A simple model of thermal conduction in human skin: temperature perception and thermal effusivity

Abstract: In this work we address the well-known fact that upon touching different materials, even if at the same environment temperature, one perceives warmer or cooler sensations depending on properties other than temperature itself. A simple, one-dimensional, non-stationary model for thermal behavior of the human skin layer is devised mainly with educational purposes and the associated Fourier heat equation is solved and discussed. In particular, we emphasize the fact that thermal conductivity alone is not adequate t… Show more

“…where, 𝑄 is the conduction heat transfer rate, 𝑘 denotes the thermal conductivity of the investigated materials, 𝐴 𝑠 is the heat transfer surface area, 𝑇 is the abbreviation of temperature, and 𝑛 is the length in the investigated axis. On the other hand, thermal effusivity (responsivity) corresponds the thermal energy exchange capability of the structure with its ambient [31,32]. Thermal effusivity of an investigated topology can be calculated as:…”

Eklemeli imal edilmiş gözenekli topolojilerin ısıl performansı üzerine deneysel incelemeler

“…where, 𝑄 is the conduction heat transfer rate, 𝑘 denotes the thermal conductivity of the investigated materials, 𝐴 𝑠 is the heat transfer surface area, 𝑇 is the abbreviation of temperature, and 𝑛 is the length in the investigated axis. On the other hand, thermal effusivity (responsivity) corresponds the thermal energy exchange capability of the structure with its ambient [31,32]. Thermal effusivity of an investigated topology can be calculated as:…”

Eklemeli imal edilmiş gözenekli topolojilerin ısıl performansı üzerine deneysel incelemeler

The role of thermal effusivity in heat exchange between finite-sized bodies

Analysis of a diffusion-reaction heat transfer problem in a finite thickness layer adjoined by a semi-infinite medium