Evaluating the Effect of the Characteristics of Sidewalk Mate-rials in Improving the Thermal Comfort of the Urban Environ-ment with an Emphasis on Cool Pavement

Authors

1 Master of Science, Department of Architecture, Faculty of Architecture and Urbanism, Imam Khomeini Interna-tional University, Qazvin, Iran

2 assistant professor, Department of Architecture, Faculty of Architecture and Urbanism, Imam Khomeini Inter-national University, Qazvin, Iran

3 Department of Architecture and Urban Planning, Technical and Vocational University (TVU), Tehran, Iran

Abstract

The expansion of urban societies caused significant changes in the living environment of humans. These changes caused many problems, including the increase in thermal tensions and lack of thermal comfort in the cities. Among these changes is the presence of artificial surfaces in urban spaces, which have replaced natural surfaces and include a high percentage of the surface of cities. The difference in the characteristics of the artificial surfaces has made their impact on the thermal comfort conditions of the environment different compared to the natural surfaces. In this research, sidewalks, which include a large part of artificial surfaces in cities, are the subject of study, and the effects of changes in their characteristics on thermal comfort in open spaces are evaluated. Field measurements and numerical simulation methods were used in this study. Field measurements were carried out by a data logger on the campus of Imam Khomeini University of Qazvin. Also, numerical simulations were performed for the hottest day of the year (July 25, 1401) by modeling the site using Envimet software. The results of the data obtained from the simulations were validated with the measured data. Then two characteristics of pavement materials, albedo (reflection coefficient) and material thickness, were investigated in different amounts of simulation and the results obtained from their impact on the thermal comfort of the environment were evaluated by two indices of Physiological Equivalent Temperature (PET) and Universal Thermal Climate Index (UTCI). According to the results, albedo has a greater effect on thermal indices, and reducing its value from 0.8 to 0.2 to a maximum of 3 and an average of 0.4 degrees Celsius will cause a decrease in the thermal comfort index of PET. The thickness of the pavement materials was also evaluated, and the related results indicate the very small and partial effect of changes in this characteristic on the thermal comfort of the environment.

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Urban Structure and Function Studies
Volume 11, Issue 39
2024
Pages 217-246

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History

  • Receive Date: 26 November 2023
  • Revise Date: 20 January 2024
  • Accept Date: 16 March 2024

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