TITLE:
Computational Fluid Dynamics Analysis of Multi-Bladed Horizontal Axis Wind Turbine Rotor
AUTHORS:
Nasim A. Mamaghani, Peter E. Jenkins
KEYWORDS:
Computational Fluid Dynamics, Horizontal Axis Wind Turbine, Multi-Bladed Rotor, Aerodynamic Torque
JOURNAL NAME:
World Journal of Mechanics,
Vol.10 No.9,
September
22,
2020
ABSTRACT: The principal objective of this work was to investigate the 3D flow field around a multi-bladed horizontal axis wind turbine (HAWT) rotor and to investigate its performance characteristics. The aerodynamic performance of this novel rotor design was evaluated by means of a Computational Fluid Dynamics commercial package. The Reynolds Averaged Navier-Stokes (RANS) equations were selected to model the physics of the incompressible Newtonian fluid around the blades. The Shear Stress Transport (SST) k-ω turbulence model was chosen for the assessment of the 3D flow behavior as it had widely used in other HAWT studies. The pressure-based simulation was done on a model representing one-ninth of the rotor using a 40-degree periodicity in a single moving reference frame system. Analyzing the wake flow behavior over a wide range of wind speeds provided a clear vision of this novel rotor configuration. From the analysis, it was determined that the flow becomes accelerated in outer wake region downstream of the rotor and by placing a multi-bladed rotor with a larger diameter behind the forward rotor resulted in an acceleration of this wake flow which resulted in an increase the overall power output of the wind machine.