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【目的】针对高压柔性直流(柔直)输电系统中和应涌流暂态冲击引发换流器保护动作而停运的问题,【方法】首先阐述和应涌流的产生机理,然后对不同并网电压电流采集控制方式下换流器运行受和应涌流的影响特性进行研究。在此基础上,提出一种基于网侧-阀侧控制模式切换的和应涌流下换流器暂态冲击抑制方法。最后在MATLAB/Simulink软件中搭建实际工程的电磁暂态模型进行仿真验证。【结果】仿真结果表明,不同采集控制方式会显著影响和应涌流下换流器的暂态电气特性。【结论】相比于网侧采集控制方式,所提出的阀侧采集控制方法可大幅降低换流器受和应涌流的扰动影响,换流器桥臂电流峰值和子模块电容电压波动分别减小40%和67%,有助于柔直换流器安全平稳运行。
Abstract:[Objective]In order to address the issue of shutdowns caused by converter protection actions due to inrush currents and transient impulses in high-voltage flexible direct current(HVDC) transmission systems, [Methods]first, the generation mechanism of inrush currents was explained. Then, the impact characteristics of inrush currents on the operation of modular multilevel converter(MMC) under different grid voltages and current collection control method were investigated. Based on this, a transient impulse suppression method for MMC under inrush currents was proposed, which involved switching between the grid-side and valve-side control modes. Finally, an electromagnetic transient model of the actual engineering system was built in MATLAB/Simulink for simulation verification.[Results]The simulation result demonstrated that different collection control method had a significant impact on the transient electrical characteristics of MMC under inrush currents.[Conclusion]Compared to the grid-side control method, the proposed valve-side collection control method significantly reduces the disturbance impact of inrush currents on the converter. The peak current in the converter bridge arm and the voltage fluctuation of the submodule capacitor decrease by 40% and 67%, respectively, which can ensure the safe and stable operation of the flexible HVDC converter.
[1] 周业荣,李相锐,绳博宇,等.水风光蓄互补发电系统中风光容量配置研究[J].水利水电技术(中英文),2023,54(11):1-14.ZHOU Yerong,LI Xiangrui,SHENG Boyu,et al.Study of wind-photovoltaic optimal capacity configuration in hydro-wind-photovoltaic-pumped storage complementary power generation system[J].Water Resources and Hydropower Engineering,2023,54(11):1-14.
[2] 常宝真,罗萍萍,林济铿.高光伏渗透率配电网的电压协调控制策略研究[J].水利水电技术(中英文),2023,54(10):203-212.CHANG Baozhen,LUO Pingping,LIN Jikeng.Research of voltage coordinated control strategy of high photovoltaic penetration distribution network[J].Water Resources and Hydropower Engineering,2023,54(10):203-212.
[3] 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 Z Y,ZHANG Q P,DONG C,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.
[4] 汤广福,贺之渊,庞辉.柔性直流输电工程技术研究、应用及发展[J].电力系统自动化,2013,37(15):3-14.TANG G F,HE Z Y,PANG H.Research,application and development of VSC-HVDC engineering technology[J].Automation of Electric Power Systems,2013,37(15):3-14.
[5] 汤广福,贺之渊,滕乐天,等.电压源换流器高压直流输电技术最新研究进展[J].电网技术,2008,32(22):39-44.TANG G F,HE Z Y,TENG L T,et al.New progress on HVDC technology based on voltage source converter[J].Power System Technology,2008,32(22):39-44.
[6] 郭贤珊,周杨,梅念,等.张北柔直电网的构建与特性分析[J].电网技术,2018,42(11):3698-3707.GUO X S,ZHOU Y,MEI N,et al.Construction and characteristic analysis of Zhangbei flexible DC grid[J].Power System Technology,2018,42(11):3698-3707.
[7] 李生虎,李璐璐,陶帝文,等.计及子模块的双极MMC-HVDC可靠性及灵敏度分析[J].电力系统及其自动化学报,2023,35(5):129-137.LI S H,LI L L,TAO D W,et al.Reliability and sensitivity analysis of bipolar MMC-HVDC considering sub-modules[J].Proceedings of the CSU-EPSA,2023,35(5):129-137.
[8] 何炎,李周,李亚州,等.基于真双极接线的VSC-MTDC系统功率转代策略[J].电力系统自动化,2017,41(19):95-101.HE Y,LI Z,LI Y Z,et al.Power conversion strategy of VSC-MTDC system based on real bipolar wiring mode[J].Automation of Electric Power Systems,2017,41(19):95-101.
[9] 戚宣威,尹项根,张哲,等.变压器空投导致相邻元件差动保护误动分析及防范措施[J].电力系统自动化,2016,40(3):129-134.QI X W,YIN X G,ZHANG Z,et al.Analysis on mal-operation for current differential protection due to adjacent transformer switching-on and its countermeasures[J].Automation of Electric Power Systems,2016,40(3):129-134.
[10] QI X W,YIN X G,ZHANG Z,et al.Study on the unusual misoperation of differential protection during transformer energization and its countermeasure[J].IEEE Transactions on Power Delivery,2016,31(5):1998-2007.
[11] 郑伟,张楠,周全.和应涌流导致直流闭锁极保护误动作分析[J].电力系统自动化,2013,37(11):119-124.ZHENG W,ZHANG N,ZHOU Q.Analysis of DC blocked pole protection misoperation caused by sympathetic inrush current[J].Automation of Electric Power Systems,2013,37(11):119-124.
[12] 黄科峰.南澳柔性直流输电系统启动中电压跌落原因分析及抑制措施研究[D].广州:华南理工大学,2018.HUANG K F.Reason Analysis of Voltage Drop in the Process of Charging Startup of Nan’ao HVDC Flexible Transmission System and Suppression Measures Study[D].Guangzhou:South China University of Technology,2018.
[13] 毕大强,王祥珩,李德佳,等.变压器和应涌流的理论探讨[J].电力系统自动化,2005,29(6):1-8.BI Daqiang,WANG Xiangheng,LI Dejia,et al.Theory analysis of the sympathetic inrush in operating transformers[J].Automation of Electric Power Systems,2005,29(6):1-8.
[14] 司马文霞,刘永来,杨鸣,等.考虑铁心深度饱和的单相双绕组变压器改进π模型[J].中国电机工程学报,2018,38(24):7131-7140.SIMA W X,LIU Y L,YANG M,et al.An improved π model for single-phase two winding transformers considering deep saturation of the iron core[J].Proceedings of the CSEE,2018,38(24):7131-7140.deep saturation of the iron core[J].Proceedings of the CSEE,2018,38(24):7131-7140.
[15] SIMA W X,PENG D X,YANG M,et al.Reversible wideband hybrid model of two-winding transformer including the core nonlinearity and EMTP implementation[J].IEEE Transactions on Industrial Electronics,2021,68(4):3159-3169.
[16] 王奕,戚宣威,罗航,等.复杂和应涌流及其对电流差动保护的影响[J].电力系统自动化,2014,38(6):98-105.WANG Y,QI X W,LUO H,et al.Complex sympathetic inrush and its influence on current differential protection[J].Automation of Electric Power Systems,2014,38(6):98-105.
[17] JIN N,XING J W,LIN X N,et al.Countermeasure on preventing line zero-sequence overcurrent protection from mal-operation due to magnetizing inrush[J].IEEE Transactions on Power Delivery,2020,35(3):1476-1487.
[18] 谷君,郑涛,肖仕武,等.基于时差法的Y/Δ接线变压器和应涌流鉴别新方法[J].中国电机工程学报,2007,27(13):6-11.GU Jun,ZHENG Tao,XIAO Shiwu,et al.A new algorithm based on time differential method to identify sympathetic inrush of transformers connected in Wye-delta mode[J].Proceedings of the CSEE,2007,27(13):6-11.
[19] 毕大强,孙叶,王祥珩,等.非饱和区等效瞬时电感在判别变压器和应涌流中的应用研究[J].电力设备,2008(4):21-24.BI D Q,SUN Y,WANG X H,et al.Application of equivalent instantaneous inductance in nonstaturation zone to identify the sympathetic inrush in transformer[J].Electrical Equipment,2008(4):21-24.
[20] BAOMING G,DE ALMEIDA A T,QIONGLIN Z,et al.An equivalent instantaneous inductance-based technique for discrimination between inrush current and internal faults in power transformers[J].IEEE Transactions on Power Delivery,2005,20(4):2473-2482.
[21] ZHAO Y C,CROSSLEY P.Countermeasure to prevent the incorrect blocking of differential protection applied to converter transformers[J].IEEE Transactions on Power Delivery,2020,35(1):95-105.
[22] CHEN Z W,LI H N,DONG X F,et al.Magnetizing inrush current elimination strategy based on a parallel type asynchronous closing hybrid transformer[J].IEEE Transactions on Power Electronics,2023,38(1):931-943.
[23] JAZEBI S,DOGAN R,KOVAN B,et al.Reduction of inrush currents in toroidal transformers by sector winding design[J].IEEE Transactions on Power Electronics,2016:1.
[24] PAN Y L,YIN X G,ZHANG Z,et al.Three-phase transformer inrush current reduction strategy based on prefluxing and controlled switching[J].IEEE Access,2021,9:38961-38978.
[25] CANO-GONZáLEZ R,BACHILLER-SOLER A,ROSENDO-MACíAS J A,et al.Inrush current mitigation in three-phase transformers with isolated neutral[J].Electric Power Systems Research,2015,121:14-19.
[26] ZHANG S,YAO C G,ZHAO X Z,et al.Improved flux-controlled VFCV strategy for eliminating and measuring the residual flux of three-phase transformers[J].IEEE Transactions on Power Delivery,2020,35(3):1237-1248.
[27] KOVAN B,DE LEON F,CZARKOWSKI D,et al.Mitigation of inrush currents in network transformers by reducing the residual flux with an ultra-low-frequency power source[J].IEEE Transactions on Power Delivery,2011,26(3):1563-1570.
[28] 陈志伟,董小飞,丁国成,等.不考虑剩磁非同步合闸技术的混合变压器励磁涌流治理策略研究[J].中国电机工程学报,2022,42(13):4982-4992.CHEN Z W,DONG X F,DING G C,et al.Research on excitation inrush current management strategy of hybrid transformer without considering remanence asynchronous closing technology[J].Proceedings of the CSEE,2022,42(13):4982-4992.
[29] CHEN Z W,HE Y X,DING G C,et al.Magnetic flux bias compensation based on voltage injection method with an auxiliary DC/DC converter[J].IEEE Transactions on Industrial Electronics,2023,70(9):8698-8708.
[30] MA S M,LIN X N,LI Z T,et al.A system-level suppression method for DC bias based on reverse unbalanced currents in the same transmission section[J].IEEE Access,2021,9:126967-126975.
[31] 李晓华,张冬怡,丁晓兵,等.换流变压器和应涌流的正序二次谐波特性分析[J].电力系统自动化,2018,42(13):202-207.LI X H,ZHANG D Y,DING X B,et al.Analysis on positive-sequence second harmonic characteristic of sympathetic inrush current for converter transformer[J].Automation of Electric Power Systems,2018,42(13):202-207.
[32] 袁宇波,李德佳,陆于平,等.变压器和应涌流的物理机理及其对差动保护的影响[J].电力系统自动化,2005,29(6):9-14.YUAN Y B,LI D J,LU Y P,et al.Physical mechanism of sympathetic inrush of transformer and its influence on differential protection[J].Automation of Electric Power Systems,2005,29(6):9-14.
基本信息:
DOI:10.13928/j.cnki.wrahe.2025.06.015
中图分类号:TM721.1
引用信息:
[1]李雨,卢毅,雷鸣,等.柔直换流器和应涌流影响特性分析及暂态冲击抑制方法研究[J].水利水电技术(中英文),2025,56(06):174-183.DOI:10.13928/j.cnki.wrahe.2025.06.015.
基金信息:
国网冀北电力有限公司科技项目(52018K22001C); 国家自然科学基金项目(52207219)
2024-08-29
2024-08-29
2024-08-29