Abstract
To evaluate the quality of new energy-saving and performance-supporting building and urban settings, the thermal sensation and comfort models are often used. The accuracy of these models is related to accurate prediction of the human thermo-physiological response that, in turn, is highly sensitive to the local effect of clothing. This study aimed at the development of an empirical regression model of the air gap thickness and the contact area in clothing to accurately simulate human thermal and perceptual response. The statistical model predicted reliably both parameters for 14 body regions based on the clothing ease allowances. The effect of the standard error in air gap prediction on the thermo-physiological response was lower than the differences between healthy humans. It was demonstrated that currently used assumptions and methods for determination of the air gap thickness can produce a substantial error for all global, mean, and local physiological parameters, and hence, lead to false estimation of the resultant physiological state of the human body, thermal sensation, and comfort. Thus, this model may help researchers to strive for improvement of human thermal comfort, health, productivity, safety, and overall sense of well-being with simultaneous reduction of energy consumption and costs in built environment.
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The authors would like to thank Jemma Greve from Laboratory for Biomimetic Textiles and Membranes at Empa for consultation on scientific English writing.
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Psikuta, A., Mert, E., Annaheim, S. et al. Local air gap thickness and contact area models for realistic simulation of human thermo-physiological response. Int J Biometeorol 62, 1121–1134 (2018). https://doi.org/10.1007/s00484-018-1515-5
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DOI: https://doi.org/10.1007/s00484-018-1515-5