Analytical Model for Thermoregulation of the Human Body in Contact with a Phase Change Material (PCM) Cooling Vest
Abstract
:1. Introduction
2. Materials and Methods
2.1. Hotplate
2.2. Sample Preparation
2.3. Procedure
3. Heat Transfer Theory
3.1. Basic Heat Equations
3.2. Human Cooling Model
Skin Temperature
3.3. Solutions for T1 and T3
3.3.1. Solution 1: Human Body Cooling with Heat Production and Radiation; No PCM Layer
3.3.2. Solution 2A: Human Body Cooling with PCM Layer, Heat Production and Radiation
3.3.3. Solution 2B: Human Body Cooling with PCM during Melting Stage
3.3.4. Solution 3A: Hot Plate with PCM Transients and Radiation
3.3.5. Solution 3B: Hot Plate during PCM Melting with Radiation at the PCM Surface
4. Model Verification
4.1. Comparison with Measured Cooling Power of PCM Ice Packs
4.2. Comparison with Data Reported in Literature
5. Parametric Study
6. Discussion, Limitations and Recommendations for Future Work
- The model considers one-dimensional planar heat transfer and thus neglects the effects of body curvature on the conduction and heat loss (or gain) to the environment. Since a curved body has more surface area per unit volume, this assumption underestimates the radiation contribution, and this effect gets larger for more curved body parts such as arms and legs. Since we are interested in the heat transfer near the PCM layer, the rule of thumb is that the model is valid if the PCM thickness is much less than that of (half of) the body, d3/d1 « 1. Note that in thermophysiology models the body is usually considered to consist of cylindrical elements [12,13,14]. This may be a good approximation for the arms and legs but could be less appropriate for the trunk area.
- In order to simulate human thermoregulation in realistic conditions, heat loss by sweat evaporation, respiration and the effect of subcutaneous blood flow must be taken into account. As mentioned before, all these effects essentially act as an energy source or loss contributions in the body core layer and thus only change the numerical value of the Q1 parameter in our model. The equations to model these energy loss terms are conveniently described in [33].
- In practice, only a part of the torso surface is covered with PCM packs. The effect of such a partial coverage on the core temperature can be estimated by a simple averaging process.
7. Conclusions
- A set of closed-form equations is presented which do not need a numerical solver and directly relate cooling vest design parameters such as the PCM mass and melting temperature to its performance
- The model was able to reproduce cooling power data obtained from experiments with ice packs on a hot plate with constant surface temperature as well as PCM cooling data in various literature sources;
- The relation between the PCM performance and the PCM melting temperature and layer thickness is shown in a dedicated parametric study.
Supplementary Materials
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
Nomenclature
A | Surface area of layer element (m2) | ||
A1, A2 | Parameters in solution for T (°C) | Greek symbols | |
C | Parameter in Equations (14) and (15) (s−1) | α | Parameter in exponential function (s−1) |
c1, c3 | Specific heat (J kg−1 K−1) | β | Parameter in Equations (13) and (15) (-) |
d | Layer thickness (m); d1 is half the torso thickness | γ | Parameter in Equations (13) and (15) (-) |
E | Energy (J) | δ | Parameter in Equations (13) and (15) (-) |
f | Fraction (-) | ρ | Density (kg m−3) |
hi | Parameter (s−1) | Sub- and superscripts | |
hr | radiative heat transfer coefficient (Wm−2K−1) | 0 | Solution at t = 0 |
H | Parameter (s−1) | 1 | Body core layer |
k | Thermal conductivity (Wm−1K−1) | 2 | Insulation between body core and PCM layer |
L | Latent heat of PCM (J/kg) | 3 | PCM layer |
mi | Mass of layer i (kg) | 4 | Outside insulation |
P | Cooling power (W) | a | ambient |
q | Heat flux (W/m2) | eff | effective |
Q | Heat production per unit area (W/m2) | HF | Heat flow |
Q’ | Q/(ρcd) (K/s) | hp | hotplate |
QV | Volumetric heat production (W/m3) | i | Layer number |
R | Thermal resistance (m2K W−1) | l | liquid |
t | Time (s) | m | melt |
T | Temperature (°C) | R | Resistance contribution |
x | Thickness coordinate (m) | rad | Radiation contribution |
s | solid | ||
Abbreviations | skin | Skin Layer | |
PCM | Phase change material |
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Property | Layer 1 | Layer 2 | Layer 3 | Layer 4 | |||
---|---|---|---|---|---|---|---|
Body Core [14] | Skin [14] | Underwear | PCM Pocket | Air Gap | PCM, Na2SO4 | Outer Layer | |
Thermal conductivity [Wm−1K−1] | 0.42 | 0.47 | 0.0614 | 0.0317 | 0.025 | 0.6 | 0.0592 |
Specific heat [J/kg] | 3800 | - | 1340 | 1340 | - | 3600 | 1210 |
Density [kg/m3] | 1085 | - | 317 | 392 | - | 500 | 607 |
Thickness [mm] | 123 | 2.0 | 0.356 | 0.16 | 5 | 19.5 | 0.338 |
Melting temperature [°C] | - | - | - | - | - | 21 | - |
Melting enthalpy [kJ/kg] | - | - | - | - | - | 144 | - |
Thermal resistance [m2KW−1] | - | 0.0048 | 0.0058 | 0.0050 | 0.20 | - | 0.0057 |
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Jansen, K.M.B.; Teunissen, L. Analytical Model for Thermoregulation of the Human Body in Contact with a Phase Change Material (PCM) Cooling Vest. Thermo 2022, 2, 232-249. https://doi.org/10.3390/thermo2030017
Jansen KMB, Teunissen L. Analytical Model for Thermoregulation of the Human Body in Contact with a Phase Change Material (PCM) Cooling Vest. Thermo. 2022; 2(3):232-249. https://doi.org/10.3390/thermo2030017
Chicago/Turabian StyleJansen, Kaspar M. B., and Lennart Teunissen. 2022. "Analytical Model for Thermoregulation of the Human Body in Contact with a Phase Change Material (PCM) Cooling Vest" Thermo 2, no. 3: 232-249. https://doi.org/10.3390/thermo2030017
APA StyleJansen, K. M. B., & Teunissen, L. (2022). Analytical Model for Thermoregulation of the Human Body in Contact with a Phase Change Material (PCM) Cooling Vest. Thermo, 2(3), 232-249. https://doi.org/10.3390/thermo2030017