Numerical investigation of Savonius wind turbine farms

The Savonius vertical axis wind turbine is a simple device, easy to manufacture, has good starting characteristics, and rotates with wind from any direction; nevertheless, it has a lower efficiency than the other wind turbines. The aim of this paper is to numerically explore the non-linear unsteady flow over a conventional Savonius using three dimensional computations with emphasis on the placement of these turbines in a linear array and the effect of an obstacle that acts as a wind deflector. First, an infinite array of turbines is used to study the gap distance between the wind turbine axis rotors. This investigation is conducted via numerical simulations based on the computational fluid dynamics computer program Fluent 14.5. It is found that a gap distance L = 1.4R gives a very good performance. Second, four farms with different number of turbines—from 3 to 21 turbines—are studied. The effect on the power coefficient of the number of turbines in each farm is reported and analyzed. Third, a new arrangement that includes an obstacle at one end of the array of turbines is presented. The best configuration explored in this work increases the power coefficient of each Savonius wind turbine by 82% compared to a single turbine. Finally, the effect of the wind direction for the best configuration is presented and the range of wind angles for which the farm outperforms isolated turbines is calculated.

[1]  Mohammed Shaheen,et al.  Numerical study of two-bucket Savonius wind turbine cluster , 2015 .

[2]  Yan Li,et al.  Wind Tunnel Tests on a Different Phase Three-Stage Savonius Rotor , 2005 .

[3]  S. J. Savonius,et al.  The S-rotor and its applications , 1931 .

[4]  Ki-Wahn Ryu,et al.  Effects of end plates with various shapes and sizes on helical Savonius wind turbines , 2015 .

[5]  W. A. El-Askary,et al.  Harvesting wind energy for improving performance of Savonius rotor , 2015 .

[6]  M. A. Kamoji,et al.  Performance tests on helical Savonius rotors , 2009 .

[7]  Ying Xue Yao,et al.  Design based on a parametric analysis of a drag driven VAWT with a tower cowling , 2013 .

[8]  Seach Chyr Goh,et al.  Tow testing of Savonius wind turbine above a bluff body complemented by CFD simulation , 2016 .

[9]  David Afungchui,et al.  Vortical structures in the wake of the savonius wind turbine by the discrete vortex method , 2014 .

[10]  Gábor Janiga,et al.  Optimal blade shape of a modified Savonius turbine using an obstacle shielding the returning blade , 2011 .

[11]  Grzegorz Liskiewicz,et al.  Numerical investigation of conventional and modified Savonius wind turbines , 2013 .

[12]  Takenori Ogawa,et al.  The Effects of a Deflecting Plate and Rotor End Plates on Performances of Savonius-type Wind Turbine , 1986 .

[13]  V. J. Modi,et al.  On the Performance of the Savonius Wind Turbine , 1989 .

[14]  Burçin Deda Altan,et al.  The use of a curtain design to increase the performance level of a Savonius wind rotors , 2010 .

[15]  M. H. Mohamed,et al.  Innovative improvement of a drag wind turbine performance , 2016 .

[16]  Jean-Luc Menet,et al.  A double-step Savonius rotor for local production of electricity: a design study , 2004 .

[17]  Marius Paraschivoiu,et al.  CFD based synergistic analysis of wind turbines for roof mounted integration , 2016 .

[18]  Xiaojing Sun,et al.  Numerical study on coupling effects among multiple Savonius turbines , 2012 .

[19]  Gábor Janiga,et al.  Optimization of Savonius turbines using an obstacle shielding the returning blade , 2010 .

[20]  Hee-Chang Lim,et al.  Effect of twist angle on the performance of Savonius wind turbine , 2016 .

[21]  Chiun-Hsun Chen,et al.  Novel plant development of a parallel matrix system of Savonius wind rotors with wind deflector , 2015 .