Abstract
An increase in the share of weather-dependent generation at low voltage levels necessitates incorporating the low-voltage network in optimizing a distribution network. Optimization in a multi-voltage network requires significant computation time and effort due to many nodes operating at different voltage levels. This research proposes a decomposition and strategic optimization method to reduce the computation requirements for such large multi-voltage distribution networks. The proposed algorithm reduces the space complexity and the computation time required for solving the optimization routines of these multi-voltage distribution networks. A virtual transformer model incorporates tap-changer as a continuous variable in the semidefinite programming power flow optimization model. The zero-duality gap condition for multiple virtual transformers is proven empirically. Compared to a centralized optimization using the same power flow model, the proposed framework reduced the computation time by 96%.
Original language | English |
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Article number | 110127 |
Journal | International Journal of Electrical Power and Energy Systems |
Volume | 161 |
Number of pages | 12 |
ISSN | 0142-0615 |
DOIs | |
Publication status | Published - 2024 |
Keywords
- Controllability
- Distributed Renewable Generation
- Multi-voltage Distribution Network
- Observability
- On-load tap changers
- Reactive Power
- Voltage-Violations