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I.V. Mishustin and A.A. Movchan, "Analog of the Plastic Flow Theory for Describing Martensitic Inelastic Strains in Shape Memory Alloys," Mech. Solids. 50 (2), 176-190 (2015)
Year 2015 Volume 50 Number 2 Pages 176-190
DOI 10.3103/S0025654415020077
Title Analog of the Plastic Flow Theory for Describing Martensitic Inelastic Strains in Shape Memory Alloys
Author(s) I.V. Mishustin (Institute of Applied Mechanics, Russian Academy of Sciences, Leningradskii pr. 7, Moscow, 125040 Russia, lewis@nm.ru)
A.A. Movchan (Institute of Applied Mechanics, Russian Academy of Sciences, Leningradskii pr. 7, Moscow, 125040 Russia, movchan47@mail.ru)
Abstract Martensitic inelasticity effects in shape memory alloys are described by a version of the plastic flow theory with isotropic and translational hardening, where the maximum value of the phase-structure strain intensity is taken for the isotropic hardening parameter. We show that, in the framework of this model, the entire inelastic deformation process is generally divided into the stages of purely translational and combined hardening and the tangent modulus is discontinuous on the interface between these stages.
Keywords shape memory alloy, martensitic inelasticity, plastic flow theory, isotropic hardening, translational hardening, tangent modulus
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Received 29 September 2014
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