Magnetizing force, which acts in a magnetic field of steep gradient, was applied to air in a cube heated from above and cooled from below, and with the four vertical walls thermally insulated. A four-poles magnet was installed to apply the cusp-shaped magnetic field to air in the cubic enclosure. A simple model equation was derived for magnetizing force and numerically computed for the system. Without a magnetic field, the conduction was stable, but under the magnetizing force a strong downward flow occurred from the center of the top heated plate and the average Nusselt number attained Nu=1.17 at Ra=105 and γ=0.5, which is equivalent to a temperature difference of 4 [°C] between the top and bottom walls under a maximum magnetic induction of 0.9 [T] inside a cube of 0.0643[m3] heated from above. The flow visualization experiment with hot incense smoke proved the downward flow from the top hot plate.

Issue Section:
Natural and Mixed Convection
Keywords:
convection, magnetohydrodynamics, flow visualisation, confined flow
Topics:
Convection, Flow visualization, Gravity (Force), Magnetic fields, Magnetic induction, Poles (Building), Temperature, Flow (Dynamics), Smoke, Heat conduction, Magnets
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