Verifying Diversity Defense Mechanisms against Common Cause Failures for Safety Instrumented Systems Using a Stress-Strength Model

2012 International Conference on Control Engineering and Communication Technology Pub Date : 2012-12-07 DOI:10.1109/ICCECT.2012.201

Kai Wang, Aidong Xu, Hong Wang

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引用次数: 6

Abstract

Common cause failure (CCF) is a serious threat to Safety Instrumented Systems (SIS) reliability. It is therefore important to model and quantify CCF in reliability analysis. Diversity has long been used to protect redundant systems against CCF. Whilst there is clear evidence that diversity can bring benefits when compared with identical redundancy systems, these benefits can be difficult to quantify. Therefore, a novel CCF model which studies CCF from the viewpoint of Root Cause (RC) and Coupling Factor is proposed in this paper. The key parameters of the novel CCF model can be determined based on a stress-strength model by classifying variables of stressors and strengths according to RC categories. An application example is provided that illustrates how the proposed CCF model performs for a chemical reactor safety system (CRSS) for protection against high pressure and temperature. The results not only confirm that diversity techniques lower the CCF probability but also provide quantitative assessment of how large the improvements can be in different diversity techniques.

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使用应力-强度模型验证安全仪表系统针对共因故障的多样性防御机制

共因故障(CCF)严重威胁着安全仪表系统(SIS)的可靠性。因此，在可靠性分析中对CCF进行建模和量化是非常重要的。长期以来，多样性一直被用来保护冗余系统免受CCF的影响。虽然有明确的证据表明，与相同的冗余系统相比，多样性可以带来好处，但这些好处很难量化。为此，本文提出了一种从根本原因和耦合因子的角度研究CCF的新型CCF模型。基于应力-强度模型，将应力源和强度变量按RC分类，确定了新型CCF模型的关键参数。给出了一个应用实例，说明了所提出的CCF模型在化学反应堆安全系统(CRSS)中对高压和高温的保护效果。结果不仅证实了多样性技术降低了CCF概率，而且还提供了对不同多样性技术的改进程度的定量评估。

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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2012 International Conference on Control Engineering and Communication Technology

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