An algorithm for DC segmentation of AC power systems to mitigate electromechanical oscillations

TL;DR

This paper introduces a systematic algorithm for DC segmentation of AC power systems using VSC-HVDC links, aiming to mitigate electromechanical oscillations by targeting inter-area modes through small-signal stability techniques.

Contribution

It presents the first systematic algorithm for DC segmentation based on small-signal stability and dominant oscillation paths, validated on test systems.

Findings

Effective mitigation of inter-area oscillations demonstrated

Algorithm successfully applied to test systems

Validation through non-linear simulations and stability analysis

Abstract

In the last decades, various events have shown that electromechanical oscillations are a major concern for large interconnected Alternative Current (AC) power systems. DC segmentation - a method that consist in turning large AC grids into a set of asynchronous AC clusters linked by Direct Current (DC) links - is a promising solution to mitigate this and other issues. However, no systematic segmentation procedure for a given AC power system exists so far. This paper aims at filling this gap and proposes an algorithm for DC segmentation for a given AC power system to mitigate electromechanical oscillations. In this proposal, DC segmentation is implemented with High Voltage Direct Current links based on Voltage Source Converters (VSC-HVDC). The algorithm uses small-signal stability techniques and the concept of dominant inter-area oscillation paths to stop the main inter-area mode of the power system. The algorithm will be explained using a six-generator test system and it will then be used on the Nordic 44 test system. The proposed algorithm for DC segmentation has been validated by means of non-linear time-domain simulation and small-signal stability analysis (SSSA).