Boundary element formulations for the dynamic analysis of cracked structures

A new methodology for computing dynamic stress intensity factors in the frequency domain based on the mixed boundary element method, a combination of the equations corresponding to the integral representations of displacements and tractions, is proposed and analysed. The expressions of hypersingular

In this paper a general boundary element formulation for the three-dimensional elastoplastic analysis of cracked bodies is presented. The non-linear formulation is based on the Dual Boundary Element Method. The continuity requirements of the field variables are fulfilled by a discretization strategy

In this paper, a cracked element is developed incorporating a non-propagating edge crack into a structural beam member. The additional flexibility that the crack generates is evaluated using strain energy density factors given by linear fracture mechanics. Based on this flexibility the stiffness mat

In this paper, the dual boundary element method in time domain is developed for three-dimensional dynamic crack problems. The boundary integral equations for displacement and traction in time domain are presented. By using the displacement equation and traction equation on crack surfaces, the discon