Fault tree analysis and process instrumentation of S2WRS based hydrogen cooling system

2010 IEEE International Energy Conference Pub Date : 2010-12-01 DOI:10.1109/ENERGYCON.2010.5771709

G. Biswal, R. Maheshwari, M. Dewal

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引用次数: 9

Abstract

A comprehensive hydrogen cooling system (HCS) is required for cooling of the generators of 2×300 MW unit power plant at a pressure of 4 to 5 bar. The faster heat dissipation of generators depends on purity of hydrogen (H2), as it improves its ability to dissipate heat within generators. Therefore, the process involved should be reliable enough to maintain the availability of Hydrogen as and when required at desired pressure. Thus, the requirement of a highly reliable and efficient process instrumentation system is a must. The key focus of this paper is to present fault tree analysis (FTA) having improved system reliability of proposed model as compared to existing available systems. A novel six stages warm redundant structured (S2WRS) HCS for cooling of the generators in typical thermal power plant is proposed. The system reliability test of proposed S2WRS model is simulated using MATLAB. The entire process instrumentation system is designed and simulated on RSViewSE, a real-time supervisory control and data acquisition (SCADA) platform by Rockwell Automation. This process model is designed as per specifications guided by IEEE C37.1–2007, IEEE 1413–2003, IEEE 493–1997, IEC 60034–3, IEC 61025 and IEC 61131–3.

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基于S2WRS的氢冷却系统故障树分析及过程仪表

在4 ~ 5bar的压力下，对2×300 MW机组电厂的发电机进行冷却，需要一个综合的氢冷却系统(HCS)。发电机更快的散热取决于氢气(H2)的纯度，因为它提高了其在发电机内散热的能力。因此，所涉及的过程应该足够可靠，以便在需要时在所需的压力下保持氢气的可用性。因此，对高可靠性和高效率的过程仪表系统的要求是必须的。本文的重点是介绍故障树分析(FTA)与现有可用系统相比，提高了系统可靠性。提出了一种用于典型火电厂发电机冷却的新型六级热冗余结构(S2WRS) HCS。利用MATLAB对所提出的S2WRS模型进行了系统可靠性测试。整个过程仪表系统在罗克韦尔自动化的实时监控和数据采集(SCADA)平台RSViewSE上进行了设计和仿真。该过程模型是按照IEEE C37.1-2007, IEEE 1413-2003, IEEE 493-1997, IEC 60034-3, IEC 61025和IEC 61131-3的规范设计的。

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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2010 IEEE International Energy Conference

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