SU1012988A2 - Electromagnetic separator - Google Patents

Abstract

1. ELECTROMAGNETIC SEPARATOR on author. St. 810282, from the fact that, in order to increase the efficiency of the separation process of non-ferrous metals due to the preliminary separation of ferromagnetic inclusions, the separator is equipped with an additional magnetic system made of blocks of permanent magnets installed alternately polarizing in the direction of the split material, pole tips of which are made in the form of triangular prisms, with the blocks placed with a gap above the discharge device along its inclined plates on either side of them. 2. A separator according to claim 1, characterized in that the permanent magnets forming the unit; placed one above the other with an offset in nap (L to the inclined plates of the discharge device. with to: o 00 oo

Description

The invention relates to the enrichment of minerals and can be used in the separation of secondary non-ferrous metals into groups of grades of alloy.

According to the main author. St. 8102S2 is known for an electromagnetic separator comprising a feeder, an electromagnetic system with pole pieces arranged with a gap between the working faces made in the form of interconnected meadow and conical surfaces, an unloading device installed in an interpolar lamp, consisting of plates placed at an angle to each other and interconnected barriers, and the discharge device is equipped with an additional plate, made in the form of a ring with a groove, and the main layer The bends are curved to form a ring and fixed on an additional plate flj.

A disadvantage of the known device is the low efficiency of the separation process of non-ferrous metals due to the formation of a plug of ferromagnetic particles attracted to the pole tip along the material.

The purpose of the invention is to increase the efficiency of the separation process of non-ferrous metals by pre-separating ferromagnetic inclusions.

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This goal is achieved by the fact that the electromagnetic separator is equipped with an additional magnetic system, made of blocks of permanent magnets, installed with alternating polarity in the direction of the material to be divided, the pole pieces of which are made in the form of triangular prisms, while the blocks are placed with a gap of unloading device along its inclined plates on either side of them.

In addition, the permanent magnets forming the unit can be placed one above the other, shifted towards the inclined plates of the discharge device.

FIG. 1 shows the structure of the proposed separator; in fig. 2 scheme of placement of an additional magnetic system; in fig. 3 - construction of permanent magnet blocks with HakOHe4HHKarM pole magnets and their location over the separator discharge device.

The separator includes a feeder 1, an electromagnetic system with pole pieces 2 and windings 3, with the working faces of pole pieces 2 made in the form of interconnected arc and conical surfaces, a discharge device 4, an additional magnetic system consisting of blocks of 5 permanent magnets with pole tips 6, made in the form of triangular prisms, and the blocks of permanent magnets are assembled with the plates displaced in the direction of the inclined faces of the discharge device. azovany ferromagnetic isolation zone 7 and the zone 8 vklcheny separation of nonferrous metals.

The separator works as follows.

The source material is fed by the feeder 1 from the bottom to the separation zones 7 and 8. Under the action of a magnetic field of an additional magnetic system, assembled from a block of 5 permanent magnets with pole pieces 6, ferromagnetic particles are removed from the stream of chips and drawn into the discharge device 4. Under the action of an electromagnetic field, the weakly magnetic chips are drawn into the gap of the electromagnetic system formed by the pole pieces 2 inside the discharge device. By rotating the unloading device, the ferromagnetic particles and weakly magnetic chips are removed from the separation zones and discharged into the respective containers.

The supply of blocks of permanent mag- and nites with pole tips in the form of triangular prisms, whose large faces are aligned with the surface of the base of the blocks, allows the magnetic flux to be redistributed from the surface of the blocks, intensifying it from the edges of the pole tips forming the interpolar gap, and ribs, and weaken from external edges of tips. Due to this, in the interpolar gap and below the edges of the pole tips a magnetic field is created with the intensity H and the gradient of the magnetic field H rod H sufficient to create a magnetic force able to extract ferromagnetic particles from the chip flow and draw them into the interpolar gap, i.e. . make a preliminary separation of the ferromagnetic fraction of the chips.

The opposite-pole blocks of permanent magnets with pole tips are installed at different levels, the image between the pole terminals: the end-points and the feeder at the entrance to the separation zone are larger than they are from it. It is necessary to install raznopopnyh blocks at different levels with the difference in the gaps between the edges of the pole tips on

When entering the separation zone uh, it is caused by the necessity of eliminating the formation of strands of ferromagnetic particles near the first edge of the pole piece in the direction of chip movement under the separation. The sharp corners of the pole tips are much more magnetic than the entire stem, which leads to the emergence of a zone in the area of an acute angle (edge) with increased extraction capacity. Ferromagnetic particles, not income to the division zone, are removed from the chip flow and are attracted to the edge of the pole tip, forming strand from ferromagnetic particles that prevent further chip movement. The formation of a gap between the pole tips and the feeder at the entrance to the division zone is large, than at the exit from it, allows to eliminate the described effect. Ferromagnetic particles are drawn into the interpolar gap, mine the edge of a pole tip. The formation of magnetic strands near the rim of the antipolar tip is not observed, since the ferromagnetic particles are removed from the stream of chips, not the income before it.

In order for the ferromagnetic particles extracted from the chip flow to fill the entire internal volume of the discharge device, the permanent magnet blocks are assembled with the plates displaced in the direction of the inclined sides of the discharge device. When executing blocks of permanent magnets without displacing the plins. Tin, an incomplete filling of the internal volume of the discharging -adjustment is observed. The ferromagnetic particles fill the internal volume only up to the upper level of the pole tips, which significantly limits the separator performance in the ferromagnetic fraction. When executing blocks of constants. magnets with a mix of plates in

In the direction of the inclined plates of the unloading device, the lateral surface of the blocks of the magnet system is ribbed. Around the edges of the blocks and between the opposite-polar edges of the blocks, zones with increased magnetic forces appear, and the magnitudes of these forces increase as the opposite-polar blocks approach each other, i.e. created a magnetic magnets in

Q direction of the tip of the discharge device. Thus, the conditions are created so that the ferromagnetic particles extracted from the stream of chips, not lingering in

5, in the region of the upper level of the pole tips, and were drawn into zones with elevated values of magnetic force, completely filled the internal volume of the discharge device.

The supply of an electromagnetic separator with an additional magnetic system, made in the form of blocks of permanent magnets with pole pieces made in the forge of triangular prisms, improves the efficiency of the separation process by pre-separating the ferromagnetic fraction.

Claims (2)

1. ELECTROMAGNETIC SEPARATOR by ed. St. No. 810282, characterized in that, in order to increase the efficiency of the process of separation of non-ferrous metals due to ¹ preliminary separation of ferromagnetic inclusions, the separator is equipped with an additional magnetic system made of blocks of permanent magnets installed with alternating polarity in the direction of movement of the material to be separated, pole the tips of which are made in the form of triangular prisms, while the blocks are placed with a gap above the unloading device along its inclined plates on both sides of them. · 2. The separator by π. 1, characterized in that the permanent magnets forming a block; placed one above the other with an offset towards the inclined plates of the unloading device. Figure 1 SU .... 1012988 A