Thermo-Electro-Fluidic Simulation Study of Impact of Blower Motor Heat on Performance of Peltier Cooler for Protective Clothing

Thermo-Electro-Fluidic Simulation Study of Impact of Blower Motor Heat on Performance of Peltier Cooler for Protective Clothing

The necessity for portable cooling devices to prevent thermal-related diseases in workers wearing protective clothing in hot outdoor weather conditions, such as COVID-19 quarantine sites, is increasing. Coolers for such purposes require a compact design and low-power consumption characteristics to m...

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Bibliographic Details
Published in:Energies (Basel) Vol. 16; no. 10; p. 4052
Main Author: Son, Kwon Joong
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-05-2023
Subjects:
CAE
Coefficients
Cold
computational fluid dynamics
Computer aided engineering
conjugate heat transfer
Coolers
Cooling
Coronaviruses
COVID-19
Design
Design improvements
Heat
Heat generation
Heat transfer
Motor task performance
multiphysics simulation
Numerical analysis
Peltier effect
Peltier effects
Performance evaluation
Portable equipment
Power consumption
Protective clothing
Quarantine
Refrigeration
Reynolds number
Simulation
Temperature
thermoelectric cooling
Thermoelectricity
Turbulence models
Weather
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Summary:The necessity for portable cooling devices to prevent thermal-related diseases in workers wearing protective clothing in hot outdoor weather conditions, such as COVID-19 quarantine sites, is increasing. Coolers for such purposes require a compact design and low-power consumption characteristics to maximize wearability and operating time. Therefore, a thermoelectric device based on the Peltier effect has been widely used rather than a relatively bulky system based on a refrigeration cycle accompanying the phase change of a refrigerant. Despite a number of previous experimental and numerical studies on the Peltier cooling device, there remains much research to be conducted on the effect and removal of motor-related internal heat sources deteriorating the cooling performance. Specifically, this paper presents thermo-electro-fluidic simulations on the impact of heat from an air blower on the coefficient of performance of a Peltier cooler. In addition, a numerical study on the outcome of heat source removal is also evaluated and discussed to draw an improved design of the cooler in terms of cooling capacity and coefficient of performance. The simulation results predicted that the coefficient of performance could be raised by 10.6% due to the suppression of heat generation from a blower motor. Accordingly, the cooling capacity of the specific Peltier cooler investigated in this study was expected to be considerably improved by 80.6% from 4.68 W to 8.45 W through the design change.
ISSN:1996-1073
1996-1073
DOI:10.3390/en16104052