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The Installation Effect and Optimal Pipe Sizes of an Anti-Wind Net by Computational Analysis

전산 해석에 의한 파풍망의 설치 효과와 최적 파이프 규격

  • Published : 2007.12.25

Abstract

This study was carried out to(1) visualize the installation effect of an anti-wind net; (2) evaluate structural stability of typical anti-wind nets in Jeju; and (3) present the optimal specification of pipes in an anti-wind net for maximum instant wind velocities of 40 m/s and 45 m/s. The analyses were done for anti-wind nets with a mesh of 4 mm and a height of 3 m by using CFX and ANSYS. The results showed that the wind went down due to flow resistance when passing through an. anti-wind net. The anti-wind net with the supporting pipe being installed every two main columns was certainly unstable because the main column not sustained by the supporting pipe became cantilever. With regard to the position of a fixing point of the supporting pipe, von Mises stress on pipes was certainly increased as vertical positions of the supporting pipe were changed to be too lower or higher than an adequate position but there was little difference according to horizontal positions. The adequate vertical position was $2{\sim}2.5\;m$ high from the ground. For a maximum instant wind velocity of 40 m/s, the optimal specification of pipes was a main column of ${\varphi}48.1{\times}2.1$ t@2,000, cross beams(bottom and top) of ${\varphi}26.7{\times}1.9\;t$, cross beams(center) of ${\varphi}33.5{\times}2.1$ t/2ea and a supporting pipe of ${\varphi}31.8{\times}1.5$ t@2,000. In case of a maximum instant wind velocity of 45 m/s, the optimal specification of pipes with structural stability was a main column of ${\varphi}48.6{\times}3.25$ t@2,000, cross beams(bottom and top) of ${\varphi}26.7{\times}1.9\;t$, cross beams(center) of ${\varphi}48.1{\times}2.1$ t/2ea and a supporting pipe of ${\varphi}31.8{\times}1.5$ t@2,000.

Keywords

References

  1. Yum, S. H., H. J. Kim, H. Chun, S. Y. Lee, Y. I. Kang, N. G. Yun and J. H. Jeong. 2005. Analysis on the effect of structural reinforcement on the components of the non-heating greenhouse in Jeju using ANSYS/CFX. Proceedings of the International Conference on Research Highlights and Vanguard Technology on Environmental Engineering in Agricultural Systems. pp. 339-344
  2. Yum, S. H., C. S. Kim and Y. D. Choi. 2006. Analysis of the structural safety of a wind-protecting wall using ANSYS/CFX. Journal of Bio-Environment Control 15(2):138-148. (In Korean)
  3. Yum, S. H., H. J. Kim, H. Chun, S. Y. Lee and Y. H. Kim. 2006. Actual status of horticultural facilities in Jeju. Journal of Bio-Environment Control 15(1):104-107. (In Korean)
  4. 농림부, 농촌진흥청. 2007. 원예특작시설 내재해형 설계도 및 시방서(비닐하우스.인삼재배시설)

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  2. Effects of an Anti-wind Net on Wind Velocity Reduction by a Wind Tunnel Test and CFD vol.36, pp.5, 2011, https://doi.org/10.5307/JBE.2011.36.5.355
  3. Meteorological Analysis of Installation Effects of a Windbreak Net on Reducing Wind Speed at An Apple Orchard vol.15, pp.4, 2013, https://doi.org/10.5532/KJAFM.2013.15.4.298