A plane-strain elastoplastic finite-element model for cold rolling of thin strip

A formulation for ®nite element plane strain limit analysis of rigidly perfectly plastic solids governed by von Mises' plasticity condition is presented. The approach is based on the kinematic theorem of limit analysis formulated as a minimum problem for a convex and non-smooth dissipation functiona

Many practical built-up structures, e.g., the modern car body, are essentially assemblies of numerous thin plates joined at many edges. The plates are often so thin that they cannot support appreciable loads out of plane. In the case of a car, the body can only support the static loads of either the

This paper presents a phenomenological model for the simulation and analysis of stress-induced orientational hardening in semicrystalline polymers and polycarbonates at ÿnite strains. The notion of intermediate (local) stress-free conÿguration is used to develop a set of constitutive equations, and

In order to predict the loads and prolile of strip in a cold rolling process, a mathematical model was developed. This model combines well-known classical and analytical solutions for rolling direction with a numerical approach to width direction. Up to 10 passes on 2-or 4-high mills can be simulate

An updated Lagrangian implicit FEM model for the analysis of large thermo-mechanically coupled hyperelasticviscoplastic deformations of isotropic porous materials is considered. An appropriate framework for constitutive modelling is introduced that includes a stress-free thermally expanded conÿgurat