Friction moment analysis of space gyroscope bearing with ribbon cage under ultra-low oscillatory motion 被引量：5

Friction moment analysis of space gyroscope bearing with ribbon cage under ultra-low oscillatory motion

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摘要 This paper presents the model of calculating the total friction moment of space gyroscope ball bearings which usually work under ultra-low oscillatory motion and are very sensitive to the friction moment. The aim is to know the proportion of the friction moment caused by each frictional source in the bearing＇s total friction moment, which is helpful to optimize the bearing design to deduce the friction moment. In the model, the cage dynamic equations considering six degree-of-freedom and the balls dynamic equations considering two degree-of-freedom were solved.The good trends with different loads between the measured friction moments and computational results prove that the model under constant rate was validated. The computational results show that when the speed was set at 5 r/min, the bearing＇s maximum total friction moment when oscillation occurred was obviously larger than that occurred at a constant rate. At the onset of each oscillatory motion, the proportion of the friction moment caused by cage in the bearing＇s total friction moment was very high, and it increased with the increasing speed. The analyses of different cage thicknesses and different clearances between cage pocket and ball show that smaller thickness and clearance were preferred. This paper presents the model of calculating the total friction moment of space gyroscope ball bearings which usually work under ultra-low oscillatory motion and are very sensitive to the friction moment. The aim is to know the proportion of the friction moment caused by each frictional source in the bearing＇s total friction moment, which is helpful to optimize the bearing design to deduce the friction moment. In the model, the cage dynamic equations considering six degree-of-freedom and the balls dynamic equations considering two degree-of-freedom were solved.The good trends with different loads between the measured friction moments and computational results prove that the model under constant rate was validated. The computational results show that when the speed was set at 5 r/min, the bearing＇s maximum total friction moment when oscillation occurred was obviously larger than that occurred at a constant rate. At the onset of each oscillatory motion, the proportion of the friction moment caused by cage in the bearing＇s total friction moment was very high, and it increased with the increasing speed. The analyses of different cage thicknesses and different clearances between cage pocket and ball show that smaller thickness and clearance were preferred.

作者 Jiang Shaona Chen Xiaoyang Gu Jiaming Shen Xuejin

机构地区 Research Institute of Bearings Shanghai Tianan Bearing Co.

出处《Chinese Journal of Aeronautics》 SCIE EI CAS CSCD 2014年第5期1301-1311,共11页 中国航空学报（英文版）

基金 supports from the National ‘‘the eleventh-five years’’ Projects of Science and Technology under contract (No. D09-0109-06-004) of China Innovative Team Program of Universities in Shanghai of Shanghai Municipality Education Commission (No. B-48-0109-09-002) of China

关键词 Ball bearings Cage thicknesses Clearances Dynamic equations Friction moment Frictional sources Oscillatory motion Ball bearings Cage thicknesses Clearances Dynamic equations Friction moment Frictional sources Oscillatory motion

分类号 TH133.3 [机械工程—机械制造及自动化] U661.7 [交通运输工程—船舶及航道工程]

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2014年第5期

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