Analysis of unsteady flow over Offshore Wind Turbine in combination with different types of foundations

Israa Alesbe; Moustafa Abdel-Maksoud; Sattar Aljabair

doi:10.1007/s11804-017-1414-x

Journal of Marine Science and Application ›› 2017, Vol. 16 ›› Issue (2) : 199 -207. DOI: 10.1007/s11804-017-1414-x

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Analysis of unsteady flow over Offshore Wind Turbine in combination with different types of foundations

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Abstract

Environmental effects have an important influence on Offshore Wind Turbine (OWT) power generation efficiency and the structural stability of such turbines. In this study, we use an in-house Boundary Element (BEM)—panMARE code—to simulate the unsteady flow behavior of a full OWT with various combinations of aerodynamic and hydrodynamic loads in the time domain. This code is implemented to simulate potential flows for different applications and is based on a three-dimensional first-order panel method. Three different OWT configurations consisting of a generic 5 MW NREL rotor with three different types of foundations (Monopile, Tripod, and Jacket) are investigated. These three configurations are analyzed using the RANSE solver which is carried out using ANSYS CFX for validating the corresponding results. The simulations are performed under the same environmental atmospheric wind shear and rotor angular velocity, and the wave properties are wave height of 4 m and wave period of 7.16 s. In the present work, wave environmental effects were investigated firstly for the two solvers, and good agreement is achieved. Moreover, pressure distribution in each OWT case is presented, including detailed information about local flow fields. The time history of the forces at inflow direction and its moments around the mudline at each OWT part are presented in a dimensionless form with respect to the mean value of the last three loads and the moment amplitudes obtained from the BEM code, where the contribution of rotor force is lower in the tripod case and higher in the jacket case and the calculated hydrodynamic load that effect on jacket foundation type is lower than other two cases.

Keywords

panel method / time domain / offshore wind turbine / RANSE solver / Boundary element method / unsteady flow

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Israa Alesbe, Moustafa Abdel-Maksoud, Sattar Aljabair. Analysis of unsteady flow over Offshore Wind Turbine in combination with different types of foundations. Journal of Marine Science and Application, 2017, 16(2): 199-207 DOI:10.1007/s11804-017-1414-x

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References

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

[1]	American Bureau of Shipping Design standards for offshore wind farms, 2011, Houston: Final report, U.S. American Bureau of Shipping

[2]	Bauer M, Abdel-Maksoud M. Propeller induced loads on quay walls. 2nd Workshop on Ports for Container Ships of Future Generations, 2011

[3]	Chandrasekaran S. Dynamic analysis and design of offshore structures, 2015

[4]	Choi SJ, Lee KH, Hong K, Shin SH, Gudmestad OT. Nonlinear wave forces on an offshore wind turbine foundation in shallow waters. International Journal of Ocean System Engineering, 2013, 3(2): 68-76

[5]	Derakhshan S, Tavaziani A. Study of wind turbine aerodynamic performance using numerical methods. Journal of Clean Energy Technologies, 2015, 3(2): 83-90

[6]	Erich H. Wind turbines: Fundamentals, technologies, application, economics, 2013

[7]	Faltinsen OM. Sea loads on ships and offshore structures, 1995, Cambridge, UK: Cambridge University Press

[8]

Ferreira González D, Lemmerhirt M, König M, Abdel-Maksoud M, Düster A, 2015. Numerical and experimental investigation regarding the landing manoeuvre of a catamaran vessel at an offshore wind turbine in waves. International Conference on Ocean, Offshore, and Arctic Engineering, St. John’s, Canada, OMAE2015-42071. DOI: 10.1115/OMAE2015-42071

[9]	Greve M. Non-viscous calculation of propeller forces under consideration of free surface effects, 2015, Hamburg: Fluid Dynamic and Ship Theory Institute, Hamburg University of Technology

[10]	Hansen AC, Laino DJ. User’s guide to the wind turbine dynamics computer programs YawDyn and AeroDyn for ADAMS, 1999

[11]	Hirt CW, Nichols D. Volume of fluid (VOF) method for the dynamics of free boundaries. Journal of Computational Physics, 1981, 39(1): 201-225

[12]	Jonkman J, Butterfield S, Musial W, Scott G. Definition of a 5-MW reference wind turbine for offshore system development, 2009, Golden, United States: Technical report NREL/TP-500-38060, National Renewable Energy Laboratory

[13]	Jose prasobh MJ, Karmakar D, Satheesh babu PK. Coupled dynamic analysis of spar-type offshore floating wind turbine. International Conference on Emerging Trends in Engineering and Management (ICETEM14), 2014, 30-31

[14]	Katz J, Ploklin A. Low-speed aerodynamics, 2001, Cambridge, UK: Cambridge University Press

[15]	Markus D. A code based methodology to account for wave loading in the design of offshore structures, 2009, Germany: Universität Stuttgart

[16]	MMI Engineering Inc, 2009. Comparative study of OWTG standards. Prepared for JIP Sponsorship, MMI Project No. MMW528, Oakland.

[17]	Ruehl K, Michelen C, Kanner S, Lawson M, Yu YH. preliminary verification and validation of WEC-Sim, an open-source wave energy converter design tool. 33rd International Conference on Ocean, Offshore and Arctic Engineering, 2014

[18]	Schaffarczyk A, 2014. Introduction to wind turbine aerodynamics. Springer-Verlag, Berlin Heidelberg, Kiel.

[19]	Timmons D, Jonathan M, Harris K, Roach B. The economics of renewable energy, 2014, Medford: Global Development and Environment Institute, Tufts University

[20]	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 30. Technical report, Fraunhofer Institute for Wind Energy and Energy System Technology, Bremerhaven.

[21]	Vorpahl F, Schwarze H, Fischer T, Seidel M, Jonkman J. Offshore wind turbine environmental loads simulation and design. WIREs Energy and Environment, 2012, 2(5): 548-570