Yawed flow conditions introduce unsteady loads in a wind turbine that affect generated power quality and fatigue life. An unsteady phenomenon of special concern is dynamic stall, due to the significant load fluctuations associated with it. Although the assumptions underlying blade element momentum (BEM) models are totally inadequate in yawed flow conditions, these models, modified with engineering models, are still widely used in industry. It is therefore relevant to assess the capabilities of BEM models in predicting the location of dynamic stall on the blade for a rotor in yawed flow conditions. A rotor model is placed in an open jet wind tunnel and tested in yawed flow conditions. The locations of dynamic stall on the blade of a rotor model as a function of the blade position are observed. Two experimental techniques are used; tufts glued to the blade and hot-film anemometry in the near wake. The results from the two techniques are compared and possible causes for differences are identified. Furthermore, the rotor model in yaw is modeled with a simple BEM model, utilizing a Gormont dynamic stall model. The regions of dynamic stall on the blades predicted by the BEM model are compared with the experimental results. The BEM model seems capable of a crude prediction of the dynamic stall locations found for the rotor model in yawed flow conditions.
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November 2006
Research Papers
Stall in Yawed Flow Conditions: A Correlation of Blade Element Momentum Predictions With Experiments
Wouter Haans,
Wouter Haans
Ph.D. Student
Faculty of Aerospace Engineering, Kluyverweg 1,
Delft University of Technology
, Delft, 2629 HS, The Netherlands
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Tonio Sant,
Tonio Sant
Ph.D. Student
Faculty of Aerospace Engineering, Kluyverweg 1,
Delft University of Technology
, Delft, 2629 HS, The Netherlands and University of Malta
, Msida, MDS 07, Malta
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Gijs van Kuik,
Gijs van Kuik
Professor
Faculty of Aerospace Engineering, Kluyverweg 1,
Delft University of Technology
, Delft, 2629 HS, The Netherlands
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Gerard van Bussel
Gerard van Bussel
Associate Professor
Faculty of Aerospace Engineering, Kluyverweg 1,
Delft University of Technology
, Delft, 2629 HS, The Netherlands
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Wouter Haans
Ph.D. Student
Faculty of Aerospace Engineering, Kluyverweg 1,
Delft University of Technology
, Delft, 2629 HS, The Netherlands
Tonio Sant
Ph.D. Student
Faculty of Aerospace Engineering, Kluyverweg 1,
Delft University of Technology
, Delft, 2629 HS, The Netherlands and University of Malta
, Msida, MDS 07, Malta
Gijs van Kuik
Professor
Faculty of Aerospace Engineering, Kluyverweg 1,
Delft University of Technology
, Delft, 2629 HS, The Netherlands
Gerard van Bussel
Associate Professor
Faculty of Aerospace Engineering, Kluyverweg 1,
Delft University of Technology
, Delft, 2629 HS, The NetherlandsJ. Sol. Energy Eng. Nov 2006, 128(4): 472-480 (9 pages)
Published Online: July 16, 2006
Article history
Received:
April 21, 2006
Revised:
July 16, 2006
Citation
Haans, W., Sant, T., van Kuik, G., and van Bussel, G. (July 16, 2006). "Stall in Yawed Flow Conditions: A Correlation of Blade Element Momentum Predictions With Experiments." ASME. J. Sol. Energy Eng. November 2006; 128(4): 472–480. https://doi.org/10.1115/1.2349545
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