Rheology of thermally convective flow of hybrid nanomaterial through slender needle: numerical computation
In industrial process, improving the transfer of heat has become the primary focus. In comparison with convectional heat transfer fluids and nanofluids containing single nanoparticles, hybrid nanofluids have the potential to offer improved heat transfer performance and thermophysical features. In or...
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| Veröffentlicht in: | Journal of thermal analysis and calorimetry Jg. 148; H. 24; S. 14205 - 14213 |
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| Format: | Journal Article |
| Sprache: | Englisch |
| Veröffentlicht: |
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Springer International Publishing
01.12.2023
Springer Springer Nature B.V |
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| ISSN: | 1388-6150, 1588-2926 |
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| Abstract | In industrial process, improving the transfer of heat has become the primary focus. In comparison with convectional heat transfer fluids and nanofluids containing single nanoparticles, hybrid nanofluids have the potential to offer improved heat transfer performance and thermophysical features. In order to approximate the flow and thermal transport properties, a numerical investigation is conducted in this study. The present study investigates the radiative hybrid silica–alumina/ethylene glycol nanofluid flow properties of heat transfer and fluid flow toward thin needle. The fluid flow model is designed to be governed by a partial differential equation. The PDEs are turned into ODEs using similarity requirements, and then solved numerically using the finite difference approach via the built-in MATLAB function bvp4c. The outcome of flow controlling parameters on velocity, temperature, friction drag, and heat transport rate is presented. The study exhibits that duality of solutions occurs in a particular range when
χ
c
<
χ
≤
-
2.2
and unique solution at
χ
>
-
2.2
.
The results revel that reduction in skin friction and heat transport rate occurs by the inclusion of magnetic strength in hybrid nanofluid. It is also found that when the size of solid nanoparticle increased, the rate of heat transfer across the needle’s surface dramatically improved. |
|---|---|
| AbstractList | In industrial process, improving the transfer of heat has become the primary focus. In comparison with convectional heat transfer fluids and nanofluids containing single nanoparticles, hybrid nanofluids have the potential to offer improved heat transfer performance and thermophysical features. In order to approximate the flow and thermal transport properties, a numerical investigation is conducted in this study. The present study investigates the radiative hybrid silica–alumina/ethylene glycol nanofluid flow properties of heat transfer and fluid flow toward thin needle. The fluid flow model is designed to be governed by a partial differential equation. The PDEs are turned into ODEs using similarity requirements, and then solved numerically using the finite difference approach via the built-in MATLAB function bvp4c. The outcome of flow controlling parameters on velocity, temperature, friction drag, and heat transport rate is presented. The study exhibits that duality of solutions occurs in a particular range when χc<χ≤-2.2 and unique solution at χ>-2.2. The results revel that reduction in skin friction and heat transport rate occurs by the inclusion of magnetic strength in hybrid nanofluid. It is also found that when the size of solid nanoparticle increased, the rate of heat transfer across the needle’s surface dramatically improved. In industrial process, improving the transfer of heat has become the primary focus. In comparison with convectional heat transfer fluids and nanofluids containing single nanoparticles, hybrid nanofluids have the potential to offer improved heat transfer performance and thermophysical features. In order to approximate the flow and thermal transport properties, a numerical investigation is conducted in this study. The present study investigates the radiative hybrid silica-alumina/ethylene glycol nanofluid flow properties of heat transfer and fluid flow toward thin needle. The fluid flow model is designed to be governed by a partial differential equation. The PDEs are turned into ODEs using similarity requirements, and then solved numerically using the finite difference approach via the built-in MATLAB function bvp4c. The outcome of flow controlling parameters on velocity, temperature, friction drag, and heat transport rate is presented. The study exhibits that duality of solutions occurs in a particular range when [Formula omitted] and unique solution at [Formula omitted] The results revel that reduction in skin friction and heat transport rate occurs by the inclusion of magnetic strength in hybrid nanofluid. It is also found that when the size of solid nanoparticle increased, the rate of heat transfer across the needle's surface dramatically improved. In industrial process, improving the transfer of heat has become the primary focus. In comparison with convectional heat transfer fluids and nanofluids containing single nanoparticles, hybrid nanofluids have the potential to offer improved heat transfer performance and thermophysical features. In order to approximate the flow and thermal transport properties, a numerical investigation is conducted in this study. The present study investigates the radiative hybrid silica–alumina/ethylene glycol nanofluid flow properties of heat transfer and fluid flow toward thin needle. The fluid flow model is designed to be governed by a partial differential equation. The PDEs are turned into ODEs using similarity requirements, and then solved numerically using the finite difference approach via the built-in MATLAB function bvp4c. The outcome of flow controlling parameters on velocity, temperature, friction drag, and heat transport rate is presented. The study exhibits that duality of solutions occurs in a particular range when χ c < χ ≤ - 2.2 and unique solution at χ > - 2.2 . The results revel that reduction in skin friction and heat transport rate occurs by the inclusion of magnetic strength in hybrid nanofluid. It is also found that when the size of solid nanoparticle increased, the rate of heat transfer across the needle’s surface dramatically improved. |
| Audience | Academic |
| Author | Yasir, Muhammad Khan, Masood |
| Author_xml | – sequence: 1 givenname: Muhammad surname: Yasir fullname: Yasir, Muhammad email: myasir@math.qau.edu.pk organization: Department of Mathematics, Quaid-I-Azam University – sequence: 2 givenname: Masood surname: Khan fullname: Khan, Masood organization: Department of Mathematics, Quaid-I-Azam University |
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| CitedBy_id | crossref_primary_10_1007_s40042_024_01271_9 crossref_primary_10_1007_s41939_024_00617_x crossref_primary_10_1016_j_cis_2025_103495 crossref_primary_10_1007_s41939_024_00539_8 crossref_primary_10_1016_j_icheatmasstransfer_2024_107702 crossref_primary_10_1016_j_hybadv_2024_100370 crossref_primary_10_1007_s12668_024_01586_8 crossref_primary_10_1016_j_rineng_2024_103262 crossref_primary_10_1007_s10773_024_05827_0 crossref_primary_10_1007_s10973_025_14418_y crossref_primary_10_1016_j_triboint_2023_109180 |
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| Keywords | Non-uniform heat source/sink Slender needle Thermally radiative flow Numerical computation Hybrid nanomaterial |
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