用有限元法分析使用非稳定流体膜润滑剂的滑动轴承的热效应和表面粗糙度效应性能

IF 1.2 Q2 MATHEMATICS, APPLIED
G. Tessema, G. A. Derese, A. A. Tiruneh
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引用次数: 0

摘要

本研究采用流线型上风 Petrov-Galerkin (SUPG) 有限元方法研究了带有非稳定流体膜的倾斜滑块轴承的热效应和表面粗糙度效应。考虑了一维横向和纵向表面粗糙度模型,假设粗糙度是随机的,具有高斯随机分布。为简化数值计算,将表面纹理引起的不规则性转化为规则域。在所有修正雷诺数的非平行滑块轴承中,综合效应的轴承性能低于一维纵向表面粗糙度的热效应和表面粗糙度效应;这意味着在表面粗糙度效应和综合效应条件之间的非平行(w=0.4)条件下,承载能力性能分别降低了 13%,摩擦力变化极小。然而,对于非平行一维横向滑动轴承,在所有修正的雷诺数条件下,热效应的轴承性能均低于综合效应和表面粗糙度效应,其中在综合效应和热效应条件下,在所有变化的雷诺值条件下,承载能力性能实际上分别降低了 19%,摩擦力降低了 2%。此外,还研究了不同温度下的综合效应。结果表明,在纵向和横向模型中,当垫片温度低于滑块温度时,非平行滑块轴承的承载能力性能高于其他情况,而当滑块温度低于垫片温度时,阻力摩擦力在两种模型中均占主导地位。一般来说,考虑表面纹理和惯性效应会提高滑块的性能。所获得的结果用图表显示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Performance Analysis of Thermal and Surface Roughness Effect of Slider Bearings with Unsteady Fluid Film Lubricant Using Finite Element Method
The streamline upwind Petrov-Galerkin (SUPG) finite element method was used in this study to investigate the thermal and surface roughness effects on an inclined slider bearing with an unsteady fluid film. One-dimensional transverse and longitudinal surface roughness models were considered with the supposition that roughness is stochastic and has a Gaussian random distribution. For simplicity of numerical computation, the irregularity caused by the texture of the surface is transformed into a regular domain. The bearing performance of the combined effect is lower than the thermal and surface roughness effects of the one-dimensional longitudinal surface roughness for all modified Reynolds numbers of nonparallel slider bearings; this means that for nonparallel (w=0.4) between the surface roughness effect and the combined effect condition, there is a decrease of 13% in load-carrying capacity performance and a minimal change in friction force, respectively. However, in the case of nonparallel one-dimensional transverse type slider bearings, the bearing performance of the thermal effect is lower than the combined and surface roughness effects for all modified Reynolds numbers, where between the combined effect and the thermal effect condition, there is a reduction of 19% in load-carrying capacity performance and 2% in friction force practically for all changed Reynolds values, respectively. Furthermore, the combined effects at various temperatures have been investigated. As a result, in both longitudinal and transverse models, in the case of the pad temperature being lower than the slider, the load-carrying capacity performance is higher than in other cases for nonparallel slider bearings, whereas when the slider temperature is lower than the pad temperature, the drag frictional force is the leading one in both models. In general, considering surface texture and inertial effects will increase the performance of a slider. The results obtained are displayed using figures and tables.
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来源期刊
Journal of Applied Mathematics
Journal of Applied Mathematics MATHEMATICS, APPLIED-
CiteScore
2.70
自引率
0.00%
发文量
58
审稿时长
3.2 months
期刊介绍: Journal of Applied Mathematics is a refereed journal devoted to the publication of original research papers and review articles in all areas of applied, computational, and industrial mathematics.
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