前悬架下控制臂设计疲劳寿命不确定性量化

Misganaw Abebe, Bonyong Koo
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引用次数: 0

摘要

本研究的目的是探讨前悬挂下控制臂在疲劳载荷情况下设计变量的不确定性,以估计可靠和稳健的产品。本研究提供了一种系统不确定性量化(UQ)的方法,并采取了以下步骤:首先,建立了一个有限元模型来预测碰撞载荷条件下控制臂的疲劳寿命。其次,基于一种全局分析,开发了一种灵敏度方案来识别模型中最显著和最不显著的设计输入变量。第三,采用基于物理和数据驱动的不确定性量化方案,通过蒙特卡罗模拟对模型输入参数的不确定性进行量化。模拟使用了10,000个材料性能和几何不确定性变量样本,变异系数从1%到3%不等。最后,置信区间结果显示与平均值(基线)的偏差约为21.74%。因此,通过应用系统的UQ,可以在设计初期就设计出更可靠、更健壮的汽车悬架控制臂,从而更有效、更好地逼近不确定条件下的疲劳寿命。
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Fatigue Life Uncertainty Quantification of Front Suspension Lower Control Arm Design
The purpose of this study is to investigate the uncertainty of the design variables of a front suspension lower control arm under fatigue-loading circumstances to estimate a reliable and robust product. This study offers a method for systematic uncertainty quantification (UQ), and the following steps were taken to achieve this: First, a finite element model was built to predict the fatigue life of the control arm under bump-loading conditions. Second, a sensitivity scheme, based on one of the global analyses, was developed to identify the model’s most and least significant design input variables. Third, physics-based and data-driven uncertainty quantification schemes were employed to quantify the model’s input parameter uncertainties via a Monte Carlo simulation. The simulations were conducted using 10,000 samples of material properties and geometrical uncertainty variables, with the coefficients of variation ranging from 1 to 3%. Finally, the confidence interval results show a deviation of about 21.74% from the mean (the baseline). As a result, by applying systematic UQ, a more reliable and robust automobile suspension control arm can be designed during the early stages of design to produce a more efficient and better approximation of fatigue life under uncertain conditions.
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