Articles | Volume 3, issue 2
https://doi.org/10.5194/wes-3-905-2018
https://doi.org/10.5194/wes-3-905-2018
Research article
 | 
27 Nov 2018
Research article |  | 27 Nov 2018

Near-wake analysis of actuator line method immersed in turbulent flow using large-eddy simulations

Jörn Nathan, Christian Masson, and Louis Dufresne

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Cited articles

Carrión, M., Steijl, R., Woodgate, M., Barakos, G., Munduate, X., and Gomez-Iradi, S.: Computational fluid dynamics analysis of the wake behind the MEXICO rotor in axial flow conditions, Wind Energy, 18, 1023–1045, 2015. a, b
Gilling, L.: TuGen, Tech. rep., Department of Civil Engineering, Aalborg University, 2009. a
Glauert, H.: Airplane Propellers, in: Aerodynamic Theory, Vol. IV, Division L, edited by: Durand, W. F., 169–360, Springer, New York, 1935. a
ISO 61400: IEC 61400 – ONLINE COLLECTION – Wind turbines, International Standard, 23 April 2015, Edition 1.0, 1000 pp., 2015. a
Ivanell, S., Mikkelsen, R. F., Sørensen, J. N., and Henningson, D.: Stability analysis of the tip vortices of a wind turbine, Wind Energy, 13, 705–715, 2010. a, b, c
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Short summary
The interaction between wind turbines through their wakes is an important aspect of the conception and operation of a wind farm. Wakes are characterized by an elevated turbulence level and a noticeable velocity deficit which causes a decrease in energy output and fatigue on downstream turbines. In order to gain a better understanding of this phenomenon, this work uses large-eddy simulations together with an actuator line model and different ambient turbulences.
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