Pin Liu, Yusuke Oka, Yoichi Kinoue, Norimasa Shiomi, Toshiaki Setoguchi, Yingzi Jin
Department of Mechanical Engineering, Saga University, Saga, Japan.
Faculty of Mechanical Engineering & Automation, Zhejiang Sci-Tech University, Hangzhou, China.
DOI: 10.4236/ojfd.2013.32A001   PDF    HTML     4,627 Downloads   8,025 Views   Citations

Abstract

Half-ducted fan and ducted fan have been designed and numerically analyzed for investigating the radial flow effect on the overall performance and the three dimensional flow field in design. Based on quasi-three dimensional flow theory, the meridional flow was calculated by adopting the radial balance equations, while the calculation of the blade to blade flow was obtained by 2D cascade data with the correction by a potential flow theory. Two types of axial flow fan were designed. One is the full ducted case as if it was in the straight pipe and another is the half-ducted case with the radial inflow and outflow. The previous experimental results of authors were used to decide the inclinations of both the inflow and outflow. And the circular arc blade with equal thickness was adopted. The numerical results indicate that both of the designed fans can reach the specified efficiency and also the efficiency surpasses more than 11%. Furthermore, the static pressure characteristic of half-ducted fan is much better than that of ducted fan. In comparison of the three dimensional internal flow of these two fans, the improvement of the flow angle at inlet and outlet, the distributions of velocity in the flow field and the pressure distributions on the blade surfaces can be achieved more successfully in accordance with the design intension on consideration of flow angle in design. The conclusion that half-ducted design with considering radial inflow and outflow is feasible and valid in comparison with ducted design for axial flow fans has been obtained at the end of the paper.

Keywords

Axial Flow Fan; Rotational Vortex; Half-Ducted Fans; Internal Flow; Numerical Analysis

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Conflicts of Interest

The authors declare no conflicts of interest.

References

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