Fatigue life predictions by integrating EVICD fatigue damage model and an advanced cyclic plasticity theory

International Journal of Plasticity

Volumn 25, Issue 5, 2009, Pages 780-801

  Jiang, Yanyao ^a   Ott, Walter ^b   Baum, Christian ^c   Vormwald, Michael ^d   Nowack, Horst ^e  

^a University of Nevada   (United States)

^b TH Köln University of Applied Sciences   (Germany)

^c TPW Company   (Germany)

^d DARMSTADT UNIVERSITY OF TECHNOLOGY   (Germany)

^e UNIVERSITY OF DUISBURG ESSEN   (Germany)

Author keywords

Cyclic plasticity; Fatigue prediction; Multiaxial fatigue

Indexed keywords

FORECASTING; PLASTIC DEFORMATION; PLASTICITY; STEEL STRUCTURES; STRESS-STRAIN CURVES;

CUMULATIVE DAMAGES; CYCLE COUNTING; CYCLIC PLASTICITY; CYCLIC STRESS-STRAIN CURVES; DAMAGE PREDICTIONS; EXPERIMENTAL OBSERVATIONS; FATIGUE DAMAGE MODELS; FATIGUE LIFE PREDICTIONS; FATIGUE LIVES; FATIGUE MODELS; FATIGUE PREDICTION; LOADING CONDITIONS; MATERIAL CONSTANTS; METALLIC MATERIALS; MULTIAXIAL FATIGUE; MULTIAXIAL STRESS STATE; PLASTIC-STRAIN ENERGIES; PREDICTION MODELS; RANDOM LOADINGS; STRESS-STRAIN RESPONSE;

FATIGUE DAMAGE;

EID: 62049083781     PISSN: 07496419     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijplas.2008.06.007     Document Type: Article

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