Reliability evaluation of bulk power system considering compressed air energy storage

2017 IEEE Electrical Power and Energy Conference (EPEC) Pub Date : 2017-10-01 DOI:10.1109/EPEC.2017.8286234

O. Ansari, Safal Bhattarai, R. Karki, C. Chung

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引用次数: 5

Abstract

The integration of large-scale energy storage systems (ESSs) have been identified as a viable option to mitigate the adverse effects of renewable energy sources (RES) on the power system operation and reliability. Currently, compressed air energy storage (CAES) is one of the two large-scale energy storage technologies with low capital and operational costs. This paper presents a method to integrate a new CAES reliability model in the bulk power system reliability evaluation and investigates quantitative benefits derived from the CAES. A state-duration sampling method is adopted for the reliability evaluation. A detailed reliability model of the CAES that considers its actual operating mechanism is first developed. Each system contingency state is then analyzed using a unit commitment (UC) method instead of hourly optimal power flow (OPF). This ensures that the inter-temporal constraints introduced by the CAES, such as its state-of-charge (SOC), are included in the analysis. Case studies are performed on a six-bus test system containing a wind farm and a CAES. The results indicate that the CAES can improve the overall reliability of the system. In particular, the reliability indices of the bus where the CAES is connected show the greatest improvement.

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考虑压缩空气储能的大容量电力系统可靠性评估

大规模储能系统(ess)的集成已被确定为减轻可再生能源(RES)对电力系统运行和可靠性的不利影响的可行选择。目前，压缩空气储能(CAES)是两种投资和运营成本较低的大型储能技术之一。本文提出了一种将CAES可靠性模型集成到大容量电力系统可靠性评估中的方法，并对CAES所带来的量化效益进行了研究。采用状态-持续采样法进行可靠性评估。首先建立了考虑CAES实际运行机制的CAES的详细可靠性模型。然后使用单元承诺(UC)方法而不是每小时最优潮流(OPF)来分析系统的每个应急状态。这确保了CAES引入的跨时间约束，例如其充电状态(SOC)，都包含在分析中。在包含风电场和CAES的六总线测试系统上进行了案例研究。结果表明，CAES可以提高系统的整体可靠性。特别是连接CAES的母线的可靠性指标改善最大。

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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2017 IEEE Electrical Power and Energy Conference (EPEC)

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