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工程设计学报  2014, Vol. 21 Issue (1): 51-55    DOI: 10.3785/j.issn. 1006-754X.2014.01.009
建模、仿真、分析和优化     
A11VO190轴向柱塞泵滑靴副摩擦特性的研究
申儒林,潘友峰
中南大学 机电工程学院,湖南 长沙 410083
Friction characteristic analysis of slipper pair in A11VO190 axial piston pumps
SHEN Ru-lin,PAN You-feng
College of Mechanical and Electrical Engineering, Central South University, Changsha 410083, China
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摘要: 为了分析A11VO190恒功率轴向柱塞泵滑靴副的摩擦特性,建立了剩余压紧力滑靴的数学模型.在考虑由热膨胀引起的热楔力和由阶梯结构引起的动压效应的基础上,根据空间力系平衡原理,利用软件Matlab计算滑靴在排油区的动态特性,得到滑靴在斜盘不同位置的油膜厚度.在此基础上推导出滑靴副摩擦功率损失和泄漏功率损失的计算公式,并对比不同负载压力和主轴转速对油膜厚度和功率损失的影响.结果表明:负载压力增大,油膜厚度减小,功率损失增加;转速增大,油膜厚度增大,功率损失也随之增加.
关键词: 热楔力动压效应滑靴油膜厚度功率损失    
Abstract: To analyze the friction characteristics of slipper pair in A11VO190 constant power axial piston pump,a mathematical model of overclamped slipper was created. In considering the thermal wedge force caused by thermal expansion and the dynamic pressure effect caused by step structure,according to the equilibrium of spatial force system principle,the slipper’s dynamic characteristics in oil delivery region was calculated by the software Matlab,and the thickness of oil film at different position of the swash plate was obtained. The formula of friction power loss and leakage power loss was then deduced,and the effects of load pressure and spindle turning speed on film thickness and the power loss were compared.It is shown that the thickness decreases with the increasing of load pressure,while the power loss is on the contrary. Both film thickness and power loss increase with the increasing of turning speed.
Key words: thermal wedge force    dynamic pressure effect    slipper    thickness of oil film    power loss
出版日期: 2014-02-28
基金资助:

国防预研究基金资助项目(2206).

作者简介: 申儒林(1968-),男,湖南长沙人,副教授,博士,从事机械界面科学与摩擦学研究,E-mail:srl1234@126.com.
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引用本文:

申儒林,潘友峰. A11VO190轴向柱塞泵滑靴副摩擦特性的研究[J]. 工程设计学报, 2014, 21(1): 51-55.

SHEN Ru-lin,PAN You-feng. Friction characteristic analysis of slipper pair in A11VO190 axial piston pumps. Chinese Journal of Engineering Design, 2014, 21(1): 51-55.

链接本文:

https://www.zjujournals.com/gcsjxb/CN/10.3785/j.issn. 1006-754X.2014.01.009        https://www.zjujournals.com/gcsjxb/CN/Y2014/V21/I1/51

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