Low-cycle fatigue damage accumulation near the cold-expanded hole by crack compliance data

•Novel destructive method is implemented for quantitative assessment of fatigue damage.•Narrow notches serve to manifest a damage degree.•Normalized fracture mechanics parameters obtained serve as a current damage indicator.•Damage accumulation functions are presented in an explicit form.•Stress rat...

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Bibliographic Details
Published in:International journal of fatigue 2022-02, Vol.155, p.106590, Article 106590
Main Authors: Matvienko, Yury, Pisarev, Vladimir, Eleonsky, Svyatoslav
Format: Article
Language:English
Subjects:
Axial stress
Cold
Cold-expanded hole
Crack compliance method
Damage accumulation
Deformation
Displacement
Electronic speckle pattern interferometry
Fatigue failure
Fatigue life
Fracture mechanics
Fracture mechanics parameters
Low cycle fatigue
Materials fatigue
Notches
Numerical integration
Parameters
Residual stress
Speckle patterns
Stress concentration
Stress intensity factors
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Summary:•Novel destructive method is implemented for quantitative assessment of fatigue damage.•Narrow notches serve to manifest a damage degree.•Normalized fracture mechanics parameters obtained serve as a current damage indicator.•Damage accumulation functions are presented in an explicit form.•Stress ratio influence on damage accumulation rate is analyzed. Novel destructive method is implemented for quantitative assessment of fatigue damage accumulation in the stress concentration zone near the cold-expanded hole, which is characterized by residual stress influence. Damage accumulation is reached by preliminary push–pull loading of plane specimens with cold-expanded holes. Artificially introduced narrow notches, emanating from the hole edge at different stages of low-cycle fatigue, serve to manifest a damage level. Deformation response to local material removing is measured by electronic speckle pattern interferometry (ESPI) in terms of in-plane displacement components. Notches are inserted under constant external load to increase the measurement accuracy by reaching optimal fringe density. Normalized values of the notch mouth open displacement (NMOD), in-plane displacement component acting in the notch direction (U), the stress intensity factor (SIF), the T-stress and the biaxiality ratio are used as current damage indicator. Numerical integration of curves, describing an evolution of each fracture mechanics parameter, produces the damage accumulation function in an explicit form. It is established that all five fracture mechanics parameters give very close results. Developed approach is the essential link in predictable joints design to reach maximal beneficial effect of cold hole expansion on the fatigue life improvement of advanced aerospace structures.
ISSN:0142-1123
1879-3452
DOI:10.1016/j.ijfatigue.2021.106590