Vibration Analysis of Locomotive Rotor System

doi:10.3901/JME.2018.12.102

Abstract

Abstract: With the continuous improvement of locomotive speed, it has demanded higher requirement of the stability and operating safety. Firstly, taking into account the composite factors such as bear elastic-support and gear mesh stiffness. the dynamical model of Locomotive transmission Finite-element system is established based on Lagrange principle of minimum potential energy. Secondly, numerical solution of critical speed and modal response solved by iteration method. Finally, under the action of bear supporting stiffness, gear mesh stiffness and wheel-rail contact force, the amplitude-frequency response of rotor system are analysed qualitatively. The results show that when frequency was near to the gear mash frequency and natural frequency of the drive system, vibration amplitudes increased obviously with complex environment. In the meantime, the amplitude of the passing frequency of rolling bearing decreased. Moreover, under influence of the rail contact stiffness, vibration amplitude of associated with the gear mesh frequency, natural frequency and passing frequency of rolling bearing were disturbed.

Key words: critical speed, finite-element method, meshing gear, vibration respone, wheel-rail excitation

CLC Number:

O322

YANG Liu, LI Qiang, YANG Shaopu, WANG Jiujian, GU Xiaohui. Vibration Analysis of Locomotive Rotor System[J]. Journal of Mechanical Engineering, 2018, 54(12): 102-108.

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