2019
DOI: 10.5194/wes-2019-70
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Is the Blade Element Momentum Theory overestimating Wind Turbine Loads? – A Comparison with a Lifting Line Free Vortex Wake Method

Abstract: Abstract. Load calculations play a key role in determining the design loads of different wind turbine components. State of the art in the industry is to use the Blade Element Momentum (BEM) theory to calculate the aerodynamic loads. Due to their simplifying assumptions of the rotor aerodynamics, BEM methods have to rely on several engineering correction models to capture the aerodynamic phenomena present in Design Load Cases (DLCs) with turbulent wind. Because of this, BEM methods can overestimate aerodynamic … Show more

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Cited by 6 publications
(8 citation statements)
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“…The BEM model features a local implementation, i.e., solving the momentum equations separately for each blade element rather than once for a full annulus. Several engineering extensions are used such as a dynamic inflow model (Snel and Schepers, 1994), yaw model (Schepers and Vermeer, 1998;Schepers, 1999), root and tip loss model (Prandtl and Betz, 1927), and a turbulent wake state model (replacement of the theoretical momentum equation with a linear relation between thrust coefficient and axial-induction factor above a value of 0.38 for this parameter).…”
Section: Ecn Aero-modulementioning
confidence: 99%
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“…The BEM model features a local implementation, i.e., solving the momentum equations separately for each blade element rather than once for a full annulus. Several engineering extensions are used such as a dynamic inflow model (Snel and Schepers, 1994), yaw model (Schepers and Vermeer, 1998;Schepers, 1999), root and tip loss model (Prandtl and Betz, 1927), and a turbulent wake state model (replacement of the theoretical momentum equation with a linear relation between thrust coefficient and axial-induction factor above a value of 0.38 for this parameter).…”
Section: Ecn Aero-modulementioning
confidence: 99%
“…The internal BEM-based aerodynamic model features several engineering extensions such as a dynamic inflow model (Snel and Schepers, 1994), yaw model (Schepers and Vermeer, 1998;Schepers, 1999), root and tip loss model (Prandtl and Betz, 1927), and turbulent wake state model based on the formulation of Wilson. For the airfoil data, the modeling of dynamic stall behavior (Snel, 1997) and rotational effects on lift (Snel et al, 1993) is optional based on Snel's models.…”
Section: Phatasmentioning
confidence: 99%
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“…More results are given in the dedicated AVATAR report Boorsma et al (2016a). Over the last decades several publications have researched the added benefit of vortex wake models over BEM based models Hauptmann et al (2014); Gupta (2006); Boorsma et al (2016b) and more recently Perez-Becker et al (2019). Some of these feature a validation against wind tunnel data, for which the inflow conditions and turbine are not always representative for design load calculations on a multi MW wind turbine.…”
Section: Computational Fluid Dynamics (Cfd) Modelsmentioning
confidence: 99%
“…FAST is a computational-efficient simulator and is the reference software for the simulation of offshore floating wind turbines [21][22][23]. Nevertheless, it is characterised by a low accessibility because of its complex background code.…”
Section: Introductionmentioning
confidence: 99%