Numerical Analysis of the Performance of the DU91-W2-250 Airfoil for Straight-Bladed Vertical-Axis Wind Turbine Application
This paper presents a numerical analysis of the
performance of a three-bladed Darrieus vertical-axis wind turbine
based on the DU91-W2-250 airfoil. A complete campaign of 2-D
simulations, performed for several values of tip speed ratio and based
on RANS unsteady calculations, has been performed to obtain the
rotor torque and power curves. Rotor performances have been
compared with the results of a previous work based on the use of the
NACA 0021 airfoil. Both the power coefficient and the torque
coefficient have been determined as a function of the tip speed ratio.
The flow field around rotor blades has also been analyzed. As a final
result, the performance of the DU airfoil based rotor appears to be
lower than the one based on the NACA 0021 blade section. This
behavior could be due to the higher stall characteristics of the NACA
profile, being the separation zone at the trailing edge more extended
for the DU airfoil.
[1] European Wind Energy Association, EU energy policy after
2020,www.ewea.org, 2011.
[2] A. S. Bahaj, L. Meyers and P. A. B. James, "Urban energy generation:
Influence of micro-wind turbine output on electricity consumptions in
buildings", Energy and Buildings, Vol. 39, Issue 2, February 2007, pp.
154-165.
[3] S. Mertens, Wind Energy in the built environment, Multiscience
Publishing, 2006.
[4] W. Tong, W. Langreder, A. P. Schaffarczyk, S. G. Voutsinas, R. Z.
Szasz, L. Fuchs, L. D. Willey, L. Staudt, P. Cooper, C. Lewis, T.
Kanemoto, K. Kubo, D. Zheng, S. Bose, H. Matsumiya, B. F. Sorensen,
J. W. Holmes, P. Brondsted, K. Branner, A. W. Hulskamp, H. E. N.
Bersee, R. Hicks, B. Basu, J. van der Tempel, N. F. B. Diepeveen, D. J.
Cerda Salzmann, W. E. de Vries, P. Milan, M. Wachter, S. Barth, J.
Peinke, Y. Jiang, P. Pantazopoulou, M. Leahy, D. Connolly and N.
Buckley, Wind power generation and wind turbine design, WIT Press,
Southampton, UK, May 28, 2010.
[5] W. A. Timmer and R. P. J. O. M. van Rooij, "Summary of the delft
university wind turbine dedicated airfoils", AIAA-2003-0352.
[6] W. A. Timmer and R. P. J. O. M. van Rooij, "Design of airfoils for wind
turbine blades", DUWIND, section Wind Energy, Faculty CiTG, 3 May,
2004.
[7] M. Raciti Castelli, G. Grandi and E. Benini, "Numerical Analysis of
Laminar to Turbulent Transition around DU91-W2-250 airfoil",
submitted to ICAFM 2012: International Conference on Advances in
Fluid Mechanics, Florence (Italy), February 28-29, 2012.
[8] I. Paraschivoiu, Wind Turbine Design: With Emphasis on Darrieus
Concept, Polytechnic International Press, 2002.
[9] S. Ferreira, H. Bijl, G. van Bussel and G. van Kuik, "Simulating
dynamic stall in a 2D VAWT: modeling strategy, verification and
validation with particle image velocimetry data", The Science of making
torque from wind. Journal of Physics: Conference Series 75, 2007.
[10] S. Wang, Z. Tao, L. Ma, D. Ingham and M. Pourkashanian,
"Numerical investigations on dynamic stall associated with low
Reynolds number flows over airfoils", 2nd International Conference on
Computer Engineering and Technology (ICCET), Chengdu (China), 16-
18 April, 2010.
[11] V. Kumar, M. Paraschivoiu and I. Paraschivoiu, "Low Reynolds number
verical axis wind turbine for Mars", Wind Engineering, Vol. 34, No. 4,
June 2010.
[12] M. Raciti Castelli and E. Benini, "Effect of blade inclination angle on a
Darrieus Wind Turbine", Journal of turbomachinery, October 2011,
Vol 133.
[13] M. Raciti Castelli, G. Pavesi, E. Benini, L. Battisti and G. Ardizzon,
"Modeling strategy and numerical validation for a Darrieus vertical axis
micro-wind turbine", Proceedings of the ASME 2010 International
Mechanical Engineering Congress & Exposition, November 12-18
2010, Vancouver, British Colummbia, IMECE2010-39548.
[14] M. Raciti Castelli and E. Benini, "Effect of blade thickness on Darrieus
Vertical-Axis Wind turbine performance", CSSim 2011, 2nd
International Conference on Computer Modelling and Simulation, 5-7
September 2011, Brno (Czech Republic).
[15] M. Raciti Castelli, A. Englaro and E. Benini, "The Darrieus wind
turbine: Proposal for a new performance prediction model based on
CFD", Energy 36 (2011), pp. 4919-4934.
[16] J. H. Strickland, "The Darrieus turbine: a performance prediction model
using multiple streamtube", SAND75, 2007.
[17] R. M. Cumming, J. R. Forsythe, S. A. Morton and K. D. Squires,
"Computational challenges in high angle of attack flow prediction",
Progr Aerosp Sci 2003; 39(5):369-84.
[1] European Wind Energy Association, EU energy policy after
2020,www.ewea.org, 2011.
[2] A. S. Bahaj, L. Meyers and P. A. B. James, "Urban energy generation:
Influence of micro-wind turbine output on electricity consumptions in
buildings", Energy and Buildings, Vol. 39, Issue 2, February 2007, pp.
154-165.
[3] S. Mertens, Wind Energy in the built environment, Multiscience
Publishing, 2006.
[4] W. Tong, W. Langreder, A. P. Schaffarczyk, S. G. Voutsinas, R. Z.
Szasz, L. Fuchs, L. D. Willey, L. Staudt, P. Cooper, C. Lewis, T.
Kanemoto, K. Kubo, D. Zheng, S. Bose, H. Matsumiya, B. F. Sorensen,
J. W. Holmes, P. Brondsted, K. Branner, A. W. Hulskamp, H. E. N.
Bersee, R. Hicks, B. Basu, J. van der Tempel, N. F. B. Diepeveen, D. J.
Cerda Salzmann, W. E. de Vries, P. Milan, M. Wachter, S. Barth, J.
Peinke, Y. Jiang, P. Pantazopoulou, M. Leahy, D. Connolly and N.
Buckley, Wind power generation and wind turbine design, WIT Press,
Southampton, UK, May 28, 2010.
[5] W. A. Timmer and R. P. J. O. M. van Rooij, "Summary of the delft
university wind turbine dedicated airfoils", AIAA-2003-0352.
[6] W. A. Timmer and R. P. J. O. M. van Rooij, "Design of airfoils for wind
turbine blades", DUWIND, section Wind Energy, Faculty CiTG, 3 May,
2004.
[7] M. Raciti Castelli, G. Grandi and E. Benini, "Numerical Analysis of
Laminar to Turbulent Transition around DU91-W2-250 airfoil",
submitted to ICAFM 2012: International Conference on Advances in
Fluid Mechanics, Florence (Italy), February 28-29, 2012.
[8] I. Paraschivoiu, Wind Turbine Design: With Emphasis on Darrieus
Concept, Polytechnic International Press, 2002.
[9] S. Ferreira, H. Bijl, G. van Bussel and G. van Kuik, "Simulating
dynamic stall in a 2D VAWT: modeling strategy, verification and
validation with particle image velocimetry data", The Science of making
torque from wind. Journal of Physics: Conference Series 75, 2007.
[10] S. Wang, Z. Tao, L. Ma, D. Ingham and M. Pourkashanian,
"Numerical investigations on dynamic stall associated with low
Reynolds number flows over airfoils", 2nd International Conference on
Computer Engineering and Technology (ICCET), Chengdu (China), 16-
18 April, 2010.
[11] V. Kumar, M. Paraschivoiu and I. Paraschivoiu, "Low Reynolds number
verical axis wind turbine for Mars", Wind Engineering, Vol. 34, No. 4,
June 2010.
[12] M. Raciti Castelli and E. Benini, "Effect of blade inclination angle on a
Darrieus Wind Turbine", Journal of turbomachinery, October 2011,
Vol 133.
[13] M. Raciti Castelli, G. Pavesi, E. Benini, L. Battisti and G. Ardizzon,
"Modeling strategy and numerical validation for a Darrieus vertical axis
micro-wind turbine", Proceedings of the ASME 2010 International
Mechanical Engineering Congress & Exposition, November 12-18
2010, Vancouver, British Colummbia, IMECE2010-39548.
[14] M. Raciti Castelli and E. Benini, "Effect of blade thickness on Darrieus
Vertical-Axis Wind turbine performance", CSSim 2011, 2nd
International Conference on Computer Modelling and Simulation, 5-7
September 2011, Brno (Czech Republic).
[15] M. Raciti Castelli, A. Englaro and E. Benini, "The Darrieus wind
turbine: Proposal for a new performance prediction model based on
CFD", Energy 36 (2011), pp. 4919-4934.
[16] J. H. Strickland, "The Darrieus turbine: a performance prediction model
using multiple streamtube", SAND75, 2007.
[17] R. M. Cumming, J. R. Forsythe, S. A. Morton and K. D. Squires,
"Computational challenges in high angle of attack flow prediction",
Progr Aerosp Sci 2003; 39(5):369-84.
@article{"International Journal of Mechanical, Industrial and Aerospace Sciences:57424", author = "M. Raciti Castelli and G. Grandi and E. Benini", title = "Numerical Analysis of the Performance of the DU91-W2-250 Airfoil for Straight-Bladed Vertical-Axis Wind Turbine Application", abstract = "This paper presents a numerical analysis of the
performance of a three-bladed Darrieus vertical-axis wind turbine
based on the DU91-W2-250 airfoil. A complete campaign of 2-D
simulations, performed for several values of tip speed ratio and based
on RANS unsteady calculations, has been performed to obtain the
rotor torque and power curves. Rotor performances have been
compared with the results of a previous work based on the use of the
NACA 0021 airfoil. Both the power coefficient and the torque
coefficient have been determined as a function of the tip speed ratio.
The flow field around rotor blades has also been analyzed. As a final
result, the performance of the DU airfoil based rotor appears to be
lower than the one based on the NACA 0021 blade section. This
behavior could be due to the higher stall characteristics of the NACA
profile, being the separation zone at the trailing edge more extended
for the DU airfoil.", keywords = "CFD, vertical axis wind turbine, DU91-W2-250,
NACA 0021", volume = "6", number = "3", pages = "641-6", }
