Abstract
Modern distribution networks face an increasing number of challenges in maintaining balanced grid voltages because of the rapid increase in single-phase distributed generators. Because of the proliferation of inverter-based resources, such as photovoltaic (PV) resources, in distribution networks, a novel method is proposed for mitigating voltage unbalance at the point of common coupling by tuning the volt–var curve of each PV inverter through a day-ahead deep reinforcement learning training platform with forecast data in a digital twin grid. The proposed strategy uses proximal policy optimization, which can effectively search for a global optimal solution. Deep reinforcement learning has a major advantage in that the calculation time required to derive an optimal action in the smart inverter can be significantly reduced. In the proposed framework, multiple agents with multiple inverters require information on the load consumption and active power output of each PV inverter. The results demonstrate the effectiveness of the proposed control strategy on the modified IEEE 13 standard bus systems with time-varying load and PV profiles. A comparison of the effect on voltage unbalance mitigation shows that the proposed inverter can address voltage unbalance issues more efficiently than a fixed droop inverter.
Highlights
Accepted: 21 September 2021The effort in decarbonizing a power system is undergoing major changes including a large amount of distributed generation (DG) replacing conventional generators and transportation undergoing electrification
At the point of common coupling (PCC) in the distribution network (DN), it is necessary to reduce the voltage unbalance because it is directly connected to the high-voltage stage with a three-phase transformer
Distribution networks are experiencing a steady increase in the number of unbalanced components, such as single-phase PV systems, electric vehicle (EV) charging stations, and loads distributed along feeders that cause voltage unbalance at the PCC
Summary
The effort in decarbonizing a power system is undergoing major changes including a large amount of distributed generation (DG) replacing conventional generators and transportation undergoing electrification. The existing voltage control methods using DRL only focus on adjusting voltage profiles without looking into mitigating voltage unbalance and are not flexible enough to adopt changing distribution networks with various newly connected devices and inverter-based resources. A novel volt–var control strategy for single-phase DG smart inverters for mitigating voltage unbalance targeting the PCC under time-varying operating conditions in a three-phase distribution system is proposed. The proposed volt–var control, which is used by the distribution system operator in control rooms, was predefined through day-ahead training based on forecast PV and load consumption data. The procedure fordetailed using the developed platform mainly includes balance factor at PCC, the volt-var curve and the reactive power capability of each inthe training stage, day-ahead training of smart inverters with forecast information about verter
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