Sage Journals: Discover world-class research

Abstract

Banki wind turbine is a kind of vertical axis wind turbine (VAWT) with high solidity, and has been proved to have a relatively high starting torque and maximum power coefficient under low wind conditions. This study introduces an arc-shaped windshield to further improve the performance of Banki wind turbines. The windshield is placed in front of the turbine to deflect wind and reduce the negative torque on the blades in the upwind direction. Computational investigations are carried out to study the influence of the angle of the arc-shaped windshield on the performance of the turbine using the commercial computational fluid dynamics (CFD) code Fluent 13.0. The results demonstrated that the maximum power coefficient of the Banki wind turbine was increased by 66.9% with the optimal windshield angle of 60°. The maximum power coefficient was found to be 0.2784 at a tip speed ratio of 0.5 in the presence of the windshield.

Keywords

vertical axis wind turbine VAWT Banki CFD

Get full access to this article

View all access options for this article.

References

Herbert

G M J

Iniyan

Sreevalsan

. A review of wind energy technologies. Renewable and Sustainable Energy Reviews, 2007, 11:1117–1145.

Pope

Naterer

Dincer

, Power correlation for vertical axis wind turbines with varying geometries. International Journal of Energy Research, 2011, 35:423–435.

Mishnaevsky

Freere

Sinha

, Small wind turbines with timber blades for developing countries: Materials choice, development, installation and experiences. Renewable Energy. 2011, 36:2128–2138.

Armstrong

Fiedler

Tullis

Flow separation on a high Reynolds number, high solidity vertical axis wind turbine with straight and canted blades and canted blades with fences. Renewable Energy. 2012, 41:13–22.

Yang

Lawn

Fluid dynamic performance of a vertical axis turbine for tidal currents. Renewable Energy, 2011, 36:3355–3366.

Declaire

Engblom

Agren

, Analytical solutions for a single blade in vertical axis turbine motion in two-dimensions. European Journal of Mechanics B/Fluids, 2009, 28:506–520.

Calisal

Three-dimensional effects and arm effects on modeling a vertical axis tidal current turbine. Renewable Energy, 2010, 35:2325–2334.

Lain

Osorio

Simulation and evaluation of a straight-bladed Darrieus-type cross flow marine turbine. Journal of Scientific & Industrial Research, 2010, 69:906–912.

Howell

Qin

Edwards

, Wind tunnel and numerical study of a small vertical axis wind turbine. Renewable Energy, 2010, 35:412–422.

10.

Schonbore

Chantzidakis

Development of a hydraulic control mechanism for cyclic pitch marine current turbines. Renewable Energy, 2007, 32:662–679.

11.

Ponta

Dutt

An improved vertical axis water current turbine incorporating a channeling device. Renewable Energy, 2000, 20:223–241.

12.

Gupta

Biswas

Computational fluid dynamics analysis of a twisted three-bladed H-Darrieus rotor. Renewable and Sustainable Energy, 2010, 2:1–15.

13.

McTavish

Feszty

Sankar

Steady and rotating computational fluid dynamics simulations of a novel vertical axis wind turbine for small-scale power generation. Renewable Energy, 2012, 41:171–179.

14.

Saha

Thotla

Maity

Optimum design configuration of Savonius rotor through wind tunnel experiments. Journal of Wind Engineering and Industrial Aerodynamics, 2008, 96:1359–1375.

15.

Irabu

Roy

Study of direct force measurement and characteristics on blades of Savonius rotor at static state. Experimental

Thermal and Fluid Science, 2011, 35:653–659.

16.

Akwa

Junior

Petry

Discussion on the verification of the overlap ratio influence on performance coefficients of a Savonius wind rotor using computational fluid dynamics. Renewable Energy, 2012, 38:141–149.

17.

Golecha

Eldho

Prabhu

Influence of the deflector plate on the performance of modified Savonius water turbine. Applied Energy, 2011, 88: 3207–3217.

18.

Altan

Atilgan

An experimental and numerical study on the improvement of the performance of Savonius wind rotor. Energy Conversion and Management, 2008, 49:3425–3432.

19.

Dragomirescu

Performance assessment of a small wind turbine with crossflow runner by numerical simulations. Renewable Energy, 2011, 36:957–965.

20.

Fluent 13.0 user's guide. ANSYS Inc., 2011.

A Numerical Study on the Improvement of the Performance of a Banki Wind Turbine

Abstract

Keywords

Get full access to this article

References