2025年5月14日 周三
首页 > 过刊浏览>2024年第39卷第2期 >20-27,73. DOI:10.19781/j.issn.1673-9140.2024.02.003
PDF HTML阅读 XML下载 导出引用 引用提醒
基于功率外环附加阻尼控制的柔性直流抑制送端火电机组次同步振荡研究
CSTR:
[cstr]
作者:
作者单位:

(1.国网冀北电力有限公司电力科学研究院,北京 100045;2. 国网天津市电力公司滨海供电分公司,天津 300450;3.华北电力大学电气与电子工程学院,北京 102206)

通讯作者:

肖仕武(1974—),男,博士,副教授,主要从事电力系统稳定与控制、电力系统继电保护等方面的研究;E?mail:xsw@ncepu.edu.com

中图分类号:

TM712

基金项目:

国家自然科学基金(52130709)


Research on subsynchronous oscillation suppression strategy of flexible HVDC with thermal power units based on external loop damping control
Author:
Affiliation:

(1.State Grid Jibei Electric Power Research Institute, Beijing 100045, China; 2.Binhai Power Supply Branch of State Grid Tianjin Electric Power Company,Tianjin 300450, China; 3.School of Electrical and Electronic Engineering, North China Electric Power University, Beijing 102206, China)

  • 摘要
    • | |
  • 访问统计
    • |
  • 参考文献 [24]
    • | | | |
  • 文章评论
    摘要:

    利用柔性直流控制的灵活性抑制次同步振荡被广泛研究,但是对于有功、无功控制回路的抑制效果不同的机理解释很少。针对柔直近区火电机组的次同步振荡问题,提出一种基于功率外环附加阻尼控制的柔直抑制次同步振荡策略。通过对电气阻尼曲线负阻尼频段分析,结合柔直变流器控制特点,选取附加控制的最优位置,通过基于功率外环附加阻尼控制提高火电机组电气阻尼。然后,建立复转矩系数传递函数,分析有功、无功外环附加阻尼控制效果的强弱与柔直功率外环参数相关,主要是与传输有功、无功功率大小有关,揭示柔直功率外环d轴和q轴附加阻尼控制时对电气阻尼影响差异的机理。最后,通过PSCAD时域模型仿真验证分析的正确性。

    Abstract:

    The flexibility of flexible DC control has been widely studied to suppress subsynchronous oscillation, but there is little explanation of the mechanism for the different suppressive effects of active and reactive control loops. Aiming at the subsynchronous oscillation problem of thermal power units in the vicinity of flexible DC, a suppression strategy for subsynchronous oscillation of flexible DC based on additional damping control of the power outer loop is proposed. By analyzing the negative damping frequency band of the electrical damping curve and combining the control characteristics of the flexible DC converter, the optimal position for additional control is selected, and the electrical damping of the thermal power unit is improved through additional damping control based on the power outer loop. Then, a transfer function of the complex torque coefficient is established, and it is analyzed that the damping effect of the active and reactive outer loop with additional damping control is related to the parameters of the power outer loop, mainly related to the transmitted active and reactive power, revealing the mechanism of the difference in the impact of additional damping control on the electrical damping of the d-axis and q-axis of the power outer loop. Finally, the correctness of the analysis is verified through simulation of PSCAD time-domain model.

    参考文献
    [1] 董文凯,任必兴,王海风,等.适用于系统次同步振荡分析的风电场等值建模方法综述[J].电力工程技术,2022,41(4):33-43. DONG Wenkai,REN Bixing,WANG Haifeng,et al.Small-signal equivalent modeling methods of the wind farm and its application in sub-synchronous oscillations analysis of gird-connected wind power systems[J].Electric Power Engineering Technology,2022,41(4):33-43.
    [2] 李大虎,李佳,周悦,等.常规直流送端近区电网中调相机和柔性直流的无功协调控制[J].电力建设,2023,44(12):148-160. LI Dahu,LI Jia,ZHOU Yue,et al.Reactive power-coordinated control of a synchronous condenser and VSC-HVDC in the sending-side near region power grid of an LCC-HVDC[J].Electric Power Construction,2023,44(12):148-160.
    [3] 王杨,王超群,晁苗苗,等.基于同步相量数据幅频特征的次超同步振荡模式辨识[J].电力系统保护与控制,2023,51(19):1-11. WANG Yang,WANG Chaoqun,CHAO Miaomiao,et al.Sub-and super-synchronous oscillation mode identification based on amplitude and frequency characteristics of synchronous phasor data[J].Power System Protection and Control,2023,51(19):1-11.
    [4] 许洪华,邵桂萍,鄂春良,等.我国未来能源系统及能源转型现实路径研究[J].发电技术,2023,43(4):484-491. XU Honghua,SHAO Guiping,E Chunliang,et al.Research on China’s future energy system and the realistic path of energy transformation[J].Power Generation Technology,2023,43(4):484-491.
    [5] 雷傲宇,汪林光,梅勇,等.多端柔性直流电网的中高频振荡特性分析[J].电网与清洁能源,2023,39(7):55-60. LEI Aoyu,WANG Linguang,MEI Yong,et al.An analysis of medium & high-frequency oscillation characteristics in multi-terminal flexible HVDC Networks[J].Power System and Clean Energy,2023,39(7):55-60.
    [6] 尹聪琦,谢小荣,刘辉,等.柔性直流输电系统振荡现象分析与控制方法综述[J].电网技术,2018,42(4):1117-1123. YIN Congqi,XIE Xiaorong,LIU Hui,et al.Analysis and control of the oscillation phenomenon in VSC-HVDC transmission system[J].Power System Technology,2018,42(4):1117-1123.
    [7] [1]刘博昊,肖仕武.柔性直流引发火电机组次同步振荡的电气负阻尼关键因素分析[J/OL].现代电力:1-9[2023-06-07].https://doi.org/10.19725/j.cnki.1007-2322.2022.0347. LIU Bohao,XIAO Shiwu.Key factors analysis of negative electrical damping for sub-synchronous oscillation in thermal power units induced by flexible-HVDC[J/OL].Modern Power:1-9[2023-06-07].https://doi.org/10.19725/j.cnki.1007-2322.2022.0347.
    [8] 杨贵军,莫云晓,龙英云,等.模块化多电平换流器子模块检测技术研究[J].高压电器,2023,59(10):170-178. YANG Guijun,MO Yunxiao,LONG Yingyun,et al.Research on detection technology of sub-model of modular multilevel converter[J].High Voltage Apparatus,2023,59(10):170-178.
    [9] 孙银锋,刘金鑫,梁栋.基于附加改进有源滤波器的柔性直流输电系统高频振荡抑制策略[J].智慧电力,2023,51(10):85-92. SUN Yinfeng,LIU Jinxin,LIANG Dong.High frequency oscillation suppression strategy for flexible HVDC system based on improved active filter[J].Smart Power,2023,51(10):85-92.
    [10] 黄伟煌,李明,郭铸,等.基于小干扰稳定性的多端混合高压直流输电系统控制参数分析与优化方法[J].电网技术,2020,44(8):2941-2949. HUANG Weihuang,LI Ming,GUO Zhu,et al.Control parameter analysis and optimization method of multi-terminal hybrid HVDC transmission system based on small signal stability[J].Power System Technology,2020,44(8):2941-2949.
    [11] 李明节,于钊,许涛,等.新能源并网系统引发的复杂振荡问题及其对策研究[J].电网技术,2017,41(4):1035-1042. LI Mingjie,YU Zhao,XU Tao,et al.Study of complex oscillation caused by renewable energy integration and its solution[J].Power System Technology,2017,41(4):1035-1042.
    [12] Lü J,CAI X,AMIN M,et al.Sub-synchronous oscillation mechanism and its suppression in MMC-based HVDC connected wind farms[J].IET Generation,Transmission & Distribution,2018,12(4):1021-1029.
    [13] 李生虎,叶剑桥,陈东.基于无源控制的DFIG并网次同步控制相互作用抑制策略研究[J].电力系统保护与控制,2023,51(11):77-85. LI Shenghu,YE Jianqiao,CHEN Dong.Passive control strategy to mitigate sub-synchronous control interaction of DFIG-based integrated power systems[J].Power System Protection and Control,2023,51(11):77-85.
    [14] 张学广,邱望明,方冉,等.基于变流器改进控制的双馈风电机组SSO抑制方法[J].电机与控制学报,2020,24(2):1-9. ZHANG Xueguang,QIU Wangming,FANG Ran,et al.SSO mitigation method of DFIG based on improved control of converter[J].Electric Machines and Control,2020,24(2):1-9.
    [15] 顾文,吕万,杨宏宇,等.电力系统次同步振荡的检测技术综述[J].电测与仪表,2022,59(7):9-18. GU Wen,Lü Wan,YANG Hongyu,et al.Review of detection technology of sub-synchronous oscillation in power systems[J].Electrical Measurement & Instrumentation,2022,59(7):9-18.
    [16] 徐友平,张珂,潘晓杰,等.渝鄂背靠背柔性直流附加阻尼控制策略研究[J].电力系统保护与控制,2016,44(18):163-169. XU Youping,ZHANG Ke,PAN Xiaojie,et al.Damping control based on back to back VSC-HVDC connecting Chongqing and Hubei Power Grid[J].Power System Protection and Control,2016,44(18):163-169.
    [17] WANG S J,XU Z,WANG S.New findings on bypass damping filter in increasing subsynchronous resonance damping of series compensated system[J].IET Generation,Transmission & Distribution,2015,9(13):1718-1726.
    [18] 周彦彤,郝丽丽,王昊昊,等.大容量风电场柔直并网系统的送/受端次同步振荡分析与抑制[J].电力自动化设备,2020,40(3):100-106. ZHOU Yantong,HAO Lili,WANG Haohao,et al.Analysis and suppression of SSO at sending/receiving end in VSC-HVDC system connected large-capacity wind farms[J].Electric Power Automation Equipment,2020,40(3):100-106.
    [19] 任健淼,肖仕武.基于频域振荡模式的次/超同步分量可观可控分析[J].电力系统自动化,2023,47(3):30-39. REN Jianmiao,XIAO Shiwu.Observability and controllability analysis of sub-/ super-synchronous components based on frequency domain oscillation mode[J].Automation of Electric Power Systems,2023,47(3):30-39.
    [20] 江桂芬,孙海顺,陈霞,等.宁夏多直流外送系统SSO特性分析及次同步阻尼控制器设计[J].电工技术学报,2017,32(S1):30-38. JIANG Guifen,SUN Haishun,CHEN Xia,et al.SSO characteristic analysis and subsynchronous damping controller design of Ningxia multi-DC transmission system[J].Transactions of China Electrotechnical Society,2017,32(S1):30-38.
    [21] 米季炯.火电机组经柔直系统送出的次同步振荡阻尼特性研究[D].北京:华北电力大学,2021. MI Jijiong.Research on the damping characteristics of the subsynchronous oscillation of thermal power units connected via MMC-HVDC system[D].Beijing:North China Electric Power University,2021.
    [22] HARNEFORS L.Analysis of subsynchronous torsional interaction with power electronic converters[J].IEEE Transactions on Power Systems,2007,22(1):305-313.
    [23] KHAZAEI J,BEZA M,BONGIORNO M.Impedance analysis of modular multi-level converters connected to weak AC grids[J].IEEE Transactions on Power Systems,2018,33(4):4015-4025.
    [24] 鲁晓军,林卫星,安婷,等.MMC电气系统动态相量模型统一建模方法及运行特性分析[J].中国电机工程学报,2016,36(20):5479-5491+5724. LU Xiaojun,LIN Weixing,AN Ting,et al.A unified dynamic phasor modeling and operating characteristic analysis of electrical system of MMC[J].Proceedings of the CSEE,2016,36(20):5479-5491+ 5724.
    相似文献
    引证文献
    网友评论
    网友评论
    分享到微博
    发 布
引用本文

李长宇,刘博昊,肖仕武,等.基于功率外环附加阻尼控制的柔性直流抑制送端火电机组次同步振荡研究[J].电力科学与技术学报,2024,39(2):20-27,73.
LI Changyu, LIU Bohao, XIAO Shiwu, et al. Research on subsynchronous oscillation suppression strategy of flexible HVDC with thermal power units based on external loop damping control[J]. Journal of Electric Power Science and Technology,2024,39(2):20-27,73.

复制
分享
文章指标
  • 点击次数:212
  • 下载次数: 659
  • HTML阅读次数: 0
  • 引用次数: 0
历史
  • 在线发布日期: 2024-05-29
文章二维码

微信公众号二维码

您是本站第 108214 访问者

通信地址:长沙市(天心区)万家丽南路960号长沙理工大学

电话/传真:0731-85258195 E-mail:dlxb04@163.com

版权所有:电力科学与技术学报 ® 2025 版权所有

京公网安备 11010802026262号