Experimental Verification of the Hydro-elastic Model of A Scaled Floating Offshore Wind Turbine

Signe Møller Mortensen, Kasper Laugesen, Jesper Kirkegaard Jensen, Kasper Jessen, Mohsen N. Soltani

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2 Citationer (Scopus)

Resumé

Modeling is essential for designing control and making prediction. For the case of floating offshore wind turbine, providing a model that is validated is a challenging task as testing prototypes in the field are expensive and difficult and it may cause loss of turbine. For this reason, wind turbines are scaled down to be tested at a wind and wave laboratory where deep sea environment is realized after scaling. In this paper, theoretical hydro-elastic model of a floating offshore wind turbine is presented. The hydro-elastic model that is simulated both by a Simulink model and by high fidelity wind turbine simulation tool, FAST, is then verified by laboratory experiments. A comparison is performed to show the model dynamics compared with the experimental results. Presented results show that the model of the laboratory-scale wind turbine correctly represents the main dynamic behavior of the theoretical model.
OriginalsprogEngelsk
TitelProceedings of the 2nd IEEE Conference on Control Technology and Applications : CCTA
Antal sider8
Forlag/udgivende institutionIEEE Press
Udgivelsesdato26 okt. 2018
Sider1623-1630
Artikelnummer8511565
ISBN (tryk)978-1-5386-7699-8
ISBN (elektronisk)978-1-5386-7698-1
DOI'er
PublikationsstatusUdgivet - 26 okt. 2018
Begivenheder2018 IEEE Conference on Control Technology and Applications (CCTA) - The Scandic Hotel Copenhagen, Copenhagen, Danmark
Varighed: 21 aug. 201824 aug. 2018

Konference

Konference2018 IEEE Conference on Control Technology and Applications (CCTA)
AfholdelsesstedThe Scandic Hotel Copenhagen
LandDanmark
ByCopenhagen
Periode21/08/201824/08/2018

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Offshore wind turbines
Wind turbines
Dynamic models
Turbines
Testing

Citer dette

Mortensen, S. M., Laugesen, K., Kirkegaard Jensen, J., Jessen, K., & N. Soltani, M. (2018). Experimental Verification of the Hydro-elastic Model of A Scaled Floating Offshore Wind Turbine. i Proceedings of the 2nd IEEE Conference on Control Technology and Applications: CCTA (s. 1623-1630). [8511565] IEEE Press. https://doi.org/10.1109/CCTA.2018.8511565
Mortensen, Signe Møller ; Laugesen, Kasper ; Kirkegaard Jensen, Jesper ; Jessen, Kasper ; N. Soltani, Mohsen. / Experimental Verification of the Hydro-elastic Model of A Scaled Floating Offshore Wind Turbine. Proceedings of the 2nd IEEE Conference on Control Technology and Applications: CCTA. IEEE Press, 2018. s. 1623-1630
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title = "Experimental Verification of the Hydro-elastic Model of A Scaled Floating Offshore Wind Turbine",
abstract = "Modeling is essential for designing control and making prediction. For the case of floating offshore wind turbine, providing a model that is validated is a challenging task as testing prototypes in the field are expensive and difficult and it may cause loss of turbine. For this reason, wind turbines are scaled down to be tested at a wind and wave laboratory where deep sea environment is realized after scaling. In this paper, theoretical hydro-elastic model of a floating offshore wind turbine is presented. The hydro-elastic model that is simulated both by a Simulink model and by high fidelity wind turbine simulation tool, FAST, is then verified by laboratory experiments. A comparison is performed to show the model dynamics compared with the experimental results. Presented results show that the model of the laboratory-scale wind turbine correctly represents the main dynamic behavior of the theoretical model.",
keywords = "Floating, Wind Turbine, Hydrodynamic, Scaled Wind Turbine, Experimental, Modeling",
author = "Mortensen, {Signe M{\o}ller} and Kasper Laugesen and {Kirkegaard Jensen}, Jesper and Kasper Jessen and {N. Soltani}, Mohsen",
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Mortensen, SM, Laugesen, K, Kirkegaard Jensen, J, Jessen, K & N. Soltani, M 2018, Experimental Verification of the Hydro-elastic Model of A Scaled Floating Offshore Wind Turbine. i Proceedings of the 2nd IEEE Conference on Control Technology and Applications: CCTA., 8511565, IEEE Press, s. 1623-1630, 2018 IEEE Conference on Control Technology and Applications (CCTA), Copenhagen, Danmark, 21/08/2018. https://doi.org/10.1109/CCTA.2018.8511565

Experimental Verification of the Hydro-elastic Model of A Scaled Floating Offshore Wind Turbine. / Mortensen, Signe Møller; Laugesen, Kasper; Kirkegaard Jensen, Jesper; Jessen, Kasper; N. Soltani, Mohsen.

Proceedings of the 2nd IEEE Conference on Control Technology and Applications: CCTA. IEEE Press, 2018. s. 1623-1630 8511565.

Eksport af forskningsdata: Bidrag til bog/antologi/rapport/konference proceedingKonferenceartikel i proceedingForskningpeer review

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AU - Laugesen, Kasper

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AU - N. Soltani, Mohsen

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Mortensen SM, Laugesen K, Kirkegaard Jensen J, Jessen K, N. Soltani M. Experimental Verification of the Hydro-elastic Model of A Scaled Floating Offshore Wind Turbine. i Proceedings of the 2nd IEEE Conference on Control Technology and Applications: CCTA. IEEE Press. 2018. s. 1623-1630. 8511565 https://doi.org/10.1109/CCTA.2018.8511565