AI Chat Paper
Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.
{{lang === 'zh_CN' ? '文章概述' : 'Summary'}}
{{lang === 'en_US' ? '中' : 'Eng'}}
Chat more with AI
Powered by AMiner. Clicking this button will take you away from SciOpen.
Home Building Simulation Article
Article Link
Cite
EndNote(RIS) BibTeX
Collect
Submit Manuscript
Show Outline
Outline
Show full outline
Hide outline
Outline
Show full outline
Hide outline
Research Article

Influences of spherical tree canopy on thermal radiation disturbance to exterior wall under the condition of no shade cast on the wall

Tailong ZhangXiaoyue ZhaoYu ZhaoDerek LukolongoMwewa ChabiFeng Qi( )
School of Landscape Architecture, Zhejiang A & F University, Lin'an 311300, China
Show Author Information

Abstract

Research on the influence of thermal radiation of tree canopies to adjacent exterior walls has relevance to the selection of tree species and the spatial arrangement of trees for urban planning. In the last decade, there have been many studies on the influence of tree shadows on the thermal environment and energy consumption of buildings. However, there is a lack of research on how trees affect the thermal radiation of adjacent buildings, when they do not cast direct shadows on the walls. In view of this, a combination of experiment and simulation was used to explore the influence of spherical canopy on the intensity changes of net long-wave thermal radiation (TRDL) and net short-wave thermal radiation (TRDS) absorbed by the adjacent wall. Both measured and simulated results show that the tree canopy has a TRD (the sum of TRDL and TRDS) effect on the south wall of adjacent buildings in summer. The peak of TRD from the tree to the adjacent wall was obtained by ENVI-met under 27 scenarios. A functional relationship was further given between the peak TRD and the canopy diameter (DC), the minimum distance between wall and tree canopy (DW-T). Moreover, the influence of DC, DW-T and leaf area density (LAD) on TRD was discussed by simulation. Additionally, the TRD of canopy decays exponentially in the horizontal direction and linearly in the vertical direction of the wall. The above methods and results can guide the selection of tree species, green space design around buildings and the evaluation of the influence of trees on indoor cooling energy consumption in summer.

Keywords

thermal radiationENVI-metdisturbancetree canopyexterior wall

References

 

Aboelata A (2021). Assessment of green roof benefits on buildings' energy-saving by cooling outdoor spaces in different urban densities in arid cities. Energy, 219: 119514.
Crossref Google Scholar
 

Berardi U, Jandaghian Z, Graham J (2020). Effects of greenery enhancements for the resilience to heat waves: A comparison of analysis performed through mesoscale (WRF) and microscale (Envi-met) modeling. Science of the Total Environment, 747: 141300.
Crossref Google Scholar
 

Berry R, Livesley SJ, Lu A (2013). Tree canopy shade impacts on solar irradiance received by building walls and their surface temperature. Building and Environment, 69: 91–100.
Crossref Google Scholar
 

Bruse M, Fleer H (1998). Simulating surface–plant–air interactions inside urban environments with a three dimensional numerical model. Environmental Modelling & Software, 13: 373–384.
Google Scholar
 

Calcerano F, Martinelli L (2016). Numerical optimisation through dynamic simulation of the position of trees around a stand-alone building to reduce cooling energy consumption. Energy and Buildings, 112: 234–243.
Crossref Google Scholar
 

Chan SY, Chau CK (2021). On the study of the effects of microclimate and park and surrounding building configuration on thermal comfort in urban Parks. Sustainable Cities and Society, 64: 102512.
Crossref Google Scholar
 

Chen X, Zhang Q, Zhai ZJ, Ma X (2019). Optimization and sensitivity analysis of design parameters for a ventilation system using phase change materials. Building Simulation, 12: 961–971.
Crossref Google Scholar
 

Deng J, Pickles BJ, Kavakopoulos A, et al. (2019). Concept and methodology of characterising infrared radiative performance of urban trees using tree crown spectroscopy. Building and Environment, 157: 380–390.
Crossref Google Scholar
 

Deng J, Pickles BJ, Smith ST, et al. (2020). Infrared radiative performance of urban trees: spatial distribution and interspecific comparison among ten species in the UK by in situ spectroscopy. Building and Environment, 172: 106682.
Crossref Google Scholar
 
Department of Construction of Zhejiang Province (2001). DB33/T1009-2001. Technical Regulations for Landscaping in Zhejiang Province in China. (in Chinese)
 

Fahmy M, Sharples S, Yahiya M (2010). LAI based trees selection for mid latitude urban developments: A microclimatic study in Cairo, Egypt. Building and Environment, 45: 345–357.
Crossref Google Scholar
 

Fahmy M, Ibrahim Y, Hanafi E, et al. (2018). Would LEED-UHI greenery and high albedo strategies mitigate climate change at neighborhood scale in Cairo, Egypt? Building Simulation, 11: 1273–1288.
Crossref Google Scholar
 

Grylls T, van Reeuwijk M (2021). Tree model with drag, transpiration, shading and deposition: Identification of cooling regimes and large-eddy simulation. Agricultural and Forest Meteorology, 298–299: 108288.
Google Scholar
 

Hsieh CM, Li J, Zhang L, Schwegler B (2018). Effects of tree shading and transpiration on building cooling energy use. Energy and Buildings, 159: 382–397.
Crossref Google Scholar
 

IBM (2015). IBM SPSS Statistics for Windows, Version 23.0. Armonk, NY, USA: IBM Corp.
 

Jonckheere I, Fleck S, Nackaerts K, et al. (2004). Review of methods for in situ leaf area index determination: Part Ⅰ. Theories, sensors and hemispherical photography. Agricultural and Forest Meteorology, 121: 19–35.
Crossref Google Scholar
 

Lalic B, Mihailovic DT (2004). An empirical relation describing leaf-area density inside the forest for environmental modeling. Journal of Applied Meteorology, 43: 641–645.
Crossref
 

Lee SH, Park SU (2008). A vegetated urban canopy model for meteorological and environmental modelling. Boundary-Layer Meteorology, 126: 73–102.
Google Scholar
 

Li G, Ding B (2020). Flora of Zhejiang Province. Hangzhou, China: Zhejiang Science and Technology Publishing House. (in Chinese)
 

Li D, Wu S, Liang Z, et al. (2020). The impacts of urbanization and climate change on urban vegetation dynamics in China. Urban Forestry & Urban Greening, 54: 126764.
Google Scholar
 

Liu D, Hu S, Liu J (2020a). Contrasting the performance capabilities of urban radiation field between three microclimate simulation tools. Building and Environment, 175: 106789.
Crossref Google Scholar
 

Liu Z, Brown RD, Zheng S, et al. (2020b). An in-depth analysis of the effect of trees on human energy fluxes. Urban Forestry & Urban Greening, 50: 126646.
Google Scholar
 

Meir P, Grace J, Miranda AC (2000). Photographic method to measure the vertical distribution of leaf area density in forests. Agricultural and Forest Meteorology, 102: 105–111.
Crossref Google Scholar
 

Morakinyo TE, Balogun AA, Adegun OB (2013). Comparing the effect of trees on thermal conditions of two typical urban buildings. Urban Climate, 3: 76–93.
Crossref Google Scholar
 

Mourid A, El Alami M, Kuznik F (2018). Experimental investigation on thermal behavior and reduction of energy consumption in a real scale building by using phase change materials on its envelope. Sustainable Cities and Society, 41: 35–43.
Crossref Google Scholar
 

Rui L, Buccolieri R, Gao Z, et al. (2019). Study of the effect of green quantity and structure on thermal comfort and air quality in an urban-like residential district by ENVI-met modelling. Building Simulation, 12: 183–194.
Crossref Google Scholar
 

Su X (2012). Plant Landscape Planning and Design. Beijing: China Forestry Press. (in Chinese)
 

Tan PY, Wong NH, Tan CL, et al. (2020). Transpiration and cooling potential of tropical urban trees from different native habitats. Science of the Total Environment, 705: 135764.
Crossref Google Scholar
 

Tsoka S, Leduc T, Rodler A (2021). Assessing the effects of urban street trees on building cooling energy needs: The role of foliage density and planting pattern. Sustainable Cities and Society, 65: 102633.
Crossref Google Scholar
 
UN (2015). Transforming Our World: The 2030 Agenda for Sustainable Development. United Nations.
 

Wang M, Chang HC, Merrick JR, et al. (2016). Assessment of solar radiation reduction from urban forests on buildings along highway corridors in Sydney. Urban Forestry & Urban Greening, 15: 225–235.
Google Scholar
 

Wang X, Dallimer M, Scott CE, et al. (2021a). Tree species richness and diversity predicts the magnitude of urban heat island mitigation effects of greenspaces. Science of the Total Environment, 770: 145211.
Crossref Google Scholar
 

Wang Y, Ni Z, Hu M, et al. (2021b). A practical approach of urban green infrastructure planning to mitigate urban overheating: Case study of Guangzhou. Journal of Cleaner Production, 287: 124995.
Crossref Google Scholar
 

Wu S, Liang Z, Li S (2019). Relationships between urban development level and urban vegetation states: a global perspective. Urban Forestry & Urban Greening, 38: 215–222.
Google Scholar
 

Yang Y, Zhou D, Gao W, et al. (2018). Simulation on the impacts of the street tree pattern on built summer thermal comfort in cold region of China. Sustainable Cities and Society, 37: 563–580.
Crossref Google Scholar
 

Yang Y, Gatto E, Gao Z, et al. (2019). The "plant evaluation model" for the assessment of the impact of vegetation on outdoor microclimate in the urban environment. Building and Environment, 159: 106151.
Crossref Google Scholar
 

Yang X, Peng LLH, Jiang Z, et al. (2020). Impact of urban heat island on energy demand in buildings: Local climate zones in Nanjing. Applied Energy, 260: 114279.
Crossref Google Scholar
 

Yue W, Liu X, Zhou Y, et al. (2019). Impacts of urban configuration on urban heat island: An empirical study in China mega-cities. Science of the Total Environment, 671: 1036–1046.
Crossref Google Scholar
 

Zhang L, Zhan Q, Lan Y (2018). Effects of the tree distribution and species on outdoor environment conditions in a hot summer and cold winter zone: A case study in Wuhan residential quarters. Building and Environment, 130: 27–39.
Crossref Google Scholar
 

Zhang M, Gao Z (2021). Effect of urban form on microclimate and energy loads: Case study of generic residential district prototypes in Nanjing, China. Sustainable Cities and Society, 70: 102930.
Crossref Google Scholar
 
Zhao H (2009). "Beautiful China": "Chinese Dream" of Green Development. In: The Economics and Politics of China's Energy Security Transition. London: Academic Press. pp. 331–361.
 

Zhejiang Bureau of Statistics (2020). Zhejiang Statistical Yearbook. Beijing: China Statistics Press. (in Chinese)
Building Simulation
Volume 15 Issue 7,
July 2022
Pages 1367-1383
DOI: 10.1007/s12273-021-0829-0
Cite this article:
Zhang T, Zhao X, Zhao Y, et al. Influences of spherical tree canopy on thermal radiation disturbance to exterior wall under the condition of no shade cast on the wall. Building Simulation, 2022, 15(7): 1367-1383. https://doi.org/10.1007/s12273-021-0829-0

613

Views

10

Crossref

14

Web of Science

13

Scopus

0

CSCD

Altmetrics
Received: 24 February 2021
Revised: 14 July 2021
Accepted: 28 July 2021
Published: 15 September 2021
© Tsinghua University Press and Springer-Verlag GmbH Germany, part of Springer Nature 2021
Return