Finite Element Analysis of Internal Gear in High-Speed Planetary Gear Units 被引量：8

Finite Element Analysis of Internal Gear in High-Speed Planetary Gear Units

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摘要 The stress and the elastic deflection of internal ring gear in high-speed spur planetary gear units are investigated. A rim thickness parameter is defined as the flexibility of internal ring gear. Six evenly spaced linear springs are used to describe the fitting status between internal ring gear and the gearcase. The finite element model of the whole internal ring gear is established by means of Pro/E and ANSYS. The loads on meshing teeth of internal ring gear are applied according to the contact ratio and the load-sharing coefficient. With the finite element analysis (FEA), the influences of flexibility and fitting status on the stress and elastic deflection of internal ring gear are predicted. The simulation reveals that the principal stress and deflection increase with the decrease of rim thickness of internal ring gear. Moreover, larger spring stiffness helps to reduce the stress and deflection of internal ring gear. Therefore, the flexibility of internal ring gear must be considered during the design of high-speed planetary gear transmissions. The stress and the elastic deflection of internal ring gear in high-speed spur planetary gear units are investigated. A rim thickness parameter is defined as the flexibility of internal ring gear. Six evenly spaced linear springs are used to describe the fitting status between internal ring gear and the gearcase, The finite element model of the whole internal ring gear is established by means of Pro/E and ANSYS. The loads on meshing teeth of internal ring gear are applied according to the contact ratio and the load-sharing coefficient. With the finite element analysis （FEA）, the influences of flexibility and fitting status on the stress and elastic deflection of internal ring gear are predicted. The simulation reveals that the principal stress and deflection increase with the decrease of rim thickness of internal ring gear. Moreover, larger spring stiffness helps to reduce the stress and deflection of internal ring gear. Therefore, the flexibility of internal ring gear must be considered during the design of high-speed planetary gear transmissions.

作者葛楠张俊

机构地区 School of Mechanical Engineering

出处《Transactions of Tianjin University》 EI CAS 2008年第1期11-15,共5页 天津大学学报（英文版）

基金 Key Project of Ministry of Education of China (No.106050).

关键词行星齿轮传动内环形齿轮有限元性能 planetary gear transmissions internal ring gear finite element method

分类号 TH132.41 [机械工程—机械制造及自动化]

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Finite Element Analysis of Internal Gear in High-Speed Planetary Gear Units 被引量：8

参考文献10

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