Modeling and computational analysis of hybrid class nanomaterials subject to entropy generation

BACKGROUND AND OBJECTIVE Nanoliquids are dilute suspensions of nanoparticles with at least one of their principal dimensions smaller than 100 nm. Form literature, nanoliquids have been found to possess increased thermos-physical characteristics like thermal diffusivity, thermal conductivity, convective heat transport coefficients and viscosity associated to those of continuous phase liquids foe example oil, ethylene glycol and water. Nanoliquids have novel characteristics that make them possibly beneficial in numerous applications in heat transport like fuel cells, microelectronics, hybrid-powered engines, pharmaceutical processes, domestic refrigerator, engine cooling thermal management, chiller and heat exchanger. The above applications of nanofluids/hybrid nanofluids insist the researchers and engineers to develop new methodologies and technique in the field of heat transport. Therefore, we have considered mixed convective flow hybrid nanomaterial over a convectively heated surface of disk. Flow nature is discussed due to stretchable rotating surface of disk. Applied magnetic field is accounted. Ohmic heating and dissipation effects are utilized in the modeling of energy expression. Total entropy rate is calculated. METHODS Suitable transformation leads to ordinary differential equations. Shooting method is implemented for numerical outcomes. Comparative analysis is made for the present result with published ones. RESULTS The effects of key parameters like magnetic parameter, mixed convection variable and Eckert and Biot numbers on the dimensionless velocity, surface drag force, temperature, (heat transfer rate) Nusselt number and entropy rate are discussed in detail and presented graphically. Furthermore, the outcomes demonstrate that velocity of liquid particles decline against magnetic parameter. Temperature and associated layer upsurge versus magnetic parameter and Eckert number. Skin friction coefficient (drag force) improves through higher values of stretching and magnetic variables. Heat transfer rate is more for higher Eckert number and magnetic parameter. Entropy rate is also enhances against Eckert number and Brickman number. CONCLUSIONS Magnitude of surface drag force increases for higher values of stretching and magnetic variables. Magnitude of heat transfer rate is more when magnetic variable and Eckert number attain the maximum values. Brinkman number is used to decrease the entropy rate. Furthermore, velocity and temperature show contrast behavior versus magnetic parameter i.e., velocity of fluid particles decreases.

[1]  Tasawar Hayat,et al.  Importance of Darcy-Forchheimer relation in chemically reactive radiating flow towards convectively heated surface , 2017 .

[2]  Naseema Aslam,et al.  Physical significance of heat generation/absorption and Soret effects on peristalsis flow of pseudoplastic fluid in an inclined channel , 2019, Journal of Molecular Liquids.

[3]  Ahmed Alsaedi,et al.  A comparative study of Casson fluid with homogeneous-heterogeneous reactions. , 2017, Journal of colloid and interface science.

[4]  Mustafa Turkyilmazoglu,et al.  Three dimensional MHD stagnation flow due to a stretchable rotating disk , 2012 .

[5]  M. Sheikholeslami,et al.  Numerical approach for MHD Al2O3-water nanofluid transportation inside a permeable medium using innovative computer method , 2019, Computer Methods in Applied Mechanics and Engineering.

[6]  Mohammad Hemmat Esfe,et al.  An applicable study on the thermal conductivity of SWCNT-MgO hybrid nanofluid and price-performance analysis for energy management , 2017 .

[7]  Kai Zhang,et al.  Review of nanofluids for heat transfer applications , 2009 .

[8]  Mustafa Turkyilmazoglu,et al.  Fluid flow and heat transfer over a rotating and vertically moving disk , 2018, Physics of Fluids.

[9]  Tasawar Hayat,et al.  Radiative flow of micropolar nanofluid accounting thermophoresis and Brownian moment , 2017 .

[10]  Mustafa Turkyilmazoglu,et al.  Effects of uniform radial electric field on the MHD heat and fluid flow due to a rotating disk , 2012 .

[11]  Tasawar Hayat,et al.  Entropy generation in Darcy-Forchheimer bidirectional flow of water-based carbon nanotubes with convective boundary conditions , 2018, Journal of Molecular Liquids.

[12]  Liancun Zheng,et al.  Flow and heat transfer of nanofluids over a rotating disk with uniform stretching rate in the radial direction , 2017 .

[13]  J. Prakash,et al.  Convective boundary conditions effect on peristaltic flow of a MHD Jeffery nanofluid , 2016, Applied Nanoscience.

[14]  Tasawar Hayat,et al.  Simulation of ferromagnetic nanomaterial flow of Maxwell fluid , 2018 .

[15]  Ahmed Alsaedi,et al.  Magnetohydrodynamic (MHD) flow of nanofluid with double stratification and slip conditions , 2018 .

[16]  Ahmed Alsaedi,et al.  Entropy optimization in cubic autocatalysis chemical reactive flow of Williamson fluid subjected to viscous dissipation and uniform magnetic field , 2019, Journal of Central South University.

[17]  Ahmed Alsaedi,et al.  Entropy generation minimization (EGM) for convection nanomaterial flow with nonlinear radiative heat flux , 2018, Journal of Molecular Liquids.

[18]  Ahmed Alsaedi,et al.  Magnetohydrodynamic (MHD) mixed convection flow of micropolar liquid due to nonlinear stretched sheet with convective condition , 2016 .

[19]  Ahmed Alsaedi,et al.  Stagnation point flow with Cattaneo-Christov heat flux and homogeneous-heterogeneous reactions , 2016 .

[20]  Ahmed Alsaedi,et al.  Physical aspects of Darcy-Forchheimer bidirectional flow in carbon nanotubes (SWCNTs and MWCNTs) , 2019, International Journal of Numerical Methods for Heat & Fluid Flow.

[21]  Tasawar Hayat,et al.  Theoretical investigation of Ree-Eyring nanofluid flow with entropy optimization and Arrhenius activation energy between two rotating disks , 2019, Comput. Methods Programs Biomed..

[22]  Ahmed Alsaedi,et al.  Analysis of thixotropic nanomaterial in a doubly stratified medium considering magnetic field effects , 2016 .

[23]  Davood Toghraie,et al.  Effects of temperature and nanoparticles concentration on rheological behavior of Fe3O4–Ag/EG hybrid nanofluid: An experimental study , 2016 .

[24]  Saeed Alem Varzane Esfehani,et al.  Second law analysis of nanofluid flow , 2011 .

[25]  Ahmed Alsaedi,et al.  Entropy generation minimization and binary chemical reaction with Arrhenius activation energy in MHD radiative flow of nanomaterial , 2018, Journal of Molecular Liquids.

[26]  Tasawar Hayat,et al.  Simulation of nonlinear convective thixotropic liquid with Cattaneo-Christov heat flux , 2017 .

[27]  Ahmed Alsaedi,et al.  Impact of heat generation/absorption and homogeneous-heterogeneous reactions on flow of Maxwell fluid , 2017 .

[28]  Davood Domiri Ganji,et al.  CVFEM analysis for Fe3O4–H2O nanofluid in an annulus subject to thermal radiation , 2019, International Journal of Heat and Mass Transfer.

[29]  Ahmed Alsaedi,et al.  Non-Darcy flow of water-based single (SWCNTs) and multiple (MWCNTs) walls carbon nanotubes with multiple slip conditions due to rotating disk , 2018, Results in Physics.

[30]  Tasawar Hayat,et al.  Impact of Cattaneo–Christov heat flux model in flow of variable thermal conductivity fluid over a variable thicked surface , 2016 .

[31]  Riaz Muhammad,et al.  Transport of Jeffrey nanomaterial in cubic autocatalytic chemically nonlinear radiated flow with entropy generation , 2019, Applied Nanoscience.

[32]  Tasawar Hayat,et al.  Newtonian heating effect in nanofluid flow by a permeable cylinder , 2017 .

[33]  Liancun Zheng,et al.  Steady flow and heat transfer of the power-law fluid over a rotating disk , 2011 .

[34]  A. Alsaedi,et al.  Transportation of CNTs based nanomaterial flow confined between two coaxially rotating disks with entropy generation , 2019, Physica A: Statistical Mechanics and its Applications.

[35]  Tasawar Hayat,et al.  Behavior of stratification phenomenon in flow of Maxwell nanomaterial with motile gyrotactic microorganisms in the presence of magnetic field , 2017 .

[36]  Ben-Wen Li,et al.  Convective stagnation point flow of a MHD non-Newtonian nanofluid towards a stretching plate , 2018, International Journal of Heat and Mass Transfer.

[37]  Somchai Wongwises,et al.  Enhancement of heat transfer using nanofluids—An overview , 2010 .

[38]  Tasawar Hayat,et al.  Effectiveness of magnetic nanoparticles in radiative flow of Eyring-Powell fluid , 2017, Journal of Molecular Liquids.

[39]  Babak Fazelabdolabadi,et al.  Thermal and rheological properties improvement of drilling fluids using functionalized carbon nanotubes , 2015, Applied Nanoscience.

[40]  Riaz Muhammad,et al.  Optimization of SWCNTs and MWCNTs (single and multi-wall carbon nanotubes) in peristaltic transport with thermal radiation in a non-uniform channel , 2019, Journal of Molecular Liquids.

[41]  Ahmed Alsaedi,et al.  A framework for nonlinear thermal radiation and homogeneous-heterogeneous reactions flow based on silver-water and copper-water nanoparticles: A numerical model for probable error , 2017 .

[42]  Hussein Togun,et al.  Laminar CuO–water nano-fluid flow and heat transfer in a backward-facing step with and without obstacle , 2016, Applied Nanoscience.

[43]  Riaz Muhammad,et al.  On entropy generation effectiveness in flow of power law fluid with cubic autocatalytic chemical reaction , 2019, Applied Nanoscience.

[44]  R. Meland,et al.  Flow of a power-law fluid over a rotating disk revisited , 2001 .

[45]  Mustafa Turkyilmazoglu Free and circular jets cooled by single phase nanofluids , 2019, European Journal of Mechanics - B/Fluids.

[46]  M. Turkyilmazoglu,et al.  Direct contact melting due to a permeable rotating disk , 2019, Physics of Fluids.

[47]  Rahman Saidur,et al.  A REVIEW ON APPLICATIONS AND CHALLENGES OF NANOFLUIDS , 2011 .

[48]  A. Sousa,et al.  Enhanced heat transfer and friction factor of MWCNT–Fe3O4/water hybrid nanofluids , 2014 .

[49]  Tasawar Hayat,et al.  Stratified flow of an Oldroyd-B nanoliquid with heat generation , 2017 .

[50]  M. Biglari,et al.  An inspection of thermal conductivity of CuO-SWCNTs hybrid nanofluid versus temperature and concentration using experimental data, ANN modeling and new correlation , 2017 .

[51]  Sumaira Qayyum,et al.  Entropy optimization in flow of Williamson nanofluid in the presence of chemical reaction and Joule heating , 2019, International Journal of Heat and Mass Transfer.

[52]  Ahmed Alsaedi,et al.  Modern developments about statistical declaration and probable error for skin friction and Nusselt number with copper and silver nanoparticles , 2017 .

[53]  Ahmed Alsaedi,et al.  Nanofluid flow due to rotating disk with variable thickness and homogeneous-heterogeneous reactions , 2017 .

[54]  Tasawar Hayat,et al.  VIV study of an elastically mounted cylinder having low mass-damping ratio using RANS model , 2018, International Journal of Heat and Mass Transfer.

[55]  Muhammad Farooq,et al.  Research progress in the development of natural gas as fuel for road vehicles: A bibliographic review (1991–2016) , 2016 .

[56]  Liancun Zheng,et al.  Flow and heat transfer of Ostwald-de Waele fluid over a variable thickness rotating disk with index decreasing , 2016 .

[57]  Tasawar Hayat,et al.  Water-carbon nanofluid flow with variable heat flux by a thin needle , 2016 .

[58]  O. Anwar Bég,et al.  Mixed convection flow along an inclined permeable plate: effect of magnetic field, nanolayer conductivity and nanoparticle diameter , 2015, Applied Nanoscience.

[59]  Ying Chen,et al.  Solidification behavior of hybrid TiO2 nanofluids containing nanotubes and nanoplatelets for cold thermal energy storage , 2017 .