1. Physical Model Tests on Spar Buoy for Offshore Floating Wind Energy Conversion
- Author
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Tomasicchio, Giuseppe Roberto, Vicinanza, Diego, Belloli, Marco, Lugli, Claudio, Latham, John-Paul, Iglesias Rodriguez, Jose Gregorio, Jensen, Bjarne, Vire, Axelle, Monbaliu, Jaak, Taruffi, Federico, Pustina, Luca, Leone, Elisa, Russo, Sara, Francone, Antonio, Fontanella, Alessandro, Di Carlo, Simone, Muggiasca, Sara, Decorte, Griet, Rivera, Irene, Ferrante, Vincenzo, Battistella, Tommaso, Guanche García, Raúl, Martínez Díaz, Abel, Elsässer, Björn, Via-Estrem, Lluis, Xiang, Jiansheng, Andersen, Morten Thøtt, Kofoed, Jens Peter, Bech Kramer, Morten, Musci, Elena, Lusito, Letizia, and Universidad de Cantabria
- Subjects
hydrodynamic behavior ,Hydrodynamic behavior ,offshore structures ,Spar buoy ,floating wind turbine ,spar buoy ,Offshore structures ,Floating wind turbine - Abstract
The present paper describes the experiences gained from the design methodology and operation of a 3D physical modelexperiment aimed to investigate the dynamic behaviour of a spar buoy floating offshore wind turbine. The physical model consists in a Froude-scaled NREL 5MW reference wind turbine (RWT) supported on the OC3-Hywind floating platform. Experimental tests have been performed at Danish Hydraulic Institute (DHI) offshore wave basin within the European Union-Hydralab+ Initiative, in April 2019. The floating wind turbine model has been subjected to a combination of regular and irregular wave attacks and different wind loads. Measurements of displacements, rotations, accelerations, forces response of the floating model and at the mooring lines have been carried out. First, free decay tests have been analysed to obtain the natural frequency and the modal damping ratios of each degree of freedom governing the offshore. Then, the results concerning regular waves, with orthogonal incidence to the structure, are presented. The results show that most of longitudinal dynamic response occurs at the wave frequency and most of lateral dynamic response occurs at rigid-body frequencies. This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 654110, HYDRALAB+.
- Published
- 2020