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Hybrid Nanofluid Flow Past a Shrinking Cylinder with Prescribed Surface Heat Flux

Najiyah Safwa Khashi’ie, Iskandar Waini, Nurul Amira Zainal, Khairum Hamzah, Abdul Rahman Mohd Kasim

2020Symmetry49 citationsDOIOpen Access PDF

Abstract

This numerical study was devoted to examining the occurrence of non-unique solutions in boundary layer flow due to deformable surfaces (cylinder and flat plate) with the imposition of prescribed surface heat flux. The hybrid Al2O3-Cu/water nanofluid was formulated using the single phase model with respective correlations of hybrid nanofluids. The governing model was simplified by adopting a similarity transformation. The transformed differential equations were then numerically computed using the efficient bvp4c solver with the ranges of the control parameters 0.5%≤ϕ1,ϕ2≤1.5% (Al2O3 and Cu volumetric concentration), 0≤K≤0.2 (curvature parameter), 2.6<S≤3.2 (suction parameter) and −2.5<λ≤0.5 (stretching/shrinking parameter). Dual steady solutions are presentable for both a cylinder (K>0) and a flat plate (K=0) with the inclusion of only the suction (transpiration) parameter. The real and stable solutions were mathematically validated through the stability analysis. The Al2O3-Cu/water nanofluid with ϕ1=0.5% (alumina) and ϕ2=1.5% (copper) has the highest skin friction coefficient and heat transfer rate, followed by the hybrid nanofluids with volumetric concentrations (ϕ1=1%,ϕ2=1%) and (ϕ1=1.5%,ϕ2=0.5%), respectively. Surprisingly, the flat plate surface abates the separation of boundary layer while it enhances the heat transfer process.

Topics & Concepts

NanofluidMaterials scienceHeat fluxMechanicsBoundary layerHeat transferCylinderThermodynamicsHeat transfer coefficientCurvatureSuctionPhysicsMathematicsGeometryNanofluid Flow and Heat TransferHeat Transfer MechanismsHeat Transfer and Optimization