Exchange interaction and models of contact generation of disturbances in tribosystems

Authors

DOI:

https://doi.org/10.15587/1729-4061.2020.209927

Keywords:

contact tribodynamics, corpuscular-vortex-wave thermal complex, exchange interaction, collapse, acoustic emission

Abstract

The physical mechanisms have been investigated that form and transform the corpuscular-vortex-wave thermal complexes of disturbances in contact tribosystems based on the quantum-mechanical exchange interaction. The presence of a contact gap determines the generation of pairs of quasi-particles-disturbances stabilized by wavelength and frequency. Internal instability and collapse processes in such a system of disturbances lead to the formation of defects in a tribopair's material and underlie the emergency friction regimes. This paper gives specific technical examples of the generation of thermal complexes at fretting, during the friction of sliding and rolling, and at cutting. It has been established that the destructive nature of the process of fretting at low values of reverse sliding speeds is caused by the generation and collapse of the corpuscular-vortex-wave thermal complexes. An example of acoustic friction emission in the ultrasonic region of the spectrum has been used to show the quantum nature of the disturbances generated by friction. The high-frequency spectrum of acoustic emission corresponds to the unbalanced composition of the disturbances and leads to the formation of wear particles. The exchange interaction in a tribosystem involving rolling on the plane has been considered. The results of statistical analysis of such rolling showed the existence of the effect of negative friction caused by the quantum generation of longwave disturbances. It has been demonstrated that the collapsed component of the generation of disturbances is significantly increased under the modes of materials destruction, including when cutting the materials. The corpuscular-vortex-wave mechanism of selective transfer and hydrogen wear in tribosystems has been described. It is shown that the properties of a servovite film under the mode of selective transfer are provided by the collapse processes in the system of disturbances. Similar processes at the vortex-wave transfer of hydrogen atoms in metals lead to the wear and destruction of the surface layer of friction

Author Biographies

Yuriy Zaspa, Khmelnytskyi National University Instytuts’ka str., 11, Khmelnytskyi, Ukraine, 29016

PhD, Associate Professor

Department of Physics an Engineering

Aleksandr Dykha, Khmelnytskyi National University Instytuts’ka str., 11, Khmelnytskyi, Ukraine, 29016

Doctor of Technical Sciences, Professor, Head of Department

Department of Machines’ Durability and Reliability

Dmytro Marchenko, Mykolaiv National Agrarian University Georgiy Gongadze str., 9, Mykolayiv, Ukraine, 54020

PhD, Associate Professor

Department of Tractors and Agricultural Machinery, Operation and Technical Service

Serhii Matiukh, Khmelnytskyi National University Instytuts’ka str., 11, Khmelnytskyi, Ukraine, 29016

PhD, Associate Professor, Vice-rector of Scientific and Pedagogical Work

Yuri Kukurudzyak, Vinnytsia National Technical University Khmelnytske shoes str., 95, Vinnytsya, Ukraine, 21021

PhD, Associate Professor

Department of Automobiles and Transport Management

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Published

2020-08-31

How to Cite

Zaspa, Y., Dykha, A., Marchenko, D., Matiukh, S., & Kukurudzyak, Y. (2020). Exchange interaction and models of contact generation of disturbances in tribosystems. Eastern-European Journal of Enterprise Technologies, 4(5 (106), 25–34. https://doi.org/10.15587/1729-4061.2020.209927

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Section

Applied physics