SU732014A1 - Apparatus for magnetohydrodynamic separation - Google Patents

Description

The invention relates to mineral processing by the magnetohydrodynamic method, namely, magnetohydrodynamic separators.

A device for magnetohydrodynamic separation, in which at the boundary of the zone of action of electromagnetic forces ^s conditions are created for the occurrence of vortices [1].

The resulting vortices so worsen the separation conditions that it is necessary to arrange various kinds of systems of individual plate electrodes in order to break these vortices into smaller ones. However, even in this case, the vortices cannot be completely suppressed, and it worsens the separation conditions.

The cause of the vortices is the appearance of a transverse volumetric gradient of ⁵ forces at the boundary of the electric and magnetic fields.

It is also known for magnetohydrodynamic separation device comprising a closed cuvette filled with electrolyte _20, the non-conductive and non-magnetic material placed in a transverse magnetic field and having electrodes, and means for supplying the separated materia2 la separation and removal of products (Golosova separator) [2].

However, in this device, the electrodes are located on the side surface of the cell in special outlet channels and are not in the magnetic field. When separating the separated material, a transverse gradient of volume forces appears on it at the boundary between the electric and magnetic fields, which is the reason for the appearance of vortices that worsen the separation process.

Closest to the invention is a device for magnetohydrodynamic separation, comprising a closed cell filled with an electrolyte of non-conductive and non-magnetic material, placed in a transverse magnetic field and having mesh electrodes mounted on the end walls of the cell in the magnetic field, and devices for supplying the separated material and removing separation products [3].

In this device, due to the implementation of mesh electrodes, it is not possible to eliminate the causes of vortices.

The aim of the invention is to increase the efficiency of the separation process by eliminating vortices at the boundary of the zone of action of electromagnetic forces.

This goal is achieved by the fact that in the device for magnetohydrodynamic separation, which includes a closed cell filled with an electrolyte from a non-conductive and non-magnetic material, placed in a transverse magnetic field, electrodes mounted on the end walls of the cell in the magnetic field, and devices for supplying the material to be separated and removing separation products, the electrodes are solid.

In this case, the transverse gradient of the volume forces at each point of the device for magnetohydrodynamic separation will be zero, and as a result, vortices will not form.

The drawing shows a diagram of the proposed device.

The device for magnetohydrodynamic separation consists of a closed cell 1 made of non-conductive and non-magnetic material The cuvette is placed in a transverse magnetic field of intensity H (its boundaries in the drawing are conventionally indicated by a dotted line) created by the electromagnet 5.

The device operates as follows: When the separated material enters the introducing device 3, the electromagnet 5 is turned on and the electrodes 2 are connected, to the conductive liquid (electrolyte), which carries the separated material into the separation zone (magnetic field), a volumetric force acts in crossed electric and magnetic fields f of electromagnetic origin, and the total volumetric sid acting on the elementary volume of the liquid is f + v.

In the proposed device, the transverse gradient of volumetric forces does not arise, since the electrodes are in the zone of action of the magnetic field, therefore, there are no conditions for the formation of vortices either. The arrow indicates the movement of the electrolyte.

In a device for magnetohydrodynamic separation, separation can be carried out both by density and particle size, and by electrical conductivity. Separation can be carried out in a horizontal, on <0 inclined or vertical flow, and in all cases vortices at the boundaries of the zone of action of electromagnetic forces will not occur.

The proposed device improves the purity of separation of the mixtures, and there is no restriction on the size of the particles in the separated mixture, i.e. there will be no need for preliminary grinding.

Claims (3)

The aim of the invention is to increase the efficiency of the separation process by eliminating vortices at the boundary of the electromagnetic forces. This goal is achieved by the fact that in a device for magnetohydrodynamic separation, including a closed cell filled with electrolyte of non-conductive and non-magnetic material placed in a transverse magnetic field, electrodes installed on the end walls of the cell in the magnetic field, and devices for supplying the separable material and removal of separation products, the electrodes are made flat. In this case, the transverse gradient of the bulk forces at each point of the device for magnetohydrodynamic separation will be zero, and as a result, vortices are not formed. The drawing shows a diagram of the proposed device. The device for magnetohydrodynamic separation consists of a closed cell 1 made of non-conductive and non-magnetic material filled with electrolyte, on the end walls of which electrodes 2 are installed. The cell has devices 3 and 4, respectively, to inject the material to be separated and to remove the separation products. The cuvette is placed in a transverse magnetic field of H intensity (its boundaries in the drawing are conventionally indicated by a dotted line) created by an electromagnet 5. The device works as follows. When a separated material enters the input device 3, turns on the electromagnet 5 and connects the electrodes 2 to the conducting fluid (electrolyte), which carries the material to be separated into the separation zone (magnetic field), in the crossed electric and magnetic fields a volume force f of electromagnetic origin acts, and the total Bulk si.la acting on the elementary volume of fluid equal to f -f v. In the proposed device, a transverse gradient of bulk forces does not occur, since the electrodes are in the zone of action of a magnetic field, therefore, there are no conditions for the formation of vortices either. The arrow shows the movement of the electrolyte. In a device for magnetohydrodynamic separation, separation can be carried out both in terms of density and particle size and the electrical conductivity. Separation may occur in a horizontal, oblique or vertical flow, and in all cases, vortices at the boundaries of the zone of action of electromagnetic forces will not occur. The proposed device improves the purity of the separation of the mixtures, and there is no limit to the size of the particles in the mixture being separated, i.e. there is no need for pre-grinding. The invention of a device for magnetohydrodynamic separation, comprising a closed electrolyte-filled cuvette of non-conducting and non-magnetic material placed in a transverse magnetic field, electrodes mounted on the end walls of the cuvette in the magnetic field, and a device for supplying the separated material and removing the separation products, characterized in that, in order to increase the efficiency of the separation process by eliminating vortices at the boundary of the electromagnetic forces, dy are solid. Sources of information taken into account in the examination 1. Andrew U. Ts. Magnetic-hydrodynamic separation of granular mixtures. M., Tsvetmetinformatsi, 1967, p. 5-7. 2. Andrew U. Ts. Magnetic-hydrodynamic separation of granular mixtures. M., Tsvetmetinformatsi, 1967, p. 28-29 (prototype). , 3. Copyright certificate for application number 1150562/03, 28.04.67.