In distribution networks, the hosting capacity for Renewable Energy Sources (RESs) is constrained by overvoltage and overcurrent limits, which increase the risk of overloading components and causing voltage violations. RESs curtailment is a common but not optimal strategy used to mitigate these issues. While many existing solutions rely on nonlinear optimization problems or complex algorithms, this paper introduces a novel linear optimization approach for minimizing RES curtailment exploiting flexibility resources of the grid. The proposed method ensures compliance with voltage, current, and transformer overload constraints by replacing traditional load flow equations with linear relationships based on voltage drop calculations.
Minimization of Renewable Energy Curtailment in Radial and Weakly Meshed Distribution Networks / Bonfiglio, A.; Bruno, S.; Martino, M.; Musca, R.; Velini, A.; Zizzo, G.. - 2025(2025), pp. 1-5. ( 20th Annual System of Systems Engineering Conference, SoSE 2025 alb 2025) [10.1109/SoSE66311.2025.11083794].
Minimization of Renewable Energy Curtailment in Radial and Weakly Meshed Distribution Networks
Bruno S.;Velini A.;
2025
Abstract
In distribution networks, the hosting capacity for Renewable Energy Sources (RESs) is constrained by overvoltage and overcurrent limits, which increase the risk of overloading components and causing voltage violations. RESs curtailment is a common but not optimal strategy used to mitigate these issues. While many existing solutions rely on nonlinear optimization problems or complex algorithms, this paper introduces a novel linear optimization approach for minimizing RES curtailment exploiting flexibility resources of the grid. The proposed method ensures compliance with voltage, current, and transformer overload constraints by replacing traditional load flow equations with linear relationships based on voltage drop calculations.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
