Constitutive modeling for flow behavior of GCr15 steel under hot compression experiments

Materials and Design

Volumn 43, Issue , 2013, Pages 393-401

  Yin, Fei ^a,b   Hua, Lin ^a,b   Mao, Huajie ^a   Han, Xinghui ^a,b  

^a WUHAN UNIVERSITY OF TECHNOLOGY   (China)

^b Hubei Key Laboratory of Advanced Technology of Automotive Parts   (China)

Author keywords

Constitutive model; Flow behavior; Hot deformation; Steel

Indexed keywords

ARRHENIUS EQUATION; BEARING STEELS; COMPRESSION EXPERIMENTS; COMPRESSIVE DEFORMATION BEHAVIOR; DEFORMATION TEMPERATURES; DYNAMIC SOFTENING; EXPERIMENTAL VALUES; FLOW BEHAVIORS; GCR15 STEEL; HOT COMPRESSION TESTS; PEAK STRESS; PREDICTION ACCURACY; STRESS LEVELS; STRESS VALUES; TEMPERATURE RANGE; TRUE STRESS-STRAIN CURVES; ZENER-HOLLOMON PARAMETER;

COMPRESSION TESTING; CONSTITUTIVE EQUATIONS; CONSTITUTIVE MODELS; DEFORMATION; FLOW FIELDS; HOT WORKING; INVERSE KINEMATICS; RELIABILITY ANALYSIS; STEEL; STRESS-STRAIN CURVES;

STRAIN RATE;

EID: 84864568489     PISSN: 02641275     EISSN: 18734197     Source Type: Journal    
DOI: 10.1016/j.matdes.2012.07.009     Document Type: Article

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