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Heat transfer and entropy generation analysis of hybrid graphene/Fe3O4 ferro-nanofluid flow under the influence of a magnetic field
Mehrali, M ; Sharif University of Technology | 2017
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- Type of Document: Article
- DOI: 10.1016/j.powtec.2016.12.024
- Publisher: Elsevier B.V , 2017
- Abstract:
- The heat transfer characteristics and entropy generation rate of hybrid graphene-magnetite nanofluids under forced laminar flow that subjected to the permanent magnetic fields were investigated. For this purpose, a nanoscale reduced graphene oxide-Fe3O4 hybrid was synthesized by using graphene oxide, iron salts and tannic acid as the reductant and stabilizer. The thermophysical and magnetic properties of the hybrid nanofluid have been widely characterized and thermal conductivity has shown an enhancement of 11%. The experimental results indicated that the heat transfer enhancement of hybrid magnetite nanofluid compared to the case of distilled was negligible when no magnetic field was applied. Additionally, the heat transfer characteristics have been improved significantly under magnetic field. The outcome of the analysis shows that the total entropy generation rate was reduced up to 41% compared to distilled water. It appears that these magnetic hybrid nanofluids can function as good alternative fluids in the magnetic thermal engineering systems. © 2016 Elsevier B.V
- Keywords:
- Laminar flow ; Magnetic field ; Magnetic nanofluid ; Graphene ; Heat convection ; Magnetic fields ; Magnetism ; Magnetite ; Thermal conductivity ; Convective heat transfer ; Entropy generation ; Entropy generation analysis ; Heat transfer characteristics ; Heat Transfer enhancement ; Magnetic nanofluid ; Permanent magnetic fields ; Reduced graphene oxides ; Nanofluidics ; Distilled water ; Graphene oxide magnetite nanofluid ; Iron salt ; Nanoparticle ; Nanosheet ; Stabilizing agent ; Tannin ; Unclassified drug ; Article ; Chemical composition ; Chemical structure ; Entropy ; Flow rate ; Fluid flow ; Heat transfer ; Molecular stability ; Nanoanalysis ; Nanofabrication ; Nanofluidics ; Particle size ; Sedimentation ; Thermal conductivity ; Transmission electron microscopy ; Viscosity ; X ray diffraction
- Source: Powder Technology ; Volume 308 , 2017 , Pages 149-157 ; 00325910 (ISSN)
- URL: https://www.sciencedirect.com/science/article/pii/S0032591016308932