一类齿轮传动系统的簇发振荡现象研究
Study on the Bursting Oscillations Phenomenon of a Kind of Gear Transmission System
DOI: 10.12677/OJAV.2021.94016, PDF,    国家自然科学基金支持
作者: 杨 园, 钱有华*:浙江师范大学数学与计算机科学学院,浙江 金华
关键词: 非光滑齿轮传动系统分岔簇发振荡Non-Smooth Gear Transmission System Bifurcation Bursting Oscillation
摘要: 本文以带有一齿侧间隙的非光滑齿轮传动系统为研究对象,系统被非光滑分界面分成不同的子系统,当激励频率远小于系统固有频率时,会产生诸如簇发振荡等特殊行为。将整个激励项看做慢变参数,激励系统转化为广义自治系统也即快子系统,分析快子系统平衡点的稳定性以及分岔条件,并运用快慢分析法和转换相图揭示了簇发振荡的动力学机理。考虑无量纲一齿侧间隙、啮合频率、啮合刚度和波动幅值对齿轮传动的影响,借助分岔图、相图、庞加莱映射以及最大李雅普诺夫指数来分析其系统的动力学机制。研究结果发现无量纲啮合频率、啮合刚度和波动幅值对系统有一定的影响,研究结果可以为齿轮传动系统安全设计提供参考。
Abstract: Taking a non-smooth gear transmission system with a toothed clearance as the research object, the system is divided into different subsystems by non-smooth interfaces. When the excitation frequency is far less than the natural frequency of the system, special behaviors such asbursting oscillation will occur. The whole excitation is regarded as a slow parameter, and the excitation system is transformed into a generalized autonomous system, that is, a fast subsystem. The stability and bifurcation conditions of the equilibrium point of the fast subsystem are analyzed, and the dynamic mechanism of bursting oscillation is revealed by using the fast and slow analysis method and transformation phase diagram. Considered the impact of dimensionless toothed clearance, meshing frequency, meshing stiffness and fluctuation amplitude on the gear transmission, the bifurcation mechanism and the bursting oscillation of the system are based on bifurcation diagrams, Lyapunov exponents and phase portraits, poincare maps. The results show that the dimensionless meshing frequency, meshing stiffness and fluctuation amplitude have some effect on the system. The research results can provide reference for the safety design of gear transmission system.
文章引用:杨园, 钱有华. 一类齿轮传动系统的簇发振荡现象研究[J]. 声学与振动, 2021, 9(4): 153-165. https://doi.org/10.12677/OJAV.2021.94016

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