基于暂态能量裕度的电力系统脆弱性评估

摘要
图/表
参考文献
相关文章 (1)

全文: PDF (373 KB)
输出: BibTeX | EndNote (RIS)

摘要电力系统暂态失稳是引发系统灾难性事故的一个重要方面, 从暂态稳定角度分析系统的脆弱程度是不可或缺的。电力系统的脆弱水平往往受到天气条件、负荷水平、随机故障的影响, 必须合理考虑这些不确定性因素。本文建立了计及气候因素的故障概率模型, 提出了从暂态能量裕度角度对电力系统脆弱性进行评估的思想。为避免严重程度高但发生概率小的事故被忽略掉, 提出使用概率和能量裕度两个指标来评估系统的脆弱性。借助暂态能量函数定义了事故的能量裕度指标的计算公式, 它能反映负荷水平的影响。利用各事故的脆弱性裕度指标还可以识别系统的薄弱环节。借助概率理论和范数理论, 利用各事故脆弱性的概率指标和能量裕度指标分别推导出计算整个系统综合脆弱性的概率指标和能量裕度指标的模型, 并在此基础上提出了电力系统脆弱性的评估算法。通过算例分析, 本文建立的故障概率模型、提出的系统综合脆弱性指标体系以及评估算法是合理有效的。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	卢锦玲
	朱永利

关键词 ：暂态能量裕度, 电力系统脆弱性, 天气条件, 脆弱性指标, 范数理论

Abstract：Losing transient stability is an important aspect leading to a disastrous accident in a power system, so analysing power system vulnerability from the viewpoint of transient stability is indispensable. The vulnerability level of a system is often affected by weather condition, load demand level and random faults in the system, so these uncertain factors must be reasonably considered. In this paper, contingent faults’ probability models taking the weather factor into account are set up, and the idea of evaluating a power system’s vulnerability based on the system’s transient energy margin is proposed. In order to avoid a serious fault of smaller occurring probability is ignored, the idea of using both probability index and energy margin index to evaluate a system’s vulnerability is put forward. The formula to calculate the energy margin index of a fault is defined based on the transient energy function, which can reflect the influence of load demand change to the system's vulnerability. The weak components in the system can be found by means of energy margin indices relating to faults. Moreover, based on probability theory and Norm theory, the models to calculate compositive probability index and energy margin index of power system are derived. The models’ parameters are probability indices and energy margin indices of all possible faults in the system. Based on the models, an assessing algorithm for a power system vulnerability is proposed. By doing vulnerability analysis of an example power network, the feasibility and effectiveness of the above proposed models and assessing algorithm is proved.

Key words： Transient energy margin power system vulnerability weather condition vulnerability index Norm theory

收稿日期: 2009-01-18 出版日期: 2014-03-04

PACS:

TM712

基金资助:中央高校基本科研业务费专项基金资助项目（09QG06）

作者简介: 卢锦玲女, 1971年生, 博士, 副教授, 研究方向为人工智能在电力系统中的应用等。朱永利男, 1963年生, 教授, 博士生导师, 主要研究方向为人工智能和电网调度自动化。

引用本文:

卢锦玲, 朱永利. 基于暂态能量裕度的电力系统脆弱性评估[J]. 电工技术学报, 2010, 25(6): 96-103. Lu Jinling, Zhu Yongli. Power System Vulnerability Assessment Based on Transient Energy Margin. Transactions of China Electrotechnical Society, 2010, 25(6): 96-103.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2010/V25/I6/96

[1] Taylor C W, Erickson D C. Recording and analyzing the July 2 cascading outage[J]. IEEE Computer Applications in Power, 1999(1): 26-30.
[2] Taylor C W. Improving GRID behavior[J]. IEEE Spectrum, 1999, 18(6): 40-45.
[3] Afouad A, Qin Zhou, Vittalv V. System vulnerability as a concept to assess power system dynamic security[J]. IEEE Trans. on Power Systems, 1994, 9(2): 1009- 1015.
[4] 陈为化, 江全元, 曹一家, 等. 基于风险理论的复杂电力系统脆弱性评估[J]. 电网技术, 2005, 29(4): 12-19.
[5] Qin Zhou, Davidson J. Application of artificial neural networks in power system security and vulnerability assessment[J]. IEEE Trans. on Power Systems, 2002, 9(1): 525-532．
[6] Kamwa I, Béland J, Cnabb D. PMU-based vulnerability assessment using wide-area severity indices and tracking modal analysis[C]. Power Systems Conference and Exposition, Atlanta, USA, 2006.
[7] Yu Xingbin, Singh Chanan. Integrated power system vulnerability analysis considering protection failures[C]. Power Engineering Society General Meeting, IEEE, 2003, 2: 706-711.
[8] Albert R, Albert I, Nakarado G L. Structural vulnerability of the North American power grid[J]. Physical Review E, 2004, 69(2): 025103/1-4.
[9] Zhao L, Park K, Lai Y C. Attack vulnerability of scale-free networks due to cascading breakdown[J]. Physical Review E, 2004, 70(2): 035101/1-4.
[10] 丁明, 韩平平. 加权拓扑模型下的小世界电网脆弱性评估[J]. 中国电机工程学报, 2008, 28(10): 20-25.
[11] 陈晓刚, 孙可, 曹一家. 基于复杂网络理论的大电网结构脆弱性分析[J]. 电工技术学报, 2007, 22(10): 138-144.
[12] Mao Anji, Yu Jiaxi, Guo Zhizhong. Electric power grid structural vulnerability assessment[C]. Power Engineering Society General Meeting, Montreal, Canada, 2006.
[13] 刘玉田, 林非. 基于相量测量技术和模糊径向基网络的暂态稳定性预测[J]. 中国电机工程学报, 2000, 20(2): 19-23.
[14] 袁越, 久保川淳司, 佐佐木博司. 考虑暂态稳定约束的可用传输能力计算[J]. 电力系统自动化, 2004, 28(10): 34-39.
[15] 傅书易, 倪以信, 薛禹胜. 直接法稳定分析[M]. 北京：中国电力出版社, 1999.
[16] 郭晓敏, 韩富春. 基于状态空间法的架空输电线路的可靠性评估[J]. 电气技术, 2006(7): 39-41.
[17] Billinon R, Allan R N. Reliability evaluation of power system[M]. 2nd ed. New York: Plenum, 1996.
[18] 郭永基. 电力系统可靠性分析[M]. 北京：清华大学出版社, 2003.
[19] 李文沅, 卢继平.暂态稳定概率评估的蒙特卡罗方法[J]. 中国电机工程学报, 2005, 25(10): 18-23.