特高压直流输电系统接地极引线阻抗监视策略

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摘要为提升特高压直流输电系统接地极引线的故障识别性能,提出一种新的接地极引线阻抗监视策略。对输电线路的全频带阻抗—距离特性进行了理论分析,以此为基础提出了基于高频信号注入的接地极引线阻抗监视策略,并给出了注入信号频率选择原则及故障告警判据。研究表明:若接地极引线长度超过注入信号的1/2波长,金属性接地故障时,阻抗监视装置测量阻抗的虚部随故障距离呈周期性变化,加大了判据整定的难度。因此注入信号频率的选择应保证金属性故障时,线路阻抗随故障距离的增加而单调变化,同时最大的故障阻抗模值应小于线路正常运行时的阻抗,且留有一定裕度。PSCAD仿真验证了该策略的有效性。

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关键词 ：特高压直流输电系统, 接地极引线, 阻抗监视, 阻抗—距离特性, 注入信号频率, 全频带

Abstract：A novel impedance monitoring scheme is proposed in this paper in order to detect faults occurring in the ground electrode lines of ultra high voltage DC (UHVDC) transmission systems reliably and rapidly. Firstly, the theoretical analysis of the full-band impedance vs. distance characteristic of the ground electrode line is carried out. Because a high frequency signal injection-based method is used in the proposed scheme, the principle of determining the frequency of the injection signal is discussed and the criterion of fault alarm are given. The study shows that the imaginary part of the measured impedance has a periodic variation with the distance of the bolted fault when the length of the ground electrode line is larger than half the injection signal’s wave length, which increases the difficulty of setting the criterion. Therefore the selected frequency of the injected signal should ensure that in case of a bolted fault the line impedance changes monotonically with the fault distance, and the modulus value of the maximum fault impedance should be less than that of a normal operation case with a certain margin. Some PSCAD based simulations are performed to verify the proposed scheme. The results show that the faults occur in the ground electrode line can be detected rapidly and reliably, and the proposed scheme has good practice perspective.

Key words： Ultra-high voltage DC transmission system ground electrode line impedance monitoring impedance-distance characteristic frequency of injection signal full frequency range

收稿日期: 2015-04-28 出版日期: 2016-07-12

PACS:

TM77

通讯作者: 王鱼女,1990年生,硕士研究生,研究方向为电力系统继电保护。E-mail:zzzx.fish@stu.xjtu.edu.cn

作者简介: 滕予非男,1984年生,高级工程师,博士,研究方向为电力系统分析与控制。E-mail:yfteng2011@163.com

引用本文:

滕予非,王鱼，焦在滨，张纯,庞广恒. 特高压直流输电系统接地极引线阻抗监视策略[J]. 电工技术学报, 2016, 31(11): 157-164. Teng Yufei Wang Yu Jiao Zaibin Zhang Chun Pang Guangheng. Impedance Monitoring Scheme for Ground Electrode Line of Ultra High Voltage DC Transmission System. Transactions of China Electrotechnical Society, 2016, 31(11): 157-164.

链接本文:

https://dgjsxb.ces-transaction.com/CN/Y2016/V31/I11/157

[1] 李兴源,赵睿,刘天琪,等.传统高压直流输电系统稳定性分析和控制综述[J].电工技术学报,2013,28(10):288-300.
Li Xingyuan,Zhao Rui,Liu Tianqi,et al.Research of conventional high voltage direct current transmission system stability analysis and control[J].Transactions of China Electrotechnical Society,2013,28(10):288-300.
[2] 刘振亚,张启平,董存,等.通过特高压直流实现大型能源基地风、光、火电力大规模高效率安全外送研究[J].中国电机工程学报,2014,34(16):2513-2522.
Liu Zhenya,Zhang Qiping,Dong Cun,et al.Efficient and security transmission of wind,photovoltaic and thermal power of large-scale energy resource bases through UHVDC projects[J].Proceedings of the CSEE,2014,34(16):2513-2522.
[3] Hammons T J,Woodford D,Loughtan M,et al.Role of HVDC transmission in future energy development[J].IEEE Power Engineering Review,2000,20(2):10-25.
[4] 穆子龙,李洪兵,李志勇.基于PID控制和改进粒子群优化算法的特高压直流附加次同步振荡阻尼控制器设计[J] 中国电机工程学报,2014,34(增1):93-99.
Mu Zilong,Li Hongbing,Li Zhiyong.Design of UHVDC supplementary subsynchronous damping controller based on PID control and improved particle swarm optimization algorithm[J].Proceedings of the CSEE,2014,34(S1):93-99.
[5] 陈亦平,程哲,张昆,等.高压直流输电系统孤岛运行调频策略[J].中国电机工程学报,2013,33(4):96-102.
Chen Yiping,Cheng Zhe,Zhang Kun,et al.Frequency regulation strategy for islanding operation of HVDC[J].Proceedings of the CSEE,2013,33(4):96-102.
[6] 魏玥,刘天琪,晏小彬,等.高压直流输电系统直流偏磁下的谐波不稳定判据研究[J].电力系统保护与控制,2014,42(17):139-144.
Wei Yue,Liu Tianqi,Yan Xiaobin,et al.Study of harmonic instability criterion under DC magnetic bias in HVDC system[J].Power System Protection and Control,2014,42(17):139-144.
[7] Chen Fan,Zhang Bo,He Jinliang.Influence of coke bed on HVDC grounding electrode heat dissipation[J].IEEE Transactions on Magnetics,2008,44(6):826-829.
[8] 孙帮新,陈辉祥.高压直流输电共用接地极技术研究[J].高电压技术,2006,32(12):150-153.
Sun Bangxin,Chen Huixiang.Common grounding technique used in the HVDC[J].High Voltage Engineering,2006,32(12):150-153.
[9] 陈凡,何金良,张波,等.共用接地极对云广与贵广II回直流系统的影响[J].高电压技术,2009,35(4):743-748.
Chen Fan,He Jinliang,Zhang Bo,et al.Influence of common grounding electrode on Yunnan-Guangdong DC transmission project and Guizhou-Guangdong II DC transmission project[J].High Voltage Engineering,2009,35(4):743-748.
[10]赵小军,张晓欣,李慧奇,等.基于谐波平衡法的变压器直流偏磁电路-磁路频域耦合模型[J].电工技术学报,2014,29(9):211-218.
Zhao Xiaojun,Zhang Xiaoxin,Li Huiqi,et al.Frequency domain coupled model between magnetic and electric circuit of DC biased transformers by harmonic balance method[J].Transactions of China Electrotechnical Society,2014,29(9):211-218.
[11]Bolduc L,Granger M,Pare G,et al.Development of a DC current blocking device for transformer neutrals[J].IEEE Transactions on Power Delivery,2005,20(1):163-168.
[12]潘超,王泽忠,李海龙,等.基于瞬态场路耦合模型的变压器直流偏磁计算[J].电工技术学报,2013,28(5):174-181.
Pan Chao,Wang Zezhong,Li Hailong,et al.DC-bias calculation for single phase transformers based on transient field-circuit coupled model[J].Transactions of China Electrotechnical Society,2013,28(5):174-181.
[13]朱韬析,欧开健,朱青山,等.直流输电系统接地极过电压保护缺陷分析及改进措施[J].电力系统自动化,2008,32(7):104-107.
Zhu Taoxi,Ou Kaijian,Zhu Qingshan,et al.Analysis of defect in open electric protection of HVDC transmission project[J].Automation of Electric Power Systems,2008,32(7):104-107.
[14]蔡永梁,张楠,冯鸫,等.基于行波原理直流输电系统接地极线路故障测距系统设计[J].南方电网技术,2011,5(2):41-43.
Cai Yongliang,Zhang Nan,Feng Dong,et al.Design of traveling wave based fault location system of HVDC electrode lines[J].Southern Power System Technology,2011,5(2):41-43.
[15]杨光,朱韬析,魏丽君,等.直流输电系统接地极线路故障研究[J].电力系统保护与控制,2009,37(21):45-49.
Yang Guang,Zhu Taoxi,Wei lijun,et al.Research on the faults of electrode line of HVDC transmission system in monopolar ground return operation[J].Power System Protection and Control,2009,37(21):45-49.
[16]成敬周,徐政.直流输电共用接地极线方式的保护特性[J].电力系统自动化,2012,36(14):77-82.
Cheng Jingzhou,Xu Zheng.Protection characteristics of HVDC common grounding electrode lines[J].Automation of Electric Power Systems,2012,36(14):77-82.
[17]肖遥,牛保红,尚春,等.一种快速切除HVDC输电系统接地极线路接地故障的方案[J].电力系统自动化,2009,33(18):107-109.
Xiao Yao,Niu Baohong,Shang Chun,et al.A proposal for fast tripping grounding electrode line fault of HVDC[J].Automation of Electric Power Systems,2009,33(18):107-109.
[18]曾祥君,张玺,阳韬,等.高压直流输电系统接地极不平衡保护改进措施研究[J].电力系统保护与控制,2014,42(24):132-137.
Zeng Xiangjun,Zhang Xi,Yang Tao,et al.Improvement measures of electrodes line unbalance protection for HVDC system[J].Power System Protection and Control,2014,42(24):132-137.
[19]郭剑,朱艺颖.直流输电系统共用接地极的暂态接地性能分析[J].电网技术,2008,32(24):46-49.
Guo Jian,Zhu Yiying.Analysis on transient grounding performance of common grounding electrodes in HVDC system[J].Power System Technology,2008,32(24):46-49.
[20]王磊.PEMO2000接地极线监测特性分析[J].电力建设,2008,29(8):41-43.
Wang Lei.Analysis of ground wire monitoring characteristics of PEMO2000[J].Electric Power Construction,2008,29(8):41-43.
[21]钱龙.直流系统接地极监测与保护分析[D].北京:华北电力大学,2012.
[22]贺家李,葛耀中.超高压输电线故障分析与继电保护[M].北京:科学出版社,1987.
[23]Gunnar A.Electrode line protection:US,5117323[P].1992-03-26.