Influence of tooth surface wear and nonlinear contact stiffness on dynamic responses of helical gears

Q4 Engineering

Recent Patents on Mechanical Engineering Pub Date : 2022-08-05 DOI:10.2174/2212797615666220805121848

Lin Han, Shaoshuai Liu, Yang Qi, Weiguang Li

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引用次数: 0

Abstract

Tooth surface wear is inevitable in helical geared transmission. Consequently, the worn profile deviates from ideal involute one. As a result, the structural stiffness of worn tooth and contact stiffness of tooth-pair are both changed. This work presents an improved calculation method for structural stiffness of worn teeth by combining slicing and potential energy method, considering non-uniform distribution of wear amount along tooth surface. Then a nonlinear contact stiffness model is employed to investigate the influence of wear on contact stiffness. Meanwhile, taking wear as one kind of profile deviation, the analytical model of time-varying mesh stiffness (TVMS) of helical gear pair is derived. Furthermore, governing equations with 6 degree-of-freedom is established and influences of wear on dynamic responses are revealed. Results indicate that structural stiffness of worn teeth decreases but contact stiffness does not always keep increasing or decreasing. The fluctuation of dynamic transmission error with the nonlinear contact model is not as significant as that from constant contact stiffness model. The approach presented in this work is suitable for condition monitoring of helical gears in view of long-term service.

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齿面磨损和非线性接触刚度对斜齿轮动态响应的影响

齿面磨损是螺旋齿轮传动中不可避免的问题。因此，磨损的轮廓偏离理想的渐开线轮廓。因此，磨损齿的结构刚度和齿副的接触刚度都发生了变化。考虑磨损量沿齿面分布的不均匀性，提出了一种结合切片法和势能法的磨损齿结构刚度计算方法。然后采用非线性接触刚度模型研究了磨损对接触刚度的影响。同时，将磨损作为齿形偏差的一种，推导了斜齿轮副时变啮合刚度的解析模型。建立了六自由度控制方程，揭示了磨损对动力响应的影响。结果表明，磨损齿的结构刚度降低，但接触刚度并不总是增加或减少。非线性接触模型下的动态传动误差波动幅度不如恒定接触刚度模型下的动态传动误差波动幅度大。考虑到斜齿轮的长期使用，本文提出的方法适用于斜齿轮的状态监测。

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

Recent Patents on Mechanical Engineering Engineering-Mechanical Engineering

CiteScore

0.80

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0.00%

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