Analysis of macro channel heat exchanger for fever relief cool cap using thermoelectric

Fever is happened when the human having infection or other illness which the body temperature is higher than normal body temperature. The heat load released during the fever cause the uncomfortable condition to the human. Thermoelectric is used in the design of heat exchanger to provide cooling by u...

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Bibliographic Details
Published in:IOP conference series. Materials Science and Engineering 2019-11, Vol.670 (1), p.12040
Main Authors: Goh, C Y, Rahman, M N Y, Razlan, Z M, Bakar, S A, Wan, W K, Zunaidi, I, Harun, A, Hashim, M S M, Faizi, M K, Ibrahim, I, Kamarrudin, N S, Azmi, M S Muhamad
Format: Article
Language:English
Subjects:
Aluminum oxide
Body temperature
CAD
Computational fluid dynamics
Computer aided design
Design criteria
Enthalpy
Fever
Fluid flow
Heat exchanger tubes
Heat exchangers
Nanofluids
Temperature effects
Thermal comfort
Working fluids
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Summary:Fever is happened when the human having infection or other illness which the body temperature is higher than normal body temperature. The heat load released during the fever cause the uncomfortable condition to the human. Thermoelectric is used in the design of heat exchanger to provide cooling by using electricity which reliefs the fever uncomfortable. The thermal comfort zone for human and the analysis of the heat load from the human head surface are determined. The analysis focuses on the fever teenagers aged range from 15 to 25. The range of the thermal comfort zone is from 20 °C to 25 °C whereas the range for the total heat load from the head surface is from 10.56 W to 16.39 W. The findings from the analysis will be used in the design of heat exchanger that suites the requirement from the analysis result. The fluid flow effect of the working fluid and thermal effect of the heat exchanger are simulated by ANSYS Fluent. In addition, the different types of Peltier plate and fluid as well as the different materials of heat exchanger and tube have applied into heat exchanger design model for observing the effect of the fluid flow in heat exchanger. Using ANSYS Fluent, the temperature contours are compared and found that the combination of alumina Al2O3 nanofluid, copper heat exchanger have better performance due to high heat transfer rate while the tube materials show no effect. The best performance of cooling in the design of the heat exchanger is proposed. These design criteria include the selection of the material of heat exchanger, tube and fluid as well as the selection of the device such as Peltier plate, battery, cooler fan and pump.
ISSN:1757-8981
1757-899X
DOI:10.1088/1757-899X/670/1/012040