基于背靠背变流器柔性互联微电网群的分层分布式协同控制及其稳定分析

doi:10.19595/j.cnki.1000-6753.tces.240313

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摘要在基于背靠背变流器柔性互联的交流微电网群中,传统的分层控制架构可以实现各微电网（MG）单元内的频率/电压无差恢复和功率均分的控制目标,但无法实现微电网群全局层面的有功均分控制目标,因此,亟须提出柔性互联微电网群的分层协同控制方法,并分析其小信号稳定性。该文提出一种柔性互联微电网群全新的分层分布式协同控制架构,各背靠背变流器可通过两侧MG单元有效交互实现集群层面的全局控制目标,实现全局层面的有功均分。进一步建立分层分布式控制架构下微电网群系统的小信号模型,分析其稳定性的主导失稳模态,并与已有文献方法进行了功率传输稳定性的比较分析。最后,利用Matlab/Simulink搭建了仿真模型,验证了控制策略的有效性和优越性。

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关键词 ：背靠背变流器, 柔性互联, 微电网群, 分层协同控制, 小信号稳定性分析

Abstract：A single microgrid (MG) has a small capacity and poor stability problems. Combining multiple microgrids adjacent to each other in geographical space into a more compact whole, that is, microgrid cluster (MGC), is an effective way to improve the distributed power supply (DG) consumption level. The traditional interconnection mode has the defect that the disturbance between MG units cannot be isolated from each other, and the interactive power can only be adjusted indirectly. Although the flexible interconnection based on back-to-back converters (BTBC) has the advantages of inter-regional power flow continuous regulation and fault zone buffering, the flexible interconnection MGC system cannot form an effective “frequency signal” transmission among MG units. It is difficult to achieve active power sharing at the global level of microgrid clusters. The current MGC system based on BTBC interconnection has significant defects, mainly manifested as the lack of effective hierarchical cooperative control architecture design and stable dominant characteristics analysis under hierarchical cooperative control. A new control method based on the flexible interconnection of BTBC needs to be proposed.
Firstly, this paper proposes a novel distributed hierarchical coordinated control architecture, including a physical layer of flexible interconnected microgrid cluster and an information layer with sparse communication in a two-layer structure. Under this control architecture, the control objectives can be realized, such as secondary restoration control, reactive power sharing control, and global active power sharing control for each DG frequency/port bounded voltage in the MG unit. Secondly, two control strategies are proposed to achieve global active power sharing. Local control is independent of communication but cannot be parallel with frequency invariant control, and hierarchical cooperative control depends on communication but can realize frequency invariant control at the same time. Thirdly, a full-order small signal model of the system is established, and the dominant modes are analyzed. Finally, Matlab/Simulink simulation is carried out to verify the effectiveness and superiority of the proposed control strategies.
The conclusions are as follows. (1) Compared with the traditional hierarchical cooperative control and local control, the proposed strategy can achieve both MG frequency/voltage restorations and active/reactive power-sharing management. (2) The stable dominant modes of the proposed hierarchical cooperative control are the voltage and power angle dynamics in each MG. The stable dominant modes of local control are the dynamics in BTBCs. (3) The stability of the proposed hierarchical cooperative control strategy is close to the strategy mentioned in the literature [15]. It does not need to measure (or estimate) the local load in real-time, has no undefined solution problem, is easy to apply in practice.

Key words： Back-to-back converters flexible interconnection microgrid cluster hierarchical cooperative control small signal stability analysis

收稿日期: 2024-02-28

PACS:	TM46
	TM73

基金资助:国家自然科学基金（52207087）和安徽省自然科学基金（2108085QE236）资助项目

通讯作者: 孟潇潇男,1992年生,讲师,硕士生导师,研究方向为新型电力系统的稳定分析与控制、微电网控制技术等。E-mail: mxxfreedom@hfut.edu.cn

作者简介: 尤泽豪男,2000年生,硕士研究生,研究方向为微电网稳定分析与控制。E-mail: 2022170506@mail.hfut.edu.cn

引用本文:

孟潇潇, 尤泽豪, 张茂凡, 邵冰冰. 基于背靠背变流器柔性互联微电网群的分层分布式协同控制及其稳定分析[J]. 电工技术学报, 2024, 39(24): 7917-7932. Meng Xiaoxiao, You Zehao, Zhang Maofan, Shao Bingbing. Distributed Hierarchical Cooperative Control and Stability Analysis of Flexible Interconnected Microgrid Cluster Via Back-to-Back Converters. Transactions of China Electrotechnical Society, 2024, 39(24): 7917-7932.

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