DOI QR코드

DOI QR Code

스테인리스 쿨링포그의 온도저감효과 검증을 위한 모델설계 및 실증 실험

Model Design and Demonstration Test for the Verification of Temperature Reduction Effect of Cooling Fog System with Stainless Steel

  • 김재경 (서울대학교 생태조경지역시스템공학부 조경학전공) ;
  • 강준석 (서울대학교 생태조경지역시스템공학부 조경학전공) ;
  • 김회진 (유비 E&C)
  • Kim, Jaekyoung (Department of Landscape Architecture and Rural Systems Engineering, Seoul national University) ;
  • Kang, Junsuk (Department of Landscape Architecture and Rural Systems Engineering, Seoul national University) ;
  • Kim, Hoijin (UB E&C)
  • 투고 : 2020.01.28
  • 심사 : 2020.05.15
  • 발행 : 2020.06.30

초록

According to a NASA Goddard Institute for Space Studies report, temperatures have risen by approximately 1℃ so far, based on temperatures recorded in 1880. The 2003 heatwave in Europe affected approximately 35,000 people across Europe. In this study, a cooling fog, which is used in smart cities, was designed to efficiently reduce the temperature during a heatwave and its pilot test results were interpreted. A model experiment of the cooling fog was conducted using a chamber, in which nano mist spray instruments and spray nozzles were installed. The designed cooling fog chamber model showed a temperature reduction of up to 13.8℃ for artificial pavement and up to 8.0℃ for green surfaces. However, this model was limited by constant wind speed in the experiment. Moreover, if the cooling fog is used when the wind speed is more than 3m/s in the active green zone, the temperature reduction felt by humans is expected to be even greater. As a second study, the effect of cooling fog on temperature reduction was analyzed by installing a pilot test inside the Land Housing Institute (LHI). The data gathered in this research can be useful for the study of heat reduction techniques in urban areas.

키워드

참고문헌

  1. Arbel, A., Yekutieli, Or., Barak, M., 1999, Performance of a fog system for cooling greenhouses, Journal of Agricultural Engineering Research, 72(2), 129-136. https://doi.org/10.1006/jaer.1998.0351
  2. Jung, H. D., 2018, A Case study on policy direction for heat response in Daejeon.
  3. Katsoulas, N., Kitta, E., Kittas, C., Tsirogiannis, Il., Stamati, E., Sayvas, D., 2006, Greenhouse cooling by a fog system: Effects on microclimate and on production and quality of a soilless pepper crop, International Symposium on Greenhouse Cooling 719.
  4. Kim, J. K., Kim, W. H., Kim, E. I., Analysis of temperature influence experiment on green spaces in campus, Journal of Korea Academia-Industrial cooperation Society, 21(2), 511-520. https://doi.org/10.5762/KAIS.2020.21.2.511
  5. Kim, Y. J., Ryu, Y. S., Ryun, J. H., Oh, K. Y., Kim, S. H., 1997, Fog Nozzle-Greenhouse cooling system analysis, Protected horticulture and plant factory, 6(1), 48-54.
  6. Kwon, J. K., Lee, J. H., Park, K. S., Choi, H. G., Ryu, I. G., Cho, M. H., Kang, N. J., 2017, Effect of fog system and air circulation fan on the fruit quality of summer grown melon, Journal of Agriculture & Life Science 51(1), 69-75. https://doi.org/10.14397/jals.2017.51.1.69
  7. Nam, S. U., Kim, Y. S., Suh, D. U., 2014, Change in the plant temperature of tomato by fogging and airflow in plastic greenhouse, Protected horticulture and plant factory 23(1), 11-18. https://doi.org/10.12791/KSBEC.2014.23.1.011
  8. Nelson, C. A., Tew, M., Phetteplace, G., Schwerdt, R., Maarouf, A., Osczevski, R., Bluestein, M., Shaykewich, J., Dmarsh, D., Derby, J., 2002, Joint development and implementation by the united states and Canada of a new Wind Chill Temperature (WCT) index.
  9. Suh, W. M., Yoon, Y. C., Lee, J. Y., Lee, S. G., 1999, Greenhouse cooling by fog system, Journal of Agriculture Engineers 41(1), 60-71.