Performance of Normal Geometrical Hydrodynamic Inclined Fixed Pad Thrust Slider Bearing with the Interfacial Slippage Occurring on the Stationary Surface in the Inlet Zone and on the Whole Moving Surface

Yansun Zhou; Yongbin Zhang; Xuedong Jiang; Mingjun Pang

doi:10.31875/2409-9848.2020.07.4

Articles

Vol. 7 (2020)

Performance of Normal Geometrical Hydrodynamic Inclined Fixed Pad Thrust Slider Bearing with the Interfacial Slippage Occurring on the Stationary Surface in the Inlet Zone and on the Whole Moving Surface

Yansun Zhou⁺⁻
Yongbin Zhang⁺⁻
Xuedong Jiang⁺⁻
Mingjun Pang⁺⁻

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DOI: https://doi.org/10.31875/2409-9848.2020.07.4
Submitted: June 25, 2020
Published: 2020-06-25

Abstract

An anaysis is presented for investigating the performance of the hydrodynamic inclined fixed pad thrust slider bearing with a normal geometry where the interfacial slippage occurs on the stationary surface in the inlet zone and on the whole moving surface, based on the limiting interfacial shear strength model. The calculation results show that compared with the classical mode of the bearing (without any interfacial slippage), this bearing has a significantly higher load-carrying capacity but a much lower friction coefficient in the same operating condition. The study shows the considerable improvement of the bearing performance by the introduced interfacial slippage.

References

Liang MP, Wang JC. The inner ring of an energy conserved rolling bearing. CN201620618280.7, 2016.
Hu DY. An energy conserved bearing. CN201420842351.2, 2014.
Zhang KB, Fan XX. The chamber for an energy conserved bearing free of maintenance for special use in the hair-cut machine. CN200520029666.6, 2005.
Li SM. The arrangements for the supporter of an energy conserved bearing for used in a ball grinding machine. CN201320592044.9, 2013.
Xie ZL, Rao ZS, Na T, Liu L, Chen R. Theoretical and experimental research on the friction coefficientof water lubricated bearing with consideration of wall slip effects. Mech Ind 2016; 17: 106. https://doi.org/10.1051/meca/2015039
Wu H, Zhao J, Xia W, Cheng X, He A, Yun J, Wang L, Huang H, Jiao S, Huang L, Zhang S, Jiang Z. Analysis ofTiO2 nanoadditive water-based lubricants in hot rolling of microalloyed steel. J Manufactur Proc 2017; 27: 26-36. https://doi.org/10.1016/j.jmapro.2017.03.011
Fortier AE, Salant RF. Numerical analysis of a journal bearing with a heterogeneous slip/no-slip surface. ASME J Trib 2005; 127; 820-825. https://doi.org/10.1115/1.2033897
Salant RF, Fortier AE. Numerical analysis of a slider bearing with a heterogeneous slip/no-slip surface. Trib Trans 2004; 47: 328-334. https://doi.org/10.1080/05698190490455348
Zhang YB. A tilted pad thrust slider bearing improved by the boundary slippage. Meccanica 2013; 48: 769-781. https://doi.org/10.1007/s11012-012-9630-6
Zhang YB. An improved hydrodynamic journal bearing with the boundary slippage. Meccanica 2015; 50: 25-38. https://doi.org/10.1007/s11012-014-0064-1
Zhang YB. Recent patents on energy conservation in gears and bearings by the boundary slippage technology. Recent Patent Mech Eng 2015; 8: 33-37. https://doi.org/10.2174/2212797608666150123002309
Zhang YB. An energy conserved hydrodynamic journal bearing by the boundary slippage technology. Recent Paten Mech Eng 2016; 9: 63-70. https://doi.org/10.2174/2212797609666160118234638
Zhang YB. Boundary slippage for generating hydrodynamic load-carrying capacity. Appl Math Mech 2008; 29: 1155- 1164. https://doi.org/10.1007/s10483-008-0905-y
Zhang YB. A concentric hydrodynamic journal bearing constructed by the boundary slippage. J Theor Appl Mech Warsaw 2016; 54: 345-352. https://doi.org/10.15632/jtam-pl.54.2.345
Wang JY, Zhang YB, Pan LZ, Dong YW, Tang ZP. Abnormal hydrodynamic step bearing formed by boundary slippage. J Balkan Trib Assoc 2018; 24: 75-85.
Cheng HS, Zhang YB, Tang ZP, Dong YW, Pan LZ. Abnormal hydrodynamic inclined fixed pad thrust slider bearing formed by boundary slippage. J Balkan Trib Assoc 2018; 24: 64-74.
Xia Y, Zhang YB, Sun ZY, Jiang XD, Dong YW, Wang Y. Normal geometrical hydrodynamic wedge-platform thrust slider bearing with the interfacial slippage occurring on the whole stationary surface. J Balkan Trib Assoc 2020; 26: 147- 162.
Zhou Y, Zhang YB, Dong YW, Jiang XD, Wang Y. Performance of normal geometrical hydrodynamic step bearing with the interfacial slippage occurring on the whole stationary surface. J Balkan Trib Assoc 2019; Ms. No. 2339/14.06.2019, revised.
Xia YT, Zhang YB, Wang Y, Jiang XD, Dong YW. Hydrodynamic wedge-platform thrust slider bearing with the interfaical slippage on the whole moving surface. J Balkan Trib Assoc 2019; 25: 372-382.
Xia YT, Zhang YB. Performance of the hydrodynamic wedgeplatform thrust slider bearing with the interfacial slippage occurring on the stationary surface in the inlet zone and on the whole moving surface. J Balkan Trib. Assoc 2020; Ms. No. 2374/04.02.2020, revised.
Zhang YB. Review of hydrodynamic lubrication with interfacial slippage. J Balkan Trib Assoc 2014; 20: 522-538.
Rozeanu L, Tipei N. Slippage phenomena at the interface between the adsorbed layer and the bulk of the lubricant: Theory and experiment. Wear 1980; 64: 245-257. https://doi.org/10.1016/0043-1648(80)90131-3
Jacobson BO, Hamrock BJ. Non-Newtonian fluid model incorporated into elastohydrodynamic lubrication of rectangular contacts. ASME J Trib 1984; 106: 275-284. https://doi.org/10.1115/1.3260901
Zhang YB. Contact-fluid interfacial shear strength and its critical importance in elastohydrodynamic lubrication. Industr Lubri Trib 2006; 58: 4-14. https://doi.org/10.1108/00368790610640064
Zhang YB. A molecular calculation of the solid-liquid interfacial shear strength for low liquid pressures by using the Lennard-Jones potential model. J Balkan Trib Assoc 2014; 20: 618-629.
Zhang YB. A molecular calculation of the solid-liquid interfacial shear strength for low liquid pressures by using the Coulomb interaction model. J Balkan Trib Assoc 2015; 21: 594-605.
Zhang YB. Varying parametric study of the solid-liquid interfacial shear strength for low liquid pressures by using the Lennard-Jones potential model. J Balkan Trib Assoc 2014; 20: 630-638.
Pinkus O, Sternlicht B. Theory of hydrodynamic lubrication, McGraw-Hill, New York 1961.

Keywords

Bearing, Friction coefficient, Hydrodynamic lubrication, Interfacial slippage, Load.

How to Cite

Yansun Zhou, Yongbin Zhang, Xuedong Jiang, & Mingjun Pang. (2020). Performance of Normal Geometrical Hydrodynamic Inclined Fixed Pad Thrust Slider Bearing with the Interfacial Slippage Occurring on the Stationary Surface in the Inlet Zone and on the Whole Moving Surface. Journal of Modern Mechanical Engineering and Technology, 7, 27–34. https://doi.org/10.31875/2409-9848.2020.07.4

[1] Liang MP, Wang JC. The inner ring of an energy conserved rolling bearing. CN201620618280.7, 2016.

[2] Hu DY. An energy conserved bearing. CN201420842351.2, 2014.

[3] Zhang KB, Fan XX. The chamber for an energy conserved bearing free of maintenance for special use in the hair-cut machine. CN200520029666.6, 2005.

[4] Li SM. The arrangements for the supporter of an energy conserved bearing for used in a ball grinding machine. CN201320592044.9, 2013.

[5] Xie ZL, Rao ZS, Na T, Liu L, Chen R. Theoretical and experimental research on the friction coefficientof water lubricated bearing with consideration of wall slip effects. Mech Ind 2016; 17: 106. https://doi.org/10.1051/meca/2015039

[6] Wu H, Zhao J, Xia W, Cheng X, He A, Yun J, Wang L, Huang H, Jiao S, Huang L, Zhang S, Jiang Z. Analysis ofTiO2 nanoadditive water-based lubricants in hot rolling of microalloyed steel. J Manufactur Proc 2017; 27: 26-36. https://doi.org/10.1016/j.jmapro.2017.03.011

[7] Fortier AE, Salant RF. Numerical analysis of a journal bearing with a heterogeneous slip/no-slip surface. ASME J Trib 2005; 127; 820-825. https://doi.org/10.1115/1.2033897

[8] Salant RF, Fortier AE. Numerical analysis of a slider bearing with a heterogeneous slip/no-slip surface. Trib Trans 2004; 47: 328-334. https://doi.org/10.1080/05698190490455348

[9] Zhang YB. A tilted pad thrust slider bearing improved by the boundary slippage. Meccanica 2013; 48: 769-781. https://doi.org/10.1007/s11012-012-9630-6

[10] Zhang YB. An improved hydrodynamic journal bearing with the boundary slippage. Meccanica 2015; 50: 25-38. https://doi.org/10.1007/s11012-014-0064-1

[11] Zhang YB. Recent patents on energy conservation in gears and bearings by the boundary slippage technology. Recent Patent Mech Eng 2015; 8: 33-37. https://doi.org/10.2174/2212797608666150123002309

[12] Zhang YB. An energy conserved hydrodynamic journal bearing by the boundary slippage technology. Recent Paten Mech Eng 2016; 9: 63-70. https://doi.org/10.2174/2212797609666160118234638

[13] Zhang YB. Boundary slippage for generating hydrodynamic load-carrying capacity. Appl Math Mech 2008; 29: 1155- 1164. https://doi.org/10.1007/s10483-008-0905-y

[14] Zhang YB. A concentric hydrodynamic journal bearing constructed by the boundary slippage. J Theor Appl Mech Warsaw 2016; 54: 345-352. https://doi.org/10.15632/jtam-pl.54.2.345

[15] Wang JY, Zhang YB, Pan LZ, Dong YW, Tang ZP. Abnormal hydrodynamic step bearing formed by boundary slippage. J Balkan Trib Assoc 2018; 24: 75-85.

[16] Cheng HS, Zhang YB, Tang ZP, Dong YW, Pan LZ. Abnormal hydrodynamic inclined fixed pad thrust slider bearing formed by boundary slippage. J Balkan Trib Assoc 2018; 24: 64-74.

[17] Xia Y, Zhang YB, Sun ZY, Jiang XD, Dong YW, Wang Y. Normal geometrical hydrodynamic wedge-platform thrust slider bearing with the interfacial slippage occurring on the whole stationary surface. J Balkan Trib Assoc 2020; 26: 147- 162.

[18] Zhou Y, Zhang YB, Dong YW, Jiang XD, Wang Y. Performance of normal geometrical hydrodynamic step bearing with the interfacial slippage occurring on the whole stationary surface. J Balkan Trib Assoc 2019; Ms. No. 2339/14.06.2019, revised.

[19] Xia YT, Zhang YB, Wang Y, Jiang XD, Dong YW. Hydrodynamic wedge-platform thrust slider bearing with the interfaical slippage on the whole moving surface. J Balkan Trib Assoc 2019; 25: 372-382.

[20] Xia YT, Zhang YB. Performance of the hydrodynamic wedgeplatform thrust slider bearing with the interfacial slippage occurring on the stationary surface in the inlet zone and on the whole moving surface. J Balkan Trib. Assoc 2020; Ms. No. 2374/04.02.2020, revised.

[21] Zhang YB. Review of hydrodynamic lubrication with interfacial slippage. J Balkan Trib Assoc 2014; 20: 522-538.

[22] Rozeanu L, Tipei N. Slippage phenomena at the interface between the adsorbed layer and the bulk of the lubricant: Theory and experiment. Wear 1980; 64: 245-257. https://doi.org/10.1016/0043-1648(80)90131-3

[23] Jacobson BO, Hamrock BJ. Non-Newtonian fluid model incorporated into elastohydrodynamic lubrication of rectangular contacts. ASME J Trib 1984; 106: 275-284. https://doi.org/10.1115/1.3260901

[24] Zhang YB. Contact-fluid interfacial shear strength and its critical importance in elastohydrodynamic lubrication. Industr Lubri Trib 2006; 58: 4-14. https://doi.org/10.1108/00368790610640064

[25] Zhang YB. A molecular calculation of the solid-liquid interfacial shear strength for low liquid pressures by using the Lennard-Jones potential model. J Balkan Trib Assoc 2014; 20: 618-629.

[26] Zhang YB. A molecular calculation of the solid-liquid interfacial shear strength for low liquid pressures by using the Coulomb interaction model. J Balkan Trib Assoc 2015; 21: 594-605.

[27] Zhang YB. Varying parametric study of the solid-liquid interfacial shear strength for low liquid pressures by using the Lennard-Jones potential model. J Balkan Trib Assoc 2014; 20: 630-638.

[28] Pinkus O, Sternlicht B. Theory of hydrodynamic lubrication, McGraw-Hill, New York 1961.