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Swirling MHD-flow in a closed channel with a circular cross-section
Russian version
Mitropolit I.Iu.1, Golbraikh E.2, Kolesnichenko I.V.1
1Institute of Continuous Media Mechanics, Ural Branch, Russian Academy of Sciences, Perm, Russia
2Ben Gurion University of the Negev,Beer Sheva, Israel
Email: mitropolit.i@icmm.ru
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In this article, the hydrodynamic characteristics of the liquid metal flow created inside a closed channel with a circular cross-section by the combined action of travelling and rotating magnetic fields of different values of the corresponding force parameters are investigated using numerical modeling. The dependences of the pressure drop, flow rate, flow energy and other quantities on the value of the rotating magnetic field force parameter are obtained.The influence of the intensity of the swirling of the liquid metal realized by the rotating magnetic field on the characteristics of the flow created by the travelling magnetic field is assessed. The values of the force parameter of the rotating magnetic field are obtained, at which it is possible to achieve an increase in the pressure drop between the channel inlet and outlet due to the swirling of the flow, and assumptions are made about the physical causes of this effect. The influence of structural elements in the considered channel configuration on the flow properties is estimated. Keywords: magnetohydrodynamics, numerical modeling, travelling magnetic field, rotating magnetic field.
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