Design of aggregators for the day-ahead management of microgrids providing active and reactive power services

TL;DR

This paper presents a three-phase framework for aggregating microgrids to provide active and reactive power services, enhancing grid stability and efficiency through distributed optimization and coordinated scheduling.

Contribution

It introduces a novel multi-phase control scheme for microgrid aggregation that ensures scalability, confidentiality, and compliance with voltage and current constraints.

Findings

Effective day-ahead active power scheduling for microgrids.

Reactive power management maintains voltage stability.

Scalability demonstrated on IEEE 13-bus system.

Abstract

The increasing diffusion of distributed energy generation systems requires the development of new control paradigms for the coordination of micro-generators, storage systems, and loads aimed at maintaining the efficiency and the safe operability of the electricity network. MicroGrids (MGs) are an interesting way to locally manage groups of generation devices, but they cannot singularly provide a significant contribution to sustain the main electricity grid in terms of ancillary services, such as the availability of a minimum amount of power reserve for the frequency regulation. For these reasons, in this paper we propose a framework for the aggregation and coordination of interconnected MGs to provide ancillary services to the main utility. The proposed framework is structured in three main phases. In the first one, a distributed optimization algorithm computes the day-ahead profile of the active power production of the MGs based on the available forecasts of the renewable sources production and the loads absorption. In this phase, scalability of the optimization problem and confidentiality requirements are guaranteed. In the second phase, reactive power flows are scheduled and it is ensured that the active power trends planned in the first phase do not compromise the voltage/current limitations. A final third phase is used to schedule the active and reactive power profiles of the generation units of each MG to make them consistent with the requirements and results of the previous two phases. The developed method is used for control of the IEEE 13-bus system network and the results achieved are thoroughly discussed in terms of performance and scalability properties.