AZIMUT project (Spanish CENIT R&D program) is designed to establish the technological groundwork for the subsequent development of a large-scale offshore wind turbine. The project (2010–2013) has analyzed different alternative configurations for the floating offshore wind turbines (FOWT): SPAR, tension leg platform (TLP), and semisubmersible platforms were studied. Acciona, as part of the consortium, was responsible of scale-testing a semisubmersible platform to support a 1.5 MW wind turbine. The geometry of the floating platform considered in this paper has been provided by the Hiprwind FP7 project and is composed by three buoyant columns connected by bracings. The main focus of this paper is on the hydrodynamic modeling of the floater, with especial emphasis on the estimation of the wave drift components and their effects on the design of the mooring system. Indeed, with natural periods of drift around 60 s, accurate computation of the low-frequency second-order components is not a straightforward task. Methods usually adopted when dealing with the slow-drifts of deep-water moored systems, such as the Newman's approximation, have their errors increased by the relatively low resonant periods of the floating system and, since the effects of depth cannot be ignored, the wave diffraction analysis must be based on full quadratic transfer functions (QTFs) computations. A discussion on the numerical aspects of performing such computations is presented, making use of the second-order module available with the seakeeping software wamit®. Finally, the paper also provides a preliminary verification of the accuracy of the numerical predictions based on the results obtained in a series of model tests with the structure fixed in bichromatic waves.
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June 2015
Research-Article
Influence of Wave Induced Second-Order Forces in Semisubmersible FOWT Mooring Design
Carlos Lopez-Pavon,
Carlos Lopez-Pavon
Acciona Energia
,Madrid 28108
, Spain
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Rafael A. Watai,
Rafael A. Watai
Numerical Offshore Tank (TPN),
e-mail: rafael.watai@tpn.usp.br
University of São Paulo
,São Paulo 05508-010
, Brazil
e-mail: rafael.watai@tpn.usp.br
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Felipe Ruggeri,
Felipe Ruggeri
Numerical Offshore Tank (TPN),
e-mail: felipe.ruggeri@tpn.usp.br
University of São Paulo
,São Paulo 05508-010
, Brazil
e-mail: felipe.ruggeri@tpn.usp.br
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Alexandre N. Simos,
Alexandre N. Simos
Department of Naval Architecture
and Ocean Engineering,
Escola Politécnica,
e-mail: alesimos@usp.br
and Ocean Engineering,
Escola Politécnica,
University of São Paulo
,São Paulo 05508-010
, Brazil
e-mail: alesimos@usp.br
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Antonio Souto-Iglesias
Antonio Souto-Iglesias
Department of Naval Architecture (ETSIN),
e-mail: antonio.souto@upm.es
Technical University of Madrid (UPM)
,Madrid 28040
, Spain
e-mail: antonio.souto@upm.es
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Carlos Lopez-Pavon
Acciona Energia
,Madrid 28108
, Spain
Rafael A. Watai
Numerical Offshore Tank (TPN),
e-mail: rafael.watai@tpn.usp.br
University of São Paulo
,São Paulo 05508-010
, Brazil
e-mail: rafael.watai@tpn.usp.br
Felipe Ruggeri
Numerical Offshore Tank (TPN),
e-mail: felipe.ruggeri@tpn.usp.br
University of São Paulo
,São Paulo 05508-010
, Brazil
e-mail: felipe.ruggeri@tpn.usp.br
Alexandre N. Simos
Department of Naval Architecture
and Ocean Engineering,
Escola Politécnica,
e-mail: alesimos@usp.br
and Ocean Engineering,
Escola Politécnica,
University of São Paulo
,São Paulo 05508-010
, Brazil
e-mail: alesimos@usp.br
Antonio Souto-Iglesias
Department of Naval Architecture (ETSIN),
e-mail: antonio.souto@upm.es
Technical University of Madrid (UPM)
,Madrid 28040
, Spain
e-mail: antonio.souto@upm.es
Contributed by the Ocean, Offshore, and Arctic Engineering Division of ASME for publication in the JOURNAL OF OFFSHORE MECHANICS AND ARCTIC ENGINEERING. Manuscript received July 1, 2013; final manuscript received March 23, 2015; published online April 16, 2015. Editor: Solomon Yim.
J. Offshore Mech. Arct. Eng. Jun 2015, 137(3): 031602 (10 pages)
Published Online: June 1, 2015
Article history
Received:
July 1, 2013
Revision Received:
March 23, 2015
Online:
April 16, 2015
Citation
Lopez-Pavon, C., Watai, R. A., Ruggeri, F., Simos, A. N., and Souto-Iglesias, A. (June 1, 2015). "Influence of Wave Induced Second-Order Forces in Semisubmersible FOWT Mooring Design." ASME. J. Offshore Mech. Arct. Eng. June 2015; 137(3): 031602. https://doi.org/10.1115/1.4030241
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