Stress intensity factor for cracked submarine pipeline with concrete cover

Stress intensity factors are presented for cracks at the edges of the central holes in a panel containing a uniformly spaced array of circular holes. The finite element method is employed to obtain numerical values of the J-integral and the near-tip displacements from which the stress intensity fact

AlMsnct-A model for fatigue crack growth, similar to that of Majumdar and Morrow, is proposed where the ' crack growth rate is determined from the iow cycle fatigue and cyclic strcss~train response of tbc material. The model is for a constant stress range at infinity, but does allow for a v&able str

Propagation of curved cracks under general remote loads and boundary conditions is an important aspect of fracture mechanics and structural geology. Nonuniform remote stress and mechanical interaction with nearby cracks or free surfaces can cause cracks to propagate along curved paths [1][2][3][4][5

## Stress intensity factors were determined for very short edge cracks with different inclinations but equal depths of crack tips from the heated edge of a plate under transient thermal stresses. The critical orientation of edge cracks was found experimentally.

The purpose of this report is to present some recent stress intensity factor solutions for cracked rings and holes which may be of general interest to other investigators. The present results are based on mode I solutions reported previously for radially cracked holes in large plates [I] and for rad