瑞利步进轴承的再循环流量和压力分布

IF 1.5 Q3 ENGINEERING, MECHANICAL
F. Shen, Chengjin Yan, Jian Dai, Zhaomiao Liu
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引用次数: 1

摘要

采用解析和数值方法研究了无限宽瑞利步进滑块轴承的流动特性。采用有限体积法求解了质量守恒方程和动量守恒方程,并对整个流场进行了模拟。获得了被雷诺润滑方程所忽略的流态和压力分布的更详细信息,如瑞利台阶周围的跳跃现象、涡结构和剪应力分布。对优化几何形状的瑞利步进轴承的压力分布进行了数值模拟,得到的结果与经典雷诺润滑方程的解析解一致。仿真结果表明,流场的最大压力在阶跃尖端处,而不是在下表面,根据Navier-Stokes方程计算的应变率增量比根据Reynolds理论计算的应变率增量约大49%。下表面最大压力的位置略小于第一个区域的长度。这些被雷诺润滑方程所忽略的结果对于轴承的设计是重要的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Recirculation Flow and Pressure Distributions in a Rayleigh Step Bearing
Flow characteristics in the Rayleigh step slider bearing with infinite width have been studied using both analytical and numerical methods. The conservation equations of mass and momentum were solved utilizing a finite volume approach and the whole flow field was simulated. More detailed information about the flow patterns and pressure distributions neglected by the Reynolds lubrication equation has been obtained, such as jumping phenomenon around a Rayleigh step, vortex structure, and shear stress distribution. The pressure distribution of the Rayleigh step bearing with optimum geometry has been numerically simulated and the results obtained agreed with the analytical solution of the classical Reynolds lubrication equation. The simulation results show that the maximum pressure of the flow field is at the step tip not on the lower surface and the increment of the strain rate from Navier-Stokes equation is approximately 49 percent greater than that from Reynolds theory at the step tip. It is also shown that the position of the maximum pressure of the lower surface is a little less than the length of the first region. These results neglected by the Reynolds lubrication equation are important for designing a bearing.
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来源期刊
Advances in Tribology
Advances in Tribology ENGINEERING, MECHANICAL-
CiteScore
5.00
自引率
0.00%
发文量
1
审稿时长
13 weeks
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