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构网型MMC双阀组能量耦合机理分析及其协同控制策略OA

Analysis of Strategy for Energy Coupling Mechanism and Coordinated Control for Grid-Forming MMC with Dual Valve Groups

中文摘要英文摘要

[目的]构网型特高压柔性直流换流站是支撑高比例新能源外送的重要方案,但其多阀组串并联结构在构网控制下易引发直流电压分配不均与能量耦合问题.文章旨在揭示双阀组系统能量耦合机理,并提出相应控制策略,以实现阀组间能量解耦与内部电容能量均衡.[方法]首先建立双阀组系统能量交互数学模型,从理论上分析能量耦合的产生机制.然后提出一种基于子模块能量平衡理论的双模块化多电平换流器(modular multilevel converter,MMC)阀组主从构网控制策略,以抑制阀组间能量交互并实现解耦控制.最后通过PSCAD/EMTDC平台搭建送端构网型特高压MMC多阀组电磁暂态仿真模型,验证理论分析的正确性与所提控制策略的有效性.[结果]所提出的控制策略有效抑制了双阀组间的能量交互,实现了阀组间能量解耦,同时在保持稳定功率传输的前提下,平衡了换流阀内部及阀组间的子模块电容能量分布.[结论]通过数学建模与主从构网控制策略,解决了构网型特高压MMC双阀组运行时的能量耦合问题.该方法不仅实现了阀组间能量解耦与电容能量均衡,也为实际工程中多阀组柔性直流系统的稳定运行提供了理论依据与控制方案.

[Objective]Grid-forming ultra-high voltage(UHV)flexible DC converter stations are a crucial solution for supporting the large-scale transmission of high-share renewable energy.However,their multi-valve group series-parallel structure under grid-forming control is prone to issues such as uneven DC voltage distribution and energy coupling.This paper aims to uncover the energy coupling mechanism in dual-valve group systems and proposes a corresponding control strategy to achieve energy decoupling among valve groups and internal capacitor energy balance.[Methods]First,an energy interaction mathematical model of the dual-valve group system is established to theoretically analyze the generation mechanism of energy coupling.Subsequently,a master-slave grid-forming control strategy for modular multilevel converter(MMC)with dual valve groups,based on submodule energy balancing theory,is proposed to suppress inter-valve group energy interaction and achieve decoupling control.Finally,the correctness of the theoretical analysis and the effectiveness of the proposed control strategy are verified through an electromagnetic transient simulation model of a sending-end grid-forming UHV MMC with multiple valve groups built on the PSCAD/EMTDC platform.[Results]The proposed control strategy effectively suppresses the energy interaction between the dual valve groups,achieving energy decoupling between them.Simultaneously,it balances the submodule capacitor energy distribution within the converter valves and between the valve groups while maintaining stable power transmission.[Conclusions]Through mathematical modeling and a master-slave grid-forming control strategy,the issue of energy coupling during the operation of grid-forming UHV MMC with dual valve groups has been effectively addressed.This approach not only achieves energy decoupling and capacitor energy balancing between valve groups but also provides a theoretical foundation and a control solution for the stable operation of multi-valve group flexible DC systems in practical engineering applications.

赵家雯;韩民晓;芦文泽;熊凌飞;樊林禛

华北电力大学电气与电子工程学院,北京市 102206华北电力大学电气与电子工程学院,北京市 102206华北电力大学电气与电子工程学院,北京市 102206国网经济技术研究院有限公司,北京市 102209国网经济技术研究院有限公司,北京市 102209

信息技术与安全科学

特高压(UHV)柔性直流输电系统构网型控制模块化多电平换流器(MMC)能量耦合机理

ultra-high voltage(UHV)flexible DC transmission systemgrid-forming controlmodular multilevel converter(MMC)energy coupling mechanism

《电力建设》 2026 (3)

106-118,13

智能电网国家科技重大专项项目(2024ZD0800200) This work is supported by Smart Grid National Science and Technology Major Special Project of China under Grant(No.2024ZD0800200).

10.12204/j.issn.1000-7229.2026.03.009

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