Assessing Power Flow Controllability via Variable Line Reactance

TL;DR

This paper introduces a framework to quantify the system-wide controllability of power flows through reactance adjustments, demonstrating that installing PFCs on all lines achieves complete controllability and analyzing how PFC placement affects flow flexibility.

Contribution

It develops a novel analytical framework for system-wide power flow controllability and provides empirical methods to optimize PFC placement and sizing for enhanced network flexibility.

Findings

Installing PFCs on all lines enables complete controllability.

Controllability increases with the number and reactance range of PFCs.

Empirical validation confirms the effectiveness of the proposed approach.

Abstract

The rapid growth of large data center loads and inverter-based generation is increasing the stress on transmission networks, while expanding grid capacity at the required pace remains challenging. Power flow controllers (PFCs) that adjust effective line reactances to redistribute flows are often viewed as an interim solution to improve transmission network utilization. Traditional flexibility metrics and analysis approaches for PFCs focus on a limited number of operating points and contingencies. Towards gaining system-wide insights, this paper introduces a framework to quantify network flow controllability- the extent to which line flows can be reshaped through reactance adjustments. We derive analytical results demonstrating that installing PFCs on all lines enables complete controllability of feasible flow patterns. Building on these, we conduct empirical studies on the IEEE 39-bus system to examine how controllability varies with the number of PFCs and their reactance adjustment range. These analyses employ a mixed-integer linear program to optimize the siting and sizing of PFCs. Finally, we validate findings under AC power flow physics using an optimization routine that steers flows toward desired setpoints.