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Wind-wave induced dynamic response analysis for motions and mooring loads of a spar-type offshore floating wind turbine 被引量:22

Wind-wave induced dynamic response analysis for motions and mooring loads of a spar-type offshore floating wind turbine
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摘要 Due to the energy crisis and the environmental issues like pollution and global warming, the exploration for renewable and clean energies becomes crucial. The offshore floating wind turbines(OFWTs) draw a great deal of attention recently as a means to exploit the steadier and stronger wind resources available in deep water seas. This paper studies the hydrodynamic characteristics of a spar-type wind turbine known as the OC3-Hywind concept and the dynamic responses of the turbine. Response characteristics of motions and mooring loads of the system under different sea states are evaluated and the effects of the loads induced by the wind and the wave on the system are discussed. The calculations are carried out with the numerical simulation code FAST in the time domain and the frequency analysis is made by using the FFT method. The results and the conclusions from this paper might help better understand the behavior characteristics of the floating wind turbine system under actual ocean environments and provide valuable data in design and engineering practice. Due to the energy crisis and the environmental issues like pollution and global warming, the exploration for renewable and clean energies becomes crucial. The offshore floating wind turbines(OFWTs) draw a great deal of attention recently as a means to exploit the steadier and stronger wind resources available in deep water seas. This paper studies the hydrodynamic characteristics of a spar-type wind turbine known as the OC3-Hywind concept and the dynamic responses of the turbine. Response characteristics of motions and mooring loads of the system under different sea states are evaluated and the effects of the loads induced by the wind and the wave on the system are discussed. The calculations are carried out with the numerical simulation code FAST in the time domain and the frequency analysis is made by using the FFT method. The results and the conclusions from this paper might help better understand the behavior characteristics of the floating wind turbine system under actual ocean environments and provide valuable data in design and engineering practice.
作者 马钰 胡志强 肖龙飞
机构地区 State Key Laboratory of Ocean Engineering
出处 《Journal of Hydrodynamics》 SCIE EI CSCD 2014年第6期865-874,共10页 水动力学研究与进展B辑(英文版)
基金 Project supported by the State Key Laboratory of Ocean Engineering,Shanghai Jiao Tong University(Grant No.GKZD010023)
关键词 offshore floating wind turbine wind-and wave-induced response analysis numerical simulation effective RAO offshore floating wind turbine,wind-and wave-induced response analysis,numerical simulation,effective RAO
分类号 TM614 [电气工程—电力系统及自动化]
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参考文献16

  • 1JONKMAN J., BUTTERFIELD S. and MUSIAL W. et al. Definition of a 5-MW reference wind turbine for off- shore system development[R]. Technical Report NREL/ TP-500-38060, Golden, Colorado, USA: NREL, 2009.
  • 2JONKMAN J. Dynamics of offshore floating wind tur- bines-Model development and verification[J]. Wind Energy, 2009, 12(5): 459-492.
  • 3JONKMAN J., LARSEN T. J. and HANSEN A. M. et al. Offshore code comparison collaboration within lEA wind Task 23: Phase IV results regarding floating wind turbine modeling[C]. European Wind Energy Confe- rence. Warsaw, Poland, 2010.
  • 4MADJID K., MOAN T. Wave-and wind-induced dyna- mic response of a spar-type offshore wind turbine[J]. Journal of waterway, port, coastal, and ocean engi- neering, 2011, 138(1): 9-20.
  • 5SKAARE B., HANSON T. D. and NIELSEN F. G. et al. Integrated dynamic analysis of floating offshore wind turbines[C]. European Wind Energy Conference and Exhibition. Milan, Italy, 2007.
  • 6DOMINIQUE R., CERMELLI C. and AUBAULT A. et al. Wind float: A floating foundation for offshore wind turbines[J]. Journal of Renewable and Sustainable Energy, 2010, 2(3): 033104.
  • 7HYUNKYOUNG S., CHO S. and JUNG K. Model test of an inverted conical cylinder floating offshore wind turbine moored by a spring-tensioned-leg[J]. Interna- tional Journal of Naval Architecture and Ocean En- gineering, 2014, 6(1): 1-13.
  • 8MARTIN H. R., KIMBALL R. W. and V1SELLI A. M. et al. Methodology for wind/wave basin testing of floa- ting offshore wind turbines[J]. Journal of Offshore Mechanics and Arctic Engineering, 2014, 136(2): 020905.
  • 9KOO B. J., GOUPEE A. J. and KIMBALL R. W. et al. Model tests for a floating wind turbine on three di- fferent floaters[J]. Journal of Offshore Mechanics and Arctic Engineering, 2014, 136(2): 020907.
  • 10GOUPEE A. J., KOO B. J. and KIMBALL R. W. et al. Experimental comparison of three floating wind turbine concepts[J]. Journal of Offshore Mechanics and Arc- tic Engineering, 2014, 136(2): 020906.

同被引文献121

引证文献22

二级引证文献94

Journal of Hydrodynamics
2014年 第6期

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