Title :
Digital Current Control of a Voltage Source Converter With Active Damping of LCL Resonance
Author :
Wu, Eric ; Lehn, Peter W.
Author_Institution :
Dept. of Electr. & Comput. Eng., Toronto Univ., Ont.
Abstract :
Inductance-capacitor-inductance (LCL)-filters installed at converter outputs offer higher harmonic attenuation than L-filters, but careful design is required to damp LCL resonance, which can cause poorly damped oscillations and even instability. A new topology is presented for a discrete-time current controller which damps this resonance, combining deadbeat current control with optimal state-feedback pole assignment. By separating the state feedback gains into deadbeat and damping feedback loops, transient overcurrent protection is realizable while preserving the desired pole locations. Moreover, the controller is shown to be robust to parameter uncertainty in the grid inductance. Experimental tests verify that fast well-damped transient response and overcurrent protection is possible at low switching frequencies relative to the resonant frequency
Keywords :
damping; digital control; discrete time systems; electric current control; oscillations; overcurrent protection; pole assignment; power convertors; power harmonic filters; state feedback; transient response; LCL resonance; active damping; damping feedback loops; digital current control; discrete-time current controller; harmonic attenuation; inductance-capacitor-inductance filters; optimal state-feedback pole assignment; resonant frequency; transient overcurrent protection; transient response; voltage source converter; Attenuation; Current control; Damping; Feedback loop; Optimal control; Protection; Resonance; Robust control; State feedback; Topology; Electromagnetic interference (EMI); inductance–capacitor–inductance (LCL)-filter; voltage source converters (VSCs);
Journal_Title :
Power Electronics, IEEE Transactions on
DOI :
10.1109/TPEL.2006.880271
