Design and Performance Analysis of Composite Airfoil Wind Turbine Blade
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Date
2021Author
Mwanyika, Hegespo
Jande, Yusufu
Kivevele, Thomas
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Small horizontal axis wind turbine rotors with composite airfoil rotor blades were designed and
investigated in the present study in order to improve its performance in low wind speed and low
Reynolds number (Re) conditions for standalone system. The geometrical and aerodynamic
nature of a single airfoil small horizontal axis wind turbine blade curtails efficient energy
harnessing of the rotor blade. The use of composite airfoil rotor blade improves energy
production but imposes uncertainty in determining an optimal design angle of attack and the off
design aerodynamic behaviour of the rotor. This research investigated the effects of two airfoils
used at different sections in a composite blade and determined the blade’s optimal design angle
of attack for maximum power generation. The wind turbine rotor blades were designed using
blade element momentum (BEM) method and modelled by SolidWorks software. The SG6042
and SG6043 airfoils were used for the composite airfoil blades. Five wind turbines were
designed with rotor blades of design angles of attack from 3° to 7°. The five wind turbine
blades were simulated in computational fluid dynamics to determine the optimal design angle of
attack. The composite airfoil wind turbine blade showed improved performance, whereas, the
wind power generated ranged from 4966 W to 5258 W and rotor power coefficients ranged
from 0.443 to 0.457. The blade with design angle of attack of 6° showed highest performance