大容量SVC相控电抗器对站用低压直流电源的影响分析及防范措施

doi:10.11930/j.issn.1004-9649.202102078

中国电力 ›› 2021, Vol. 54 ›› Issue (12): 45-53.DOI: 10.11930/j.issn.1004-9649.202102078

• 国家“十三五”智能电网重大专项专栏：（九）柔性交流输配电技术 • 上一篇下一篇

大容量SVC相控电抗器对站用低压直流电源的影响分析及防范措施

温才权¹, 全杰雄¹, 周凯², 潘龙斌¹, 李成¹

1. 南方电网超高压输电公司梧州局, 广西梧州 543002;
2. 四川大学电气信息学院, 四川成都 610065

收稿日期:2021-02-23 修回日期:2021-09-24 出版日期:2021-12-05 发布日期:2021-12-16
作者简介:温才权(1986-),男,通信作者,高级工程师,从事变电运行维护研究,E-mail:csgwcq@139.com;全杰雄(1988-),男,工程师,从事变电运行维护研究,E-mail:csgqjx@139.com;周凯(1988-),男,教授,博士生导师,从事高电压与绝缘技术研究,E-mail:zhoukai_scu@163.com;潘龙斌(1971-),男,工程师,从事变电运行维护研究,E-mail:Panlongbin@im.ehv.csg;李成(1987-),男,工程师,从事变电运行维护研究,E-mail:Licheng@im.ehv.csg
基金资助:
南方电网有限公司科技项目（提高二次系统抗干扰性能关键技术研究，CGYKJXM20180555；提高SVC系统运行可靠性关键技术研究，GY2014-2-0009）。

Analysis on Influence of Large Capacity SVC Reactor on Low Voltage DC Power Supply for Station and Preventive Measures

WEN Caiquan¹, QUAN Jiexiong¹, ZHOU Kai², PAN Longbin¹, LI Cheng¹

1. CSG EHV Power Transmission Company Wuzhou Office, Wuzhou 543002, China;
2. School of Electrical Engineering and Information, Sichuan University, Chengdu 610065, China

Received:2021-02-23 Revised:2021-09-24 Online:2021-12-05 Published:2021-12-16
Supported by:
This work is supported by Science and Technology Project of CSG(Research on Key Technology of Improving Anti Jamming Performance of Secondary System, No.CGYKJXM20180555; Research on Key Technology of Improving Operation Reliability of SVC System, No.GY2014-2-0009)

摘要/Abstract

摘要： 大容量静态无功补偿装置（static var compensator，SVC）相控电抗器对站用低压直流电源影响问题特殊且严重。为深入了解SVC对厂站低压直流电源的影响，对某变电站SVC现场设备进行实测，进而对SVC及附近区域建立三维电磁场仿真模型。通过与现场的实测值进行对比，并在实验室建立等比例模型验证仿真的等效性，在此基础上分析在电抗器敷设不同的屏蔽材料对直流电源电能质量改善情况以及带来的衍生问题。结果表明：大型SVC相控电抗器对厂站低压直流电源的影响已超过规程允许值，而敷设硅钢片、铝板、铁板均可有效降低干扰，并且带来的电感变化、发热等情况在可接受范围内。

关键词: 静态无功补偿装置, 直流电源, 电能质量, 保护误动系数, 对地电压偏移系数

Abstract: The influence of phase controlled reactors of a large capacity SVC on the low voltage DC power supply of a power substation can be very serious. In order to understand this influence, field measurement of SVC is carried out in a substation. Furthermore, a three-dimension electromagnetic field simulation model is established for SVC and its adjacent area. A full-scale model is established in the laboratory to verify the equivalence of the simulation results through comparison with the field measurement. An analysis is made on the improvement of DC power quality brought about by different shielding materials and related problems. The results show that the influence of phase controlled reactors of a large capacity SVC on the low voltage DC power supply of a power substation has exceeded the allowable value stipulated by relevant code, and the layout optimization of silicon steel sheet, aluminum plate and iron plate can effectively reduce the interference, and the resulting inductance change and heating are acceptable.

Key words: static var compensator, DC power supply, power quality, risk coefficient for protection malfunction, voltages to ground offset coefficient

温才权, 全杰雄, 周凯, 潘龙斌, 李成. 大容量SVC相控电抗器对站用低压直流电源的影响分析及防范措施[J]. 中国电力, 2021, 54(12): 45-53.

WEN Caiquan, QUAN Jiexiong, ZHOU Kai, PAN Longbin, LI Cheng. Analysis on Influence of Large Capacity SVC Reactor on Low Voltage DC Power Supply for Station and Preventive Measures[J]. Electric Power, 2021, 54(12): 45-53.

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大容量SVC相控电抗器对站用低压直流电源的影响分析及防范措施

Analysis on Influence of Large Capacity SVC Reactor on Low Voltage DC Power Supply for Station and Preventive Measures

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大容量SVC相控电抗器对站用低压直流电源的影响分析及防范措施

Analysis on Influence of Large Capacity SVC Reactor on Low Voltage DC Power Supply for Station and Preventive Measures

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