Abstract
The active system model was established under dry sliding friction in reciprocating motion, and the three-dimensional crack was established in the friction surface center of cuboid model. The characteristics of stress intensity factors were investigated by fracture mechanics and finite element method. The variation regulations of the stress intensity factors were obtained under different contact pressure, friction coefficient, ellipse shape ratio and ellipse parameter angle. The stress intensity factor KI increases with increasing of contact pressure in away from crack, and decreases with increasing of contact pressure in near crack. The stress intensity factor KII increases with increasing of contact pressure during a working cycle. During sliding block moving toward crack, the KI decreases with increasing of friction coefficient. The KI increases with increasing of friction coefficient during sliding block moving away from crack. The influences of friction coefficient on variation of KII nearly coincide with contact pressure. The KI and KII increase with increasing of ellipse shape ratio. The KI decreases, and then increases, the average value KII decreases with increasing of ellipse parameter angle. The fatigue cracks are mainly mode I-II composite cracks. The squeeze or tear effects generated by combined action of friction force and tension have obvious influences on the KI. The influences of the relative sliding between crack faces generated by contact pressure on the KII are dominant.
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This project was supported by the National Natural Science Foundation of China (No. 51875095).
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Yan, Y., Zhang, Y., Wu, X., Li, W. (2020). The Analysis for Stress Intensity Factor of Three-Dimensional Crack Under Combined Action of Friction Force and Tension. In: Wang, D., Petuya, V., Chen, Y., Yu, S. (eds) Recent Advances in Mechanisms, Transmissions and Applications. MeTrApp 2019. Mechanisms and Machine Science, vol 79. Springer, Singapore. https://doi.org/10.1007/978-981-15-0142-5_23
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DOI: https://doi.org/10.1007/978-981-15-0142-5_23
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