Damage index estimation by analysis of meteorological disasters on
Keywords:
damage index, global warming, heavy snow, strong wind, heavy rain, protected horticulture, typhoon, vinyl houseAbstract
This study focuses on the analysis of the effect of meteorological disasters on film plastic greenhouses by typhoons, heavy snow, strong wind, and heavy rain. The data of meteorological disasters from 1998 to 2015 were analyzed on provincial basis to calculate the damage rate depending on the weather cause. The cumulative damage area is 20279 hm2. The damage rates of typhoons, heavy snow, strong wind, and heavy rain are 46.4%, 47.4%, 2.5%, and 3.8%, respectively. The damage index of the greenhouse, which is the ratio of the greenhouse area to the cumulative damage area, was proposed to estimate the disaster risk for 17 administrative districts. The damage index data and the cumulative damage areas were divided using the Jenks’ Natural Breaks method. The average damage index is 0.66, and the damage indices are high in the metropolitan cities. Keywords: damage index, global warming, heavy snow, strong wind, heavy rain, protected horticulture, typhoon, vinyl house DOI: 10.25165/j.ijabe.20191205.4493 Citation: Ryu H R, Choi M K, Cho M W, Yu I H, Kim S Y. Damage index estimation by analysis of meteorological disasters on film plastic greenhouses. Int J Agric & Biol Eng, 2019; 12(5): 58–63.References
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[2] Yum S H, Kim S H, Lee S B, Kim M Y, Kim C S. Effect of a supplementary pole on the structural stability in the single-span plastic greenhouses. Journal of Bio-Environment Control, 2010; 19(2): 63–69.
[3] Kim B K, Lee S H, Kim J W, Shin K J. Collapse prevention method of long-span plastic greenhouse for heavy snow. Journal of Korean Society of Steel Construction, 2010; 22(1): 67–74.
[4] Jung D J, Teng C. Effect of wire bracing to snow load acting on vinyl house frame. Journal of the Korean Institute of Rural Architecture, 2010; 12(3): 27–34.
[5] Shin K J, Shin D H, Lee S H, Chae S H. Reinforcement method of a long span plastic greenhouse using Tension-tie. Journal of Korean Society of Steel Construction, 2011; 23(1): 41–49.
[6] You H Y, Paek Y, Kim H J, Chun H, Yu I H. A study on structural behaviour characteristics of high-rise improved 1-2W vinyl-house for paprika cultivation. Proceeding of Bio-Environment Control, 2007; 16(2): 42.
[7] Ryu H R, Yu I H, Cho M W, Um Y C. Structural reinforcement methods and structural safety analysis for the elevated eaves height 1-2W type plastic greenhouse. Journal of Bio-Environment Control, 2009; 18(3): 192–199.
[8] Yum S H, Kim C S, Choi Y D. Analysis of the structural safety of a wind-protecting wall using Ansys/Cfx. Journal of Bio-Environment Control, 2006; 15(2): 138–148.
[9] Yum S H, Kang S-H. An experimental study on characteristics of
pressure drop of screens used in horticultural facilities. Journal of the Korean Society of Agricultural Engineers, 2013; 55(6): 31–35.
[10] Ryu H R, Cho M W, Yu I H, Moon D G. Finite element modeling for structure–soil interaction analysis of plastic greenhouse foundation. Korean Journal of Agricultural Science, 2014; 41(4): 455–460.
[11] Yu I H, Lee E H, Cho M W, Ryu H R, Kim Y C. Development of multi-span plastic greenhouse for tomato cultivation. Journal of Bio-Environment Control, 2012; 21(4): 428–436.
[12] Yu I H, Lee E H, Cho M W, Ryu H R, Gyung M D. Development of single-span plastic greenhouses for hot pepper rainproof cultivation. Protected Horticulture and Plant Factory, 2013; 22(4): 371–377.
[13] Yu I H, Lee E H, Cho M W, Ryu H R, Moon D G. Development of rain shelter for chinese cabbage rainproof cultivation. Protected Horticulture and Plant Factory, 2014; 23(4): 293–302.
[14] Park J K, Jang E S, Choi H J. An analysis of meteorological disasters occurred in the korean peninsula. Journal of the Environmental Science International, 2005; 14(6): 613–619.
[15] Choi H J. Review of risk model and application of the prevention meteorological information to reduce the natural disasters. Master's degree thesis, Kimhae: Inje University, 2007, 2: 17.
[16] Ahn S H, Park K J, Kim J Y, Kim B J. The characteristics of the frequency and damage for meteorological disasters in Korea. Journal of Korean Society of Hazard Mitigation, 2015; 15(2): 133–144.
[17] Moriyama H, Sase S, Kowata H, Ishii M. Engineering analysis of the greenhouse structures damaged by typhoon 0221 in Chiba and Ibaraki. Journal of SASJ, 2003; 34(3): 199–212.
[18] Moriyama H, Toyoda H. Characteristics of greenhouses by heavy snow in January 1998 in Southern Tohoku area. Journal of SASJ, 1999; 30(2): 205–214.
[19] Lee S G. Destruction shapes and structural safety of greenhouses by strong wind. Korean Journal of Horticultural Science & Technology, 2001; 19(4): 623–628.
[20] Ryu H R, Lee E H, Cho M W, Yu I H, Kim Y C. Evaluation on the behavioral characteristics of plastic greenhouse by full-scale testing and finite element analysis. Journal of Bio-Environment Control, 2012; 21(4): 459–465.
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[22] Lee S Y, Kim H J, Yum S H, Kang Y I, Chun H, Nam Y I. Investigation and analysis of damaged single-span greenhouse by Typhoon 'Maemi'. Proceedings of the Korean Society for Bio-Environment Control Conference, 2005.
[23] Ministry of Agriculture Food and Rural Affairs (MAFRA). Annals of Greenhouse Status and Vegetables Production in Korea. Gwacheon: MAFRA, 2015. http://library.mafra.go.kr/skyblueimage/25004.pdf. Accessed on [2017-01-09].
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[25] Ministry of Agriculture Food and Rural Affairs (MAFRA) and Rural Development Administration (RDA). Design and Construction Code on Horticultural and Herbal Facilities for Disaster Resistance. Gwacheon and Jeonju: MAFRA & RDA. 2014. http://www.nongsaro.go.kr/portal/ contentsFileView.do?cntntsNo=89218&fileSeCode=185001&fileSn=1. Accessed on [2017-01-09].
[26] Korea Meteorological Administration (KMA). Annual Climatological Report. Seoul: KMA. 2015. http://www.kma.go.kr/repositary/sfc/pdf/ sfc_ann_2015.pdf. Accessed on [2017-01-09].
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[28] Korea Meteorological Administration (KMA). Annual Climatological Report. Seoul: KMA. 2012. http://www.kma.go.kr/repositary/sfc/pdf/ sfc_ann_2012.pdf. Accessed on [2017-01-09].
[2] Yum S H, Kim S H, Lee S B, Kim M Y, Kim C S. Effect of a supplementary pole on the structural stability in the single-span plastic greenhouses. Journal of Bio-Environment Control, 2010; 19(2): 63–69.
[3] Kim B K, Lee S H, Kim J W, Shin K J. Collapse prevention method of long-span plastic greenhouse for heavy snow. Journal of Korean Society of Steel Construction, 2010; 22(1): 67–74.
[4] Jung D J, Teng C. Effect of wire bracing to snow load acting on vinyl house frame. Journal of the Korean Institute of Rural Architecture, 2010; 12(3): 27–34.
[5] Shin K J, Shin D H, Lee S H, Chae S H. Reinforcement method of a long span plastic greenhouse using Tension-tie. Journal of Korean Society of Steel Construction, 2011; 23(1): 41–49.
[6] You H Y, Paek Y, Kim H J, Chun H, Yu I H. A study on structural behaviour characteristics of high-rise improved 1-2W vinyl-house for paprika cultivation. Proceeding of Bio-Environment Control, 2007; 16(2): 42.
[7] Ryu H R, Yu I H, Cho M W, Um Y C. Structural reinforcement methods and structural safety analysis for the elevated eaves height 1-2W type plastic greenhouse. Journal of Bio-Environment Control, 2009; 18(3): 192–199.
[8] Yum S H, Kim C S, Choi Y D. Analysis of the structural safety of a wind-protecting wall using Ansys/Cfx. Journal of Bio-Environment Control, 2006; 15(2): 138–148.
[9] Yum S H, Kang S-H. An experimental study on characteristics of
pressure drop of screens used in horticultural facilities. Journal of the Korean Society of Agricultural Engineers, 2013; 55(6): 31–35.
[10] Ryu H R, Cho M W, Yu I H, Moon D G. Finite element modeling for structure–soil interaction analysis of plastic greenhouse foundation. Korean Journal of Agricultural Science, 2014; 41(4): 455–460.
[11] Yu I H, Lee E H, Cho M W, Ryu H R, Kim Y C. Development of multi-span plastic greenhouse for tomato cultivation. Journal of Bio-Environment Control, 2012; 21(4): 428–436.
[12] Yu I H, Lee E H, Cho M W, Ryu H R, Gyung M D. Development of single-span plastic greenhouses for hot pepper rainproof cultivation. Protected Horticulture and Plant Factory, 2013; 22(4): 371–377.
[13] Yu I H, Lee E H, Cho M W, Ryu H R, Moon D G. Development of rain shelter for chinese cabbage rainproof cultivation. Protected Horticulture and Plant Factory, 2014; 23(4): 293–302.
[14] Park J K, Jang E S, Choi H J. An analysis of meteorological disasters occurred in the korean peninsula. Journal of the Environmental Science International, 2005; 14(6): 613–619.
[15] Choi H J. Review of risk model and application of the prevention meteorological information to reduce the natural disasters. Master's degree thesis, Kimhae: Inje University, 2007, 2: 17.
[16] Ahn S H, Park K J, Kim J Y, Kim B J. The characteristics of the frequency and damage for meteorological disasters in Korea. Journal of Korean Society of Hazard Mitigation, 2015; 15(2): 133–144.
[17] Moriyama H, Sase S, Kowata H, Ishii M. Engineering analysis of the greenhouse structures damaged by typhoon 0221 in Chiba and Ibaraki. Journal of SASJ, 2003; 34(3): 199–212.
[18] Moriyama H, Toyoda H. Characteristics of greenhouses by heavy snow in January 1998 in Southern Tohoku area. Journal of SASJ, 1999; 30(2): 205–214.
[19] Lee S G. Destruction shapes and structural safety of greenhouses by strong wind. Korean Journal of Horticultural Science & Technology, 2001; 19(4): 623–628.
[20] Ryu H R, Lee E H, Cho M W, Yu I H, Kim Y C. Evaluation on the behavioral characteristics of plastic greenhouse by full-scale testing and finite element analysis. Journal of Bio-Environment Control, 2012; 21(4): 459–465.
[21] Ministry of Public Safety and Security (MPSS). Statistical Yearbook of Natural Disaster Sejong: MPSS. 2017. http://www.safekorea.kr/ idsiSFK/367/menuMap.do?w2xPath=/idsiSFK/wq/sfk/cs/csc/bbs_conf.xml&bbs_no=26. Accessed on [2017-01-09].
[22] Lee S Y, Kim H J, Yum S H, Kang Y I, Chun H, Nam Y I. Investigation and analysis of damaged single-span greenhouse by Typhoon 'Maemi'. Proceedings of the Korean Society for Bio-Environment Control Conference, 2005.
[23] Ministry of Agriculture Food and Rural Affairs (MAFRA). Annals of Greenhouse Status and Vegetables Production in Korea. Gwacheon: MAFRA, 2015. http://library.mafra.go.kr/skyblueimage/25004.pdf. Accessed on [2017-01-09].
[24] Korea Meteorological Administration (KMA). Annual Climatological Report. Seoul: KMA. 2004. http://www.kma.go.kr/repositary/sfc/pdf/ sfc_ann_2004.pdf. Accessed on [2017-01-09].
[25] Ministry of Agriculture Food and Rural Affairs (MAFRA) and Rural Development Administration (RDA). Design and Construction Code on Horticultural and Herbal Facilities for Disaster Resistance. Gwacheon and Jeonju: MAFRA & RDA. 2014. http://www.nongsaro.go.kr/portal/ contentsFileView.do?cntntsNo=89218&fileSeCode=185001&fileSn=1. Accessed on [2017-01-09].
[26] Korea Meteorological Administration (KMA). Annual Climatological Report. Seoul: KMA. 2015. http://www.kma.go.kr/repositary/sfc/pdf/ sfc_ann_2015.pdf. Accessed on [2017-01-09].
[27] Korea Meteorological Administration (KMA). Annual Climatological Report. Seoul: KMA. 2007. http://www.kma.go.kr/repositary/sfc/pdf/ sfc_ann_2007.pdf. Accessed on [2017-01-09].
[28] Korea Meteorological Administration (KMA). Annual Climatological Report. Seoul: KMA. 2012. http://www.kma.go.kr/repositary/sfc/pdf/ sfc_ann_2012.pdf. Accessed on [2017-01-09].
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Published
2019-10-14
How to Cite
Ryu, H., Choi, M., Cho, M., Yu, I., & Kim, S. (2019). Damage index estimation by analysis of meteorological disasters on. International Journal of Agricultural and Biological Engineering, 12(5), 58–63. Retrieved from https://ijabe.migration.pkpps03.publicknowledgeproject.org/index.php/ijabe/article/view/4493
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Animal, Plant and Facility Systems
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