考虑动态频率约束的含高渗透率光伏电源的孤立电网机组组合

doi:10.19595/j.cnki.1000-6753.tces.151864

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摘要孤立电网具有低惯性及一次调频能力弱的特点,高渗透光伏接入孤立电网后会进一步降低孤立电网惯性及其调频能力。为了保障系统有充足的频率响应能力,本文在UC中考虑动态频率约束,并且通过光伏电源减出力参与调频来增强系统的调频能力。推导考虑光伏电源调频情况下,系统发生故障时最大频降、最大频降出现时间的表达式。基于此,推导了光伏的最小调频容量表达式,用以限制UC在优化过程留有充足但不过量的光伏电源调频容量。根据以上推导建立考虑动态频率约束的含高渗透率光伏电源的孤立电网UC优化模型。针对所提的混合整数非线性优化模型,采用产生Benders割以及优化割的方法来降低问题的求解复杂度。最后采用含高渗透率光伏电源的孤立电网算例进行测试,结果表明所提模型能够兼具安全性和经济性,测试过程也表明了所提求解方法的有效性及优越性。

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	叶婧
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关键词 ：孤立电网, 机组组合, 动态频率, 光伏发电, Benders分解

Abstract：Isolated grid (IG) usually has small inertia constant and limited ability of primary frequency regulation. In addition, high penetration level of photovoltaic power plants (PV-PPS) integrated to IG will deteriorate system inertia and primary frequency regulation ability. To ensure the stability of frequency, unit commitment (UC) model considering dynamic frequency limit (DFL) was proposed in this paper, and PV-PPS were deloaded to participate in frequency regulation. Based on frequency response model with PV-PPS participating in frequency regulation, the expression of required minimum frequency regulation capacity of PV-PPS was deduced, which guided PV-PPS retain sufficient but not excessive capacity. Then, taken DFL into consideration, a UC model with frequency regulation capacity of PV-PPS was proposed. In order to avoid complex solving procedure, the optimization cut and benders cut were used for eliminating frequency limit/regulation capacity violations in iteration method. The results indicate that security and economy can be achieved by the proposed scheme.

Key words： Isolated grid unit commitment dynamic frequency photovoltaic generation Benders decomposition

收稿日期: 2015-11-16 出版日期: 2017-07-19

PACS:

TM732

基金资助:国家自然科学基金重大项目（51190105）,国家自然科学基金（51177111）和太阳能高效利用湖北省协同创新中心重大专项（HBSZD2014003）资助

通讯作者: 林涛男,1969年生,教授,博士生导师,主要从事电力系统运行与控制、电力系统继电保护、电能质量分析与控制等的研究。E-mail: tlin@whu.edu.com

作者简介: 叶婧女,1986年生,博士,主要从事电力系统优化运行等的研究。E-mail: yejing2000310@163.com

引用本文:

叶婧, 林涛, 张磊, 毕如玉, 徐遐龄. 考虑动态频率约束的含高渗透率光伏电源的孤立电网机组组合[J]. 电工技术学报, 2017, 32(13): 194-202. Ye Jing, Lin Tao, Zhang Lei, Bi Ruyu, Xu Xialing. Isolated Grid Unit Commitment with Dynamic Frequency Constraint Considering Photovoltaic Power Plants Participating in Frequency Regulation. Transactions of China Electrotechnical Society, 2017, 32(13): 194-202.

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