Physically-based modeling of the cyclic macroscopic behaviour of metals

Procedia Engineering

Volumn 2, Issue 1, 2010, Pages 531-540

  Sauzay, Maxime ^a   Evrard, Pierre ^a,b   Steckmeyer, Antonin ^a   Ferri, Emilie ^a,c  

^a DIF   (France)

^b CEA DIF   (France)

^c UNIV GRENOBLE ALPES   (France)

Author keywords

Crystalline plasticity; Cyclic behaviour; Finite element method; Homogeneization; Metallic polycrystals

Indexed keywords

CONSTITUTIVE LAW; CRYSTALLINE PLASTICITY; CYCLIC BEHAVIOUR; CYCLIC STRAIN; EXPERIMENTAL DATA; FE METHOD; FINITE ELEMENTS; GRAIN SIZE; HOMOGENEIZATION; MACROSCOPIC SCALE; MACROSCOPIC STRESS; METALS AND ALLOYS; MULTIPLE SLIPS; PHYSICALLY BASED MODELING; PLANARITY; PLASTIC STRAIN; SCALE TRANSITION; SINGLE SLIP; SLIP SYSTEM; STACKING FAULT ENERGIES; STRAIN CURVES;

CRYSTALLINE MATERIALS; FATIGUE CRACK PROPAGATION; FINITE ELEMENT METHOD; METALLURGY; PLASTICITY; POLYCRYSTALS;

SINGLE CRYSTALS;

EID: 77954114901     PISSN: None     EISSN: 18777058     Source Type: Conference Proceeding    
DOI: 10.1016/j.proeng.2010.03.057     Document Type: Conference Paper

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