Abstract
Small-scale wind turbines with innovative design are introduced for small applications, providing clean renewable energy to rural homes, street lighting, and hybrid systems. Energy ball wind turbine, known as Venturi wind turbine, has untraditional blades’ shape and special aerodynamic behavior that creates a venturi effect on the air stream passing through its aspherical shape. This article represents an integration of computational fluid dynamics and wind tunnel experimentation to study the aerodynamic performance of a manufactured model of energy ball wind turbine. Physical models with different twist angles were fabricated and tested in a small wind test section. In these experiments, dynamic torque, angular velocity, and coefficient of performance values were measured at different speeds. The experimental power coefficient results were discussed showing the best-tested twist angle. Fluid flow simulation has been developed in ANSYS FLUENT software. The findings of these numerical simulations have provided pressure contour, velocity contour, and torque values which help to study the solidity effect on turbine’s power coefficient. Nevertheless, the velocity contours provided from the computational analysis ensure the Venturi effect of the energy ball wind turbine design.
Highlights
A new generation of small wind turbines appeared after the oil crisis
Small-scale wind turbines (SSWTs) operate with relatively high rotational speed due to the small radius so that there is no need for a gearbox
This study indicates that the power coefficient of the energy ball wind turbine (EBWT) of diameter 1 m is 0.18, while it is 0.24 for EBWT with 2 m diameter
Summary
A new generation of small wind turbines appeared after the oil crisis. Wind turbine technologies, recently, have significantly improved the increase in turbine size, efficiency, and ease of installation. Small-scale wind turbines (SSWTs) operate with relatively high rotational speed due to the small radius so that there is no need for a gearbox This approach reduces the cost, maintenance, and improves the reliability and efficiency at low wind speed operation. Small wind turbines have less generating capacity than the huge commercial turbines found on wind farms Their reduced costs and added versatility allow wind power to be used in a wider set of applications instead of working 80% of the time due to its low cut-in wind speed velocity. These small turbines are used primarily for distributed generation—generating electricity for use on-site—rather than transmitting
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
