Aspects of the Modeling of High-Cycle Fatigue

Błażej Paluszyński; Thomas Böhlke

doi:10.4028/www.scientific.net/KEM.348-349.121

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Cyclic Plasticity of a Cracked Structure Subjected to Mixed Mode Loading
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Molecule Mechanics Simulation on the Deformation and Damage Process in POSS Nanocomposite
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Cyclic Plastic Response and Fatigue Life of Materials
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Growth of Short Fatigue Cracks Emanating from Notches in an Austenitic-Ferritic Stainless Steel
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Aspects of the Modeling of High-Cycle Fatigue
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Damage Assessment of Steel Bridge Members by Fatigue Vulnerability Considering Corrosion and Traffic Variation with Time
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Comparison of DBEM and FEM Crack Path Predictions with Experimental Findings for a SEN-Specimen under Anti-Plane Shear Loading
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Progressive Failure Analysis of Composite Pressure Vessels by Finite Element Method
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Crack Growth Process of Ni-Single Crystal with Cathodic Hydrogen Charging
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HomeKey Engineering MaterialsKey Engineering Materials Vols. 348-349Aspects of the Modeling of High-Cycle Fatigue

Aspects of the Modeling of High-Cycle Fatigue

Abstract:

An overview on modeling of high-cycle fatigue is given and experimental findings of the damage accumulation are discussed. Finally we sketch an isotropic constitutive model for the description of the damage accumulation due to high-cycle fatigue.

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Key Engineering Materials (Volumes 348-349)

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121-124

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https://doi.org/10.4028/www.scientific.net/KEM.348-349.121

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Online since:

September 2007

Authors:

Błażej Paluszyński, Thomas Böhlke

Keywords:

Continuum Damage Mechanics, Damage Accumulation, High Cycle Fatigue (HCF)

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