SU1084074A1 - Magnetic and hydraulic separator - Google Patents

Abstract

1. MAGNETIC-GDRAVLICHESKY SEPARATOR, comprising a housing, a magnetic system housed in the housing and made in the form of a slit lattice of magnetic plates arranged parallel to each other, feeding and unloading devices, perforated sockets installed in the housing, characterized in that To increase the efficiency of the process by obtaining cleaner separation products, the casing is made of separate sections pasMejqeHHbix one above the other, the magnetic system is installed in each section, with magnetic plates systems in adjacent sections are mutually perpendicular. (L 2. The separator according to claim 1, which is powered by the fact that the power supply is located in the middle part of the body between the sections. 00 4 O J

Description

The invention relates to devices for beneficiation of minerals, mainly finely disseminated iron ores.

A device for magnetic enrichment of iron ores is known, comprising a housing, devices for feeding raw material, water and discharging separation products, installed a horizontally movable sieve with a bed layer and a magnetic system installed in the working area, the sieve being made of elastic non-magnetic material

The closest to the proposed technical essence and the achieved effect is a magnetohydraulic separator, including a housing, a magnetic system placed in the housing and made in the form of a slit lattice of magnetic plates arranged parallel to each other, supply and discharge devices, perforated pipes installed in the housing T23

A disadvantage of the known devices is the low efficiency of the process due to clogging of the separation products with inclusions of the separated fractions (concentrate - tails and vice versa).

The purpose of the invention is to increase the efficiency of the process by half-blending cleaner separation products.

The goal is achieved by the fact that in a magnetic-hydraulic separator, including a housing, a magnetic system placed in the housing and made in the form of a slit lattice of magnetic plates arranged parallel to each other, the power supply and discharge devices, perforated sockets installed in the housing, are made of There are separate sections placed one: Above the other, and the magnetic system is installed in each section, and the plates of the magnetic systems in the adjacent sections are mutually perpendicular. .

In addition, the power tool is located in the middle of the housing between the sections.

The drawing depicts a magnetic-hydraulic separator.

The separator includes a housing 1 made of five to six sections 2, in which magnetic systems 3 are installed, made in the form of slotted grids 4 of magnetic plates 5 arranged parallel to each other (for example, the registers can be made of steel plates installed one from

the other at a distance of 130-150 mm and glued on both sides with magnetized ferrite-barium tiles 6, having a magnetic field strength of 300,500 Oe on the surface). The cross section of each section 2 is 700/700 mm, height 500 mm. Moreover, the height of the plates 5 300 mm. Plates 5 are installed ya metal shelves 7. In

A fixture 8 is disposed in the upper section between the sections in the middle part of the body and the power supply device 9. In each slot of the lower magnetic shield of the bar there is a thick-walled perforator, ovined rubber nipple 10 (50-60 mm), connected to the compressed air inlet 1 1 .

A concentrate collector 12 is installed under the casing, to which water is supplied through the nozzle 13 and which is provided with a nozzle 14 for discharging the concentrate. Moreover, the density of the produced concentrate is adjusted by a screw device 15, pinching the rubber hose 16.

The separator works as follows. .

The finely divided iron ore suspension with a particle size of 3040 µm, a density of 1200–1300 g / l is fed through a feed device 9 to the central section of the separator. The non-magnetic particles of the suspension are carried upward in an upward flow into the upper section and removed by means of the discharge device 8 from the separator. Since the plates are magnetic grids

0 are mutually perpendicular, then randomly trapped magnetic particles, when they move up, meet the surface of the plates and flocculate, and then the floccules under the action of a force

5 tons of tin are moved downward, mixed with the magnetic fraction and scrubbed on the magnetic grids located below the nozzle 9, etc. through all sections. In order to better wash non-magnetic particles from the magnetic fraction, water is supplied to it through nozzle 13. In addition, the magnetic fraction between the magnetic grids is moved by ascending air puzzles that are generated in rubber nozzles 10 connected to nozzle 11, through which compressed air. A flocculator in magnetic grids magnetic fraction enters the collection 12, from which it is withdrawn via the nozzle 14 from the apparatus. The unloading density of the magnetic fraction is set at 1400-1500 g / l and is adjusted by a screw 15 that changes the cross section of the rubber hose 16. Installing magnetic grids one above the other results in the weight of the working volume of the magnetic-hydraulic separator being divided into vertical square channels, the walls of which magnetized. This increases the likelihood of collision of paramagnetic (ferromagnetic) suspension particles with the surfaces of magnetic plates, and, consequently, increases the enrichment efficiency, as it allows to clean up both the magnetic product - and the nonmagnetic - tails in a single device. When particles of the suspension move upward from the point of feeding power into the device through several magnetic arrays as a result of the action of turbulent pulsations, the magnetic fraction is mixed, its portions G) 1 constantly collide with the magnetic plates, flocculate and, continuing, interact with the magnetic plates of the grating located below the feed inlet up to release from the separator. In this case, there are many. : Close destruction and restoration of magnetic flocs and, thus, they are cleaned from mechanically entrained quartz particles. The nonmagnetic fraction in each magnetic lattice under the action of an extrusion force is concentrated in the center of the lattice gaps, where the magnetic field strength is close to zero due to the same magnetisation of the plates. The non-magnetic fraction is mixed here, and the magnetic particles randomly thrown into the center of the channel are returned to the magnetic plates. Installing magnetic gratings one above the other with gaps between them in the presence of turbulent pulsations ensures multiple cleaning of magnetic and non-magnetic fractions. Due to the fact that the walls of the magnetic gratings have the same polarity, the magnetic field in. The gap between them is very non-uniform: in the center of the gap the field strength is close to zero (magnetic field lines of the same name repel each other), and 300 O on the surface. Therefore, the magnetic force acting on ferromagnetic particles (about 20 cm from the wall) is insufficient for their retention "Under the influence of gravity and turbulent pulsations, the particles in this region do not lose their mobility and therefore special devices for cleaning magnetic layers are not required. Air bubbles, rising in the gaps of the magnetic grids, promote the mixing of the pulp in a magnetic field. This improves the cleaning of the magnetic fraction from the magnetic and non-magnetic from the magitite. Thus, the proposed Separator will improve the efficiency of the separation process in comparison with the known.

Claims (2)

1. MAGNETIC-HYDRAULIC SEPARATOR, comprising a housing, a magnetic system located in the housing and made in the form of a slit grating of magnetic plates arranged parallel to each other, feeding and unloading devices, perforated nozzles installed in the housing, characterized in that, with In order to increase the efficiency of the process by obtaining cleaner separation products, the casing is made of separate sections placed one above the other, a magnetic system is installed in each section, with magnetic plates with System in adjacent sections are located mutually perpendicular. § 2. The separator according to claim 1, wherein the feed device is located in the middle of the housing between the sections. SU. „, 1084074>