Effects of magnetic field strength and direction on anisotropic thermal conductivity of ferrofluids (magnetic nanofluids) at filmwise condensation over a vertical cylinder

[Display omitted] •An analytical solution for the nanoparticle distribution of MNFs at condensate film.•Effects of magnetic field intensity and direction on cooling performance of MNF.•Nanoparticle migration of MNFs inside the film condensation.•Effects of distribution of nanoparticles on heat trans...

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Bibliographic Details
Published in:Advanced powder technology : the international journal of the Society of Powder Technology, Japan Japan, 2016-07, Vol.27 (4), p.1539-1546
Main Authors: Malvandi, A., Heysiattalab, S., Ganji, D.D.
Format: Article
Language:English
Subjects:
Anisotropic thermal conductivity
External magnetic field
Filmwise condensation
Magnetic nanofluids
Nanoparticle migration
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Summary:[Display omitted] •An analytical solution for the nanoparticle distribution of MNFs at condensate film.•Effects of magnetic field intensity and direction on cooling performance of MNF.•Nanoparticle migration of MNFs inside the film condensation.•Effects of distribution of nanoparticles on heat transfer rate. Brownian diffusion and thermophoresis are two primary sources of nanoparticle migration in nanofluids which have considerable impact on thermophysical properties of ferrofluids (magnetic nanofluids). Furthermore, orientation and intensity of magnetic fields influence the thermal conductivity of ferrofluids and make them anisotropic. In this paper, a theoretical investigation on filmwise condensation of ferrofluids over a vertical cylinder in the presence of a uniform variable-directional magnetic field is investigated, taking into account the anisotropic effects of thermal conductivity. The modified Buongiorno’s model is employed for the nanoparticle–fluid suspension to simulate the nanoparticle slip velocity relative to the base fluid originating from the thermophoresis (nanoparticle slip velocity due to temperature gradient) and Brownian motion (nanoparticle slip velocity due to concentration gradient). The distribution of nanoparticles inside a condensate film is analytically obtained and it is revealed that the heat transfer rate is improved further when the angle between the magnetic field and temperature gradient grows.
ISSN:0921-8831
1568-5527
DOI:10.1016/j.apt.2016.05.015