THERMAL SCIENCE

International Scientific Journal

Thermal Science - Online First

External Links

online first only

Two-dimensional Cu-water nanofluid flow and heat transfer over an inclined wall and between two inclined walls: The numerical solution of PDES and ODES

ABSTRACT
In this paper, we attempt to investigate the steady and laminar flow of incompressible Water based nanofluid between inclined plates and over an inclined plate. A uniform and external magnetic field is applied in order to control the nonfluid flow. Copper-Water based nanofluid can be also used for heat transfer enhancement. We can gain additional thermal energy in the fluid by increasing the volume fraction of copper nanoparticles in the base fluid and improving the thermophysical parameters for the single-phase model. The results also show that adjusting the Prandtl and Eckert numbers causes the velocity profile to change fast. According to our findings, fluid elements may be more intensively accelerated by raising the nano additive concentration and enhancing the thermo-physical characteristics of the fluid.
KEYWORDS
PAPER SUBMITTED: 2022-01-29
PAPER REVISED: 2022-02-20
PAPER ACCEPTED: 2022-02-26
PUBLISHED ONLINE: 2022-04-09
DOI REFERENCE: https://doi.org/10.2298/TSCI220129051A
REFERENCES
  1. Muneeshwaran, M., et al., Role of hybrid-nanofluid in heat transfer enhancement - A review, International Communications in Heat and Mass Transfer, 125 (2021), 105341.
  2. Sheikholeslami, M., Farshad, S.A., Investigation of Solar Collector System with Turbulator Considering Hybrid Nanoparticles, Renewable Energy, 171 (2021), pp. 1128-1158.
  3. Zhang, D., et al., Heat transfer and flow visualization of pulsating heat pipe with silica nanofluid: An experimental study, International Journal of Heat and Mass Transfer, 183 (2022), 122100.
  4. Olabi, A.G., et al., Geometrical effect coupled with nanofluid on heat transfer enhancement in heat exchangers, International Journal of Thermofluids 10 (2021), 100072.
  5. Wiriyasart, S., et al., Heat transfer enhancement of thermoelectric cooling module with nanofluid and ferrofluid as base fluids, Case Studies in Thermal Engineering 24 (2021), 100877.
  6. Azimi, M., Riazi, R., MagnetoHydroDynamic GO-water Nanofluid Flow and Heat Transfer between Two Parallel Disks, Thermal Science, 22 (2018), 1, pp.383-390.
  7. Azimi, M., Mozaffari, A., Heat Transfer Analysis of Unsteady Graphene Oxide Nanofluid Flow Using a Fuzzy Identifier Evolved by Genetically Encoded Mutable Smart Bee Algorithm, Engineering Science and Technology, an International Journal, 18 (2015), 1, pp.106-123.
  8. Ali, A., Shehzadi, et al., Heat and Mass Transfer Analysis of 3D Maxwell Nanofluid Over an Exponentially Stretching Surface, Physica Scripta, 94 (2019), 6, p.065206.
  9. Sheikholeslami, M., Bhatti, M. Active Method for Nanofluid Heat Transfer Enhancement by Means of EHD, International Journal of Heat and Mass Transfer, 109 (2017), pp.115-122.
  10. Nilsson, S., Feasibility study of magnetic flow meters for molten salt reactors, Thesis, 2020.
  11. Kumbinarasaiah, S., Raghunatha., K. R., Numerical solution of the Jeffery-Hamel flow through the wavelet technique, Heat Transfer, 51 (2022).
  12. Qayyum, M., Oscar, I., Exploration of Unsteady Squeezing Flow Through Least Squares Homotopy Perturbation Method, Journal of Mathematics (2021).
  13. Azimi, M., Riazi, R., MHD Unsteady Go-Water-Squeezing Nanofluid Flow-Heat and Mass Transfer Between Two Infinite Parallel Moving Plates: Analytical Investigation, Sadhana, 42 (2017), 3, pp.1-7.
  14. Azimi, M., Riazi, R., Flow and Heat Transfer of MHD Graphene Oxide-Water Nanofluid Between Two Non-parallel Walls, Thermal Science, 21 (2017), 5, pp. 2095-2104
  15. Chaich, Z., et al., Thermodynamic Analysis of Viscoelastic Fluid in a Porous Meduim with Prescribed Wall Heat Flux over Stretching Sheet Subjected to a Tansitive Magnetic Field, Thermal Science, 23 (2019), 1, pp. 219-231.
  16. Dadheech, Prvaeen Kumar, et al., Transportation of Al2O3-SiO2-TiO2 Modified Nanofluid Over an Exponentially Stretching Surface with Inclined Magnetohydrodynamic., Thermal Science, 25 (2021), pp.279-285.
  17. Shen, Bingyu, et al., Bioconvection Heat Transfer of a Nanofluid Over a Stretching Sheet with Velocity Slip and Temperature Jump, Thermal Science, 21 2017, pp.2347-2356.
  18. Awad, Mohamed M., Comments on "Magnetohydrodynamic flow of nanofluid over permeable stretching sheet with convective boundary conditions", Thermal Science, 24 (2020), 5A, p.3047.
  19. Al-Mamun, et al., Numerical Simulation of Periodic MHD Casson Nanofluid Flow Through Porous Stretching Sheet, SN Applied Sciences, 3 (2021), 2, pp. 1-14.
  20. Khashi'ie, N.S., et al., Three-Dimensional Hybrid Nanofluid Flow and Heat Transfer Past a Permeable Stretching/Shrinking Sheet with Velocity Slip and Convective Condition, Chinese Journal of Physics, 66 (2020), pp. 157-171.
  21. Wahid, N.S., Arifin, N.M., Khashi'ie, N.S., Pop, I.: Hybrid nanofluid slip flow over an exponentially stretching/shrinking permeable sheet with heat generation. Mathematics 9(1), 30 (2021).
  22. Ali, L., et.al., Analysis of magnetic properties of nano-particles due to a magnetic dipole in micropolar fluid flow over a stretching sheet. Coatings 10(2), 170 (2020).
  23. Hazarika, S., et.al., Investigation of nanoparticles Cu, Ag and Fe3O4 on thermophoresis and viscous dissipation of MHD nanofluid over a stretching sheet in a porous regime: A numerical modelling. Mathematics and Computers in Simulation 182, 819-837 (2021).
  24. Hayat, T., et.al., Impact of induced magnetic field on second-grade nanofluid flow past a convectively heated stretching sheet. Applied Nanoscience 10(8), 3001-3009 (2020).
  25. Dennis, S., et.al., Flow along a diverging channel. Journal of Fluid Mechanics 336, 183-202 (1997).
  26. Nourazar, S., et.al., On the expedient solution of the magneto-hydrodynamic jeffery-hamel flow of casson fluid. Scientific reports 8(1), 1-16 (2018).
  27. Adel, W., et al., Numerical Approach for Simulating the Nonlinear MHD Jeffery-Hamel Flow Problem, International Journal of Applied and Computational Mathematics 74 (2021).
  28. Waini, I., et.al, Unsteady Flow and Heat Transfer Past a Stretching/Shrinking Sheet in a Hybrid Nanofluid, International Journal of Heat and Mass Transfer, 136 (2019), pp. 288-297.
  29. Varun Kumar, R. S., et al. Effect of electromagnetic field on the thermal performance of longitudinal trapezoidal porous fin using DTM-Pade approximant, Heat Transfer (2022).
  30. S. Vakilipour, et.al., Developing a physical influence upwind scheme for pressurebased cell-centered finite volume methods, International Journal for Numerical Methods in Fluids 89 (2019) , 1, pp.43-70.