RU1803191C - Magnetic separator - Google Patents

Abstract

Usage: wet magnetic ore separation with the release of magnetite and other ferromagnetic substances with increased magnetic susceptibility. SUMMARY OF THE INVENTION: A magnetic separator, the working member of which is made up of a set of parallel disks on a shaft with an annular magnetic system consisting of poles with alternating polarity around the circumference with a pin pitch of the cleaning mechanism. The working body is cleaned using a non-magnetic disk on which ferromagnetic pins of different lengths are fixed: long ones are located between the poles of the magnetic system, and short ones are opposite the poles, 3 ill.

Description

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The invention relates to mineral processing and can be used in ferrous and non-ferrous metallurgy, coal and chemical industries, to increase magnetite and other ferromagnetic substances with increased magnetic susceptibility.

The purpose of the invention is to increase the efficiency of the magnetic separation process.

This goal is achieved in that in a magnetic separator comprising a working body in the form of disks mounted with the possibility of rotation around a horizontal axis, on which an annular magnetic system of permanent magnets of alternating polarity is placed, disks with protrusions on the side surfaces for removing the magnetic product surfaces of the working body, installed in between the disks of the working body with the possibility of rotation

around a horizontal axis parallel to the axis of the working body and offset relative to it, a bath with a device for unloading a non-magnetic product, a feeder and a device for supplying water, characterized in that, in order to increase the separation efficiency, the disks for removing the magnetic product from the surface of the working body of non-magnetic material, and the protrusions of the disks are made in the form of pins of different lengths of ferromagnetic material, with long pins located between the poles, and short pins against the poles of the magnet total system of the working body.

Due to the fact that the dielectric strips for removing the magnetic product from the power supply and the working element are made of non-magnetic material, and the pins are made of magnetic material, the magnetic field does not close across the entire surface of the removable disk, which facilitates flushing

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magnetic product. The pins inserted in the field create an uneven magnetic field, and a maximum gradient is induced on the pins themselves.

Magnetic particles are attracted to the surface of the disks by radial and tangential components of the magnetic field strength. The radial value of the force acts against the poles, and the tangent component between the poles. The radial component forms a layer of material against the center of the poles, in which the magnetic strands are located perpendicular to the surface of the pole, the tangent component forms a layer of material above the pole space and the strands are parallel to the surface of the disks. The thickness of the layer against the pole is much greater than between the poles. Therefore, for more effective material removal, the pins of the disks for removing the magnetic product must be of different lengths.

The removal of magnetic particles located opposite the poles is more efficiently carried out by short pins, because in this case they cross a larger number of lines of force (at a close distance, the magnetic lines are parallel to the pin) and the maximum value of a strong magnetic field is induced on them, and magnetic particles located between the poles are more effectively removed by long pins, because the magnetic field lines of the floor are parallel to the disk and the closer the pins are to the surface of the disk, the more forces x they cross the line and they are induced by the maximum value of the power of the magnetic field.

Thus, by increasing the length of the pins, an increase in the removal efficiency of the magnetic product material from the magnetic disk is achieved, which ultimately leads to an increase in separation efficiency.

The cleaning mechanism is made of non-magnetic material, therefore, the magnetic field arising on the pins does not close, as a result of which the washing of the material from the pick-up disk in the discharge zone is facilitated.

This allows an increase in the efficiency of the enrichment process.

Figure 1 schematically shows a magnetic separator; figure 2 is a section aa in figure 1; in Fig.Z - node I in Fig.2 (cleaning mechanism).

The magnetic separator consists of a feeder 1, which serves to supply the initial power, bath 2, the working body, made in the form of a set on the shaft of parallel disks 3 with gaps between them, with an annular magnetic system 4, consisting of 5 poles with alternating circular circumference with a step of the cleaning mechanism 5, the concentrate receiver 6, the tail receiver 7, sprayed 8 and 9, used to flush the concentrate and supply additional water, the drive of the working body 10, the drive of the cleaning mechanism 11 and the frame 12, on which all nodes are mounted. The cleaning mechanism 5 consists of a non-magnetic disk 13 with ferromagnetic short pins 15 and long pins 14 fixed to it, with long pins located between the poles and short pins against the poles. The pins are located on a concentric circle with a step between diameters equal to the diameter of the pin and alternating along the circle with a step equal to the pitch of the poles of the magnetic system.

The separator operates as follows.

The source material from the feeder 1 enters the space between the end surfaces of the working member 3, directly to the magnetic system 4. The ferromagnetic particles are attracted to the magnetic system by the action of the magnetic field and transported to the cleaning zone. Along the path of movement, the attracted material enters the zone where it sprayed

5 g water is supplied, which provides additional removal of sludge particles. In the zone of cleaning the working disk 3 from the extracted material, the long pins 14 capture material adhering to the pole space, and the short pins 15 of the material adhering to the poles and transport outside the working disk 3, where the adhered material is washed off by spraying water 8, into a concentrate receiver 5 nickel 6. Non-magnetic particles are discharged into the tail receiver 7. Tests of the separator prototype showed that a removal disk consisting of alternating-length ferromagnetic pins mounted on a disk of

0 non-magnetic material, in comparison with the prototype allows a larger removal of the magnetic product, reduces the loss of iron in the tailings, and, ultimately, leads to an increase in efficiency

5 enrichment.

Formula Magnetic separator, comprising a working element in the form of disks mounted with the possibility of rotation around the horizontal axis, on which an annular magnetic system of permanent magnets of alternating polarity is placed, disks with protrusions on the side surfaces for removing the magnetic product from the surface of the working body, a bath is installed in the spaces between the disks of the working body with the possibility of rotation around a horizontal axis parallel to and displaced relative to the axis of the working body a device for discharging the non-magnetic product feeder and priFig

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a method for supplying water, characterized in that, in order to increase the separation efficiency, the disks for removing the magnetic product from the surface of the working body are made of non-magnetic material, and the protrusions of the disks are made in the form of pins of different lengths of ferromagnetic material, with long pins located between the poles , and short pins - against the poles of the magnetic system of the working body.

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VNIIIPI of the State Committee for Inventions and Discover at the USSR State Committee for Science and Technology 113035, Moscow, Zh-35, Rauska nab., 4/5

Production and Publishing Plant Patent, Uzhgorod, 101 Gagarina St.