Scenario-Based Network Reconfiguration and Renewable Energy Resources Integration in Large-Scale Distribution Systems Considering Parameters Uncertainty

Renewable energy integration has been recently promoted by many countries as a cleaner alternative to fossil fuels. In many research works, the optimal allocation of distributed generations (DGs) has been modeled mathematically as a DG injecting power without considering its intermittent nature. In...

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Vydáno v:Mathematics (Basel) Ročník 9; číslo 1; s. 26
Hlavní autoři: Ali, Ziad M., Diaaeldin, Ibrahim Mohamed, H. E. Abdel Aleem, Shady, El-Rafei, Ahmed, Abdelaziz, Almoataz Y., Jurado, Francisco
Médium: Journal Article
Jazyk:angličtina
Vydáno: MDPI AG 01.01.2021
Témata:
bilevel multi-objective nonlinear programming optimization
DG uncertainty
distributed generation
graphically based network reconfiguration
hosting capacity maximization
power loss minimization
ISSN:2227-7390, 2227-7390
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Shrnutí:Renewable energy integration has been recently promoted by many countries as a cleaner alternative to fossil fuels. In many research works, the optimal allocation of distributed generations (DGs) has been modeled mathematically as a DG injecting power without considering its intermittent nature. In this work, a novel probabilistic bilevel multi-objective nonlinear programming optimization problem is formulated to maximize the penetration of renewable distributed generations via distribution network reconfiguration while ensuring the thermal line and voltage limits. Moreover, solar, wind, and load uncertainties are considered in this paper to provide a more realistic mathematical programming model for the optimization problem under study. Case studies are conducted on the 16-, 59-, 69-, 83-, 415-, and 880-node distribution networks, where the 59- and 83-node distribution networks are real distribution networks in Cairo and Taiwan, respectively. The obtained results validate the effectiveness of the proposed optimization approach in maximizing the hosting capacity of DGs and power loss reduction by greater than 17% and 74%, respectively, for the studied distribution networks.
ISSN:2227-7390
2227-7390
DOI:10.3390/math9010026