Hostname: page-component-848d4c4894-pjpqr Total loading time: 0 Render date: 2024-06-23T08:35:30.040Z Has data issue: false hasContentIssue false
  • English
  • Français

Magnetohydrodynamic flow in a right-angle bend in a strong magnetic field

Published online by Cambridge University Press:  26 April 2006

R. Stieglitz ,
L. Barleon ,
L. BüHler  and
S. Molokov
R. Stieglitz
Affiliation:
JATF, Forschungszentrum Karlsruhe GmbH, Postfach 3640, D-76021 Germany
L. Barleon
Affiliation:
JATF, Forschungszentrum Karlsruhe GmbH, Postfach 3640, D-76021 Germany
L. BüHler
Affiliation:
JATF, Forschungszentrum Karlsruhe GmbH, Postfach 3640, D-76021 Germany
S. Molokov
Affiliation:
Coventry University, MIS, Priory Street, Coventry CV1 5FB, UK
Get access Rights & Permissions [Opens in a new window]

Abstract

The magnetohydrodynamic (MHD) flow through sharp 90° bends of rectangular cross-section, in which the flow turns from a direction almost perpendicular to the magnetic field to a direction almost aligned with the magnetic field, is investigated experimentally for high values of the Hartmann number M and of the interaction parameter N. The bend flow is characterized by strong three-dimensional effects causing a large pressure drop and large deformations in the velocity profile. Since such bends are basic elements of fusion reactors, the scaling laws of magnetohydrodynamic bends flows with the main flow parameters such as M and N as well as the sensitivity to small magnetic field inclinations are of major importance. The obtained experimental results are compared to those of an asymptotic theory.

In the case where one branch of the bend is perfectly aligned with the magnetic field good agreement between the results obtained by the asymptotic model and by the experiments was found at high M ≈ 8 × 10 and N ≈ 105 for pressure as well as for electric potentials on the duct surface. At lower values of N a significant influence of inertia has been detected. The pressure drop due to inertial effects was found to scale with N−1/3. The same – 1/3-power dependency on N has been found in the vicinity of the bend for the electric potentials at walls aligned with the magnetic field. At walls with a significant normal component of the field an influence neither of the Hartmann number nor of the interaction parameter has been found. This suggests that the inertial part of the pressure drop arises from inertial side layers, whereas the core flow remains inertialess and inviscid. A variation of the Hartmann number is of negligible influence compared to inertia effects with respect to pressure drop and surface potential distribution. The viscous part of the pressure drop scales with M−½.

Changes of the magnetic field orientation with respect to the bend lead in general to different flow patterns in the duct, because the electric current paths are changed. The inertia–electromagnetic interaction determines the magnitude of the inertial part of the pressure drop, which scales with N−1/3 for any magnetic field orientation. The dependence of the pressure drop on M remains proportional to M−½. With increasing M and N the measured data tend to those predicted by the asymptotic model. Local measurements within the liquid metal exhibit discrepancies with the model predictions for which no adequate explanation has been found. But they show that below a critical interaction parameter flow regions exist in which the flow is time dependent. These regions are highly localized, whereas the flow in the rest of the bend remains steady.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 326 , 10 November 1996 , pp. 91 - 123
Copyright
© 1996 Cambridge University Press

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Barleon, L., Bühler, L., Mack, K.-J., Molokov, S., Stieglitz, R., Picologlou, B. F., Hua, T. Q. & Reed, C. B. 1992 Investigations of liquid metal flow through a right angle bend under fusion relevant conditions. Proc. 17th Symp. on Fusion Technology (SOFT), Rome, vol. 2, pp. 12761280. Elsevier.
Barleon, L., Bühler, L., Mack, K.-J., Stieglitz, R., Picologlou, B. F., Hua, T. Q. & Reed, C. B. 1993a Liquid metal flow through a right angle bend in a strong magnetic field. Fusion Technol. 21(3) (2B), 21972203.Google Scholar
Barleon, L., Bühler, L., Molokov, S., Stieglitz, R., Picologlou, B. F., Hua, T. Q. & Reed, C. B. 1993b Magnetohydrodynamic flow through a right angle bend. Magnetohydrodynamics 30, 428438.Google Scholar
Barleon, L., Casal, V. & Lenhart, L. 1991 MHD-flow in liquid metal cooled blankets. Fusion Engng Des. 14, 401412.Google Scholar
Bocheninskii, V. P., Tananaev, A. V. & Yakovlev, V. V. 1977 An experimental study of the flow of an electrically conducting liquid along curved tubes of circular cross-section in strong magnetic fields. Magnetohydrodyn. 14, 431435.Google Scholar
Bühler, L. 1993 Magnetohydrodynamische Strömungen flüssiger Metalle in allgemeinen dreidimensionalen Geometrien unter der Einwirkung starker, lokal variabler Magnetfelder. Kernforschungszentrum Karlsruhe Rep. 5095.Google Scholar
Bühler, L. 1995 Magnetohydrodynamic flows in arbitrary geometries in strong non-uniform magnetic fields - a numerical code for the design of fusion reactor blankets. Fusion Technol. 27, 324.Google Scholar
Grinberg, G. K., Kaudze, M. Z. & Lielausis, O. A. 1985 Local MHD resistances on a liquid sodium circuit with a super-conducting magnet. Magnetohydrodyn. 21, 93103.Google Scholar
Holroyd, R. J. 1979 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 1. Ducts with non-conducting walls. J. Fluid Mech. 93, 603630.Google Scholar
Holroyd, R. J. 1980 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. J. Fluid Mech. 96, 355374.Google Scholar
Holroyd, R. J. & Hunt, J. C. R. 1980 Theoretical and experimental studies of liquid metal flow in strong non-uniform magnetic fields in ducts and complex geometry. Proc. 2nd Beer-Sheva Intl Seminar on MHD-Flows and Turbulence (ed. H. Branover & A. Yakhat), pp. 2343. Israel Universities Press.
Holroyd, R. J. & Mitchell, J. T. D. 1984 Liquid Lithium as a coolant for Tokamak Reactors. Nuclear Engng Des./Fusion 1, 1738.Google Scholar
Hua, T. Q. & Walker, J. S. 1991 MHD considerations for poloidal-toroidal coolant ducts of self-cooled blankets. Fusion Techn. 19, 951960.Google Scholar
Hunt, J. C. R. 1965 Magnetohydrodynamic duct flow in rectangular ducts. J. Fluid Mech. 21, 577590.Google Scholar
Hunt, J. C. R. & Holroyd, R. J. 1977 Applications on laboratory and theoretical MHD duct flow studies in fusion reactor technology. UKEA-CLM-R-169. Culham Laboratory; Abingdon, Oxfordshire.
Hunt, J. C. R. & Leibovich, S. 1967 Magnetohydrodynamic duct flow in channels of variable cross-section with strong transverse magnetic field. J. Fluid Mech. 28, 241260.Google Scholar
Kulikovskii, A. G. 1968 On slow steady flows of conductive fluid with high Hartmann number. Fluid Dyn. 3, 15.Google Scholar
Kyrlidis, A., Brown, R. A. & Walker, J. S. 1990 Creeping flow of a conducting fluid past axis-symmetric bodies in the presence of an aligned magnetic field. Phys. Fluids A 2, 22302239.Google Scholar
Malang, S., Arheidt, K., Barleon, L., Borgstedt, H.-U., Casal, V., Fischer, U., Link, W., Reimann, J. & Rust, K. 1988 Self-cooled liquid-metal blanket concept. Fusion Technol. 14, 13431356.Google Scholar
Molokov, S. 1993 Fully developed liquid-metal flow in multiple rectangular ducts in a strong uniform magnetic field. Eur. J. Mech. /B. Fluids 12, 769787.Google Scholar
Mokokov, S. & Bühler, L. 1994 Liquid metal flow in a U-bend in a strong uniform magnetic field. J. Fluid Mech. 267, 325352.Google Scholar
Molokov, S. & Bühler, L. 1995 Asymptotic analysis of magnetohydrodynamic flows in bends. Z. Angew. Math. Mech. 75, 345346.Google Scholar
Molokov, S., Bühler, L. & Stieglitz, R. 1994 Asymptotic structure of magnetohydrodynamic flows in bends. Proc. 2nd Intl Conf. on Energy Transfer in Magnetohydrodynamic Flows. Aussois, France, 26–30 Sept., 1994, pp. 473484.
Moon, T. J., Hua, T. Q. & Walker, J. S. 1991 Liquid metal flow in a backward elbow in the plane of a strong magnetic field. J. Fluid Mech. 227, 273292.Google Scholar
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, 397418.Google Scholar
Moreau, R. 1990 Magnetohydrodynamics, pp. 272304, 165197. Kluwer.
O'Donell, J. O., Papanikolaou, P. G. & Reed, C. B. 1989 The thermophysical transport properties of eutectic NaK near room temperature. Argonne National Laboratory/Fusion Power Program rep. TM-237.
Reed, C. B. & Picologlou, B. F. 1986 Techniques for mesurements of velocity in liquid metal MHD-flows. 7th Top. Meeting on Fusion Technology, Nevada.
Reed, C. B. & Picologlou, B. F. 1989 Side wall flow instabilities in a liquid metal MHD-flow under blanket relevant conditions. Fusion Technol. 15, 705715.Google Scholar
Reed, C. B., Picologlou, B. F. & Walker, J. S. 1987 ALEX-Results - A comparison of measurements from a round and a rectangular duct with 3D-code predictions. IEEE 87CH2507-2, vol. 2, pp. 12671270.
Reimann, J., Bucenieks, I., Dementiev, S., Flerov, A., Molokov, S. & Platnieks, I. 1994 MHD-velocity distributions in U-bends partially parallel to the magnetic field. Proc. 2nd Int. Conf. on Energy Transfer in Magnetohydrodynamic Flows, Aussois, France, 26th–30th Sept., 1994, pp. 391402.
Stieglitz, R. 1994 Magnetohydrodynamische Strömungen in Ein- und Mehrkanalumlenkungen (in German). University of Karlsruhe, PhD thesis.
Tillack, M. S. 1990 Magnetohydrodynamic flow in rectangular ducts-design equations for pressure drop and flow quantity. UCLA-FNT-41.
Ting, A. L., Walker, J. S., Moon, T. J., Reed, C. B. & Picologlou, B. F. 1991 Linear stability analysis for high velocity boundary layers in liquid metal magnetohydrodynamics. Intl I. Engng Sci. 29, 939948.Google Scholar
Walker, J. S. 1981 Magnetohydrodynamic duct flows in rectanguar ducts with thin conducting walls, Part I J. Mèc. 20, 79112.Google Scholar
Walker, J. S., Ludford, G. S. S. & Hunt, J. C. R. 1972 Three-dimensional MHD duct flows with strong transverse magnetic fields. Part 3. Variable rectangular ducts with insulating walls. J. Fluid Mech. 56, 121141.Google Scholar