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Abstract

A three-mass mechanical model that considers both shaft and blade flexibilities was used for the design of a torsional damper to damp drive-train vibrations in a wind turbine. Two torsional dampers were designed: one considering only the drive-train mode and another considering both the drive-train and blade in-plane symmetrical modes. The dampers performance was tested on a simple wind turbine model in Simulink® and then implemented in a more complete model in GH Bladed®. The simulation results on both wind turbine models correlate very well. This result indicates that a three-mass model is a good model for representing the shaft and blade flexibilities for designing a torsional damper. Simulation results show that considering both drive-train and blade in-plane mode frequencies when designing the torsional damper can lead to a better performance in damping torsional vibrations.

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References

Kurronen

Haavisto

Pyrhönen

Challenges in applying permanent magnet (PM) technology to wind power generators in EWEC. 2010. Brussels.

Burton

Sharpe

Jenkins

Bossanyi

E. A.

, Wind Energy Handbook. 2001, John Wiley & Sons Ltd. p. 498.

Cazelitz

Kleinkauf

Kruger

Petschenka

Reichard

Storzel

Reduction of fatigue loads on wind energy converters by advanced control methods. in EWEC. 1997. Dublin, Ireland.

Laubrock

Woldmann

T. P.

Bilges

, Method for the active damping of the drive train in a wind energy plant. 2009, Nordex Energy GmbH: United States. p. 5.

Suryanarayanan

Avangliano

Barbu

, Vibration damping method for variable speed wind turbines. 2008, General Electric Company: United States. p. 12.

Nielsen

, Damping of drive train oscillations by DC-Link absorption means. 2011, Vestas Wind Systems: International. p. 21.

Bossanyi

E. A.

, Wind Turbine Control for Load Reduction. Wind Energy, 2003. 6 (3): P. 229–244.

Bossanyi

E. A.

, The Design of closed loop controllers for wind turbines. Wind Energy, 2000. 3 (3): P. 149–163.

Bossanyi

E. A.

Controller for 5MW reference turbine. 2009 [cited 2011 26 June]; Available from: www.upwind.eu/.

10.

Zuo-Xia

Li-Zhe

Heng-Yi

Xiao-Dong

Damping Control Study of the Drive Train of DFIG Wind Turbine. in

International Conference on Energy and Environment Technology, (ICEET). 2009.

11.

Hansen

A. D.

Michalke

, Multi-pole permanent magnet synchronous generator wind turbines' grid support capability in uninterrupted operation during grid faults. Renewable Power Generation IET, 2009. 3 (3): P. 333–348.

12.

Hua

Dewei

Bin

Geng

, Active Damping for PMSG-Based WECS With DC-Link Current Estimation. IEEE Transactions on Industrial Electronics, 2011. 58(4): P. 1110–1119.

13.

Hansen

A. D.

Michalke

, Modelling and control of variable-speed multi-pole permanent magnet synchronous generator wind turbine. Wind Energy, 2008. 11 (5): P. 537–554.

14.

Ramtharan

, Control of Variable speed wind generators. PhD thesis, The University of Manchester, 2008.

15.

Ramtharan

Jenkins

Anaya-Lara

Bossanyi

, Influence of rotor structural dynamics representations on the electrical transient performance of FSIG and DFIG wind turbines. Wind Energy, 2007. 10 (4): P. 293–301.

16.

Chen

Transient Stability Analysis of Wind Turbines with Induction Generators Considering Blades and Shaft Flexibility. in Industrial Electronics Society, 2007. IECON 2007. 33rd Annual Conference of the IEEE. 2007.

17.

Harris

C. M.

, Shock and vibration handbook. 1996, McGraw Hill. p. 39.1–38.14.

18.

Thomas

W.T.

, Theory of vibration with applications. 1993, Chapman & Hall. p. 131–145, 268–337.

19.

Geng

Yang

, Comparison of oscillation damping capability in three power control strategies for PMSG-based WECS. Wind Energy, 2011. 14 (3): P. 389–406.

Torsional Damping considering Both Shaft and Blade Flexibilities

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