SU1680334A1 - Electromagnetic separator - Google Patents

Description

The invention relates to magnetic enrichment and m. used in the mining industry of national economy. The purpose of the invention is to increase the efficiency of the separation process by increasing the magnetic field strength in the separation zone. A non-magnetic drum 2 is rotatably mounted in the separator bath. On the drum 2 there is a combined magnetic system consisting of electromagnetic coils (K) 9 and permanent magnets (PM) 8. The electromagnetic system is made of ferromagnetic rods in the form of an H-shaped core, and PM 8 is located between the vertical rods 6 below the horizontal rod or jumper (P) 7.

The invention relates to magnetic enrichment, in particular to the construction of magnetic separators, and can be used in ore dressing plants.

The purpose of the invention is to increase the efficiency of the separation process by increasing the magnetic field strength.

Above PM 8 around rods 6 or P 7 are placed K 9. When the electromagnetic system is not in the separation zone, K 9 is de-energized, PM 8 is closed P 7 short and there is no magnetic field in the region of the ends of the rods 6. Before entering the separation zone, K 9 is connected to a power source. In K 9, a current appears, and in P 7 and in the upper parts of the rods 6 a magnetic flux appears, the lines of force of which close in the region of the ends of the rods 6. Under the influence of a magnetic field, the magnetic product is attracted to the ends, which leads to a decrease in magnetic resistance and an increase in magnetic flux electromagnet, which displaces the magnetic flux PM 8 from P 7. The power lines PM 8 begin to close through the ends of the rods 6 and the extracted product. Magnetic fluxes PM 8 and K 9 are added together, which leads to an increase in the material being attracted. The magnetic flux of the electromagnet increases again, the amount of attracted product increases, etc. The process is an avalanche. The extracted product is carried out by the rotation of the drum from the separation zone, K 9 is turned off, the magnetic flux K 9 disappears, and the magnetic flux PM 8 closes through P 7. The magnetic product is removed by jets of water or scrapers. 2 hp ff, 5 ill.

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FIG. 1 shows a separator with a magnetic system located on the outer surface of the drum, a general view; in fig. 2 - the design of an elementary combined magnetic system with electromagnetic coils on the rods; in fig. 3 - the same, with an electromagnetic coil on the jumper; in fig. 4 - block design

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elementary combined magnetic systems: in FIG. 5 - picture of the addition of magnetic fields in working condition in an elementary combined magnetic system ..

The electromagnetic separator includes a bath 1, a drum 2 made of non-magnetic material mounted in a bath for rotation, a combined magnetic system 3 consisting of electromagnets and permanent magnets located on the surface of the drum, and receivers of separation products 4 and 5.

The electromagnetic system of the separator is made of ferromagnetic rods in the form of an H-shaped core formed by two vertical rods 6 attached to the surface of the drum 2 by a horizontal rod or jumper 7 connecting the rods 6 and making up a whole with it. Between the rods 6, under the bridge 7, there is a permanent magnet 8, which, by its poles, adjoins the side surfaces of the rods 6 and whose magnetic field lines are closed through the bridge 7 so that there is no magnetic field on the upper end surface of the rods 6. This means that the jumper 7 magnet 8 is short-circuited. On the rods 6 above the jumper are electromagnetic coils 9. Coils 9 can also be placed around jumper 7 (FIG. 3).

Elementary combined magnetic systems can be combined into separate blocks (fug. 4) arranged in rows along or perpendicular to the axis of the drum 2. At the same time, adjacent electromagnets have common electromagnetic coils 10 and face one another so that the permanent magnets adjacent to the rods covered by common coil 10, have the same polarity.

In order to reduce the scattering flux, permanent magnets located opposite each other in adjacent rows should also have the same polarity, which determines the symmetric arrangement of the elementary magnetic systems in all rows.

The gaps between the rows and the free space between the coils filled with non-ferromagnetic material 11 to the level of the upper end surfaces of the rods, which is given the shape of a portion of the cylindrical surface with a diameter equal to the diameter of the drum, increased by two lengths of the rods 6.

The combined magnetic system of the type described may be located on the outer or inner surface of the drum.

The separator works as follows.

In the initial state when the drum 2 rotates, this system is not in the separation zone, the system coils 9 are de-energized, the magnet 8 by jumper 7 is short-circuited, and there is no magnetic field in the region of the end surfaces of the rods 6.

Before the elementary magnetic system directly enters the separation zone, the sliding contact of the switching device connects the coils 9 to the power supply, a current appears in the coils, and a magnetic flux appears in bridge 7 and the upper parts of the rods 6, the power lines of which close in air in the area of the end surfaces of the rods 6 After the upper parts of the rods 6 are dipped into the pulp, under the action of a magnetic field the magnetic product 12 (FIG. 5) is attracted to the surface formed by the end surfaces of the rod. 6 minutes and the surface of a nonmagnetic material located between the rods. With a constant magnetomobile force, this leads to a decrease in the magnetic resistance to the magnetic flux created by the electromagnetic coils 9. The magnetic flux of the electromagnet increases dramatically and begins to displace the magnetic flux of the permanent magnet 8 from bar 7. Since then the magnetic field lines of the permanent magnet 8 begin to close through the tops of the rods 6 and the product to be extracted. In this case, the magnetic flux of the permanent magnet is added to the magnetic flux of the electromagnet (Fig. 5), which leads to an increase in the number of attracted magnetic product. The magnetic flux of the electromagnet increases again and carries out an even greater displacement of the magnetic flux of the permanent magnet 8 from the jumper 7 and its direction in the region of the end surfaces of the rods 6. The amount of attracted magnetic product increases, etc. The process of increasing avalanche. The extracted magnetic product with further rotation of the drum 2 is taken out in the discharge zone, where the sliding contact disconnects the coil 9 from the power source. The magnetic flux of the electromagnet disappears, and the magnetic flux of the permanent magnet 8 closes at the shortest distance through the jumper 7, which shunts the attracted product. The latter is easily removed with water jets or a scraper.

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Claims (3)

Claim 1. Electromagnetic separator, which includes a bath, rotated non-magnetic drum in the bath, a combined electromagnetic system located in it, consisting of permanent magnets and magnetizing coils, feeder and receivers of separation products, characterized in that separation process by increasing the magnetic field strength, the electromagnetic system is made of ten ferromagnetic rods in the form of an H-shaped core, a permanent magnet is located between the vertical rods below the horizontal core of the core, and the magnetization coils are located above the permanent magnet around the rods. 2. A separator according to claim 1, differing in that the coils are located on vertical rods. 3. Separator pop. 1, characterized in that the coils are located on horizontal rods. FIG. 2 FIG. 3 11 th 1680334 FIG. H FIG. five