[EECS Colloquium] Seminar: Thursday, May 4, Faculty Candidate, 11am

[Bollmann, Paul]

Seminar: ECE Faculty Candidate   Thursday May 4th 11:00 – 11:50am KEC 1007   Ted Brekken Postdoctoral Researcher University of Minnesota     A Novel Control Scheme for a Doubly-fed Induction Wind Generator Under Unbalanced Grid Voltage Conditions   Wind energy is often installed in rural, remote areas characterized by weak, unbalanced power transmission grids. In induction wind generators, unbalanced three-phase stator voltages cause a number of problems, such as saturation, over-current, and stress on the mechanical components from torque pulsations. Therefore, for high levels of unbalance, induction wind generators are switched out of the network. This can further weaken the grid. A special type of induction generator, called a doubly-fed induction generator, has found wide use in high-power wind applications. The wound rotor construction of a doubly-fed induction machine allows for rotor current control via a rotor-connected power converter. Control of the rotor currents in turn allows for variable speed operation and reactive power control. The goal of the research is to further extend the control strategy beyond the standard variable speed and reactive power control to also include compensatory features that can correct for the problems caused by an unbalanced stator voltage. This improves the robustness and all-around performance of doubly-fed induction wind generators, allowing them to operate in conditions in which they would normally be removed from the grid. Unbalanced stator voltages appear as a positive and negative sequence 3-phase voltage at the stator terminals. The negative sequence causes a flux field in the machine to rotate counter to the main, positive sequence direction. This causes a second harmonic pulsation in the machine torque (active power) and reactive power. Also, the machine stator currents become unbalanced. When using synchronous frame vector control, the second harmonic disturbance caused by the unbalance will be propagated through all synchronous frame variables. The developed control compensates for the second harmonic, and hence the unbalance, by injecting a supplementary rotor voltage to cancel the second harmonic in both the torque and stator reactive power synchronous frame control loops. This also has the effect of reducing the stator current unbalance. This novel control was implemented and tested on a 15 kW doubly-fed induction machine. Theory and results will be presented.     Biography:   Ted Brekken is postdoctoral researcher at the University of Minnesota and a laboratory instructor at the University of St. Thomas in St. Paul Minnesota. He received his B.S., M.S., and Ph.D. from the University of Minnesota in 1999, 2002, and 2005 respectively. He studied electric vehicle motor design at Postech in Pohang, South Korea in 1999. He also studied wind turbine control at the Norwegian University of Science and Technology in Trondheim, Norway in 2004-2005 on a Fulbright scholarship. His research interests include control, power electronics and electric drives; specifically digital control techniques applied to renewable energy systems.

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