Computational fluid dynamics simulation and experimental investigation of a thermoelectric system for predicting influence of applied voltage and cooling water on cooling performance

Ceviz, Mehmet Akif; Afshari, Faraz; Muratçobanoğlu, Burak; Ceylan, Murat; Manay, Eyüphan

doi:10.1108/hff-03-2022-0160

Cited by 16 publications

(4 citation statements)

References 46 publications

(37 reference statements)

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“…where P P and P b are the power consumption of the Peltier element and the blowers, respectively. For the Peltier cooler of the design shown in Figure 1, the cooling capacity Q c represents the net thermal energy reduction rate in the cold air duct [24], so it can be expressed as…”

Section: Performance Test Resultsmentioning

confidence: 99%

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

Son

2023

Energies

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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.

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Section: Performance Test Resultsmentioning

confidence: 99%

“…Three-dimensional steady-state CFD analysis of thermoelectric air cooling chamber with a liquid heat exchanger on the high-temperature side was carried out based on the realizable k − turbulent model [24]. Design verification of a portable Peltier air cooler integrated with the work jacket was performed with CFD simulations [8].…”

Section: Introductionmentioning

confidence: 99%

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

Son

2023

Energies

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“…As stated above, k – ɛ turbulence model was used in the simulations section of the present work and this model could be expressed using the governing equations below where k illustrates turbulent kinetic energy and ɛ demonstrates the rate of dissipation in kinetic energy (Ansys, 2017; Ceviz et al , 2022): …”

Section: Methodsmentioning

confidence: 99%

Numerical and experimental investigation for enhancing thermal performance of a concentric heat exchanger using different scenarios

Aytaç

Badali

Tuncer

2023

HFF

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Purpose Heat exchangers (HEs) which provide heat transfer and transfer energy through direct or indirect contact between fluids have an essential role in many processes as a part of various industries from pharmaceutical production to electronic devices. Using nanofluid as working fluid and integrating different types of turbulators could be used to upgrade the thermal effectiveness of HEs. Recently, to obtain more increment in thermal effectiveness, hybrid nanofluids are used that are prepared by mixing two or more various nanoparticles. The purpose of this experimental and numerical study is investigating different scenarios for improving the effectiveness of a concentric U-tube type HE. Design/methodology/approach In the numerical section of this study, different turbulator modifications, including circular and quarter circular rings, were modeled to determine the effect of adding turbulator on thermal performance. In addition, Al2O3/water and SiO2/water single and Al2O3–SiO2/water hybrid nanofluids were experimentally tested in an unmodified concentric U-tube HE in two different modes, including counter flow and parallel flow. Al2O3–SiO2/water hybrid nanofluid was prepared at 2% (wt./wt.) particle ratio and compared with Al2O3/water and SiO2/water single type nanofluids at same particle ratios and with distilled water. Findings Numerical modeling findings exhibited that integrating turbulators to the concentric tube type HE caused to raise in the effectiveness by improving heat transfer area. Also, experimental results indicated that using both hybrid and single type nanofluids notably upgraded the thermal performance of the concentric U-tube HE. Integrating turbulators cannot be an effective alternative in a concentric U-tube type HE with lower diameter because of raise in pressure drop. Numerically achieved findings exhibited that using quarter circular turbulators decreased pressure drop in comparison with circular turbulators. According to the experimental outcomes, using hybrid Al2O3–SiO2/water nanofluid leads to obtain more thermal performance in comparison with single type nanofluids. The highest increment in overall heat transfer coefficient of HE by using Al2O3–SiO2/water nanofluid achieved as 58.97% experimentally. Originality/value The overall outcomes of the current research exhibited the positive impacts of using hybrid nanofluid and integrating turbulators. In this empirical and numerical survey, numerical simulations were performed to specify the impact of applying different turbulators and hybrid nanofluid on the flow and thermal characteristics in a concentric U-tube HE. The achieved outcomes exhibited that using hybrid nanofluid can notably increase the thermal performance with negligible pressure drop in comparison with two different turbulator modifications.

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“…However, optimization of the cooling/heating performance of the thermoelectric modules has not been taken into consideration. It was found that the efficiency did not increase as the voltage was adjusted [ 17 ]. Those temperature controllers are to minimize the deviations between the desired temperatures and the actual temperatures.…”

Section: Introductionmentioning

confidence: 99%

Maximizing cooling/heating performance of thermoelectric modules across variable thermal loads via optimal control based on COP curves

Korprasertsak,

Leephakpreeda

2024

Heliyon

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Computational fluid dynamics simulation and experimental investigation of a thermoelectric system for predicting influence of applied voltage and cooling water on cooling performance

Cited by 16 publications

References 46 publications

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

Numerical and experimental investigation for enhancing thermal performance of a concentric heat exchanger using different scenarios

Maximizing cooling/heating performance of thermoelectric modules across variable thermal loads via optimal control based on COP curves

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