Aerodynamic analysis of wind turbine rotor blades

• Autorzy: Martinez J. , Doerffer P. , Szulc O. , Tejero F.
• Języki publikacji: EN

Abstrakty

EN

One of the main achievements of the PLGrid Plus project is the implementation of new tools and services designed for the numerical prediction of the aerodynamic performance of wind energy turbines. An innovative and unique integration tool (Aero-T) is aiming at automating all stages (pre-, solution and post-processing) of the numerical simulation of the flow around wind turbine rotor blades using commercial CFD software based on the RANS approach and block-structured computational grids. The FINE/Turbo package (Numeca Int.) is applied in the structured grid generation process and solution phases, while the analysis of results is left to the Tecplot 360 (Tecplot Inc.) software. A demonstrator based on the NREL Phase VI rotor experiment (conducted at NASA Ames) is introduced to prove the excellent prediction capabilities of Aero-T.

Słowa kluczowe

EN

aerodynamics; CFD; NREL Phase VI rotor; wind turbine

• Wydawca: Politechnika Gdańska
• Czasopismo: TASK Quarterly : scientific bulletin of Academic Computer Centre in Gdansk
• Rocznik: 2015
• Tom: Vol. 19, No 2
• Strony: 129--140
• Opis fizyczny: Bibliogr. 18 poz., rys., tab.

Twórcy

autor

Martinez J.

• Institute of Fluid-Flow Machinery, Polish Academy of Sciences, Fiszera 14, 80-231 Gdansk, Poland

autor

Doerffer P.

• Institute of Fluid-Flow Machinery, Polish Academy of Sciences, Fiszera 14, 80-231 Gdansk, Poland

autor

Szulc O.

• Institute of Fluid-Flow Machinery, Polish Academy of Sciences, Fiszera 14, 80-231 Gdansk, Poland

autor

Tejero F.

• Institute of Fluid-Flow Machinery, Polish Academy of Sciences, Fiszera 14, 80-231 Gdansk, Poland

Bibliografia

• [1] Hansen M O L, Sorensen J N, Voutsinas S, Sorensen N and Madesen H A S 2006 Progress in Aerospace Sciences 42 (4) 285
• [2] Esfahanian V, Salavati Pour A, Harsini I, Haghani A, Pasandeh R, Shahbazi A and Ahmadi G 2013 Journal of Wind Engineering and Industrial Aerodynamics 120 29
• [3] Martinez J, Bernabini L, Probst O and Rodriguez C 2005 Wind Energy 8 (4) 385
• [4] Lee Y H and Mo J O 2011 Journal of Mechanical Science and Technology 25 (5) 1341
• [5] Arakawa C, Fleig O, Iida M and Shimooka M 2005 Journal of the Earth Simulator 2 11
• [6] Hand M M, Simms D A, Fingersh L J, Jager D W, Cotrell J R, Schreck S and Larwood S M 2011 National Renewable Energy Laboratory. Technical Report, NREL/TP- 500-29955
• [7] Yelmule M M and Anjuri E 2013 International Journal of Renewable Energy Research (IJRER) 3 (2) 261
• [8] Mo J O and Lee Y H 2012 Journal of Mechanical Science and Technology 26 (1) 81
• [9] Gomez-Iradi S, Steijl R and Barakos G N 2009 Journal of Solar Energy Engineering 131 (3) 1
• [10] Doerffer P, Szulc O, Tejero Embuena F L and Martinez Suarez J 2014 Aerodynamic and aero-acoustic analysis of helicopter rotor blades in hover, eScience on Distributed Computing Infrastructure. Achievements of PL-Grid Plus Domain-Specific Services and Tools, Bubak M, Kitowski J and Wiatr K (Eds.), Springer, 8 429
• [11] Martinez J, Doerffer P and Szulc O 2015 CFD validated technique for prediction of aerodynamic characteristics on horizontal axis wind energy turbines, Proceedings of EWEA OFFSHORE
• [12] Lindenburg C 2003 Energy Research Centre of the Netherlands. Technical Report, ECNC–03-025
• [13] Somers D M 1997 National Renewable Energy Laboratory. Technical Report, NREL/SR- 440-6918
• [14] Schreck S (Ed.) 2002 Wind Energy 5 77
• [15] Sutherland W 1893 Philosophical Magazine 36 507
• [16] Spalart P R and Allmaras S R 1992 AIAA Paper, 92-0439
• [17] Choi Y H and Merkle C L 1993 Journal of Computational Physics 105 (2) 207
• [18] Menter F 1994 AIAA Journal 32 (8) 1598