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A constitutive model for the uniaxial tensile plastic behavior of metals based on the instantaneous strain-hardening exponent

Tiago Bristt Gonoring, Mariane Gonçalves de Miranda Salustre, Gabriela Aksascki Caetano, João Batista Ribeiro Martins, M. T. D. Orlando

2022Journal of Materials Research and Technology17 citationsDOIOpen Access PDF

Abstract

The present work develops a new constitutive equation model for strain-hardening behavior of metallic materials (named herein as the Gonoring model) based on the definition of the instantaneous strain-hardening exponent. This new proposal was applied to experimental uniaxial tensile data of a lean duplex stainless steel alloy UNS s32304 (LDSS 2304) in the as-received (AR) condition and on identical heat-treated specimens at four different temperatures. This choice was justified because this is a steel that presents two phases (ferrite and austenite), which makes it a more universal example from the point of view of applying a new constitutive equation model. These heat treatments induced sigmoidal strain-hardening behavior at uniaxial tensile in this alloy. The Gonoring proposal was able to predict the strain-hardening behavior of both the sigmoidal and parabolic-shaped strain-hardening curve of a lean duplex stainless steel alloy 2304.

Topics & Concepts

Materials scienceConstitutive equationHardening (computing)Strain hardening exponentAlloyUniaxial tensionUltimate tensile strengthAustenitePlasticityComposite materialMetallurgyWork hardeningFerrite (magnet)ExponentStructural engineeringFinite element methodMicrostructurePhilosophyLinguisticsLayer (electronics)EngineeringMicrostructure and Mechanical Properties of SteelsMicrostructure and mechanical propertiesHigh Temperature Alloys and Creep
A constitutive model for the uniaxial tensile plastic behavior of metals based on the instantaneous strain-hardening exponent | Litcius