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Performance analysis of the airfoil-slat arrangements for hydro and wind turbine applications

Author

Listed:
  • Yavuz, T.
  • Koç, E.
  • Kılkış, B.
  • Erol, Ö.
  • Balas, C.
  • Aydemir, T.

Abstract

Standard airfoils historically used for wind and hydrokinetic turbines had maximum lift coefficients of around 1.3 at stall angles of attack, which is about 12°. At these conditions, the minimum flow velocities to generate electric power were about 7 m/s and 2 m/s for the wind turbine and the hydrokinetic turbine cases, respectively. In this study, NACA4412-NACA6411 slat–airfoil arrangement was chosen for these two cases in order to investigate the potential performance improvements. Aerodynamic performances of these cases were both numerically and experimentally investigated. The 2D and 3D numerical analysis software were used and the optimum geometric and flow conditions leading to the maximum power coefficient or the maximum lift to drag ratio were obtained. The maximum lift to drag ratio of 24.16 was obtained at the optimum geometric and flow parameters. The maximum power coefficient of 0.506 and the maximum torque were determined at the tip speed ratios of 5.5 and 4.0 respectively. The experimental work conducted in a towing tank gave the power coefficient to be 0.47 which is about %7 lower than the numerical results obtained. Hence, there is reasonable agreement between numerical end experimental values. It may be concluded that slat-hydrofoil or airfoil arrangements may be applied in the design of wind and hydrokinetic turbines for electrical power generation in lower wind velocities (3–4 m/s) and current velocities (about 1 m/s).

Suggested Citation

  • Yavuz, T. & Koç, E. & Kılkış, B. & Erol, Ö. & Balas, C. & Aydemir, T., 2015. "Performance analysis of the airfoil-slat arrangements for hydro and wind turbine applications," Renewable Energy, Elsevier, vol. 74(C), pages 414-421.
  • Handle: RePEc:eee:renene:v:74:y:2015:i:c:p:414-421
    DOI: 10.1016/j.renene.2014.08.049
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    References listed on IDEAS

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    1. Jo, Chul hee & Yim, Jin young & Lee, Kang hee & Rho, Yu ho, 2012. "Performance of horizontal axis tidal current turbine by blade configuration," Renewable Energy, Elsevier, vol. 42(C), pages 195-206.
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    1. Serdar GENÇ, Mustafa & KOCA, Kemal & AÇIKEL, Halil Hakan, 2019. "Investigation of pre-stall flow control on wind turbine blade airfoil using roughness element," Energy, Elsevier, vol. 176(C), pages 320-334.
    2. Zhu, Haitian & Hao, Wenxing & Li, Chun & Ding, Qinwei & Wu, Baihui, 2018. "A critical study on passive flow control techniques for straight-bladed vertical axis wind turbine," Energy, Elsevier, vol. 165(PA), pages 12-25.
    3. Shafiqur Rehman & Md. Mahbub Alam & Luai M. Alhems & M. Mujahid Rafique, 2018. "Horizontal Axis Wind Turbine Blade Design Methodologies for Efficiency Enhancement—A Review," Energies, MDPI, vol. 11(3), pages 1-34, February.
    4. Zaki, Abanoub & Abdelrahman, M.A. & Ayad, Samir S. & Abdellatif, O.E., 2022. "Effects of leading edge slat on the aerodynamic performance of low Reynolds number horizontal axis wind turbine," Energy, Elsevier, vol. 239(PD).
    5. Jonathan Aguilar & Ainhoa Rubio-Clemente & Laura Velasquez & Edwin Chica, 2019. "Design and Optimization of a Multi-Element Hydrofoil for a Horizontal-Axis Hydrokinetic Turbine," Energies, MDPI, vol. 12(24), pages 1-18, December.
    6. Dallatu Abbas Umar & Chong Tak Yaw & Siaw Paw Koh & Sieh Kiong Tiong & Ammar Ahmed Alkahtani & Talal Yusaf, 2022. "Design and Optimization of a Small-Scale Horizontal Axis Wind Turbine Blade for Energy Harvesting at Low Wind Profile Areas," Energies, MDPI, vol. 15(9), pages 1-22, April.
    7. Laws, Nicholas D. & Epps, Brenden P., 2016. "Hydrokinetic energy conversion: Technology, research, and outlook," Renewable and Sustainable Energy Reviews, Elsevier, vol. 57(C), pages 1245-1259.

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