Constitutive Modeling of TWIP Steel in Uni-Axial Tension

Jin Kyung Kim; Yuri Estrin; Hossein Beladi; Sung Kyu Kim; Kwang Geun Chin; Bruno C. De Cooman

doi:10.4028/www.scientific.net/MSF.654-656.270

Paper Titles

Effect of Thermomechanical Processing Parameters on the Microstructure Development in Low Si TRIP Steel
p.254

Selective Oxidation and Sub-Surface Phase Transformation during Austenitic Annealing of TWIP Steels
p.258

Effect of N on Microstructure and Tensile Behavior of TWIP Steel
p.262

Hot-Working Behaviour of Advanced High-Manganese C-Mn-Si-Al Steels
p.266

Constitutive Modeling of TWIP Steel in Uni-Axial Tension
p.270

Development of a Robust TRIP800 Concept for GI/GA Automotive Applications
p.274

On the Stretch-Flangeability of High Mn TWIP Steels
p.278

Processing, Properties and Microstructure of a 1.2%Al TRIP Steel
p.282

Ultra Fine-Grained 6wt% Manganese TRIP Steel
p.286

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Constitutive Modeling of TWIP Steel in Uni-Axial Tension

Abstract:

High Mn steels demonstrate an exceptional combination of high strength and ductility due to their high work hardening rate during deformation. The microstructure evolution and work hardening behavior of Fe18Mn0.6C1.5Al TWIP steel in uni-axial tension were examined. The purpose of this study was to determine the contribution of all the relevant deformation mechanism : slip, twinning and dynamic strain aging. Constitutive modeling was carried out based on the Kubin-Estrin model, in which the densities of mobile and forest dislocations are coupled in order to account for the continuous immobilization of mobile dislocations during straining. These coupled dislocation densities were also used for simulating the contribution of dynamic strain aging on the flow stress. The model was modified to include the effect of twinning.