Keskeiset käsitteet
A two-stage robust optimization approach that configures and operates networked microgrids to maximize the delivery of uncertain loads in unbalanced distribution grids, while minimizing generation costs.
Tiivistelmä
The content presents a robust optimization framework to address the problem of network partitioning and operation in distribution grids with uncertain loads.
Key highlights:
- Formulates a two-stage robust optimization problem to determine the optimal network partitioning and generator set-points that maximize load delivery while minimizing generation costs.
- The first stage is a mixed-integer linear program that optimizes the network partitioning decisions, ensuring radial topology and the presence of at least one grid-forming DER in each energized microgrid.
- The second stage adjusts generator set-points to handle the revealed uncertain loads, subject to three-phase unbalanced power flow constraints.
- Proposes a cutting-plane algorithm to solve the two-stage robust optimization problem efficiently, with convergence guarantees.
- Demonstrates the benefits of networked microgrids in maximizing load delivery under uncertainty, using a case study on the IEEE 37-bus test system.
- Evaluates the robustness of the solutions against non-convex AC power flow constraints.
The proposed approach provides a comprehensive framework to enhance the resilience of distribution grids by optimally partitioning the network into networked microgrids that can effectively handle uncertain load conditions.
Tilastot
The total nominal load in the 37-bus network is 2542 kW.
The total generation capacity of the DERs in the network is 2180 kW.
The ramping limit for each DER is set at 30% of its capacity.
Lainaukset
"To mitigate the vulnerability of distribution grids to severe weather events, some electric utilities use preemptive de-energization as the primary line of defense, causing significant power outages."
"Networked microgrids are gaining significant traction as a means to improve the resilience and economic efficiency of modern distribution grids, especially during extreme weather events and unforeseen contingencies."