±1100 kV特高压直流换流站PCOV计算及影响因素分析

doi:10.11930/j.issn.1004-9649.202001102

中国电力 ›› 2021, Vol. 54 ›› Issue (10): 63-71.DOI: 10.11930/j.issn.1004-9649.202001102

• 国家“十三五”智能电网重大专项专栏：（八）直流电网故障电流抑制技术专栏 • 上一篇下一篇

±1100 kV特高压直流换流站PCOV计算及影响因素分析

马江江¹, 齐磊¹, 朱毅²

1. 新能源电力系统国家重点实验室(华北电力大学)，北京 102206;
2. 国网山东省电力公司经济技术研究院，山东济南 250021

收稿日期:2020-01-19 修回日期:2020-07-13 出版日期:2021-10-05 发布日期:2021-10-16
作者简介:马江江(1994-),男,硕士研究生,从事电力系统先进输电技术研究,E-mail:majiangjlw@163.com;齐磊(1978-),男,通信作者,教授,博士生导师,从事先进输电技术及装备、电力系统电磁兼容等研究,E-mail:qilei@ncepu.edu.cn;朱毅(1978-),男,硕士,高级工程师,从事电网规划设计研究工作,E-mail:70337421@qq.com
基金资助:
国家电网有限公司科技项目(特高压直流换流站主设备高频建模及其应用，SGTYHT/17-JS-199)

Calculation and Influencing Factor Analysis of PCOV in ±1 100 kV UHVDC Converter Station

MA Jiangjiang¹, QI Lei¹, ZHU Yi²

1. State Key Laboratory of Alternate Electrical Power System with Renewable Energy Sources (North China Electric Power University), Beijing 102206, China;
2. State Grid Shandong Economics and Technology Research Institute, Jinan 250021, China

Received:2020-01-19 Revised:2020-07-13 Online:2021-10-05 Published:2021-10-16
Supported by:
This work is supported by Science and Technology Project of SGCC (High Frequency Modeling and Application of Main Equipment in UHVDC Converter Station, No.SGTYHT/17-JS-199)

摘要/Abstract

摘要： 含换相过冲的持续运行电压峰值（peak value of the continuous operating voltage, PCOV）是决定换流站直流避雷器参考电压的一个重要参数。针对昌吉—古泉±1100 kV特高压直流工程建立了换流阀、换流变压器、平波电抗器、PLC滤波器等主设备模型，基于±1100 kV特高压换流站系统等效电路模型仿真计算了各类型直流避雷器的PCOV水平。对比公式法计算结果，PCOV水平整体上一致，最大偏差为13.4%，说明公式法计算值仍留有一定的安全裕度。基于所建立的模型进一步对PCOV计算的影响因素进行分析，结果表明，换流阀的阻尼电阻、阻尼电容、饱和电抗器铁芯电感、换流变压器漏感和平波电抗器电感对PCOV计算的影响较大。

关键词: 特高压直流, 换相过冲, 持续运行电压峰值, 直流避雷器

Abstract: The peak value of the continuous operating voltage including commutation overshoot is an important parameter that determines the reference voltage of the DC arrester in the converter station. Based on the Changji-Guquan ±1100 kV UHVDC project, the models of main equipment including converter valve, converter transformer, flat wave reactor and PLC filter are established. The PCOV level of each type of DC arrester is simulated according to the equivalent circuit model of the ±1100 kV UHVDC converter station. Compared with the results calculated by the formula method, the simulated PCOV level is consistent on the whole, with the maximum deviation of 13.4%, indicating that the formula method still has a certain safety margin. Based on the models established in this paper, the influencing factors of PCOV are further analyzed, and the results show that the damping resistance, damping capacitance, the iron inductance of the saturated reactor, the leakage inductance of the converter transformer and the inductance of flat-wave reactor have a great influence on PCOV calculation.

Key words: UHVDC, commutation overshoot, peak value of the continuous operating voltage(PCOV), DC arrester

马江江, 齐磊, 朱毅. ±1100 kV特高压直流换流站PCOV计算及影响因素分析[J]. 中国电力, 2021, 54(10): 63-71.

MA Jiangjiang, QI Lei, ZHU Yi. Calculation and Influencing Factor Analysis of PCOV in ±1 100 kV UHVDC Converter Station[J]. Electric Power, 2021, 54(10): 63-71.

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参考文献

[1] 汤广福, 庞辉, 贺之渊. 先进交直流输电技术在中国的发展与应用[J]. 中国电机工程学报, 2016, 36(7): 1760–1771
TANG Guangfu, PANG Hui, HE Zhiyuan. R & D and application of advanced power transmission technology in China[J]. Proceedings of the CSEE, 2016, 36(7): 1760–1771
[2] 曹昉, 舒雅丽, 李成仁, 等. 基于分类潮流追踪法的特高压输电网损分摊[J]. 中国电力, 2018, 51(7): 54–60
CAO Fang, SHU Yali, LI Chengren, et al. UHV transmission loss allocation based on classified power flow tracing method[J]. Electric Power, 2018, 51(7): 54–60
[3] 董存, 梁志峰, 礼晓飞, 等. 跨区特高压直流外送优化提升新能源消纳能力研究[J]. 中国电力, 2019, 52(4): 41–50
DONG Cun, LIANG Zhifeng, LI Xiaofei, et al. Study on power optimization of the trans-regional UHVDC delivery channels in promoting renewable energy accommodation capacity[J]. Electric Power, 2019, 52(4): 41–50
[4] 郭贤珊, 赵峥, 付颖, 等. 昌吉—古泉±1100 kV特高压直流工程绝缘配合方案[J]. 高电压技术, 2018, 44(4): 1343–1350
GUO Xianshan, ZHAO Zheng, FU Ying, et al. Insulation coordination scheme for ±1 100 kV UHVDC project from Changji to Guquan[J]. High Voltage Engineering, 2018, 44(4): 1343–1350
[5] 郭焕, 温家良, 汤广福, 等. 高压直流输电晶闸管阀关断的电压应力分析[J]. 中国电机工程学报, 2010, 30(12): 1–6
GUO Huan, WEN Jialiang, TANG Guangfu, et al. Analysis of the turn-off voltage stress on HVDC thyristor valve[J]. Proceedings of the CSEE, 2010, 30(12): 1–6
[6] 孙海峰. 换流站换流系统的宽频电路建模方法和应用的研究[D]. 北京: 华北电力大学(北京), 2010.
SUN Haifeng. Research and application of wideband circuit modeling method of converter systems in converter stations[D]. Beijing: North China Electric Power University, 2010.
[7] 周沛洪, 何慧雯, 戴敏, 等. ±1100 kV直流换流站避雷器布置、参数和设备绝缘水平的选择[J]. 高电压技术, 2014, 40(9): 2871–2884
ZHOU Peihong, HE Huiwen, DAI Min, et al. Selection of arresters arrangement, parameters and apparatuses insulation levels for ±1100 kV DC converter station[J]. High Voltage Engineering, 2014, 40(9): 2871–2884
[8] 钱珞江, 李高望, 李存军. UHVDC高端换流变阀侧电压PCOV的一种数字仿真模型[J]. 电力建设, 2015, 36(9): 69–72
QIAN Luojiang, LI Gaowang, LI Cunjun. A PCOV digital simulation model of HV transformer valve side voltage in UHVDC system[J]. Electric Power Construction, 2015, 36(9): 69–72
[9] 高冲, 张静, 周建辉, 等. 基于晶闸管反向恢复电流分段拟合的直流换流阀换相过冲电压计算方法研究[J]. 中国电机工程学报, 2018, 38(2): 547–554, 685
GAO Chong, ZHANG Jing, ZHOU Jianhui, et al. Study on the calculation of the commutation overshoot of HVDC valve based on the piecewise fitting of reverse recovery current of thyristor[J]. Proceedings of the CSEE, 2018, 38(2): 547–554, 685
[10] CHANG W L, SONG B P. Determination of thyristor reverse recovery current parameters[J]. IEEE Proceedings, 1988, 135(2): 91–96.
[11] LEE C, PARK S B. Design of a thyristor snubber circuit by considering the reverse recovery process[J]. IEEE Transactions on Power Electronics, 1988, 3(4): 440–446.
[12] LEE C W, Park S B. An optimum parameter determination for the SCR turnoff model[C]// IEEE International Symposium on Circuits and Systems, Philadelphia, USA, 1987.
[13] 蓝元良, 汤广福, 印永华, 等. 串联晶闸管反向恢复暂态过程的研究[J]. 电网技术, 2006, 30(16): 15–19
LAN Yuanliang, TANG Guangfu, YIN Yonghua, et al. Study on transient of reverse recovery of series thyristors[J]. Power System Technology, 2006, 30(16): 15–19
[14] 汤广福, 贺之渊, 邓占锋. 基于器件物理特性的晶闸管阀串联机制系统化研究[J]. 中国电机工程学报, 2006, 26(12): 39–44
TANG Guangfu, HE Zhiyuan, DENG Zhanfeng. Study on thyristor valve series mechanism based on device physical characteristic[J]. Proceedings of the CSEE, 2006, 26(12): 39–44
[15] FIORILLO F, NOVIKOV A. An improved approach to power losses in magnetic laminations under nonsinusoidal induction waveform[J]. IEEE Transactions on Magnetics, 1990, 26(5): 2904–2910.
[16] SUBBA V. Equivalent circuit of solid iron core for impact excitation problems[J]. Proceedings of IEE, 1964, 111(2): 349–357.
[17] ZHU J G, HUI S Y R. Discrete modeling of magnetic cores including hysteresis eddy current and anomalous losses[J]. IEE Proceedings-A, 1993, 140(4): 317–322.
[18] O’Kelly D. Flux penetration and losses in steel plate with nonsinusoidal magnetization[J]. IEE Proceedings-A, 1988, 135(4): 193–198.
[19] 张文亮, 汤广福. ±800 kV/4 750A特高压直流换流阀宽频建模及电压分布特性研究[J]. 中国电机工程学报, 2010, 30(31): 1–6
ZHANG Wenliang, TANG Guangfu. Study on wide-band model and voltage distribution of 800 kV/4 750 A UHVDC valves[J]. Proceedings of the CSEE, 2010, 30(31): 1–6
[20] 张静. 高压直流输电换流阀电热特性研究[D]. 北京: 中国电力科学研究院, 2009.
ZHANG Jing. Study on the electrothermal properties of HVDC thyristor valve[D]. Beijing: China Electric Power Research Institute, 2009.
[21] 唐义. 特高压直流换流阀集成宽频等效电路模型及其应用研究[D]. 北京: 华北电力大学(北京), 2017.
TANG Yi. UHVDC converter valve integrated wide-band equivalent circuit models and application research[D]. Beijing: North China Electric Power University, 2017.
[22] 王振, 任孟干, 国建宝, 等. 直流输电换流阀晶闸管过电压保护研究[J]. 电力系统保护与控制, 2020, 48(10): 182–187
WANG Zhen, REN Menggan, GUO Jianbao, et al. Research on overvoltage protection of a thyristor on DC converter valves[J]. Power System Protection and Control, 2020, 48(10): 182–187
[23] 常忠廷, 才利存, 徐涛, 等. 基于非对称电压的换流阀暂态低电压运行实验实现方法[J]. 智慧电力, 2019, 47(3): 104–109
CHANG Zhongting, CAI Licun, XU Tao, et al. Implementation method for transient low voltage running test of thyristor valve based on asymmetrical voltage[J]. Smart Power, 2019, 47(3): 104–109
[24] 王延召, 周兵, 张业茂, 等. ±1100 kV换流站交流滤波器场的工频电场仿真[J]. 中国电力, 2019, 52(6): 121–127
WANG Yanzhao, ZHOU Bing, ZHANG Yemao, et al. Simulation of the power frequency electric field in the AC filter area of the HVDC converter station[J]. Electric Power, 2019, 52(6): 121–127
[25] ±800 kV 特高压直流换流站过电压保护和绝缘配合导则: Q/GDW 144—2006 [S].

±1100 kV特高压直流换流站PCOV计算及影响因素分析

Calculation and Influencing Factor Analysis of PCOV in ±1 100 kV UHVDC Converter Station

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±1100 kV特高压直流换流站PCOV计算及影响因素分析

Calculation and Influencing Factor Analysis of PCOV in ±1 100 kV UHVDC Converter Station

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