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表面织构对曲轴轴承润滑性能的影响

刘成 吕延军 李莎 刘万万 杨茹

刘成, 吕延军, 李莎, 刘万万, 杨茹. 表面织构对曲轴轴承润滑性能的影响[J]. 交通运输工程学报, 2017, 17(3): 65-74.
引用本文: 刘成, 吕延军, 李莎, 刘万万, 杨茹. 表面织构对曲轴轴承润滑性能的影响[J]. 交通运输工程学报, 2017, 17(3): 65-74.
LIU Cheng, LU: Yan-jun, LI Sha, LIU Wan-wan, YANG Ru. Effect of surface texture on tribological performance of crankshaft bearing[J]. Journal of Traffic and Transportation Engineering, 2017, 17(3): 65-74.
Citation: LIU Cheng, LU: Yan-jun, LI Sha, LIU Wan-wan, YANG Ru. Effect of surface texture on tribological performance of crankshaft bearing[J]. Journal of Traffic and Transportation Engineering, 2017, 17(3): 65-74.

表面织构对曲轴轴承润滑性能的影响

基金项目: 

学基金项目 2014JM2-5082

陕西省教育厅科学研究计划项目 15JS068

详细信息
    作者简介:

    刘成(1988-), 男, 湖北石首人, 西安理工大学工学博士研究生, 从事先进摩擦学理论研究

    吕延军(1972-), 男, 陕西韩城人, 西安理工大学教授, 工学博士

  • 中图分类号: U664.21

Effect of surface texture on tribological performance of crankshaft bearing

More Information
  • 摘要: 考虑凹槽与凹坑织构之间的协同润滑效应, 在曲轴轴承表面设计了抛物线凹槽-球形凹坑复合织构, 以改善轴承的润滑性能; 为了分析抛物线凹槽-球形凹坑复合织构对曲轴轴承润滑性能的影响, 基于平均Reynolds方程和Greenwood-Tripp微凸体接触方程构建了曲轴轴承的混合润滑模型, 并采用质量守恒的边界条件处理油膜的破裂和再形成行为, 分析了凹槽织构、凹坑织构与凹槽-凹坑复合织构的摩擦学性能, 研究了凹槽-凹坑复合织构的分布位置和结构参数对轴承承载力和摩擦力的影响。分析结果表明: 凹槽-凹坑复合织构具有高于凹槽织构的承载力和低于凹坑织构的摩擦力; 存在最优的凹槽宽度为1.3mm, 凹槽面积率为0.7, 凹槽最大深度为25μm, 凹坑数量为6, 凹坑面积率为0.7, 凹坑最大深度为20μm, 使得轴承量纲为1的承载力最大; 存在最优的凹槽宽度为2.6mm, 凹槽面积率为0.7, 凹槽最大深度为30μm, 凹坑数量为15, 凹坑面积率为0.7, 凹坑最大深度为35μm, 使得轴承量纲为1的摩擦力最小; 当凹槽-凹坑复合织构的分布位置、结构参数取最优值时, 相对于无织构轴承而言, 轴承的承载力提高了4.1%, 摩擦力减小了19.6%。

     

  • 图  1  轴承

    Figure  1.  Bearing

    图  2  抛物线凹槽-球形凹坑复合织构

    Figure  2.  Parabolic groove-spherical dimple compound texture

    图  3  抛物线凹槽

    Figure  3.  Parabolic groove

    图  4  球形凹坑

    Figure  4.  Spherical dimple

    图  5  量纲为1的承载力和偏心率的关系曲线

    Figure  5.  Relationship curves of dimensionless load-carrying capacity and eccentricity ratio

    图  6  量纲为1的摩擦力和偏心率的关系曲线

    Figure  6.  Relationship curves of dimensionless friction force and eccentricity ratio

    图  7  量纲为1的承载力和织构区域起始角度的关系曲线

    Figure  7.  Relationship curves of dimensionless load-carrying capacity and start angle of textured zone

    图  8  量纲为1的承载力和角度比的关系曲线

    Figure  8.  Relationship curve of dimensionless load-carrying capacity and angle ratio

    图  9  量纲为1的承载力和凹槽面积率的关系曲线

    Figure  9.  Relationship curves of dimensionless load-carrying capacity and groove area density

    图  10  量纲为1的承载力和凹槽最大深度的关系曲线

    Figure  10.  Relationship curves of dimensionless load-carrying capacity and groove maximum depth

    图  11  量纲为1的承载力和凹坑面积率的关系曲线

    Figure  11.  Relationship curves of dimensionless load-carrying capacity and dimple area density

    图  12  量纲为1的承载力和凹坑最大深度的关系曲线

    Figure  12.  Relationship curves of dimensionless load-carrying capacity and dimple maximum depth

    图  13  无织构时轴承的压力分布

    Figure  13.  Pressure distribution of untextured bearing

    图  14  量纲为1的承载力最大时复合织构轴承的压力分布

    Figure  14.  Pressure distribution of bearing with compound texture when dimensionless load-carrying capacity is largest

    图  15  量纲为1的摩擦力和织构区域起始角度的关系曲线

    Figure  15.  Relationship curves of dimensionless friction force and start angle of textured zone

    图  16  量纲为1的摩擦力和角度比的关系曲线

    Figure  16.  Relationship curve of dimensionless friction force and angle ratio

    图  17  量纲为1的摩擦力和凹槽面积率的关系曲线

    Figure  17.  Relationship curves of dimensionless friction force and groove area density

    图  18  量纲为1的摩擦力和凹槽最大深度的关系曲线

    Figure  18.  Relationship curves of dimensionless friction force and groove maximum depth

    图  19  量纲为1的摩擦力和凹坑面积率的关系曲线

    Figure  19.  Relationship curves of dimensionless friction force and dimple area density

    图  20  量纲为1的摩擦力和凹坑最大深度的关系曲线

    Figure  20.  Relationship curves of dimensionless friction force and dimple maximum depth

    图  21  量纲为1的摩擦力最小时有无织构的轴承压力分布

    Figure  21.  Pressure distributions of textured and untextured bearings when dimensionless friction force is smallest

    表  1  有量纲承载力和摩擦力

    Table  1.   Dimensional load-carrying capacities and friction forces

    下载: 导出CSV
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  • 收稿日期:  2016-12-25
  • 刊出日期:  2017-06-25

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