Özet:

Energy consumption in the world is increasing rapidly due to population growth and technological developments. Renewable energy sources have gained importance thanks to fossil fuel reserves being limited and their negative impacts on the environment. The design of blade geometry is crucial to enhancing the efficiency of wind turbines that convert kinetic energy in the wind, one of the renewable energy sources, into electrical energy. In this study, the effect of the change in the geometry of the lower surface of the NACA 63-415 airfoil used in wind turbines on aerodynamic performance was investigated numerically with the ANSYS Fluent CFD software. The experimental lift coefficient (CL) values for a range of angles of attack 0° to 20° at a Reynolds number of 1.6x106 number, were compared with the numerical CL values obtained using Spalarat Almaras and SST k-ω turbulence models. Since CL values obtained by the SST k-ω turbulence model fitted better with the experimental data, the calculations were performed using this model. In this study, NCAY10, NCAY20 and NCAY30 blade profiles were produced by reducing the dimensions of the lower surface of the NACA 63-415 airfoil by 10%, 20% and 30%, respectively. Numerical results showed that the new airfoils improved the aerodynamic performance compared to the NACA 63-415 airfoil and the maximum CL/CD values were obtained using the NCAY30 airfoil. It is thought that this study will contribute to the literature on enhancing the performance of the existing airfoils.

Anahtar Kelimeler: