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介绍了针对直流输电线路的双端行波法、单端行波法和时域故障分析法等故障测距方法的原理、特点及应用现状。 针对实际工程应用中出现的行波测距法数据来源可靠性相对较低以及时域故障分析法故障测距精度低等问题, 提出了时域故障分析法与行波法相结合的直流输电线路综合故障测距方法。 利用双数据源, 包括高速数据及低速数据, 通过单端行波法/时域法分别计算可能故障点,并利用小波变换模极大值的幅值、极性特征筛选确定故障点,将单端行波测距法的精度优势和时域法测距数据的可靠性优势相结合。 最后通过PSCAD仿真对该方法的有效性进行了验证。
Abstract:This paper introduces the principle, characteristics and application status of various fault location methods for DC transmission lines, including double ended traveling wave method, single ended traveling wave method and time-domain fault analysis method. A comprehensive method for fault location of DC transmission line is proposed in this paper, which combines time domain fault analysis method with traveling wave method, aiming to solve the issues of relatively low reliability of data sources of the traveling wave method and low accuracy of fault location for the time domain method in the practical engineering application. Using dual data sources including high-speed and low-speed data, possible fault points are calculated using single ended traveling wave method/time-domain method, and fault points are determined by filtering the amplitude and polarity characteristics of wavelet transform modulus maximum. The accuracy advantage of single ended traveling wave method is combined with the reliability advantage of time-domain method. Through EMTDC simulation, the validity of the method is verified in this paper.
[1] 葛耀中.新型继电保护与故障测距原理与技术[M].西安:西安交通大学出版社,2007.
[2] H. Cao, Z. Wang. A Novel Whole- line Fast Protection Scheme Based on Single- end Line Current for HVDC Transmission Lines[C]//2022 Asian Conference on Frontiers of Power and Energy (ACFPE). Chengdu: ACFPE, 2022.
[3] O. D. Naidu, A. K. Pradhan. Precise Traveling Wave Based Transmission Line Fault Location Method Using Single- Ended Data[J]. IEEE Transactions on Industrial Informatics, 2021, 17(8): 5197-5207.
[4] 杨林,王宾,董新洲.高压直流输电线路故障测距研究综述[J].电力系统自动化,2018,42(8):185-191. YANG Lin, WANG Bin, DONG Xinzhou. A review of fault location research on high- voltage direct current transmission lines[J]. Automation of Electric Power Systems, 2018, 42(8): 185-191.
[5] 束洪春,杨竞及,张广斌.高压直流输电线路的双端行波频差比值故障测距[J].中国电机工程学报,2022,42(18):6715-6727. SHU Hongchun, YANG Jingji, ZHANG Guangbin. Fault Location of Double Terminal Traveling Wave Frequency Difference Ratio in High Voltage Direct Current Transmission Lines[J]. Proceedings of the CSEE, 2022, 42(18): 6715-6727.
[6] X. Yu, X. Wu, F. Zhu, et al. A Pilot Direction Protection Based on Transient Voltage for HVDC Transmission Lines[C]// 20238th Asia Conference on Power and Electrical Engineering (ACPEE). Tianjin: ACPEE, 2023.
[7] 刘杰.基于改进双端行波法的特高压输电线路故障定位方法研究[J].东北电力技术,2023,44(6):11-15. LIU Jie. Research on Fault Location Method of UHV Transmission Line Based on Improved Double-Ended Traveling Wave Method[J]. Northeast Electric Power Technology, 2023, 44(6): 11-15.
[8] 王炜,王全金,尹力,等.基于零模行波波速量化的高压输电线路双端故障定位方法[J].电力自动化设备,2022,42(12):165-170. WANG Wei, WANG Quanjin, YIN Li, et al. A fault location method for high-voltage transmission lines based on zero mode traveling wave velocity quantization[J]. Electric Power Automation Equipment, 2022, 42(12): 165-170.
[9] LOPES F V, DANTAS K M, SILVA K M, et al. Accuratetwo- terminal transmission line fault location usingtraveling waves[J]. IEEE Transactions on Power Delivery, 2018, 33(2): 873-880.
[10] 邢鲁华.高压直流输电线路保护与故障测距原理研究[D].济南:山东大学,2014.
[11] 赵妍卉.HVDC输电线路行波故障定位方法的研究[D].武汉:华中科技大学,2006.
[12] C. Zhang, G. Song, T. Wang, et al. Single- Ended Traveling Wave Fault Location Method in DC Transmission Line Based on Wave Front Information[J]. IEEE Transactions on Power Delivery 2019, 34(5): 2028-2038.
[13] A. Burek, P. Balcerek, M. Smolana, et al. Modern single-ended fault locationin HVDC systems based on fault transients[C]// 2019 Modern Electric Power Systems (MEPS). Wroclaw: 2019: 1-6.
[14] Imani, Amir, Z. Moravej, et al. A novel time- domain method for fault detection and classification in VSC- HVDC transmission lines[J]. International Journal of Electrical Power& Energy Systems, 2022(140): 108056.
[15] 朱超,任艳霞.电力电缆故障暂态信息测量技术研究[J].电力科技与环保,2017,33(1):51-52. ZHU Chao, REN Yanxia. Research on transient information measurement technology cable fault[J]. Electric Power Environmental Protection, 2017, 33(1): 51-52.
[16] 王海港,谢民,孙月琴,等.输电线路双端故障测距时域算法实用研究[J].电力系统保护与控制,2016,44(22):142-147. WANG Haigang, XIE Min, SUN Yueqin, et al. Practical research on time- domain algorithm for fault location of dual terminal transmission lines[J]. Power System Protection and Control, 2016, 44(22): 142-147.
[17] 李洪波.超高压直流输电线路故障测距原理研究及软件开发[D].天津:天津大学,2009.
[18] J. Zhang, Z. Gao, X. Xie, et al. Fault location of HVDC transmission line based on improved genetic algorithm[C]// 2019 IEEE 8th International Conference on Advanced Power System Automation and Protection (APAP). Xi'an: IEEE, 2019: 186-190.
[19] 宋国兵,蔡新雷,高淑萍,等.高压直流输电线路故障定位研究综述[J].电力系统保护与控制,2012,40(5):133-137. SONG Guobing, CAI Xinlei, GAO Shupong, et al. Survey of fault location research for HVDC transmission lines[J]. Power System Protection and Control, 2012, 40(5): 133-137.
[20] 曹赟,姚方,文福拴.基于微型同步相量测量单元的配电网单相接地故障定位[J].分布式能源,2022,7(1):20-27. CAO Yun, YAO Fang, WEN Fushuan. Distribution Network Single-Phase Grounding Fault Location Based on Micro-Phasor Measurement Units[J]. Distributed Energy, 2022, 7(1): 20-27.
[21] 黄家裕,陈礼义,孙德昌.电力系统数字仿真[M].北京:中国电力出版社,1995:141-146.
[22] S. Lin, L. Liu, P. Sun, et al. Fault Location Algorithm Based on Characteristic- Harmonic Measured Impedance for HVDC Grounding Electrode Lines[J]. IEEE Transactions on Instrumentation and Measurement, 2020, 69(12): 9578-9585.
[23] 刘玥君,张新语,郭峻菘,等.输电线路在冰风荷载作用下的可靠性研究[J].东北电力大学学报,2020,40(5):63-68. LIU Yuejun, ZHANG Xinyu, GUO Junsong, et al. Study on the Reliability of Electric Transmission Line under Ice Load and Wind LoadJournal of Northeast Electric Power University, 2020, 40(5): 63-68.
[24] 国网四川省电力公司电力科学研究院.基于双数据源的直流输电线路故障测距法:CN201710112788.9[P].2019-08-13.
基本信息:
DOI:10.19929/j.cnki.nmgdljs.2024.0042
中图分类号:
引用信息:
[1]阚光强1,杨勇波2,鲜永辉1.基于双数据源的直流输电线路故障测距方法[J].内蒙古电力技术,2024,42(03):68-73.DOI:10.19929/j.cnki.nmgdljs.2024.0042.
基金信息:
湖南省自然科学基金青年项目“新型磁场可调整子轴向励磁高速永磁飞轮储能电机研究”(2021JJ40099)