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Simulation of flow dynamics and heat transfer behavior of nanofluid in microchannel with rough surfaces

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dc.contributor.authorKashani, Ali
dc.contributor.authorRasheed, Rassol Hamed
dc.contributor.authorHussein, Muntadher Abed
dc.contributor.authorAkbari, Omid Ali
dc.contributor.authorAbdul-Redha, Hadeel Kareem
dc.contributor.authorAhmadi Sheikh Shabani, Gholamreza
dc.contributor.authorSalahshour, Soheil
dc.contributor.authorSabetvand, Roozbeh
dc.contributor.institutionKashani, Ali, Department of Mechanical Engineering, Islamic Azad University, Ahvaz branch, Ahvaz, Iran
dc.contributor.institutionRasheed, Rassol Hamed, Air Conditioning Engineering Department, University of Warith Al-Anbiyaa, Karbala, Iraq
dc.contributor.institutionHussein, Muntadher Abed, Al-Manara College for Medical Sciences, Amarah, Iraq
dc.contributor.institutionAkbari, Omid Ali, Department of Mechanical Engineering, Arak University, Arak, Iran
dc.contributor.institutionAbdul-Redha, Hadeel Kareem, Al-Amarah University College, Amarah, Iraq
dc.contributor.institutionAhmadi Sheikh Shabani, Gholamreza, Faculty of Mechanical and Energy Engineering, Shahid Beheshti University, Tehran, Iran
dc.contributor.institutionSalahshour, Soheil, Faculty of Engineering and Natural Sciences, Istanbul Okan University, Tuzla, Turkey, Faculty of Engineering and Natural Sciences, Bahçeşehir Üniversitesi, Istanbul, Turkey, Department of Mathematics and Computer Science, Lebanese American University, Beirut, Lebanon
dc.contributor.institutionSabetvand, Roozbeh, Department of Energy Engineering and Physics, Amirkabir University of Technology, Tehran, Iran
dc.date.accessioned2025-10-05T14:41:08Z
dc.date.issued2024
dc.description.abstractMicrochannels containing cooling fluid are among the most widely used equipment in the cooling of microscale devices, such as heat sinks in the electronics industry. In this numerical research, the flow of water/magnesium-oxide nanofluid in a 3D rectangular microchannel is simulated and investigated. The flow field and heat transfer are analyzed for the laminar flow with Reynold number (Re)= 100, 300, 700, and 1000 and nanoparticle volume fraction (φ) =0, 0.02, and 0.04. The rough surfaces include rectangular cubic ribs arranged in three one in each row along the length with 2, 3, 4, and 5 rows. The ribbed surface is under a constant heat flux. The results include examining changes in Nusselt number (Nu), pressure drop, pumping power, friction factor, and total flow entropy generation. Moreover, the contours of the temperature, pressure, and velocity distribution fields will be discussed. The results reveal that the heat transfer and physics of flow are highly dependent on hydrodynamic behavior. Increasing the number of ribs on the hot surfaces increases the pressure drop, pumping power, and heat transfer. Increasing φ also greatly affects the heat transfer rate. In the case of using 5 ribs and with φ=0.04, in Re=1000 and 700, the microchannel has the highest average Nu, pressure drop, and pumping power. © 2024 Elsevier B.V., All rights reserved.
dc.identifier.doi10.1016/j.ijft.2024.100901
dc.identifier.issn26662027
dc.identifier.scopus2-s2.0-85206157261
dc.identifier.urihttps://doi.org/10.1016/j.ijft.2024.100901
dc.identifier.urihttps://hdl.handle.net/20.500.14719/6908
dc.identifier.volume24
dc.language.isoen
dc.publisherElsevier B.V.
dc.relation.oastatusAll Open Access
dc.relation.oastatusGold Open Access
dc.relation.sourceInternational Journal of Thermofluids
dc.subject.authorkeywordsEntropy Generation
dc.subject.authorkeywordsFlow Hydrodynamics
dc.subject.authorkeywordsFriction Factor
dc.subject.authorkeywordsHeat Transfer
dc.subject.authorkeywordsMicrochannel
dc.subject.authorkeywordsRectangular Rib
dc.subject.authorkeywordsWater/magnesium-oxide Nanofluid
dc.subject.authorkeywordsComputer Resource Management
dc.subject.authorkeywordsElectronic Cooling
dc.subject.authorkeywordsElectronics Industry
dc.subject.authorkeywordsLasers
dc.subject.authorkeywordsSignal Receivers
dc.subject.authorkeywordsEntropy Generation
dc.subject.authorkeywordsFlow Dynamics
dc.subject.authorkeywordsFlow Hydrodynamics
dc.subject.authorkeywordsFriction Factors
dc.subject.authorkeywordsHeat Transfer Behavior
dc.subject.authorkeywordsNanofluids
dc.subject.authorkeywordsPumping Power
dc.subject.authorkeywordsRectangular Rib
dc.subject.authorkeywordsRough Surfaces
dc.subject.authorkeywordsWater/magnesium-oxide Nanofluid
dc.subject.authorkeywordsLaminar Flow
dc.subject.indexkeywordsComputer resource management
dc.subject.indexkeywordsElectronic cooling
dc.subject.indexkeywordsElectronics industry
dc.subject.indexkeywordsLasers
dc.subject.indexkeywordsSignal receivers
dc.subject.indexkeywordsEntropy generation
dc.subject.indexkeywordsFlow dynamics
dc.subject.indexkeywordsFlow hydrodynamics
dc.subject.indexkeywordsFriction factors
dc.subject.indexkeywordsHeat transfer behavior
dc.subject.indexkeywordsNanofluids
dc.subject.indexkeywordsPumping power
dc.subject.indexkeywordsRectangular rib
dc.subject.indexkeywordsRough surfaces
dc.subject.indexkeywordsWater/magnesium-oxide nanofluid
dc.subject.indexkeywordsLaminar flow
dc.titleSimulation of flow dynamics and heat transfer behavior of nanofluid in microchannel with rough surfaces
dc.typeArticle
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