Numerical study of magnetic field on mixed convection and entropy generation of nanofluid in a trapezoidal enclosure
Numerical study of magnetic field on mixed convection and entropy generation of nanofluid in a trapezoidal enclosure
The flow under influence of magnetic field is experienced in cooling electronic devices and voltage transformers, nuclear reactors, biochemistry and in physical phenomenon like geology. In this study, the effects of magnetic field on the flow field, heat transfer and entropy generation of Cu–water nanofluid mixed convection in a trapezoidal enclosure have been investigated. The top lid is cold and moving toward right or left, the bottom wall is hot and the side walls are insulated and their angle from the horizon are 15°, 30°, 45° and 60°. Simulations have been carried out for constant Grashof number of 104, Reynolds numbers of 30, 100, 300 and 1000, Hartmann numbers of 25, 50, 75 and 100 and nanoparticles volume fractions of zero up to 0.04. The finite volume method and SIMPLER algorithm have been utilized to solve the governing equations numerically. The results showed that with imposing the magnetic field and enhancing it, the nanofluid convection and the strength of flow decrease and the flow tends toward natural convection and finally toward pure conduction. For this reason, for all of the considered Reynolds numbers and volume fractions, by increasing the Hartmann number the average Nusselt number decreases. Furthermore, for any case with constant Reynolds and Hartmann numbers by increasing the volume fraction of nanoparticles the maximum stream function decreases. For all of the studied cases, entropy generation due to friction is negligible and the total entropy generation is mainly due to irreversibility associated with heat transfer and variation of the total entropy generation with Hartmann number is similar to that of the average Nusselt number. With change in lid movement direction at Reynolds number of 30 the average Nusselt number and total entropy generation are changed, but at Reynolds number of 1000 it has a negligible effect.
Nanofluid, Entropy generation, Magnetic field, Trapezoidal enclosure, Variable properties
133-145
Aghaei, Alireza
42d20a46-562a-450e-8fa0-cf0029da419b
Khorasanizadeh, Hossein
6c60ce5b-2a1d-4f74-8c43-bb31c1855a67
Sheikhzadeh, Ghanbarali
532ddd7e-3bf1-4b5b-af65-29f012e17d9d
Abbaszadeh, Mahmoud
594e03c0-a134-4b95-b1db-35171b8f0561
1 April 2016
Aghaei, Alireza
42d20a46-562a-450e-8fa0-cf0029da419b
Khorasanizadeh, Hossein
6c60ce5b-2a1d-4f74-8c43-bb31c1855a67
Sheikhzadeh, Ghanbarali
532ddd7e-3bf1-4b5b-af65-29f012e17d9d
Abbaszadeh, Mahmoud
594e03c0-a134-4b95-b1db-35171b8f0561
Aghaei, Alireza, Khorasanizadeh, Hossein, Sheikhzadeh, Ghanbarali and Abbaszadeh, Mahmoud
(2016)
Numerical study of magnetic field on mixed convection and entropy generation of nanofluid in a trapezoidal enclosure.
Journal of Magnetism and Magnetic Materials, 403, .
(doi:10.1016/j.jmmm.2015.11.067).
Abstract
The flow under influence of magnetic field is experienced in cooling electronic devices and voltage transformers, nuclear reactors, biochemistry and in physical phenomenon like geology. In this study, the effects of magnetic field on the flow field, heat transfer and entropy generation of Cu–water nanofluid mixed convection in a trapezoidal enclosure have been investigated. The top lid is cold and moving toward right or left, the bottom wall is hot and the side walls are insulated and their angle from the horizon are 15°, 30°, 45° and 60°. Simulations have been carried out for constant Grashof number of 104, Reynolds numbers of 30, 100, 300 and 1000, Hartmann numbers of 25, 50, 75 and 100 and nanoparticles volume fractions of zero up to 0.04. The finite volume method and SIMPLER algorithm have been utilized to solve the governing equations numerically. The results showed that with imposing the magnetic field and enhancing it, the nanofluid convection and the strength of flow decrease and the flow tends toward natural convection and finally toward pure conduction. For this reason, for all of the considered Reynolds numbers and volume fractions, by increasing the Hartmann number the average Nusselt number decreases. Furthermore, for any case with constant Reynolds and Hartmann numbers by increasing the volume fraction of nanoparticles the maximum stream function decreases. For all of the studied cases, entropy generation due to friction is negligible and the total entropy generation is mainly due to irreversibility associated with heat transfer and variation of the total entropy generation with Hartmann number is similar to that of the average Nusselt number. With change in lid movement direction at Reynolds number of 30 the average Nusselt number and total entropy generation are changed, but at Reynolds number of 1000 it has a negligible effect.
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Accepted/In Press date: 24 November 2015
e-pub ahead of print date: 2 December 2015
Published date: 1 April 2016
Keywords:
Nanofluid, Entropy generation, Magnetic field, Trapezoidal enclosure, Variable properties
Identifiers
Local EPrints ID: 445433
URI: http://eprints.soton.ac.uk/id/eprint/445433
ISSN: 0304-8853
PURE UUID: b32173fe-668f-46f9-ace9-685720c49a36
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Date deposited: 08 Dec 2020 17:32
Last modified: 16 Mar 2024 10:09
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Contributors
Author:
Alireza Aghaei
Author:
Hossein Khorasanizadeh
Author:
Ghanbarali Sheikhzadeh
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