Mixed Convective Stagnation Point Flow Of A Hybrid Nanofluid Toward A Vertical Cylinder
Purpose: The purpose of this paper is to numerically analyze the stagnation point flow of Cu-Al2O3/water hybrid nanofluid with mixed convection past a flat plate and circular cylinder. Design/methodology/approach: The similarity equations that reduced from the boundary layer and energy equations are...
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Emerald Group Publishing Ltd.
2021
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my.utem.eprints.259142022-05-06T10:16:25Z http://eprints.utem.edu.my/id/eprint/25914/ Mixed Convective Stagnation Point Flow Of A Hybrid Nanofluid Toward A Vertical Cylinder Khashi’ie, Najiyah Safwa M. Arifin, Norihan Merkin, John H. Yahaya, Rusya Iryanti Pop, Ioan Purpose: The purpose of this paper is to numerically analyze the stagnation point flow of Cu-Al2O3/water hybrid nanofluid with mixed convection past a flat plate and circular cylinder. Design/methodology/approach: The similarity equations that reduced from the boundary layer and energy equations are solved using the bvp4c solver. The duality of solutions is observed within the specific range of the control parameters, namely, mixed convection parameter λ, curvature parameter (Formula presented.) and nanoparticles volumetric concentration (Formula presented.) for alumina, while for copper (Formula presented.). The stability analysis is also designed to justify the particular solutions’ stability. Additionally, the idea to obtain the solution for large value of (Formula presented.) and (Formula presented.) is also presented in this paper. Findings: Two solutions exist in opposing and assisting flows up to a critical value (Formula presented.) where (Formula presented.) lies in the opposing region. An upsurge of the curvature parameter tends to extend the critical value (delay the separation process), whilst increase the heat transfer performance of the working fluid. Meanwhile, the application of hybrid Cu-Al2O3/water nanofluid also can decelerate the separation of laminar boundary layer flow and produce higher heat transfer rate than the Cu–water nanofluid and pure water. Originality/value: The results are new and original. This study benefits to the other researchers, specifically in the observation of the fluid flow characteristics and heat transfer rate of the hybrid nanofluid. Also, this paper features with the mathematical formulation for the solution with large values of (Formula presented.) and (Formula presented.) Emerald Group Publishing Ltd. 2021-11 Article PeerReviewed text en http://eprints.utem.edu.my/id/eprint/25914/2/KHASHI%27IE%20ET%20AL.%20%282021%29-HFF.PDF Khashi’ie, Najiyah Safwa and M. Arifin, Norihan and Merkin, John H. and Yahaya, Rusya Iryanti and Pop, Ioan (2021) Mixed Convective Stagnation Point Flow Of A Hybrid Nanofluid Toward A Vertical Cylinder. International Journal of Numerical Methods for Heat and Fluid Flow, 31 (12). pp. 3689-3710. ISSN 0961-5539 https://www.emerald.com/insight/content/doi/10.1108/HFF-11-2020-0725/full/html https://doi.org/10.1108/HFF-11-2020-0725 |
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Purpose: The purpose of this paper is to numerically analyze the stagnation point flow of Cu-Al2O3/water hybrid nanofluid with mixed convection past a flat plate and circular cylinder. Design/methodology/approach: The similarity equations that reduced from the boundary layer and energy equations are solved using the bvp4c solver. The duality of solutions is observed within the specific range of the control parameters, namely, mixed convection parameter λ, curvature parameter (Formula presented.) and nanoparticles volumetric concentration (Formula presented.) for alumina, while for copper (Formula presented.). The stability analysis is also designed to justify the particular solutions’ stability. Additionally, the idea to obtain the solution for large value of (Formula presented.) and (Formula presented.) is also presented in this paper. Findings: Two solutions exist in opposing and assisting flows up to a critical value (Formula presented.) where (Formula presented.) lies in the opposing region. An upsurge of the curvature parameter tends to extend the critical value (delay the separation process), whilst increase the heat transfer performance of the working fluid. Meanwhile, the application of hybrid Cu-Al2O3/water nanofluid also can decelerate the separation of laminar boundary layer flow and produce higher heat transfer rate than the Cu–water nanofluid and pure water. Originality/value: The results are new and original. This study benefits to the other researchers, specifically in the observation of the fluid flow characteristics and heat transfer rate of the hybrid nanofluid. Also, this paper features with the mathematical formulation for the solution with large values of (Formula presented.) and (Formula presented.) |
| format |
Article |
| author |
Khashi’ie, Najiyah Safwa M. Arifin, Norihan Merkin, John H. Yahaya, Rusya Iryanti Pop, Ioan |
| spellingShingle |
Khashi’ie, Najiyah Safwa M. Arifin, Norihan Merkin, John H. Yahaya, Rusya Iryanti Pop, Ioan Mixed Convective Stagnation Point Flow Of A Hybrid Nanofluid Toward A Vertical Cylinder |
| author_facet |
Khashi’ie, Najiyah Safwa M. Arifin, Norihan Merkin, John H. Yahaya, Rusya Iryanti Pop, Ioan |
| author_sort |
Khashi’ie, Najiyah Safwa |
| title |
Mixed Convective Stagnation Point Flow Of A Hybrid Nanofluid Toward A Vertical Cylinder |
| title_short |
Mixed Convective Stagnation Point Flow Of A Hybrid Nanofluid Toward A Vertical Cylinder |
| title_full |
Mixed Convective Stagnation Point Flow Of A Hybrid Nanofluid Toward A Vertical Cylinder |
| title_fullStr |
Mixed Convective Stagnation Point Flow Of A Hybrid Nanofluid Toward A Vertical Cylinder |
| title_full_unstemmed |
Mixed Convective Stagnation Point Flow Of A Hybrid Nanofluid Toward A Vertical Cylinder |
| title_sort |
mixed convective stagnation point flow of a hybrid nanofluid toward a vertical cylinder |
| publisher |
Emerald Group Publishing Ltd. |
| publishDate |
2021 |
| url |
http://eprints.utem.edu.my/id/eprint/25914/2/KHASHI%27IE%20ET%20AL.%20%282021%29-HFF.PDF http://eprints.utem.edu.my/id/eprint/25914/ https://www.emerald.com/insight/content/doi/10.1108/HFF-11-2020-0725/full/html https://doi.org/10.1108/HFF-11-2020-0725 |
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