International Journal of Clothing Science and Technology, Volume 27, Issue 1, March 2015.
Purpose The purpose of the paper is to simulate the effect of clothing insulation and activity on the interaction between the human body and the environment Design/methodology/approach A thermo-physiological model, integrated into a Fluent CFD software package is applied. The temperature of the skin surface, clothing surface and heat flux (dry and total heat flux) through layers of clothing with different insulation level are numerically investigated in function of the clothing insulation and the different activities performed indoors Findings The increase of the clothing insulation leads to increase of both skin and clothing temperature. Higher temperature difference ∆T between the room temperature and skin temperature provokes more dynamic change of the skin temperature and decreases the thermal comfort of the person. The increase of the metabolic rate however leads to more uniform skin temperature, regardless the temperature difference ∆T. With the increase of the clothing insulation for a constant metabolic rate the total heat flux remains constant, but the dry heat flux decreases, while the evaporative heat flux increases. Originality/value The joint influence of clothing insulation and indoor activities on the thermal interaction between the body and the environment is assesses using a thermo-physiological model, integrated in a CFD software package
Purpose The purpose of the paper is to simulate the effect of clothing insulation and activity on the interaction between the human body and the environment Design/methodology/approach A thermo-physiological model, integrated into a Fluent CFD software package is applied. The temperature of the skin surface, clothing surface and heat flux (dry and total heat flux) through layers of clothing with different insulation level are numerically investigated in function of the clothing insulation and the different activities performed indoors Findings The increase of the clothing insulation leads to increase of both skin and clothing temperature. Higher temperature difference ∆T between the room temperature and skin temperature provokes more dynamic change of the skin temperature and decreases the thermal comfort of the person. The increase of the metabolic rate however leads to more uniform skin temperature, regardless the temperature difference ∆T. With the increase of the clothing insulation for a constant metabolic rate the total heat flux remains constant, but the dry heat flux decreases, while the evaporative heat flux increases. Originality/value The joint influence of clothing insulation and indoor activities on the thermal interaction between the body and the environment is assesses using a thermo-physiological model, integrated in a CFD software package