Adaptive H∞ control of large wind turbines

Author

Bobanac, Vedran ; Vasak, Mario

Author_Institution

BOBLab d.o.o., Zagreb, Croatia

fYear

2015

fDate

17-19 March 2015

Firstpage

85

Lastpage

92

Abstract

Modern, large wind turbines require multiobjective, robust controllers in order to fulfill all the control objectives. In the presented work linear matrix inequality (LMI) approach to H_∞ control and linear parameter-varying (LPV) theory are utilized to design multivariable, adaptive controller which aims at improving rotational speed control and at reducing tower structural loads. Designed H_∞ pitch controller is implemented in the operating region above rated wind speed, in a self-sufficient structure which does not require any additonal control loops. Behaviour of the H_∞ controller is compared with the baseline control system designed by classical mehtods. Simulations are performed in professional software tool GH Bladed and the subsequent analysis is carried out by calculating damage equivalent loads (DEL).

Keywords

H^∞ control; adaptive control; angular velocity control; linear matrix inequalities; linear systems; multivariable control systems; robust control; wind turbines; DEL; H_∞ pitch controller; LMI approach; LPV theory; adaptive H_∞ controller; baseline control system; control loops; damage equivalent loads; linear matrix inequality approach; linear parameter-varying theory; multiobjective robust controllers; professional software tool GH Bladed; rotational speed control; self-sufficient structure; subsequent analysis; wind turbines; Control systems; Mathematical model; Poles and towers; Transfer functions; Vibrations; Wind speed; Wind turbines;

fLanguage

English

Publisher

ieee

Conference_Titel

Industrial Technology (ICIT), 2015 IEEE International Conference on

Conference_Location

Seville

Type

conf

DOI

10.1109/ICIT.2015.7125081

Filename

7125081