27 8 0 3 3 ( v1 , v2 ,
δ
)
3-PaRR (Fig. 2.8a) 3-PaRP (Fig. 2.8b) 3-PaPR (Fig. 2.9a) 3-PPaR (Fig. 2.9b) 14 6 6 6 18 5 0 3 3 ( v1 , v 2 , δ )
( v1 , v2 ,
δ
)
( v1 , v 2 ,
δ
)
δ
)
( v1 , v 2 , 3 3 3 3 3 3 3 3 3 ( v1 , v 2 , 3 9 15 3 15 0 6
( v1 , v2 , 3 3 3 6 6 6 3 3 3 ( v1 , v2 , 3 18 24 3 24 0 9
fj
3
9
6
fj
3
9
6
fj
9
27
18
δ
)
δ
)
δ
)
m number of links including the fixed base, pGi number of joints in the Gi-limb, p total number of joints in the parallel mechanisma, q number of independent closed
40
2 Overconstrained planar parallel robots with coupled motions
loops in the parallel mechanismb, k1 number of simple limbs, k2 number of complex limbs, k total number of limbsc, (RGi) basis of the vector space of relative velocities between the moving and reference platforms in Gi-limb disconnected from the parallel mechanism, SGi connectivity between the moving and reference platforms in Gi-limb disconnected from the parallel mechanismd, rGi number of joint parameters that lost their independence in the closed loops combined in Gi-limb, MGi mobility of Gi-limbe, (RF) basis of the vector space of relative velocities between the moving and reference platforms in the parallel mechanismf, SF connectivity between the mobile and reference platforms in the parallel mechanismg, rl total number of joint parameters that lose their independence in the closed loops combined in the k limbsh, rF total number of joint parameters that lose their independence in the closed loops combined in the parallel mechanismi, MF mobility of the parallel mechanismj, NF number of overconstraints in the parallel mechanismk, TF degree of structural redundancy of the parallel mechanisml, fj mobility of jth joint. p= ∑ i =1 pGi , k
a
b
q=p-m+1, k=k1+k2, d SGi=dim(RGi) , i=1,2,...,k,
c
MGi= ∑ j =Gi1 f j − rGi , i=1,2,...,k, p
e
(RF)=(RG1) ∩ ... ∩ (RGk), SF=dim(RF) ,
f
g h
rl= ∑ i =1 rGi ,
i
rF = ∑ i =1 SGi − S F + rl ,
j
M F = ∑ i =1 f i − rF ,
k
p
N F = 6q − rF , TF = M F − S F .
k l
k
2.1 Basic solutions
41
Table 2.5. Structural parametersa of planar parallel mechanisms in Figs. 2.11-2.15 No. Structural Solution parameter 1PPR-2RRR (Fig. 2.11) 1PPR-2RRP (Fig. 2.12a) 1PPR-2RPR (Fig. 2.12b) 1PPR-2PRR (Fig. 2.13a) 1PPR-2PRP (Fig. 2.13b) 1 m 8 2 p1 3 3 p2 3 4 p3 3 5 p 9 6 q 2 7 k1 3 8 k2 0 9 k 3 10 (RG1) ( v1 , v 2 , δ ) 11 (RG2) ( v1 , v 2 , δ ) 12
(RG3)
13 14 15 16 17 18 19 20 21 22
SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
23 24 25 26 27 28 29
SF rl rF MF NF TF
30 31 32 a
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
( v1 , v 2 , 3 3 3 0 0 0 3 3 3 ( v1 , v 2 , 3 0 6 3 6 0 3
δ
)
δ
)
1PaPR-2PaRR 1PaPR-2PPaR (Fig. 2.14a, b) 1PaPR-2PaRP (Fig. 2.15b) 14 6 6 6 18 5 0 3 3 ( v1 , v 2 , δ ) ( v1 , v 2 , ( v1 , v 2 , 3 3 3 3 3 3 3 3 3 ( v1 , v 2 , 3 9 15 3 15 0 6
δ
)
δ
)
δ
)
1PaPR-2PaPaR (Fig. 2.15a)
18 6 9 9 24 7 0 3 3 ( v1 , v 2 , ( v1 , v 2 , ( v1 , v 2 , 3 3 3 3 6 6 3 3 3 ( v1 , v 2 , 3 15 21 3 21 0 6
fj
3
6
9
fj
3
6
9
fj
9
18
24
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
δ
)
δ
)
δ
)
42
2 Overconstrained planar parallel robots with coupled motions
Table 2.6. Structural parametersa of planar parallel mechanisms in Figs. 2.16-2.21 No. Structural Solution parameter 3RRR (Fig. 2.16) 3RPR, 2RPR-1RPR (Fig. 2.17) 2RPP-1RPP (Fig. 2.18) 2PRR-1RPP, 2RRR-1RPP, 2RPR-1RPP (Fig. 2.21) 1 m 8 2 p1 3 3 p2 3 4 p3 3 5 p 9 6 q 2 7 k1 3 8 k2 0 9 k 3 10 (RG1) ( v1 , v 2 , δ ) 11 (RG2) ( v1 , v 2 , δ ) 12
(RG3)
13 14 15 16 17 18 19 20 21 22
SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
23 24 25 26 27 28 29
SF rl rF MF NF TF
30 31 32 a
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
( v1 , v 2 , 3 3 3 0 0 0 3 3 3 ( v1 , v2 , 3 0 6 3 6 0 3
δ
)
δ
)
2RPPa-1RPPa 2RPaPa-1RPaPa (Fig. 2.19) (Fig. 2.20b) 2RPaP-1RPaP (Fig. 2.20a) 14 6 6 6 18 5 0 3 3 ( v1 , v2 , ( v1 , v2 , ( v1 , v2 , 3 3 3 3 3 3 3 3 3 ( v1 , v2 , 3 9 15 3 15 0 6
δ
)
δ
)
δ
)
δ
)
20 9 9 9 27 8 0 3 3 ( v1 , v2 , ( v1 , v2 , ( v1 , v2 , 3 3 3 6 6 6 3 3 3 ( v1 , v2 , 3 18 24 3 24 0 9
fj
3
6
9
fj
3
6
9
fj
9
18
27
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
δ
)
δ
)
δ
)
2.1 Basic solutions
43
Table 2.7. Structural parametersa of planar parallel mechanisms in Figs. 2.22-2.24 No. Structural Solution parameter 2PPaR-1RPP (Fig. 2.22a) 2PaRR-1RPP (Fig. 2.22b) 1 m 12 2 p1 6 3 p2 6 4 p3 3 5 p 15 6 q 4 7 k1 1 8 k2 2 9 k 3 10 (RG1) ( v1 , v 2 , δ ) 11 (RG2) ( v1 , v 2 , δ ) 12
(RG3)
13 14 15 16 17 18 19 20 21 22
SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
23 24 25 26 27 28 29
SF rl rF MF NF TF
30 31 32 a
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
( v1 , v 2 , 3 3 3 3 3 0 3 3 3 ( v1 , v 2 , 3 6 12 3 12 0 6
δ
)
δ
)
2PaPaR-1RPP 2PRR-1RPPa, 2RRR-1RPPa (Fig. 2.22c) 2RPR-1RPPa (Fig. 2.23a,b,c) 2PRR-1RPaP, 2RRR-1RPaP 2RPR-1RPaP (Fig. 2.24a,b,c) 16 10 9 3 9 3 3 6 21 12 6 3 1 2 2 1 3 3 ( v1 , v2 , δ ) ( v1 , v2 , δ ) ( v1 , v2 , ( v1 , v2 , 3 3 3 6 6 0 3 3 3 ( v1 , v2 , 3 12 18 3 18 0 9
δ
)
( v1 , v2 ,
δ
)
δ
)
( v1 , v2 , 3 3 3 0 0 3 3 3 3 ( v1 , v2 , 3 3 9 3 9 0 3
fj
6
9
3
fj
3
3
6
fj
15
21
12
δ
)
δ
)
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
44
2 Overconstrained planar parallel robots with coupled motions
Table 2.8. Structural parametersa of planar parallel mechanisms in Figs. 2.25-2.28 No. Structural Solution parameter 2PRR-1RPaPa 2RRR-1RPaPa 2RPR-1RPaPa (Fig. 2.25a,b,c) 1 m 12 2 p1 3 3 p2 3 4 p3 9 5 p 15 6 q 4 7 k1 2 8 k2 1 9 k 3 10 (RG1) ( v1 , v 2 , δ ) 11 (RG2) ( v1 , v 2 , δ ) 12
(RG3)
13 14 15 16 17 18 19 20 21 22
SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
23 24 25 26 27 28 29
SF rl rF MF NF TF
30 31 32 a
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
( v1 , v 2 , 3 3 3 0 0 6 3 3 3 ( v1 , v 2 , 3 6 12 3 12 0 3
δ
)
δ
)
2PPaR-1RPPa (Fig. 2.26a) 2PaRR-1RPPa (Fig. 2.26b) 2PPaR-1RPaP (Fig. 2.27a) 2PaRR-1RPaP (Fig. 2.27b) 14 6 6 6 18 5 0 3 3 ( v1 , v2 , δ )
2PaPaR-1RPPa (Fig. 2.28a) 2PaPaR-1RPaP (Fig. 2.28b) 18 9 9 6 24 7 0 3 3 ( v1 , v2 , δ )
( v1 , v2 , ( v1 , v2 , 3 3 3 3 3 3 3 3 3 ( v1 , v2 , 3 9 15 3 15 0 6
δ
)
( v1 , v2 ,
δ
)
δ
)
( v1 , v2 , 3 3 3 6 6 3 3 3 3 ( v1 , v2 , 3 15 21 3 21 0 9
fj
3
6
9
fj
9
6
6
fj
15
18
24
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
δ
)
δ
)
2.1 Basic solutions
45
Table 2.9. Structural parametersa of planar parallel mechanisms in Figs. 2.29-2.33 No. Structural Solution parameter 2PPaR-1RPaPa 2PaPaR-1RPaPa 2PRR-1RPaPa (Fig. 2.31a) (Fig. 2.29a) (Fig. 2.30) 2PRR-1RPaPat (Fig. 2.31b) 2PaRR-1RPaPa 2RRR-1RPaPa (Fig. 2.32a) (Fig. 2.29b) 2RRR-1RPaPat (Fig. 2.32b) 2RPR-1RPaPa (Fig. 2.33a) 2RPR-1RPaPat (Fig. 2.33b) 1 m 16 20 12 2 p1 6 9 3 3 p2 6 9 3 4 p3 9 9 9 5 p 21 27 15 6 q 6 8 4 7 k1 0 0 2 8 k2 3 3 1 9 k 3 3 3 10 (RGi) ( v1 , v2 , δ ) ( v1 , v2 , δ ) ( v1 , v 2 , δ ) i=1,2,3 11 SG1 3 3 3 12 SG2 3 3 3 13 SG3 3 3 3 14 rG1 3 6 0 15 rG2 3 6 0 16 rG3 6 6 6 17 MG1 3 3 3 18 MG2 3 3 3 19 MG3 3 3 3 20 (RF) ( v1 , v2 , δ ) ( v1 , v2 , δ ) ( v1 , v2 , δ ) 21 SF 3 3 3 22 rl 12 18 6 23 rF 18 24 12 24 MF 3 3 3 25 NF 18 24 12 26 TF 0 0 0 p1 27 6 9 3 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
fj
6
9
3
fj
9
9
9
fj
21
27
15
See footnote of Table 2.4 for the nomenclature of structural parameters
46
2 Overconstrained planar parallel robots with coupled motions
Table 2.10. Structural parametersa of planar parallel mechanisms in Figs. 2.342.36 No. Structural parameter
1 2 3 4 5 6 7 8 9 10
m p1 p2 p3 p q k1 k2 k (RG1)
11
(RG2)
12
(RG3)
13 14 15 16 17 18 19 20 21 22
SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
23 24 25 26 27 28 29
SF rl rF MF NF TF
30 31 32 a
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PPaR-1RPaPa (Fig. 2.34a) 2PPaR-1RPaPat (Fig. 2.34b) 2PaRR-1RPaPa (Fig. 2.35a) 2PaRR-1RPaPat (Fig. 2.35b) 16 6 6 9 21 6 0 3 3 ( v1 , v2 , δ ) ( v1 , v2 , ( v1 , v2 , 3 3 3 3 3 6 3 3 3 ( v1 , v2 , 3 12 18 3 18 0 6
δ
)
δ
)
δ
)
2PaPaR-1RPaPa (Fig. 2.36a) 2PaPaR-1RPaPat (Fig. 2.36b)
20 9 9 9 27 8 0 3 3 ( v1 , v2 , ( v1 , v2 , ( v1 , v2 , 3 3 3 6 6 6 3 3 3 ( v1 , v2 , 3 18 24 3 24 0 9
fj
6
9
fj
9
9
fj
21
27
δ
)
δ
)
δ
)
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
2.1 Basic solutions
47
Fig. 2.4. Overconstrained PPMs with coupled motions of types 3-RRR (a) and 3RRP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology R||R||R (a) and R||R ⊥ P (b)
48
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.5. Overconstrained PPMs with coupled motions of types 3-RPR (a) and 3PRR (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology R ⊥ P ⊥ ||R (a) and P ⊥ R||R (b)
2.1 Basic solutions
49
Fig. 2.6. Overconstrained PPM with coupled motions of type 3-PRP defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology P ⊥ R ⊥ P
Fig. 2.7. Overconstrained PPM with coupled motions of type 3-PaPaR defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=24, limb topology Pa||Pa||R
50
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.8. Overconstrained PPMs with coupled motions of types 3-PaRR (a) and 3PaRP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=15, limb topology Pa||R||R (a) and Pa||R ⊥ P (b)
2.1 Basic solutions
51
Fig. 2.9. Overconstrained PPMs with coupled motions of types 3-PaPR (a) and 3PPaR (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=15, limb topology Pa ⊥ P ⊥ ||R (a) and P ⊥ Pa||R (b)
52
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.10. Overconstrained PPM with one decoupled translation of type 3-PPR defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology P ⊥ P ⊥ ⊥ R
Fig. 2.11. Overconstrained PPM with one decoupled translation of type 1PPR2RRR defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology P ⊥ P ⊥ ⊥ R and R||R||R
2.1 Basic solutions
53
Fig. 2.12. Overconstrained PPMs with one decoupled translation of types 1PPR2RRP (a) and 1PPR-2RPR (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology P ⊥ P ⊥ ⊥ R and R||R ⊥ P (a), P ⊥ P ⊥ ⊥ R and R ⊥ P ⊥ ||R (b)
54
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.13. Overconstrained PPMs with one decoupled translation of types 1PPR2PRR (a) and 1PPR-2PRP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology P ⊥ P ⊥ ⊥ R and P ⊥ R||R (a), P ⊥ P ⊥ ⊥ R and P ⊥ R ⊥ P (b)
2.1 Basic solutions
55
Fig. 2.14. Overconstrained PPMs with one decoupled translation of types 1PaPR2PaRR (a) and 1PaPR-2PPaR (b) defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=15, limb topology Pa ⊥ P ⊥ ||R and Pa||R||R (a), Pa ⊥ P ⊥ ||R and P ⊥ Pa||R (b)
56
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.15. Overconstrained PPMs with one decoupled translation of types 1PaPR2PaPaR (a) and 1PaPR-2PaRP (b) defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=21 (a), NF=15 (b), limb topology Pa ⊥ P ⊥ ||R and Pa||Pa||R (a), Pa ⊥ P ⊥ ||R and Pa||R ⊥ P (b)
2.1 Basic solutions
57
Fig. 2.16. 3RRR-type overconstrained PPMs with partially decoupled translations defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=6, limb topology R||R||R
58
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.17. Overconstrained PPMs with partially decoupled translations of types 3RPR (a) and 2RPR-1RPR (b) defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=6, limb topology R ⊥ P ⊥ ||R (a), R ⊥ P ⊥ ||R and R ⊥ P ⊥ ||R (b)
2.1 Basic solutions
59
Fig. 2.18. Overconstrained PPM with decoupled rotation of type 2RPP-1RPP defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology R ⊥ P ⊥ ⊥ P
Fig. 2.19. Overconstrained PPM with decoupled rotation of type 2RPPa-1RPPa, NF=21 defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=15, limb topology R ⊥ P ⊥ ||Pa
60
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.20. Overconstrained PPMs with decoupled rotation of types 2RPaP-1RPaP (a) and 2RPaPa-1RPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=15, (a), NF=24 (b), limb topology R||Pa ⊥ P (a) and R||Pa||Pa (b)
2.1 Basic solutions
61
Fig. 2.21. Overconstrained PPMs with uncoupled rotation of types 2PRR-1RPP (a), 2RRR-1RPP (b) and 2RPR-1RPP (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology R ⊥ P ⊥ ⊥ P and P ⊥ R||R (a), R||R||R (b), R ⊥ P ⊥ ||R (c)
62
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.22. Overconstrained PPMs with uncoupled rotation of types 2PPaR-1RPP (a), 2PaRR-1RPP (b) and 2PaPaR-1RPP (c) defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=12 (a) and (b), NF=18 (c), limb topology R ⊥ P ⊥ ⊥ P and P ⊥ Pa||R (a), Pa||R||R (b), Pa||Pa||R (c)
2.1 Basic solutions
63
Fig. 2.23. Overconstrained PPMs with uncoupled rotation of types 2PRR-1RPPa (a), 2RRR-1RPPa (b) and 2RPR-1RPPa (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9, limb topology R ⊥ P ⊥ ||Pa and P ⊥ R||R (a), R||R||R (b), R ⊥ P ⊥ ||R (c)
64
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.24. Overconstrained PPMs with uncoupled rotation of types 2PRR-1RPaP (a), 2RRR-1RPaP (b) and 2RPR-1RPaP (c) defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=9, limb topology R||Pa ⊥ P and P ⊥ R||R (a), R||R||R (b), R ⊥ P ⊥ ||R (c)
2.1 Basic solutions
65
Fig. 2.25. Overconstrained PPMs with uncoupled rotation of types 2PRR-1RPaPa (a), 2RRR-1RPaPa (b) and 2RPR-1RPaPa (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12, limb topology R||Pa||Pa and P ⊥ R||R (a), R||R||R (b), R ⊥ P ⊥ ||R (c)
66
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.26. Overconstrained PPMs with uncoupled rotation of types 2PPaR-1RPPa (a) and 2PaRR-1RPPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=15, limb topology R ⊥ P ⊥ ||Pa and P ⊥ Pa||R (a), Pa||R||R (b)
2.1 Basic solutions
67
Fig. 2.27. Overconstrained PPMs with uncoupled rotation of types 2PPaR-1RPaP (a) and 2PaRR-1RPaP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=15, limb topology R||Pa ⊥ P and P ⊥ Pa||R (a), Pa||R||R (b)
68
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.28. Overconstrained PPMs with uncoupled rotation of types 2PaPaR1RPPa (a) and 2PaPaR-1RPaP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=21, limb topology Pa||Pa||R and R ⊥ P ⊥ ||Pa (a), R||Pa ⊥ P (b)
2.1 Basic solutions
69
Fig. 2.29. Overconstrained PPMs with uncoupled rotation of types 2PPaR1RPaPa (a) and 2PaRR-1RPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=18, limb topology R||Pa||Pa and P ⊥ Pa||R (a), Pa||R||R (b)
70
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.30. 2PaPaR-1RPaPa-type overconstrained PPM with uncoupled rotation defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=24, limb topology Pa||Pa||R and R||Pa||Pa
2.1 Basic solutions
71
Fig. 2.31. Overconstrained PPMs with uncoupled rotation of types 2PRR-1RPaPa (a) and 2PRR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12, limb topology P ⊥ R||R and R||Pa||Pa (a), R||Pa||Pat (b)
72
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.32. Overconstrained PPMs with uncoupled rotation of types 2RRR-1RPaPa (a) and 2RRR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12, limb topology R||R||R and R||Pa||Pa (a), R||Pa||Pat (b)
2.1 Basic solutions
73
Fig. 2.33. Overconstrained PPMs with uncoupled rotation of types 2RPR-1RPaPa (a) and 2RPR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12, limb topology R ⊥ P ⊥ ||R and R||Pa||Pa (a), R||Pa||Pat (b)
74
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.34. Overconstrained PPMs with uncoupled rotation of types 2PPaR1RPaPa (a) and 2PPaR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=18, limb topology P ⊥ Pa||R and R||Pa||Pa (a), R||Pa||Pat (b)
2.1 Basic solutions
75
Fig. 2.35. Overconstrained PPMs with uncoupled rotation of types 2PaRR1RPaPa (a) and 2PaRR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=18, limb topology Pa||R||R and R||Pa||Pa (a), R||Pa||Pat (b)
76
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.36. Overconstrained PPMs with uncoupled rotation of types 2PaPaR1RPaPa (a) and 2PaPaR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=24, limb topology Pa||Pa||R and R||Pa||Pa (a), R||Pa||Pat (b)
2.1 Basic solutions
77
2.1.2 Non fully-parallel solutions The non fully-parallel solutions presented in Figs. 2.37-2.43 are obtained from the fully-parallel solutions in Figs. 2.21, 2.23-2.25, 2.31-2.33 by superposing the last revolute joints of limbs G1 and G2. In this way, these two limbs compose just one complex limb denoted by G1-G2 in which two actuators are combined. For example, the solutions in Fig. 2.37 combine one simple and one complex limb. Simple limb G3 is of type RPP and complex limb G1-G2 is of types (PRRRP)R (Fig. 2.37a), (RRRRR)R (Fig. 2.37b) and (RPRPR)R (Fig. 2.37c). One closed loop defined in the brackets is combined in each complex limb G1-G2. The solutions in Figs. 2.38-2.43 combine two complex limbs G1-G2 and G3. The rotation axis of the moving platform has a fixed position in the solutions in Figs. 2.38-2.40 and a variable position in Figs. 2.41-2.43. The structural parameters of the solutions presented in Figs. 2.37-2.43 are systematized in Tables 2.10 and 2.11. The basis of the vector space of the relative velocities between the moving and the fixed platforms in the complex limb G1-G2 isolated from the parallel mechanism is denoted by (RG1-G2) in Tables 2.10 and 2.11. The connectivity between the moving and the fixed platforms of this complex limb isolated from the parallel mechanism is denoted by SG1-G2 (see Table 2.10-2.11). The non fully-parallel solutions presented in Figs. 2.37-2.43 have the same number of overconstraints as their fully-parallel counterparts in Figs. 2.21, 2.23-2.25, 2.31-2.33.
78
2 Overconstrained planar parallel robots with coupled motions
Table 2.11. Structural parametersa of planar parallel mechanisms in Figs. 2.372.39 No. Structural parameter
Solution (PRRRP)R-RPP (Fig. 2.37a) (RRRRR)R-RPP (Fig. 2.37b) (RPRPR)R-RPP (Fig. 2.37c)
1 2 3 4 5 6 7 8 9
m p1 p2 p q k1 k2 k (RG1-G2)
10
(RG3)
11 12 13 14 15 16 17
SG1-G2 SG3 rG1-G2 rG3 MG1-G2 MG3 (RF)
18 19 20 21 22 23 24
SF rl rF MF NF TF
8 6 3 9 2 1 1 2 ( v1 , v 2 , ( v1 , v 2 , 3 3 3 0 3 3 ( v1 , v 2 , 3 3 6 3 6 0 6
25 26 a
∑ ∑ ∑
p1 j =1 p2 j =1 p j =1
fj
δ
)
δ
)
δ
)
(PRRRP)R-RPPa (Fig. 2.38a) (RRRRR)R-RPPa (Fig. 2.38b) (RPRPR)R-RPPa (Fig. 2.38c) (PRRRP)R-RpaP (Fig. 2.39a) (RRRRR)R-RPaP (Fig. 2.39b) (RPRPR)R-RPaP (Fig. 2.39c) 10 6 6 12 3 0 2 2 ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 3 3 3 3 3 3 ( v1 , v 2 , δ ) 3 6 9 3 9 0 6
fj
3
6
fj
9
12
See footnote of Table 2.4 for the nomenclature of structural parameters
2.1 Basic solutions
79
Table 2.12. Structural parametersa of planar parallel mechanisms in Figs. 2.402.43 No.
Structural parameter
1 2 3 4 5 6 7 8 9
m p1 p2 p q k1 k2 k (RG1-G2)
10
(RG3)
11 12 13 14 15 16 17
SG1-G2 SG3 rG1-G2 rG3 MG1-G2 MG3 (RF)
18 19 20 21 22 23 24
SF rl rF MF NF TF
25 26 a
∑ ∑ ∑
p1 j =1 p2 j =1 p j =1
fj
Solution (PRRRP)R-RpaPa (Fig. 2.40a) (RRRRR)R-RPaPa (Fig. 2.40b) (RPRPR)R-RPaPa (Fig. 2.40c) (PRRRP)R-RPaPa (Fig. 2.41a) (PRRRP)R-RPaPat (Fig. 2.41b) (RRRRR)R-RPaPa (Fig. 2.42a) (RRRRR)R-RPaPat (Fig. 2.42b) (RPRPR)R-RPaPa (Fig. 2.43a) (RPRPR)R-RPaPat (Fig. 2.43b) 12 6 9 15 4 0 2 2 ( v1 , v 2 , δ ) ( v1 , v2 , δ ) 3 3 3 6 3 3 ( v1 , v2 , δ ) 3 9 12 3 12 0 6
fj
9
fj
15
See footnote of Table 2.4 for the nomenclature of structural parameters
80
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.37. Overconstrained PPMs with uncoupled rotation of types (PRRRP)RRPP (a), (RRRRR)R-RPP (b) and (RPRPR)R-RPP (c), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6
2.1 Basic solutions
81
Fig. 2.38. Overconstrained PPMs with uncoupled rotation of types (PRRRP)RRPPa (a), (RRRRR)R-RPPa (b) and (RPRPR)R-RPPa (c), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9
82
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.39. Overconstrained PPMs with uncoupled rotation of types (PRRRP)RRPaP (a), (RRRRR)R-RPaP (b) and (RPRPR)R-RPaP (c), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9
2.1 Basic solutions
83
Fig. 2.40. Overconstrained PPMs with uncoupled rotation of types (PRRRP)RRPaPa (a), (RRRRR)R-RPaPa (b) and (RPRPR)R-RPaPa (c), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12
84
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.41. Overconstrained PPMs with uncoupled rotation of types (PRRRP)RRPaPa (a) and (PRRRP)R-RPaPat (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12
2.1 Basic solutions
85
Fig. 2.42. Overconstrained PPMs with uncoupled rotation of types (RRRRR)RRPaPa (a) and (RRRRR)R-RPaPat (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12
86
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.43. Overconstrained PPMs with uncoupled rotation of types (RPRPR)RRPaPa (a) and (RPRPR)R-RPaPat (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12
2.2 Derived solutions
87
2.2 Derived solutions Solutions with lower degrees of overconstraint can be derived from the basic solutions in Figs. 2.4-2.43 by using joints with idle mobilities. A large set of solutions can be obtained by introducing idle mobilities in the limbs. The joints combining idle mobilities are denoted by an asterisk. The idle mobilities which can be combined in a parallelogram loop are systematized in Fig. 1.2 and Table 1.1. One idle mobility is combined in each cylindrical joint C* and two idle mobilities in each spherical joint S*. These idle mobilities can be introduced outside or inside the loops combined in the limbs. The rotational mobility of the revolute joint denoted by R* is an idle mobility. In the cylindrical joint denoted by C* in Figs. 2.45, 2.46b, 2.54b, 2.55a, 2.61, 2.62a the translation is the actuated motion and the rotation is the idle mobility. The rotation is also the idle mobility in the cylindrical joint denoted by C* in Figs 2.65a, 2.70, 2.71 and 2.72a. We recall that the notation Pacs is associated with a parallelogram loop with three idle mobilities combined in a cylindrical and a spherical joint, and Pass with four idle mobilities combined in two spherical joints adjacent to the same link. In the cylindrical joints of the Pacs-type parallelogram loops (Figs. 2.84-2.95 and 2.104-2.109) the translational motion is an idle mobility. We note that in the Pass-type parallelogram loop, three idle mobilities are introduced in the loop and one outside the loop. If the link adjacent to the two spherical joints is a binary link than the idle mobility introduced outside the loop becomes an internal rotational mobility of the binary link around the axis passing by the centre of the two spherical joints. This internal mobility gives one degree of structural redundancy (see Table 2.13). If the link adjacent to the two spherical joints is connected in the limb by three or more joints (polinary link) than the rotational motion around the axis passing by the centre of the two spherical joints is an idle (potential) mobility of the limb. This mobility is restricted by the constraints of the parallel mechanism and remains just a potential mobility. For example in Fig. 2.68c, this rotational motion is internal mobility of links 3A and 3B, and idle mobility for the ternary links 7A and 7B. Examples of solutions with identical limbs and 3-18 overconstraints derived from the basic solutions in Figs. 2.4-2.10 are illustrated in Figs. 2.44-2.52. The solutions with one decoupled translation v1 = v1 ( &q1 ) and 3-15 overconstraints illustrated in Figs. 2.53-2.59 are derived from the basic solutions in Figs. 2.11-2.15. The solutions with partially decoupled translational motions and three overconstraints illustrated in Figs. 2.60-2.61 are derived from the solutions in Figs. 2.16 and 2.17. The solutions with decoupled
88
2 Overconstrained planar parallel robots with coupled motions
rotational motion ωδ = ωδ ( &q3 ) and 2-22 overconstraints illustrated in Figs. 2.62-2.95 are derived from the solutions in Figs. 2.18-2.36. The non fully-parallel solutions with 2-8 overconstraints illustrated in Figs. 2.96-2.109 are derived from the solutions in Figs. 2.37-2.43. The bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms in Figs. 2.44-109 are given in Tables 2.14 and 2.15. The limb topology and connecting conditions of these solutions are systematized in Tables 2.16-2.21, as are their structural parameters in Tables 2.22-2.40.
Table 2.13. Links with internal mobilities and the degree of structural redundancy TF of overconstrained SPMs with uncoupled planar motion of the moving platform No. Parallel mechanism Figure
TF
Link with internal rotational mobility in limb G1 G2 G3
1
3
3A
3B
3C
6 3 2
3A, 6 A 4A 3A
3 B, 6B 4B 3B
3 C, 6C 4C -
1 1 2
-
-
5C 4C 3 C, 6C
2 3 4 5 6 7
Figs. 2.47b, 2.50b, 2.51a Fig. 2.50a Fig.2.51b Figs. 2.68c, 2.79b, 2.82 Figs. 2.72, 2.98 Figs. 2.73, 2.99 Figs. 2.74, 2.100
2.2 Derived solutions
89
Table 2.14. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 2.44-2.95 No. Parallel mechanism 1 Figs. 2.44-2.46, 2.60 2 Figs. 2.47a, 2.48, 2.49, 2.56, 2.57 3 Figs. 2.47b, 2.50, 2.51, 2.72-2.74 4 Figs. 2.52, 2.53, 2.54a, 2.55b 5 Figs. 2.54b, 2.61b 6 Fig. 2.55a
Basis (RG1) ( v1 , v 2 ,
α,
δ
)
( v1 , v 2 ,
α
,
β
,
( v1 , v 2 ,
δ
)
( v1 , v 2 ,
β
,
δ
( v1 , v 2 ,
β
,
( v1 , v 2 ,
α
7
Fig. 2.58
( v1 , v 2 ,
Figs. 2.59, 2.61a, 2.63, 2.64, 2.80b, 2.81b 9 Figs. 2.62, 2.80a, 2.81a, 2.82 10 Figs. 2.65, 2.69-2.71, 2.75-2.78, 2.79a, 2.84-2.86 11 Figs. 2.66, 2.87-2.89 12 Figs. 2.67
8
δ
)
β,
( v1 , v 2 , v 3 ,
α
,
δ
)
)
( v1 , v 2 ,
α
,
δ
δ
)
( v1 , v 2 ,
β
,
,
δ
)
( v1 , v 2 ,
β
α
,
δ
)
( v1 , v 2 ,
( v1 , v 2 ,
α
,
δ
)
( v1 , v 2 ,
β
,
δ
)
( v1 , v 2 , v 3 ,
α
,
( v1 , v 2 ,
δ
)
13 Figs. 2.68a,c ( v1 , v2 ,
β
,
δ
14 Figs. 2.68b
( v1 , v 2 ,
α
,
15 Figs. 2.79b, 2.83a 16 Figs. 2.83b
( v1 , v 2 ,
β
( v1 , v 2 ,
α
( v1 , v 2 , v 3 ,
,
δ
)
β
,
( v1 , v 2 , v 3 ,
δ
β
)
,
δ
)
( v1 , v 2 ,
δ
)
)
( v1 , v 2 ,
α
,
δ
)
δ
)
( v1 , v 2 ,
α
,
δ
)
,
δ
)
( v1 , v 2 ,
β
,
δ
)
α
,
δ
)
( v1 , v 2 ,
β
,
δ
)
( v1 , v 2 ,
β
,
δ
)
( v1 , v 2 ,
α
,
δ
)
( v1 , v 2 ,
α
,
δ
)
( v1 , v 2 ,
β
,
δ
)
( v1 , v 2 ,
δ
)
( v1 , v 2 ,
δ
)
( v1 , v 2 ,
α
,
β
,
δ
)
( v1 , v 2 , v 3 ,
)
δ
(RG3) ( v1 , v 2 ,
δ )
( v1 , v 2 ,
( v1 , v 2 ,
17 Figs. 2.90, 2.93
(RG2) ( v1 , v 2 ,
)
δ
( v1 , v 2 ,
α
,
( v1 , v 2 ,
δ
)
)
( v1 , v 2 ,
α
,
δ
)
( v1 , v 2 ,
δ
)
δ
)
( v1 , v 2 ,
β
,
δ
)
( v1 , v 2 ,
δ
)
,
δ
)
( v1 , v 2 ,
α
,
δ
)
( v1 , v 2 ,
α
,
β
,
δ
)
,
δ
)
( v1 , v 2 ,
β
,
δ
)
( v1 , v 2 ,
α
,
β
,
δ
)
( v1 , v 2 ,
δ
)
β
β
,
δ
δ
)
)
( v1 , v 2 , v 3 ,
β
α
,
,
δ
δ
)
)
90
2 Overconstrained planar parallel robots with coupled motions
Table 2.14. (cont.) 18 Figs. 2.91, 2.94 19 Figs. 2.92, 2.95
( v1 , v 2 , v 3 ,
α
,
δ
)
( v1 , v 2 , v 3 ,
α
,
β
,
δ
( v1 , v 2 , v 3 ,
β
,
δ
)
) ( v1 , v 2 , v 3 ,
α
,
β
,
δ
( v1 , v 2 ,
δ
)
) ( v1 , v 2 ,
δ
)
Table 2.15. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 2.96-2.109 No. Parallel mechanism 1 Figs. 2.96 2
Figs. 2.97, 2.101-2.103
3
Figs. 2.98, 2.99, 2.100, 2.104-2.106 Figs. 2.107-109
4
Basis (RG1-G2) ( v1 , v 2 , v 3 , δ ) ( v1 , v 2 , β , δ )
(RG3) ( v1 , v 2 , ( v1 , v 2 ,
δ
)
δ
)
( v1 , v 2 ,
( v1 , v 2 ,
δ
)
( v1 , v 2 ,
δ
)
δ
( v1 , v 2 , v 3 ,
) β
,
δ
)
Table 2.16. Limb topology and the number of overconstraints NF of the derived PPMs with idle mobilities presented in Figs. 2.44-2.46 No. Basic PPM Type 1 3-RRR (Fig. 2.4a) 2 3-RRP (Fig. 2.4b) 3 3-RPR (Fig. 2.5a) 4 3-PRR (Fig. 2.5b) 5 3-PRP (Fig. 2.6) 6
NF 6 6 6 6 6
Derived PPM Type 3-RR*RR (Fig. 2.44a) 3-RRC* (Fig. 2.44b) 3-RC*R (Fig. 2.45a) 3-C*RR (Fig. 2.45b) 3-PRC* (Fig. 2.46a) 3-C*RP (Fig. 2.46b)
NF 3
Limb topology R ⊥ R* ⊥ ||R||R
3
R||R ⊥ C*
3
R ⊥ C* ⊥ ||R
3
C* ⊥ R||R
3
P ⊥ R ⊥ C*
3
C* ⊥ R ⊥ P
2.2 Derived solutions
91
Table 2.17. Limb topology and the number of overconstraints NF of the derived PPMs with idle mobilities presented in Figs. 2.47-2.54 No. Basic PPM Type 1 3-PaPaR (Fig. 2.7) 2 3
3-PaRR (Fig. 2.8a)
NF 24
15
4 5
3-PaRP (Fig. 2.8b)
15
6 7
3-PaPR (Fig. 2.9a)
15
8 9
3-PPaR (Fig. 2.9b)
15
10 11 12 13 14
3-PPR (Fig. 2.10) 1PPR-2RRR (Fig. 2.11) 1PPR-2RRP (Fig. 2.12a) 1PPR-2RPR (Fig. 2.12b)
6 6 6 6
Derived PPM Type 3-PaPaS* (Fig. 2.48a) 3-PassPassR (Fig. 2.50a) 3-PaRS* (Fig. 2.47a) 3-PassRR (Fig. 2.47b) 3-PaS*P (Fig. 2.48b) 3-PassRP (Fig. 2.50b) 3-PaPS* (Fig. 2.49a) 3-PassPR (Fig. 2.51a) 3-PPaS* (Fig. 2.49b) 3-PPassR (Fig. 2.51b) 3-PC*R (Fig. 2.52) 1PC*R-2RR*RR (Fig. 2.53) 1PC*R-2RRC* (Fig. 2.54a) 1PC*R-2RC*R (Fig. 2.54b)
NF 18
Limb topology Pa||PaS*
6
Pass||Pass||R
9
Pa||RS*
6
Pass||R||R
9
PaS*P
6
Pass||R ⊥ P
9
Pa ⊥ PS*
6
Pass ⊥ P ⊥ ||R
9
P ⊥ PaS*
6
P ⊥ Pass||R
3
P ⊥ C* ⊥ ⊥ R
3
P ⊥ C* ⊥ ⊥ R R ⊥ R* ⊥ ||R||R P ⊥ C* ⊥ ⊥ R R||R ⊥ C* P ⊥ C* ⊥ ⊥ R R ⊥ C* ⊥ ||R
3 3
92
2 Overconstrained planar parallel robots with coupled motions
Table 2.18. Limb topology and the number of overconstraints NF of the derived PPMs with idle mobilities presented in Figs. 2.55-2.64 No. Basic PPM Type 1 1PPR-2PRR (Fig. 2.13a) 2 1PPR-2PRP (Fig. 2.13b) 3 1PaPR-2PaRR (Fig. 2.14a) 4 5
1PaPR-2PPaR (Fig. 2.14b)
NF 6 6 15
15
6 7
1PaPR-2PaPaR (Fig. 2.15a)
21
8 9
1PaPR-2PaRP (Fig. 2.15b)
15
10 11 12 13 14 15 16 17
3RRR (Fig. 2.16a,b) 3RPR (Fig. 2.17a) 2RPR-1RPR (Fig. 2.17b) 2RPP-1RPP (Fig. 2.18) 2RPPa-1RPPa (Fig. 2.19) 2RPaP-1RPaP (Fig. 2.20a) 2RPaPa-1RPaPa (Fig. 2.20b)
6 6 6 6 15 15 24
Derived PPM Type 1C*PR-2C*RR (Fig. 2.55a) 1PC*R-2PRC* (Fig. 2.55b) 1PaPS*-2PaRS* (Fig. 2.56a) 1PassPR-2PassRR (Fig. 2.58a) 1PaPS*-2PPaS* (Fig. 2.56b) 1PassPR-2PPassR (Fig. 2.58b) 1PaPS*-2PaPaS* (Fig. 2.57a) 1PassPR-2PaPassR (Fig. 2.59a) 1PaPS*-2PaS*P (Fig. 2.57b) 1PassPR-2PassRP (Fig. 2.59b) 3RR*RR (Fig. 2.60a,b) 3RC*R (Fig. 2.61a) 2RC*R-1RC*R (Fig. 2.61b) 2RPC*-1RPC* (Fig. 2.62) 2RC*Pa-1RC*Pa (Fig. 2.63) 2RPaC*-1RPaC* (Fig. 2.64a) 2RPaPass-1RPaPass (Fig. 2.64b)
NF 3
3
Limb topology C* ⊥ P ⊥ ⊥ R C* ⊥ R||R P ⊥ C* ⊥ ⊥ R P ⊥ R ⊥ C* Pa ⊥ PS* Pa||RS* Pass ⊥ P ⊥ ||R Pass||R||R 1Pa ⊥ PS* P ⊥ PaS* Pass ⊥ P ⊥ ||R P ⊥ Pass||R Pa ⊥ PS* Pa||PaS* Pass ⊥ P ⊥ ||R Pass||R ⊥ P Pa ⊥ PS* PaS*P Pass ⊥ P ⊥ ||R Pass||R ⊥ P R ⊥ R* ⊥ ||R||R
3
R ⊥ C* ⊥ ||R
3 3
R ⊥ C* ⊥ ||R R ⊥ C* ⊥ ||R R ⊥ P ⊥ ⊥ C*
12
R ⊥ C* ⊥ ||Pa
12
R||Pa ⊥ C* R||Pa ⊥ C* R||Pa||Pass R||Pa||Pass
3 9 3 9 3 15 9 9 3
12
2.2 Derived solutions
93
Table 2.19. Limb topology and the number of overconstraints NF of the derived PPMs with idle mobilities presented in Figs. 2.65-2.89 No. Basic PPM Type 1 2PRR-1RPP (Fig. 2.21a) 2
6
3
6
2RRR-1RPP (Fig. 2.21b)
4 5
6 2RPR-1RPP (Fig. 2.21c)
6 7
NF 6
6 6
2PPaR-1RPP (Fig. 2.22a)
12
8 9
2PaRR-1RPP (Fig. 2.22b)
12
10 11
2PaPaR-1RPP (Fig. 2.22c)
18
12 13
2PRR-1RPPa (Fig. 2.23a)
9
14 15
2RRR-1RPPa (Fig. 2.23b)
9
16 17
2RPR-1RPPa (Fig. 2.23c)
9
18 19
2PRR-1RPaP (Fig. 2.24a)
9
Derived PPM Type 2PRC*-1RPP (Fig. 2.65a) 2PS*R-1RPP (Fig. 2.66a) 2RRC*-1RPP (Fig. 2.65b) 2RS*R-1RPP (Fig. 2.66b) 2RPC*-1RPP (Fig. 2.65c) 2S*PR-1RPP (Fig. 2.66c) 2PPaR-1RC*C* (Fig. 2.67a) 2PPassR-1RPP (Fig. 2.68a) 2PaRR-1RC*C* (Fig. 2.67b) 2PassRR-1RPP (Fig. 2.68b) 2PaPaR-1RC*C* (Fig. 2.67c) 2PassPassR-1RPP (Fig. 2.68c) 2PRC*-1RPPa (Fig. 2.69a) 2PRR-1RPPass (Fig. 2.72a) 2RRC*-1RPPa (Fig. 2.69b) 2RRR-1RPPass (Fig. 2.72b) 2RPC*-1RPPa Fig. 2.69c) 2RPR-1RPPass (Fig. 2.72c) 2PRC*-1RPaP (Fig. 2.70a)
NF 4 2 4 2 4 2 10 4 10 4 16 4 7 6 7 6 7 6 7
Limb topology P ⊥ R||C* R ⊥ P ⊥⊥ P PS*R R ⊥ P ⊥⊥ P R||R||C* R ⊥ P ⊥⊥ P RS*R R ⊥ P ⊥⊥ P R ⊥ P ⊥ ||C* R ⊥ P ⊥⊥ P SP ⊥ R R ⊥ P ⊥⊥ P P ⊥ Pa||R R ⊥ C* ⊥ ⊥ C* P ⊥ Pass||R R ⊥ P ⊥⊥ P Pa||R||R R ⊥ C* ⊥ ⊥ C* Pass||R||R R ⊥ P ⊥⊥ P Pa||Pa||R Pass||Pass||R R ⊥ P ⊥⊥ P P ⊥ R||C* R ⊥ P ⊥ ||Pa P ⊥ R||R R ⊥ P ⊥ ||Pass R||R||C* R ⊥ P ⊥ ||Pa R||R||R R ⊥ P ⊥ ||Pass R ⊥ P ⊥ ||C* R ⊥ P ⊥ ||Pa R ⊥ P ⊥ ||R R ⊥ P ⊥ ||Pass P ⊥ R||C* R||Pa ⊥ P
94
2 Overconstrained planar parallel robots with coupled motions
Table 2.19. (cont.) 20 21
2RRR-1RPaP (Fig. 2.24b)
9
22 23
2RPR-1RPaP (Fig. 2.24c)
9
24 25
2PRR-1RPaPa (Fig. 2.25a)
12
26 27
2RRR-1RPaPa (Fig. 2.25b)
12
28 29
2RPR-1RPaPa (Fig. 2.25c)
12
30 31
2PPaR-1RPPa (Fig. 2.26a)
15
32 33
2PaRR-1RPPa (Fig. 2.26b)
15
34 35
2PPaR-1RPaP (Fig. 2.27a)
15
36 37
2PaRR-1RPaP (Fig. 2.27b)
15
38 39
2PaPaR-1RPPa (Fig. 2.28a)
21
40 41
2PaPaR-1RPaP (Fig. 2.28b)
21
2PRR-1RPassP (Fig. 2.73a) 2RRC*-1RPaP (Fig. 2.70b) 2RRR-1RPassP (Fig. 2.73b) 2RPC*-1RPaP (Fig. 2.70c) 2RPR-1RPassP (Fig. 2.73c) 2PRC*-1RPaPa (Fig. 2.71a) 2PRR-1RPassPass (Fig. 2.74a) 2RRC*-1RPaPa (Fig. 2.71b) 2RRR-1RPassPass (Fig. 2.74b) 2RPC*-1RPaPa (Fig. 2.71c) 2RPR-1RPassPass (Fig. 2.74c) 2PPaC*-1RPPa (Fig. 2.75a) 2PPassR-1RPPass (Fig. 2.80a) 2PaRC*-1RPPa (Fig. 2.75b) 2PassRR-1RPPass (Fig. 2.80b) 2PPaC*-1RPaP (Fig. 2.76a) 2PPassR-1RPassP (Fig. 2.81a) 2PaRC*-1RPaP (Fig. 2.76b) 2PassRR-1RPassP (Fig. 2.81b) 2PaPaC*-1RPPa (Fig. 2.77a) 2PassPassR-1RPPass (Fig. 2.82a) 2PaPaC*-1RPaP (Fig. 2.77b)
6 7 6 7 6 10 6 10 6 10 6 13 3 13 3 13 3 13 3 19 3 19
P ⊥ R||R R||Pass ⊥ P R||R||C* R||Pa ⊥ P R||R||R R||Pass ⊥ P R ⊥ P ⊥ ||C* R||Pa ⊥ P R ⊥ P ⊥ ||R R||Pass ⊥ P P ⊥ R||C* R||Pa||Pa P ⊥ R||R R||Pass||Pass R||R||C* R||Pa||Pa R||R||R R||Pass||Pass R ⊥ P ⊥ ||C* R||Pa||Pa R ⊥ P ⊥ ||R R||Pass||Pass P ⊥ Pa||C* R ⊥ P ⊥ ||Pa P ⊥ Pass||R R ⊥ P ⊥ ||Pass Pa||R||C* R ⊥ P ⊥ ||Pa Pass||R||R R ⊥ P ⊥ ||Pass P ⊥ Pa||C* R||Pa ⊥ P P ⊥ Pass||R R ⊥ Pass ⊥ ||P Pa||R||C* R||Pa ⊥ P Pass||R||R R ⊥ Pass ⊥ ||P Pa||Pa||C* R ⊥ P ⊥ ||Pa Pass||Pass||R R ⊥ P ⊥ ||Pass Pa||Pa||C* R||Pa ⊥ P
2.2 Derived solutions Table 2.19. (cont.) 42 43
2PPaR-1RPaPa (Fig. 2.29a)
18
44 45
2PaRR-1RPaPa (Fig. 2.29b)
18
46 47
2PaPaR-1RPaPa (Fig. 2.30)
24
48 49
2PRR-1RPaPa (Fig. 2.31a)
12
50 51
2PRR-1RPaPat (Fig. 2.31b)
12
52 53
2RRR-1RPaPa (Fig. 2.32a)
12
54 55
2RRR-1RPaPat (Fig. 2.32b)
12
56 57
2RPR-1RPaPa (Fig. 2.33a)
12
58 59 60
2RPR-1RPaPat (Fig. 2.33b)
12
2PassPassR-1RPassP (Fig. 2.82b) 2PPaC*-1RPaPa (Fig. 2.78a) 2PPassR-1RPassPass (Fig. 2.83a) 2PaRC*-1RPaPa (Fig. 2.78b) 2PassRR-1RPassPass (Fig. 2.83b) 2PaPaC*-1RPaPa (Fig. 2.79a) 2PassPassR-1RPassPass (Fig. 2.79b) 2PRC*-1RPacsPacs (Fig. 2.84a) 2PS*R-1RPacsPacs (Fig. 2.87a) 2PRC*-1RPacsPatcs (Fig. 2.84b) 2PS*R-1RPacsPatcs (Fig. 2.87b) 2RRC*-1RPacsPacs (Fig. 2.85a) 2RS*R-1RPacsPacs (Fig. 2.88a) 2RRC*-1RPacsPatcs (Fig. 2.85b) 2RS*R-1RPacsPatcs (Fig. 2.88b) 2RPC*-1RPacsPacs (Fig. 2.86a) 2S*PR-1RPacsPacs (Fig. 2.89a) 2RPC*-1RPacsPatcs (Fig. 2.86b) 2S*PR-1RPacsPatcs (Fig. 2.89b)
3 16 2 16 2 22 2 4 2 4 2 4 2 4 2 4 2 4 2
Pass||Pass||R R||Pass ⊥ P P ⊥ Pa||C* R||Pa||Pa P ⊥ Pass||R R||Pass||Pass Pa||R||C* R||Pa||Pa Pass||R||R R||Pass||Pass Pa||Pa||C* R||Pa||Pa Pass||Pass||R R||Pass||Pass P ⊥ R||C* R||Pacs||Pacs PS*R R||Pacs||Pacs P ⊥ R||C* R||Pacs||Pat cs PS*R R||Pacs||Patcs R||R||C* R||Pacs||Pacs RS*R R||Pacs||Pacs R||R||C* R||Pacs||Patcs R||R||C* R||Pacs||Patcs R ⊥ P ⊥ ||C* R||Pacs||Pacs S*P ⊥ R R||Pacs||Pacs R ⊥ P ⊥ ||C* R||Pacs||Patcs S*P ⊥ R R||Pacs||Patcs
95
96
2 Overconstrained planar parallel robots with coupled motions
Table 2.20. Limb topology and the number of overconstraints NF of the derived PPMs with idle mobilities presented in Figs. 2.90-2.95 No. Basic PPM Type 61 2PPaR-1RPaPa (Fig. 2.34a) 62 63
NF 18
2PPaR-1RPaPat (Fig. 2.34b)
18
2PaRR-1RPaPa (Fig. 2.35a)
18
2PaRR-1RPaPat (Fig. 2.35b)
18
2PaPaR-1RPaPa (Fig. 2.36a)
24
2PaPaR-1RPaPat (Fig. 2.36b)
24
64 65 66 67 68 69 70 71 72
Derived PPM Type NF 2PPassC*-1RPaPa 8 (Fig. 2.90a) 2PPassC*-1RPacsPacs 2 (Fig. 2.93a) 2PPassC*-1RPaPat 8 (Fig. 2.90b) 2PPassC*-1RPacsPatcs 2 (Fig. 2.93b) 2PassRC*-1RPaPa 8 (Fig. 2.91a) 2PassRC*-1RPacsPacs 2 (Fig. 2.94a) 2PassRC*-1RPaPat 8 (Fig. 2.91b) 2PassRC*-1RPacsPatcs 2 (Fig. 2.94b) 2PassPassC*-1RPaPa 6 (Fig. 2.92a) 2PassPassC*-1RPacsPacs 3 (Fig. 2.95a) 2PassPassC*-1RPaPat 6 (Fig. 2.92b) 2PassPassC*-1RPacsPatcs 3 (Fig. 2.95b)
Limb topology P ⊥ Pass||C* R||Pa||Pa P||Pass||C* R||Pacs||Pacs P ⊥ Pass||C* R||Pa||Pat P||Pass||C* R||Pacs||Patcs Pass||R||C* R||Pa||Pa Pass||R||C* R||Pacs||Pacs Pass||R||C* R||Pa||Pat Pass||R||C* R||Pacs||Patcs Pass||Pass||C* R||Pa||Pa Pass||Pass||C* R||Pacs||Pacs Pass||Pass||C* R||Pa||Pat Pass||Pass||C* R||Pacs||Patcs
2.2 Derived solutions
97
Table 2.21. Limb topology and the number of overconstraints NF of the derived PPMs with idle mobilities presented in Figs. 2.96-2.109 No. Basic PPM Type 1 (PRRRP)R-RPP (Fig. 2.37a) 2 3
(RRRRR)R-RPP (Fig. 2.37b)
NF 6
6
4 5
(RPRPR)R-RPP (Fig. 2.37c)
6
6 7
(PRRRP)R-RPPa (Fig. 2.38a)
9
8 9
(RRRRR)R-RPPa (Fig. 2.38b)
9
10 11
(RPRPR)R-RPPa (Fig. 2.38c)
9
12 13
(PRRRP)R-RPaP (Fig. 2.39a)
9
14 15
(RRRRR)R-RPaP (Fig. 2.39b)
9
16 17
(RPRPR)R-RPaP (Fig. 2.39c)
9
18 19 20
(PRRRP)R-RPaPa 12 (Fig. 2.40a)
Derived PPM Type (PRRRP)C*-RPP (Fig. 2.96a) (PS*RS*P)R-RPP (Fig. 2.97a) (RRRRR)C*-RPP (Fig. 2.96b) (RS*RS*R)R-RPP (Fig. 2.97b) (RPRPR)C*-RPP (Fig. 2.96c) (S*PRPS*)R-RPP (Fig. 2.97c) (PRRRP)R-RPPass (Fig. 2.98a) (PS*RS*P)R-RPPa (Fig. 2.101a) (RRRRR)R-RPPass (Fig. 2.98b) (RS*RS*R)R-RPPa (Fig. 2.101b) (RPRPR)R-RPPass (Fig. 2.98c) (S*PRPS*)R-RPPa (Fig. 2.101c) (PRRRP)R-RPassP (Fig. 2.99a) (PS*RS*P)R-RPaP (Fig. 2.102a) (RRRRR)R-RPassP (Fig. 2.99b) (RS*RS*R)R-RPaP (Fig. 2.102b) (RPRPR)R-RPassP (Fig. 2.99c) (S*PRPS*)R-RPaP (Fig. 2.102c) (PRRRP)R-RPassPass (Fig. 2.100a) (PS*RS*P)R-RPaPa (Fig. 2.103a)
NF 5
Limb topology (PRRRP)C* R ⊥ P ⊥⊥ P
2 5
(RRRRR)C* R ⊥ P ⊥⊥ P
2 5 2 6 5 6 5 6 5 6 5 6 5 6 5 6 8
(RPRPR)C* R ⊥ P ⊥⊥ P (S*PRPS*)R R ⊥ P ⊥⊥ P (PRRRP)R R ⊥ P ⊥ ||Pass (PS*RS*P) R ⊥ P ⊥ ||Pa (RRRRR)R R ⊥ P ⊥ ||Pass (RS*RS*R)R R ⊥ P ⊥ ||Pa (RPRPR)R R ⊥ P ⊥ ||Pass (S*PRPS*)R R ⊥ P ⊥ ||Pa PRRRP)R R||Pass ⊥ P (PS*RS*P)R R||Pa ⊥ P (RRRRR)R R||Pass ⊥ P (RS*RS*R)R R||Pa ⊥ P (RPRPR)R R||Pass ⊥ P (S*PRPS*)R R||Pa ⊥ P (PRRRP)R R||Pass||Pass (PS*RS*P)R R||Pa||Pa
98
2 Overconstrained planar parallel robots with coupled motions
Table 2.21. (cont.) 21
(RRRRR)R-RPaPa 12 (Fig. 2.40b)
22 23
(RPRPR)R-RPaPa 12 (Fig. 2.40c)
24 25
(PRRRP)R-RPaPa 12 (Fig. 2.41a)
26 27
(PRRRP)R-RPaPat 12 (Fig. 2.41b)
28 29
(RRRRR)R-RPaPa 12 (Fig. 2.42a)
30 31
(RRRRR)R-RPaPat 12 (Fig. 2.42b)
32 33
(RPRPR)R-RPaPa 12 (Fig. 2.43a)
34 35 36
(RPRPR)R-RPaPat 12 (Fig. 2.43b)
(RRRRR)R-RPassPass (Fig. 2.100b) (RS*RS*R)R-RPaPa (Fig. 2.103b) (RPRPR)R-RPassPass (Fig. 2.100c) (S*PRPS*)R-RPaPa (Fig. 2.103c) (PRRRP)R-RPacsPacs (Fig. 2.104a) (PS*RS*P)R-RPacsPacs (Fig. 2.107a) (PRRRP)R-RPacsPatcs (Fig. 2.104b) (PS*RS*P)R-RPacsPatcs (Fig. 2.107b) (RRRRR)R-RPacsPacs (Fig. 2.105a) (RS*RS*R)R-RPacsPacs (Fig. 2.108a) (RRRRR)R-RPacsPatcs (Fig. 2.105b) (RS*RS*R)R-RPacsPatcs (Fig. 2.108b) (RPRPR)R-RPacsPacs (Fig. 2.106a) (S*PRPS*)R-RPacsPacs (Fig. 2.109a) (RPRPR)R-RPacsPatcs (Fig. 2.106b) (S*PRPS*)R-RPacsPatcs (Fig. 2.109b)
6 8 6 8 6 2 6 2 6 2 6 2 6 2 6 2
RRRRR)R R||Pass||Pass (RS*RS*R)R R||Pa||Pa (RPRPR)R R||Pass||Pass (S*PRPS*)R R||Pa||Pa (PRRRP)R R||Pacs||Pacs (PS*RS*P)R R||Pacs||Pacs (PRRRP)R R||Pacs||Patcs (PS*RS*P)R R||Pacs||Patcs (RRRRR)R R||Pacs||Pacs (RS*RS*R)R R||Pacs||Pacs (RRRRR)R R||Pacs||Patcs (RS*RS*R)R R||Pacs||Patcs (RPRPR)R R||Pacs||Pacs (S*PRPS*)R R||Pacs||Pacs (RPRPR)R R||Pacs||Patcs (S*PRPS*)R R||Pacs||Patcs
2.2 Derived solutions
99
Table 2.22. Structural parametersa of planar parallel mechanisms in Figs. 2.442.46 No. Structural parameter
Solution 3-RR*RR (Fig. 2.44a)
1 2 3 4 5 6 7 8 9 10
11 4 4 4 12 2 3 0 3 See Table 2.14
3-RRC* (Fig. 2.44b) 3-RC*R (Fig. 2.45a) 3-C*RR (Fig. 2.45b) 3-PRC* (Fig. 2.46a) 3-C*RP (Fig. 2.46b) 8 3 3 3 9 2 3 0 3 See Table 2.14
4 4 4 0 0 0 4 4 4 ( v1 , v 2 , 3 0 9 3 3 0 4
4 4 4 0 0 0 4 4 4 ( v1 , v 2 , 3 0 9 3 3 0 4
11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
4
4
fj
4
4
fj
12
12
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
100
2 Overconstrained planar parallel robots with coupled motions
Table 2.23. Structural parametersa of planar parallel mechanisms in Figs. 2.472.49 No. Structural parameter
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 3-PaRS* (Fig. 2.47a) 3-PaS*P (Fig. 2.48b) 3-PaPS* (Fig. 2.49a) 3-PPaS* (Fig. 2.49b) 14 6 6 6 18 5 0 3 3 See Table 2.14
3-PassRR (Fig. 2.47b)
3-PaPaS* (Fig. 2.48a)
14 6 6 6 18 5 0 3 3 See Table 2.14
20 9 9 9 27 8 0 3 3 See Table 2.14
5 5 5 3 3 3 5 5 5 ( v1 , v 2 , 3 9 21 3 9 0 8
3 3 3 6 6 6 4 4 4 ( v1 , v 2 , 3 18 24 6 6 3 10
5 5 5 6 6 6 5 5 5 ( v1 , v 2 , 3 18 30 3 18 0 11
δ
)
δ
)
fj
8
10
11
fj
8
10
11
fj
24
30
33
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
2.2 Derived solutions
101
Table 2.24. Structural parametersa of planar parallel mechanisms in Figs. 2.502.52 No. Structural parameter
Solution 3-PassPassR (Fig. 2.50a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
20 9 9 9 27 8 0 3 3 See Table 2.14
3-PassRP (Fig. 2.50b) 3-PassPR (Fig. 2.51a) 3-PPassR (Fig. 2.51b) 14 6 6 6 18 5 0 3 3 See Table 2.14
8 3 3 3 9 2 3 0 3 See Table 2.14
3 3 3 12 12 12 5 5 5 ( v1 , v 2 , 3 36 42 9 6 6 17
3 3 3 6 6 6 4 4 4 ( v1 , v 2 , 3 18 24 6 6 3 10
4 4 4 0 0 0 4 4 4 ( v1 , v 2 , 3 0 9 3 3 0 4
δ
)
δ
)
3-PC*R (Fig. 2.52)
fj
17
10
4
fj
17
10
4
fj
51
30
12
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
102
2 Overconstrained planar parallel robots with coupled motions
Table 2.25. Structural parametersa of planar parallel mechanisms in Figs. 2.532.56 No. Structural Solution parameter 1PC*R-2RR*RR 1PC*R-2RRC* (Fig. 2.54a) (Fig. 2.53) 1PC*R-2RC*R (Fig. 2.54b) 1C*PR-2C*RR (Fig. 2.55a) 1PC*R-2PRC* (Fig. 2.55b) 1 m 10 8 2 p1 3 3 3 p2 4 3 4 p3 4 3 5 p 11 9 6 q 2 2 7 k1 3 3 8 k2 0 0 9 k 3 3 10 (RGi) See Table 2.14 See Table 2.14 (i=1,2,3) 11 SG1 4 4 12 SG2 4 4 13 SG3 4 4 14 rG1 0 0 15 rG2 0 0 16 rG3 0 0 17 MG1 4 4 18 MG2 4 4 19 MG3 4 4 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 22 rl 0 0 23 rF 9 9 24 MF 3 3 25 NF 3 3 26 TF 0 0 p1 27 4 4 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
1PaPS*-2PaRS* (Fig. 2.56a) 1PaPS*-2PPaS* (Fig. 2.56b) 14 6 6 6 18 5 0 3 3 See Table 2.14 5 5 5 3 3 3 5 5 5 ( v1 , v 2 , 3 9 21 3 9 0 8
j
fj
4
4
8
fj
4
4
8
fj
12
12
24
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
2.2 Derived solutions
103
Table 2.26. Structural parametersa of planar parallel mechanisms in Figs. 2.57 and 2.58 No. Structural Solution parameter 1PaPS*-2PaPaS* (Fig. 2.57a)
1PaPS*-2PaS*P (Fig. 2.57b)
1 2 3 4 5 6 7 8 9 10
18 6 9 9 24 7 0 3 3 See Table 2.14
14 6 6 6 18 5 0 3 3 See Table 2.14
1PassPR-2PassRR (Fig. 2.58a) 1PassPR-2PPassR (Fig. 2.58b) 14 6 6 6 18 5 0 3 3 See Table 2.14
5 5 5 3 6 6 5 5 5 ( v1 , v 2 , 3 15 27 3 15 0 8
5 5 5 3 3 3 5 5 5 ( v1 , v 2 , 3 9 21 3 9 0 8
4 4 4 6 6 6 4 4 4 ( v1 , v 2 , 3 18 27 3 3 0 10
11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
δ
)
fj
11
8
10
fj
11
8
10
fj
30
24
30
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
104
2 Overconstrained planar parallel robots with coupled motions
Table 2.27. Structural parametersa of planar parallel mechanisms in Figs. 2.59 and 2.60 No. Structural Solution parameter 1PassPR-2PaPassR (Fig. 2.59a) 1 m 18 2 p1 6 3 p2 9 4 p3 9 5 p 24 6 q 7 7 k1 0 8 k2 3 9 k 3 10 (RGi) See Table 2.14 (i=1,2,3) 11 SG1 4 12 SG2 4 13 SG3 4 14 rG1 6 15 rG2 9 16 rG3 9 17 MG1 4 18 MG2 4 19 MG3 4 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 24 23 rF 33 24 MF 3 25 NF 9 26 TF 0 p1 27 10 f
1PassPR-2PassRP (Fig. 2.59b) 14 6 6 6 18 5 0 3 3 See Table 2.14
3RR*RR (Fig. 2.60) 11 4 4 4 12 2 3 0 3 See Table 2.14
4 4 4 6 6 6 4 4 4 ( v1 , v 2 , 3 18 27 3 3 0 10
4 4 4 0 0 0 4 4 4 ( v1 , v 2 , 3 0 9 3 3 0 4
28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
δ
)
δ
)
j
fj
13
10
4
fj
13
10
4
fj
36
30
12
See footnote of Table 2.4 for the nomenclature of structural parameters
2.2 Derived solutions
105
Table 2.28. Structural parametersa of planar parallel mechanisms in Figs. 2.612.64 No. Structural Solution parameter 3RC*R (Fig. 2.61a) 2RC*R-1RC*R (Fig. 2.61b) 2RPC*-1RPC* (Fig. 2.62) 1 m 8 2 p1 3 3 p2 3 4 p3 3 5 p 9 6 q 2 7 k1 3 8 k2 0 9 k 3 10 (RGi) See Table 2.14 (i=1,2,3) 11 SG1 4 12 SG2 4 13 SG3 4 14 rG1 0 15 rG2 0 16 rG3 0 17 MG1 4 18 MG2 4 19 MG3 4 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 0 23 rF 9 24 MF 3 25 NF 3 26 TF 0 p1 27 4 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2RC*Pa-1RC*Pa (Fig. 2.63) 2RPaC*-1RPaC* (Fig. 2.64a)
2RPaPass-1RPaPass (Fig. 2.64b)
14 6 6 6 18 5 0 3 3 See Table 2.14
20 9 9 9 27 8 3 0 3 See Table 2.14
4 4 4 3 3 3 4 4 4 ( v1 , v 2 , 3 9 18 3 12 0 7
4 4 4 9 9 9 4 4 4 ( v1 , v 2 , 3 27 36 3 12 0 13
δ
)
fj
4
7
13
fj
4
7
13
fj
12
21
39
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
106
2 Overconstrained planar parallel robots with coupled motions
Table 2.29. Structural parametersa of planar parallel mechanisms in Figs. 2.652.67 No. Structural Solution parameter 2PRC*-1RPP 2PS*R-1RPP 2PPaR-1RC*C* (Fig. 2.65a) (Fig. 2.66a) (Fig. 2.67a) 2RRC*-1RPP 2RS*R-1RPP 2PaRR-1RC*C* (Fig. 2.65b) (Fig. 2.66b) (Fig. 2.67b) 2RPC*-1RPP 2S*PR-1RPP (Fig. 2.65c) (Fig. 2.66c) 1 m 8 8 12 2 p1 3 3 6 3 p2 3 3 6 4 p3 3 3 3 5 p 9 9 15 6 q 2 2 4 7 k1 3 3 2 8 k2 0 0 1 9 k 3 3 3 10 (RGi) See Table 2.14See Table 2.14See Table 2.14 (i=1,2,3) 11 SG1 4 5 3 12 SG2 4 5 3 13 SG3 3 3 5 14 rG1 0 0 3 15 rG2 0 0 3 16 rG3 0 0 0 17 MG1 4 5 3 18 MG2 4 5 3 19 MG3 3 3 5 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 3 22 rl 0 0 6 23 rF 8 10 14 24 MF 3 3 3 25 NF 4 2 10 26 TF 0 0 0 p1 27 4 5 6 f
3 3 5 6 6 0 3 3 5 ( v1 , v 2 , 3 12 20 3 16 0 9
28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PaPaR-1RC*C* (Fig. 2.67c)
16 9 9 3 21 6 2 1 3 See Table 2.14
fj
4
5
6
9
fj
3
3
5
5
fj
11
13
17
23
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
2.2 Derived solutions
107
Table 2.30. Structural parametersa of planar parallel mechanisms in Figs. 2.682.70 No. Structural Solution parameter 2PPassR-1RPP 2PassPassR-1RPP (Fig. 2.68a) (Fig. 2.68c) 2PassRR-1RPP (Fig. 2.68b)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
12 6 6 3 15 4 1 2 3 See Table 2.14
16 9 9 3 21 6 1 2 3 See Table 2.14
2PRC*-1RPPa (Fig. 2.69a) 2RRC*-1RPPa (Fig. 2.69b) 2RPC*-1RPPa (Fig. 2.69c) 2PRC*-1RPaP (Fig. 2.70a) 2RRC*-1RPaP (Fig. 2.70b) 2RPC*-1RPaP (Fig. 2.70c) 10 3 3 6 12 3 2 1 3 See Table 2.14
4 4 3 6 6 0 4 4 3 ( v1 , v 2 , 3 12 20 3 4 0 10
4 4 3 12 12 0 5 5 3 ( v1 , v 2 , 3 24 32 5 4 2 17
4 4 3 0 0 3 4 4 3 ( v1 , v 2 , 3 3 11 3 7 0 4
δ
)
δ
)
fj
10
17
4
fj
3
3
6
fj
23
37
14
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
108
2 Overconstrained planar parallel robots with coupled motions
Table 2.31. Structural parametersa of planar parallel mechanisms in Figs. 2.712.74 No. Structural Solution parameter 2PRC*-1RPaPa (Fig. 2.71a) 2RRC*-1RPaPa (Fig. 2.71b) 2RPC*-1RPaPa (Fig. 2.71c) 1 m 12 2 p1 3 3 p2 3 4 p3 9 5 p 15 6 q 4 7 k1 2 8 k2 1 9 k 3 10 (RGi) See Table 2.14 (i=1,2,3) 11 SG1 4 12 SG2 4 13 SG3 3 14 rG1 0 15 rG2 0 16 rG3 6 17 MG1 4 18 MG2 4 19 MG3 3 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 6 23 rF 14 24 MF 3 25 NF 10 26 TF 0 p1 27 4 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PRR-1RPPass (Fig. 2.72a) 2RRR-1RPPass (Fig. 2.72b) 2RPR-1RPPass (Fig. 2.72c) 2PRR-1RPassP (Fig. 2.73a) 2RRR-1RPassP (Fig. 2.73b) 2RPR-1RPassP (Fig. 2.73c) 10 3 3 6 12 3 2 1 3 See Table 2.14
2PRR-1RPassPass (Fig. 2.74a) 2RRR-1RPassPass (Fig. 2.74b) 2RPR-1RPassPass (Fig. 2.74c) 12 3 3 9 15 4 2 1 3 See Table 2.14
3 3 3 0 0 6 3 3 4 ( v1 , v 2 , 3 6 12 4 6 1 3
3 3 3 0 0 12 3 3 5 ( v1 , v 2 , 3 12 18 5 6 2 3
δ
)
fj
4
3
3
fj
9
10
17
fj
17
16
23
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
2.2 Derived solutions
109
Table 2.32. Structural parametersa of planar parallel mechanisms in Figs. 2.752.78 No. Structural Solution parameter 2PPaC*-1RPPa (Fig. 2.75a) 2PaRC*-1RPPa (Fig. 2.75b) 2PPaC*-1RpaP (Fig. 2.76a) 2PaRC*-1RPaP (Fig. 2.76b) 1 m 14 2 p1 6 3 p2 6 4 p3 6 5 p 18 6 q 5 7 k1 0 8 k2 3 9 k 3 10 (RGi) See Table 2.14 (i=1,2,3) 11 SG1 4 12 SG2 4 13 SG3 3 14 rG1 3 15 rG2 3 16 rG3 3 17 MG1 4 18 MG2 4 19 MG3 3 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 9 23 rF 17 24 MF 3 25 NF 13 26 TF 0 p1 27 7 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
2PaPaC*-1RPPa 2PPaC*-1RPaPa (Fig. 2.77a) (Fig. 2.78a) 2PaPaC*-1RPaP 2PaRC*-1RPaPa (Fig. 2.77b) (Fig. 2.78b) 18 16 9 6 9 6 6 9 24 21 7 6 0 0 3 3 3 3 See Table 2.14 See Table 2.14 4 4 3 6 6 3 4 4 3 ( v1 , v 2 , 3 15 23 3 19 0 10
δ
)
4 4 3 3 3 6 4 4 3 ( v1 , v 2 , 3 12 20 3 16 0 7
j
fj
7
10
7
fj
6
6
9
fj
20
26
23
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
110
2 Overconstrained planar parallel robots with coupled motions
Table 2.33. Structural parametersa of planar parallel mechanisms in Figs. 2.792.81 No. Structural Solution parameter 2PaPaC*-1RPaPa 2PassPassR-1RPassPass 2PPassR-1RPPass (Fig. 2.79a) 2PassRR-1RPPass (Fig. 2.79b) (Fig. 2.80a,b) 2PPassR-1RPassP 2PassRR-1RPassP (Fig. 2.81a,b) 1 m 20 20 14 2 p1 9 9 6 3 p2 9 9 6 4 p3 9 9 6 5 p 27 27 18 6 q 8 8 5 7 k1 0 0 0 8 k2 3 3 3 9 k 3 3 3 10 (RGi) See Table 2.14 See Table 2.14 See Table 2.14 (i=1,2,3) 11 SG1 4 4 4 12 SG2 4 4 4 13 SG3 3 5 4 14 rG1 6 12 6 15 rG2 6 12 6 16 rG3 6 12 6 17 MG1 4 5 4 18 MG2 4 5 4 19 MG3 3 5 4 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 3 22 rl 18 36 18 23 rF 26 46 27 24 MF 3 5 3 25 NF 22 2 3 26 TF 0 2 0 p1 27 10 17 10 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
fj
10
17
10
fj
9
17
10
fj
29
51
30
See footnote of Table 2.4 for the nomenclature of structural parameters
2.2 Derived solutions
111
Table 2.34. Structural parametersa of planar parallel mechanisms in Figs. 2.822.86 No. Structural Solution parameter 2PassPassR1RPPass (Fig. 2.82a) 2PassPassR1RPassP (Fig. 2.82b) 1 m 18 2 p1 9 3 p2 9 4 p3 6 5 p 24 6 q 7 7 k1 0 8 k2 3 9 k 3 10 (RGi) See Table 2.14 (i=1,2,3) 11 SG1 4 12 SG2 4 13 SG3 4 14 rG1 12 15 rG2 12 16 rG3 6 17 MG1 5 18 MG2 5 19 MG3 4 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 30 23 rF 39 24 MF 5 25 NF 3 26 TF 2 p1 27 17 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PPassR1RPassPass (Fig. 2.83a) 2PassRR1RPassPass (Fig. 2.83b) 16 6 6 9 21 6 0 3 3 See Table 2.14
2PRC*-1RPacsPacs (Fig. 2.84a) 2PRC*-1RPacsPatcs (Fig. 2.84b) 2RRC*-1RPacsPacs (Fig. 2.85a) 2RRC*-1RPacsPatcs (Fig. 2.85b) 2RPC*-1RPacsPacs (Fig. 2.86a) 2RPC*-1RPacsPatcs (Fig. 2.86b) 12 3 3 9 15 4 2 1 3 See Table 2.14
4 4 5 6 6 12 4 4 5 ( v1 , v 2 , 3 24 34 3 2 0 10
4 4 3 0 0 12 4 4 3 ( v1 , v 2 , 3 12 20 3 4 0 4
δ
)
fj
17
10
4
fj
10
17
15
fj
44
37
23
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
112
2 Overconstrained planar parallel robots with coupled motions
Table 2.35. Structural parametersa of planar parallel mechanisms in Figs. 2.872.91 No. Structural Solution parameter 2PS*R-1RPacsPacs (Fig. 2.87a) 2PS*R-1RPacsPatcs (Fig. 2.87b) 2RS*R-1RPacsPacs (Fig. 2.88a) 2RS*R-1RPacsPatcs (Fig. 2.88b) 2S*PR-1RPacsPacs (Fig. 2.89a) 2S*PR-1RPacsPatcs (Fig. 2.89b) 1 m 12 2 p1 3 3 p2 3 4 p3 9 5 p 15 6 q 4 7 k1 2 8 k2 1 9 k 3 10 (RGi) See Table 2.14 (i=1,2,3) 11 SG1 5 12 SG2 5 13 SG3 3 14 rG1 0 15 rG2 0 16 rG3 12 17 MG1 5 18 MG2 5 19 MG3 3 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 12 23 rF 22 24 MF 3 25 NF 2 26 TF 0 p1 27 5 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PPassC*-1RPaPa (Fig. 2.90a) 2PPassC*-1RPaPat (Fig. 2.90b) 2PassRC*-1RPaPa (Fig. 2.91a) 2PassRC*-1RPaPat (Fig. 2.91b)
16 6 6 9 21 6 0 3 3 See Table 2.14 5 5 3 6 6 6 5 5 3 ( v1 , v 2 , 3 18 28 3 8 0 11
fj
5
11
fj
15
9
fj
25
31
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
2.2 Derived solutions
113
Table 2.36. Structural parametersa of planar parallel mechanisms in Figs. 2.922.95 No. Structural Solution parameter 2PassPassC*- 2PPassC*-1RPacsPacs (Fig. 2.93a) 1RPaPa 2PPassC*-1RPacsPatcs (Fig. 2.93b) (Fig. 2.92a) 2PassRC*-1RPacsPacs (Fig. 2.94a) 2PassPassC*- 2PassRC*-1RPacsPatcs (Fig. 2.94b) 1RPaPat (Fig. 2.92b) 1 m 20 16 2 p1 9 6 3 p2 9 6 4 p3 9 9 5 p 27 21 6 q 8 6 7 k1 0 0 8 k2 3 3 9 k 3 3 10 (RGi) See Table 2.14See Table 2.14 (i=1,2,3) 11 SG1 6 5 12 SG2 6 5 13 SG3 3 3 14 rG1 12 6 15 rG2 12 6 16 rG3 6 12 17 MG1 6 5 18 MG2 6 5 19 MG3 3 3 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 22 rl 30 24 23 rF 42 34 24 MF 3 3 25 NF 6 2 26 TF 0 0 p1 27 18 11 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PassPassC*1RPacsPacs (Fig. 2.95a) 2PassPassC*1RPacsPatcs (Fig. 2.95b) 20 9 9 9 27 8 0 3 3 See Table 2.14 6 6 3 12 12 9 6 6 3 ( v1 , v 2 , 3 33 45 3 3 0 18
fj
18
11
18
fj
9
15
12
fj
45
37
48
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
114
2 Overconstrained planar parallel robots with coupled motions
Table 2.37. Structural parametersa of planar parallel mechanisms in Figs. 2.96 and 2.97 No. Structural Solution parameter (PRRRP)C*-RPP (Fig. 2.96a) (RRRRR)C*-RPP (Fig. 2.96b) (RPRPR)C*-RPP (Fig. 2.96c) 1 m 8 2 p1 6 3 p2 3 4 p 9 5 q 2 6 k1 1 7 k2 1 8 k 2 9 (RG1-G2) ( v1 , v 2 , v 3 , δ ) 10
(RG3)
11 12 13 14 15 16 17
SG1-G2 SG3 rG1-G2 rG3 MG1-G2 MG3 (RF)
18 19 20 21 22 23 24
SF rl rF MF NF TF
25 26 a
∑ ∑ ∑
p1 j =1 p2 j =1 p j =1
fj
( v1 , v 2 , 4 3 3 0 4 3 ( v1 , v 2 , 3 3 7 3 5 0 7
δ
)
δ
)
(PS*RS*P)R-RPP (Fig. 2.97a) (RS*RS*R)R-RPP (Fig. 2.97b) (S*PRPS*)R-RPP (Fig. 2.97c) 8 6 3 9 2 1 1 2 ( v1 , v 2 , β , δ ) ( v1 , v 2 , 4 3 6 0 4 3 ( v1 , v 2 , 3 6 10 3 2 0 10
fj
3
3
fj
10
13
δ
)
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
2.2 Derived solutions
115
Table 2.38. Structural parametersa of planar parallel mechanisms in Figs. 2.982.100 No. Structural Solution parameter (PRRRP)R-RPPass (Fig. 2.98a) (RRRRR)R-RPPass (Fig. 2.98b) (RPRPR)R-RPPass (Fig. 2.98c) PRRRP)R-RPassP (Fig. 2.99a) (RRRRR)R-RPassP (Fig. 2.99b) (RPRPR)R-RPassP (Fig. 2.99c) 1 m 10 2 p1 6 3 p2 6 4 p 12 5 q 3 6 k1 0 7 k2 2 8 k 2 9 (RG1-G2) ( v1 , v 2 , δ ) 10 (RG3) ( v1 , v 2 , δ ) 11 SG1-G2 3 12 SG3 3 13 rG1-G2 3 14 rG3 6 15 MG1-G2 3 16 MG3 4 17 (RF) ( v1 , v 2 , δ ) 18 SF 3 19 rl 9 20 rF 12 21 MF 4 22 NF 6 23 TF 1 p1 24 6 f
(PRRRP)R-RPassPass (Fig. 2.100a) (RRRRR)R-RPassPass (Fig. 2.100b) (RPRPR)R-RPassPass (Fig. 2.100c) 12 6 9 15 4 0 2 2 ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 3 3 3 12 3 5 ( v1 , v 2 , δ ) 3 15 18 5 6 2 6
25 26 a
∑ ∑ ∑
j =1
p2 j =1 p j =1
j
fj
10
17
fj
16
23
See footnote of Table 2.4 for the nomenclature of structural parameters
116
2 Overconstrained planar parallel robots with coupled motions
Table 2.39. Structural parametersa of planar parallel mechanisms in Figs. 2.1012.103 No. Structural Solution parameter (PS*RS*P)R-RPPa (Fig. 2.101a) (RS*RS*R)R-RPPa (Fig. 2.101b) (S*PRPS*)R-RPPa (Fig. 2.101c) (PS*RS*P)R-RPaP (Fig. 2.102a) (RS*RS*R)R-RPaP (Fig. 2.102b) (S*PRPS*)R-RPaP (Fig. 2.102c) 1 m 10 2 p1 6 3 p2 6 4 p 12 5 q 3 6 k1 0 7 k2 2 8 k 2 9 (RG1-G2) ( v1 , v 2 , β , δ ) 10
(RG3)
11 12 13 14 15 16 17
SG1-G2 SG3 rG1-G2 rG3 MG1-G2 MG3 (RF)
18 19 20 21 22 23 24
SF rl rF MF NF TF
25 26 a
∑ ∑ ∑
p1 j =1 p2 j =1 p j =1
fj
( v1 , v 2 , 4 3 6 3 4 3 ( v1 , v 2 , 3 9 13 3 5 0 10
δ
)
δ
)
(PS*RS*P)R-RPaPa (Fig. 2.103a) (RS*RS*R)R-RPaPa (Fig. 2.103b) (S*PRPS*)R-RPaPa (Fig. 2.103c) 12 6 9 15 4 0 2 2 ( v1 , v 2 , β , δ ) ( v1 , v 2 , 4 3 6 6 4 3 ( v1 , v 2 , 3 12 16 3 8 0 10
fj
6
9
fj
16
19
δ
)
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
2.2 Derived solutions
117
Table 2.40. Structural parametersa of planar parallel mechanisms in Figs. 2.1042.109 No. Structural Solution parameter (PRRRP)R-RPacsPacs (Fig. 2.104a) (PRRRP)R-RPacsPatcs (Fig. 2.104b) (RRRRR)R-RPacsPacs (Fig. 2.105a) (RRRRR)R-RPacsPatcs (Fig. 2.105b) (RPRPR)R-RPacsPacs (Fig. 2.106a) (RPRPR)R-RPacsPatcs (Fig. 2.106b) 1 m 12 2 p1 6 3 p2 9 4 p 15 5 q 4 6 k1 0 7 k2 2 8 k 2 9 (RG1-G2) ( v1 , v 2 , δ ) 10
(RG3)
11 12 13 14 15 16 17
SG1-G2 SG3 rG1-G2 rG3 MG1-G2 MG3 (RF)
18 19 20 21 22 23 24
SF rl rF MF NF TF
25 26 a
∑ ∑ ∑
p1 j =1 p2 j =1 p j =1
fj
( v1 , v 2 , 3 3 3 12 3 3 ( v1 , v 2 , 3 15 18 3 6 0 6
δ
)
δ
)
(PS*RS*P)R-RPacsPacs (Fig. 2.107a) (PS*RS*P)R-RPacsPatcs (Fig. 2.107b) (RS*RS*R)R-RPacsPacs (Fig. 2.108a) (RS*RS*R)R-RPacsPatcs (Fig. 2.108b) (S*PRPS*)R-RPacsPacs (Fig. 2.109a) (S*PRPS*)R-RPacsPatcs (Fig. 2.109b) 12 6 9 15 4 0 2 2 ( v1 , v 2 , β , δ ) ( v1 , v 2 , 4 3 6 12 4 3 ( v1 , v 2 , 3 18 22 3 2 0 10
fj
9
15
fj
15
25
δ
)
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
118
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.44. Overconstrained PPMs with coupled motions of types 3-RR*RR (a) and 3-RRC* (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R ⊥ R* ⊥ ||R||R (a) and R||R ⊥ C* (b)
2.2 Derived solutions
119
Fig. 2.45. Overconstrained PPMs with coupled motions of types 3-RC*R (a) and 3-C*RR (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R ⊥ C* ⊥ ||R (a) and C* ⊥ R||R (b)
120
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.46. Overconstrained PPMs with coupled motions of types 3-PRC* (a) and 3-C*RP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology P ⊥ R ⊥ C* (a) and C* ⊥ R ⊥ P (b)
2.2 Derived solutions
121
Fig. 2.47. Overconstrained PPMs with coupled motions of types 3-PaRS* (a) and 3-PassRR (b) defined by SF=3, (RF)=( v1 , v2 , δ ) and MF=3, NF=9, TF=0 (a), MF=6, NF=6, TF=3 (b), limb topology Pa||RS* (a) and Pass||R||R (b)
122
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.48. Overconstrained PPMs with coupled motions of types 3-PaPaS* (a) and 3-PaS*P (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=18 (a), NF=9 (b), limb topology Pa||PaS* (a) and PaS*P (b)
2.2 Derived solutions
123
Fig. 2.49. Overconstrained PPMs with coupled motions of types 3-PaPS* (a) and 3-PPaS* (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9, limb topology Pa ⊥ PS* (a) and P ⊥ PaS* (b)
124
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.50. Overconstrained PPMs with coupled motions of types 3-PassPassR (a) and 3-PassRP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=6 and MF=9, TF=6 (a) MF=6, TF=3 (a), limb topology Pass||Pass||R (a) and Pass||R ⊥ P (b)
2.2 Derived solutions
125
Fig. 2.51. Overconstrained PPMs with coupled motions of types 3-PassPR (a) and 3-PPassR (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=6, TF=3, limb topology Pass ⊥ P ⊥ ||R (a) and P ⊥ Pass||R (b)
126
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.52. Overconstrained PPM with one decoupled translation of type 3-PC*R defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology P ⊥ C* ⊥ ⊥ R
Fig. 2.53. Overconstrained PPM with one decoupled translation of type 1PC*R2RR*RR defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology P ⊥ C* ⊥ ⊥ R and R ⊥ R* ⊥ ||R||R
2.2 Derived solutions
127
Fig. 2.54. Overconstrained PPMs with one decoupled translation of types 1PC*R2RRC* (a) and 1PC*R-2RC*R (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology P ⊥ C* ⊥ ⊥ R and R||R ⊥ C* (a), P ⊥ C* ⊥ ⊥ R and R ⊥ C* ⊥ ||R (b)
128
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.55. Overconstrained PPMs with one decoupled translation of types 1C*PR2C*RR (a) and 1PC*R-2PRC* (b) defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=3, limb topology P ⊥ C* ⊥ ⊥ R and C* ⊥ R||R (a), P ⊥ C* ⊥ ⊥ R and P ⊥ R ⊥ C* (b)
2.2 Derived solutions
129
Fig. 2.56. Overconstrained PPMs with one decoupled translation of types 1PaPS*-2PaRS* (a) and 1PaPS*-2PPaS* (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9, limb topology Pa ⊥ PS* and Pa||RS* (a), Pa ⊥ PS* and P ⊥ PaS* (b)
130
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.57. Overconstrained PPMs with one decoupled translation of types 1PaPS*-2PaPaS* (a) and 1PaPS*-2PaS*P (b) defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=15 (a), NF=9 (b), limb topology Pa ⊥ PS* and Pa||PaS* (a), Pa ⊥ PS* and PaS*P (b)
2.2 Derived solutions
131
Fig. 2.58. Overconstrained PPMs with one decoupled translation of types 1PassPR-2PassRR (a) and 1PassPR-2PPassR (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology Pass ⊥ P ⊥ ||R and Pass||R||R (a), Pass ⊥ P ⊥ ||R and P ⊥ Pass||R (b)
132
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.59. Overconstrained PPMs with one decoupled translation of types 1PassPR-2PaPassR (a) and 1PassPR-2PassRP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9 (a), NF=3 (b), limb topology Pass ⊥ P ⊥ ||R and Pa||Pass||R (a), Pass ⊥ P ⊥ ||R and Pass||R ⊥ P (b)
2.2 Derived solutions
133
Fig. 2.60. 3RR*RR-type overconstrained PPMs with partially decoupled translations defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=3, limb topology R ⊥ R* ⊥ ||R||R
134
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.61. Overconstrained PPMs with partially decoupled translations of types 3RC*R (a) and 2RC*R-1RC*R (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R ⊥ C* ⊥ ||R (a), R ⊥ C* ⊥ ||R and R ⊥ C* ⊥ ||R (b)
2.2 Derived solutions
135
Fig. 2.62. Overconstrained PPM with decoupled rotation of type 2RPC*-1RPC* defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R ⊥ P ⊥ ⊥ C*
Fig. 2.63. Overconstrained PPM with decoupled rotation of type 2RC*Pa1RC*Pa defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12, limb topology R ⊥ C* ⊥ ||Pa
136
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.64. Overconstrained PPMs with decoupled rotation of types 2RPaC*1RPaC* (a) and 2RPaPass-1RPaPass (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12, limb topology R||Pa ⊥ C* (a) and R||Pa||Pass (b)
2.2 Derived solutions
137
Fig. 2.65. Overconstrained PPMs with uncoupled rotation of types 2PRC*-1RPP (a), 2RRC*-1RPP (b) and 2RPC*-1RPP (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=4, limb topology R ⊥ P ⊥ ⊥ P and P ⊥ R||C* (a), R||R||C* (b), R ⊥ P ⊥ ||C* (c)
138
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.66. Overconstrained PPMs with uncoupled rotation of types 2PS*R-1RPP (a), 2RS*R-1RPP (b) and 2S*PR-1RPP (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology R ⊥ P ⊥ ⊥ P and PS*R (a), RS*R (b), SP ⊥ R (c)
2.2 Derived solutions
139
Fig. 2.67. Overconstrained PPMs with uncoupled rotation of types 2PPaR1RC*C* (a), 2PaRR-1RC*C* (b) and 2PaPaR-1RC*C* (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=10 (a), (b) NF=16 (c), limb topology R ⊥ C* ⊥ ⊥ C* and P ⊥ Pa||R (a), Pa||R||R (b), Pa||Pa||R (c)
140
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.68. Overconstrained PPMs with uncoupled rotation of types 2PPassR-1RPP (a), 2PassRR-1RPP (b) and 2PassPassR-1RPP (c) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=4 and MF=3, TF=0 (a and b), MF=5, TF=2 (c), limb topology R ⊥ P ⊥ ⊥ P and P ⊥ Pass||R (a), Pass||R||R (b), Pass||Pass||R (c)
2.2 Derived solutions
141
Fig. 2.69. Overconstrained PPMs with uncoupled rotation of types 2PRC*-1RPPa (a), 2RRC*-1RPPa (b) and 2RPC*-1RPPa (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=7, limb topology R ⊥ P ⊥ ||Pa and P ⊥ R||C* (a), R||R||C* (b), R ⊥ P ⊥ ||C* (c)
142
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.70. Overconstrained PPMs with uncoupled rotation of types 2PRC*-1RPaP (a), 2RRC*-1RPaP (b) and 2RPC*-1RPaP (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=7, limb topology R||Pa ⊥ P and P ⊥ R||C* (a), R||R||C* (b), R ⊥ P ⊥ ||C* (c)
2.2 Derived solutions
143
Fig. 2.71. Overconstrained PPMs with uncoupled rotation of types 2PRC*1RPaPa (a), 2RRC*-1RPaPa (b) and 2RPC*-1RPaPa (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=10, limb topology R||Pa||Pa and P ⊥ R||C* (a), R||R||C* (b), R ⊥ P ⊥ ||C* (c)
144
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.72. Overconstrained PPMs with uncoupled rotation of types 2PRR-1RPPass (a), 2RRR-1RPPass (b) and 2RPR-1RPPass (c) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=6, TF=1, limb topology R ⊥ P ⊥ ||Pass and P ⊥ R||R (a), R||R||R (b), R ⊥ P ⊥ ||R (c)
2.2 Derived solutions
145
Fig. 2.73. Overconstrained PPMs with uncoupled rotation of types 2PRR-1RPassP (a), 2RRR-1RPassP (b) and 2RPR-1RPassP (c) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4 NF=6, TF=1, limb topology R||Pass ⊥ P and P ⊥ R||R (a), R||R||R (b), R ⊥ P ⊥ ||R (c)
146
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.74. Overconstrained PPMs with uncoupled rotation of types 2PRR1RPassPass (a), 2RRR-1RPassPass (b) and 2RPR-1RPassPass (c) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=6, TF=2, limb topology R||Pass||Pass and P ⊥ R||R (a), R||R||R (b), R ⊥ P ⊥ ||R (c)
2.2 Derived solutions
147
Fig. 2.75. Overconstrained PPMs with uncoupled rotation of types 2PPaC*1RPPa (a) and 2PaRC*-1RPPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=13, limb topology R ⊥ P ⊥ ||Pa and P ⊥ Pa||C* (a), Pa||R||C* (b)
148
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.76. Overconstrained PPMs with uncoupled rotation of types 2PPaC*1RPaP (a) and 2PaRC*-1RPaP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=13, limb topology R||Pa ⊥ P and P ⊥ Pa||C* (a), Pa||R||C* (b)
2.2 Derived solutions
149
Fig. 2.77. Overconstrained PPMs with uncoupled rotation of types 2PaPaC*1RPPa (a) and 2PaPaC*-1RPaP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=19, limb topology Pa||Pa||C* and R ⊥ P ⊥ ||Pa (a), R||Pa ⊥ P (b)
150
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.78. Overconstrained PPMs with uncoupled rotation of types 2PPaC*1RPaPa (a) and 2PaRC*-1RPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=16, limb topology R||Pa||Pa and P ⊥ Pa||C* (a), Pa||R||C* (b)
2.2 Derived solutions
151
Fig. 2.79. Overconstrained PPMs with uncoupled rotation of types 2PaPaC*1RPaPa (a) and 2PassPassR-1RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ) and MF=3, NF=22, TF=0 (a), MF=5, NF=2, TF=2 (b), limb topology Pa||Pa||C* and R||Pa||Pa (a), Pass||Pass||R and R||Pass||Pass (b)
152
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.80. Overconstrained PPMs with uncoupled rotation of types 2PPassR1RPPass (a) and 2PassRR-1RPPass (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R ⊥ P ⊥ ||Pass and P ⊥ Pass||R (a), Pass||R||R (b)
2.2 Derived solutions
153
Fig. 2.81. Overconstrained PPMs with uncoupled rotation of types 2PPassR1RPassP (a) and 2PassRR-1RPassP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R ⊥ Pass ⊥ ||P and P ⊥ Pass||R (a), Pass||R||R (b)
154
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.82. Overconstrained PPMs with uncoupled rotation of types 2PassPassR 1RPPass (a) and 2PassPassR-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=3, TF=2, limb topology Pass||Pass||R and R ⊥ P ⊥ ||Pass (a), R||Pass ⊥ P (b)
2.2 Derived solutions
155
Fig. 2.83. Overconstrained PPMs with uncoupled rotation of types 2PPassR1RPassPass (a) and 2PassRR-1RPassPass (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology R||Pass||Pass and P ⊥ Pass||R (a), Pass||R||R (b)
156
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.84. Overconstrained PPMs with uncoupled rotation of types 2PRC*1RPacsPacs (a) and 2PRC*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=4, limb topology P ⊥ R||C* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
2.2 Derived solutions
157
Fig. 2.85. Overconstrained PPMs with uncoupled rotation of types 2RRC*1RPacsPacs (a) and 2RRC*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=4, limb topology R||R||C* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
158
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.86. Overconstrained PPMs with uncoupled rotation of types 2RPC*1RPacsPacs (a) and 2RPC*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=4, limb topology R ⊥ P ⊥ ||C* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
2.2 Derived solutions
159
Fig. 2.87. Overconstrained PPMs with uncoupled rotation of types 2PS*R1RPacsPacs (a) and 2PS*R-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology PS*R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
160
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.88. Overconstrained PPMs with uncoupled rotation of types 2RS*R1RPacsPacs (a) and 2RS*R-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology RS*R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
2.2 Derived solutions
161
Fig. 2.89. Overconstrained PPMs with uncoupled rotation of types 2S*PR1RPacsPacs (a) and 2S*PR-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology S*P ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
162
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.90. Overconstrained PPMs with uncoupled rotation of types 2PPassC*1RPaPa (a) and 2PPassC*-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=8, limb topology P ⊥ Pass||C* and R||Pa||Pa (a), R||Pa||Pat (b)
2.2 Derived solutions
163
Fig. 2.91. Overconstrained PPMs with uncoupled rotation of types 2PassRC*1RPaPa (a) and 2PassRC*-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=8, limb topology Pass||R||C* and R||Pa||Pa (a), R||Pa||Pat (b)
164
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.92. Overconstrained PPMs with uncoupled rotation of types 2PassPassC*1RPaPa (a) and 2PassPassC*-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology Pass||Pass||C* and R||Pa||Pa (a), R||Pa||Pat (b)
2.2 Derived solutions
165
Fig. 2.93. Overconstrained PPMs with uncoupled rotation of types 2PPassC*1RPacsPacs (a) and 2PPassC*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology P||Pass||C* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
166
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.94. Overconstrained PPMs with uncoupled rotation of types 2PassRC*1RPacsPacs (a) and 2PassRC*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology Pass||R||C*and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
2.2 Derived solutions
167
Fig. 2.95. Overconstrained PPMs with uncoupled rotation of types 2PassPassC*1RPacsPacs (a) and 2PassPassC*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology Pass||Pass||C*and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
168
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.96. Overconstrained PPMs with uncoupled rotation of types (PRRRP)C*RPP (a), (RRRRR)C*-RPP (b) and (RPRPR)C*-RPP (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=5
2.2 Derived solutions
169
Fig. 2.97. Overconstrained PPMs with uncoupled rotation of types (PS*RS*P)RRPP (a), (RS*RS*R)R-RPP (b) and (S*PRPS*)R-RPP (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2
170
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.98. Overconstrained PPMs with uncoupled rotation of types (PRRRP)RRPPass (a), (RRRRR)R-RPPass (b) and (RPRPR)R-RPPass (c) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=6, TF=1
2.2 Derived solutions
171
Fig. 2.99. Overconstrained PPMs with uncoupled rotation of types (PRRRP)RRPassP (a), (RRRRR)R-RPassP (b) and (RPRPR)R-RPassP (c) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=6, TF=1
172
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.100. Overconstrained PPMs with uncoupled rotation of types (PRRRP)RRPassPass (a), (RRRRR)R-RPassPass (b) and (RPRPR)R-RPassPass (c) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=6, TF=2
2.2 Derived solutions
173
Fig. 2.101. Overconstrained PPMs with uncoupled rotation of types (PS*RS*P)RRPPa (a), (RS*RS*R)R-RPPa (b) and (S*PRPS*)R-RPPa (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=5
174
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.102. Overconstrained PPMs with uncoupled rotation of types (PS*RS*P)RRPaP (a), (RS*RS*R)R-RPaP (b) and (S*PRPS*)R-RPaP (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=5
2.2 Derived solutions
175
Fig. 2.103. Overconstrained PPMs with uncoupled rotation of types (PS*RS*P)RRPaPa (a), (RS*RS*R)R-RPaPa (b) and (S*PRPS*)R-RPaPa (c) defined by MF=SF=3, (RF)=( v1 , v 2 , δ ), TF=0, NF=8
176
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.104. Overconstrained PPMs with uncoupled rotation of types (PRRRP)RRPacsPacs (a) and (PRRRP)R-RPacsPatcs (b) defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=6
2.2 Derived solutions
177
Fig. 2.105. Overconstrained PPMs with uncoupled rotation of types (RRRRR)RRPacsPacs (a) and (RRRRR)R-RPacsPatcs (b) defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=6
178
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.106. Overconstrained PPMs with uncoupled rotation of types (RPRPR)RRPacsPacs (a) and (RPRPR)R-RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6
2.2 Derived solutions
179
Fig. 2.107. Overconstrained PPMs with uncoupled rotation of types (PS*RS*P)RRPacsPacs (a) and (PS*RS*P)R-RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2
180
2 Overconstrained planar parallel robots with coupled motions
Fig. 2.108. Overconstrained PPMs with uncoupled rotation of types (RS*RS*R)RRPacsPacs (a) and (RS*RS*R)R-RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2
2.2 Derived solutions
181
Fig. 2.109. Overconstrained PPMs with uncoupled rotation of types (S*PRPS*)RRPacsPacs (a) and (S*PRPS*)R-RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2
3 Non overconstrained planar parallel robots with coupled motions
Equation (1.15) indicates that non overconstrained solutions of planar parallel robots with coupled motions and q independent loops meet the p condition ∑ 1 f i = 3 + 6q . Various solutions fulfil this condition along with SF=3, (RF)=( v1 ,v2 ,ωδ ) and NF=0. They can have identical limbs or limbs with different structures and may be actuated by linear or rotating motors. These solutions are derived from the overconstrained counterparts presented in Figs. 2.4-2.43 by introducing the required idle mobilities. They can be fully- or not fully-parallel solutions with the actuators mounted on the base or on a moving link.
3.1 Fully-parallel solutions The fully-parallel non overconstrained solutions presented in Figs. 3.13.32 are derived from the solutions in Figs. 2.4-2.36 by introducing the required idle mobilities. Attention must be paid when introducing the idle mobilities so as not to modify the mobility of the parallel mechanism and the connectivity of the moving platform. The idle mobilities can be introduced outside or inside the loops combined in the limbs. For example, the non overconstrained solutions in Fig. 3.1 are derived from the overconstrained solutions in Fig. 2.4 by introducing two rotational idle mobilities in each spherical joint. They are introduced by replacing one revolute joint in each limb of the solutions in Fig. 2.4 by a spherical joint. We recall that the notation Pacs is associated with a parallelogram loop with three idle mobilities combined in a cylindrical and a spherical joint, and Pass with four idle mobilities combined in two spherical joints adjacent to the same link. In the cylindrical joints of the parallelogram loop denoted by Pacs (Figs. 3.28-3.33 and 3.38-3.40) the translational motion is an idle mobility. In the parallelogram loop Pass-type, three idle mobilities are introduced in the loop and one outside the loop. If the link adjacent to the G. Gogu, Structural Synthesis of Parallel Robots, Solid Mechanics and Its Applications 173, DOI 10.1007/978-90-481-9831-3_3, © Springer Science + Business Media B.V. 2010
183
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3 Non overconstrained planar parallel robots with coupled motions
two spherical joints is a binary link than the idle mobility introduced outside the loop becomes an internal rotational mobility of the binary link around the axis passing by the centre of the two spherical joints. This internal mobility gives one degree of structural redundancy (see Table 3.1). If the link adjacent to the two spherical joints is connected in the limb by three or more joints (polinary link) than the rotational motion around the axis passing by the centre of the two spherical joints is an idle (potential) mobility of the limb. This mobility is restricted by the constraints of the parallel mechanism and remains just a potential mobility. For example in Fig. 3.27, this rotational motion is internal mobility of links 3C and 6C, and idle mobility for the ternary links 4A, 7A and 4B, 7B. The limb topology of the non overconstrained solutions (NF=0) in Figs. 3.1-3.32 are systematized in Tables 3.2-3.5, as are their structural parameters in Tables 3.7-3.14. The bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms in Figs. 3.1-3.32 are given in Table 3.6. Table 3.1. Links with internal mobilities and the degree of structural redundancy TF of overconstrained SPMs with uncoupled planar motion of the moving platform No. Parallel mechanism Example
TF
Link with internal rotational mobility in limb G1 G2 G3
1 2
6 3
3A, 6 A 3A
3 B, 6B 3B
3 C, 6C 3C
3 3 5 1 1 2 1
4A 3A 3A -
4B 4B 3 B, 6B -
4C 4C 3 C, 6C 5C 4C 3 C, 6C 3C
3 4 5 6 7 8 9
Fig. 3.4a Figs. 3.4b, 3.5a, 3.6, 3.11a, 3.12b Fig. 3.5b Fig. 3.11b Fig. 3.12a Fig. 3.20, 3.23 Fig. 3.21, 3.24a Fig. 3.22, 3.26, 3.27 Fig. 3.24b, 3.25
3.1 Fully-parallel solutions
185
Table 3.2. Limb topology of the non overconstrained PPMs with idle mobilities presented in Figs. 3.1-3.11 No. Basic PPM Type 1 3-RRR (Fig. 2.4a) 2 3-RRP (Fig. 2.4b) 3 3-RPR (Fig. 2.5a) 4 3-PRR (Fig. 2.5b) 5 3-PRP (Fig. 2.6) 6 7 8 9 10 11 12 13
3-PaPaR (Fig. 2.7) 3-PaRR (Fig. 2.8a) 3-PaRP (Fig. 2.8b) 3-PaPR (Fig. 2.9a) 3-PPaR (Fig. 2.9b) 3-PPR (Fig. 2.10) 1PPR-2RRR (Fig. 2.11)
NF 6 6 6 6 6
24 15 15 15 15 6 6
14 15 16 17 18 19 20
1PPR-2RRP (Fig. 2.12a) 1PPR-2RPR (Fig. 2.12b) 1PPR-2PRR (Fig. 2.13a) 1PPR-2PRP (Fig. 2.13b) 1PaPR-2PaRR (Fig. 2.14a) 1PaPR-2PPaR (Fig. 2.14b)
6 6 6 6 15 15
PPM with NF=0 Type 3-RRS* (Fig. 3.1a) 3-RS*P (Fig. 3.1b) 3-RPS* (Fig. 3.2a) 3-PRS* (Fig. 3.2b) 3-PS*P (Fig. 3.3a) 3-C*RC* (Fig. 3.3b) 3-PassPassS* (Fig. 3.4a) 3-PassRS* (Fig. 3.6) 3-PassS*P (Fig. 3.4b) 3-PassPS* (Fig. 3.5a) 3-PPassS* (Fig. 3.5b) 3-PPS* (Fig. 3.7) 1PPS*-2RRS* (Fig. 3.8a) 1C*C*R-2RRS* (Fig. 3.8b) 1PPS*-2RS*P (Fig. 3.9a) 1PPS*-2RPS* (Fig. 3.9b) 1PPS*-2PRS* (Fig. 3.10a) 1C*C*R-2C*RC* (Fig. 3.10b) 1PassPS*-2PassRS* (Fig. 3.11a) 1PassPS*-2PPassS* (Fig. 3.11b)
Limb topology R||RS* RS*P R ⊥ PS* P ⊥ RS* PS*P C* ⊥ R ⊥ C* Pass||PassS* Pass||RS* PassS*P Pass ⊥ PS* P ⊥ PassS* P ⊥ PS* P ⊥ PS* R||RS* C* ⊥ C* ⊥ ⊥ R R||RS* P ⊥ PS* RS*P P ⊥ PS* R ⊥ PS* P ⊥ PS* P ⊥ RS* C* ⊥ C* ⊥ ⊥ R C* ⊥ R ⊥ C* Pass ⊥ PS* Pass||RS* Pass ⊥ PS* P ⊥ PassS*
186
3 Non overconstrained planar parallel robots with coupled motions
Table 3.3. Limb topology of the non overconstrained PPMs with idle mobilities presented in Figs. 3.12-3.20 No. Basic PPM Type 1 1PaPR-2PaPaR (Fig. 2.15a) 2 1PaPR-2PaRP (Fig. 2.15b) 3 3RRR (Fig. 2.16a,b) 4 3RPR (Fig. 2.17a) 5 2RPR-1RPR (Fig. 2.17b) 6 2RPP-1RPP (Fig. 2.18) 7 2RPPa-1RPPa (Fig. 2.19) 8 2RPaP-1RPaP (Fig. 2.20a) 9 2RPaPa-1RPaPa (Fig. 2.20b) 10 2PRR-1RPP (Fig. 2.21a) 11 2RRR-1RPP (Fig. 2.21b) 12 2RPR-1RPP (Fig. 2.21c) 13 2PPaR-1RPP (Fig. 2.22a) 14 2PaRR-1RPP (Fig. 2.22b) 15 2PaPaR-1RPP (Fig. 2.22c) 16 2PRR-1RPPa (Fig. 2.23a) 17 2RRR-1RPPa (Fig. 2.23b) 18 2RPR-1RPPa (Fig. 2.23c)
NF 21 15 6 6 6 6 15 15 24 6 6 6 12 12 18 9 9 9
PPM with NF=0 Type 1PassPS*-2PassPassS* (Fig. 3.12a) 1PassPS*-2PassS*P (Fig. 3.12b) 3RRS* (Fig. 3.13a,b) 3RPS* (Fig. 3.14a) 2RPS*-1RPS* (Fig. 3.14b) 2RC*C*-1RC*C* (Fig. 3.15) 2RC*Pass-1RC*Pass (Fig. 3.16) 2RPassC*-1RPassC* (Fig. 3.17a) 2RPassPass-1RPassPass (Fig. 3.17b) 2PS*C*-1RPP (Fig. 3.18a) 2RS*C*-1RPP (Fig. 3.18b) 2S*PC*-1RPP (Fig. 3.18c) 2PR*PassC*-1RPP (Fig. 3.19a) 2PassR*RC*-1RPP (Fig. 3.19b) 2PassPassC*-1RPP (Fig. 3.19c) 2PS*C*-1RPPass (Fig. 3.20a) 2RS*C*-1RPPass (Fig. 3.20b) 2S*PC*-1RPPass (Fig. 3.20c)
Limb topology Pass ⊥ PS* Pass||PassS* Pass ⊥ PS* PassS*P R||RS* R ⊥ PS* R ⊥ PS* R ⊥ PS* R ⊥ C* ⊥ ⊥ C* R ⊥ C* ⊥ ⊥ C* R ⊥ C* ⊥ ||Pass R ⊥ C* ⊥ ||Pass R||Pass ⊥ C* R||Pass ⊥ C* R||Pass||Pass R||Pass||Pass PS*C* R ⊥ P ⊥⊥ P RS*C* R ⊥ P ⊥⊥ P S*PC* R ⊥ P ⊥⊥ P P||R ⊥ Pass||C* R ⊥ P ⊥⊥ P Pass ⊥ R* ⊥ ||R||C* R ⊥ P ⊥⊥ P Pass||Pass||C* R ⊥ P ⊥⊥ P PS*C* R ⊥ P ⊥ ||Pass RS*C* R ⊥ P ⊥ ||Pass S*PC* R ⊥ P ⊥ ||Pass
3.1 Fully-parallel solutions
187
Table 3.4. Limb topology of the non overconstrained PPMs with idle mobilities presented in Figs. 3.21-3.29 No. Basic PPM Type 1 2PRR-1RPaP (Fig. 2.24a) 2 2RRR-1RPaP (Fig. 2.24b) 3 2RPR-1RPaP (Fig. 2.24c) 4 2PRR-1RPaPa (Fig. 2.25a) 5 2RRR-1RPaPa (Fig. 2.25b) 6 2RPR-1RPaPa (Fig. 2.25c) 7 2PPaR-1RPPa (Fig. 2.26a) 8 2PaRR-1RPPa (Fig. 2.26b) 9 2PPaR-1RPaP (Fig. 2.27a) 10 2PaRR-1RPaP (Fig. 2.27b) 11 2PaPaR-1RPPa (Fig. 2.28a) 12 2PaPaR-1RPaP (Fig. 2.28b) 13 2PPaR-1RPaPa (Fig. 2.29a) 14 2PaRR-1RPaPa (Fig. 2.29b) 15 2PaPaR-1RPaPa (Fig. 2.30) 16 2PRR-1RPaPa (Fig. 2.31a) 17 2PRR-1RPaPat (Fig. 2.31b) 18 2RRR-1RPaPa (Fig. 2.32a) 19 2RRR-1RPaPat (Fig. 2.32b)
NF 9 9 9 12 12 12 15 15 15 15 21 21 18 18 24 12 12 12 12
PPM with NF=0 Type 2PS*C*-1RPassP (Fig. 3.21a) 2RS*C*-1RPassP (Fig. 3.21b) 2S*PC*-1RPassP (Fig. 3.21c) 2PS*C*-1RPassPass (Fig. 3.22a) 2RS*C*-1RPassPass (Fig. 3.22b) 2S*PC*-1RPassPass (Fig. 3.22c) 2PR*PassC*-1RPPass (Fig. 3.23a) 2PassR*RC*-1RPPass (Fig. 3.23b) 2PR*PassC*-1RPassP (Fig. 3.25a) 2PassR*RC*-1RPassP (Fig. 3.25b) 2PassPassC*-1RPPass (Fig. 3.24a) 2PassPassC*-1RPassP (Fig. 3.24b) 2PR*PassC*-1RPassPass (Fig. 3.26a) 2PassR*RC*-1RPassPass (Fig. 3.26b) 2PassPassC*-1RPassPass (Fig. 3.27) 2PS*C*-1RPacsPacs (Fig. 3.28a) 2PS*C*-1RPacsPatcs (Fig. 3.28b) 2RS*C*-1RPacsPacs (Fig. 3.29a) 2RS*C*-1RPacsPatcs (Fig. 3.29b)
Limb topology PS*C* R||Pass ⊥ P RS*C* R||Pass ⊥ P S*PC* R||Pass ⊥ P PS*C* R||Pass||Pass RS*C* R||Pass||Pass S*PC* R||Pass||Pass P||R* ⊥ Pass||C* R ⊥ P ⊥ ||Pass Pass ⊥ R* ⊥ ||R||C* R ⊥ P ⊥ ||Pass P||R* ⊥ Pass||C* R||Pass ⊥ P Pass ⊥ R* ⊥ ||R||C* R||Pass ⊥ P Pass||Pass||C* R ⊥ P ⊥ ||Pass Pass||Pass||C* R||Pass ⊥ P P||R* ⊥ Pass||C* R||Pass||Pass Pass ⊥ R* ⊥ ||R||C* R||Pass||Pass Pass||Pass||C* R||Pass||Pass PS*C* R||Pacs||Pacs PS*C* R||Pacs||Patcs RS*C* R||Pacs||Pacs RS*C* R||Pacs||Patcs
188
3 Non overconstrained planar parallel robots with coupled motions
Table 3.5. Limb topology of the non overconstrained PPMs with idle mobilities presented in Figs. 3.30-3.33 No. Basic PPM Type 1 2RPR-1RPaPa (Fig. 2.33a) 2 2RPR-1RPaPat (Fig. 2.33b) 3 2PPaR-1RPaPa (Fig. 2.34a) 4 2PPaR-1RPaPat (Fig. 2.34b) 5 2PaRR-1RPaPa (Fig. 2.35a) 6 2PaRR-1RPaPat (Fig. 2.35b) 7 2PaPaR-1RPaPa (Fig. 2.36a) 8 2PaPaR-1RPaPat (Fig. 2.36b)
PPM with NF=0 Type 2S*PC*-1RPacsPacs (Fig. 3.30a) 2S*PC*-1RPacsPatcs (Fig. 3.30b) 2PR*PassC*-1RPacsPacs (Fig. 3.31a) 2PR*PassC*-1RPacsPatcs (Fig. 3.31b) 2PassR*RC*-1RPacsPacs (Fig. 3.32a) 2PassR*RC*-1RPacsPatcs (Fig. 3.32b) 2PassPassC*-1RPacsPacs (Fig. 3.33a) 2PassPassC*-1RPacsPatcs (Fig. 3.33b)
NF 12 12 18 18 18 18 24 24
Limb topology S*PC* R||Pacs||Pacs S*PC* R||Pacs||Patcs P||R* ⊥ Pass||C* R||Pacs||Pacs P||R* ⊥ Pass||C* R||Pacs||Patcs Pass ⊥ R* ⊥ ||R||C* R||Pacs||Pacs Pass ⊥ R* ⊥ ||R||C* R||Pacs||Patcs Pass||Pass||C* R||Pacs||Pacs Pass||Pass||C* R||Pacs||Patcs
Table 3.6. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 3.1-3.33 No. Parallel mechanism 1 Figs. 3.1, 3.4-3.9, 3.13 2 Figs. 3.2, 3.3, 3.10-3.12, 3.14-3.17 3 Figs. 3.18, 3.19-3.33
Basis (RG1) ( v1 , v 2 ,
α
,
β
,
δ
)
(RG2) ( v1 , v 2 , v 3 ,
β
,
δ
)
(RG3) ( v1 , v 2 , v 3 ,
( v1 , v 2 ,
α
,
β
,
δ
)
( v1 , v 2 , v 3 ,
α
,
δ
)
( v1 , v 2 , v 3 ,
) ( v1 , v 2 , v 3 ,
α
,
β
,
( v1 , v 2 , v 3 ,
α
,
β
,
δ
δ
) ( v1 , v 2 ,
δ
α
β
)
,
,
δ
δ
)
)
3.1 Fully-parallel solutions
189
Table 3.7. Structural parametersa of non overconstrained PPMs in Figs. 3.1-3.7 No. Structural Solution parameter 3-RRS*, 3-RS*P (Fig. 3.1) 3-PassPassS* 3-PassS*P (Fig. 3.4b) 3-RPS*, PRS* (Fig. 3.2) (Fig. 3.4a) 3-PassPS* (Fig. 3.5a) 3-PS*P, 3-C*RC* (Fig. 3.3) 3-PPassS* (Fig. 3.5b) 3-PPS* (Fig. 3.7) 3-PassRS* (Fig. 3.6) 1 m 8 20 14 2 p1 3 9 6 3 p2 3 9 6 4 p3 3 9 6 5 p 9 27 18 6 q 2 8 5 7 k1 3 0 0 8 k2 0 3 3 9 k 3 3 3 10 (RGi) see Table 3.5 see Table 3.5 see Table 3.5 (i=1,2,3) 11 SG1 5 5 5 12 SG2 5 5 5 13 SG3 5 5 5 14 rG1 0 12 6 15 rG2 0 12 6 16 rG3 0 12 6 17 MG1 5 7 6 18 MG2 5 7 6 19 MG3 5 7 6 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 3 22 rl 0 36 18 23 rF 12 48 30 24 MF 3 9 6 25 NF 0 0 0 26 TF 0 6 3 p1 27 5 19 12 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
fj
5
19
12
fj
5
19
12
fj
15
57
36
See footnote of Table 2.4 for the nomenclature of structural parameters
190
3 Non overconstrained planar parallel robots with coupled motions
Table 3.8. Structural parametersa of non overconstrained PPMs in Figs. 3.8-3.12 No. Structural Solution parameter 1PPS*-2RRS* (Fig. 3.8a) 1C*C*R-2RRS* (Fig. 3.8b) 1PPS*-2RS*P (Fig. 3.9a) 1PPS*-2RPS* (Fig. 3.9b) 1PPS*-2PRS* (Fig. 3.10a) 1C*C*R-2C*RC* (Fig. 3.10b) 1 m 8 2 p1 3 3 p2 3 4 p3 3 5 p 9 6 q 2 7 k1 3 8 k2 0 9 k 3 10 (RGi) see Table 3.5 (i=1,2,3) 11 SG1 5 12 SG2 5 13 SG3 5 14 rG1 0 15 rG2 0 16 rG3 0 17 MG1 5 18 MG2 5 19 MG3 5 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 0 23 rF 12 24 MF 3 25 NF 0 26 TF 0 p1 27 5 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
1PassPS*-2PassRS* (Fig. 3.11a) 1PassPS*-2PPassS* (Fig. 3.11b) 1PassPS*-2PassS*P (Fig. 3.12b) 14 6 6 6 18 5 0 3 3 see Table 3.5
18 6 9 9 24 7 0 3 3 see Table 3.5
5 5 5 6 6 6 6 6 6 ( v1 , v 2 , 3 18 30 6 0 3 12
5 5 5 6 12 12 6 7 7 ( v1 , v 2 , 3 30 42 8 0 5 12
δ
)
1PassPS*2PassPassS* (Fig. 3.12a)
j
fj
5
12
19
fj
5
12
19
fj
15
36
50
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
3.1 Fully-parallel solutions
191
Table 3.9. Structural parametersa of non overconstrained PPMs in Figs. 3.13-3.17 No. Structural Solution parameter 3RRS* (Fig. 3.13) 3RPS* (Fig. 3.14a) 2RPS*-1RPS* (Fig. 3.14b) 2RC*C*-1RC*C* (Fig. 3.15) 1 m 8 2 p1 3 3 p2 3 4 p3 3 5 p 9 6 q 2 7 k1 3 8 k2 0 9 k 3 10 (RGi) see Table 3.5 (i=1,2,3) 11 SG1 5 12 SG2 5 13 SG3 5 14 rG1 0 15 rG2 0 16 rG3 0 17 MG1 5 18 MG2 5 19 MG3 5 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 0 23 rF 12 24 MF 3 25 NF 0 26 TF 0 p1 27 5 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2RC*Pass-1RC*Pass 2RPassPass(Fig. 3.16) 1RPassPass ss ss 2RPa C*-1RPa C* (Fig. 3.17b) (Fig. 3.17a) 14 20 6 9 6 9 6 9 18 27 5 8 0 0 3 3 3 3 see Table 3.5 see Table 3.5 5 5 5 6 6 6 5 5 5 ( v1 , v 2 , 3 18 30 3 0 0 11
δ
)
5 5 5 12 12 12 5 5 5 ( v1 , v 2 , 3 36 48 3 0 0 17
fj
5
11
17
fj
5
11
17
fj
15
33
51
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
192
3 Non overconstrained planar parallel robots with coupled motions
Table 3.10. Structural parametersa of non overconstrained PPMs in Figs. 3.18 and 3.19 No. Structural Solution parameter 2PS*C*-1RPP (Fig. 3.18a) 2PR*PassC*-1RPP 2RS*C*-1RPP (Fig. 3.18b) (Fig. 3.19a) 2S*PC*-1RPP (Fig. 3.18c) 2PassR*RC*-1RPP (Fig. 3.19b) 1 m 8 14 2 p1 3 7 3 p2 3 7 4 p3 3 3 5 p 9 17 6 q 2 4 7 k1 3 1 8 k2 0 2 9 k 3 3 10 (RGi) see Table 3.5 see Table 3.5 (i=1,2,3) 11 SG1 6 6 12 SG2 6 6 13 SG3 3 3 14 rG1 0 6 15 rG2 0 6 16 rG3 0 0 17 MG1 6 6 18 MG2 6 6 19 MG3 3 3 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 22 rl 0 12 23 rF 12 24 24 MF 3 3 25 NF 0 0 26 TF 0 0 p1 27 6 12 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
2PassPassC*1RPP (Fig. 3.19c) 16 9 9 3 21 6 1 2 3 see Table 3.5 6 6 3 12 12 0 6 6 3 ( v1 , v 2 , 3 24 36 3 0 0 18
j
fj
6
12
18
fj
3
3
3
fj
15
27
39
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
3.1 Fully-parallel solutions
193
Table 3.11. Structural parametersa of non overconstrained PPMs in Figs. 3.203.23 No. Structural Solution parameter 2PS*C*-1RPPass (Fig. 3.20a) 2RS*C*-1RPPass (Fig. 3.20b) 2S*PC*-1RPPass (Fig. 3.20c) 2PS*C*-1RPassP (Fig. 3.21a) 2RS*C*-1RPassP (Fig. 3.21b) 2S*PC*-1RPassP (Fig. 3.21c) 1 m 10 2 p1 3 3 p2 3 4 p3 6 5 p 12 6 q 3 7 k1 2 8 k2 1 9 k 3 10 (RGi) see Table 3.5 (i=1,2,3) 11 SG1 6 12 SG2 6 13 SG3 3 14 rG1 0 15 rG2 0 16 rG3 6 17 MG1 6 18 MG2 6 19 MG3 4 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 6 23 rF 18 24 MF 4 25 NF 0 26 TF 1 p1 27 6 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PS*C*-1RPassPass 2PR*PassC*(Fig. 3.22a) 1RPPass ss ss 2RS*C*-1RPa Pa (Fig. 3.23a) (Fig. 3.22b) 2PassR*RC*ss ss 2S*PC*-1RPa Pa 1RPPass (Fig. 3.23b) (Fig. 3.22c) 12 16 3 7 3 7 9 6 15 20 4 5 2 0 1 3 3 3 see Table 3.5 see Table 3.5 6 6 3 0 0 12 6 6 5 ( v1 , v 2 , 3 12 24 5 0 2 6
δ
)
6 6 3 6 6 6 6 6 4 ( v1 , v 2 , 3 18 30 4 0 1 12
fj
6
6
12
fj
10
17
10
fj
22
29
34
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
194
3 Non overconstrained planar parallel robots with coupled motions
Table 3.12. Structural parametersa of non overconstrained PPMs in Figs. 3.243.26 No. Structural Solution parameter 2PassPassC*-1RPPass (Fig. 3.24a) 2PassPassC*-1RPassP (Fig. 3.24b)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
18 9 9 6 24 7 0 3 3 see Table 3.5
16 7 7 6 20 5 0 3 3 see Table 3.5
2PR*PassC*1RPassPass (Fig. 3.26a) 2PassR*RC*1RPassPass (Fig. 3.26b) 18 7 7 9 23 6 0 3 3 see Table 3.5
6 6 3 12 12 6 6 6 4 ( v1 , v 2 , 3 30 42 4 0 1 18
6 6 3 6 6 6 6 6 4 ( v1 , v 2 , 3 18 30 4 0 1 12
6 6 3 6 6 12 6 6 5 ( v1 , v 2 , 3 24 36 5 0 2 12
δ
)
2PR*PassC*-1RPassP (Fig. 3.25a) 2PassR*RC*-1RPassP (Fig. 3.25b)
δ
)
fj
18
12
12
fj
10
10
17
fj
46
34
41
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
3.1 Fully-parallel solutions
195
Table 3.13. Structural parametersa of non overconstrained PPMs in Figs. 3.273.30 No. Structural Solution parameter 2PassPassC*-1RPassPass (Fig. 3.27)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
20 9 9 9 27 8 0 3 3 see Table 3.5
2PS*C*-1RPacsPacs (Fig. 3.28a) 2PS*C*-1RPacsPatcs (Fig. 3.28b) 2RS*C*-1RPacsPacs (Fig. 3.29a) 2RS*C*-1RPacsPatcs (Fig. 3.29b) 2S*PC*-1RPacsPacs (Fig. 3.30a) 2S*PC*-1RPacsPatcs (Fig. 3.30b) 12 3 3 9 15 4 2 1 3 see Table 3.5
6 6 3 12 12 12 6 6 5 ( v1 , v 2 , 3 36 48 5 0 2 18
6 6 3 0 0 12 6 6 3 ( v1 , v 2 , 3 12 24 3 0 0 6
δ
)
fj
18
6
fj
17
15
fj
53
27
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
196
3 Non overconstrained planar parallel robots with coupled motions
Table 3.14. Structural parametersa of non overconstrained PPMs in Figs. 3.313.33 No. Structural Solution parameter 2PR*PassC*-1RPacsPacs (Fig. 3.31a) 2PR*PassC*-1RPacsPatcs (Fig. 3.31b) 2PassR*RC*-1RPacsPacs (Fig. 3.32a) 2PassR*RC*-1RPacsPatcs (Fig. 3.32b) 1 m 18 2 p1 7 3 p2 7 4 p3 9 5 p 23 6 q 6 7 k1 0 8 k2 3 9 k 3 10 (RGi) see Table 3.5 (i=1,2,3) 11 SG1 6 12 SG2 6 13 SG3 3 14 rG1 6 15 rG2 6 16 rG3 12 17 MG1 6 18 MG2 6 19 MG3 3 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 24 23 rF 36 24 MF 3 25 NF 0 26 TF 0 p1 27 12 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
2PassPassC*-1RPacsPacs (Fig. 3.33a) 2PassPassC*-1RPacsPatcs (Fig. 3.33b) 20 9 9 9 27 8 0 3 3 see Table 3.5 6 6 3 12 12 12 6 6 3 ( v1 , v 2 , 3 36 48 3 0 0 18
δ
)
j
fj
12
18
fj
15
15
fj
39
51
See footnote of Table 2.4 for the nomenclature of structural parameters
3.1 Fully-parallel solutions
197
Fig. 3.1. Non overconstrained PPMs with coupled motions of types 3-RRS* (a) and 3-RS*P (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology R||RS* (a) and RS*P (b)
198
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.2. Non overconstrained PPMs with coupled motions of types 3-RPS* (a) and 3-PRS* (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology R ⊥ PS* (a) and P ⊥ RS* (b)
3.1 Fully-parallel solutions
199
Fig. 3.3. Non overconstrained PPMs with coupled motions of types 3-PS*P (a) and 3-C*RC* (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology PS*P (a) and C* ⊥ R ⊥ C* (b)
200
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.4. Non overconstrained PPMs with coupled motions of types 3-PassPassS* (a) and 3-PassS*P (b) defined by SF=3, (RF)=( v1 , v2 , δ ) and MF=9, NF=0, TF=6 (a), MF=6, NF=0, TF=3 (b), limb topology Pass||PassS* (a) and PassS*P (b)
3.1 Fully-parallel solutions
201
Fig. 3.5. Non overconstrained PPMs with coupled motions of types 3-PassPS* (a) and 3-PPassS* (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0, TF=3, limb topology Pass ⊥ PS* (a) and P ⊥ PassS* (b)
202
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.6. Non overconstrained PPM with coupled motions of type 3-PassRS* defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0, TF=3, limb topology Pass||RS*
Fig. 3.7. Non overconstrained PPM with one decoupled translation of type 3PPS* defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology P ⊥ PS*
3.1 Fully-parallel solutions
203
Fig. 3.8. Non overconstrained PPMs with one decoupled translation of types 1PPS*-2RRS* (a) and 1C*C*R-2RRS* (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology R||RS* and P ⊥ PS* (a) R||RS* and
C* ⊥ C* ⊥ ⊥ R (b)
204
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.9. Non overconstrained PPMs with one decoupled translation of types 1PPS*-2RS*P (a) and 1PPS*-2RPS* (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology P ⊥ PS* and RS*P (a) and P ⊥ PS* and R ⊥ PS* (b)
3.1 Fully-parallel solutions
205
Fig. 3.10. Non overconstrained PPMs with one decoupled translation of types 1PPS*-2PRS* (a) and 1C*C*R-2C*RC* (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology P ⊥ PS* and P ⊥ RS* (a),
C* ⊥ C* ⊥ ⊥ R and C* ⊥ R ⊥ C* (b)
206
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.11. Non overconstrained PPMs with one decoupled translation of types 1PassPS*-2PassRS* (a) and 1PassPS*-2PPassS* (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0, TF=3, limb topology Pass ⊥ PS* and Pass||RS* (a) and Pass ⊥ PS* and P ⊥ PassS* (b)
3.1 Fully-parallel solutions
207
Fig. 3.12. Non overconstrained PPMs with one decoupled translation of types 1PassPS*-2PassPassS* (a) and 1PassPS*-2PassS*P (b) defined by SF=3, (RF)=( v1 , v2 , δ ) and MF=8, NF=0, TF=5 (a), MF=6, NF=0, TF=3 (b), limb topology Pass ⊥ PS* and Pass||PassS* (a) and Pass ⊥ PS* and PassS*P (b)
208
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.13. 3RRS*-type non overconstrained PPMs with partially decoupled translations defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology R||RS*
3.1 Fully-parallel solutions
209
Fig. 3.14. Overconstrained PPMs with partially decoupled translations of types 3RPS* (a) and 2RPS*-1RPS* (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology R ⊥ PS* (a), R ⊥ PS* and R ⊥ PS* (b)
210
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.15. Non overconstrained PPM with partially decoupled rotation of type 2RC*C*-1RC*C* defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology R ⊥ C* ⊥ ⊥ C*
Fig. 3.16. Non overconstrained PPM with partially decoupled rotation of type 2RC*Pass-1RC*Pass defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology R ⊥ C* ⊥ ||Pass
3.1 Fully-parallel solutions
211
Fig. 3.17. Non overconstrained PPMs with partially decoupled rotation of types 2RPassC*-1RPassC* (a) and 2RPassPass-1RPassPass (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology R||Pass ⊥ C* (a) and R||Pass||Pass (b)
212
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.18. Non overconstrained PPMs with with uncoupled rotation of types 2PS*C*-1RPP (a), 2RS*C*-1RPP (b) and 2S*PC*-1RPP (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology R ⊥ P ⊥ ⊥ P and PS*C* (a), RS*C* (b), S*PC* (c)
3.1 Fully-parallel solutions
213
Fig. 3.19. Non overconstrained PPMs with with uncoupled rotation of types 2PR*PassC*-1RPP (a), 2PassR*RC*-1RPP (b) and 2PassPassC*-1RPP (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology R ⊥ P ⊥ ⊥ P and P||R ⊥ Pass||C* (a), Pass ⊥ R* ⊥ ||R||C* (b), Pass||Pass||C* (c)
214
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.20. Non overconstrained PPMs with with uncoupled rotation of types 2PS*C*-1RPPass (a), 2RS*C*-1RPPass (b) and 2S*PC*-1RPPass (c) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4 NF=0, TF=1, limb topology R ⊥ P ⊥ ||Pass and PS*C* (a), RS*C* (b), S*PC* (c)
3.1 Fully-parallel solutions
215
Fig. 3.21. Non overconstrained PPMs with with uncoupled rotation of types 2PS*C*-1RPassP (a), 2RS*C*-1RPassP (b) and 2S*PC*-1RPassP (c) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology R|| Pass ⊥ P and PS*C* (a), RS*C* (b), S*PC* (c)
216
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.22. Non overconstrained PPMs with with uncoupled rotation of types 2PS*C*-1RPassPass (a), 2RS*C*-1RPassPass (b) and 2S*PC*-1RPassPass (c) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0, TF=2, limb topology R||Pass||Pass and PS*C* (a), RS*C* (b), S*PC* (c)
3.1 Fully-parallel solutions
217
Fig. 3.23. Non overconstrained PPMs with with uncoupled rotation of types 2PR*PassC*-1RPPass (a) and 2PassR*RC*-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology R ⊥ P ⊥ ||Pass and ss ss || P||R* ⊥ Pa ||C* (a), Pa ⊥ R* ⊥ R||C* (b)
218
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.24. Non overconstrained PPMs with with uncoupled rotation of types 2PassPassC*-1RPPass (a) and 2PassPassC*-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology Pass||Pass||C* and R ⊥ P ⊥ ||Pass (a), R||Pass ⊥ P (b)
3.1 Fully-parallel solutions
219
Fig. 3.25. Non overconstrained PPMs with with uncoupled rotation of types 2PR*PassC*-1RPassP (a) and 2PassR*RC*-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology R||Pass ⊥ P and P||R* ⊥ Pass||C* (a), Pass ⊥ R* ⊥ ||R||C* (b)
220
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.26. Non overconstrained PPMs with with uncoupled rotation of types 2PR*PassC*-1RPassPass (a) and 2PassR*RC*-1RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0, TF=2, limb topology R||Pass||Pass and P||R* ⊥ Pass||C* (a), Pass ⊥ R* ⊥ ||R||C* (b)
3.1 Fully-parallel solutions
221
Fig. 3.27. 2PassPassC*-1RPassPass-type non overconstrained PPM with uncoupled rotation SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0, TF=2, limb topology Pass||Pass||C* and R||Pass||Pass
222
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.28. Non overconstrained PPMs with uncoupled rotation of types 2PS*C*1RPacsPacs (a) and 2PS*C*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology PS*C* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
3.1 Fully-parallel solutions
223
Fig. 3.29. Non overconstrained PPMs with uncoupled rotation of types 2RS*C*1RPacsPacs (a) and 2RS*C*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology RS*C* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
224
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.30. Non overconstrained PPMs with uncoupled rotation of types 2S*PC*1RPacsPacs (a) and 2S*PC*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology S*PC* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
3.1 Fully-parallel solutions
225
Fig. 3.31. Non overconstrained PPMs with uncoupled rotation of types 2PR*PassC*-1RPacsPacs (a) and 2PR*PassC*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology P||R* ⊥ Pass||C* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
226
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.32. Non overconstrained PPMs with uncoupled rotation of types 2PassR*RC*-1RPacsPacs (a) and 2PassR*RC*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology Pass ⊥ R* ⊥ ||R||C* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
3.1 Fully-parallel solutions
227
Fig. 3.33. Non overconstrained PPMs with uncoupled rotation of types 2PassPassC*-1RPacsPacs (a) and 2PassPassC*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology Pass||Pass||C* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
228
3 Non overconstrained planar parallel robots with coupled motions
3.2 Non fully-parallel solutions The non fully-parallel solutions presented in Figs. 3.34-3.40 are obtained from the fully-parallel solutions in Figs. 3.18, 3.20-3.22 and 3.28-3.30 by superposing the last revolute joints of limbs G1 and G2. In this way, these two limbs compose just one complex limb denoted by G1-G2 in which two actuators are combined. For example, the solutions in Fig. 3.34 combine one simple and one complex limb. Simple limb G3 is of type RPP and complex limb G1-G2 is of types (PS*C*S*P)C* (Fig. 3.34a), (RS*C*S*R)C* (Fig. 3.34b) and (S*PC*PS*)C* (Fig. 3.34c). One closed loop defined in the brackets is combined in each complex limb G1-G2 of these solutions. The solutions in Figs. 3.35-3.40 combine two complex limbs G1-G2 and G3. In these solutions, complex limb G3 is of types RPPass (Fig. 3.35), RPassP (Fig. 3.36), RPassPass (Fig. 3.37), RPacsPacs (Fig. 3.38a, 3.39a, 3.40a) and RPacsPatcs (Fig. 3.38b, 3.39b and 3.40b). We recall that the notations Pacs and Patcs are associated with a parallelogram and telescopic parallelogram loops with three idle mobilities combined in a cylindrical and a spherical joint, and Pass with four idle mobilities combined in two spherical joints adjacent to the same link. In the cylindrical joints of the parallelogram loops denoted by Pacs and Patcs (Figs. 3.38-3.40) the translational motion is an idle mobility. In the parallelogram loop Pass-type, three idle mobilities are introduced in the loop and one outside the loop. The idle mobility introduced outside the loop (Figs. 3.35-3.37) becomes an internal rotational mobility of the binary link adjacent to the two spherical joints. This is the case of the binary links 5C (Fig. 3.35), 4C (Fig. 3.36), 3C and 6C (Fig. 3.37). This internal mobility gives one degree of structural redundancy. The rotation axis of the moving platform has a fixed position in the solutions in Figs. 3.34-3.37 and a variable position in Figs. 3.38-3.40. The limb topology of these non overconstrained solutions (NF=0) are systematized in Table 3.15 and the structural parameters in Tables 3.16 and 3.17. The basis of the vector space of the relative velocities between the moving and the fixed platforms in the complex limb G1-G2 isolated from the parallel mechanism is denoted by (RG1-G2) in Tables 3.16 and 3.17. The connectivity between the moving and the fixed platforms of this complex limb isolated from the parallel mechanism is denoted by SG1-G2 (see Table 3.16 and 3.17).
3.2 Non fully-parallel solutions
229
Table 3.15. Limb topology of the non overconstrained PPMs with idle mobilities presented in Figs. 3.34-3.40 No. Basic PPM Type 1 (PRRRP)R-RPP (Fig. 2.37a) 2 (RRRRR)R-RPP (Fig. 2.37b) 3 (RPRPR)R-RPP (Fig. 2.37c) 4 (PRRRP)R-RPPa (Fig. 2.38a) 5 (RRRRR)R-RPPa (Fig. 2.38b) 6 (RPRPR)R-RPPa (Fig. 2.38c) 7 (PRRRP)R-RPaP (Fig. 2.39a) 8 (RRRRR)R-RPaP (Fig. 2.39b) 9 (RPRPR)R-RPaP (Fig. 2.39c) 10 (PRRRP)R-RPaPa (Fig. 2.40a) 11 (RRRRR)R-RPaPa (Fig. 2.40b) 12 (RPRPR)R-RPaPa (Fig. 2.40c) 13 (PRRRP)R-RPaPa (Fig. 2.41a) 14 (PRRRP)R-RPaPat (Fig. 2.41b) 15 (RRRRR)R-RPaPa (Fig. 2.42a) 16 (RRRRR)R-RPaPat (Fig. 2.42b) 17 (RPRPR)R-RPaPa (Fig. 2.43a) 18 (RPRPR)R-RPaPat (Fig. 2.43b)
NF 6 6 6 9 9 9 9
9 12 12 12 12 12 12 12 12 12
PPM with NF=0 Type Limb topology (PS*C*S*P)C*-RPP (PS*C*S*P)C* (Fig. 3.34a) R ⊥ P ⊥⊥ P (RS*C*S*R)C*-RPP (RS*C*S*R)C* (Fig. 3.34b) R ⊥ P ⊥⊥ P (S*PC*PS*)C*-RPP (S*PC*PS*)C* (Fig. 3.34c) R ⊥ P ⊥⊥ P (PS*C*S*P)C* (PS*C*S*P)C*-RPPass (Fig. 3.35a) R ⊥ P ⊥ ||Pass (RS*C*S*R)C*-RPPass (RS*C*S*R)C* (Fig. 3.35b) R ⊥ P ⊥ ||Pass (S*PC*PS*)C*-RPPass (S*PC*PS*)C* R ⊥ P ⊥ ||Pass (Fig. 3.35c) (PS*C*S*P)C*-RPassP (PS*C*S*P)C* (Fig. 3.36a) R||Pass ⊥ P (RS*C*S*R)C*-RPassP (RS*C*S*R)C* (Fig. 3.36b) R||Pass ⊥ P (S*PC*PS*)C* (S*PC*PS*)C*-RPassP (Fig. 3.36c) R||Pass ⊥ P (PS*C*S*P)C*-RPassPass (PS*C*S*P)C* (Fig. 3.37a) R||Pass||Pass ss ss (RS*C*S*R)C*-RPa Pa (RS*C*S*R)C* (Fig. 3.37b) R||Pass||Pass ss ss (S*PC*PS*)C*-R Pa Pa (S*PC*PS*)C* R||Pass||Pass (Fig. 3.37c) cs cs (PS*C*S*P)C*-RPa Pa (PS*C*S*P)C* R||Pacs||Pacs (Fig. 3.38a) cs tcs (PS*C*S*P)C*-RPa Pa (PS*C*S*P)C* (Fig. 3.38b) R||Pacs||Patcs cs cs (RS*C*S*R)C*-RPa Pa (RS*C*S*R)C* (Fig. 3.39a) R||Pacs||Pacs cs tcs (RS*C*S*R)C*-RPa Pa (RS*C*S*R)C* R||Pacs||Patcs (Fig. 3.39b) cs cs (S*PC*PS*)C*-RPa Pa (S*PC*PS*)C* (Fig. 3.40a) R||Pacs||Pacs cs tcs (S*PC*PS*)C*-RPa Pa (S*PC*PS*)C* (Fig. 3.40b) R||Pacs||Patcs
230
3 Non overconstrained planar parallel robots with coupled motions
Table 3.16. Structural parametersa of non overconstrained PPMs in Figs. 3.343.36 No. Structural parameter
1 2 3 4 5 6 7 8 9
m p1 p2 p q k1 k2 k (RG1-G2)
10
(RG3)
11 12 13 14 15 16 17
SG1-G2 SG3 rG1-G2 rG3 MG1-G2 MG3 (RF)
18 19 20 21 22 23 24
SF rl rF MF NF TF
25 26 a
∑ ∑ ∑
p1 j =1 p2 j =1 p j =1
fj
Solution (PS*C*S*P)C*-RPP (Fig. 3.34a) (RS*C*S*R)C*-RPP (Fig. 3.34b) (S*PC*PS*)C*-RPP (Fig. 3.34b) 8 6 3 9 2 1 1 2 ( v1 , v 2 , v 3 , α , β , δ )
(PS*C*S*P)C*-RPPass (Fig. 3.35a) (RS*C*S*R)C*-RPPass (Fig. 3.35b) (S*PC*PS*)C*-RPPass (Fig. 3.35c) (PS*C*S*P)C*-RPassP (Fig. 3.36a) (RS*C*S*R)C*-RPassP (Fig. 3.36b) (S*PC*PS*)C*-R Pass P (Fig. 3.36c) 10 6 6 12 3 0 2 2 ( v1 , v 2 , v 3 , α , β , δ )
( v1 , v 2 , 6 3 6 0 6 3 ( v1 , v 2 , 3 6 12 3 0 0 12
( v1 , v 2 , 6 3 6 6 6 4 ( v1 , v 2 , 3 12 18 4 0 1 12
δ
)
δ
)
fj
3
10
fj
15
22
δ
)
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
3.2 Non fully-parallel solutions
231
Table 3.17. Structural parametersa of non overconstrained PPMs in Figs. 3.373.40 No. Structural parameter (PS*C*S*P)C*RPacsPacs (Fig. 3.37a) (RS*C*S*R)C*RPacsPacs (Fig. 3.37b) (S*PC*PS*)C*RPacs Pacs (Fig. 3.37c) 1 m 12 2 p1 6 3 p2 9 4 p 15 5 q 4 6 k1 0 7 k2 2 8 k 2 9 (RG1-G2) ( v1 , v2 , v3 , α , β , δ )
Solution (PS*C*S*P)C*-RPacsPacs (Fig. 3.38a) (PS*C*S*P)C*-RPacsPatcs (Fig. 3.38b) (RS*C*S*R)C*-RPacsPacs (Fig. 3.39a) (RS*C*S*R)C*-RPacsPatcs (Fig. 3.39b) (S*PC*PS*)C*-RPacsPacs (Fig. 3.40a) (S*PC*PS*)C*-RPacsPatcs (Fig. 3.40b) 12 6 9 15 4 0 2 2 ( v1 , v 2 , v 3 , α , β , δ ) ( v1 , v 2 , 6 3 6 12 6 3 ( v1 , v 2 , 3 18 24 3 0 0 12
10
(RG3)
11 12 13 14 15 16 17
SG1-G2 SG3 rG1-G2 rG3 MG1-G2 MG3 (RF)
18 19 20 21 22 23 24
SF rl rF MF NF TF
25 26 a
∑ ∑ ∑
p1 j =1 p2 j =1 p j =1
fj
( v1 , v 2 , 6 3 6 12 6 5 ( v1 , v 2 , 3 18 24 5 0 2 12
δ
)
δ
)
fj
17
15
fj
29
27
δ
)
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
232
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.34. Non overconstrained PPMs with uncoupled rotation of types (PS*C*S*P)C*-RPP (a), (RS*C*S*R)C*-RPP (b) and (S*PC*PS*)C*-RPP (c) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0
3.2 Non fully-parallel solutions
233
Fig. 3.35. Non overconstrained PPMs with uncoupled rotation of types (PS*C*S*P)C*-RPPass (a), (RS*C*S*R)C*-RPPass (b) and (S*PC*PS*)C*RPPass (c) defined by MF=SF=4, (RF)=( v1 , v2 , δ ), TF=0, NF=1
234
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.36. Non overconstrained PPMs with uncoupled rotation of types (PS*C*S*P)C*-RPassP (a), (RS*C*S*R)C*-RPassP (b) and (S*PC*PS*)C*RPassP (c) defined by MF=SF=4, (RF)=( v1 , v2 , δ ), TF=0, NF=1
3.2 Non fully-parallel solutions
235
Fig. 3.37. Non overconstrained PPMs with uncoupled rotation of types (PS*C*S*P)C*-RPassPass (a), (RS*C*S*R)C*-RPassPass (b) and (S*PC*PS*)C*RPass Pass (c) defined by MF=SF=5, (RF)=( v1 , v2 , δ ), TF=0, NF=2
236
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.38. Non overconstrained PPMs with uncoupled rotation of types (PS*C*S*P)C*-RPacsPacs (a) and (PS*C*S*P)C*-RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0
3.2 Non fully-parallel solutions
237
Fig. 3.39. Non overconstrained PPMs with uncoupled rotation of types (RS*C*S*R)C*-RPacsPacs (a) and (RS*C*S*R)C*-RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0
238
3 Non overconstrained planar parallel robots with coupled motions
Fig. 3.40. Non overconstrained PPMs with uncoupled rotation of types (S*PC*PS*)C*-RPacsPacs (a) and (S*PC*PS*)C*-RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0
4 Planar parallel robots with uncoupled motions
Planar parallel robotic manipulator (PPM) with uncoupled motions with various degrees of overconstraint may be obtained by using simple and/or complex limbs. In these solutions, each operational velocity given by Eq. (1.18) depends on just one actuated joint velocity: v1 = v1 ( &q1 ) , v2 = v2 ( &q2 ) and ωδ = ωδ ( &q3 ) . The Jacobian matrix in Eq. (1.18) is a diagonal matrix. They can be actuated by linear and rotating actuators which can be mounted on the fixed base or on a moving link. In the solutions presented in this section, the actuators are associated with a revolute or prismatic joint mounted on the fixed base.
4.1 Overconstrained solutions Equation (1.16) indicates that overconstrained solutions of PPMs with uncoupled motions and q independent loops meet the condition p ∑ 1 fi < 3 + 6q . Various basic or derived solutions fulfil this condition along with MF=SF=3 and (RF)=( v1 ,v2 ,ωδ ). 4.1.1 Basic solutions In the basic solutions of overconstrained PPMs with uncoupled motions, F ← G1-G2-G3, the moving platform n nGi (i=1, 2, 3) is connected to the reference platform 1 1Gi 0 by three limbs with three degrees of connectivity. The simple and complex limbs presented in Figs. 2.1f,g, 2.2e-h and 2.3a,b are used in the solutions illustrated in this section (Figs. 4.1-4.6). The complex limbs combine one (Fig. 2.2e-g) or two (Figs. 2.2h and 2.3a) planar parallelogram loops of types Pa. One planar telescopic parallelogram loop of type Pat (Fig. 2.3b) along with a Pa-type loop is combined in the complex limb in Fig. 2.3b. No idle mobilities exist in these basic solutions. G. Gogu, Structural Synthesis of Parallel Robots, Solid Mechanics and Its Applications 173, DOI 10.1007/978-90-481-9831-3_4, © Springer Science + Business Media B.V. 2010
239
240
4 Planar parallel robots with uncoupled motions
Basic solutions of PPMs with uncoupled motions and different limb topologies can be obtained by using the following combinations of limbs: (i) two identical limbs G1 and G2 from Fig. 2.2e and G3-limb from Figs. 2.1g, 2.2f-h or 2.3a,b, (ii) two different limbs G1 and G2 from Figs. 2.1f and 2.2e and G3 limb from Figs. 2.1g, 2.2f-h or 2.3a,b. The rotation axis of the moving platform can be in a fixed or variable position. G3-limb in Figs. 2.1g and 2.2f-h are used to give a fixed position of the rotation axis and G3-limb in Fig. 2.3a,b to obtain a variable position. The limb topologies and connecting conditions in the PPMs with uncoupled motions presented in Figs. 4.1-4.6 are systematized in Table 4.1 and their structural parameters in Tables 4.2 and 4.3. The solutions in Figs 4.3a and 4.6a can provide an unlimited angle of rotation of the moving platform. In the fully-parallel solutions in Figs. 4.1-4.6, the moving platform n nGi (i=1, 2, 3) is connected to the reference platform 1 1Gi 0 by three planar limbs with three degrees of connectivity, and one actuator is combined in a revolute or prismatic pair of each limb. Non fully-parallel solutions can be obtained from the fully-parallel solutions in Figs. 4.1-4.6 by superposing the last revolute joints of limbs G1 and G2. In this way, these two limbs compose just one complex limb denoted by G1-G2 in which two actuators are combined, as we have presented in Chapters 2 and 3. Note 1: The limbs presented in Figs. 2.1-2.3 can also be used to generate basic solutions of overconstrained PPMs with decoupled motions. Basic solutions of PPMs with decoupled motions and different limb topologies can be obtained by using G1-limb from Figs. 2.1f and 2.2e, G2lumb from Figs. 2.1a-e and 2.2a-d and G3-limb from Figs. 2.1g, 2.2f-h or 2.3a,b. A large number of solutions with decoupled motions can be obtained by various combinations of the three limbs. These solutions are not presented in this book.
4.1 Overconstrained solutions
241
Table 4.1. Limb topology and connecting conditions of the overconstrained PPM with no idle mobilities presented in Figs. 4.1-4.6 No. PPM type
Limb topology
Connecting conditions
1
2PaPR-1RPP (Fig. 4.1a)
2
2PaPR-1RPPa (Fig. 4.1b)
The directions of the revolute joints of the three limbs are parallel. The last revolute joint of limbs G1 and G2 have superposed axes. Idem No. 1
3
2PaPR-1RPaP (Fig. 4.2a)
4
2PaPR-1RPaPa (Fig. 4.2b)
5
2PaPR-1RPaPa (Fig. 4.3a)
6
2PaPR-1RPaPat (Fig. 4.3b)
7
PPR-PaPR-RPP (Fig. 4.4a)
8
PPR-PaPR-RPPa (Fig. 4.4b)
Pa ⊥ P ⊥ ||R (Fig. 2.2e) R ⊥ P ⊥⊥ P (Fig. 2.1g) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R ⊥ P ⊥ ||Pa (Fig. 2.2f) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R||Pa ⊥ P (Fig. 2.2g) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R||Pa||Pa (Fig. 2.2h) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R||Pa||Pa (Fig. 2.3a) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R||Pa||Pat (Fig. 2.3b) P ⊥ P ⊥⊥ R (Fig. 2.1f) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R ⊥ P ⊥⊥ P (Fig. 2.1g) P ⊥ P ⊥⊥ R (Fig. 2.1f) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R ⊥ P ⊥ ||Pa (Fig. 2.2f)
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
242
4 Planar parallel robots with uncoupled motions
Table 4.1. (cont.) 9
PPR-PaPR-RPaP (Fig. 4.5a)
10
PPR-PaPR-RPaPa (Fig. 4.5b)
11
PPR-PaPR-RPaPa (Fig. 4.6a)
12
PPR-PaPR-RPaPat (Fig. 4.6b)
P ⊥ P ⊥⊥ R (Fig. 2.1f) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R||Pa ⊥ P (Fig. 2.2g) P ⊥ P ⊥⊥ R (Fig. 2.1f) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R||Pa||Pa (Fig. 2.2h) P ⊥ P ⊥⊥ R (Fig. 2.1f) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R||Pa||Pa (Fig. 2.3a) P ⊥ P ⊥⊥ R (Fig. 2.1f) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R||Pa||Pat (Fig. 2.3b)
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
4.1 Overconstrained solutions
243
Table 4.2. Structural parametersa of planar parallel mechanisms in Figs. 4.1-4.3 No. Structural Solution parameter 2PaPR-1RPP (Fig. 4.1a)
1 2 3 4 5 6 7 8 9 10
m p1 p2 p3 p q k1 k2 k (RG1)
11
(RG2)
12
(RG3)
13 14 15 16 17 18 19 20 21 22
SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
23 24 25 26 27 28 29
SF rl rF MF NF TF
30 31 32 a
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
12 6 6 3 15 4 1 2 3 ( v1 , v 2 , ( v1 , v 2 ,
fj
( v1 , v 2 , 3 3 3 3 3 0 3 3 3 ( v1 , v 2 , 3 6 12 3 12 0 6
δ
)
δ
)
δ
)
δ
)
δ
)
2PaPR-1RPaPa (Fig. 4.2b) 2PaPR-1RPaPa 2PaPR-1RPaPa (Fig. 4.3a,b) 16 6 6 9 21 6 0 3 3 ( v1 , v2 , δ )
δ
)
( v1 , v2 ,
δ
)
δ
)
( v1 , v2 , 3 3 3 3 3 6 3 3 3 ( v1 , v2 , 3 12 18 3 18 0 6
2PaPR-1RPPa (Fig. 4.1b) 2PaPR-1RPaP (Fig. 4.2a) 14 6 6 6 18 5 0 3 3 ( v1 , v2 , ( v1 , v2 , ( v1 , v2 , 3 3 3 3 3 3 3 3 3 ( v1 , v2 , 3 9 15 3 15 0 6
fj
6
6
6
fj
3
6
9
fj
15
18
21
δ
)
δ
)
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
244
4 Planar parallel robots with uncoupled motions
Table 4.3. Structural parametersa of planar parallel mechanisms in Figs. 4.4-4.6 No. Structural Solution parameter PPR-PaPR-RPP (Fig. 4.4a)
1 2 3 4 5 6 7 8 9 10
m p1 p2 p3 p q k1 k2 k (RG1)
11
(RG2)
12
(RG3)
13 14 15 16 17 18 19 20 21 22
SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
23 24 25 26 27 28 29
SF rl rF MF NF TF
30 31 32 a
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
10 3 6 3 12 3 2 1 3 ( v1 , v 2 , ( v1 , v 2 ,
fj
( v1 , v 2 , 3 3 3 0 3 0 3 3 3 ( v1 , v 2 , 3 3 9 3 9 0 3
δ
)
δ
)
δ
)
δ
)
PPR-PaPR-RPPa (Fig. 4.4b) PPR-PaPR-RPaP (Fig. 4.5a) 12 3 6 6 15 4 1 2 3 ( v1 , v2 , ( v1 , v2 , ( v1 , v2 , 3 3 3 0 3 3 3 3 3 ( v1 , v2 , 3 6 12 3 12 0 3
δ
)
PPR-PaPR-RPaPa (Fig. 4.5b) PPR-PaPR-RPaPa PPR-PaPR-RPaPat (Fig. 4.6a,b) 14 3 6 9 18 5 0 3 3 ( v1 , v2 , δ )
δ
)
( v1 , v2 ,
δ
)
δ
)
( v1 , v2 , 3 3 3 0 3 6 3 3 3 ( v1 , v2 , 3 9 15 3 15 0 3
fj
6
6
6
fj
3
6
9
fj
12
15
18
δ
)
δ
)
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
4.1 Overconstrained solutions
245
Fig. 4.1. Overconstrained PPMs with uncoupled motions of types 2PaPR-1RPP (a) and 2PaPR-1RPPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12 (a), NF=15 (b), limb topology Pa ⊥ P ⊥ ||R and R ⊥ P ⊥ ⊥ P (a), R ⊥ P ⊥ ||Pa (b)
246
4 Planar parallel robots with uncoupled motions
Fig. 4.2. Overconstrained PPMs with uncoupled motions of types 2PaPR-1RPaP (a) and 2PaPR-1RPaPa (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=15 (a), NF=18 (b), limb topology Pa ⊥ P ⊥ ||R and R||Pa ⊥ P (a), R||Pa||Pa (b)
4.1 Overconstrained solutions
247
Fig. 4.3. Overconstrained PPMs with uncoupled motions of types 2PaPR-1RPaPa (a) and 2PaPR-1RPaPat (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=18, limb topology Pa ⊥ P ⊥ ||R and R||Pa||Pa (a), R||Pa||Pat (b)
248
4 Planar parallel robots with uncoupled motions
Fig. 4.4. Overconstrained PPMs with uncoupled motions of types PPR-PaPRRPP (a) and PPR-PaPR-RPPa (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9 (a), NF=12 (b), limb topology P ⊥ P ⊥ ⊥ R, Pa ⊥ P ⊥ ||R and R ⊥ P ⊥ ⊥ P (a), R ⊥ P ⊥ ||Pa (b)
4.1 Overconstrained solutions
249
Fig. 4.5. Overconstrained PPMs with uncoupled motions of types PPR-PaPRRPaP (a) and PPR-PaPR-RPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12 (a), NF=15 (b), limb topology P ⊥ P ⊥ ⊥ R, Pa ⊥ P ⊥ ||R and R||Pa ⊥ P (a), R||Pa||Pa (b)
250
4 Planar parallel robots with uncoupled motions
Fig. 4.6. Overconstrained PPMs with uncoupled motions of types PPR-PaPRRPaPa (a) and PPR-PaPR-RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=15, limb topology P ⊥ P ⊥ ⊥ R, Pa ⊥ P ⊥ ||R and R||Pa||Pa (a), R||Pa||Pat (b)
4.1 Overconstrained solutions
251
4.1.2 Derived solutions Solutions with lower degrees of overconstraint can be derived from the basic solutions in Figs. 4.1-4.6 by using joints with idle mobilities. A large set of solutions can be obtained by introducing one or two idle mobilities outside the planar loops and up to three idle mobilities in each planar loop combined in the limbs. We recall that the joints combining idle mobilities are denoted by an asterisk. The idle mobilities which can be combined in a parallelogram loop are systematized in Fig. 1.2 and Table 1.1. The rotational mobility of the revolute joint denoted by R* is an idle mobility. One idle mobility is combined in each cylindrical joint C* and two idle mobilities in each spherical joint S*. These idle mobilities can be introduced outside or inside the planar loops combined in the limbs. For example, in the cylindrical joint denoted by C*, the idle mobility is the rotational motion in Figs. 4.7, 4.8a, 4.10 and 4.11 and the translational motion in Fig. 4.13a. In the limbs with two cylindrical joints C* in Figs. 4.13b, 4.14-4.18, the idle mobility is the rotational motion is in the first cylindrical joint and the translational motion in the second one. The notation Pacs is associated with a parallelogram loop with three idle mobilities combined in a cylindrical and a spherical joint, and Pass with four idle mobilities combined in two spherical joints adjacent to the same coupler link. In the parallelogram loop Passtype, three idle mobilities are introduced in the loop and one outside the loop. The idle mobility introduced outside the parallelogram loop is the internal mobility of the coupler link adjacent to the two spherical joints. Examples of solutions with 1-12 overconstraints derived from the basic solutions in Figs. 4.1-4.6 are illustrated in Figs. 4.7-4.18. The limb topology and the number of overconstraints of these solutions are systematized in Table 4.4 and the structural parameters in Tables 4.5-4.10.
252
4 Planar parallel robots with uncoupled motions
Table 4.4. Limb topology and the number of overconstraints NF of the derived PPMs with idle mobilities presented in Figs. 4.7-4.18 No. Basic PPM Type 1 2PaPR-1RPP (Fig. 4.1a) 2 3
2PaPR-1RPPa (Fig. 4.1b)
4 5
2PaPR-1RPaP (Fig. 4.2a)
6 7
2PaPR-1RPaPa (Fig. 4.2b)
8 9
2PaPR-1RPaPa (Fig. 4.3a)
10 11 2PaPR-1RPaPat (Fig. 4.3b) 12 13 PPR-PaPR-RPP (Fig. 4.4a) 14
15 PPR-PaPR-RPPa (Fig. 4.4b) 16
17 PPR-PaPR-RPaP (Fig. 4.5a)
Derived PPM NF Type 12 2PaPR-1RC*C* (Fig. 4.7a) 2PassPC*-1RPP (Fig. 4.13a) 15 2PaPR-1RC*Pass (Fig. 4.7b) 2PassC*C*-1RPPa (Fig. 4.13b) 15 2PaPR-1RPassC* (Fig. 4.8a) 2PassC*C*-1RPaP (Fig. 4.14a) 18 2PaPR-1RPassPass (Fig. 4.8b) 2PassC*C*-1RPaPa (Fig. 4.14b) 18 2PaPR-1RPacsPacs (Fig. 4.9a) 2PassPC*-1RPaPa (Fig. 4.15a) 18 2PaPR-1RPacsPatcs (Fig. 4.9b) 2PassPC*-1RPaPat (Fig. 4.15b) 9 PPR-PaPR-RC*C* (Fig. 4.10a) PC*C*-PassC*C*-RPP (Fig. 4.16a) 12 PPR-PaPR-RC*Pass (Fig. 4.10b) PR*C*C*-PassC*C*-RPPa (Fig. 4.16b) 12 PPR-PaPR-RPassC* (Fig. 4.11a)
NF Limb topology 10 Pa ⊥ P ⊥ ||R R ⊥ C* ⊥ ⊥ C* 2 Pass ⊥ P ⊥ ||C* R ⊥ P ⊥⊥ P 10 Pa ⊥ P ⊥ ||R R ⊥ C* ⊥ ||Pass 3 Pass ⊥ C* ⊥ ||C* R ⊥ P ⊥ ||Pa 10 Pa ⊥ P ⊥ ||R R||Pass ⊥ C* 3 Pass ⊥ C* ⊥ ||C* R||Pa ⊥ P 10 Pa ⊥ P ⊥ ||R R||Pass||Pass 6 Pass ⊥ C* ⊥ ||C* R||Pa||Pa 12 R||Pacs||Pacs Pa ⊥ P ⊥ ||R 8 Pass ⊥ P ⊥ ||C* R||Pa||Pa 12 R||Pacs||Patcs Pa ⊥ P ⊥ ||R 8 Pass ⊥ P ⊥ ||C* R||Pa||Pat 7 P ⊥ P ⊥ ⊥ R, Pa ⊥ P ⊥ ||R R ⊥ C* ⊥ ⊥ C* 1 P ⊥ C* ⊥ ⊥ C* Pass ⊥ C* ⊥ ||C* R ⊥ P ⊥⊥ P 7 P ⊥ P ⊥⊥ R Pa ⊥ P ⊥ ||R R ⊥ C* ⊥ ||Pass 3 P||R* ⊥ C* ⊥ ⊥ C* Pass ⊥ C* ⊥ ||C* R ⊥ P ⊥ ||Pa 7 P ⊥ P ⊥⊥ R Pa ⊥ P ⊥ ||R R||Pass ⊥ C*
4.1 Overconstrained solutions
253
Table 4.4. (cont.) PR*C*C*-PassC*C*-RPaP (Fig. 4.17a)
18
P||R* ⊥ C* ⊥ ⊥ C* Pass ⊥ C* ⊥ ||C* R||Pa ⊥ P P ⊥ P ⊥⊥ R Pa ⊥ P ⊥ ||R R||Pass||Pass P||R* ⊥ C* ⊥ ⊥ C* Pass ⊥ C* ⊥ ||C* R||Pa||Pa P ⊥ P ⊥⊥ R Pa ⊥ P ⊥ ||R R||Pacs||Pacs P||R* ⊥ C* ⊥ ⊥ C* Pass ⊥ C* ⊥ ||C* R||Pa||Pa P ⊥ P ⊥⊥ R Pa ⊥ P ⊥ ||R R||Pacs||Patcs P||R* ⊥ C* ⊥ ⊥ C* Pass ⊥ C* ⊥ ||C* R||Pa||Pat
3
19 PPR-PaPR-RPaPa 15 PPR-PaPR-RPassPass (Fig. 4.5b) (Fig. 4.11b)
7
PR*C*C*-PassC*C*-RPaPa 6 (Fig. 4.17b)
20
21 PPR-PaPR-RPaPa 15 PPR-PaPR-RPacsPacs (Fig. 4.6a) (Fig. 4.12a)
9
PR*C*C*-PassC*C*-RPaPa 6 (Fig. 4.18a)
22
23 PPR-PaPR-RPaPat 15 PPR-PaPR-RPacsPatcs (Fig. 4.6b) (Fig. 4.12b)
9
PR*C*C*-PassC*C*-RPaPat 6 (Fig. 4.18b)
24
Table 4.5. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 4.7-4.18 No. Parallel mechanism 1 Figs. 4.7, 4.8, 4.10, 4.11 2 Figs. 4.9, 4.12 3 Figs. 4.13a,
Basis (RG1) ( v1 , v 2 , ( v1 , v 2 ,
( v1 , v 2 , v 3 ,
α
,
δ
)
4
( v1 , v 2 , v 3 ,
α
,
β
,
( v1 , v 2 , v 3 ,
β
,
δ
)
5
Figs. 4.13b, 4.14, 4.15, 4.16b, 4.17, 4.18 Figs. 4.16a
δ
)
(RG2) ( v1 , v 2 ,
δ
)
( v1 , v 2 ,
δ
δ
)
(RG3) ( v1 , v 2 ,
α
,
δ
)
( v1 , v2 ,
δ
)
( v1 , v 2 ,
δ
)
( v1 , v 2 , v 3 ,
β
,
δ
)
) ( v1 , v 2 , v 3 ,
α
,
β
,
δ
) ( v1 , v 2 ,
δ
)
( v1 , v 2 , v 3 ,
α
,
β
,
δ
) ( v1 , v 2 ,
δ
)
β
,
δ
)
254
4 Planar parallel robots with uncoupled motions
Table 4.6. Structural parametersa of overconstrained PPMs in Figs. 4.7 and 4.8. No. Structural Solution parameter 2PaPR-1RC*C* (Fig. 4.7a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
12 6 6 3 15 4 1 2 3 see Table 4.5
2PaPR-1RC*Pass (Fig. 4.7b) 2PaPR-1RPassC* (Fig. 4.8a) 14 6 6 6 18 5 0 3 3 see Table 4.5
16 6 6 9 21 6 0 3 3 see Table 4.5
3 3 5 3 3 0 3 3 5 ( v1 , v 2 , 3 6 14 3 10 0 6
3 3 5 3 3 6 3 3 5 ( v1 , v 2 , 3 12 20 3 10 0 6
3 3 5 3 3 12 3 3 5 ( v1 , v 2 , 3 18 26 3 10 0 6
δ
)
δ
)
2PaPR-1RPassPass (Fig. 4.8b)
fj
6
6
6
fj
5
11
17
fj
17
23
29
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
4.1 Overconstrained solutions
255
Table 4.7. Structural parametersa of overconstrained PPMs in Figs. 4.9 and 4.10. No. Structural Solution parameter 2PaPR-1RPacsPacs (Fig. 4.9a) 2PaPR-1RPacsPatcs (Fig. 4.9b) 1 m 16 2 p1 6 3 p2 6 4 p3 9 5 p 21 6 q 6 7 k1 0 8 k2 3 9 k 3 10 (RGi) see Table 4.5 (i=1,2,3) 11 SG1 3 12 SG2 3 13 SG3 3 14 rG1 3 15 rG2 3 16 rG3 12 17 MG1 3 18 MG2 3 19 MG3 3 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 18 23 rF 24 24 MF 3 25 NF 12 26 TF 0 p1 27 6 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
PPR-PaPR-RC*C* (Fig. 4.10a)
PPR-PaPR-RC*Pass (Fig. 4.10b)
10 3 6 3 12 3 2 1 3 see Table 4.5
12 3 6 6 15 4 1 2 3 see Table 4.5
3 3 5 0 3 0 3 3 5 ( v1 , v 2 , 3 3 11 3 7 0 3
3 3 5 0 3 6 3 3 5 ( v1 , v 2 , 3 9 17 3 7 0 3
δ
)
fj
6
6
6
fj
15
5
11
fj
27
14
20
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
256
4 Planar parallel robots with uncoupled motions
Table 4.8. Structural parametersa of overconstrained PPMs in Figs. 4.11 and 4.12. No. Structural Solution parameter PPR-PaPR-RPassC* PPR-PaPR-RPassPass PPR-PaPR-RPacsPacs (Fig. 4.11a) (Fig. 4.12a) (Fig. 4.11b) PPR-PaPR-RPacsPatcs (Fig. 4.12b) 1 m 12 14 14 2 p1 3 3 3 3 p2 6 6 6 4 p3 6 9 9 5 p 15 18 18 6 q 4 5 5 7 k1 1 2 1 8 k2 2 1 2 9 k 3 3 3 10 (RGi) see Table 4.5 see Table 4.5 see Table 4.5 (i=1,2,3) 11 SG1 3 3 3 12 SG2 3 3 3 13 SG3 5 5 3 14 rG1 0 0 0 15 rG2 3 3 3 16 rG3 6 12 12 17 MG1 3 3 3 18 MG2 3 3 3 19 MG3 5 5 3 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 3 22 rl 9 15 15 23 rF 17 23 21 24 MF 3 3 3 25 NF 7 7 9 26 TF 0 0 0 p1 27 3 3 3 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
fj
6
6
6
fj
11
17
15
fj
20
26
24
See footnote of Table 2.4 for the nomenclature of structural parameters
4.1 Overconstrained solutions
257
Table 4.9. Structural parametersa of overconstrained PPMs in Figs. 4.13-4.15. No. Structural Solution parameter 2PassPC*-1RPP (Fig. 4.13a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
12 6 6 3 15 4 1 2 3 see Table 4.5
14 6 6 6 18 5 0 3 3 see Table 4.5
2PassC*C*-1RPaPa (Fig. 4.14b) 2PassPC*-1RPaPa (Fig. 4.15a) 2PassPC*-1RPaPat (Fig. 4.15b) 16 6 6 9 21 6 0 3 3 see Table 4.5
5 5 3 6 6 0 5 5 3 ( v1 , v 2 , 3 12 22 3 2 0 11
6 6 3 6 6 3 6 6 3 ( v1 , v 2 , 3 15 27 3 3 0 12
6 6 3 6 6 6 6 6 3 ( v1 , v 2 , 3 18 30 3 6 0 12
δ
)
2PassC*C*-1RPPa (Fig. 4.13b) 2PassC*C*-1RPaP (Fig. 4.14a)
δ
)
fj
11
12
12
fj
3
6
9
fj
25
30
33
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
258
4 Planar parallel robots with uncoupled motions
Table 4.10. Structural parametersa of overconstrained PPMs in Figs. 4.16-4.18. No. Structural Solution parameter PC*C*-PassC*C*RPP (Fig. 4.16a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
10 3 6 3 12 3 2 1 3 see Table 4.5
13 4 6 6 16 4 1 2 3 see Table 4.5
PR*C*C*-PassC*C*RPaPa (Fig. 4.17b) PR*C*C*-PassC*C*RPaPa (Fig. 4.18a) PR*C*C*-PassC*C*RPaPat (Fig. 4.18b) 15 4 6 9 19 5 1 2 3 see Table 4.5
5 6 3 0 6 0 5 6 3 ( v1 , v 2 , 3 9 17 3 1 0 5
6 6 3 0 6 3 6 6 3 ( v1 , v 2 , 3 0 21 3 3 0 6
6 6 3 0 6 6 6 6 3 ( v1 , v 2 , 3 12 24 3 6 0 6
δ
)
PR*C*C*-PassC*C*RPPa (Fig. 4.16b) PR*C*C*-PassC*C*RPaP (Fig. 4.17a)
δ
)
fj
12
12
12
fj
3
6
9
fj
20
24
27
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
4.1 Overconstrained solutions
259
Fig. 4.7. Overconstrained PPMs with uncoupled motions of types 2PaPR-1RC*C* (a) and 2PaPR-1RC*Pass (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=10, limb topology Pa ⊥ P ⊥ ||R and R ⊥ C* ⊥ ⊥ C* (a), R ⊥ C* ⊥ ||Pass (b)
260
4 Planar parallel robots with uncoupled motions
Fig. 4.8. Overconstrained PPMs with uncoupled motions of types 2PaPR1RPassC* (a) and 2PaPR-1RPassPass (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=10, limb topology Pa ⊥ P ⊥ ||R and R||Pass ⊥ C* (a), R||Pass||Pass (b)
4.1 Overconstrained solutions
261
Fig. 4.9. Overconstrained PPMs with uncoupled motions of types 2PaPR1RPacsPacs (a) and 2PaPR-1RPacsPatcs (b), defined by MF=SF=3, (RF)= ( v1 , v2 , δ ), TF=0, NF=12, limb topology Pa ⊥ P ⊥ ||R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
262
4 Planar parallel robots with uncoupled motions
Fig. 4.10. Overconstrained PPMs with uncoupled motions of types PPR-PaPRRC*C* (a) and PPR-PaPR-RC*Pass (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=7, limb topology P ⊥ P ⊥ ⊥ R, Pa ⊥ P ⊥ ||R and R ⊥ C* ⊥ ⊥ C* (a), R ⊥ C* ⊥ ||Pass (b)
4.1 Overconstrained solutions
263
Fig. 4.11. Overconstrained PPMs with uncoupled motions of types PPR-PaPRRPassC* (a) and PPR-PaPR-RPassPass (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=7, limb topology P ⊥ P ⊥ ⊥ R, Pa ⊥ P ⊥ ||R and R||Pass ⊥ C* (a), R||Pass||Pass (b)
264
4 Planar parallel robots with uncoupled motions
Fig. 4.12. Overconstrained PPMs with uncoupled motions of types PPR-PaPRRPacsPacs (a) and PPR-PaPR-RPacsPatcs (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9, limb topology P ⊥ P ⊥ ⊥ R, Pa ⊥ P ⊥ ||R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
4.1 Overconstrained solutions
265
Fig. 4.13. Overconstrained PPMs with uncoupled motions of types 2PassPC*1RPP (a) and 2PassC*C*-1RPPa (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2 (a), NF=3 (b), limb topology Pass ⊥ P ⊥ ||C* and R ⊥ P ⊥ ⊥ P (a), Pass ⊥ C* ⊥ ||C* and R ⊥ P ⊥ ||Pa (b)
266
4 Planar parallel robots with uncoupled motions
Fig. 4.14. Overconstrained PPMs with uncoupled motions of types 2PassC*C*1RPaP (a) and 2PassC*C*-1RPaPa (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3 (a), NF=6 (b), limb topology Pass ⊥ C* ⊥ ||C* and R||Pa ⊥ P (a), R||Pa||Pa (b)
4.1 Overconstrained solutions
267
Fig. 4.15. Overconstrained PPMs with uncoupled motions of types 2PassPC*1RPaPa (a) and 2PassPC*-1RPaPat (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology Pass ⊥ P ⊥ ||C* and R||Pa||Pa (a), R||Pa||Pat (b)
268
4 Planar parallel robots with uncoupled motions
Fig. 4.16. Overconstrained PPMs with uncoupled motions of types PC*C*PassC*C*-RPP (a) and PR*C*C*-PassC*C*-RPPa (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=1 (a), NF=3 (b), limb topology P||R* ⊥ C* ⊥ ⊥ C*, Pass ⊥ C* ⊥ ||C* and R ⊥ P ⊥ ⊥ P (a), R ⊥ P ⊥ ||Pa (b)
4.1 Overconstrained solutions
269
Fig. 4.17. Overconstrained PPMs with uncoupled motions of types PR*C*C*PassC*C*-RPaP (a) and PR*C*C*-PassC*C*-RPaPa (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3 (a), NF=6 (b), limb topology P||R* ⊥ C* ⊥ ⊥ C*, Pass ⊥ C* ⊥ ||C* and R||Pa ⊥ P (a), R||Pa||Pa (b)
270
4 Planar parallel robots with uncoupled motions
Fig. 4.18. Overconstrained PPMs with uncoupled motions of types PR*C*C*PassC*C*-RPaPa (a) and PR*C*C*-PassC*C*-RPaPat (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology P||R* ⊥ C* ⊥ ⊥ C*, Pass ⊥ C* ⊥ ||C* and R||Pa||Pa (a), R||Pa||Pat (b)
4.2 Non overconstrained solutions
271
4.2 Non overconstrained solutions Equation (1.15) indicates that non overconstrained solutions of planar parallel robots with uncoupled motions and q independent loops meet the p condition ∑ 1 f i = 3 + 6q along with MF=SF=3 and (RF)=( v1 ,v2 ,ωδ ). The non overconstrained solutions of planar parallel robots with uncoupled motions presented in this section (Figs. 4.19-4.24) are derived from overconstrained counterparts presented in Figs. 4.1-4.6 by introducing the required idle mobilities. For example, the non overconstrained solution in Fig. 4.19a is derived from the overconstrained solution in Fig. 4.1a by combining three idle mobilities in each parallelogram loop and three idle mobilities outside each parallelogram loop in limbs G1 and G2. Two idle mobilities are introduced in each limb in two cylindrical joints denoted by C*. The rotational motion is the idle mobility in the first cylindrical joint and the translational motion in the second cylindrical joint of the limb. We recall that one translational and two rotational idle mobilities are introduced in one cylindrical and one spherical joint of the the parallelogram and telescopic parallelogram loops denoted by Pacs and Patcs (Figs. 4.21 and 4.24). In the cylindrical joints of these loops, the translational motion is an idle mobility. In the parallelogram loop Pass-type, three idle mobilities are introduced in the loop and one outside the loop. If the link adjacent to the two spherical joints is a binary link than the idle mobility introduced outside the loop becomes an internal rotational mobility of this binary link around the axis passing by the centre of the two spherical joints. This internal mobility gives one degree of structural redundancy. If the link adjacent to the two spherical joints is connected in the limb by three or more joints (polinary link) than the rotational motion around the axis passing by the centre of the two spherical joints is an idle (potential) mobility of the limb. For example in Fig. 4.19b, this rotational motion is internal mobility of binary link 5C, and idle mobility for the ternary links 4A and 4B. Table 4.11. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 4.19-4.24 No. Parallel mechanism 1 Figs. 4.19-4.21, 4.22a, 4.23a, 4.24 2 Figs. 4.22b, 4.23b
Basis (RG1) ( v1 , v 2 , v 3 ,
α,
( v1 , v 2 , v 3 ,
β
,
β,
(RG2) ) δ ( v1 , v 2 , v 3 ,
)
( v1 , v 2 , v 3 ,
δ
α,
α
,
β,
β
,
(RG3) ) δ ( v1 , v 2 ,
δ
)
) ( v1 , v 2 ,
α
,
δ
δ
)
272
4 Planar parallel robots with uncoupled motions
The bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 4.19-4.24 are given in Table 4.11. The limb topology and connecting conditions of these solutions are systematized in Table 4.12, as are their structural parameters in Tables 4.13-4.15. Table 4.12. Limb topology of the non overconstrained PPMs presented in Figs. 4.19-4.24 No. Basic PPM Type 1 2PaPR-1RPP (Fig. 4.1a) 2 2PaPR-1RPPa (Fig. 4.1b) 3 2PaPR-1RPaP (Fig. 4.2a) 4 2PaPR-1RPaPa (Fig. 4.2b) 5 2PaPR-1RPaPa (Fig. 4.3a) 6 2PaPR-1RPaPat (Fig. 4.3b) 7 PPR-PaPR-RPP (Fig. 4.4a)
NF 12 15 15 18 18 18 9
8
PPR-PaPR-RPPa (Fig. 4.4b)
12
9
PPR-PaPR-RPaP (Fig. 4.5a)
12
10
PPR-PaPR-RPaPa 15 (Fig. 4.5b)
11
PPR-PaPR-RPaPa 15 (Fig. 4.6a)
12
PPR-PaPR-RPaPat 15 (Fig. 4.6b)
PPM with NF=0 Type 2PassC*C*-1RPP (Fig. 4.19a) 2PassC*C*-1RPPass (Fig. 4.19b) 2PassC*C*-1RPassP (Fig. 4.20a) 2PassC*C*-1RPassPass (Fig. 4.20b) 2PassC*C*-1RPacsPacs (Fig. 4.21a) 2PassC*C*-1RPacsPatcs (Fig. 4.21b) PR*C*C*-PassC*C*-RPP (Fig. 4.22a)
Limb topology Pass ⊥ C* ⊥ ||C* R ⊥ P ⊥⊥ P Pass ⊥ C* ⊥ ||C* R ⊥ P ⊥ ||Pass Pass ⊥ C* ⊥ ||C* R||Pass ⊥ P Pass ⊥ C* ⊥ ||C* R||Pass||Pass Pass ⊥ C* ⊥ ||C* R||Pacs||Pacs Pass ⊥ C* ⊥ ||C* R||Pacs||Patcs P||R* ⊥ C* ⊥ ⊥ C* Pass ⊥ C* ⊥ ||C* R ⊥ P ⊥⊥ P ss ss PC*C*-Pa C*C*-RPPa P ⊥ C* ⊥ ⊥ C* (Fig. 4.22b) Pass ⊥ C* ⊥ ||C* R ⊥ P ⊥ ||Pass ss ss PR*C*C*- Pa C*C*-RPa P P||R* ⊥ C* ⊥ ⊥ C* (Fig. 4.23a) Pass ⊥ C* ⊥ ||C* R||Pass ⊥ P ss ss ss PC*C*-Pa C*C*-RPa Pa P ⊥ C* ⊥ ⊥ C* (Fig. 4.23b) Pass ⊥ C* ⊥ ||C* R||Pass||Pass ss PR*C*C*- Pa C*C*P||R* ⊥ C* ⊥ ⊥ C* cs cs RPa Pa Pass ⊥ C* ⊥ ||C* (Fig. 4.24a) R||Pacs||Pacs ss PR*C*C*-Pa C*C*P||R* ⊥ C* ⊥ ⊥ C* cs tcs RPa Pa Pass ⊥ C* ⊥ ||C* (Fig. 4.24b) R||Pacs||Patcs
4.2 Non overconstrained solutions
273
Table 4.13. Structural parametersa of non overconstrained PPMs in Figs. 4.19 and 4.20 No. Structural Solution parameter 2PassC*C*-1RPP (Fig. 4.19a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
12 6 6 3 15 4 1 2 3 see Table 4.11
2PassC*C*-1RPPass (Fig. 4.19b) 2PassC*C*-1RPassP (Fig. 4.20a) 14 6 6 6 18 5 0 3 3 see Table 4.11
16 6 6 9 21 6 0 3 3 see Table 4.11
6 6 3 6 6 0 6 6 3 ( v1 , v 2 , 3 12 24 3 0 0 12
6 6 3 6 6 6 6 6 4 ( v1 , v 2 , 3 18 30 4 0 1 12
6 6 3 6 6 12 6 6 5 ( v1 , v 2 , 3 24 36 5 0 2 12
δ
)
δ
)
2PassC*C*-1RPassPass (Fig. 4.20b)
fj
12
12
12
fj
3
10
17
fj
27
34
41
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
274
4 Planar parallel robots with uncoupled motions
Table 4.14. Structural parametersa of non overconstrained PPMs in Figs. 4.21 and 4.22 No. Structural Solution parameter 2PassC*C*-1RPacsPacs (Fig. 4.21a) 2PassC*C*-1RPacsPatcs (Fig. 4.21b) 1 m 16 2 p1 6 3 p2 6 4 p3 9 5 p 21 6 q 6 7 k1 0 8 k2 3 9 k 3 10 (RGi) see Table 4.11 (i=1,2,3) 11 SG1 6 12 SG2 6 13 SG3 3 14 rG1 6 15 rG2 6 16 rG3 12 17 MG1 6 18 MG2 6 19 MG3 3 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 24 23 rF 36 24 MF 3 25 NF 0 26 TF 0 p1 27 12 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
PR*C*C*PassC*C*-RPP (Fig. 4.22a)
PC*C*PassC*C*-RPPass (Fig. 4.22b)
11 4 6 3 13 3 2 1 3 see Table 4.11
12 3 6 6 15 4 1 2 3 see Table 4.11
6 6 3 0 6 0 6 6 3 ( v1 , v 2 , 3 6 18 3 0 0 6
5 6 4 0 6 6 5 6 4 ( v1 , v 2 , 3 12 24 3 0 0 5
δ
)
δ
j
fj
12
12
12
fj
15
3
10
fj
39
21
27
See footnote of Table 2.4 for the nomenclature of structural parameters
)
4.2 Non overconstrained solutions
275
Table 4.15. Structural parametersa of non overconstrained PPMs in Figs. 4.23 and 4.24 No. Structural Solution parameter PR*C*C*PassC*C*RPassP (Fig. 4.23a) 1 m 13 2 p1 4 3 p2 6 4 p3 6 5 p 16 6 q 4 7 k1 1 8 k2 2 9 k 3 10 (RGi) see Table 4.11 (i=1,2,3) 11 SG1 6 12 SG2 6 13 SG3 3 14 rG1 0 15 rG2 6 16 rG3 6 17 MG1 6 18 MG2 6 19 MG3 4 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 12 23 rF 24 24 MF 4 25 NF 0 26 TF 1 p1 27 6 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
PC*C*PassC*C*RPassPass (Fig. 4.23b) 14 3 6 9 18 5 1 2 3 see Table 4.11
PR*C*C*-PassC*C*-RPacsPacs (Fig. 4.24a) PR*C*C*-PassC*C*-RPacsPatcs (Fig. 4.24b) 15 4 6 9 19 5 1 2 3 see Table 4.11
5 6 4 0 6 12 5 6 5 ( v1 , v 2 , 3 18 30 4 0 1 5
6 6 3 0 6 12 6 6 3 ( v1 , v 2 , 3 18 30 3 0 0 6
δ
)
δ
)
j
fj
12
12
12
fj
10
17
15
fj
28
34
33
See footnote of Table 2.4 for the nomenclature of structural parameters
276
4 Planar parallel robots with uncoupled motions
Fig. 4.19. Non overconstrained PPMs with uncoupled motions of types 2PassC*C*-1RPP (a) and 2PassC*C*-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ) and MF=3, NF=0, TF=0 (a), MF=4, NF=0, TF=1 (b), limb topology Pass ⊥ C* ⊥ ||C* and R ⊥ P ⊥ ⊥ P (a), R ⊥ P ⊥ ||Pass (b)
4.2 Non overconstrained solutions
277
Fig. 4.20. Non overconstrained PPMs with uncoupled motions of types 2PassC*C*-1RPassP (a) and 2PassC*C*-1RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ) and MF=4, NF=0, TF=1 (a), MF=5, NF=0, TF=2 (b), limb topology Pass ⊥ C* ⊥ ||C* and R||Pacs ⊥ P (a), R||Pass||Pass (b)
278
4 Planar parallel robots with uncoupled motions
Fig. 4.21. Non overconstrained PPMs with uncoupled motions of types 2PassC*C*-1RPacsPacs (a) and 2PassC*C*-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology Pass ⊥ C* ⊥ ||C* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
4.2 Non overconstrained solutions
279
Fig. 4.22. Non overconstrained PPMs with uncoupled motions of types PR*C*C*PassC*C*-RPP (a) and PC*C*-PassC*C*-RPPass (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology P||R* ⊥ C* ⊥ ⊥ C*, Pass ⊥ C* ⊥ ||C* and R ⊥ P ⊥ ⊥ P (a), P ⊥ C* ⊥ ⊥ C*, Pass ⊥ C* ⊥ ||C* and R ⊥ P ⊥ ||Pass (b)
280
4 Planar parallel robots with uncoupled motions
Fig. 4.23. Non overconstrained PPMs with uncoupled motions of types PR*C*C*PassC*C*-RPassP (a) and PC*C*-PassC*C*-RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology P||R* ⊥ C* ⊥ ⊥ C*, Pass ⊥ C* ⊥ ||C* and R||Pass ⊥ P (a), P ⊥ C* ⊥ ⊥ C*, Pass ⊥ C* ⊥ ||C* and R||Pass||Pass (b)
4.2 Non overconstrained solutions
281
Fig. 4.24. Non overconstrained PPMs with uncoupled motions of types PR*C*C*PassC*C*-RPacsPacs (a) and PR*C*C*-PassC*C*-RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology P||R* ⊥ C* ⊥ ⊥ C*, Pass ⊥ C* ⊥ ||C* and R||Pacs||Pacs (a), R||Pa cs||Pa tcs (b)
5 Maximally regular planar parallel robots
Maximally regular planar parallel robots are actuated by one rotating and two linear actuators and can have various degrees of overconstraint. In these solutions, the three operational velocities are equal to their corresponding actuated joint velocities: v1 = &q1 , v2 = &q2 and ωδ = &q3 . The Jacobian matrix in Eq. (1.18) is the identity matrix. We call planar Isoglide3-T2R1 the parallel mechanisms of this family.
5.1 Overconstrained solutions Equation (1.16) indicates that overconstrained solutions of maximally regular planar parallel robots with q independent loops meet the condition p ∑ 1 fi < 3 + 6q . Various solutions fulfil this condition along with MF=SF=3 and (RF)=( v1 ,v2 ,ωδ ). They have two identical limbs for positioning and a different limb for rotating the moving platform. 5.1.1 Basic solutions In the basic solutions of overconstrained maximally regular planar parallel robots, F ← G1-G2-G3, the moving platform n nGi (i=1, 2, 3) is connected to the reference platform 1 1Gi 0 by three limbs with three degrees of connectivity (Figs. 5.1-5.3). Two identical simple limbs (Fig. 2.1f) are used to position the moving platform and one simple (Fig. 2.1g) or complex (Figs. 2.2f-h and Fig. 2.3) limb to rotate it upon an axis of fixed or variable position. The solution in Fig 5.3a can provide an unlimited angle of rotation of the moving platform upon an axis of variable position. No idle mobilities exist in these basic solutions. The limb topologies and connecting conditions in the overconstrained maximally regular PPMs presented in Figs. 5.1-3.3 are systematized in Table 5.1 as are their structural parameters in Table 5.2.
G. Gogu, Structural Synthesis of Parallel Robots, Solid Mechanics and Its Applications 173, DOI 10.1007/978-90-481-9831-3_5, © Springer Science + Business Media B.V. 2010
283
284
5 Maximally regular planar parallel robots
Table 5.1. Limb topology and connecting conditions of the overconstrained maximally regular PPMs with no idle mobilities presented in Figs. 5.1-5.3 No. PPM type
Limb topology
Connecting conditions
1
2PPR-1RPP (Fig. 5.1a)
2
2PPR-1RPPa (Fig. 5.1b)
The directions of the revolute joints of the three limbs are parallel. The last revolute joint of limbs G1 and G2 have the same axis. Idem No. 1
3
2PPR-1RPaP (Fig. 5.2a)
4
2PPR-1RPaPa (Fig. 5.2b)
5
2PPR-1RPaPa (Fig. 5.3a)
6
2PPR-1RPaPat (Fig. 5.3b)
P ⊥ P ⊥⊥ R (Fig. 2.1f) R ⊥ P ⊥⊥ P (Fig. 2.1g) P ⊥ P ⊥⊥ R (Fig. 2.1f) R ⊥ P ⊥ ||Pa (Fig. 2.2f) P ⊥ P ⊥⊥ R (Fig. 2.1f) R||Pa ⊥ P (Fig. 2.2g) P ⊥ P ⊥⊥ R (Fig. 2.1f) R||Pa||Pa (Fig. 2.2h) P ⊥ P ⊥⊥ R (Fig. 2.1f) R||Pa||Pa (Fig. 2.3a) P ⊥ P ⊥⊥ R (Fig. 2.1f) R||Pa||Pat (Fig. 2.3b)
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
5.1 Overconstrained solutions
285
Table 5.2. Structural parametersa of maximally regular planar parallel mechanisms in Figs. 5.1-5.3 No. Structural Solution parameter 2PPR-1RPP (Fig. 5.1a)
1 2 3 4 5 6 7 8 9 10
m p1 p2 p3 p q k1 k2 k (RG1)
8 3 3 3 9 2 3 0 3 ( v1 , v 2 ,
11
(RG2)
12
(RG3)
13 14 15 16 17 18 19 20 21 22
SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
23 24 25 26 27 28 29
SF rl rF MF NF TF
( v1 , v2 , ( v1 , v2 , 3 3 3 0 0 0 3 3 3 ( v1 , v2 , 3 0 6 3 6 0 3
30 31 32 a
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
2PPR-1RPPa (Fig. 5.1b) 2PPR-1RPaP (Fig. 5.2a) 10 3 3 6 12 3 2 1 3 ( v1 , v2 , δ )
δ
)
( v1 , v2 ,
δ
)
δ
)
( v1 , v2 , 3 3 3 0 0 3 3 3 3 ( v1 , v2 , 3 3 9 3 9 0 3
δ
)
δ
)
δ
)
2PPR-1RPaPa (Fig. 5.2b) 2PPR-1RPaPa (Fig. 5.3a) 2PPR-1RPaPat (Fig. 5.3b) 12 3 3 9 15 4 2 1 3 ( v1 , v2 , ( v1 , v2 , ( v1 , v2 , 3 3 3 0 0 6 3 3 3 ( v1 , v2 , 3 6 12 3 12 0 3
fj
3
3
3
fj
3
6
9
fj
9
12
15
δ
)
δ
)
δ
)
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
286
5 Maximally regular planar parallel robots
Fig. 5.1. Overconstrained maximally regular PPMs of types 2PPR-1RPP (a) and 2PPR-1RPPa (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6 (a), NF=9 (b), limb topology P ⊥ P ⊥ ⊥ R and R ⊥ P ⊥ ⊥ P (a), R ⊥ P ⊥ ||Pa (b)
5.1 Overconstrained solutions
287
Fig. 5.2. Overconstrained maximally regular PPMs of types 2PPR-1RPaP (a) and 2PPR-1RPaPa (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9 (a), NF=12 (b), limb topology P ⊥ P ⊥ ⊥ R and R||Pa ⊥ P (a), R||Pa||Pa (b)
288
5 Maximally regular planar parallel robots
Fig. 5.3. Overconstrained maximally regular PPMs of types 2PPR-1RPaPa (a) and 2PPR-1RPaPat (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=12, limb topology P ⊥ P ⊥ ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
5.1 Overconstrained solutions
289
5.1.2 Derived solutions Solutions with lower degrees of overconstraint can be derived from the basic solutions in Figs. 5.1-5.3 by using joints with idle mobilities. A large set of solutions can be obtained by introducing one or two idle mobilities outside the planar loops and up to three idle mobilities in each planar loop combined in the limbs (Figs. 5.4-5.9). We recall that the joints combining idle mobilities are denoted by an asterisk. The idle mobilities which can be combined in a parallelogram loop are systematized in Fig. 1.2 and Table 1.1. The rotational mobility of the revolute joint denoted by R* is an idle mobility. One idle mobility is combined in each cylindrical joint C* and two idle mobilities in each spherical joint S*. In the cylindrical joint denoted by C* in Figs 5.4 and 5.5, the rotational motion is an idle mobility. In the limbs with two cylindrical joints C* in Figs. 5.7-5.9, the idle mobility is the rotational motion in the first cylindrical joint and the translational motion in the second one. The notation Pacs is associated with a parallelogram loop with three idle mobilities combined in a cylindrical and a spherical joint, and Pass with four idle mobilities combined in two spherical joints adjacent to the same coupler link. In the parallelogram loop Pass-type, three idle mobilities are introduced in the loop and one outside the loop. The idle mobility introduced outside the parallelogram loop is the internal mobility of the coupler link adjacent to the two spherical joints. Examples of solutions with 2 to 8 overconstraints derived from the basic solutions in Figs. 4.1-4.6 are illustrated in Figs. 5.4-5.9. The basis of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 5.4-5.9 are given in Table 5.3. The limb topology and connecting conditions of these solutions are systematized in Table 5.4 and the structural parameters of these solutions are presented in Tables 5.5-5.7.
290
5 Maximally regular planar parallel robots
Table 5.3. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 5.4-5.9 No. Parallel Basis mechanism (RG1) 1 Figs. 5.4, 5.5 ( v1 , v2 , 2
Fig. 5.6
3
Figs. 5.7, 5.8 ( v1 , v2 , v3 ,
β
,
δ
)
4
Fig. 5.9
α
,
β
,
( v1 , v 2 ,
δ
)
(RG2) ( v1 , v 2 ,
δ
)
( v1 , v 2 ,
( v1 , v 2 , v 3 ,
δ
δ
)
(RG3) ( v1 , v 2 ,
α
,
δ
)
( v1 , v 2 ,
δ
)
( v1 , v 2 ,
δ
)
) ( v1 , v 2 ,
δ
)
( v1 , v 2 , v 3 ,
α
,
δ
)
) ( v1 , v 2 , v 3 ,
α
,
β
,
δ
β
,
δ
)
Table 5.4. Limb topology and the number of overconstraints NF of the derived maximally regular PPMs with idle mobilities presented in Figs. 5.4-5.9 No. Basic PPM Type 1 2PPR-1RPP (Fig. 5.1a) 2 3
2PPR-1RPPa (Fig. 5.1b)
4 5
2PPR-1RPaP (Fig. 5.2a)
6 7
2PPR-1RPaPa (Fig. 5.2b)
8 9
2PPR-1RPaPa (Fig. 5.3a)
10 11 2PPR-1RPaPat (Fig. 5.3b) 12
Derived PPM NF Type 6 2PPR-1RC*C* (Fig. 5.4a) 2PC*C*-1RPP (Fig. 5.7a) 9 2PPR-1RC*Pass (Fig. 5.4b) 2PC*C*-1RPPass (Fig. 5.7b) 9 2PPR-1RPassC* (Fig. 5.5a) 2PC*C*-1RPaP (Fig. 5.8a) 12 2PPR-1RPassPass (Fig. 5.5b) 2PC*C*-1RPaPa (Fig. 5.8b) 12 2PPR-1RPacsPacs (Fig. 5.6a) 2PR*C*C*-1RPaPa (Fig. 5.9a) 12 2PPR-1RPacsPatcs (Fig. 5.6a) 2PR*C*C*-1RPaPat (Fig. 5.9a)
NF Limb topology 4 P ⊥ P ⊥⊥ R R ⊥ C* ⊥ ⊥ C* 2 P ⊥ C* ⊥ ⊥ C* R ⊥ P ⊥⊥ P 4 P ⊥ P ⊥⊥ R R ⊥ C* ⊥ ||Pass 1 P ⊥ C* ⊥ ⊥ C* R ⊥ P ⊥ ||Pass 4 P ⊥ P ⊥⊥ R R||Pass ⊥ C* 5 P ⊥ C* ⊥ ⊥ C* R||Pa ⊥ P 4 P ⊥ P ⊥⊥ R R||Pass||Pass 8 P ⊥ C* ⊥ ⊥ C* R||Pa||Pa 6 P ⊥ P ⊥⊥ R R||Pacs||Pacs 6 P||R ⊥ C* ⊥ ⊥ C* R||Pa||Pa 6 P ⊥ P ⊥⊥ R R||Pacs||Patcs 6 P||R ⊥ C* ⊥ ⊥ C* R||Pa||Pat
5.1 Overconstrained solutions Table 5.5. Structural parametersa of overconstrained PPMs in Figs. 5.4 and 5.5 No. Structural Solution parameter 2PPR-1RC*C* (Fig. 5.4a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
8 3 3 3 9 2 3 0 3 see Table 5.3
2PPR-1RC*Pass (Fig. 5.4b) 2PPR-1RPassC* (Fig. 5.5a) 10 3 3 6 12 3 2 1 3 see Table 5.3
12 3 3 9 15 4 2 1 3 see Table 5.3
3 3 5 0 0 0 3 3 5 ( v1 , v 2 , 3 0 8 3 4 0 3
3 3 5 0 0 6 3 3 5 ( v1 , v 2 , 3 6 14 3 4 0 3
3 3 5 0 0 12 3 3 5 ( v1 , v 2 , 3 12 20 3 4 0 3
δ
)
δ
)
2PPR-1RPassPass (Fig. 5.5b)
fj
3
3
3
fj
5
11
17
fj
11
17
23
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
291
292
5 Maximally regular planar parallel robots
Table 5.6. Structural parametersa of overconstrained PPMs in Figs. 5.6 and 5.7 No. Structural Solution parameter 2PPR-1RPacsPacs (Fig. 5.6a) 2PPR-1RPacsPatcs (Fig. 5.6b) 1 m 12 2 p1 3 3 p2 3 4 p3 9 5 p 15 6 q 4 7 k1 2 8 k2 1 9 k 3 10 (RGi) see Table 5.3 (i=1,2,3) 11 SG1 3 12 SG2 3 13 SG3 3 14 rG1 0 15 rG2 0 16 rG3 12 17 MG1 3 18 MG2 3 19 MG3 3 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 12 23 rF 18 24 MF 3 25 NF 6 26 TF 0 p1 27 3 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PC*C*-1RPP (Fig. 5.7a)
2PC*C*-1RPPass (Fig. 5.7b)
8 3 3 3 9 2 3 0 3 see Table 5.3
10 3 3 6 12 3 2 1 3 see Table 5.3
5 5 3 0 0 0 5 5 3 ( v1 , v 2 , 3 0 10 3 2 0 5
5 5 4 0 0 6 5 5 4 ( v1 , v 2 , 3 6 17 3 1 0 5
δ
)
fj
3
5
5
fj
15
3
10
fj
21
13
20
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
5.1 Overconstrained solutions
293
Table 5.7. Structural parametersa of overconstrained PPMs in Figs. 5.8 and 5.9 No. Structural Solution parameter 2PC*C*-1RPaP (Fig. 5.8a)
2PC*C*-1RPaPa (Fig. 5.8b)
1 2 3 4 5 6 7 8 9 10
10 3 3 6 12 3 2 1 3 see Table 5.3
12 3 3 9 15 4 2 1 3 see Table 5.3
2PR*C*C*-1RPaPa (Fig. 5.9a) 2PR*C*C*-1RPaPat (Fig. 5.9b) 14 4 4 9 17 4 2 1 3 see Table 5.3
5 5 3 0 0 3 5 5 3 ( v1 , v 2 , 3 3 13 3 5 0 5
5 5 3 0 0 6 5 5 3 ( v1 , v 2 , 3 6 16 3 8 0 5
6 6 3 0 0 6 6 6 3 ( v1 , v 2 , 3 6 18 3 6 0 6
11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
δ
)
fj
5
5
6
fj
6
9
9
fj
16
19
21
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
294
5 Maximally regular planar parallel robots
Fig. 5.4. Overconstrained maximally regular PPMs of types 2PPR-1RC*C* (a) and 2PPR-1RC*Pass (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=4, limb topology P ⊥ P ⊥ ⊥ R and R ⊥ C* ⊥ ⊥ C* (a), R ⊥ C* ⊥ ||Pass (b)
5.1 Overconstrained solutions
295
Fig. 5.5. Overconstrained maximally regular PPMs of types 2PPR-1RPassC* (a) and 2PPR-1RPassPass (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=4, limb topology P ⊥ P ⊥ ⊥ R and R||Pass ⊥ C* (a), R||Pass||Pass (b)
296
5 Maximally regular planar parallel robots
Fig. 5.6. Overconstrained maximally regular PPMs of types 2PPR-1RPacsPacs (a) and 2PPR-1RPacsPatcs (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology P ⊥ P ⊥ ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
5.1 Overconstrained solutions
297
Fig. 5.7. Overconstrained maximally regular PPMs of types 2PC*C*-1RPP (a) and 2PC*C*-1RPPass (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2 (a), NF=1 (b), limb topology P ⊥ C* ⊥ ⊥ C* and R ⊥ P ⊥ ⊥ P (a), R ⊥ P ⊥ ||Pass (b)
298
5 Maximally regular planar parallel robots
Fig. 5.8. Overconstrained maximally regular PPMs of types 2PC*C*-1RPaP (a) and 2PC*C*-1RPaPa (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=5 (a), NF=8 (b), limb topology P ⊥ C* ⊥ ⊥ C* and R||Pa ⊥ P (a), R||Pa||Pa (b)
5.1 Overconstrained solutions
299
Fig. 5.9. Overconstrained maximally regular PPMs of types 2PR*C*C*-1RPaPa (a) and 2PR*C*C*-1RPaPat (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology P||R ⊥ C* ⊥ ⊥ C* and R||Pa||Pa (a), R||Pa||Pat (b)
300
5 Maximally regular planar parallel robots
5.2 Non overconstrained solutions Equation (1.15) indicates that non overconstrained solutions of maximally regular planar parallel robots with q independent loops meet the condition p ∑ 1 fi = 3 + 6q along with MF=SF=3 and (RF)=( v1 ,v2 ,ωδ ). The non overconstrained solutions of maximally regular planar parallel robots presented in this section (Figs. 5.10-5.12) are derived from overconstrained counterparts presented in Figs. 5.1-5.3 by introducing the required idle mobilities. For example, the non overconstrained solution in Fig. 5.10a is derived from the overconstrained solution in Fig. 5.1a by combining three idle mobilities in each limb G1 and G2. They are introduced in one revolute and two cylindrical joints denoted by R* and C*. The rotational motion is the idle mobility in the first cylindrical joint and the translational motion in the second cylindrical joint of the limb. We recall that one translational and two rotational idle mobilities are introduced in one cylindrical and one spherical joint of the the parallelogram and telescopic parallelogram loops denoted by Pacs and Patcs (Figs. 5.3, 5.6, 5.9 and 5.12). In the cylindrical joints of these loops, the translational motion is an idle mobility. In the parallelogram loop Passtype four idle mobilities are combined in two spherical joints adjacent to the same link. Three idle mobilities are introduced in the loop and one outside the loop. If the link adjacent to the two spherical joints is a binary link than the idle mobility introduced outside the loop becomes an internal rotational mobility of the binary link around the axis passing by the centre of the two spherical joints. This is the case of binary links 4C (Fig. 5.11a) and 3C, 6C (Fig. 5.11b). Each internal mobility gives one degree of structural redundancy. If the link adjacent to the two spherical joints is connected in the limb by three or more joints (polinary link) than the rotational motion around the axis passing by the centre of the two spherical joints is an idle (potential) mobility of the limb. This is the case of link 6 in Fig. 5.10b. The basis of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 5.10-5.12 are given in Table 5.8. The limb topology and connecting conditions of these solutions are systematized in Table 5.9 and the structural parameters of these solutions are presented in Tables 5.10 and 5.11.
5.2 Non overconstrained solutions
301
Table 5.8. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 5.10-5.12 No. Parallel mechanism 1 Figs. 5.10a 5.11, 5.12 2 Figs. 5.10b
Basis (RG1) ( v1 , v 2 , v 3 ,
α,
( v1 , v 2 , v 3 ,
β
,
β,
(RG2) ) δ ( v1 , v 2 , v 3 ,
)
( v1 , v 2 , v 3 ,
δ
α,
α
,
β,
β
,
(RG3) ) δ ( v1 , v 2 ,
δ
)
) ( v1 , v 2 ,
α
,
δ
δ
)
Table 5.9. Limb topology of the non overconstrained maximally regular PPMs presented in Figs. 5.10-5.12 No. Basic PPM Type 1 2PPR-1RPP (Fig. 5.1a) 2 2PPR-1RPPa (Fig. 5.1b) 3 4 5 6
2PPR-1RPaP (Fig. 5.2a) 2PPR-1RPaPa (Fig. 5.2b) 2PPR-1RPaPa (Fig. 5.3a) 2PPR-1RPaPat (Fig. 5.3b)
NF 6 9
9 12 12 12
PPM with NF =0 Type 2PR*C*C*-1RPP (Fig. 5.10a) PC*C*-PR*C*C*-RPPass (Fig. 5.10b) 2PR*C*C*-1RPacsP (Fig. 5.11a) 2PR*C*C*-1RPacsPacs (Fig. 5.11b) 2PR*C*C*-1RPacsPacs (Fig. 5.12a) 2PR*C*C*-1RPacsPatcs (Fig. 5.12b)
Limb topology P||R* ⊥ C* ⊥ ⊥ C* R ⊥ P ⊥⊥ P P ⊥ C* ⊥ ⊥ C* P||R* ⊥ C* ⊥ ⊥ C* R ⊥ P ⊥ ||Pass P||R* ⊥ C* ⊥ ⊥ C* R||Pacs ⊥ P P||R* ⊥ C* ⊥ ⊥ C* R||Pacs||Pacs P||R* ⊥ C* ⊥ ⊥ C* R||Pacs||Pacs P||R* ⊥ C* ⊥ ⊥ C* R||Pacs||Patcs
302
5 Maximally regular planar parallel robots
Table 5.10. Structural parametersa of non overconstrained PPMs in Fig. 5.10 No.
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 a
Structural parameter m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PR*C*C*-1RPP (Fig. 5.10a) 10 4 4 3 11 2 3 0 3 see Table 5.8
PC*C*-PR*C*C*-RPPass (Fig. 5.10b) 11 3 4 6 13 3 2 1 3 see Table 5.8
6 6 3 0 0 0 6 6 3 ( v1 , v 2 , 3 0 12 3 0 0 6
5 6 4 0 0 6 5 6 3 ( v1 , v 2 , 3 6 18 3 0 0 5
δ
)
fj
6
6
fj
3
10
fj
15
21
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
5.2 Non overconstrained solutions
303
Table 5.11. Structural parametersa of non overconstrained PPMs in Figs. 5.11 and 5.12 No. Structural Solution parameter 2PR*C*C*1RPassP (Fig. 5.11a) 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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PR*C*C*-1RPassPass 2PR*C*C*-1RPacsPacs (Fig. 5.11b) (Fig. 5.12a) 2PPR-1RPacsPatcs (Fig. 5.12b) 12 14 14 4 4 4 4 4 4 6 9 9 14 17 17 3 4 4 2 2 2 1 1 1 3 3 3 see Table 5.8 see Table 5.8 see Table 5.8 6 6 3 0 0 6 6 6 4 ( v1 , v 2 , 3 6 18 4 0 1 6
δ
)
6 6 3 0 0 12 6 6 5 ( v1 , v 2 , 3 6 24 5 0 2 6
δ
)
6 6 3 0 0 12 6 6 3 ( v1 , v 2 , 3 6 24 3 0 0 6
fj
6
6
6
fj
10
17
15
fj
22
29
27
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
304
5 Maximally regular planar parallel robots
Fig. 5.10. Non overconstrained maximally regular PPMs of types 2PR*C*C*1RPP (a) and PC*C*-PR*C*C*-RPPass (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology P||R* ⊥ C* ⊥ ⊥ C*, R ⊥ P ⊥ ⊥ P (a) and P ⊥ C* ⊥ ⊥ C*, P||R* ⊥ C* ⊥ ⊥ C*, R ⊥ P ⊥ ||Pass (b)
5.2 Non overconstrained solutions
305
Fig. 5.11. Non overconstrained maximally regular PPMs of types 2PR*C*C*1RPassP (a) and 2PR*C*C*-1RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0, and MF=4, TF=1 (a), MF=5, TF=2 (b), limb topology P||R* ⊥ C* ⊥ ⊥ C* and R||Pass ⊥ P (a), R||Pass||Pass (b)
306
5 Maximally regular planar parallel robots
Fig. 5.12. Non overconstrained maximally regular PPMs of types 2PR*C*C*1RPacsPacs (a) and 2PR*C*C*-1RPacsPatcs (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology P||R* ⊥ C* ⊥ ⊥ C* and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
6 Spatial PMs with coupled planar motion of the moving platform
The solutions of spatial parallel mechanism with planar motion of the moving platform have in their structure at least one spatial limb. In the general case, in a spatial parallel robotic manipulator (SPM) with coupled planar motions of the moving platform each operational velocity depends in the general case on three actuated joint velocities. In this section we focus on the solutions with decoupled rotation of the moving platform & 2 ) , v2 = v2 ( &q1 ,q & 2 ) and ωδ = ωδ ( &q3 ) . In these solutions, with v1 = v1 ( &q1 ,q the Jacobian matrix in Eq. (6.1) is not triangular and the parallel robot is considered with coupled motions. They have just a few partially decoupled motions.
6.1 Overconstrained solutions The overconstrained solutions of SPMs with coupled planar motions of the moving platform and q independent loops meet the condition p ∑ 1 fi < 3 + 6q . The limbs can be simple or complex kinematic chains and the actuators can be mounted on the fixed base or on a moving link. Basic and derived fully-parallel solutions are presented in this section. 6.1.1 Basic solutions In the basic fully-parallel solutions of SPMs with coupled motions F ← G1G2-G3 presented in this section, the moving platform n nGi (i=1, 2, 3) is connected to the reference platform 1 1Gi 0 by three limbs. One actuator is combined in a revolute or prismatic pair of each limb. Two identical planar limbs G1 and G2 are used for positioning the moving platform and a spatial limb G3 for orienting it. There are no idle mobilities in these basic solutions.
G. Gogu, Structural Synthesis of Parallel Robots, Solid Mechanics and Its Applications 173, DOI 10.1007/978-90-481-9831-3_6, © Springer Science + Business Media B.V. 2010
307
308 6 Spatial PMs with coupled planar motion of the moving platform
The various types of simple and complex planar limbs with three degrees of connectivity used in the basic solutions illustrated in this section are presented in Figs. 2.1a-c and 2.2a-c. The simple limbs combine only revolute and prismatic joints. One (Fig. 2.2a,c) or two (Figs. 2.2b) planar parallelogram loops are combined in these planar complex limbs. The various types of simple and complex spatial limbs used in the basic solutions illustrated in this section are presented in Fig. 6.1. The simple limb in Fig. 6.1a has six degrees of connectivity and combines just revolute and prismatic joints in a double universal joint with telescopic intermediary shaft. Three planar parallelogram loops are combined in the spatial complex limbs with four degrees of connectivity in Fig. 6.1band c. Various solutions of SPMs with coupled planar motion of the moving platform and no idle mobilities can be obtained by using G1- and G2-limbs with identical or different topology presented in Figs. 2.1a-c and 2.2a-c and a spatial G3-limb in Fig. 6.1. Only solutions with identical G1- and G2-limbs are illustrated in Figs. 6.2-6.16. The revolute joints in G1- and G2-limbs have parallel axes and the directions of the prismatic joints are parallel to a plane perpendicular to the rotation axes of the revolute joints. The actuated revolute joint in G3-limb is perpendicular to the translation plane of the moving platform. The actuators are mounted on the fixed base excepting the solutions in Figs. 6.3, 6.10 and 6.11 in which the linear actuators are mounted on a moving link. The limb topology and connecting conditions of the solutions in Figs. 6.2-6.16 are systematized in Table 6.1, as are their structural parameters in Tables 6.2 and 6.3. The solutions in Figs. 6.2-6.16 give a decoupled and unlimited rotational motion of the moving platform.
6.1 Overconstrained solutions
309
Fig. 6.1. Simple (a) and complex limbs (b-c) with MG=SG=6 (a) and MG=SG=4 (b) for SPMs with planar motion of the moving platform
310 6 Spatial PMs with coupled planar motion of the moving platform Table 6.1. Limb topology and connecting conditions of the overconstrained SPM with no idle mobilities presented in Figs. 6.2-6.16 No. SPM type
Limb topology
Connecting conditions
1
2PRR-1RRRPRR (Fig. 6.2a)
P ⊥ R||R (Fig. 2.1c) R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (Fig. 6.1a)
2
2RRR-1RRRPRR (Fig. 6.2b)
3
2RPR-1RRRPRR (Fig. 6.3)
4
2PPaR-1RRRPRR (Fig. 6.4)
5
2PaRR-1RRRPRR (Fig. 6.5a)
6
2PaPaR-1RRRPRR (Fig. 6.5b)
7
2PRR-1RPaPaPa (Fig. 6.6a)
8
2PRR-1RPaPaPa (Fig. 6.6b)
9
2PRR-1RPaPaPa (Fig. 6.7)
R||R||R (Fig. 2.1a) R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (Fig. 6.1a) R ⊥ P ⊥ ||R (Fig. 2.1b) R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (Fig. 6.1a) P ⊥ Pa||R (Fig. 2.2c) R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (Fig. 6.1a) Pa||R||R (Fig. 2.2a) R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (Fig. 6.1a) Pa||Pa||R (Fig. 2.2b) R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (Fig. 6.1a) P ⊥ R||R (Fig. 2.1c) R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (Fig. 6.1b) P ⊥ R||R (Fig. 2.1c) R ⊥ Pa ⊥ ⊥ Pa||Pa (Fig. 6.1c) P ⊥ R||R (Fig. 2.1c) R ⊥ Pa||Pa ⊥ ⊥ Pa (Fig. 6.1d)
The directions of the revolute joints of limbs G1 and G2 are parallel. The last revolute joints of limbs G1 and G2 have superposed axes. Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
6.1 Overconstrained solutions Table 6.1. (cont.) 10
2RRR-1RPaPaPa (Fig. 6.8)
11
2RRR-1RPaPaPa (Fig. 6.9a)
12
2RRR-1RPaPaPa (Fig. 6.9b)
13
2RPR-1RPaPaPa (Fig. 6.10a)
14
2RPR-1RPaPaPa (Fig. 6.10b)
15
2RPR-1RPaPaPa (Fig. 6.11)
16
2PPaR-1RPaPaPa (Fig. 6.12)
17
2PPaR-1RPaPaPa (Fig. 6.13a)
18
2PPaR-1RPaPaPa (Fig. 6.13b)
19
2PaRR-1RPaPaPa (Fig. 6.14a)
R||R||R (Fig. 2.1a) R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (Fig. 6.1b) R||R||R (Fig. 2.1a) R ⊥ Pa ⊥ ⊥ Pa||Pa (Fig. 6.1c) R||R||R (Fig. 2.1a) R ⊥ Pa||Pa ⊥ ⊥ Pa (Fig. 6.1d) R ⊥ P ⊥ ||R (Fig. 2.1b) R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (Fig. 6.1b) R ⊥ P ⊥ ||R (Fig. 2.1b) R ⊥ Pa ⊥ ⊥ Pa||Pa (Fig. 6.1c) R ⊥ P ⊥ ||R (Fig. 2.1b) R ⊥ Pa||Pa ⊥ ⊥ Pa (Fig. 6.1d) P ⊥ Pa||R (Fig. 2.2c) R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (Fig. 6.1b) P ⊥ Pa||R (Fig. 2.2c) R ⊥ Pa ⊥ ⊥ Pa||Pa (Fig. 6.1c) P ⊥ Pa||R (Fig. 2.2c) R ⊥ Pa||Pa ⊥ ⊥ Pa (Fig. 6.1d) Pa||R||R (Fig. 2.2a) R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (Fig. 6.1b)
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
311
312 6 Spatial PMs with coupled planar motion of the moving platform Table 6.1. (cont.) 20
2PaRR-1RPaPaPa (Fig. 6.14b)
21
2PaRR-1RPaPaPa (Fig. 6.15a)
22
2PaPaR-1RPaPaPa (Fig. 6.15b)
23
2PaPaR-1RPaPaPa (Fig. 6.16a)
24
2PaPaR-1RPaPaPa (Fig. 6.16b)
Pa||R||R (Fig. 2.2a) R ⊥ Pa ⊥ ⊥ Pa ||Pa (Fig. 6.1c) Pa||R||R (Fig. 2.2a) R ⊥ Pa||Pa ⊥ ⊥ Pa (Fig. 6.1d) Pa||Pa||R (Fig. 2.2b) R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (Fig. 6.1b) Pa||Pa||R (Fig. 2.2a) R ⊥ Pa ⊥ ⊥ Pa||Pa (Fig. 6.1c) Pa||Pa||R (Fig. 2.2a) R ⊥ Pa||Pa ⊥ ⊥ Pa (Fig. 6.1d)
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
6.1 Overconstrained solutions
313
Table 6.2. Structural parametersa of spatial parallel mechanisms in Figs. 6.2-6.5 No. Structural Solution parameter 2PRR-1RRRPRR 2RRR-1RRRPRR (Fig. 6.2a,b) 2RPR-1RRRPRR (Fig. 6.3) 1 m 11 2 p1 3 3 p2 3 4 p3 6 5 p 12 6 q 2 7 k1 3 8 k2 0 9 k 3 10 (RG1) ( v1 , v 2 , δ ) 11 (RG2) ( v1 , v 2 , δ ) 12
(RG3)
( v1 , v 2 , v 2 ,
13 14 15 16 17 18 19 20 21 22
SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
23 24 25 26 27 28 29
SF rl rF MF NF TF
3 3 6 0 0 0 3 3 6 ( v1 , v 2 , 3 0 9 3 3 0 3
30 31 32 a
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
α,
)
β,
δ
2PPaR-1RRRPRR (Fig. 6.4) 2PaRR-1RRRPRR (Fig. 6.5a)
2PaPaR-1RRRPRR (Fig. 6.5b)
15 6 6 6 18 4 1 2 3 ( v1 , v2 , ( v1 , v2 ,
19 9 9 6 24 6 1 2 3 ( v1 , v2 , ( v1 , v2 ,
δ
)
δ
)
)( v1 , v2 , v2 , 3 3 6 3 3 0 3 3 6 ( v1 , v2 , 3 6 15 3 9 0 6
δ
α,
)
β,
δ
δ
)
δ
)
)( v1 , v2 , v2 , 3 3 6 6 6 0 3 3 6 ( v1 , v2 , 3 12 21 3 15 0 9
fj
3
6
9
fj
6
6
6
fj
12
18
24
δ
α
)
See footnote of Table 2.4 for the nomenclature of structural parameters
,
β
,
δ
)
314 6 Spatial PMs with coupled planar motion of the moving platform Table 6.3. Structural parametersa of spatial parallel mechanisms in Figs. 6.6-6.16 No. Structural Solution parameter 2PRR-1RPaPaPa 2RRR-1RPaPaPa 2RPR-1RPaPaPa (Figs. 6.6-6.11) 1 2 3 4 5 6 7 8 9 10
m p1 p2 p3 p q k1 k2 k (RG1)
11
(RG2)
12
(RG3)
13 14 15 16 17 18 19 20 21 22
SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
23 24 25 26 27 28 29
SF rl rF MF NF TF
30 31 32 a
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
15 3 3 13 19 5 2 1 3 ( v1 , v 2 , ( v1 , v 2 ,
δ
)
δ
)
2PPaR-1RPaPaPa 2PaRR-1RPaPaPa (Figs. 6.12-6.14, 6.15a)
2PaPaR-1RPaPaPa (Figs. 6.15b, 6.16)
19 6 6 13 25 7 0 3 3 ( v1 , v2 , ( v1 , v2 ,
23 9 9 13 31 9 0 3 3 ( v1 , v2 , ( v1 , v2 ,
δ
)
δ
)
δ
)
δ
)
( v1 , v 2 , v 2 , δ ) 3 3 4 0 0 9 3 3 4 ( v1 , v 2 , δ ) 3 9 16 3 14 0 3
( v1 , v 2 , v 2 , δ ) 3 3 4 3 3 9 3 3 4 ( v1 , v2 , δ ) 3 15 22 3 20 0 6
( v1 ,v2 , v2 , δ ) 3 3 4 6 6 9 3 3 4 ( v1 , v2 , δ ) 3 21 28 3 26 0 9
fj
3
6
9
fj
13
13
13
fj
19
25
31
fj
See footnote of Table 2.4 for the nomenclature of structural parameters
6.1 Overconstrained solutions
315
Fig. 6.2. Overconstrained SPMs with planar motion of the moving platform of types 2PRR-1RRRPRR (a) and 2RRR-1RRRPRR (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R and P ⊥ R||R (a), R||R||R (b)
316 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.3. 2RPR-1RRRPRR-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R ⊥ P ⊥ ||R and R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R
Fig. 6.4. 2PPaR-1RRRPRR-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9, limb topology P ⊥ Pa||R and R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R
6.1 Overconstrained solutions
317
Fig. 6.5. Overconstrained SPMs with planar motion of the moving platform of types 2PaRR-1RRRPRR (a) and 2PaPaR-1RRRPRR (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9 (a), NF=15 (b), limb topology R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R and Pa||R||R (a), Pa||Pa||R (b)
318 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.6. 2PRR-1RPaPaPa-type overconstrained SPMs with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology P ⊥ R||R and R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (a), R ⊥ Pa ⊥ ⊥ Pa||Pa (b)
6.1 Overconstrained solutions
319
Fig. 6.7. 2PRR-1RPaPaPa-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology P ⊥ R||R and R ⊥ Pa||Pa ⊥ ⊥ Pa
Fig. 6.8. 2RRR-1RPaPaPa-type overconstrained SPMs with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology R||R||R and R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa
320 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.9. 2RRR-1RPaPaPa-type overconstrained SPMs with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology R||R||R and R ⊥ Pa ⊥ ⊥ Pa||Pa (a), R ⊥ Pa||Pa ⊥ ⊥ Pa (b)
6.1 Overconstrained solutions
321
Fig. 6.10. 2RPR-1RPaPaPa-type overconstrained SPMs with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology R ⊥ P ⊥ ||R and R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (a), R ⊥ Pa ⊥ ⊥ Pa||Pa (b)
322 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.11. 2RPR-1RPaPaPa-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology R ⊥ P ⊥ ||R and R ⊥ Pa||Pa ⊥ ⊥ Pa
Fig. 6.12. 2PPaR-1RPaPaPa-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology P ⊥ Pa||R and R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa
6.1 Overconstrained solutions
323
Fig. 6.13. 2PPaR-1RPaPaPa-type overconstrained SPMs with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology P ⊥ Pa||R and R ⊥ Pa ⊥ ⊥ Pa||Pa (a), R ⊥ Pa||Pa ⊥ ⊥ Pa (b)
324 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.14. 2PaRR-1RPaPaPa-type overconstrained SPMs with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology Pa||R||R and R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (a), R ⊥ Pa ⊥ ⊥ Pa||Pa (b)
6.1 Overconstrained solutions
325
Fig. 6.15. Overconstrained SPMs with planar motion of the moving platform pf types 2PaRR-1RPaPaPa (a) and 2PaPaR-1RPaPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20 (a), NF=26 (b), limb topology Pa||R||R and R ⊥ Pa||Pa ⊥ ⊥ Pa (a), Pa||Pa||R and R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (b)
326 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.16. 2PaPaR-1RPaPaPa-type overconstrained SPMs with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=26, limb topology Pa||Pa||R and R ⊥ Pa ⊥ ⊥ Pa||Pa (a), R ⊥ Pa||Pa ⊥ ⊥ Pa (b)
6.1 Overconstrained solutions
327
6.1.2 Derived solutions Solutions with lower degrees of overconstraint can be derived from the basic solutions in Figs. 6.2-6.16 by using joints with idle mobilities. One or two idle mobilities can be introduced in the solutions in Figs. 6.2 and 6.3a. A large set of solutions can be obtained by introducing up to three idle mobilities in each planar parallelogram loop and up to three idle mobilities outside the planar loops combined in the limbs in Figs. 6.4b and 6.5. Up to five idle mobilities can be introduced outside the planar loops combined in the limbs in Figs. 6.6-6.16. Examples of solutions with 1-7 overconstraints derived from the basic solutions in Figs. 6.2-6.16 are illustrated in Figs. 6.17-6.31. We recall that the joints combining idle mobilities are denoted by an asterisk. The idle mobilities which can be combined in a parallelogram loop are systematized in Fig. 1.2 and Table 1.1. The rotational mobility of the revolute joint denoted by R* is an idle mobility. One idle mobility is combined in each cylindrical joint C* and two idle mobilities in each spherical joint S*. For example, in the cylindrical joint denoted by C* in Figs. 6.216.31, the idle mobility is the rotational motion. In the parallelogram loop Pass-type, three idle mobilities are introduced in the loop and one outside the loop. The idle mobility introduced outside the parallelogram loop becomes an internal mobility of the links adjacent to the two spherical joints – see for example links 3A and 3B in Figs. 6.20a, 6.29-6.31. In these cases, the parallel robot has two degrees of structural redundancy. Table 6.4. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 6.17-6.31 No. Parallel mechanism 1 Figs. 6.17, 6.18 2 Figs. 6.19, 6.20b 3 Fig. 6.20a 4 5
6
Basis (RG1) ( v1 , v 2 ,
α,
( v1 , v 2 ,
β
,
( v1 , v 2 ,
δ
Figs. ( v1 , v 2 , 6.21-6.26 Figs. ( v1 , v 2 , 6.27, 6.28 6.30b, 6.31 Figs. 6.29, ( v1 , v2 , 6.30a
β ,
(RG2) ) ( v1 , v2 , δ
δ
)
)
( v1 , v 2 ,
α
,
)
( v1 , v 2 ,
δ
)
δ
)
( v1 , v 2 , v 3 ,
α
,
β
,
β
,
( v1 , v 2 , v 3 ,
α
,
δ
)
δ
)
( v1 , v 2 , v 3 ,
δ
)
δ
δ
)
δ
)
δ
(RG3) ( v1 , v 2 , v 3 ,
α
,
β
,
δ
)
( v1 , v 2 , v 3 ,
α
,
β
,
δ
)
( v1 , v 2 , v 3 ,
α
,
β
,
δ
)
) ( v1 , v 2 , v 3 ,
α
,
β
,
δ
)
( v1 , v 2 , v 3 ,
α
,
β
,
δ
)
( v1 , v 2 , v 3 ,
α
,
β
,
δ
)
328 6 Spatial PMs with coupled planar motion of the moving platform Table 6.5. Limb topology and the number of overconstraints NF of the derived SPMs with idle mobilities presented in Figs. 6.17-6.31 No. Basic SPM Type 1 2PRR-1RRRPRR (Fig. 6.2a)
Derived SPM NF Type 3 PS*R-PRR-RRRPRR (Fig. 6.17a)
2
2RRR-1RRRPRR (Fig. 6.2b)
3
RS*R-RRR-RRRPRR (Fig. 6.17b)
3
2RPR-1RRRPRR (Fig. 6.3)
3
S*PR-RPR-RRRPRR (Fig. 6.18)
4
2PPaR-1RRRPRR (Fig. 6.4) 2PaRR-1RRRPRR (Fig. 6.5a) 2PaPaR-1RRRPRR (Fig. 6.5b) 2PRR-1RPaPaPa (Fig. 6.6a)
9
2PPassR-1RRRPRR (Fig. 6.19) 2PassRR-1RRRPRR (Fig. 6.20a) 2PaPassR-1RRRPRR (Fig. 6.20b) PRR-PS*C*RPaPassPass (Fig. 6.21a) PRR-PS*C*RPassPaPass (Fig. 6.21b) PRR-PS*C*RPaPassPass (Fig. 6.22) RRR-RS*C*RPaPassPass (Fig. 6.23) RRR-RS*C*RPassPaPass (Fig. 6.24a) RRR-RS*C*RPaPassPass (Fig. 6.24b) RPR-S*PC*RPaPassPass (Fig. 6.25a) RPR-S*PC*RPassPaPass (Fig. 6.25b)
5 6 7
9 15 14
8
2PRR-1RPaPaPa (Fig. 6.6b)
14
9
2PRR-1RPaPaPa (Fig. 6.7)
14
10 2RRR-1RPaPaPa (Fig. 6.8)
14
11 2RRR-1RPaPaPa (Fig. 6.9a)
14
12 2RRR-1RPaPaPa (Fig. 6.9b)
14
13 2RPR-1RPaPaPa (Fig. 6.10a)
14
14 2RPR-1RPaPaPa (Fig. 6.10b)
14
NF Limb topology 1 PS*R P ⊥ R||R R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R 1 RS*R R||R||R R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R 1 SP ⊥ R R ⊥ P ⊥ ||R R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R 1 P ⊥ Pass||R R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R 3 Pass||R||R R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R 7 Pa||Pass||R R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R 3 P ⊥ R||R PS*C* R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass 3 P ⊥ R||R PS*C* R ⊥ Pass ⊥ ⊥ Pa||Pass 3 P ⊥ R||R PS*C* R ⊥ Pa||Pass ⊥ ⊥ Pass 3 R||R||R RS*C* R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass 3 R||R||R RS*C* R ⊥ Pass ⊥ ⊥ Pa||Pass 3 R||R||R RS*C* R ⊥ Pa||Pass ⊥ ⊥ Pass 3 R ⊥ P ⊥ ||R S*P ⊥ C* R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass 3 R ⊥ P ⊥ ||R S*P ⊥ C* R ⊥ Pass ⊥ ⊥ Pa||Pass
6.1 Overconstrained solutions
329
Table 6.5. (cont.) 14 RPR-S*PC*RPaPassPass (Fig. 6.26) 2PPaR-1RPaPaPa 20 PPassR-PPassC*(Fig. 6.12) RPaPassPass (Fig. 6.27) 2PPaR-1RPaPaPa 20 PPassR-PPassC*(Fig. 6.13a) RPassPaPass (Fig. 6.28a) 2PPaR-1RPaPaPa 20 PPassR-PPassC*(Fig. 6.13b) RPaPassPass (Fig. 6.28b) 2PaRR-1RPaPaPa 20 PassRR-PassRC*(Fig. 6.14a) RPaPassPass (Fig. 6.29a) 2PaRR-1RPaPaPa 20 PassRR-PassRC*(Fig. 6.14b) RPassPaPass (Fig. 6.29b) 2PaRR-1RPaPaPa 20 PassRR-PassRC*(Fig. 6.15a) RPaPassPass (Fig. 6.30a) 2PaPaR-1RPaPaPa 26 PassPassR-PassPassC*(Fig. 6.15b) RPaPassPass (Fig. 6.30b) 2PaPaR-1RPaPaPa 26 PassPassR-PassPassC*(Fig. 6.16a) RPassPaPass (Fig. 6.31a) 2PaPaR-1RPaPaPa 26 PassPassR-PassPassC*(Fig. 6.16b) RPaPassPass (Fig. 6.31b)
15 2RPR-1RPaPaPa (Fig. 6.11)
3
16
3
17
18
19
20
21
22
23
24
3
3
5
5
5
3
3
3
R ⊥ P ⊥ ||R SP ⊥ C* R ⊥ Pa||Pass ⊥ ⊥ Pass P ⊥ Pass||R P ⊥ Pass||C* R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass P ⊥ Pass||R P ⊥ Pass||C* R ⊥ Pass ⊥ ⊥ Pa||Pass P ⊥ Pass||R P ⊥ Pass||C* R ⊥ Pa||Pass ⊥ ⊥ Pass Pass||R||R Pass||R||C* R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass Pass||R||R Pass||R||C* R ⊥ Pass ⊥ ⊥ Pa||Pass Pass||R||R Pass||R||C* R ⊥ Pa||Pass ⊥ ⊥ Pass Pass||Pass||R Pass||Pass||C* R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass Pass||Pass||R Pass||Pass||C* R ⊥ Pass ⊥ ⊥ Pa||Pass Pass||Pass||R Pass||Pass||C* R ⊥ Pa||Pass ⊥ ⊥ Pass
The basis of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 6.17-6.31 are given in Table 6.4. The limb topology and the number of overconstraints of these solutions are systematized in Table 6.5, as are their structural parameters in Tables 6.6-6.9.
330 6 Spatial PMs with coupled planar motion of the moving platform Table 6.6. Structural parametersa of spatial parallel mechanisms in Figs. 6.17-6.19 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution PS*R-PRR-RRRPRR (Fig. 6.17a) RS*R-RRR-RRRPRR (Fig. 6.17b) S*PR-RPR-RRRPRR (Fig. 6.18) 11 3 3 6 12 2 3 0 3 see Table 6.4
15 6 6 6 18 4 1 2 3 see Table 6.4
5 3 6 0 0 0 5 3 6 ( v1 , v 2 , 3 0 11 3 1 0 5
4 4 6 6 6 0 4 4 6 ( v1 , v 2 , 3 12 23 3 1 0 10
δ
)
2PPassR-1RRRPRR (Fig. 6.19)
fj
3
10
fj
6
6
fj
14
26
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
6.1 Overconstrained solutions
331
Table 6.7. Structural parametersa of spatial parallel mechanisms in Figs. 6.20-6.25 No. Structural Solution parameter 2PassRR1RRRPRR (Fig. 6.20a)
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
m p1 p2 p3 p q k1 k2 k (RGi) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
21 22 23 24 25 26 27
SF rl rF MF NF TF
28 29 30 a
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PaPassR- PRR-PS*C*-RPaPassPass (Fig. 6.21a) 1RRRPRR PRR-PS*C*-RPassPaPass (Fig. 6.21b) (Fig. 6.20b) PRR-PS*C*-RPaPassPass (Fig. 6.22) RRR-RS*C*-RPaPassPass (Fig. 6.23) RRR-RS*C*-RPassPaPass (Fig. 6.24a) RRR-RS*C*-RPaPassPass (Fig. 6.24b) RPR-S*PC*-RPaPassPass (Fig. 6.25a) RPR-S*PC*-RPassPaPass (Fig. 6.25b) 15 19 15 6 9 3 6 9 3 6 6 13 18 24 19 4 6 5 1 1 2 2 2 1 3 3 3 see Table 6.4 see Table 6.4 see Table 6.4 3 4 3 3 4 6 6 6 6 6 9 0 6 9 0 0 0 15 4 4 3 4 4 6 6 6 6 ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 3 3 3 12 18 15 21 29 27 5 3 3 3 7 3 2 0 0 10 13 3
fj
10
13
6
fj
6
6
21
fj
26
32
30
See footnote of Table 2.4 for the nomenclature of structural parameters
332 6 Spatial PMs with coupled planar motion of the moving platform Table 6.8. Structural parametersa of spatial parallel mechanisms in Figs. 6.26-6.28 No.
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 a
Structural parameter
Solution RPR-S*PC*-RPaPassPass (Fig. 6.26)
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
15 3 3 13 19 5 2 1 3 see Table 6.4
PPassR-PPassC*-RPaPassPass (Fig. 6.27) PPassR-PPassC*-RPassPaPass (Fig. 6.28a) PPassR-PPassC*-RPaPassPass (Fig. 6.28b) 19 6 6 13 25 7 0 3 3 see Table 6.4
3 6 6 0 0 15 3 6 6 ( v1 , v 2 , 3 15 27 3 3 0 3
4 5 6 6 6 15 4 5 6 ( v1 , v 2 , 3 27 39 3 3 0 10
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
6
11
fj
21
21
fj
30
42
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
6.1 Overconstrained solutions
333
Table 6.9. Structural parametersa of spatial parallel mechanisms in Figs. 6.29-6.31 No. Structural Solution parameter PassRR-PassRC*-RPaPassPass (Fig. 6.29a) PassRR-PassRC*-RPassPaPass (Fig. 6.29b) PassRR-PassRC*-RPaPassPass (Fig. 6.30a) 1 m 19 2 p1 6 3 p2 6 4 p3 13 5 p 25 6 q 7 7 k1 0 8 k2 3 9 k 3 10 (RGi) see Table 6.4 (i=1,2,3) 11 SG1 3 12 SG2 4 13 SG3 6 14 rG1 6 15 rG2 6 16 rG3 15 17 MG1 4 18 MG2 5 19 MG3 6 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 27 23 rF 37 24 MF 5 25 NF 5 26 TF 2 p1 27 10 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
PassPassR-PassPassC*-RPaPassPass (Fig. 6.30b) PassPassR-PassPassC*-RPassPaPass (Fig. 6.31a) PassPassR-PassPassC*-RPaPassPass (Fig. 6.31b) 23 9 9 13 31 9 0 3 3 see Table 6.4 4 5 6 12 12 15 5 6 6 ( v1 , v 2 , 3 39 51 5 3 2 17
δ
)
j
fj
11
18
fj
21
21
fj
42
56
See footnote of Table 2.4 for the nomenclature of structural parameters
334 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.17. Overconstrained SPMs with planar motion of the moving platform of types PS*R-PRR-RRRPRR (a) and RS*R-RRR-RRRPRR (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=1, limb topology R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R and PS*R, P ⊥ R||R (a), RS*R, R||R||R (b)
6.1 Overconstrained solutions
335
Fig. 6.18. S*PR-RPR-RRRPRR-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=1, limb topology SP ⊥ R, R ⊥ P ⊥ ||R and R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R
Fig. 6.19. 2PPassR-1RRRPRR-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=1, limb topology P ⊥ Pass||R and R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R
336 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.20. Overconstrained SPMs with planar motion of the moving platform of types 2PassRR-1RRRPRR (a) and 2PaPassR-1RRRPRR (b) defined by MF=5, SF=3, (RF)=( v1 , v2 , δ ), TF=2, NF=3 (a), MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=7 (b), limb topology R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R and Pass||R||R (a), Pa||Pass||R (b)
6.1 Overconstrained solutions
337
Fig. 6.21. Overconstrained SPMs with planar motion of the moving platform of types PRR-PS*C*-RPaPassPass (a) and PRR-PS*C*-RPassPaPass (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology P ⊥ R||R, PS*C* and R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass (a), R ⊥ Pass ⊥ ⊥ Pa||Pass (b)
338 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.22. PRR-PS*C*-RPaPassPass-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology P ⊥ R||R, PS*C* and R ⊥ Pa||Pass ⊥ ⊥ Pass
Fig. 6.23. RRR-RS*C*-RPaPassPass-type overconstrained SPMs with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R||R||R, RS*C* and R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass
6.1 Overconstrained solutions
339
Fig. 6.24. Overconstrained SPMs with planar motion of the moving platform of types RRR-RS*C*-RPassPaPass (a) and RRR-RS*C*-RPaPassPass (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R||R||R, RS*C* and R ⊥ Pass ⊥ ⊥ Pa||Pass (a), R ⊥ Pa||Pass ⊥ ⊥ Pass (b)
340 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.25. Overconstrained SPMs with planar motion of the moving platform of types RPR-S*PC*-RPaPassPass (a) and RPR-S*PC*-RPassPaPass (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R ⊥ P ⊥ ||R, S*P ⊥ C* and R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass (a), R ⊥ Pass ⊥ ⊥ Pa||Pass (b)
6.1 Overconstrained solutions
341
Fig. 6.26. RPR-S*PC*-RPaPassPass-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology R ⊥ P ⊥ ||R, SP ⊥ C* and R ⊥ Pa||Pass ⊥ ⊥ Pass
Fig. 6.27. PPassR-PPassC*-RPaPassPass-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology P ⊥ Pass||R, P ⊥ Pass||C* and R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass
342 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.28. Overconstrained SPMs with planar motion of the moving platform of types PPassR-PPassC*-RPassPaPass (a) and PPassR-PPassC*-RPaPassPass (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3, limb topology P ⊥ Pass||R, P ⊥ Pass||C* and R ⊥ Pass ⊥ ⊥ Pa||Pass (a), R ⊥ Pa||Pass ⊥ ⊥ Pass (b)
6.1 Overconstrained solutions
343
Fig. 6.29. Overconstrained SPMs with planar motion of the moving platform of types PassRR-PassRC*-RPaPassPass (a) and PassRR-PassRC*-RPassPaPass (b) defined by MF=5, SF=3, (RF)=( v1 , v2 , δ ), TF=2, NF=5, limb topology Pass||R||R, Pass||R||C* and R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass (a), R ⊥ Pass ⊥ ⊥ Pa ||Pass (b)
344 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.30. Overconstrained SPMs with planar motion of the moving platform pf types PassRR-PassRC*-RPaPassPass (a), PassPassR-PassPassC*-RPaPassPass (b) defined by MF=5, SF=3, (RF)=( v1 , v2 , δ ), TF=2, NF=5 (a), NF=3 (b), limb topology Pass||R||R, Pass||R||C*, R ⊥ Pa||Pass ⊥ ⊥ Pass (a) and Pass||Pass||R, Pass||Pass||C*, R ⊥ Pa ⊥ ⊥ Pass ⊥ ||Pass (b)
6.1 Overconstrained solutions
345
Fig. 6.31. Overconstrained SPMs with planar motion of the moving platform of types PassPassR-PassPassC*-RPassPaPass (a), PassPassR-PassPassC*-RPaPassPass (b) defined by MF=5, SF=3, (RF)=( v1 , v2 , δ ), TF=2, NF=3, limb topology Pass||Pass||R, Pass||Pass||C* and R ⊥ Pass ⊥ ⊥ Pa||Pass (a), R ⊥ Pa||Pass ⊥ ⊥ Pass (b)
346 6 Spatial PMs with coupled planar motion of the moving platform
6.2 Non overconstrained solutions Equation (1.15) indicates that non overconstrained solutions of spatial parallel robots with coupled motions and q independent loops meet the p condition ∑ 1 f i = 3 + 6q . Various solutions fulfil this condition along with SF=3, (RF)=( v1 ,v2 ,ωδ ) and NF=0 (Figs. 6.32-6.46). These solutions are derived from the overconstrained counterparts presented in Figs. 6.2-6.16 by introducing the required idle mobilities. They can have the actuators mounted on the base or on a moving link. We recall that the idle mobilities can be introduced outside or inside the closed loops combined in the limbs. The notation Pass is associated with the parallelogram loops which combine four idle mobilities in two spherical joints adjacent to the same coupler link. In these cases, three idle mobilities are introduced in the loop and one outside the loop. If the link adjacent to the two spherical joints is a binary link than the idle mobility introduced outside the loop becomes an internal rotational mobility of this binary link around the axis passing by the centre of the two spherical joints. Each internal mobility gives one degree of structural redundancy (see Table 6.10). If the link adjacent to the two spherical joints is connected in the limb by three or more joints (polinary link) than the rotational motion around the axis passing by the centre of the two spherical joints is an idle (potential) mobility of the limb. This motion is restricted by the constraints of the parallel mechanism and remains just a potential mobility. For example (Fig. 6.36a) this rotational motion is internal mobility of binary link 3C and idle mobility of polinary links 8C and 11. The bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 6.32-6.46 are given in Table 6.11. The limb topology and connecting conditions of these solutions are systematized in Table 6.12, as are their structural parameters of these solutions are presented in Tables 6.13-6.16.
6.2 Non overconstrained solutions
347
Table 6.10. Links with internal mobilities and the degree of structural redundancy TF of non overconstrained SPMs with uncoupled planar motion of the moving platform No. Parallel mechanism Figure 1 2 3
4 5 6
TF
Fig. 6.35a 2 Fig. 6.35b 2 Figs. 6.36a, 6.37, 6.38, 1 6.39b, 6.40a, 6.41, 6.42, 6.43b Figs. 6.36b, 6.39a, 1 6.40b, 6.43a Figs. 6.44a, 6.45, 3 6.46b Fig. 6.44b, 6.46a 3
Link with internal rotational mobility in limb G1 G2 G3 3A 3A, 5 A -
3B -
3C
-
-
7C
3A
3B
3C
3A
3B
7C
Table 6.11. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 6.32-6.46 No. Parallel Basis mechanism (RG1) 1 Figs. 6.32, ( v1 , v2 , v3 , α , β , 6.33 2 Figs. 6.34, ( v1 , v2 , β , δ ) 6.35a, 6.45b, 6.46 3 Figs. 6.35b, ( v1 , v2 , δ ) 6.44, 6.45a 4 Figs. ( v1 , v 2 , δ ) 6.36-6.41 5 Figs. 6.42, ( v1 , v2 , β , δ ) 6.43
δ
(RG2) ) ( v1 , v 2 ,
δ
)
(RG3) ( v1 , v 2 , v 3 ,
α
,
β
,
δ
)
( v1 , v 2 , v 3 ,
α
,
β
,
δ
)
( v1 , v 2 , v 3 ,
α
,
δ
)
( v1 , v 2 , v 3 ,
α
,
β
,
δ
) ( v1 , v 2 , v 3 ,
α
,
β
,
δ
)
( v1 , v 2 , v 3 ,
α
,
β
,
δ
) ( v1 , v 2 , v 3 ,
α
,
β
,
δ
)
( v1 , v 2 , v 3 ,
α
,
δ
)
( v1 , v 2 , v 3 ,
α
,
β
,
δ
)
348 6 Spatial PMs with coupled planar motion of the moving platform Table 6.12. Limb topology of the non overconstrained SPMs presented in Figs. 6.32-6.46 No. Basic SPM Type 1 2PRR-1RRRPRR (Fig. 6.2a)
SPM with NF =0 NF Type 3 PS*C*-PRR-RRRPRR (Fig. 6.32a)
2
2RRR-1RRRPRR (Fig. 6.2b)
3
3
2RPR-1RRRPRR (Fig. 6.3)
3
4
2PPaR-1RRRPRR 9 (Fig. 6.4)
5
2PaRR-1RRRPRR 9 (Fig. 6.5a)
6
2PaPaR-1RRRPRR 15 (Fig. 6.5b)
7
2PRR-1RPaPaPa (Fig. 6.6a)
14
8
2PRR-1RPaPaPa (Fig. 6.6b)
14
9
2PRR-1RPaPaPa (Fig. 6.7)
14
10 2RRR-1RPaPaPa (Fig. 6.8)
14
11 2RRR-1RPaPaPa (Fig. 6.9a)
14
12 2RRR-1RPaPaPa (Fig. 6.9b)
14
13 2RPR-1RPaPaPa (Fig. 6.10a)
14
Limb topology PS*C* P ⊥ R||R R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R RS*C*-RRR-RRRPRR RS*C* (Fig. 6.32b) R||R||R R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R S*PC*-RPR-RRRPRR SP ⊥ C* (Fig. 6.33) R ⊥ P ⊥ ||R R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R ss ss PPa R-PPa C*-RRRPRR P ⊥ Pass||R (Fig. 6.34) P ⊥ Pass||C* R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R ss ss Pa RR*R-Pa RRC*Pass||R ⊥ R* ⊥ ||R RRRPRR Pass||R ⊥ R* ⊥ ||C* (Fig. 6.35a) R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R ss ss ss ss Pa Pa R-Pa Pa C*Pass||Pass||R RRRPRR Pass||Pass||C* (Fig. 6.35b) R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R ss ss ss PRR-PS*C*-RPa Pa Pa P ⊥ R||R PS*C* (Fig. 6.36a) R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass ss ss ss PRR-PS*C*-RPa Pa Pa P ⊥ R||R PS*C* (Fig. 6.36b) R ⊥ Pass ⊥ ⊥ Pass||Pass ss ss ss PRR-PS*C*-RPa Pa Pa P ⊥ R||R PS*C* (Fig. 6.37) R ⊥ Pass||Pass ⊥ ⊥ Pass ss ss ss RRR-RS*C*-RPa Pa Pa R||R||R RS*C* (Fig. 6.38) R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass ss ss ss RRR-RS*C*-RPa Pa Pa R||R||R (Fig. 6.39a) RS*C* R ⊥ Pass ⊥ ⊥ Pa||Pass ss ss ss RRR-RS*C*-RPa Pa Pa R||R||R (Fig. 6.39b) RS*C* R ⊥ Pass||Pass ⊥ ⊥ Pass ss ss ss RPR-S*PC*-RPa Pa Pa R ⊥ P ⊥ ||R S*P ⊥ C* (Fig. 6.40a) R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass
6.2 Non overconstrained solutions
349
Table 6.12. (cont.) 14 RPR-S*PC*RPassPassPass (Fig. 6.40b) 2RPR-1RPaPaPa 14 RPR-S*PC*(Fig. 6.11) RPassPassPass (Fig. 6.41) 2PPaR-1RPaPaPa 20 PPassR-PPassC*(Fig. 6.12) RPassPassPass (Fig. 6.42) 2PPaR-1RPaPaPa 20 PPassR-PPassC*(Fig. 6.13a) RPassPassPass (Fig. 6.43a) 2PPaR-1RPaPaPa 20 PPassR-PPassC*(Fig. 6.13b) RPassPassPass (Fig. 6.43b) 2PaRR-1RPaPaPa 20 PassRR-PassRR*R*C*(Fig. 6.14a) RPassPassPass (Fig. 6.44a) 2PaRR-1RPaPaPa 20 PassRR-PassRR*R*C*(Fig. 6.14b) RPassPassPass (Fig. 6.44b) 2PaRR-1RPaPaPa 20 PassRR-PassRR*R*C*(Fig. 6.15a) RPassPassPass (Fig. 6.45a) 2PaPaR-1RPaPaPa 26 PassPassR-PassPassC*(Fig. 6.15b) RPassPassPass (Fig. 6.45b) 2PaPaR-1RPaPaPa 26 PassPassR-PassPassC*(Fig. 6.16a) RPassPassPass (Fig. 6.46a) 2PaPaR-1RPaPaPa 26 PassPassR-PassPassC*(Fig. 6.16b) RPassPassPass (Fig. 6.46b)
14 2RPR-1RPaPaPa (Fig. 6.10b) 15
16
17
18
19
20
21
22
23
24
R ⊥ P ⊥ ||R S*P ⊥ C* R ⊥ Pass ⊥ ⊥ Pass||Pass R ⊥ P ⊥ ||R S*P ⊥ C* R ⊥ Pass||Pass ⊥ ⊥ Pass P ⊥ Pass||R P ⊥ Pass||C* R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass P ⊥ Pass||R P ⊥ Pass||C* R ⊥ Pass ⊥ ⊥ Pass||Pass P ⊥ Pass||R P ⊥ Pass||C* R ⊥ Pass||Pass ⊥ ⊥ Pass Pass||R||R Pass||R ⊥ R* ⊥ ⊥ R* ⊥ ⊥ C* R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass Pass||R||R Pass||R ⊥ R* ⊥ ⊥ R* ⊥ ⊥ C* R ⊥ Pass ⊥ ⊥ Pass||Pass Pass||R||R Pass||R ⊥ R* ⊥ ⊥ R* ⊥ ⊥ C* R ⊥ Pass||Pass ⊥ ⊥ Pass Pass||Pass||R Pass||Pass||C* R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass Pass||Pass||R Pass||Pass||C* R ⊥ Pass ⊥ ⊥ Pass||Pass Pass||Pass||R Pass||Pass||C* R ⊥ Pass||Pass ⊥ ⊥ Pass
350 6 Spatial PMs with coupled planar motion of the moving platform Table 6.13. Structural parametersa of spatial parallel mechanisms in Figs. 6.326.34 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution PS*C*-PRR-RRRPRR (Fig. 6.32a) RS*C*-RRR-RRRPRR (Fig. 6.32b) S*PC*-RPR-RRRPRR (Fig. 6.33) 11 3 3 6 12 2 3 0 3 See Table 6.11
15 6 6 6 18 4 1 2 3 See Table 6.11
6 3 6 0 0 0 6 3 6 ( v1 , v 2 , 3 0 12 3 0 0 6
4 5 6 6 6 0 4 5 6 ( v1 , v 2 , 3 12 24 3 0 0 10
δ
)
PPassR-PPassC*-RRRPRR (Fig. 6.34)
fj
3
11
fj
6
6
fj
15
27
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
6.2 Non overconstrained solutions
351
Table 6.14. Structural parametersa of spatial parallel mechanisms in Figs. 6.356.40 No. Structural Solution parameter PassRR*RPassRRC*RRRPRR (Fig. 6.35a) 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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
p1 j =1 p2 j =1 p3 j =1 p j =1
PRR-PS*C*-RPassPassPass (Fig. 6.36) PRR-PS*C*-RPassPassPass (Fig. 6.37) RRR-RS*C*-RPassPassPass (Fig. 6.38) RRR-RS*C*-RPassPassPass (Fig. 6.39) RPR-S*PC*-RPassPassPass (Fig. 6.40) 15 3 3 13 19 5 2 1 3 See Table 6.11
17 7 7 6 20 4 1 2 3 See Table 6.11 4 5 6 6 6 0 5 6 6 ( v1 , v 2 , δ ) 3 12 24 5 0 2 11
19 9 9 6 24 6 1 2 3 See Table 6.11 3 6 6 12 12 0 5 6 6 ( v1 , v 2 , δ ) 3 24 36 5 0 2 17
3 6 6 0 0 18 3 6 7 ( v1 , v 2 , 3 18 30 4 0 1 3
fj
12
18
6
fj
6
6
25
fj
29
41
34
SF rl rF MF NF TF
∑ ∑ ∑ ∑
PassPassRPassPassC*RRRPRR (Fig. 6.35b)
fj
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
352 6 Spatial PMs with coupled planar motion of the moving platform Table 6.15. Structural parametersa of spatial parallel mechanisms in Figs. 6.416.43 No.
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 a
Structural parameter
Solution RPR-S*PC*-RPassPassPass (Fig. 6.41)
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
15 3 3 13 19 5 2 1 3 See Table 6.11
PPassR-PPassC*-RPassPassPass (Fig. 6.42) PPassR-PPassC*-RPassPassPass (Fig. 6.43) 19 6 6 13 25 7 0 3 3 See Table 6.11
3 6 6 0 0 18 3 6 7 ( v1 , v 2 , 3 18 30 4 0 1 3
4 5 6 6 6 18 4 5 7 ( v1 , v 2 , 3 30 42 4 0 1 10
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
6
11
fj
25
25
fj
34
46
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
6.2 Non overconstrained solutions
353
Table 6.16. Structural parametersa of spatial parallel mechanisms in Figs. 6.446.46 No. Structural Solution parameter PassRR-PassRR*R*C*RPassPassPass (Fig. 6.44) PassRR-PassRR*R*C*RPassPassPass (Fig. 6.45a) 1 m 21 2 p1 6 3 p2 8 4 p3 13 5 p 27 6 q 7 7 k1 0 8 k2 3 9 k 3 10 (RGi) See Table 6.11 (i=1,2,3) 11 SG1 3 12 SG2 6 13 SG3 6 14 rG1 6 15 rG2 6 16 rG3 18 17 MG1 4 18 MG2 7 19 MG3 7 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 30 23 rF 42 24 MF 6 25 NF 0 26 TF 3 p1 27 10 f
4 5 6 12 12 18 5 6 7 ( v1 , v 2 , 3 42 54 6 0 3 17
28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
PassPassR-PassPassC*RPassPassPass (Figs. 6.45b, 6.46)
23 9 9 13 31 9 0 3 3 See Table 6.11
fj
13
18
fj
25
25
fj
48
60
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
354 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.32. Non overconstrained SPMs with planar motion of the moving platform of types PS*C*-PRR-RRRPRR (a) and RS*C*-RRR-RRRPRR (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R and PS*C*, P ⊥ R||R (a), RS*C*, R||R||R (b)
6.2 Non overconstrained solutions
355
Fig. 6.33. S*PC*-RPR-RRRPRR-type non overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology SP ⊥ C*, R ⊥ P ⊥ ||R and R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R
Fig. 6.34. PPassR-PPassC*-RRRPRR-type non overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology P ⊥ Pass||R, P ⊥ Pass||C* and R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R
356 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.35. Non overconstrained SPMs with planar motion of the moving platform of types PassRR*R-PassRRC*-RRRPRR (a) and PassPassR-PassPassC*-RRRPRR (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0, TF=2, limb topology R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R and Pass||R ⊥ R* ⊥ ||R, Pass||R ⊥ R* ⊥ ||C* (a), Pass||Pass||R, Pass||Pass||C* (b)
6.2 Non overconstrained solutions
357
Fig. 6.36. PRR-PS*C*-RPassPassPass-type non overconstrained SPMs with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology P ⊥ R||R, PS*C* and R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass (a), R ⊥ Pass ⊥ ⊥ Pass||Pass (b)
358 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.37. PRR-PS*C*-RPassPassPass-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology P ⊥ R||R, PS*C* and R ⊥ Pass||Pass ⊥ ⊥ Pass
Fig. 6.38. RRR-RS*C*-RPassPassPass-type non overconstrained SPMs with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology R||R||R, RS*C* and R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass
6.2 Non overconstrained solutions
359
Fig. 6.39. RRR-RS*C*-RPassPassPass-type non overconstrained SPMs with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology R ⊥ Pass||Pass ⊥ ⊥ Pass (b)
R||R||R,
RS*C*
and
R ⊥ Pass ⊥ ⊥ Pass||Pass
(a),
360 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.40. RPR-S*PC*-RPassPassPass-type non overconstrained SPMs with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology R ⊥ P ⊥ ||R, S*P ⊥ C* and R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass (a), R ⊥ Pass ⊥ ⊥ Pass||Pass (b)
6.2 Non overconstrained solutions
361
Fig. 6.41. RPR-S*PC*-RPassPassPass-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology R ⊥ P ⊥ ||R, SP ⊥ C* and R ⊥ Pass||Pass ⊥ ⊥ Pass
Fig. 6.42. PPassR-PPassC*-RPassPassPass-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology P ⊥ Pass||R, P ⊥ Pass||C* and R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass
362 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.43. PPassR-PPassC*-RPassPassPass-type non overconstrained SPMs with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology P ⊥ Pass||R, P ⊥ Pass||C* and R ⊥ Pass ⊥ ⊥ Pass||Pass (a), R ⊥ Pass||Pass ⊥ ⊥ Pass (b)
6.2 Non overconstrained solutions
363
Fig. 6.44. PassRR-PassRR*R*C*-RPassPassPass-type non overconstrained SPMs with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0, TF=3, limb topology Pass||R||R, Pass||R ⊥ R* ⊥ ⊥ R* ⊥ ⊥ C* and R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass (a), R ⊥ Pass ⊥ ⊥ Pass||Pass (b)
364 6 Spatial PMs with coupled planar motion of the moving platform
Fig. 6.45. Non overconstrained SPMs with planar motion of the moving platform of types PassRR-PassRR*R*C*-RPassPassPass (a), PassPassR-PassPassC*RPassPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0, TF=3, limb topology Pass||R||R, Pass||R ⊥ R* ⊥ ⊥ R* ⊥ ⊥ C*, R ⊥ Pass||Pass ⊥ ⊥ Pass (a) and Pass||Pass||R, Pass||Pass||C*, R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass (b)
6.2 Non overconstrained solutions
365
Fig. 4.46. PassPassR-PassPassC*-RPassPassPass-type non overconstrained SPMs with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0, TF=3, limb topology Pass||Pass||R, Pass||Pass||C* and R ⊥ Pass ⊥ ⊥ Pass||Pass (a), R ⊥ Pass||Pass ⊥ ⊥ Pass (b)
7 Spatial PMs with uncoupled planar motion of the moving platform
In the general case, in a spatial parallel robotic manipulator (SPM) with uncoupled planar motions of the moving platform at least one spatial limb exists and each operational velocity depends on just one actuated joint velocity: v1 = v1 ( &q1 ) , v2 = v2 ( &q2 ) and ωδ = ωδ ( &q3 ) . The Jacobian matrix in Eq. (1.18) is a diagonal matrix. The overconstrained and non overconstrained solutions presented in this section use rotating actuators mounted on the fixed base.
7.1 Overconstrained solutions The overconstrained solutions of SPMs with uncoupled planar motions of the moving platform and q independent loops meet the condition p ∑ 1 fi < 3 + 6q . The limbs can be simple or complex kinematic chain. Basic and derived fully-parallel solutions are presented in this section. 7.1.1 Basic solutions In the basic fully-parallel solutions of SPMs with uncoupled motions F ← G1-G2-G3 presented in this section, the moving platform n nGi (i=1, 2, 3) is connected to the reference platform 1 1Gi 0 by three limbs. One actuator is combined in a revolute joint of each limb. Two planar or spatial limbs G1 and G2 are used for positioning the moving platform and a spatial or planar limb G3 for orienting it. There are no idle mobilities in these basic solutions. Various solutions of SPMs with uncoupled planar motion of the moving platform and no idle mobilities can be obtained by using G1- and G2-limbs with identical or different topology presented in Figs. 2.2e, 7.1 and 7.2, and a planar or spatial G3-limb in Figs. 2.2f-h, 2.3 and 6.1. Only solutions with identical G1- and G2-limbs are illustrated in Figs. 7.3-7.34. G. Gogu, Structural Synthesis of Parallel Robots, Solid Mechanics and Its Applications 173, DOI 10.1007/978-90-481-9831-3_7, © Springer Science + Business Media B.V. 2010
367
368 7 Spatial PMs with uncoupled planar motion of the moving platform
The basic solutions illustrated in Figs. 7.3 and 7.4 combine two planar limbs with three degrees of connectivity in Fig. 2.2e with one spatial limb with four or six degrees of connectivity in Fig. 6.1. The basic solutions illustrated in Figs. 7.5-7.34 combine two spatial limbs with four or five degrees of connectivity in Figs. 7.1 and 7.2 with one planar limb in Figs. 2.1g, 2.2f-h and 3a,b. Planar parallelogram and rhombus loops with on degrees of mobility and planar loops with two or three degrees of mobility are combined in the limbs presented in Figs. 7.1 and 7.2. The limb topology and connecting conditions of the solutions in Figs. 7.3-7.34 are systematized in Tables 7.1-7.6. The bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms in Figs. 7.3-7.34 are given in Table 7.7, and the structural parameters of these solutions are systematized in Tables 7.8-7.18.
Table 7.1. Limb topology and connecting conditions of the overconstrained SPM with no idle mobilities presented in Figs. 7.3 and 7.34 No. SPM type
Limb topology
Connecting conditions
1
2PaPR-1RRRPRR (Fig. 7.3a)
Pa ⊥ P ⊥ ||R (Fig. 2.2e) R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (Fig. 6.1a)
2
2PaPR-1RPaPaPa (Fig. 7.3b)
3
2PaPR-1RPaPaPa (Fig. 7.4a)
4
2PaPR-1RPaPaPa (Fig. 7.4b)
Pa ⊥ P ⊥ ||R (Fig. 2.2e) R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (Fig. 6.1b) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R ⊥ Pa ⊥ ⊥ Pa||Pa (Fig. 6.1c) Pa ⊥ P ⊥ ||R (Fig. 2.2e) R ⊥ Pa|| Pa ⊥ ⊥ Pa (Fig. 6.1d)
The directions of the revolute joints of limbs G1 and G2 are parallel. The last revolute joints of limbs G1 and G2 have superposed axes. Idem No. 1
Idem No. 1
Idem No. 1
7.1 Overconstrained solutions
369
Fig. 7.1. Complex limbs G1 and G2 with MG=SG=4 (a, d) and MG=SG=5 (b, c) for SPMs with planar motion of the moving platform
370 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.2. Complex limbs G1 and G2 with MG=SG=5 for SPMs with planar motion of the moving platform
7.1 Overconstrained solutions
371
Table 7.2. Limb topology and connecting conditions of the overconstrained SPM with no idle mobilities presented in Figs. 7.5-7.9 No. SPM type
Limb topology
Connecting conditions
1
2PaRRRR-1RPP (Fig. 7.5a)
Pa ⊥ R||R||R ⊥ R (Fig. 7.1a) R ⊥ P ⊥⊥ P (Fig. 2.1g)
2
2PaPaRRR-1RPP (Fig. 7.5b)
3
2PaRRPaR-1RPP (Fig. 7.6a)
4
2PaPaPaR-1RPP (Fig. 7.6b)
5
2PaRRbRR-1RPP (Fig. 7.7)
6
2PaRRbRbRR-1RPP (Fig. 7.8)
7
2PaPn2RR-1RPP (Fig. 7.9a)
8
2PaPn3R-1RPP (Fig. 7.9b)
Pa ⊥ Pa||R||R ⊥ R (Fig. 7.1b) R ⊥ P ⊥⊥ P (Fig. 2.1g) Pa ⊥ R||R||Pa ⊥ R (Fig. 7.1c) R ⊥ P ⊥⊥ P (Fig. 2.1g) Pa ⊥ Pa||Pa ⊥ R (Fig. 7.1d) R ⊥ P ⊥⊥ P (Fig. 2.1g) Pa ⊥ R||Rb||R ⊥ R (Fig. 7.2a) R ⊥ P ⊥⊥ P (Fig. 2.1g) Pa ⊥ R||Rb||Rb||R ⊥ R (Fig. 7.2b) R ⊥ P ⊥⊥ P (Fig. 2.1g) Pa ⊥ Pn2||R ⊥ R (Fig. 7.2c) R ⊥ P ⊥⊥ P (Fig. 2.1g) Pa ⊥ Pn3 ⊥ R (Fig. 7.2d) R ⊥ P ⊥⊥ P (Fig. 2.1g)
The last revolute joints of limbs G1 and G2 have superposed axes and parallel to the axis of the first revolute joint of G3-limb. Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
372 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.3. Limb topology and connecting conditions of the overconstrained SPM with no idle mobilities presented in Figs. 7.10-7.14 No. SPM type
Limb topology
Connecting conditions
1
2PaRRRR-1RPPa (Fig. 7.10a)
Pa ⊥ R||R||R ⊥ R (Fig. 7.1a) R ⊥ P ⊥ ||Pa (Fig. 2.2f)
2
2PaPaRRR-1RPPa (Fig. 7.10b)
The last revolute joints of limbs G1 and G2 have superposed axes and parallel to the axis of the first revolute joint of G3-limb. Idem No. 1
3
4
5
6
7
8
Pa ⊥ Pa||R||R ⊥ R (Fig. 7.1b) R ⊥ P ⊥ ||Pa (Fig. 2.2f) 2PaRRPaR-1RPPa Pa ⊥ R||R||Pa ⊥ R (Fig. 7.11a) (Fig. 7.1c) R ⊥ P ⊥ ||Pa (Fig. 2.2f) 2PaPaPaR-1RPPa Pa ⊥ Pa||Pa ⊥ R (Fig. 7.11b) (Fig. 7.1d) R ⊥ P ⊥ ||Pa (Fig. 2.2f) 2PaRRbRR-1RPPa Pa ⊥ R||Rb||R ⊥ R (Fig. 7.12) (Fig. 7.2a) R ⊥ P ⊥ ||Pa (Fig. 2.2f) 2PaRRbRbRR-1RPPa Pa ⊥ R||Rb||Rb||R ⊥ R (Fig. 7.13) (Fig. 7.2b) R ⊥ P ⊥ ||Pa (Fig. 2.2f) Pa ⊥ Pn2||R ⊥ R 2PaPn2RR-1RPPa (Fig. 7.14a) (Fig. 7.2c) R ⊥ P ⊥ ||Pa (Fig. 2.2f) 2PaPn3R-1RPPa Pa ⊥ Pn3 ⊥ R (Fig. 7.14b) (Fig. 7.2d) R ⊥ P ⊥ ||Pa (Fig. 2.2f)
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
7.1 Overconstrained solutions
373
Table 7.4. Limb topology and connecting conditions of the overconstrained SPM with no idle mobilities presented in Figs. 7.15-7.19 No. SPM type
Limb topology
Connecting conditions
1
2PaRRRR-1RPaP (Fig. 7.15a)
Pa ⊥ R||R||R ⊥ R (Fig. 7.1a) R||Pa ⊥ P (Fig. 2.2g)
2
2PaPaRRR-1RPaP (Fig. 7.15b)
The last revolute joints of limbs G1 and G2 have superposed axes and parallel to the axis of the first revolute joint of G3-limb. Idem No. 1
3
4
5
6
7
8
Pa ⊥ Pa||R||R ⊥ R (Fig. 7.1b) R||Pa ⊥ P (Fig. 2.2g) 2PaRRPaR-1RPaP Pa ⊥ R||R||Pa ⊥ R (Fig. 7.16a) (Fig. 7.1c) R||Pa ⊥ P (Fig. 2.2g) 2PaPaPaR-1RPaP Pa ⊥ Pa||Pa ⊥ R (Fig. 7.16b) (Fig. 7.1d) R||Pa ⊥ P (Fig. 2.2g) 2PaRRbRR-1RPaP Pa ⊥ R||Rb||R ⊥ R (Fig. 7.17) (Fig. 7.2a) R||Pa ⊥ P (Fig. 2.2g) 2PaRRbRbRR-1RPaP Pa ⊥ R||Rb||Rb||R ⊥ R (Fig. 7.18) (Fig. 7.2b) R||Pa ⊥ P (Fig. 2.2g) Pa ⊥ Pn2||R ⊥ R 2PaPn2RR-1RPaP (Fig. 7.19a) (Fig. 7.2c) R||Pa ⊥ P (Fig. 2.2g) 2PaPn3R-1RPaP Pa ⊥ Pn3 ⊥ R (Fig. 7.19b) (Fig. 7.2d) R||Pa ⊥ P (Fig. 2.2g)
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
374 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.5. Limb topology and connecting conditions of the overconstrained SPM with no idle mobilities presented in Figs. 7.20-7.24 No. SPM type
Limb topology
Connecting conditions
1
2PaRRRR-1RPaPa (Fig. 7.20a)
Pa ⊥ R||R||R ⊥ R (Fig. 7.1a) R||Pa||Pa (Fig. 2.2h)
2
Pa ⊥ Pa||R||R ⊥ R (Fig. 7.1b) R||Pa||Pa (Fig. 2.2h) 2PaRRPaR-1RPaPa Pa ⊥ R||R||Pa ⊥ R (Fig. 7.21a) (Fig. 7.1c) R||Pa||Pa (Fig. 2.2h) 2PaPaPaR-1RPaPa Pa ⊥ Pa||Pa ⊥ R (Fig. 7.21b) (Fig. 7.1d) R||Pa||Pa (Fig. 2.2h) 2PaRRbRR-1RPaPa Pa ⊥ R||Rb||R ⊥ R (Fig. 7.22) (Fig. 7.2a) R||Pa||Pa (Fig. 2.2h) 2PaRRbRbRR-1RPaPa Pa ⊥ R||Rb||Rb||R ⊥ R (Fig. 7.23) (Fig. 7.2b) R||Pa||Pa (Fig. 2.2h) 2PaPn2RR-1RPaPa Pa ⊥ Pn2||R ⊥ R (Fig. 7.24a) (Fig. 7.2c) R||Pa||Pa (Fig. 2.2h) 2PaPn3R-1RPaPa Pa ⊥ Pn3 ⊥ R (Fig. 7.24b) (Fig. 7.2d) R||Pa||Pa (Fig. 2.2h)
The last revolute joints of limbs G1 and G2 have superposed axes and parallel to the axis of the first revolute joint of G3limb. Idem No. 1
3
4
5
6
7
8
2PaPaRRR-1RPaPa (Fig. 7.20b)
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
7.1 Overconstrained solutions
375
Table 7.6. Limb topology and connecting conditions of the overconstrained SPM with no idle mobilities presented in Figs. 7.25-7.34 No. SPM type
Limb topology
Connecting conditions
1
2PaRRRR-1RPaPa (Fig. 7.25a)
Pa ⊥ R||R||R ⊥ R (Fig. 7.1a) R||Pa||Pa (Fig. 2.3a)
2
2PaRRRR-1RPaPat (Fig. 7.25b)
3
2PaPaRRR-1RPaPa (Fig. 7.26a)
4
2PaPaRRR-1RPaPat (Fig. 7.26b)
5
2PaRRPaR-1RPaPa (Fig. 7.27a)
6
2PaRRPaR-1RPaPat (Fig. 7.27b)
7
2PaPaPaR-1RPaPa (Fig. 7.28a)
8
2PaPaPaR-1RPaPat (Fig. 7.28b)
9
2PaRRbRR-1RPaPa (Fig. 7.29)
10
2PaRRbRR-1RPaPat (Fig. 7.30)
Pa ⊥ R||R||R ⊥ R (Fig. 7.1a) R||Pa||Pat (Fig. 2.3b) Pa ⊥ Pa||R||R ⊥ R (Fig. 7.1b) R||Pa||Pa (Fig. 2.3a) Pa ⊥ Pa||R||R ⊥ R (Fig. 7.1b) R||Pa||Pat (Fig. 2.3b) Pa ⊥ R||R||Pa ⊥ R (Fig. 7.1c) R||Pa||Pa (Fig. 2.3a) Pa ⊥ R||R||Pa ⊥ R (Fig. 7.1c) R||Pa||Pat (Fig. 2.3b) Pa ⊥ Pa||Pa ⊥ R (Fig. 7.1d) R||Pa||Pa (Fig. 2.3a) Pa ⊥ Pa||Pa ⊥ R (Fig. 7.1d) R||Pa||Pat (Fig. 2.3b) Pa ⊥ R||Rb||R ⊥ R (Fig. 7.2a) R||Pa||Pa (Fig. 2.3a) Pa ⊥ R||Rb||R ⊥ R (Fig. 7.2a) R||Pa||Pat (Fig. 2.3b)
The last revolute joints of limbs G1 and G2 have superposed axes and parallel to the revolute axes of G3limb. Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
376 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.6. (cont.) 11
2PaRRbRbRR-1RPaPa (Fig. 7.31)
12
2PaRRbRbRR-1RPaPat (Fig. 7.32)
13
2PaPn2RR-1RPaPa (Fig. 7.33a)
14
2PaPn2RR-1RPaPat (Fig. 7.33b)
15
2PaPn3R-1RPaPa (Fig. 7.34a)
16
2PaPn3R-1RPaPat (Fig. 7.34b)
Pa ⊥ R||Rb||Rb||R ⊥ R (Fig. 7.2b) R||Pa||Pa (Fig. 2.3a) Pa ⊥ R||Rb||Rb||R ⊥ R (Fig. 7.2b) R||Pa||Pat (Fig. 2.3b) Pa ⊥ Pn2||R ⊥ R (Fig. 7.2c) R||Pa||Pa (Fig. 2.3a) Pa ⊥ Pn2||R ⊥ R (Fig. 7.2c) R||Pa||Pat (Fig. 2.3b) Pa ⊥ Pn3 ⊥ R (Fig. 7.2d) R||Pa||Pa (Fig. 2.3a) Pa ⊥ Pn3 ⊥ R (Fig. 7.2d) R||Pa||Pat (Fig. 2.3b)
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Table 7.7. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 7.3-7.34 No. Parallel mechanism 1 Fig. 7.3a
Basis (RG1) ( v1 , v 2 ,
2
Figs. 7.3b, 7.4
( v1 , v 2 ,
3
Figs. 7.5, 7.6a, ( v1 , v2 , v2 , 7.7-7.10, 7.11a 7.12-7.15, 7.16a, 7.17-7.20, 7.21a, 7.22-7.27, 7.297.34 Figs. 7.6b, 7.11b ( v1 ,v2 , v2 , 7.16b, 7.21b, 7.28
4
δ
)
(RG2) ( v1 , v 2 ,
δ
)
( v1 , v 2 , α
,
δ
)
δ
δ
)
(RG3) ( v1 , v 2 , v 3 ,
α
,
δ
)
( v1 , v 2 , v 2 ,
δ
)
) ( v1 , v 2 , v 2 ,
β
,
( v1 , v 2 , v 2 ,
δ
)
δ
) ( v1 , v 2 ,
δ
)
( v1 , v 2 ,
δ
)
β
,
δ
)
7.1 Overconstrained solutions
377
Table 7.8. Structural parametersa of spatial parallel mechanisms in Figs. 7.3 and 7.4 No.
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 a
Structural parameter
Solution 2PaPR-1RRRPRR (Fig. 7.3a)
2PaPR-1RPaPaPa (Figs. 7.3b, 7.4)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
15 6 6 6 18 4 1 2 3 See Table 7.7
19 6 6 13 25 7 0 3 3 See Table 7.7
3 3 6 3 3 0 3 3 6 ( v1 , v 2 , 3 6 15 3 9 0 6
3 3 4 3 3 9 3 3 4 ( v1 , v 2 , 3 15 22 3 20 0 6
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
6
6
fj
6
13
fj
18
25
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
378 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.9. Structural parametersa of spatial parallel mechanisms in Figs. 7.5 and 7.6 No. Structural Solution parameter 2PaRRRR-1RPP (Fig. 7.5a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PaPaPaR-1RPP (Fig. 7.6b)
16 8 8 3 19 4 1 2 3 See Table 7.7
2PaPaRRR-1RPP (Fig. 7.5b) 2PaRRPaR-1RPP (Fig. 7.6a) 20 11 11 3 25 6 1 2 3 See Table 7.7
22 13 13 3 29 8 1 2 3 See Table 7.7
5 5 3 3 3 0 5 5 3 ( v1 , v 2 , 3 6 16 3 8 0 8
5 5 3 6 6 0 5 5 3 ( v1 , v 2 , 3 12 22 3 14 0 11
4 4 3 9 9 0 4 4 3 ( v1 , v 2 , 3 18 26 3 22 0 13
δ
)
δ
)
fj
8
11
13
fj
3
3
3
fj
19
25
29
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.1 Overconstrained solutions
379
Table 7.10. Structural parametersa of spatial parallel mechanisms in Figs. 7.7-7.9 No.
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 a
Structural Solution parameter 2PaRRbRR-1RPP (Fig. 7.7) 2PaPn2RR-1RPP (Fig. 7.9a) 2PaPn3R-1RPP (Fig. 7.9b) m 20 p1 11 p2 11 p3 3 p 25 q 6 k1 1 k2 2 k 3 (RGi) See Table 7.7 i=1,2,3 SG1 5 SG2 5 SG3 3 rG1 6 rG2 6 rG3 0 MG1 5 MG2 5 MG3 3 (RF) ( v1 , v 2 , δ ) SF 3 rl 12 rF 22 MF 3 NF 14 TF 0 p1 11 f
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
2PaRRbRbRR-1RPP (Fig. 7.8)
24 14 14 3 31 8 1 2 3 See Table 7.7 5 5 3 9 9 0 5 5 3 ( v1 , v 2 , 3 18 28 3 20 0 14
δ
)
j
fj
11
14
fj
3
3
fj
25
31
See footnote of Table 2.4 for the nomenclature of structural parameters
380 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.11. Structural parametersa of spatial parallel mechanisms in Figs. 7.10 and 7.11 No. Structural Solution parameter 2PaRRRR-1RPPa (Fig. 7.10a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PaPaPaR-1RPPa (Fig. 7.11b)
18 8 8 6 22 5 0 3 3 See Table 7.7
2PaPaRRR-1RPPa (Fig. 7.10b) 2PaRRPaR-1RPPa (Fig. 7.11a) 22 11 11 6 28 7 0 3 3 See Table 7.7
24 13 13 6 32 9 0 3 3 See Table 7.7
5 5 3 3 3 3 5 5 3 ( v1 , v 2 , 3 9 19 3 11 0 8
5 5 3 6 6 3 5 5 3 ( v1 , v 2 , 3 15 25 3 17 0 11
4 4 3 9 9 3 4 4 3 ( v1 , v 2 , 3 21 29 3 25 0 13
δ
)
δ
)
fj
8
11
13
fj
6
6
6
fj
22
28
32
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.1 Overconstrained solutions
381
Table 7.12. Structural parametersa of spatial parallel mechanisms in Figs. 7.127.14 No.
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 a
Structural Solution parameter 2PaRRbRR-1RPPa (Fig. 7.12) 2PaPn2RR-1RPPa (Fig. 7.14a) 2PaPn3R-1RPPa (Fig. 7.14b) m 22 p1 11 p2 11 p3 6 p 28 q 7 k1 0 k2 3 k 3 (RGi) See Table 7.7 i=1,2,3 SG1 5 SG2 5 SG3 3 rG1 6 rG2 6 rG3 3 MG1 5 MG2 5 MG3 3 (RF) ( v1 , v 2 , δ ) SF 3 rl 15 rF 25 MF 3 NF 17 TF 0 p1 11 f
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PaRRbRbRR-1RPPa (Fig. 7.13) 26 14 14 6 34 9 0 3 3 See Table 7.7 5 5 3 9 9 3 5 5 3 ( v1 , v 2 , 3 21 31 3 23 0 14
fj
11
14
fj
6
6
fj
28
34
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
382 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.13. Structural parametersa of spatial parallel mechanisms in Figs. 7.15 and 7.16 No. Structural Solution parameter 2PaRRRR-1RPaP (Fig. 7.15a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PaPaPaR-1RPaP (Fig. 7.16b)
18 8 8 6 22 5 0 3 3 See Table 7.7
2PaPaRRR-1RPaP (Fig. 7.15b) 2PaRRPaR-1RPaP (Fig. 7.16a) 22 11 11 6 28 7 0 3 3 See Table 7.7
24 13 13 6 32 9 0 3 3 See Table 7.7
5 5 3 3 3 3 5 5 3 ( v1 , v 2 , 3 9 19 3 11 0 8
5 5 3 6 6 3 5 5 3 ( v1 , v 2 , 3 15 25 3 17 0 11
4 4 3 9 9 3 4 4 3 ( v1 , v 2 , 3 21 29 3 25 0 13
δ
)
δ
)
fj
8
11
13
fj
6
6
6
fj
22
28
32
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.1 Overconstrained solutions
383
Table 7.14. Structural parametersa of spatial parallel mechanisms in Figs. 7.177.19 No.
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 a
Structural Solution parameter 2PaRRbRR-1RPaP (Fig. 7.17) 2PaPn2RR-1RPaP (Fig. 7.19a) 2PaPn3R-1RPaP (Fig. 7.19b) m 22 p1 11 p2 11 p3 6 p 28 q 7 k1 0 k2 3 k 3 (RGi) See Table 7.7 i=1,2,3 SG1 5 SG2 5 SG3 3 rG1 6 rG2 6 rG3 3 MG1 5 MG2 5 MG3 3 (RF) ( v1 , v 2 , δ ) SF 3 rl 15 rF 25 MF 3 NF 17 TF 0 p1 11 f
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PaRRbRbRR-1RPaP (Fig. 7.18) 26 14 14 6 34 9 0 3 3 See Table 7.7 5 5 3 9 9 3 5 5 3 ( v1 , v 2 , 3 21 31 3 23 0 14
fj
11
14
fj
6
6
fj
28
34
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
384 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.15. Structural parametersa of spatial parallel mechanisms in Figs. 7.20 and 7.21 No. Structural Solution parameter 2PaRRRR-1RPaPa (Fig. 7.20a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PaPaPaR-1RPaPa (Fig. 7.21b)
20 8 8 9 25 6 0 3 3 See Table 7.7
2PaPaRRR-1RPaPa (Fig. 7.20b) 2PaRRPaR-1RPaPa (Fig. 7.21a) 24 11 11 9 31 8 0 3 3 See Table 7.7
26 13 13 9 35 10 0 3 3 See Table 7.7
5 5 3 3 3 6 5 5 3 ( v1 , v 2 , 3 12 22 3 14 0 8
5 5 3 6 6 6 5 5 3 ( v1 , v 2 , 3 18 28 3 20 0 11
4 4 3 9 9 6 4 4 3 ( v1 , v 2 , 3 24 32 3 28 0 13
δ
)
δ
)
fj
8
11
13
fj
9
9
9
fj
25
31
35
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.1 Overconstrained solutions
385
Table 7.16. Structural parametersa of spatial parallel mechanisms in Figs. 7.227.24 No.
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 a
Structural Solution parameter 2PaRRbRR-1RPaPa (Fig. 7.22) 2PaPn2RR-1RPaPa (Fig. 7.24a) 2PaPn3R-1RPaPa (Fig. 7.24b) m 24 p1 11 p2 11 p3 9 p 31 q 8 k1 0 k2 3 k 3 (RGi) See Table 7.7 i=1,2,3 SG1 5 SG2 5 SG3 3 rG1 6 rG2 6 rG3 6 MG1 5 MG2 5 MG3 3 (RF) ( v1 , v 2 , δ ) SF 3 rl 18 rF 28 MF 3 NF 20 TF 0 p1 11 f
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PaRRbRbRR-1RPaPa (Fig. 7.23) 28 14 14 9 37 10 0 3 3 See Table 7.7 5 5 3 9 9 6 5 5 3 ( v1 , v 2 , 3 24 34 3 26 0 14
fj
11
14
fj
9
9
fj
31
37
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
386 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.17. Structural parametersa of spatial parallel mechanisms in Figs. 7.257.28 No. Structural Solution parameter 2PaRRRR-1RPaPa 2PaPaRRR-1RPaPa 2PaPaPaR-1RPaPa 2PaRRRR-1RPaPat 2PaPaRRR-1RPaPat 2PaPaPaR-1RPaPat (Fig. 7.25a,b) (Fig. 7.28a,b) (Fig. 7.26a,b) 2PaRRPaR-1RPaPa 2PaRRPaR-1RPaPat (Fig. 7.27a,b) 1 m 20 24 26 2 p1 8 11 13 3 p2 8 11 13 4 p3 9 9 9 5 p 25 31 35 6 q 6 8 10 7 k1 0 0 0 8 k2 3 3 3 9 k 3 3 3 10 (RGi) See Table 7.7 See Table 7.7 See Table 7.7 i=1,2,3 11 SG1 5 5 4 12 SG2 5 5 4 13 SG3 3 3 3 14 rG1 3 6 9 15 rG2 3 6 9 16 rG3 6 6 6 17 MG1 5 5 4 18 MG2 5 5 4 19 MG3 3 3 3 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 3 22 rl 12 18 24 23 rF 22 28 32 24 MF 3 3 3 25 NF 14 20 28 26 TF 0 0 0 p1 27 8 11 13 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
fj
8
11
13
fj
9
9
9
fj
25
31
35
See footnote of Table 2.4 for the nomenclature of structural parameters
7.1 Overconstrained solutions
387
Table 7.18. Structural parametersa of spatial parallel mechanisms in Figs. 7.297.34 No.
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 a
Structural Solution parameter 2PaRRbRR-1RPaPa (Fig. 7.29) 2PaRRbRR-1RPaPat (Fig. 7.30) 2PaPn2RR-1RPaPa (Fig. 7.33a) 2PaPn2RR-1RPaPat (Fig. 7.33b) 2PaPn3R-1RPaPa (Fig. 7.34a) 2PaPn3R-1RPaPat (Fig. 7.34b) m 24 p1 11 p2 11 p3 9 p 31 q 8 k1 0 k2 3 k 3 (RGi) See Table 7.7 i=1,2,3 SG1 5 SG2 5 SG3 3 rG1 6 rG2 6 rG3 6 MG1 5 MG2 5 MG3 3 (RF) ( v1 , v 2 , δ ) SF 3 rl 18 rF 28 MF 3 NF 20 TF 0 p1 11 f
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PaRRbRbRR-1RPaPa (Fig. 7.31) 2PaRRbRbRR-1RPaPat (Fig. 7.32)
28 14 14 9 37 10 0 3 3 See Table 7.7 5 5 3 9 9 6 5 5 3 ( v1 , v 2 , 3 24 34 3 26 0 14
fj
11
14
fj
9
9
fj
31
37
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
388 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.3. Overconstrained SPMs with planar motion of the moving platform of types 2PaPR-1RRRPRR (a) and 2PaPR-1RPaPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=9 (a), NF=20 (b), limb topology Pa ⊥ P ⊥ ||R and
R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (a), R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (b)
7.1 Overconstrained solutions
389
Fig. 7.4. 2PaPR-1RPaPaPa-type overconstrained SPMs with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology Pa ⊥ P ⊥ ||R and R ⊥ Pa ⊥ ⊥ Pa||Pa (a), R ⊥ Pa|| Pa ⊥ ⊥ Pa (b)
390 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.5. Overconstrained SPMs with planar motion of the moving platform of types 2PaRRRR-1RPP (a) and 2PaPaRRR-1RPP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=8 (a), NF=14 (b), limb topology R ⊥ P ⊥ ⊥ P and Pa ⊥ R||R||R ⊥ R (a), Pa ⊥ Pa||R||R ⊥ R (b)
7.1 Overconstrained solutions
391
Fig. 7.6. Overconstrained SPMs with planar motion of the moving platform of types 2PaRRPaR-1RPP (a) and 2PaPaPaR-1RPP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14 (a), NF=22 (b), limb topology R ⊥ P ⊥ ⊥ P and Pa ⊥ R||R||Pa ⊥ R (a), Pa ⊥ Pa||Pa ⊥ R (b)
392 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.7. 2PaRRbRR-1RPP-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology R ⊥ P ⊥ ⊥ P and Pa ⊥ R||Rb||R ⊥ R
7.1 Overconstrained solutions
393
Fig. 7.8. 2PaRRbRbRR-1RPP-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology R ⊥ P ⊥ ⊥ P and Pa ⊥ R||Rb||Rb||R ⊥ R
394 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.9. Overconstrained SPMs with planar motion of the moving platform of types 2PaPn2RR-1RPP (a) and 2PaPn3R-1RPP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology R ⊥ P ⊥ ⊥ P and Pa ⊥ Pn2||R ⊥ R (a), Pa ⊥ Pn3 ⊥ R (b)
7.1 Overconstrained solutions
395
Fig. 7.10. Overconstrained SPMs with planar motion of the moving platform of types 2PaRRRR-1RPPa (a) and 2PaPaRRR-1RPPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=11 (a), NF=17 (b), limb topology R ⊥ P ⊥ ||Pa and Pa ⊥ R||R||R ⊥ R (a), Pa ⊥ Pa||R||R ⊥ R (b)
396 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.11. Overconstrained SPMs with planar motion of the moving platform of types 2PaRRPaR-1RPPa (a) and 2PaPaPaR-1RPPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=17 (a), NF=25 (b), limb topology R ⊥ P ⊥ ||Pa and Pa ⊥ R||R||Pa ⊥ R (a), Pa ⊥ Pa||Pa ⊥ R (b)
7.1 Overconstrained solutions
397
Fig. 7.12. 2PaRRbRR-1RPPa-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=17, limb topology Pa ⊥ R||Rb||R ⊥ R and R ⊥ P ⊥ ||Pa
398 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.13. 2PaRRbRbRR-1RPPa-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=23, limb topology Pa ⊥ R||Rb||Rb||R ⊥ R and R ⊥ P ⊥ ||Pa and (a)
7.1 Overconstrained solutions
399
Fig. 7.14. Overconstrained SPMs with planar motion of the moving platform of types 2PaPn2RR-1RPPa (a) and 2PaPn3R-1RPPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=17, limb topology R ⊥ P ⊥ ||Pa and Pa ⊥ Pn2||R ⊥ R (a), Pa ⊥ Pn3 ⊥ R (b)
400 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.15. Overconstrained SPMs with planar motion of the moving platform of types 2PaRRRR-1RPaP (a) and 2PaPaRRR-1RPaP (b), defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=11 (a), NF=17 (b) limb topology R||Pa ⊥ P and Pa ⊥ R||R||R ⊥ R (a), Pa ⊥ Pa||R||R ⊥ R (b)
7.1 Overconstrained solutions
401
Fig. 7.16. Overconstrained SPMs with planar motion of the moving platform of types 2PaRRPaR-1RPaP (a) and 2PaPaPaR-1RPaP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=17 (a), NF=25 (b), limb topology R||Pa ⊥ P and Pa ⊥ R||R||Pa ⊥ R (a), Pa ⊥ Pa||Pa ⊥ R (b)
402 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.17. 2PaRRbRR-1RPaP-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=17, limb topology Pa ⊥ R||Rb||R ⊥ R and R||Pa ⊥ P
7.1 Overconstrained solutions
403
Fig. 7.18. 2PaRRbRbRR-1RPaP-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=23, limb topology Pa ⊥ R||Rb||Rb||R ⊥ R and R||Pa ⊥ P
404 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.19. Overconstrained SPMs with planar motion of the moving platform of types 2PaPn2RR-1RPaP (a) and 2PaPn3R-1RPaP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=17, limb topology R||Pa ⊥ P and Pa ⊥ Pn2||R ⊥ R (a), Pa ⊥ Pn3|| ⊥ R (b)
7.1 Overconstrained solutions
405
Fig. 7.20. Overconstrained SPMs with planar motion of the moving platform of types 2PaRRRR-1RPaPa (a) and 2PaPaRRR-1RPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14 (a), NF=20 (b), limb topology R||Pa||Pa and Pa ⊥ R||R||R ⊥ R (a), Pa ⊥ Pa||R||R ⊥ R (b)
406 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.21. Overconstrained SPMs with planar motion of the moving platform of types 2PaRRPaR-1RPaPa (a) and 2PaPaPaR-1RPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20 (a), NF=28 (b), limb topology R||Pa||Pa and Pa ⊥ R||R||Pa ⊥ R (a), Pa ⊥ Pa||Pa ⊥ R (b)
7.1 Overconstrained solutions
407
Fig. 7.22. 2PaRRbRR-1RPaPa-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology Pa ⊥ R||Rb||R ⊥ R and R||Pa||Pa
408 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.23. 2PaRRbRbRR-1RPaPa-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=26, limb topology Pa ⊥ R||Rb||Rb||R ⊥ R and R||Pa||Pa
7.1 Overconstrained solutions
409
Fig. 7.24. Overconstrained SPMs with planar motion of the moving platform of types 2PaPn2RR-1RPaPa (a) and 2PaPn3R-1RPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology R||Pa||Pa and Pa ⊥ Pn2||R ⊥ R (a), Pa ⊥ Pn3|| ⊥ R (b)
410 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.25. Overconstrained SPMs with planar motion of the moving platform of types 2PaRRRR-1RPaPa (a) and 2PaRRRR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology Pa ⊥ R||R||R ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
7.1 Overconstrained solutions
411
Fig. 7.26. Overconstrained SPMs with planar motion of the moving platform of types 2PaPaRRR-1RPaPa (a) and 2PaPaRRR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology Pa ⊥ Pa||R||R ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
412 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.27. Overconstrained SPMs with planar motion of the moving platform of types 2PaRRPaR-1RPaPa (a) and 2PaRRPaR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology Pa ⊥ R||R||Pa ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
7.1 Overconstrained solutions
413
Fig. 7.28. Overconstrained SPMs with planar motion of the moving platform of types 2PaPaPaR-1RPaPa (a) and 2PaPaPaR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=28, limb topology Pa ⊥ Pa||Pa ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
414 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.29. 2PaRRbRR-1RPaPa-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology Pa ⊥ R||Rb||R ⊥ R and R||Pa||Pa
7.1 Overconstrained solutions
415
Fig. 7.30. 2PaRRbRR-1RPaPat-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology Pa ⊥ R||Rb||R ⊥ R and R||Pa||Pat
416 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.31. 2PaRRbRbRR-1RPaPa-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=26, limb topology Pa ⊥ R||Rb||Rb||R ⊥ R and R||Pa||Pa
7.1 Overconstrained solutions
417
Fig. 7.32. 2PaRRbRbRR-1RPaPat-type overconstrained SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=26, limb topology Pa ⊥ R||Rb||Rb||R ⊥ R and R||Pa||Pat
418 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.33. Overconstrained SPMs with planar motion of the moving platform of types 2PaPn2RR-1RPaPa (a) and 2PaPn2RR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology Pa ⊥ Pn2||R ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
7.1 Overconstrained solutions
419
Fig. 7.34. Overconstrained SPMs with planar motion of the moving platform of types 2PaPn3R-1RPaPa (a) and 2PaPn3R-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology Pa ⊥ Pn3 ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
420 7 Spatial PMs with uncoupled planar motion of the moving platform
7.1.2 Derived solutions Solutions with lower degrees of overconstraint can be derived from the basic solutions in Figs. 7.3-7.34 by using joints with idle mobilities. A large set of solutions can be obtained by introducing up to three idle mobilities in each planar closed loop and up to three idle mobilities outside the planar loops combined in the limbs. Examples of solutions with 1 to 8 overconstraints derived from the basic solutions in Figs. 7.3-7.34 are illustrated in Figs. 7.35-7.66. We recall that the idle mobilities can be introduced outside or inside the planar loops combined in the limbs. The idle mobilities which can be combined in a parallelogram loop are systematized in Fig. 1.2 and Table 1.1. In the cylindrical joints of the rhombus loops denoted by Rbcs (Figs. 7.39, 7.40, 7.44, 7.45, 7.49, 7.50, 7.54, 7.55 and 7.61-7.66) and the parallelogram loops denoted by Pacs (Figs. 7.57, 7.58 and 7.61-7.66), the translational motion is an idle mobility. The notations Pacs and Rbcs are associated with the parallelogram and rhombus loops with three idle mobilities combined in a cylindrical and a spherical joint. The notations Pass, Pn2ss and Pn3ss are associated with parallelogram loops and planar loops with 2 and 3 degrees of freedom which combine four idle mobilities in two spherical joints adjacent to the same coupler link. In these cases, three idle mobilities are introduced in the loop and one outside the loop. If the link adjacent to the two spherical joints is a binary link than the idle mobility introduced outside the loop becomes an internal rotational mobility of this binary link around the axis passing by the centre of the two spherical joints. Each internal mobility gives one degree of structural redundancy (see Table 7.19). If the link adjacent to the two spherical joints is connected in the limb by three or more joints (polinary link) than the rotational motion around the axis passing by the centre of the two spherical joints can be either active or idle (potential) mobility of the limb. The active motion is compatible with the non constrained motions of the limb, while the idle mobility is restricted by the constraints of the parallel mechanism and remains just a potential mobility. For example in Fig. 7.43a, this rotational motion is an active mobility of the ternary links 4A and 4B and an idle mobility for the ternary links 8A and 8B. The bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms in Figs. 7.35-7.66 are given in Table 7.20. The limb topology and connecting conditions of these solutions are systematized in Tables 7.21-7.23, as are their structural parameters in Tables 7.24-7.38.
7.1 Overconstrained solutions
421
Table 7.19. Links with internal mobilities and the degree of structural redundancy TF of overconstrained SPMs with uncoupled planar motion of the moving platform No. Parallel mechanism Figure
TF
Link with internal rotational mobility in limb G1 G2 G3
1
1
-
-
3C
1 4
3A, 6A
3B, 6B
7C -
2 4 2
7A 6A, 9A 5A
7B 6B, 9B 5B
-
4
3A, 5A
3B, 5B
-
2 5 2
6A 3A, 6A 6A
6B 3B, 6B 6B
3C -
3 5
5A 3A, 5A
5B 3B, 5B
3C 3C
2 3 4 5 6
7 8 9 10 11 12
Figs. 7.35b, 7.36b, 7.47a Fig. 7.36a Figs. 7.37b, 7.42b, 7.52b, 7.58 Fig. 7.38a Fig. 7.38b Figs. 7.39, 7.40, 7.44, 7.45, 7.54, 7.55, 7.61-7.64 Figs. 7.41, 7.46, 7.56, 7.65, 7.66 Figs. 7.43b Fig. 7.47b Figs. 7.48b, 7.53b, 7.60 Figs. 7.49, 7.50 Fig. 7.51
Table 7.20. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 7.35-7.66 No. Parallel mechanism 1 Figs. 7.35, 7.36 2 Figs. 7.37-7.41, 7.47, 7.497.52, 7.547.58, 7.617.66 3 Figs. 7.42, 7.44-7.46, 4 Figs. 7.43, 7.48, 7.53, 7.59, 7.60
Basis (RG1) ( v1 , v 2 ,
α
,
δ
(RG2) ( v1 , v 2 ,
)
β
,
δ
(RG3) ( v1 , v 2 , v 3 ,
)
α
( v1 , v 2 , v 2 ,
α
,
δ
)
( v1 , v 2 , v 2 ,
β
,
δ
)
( v1 , v 2 ,
δ
)
( v1 , v 2 , v 2 ,
α
,
δ
)
( v1 , v 2 , v 2 ,
β
,
δ
)
( v1 , v 2 ,
α
,
) ( v1 , v 2 ,
δ
)
( v1 ,v2 , v3 ,
α
,
β
,
δ
) ( v1 ,v2 , v3 ,
α
,
β
,
δ
,
δ
β
)
,
δ
)
422 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.21. Limb topology and the number of overconstraints NF of the derived SPMs with idle mobilities presented in Figs. 7.35-7.45 No. Basic SPM Type 1 2PaPR-1RRRPRR (Fig. 7.3a) 2 2PaPR-1RPaPaPa (Fig. 7.3b) 3 2PaPR-1RPaPaPa (Fig. 7.4a) 4 2PaPR-1RPaPaPa (Fig. 7.4b) 5 2PaRRRR-1RPP (Fig. 7.5a) 6 2PaPaRRR-1RPP (Fig. 7.5b) 7 2PaRRPaR-1RPP (Fig. 7.6a) 8 2PaPaPaR-1RPP (Fig. 7.6b) 9 2PaRRbRR-1RPP (Fig. 7.7) 10 2PaRRbRbRR1RPP (Fig. 7.8) 11 2PaPn2RR-1RPP (Fig. 7.9a) 12 2PaPn3R-1RPP (Fig. 7.9b) 13 2PaRRRR-1RPPa (Fig. 7.10a) 14 2PaPaRRR-1RPPa (Fig. 7.10b) 15 2PaRRPaR-1RPPa (Fig. 7.11a) 16 2PaPaPaR-1RPPa (Fig. 7.11b) 17 2PaRRbRR-1RPPa (Fig. 7.12) 18 2PaRRbRbRR1RPPa (Fig. 7.13)
Derived SPM NF Type NF 9 2PassPR-1RRRPRR 1 (Fig. 7.35a) 20 2PassPR-1RPassPassPass 1 (Fig. 7.35b) 20 2PassPR-1RPassPassPass 1 (Fig. 7.36a) 20 2PassPR-1RPassPassPass 1 (Fig. 7.36b) 8 2PassRRR-1RPP 2 (Fig. 7.37a) 14 2PassPassRRR-1RPP 2 (Fig. 7.37b) 2 14 2PassRPassR-1RPP (Fig. 7.38a) 22 2PassPassPassR-1RPP 2 (Fig. 7.38b) 14 2PassRbssRR-1RPP 2 (Fig. 7.39) 20 2PassRbssRbcsRR-1RPP 2 (Fig. 7.40)
14 2PassPn2ssRR-1RPP (Fig. 7.41a) 14 2PassPn3ssR-1RPP (Fig. 7.41b) 11 2PassRRR-1RPPass (Fig. 7.42a) 17 2PassPassRRR-1RPPass (Fig. 7.42b) 17 2PassRPassR-1RPPa (Fig. 7.43a) 25 2PassPassPassR-1RPPa (Fig. 7.43b) 17 2PassRbssRR-1RPPass (Fig. 7.44) 23 2PassRbssRbcsRR1RPPass (Fig. 7.45)
2 2 1 1 3 3 1 1
Limb topology Pass ⊥ P ⊥ ||R R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R Pass ⊥ P ⊥ ||R R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass Pass ⊥ P ⊥ ||R R ⊥ Pass ⊥ ⊥ Pass||Pass Pass ⊥ P ⊥ ||R R ⊥ Pass||Pass ⊥ ⊥ Pass Pass ⊥ R||R ⊥ R R ⊥ P ⊥⊥ P Pass ⊥ Pass||R||R ⊥ R R ⊥ P ⊥⊥ P Pass ⊥ R||Pass ⊥ R R ⊥ P ⊥⊥ P Pass ⊥ Pass||Pass ⊥ R R ⊥ P ⊥⊥ P Pass ⊥ Rbss||R ⊥ R R ⊥ P ⊥⊥ P Pass ⊥ Rbss||Rbcs||R ⊥ R R ⊥ P ⊥⊥ P
Pass ⊥ Pn2ss||R ⊥ R R ⊥ P ⊥⊥ P Pass ⊥ Pn3ss ⊥ R R ⊥ P ⊥⊥ P Pass ⊥ R||R ⊥ R R ⊥ P ⊥ ||Pass Pass ⊥ Pass||R||R ⊥ R R ⊥ P ⊥ ||Pass Pass ⊥ R||Pass ⊥ R R ⊥ P ⊥ ||Pa Pass ⊥ Pass||Pass ⊥ R R ⊥ P ⊥ ||Pa Pass ⊥ Rbss||R ⊥ R R ⊥ P ⊥ ||Pass Pass ⊥ Rbss||Rbcs||R ⊥ R R ⊥ P ⊥ ||Pass
7.1 Overconstrained solutions
423
Table 7.22. Limb topology and the number of overconstraints NF of the derived SPMs with idle mobilities presented in Figs. 7.46-7.56 No. Basic SPM Type NF 1 2PaPn2RR-1RPPa 17 (Fig. 7.14a) 2 2PaPn3R-1RPPa 17 (Fig. 7.14b) 3 2PaRRRR-1RPaP 11 (Fig. 7.15a) 4 2PaPaRRR-1RPaP 17 (Fig. 7.15b) 5 2PaRRPaR-1RPaP 17 (Fig. 7.16a) 6 2PaPaPaR-1RPaP 25 (Fig. 7.16b) 7 2PaRRbRR-1RPaP 17 (Fig. 7.17) 8 2PaRRbRbRR23 1RPaP (Fig. 7.18) 9 2PaPn2RR-1RPaP 17 (Fig. 7.19a) 10 2PaPn3R-1RPaP 17 (Fig. 7.19b) 11 2PaRRRR-1RPaPa 14 (Fig. 7.20a) 12 2PaPaRRR-1RPaPa 20 (Fig. 7.20b) 13 2PaRRPaR-1RPaPa 20 (Fig. 7.21a) 14 2PaPaPaR-1RPaPa 28 (Fig. 7.21b) 15 2PaRRbRR-1RPaPa 20 (Fig. 7.22) 16 2PaRRbRbRR26 1RPaPa (Fig. 7.23) 17 2PaPn2RR-1RPaPa 20 (Fig. 7.24a) 18 2PaPn3R-1RPaPa 20 (Fig. 7.24b)
Derived SPM Type NF 2PassPn2ssRR-1RPPass 1 (Fig. 7.46a) 2PassPn3ssR-1RPPass 1 (Fig. 7.46b) 2 2PassRRR-1RPassP (Fig. 7.47a) 2PassPassRRR-1RPassP 2 (Fig. 7.47b) 3 2PassRPassR-1RPaP (Fig. 7.48a) 2PassPassPassR-1RPaP 3 (Fig. 7.48b) 2PassRbssRR-1RPassP 2 (Fig. 7.49) 2 2PassRbssRbcsRR1RPassP (Fig. 7.50) 2PassPn2ssRR-1RPassP 2 (Fig. 7.51a) 2PassPn3ssR-1RPassP 2 (Fig. 7.51b) 8 2PassRRR-1RPaPa (Fig. 7.52a) 2PassPassRRR-1RPaPa 8 (Fig. 7.52b) 2PassRPassR-1RPaPa 6 (Fig. 7.53a) 2PassPassPassR-1RPaPa 6 (Fig. 7.53b) 2PassRbssRR-1RPaPa 8 (Fig. 7.54) 8 2PassRbssRbcsRR1RPaPa (Fig. 7.55) 2PassPn2ssRR-1RPaPa 8 (Fig. 7.56a) 2PassPn3ssR-1RPaPa 8 (Fig. 7.56b)
Limb topology Pass ⊥ Pn2ss||R ⊥ R R ⊥ P ⊥ ||Pass Pass ⊥ Pn3ss ⊥ R R ⊥ P ⊥ ||Pass Pass ⊥ R||R ⊥ R R||Pass ⊥ P Pass ⊥ Pass||R||R ⊥ R R||Pass ⊥ P Pass ⊥ R||Pass ⊥ R R||Pa ⊥ P Pass ⊥ Pass||Pass ⊥ R R||Pa ⊥ P Pass ⊥ Rbss||R ⊥ R R||Pass ⊥ P Pass ⊥ Rbss||Rbcs||R ⊥ R R||Pass ⊥ P
Pass ⊥ Pn2ss||R ⊥ R R||Pass ⊥ P Pass ⊥ Pn3ss ⊥ R R||Pass ⊥ P Pass ⊥ R||R ⊥ R R||Pa||Pa Pass ⊥ Pass||R||R ⊥ R R||Pa||Pa Pass ⊥ R||Pass ⊥ R R||Pa||Pa Pass ⊥ Pass||Pass ⊥ R R||Pa||Pa Pass ⊥ Rbss||R ⊥ R R||Pa||Pa Pass ⊥ Rbss||Rbcs||R ⊥ R R||Pa||Pa Pass ⊥ Pn2ss||R ⊥ R R||Pa||Pa Pass ⊥ Pn3ss ⊥ R R||Pa||Pa
424 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.23. Limb topology and the number of overconstraints NF of the derived SPMs with idle mobilities presented in Figs. 7.57-7.66 No. Basic SPM Type NF 1 2PaRRRR-1RPaPa 14 (Fig. 7.25a) 2 2PaRRRR-1RPaPat 14 (Fig. 7.25b) 3 2PaPaRRR-1RPaPa 20 (Fig. 7.26a) 4
5 6
7 8
9 10
11
12
13
14
15 16
Derived SPM Type NF 2PassRRR-1RPacsPacs 2 (Fig. 7.57a) 2PassRRR-1RPacsPatcs 2 (Fig. 7.57b) 2PassPassRRR2 1RPacsPacs (Fig. 7.58a) 2PaPaRRR2 20 2PassPassRRR1RPaPat 1RPacsPatcs (Fig. 7.26b) (Fig. 7.58b) 2PaRRPaR-1RPaPa 20 2PassRPassR-1RPaPa 6 (Fig. 7.27a) (Fig. 7.59a) 20 2PassRPassR-1RPaPat 6 2PaRRPaR(Fig. 7.59b) 1RPaPat (Fig. 7.27b) 2PaPaPaR-1RPaPa 28 2PassPassPassR-1RPaPa 6 (Fig. 7.28a) (Fig. 7.60a) 2PaPaPaR28 2PassPassPassR-1RPaPat 6 (Fig. 7.60b) 1RPaPat (Fig. 7.28b) 2PaRRbRR-1RPaPa 20 2PassRbssRR-1RPacsPacs 2 (Fig. 7.29) (Fig. 7.61) 2PaRRbRR20 2PassRbssRR-1RPacsPatcs2 (Fig. 7.62) 1RPaPat (Fig. 7.30) 2PaRRbRbRR2 26 2PassRbssRbcsRR1RPaPa 1RPacsPacs (Fig. 7.31) (Fig. 7.63) 2PaRRbRbRR2 26 2PassRbssRbcsRR1RPaPat 1RPacsPatcs (Fig. 7.32) (Fig. 7.64) 2PaPn2RR-1RPaPa 20 2PassPn2ssRR2 (Fig. 7.33a) 1RPacsPacs (Fig. 7.65a) 2PaPn2RR2 20 2PassPn2ssRR1RPaPat 1RPacsPatcs (Fig. 7.33b) (Fig. 7.65b) 2PaPn3R-1RPaPa 20 2PassPn3ssR-1RPacsPacs 2 (Fig. 7.34a) (Fig. 7.66a) 2PaPn3R-1RPaPat 20 2PassPn3ssR-1RPacsPatcs 2 (Fig. 7.34b) (Fig. 7.66b)
Limb topology Pass ⊥ R||R ⊥ R R||Pacs||Pacs Pass ⊥ R||R ⊥ R R||Pacs||Patcs Pass ⊥ Pass||R||R ⊥ R R||Pacs||Pacs
Pass ⊥ Pass||R||R ⊥ R R||Pacs||Patcs Pass ⊥ R||Pass ⊥ R R||Pa||Pa Pass ⊥ R||Pass ⊥ R R||Pa||Pat Pass ⊥ Pass||Pass ⊥ R R||Pa||Pa Pass ⊥ Pass||Pass ⊥ R R||Pa||Pat Pass ⊥ Rbss||R ⊥ R R||Pacs||Pacs Pass ⊥ Rbss||R ⊥ R R||Pacs||Patcs Pass ⊥ Rbss||Rbcs||R ⊥ R R||Pacs||Pacs Pass ⊥ Rbss||Rbcs||R ⊥ R R||Pacs||Patcs Pass ⊥ Pn2ss||R ⊥ R R||Pacs||Pacs Pass ⊥ Pn2ss||R ⊥ R R||Pacs||Patcs Pass ⊥ Pn3ss ⊥ R R||Pacs||Pacs Pass ⊥ Pn3ss ⊥ R R||Pacs||Patcs
7.1 Overconstrained solutions
425
Table 7.24. Structural parametersa of spatial parallel mechanisms in Figs. 7.35 and 7.36 No.
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 a
Structural parameter
Solution 2PassPR-1RRRPRR (Fig. 7.35a)
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
15 6 6 6 18 4 1 2 3 See Table 7.20
2PassPR-1RPassPassPass (Fig. 7.35b) 2PassPR-1RPassPassPass (Fig. 7.36) 19 6 6 13 25 7 0 3 3 See Table 7.20
4 4 6 6 6 0 4 4 6 ( v1 , v 2 , 3 12 23 3 1 0 10
4 4 6 6 6 18 4 4 7 ( v1 , v 2 , 3 30 41 4 1 1 10
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
10
10
fj
6
25
fj
26
45
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
426 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.25. Structural parametersa of spatial parallel mechanisms in Fig. 7.37 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRRR-1RPP (Fig. 7.37a) 14 7 7 3 17 4 1 2 3 See Table 7.20
2PassPassRRR-1RPP (Fig. 7.37b) 20 11 11 3 25 6 1 2 3 See Table 7.20
5 5 3 6 6 0 5 5 3 ( v1 , v 2 , 3 12 22 3 2 0 11
5 5 3 12 12 0 7 7 3 ( v1 , v 2 , 3 24 34 7 2 4 19
δ
)
fj
11
19
fj
3
3
fj
25
41
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.1 Overconstrained solutions
427
Table 7.26. Structural parametersa of spatial parallel mechanisms in Figs. 7.387.40 No.
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 a
Structural Solution parameter 2PassRPassR-1RPP (Fig. 7.38a) 2PassRbssRR-1RPP (Fig. 7.39) m 18 p1 10 p2 10 p3 3 p 23 q 6 k1 1 k2 2 k 3 (RGi) See Table 7.20 (i=1,2,3) SG1 5 SG2 5 SG3 3 rG1 12 rG2 12 rG3 0 MG1 6 MG2 6 MG3 3 (RF) ( v1 , v 2 , δ ) SF 3 rl 24 rF 34 MF 5 NF 2 TF 2 p1 18 f
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
2PassPassPassR-1RPP 2PassRbssRbcsRR(Fig. 7.38b) 1RPP (Fig. 7.40) 22 13 13 3 29 8 1 2 3 See Table 7.20
22 13 13 3 29 8 1 2 3 See Table 7.20
5 5 3 18 18 0 7 7 3 ( v1 , v 2 , 3 36 46 7 2 4 25
5 5 3 18 18 0 6 6 3 ( v1 , v 2 , 3 36 46 5 2 2 24
δ
)
j
fj
18
25
24
fj
3
3
3
fj
39
53
51
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
428 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.27. Structural parametersa of spatial parallel mechanisms in Figs. 7.41 and 7.42 No. Structural Solution parameter 2PassPn2ssRR-1RPP (Fig. 7.41a) 2PassPn3ssR-1RPP (Fig. 7.41b) 1 m 20 2 p1 11 3 p2 11 4 p3 3 5 p 25 6 q 6 7 k1 1 8 k2 2 9 k 3 10 (RGi) See Table 7.20 (i=1,2,3) 11 SG1 5 12 SG2 5 13 SG3 3 14 rG1 12 15 rG2 12 16 rG3 0 17 MG1 7 18 MG2 7 19 MG3 3 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 24 23 rF 34 24 MF 7 25 NF 2 26 TF 4 p1 27 19 f
16 7 7 6 20 5 0 3 3 See Table 7.20
22 11 11 6 28 7 0 3 3 See Table 7.20
5 5 4 6 6 6 5 5 4 ( v1 , v 2 , 3 18 29 3 1 0 11
5 5 4 12 12 6 7 7 4 ( v1 , v 2 , 3 30 41 7 1 4 19
28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
2PassRRR-1RPPass 2PassPassRRR-1RPPass (Fig. 7.42a) (Fig. 7.42b)
δ
)
δ
)
j
fj
19
11
19
fj
3
10
10
fj
41
32
48
See footnote of Table 2.4 for the nomenclature of structural parameters
7.1 Overconstrained solutions
429
Table 7.28. Structural parametersa of spatial parallel mechanisms in Figs. 7.43 and 7.44 No. Structural Solution parameter 2PassRPassR-1RPPa 2PassPassPassR-1RPPa 2PassRbssRR(Fig. 7.43a) (Fig. 7.43b) 1RPPass (Fig. 7.44) 1 m 20 24 20 2 p1 10 13 10 3 p2 10 13 10 4 p3 6 6 6 5 p 26 32 26 6 q 7 9 7 7 k1 0 0 0 8 k2 3 3 3 9 k 3 3 3 10 (RGi) See Table 7.20 See Table 7.20 See Table 7.20 (i=1,2,3) 11 SG1 6 6 5 12 SG2 6 6 5 13 SG3 3 3 4 14 rG1 12 18 12 15 rG2 12 18 12 16 rG3 3 3 6 17 MG1 6 7 6 18 MG2 6 7 6 19 MG3 3 3 4 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 3 22 rl 27 39 30 23 rF 39 51 41 24 MF 3 5 5 25 NF 3 3 1 26 TF 0 2 2 p1 27 18 25 18 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
fj
18
25
18
fj
6
6
10
fj
42
56
46
See footnote of Table 2.4 for the nomenclature of structural parameters
430 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.29. Structural parametersa of spatial parallel mechanisms in Figs. 7.45 and 7.46 No.
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 a
Structural parameter
Solution 2PassRbssRbcsRR-1RPPass (Fig. 7.45)
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
24 13 13 6 32 9 0 3 3 See Table 7.20
2PassPn2ssRR-1RPPass (Fig. 7.46a) 2PassPn3ssR-1RPPass (Fig. 7.46b) 22 11 11 6 28 7 0 3 3 See Table 7.20
5 5 4 18 18 6 6 6 4 ( v1 , v 2 , 3 42 53 5 1 2 24
5 5 4 12 12 6 7 7 4 ( v1 , v 2 , 3 30 41 7 1 4 19
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
24
19
fj
10
10
fj
58
48
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.1 Overconstrained solutions Table 7.30. Structural parametersa of spatial parallel mechanisms in Fig. 7.47 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRRR-1RPassP (Fig. 7.47a) 16 7 7 6 20 5 0 3 3 See Table 7.20
2PassPassRRR-1RPassP (Fig. 7.47b) 22 11 11 6 28 7 0 3 3 See Table 7.20
5 5 3 6 6 6 5 5 4 ( v1 , v 2 , 3 18 28 4 2 1 11
5 5 3 12 12 6 7 7 4 ( v1 , v 2 , 3 30 40 8 2 5 19
δ
)
fj
11
19
fj
10
10
fj
32
48
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
431
432 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.31. Structural parametersa of spatial parallel mechanisms in Fig. 7.48 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRPassR-1RPaP (Fig. 7.48a) 20 10 10 6 26 7 0 3 3 See Table 7.20
2PassPassPassR-1RPaP (Fig. 7.48b) 24 13 13 6 32 9 0 3 3 See Table 7.20
6 6 3 12 12 3 6 6 3 ( v1 , v 2 , 3 27 39 3 3 0 18
6 6 3 18 18 3 7 7 3 ( v1 , v 2 , 3 39 51 5 3 2 25
δ
)
fj
18
25
fj
6
6
fj
42
56
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.1 Overconstrained solutions
433
Table 7.32. Structural parametersa of spatial parallel mechanisms in Figs. 7.497.51 No.
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 a
Structural Solution parameter 2PassRbssRR1RPassP (Fig. 7.49)
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
20 10 10 6 26 7 0 3 3 See Table 7.20
24 13 13 6 32 9 0 3 3 See Table 7.20
2PassPn2ssRR-1RPassP (Fig. 7.51a) 2PassPn3ssR-1RPassP (Fig. 7.51b) 22 11 11 6 28 7 0 3 3 See Table 7.20
5 5 3 12 12 6 6 6 4 ( v1 , v 2 , 3 30 40 6 2 3 18
5 5 3 18 18 6 6 6 4 ( v1 , v 2 , 3 42 52 6 2 3 24
5 5 3 12 12 6 7 7 4 ( v1 , v 2 , 3 30 40 8 2 5 19
δ
)
2PassRbssRbcsRR1RPassP (Fig. 7.50)
δ
)
fj
18
24
19
fj
10
10
10
fj
46
58
48
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
434 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.33. Structural parametersa of spatial parallel mechanisms in Fig. 7.52 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRRR-1RPaPa (Fig. 7.52a) 18 7 7 9 23 6 0 3 3 See Table 7.20
2PassPassRRR-1RPaPa (Fig. 7.52b) 24 11 11 9 31 8 0 3 3 See Table 7.20
5 5 3 6 6 6 5 5 3 ( v1 , v 2 , 3 18 28 3 8 0 11
5 5 3 12 12 6 7 7 3 ( v1 , v 2 , 3 30 40 7 8 4 19
δ
)
fj
11
19
fj
9
9
fj
31
47
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.1 Overconstrained solutions Table 7.34. Structural parametersa of spatial parallel mechanisms in Fig. 7.53 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRPassR-1RPaPa (Fig. 7.53a) 22 10 10 9 29 8 0 3 3 See Table 7.20
2PassPassPassR-1RPaPa (Fig. 7.53b) 26 13 13 9 35 10 0 3 3 See Table 7.20
6 6 3 12 12 6 6 6 3 ( v1 , v 2 , 3 30 42 3 6 0 18
6 6 3 18 18 6 7 7 3 ( v1 , v 2 , 3 42 54 5 6 2 25
δ
)
fj
18
25
fj
9
9
fj
45
59
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
435
436 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.35. Structural parametersa of spatial parallel mechanisms in Figs. 7.547.56 No.
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 a
Structural parameter
Solution 2PassRbssRR1RPaPa (Fig. 7.54)
2PassRbssRbcsRR1RPaPa (Fig. 7.55)
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
22 10 10 9 29 8 0 3 3 See Table 7.20
26 13 13 9 35 10 0 3 3 See Table 7.20
2PassPn2ssRR1RPaPa (Fig. 7.56a) 2PassPn3ssR1RPaPa (Fig. 7.56b) 24 11 11 9 31 8 0 3 3 See Table 7.20
5 5 3 12 12 6 6 6 3 ( v1 , v 2 , 3 30 40 5 8 2 18
5 5 3 18 18 6 6 6 3 ( v1 , v 2 , 3 42 52 5 8 2 24
5 5 3 12 12 6 7 7 3 ( v1 , v 2 , 3 30 40 7 8 4 19
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
δ
)
fj
18
24
19
fj
9
9
9
fj
45
57
47
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
7.1 Overconstrained solutions
437
Table 7.36. Structural parametersa of spatial parallel mechanisms in Figs. 7.577.59 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRRR1RPacsPacs (Fig. 7.57a) 2PassRRR1RPacsPatcs (Fig. 7.57b) 18 7 7 9 23 6 0 3 3 See Table 7.20
2PassPassRRR1RPacsPacs (Fig. 7.58a) 2PassPassRRR1RPacsPatcs (Fig. 7.58b) 24 11 11 9 31 8 0 3 3 See Table 7.20
2PassRPassR1RPaPa (Fig. 7.59a) 2PassRPassR1RPaPat (Fig. 7.59b) 22 10 10 9 29 8 0 3 3 See Table 7.20
5 5 3 6 6 12 5 5 3 ( v1 , v 2 , 3 24 34 3 2 0 11
5 5 3 12 12 12 7 7 3 ( v1 , v 2 , 3 36 46 7 2 5 19
6 6 3 12 12 6 6 6 3 ( v1 , v 2 , 3 30 42 3 6 0 18
δ
)
δ
)
fj
11
19
18
fj
15
15
9
fj
37
53
45
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
438 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.37. Structural parametersa of spatial parallel mechanisms in Figs. 7.607.62 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassPassPassR-1RPaPa (Fig. 7.60a) 2PassPassPassR-1RPaPat (Fig. 7.60b) 26 13 13 9 35 10 0 3 3 See Table 7.20
2PassRbssRR-1RPacsPacs (Fig. 7.61) 2PassRbssRR-1RPacsPatcs (Fig. 7.62) 22 10 10 9 29 8 0 3 3 See Table 7.20
6 6 3 18 18 6 7 7 3 ( v1 , v 2 , 3 42 54 5 6 2 25
5 5 3 12 12 12 6 6 3 ( v1 , v 2 , 3 36 46 5 2 2 18
δ
)
fj
25
18
fj
9
15
fj
59
51
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.1 Overconstrained solutions
439
Table 7.38. Structural parametersa of spatial parallel mechanisms in Figs. 7.637.66 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRbssRbcsRR1RPacsPacs (Fig. 7.63) 2PassRbssRbcsRR1RPacsPatcs (Fig. 7.64) 26 13 13 9 35 10 0 3 3 See Table 7.20 5 5 3 18 18 12 6 6 3 ( v1 , v 2 , 3 48 58 5 2 2 24
δ
)
2PassPn2ssRR-1RPacsPacs (Fig. 7.65a) 2PassPn2ssRR-1RPacsPatcs (Fig. 7.65b) 2PassPn3ssR-1RPacsPacs (Fig. 7.66a) 2PassPn3ssR-1RPacsPatcs (Fig. 7.66b)
24 11 11 9 31 8 0 3 3 See Table 7.20 5 5 3 12 12 12 7 7 3 ( v1 , v 2 , 3 36 46 7 2 4 19
fj
24
19
fj
15
15
fj
63
53
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
440 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.35. Overconstrained SPMs with planar motion of the moving platform of types 2PassPR-1RRRPRR (a) and 2PassPR-1RPassPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=1 and MF=3, TF=0, (a), MF=4, TF=1, (b), limb topology
Pass ⊥ P ⊥ ||R and R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (a), R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass (b)
7.1 Overconstrained solutions
441
Fig. 7.36. 2PassPR-1RPassPassPass-type overconstrained SPMs with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, TF=1, NF=1, limb topology Pass ⊥ P ⊥ ||R and R ⊥ Pass ⊥ ⊥ Pass||Pass (a), R ⊥ Pass||Pass ⊥ ⊥ Pass (b)
442 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.37. Overconstrained SPMs with planar motion of the moving platform of types 2PassRRR-1RPP (a) and 2PassPassRRR-1RPP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=2 and MF=3, TF=0, (a), MF=7, TF=4 (b), limb topology
R ⊥ P ⊥ ⊥ P and Pass ⊥ R||R ⊥ R (a), Pass ⊥ Pass||R||R ⊥ R (b)
7.1 Overconstrained solutions
443
Fig. 7.38. Overconstrained SPMs with planar motion of the moving platform of types 2PassRPassR-1RPP (a) and 2PassPassPassR-1RPP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=2 and MF=5, TF=2, (a), MF=7, TF=4 (b), limb topology
R ⊥ P ⊥ ⊥ P and Pass ⊥ R||Pass ⊥ R (a), Pass ⊥ Pass||Pass ⊥ R (b)
444 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.39. 2PassRbssRR-1RPP-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, TF=2, NF=2, limb topology R ⊥ P ⊥ ⊥ P and Pass ⊥ Rbss||R ⊥ R
7.1 Overconstrained solutions
445
Fig. 7.40. 2PassRbssRbcsRR-1RPP-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, TF=2, NF=2, limb topology R ⊥ P ⊥ ⊥ P and Pass ⊥ Rbss||Rbcs||R ⊥ R
446 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.41. Overconstrained SPMs with planar motion of the moving platform of types 2PassPn2ssRR-1RPP (a) and 2PassPn3ssR-1RPP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, TF=4, NF=2, limb topology R ⊥ P ⊥ ⊥ P and Pass ⊥ Pn2ss||R ⊥ R (a), Pass ⊥ Pn3ss ⊥ R (b)
7.1 Overconstrained solutions
447
Fig. 7.42. Overconstrained SPMs with planar motion of the moving platform of types 2PassRRR-1RPPass (a) and 2PassPassRRR-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=1 and MF=3, TF=0, (a), MF=7, TF=4 (b), limb topology R ⊥ P ⊥ ||Pass and Pass ⊥ R||R ⊥ R (a), Pass ⊥ Pass||R||R ⊥ R (b)
448 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.43. Overconstrained SPMs with planar motion of the moving platform of types 2PassRPassR-1RPPa (a) and 2PassPassPassR-1RPPa (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=3 and MF=3, TF=0, (a), MF=5, TF=2 (b), limb topology R ⊥ P ⊥ ||Pa and Pass ⊥ R||Pass ⊥ R (a), Pass ⊥ Pass||Pass ⊥ R (b)
7.1 Overconstrained solutions
449
Fig. 7.44. 2PassRbssRR-1RPPass-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, TF=2, NF=1, limb topology R ⊥ P ⊥ ||Pass and Pass ⊥ Rbss||R ⊥ R
450 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.45. 2PassRbssRbcsRR-1RPPass-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v 2 , δ ), MF=5, TF=2, NF=1, limb topology R ⊥ P ⊥ ||Pass and Pass ⊥ Rbss||Rbcs||R ⊥ R
7.1 Overconstrained solutions
451
Fig. 7.46. Overconstrained SPMs with planar motion of the moving platform of types 2PassPn2ssRR-1RPPass (a) and 2PassPn3ssR-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, TF=4, NF=1, limb topology R ⊥ P ⊥ ||Pass and Pass ⊥ Pn2ss||R ⊥ R (a), Pass ⊥ Pn3ss ⊥ R (b)
452 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.47. Overconstrained SPMs with planar motion of the moving platform of types 2PassRRR-1RPassP (a) and 2PassPassRRR-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=2 and MF=4, TF=1, (a), MF=8, TF=5 (b), limb topology R||Pass ⊥ P and Pass ⊥ R||R ⊥ R (a), Pass ⊥ Pass||R||R ⊥ R (b)
7.1 Overconstrained solutions
453
Fig. 7.48. Overconstrained SPMs with planar motion of the moving platform of types 2PassRPassR-1RPaP (a) and 2PassPassPassR-1RPaP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=3 and MF=3, TF=0, (a), MF=5, TF=2 (b), limb topology R||Pa ⊥ P and Pass ⊥ R||Pass ⊥ R (a), Pass ⊥ Pass||Pass ⊥ R (b)
454 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.49. 2PassRbssRR-1RPassP-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, TF=3, NF=2, limb topology Pass ⊥ Rbss||R ⊥ R and R||Pass ⊥ P
7.1 Overconstrained solutions
455
Fig. 7.50. 2PassRbssRbcsRR-1RPassP-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v 2 , δ ), MF=6, TF=3, NF=2, limb topology Pass ⊥ Rbss||Rbcs||R ⊥ R and R||Pass ⊥ P
456 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.51. Overconstrained SPMs with planar motion of the moving platform of types 2PassPn2ssRR-1RPassP (a) and 2PassPn3ssR-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=8, TF=5, NF=2, limb topology R||Pass ⊥ P and Pass ⊥ Pn2ss||R ⊥ R (a), Pass ⊥ Pn3ss ⊥ R (b)
7.1 Overconstrained solutions
457
Fig. 7.52. Overconstrained SPMs with planar motion of the moving platform of types 2PassRRR-1RPaPa (a) and 2PassPassRRR-1RPaPa (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=8 and MF=3, TF=0, (a), MF=7, TF=4 (b), limb topology R||Pa||Pa and Pass ⊥ R||R ⊥ R (a), Pass ⊥ Pass||R||R ⊥ R (b)
458 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.53. Overconstrained SPMs with planar motion of the moving platform of types 2PassRPassR-1RPaPa (a) and 2PassPassPassR-1RPaPa (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=6 and MF=3, TF=0, (a), MF=5, TF=2 (b), limb topology R||Pa||Pa and Pass ⊥ R||Pass ⊥ R (a), Pass ⊥ Pass||Pass ⊥ R (b)
7.1 Overconstrained solutions
459
Fig. 7.54. 2PassRbssRR-1RPaPa-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, TF=2, NF=8, limb topology Pass ⊥ Rbss||R ⊥ R and R||Pa||Pa
460 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.55. 2PassRbssRbcsRR-1RPaPa-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v 2 , δ ), MF=5, TF=2, NF=8, limb topology Pass ⊥ Rbss||Rbcs||R ⊥ R and R||Pa||Pa
7.1 Overconstrained solutions
461
Fig. 7.56. Overconstrained SPMs with planar motion of the moving platform of types 2PassPn2ssRR-1RPaPa (a) and 2PassPn3ssR-1RPaPa (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, TF=4, NF=8, limb topology R||Pa||Pa and Pass ⊥ Pn2ss||R ⊥ R (a), Pass ⊥ Pn3ss ⊥ R (b)
462 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.57. Overconstrained SPMs with planar motion of the moving platform of types 2PassRRR-1RPacsPacs (a) and 2PassRRR-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology Pass ⊥ R||R ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
7.1 Overconstrained solutions
463
Fig. 7.58. Overconstrained SPMs with planar motion of the moving platform of types 2PassPassRRR-1RPacsPacs (a) and 2PassPassRRR-1RPacsPatcs (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, TF=4, NF=2, limb topology Pass ⊥ Pass||R||R ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
464 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.59. Overconstrained SPMs with planar motion of the moving platform of types 2PassRPassR-1RPaPa (a) and 2PassRPassR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=6, limb topology Pass ⊥ R||Pass ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
7.1 Overconstrained solutions
465
Fig. 7.60. Overconstrained SPMs with planar motion of the moving platform of types 2PassPassPassR-1RPaPa (a) and 2PassPassPassR-1RPaPat (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, TF=2, NF=6, limb topology Pass ⊥ Pass||Pass ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
466 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.61. 2PassRbssRR-1RPacsPacs-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, TF=2, NF=2, limb topology Pass ⊥ Rbss||R ⊥ R and R||Pacs||Pacs
7.1 Overconstrained solutions
467
Fig. 7.62. 2PassRbssRR-1RPacsPatcs-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, TF=2, NF=2, limb topology Pass ⊥ Rbss||R ⊥ R and R||Pacs||Patcs
468 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.63. 2PassRbssRbcsRR-1RPacsPacs-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v 2 , δ ), MF=5, TF=2, NF=2, limb topology Pass ⊥ Rbss||Rbcs||R ⊥ R and R||Pacs||Pacs
7.1 Overconstrained solutions
469
Fig. 7.64. 2PassRbssRbcsRR-1RPacsPatcs-type overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v 2 , δ ), MF=5, TF=2, NF=2, limb topology Pass ⊥ Rbss||Rbcs||R ⊥ R and R||Pacs||Patcs
470 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.65. Overconstrained SPMs with planar motion of the moving platform of types 2PassPn2ssRR-1RPacsPacs (a) and 2PassPn2ssRR-1RPacsPatcs (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, TF=4, NF=2, limb topology Pass ⊥ Pn2ss||R ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
7.1 Overconstrained solutions
471
Fig. 7.66. Overconstrained SPMs with planar motion of the moving platform of types 2PassPn3ssR-1RPacsPacs (a) and 2PassPn3ssR-1RPacsPatcs (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, TF=4, NF=2, limb topology Pass ⊥ Pn3ss ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
472 7 Spatial PMs with uncoupled planar motion of the moving platform
7.2 Non overconstrained solutions Equation (1.15) indicates that non overconstrained solutions of spatial parallel robots with uncoupled motions and q independent loops meet the p condition ∑ 1 f i = 3 + 6q . Various solutions fulfil this condition along with SF=3, (RF)=( v1 ,v2 ,ωδ ) and NF=0 (Figs. 7.67-7.100). These solutions are derived from the overconstrained counterparts presented in Figs. 7.3-7.34 by introducing the required idle mobilities. We recall that the joints combining idle mobilities are denoted by an asterisk. These idle mobilities can be introduced outside or inside the loops combined in the limbs. The rotational mobility of the revolute joint denoted by R* is an idle mobility. One idle mobility is combined in each cylindrical joint C* and two idle mobilities in each spherical joint. For example, in the cylindrical joint denoted by C* in Figs. 7.67 and 7.68, the idle mobility is the rotational motion. The translational motion is an idle mobility in the cylindrical joint of the rhombus loops denoted by Rbcs (Figs. 7.72, 7.77, 7.82 and 7.87) and in the parallelogram loops denoted by Pacs (Figs. 7.89-7.100). The notations Pass, Pn2ss and Pn3ss are associated with parallelogram loops and planar loops with 2 and 3 degrees of freedom which combine four idle mobilities in two spherical joints adjacent to the same coupler link. In these cases, three idle mobilities are introduced in the loop and one outside the loop. If the link adjacent to the two spherical joints is a binary link than the idle mobility introduced outside the loop becomes an internal rotational mobility of the binary link around the axis passing by the centre of the two spherical joints. Each internal mobility gives one degree of structural redundancy (see Table 7.39). If the link adjacent to the two spherical joints is connected in the limb by three or more joints (polinary link) than the rotational motion around the axis passing by the centre of the two spherical joints can be either active or idle (potential) mobility of the limb. The active motion is compatible with the non constrained motions of the limb, while the idle mobility is restricted by the constraints of the parallel mechanism and remains just a potential mobility. For example in Fig. 7.75a, this rotational motion is an active mobility of ternary links 4A and 4B, an idle mobility for ternary links 8A and 8B and an internal mobility of link 5C. The bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms in Figs. 7.67-7.100 are given in Table 7.40. The limb topology and connecting conditions of these solutions are systematized in Tables 7.41-7.44, as are their structural parameters in Tables 7.45-7.60.
7.2 Non overconstrained solutions
473
Table 7.39. Links with internal mobilities and the degree of structural redundancy TF of overconstrained SPMs with uncoupled planar motion of the moving platform No. Parallel mechanism Figure
TF
Link with internal rotational mobility in limb G1 G2 G3
1
1
-
-
3C
1 4 2 2
3A, 6A 6A 5A
3B, 6B 6B 5B
7C -
4 1 5 3 3 5 5 3 3 5 2 6 4 6 4 2
3A, 5A 3A, 6A 6A 5A 3A, 5A 3A, 6A 6A 5A 3A, 5A 3A, 6A 5A 3A, 5A 3A, 6A 6A
3B, 5B 3B, 6B 6B 5B 3B, 5B 3B, 6B 6B 5B 3B, 5B 3B, 6B 5B 3B, 5B 3B, 6B 6B
5C 5C 5C 5C 5C 3C 3C 3C 3C 3 C, 6 C 3 C, 6 C 3 C, 6 C 3 C, 6 C -
2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21
Figs. 7.67b, 7.68b, 7.79a, 7.80a Fig. 7.68a Fig. 7.69b, Fig. 7.70b Figs. 7.71, 7.72, 7.93-7.96 Figs. 7.73, 7.97-7.100 Figs. 7.74a, 7.75a, Fig. 7.74b, Fig. 7.75b Figs. 7.76, 7.77 Fig. 7.78 Fig. 7.79b, Figs. 7.80b Figs. 7.81, 7.82 Fig. 7.83 Figs. 7.84a, 7.85a, Fig. 7.84b, 7.85b Fig. 7.86, 7.87 Fig. 7.88, Fig. 7.90 Fig. 7.92
Table 7.40. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 7.67-7.100 No. Parallel mechanism 1 Figs. 7.67, 7.68 2 Figs. 7.697.100
Basis (RG1) ( v1 , v 2 ,
α,
( v1 , v 2 , v 3 ,
δ
α
,
(RG2) ( v1 , v 2 , v 3 ,
) β
,
δ
) ( v1 , v 2 , v 3 ,
β,
α
,
(RG3) ( v1 , v 2 , v 3 ,
δ )
β
,
δ
) ( v1 , v 2 ,
δ
α
)
,
β
,
δ
)
474 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.41. Limb topology of the non overconstrained SPMs presented in Figs. 7.67-7.75 No. Basic SPM SPM with NF=0 Type NF Type 1 2PaPR-1RRRPRR 9 PassPR- PassPC*(Fig. 7.3a) RRRPRR (Fig. 7.67a) 2 2PaPR-1RPaPaPa 20 PassPR-PassPC*(Fig. 7.3b) RPassPassPass (Fig. 7.67b) 3 2PaPR-1RPaPaPa 20 PassPR-PassPC*(Fig. 7.4a) RPassPassPass (Fig. 7.68a) 4 2PaPR-1RPaPaPa 20 PassPR-PassPC*(Fig. 7.4b) RPassPassPass (Fig. 7.68b) 8 2PassRRR*R-1RPP 5 2PaRRRR-1RPP (Fig. 7.5a) (Fig. 7.69a) 6 2PaPaRRR-1RPP 14 2PassPassRRR*R-1RPP (Fig. 7.5b) (Fig. 7.69b) 7 2PaRRPaR-1RPP 14 2PassRPassR-1RPP (Fig. 7.6a) (Fig. 7.70a) 8 2PaPaPaR-1RPP 22 2PassPassPassR-1RPP (Fig. 7.6b) (Fig. 7.70b) 9 2PaRRbRR-1RPP 14 2PassRbssRR*R-1RPP (Fig. 7.7) (Fig. 7.71) 10 2PaRRbRbRR20 2PassRbssRbcsRR*R1RPP 1RPP (Fig. 7.8) (Fig. 7.72) 11 2PaPn2RR-1RPP (Fig. 7.9a) 12 2PaPn3R-1RPP (Fig. 7.9b) 13 2PaRRRR-1RPPa (Fig. 7.10a) 14 2PaPaRRR-1RPPa (Fig. 7.10b) 15 2PaRRPaR-1RPPa (Fig. 7.11a) 16 2PaPaPaR-1RPPa (Fig. 7.11b)
14 14 11 17 17 25
Limb topology Pass ⊥ P ⊥ ||R Pass ⊥ P ⊥ ||C* R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R Pass ⊥ P ⊥ ||R Pass ⊥ P ⊥ ||C* R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass Pass ⊥ P ⊥ ||R Pass ⊥ P ⊥ ||C* R ⊥ Pass ⊥ ⊥ Pass||Pass Pass ⊥ P ⊥ ||R Pass ⊥ P ⊥ ||C* R ⊥ Pass||Pass ⊥ ⊥ Pass Pass ⊥ R||R ⊥ ⊥ R ⊥ ⊥ R R ⊥ P ⊥⊥ P Pass ⊥ Pass||R||R ⊥ ⊥ R ⊥ ⊥ R R ⊥ P ⊥⊥ P Pass ⊥ R||Pass ⊥ ||R R ⊥ P ⊥⊥ P Pass ⊥ Pass||Pass ⊥ ||R R ⊥ P ⊥⊥ P Pass ⊥ Rbss||R ⊥ ⊥ R ⊥ ⊥ R R ⊥ P ⊥⊥ P Pass ⊥ Rbss||Rbcs||R ⊥ ⊥ R ⊥⊥ R R ⊥ P ⊥⊥ P ss ss 2Pa Pn2 RR*R-1RPP Pass ⊥ Pn2ss||R ⊥ ⊥ R ⊥ ⊥ R (Fig. 7.73a) R ⊥ P ⊥⊥ P ss ss 2Pa Pn3 R*R-1RPP Pass ⊥ Pn3ss ⊥ ⊥ R ⊥ ⊥ R (Fig. 7.73b) R ⊥ P ⊥⊥ P ss ss 2Pa RRR*R-1RPPa Pass ⊥ R||R ⊥ ⊥ R ⊥ ⊥ R (Fig. 7.74a) R ⊥ P ⊥ ||Pass ss ss ss 2Pa Pa RRR*R-1RPPa Pass ⊥ Pass||R||R ⊥ ⊥ R ⊥ ⊥ R (Fig. 7.74b) R ⊥ P ⊥ ||Pass 2PassRPassR-1RPPass Pass ⊥ R||Pass ⊥ ||R (Fig. 7.75a) R ⊥ P ⊥ ||Pass ss ss ss ss 2Pa Pa Pa R-1RPPa Pass ⊥ Pass||Pass ⊥ ||R R ⊥ P ⊥ ||Pass (Fig. 7.75b)
7.2 Non overconstrained solutions
475
Table 7.42. Limb topology of the non overconstrained SPMs presented in Figs. 7.76-7.85 No. Basic SPM SPM with NF=0 Type NF Type 1 2PaRRbRR-1RPPa 17 2PassRbssRR*R-1RPPass (Fig. 7.12) (Fig. 7.76) 2 2PaRRbRbRR23 2PassRbssRbcsRR*R1RPPa 1RPPass (Fig. 7.13) (Fig. 7.77) 3 4 5 6
7 8 9 10
11
12 13 14
15 16
17 2PassPn2ssRR*R-1RPPass (Fig. 7.78a) 17 2PassPn3ssR*R-1RPPass (Fig. 7.78b) 11 2PassRRR*R-1RPassP (Fig. 7.79a) 17 2PassPassRRR*R1RPassP (Fig. 7.79b) 2PaRRPaR-1RPaP 17 2PassRPassR-1RPassP (Fig. 7.16a) (Fig. 7.80a) 2PaPaPaR-1RPaP 25 2PassPassPassR-1RPassP (Fig. 7.16b) (Fig. 7.80b) 2PaRRbRR-1RPaP 17 2PassRbssRR*R-1RPassP (Fig. 7.17) (Fig. 7.81) 2PaRRbRbRR23 2PassRbssRbcsRR*R1RPaP 1RPassP (Fig. 7.18) (Fig. 7.82) 2PaPn2RR-1RPaP 17 2PassPn2ssRR*R(Fig. 7.19a) 1RPassP (Fig. 7.83a) 2PaPn3R-1RPaP 17 2PassPn3ssR*R-1RPassP (Fig. 7.19b) (Fig. 7.83b) 2PaRRRR-1RPaPa 14 2PassRRR*R-1RPassPass (Fig. 7.20a) (Fig. 7.84a) 2PaPaRRR-1RPaPa 20 2PassPassRRR*R(Fig. 7.20b) 1RPassPass (Fig. 7.84b) 2PaRRPaR-1RPaPa 20 2PassRPassR-1RPassPass (Fig. 7.21a) (Fig. 7.85a) 2PaPaPaR-1RPaPa 28 2PassPassPassR(Fig. 7.21b) 1RPassPass (Fig. 7.85b) 2PaPn2RR-1RPPa (Fig. 7.14a) 2PaPn3R-1RPPa (Fig. 7.14b) 2PaRRRR-1RPaP (Fig. 7.15a) 2PaPaRRR-1RPaP (Fig. 7.15b)
Limb topology Pass ⊥ Rbss||R ⊥ ⊥ R ⊥ ⊥ R R ⊥ P ⊥ ||Pass Pass ⊥ Rbss||Rbcs||R ⊥ ⊥ R ⊥⊥ R R ⊥ P ⊥ ||Pass Pass ⊥ Pn2ss||R ⊥ ⊥ R ⊥ ⊥ R R ⊥ P ⊥ ||Pass Pass ⊥ Pn3ss ⊥ ⊥ R ⊥ ⊥ R R ⊥ P ⊥ ||Pass Pass ⊥ R||R ⊥ ⊥ R ⊥ ⊥ R R||Pass ⊥ P Pass ⊥ Pass||R||R ⊥ ⊥ R ⊥ ⊥ R R||Pass ⊥ P Pass ⊥ R||Pass ⊥ ||R R||Pass ⊥ P Pass ⊥ Pass||Pass ⊥ ||R R||Pass ⊥ P Pass ⊥ Rbss||R ⊥ ⊥ R ⊥ ⊥ R R||Pass ⊥ P Pass ⊥ Rbss||Rbcs||R ⊥ ⊥ R ⊥⊥ R R||Pass ⊥ P Pass ⊥ Pn2ss||R ⊥ ⊥ R ⊥ ⊥ R R||Pass ⊥ P
Pass ⊥ Pn3ss ⊥ ⊥ R ⊥ ⊥ R R||Pass ⊥ P Pass ⊥ R||R ⊥ ⊥ R ⊥ ⊥ R R||Pass||Pass Pass ⊥ Pass||R||R ⊥ ⊥ R ⊥ ⊥ R R||Pass||Pass Pass ⊥ R||Pass ⊥ ||R R||Pass||Pass Pass ⊥ Pass||Pass ⊥ ||R R||Pass||Pass
476 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.43. Limb topology of the non overconstrained SPMs presented in Figs. 7.86-7.92 No. Basic SPM Type 1 2PaRRbRR1RPaPa (Fig. 7.22) 2 2PaRRbRbRR1RPaPa (Fig. 7.23)
SPM with NF=0 NF Type 20 2PassRbssRR*R1RPassPass (Fig. 7.86) 26 2PassRbssRbcsRR*R1RPassPass (Fig. 7.87)
2PaPn2RR1RPaPa (Fig. 7.24a) 4 2PaPn3R1RPaPa (Fig. 7.24b) 5 2PaRRRR1RPaPa (Fig. 7.25a) 6 2PaRRRR1RPaPat (Fig. 7.25b) 7 2PaPaRRR1RPaPa (Fig. 7.26a) 8 2PaPaRRR1RPaPat (Fig. 7.26b) 9 2PaRRPaR1RPaPa (Fig. 7.27a) 10 2PaRRPaR1RPaPat (Fig. 7.27b) 11 2PaPaPaR1RPaPa (Fig. 7.28a) 12 2PaPaPaR1RPaPat (Fig. 7.28b)
20 2PassPn2ssRR*R1RPassPass (Fig. 7.88a) 20 2PassPn3ssR*R1RPassPass (Fig. 7.88b) 14 2PassRRR*R1RPacsPacs (Fig. 7.89a) 14 2PassRRR*R1RPacsPatcs (Fig. 7.89b) 20 2PassPassRRR*R1RPacsPacs (Fig. 7.90a) 20 2PassPassRR*R1RPacsPatcs (Fig. 7.90b) 20 2PassRPassR1RPacsPacs (Fig. 7.91a) 20 2PaRRPaR1RPacsPatcs (Fig. 7.91b) 28 2PassPassPassR1RPacsPacs (Fig. 7.92a) 28 2PassPassPassR1RPacsPatcs (Fig. 7.92b)
3
Limb topology Pass ⊥ Rbss||R ⊥ ⊥ R ⊥ ⊥ R R||Pass||Pass
Pass ⊥ Rbss||Rbcs||R ⊥ ⊥ R ⊥⊥ R R||Pass||Pass Pass ⊥ Pn2ss||R ⊥ ⊥ R ⊥ ⊥ R R||Pass||Pass Pass ⊥ Pn3ss ⊥ ⊥ R ⊥ ⊥ R R||Pass||Pass Pass ⊥ R||R ⊥ R* ⊥ ⊥ R R||Pacs||Pacs Pass ⊥ R||R ⊥ R* ⊥ ⊥ R R||Pacs||Patcs Pass ⊥ Pass||R||R ⊥ R* ⊥ ⊥ R R||Pacs||Pacs Pass ⊥ Pass||R||R ⊥ R* ⊥ ⊥ R R||Pacs||Patcs Pass ⊥ R||Pass ⊥ R R||Pacs||Pacs Pass ⊥ R||Pass ⊥ R R||Pacs||Patcs Pass ⊥ Pass||Pass ⊥ R R||Pacs||Pacs Pass ⊥ Pass||Pass ⊥ R R||Pacs||Patcs
7.2 Non overconstrained solutions
477
Table 7.44. Limb topology of the non overconstrained SPMs presented in Figs. 7.93-7.100 No. Basic SPM Type 13 2PaRRbRR1RPaPa (Fig. 7.29) 14 2PaRRbRR1RPaPat (Fig. 7.30) 15 2PaRRbRbRR1RPaPa (Fig. 7.31) 16 2PaRRbRbRR1RPaPat (Fig. 7.32) 2PaPn2RR1RPaPa (Fig. 7.33a) 2PaPn2RR1RPaPat (Fig. 7.33b) 2PaPn3R1RPaPa (Fig. 7.34a) 2PaPn3R1RPaPat (Fig. 7.34b)
SPM with NF=0 NF Type 20 2PassRbssRR*R1RPacsPacs (Fig. 7.93) 20 2PassRbssRR*R1RPacsPatcs (Fig. 7.94) 26 2PassRbssRbcsRR*R1RPacsPacs (Fig. 7.95) 26 2PassRbssRbcsRR*R1RPacsPatcs (Fig. 7.96) 20 2PassPn2ssRR*R1RPacsPacs (Fig. 7.97) 20 2PassPn2ssRR*R1RPacsPatcs (Fig. 7.98) 20 2PassPn3ssR*R1RPacsPacs (Fig. 7.99) 20 2PassPn3ssR*R1RPacsPatcs (Fig. 7.100)
Limb topology Pass ⊥ Rbss||R ⊥ R* ⊥ ⊥ R R||Pacs||Pacs
Pass ⊥ Rbss||R ⊥ R* ⊥ ⊥ R R||Pacs||Patcs Pass ⊥ Rbss||Rbcs||R ⊥ R* ⊥⊥ R R||Pacs||Pacs Pass ⊥ Rbss||Rbcs||R ⊥ R* ⊥⊥ R R||Pacs||Patcs Pass ⊥ Pn2ss||R ⊥ R* ⊥ ⊥ R R||Pacs||Pacs Pass ⊥ Pn2ss||R ⊥ R* ⊥ ⊥ R R||Pacs||Patcs Pass ⊥ Pn3ss ⊥ R* ⊥ ⊥ R R||Pacs||Pacs Pass ⊥ Pn3ss ⊥ R* ⊥ ⊥ R R||Pacs||Patcs
478 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.45. Structural parametersa of spatial parallel mechanisms in Figs. 7.67 and 7.68 No.
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 a
Structural parameter
Solution PassPR-PassPC*-RRRPRR (Fig. 7.67a)
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
15 6 6 6 18 4 1 2 3 See Table 7.40
PassPR-PassPC*-RPassPassPass (Fig. 7.67b) PassPR-PassPC*-RPassPassPass (Fig. 7.68a,b) 19 6 6 13 25 7 0 3 3 See Table 7.40
4 5 6 6 6 0 4 5 6 ( v1 , v 2 , 3 12 24 3 0 0 10
4 5 6 6 6 18 4 5 7 ( v1 , v 2 , 3 30 42 4 0 1 10
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
11
11
fj
6
25
fj
27
46
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.2 Non overconstrained solutions Table 7.46. Structural parametersa of spatial parallel mechanisms in Fig. 7.69 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRRR*R-1RPP (Fig. 7.69a) 16 8 8 3 19 4 1 2 3 See Table 7.40
2PassPassRRR*R-1RPP (Fig. 7.69b) 22 12 12 3 27 6 1 2 3 See Table 7.40
6 6 3 6 6 0 6 6 3 ( v1 , v 2 , 3 12 24 3 0 0 12
6 6 3 12 12 0 8 8 3 ( v1 , v 2 , 3 24 36 7 0 4 20
δ
)
fj
12
20
fj
3
3
fj
27
43
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
479
480 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.47. Structural parametersa of spatial parallel mechanisms in Figs. 7.70 and 7.71 No.
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 a
Structural Solution parameter 2PassRPassR-1RPP 2PassPassPassR-1RPP 2PassRbssRR*R(Fig. 7.70a) (Fig. 7.70b) 1RPP (Fig. 7.71) m 18 22 20 p1 10 13 11 p2 10 13 11 p3 3 3 3 p 23 29 25 q 6 8 6 k1 1 1 1 k2 2 2 2 k 3 3 3 (RGi) See Table 7.40 See Table 7.40 See Table 7.40 (i=1,2,3) SG1 6 6 6 SG2 6 6 6 SG3 3 3 3 rG1 12 18 12 rG2 12 18 12 rG3 0 0 0 MG1 6 7 7 MG2 6 7 7 MG3 3 3 3 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) SF 3 3 3 rl 24 36 24 rF 36 48 36 MF 3 5 5 NF 0 0 0 TF 0 2 2 p1 18 25 19 f
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
fj
18
25
19
fj
3
3
3
fj
39
53
41
See footnote of Table 2.4 for the nomenclature of structural parameters
7.2 Non overconstrained solutions
481
Table 7.48. Structural parametersa of spatial parallel mechanisms in Figs. 7.72 and 7.73 No. Structural parameter
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRbssRbcsRR*R-1RPP (Fig. 7.72)
24 14 14 3 31 8 1 2 3 See Table 7.40
2PassPn2ssRR*R-1RPP (Fig. 7.73a) 2PassPn3ssR*R-1RPP (Fig. 7.73b) 22 12 12 3 27 6 1 2 3 See Table 7.40
6 6 3 18 18 0 7 7 3 ( v1 , v 2 , 3 36 48 5 0 2 25
6 6 3 12 12 0 8 8 3 ( v1 , v 2 , 3 24 36 7 0 4 20
δ
)
fj
25
20
fj
3
3
fj
53
43
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
482 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.49. Structural parametersa of spatial parallel mechanisms in Fig. 7.74 No. Structural parameter 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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRRR*R-1RPPass (Fig. 7.74a) 18 8 8 6 22 5 0 3 3 See Table 7.40
2PassPassRRR*R-1RPPass (Fig. 7.74b) 24 12 12 6 30 7 0 3 3 See Table 7.40
6 6 3 6 6 6 6 6 4 ( v1 , v 2 , 3 18 30 4 0 1 12
6 6 3 12 12 6 8 8 4 ( v1 , v 2 , 3 30 42 8 0 5 20
δ
)
fj
12
20
fj
10
10
fj
34
50
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.2 Non overconstrained solutions
483
Table 7.50. Structural parametersa of spatial parallel mechanisms in Figs. 7.75 and 7.76 No. Structural Solution parameter 2PassRPassR-1RPPass 2PassPassPassR-1RPPass 2PassRbssRR*R(Fig. 7.75a) (Fig. 7.75b) 1RPPass (Fig. 7.76) 1 m 20 24 22 2 p1 10 13 11 3 p2 10 13 11 4 p3 6 6 6 5 p 26 32 28 6 q 7 9 7 7 k1 0 0 0 8 k2 3 3 3 9 k 3 3 3 10 (RGi) See Table 7.40 See Table 7.40 See Table 7.40 (i=1,2,3) 11 SG1 6 6 6 12 SG2 6 6 6 13 SG3 3 3 3 14 rG1 12 18 12 15 rG2 12 18 12 16 rG3 6 6 6 17 MG1 6 7 7 18 MG2 6 7 7 19 MG3 4 4 4 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 3 22 rl 30 42 30 23 rF 42 54 42 24 MF 4 6 6 25 NF 0 0 0 26 TF 1 3 3 p1 27 18 25 19 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
fj
18
25
19
fj
10
10
10
fj
46
60
48
See footnote of Table 2.4 for the nomenclature of structural parameters
484 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.51. Structural parametersa of spatial parallel mechanisms in Figs. 7.77 and 7.78 No.
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 a
Structural parameter
Solution 2PassRbssRbcsRR*R-1RPPass (Fig. 7.77)
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
26 14 14 6 34 9 0 3 3 See Table 7.40
2PassPn2ssRR*R-1RPPass (Fig. 7.78a) 2PassPn3ssR*R-1RPPass (Fig. 7.78b) 24 12 12 6 30 7 0 3 3 See Table 7.40
6 6 3 18 18 6 7 7 4 ( v1 , v 2 , 3 42 54 6 0 3 25
6 6 3 12 12 6 8 8 4 ( v1 , v 2 , 3 30 42 8 0 5 20
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
25
20
fj
10
10
fj
60
50
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.2 Non overconstrained solutions
485
Table 7.52. Structural parametersa of spatial parallel mechanisms in Fig. 7.79 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRRR*R-1RPassP (Fig. 7.79a) 18 8 8 6 22 5 0 3 3 See Table 7.40
2PassPassRRR*R-1RPassP (Fig. 7.79b) 24 12 12 6 30 7 0 3 3 See Table 7.40
6 6 3 6 6 6 6 6 4 ( v1 , v 2 , 3 18 30 4 0 1 12
6 6 3 12 12 6 8 8 4 ( v1 , v 2 , 3 30 42 8 0 5 20
δ
)
fj
12
20
fj
10
10
fj
34
50
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
486 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.53. Structural parametersa of spatial parallel mechanisms in Figs. 7.80 and 7.81 No. Structural Solution parameter 2PassRPassR-1RPassP 2PassPassPassR-1RPassP 2PassRbssRR*R(Fig. 7.80a) (Fig. 7.80b) 1RPassP (Fig. 7.81) 1 m 20 24 22 2 p1 10 13 11 3 p2 10 13 11 4 p3 6 6 6 5 p 26 32 28 6 q 7 9 7 7 k1 0 0 0 8 k2 3 3 3 9 k 3 3 3 10 (RGi) See Table 7.40 See Table 7.40 See Table 7.40 (i=1,2,3) 11 SG1 6 6 6 12 SG2 6 6 6 13 SG3 3 3 3 14 rG1 12 18 12 15 rG2 12 18 12 16 rG3 6 6 6 17 MG1 6 7 7 18 MG2 6 7 7 19 MG3 4 4 4 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 3 22 rl 30 42 30 23 rF 42 54 42 24 MF 4 6 6 25 NF 0 0 0 26 TF 1 3 3 p1 27 18 25 19 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
fj
18
25
19
fj
10
10
10
fj
46
60
48
See footnote of Table 2.4 for the nomenclature of structural parameters
7.2 Non overconstrained solutions
487
Table 7.54. Structural parametersa of spatial parallel mechanisms in Figs. 7.82 and 7.83 No.
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 a
Structural parameter
Solution 2PassRbssRbcsRR*R-1RPassP (Fig. 7.82)
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
26 14 14 6 34 9 0 3 3 See Table 7.40
2PassPn2ssRR*R-1RPassP (Fig. 7.83a) 2PassPn3ssR*R-1RPassP (Fig. 7.83b) 24 12 12 6 30 7 0 3 3 See Table 7.40
6 6 3 18 18 6 7 7 4 ( v1 , v 2 , 3 42 54 6 0 3 25
6 6 3 12 12 6 8 8 4 ( v1 , v 2 , 3 30 42 8 0 5 20
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
25
20
fj
10
10
fj
60
50
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
488 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.55. Structural parametersa of spatial parallel mechanisms in Fig. 7.84 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRRR*R-1RPassPass (Fig. 7.84a) 20 8 8 9 25 6 0 3 3 See Table 7.40
2PassPassRRR*R-1RPassPass (Fig. 7.84b) 26 12 12 9 33 8 0 3 3 See Table 7.40
6 6 3 6 6 12 6 6 5 ( v1 , v 2 , 3 24 36 5 0 2 12
6 6 3 12 12 12 8 8 5 ( v1 , v 2 , 3 36 48 9 0 6 20
δ
)
fj
12
20
fj
17
17
fj
41
57
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.2 Non overconstrained solutions Table 7.56. Structural parametersa of spatial parallel mechanisms in Fig. 7.85 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRPassR-1RPassPass (Fig. 7.85a) 22 10 10 9 29 8 0 3 3 See Table 7.40
2PassPassPassR-1RPassPass (Fig. 7.85b) 26 13 13 9 35 10 0 3 3 See Table 7.40
6 6 3 12 12 12 6 6 5 ( v1 , v 2 , 3 36 48 5 0 2 18
6 6 3 18 18 12 7 7 5 ( v1 , v 2 , 3 48 60 7 0 4 25
δ
)
fj
18
25
fj
17
17
fj
53
67
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
489
490 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.57. Structural parametersa of spatial parallel mechanisms in Figs. 7.867.88 No.
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 a
Structural parameter
Solution 2PassRbssRR*R1RPassPass (Fig. 7.86)
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
24 11 11 9 31 8 0 3 3 See Table 7.40
2PassRbssRbcsRR*R- 2PassPn2ssRR*R1RPassPass 1RPassPass (Fig. 7.87) (Fig. 7.88a) 2PassPn3ssR*R1RPassPass (Fig. 7.88b) 28 26 14 12 14 12 9 9 37 33 10 8 0 0 3 3 3 3 See Table 7.40 See Table 7.40
6 6 3 12 12 12 7 7 5 ( v1 , v 2 , 3 36 48 7 0 4 19
6 6 3 18 18 12 7 7 5 ( v1 , v 2 , 3 48 60 7 0 4 25
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
δ
)
6 6 3 12 12 12 8 8 5 ( v1 , v 2 , 3 36 48 9 0 6 20
fj
19
25
20
fj
17
17
17
fj
55
67
57
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
7.2 Non overconstrained solutions
491
Table 7.58. Structural parametersa of spatial parallel mechanisms in Figs. 7.897.91 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassRRR*R1RPacsPacs (Fig. 7.89a) 2PassRRR*R1RPacsPatcs (Fig. 7.89b) 20 8 8 9 25 6 0 3 3 See Table 7.40
2PassPassRRR*R1RPacsPacs (Fig. 7.90a) 2PassPassRR*R1RPacsPatcs (Fig. 7.90b) 26 12 12 9 33 8 0 3 3 See Table 7.40
2PassRPassR1RPacsPacs (Fig. 7.91a) 2PaRRPaR1RPacsPatcs (Fig. 7.91b) 22 10 10 9 29 8 0 3 3 See Table 7.40
6 6 3 6 6 12 6 6 3 ( v1 , v 2 , 3 24 36 3 0 0 12
6 6 3 12 12 12 8 8 3 ( v1 , v 2 , 3 36 48 7 0 4 20
6 6 3 12 12 12 6 6 3 ( v1 , v 2 , 3 36 48 3 0 0 18
δ
)
δ
)
fj
12
20
18
fj
15
15
15
fj
39
55
51
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
492 7 Spatial PMs with uncoupled planar motion of the moving platform Table 7.59. Structural parametersa of spatial parallel mechanisms in Figs. 7.927.94 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PassPassPassR-1RPacsPacs (Fig. 7.92a) 2PassPassPassR-1RPacsPatcs (Fig. 7.92b) 26 13 13 9 35 10 0 3 3 See Table 7.40
2PassRbssRR*R-1RPacsPacs (Fig. 7.93) 2PassRbssRR*R-1RPacsPatcs (Fig. 7.94) 24 11 11 9 31 8 0 3 3 See Table 7.40
6 6 3 18 18 12 7 7 3 ( v1 , v 2 , 3 48 60 5 0 2 25
6 6 3 12 12 12 7 7 3 ( v1 , v 2 , 3 36 48 5 0 2 19
δ
)
fj
25
19
fj
15
15
fj
65
53
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
7.2 Non overconstrained solutions
493
Table 7.60. Structural parametersa of spatial parallel mechanisms in Figs. 7.957.100 No.
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 a
Structural Solution parameter 2PassRbssRbcsRR*R1RPacsPacs (Fig. 7.95) 2PassRbssRbcsRR*R1RPacsPatcs (Fig. 7.96) m 28 p1 14 p2 14 p3 9 p 37 q 10 k1 0 k2 3 k 3 (RGi) See Table 7.40 (i=1,2,3) SG1 6 SG2 6 SG3 3 rG1 18 rG2 18 rG3 12 MG1 7 MG2 7 MG3 3 (RF) ( v1 , v 2 , δ ) SF 3 rl 48 rF 60 MF 5 NF 0 TF 2 p1 25 f
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PassPn2ssRR*R-1RPacsPacs (Fig. 7.97) 2PassPn2ssRR*R-1RPacsPatcs (Fig. 7.98) 2PassPn3ssR*R-1RPacsPacs (Fig. 7.99) 2PassPn3ssR*R-1RPacsPatcs (Fig. 7.100)
26 12 12 9 33 8 0 3 3 See Table 7.40 6 6 3 12 12 12 8 8 3 ( v1 , v 2 , 3 36 48 7 0 4 20
fj
25
20
fj
15
15
fj
65
55
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
494 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.67. Non overconstrained SPMs with planar motion of the moving platform of types PassPR-PassPC*-RRRPRR (a) and PassPR-PassPC*-RPassPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=3, TF=0, (a), MF=4, TF=1 (b), limb topology Pass ⊥ P ⊥ ||R, Pass ⊥ P ⊥ ||C* and R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (a), R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass (b)
7.2 Non overconstrained solutions
495
Fig. 7.68. PassPR-PassPC*-RPassPassPass-type non overconstrained SPMs with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, Pass ⊥ P ⊥ ||C* and TF=1, limb topology Pass ⊥ P ⊥ ||R, NF=0, ss ss ss ⊥ ss ss ⊥ ss R ⊥ Pa ⊥ Pa ||Pa (a), R ⊥ Pa ||Pa ⊥ Pa (b)
496 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.69. Non overconstrained SPMs with planar motion of the moving platform of types 2PassRRR*R-1RPP (a) and 2PassPassRRR*R-1RPP defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=3, TF=0, (a), MF=7, TF=4 (b), limb topology
R ⊥ P ⊥ ⊥ P and Pass ⊥ R||R ⊥ ⊥ R ⊥ ⊥ R (a), Pass ⊥ Pass||R||R ⊥ ⊥ R ⊥ ⊥ R (b)
7.2 Non overconstrained solutions
497
Fig. 7.70. Non overconstrained SPMs with planar motion of the moving platform of types 2PassRPassR-1RPP (a) and 2PassPassPassR-1RPP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=3, TF=0, (a), MF=5, TF=2 (b), limb topology
R ⊥ P ⊥ ⊥ P and Pass ⊥ R||Pass ⊥ ||R (a), Pass ⊥ Pass||Pass ⊥ ||R (b)
498 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.71. 2PassRbssRR*R-1RPP-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0,
TF=2, limb topology Pass ⊥ Rbss||R ⊥ ⊥ R ⊥ ⊥ R and R ⊥ P ⊥ ⊥ P
7.2 Non overconstrained solutions
499
Fig. 7.72. 2PassRbssRbcsRR*R-1RPP-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0,
TF=2, limb topology Pass ⊥ Rbss||Rbcs||R ⊥ ⊥ R ⊥ ⊥ R and R ⊥ P ⊥ ⊥ P
500 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.73. Non overconstrained SPMs with planar motion of the moving platform of types 2PassPn2ssRR*R-1RPP (a) and 2PassPn3ssR*R-1RPP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, NF=0, TF=4 limb topology R ⊥ P ⊥ ⊥ P and
Pass ⊥ Pn2ss||R ⊥ ⊥ R ⊥ ⊥ R (a), Pass ⊥ Pn3ss ⊥ ⊥ R ⊥ ⊥ R (b)
7.2 Non overconstrained solutions
501
Fig. 7.74. Non overconstrained SPMs with planar motion of the moving platform of types 2PassRRR*R-1RPPass (a) and 2PassPassRRR*R-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=4, TF=1, (a), MF=8, TF=5 (b), limb topology R ⊥ P ⊥ ||Pass and Pass ⊥ R||R ⊥ ⊥ R ⊥ ⊥ R (a), Pass ⊥ Pass||R||R ⊥ ⊥ R ⊥ ⊥ R (b)
502 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.75. Non overconstrained SPMs with planar motion of the moving platform of types 2PassRPassR-1RPPass (a) and 2PassPassPassR-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=4, TF=1, (a), MF=6, TF=3 (b), limb topology R ⊥ P ⊥ ||Pass and Pass ⊥ R||Pass ⊥ ||R (a), Pass ⊥ Pass||Pass ⊥ ||R (b)
7.2 Non overconstrained solutions
503
Fig. 7.76. 2PassRbssRR*R-1RPPass-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0,
TF=3, limb topology Pass ⊥ Rbss||R ⊥ ⊥ R ⊥ ⊥ R and R ⊥ P ⊥ ||Pass
504 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.77. 2PassRbssRbcsRR*R-1RPPass-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0,
TF=3, limb topology Pass ⊥ Rbss||Rbcs||R ⊥ ⊥ R ⊥ ⊥ R and R ⊥ P ⊥ ||Pass
7.2 Non overconstrained solutions
505
Fig. 7.78. Non overconstrained SPMs with planar motion of the moving platform of types 2PassPn2ssRR*R-1RPPass (a) and 2PassPn3ssR*R-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=8, NF=0, TF=5, limb topology R ⊥ P ⊥ ||Pass and
Pass ⊥ Pn2ss||R ⊥ ⊥ R ⊥ ⊥ R (a), Pass ⊥ Pn3ss ⊥ ⊥ R ⊥ ⊥ R (b)
506 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.79. Non overconstrained SPMs with planar motion of the moving platform of types 2PassRRR*R-1RPassP (a) and 2PassPassRRR*R-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=4, TF=1, (a), MF=8, TF=5 (b), limb topology R||Pass ⊥ P and Pass ⊥ R||R ⊥ ⊥ R ⊥ ⊥ R (a), Pass ⊥ Pass||R||R ⊥ ⊥ R ⊥ ⊥ R (b)
7.2 Non overconstrained solutions
507
Fig. 7.80. Non overconstrained SPMs with planar motion of the moving platform of types 2PassRPassR-1RPassP (a) and 2PassPassPassR-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=4, TF=1, (a), MF=6, TF=3 (b), limb topology R||Pass ⊥ P and Pass ⊥ R||Pass ⊥ ||R (a), Pass ⊥ Pass||Pass ⊥ ||R (b)
508 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.81. 2PassRbssRR*R-1RPassP-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0,
TF=3, limb topology Pass ⊥ Rbss||R ⊥ ⊥ R ⊥ ⊥ R and R||Pass ⊥ P
7.2 Non overconstrained solutions
509
Fig. 7.82. 2PassRbssRbcsRR*R-1RPassP-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0,
TF=3, limb topology Pass ⊥ Rbss||Rbcs||R ⊥ ⊥ R ⊥ ⊥ R and R||Pass ⊥ P
510 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.83. Non overconstrained SPMs with planar motion of the moving platform of types 2PassPn2ssRR*R-1RPassP (a) and 2PassPn3ssR*R-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=8, NF=0, TF=5, limb topology R||Pass ⊥ P and
Pass ⊥ Pn2ss||R ⊥ ⊥ R ⊥ ⊥ R (a), Pass ⊥ Pn3ss ⊥ ⊥ R ⊥ ⊥ R (b)
7.2 Non overconstrained solutions
511
Fig. 7.84. Non overconstrained SPMs with planar motion of the moving platform of types 2PassRRR*R-1RPassPass (a) and 2PassPassRRR*R-1RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=5, TF=2, (a), MF=9, TF=6 (b), limb topology R||Pass||Pass and Pass ⊥ R||R ⊥ ⊥ R ⊥ ⊥ R (a), Pass ⊥ Pass||R||R ⊥ ⊥ R ⊥ ⊥ R (b)
512 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.85. Non overconstrained SPMs with planar motion of the moving platform of types 2PassRPassR-1RPassPass (a) and 2PassPassPassR-1RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=5, TF=2, (a), MF=7, TF=4 (b), limb topology R||Pass||Pass and Pass ⊥ R||Pass ⊥ ||R (a), Pass ⊥ Pass||Pass ⊥ ||R (b)
7.2 Non overconstrained solutions
513
Fig. 7.86. 2PassRbssRR*R-1RPassPass-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, NF=0,
TF=4, limb topology Pass ⊥ Rbss||R ⊥ ⊥ R ⊥ ⊥ R and R||Pass||Pass
514 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.87. 2PassRbssRbcsRR*R-1RPassPass-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7,
NF=0, TF=4, limb topology Pass ⊥ Rbss||Rbcs||R ⊥ ⊥ R ⊥ ⊥ R and R||Pass||Pass
7.2 Non overconstrained solutions
515
Fig. 7.88. Non overconstrained SPMs with planar motion of the moving platform of types 2PassPn2ssRR*R-1RPassPass (a) and 2PassPn3ssR*R-1RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=9, NF=0, TF=6, limb topology
R||Pass||Pass and Pass ⊥ Pn2ss||R ⊥ ⊥ R ⊥ ⊥ R (a), Pass ⊥ Pn3ss ⊥ ⊥ R ⊥ ⊥ R (b)
516 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.89. Non overconstrained SPMs with planar motion of the moving platform of types 2PassRRR*R-1RPacsPacs (a) and 2PassRRR*R-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology Pass ⊥ R||R ⊥ R* ⊥ ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
7.2 Non overconstrained solutions
517
Fig. 7.90. Non overconstrained SPMs with planar motion of the moving platform of types 2PassPassRRR*R-1RPacsPacs (a) and 2PassPassRR*R-1RPacsPatcs (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, NF=0, TF=4, limb topology
Pass ⊥ Pass||R||R ⊥ R* ⊥ ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
518 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.91. Non overconstrained SPMs with planar motion of the moving platform of types 2PassRPassR-1RPacsPacs (a) and 2PaRRPaR-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=0, limb topology Pass ⊥ R||Pass ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
7.2 Non overconstrained solutions
519
Fig. 7.92. Non overconstrained SPMs with planar motion of the moving platform of types 2PassPassPassR-1RPacsPacs (a) and 2PassPassPassR-1RPacsPatcs (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0, TF=2, limb topology Pass ⊥ Pass||Pass ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
520 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.93. 2PassRbssRR*R-1RPacsPacs-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v 2 , δ ), MF=5, NF=0,
TF=2, limb topology Pass ⊥ Rbss||R ⊥ R* ⊥ ⊥ R and R||Pacs||Pacs
7.2 Non overconstrained solutions
521
Fig. 7.94. 2PassRbssRR*R-1RPacsPatcs-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0,
TF=2, limb topology Pass ⊥ Rbss||R ⊥ R* ⊥ ⊥ R and R||Pacs||Patcs
522 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.95. 2PassRbssRbcsRR*R-1RPacsPacs-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5,
NF=0, TF=2, limb topology Pass ⊥ Rbss||Rbcs||R ⊥ R* ⊥ ⊥ R and R||Pacs||Pacs
7.2 Non overconstrained solutions
523
Fig. 7.96. 2PassRbssRbcsRR*R-1RPacsPatcs-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5,
NF=0, TF=2, limb topology Pass ⊥ Rbss||Rbcs||R ⊥ R* ⊥ ⊥ R and R||Pacs||Patcs
524 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.97. 2PassPn2ssRR*R-1RPacsPacs-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, NF=0,
TF=4, limb topology Pass ⊥ Pn2ss||R ⊥ R* ⊥ ⊥ R and R||Pacs||Pacs
7.2 Non overconstrained solutions
525
Fig. 7.98. 2PassPn2ssRR*R-1RPacsPatcs-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, NF=0,
TF=4, limb topology Pass ⊥ Pn2ss||R ⊥ R* ⊥ ⊥ R and R||Pacs||Patcs
526 7 Spatial PMs with uncoupled planar motion of the moving platform
Fig. 7.99. 2PassPn3ssR*R-1RPacsPacs-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, NF=0,
TF=4, limb topology Pass ⊥ Pn3ss ⊥ R* ⊥ ⊥ R and R||Pacs||Pacs
7.2 Non overconstrained solutions
527
Fig. 7.100. 2PassPn3ssR*R-1RPacsPatcs-type non overconstrained SPM with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, NF=0,
TF=4, limb topology Pass ⊥ Pn3ss ⊥ R* ⊥ ⊥ R and R||Pacs||Patcs
8 Maximally regular SPMs with planar motion of the moving platform
Maximally regular spatial parallel robotic manipulators (SPMs) are actuated by one rotating and two linear actuators and can have various degrees of overconstraint. In these solutions, the three operational velocities are equal to their corresponding actuated joint velocities: v1 = &q1 , v2 = &q2 and ωδ = &q3 . The Jacobian matrix in Eq. (1.18) is the identity matrix. We call spatial Isoglide3-T2R1 with planar motion of the moving platform the parallel mechanisms of this family in which at least one limb is a spatial kinematic chain.
8.1 Overconstrained solutions Equation (1.16) indicates that overconstrained solutions of maximally regular spatial parallel robots with q independent loops meet the condition p ∑ 1 fi < 3 + 6q . Various solutions fulfil this condition along with MF=SF=3 and (RF)=( v1 ,v2 ,ωδ ). They have two identical limbs for positioning and a different limb for rotating the moving platform. 8.1.1 Basic solutions In the basic solutions of overconstrained maximally regular spatial parallel robots, F ← G1-G2-G3, the moving platform n nGi (i=1, 2, 3) is connected to the reference platform 1 1Gi 0 by three limbs. Two planar or spatial limbs G1 and G2 are used for positioning the moving platform and a spatial or planar limb G3 for orienting it. Thera are no idle mobilities in the basic solutions. Various solutions of maximally regular SPMs with planar motion of the moving platform and no idle mobilities can be obtained by using G1- and G2-limbs with identical or different topology presented in Figs. 2.1f, 8.1 and 8.2, and a planar or spatial G3-limb in Figs. 2.1g, 2.2f-h, 2.3 and 6.1. G. Gogu, Structural Synthesis of Parallel Robots, Solid Mechanics and Its Applications 173, DOI 10.1007/978-90-481-9831-3_8, © Springer Science + Business Media B.V. 2010
529
530
8 Maximally regular SPMs with planar motion of the moving platform
Only solutions with identical G1- and G2-limbs are illustrated in Figs. 8.38.29. The bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms in Figs. 8.3-8.29 are given in Table 8.1. The limb topology and connecting conditions of these solutions are systematized in Tables 8.2-8.8, as are their structural parameters in Tables 8.9-8.19.
Table 8.1. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 8.3-8.29 No. Parallel mechanism 1 Fig. 8.3a 2 3
4
Basis (RG1) ( v1 , v 2 ,
δ
)
Figs. 8.3b, 8.4 ( v1 , v2 , δ ) Figs. 8.5, 8.6a, ( v1 , v2 , v2 , α , 8.7-8.9, 8.10a, 8.11-8.13, 8.14a 8.15-8.17, 8.18a, 8.19-8.23, 8.258.29 Figs. 8.6b, 8.10b, ( v1 ,v2 , v2 , δ ) 7.11b, 8.14b, 8.18b, 8.24
δ
(RG2) ( v1 , v 2 ,
δ
)
(RG3) ( v1 , v 2 , v 3 ,
α
,
( v1 , v 2 ,
δ
)
( v1 , v 2 , v 2 ,
δ
)
) ( v1 , v 2 , v 2 ,
β
,
( v1 , v 2 , v 2 ,
δ
)
δ
) ( v1 , v 2 ,
δ
)
( v1 , v 2 ,
δ
)
β
,
δ
)
8.1 Overconstrained solutions
531
Table 8.2. Limb topology and connecting conditions of the overconstrained maximally regular SPMs with planar motion of the moving platform and no idle mobilities presented in Figs. 8.3-8.5 No. SPM type
Limb topology
Connecting conditions
1
2PPR-1RRRPRR (Fig. 8.3a)
P ⊥ P ⊥⊥ R (Fig. 2.1f) R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (Fig. 6.1a)
2
2PPR-1RPaPaPa (Fig. 8.3b)
3
2PPR-1RPaPaPa (Fig. 8.4a)
4
2PPR-1RPaPaPa (Fig. 8.4b)
5
2PRRRR-1RPP (Fig. 8.5a)
6
2PPaRRR-1RPP (Fig. 8.5b)
P ⊥ P ⊥⊥ R (Fig. 2.1f) R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (Fig. 6.1b) P ⊥ P ⊥⊥ R (Fig. 2.1f) R ⊥ Pa ⊥ ⊥ Pa||Pa (Fig. 6.1c) P ⊥ P ⊥⊥ R (Fig. 2.1f) R ⊥ Pa||Pa ⊥ ⊥ Pa (Fig. 6.1d) P||R||R||R ⊥ R (Fig. 8.1a) R ⊥ P ⊥⊥ P (Fig. 2.1g) P||Pa||R||R ⊥ R (Fig. 8.1b) R ⊥ P ⊥⊥ P (Fig. 2.1g)
The directions of the translational actuated joints are orthogonal. The last revolute joints of limbs G1 and G2 have the same axis which is parallel to the axis of the actuated revolute joint of limb G3. Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
532
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.3. Limb topology and connecting conditions of the overconstrained maximally regular SPMs with planar motion of the moving platform and no idle mobilities presented in Figs. 8.6-8.9 No. SPM type
Limb topology
Connecting conditions
1
2PRRPaR-1RPP (Fig. 8.6a)
P||R||R||Pa ⊥ R (Fig. 8.1c) R ⊥ P ⊥⊥ P (Fig. 2.1g)
2
2PPaPaR-1RPP (Fig. 8.6b)
3
2PRRbRR-1RPP (Fig. 8.7a)
4
2PRRbRbRR-1RPP (Fig. 8.7b)
5
2PPn2RR-1RPP (Fig. 8.8a)
6
2PPn3R-1RPP (Fig. 8.8b)
7
2PRRRR-1RPPa (Fig. 8.9a)
8
2PPaRRR-1RPPa (Fig. 8.9b)
P||Pa||Pa ⊥ R (Fig. 8.1d) R ⊥ P ⊥⊥ P (Fig. 2.1g) P||R||Rb||R ⊥ R (Fig. 8.2a) R ⊥ P ⊥⊥ P (Fig. 2.1g) P||R||Rb||Rb||R ⊥ R (Fig. 8.2b) R ⊥ P ⊥⊥ P (Fig. 2.1g) P||Pn2||R ⊥ R (Fig. 8.2c) R ⊥ P ⊥⊥ P (Fig. 2.1g) P||Pn3 ⊥ R (Fig. 8.2d) R ⊥ P ⊥⊥ P (Fig. 2.1g) P||R||R||R ⊥ R (Fig. 8.1a) R ⊥ P ⊥ ||Pa (Fig. 2.2f) P||Pa||R||R ⊥ R (Fig. 8.1b) R ⊥ P ⊥ ||Pa (Fig. 2.2f)
The directions of the translational actuated joints are orthogonal. The last revolute joints of limbs G1 and G2 have the same axis which is parallel to the axis of the actuated revolute joint of limb G3. Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
8.1 Overconstrained solutions
533
Table 8.4. Limb topology and connecting conditions of the overconstrained maximally regular SPMs with planar motion of the moving platform and no idle mobilities presented in Figs. 8.10-8.13 No. SPM type
Limb topology
Connecting conditions
1
2PRRPaR-1RPPa (Fig. 8.10a)
P||R||R||Pa ⊥ R (Fig. 8.1c) R ⊥ P ⊥ ||Pa (Fig. 2.2f)
2
2PPaPaR-1RPPa (Fig. 8.10b)
3
2PRRbRR-1RPPa (Fig. 8.11a)
4
2PRRbRbRR-1RPPa (Fig. 8.11b)
5
2PPn2RR-1RPPa (Fig. 8.12a)
6
2PPn3R-1RPPa (Fig. 8.12b)
7
2PRRRR-1RPaP (Fig. 8.13a)
8
2PPaRRR-1RPaP (Fig. 8.13b)
P||Pa||Pa ⊥ R (Fig. 8.1d) R ⊥ P ⊥ ||Pa (Fig. 2.2f) P||R||Rb||R ⊥ R (Fig. 8.2a) R ⊥ P ⊥ ||Pa (Fig. 2.2f) P||R||Rb||Rb||R ⊥ R (Fig. 8.2b) R ⊥ P ⊥ ||Pa (Fig. 2.2f) P||Pn2||R ⊥ R (Fig. 8.2c) R ⊥ P ⊥ ||Pa (Fig. 2.2f) P||Pn3 ⊥ R (Fig. 8.2c) R ⊥ P ⊥ ||Pa (Fig. 2.2f) P||R||R||R ⊥ R (Fig. 8.1a) R||Pa ⊥ P (Fig. 2.2g) P||Pa||R||R ⊥ R (Fig. 8.1b) R||Pa ⊥ P (Fig. 2.2g)
The directions of the translational actuated joints are orthogonal. The last revolute joints of limbs G1 and G2 have the same axis which is parallel to the axis of the actuated revolute joint of limb G3. Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
534
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.5. Limb topology and connecting conditions of the overconstrained maximally regular SPMs with planar motion of the moving platform and no idle mobilities presented in Figs. 8.14-8.17 No. SPM type
Limb topology
Connecting conditions
1
2PRRPaR-1RPaP (Fig. 8.14a)
P||R||R||Pa ⊥ R (Fig. 8.1c) R||Pa ⊥ P (Fig. 2.2g)
2
2PPaPaR-1RPaP (Fig. 8.14b)
3
2PRRbRR-1RPaP (Fig. 8.15a)
4
2PRRbRbRR-1RPaP (Fig. 8.15b)
5
2PPn2RR-1RPaP (Fig. 8.16a)
6
2PPn3R-1RPaP (Fig. 8.16b)
7
2PRRRR-1RPaPa (Fig. 8.17a)
8
2PPaRRR-1RPaPa (Fig. 8.17b)
P||Pa||Pa ⊥ R (Fig. 8.1d) R||Pa ⊥ P (Fig. 2.2g) P||R||Rb||R ⊥ R (Fig. 8.2a) R||Pa ⊥ P (Fig. 2.2g) P||R||Rb||Rb||R ⊥ R (Fig. 8.2b) R||Pa ⊥ P (Fig. 2.2g) P||Pn2||R ⊥ R (Fig. 8.2c) R||Pa ⊥ P (Fig. 2.2g) P||Pn3 ⊥ R (Fig. 8.2d) R||Pa ⊥ P (Fig. 2.2g) P||R||R||R ⊥ R (Fig. 8.1a) R||Pa||Pa (Fig. 2.2h) P||Pa||R||R ⊥ R (Fig. 8.1b) R||Pa||Pa (Fig. 2.2h)
The directions of the translational actuated joints are orthogonal. The last revolute joints of limbs G1 and G2 have the same axis which is parallel to the axis of the actuated revolute joint of limb G3. Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
8.1 Overconstrained solutions
535
Table 8.6. Limb topology and connecting conditions of the overconstrained maximally regular SPMs with planar motion of the moving platform and no idle mobilities presented in Figs. 8.18-8.21 No. SPM type
Limb topology
Connecting conditions
1
2PRRPaR-1RPaPa (Fig. 8.18a)
P||R||R||Pa ⊥ R (Fig. 8.1c) R||Pa||Pa (Fig. 2.2h)
2
2PPaPaR-1RPaPa (Fig. 8.18b)
The directions of the translational actuated joints are orthogonal. The last revolute joints of limbs G1 and G2 have the same axis which is parallel to the axis of the actuated revolute joint of limb G3. Idem No. 1
3
4
5
6
7
8
P||Pa||Pa ⊥ R (Fig. 8.1d) R||Pa||Pa (Fig. 2.2h) 2PRRbRR-1RPaPa P||R||Rb||R ⊥ R (Fig. 8.19a) (Fig. 8.2a) R||Pa||Pa (Fig. 2.2h) 2PRRbRbRR-1RPaPa P||R||Rb||Rb||R ⊥ R (Fig. 8.19b) (Fig. 8.2b) R||Pa||Pa (Fig. 2.2h) 2PPn2RR-1RPaPa P||Pn2||R ⊥ R (Fig. 8.20a) (Fig. 8.2c) R||Pa||Pa (Fig. 2.2h) P||Pn3 ⊥ R 2PPn3R-1RPaPa (Fig. 8.20b) (Fig. 8.2d) R||Pa||Pa (Fig. 2.2h) 2PRRRR-1RPaPa P||R||R||R ⊥ R (Fig. 8.21a) (Fig. 8.1a) R||Pa||Pa (Fig. 2.3a) 2PRRRR-1RPaPat P||R||R||R ⊥ R (Fig. 8.21b) (Fig. 8.1a) R||Pa||Pat (Fig. 2.3b)
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
536
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.7. Limb topology and connecting conditions of the overconstrained maximally regular SPMs with planar motion of the moving platform and no idle mobilities presented in Figs. 8.22-8.25 No. SPM type
Limb topology
Connecting conditions
1
2PPaRRR-1RPaPa (Fig. 8.22a)
P||Pa||R||R ⊥ R (Fig. 8.1b) R||Pa||Pa (Fig. 2.3a)
2
2PPaRRR-1RPaPat (Fig. 8.22b)
3
2PRRPaR-1RPaPa (Fig. 8.23a)
4
2PRRPaR-1RPaPat (Fig. 8.23b)
5
2PPaPaR-1RPaPa (Fig. 8.24a)
6
2PPaPaR-1RPaPat (Fig. 8.24b)
7
2PRRbRR-1RPaPa (Fig. 8.25a)
8
2PRRbRR-1RPaPat (Fig. 8.25b)
P||Pa||R||R ⊥ R (Fig. 8.1b) R||Pa||Pat (Fig. 2.3b) P||R||R||Pa ⊥ R (Fig. 8.1c) R||Pa||Pa (Fig. 2.3a) P||R||R||Pa ⊥ R (Fig. 8.1c) R||Pa||Pat (Fig. 2.3b) P||Pa||Pa ⊥ R (Fig. 8.1d) R||Pa||Pa (Fig. 2.3a) P||Pa||Pa ⊥ R (Fig. 8.1d) R||Pa||Pat (Fig. 2.3b) P||R||Rb||R ⊥ R (Fig. 8.2a) R||Pa||Pa (Fig. 2.3a) P||R||Rb||R ⊥ R (Fig. 8.2a) R||Pa||Pat (Fig. 2.3b)
The directions of the translational actuated joints are orthogonal. The last revolute joints of limbs G1 and G2 have the same axis which is parallel to the axis of the actuated revolute joint of limb G3. Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
8.1 Overconstrained solutions
537
Table 8.8. Limb topology and connecting conditions of the overconstrained maximally regular SPMs with planar motion of the moving platform and no idle mobilities presented in Figs. 8.26-8.29 No. SPM type
Limb topology
1
2PRRbRbRR-1RPaPa P||R||Rb||Rb||R ⊥ R (Fig. 8.26) (Fig. 8.2b) R||Pa||Pa (Fig. 2.3a)
2
2PRRbRbRR-1RPaPat P||R||Rb||Rb||R ⊥ R (Fig. 8.27) (Fig. 8.2b) R||Pa||Pat (Fig. 2.3b) 2PPn2RR-1RPaPa P||Pn2||R ⊥ R (Fig. 8.28a) (Fig. 8.2c) R||Pa||Pa (Fig. 2.3a) 2PPn2RR-1RPaPat P||Pn2||R ⊥ R (Fig. 8.28b) (Fig. 8.2c) R||Pa||Pat (Fig. 2.3a) 2PPn3R-1RPaPa P||Pn3 ⊥ R (Fig. 8.29a) (Fig. 8.2d) R||Pa||Pa (Fig. 2.3a) P||Pn3 ⊥ R 2PPn3R-1RPaPat (Fig. 8.29b) (Fig. 8.2d) R||Pa||Pat (Fig. 2.3b)
3
4
5
6
Connecting conditions The directions of the translational actuated joints are orthogonal. The last revolute joints of limbs G1 and G2 have the same axis which is parallel to the axis of the actuated revolute joint of limb G3. Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
Idem No. 1
538
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.9. Structural parametersa of spatial parallel mechanisms in Figs. 8.3 and 8.4 No.
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 a
Structural parameter
Solution 2PPR-1RRRPRR (Fig. 8.3a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
11 3 3 6 12 2 3 0 3 See Table 8.1
2PPR-1RPaPaPa (Fig. 8.3b) 2PPR-1RPaPaPa (Fig. 8.4a,b) 15 3 3 13 19 5 2 1 3 See Table 8.1
3 3 6 0 0 0 3 3 6 ( v1 , v 2 , 3 0 9 3 3 0 3
3 3 4 0 0 9 3 3 4 ( v1 , v 2 , 3 9 16 3 14 0 3
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
3
3
fj
6
13
fj
12
19
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
8.1 Overconstrained solutions
539
Table 8.10. Structural parametersa of spatial parallel mechanisms in Figs. 8.5 and 8.6 No.
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 a
Structural parameter
Solution 2PRRRR-1RPP (Fig. 8.5a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PPaPaR-1RPP (Fig. 8.6b)
12 5 5 3 13 2 3 0 3 See Table 8.1
2PPaRRR-1RPP (Fig. 8.5b) 2PRRPaR-1RPP (Fig. 8.6a) 16 8 8 3 19 4 1 2 3 See Table 8.1
18 10 10 3 23 6 1 2 3 See Table 8.1
5 5 3 0 0 0 5 5 3 ( v1 , v 2 , 3 0 10 3 2 0 5
5 5 3 3 3 0 5 5 3 ( v1 , v 2 , 3 6 16 3 8 0 8
4 4 3 6 6 0 4 4 3 ( v1 , v 2 , 3 12 20 3 16 0 10
δ
)
δ
)
fj
5
8
10
fj
3
3
3
fj
13
19
23
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
540
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.11. Structural parametersa of spatial parallel mechanisms in Figs. 8.7 and 8.8 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PRRbRR-1RPP (Fig. 8.7a) 2PPn2RR-1RPP (Fig. 8.8a) 2PPn3R-1RPP (Fig. 8.8b) 16 8 8 3 19 4 1 2 3 See Table 8.1 5 5 3 3 3 0 5 5 3 ( v1 , v 2 , 3 6 16 3 8 0 8
δ
)
2PRRbRbRR-1RPP (Fig. 8.7b)
20 11 11 3 25 6 1 2 3 See Table 8.1 5 5 3 6 6 0 5 5 3 ( v1 , v 2 , 3 12 22 3 14 0 11
fj
8
11
fj
3
3
fj
19
25
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
8.1 Overconstrained solutions
541
Table 8.12. Structural parametersa of spatial parallel mechanisms in Figs. 8.9 and 8.10 No.
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 a
Structural Solution parameter 2PRRRR-1RPPa (Fig. 8.9a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PPaPaR-1RPPa (Fig. 8.10b)
14 5 5 6 16 3 2 1 3 See Table 8.1
2PPaRRR-1RPPa (Fig. 8.9b) 2PRRPaR-1RPPa (Fig. 8.10a) 18 8 8 6 22 5 0 3 3 See Table 8.1
20 10 10 6 26 7 0 3 3 See Table 8.1
5 5 3 0 0 3 5 5 3 ( v1 , v 2 , 3 3 13 3 5 0 5
5 5 3 3 3 3 5 5 3 ( v1 , v 2 , 3 9 19 3 11 0 8
4 4 3 6 6 3 4 4 3 ( v1 , v 2 , 3 15 23 3 19 0 10
δ
)
δ
)
fj
5
8
10
fj
6
6
6
fj
16
22
26
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
542
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.13. Structural parametersa of spatial parallel mechanisms in Figs. 8.11 and 8.12 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PRRbRR-1RPPa (Fig. 8.11a) 2PPn2RR-1RPPa (Fig. 8.12a) 2PPn3R-1RPPa (Fig. 8.12b) 18 8 8 6 22 5 0 3 3 See Table 8.1
22 11 11 6 28 7 0 3 3 See Table 8.1
5 5 3 3 3 3 5 5 3 ( v1 , v 2 , 3 9 19 3 11 0 8
5 5 3 6 6 3 5 5 3 ( v1 , v 2 , 3 15 25 3 17 0 11
δ
)
2PRRbRbRR-1RPPa (Fig. 8.11b)
fj
8
11
fj
6
6
fj
22
28
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
8.1 Overconstrained solutions
543
Table 8.14. Structural parametersa of spatial parallel mechanisms in Figs. 8.13 and 8.14 No.
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 a
Structural Solution parameter 2PRRRR-1RPaP (Fig. 8.13a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PPaPaR-1RPaP (Fig. 8.14b)
14 5 5 6 16 3 2 1 3 See Table 8.1
2PPaRRR-1RPaP (Fig. 8.13b) 2PRRPaR-1RPaP (Fig. 8.14a) 18 8 8 6 22 5 0 3 3 See Table 8.1
20 10 10 6 26 7 0 3 3 See Table 8.1
5 5 3 0 0 3 5 5 3 ( v1 , v 2 , 3 3 13 3 5 0 5
5 5 3 3 3 3 5 5 3 ( v1 , v 2 , 3 9 19 3 11 0 8
4 4 3 6 6 3 4 4 3 ( v1 , v 2 , 3 15 23 3 19 0 10
δ
)
δ
)
fj
5
8
10
fj
6
6
6
fj
16
22
26
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
544
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.15. Structural parametersa of spatial parallel mechanisms in Figs. 8.15 and 8.16 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PRRbRR-1RPaP (Fig. 8.15a) 2PPn2RR-1RPaP (Fig. 8.16a) 2PPn3R-1RPaP (Fig. 8.16b) 18 8 8 6 22 5 0 3 3 See Table 8.1
22 11 11 6 28 7 0 3 3 See Table 8.1
5 5 3 3 3 3 5 5 3 ( v1 , v 2 , 3 9 19 3 11 0 8
5 5 3 6 6 3 5 5 3 ( v1 , v 2 , 3 15 25 3 17 0 11
δ
)
2PRRbRbRR-1RPaP (Fig. 8.15b)
fj
8
11
fj
6
6
fj
22
28
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
8.1 Overconstrained solutions
545
Table 8.16. Structural parametersa of spatial parallel mechanisms in Figs. 8.17 and 8.18 No.
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 a
Structural Solution parameter 2PRRRR-1RPaPa (Fig. 8.17a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PPaPaR-1RPaPa (Fig. 8.18b)
16 5 5 9 19 4 2 1 3 See Table 8.1
2PPaRRR-1RPaPa (Fig. 8.17b) 2PRRPaR-1RPaPa (Fig. 8.18a) 20 8 8 9 25 6 0 3 3 See Table 8.1
22 10 10 9 29 8 0 3 3 See Table 8.1
5 5 3 0 0 6 5 5 3 ( v1 , v 2 , 3 6 16 3 8 0 5
5 5 3 3 3 6 5 5 3 ( v1 , v 2 , 3 12 22 3 14 0 8
4 4 3 6 6 6 4 4 3 ( v1 , v 2 , 3 18 26 3 22 0 10
δ
)
δ
)
fj
5
8
10
fj
9
9
9
fj
19
25
29
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
546
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.17 Structural parametersa of spatial parallel mechanisms in Figs. 8.19 and 8.20 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PRRbRR-1RPaPa (Fig. 8.19a) 2PPn2RR-1RPaPa (Fig. 8.20a) 2PPn3R-1RPaPa (Fig. 8.20b) 20 8 8 9 25 6 0 3 3 See Table 8.1 5 5 3 3 3 6 5 5 3 ( v1 , v 2 , 3 12 22 3 14 0 8
δ
)
2PRRbRbRR-1RPaPa (Fig. 8.19b)
24 11 11 9 31 8 0 3 3 See Table 8.1 5 5 3 6 6 6 5 5 3 ( v1 , v 2 , 3 18 28 3 20 0 11
fj
8
11
fj
9
9
fj
25
31
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
8.1 Overconstrained solutions
547
Table 8.18. Structural parametersa of spatial parallel mechanisms in Figs. 8.218.24 No.
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 a
Structural Solution parameter 2PRRRR-1RPaPa (Fig. 8.21a) 2PRRRR-1RPaPat (Fig. 8.21b)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
16 5 5 9 19 4 2 1 3 See Table 8.1
2PPaRRR-1RPaPa 2PPaRRR-1RPaPat (Fig. 8.22a,b) 2PRRPaR-1RPaPa 2PRRPaR-1RPaPat (Fig. 8.23a,b) 20 8 8 9 25 6 0 3 3 See Table 8.1
22 10 10 9 29 8 0 3 3 See Table 8.1
5 5 3 0 0 6 5 5 3 ( v1 , v 2 , 3 6 16 3 8 0 5
5 5 3 3 3 6 5 5 3 ( v1 , v 2 , 3 12 22 3 14 0 8
4 4 3 6 6 6 4 4 3 ( v1 , v 2 , 3 18 26 3 22 0 10
δ
)
δ
)
2PPaPaR-1RPaPa (Fig. 8.24a) 2PPaPaR-1RPaPat (Fig. 8.24b)
fj
5
8
10
fj
9
9
9
fj
19
25
29
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
548
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.19. Structural parametersa of spatial parallel mechanisms in Figs. 8.258.29 No.
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 a
Structural parameter
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
Solution 2PRRbRR-1RPaPa (Fig. 8.25a) 2PRRbRR-1RPaPat (Fig. 8.25b) 2PPn2RR-1RPaPa (Fig. 8.28a) 2PPn2RR-1RPaPat (Fig. 8.28b) 2PPn3R-1RPaPa (Fig. 8.29a) 2PPn3R-1RPaPat (Fig. 8.29b) 20 8 8 9 25 6 0 3 3 See Table 8.1
24 11 11 9 31 8 0 3 3 See Table 8.1
5 5 3 3 3 6 5 5 3 ( v1 , v 2 , 3 12 22 3 14 0 8
5 5 3 6 6 6 5 5 3 ( v1 , v 2 , 3 18 28 3 20 0 11
δ
)
2PRRbRbRR-1RPaPa (Fig. 8.26) 2PRRbRbRR-1RPaPat (Fig. 8.27)
fj
8
11
fj
9
9
fj
25
31
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
8.1 Overconstrained solutions
549
Fig. 8.1. Simple (a) and complex (b-d) limbs G1 and G2 with MG=SG=5 (a-c) and MG=SG=4 (d) for SPMs with planar motion of the moving platform
550
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.2. Complex limbs G1 and G2 with MG=SG=5 for SPMs with planar motion of the moving platform
8.1 Overconstrained solutions
551
Fig. 8.3. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPR-1RRRPRR (a) and 2PPR-1RPaPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=3 (a), NF=14 (b), limb topology P ⊥ P ⊥ ⊥ R and R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (a), R ⊥ Pa ⊥ ⊥ Pa ⊥ ||Pa (b)
552
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.4. 2PPR-1RPaPaPa-type overconstrained maximally regular SPMs with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb R ⊥ Pa||Pa ⊥ ⊥ Pa (b)
topology
P ⊥ P ⊥⊥ R
and
R ⊥ Pa ⊥ ⊥ Pa||Pa
(a),
8.1 Overconstrained solutions
553
Fig. 8.5. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR-1RPP (a) and 2PPaRRR-1RPP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2 (a), NF=8 (b), limb topology R ⊥ P ⊥ ⊥ P and P||R||R||R ⊥ R (a), P||Pa||R||R ⊥ R (b)
554
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.6. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPaR-1RPP (a) and 2PPaPaR-1RPP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=8 (a), NF=16 (b), limb topology R ⊥ P ⊥ ⊥ P and P||R||R||Pa ⊥ R (a), P||Pa||Pa ⊥ R (b)
8.1 Overconstrained solutions
555
Fig. 8.7. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbRR-1RPP (a) and 2PRRbRbRR-1RPP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=8 (a), NF=14 (b), limb topology R ⊥ P ⊥ ⊥ P and P||R||Rb||R ⊥ R (a), P||R||Rb||Rb||R ⊥ R (b)
556
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.8. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2RR-1RPP (a) and 2PPn3R-1RPP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=8, limb topology R ⊥ P ⊥ ⊥ P and P||Pn2||R ⊥ R (a), P||Pn3 ⊥ R (b)
8.1 Overconstrained solutions
557
Fig. 8.9. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR-1RPPa (a) and 2PPaRRR-1RPPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=5 (a), NF=11 (b), limb topology R ⊥ P ⊥ ||Pa and P||R||R||R ⊥ R (a), P||Pa||R||R ⊥ R (b)
558
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.10. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPaR-1RPPa (a) and 2PPaPaR-1RPPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=11 (a), NF=19 (b), limb topology R ⊥ P ⊥ ||Pa and P||R||R||Pa ⊥ R (a), P||Pa||Pa ⊥ R (b)
8.1 Overconstrained solutions
559
Fig. 8.11. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbRR-1RPPa (a) and 2PRRbRbRR-1RPPa (b) defined by MF=SF=3, (RF)=( v1 , v 2 , δ ), TF=0, NF=11 (a), NF=17 (b), limb topology R ⊥ P ⊥ ||Pa and P||R||Rb||R ⊥ R (a), P||R||Rb||Rb||R ⊥ R (b)
560
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.12. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2RR-1RPPa (a) and 2PPn3R-1RPPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=11, limb topology R ⊥ P ⊥ ||Pa and P||Pn2||R ⊥ R (a), P||Pn3 ⊥ R (b)
8.1 Overconstrained solutions
561
Fig. 8.13. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR-1RPaP (a) and 2PPaRRR-1RPaP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=5 (a), NF=11 (b), limb topology R||Pa ⊥ P and P||R||R||R ⊥ R (a), P||Pa||R||R ⊥ R (b)
562
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.14. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPaR-1RPaP (a) and 2PPaPaR-1RPaP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=11 (a), NF=19 (b), limb topology R||Pa ⊥ P and P||R||R||Pa ⊥ R (a), P||Pa||Pa ⊥ R (b)
8.1 Overconstrained solutions
563
Fig. 8.15. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbRR-1RPaP (a) and 2PRRbRbRR-1RPaP (b) defined by MF=SF=3, (RF)=( v1 , v 2 , δ ), TF=0, NF=11 (a), NF=17 (b), limb topology R||Pa ⊥ P and P||R||Rb||R ⊥ R (a), P||R||Rb||Rb||R ⊥ R (b)
564
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.16. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2RR-1RPaP (a) and 2PPn3R-1RPaP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=11, limb topology R||Pa ⊥ P and P||Pn2||R ⊥ R (a), P||Pn3 ⊥ R (b)
8.1 Overconstrained solutions
565
Fig. 8.17. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR-1RPaPa (a) and 2PPaRRR-1RPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=8 (a), NF=14 (b), limb topology R||Pa||Pa and P||R||R||R ⊥ R (a), P||Pa||R||R ⊥ R (b)
566
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.18. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPaR-1RPaPa (a) and 2PPaPaR-1RPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14 (a), NF=22 (b), limb topology R||Pa||Pa and P||R||R||Pa ⊥ R (a), P||Pa||Pa ⊥ R (b)
8.1 Overconstrained solutions
567
Fig. 8.19. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbRR-1RPaPa (a) and 2PRRbRbRR-1RPaPa (b) defined by MF=SF=3, (RF)=( v1 , v 2 , δ ), TF=0, NF=14 (a), NF=20 (b), limb topology R||Pa||Pa and P||R||Rb||R ⊥ R (a), P||R||Rb||Rb||R ⊥ R (b)
568
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.20. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2RR-1RPaPa (a) and 2PPn3R-1RPaPa (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology R||Pa||Pa and P||Pn2||R ⊥ R (a), P||Pn3 ⊥ R (b)
8.1 Overconstrained solutions
569
Fig. 8.21. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR-1RPaPa (a) and 2PRRRR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=8, limb topology P||R||R||R ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
570
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.22. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPaRRR-1RPaPa (a) and 2PPaRRR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology P||Pa||R||R ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
8.1 Overconstrained solutions
571
Fig. 8.23. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPaR-1RPaPa (a) and 2PRRPaR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology P||R||R||Pa ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
572
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.24. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPaPaR-1RPaPa (a) and 2PPaPaR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=22, limb topology P||Pa||Pa ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
8.1 Overconstrained solutions
573
Fig. 8.25. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbRR-1RPaPa (a) and 2PRRbRR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology P||R||Rb||R ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
574
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.26. 2PRRbRbRR-1RPaPa-type overconstrained maximally regular SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology P||R||Rb||Rb||R ⊥ R and R||Pa||Pa
8.1 Overconstrained solutions
575
Fig. 8.27. 2PRRbRbRR-1RPaPat-type overconstrained maximally regular SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=20, limb topology P||R||Rb||Rb||R ⊥ R and R||Pa||Pat
576
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.28. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2RR-1RPaPa (a) and 2PPn2RR-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology P||Pn2||R ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
8.1 Overconstrained solutions
577
Fig. 8.29. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn3R-1RPaPa (a) and 2PPn3R-1RPaPat (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=14, limb topology P||Pn3 ⊥ R and R||Pa||Pa (a), R||Pa||Pat (b)
578
8 Maximally regular SPMs with planar motion of the moving platform
8.1.2 Derived solutions Solutions with lower degrees of overconstraint can be derived from the basic solutions in Figs. 8.3-8.29 by using joints with idle mobilities. A large set of solutions can be obtained by introducing idle mobilities outside and/or in the planar loops combined in the limbs (Figs. 8.30-8.56). We recall that the idle mobilities which can be combined in a parallelogram loop are systematized in Fig. 1.2 and Table 1.1. In the cylindrical joint denoted by C*, the rotational motion is an idle mobility in Figs 8.30, 8.31 8.32a. In the cylindrical joints of the rhombus loops denoted by Rbcs (Figs. 8.34, 8.38, 8.42, 8.46) and the parallelogram loops denoted by Pacs (Figs. 8.52-8.56), the translational motion is an idle mobility. The notations Pacs and Rbcs are associated with the parallelogram and rhombus loops with three idle mobilities combined in a cylindrical and a spherical joint. The notations Pass, Pn2ss and Pn3ss are associated with parallelogram loops and planar loops with 2 and 3 degrees of freedom which combine four idle mobilities in two spherical joints adjacent to the same link. In these cases, three idle mobilities are introduced in the loop and one outside the loop. If the link adjacent to the two spherical joints is a binary link than the idle mobility introduced outside the loop becomes an internal rotational mobility of this binary link around the axis passing by the centre of the two spherical joints. Each internal mobility gives one degree of structural redundancy (see Table 8.20). If the link adjacent to the two spherical joints is connected in the limb by three or more joints (polinary link) than the rotational motion around the axis passing by the centre of the two spherical joints becomes an idle (potential) mobility of the limb. This idle mobility is restricted by the constraints of the parallel mechanism and remains just a potential mobility. For example in Fig. 8.68b, this rotational motion is internal mobility for binary links 3A, 3B and 4C, and idle mobility for ternary links 8A and 8B. Examples of solutions with 1 to 8 overconstraints derived from the basic solutions in Figs. 8.3-8.29 are illustrated in Figs. 8.30-8.56. The bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 8.30-8.56 are given in Table 8.21. The limb topology and connecting conditions of these solutions are systematized in Tables 8.22-8.24, as are their structural parameters in Tables 8.25-8.35.
8.1 Overconstrained solutions
579
Table 8.20. Links with internal mobilities and the degree of structural redundancy TF of overconstrained maximally regular SPMs with planar motion of the moving platform No. Parallel mechanism Figure 1 2 3 4 5 6 7 8 9 10
Link with internal rotational mobility in limb G1 G2 G3
TF
Figs. 8.30b, 8.31b, 1 8.40a, 8.42 Fig. 8.31a 1 Figs. 8.32b, 8.33b, 8.35, 2 8.36b, 8.51, 8.55, 8.56 Figs. 8.33a, 8.37a 2 Figs. 8.37b, 8.39 3 Fig. 8.38 1 Figs. 8.41b, 8.43, 3 Figs. 8.44a, 8.46 2 Figs. 8.44b, 8.45b, 8.47 4 Fig. 8.45a 4
-
-
3C
3A
3B
7C -
5A 3A 3A 3A 5A
5B 3B 3B 3B 5B
4C 4C 3C 3 C, 6C 3 C, 6C 3 C, 6C
Table 8.21. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 8.30-8.56 No. Parallel mechanism 1 Figs. 8.30, 8.31, 2 Fig. 8.32a 3
4
5 6
Basis (RG1) ( v1 , v 2 ,
β
( v1 , v 2 , v 3 ,
Figs. 8.32b, ( v1 , v2 , v3 , 8.33a, 8.34, 8.35, 8.38, 8.39, 8.40a, 8.42-8.44, 8.45a, 8.46-8.50, 8.52-8.56 Figs. 8.33b, ( v1 , v2 , v3 , 8.37b, 8.41b, 8.45b, 8.51 Figs. 8.36, ( v1 , v2 , v3 , 8.37a, Fig. 8.40b, ( v1 ,v2 , v3 , 8.41a
,
δ
(RG2) ( v1 , v 2 ,
)
α
,
δ
(RG3) ( v1 ,v2 , v3 ,
)
α
α
,
δ
)
( v1 , v 2 , v 3 ,
β
,
δ
)
( v1 , v 2 ,
β
,
α
,
δ
)
( v1 , v 2 , v 3 ,
β
,
δ
)
( v1 , v 2 ,
δ
)
β
,
δ
)
( v1 , v 2 , v 3 ,
α
,
δ
)
( v1 , v 2 ,
δ
)
α
,
δ
)
( v1 , v 2 , v 3 ,
β
,
δ
)
( v1 , v 2 ,
α
,
) ( v1 , v 2 ,
δ
)
α
,
β
,
δ
) ( v1 ,v2 , v3 ,
α
,
β
,
δ
,
β
δ
)
δ
)
,
δ
)
580
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.22. Limb topology and the number of overconstraints NF of the derived maximally regular SPMs with idle mobilities presented in Figs. 8.30-8.38 No. Basic SPM Type 1 2PPR-1RRRPRR (Fig. 8.3a) 2 2PPR-1RPaPaPa (Fig. 8.3b) 3 2PPR-1RPaPaPa (Fig. 8.4a) 4 2PPR-1RPaPaPa (Fig. 8.4b) 5 2PRRRR-1RPP (Fig. 8.5a) 6 2PPaRRR-1RPP (Fig. 8.5b) 7 2PRRPaR-1RPP (Fig. 8.6a) 8 2PPaPaR-1RPP (Fig. 8.6b) 9 2PRRbRR-1RPP (Fig. 8.7a) 10 2PRRbRbRR-1RPP (Fig. 8.7b) 11 2PPn2RR-1RPP (Fig. 8.8a) 12 2PPn3R-1RPP (Fig. 8.8b) 13 2PRRRR-1RPPa (Fig. 8.9a) 14 2PPaRRR-1RPPa (Fig. 8.9b) 15 2PRRPaR-1RPPa (Fig. 8.10a) 16 2PPaPaR-1RPPa (Fig. 8.10b) 17 2PRRbRR-1RPPa (Fig. 8.11a) 18 2PRRbRbRR1RPPa (Fig. 8.11b)
Derived SPM NF Type 3 2PC*R-1RRRPRR (Fig. 8.30a) 14 2PC*R-1RPassPassPass (Fig. 8.30b) 14 2PC*R-1RPassPassPass (Fig. 8.31a) 14 2PC*R-1RPassPassPass (Fig. 8.31b) 2 2PRRRR-1RPC* (Fig. 8.32a) 8 2PPassRRR-1RPP (Fig. 8.32b) 8 2PRRPassR-1RPP (Fig. 8.33a) 16 2PPassPassR-1RPP (Fig. 8.33b) 8 2PRRbcsRR-1RPP (Fig. 8.34a) 14 2PRRbcsRbcsRR-1RPP (Fig. 8.34b) 8 2PPn2ssRR-1RPP (Fig. 8.35a) 8 2PPn3ssR-1RPP (Fig. 8.35b) 5 2PRRRR-1RPPass (Fig. 8.36a) 11 2PPassRRR-1RPPass (Fig. 8.36b) 11 2PRRPassR-1RPPass (Fig. 8.37a) 19 2PPassPassR-1RPPass (Fig. 8.37b) 11 2PRRbcsRR-1RPPass (Fig. 8.38a) 17 2PRRbcsRbcsRR1RPPass (Fig. 8.38b)
NF Limb topology 1 P ⊥ C* ⊥ ⊥ R R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R 1 P ⊥ C* ⊥ ⊥ R R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass 1 P ⊥ C* ⊥ ⊥ R R ⊥ Pass ⊥ ⊥ Pass||Pass 1 P ⊥ C* ⊥ ⊥ R R ⊥ Pass||Pass ⊥ ⊥ Pass 1 P||R||R||R ⊥ R R ⊥ P ⊥ ⊥ C* 2 P||Pass||R||R ⊥ R R ⊥ P ⊥⊥ P 2 P||R||R||Pass ⊥ R R ⊥ P ⊥⊥ P 2 P||Pass||Pass ⊥ R R ⊥ P ⊥⊥ P 2 P||R||Rbcs||R ⊥ R R ⊥ P ⊥⊥ P 2 P||R||Rbcs||Rbcs||R ⊥ R R ⊥ P ⊥⊥ P 2 P||Pn2ss||R ⊥ R R ⊥ P ⊥⊥ P 2 P||Pn3ss ⊥ R R ⊥ P ⊥⊥ P 1 P||R||R||R ⊥ R R ⊥ P ⊥ ||Pass 1 P||Pass||R||R ⊥ R R ⊥ P ⊥ ||Pass 1 P||R||R||Pass ⊥ R R ⊥ P ⊥ ||Pass 2 P||Pass||Pass ⊥ R R ⊥ P ⊥ ||Pass 2 P||R||Rbcs||R ⊥ R R ⊥ P ⊥ ||Pass 2 P||R||Rbcs||Rbcs||R ⊥ R R ⊥ P ⊥ ||Pass
8.1 Overconstrained solutions
581
Table 8.23. Limb topology and the number of overconstraints NF of the derived maximally regular SPMs with idle mobilities presented in Figs. 8.39-8.47 No. Basic SPM Type 1 2PPn2RR-1RPPa (Fig. 8.12a) 2 2PPn3R-1RPPa (Fig. 8.12b) 3 2PRRRR-1RPaP (Fig. 8.13a) 4 2PPaRRR-1RPaP (Fig. 8.13b) 5 2PRRPaR-1RPaP (Fig. 8.14a) 6 2PPaPaR-1RPaP (Fig. 8.14b) 7 2PRRbRR-1RPaP (Fig. 8.15a) 8 2PRRbRbRR1RPaP (Fig. 8.15b) 9 2PPn2RR-1RPaP (Fig. 8.16a) 10 2PPn3R-1RPaP (Fig. 8.16b) 11 2PRRRR-1RPaPa (Fig. 8.17a) 12 2PPaRRR-1RPaPa (Fig. 8.17b) 13 2PRRPaR-1RPaPa (Fig. 8.18a) 14 2PPaPaR-1RPaPa (Fig. 8.18b) 15 2PRRbRR-1RPaPa (Fig. 8.19a) 16 2PRRbRbRR1RPaPa (Fig. 8.19b) 17 2PPn2RR-1RPaPa (Fig. 8.20a) 18 2PPn3R-1RPaPa (Fig. 8.20b)
Derived SPM NF Type NF 11 2PPn2ssRR-1RPPass 2 (Fig. 8.39a) 11 2PPn3ssR-1RPPass 2 (Fig. 8.39b) 5 2PRRRR-1RPassP 2 (Fig. 8.40a) 11 2PPassRRR-1RPaP 3 (Fig. 8.40b) 11 2PRRPassR-1RPaP 3 (Fig. 8.41a) 19 2PPassPassR-1RPassP 2 (Fig. 8.41b) 11 2PRRbcsRR-1RPassP 2 (Fig. 8.42a) 17 2PRRbcsRbcsRR2 1RPassP (Fig. 8.42b) 11 2PPn2ssRR-1RPassP 2 (Fig. 8.43a) 11 2PPn3ssR-1RPassP 2 (Fig. 8.43b) 8 2PRRRR-1RPassPass 2 (Fig. 8.44a) 14 2PPassRRR-1RPassPass 2 (Fig. 8.44b) 14 2PRRPassR-1RPassPass 2 (Fig. 8.45a) 22 2PPassPassR-1RPassPass 2 (Fig. 8.45b) 14 2PRRbssRR-1RPassPass 2 (Fig. 8.46a) 20 2PRRbssRbssRR2 1RPassPass (Fig. 8.46b) 14 2PPn2ssRR-1RPassPass 2 (Fig. 8.47a) 14 2PPn3ssR-1RPassPass 2 (Fig. 8.47a)
Limb topology P||Pn2ss||R ⊥ R R ⊥ P ⊥ ||Pass P||Pn3ss ⊥ R R ⊥ P ⊥ ||Pass P||R||R||R ⊥ R R||Pass ⊥ P P||Pa||R||R ⊥ R R||Pa ⊥ P P||R||R||Pass ⊥ R R||Pa ⊥ P P||Pass||Pass ⊥ R R||Pass ⊥ P P||R||Rbcs||R ⊥ R R||Pass ⊥ P P||R||Rbcs||Rbcs||R ⊥ R R||Pass ⊥ P P||Pn2ss||R ⊥ R R||Pass ⊥ P P||Pn3ss ⊥ R R||Pass ⊥ P P||R||R||R ⊥ R R||Pass||Pass P||Pass||R||R ⊥ R R||Pass||Pass P||R||R||Pass ⊥ R R||Pass||Pass P||Pass||Pass ⊥ R R||Pass||Pass P||R||Rbss||R ⊥ R R||Pass||Pass P||R||Rbss||Rbss||R ⊥ R R||Pass||Pass P||Pn2ss||R ⊥ R R||Pass||Pass P||Pn3ss ⊥ R R||Pass||Pass
582
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.24. Limb topology and the number of overconstraints NF of the derived maximally regular SPMs with idle mobilities presented in Figs. 8.48-8.56 No. Basic SPM Type 1 2PRRRR-1RPaPa (Fig. 8.21a) 2 2PRRRR-1RPaPat (Fig. 8.21b) 3 2PPaRRR-1RPaPa (Fig. 8.22a) 4 2PPaRRR-1RPaPat (Fig. 8.22b) 5 2PRRPaR-1RPaPa (Fig. 8.23a) 6 2PRRPaR-1RPaPat (Fig. 8.23b) 7 2PPaPaR-1RPaPa (Fig. 8.24a) 8 2PPaPaR-1RPaPat (Fig. 8.24b) 9 2PRRbRR-1RPaPa (Fig. 8.25a) 10 2PRRbRR-1RPaPat (Fig. 8.25b) 11 2PRRbRbRR1RPaPa (Fig. 8.26) 12 2PRRbRbRR1RPaPat (Fig. 8.27) 13 2PPn2RR-1RPaPa (Fig. 8.28a) 14 2PPn2RR-1RPaPat (Fig. 8.28b) 15 2PPn3R-1RPaPa (Fig. 8.29a) 16 2PPn3R-1RPaPat (Fig. 8.29b)
Derived SPM NF Type NF 8 2PRRRR-1RPacsPacs 2 (Fig. 8.48a) 8 2PRRRR-1RPacsPatcs 2 (Fig. 8.48b) 14 2PPaRRR-1RPacsPacs 8 (Fig. 8.49a) 14 2PPaRRR-1RPacsPatcs 8 (Fig. 8.49b) 14 2PRRPaR-1RPacsPacs 8 (Fig. 8.50a) 14 2PRRPaR-1RPacsPatcs 8 (Fig. 8.50b) 22 2PPassPassR-1RPacsPacs 2 (Fig. 8.51a) 22 2PPassPassR-1RPacsPatcs2 (Fig. 8.51b) 14 2PRRbcsRR-1RPacsPacs 2 (Fig. 8.52a) 14 2PRRbcsRR-1RPacsPatcs 2 (Fig. 8.52b) 20 2PRRbcsRbcsRR2 1RPacsPacs (Fig. 8.53) 20 2PRRbcsRbcsRR2 1RPacsPatcs (Fig. 8.54) 14 2PPn2ssRR-1RPacsPacs 2 (Fig. 8.55a) 14 2PPn2ssRR-1RPacsPatcs 2 (Fig. 8.55b) 14 2PPn3ssR-1RPacsPacs 2 (Fig. 8.56a) 14 2PPn3ssR-1RPacsPatcs 2 (Fig. 8.56b)
Limb topology P||R||R||R ⊥ R R||Pacs||Pacs P||R||R||R ⊥ R R||Pacs||Patcs P||Pa||R||R ⊥ R R||Pacs||Pacs P||Pa||R||R ⊥ R R||Pacs||Patcs P||R||R||Pa ⊥ R R||Pacs||Pacs P||R||R||Pa ⊥ R R||Pacs||Patcs P||Pass||Pass ⊥ R R||Pacs||Pacs P||Pass||Pass ⊥ R R||Pacs||Patcs P||R||Rbcs||R ⊥ R R||Pacs||Pacs P||R||Rbcs||R ⊥ R R||Pacs||Patcs P||R||Rbcs||Rbcs||R ⊥ R R||Pacs||Pacs P||R||Rbcs||Rbcs||R ⊥ R R||Pacs||Patcs P||Pn2ss||R ⊥ R R||Pacs||Pacs P||Pn2ss||R ⊥ R R||Pacs||Patcs P||Pn3ss ⊥ R R||Pacs||Pacs P||Pn3ss ⊥ R R||Pacs||Patcs
8.1 Overconstrained solutions
583
Table 8.25. Structural parametersa of spatial parallel mechanisms in Figs. 8.30 and 8.31 No. Structural parameter
Solution 2PC*R-1RRRPRR (Fig. 8.30a)
1 2 3 4 5 6 7 8 9 10
11 3 3 6 12 2 3 0 3 See Table 8.21
2PC*R-1RPassPassPass (Fig. 8.30b) 2PC*R-1RPassPassPass (Fig. 8.31a,b) 15 3 3 13 19 5 2 1 3 See Table 8.21
4 4 6 0 0 0 4 4 6 ( v1 , v 2 , 3 0 11 3 1 0 4
4 4 6 0 0 18 4 4 7 ( v1 , v 2 , 3 18 29 4 1 1 4
11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
4
4
fj
6
25
fj
14
33
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
584
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.26. Structural parametersa of spatial parallel mechanisms in Figs. 8.32 and 8.33 No. Structural Solution parameter 2PRRRR-1RPC* (Fig. 8.32a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PPassPassR-1RPP (Fig. 8.33b)
12 5 5 3 13 2 3 0 3 See Table 8.21
2PPassRRR-1RPP (Fig. 8.32b) 2PRRPassR-1RPP (Fig. 8.33a) 16 8 8 3 19 4 1 2 3 See Table 8.21
5 5 4 0 0 0 5 5 4 ( v1 , v 2 , 3 0 11 3 1 0 5
5 5 3 6 6 0 6 6 3 ( v1 , v 2 , 3 12 22 5 2 2 12
5 5 3 12 12 0 6 6 3 ( v1 , v 2 , 3 24 34 5 2 2 18
δ
)
δ
)
18 10 10 3 23 6 1 2 3 See Table 8.21
fj
5
12
18
fj
4
3
3
fj
14
27
39
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
8.1 Overconstrained solutions
585
Table 8.27. Structural parametersa of spatial parallel mechanisms in Figs. 8.34 and 8.35 No. Structural Solution parameter 2PRRbcsRR-1RPP 2PRRbcsRbcsRR-1RPP 2PPn2ssRR-1RPP (Fig. 8.34a) (Fig. 8.34b) (Fig. 8.35a) 2PPn3ssR-1RPP (Fig. 8.35b) 1 m 16 20 16 2 p1 8 11 8 3 p2 8 11 8 4 p3 3 3 3 5 p 19 25 19 6 q 4 6 4 7 k1 1 1 1 8 k2 2 2 2 9 k 3 3 3 10 (RGi) See Table 8.21 See Table 8.21 See Table 8.21 i=1,2,3 11 SG1 5 5 5 12 SG2 5 5 5 13 SG3 3 3 3 14 rG1 6 12 6 15 rG2 6 12 6 16 rG3 0 0 0 17 MG1 5 5 6 18 MG2 5 5 6 19 MG3 3 3 3 20 (RF) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) ( v1 , v 2 , δ ) 21 SF 3 3 3 22 rl 12 24 12 23 rF 22 34 22 24 MF 3 3 5 25 NF 2 2 2 26 TF 0 0 2 p1 27 11 17 12 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
fj
11
17
12
fj
3
3
3
fj
25
37
27
See footnote of Table 2.4 for the nomenclature of structural parameters
586
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.28. Structural parametersa of spatial parallel mechanisms in Figs. 8.36 and 8.37 No.
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 a
Structural Solution parameter 2PRRRR-1RPPass (Fig. 8.36a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
14 5 5 6 16 3 2 1 3 See Table 8.21
2PPassRRR-1RPPass (Fig. 8.36b) 2PRRPassR-1RPPass (Fig. 8.37a) 18 8 8 6 22 5 0 3 3 See Table 8.21
20 10 10 6 26 7 0 3 3 See Table 8.21
5 5 4 0 0 6 5 5 4 ( v1 , v 2 , 3 6 17 3 1 0 5
5 5 4 6 6 6 6 6 4 ( v1 , v 2 , 3 18 29 5 1 2 12
5 5 3 12 12 6 6 6 4 ( v1 , v 2 , 3 30 40 6 2 3 18
δ
)
δ
)
2PPassPassR1RPPass (Fig. 8.37b)
fj
5
12
18
fj
10
10
10
fj
20
34
46
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
8.1 Overconstrained solutions
587
Table 8.29. Structural parametersa of spatial parallel mechanisms in Figs. 8.38 and 8.39 No.
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 a
Structural parameter
Solution 2PRRbcsRR1RPPass (Fig. 8.38a)
2PRRbcsRbcsRR1RPPass (Fig. 8.38b)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
18 8 8 6 22 5 0 3 3 See Table 8.21
22 11 11 6 28 7 0 3 3 See Table 8.21
2PPn2ssRR-1RPPass (Fig. 8.39a) 2PPn3ssR-1RPPass (Fig. 8.39b) 18 8 8 6 22 5 0 3 3 See Table 8.21
5 5 3 6 6 6 5 5 4 ( v1 , v 2 , 3 18 28 4 2 1 11
5 5 3 12 12 6 5 5 4 ( v1 , v 2 , 3 30 40 4 2 1 17
5 5 3 6 6 6 6 6 4 ( v1 , v 2 , 3 18 28 6 2 3 12
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
δ
)
fj
11
17
12
fj
10
10
10
fj
32
44
34
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
588
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.30. Structural parametersa of spatial parallel mechanisms in Figs. 8.40 and 8.41 No.
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 a
Structural Solution parameter 2PRRRR-1RPassP (Fig. 8.40a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
14 5 5 6 16 3 2 1 3 See Table 8.21
2PPassRRR-1RPaP (Fig. 8.40b) 2PRRPassR-1RPaP (Fig. 8.41a) 18 8 8 6 22 5 0 3 3 See Table 8.21
20 10 10 6 26 7 0 3 3 See Table 8.21
5 5 3 0 0 6 5 5 4 ( v1 , v 2 , 3 6 16 4 2 1 5
6 6 3 6 6 3 6 6 3 ( v1 , v 2 , 3 15 27 3 3 0 12
5 5 3 12 12 6 6 6 4 ( v1 , v 2 , 3 30 40 6 2 3 18
δ
)
δ
)
2PPassPassR1RPassP (Fig. 8.41b)
fj
5
12
18
fj
10
6
10
fj
20
30
46
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
8.1 Overconstrained solutions
589
Table 8.31. Structural parametersa of spatial parallel mechanisms in Figs. 8.42 and 8.43 No.
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 a
Structural Solution parameter 2PRRbcsRR1RPassP (Fig. 8.42a) m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
18 8 8 6 22 5 0 3 3 See Table 8.21
22 11 11 6 28 7 0 3 3 See Table 8.21
2PPn2ssRR-1RPassP (Fig. 8.43a) 2PPn3ssR-1RPassP (Fig. 8.43b) 18 8 8 6 22 5 0 3 3 See Table 8.21
5 5 3 6 6 6 5 5 4 ( v1 , v 2 , 3 18 28 4 2 1 11
5 5 3 12 12 6 5 5 4 ( v1 , v 2 , 3 30 40 4 2 1 17
5 5 3 6 6 6 6 6 4 ( v1 , v 2 , 3 18 28 6 2 3 12
δ
)
2PRRbcsRbcsRR1RPassP (Fig. 8.42b)
δ
)
fj
11
17
12
fj
10
10
10
fj
32
44
34
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
590
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.32. Structural parametersa of spatial parallel mechanisms in Figs. 8.44 and 8.45 No.
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 a
Structural Solution parameter 2PRRRR1RPassPass (Fig. 8.44a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
16 5 5 9 19 4 2 1 3 See Table 8.21
2PPassRRR1RPassPass (Fig. 8.44b) 2PRRPassR1RPassPass (Fig. 8.45a) 20 8 8 9 25 6 0 3 3 See Table 8.21
22 10 10 9 29 8 0 3 3 See Table 8.21
5 5 3 0 0 12 5 5 5 ( v1 , v 2 , 3 12 22 5 2 2 5
5 5 3 6 6 12 6 6 5 ( v1 , v 2 , 3 24 34 7 2 4 12
5 5 3 12 12 12 6 6 5 ( v1 , v 2 , 3 36 46 7 2 4 18
δ
)
δ
)
2PPassPassR1RPassPass (Fig. 8.45b)
fj
5
12
18
fj
17
17
17
fj
27
41
53
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
8.1 Overconstrained solutions
591
Table 8.33. Structural parametersa of spatial parallel mechanisms in Figs. 8.46 and 8.47 No.
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 a
Structural parameter
Solution 2PRRbssRR1RPassPass (Fig. 8.46a)
2PRRbssRbssRR1RPassPass (Fig. 8.46b)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
20 8 8 9 25 6 0 3 3 See Table 8.21
24 11 11 9 31 8 0 3 3 See Table 8.21
2PPn2ssRR1RPassPass (Fig. 8.47a) 2PPn3ssR1RPassPass (Fig. 8.47b) 20 8 8 9 25 6 0 3 3 See Table 8.21
5 5 3 6 6 12 5 5 5 ( v1 , v 2 , 3 24 34 5 2 2 11
5 5 3 12 12 12 5 5 5 ( v1 , v 2 , 3 36 46 5 2 2 17
5 5 3 6 6 12 6 6 5 ( v1 , v 2 , 3 24 34 7 2 4 12
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
δ
)
fj
11
17
12
fj
17
17
17
fj
39
51
41
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
592
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.34. Structural parametersa of spatial parallel mechanisms in Figs. 8.488.51 No.
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 a
Structural Solution parameter 2PRRRR1RPacsPacs (Fig. 8.48a) 2PRRRR1RPacsPatcs (Fig. 8.48b m 16 p1 5 p2 5 p3 9 p 19 q 4 k1 2 k2 1 k 3 (RGi) See Table 8.21 i=1,2,3 SG1 5 SG2 5 SG3 3 rG1 0 rG2 0 rG3 12 MG1 5 MG2 5 MG3 3 (RF) ( v1 , v 2 , δ ) SF 3 rl 12 rF 22 MF 3 NF 2 TF 0 p1 5 f
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PPaRRR-1RPacsPacs 2PPaRRR-1RPacsPatcs (Fig. 8.49a,b) 2PRRPaR-1RPacsPacs 2PRRPaR-1RPacsPatcs (Fig. 8.50a,b) 20 8 8 9 25 6 0 3 3 See Table 8.21
2PPassPassR1RPacsPacs (Fig. 8.51a) 2PPassPassR1RPacsPatcs (Fig. 8.51b) 22 10 10 9 29 8 0 3 3 See Table 8.21
5 5 3 3 3 12 5 5 3 ( v1 , v 2 , 3 18 28 3 8 0 8
5 5 3 12 12 12 6 6 3 ( v1 , v 2 , 3 36 46 5 2 2 18
δ
)
fj
5
8
18
fj
15
15
15
fj
25
31
51
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
8.1 Overconstrained solutions
593
Table 8.35. Structural parametersa of spatial parallel mechanisms in Figs. 8.528.56 No. Structural Solution parameter 2PRRbcsRR1RPacsPacs (Fig. 8.52a) 2PRRbcsRR1RPacsPatcs (Fig. 8.52b) 1 m 20 2 p1 8 3 p2 8 4 p3 9 5 p 25 6 q 6 7 k1 0 8 k2 3 9 k 3 10 (RGi) See Table 8.21 i=1,2,3 11 SG1 5 12 SG2 5 13 SG3 3 14 rG1 6 15 rG2 6 16 rG3 12 17 MG1 5 18 MG2 5 19 MG3 3 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 24 23 rF 34 24 MF 3 25 NF 2 26 TF 0 p1 27 11 f
2PRRbcsRbcsRR1RPacsPacs (Fig. 8.53) 2PRRbcsRbcsRR1RPacsPatcs (Fig. 8.54) 24 11 11 9 31 8 0 3 3 See Table 8.21
2PPn2ssRR-1RPacsPacs 2PPn2ssRR-1RPacsPatcs (Fig. 8.55a,b) 2PPn3ssR-1RPacsPacs 2PPn3ssR-1RPacsPatcs (Fig. 8.56a,b) 20 8 8 9 25 6 0 3 3 See Table 8.21
5 5 3 12 12 12 5 5 3 ( v1 , v 2 , 3 36 46 3 2 0 17
5 5 3 6 6 12 6 6 3 ( v1 , v 2 , 3 24 34 5 2 2 12
28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
δ
)
fj
11
17
12
fj
15
15
15
fj
37
49
39
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
594
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.30. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PC*R-1RRRPRR (a) and 2PC*R-1RPassPassPass (b), defined by SF=3, (RF)=( v1 , v2 , δ ), NF=1 and MF=3, TF=0, (a) MF=4, TF=1, (b) limb topology P ⊥ C* ⊥ ⊥ R and R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (a), R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass (b)
8.1 Overconstrained solutions
595
Fig. 8.31. 2PC*R-1RPassPassPass-type overconstrained maximally regular SPMs with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v 2 , δ ), NF=1, MF=4, TF=1, limb topology P ⊥ C* ⊥ ⊥ R and R ⊥ Pass ⊥ ⊥ Pass||Pass (a), R ⊥ Pass||Pass ⊥ ⊥ Pass (b)
596
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.32. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR-1RPC* (a) and 2PPassRRR-1RPP (b) defined by SF=3, (RF)=( v1 , v2 , δ ) and MF=3, TF=0, NF=1 (a), MF=5, TF=2, NF=2 (b), limb topology P||R||R||R ⊥ R and R ⊥ P ⊥ ⊥ C* (a), P||Pass||R||R ⊥ R and R ⊥ P ⊥ ⊥ P (b)
8.1 Overconstrained solutions
597
Fig. 8.33. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPassR-1RPP (a) and 2PPassPassR-1RPP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, TF=2, NF=2, limb topology R ⊥ P ⊥ ⊥ P and P||R||R||Pass ⊥ R (a), P||Pass||Pass ⊥ R (b)
598
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.34. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbcsRR-1RPP (a) and 2PRRbcsRbcsRR-1RPP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology R ⊥ P ⊥ ⊥ P and P||R||Rbcs||R ⊥ R (a), P||R||Rbcs||Rbcs||R ⊥ R (b)
8.1 Overconstrained solutions
599
Fig. 8.35. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2ssRR-1RPP (a) and 2PPn3ssR-1RPP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, TF=2, NF=2, limb topology R ⊥ P ⊥ ⊥ P and P||Pn2ss||R ⊥ R (a), P||Pn3ss ⊥ R (b)
600
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.36. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR-1RPPass (a) and 2PPassRRR-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=1 and MF=3, TF=0 (a), MF=5, TF=2 (b), limb topology R ⊥ P ⊥ ||Pass and P||R||R||R ⊥ R (a), P||Pass||R||R ⊥ R (b)
8.1 Overconstrained solutions
601
Fig. 8.37. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPassR-1RPPass (a) and 2PPassPassR-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ) and MF=5, TF=2, NF=1 (a), MF=6, TF=3, NF=2 (b), limb topology R ⊥ P ⊥ ||Pass and P||R||R||Pass ⊥ R (a), P||Pass||Pass ⊥ R (b)
602
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.38. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbcsRR-1RPPass (a) and 2PRRbcsRbcsRR-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, TF=1, NF=2, limb topology R ⊥ P ⊥ ||Pass and P||R||Rbcs||R ⊥ R (a), P||R||Rbcs||Rbcs||R ⊥ R (b)
8.1 Overconstrained solutions
603
Fig. 8.39. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2ssRR-1RPPass (a) and 2PPn3ssR-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, TF=3, NF=2, limb topology R ⊥ P ⊥ ||Pass and P||Pn2ss||R ⊥ R (a), P||Pn3ss ⊥ R (b)
604
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.40. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR-1RPassP (a) and 2PPassRRR-1RPaP (b) defined by SF=3, (RF)=( v1 , v2 , δ ) and MF=4, TF=1, NF=2 (a), MF=3, TF=0, NF=3 (b), limb topology P||R||R||R ⊥ R and R||Pass ⊥ P (a), P||Pa||R||R ⊥ R and R||Pa ⊥ P (b)
8.1 Overconstrained solutions
605
Fig. 8.41. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPassR-1RPaP (a) and 2PPassPassR-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ) and MF=3, TF=0, NF=3 (a), MF=6, TF=3, NF=2 (b), limb topology P||R||R||Pass ⊥ R and R||Pa ⊥ P (a), P||Pass||Pass ⊥ R and R||Pass ⊥ P (b)
606
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.42. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbcsRR-1RPassP (a) and 2PRRbcsRbcsRR-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, TF=1, NF=2, limb topology R||Pass ⊥ P and P||R||Rbcs||R ⊥ R (a), P||R||Rbcs||Rbcs||R ⊥ R (b)
8.1 Overconstrained solutions
607
Fig. 8.43. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2ssRR-1RPassP (a) and 2PPn3ssR-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, TF=3, NF=2, limb topology R||Pass ⊥ P and P||Pn2ss||R ⊥ R (a), P||Pn3ss ⊥ R (b)
608
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.44. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR-1RPassPass (a) and 2PPassRRR-1RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=2 and MF=5, TF=2 (a), MF=7, TF=4 (b), limb topology R||Pass||Pass and P||R||R||R ⊥ R (a), P||Pass||R||R ⊥ R (b)
8.1 Overconstrained solutions
609
Fig. 8.45. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPassR-1RPassPass (a) and 2PPassPassR-1RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, TF=4, NF=2, limb topology R||Pass||Pass and P||R||R||Pass ⊥ R (a), P||Pass||Pass ⊥ R (b)
610
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.46. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbssRR-1RPassPass (a) and 2PRRbssRbssRR1RPassPass (b) defined by SF=3, (RF)=( v1 , v 2 , δ ), MF=5, TF=2, NF=2, limb topology R||Pass||Pass and P||R||Rbss||R ⊥ R (a), P||R||Rbss||Rbss||R ⊥ R (b)
8.1 Overconstrained solutions
611
Fig. 8.47. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2ssRR-1RPassPass (a) and 2PPn3ssR-1RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=7, TF=4, NF=2, limb topology R||Pass||Pass and P||Pn2ss||R ⊥ R (a), P||Pn3ss ⊥ R (b)
612
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.48. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR-1RPacsPacs (a) and 2PRRRR-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology P||R||R||R ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
8.1 Overconstrained solutions
613
Fig. 8.49. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPaRRR-1RPacsPacs (a) and 2PPaRRR-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=8, limb topology P||Pa||R||R ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
614
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.50. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPaR-1RPacsPacs (a) and 2PRRPaR-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=8, limb topology P||R||R||Pa ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
8.1 Overconstrained solutions
615
Fig. 8.51. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPassPassR-1RPacsPacs (a) and 2PPassPassR1RPacsPatcs (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=2, TF=2, limb topology P||Pass||Pass ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
616
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.52. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbcsRR-1RPacsPacs (a) and 2PRRbcsRR-1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology P||R||Rbcs||R ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
8.1 Overconstrained solutions
617
Fig. 8.53. 2PRRbcsRbcsRR-1RPacsPacs-type overconstrained maximally regular SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology P||R||Rbcs||Rbcs||R ⊥ R and R||Pacs||Pacs
618
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.54. 2PRRbcsRbcsRR-1RPacsPatcs-type overconstrained maximally regular SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), TF=0, NF=2, limb topology P||R||Rbcs||Rbcs||R ⊥ R and R||Pacs||Patcs
8.1 Overconstrained solutions
619
Fig. 8.55. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2ssRR-1RPacsPacs (a) and 2PPn2ssRR-1RPacsPatcs (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, TF=2, NF=2, limb topology P||Pn2ss||R ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
620
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.56. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn3ssR-1RPacsPacs (a) and 2PPn3ssR-1RPacsPatcs (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, TF=2, NF=2, limb topology P||Pn3ss ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
8.2 Non overconstrained solutions
621
8.2 Non overconstrained solutions Equation (1.15) indicates that non overconstrained solutions of maximally regular spatial parallel robots with q independent loops meet the condition p ∑ 1 fi = 3 + 6q along with MF=SF=3 and (RF)=( v1 ,v2 ,ωδ ). The non overconstrained solutions of maximally regular spatial parallel robots presented in this section (Figs. 8.57-5.83) are derived from the overconstrained counterparts presented in Figs. 8.3-8.29 by introducing the required idle mobilities. For example, the non overconstrained solution in Fig. 8.57a is derived from the overconstrained solution in Fig. 8.3a by combining one idle mobility in limb G1 and two idle mobilities in limb G2. They are introduced in the three cylindrical joints denoted by C*. The rotational motion is the idle mobility in the cylindrical joints between the links 2A-3A and 2B-3B, and the translational motion is idle mobility in the cylindrical joint between the links 3B-7. In the cylindrical joints of the rhombus loops denoted by Rbcs (Figs. 8.61, 8.65, 8.69, 8.73, 8.80 and 8.81) and the parallelogram loops denoted by Pacs (Figs. 8.75-8.83), the translational motion is an idle mobility. We recall that the notations Pacs and Rbcs are associated with the parallelogram and rhombus loops with three idle mobilities combined in a cylindrical and a spherical joint. The notations Pass, Pn2ss and Pn3ss are associated with parallelogram loops and planar loops with 2 and 3 degrees of freedom which combine four idle mobilities in two spherical joints adjacent to the same coupler link. In these cases, three idle mobilities are introduced in the loop and one outside the loop. If the link adjacent to the two spherical joints is a binary link than the idle mobility introduced outside the loop becomes an internal rotational mobility of this binary link around the axis passing by the centre of the two spherical joints. Each internal mobility gives one degree of structural redundancy (see Table 8.36). If the link adjacent to the two spherical joints is connected in the limb by three or more joints (polinary link) than the rotational motion around the axis passing by the centre of the two spherical joints becomes an idle (potential) mobility of the limb. This idle mobility is restricted by the constraints of the parallel mechanism and remains just a potential mobility. For example in Fig. 8.68b, this rotational motion is an internal mobility for binary links 4A, 4B and 3C, and an idle mobility for ternary links 9A and 9B. The bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 8.57-5.83 are given in Table 8.37. The limb topology and connecting conditions of these solutions are systematized in Tables 8.38-8.41, as are their structural parameters in Tables 8.42 and 8.52.
622
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.36. Links with internal mobilities and the degree of structural redundancy of non overconstrained maximally regular SPMs with planar motion of the moving platform No. Parallel mechanism Figure
TF
Link with internal rotational mobility in limb G1 G2 G3
1
1
-
-
3C
1 2 2
4A 3A
4B 3B
7C -
1 3 3 3 3 2 4 4
4A 3A 4 3A 4 3A
4B 3 4 3B 4 3B
4C 4C 4C 3C 3C 3C , 6 C 3 C, 6C 3 C, 6C
2 3 4 5 6 7 8 9 10 11 12
Figs. 8.57b, 8.58b, 8.67, 8.68a, 8.69 Fig. 8.58a Fig. 8.60b Figs. 8.62, 8.78, 8.82, 8.83 Figs. 8.63, 8.64a, 8.65 Fig. 8.64b Fig. 8.66 Fig. 8.68b Fig. 8.70 Figs. 8.76, 8.72a, 8.73 Fig. 8.72b Fig. 8.74
Table 8.37. Bases of the operational velocity spaces of the limbs isolated from the parallel mechanisms presented in Figs. 8.57-8.83 No. Parallel mechanism 1 Figs. 8.57, 8.58 2 Fig. 8.59-8.83
Basis (RG1) ( v1 , v 2 ,
( v1 ,v2 , v3 ,
(RG2) ( v1 , v 2 , v 3 ,
δ )
β , α
,
β
,
δ
) ( v1 ,v2 , v3 ,
α, α
,
δ β
(RG3) ( v1 ,v2 , v3 ,
) ,
δ
) ( v1 , v 2 ,
δ
α
)
,
β
,
δ
)
8.2 Non overconstrained solutions
623
Table 8.38. Limb topology of the non overconstraint maximally regular SPMs presented in Figs. 8.57-8.64 No. Basic SPM Type 1 2PPR-1RRRPRR (Fig. 8.3a)
SPM with NF=0 NF Type 3 PC*R-PC*C*RRRPRR (Fig. 8.57a) 14 PC*R-PC*C*RPassPassPass (Fig. 8.57b)
2
2PPR-1RPaPaPa (Fig. 8.3b)
3
2PPR-1RPaPaPa (Fig. 8.4a)
14
4
2PPR-1RPaPaPa (Fig. 8.4b)
14
5
2PRRRR-1RPP (Fig. 8.5a) 6 2PPaRRR-1RPP (Fig. 8.5b) 7 2PRRPaR-1RPP (Fig. 8.6a) 8 2PPaPaR-1RPP (Fig. 8.6b) 9 2PRRbRR-1RPP (Fig. 8.7a) 10 2PRRbRbRR-1RPP (Fig. 8.7b)
11 2PPn2RR-1RPP (Fig. 8.8a) 12 2PPn3R-1RPP (Fig. 8.8b) 13 2PRRRR-1RPPa (Fig. 8.9a) 14 2PPaRRR-1RPPa (Fig. 8.9b) 15 2PRRPaR-1RPPa (Fig. 8.10a) 16 2PPaPaR-1RPPa (Fig. 8.10b)
2 8 8 16 8 14
8 8 5 11 11 19
Limb topology P ⊥ C* ⊥ ⊥ R P ⊥ C* ⊥ ⊥ C* R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R P ⊥ C* ⊥ ⊥ R P ⊥ C* ⊥ ⊥ C* R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass PC*R-PC*C*P ⊥ C* ⊥ ⊥ R ss ss ss RPa Pa Pa P ⊥ C* ⊥ ⊥ C* (Fig. 8.58a) R ⊥ Pass ⊥ ⊥ Pass||Pass PC*R-PC*C*P ⊥ C* ⊥ ⊥ R RPassPassPass P ⊥ C* ⊥ ⊥ C* (Fig. 8.58b) R ⊥ Pass||Pass ⊥ ⊥ Pass 2PRRRR*R-1RPP P||R||R||R ⊥ R* ⊥ ⊥ R (Fig. 8.59a) R ⊥ P ⊥⊥ P ss 2PPa RRR-1RPP P||Pass||R||R ⊥ R (Fig. 8.59b) R ⊥ P ⊥⊥ P ss 2PRRPa R-1RPP P||R||R||Pass ⊥ R (Fig. 8.60a) R ⊥ P ⊥⊥ P ss ss 2PPa Pa R-1RPP P||Pass||Pass ⊥ R (Fig. 8.60b) R ⊥ P ⊥⊥ P cs 2PRRb RR*R-1RPP P||R||Rbcs||R ⊥ R* ⊥ ⊥ R (Fig. 8.61a) R ⊥ P ⊥⊥ P cs cs 2PRRb Rb RR*RP||R||Rbcs||Rbcs||R ⊥ R* ⊥ ⊥ R 1RPP R ⊥ P ⊥⊥ P (Fig. 8.61b) 2PPn2ssRR*R-1RPP P||Pn2ss||R ⊥ R* ⊥ ⊥ R (Fig. 8.62a) R ⊥ P ⊥⊥ P ss 2PPn3 R*R-1RPP P||Pn3ss ⊥ R* ⊥ ⊥ R (Fig. 8.62b) R ⊥ P ⊥⊥ P ss 2PRRRR*R-1RPPa P||R||R||R ⊥ R* ⊥ ⊥ R (Fig. 8.63a) R ⊥ P ⊥ ||Pass ss ss 2PPa RRR-1RPPa P||Pass||R||R ⊥ R (Fig. 8.63b) R ⊥ P ⊥ ||Pass ss ss 2PRRPa R-1RPPa P||R||R||Pass ⊥ R (Fig. 8.64a) R ⊥ P ⊥ ||Pass ss ss 2PR*Pa Pa RP||R*||Pass||Pass ⊥ R ss 1RPPa R ⊥ P ⊥ ||Pass (Fig. 8.64b)
624
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.39. Limb topology and the number of overconstraints NF of the derived maximally regular SPMs with idle mobilities presented in Figs. 8.65-8.72 No. Basic SPM Type 1 2PRRbRR-1RPPa (Fig. 8.11a)
SPM with NF=0 Limb topology NF Type 11 2PRRbcsRR*RP||R||Rbcs||R ⊥ R* ⊥ ⊥ R 1RPPass R ⊥ P ⊥ ||Pass (Fig. 8.65a) 2 2PRRbRbRR17 2PRRbcsRbcsRR*RP||R||Rbcs||Rbcs||R ⊥ R* ⊥ ⊥ R ss 1RPPa 1RPPa R ⊥ P ⊥ ||Pass (Fig. 8.11b) (Fig. 8.65b) 3 2PPn2RR-1RPPa 11 2PPn2ssR*RR-1RPPass P||Pn2ss||R ⊥ R* ⊥ ⊥ R (Fig. 8.12a) (Fig. 8.66a) R ⊥ P ⊥ ||Pass ss ss 4 2PPn3R-1RPPa 11 2PPn3 R*R-1RPPa P||Pn3ss ⊥ R* ⊥ ⊥ R (Fig. 8.12b) (Fig. 8.66b) R ⊥ P ⊥ ||Pass ss 5 2PRRRR-1RPaP 5 2PRRR*RR-1RPa P P||R||R||R ⊥ R* ⊥ ⊥ R (Fig. 8.13a) (Fig. 8.67a) R||Pass ⊥ P ss ss 6 2PPaRRR-1RPaP 11 2PPa RRR-1RPa P P||Pa||R||R ⊥ R (Fig. 8.13b) (Fig. 8.67b) R||Pass ⊥ P ss ss 7 2PRRPaR-1RPaP 11 2PRRPa R-1RPa P P||R||R||Pass ⊥ R (Fig. 8.14a) (Fig. 8.68a) R||Pass ⊥ P ss ss 8 2PPaPaR-1RPaP 19 2PR*Pa Pa RP||R*||Pass||Pass ⊥ R ss (Fig. 8.14b) 1RPa P R||Pass ⊥ P (Fig. 8.68b) 9 2PRRbRR-1RPaP 11 2PRRbcsRR*RP||R||Rbcs||R ⊥ R* ⊥ ⊥ R ss (Fig. 8.15a) 1RPa P R||Pass ⊥ P (Fig. 8.69a) 10 2PRRbRbRR17 2PRRbcsRbcsRR*RP||R||Rbcs||Rbcs||R ⊥ R* ⊥ ⊥ R ss 1RPaP 1RPa P R||Pass ⊥ P (Fig. 8.15b) (Fig. 8.69b) 11 2PPn2RR-1RPaP 11 2PPn2ssRR*RP||Pn2ss||R ⊥ R* ⊥ ⊥ R (Fig. 8.16a) 1RPassP R||Pass ⊥ P (Fig. 8.70a) 12 2PPn3R-1RPaP 11 2PPn3ssR*R-1RPassP 2PPn3ssR*R-1RPassP (Fig. 8.16b) (Fig. 8.70b) R||Pass ⊥ P ss ss 13 2PRRRR-1RPaPa 8 2PRRRR*R-1RPa Pa P||R||R||R ⊥ R* ⊥ ⊥ R (Fig. 8.17a) (Fig. 8.71a) R||Pass||Pass ss ss ss 14 2PPaRRR-1RPaPa 14 2PPa RRR-1RPa Pa P||Pass||R||R ⊥ R (Fig. 8.17b) (Fig. 8.71b) R||Pass||Pass ss 15 2PRRPaR-1RPaPa 14 2PRRPa RP||R||R||Pass ⊥ R ss ss (Fig. 8.18a) 1RPa Pa R||Pass||Pass (Fig. 8.72a) 16 2PPaPaR-1RPaPa 22 2PR*PassPassRP||R*||Pass||Pass ⊥ R ss ss (Fig. 8.18b) 1RPa Pa R||Pass||Pass (Fig. 8.72b)
8.2 Non overconstrained solutions
625
Table 8.40. Limb topology and the number of overconstraints NF of the derived maximally regular SPMs with idle mobilities presented in Figs. 8.73-8.78 No. Basic SPM SPM with NF=0 Type NF Type 1 2PRRbRR-1RPaPa 14 2PRRbssRR*R(Fig. 8.19a) 1RPassPass (Fig. 8.73a) 2 2PRRbRbRR20 2PRRbssRbssRR*R1RPaPa 1RPassPass (Fig. 8.19b) (Fig. 8.73b) 3 2PPn2RR-1RPaPa 14 2PPn2ssRR*R(Fig. 8.20a) 1RPassPass (Fig. 8.74a) 4 2PPn3R-1RPaPa 14 2PPn3ssR*R(Fig. 8.20b) 1RPassPass (Fig. 8.74b) 5 2PRRRR-1RPaPa 8 2PRRRR*R(Fig. 8.21a) 1RPacsPacs (Fig. 8.75a) 6 2PRRRR-1RPaPat 8 2PRRRR*R(Fig. 8.21b) 1RPacsPatcs (Fig. 8.75b) 7 2PPaRRR-1RPaPa 14 2PPassRRR(Fig. 8.22a) 1RPacsPacs (Fig. 8.76a) 8 2PPaRRR-1RPaPat 14 2PPassRRR(Fig. 8.22b) 1RPacsPatcs (Fig. 8.76b) 9 2PRRPaR-1RPaPa 14 2PRRPassR(Fig. 8.23a) 1RPacsPacs (Fig. 8.77a) 10 2PRRPaR-1RPaPat 14 2PRRPassR(Fig. 8.23b) 1RPacsPatcs (Fig. 8.77b) 11 2PPaPaR-1RPaPa 22 2PPassPassR*R(Fig. 8.24a) 1RPacsPacs (Fig. 8.78a) 12 2PPaPaR-1RPaPat 22 2PPassPassR*R(Fig. 8.24b) 1RPacsPatcs (Fig. 8.78b)
Limb topology P||R||Rbss||R ⊥ R* ⊥ ⊥ R R||Pass||Pass P||R||Rbss||Rbss||R ⊥ R* ⊥ ⊥ R R||Pass||Pass P||Pn2ss||R ⊥ R* ⊥ ⊥ R R||Pass||Pass P||Pn3ss ⊥ R* ⊥ ⊥ R R||Pass||Pass P||R||R||R ⊥ R* ⊥ ⊥ R R||Pacs||Pacs P||R||R||R ⊥ R* ⊥ ⊥ R R||Pacs||Patcs P||Pass||R||R ⊥ R R||Pacs||Pacs P||Pass||R||R ⊥ R R||Pacs||Patcs P||R||R||Pass ⊥ R R||Pacs||Pacs P||R||R||Pass ⊥ R R||Pacs||Patcs P||Pass||Pass||R ⊥ R R||Pacs||Pacs P||Pass||Pass||R ⊥ R R||Pacs||Patcs
626
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.41. Limb topology and the number of overconstraints NF of the derived maximally regular SPMs with idle mobilities presented in Figs. 8.79-8.83 No. Basic SPM SPM with NF=0 Type NF Type 1 2PRRbRR-1RPaPa 14 2PRRbcsRR*R(Fig. 8.25a) 1RPacsPacs (Fig. 8.79a) 2 2PRRbRR-1RPaPat 14 2PRRbcsRR*R(Fig. 8.25b) 1RPacsPatcs (Fig. 8.79b) 3 2PRRbRbRR26 2PRRbcsRbcsRR*R1RPaPa 1RPacsPacs (Fig. 8.26) (Fig. 8.80) 4 2PRRbRbRR27 2PRRbcsRbcsRR*R1RPaPat 1RPacsPatcs (Fig. 8.27) (Fig. 8.81) 5 2PPn2RR-1RPaPa 14 2PPn2ssRR*R(Fig. 8.28a) 1RPacsPacs (Fig. 8.82a) 6 2PPn2RR-1RPaPat 14 2PPn2ssRR*R(Fig. 8.28b) 1RPacsPatcs (Fig. 8.82b) 7 2PPn3R-1RPaPa 14 2PPn3ssR*R(Fig. 8.29a) 1RPacsPacs (Fig. 8.83a) 8 2PPn3R-1RPaPat 14 2PPn3ssR*R(Fig. 8.29b) 1RPacsPatcs (Fig. 8.83b)
Limb topology P||R||Rbcs||R ⊥ R* ⊥ ⊥ R R||Pacs||Pacs P||R||Rbcs||R ⊥ R* ⊥ ⊥ R R||Pacs||Patcs P||R||Rbcs||Rbcs||R ⊥ R* ⊥ ⊥ R R||Pacs||Pacs P||R||Rbcs||Rbcs||R ⊥ R* ⊥ ⊥ R R||Pacs||Patcs P||Pn2ss||R ⊥ R* ⊥ ⊥ R R||Pacs||Pacs P||Pn2ss||R ⊥ R* ⊥ ⊥ R R||Pacs||Patcs P||Pn3ss ⊥ R* ⊥ ⊥ R R||Pacs||Pacs P||Pn3ss ⊥ R* ⊥ ⊥ R R||Pacs||Patcs
8.2 Non overconstrained solutions
627
Table 8.42. Structural parametersa of spatial parallel mechanisms in Figs. 8.57 and 8.58 No. Structural parameter
Solution PC*R-PC*C*-RRRPRR (Fig. 8.57a)
1 2 3 4 5 6 7 8 9 10
11 3 3 6 12 2 3 0 3 See Table 8.37
PC*R-PC*C*-RPassPassPass (Fig. 8.57b) PC*R-PC*C*-RPassPassPass (Fig. 8.58a,b) 15 3 3 13 19 5 2 1 3 See Table 8.37
4 5 6 0 0 0 4 5 6 ( v1 , v 2 , 3 0 12 3 0 0 4
4 5 6 0 0 18 4 5 7 ( v1 , v 2 , 3 18 30 4 0 1 4
11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
fj
5
5
fj
6
25
fj
15
34
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
628
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.43. Structural parametersa of spatial parallel mechanisms in Figs. 8.59 and 8.60 No. Structural Solution parameter 2PRRRR*R-1RPP (Fig. 8.59a)
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 a
m p1 p2 p3 p q k1 k2 k (RGi) (i=1,2,3) SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
2PPassPassR-1RPP (Fig. 8.60b)
14 6 6 3 15 2 3 0 3 See Table 8.37
2PPassRRR-1RPP (Fig. 8.59b) 2PRRPassR-1RPP (Fig. 8.60a) 16 8 8 3 19 4 1 2 3 See Table 8.37
6 6 3 0 0 0 6 6 3 ( v1 , v 2 , 3 0 12 3 0 0 6
6 6 3 6 6 0 6 6 3 ( v1 , v 2 , 3 12 24 3 0 0 12
6 6 3 12 12 0 7 7 3 ( v1 , v 2 , 3 24 36 5 0 2 19
δ
)
δ
)
20 11 11 3 25 6 1 2 3 See Table 8.37
fj
6
12
19
fj
3
3
3
fj
15
27
41
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
8.2 Non overconstrained solutions
629
Table 8.44. Structural parametersa of spatial parallel mechanisms in Figs. 8.61 and 8.62 No. Structural Solution parameter 2PRRbcsRR*R1RPP (Fig. 8.61a)
2PRRbcsRbcsRR*R1RPP (Fig. 8.61b)
1 2 3 4 5 6 7 8 9 10
18 9 9 3 21 4 1 2 3 See Table 8.37
22 12 12 3 27 6 1 2 3 See Table 8.37
2PPn2ssRR*R-1RPP (Fig. 8.62a) 2PPn3ssR*R-1RPP (Fig. 8.62b) 18 9 9 3 21 4 1 2 3 See Table 8.37
6 6 3 6 6 0 6 6 3 ( v1 , v 2 , 3 12 24 3 0 0 12
6 6 3 12 12 0 6 6 3 ( v1 , v 2 , 3 24 36 3 0 0 18
6 6 3 6 6 0 7 7 3 ( v1 , v 2 , 3 12 24 5 0 2 13
11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 a
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
δ
)
fj
12
18
13
fj
3
3
3
fj
27
39
29
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
630
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.45. Structural parametersa of spatial parallel mechanisms in Figs. 8.63 and 8.64 No.
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 a
Structural Solution parameter 2PRRRR*R1RPPass (Fig. 8.63a) m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
16 6 6 6 18 3 2 1 3 See Table 8.37
2PPassRRR-1RPPass (Fig. 8.63b) 2PRRPassR-1RPPass (Fig. 8.64a) 18 8 8 6 22 5 0 3 3 See Table 8.37
22 11 11 6 28 7 0 3 3 See Table 8.37
6 6 3 0 0 6 6 6 4 ( v1 , v 2 , 3 6 18 4 0 1 6
6 6 3 6 6 6 6 6 4 ( v1 , v 2 , 3 18 30 4 0 1 12
6 6 3 12 12 6 7 7 4 ( v1 , v 2 , 3 30 42 6 0 3 19
δ
)
δ
)
2PR*PassPassR1RPPass (Fig. 8.64b)
fj
6
12
19
fj
10
10
10
fj
22
34
48
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
8.2 Non overconstrained solutions
631
Table 8.46. Structural parametersa of spatial parallel mechanisms in Figs. 8.65 and 8.66 No.
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 a
Structural parameter
Solution 2PRRbcsRR*R1RPPass (Fig. 8.65a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
20 9 9 6 24 5 0 3 3 See Table 8.37
2PRRbcsRbcsRR*R- 2PPn2ssR*RR1RPPass 1RPPass (Fig. 8.65b) (Fig. 8.66a) 2PPn3ssR*R1RPPass (Fig. 8.66b) 24 20 12 9 12 9 6 6 30 24 7 5 0 0 3 3 3 3 See Table 8.37 See Table 8.37
6 6 3 6 6 6 6 6 4 ( v1 , v 2 , 3 18 30 4 0 1 12
6 6 3 12 12 6 6 6 4 ( v1 , v 2 , 3 30 42 4 0 1 18
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
δ
)
6 6 3 6 6 6 7 7 4 ( v1 , v 2 , 3 18 30 6 0 3 13
fj
12
18
13
fj
10
10
10
fj
34
46
36
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
632
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.47. Structural parametersa of spatial parallel mechanisms in Figs. 8.67 and 8.68 No.
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 a
Structural Solution parameter 2PRRR*RR1RPassP (Fig. 8.67a) m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
16 6 6 6 18 3 2 1 3 See Table 8.37
2PPassRRR-1RPassP (Fig. 8.67b) 2PRRPassR-1RPassP (Fig. 8.68a) 18 8 8 6 22 5 0 3 3 See Table 8.37
22 11 11 6 28 7 0 3 3 See Table 8.37
6 6 3 0 0 6 6 6 4 ( v1 , v 2 , 3 6 18 4 0 1 6
6 6 3 6 6 6 6 6 4 ( v1 , v 2 , 3 18 30 4 0 1 12
6 6 3 12 12 6 7 7 4 ( v1 , v 2 , 3 30 42 6 0 3 19
δ
)
δ
)
2PR*PassPassR1RPassP (Fig. 8.68b)
fj
6
12
19
fj
10
10
10
fj
22
34
48
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
8.2 Non overconstrained solutions
633
Table 8.48. Structural parametersa of spatial parallel mechanisms in Figs. 8.69 and 8.70 No.
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 a
Structural Solution parameter 2PRRbcsRR*R1RPassP (Fig. 8.69a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
20 9 9 6 24 5 0 3 3 See Table 8.37
2PRRbcsRbcsRR*R- 2PPn2ssRR*R1RPassP 1RPassP (Fig. 8.69b) (Fig. 8.70a) 2PPn3ssR*R1RPassP (Fig. 8.70b) 24 20 12 9 12 9 6 6 30 24 7 5 0 0 3 3 3 3 See Table 8.37 See Table 8.37
6 6 3 6 6 6 6 6 4 ( v1 , v 2 , 3 18 30 4 0 1 12
6 6 3 12 12 6 6 6 4 ( v1 , v 2 , 3 30 42 4 0 1 18
δ
)
δ
)
6 6 3 6 6 6 7 7 4 ( v1 , v 2 , 3 18 30 6 0 3 13
fj
12
18
13
fj
10
10
10
fj
34
46
36
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
634
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.49. Structural parametersa of spatial parallel mechanisms in Figs. 8.71 and 8.72 No.
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 a
Structural Solution parameter 2PRRRR*R1RPassPass (Fig. 8.71a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF) SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
18 6 6 9 21 4 2 1 3 See Table 8.37
2PPassRRR1RPassPass (Fig. 8.71b) 2PRRPassR1RPassPass (Fig. 8.72a) 20 8 8 9 25 6 0 3 3 See Table 8.37
24 11 11 9 31 8 0 3 3 See Table 8.37
6 6 3 0 0 12 6 6 5 ( v1 , v 2 , 3 12 24 5 0 2 6
6 6 3 6 6 12 6 6 5 ( v1 , v 2 , 3 24 36 5 0 2 12
6 6 3 12 12 12 7 7 5 ( v1 , v 2 , 3 36 48 7 0 4 19
δ
)
δ
)
2PR*PassPassR1RPassPass (Fig. 8.72b)
fj
6
12
19
fj
17
17
17
fj
29
41
55
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
8.2 Non overconstrained solutions
635
Table 8.50. Structural parametersa of spatial parallel mechanisms in Figs. 8.73 and 8.74 No.
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 a
Structural parameter
Solution 2PRRbssRR*R1RPassPass (Fig. 8.73a)
m p1 p2 p3 p q k1 k2 k (RGi) i=1,2,3 SG1 SG2 SG3 rG1 rG2 rG3 MG1 MG2 MG3 (RF)
22 9 9 9 27 6 0 3 3 See Table 8.37
2PRRbssRbssRR*R- 2PPn2ssRR*R1RPassPass 1RPassPass (Fig. 8.73b) (Fig. 8.74a) 2PPn3ssR*R1RPassPass (Fig. 8.74b) 26 22 12 9 12 9 9 9 33 27 8 6 0 0 3 3 3 3 See Table 8.37 See Table 8.37
6 6 3 6 6 12 6 6 5 ( v1 , v 2 , 3 24 36 5 0 2 12
6 6 3 12 12 12 6 6 5 ( v1 , v 2 , 3 36 48 5 0 2 18
SF rl rF MF NF TF
∑ ∑ ∑ ∑
p1 j =1 p2 j =1 p3 j =1 p j =1
fj
δ
)
δ
)
6 6 3 6 6 12 7 7 5 ( v1 , v 2 , 3 24 36 7 0 4 13
fj
12
18
13
fj
17
17
17
fj
41
53
43
See footnote of Table 2.4 for the nomenclature of structural parameters
δ
)
636
8 Maximally regular SPMs with planar motion of the moving platform
Table 8.51. Structural parametersa of spatial parallel mechanisms in Figs. 8.758.78 No.
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 a
Structural Solution parameter 2PRRRR*R1RPacsPacs (Fig. 8.75a) 2PRRRR*R1RPacsPatcs (Fig. 8.75b) m 18 p1 6 p2 6 p3 9 p 21 q 4 k1 2 k2 1 k 3 (RGi) See Table 8.37 i=1,2,3 SG1 6 SG2 6 SG3 3 rG1 0 rG2 0 rG3 12 MG1 6 MG2 6 MG3 3 (RF) ( v1 , v 2 , δ ) SF 3 rl 12 rF 24 MF 3 NF 0 TF 0 p1 6 f
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PPassRRR-1RPacsPacs 2PPassRRR-1RPacsPatcs (Fig. 8.76a,b) 2PRRPassR-1RPacsPacs 2PRRPassR-1RPacsPatcs (Fig. 8.77a,b) 20 8 8 9 25 6 0 3 3 See Table 8.37
2PPassPassR*R1RPacsPacs (Fig. 8.78a) 2PPassPassR*R1RPacsPatcs (Fig. 8.78b) 24 11 11 9 31 8 0 3 3 See Table 8.37
6 6 3 6 6 12 6 6 3 ( v1 , v 2 , 3 24 36 3 0 0 12
6 6 3 12 12 12 7 7 3 ( v1 , v 2 , 3 36 48 5 0 2 19
δ
)
fj
6
12
19
fj
15
15
15
fj
27
39
53
δ
See footnote of Table 2.4 for the nomenclature of structural parameters
)
8.2 Non overconstrained solutions
637
Table 8.52. Structural parametersa of spatial parallel mechanisms in Figs. 8.798.83 No. Structural Solution parameter 2PRRbcsRR*R1RPacsPacs (Fig. 8.79a) 2PRRbcsRR*R1RPacsPatcs (Fig. 8.79b) 1 m 22 2 p1 9 3 p2 9 4 p3 9 5 p 27 6 q 6 7 k1 0 8 k2 3 9 k 3 10 (RGi) See Table 8.37 i=1,2,3 11 SG1 6 12 SG2 6 13 SG3 3 14 rG1 6 15 rG2 6 16 rG3 12 17 MG1 6 18 MG2 6 19 MG3 3 20 (RF) ( v1 , v 2 , δ ) 21 SF 3 22 rl 24 23 rF 36 24 MF 3 25 NF 0 26 TF 0 p1 27 12 f 28 29 30 a
∑ ∑ ∑ ∑
j =1
p2 j =1 p3 j =1 p j =1
j
2PRRbcsRbcsRR*R-2PPn2ssRR*R-1RPacsPacs 1RPacsPacs 2PPn2ssRR*R-1RPacsPatcs (Fig. 8.80) (Fig. 8.82a,b) 2PRRbcsRbcsRR*R-2PPn3ssR*R-1RPacsPacs 1RPacsPatcs 2PPn3ssR*R-1RPacsPatcs (Fig. 8.81) (Fig. 8.83a,b) 26 22 12 9 12 9 9 9 33 27 8 6 0 0 3 3 3 3 See Table 8.37 See Table 8.37 6 6 3 12 12 12 6 6 3 ( v1 , v 2 , 3 36 48 3 0 0 18
δ
)
6 6 3 6 6 12 7 7 3 ( v1 , v 2 , 3 24 36 5 0 2 13
fj
12
18
13
fj
15
15
15
fj
39
51
41
δ
)
See footnote of Table 2.4 for the nomenclature of structural parameters
638
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.57. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types PC*R-PC*C*-RRRPRR (a) and PC*R-PC*C*RPassPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=3, TF=0, (a) MF=4, TF=1, (b) limb topology P ⊥ C* ⊥ ⊥ R, R ⊥ R ⊥ R ⊥ P ⊥ ||R ⊥ R (a), R ⊥ Pass ⊥ ⊥ Pass ⊥ ||Pass (b)
P ⊥ C* ⊥ ⊥ C*
and
8.2 Non overconstrained solutions
639
Fig. 8.58. PC*R-PC*C*-RPassPassPass-type non overconstrained maximally regular SPMs with planar motion of the moving platform defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology P ⊥ C* ⊥ ⊥ R, P ⊥ C* ⊥ ⊥ C* and R ⊥ Pass ⊥ ⊥ Pass||Pass (a), R ⊥ Pass||Pass ⊥ ⊥ Pass (b)
640
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.59. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR*R-1RPP (a) and 2PPassRRR-1RPP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), NF=0, TF=0, limb topology R ⊥ P ⊥ ⊥ P and P||R||R||R ⊥ R* ⊥ ⊥ R (a), P||Pass||R||R ⊥ R (b)
8.2 Non overconstrained solutions
641
Fig. 8.60. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPassR-1RPP (a) and 2PPassPassR-1RPP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=3, TF=0 (a), MF=5, TF=2 (a), limb topology R ⊥ P ⊥ ⊥ P and P||R||R||Pass ⊥ R (a), P||Pass||Pass ⊥ R (b)
642
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.61. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbcsRR*R-1RPP (a) and 2PRRbcsRbcsRR*R1RPP (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), NF=0, TF=0, limb topology R ⊥ P ⊥ ⊥ P and P||R||Rbcs||R ⊥ R* ⊥ ⊥ R (a), P||R||Rbcs||Rbcs||R ⊥ R* ⊥ ⊥ R (b)
8.2 Non overconstrained solutions
643
Fig. 8.62. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2ssRR*R-1RPP (a) and 2PPn3ssR*R-1RPP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0, TF=2, limb topology R ⊥ P ⊥ ⊥ P and P||Pn2ss||R ⊥ R* ⊥ ⊥ R (a), P||Pn3ss ⊥ R* ⊥ ⊥ R (b)
644
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.63. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR*R-1RPPass (a) and 2PPassRRR-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology R ⊥ P ⊥ ||Pass and P||R||R||R ⊥ R* ⊥ ⊥ R (a), P||Pass||R||R ⊥ R (b)
8.2 Non overconstrained solutions
645
Fig. 8.64. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPassR-1RPPass (a) and 2PR*PassPassR1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0 and MF=4, TF=1, (a), MF=6, TF=3 (b), limb topology R ⊥ P ⊥ ||Pass and P||R||R||Pass ⊥ R (a), P||R*||Pass||Pass ⊥ R (b)
646
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.65. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbcsRR*R-1RPPass (a) and 2PRRbcsRbcsRR*R1RPPass (b) defined by SF=3, (RF)=( v1 , v 2 , δ ), MF=4, NF=0, TF=1, limb topology R ⊥ P ⊥ ||Pass P||R||Rbcs||Rbcs||R ⊥ R* ⊥ ⊥ R (b)
and
P||R||Rbcs||R ⊥ R* ⊥ ⊥ R
(a),
8.2 Non overconstrained solutions
647
Fig. 8.66. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2ssR*RR-1RPPass (a) and 2PPn3ssR*R-1RPPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0, TF=3, limb topology R ⊥ P ⊥ ||Pass and P||Pn2ss||R ⊥ R* ⊥ ⊥ R (a), P||Pn3ss ⊥ R* ⊥ ⊥ R (b)
648
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.67. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRR*RR-1RPassP (a) and 2PPassRRR-1RPassP (b) defined by SF=3, (RF)=( v1 , v 2 , δ ) and MF=4, NF=0, TF=1, limb topology R||Pass ⊥ P and P||R||R||R ⊥ R* ⊥ ⊥ R (a), P||Pa||R||R ⊥ R (b)
8.2 Non overconstrained solutions
649
Fig. 8.68. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPassR-1RPassP (a) and 2PR*PassPassR1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), NF=0, and MF=4, TF=1 (a), MF=6, TF=3 (b), limb topology R||Pass ⊥ P and P||R||R||Pass ⊥ R (a), P||R*||Pass||Pass ⊥ R (b)
650
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.69. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbcsRR*R-1RPassP (a) and 2PRRbcsRbcsRR*R1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=4, NF=0, TF=1, limb topology R||Pass ⊥ P and P||R||Rbcs||R ⊥ R* ⊥ ⊥ R (a), P||R||Rbcs||Rbcs||R ⊥ R* ⊥ ⊥ R (b)
8.2 Non overconstrained solutions
651
Fig. 8.70. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2ssRR*R-1RPassP (a) and 2PPn3ssR*R-1RPassP (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=6, NF=0, TF=3, limb topology R||Pass ⊥ P and P||Pn2ss||R ⊥ R* ⊥ ⊥ R (a), P||Pn3ss ⊥ R* ⊥ ⊥ R (b)
652
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.71. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR*R-1RPassPass (a) and 2PPassRRR1RPassPass (b) defined by SF=3, (RF)=( v1 , v 2 , δ ), MF=5, NF=0, TF=2, limb topology R||Pass||Pass and P||R||R||R ⊥ R* ⊥ ⊥ R (a), P||Pass||R||R ⊥ R (b)
8.2 Non overconstrained solutions
653
Fig. 8.72. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPassR-1RPassPass (a) and 2PR*PassPassR1RPassPass (b) defined by SF=3, (RF)=( v1 , v 2 , δ ), NF=0 and MF=5, TF=2 (a), MF=7, TF=4 (b), limb topology R||Pass||Pass and P||R||R||Pass ⊥ R (a), P||R*||Pass||Pass ⊥ R (b)
654
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.73. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbssRR*R-1RPassPass (a) and 2PRRbssRbssRR*R-1RPassPass (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0, TF=2, limb topology R||Pass||Pass and P||R||Rbss||R ⊥ R* ⊥ ⊥ R (a), P||R||Rbss||Rbss||R ⊥ R* ⊥ ⊥ R (b)
8.2 Non overconstrained solutions
655
Fig. 8.74. Overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2ssRR*R-1RPassPass (a) and 2PPn3ssR*R1RPassPass (b) defined by SF=3, (RF)=( v1 , v 2 , δ ), MF=7, NF=0, TF=4, limb topology R||Pass||Pass and P||Pn2ss||R ⊥ R* ⊥ ⊥ R (a), P||Pn3ss ⊥ R* ⊥ ⊥ R (b)
656
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.75. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRRR*R-1RPacsPacs (a) and 2PRRRR*R1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), NF=0, TF=0, limb topology P||R||R||R ⊥ R* ⊥ ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
8.2 Non overconstrained solutions
657
Fig. 8.76. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPassRRR-1RPacsPacs (a) and 2PPassRRR1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), NF=0, TF=0, limb topology P||Pass||R||R ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
658
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.77. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRPassR-1RPacsPacs (a) and 2PRRPassR1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), NF=0, TF=0, limb topology P||R||R||Pass ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
8.2 Non overconstrained solutions
659
Fig. 8.78. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPassPassR*R-1RPacsPacs (a) and 2PPassPassR*R1RPacsPatcs (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0, TF=2, limb topology P||Pass||Pass||R ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
660
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.79. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PRRbcsRR*R-1RPacsPacs (a) and 2PRRbcsRR*R1RPacsPatcs (b) defined by MF=SF=3, (RF)=( v1 , v2 , δ ), NF=0, TF=0, limb topology P||R||Rbcs||R ⊥ R* ⊥ ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
8.2 Non overconstrained solutions
661
Fig. 8.80. 2PRRbcsRbcsRR*R-1RPacsPacs-type non overconstrained maximally regular SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), NF=0, TF=0, limb topology P||R||Rbcs||Rbcs||R ⊥ R* ⊥ ⊥ R and R||Pacs||Pacs
662
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.81. 2PRRbcsRbcsRR*R-1RPacsPatcs-type non overconstrained maximally regular SPM with planar motion of the moving platform defined by MF=SF=3, (RF)=( v1 , v2 , δ ), NF=0, TF=0, limb topology P||R||Rbcs||Rbcs||R ⊥ R* ⊥ ⊥ R and R||Pacs||Patcs
8.2 Non overconstrained solutions
663
Fig. 8.82. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn2ssRR*R-1RPacsPacs (a) and 2PPn2ssRR*R1RPacsPatcs (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0, TF=2, limb topology P||Pn2ss||R ⊥ R* ⊥ ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
664
8 Maximally regular SPMs with planar motion of the moving platform
Fig. 8.83. Non overconstrained maximally regular SPMs with planar motion of the moving platform of types 2PPn3ssR*R-1RPacsPacs (a) and 2PPn3ssR*R1RPacsPatcs (b) defined by SF=3, (RF)=( v1 , v2 , δ ), MF=5, NF=0, TF=2, limb topology P||Pn3ss ⊥ R* ⊥ ⊥ R and R||Pacs||Pacs (a), R||Pacs||Patcs (b)
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Index
A actuator, 2 algorithm evolutionary, 16 approach systematic, 10 B base, 2 fixed, 2, 3 basic solution, 107, 283 basis, 13 of operational velocity space, 15 of vector space, 15 branch mobility, 12
dimension vector space, 14 E element 3 pairing, 3 reference, 3 end-effector, 9 equation constraint, 11 evolutionary morphology, 16 F frame, 3 fully-isotropic, 16 G
C characteristic point, 15 condition number, 17 connectivity, 12, 13, 78 connecting conditions, 28 constraint equation, 11 coupled motions, 16, 27 CPM, 18 D decoupled motions, 16 degree of freedom, 10 of overconstraint, 289 design objectives, 16
graph, 7 structural, 7 H hexapod, 2 I idle mobility, 5, 88, 183, 228, 251, 271, 289, 300, IFMA, 17 independent motion, 13 Isoglide3-T2R1
planar, 283 spatial, 529 Isoglide3-T3, 18 isotropy, 17
684
Index
J Jacobian matrix, 16 joint, 3 Cardan, 4 heterokinetic, 4 homokinetic, 4 universal, 4 K kinematic pair, 2, 4 kinematic chain, 2, 3 closed, 4 complex, 4 open, 4 serial, 2 simple, 4 L limb, 2 complex, 4 simple, 4 topology, 28, 89, 184, 228, 240, 272, 283, 289, 300, 329, link, 3 binary, 4 distal, 4 monary, 3 polinary, 4 loop parallelogram, 5 rhombus, 472 M mechanism, 2, 3 element, 3 parallel, 2 kinematotropic, 12 mobility, 10, 13 external, 11 full-cycle, 11 general, 11 idle, 5
instantaneous, 12 internal, 11 88, 184, 228, 251, model kinematic, 19 direct, 19 morphological operator, 16 motion coupling, 16 N number of overconstraints, 12, 13, 251 O operational vector space, 89 velocity space, 13 Orthogonal Tripteron, 18 overconstraint, 12 P paire, 2 cylindrical, 4 helical, 4 kinematic, 4 lower , 4 passive, 9 planar, 4 revolute, 4 spherical, 4 pairing element, 3 Pantopteron, 18 parallel mechanism, 5, 12 parallel robotic manipulator, 1, 16 fully-isotropic, 17 maximally regular, 16 non overconstrained, 15 non redundant, 14 overconstrained, 15 redundant, 14 redundantly-actuated, 2 translational, 1 R2-type, 18
Index R3-type, 18 T1R2-type, 18 T1R3-type, 18 T2R1-type, 18, 19 T2R2-type, 18 T2R3-type, 18 T3-type, 17, 18 T3R1-type, 18 T3R2-type, 18 T3R3-type, 18 with coupled motions, 17 with decoupled motions, 17 with planar motion of the moving platform, 19 with uncoupled motions, 16 3-PRR-type, 21 3-RPR-type, 22 3-RRR-type, 23 performance index, 17 platform, 2 fixed, 2 moving, 2, 4 reference, 4 PPM, 27 basic solutions, 27, 239, 283 coupled motions, 27, 183 decoupled motions, 240 derived solutions , 88, 251, 289 fully-parallel, 27, 183, 240 maximally regular, 283, 300 non fully-parallel, 27, 78, 228 non overconstrained, 183, 271, 300, overconstrained, 27, 239, 283 uncoupled motions, 239 point characteristic, 15 protoelement, 16 R rank, 11 redundancy, 13 robot, 1, fully parallel, 9 hexapod, 2
685
hybrid, 9 non fully-parallel, 10 parallel, 2, 9 serial, 9 robotics, 2 S singular configuration,12 SPM, 307 basic solutions, 307, 367, 529 coupled motions, 307 derived solutions, 327, 577 fully-parallel, 307, 367 maximally regular, 529, 620 non overconstrained, 346, 472, 620 overconstrained, 307, 367, 529 uncoupled motions, 367, 472 structural diagram, 7 graph, 7 parameters, 10, redundancy, 13 228 synthesis, 10 synthesis structural, 10 systematic approach, 10 T theory of linear transformations, 12 topology, 10 U uncoupled motions, 16 universal joint, 4 V velocity, 20 velocity vector space, 12