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Erschienen in:

2012 | OriginalPaper | Buchkapitel

12. Structured Linear Parameter Varying Control of Wind Turbines

verfasst von : Fabiano Daher Adegas, Christoffer Sloth, Jakob Stoustrup

Erschienen in: Control of Linear Parameter Varying Systems with Applications

Verlag: Springer US

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Abstract

High performance and reliability are required for wind turbines to be competitive within the energy market. To capture their nonlinear behavior, wind turbines are often modeled using parameter-varying models. In this chapter, a framework for modelling and controller design of wind turbines is presented. We specifically consider variable-speed, variable-pitch wind turbines with faults on actuators and sensors. Linear parameter-varying (LPV) controllers can be designed by a proposed method that allows the inclusion of faults in the LPV controller design. Moreover, the controller structure can be arbitrarily chosen: static output feedback, dynamic (reduced order) output feedback, decentralized, among others. The controllers are scheduled on an estimated wind speed to manage the parametervarying nature of the model and on information from a fault diagnosis system. The optimization problems involved in the controller synthesis are solved by an iterative LMI-based algorithm. The resulting controllers can also be easily implemented in practice due to low data storage and simple math operations. The performance of the LPV controllers is assessed by nonlinear simulations results.

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Adegas F, Stoustrup J (2011) Robust structured control design via LMI optimization. In: Proceedings of the 18th IFAC world congress, Milano, Italy, pp 7933–7938

Adegas F, Stoustrup J (2011) Structured control of affine linear parameter varying systems. In: Proceedings of the American control conference, San Francisco, CA, USA, pp 739–744

Apkarian P (1997) On the discretization of LMI-synthesized linear parameter-varying controllers. Automatica 33(4):655–661. DOI 10.1016/S0005-1098(96)00211-7MathSciNetMATHCrossRef

Apkarian P, Adams R (1998) Advanced gain-scheduling techniques for uncertain systems. IEEE Trans Contr Syst Technol 6(1):21–32. DOI 10.1109/87.654874CrossRef

Bianchi FD, Battista HD, Mantz RJ (2007) Wind turbine control systems: Principles, modelling and gain scheduling design. Springer, London

Bianchi D, Mantz RJ, Christiansen CF (2005) Gain scheduling control of variable-speed wind energy conversion systems using quasi-LPV models. Contr Eng Pract 13(2):247–255. DOI 10.1016/j.conengprac.2004.03.006CrossRef

Bossanyi EA (2000) The design of closed loop controllers for wind turbines. Wind Energ 3(3):149–163. DOI 10.1002/we.34CrossRef

Bossanyi E, Witcher D (2011) “controller for 5 MW reference turbine”, deliverable 5.1.1, project upwind. Tech. rep., Garrad Hassan & Partners

Caigny JD, Camino JF, Oliveira RCLF, Peres PLD, Swevers J (2010) Gain-scheduled H ₂ and H _∞ control of discrete-time polytopic time-varying systems. IET Contr Theor Appl 4(3):362–380. DOI 10.1049/iet-cta.2008.0364CrossRef

10.

Caigny JD, Camino JF, Oliveira RCLF, Peres PLD, Swevers J (2011) Gain-scheduled dynamic output feedback control for discrete-time LPV systems. Int J Robust Nonlinear Contr DOI 10.1002/rnc.1711

11.

Dolan DSL, Lehn PW (2006) Simulation model of wind turbine 3p torque oscillations due to wind shear and tower shadow. IEEE Trans Energ Convers 21(3):717–724. DOI 10.1109/TEC.2006.874211CrossRef

12.

Esbensen T, Sloth C (2009) Fault diagnosis and fault-tolerant control of wind turbines. Master’s thesis, Aalborg University

13.

Florin I (2004) Anca Daniela Hansen, Poul Srensen, Frede Blaabjerg, Wind Turbine Blockset in Matlab/Simulink

14.

GWEC (2010) Annual market update 2010. Tech. rep., Global Wind Energy Council

15.

Hansen MOL (2008) Aerodynamics of wind turbines. Earthscan, London

16.

Hansen MH, Bye S (2011) Effect of dynamic inflow on tuning of a PI pitch controller

17.

Niss MOK, Esbensen T, Sloth C, Stoustrup J, Odgaard PF (2009) A youla-kucera approach to gain-scheduling with application to wind turbine control. In: Proceedings of the 3rd IEEE multi-conference on systems and control, Saint Petersburg, Russia, pp 1489–1494. DOI 10.1109/CCA.2009.5281172

18.

Odgaard PF, Stoustrup J, Kinnaert M (2009) Fault tolerant control of wind turbines – a benchmark model. In: Proceedings of the 7th IFAC symposium on fault detection, supervision and safety of technical processes, Barcelona, Spain, pp 155–160. DOI 10. 3182/20090630-4-ES-2003.00026

19.

Østergaard KZ (2008) Robust, gain-scheduled control of wind turbines. PhD thesis, Aalborg University

20.

Østergaard K, Brath P, Stoustrup J (2007) Estimation of effective wind speed. J Phys Conf Ser 75(1):1–9. DOI 10.1088/1742-6596/75/1/012082

21.

Østergaard K, Brath P, Stoustrup J (2009) Linear parameter varying control of wind turbines covering both partial load and full load conditions. Int J Robust Nonlinear Contr 19(1):92–116. DOI 10.1002/rnc.1340CrossRef

22.

Rugh W, Shamma J (2000) Research on gain scheduling. Automatica 36(10):1401–1425. DOI 10.1016/S0005-1098(00)00058-3MathSciNetMATHCrossRef

23.

Savini B, Lupto R (2011) Supervisory controller and load calculation with individual pitch controller for 5 MW reference turbine. Tech. rep., GL Garrad Hassan

24.

Skelton RE, Iwasaki T, Grigoriadis K (1998) A unified algebraic approach to linear control design. Taylor & Francis, London

25.

Sloth C, Esbensen T, Niss MOK, Stoustrup J, Odgaard PF (2009) Robust LMI-based control of wind turbines with parametric uncertainties. In: Proceedings of the 3rd IEEE multi-conference on systems and control, Saint Petersburg, Russia, pp 776–781. DOI 10.1109/CCA.2009.5281171

26.

Sloth C, Esbensen T, Stoustrup J (2011) Robust and fault-tolerant linear parameter-varying control of wind turbines. Mechatronics 21(4):645–659. DOI 10.1016/j.mechatronics. 2011.02.001CrossRef

27.

de Souza CE, Barbosa KA, Neto AT (2006) Robust H _∞ filtering for discrete-time linear systems with uncertain time-varying parameters. IEEE Trans Signal Process 54(6):2110–2118. DOI 10.1109/TSP.2006.874349CrossRef

Titel: Structured Linear Parameter Varying Control of Wind Turbines
verfasst von: Fabiano Daher Adegas
Christoffer Sloth
Jakob Stoustrup
Verlag: Springer US
Buch: Control of Linear Parameter Varying Systems with Applications
Print ISBN: 978-1-4614-1832-0

Electronic ISBN: 978-1-4614-1833-7

Copyright-Jahr: 2012
DOI: https://doi.org/10.1007/978-1-4614-1833-7_12