2025年4月3日 周四
首页 > 过刊浏览>2024年第39卷第5期 >226-234. DOI:10.19781/j.issn.1673-9140.2024.05.023
PDF HTML阅读 XML下载 导出引用 引用提醒
电网不平衡下基于MMC的分数阶积分滑模控制策略研究
作者:
作者单位:

(1.上海电力大学自动化工程学院,上海 200090;2.上海太阳能工程技术研究中心有限公司,上海 310012;3.国网浙江省电力有限公司余姚市供电公司,江苏 余姚 315400)

通讯作者:

杨旭红(1969—),女,博士,教授,主要从事智能电网控制技术、新能源发电及储能技术、火电和核电机组的仿真建模及控制技术等方面的研究;E?mail: yangxuhong.sh@163.com

中图分类号:

TM46;TP273

基金项目:

国家自然科学基金(51777120)


Fractional‑order integral sliding mode control strategy based on MMC under unbalanced grid conditions
Author:
Affiliation:

(1.School of Automatic Engineering, Shanghai University of Electric Power, Shanghai 200090, China; 2.Shanghai Solar Energy Engineering Technology Research Center Co., Ltd., Shanghai 310012, China; 3.Yuyao Power Supply Company, State Grid Zhejiang Electric Power Co., Ltd., Yuyao 315400, China)

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

    为增强模块化多电平换流器(modular multilevel converter, MMC)在电网不平衡条件下的系统性能,该文提出一种分数阶积分滑模控制 (fractional order integral sliding mode control,FO?I?SMC)策略。首先,分析MMC的拓扑结构,并推导出正、负序电压与输出电流的基频外特性方程和正负零序环流的二倍频内特性方程。其次,结合控制目标和MMC的数学模型,设计出应用于电网电压不平衡的分数阶滑模控制器。该控制器旨在降低交流侧输出电流与直流侧环流谐波含量。最后,在MATLAB/Simulink仿真平台建立相应模型,验证该算法的有效性。研究结果证明:采用FO?I?SMC控制策略的MMC的系统性能要明显优于采用比例积分(proportional integral, PI)控制策略和积分滑模控制(integral sliding mode control, ISMC)策略的。

    Abstract:

    To enhance the system performance of the modular multilevel converter (MMC) under unbalanced grid conditions, this paper proposes a fractional order integral sliding mode control (FO-I-SMC) strategy. Firstly, the topology of the MMC is analyzed, and the fundamental frequency external characteristic equations of positive- and negative-sequence voltages and output currents, as well as the double frequency internal characteristic equations of positive-, negative-, and zero-sequence circulating currents, are derived. Secondly, combining the control objectives with the mathematical model of the MMC, a fractional order sliding mode controller is designed for application in unbalanced grid voltages. This controller aims to reduce the harmonic content in the AC-side output current and the DC-side circulating current. Finally, a corresponding model is established on the Matlab/Simulink simulation platform to verify the effectiveness of the proposed algorithm. The research results demonstrate that the system performance of the MMC using the FO-I-SMC strategy is significantly better than that using the proportional integral (PI) control strategy and the integral sliding mode control (ISMC) strategy.

    参考文献
    [1] 李宇泽,齐峰,朱英伟,等.多能互补综合能源电力系统的建设模式初探[J].电力科学与技术学报,2019,34(1):3-10. LI Yuze,QI Feng,ZHU Yingwei,et al.A preliminary investigation on construction modes of a multi-energy complementary integrated energy system[J].Journal of Electric Power Science and Technology,2019,34(1):3-10.
    [2] 李冠宏,路茂增,边敦新,等.基于三次谐波电压注入的扩展混合型MMC运行区域的控制方法[J].电测与仪表,2023,60(8):164-170. LI Guanhong,LU Maozeng,BIAN Dunxin,et al.Third harmonic voltage injection based control method with expanding the operation area of hybrid MMC[J].Electrical Measurement & Instrumentation,2023,60(8):164-170.
    [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] 李道强,龚建荣,李忠憓,等.电力市场环境下的差价合约电量分解问题[J].电力科学与技术学报,2020,35(1):40-49. LI Daoqiang,GONG Jianrong,LI Zhonghui,et al.Decomposition of an electrical energy contract for difference in electricity market environment[J].Journal of Electric Power Science and Technology,2020,35(1):40-49.
    [5] 晁武杰,唐志军,林国栋,等.基于桥臂电抗器耦合的MMC-HVDC系统故障过流抑制方法[J].电测与仪表,2023,60(12):111-116. CHAO Wujie,TANG Zhijun,LIN Guodong,et al.Fault over-current suppression method for MMC-HVDC system based on bridge arm reactor coupling[J].Electrical Measurement & Instrumentation,2023,60(12):111-116.
    [6] 文劲宇,周博,魏利屾.中国未来电力系统储电网初探[J].电力系统保护与控制,2022,50(7):1-10. WEN Jinyu,ZHOU Bo,WEI Lishen.Preliminary study on an energy storage grid for future power system in China[J].Power System Protection and Control,2022,50(7):1-10.
    [7] 张沈习,王丹阳,程浩忠,等.双碳目标下低碳综合能源系统规划关键技术及挑战[J].电力系统自动化,2022,46(8):189-207. ZHANG Shenxi,WANG Danyang,CHENG Haozhong,et al.Key technologies and challenges of low-carbon integrated energy system planning for carbon emission peak and carbon neutrality[J].Automation of Electric Power Systems,2022,46(8):189-207.
    [8] 杨洁,吴志强,范宏.基于实时电价的含储能可再生能源系统协同调度策略[J].智慧电力,2023,51(4):46-53. YANG Jie,WU Zhiqiang,FAN Hong.Collaborative scheduling strategy for renewable energy systems with energy storage based on real time price[J].Smart Power,2023,51(4):46-53.
    [9] 陈海荣,徐政.基于同步坐标变换的VSC-HVDC暂态模型及其控制器[J].电工技术学报,2007,22(2):121-126. CHEN Hairong,XU Zheng.Transient model and controller design for VSC-HVDC based on synchronous reference frame[J].Transactions of China Electrotechnical Society,2007,22(2):121-126.
    [10] GUAN M Y,XU Z.Modeling and control of a modular multilevel converter-based HVDC system under unbalanced grid conditions[J].IEEE Transactions on Power Electronics,2012,27(12):4858-4867.
    [11] BERGNA-DIAZ G,ZONETTI D,SANCHEZ S,et al.PI passivity-based control of modular multilevel converters for multi-terminal HVDC systems[C]//2017 IEEE 18th Workshop on Control and Modeling for Power Electronics(COMPEL).Stanford,CA,USA.IEEE,2017:1-8.
    [12] 程启明,孙伟莎,程尹曼,等.电网电压不平衡下MMC的无源控制策略[J].电力自动化设备,2019,39(4):78-85. CHENG Qiming,SUN Weisha,CHENG Yinman,et al.Passive control strategy of MMC under unbalanced grid voltage[J].Electric Power Automation Equipment,2019,39(4):78-85.
    [13] 宋平岗,吴继珍,邹欢.不平衡电网电压下MMC的比例降阶谐振控制策略[J].电测与仪表,2017,54(2):38-45. SONG Pinggang,WU Jizhen,ZOU Huan.Proportional reduced order resonant control strategy for MMC under unbalanced grid voltage conditions[J].Electrical Measurement & Instrumentation,2017,54(2):38-45.
    [14] 年珩,程鹏.电网电压不平衡时PWM整流器的谐振直接功率控制策略[J].电工技术学报,2013,28(11):86-94. NIAN Heng,CHENG Peng.Resonant based direct power control strategy for PWM rectifier under unbalanced grid voltage condition[J].Transactions of China Electrotechnical Society,2013,28(11):86-94.
    [15] 孙伟莎,程启明,程尹曼,等.不平衡电网电压下MMC滑模变结构控制策略[J].太阳能学报,2020,41(9):310-317. SUN Weisha,CHENG Qiming,CHENG Yinman,et al.Mmc control strategy based on sliding mode variable structure under unbalanced grid voltage[J].Acta Energiae Solaris Sinica,2020,41(9):310-317.
    [16] TU Q R,XU Z,HUANG H Y,et al.Parameter design principle of the arm inductor in modular multilevel converter based HVDC[C]//2010 International Conference on Power System Technology.Hangzhou.IEEE,2010:1-6.
    [17] LI B B,XU Z G,SHI S L,et al.Comparative study of the active and passive circulating current suppression methods for modular multilevel converters[J].IEEE Transactions on Power Electronics,2018,33(3):1878-1883.
    [18] 吴冬晖.基于PIR控制的MMC环流抑制策略[J].兰州文理学院学报(自然科学版),2021,35(1):77-81. WU Donghui.MMC circulation suppression strategy based on PIR control[J].Journal of Lanzhou University of Arts and Science (Natural Science),2021,35(1):77-81.
    [19] 杨晓峰,李泽杰,郑琼林.基于虚拟阻抗滑模控制的MMC环流抑制策略[J].中国电机工程学报,2018,38(23):6893-6904+7123. YANG Xiaofeng,LI Zejie,ZHENG Qionglin.A novel MMC circulating current suppressing strategy based on virtual impedance sliding mode control[J].Proceedings of the CSEE,2018,38(23):6893-6904+7123.
    [20] 杨旭红,方浩旭,贾巍.基于分数阶滑模控制的直接矩阵变换器控制策略研究[J].电力系统保护与控制,2022,50(19):158-166. YANG Xuhong,FANG Haoxu,JIA Wei.Research on fractional-order sliding-mode control of a direct matrix converter[J].Power System Protection and Control,2022,50(19):158-166.
    [21] 秦明皇,陶栩,佃松宜,等.伺服电机速度的分数阶滑模容错控制[J].空间控制技术与应用,2022,48(4):86-95. QIN Minghuang,TAO Xu,DIAN Songyi,et al.Fractional sliding mode fault-tolerant control of speed for servo motor[J].Aerospace Control and Application,2022,48(4):86-95.
    [22] 雷城,蓝益鹏,孙云鹏.直线同步电动机磁悬浮系统的模糊分数阶滑模控制[J].电机与控制学报,2022,26(3):94-100. LEI Cheng,LAN Yipeng,SUN Yunpeng.Fuzzy fractional sliding mode control of magnetic levitation system of linear synchronous motors[J].Electric Machines and Control,2022,26(3):94-100.
    [23] 熊林云,王杰.永磁同步电机电能质量分数阶滑模控制[J].中国电机工程学报,2019,39(10):3065-3075. XIONG Linyun,WANG Jie.Fractional order sliding mode control of PMSG wind turbine for power quality enhancement[J].Proceedings of the CSEE,2019,39(10):3065-3075.
    [24] 杨博,THIDAR Swe,钟林恩,等.并网光伏逆变器鲁棒分数阶滑模控制设计[J].控制理论与应用,2020,37(2):374-386. YANG Bo,SWE T,ZHONG Lin'en,et al.Robust fractional-order sliding-mode control design of grid-connected photovoltaic inverters[J].Control Theory & Applications,2020,37(2):374-386.
    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

杨旭红,袁 春,钱峰伟,等.电网不平衡下基于MMC的分数阶积分滑模控制策略研究[J].电力科学与技术学报,2024,39(5):226-234.
YANG Xuhong, YUAN Chun, QIAN Fengwei, et al. Fractional‑order integral sliding mode control strategy based on MMC under unbalanced grid conditions[J]. Journal of Electric Power Science and Technology,2024,39(5):226-234.

复制
分享
文章指标
  • 点击次数:100
  • 下载次数: 162
  • HTML阅读次数: 0
  • 引用次数: 0
历史
  • 在线发布日期: 2024-12-02
文章二维码

微信公众号二维码

您是本站第 83027 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