Granular Optimal Load-Side Control of Power Systems with Electric Spring Aggregators

TL;DR

This paper presents a distributed control scheme for electric spring aggregators in subtransmission networks that simultaneously regulates frequency and voltage while minimizing costs, demonstrating effective power response and voltage stability.

Contribution

It introduces a novel distributed optimization-based control scheme for electric spring aggregators that coordinates active and reactive power for frequency and voltage regulation.

Findings

Achieves required active power response for frequency regulation.

Maintains bus voltages within acceptable range.

Minimizes operational costs during regulation.

Abstract

To implement controllable loads for frequency regulation in transmission networks in a practical way, the control scheme needs to be granulated down at least to subtransmission networks since loads in transmission networks are usually the aggregation of lower voltage networks. However, not only frequency but also bus voltage will be affected by active power changes in subtransmission networks due to a higher R/X ratio of transmission lines. Further, the costs for loads participating in frequency and voltage regulation should also be considered. In this paper, a control scheme is proposed for electric spring (ES) aggregators which consist of back-to-back ESs and exponential type of noncritical loads in subtransmission networks. A distributed optimization which aims to minimize the costs and implements both frequency and voltage regulation is adopted for ES aggregators to obtain new active and reactive power setpoints by sharing information with neighbors. Power consumption of each ES aggregator is then adjusted accordingly to conduct frequency and voltage regulation simultaneously. Simulation results show that ES aggregators are able to achieve required active power response and regulate frequency cooperatively, and meanwhile maintain bus voltages within the acceptable range with minimized costs under the proposed control scheme.