Distributed Online Voltage Control in Active Distribution Networks Considering PV Curtailment

In this paper, we propose a distributed online voltage control algorithm for distribution networks with multiple photovoltaic (PV) systems based on dual-ascent method. Conventional distributed algorithms implement voltage control only when the algorithms converge. However, our proposed algorithm is...

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Veröffentlicht in:	IEEE transactions on industrial informatics 2019-10, Vol.15 (10), p.5519-5530
Hauptverfasser:	Li, Jiayong, Xu, Zhao, Zhao, Jian, Zhang, Chaorui
Format:	Artikel
Sprache:	eng
Schlagworte:	Active control Algorithms Ascent Control algorithms Control theory Convergence Decentralized control Distributed algorithm Distributed algorithms Distribution management distribution networks (DNs) dual-ascent method Electric potential Electronic equipment tests Inverters Mathematical model Networks online voltage control Optimization photovoltaic (PV) system Photovoltaic cells Reactive power Robustness (mathematics) Stability Voltage Voltage control
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creator	Li, Jiayong Xu, Zhao Zhao, Jian Zhang, Chaorui
description	In this paper, we propose a distributed online voltage control algorithm for distribution networks with multiple photovoltaic (PV) systems based on dual-ascent method. Conventional distributed algorithms implement voltage control only when the algorithms converge. However, our proposed algorithm is able to carry out voltage control immediately. In particular, we derive a closed-form solution for PV controllers to locally update the active and reactive power set points aiming at minimizing the total loss and maintaining bus voltages within the acceptable ranges. The optimality is guaranteed and the convergence is established analytically. Moreover, our proposed algorithm only requires the information exchange between neighboring PV systems, thus reducing communication complexity. Finally, numerical tests on IEEE 37-bus distribution system verify the effectiveness and robustness of our proposed algorithm.
doi_str_mv	10.1109/TII.2019.2903888
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Conventional distributed algorithms implement voltage control only when the algorithms converge. However, our proposed algorithm is able to carry out voltage control immediately. In particular, we derive a closed-form solution for PV controllers to locally update the active and reactive power set points aiming at minimizing the total loss and maintaining bus voltages within the acceptable ranges. The optimality is guaranteed and the convergence is established analytically. Moreover, our proposed algorithm only requires the information exchange between neighboring PV systems, thus reducing communication complexity. 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Conventional distributed algorithms implement voltage control only when the algorithms converge. However, our proposed algorithm is able to carry out voltage control immediately. In particular, we derive a closed-form solution for PV controllers to locally update the active and reactive power set points aiming at minimizing the total loss and maintaining bus voltages within the acceptable ranges. The optimality is guaranteed and the convergence is established analytically. Moreover, our proposed algorithm only requires the information exchange between neighboring PV systems, thus reducing communication complexity. 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subjects	Active control Algorithms Ascent Control algorithms Control theory Convergence Decentralized control Distributed algorithm Distributed algorithms Distribution management distribution networks (DNs) dual-ascent method Electric potential Electronic equipment tests Inverters Mathematical model Networks online voltage control Optimization photovoltaic (PV) system Photovoltaic cells Reactive power Robustness (mathematics) Stability Voltage Voltage control
title	Distributed Online Voltage Control in Active Distribution Networks Considering PV Curtailment
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