The impact of urban green infrastructure as a sustainable approach towards tropical micro-climatic changes and human thermal comfort

《The impact of urban green infrastructure as a sustainable approach towards tropical micro-climatic changes and human thermal comfort》

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来源: URBAN FORESTRY & URBAN GREENING,Vol.34,P.1-9

语言: 英文

关键字: CO2 concentration; Indoor thermal comfort; Occupants' satisfaction; Relative humidity; Vertical greening systems (VGS); LIVING WALLS; FACADES; SYSTEMS; SPACE; BUILDINGS; TEMPERATURE; PERFORMANCE; CITIES; URBANIZATION; PERCEPTION

作者单位: [Galagoda, R. U.; Jayasinghe, G. Y.] Univ Ruhuna, Fac Agr, Dept Agr Engn, Matara, Sri Lanka. [Halwatura, R. U.; Rupasinghe, H. T.] Univ Moratuwa, Dept Civil Engn, Fac Engn, Moratuwa, Sri Lanka. [Jayasinghe, G. Y.] Univ Melbourne, Dept Agr & Food Syst, Melbourne, Vic, Australia. [Galagoda, R. U.] Univ Ruhuna, Fac Agr, Dept Agr Engn, Mapalana, Sri Lanka. Jayasinghe, GY (reprint author), Univ Ruhuna, Fac Agr, Dept Agr Engn, Matara, Sri Lanka.; Jayasinghe, GY (reprint author), Univ Melbourne, Dept Agr & Food Syst, Melbourne, Vic, Australia.; Jayasinghe, GY (reprint author), Univ Ruhuna, Fac Agr, Dept Agr Engn, Mapalana, Sri Lanka. E-Mail: jayasinghe@ageng.ruh.ac.lk

摘要: Green infrastructures such as living walls are technological solutions to replace the declined greenery at urbanized environment and also reliable applications for thermal regulation in buildings through insulation effect and escalates the energy use efficiency. Thermal comfort and local climate are spatiotemporally variable. The existing research gap should be addressed by evaluating the performance of vertical green walls in tropical condition. In this study, thermal performance, relative humidity (RH) and CO2 concentration were quantified for basic three types of green infrastructures; such as (T-1) living walls, (T-2) indirect green facades and (T-3) direct green facades located in Colombo metropolitan in Sri Lanka. An in-situ experimental study was conducted considering temperatures at 1 m and 0.1 m distance in front of the green walls, inside the foliage, air gap and external wall surface comparatively to adjacent bare wall control. Three case studies per green infrastructure within Colombo metropolitan area were purposively selected. Simultaneously, RH and CO2 concentration at 0.1 m in front of the green and bare walls were measured for the performance quantification. The internal thermal comfort simulation and occupants' satisfaction questionnaire survey was executed to assess the green infrastructure performances. The study revealed that vertical greenery systems were highly effective on external wall surface temperature reductions at 1100 h-1500 h time zones. T-1 and T-2 accounted for superior temperature reduction in the range of 1.61 degrees C-1.72 degrees C through the facade relative to the distance than T3. Maximum temperature reduction compared to the bare wall control was obtained for the T-1 (0.28 degrees C-8.0 degrees C) followed by T-2 (1.34 degrees C-7.86 degrees C) and T-3 (1.34 degrees C-6.64 degrees C). Averaged RH increment (1.6%-1.81%) and CO2 reduction (0.63%) occurred near green walls at day time compared to control. An average 28 degrees C simulated indoor temperature circumstantiate the indoor thermal comfort. 58% and 89.5% occupants' were satisfied with thermal and visual comfort respectively, thus emphasizing facade greening as a sustainable approach on micro climatic changes and human thermal comfort.