Performance Optimization of Wind Turbine Rotors with Active Flow Control (Part 1)

This article describes the performance optimization of wind turbine rotors with active flow control. The active Gurney flap concept was tested in the wind tunnel under dynamic AoA variations to simulate unsteady inflow conditions. A high-deflection micro flap was actuated by four digital electric se...

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Bibliographic Details
Published in:Mechanical engineering (New York, N.Y. 1919) N.Y. 1919), 2012-04, Vol.134 (4), p.51-51
Main Authors: Pechlivanoglou, G, Nayeri, C.N, Paschereit, C.O
Format: Magazinearticle
Language:English
Subjects:
Active control
Aerodynamics
Aeroelasticity
Air-turbines
Blades
Electric currents
Flow control
Installations
Investigations
Load
Neural networks
Product information
Reduction
Rotors
Turbines
Wind power
Wind turbines
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Summary:This article describes the performance optimization of wind turbine rotors with active flow control. The active Gurney flap concept was tested in the wind tunnel under dynamic AoA variations to simulate unsteady inflow conditions. A high-deflection micro flap was actuated by four digital electric servos with a maximum deflection rate of 360°/sec. A custom code was created to allow dynamic AoA variations of the test wing with simultaneous dynamic force measurements. During the dynamic investigations, various control strategies were tested, starting from standard PID controllers with semi-empirical parameter tuning models to Direct Inverse Controllers with neural network tuning strategies and pure self-learning neural network controllers. The results of the closed-loop measurements using the manually tuned PID controller showed a reduction potential for the dynamic lift loads in the range of 70% as well as a stable controller behavior. The Direct Inverse Controller not only showed a load reduction of 36.8%, but also significant improvement potential with respect to its fine-tuning.
ISSN:0025-6501
1943-5649
DOI:10.1115/1.2012-APR-8