Abstract
Thermal comfort plays a main role in encouraging people to use outdoor spaces, specifically in hot arid and humid climates. The reconciliation of climatic aspects during the urban design phase is limited in implementation, due to the need for multidisciplinary collaboration between desperate scientific fields of climatology, urban planning, and urban environmental modelling. This paper aims to create an integrated interface between the microclimate, outdoor thermal comfort, and design guidelines. The investigation combines subjective and objective approaches, including on-site field measurements, a structured questionnaire using the seven-point American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE 55) thermal sensation votes, and a correlation study of these votes and the microclimatic parameters. Pedestrian thermal comfort was then examined under six shading scenarios, addressing the form and opening of shading devices using computational fluid dynamics. Modelling is based on four dependent variables: wind velocity, ventilation flow rate, air temperature, and the physiological equivalent temperature (PET) index. Findings indicate that the form and location of apertures of the shading devices were the dominant factors in achieving thermal comfort on the urban scale, and led to a reduction in air temperature and a physiological equivalent temperature of 2.3–2.4 °C. Subjective votes indicate that people who live in hot arid climates have a wider range of adaptation and tolerance to local climatic conditions Accordingly, a psychometric chart, for the case study outdoor thermal comfort was developed.
Highlights
The 2020 Global Risks Perception survey issued by the World Economic Forum classified climate change and associated environmental matters as being in the top five global risks most likely to occur in the decade
Human performance of mental and physical tasks diminishes at uncomfortably high temperatures, while illness and death caused by air pollution are likely to increase during extreme hot weather [2,3,4]
As shown thermal perceptions were examined based on the interviewees’ thermal sensation votes in relation to in Figure 6, a high percentage of respondents who voted for the three central TSV categories occupying the calculated physiological equivalent temperature (PET)
Summary
The 2020 Global Risks Perception survey issued by the World Economic Forum classified climate change and associated environmental matters as being in the top five global risks most likely to occur in the decade. This is in addition to a report by the Intergovernmental Panel on Climate Change [1]. Climate change predictions suggest a high probability of a further rise in global temperatures by 1.5 ◦ C between 2030 and 2052, if the present rate of increase remains unmanaged. Human performance of mental and physical tasks diminishes at uncomfortably high temperatures, while illness and death caused by air pollution are likely to increase during extreme hot weather [2,3,4].
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