2025年4月15日 周二
首页 > 过刊浏览>2024年第39卷第6期 >43-52. DOI:10.19781/j.issn.1673-9140.2024.06.005
PDF HTML阅读 XML下载 导出引用 引用提醒
基于MC‑MSDARL和PSO‑BA的直流换流站无功控制优化方法
作者:
作者单位:

(1.中国南方电网有限责任公司超高压输电公司柳州局,广西 柳州 545006;2.南京南瑞继保电气有限公司,江苏 南京 211102)

通讯作者:

黄松强(1989—),男,高级工程师,主要从事电力系统稳定分析、直流输电技术研究;E?mail:hsongqiang12@126.com

中图分类号:

TM723

基金项目:

中国南方电网有限责任公司科技项目(CGYKJXM20220102)


Optimization method for reactive power control of DC converter stations based on MC‑MSDARL and PSO‑BA
Author:
Affiliation:

(1.Liuzhou Bureau of EHV Transmission Company,China Southern Power Grid Co., Ltd., Liuzhou 545006, China;2.NR Electric Co., Ltd., Nanjing 211102, China)

  • 摘要
    • | |
  • 访问统计
    • |
  • 参考文献 [35]
    • | | | |
  • 文章评论
    摘要:

    随着直流输电工程规模的不断扩大,交直流互联系统给电网暂态电压恢复带来了一定的挑战。为了解决换流站受电压波动影响导致换流变分接开关频繁动作的问题,提出一种基于多通道融合、多尺度动态自适应残差学习(multi channel fusion and multi?scale dynamic adaptive residual learning, MC?MSDARL)和粒子群蝙蝠算法(particle swarm optimization?bat algorithm, PSO?BA)的直流换流站无功控制优化方法。首先,开展换流站暂态过压特性研究,分析交流滤波器、无功补偿设备以及调相机对暂态过压的影响;然后,通过多尺度动态自适应残差卷积方式动态自动更新卷积核大小,提高模型学习能力,映射直流系统运行状态和电压稳定的关系,构建电压暂态稳定预测模型;最后,建立减小电压波动和降低网络损耗的直流换流站无功控制优化模型,利用PSO?BA进行模型求解。通过PSASP搭建直流电网进行仿真验证,实验结果表明,所提方法提高了电压暂态稳定能力,有效解决了换流变分接开关频繁动作的问题。

    Abstract:

    As the scale of direct current (DC) transmission projects continues to expand, the alternating current (AC)-DC interconnection system has brought certain challenges to the transient voltage recovery capability of the power grid. In order to reduce frequent operations of tap changers of converter transformers caused by voltage fluctuations in converter stations, an optimization method for reactive power control of DC converter stations based on multi-channel fusion and multi-scale dynamic adaptive residual learning (MC-MSDARL) and particle swarm optimization-bat algorithm (PSO-BA) is proposed. Firstly, research is conducted on the transient overvoltage characteristics of the converter stations, and the impact of AC filters, reactive power compensation equipment, and phase-shifting cameras on transient overvoltage is analyzed. Then, the multi-scale dynamic adaptive residual convolution method is used to dynamically update the size of the convolution kernel, improve the model’s learning ability, map the relationship between the operating state of the DC system and voltage stability, and construct a transient voltage stability prediction model. Finally, an optimization model for reactive power control of DC converter stations is established to reduce voltage fluctuations and network losses, and the PSO-BA is used to solve the model. PSASP is employed to build a DC power grid for simulation verification, and the experimental results show that the proposed method improves the transient voltage stability capability and effectively reduces frequent operations of tap changers of converter transformers.

    参考文献
    [1] 马光,张伊宁,陈哲,等.含大规模风电的交直流混联系统风险评估方法[J].电网技术,2019,43(9):3241-3252.MA Guang,ZHANG Yining,CHEN Zhe,et al.Risk assessment method for hybrid AC/DC system with large-scale wind power integration[J].Power System Technology,2019,43(9):3241-3252.
    [2] 李明节.大规模特高压交直流混联电网特性分析与运行控制[J].电网技术,2016,40(4):985-991.LI Mingjie.Characteristic analysis and operational control of large-scale hybrid UHV AC/DC power grids[J].Power System Technology,2016,40(4):985-991.
    [3] 耿世平,余敏,郭晓鹏,等.基于柔性变电站的交直流配电技术经济评估[J].电力科学与技术学报,2022,37(1):140-150.GENG Shiping,YU Min,GUO Xiaopeng,et al.Technical and economic evaluation of AC and DC distribution based on flexible substation[J].Journal of Electric Power Science and Technology,2022,37(1):140-150.
    [4] 陈睿康,李凤婷,尹纯亚,等.基于改进VDCOL的直流系统后续换相失败抑制策略[J].电力工程技术,2022,41(2):2-9. CHEN Ruikang,LI Fengting,YIN Chunya,et al.Suppression strategy for subsequent commutation failure of DC system based on improved VDCOL[J].Electric Power Engineering Technology,2022,41(2):2-9.
    [5] 陈光宇,吴文龙,戴则梅,等.计及故障场景集的风光储混合系统区域无功储备多目标优化[J].电力系统自动化,2022,46(17):194-204.CHEN Guangyu,WU Wenlong,DAI Zemei,et al.Multi-objective optimization of regional reactive power reserve in hybrid system with wind,photovoltaic and energy storage considering fault scenario set[J].Automation of Electric Power Systems,2022,46(17):194-204.
    [6] 莫静山,颜伟,文旭,等.考虑换流站独立控制约束的交直流系统静态无功优化方法[J].电力系统自动化,2021,45(15):77-84.MO Jingshan,YAN Wei,WEN Xu,et al.Optimization method for static reactive power of AC/DC system considering independent control constraints of converter station[J].Automation of Electric Power Systems,2021,45(15):77-84.
    [7] 姜涛,李雪,李国庆,等.含多端柔性直流的交直流电力系统静态电压稳定域构建方法[J].电工技术学报,2022,37(7):1746-1759.JIANG Tao,LI Xue,LI Guoqing,et al.A predictor-corrector algorithm for forming voltage stability region of hybrid AC/DC power grid with inclusion of VSC-MTDC[J].Transactions of China Electrotechnical Society,2022,37(7):1746-1759.
    [8] 郭培,陈波,高云超,等.基于XGBOOST-PSO提高受端电网电压暂态稳定的发电机无功优化方法[J].电力系统保护与控制,2023,51(13):148-158.GUO Pei,CHEN Bo,GAO Yunchao,et al.A generator reactive power optimization method based on XGBOOST-PSO to improve the voltage transient stability of a receiving terminal network[J].Power System Protection and Control,2023,51(13):148-158.
    [9] 艾红杰,黄金海,吴金波,等.陕北?武汉特高压直流输电工程无功控制策略研究[J].电力系统保护与控制,2021,49(14):149-156.AI Hongjie,HUANG Jinhai,WU Jinbo,et al.Reactive power control strategy for the Shanbei-Wuhan UHVDC transmission project[J].Power System Protection and Control,2021,49(14):149-156.
    [10] 秦艳辉,尹纯亚,段青熙,等.直流近区系统故障下的暂态电压特性分析及支撑策略研究[J].电力系统保护与控制,2023,51(17):169-177.QIN Yanhui,YIN Chunya,DUAN Qingxi,et al.Research on transient voltage characteristics and support strategy under a fault occurred in the near-zone of HVDC sending system[J].Power System Protection and Control,2023,51(17):169-177.
    [11] 张艳梅,娄彦涛,孙小平,等.柔性直流输电系统的功率模块涡流损耗及其温升分析[J].高压电器,2023,59(2):69-80. ZHANG Yanmei,LOU Yantao,SUN Xiaoping,et al.Analysis of eddy current loss and temperature rise in power module of VSC-HVDC[J].High Voltage Apparatus,2023,59(2):69-80.
    [12] 贺静波,庄伟,许涛,等.暂态过电压引起风电机组连锁脱网风险分析及对策[J].电网技术,2016,40(6):1839-1844.HE Jingbo,ZHUANG Wei,XU Tao,et al.Study on cascading tripping risk of wind turbines caused by transient overvoltage and its countermeasures[J].Power System Technology,2016,40(6):1839-1844.
    [13] 陈国平,李明节,许涛,等.关于新能源发展的技术瓶颈研究[J].中国电机工程学报,2017,37(1):20-27.CHEN Guoping,LI Mingjie,XU Tao,et al.Study on technical bottleneck of new energy development[J].Proceedings of the CSEE,2017,37(1):20-27.
    [14] 汤奕,郑晨一,楼伯良,等.抑制连续换相失败的直流功率控制策略[J].电网技术,2019,43(10):3514-3522.TANG Yi,ZHENG Chenyi,LOU Boliang,et al.Research on DC power control strategy for mitigating continuous commutation failure[J].Power System Technology,2019,43(10):3514-3522.
    [15] 孙华东,张振宇,林伟芳,等.2011年西北电网风机脱网事故分析及启示[J].电网技术,2012,36(10):76-80.SUN Huadong,ZHANG Zhenyu,LIN Weifang,et al.Analysis on serious wind turbine generators tripping accident in Northwest China power grid in 2011 and its lessons[J].Power System Technology,2012,36(10):76-80.
    [16] 常海军,霍超,刘福锁,等.提高弱送端电网暂态电压稳定水平的调相机优化配置研究[J].电力系统保护与控制,2019,47(6):90-95.CHANG Haijun,HUO Chao,LIU Fusuo,et al.Research on optimal allocation method of synchronous condensers for improving transient voltage stability level of weak sending-end power grid[J].Power System Protection and Control,2019,47(6):90-95.
    [17] 梁贵书,晏阔,高飞,等.变压器混合式有载分接开关熄弧方法的仿真及试验研究[J].高电压技术,2014,40(10):3156-3163.LIANG Guishu,YAN Kuo,GAO Fei,et al.Study on simulation and experiments of method of extinction hybrid on-load tap changer in transformers[J].High Voltage Engineering,2014,40(10):3156-3163.
    [18] BENSLIMANE A,BOUCHNAIF J,ESSOUFI M,et al.Comparative study of semiconductor power losses between CSI-based STATCOM and VSI-based STATCOM,both used for unbalance compensation[J].Protection and Control of Modern Power Systems,2020,5(1):1-14.
    [19] 杨欢欢,朱林,蔡泽祥,等.直流控制对直流系统无功动态特性的影响分析[J].电网技术,2014,38(10):2631-2637.YANG Huanhuan,ZHU Lin,CAI Zexiang,et al.Influence of HVDC control on HVDC reactive power dynamic characteristic[J].Power System Technology,2014,38(10):2631-2637.
    [20] 全少理,郭勇,杨卓,等.基于灵敏度分析的交直流配电网无功补偿策略[J].电力科学与技术学报,2021,36(5):104-112.QUAN Shaoli,GUO Yong,YANG Zhuo,et al.Reactive power compensation strategy for AC/DC hybrid distribution network based on the sensitivity analysis[J].Journal of Electric Power Science and Technology,2021,36(5):104-112.
    [21] 巩伟峥,肖洋,夏潮,等.华东电网调相机AVC控制策略研究[J].电网技术,2020,44(8):3106-3113.GONG Weizheng,XIAO Yang,XIA Chao,et al.Study on AVC control strategy of synchronous condenser in East China grid[J].Power System Technology,2020,44(8):3106-3113.
    [22] 李锴,邵德军,徐友平,等.基于新一代调相机的多目标无功电压协调控制系统研究[J].电网技术,2019,43(8):2961-2967.LI Kai,SHAO Dejun,XU Youping,et al.Research on coordinated multi-objective reactive voltage control system based on new type synchronous condenser[J].Power System Technology,2019,43(8):2961-2967.
    [23] 续昕,张恒旭,李常刚,等.基于轨迹灵敏度的紧急切负荷优化算法[J].电力系统自动化,2016,40(18):143-148.XU Xin,ZHANG Hengxu,LI Changgang,et al.Emergency load shedding optimization algorithm based on trajectory sensitivity[J].Automation of Electric Power Systems,2016,40(18):143-148.
    [24] 赵晋泉,汤建军,吴迪,等.直流馈入受端电网暂态电压与频率稳定紧急协调控制策略[J].电力系统自动化,2020,44(22):45-53.ZHAO Jinquan,TANG Jianjun,WU Di,et al.Emergency coordination control strategy for transient voltage and transient frequency stability in HVDC infeed receiving-end power grid[J].Automation of Electric Power Systems,2020,44(22):45-53.
    [25] 郑超,汤涌,马世英,等.网源稳态调压对暂态无功支撑能力的影响研究[J].中国电机工程学报,2014,34(1):115-122.ZHENG Chao,TANG Yong,MA Shiying,et al.Study on the influence of steady-state voltage regulation schemes on transient reactive power supporting capability[J].Proceedings of the CSEE,2014,34(1):115-122.
    [26] 陈波,熊华强,舒展,等.含同步调相机的直流换流站稳态无功协调控制策略[J].电力自动化设备,2020,40(11):156-164.CHEN Bo,XIONG Huaqiang,SHU Zhan,et al.Steady-state reactive power coordinated control strategy for DC converter station with synchronous condenser[J].Electric Power Automation Equipment,2020,40(11):156-164.
    [27] 王少雄,潘学萍,颜君凯,等.大容量调相机参与下特高压交直流电力系统稳态电压协同控制[J].电力系统保护与控制,2020,48(24):120-127.WANG Shaoxiong,PAN Xueping,YAN Junkai,et al.Coordinated control of steady-state voltage for UHVDC/AC power systems with large-scale synchronous condenser integration[J].Power System Protection and Control,2020,48(24):120-127.
    [28] 马志侠,张林鍹,邱朝洁,等.基于CEEMD-SSA-LSTM的园区综合能源系统两阶段优化调度[J].高电压技术,2023,49(4):1430-1440.MA Zhixia,ZHANG Linxuan,QIU ChaoJie,et al.Two-stage optimal scheduling of the park integrated energy system based on CEEMD-SSA-LSTM[J].High Voltage Engineering,2023,49(4):1430-1440.
    [29] 管霖,黄济宇,蔡锱涵,等.图深度学习技术在电力系统分析与决策领域的应用与展望[J].高电压技术,2022,48(9):3405-3422.GUAN Lin,HUANG Jiyu,CAI Zihan,et al.Application and prospect of graph deep learning technique in power system analysis and decision[J].High Voltage Engineering,2022,48(9):3405-3422.
    [30] ZHANG Y,WANG X N,WANG J H,et al.Deep reinforcement learning based volt-VAR optimization in smart distribution systems[J].IEEE Transactions on Smart Grid,2021,12(1):361-371.
    [31] 蔡昌春,程增茂,张关应,等.基于数据驱动的配电网无功优化[J].电网技术:2018,42(4):1217-1225. CAI Changchun,CHENG Zengmao,ZHANG Guanying,et al.Reactive power optimization of distribution network based on data-driven method[J].Power System Technology,2018,42(4):1217-1225.
    [32] 邵美阳,吴俊勇,石琛,等.基于数据驱动和深度置信网络的配电网无功优化[J].电网技术,2019,43(6):1874-1885.SHAO Meiyang,WU Junyong,SHI Chen,et al.Reactive power optimization of distribution network based on data driven and deep belief network[J].Power System Technology,2019,43(6):1874-1885.
    [33] ZHAO J L,ZHANG Z Q,YU H,et al.Cloud-edge collaboration-based local voltage control for DGs with privacy preservation[J].IEEE Transactions on Industrial Informatics,2023,19(1):98-108.
    [34] LIAO W L,CHEN J J,LIU Q,et al.Data-driven reactive power optimization for distribution networks using capsule networks[J].Journal of Modern Power Systems and Clean Energy,2022,10(5):1274-1287.
    [35] SUN X Z,QIU J,TAO Y C,et al.A multi-mode data-driven volt/var control strategy with conservation voltage reduction in active distribution networks[J].IEEE Transactions on Sustainable Energy,2022,13(2):1073-1085.
    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

黄松强,陈明佳,杨海亮,等.基于MC‑MSDARL和PSO‑BA的直流换流站无功控制优化方法[J].电力科学与技术学报,2024,39(6):43-52.
HUANG Songqiang, CHEN Mingjia, YANG Hailiang, et al. Optimization method for reactive power control of DC converter stations based on MC‑MSDARL and PSO‑BA[J]. Journal of Electric Power Science and Technology,2024,39(6):43-52.

复制
分享
文章指标
  • 点击次数:44
  • 下载次数: 112
  • HTML阅读次数: 0
  • 引用次数: 0
历史
  • 在线发布日期: 2025-02-14
文章二维码

微信公众号二维码

您是本站第 91509 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