International Journal of Renewable Energy Research-IJRER

This article presents a computational simulation that studies the variation of power, depending on the number of blades in the runner. To develop the study, six CAD models were created using the software Solid Edge ST8, which comprises 16, 20, 23, 25, 28 and 32 blades, each corresponding to the volume of water taken into the turbine. The discretization of the control volume (water inside the turbine) was performed in the ‘meshing’ module Ansys® Workbench V17.0. The configuration of the equations that govern the fluid dynamics has been solved using Ansys CFX, where a model of homogeneous turbulence was used for the multiphase fluid (water-air), also a turbulence model that corresponds to k-e for both phases was implemented, setting the next values as boundary conditions: a speed of 3.6 m/s in the nozzle, rotational speed of 450 RPM and atmospheric pressure at the outlet. There is an increment of the 3.2% in the power generated by Michell Banki turbine, when the number of blades in the runner changes from 16 to 28. rms do not have to be defined. 

Cross-Flow Turbine; Transient state; Ansys CFX 17.0; CFD analysis; Micropower.

N. Unidas and D. Sostenible, “La sostenibilidad del desarrollo a 20 años de la Cumbre para la Tierra: Avances, brechas y lineamientos estratégicos para América Latina y el Caribe,†2012.

Andrade JD, Curiel C, Kenyery F, Aguillon O, Vasquez A, Asuaje M. Numerical investigation of the internal flow in a Banki turbine. Int J Rotating Mach 2011; 12:841214.

Nadim M. Aziz and V. R. Desai, “An Experimental Study of the Effect of Some Design Parameters in Cross-Flow Turbine Efficiencyâ€, Engineering Report, Department of Civil Engineering, Clemson University, 1991.

Aziz, N.M.; Totapally, H.G.S. Design Parameter Refinement for Improved Cross Flow Turbine Performance. In Engineering Report, Departement of Civil Engineering, Clemson University, Clemson, SC, USA, 1994.

H. Olgun and A. Ulku. A study of cross-flow turbine – effects of turbine desing parameters on its performance. Department of mechanical engineering, University of Karadeniz Technical, Trabzon, 2884 – 2838

Y D Choi, H Y Yoon, M Inagaki, S Ooike, Y J Kim and Y H Lee, Performance improvement of a cross-flow hydro turbine by air layer effect. IOP Publishing, doi:10.1088/1755-1315/12/1/012030.

Vincenzo Sammartano, Costanza Aricò, Armando Carravetta, Oreste Fecarotta and Tullio Tucciarelli. Banki-Michell Optimal Design by Computational Fluid Dynamics Testing and Hydrodynamic Analysis. Energies ( 2013), 6, 2362-2385

Nirmal Acharya, Chang-Gu Kim, Bhola Thapa y Young-Ho Lee. Numerical analysis and performance enhancement of a cross-flow hydro turbine. Renewable Energy 80 (2015) 819-826.

S. Mani, P. K. Shukla, C. Parashar, and P. G. Student, “Effect of Changing Number of Blades and Discharge on the Performance of a Cross-Flow Turbine for Micro Hydro Power Plants Depart ment of Civ il Engineering,†Int. J. Eng. Sci. Comput., 2016.

Hernández B. Carlos A. Diseño y Estandarización de Turbinas Michell-Banki. OLADE (Organización latinoamericana de Energía). 1980, 2-21.

C. Ansys, “ANSYS CFX-solver theory guide,†ANSYS CFX Release, vol. 15317, no. April, pp. 724–746, 2009.