Integral formulation and self-consistent modelling of elastoviscoplastic behavior of heterogeneous materials

Predicting the overall behavior of heterogeneous materials, from their local properties at the scale of heterogeneities, represents a critical step in the design and modeling of new materials. Within this framework, an internal variables approach for scale transition problem in elastic-viscoplastic

We propose a simple, straightforward self-consistent method for predicting the inelastic stress-strain behavior of multiphase materials. Each constituent phase is modeled as an isotropic, incompressible viscoplastic solid. A self-consistent scheme is used to derive the properties of the composite. A

An anisotropic hardening constitutive model based on the generalized isotropic hardening (GIH) rule was implemented into the nonlinear ®nite element method. The GIH rule describes discrete formation of homology centers and simultaneous hardening of both inner and outer yield surfaces. Consequently,