Strain-based running-reliability characterisation in time-domain for risk monitoring under various load conditions

Eksploatacja i Niezawodność – Maintenance and Reliability Pub Date : 2024-04-14 DOI:10.17531/ein/186825

Salvinder Singh Karam Singh, L. Abdullah, Shahrum Abdullah, Abdul Hadi Azman, Ahmad Kamal Ariffin

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Abstract

This aim of this paper is to characterise the strain-based fatigue life data in time-domain using the newly modelled running-reliability technique that considers the load sequence effect. Current established conventional strain life models do not consider dependence for fatigue life of low or high amplitudes, on which with occur first in the load history. Finite element analysis is carried out to ensure the strain signals are captured at the most critical region during road test at various conditions. Fatigue life of 2.74 × 104 to 6.07 × 105 cycle/block with mean cycle to failure of 4.32 × 106 to 7.00 × 106 cycle/block is predicted based on the cycle sequence effect using cycle-counting method. The newly modelled running-reliability technique is formulated to extract the features of high amplitude excitation obtained from the strain signals for characterising the fatigue reliability features under load sequence effect. Hence, the reliability-hazard relationship for fatigue reliability characterisation of strain-based approach in time-domain using running-reliability technique.

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基于应变的时域运行可靠性表征，用于各种负载条件下的风险监测

本文的目的是利用考虑了载荷序列效应的新运行可靠性模型技术，在时域中描述基于应变的疲劳寿命数据的特征。目前建立的传统应变寿命模型没有考虑低振幅或高振幅的疲劳寿命与载荷历史中哪种情况最先发生有关。在各种条件下进行路试时，为确保在最关键区域捕捉到应变信号，进行了有限元分析。根据循环序列效应，采用循环计数法预测疲劳寿命为 2.74 × 104 至 6.07 × 105 周期/块，平均失效周期为 4.32 × 106 至 7.00 × 106 周期/块。新建模的运行可靠性技术可从应变信号中提取高振幅激励特征，用于描述载荷序列效应下的疲劳可靠性特征。因此，利用运行可靠性技术，在时域中利用基于应变的方法表征疲劳可靠性的可靠性-危险关系。

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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Eksploatacja i Niezawodność – Maintenance and Reliability

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