Title :
Impedance-Based Resonance Analysis in a VSC-HVDC System
Author :
Ling Xu ; Lingling Fan
Author_Institution :
Dept. of Electr. Eng., Univ. of South Florida, Tampa, FL, USA
Abstract :
Resonances can limit power transfer in a voltage-source converter-high voltage dc (VSC-HVDC) system. The objective of this paper is to develop impedance models for the rectifier ac system and the inverter ac system for a VSC-HVDC system. Resonance stability will be examined using Nyquist stability criterion and impedance frequency responses. The impedance models consider the outer control loop and the inner current control loops of VSCs. Impacting factors are then examined. Stability analysis demonstrates that the feedforward filter, line length, and power transfer level have a significant impact on resonances. Time-domain simulation results obtained by Matlab SimPowerSystems are used to validate the analysis.
Keywords :
HVDC power convertors; HVDC power transmission; electric current control; frequency response; invertors; power transmission control; rectifying circuits; time-domain analysis; Matlab SimPowerSystems; Nyquist stability criterion; VSC-HVDC system; feedforward filter; impedance frequency response; impedance model; impedance-based resonance analysis; inner current control loop; inverter AC system; line length; outer control loop; power transfer level; rectifier AC system; resonance stability; stability analysis; time-domain simulation; voltage source converter-high-voltage DC system; Admittance; HVDC transmission; Impedance; Power conversion; Power system stability; Resonance; Stability analysis; Voltage control; Admittance; impedance; resonance stability; voltage-source converter-high voltage dc (VSC-HVDC);
Journal_Title :
Power Delivery, IEEE Transactions on
DOI :
10.1109/TPWRD.2013.2272382
