Download This PaperOptimal Planning of Urban-Scale Rooftop Pv Systems: Maximizing Renewable Energy Integration by Reducing Grid Congestion-Induced Curtailments
61 Pages Posted: 12 Apr 2025
Abstract
Urban-scale rooftop PV systems are experiencing rapid growth. Existing planning methods primarily focus on optimizing their locations and capacities to maximize either distributed renewable energy or economic benefits. However, large-scale deployment of distributed rooftop PV systems can cause complex transmission congestion, leading to significant curtailments of centralized renewable energy and reducing the integration of both distributed and centralized renewable energy sources. To address this issue, this study proposes an optimal planning method for urban-scale rooftop PV systems aimed at maximizing total renewable energy integration by reducing grid congestion-induced curtailments. To handle the high-dimensional optimization problem, the method employs mixed-integer linear programming to determine the optimal planning of distributed PV systems at individual buses within transmission network. The impacts of PV deployment on transmission congestion are quantified using power transfer distribution factors, which helps prioritize or avoid deploying PV systems on buses that could alleviate or exacerbate congestion, thereby reducing curtailments. Using a case study of 9,246 buildings in Nanjing, the proposed method was validated against a baseline approach that aimed solely at maximizing distributed rooftop PV generation under different budget levels. Results demonstrated that the proposed method reduced centralized renewable energy curtailment by 61.47%, enhancing total renewable energy integration.
Keywords: Urban-scale rooftop PV, optimal planning, transmission congestion, renewable curtailment, high-dimensional search
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