Julia Sachs1, Cristina Massari, Adam Hawkes, Oliver Sawodny2
11:20 - 11:40 | Wed 22 Aug | Christiansborg | WeA2.5
The accumulation of energy systems, comprising of diesel generators, storage devices and renewable sources, to a large interacting network is a promising approach to achieve a low cost energy supply in remote areas. The main potential for cost reduction is through optimized operation of the network. Power management of these networks can be challenging due to sudden variations in load demand and high fluctuations in power supplied by renewables. A distributed optimization approach for efficient operation guaranteeing improved robustness towards faults, reduced complexity, and an uninterrupted energy supply is presented. The approach includes detailed component modeling to assure the satisfaction of all operation constraints during the system operation. An extended Alternating Direction Method of Multipliers approach is used for the distributed optimization separating the mixed integer linear optimization problem into sub-problems. Case studies are carried out by using real-world data to illustrate the performance and economic benefits of the proposed method in comparison to the centralized approach. Results show the effectiveness of the optimization strategy in terms of computational feasibility, accuracy, and increased robustness and its suitability for the integration into a distributed model predictive control.