Dynamic modeling of central bevel gear transmission system in aero-engine

IF 0.3 4区工程技术 Q4 ACOUSTICS

Noise Control Engineering Journal Pub Date : 2022-01-01 DOI:10.3397/1/37704

Jia-You Liu, Hao Zhang, Jing-yu Zhai, Qingkai Han

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Abstract

Aero-engine is the most critical part of an aircraft. As its key component, the central bevel gear transmission system is always designed only considering the meshing vibration and ignoring structural characteristics of shafts and bearings, and comprehensive vibration characteristics is not well addressed. The transmission system may suffer severe vibration. To accurately study the dynamic characteristics of the system, a model of a central bevel gear transmission system is developed considering the effects of bevel gear mesh stiffness, shaft stiffness, bearing stiffness, and unbalance excitation in this paper. It has been validated by finite element software ANSYS. On this basis, the influence of variation of bearing stiffness and mesh stiffness on the natural characteristics of the central bevel gear transmission system is investigated. The influence of unbalance on the radial vibration and gear meshing force is studied by the analytical calculation method. A case study is carried out. The results show that variation of stiffness within a certain range will cause dramatic changes in the natural characteristics of the system. The unbalance of the driven bevel gear shaft has an effect on the radial vibration and meshing force of the system. The proposed model can reflect radial vibration characteristics, axial vibration characteristics, torsional vibration characteristics, and some coupled natural characteristics of the system. This research provides a theoretical basis to optimize dynamic performance and reduce the vibration of the system and will be helpful in designing the central bevel gear transmission system.

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航空发动机中心锥齿轮传动系统动力学建模

航空发动机是飞机最关键的部件。中央锥齿轮传动系统作为其关键部件，其设计往往只考虑啮合振动，而忽略了轴和轴承的结构特点，综合振动特性没有得到很好的解决。传动系统可能会受到严重的振动。为了准确地研究系统的动态特性，本文建立了一个考虑锥齿轮啮合刚度、轴刚度、轴承刚度和不平衡激励影响的中心锥齿轮传动系统模型。并通过有限元软件ANSYS进行了验证。在此基础上，研究了轴承刚度和啮合刚度的变化对中心锥齿轮传动系统固有特性的影响。采用解析计算方法研究了不平衡对径向振动和齿轮啮合力的影响。进行了案例研究。结果表明，刚度在一定范围内的变化会使系统的固有特性发生显著变化。从动锥齿轮轴的不平衡对系统的径向振动和啮合力有影响。所提出的模型可以反映系统的径向振动特性、轴向振动特性、扭转振动特性以及一些耦合的固有特性。该研究为优化系统动态性能、降低系统振动提供了理论依据，对中心锥齿轮传动系统的设计具有一定的指导意义。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Noise Control Engineering Journal 工程技术-工程：综合

CiteScore

0.90

自引率

25.00%

发文量

审稿时长

3 months

期刊介绍： NCEJ is the pre-eminent academic journal of noise control. It is the International Journal of the Institute of Noise Control Engineering of the USA. It is also produced with the participation and assistance of the Korean Society of Noise and Vibration Engineering (KSNVE). NCEJ reaches noise control professionals around the world, covering over 50 national noise control societies and institutes. INCE encourages you to submit your next paper to NCEJ. Choosing NCEJ: Provides the opportunity to reach a global audience of NCE professionals, academics, and students; Enhances the prestige of your work; Validates your work by formal peer review.