Dynamic Loads and Response of a Spar Buoy Wind Turbine with Pitch-Controlled Rotating Blades: An Experimental Study

Dynamic Loads and Response of a Spar Buoy Wind Turbine with Pitch-Controlled Rotating Blades: An Experimental Study

New large-scale laboratory data are presented on a physical model of a spar buoy wind turbine with angular motion of control surfaces implemented (pitch control). The peculiarity of this type of rotating blade represents an essential aspect when studying floating offshore wind structures. Experiment...

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Bibliographic Details
Main Authors: Sara Russo, Pasquale Contestabile, Andrea Bardazzi, Elisa Leone, Gregorio Iglesias, Giuseppe R. Tomasicchio, Diego Vicinanza
Format: Article
Language:English
Published: MDPI AG 2021-06-01
Series:Energies
Subjects:
spar buoy
floating wind turbine
pitch control
rotating blades
offshore wind
Online Access:https://www.mdpi.com/1996-1073/14/12/3598
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spelling doaj-f3660cd2b2af4fbcbdca2f216fd29f5a2021-07-01T00:24:27ZengMDPI AGEnergies1996-10732021-06-01143598359810.3390/en14123598Dynamic Loads and Response of a Spar Buoy Wind Turbine with Pitch-Controlled Rotating Blades: An Experimental StudySara Russo0Pasquale Contestabile1Andrea Bardazzi2Elisa Leone3Gregorio Iglesias4Giuseppe R. Tomasicchio5Diego Vicinanza6Department of Engineering, University of Campania “Luigi Vanvitelli”, Via Roma, 29, 81031 Aversa, ItalyDepartment of Engineering, University of Campania “Luigi Vanvitelli”, Via Roma, 29, 81031 Aversa, ItalyDepartment of Engineering, University of Campania “Luigi Vanvitelli”, Via Roma, 29, 81031 Aversa, ItalyDepartment of Engineering for Innovation, EUMER Campus Ecotekne, University of Salento, Via Monteroni, 73100 Lecce, ItalySchool of Engineering, University College Cork, College Road, T12 K8AF Cork, IrelandDepartment of Engineering for Innovation, EUMER Campus Ecotekne, University of Salento, Via Monteroni, 73100 Lecce, ItalyDepartment of Engineering, University of Campania “Luigi Vanvitelli”, Via Roma, 29, 81031 Aversa, ItalyNew large-scale laboratory data are presented on a physical model of a spar buoy wind turbine with angular motion of control surfaces implemented (pitch control). The peculiarity of this type of rotating blade represents an essential aspect when studying floating offshore wind structures. Experiments were designed specifically to compare different operational environmental conditions in terms of wave steepness and wind speed. Results discussed here were derived from an analysis of only a part of the whole dataset. Consistent with recent small-scale experiments, data clearly show that the waves contributed to most of the model motions and mooring loads. A significant nonlinear behavior for sway, roll and yaw has been detected, whereas an increase in the wave period makes the wind speed less influential for surge, heave and pitch. In general, as the steepness increases, the oscillations decrease. However, higher wind speed does not mean greater platform motions. Data also indicate a significant role of the blade rotation in the turbine thrust, nacelle dynamic forces and power in six degrees of freedom. Certain pairs of wind speed-wave steepness are particularly unfavorable, since the first harmonic of the rotor (coupled to the first wave harmonic) causes the thrust force to be larger than that in more energetic sea states. The experiments suggest that the inclusion of pitch-controlled, variable-speed blades in physical (and numerical) tests on such types of structures is crucial, highlighting the importance of pitch motion as an important design factor.https://www.mdpi.com/1996-1073/14/12/3598spar buoyfloating wind turbinepitch controlrotating bladesoffshore wind
collection DOAJ
language English
format Article
sources DOAJ
author Sara Russo
Pasquale Contestabile
Andrea Bardazzi
Elisa Leone
Gregorio Iglesias
Giuseppe R. Tomasicchio
Diego Vicinanza
spellingShingle Sara Russo
Pasquale Contestabile
Andrea Bardazzi
Elisa Leone
Gregorio Iglesias
Giuseppe R. Tomasicchio
Diego Vicinanza
Dynamic Loads and Response of a Spar Buoy Wind Turbine with Pitch-Controlled Rotating Blades: An Experimental Study
Energies
spar buoy
floating wind turbine
pitch control
rotating blades
offshore wind
author_facet Sara Russo
Pasquale Contestabile
Andrea Bardazzi
Elisa Leone
Gregorio Iglesias
Giuseppe R. Tomasicchio
Diego Vicinanza
author_sort Sara Russo
title Dynamic Loads and Response of a Spar Buoy Wind Turbine with Pitch-Controlled Rotating Blades: An Experimental Study
title_short Dynamic Loads and Response of a Spar Buoy Wind Turbine with Pitch-Controlled Rotating Blades: An Experimental Study
title_full Dynamic Loads and Response of a Spar Buoy Wind Turbine with Pitch-Controlled Rotating Blades: An Experimental Study
title_fullStr Dynamic Loads and Response of a Spar Buoy Wind Turbine with Pitch-Controlled Rotating Blades: An Experimental Study
title_full_unstemmed Dynamic Loads and Response of a Spar Buoy Wind Turbine with Pitch-Controlled Rotating Blades: An Experimental Study
title_sort dynamic loads and response of a spar buoy wind turbine with pitch-controlled rotating blades: an experimental study
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2021-06-01
description New large-scale laboratory data are presented on a physical model of a spar buoy wind turbine with angular motion of control surfaces implemented (pitch control). The peculiarity of this type of rotating blade represents an essential aspect when studying floating offshore wind structures. Experiments were designed specifically to compare different operational environmental conditions in terms of wave steepness and wind speed. Results discussed here were derived from an analysis of only a part of the whole dataset. Consistent with recent small-scale experiments, data clearly show that the waves contributed to most of the model motions and mooring loads. A significant nonlinear behavior for sway, roll and yaw has been detected, whereas an increase in the wave period makes the wind speed less influential for surge, heave and pitch. In general, as the steepness increases, the oscillations decrease. However, higher wind speed does not mean greater platform motions. Data also indicate a significant role of the blade rotation in the turbine thrust, nacelle dynamic forces and power in six degrees of freedom. Certain pairs of wind speed-wave steepness are particularly unfavorable, since the first harmonic of the rotor (coupled to the first wave harmonic) causes the thrust force to be larger than that in more energetic sea states. The experiments suggest that the inclusion of pitch-controlled, variable-speed blades in physical (and numerical) tests on such types of structures is crucial, highlighting the importance of pitch motion as an important design factor.
topic spar buoy
floating wind turbine
pitch control
rotating blades
offshore wind
url https://www.mdpi.com/1996-1073/14/12/3598
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AT pasqualecontestabile dynamicloadsandresponseofasparbuoywindturbinewithpitchcontrolledrotatingbladesanexperimentalstudy
AT andreabardazzi dynamicloadsandresponseofasparbuoywindturbinewithpitchcontrolledrotatingbladesanexperimentalstudy
AT elisaleone dynamicloadsandresponseofasparbuoywindturbinewithpitchcontrolledrotatingbladesanexperimentalstudy
AT gregorioiglesias dynamicloadsandresponseofasparbuoywindturbinewithpitchcontrolledrotatingbladesanexperimentalstudy
AT giuseppertomasicchio dynamicloadsandresponseofasparbuoywindturbinewithpitchcontrolledrotatingbladesanexperimentalstudy
AT diegovicinanza dynamicloadsandresponseofasparbuoywindturbinewithpitchcontrolledrotatingbladesanexperimentalstudy
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