Abstract
The paper presents a technique and an accurate implementation of a self-similar solution of the problem of calculating the hydrodynamic endless radial friction bearing coated by low-melting-point metal of bearing bush operating at a viscoelastic lubricant with the account of the dependence of viscosity of the lubricant and the shear modulus on temperature. Based on the equation of motion of the liquid lubricating material having viscoelastic properties (Maxwell liquid) for the case of a “thin layer”, with the dependence of the viscosity of the lubricant and the shear modulus on the temperature, the continuity equation and the energy dissipation rate for determining the function of formula \( \Phi \left( {\theta } \right) \), conditioned by the melt surface of the bearing bush coated by low-melting-point metal, the asymptotic solution for the zero and first approximation in powers of the small parameter K conditioned by the melt are found. As a result of problem solving, the velocity field and pressure in the lubricating layer and the molten layer are determined, as well as the value of the function \( \Phi _{ 1} \left( {\theta } \right) \) conditioned by the melt surface of the bearing bush coated by low-melting-point metal. The numerical analysis of the obtained analytical expressions for the load-bearing capacity and friction force with simultaneous consideration of important factors such as the viscosity of liquid viscoelastic lubricant, shear modulus, Deborah number, the parameter characterizing the dependence of viscosity on the lubricant, and shear modulus on temperature, allowed one to refine the tribotechnical design models in the following order: load-bearing capacity by 22%, frictional force by 27%.
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References
Kropachev DY, Grishin AA, Maslo AD (2012) Methods for the rapid measurement of the temperature of metal melt for the needs of machine-building enterprises. Cast Metall 3(66):126–127
Perelman VI (1964) Quick reference book of the chemist. Chemistry, Moscow-Leningrad
Zadorozhnaya EA, Mukhortov IV, Levanov IG (2011) Application of non-Newtonian models of lubricating fluids in the calculation of complex loaded friction units for piston and rotor machines. Frict Lubr Mach Mech 7:22–30
Prokopiev VN, Boyarshinova AK, Zadorozhnaya EA (2005) Dynamics of a complex loaded bearing lubricated by a non-Newtonian liquid. Probl Mach Build Mach Reliab 6:108–114
Prokopiev VN, Zadorozhnaya EA, Karavaev VG, Leanov IG (2010) Perfection of the calculation method for complex loaded friction bearings lubricated with non-Newtonian oils. Probl Mach Build Mach Reliab 1:63–67
Wilson (1976) Grease with melt. Probl Frict Lubr 1:19
Beretta GP, Niro A, Silvestri M (1992) Friction bearings lubricated by their own melt or by product of sublimation. Works of the American Society of Engineers, vol 1, pp 86–90
Kotelnitskaya LI, Demdova NN (2002) Calculation of radial bearings with efficient work on lubrication with melt in turbulent mode. Bull Rostov State Transp Univ 2:18–23
Prikhodko VM, Kotelnitskaya LI (2001) Mathematical model of hydrodynamic lubrication during melting of bearing surface of radial bearing. Frict Tear 22(6):606–608
Akhverdiev КS, Mukutadze MA, Lagunova EO, Vasilenko VV (2017) Hydrodynamic calculation of a radial bearing lubricated by a melt of a fusible coating in the presence of a lubricant. Bull RSTU 2(66):129–135
Akhverdiev KS, Lagunova EO, Vasilenko VV (2017) Calculation model of a radial bearing lubricated by the melt, taking into account the dependence of viscosity on pressure. Bull DSTU 3(90):27–37
Vasilenko VV, Lagunova EO, Mukutadze MA (2017) Hydrodynamic calculation of a radial bearing lubricated by a melt of a fusible coating in the presence of a lubricant. Internet Magazine “Naukovedenie” 9(5). https://naukovedenie.ru/PDF/20TVN517.pdf
Lagunova EO (2017) Wedge-shaped sliding supports operating on viscoelastic lubricant material due to the melt, taking into account the dependence of viscosity and shear modulus on pressure. Int J Appl Eng Res 12(19):9120–9127
Lagunova EO (2017) Radial plain bearings operating on viscoelastic lubricant conditioned by the melt, taking into account the dependence of the viscosity of the lubricant and the shear modulus on the pressure. Int J Appl Eng Res 12(19):9128–9137
Vasilenko VV, Lagunova EO, Mukutadze MA, Prikhodko VM (2017) Calculation model of the radial bearing, caused by the melt, taking into account the dependence of viscosity on pressure. Int J Appl Eng Res 12(19):9138–9148
Akhverdiev КS, Mukutadze MA, Lagunova EO, Vasilenko VV (2017) Wedge-shaped sliding supports, operating on a micropolar lubricant, conditioned by the melt. Bull RSTU 3(67):8–15
Lagunova EO (2017) Simulation of wedge-shaped slip bearings taking into account the rheological properties of an electrically conductive lubricant. Bull SUSU. Series “Machine Building” 17(4):13–25. https://doi.org/10.14529/engin170402
Ng Pen Linearized (1965) Theory of turbulent lubricant flow. Theor Bases Eng Calc 3:157–162
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The publication has been issued in the scope of realization of fellowship of OJSC “RZD” No. 2210370/22.12.20016 for the development of scientific and pedagogical schools in the area of the railway transport.
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Lagunova, E.O., Mukutadze, M.A. (2019). Radial Friction Bearings Conditioned by Melt. In: Radionov, A., Kravchenko, O., Guzeev, V., Rozhdestvenskiy, Y. (eds) Proceedings of the 4th International Conference on Industrial Engineering. ICIE 2018. Lecture Notes in Mechanical Engineering. Springer, Cham. https://doi.org/10.1007/978-3-319-95630-5_94
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DOI: https://doi.org/10.1007/978-3-319-95630-5_94
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