Coordinated Control of Energy Storage in Networked Microgrids under Unpredicted Load Demands

TL;DR

This paper presents a nonlinear control strategy for energy storage in networked microgrids to handle unpredicted load changes, ensuring stability and coordination among multiple SST-connected microgrids.

Contribution

It introduces an input-output linearization control method for nonlinear power balancing in microgrids with energy storage, including coordination among multiple SSTs.

Findings

Control guarantees closed-loop stability.

Effective coordination among multiple SSTs.

Validated on IEEE 34-bus system.

Abstract

In this paper a nonlinear control design for power balancing in networked microgrids using energy storage devices is presented. Each microgrid is considered to be interfaced to the distribution feeder though a solid-state transformer (SST). The internal duty cycle based controllers of each SST ensures stable regulation of power commands during normal operation. But problem arises when a sudden change in load or generation occurs in any microgrid in a completely unpredicted way in between the time instants at which the SSTs receive their power setpoints. In such a case, the energy storage unit in that microgrid must produce or absorb the deficit power. The challenge lies in designing a suitable regulator for this purpose owing to the nonlinearity of the battery model and its coupling with the nonlinear SST dynamics. We design an input-output linearization based controller, and show that it guarantees closed-loop stability via a cascade connection with the SST model. The design is also extended to the case when multiple SSTs must coordinate their individual storage controllers to assist a given SST whose storage capacity is insufficient to serve the unpredicted load. The design is verified using the IEEE 34-bus distribution system with nine SST-driven microgrids.