A progressive method to solve large-scale AC optimal power flow with discrete variables and control of the feasibility

Author

Ruiz, Manuel ; Maeght, Jean ; Marie, Alexandre ; Panciatici, Patrick ; Renaud, Arnaud

Author_Institution

Artelys, Paris, France

fYear

2014

fDate

18-22 Aug. 2014

Firstpage

1

Lastpage

7

Abstract

This paper introduces a study on power system networks which aims to produce a dynamic simulation based security assessment taking into account uncertainties. An extended Optimal Power Flow without any guarantee on feasibility leads to the resolution of a Mixed-Integer NonLinear Problem (MINLP). Solving a (MINLP) is very challenging and even harder when the problem is not convex and could be unfeasible. A custom filtering method which tries to explain infeasibilities and uses the nonlinear solver KNITRO to reformulate discrete variables into nonlinear constraints is proposed. Preliminary results on the French and European power systems network demonstrate the interest of this approach on real-life cases.

Keywords

load flow; power system security; power system simulation; European power system; French power system; MINLP; discrete variable; dynamic simulation; feasibility control; filtering method; large-scale AC optimal power flow; mixed-integer nonlinear problem; nonlinear constraint; nonlinear solver KNITRO; power system network; security assesment; Artificial neural networks; Couplers; Extremities; Optimization; Power transformers; Production; Security;

fLanguage

English

Publisher

ieee

Conference_Titel

Power Systems Computation Conference (PSCC), 2014

Conference_Location

Wroclaw

Type

conf

DOI

10.1109/PSCC.2014.7038395

Filename

7038395