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dc.contributor.authorSirikasemsuk S.
dc.contributor.authorWiriyasart S.
dc.contributor.authorPrurapark R.
dc.contributor.authorNaphon N.
dc.contributor.authorNaphon P.
dc.description.abstractWe investigated the results of the cooling performance of the pulsating water/nanofluids flowing in the thermoelectric cooling module for cooling electric vehicle battery systems. The experimental system was designed and constructed to consider the effects of the water block configuration, hot and cold side flow rates, supplied power input, and coolant types on the cooling performance of the thermoelectric module. The measured results from the present study with the Peltier module are verified against those without the thermoelectric module. Before entering the electric vehicle battering system with a Peltier module, the inlet coolant temperatures were 2.5-3.5℃ lower than those without the thermoelectric system. On the hot side, the maximum COP of the thermoelectric cooling module was 1.10 and 1.30 for water and nanofluids as coolant, respectively. The results obtained from the present approach can be used to optimize the battery cooling technique to operate in an appropriate temperature range for getting higher energy storage, durability, lifecycles, and efficiency. © 2021 International Information and Engineering Technology Association. All rights reserved.
dc.subjectAutomobile cooling systems
dc.subjectElectric vehicles
dc.subjectLife cycle
dc.subjectThermal management (electronics)
dc.subjectThermoelectric equipment
dc.subjectVehicle performance
dc.subjectBattery systems
dc.subjectCooling performance
dc.subjectElectric vehicle batteries
dc.subjectExperimental system
dc.subjectPeltier module
dc.subjectPulsating flow
dc.subjectThermo-electric modules
dc.subjectWater blocks
dc.subjectWater nanofluids
dc.titleWater/nanofluid pulsating flow in thermoelectric module for cooling electric vehicle battery systems
dc.identifier.bibliograpycitationInternational Journal of Heat and Technology. Vol 39, No.5 (2021), p.1618-1626
Appears in Collections:Scopus 1983-2021

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