Hierarchical control of parallel voltage source inverters in AC microgrids

• Main Authors: Zhongwen Li, Zhiping Cheng, Yali Xu, Yifan Wang, Jing Liang, Jinfeng Gao
• Format: Article
• Language: English
• Published: Wiley 2018-10-01
• Series: The Journal of Engineering
• Subjects: invertors; variable structure systems; transient response; electric current control; multi-agent systems; control system synthesis; voltage control; distributed power generation; PI control; power generation control; distributed control; hierarchical systems; voltage-source convertors; H^2 control; H^∞ control; voltage magnitude; frequency deviations; droop controller; parallel voltage source inverters; AC microgrids; distributed hierarchical control strategy; VSIs; multiagent system-based distributed economic automatic generation control; double-loop proportional-integral control method; mixed H(2)-H(∞)-based outer-loop voltage control; sliding mode control-based inner-loop current control; fast transient response; circulating current avoidance; MAS-based EAGC; distributed automatic voltage control; optimal active power dispatch
• Online Access: https://digital-library.theiet.org/content/journals/10.1049/joe.2018.8620
• ISSN: 2051-3305

Here, a distributed hierarchical control strategy is proposed for the parallel operating of voltage source inverters (VSIs) in AC microgrids (MGs). For the output voltage control of a VSI, conventional double-loop proportional-integral (PI) control method has deteriorative performance under disturbance parameters conditions and has a narrow range of stable operation. Here, the sliding mode control (SMC)-based inner-loop current control (level0) and mixed H(2)/H(∞)-based outer-loop voltage control (level1) are proposed for the output voltage control of a VSI, which combines the advantages of robustness and fast transient response. The droop control (level2) is applied to avoid circulating currents among the VSIs without using any critical communication between them. The multi-agent system (MAS)-based distributed economic automatic generation control (EAGC) and distributed automatic voltage control (AVC) (level3) are proposed to restore the voltage magnitude and frequency deviations caused by droop controller and achieve optimal active power dispatch at the same time.