Characteristic Aerodynamic Loads and Load Effects on the Dynamics of a Floating Vertical Axis Wind Turbine

Zhengshun Cheng; Puyang Zhang

doi:10.1007/s12209-017-0088-4

Transactions of Tianjin University ›› 2017, Vol. 23 ›› Issue (6) : 555 -561. DOI: 10.1007/s12209-017-0088-4

Research Article

Characteristic Aerodynamic Loads and Load Effects on the Dynamics of a Floating Vertical Axis Wind Turbine

Zhengshun Cheng ¹^,²^,^a
, Puyang Zhang ²^,³

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Abstract

The development of offshore wind farms in deep water favors floating wind turbine designs, but floating horizontal axis wind turbines are facing the challenge of high cost of energy (CoE). The development of innovative designs to reduce the CoE is thus desirable, such as floating vertical axis wind turbines (VAWTs). This study demonstrates the characteristics of aerodynamic loads and load effects of a two-bladed floating VAWT supported by a semi-submersible platform. Fully coupled simulations are performed using the time-domain aero-hydro-servo-elastic code SIMO-RIFLEX-AC. It is found that thrust, lateral force, and aerodynamic torque vary considerably and periodically with the rotor azimuth angle. However, the variation in the generator torque can be alleviated to some extent by the control strategy applied. Moreover, the variations of platform motions and tensions in the mooring lines are strongly influenced by turbulent winds, whereas those of tower-base bending moments are not. The tower-base bending moments exhibit notable two-per-revolution (2P) response characteristics.

Keywords

Floating vertical axis wind turbine / Aerodynamic load / Load effect / Aero-hydro-servo-elastic

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Zhengshun Cheng, Puyang Zhang. Characteristic Aerodynamic Loads and Load Effects on the Dynamics of a Floating Vertical Axis Wind Turbine. Transactions of Tianjin University, 2017, 23(6): 555-561 DOI:10.1007/s12209-017-0088-4

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Paquette J, Barone M (2012) Innovative offshore vertical-axis wind turbine rotor project. In: EWEA 2012 annual event, Copenhagen, Denmark

[2]	Cheng Z (2016) Integrated dynamic analysis of floating vertical axis wind turbines. Dissertation, Norwegian University of Science and Technology, Norway

[3]	Antonutti R (2016) Numerical study of floating wind turbines: hydro- and aeromechanics. Dissertation, The University of Edinburgh, UK

[4]	Collu M, Borg M, Shires A et al (2013) FloVAWT: progress on the development of a coupled model of dynamics for floating offshore vertical axis wind turbines. In: ASME 2013 32nd international conference on ocean, offshore and arctic engineering. Nantes, France

[5]	Owens BC, Hurtado JE, Paquette JA et al (2013) Aeroelastic modeling of large offshore vertical-axis wind turbines: Development of the offshore wind energy simulation toolkit. In: Proceedings of the 54th AIAA/ASME/ASCE/AHS/ASC structures, structural dynamics, and materials conference, Boston, USA

[6]	Larsen TJ, Hansen AM. How 2 HAWC2, the user’s manual, 2013, Roskilde: Risø National Laboratory, Technical University of Denmark.

[7]	MARINTEK (2012) Simo-theory manual version 4.0. Norwegian Marine Technology Research Institute, Trondheim, Norway

[8]	Wang K, Moan T, Hansen MOL (2013) A method for modeling of floating vertical axis wind turbine. In: Proceedings of the 32nd international conference on ocean, offshore and arctic engineering, Nantes, France

[9]	Cheng ZS, Madsen HA, Gao Z, et al. A fully coupled method for numerical modeling and dynamic analysis of floating vertical axis wind turbines. Renew Energy, 2017, 107: 604-619.

[10]	Paraschivoiu I. Wind turbine design with emphasis on Darrieus concept, 2002, Montreal: Polytechnic International Press.

[11]	Eriksson S, Bernhoff H, Leijon M. Evaluation of different turbine concepts for wind power. Renew Sustain Energy Rev, 2008, 12: 1419-1434.

[12]	Borg M, Shires A, Collu M. Offshore floating vertical axis wind turbines, dynamics modelling state of the art. Part I: aerodynamics. Renew Sustain Energy Rev, 2014, 39: 1214-1225.

[13]	Cheng ZS, Wang K, Gao Z, et al. A comparative study on dynamic responses of spar-type floating horizontal and vertical axis wind turbines. Wind Energy, 2017, 20: 305-323.

[14]	Cheng Z, Wang K, Gao Z, et al. Dynamic response analysis of three floating wind turbine concepts with a two-bladed Darrieus rotor. J Ocean Wind Energy, 2015, 2: 213-222.

[15]	Vita L (2011) Offshore floating vertical axis wind turbines with rotating platform. Dissertation, Technical University of Denmark, Denmark

[16]	Jonkman JM, Butterfield S, Musial W et al (2009) Definition of a 5-MW reference wind turbine for offshore system development. Tech. Rep. NREL/TP500-38060, National Renewable Energy Laboratory, Golden, USA

[17]	MARINTEK (2012) Riflex theory manual, version 4.0. Norwegian Marine Technology Research Institute, Trondheim, Norway

[18]	Cheng ZS, Madsen HA, Gao Z, et al. Aerodynamic modeling of offshore vertical axis wind turbines using the actuator cylinder method. Energy Proc, 2016, 94: 531-543.

[19]	Madsen HA (1982) The Actuator Cylinder: A flow model for vertical axis wind turbines. Dissertation, Institute of Industrial Constructions and Energy Technology, Aalborg University Centre, Denmark