Effect of Interstage Torsional Damping on Nonlinear Dynamic Characteristics of Two-Stage Planetary Gear System-Reference-Cited by-同舟云学术

Effect of Interstage Torsional Damping on Nonlinear Dynamic Characteristics of Two-Stage Planetary Gear System

Published:2024-05-13 Issue:6 Volume:19 Page:
ISSN:1555-1415
Container-title:Journal of Computational and Nonlinear Dynamics
language:en
Short-container-title:

Author:

Man Jianhao¹,Chen Long²^ORCID,He Junjie³,Hu Wei⁴,Lu Kuihua⁵,Liu Xiao-ang¹

Affiliation:

1. Tianjin Key Laboratory of Power Transmission and Safety Technology for New Energy Vehicles, School of Mechanical Engineering, Hebei University of Technology , Tianjin 300131, China

2. School of Mechanical Engineering, Northwestern Polytechnical University , Xian Shanxi 710072, China

3. Beijing Automotive Research Institute Co., Ltd., Tianjin Key Laboratory of Power Transmission and Safety Technology for New Energy Vehicles, School of Mechanical Engineering, Hebei University of Technology , Tianjin 300131, China

4. World Transmission Technology (Tianjin) Co., Ltd , Tianjin 300409, China

5. World Tech Intelligence Technology (Tianjin) Co., Ltd , Tianjin 300409, China

Abstract

Abstract This paper explores the influence of interstage torsional damping on the nonlinear dynamics of a two-stage planetary gear transmission system. A comprehensive nonlinear dynamic model is developed, incorporating interstage torsional damping, stiffness, time-varying meshing parameters, damping, and tooth side clearance. The nonlinear equations are derived and solved using the fourth-order Runge–Kutta method. The investigation reveals that the changes in torsional damping between stages significantly affect the nonlinear dynamic characteristics of the system, especially under load fluctuations. Bifurcation characteristics are analyzed using phase diagrams, Poincaré diagrams, time history diagrams, and frequency–domain spectrograms. The simulation results demonstrate that heightened torsional damping between stages distinctly affects the motion states across excitation frequencies. Notably, it mitigates the unstable motion state caused by high-frequency excitation when tooth side clearance is minimal.

Publisher

ASME International

Link

https://asmedigitalcollection.asme.org/computationalnonlinear/article-pdf/19/6/061004/7341287/cnd_019_06_061004.pdf

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