Finite element simulation of martensitic transformation in single-crystal TRIP steel based on crystal plasticity theory with cellular automata approach

Key Engineering Materials

Volumn 274-276, Issue I, 2004, Pages 679-684

  Iwamoto, Takeshi ^a   Tsuta, Toshio ^b  

^a HIROSHIMA UNIVERSITY   (Japan)

^b HIROSHIMA INTERNATIONAL UNIVERSITY   (Japan)

Author keywords

Cellular Automaton; Computational Mechanics; Constitutive Equation; Crystal Plasticity; FEM; Pattern Formation; Strain induced Martensitic Transformation; TRIP steel

Indexed keywords

AUTOMATA THEORY; DEFORMATION; DUCTILITY; MECHANICAL PROPERTIES; SINGLE CRYSTALS; STEEL; STRAIN; CELLULAR AUTOMATA; COMPUTATIONAL MECHANICS; FINITE ELEMENT METHOD; MARTENSITIC TRANSFORMATIONS; PLASTICITY;

CELLULAR AUTOMATON; COMPUTATIONAL MECHANICS; CONSTITUTIVE EQUATION; CRYSTAL PLASTICITY; STRAIN-INDUCED MARTENSITIC TRANSFORMATION; TRIP STEEL; PATTERN FORMATION; STRAIN INDUCED MARTENSITIC TRANSFORMATION (SIMT);

MARTENSITIC TRANSFORMATIONS; STEEL STRUCTURES;

EID: 33646197752     PISSN: 10139826     EISSN: 16629795     Source Type: Book Series    
DOI: 10.4028/www.scientific.net/kem.274-276.679     Document Type: Article

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