Control and Stability of a Multilevel Power System for a Future Distribution Network

TL;DR

This paper introduces a multilevel control framework utilizing energy storage to enhance stability in future distribution networks with high renewable integration, employing distributed control and stability analysis.

Contribution

It develops a novel distributed control strategy with stability guarantees for complex multilevel power systems integrating renewable energy.

Findings

Stability conditions established for the proposed control system.

Performance bounds quantify the effectiveness of distributed control.

Simulation results demonstrate improved frequency and voltage stability.

Abstract

The growing integration of renewable energy sources into distribution networks poses significant challenges to frequency and voltage stability due to their intermittent nature and low-inertia dynamics. This paper proposes a multilevel control framework for a future decarbonized power system, using energy storage systems as power buffers to mitigate frequency and voltage fluctuations. A nonlinear interconnected model is formulated to characterize the complex dynamics across multiple levels of the distribution network. To reduce operational complexity and communication overhead of these dynamics, a distributed linear quadratic regulator control strategy is developed for information exchange in a bottom-up approach, where each level implements local feedback control within a short time horizon. Stability conditions for both open-loop and closed-loop systems are established using Lyapunov-based analysis. In addition, explicit performance bounds are derived to quantify the optimal difference between the proposed distributed strategy and the centralized control method, demonstrating the effectiveness of the proposed framework.