C. Casillas Farfán - Faculty of Mechanical Engineering, Universidad Michoacana, Morelia, Michoacan, México
G. Solorio Díaz - Faculty of Mechanical Engineering, Universidad Michoacana, Morelia, Michoacan, México
V. López Garza - Faculty of Mechanical Engineering, Universidad Michoacana, Morelia, Michoacan, México
S. Galván González - Faculty of Mechanical Engineering, Universidad Michoacana, Morelia, Michoacan, México
K. Figueroa - Faculty of Physical and Mathematical Sciences, Universidad Michoacana, Morelia, Michoacan, México

This article introduces a novel Induction Blade (IB) prototype modeled by Blade Element Momentum (BEM) theory, which develops higher torque during the starting phase for Horizontal Axis Wind Turbines (HAWT), especially for micro-turbines. The IB is composed of two parallel blades joined at their tips and roots, forming a distinctive hole in the space between the blades that generates a Venturi effect as air passes through. This phenomenon in the IB hole together with the extra lift generated by the area of the second blade produce extra valuable torque during the starting phase. We used Computational Fluid Dynamics (CFD) analysis to evaluate the aerodynamic properties of this design compared with a traditional blade design of the same radius. The IB and traditional prototypes were built (۵۰W, diameter ۰.۶۲m, λ=۹ and at speed rated ۸m/s) by additive manufacturing in a ۳D printer and their aerodynamic behaviors tested in a small wind tunnel (square section ۰.۷m x ۰.۷m). Our results using CFD analysis show that this novel IB produces up to ۶۵% extra torque without losing output power for low wind velocity (۵-۸ m/s). IMPI (Mexican Institute of Industrial Protection) protects this prototype shape.

Torque analysis, Computational fluid dynamics, Wind tunnel test, BEM Theory, ۳D printing, Prototype, Micro-turbines