Optimal Design and Dynamic Simulation of Mountain Bike with Rear Suspension 被引量：2

Optimal Design and Dynamic Simulation of Mountain Bike with Rear Suspension

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摘要 This paper investigates the dynamic design methodology of mountain bikes with rear suspension. Firstly, a multi-rigid body dynamic model of rider and mountain bike coupled system is constructed. The rider model includes 19 skeletons, 18 joints and 118 main muscles. Secondly, to validate the feasibility of the model, an experiment test is designed to reflect the real cycling status. Finally, aiming at enhancing the performance of the rider vibration comfort, the scale parameters of rear suspension are optimized with computer simulation and uniform design. The mathematical model in the vibration performance and the design variables is constructed with regression analysis. The result shows that when the length of side link is 90 mm, the length of connected rod is 336.115 1 mm and the included angle between absorber and side link is 60°, the mountain bike has better vibration comfort. This study and relevant conclusions are of practical importance to the design of the mountain bike＇s rear suspension system. This paper investigates the dynamic design methodology of mountain bikes with rear suspension. Firstly, a multi-rigid body dynamic model of rider and mountain bike coupled system is constructed. The rider model includes 19 skeletons, 18 joints and 118 main muscles. Secondly, to validate the feasibility of the model, an experiment test is designed to reflect the real cycling status. Finally, aiming at enhancing the performance of the rider vibration comfort, the scale parameters of rear suspension are optimized with computer simulation and uniform design. The mathematical model in the vibration performance and the design variables is constructed with regression analysis. The result shows that when the length of side link is 90 mm, the length of connected rod is 336.115 1 mm and the included angle between absorber and side link is 60°, the mountain bike has better vibration comfort. This study and relevant conclusions are of practical importance to the design of the mountain bike＇s rear suspension system.

作者 BU Yan XIANG Zhongxia HUANG Tian ZHANG Xu WANG Xinghua

机构地区 School of Mechanical Engineering Tianjin Entry-exit Inspection and Quarantine Bureau

出处《Chinese Journal of Mechanical Engineering》 SCIE EI CAS CSCD 2009年第1期21-26,共6页 中国机械工程学报（英文版）

基金 supported by Tianjin Municipal Science and Technology Development Project of China (Grant No. 043186211) Tianjin Municipal Key Laboratory of Advanced Manufacturing Technology and Equipment of Tianjin University of China

关键词 mountain bike model building dynamic simulation experiment test vibrant comfort optimal design mountain bike, model building, dynamic simulation, experiment test, vibrant comfort, optimal design

分类号 TP391.9 [自动化与计算机技术—计算机应用技术] U484 [交通运输工程—载运工具运用工程]

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参考文献14

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5XIANG Zhongxia,XU Ruifen,BU Yan,WU Xiaofan.Optimal Design of Bicycle Frame Parameters Considering Biomechanics[J].Chinese Journal of Mechanical Engineering,2011,24(1):141-145. 被引量：3

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Optimal Design and Dynamic Simulation of Mountain Bike with Rear Suspension 被引量：2

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