Distributionally robust microgrid formation for service restoration in distribution systems against extended extreme events

Distributionally robust microgrid formation for service restoration in distribution systems against extended extreme events

Extended extreme events with long-lasting destructive effects may result in significant power outages and subsequent contingencies within the distribution system (DS). Microgrid formation (MF) has emerged as a crucial approach for service restoration (SR) under such circumstances since local resourc...

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Bibliographic Details
Main Authors: Ran Zhu, Hongzhe Liu, Wenwu Yu, Wei Gu, Jin Zhao
Format: Article
Language:English
Published: Elsevier 2025-08-01
Series:International Journal of Electrical Power & Energy Systems
Subjects:
Service restoration
Resilience
Microgrid formation
Uncertainty management
Distributionally robust optimization
Parallel algorithm
Online Access:http://www.sciencedirect.com/science/article/pii/S0142061525002716
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Summary:Extended extreme events with long-lasting destructive effects may result in significant power outages and subsequent contingencies within the distribution system (DS). Microgrid formation (MF) has emerged as a crucial approach for service restoration (SR) under such circumstances since local resources can be utilized to provide temporary power supplies. This paper proposes a novel MF-based SR approach for the DS to maximize the expected weighted load served ratio (WLSR) by allocating mobile power sources and dynamic MF scheduling in the worst case against extended extreme events. Specially, a three-layer distributionally robust optimization SR model is developed in which the uncertainties resulting from subsequent contingencies and uncertain outputs from renewables can be effectively tackled using two different distribution ambiguity sets. Additionally, a two-step MF model allowing for de-energized nodes is incorporated into the SR model. Furthermore, to enhance the computational efficiency, a parallel solving strategy is developed, based on the column-and-constraint generation algorithm, the alternating optimization procedure, and the progressive hedging algorithm. Finally, the case studies are given to demonstrate that the proposed strategy has a good performance on enhancing system resilience by improving the WLSR index during extended extreme events with subsequent uncertainties and facilitating time-sensitive decision-making for SR.
ISSN:0142-0615

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