The impact of elastohydrodynamic lubrication on the time-varying meshing stiffness of planetary gear-annulus pair

Abstract

This study proposes a novel method for calculating the time-varying mesh stiffness (TVMS) of a planetary gear-annulus pair considering elastohydrodynamic lubrication (EHL) to investigate the impact of EHL characteristics between gear surfaces on the mesh stiffness in planetary transmission systems. First, based on the contact performance of gear pairs under EHL, a mesh model and an EHL model for planetary gear-annulus pairs were established. The relationships between the relative sliding velocity, relative curvature radius, and roll-absorbing speed during gear meshing were established. Additionally, a generalised Reynolds equation and load equation were formulated based on the relationship between pressure, lubricant viscosity, and density, allowing for an analysis of the effects of the roll-absorbing speed and load torque on the oil film pressure and thickness between the gear surfaces. Second, the local slope method was employed to solve for the oil film stiffness between the gear surfaces, and a contact stiffness model of the planetary gear-annulus pair, incorporating the oil film stiffness, was established using the slicing method. The TVMS of the planetary gear-annulus pair was then solved using the potential energy method based on the obtained oil film pressure and thickness values, as follows: Compared with traditional potential energy methods, this approach improved the accuracy of the TVMS calculations for a planetary gear-annulus pair. Finally, the effects of different entrainment velocities and load torque on the TVMS were assessed. The results showed that as the roll-absorbing speed increased, the TVMS decreased, whereas an increase in the load torque led to an increase in TVMS.

Keywords

Planetary gear systems elastohydrodynamic lubrication characteristics contact stiffness time-Variant meshing stiffness oil film pressure and thickness

Get full access to this article

View all access options for this article.

References

, et al.

Mesh stiffness and nonlinear dynamic response of a spur gear pair considering tribo-dynamic effect.

Mech Mach Theory 2020; 153: 103989.

Dowson

Higginson

. A numerical solution to the elastohydrodynamic problem. J Mech Eng Sci 1959; 1: 6–15.

Adkins

Radzimovsky

. Lubrication phenomena in spur gears: capacity, film thickness variation, and efficiency. J. Basic Eng. 1965; 87: 655–663.

Vichard

. Transient effects in the lubrication of Hertzian contacts. J Mech Eng Sci 1971; 13: 173–189.

Y-Z

Zhu

. A full numerical solution to the mixed lubrication in point contacts. J. Trib 2000; 122: 1–9.

Liu

Yang

. Analysis of the thermal elastohydrodynamic lubrication of a finite line contact. Tribol Int 2002; 35: 137–144.

Zhu

Liu

, et al.

A thermal finite line contact EHL model of a helical gear pair.

Proc Inst Mech Eng Part J J Eng Tribol 2013; 227: 299–309.

Wan

G-x

Gong

J-z

, et al.

An improved algorithm for the normal contact stiffness and damping of a mechanical joint surface.

Proc Inst Mech Eng Part B J Eng Manuf 2014; 228: 751–765.

Tang

, et al.

Novel mathematical modelling methods of comprehensive mesh stiffness for spur and helical gears.

Appl Math Model 2018; 64: 524–540.

10.

Feng

, et al.

An improved analytical method for calculating time-varying mesh stiffness of helical gears.

Meccanica 2018; 53: 1131–1145.

11.

Zhang

Liu

Zhu

, et al.

Oil film stiffness and damping in an elastohydrodynamic lubrication line contact-vibration.

J Mech Sci Technol 2016; 30: 3031–3039.

12.

Huang

W-k

Zhao

Z-f

, et al.

An iterative model for mesh stiffness of spur gears considering slice coupling under elastohydrodynamic lubrication.

J Cent South Univ 2023; 30: 3414–3434.

13.

Pei

Han

Tao

. An improved stiffness model for line contact elastohydrodynamic lubrication and its application in gear pairs. Ind Lubr Tribol 2020; 72: 703–708.

14.

Zhou

Xiao

Chen

, et al.

Normal and tangential oil film stiffness of modified spur gear with non-Newtonian elastohydrodynamic lubrication.

Tribol Int 2017; 109: 319–327.

15.

Zhou

Xiao

. Stiffness and damping models for the oil film in line contact elastohydrodynamic lubrication and applications in the gear drive. Appl Math Model 2018; 61: 634–649.

16.

Xiao

Gao

. Mesh stiffness model of a spur gear pair with surface roughness in mixed elastohydrodynamic lubrication. J Braz Soc Mech Sci Eng 2022; 44: 136.

17.

Zhao

Yang

Han

, et al.

Meshing characteristics of spur gears considering three-dimensional fractal rough surface under elastohydrodynamic lubrication.

Machines 2022; 10: 705.

18.

Wan

Cao

, et al.

Mesh stiffness calculation using an accumulated integral potential energy method and dynamic analysis of helical gears.

Mech Mach Theory 2015; 92: 447–463.

19.

Wang

Luo

Zou

. Time-varying meshing stiffness calculation of an internal gear pair with small tooth number difference by considering the multi-tooth contact problem. J Mech Sci Technol 2021; 35: 4073–4083.

20.

Sainsot And

Velex

Duverger

. Contribution of gear body to tooth deflections—a new bidimensional analytical formula. J. Mech. Des 2004; 126: 748–752.

21.

Xie

Hua

Lan

, et al.

Improved analytical models for mesh stiffness and load sharing ratio of spur gears considering structure coupling effect.

Mech Syst Signal Process 2018; 111: 331–347.