Complex stress intensity factors at tips of cracks along interfaces of dissimilar media

The stress intensity factors of an interface crack in dissimilar materials are clarified and an extrapolation method to determine the stress intensity factors of an interface crack is proposed. The BEM using Hetenyi's fundamental solution is applied to crack problems in dissimilar materials and vari

The sohttion of crack problems in plane or antiplane elasticity can be reduced to the solution of a singular integral equation along the cracks. In this paper the Rada~hebyshev method of numerical integration and soiution of singular integral equations is modified, through a variable transformation,

## A&r& -By means of Fourier and Hankel transform methods and general conclusions from previous papers, this paper deduced the accurate solutions for stress intensity factors for hvo different materials with interface cracks subjected by concentrated forces at any point and at axis of symmetry for

AImtract-In this paper, the distribution of stress and displacement due to propagation of two parallel and co-planar Grilhth cracks with constant velocity under antiplane shear stress at the interface of two dissimilar elastic media are presented. In the lirst case, cracks are assumed to propagate a

A new type of finite element is introduced which embodies the inverse square root singularity present near a crack in an elastic medium. Using this element near the tip in two typical cracked configurations, stress intensity factors within 5 per cent of accepted values were obtained with meshes havi