Characteristics of heat transfer and flow resistance of magnetic fluid flow through porous media combined with magnetic field effect

•Enhancement technique of magnetic fluid under magnetic fields in porous media was studied.•Analogous heat transfer between non-porous and porous media under magnetic fields was revealed.•The combined technique resulted in a synergetic enhancement in heat transfer at low flow rates.•Predictive formu...

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Bibliographic Details
Published in:Experimental thermal and fluid science 2023-06, Vol.144, p.110851, Article 110851
Main Authors: Rakpakdee, Wannarat, Motozawa, Masaaki, Fukuta, Mitsuhiro, Chaiworapuek, Weerachai
Format: Article
Language:English
Subjects:
Heat transfer
Internal convection
Magnetic field
Magnetic fluid
Porous media
Pressure drop
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Summary:•Enhancement technique of magnetic fluid under magnetic fields in porous media was studied.•Analogous heat transfer between non-porous and porous media under magnetic fields was revealed.•The combined technique resulted in a synergetic enhancement in heat transfer at low flow rates.•Predictive formulas were proposed for Nusselt number and performance evaluation criterion. The heat transfer and flow resistance of magnetic fluid flow under a magnetic field in the absence and presence of porous media were investigated experimentally in a rectangular duct. A ceramic foam, with a pore density of 13PPI (pores per inch), was used as a porous media. The mainstream flow rate varied between 0.1 and 3.7 l/min, while the magnetic intensity was adjusted to 0, 100, 300, and 500 mT. The results showed heat transfer was enhanced in both the non-porous and porous ceramic by applying the magnetic field to the magnetic fluid flow. Under a magnetic intensity of 500 mT, the heat transfer increments in the absence and presence of the foam were approximately 16.8% and 15.3%, respectively. By applying a magnetic fluid flow through the foam, the maximum heat transfer increment reached 171.7% compared to the absence of foam at the same flow rate. Notably, combining the use of a magnetic field and the ceramic foam resulted in a synergetic enhancement in heat transfer at low flow rates. The magnetic fluid flowing through the foam had a substantially higher flow resistance than the non-foam magnetic fluid flow. The pressure drop increased by applying a magnetic field to the magnetic fluid in the absence and presence of foam. The performance of the combined heat transfer techniques was evaluated in this research based on a performance evaluation criterion value. The results revealed that by applying the magnetic field, the performance evaluation criterion value of the magnetic fluid flow in the presence of foam was higher than in the absence of foam. Finally, the predictive formulas for Nusselt number and performance evaluation criterion as a function of Magnetic fluid heat transfer number were proposed.
ISSN:0894-1777
1879-2286
DOI:10.1016/j.expthermflusci.2023.110851