Title :
Advanced SVC models for Newton-Raphson load flow and Newton optimal power flow studies
Author :
Ambriz-Pérez, H. ; Acha, E. ; Fuerte-Esquivel, C.R.
Author_Institution :
Dept. of Electron. & Electr. Eng., Glasgow Univ., UK
fDate :
2/1/2000 12:00:00 AM
Abstract :
Advanced load flow models for the static VAr compensator (SVC) are presented in this paper. The models are incorporated into existing load flow (LF) and optimal power flow (OPF) Newton algorithms. Unlike SVC models available in open literature the new models depart from the generator representation of the SVC and are based instead on the variable shunt susceptance concept. In particular, a SVC model which uses the firing angle as the state variable provides key information for cases when the load flow solution is used to initialize other power system applications, e.g., harmonic analysis. The SVC state variables are combined with the nodal voltage magnitudes and angles of the network in a single frame-of-reference for a unified, iterative solution through Newton methods. Both algorithms, the LF and the OPF exhibit very strong convergence characteristics, regardless of network size and the number of controllable devices. Results are presented which demonstrate the prowess of the new SVC models
Keywords :
Newton method; Newton-Raphson method; electric admittance; load flow; power system harmonics; static VAr compensators; FACTS; Newton optimal power flow; Newton-Raphson load flow; advanced SVC models; firing angle; harmonic analysis; iterative solution; load flow solution; nodal voltage magnitudes; state variable; variable shunt susceptance; voltage control; Harmonic analysis; Iterative methods; Load flow; Load modeling; Power system analysis computing; Power system harmonics; Power system modeling; Shunt (electrical); Static VAr compensators; Voltage;
Journal_Title :
Power Systems, IEEE Transactions on
