Finite element method combined with dynamic photoelastic analysis to determine dynamic stress-intensity factors

+ract-A formula is derived for determining the stress intensity factors from the path independent J-integral which has been formulated in the previous paper as the energy release rate by taking the effect of inertia into account. Both pure and mixed mode problems of a suddenly loaded crack can be an

A technique to evaluate the dynamic stress intensity factors and T-stress is developed by extending the scaled boundary finite-element method. Only the boundary of the problem domain is discretized. The inertial effect at high frequencies is modeled by a continued fraction solution of the dynamic st

In the present paper, a combination of the boundary element method is proposed for calculating the stress intensity factors of two-dimensional crack problems including mixed mode ones. In this method, finite elements are only allocated around a crack tip and boundary elements are used to discretize

Fatigue crack growth (fcg) and threshold behavior of engineering alloys may be studied using an ultrasonic fatigue device, in which the loading frequency is 20 kHz. In this investigation, the stress intensity factors in ultrasonic fatigue testing were determined through dynamic modal analysis and th