Computational case study on tangent hyperbolic hybrid nanofluid flow: Single phase thermal investigation

Heat transmission is inevitable in industrial and manufacturing processes. The hybrid nanofluid with its advanced thermal exponent due to the two-part nanoparticle which helps to boost the thermal transfer capacity of standard nanofluids to achieve it. The flow and thermal transference properties of...

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Main Authors: Wasim Jamshed, Kottakkaran Sooppy Nisar, Siti Suzilliana Putri Mohamed Isa, Sawera Batool, Abdel-Haleem Abdel-Aty, M. Zakarya
Format: Article
Language:English
Published: Elsevier 2021-10-01
Series:Case Studies in Thermal Engineering
Subjects:
Online Access:http://www.sciencedirect.com/science/article/pii/S2214157X21004093
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author Wasim Jamshed
Kottakkaran Sooppy Nisar
Siti Suzilliana Putri Mohamed Isa
Sawera Batool
Abdel-Haleem Abdel-Aty
M. Zakarya
author_facet Wasim Jamshed
Kottakkaran Sooppy Nisar
Siti Suzilliana Putri Mohamed Isa
Sawera Batool
Abdel-Haleem Abdel-Aty
M. Zakarya
author_sort Wasim Jamshed
collection DOAJ
description Heat transmission is inevitable in industrial and manufacturing processes. The hybrid nanofluid with its advanced thermal exponent due to the two-part nanoparticle which helps to boost the thermal transfer capacity of standard nanofluids to achieve it. The flow and thermal transference properties of hybrid nanofluid of such kind via a slippery surface has investigated in this study. The pore mediums, heat source, viscous dissipation, thermal conducting variants, and thermal radiative impacts were explored. The controlled equations are solved using the finite difference numerical methodology. The hybrid Tangent hyperbolic nanofluid, which is made up of viscous non-Newtonian fluid EG (ethylene glycol) and two types of nano-solid particles of copper (Cu) and titanium dioxide (TiO2) has been studied. It's worth noting that, when compared to the conventional nanofluid (Cu-EG), the heat transfer level of TiO2–Cu/EG hybrid combo has been continuously increased. The thermal efficiency of TiO2–Cu/EG over Cu-EG is realized with a least of 1.4% and supreme of 3.3%. By integration of nanoparticles ratio, the entropy system is enlarged due to fractional size, radiative variant, thermal conductance and the Weissenberg number.
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spelling doaj.art-64a5a15cc9434f6d87cf654501a6e0eb2022-12-21T21:59:09ZengElsevierCase Studies in Thermal Engineering2214-157X2021-10-0127101246Computational case study on tangent hyperbolic hybrid nanofluid flow: Single phase thermal investigationWasim Jamshed0Kottakkaran Sooppy Nisar1Siti Suzilliana Putri Mohamed Isa2Sawera Batool3Abdel-Haleem Abdel-Aty4M. Zakarya5Department of Mathematics, Capital University of Science and Technology (CUST), Islamabad, 44000, Pakistan; Corresponding author.Department of Mathematics, College of Arts and Sciences, Prince Sattam bin Abdulaziz University, Wadi Aldawaser, 11991, Saudi Arabia; Corresponding author.Institute for Mathematical Research, Universiti Putra Malaysia, 43400, UPM Serdang, Selangor Darul Ehsan, MalaysiaDepartment of Physics, Benazir Bhutto Shaheed University (BBSU), Peshawar, 25000, PakistanDepartment of Physics, College of Sciences, University of Bisha, P.O. Box 344, Bisha, 61922, Saudi Arabia; Physics Department, Faculty of Science, Al-Azhar University, Assiut, 71524, EgyptDepartment of Mathematics, College of Science, King Khalid University, P.O. Box 9004, 61413, Abha, Saudi Arabia; Department of Mathematics, Faculty of Science, Al-Azhar University, 71524, Assiut, EgyptHeat transmission is inevitable in industrial and manufacturing processes. The hybrid nanofluid with its advanced thermal exponent due to the two-part nanoparticle which helps to boost the thermal transfer capacity of standard nanofluids to achieve it. The flow and thermal transference properties of hybrid nanofluid of such kind via a slippery surface has investigated in this study. The pore mediums, heat source, viscous dissipation, thermal conducting variants, and thermal radiative impacts were explored. The controlled equations are solved using the finite difference numerical methodology. The hybrid Tangent hyperbolic nanofluid, which is made up of viscous non-Newtonian fluid EG (ethylene glycol) and two types of nano-solid particles of copper (Cu) and titanium dioxide (TiO2) has been studied. It's worth noting that, when compared to the conventional nanofluid (Cu-EG), the heat transfer level of TiO2–Cu/EG hybrid combo has been continuously increased. The thermal efficiency of TiO2–Cu/EG over Cu-EG is realized with a least of 1.4% and supreme of 3.3%. By integration of nanoparticles ratio, the entropy system is enlarged due to fractional size, radiative variant, thermal conductance and the Weissenberg number.http://www.sciencedirect.com/science/article/pii/S2214157X21004093Tangent hyperbolic-hybrid nanofluidTemperature dependent thermal conductivityHeat sourceEntropy optimizationFinite difference method
spellingShingle Wasim Jamshed
Kottakkaran Sooppy Nisar
Siti Suzilliana Putri Mohamed Isa
Sawera Batool
Abdel-Haleem Abdel-Aty
M. Zakarya
Computational case study on tangent hyperbolic hybrid nanofluid flow: Single phase thermal investigation
Case Studies in Thermal Engineering
Tangent hyperbolic-hybrid nanofluid
Temperature dependent thermal conductivity
Heat source
Entropy optimization
Finite difference method
title Computational case study on tangent hyperbolic hybrid nanofluid flow: Single phase thermal investigation
title_full Computational case study on tangent hyperbolic hybrid nanofluid flow: Single phase thermal investigation
title_fullStr Computational case study on tangent hyperbolic hybrid nanofluid flow: Single phase thermal investigation
title_full_unstemmed Computational case study on tangent hyperbolic hybrid nanofluid flow: Single phase thermal investigation
title_short Computational case study on tangent hyperbolic hybrid nanofluid flow: Single phase thermal investigation
title_sort computational case study on tangent hyperbolic hybrid nanofluid flow single phase thermal investigation
topic Tangent hyperbolic-hybrid nanofluid
Temperature dependent thermal conductivity
Heat source
Entropy optimization
Finite difference method
url http://www.sciencedirect.com/science/article/pii/S2214157X21004093
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