Title :
Impact of unbalance on electrical and torsional resonances in power electronic interfaced wind energy systems
Author_Institution :
Electr. Eng., Univ. of South Florida, Tampa, FL, USA
Abstract :
Type 3 wind generators in series compensated networks could lead to subsynchronous resonances (SSR). Previous research focuses on balanced operation only. In this paper, impact of unbalance on Type 3 wind energy systems is investigated in two aspects: (i) impact on electric resonances and (ii) impact on torsional resonances. In the first aspect, impedance models of the system in DQ domain and phase domain are developed. Particularly, negative sequence impedances are examined. Nyquist stability criterion is applied to detect possible resonances. In the second aspect, transfer functions of the electromagnetic torque versus the rotating speed due to negative sequence components are developed. The impact of negative sequence components on electromechanical damping is then analyzed. The analysis results are verified by time-domain simulation results.
Keywords :
Nyquist criterion; Nyquist stability; electric generators; electric impedance; electromechanical effects; subsynchronous resonance; time-domain analysis; transfer functions; wind power plants; DQ domain; Nyquist stability criterion; SSR; electric resonance; electromagnetic torque; electromechanical damping; impedance model; negative sequence components; negative sequence impedance; phase domain; power electronic interfaced wind energy system; resonance detection; rotating speed; series compensated network; subsynchronous resonance; time-domain simulation; torsional resonance; transfer functions; type 3 wind energy system; type 3 wind generators; Educational institutions; Generators; Impedance; Power electronics; Wind energy; Wind energy generation; Wind power generation;
Conference_Titel :
PES General Meeting | Conference & Exposition, 2014 IEEE
Conference_Location :
National Harbor, MD
DOI :
10.1109/PESGM.2014.6939210
