Uncertainty Quantification And Sensitivity Analysis For The Self-Excited Vibration Of A Spline-Shafting System

X. Ma, Yucai Zhong, P. Cao, Jie-Hong Yuan, Zhenguo Zhang
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Abstract

Self-excited vibrations can occur in the spline-shafting system due to internal friction of the tooth surface. However, due to manufacturing errors, design tolerances, and time-varying factors, the parameters that induce self-excited vibrations are always uncertain. This study provides new insights into the uncertainty quantification and sensitivity analysis of a spline-shaft system suffering from self-excited vibrations. The non-intrusive generalised polynomial chaos expansion (gPCE) with unknown deterministic coefficients is used to represent the propagation of uncertainties in the rotor dynamics, which allows rapid estimation of the statistics of the non-linear responses. Furthermore, the global sensitivity analysis of the stochastic self-excited vibration response of the rotor system with probabilistic uncertain parameters is evaluated by Sobol indices. The relative influence of different random parameters on the vibration behavior and initial displacement conditions for the occurrence of self-excited vibration is investigated. The accuracy of the adopted method based on the gPCE metamodel is validated by conventional Monte Carlo simulation (MCS). Finally, the effects of parameter uncertainties considering random distribution characteristics on the stochastic vibration characteristics of the rotor system are discussed, which demonstrates the need to consider input uncertainties in analysis and design to ensure robust system performance.
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花键轴系自激振动的不确定性量化及灵敏度分析
由于齿面内摩擦,在花键轴系中可发生自激振动。然而,由于制造误差、设计公差和时变因素,引起自激振动的参数总是不确定的。该研究为花键轴系统自激振动的不确定度量化和灵敏度分析提供了新的见解。采用具有未知确定性系数的非侵入式广义多项式混沌展开(gPCE)来表示转子动力学中的不确定性传播,从而可以快速估计非线性响应的统计量。此外,利用Sobol指标对具有概率不确定参数的转子系统随机自激振动响应进行了全局灵敏度分析。研究了不同随机参数对振动特性和产生自激振动的初始位移条件的相对影响。通过传统的蒙特卡罗仿真(MCS)验证了基于gPCE元模型的方法的准确性。最后,讨论了考虑随机分布特性的参数不确定性对转子系统随机振动特性的影响,说明在分析和设计中需要考虑输入不确定性,以保证系统的鲁棒性。
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来源期刊
CiteScore
5.20
自引率
13.60%
发文量
34
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