مطالعه ای بر عملکرد دیوار سبز در جهت کاهش اتلاف حرارتی: آزمون تجربی در اقلیم معتدل و مرطوب رشت
الموضوعات :
عبداله بقائی دائمی
1
,
فرزانه اسدی ملک جهان
2
1 - باشگاه پژوهشگران جوان و نخبگان، واحد رشت، دانشگاه آزاد اسلامی، رشت، ایران. *(مسئول مکاتبات)
2 - رئیس مجتمع فنی، گروه معماری، واحد رشت، دانشگاه آزاد اسلامی، رشت، ایران
تاريخ الإرسال : 21 الأحد , صفر, 1441
تاريخ التأكيد : 20 الإثنين , جمادى الأولى, 1442
تاريخ الإصدار : 09 الأربعاء , رمضان, 1442
الکلمات المفتاحية:
اتلاف حرارتی,
اقلیم معتدل و مرطوب رشت,
دیوار سبز,
آزمایش تجربی,
ملخص المقالة :
زمینه و هدف: بهینه سازی مصرف و جلوگیری از هدر رفت انرژی، یکی از پارامترهای مهم در طراحی ساختمان های سبز و غیرفعال در راستای اهداف توسعه پایدار به شمار می رود. تحقیقات اخیر توجه به مباحث مربوط به بهینه سازی انرژی و کاهش اتلاف حرارتی را نشان می دهد. هدف اصلی مقاله حاضر، ارزیابی عملکرد حرارتی دیوار سبز و بهینه سازی مصرف انرژی بوده که در اقلیم معتدل و مرطوب رشت انجام گرفته است.روش بررسی: این مقاله به صورت آزمایش تجربی و میدانی بر روی یک ساختمان مسکونی دو طبقه دارای پوشش سبز انجام شده است. در این راستا، داده های سه ساعته دما و رطوبت در محیط داخلی و خارجی ساختمان با استفاده از دستگاه دیتالاگر98583 MIC در فصل زمستان و تابستان ثبت گردید.یافته ها: نتایج حاصل از آزمون تجربی نشان داد که که میانگین دما در محیط داخلی دیوار معمولی و دیوار سبز در فصل زمستان و فصل تابستان به ترتیب حدود 3/17 و 18، 5/30 و 28 درجه سانتی گراد است. بر این اساس، دیوار سبز در فصل زمستان توانست حدود 7/0 درجه سانتی گراد دمای داخلی را در مقایسه با دیوار معمولی گرم تر نگه دارد. در فصل تابستان نیز مشخص شد که دیوار سبز قادر بود تا در حدود 5/2 درجه سانتی گراد دمای محیط داخلی را خنک تر نگه داردبحث و نتیجه گیری: یافته ها نشان داد که دیوار سبز در فصل زمستان در مقایسه با دیوار معمولی حدود 4 درصد و در فصل تابستان حدود 9 درصد عملکرد حرارتی بهتری را از خود نشان داده است. به طور کلی،دیوار سبز در آب و هوای معتدل هم در زمستان و هم در تابستان می تواند رفتار حرارتی مناسبی را داشته باشد. در نهایت نیز مشخص شد که دیوار سبز در فصل تابستان در مقایسه با فصل زمستان می تواند عملکردی 50 درصد موثرتری را در کاهش تلفات حرارتی داشته باشد.
المصادر:
Zalba, B; Marı́n, J.M; Cabeza, L.F; and Mehling, H (2003), Review on thermal energy storage with phase change: materials, heat transfer analysis and applications, Applied Thermal Engineering 23(3): 251-283.
Niachou, A., et al. (2001). Analysis of the green roof thermal properties and investigation of its energy performance, Energy and Buildings 33(7): 719-729.
Çomaklı, K; and Yüksel, B (2003), Optimum insulation thickness of external walls for energy saving, Applied Thermal Engineering 23(4): 473-479.
Khudhair, A.M; and Farid, M.M (2004), A review on energy conservation in building applications with thermal storage by latent heat using phase change materials, Energy Conversion and Management 45(2): 263-275.
Al-Homoud, D.M.S (2005), Performance characteristics and practical applications of common building thermal insulation materials, Building and Environment 40(3): 353-366.
Dombaycı, Ö.A; Gölcü, M; and Pancar, Y (2006), Optimization of insulation thickness for external walls using different energy-sources, Applied Energy 83(9): 921-928.
Sailor, D.J (2008), A green roof model for building energy simulation programs, Energy and Buildings 40(8): 1466-1478.
R. Widiastuti, E. Prianto, WS. Budi, Investigation on the Thermal Performance of Green Facade in Tropical Climate Based on the Modelling Experiment, International Journal of Architecture, Engineering and Construction. 7 (2018) 26-33, https://doi.org/10.7492/ijaec.2018.004.
Susorova, I; Angulo, M; Bahrami, P; and Stephens, B (2013), A model of vegetated exterior facades for evaluation of wall thermal performance, Building and Environment 67: 1-13.
Perini, K; and Rosasco, P (2013). Cost–benefit analysis for green façades and living wall systems, Building and Environment 70: 110-121.
Jo, H.K; and McPherson, E.G (2001). Indirect carbon reduction by residential vegetation and planting strategies in Chicago, USA, Journal of Environmental Management 61(2): 165-177.
Kleerekoper, L; Esch, M.V; and Salcedo, T.B (2012), How to make a city climate-proof, addressing the urban heat island effect, Resources, Conservation and Recycling 64: 30-38.
Alexandri, E; and Jones, P (2008), Temperature decreases in an urban canyon due to green walls and green roofs in diverse climates, Building and Environment 43(4): 480-493.
Sheweka, S.M; and Mohamed, N.M (2012), Green Facades as a New Sustainable Approach towards Climate Change, Energy Procedia 18: 507-520.
Wong, N.H; Kwang Tan , A.Y; Tan, P.Y; and Wong, N.C (2009), Energy simulation of vertical greenery systems, Energy and Buildings 41(12): 1401-1408.
Wong, N.H; Kwang Tan, A.Y; Chen, Y; Sekar, K; Tan, P.Y; Chan, D; Chiang, K; and Wong, N.C (2010), Thermal evaluation of vertical greenery systems for building walls, Building and Environment 45(3): 663-672.
Azkorra, Z; Pérez, G; Coma, J; Cabeza, L.F; Bures, S; Álvaro, J.E; Erkoreka, A; and Urrestarazu, M (2015), Evaluation of green walls as a passive acoustic insulation system for buildings, Applied Acoustics 89: 46-56.
Pérez, G., et al. (2011), Green vertical systems for buildings as passive systems for energy savings, Applied Energy 88(12): 4854-4859.
Mehrinejad Khotbehsara, E; Baghaei Daemei, A; and Asadi Malekjahan, F (2019), Simulation study of the eco green roof in order to reduce heat transfer in four different climatic zones, Results in Engineering, Volume 2: 100010.
Mehrinejad Khotbehsara, E; Purshaba, F; Noormousavi Nasab, S; Baghaei Daemei, A; Eghbal Yakhdani, P; and Vali, R (2018), Traditional Climate Responsible Solutions in Iranian Ancient Architecture in Humid Region, Civil Engineering Journal, Volume 4, Issue 10: 2502-2512.
Baghaei Daemei, A; Eghbali, S.R; and Mehrinejad Khotbehsara, E (2019), Bioclimatic design strategies: A guideline to enhance human thermal comfort in Cfa climate zones, Journal of Building Engineering, Volume 25: 100758.
Baghaei Daemei, A; Haghgooy Osmavandani, P; and Samim Nikpey, M (2018), Study on Vernacular Architecture Patterns to Improve Natural Ventilation Estimating in Humid Subtropical Climate, Civil Engineering Journal, Volume 4, Issue 9: 2097-2110.
X. Nan, H. Yan, R. Wu, Y. Shi, Z. Bao, Assessing the thermal performance of living wall systems in wet and cold climates during the winter, Energy and Building, 208 (2020) 109680, https://doi.org/10.1016/j.enbuild.2019.109680.
Azmoodeh, M.; and Heidari, S (2014). Investigation of spatial and temporal distributions of air pollutants over Tehran in cold months of 2011-2013. Journal of Environmental Science and Technology 16(1): 361-370 (in Persian).
Azmoodeh, M.; and Heidari, S (2017). Effect of Urban Green Walls on Reduction of Temperature in Microclimates and Urban Heat Island. Journal of Environmental Science and Technology 19(5): 597-606. doi: 10.22034/jest.2017.11398 (in Persian).
Azmoodeh, M.; Heidari, S.; and Zamani, Z (1970). CBA Evaluation of Green Walls Implementation in Tehran City. Journal of Environmental Science and Technology 21(3): 237-247. doi: 10.22034/jest.2019.14556 (in Persian).
Kolyaei, M.; Hamzenejad, M.; Litkouhi, S.; and Bahrami, P. (2020). The impact internal and external indicators green wall On Environmental and Energy Savings Performance. Journal of Environmental Science and Technology 21(11): 253-267. doi: 10.22034/jest.2018.20435.2946 (in Persian).
Kolyaei, M.; Hamzenejad, M.; Bahrami, P.; and Litkouhi, S (2018). Comparing different types of green wall in order to achieve sustainability. Journal of Environmental Science and Technology, doi: 10.22034/jest.2018.16480.2505 (in Persian).
Bjerre, A.L (2011), “Green Walls.” Bachelor of Architectural Technology and Construction Management, VIA University College, Horsens, Denmark.
Susorova, I; Azimi, P; and Stephens, B (2014). The effects of climbing vegetation on the local microclimate, thermal performance, and air infiltration of four building facade orientations, Building and Environment 76: 113-124.
Olivieri, F., et al. (2014), Experimental study of the thermal-energy performance of an insulated vegetal façade under summer conditions in a continental mediterranean climate, Building and Environment 77: 61-76.
Cameron, R.W.F; Taylor, J; and Emmett, M (2015), A Hedera green façade – Energy performance and saving under different maritime-temperate, winter weather conditions, Building and Environment 92: 111-121.
Djedjig, R; Bozonnet, E; Belarbi, R (2016), Modeling green wall interactions with street canyons for building energy simulation in urban context, Urban Climate, Volume 16: 75-85.
Wong, I; Baldwin, A.N (2016), Investigating the potential of applying vertical green walls to high-rise residential buildings for energy-saving in sub-tropical region, Building and Environment, Volume 97: 34-39.
Hoelscher, M.T; Nehls, T; Jänicke, B; and Wessolek, G (2016), Quantifying cooling effects of facade greening: Shading, transpiration and insulation, Energy and Buildings, Volume 114: 283-290.
Coma, J; Pérez, G; Gracia, A.D; Burés, S, Urrestarazu, M; and Cabeza, L.F (2017), Vertical greenery systems for energy savings in buildings: A comparative study between green walls and green facades, Building and Environment, Volume 111: 228-237.
Serra, VL; Candelari, BE; Giordano, R; Montacchini, E; Tedesco, S; Larcher, F; Schiavi, A (2017). A novel vertical greenery module system for building envelopes: The results and outcomes of a multidisciplinary research project, Energy and Buildings, Volume 146: 333-352.
Pérez, G; Coma, J; Sol, S; and Cabeza, LF (2017), Green facade for energy savings in buildings: The influence of leaf area index and facade orientation on the shadow effect, Applied Energy, Volume 187: 424-437.
Helge, S (2016), Modeling urban microclimate: development, implementation and evaluation of new and improved calculation methods for the urban microclimate model ENVI-met, Dissertation Universit¨at Mainz Geographisches Institut. URL: https://publications.ub.uni-mainz.de/theses/frontdoor.php?source_opus=100000507.
Radić, M; Dodig, MB; Auer, T (2019), Green facades and living walls-A review establishing the classification of construction types and mapping the benefits, Sustainability, Volume 11 (17): 4579, https://doi.org/10.3390/su11174579.
_||_
Zalba, B; Marı́n, J.M; Cabeza, L.F; and Mehling, H (2003), Review on thermal energy storage with phase change: materials, heat transfer analysis and applications, Applied Thermal Engineering 23(3): 251-283.
Niachou, A., et al. (2001). Analysis of the green roof thermal properties and investigation of its energy performance, Energy and Buildings 33(7): 719-729.
Çomaklı, K; and Yüksel, B (2003), Optimum insulation thickness of external walls for energy saving, Applied Thermal Engineering 23(4): 473-479.
Khudhair, A.M; and Farid, M.M (2004), A review on energy conservation in building applications with thermal storage by latent heat using phase change materials, Energy Conversion and Management 45(2): 263-275.
Al-Homoud, D.M.S (2005), Performance characteristics and practical applications of common building thermal insulation materials, Building and Environment 40(3): 353-366.
Dombaycı, Ö.A; Gölcü, M; and Pancar, Y (2006), Optimization of insulation thickness for external walls using different energy-sources, Applied Energy 83(9): 921-928.
Sailor, D.J (2008), A green roof model for building energy simulation programs, Energy and Buildings 40(8): 1466-1478.
R. Widiastuti, E. Prianto, WS. Budi, Investigation on the Thermal Performance of Green Facade in Tropical Climate Based on the Modelling Experiment, International Journal of Architecture, Engineering and Construction. 7 (2018) 26-33, https://doi.org/10.7492/ijaec.2018.004.
Susorova, I; Angulo, M; Bahrami, P; and Stephens, B (2013), A model of vegetated exterior facades for evaluation of wall thermal performance, Building and Environment 67: 1-13.
Perini, K; and Rosasco, P (2013). Cost–benefit analysis for green façades and living wall systems, Building and Environment 70: 110-121.
Jo, H.K; and McPherson, E.G (2001). Indirect carbon reduction by residential vegetation and planting strategies in Chicago, USA, Journal of Environmental Management 61(2): 165-177.
Kleerekoper, L; Esch, M.V; and Salcedo, T.B (2012), How to make a city climate-proof, addressing the urban heat island effect, Resources, Conservation and Recycling 64: 30-38.
Alexandri, E; and Jones, P (2008), Temperature decreases in an urban canyon due to green walls and green roofs in diverse climates, Building and Environment 43(4): 480-493.
Sheweka, S.M; and Mohamed, N.M (2012), Green Facades as a New Sustainable Approach towards Climate Change, Energy Procedia 18: 507-520.
Wong, N.H; Kwang Tan , A.Y; Tan, P.Y; and Wong, N.C (2009), Energy simulation of vertical greenery systems, Energy and Buildings 41(12): 1401-1408.
Wong, N.H; Kwang Tan, A.Y; Chen, Y; Sekar, K; Tan, P.Y; Chan, D; Chiang, K; and Wong, N.C (2010), Thermal evaluation of vertical greenery systems for building walls, Building and Environment 45(3): 663-672.
Azkorra, Z; Pérez, G; Coma, J; Cabeza, L.F; Bures, S; Álvaro, J.E; Erkoreka, A; and Urrestarazu, M (2015), Evaluation of green walls as a passive acoustic insulation system for buildings, Applied Acoustics 89: 46-56.
Pérez, G., et al. (2011), Green vertical systems for buildings as passive systems for energy savings, Applied Energy 88(12): 4854-4859.
Mehrinejad Khotbehsara, E; Baghaei Daemei, A; and Asadi Malekjahan, F (2019), Simulation study of the eco green roof in order to reduce heat transfer in four different climatic zones, Results in Engineering, Volume 2: 100010.
Mehrinejad Khotbehsara, E; Purshaba, F; Noormousavi Nasab, S; Baghaei Daemei, A; Eghbal Yakhdani, P; and Vali, R (2018), Traditional Climate Responsible Solutions in Iranian Ancient Architecture in Humid Region, Civil Engineering Journal, Volume 4, Issue 10: 2502-2512.
Baghaei Daemei, A; Eghbali, S.R; and Mehrinejad Khotbehsara, E (2019), Bioclimatic design strategies: A guideline to enhance human thermal comfort in Cfa climate zones, Journal of Building Engineering, Volume 25: 100758.
Baghaei Daemei, A; Haghgooy Osmavandani, P; and Samim Nikpey, M (2018), Study on Vernacular Architecture Patterns to Improve Natural Ventilation Estimating in Humid Subtropical Climate, Civil Engineering Journal, Volume 4, Issue 9: 2097-2110.
X. Nan, H. Yan, R. Wu, Y. Shi, Z. Bao, Assessing the thermal performance of living wall systems in wet and cold climates during the winter, Energy and Building, 208 (2020) 109680, https://doi.org/10.1016/j.enbuild.2019.109680.
Azmoodeh, M.; and Heidari, S (2014). Investigation of spatial and temporal distributions of air pollutants over Tehran in cold months of 2011-2013. Journal of Environmental Science and Technology 16(1): 361-370 (in Persian).
Azmoodeh, M.; and Heidari, S (2017). Effect of Urban Green Walls on Reduction of Temperature in Microclimates and Urban Heat Island. Journal of Environmental Science and Technology 19(5): 597-606. doi: 10.22034/jest.2017.11398 (in Persian).
Azmoodeh, M.; Heidari, S.; and Zamani, Z (1970). CBA Evaluation of Green Walls Implementation in Tehran City. Journal of Environmental Science and Technology 21(3): 237-247. doi: 10.22034/jest.2019.14556 (in Persian).
Kolyaei, M.; Hamzenejad, M.; Litkouhi, S.; and Bahrami, P. (2020). The impact internal and external indicators green wall On Environmental and Energy Savings Performance. Journal of Environmental Science and Technology 21(11): 253-267. doi: 10.22034/jest.2018.20435.2946 (in Persian).
Kolyaei, M.; Hamzenejad, M.; Bahrami, P.; and Litkouhi, S (2018). Comparing different types of green wall in order to achieve sustainability. Journal of Environmental Science and Technology, doi: 10.22034/jest.2018.16480.2505 (in Persian).
Bjerre, A.L (2011), “Green Walls.” Bachelor of Architectural Technology and Construction Management, VIA University College, Horsens, Denmark.
Susorova, I; Azimi, P; and Stephens, B (2014). The effects of climbing vegetation on the local microclimate, thermal performance, and air infiltration of four building facade orientations, Building and Environment 76: 113-124.
Olivieri, F., et al. (2014), Experimental study of the thermal-energy performance of an insulated vegetal façade under summer conditions in a continental mediterranean climate, Building and Environment 77: 61-76.
Cameron, R.W.F; Taylor, J; and Emmett, M (2015), A Hedera green façade – Energy performance and saving under different maritime-temperate, winter weather conditions, Building and Environment 92: 111-121.
Djedjig, R; Bozonnet, E; Belarbi, R (2016), Modeling green wall interactions with street canyons for building energy simulation in urban context, Urban Climate, Volume 16: 75-85.
Wong, I; Baldwin, A.N (2016), Investigating the potential of applying vertical green walls to high-rise residential buildings for energy-saving in sub-tropical region, Building and Environment, Volume 97: 34-39.
Hoelscher, M.T; Nehls, T; Jänicke, B; and Wessolek, G (2016), Quantifying cooling effects of facade greening: Shading, transpiration and insulation, Energy and Buildings, Volume 114: 283-290.
Coma, J; Pérez, G; Gracia, A.D; Burés, S, Urrestarazu, M; and Cabeza, L.F (2017), Vertical greenery systems for energy savings in buildings: A comparative study between green walls and green facades, Building and Environment, Volume 111: 228-237.
Serra, VL; Candelari, BE; Giordano, R; Montacchini, E; Tedesco, S; Larcher, F; Schiavi, A (2017). A novel vertical greenery module system for building envelopes: The results and outcomes of a multidisciplinary research project, Energy and Buildings, Volume 146: 333-352.
Pérez, G; Coma, J; Sol, S; and Cabeza, LF (2017), Green facade for energy savings in buildings: The influence of leaf area index and facade orientation on the shadow effect, Applied Energy, Volume 187: 424-437.
Helge, S (2016), Modeling urban microclimate: development, implementation and evaluation of new and improved calculation methods for the urban microclimate model ENVI-met, Dissertation Universit¨at Mainz Geographisches Institut. URL: https://publications.ub.uni-mainz.de/theses/frontdoor.php?source_opus=100000507.
Radić, M; Dodig, MB; Auer, T (2019), Green facades and living walls-A review establishing the classification of construction types and mapping the benefits, Sustainability, Volume 11 (17): 4579, https://doi.org/10.3390/su11174579.