SU1724376A1 - Electromagnetic separator - Google Patents

Abstract

Electromagnetic separator. Usage: magnetic separation of non-ferrous metal waste. SUMMARY OF THE INVENTION: The separator includes an electromagnetic system 1 with pole pieces 2 and 3 and windings 4. The first pole nozzle 3, in the direction of movement of the feeder tape, is made in the form of a rectangular plate with teeth on narrow sides and is divided into two equal parts by a non-magnetic insert 5. Teeth are made arcuate and have a triangular cross-section in cross section. The discharge device 6 consists of two rigidly connected sector parts 7 and 8. One sector part 7 is located in front of the first feeder pole pole 3, the other part 8 is in the interpolar gap of the system 1. The discharge device 6 is installed with oscillations around vertical axis 9. The latter is fixed in bearings in the center of the non-magnetic insert 5. The material is fed by the feeder 10 to the zone of the weak floor and pole tip 3. The presence of the non-magnetic insert 5 makes the field alternating. Under the action of such a floor, floccules rotate. The highly magnetic particles are attracted to the first part 7 of the discharge device and are unloaded due to vibrations. Weakly magnetic particles go farther and are extracted in a strong interpolar gap tulle. Their unloading is also provided due to oscillations of the unloading device 6. Non-magnetic particles are carried away by the tape of the feeder 10. 2 sludge. (L s x |. U s vj o

Description

The invention relates to a dressing technique and can be used in the segregation of non-ferrous metal wastes.

Known electromagnetic separator, the key of the electromagnetic system with polarized tips, discharge device; additional magnetic conductors with working faces, made equidistant to the discharge device, and an additional pole tip and feeder.

A disadvantage of the known separator is the low efficiency of the separation process of non-ferrous metals, due to the formation of ferromagnetic strands on an additional pole piece, which leads to clogging of the weakly magnetic fraction.

Known electromagnetic separator, which includes an electromagnetic system with windings and pole pieces, the end part of which is made arcuate, the discharge device with an additional plate, vertical partitions 4 and a conveyor belt.

This separator does not allow to sufficiently effectively isolate the magnetic and weakly magnetic fractions when the raw material arrives at the pole tip, the end part of which is made arcuate, the particles are strongly and weakly magnetic, fractions are entrained together and thus litter the synglomagnetic. The reason for this is the interaction of particles of both fractions in the zone of action of a weak magnetic field.

It is known that during the enrichment of a highly magnetic material, the magnetic particles of which have sharply increased magnetic properties, the appearance of magnetic flocculation of these particles and the formation of ferromagnetic strands, elongated in the direction of the field lines, is observed.

. The aim of the invention is to increase the efficiency of the separation process of non-ferrous metals by improving the purity of the separation products and their separate unloading.

For this, the separator is equipped with a non-magnetic insert, the first in the course of movement of the feeder tape - the pole tip is made in the form of a rectangular plate with teeth on narrow sides, oriented along the tape and divided by a non-magnetic insert into two equal parts, and the teeth are made arc-shaped, while unloading the device is made of two rigidly connected sector parts and is installed with the possibility of oscillations around a vertical axis fixed in the center of the nonmagnetic insert, with one sector part of olozhena before the first tape feeder along the pole piece and the other - in the gap of an electromagnet.

Making the pole piece in the form of a rectangular plate with teeth on the narrow sides reduces the magnetic force, since gradient of tension in this case

0 is less important. This reduces the appearance of magnetic flocculation. strongly magnetic particles and significantly reduce the formation of ferromagnetic strands. Split pole tip into

5 vertical plane non-magnetic inset gives the magnetic field alternating character. Weakly and strongly magnetic particles that fall into this field experience from his side alternating signs.

However, the resulting impact, the resulting ferromagnetic strands rotate, fall away from the pole, and then reattach to the pole tip. This allows weakly-magnetic particles to pass through highly-magnetic particles for a short period of time. Thus, self-purification of strongly magnetic particles from weakly magnetic ones takes place.

Performing an unloading device of two rigidly interconnected sector parts, each of which is intended for unloading only one of the fractions (strongly or weakly magnetic), reduces interfluidization.

5 end products. This is due to the fact that the unloading device, whose axis is located in the center of the non-magnetic insert, makes a reciprocating rotation. In this case

0, each sector operates with only one fraction, in contrast to the known unloading devices, when the discharge is carried out alternately: Strong magnetic and then weakly magnetic or vice versa. In known constructions, there is a mutual intake due to the mechanical joints of the particles, or due to other factors, which leads to the entry of weakly magnetic particles into the magnetic field,

0 intended for high-magnet. In the proposed design of the discharge device, these disadvantages are eliminated, since each of the sectors operates in only one zone and unloads only

5 one fraction during the whole separation process. Thus, the possibility of clogging of any fraction by the discharging device is eliminated, and consequently, there is a qualitative improvement in fission products.

The installation of the axis of the unloading device in the bearings located in the center of the non-magnetic insert makes it possible to eliminate the influence of the magnetic field both on the bearing itself and on the speed of rotation of the unloading device.

The non-magnetic insert allows you to increase the life of the discharge device.

Figure 1 shows a profile section of an electromagnetic separator; figure 2 - discharge device with a pole tip.

The electromagnetic separator includes an electromagnetic system 1c with pole lugs 2 and 3 and windings 4, with the pole tip 3 first in the course of the belt run of the feeder made in the form of a rectangular plate with teeth on narrow sides and divided in a vertical plane with a nonmagnetic insert 5, and the teeth are arcuate, unloading device 6. consisting of two sector parts 7 and 8, a vertical axis 9 of the unloading device 6, installed in bearings located in the center of the nonmagnetic insert 5, and a feeder 10.

The separator works as follows: 30Mj

The source material is fed by the feeder 10 to a zone with a weak magnetic field created by a pole tip 3. Under the influence of an alternating weak magnetic field excited by a non-magnetic insert 5, the strongly and weakly magnetic fractions receive a different direction of movement from the magnetic force. As a result, weakly magnetic particles, which could in any way be interconnected before separation with strongly magnetic particles, fall into the region of the alternating magnetic field, are released from this bond and continue moving further into the strong magnetic field. Particles with greater magnetic - susceptibility, which interact with a weak magnetic field, fall into the sector part 7 of the discharge device 6. Lastly, the work in the mode of reciprocating rotation removes particles from the region of weak

magnetic field, after which they themselves are unloaded (1st stage of separation).

Low-magnetic and non-magnetic particles are fed by the feeder 10 into the zone of a strong magnetic field created by pole tips 2 and 3, where the weak-magnetic are extracted by the magnetic field and enter the sector part 8 of the discharge device 6. Lastly, the work in the reciprocating mode removes the weak-magnetic particles from the area a strong magnetic field beyond which they are unloaded (2nd separation stage). Non-magnetic particles are discharged by the feeder.

The proposed design of the pole tip 3 and the discharge device 6 provides better extraction of weakly and strongly magnetic particles.

The economic effect is achieved by obtaining a higher grade of the products obtained and realizing them at a higher cost.

Claims (1)

The formula is a bp and Electromagnetic separator, which includes a tape feeder, an electromagnet with pole tips placed above it, the working faces of which are made in the form of triangular-section teeth, and an unloading device, whose working surfaces are equidistant surfaces of the working faces of the pole pieces, differing from that, in order to increase the efficiency of the separation process due to the improvement of the purity of the separation products and their separate unloading, it is equipped with a non-magnetic insert, the first along Vision tape feeder pole piece is formed as a rectangular plate with teeth on the narrow sides oriented along the belt and inserting a nonmagnetic divided into two parts, and the teeth are arcuate. the unloading device is made of two rigidly connected sector parts and is installed with the possibility of oscillations around a vertical axis fixed in the center of the nonmagnetic insert, with one sector part located in front of the first pole tip along the feeder and the other in the interpolar gap of the electromagnet .