THERMAL SCIENCE

International Scientific Journal

Salman Zeb

,

Sapna Gul

,

Kamal Shah

,

Dania Santina

,

Nabil Mlaiki

MELTING HEAT TRANSFER AND THERMAL RADIATION EFFECTS ON MHD TANGENT HYPERBOLIC NANOFLUID FLOW WITH CHEMICAL REACTION AND ACTIVATION ENERGY

ABSTRACT
In this research, we take into account tangent hyperbolic nanofluid flow along a moving stretched surface with thermal radiation, exothermic/endothermic chemical reaction and activation energy effects under melting condition. Governing PDE are transformed to dimensionless non-linear ODE with the add of appropriate similarity variables. The resulting non-linear ODE are solved numerically. The flow parameters influences on the fluid's velocity, temperature, and concentration distributions are investigated. The results revealed that temperature profile is declining while concentration and velocity profiles are increasing for enhancing melting parameter.
KEYWORDS
tangent hyperbolic fluid, melting condition, thermal radiation, activation energy, chemical reaction, magneto hydrodynamics
PAPER SUBMITTED: 2022-04-01
PAPER REVISED: 2022-04-04
PAPER ACCEPTED: 2022-04-14
PUBLISHED ONLINE: 2023-04-08
DOI REFERENCE: https://doi.org/10.2298/TSCI23S1253Z
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2023, VOLUME 27, ISSUE Special issue 1, PAGES [253 - 261]
REFERENCES
  1. Choi, S. U. S., Eastman, J. A., Enhancing Thermal Conductivity of Fluids with Nanoparticles, (No. ANL/ MSD/CP-84938; CONF-951135-29), Argonne National Lab. (ANL), Argonne, Ill., USA, 1995
  2. Choi, S. U. S., Nanofluids: From Vision Reality through Research, Journal Heat Transfer, 131 (2009), 3, 033106
  3. Yu, W., et al., Review and Comparison of Nanofluid Thermal Conductivity and Heat Transfer Enhancements, Heat Transf. Eng., 29 (2008), 5, pp. 432-460
  4. Tyler, T., et al., Thermal Transport Properties of Diamond-Based Nanofluids and Nanocomposites, Diam. Relat. Mater., 15 (2006), 11-12, pp. 2078-2081
  5. Das, S. K., Heat Transfer in Nanofluids - A Review, Heat Transf. Eng., 27 (2006), 10, pp. 3-19
  6. Liu, M. S., et al, Enhancement of Thermal Conductivity with Carbon Nanotube for Nanofluids, Int. Commun. Heat Mass Transf., 32 (2005), 9, pp. 1202-1210
  7. Prasannakumara, B. C., et al., The MHD Flow and Non-Linear Radiative Heat Transfer of Sisko Nanofluid over a Non-Linear Stretching Sheet, Inform. Med. Unlocked., 9 (2017), C, pp. 123-132
  8. Hsiao, K. L., To Promote Radiation Electrical MHD Activation Energy Thermal Extrusion Manufacturing System Efficiency by Using Carreau-Nanofluid with Parameters Control Method, Energy, 130 (2017), July, pp. 486-499
  9. Gholinia, M., et al., A Numerical Investigation of Free Convection MHD Flow of Walters-B Nanofluid over an Inclined Stretching Sheet under the Impact of Joule Heating, Therm. Sci. Eng. Prog., 11 (2019), June, pp. 272-282
  10. Kumar, K. G., Exploration of Flow and Heat Transfer of non-Newtonian Nanofluid over a Stretching Sheet by Considering Slip Factor, Int. J. Numer. Method Heat Fluid-Flow, 30 (2019), 4, pp. 1991-2001
  11. Abbas, N., et al., Theoretical Study of Micropolar Hybrid Nanofluid over Riga Channel with Slip Conditions, Phys. A: Stat. Mech. Appl., 551 (2020), 124083
  12. Kumar, K. G., et al., Significance of Arrhenius Activation Energy in Flow and Heat Transfer of Tangent Hyperbolic Fluid with Zero Mass Flux Condition, Microsyst. Technol., 26 (2020), 8, pp. 2517-2526
  13. Gowda, R. J. P., et al., Impact of Binary Chemical Reaction and Activation Energy on Heat and Mass Transfer of Marangoni Driven Boundary-Layer Flow of a Non-Newtonian Nanofluid, Processes, 9 (2021), 4, 702
  14. Obalalu, A. M., et al., Effect of Melting Heat Transfer on Electromagnetohydrodynamic Non-Newtonian Nanofluid-Flow over a Riga Plate with Chemical Reaction and Arrhenius Activation Energy, Eur. Phys. J. Plus, 136 (2021), 8, pp. 1-16
  15. Kumar, T. P., Uma, M. S., The MHD Casson Nanofluid-Flow over a Stretching Surface with Melting Heat Transfer Condition, Heat Transfer, 51 (2022), 8, pp. 7328-7347
  16. Ullah, I., et al., Theoretical Analysis of Activation Energy Effect on Prandtl-Eyring Nanoliquid-Flow Subject to Melting Condition, Journal Non-Equil. Thermody., 47 (2022), 1, pp. 1-12
  17. Maleque, K. A., Effects of Binary Chemical Reaction and Activation Energy on MHD Boundary-Layer Heat and Mass Transfer Flow with Viscous Dissipation and Heat Generation/Absorption, Int. Sch. Res. Notices, 2013 (2013), ID284637
  18. Kumar, K. G., et al., An Unsteady Squeezed Flow of a Tangent Hyperbolic Fluid over a Sensor Surface in the Presence of Variable Thermal Conductivity, Results Phys., 7 (2017), pp. 3031-3036
  19. Dhlamini, M., et al., Activation Energy and Binary Chemical Reaction Effects in Mixed Convective Nanofluid-Flow with Convective Boundary Conditions, Journal Comput. Des. Eng., 6 (2019), 2, pp. 149-158
PDF VERSION [DOWNLOAD]
Melting heat transfer and thermal radiation effects on MHD tangent hyperbolic nanofluid flow with chemical reaction and activation energy

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence