Wind energy is a promising alternate energy resource. However, the on-land wind farms are limited by space, noise, and visual pollution and, therefore, many countries build wind farms near the shore. Until now, most offshore wind farms have been built in relatively shallow water (less than 30 m) with fixed tower type wind turbines. Recently, several countries have planned to move wind farms to deep water offshore locations to find stronger and steadier wind fields as compared to near shore locations. For the wind farms in deeper water, floating platforms have been proposed to support the wind turbine. The model tests described in this paper were performed at MARIN (maritime research institute netherlands) with a model setup corresponding to a 1:50 Froude scaling. The wind turbine was a scaled model of the national renewable energy lab (NREL) 5 MW horizontal axis reference wind turbine supported by three different generic floating platforms: a spar, a semisubmersible, and a tension-leg platform (TLP). The wave environment used in the tests is representative of the offshore in the state of Maine. In order to capture coupling between the floating platform and the wind turbine, the 1st bending mode of the turbine tower was also modeled. The main purpose of the model tests was to generate data on coupled motions and loads between the three floating platforms and the same wind turbine for the operational, design, and survival seas states. The data are to be used for the calibration and improvement of the existing design analysis and performance numerical codes. An additional objective of the model tests was to establish the advantages and disadvantages among the three floating platform concepts on the basis of the test data. The paper gives details of the scaled model wind turbine and floating platforms, the setup configurations, and the instrumentation to measure motions, accelerations, and loads along with the wind turbine rpm, torque, and thrust for the three floating wind turbines. The data and data analysis results are discussed in the work of Goupee et al. (2012, “Experimental Comparison of Three Floating Wind Turbine Concepts,” OMAE 2012-83645).
Skip Nav Destination
University of Maine,
35 Flagstaff Road,
54 Pleasant Street,
Houston, TX 77079
Article navigation
Special Section Articles
Model Tests for a Floating Wind Turbine on Three Different Floaters
Andrew J. Goupee,
University of Maine,
35 Flagstaff Road,
Andrew J. Goupee
Advanced Structures and Composites Center
,University of Maine,
35 Flagstaff Road,
Orono, ME 04469
Search for other works by this author on:
Richard W. Kimball,
54 Pleasant Street,
Richard W. Kimball
Maine Maritime Academy
, 54 Pleasant Street,
Castine, ME 04420
Search for other works by this author on:
Kostas F. Lambrakos
Houston, TX 77079
Kostas F. Lambrakos
Technip USA, Inc.
, 11700 Katy Freeway, Suite 150
,Houston, TX 77079
Search for other works by this author on:
Bonjun J. Koo
Andrew J. Goupee
Advanced Structures and Composites Center
,University of Maine,
35 Flagstaff Road,
Orono, ME 04469
Richard W. Kimball
Maine Maritime Academy
, 54 Pleasant Street,
Castine, ME 04420
Kostas F. Lambrakos
Technip USA, Inc.
, 11700 Katy Freeway, Suite 150
,Houston, TX 77079
1Corresponding author.
Contributed by the Ocean, Offshore, and Arctic Engineering Division of ASME for publication in the Journal of Offshore Mechanics and Arctic Engineering. Manuscript received January 14, 2013; final manuscript received May 2, 2013; published online March 24, 2014. Assoc. Editor: Krish Thiagarajan.
J. Offshore Mech. Arct. Eng. May 2014, 136(2): 020907 (11 pages)
Published Online: March 24, 2014
Article history
Received:
January 14, 2013
Revision Received:
May 2, 2013
Citation
Koo, B. J., Goupee, A. J., Kimball, R. W., and Lambrakos, K. F. (March 24, 2014). "Model Tests for a Floating Wind Turbine on Three Different Floaters." ASME. J. Offshore Mech. Arct. Eng. May 2014; 136(2): 020907. https://doi.org/10.1115/1.4024711
Download citation file:
Get Email Alerts
Slamming characteristics of a rigid wedge during symmetric and asymmetric water entry
J. Offshore Mech. Arct. Eng
Layout Optimization of Wave Energy Park Based on Multi-Objective Optimization Algorithm
J. Offshore Mech. Arct. Eng
Wear of Wave Energy Converters Mooring Lines Belts
J. Offshore Mech. Arct. Eng (April 2025)
Related Articles
Experimental Comparison of Three Floating Wind Turbine Concepts
J. Offshore Mech. Arct. Eng (May,2014)
Extreme Dynamic Structural Response Analysis of Catenary Moored Spar Wind Turbine in Harsh Environmental Conditions
J. Offshore Mech. Arct. Eng (November,2011)
Research on the Influence of Helical Strakes and Its Parameters on Dynamic Response of Platform of Floating Wind Turbine Based on Optimization Method of Orthogonal Design
J. Sol. Energy Eng (October,2017)
Effects of Hull Flexibility on the Structural Dynamics of a Tension Leg Platform Floating Wind Turbine
J. Offshore Mech. Arct. Eng (February,2020)
Related Proceedings Papers
Related Chapters
Wind Energy in the U.S.
Wind Energy Applications
A Utility Perspective of Wind Energy
Wind Turbine Technology: Fundamental Concepts in Wind Turbine Engineering, Second Edition
Instrument Calibration Methods
Metrology and Instrumentation: Practical Applications for Engineering and Manufacturing