Abstract
The occurrence of voltage violations is a major deterrent for absorbing more rooftop solar power into smart Low-Voltage Distribution Grids (LVDGs). Recent studies have focused on decentralized control methods to solve this problem due to the high computational time in performing load flows in centralized control techniques. To address this issue, a novel sensitivity matrix was developed to estimate the voltages of the network by replacing load flow simulations. In this paper, a Centralized Active, Reactive Power Management System (CARPMS) is proposed to optimally utilize the reactive power capability of smart Photovoltaic (PV) inverters with minimal active power curtailment to mitigate the voltage violation problem. The developed sensitivity matrix is able to reduce the time consumed by 55.1% compared to load flow simulations, enabling near-real-time control optimization. Given the large solution space of power systems, a novel two-stage optimization is proposed, where the solution space is narrowed down by a Feasible Region Search (FRS) step, followed by Particle Swarm Optimization (PSO). The failure of standalone PSO to converge to a feasible solution for 34% of the scenarios evaluated further validates the necessity of the two-stage optimization using FRS. The performance of the proposed methodology was analysed in comparison to the load flow method to demonstrate the accuracy and the capability of the optimization algorithm to mitigate voltage violations in near-real time. The deviations of the mean voltages of the proposed methodology from the load flow method were: 6.5×10−3 p.u for reactive power control using Q-injection, 1.02×10−2 p.u for reactive power control using Q-absorption, and 0 p.u for active power curtailment case.
Highlights
We propose a Centralized Active, Reactive Power Management System (CARPMS), which uses the combination of both Reactive Power Control (RPC) and Active Power Curtailment (APC) to mitigate the voltage violations in Low-Voltage Distribution Grids (LVDGs) at the tertiary control level
The effectiveness and necessity of the Feasible Region Search (FRS) combination with Particle Swarm Optimization (PSO) was analysed by running 100 Monte Carlo simulations with FRS and without FRS
It was observed that nearly 34% of the simulation scenarios were not solved by the PSO-only optimization to remove the voltage violations
Summary
Low-Voltage Distribution Grids (LVDGs) has gained high prominence due to technological advancements, increased demand in sustainable energy resources and the advent of decarbonisation programs by many countries [1,2,3]. The high penetration of rooftop PV in LVDGs can result in reverse power flows [7] and an increase in the neutral current, leading to distribution and transformer losses due to overheating of the conductor [5,8,9,10,11]. Studies have revealed that voltage violations can occur at a penetration level as low as 2.5% due to the integration of rooftop PV panels at prosumers’ will [13]. How to mitigate the voltage violations in LVDGs is a long-standing question to which much time and study have been devoted
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