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An extended Cam Clay model for soft anisotropic rocks
Computers and Geotechnics 2 (1986) 69-88
AN EXTENDED CAM CLAY ~K)DEL FOR SOFT ANISOTROPIC ROCKS
Roberto Nova
Department of Structural Engineering Milan University of Technology Piazza Leonardo da Vinci 32, 20133 Hilano, Italy
ABSTRACT
The mechanical behaviour of soft sedimentary rocks in triaxial compression is modelled by means of a constitutive law which has been formulated by extending the original Cam Clay model. The geological material is assumed to be linearly elastic-plastic, strain-hardening, with fixed transverse isotropy. Theoretical predictions are compared to observed behaviour at different confining pressures of specimens of diatomite with various bedding inclinations. Although quantitative agreement is not always satisfactory, the trend of the tests is qualitatively well matched, what proves the paradigmatic value of this type of model not only for soils but even for soft rocks.
INTRODUCTION Rock formations of sedimentary origin like calcarenites, sandstones are
frequently met in Italy as foundation subsoil.
diatomites,
From the Civil
Engineering viewpoint [1], strength and deformability of the intact the controlling
factors
in
structural discontinuities characteristics of From an
are
widely
design, spaced,
since
fissures
whilst
the
rock and
are other
mechanical
the rocks are rather weak, because of their high porosity.
extensive
calcarenites and
foundation
mr
turfs,
study
performed
Pellegrino
at
the
[1],[2],[3],
University it
of
Naples
on
appears that for small
confining pressures these types of rocks exhibit a rock-like
behaviour,
i.e.
quasilinear elastic behaviour and brittle failure, whilst after a well defined threshold, the
stress
strain relationship becomes non linear, accompanied by 69
C o m p u ~ and Geo~chnics 0266-352X/86/$03.50
© Elsevier Applied Science Publishers Ltd, England, 1986. Printed in Great Britain
7O large plastic strains and ductile in nature, more similar to the behavio1~r
of
a soft soil than to that of a hard rock. Similar results have been obtained diatomite from
the
by
f4ontagne d'Andance,
Allirot
and
Boehler
[4]
on
a
Ardeche, France, whose structure is
made of a regular alternance of diatom valves and fossilized debris. The experimental description of
the
evidence behaviour
therefore of
such
suggests materials
that can
the
mathematical
be based on the same
concepts on which the constitutive models for virgin soils are founded.
]here
appear to be two main intuitive differences.
First, the initial yield surface
does not coincide with the origin of axes in
the
assumed for
virgin soils.
space,
as
usually
In this respect, lithification acts as an apparent
preconsolidation pressure. markedly anisotropic.
stress
Second, the
From
behaviour
of
sedimentary
rocks
is
an engineering standpoint no sensible result can
be arrived at if anistotropy is not taken into account. The aim of this paper is to confirm these intuitive considerations on the basis of a comparison between theoretical predictions and actual behaviour.
First
anisotropy.
the
original
experimental
Cam Clay model will be extended to cope with
Secondly, on the basis of some experimental results, a
to determine the constitutive parameters will be shown. between calculated
results
and
experimental
evidence
in
several triaxial
compression tests on specimens at different inclination with major principal
stress
direction
will
be
procedure
Finally, a comparison
presented.
respect
to
the
A discussion on the
results obtained, on the potential and limitations of the model proposed
will
end the paper. lhe main effort will not be directed, however, to the exact experimental curves would be
necessary,
for
which
but
phenomenological behaviour
rather of
matching
of
an 'ad hoe', extensive experimental programme
soft
towards
the
anisotropic
understanding rocks
as a whole.
of
the
Further
refinement will be necessary to achieve the goal of formulating a constitl~tive model for such materials that enjoys full validity even
from
a
quantitative
point of view. In the following, the term stress will be always used
in
the
sense
of
effective stress.
THEORETICAL CONSIDERATIONS
Sedimentary rocks may often be idealized as homogeneous but isotropic materials,
where
the
axis
of
symmetry
transversely
is normal to the bedding
71 plane.
We shall define as intrinsic reference frame, a cartesian frame
one axis, Xv,
where
say, coincides with the symmetry axis, and, consequently, the
plane of isotropy is the plane (XH1,XH2) , see Figure I. Xv
i
XH2D"
f
Figure 1. Intrinsic reference frame.
Since experimental evidence suggests that for low the material
hydrostatic
pressures
behaviour is approximately linear and quasi reversible, we shall
assume that linear elasticity is suitahle in this range, lhe constitutive law written in the intrinsic reference frame is then given by
eV
SH1
1 EV
vVH E~4
~VH
EH
~l
, CH2~
E~HH
EH symm.
YVHI I
YVH2 I YHHJ
(1)
1 0
GVH
0 1
GVH
0 1 GHH
where E
is the longitudinal elastic modulus in the direction of the axis or v symmetry, while E H is the corresponding modulus in any direction in the isotropic plane, ~VH and ~HH are Poisson's ratios and GVH and
GHH
are
shear
72 Since GHH is Liae shear modulus in tile plane of isotropy
moduli.
EH
g!i H :
(2) 2(I+~HH) Equafiinn 1 i s v a l i d
threshold value.
when
the
hydrostatic
then
given
On
lower
than
a
the
lhe limit of validity of
Equation
I
by a yield function whose expression is a priori unknown
and that could be determined programme.
is
It is straightforward to assume that this value will depend
on the particular stress path Followed. will be
pressure
basis
only of
by
means
of
an
extensive
experimental
some results published in [I], we shall assume
that the yield function is given by an expression similar to that of Cam Clay, which in triaxial compression reads
f : q + Mp In(p/p c) = 0
(5)
where
q ~ rSl -
'~3
(4)
1 P ~ -- (~1 + 203) 3
(5)
and Pc is the threshold pressure in taken positive
hydrostatic
compression.
in compression, as well as strains.
and minor principal
confining pressure.
stresses
respectively.
The
~I
latter
Stresses
~3
and
is
are
are the major equal
to
the
Figure 2 shows a comparison between the calculated y i e l d
surface and f a i l u r e locus and the observed y i e l d
and
failure
points
for
a
calcarenite (C2). To take account of anisotropy a generalization of Equation 3 to the stress space is necessary.
The simplest way to do that ls to assume that for
an i s o t r o p i e materlal the y i e l d function can be obtained by r o t a t i n g 3 around
full
Equation
the hydrostatic axis, following a procedure similar to that employed
in [5] to smooth the Mohr-Coulomb yield
condition.
If
s.. zj
is
the
stress
deviator and S.
n.. ~ '1.]
,
iJ
(6)
P
it is easy to show that the yield function can be written as 3 ! f = (-- qijnij) 2 + M in (p/pc) = 0 2
(7)
73
q (MPa) 10
f
/, p {MPa) i=,,,=
1'0
5
Figure 2.
Comparison between experimental yield
calculated f a i l u r e locus (heavy line) and yield
and f a i l u r e
curve ( l i g h t
points and
line)
on the
basis of Cam Clay model (M:I.5~, pc= 8.0 Mpa) - data after [ I ] . Io take account of the structural procedure similar
to
condition to orthotropic materials tenser A..
ijrs
= A
of
sedimentary
will
be
followed.
Define
a
..
rs13
= A..
zjsr
= A..
be
a
quadruple
(8)
j1rs
and is invariant with respect to s rotation of axes in the plane of It can
rocks,
which enjoys the following symmetries
1jrs
A..
anisotropy
that proposed by Hill [6] for extending Von Mises yield
shown
that
the
isotropy.
most general tensor enjoying these properties is
given in the intrinsic reference frame by
74 b
A,
.
b
b
d
e
b
e
d
=
(9)
ijrs c
c
0
0
0
c
c
0
0
0
0 0
0
0
c
c
0
0
0
0
c
c
0 0
0 0
0 0
0 0
0 0 d-e d-e d~e ~
T
@
where a,b,e,d and e are five material parameters.
Equation
7
may
then
be
transformed into Equation 10, that reads 3 ± f = (--qijAijrsqrs)2 + M In (p/pc) = 0 2
(io
Equation (10) reduces to Equation (7) when a=d=l,b=e=O,c=l/2. Indeed the tensor I . .
ijrs
obtained in t h i s way, i . e .
I
(11
lijrs ~ ~(~irajs + 8isajr) acts as a unit tensor in the sense that
(12)
qijlijrsqr s s qijqij The special case of isotropy is then encompassed by putting
A..
13rs
= I..
(13)
zJrs
From Equation
10
we
see
that
only
Four
of
tile
five
parameters
characterizing
A.. are independent parameters, so that for the sake of ijrs convenience we shall assume d=1. Further, For the sake of simplicity and to keep the
number
of constitutive parameters to the minimum, we also take e=O.
The terms that relate to the isotropic plane are then identical to those of an isotropic material. constants that
The
parameters
characterize
the
a,b
and
c
are
additional
material
anisotropy of a specific rock and should be
determined experimentally. The plastic Flow rule will be plastic potential
assumed
to
and yield Function coincide.
be
associated
so
that
the
Such a hypothesis is made for
75 the sake of convenience. parameters and
avoids
In the
fact
it
limits
choice
of
a
the
number
of
constitutive
different function for the plastic
potential, which would be rather awkward for lack of
consistent
experimental
data. Prager's consistency rule may be therefore written as: @f
~f
~Ohk~hk + ~
0c = 0
(14)
~Pc where a dot d e n o t e s i n c r e m e n t or r a t e .
I t w i l l be
v a r i e s with p l a s t i c
vP .
volumetric strain,
Again on t h e b a s i s o f t h e e x p e r i m e n t a l r e s u l t s
further
assumed
shown i n [ 1 ] ,
[4],
that
Pc
it will
be assumed t h a t
Pc = Peo exp (vP/X p)
(15)
where Pco is the threshold pressure for which the rock hehaviour ceases to linear and
reversible
in
material constant,
whose
compressibility.
For
a
hydrostatic
physical example,
meaning for
compression is
another
test,
that
of
calcarenite
hydrostatic compression in [I] the appropriate value of Xp shown in
Figure
3
while Xp a
be is a
logarithmic
(CI) tested is Xp
in
=.025.
As
the agreement between calculated and experiments1 data is
satisfactory, if the bulk modulus K of the considered calcarenite is taken
to
be K=128 Mpa and Pco =2 Mpa. From the very definition of plastic potential and
by
the
hypothesis
of
an
associated flow rule, plastic strain increments are given by Bf ~j
= C~jhk~hk ~ A
(16) ij
where A
is a
scalar
multiplier and C~jhk is the plastic compliance tensor.
Thus by substituting Equation 16 in Equation 14 and solving for A
, we get
Bf ~hk
A = - ~f
Bpc
8vp ~f (-- --) @Pc Bvp B¢~k@~hk
Finally, taking
account
(17)
of
Equations
10,15,16
and
17,
tile plastic
compliance tensor is given by
C~jhk =
qijqhk H
(IB)
76
P (MPa) I0
,'0
o Figure 3. Calculated
and
experimental
,'s v'/. data
for
calcarenite in hydrostatic
compressinn (C1)-data after [I].
where
3 ~ -
qij =
' lm~s
'lm
1
[~
2
A 3 ~in
zr
~
js
Aqq = [ 7 Almrs qlm qrs ]~
- -
1 (~rs + Rrs)Si j ] + - tl,S.. 3 3 ]3
(19) (20)
and Mp
H : Z p (X
Aq~)
(21)
is tile hardening modulus. E1asEic and plastic strains could be Ehen calculated from Equations I and 18 for any given stress path once appropriate constitutive parameters had been
77 chosen. When H is positive the yield surface expands for outward the ductile.
current
stress
rates
For H=O, hardening is no more possible and unlimited
may take place under very small stress increments. however, we
directed
yield surface and the rock behaviour is irreversible but shear
strains
At variance with Cam Clay,
shall assume fully brittle behaviour for negative H.
ductility of rocks after peak is generally very limited.
Indeed, the
Moreover, the strain
pattern within the sample is non uniform but concentrated in a thin shear band where fracturing takes place.
Any description af such a
Continuum Mechanics
would
misleading.
concepts
be
probably
situation
illegitimate
Io avoid this shortcoming, we shall assume that a
based
on
and possibly specimen
will
abruptly fail when the yield surface will be attained in the region where H i8 negative.
This
shown e.g.
assumption
very
often agrees with experimental evidence, as
in [4].
Figure 4 illustrates the difference of behaviour in ductile ranges.
The
behaviour
of
the
yield locus (paths AB and CD). H
At
D
rock
and
brittle
is considered to be elastic within the
At B the first
sample
fails
abruptly
since
the second sample yields since H>O and loading may be carried on
until point E associated with H = 0 and theoretically infinite strains. From Equation 20 we see that the failure locus
for
the
ductile
locus
region,
for
is
which
given
by
H=O,
which
failure condition.
it
reduces
to
a
purely
the
a cone, which is not
centered on the hydrostatic axis because of the anisotropy of the isotropic materials
is
rock.
For
frictional Drucker-Prager [5]
The parameter M is then linked to the
angle
of
internal
friction of the rock.
DETERMINATION OF CONSTITUTIVE PARAMETERS
The constitiitive characterize a
parameters
transversely
to
be
following tile model presented, are then Yo,Jng's moduli,
two
determined
volumetric compressibility
as
(logarithmic),
constants
compression should
he
and
specified.
constitutive parameters
many
as
are
one
finally
to
fully
eleven.
In
fact
two
For
necessary.
friction
Not
parameter,
three
the yield pressure in hydrostatic isotropic
materials
only
five
Anisotropy is then responsible for a
formidable complication of both the theoretical and the modelling.
order
Poisson's ratios, one elastic shear modulus, the plastic
plastic anisotropy
of rock
in
isotropic elastic-plastic strain hardening rock,
experimental
aspects
only the stress strain law is much more complicated
78
q
H<0
0
A
C
p
Pco
A,C
Em
Figure 4. Brittle and ductile ranges according to the model.
than the corresponding one for an isotropic material, but also the
number
of
parameters to be experimentally determined is much larger. In the following,
we shall attempt to characterize
the
behavio~r
of
a
diatomite on the basis of a very extensive experimental programme performed in [4], [7],
which,
to
the author knowledge, constitutes the widest study ever
conducted on rock anisotropy. In [4], samples of diatomite with different inclinations to plane have
been
tested
confining pressures. specimens undergo
in
standard
triaxial
After an initally linear stress strain
either
the
with
bedding different
behaviour,
rock
brittle fracture or ductile hardening, depending on
sample inclination and confining pressure. rock tends
compression
As could be easily
expected,
the
to become more and more ductile for increasing confining pressure.
However, the stress strain relationship and the
failure
modes
are
markedly
influenced by sample inclination. ]o start with, we shall consider the initially linear part of the strain law,
that according to the model will Be assumed to !~e elastic.
stress Since
79 the initial slope of pressure, at constant. diagram
the
least
curve
is
roughly
for ~) < 4 MPa ,
the
independent
elastic
of
moduli
tile confining
will
be taken as
Since Ao (Cv,q)
inclination.
is the only non-zero stress increment, the slope of tile v gives the longitudinal elastic modulus for each sample
Dots in Figure 5 give the estimated values of the
the basis of the experimental data. longitudinal modulus
is
stiffness
on
When the bedding is horizontal (~9=0°) the
Ev=18z$ MPa,
while
Equation 1 and the tensor transformation rules, e compliance C1111 along the direction x I of (vertical), which is inclined of an angle $
EH=640 MPa.
for ,%=90° , we
get
the
that
the
From
elastic
major principal stress
to the axis of symmetry
of
the
specimen, in a triaxial test at constant cell pressure, is given by 1 I e 4 Vvh C1111 = -- cos ~ + 2(- ~ + ~)sin Ev EH. 2GvH
I 4 2 ~ cos 2 ~ + --sin ~ EH
By taking C~111=.00333 MPa -1 for &=45 ° we get the dotted
(23)
line
shown
in
Figure 5, which nicely fits the experimental data. For the type of test we have intention to model in the following, the e C1111(~) is enough. The other parameters could be determined in
knowledge of
principle by measuring the strains in the directions perpendicular to that loading for
~=90 °
of
but these are unfortunately not available and we shall not
make any attempt to guess their values. The values of X p
and Pco could be
hydrostatic compression test.
determined
from
the
results
of
a
In that case in fact the volumetric strain v is
given by
v = p/K
(23)
if p is less than Pco' K being the bulk modulus, and by
(24)
v = p/K + X p in(p/pc o) for larger
values
of
p, as can be inferred from Equation 18, after algebra.
Since, as shown in Figure 3, the first linear, K
can be easily determined.
shown by the curve, see e.g.
part
of
the
strain
law
is
The pressure Pco corresponds to the kink
Figure 3, and finally X p
means of a best fitting procedure.
stress
may be
determined
by
80
E 8 (MPa) 800
600
/
J
/° / 400
°/ / . _ ---&
200
0
Figure 5. Comparison
I
I
30
60
of calculated
@
IO
and experimental
]nngitudinal
stiffness
for
different sample inclinations.
In this case, since complete available tria×ia]
Lhe
va]ue
compression
of
o
~CO
tasts.
information
and
Xp
on experimental
will be inferred
~!e shall assume henceforth
results
is
not
from the results of
that
Pco=6.8 MPa
and
xP=.I. For confining pressures ductile in
nature.
asymptotically
In
large enough,
triaxial
the model predicts that failure
compression
approached which depends on the
a
limiting
sample
is
stress
rstio is
inclination.
Indeed,
since in this ease
"~11
Sli
2q
2
p
3p
3
'~22 = ~33 = From Equation given by
"fi
(25)
s33 q ~ " = - - - -- - -p 3p 3 21
we
get
the
asymptotic
value q L
for which H = O, that is
81
(26)
qL = (J6 M)/(4A1111 + 2A2233 + A2222 + A3333 - 4Al133 - 4Al122 )½ ~hece from Equation 9 and the tensor transformation rules we have = a cos 4 Al111 A2233 = b s i n 2
&+ s i n 4
~+ 2(b + 2 c ) s i n 2
$cos 2
A2222 = 1 A3333 = a s i n 4 & + cos 4 ~ + 2(b + 2 c ) s i n 2 5 cos 2 9 Al122 = h cos ~
(27)
Al133 = b ( s i n 4 6 + cos 4 6) + (a + 1 - 4 c ) s i n 2 & cos 2
I% can be seen by differentiating the denominator of Equation
(26)
that
qL
has three extrema for ~=0 °, ~=90 ° and for .
6c
+
4b
-
2a
-
I
= tan -I [(
(28)
)~] 6c + 2b - a - 2
To these
values
of
the
inclination correspond the following stress ratios,
qO = / 6 M/(~a + 2 - 8b) ½
(29)
respectively
t
~90 = / 6 H / ( 5 + a - 2b) ~
(30)
n~* : M
(31)
If n~. is a local minimum then qO and vice versa.
and q90 should necessarily be local maxima,
By performing triaxial compresssion
differently inclined
samples
at
a
tests
on
a
number
confining pressure such that all samples
fail in the ductile range, it is possible to determine the extreme the stress ratio (generally a minimum) for 00<9<90 ° Equation 30 find c. once M
of
value
and then to find M.
for From
it is possible tc~ determine (a-2b) and then, from Equation 28, to
Unfortunately Equation 29 is useless since ~0 and
(a-2b) are chosen.
is completely
defined
The most convenient values for a and b should
be chosen on the basis of a best fitting procedure. For the considered diatomite the following values have been chosen on the basis of the experimental results for a confining pressure equal to 2 MPa: 1.69,
a = . 4 , b= .038,
together with calculated
the
e=
.5.
The
calculated
tt
values
are
the difference
is slightly
values,
although
more than 5%.
plotted
may be noted t h a t t h e
c u r v e F i t s v e r y w e l l t h e e x p e r i m e n t a l d a t a f o r 45°<~<90 °
agreement i s t e s s good f o r t h e o t h e r ratios,
failure
e x p e r i m e n t a l p o i n t s i n F i g u r e 6.
M:
in
terms
while the of
stress
82
O'tf - ~3
•
0" 3 = & MPa
x
20
=2
I0
x
o
Figure 6
'
Calculated
3b
and
4-
'
9o
experimental
failure
values of deviator stress at
various confining pressures.
In F i g u r e 7 the c o r r e s p o n d i n g y i e l d l o c i plotted, HPa.
having
The f a i l u r e
c a l c u l a f i e d and is brittle When o}
assumed
thafi
for different
t o observed v a l u e s .
in nature for all
1
HPa
are
then
The model p r e d i c t s t h a t f a i l u r e
i n c l i n a f i i o n s when °3
i s l e s s than a b o u t ,
.6 HPa.
= 1.MPa, failure is brittle for $>45 ° while it is ductile for $<45 ° .
These results are in very good agreement with experimental evidence. the quantitative predictions are values.
are
i n h y d r o s t a t i c compression Pco i s equal t o 6.8
v a l u e s £or c o n f i n i n g pressures o f 0.5 and compared
values of $
somewhat
less
than
the
However,
observed
failure
This may be due to several reasons but it is the assumed shape of the
yield function
that
is
probably
the main responsible for this discrepancy.
Nevertheless, on the ~#hole, the qualitative agreement looks
reasonabty
good.
ql
83
(MPa 6
e=°3o
i !
I
p (MPa) Figure 7. Predicted initial yield loci for various sample inclinations.
COMPARISON BETWEEN CALCULATED AND EXPERIMENTAL RESULTS
The model has been checked against the experimental data Figure 8
given
in
[4].
shows calculated and observed results for different values of sample
inclination, in triaxial tests at constant cel]
pressure
on
the
considered
diatomite. Although in some cases quantitative agreement is especially for o]=4 MPa, it match on the
whole
particular the
the
general
transition
brittle for
is
o3=1MPa
experimental curve
has
trend
from
brittle
reproduced by the model for any pressure, failure
brittle when been
concentrate. uniform and
effects
along
for
from
the
to
experimental
being
and
&=90 °.
results.
Indeed
under
zero
In
In
those
confining
Failure is also two
cases
the
chopped off just after peak since after a drop,
the
again. plane
of
within
the
This
has
slip
where
sample
been
is
attributed
strains then
to
tend
to
largely
non
makes no sense a comparison with calculated results which, by
their very nature, assume uniform distribution of stresses and strains the sample.
good,
ductile behaviour is quite well
all sample inclinations.
&=60 °
The state of stress it
of
inclination.
the experimental curves tend to rise interlocking
far
is clear from Figure 8 that the model predictions
Ibis is a common feature when softening occurs.
within
For this reason,
84 ”
0
-3
>
t
‘c-l
0
/ -
u
I
\
I
7% I
L.7
85 whenever the model predicts the occurrence of a peak the ideal test is stopped at peak,
although
the
model itself would predict a strength reduction until
the line for which H=O is reached, theoretically with infinitely
large
shear
strains. Failure for all other tests is calculated and
experimental
ductile.
The
only
difference
between
curves occurs for ~=90 ° and ~3 = 2 MPa, where the
latter shows the existence of a peak, while the former tends to
a
horizontal
asymptote.
However, the large ductility of the actual sample after peak is an
index that
the
state
of
the sample is close to the transition from brittle
(existence of a peak) to ductile (asymptotic) behaviour. Another feature described by the model is the fact that while the elastic stiffness increases passing from ~=0 ° trend with
a
minimum
for ~
to ~=90 °, the strength has
close to 60 ° .
an
the model predicts that the elastic range is abandoned first, i.e. deviatoric stresses,
when
°3
is
the largest.
however, corresponds the largest strength.
clearly
shown
also
by
for
lower
To that confining pressure,
This fact causes a mutual crossing
of the stress strain curves for different confining pressures. behaviour is
inverse
Moreover, for all inclinations,
This
the experimental curves.
type
of
Finally, the
model predicts that the strength in unconfined compression is smaller but very close t~ that for a triaxial for &=O ~
where failure
is
test
with
ductile.
o3=I MPa for This
is
also
all
inclinations
clearly
shown
but
by the
experimental data. An evident difference between calculated and experimental curves lies
in
that, while for the former the crossing over the first yield function causes a sharp change in stiffness, the actual behaviour is much smoother. due to
two
facts.
First,
real specimens are non uniform and non uniformly
stretched because ef various types of imperfections.
This means that yielding
occurs under different loadings in different points within results in
a
Secondly, it inadequate in
stiffer is
response
possible
that
and
a
smoother
the
classical
the
transition elastic
sample,
what
to plasticity.
plastic
model
is
that phenomenological behaviour of all materials is such that s
smoother transition than that predicted by elastoplasticity is overcome this
This may be
difficulty
observed.
In
the concept of bounding surface and elastic nucleus
forwarded by Dafa]ias and Popov [8] for metals and by [9] for soils could be employed.
Dafalias
and
Herrmann
However, this would clearly render even more
complex the constitutive law presented.
86 CONCLUSIONS
It has been shown in this paper thaL an elastic model
similar
to
Cam
Clay
may
describe
the
plasLic
behavio~r
strainhardening in
axisymmetric
compression of soft sedimentary rocks with satisfactory q~,alitative with experimental
evidence.
agreement
Two modifications bare heen necessary.
First iL
was assumed that an initial elastic region of finite dimensions exisl-s, due t~ the lithification
process.
ovecconsolidation
in
This
soils.
is
seen
Clearly,
as
the
mechanically
destructuration
accompanies yielding could damage the material and properties.
eq~Jivalent
change
process
even
its
t')
which elastic
This fact has been neglected For the sake of simplicity, since no
clear indication
of
this
fact
exists,
at
least
Fur
the
type
of rocks
considered in this study° Secondly, it was necessary to extend the original Cam Clay model to
cope
with transverse isotropy, which is a common Feature for all sedimentary rocks. How large
is
the
relevance of anisotropy on the behaviour of such materials
can be inferred from the experimental results of Figure 8. convenience the
anisotropy
the deformation process.
of
three
the
sake
of
The extension of the model has been performed in the
simplest possible way, involving three new parameters for and another
For
the samples has been taken to be fixed during
for plastic.
elastic
anisotropy
A total of eleven constitutive parameters is
then necessary to fully characterize the material behaviour.
This number
may
look quite large, but the author does not see how the model presented could he made simpler, if account should be taken of anisotrooy. Indeed the very simple extension performed of Cam Clay is heel of
the model.
the
Achille's
In fact, since for an isatropic material Equation 7 would
give rise to a large
overpredir.tion
of
strength
in
plane
strain
and
in
triaxial extension tesLs, it is very likely that similar erroneous predictions would be
consequence
of
the anisotropic model, as well.
A more apprNpriate
" e x t e n s i o n " o f Cam Cla,, t o 3D c o n d i t i o n s t a k i n q a n i s ~ t r o p y i n t o account produce a
v e r y c o m p l i c a t e d e x p r e s s i o n f o r the y i e l d
w~uld
f u n c t i o n and c o n s e q u e n t l y
would make very cumbersome, although still conceptually sim[~le, the derivation of the stress strain law.
Although the calculated results
quantitative is
not
agreement
always
between
satisfactory,
experimental
picture of the behaviour of sedimentary rocks which seems with experimental
evidence.
strength with
inclination
described and
the
also well matched.
The and
transition
trend
confining
of
data
and
the modet gives an overall
the
in
Fair
agreement
variation of stiffness and
pressure
is
qualitatively
well
level between brittle and ductile behaviour is
However, calculated strength
is
generally
too
h]w
for
87 small confining
pressures
and
becomes dramatically higher than the observed
values for high confining pressures. To fit actual experimental results in a more satisfactory way also from a quantitative point of view, some modifications are
necessary.
For
instance
the yield function should allow for some strength in tension and the lines for wich 11=0 should
be
concave
downward.
Also,
a way to describe a smoother
transition from elastic to elastic plastic range should be sought. more
refined
expression
for
yield
function
should
be
Finally
found
to
a
avoid
overestimation of strength in plane stain and triaxial extension. Although the model implementation for
the
is
therefore
solution
not
yet
ready
for
finite
elements
of boundary value problems, it appears that
the framework of strainhardening plasticity is adequate not only for soils but also for soft sedimentary rocks. theory constitutes
a
geologic materials. evidence, a
new
unifying Should
paradigm
It is then natural
this for
to
argue
that
such
a
framework for the description of all types of opinion
geologic
be media
confirmed
by
experimental
would emerge that joins in a
unique description stiffness and strength and overcomes the existing dichotomy between the classical description of the mechanical characteristics
of
these
kinds of materials.
ACKNOWLEDGMENTS
This research has been partly supported by CNR (National Research Council of Italy) and MPI (Ministry of Education).
REFERENCES
1. Pellegrino A., Mechanical behaviour of
soft
rocks
under
high
stresses.
Proc 2nd ICISRM, Belgrade (1970), 2, paper 3-25. 2. Pellegrino A., Proprieta' Napoletano, Proc.
fisieo
dei
terreni
vulcaniei
e resistenzs
a
rottura
del
tufo
giallo
9th Italian Geotechnical Conference, Genova 1968.
4. Allirot D., Boehler J.P., Evolutions des proprietes meeaniques d'une stratifiee sous pression de confinement, Proc. 1, 15-22.
del
8th Italian Geotechnical Conference, Cagliari 1967.
3. Pellegrino A., Compressibilita' napoletano, Proc.
meccaniche
roche
4th ICISRH, Montreux, 1979,
88 5. Drucker D.C., Prager W., Soil design, Quart.
Hechanics
and
plastic
analysis
or
limit
APP" Math., 10(1952), 157-165
6. H i l l R., The mathematical ~ e o r y of p l a s t i c i t y , Clarendon Press, Oxford. 7. A l l i r o t D., Boehler ,].P., anisotropic rock
under
Sawczuk A., hydrostatic
Irreversible
pressure,
Int.
deformations 3.
of
an
Rock Mech. Min.
5 c i . , 14(1977), 77-85. 8. Dafalias Y.F., Popav E.P., A model of n o n l i n e a r ly hardening
materials
for
complex loadings Acta Mech., 21(1975), 173-192. 9. Dafalias Y.F., p l a s t i c i t y , Soil
Herrmann L.R.,
Bounding
Mechanics-Transient
Zienkiewicz eds) 3.
Wiley, ch.
surface
formulation
and c y c l i c loads, (G.N.
10, 255-282, (1982).
of
soil
Pande, O.C.
AN EXTENDED CAM CLAY ~K)DEL FOR SOFT ANISOTROPIC ROCKS
Roberto Nova
Department of Structural Engineering Milan University of Technology Piazza Leonardo da Vinci 32, 20133 Hilano, Italy
ABSTRACT
The mechanical behaviour of soft sedimentary rocks in triaxial compression is modelled by means of a constitutive law which has been formulated by extending the original Cam Clay model. The geological material is assumed to be linearly elastic-plastic, strain-hardening, with fixed transverse isotropy. Theoretical predictions are compared to observed behaviour at different confining pressures of specimens of diatomite with various bedding inclinations. Although quantitative agreement is not always satisfactory, the trend of the tests is qualitatively well matched, what proves the paradigmatic value of this type of model not only for soils but even for soft rocks.
INTRODUCTION Rock formations of sedimentary origin like calcarenites, sandstones are
frequently met in Italy as foundation subsoil.
diatomites,
From the Civil
Engineering viewpoint [1], strength and deformability of the intact the controlling
factors
in
structural discontinuities characteristics of From an
are
widely
design, spaced,
since
fissures
whilst
the
rock and
are other
mechanical
the rocks are rather weak, because of their high porosity.
extensive
calcarenites and
foundation
mr
turfs,
study
performed
Pellegrino
at
the
[1],[2],[3],
University it
of
Naples
on
appears that for small
confining pressures these types of rocks exhibit a rock-like
behaviour,
i.e.
quasilinear elastic behaviour and brittle failure, whilst after a well defined threshold, the
stress
strain relationship becomes non linear, accompanied by 69
C o m p u ~ and Geo~chnics 0266-352X/86/$03.50
© Elsevier Applied Science Publishers Ltd, England, 1986. Printed in Great Britain
7O large plastic strains and ductile in nature, more similar to the behavio1~r
of
a soft soil than to that of a hard rock. Similar results have been obtained diatomite from
the
by
f4ontagne d'Andance,
Allirot
and
Boehler
[4]
on
a
Ardeche, France, whose structure is
made of a regular alternance of diatom valves and fossilized debris. The experimental description of
the
evidence behaviour
therefore of
such
suggests materials
that can
the
mathematical
be based on the same
concepts on which the constitutive models for virgin soils are founded.
]here
appear to be two main intuitive differences.
First, the initial yield surface
does not coincide with the origin of axes in
the
assumed for
virgin soils.
space,
as
usually
In this respect, lithification acts as an apparent
preconsolidation pressure. markedly anisotropic.
stress
Second, the
From
behaviour
of
sedimentary
rocks
is
an engineering standpoint no sensible result can
be arrived at if anistotropy is not taken into account. The aim of this paper is to confirm these intuitive considerations on the basis of a comparison between theoretical predictions and actual behaviour.
First
anisotropy.
the
original
experimental
Cam Clay model will be extended to cope with
Secondly, on the basis of some experimental results, a
to determine the constitutive parameters will be shown. between calculated
results
and
experimental
evidence
in
several triaxial
compression tests on specimens at different inclination with major principal
stress
direction
will
be
procedure
Finally, a comparison
presented.
respect
to
the
A discussion on the
results obtained, on the potential and limitations of the model proposed
will
end the paper. lhe main effort will not be directed, however, to the exact experimental curves would be
necessary,
for
which
but
phenomenological behaviour
rather of
matching
of
an 'ad hoe', extensive experimental programme
soft
towards
the
anisotropic
understanding rocks
as a whole.
of
the
Further
refinement will be necessary to achieve the goal of formulating a constitl~tive model for such materials that enjoys full validity even
from
a
quantitative
point of view. In the following, the term stress will be always used
in
the
sense
of
effective stress.
THEORETICAL CONSIDERATIONS
Sedimentary rocks may often be idealized as homogeneous but isotropic materials,
where
the
axis
of
symmetry
transversely
is normal to the bedding
71 plane.
We shall define as intrinsic reference frame, a cartesian frame
one axis, Xv,
where
say, coincides with the symmetry axis, and, consequently, the
plane of isotropy is the plane (XH1,XH2) , see Figure I. Xv
i
XH2D"
f
Figure 1. Intrinsic reference frame.
Since experimental evidence suggests that for low the material
hydrostatic
pressures
behaviour is approximately linear and quasi reversible, we shall
assume that linear elasticity is suitahle in this range, lhe constitutive law written in the intrinsic reference frame is then given by
eV
SH1
1 EV
vVH E~4
~VH
EH
~l
, CH2~
E~HH
EH symm.
YVHI I
YVH2 I YHHJ
(1)
1 0
GVH
0 1
GVH
0 1 GHH
where E
is the longitudinal elastic modulus in the direction of the axis or v symmetry, while E H is the corresponding modulus in any direction in the isotropic plane, ~VH and ~HH are Poisson's ratios and GVH and
GHH
are
shear
72 Since GHH is Liae shear modulus in tile plane of isotropy
moduli.
EH
g!i H :
(2) 2(I+~HH) Equafiinn 1 i s v a l i d
threshold value.
when
the
hydrostatic
then
given
On
lower
than
a
the
lhe limit of validity of
Equation
I
by a yield function whose expression is a priori unknown
and that could be determined programme.
is
It is straightforward to assume that this value will depend
on the particular stress path Followed. will be
pressure
basis
only of
by
means
of
an
extensive
experimental
some results published in [I], we shall assume
that the yield function is given by an expression similar to that of Cam Clay, which in triaxial compression reads
f : q + Mp In(p/p c) = 0
(5)
where
q ~ rSl -
'~3
(4)
1 P ~ -- (~1 + 203) 3
(5)
and Pc is the threshold pressure in taken positive
hydrostatic
compression.
in compression, as well as strains.
and minor principal
confining pressure.
stresses
respectively.
The
~I
latter
Stresses
~3
and
is
are
are the major equal
to
the
Figure 2 shows a comparison between the calculated y i e l d
surface and f a i l u r e locus and the observed y i e l d
and
failure
points
for
a
calcarenite (C2). To take account of anisotropy a generalization of Equation 3 to the stress space is necessary.
The simplest way to do that ls to assume that for
an i s o t r o p i e materlal the y i e l d function can be obtained by r o t a t i n g 3 around
full
Equation
the hydrostatic axis, following a procedure similar to that employed
in [5] to smooth the Mohr-Coulomb yield
condition.
If
s.. zj
is
the
stress
deviator and S.
n.. ~ '1.]
,
iJ
(6)
P
it is easy to show that the yield function can be written as 3 ! f = (-- qijnij) 2 + M in (p/pc) = 0 2
(7)
73
q (MPa) 10
f
/, p {MPa) i=,,,=
1'0
5
Figure 2.
Comparison between experimental yield
calculated f a i l u r e locus (heavy line) and yield
and f a i l u r e
curve ( l i g h t
points and
line)
on the
basis of Cam Clay model (M:I.5~, pc= 8.0 Mpa) - data after [ I ] . Io take account of the structural procedure similar
to
condition to orthotropic materials tenser A..
ijrs
= A
of
sedimentary
will
be
followed.
Define
a
..
rs13
= A..
zjsr
= A..
be
a
quadruple
(8)
j1rs
and is invariant with respect to s rotation of axes in the plane of It can
rocks,
which enjoys the following symmetries
1jrs
A..
anisotropy
that proposed by Hill [6] for extending Von Mises yield
shown
that
the
isotropy.
most general tensor enjoying these properties is
given in the intrinsic reference frame by
74 b
A,
.
b
b
d
e
b
e
d
=
(9)
ijrs c
c
0
0
0
c
c
0
0
0
0 0
0
0
c
c
0
0
0
0
c
c
0 0
0 0
0 0
0 0
0 0 d-e d-e d~e ~
T
@
where a,b,e,d and e are five material parameters.
Equation
7
may
then
be
transformed into Equation 10, that reads 3 ± f = (--qijAijrsqrs)2 + M In (p/pc) = 0 2
(io
Equation (10) reduces to Equation (7) when a=d=l,b=e=O,c=l/2. Indeed the tensor I . .
ijrs
obtained in t h i s way, i . e .
I
(11
lijrs ~ ~(~irajs + 8isajr) acts as a unit tensor in the sense that
(12)
qijlijrsqr s s qijqij The special case of isotropy is then encompassed by putting
A..
13rs
= I..
(13)
zJrs
From Equation
10
we
see
that
only
Four
of
tile
five
parameters
characterizing
A.. are independent parameters, so that for the sake of ijrs convenience we shall assume d=1. Further, For the sake of simplicity and to keep the
number
of constitutive parameters to the minimum, we also take e=O.
The terms that relate to the isotropic plane are then identical to those of an isotropic material. constants that
The
parameters
characterize
the
a,b
and
c
are
additional
material
anisotropy of a specific rock and should be
determined experimentally. The plastic Flow rule will be plastic potential
assumed
to
and yield Function coincide.
be
associated
so
that
the
Such a hypothesis is made for
75 the sake of convenience. parameters and
avoids
In the
fact
it
limits
choice
of
a
the
number
of
constitutive
different function for the plastic
potential, which would be rather awkward for lack of
consistent
experimental
data. Prager's consistency rule may be therefore written as: @f
~f
~Ohk~hk + ~
0c = 0
(14)
~Pc where a dot d e n o t e s i n c r e m e n t or r a t e .
I t w i l l be
v a r i e s with p l a s t i c
vP .
volumetric strain,
Again on t h e b a s i s o f t h e e x p e r i m e n t a l r e s u l t s
further
assumed
shown i n [ 1 ] ,
[4],
that
Pc
it will
be assumed t h a t
Pc = Peo exp (vP/X p)
(15)
where Pco is the threshold pressure for which the rock hehaviour ceases to linear and
reversible
in
material constant,
whose
compressibility.
For
a
hydrostatic
physical example,
meaning for
compression is
another
test,
that
of
calcarenite
hydrostatic compression in [I] the appropriate value of Xp shown in
Figure
3
while Xp a
be is a
logarithmic
(CI) tested is Xp
in
=.025.
As
the agreement between calculated and experiments1 data is
satisfactory, if the bulk modulus K of the considered calcarenite is taken
to
be K=128 Mpa and Pco =2 Mpa. From the very definition of plastic potential and
by
the
hypothesis
of
an
associated flow rule, plastic strain increments are given by Bf ~j
= C~jhk~hk ~ A
(16) ij
where A
is a
scalar
multiplier and C~jhk is the plastic compliance tensor.
Thus by substituting Equation 16 in Equation 14 and solving for A
, we get
Bf ~hk
A = - ~f
Bpc
8vp ~f (-- --) @Pc Bvp B¢~k@~hk
Finally, taking
account
(17)
of
Equations
10,15,16
and
17,
tile plastic
compliance tensor is given by
C~jhk =
qijqhk H
(IB)
76
P (MPa) I0
,'0
o Figure 3. Calculated
and
experimental
,'s v'/. data
for
calcarenite in hydrostatic
compressinn (C1)-data after [I].
where
3 ~ -
qij =
' lm~s
'lm
1
[~
2
A 3 ~in
zr
~
js
Aqq = [ 7 Almrs qlm qrs ]~
- -
1 (~rs + Rrs)Si j ] + - tl,S.. 3 3 ]3
(19) (20)
and Mp
H : Z p (X
Aq~)
(21)
is tile hardening modulus. E1asEic and plastic strains could be Ehen calculated from Equations I and 18 for any given stress path once appropriate constitutive parameters had been
77 chosen. When H is positive the yield surface expands for outward the ductile.
current
stress
rates
For H=O, hardening is no more possible and unlimited
may take place under very small stress increments. however, we
directed
yield surface and the rock behaviour is irreversible but shear
strains
At variance with Cam Clay,
shall assume fully brittle behaviour for negative H.
ductility of rocks after peak is generally very limited.
Indeed, the
Moreover, the strain
pattern within the sample is non uniform but concentrated in a thin shear band where fracturing takes place.
Any description af such a
Continuum Mechanics
would
misleading.
concepts
be
probably
situation
illegitimate
Io avoid this shortcoming, we shall assume that a
based
on
and possibly specimen
will
abruptly fail when the yield surface will be attained in the region where H i8 negative.
This
shown e.g.
assumption
very
often agrees with experimental evidence, as
in [4].
Figure 4 illustrates the difference of behaviour in ductile ranges.
The
behaviour
of
the
yield locus (paths AB and CD). H
At
D
rock
and
brittle
is considered to be elastic within the
At B the first
sample
fails
abruptly
since
the second sample yields since H>O and loading may be carried on
until point E associated with H = 0 and theoretically infinite strains. From Equation 20 we see that the failure locus
for
the
ductile
locus
region,
for
is
which
given
by
H=O,
which
failure condition.
it
reduces
to
a
purely
the
a cone, which is not
centered on the hydrostatic axis because of the anisotropy of the isotropic materials
is
rock.
For
frictional Drucker-Prager [5]
The parameter M is then linked to the
angle
of
internal
friction of the rock.
DETERMINATION OF CONSTITUTIVE PARAMETERS
The constitiitive characterize a
parameters
transversely
to
be
following tile model presented, are then Yo,Jng's moduli,
two
determined
volumetric compressibility
as
(logarithmic),
constants
compression should
he
and
specified.
constitutive parameters
many
as
are
one
finally
to
fully
eleven.
In
fact
two
For
necessary.
friction
Not
parameter,
three
the yield pressure in hydrostatic isotropic
materials
only
five
Anisotropy is then responsible for a
formidable complication of both the theoretical and the modelling.
order
Poisson's ratios, one elastic shear modulus, the plastic
plastic anisotropy
of rock
in
isotropic elastic-plastic strain hardening rock,
experimental
aspects
only the stress strain law is much more complicated
78
q
H<0
0
A
C
p
Pco
A,C
Em
Figure 4. Brittle and ductile ranges according to the model.
than the corresponding one for an isotropic material, but also the
number
of
parameters to be experimentally determined is much larger. In the following,
we shall attempt to characterize
the
behavio~r
of
a
diatomite on the basis of a very extensive experimental programme performed in [4], [7],
which,
to
the author knowledge, constitutes the widest study ever
conducted on rock anisotropy. In [4], samples of diatomite with different inclinations to plane have
been
tested
confining pressures. specimens undergo
in
standard
triaxial
After an initally linear stress strain
either
the
with
bedding different
behaviour,
rock
brittle fracture or ductile hardening, depending on
sample inclination and confining pressure. rock tends
compression
As could be easily
expected,
the
to become more and more ductile for increasing confining pressure.
However, the stress strain relationship and the
failure
modes
are
markedly
influenced by sample inclination. ]o start with, we shall consider the initially linear part of the strain law,
that according to the model will Be assumed to !~e elastic.
stress Since
79 the initial slope of pressure, at constant. diagram
the
least
curve
is
roughly
for ~) < 4 MPa ,
the
independent
elastic
of
moduli
tile confining
will
be taken as
Since Ao (Cv,q)
inclination.
is the only non-zero stress increment, the slope of tile v gives the longitudinal elastic modulus for each sample
Dots in Figure 5 give the estimated values of the
the basis of the experimental data. longitudinal modulus
is
stiffness
on
When the bedding is horizontal (~9=0°) the
Ev=18z$ MPa,
while
Equation 1 and the tensor transformation rules, e compliance C1111 along the direction x I of (vertical), which is inclined of an angle $
EH=640 MPa.
for ,%=90° , we
get
the
that
the
From
elastic
major principal stress
to the axis of symmetry
of
the
specimen, in a triaxial test at constant cell pressure, is given by 1 I e 4 Vvh C1111 = -- cos ~ + 2(- ~ + ~)sin Ev EH. 2GvH
I 4 2 ~ cos 2 ~ + --sin ~ EH
By taking C~111=.00333 MPa -1 for &=45 ° we get the dotted
(23)
line
shown
in
Figure 5, which nicely fits the experimental data. For the type of test we have intention to model in the following, the e C1111(~) is enough. The other parameters could be determined in
knowledge of
principle by measuring the strains in the directions perpendicular to that loading for
~=90 °
of
but these are unfortunately not available and we shall not
make any attempt to guess their values. The values of X p
and Pco could be
hydrostatic compression test.
determined
from
the
results
of
a
In that case in fact the volumetric strain v is
given by
v = p/K
(23)
if p is less than Pco' K being the bulk modulus, and by
(24)
v = p/K + X p in(p/pc o) for larger
values
of
p, as can be inferred from Equation 18, after algebra.
Since, as shown in Figure 3, the first linear, K
can be easily determined.
shown by the curve, see e.g.
part
of
the
strain
law
is
The pressure Pco corresponds to the kink
Figure 3, and finally X p
means of a best fitting procedure.
stress
may be
determined
by
80
E 8 (MPa) 800
600
/
J
/° / 400
°/ / . _ ---&
200
0
Figure 5. Comparison
I
I
30
60
of calculated
@
IO
and experimental
]nngitudinal
stiffness
for
different sample inclinations.
In this case, since complete available tria×ia]
Lhe
va]ue
compression
of
o
~CO
tasts.
information
and
Xp
on experimental
will be inferred
~!e shall assume henceforth
results
is
not
from the results of
that
Pco=6.8 MPa
and
xP=.I. For confining pressures ductile in
nature.
asymptotically
In
large enough,
triaxial
the model predicts that failure
compression
approached which depends on the
a
limiting
sample
is
stress
rstio is
inclination.
Indeed,
since in this ease
"~11
Sli
2q
2
p
3p
3
'~22 = ~33 = From Equation given by
"fi
(25)
s33 q ~ " = - - - -- - -p 3p 3 21
we
get
the
asymptotic
value q L
for which H = O, that is
81
(26)
qL = (J6 M)/(4A1111 + 2A2233 + A2222 + A3333 - 4Al133 - 4Al122 )½ ~hece from Equation 9 and the tensor transformation rules we have = a cos 4 Al111 A2233 = b s i n 2
&+ s i n 4
~+ 2(b + 2 c ) s i n 2
$cos 2
A2222 = 1 A3333 = a s i n 4 & + cos 4 ~ + 2(b + 2 c ) s i n 2 5 cos 2 9 Al122 = h cos ~
(27)
Al133 = b ( s i n 4 6 + cos 4 6) + (a + 1 - 4 c ) s i n 2 & cos 2
I% can be seen by differentiating the denominator of Equation
(26)
that
qL
has three extrema for ~=0 °, ~=90 ° and for .
6c
+
4b
-
2a
-
I
= tan -I [(
(28)
)~] 6c + 2b - a - 2
To these
values
of
the
inclination correspond the following stress ratios,
qO = / 6 M/(~a + 2 - 8b) ½
(29)
respectively
t
~90 = / 6 H / ( 5 + a - 2b) ~
(30)
n~* : M
(31)
If n~. is a local minimum then qO and vice versa.
and q90 should necessarily be local maxima,
By performing triaxial compresssion
differently inclined
samples
at
a
tests
on
a
number
confining pressure such that all samples
fail in the ductile range, it is possible to determine the extreme the stress ratio (generally a minimum) for 00<9<90 ° Equation 30 find c. once M
of
value
and then to find M.
for From
it is possible tc~ determine (a-2b) and then, from Equation 28, to
Unfortunately Equation 29 is useless since ~0 and
(a-2b) are chosen.
is completely
defined
The most convenient values for a and b should
be chosen on the basis of a best fitting procedure. For the considered diatomite the following values have been chosen on the basis of the experimental results for a confining pressure equal to 2 MPa: 1.69,
a = . 4 , b= .038,
together with calculated
the
e=
.5.
The
calculated
tt
values
are
the difference
is slightly
values,
although
more than 5%.
plotted
may be noted t h a t t h e
c u r v e F i t s v e r y w e l l t h e e x p e r i m e n t a l d a t a f o r 45°<~<90 °
agreement i s t e s s good f o r t h e o t h e r ratios,
failure
e x p e r i m e n t a l p o i n t s i n F i g u r e 6.
M:
in
terms
while the of
stress
82
O'tf - ~3
•
0" 3 = & MPa
x
20
=2
I0
x
o
Figure 6
'
Calculated
3b
and
4-
'
9o
experimental
failure
values of deviator stress at
various confining pressures.
In F i g u r e 7 the c o r r e s p o n d i n g y i e l d l o c i plotted, HPa.
having
The f a i l u r e
c a l c u l a f i e d and is brittle When o}
assumed
thafi
for different
t o observed v a l u e s .
in nature for all
1
HPa
are
then
The model p r e d i c t s t h a t f a i l u r e
i n c l i n a f i i o n s when °3
i s l e s s than a b o u t ,
.6 HPa.
= 1.MPa, failure is brittle for $>45 ° while it is ductile for $<45 ° .
These results are in very good agreement with experimental evidence. the quantitative predictions are values.
are
i n h y d r o s t a t i c compression Pco i s equal t o 6.8
v a l u e s £or c o n f i n i n g pressures o f 0.5 and compared
values of $
somewhat
less
than
the
However,
observed
failure
This may be due to several reasons but it is the assumed shape of the
yield function
that
is
probably
the main responsible for this discrepancy.
Nevertheless, on the ~#hole, the qualitative agreement looks
reasonabty
good.
ql
83
(MPa 6
e=°3o
i !
I
p (MPa) Figure 7. Predicted initial yield loci for various sample inclinations.
COMPARISON BETWEEN CALCULATED AND EXPERIMENTAL RESULTS
The model has been checked against the experimental data Figure 8
given
in
[4].
shows calculated and observed results for different values of sample
inclination, in triaxial tests at constant cel]
pressure
on
the
considered
diatomite. Although in some cases quantitative agreement is especially for o]=4 MPa, it match on the
whole
particular the
the
general
transition
brittle for
is
o3=1MPa
experimental curve
has
trend
from
brittle
reproduced by the model for any pressure, failure
brittle when been
concentrate. uniform and
effects
along
for
from
the
to
experimental
being
and
&=90 °.
results.
Indeed
under
zero
In
In
those
confining
Failure is also two
cases
the
chopped off just after peak since after a drop,
the
again. plane
of
within
the
This
has
slip
where
sample
been
is
attributed
strains then
to
tend
to
largely
non
makes no sense a comparison with calculated results which, by
their very nature, assume uniform distribution of stresses and strains the sample.
good,
ductile behaviour is quite well
all sample inclinations.
&=60 °
The state of stress it
of
inclination.
the experimental curves tend to rise interlocking
far
is clear from Figure 8 that the model predictions
Ibis is a common feature when softening occurs.
within
For this reason,
84 ”
0
-3
>
t
‘c-l
0
/ -
u
I
\
I
7% I
L.7
85 whenever the model predicts the occurrence of a peak the ideal test is stopped at peak,
although
the
model itself would predict a strength reduction until
the line for which H=O is reached, theoretically with infinitely
large
shear
strains. Failure for all other tests is calculated and
experimental
ductile.
The
only
difference
between
curves occurs for ~=90 ° and ~3 = 2 MPa, where the
latter shows the existence of a peak, while the former tends to
a
horizontal
asymptote.
However, the large ductility of the actual sample after peak is an
index that
the
state
of
the sample is close to the transition from brittle
(existence of a peak) to ductile (asymptotic) behaviour. Another feature described by the model is the fact that while the elastic stiffness increases passing from ~=0 ° trend with
a
minimum
for ~
to ~=90 °, the strength has
close to 60 ° .
an
the model predicts that the elastic range is abandoned first, i.e. deviatoric stresses,
when
°3
is
the largest.
however, corresponds the largest strength.
clearly
shown
also
by
for
lower
To that confining pressure,
This fact causes a mutual crossing
of the stress strain curves for different confining pressures. behaviour is
inverse
Moreover, for all inclinations,
This
the experimental curves.
type
of
Finally, the
model predicts that the strength in unconfined compression is smaller but very close t~ that for a triaxial for &=O ~
where failure
is
test
with
ductile.
o3=I MPa for This
is
also
all
inclinations
clearly
shown
but
by the
experimental data. An evident difference between calculated and experimental curves lies
in
that, while for the former the crossing over the first yield function causes a sharp change in stiffness, the actual behaviour is much smoother. due to
two
facts.
First,
real specimens are non uniform and non uniformly
stretched because ef various types of imperfections.
This means that yielding
occurs under different loadings in different points within results in
a
Secondly, it inadequate in
stiffer is
response
possible
that
and
a
smoother
the
classical
the
transition elastic
sample,
what
to plasticity.
plastic
model
is
that phenomenological behaviour of all materials is such that s
smoother transition than that predicted by elastoplasticity is overcome this
This may be
difficulty
observed.
In
the concept of bounding surface and elastic nucleus
forwarded by Dafa]ias and Popov [8] for metals and by [9] for soils could be employed.
Dafalias
and
Herrmann
However, this would clearly render even more
complex the constitutive law presented.
86 CONCLUSIONS
It has been shown in this paper thaL an elastic model
similar
to
Cam
Clay
may
describe
the
plasLic
behavio~r
strainhardening in
axisymmetric
compression of soft sedimentary rocks with satisfactory q~,alitative with experimental
evidence.
agreement
Two modifications bare heen necessary.
First iL
was assumed that an initial elastic region of finite dimensions exisl-s, due t~ the lithification
process.
ovecconsolidation
in
This
soils.
is
seen
Clearly,
as
the
mechanically
destructuration
accompanies yielding could damage the material and properties.
eq~Jivalent
change
process
even
its
t')
which elastic
This fact has been neglected For the sake of simplicity, since no
clear indication
of
this
fact
exists,
at
least
Fur
the
type
of rocks
considered in this study° Secondly, it was necessary to extend the original Cam Clay model to
cope
with transverse isotropy, which is a common Feature for all sedimentary rocks. How large
is
the
relevance of anisotropy on the behaviour of such materials
can be inferred from the experimental results of Figure 8. convenience the
anisotropy
the deformation process.
of
three
the
sake
of
The extension of the model has been performed in the
simplest possible way, involving three new parameters for and another
For
the samples has been taken to be fixed during
for plastic.
elastic
anisotropy
A total of eleven constitutive parameters is
then necessary to fully characterize the material behaviour.
This number
may
look quite large, but the author does not see how the model presented could he made simpler, if account should be taken of anisotrooy. Indeed the very simple extension performed of Cam Clay is heel of
the model.
the
Achille's
In fact, since for an isatropic material Equation 7 would
give rise to a large
overpredir.tion
of
strength
in
plane
strain
and
in
triaxial extension tesLs, it is very likely that similar erroneous predictions would be
consequence
of
the anisotropic model, as well.
A more apprNpriate
" e x t e n s i o n " o f Cam Cla,, t o 3D c o n d i t i o n s t a k i n q a n i s ~ t r o p y i n t o account produce a
v e r y c o m p l i c a t e d e x p r e s s i o n f o r the y i e l d
w~uld
f u n c t i o n and c o n s e q u e n t l y
would make very cumbersome, although still conceptually sim[~le, the derivation of the stress strain law.
Although the calculated results
quantitative is
not
agreement
always
between
satisfactory,
experimental
picture of the behaviour of sedimentary rocks which seems with experimental
evidence.
strength with
inclination
described and
the
also well matched.
The and
transition
trend
confining
of
data
and
the modet gives an overall
the
in
Fair
agreement
variation of stiffness and
pressure
is
qualitatively
well
level between brittle and ductile behaviour is
However, calculated strength
is
generally
too
h]w
for
87 small confining
pressures
and
becomes dramatically higher than the observed
values for high confining pressures. To fit actual experimental results in a more satisfactory way also from a quantitative point of view, some modifications are
necessary.
For
instance
the yield function should allow for some strength in tension and the lines for wich 11=0 should
be
concave
downward.
Also,
a way to describe a smoother
transition from elastic to elastic plastic range should be sought. more
refined
expression
for
yield
function
should
be
Finally
found
to
a
avoid
overestimation of strength in plane stain and triaxial extension. Although the model implementation for
the
is
therefore
solution
not
yet
ready
for
finite
elements
of boundary value problems, it appears that
the framework of strainhardening plasticity is adequate not only for soils but also for soft sedimentary rocks. theory constitutes
a
geologic materials. evidence, a
new
unifying Should
paradigm
It is then natural
this for
to
argue
that
such
a
framework for the description of all types of opinion
geologic
be media
confirmed
by
experimental
would emerge that joins in a
unique description stiffness and strength and overcomes the existing dichotomy between the classical description of the mechanical characteristics
of
these
kinds of materials.
ACKNOWLEDGMENTS
This research has been partly supported by CNR (National Research Council of Italy) and MPI (Ministry of Education).
REFERENCES
1. Pellegrino A., Mechanical behaviour of
soft
rocks
under
high
stresses.
Proc 2nd ICISRM, Belgrade (1970), 2, paper 3-25. 2. Pellegrino A., Proprieta' Napoletano, Proc.
fisieo
dei
terreni
vulcaniei
e resistenzs
a
rottura
del
tufo
giallo
9th Italian Geotechnical Conference, Genova 1968.
4. Allirot D., Boehler J.P., Evolutions des proprietes meeaniques d'une stratifiee sous pression de confinement, Proc. 1, 15-22.
del
8th Italian Geotechnical Conference, Cagliari 1967.
3. Pellegrino A., Compressibilita' napoletano, Proc.
meccaniche
roche
4th ICISRH, Montreux, 1979,
88 5. Drucker D.C., Prager W., Soil design, Quart.
Hechanics
and
plastic
analysis
or
limit
APP" Math., 10(1952), 157-165
6. H i l l R., The mathematical ~ e o r y of p l a s t i c i t y , Clarendon Press, Oxford. 7. A l l i r o t D., Boehler ,].P., anisotropic rock
under
Sawczuk A., hydrostatic
Irreversible
pressure,
Int.
deformations 3.
of
an
Rock Mech. Min.
5 c i . , 14(1977), 77-85. 8. Dafalias Y.F., Popav E.P., A model of n o n l i n e a r ly hardening
materials
for
complex loadings Acta Mech., 21(1975), 173-192. 9. Dafalias Y.F., p l a s t i c i t y , Soil
Herrmann L.R.,
Bounding
Mechanics-Transient
Zienkiewicz eds) 3.
Wiley, ch.
surface
formulation
and c y c l i c loads, (G.N.
10, 255-282, (1982).
of
soil
Pande, O.C.