Journal of Bio-Environment Control (생물환경조절학회지)

The Korean Society for Bio-Environment Control (한국생물환경조절학회)
권호 표지

Heating Performance of Hot Water Supplying System in Greenhouse

온수배관을 이용한 온실의 난방성능

  • Yoon, Yong-Cheol (Dept. of Agricultural Eng., Gyeongsang National Univ. (Institute of Agriculture and Life Science, GNU)) ;
  • Shin, Yik-Soo (Graduate School, Gyeongsang National Univ.) ;
  • Kim, Hyeon-Tae (Dept. of Bio-Industrial Machinery Eng., Gyeongsang National Univ. (Insti. of Agric. & Life Sci.)) ;
  • Bae, Seoung-Beom (T.O.P TECH, Business Incubator Center, Changwon Moonsung College) ;
  • Choi, Jin-Sik (S.H.E.C. Co., Ltd.) ;
  • Suh, Won-Myung (Dept. of Agricultural Eng., Gyeongsang National Univ. (Institute of Agriculture and Life Science, GNU))
  • 윤용철 (경상대학교 지역환경기반공학과(농업생명과학연구원)) ;
  • 신익수 (경상대학교 대학원) ;
  • 김현태 (경상대학교 생물산업기계공학과(농업생명과학연구원)) ;
  • 배승범 (티오피 테크) ;
  • 최진식 ((주)신한엔지니어링) ;
  • 서원명 (경상대학교 지역환경기반공학과(농업생명과학연구원))
  • Received : 2012.05.04
  • Accepted : 2012.06.15
  • Published : 2012.06.30
Download PDF
⟨ Previous Next ⟩

Abstract

This research was conducted to obtain basic data with regard to the heating performance that would be produced by installing an aluminum hot water pipe inside the greenhouse with the goal of reducing the heating energy in greenhouse. The research results are summarized as follows. The degree of difference in relation to the temperature by height within the greenhouse during the entire experiment was significant - within the range of 4.0~$7.0^{\circ}C$. The temperature difference between incoming and outgoing water was about $3.3^{\circ}C$ greater when FCU was activated compared to when it was not activated. Meanwhile, the amount of energy consumed increased about 36.2~40.1%. The amount of pyrexia per hour also increased by 44.6~52.0%. During the experiment period, circulated flux was within the range of 0.48~$0.49L{\cdot}s^{-1}$ while average fluid speed was 1.53~$1.56m{\cdot}s^{-1}$. The average temperature difference between incoming and outgoing water was 6.24~$11.50^{\circ}C$. The amount of heating value by each set temperature within the minimum outdoor temperature range of -14.0~$-0.6^{\circ}C$ was 135,930~307,150 kcal, and the range was within the 9,610~$19,630kcal{\cdot}h^{-1}$ per hour. This demonstrated that about 23~53% heating energy of the maximum heating load could be supplied. Total radiating value and amount of energy consumed were 2,548,306 kcal and 3,075.7 kWh, respectively. When heating takes place using oil, which is a fossil fuel, the total amount of light oil consumed was 281.6 L while the cost was 321,000 won. When the electricity cost for farms is applied, the total cost was about 110,730 won, which is about 33.5% of the cost required compared to oil consumption. The temperature at in the experiment area was about 8.3~$14.6^{\circ}C$ higher compared to that of the control area.

본 연구는 온실의 난방 에너지 절감을 목적으로 온실 내부에 알루미늄 온수배관을 설치하여 난방효과에 대한 기초자료를 구축하고자 수행되었다. 그 연구결과를 요약하면 다음과 같다. 전체 실험을 포함하여 온실내의 높이별 온도편차는 4.0~$7.0^{\circ}C$ 정도의 범위로서 그 차이가 크게 나타났다. 팬코일유니트(FCU)를 작동시킨 경우가 작동시키지 않은 경우에 비해 유출입수의 온도차가 $3.3^{\circ}C$ 정도 크고, 소비전력량은 36.2~40.1%정도 증가하였으며, 시간당 방열량은 44.6~52.0% 정도 증가하는 것으로 나타났다. 실험기간동안 순환유량은 0.48~$0.49L{\cdot}s^{-1}$ 정도의 범위에 있었고, 평균유속은 1.53~$1.56m{\cdot}s^{-1}$ 정도였다. 유출입수의 평균 온도차는 6.24~$11.50^{\circ}C$이었다. 최저 외기온 -14.0~$-0.6^{\circ}C$ 범위에서 설정온도별 방열량은 135,930~307,150kcal 정도의 범위로서 시간당 9,610~$19,630kcal{\cdot}h^{-1}$ 정도의 범위에 있었다. 이것은 최대난방부하의 약 23~53% 정도의 난방에너지를 공급할 수 있을 것으로 나타났다. 전체 방열량과 소비전력량은 각각 2,548,306kcal 및 3,075.7kWh이다. 화석연료인 경유로 난방할 경우, 소요되는 경유의 총 소비량은 281.6L 정도이고 비용은 321,000won인 것으로 나타났다. 농가용 전력요금을 적용하면 전력사용에 대한 총비용은 110,730won 정도로서 경유 소비 비용의 33.5% 정도로 나타났다. 실험구의 온도가 대조구보다 약 8.3~$14.6^{\circ}C$ 정도 높게 나타났다.

Keywords

References

  1. http://www.naver.com.
  2. http://www.nogmin.com.0000
  3. Kim, J.H., T.W. Kim, J.K. Song, K.D. Nah, Y.S. Ha, T.S. Kim, and E.T. Kim. 2011. Study on temperature variation by greenhouse soil warming system using solar thermal energy(3) -verification experiment on commercialization of cultivation-. J. of Biosystems Eng. 36(3):211-216 (in Korean). https://doi.org/10.5307/JBE.2011.36.3.211
  4. Kim, M.G., S.W. Nam, W.M. Suh, Y.C. Yoon, S.G. Lee, and H.W. Lee. 2000. Agricultural structural engineering. ed. Hyangmunsa. Seoul, Korea. p. 170 (in Korean).
  5. Koo, G.H., J.K. Song, and G.S. Park. 1998. Modelling development and environmental analysis of oriental melon greenhouse in SUNGJU(1). J. Bio. Fac. Env. 7(4):311-323 (in Korean).
  6. Kwon, J.K., J.P. Moon, S.H. Lee, J.H. Seong, S.J. Lee, B.M. Choi, and K.J. Kim. 2012. Development of diagnostic system for heat loss of horticultural facility. proceeding of the KSAM 2012 winter conference. 17(1): 346 (in Korean).
  7. Lee, Y.B., H.J. Jun, and J.E. Son. 2010. Protected horticulture new edition. ed. Hyangmoonsa, Seoul, Korea. pp. 132-133 (in Korean).
  8. Lee, H.S., Y.S. Ryou, J.P. Moon, N.K. Yun, J.K. Kwon, S.L. Lee, and K.M. Kim. 2011. Solar energy storage effectiveness on double layered single span plastic greenhouse. J. of Biosystems Eng. 36(3):217- 222 (in Korean). https://doi.org/10.5307/JBE.2011.36.3.217
  9. Ministry for Food, Agriculture, Forestry and Fisheries (MIFAFF). 2011a. Greenhouse status for the vegetable grown in facilities and the vegetable productions in 2010. ed. Gwacheon, Korea (in Korean).
  10. Ministry for Food, Agriculture, Forestry and Fisheries (MIFAFF). 2011b. Cultivation status of floricultural crop in 2010. ed. Gwacheon, Korea (in Korean).
  11. Park, H.S. 2011. Casting plan for rationalization of energy use in the agriculture and fishery. Proceedings of the KSBEC 2011 spring conference and symposium. Korean Society for Bio-Environ. Control 20:28- 38 (in Korean).
  12. Rural Development Administration (RDA). 2010. New agricultural energy reducing technique. ed. Suwon, Korea (in Korean).
  13. Rural Development Administration (RDA). 2009. Case collection of heat loss audit for agricultural facilities. ed. Suwon, Korea (in Korean).
  14. Rural Development Administration (RDA). 2008a. Guidebook of energy saving for overcoming high oil price in protected horticulture. ed. Suwon, Korea (in Korean).
  15. Rural Development Administration (RDA). 2008b. Technology of operating cost down for agriculture. ed. Suwon, Korea (in Korean).
  16. Suh, W.M., J.W. Leem, Y.J. Kim, Y.B. Min, H.T. Kim, M.R. Huh, and Y.C. Yoon. 2010. Heating effect by electric radiator in greenhouse of chrysanthemum cultivation. J. Agri. & Life Science. 44(4):79-85 (in Korean).
  17. Suh, W.M., Y.C. Yoon, and J.K. Kwon. 2003. Heat exchange performance of improved heat recovery system. J. Bio-Env. Cont. 12(3):107-113 (in Korean).
  18. Suh, W.M., Y.C. Yoon, and J.G. Kang. 2000. Analysis of heat exchanging performance of heat recovering device attached to exhaust gas duct. J. Bio-Env. Cont. 9(4):212-222 (in Korean).
  19. Yoon, Y.C., Y.S. Shin, S.B. Bae, T. Kim, J.S. Choi, and W.M. Suh. 2012. Variation of indoor air temperature by using hot water piping in greenhouse. J. of Agric. & Life Sci. 46(2):179-190 (in Korean).
  20. Yoon, Y.C., J.U. Im, H.T. Kim, Y.J. Kim, and W.M. Suh. 2011. Estimation of surplus solar energy in greenhouse based on region. J. Agric. & Life Sci. 45:135- 141 (in Korean).
  21. Yoon, Y.C., Y.H. Bae, Y.S. Ryou, S.H. Lee, and W.M. Suh. 2009. Power generating performance of photovoltaic power system for greenhouse equipment operation. J. Bio-Env. Con. 18(3):177-184 (in Korean).
  22. Yoon, Y.C., W.M. Suh, and S.G. Lee. 1998. A study on the greenhouse heating performance of heat pump system. J. KSAE, 40(3):94-102 (in Korean).