A general failure criterion for plain concrete

A rationale for internal hydrogen embrittlement failure is constructed from the following elements: (I) stress enhanced hydrogen accumulation; (2) formation of a microerack; (3) precipitation of hydrogen in the microcrack and build up of pressure; (4) attainment of a critical combination of pressure

A material model for plain concrete formulated within the framework of multisurface elastoplasticity-damage theory is proposed in this paper. Anisotropic sti ness degradation as well as inelastic deformations are taken into account. The applicability of the model encompasses cracking as well as the

Several computational aspects of the fracture energy based softening plasticity model for plain concrete are considered. A need for a more robust stress return strategy is identified, as the basic closest point projection algorithm leads to regions of nonconvergence, associated with zones of high cu

A coordinate-free formulation of a failure criterion for transversely isotropic solids is proposed. In the threedimensional stress space the criterion is represented by an elliptic paraboloid. The anisotropic form of the proposed criterion is based on generalization of the second invariant of the de