Multi-resolution wavelet pitch controller for spar-type floating offshore wind turbines including wave-current interactions

This paper proposes a wavelet multi-resolution based individual pitch control strategy for spar-type floating offshore wind turbines (FOWTs) and investigates its performance under joint wind-wave-current loads considering the effects of wave-current interactions. A multi-resolution analysis (MRA) ba...

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Bibliographic Details
Published in:Journal of sound and vibration 2020-03, Vol.470, p.115170, Article 115170
Main Authors: Sarkar, Saptarshi, Chen, Lin, Fitzgerald, Breiffni, Basu, Biswajit
Format: Article
Language:English
Subjects:
Aerodynamic loads
Computer simulation
Controllers
Energy conservation
Frequencies
Individual pitch control
Linear quadratic regulator
Multi-resolution wavelet LQR
Optimal control
Pitch (inclination)
Resonant frequencies
Spar-type floating offshore wind turbine
Turbines
Wave-current interaction
Wavelet analysis
Wavelet transforms
Wind power
Wind turbines
Wind waves
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Summary:This paper proposes a wavelet multi-resolution based individual pitch control strategy for spar-type floating offshore wind turbines (FOWTs) and investigates its performance under joint wind-wave-current loads considering the effects of wave-current interactions. A multi-resolution analysis (MRA) based wavelet controller that modifies an optimal control problem cast in linear quadratic regulator (LQR) form constrained to a band of frequency has been used in this paper. The weighting matrices of the LQ regulator are varied in different frequency bands depending on the emphasis to be placed on the response energy and control effort to minimize the cost functional of that frequency band. This formulation results in frequency band dependent controller gains that lead to a time-varying controller. Daubechies wavelet is used in the MRA based filter that ensures perfect decomposition of the time signal over a finite interval and fast numerical implementation for control application. The multi-resolution wavelet-LQR individual blade pitch controller is used to control blade out-of-plane vibrations with additional emphasis on 1P frequency of the wind turbine. The emphasis on 1P frequency along with the blade's out-of-plane natural frequency is shown to reduce aerodynamic loads corresponding to 1st rotational frequency of the wind turbine which in turn reduces vibrations in other modes of the wind turbine. The proposed controller is simulated using a 5-MW baseline offshore wind turbine with realistic operational conditions including wave-current interactions. The controller has been proved to be effective in every analyzed met-ocean condition.
ISSN:0022-460X
1095-8568
DOI:10.1016/j.jsv.2020.115170