Shock-Loading-Based Reliability Modeling with Dependent Degradation Processes and Random Shocks

IF 0.9 Q3 ENGINEERING, MULTIDISCIPLINARY

International Journal of Reliability Quality and Safety Engineering Pub Date : 2022-06-27 DOI:10.1142/s0218539322500024

Rui Wang, Mengmeng Zhu

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引用次数: 1

Abstract

In general, a system deteriorates due to internal physical degradation and external random shocks. Previous studies mainly focused on establishing dependent competing risk models to evaluate mutual effects of degradation processes and random shocks affecting system health. However, there is a lack of consideration about the magnitude of impacts caused by random shocks on degradation processes. Thus, a shock-loading-based degradation model is proposed to classify the magnitude of impacts from random shocks on degradation processes based on the threshold of the cumulative shock loading. Copula methods are utilized to derive joint reliability function from multiple marginal distributions of degradation processes. Two numerical examples are utilized to demonstrate the reliability prediction performance of the proposed model. First, a simulated example is used. The second example employs the turbofan engine degradation data from the NASA Prognostic Data Repository to show the performance of the proposed shock-loading-based degradation process and its corresponding system reliability model.

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基于依赖退化过程和随机冲击的冲击载荷可靠性建模

一般来说，系统的退化是由于内部的物理退化和外部的随机冲击。以往的研究主要集中在建立依赖竞争风险模型来评估退化过程和随机冲击对系统健康的相互影响。然而，缺乏对随机冲击对退化过程影响程度的考虑。因此，提出了一种基于冲击载荷的退化模型，该模型基于累积冲击载荷阈值对随机冲击对退化过程的影响程度进行分类。利用Copula方法从退化过程的多个边际分布中推导出联合可靠度函数。通过两个算例验证了该模型的可靠性预测性能。首先，使用了一个模拟示例。第二个示例使用来自NASA预测数据存储库的涡扇发动机退化数据来展示所提出的基于冲击载荷的退化过程及其相应的系统可靠性模型的性能。

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来源期刊

International Journal of Reliability Quality and Safety Engineering ENGINEERING, MULTIDISCIPLINARY-

CiteScore

1.70

自引率

25.00%

发文量

期刊介绍： IJRQSE is a refereed journal focusing on both the theoretical and practical aspects of reliability, quality, and safety in engineering. The journal is intended to cover a broad spectrum of issues in manufacturing, computing, software, aerospace, control, nuclear systems, power systems, communication systems, and electronics. Papers are sought in the theoretical domain as well as in such practical fields as industry and laboratory research. The journal is published quarterly, March, June, September and December. It is intended to bridge the gap between the theoretical experts and practitioners in the academic, scientific, government, and business communities.