Abstract

Higher penetration of intermittent solar photovoltaic (PV) systems in the distribution grid results in frequent voltage fluctuations. The conventional voltage regulating devices operating on a slow-timescale need to be supplemented with the fast-operating smart inverters with adjustable reactive power setpoints. Complete and accurate information about distribution network topology and line parameters is necessary for conventional model-based Volt-VAR control (VVC) methods. However, such information is often unavailable. To tackle these challenges, a reinforcement learning-based two-timescale VVC algorithm is proposed in this paper that jointly controls the conventional voltage regulating devices at the slow-timescale and the smart inverters at the fast-timescale. Our proposed VVC algorithm simultaneously minimizes voltage violation costs and system operation costs in a model-free manner utilizing historical operational data. Two hierarchically organized agents are set up for the slow-timescale and fast-timescale problems, which are coupled through a communication scheme. The two sets of control policies are learned concurrently by a deep deterministic policy gradient and multi-agent soft actor-critic algorithm respectively. Comprehensive numerical studies performed with the IEEE 123-bus distribution test feeder show that the proposed framework can identify near optimal control actions of voltage regulating devices and smart inverters in real-time operations.

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