SEARCH

SEARCH BY CITATION

Cited in:

CrossRef

This article has been cited by:

  1. 1
    Sara Salehyar, Qiang Zhu, Aerodynamic dissipation effects on the rotating blades of floating wind turbines, Renewable Energy, 2015, 78, 119

    CrossRef

  2. 2
    Hezhen Yang, Yun Zhu, Qijin Lu, Jun Zhang, Dynamic reliability based design optimization of the tripod sub-structure of offshore wind turbines, Renewable Energy, 2015, 78, 16

    CrossRef

  3. 3
    Wei Shi, Jonghoon Han, Changwan Kim, Daeyong Lee, Hyunkyoung Shin, Hyunchul Park, Feasibility study of offshore wind turbine substructures for southwest offshore wind farm project in Korea, Renewable Energy, 2015, 74, 406

    CrossRef

  4. 4
    Y-J. Lee, C.-Y. Ho, Z.-Z. Huang, Hydrodynamic Responses of a Spar-Type Floating Wind Turbine in High Waves, Journal of Mechanics, 2015, 31, 01, 105

    CrossRef

  5. 5
    M.A. Benitz, M.A. Lackner, D.P. Schmidt, Hydrodynamics of offshore structures with specific focus on wind energy applications, Renewable and Sustainable Energy Reviews, 2015, 44, 692

    CrossRef

  6. 6
    Tonio Sant, David Bonnici, Russell Farrugia, Daniel Micallef, Measurements and modelling of the power performance of a model floating wind turbine under controlled conditions, Wind Energy, 2015, 18, 5
  7. 7
    Bing Feng Ng, Rafael Palacios, J. Michael R. Graham, Model-based aeroelastic analysis and blade load alleviation of offshore wind turbines, International Journal of Control, 2015, 1

    CrossRef

  8. 8
    Anand P. Deshmukh, James T. Allison, Multidisciplinary dynamic optimization of horizontal axis wind turbine design, Structural and Multidisciplinary Optimization, 2015,

    CrossRef

  9. 9
    E.Y. Choi, J.R. Cho, Y.U. Cho, W.B. Jeong, S.B. Lee, S.P. Hong, H.H. Chun, Numerical and experimental study on dynamic response of moored spar-type scale platform for floating offshore wind turbine, Structural Engineering and Mechanics, 2015, 54, 5, 909

    CrossRef

  10. 10
    Michael Borg, Maurizio Collu, Offshore floating vertical axis wind turbines, dynamics modelling state of the art. Part III: Hydrodynamics and coupled modelling approaches, Renewable and Sustainable Energy Reviews, 2015, 46, 296

    CrossRef

  11. 11
    Amir Rasekhi Nejad, Erin E. Bachynski, Marit I. Kvittem, Chenyu Luan, Zhen Gao, Torgeir Moan, Stochastic dynamic load effect and fatigue damage analysis of drivetrains in land-based and TLP, spar and semi-submersible floating wind turbines, Marine Structures, 2015, 42, 137

    CrossRef

  12. 12
    Thanh-Toan Tran, Dong-Hyun Kim, The platform pitching motion of floating offshore wind turbine: A preliminary unsteady aerodynamic analysis, Journal of Wind Engineering and Industrial Aerodynamics, 2015, 142, 65

    CrossRef

  13. 13
    Yu MA, Zhi-qiang HU, Long-fei XIAO, Wind-wave induced dynamic response analysis for motions and mooring loads of a spar-type offshore floating wind turbine, Journal of Hydrodynamics, Ser. B, 2015, 26, 6, 865

    CrossRef

  14. 14
    Antoni Calderer, Xin Guo, Lian Shen, Fotis Sotiropoulos, Coupled fluid-structure interaction simulation of floating offshore wind turbines and waves: a large eddy simulation approach, Journal of Physics: Conference Series, 2014, 524, 012091

    CrossRef

  15. 15
    Nianxin Ren, Yugang Li, Jinping Ou, Coupled wind-wave time domain analysis of floating offshore wind turbine based on Computational Fluid Dynamics method, Journal of Renewable and Sustainable Energy, 2014, 6, 2, 023106

    CrossRef

  16. 16
    Namkug Ku, Sol Ha, Myoung-Il Roh, Crane Modeling and Simulation in Offshore Structure Building Industry, International Journal of Computer Theory and Engineering, 2014, 6, 3, 278

    CrossRef

  17. 17
    Wei Shi, Hyun-Chul Park, Sangkwon Na, Jinseop Song, Sangjin Ma, Chang-Wan Kim, Dynamic analysis of three-dimensional drivetrain system of wind turbine, International Journal of Precision Engineering and Manufacturing, 2014, 15, 7, 1351

    CrossRef

  18. 18
    Namkug Ku, Sol Ha, Dynamic response analysis of heavy load lifting operation in shipyard using multi-cranes, Ocean Engineering, 2014, 83, 63

    CrossRef

  19. 19
    S.E. Hirdaris, W. Bai, D. Dessi, A. Ergin, X. Gu, O.A. Hermundstad, R. Huijsmans, K. Iijima, U.D. Nielsen, J. Parunov, N. Fonseca, A. Papanikolaou, K. Argyriadis, A. Incecik, Loads for use in the design of ships and offshore structures, Ocean Engineering, 2014, 78, 131

    CrossRef

  20. 20
    Yulin Si, Hamid Reza Karimi, Huijun Gao, Modelling and optimization of a passive structural control design for a spar-type floating wind turbine, Engineering Structures, 2014, 69, 168

    CrossRef

  21. 21
    Dongsheng Qiao, Jinping Ou, Mooring Line Damping Estimation for a Floating Wind Turbine, The Scientific World Journal, 2014, 2014, 1

    CrossRef

  22. 22
    F. Viadero, A. Fernández, M. Iglesias, A. de-Juan, E. Liaño, M.A. Serna, Non-stationary dynamic analysis of a wind turbine power drivetrain: Offshore considerations, Applied Acoustics, 2014, 77, 204

    CrossRef

  23. 23
    Ali Nematbakhsh, David J. Olinger, Gretar Tryggvason, Nonlinear simulation of a spar buoy floating wind turbine under extreme ocean conditions, Journal of Renewable and Sustainable Energy, 2014, 6, 3, 033121

    CrossRef

  24. 24
    Michael Borg, Maurizio Collu, Athanasios Kolios, Offshore floating vertical axis wind turbines, dynamics modelling state of the art. Part II: Mooring line and structural dynamics, Renewable and Sustainable Energy Reviews, 2014, 39, 1226

    CrossRef

  25. 25
    Ahmad Bilal Awan, Zeeshan Ali Khan, Recent progress in renewable energy – Remedy of energy crisis in Pakistan, Renewable and Sustainable Energy Reviews, 2014, 33, 236

    CrossRef

  26. 26
    Jin-Rae Cho, Bo-Sung Kim, Eun-Ho Choi, Shi-Bok Lee, O-Kaung Lim, Semi-analytical numerical approach for the structural dynamic response analysis of spar floating substructure for offshore wind turbine, Structural Engineering and Mechanics, 2014, 52, 3, 633

    CrossRef

  27. 27
    Gordon M. Stewart, Matthew A. Lackner, The impact of passive tuned mass dampers and wind–wave misalignment on offshore wind turbine loads, Engineering Structures, 2014, 73, 54

    CrossRef

  28. 28
    Fabian Vorpahl, Michael Strobel, Jason M. Jonkman, Torben J. Larsen, Patrik Passon, James Nichols, Verification of aero-elastic offshore wind turbine design codes under IEA Wind Task XXIII, Wind Energy, 2014, 17, 4
  29. 29
    Enzo Marino, Claudio Lugni, Claudio Borri, A novel numerical strategy for the simulation of irregular nonlinear waves and their effects on the dynamic response of offshore wind turbines, Computer Methods in Applied Mechanics and Engineering, 2013, 255, 275

    CrossRef

  30. 30
    Wei Shi, Hyunchul Park, Jonghoon Han, Sangkwon Na, Changwan Kim, A study on the effect of different modeling parameters on the dynamic response of a jacket-type offshore wind turbine in the Korean Southwest Sea, Renewable Energy, 2013, 58, 50

    CrossRef

  31. 31
    Matthew A. Lackner, An investigation of variable power collective pitch control for load mitigation of floating offshore wind turbines, Wind Energy, 2013, 16, 4
  32. 32
    Matthew A. Lackner, An investigation of variable power collective pitch control for load mitigation of floating offshore wind turbines, Wind Energy, 2013, 16, 3
  33. 33
    Kangsu Lee, Jongsoon Im, Jangyong Lee, Chang Yong Song, Dynamic Response Analysis for Upper Structure of 5MW Offshore Wind Turbine System based on Multi-Body Dynamics Simulation, Journal of the Korean Society for Marine Environment & Energy, 2013, 16, 4, 239

    CrossRef

  34. 34
    S.H. Jeon, Y.U. Cho, M.W. Seo, J.R. Cho, W.B. Jeong, Dynamic response of floating substructure of spar-type offshore wind turbine with catenary mooring cables, Ocean Engineering, 2013, 72, 356

    CrossRef

  35. 35
    Yingguang Wang, Yiqing Xia, Xiaojun Liu, Establishing robust short-term distributions of load extremes of offshore wind turbines, Renewable Energy, 2013, 57, 606

    CrossRef

  36. 36
    Yulin Si, Hamid Reza Karimi, Huijun Gao, Modeling and Parameter Analysis of the OC3-Hywind Floating Wind Turbine with a Tuned Mass Damper in Nacelle, Journal of Applied Mathematics, 2013, 2013, 1

    CrossRef

  37. 37
    Madjid Karimirad, Modeling aspects of a floating wind turbine for coupled wave–wind-induced dynamic analyses, Renewable Energy, 2013, 53, 299

    CrossRef

  38. 38
    Alexander J. Coulling, Andrew J. Goupee, Amy N. Robertson, Jason M. Jonkman, Habib J. Dagher, Validation of a FAST semi-submersible floating wind turbine numerical model with DeepCwind test data, Journal of Renewable and Sustainable Energy, 2013, 5, 2, 023116

    CrossRef

  39. 39
    S.C. Pryor, R.J. Barthelmie, Climate Vulnerability, 2013,

    CrossRef

  40. 40
    Ming-Chen Hsu, Yuri Bazilevs, Fluid–structure interaction modeling of wind turbines: simulating the full machine, Computational Mechanics, 2012, 50, 6, 821

    CrossRef

  41. 41
    Kevin Maki, Ricardo Sbragio, Nickolas Vlahopoulos, System design of a wind turbine using a multi-level optimization approach, Renewable Energy, 2012, 43, 101

    CrossRef

  42. 42
    Nianxin Ren, Yugang Li, Jinping Ou, The wind-wave tunnel test of a tension-leg platform type floating offshore wind turbine, Journal of Renewable and Sustainable Energy, 2012, 4, 6, 063117

    CrossRef

  43. 43
    M. Karimirad, Comprehensive Renewable Energy, 2012,

    CrossRef

  44. 44
    Wind Energy Systems, 2012,

    CrossRef

  45. 45
    Y.H. Bae, M.H. Kim, Discussion on "Rotor-floater-mooring coupled dynamic analysis of mono-column-TLP-type FOWT (Floating Offshore Wind Turbine)", Ocean Systems Engineering, 2011, 1, 3, 243

    CrossRef

  46. 46
    J. M. Jonkman, D. Matha, Dynamics of offshore floating wind turbines—analysis of three concepts, Wind Energy, 2011, 14, 4
  47. 47
    Eric D. Stoutenburg, Nicholas Jenkins, Mark Z. Jacobson, Power output variations of co-located offshore wind turbines and wave energy converters in California, Renewable Energy, 2010, 35, 12, 2781

    CrossRef