RISS 학술연구정보서비스

검색
다국어 입력

http://chineseinput.net/에서 pinyin(병음)방식으로 중국어를 변환할 수 있습니다.

변환된 중국어를 복사하여 사용하시면 됩니다.

예시)
  • 中文 을 입력하시려면 zhongwen을 입력하시고 space를누르시면됩니다.
  • 北京 을 입력하시려면 beijing을 입력하시고 space를 누르시면 됩니다.
닫기
    인기검색어 순위 펼치기

    RISS 인기검색어

      KCI등재

      The cooling effect of vertical greening systems using solar radiation measurement

      한글로보기

      https://www.riss.kr/link?id=A109243743

      • 0

        상세조회
      • 0

        다운로드
      서지정보 열기
      • 내보내기
      • 내책장담기
      • 공유하기
      • 오류접수

      부가정보

      다국어 초록 (Multilingual Abstract) kakao i 다국어 번역

      Vertical greening systems (VGS) can effectively mitigate the urban heat island effect in urban canyons with dense high-rise buildings. This study evaluates the cooling effect of VGS on solar radiation and atmospheric temperature. A thermodynamic analysis was utilized to assess the impact of VGS on outdoor thermal comfort. CNR4 equipment collected data on long-wave and short-wave radiation from Fatsia japonica plants. These data formed the basis for simulation analyses with the Envi-met model, which showed that VGS exhibit significant diurnal surface temperature variations in the urban environment during the summer months. Areas with VGS had higher temperatures than those of high albedo walls (HAW) from 2:00 to 4:00 and recorded lower temperatures than those of HAW between 13:00 and 15:00. VGS absorb short-wave and long-wave radiation better than HAW. The average short-wave radiation of VGS is 43.91 W/h2, compared to 31.50 W/h2 for HAW, while the average long-wave radiation of VGS is 2.82 W/h2, compared to -1.53 W/h2 for HAW. Envi-met simulations indicate that the surface temperature of the VGS decreases after 15:00, to about 0.1°C cooler than HAW. The data from July 15 indicate that VGS significantly outperformed HAW in terms of cooling the maximum temperature at 13:00 and stabilizing the minimum temperature at 3:00. Furthermore, the extent of the cooling effect of the VGS was approximately 1.5 meters. This demonstrates that VGS, as an eco-friendly solution, can improve the urban thermal environment, increase the urban greening rate, and promote ecologically balanced development.
      번역하기

      Vertical greening systems (VGS) can effectively mitigate the urban heat island effect in urban canyons with dense high-rise buildings. This study evaluates the cooling effect of VGS on solar radiation and atmospheric temperature. A thermodynamic analy...

      Vertical greening systems (VGS) can effectively mitigate the urban heat island effect in urban canyons with dense high-rise buildings. This study evaluates the cooling effect of VGS on solar radiation and atmospheric temperature. A thermodynamic analysis was utilized to assess the impact of VGS on outdoor thermal comfort. CNR4 equipment collected data on long-wave and short-wave radiation from Fatsia japonica plants. These data formed the basis for simulation analyses with the Envi-met model, which showed that VGS exhibit significant diurnal surface temperature variations in the urban environment during the summer months. Areas with VGS had higher temperatures than those of high albedo walls (HAW) from 2:00 to 4:00 and recorded lower temperatures than those of HAW between 13:00 and 15:00. VGS absorb short-wave and long-wave radiation better than HAW. The average short-wave radiation of VGS is 43.91 W/h2, compared to 31.50 W/h2 for HAW, while the average long-wave radiation of VGS is 2.82 W/h2, compared to -1.53 W/h2 for HAW. Envi-met simulations indicate that the surface temperature of the VGS decreases after 15:00, to about 0.1°C cooler than HAW. The data from July 15 indicate that VGS significantly outperformed HAW in terms of cooling the maximum temperature at 13:00 and stabilizing the minimum temperature at 3:00. Furthermore, the extent of the cooling effect of the VGS was approximately 1.5 meters. This demonstrates that VGS, as an eco-friendly solution, can improve the urban thermal environment, increase the urban greening rate, and promote ecologically balanced development.

      더보기

      참고문헌 (Reference)

      1 Cameron RW, "What’s ‘cool’ in the world of green façades? How plant choice influences the cooling properties of green walls" 73 : 198-207, 2014

      2 Medl A, "Vertical greening systems-A review on recent technologies and research advancement" 125 : 227-239, 2017

      3 Price A, "Vertical greenery systems as a strategy in urban heat island mitigation" 226 : 247-, 2015

      4 Koch K, "Urban heat stress mitigation potential of green walls : A review" 55 : 126843-, 2020

      5 Nasir MHA, "Thermal performance of double brick wall construction on the building envelope of high-rise hotel in Malaysia" 31 : 101389-, 2020

      6 Wong NH, "Thermal evaluation of vertical greenery systems for building walls" 45 (45): 663-672, 2010

      7 Morakinyo TE, "Thermal benefits of vertical greening in a high-density city : Case study of Hong Kong" 37 : 42-55, 2019

      8 Zhang L, "Thermal behavior of a vertical green facade and its impact on the indoor and outdoor thermal environment" 204 : 109502-, 2019

      9 Yang Y, "The"plant evaluation model"for the assessment of the impact of vegetation on outdoor microclimate in the urban environment" 159 : 106151-, 2019

      10 Alsaad H, "The potential of facade greening in mitigating the effects of heatwaves in Central European cities" 216 : 109021-, 2022

      1 Cameron RW, "What’s ‘cool’ in the world of green façades? How plant choice influences the cooling properties of green walls" 73 : 198-207, 2014

      2 Medl A, "Vertical greening systems-A review on recent technologies and research advancement" 125 : 227-239, 2017

      3 Price A, "Vertical greenery systems as a strategy in urban heat island mitigation" 226 : 247-, 2015

      4 Koch K, "Urban heat stress mitigation potential of green walls : A review" 55 : 126843-, 2020

      5 Nasir MHA, "Thermal performance of double brick wall construction on the building envelope of high-rise hotel in Malaysia" 31 : 101389-, 2020

      6 Wong NH, "Thermal evaluation of vertical greenery systems for building walls" 45 (45): 663-672, 2010

      7 Morakinyo TE, "Thermal benefits of vertical greening in a high-density city : Case study of Hong Kong" 37 : 42-55, 2019

      8 Zhang L, "Thermal behavior of a vertical green facade and its impact on the indoor and outdoor thermal environment" 204 : 109502-, 2019

      9 Yang Y, "The"plant evaluation model"for the assessment of the impact of vegetation on outdoor microclimate in the urban environment" 159 : 106151-, 2019

      10 Alsaad H, "The potential of facade greening in mitigating the effects of heatwaves in Central European cities" 216 : 109021-, 2022

      11 Bevilacqua P, "The effectiveness of green roofs in reducing building energy consumptions across different climates. A summary of literature results" 151 : 111523-, 2021

      12 Marino C, "The effect of the short wave radiation and its reflected components on the mean radiant temperature : modelling and preliminary experimental results" 9 : 42-51, 2017

      13 Alexandri E, "Temperature decreases in an urban canyon due to green walls and green roofs in diverse climates" 43 (43): 480-493, 2008

      14 Pianella A, "Substrate depth, vegetation and irrigation affect green roof thermal performance in a mediterranean type climate" 9 (9): 1451-, 2017

      15 Paudyal K, "Spatial assessment of the impact of land use and land cover change on supply of ecosystem services in Phewa watershed, Nepal" 36 : 100895-, 2019

      16 Yang Y, "Solar radiation effects on dry matter accumulations and transfer in maize" 12 : 727134-, 2021

      17 Oliveira ELD, "Relations between urban subsoil and climate change in different neighborhoods of Rio de Janeiro" 23 : e01782-, 2020

      18 Kim ES, "Quantifying outdoor cooling effects of vertical greening system on mean radiant temperature" 15 : 100211-, 2023

      19 Hayes AT, "Nature-Based Solutions(NBSs)to mitigate Urban Heat Island(UHI)effects in Canadian cities" 12 (12): 925-, 2022

      20 Zhang Y, "Multi-scale structure synergistic strategy : A transpiration inspired hierarchical aerogel evaporator for highly efficient solar-driven clean water production" 10 (10): 107934-, 2022

      21 Lauster M, "Modelling long-wave radiation heat exchange for thermal network building simulations at urban scale using Modelica" Modelica Association 125-133, 2014

      22 Zhao C, "Long-wave infrared radiation properties of vertical green façades in subtropical regions" 223 : 109518-, 2022

      23 Carroll J, "Japanese Aralia care: How to grow Fatsia Japonica"

      24 Peng J, "How to quantify the cooling effect of urban parks? Linking maximum and accumulation perspectives" 252 : 112135-, 2021

      25 Shahmohamadi P, "Healthy environment : The need to mitigate urban heat island effects on human health" 20 : 61-70, 2011

      26 Djedjig R, "Experimental study of the urban microclimate mitigation potential of green roofs and green walls in street Canyons" 10 (10): 34-44, 2015

      27 Crank PJ, "Evaluating the ENVI-met microscale model for suitability in analysis of targeted urban heat mitigation strategies" 26 : 188-197, 2018

      28 Cortes A, "Evaluating mitigation strategies for urban heat island in Mandaue city using ENVI-met" 11 (11): 97-106, 2022

      29 Chen Q, "Establishment and validation of a solar radiation model for a living wall system" 195 : 105-115, 2019

      30 The Paper, "Enhancing cultural and climate leadership is key to sustainable development in the world’s cities (1)"

      31 Pan L, "Energy saving potential and life cycle environmental impacts of a vertical greenery system in Hong Kong : A case study" 96 : 293-300, 2016

      32 Lee LSH, "Energy benefits of green-wall shading based on novel-accurate apportionment of short-wave radiation components" 238 : 1506-1518, 2019

      33 Brar VW, "Electronic modulation of infrared radiation in graphene plasmonic resonators" 6 : 7032-, 2015

      34 Tan CL, "Effects of vertical greenery on mean radiant temperature in the tropical urban environment" 127 : 52-64, 2014

      35 Ali-Toudert F, "Effects of asymmetry, galleries, overhanging façades and vegetation on thermal comfort in urban street canyons" 81 (81): 742-754, 2007

      36 Erell E, "Effect of high-albedo materials on pedestrian heat stress in urban street canyons" 10 : 367-386, 2014

      37 Saiz S, "Comparative life cycle assessment of standard and green roofs" 40 (40): 4312-4316, 2006

      38 Shafiee E, "Assessment of the effect of living wall systems on the improvement of the urban heat island phenomenon" 181 : 106923-, 2020

      39 Ng E, "A study on the cooling effects of greening in a high-density city : An experience from Hong Kong" 47 : 256-271, 2012

      40 Su M, "A review on the mechanisms behind thermal effect of building Vertical Greenery Systems(VGS) : Methodology, performance and impact factors" 303 : 113785-, 2024

      더보기

      분석정보

      View

      상세정보조회

      0

      Usage

      원문다운로드

      0

      대출신청

      0

      복사신청

      0

      EDDS신청

      0

      동일 주제 내 활용도 TOP

      더보기

      주제

      연도별 연구동향

      연도별 활용동향

      연관논문

      연구자 네트워크맵

      공동연구자 (7)

      유사연구자 (20) 활용도상위20명

      이 자료와 함께 이용한 RISS 자료

      나만을 위한 추천자료

      해외이동버튼