Distributed Optimal Power Flow for VSC-MTDC Meshed AC/DC Grids Using ALADIN

TL;DR

This paper develops a distributed optimization method using ALADIN to efficiently solve the complex nonconvex optimal power flow problem in VSC-MTDC hybrid AC/DC power systems, outperforming existing methods.

Contribution

It adapts the ALADIN algorithm for nonconvex AC/DC OPF problems in VSC-MTDC systems, providing a fully distributed solution with convergence guarantees.

Findings

ALADIN outperforms ADMM in convergence speed.

The method demonstrates robustness on IEEE benchmark systems.

The approach effectively handles nonconvex hybrid AC/DC OPF problems.

Abstract

The increasing application of voltage source converter (VSC) high voltage direct current (VSC-HVDC) technology in power grids has raised the importance of incorporating DC grids and converters into the existing transmission network. This poses significant challenges in dealing with the resulting optimal power flow (OPF) problem. In this paper, a recently proposed nonconvex distributed optimization algorithm -- Augmented Lagrangian based Alternating Direction Inexact Newton method (ALADIN), is tailored to solve the nonconvex AC/DC OPF problem for emerging voltage source converter (VSC) based multiterminal high voltage direct current (VSC-MTDC) meshed AC/DC hybrid systems. The proposed scheme decomposes this AC/DC hybrid OPF problem and handles it in a fully distributed way. Compared to the existing state-of-art Alternating Direction Method of Multipliers(ADMM), which is in general, not applicable for nonconvex problems, ALADIN has a theoretical convergence guarantee. Applying these two approaches to (VSC-MTDC) coupled with an IEEE benchmark AC power system illustrates that the tailored ALADIN outperforms ADMM in convergence speed and numerical robustness.