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2016 | OriginalPaper | Buchkapitel

Modelling of Floating Offshore Wind Technologies

verfasst von : Denis Matha, Joao Cruz, Marco Masciola, Erin E. Bachynski, Mairéad Atcheson, Andrew J. Goupee, Sébastien M. H. Gueydon, Amy N. Robertson

Erschienen in: Floating Offshore Wind Energy

Verlag: Springer International Publishing

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Abstract

The modelling of FOWT forms a critical stage of the design process, as it allows a fully coupled dynamic assessment of the response of the concept while accounting for blade-rotor dynamics, support structure motions and mooring dynamics. For both new and for existing concepts, modelling offers the potential to test, in controlled environments, a series of assumptions and scenarios at a relatively minor cost. Two fundamental modelling approaches can be followed: numerical and experimental.

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Vorheriges Kapitel Overview of Floating Offshore Wind Technologies

Nächstes Kapitel Key Design Considerations

Note that \( \sinh^{ - 1} (x) = \ln \left( {x + \sqrt {1 + x^{2} } } \right) \), and Eq. (54) can have a different appearance in various text books, although the equations are equivalent.

Norwegian Pertoleum Directorate.

Anderson JD Jr (2007) Fundamentals of aerodynamics, 4th edn. McGraw-Hill, New York

Bekiropoulos D, Rieß RM, Lutz T et al (2012) Simulation of unsteady aerodynamic effects on floating offshore wind turbines. In: Proceedings of the German wind energy conference (DEWEK), Bremen, Germany, 7–8 Nov 2012

de Vaal JB, Hansen MOL, Moan T (2012) Effect of wind turbine surge motion on rotor thrust and induced velocity. Wind Energy 17(1):105–121CrossRef

IEC 61400-12 (2005) Wind turbines—Part 12-1: power performance measurements of electricity producing wind turbines. International Electrotechnical Commission (IEC), Geneva, Switzerland

Leishman JG (2006) Principles of helicopter aerodynamics, 2nd edn. Cambridge University Press, New York

Matha D, Fischer S-A, Hauptmann S et al (2013) Variations in ultimate load predictions for floating offshore wind turbine extreme pitching motions applying different aerodynamic methodologies. In: Proceedings of the 23rd international offshore and polar engineering (ISOPE 2013), Anchorage, Alaska, USA, 30 June–4 July 2013

Moriarty PJ, Hansen AC (2005) AeroDyn theory manual. National Renewable Energy Laboratory (NREL), Golden, CO, USA

Quallen S, Xing T, Carrica P et al (2013) CFD simulation of a floating offshore wind turbine system using a quasi-static crowfoot mooring-line model. In: Proceedings of the 23rd international offshore and polar engineering (ISOPE 2013), Anchorage, Alaska, USA, 30 June–4 July 2013

Sant T (2007) Improving BEM-based aerodynamic models in wind turbine design codes. Dissertation, Delft University Wind Energy Research Institute, Delft, The Netherlands

Sebastian T (2012) The aerodynamics and near wake of an offshore floating horizontal axis wind turbine. Ph.D. thesis, University of Massachusetts Amherst

Aubault A, Cermelli C, Roddier D (2009) WindFloat: a floating foundation for offshore wind turbine—Part III: structural analysis. In: Proceedings of the 28th international conference of offshore mechanics and arctic engineers (OMAE), Honolulu, HI, USA, 31 May–5 June 2009

Bredmose H, Mariegaard J, Paulsen BT et al (2013) The wave loads project. DTU Wind Energy, no. 0045

Bunnik T, Veldman A, Wellens P (2008) Prediction of extreme wave loads in focused wave groups. In: Proceedings of the 18th International offshore and polar conference, Vancouver, BC, Canada, 6–11 July 2008

Cruz J (2009) Numerical and experimental modelling of offshore wave energy converters. Ph.D. thesis, Instituto Superior Técnico

Day AH, Babarit A, Fontaine A et al (2015) Hydrodynamic modelling of marine renewable energy devices: a state of the art review. Ocean Eng 108(2015):46–69CrossRef

Faltinsen OM (1990) Sea loads on ships and offshore structures. Cambridge University Press, Cambridge

Havelock T (1942) The damping of the heaving and pitching motion of a ship. Phil Mag 33(7):666–673MathSciNetCrossRefMATH

Hess J (1990) Panel methods in computational fluid dynamics. Annu Rev Fluid Mech 22:255–274CrossRef

Hess J, Smith A (1964) Calculation of nonlifting potential flow about arbitrary three-dimensional bodies. J Ship Res 8:22–44

Jonkman J (2009) Definition of the floating system for phase IV of OC3, National Wind Technology Center (NWTC), National Renewable Energy Laboratory (NREL), 12 Feb 2009

Lamb H (1932) Hydrodynamics, 6th edn. Cambridge University Press, CambridgeMATH

Le Méhauté B (1976) An introduction to hydrodynamics and water waves. Springer, New YorkCrossRefMATH

Lee C-H, Maniar HD, Newman JN, Zhu X (1996) Computations of wave loads using a B-spline panel method. In: Proceedings of the 21st symposium on naval hydrodynamics, Trondheim, Norway, pp 75–92

Linton CM (1991) Radiation and diffraction of water waves by a submerged sphere in finite depth. Ocean Eng 18(1/2):61–74CrossRef

Lopez-Pavon C, Souto-Iglesias A (2015) Hydrodynamic coefficients and pressure loads on heave plates for semi-submersible floating offshore wind turbines: a comparative analysis using large scale models. Renew Energy 81:864–881CrossRef

Maniar H (1995) A three-dimensional higher order panel method based on B-splines. Ph.D. thesis, Massachusetts Institute of Technology

Mei CC (1989) The applied dynamics of ocean surface waves. Advanced series on ocean engineering, vol 1. World Scientific, Singapore

Mei CC, Stiassnie M, Yue DKP (2005) Theory and applications of ocean surface waves, Part 1: linear aspects, Part 2: nonlinear aspects. Advanced series on ocean engineering, vol 23. World Scientific, Singapore

Morison JR, O’Brien MP, Johnson JW, Schaaf SA (1950) The force exerted by surface waves on piles. Petrol Trans 189:149–154

Newman JN (1977) Marine hydrodynamics. The MIT Press, Cambridge

Newman JN (1992) Panel methods in marine hydrodynamics. In: Proceedings of the 11th Australasian fluid mechanics conference, Hobart, Australia, Keynote Paper K-2

Newman JN, Lee CH (1992) Sensitivity of wave loads to the discretization of bodies. In: Proceedings of the 6th behaviour of offshore structures (BOSS) international conference, London, UK, vol 1, pp 50–63

Robertson A, Jonkman J, Vorpahl F et al (2014) Offshore Code Comparison Collaboration Continuation within IEA Wind Task 30: Phase II results regarding a floating semisubmersible wind system. In: Proceedings of the 33rd international conference on ocean, offshore and Artic engineering, San Francisco, CA, USA, 8–13 June 2013

Sarpkaya T, Isaacson M (1981) Mechanics of wave forces on offshore structures. Van Nostrand Reinhold Company, New York

Sethuraman L, Venugopal V (2013) Hydrodynamic response of a stepped spar floating wind turbine: Numerical modelling and tank testing. Renew Energy 52:160–174CrossRef

Sumer BM, Fredsøe J (1997) Hydrodynamics around cylindrical structures. Advanced series on ocean engineering, vol 12. World Scientific, Singapore

UpWind (2011) Deliverable D4.3.6: final report for WP4.3: design methods and standards

Wehausen JV, Laitone EV (1960) Surface waves. Volume IX of Encyclopaedia of physics. Springer, New York, pp 446–778

API RP 2SK (2005) Design and analysis of stationkeeping systems for floating structures, 3rd edn. American Petroleum Institute (API), Washington D.C.

API RP 2SM (2014) Design, manufacture, installation, and maintenance of synthetic fiber ropes for offshore mooring, 2nd edn. American Petroleum Institute (API), Washington D.C.

Bae Y, Kim M, Im S, Chang I (2011) Aero-elastic-control-floater-mooring coupled dynamic analysis of floating offshore wind turbines. In: Proceedings of the 21st international offshore and polar engineering conference (ISOPE), Maui, Hawaii, USA, 19–24 June 2011

Balzola R (1999) Mooring line damping in very large water depths. Ph.D. thesis, Massachusetts Institute of Technology

Bauduin C, Naciri M (2000) A contribution on quasi-static mooring line damping. J Offshore Mech Arct Eng 122(2):125–133CrossRef

Buckham B, Driscoll FR, Nahon M (2004) Development of a finite element cable model for use in low-tension dynamics simulation. J Appl Mech 71(4):476–485CrossRefMATH

Cermelli C, Bhat S (2002) Fiber mooring for ultra-deepwater applications. In: Proceedings of the 12th international offshore and polar engineering conference (ISOPE), Kitakyushu, Japan, 25–31 May 2001

Chai Y, Varyani K, Barltrop N (2002) Semi-analytical quasi-static formulation for three-dimensional partially grounded mooring system problems. Ocean Eng 29(6):627–649CrossRef

Chandrasekaran S, Jain A (2002) Dynamic behaviour of square and triangular offshore tension leg platforms under regular wave loads. Ocean Eng 29(3):279–313CrossRef

Choo Y, Casarella M (1973) A survey of analytical methods for dynamic simulation of cable-body systems. J Hydronaut 7(4):137–144CrossRef

Chung J, Hulbert G (1993) A time integration algorithm for structural dynamics with improved numerical dissipation: the generalized-α method. J Appl Mech 60(2):371–375MathSciNetCrossRefMATH

De Zoysa A (1978) Steady-state analysis of undersea cables. Ocean Eng 5(3):209–223CrossRef

Friswell M (1995) Steady-state analysis of underwater cables. J Waterw Port Coast Ocean Eng 121(2):98–104CrossRef

Garrett D (1982) Dynamic analysis of slender rods. J Energy Res Technol 104(4):302–306CrossRef

Gatti-Bono C, Perkins N (2004) Numerical simulations of cable/seabed interaction. J Offshore Polar Eng 14:118–124

Gobat JI (2000) The dynamics of geometrically compliant mooring systems. Ph.D. thesis, Massachusetts Institute of Technology (MIT) and Woods Hole Oceanographic Institution

Gobat JI, Grosenbaugh M (2001) Application of the generaliszed-α method to the time integration of the cable dynamics equations. Comput Methods Appl Mech Eng 190(37):4817–4829MathSciNetCrossRefMATH

Huang S (1994) Dynamic analysis of three-dimensional marine cables. Ocean Eng 21(6):587–605CrossRef

Hughes TJ (1977) Unconditionally stable algorithms for nonlinear heat conduction. Comput Methods Appl Mech Eng 10(2):135–139CrossRef

Inman DJ, Singh RC (1994) Engineering vibration. Prentice Hall Englewood Cliffs, NJ

Irvine M (1992) Cable structures, vol 5. Dover Publications, New York

ISO 19901-7 (2013) Petroleum and natural gas industries–specific requirements for offshore structures–part 7: station keeping systems for floating offshore structures and mobile offshore units, 2nd edn. International Standards Organization (ISO), Geneva

Jain R (1980) A simple method of calculating the equivalent stiffnesses in mooring cables. Appl Ocean Res 2(3):139–142CrossRef

Jonkman JM (2007) Dynamics modeling and loads analysis of an offshore floating wind turbine. Ph.D. thesis, University of Colorado

Kamman JW, Huston RL (1999) Modeling of variable length towed and tethered cable systems. J Guid Control Dyn 22(4):6020–6608CrossRef

Ketchmam J, Lou Y (1975). Application of the finite element method to towed cable dynamics. In: Proceedings of the IEEE OCEANS 75 conference, pp 98–107, San Diego, CA, USA, 22–25 Sept 1975

Leonard JW, Nath JH (1981) Comparison of finite element and lumped parameter methods for oceanic cables. Eng Struct 3(3):153–167CrossRef

Liu Y, Bergdahl L (1997) Influence of current and seabed friction on mooring cable response: comparison between time-domain and frequency-domain analysis. Eng Struct 19(11):945–953CrossRef

Liu Y, Shu CW, Tadmor E, Zhang M (2008) L2 stability analysis of the central discontinuous galerkin method and a comparison between the central and regular discontinuous galerkin methods. ESAIM: Math Model Numer Anal 42(4):593–607MathSciNetCrossRefMATH

Low Y (2009) Frequency domain analysis of a tension leg platform with statistical linearization of the tendon restoring forces. Mar Struct 22(3):480–503MathSciNetCrossRef

Malaeb D (1983) Dynamic analysis of tension-leg platforms. Ph.D. thesis, Texas A&M University

Masciola MD, Nahon M, Driscoll FR (2011) Static analysis of the lumped mass cable model using a shooting algorithm. J Waterw Port Coast Ocean Eng 138(2):164–171CrossRef

Masciola M, Jonkman J, Robertson A (2013) Implementation of a multisegmented, quasi-static cable model. In: Proceedings of the 23rd international offshore and polar engineering (ISOPE 2013), Anchorage, Alaska, USA, 30 June–4 July 2013

Mehrabi AB, Tabatabai H (1998) Unified finite difference formulation for free vibration of cables. J Struct Eng 124(11):1313–1322CrossRef

Mekha B, Johnson C, Roesset J (1996) Implications of tendon modeling on nonlinear response of TLP. J Struct Eng 122(2):142–149CrossRef

Merchant H, Kelf M (1973) Nonlinear analysis of submerged ocean buoy systems. In: Proceedings of the IEEE OCEANS 73 conference, Seattle, WA, USA, 25–28 Sept 1973, pp 390–395

Morgan J (1983) Dynamic analysis of tension-leg platforms. ASME energy sources technology conference and exhibition, Houston, TX, USA

Nicoll RS (2006) Dynamic simulation of marine risers with vortex induced vibration. Master’s thesis, University of Victoria

Nordgren R (1987) Analysis of high-frequency vibration of tension leg platforms. J Offshore Mech Arct Eng 109(2):119–125MathSciNetCrossRef

Oran C (1983) Overall dynamic characteristics of tension leg platform. In: Proceedings of the 15th annual offshore technology conference, Houston, TX, USA, 2–5 May 1983, pp 2–5

Peyrot A, Goulois A (1979) Analysis of cable structures. Comput Struct 10(5):805–813CrossRefMATH

Powell G, Simons J (1981) Improved iteration strategy for nonlinear structures. Int J Numer Meth Eng 17(10):1455–1467CrossRefMATH

Ran Z (2000) Coupled dynamic analysis of floating structures in waves and currents. Ph.D. thesis, Texas A&M University

Rupe R, Thresher R (1975) The anchor-last deployment problem for inextensible mooring lines. J Manuf Sci Eng 97(3):1046–1052

Schram JW, Reyle SP (1968) A three-dimensional dynamic analysis of a towed system. J Hydronaut 2(4):213–220CrossRef

Shugar T (1991) Automated dynamic relaxation solution method for compliant structures. In: Proceedings of the annual meeting of the American Society of Mechanical Engineers, New York, NY, vol 4, pp 1–12

Skop R (1988) Mooring systems: a state-of-the-art review. J Offshore Mech Arctic Eng 110(4):365–372CrossRef

Strang G (1988) Linear algebra and its applications, 3rd edn. Harcourt Brace Jovanovich, Fort WorthMATH

Sun Y, Leonard J, Chiou R (1994) Simulation of unsteady oceanic cable deployment by direct integration with suppression. Ocean Eng 21(3):243–256CrossRef

Van den Boom H (1985) Dynamic behaviour of mooring lines. In: Proceedings of the 4th behaviour of offshore structures (BOSS) international conference, Delft, The Netherlands, 1–5 July 1985

Veselic K (1995) Finite catenary and the method of Lagrange. SIAM Rev 37(2):224–229MathSciNetCrossRefMATH

Walton T, Polachek H (1960) Calculation of transient motion of submerged cables. Math Comput 14(69):27–46MathSciNetCrossRefMATH

Webster R (1980) On the static analysis of structures with strong geometric nonlinearity. Comput Struct 11(1):137–145MathSciNetCrossRefMATH

Williams P, Trivailo P (2007) Dynamics of circularly towed aerial cable systems, Part I: optimal configurations and their stability. J Guid Control Dyn 30(3):753–765CrossRef

Wilson JF (2003) Dynamics of offshore structures. Wiley, Hoboken

Wu S (1995) Adaptive dynamic relaxation technique for static analysis of catenary mooring. Mar Struct 8(5):585–599CrossRef

Zienkiewicz OC, Taylor RL (2000) The finite element method. Solid mechanics, 5th edn, vol 2. Butterworth-Heinemann, Oxford

Zueck R, Powell G (1995) Stable numerical solver for cable structures. In: Proceedings of the international symposium on cable dynamics, Liege, Belgium, 19–21 Oct 1995

Bachynski EE (2014) Design and dynamic analysis of tension leg platform wind turbines. Dissertation, Norwegian University of Science and Technology

Bachynski EE, Moan T (2014) Ringing loads on tension leg platform wind turbines. Ocean Eng 84:237–248CrossRef

Cook RD, Malkus DS, Plesha ME, Witt RJ (2002) Concepts and applications of finite element analysis, 4th edn. Wiley, Hoboken

DNV-RP-C203 (2010) Fatigue design of offshore steel structures. Det Norske Veritas, Høvik

DNV-OS-J103 (2013) Design of floating wind turbine structures. Det Norske Veritas, Høvik

Dr.techn. OLAVOLSEN (2012) EU Seventh framework programme: high power, high reliability offshore wind technology (HiPRwind) project—WP1: Platform concept

Hibbeler RC (2011) Mechanics of materials, 8th edn. Pearson Prentice Hall, BostonMATH

Hoff JR (2001) Estimation of linear and quadratic roll damping from free-decay tests. Norwegian University of Science and Technology, Trondheim

Krenk S (2009) Non-linear modelling and analysis of solids and structures. Cambridge University Press, CambridgeCrossRefMATH

Kvittem MI (2014) Modelling and response analysis for fatigue design of a semi-submersible wind turbine. Dissertation, Norwegian University of Science and Technology, Trondheim, Norway

Taghipour R, Perez T, Moan T (2008) Hybrid frequency-time domain models for dynamic response analysis of marine structures. Ocean Eng 35:685–705CrossRef

Aksnes V, Berthelsen P, Da Fonseca N, Reinholdtsen S (2015) On the need for calibration of numerical models of large floating units against experimental data. In: Proceedings of the 25th international offshore and polar engineering conference (ISOPE) Kona, Hawaii, USA, 21–26 June 2015

Bae YH (2014) Development of a dynamic mooring module FEAM for FAST v8. Texas A&M University (TAMU), TX, USA

Bellew S, Yde A, Verelst D (2014) Application of the aero-hydro-elastic model, HAWC2-WAMIT, to offshore data from floating power plants hybrid wind-and-wave-energy test platform, P37. In: Proceedings of the 5th international conference on ocean energy (ICOE), Halifax, Canada, 4–6 Nov 2014

Bossanyi EA (2003) GH Bladed theory manual, Issue no. 11. Garrad Hassan and Partners Ltd., Bristol

Buils Urbano R, Nichols J, Livingstone M et al (2013) Advancing numerical modelling of floating offshore wind turbines to enable efficient structural design. In: Proceedings of the European Wind Energy Association (EWEA) Offshore, Frankfurt, Germany, 19–21 Nov 2013

Bulk M (2012) Evaluation of a lifting line free vortex wake method for wind turbine simulations. Thesis, University of Stuttgart

Cordle A (2010) State-of-the-art in design tools for floating offshore wind turbines. Project UpWind, deliverable report D4.3.5 (WP 4: Offshore Foundations and Support Structures)

Cordle A, Jonkman J (2011) State of the art in floating wind turbine design tools. In: Proceedings of the 21st international offshore and polar engineering conference (ISOPE), Maui, Hawaii, USA, 19–24 June 2011

Goupee AJ, Koo BJ, Lamrakos KF et al (2012) Offshore wind energy: model tests for three floating wind turbine concepts. In: Proceedings of the offshore technical conference, Houston, TX, USA, 30 April–2 May 2012

Hall M (2015) MoorDyn user’s guide v.1.0.1. Department of Mechanical Engineering, University of Maine, Orono, ME, USA

Jonkman J (2010) Definition of the floating system for phase IV of OC3. Technical report NREL/TP-500-47535, National Renewable Energy Laboratory (NREL), Golden, CO, USA, May 2010

Jonkman J (2013) The new modularization framework for the FAST wind turbine CAE tool. In: Proceedings of the 51st AIAA aerospace sciences meeting, Dallas, TX, USA, 7–10 Jan 2013

Jonkman B, Jonkman J (2015) FAST v8.12.00a-bjj - Guide to changes in FAST v8. National Renewable Energy Laboratory (NREL), Golden, CO, Oct 2015

Jonkman J, Musial W (2010) Offshore code comparison collaboration (OC3) for IEA Task 23 offshore wind technology and deployment. Technical report NREL/TP-5000-48191, National Renewable Energy Laboratory (NREL), Golden, CO, USA, December 2010

Jonkman J, Butterfield S, Passon P el al (2007) Offshore code comparison collaboration within IEA Wind Annex XXIII: Phase II results regarding monopile foundation modeling. In: Proceedings of the IEA European offshore wind conference, Berlin, Germany, 4–6 Dec 2007

Jonkman J, Butterfield S, Musial W, Scott G (2009) Definition of a 5-MW reference wind turbine for offshore system development. Technical report NREL/TP-500-38060, National Renewable Energy Laboratory (NREL), Golden, CO, USA, Feb 2009

Jonkman J, Larsen T, Hansen A et al (2010) Offshore code comparison collaboration within IEA Wind Task 23: Phase IV results regarding floating wind turbine modelling. In: Proceedings of the European wind energy conference (EWEC), Warsaw, Poland, 20–23 April 2010

Jonkman J, Hayman G, Jonkman B, Damiani R (2015a) AeroDyn v15 user’s guide and theory manual—draft version 6-Oct-2015. National Renewable Energy Laboratory (NREL), Golden, CO, USA

Jonkman J, Robertson A, Hayman G (2015b) HydroDyn user’s guide and theory manual—draft version. National Renewable Energy Laboratory (NREL), Golden, CO, USA

Larsen TJ, Hansen AM (2015) How 2 HAWC2, the user’s manual. Technical report Risø-R-1597(ver. 4–6), Risø National Laboratory, Technical University of Denmark, Denmark

Lindenburg C, Schepers JG (2000) Phatas-IV aeroelastic modelling release “dec-1999” and “nov-200”. Technical report ECN-CX-00-027, Energy Research Centre of the Netherlands (ECN), The Netherlands

Matha D, Beyer F (2013) Offshore wind turbine hydrodynamics modelling in SIMPACK. SIMPACK News, Ed. July 2013

Matha D, Fischer T, Kuhn M, Jonkman J (2009) Model development and loads analysis of an offshore wind turbine on a tension leg platform. In: Proceedings of the European offshore wind conference (EOWC), Stockholm, Sweden, 14–16 Sept 2009

Matha D, Schlipf M, Cordle A et al (2011) Challenges in simulation of aerodynamics, hydrodynamics and mooring-line dynamics of floating offshore wind turbines. In: Proceedings of the 21st international offshore and polar engineering conference (ISOPE), Maui, Hawaii, USA, 19–24 June 2011

Nichols J, Camp T, Jonkman J et al (2008) Offshore code comparison collaboration within IEA wind annex XXIII: Phase III results regarding tripod support structure modelling. In: Proceedings of the 47th AIAA aerospace sciences meeting. Orlando, FL, USA, 5–8 Jan 2008

Ormberg H, Bachynski EE (2012) Global analysis of floating wind turbines: code development, model sensitivity and benchmark study. In: Proceedings of the 22nd international offshore and polar engineering conference, Rhodes, Greece, vol 1, pp 366–373

Passon P, Kühn M, Butterfield S et al (2007) OC3-Benchmark exercise of aero-elastic offshore wind turbine codes, J Phys Conf Ser (Online) 75:12

Popko W, Vorpahl F, Zuga A et al (2012) Offshore code comparison collaboration continuation (OC4), Phase I—results of coupled simulations of an offshore wind turbine with jacket support structure. In: Proceedings of the 22nd international ocean and polar engineers conference (ISOPE), Rhodes, Greece, 17–23 June 2012

Robertson A, Jonkman J, Vorpahl F et al (2014) Offshore code comparison collaboration continuation within IEA Wind Task 30: Phase II results regarding a floating semisubmersible wind system. In: Proceedings of the 33rd international conference on ocean, offshore and Artic engineering, San Francisco, CA, USA, 8–13 June 2014

Skaare B, Hanson TD, Nielsen FG et al (2007) Dynamics of floating wind turbines utilising integrated hydro- and aerodynamic analysis. In: Proceedings of the European wind energy conference (EWEC) 2007, Milan, Italy, 7–10 May 2007

Vorpahl F, Popko W, Kaufer D (2011) Description of a basic model of the “UpWind reference jacket” for code comparison in the OC4 project under IEA Wind Annex XXX. May 2011. Fraunhofer Institute for Wind Energy and Energy System Technology (IWES), Bremerhaven, Germany

Browning JR, Jonkman JM, Robertson AN, Goupee AJ (2012) Calibration and validation of the FAST dynamic simulation tool for a spar-type floating offshore wind turbine. In: Proceedings of the science of making torque from wind conference, Oldenburg, Germany, 9–11 Oct 2012

Chakrabarti SK (1994) Offshore structure modeling. World Scientific Publishing Co. Pte. Ltd., Singapore

Coulling AJ, Goupee AJ, Robertson AN et al (2013) Validation of a FAST semi-submersible floating wind turbine model with deepcwind test data. J Renew Sustain Energy 5:023116CrossRef

de Ridder E-J, Otto W, Zondervan G et al (2014) Development of a scaled-down floating wind turbine for offshore basin testing. In: Proceedings of the 33rd international conference on ocean, offshore and arctic engineering, San Francisco, CA, USA, 8–13 June 2014

Drela M (1989) XFOIL: An analysis and design system for low Reynolds number airfoils. In: Mueller T (ed) Low Reynolds number aerodynamics. Lectures notes in engineering, vol 54. Springer, Heidelberg, pp 1–12

Goupee AJ, Fowler MJ, Kimball RW et al (2014) Additional wind/wave basin testing of the deepcwind semi-submersible with a performance-matched wind turbine. In: Proceedings of the 33rd international conference on ocean, offshore and arctic engineering, San Francisco, CA, USA, 8–13 June 2014

Gueydon S (2015) Verification of the second-order wave loads on the OC4-semisubmersible. Work presented at the 12th deep sea offshore wind R&D conference EERA DeepWind’2015, Trondheim, Norway, 4–6 Feb 2015

Gueydon S, Fernandes G (2013) Scaling methodologies for floating wind turbines. In: Proceedings of European Wind Energy Association offshore conference, Frankfurt, Germany, 19–21 Nov 2013

Gueydon S, Weller S (2013) Study of a floating foundation for wind turbines. J Offshore Mech Arct Eng 135(3):031903CrossRef

Huijs F, de Ridder E-J, Savenije F (2014) Comparison of model tests and coupled simulations for a semi-submersible floating wind turbine. In: Proceedings of the 33rd international conference on ocean, offshore and arctic engineering, San Francisco, CA, USA, 8–13 June 2014

Jonkman JM (2010) Definition of the floating system for phase IV of OC3. NREL technical report NREL/TP-500-47535, National Renewable Energy Laboratory (NREL), Golden, CO, USA, May 2010

Jonkman JM, Buhl Jr ML (2005) FAST user’s guide. NREL technical report NREL/EL-500-38230, National Renewable Energy Laboratory (NREL), Golden, CO, USA, Aug 2005

Jonkman JM, Butterfield S, Musial W, Scott G (2009) Definition of a 5-MW reference wind turbine for offshore system development. NREL technical report NREL/TP-500-38060, National Renewable Energy Laboratory (NREL), Golden, CO, USA, Feb 2009

Kimball RW, Goupee AJ, Fowler MJ et al (2014) Wind/wave basin verification of a performance-matched scale-model wind turbine on a floating offshore wind turbine platform. In: Proceedings of the 33rd international conference on ocean, offshore and arctic engineering, San Francisco, CA, USA, 8–13 June 2014

Koo BJ, Goupee AJ, Kimball RW, Lambrakos KF (2014) Model tests for a floating wind turbine on three different floaters. J Offshore Mech Arct Eng 136(2):021904CrossRef

Martin HR (2011) Development of a scale model wind turbine for testing of offshore floating wind turbine systems. M.Sc. thesis, University of Maine

Martin HR, Kimball RW, Viselli AM, Goupee AJ (2014) Methodology for wind/wave basin testing of floating offshore wind turbines. J Offshore Mech Arct Eng 136(2):020905-1CrossRef

Nielsen FG, Hanson TD, Skaare B (2006) Integrated dynamic analysis of floating offshore wind turbines. In: Proceeding of the 25th international conference on offshore mechanics and arctic engineering, Hamburg, Germany, 4–9 June 2006

Prowell I, Robertson AN, Jonkman JM et al (2013) Numerical prediction of experimentally observed scale-model behaviour of an offshore wind turbine supported by a tension-leg platform. In: Proceedings of the offshore technology conference 2013, Houston, TX, USA, 6–9 May 2013

Rao SS (2004) Mechanical vibrations, 4th edn. Pearson Prentice Hall, Upper Saddle River

Ren N, Li Y, Ou J (2012) The effect of additional mooring chains on the motion performance of a floating wind turbine with a tension leg platform. Energies 5(4):1135–1149CrossRef

Robertson AN, Jonkman JM, Masciola MD et al (2013) Summary of conclusions and recommendations drawn from the DeepCwind scaled floating offshore wind system test campaign. In: Proceedings of the ocean, offshore and arctic engineering conference, Nantes, 9–14 June 2013

Roddier D, Cermelli C, Aubault A, Weinstin A (2010) WindFloat: a floating foundation for offshore wind turbines. J Renew Sustain Energy 2:033104CrossRef

Stewart GM, Lackner MA, Robertson AN et al (2012) Calibration and validation of a fast floating wind turbine model of the DeepCwind scaled tension-leg platform. In: Proceedings of the 22nd international Ocean and polar engineering conference, Rhodes, Greece, 17–22 June 2012

Weller S, Gueydon S (2012) Analysis of the DeepCwind model tests and a first attempt to simulate a semi-submersible floating wind turbine. Report no. 24602-MSG-1, MARIN, Wageningen, The Netherlands

Windsea AS (2010) Next generation floating wind farm. Scand Oil-Gas Mag 7(8):250–253

Titel: Modelling of Floating Offshore Wind Technologies
verfasst von: Denis Matha
Joao Cruz
Marco Masciola
Erin E. Bachynski
Mairéad Atcheson
Andrew J. Goupee
Sébastien M. H. Gueydon
Amy N. Robertson
Verlag: Springer International Publishing
Buch: Floating Offshore Wind Energy
Print ISBN: 978-3-319-29396-7

Electronic ISBN: 978-3-319-29398-1

Copyright-Jahr: 2016
DOI: https://doi.org/10.1007/978-3-319-29398-1_4