Torsional Damping Control of Gearless Full-Converter Large Wind Turbine Generators with Permanent Magnet Synchronous Machines

Abstract

This study examines the torsional damping requirements for megawatt scale wind turbines having synchronous generators with full-wave ac/dc/ac inversion technology. The particular type has a low-speed permanent magnet synchronous generator with gearless drive train and a full power-frequency converter. The electrical connection via the full converter provides no torsional damping to reduce speed oscillations. With a large number of poles, this means that torsional oscillations in the mechanical drive train can be easily excited. The analysis investigates how control algorithms for the converters can help mitigate such torsional oscillations. The torsional oscillations, both during continuous operation in wind and during a voltage dip, are analysed. Improvements resulting from a controller are presented. A windfarm model is developed to analyse the possibility of interaction between individual controllers.

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References

The Grid Code, National Grid Electricity Transmission Std. [Online]. Available: http://www.nationalgrid.com/uk.

Fernandez

J.L.

, “Grid codes for wind energy in Spain and developments in Europe”, in Large Scale Integration of Wind Energy, Brussels, Belgium, Nov. 2006.

Windfarm Power Station Grid Code Provisions, ESB National Grid Std. [Online]. Available: http://www.eirgrid.com.

Grid Code: High and Extra High Voltage, E.On Netz GmbH Std., Sept. 2006.

Hansen

A.D.

Hansen

L.H.

, Wind turbine concept market penetration over 10 years (1995–2004), Wind Energy, vol. 10, No. 1, pp. 81–97, Jan. 2007.

DIgSILENT GmbH. [Online]. Available: http://www.digsilent.de/.

Sørensen

P.E.

Hansen

A.D.

Janosi

Bech

Bak-Jensen

, Simulation of interaction between windfarm and power system, Risø National Laboratory, Roskilde, Denmark, Tech. Rep. R-1281, Dec. 2001.

Slootweg

J.G.

Polinder

Kling

W.L.

, Dynamic modelling of a wind turbine with direct drive synchronous generator and back to back voltage source converter and its controls, in Proc European Wind Energy Conference, Copenhagen, Denmark, July 2001, pp. 1014–1017.

Akhmatov

, Analysis of dynamic behaviour of electric power systems with large amounts of wind power, Ph.D. dissertation Tech. Univ. of Denmark, Lyngby Denmark, 2003. [Online] Available: http://www.dtu.dk. Also published by MultiScience Publishers, UK 2006.

10.

Westlake

A.J.G.

Bumby

J.R.

Spooner

, Damping the power angle oscillations of a permanent magnet synchronous generator with particular reference to wind turbine applications, IEE Proc. on Electric Power Applications, 1996, Vol. 143, no. 3, pp. 269–280.

11.

Krause

P.C.

Wasynczuk

Sudhoff

S.D.

, Analysis of Electrical Machinery and Drive Systems, ser. Power Engineering. IEEE Press, 2002.

12.

Kundur

, Power System Stability and Control. McGraw-Hill Professional, 1994.

13.

Pierik

J.T.G.

Morren

Wiggelinkhuizen

E.J.

de Haan

S.W.H.

van Engelen

T.G.

Bozelie

, Electrical and control aspects offshore windfarms (ERAO II) Volume 1: Dynamic models of windfarms, ECN, Tech. Rep.

14.

Mohan

Undeland

Robbins

, Power Electronics: Converters, Drives and Applications, 3rd Ed. Wiley, 2002.

15.

Heier

, Grid Integration of Wind Energy Conversion Systems, 2nd Ed, Wiley, 2006.

16.

Ramtharan

Jenkins

Anaya-Lara

, Modelling and control of synchronous generators for wide-range variable speed wind turbines, Wind Energy, vol. 10, No. 3, Mar. 2007.

17.

Michalke

Hansen

A.D.

Harthopf

Control Strategy of a Variable Speed Wind Turbine with Multipole Permanent Magnet Synchronous Generator, European Wind Energy Conference, Milan, Italy, 2007.

18.

Jauch

, Transient and Dynamic Control of a Variable Speed Wind Turbine with Synchronous Generator, Wind Energy, vol. 10, No. 3, pp. 247–269, Feb. 2007.