Numerical Investigation of Magnetohydrodynamic Forced Convection and Entropy Production of Ferrofluid Around a Confined Cylinder Using Wire Magnetic Sources

The current study numerically explored the hydrothermal flow and entropy generation properties of ferrofluid (water and Fe 3 O 4 ) on a cylindrical body in the rectangular channel subjected to the non-uniform magnetic field going through current carrying wires. The effect of various parameters, such...

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Bibliographic Details
Published in:Arabian journal for science and engineering (2011) 2023-09, Vol.48 (9), p.11591-11620
Main Authors: Tumse, Sergen, Zontul, Harun, Hamzah, Hudhaifa, Sahin, Besir
Format: Article
Language:English
Subjects:
Cylinders
Cylindrical bodies
Drag coefficients
Electrons
Engineering
Entropy
Ferrofluids
Flow characteristics
Fluid dynamics
Fluid flow
Forced convection
Hartmann number
Humanities and Social Sciences
Iron oxides
Magnetic fields
multidisciplinary
Nonuniform magnetic fields
Research Article-Mechanical Engineering
Reynolds number
Science
Steady flow
Unsteady flow
Vortex shedding
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Summary:The current study numerically explored the hydrothermal flow and entropy generation properties of ferrofluid (water and Fe 3 O 4 ) on a cylindrical body in the rectangular channel subjected to the non-uniform magnetic field going through current carrying wires. The effect of various parameters, such as ferrofluid volume fraction, Φ the strength of the non-uniform magnetic field, Ha , and Reynolds number, Re , on the flow characteristics, and forced convection heat transfer, is investigated using finite-volume-based Ansys Fluent 20. Obtained results demonstrate that the applied magnetic field shortens the length of recirculating wake downstream of the cylinder at Re = 25 and makes unsteady flow with alternate vortex shedding as time-independent steady flow for Hartmann numbers greater than Ha  ≥ 6 at Re  = 100. At Re  = 50, the total drag coefficient, C D , gets higher by almost 20% when Ha increases from Ha  = 0 to Ha  = 6 and subsequently grows by 61% at Ha  = 10. The findings show that the average Nusselt number, Nu avg , demonstrates monotonic behavior with the Ha and it augments when the strength of the non-uniform magnetic field increases. The Nu avg improvement is in the vicinity of 11.71% at Ha  = 10 and 23.26% at Ha  = 18 for Re  = 25. The maximum value of entropy generation reduces, S L , when the non-uniform magnetic field is applied. Moreover, increasing the Hartmann number, Ha influences the high levels region of entropy production by relatively extending this zone towards the downstream of the channel and covering more area around the cylinder. According to the outcomes of numerical simulation, there is an increase in Nu avg with 3.98% and 3.88% for Ha  = 2 and 18, respectively, when the ferrofluid volume fraction rises from Φ  = 0% to Φ  = 4% at Re  = 25. Finally, the optimum thermal performance criterion, ξ, is obtained at Re  = 150 for Ha  = 0 and Φ  = 4%.
ISSN:2193-567X
1319-8025
2191-4281
DOI:10.1007/s13369-022-07470-5