Subinterface crack in dissimilar orthotropic materials

Int. J. Solids Srruc!ures Vol. 32, No. 19. pp. 2873-2889, 1995 Copyright 0 1995 Elsevier Science Ltd Printed in Great Britain. All rights reserved OO2&7683/95 $9.50 + .Xl

0020-7683(94)00256-8

SUBINTERFACE CRACK IN DISSIMILAR ORTHOTROPIC MATERIALS J. C. SUNG and J. Y. LIOU Department of Civil Engineering, National Cheng Kung University, Tainan, Taiwan, 70101. (Received

18April 1994 ; in revisedform 12 October 1994)

Abstract-A subinterface crack in dissimilar orthotropic materials is considered. The principal axes of one of the materials (say material no. 2 which contains the crack) are aligned along the coordinate axes while the other material’s principal axes (say material no. 1) can have an arbitrary angle y relative to the interface boundary. The effects of material no. 1 on the behavior of material no. 2 are completely through six generalized Dundurs’ constants that are functions of y. When y = 0 or when the material constant 6”’ of material no. 1 is equal to one, two of the six constants vanish and only four left have to be considered. A peculiar phenomenon is observed for 6”’ = 1, i.e. when the material constant 6(‘) of material no. 1 is equal to one the effect of the alignments of material no. 1 on the behavior of material no. 2 is indifferent. Several features of the stress intensity factors for crack faces subjected to self-equilibrating loadings are further investigated without resorting to solving the equations. Some numerical results for crack faces subjected to uniform pressure or shear loadings are also given.

1. INTRODUCTION

The problem of subinterface crack in dissimilar isotropic materials was first investigated by Erdogan (1971). Tamate and Iwasaka (1976) extended Erdogan’s work by considering a slant crack near the interface. An asymptotic relationship between interface crack and subinterface crack problems has been derived by Hutchinson et al. (1987). Lu and Lardner (1992) recently considered the problem of subinterface cracks in layered isotropic material and provided a comprehensive literature survey of the analysis of isotropic interface or subinterface cracks. The subinterface crack problems for dissimilar anisotropic materials have not been treated as well as the corresponding interface crack problems, which have been widely studied by many researchers (Gotoh (1967), Clements (1971), Willis (1971), Ting (1986), Suo (1990) and Hwu (1993), among others). A crack of arbitrary size and orientation near a bimaterial interface between dissimilar anisotropic materials has been investigated by Miller (1989). Recently, in a series of papers by Wu and Erdogan (1993 a,b,c), the problems of orthotropic laminated plates under membrane and bending loads have been investigated. In this paper, we shall treat the problem similar to the one investigated by Miller (1989), but from a different point of view. An orthotropic material (material no. 2) with aligned principal axes coinciding with the co-ordinate axes is perfectly bonded to another orthotropic material (material no. 1) with the material principal axes having an arbitrary angle y relative to the interface boundary. A subinterface crack is situated horizontally in material no. 2. A system of singular integral equations is developed, and explicit expressions for the kernel functions are given in real forms. The kernel functions for many special cases can be recovered from the present results, for example, the kernel functions for the isotropic bimaterial problem are included as special cases in our results. From the explicit forms of the kernel functions, we observe that all material constants of material no. 1 are absorbed by the six generalized Dundurs’ constants that are introduced in the paper. Hence the effects of material no. 1 on the behavior of material no. 2 will be completely determined through these six constants. These constants are functions of y, and only four have to be considered when y = 0, since two of them vanish at y = 0. Another condition leading to only four generalized constants, which are found to be independent of y, is when 6”’ = 1. Hence when material constant 6(l) of material no. 1 is equal to one, the effect of the 2873

J. C. Sung and J. Y. Liou

2874

alignments of material no. 1 on the behavior of material no. 2 is indifferent. The kernel functions developed are further employed to investigate some interesting features for the stress intensity factors when crack faces are subjected to self-equilibrating loadings, which are discussed in Section 4 of this paper. Finally, some numerical results for crack faces subjected to uniform pressure or shear loadings are presented. 2. STROH FORMALISM

A two-dimensional deformation of a linear elastic solid whose field quantities are functions of only x, and x2 is considered here. The general expressions for the displacement u and stress function 4 for such a deformation are (Eshelby et al. (1953), Stroh (1958)) : u = 2 Re {Af(z)}

(1)

4 = 2 Re {Bf(z)}

(2)

where Re ( } denotes the real part, and where f(4

=

[fi(Z1),f2(Z2),f3(Z3)lT

1,2,3). Matrix A, with components denoted by with zk = X1 +&X2 (k = pk are determined from the following eigenvalue problem : {Ciikl

ak,

+Ci2kI)+PTCi2k2}

+Pj(CtlkZ

=

0

(no

sum

on

akj,

and constants

j)

(4)

where are the elastic constants. Without loss of generality, one may take the imaginary part of pk to be positive. Matrix B in eqn (2) is defined by cijkl

B = R=A+TAP

(5)

where

and P = diag (pI,p2,p3).

& =

Cilk2

(6)

Tik

Ci2k2

(7)

=

The stress function 4 is related to the stress components by

hJJ12~~,3)T=~=

(C2I

7 022,

(T2dT

-84

- 2 Re{BPf’(z)}

2

=

~a’ ax,

=

2 Re {Bf’(z)}

where P(z) =

W)

x

(10)

=

The matrices A and B satisfy the following orthogonality and Smith (1977)) :

relations (Stroh (1958), Chadwick

(11) where I is a 3 x 3 unit matrix. It follows from eqn (11) that the matrix L defined as

Subinterface crack in dissimilar orthotropic materials

2875

L = -2iBBT

(12)

where i2 = - 1, is real, symmetric, and positive definite, whereas S given by S = i(2ABT-I)

(13)

is real. In the following sections, we shall focus on the problem that the assumption that the x,-axis coincides with the material alignments will always introduce. This makes the anti-plane behavior decouple from that for the in-plane response for orthotropic material. Hence, we shall ignore the anti-plane deformation. Accordingly, the size of the matrices and vectors defined above and in what follows will become 2 x 2 and 2 x 1, respectively. For example, the matrices B, L, and S for orthotropic material are (Dongye and Ting (1989))

(14)

L = diag(L,,(2)1’2L,,)

SC

[

,”

(15)

-(y2s2’]

(16)

2'

where '/2

G6[(c*lc22)"2--121 S2'

(17)

=

i

c22PG6+c12+(clIc22)"21

Ll'

=

[(cllc22)"2

I

+C,21~2,

(18)

and CUP(a$ = 1,2, . . . ,6) is a contracted notation for cij,+ The parameters ki and k2 in eqn (14) are complex constants determined by the normalization conditions of eqn (11). The matrices B, L, and S and constants pcl can be expressed in terms of Krenk’s parameters K, 6, v, and E (Krenk (1979), Sung and Liou (1994a)) as follows :

V-7 E

80+0_

B=

1

+w._)]‘/~ eini4 [6(0+ -o-)]‘I2 ecini4 U>l [~(~++~_)]-“2e-in/4 [6(~+-o_)]-‘i2ei”i4 ’ -[&CO+

, ,lc, <1 (19) [6((u_ -ico+)]-‘ eiz’ /2 [6(0_ 4 +iw+)]-“2ein/4 1 [6(0_ -ic~+)]‘/~ eiXi4

-[6(0_

+iw+)]li2 eini4

(20)

p’ = where

i&o+ +a_),

rc > 1

6(io+ -o_),

I4 < 1 ’ p2 = i G(ico+ +a_),

1

i6(w+ -w_),

IC2 1 Id < 1

(21)

2876

J. C. Sungand w+

=Jtl+rc)/2,

J. Y. Liou w_

=dm

(22)

since the elastic constants are related to Krenk’s parameters by

c,, =-

d2E

l-v2’

E c22

=

VE Cl2

=-

62(1-112)’

C66

1 - \‘I ’

=

GE_3

(23)

where E is the plane-strain effective stiffness, v the effective Poisson’s ratio, 6 the stiffness ratio, and K the shear parameter. The positive definiteness of the strain energy density requires that 6 > 0, E > 0, /VI < 1, and IC> - 1. Note that degenerate materials occur when K = 1 since p, = p2 at IC= 1. Note also that, for isotropic material, 6 = K = 1 and E and v are reduced to, for the plane-strain case, EJ( 1 - vf) and vJ( 1 - v,), respectively, where E, is the Young’s modulus and vi is the Poisson’s ratio for isotropic material. For later reference, we introduce matrix E, defined by Ei = BI,B--’

(24)

where I, = diag (1, 0), I2 = diag (0, 1 ), which can also be expressed in terms of Krenk’s parameters as

1’ 6’ 1 1’ -6 ’ 1

i6 w- -w+

Lu-

w--w+ -_ib-’

-id ~nL+cu+

E, = w- +iw+ -6-l

3. SINGULAR

Sico,

w_-io,

INTEGRAL

ti>l

(til < I

K>l

(25)

IKI < 1

EQUATIONS

The problem considered is shown in Fig. 1. One aligned orthotropic material (called material no. 2), with the material principal axes parallel with the coordinate axes, is bonded

Fig. 1. Geometry

of the problem

Subinterface crack in dissimilar orthotropic materials

287-l

perfectly along the interface to another orthotropic material (called material no. l), whose material in-plane principal axes can have an angle y relative to the bonded interface. A subinterface crack of length 2c is situated a distance d from the interface with material no. 2. The faces of the crack are subjected to self-equilibrating forces. The problem can be simulated by distributing dislocations on the crack faces. By doing so, the problem is then formulated in terms of a system of singular integral equations from which the dislocation densities can be determined. In a recent paper by the present authors (Sung and Liou (1994b)), the problem of two aligned orthotropic materials with cracks being perpendicular to the interface is treated. In that paper, the kernel functions obtained are given explicitly in real forms and four generalized Dundurs’ constants are introduced (Sung and Liou (1994b)). In this section, we shall show that for the present problem, even though one of the orthotropic materials is not aligned, the kernel functions can still be expressed in real forms that are useful in investigations of subinterface crack problems. Instead of four constants, this time we shall introduce six generalized Dundurs’ constants. The procedures to obtain real kernel functions are similar to those described in the paper mentioned above (Sung and Liou (1994b)). Hence we shall outline in the following only the main results. First, note that the complex forms of the system of singular integral equations and the auxiliary conditions are (Sung and Liou (1994b))

s c

bc2’(t) dt = 0,

(26)

--c

respectively, where superscript (2) (or (1)) will denote quantities related to material no. 2 (or material no. 1) and

K(& t) = - 2

Re {Fki(<, t)Ei2’ME’,“)

i

(27)

k=lj=l

bC2’(t)= L”‘b,(t),

ItI d c

(28)

In eqns (27) and (28) b2(t) are dislocation densities defined on the crack faces, and functions Fki are given by Fkj((, t) = [(&j- t) - d(pi2’-#‘)]

-’

(29)

and matrix M is given by (Ting (1982, 1992)) M

=

-I--‘G

(30)

where H = R(y)T(iA(‘)B(‘)-‘)SZ(y) + (iA(‘)B@-‘)

(31)

G = n(y)T(iA(l)B(l)-‘)SZ(y) - (iA(2)B(2)-‘)

(32)

and

with

2878

J. C. Sung and J. Y. Liou

Matrix M can be expressed follows 1

M= 1 -B’Bz where the six generalized

[ -sin(y)

explicitly

-A’&

Dundurs’

cos (y)

in terms

1

sin(Y)

cos(Y)

WY) =

(33)

of six generalized

Dundurs’

M’+P’P2+&&

(n’ -iB’)(l+a2)

(A, +&)(l

512+B,Pz +2,/l,

constants

+a,)

constants

1

as

(34)

are defined by

-u,, -u22 c(’ = D,,’ c12 = D22

’

(35) of the matrices D and U, where D,, and r/,, (no sum) are the diagonal components respectively, and W,* and D,, are the elements of the first row and second column of W and D, respectively. Matrices D, U, and W are given, in terms of Krenk’s parameters, by D = Re {H} = CQJ)~L(“~‘~~(~)+L(~’

=I

$+&(I

+sin2(y)(6”)*

’

-

~ sin(y) cos(y)(6”’ E”’

’-cY’))

2w”‘&” *(l+sin2(~)(6”’

‘-l))+p

E’2’

1

(36)

z(l

+ sin’(y)(S(“’ - 1)) - s

cos(y)(6”‘~ ’-cY’))

---sin(y) E”’

cos(y)(6”’

Zw’“6’ I ) + E’“(1+sin2(y)(~“’

’-iV’))

‘-l))-p

E”’ (37)

and

w =

Im {H} = Im {G} = -Q(y)rS(l)L(l) 0

=

-(l

-v”‘)E

(‘)-‘+(l

‘Q(y)+s(2)~(2)m’ (1

_v(2,)E’2’m’

_,(‘))E(‘)

’_ 0

(1

_V(2))E(2)-’

(38) 1

Note that W is independent of y. Note also that, when material no. 1 is aligned in parallel with the co-ordinate axes, i.e. y = 0, matrices D and U become diagonal, so that /2’= ,I2 = 0. Hence only four generalized Dundurs’ constants have to be considered for two aligned orthotropic materials. Another point to be emphasized is that, when material no. 1 has the

2879

Subinterface crack in dissimilar orthotropic materials

special property that 6 (‘) = 1 then the matrices D and U become diagonal again, and hence only four generalized Dundurs’ constants have to be considered for this special case. Furthermore, not only are matrices D and U diagonal, but matrices D and U are also independent of y as long as the condition 6(‘, = 1 of material no. 1 is satisfied. The features of ~5~‘=) 1 of material no. 1 will be further explored later. Note also that, for an isotropic bimaterial problem, the six constants defined are reduced to u, =a2

=a,

Bl = 82 = B, A, =A*

=o

(39)

where a and /3 are Dundurs’ constants (1968). On substituting eqns (21), (29), and (34) into eqn (27), the kernel functions become

K, I

K=

8@-‘K2,

c?(~)K,~

W)

K22 I ’

where (41)

and d(<, t) is given by d(r, t) = (2(t- r)Z+20!2’2(26(2)d)2)((5-t)4 + (4c@--2)(&-

f)2(2sW)2 +

The coefficients appearing in eqn (41) are CA’= 0

cl’ = &)(N,2+N2,)-N,, c:’ =(l +205(H,2

-(1+2e@)N,, -fV2,)

c3” = N22+(3-2W~,‘)N,, C4”

= N2,

C:’ =

-3&‘(N,2+Nz,)

-A,,

-2N,,

ci2 = 2w$‘*(N2, -A,,) c:’ = (1 +4w~‘2 )0y’(N,2 +N2,)-(1+2~~“)N,, c;’ = (4c@ - l)(N,2 -A*,) ci2 = N,, -(100!2”-3)N22+0!2’(N,2+N2,) c:’ = fV,2 -N2, c:” = -2N,, I2 = c@‘(N,, -N,2)-2~~)ZN22 co c; 2 = (20@ - 1)&z - (2fI@ + 1)N2,

-(1+8~~‘~)N22

(2Pd)“)

(42)

2880

J. C. Sung and J. Y. Liou

c;’ = (20$‘~ + l)N, , + (40’:‘~ - 1)NZ2 -o’:‘(3N,,

+ (8w’$” - l)N, 2)

c:’ = ni,, -(80:“2-3)N,? cl’ = N?? -N,

, -20”‘N+

IZ

c:2 = -2N,,

c;’ = o:"(N2, CT I

=

(2&

-N,2)+2co',?'2N22 - (2wy’2 + l)A, 1

- l)&,

c:’ = -(20+ (2)’+ l)N, , - (4~ ‘:“-~)N,,+co’$‘(~N,~+(~~‘:“-~)N,,) C:’

=

fl,2-(80(:)2-3)fi2,

c:’ = N,, -Nzz+2w:2’Nz, c:’ = -2ii721

(43)

In eqns (43), I’?,~$~,,

and N,,(k,j

= 1,2) are defined by

(44)

where the six generalized

Dundurs’

constants

are

c( _ l-AA-‘[l+sin’y(6”‘‘--l)] Il+AA~‘[l+sin”y(6”‘‘-l)] 1 -AA[l

$-sin’ y(6”’ ‘-l)]

1 +AA[l

+sin’ )‘(c?“)~~- l)]

x2 = [(1 - ,,(Q)/EQ)] - [(1 - v”‘)/E”‘]

/I, = #I’

(2W’:‘/E’“)

+ ( ~co’$‘/E”‘)AA

[l +sin* 1/(6”” - l)]

[(I _v”‘)/py-[(] _,(‘))/E”‘] pz = d’?’ ’ ._. (2~0’;-‘/E’~‘) + (2w(+“/E”‘)A[l +sin* ~(6”’ ’- l)] ;,, = ij(2)

Asinycosy(6”‘--6”‘~‘) l+AA-‘[1+sin2y(6”‘‘-l)]

)“2 =

p-’

Asinlicosy(6”‘-_6”‘~‘) (45) 1 +AA[l

+sin2 y(6”‘-‘-

l)]

which are found to be determined completely by Krenk’s parameters for both orthotropic materials and are functions of y. In above equations, A and A are defined by

Subinterface crack in dissimilar orthotropic materials A =

(2~‘:‘/~“‘)/(2~~‘/E(z))

A =

#‘)/8(*)

2881

(46)

It islclear from eqns (4O)-(46) that the dependence of the kernel functions on the parameters is given by

KS = K&t,

t, Id*),6’*‘d,a,,

d(*)-‘fi,,6(*)f12, P-‘A,, 6(*)1,)

a*,

(47)

Since the material constants of material no. 1 are all absorbed by the six generalized Dundurs’ constants, and hence the effects of material no. 1 on the behavior of material no. 2 will be directly reflected by these six constants only. Note that these six constants are functions of y. When y = 0, only four constants, i.e. a,,a2,j?,, and j?*,have to be considered, since il, = A2= 0 at y = 0. Note also that, when material no. 1 has the special property that 8(l) = 1 is satisfied, then one would find that 1, = A* = 0

(48)

again, and the other four constants for 6 (I) = 1 are independent of y. The kernel functions for this special material no. 1 are therefore also independent of y. Hence we can conclude that, when 6(‘) for material no. 1 is equal to unity, then the influence of the alignment of material no. 1 on the behavior of material no. 2 is indifferent. According to eqn (23), one can see immediately that the elastic constants Cl1 and C,, of material no. 1 will be related by Cl1

=

(49)

c22

for a(‘) = 1. The kernel functions for some special cases can be considered from the above general results. First, let us consider the case for an isotropic bimaterial problem, i.e. let K(‘)= 6(‘) = 1 and K(*)= 8’) = 1. One finds from eqn (45) that

which are, of course, all independent values in eqn (44), one finds that

a, =a2

=a

Bl

=

=

Iz,

=A*

I32

B

=o

(50)

of the material angle y. Substituting these special

N,, = N2* =-

a+/?*

1-b’ N12 =N21 =B(1+c1) l-/3’

(51)

and N,* = iV*, = 0. With these results and noting that 0’:’ = a?) = 1, one would find that the kernel functions obtained are the same as those obtained by Erdogan (1971). We next consider the case when E<‘)<
(52)

2882

J. C. Sung and J. Y. Liou

With these values, one finds that the kernel functions are then reduced to those for the problem of a half-plane solid with a traction-free condition (Sung and Liou (1994a)). If one considers the condition that E(‘)>>E(‘) (or A + 0), then the kernel functions for the problem of a half-plane solid with a clamped boundary can be obtained. This can be achieved by noting that

I, = 22 =o

(53)

and N

II

= N

= 4c@+(l 22

-v(2))2

40’:“_(l-v’2’)2

iv,2 = N2, =

4Q(

1 -v(2))

40~“-(l

_@)2

iV,2 =IQ2, =o

(54)

when E(‘)>> EC’).

4. STRESS INTENSITY

FACTORS

The kernel functions developed in the previous section are used to investigate some phenomena for the stress intensity factors for crack faces subjected to uniform pressure or shear loadings. For crack faces subjected to self-equilibrating loadings, the phenomena discussed below are still valid. Hence we shall discuss only cases for uniform loading. Noting that the explicit forms of the kernel functions given by eqn (40) involve the material parameter rY2),it would then be convenient to redefine the unknown function b(‘)(t) by

bC2’(t)=

1 [0

0

1

h(2)-’ b(t)

(55)

Hence, the singular integral equations, after the interval of the integration is normalized from ItI < c to Jt( c 1, become

where z and 0 are the applied uniform shear and pressure loadings, respectively. The kernel functions K,*8 are obtained by replacing dC2’dby 6’2’d/c in eqns (41) and (42) and are functions of

(57)

Hence the solution of b(t) will have a similar dependence, i.e.

2883

Subinterface. crack in dissimilar orthotropic materials

where

Note that, once the unknown quantities b(t) have been determined, the stress intensity factors, e.g. at the right crack tip, can be extracted directly by the following formula (Sung and Liou (1994a)) :

wkre the functions

l

=-- lim “e-1+

fna

are defined by

J2(5_1) l s

-1

f$(t,d2),

ac2’d -,b!,,a2,8(2)-‘~,,~(2)~2,8(2)-‘~,,8(2)j12 c

)

&

=&

Functions

f&,which

are regular in the interval 1tl < 1, are related to functions

cY2’d 2’-1a,,6’2’82,6’2’-‘1,,6’2’~2 &fJ t, fcC2),-,a,,a2,6’ c (

=

(61) f $,, by

1

~f~~(t,1((2),~,.l,a,,6”‘18,,6’2’82,~(2)-~~,,Sl2)j2)

We have to mention that, for the isotropic bimaterial problem, the counterpart is

(62) of eqn (60)

(63) where

are functions that usually need to be calculated numerically. In the following, we investigate some interesting phenomena for the stress intensity factors for the case when the alignments of material no. 1 are along the coordinate axes, i.e. y = 0. It is noted again that A, = A2= 0 when y = 0, and hence only four generalized Dundurs’ constants will be involved in the following discussions.

2884

J. C. Sung and J. Y. Liou

Case I

Suppose material no. 2 has the special property

that rcC2) = 1; the kernel functions

K,*, in eqn (57) will then be exactly the same as those functions for the isotropic bimaterial

problem as long as the generalized Dundurs’ constants for orthotropic chosen such that

bimaterials are

~1,= a2 = CI (note that, if c(, = a2, then 8’) = ~3’~‘) 8(2)-‘p, = #2)p2 = B

(65)

are satisfied where cr,p are Dundurs’ constants. Hence, from eqns (61) and (64) we can conclude that

(66)

This implies that the solutions to the orthotropic bimaterial problem with material compositions satisfying the above conditions can be obtained directly from those for the isotropic bimaterial problem. Case II Suppose that the compositions of two orthotropic materials are such that W = 0; the kernel functions will then totally vanish if the conditions a, =a2

=0

(67)

are also satisfied. This implies that the stress intensity factors for such dissimilar orthotropic compositions will be totally independent of the material constants. The results are therefore the same as those for a homogeneous medium. Case III

Suppose that the material axes are rotated by 90” for both orthotropic materials. One would then find that the parameters ~3~‘ and ) 8’) are changed in the following way :

Hence the constants a,, a2, @-’ /3,, and 8’)fi2 appearing in the functions f& will remain unchanged if 6(I) = ?Y2)is satisfied. This is due to the fact that a = a = (20’:‘/E’2’) - (20’:‘/E”‘) I

2

(2W~‘/P’)

&‘2’-‘pr = $2’/3, =

+ (2o’:‘jE”‘)

(1 _ V(2))/E(2)- (1 _ p)/jp (20~‘/P’)

+(2&‘/P))

(69)

when 8’) = ~5’~‘Hence . the functionsfaP for the 90”-rotated case can be obtained by just replacing 6’2’d/c by 6 c2)m’d/c from the before-rotated situation. With these newly obtained

2885

Subinterface crack in dissimilar orthotropic materials

y=O

-1.1

d2)=

1

6(2)d/c=0.2

-0.0

1:1

-1.1

-0.0

1 1

a

a Fig. 2 (a) and (b). Functionsf&

defined in eqn (66) versus 01for y = 0, K@)= 1, and 6%/~ = 0.2 and for various values of /I.

functions, the stress intensity factors for the 90”-rotated case problem can then be computed directly by eqn (60) with do) replaced by cV~)-’in that formula.

5. SOME NUMERICAL

RESULTS

As has been discussed in the previous section, when the alignment of the principal axes of material no. 1 is along the coordinate axes, i.e. y = 0, and if rct2)= 1, then the functions f& related to the stress intensity factors given by eqn (60), can be obtained from the corresponding isotropic bimaterial problem. Since, to our knowledge, no information is available for& in the literature even for the isotropic bimaterial case, we therefore compute these functions numerically. A numerical scheme based on that of Gerasoulis (1982) is developed. Figures 2(a) and 2(b) are the results for these functions versus a for ~5’~‘d/c= 0.2. The effects of /? are also shown in these figures. One should note that material no. 1 becomes very flexible when al = a2 + - 1 and material no. 1 becomes very stiff when a1 = a2 --) 1. Note also that, when a = /3 = 0, the problem becomes homogeneous. Another point that we wish to address is to see the effect of rcC2) on functionsf& for two aligned orthotropic materials, i.e. y = 0. For simplicity, only the results for a, = a2 = a0 (i.e. ~5~‘ =) ~5~‘))and ~W’~, = 8(2)j12= fiO = 0 are given. The results are shown in Figs 3(a) and 3(b). It is observed that fi2and fi2 (Fig. 3(b)) are insensitive to the parameter K(‘) for this special choice of the four generalized Dundurs’ constants.

As noted previously, the generalized Dundurs’ constants are functions of y. It would therefore be useful to plot these constants versus y to see how dependent they are. Note that aI,a2,A.,, and 1, are dependent on the material parameters ~5(‘),6(~), and A only. Hence we plot in Figs 4(a) and 4(b) only the behavior of a,,a2,&, and A2for ~55~‘ = )2 and ~5~‘ =) 1 for various values of A. Note that a, = a2 = 1 and Iz, = A2= 0 when A = 0 (corresponding to material no. 1 being very stiff) and a, = a2 = - 1 when A --+cc (corresponding to material no. 1 being very flexible). It is observed from eqn (45) that constants a,,a2 and &,A2 are

J. C. Sung and J. Y. Liou

2886

1.5

,

y=O

&,=O

y=o

6(2)d/c=0.2

po=o l_+2) d/c=02

7-

-1.I

-0.0

1

-1.1

-0.0

a0

1

a0

Fig. 3 (a) and (b). Functions&

defined in eqn (61) versus a, for y = O,BO= 0, and @d/c = 0.2 and for various values of K@).

related to each other by

al(y) =

( ) (5-Y1

a2 t -Y

,

A(Y) =A2 (p=2

&

1

(70)

p=2 0.8

p=

1

,

-

A=0 ______ A=1

---

a1

-

-

--_ --__ - -.__ ‘.._ =._

A=10 A=100 A=1000

&. . ;= -0. -.___

__p,“._/--

,w -.

i

- -

0

30

60

Y

90

0

A=100

30

60

90

Y

Fig. 4 (a) and (b). Generalized Dundurs’ constants a,,aZ,&, and I, versus y for 6”’ = 2, and P and for various values of A.

= 1

Subinterface crack in dissimilar orthotropic materials &=o.

/&

1

,5”‘=2 &l

2887

,j’0’d/c=0.2

5 __o____.o-----

f4 a@

__B---

_____o_.---=---

1.0

f aP 0.8

3

fll

-----*----_~____~_____o-______~____

t

2 0.6 1

_+__‘_+----” -2- - _____+_____w----*---0.2

_____*__-__* __----( __-I I ,T,, , , , , , ,, , , , , ,

-3+m%wyT 0

30

60

0

90

60

30

Y

90

Y

Fig. 5 (a) and (b). Functions&, defined in eqp (61) versus y for j$, = 0, and S2)d/c = 0.2 and for various values of A.

K@) =

1, 8’) = 2, ~5~‘ =) 1,

as long as a(*) = 1. Figures 4(a) and 4(b) have this feature since 6(*)= 1 in plotting these figures. It is noted from Fig. 4 that the results for ctl and a2 (and also for 1, and 2,) for A = 100 and A = 1000 are quite close. To see the effect of y on the functions defined in eqn (61), we computed these functions numerically for the following special material compositions :

Material no. 1

Material no. 2

6”’ = 2 (orthotropic)

Case I : #’ = 1 $2) = 1

Case II :

(isotropic)

(orthotropic)

K(2) = 5 $2) = 1

and, for simplicity, we let 1_

y(‘)

E(‘)

1-

p

(71)

= - E(2)

so that 6’*‘-‘8, = S’*‘/?Z= /I0 = 0. Note that the effect of parameter K(‘)of material no. 1

is reflected by the parameter A. The depth of the crack is chosen such that #*‘d/c = 0.2. Figures5(a) and 5(b) are the results for faP for the case when material no. 2 is isotropic. The results for the case when material no. 2 is orthotropic It is found from the numerical results that for

A= 0

= 5)

for

A = O,l,lO

5)

for

A = 0,l

f2,(K(2) = 1) xf2,(ic(*) = 5) f**(K

(*) =

1) ~:f**(fP

fi2(k(*) = 1) z5fi2(~(*)

are plotted in Figs 6(a) and 6(b).

=

(72)

2888

J. C. Sung and J. Y. Liou &=O

p-

J”‘=2

-5

&l

&j/c=0,2

____. ----_____*_____x-----

0

30

60

90

Y Fig. 6 (a) and (b). Functions& defined in eqn (61) versus y for B,, = 0, and @d/c = 0.2 and for various values of A.

7~60~

&,=O

6% 2 S@)= 1 6@)d/c=0.2

1.4

&,=()

740’

KC’) = 5, g(l) = 2, ~3’~)=

#)=2

&1

1,

&(2)d/cq)2

6, I----____

f.2 c---

---------

1.0

f

a8

i

0.8

fll

0.6

__--

______-------

____._.--

--

0.4

\ -!,L, O-

0.2 -------

f 21

-0.0 -0.2

---

It

;;;32

I\ ’ \\

-2

‘CK; Ic

-3

111”1’I’II’I”I’JI’,JIII,(II(

-50

50

150

250

350

450

550

f

12

-

“....y__- - - - - ----____ -----____

-50 50 150 250 350 450 550 A A Fig. 7 (a) and (b). Functionsf$ defined in eqn (61) versus A for fi,, = 0, y = 60°, S”’ = 2, 6”’ = 1, and #“d/c = 0.2 and for various values of K(*‘.

for all y. To see the effect of A on these functions, we therefore plot fMsversus A in Figs 7(a) and 7(b) for various values of rc(*)for y = 60’. It may be seen from these figures that functionsf,, andf,, are insensitive to K(*)when A is small, whereas functionf, , increases rapidly for small values of A and then becomes approximately constant for the other values

of A.

Subinterface crack in dissimilar orthotropic materials 6. CONCLUDING

2889

REMARKS

The problem of a subinterface crack in dissimilar orthotropic materials is investigated. With the use of the material parameters introduced by Krenk in conjunction with the Stroh formalism, the kernels of the singular integral equations are expressed in real forms. These forms reveal that the effects of the material (without crack) on the behavior of the material (with crack) are determined completely through six generalized Dundurs’ constants. The alignments of the material (without crack) are found to have no effect on the behavior of the material (with crack) when the material (without crack) has the property that 6 = 1. The real expressions for the kernels are further employed to discuss some features of the stress intensity factors. Some numerical results for the stress intensity factors for crack faces subjected to uniform pressure or shear loadings are also given. REFERENCES Chadwick. P. and Smith. G. D. (1977). Foundations of the theory of surface waves in anisotropic elastic materials. Adv. Appl. Mech. 17, 303-376.

’

Clements, D. L. (1971). A crack between dissimilar anisotropic media. In?. J. Engng Sci. 9,257-265. Doneve. C. and Tine. T. C. T. (1989). Exnhcit exnressions of Bamett-Lothe tensors and their associated tensors fo;orthotropic materials. Q. 3. Appl. Math. 47;723-734. Dundurs, J. (1968). Elastic Interaction of Dislocations with Znhomogeneities: Mathematic Theory of Dislocation, pp. 70-l 15. ASME, New York, NY, USA. Erdogan, F. (1971). Bonded dissimilar materials containing cracks parallel to the interface. Engng Fracr. Mech. 3,231-240.

Eshelby, J. D., Read, W. T. and Shockley, W. (1953). Anisotropic elasticity with applications to dislocation theory. Acta Metall. 1,251-259. Gerasoulis, A. (1982). The use of piecewise quadratic polynomials for the solution of singular integral equations of Cauchy type. Comput. Math. Appl. 8, 15-22. Gotoh, M. (1967). Some problems of bonded anisotropic plates with crack along the bond. Znt. J. Fract. Mech. 3,253-265.

Hutchinson, J. W., Mear, M. E. and Rice, J. R. (1987). Crack paralleling an interface between dissimilar materials. ASME

J. Appl. Mech. 54,828-832.

Hwu, C. (1993). Explicit solutions for collinear interface crack problems. Znr. J. Solids Structures 30,301-312. Krenk, S. (1979). On the elastic constants of plane orthotropic elasticity. J. Compos. Mater. 13, 108-I 16. Lu, H. and Lardner, T. J. (1992). Mechanics of subinterface cracks in layered material. Znt. J. Solids Srrucfures 29,669-688.

Miller, G. R. (1989). Analysis of crack near interfaces between dissimilar anisotropic materials. In?. J. Engng Sci. 27,667-678.

Stroh, A. N. (1958). Dislocations and cracks in anisotropic elasticity. Philos. Mag. 7,625646. Sung, J. C. and Liou, J. Y. (1994a). Analysis of a crack embedded in a linear elastic half-plane solid. ASME J. Appl. Mech. to be published. Sung, J. C. and Liou, J. Y. (1994b). Some phenomena of cracks perpendicular to an interface between dissimilar orthotropic materials. ASME J. Appl. Mech. accepted for publication. Suo, Z. (1990). Singularities, interfaces and cracks in dissimilar anisotropic media. Proc. R. Sot. A 427, 331-358. Tamate, 0. and Iwasaka, N. (1976). Interaction between a bimaterial interface and an arbitrary oriented crack. Trans. Japan Sot. Mech. Engng 42,23-30.

Ting, T. C. T. (1982). Effects of change of reference co-ordinates on the stress analyses of anisotropic elastic materials. In?. J. Solids Structures 18, 139-I 52. Ting, T. C. T. (1986). Explicit solution and invariance of the singularities at an interface crack in anisotropic composites. Znt. J. Solids Structures 22,965-983. Ting, T. C. T. (1992). Image singularities of Green’s functions for anisotropic elastic half-spaces and bimaterials. Q. J. Mech. Appl. Maih. 45, 119-I 39. Ting, T. C. T. and Hoang, P. H. (1984). Singularities at the tip of a crack normal to the interface of an anisotropic layered composite. Znt. J. Solids Structures 20,439454. Willis, J. R. (1971). Fracture mechanics of interfacial cracks. J. Mech. Phys. Solids 19, 353-368. Wu, B. and Erdogan, F. (1993a). Fracture mechanics of orthotropic laminated plate-I : The through crack problem. Znt. J. Solids Structures 30,2357-2378. Wu, B. and Erdogan, F. (1993b). Fracture mechanics of orthotropic laminated plate-11 : The plane strain crack problem for two bonded orthotropic layers. Znt. J. Solids Sfructures 30,2379-2391. Wu, B. and Erdogan, F. (1993~). Fracture mechanics of orthotropic laminated plate-III : The surface crack problem. Znt. J. Solids Structures 30,2393-2406.