Michel Frémond, Michele Marino, Elisabetta Rocca
Published 2017-05-31Version 1
We present here a model for instantaneous collisions in a solid made of shape memory alloys (SMA) by means of a predictive theory which is based on the introduction not only of macroscopic velocities and temperature, but also of microscopic velocities responsible of the austenite-martensites phase changes. Assuming time discontinuities for velocities, volume fractions and temperature, and applying the principles of thermodynamics for non-smooth evolutions together with constitutive laws typical of SMA, we end up with a system of nonlinearly coupled elliptic equations for which we prove an existence and uniqueness result in the 2 and 3 D cases. Finally, we also present numerical results for a SMA 2D solid subject to an external percussion by an hammer stroke.
Shape memory alloys as gradient-polyconvex materials
Existence of solutions for a mathematical model related to solid-solid phase transitions in shape memory alloys
Energy scaling laws for geometrically linear elasticity models for microstructures in shape memory alloys
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