Abstract
The mechanism of adhesive friction between viscoelastic materials is a key question. In this study, the friction process of the adhesive interface between a friction lining and a wire rope is dynamically observed in real time to analyze the adhesion hysteresis friction intuitively and quantitatively. The adhesion is determined by the state of motion, while the relative displacement of the wire rope and lining is used to find the magnitude of the adhesive friction. The hysteresis friction is reflected by the internal deformation of the lining. The magnitude of the hysteresis friction is determined by the displacement difference (Δx) in the sliding direction of two marked points at different distances from the contact surface. The results show that the adhesion friction is proportional to the loss modulus and the hysteresis friction is proportional to the ratio of the loss modulus to the square of the storage modulus (E″/(E′2)). The frictional vibration first decreases and then increases with the increase in pressure. The K25 lining has the highest adhesion hysteresis friction and minimal frictional vibration. The result provides a simple and intuitive method for research into the friction transmission and vibration of viscoelastic materials.
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This study is supported by the joint Ph.D. program of “double first rate” construction disciplines of China University of Mining and Technology (CUMT).
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Cun-ao FENG. He is a Ph.D. candidate at China University of Mining and Technology. He was a joint Ph.D. student at the University of British Columbia from 2018 to 2019. He has published 9 journal papers. His current research interests cover tribology of soft materials, friction reliability of mining machinery, viscoelastic materials, and wear-resistant materials.
De-kun ZHANG. He received his Ph.D. degree from China University of Mining and Technology in 2003. He is a professor at China University of Mining and Technology since 2008. His current research interests cover fretting, friction reliability of mining machinery, bio-tribology of artificial joints, bionic design of functional materials, and wear-resistant materials, etc. He has published 2 monographs, more than 180 papers, of which over 100 publications are included in SCI, and he has also obtained more than 30 patents for invention. His main academic part-time jobs include the deputy chairman of the Tribological Branch of the Chinese Mechanical Engineering Society, the chairman of the Tribological Branch of the Jiangsu Mechanical Engineering Society, and so on.
Kai CHEN. He received his Ph.D. degree from China University of Mining and Technology in 2015. He is currently an associate professor at China University of Mining and Technology. He has published over 50 journal papers. His current research interests cover the bionic design of functional materials, tribology of soft materials, and bio-tribology of artificial joints.
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Feng, Ca., Zhang, Dk. & Chen, K. Microscopic dynamic observation of adhesion hysteresis friction and exploration of the influence of different pressures on friction transmission. Friction 9, 758–773 (2021). https://doi.org/10.1007/s40544-020-0372-5
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DOI: https://doi.org/10.1007/s40544-020-0372-5