Liquid metal flow in a U-bend in a strong uniform magnetic field-Reference-Cited by-同舟云学术

Liquid metal flow in a U-bend in a strong uniform magnetic field

Published:1994-05-25 Issue: Volume:267 Page:325-352
ISSN:0022-1120
Container-title:Journal of Fluid Mechanics
language:en
Short-container-title:J. Fluid Mech.

Author:

Molokov S.,Bühler L.

Abstract

Magnetohydrodynamic flows in a U-bend and in a right-angle bend are considered with reference to the toroidal concepts of self-cooled liquid-metal blankets. The ducts composing the bends have rectangular cross-sections. The applied magnetic field is aligned with the toroidal duct and perpendicular to ducts supplying liquid metal. For high Hartmann numbers the flow region is divided into cores and boundary layers of different types. The magnetohydrodynamic equations are reduced to a system of partial differential equations governing wall electric potentials and the core pressure. The system is solved numerically. The results show that the flow is very sensitive to variations of certain parameters, such as the wall conductance ratio and the aspect ratio of the toroidal duct cross-section. Depending on these parameters, the flow exhibits a variety of qualitatively different flow patterns. In particular, structures of helical and vortex type are obtained. A high-velocity jet occurs at the plasma-facing first wall and there is mixing of the fluid in the toroidal duct. These factors lead to desirable heat-transfer conditions.

Publisher

Cambridge University Press (CUP)

Subject

Mechanical Engineering,Mechanics of Materials,Condensed Matter Physics

Reference22 articles.

1. Barleon, L. , Bühler, L. , Molokov, S. & Stieglitz, R. 1993b Magnetohydrodynamic flow through a right angle bend. Seventh Beer-Sheva Intl Seminar on MHD Flows and Turbulence, Israel, February 14–18, 1993 (to be published).

2. An experimental study of the effects of wall conductivity, non-uniform magnetic fields and variable area ducts on liquid metal flows at high Hartmann number. Part 2. Ducts with conducting walls

3. Hunt, J. C. R. & Leibovich, S. 1967 Magnetohydrodynamic flows in channels of variable crosssection with strong transverse magnetic field.J. Fluid Mech. 28,241–260.

4. Hunt, J. C. R. & Holroyd, R. J. 1977 Applications of laboratory and theoretical MHD duct flow studies in fusion reactor technology. Culham Laboratory Rep. CLM-R169 .

5. Moon, T. J. & Walker, J. S. 1990 Liquid metal flow through a sharp elbow in the plane of a strong magnetic field.J. Fluid Mech. 213,397–418.

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