Heat Transfer Study Of The Ferrofluid Flow In A Vertical Annular Cylindrical Duct Under The Influence Of A Transverse Magnetic Field

We studied the laminar fully developed ferrofluid flow and heat transfer phenomena of an otherwise magnetic fluid into a vertical annular duct of circular cross-section and uniform temperatures on walls which were subjected to a transverse external magnetic field. A computational algorithm was used, which coupled the continuity, momentum, energy, magnetization and Maxwell's equations, accompanied by the appropriate conditions, using the continuity-vorticity-pressure (C.V.P.) method and a non-uniform grid. The results were obtained for different values of field strength and particles' volumetric concentration, wherein the effects of the magnetic field on the ferrofluid flow and the temperature are revealed. It is shown that the axial velocity distribution is highly affected by the field strength and the volumetric concentration, the axial pressure gradient depends almost linearly on the field strength, while the heat transfer significantly increases due to the generated secondary flow.