Research on the Critical Speed of a Mixed-Flow Turbocharger with Hybrid Ceramic Ball Bearing 被引量：3

Research on the Critical Speed of a Mixed-Flow Turbocharger with Hybrid Ceramic Ball Bearing

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摘要 The critical speeds for a vehicle turbocharger with hybrid ceramic ball bearing are researched. The ball bearing-rotor system produces resonance when it working in critical speed and that makes the turbocharger injury working for a long time. The calculation and analysis methods of the critical speed for the vehicle turbocharger are described. The critical speed is computed by two methods including Riccati transfer matrix and DyRoBeS finite element method for a vehicle turbocharger with hybrid ceramic ball bearing. The vibration experiment had been taken to validate the calculating result, Comparison between the results by two calculation methods and the test results show that the first critical speed differences are 6.47 % and 5.66 %, the second critical speed differences are 2.87 % and 2.94 % respectively. And then, the primary factors which influence the critical speed are analyzed, the conclusions will be helpful for the vehicle turbocharger bearing-rotor system design. The critical speeds for a vehicle turbocharger with hybrid ceramic ball bearing are researched. The ball bearing-rotor system produces resonance when it working in critical speed and that makes the turbocharger injury working for a long time. The calculation and analysis methods of the critical speed for the vehicle turbocharger are described. The critical speed is computed by two methods including Riccati transfer matrix and DyRoBeS finite element method for a vehicle turbocharger with hybrid ceramic ball bearing. The vibration experiment had been taken to validate the calculating result, Comparison between the results by two calculation methods and the test results show that the first critical speed differences are 6.47 % and 5.66 %, the second critical speed differences are 2.87 % and 2.94 % respectively. And then, the primary factors which influence the critical speed are analyzed, the conclusions will be helpful for the vehicle turbocharger bearing-rotor system design.

作者黄若葛新滨马朝臣

机构地区 School of Mechanical Engineering

出处《Journal of Beijing Institute of Technology》 EI CAS 2009年第3期298-303,共6页 北京理工大学学报（英文版）

关键词 mixed-flow turbocharger ceramic ball bearing bearing-rotor system critical speed bearing equivalent stiffness mixed-flow turbocharger ceramic ball bearing bearing-rotor system critical speed bearing equivalent stiffness

分类号 TH133.3 [机械工程—机械制造及自动化]

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Journal of Beijing Institute of Technology

2009年第3期

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