Develop and verify Energy-Based Statistical Linearization Technique to Analysis Nonlinear Stochastic Vibration of A Spur Gear Pair

IF 1.9 4区工程技术 Q2 ACOUSTICS

Journal of Vibration and Acoustics-Transactions of the Asme Pub Date : 2022-09-08 DOI:10.1115/1.4055560

J. Taheri Kahnamouei, Jianming Yang

引用次数: 1

Abstract

In this article, an energy-based statistical linearization method (SL) is proposed to simulate a nonlinear dynamic model of spur gear pair. The gear pair operates under combined deterministic and random loads, and both backlash and time-varying mesh stiffness are considered in the dynamic model. The equivalent linear function approximates the teeth backlash nonlinearity in the gear model. The energy-based linearization, which minimizes the error in potential energy between the original and equivalent linear systems, is used. Simulations are conducted on a gear-pair, and the effect of the input torque on the dynamic response of the gear pair is then examined. The results demonstrate that for high input torque, the system operates in the linear range. For low input torque, the results are not similar to the original because the system became strongly nonlinear. Monte Carlo simulations were carried out to verify the accuracy of the presented method.

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开发并验证了基于能量的统计线性化技术对直齿齿轮副非线性随机振动的分析

本文提出了一种基于能量的统计线性化方法来模拟直齿齿轮副的非线性动力学模型。齿轮副在确定性载荷和随机载荷双重作用下工作，动力学模型同时考虑了齿隙和时变啮合刚度。等效线性函数近似于齿轮模型中的齿隙非线性。采用基于能量的线性化方法，使原始系统和等效线性系统之间的势能误差最小化。以某齿轮副为例进行了仿真，分析了输入转矩对齿轮副动态响应的影响。结果表明，当输入转矩较大时，系统工作在线性范围内。当输入转矩较低时，系统变得强烈非线性，结果与原来不同。通过蒙特卡罗仿真验证了所提方法的准确性。

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

Journal of Vibration and Acoustics-Transactions of the Asme 工程技术-工程：机械

CiteScore

4.20

自引率

11.80%

发文量

审稿时长

7 months

期刊介绍： The Journal of Vibration and Acoustics is sponsored jointly by the Design Engineering and the Noise Control and Acoustics Divisions of ASME. The Journal is the premier international venue for publication of original research concerning mechanical vibration and sound. Our mission is to serve researchers and practitioners who seek cutting-edge theories and computational and experimental methods that advance these fields. Our published studies reveal how mechanical vibration and sound impact the design and performance of engineered devices and structures and how to control their negative influences. Vibration of continuous and discrete dynamical systems; Linear and nonlinear vibrations; Random vibrations; Wave propagation; Modal analysis; Mechanical signature analysis; Structural dynamics and control; Vibration energy harvesting; Vibration suppression; Vibration isolation; Passive and active damping; Machinery dynamics; Rotor dynamics; Acoustic emission; Noise control; Machinery noise; Structural acoustics; Fluid-structure interaction; Aeroelasticity; Flow-induced vibration and noise.