Effects of the transverse stress on biaxial fatigue crack growth predicted by plasticity-corrected stress intensity factor

•A plasticity-corrected stress intensity factor is applied to biaxial fatigue.•The effects of transverse stress on fatigue crack growth is clarified.•A rational explanation is given for the conflicting experimental observations.•An analytical method for fatigue crack growth in biaxial loading is pro...

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Bibliographic Details
Published in:International journal of fatigue 2014-04, Vol.61, p.101-106
Main Authors: Dai, Peng, Feng, Miaolin, Li, Zhonghua
Format: Article
Language:English
Subjects:
Applied sciences
Biaxial fatigue
Crack propagation
Cracks
Exact sciences and technology
Fatigue
Fatigue (materials)
Fatigue crack growth
Fatigue failure
Fracture mechanics
Mathematical models
Mechanical properties and methods of testing. Rheology. Fracture mechanics. Tribology
Metals. Metallurgy
Plastic zone
Stress intensity factor
Stresses
Transverse stress
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Summary:•A plasticity-corrected stress intensity factor is applied to biaxial fatigue.•The effects of transverse stress on fatigue crack growth is clarified.•A rational explanation is given for the conflicting experimental observations.•An analytical method for fatigue crack growth in biaxial loading is proposed. The transverse stress has an important effect on the biaxial fatigue crack behavior. However, the experimental evidence has provided conflicting indications: it is sometimes considered to increase, decrease or have no effect. These complex phenomena cannot be rationally explained by the existing mechanical models. The effect of the transverse stress on the fatigue crack growth behavior is still one of the most puzzling questions in biaxial fatigue. Physically, this effect is a transverse stress induced plasticity phenomenon. In this paper, a plasticity-corrected stress intensity factor (PC-SIF) is proposed to describe the effect of transverse stress on biaxial fatigue. By use of this new crack driving force some important phenomena associated with transverse stress are predicted. Comparisons with experimental results showed that the PC-SIF as an effective mechanical parameter is capable of predicting the effects of the crack length, the stress level, cyclic stress ratio, biaxial stress ratio and phase difference on the biaxial fatigue crack growth. Consequently, the alleged conflicting experimental results have been rationally explained by the PC-SIF.
ISSN:0142-1123
1879-3452
DOI:10.1016/j.ijfatigue.2013.12.010