Integration of multiple passive load mitigation technologies by automated design optimization—The case study of a medium‐size onshore wind turbine

Integration of multiple passive load mitigation technologies by automated design optimization—The case study of a medium‐size onshore wind turbine

The present work considers the application to a medium‐size onshore wind turbine of passive load mitigation technologies, first individually and then integrated together. The study is conducted with the help of a comprehensive automated design optimization procedure, which eases the generation and c...

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Bibliographic Details
Published in:Wind energy (Chichester, England) England), 2019-01, Vol.22 (1), p.65-79
Main Authors: Bortolotti, Pietro, Bottasso, Carlo L., Croce, Alessandro, Sartori, Luca
Format: Article
Language:eng
Subjects:
Automation
Case studies
Coupling
Design
Design optimization
Energy conservation
Energy costs
Fibers
Laminates
Mitigation
onshore wind
Optimization
passive load alleviation
Power loss
Suction
Sweeping
systems engineering
Turbine blades
Turbines
Wind power
wind turbine design
Wind turbines
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Summary:The present work considers the application to a medium‐size onshore wind turbine of passive load mitigation technologies, first individually and then integrated together. The study is conducted with the help of a comprehensive automated design optimization procedure, which eases the generation and comparison of consistent solutions, each satisfying the same overall requirements. Passive load mitigation is here obtained by inducing bend‐twist coupling to the blades. The coupling is generated by rotating the fibers of anisotropic laminates, by the aerodynamic sweeping of the blade and by offsetting the spar caps in opposite directions on the pressure and suction sides. The first two solutions yield significant benefits, while the third, for this particular wind turbine, is ineffective. In addition, the typical power losses associated with bend‐twist coupled blades are reduced by a novel regulation strategy that varies the fine pitch setting in the partial load region. After having considered each load mitigation technology by itself, fiber rotation and sweeping are combined together and used to design a rotor with a larger swept area. The final design generates cost of energy savings thanks to a large‐diameter, highly coned, soft‐in‐bending rotor that results in lower turbine costs and a higher energy capture compared with the baseline design.
ISSN:1095-4244
1099-1824