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Lecture Notes in Earth Sciences Edited by Somdev Bhattacharji, Gerald M. Friedman, Horst J. Neugebauer and Adolf Seilacher
14 N. Cristescu H.I. Ene (Eds.)
Rock and Soil Rheology Proceedings of the Euromech Colloquium 196 September 10-13, 1985 Bucharest, Romania
Springer-Verlag Berlin Heidelberg NewYork London Paris Tokyo
Editors Prof. Dr. Nicolae Cristescu University of Bucharest, Faculty of Mathematics Str. Academlel 14, Bucharest 1 C o d 70109, Romania Dr. Horia I. Ene INCREST, Department of Mathematics Bd. Pacii 220, 7 9 6 2 2 Bucharest, Romania
ISBN 3 - 5 4 0 - 1 8 8 4 1 - X Spnnger-Verlag Berlin Heidelberg N e w York ISBN 0 - 3 8 7 - 1 8 8 4 1 - X Springer-Verlag N e w York Berlin Heidelberg
Thrs work ~s subject to copynght All rights are reserved, whether the whole or part of the material ~s concerned, specifically the nghts of translation, repnnt~ng, re-use of dlustratlons, recitation, broadcasting, reproductron on mlcrofdms or in other ways, and storage in data banks Duplication of th~s pubhcat~onor parts thereof ~sonly permitted under the provisions of the German Copyright Law of September 9, 1965, ~nits version of June 24, 1985, and a copyright fee must always be pawd Violations fall under the prosecution act of the German Copyright Law © Sprmger-Verlag Berhn Heidelberg 1988 Printed In Germany Printing and blndtng Druckhaus Beltz, Hemsbach/Bergstr 2132/3140-543210
CONTENTS
I. T H E O R E T I C A L
F. G i l b e r t
APPROACH .................................
1
C h a n g e of S c a l e M e t h o d s A p p l i e d in M e c h a n i c s of S a t u r a t e d S o i l s ............
3
The Use of the H o m o g e n i z a t i o n M e t h o d to D e s c r i b e the V i s c o e l a s t i c B e h a v i o u r of a P o r o u s S a t u r a t e d M e d i u m ............
33
A Statical Micromechanical Description of Y i e l d i n g in C o h e s i o n l e s s Soil ........
43
A M a t h e m a t i c a l M o d e l for the L i q u e f a c t i o n of S o i l s . . . . . . . . . . . . . . . . . . . . . . . . . . .
63
The K i n e m a t i c s of S e l f - S i m i l a r P l a n e Penetration Problems in Mohr-Coulomb Granular Materials ......................
83
P. H a b i b
Slip
93
II.
AND APPLICATIONS ........................
117
U n d r a i n e d C r e e p D e f o r m a t i o n of a S t r i p L o a d on C l a y . . . . . . . . . . . . . . . . . . . . . . . . . . . .
119
A C l o s e d - F o r m S o l u t i o n for the P r o b l e m of a V i s c o p l a s t i c H o l l o w Sphere. A p p l i c a t i o n to U n d e r g r o u n d C a v i t i e s in R o c k Salt ....................................
151
Horia
I. E n e
B. C a m b o u
L. D r ~ g u ~ i n
R. B u t t e r f i e l d
EXPERIMENTS
A. F. L. Hyde, J. J. B u r k e
P. B e r e s t
M.
P. L u o n g
R. R i b a c c h i
N. Cristescu, D. Fot~, E. Medve~
Surfaces
in S o i l
M e c h a n i c s .........
Characteristic State and Infrared V i b r o t h e r m o g r a p h y of S a n d . . . . . . . . . . . . . . . 173 N o n L i n e a r B e h a v i o u r of A n i s o t r o p i c Rocks ...................................
199
R o c k - S u p p o r t I n t e r a c t i o n in L i n e d Tunnels .................................
245
Y. A r k i n
D e f o r m a t i o n of L a m i n a t e d L a c u s t r i n e S e d i m e n t s of the D e a d Sea . . . . . . . . . . . . . . . 273
R. T r a c z y k
On the C o n s t r u c t i o n of a C o n s t i t u t i v e E q u a t i o n of S o i l s by M a k i n g Use of the DLS M o d e l . . . . . . . . . . . . . . . . . . . . . . . . . . .
279
LIST OF CONTRIBUTORS
¥. A r k i n Ministry of Energy and Infrastructure Geological Survey 30, Malkhe Israel Str. Jerusalem 95501 Israel. P. B e r e s t Laboratoire de M~canique des Solides Ecole Polytechnique,
F 91128 Palaiseau - C@dex
France. R. B u t t e r f i e l d Dept.
of Civil Engineering
The University Highfield Southampton,
S09 5NH
United Kingdom. B. Cambou Laboratoire de Mecanique de Solides Ecole Centrale de Lyon 36 Av. Guy de Collongue B.P.
163, 6 9 1 3 1 E c u l l y
- C@dex
France. N. C r i s t e s c u Dept.
of Mathematics
University of Bucharest Str. Academiei
14, Bucharest 70109
Romania. Lucia Dr~gusin Dept. of Mathematics Polytechnical
Institute
Spl. Independentei Romania.
313, Bucharest
Vi Horia
I. Ene
Dept.
of Mathematics,
Bd. P~cii
INCREST
220, 79622 Bucharest
Romania. F. J. G i l b e r t
Laboratoire
de M g c a n i q u e
Ecole Polytechnique,
des Solides
F 91128 Palaiseau
- C@dex
France. P. H a b i b
Laboratoire
de M e c a n i q u e
Ecole Po!ytechnique,
des Solides
F 91128 Palaiseau
- Cedex
France. A. F. L. Hyde
Dept.
of Civil E n g i n e e r i n g
University Bradford,
of Bradford BD7
IDP
United Kingdom. M. P. L u o n g
Laboratoire
de M ~ c a n i q u e
Ecole Polytechnique,
des Solides
F 91128 Palaiseau
France. R. Ribacchi
Inst.
di Scienza
Universit~
delle Construzioni
di Roma
Via E n d o s s i a n a
18, Roma,
Italy. R. T r a c z y k
Institute
of G e o t e c h n i q u e
Technical
University
Plac Grunwaldzki Poland.
of W r o c ~ a w
9, 50-370 Wroc~aw,
- C~dex
INTRODUCTION While studied
the complex m e c h a n i c a l
for
quite
a while,
established m a t h e m a t i c a l rimental tance
data.
creep,
reported have
were
were
either
the
loading number
are
not
behaviour
materials
as
for
soil
rheology
that
the
solving
modern
models,
technology
thus
the
was
study
that
is
or
models
for
the
specific
to
the
plastics. It
of rock
possible
solving
of
mechanical dilatancy these
test
very
only
involving
and
general
presence
of a great
a n d soils,
the mecha-
from
That must
and
by of
data
developed
instance
distinct
development
expe-
as for ins-
specific
in roks
aspects.
not
sound
experimental
problems
due
quite
that
Generally,
a
are
on accurate
the
for
etc.
for
existing
problems
and
as
solving
metals
the
major
damage
specific
of various
but
necessary the
made
for
pores
instance some
time
soils
decades
based
consequence,
term were
geomaterials
has
last
and
of geomaterials
materials
us remind
and/or
of
a of
these
models
Let
cracks
long
some
appropriate
histories. of
a as
generality
or by
empirical
in the
properties
for and,
c o m p r e s s i b i l i t y , long
therefore
by
studied
possessed
particular
nical
rheological
problems
properties
is only
of rocks
models were developed
incomplete
missed
engineering
and/or
Some
it
properties
that
is
of
why
also
be
other
rock
soil m e c h a n i c s
using
and
mentioned posed
time-independent
rehological
models
become
a b s o l u t e l y necessary. In
the
last
became
available
niques
and
of
scientific
the
growing
community.
development models,
decade
of
able
to
compressibility
or
as a result
interest
These
genuine
such
creep,
after various time intervals, Today rocks
can
effects cription in
are
is
clear
not
the
concepts
of
accurate
this
field
in
turn,
have
geomaterials, term
as
experimantal
of
for
properties
no the
Another
of
very
development
of
research
made
and
techin the
possible
mainly
creep,
damage
data
experimental
the
rheological
dilatancy failure
and/or
occurring
slip surface formation etc.
unless
included.
for long
that
formulated
of the concepts
someway
notion.
it
be
data,
models
describe during
so,
of the
damage
accurate
constitutive
dilatancy idea and
irreversible
is
equation
phenomena
the
failure
need
of
and a
of rocks,
dilatancy
or
for
the
time
better
des-
again
another
using
related
VIII
In soil r h e o l o g y into
consideration
routine
tests.
in
Also
it is clear that the scale effect may be taken order
to
in writing
obtain
to take
because
is a great variety
soils,
Rheology some
into account
granular or cohesionless The
of
and
therefore
research
and
problems
which
scientific
also are
approaches
That
is
interest
geology, sports, (cold,
waste
culture, hot and
reservoirs
under
true
for
seismology,
industrial
of
the
obtained
are
for
present in
volume
last
of
the
helpful
the it
phenomena,
or n o n s a t u r a t e d
to Rock and Soil
too,
years
the
major
not
Exchange
mainly
in
rheology
and
of
petroleum civil
geothermal
of
storages),
engineering, storage, goods
underground
etc. Some of the last obtained
results
review
field
of
solved
opinions
those
areas
and
where
is quite fast.
engineers,
of
to
yet
geomaterials,
energy
storage
is
in this
and the progress made
telecommunications,
refrigerated
the
some
geophlsics,
storage,
for soils
or local
196 devoted
consideration.
quite
mining
from
soil etc.
formulate
now
equations
of types of saturated
are c o n t r o v e r s i a l
especially
great
to
discussions
some
that
results
information
the m i c r o s c o p i c
aim of the E u r o m e c h C o l l o q u i u m
the main
corect
the c o n s t i t u t i v e
is n e c c e s s a r y there
a
domain
of
engineering nuclear
and
caverns
for
and
foodstuffs
oil and natural are m e n t i o n e d
gas
in the
present volume.
IrOn N~methi dealt with the difficult task of typing a large part of the m a n u s c r i p t using a Rank Xerox 860 word processor; we thank her for the excellent
job she did. Nicolae C r i s t e s c u Horia I. Ene
I. T H E O R E T I C A L
APPROACH
CHANGE OF SCALE METHODS APPLIED IN MECHANICS OF SATURATED SOILS F. GILBERT
RESUME
Deux a s p e ~ compl~me~aires de la description m~canique des sols sat~s, ut~ant d ~ m~thodes de changement d'~chelle, sont pr~sent~. Les m~thodes d'homog~n~isation pour un milieu polyphasique u t i l i sant un changement d' ~che~e par convolution s p a t h e sont tout d'abord ~tendues sous forme lagrangienne. Les ~quations de bilan au niveau macroscopique sont ainsi ~tablies ~ p a r t ~ du niveau local ( ~chelle des grains). Pour l ~ sols satur~s la vitesse de f i ~ r a t i o n ~ l e tenseur de c o n t r a i ~ e e f f e ~ v e sont int~odui~. No~ calculons explicitement l e tenseur de viscosit~ apparente et la force de flottabi~it~. Les p r o p h e t , s de p~m~abilit~ en r~gime harmonique de certains empilement~ bi-dimensionne~s de grains, qui rendent compte sch~matiquement par leur caract~re auto-similaire de la forte h~t~rog~n~it~ locale des sols, sont ensuite ~tudi~es. L'int~r~t de combiner ces deux types d'approches est soulign~.
ABSTRACT Present work deals with two compl~mentary ~ p e c ~ of mechanical d ~ c r i p t i o n of saturated s o i l s , using change of scale methods. Homogenization methods for multiphase media using change of scale by spatial convolution are f ~ t extended in Lagrangian forum. Balance equations at macroscopic scale are thus ~ t a b l i s h e d starting from corresponding equations valid at the local l e v e l (grains scale). For saturated soils seepage velocity and e f f e c t i v e stress tensor are i ~ o d u c e d . Apparent viscosity s t r ~ s tensor and buoyancy force are e x p l i c i t l y calc~ated. Permeability properties under h~monic conditions are then analysed for particular ~wo-dimensional g r a i ~ packings, whose s e l f - s i m i l a r i t y accounts schematically for strong local heterogeneity of s o i l s . Interest of combining these two kinds of approaches is emph~ized.
INTRODUCTION Predicting the macroscopic behaviour of saturated soils involves a lot of difficulties, part of which owing to the multiphase character of such a medium where solid and liquid parts are intimately mixed and interact in an intricate manner under unsteady or cycling loading conditions. generally be considered as quasi-homogeneous
They can
at macroscopic scale, in the
sense that they repeat themselves more or less in the space in a statistical manner, but appear always strongly heterogeneous at small length scale owing to the great complexity of their internal geometry. General mixture theories
(Truesdell and Toupin (1960), MOller (1975),
Bowen (1976)) have been used for soils by various authors. But apart from their perhaps too wide generality their usefulness lack of precise geometrical
is restricted by the
and physical interpretation of the various
terms. These theories must be supplemented
in any case by numerous pheno-
menological
(1980).
assumptions as made by Prevost
Furthermore the essential immiscibility character results in kinematical constraints upon the motions of the species. To account for this phenomenon theories with microstructural
content have been developed for po-
rous and granular materials and used in particular by Ahmadi Ahmadi and Shahinpoor
(1980) and
(1983). Review of theories of immiscible and struc-
tured mixtures may be found in Bedford and Drumheller
(1983). These theo-
ries need additional variables and equations which are hoped to account in a global manner for the geometrical arrangement of the constituents, its influence on the mechanical behaviour and its evolution. Another macroscopic approach for porous media, due to Biot (1961, 1962 a, 1962 b, 1977), uses a postulated
lagrangian formulation following
motion of the solid part. A discussion of theoretical and experimental results may be found in Coussy and Bourbie
(1984). However the underlying
homogenization process involved in such formulation is not very clear except for simple cases. Direct statistical assumptions
(Matheron (1965, 1967), Batchelor (1974))
or the hypothesis of fine periodic structure of the medium (Sanchez-Palencia (1974), Ene and Sanchez-Palencia
(1975), Auriault and Sanchez-Palencia
(1977), Bensoussan, Lions and Papanicolaou
(1978), Sanchez-Palencia
(1980),
Auriault
(1980), Avallet
(1981), Borne (1983))
have been used to study
various saturated porous materials. It is worth noting that part of the results so obtained are in fact much more general. Homogenization
processes using change of scale by
spatial convolution, as suggested in particular by Marle (1967, 1982), Ene and Melicescu-Receanu
(1984) and Gilbert
(1984, 1985), are hence
well suited for a comprehensive physical description of complex multiphase media as saturated soils. They allow to define in a natural way macroscopic quantities as semilocal ones linked to local quantities of each phase by accurate equations. This may be viewed as a generalization of previous works by Marle (1965), Slattery (1967, 1969, 1972), Whitaker Coudert (1973), Hassanizadeh
(1969), Gray and O'Neill
(1976),
(1979) and Hadj Hamou (1983) for instance.
This paper is organized as follows. Section 1 is devoted to definition of change of space by spatial convolution on a reference configuration and section 2 deals with basic geometrical and kinematic quantities at macroscopic scale in a multiphase medium. Balance equations at macroscopic scale are established
in sections 3 and 4, as well as associated
expression of the principle of virtual work. Application to saturated soils using actual configuration as a reference configuration is made in section 5 and stress tensors of interest are introduced. Apparent viscosity stress tensor is calculated in section 6. Explicit value of the buoyancy force is given and filtration processes are described in section 7. Unsteady permeability of particular self-similar structures is studied in the Last three sections. Hydraulic impedance of a two-dimensional narrow gap between two grains is calculated in section 8. Construction of a sort of compact grains packing is recalled in section 9 and method of solution for permeability properties is explained. Numerical results are presented in section 10 as well as possible application to periodic tices.
lat-
LAGRANGIAN
DESCRIPTION
OF
A MULTIPHASE
MEDIUM
1.- SPATIAL CONVOLUTION ON A REFERENCE CONFIGURATION FOR A MULTIPHASE MEDIUM
Let
E z and
Ex
ponding to local
be the initial and transformed physical spaces corres-
(grains scale) and semi-local descriptions
scale). Correspondence between them is made at fixed time of a positive even weight function support
D(O)
is equal to 1 ( F i g . l ) .
the position at time position at time
t
m(Z)
(macroscopic t
through use o whose integral over its bounded
It will be supposed in this part that
t of any particle is a continuous function of its : thus sliding is actually excluded.
0
/ I
/ 0
/ //
X1
Z1
D('O)
z2
t to
DIX
Figure I : Change of space by s p a t i a l convolution on a reference config~ion with a weight function m for a multicomponent medium. C o ~ t ~ t u e n t C i s found at time t i n part ~ a of ~ (X,t) whose image at time a t o i s D(X) , t h e t r a ~ l a t e d of D(O) by vector X. C o , a c t s u r f a c e of c o n s t ~ e ~ C with t h e other ones may be expressed as ~ = U P~(~) [ b ~ ) w h o s ~ images a t t are ~b (t). (For non reacting media ~ ' ~ ( ' ~ j = ~ ( ~ o J ). ~The same type of notation i s used for t h e i ~ e r n a l d ~ c o ~ t i n u i t y surfaces Z a ( t ) .
Note that except for particular purposes it is convenient to choose m of class C N on ~:~3 (with N being not too small) to ensure a sufficient regularity of macroscopic quantities. For the separate constituents considered one introduces for every constituent C a the function Ia(Z,t) defined as follows : Ia = 1 if the particle whose position is Z at t
at time t and I = O otherwise. a a Hence possible phase changes C a ~ C b along contact surface tab(t), such as o
belong to C
freezing of water in the pores (C a = water, C b = ice), may be considered. For a non reacting medium I a is clearly independent of
t.
To an additive quantity ~(a)(Z,t) relative to C a is associated an appa>a rent average < ~(a) at the macroscopic scale by the convolution product (in Lagrange variables)
a~Ia ~
=
The obtained quantity reflect small scale variations.
X,~
long trends of the medium regardless of
A sort of change of scale is thus achieved
(Fig.2)
for quantities of interest.
Q e-E z
~
Figure 2 : Macroscopic volume ~ vi~ed
"- Ex
i n E z and Ex
For instance if ~(a)- I one gets quantity
oa(%t)
:
which is to be interpreted as the volume fraction at t particles initially in D(X) which at time
t belong to
o
around X of the Ca
Derivatives of the semi-local quantities < O(a) >a are given by
(1.3)
(1.4)
:
a = (po(2)Ia([,t)) ~ ~.
•
Total mass at time t per unit volume at time t
e q u a l t o ~ - m a ( x , t ) . I t a p p e a r s as a q u a n t i t y a
o
around X is clearly o much more r e g u l a r t h a n l o c a l
mass perunit volume which is a discontinuous function in E
Z
at the grains
scale. It is convenient to define average velocity ~a(X,t) for constituent C a by reference to the apparent average
(1.1) of the momentum density a
8
where ~(a)(Z,t)
is the local velocity of C a . A mean position ~a+(X,t) for
Ca is obtained inserting in formula (2.2) positions instead of velocities. Motion of C a in E x is described by 1
(2.3a)
~a ( ~ , t )
= i~ ( x , t )
(2.3b)
~a ( X , ~ )
=
Xa ( X ) -
+
where Xa(X) is the value of x a at time to . For non reacting media the two functions ~ a ( X , t ) and ~ a + ( X , t ) a r e e q u a l a s s u g g e s t e d by i n t u i t i o n . This property is known to be false (except at particular time t ) for reacting o media. Average acceleration Ya(X,t)
for Ca in E x is taken as material deriva-
tive of Ua(X,t). Average displacement of C a is defined by
~2.~)
~
(~,t)
=
~ (~,~)
-
~(x)
and hence X is to be interpreted as a reference position. Gradient of de-
formation for C in E is a x
(2.s)
-o-a ( ~, ~)
= v~
( ~, ~)
.
Note that at time t o the gradient of deformation for C a is ~ a " fers s l i g h t l y
from t h e u n i t t e n s o r ~ . More p r e c i s e l y
if
which dif-
l o c a l mass p e r
unit volume at t o takes an uniform value for C a one gets for each constituent
(2.6)
V ~
Xa
=
I
-
I ya Sa .,.,
~
0
10 where the geometrical tensors ya(~) related to contact surfaces ra(t o) at time t
o
by
introduce a kind of departure of the medium from macro-homogeneity
at
scale of D(O).
3.- BALANCE EQUATIONS FOLLOWING MOTIONS OF THE SPECIES Balance of mass for C a is obtained through application of formula (1.4) to definition (2.1) as
Va
(3.1~
~ t) = ~'o a ,,,,
c o (x,~)
8 p . (t) '~
=
where the mass production rate ~a of C per unit volume of the reference o a configuration converts surface reactions in E z into volume reactions in E x. As a direct consequence of its definition one gets
(3.2~
v
7. c
a
( ~, t )
= o
which expresses conservation of mass for the whole medium following the motions of the various species. Balance equation of momentum for C
in E is obtained using the appaa x rent average (1.1) of the local balance equation. This procedure ensures automatically the compatibility between the two considered descriptions. One gets after some calculation material derivative of the momentum as
(3.3)
G oa ~ a
+ CV ao ~ a
=
moa F a
+
-Ro a
+
a]~Vo ,~, B a
where the body force per unit mass ~a" the interaction force per unit volume of the reference configuration ~a and the apparent Boussinesq stress o tensor Ba for Ca are defined in terms of corresponding local quantities by (3.4)
a
)
)
11 Observe that the interaction terms ~a appear quite naturally and that (ne0
glecting surface tension effects and adding formulas
7, Ro The p a r t i c u L a r L y
o
s i m p l e form o f e q u a t i o n ( 3 . 6 )
with corresponding expressions obtained for
Melicescu-Receanu 1984, G i L b e r t
of virtual
Evaluation in E
Z
and E
(Marle,
1982, Ene and
1984). V a n i s h i n g of the v e L o c i t y f L u c t u a t i o n
terms o b t a i n e d here i s cLearLy r e l a t e d the system t o be c o n s i d e r e d .
i s t o be noted and compared
Cauchy s t r e s s t e n s o r s at macros-
c o p i c s c a l e used i n f u L L y E u l e r i a n d e s c r i p t i o n s
o f the p r i n c i p l e
(3.5))
to the b e t t e r
To f o r m u l a ( 3 . 3 )
definition
used f o r
i s a s s o c i a t e d a s i m p l e form
work. X
at time t
0
and for a given macroscopic volume
of, say, the momentum of the solid part, yields slightly
different
re-
sults. Comparison has to be made between the two quantities ~(s) and U s
(3.8)
z
(3.9)
~
= ~
One can show ( G i l b e r t
~o~(~,~o)~(X,~)a~ x
1984) t h a t t h e d i f f e r e n c e
over the two small volumes C+ and C_ plying
to ~ the Serra t r a n s f o r m s
(Fig.3)
~s _ ~ ( s )
. involves integrals
obtained respectively
( M a t h e r o n , 1967, S e r r a ,
1982) t h r o u g h d i -
L a t i o n and e r o s i o n by the s y m m e t r i c a l volume D(O). Hence r e l a t i v e rence i s n e g l i g i b l e
if
diffe-
D(O) i s s m a l l enough w i t h r e s p e c t t o ,C~.
6N
8~Qo D(O)~
by ap-
--
C_ C+
Figure 3 : Volum~ contributing to t h e d i f f e r e n c e ~ - p i S l . Note t h a t for a symm~tric~ volume D(O) t he two Serra transforms ~ e given by the m e ~ o n e d Minkowski pseudo-addition and pseudos u b ~ a c t i o n.
12 Note that rigorous equations by equation in E
Z
in E
(3.9) and not by equation
x
as (3.3) involve momentum defined (3.8)
(which is the right definition
only).
4.- BALANCE EQUATIONS
FOLLOWING MOTION OF THE SOLID PART
One is generally essentially
interested
by motion relative to solid
part. We shall suppose the solid matrix to be chemically sake of simplicity
cartesian orthonormal
co-ordinates
inert and for
will be used in
the sequel. Geometrical
situation
is depicted
in figure 4 in E . X
Ex 0
Figure 4 : Companion i n E~ between the motion x~(X,t) of CA and i h e motion of a n o t h ~ c o ~ e n t Ca. Point~ of ~a belongin~ a t time t t o a c e r t a i n macroscopic volume i n E~, whose motion i s given by u (X~, t) , belong at fixed time t to ~he v ~ i a b l e volume
~ ( ~ t, Ca) given by ~ Let ~ be a macroscopic
={Y/Xa(
Y~-,t) = xs (Xs t ) j X e
,('l}
volume in E x given at time t o and moving by
assumption with velocity Us(X,t) of the solid part C s. Corresponding and momentum of C a at time part are (Fig.4) 4.1)
:
mass
t following motion x = x (X,t) of the solid S
13 With the dot
denoting derivative following in E
p a r t one g e t s f o r b a l a n c e of mass a f t e r (4.3)
• ~
transformation
X
motion of the solid
of f o r m u l a s ( 3 . 1 )
fi.,). •
(4.4a)
"¢'¢Ich ( X , ~ )
,
-F Ivl
CX;t~)
, for a # s
(4.4b)
a and M a are the masses of C a acquired by phase changes and convecwhere mch tion between t
0
and
t, per unit volume of the reference configuration ~.
Calculation yields
@
va
~
(4.~)
~ ° ~ (X,q = ~o C7,0-
(4.6)
Ma (X,t) = - divo N a ( X, t)
with
(X,~)
•
and thus classical Biot's structure is recovered. Quantity Ma(X,t)
for a
fluid C a is called fluid accumulation. Balance of momentum of Ca is expressed by
(4.+) P (o_>)
+
~(~,
~
•
o
where the surface i n t e g r a l corresponds to the open character of volume with respect to constituent Ca. Volume i n t e g r a l in formula (4.8) takes another form a f t e r transformation of formula (3.3) i n t o (note that s i m p l i f i c a t i o n f o r a = s is obvious)
m&
(4.9) # ~ + inch~
= ~ F. + ~t~'5-~ + di(o~.T~
where (4.10)
A"iR#t)
.~
is the i n t e r a c t i o n force f o r Ca at time t per unit volume of the actual configuration.
14
The apparent stress tensors ~a for the various C a are calculated as (note that for a = s, ~s = BS)
T a =
(4.11)
de~ ~s (X,~)
•
~(~ ~}.~(%~}.~ ~ (~,,~)
The principle of virtual work applied to ~, considering different virtual displacement fields ~x a for the various constituents,
a
states then
b~a
w i t h f o r any c o n s t i t u e n t Ca s u r f a c e f o r c e s a p p l i e d t o t h e t r a n s f o r m o f boundary 3~ only due to C a itself
(~.~,
~w0~f,,
Contact forces
-
f
due t o i n f l u e n c e
8~.~T ~. ~odAo of the other
.
constituents
Cb must no be
c o u n t e d t w i c e and h e n c e a r e t a k e n i n a c c o u n t by v o l u m e i n t e g r a l s
(4.13b)
W b
'
.0.
only
b~a
Virtual works of body forces, internal forces and inertia forces are expressed by
(4.13c)
~--,,ody ~J''
=
(4.13d)
8,~o,
:
d,F
~
S~)a
These e q u a t i o n s p r o v i d e a u s e f u l b a s i s f o r comparison w i t h B l o t ' s
theo-
ries. One can see in figure 4 a little difficulty unavoidable with this formulation : at time t = t
correspondence is made by x between the phases as O
= X
and thus ~ ~ X. It introduces a small distorsion in the evaluation
a s of mass and momentum of C a .
15 APPLICATION
TO
SATURATED REFERENCE
SOILS
USING
REACTUALIZED
CONFIGURATION
5.- STRESS TENSORS Let us use the particular choice t o = t : fixed reference configuration coincides with actual configuration
(note that the description is slightly
different from a fully Eulerian one). It is then a simple matter to show that sliding between grains is now allowed (see also Gilbert 1984). Two constituents are to be distinguished for a saturated soil : the solid part C S and the pore fluid Cf. Actual pon is defined as ¢ ~(~,to ) and masses
rosity
(1 -n) Ps and npf
m °s and m of may be written as
respectivelyr with obvious notations for densities at
macroscopic scale. Balances of momentum
where unit
(3.3) read (no mass production term)
g i s the a c c e l e r a t i o n
of gravity
volume) e x e r t e d on the s o l i d
part
and
R the i n t e r a c t i o n
force
s
f
by the f l u i d
the s y m m e t r i c a l apparent averages of c o r r e s p o n d i n g tensors.
FormuLas ( 5 . 1 )
ture theories.
are s i m i l a r
part ; ~
and A
(per are
LocaL Cauchy s t r e s s
to f o r m u l a s p o s t u l a t e d
in general mix-
Note t h a t p h y s i c a l meaning of each term i s e x p L i c i t L y
known
here. It is however convenient to use in soil mechanics other stress tensors. One can define in an obvious way for the fluid part an average fluid pressure
p and an apparent viscosity stress tensor
(s z)
where
P
p(f)
=
Z f by
< Pcf)>f//
and ~(f) are the local fluid pressure and the local viscosity
stress tensor. Of interest for the solid part is the modified stress tensor
16
q
sd
insensitive to any uniform translation of local stresses along the
pressure axis (5.4)
:
,v ~$d
-v@'$ +
(~'q%)
~ -~-Z
,
Hence e f f e c t i v e stress tensor ~ r i s given by (5.5)
o"v
:
o"
+ roT.
:
o ''sd
+ ~f
where the stress tensor q for the whole medium is the sum of qs and q f . Dynamic equations
where vector (5.7)
(5.1) are now written in a more useful form
b , which w i l l appear useful,
is given by
D = R + p grad n
6.- EXPLICIT CALCULATION OF THE APPARENT VISCOSITY STRESS TENSOR The (relative) (6.1)
seepage velocity U(x,t)
is defined as
0 = n(uf - Us )
at a given point in E . For incompressible constituents of uniform densix ties Ps and pf formulas (1.3) yield for consolidation problems (6.2)
div U = - div
s
which expresses conservation of total volume of the medium. Let us now consider an incompressible newtonian fluid of uniform dynamic viscosity
q flowing with seepage velocity U(x,t) through a packing
of rigid grains having different velocities and spin vectors, lid part moves with average velocity Us(X,t). to
Using formulas
so that so(1.3) with
t one gets for the apparent viscosity stress tensor
where D denotes the symmetrical part of the gradient.
Note that formula
(6.3) is valid for any geometry of the porous medium and for any fields
17 and Us" When solid part is at rest or moves with uniform velocity it reduces to the result given by Gilbert (1984). The corresponding term in formula (5.6b) is (4 = Laplacian) :
and is thus found to be negligible (with respect to b) for practical applications. Although fluid movement is generally governed essentially by viscosity, corresponding macroscopic terms disappear : o v and qsd are almost equal and fluid stress is correctly represented in E
by a simple X
pressure
p(~f = - np~).
7.- FILTRATION PROCESSES The interaction term
R
is to be splitted in three parts : a static
one owing to the possible macroscopic inhomogeneity of the soil (called "buoyancy" force), a kinematic dissipative one (drag force) and a dynamic one corresponding to inertial coupling between fluid and solid parts (virtual mass effect) (7.1)
R
=
Rstatic
÷
Rkin.
÷
Rdyn.
In this section dynamic term Rdyn. will be disregarded. Neglecting variations of fluid density at scale of D(O) one gets (Gilbert 19C4) for the static part (7.2)
Rstatic = - p grad n + pfg. ~f
where influence of the geometrical tensor Yf given by (2.7) is very small, at least in mean value (see formula (2.6)). Equation (7.2) then reads (7.3)
Rstatic ~
- p grad n
Hence in that case b (formula (5.7)) and not
R (as postulated on in-
tuitive grounds in certain mixture theories) equals zero. Note the particularly simple expression of the buoyancy force (7.3) and its obvious geometrical interpretation. Estimates in (5.6b) of vector
b, or R - Rstatic"
yield Darcy's law under various forms. Note that an estimate of b is naturally not available for any porous medium under any flow condition.
18
Slow stationary a fixed stationary a symmetrical
filtration
random porous matrix yields
intrinsic permeability
tensor
newtonian
fluid through
(Marle 1967), as D(O) grows,
k given by
k-~ 1 ~Mih ~Mil >f ~h ® ~1 "" : ~. < ~zJ ? z J~'
(z.4~
as a function of the stationary function of
of an incompressible
random tensor M(z) which maps u(f)(z) as a
uf.
One can also treat by this method the corresponding periodic slow stationary
flow through a periodic
venient here to choose for
m the discontinuous
case of spatially
fixed matrix.
It is con-
function equal to 1/ID 1 in
the basic period (IDI being the volume of the basic period of the lattice) and to 0 elsewhere. (7.5)
Equation
(5.6b) then reads
~) = n(pfg - gra--d p)
However
~) and gra---d p are not constants whatever
x.
sary to use a double averaging process, which eliminates fluctuations,
the preceding
by introducing
(7.6)
B : b * m
(7.7)
P = p * m = ((p(f)If) * m) * m
Classical
variational
with a symmetrical (7.8)
It appears neces-
structure
is then recovered yielding
intrinsic permeability
tensor
Darcy's
law
k
~ = _ 1 k (grad P - pfg) r1-,-
Denoting by ~(z) a D-periodic
function and by
~ a constant vector one
has for the various pressures
(7.9b)
p
(7.9c)
P (~) : ~. ~ +
Observe
(~)
(Gilbert
:
~.XF(X
) l-cl~e~
1984) that fluctuations
of
p around
lated to geometry only, through the periodic abovementioned
P are thus retensor
value for a periodic medium is shown to be
(7.1o)
Y f : (~-~1) ~1 ®~I + (~-~z) ~-2® ~z + (~-~31~s®~
Yf whose
19 where
n is the (constant) volume porosity and n. the variable surface I i porosity of planes z i = x i ± ~ l~il (~g. 5). The difference between p and
P is small when the elementary period contains many grains since
surface porosities become progressively equal to volume porosity as geometrical disorder in the period grows.
pressure /
~
P(x 1) : slope
I I) : s l o p e n~ n l ( x I -+ -E 1 J~l j)
v
+ 11Zli
I
1 z1 X
D(x)
Figure 5 . Average p r e s s e s p and P i n a p a r t i c u l a r p e r i o d i c medium for ~ = ~I" The vectors -~, = l~il-e i ~ e basic v e c t o r s of the periodic lattice. Note that the pressure P may be identified with the first term Po of the asymptotic development of the pressure in successive powers of the small parameter c. which is postulated in the theory of homogenization of fine periodic structures.
20 HARMONIC
FLOW
A PARTICULAR
THROUGH
FIXED
STRUCTURE
8.- HYDRAULIC IMPEDANCE OF A TWO-DIMENSIONAL NARROW GAP To obtain more complete information about behaviourof
a saturated po-
rous medium one must use postulates or analyse by numerical methods particular structures of interest, which allow to go further. Such an example is presented here concerning harmonic flow of an incompressible newtonian fluid through narrow gaps between the various parts of a fixed solid matrix. For sake of simplicity problem is studied in two dimensions ; grains are roughly schematized as parallel cylinders. Let us consider a narrow gap of minimum width 2h.. between two locally i] regular motionless cylinders of parallel axes with radii of curvature a.] and
a. respectively in the vicinity of the narrowing ]
"L~.. A ,~ p C-o>)
Yi
t
~.,,S
+hii
- L ij .~
(Fig.6).
+ L ii .v
o t, -hij
~ ,
0
the second y i e l d i n g mechanism is actived.
and sign
is 7 - ( ~ )
0 , ~
>
-
7- ( ~ ) < 0 , ~
>
for
IT
For a loading without reorientation of principal axes, i t is easy to demonstrate that ( ~ ~= + dE=) takes the sign of (0-~ - (I':) ~, then volumet r i c strains are compressive. With an additional simplifying assumption i t can be demonstrated that fulf i l l i n g equations (20) and (21) leads to the stress-dilatancy relation defined by Rowe I l l } 4.3. Load!ng- s t r e s s path_wi}h_(3_z_C~_~~_constant The previous analysis points out s l i d i n g c r i t e r i o n s defined by CT~/(F=. In such a hypothesis, loadings with ~ / ( T = = c t , cannot provide irrecoverable s t r a i n s , which does not correspond to the observed experimental behav i o r o f granular materials. To have a b e t t e r adequacy of the model, i t is necessary to modify hypothesis (4) and (19) . In f a c t , the irrecoverable strains provide an evolution of the number of contact points, which is not proportionnal to the stresses applied. to
To take into account this phenomena t e r m ~ in relation (4) and (19).
~rU~,:) P°q
can be substituted
Term a is a parameter to be defined, Po equal to the unity of pressure makes i t possible to preserve the homogeneity of the formulae. The analyses presented in section 3 and 4 can be developped with the new assumption {5}. In this case, the yielding lines of the two mechanisms are s l i g h t l y curved.
57 5.
Elasto-plastic model.
The previous microstructural analysis leads, in the general framework, of elasto-plastic theory, to a model with two yielding mechanisms (Fig.9). . The f i r s t one defined in section 3 characterizes the evolution of mean contact forces. For a bidimensional material this mechanism depends on two scalar parameters : ~d which is a kinematic hardening parameter, is linked to the evolution of the deviatoric stresses. ~:which is an isotropic softening parameter, is linked to the reorientation of the principal axes. For a monotonical loading the evolution of this mechanism leads to extensive volumetric strains. Yielding surfaces are defined in section 3. The second one defined in section 4 characterizes the width of the distributions of contact forces, For a bidimensional material, this mechanism depends only on one scalar parameter which is an isotropic softening parameter. For a monotonical loading the evolution of this mechanism leads to compressive volumetric strains. Yielding surfaces are defined in section 4. For a f i r s t loading path, the l i m i t between the two domains of activation of the two mechanisms is given by (Fig.9) : A f t e r complex loading t h i s l i m i t can change• For real loading i t can be assumed t h a t the t r a n s i t i o n from one mechanism to the other occurs progress i v e l y around the defined bounds. 6.
Predictions o f the model and experimental r e s u l t s -
.
I s o t r o p i c loading :
Hypothesis taken i n t o account in section 4.3. allows to describe i r r e c o v e r a b l e s t r a i n s under an i s o t r o p i c loading. First monotically deviatoric loading: From experimental data Habib and Luong {9} have shown, t h a t in a stress space, a " chcutactP~tic" line can be defined. This line is the l i m i t between volumetric compressive strains and volumetric extensive strains, this l i m i t does not depend on the density of the granular material (Fig.lO). These experimental results are in agreement with the analysis proposed herein. The characteristic line is in our analysis the boundary of the two yielding mechanisms. I t is possible to determine experimentally the yielding surfaces of a granular material. I t can be shown on Fig.11 from Tatsuoka and al {12} that these surfaces are very similar to the yielding surfaces defined in this work (Fig.7). Fig.12 shows that at the beginning of a deviatoric stress path the hardening observed is isotropic and kinematic and for greater value of deviatoric stresses i t is only kinematic. This kind of behavior is in keeping with the previous analysis .
58
g mech.n°l
boundaries of the 2 mechanisms for a virgin material
\
kinematic #f"
i
isotropic
Mech.n°2
yielding mech.n°l
Fig. 9 :
q
LR// / /
~ f
~z
LC
Yielding mechanisms.
~Domaine surcaract~ristique
dilatant
-
_ ~
Domaine P subcaract~ristique > ~ontr~tant
~z~
3
Fig.lO : Definition of the "characteristic" line. From Luong {9}
59
Fig.11
:
/
Y i e l d i n g surfaces
Experimental r e s u l t s from Tatsuoka and I s h i h a r a
S
{12}
4
=r2
,m
0
* pwCO~Sl, -4t 'A ~ a ¢ O n s l ,
"so
~ effective
• *
~
[~, /
'~-:~
*$ "~
+
s
6
me'Qm prlmcipal sirius
P'(~,lcn't)
iso + kinem, hardening kinematic hardening ,,A,,
(~o+ k P~ Fig.12
3-
elastic
domain
: Compression -
Extension t r i a x i a l
tests
on sand
2-
~=
1.
/
15,4 kN/m3
60 -
cyclic loading :
For c y c l i c loading with large stress reversal, volume changes show a general tendency to compaction even for dense materials (Fig.13 from Thanopoulos {13}}. This can be explained in the framework of this study because, a f t e r large stress reversal, i t is easy to demonstrate that G and Ad have the same sign in equation (17), then the volumetric strains are necessarily compressive. 6.
Conclusion
The microstructural analysis proposed in this work has allowed us to define the y i e l d i n g mechanisms of an e l a s t o - p l a s t i c model. This model seems to be in agreement with phenomena observed in experiments on granular media. Only bidimensional media were considered here, the analysis of three dimensional material does not present any t h e o r i t i c a l d i f f i c u l t y but requires taking into account a greater number of y i e l d i n g parameters.
l q-o~ e~--o55
lO~P~
essa, 2
I 6 4
,3 - -2t
-3 -2 "3 "2 "t
Fig. 13
"t I
:
2 .....~'~4__~ G
7
E,%
Cyclic loading on dense sand.
(From Thanopoulos
{13} )
61
REFERENCES 1
CAMBOUB. (1982) " O r i e n t a t i o n a l d i s t r i b u t i o n s o f c o n t a c t forces as memory parameters i n a g r a n u l a r m a t e r i a l " IUTAM Symposium proc. "Deformation and f a i l u r e o f g r a n u l a r M a t e r i a l " Delft. CAMBOU B. (1984) " Microscopic aspects o f hardening i n g r a n u l a r material". I n t e r n a t i o n a l CHISA - Prague. CAMBOU B. - SIDOROFF F. (1983) " Failure criteria for granular m a t e r i a l based on s t a t i c a l M i c r o s t r u c t u r a l v a r i a b l e s " V i l l a r d de Lans - Juin 1983. CNRS. Symposium Proc. CAMBOU B. - SIDOROFF F. ( 1 9 8 4 ) " D i s t r i b u t i o n s o r i e n t ~ e s dans un milieu granulaire et leurs representations". "Proc. o f Journ~es de M~canique A l 6 a t o i r e appliqu~e ~ la c o n s t r u c tion" - Paris. CAMBOU B. " Les m~canismes de d~formations p l a s t i q u e s dans un sol granulaire" Revue FranGaise de G~otechnique n ° 31. CAMBOU B. - SIDOROFF F. ( 1 9 8 5 ) " D e s c r i p t i o n de l ' ~ t a t d'un mat~riau g r a n u l a i r e par v a r i a b l e s i n t e r n e s s t a t i q u e s ~ p a r t i r d'une approche d i s c r e t e " . Journal de M~canique Th~orique et Appliqu~e. V o l . 4 , N° 2 ,pp.223/242. CHRISTOFFERSEN J. MEHRABADIM o - NEMAT-NASSER S. - " a Micromechanical d e s c r i p t i o n o f g r a n u l a r m a t e r i a l b e h a v i o u r " . J. o f . Appl. Mech. Voi.48 , pp. 339.344. LECKIE F , A . - ONAT E.T. (1981) " Tensorial nature of damage measur i n g i n t e r n a l v a r i a b l e s i n physical non l i n e a r i t i e s i n s t r u c t u r a l analysis." Ed. J. Hult - J.Lemaitre - Springer B e r l i n , pp. 140/155. LUONG M.P. (1980) " Ph~nom~nes c y c l i q u e s dans les sols p u l v ~ r u l e n t s " Revue FranGaise de G~otechnique n ° I 0 . pp.39/53.
10
MEHRABADI M. - NEMAT-NASSER S. - ODA M. " On s t a t i s t i c a l o f stress and f a b r i c i n g r a n u l a r m a t e r i a l s " I n t . J. Num. Anal. Meth. Geom. 6. 1982, pp. 95/108.
description
11
ROWE P.W. (1969) "The r e l a t i o n between the shear s t r e n g h t o f sands i n t r i a x i a l compression, plane s t r a i n and d i r e c t shear". G~otechnique 19 - V o l . l . pp. 75/86.
12
TATSUOKA F . - ISHIHARA K. ( 1 9 7 4 ) " Y i e l d i n g o f sand i n t r i a x i a l compression " S o i l s and Foundations, 14, 2 pp. 63/76.
13
THANOPOULOS I . (1981) " C o n t r i b u t i o n ~ l ' ~ t u d e du comportement c y c l i q u e des m i l i e u x p u l v ~ r u l e n t s " . Th~se D . I . Grenoble.
62
14
THORNTON C. - BARNES D.J. " On the mechanics o f g r a n u l a r m a t e r i a l " C.R. IUTAM Symposium "Deformation and F a i l u r e o f g r a n u l a r m a t e r i a l " D e l f t , Balkema 1982 , pp. 69/77.
15
THORNTON C . - BARNES D.J. (1984) " The r e l a t i o n s h i p between stress and m i c r o s t r u c t u r e in p a r t i c u l a t e media". CoR. Du Congr~s I n t e r n a t i o n a l CHISA - Prague.
16
WEBER J. (1966) " Recherche concernant les c o n t r a i n t e s i n t e r g r a n u l a i r e s dans les m i l i e u x p u l v ~ r u l e n t s " . B u l l e t i n de L i a i s o n des Ponts e t Chauss~es n ° 20 , pp. 3 . 1 / 3 . 2 0 .
A MATHEMATICAL
MODEL
FOR THE L I Q U E F A C T I O N
Lucia
Polytechnical
OF S O I L S
Dr~gusin
Institute,
Bucharest,
Romania
Abstract. A unitary model for mechanical soil behaviour is set forth. By u s i n g the particular cases of the material constants occurring in the constitutive equation, the model is able to interpret the behaviour of both granular and cohesive soils, either normally consolidated or overconsolidated under monotonic loading. It accounts for the occurrence of dilatancy in cohesionless soils and of liquefaction in certain cohesionless soils undergoing quasistatic cyclic loading.
1.
INTRODUCTION
The behaviour describe from the
work
soils
the
behaviour
of
three
the
constitutive processes,
reloading
processes
a
saturated
loading
for
supplies
of
join
mathematical under
this
in
bi-phase
equations
of
the
The
stress
the
the
paths
the
order
model
an
processes
mechanical
In
the
rate-type,
stress
space,
for
loading.
material,
one for the unloading
processes.
up
model
monotonic
equation
initial
for
and another
described
by
stress
to
starts
one
these
state
of
a
process being equal to the final stress state of the previous process. Strain and stress will be taken positive The material i.e.
viscous
superposed only theory
as
and
rate
dot will
an
properties
will
effects
will
indicate rate,
ordering
parameter
in
of plasticity.
Monotonic
and
in compression.
be considered not
be
independent
covered
by
but in the latter, the
sense
cyclic
time
generally
loading
will
of time,
the
model.
is
intended
used be
A
in
the
considered
as quasistatic. The materials:
model
Relying model
may
describe
the
behaviour
cohesive soils and cohesionless on
highlights
constitutive the
way
in
equations which
the
of
two
large
classes
of
soils. of
the
hypoelastic
initial
state
of
type,
the
stress
and
strain has to be formulated. The dilatancy phenomenon of cohesionless existence
soils in evinced by the
of a value of maximum density P (for certain
loading paths).
64
The
occurrence
of
cohesionless
undrained
cyclic
loading
is
stability
in
constant
density
will
the
establish
where
the
entailed
effective
the pore pressure
The
liquefaction account
The
paths
of
the
condition
featured
undergoing lack
of
p : constant
by undrained
tests
is zero.
mathematical
MATERIALS
model
set
OF G R A D E T H R E E
forth
starts
from
the
following
:
i. soils initial
on
curves.
stress
2. A CLASS OF H Y P O E L A S T I C
hypotheses
soils
have
memory,
state and the stress iio for
a certain
their
behaviour
depending
on
the
history;
stress
history,
the
dilatancy
of
soils
may
occur; iiio
because
mechanical
energy
the
related
stress
history
for to
T = T(T),
normal
at
tensor
(L = -grad x
initial
stress
surface); is of
tensor
that
of
the
the work
depends
non-
done
on the
by
stress
~
= f ( (Ps)° tr(TD)dT]dVo, V o to Ps
(defined
the
spatial
the initial solid phase
(see Dr~gusin [I]). iv. for a closed (undrained)
the work
contribution
configuration
D = ½(L + L T)
being
particle); V o = V(t o) relative mass density volume)
the
the
we suppose
t = f (ftr(TD)dV]dT to V
T is the Cauchy body
soils
be ignored,
• ¢ [to,t ]
[w(T( - ))](t)
where
drained
can not
w is a conservative
function,
is
by means the
gradient
of the
rate of
of
the
internal
deformation
velocity
of
a
volume V;(Ps) o is the initial (mass of the solid phase/total incompressible namely
there
system
(p = po ),
is a function
@ so
that dw : tr(TD)dT
: SdT.
PROPOSITION 1.
The c o n s t i t u t i v e e q u a t i o n
~=(~1x2+6ox3+~--~7y+61xY -
Z)IDI+ (~2x2+62x3-~--y+63xY+64z)D +
6 -8 +( ~3x+ 65x2)IDT+( (~4x+66 x2 + ~ y ) t r ( T D ) I + ( ~ 5
2B9 2 67y)TD2D_____~T+ x - --~-x +
(I) e7 + (-T+
~
X)IDT2+(~6+68x)tr(TD)T+(-
+ (~7 + 6 9 x ) T 2 D 2 D T 2 -
~7 87- 89 ~-- + ~ x)tr(T2D)I +
B4tr(TD)T 2-67tr(T2D)T,
65 where I is
is
the u n i t
the Jaumann-Noll
I D = t r D i s the t r a c e of D; ~ : T + WT - TW
tensor; stress
r a t e , W being
the spin
tensor; T* = T
i s the d e v i a t o r i c s t r e s s tensor; x = t r T; y = t r ( T * ) 2 ;
2 81 a2 + a7 (9 a2+9 e5+4 a7 ) el = 27 (9a2+3e5+e7) '
-27 a2 ~5+a7 (9 a2 + 12e5+5 a7 ) 9 (9e2+3e5+a7)
a9 =
I 81 =- 1--~(384+2786+287+388-1169 ),
~ITI z = t r ( T * ) {, and
I 83 : ~(84+27B6+287+368-989 ),
85 = - ~(81 8o+2782+2786+287+368-589), i m p l i e s the e x i s t e n c e of
$(x,y,z)
two p o t e n t i a l s ~,~ so t h a t
x : ~ID,
~)(x,y,z)
: tr(TD).
They are
16a3x3-3ab2xy+2b 3z laI+ 16a3x~-3ab2xoYo+2b3Zo
~ ( x , y , z ) - ~ ( X o , Y o , Z o ) =--!-I i n b2d 2 2AXo-CYo
I
+ 2--~(
~ xo
2Ax2-CY),x3 (2)
i
~(x,y,z)-~(Xo,Yo,Zo )---!-l-b2 d In x 0
~
I
I [2AXo2-(c+D)Y0 2Ax2-(C+D)v
.j
-
where I
I
a= a2+~a5+~a7 ;
2
b= a5+~a7 ;
c: 3a4+a5+a6 ;
d:9 ai+3 e2+3 a3+3 e4+ a5+ a6--~a7 ; B:~(84+2786+487+388-889);
I C=~(84-986-388+289 );
D:-(188o+682+686+-~(87-89)); and
a,b,d,A,B,D,E, > O,
d-c > O,
I
A= 82-~89 ;
E:87-84, C+D > O,
b-3a > O,
b2-3ac > O.
PROOF. From the constitutive equation (I), because :
-
2X
X
2-
X
1 +
66 we obtain
½:[d~---qCx2+ ~ x 3 ] I D + ( C x - C x 2 ) t r ( T D )
_1 ~:[_ 3a9____.bbx33a(d-c-b)+b2 xy__~x 4 2
+
-
3a
I" ra 4
~z=[~x
+
-
9a
C2Dx2y]I D
+
+
[3a321Ox2
-
Y+ Ax 3 - ?xy]tr(TD)+(bx)tr(T2D) 6a-b 2 1--T'~- x
Y
+
~a(d-c)+b 2 x z 9a
+
~x 5
-
3A Bx3y 9
(3) -
6B+E ~xy
2
+
6B+9(C+D)-2Ex2 z E z 2a 3 ~xy - b2-3ac 2A 4 18 + 3Y ]ID + [ - T x + 3a z ---~x -
- T2B x 2 y- 6B+96C-4E.xz]tr(TD)+(ax2+Ax3+Bxy_Ez)tr(T2D) Then " 2 6a3x3+3a(2ac-b2)xy+2b(b2-3ac) z ]x-3a cx 2 - y+2abexz- + 3(2Ax2-3Cy) ID:3[ dx2(6a3x3_3ab2xy+2b3z) 2ADx 5
tr(TD)={6a3x3-3a[2a(d-c)+b2]xy+2b[b2+3(d-c)]z}~÷3a2(d-c)x2y dx(6a3x3-3ab2xy+2b3z)
_
2ab(d-c)xz + [2Ax2-3(C+D)~]i+(C+D)xy dx(6a3x3-3ab2xy+2b3z) 2ADx tr(T2D)=[ 2Ax4+ (6A-C-2D)x2y-9Cy2-9Dxz 6ADx 5
'
(4)
+ E 2Ax3y2-3Cxy3-18Dxz2-36C}/2Z]x + 12ADx5 (Ax3+Bxy-Ez) ]
I(C+2D)x2+3Cy CExy2-6CEyz+6BDx2zl z 4 Y+ ' [ 6ADx 4 + 12ADx (Ax3+Bxy-Ez)l 3(Ax3+Bxy-Ez) if x ~ 0, 6a3x3-3ab2xy+2b3z ~ O, The differential forms
x
: ~I D
and
Ax3+Bxy-Ez ~ O.
~ = tr(TD)
are exact. By integrating these relations we get the expressions
(2).
REMARK. In the axial-symmetrical case, the stress tensor T and the rate of deformation tensor D have the form
I! I T =
0 TI
0 0
0
T3
D =
lilop10D3:I
67 Then x = 3P,
Y : ~q2 ,
2 3 z = ~q
and from (2), (4) we have
$(p,q)= [(9ap+ebq)(9ap-bq)+6acqa]P-6acpqq dp(9ap+2bq)(9ap-bq)
+ ~(9Ap2-Cq2)p+eCpqq 81ADp4
~(p,q): [(9ap+2bq)(9ap-bq)-6a(d-c)q2]p+6a(d-c)Pqq dp(9ap+2bq)(9ap-bq) +
3[ 9Ap2- (C+D) q2 ]P+2 (C+D) Pqq 81ADp 4
~(P'q)-
•
(5)
+
~(P°'q°)=
llnIl~Pb2dol b2-3ac
I i27Ap2-Cq2 o o I93a3p3_27ab2pq2+2b3q3 Ia I 3a3 3 2-ab 2 _2+2b3^3 + I~-I-A-D p~ 9 Po- Y Polo ~o
27Ap2-Cq 2 ) p3 (6)
~(p,q)
- ~ ( p o , q o ) = ~--~dln
0
Po- • Poqo qo a(d-c) I " 193aSp3_27ab2pqe+2b3q~ +~
3 Po
-
p3
"
In this case, the system (3) may be inverted if p ~ 0,
9ap+2bq ~ 0,
9ap-bq ~ 0,
27Ap3+2Bpq2-~Eq 3 ~ 0.
We consider the set D = {(p,q) IP > 0,
9ap + 2bq > 0,
3. THE S T A B I L I T Y
9ap - bq > 0,
WITH R E S P E C T
~3p ---Ep9B 2_
TO THE INITIAL
243A2E > 0}.
STRESS S T A T E
DEFINITION I. Let D c R 2 × R be the set in which the equation F(p,q,k) = 0 implicitly defines the function p = f(q,k) and let q -+ fk(q) be the partial function. We say that q* is a critical point df k for
fk
if
condition
(d-~] q=q,-- O. I t
d2f k Id~)q=q.
i s a nondegenerate c r i t i c a l point i f
~ 0 is also satisfied;
degenerate c r i t i c a l point.
if
d2f k Ij)q=q,
the
= 0 it is a
68
DEFINITION ~f k* ) = O. ~q(q, with respect and
a
2.
We
say
that
- k I < 6(¢),
and
V .(E) for
q
qe c V .(¢), q
d2fk
d--~--(q*) Cristescu,
let
= 0. The
nondegenerate We
q*
the
function
f .
any E > 0 t h e r e
that
equation
for
any
is
q
is
an ~(~)
k,
for
which
~f ~-~(q,k) = 0
has
a~
> 0
Ik* -
least
a
< ¢ .
Dr~gu~in and
[2]
the
following
q* a critical with
proposition
point
respect
has
for which ~q(q*
to the parameter
been
, k* )
=
k in its
criticqal points.
shall
further
~(p,q)
: qb(po,q o) state
and
study
~(p,q)
from
this
point
: ~(po,qo ) with
of
view
respect
the
to
the
curves initial
(po,qo).
From of the continuity
equation -~ = I D one has -~ = 15 P •
This
relation
represents
stable
I
f , is stable
stress
means the
that
stress
the paths
for
characterizing
constant
thus
tests with pore pressure
PROPOSITION 2 .
function
p :
function
p
p(q,k)
pertaining
: 8cAD'
If
the
equation
then
the
to
the
¢(p,q)
which
undrained
total
= k,
where
mass
behaviour
of
k = ~(po,qo)
density a
P
remains
material
under
equal to zero. ~(p,q)
= k
critical
implicitly
degenerated
domain D are
(Pl
defines
points
- adC 3cAD'
of = 0)
ql
the the and
q2 : 32bcAD )"
PROOF. satisfy
for
so
the
(qg)
k* be fixed
function
if
q*
of the equation
we have
dq2
In
point
k,
of
which
d2fk ,
proved:
in the
to the parameter
neighborhood
solution
Let k* be fixed and q* a solution
The
critical
degenerated
points
of
function
p = p(q,k)
the relations dp 0, dq =
d2p 0 dq2 = "
We
rearch
shall
for
the solutions
to the domain D. From the relation
[243acADp3-dC(9ap+2bq)(9ap-bq)]
Ii
of this
(51) , we obtain
is equivalent
to
for
: 0
43acADp3-dC[(9ap+2bq)(9ap-bq)+bq(9ap-4bq)]
This system
system
= 0.
which
$(p,q)
belongs
= 0
69
Ii °
Ii Ea laIasCAD
:
:
~
-
-T~p~]
and
(7)
adC 3cAD yielding
9a I~P
the solutions
(pl,ql)
and
(p2,q2).
[d2p) 2 -adC+3cADp ,dq 2 q=0 - 27aAp 3Dp+d
As
dq 2 1q
'
cAD 3a-8--~p )] '"
:
8b2d2C2 [ a+/3a ( ~a~- 8cAD~-~-p) ] /3ai ~ a- ~-~-p )~cAD :+ 81acADp2116b2A(3Dp+d)+5dC(a
if
c,C > 0
for
: ~b [a + /3a(3a
are
maximum
points
maximum
the
on
points
on
the
the on
ado
Po < ~
± /3ai3a-8~cDp)] From (pl,ql) relation
the
points
points
on
= ~b [ a
q
c,C < 0, q = O;
then
and minimum
on the
axis
curve
q =
q = ~b [a -
adC q = 0; for Po < 3cAD ± o-,3a
~~ -c~A-~P .) ]
-
for
p ] and are maximum points
and
stress
¢(pl,ql ) = ¢(po,qo ) viz.
there
adC 3cAD < Po < ~8cAD
the
the minimum
maximum
points
the
points
on
on the curves
are
maximum points the
on
axis
q =
[a ±
instability
point
on the axis q = O.
(6) we find
for the initial
adC Po > ~
for
b [a+ 3F~a(~5a-o~--P)], ~cAD q : 49_~
there
along
curve
on the axis
curves
points
= O.
hand axis
minimum
are minimum
points
a-8
the relation
occurs
q
other
q = ~b[a-
for
on
axis
the
exist
maximum
points
are on the curve
curve
q = 0;
. - 8cAD ~-~-p)],
minimum
If,
points
there
_ gcAD ~-~--P)]" and minimum
/~3a
there
then
adC 3adC for ~c-AD < Po < ~r6-~ there
q = 0;
_
adC Po > -~'AD
-+ 3~a( ~a-o~-~--p)]~cAD (
that state
the
first
(po,qo)
which
verifies
the
70 9a3po3
2 2 27APo-Cqo adC In po+ab-~In 9a3p 3 _27ab2p^q 2 +2b3q 3 + d 81ADp3 : in -3cAD u
v
U
v
while the second instability point state which verifies the relation
U
(p2,q2),
for
the
initial
2~A 2 - 2 f Po-Uqo ac : in 3adC --:In 9a3p3 27ab2p q2+2b3q3 + d 81ADp~ 9a3p 3
in
po+a~-~in
0
+
C
0
stress
d32
+
0
15a2C-8b2A 18ab2C
PROPOSITION 3-
by the
0
aC cA
equation
If
¢(p,q)
the function q : q ( p , k ) then
= k,
its
is
i m p l i c i t l y defined
c r i t i c a l degenerated
points
from
domain D are the solutions of the system -
(81~ 2AE2o
E2Fo )2
+
81a 2A (EoF I - EIFo)(E2F I - ~ E o E
I) = 0 (8)
q
:
EoF
i_p
EIF o
(E2F o
81a2A E 2) - ~ ,
where
Eo=-b[540AD2(b2-3ac)p2+24dD(27a2C+11b2A-18acA)p+ +d2(171a2C+32b2A)], E1=9a[108AD2(3b2+ac)p2+9dD(18b2A+2acA-9a2C)p÷2d2(10b2A-9a2C)]
,
E2=243a2bA(153D2p2+82dDp+11d2), Fo=648A2D2(b2-3ac)2p2+36dAD(45a2b2C+8b4A-117a3cC-24ab2cC)
p +
+ d2(729a4C2+360a2b2AC+32b4A2), F1:-27abA[144AD2(b2-3ac)p2+dD(68b2A2+81a2C-108acA)p+ +2d2(9a2C+4b2A)]. PROOF. The critical verify the system dq O, dp =
degenerated
points of function
d2q 0 dp2 =
viz. [9Ap2(3Dp+d)-dCq2](9ap+2bq)(9ap-bq)+162acADp3q2
=
0
q : q(p,k)
71
A p ( 9 D p + 2 d ) (9ap+2bq) ( 9 a p - b q ) + a [ 9 A p 2 ( 3 D p + d ) - d C q 2] (18ap+bq)
+
+ 5 4 a c A D p 2 q 2 = 0. By obtain
the r e l a t i o n s
p. H e n c e tical
successively
the
(8).
functions
degenerated
eliminating Relation
q = q(p,k)
q
from
these
two
(8) I is an e q u a t i o n
may
h a ve
relations of d e g r e e
we 8 in
8 or 6 or 4 or 2 or no cri-
point.
PROPOSITION 4.
Equation $ ( p , q ) : 0 has no singular
points
in D
i f b2A - 3a2C > 0. PROOF. ly s a t i s f i e d .
In
its
singular
points,
equation
$(p,q) : 0 is i d e n t i c a l -
Then
243acADp3-dC(9ap+2bq)(9ap-bq)
= 0
9Ap2(3Dp+d)-dCq2](9ap+2bq)(9ap-bq)+162acADp3q2 This
system
is e q u i v a l e n t
: O.
to
gA~2~2(2b2+3ac)2p2 + 23~D[(2b2+3ac)(8b2A-15a2C)+9a3cC]p d
The
P l ,2=d
2 + (b A - 3 a 2 C ) ( 4 b 2 A - 3 a 2 C )
first
equation
+
= 0
has the r o o t s
-~[{2b2+3ac)(8b2A-15a2C)+9a3cC]± ~a2b2C2+4aC(2b2+3ac)(aC+cA ..... 6 A D ( 2 b 2 + 3ac) 2
F r o m the b2A - 3a2C > 0. The
condition
curves
¢(p,q)
that
the
= ¢(po,qo )
two
roots
are
are
negative,
graphically
we
represented
)
find
for
c, C > 0 in fig. 1 and for c, C < 0 in fig.2. The dotted q -- ~ b [ a
The
slope
line r e p r e s e n t s
the f u n c t i o n s
+ ~/3a(3a - 8~-~-p) cAD "~],
of the s t r a i g h t
6a2B + b2A 6a 3
]. - ~/3a ( 3a - o~-~--p)~CAD,
line q = mp is the s o l u t i o n
0 m 3 - ~Bm2Q - 243A 2E = " If E < b
q = ~b[a
9a then o < m < --6"
of the e q u a t i o n
72 For
a stress
(p,q)
belonging
to
the straight
line
q = mp,
the
soil sample becomes unstable.
O.
t
~//// ~ . "/
,; ,Y//" /
/ "k
1 2:
Fig.
g. U n d r a i n e d
(P = const.)
P
~2', \ ~ The curves @(p,q)
= ~(po,qo ) have the equation
ll~ p+a(d-c) b2 in
p3 27Ap 2- (C+D)q2 - d 93a3p3-27ab2pq2+2b3q 3 81ADp 3
a(d-C)l n
in p o ÷ ÷
Po3
^,3a3_3 2"ab 2 Po- f
27Ap2o-(C+D)q2
2+2b3_ 3 - d
Poqo
qo
tests
for c, C < 0.
81ADp 3
73 Their only points of maximum value are on the axis q = O. Fig. 3 provides a graphical representation of the curves ~(p,q) : = @(po,qo ) •
Fig.
3.
Curves
~(p,q)
= const.
f
\
X
We shall further consider the response of a material having the constitutive equation (I) in the case of some particular loading. PROPOSITION 5 .
stress
path T I :
-P=
Let
i" lq°+3Ti 13(2b-3a)
Po
L
be
(I)
T cI = c o n s t a n t .
the
Then,
constitutive
((b-3a)q-9aT~
lq+3T I
equation
and
the
in the domain D, we have
4(b-3a)
b-3a)qo-9aT 1
. t((3a+2b)q+9aTi t(3a+2b)~ 6b'~:Ti 3a+2b)qo+9aT~
)
"
f" ~(b2-ac) ( I I ] 3A-C ~ I q+3Ti)2 • exp '~- b2 d q+3T1c - qo+3T cI + ~
I
]+
c2 (qo+3T1)
27C(TI)2 4CTI I~ + --~((q+3T~)3
o 6b 2T cI
(qo+3T1)31 c )_
~ + 3 T cI
+11((.~,a 1 q+3Ti) 2 where
e : D 3 - D I.
((q+3T1 ........Ic)4 - (qo+3Ti)41)~,
4AD
- _----~-E_ cI l(b_3a)q_9aT
t
I(3a+2b)qo+9aT I I
1(
T c
3 (qo+3T1) 2) - ~
......
1
(q+3Ti)3
1 (qo+3T1) 3)'
(9)
+
74
PROOF.
For an axial-symmetrical
2TI + T3 3 '
P c
Then
T 1 = p- ,
c q = T3-TI'
T 3 = p+
,
loading
we have J
I D = 2D1+D3,
DI =
ID-~ 3 '
e = D3-D I. ID+2C 3 '
D3-
$ : 2T D1 ÷
2 • + T3D 3 = pI D + ~qc. Introducing
these relations
into
(5) we get
[(3a+2b)q+9aT~][(3a-b )q+9aT1]-6acqT c cI P
(q+3Ti)2[(3a+2b)q+9aTi][(3a_b)q+9aT1
]
3A(q+3TI)2-Cq(q-6TI) 1 +
(10)
AD(q+3TI)5
27aTi
c=q
q+3Ti)[(3a+2b)q+9aT1][(3a-b)q+9aT By integrating the
relation
points
the
q : GI(q)
(10)
I]
them we find the expressions that
solutions
the of
function the
p = p(q)
equation
(9). has
of
the
One
as
finds
its
5th
degree
- dCq(q_6Ti)]+18acADTiq(q+3Ti) for
c, C > 0
llm GI(q) ~-~
interval
(O,ql) , whilst
in this
interval.
the
(11)
< 0,
lim GI(q) ~ q2
function
p = p(q)
For
c, C > 0 this
root,
(2)
if G1(q)
curve
has
= 0 has
(3)
if G1(q)
= 0 has one positive
val
(q2,ql),
(4)
roots
in interval
negative
roots
if
< 0,
q2 = one at
lim GI(q) ~ 0 9aT I 3a+2b real
least
If c, C < 0, the function p = p(q)
one critical point in the interval (q2,0). The curve p = p(q) has been graphically real
G1(q)
(q2,ql),
in interval
= 0 (5)
plotted
the
shape
(I)
three
Foots
in the
and two negative has
three
if G1(q)
(q2,ql).
2 -
3
9aT I lim GI(q) > 0, lim G1(q) > 0, where ql - b-3a' ql q+~ lows that the equation (11) will have at least point
in
= 0, where
G1(q) : [(3a+2b)q+9aT~][(b-3a)q-9aT1][3AD(q+3T1)3+3dA(q+3T~)
Since
from
critical
positive
< 0,
' it fol-
root one
in the critical
has at least
in fig.4a.
if G1(q)
= 0 has
interval
roots and
in the two
= 0 has one positive
a
(0,ql) , inter-
negative and
four
75 For
c, C < 0 the curves
drawn. The dilatancy. as
stresses
The relation critical points
with
(I'),
(2'),
GI(q) = 0
(3'),
are
(4'),
related
to
(5')
have been
the
material
(10) 2 makes obvious that the function c = e(q) has the solutions of the third degree equation in q
G2(q) = O, where G2(q) = 54aAT~(q+3T~)3+(q-6T~)[(3a+2b)q+9aT~][(b-3a)q-9aT~]. The equation G~(q) : 0 has the positive roots e
TI
[-162aAT~+b(4b-3a)
±
qi,2 = 54aAT~+ (3a+2b) (b-3a) ±A'162abAT~(14b-9a)+16b4-60ab3-99a2b2+405a3b+272a
4]
which occur if
C
TI
O, q+q2 lows that in the
lim G2(q) > O, l i m G 2 ( q ) > O, G~(q I) < 0, it folq+O q÷ql plot of the function a = E(q) (fig.4b), the curve
(I") will occur if G2(q ~) > 0, while
(2") when G2(q *) I < 0
,,q
~-~
4~
Fig.
4a.
Curves
p = p(q)
for
T 1 = const.
Fig.
4b.
Curves c = c(q) T 1 = const.
for
76 REMARK. The stress path T I : TcI = constant responds to the "triaxial al compresion" experiments. PROPOSITIOII 6. the
stress
path
T3 :
Let Tc 3 :
us
take
the
constant.
constitutive
Then,
in
the
for q > 0 corequation
(I)
domain D we
and
shall
have
p S]2qo-3T~ 13(3a+b)12 (b-3a)q+gaT ~ (b-3a) Po= \12q-3T~ ~'(b-3a)qo+9aT ~
)ac
(6a+b) qo-9aT ~
.exp~ (b2-3ac) ( I b2d 2q-3T e3 CT~ ('(2q_3T3) Ic 3 + A--~-
I ) 12A-C I 8--'8-A-D-( 2q_3T~)2 2qo-3T~ (
I T c 2)+ (2qo-3 3 )
27C(T~)2 ]) (2qo_3T~)I 3 )+ 16AD ('(2q_13T~)4 (2qoZ3T~)4 ..... (12)
%+ 3bT31"#12q 12(b-3a) qo+9aT3 ~ u-3T$ ~ I
I
(6a+b) qo-9aT~ ~ I " l(6a+b)q-9aT~ I(6a+b).j - ~A((2q_3T~)2
_~,u(
........ I (2q-3T~) 3
I
C
I
I (2qo_3T~)2")
).
(2qo-3T~)3
e the equation of the stress path is p = PROOF• If T 3 = T3, 3T~ - 2q • From the relations (5) we get 6-[ (6a+b)q-9aT~][2(b-3a)q+9aT~]+9acT~q I~ = ~i .(2q-3T~)2[ ... (6a+b)q-9aT~][2( b-3a)q+9aT~ ] +2
3A(2q-3T)2-Cq(q+3 )) AD(2q_3T~)5
~%(
27aT~ : q 2q-3T3) C [ (6a+b)q-9aT~ ][2(b-3a)q+9aT~ ] + A(2q_3T~)t ~ " By integration we obtain (12).
(13)
77
The
functions
p = p(q)
5a and fig. 5b. One o b t a i n s and
(I'),
(2'),
(3'),
and
¢ = E(q)
the c u r v e s
(4'),
(5')
(I),
have
(2),
been
(3),
plotted
(4),
in
(5) for
fig.
c, C > 0
for c, C < 0.
,~t-~ Fig.
5a.
Curves
REMARK ponds
for
T 3 = ct.
Fig.
The
stress
path
T 3 = T c3 = const,
1.
to " t r i a x i a l REMARK
curves
shown
5b
q < 0,
for
p = p(q)
2.
extension" For
in fig. the
joint
4b
¢ = ~(q)
for
q < 0
will
look
for
corres-
experiments.
a cyclic 4a,
5b. Curves T 3 = ct.
loading,
for
these
q > 0 and
occurring
in point
curves
like
the
like
those shown in fig. 5a, e e (p = T I = T 3, q = 0). F r o m
Y ~t{b-3d Fig. 6a. Curves p = p(q) for cyclic loading q C [-qo,qo ] .
Fig. 6b. Curves E = ¢(q) cyclic loading q C [-qo,qo
for ] •
78
the relations (10) and (13) we notice that this joint is reached with a continuous derivative for the curves e : e(q) and a discontinuous one for the curves p = p(q). For a cyclic loading
0, t3=t I Assuming
that
constitutive :
the
mechanical
behaviour
of
soils
is
process
Pn
described
by the
equation
} #(n)X(P n ) n:1
where X(P n ) :
is
the
~0
characteristic
'
(P'q)
¢ Pn
,
(p,q)
¢
function
of
the
expression resulting from the equation ~i(I)' 8i(I) for the unloading~ processes, for reloading processes and ~ 3 ) •
while
~
is
the
(10) with the coefficients the coefficients ~k2)i" "' ~i
~(3) for loading processes
' Pi
The initial stress state for a process final stress state of the previous process.
will
be
equal
to
the
79 For processes
@(p,q) we shall
: ~(po,qo ) assume
(~)(2)
REMARK. the
tensor
)(3)
In drained
of effective
pressure).
loading, stress
If the undrained
maintains
constant
its
shape
in
various
: (_d.~)(2) : (--..-:-) d-c
the
while
stress
tensor
in undrained
will
loading
(the tensor of effective loading
total
mass
(3) (3)
(c~___~D)(~)(.q~_:)(2)(c~___~D).
C+D
to the tensor of total stress which
preserve
d-eb : (_~)(1)
a a (I) s:(~) :I~J~(2) :I~) ( 3 ) ;
d d (~)
to
that
be equal
to
it is equal
stress minus
pore
to the stress
path
confines
itself
density,
then the pore
pressure
is
zero and the tensor of effective stress equals the tensor of total stress. DEFINITION. under
undrained
to zero,
We
the whole
The
shall
cyclic
loading
undrained
unloading,..,
plotted
say
loading
that
a
sand
if the tensor
sample
to
liquefy
stress
tends
being taken over by pore pressure.
cyclic
test
of
loading,
unloading,
in fig. 7 will have the equations
¢(3)(p,q)
: ¢(3)(Po,0) '
q g [0,qo]
¢(1)(p,q)
: ¢(1)(pl,qo),
q e [O,qo] ,
q < 0
¢(2)(p,q)
= ¢(2)(p2,_qo) ' q ¢ [_qo,0],
q < 0
¢(1)(p,q)
= ¢(1)(p3,qo),
q ¢ [-qo,0],
q > 0
@(2)(p,q)
= ¢(2)(p4,_qo) ' q e [0,qo] ,
q > 0
q %
Fig. 7. Stress path for a cyclic undrained test
tends
of effective
m
reloading,
80
Owing
to
the
shape
change
of
curves
~(p,q)
= censt.,
one noti-
ces a steady decrease of effective pressure p.
5. C O M P A R I S O N
WITH E X P E R I M E N T A L
DATA
I) Constant density curves plotted in fig. I. (g for c, C > O, adC Po < 3-c-~ ) agree with the experimental results for undrained tests on Fuji
River
sand
fig.3,5,6),
(Nova,
loose sand
3,
fig.
13.6),
(Thurairajah,
dense
2) Constant density curves plotted with
the
experimental (Nova,
data
ated
kaolin
fig.
13.12) and Weald Clay
3,
3) The "Yield imental
results
for
fig.13.11),
a
in fig.2
for undrained
test
plotted
normally
(Thurairajah,
4,
(for c, C < O) agree
on a n o r m a l l y
overconsolidated
(Mroz, Norris,
function"
sand
4, fig.4.7).
kaolin
5, fig. 8.
(Nova,
3,
10).
in fig. 3 agrees with
consolidated
consolid-
kaolin
the exper-
(Nova,
3,
fig.
13.3). 4)
c T I = TI,
For
(c, C < 0)
agree
with
the
curves
the
(I'),
5) For T I = T~,
sand (Nova,
results
the curves
kaolin (I'')
cell
for
in a
(Nova,
fig.
4a,
constant
3, fig.
13.4).
(c, C > O) agree with
pressure
4b
cell
test on a Fuji
the
River
3, fig.13.7).
6) For T I = T cI < T3 ' curves
(2),
for a constant
plotted
results
pressure test on a normally consolidated
experimental
(I'')
experimental
(11) , (I~)
the experimental on dense sand
T3 = T c 3 < T I in figs.
for loading data
and
for drained
(Thurairajah,
(12) , (2~) triaxial
6a,
6b
(c, C > 0, the
for u n l o a d i n g
agree
with
compression-extension
tests
of c o h e s i o n l e s s
if c,
4, fig.1.2).
CONCLUSION
I) Our model
descibes
C > 0 and of cohesive dilatancy
soils
the behaviour if c, C < 0.
It
involves
The
emphasis
falls
on
the
importance
the initial stress and strain state (Po' qo' 3) The occurrence the
the occurrence
of
in c o h e s i o n l e s s soils.
2)
in
soils
shape
of
of instability
unloading
and
of
stress
history
and
Po' ~o respectively).
points accounts
reloading
curves
the
of
with
for
the change
respect
to
the
initial stress state. 4) curves rence
The
for of
materials.
sharp
the
the
small
change
in
values
of mean
liquefaction
phenomenon
shape stress
unloading
p accounts
in the case
and for
of some
reloading the occur-
cohesionless
81
REFERENCES
I.
L. Dr~gu~in, A 511, 1981.
hypoelastic
2.
N. Cristeseu, L. Dr~gu~in, On the stability with respect constitutive parameters, Rev.Roumaine Math. Pures Appl., 833,1984.
3.
R. Hova, A constitutive model for soil under monotonic and cyclic loading, Soil Mechanics-Transient and Cyclic Loads, 343, 1982.
4.
A. T h u r a i r a j a h ,
5.
Proc. 8th Int. Conf. Soil.Mech. Found. Enging. 1.2,439,1973. Z. Mroz, V.A.Norris, Elastoplastic and Viscoplastic constitutive models for soils with application to cyclic loading, Soil Mechanics-Transient and Cyclic Loads, 173, 1982.
Shear
model
behaviour
for
of
soils,
sand
Int. J.Enging
under
stress
Sci.19,
to the 29,10,
reversal,
THE
KINEMATICS
OF
SELF-SIMILAR
IN M O H R - C O U L O M B
PLANE
PENETRATION
GRANULAR
PROBLEMS
MATERIALS
R. B u t t e r f i e l d
U n i v e r s i t y of Southampton,
i.
INTRODUCTION
Throughout penetrated
to
angle
(#),
shear
and
and
the
this
be
a
such
point
lines are
(1931)
the
can
develop by
on
the
defined
material
continuum, planes
equation are
and Harkness'
on
being
friction which
the
velocity
'slip-line'
(1971)
relative
to
in velocity the
slip
which
line
and
generalisation
: "As successive m a t e r i a l points
any change
the
T = C + ~tan#
also
independently on either
statement
next,
assume
Mohr-Coulomb
so
is B u t t e r f i e l d
the
shall
related
Slip can occur
are considered and
we
characteristics
the kinematic model
a slip-line
slip
stresses
stress
of Geiringers'
paper
rigid-plastic,
that
direct
characteristics.
one
U.K.
occurs
field,
along
between
is
in
the
direction of the c o n j u g a t e slip-line". When extensive
a plane, bed
of
wedge-shaped
material
there
body is displaced are
three
vertically
distinct
into an
categories
p e n e t r a t i o n problem of interest.
2. T H E
INCREMENTAL
Fig.l(a) plest for
case
a
a
a
where lifted
the
slip-line
the
surface.
ground
locally smooth
field
This
_
I
A_
is
at an angle
WEDGE
i ~
B
~0o ~
(a)
is
to cases
surface
and
body
surchar-
in Figs.l(b,c)
OF A BURIED
sim-
wedge-shaped
horizontal,
'ground'
extended
for
of
smooth,
beneath ged,
depicts
DISPLACEMENT
up-
A
~i $'f
~
(p),
rough-faced
wedges respectively.
which
The
general
the
wedge-face
case,
in
friction
Figure
1.
(a),
(b).
B
of
84
angle
(6)
is
in Fig.l(d) define
B
0 < 6 < ~,
which
symbols
is
serves
used
shown
also
to
elsewhere
in
the paper. For angle
a
(8),
given ~,
statically field such
can that
ontal Figure
s £ = cos8
1.
(c),
(d).
that,
theorem
quoted
above
be
B
on
lies
when 6
BB',
the
~
= @
(i)
us to c o n s t r u c t
a con-
velocity for these
as
sketched
Fig.2(a).
fol-
lows
that
from this power
has
been
and
ensured the
incremen-
v
tal
volume
erial
ly
matby
vertical-
downwards
equal
to
is
that
up-
lifted
by
form
displacement
the
uni-
of
AB
Such
consistent
dographs
(Fig.2b).
(for
tical
be
ho-
iden-
slip-line
fields) Z.
of
displaced
AD moving
Figure
of
dissipation
that
~, t---t1
It
immediately
positive
~
in
- p
in
A
is
ensuring
= 0
cases
HOOOGRAPH
horiz-
which to
sistent
(o.)
a
slip-line
hodograph
B
semi-
values
constructed
equivalent
allows
p
admissable
_ c o s ( 4 5 ° - ~/2) -sir&0 -exp(~2 -tar~ ) ; cos(45 ° + ~/2)
The kinematic
wedge
and
always
surface
effect
6
can
drawn
for
ating
materials
which
the
cy angle V
also dilin
dilatan> 0 by
85
extending
the
increments
kinematic
should
(Butterfield
be
the m a t e r i a l
and the h o d o g r a p h more
Fig.3 full
Thus
illustrates solution
= 30 ° ,
with
the
for e =
# = 42 ° ,
= 12.5 °
and
slip-line
in
Fig.3(a),
hodograph Fig.3(b)
dilating
zone
become
curved
ing
an
simple
and
ABC)
which,
in
and
this
CONTINUOUS
this
tail,
see
~ values
wedge is
will
extended
DA
and
example,
be
OF
as p o i n t s
applicable
A FINITE
(possibly
deeply
is to
axis AB
value of the top a p e x - a n g l e For
cannot
AB map
displacement,
along
AB
becomes
to
a
the a
further
WEDGE
incorporating
submerged
and
not be a k i n e m a t i c a l l y
question
on
the
PENETRATION
the
'penetrometer'
surface
after
solution
below)
model,
be
free
3.
of the wedge.
DEEP
case
obvious can
the
Therefore,
displacement
material
the
Figure
along
it.
surface
solutions along
ki
CB
the
of p a r t i c l e s A'B'
An
A~
the velo-
incremental
shaped
B
lead-
in
for example,
In
field
'expanded'
hodograph
3.
the slip-line
(outside
the Rankine
curved
(Y > 0) both
and
All
slip-lines
curve
Fig.2(c).
(v = 21 ° )
Fig.3(c).
cities
characteristics,
material
hodograph
to
velocity
A
(v =
in
the
all
,,
erial
a
has weight
HOOOOPJ~PH
mat-
in
to
that
1971).
~ =
the n o n - d i l a t i n g
= 0)
v
require
p = 3°
the
field
at
to
0~-
and
1972).
above
be-
complex
(Butterfield Andrawes,
inclined
and Harkness,
When
come
statement
then
whether
encompass (Fig.4). (v has
to be
(8) between
when 6 = 0, via
this This
the
not
problem, turn,
zero!),
AB and
suitably
depth,
relevant
or
in
a
the with
for
our
previous B
located
specified
establishes
the p e n e t r o m e t e r
the relationship,
for
parameter.
e,
a unique axis.
86
sinS-exp(~.tan¢)
Fig.4(a)
shows
= s i n % - S i n ( 4 5 ~ - ~/2} ; sin(45 ° + ¢/2) the
slip-line
field
for
YI
and
Last,
1983)
together
hodograph
which
sistent the of
volume AD
sing AB,
i Figure
in i.e.
so
at
be
a
ditions
which
AB
is
%~\\
cros-
remains
straXY
to
AB,
penetrometer AB
surface these
preserve
the
the
which
can
(in
this
latter
con-
geometry
by the solid t
•
de-
crucially,
parallel
solid
the void o c c u p i e d
void
so with uni-
along
is
that ahead
displacement
does
the
It
con-
material
and
is sliding
a
confirms
each
that
to
smooth).
(Butterfield with
displaced
the
hodograph
relative
therefore
~.
AB that
Additionally,
the
(2)
equal-volume
as it moves,
material
case
the
and
velocity
ight.
a case
material
behind
increment
form
such
of
fills
veloped
g
= 90°+B+0
of
body and |
t
t__
X
• x',',,xx\,,, |xXxX'X~kX\
, ~ X\
,
,
,
{
. . . . . .
t
t
t
tt It ~titt
I d
t
!
t|
"]
i-
,,
,
\~.~tlY//
/ /, ,
I
/ I
i
i
t
E
f ,t,t
t t t t JJ_L,t (el
~ t / t~, t, ,
~ t ,t ,t,
OlSPLACEHENT SCAL£ O ~0 20 38
Figure 5. (a) Displacement resultant calculated from the hodograph presented by Butterfield and Last (1983) (~ = 4 2 ° and PEN = 6 . 0 n ~ ) . (b) Displacement resultant vectors (D/B = Z0.0, e = . 5 Z a n d PEN = 6 . 0 n ~ . (c) Displacement resultant vectors. Stationary probe (D/B=Z0.0, e=0.62 a n d P E N =6 . 0 ram).
87
thereby
validate It
by
is also
subtracting
the
the s t e a d y - s t a t e
velocity
stream
of
6 > 0
can
of
interest
its
velocity
origin
to
frictional be
examples.
The
Fig.5(a)
shows
X
flowing
streamlines
that,
from
for
the
this
velocity
fix
the p e n e t r o m e t e r
hodograph
the
past
into
if we
the
Fig.4b)
incorporated
the
to note (u)
in
fluid
solution.
solution a
smooth
are
becomes
as
in
the
displayed
vectors
derived
those
measured
transfers that
for
diamond-shaped
solution
case
(which
from
a
pier.
previous
in
Fig.5(c).
the
Fig.4(b)
O
hodograph model
(% = 42 )
penetrometer
and
test
Fig.5(b) in a dense
bed of sand
4. T H E S E L F - S I M I L A R P E N E T R A T I O N O F A N
The of
a
third
set
wedge-shaped
will
clearly
have
that
p
will
not
surface
will
have
of
body
solutions
concerns
from
surface
something now
be
the
in common
arbitrary
to satisfy,
at least,
(Mahmoud,
on
a
1985).
'INFINITE' W E D G E
the of
with
since
experimentally
continuous
the
those
the
bed. of
penetration
Such
solutions
Section
geometry
of
the c o n d i t i o n
2,
the
that
except
uplifted
the TOTAL
Figure 6. volume
of
equals
the
triangle
material TOTAL
of
by
that
necessitates cos(0 The condition
et
al.
the
(1947)
above
such
the
(i.e.
onset that
of the
motion, area
of
Fig.6a). the
# = 0,
with
B
smooth
on
the
wedge
material
case
and
surface,
that
= cos~;
smooth
from
material
ABF,
studied
+ sin~)
equivalent,
wedge,
requirement,
a unique p value + p)(I
the
uplifted
DEF = that of triangle
Hill showed
displaced
volume
wedge,
p = 8 - ~ non-dilating
•
(3) frictional
material
is that,
cos(0+p) (l+f-sin~)
= cos~
- (l-f2)-sin2O; 2f
with f = cos(45 ° - ~/2) -exp (~ tan% ) cos (45 ° + #/2)
p = 0-~2
(4)
88
This Shield
solution
(1953)
should
which
be
related
distinguished
to
a
smooth,
from
that
dilating,
published
by
associated-flow
model of M o h r - C o u l o m b material. However, have
the
that,
kinematic
of
the slip-line
at
all
exactly
scaled
problem
(with
by
the self-similar
additional
geometry 3)
for
Hill
et
stages
of
and
If we
consider
is s, a typical point velocity
v
(Hill
al.,
is
et
now
then
located
define
in which
penetration
following case
the
stage
scaled
everywhere
the
s
dd~tt =
invariant
fields
shall
Fig.6a) is
was
an
be
Such
first
a
solved
extension
of
his
with
the wedge
process typical
a suitably
by
a
point
the
ratio
wedge,
and
'unit
l:s,
velocity
which
must
a
diagram'
in this diagram
determined
in such a unit diagram, in
penetration
is located by r and moves with
whole
invariant during
on
the
self-similar).
in which
s = i, our
by p and moves
that its g e o m e t r y remains For
the
slip-line
(i.e.
material
in the m a t e r i a l
of all points
to
material weight and dilatancy.
the general
can
1947)
The v e l o c i t i e s any
we
(analogous
the
other
weightless
(1947)
al.
each
solution to include friction,
p e n e t r a t i o n problem we
in the s t e a d y - s t a t e p r o b l e m of Section
penetration, of
# = 0 and
requirement
field
replicas
continuous
u.
represents
therefore
ensure
the motion. in
the
supporting
medium,
we
have, r=s-p and hence dr = W = d-~
ds + p" ~-~
ds
p-
~-~
+
S-
u
in our unit diagram s = 1 and therefore,
u
ds
= v-
We
p-~-~
can
also,
without
loss
of
generality,
specify
the
wedge
ds velocity, d-t ' to be unity whence, u
=
The display v
v
-
p;
'unit for
any
point
superimpose same
in
it
'unit' follows
vectors v and p, Fig.7b. preserved
ds
~-~
=
1
for
within
(5)
the it.
wedge-medium
Fig.6c
shows
system
such
will
then
a hodograph
for
field of Fig.6b.
We now to the
=
hodograph'
all points
the slip-line
drawn
s
then
not
only
the unit hodograph on the unit diagram, scale, from
Fig.7a,
equation
If the g e o m e t r y will
points
on (5) of
within
which as
the
the
value
difference
the unit d i a g r a m it
corresponding
of
both u
for
between is to be to v = 0
89
move
radially
points
towards
along
the
local tangent,
the c o o r d i n a t e origin
free
surface
AB
must
(with u = -I)) but also all
move
in the
direction
of
their
Fig.7c. X
::~A
UHIT DIAORAM
O
T I
~Q
(b)
-_
×
A
~(P)
--I
(c)
PART OF UNIT DIAORAH
Figure Since same on
in
velocity
AB
produced.
the g e o m e t r y be
the
of Fig.7a
correct problem
and
solution
It We
is
important
this c o n d i t i o n (4)
fields
the
(6),
u(AB)
requires
and
in Figs.
continuous
AB
that,
unit
6(a,b)
particles
with
and
in
the
to lie
again 8, #
the
penetration,
of
move
and X has
= OX - p (AB).
therefore
shown
trajectories
along boundary
From and
diagram,
7(a)
are
a
self-similarity the
unit
diagram
to note
how such
trajectories
'focus'
on
their
images in the unit hodograph.
now
is no
to
points
equation
equation
Typical
all
in Fig.7(d).
corresponding wedge
by
case
to be a straight
from
slip-line
posed.
are sketched
has
Whence,
interrelated
hodograph
present
(OX), AB
7.
extend
longer
this
smooth
solution (~ > 0)
to
and
include
the
the m a t e r i a l
case has
in which
weight
the
(y > 0).
90 The
~ > 0
changes
requirement
the
(Fig.6b).
angle
The
does
not
at which
inclusion
the
of
introduce
any
new
slip-lines
meet
the
material
weight
does,
ideas, face
it
of
the wedge
however,
radically
affect
the
similar
self-
solution.
Whereas
it will resemble
that
shown
in Fig.3
self-
be
can
such
an
if
free
1.
longer
plane.
precise
form
is,
surface
of
is
of AB) the
only when
image
of
process.
The
produce
the tangent
P,
self-similarity
well
at
be
P'
at any point
in
preserved.
salient
a solution
features
the
is such
any
unit
clearly a
and
the
met-
gener-
assumed
(P) along AB passes
superimposed
This of
for
shape through
hodograph,
a
trial
solution
are
AB not
initially
(although
no The
of
hods used to equally
the
course,
known
will
with
'expanded'
1
ate Fig.3
only
preserved
hodograph
8.
cle-
arly
similarity
Figure
merely
will
and
error
sketched
in
Fig.8. Fig.9
shows
accurately 90 60
-~. A ~ ....-
surface obtained
!
B
a
an
recorded profile driving
by
steel
wedge
(0 =
O
-30 -60
=30 ) into a bed of dilatant, brass rods i
(~=25 °) (1970).
D
It
Andrawes is en-
tirely plausible
2~0
5
corresponding -5
that
tangents to this curve will pass through in
a
unit
points
hodograph
of the form described above and a tentative
Figure surface
9. H o d o g r a p h profile
and
sketch measured vertical displacement
contours.
solution
is sketched
91
in the figure. Measured about are
7%
of
seen
to
displacement
the
contours
penetration
agree
(for a d i s p l a c e m e n t
depth)
are
plotted
in
the
with
the
predictions
of
reasonably
increment of figure.
even
These
the
very
crude hodograph. It
is
incorporated example
solely
explained
the
around
admissable
the
steady-state
However,
the
because
flow
bounding
systems
3,
a
of
u
single
the hodograph
intimately
coupled
consistent
slip-line
velocity
from with
in self-similar
the
can
system
discontinuity
be (for
BCD)
as
the
and
field
can
Harkness,
is only
be
field
(Fig.7)
such valid
1971)
meaningful
slip-line
problems
specification
'free-surface',
slip-line
(Fig.4) and
angles
of
the kinematic a
(Butterfield
solution
dilatancy
regions
(1973).
it follows
in
and
values
different
different
and Harkness
that
in Figs.l
all
that in
fundamentally,
material
depicted
noting easily
in B u t t e r f i e l d
More of
worth quite
whereas
for u = 0.
geometries
there
as for
are
is a unique
field for each value of ~.
5. C O N C L U S I O N S
The
paper
self-similar, penetrating
distinguishes
planar
problems
rigid-plastic,
ticularly
the
kinematic
establish
the
validity
either of
steady-state
self-similar
fully
consistent
between of
Mohr-Coulomb boundary
of
any
incremental,
arbitrarily
materials.
conditions,
solutions
to
flow or self-similarity.
continuous solutions
penetration for
steady-state
rough,
and such
It
rigid
emphasises
hodographs, problems
In particular
and
wedges parwhich
involving
a new
study
is p r e s e n t e d which can generate
dilating,
Mohr-Coulomb
materials
with
weight.
6. R E F E R E N C E S
Andrawes, K.Z. (1970) A contribution to P l a n e Strain Model Testing of Granular Materials, Ph. D. T h e s i s , U n i v e r s i t y of Southampton, U.K. Butterfield, R. and Andrawes, K.Z. (1972) A C o n s i s t e n t A n a l y s i s of a Soil Cutting Problem, 4th. Intl. Conf. for Terrain Vehicle Systems, Stockholm. Butterfield, R. and Harkness, R.M. (1971) The Kinematics of M o h r - C o u lomb Materials, in Stress Strain Behaviour of Soils, Pub. G.T. Foulis. Butterfield, R. and Harkness, R.M. (1973) Idealised Granular Materials, Symp. P l a s t i c i t y and Soil Mechanics, Cambridge, U.K.
92
Butterfield, R. and Last, N.C. (1983) Continuous Penetration Testing in Granular Materials, a New Analytical Solution, Intl. Symp. on i n - s i t u Testing, Paris.
Mahmoud, A.M. (1985) Continuously penetrating bodies in granular dia, P h . D . Thesis, University of Southampton, U.K. Geiringer, H. (1931) Beitrag zum Vollstandigen abenen Plastizitas blem, Proc. 3rd Intl. Cong. App. Mech. Vol. 2, Stockholm. Hill, R., Lee E.H. and Tupper S.J. (1947) The tation of Ductile Materials, Proc. Roy. Shield, R.T. (1953) Mixed Boundary Quart. Appl. Math. V o l . I I .
Value
mePro-
Theory of Wedge IndenSoc. Series A, Vol.188.
Problems
in Soil
Mechanics,
SLIP S U R F A C E S
IN S O I L M E C H A N I C S
P. H a b i b L a b o r a t o i r e de M e c h a n i q u e des Solides (Joint L a b o r a t o r y E.P.-E.N.S.M.P.-E.N.P.C., A s s o c i a t e d with CNRS), Ecole P o l y t e c h n i q u e - P a l a i s e a u , France
Abstract. Isolated slip surfaces occur in softening soils, that is to say mainly stiff clays and dense sands. T h e y do n o t o c c u r for all plastic deformations. A mechanism of progressive development of discrete slip surfaces in a heterogeneous stress field is first described, in good agreement with actual physical observations. This mechanism makes it possible to analyse mechanical strength tests and to show that the validity of the shear test is especially assured for residual strength. For the triaxial test, the peak value is seen to have physical significance, but the softening slope is shown to be function of sample size, also residual strength is not correct when a localization of strains occurs. A correction is proposed. The occurence of slip surfaces questions the validity of classical formulae. Approximate practical corrections are proposed for bearing capacity of shallow foundations on sand and for active and passive earth pressures.
I. I N T R O D U C T I O N
The slip
surfaces
(Fig. l). theory del,
being
of
since
quasi-static
common
has
not
the
of
in
widely
soil
reported
heterogeneous
remains
observations
of
phenomenon been
disregards it
deformation
an
the
localization
important
physical are
hard
on
one
or
rock
mechanics
the
classical
and
several
deformation subject
but
phenomenon to
or
carry
of
out,
(Mana
dif-
the
ac-
soil
not
transparent. fact,
we
only
Practioners
surface
in
disappointing
is only
know
depth,
to
very
that
recently
the
tes of p r o g r e s s i o n
research
since
an the
of deep
a few data
slip
by
slip
drilling is
a
interfacing
perfectly.
of slip
of
accident,
observations
that
development
knowledge
after
rebond
themselves,
of the
have
operation,
tendency
surfaces
tics
very it
Plasticity
occurrence
emerge.
table
a
of
Nevertheless,
one,
In
slip
is
However,
1966).
ficult tual
localization
As
for
partial
have
surfaces
and
the
been
I to
a
have
a regret-
collected
of around
on
sometimes
isolated,
(1983)
they
and
progression and
Suemine
when
trenching
costly
surfaces
are
surfaces.
surfaces
of
slip
and
it
on the kineindicated
100m/h.
ra-
94
Figure
1. Slip lines in granite. surfaces in contact were opened by weathering,
The
Even tion,
as
for
orientation tion
of
are
lines
materialize of
about
deformed. initial
an
contradictory.
only
on the for
We
longer
no
soils,
configuration
know
is a certain
is p a r t i c u l a r l y
field
there was
rejects
that
whether
the
are
now
obviously
obvious two
test,
to the
reports
the
identification
One
reason
is
of
axes
are
slip
surface
scatter
after
the they
a strain
themselves to
the
one. in the
on Figure
later
the
this
that
reference
to relate
the
direcon
piece
conjugate
active
situa-
of a test
or to the s u b s e q u e n t
there
which
so
compression
Available
Indeed,
surface
accessible
in relation
difficulties.
lateral
and
triaxial
surfaces,
imprecise.
serious
geneous
caused
remains
elementary
or
slip
presents
one
of
uniaxial
sometimes
3-10%
This
a
quite
or several
stresses,
Moreover, lines.
apparently
example
of one
main
subject slip
for
Figure Z . Two f a m i l i e s of slip lines with reject on t h e f i r s t when the second one moved. Note the uncertain parallelism of the second family lines orientation.
2.
orientation
In an
families than
the
of slip
initially
of
slip
other.
homo-
surfaces, This
has
to form.
In addition
certain
surfaces
of
the
second
family
show
doubtful
95
parallelism,
somewhere
the two conjugate
around
families
15 °.
raises
On
Figure
complex
Figure 3. Scatter in orientations of slip surfaces in a granite rockmass. This Coulomb
dispersion
defines
the
tion of the
strict
function
its
bouring
up
If there
path
will
is
well
modest slip
the
It
almost
form.
elementary
is
quite
as
Landslide (B.R.G.M.
easy plane
strength
is
In
4.
failure
of
understand. the
facettes
a
calcula-
along
this
plane
obvious
that
the
as
the
of the material,
fact,
at photo).
to by
unfavourable
heterogeneity
scale,
but on in
problems
for
on active
surface
are
is a slight
small
the
of a certain incline.
planes
of
known,
remarkable,
of
orientation of
identification
failure
whose
critical
a slip
surface
mean
as a
neigh-
is
direction
surmade gives
orientation.
However,
situated
minimum
hesitatingly
of a series
the general
the
the
problems.
Figure Villerville
orientation
angle
inclined
plane. face
of
in
3
a as
raised
example, faults,
just
the
in other
as
This the
surfaces
epicentres
words,
as catastrophic,
building. much
that
by slip
on slip
Figure
spectacular
slip
are
of
earthquakes
surfaces.
4 shows accident
displacement
important.
is
the is about
It are
At a more
effect
of a
particularly one
metre,
96
whereas
the
slip
emergence
(Figure
5)
occurred
at
a distance
Figure
of about
5. Landslide
at
Villerville. Slip surface emergence (B.R.G.M. photo).
250
meters.
lized,
If
there
the
Finally, leul
1983,
with
the
or
with
zero
the
Desrues
occurs
the
others occur this
with
the
certain
case
correspond But faces for toe
for
example of
a
mean
occur,
All
debatable
loca-
(Duthil-
the
slip
lines
over
many
of d e f o r m a t i o n
Although
the
merge years,
(lines
study
interesting
stress are
or on this
or
and
the
loose
of
of
this
it is and
for
where
contrary, how
rocks
high
failure do not
difficult
state
the when
especially
1983).
where
occur,
they
rocks,
surfaces
the
are
stresses;
and
(Goguel,
materials
conti-
but not with
intermediate
overthrusting
a
ca-
surfaces
consider
for
soil
Sometimes,
under
If we an
with
slip
sands).
cases, in other
sands),
disappear
through
but
occurs
or dense
identified
cases
certain
example,
sands.
fields,
shows
For
clays
dense
well
in
surface,
resistance
muds
passes
are
there
landslines,
being
belived
surprise:
stresses
and g e o l o g i c a l
certain
pile.
(stiff
materials,
They
is
see how
of a slip
threshold
soils
transition form.
of
localization.
of m o d e r a t e l y
to faults
usually
the no
of
to the house.
it generates.
formation
moderate
surfaces
suggested?
the of
do
as was
we shall
with
brittle-ductile slip
(1970)
instead
surfaces
of the rates
difficult,
and
spread
no damage
problems,
lines,
source
(compressible
is
plane
first
exceeding
under
In stress
a
deformation
been
of slip
characteristic
very
is
had
practically
nature
consequences
There
observed
very
as Roscoe
seems
the important
ses,
been
1984).
lines
extension)
phenomenon
nuous
have
characteristic the
failure
deformation
would
slip
as under
problem
sur-
appear,
as the
becomes,
97
since at
the
one
the
criterion
and
mean
the
for slip
same
stress,
t~me,
the
surface
the
type
formation
constitutive
of
stress
must
take
equation
field,
into
of
and
the
account, material,
probably
boundary
conditions. We field
shall
before
first
studying
II. S L I P
SURFACES
Experience menon
in
a
material
the
constitutive
terial
is
to
stress
field:
hardening,
strictly
if
the
homogeneous
the
softening,
and
represented
indicate
the
stress
the
following
consitutive
deformation
homogeneous
6, w h i c h
a
FIELD
interpretation
characteristics
in Figure
in
i de n t i f y i n g
indicates
classical
never
happens
case.
contibuted
equation
The
the m e c h a n i c a l curves
has
indicates
surface.
what
IN A H O M O G E N E O U S
homogeneous
the
slip
examine
the general
is
there
then
by
of
homogeneous;
if
is formation
follows:
there
is
the
behaviour
pheno-
equation
the
slight
set
of
of a
real
ma-
scatter
of
stress-strain
of a series
o
of poten-
8 b
(c)
f
//
g
Figure tial
slip planes
tain
slip.
Let
through in
(c) An
an
increase
than
develop
before
the
there
plane.
stress
which
the test
contrary, exists
Under
which,
neighbouring
plane
a
hardening.
if
stress
around in
turn,
planes.
Even
failed
first,
~ it u n d e r g o e s
this
plane
can
generates if
it
the
seen
to
occur
increase
deformation
is
a cer-
only
is
less
extend
and
piece. the
plane
behaviour
where
the
curves greatest
show
a maximum
strength
is
(Figureached
the others. If
this
the
throughout On
re 7),
in
of
in d e f o r m a t i o n
in
near
Case
sample.
be the weakest increase
deformation
there
in a test
6.
the
plane.
Young's
deformation
This
modulus
brings of
a
soil
increases, about
a
is
much
the
stress
relaxation higher
at
in
begins all
to d e c r e a s e
the
unloading
test
than
in
pieces.
the
first
98
(,}
/
I
5 Figure loading now
modulus.
behave
there
like
nificance must
test
after be
of
blocks
curve
the maximum
replaced sand,
deformation
volumes
of
softening.
not
affected
which
slide
by
along
large
the
by
a
the
in F i g u r e
because
the
7 has no
slip
deformation
stress-displacement
diagram (Figure
longer
of the volumetric 8)
loses
its
maximum
replaced
by
the
of
perceptible
the
5
lume 8. Volume variation of a sand during failure (Triaxial test).
in the m o n o l i t h i c
blocks
the
must
curve
be
of AV
is
on
curve
on
not
after and
a slip
the as
localized
on
volume at
a
once
is
curve.
in the slip plane,
as soon as r e l a x a t i o n
it appears
other
be detected
is
stress-
physically
variation the
the
surface
the
maximum
the
a
~.
important
(since
develops
theless, are
of
strength
eded), can
as a func-
although
formation
and
sig-
triaxial
volume
remark
AV
AV
a
of d i s p l a c e m e n t
5
-strain
ceased
so
continuous.
significance
This
-
real
strain ~
because, ,
any
For
strength
function
J I
dense
planes,
is not
diagram.
variation
Figure
deformations
of deformation.
stress-strain
on dense
tion
the
rigid
is l o c a l i z a t i o n The
It
Then
7. C a s e
exce-
hand,
it
the
vo-
Never-
variations given
time
whereas
they
started.
99
III. SLIP S U R F A C E S
We will taking When
the
of
loading A,
a
solid
is
then
first
FIELD
in a n o n - u n i f o r m
subjected
increases,
criterion
in a point in ~
now examine what happens
example
the
failure
IN A N O N - H O M O G E N E O D S
to
any
stress
loading
field,
(Figure
9).
the
/
reached
in a small doma-
s u r r o u n d i n g the point A.
If this domain is s u f f i c i e n t l y small, the
stress
uniform mation is
field
there;
tinuous
deformation
if
and
con-
it undergoes
We will consider the case
slight
sical,
be a for-
if the body
softening,
of Soil M e c h a n i c s tly
considered
surfaces
to
hardening.
be
there will
of slip
subject
can
with
softening
for
elastoplastic
considered
as
a
a sufficienthe
clas-
solution
good
to
Figure 9 . C r o s s i n g
be
the criterion.
plasticity
approximation
of the problem studied *). Let Figure the
It
and
examine
9 and
straight
deformed. B.
us
extending line
is m a x i m u m
(d)
happening
in
front
(Figure
perpendicular
for
occurs
and
displacement Figure
is
The d e f o r m a t i o n
B a slip
lines
(a)
What
is greater
the
line
between
(e).
~(s)
The
and
to
(c)
the
slip
the
In
a along
half
the
of
defficiency
of
At
a
crack
passes the
increases
slip
surface
certain is
through
not
approaching
B.
which
Between crosses
B
towards are
plotted
on
the explanation,
but
it would
be
shear
A.
A
the
t(s)
corresponding
from
of
distance,
practically
(b) when
crack
AB
The
for the case where ~ ~ 0).
classical
constant
10). the
which
10 (assuming ~ = 0 to simplify
easy to generalize
the
for the line
lips
~
on
AB;
domain
elastoplastic
there ~
would
. In
in the AB crack
be
the
solution
correpondlng
case
of
plane marked
the
shear
would
shear
force
F
softening by the
there
shaded
is
area
be
in each a
shear
on figure
10, whose total value: AF = f (tmx - t(s))d-s AB an
upper
strength, segment
bound
of
tr
the
AB.
is
which
is
residual
Equilibrium
can
(tmx - tr)~ , where
tmx
shear
~
only
be
*) This would not generally be true Of s t r e n g t h after the maximum is very
strenght
and
ensured
by a
is
the
the
greatest
length
of
the
displacement
of
the
in Rock Mechanics important.
where
collapse
100
crack
tip
towards
distu r b a n c e
of
approximations
the
the of
right,
elastic
Figure
in
fracture
field
10,
the
mechanics
beyond
shaded
this,
areas
be
so
mode that
equal.
II
with
with
The
the
displace-
$
ment AF
Figure
lO. D i s p l a c e m e n t
A~
the
of
by
crack
bringing
displacement
tip
and
allows
additional
A~
shear
stress
near
compensation
strength
A~-t r.
a slip
of
the
An
upper
surface.
shear
deficiency
bound
of
the
is therefore:
or again: A~
tmx
~- < t
-I r
If the
the
softening
lengthening
is
10%.
of
resisting
dotted
This
area In
reaches
of
crack
mechanism the
the
is
increase
of Figure
the
corresponds
the
possible elastic
case,
boundary
movem e n t
the
slip
surface
by
on another
slip
surface.
This
bourhood
of
sibility
of
only
resist
the
restricted,
first,
resisting t . The r
since
equal is
failure
remains
of
if
the
it
not
is
to
to the shaded total,
mx' equilibrium
the
is
to
the
slip
surface
if
plastic
deformation
difficult
if
area.
However,
in the
capable
say
mechanism
the be
of 0.9 t
"ligament" that
preceding
may is
the
occurs.
allowing
strength
reestablished
stress,
yielding
and
deformation
trate
ensures
10a is at least
contrary free
only of
to a residual
which
blocks to
concen-
immediate imagine
t there, whereas the first surface mx o c c u r e n c e of a m u l t i t u d e of d i s c r e t e slip
the
neigh-
the can
posnow
surfaces
101
side
by
side
expected.
They
difficult
to
use
are
they
inside mass, back
can
be
will
be
see
to
yielded
they
the
lead
us
concept
of
quasi-homogeneous formation. plies
I
situated
the but
I
beca-
I
,~
com-
A
practical
experience. Figure
11
represents
multitude
of
L6ders
lines
surface
of
steel
at
Figure
which
is
a
lines.
of
condensation,
such
aluminlum in
following
the
discrete even
are to
L~ders
or mild
stage.
multiplicity
surely
have
distinct
yielding slip
of
slip
lines
which
which
occur
appear
immediately
field
under
Their
occurrence
on Figure
localized
families.
around
lines,
p r o g r e s s i v e l y widen
homogeneous
plastic
of
not
lines,
steel,
They then
the
double
more
two
Contrary
exceeded.
picture
lines
process
component
good
Lfiders
elongation
limitis
]Oa. Ultimate strength the ligament.
the
tunnel.
as
edge
ligament
stamped
plate,
section
$
a
discrete
a
I
de-
This
with
tmx tr
the
11 shows
a
but
are in
caused
ceratin
after
effect
that
the
by
a
metals
the elastic
to completely in
circular extensive
of
invade
a
hardening
shape
of
a
slip lines would
in
Other
examples are seen later. We
must
insist
progressive slip
line
also even
(or
if
this by
The
blocks.
punching
"blocks"
unique
slip
lines)
observation, is
sometimes
ultimate slice
spirals
assumptions
the
Rendulic accept
the m o v e m e n t
between
In fact, foundations
shows can
design
method,
indeed
extensive
failures,
a few
that
a
circle,
logarithmic
very
fact
of
approach
Fellenius
of
the
with
certain
intuitions.
rigid
of
correlates
masked
as
on
elongation
be
the practice or that
natural that
the
subjected
of
slope
Figure 11. Multitude of discrete L~ders lines in mild stamped steel.
moving to
large
deformations.
For
smaller
102
structures and
such
passive
sion the
of
earth
the
of
lead
beads
slip
following
from
family emerges the
just
it
been
stopped surface
Figure surface remains
1Z.
glass,
Slip
surface.
free
understand
development envelopes
a
and
of
the
progres-
a
of
scientists
the of
developa
mesh of
surface
etc..).
mesh in
of
plane
Grenoble of a mass
Figure
12,
foundation.
shows
punch,
the
follow
method,
is clearly
when
the
active
development
by Darve
at
in
research
to
recently
(1961)
with the
radiography
traced
Habib
a large
to
during which
and
under
It
many
deformation
surface
and
under
possible
principal
by
and
densimeter
mass,
walls,
of force
shown
dilatancy,
of a mesh
descreases
is
been
Scheebelli-Dantu
by Chazy
on the
(y
its
of
the
surfaces
displacement
intuition have
work
of slip
has
earth
a pane
retaining
identified
by
observation
Figure drawn
been
the
or
progression
techniques
in
behind
of rollers
the
surface
placed
photographic
foundations
length
has
different
the
deformation by
surface
surface
very
ment
surface
pressure,
slip
failure
using
as
the
where
visible
that
longest
on this
surface
that
development
the
is
the
figure
slip
appeared
a
that
approached.
other
they
of
surface
By
surfaces after
the
them all.
13a
and
13b
illustrate
formation
can
be
observed
some
and
cases
others
where where
isolated the
slip
deformation
quasi-homogeneous. The
case
of
mass
(Figure
13b)
the
influence
of
stresses
in
the
the d e v e l o p m e n t
expansion
or near the
the
of
range,
up to the free
circular
surface
ligament
elastic
the
which
of can
that surface
is
it
(Figure
resist to
cavity
say
or
within
13a) not
which
of an isolated
an
earth
clearly
shows
the
increase
allows, sllp
or
surface.
of
not,
103
///~//f/" t
Shallow hunch
Deep munch
Pile
////////~ Cylindrical Landslide
expansion
k ~ , ~
near the surface
~ / ~ ~
Cylindrical
expansion
at depth from from the Passive earth Active earth pressure pressure
surface Cylindrical contraction / / / / / / ) / / / / / / j
a- SLIP SURFACE b-HOMOGENEOUS Figure
13.
Different forces,
cases of deformation (the dark the light arrows displacements).
DEFORMATION
arrows
indicate
IV. D I R E C T S H E A R T E S T
A the
classical
rectilinear
cularly rather explain
the
during
the
remain
fixed
stress
in
mastered the
Casagrande
box
test.
into
disuse,
In general, in
direct
the the
main is
of the main The
stresses
It
shear
seems there
shear
stresses
triaxial
shear
the
controlled
without
direct
and is not known, test.
measuring with
test,
smallest
tensile
of test
fallen this.
way
shear
test.
whereas stresses,
a soil and
this
test
method
any
good
reasons
change
in the triaxial or sometimes
whereas
intermediate
the
has to
for the fact that
direction,
the
is
parti-
that
during
and hence
of
being
is criticized Also
variable
strength
displacement
test.
It
they
principal cannot
be
test it is equal to to the greatest
the deformations
are perhaps
in a not
104
always
homogeneous
horizontal leads
to
shear, is
faces a
not
the
often
the
edge
the
the
first
the
of
not
the
the
triaxial
the
teeth
test
pore
Finally,
is
on
piece.
pressure
although
apparatus
motives
box
often
stresses
varies
shear
not
during
cannot
The
are
the This
during
this
reason
undoubtedly
very
corresponds
earthworks
stresses
uniform.
attach
ensuring
test.
three
shear
main
of
which
of
a
because
less
than a shear machine...
extensive
main
maybe
boxes
triaxial
costly
in
direction
is
half
less
of
intermediate field
boxes,
acknowledged,
and
situation the
the
to
However,
At
of
the
quasi-impossibility
contrary
cumbersome
in
work
mastered
test
real
(Figure
for
goes and
14)
since
conditions.
excavation,
as
be
to
convincing
example,
forward.
the
The
deformation
however,
raises
a
6
Figure
certain
number
displacement) surface
in
of
failure
stress
If
with
which
a
clay),
we
for
a
displacement
box.
The
sllp
the
understand
and
since
the
that a
the
initial all we
the cannot
know
in
complete of
the
impossible which
is
the
is
the
shear
of curve
interpret
thickness
of
a
slip
course in
then
of
place
a
Casagrande
starting
is in slip
tr
typically
different the
of
residual
(or tmx and
reached
classical
by
dilatancy
to
in
is found
sometimes shown
f o r c e - box
identify
for a sand
maximum
erratic, This
to
maximum,
be defined
is
to
(shearing
stopped
a
millimeters
slope more
is
strength
back.
obtaining
curve
of d e f o r m a t i o n
can
dilatancy
at
test.
difficult
presents
the
few
the is test
area
curve
and Cr
of
plane
before
Finally,
modulus
Cmx
sometimes
movements
the
find
it
if
a lenticular
plane.
for
front,
and
shear
When
hardening,
box,
experimentation, a
Direct
problems.
shows the
14.
slip
at
the
swaying plane.
difficult terms
of
to slip
"surface"
it
105
must
be related. Torsion
15
we
have
cylinder
the
are
¢ = 0
a
crack
were
to occur,
place
(and
in
The
not
the
as the
of torsion nder
solid
if
horizontal
on
a
helicoid
of
¢ ~ 0).
of
the
e
-
two (a)
shows
if we
had
(b)
added
elastic
Figure
curve
IS.
Torsion
15a)
and
(Figure
the c y l i n d r i c a l of
the
15b).
the
rigid-plastic
Moreover,
test
piece
notched
test piece.
test
on the solid cyli-
(Figure
thickness
Figure
a
c,
take
curves
behaviour
On
on
This
a
comparison
together
tests
with
would
case
failure
experiment.
torsion
deformations it
along
plane
of wax.
of
clearer
two
of
Consequently,
localization
much of
test
material
hardening.
a
solid
The
made
is
results
horizontal a
thickness.
is
of
a by
pieces
as
cylinder
a
with
formed
zero
a
and
cylinder notch
of
plotted
coiled
test
curve
during
the
around
In
the
case
of
the
crack
was
practically
imperceptible
piece,
There
was
no
between
of
the
a
the
test
piece
slip
of
zero
generatrices in spirals.
rejection
before
notched
crack
tests,
the
the
on
both
the w e a k e n e d
sides
section
yielded.
torsion was
test,
infinitely
mediate value
of
of
immediately
towards
upper
the
slope box
initiating run
to mode
However,
initial
between
possible
corre s p o n d s
grande
from
of
on
the
the
the
half-box
the
shear
very front
middle
is
and
correspond
test
simple.
of
back
the
the
and
and
stress-strain
edges
test
to unequal
curve
of
the
test
The
erratic
of
towards
test
is not
in
torsion
follows
using
progression
of
piece
mode
of
the two
the
Casacracks
occurs;
tiltings
progression
imyield
by the
interpretation
piece. rates
the
effects.
crack shear
the
plane
the
piece
shear
the
direct the
II
at
generated
test
the
of
whereas
slip
after
by kinematic
test
mode
the
during
the
only
curve
of
progression
A
crack
of
hardening
periphery
obvious
the
occurred
of
kinetic
torsion
of
thickness
non-uniform
propagation,
analogy
becomes
the
made
since III
shape to
this
lips
the
movements
The
corresponds
yielding
the
since
Relative
in a d e f o r m a t i o n
Comparison
II.
normal
failure.
probably
progr e s s i o n the centre
was
small.
approach
very
rotation
which
they
of
according
the to
106
the
quality
the
stress-strain
this
of
the
yielding
Figure
10
shear
curve
and
to
filling
of
corresponds
not
the
stress
initial
just
distribution
to
any
Casagrande
box.
the
the
we
The
initial
irreversible
elasticity
test,
in
the
slope
of
progression
of
phenomenon.
can
produce
horizontal
a
plane
By
applying
diagram
(Figure
of
the
16).
The
representativeness this
diagram
conditions the I I I I
i l I
~
I 1
I t I I
I
......
l!i,.m.ntl
stress
teeth lower
are
1
The
mean
measured, soil.
but
coming the
it
There
progr e s s i o n
value does
of
failure
giving
producing (Figure
a
in
correspond
a
a
the
of
curves, is
only
this
define
value.
If
sample the
the
the
magnitude
a mean
we
test
the The
force
assume
zero
most
of
test.
thin of
that,
other after
cement,
that pieces
thickness
representative
the
t . r and
When the
diagram
S
in
shear
to find curve
two humps
Figure the
completely
linear
shear to
observe
certain
merges
stregth. 17. E x p e r i m e n t i n g
the two
we
linear
residual
out,
adapted
idealdirect
hand, a
the
give
othed
an
of
17). On
Figure
the
strength
in
increasingly
obviously
maybe
of
edges
the
would
the
in way
However,
maximum
effect box
the
is important.
all,
the
residual
a series
path
to
large
stress-strain
after
scale
very to
with
stress-strain
is,
obviously
effect
attacking
stress
exists
closer
is u n d e r t a k e n
interlocked
the
not
certainly
increasingly
test
of
the
porous
uniform
possible.
boxes
of
deformation
most
the
test
transmitting
plane
the
16. D i s t r i b u t i o n of shear in the failure plane of a direct shear test.
Figure
The and
at
with
the
piece.
slip
'
of
upper
aimed
t moan
of practical
increases
thickness
stones _~
to
will
strength
value
cracks
joint
in
shear
16
value
test
displa-
shear
with
the are of t r.
smot
mean The
is
perfectly
measuring
residual
107
V. THE T R I A X I A L Now
we must
a triaxial If
the
test
stress
plane
is
plane,
see
will
if the d e t e r m i n a t i o n
draw
field
is
constant.
Figure
TEST
the
same
uniform,
the
Accepting
the
adapted
to this
10 is
of m a x i m u m
criticism shear
as the stress
existence case
of
on
a
strength
linear a
point
18 and
by
test.
potential
weak
in F i g u r e
tmx
shear
slip
in
this
shows
that
7
m
initiatian
Figure the
18.
Progression of failure in a triaxial progressive development of the failure
deficiency
Failure this
in
should
is
much
experimentation weak
the
the
cannot brittle
occurs
be
supported
type
rocks
or
maximum
value
shear
is
test.
maximum
or
as
of
and
soon
base
halos,
limited
by
as
the
onset
and ligament.
occurs,
strength
and
to
the tests
are
in
this
plane This
for of
way
a
compliance
slip
any
notch.
slip
materials
the
perfectly really
starting
This and
the
not
of
triaxiai
progressively
crticism
at
explains
deterioration,
In
develops same
with
development
planes
with
compression. which
prone
measured
of
number
brittle
better
singularity.
as
uniaxial
this
therefore
in
development the
on
under
Certainly
value
a
observed
concrete
compression
the
near
successive
one
as
logical
accept
by
of
cone
more
situated
formation
failure
the
to
point
proba b l y
in
of
piece
is not so. It
a
strength
be
test plane.
as
test under
of
the
but
does
the
to
the
strength
carried
out
repetitive,
correspond
that
a as
of the material? Triaxial sure. in
a
the of
Test
pieces
routine base
a
test
with
triaxial
hooping.
slip
on
plane
This
short
test
slenderness test
so
also
(Figure
I).
pieces ratio
that
left A
the
the
were
between central
2 and
was
of
free
ratio
lower
make
were
used
remote
from
2.5
part
possibility
slenderness
to
development than
1.5
is
108
acceptable plane
is
Paris
inclined
failure were
for
plane
prevent
the
least
the
test
test
Sannoisian
30 ° on with
the
the no
pieces.
where
clay test
on
researchers
for
for
consists
sand grease
soils,
concretes
between
19a);
have
of placing the
the
This
endeavoured and
rocks.
a thin
test
failure
pieces axis.
the
If
nothing
it
would
that
to h a r d e n i n g
stress-strain
is
and
not
to
The
sheet
piece
solution
this or at
curve
of
build
solution
of rubber the
friction-free we
have
resting
supporting
perfect,
but
chosen
on a film
steel
point
represents
a
good
•/
test piece rubber membrane ~ film e! grease / I sheath
ol .-: ..........-
i :) :i F •
....~..:-~,
!
::::- :) ../.,
.
.
(b)
-~ - / / : . / / / / / / / . / ' / ' / ~
0
test
demonstrate
susceptible
maximum
the
piece
friction,
We will
to m a t e r i a l s
before
pieces
prone to softening.
supports
(Figure
about
supports
be limited part
Many
of
impose
clay
45 °. For
at
use of shorter
must
materials
almost
inclined
to
statement to
at
is
possible
Sparnacian
le)
Figure
19.
Triaxial
test
on
a
short
test
piece.
a p p r o x i m a t i o n of a normal stress at the contact surface. The
results
short
sand
forms
round
the test
test the
(Figure
obtained
piece,
the
initial 19b),
were
as follows:
material
cylinder
when
is
which
during
pushed probably
the deformation
the crushing
sideways
and
disturbs
exceeds
a
the
of a bulge
end
15 or 20%.
In
of the
case of dense sand, a great number of slip lines appear on the bulge. The s t r e s s - s t r a i n softening
for
pieces
the
of
extensive same
accompanied
by
localization
of
these
tests
maximum
was
strength
curves of short deformation,
density
an
present
isolated
deformation. the
following
of long test
a
slip The
samples
whereas
curves
maximum
followed
plane,
in
particularly
quantitative pieces
of dense
the
was
sand
by
other
equal to
the
test
softening, words
interesting
result:
show no
for long
with
aspect
value
the stage
of
of
the
value
for
the short test piece (Figure 20). Crushing clay
of
uniaxial
low
tests
on short
plasticity
compression
this
taken
test from
material
pieces
were
sampling relevated
also
at
carried
great
localization
out on a
depth. of
Under
deforma-
109
/
0' 1 _ o 3
~mx: 42 o
~
short
sample
long sample
Figure
ZO.
deformation
Triaxial
on a failure
Figure Z1. Localization deformation in a stiff clay test piece,
tically
brittle
Considering presence pushed passing
of out
the a by
through
with
tests
on
short
and
plane
(Figure
21),
of
a
Figure
quasicomplete
stiffness grease the
film
pressure
the
test
of
the
in
piece
to
test
pieces.
was prac-
ZZ. Multitude of broken fragments in a short stiff clay test.
loss
of
with
generate
axis.
sand
but its behaviour
material,
contact
and
long
strength we
tried
the
clay,
tension
Another
means
after to
failure. avoid
likely on
the of
to
the be
planes avoiding
110
friction layers
was of
used
ensures
Figure the
The
normal
22
tests
is
with
onset
clearly
on
by
test
the
Figure
not
There
is
samples
presented
device. still
tensile lubricant
short
is
o~
molybdenum
The
of
It
anti-hooping
or
base.
Failure
fractures.
23.
consisted
influence
piece
confetti.
It
grease
does
of the
multiple
shows
indicated
samples.
lubricated
the
of
short
contact
is no hooping
the
which
of
confetti,
stress
with
heads
clay-confetti
so there
occurred
the
aluminium
bisulphide. strength,
on
The
on
result
a certain
of
softe-
MPa
~l" :35,75 m m H= 74,5 mm
l
long sample
/J~ =102mm 39.4mm
short sample ! \
/
AI mm
, 0 Figure ning
Z3. U n i a x i a l
after
practically
the
Van concrete. would
be
know
that
softening In
short
for
(1984)
These
in
the
on
sample,
long
short
but
test
and
the
pieces
long
test
value and
pieces
~f
of the maxima
the
short
one
is
with
obtained
results with
this
are
the
results
obviously
short
case,
similar
test
different
pieces
strength
with
and
is
triaxial
from
friction
much
the at
higher
tests one
which
supports.
(Hudson,
on
We
Brown,
1971). sand
with
sample.
material.
same
Mier
For obtained
of the
test clay.
8
protection.
obtained
Fairhurst
6
compression
failure
anti-friction
the
4
2
It
and
the
the
it seems
triaxial
therefore
However, curve
clays,
the
remains course
that
the
value
of m a x i m u m
apparatus
is
independent
corresponds
to
an
physical
of
intrinsic
significance
of
the
strength shape
property
the
slope
of of
of the the
uncertain. of
this
article
we
have
thrown,
then
lifted,
111
doubt
on
the
maximum
consequently value
the
value
slip
In a triaxial
surface
with
angle of internal We
Cmx
of Cr in the triaxial
correction. the
on
strength
can
also
that
6 is all
origin
calculation,
means
that
After
softening,
friction
the
Cr
critical of
a
¢c'
-strain
accept is
slip
smaller
a
but
the on
the
will and
now
show
generally
on sand,
test
and
that
the
calls
the angle
is
all
the
as
the
density
Without wishing
slip
this
test
Coulomb
line
equation
characteristic
is accomplished,
plane
maximum
smaller
for 6 of
as
of
the
sand
is
to take sides
as
corresponds,
direction plane
piece
is
with
to complete
6 = ~ - ¢ of
the
is still
therefore friction
(which
stresses).
the residual for
angle of
example,
to
6. The Mohr larger
angle
t
the
circle
than
Cr'
~
in
the
Figure
24
~-%
stress-
which
the
r
/,
a,m~-a 3 rain
defines
from
corresponding
axis
triaxial
different
the
Cmx;
the
dilatancy
slip
curve
Cmax - ~3' obtain
to
The
on
piece
increases.
line
the
the
magnitudes. strength
can
homogeneous
indicates
We
a
of slip lines and simply to be able
when
in
corresponding case
we slip
value
sand.
a
is incorrect
in compression
test
higher or as the d i l a t a n c y
the
of
in
friction ¢ is wide.
say
to the physical
measured
test
test
the
value
-~3
we
strength
to
the
test
stage defines el min - q3' giving an angle ¢' which is greater
than
the
resi-
dual strength Cr" A
simple,
gthy
but
rather
computation
lena3
0
yields
o' I
°'1 rain
mx
the following equation:
Figure
Z4.
Mohr circles of maximum residiual friction.
and
+ I . tan I~ + ~2) With
Figure
25 we
can calculate
to the ¢' m e a s u r e d value to determine This
correction
Soil Mechanics;
- tanCr
only
entails
it can become
wide m a x i m u m friction angles.
the correction
¢' - Cr to make
the value of Cr" a
few
degrees
quite c o n s i d e r a b l e
in
normal
cases
in Rock M e c h a n i c s
of for
112
VI. P R A C T I C A L A P P L I C A T I O N S We
have
just
stated
that
in
the Soil
Mechanics
correction axial
6
test
small,
~ ~ = 6 0
slip
laboratory
to make to
determine
around plane
to the
the tri-
Cr
is
I ° or 2 ° , when
has
settled
in
a
the
test piece. The
same
phenomenon
much
greater
the
slip
plane not
surfaces
and
the
uniform,
bearing m...O
OJ
10
20
30
40
SO
so
4;
path of
on
residual
Z5.
Correction ( , - ~r ) for friction (triaxial
test).
are
a
simply
say
that
numerical
tables show
functions
the
example give
order
will
make
Cmx the
with
zation,
friction
the critical qu'
(or sand
to Cmax" However,
progressively
capacity
of
this
of
softening.
range
discontinuous
this
NY(¢c = 32 °) = 31
of m a g n i t u d e
phenomenon
reduce
bearing
of of
the
localiap-
~, so we can
calculated
by
the
< qu < Y~Ny(¢mx)"
(1956)
the
limit
surface and
formula of the surface term y~Ny lies between two values:
Y~Ny(¢C) A
the
slip
failure
dilatancy
proaches classical
shallow
orientation
corresponding Figure
of
the
non-cohesive
Generalized
the
the
not
fields
instance
on
of
when
are
capacity
materials. occurs
be
stress
for
foundations
where
can
importance
by
nature
It
a
of
the
clear and
:
obviously
theoretical deformation.
Caquot-Kerisel
NY(¢m x = 40 °) = 114,
theoretical
is
the
uncertainty extremely
approach However,
which
linked
to
difficult
to
because there
of
the
remains
the
possibility of proposing approximations. If we look angle (or
of in
the
sentative tation
slip
of
the
used
strength
first at the upper bound,
internal
of
in the
friction
¢c
surfaces) state
the
of
slip
failure
is rapidly
and rigid
that
it is quite clear that the reached
Cmx
blocks.
is By
method,
in
other
surface,
we
can
not
the
doubt
analogy
words
try
in
to
slip
surface
only
repre-
the
compu-
with
by
taking
the
shear
lower
the
upper
bound
tan¢ c
va'lue
by
the
coefficient
to tanCmx
bring
friction
back
to
its
true
1t3
value. The of
situation
friction
too
¢c corresponds
short,
function width
so
of
L of
the
remains
consider
slip
coefficient
We
must
proportional network
the
the
line
which
remember
to
of
the angle
width
is
is
a
that
the
B
the
of
characteristic
stress
~I e(~/2)tan¢
+
that
L
arc,
proposed
that
intervenes the
to
two
an
twice,
first
define
the
slip
function
of L to choose
the calculation to
increasing
define
stress
surfaces
are
is unboudtedly
for the increasing of slip
of
length
to
the
homothetic
closer
coefficient
the
normal
not
circles,
the
we of
slip
but
the
to
L 2 than
to
L,
lower
bound
can
be
as follows: /L(*mx)]
Cmx e~tanCmx
2
tan2 ( ~ + --~-)
two corrections
similar
results,
ensure
a
obtained.
proposed
which
must
for
theoretical
pretention
calculation,
expressed
is
(Nq not
satisfactory The problems
that
confidence Meyerhof
surface in
on Figure
good
26.
They
as a demonstration in
the
(1961)
term.
had
It
correlation
approximation given
was with
provide but they a
devoid the
semi-
of
slip
any
circle
as follows:
1) t a n 1 . 4 ¢
surprinsing
:
[tan2(~
that
+ ~)e ~tan¢
the
two
-
1] t a n 1.4¢.
corrections
proposed
show
agreement. same
to
of
the but
indicated
be decisive
degree
remember
formula
Ny :
are
cannot
certain
We
-empirical
it
with
secondly
correction
means
the function
by analogy
Naturally,
effective
So
is
classical
Whereas
strength,
increasing
extension.
discharge the
to define
resisting
do
surface
Again
the
surface.
I{
tan
can
The
slip
an
bound.
we can formulate:
coefficient.
which
consider
side
for the lower
to the residual
can
Using
L : There
we
the
foundation. lines,
is similar
approach
propose
prone
to
softening.
earth
pressure
of non-cohesive
normal
can
be
corrections We
can
take
considered to
the
to a vertical
material.
The active
for
classical example
wall
other of
and
retaining
and passive
Ka = tan2
Mechanics
for
materials
active
(4-~) "
and
passive
a horizontal
pressure
are: Ko : tan 2 ({ + ~ )
Soil
formulae
mass
coefficients
114
B lqu=¥.~Ny N~,(4p) tg4'c
~
t,4,
I. _
"~__.++Y...__~
j(dp)e"tg+ Ny(~c)
Ny
500' 4o( 30o
J(~c)e**t04'c
2o0 F i g u r e Z6. C o r r e c t i o n s proposed for bearing capacity of shallow foundation on n o n - c o h e s i v e material w i t h an internal angle of friction ¢.
lO0
50 40 3O
Ny(+c) . . . . . . . . . .
20 10
14,c 10
With
passive
surface
30
20
earth
to occur,
40
pressure
5(3 e
when
the
2~__qc) We
can
propose
before,
the
is dense
enough
for
a slip
¢mx
same
decreasing
coefficient
of
the
upper
bound
as
that is : Cmx
tan 2 (~ + -7-) and
sand
the following range can be formulated:
for
the lower
(~ + +)
(H
simply
take
stress
normal
bound a coefficient
being
a linear to the
of the slip plane
tan¢c
×tanCmx
the
height
function slip
is fixed
of of
surface by the
function
the
of the length ~ =
retaining
-~ since
there
wall). is no
For
to
foot
We can
of the wall).
this
reason
to be proportional
Y
H/cos
for
we the
(the depth except
an
115 increasing coefficient expressed as: Y(¢mx )
Y(~c ) and as a correction:
f~ *c) The two corrections proposed are indicated on Figure 27. They are
tg¢ c
Kp 10
5 i=tg2(-~+ 2 3 L ) ~
iI /
10
Figure
20
30
40
50
ZT. C o r r e c t i o n s proposed for normal passive earth pressure wall retaining an e a r t h m a s s o f s a n d w i t h i n t e r n a l angle of friction
still close information. The
enough
to
transposition
each to
other the
to
case
obviously immediate by changing (~ + ~ ) t o
VII.
provide of
sufficient
active I~-
earth
on a
practical
pressure
is
~2)"
CONCLUSIONS
We have shown that the phenomena of deformation localization
in
116
one
or
several
slip
surfaces
consequences
in the laboratory
is
for
proposed
the triaxial
the
test,
but this test
In practice, mass
causes
of
the
is particularly
the occurrence
for more
important
A correction
shear
strength
interesting
useful
and
of discontinuities
discrepancy
compared
in
for deter-
even
irreplace-
with
at failure
of an
classical
beha-
from the hypothesis
of defor-
The corrections proposed here for the surface punch
and for active earth pressure are obviously call
have
strength.
the values calculated
mation homogeneity.
soils
residual
is especially
of residual
extensive
viour and modifies
in
In the same way, the direct shear test, either
or in torsion,
able for the determination earth
failure
and also in site practice.
determination
mining maximum strength. rectilinear
during
precise
definition
rough approximations
in the cases
be extended to other routine applications
examined.
which
They can also
in foundation engineering.
REFERENCES
Caquot A.; Kerisel, J., (1956), Traite de Mecanique hier-Villars, Paris, Ch. XVI, p. 389.
des
Sols,
Gaut-
Chazy, C.; ~abib, P., (1961), Les Piles du Quai de Floride, 5eme Congres Int. de Mec. des Sols, Paris, juillet 1961, Com. 6/27, p. 669.
Darve, F . ; Desrues, J . ; Jaequet, H., (1980),
Los Surfaces de Rupture en Mechanique des Sols en tant qu'Irreversibilite de Deformation, Cahiers du G.F.R., V. 3, j a n v i e r 1980.
Desrues, J . ,
(1984),
Materiaux
La Localisation de la Deformation dans les Granulaires, These de D o c t o r a t - e s - S c l e n c e s , INPG
Grenoble, mai 1984. D u t h i l l e u l , B., (1983), Rupture Progressive:Simulation Physique et Numerique, These de Docteur-Ingenieur, INPG Grenoble. Goguel, J., (1983), Etude Mecanique des Deformations Geologiques, B.R.G.M. Orleans, Manuels et Methodes n°6, ch. 6:Rupture Discontinue, Rupture et Glissement, p. 85. Hudson, J.A.; Brown, E.T.; Fairhurst, C., (1971), Shape of the Complete Stress-Strain Curve for Rock, 13th S)~np. on Rock Mechanics, sept. 71, pp. 773-795. Mandel, J.. (1966), Mecanique des Milieux Continus, Gauthier-Villars, Paris, Deformation Plastique Heterogene, tome II, p. 708. Meyerhoff, G.G., (1961), Fondations Superficielles: Discussion, C.R. 5eme Cong. Int. Mecanique des Sols -(Paris), tome III, p. 193. Roscoe, K.H., (1970), The Influence of Strains in Soil Geotechnique, vol. XX, 2, june 1970, pp. 129-170.
Mechanics,
Suemine, A., (1983), Observation Study on Landslide Mechanism in the Area of Crystalline Schist (part I). An Example of Propagation of Rankine S t a t e . Bull. of the Disaster Prevention I n s t . , s e p t . 83, vol. 3, Part 3, PP. 105-127, Kyoto University, Japan. Van Mier, J.G.M., (1984), Complete Stress-Straln Behaviour and Damaging Status of Concrete under Multiaxial Conditions, Int. Conf. on Concrete under Multiaxial Conditions, U n i v e r s i t e Paul Sabatier, mai 1984, vol. I, P. 79, Toulouse (France).
II.
EXPERIMENTS
AND A P P L I C A T I O N S
UNDRAINED
CREEP
STRIP
DEFORMATION
LOAD
A . F . L . H y d e ~) m)Loughborough m*) IBM (United
OF A
ON CLAY
and
J,J,Burke ~)
University Kingdom)
of T e c h n o l o g y
Ltd
S~OPSIS
Time-dependent creep effects can play an important role in the stress distributions and deformations of foundations.
Using a
phenomenological model, the analysis of undrained creep behaviour has been introduced into an elasto-plastic finite element programme.
The
creep behaviour of a strip load on a finite layer of soil has been illustrated and a study has been made of the effects of small changes in the values of the creep parameters on the overall analysis of creep deformation.
Time dependent creep deformations of a strip load are also
compared with those occurring due to consolidation. The treatment of creep behaviour has been restricted to the modelling of deviatoric creep.
When comparing creep effects on different
clays, the shape of the yield surface is an important consideration. Sensitivity analyses on the creep parameters revealed a necessity for their accurate evaluation.
Small variations in these parameters caused
correspondingly large variations in predicted settlements.
The inclusion
of creep behaviour in a consolidation and creep analysis resulted in a marked increase in settlements, creep settlements causing heave at points distant from the loading.
Consolidation and creep settlements
have opposite effects on horizontal displacements below the edge of a strip load.
120
Notation semi-width of strip foundation coefficient
of consolidation
(two dimensional)
slope of the logarithm of strain rate versus logarithm of time p'J
effective mean normal
q'
invariant
Pc
preconsolidation
qf
invariant
t
time
t1
unit time
At
time step size
A
strain rate at time t I and D = O
D
deviator
stress
shear stress pressure
shear stress at the point of critical states
(projected value)
stress
ratio of deviator stress to deviator E
Young's Modulus
Ko
coefficient
M
slope of the projection
stress at failure
of earth pressure at rest of the critical
state line in
q', p' space N
specific volume on normal normal effective
Of,
consolidation
line for unit mean
stress
value of the slope of the linear portion of a plot of logarithm of strain rate versus deviator stress ~qf
6ij
Kronecker
£:
direct strain
sC
creep strain
13
delta
creep strain rate tensor
121
k
swelling index compression
index
"o
Poisson's
°x,y,z
direct stresses
oij
stress tensor
1"
specific volume on the critical
ratio
normal effective
stress
state line for unit mean
122
Introduction Time-dependent stress distributions Kaufman and Weaver I0-15
creep effects can play an important and deformations
of foundations
and embankments.
(.1967) studying deformations which occurred over
years of the Atchafalaya
levee on the Mississippi
field data with nonlinear elastic and elasto-plastic analyses.
role in the
River compared
finite element
The results of their comparison showed that creep effects
should be included in these kinds of analyses.
Lo et al.
(1974)
monitoring a test embankment near Ottawa attributed more than half of the settlements
to creep behaviour.
Using a phenomenological Singh and Mitchell been introduced this programme
(1968) the analysis of undrained
into an elasto-plastic
creep behaviour has
finite element programme.
Using
the creep behaviour of a strip load on a finite layer of
soil has been illustrated small changes
model for creep behaviour proposed by
and a study has been made of the effects of
in the values of the creep parameters
analysis of creep deformation. accompanied by consolidation creep deformations
Creep deformation
settlements
on the overall
is likely to be
and so the time dependent
of a strip load are also compared with those occurring
during the consolidation process.
Creep Model Researchers
studying creep behaviour of cohesive soils have tended
to adopt one of two methods of analysis. soil behaviour has been developed data to check the applicability or experimental
Either a rheological model of
followed by the analysis of empirical
of the model
(Murayama and Shibata,
data has been analysed on a phenomenological
give predictive equations (Singh and Mitchell,
connecting the various measured
1968).
1958),
basis to
parameters
Any model of creep behaviour which is
123
adopted must use easily determined parameters preferably obtained from standard soil tests, must be applicable to a reasonable range of creep stresses and must describe the behaviour of a range of soil types.
The
phenomenological approach, particularly if normalised soil parameters are used, meets these criteria and lends itself to easier use for the prediction of soil behaviour. Creep tests on many soils such as London Clay (Bishop, 1966), Osaka Alluvial Clay (Murayama and Shibata,
1958) and remoulded illite
(Campanella, 1965) show a linear relationship between logarithm of creep strain and logarithm of time (Figure l(a)) and also between logarithm of creep strain rate and applied deviator stress
(Figure l(b)).
Upon
analysing experimental data on a number of clays, Singh and Mitchell
(1968)
derived an equation which was held to be valid irrespective of whether clays are undisturbed,
remoulded, normally consolidated or overconsolidated
or tested drained or undrained.
The equation expresses the strain rate,
~c, as a function of time, t, and sustained deviator stress, D.
~c
where :
=
Ae ~D (tl) m t
. . . . . .
A
=
strain rate at time t I and D = O
(i
=
value of slope of the linear portion of a plot
(i)
(projected value);
of logarithm of strain rate versus deviator stress; tI =
unit time;
m
slope of logarithm of strain rate versus
=
and
logarithm of time. The authors have chosen to use this model as it needs few parameters
to
define it and these may be determined by carrying out a small number of creep tests at different stress levels on triaxial samples.
124
Equation
1 can be written in a more useful form as:
~c
=
Ae (~ D)
(tl)m t
...
(2)
where D is the ratio of deviator stress to deviator stress at undrained failure, =
q'/q~;
=q~;
and
A, tl, ~ and m are defined above. The use of parameters
~ and D instead of a and D is more convenient
because they are both dimensionless greatly with moisture content. wide range of conditions
and the value of ~ does not vary
Thus predictions
of behaviour over a
can be made from a limited number of creep
tests. To use Equation 2 a starting value of elapsed time must be specified.
Typical values
day and one month.
for practical problems may range between one
The creep strain rate predicted by equation 2 for a
given point in the material
under a time varying stress level is shown
schematically
Under a level of stress, DI, the creep strain
in Figure 2.
rate is initially represented by point 1 and this value gradually decreases until the rate is represented by point 2. increase in load produces
At this time an
a stress of D2 giving rise to a strain rate
represented by point 3 in the figure.
The predicted
strain rate
gradually decreases with time as shown as long as no further disturbance is introduced. The predicted creep rate, ~ c a triaxial sample.
Problems
essentially uni-dimensional more dimensions overcame
is the vertical
arise when attempting
to apply this
creep strain rate to situations
(such as plane strain conditions).
these difficulties
creep strain rate of
involving
Chang et al.
by making the following assumptions:
(1974)
125
(i)
no volume
(ii)
change occurs
the principal proportional
due to creep strains;
shear strain rates are directly to the corresponding
principal
shear
stresses; (iii)
the principal deformation;
(iv)
the strains
strain axes do not rotate under and
are small.
The flow rule for creep strain
rates resulting
from these assumptions
is
where
Proper of plane
.c eij
_
3~ c , 2q' (aij - P'6iJ )
i,j
=
~c
is given by Equation
6
is the Kronecker
p'
is the mean normal
q'
is the invariant
x,y,z and axx'
consideration
direction
ax,' etc.; (2);
delta; effective
stress;
and
shear stress.
must be given to the constraints
(z-direction).
For plane
strain
in the out of plane direction
strain
relationship
written
=
(3)
"'"
strain
is zero.
in the out
conditions
The non-plastic
for a material when creep is continuing
the total stress-
can be
as:
For plane
ex
=
i g{a x, _ ~ ( o ~
+
o~)}
+
e xc
(4(a))
Ey
=
I , ~{ay - v(a~
, + a x)}
+
eyc
(4(b))
ez
=
~{azl' - v(a~ + a~)} + ezC
(4(e))
strain
conditions
e z = O and so from Equation
a~ = v(a~ + a'y) - EE~
(4(c)): (5)
126
and on substituting Ex
=
=
Ey
this in Equations
{(I - v2) ~
{(I
- ~(
~
c
(6(a))
-EV2)o (I + v)o') c ~ec . Y - ~ T x~ + Ey +
(6(b))
the brackets
o~}
c
+ E x + ~e z
The quantities within
~
(4(a)) and (4(b)) one obtains:
of Equations
(6) are the elastic
strains and so to account for the out of plane creep strains equal to ~e~ is added to the strains
a strain
in the x- and y-directions.
!
Equation
(5) is used to calculate o z .
The three creep parameters necessary deviatoric
creep behaviour
cylindrical
can be obtained
triaxial samples,
initial stress conditions.
to define the model of from a minimum of two identical
at the same moisture
content and same
The samples must be subjected
tests under different deviator stresses
covering a range,
to creep say, of 30%
to 90% of the maximum deviator stress depending on the stress history. Under these sustained Mitchell
loads,
strain is observed with time.
Singh and
(1968) expand on the subject of parameter evaluation
Appendix I.
in their
It should be noted that the parameter, m, is not unique
for a given soil and may vary depending on whether
the soil sample is
on the 'wet' or 'dry' side of critical
states.
results for Keuper Marl which indicate
a value of m of 0.86 on the 'wet'
side and 1.00 on the 'dry'
side of critical
Hyde
(1974) has obtained
states.
The computer program used was developed by Burke program allows nonlinear creep analyses
analyses
and at any stage of a load deformation
of equivalent
forces.
analysis
time
the creep strains are
above and then these are converted The equivalent
of
To model creep displacements,
an increment of time is allowed to elapse, as described
This
to be carried out independently
dependent behaviour may be introduced.
calculated
(1983).
into a set
loads are added to the external
127
load vector and the solution for the end of a time step involves a re-solution.
Because creep response under working load situations is
generally a decay process, progressively larger time steps may be used. Equation 2 was modified to include a lower cut-off for creep strains whereby values of D lower than 0.3 did not cause creep flow.
A flow
chart summarising the basic solution algorithm as stated above is shown in Figure 3.
Creep Deformation of a Strip Load on a Finite Layer of Soil To show the kind of behaviour one is likely to expect from Singh and Mitchell's (1968) creep model, it has been applied to the analyses of a strip load of width 2a underlain by a clay layer of thickness 3a and 6a (Figure 4).
The two materials used in the study were San
Francisco Bay Mud and Keuper Marl (the material parameters of which are stated in Table i) and creep deformations under different load intensities were investigated. The start of the analysis was taken at 7 days after the application of the loads.
The time stepping sequence began with a time increment of
i day and subsequent time step sizes were ever increasing and had a value of 1.5 times the previous value. Figures 5 and 6 show the creep behaviour for both depths of layer for San Francisco Bay Mud and Keuper Marl, respectively, at various loading pressures.
At a loading pressure of 50 kN/m 2 the amount of
predicted centreline creep displacement for each material is similar. As the loading increases, however, the creep displacements of San Francisco Bay Mud increase more than those of Keuper Marl.
In the case
of Keuper Marl doubling the loading pressure from 50 to iO0 kN/m 2 has the effect of increasing the centreline creep displacements at 2960 days by a factor of approximately 1.3 and 1.5 for the deep and shallow layers, respectively.
For San Francisco Bay Mud the same loading
increase causes increases in the creep displacements at 2960 days by
128
a factor of 1.4 and 2.0 for the deep and shallow layers, In doubling the loading pressure
respectively.
from IO0 to 200 kN/m 2 these factors
become 2.3 and 2.4. The above analyses
show that San Francisco Bay Mud is more prone
to creep than Keuper Marl and this could have been deduced from an inspection of their creep parameters.
However,
at low stress intensities
the amount of creep for each material
is shown to be similar.
in part due to the fact that although
the loading is identical Keuper
Marl has a lower undrained (this is illustrated
failure stress for a given stress history
in Figure 7 where the wet side yield locus ellipsi
for the two materials therefore,
This is
are shown).
For a given stress intensity,
this would imply that the ratio, D (see Equation 2), would
be higher for Keuper Marl than it would be for San Francisco Bay Mud resulting in enhanced
Sensitivity Analyses
creep strain rates for Keuper Marl.
on the Creep Parameters
When using any model of soil behaviour it is worthwhile
considering
what effect small changes in the values of the material parameters will have on an analysis parameters
so that material testing yields values of material
to the desired accuracy.
Francisco Bay Mud such a sensitivity the creep parameters problem
Using the parameters
for San
analysis has been carried out on
,a, and ,m, for the strip load on the deeper layer
(depth = 6a) at a loading pressure of 200 kN/m 2.
Figure 8 shows the effect of varying the parameter
,~,.
Values
of ,~, have been taken at 10% and 20% above and below the actual value for the material. centreline
An increase of 10% and 20% causes an increase in
creep displacements
at 2960 days of 25% and 54%, respectively.
A decrease of 10% and 20% causes - decrease in centreline
creep displace-
ments at the same time of 21% and 39%, respectively.
Increasing
therefore has a greater effect on creep displacements
than decreasing
,= .
This may also be explained with reference
,6,
to the equation of creep
129
strain rate (Equation 2). exponent,
Because
,~, appears in the equation as an
increasing the value by any amount will have more effect than
decreasing
it.
This partly explains why San Francisco Bay Mud is more
prone to creep than Keuper Marl which have values of 5.40 and 1.13, respectively. Figure 8 shows the effect of varying the parameter
,m .
Again,
values of the parameter have been taken at 10% and 20% above and below the actual value for the material. a decrease in centreline
An increase of 10% and 20% causes
creep displacements
of 28% and 48%, respectively.
A decrease of 10% and 20% causes an increase
in centreline
displacements
Thus decreasing
of 38% and 90%, r~spectively.
of ,m, has a greater influence on creep displacements
creep the value
than a similar
increase and this may be explained by the fact that ,m, appears in the creep strain rate equation as an exponent
to the reciprocal
of time.
Figure 9 also shows that creep rupture is associated with low values of am
•
The above sensitivity
analyses show that the creep parameters
and ,m, must be carefully determined because
the prediction of creep
displacements
is sensitive to small changes in their values.
Consolidation
and Creep
To examine the effects of creep during the consolidation the authors have analysed the problem of a semi-infinite Francisco Bay Mud supporting a flexible, Consolidation
in Table I.
(1983).
boundary conditions
layer of San
(elasto-plastic)
The material parameters
The finite element mesh used to approximate
layer and boundary conditions
process
porous strip load of width 20m.
settlements were computed using a nonlinear
analysis developed by Burke
,~,
are shown
the semi-infinite
are shown in Figure i0 and the additional
are that free drainage was allowed only along the
130
upper surface boundary, impermeable. throughout
the vertical
and lower boundaries
The soil had an initial vertical
its depth,
of earth pressure
ratio had a value of 0.444.
was assumed to be lightly overconsolidated ratio of 1.2.
stress of -150 kN/m 2
the value of the coefficient
at rest, Ko, was 0.8 and Poisson's
being
The soil
with an overconsolidation
The initial values of bulk and shear moduli were 4717
and 455 kN/m 2, respectively,
and the horizontal
were assumed to be 1.15 x 10 -5 m/day.
and vertical permeabilities
The coefficient
of consolidation,
c, of 5.72 x 10 -3 m2/day was calculated using the following formula:
c
-
(K +
)
. . . . . .
(7)
~w where
k
is the permeability;
Yw
is the bulk density of water;
and
K,G are the bulk and shear moduli,
respectively,
of the soil skeleton. Two analyses were carried out assuming: (a)
consolidation
of a nonlinear
(elasto-plastic)
soil skeleton;
and
(b)
consolidation
of a nonlinear soil skeleton with the inclusion of
creep effects. A uniform ramp loading was applied such that the full loading pressure of 100 kN/m 2 was obtained after the first ten time steps.
The time
stepping scheme was as follows: i0 steps of At
=
i0 days;
9 steps of At
=
102 days;
9 steps of At
=
103 days;
9 steps of At
=
i0 ~ days; and
9 steps of At
=
105 days.
The initial time step size of I0 days violated the stability criterion of Vermeer and Verruijt
(1981) for the consolidation
analysis,
131
however no problems
such as oscillating excess pore pressures were
encountered with this value of time step size.
This may, in part, be
attributed to the fact that the criterion strictly only applies
to
regular finite element meshes
problems.
for one-dimensional
The example used herein is two-dimensional is graded.
Another important
consolidation
and the finite element mesh
feature of the analysis
is that the loading
was not applied suddenly but gradually over the first ten time steps, thus reducing any tendency towards oscillating excess pore pressures. Creep effects were considered loading was complete.
from the point in time at which the ramp
The time at the end of the analysis
corresponds
to a value of time factor, T, of 57.2 calculated using the following formula: T
where
-
ct a2
° . .
c is the coefficient
(8)
. . .
of consolidation;
t is the elapsed time; and a is a reference
length
(e.g.
the semi width
of a strip load). Figure II shows the development
of settlements
at the centre of the
strip load with time factor for the two analyses performed. porportion of the total settlement
occurred during the loading period and
may be attributed to the fact that dissipation pressures was allowed during the relatively at the end of loading the settlements settlement
of the excess pore
long loading period.
due to the consolidation
The inclusion of creep behaviour
shows a marked increase in settlement Figure 12 shows the dissipation
Thus
comprise both the 'immediate'
due to the load and a contribution
of the underlying soil.
A large
in the analysis
at all times. of excess pore pressure with time
factor at a point below the strip load (position A in Figure i0).
The
effect of creep behaviour is to increase the peak value of excess pore pressure and cause this peak to occur at a later time than those shown
132
by the nonlinear consolidation
analysis.
to delay still further the subsequent
Also, creep behaviour
dissipation
tends
of the excess pore
pressures. Figure 13 shows the surface settlement loading and at T = 5.72 for the nonlinear analysis
including creep.
profile at the end of
analysis
and the nonlinear
The figure shows that settlements
creep may be significant when compared to consolidation
due to
settlements
and
also that creep may cause heave along part of the surface distant from the strip load. Figure 14 shows profiles the strip load (~ = I).
of horizontal movements below the edge of
It can be seen that the consolidation
effects are in opposition,
consolidation
creep causing an outward movement. times and at other locations other or cause oscillations
and creep
causing an inward movement and
It is conceivable
that at certain
in the soil these effects may cancel each in horizontal
be needed when horizontal movements known that the underlying material
movements.
are monitored
Care may therefore
in the field if it is
is prone to creep.
Conclusions The treatment of creep behaviour has been restricted modelling of deviatoric analysis,
creep.
to the
Of the two basic approaches
to creep
the authors have used the approach utilizing a phenomenological
model and in particular
that of Singh and Mitchell
When comparing creep effects on different
(1968).
clays at low stress
levels the shape of the yield surface and its effect on the stress ratio is an important Sensitivity parameters
consideration. analyses were carried out on the Singh & Mitchell
,~, and ,m, (because they appear as exponents
in Equation
creep (2))
of San Francisco Bay Mud and showed that they must be carefully determined. An over- or under-estimate
of the value of the parameter
cause an increase or decrease,
respectively,
in predicted
,~, by 10% may creep settlements
133
of the order of 25%.
An over-estimate of the value of the parameter
,m, by 10% may cause a decrease in predicted creep settlements of the order of 30%; an under-estimate of the value by the same amount may cause an increase in predicted creep settlements of the order of 40%. This last finding is consistent with the fact that creep rupture is associated with low values of m. The effects of combining creep with a nonlinear (elasto-plastic) consolidation analysis have been studied.
The inclusion of creep
behaviour resulted in a marked increase in settlement.
It also resulted
in increased values of peak excess pore pressures (at a later time) and these excess pore pressures took longer to dissipate.
When considering
vertical movements, creep settlements appear to cause heave along part of the surface distant from the loading.
Consolidation and creep have
opposite effects on horizontal displacements below the edge of a strip load, consolidation causing an inward movement and creep causing an outward movement.
Care may therefore be needed when analysing in-situ
horizontal displacement records if it is known that the underlying material is prone to creep.
REFERENCES BISHOP, A.W. (1966), "The strength of soils as engineering materials", Geotechnique, Vol. 16, pp. 91-128. BURKE, J.J. (1983), "A non-linear finite element analysis of soil deformation", PhD Thesis, Loughborough University of Technology. CAMPANELLA, R.G. (1965), "Effect of temperature and stress on timedeformation behaviour in saturation clay", PhD Thesis, University of California, Berkeley. CHANG, C.-Y., NAIR, K. and SINGH, R.D. (1974), "Finite element methods for the nonlinear and time-dependent analysis of geotechnical problems", Proceedings of the Converence on Analysis and Design in Geotechnical Engineering, Austin, Texas, Vol. ~ ,
pp. 269-302.
134
HYDE, A.F.L. (1974), "Repeated load triaxial testing of soils", PhD Thesis, University of Nottingham. KAUFMAN, R.I. and WEAVER, F.J. (1967), "Stability of Atchafalaya levees", Proceedings of the Journal of the Soil Mechanics and Foundations Division, ASCE, Vol. 93, No. SM4, pp. 157-176. LO, K.Y., BOZOZUK, M. and LAW, K.T. (1974), "Settlements resulting from secondary compression",
Report RR211, Research and Development Division,
Ministry of Transportation and Communications, ~RAYAMA,
Ontario, Canada.
S. and SHIBATA, T. (1958), "On the rheological characteristics
of clay, Part i", Bulletin No. 26, Disaster/Prevention
Research Institute,
Kyoto, Japan. SINGH, A. and MITCHELL, J.K. (1968), "General stress-strain time function for soils", Proceedings of the Journal of the Soil Mechanics and Foundations Division, ASCE, Vol. 94, No. SMI, pp. 21-46. VERMEER, P.A. and VERRUIJT,A~I981),
"An accuracy condition for
consolidation by finite elements", International Journal for Analytical Methods in Geomechanics, Vol. 5, pp. 1-14.
135
,.1•
t~
0
ol
O
I~,~
N
~
M
T
~o u
0 0
01 N
o
r~
0
°' [I
~p a~a
0
I
:0
I,
~
I
:"I
•
I
~1
o
1
0 ~o
0
i 0
vl
",,.J
~1
o
,-~1 I~ ~ t~
~ •~
e
co
=11o, o
ul
'~'
I
M
~
Q
o
I ,
b~
o
~.~ ~
U
ol ~1 = ol
o
o
o
I
~
-I¢
136
Log ~c
q3 q2 ql
q3 > q2 > ql
Log t Creep strain rate versus time
(a)
t 1
LoZ £c
t3 > t2 > tl
~
- ~ ~ / ~ ' ~ /
t2 t3
A3
(b)
Creep strain rate versus deviator stress
Fig I. Typical creep strain relationships
q
137
02
log ~c
51
13
log t
Figure 2
Schematic representation of creep response to a varying stress level
138
(
START
D
Obtain initial conditions
i
I
Calculate stiffness matrix and reduce it I
I Specify a set of loads
I
1
I
Solve for displacements & stresses J I I Calculate residual] force vector I I Add residual loads to the previously applied loads
I
an increment I[Specify of time I Calculate creep strain increments and
corresponding residual loads -
I
Add residual loads to ] the previously applied loads
I y
I
Solve for displacements I and stresses 1
I
YES
l
iOutput results for the time i?crement ]
lOutput results for I Ithe load increment ]
YES NO
~
Y
E
S
C STOP •
Figure 3 Flowchart of the basic solution procedure for elastoplastic and creep analyses by finite elements
139 x
~S IIII
Y~
44 Elements 163 Nodes
strip load
IIIII
Jllll I
]11~ 10a
L F
66 Elements 233 Nodes
ql--
strip load
Y
9 1 q
"7
(0
,I"/ q,,,
,I/,, 0 ;
= 0
if
F(o)
~< 0
:
spherical
coordinates
g
strain
tensor
with
principal
components
:
stress
tensor
with
principal
components
: °l
E
Young's
C
cohesion
F
yield
n
viscosity
:
unit
> ~2
g3 > ~3
ratio of t h e m a t e r i a l
criterion
(Tresca)
constant
absolute value strain rate
lI
e2,
modulus
Poisson's
?t
sl,
of t h e e q u i v a l e n t
viscoplastic
tensor
• S t a t e m e n t o f t h e problem : Since
we have
ses ; m o r e o v e r therefore
~u ~r
Su Dr
where strain
Or,gS,o ~ are the principal is p u r e l y
radial,
u =u(r,t)
stres;
and
u r
g@ = c
"
The yield stresses
symmetry,
; the d i s p l a c e m e n t
: Sr
Let v -
spherical
o 8 =~
limit
is r e a c h e d
simultaneously
by two pairs
of p r i n c i p a l
: f~ ~ ~ ( O
- o r ) - 2C=0
f8
- Or)
~ w(O8
~ = ± 1 has rate
viscoplastic
is,
the s a m e in t h i s
strain
- 2C= sign
as o
particular
rates
:
~I _ i < f ~ > + < f8 ~t ~ 2
~ v p = co ~t ~o
0
~
>
2
- or = o 8 - o r . The case,
the
total
plastic
sum of two associated
154
Then
the
constitutive ~v _ ~r
E
Str
E vV =
( ir- ~ )
Sl i %-E = ~ < ~ Since with
- m E
qo --~ -
~ ~t
state
: (1)
(2)
> (I)
and
(2) c a n b e
t = 0 and any other ~I ~-~ (r,t)
~(r,t)
follows
St
is n a t u r a l ,
It =
as
I ~l + ~ ~ E S--~
- ~r ) - 2 C
to t i m e b e t w e e n
~VP(r,t)
can be written
2 v
(~
at t = 0, t h e respect
relationship
dt
instant
integrated t.
If w e
take
,
0
~;VP(r,t)
where
positive
is
or n e g a t i v e ,
E - ~~u -=
we
then
viscoplastic
obtain
strain,
whose s i g n
can be
•
crr - 2 "9 o0 - E v p
E Ur =
with
the equivalent
(i - v )
(i')
1
o0-~
o r + ~ E eVp
(2')
: ~evP 1 { ~ n
~t Moreover, ~r ~r
the
~
equation
2
- 2 ~C
r
}
if
of equilibrium
I o
-~
~
reduces
I > 2C
r to
:
r
(3) •
r
NOTATIONS Once
the viscoplastic
zone will ved
develop
later).
leaving types
Later
residual
of zones -
criterion
inside
on,
may
this
strains
must
Elastic
zone
- Zone with
loading
considered boarder
zone
regress
a viscoplastic
(this w i l l
and eventually
it h a s
reached.
Then,
be pro-
disappear, three
:
residual
:~evP/St strains
kinds of zones may
parameter
dividing
~ 0
: ~evP/~t
= 0 , ev p ~ 0
zone").
oi = ° i ( t ) "
; they are determined
x = x(t)
exceeded,
the medium
: ev p = 0
(or " r e s i d u a l
of the
region
in t h e v o l u m e s
be distinguished
- Viscoplastic
These different
has been
f r o m the c a v i t y
:
exist, More
by the
depending
precisely,
evolution
on the evolution 8 cases
must
be
of t h e v i s c o p l a s t i c
155
The
- the
viscoplastic
- the
non
following
zone
viscoplastic example
1
zone
(5)
:
cv p = 0
(5')
. In a r e s i d u a l ~evP ~t .
0
-
:
and
v i 6 c o p ~ r ~ o n s ~ p s
In a v i s c o p l a s t i c a- the
zone
elimination
e vp ~ 0
:
zone, of
(4) -and
~Or/~r
~t : ~ = E/(2~
b- T h e e l i m i n a t i o n < ~r ~r The b o a r d e r s gration
with
Setting
(4)
+ 4 ~ C
and
(5)
:
leads
to
= 0
(6)
(I - v ~ . vp
between
(4) and
(5) l e a d s
to
4 ~ C ) + ~2~r + 3 - - = 0 r ~ r4 of the v i s c o p l a s t i c
respect
°x + ~°x ~t
of
(5) can be c o m b i n e d
between
r~
Setting
(5")
to r b e t w e e n
r = 1 and
e 4 ~3 C L ° g x 3 - A ( t )
: ax = o r
[ x(t),t
] .
zone
are
r = 1 and r = x .
r =x
leads
to
< ~ 3 - 1 > = ~ oi(t)
Then
inte-
: + ~i (t)
(7).
157
SOLUTION In
the
governing the
following, the
evolution
quantities Let
of
can
~ be
between Let
the
then
any p).
tc(~)
an
instant
an
t =
I - FULLY
~
be
ELASTIC
when =
when
~
x(t)
SPHERE
a
first
boarder
differential
A(t)
(and, if
x(t)) . The
(~ c a n
becomes {
,
~
x(t)
,
be
1 or
other
p or
viscoplastic
undergoes =
order
quantity
equation necessary,
unknown
deduced.
radius
x(t)
instant
td(~)
find
unknown
viscoplastic
particular
1 and
td(~)
will of the
easily
t = tc(~) An
we
evolution
any
value
:
> 0 a viscoplastic
x(t)
unloading
:
< 0
(A)
~t
Figure
2
In
this
case,
(4)
holds
between
r =
1 and
r =
p yields
~i(t) This r
= A(t)
case
ends
~dr/~r
=
4 ~ C.
Such
a
zone
ai = -
4 w C/3
with
elastic
VD~. =
0
sphere
(5') . I n t e g r a t i o n
of
:
1 when
necessarily (I -
: Fully (A).
i/p3).
a viscoplastic
appears
for
zone
r =
appears,
I, w h e n
i.e.
(4)
158 II - F U L L Y
RESIDUAL
OR RESIDUAL/ELASTIC
,
Figure
In t h o s e
two
This
case
III-
FULLY
1,,). ÷ t~
triO) %0)
tdU) toO)
residual
cases,
ends
or
3gvP/~t
respect
to
r = p :
(
= ~(t)
ai(tc)
4.
"tt~* ÷ ~///ll
r = 1 and
~i(t)
(D o r G)
'1f~r'-÷÷÷Vltllttl
(4) w i t h
r between
j
3 : Fully
derivating
SPHERE
i - 7
when
+ -~
residual/elastic = 0
(5")
time,
1 - --
zone
SPHERE
+ ~.
Moreover,
derivating
exp
and
(at),
yields
can
= A
(
be
used
1 _ ~i
(6) w i t h
integrating
44"k"
viscoplastic with
)
c(p) or
:
exp(~t)
: w(td)
i
respect
dt = 0
x =
p , and
to time, to
time
.,t
td(p)
sphere
_ a 4 ~ C Log
respect
with
t d (P) i(t)
by to
4-4-........... 1
:
It
Then,
respect
1 -
to(P)
4 : Fully
(7)
G) •
(E)
,,t
td, p) td(P)
i.e.
+--
1
case,
with
appears,
I
In t h i s
sphere.
integrating
e ( t c) = a i ( t d )
o 3
Figure
(D o r
')
a viscoplastic
VISCOPLASTIC
sphere
in the whole
then
~t
(E) o
then
~x = 0 :
p3
then
multiplying
between
tc(p)
and
by td(p)
159 td 0 = [ exp(~t)
So the i n s t a n t
{ oi(t)
t d w h e n this
IV - V I S C O P L A S T I C / E L A S T I C
I
case e n ds
can e a s i l y be c a l c u l a t e d .
(B)
.....
• t
5 : Viscoplastic/elastic
In the e l a s t i c
zone x < r~ 0.
conditions,
observed,
a
with
(25)
non-linearity
a decrease
of
of
the
the modulus
at increasing stress. 3.3. E f f e c t s of C r a c k C l o s u r e Penny-shaped normal
cracks
stress
and
2D
reaches
elliptical
respectively
cracks the
close
when
critical
the
critical
values
given
by
(Berg, 1965): nE m Poc = 4(1 - 9 2
e
(26)
E 2(1 - 9~) e
(27)
m) Poc where e
is the aspect ratio, that is the ratio b e t w e e n the m a x i m u m thick-
ness and the diameter When this the
the
critical crack
At
normal
value,
is
constant.
(or length)
not the
stress
the
of the crack.
is g r a d u a l l y
aspect
modified critical
and
ratio
therefore,
stress
the
increased
decreases the
crack
but
but
stays
the
diameter
compliance
completely
M Oc
closes
below of
remains and
its
effects disappear. This the
aspect
tropic
loading
luations al.
simple ratio
were
(1975),
situation of
(for
the
which
carried
Feves
and
would
cracks,
out
the for
Simmons
permit
subjecting
closed
cracks
instance (1976).
The
main
drawback
in these
(Mavko and Nur,
by
The
they should be c o n s i d e r e d merely as being
of the cracks
to d e t e r m i n e
by
are
the spectra of
sample
to
inactive).
Morlier results
(1971), are
an
iso-
Such
eva-
Simmons
interesting
et but
indicative.
analyses
1978).
the
is the effect
It is true
of
the shape
that at a given stress
211
the effect their
of
aspect
gradually
thin cracks ratio;
close
depends
however,
at
only
upon their
non-elliptical
increasing
pressure,
length
cracks,
varying
and not
with
their
tapered length;
upon ends,
there-
fore, even a rock c o n t a i n i n g cracks of the same aspect ratio would show a
gradual
thus
increase
simulating
ratios,
cracked
rock
the
sure. at
crack The
the
=eoc.
the
and in p a r t i c u l a r In general,
of
of
will
pressure
define,
an
an
isotropic
permit
(isotropic)
spectrum
e as
a
representing
will
be
anisotropic
in a similar way,
the
of
load,
crack
test
aspect
in a r a n d o m l y
integral
function
the
of
distribution
the closure
pres-
open crack density surviving + + by eoc(P); o b v i o u s l y eoc(0)=
indicated
crack
loading
to e v a l u a t e
parameters
p,
increasing
the cracks having very low values of e.
simply
density
at
of a continuous
therefore,
distribution,
For
stiffness
the p r e s e n c e
distribution,
it
will
be
possible
the integral d i s t r i b u t i o n F +ij(P)
to
of the fab-
ric tensor. For
stress
is more complex.
paths
different
At a given
from the
stress
level,
isotropic one the situation the global c o m p l i a n c e
is the
sum total of the following compliances: -
the c o m p l i a n c e of the matrix;
-
the c o m p l i a n c e d e r i v i n g
-
the
compliance
from the surviving open cracks;
deriving
from
the
sliding
of
some
of
the
cracks
initially open which were closed by the stress; -
the
compliance
cracks
when
deriving
the
shear
of
the
a D.C.
formulation
deformability
deformability.
The
of
each
final
the
stress
friction between the crack In
from
sliding
induced
by
of
the
initially load
closed
overcomes
the
surfaces. it
is
easy
crack
(or
to evaluate set
of
the
cracks)
contribution
to
the
results will o b v i o u s l y not c o r r e s p o n d
global to that
valid for an elastic body. For of
cracks,
tribution,
instance,
let us suppose
normal stresses between fore
be
resents
that
a rock
contains
a planar
set
some of which are open, with a given crack d e n s i t y dis+ eoc(P ). In the closed cracks of the set, d i f f e r e n t residual
characterized the crack
the faces will be present; by
density
an
integral
the set will there+ d i s t r i b u t i o n ecc(P), which rep-
relative only
to the cracks with
a residual
normal stress greater than p. For
a uniaxial
compressive
loading
path,
the axial
and
lateral
c o m p l i a n c e are given by: 1 16 1 - ~2 _ 2m m + + E-- + -3 - eoc(PA) c°s28 + 16 3 1- {eoc - eoc(PA) m E E m m + % + ecc - ecc~PB~K~A~. ,. ,-,
M33
=
+ (28)
212
!
Vm
=
MI3
16 1 - 92 m 3 Em
Em
+ {eoc - e o c ( P A )
+ }K(8) + ecc - ecc(PB)
(29)
where K(e)
= s i n e c o s e (sine c o s e
K(e)
= 0
o>~
- tg~ cos28)
(3O)
P A = ~a c ° s 2 e
PB = aa
sin6 cos6
- t@# cos28 tg~
3.4.
Loading"
Up in
the
load
"Undrained
to n o w
case
is
in S a t u r a t e d
the d e f o r m a b i l i t y
that
so
(31)
the
slow
cracks
that
no
of
are
water
dry
Rocks
the
rock
or
"drained",
overpressures
has
been
evaluated
that
are
is
induced
only
when
the
within
the
cracks. In
undrained
is a l l o w e d a planar on
out
of
set of
the a s p e c t
and of
Km
and
ratio
models
of
are
of
the
not
the c r a c k s
rock,
only
through
on
is w h e n the
the
the
no
normal
crack
flow
of w a t e r
compliance
density,
stiffness
but
parameter
shown
of
bulk
moduli
(O'Connel value
e = 10,
magnitude
in Fig.
7.
The
respectively
and B u d i a n s k i i ,
of
1976
corresponding
10 -3 , the shear
results
modulus
GI3
the and
to of
a
crack
the
is
solid
D.C.
not
at
" tI
to
a a = -2-~--(pI - g v ) + [u I + 2-G--(Pl - ev )] e x p ( - k ( t I - t)) (4.14) o o
u(t)
cement
takes
= P(tl)
is
have
u(t I) = u I and
obtained
either
from
P(tl)
(4.14)
= PI"
for
The
t~
~
or
ultimate from
displa-
(3.12)
for
Pl = P~"
first
A
example of
circular
steel-yieldable
together
by
certain
of
magnitude,
pressure pressure
is
kept
reaches
Pmi and
means
stops
Pmf
U-bolts
the under
the
yieldable
shaft
the
clamps.
sliding
If
joints
control.
value
support
rings;
(Cristescu
the
are
The
when
the
pressure
has
yielding
et al.
dropped
2n~dM = L R g d (sin~ + ~deOSa)
ground
sliding
2n~sM : L R g d (sin~ + ~seOS~)
is
the
overlapped
one ends
pressure so
starts
that when
made
from
are
held
reaches
a
the
ground
the
ground
(1987)) (4.15)
to (4.16)
259 Here
n
torque the two
is the of
a
number
nut,
of U-bold
the
shaft
I P[ "'. "
llol
d
the
bolt diameter, a the
II
angle
t
between
the
c"
surfaces
ents
respectively. pressures
I/ I
.
.
I I ~. I
x~ ~
1/ AM,,
O0 ,af v U0 I 20 i~
are
illustrated in fig. 4.4. The pressure
%@,,:,,
-/ U ......
.
pmf V --~ -- - - t I l #
~s and ~d are the static and dynamic friction coefficiThese
I I "o q~ I /~/~ " ~ / / / ~ 7 ~ ~L"
"d'
I .
(typical for the kind of shaft ring) and
u,=:
i\< -
--~-[---.~• . . . . . . LI I
--T -- -- - - - ~ I I
" \
ujluflul •2
a
aft v 2 Oo
( 6-v_ pm i )
,4
Fig.4.4. Variation of pressure and radial displacement in a yieldable steel shaft ring.
varies between these values
~TL~ // •_ _ "~
and
two
tightening
ring, li'~." Jl '
friction
M the
"~ ?°
g a constant (ranging between O. 15 0.20),
in a joint,
L
spacing between rings, along
thetunnel'RtheCv~ radius of curvature of
clamps
until
stabilization is obtained. It is easy to find the number of slip-creep cycles, the time during which a cycle takes place, imate pressure etc.
the ult-
~
/
/
F
~ plank
siders a lining made of circular
segments
concrete
of
panels
reinforced with
wooden 0
strips inserted between the longitudinal joints of the panels
(see fig.4.5)
(1988 a)).
(Cristescu
It is assumed
that
the reinforced concrete panels are much
more
wood
for
and
rigid this
than
the
reason
the
entire possible deformation of the lining
is essentially
to the compressibility
due
of the
wood planks. First was studied
Fig.4.$. panels
Reinforced concrete lining with inserted wooden strips.
u
260
the
compressibility
to the fibres.
Three
of
the wood
planks,
cases were
considered:
and wet planks which were previously tionship
between
when
the compressive
compressed
perpendicular
dry fir planks,
wet
already once compressed.
stress
and the reduction
planks
The rela-
of thickness
w is found to be of the form = Aw 3 + Bw 2 + Cw with A, B and C material arized, planks
for the
vergence
constants.
convenience,
inserted
between
(4.17)
in
pressure
the at
in the lining
This relationship
rock/support
of this interface
analysis.
circumference,
the rock/lining
can be also line-
then
interface
If there
the
and
the
radial
linearized
versions
equation
of
analysis.
Several
sure
prescribed
was
the
'>
wet
and dry
also
which
examples
timing t o the lining 4.6;
are
support and
can
were
by
a
possible.
con-
be
back
were
is
the
constitutive
included
in
the
rock/support
In
analysis
considered
(4.18)
This
considered.
is to be installed.
planks
n
become
P = b ~ c [A(2~(u n- u°) )3 + B(2~(u n- u°) )2 + C 2~(u n- u°)] and
are
relationship
it
all was
The results
the
ultimate
computed
at
are shown
for two cases:
4 or
•
wet
A
o
wet
2 nd [oading
A
o
wef
nonlineor
linearized
in fig.
mode[
model
I
,~- - ~ ' relative
..o~7./ o +
.4:+
u
displacement
u°
F i g . 4 . 6 . Variation of pressure and radial displacement at the rock/lining interface for 4 and 10 wood planks inserted along circumference.
what
10 planks
]
i
pres-
261
inserted 4 cm.
in
The
the circumference.
geometry
is:
a = 170 cm,
the
case
of
of
the
for the timing
planks
the initial
number
radial
planks
of
the
)u~ - o
a
the
cases
formulae
convenient
rock
by
+ Pl
v
rock/support
pressure
(or thicker)
rigid i t y
due
of
to creep
2Go +
the
followed
above
version
depth
For
350 m
instance
(4.18)
we
in
obtain
(4.19)
the most
(loading
all
linearized
displacement
a complete that
under
of
the
R = 156 cm.
was
2Go
%
yield i n g
at
planks
o I
R[(~_~ u° = ql
is
in coal
and
of the
I 2G
-
ao v
Thus
a
thickness
excavated
c = 150 cm
and
I t o = ~ in Uo
clusion
initial
to: 1 2--G
when
tunnel
b = 166 cm,
wet
The
which
unloading)
support
(ql
considered.
in
All
are d e t e r m i n e d
can
lining,
from
that
be done.
point
of
obtained
with
a
are
material
already
wet.
(4.20))
in laboratory
A major
the
previously
which
formula
the
was
(4.20)
analysis
were
and
support
b - c --S1Wl]. R
-
is
without
In
is
the
constants
con-
view
of
greater
compressed
this
case
the
smallest
involved
from
in
the
tests.
5. R O C K - S U P P O R T I N T E R A C T I O N A N A L Y S I S FOR E L A S T I C / V I S C O P L A S T I C ROCK For
elastic/viscoplastic
consitutive
equation
(2.1),
differential equation describing the lining~rock interface a s
and
(3.2)
we g e t
= -
Thus while
the
+
the
k
instantaneous
the u l t i m a t e Two
solution stresses further
-
in
response
of
(sudde~
reaction the
the
rock
convergence
in
the
of constant
pressure
during
absence
of
were
the
creep.
a lining
is in place
blast)
satisfies
problem
surrounding
constant
(3.5)
(5.1)
simplified was obtained
called
remain
~e
ground
solutions
from
the motion of
with tunnel
(i.e.
(p = const.)
governed
by
(3.6)
(3.7).
given
With
is
(Cristescu the vary
this
(1988b)).
assumption at
that
excavation
assumption
p = 0)
or
is governed
when by
the a
A the but
wall
support
262
W IP u(t)
p - c
a
assuming of
WI
=
20
that
for
H(I v +
p remains
the
primary
8H
- --~--)~c e 8H-a
constant stress
8H'c't {I - e x p [ ~ T ~
during state
creep:
and
t
here is
_
k c
W IP
the
t)]}
is
(5.2)
the
moment
value
when
the
C
deformation
by
t ~+ ~ we o b t a i n
creep
begins.
the equation
If
in
(5.2)
for
p = p~ = const,
of the ultimate ground
we
make
reaction curve
W IP ,8 H
u, ~-
H(I - T
P" -- Ov =
2G
or the r o c k / s u p p o r t
+
.......
interface
)Ta-~oI
8H.o
T@
.........
(5.3) P = P~
stabilization
curve
corresponding
to
the
particular loading \ 0.2
tory
\\ \
ci~Ib>~
\ \
his-
consid-
\
ered, i .e. due to a fast
\
excavation sudden
dec-
rease u~
from
of o
0.1
p~
which
afrecons-
obvious the
a
value
terwards mains
p
to
v
certain em c O
a
that u~,-
p~
relationship 0
o
@ F-= ' 0.008 E v 0.01 o 0.015 20 a relotive displacement { u )
0.02
(5.3) a line
Fig.5.1. Variation of pressure and radial displacement of the rock/lining interface for yieldable steel shlaft ring and various loading histories, Crosses mark incipient failure, while the border line and the dotted l i n e a r e two p o s s i b l e ultimate ground reaction curves (Cristescu (1988b)).
coal
is s h o w n for w h i c h
by
border
line
the
ultimate
ground
reaction
not
straight and t h a t
this line passing
is by
the point u = 0, P : ~v" = AS an example
5.1
is
in
obtained
fig.
for
263
H(a,~)£
~a°
CoSin(~+¢)+c
~ )2+bo~ * +
(
I
if 0DH Do r
I -
DO 0
~-~z"
(5.7)
265
This system was integrated with a p p r o p r i a t e initial and b o u n d a r y conditions using finite d i f f e r e n c e method (Cristescu (1988a)). The initial c o n d i t i o n s are obtained from the elastic solution since it is assumed that due to a fast excavation, in a very short time interval the rock response is e s s e n t i a l l y elastic. The b ou n d a r y c o n d i t i o n s are formulated at infinity (at far distances stresses and strains are those from the primary state) and at the t u n n e l / s u p p o r t interface (the pressure varies a c c o r d i n g to the r e l a t i o n s h i p c h a r a c t e r i s t i c for the kind of l i n i n g considered). If the pressure at the tunnel surface d e c r e a s e s s u d d e n l y from to a certain value which is afterwards kept constant, then the V
u lti m a t e ground r e a c t i o n curve which is obtained for a tunnel excavated 350
m,
in coal at the depth
is
shown
in
by curve b (dash-circle).
The
ulti m a t e
ob-
ground
tained
with
solution
Thus
the
more
significant with
solution. lines
the
marking
tions same
lead
a
tion
how
volume be
to the
for
P/a v < 0.3
behind
the
can
ask
the
ques-
is
the
of the rock which
will
microcracking
The
damaged and
the a d d i t i o n a l
how
big
loading amount
by
of
this
failed
rock
is
For
relatively
small
of p the amount
of the
damaged cant
rock
mainly
shown
is
on the
5.2.b. values
may
~A
0 0
be
o.ol
u
o:02
relative displacement ~Fig.5.Z. a) Ultimate ground reaction curves obtained with simplified method (curve a) and with numerical method (curve b), onset of failure curves obtained with simplified method (curve c) and with numerical method (curve d), at the depth of 350
m.
is taking
important
ultimately
lining.
lining
Ih3 m t
÷A
the
solu-
practically
one
,~ 0.1
threshold two
of constant pressure place,
÷&
is
result.
failure
0.2
the one
concerns
the
Though
÷&
~
simplified
the
failure,
cb I! II
u') u)
a
ulti-
method
than
What
\[
obtained
numerical
obtained
line
the
displacement
with
of
as
':
O.3
simplified
shown
(dash-dot). mate
reaction
the
is
04
fig.5.2.a
in
fig.
signifi-
if there are also
. ~>0.3 Q.
u)
o.2
CL
>~ o.1 _o
0 1.1
relative radius rio Fig.
S.Z. b) The amount of damaged rock behind the lining.
112
266
some
weak
structural How L@I
~ 5
', I
',1
"1
other
weaknesses
etc.
fast
damage
•
planes,
propagates
in
the
in
fig.5.3
of
pressure.
of
the
the
for
damaged
= 0.78
01
fast
I
1.2 relotive
radius
two Fig.5.3. Propagation of the damage in the rock surrounding the tunnel surface.
levels absence
amount
rock
is
and
5 days,
mainly
days.
of
quite
lasts
for
though
the
deterioration
place
rio
shown
it starts at t =
days
than
the
the
the
is
three
In
lining
significant:
more
rock
in
The
takes
the
first
presence
of
a
constant pressure is certainly
reducing
the
the
damaged
amount
rock
of
behind
the
lining.
6. T U N N E L
OR B O R E H O L E
In
to
order
study
STABILITY
possible
the rocks s u r r o u n d i n g a tunnel hole,
failure
and
loosing
of stability
of
(in the presence of a lining) or a bore-
let us consider a case which is very unfavourable.
The most impor-
tant factor influencing possible ~ailure and s t a b i l i t y is the ratio between the horizontal a h and vertical ~v far field stresses.
Let us con-
sider a case when this ratio is quite distinct from unity, Sh = 0"2~v"
The
depth of the tunnel
encing s i g n i f i c a n t l y
is c e r t a i n l y another
failure and stability,
for instance factor
influ-
besides the m e c h a n i c a l
pro-
perties of the rock. In order to make an analysis sary first
to study moments
the
stress
following
ation the rock response
of the failure,
distribution excavation.
around
Assuming
is elastic,
the
it is first neces-
circumference
that
after
a fast
the stress distribution
in the excav-
is obtained
from the well known formulae a
arr
2
h +2 a v ( 1
= p--~ + r
-
-~- a ~2)
+ ~h
2- ~ v ( 1
-
4a22 + ~ 4 4 ) c o s 28
r
r
r
(6.1) a2
gee
:
-
P --2
r
oh + av +
2
(1
2
+ ~'~) r
-
~
h
- ~ 2
v (1
+
~a r
) cos
2£
267
ev
ah are
=
- 2a2
2
(- I
r2
3~ 4-) sin 20 + r
(6.1) = 0 h - W(O h - O v ) 2 ~ e o s r
OZZ and
the
displacements
I + ur
from
(see
2e
Cristescu
(1988a))
2 a4] - V ) ra - - r 3 Cos
a2 ah + av a 2 a h - av[ { - p r-- + + 4(1 2 r 2
V
~
2e} (6.2)
I + ~ ah - qV[2(1 ue =
E It
of
the
is u s e f u l
depth
: 0.2a v = 0.0196)
(see
fig.6.1.
The
is m a r k e d initial
point
rupted
line.
bourhood tensile
of
the
stresses,
plane
lO~-~i
~L
E
--
uo!s~oo
276
FIGURE 4 Outcrop of Lisan Fro.showing convolute lamina in a specific bundle of lamina, FoJdsare tilted downstream.
FIGURE 5 Enlarged view of a convoIute fold. Note thrusting at the forward end of fold.
FIGURE 6 Low angJefauR in a specific bundle of tamina. Note undeformed overlying and underlying tamina.
277
deposition on
the
of
than at an angle to it, and the form of d e f o r m a t i o n depends
direction
deposition
specific to
the
plane
bundle
lamina
of
Shear
stress
convolute
folding
and
thrust
(Figures
4,5,6).
Shear
deposition the
restriction
the
accompanying
was
the
result
remoulding shear
of
and
sensitive
clays
only
an
Formation,
since
achieve.
Thus
flow
dependent
on
a two-fold
extrusion
by
an
saline
later
to
at
type
plane in
an
angle
faults
which
the
is
dilution
process
1952).
of
be
specific
leading
to of
in the present
in
the
for
the
to
Lisan
difficult
seem
pore
of
present
the
is
deformation
case
causing loss
related
water
saline
lamina
load)
often
However, pore
of
deformation
consequent
determined
saline
of dilution
that
(external
characteristic can
bundles
suggest
floods
pore
and Northey,
load,
specific
and
conditions
external
the
features
underlying
water
sensitivity
complete
in
stress
normal
structures
freshwater
of
(Skempton
to and
deformation
flash,
apparent
rise
overlying
sedimentary
This
3).
in press).
of
dilution
strength.
(Figure
gives
laminae
(Arkin and Michaeli,
and
to
stress
of
into
The
case
the to
bundles
dissipate
of
leads
to
water
weight
of
be and the
body of water of the flash flood.
REFERENCES
Arkin, Y. 1980. Underconsolidated tion. Sedom, S o u t h e r n Dead Qiryat Anavim, Israel.
sensitive clay in the Lisan Sea Basin. 5th Conf. Min.
Arkin, Y., and M i c h a e l i , L. (in press). The significance strength in the d e f o r m a t i o n of laminated sediments. area. Spec. I s s u e , E n g . Geol. I s r . J. of Earth S c i .
FormaEng.
of shear Dead Sea
Arkin, Y., and Starinsky, A. 1982. Lisan sediment porosity and pore water as indicators of original Lake Lisan composition. Current Research 1981 G e o l o g i c a l Survey of Israel. Begin,
Neev,
Z.B., Nathan, Y., Ehrlich, A. 1980. S t r a t i g r a p h y and facies stribution in the Lisan Formation, new evidence from south of the Dead Sea, Israel. Isr. J. of Earth Sci. Vol. pp. 182-189.
dithe 29,
D., and Emery, O.K. 1967. The Dead Sea, depositional processes and environments of evaporites. Bull. No. 41. Isr. Geol. Surv.
Picard,
L. 1942. Structure and evolution of Palestine, with comparative notes on neighbouring countries. Geol. Dept. Hebrew Univ., Jerusalem.
Skempton, A.W., and Northey, R.D. technique Vol. 3. No.l.
1952.
The
sensitivity
of clays.
Ge0-
ON THE CONSTRUCTION EQUATION
INTRODUCTION
In have
the
been
great
of
in
be
to
describe
engineering
cannot
hand,
many
practice.
solutions
determined
in
S. Dmitruk,
model
The physi c a l
This
[i, 2, 3]. interest suggested
and
soils.
And
initiated
was
a
the
by
loading
himself,
as
well
A. K w a s n i k - P i a ~ c i k
soil
Dmitruk,
from
from
intensive
[4-8,
to name
of or
the not
use
soil
[i]
study a
of
the as
literature
[4-6].
the
and
form
Lysik
models hand,
of
in
mechanics
the one
a
1969 model
raised
as
conventional
reported
great
approach involving
and
rheology
studies
have
DLS
model.
It
to a soil
results
data,
here
was
equation
compression
experimental
nonlinear
of been
some of these].
equivalent
in a triaxial
soil other
ago,
mathematical
experimental
consitutive the
years a
so
cannot
disadvantages.
in
a
On
proposed which
few
these
to
approximate
been
A
a
wide
behaviour.
developed
of
the
classical
why
had
Suchnicka
constructing the
from
linear
model
formulation
differed
of
involved
a
authors
making
area
to
of
have
Despite
limitation
constants
eliminates
on
1977
exposed
by
the
a
models
received
major
apparatus.
distrust
is
elementary
of
and
whether
established
that
number
representing
method
objective
of
models
great
which
soil. not
Apart
linear
test
of
a
models.
H. S u c h n i c k a
in
is
of
(DLS)
definitions
before
There
a body
a
rheological
have
as
developed
hand
that
The question
of
resulted
one
by
and
models
linear
standard
of soil
Such
on
notions
a
concept
model
[i, 2].
the
with
B. Lysik
rheo l o g i c a l
for
different
properties
these
regarded
of
yielded
many the
investigations,
soil
other
tions
decades
uses - s p e c i f i c a l l y
approaches,
far,
three
suggested
acceptance
the
past
number
their
USE OF THE DLS MODEL
Roman Traczyk of Geotechnique, T e c h n i c a l U n i v e r s i t y of Wroc~aw, pl. G r u n w a l d z k i 9, 50-377 Wroclaw, Poland
Institute
i.
OF A CONSTITUTIVE
OF SOIL BY MAKING
of was
sample
apparatus. obtained
specifically
to
answer
soil
might
considered which The by
those
had
the be an been
considerathe
author
reported
by
280
2. C O N C E P T
While physical
many
and
It seems,
OF
THE
IDENTIFYING
reports
mathematical
therefore,
PROCEDURE
are
available
model,
these
advisable
on
are
to present
so that no c o n f u s i o n occurs as to what
the
assumptions
mostly
written
the major
to
in
the
Polish.
formulae
involved
is included.
The e q u a t i o n of state of the DLS model may be w r i t t e n as Ro
7 = A(g where g
Ro
gR~)
+
(i)
is density of external
R° g
stress, which takes the form
~ & ~ i ( ~ ) H ( t - ~i) t - ~. i=l 1
=
R° or
~ ~' (~'~(~ ~ ~)d~
g
0+e
and gR~ denotes d e n s i t y of internal changes, gR~ =
where
~ A e i ( { ) H ( t - ~i ) i=l t - ~i
t indicates
gR~
time of o b s e r v a t i o n of loading effects,
in the state of stress,
is
the
for
being reserved When
function
of
H is H e a v i s i d e
unbalanced
internal
(3)
u shows
function,
changes,
A
time
and e(~) and
e(~)
for the parameters of the model.
the loads
kmi n defined
which is defined as 2 e'(~)H(t - ~)d~ = 0+e t -
or
of variation used
(2)
=
in
the
will be zero. Thus,
acting on the soil are smaller physical
model,
the
density
than the value of
of
for o = const ~ kmi n e q u a t i o n
internal
changes
(i) becomes
% = A T The
(4)
investigations
that kmi n may be,
reported
in principal,
in
the
literature
[4]
have
The concept of the i d e n t i f i c a t i o n p r o c e d u r e was d e v e l o p e d Kwasnzk-P1asczk model
[4].
parameters,
evaluate tests
A,
the
wherein
constant rate
tended
e({)
function
A
e(~),
to zero.
out
by making
availed
herself were long
kinds
involved
of
and
of
determination experimental
the
small
The d e t e r m i n a t i o n
at various
the
use of
applied
time
results
their
of
loading
i.e.
assessment
test results,
derivation
To
creeping
tended
The
the
data.
stain
compression stresses.
of
by A. of
and
of A enabled
on the basis of triaxial
expressions are given
to
a
strain of
the
which for A in the
[4-6].
Laboratory carried
involved
a sufficiently
the formulae
literature
8(~),
loads
after
had been o b t a i n e d and
and
procedure
authoress the
value
The
shown
identified with l o n g - t e r m strength.
on
investigations two
types
of
reported
samples.
Some
by
Kwasnik-Piascik of
these
consisted
were of
281
Jaroszow
clay
of
bentonite.
While
measure
the
of
describing shown
a
making only
the
of
scattering
use
of
of
the
of
it
A
on
intensity
intensity
values.
of
prepared
were
and water
a
given
interval
type
for
the
hand,
the results
obtained
for prepared
samples,
that
anticipation
of
by and
if at
regarded
Taking
moisture
of
the
one
soil.
have
time
content,
(Aw = 2.5%)
obvious
on
of
a for
proved
of
that c o e f f i c i e n t A may be
for
as
used
tests
[4]
samples
becomes
was
independent
intensity
believes
variability
A was
from
taken
strain
Kwasnik-Piascik
that
stress
constant
were
The results of p l a s t o m e t r i c
analysis
depending
small
stress the
others
clay
scattering hand,
the
Kwa~nik-Pia{cik
Jaroszow
structure,
stress,
regression
characteristic
account
values
state
slightly
a
undisturbed
the state of strain.
all. Thus, as
an
into
content
and
the on
A being
of
greater the other
a constant
ought tO be reconsidered. According values
of
the
to
the
e(~)
assumptions
function
were
be
described
by
the
the
found
variation of the state of stresses. e(~)
of
model,
to
the
vary
and
form
and
the
depend
on
the
K w a ~ n i k - P i a s c i k has suggested that Ro of g which takes the form of G ~
integral
and may be written as
GT = Analysis plot,
n-i Ro ~ gi A~ i=0
of
regressions
t f 0+e
=
8(~)
= f(G T)
Ro g
d~.
(5)
revealed
that
they had a similar
irrespective of what kind of loading had been applied. Although
the
GT or
high
the
investigations
probability
equation
of
soil
accurate
formulation.
considerable 2-the the
undisturbed
becomes
of
of
What
small
here
seem
constructing
DLS
model,
they
accounts
for
this
results
for
prepared
of
clay
during
that
when
the
difference
Jarosz6w
changes
obvious
success
terms
scattering
unusually
volumetric
in
discussed
between
samples
exposure
similar
the
which
to
the do
constitutive not
shortcoming soil
physical made
isotropic
investigations
to c o r r o b o r a t e
were
them
enable is
samples,
and
parameters
of
resistant
to
stress. needed
an
l--the
Thus,
to
it
examine
a
wider v a r i a b i l i t y interval for the physical properties of soil. The necessity those
of
fact, of
that
volume
distinguishing
the deviator.
variations the
Hence,
effects
occurred, of
the parameter
the of
accounted
spherical the model
for
the
tensor
and
were defined
as
where
A = f(w,e,Oo(~) ,t)
(6)
8 = f(A,w,e,~(~),t)
(7)
w
indicates
water
content,
e
denotes
porosity
factor,
ao(~)
282
describes deviator
variation stress,
of
isotropic
~ stands
for
stress, T(~)
time of
is used
stress
for variation of
variation,
and
t is time
during which stress effects are observed. The
choice
equations
(6)
significant
of
and
the
(7)
effect
terms
results
on
the
from
and,
consequently,
predicting
the A and e values,
incorporated
assumption
that
of
A
To
to
and
8.
examine
a series
of
the
they
in
exert
determine
possibilities
triaxial
a
this
compression
of tests
were carried out.
3. L A B O R A T O R Y
The
parentheses
the
values
influence
(with outflow)
in
TESTS
available
the state of stress
/
1 = ~
data
sets
show
that
it is c o n v e n i e n t
in terms of stress intensity.
_ a2)2
(al
2
+ (~2 - a3)
+
to describe
Hence, we have
2
(a 3 - ~i)
(8)
which becomes =
(o I
-
03)
(8a)
for axially s y m m e t r i c a l stress. To
describe
the
state
of
strain
the
author
availed
himself
of
the term of strain intensity. Thus, /2/ = T
(¢I - ¢2)
2
+ (e 2
and for axially symmetrical
_
¢3
)2 +
(e 3
- el)
2
(9)
strain
= ~(¢ 1 - e3). Equations variations necessary
(7)
occur
and
in
to perform
(9a)
the
(8)
are
volume
measurements
valid of
at
the
of
the
assumption
sample.
Hence,
volumetric
changes
in
that
no
it
became
the
course
of the triaxial c o m p r e s s i o n tests. The prepared Poland.
laboratory from
The
clay
method
homogeneity,
thus
consolidation.
investigations collected
of
creeping
to
tests
involved
the
preparation
contributing
The
in
Edmund
applied the were
in
samples the
abatement carried
which
openpit study
of
had
enabled
of d e f o r m a t i o n out
been
Jarosz6w,
by making
high
during use
for
two loading schemes. Scheme 1 The
samples
were c o n s o l i d a t e d
at d i f f e r e n t
pressures.
Following
283
completion axial
of
the
consolidation
procedure
loading
was
applied.
results
relations Scheme
A = f(e)
The
tests
A
identical
the
Axial
for
The soil
which
the
in
closed
and
determining
pressure
the
began
determination
A = f(e)
samples
of
of
different
to
makes
24 h,
rise.
Water
it p o s s i b l e by
block
and
specimens procedure
was
0.5 h,
porosity
relationship
same
to obtain
apparatus
after
to loading.
the
the
consolidation
the
applied
of
from
in order
was cut off prior
compression
increased
of had to
72 h and
144 h
outflow
from
to define
e({)
conducting
triaxial
tests.
Failure shearing
at
was
nature
cut
After
pressure
loading
the
were
12 days
properties. the
moment
the sample
defining
Samples
at 0.20 MN/m 2 for
physical
0.35 MN/m 2.
at
~o(~).
completed,
for
used
was
and A = f(t).
aimed
and
consoli4ated
form
were
outflow
2
between
been
The
water
at
tests
a
were
constant
at a c o n t r o l l e d
carried
rate
rate of
of
loading
out
table
by
the
motion
following
(method
(method
II).
scheme
1 revealed
I),
two
methods:
and
shearing
4. R E S U L T S
4.1.
COEFFICIENT
Creeping of
A = f(e). A
tests
The
A
involving
results
are
plotted
in
the
Fig.l.
To
linear
behaviour
investigate
[~e/M~;
0D2
0020
0D15
0010 ~
,
,
,
i
~05
Figure
1.
Coefficient
,
,
I
730
i
~___J
i
,
i
L
~75
A as a function of Jarosz6w clay samples.
,
,
I
i
, __
~20
porosity
~
I
725
factor
for
the
284
behaviour
of
press u r e
A = f(t)
analysis.
observation,
t,
the h y p o t h e s i s The large
longer
study.
the values
than
of
Despite
these,
to use
effect
of A
the
in
Oedometric
coefficient
300 h.
of
Obtaining
convenient
of
were
this
factor function
c re e p i n g There
and
a
were
subject
processes
were
no
A = f[ao(~)]
number
[7] it
on
constant
with
reasons
to
time
for
of
takes
a
this
the
kind
of
of
variation
time
of
ignoring
isotropic
the
desired
and
the
stress
of
for
the
it
A is
to d e s c r i b e
relation may
of
that
density
stress
using
further
dependence show
a
initial
when
calls
earlier
Thus,
state
requires
identical
to d e s c r i b e
performed
stress.
of
of
results
long
is p o s s i b l e
integral
relationship
samples
investigations
the
and
the
experiments
described
on ~o(~).
porosity
of lack of correlation.
number
method
constant
Analyzed
investigation
properties.
the
a
in the apparatus,
regression
the
at
be
between
written
as
follows A[~o(~ ) ] = A O - f[G ~O] . For relation
the
was
C
is
= A o - CG
constant.
determined
beings.
do
no.14
an error
easy
apparatus. yield
to
INTERVAL
following
8(~)
and
plot
of
error
which
shows
values
of
lower
porosity
a
method of
method
the
at the
initial
eliminate
only
sufficiently
of
was
analyzed
be
of
e
for
attributed
the m o m e n t
by the plot
internal factor.
of
was
using I
is
primarily
at which
the
the e - f u n c t i o n
changes It
by
method
markedly for
this
lower reason
I.
which
Unfortunately,
GT
function
should
illustrated
for
CHANGES
determination
is best
application at
The
considerable
II replaced
moment
included
the
n o r m a l l y c o n s o l i d a t e d and Go the A - G relation is linear.
between
scale.
inaccurate
This
samples
The
not
The
necessarily
sample
2,
clays
relationship logarithmic
that m e t h o d
is
for
The
in Fig.2.
exact
Hence,
OF UNBALANCED
process
scheme
(ii)
FUNCTION
the
to
,
4.2.
given
for
0o
of stresses,
in
than
according
variation
plots
to
performed
established
A[So,t] where
test
(i0)
II
process
if
the
accurate
stage the
made
it
began, of
the
force
apparatus
possible but
is
measured
until
to
define
~ - ~
investigation.
available
indications
to
the
in
the
higher
the
relation The
error
side
the
author
did
stresses
were
285
z;C
3.0
2.0
1.0
,6/
08 O.e
02
c~N~ a05
Figure
Z.
That
appropriate.
is One
why of
two these
r e l a t i o n s h i p was linear In
the
other
020
Ct30
0~0
Function of unbalanced internal changes by triaxial compression tests involving (at constant rate of table motion).
determined
applied.
0.;0
method,
methods made
of
use
calculating
of
in the initial
the
first
the
~0 (~)
assumption
stage of the
two degrees
of
no
internal
changes
occur
for
there
loading
two
seemed
that
to
be
the ~ -
testing
as they showed values lower than kmi n ([i]). Hence, that
versus GT method I
procedure.
were
neglected
it has been assumed degrees
of
loading
(kmi n < 0.030 MN/m2). When behaves
the
as shown
~ - ~
relation
by Fig.3.
is
assumed
The d e p e n d e n c e
to
be
linear,
the
plot
of e on G T may be described
with great accuracy as e = CI(GT)C2 + C 3. While varied so
C1
increased
only slightly.
they
should
be
(12) with
the
increasing
porosity
The values of C 3 showed no relation
regarded
as
incidental,
taking
into
factor,
C2
to porosity, account
measuring problems dealt with at the initial stage of shear.
the
286
2.00
;.40 '
18
OflO O.6O
0/0
Q20
o.,o
/2
0,08 eo6
78,,."
0,02
0,0;
by
triaxial of
Fig.4.
0,02
0,05
030
0"20
0,30
Figure 3. Function 0(~)versus GT d e t e r m i n e d compression tests involving method II (at constant ~ncrease intensity) and making use of the assumption that the T y relation is linear at the beginning of the process.
Neglecting
the
These
be
parallel
0.03
may
first
two
interpreted
or convergent,
which
degrees as
leads
of
loading
a pencil
of
gave
the
straight
to expression
(13)
plots
lines
and
of
either
expression
(14), respectively, e = CI(GT) C2
(13) Co
e = CI(G T + C2 ) Using the
relation
increasing
slight
of
to separate
only.
(14) for
(14)
(13),
porosity
variations
by virtue
. the C 1 values
factor,
whereas
The d e t e r m i n a t i o n the plots
the q u a n t i t i e s
of Fig.4
occurring
were the
found
to
values
of
of the CI, failed,
as
in parentheses.
C 2,
increase C2
with
underwent
C 3 constants
it was It has
impossible only
been
287
220
1/,o 12o ~o O.6O
0.~0
020
0,to OZ~ 0.o6
024
~;
&02
0,03
~05
~
~
Figure 4. F u n c t i o n by method
shown
that,
II
at
if
the
C1
assumption beginning
and
C3
are
030
8(~]
that no internal of the process.
assumed
increase with a rise of the porosity
versus OT determined changes occur at the
constant,
the
values
of
C2
factor.
5. C O N C L U D I N G C O M M E N T S
Analysis in terms of Gkmin
of
results
(GT - Gkmin), ~ = i= 1
kmi n iA~ A~
enables
the
8({)
function
to
be
described
G kmin being given by Gkmi n or
=
t f 0+¢
k ~ min t .
Relation e = f(G T) is then likely to take the form
(15)
288
8 = C I ( G ~ - Gkmin) c2 H(G T - Gkmin), w h e r e H(G T - G kmin) Taking on our e
the
into
account
invariability
interpretation can
is H e a v i s i d e
be
ourselves
makes
represented
f u n c t i on. plot
C 2 for
use by
of the s t a t e m e n t
Fig.5 gives
the
of CI,
(16)
of the
the
of
relation
a wide
statement
quantity
_
_
(16),
that the c h a n g e
that
the we
may
conclude Thus,
if
variability
of
may
of p o r o s i t y
the p l o t s of 8 for a s s u m e d
we
of p o r o s i t y .
G kmin ,
200
~/*0 _
range
also
avail
is included.
kmi n, CI, C 2 at
jl
_
700 0£0
~60
0~0
Q2O
0 . 7 0 _ _
~ 1 ~
~06
4
2
O~ ...........
/
002 ~
i
I/
Cr[MNI~J 007
ao2
o~
o o~
070
020
0~
Figure 5. F u n c t i o n e (~) versus G T c a l c u l a t e d by v i r t u e of e q u a t i o n (16).
&~ = 0.015 M N / m 2 and &{ = 0.166 h.
6. SUMMARY The
considerations
presented
in
this
paper
indicate
that
the
289
results
of
despite
the
equation
of
the
investigations
fact soil
adequately.
But
parameters
of
that in it
the
terms seems
the
performed
problem of
the
to
be
equation
of
DLS of
may
so
far
establishing model
has
particular be
deserve
not
a
constitutive
yet
been
importance
determined,
attention
using
solved
that
the
standard
laboratory apparatus.
REFERENCES I.
S. Dmitruk, B. Lysik, H. Suehnicka, Fundamental soil strength, Archiwum Hydrotechniki, 1973, Vol. (in Polish).
2.
S. Dmitruk, B. Lysik, H. Suchnieka, Problems relations in soil mechanics, Studia Geotechnica, fasc. I.
3.
S. Dmitruk, Problems of Representing Geological and Engineering Processes in Openpit Mining. Warszawa, Wydawnictwa Geologiczne, 1984 (in Polish).
4.
A. Kwagnik-Piaseik, Some problems dealt with in the identification of the DLS model. Ph.D. thesis. Technical University of Wroclaw, Institute of Geotechnique, 1978. PWr I-I0/K-242/78 (in Polish).
5.
A. Kwagnik-Piadeik, On the identification of the DLS model for a granular medium, Archiwum Hydrotechniki, 1981, Vol. 28, fasc.
6.
A. Kwa~nik-Piagcik, On the identification of the DLS model for a granular medium, Archiwum Hydrotechniki, 1981, Vol. 28, fasc. 2 (in Polish).
7.
R. Traezyk, Analysis of the indentification procedure for the DLS model. Ph.D. Thesis, Technical University of Wroc~aw, Institute of Geotechnique (in Polish).
problems of 20, fasc. 4
of physical 1973, Vol. 4,
I (in P o l i s h ) .
8.
R. Traezyk,
On
the
identification
procedure
Archiwum Hydrotechniki, 1982, Vol. 29, fase.
for the DLS model, I-2 (in Polish).