Numerical study of inclusion parameters and their influence on fatigue lifetime

•A numerical model for the determination of high cycle fatigue lifetime is proposed.•Virtual microstructures and crystal plasticity are suitable for fatigue modeling.•The model enables the numerical study on fatigue for various inclusion features.•The separate investigation of the inclusion’s influe...

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Bibliographic Details
Published in:International journal of fatigue 2018-06, Vol.111, p.70-80
Main Authors: Gillner, Karl, Henrich, Manuel, Münstermann, Sebastian
Format: Article
Language:English
Subjects:
Constitutive models
Crack propagation
Cyclic loads
Elasticity
Fatigue failure
Fatigue indicator parameter
Inclusions
Materials fatigue
Mathematical models
Metal fatigue
Microstructure
Numerical analysis
Parameter identification
Representative volume element
Structural integrity
Surface roughness
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Summary:•A numerical model for the determination of high cycle fatigue lifetime is proposed.•Virtual microstructures and crystal plasticity are suitable for fatigue modeling.•The model enables the numerical study on fatigue for various inclusion features.•The separate investigation of the inclusion’s influence reveals integrity parameters. The understanding of the influence of inclusion parameters like size, shape and surface roughness on the material’s fatigue behavior can provide important guidelines for future material design. In this study, a numerical model is used to calculate the influence of inclusions on fatigue properties. The model consists of the statistical evaluation of numerous representative volume element (RVE) calculations in combination with a crystal plasticity (CP) constitutive model. The RVEs contain inclusions which differ in size, shape, surface roughness and elastic mismatch to the matrix. These parameters have been identified to determine the fatigue lifetime for the case that inclusions are the origin of failure. For each inclusion type, up to 100 RVEs are generated. The RVEs have statistically equivalent distributed microstructural properties but differ in detail, though. The results show that the inclusion size has the biggest influence on the lifetime. The influence of shape and roughness of the inclusion surface is negligible small. The study of the elastic mismatch is matching literature findings. All in all, this study shows that the numerical model can be used to calculate the influence of inclusions on fatigue lifetime. The use of the model can help to reduce the experimental effort for specifying the minimum cleanness requirement of a steel to guarantee the structural integrity under cyclic loading.
ISSN:0142-1123
1879-3452
DOI:10.1016/j.ijfatigue.2018.01.036