SU1488005A1 - Device for classifying suspensions containing ferromagnetic particles - Google Patents

Abstract

The invention relates to the field of magnetic enrichment. The purpose of the invention is to increase the efficiency of the classification process. The device includes a vertically installed cylindrical housing / K / 1 of a non-magnetic material with a tangentially installed supply nozzle (P) 2, covering K 1 of the main electromagnetic system (EMC) 3 with windings connected to a three-phase alternating-floor source, drain (P) 4 with a hub magnetic field 5, P 6 for unloading concentrate. Below EMC 3 in height K 1, an additional П 7 is installed for outputting large ferromagnetic particles, an additional EMC 8, the windings of which are connected to a source of a three-phase alternating field opposite to the windings of EMC 3 and an additional П 9 for outputting large non-magnetic particles. Moreover, P 9 is installed with a gap inside P 6 coaxially with it. The initial suspension enters K 1 through P 2 and under the action of EMC 3 twists. Under the action of centrifugal and magnetic forces, large ferromagnetic particles are concentrated in the wall part and, moving along the wall K 1, are output through П 7. The rest of the suspension, moving down, gets into the EMC field 8, which creates a rotating field whose opposite direction original direction of rotation of the flow. When braking, large non-magnetic particles rush to the center of K 1 and unload through P 9, and ferromagnetic particles, having drawn to the wall of K 1, are removed through P 6. The completely cleaned upward flow is removed through P 4. 1 Cp. ly, 1 il.

Description

field opposite to the windings of the EMC 3, and an additional D 9 for outputting large non-magnetic particles. Moreover, P 9 is installed with a gap inside P 6 coaxially with it. The initial suspension enters K 1 through P 2 and under the influence of EMC 3 twists. Under the action of centrifugal and magnetic forces, large ferromagnetic particles are concentrated in the wall part and, moving along the wall K 1, are removed through P 7. The remaining part

The suspension, moving down, gets into the EMC field 8, which creates a rotating magnetic field whose direction is opposite to the original direction of rotation of the flow. During braking, large non-magnetic particles rush to the center of K 1 and unload through P 9, and ferromagnetic particles, drawn against the wall of K 1, are removed through P 6. The completely cleaned upward flow is removed through P 4. f-ly, 1 ill.

The invention relates to the field of magnetic enrichment and can be used to purify suspensions from ferromagnetic particles and to classify them.

The purpose of the invention is to increase the efficiency of the classification process.

The drawing shows the device section.

The device contains a vertically installed cylindrical housing 1 of a non-magnetic material with a tangentially installed power supply nozzle 2, a main electromagnetic system enclosing the case with windings 3 connected to a three-phase alternating current source, a discharge nozzle 4 with a magnetic field concentrator 5, a nozzle 6 for concentrate unloading. Below the electromagnetic system along the height of the body, an additional pipe 7 is installed for outputting large ferromagnetic particles, an additional electromagnetic system with windings 8 connected to a three-phase AC source opposed to the windings 3 of the main electromagnetic system, an additional pipe 9 for outputting large non-magnetic particles, which is installed with a gap inside the pipe 6 coaxially with him. The hub 5 is installed inside the housing 1 on the outer surface of the pipe 4.

The device works as follows.

The initial suspension enters the device body 1 through the tangential supply nozzle 2. Upon further movement of the suspension along the device, it enters the zone of action of the rotating magnetic field of the electromagnetic winding 3, where it is additionally twisted. In order to evenly distribute the influence of the magnetic field over the cross section of the device, a concentrator 5 of the magnetic field is installed at the discharge nozzle 4. Under the action of centrifugal inertia forces, the solid particles rush to the walls of the housing 1, and the ferromagnetic particles move to the walls faster than non-magnetic ones, since in addition to the centrifugal force of inertia they are also subjected to the attracting effect of the ponderomotive force of the magnetic field. As a result, a layer of solid particles is formed on the wall of the device, where large ferromagnetic particles are concentrated in the wall part of the layer and non-magnetic particles in the upper part of the layer. Under the pressure of the suspension entering the device, this layer of particles moves along the wall of the housing 1 into the lower part of the device, and in the receiving

0 the pocket of the nozzle 7 enters only the near-wall portion of the layer containing large ferromagnetic particles, while the remaining portion of the layer is cut off and falls into the lower half of the body. Additional electromagnetic winding 8, located

5 on the outer side of the lower part of the housing 1, creates inside the device a magnetic field whose direction of rotation is opposite to the direction of rotation of the magnetic field created by the winding 3. Ferromagnetic particles of small fractions not brought out of the device through the nozzle 7 are attracted to the walls of the lower part of the case the magnetic field of the additional winding 8 and, lowering, are brought out through the pipe b, and the suspension at the entrance to the region

5, the magnetic field of the additional winding 8 is decelerated by its field, while non-magnetic particles rush into the central part of the device, since with deceleration of the carrier flow due to interaction with the device wall and with retarded oppositely rotating field by the remaining ferromagnetic particles, the centrifugal force decreases sharply inertia and at the same time there is a force of hydrodynamic pressure directed to the axis of the device.

5The motion path of non-magnetic particles in the lower part of the device is a conical helix, which is lowered along which non-magnetic particles are deposited on the walls of the receiving funnel pipe 9 and removed from the device, thereby the internal upward flow is almost completely cleared of solid inclusions and is discharged through the outlet 4.

Claims (2)

1. A device for classifying suspensions containing ferromagnetic materials, including a vertically installed cylindrical body made of a non-magnetic material with a tangentially installed supply nozzle, an electromagnetic system enclosing the case with windings connected to an alternating three-phase current source, a drain nozzle and a nozzle for concentrate unloading, that, in order to increase the efficiency of the classification process, the device is equipped with the main electromagnet installed below tny system on the height of the body additional pipe for output of large ferromagnetic particles, an additional electromagnetic system with windings and an additional pipe for output of large non-magnetic particles, the windings of the additional electromagnetic system connected to the source of three-phase alternating current opposite to the windings of the main electromagnetic system, and an additional pipe for the output of large non-magnetic particles installed with a gap inside the nozzle for unloading the concentrate coaxially with it. 2. A device according to claim I, characterized in that it is provided with a magnetic field concentrator, mounted inside the housing on the outer surface of the discharge nozzle.