Boundary element analysis for elastic and elastoplastic problems of 2D orthotropic media with stress concentration

A boundary element method is developed for fracture analysis of gradient elastic planar solids under static loading. A simple version of Mindlin's general theory of gradient elastic materials is employed and the two required boundary integral equations, one for the displacement vector and the other

We present a method that extends the ¯exibility matrix method for multilayer elasticity problems to include problems with very thin layers. This method is particularly important for solving problems in which one or a number of very thin layers are juxtaposed with very thick layers. The standard ¯exi

## Abstract An advanced boundary element method (BEM) for solving two‐ (2D) and three‐dimensional (3D) problems in materials with microstructural effects is presented. The analysis is performed in the context of Mindlin's Form‐II gradient elastic theory. The fundamental solution of the equilibrium

A series of numerical tests is carried out employing some commonly used finite elements for the solution of 2-D elastostatic stress analysis problems with an automatic adaptive refinement procedure. Different kinds of elements including Lagrangian quadrilateral and triangular elements, serendipity q