From visco to perfect plasticity in thermoviscoelastic materials

TL;DR

This paper develops a thermodynamically consistent model for thermoviscoplasticity, establishing existence of solutions and analyzing the asymptotic transition to perfect plasticity as viscosity and inertia effects vanish.

Contribution

It introduces two weak solution concepts for a complex PDE system and proves their existence, also analyzing the limit to perfect plasticity with coupled temperature evolution.

Findings

Existence of entropic and weak energy solutions for the PDE system.

Convergence of solutions to the Prandtl-Reuss model in the vanishing-viscosity and inertia limit.

Coupled temperature and plasticity evolution in the limiting model.

Abstract

We consider a thermodynamically consistent model for thermoviscoplasticity. For the related PDE system, coupling the heat equation for the absolute temperature, the momentum balance with viscosity and inertia for the displacement variable, and the flow rule for the plastic strain, we propose two weak solvability concepts, 'entropic' and 'weak energy' solutions, where the highly nonlinear heat equation is suitably formulated. Accordingly, we prove two existence results by passing to the limit in a carefully devised time discretization scheme. Furthermore, we study the asymptotic behavior of weak energy solutions as the rate of the external data becomes slower and slower, which amounts to taking the vanishing-viscosity and inertia limit of the system. We prove their convergence to a global energetic solution to the Prandtl-Reuss model for perfect plasticity, whose evolution is `energetically' coupled to that of the (spatially constant) limiting temperature.