Influence of nanofluids on mixed convective heat transfer over a horizontal backward-facing step
Predictions are reported for laminar mixed convection using various types of nanofluids over a horizontal backward-facing step in a duct, in which the upstream wall and the step are considered adiabatic surfaces, while the downstream wall from the step is heated to a uniform temperature that is high...
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my.uniten.dspace-305102023-12-29T15:48:41Z Influence of nanofluids on mixed convective heat transfer over a horizontal backward-facing step Mohammed H.A. Al-aswadi A.A. Abu-Mulaweh H.I. Shuaib N.H. 15837504600 36241331700 7003564408 13907934500 Heat transfer enhancement Horizontal backward-facing step Mixed convection Nanofluids Facings Finite volume method Friction Gold Inlet flow Mixed convection Nusselt number Reynolds number Silicon compounds Silver Supersonic flow Titanium dioxide Backward facing step Conservation equations Constant temperature Expansion ratio Flow temperature Fluid temperatures Heat Transfer enhancement Horizontal backward-facing step Mixed convective Nano-fluid Nanofluids Recirculation regions Skin friction coefficient Step height Temperature differences TiO Total length Uniform temperature Wall temperatures Nanofluidics Predictions are reported for laminar mixed convection using various types of nanofluids over a horizontal backward-facing step in a duct, in which the upstream wall and the step are considered adiabatic surfaces, while the downstream wall from the step is heated to a uniform temperature that is higher than the inlet fluid temperature. The straight wall that forms the other side of the duct is maintained at constant temperature equivalent to the inlet fluid temperature. Eight different types of nanoparticles, Au, Ag, Al2O3, Cu, CuO, diamond, SiO2, and TiO2, with 5% volume fraction are used. The conservation equations along with the boundary conditions are solved using the finite volume method. Results presented in this paper are for a step height of 4.9 mm and an expansion ratio of 1.942, while the total length in the downstream of the step is 0.5 m. The Reynolds number is in the range of 75 ? Re ? 225. The downstream wall was fixed at a uniform wall temperature in the range of 0 ? ?T ? 30 �C which is higher than the inlet flow temperature. Results reveal that there is a primary recirculation region for all nanofluids behind the step. It is noticed that nanofluids without secondary recirculation region have a higher Nusselt number and it increases with Prandtl number decrement. On the other hand, nanofluids with secondary recirculation regions are found to have a lower Nusselt number. Diamond nanofluid has the highest Nusselt number in the primary recirculation region, while SiO2 nanofluid has the highest Nusselt number downstream of the primary recirculation region. The skin friction coefficient increases as the temperature difference increases and the Reynolds number decreases. � 2011 Wiley Periodicals, Inc. Final 2023-12-29T07:48:41Z 2023-12-29T07:48:41Z 2011 Article 10.1002/htj.20344 2-s2.0-79956150535 https://www.scopus.com/inward/record.uri?eid=2-s2.0-79956150535&doi=10.1002%2fhtj.20344&partnerID=40&md5=33ef7e2e3691ccbb3265d19e5779d624 https://irepository.uniten.edu.my/handle/123456789/30510 40 4 287 307 Scopus |
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Heat transfer enhancement Horizontal backward-facing step Mixed convection Nanofluids Facings Finite volume method Friction Gold Inlet flow Mixed convection Nusselt number Reynolds number Silicon compounds Silver Supersonic flow Titanium dioxide Backward facing step Conservation equations Constant temperature Expansion ratio Flow temperature Fluid temperatures Heat Transfer enhancement Horizontal backward-facing step Mixed convective Nano-fluid Nanofluids Recirculation regions Skin friction coefficient Step height Temperature differences TiO Total length Uniform temperature Wall temperatures Nanofluidics |
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Heat transfer enhancement Horizontal backward-facing step Mixed convection Nanofluids Facings Finite volume method Friction Gold Inlet flow Mixed convection Nusselt number Reynolds number Silicon compounds Silver Supersonic flow Titanium dioxide Backward facing step Conservation equations Constant temperature Expansion ratio Flow temperature Fluid temperatures Heat Transfer enhancement Horizontal backward-facing step Mixed convective Nano-fluid Nanofluids Recirculation regions Skin friction coefficient Step height Temperature differences TiO Total length Uniform temperature Wall temperatures Nanofluidics Mohammed H.A. Al-aswadi A.A. Abu-Mulaweh H.I. Shuaib N.H. Influence of nanofluids on mixed convective heat transfer over a horizontal backward-facing step |
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Predictions are reported for laminar mixed convection using various types of nanofluids over a horizontal backward-facing step in a duct, in which the upstream wall and the step are considered adiabatic surfaces, while the downstream wall from the step is heated to a uniform temperature that is higher than the inlet fluid temperature. The straight wall that forms the other side of the duct is maintained at constant temperature equivalent to the inlet fluid temperature. Eight different types of nanoparticles, Au, Ag, Al2O3, Cu, CuO, diamond, SiO2, and TiO2, with 5% volume fraction are used. The conservation equations along with the boundary conditions are solved using the finite volume method. Results presented in this paper are for a step height of 4.9 mm and an expansion ratio of 1.942, while the total length in the downstream of the step is 0.5 m. The Reynolds number is in the range of 75 ? Re ? 225. The downstream wall was fixed at a uniform wall temperature in the range of 0 ? ?T ? 30 �C which is higher than the inlet flow temperature. Results reveal that there is a primary recirculation region for all nanofluids behind the step. It is noticed that nanofluids without secondary recirculation region have a higher Nusselt number and it increases with Prandtl number decrement. On the other hand, nanofluids with secondary recirculation regions are found to have a lower Nusselt number. Diamond nanofluid has the highest Nusselt number in the primary recirculation region, while SiO2 nanofluid has the highest Nusselt number downstream of the primary recirculation region. The skin friction coefficient increases as the temperature difference increases and the Reynolds number decreases. � 2011 Wiley Periodicals, Inc. |
| author2 |
15837504600 |
| author_facet |
15837504600 Mohammed H.A. Al-aswadi A.A. Abu-Mulaweh H.I. Shuaib N.H. |
| format |
Article |
| author |
Mohammed H.A. Al-aswadi A.A. Abu-Mulaweh H.I. Shuaib N.H. |
| author_sort |
Mohammed H.A. |
| title |
Influence of nanofluids on mixed convective heat transfer over a horizontal backward-facing step |
| title_short |
Influence of nanofluids on mixed convective heat transfer over a horizontal backward-facing step |
| title_full |
Influence of nanofluids on mixed convective heat transfer over a horizontal backward-facing step |
| title_fullStr |
Influence of nanofluids on mixed convective heat transfer over a horizontal backward-facing step |
| title_full_unstemmed |
Influence of nanofluids on mixed convective heat transfer over a horizontal backward-facing step |
| title_sort |
influence of nanofluids on mixed convective heat transfer over a horizontal backward-facing step |
| publishDate |
2023 |
| _version_ |
1806428138602758144 |
| score |
13.214268 |