Numerical simulation of fatigue crack propagation under biaxial tensile loadings with phase differences
Fatigue crack propagation under the biaxial tensile loading, which loading directions are normal and parallel to the initial crack position, is highlighted in this study. Most of in-service structures and vessels are subjected to many types of loading. Generally, these loadings have different axial...
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Veröffentlicht in: | Marine structures 2015-07, Vol.42, p.53-70 |
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Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | Fatigue crack propagation under the biaxial tensile loading, which loading directions are normal and parallel to the initial crack position, is highlighted in this study. Most of in-service structures and vessels are subjected to many types of loading. Generally, these loadings have different axial components with different phases. However, the structural integrities of structures and vessels are evaluated according to design codes based on theoretical and experimental investigations under a uniaxial loading condition. Most of these codes are based on the S–N curves approach. An approach that does not use S–N curves has been favored by researchers, with the fracture mechanics approach preferred for evaluating the fatigue life of structures. An advanced fracture mechanics approach was developed based on the Re-tensile Plastic zone Generating (RPG) stress criterion for fatigue crack propagation. In this study, fatigue crack propagation tests under biaxial loading with six different phase and loading conditions are performed and the effect of the phase difference under biaxial loading is evaluated. A numerical simulation method of fatigue crack propagation based on the RPG stress criterion under different biaxial loading phase conditions is presented and compared to measured data.
•The effect of axial biaxial tensile loading phase difference on fatigue crack propagation.•Set up fatigue crack propagation testing system for controlled variable biaxial tensile loading.•Simulate crack propagation history of biaxial tensile loading with variable phase & range. |
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ISSN: | 0951-8339 1873-4170 |
DOI: | 10.1016/j.marstruc.2015.03.003 |