SU1569033A1 - Magnetic separator - Google Patents

Abstract

The invention relates to the enrichment of minerals by magnetic properties and is intended to enrich finely divided oxidized iron ores. The purpose of the invention is to increase the separation efficiency by improving the washing of the magnetic product. The magnetic separator contains a rotor (P) 3, circumferentially divided into chambers 5 filled with ferrofiller 6. In this case, P3 covers the electromagnetic system (EMC) 1, 2, in which slots (U) 16 are provided for supplying the initial power supply, and Sch17 for supplying the washing water and Sch 18 for output non-magnetic product. For EMC 1.2, in the direction of rotation of the rotor, there is a device for flushing the magnetic product. On the underside of the EMC 1.2, there are nozzles 13, 14 for supplying water and outputting a non-magnetic product. Above EMC 1 and 2 there is a capacitance 15, interconnecting between Sch 17 and 18. The distance between Sch 16, 17 and 18 is not less than the length of chambers 5. The total cross-sectional area of Sch 17 is 0.2-0.5 of the cross-section Sch 18 The magnetic field indicated by EMC 1, 2 is concentrated in the separation zone. The magnetic product is attracted to the ferrofiller 6. When chambers 5 pass over the nozzle 13, the washing water through the Sch 17 flushes the non-magnetic product, which is directed through the tank 15 to the Sh 18 to pass through the chamber 5 in a downward position and out through the nozzle 14. 1 ffl, 2 ill.

Description

The invention relates to the enrichment of minerals by magnetic properties, in particular, to devices for the enrichment of finely divided oxidized iron and other weakly magnetic ores.

The purpose of the invention is to increase the separation efficiency by improving the washing of the magnetic product.

Figure 1 shows the magnetic separator, a general view; 2 is the same schematic vertical section of the part in which the magnetic field is created and separation occurs.

The separator includes an electromagnetic system 1.2, which encloses the rotor 3 hermetically divided by partitions 4 into separate chambers 5, filled with ferro-filler 6, device 7 for supplying power, device 8 for washing the magnetic product, and device 9 for flushing the magnetic product. The arrow 10 shows the direction of movement of the rotor. In turn, the power supply device contains inlet 1 1 for supplying initial power and outlet 12 nozzles, nozzles 13 for supplying wash water and nozzles 14 for outputting a non-magnetic product, and a container 15 located above system 1.2, in which groups slots for passing the initial power supply 16, the washing water 17 and the output of the non-magnetic product 18. The nozzles 13 and 14 are located on the lower side of the electromagnetic system 1.2. Electromagnetic system 1,2 induces a magnetic field which maximally

concentrated in the separation zone. When moving, in this zone, the movable rotor 3 with ferro-filler 6 is sequentially exposed to the feed flow by means of the fixture 7 and the wash water flow by means of the fixture 8, as a result of which the rotor 3 leaves the separation zone with a magnetic product fixed on the surface of the ferrofill 6, which then outside the action of the magnetic field, is removed by means of the device 9 with the flush water flow. Food in the form of an aqueous suspension containing magnetic and non-magnetic particles is fed through pipe 11 and, passing through the slots 16, enters the chamber 5 of the rotor 3. Under the action of a magnetic field, the magnetic particles are attracted to the surface of the ferro-filler 6, and the slits in the lower part are removed through the nozzle 12. In this case, part of the non-magnetic particles are entrained in the magnetic product layer due to mechanical capture. Moving further, chamber 5 passes through an area in which, due to the arrangement of groups of slits 16 and 17 at a distance from each other equal to or greater than the length of chamber 5, the movement of the pulp is stopped and the mixing of different purpose streams is prevented. Then the magnetic product on the surface of ferro-filler 6 enters the zone of action of the rising jero flow of wash water, which is fed from the nozzle 13 and passes through the slot 17 in the lower part of the system 1.2. Stream passed through chamber 5 and containing after

This washed-out particles from the slots 17 in the upper part of the electromagnetic system 1.2, with the help of the capacitor 15, are guided into the slots 18 to pass through the chamber 5 in the downward direction. The chamber 5 itself passes through an area similar to the above described zone between the groups of slits 16 and 17. The total cross section of the group of slits 17 for passing an upward flow of wash water is 0.2-0.5 of the total cross section of a group of slits 18 for passing the same flow downstream. Due to this, the washing water moves upward at a speed greater than during the subsequent reverse movement. Such a distribution of directions and flow velocities first ensures intensive washing of the magnetic product with an upward flow, and then, when returning it to chamber 5, re-trapping of those magnetic particles that, together with non-magnetic grains, were removed from the chamber 5 by upward flow. As a result, the non-magnetic product, having passed through the slots 18 in the lower part of the system 1,2, is removed from the nozzle 14.

Claims (2)

1. Magnetic separator, including installed with the possibility of turning 10 690336 A rotor divided circumferentially into chambers filled with a ferrosillary, an electromagnetic system encompassing a rotor made with gaps for supplying initial power, washing water and outputting a non-magnetic product, nozzles for supplying washing water and outputting a non-magnetic product, and a device for flushing magnetic product located behind the electromagnetic system during the rotation of the rotor, characterized in that, in order to increase the separation efficiency by improving the washing of the magnetic product, The water supply and the non-magnetic product outlet are located on the underside of the electromagnetic system, and the slots for supplying the washing water and the non-magnetic product output are interconnected by means of a tank located above the electromagnetic system, while the slots for the initial power supply, for supplying the washing water and for the non-magnetic output product are located at a distance from one another equal to not less than the length of the chamber. 15 20 25 2. A separator according to claim 1 (characterized in that the total cross-sectional area of the slots for supplying wash water is 0.2-0.5 of the cross-sectional area of the slots for outputting a non-magnetic product. Patching Water Non-magnetic product Rnrln Nonmagnetic °° Roducht magnetic blown 1 Editor V. Bugrenkova Compiled by B.Levchayev Tehred M.Didyk Order 1410 Circulation 469 VNIIPI State Committee for Inventions and Discoveries at the State Committee on Science and Technology of the USSR 113035, Moscow, Zh-35, Raushsk nab. 4/5 Production and Publishing Combine Patent, Uzhgorod, st. Gagarin, 101 rotten blown Proofreader V. Girn to Subscription