RU201727U1 - MAGNETIC SEPARATOR - Google Patents

Abstract

The utility model relates to devices for magnetic enrichment of magnetite ores and can be used to obtain high quality products. The technical result of the proposed utility model is to increase the productivity of the device, as well as to increase the efficiency and quality of purification of separated magnetic ores by making a circular magnetic system of permanent magnets of alternating polarity with the possibility of rotation of the magnetic system from a separate independent adjustable electric drive, regardless of the rotation of the shell of the drum. The technical result of the utility model is achieved due to the fact that a magnetic separator, including two drums with non-magnetic housings, each of which contains magnetic systems made of permanent magnets, receivers of separation separation products, the new is that the drums are of the same diameter and are located one above the other, while the magnetic system of the upper drum is permanently fixed on the axis and consists of 10-12 poles of alternating polarity and is located at 140-180 ° along the drum diameter with the possibility of changing the angle of arrangement, and the magnetic system of the lower drum consists of poles with alternating polarity along the entire drum diameter by 360 °, with the possibility of its rotation from a separate electric drive , so that the axis of rotation of the magnetic system coincides with the axis of rotation of the drum, while the circular magnetic system rotates towards the material supplied for separation, creating a running magnetic field, in addition, the shell of the lower drum is connected to the conveyor belt, due to which the magnetic material is removed into the hopper magnetic product, connecting with the magnetic product of the upper drum, and a tension roller is installed to tension and hold the tape. In addition, the magnetic system of the lower drum is made with a greater intensity of magnetic field forces on its working surface than on the working surface of the upper drum. In addition to the drives for rotation of the upper and lower drums, there is an individual drive for rotation of the magnetic system of the lower drum. 3 C.p. f-crystals, 2 tables, 1 dwg

Description

The utility model relates to devices for magnetic enrichment of magnetite ores and can be used to obtain high quality products.

Known separator containing a magnetic circuit in the form of two hollow cylinders located in parallel and horizontally with an adjustable gap. Hollow cylinders are enclosed in casings. Covers and deflection aprons are made of dielectric anti-friction material. When the material to be separated moves between electromagnetic systems, it is exposed to traveling magnetic fields, which prevent the formation of stable floccules of magnetic particles with non-magnetic ones. The magnetic fractions are attracted to the surface of the casings and move first along them, and then along the surface of the deflecting aprons, the strength of the magnetic fields of which gradually decreases. Leaving the zone of action of magnetic fields, magnetic particles fall into the appropriate bunker (P-RU # 2038848, B03S 1/24, publ. 09.07.1995).

The disadvantage of this separator is that weakly magnetic and non-magnetic fractions falling down change the vertical trajectory of movement to an inclined one and, as a result, instead of a receiver for non-magnetic fraction, fall into the magnetic fraction, diluting the concentrate.

Known magnetic separator containing a housing located above the conveyor belt with a magnetic system of permanent magnets, mounted for rotation around a vertical axis (P-RU No. 2246358, B03C 1/24, publ. 20.02.2005, bull. No. 5). The rotation of the housing with the magnetic system is constant at a sufficiently high speed, and the removal of ferromagnetic particles occurs under the action of centrifugal forces. The design is rather complex and short-lived, since during operation there is a strong wear of the rotating parts.

Known multi-chamber magnetic separator with a traveling field. (PM RU No. 72880, В03С 1/12, publ. 05/10/2008, bull. No. 13).

The separator includes non-magnetic disks placed on a common axis of rotation with permanent magnets fixed on them, equipped with several separation chambers, the magnetic system is made of magnetic blocks placed along an arc of a circle of disks at 360 ° with alternating magnetic polarity at a distance between the blocks less than their width, and located on both sides of the separation chamber and on the same line, the blocks have a directional arrangement of the vectors of magnetic induction.

In the second embodiment, the magnetic system is made of single and double blocks alternating around the disk circumference with a minimum clearance, and the magnetic polarity of the single blocks is opposite to the magnetic polarity of the double blocks and the magnetic systems on both sides of the separation chambers are displaced along an arc of a circle at an angle that ensures the location of single blocks on the line passing through the center of division of double blocks and having co-directional vectors of magnetic induction.

The disadvantage of this technical solution is the complexity of the design and low performance of the separator due to multiple reversal of the magnetization of magnetic particles.

The closest technical solution to the proposed one is a magnetic separator, which includes a housing in which, in the direction of movement of the ore to be concentrated, two magnetic drums with magnetic systems inside are installed at different levels and one after another, drum bodies are made of non-magnetic material, the magnetic system is made inside the drums in an arc and is composed of permanent magnets with alternating polarity, while the magnetic system of the first drum is fixed on the axis and is located at 90 ° -180 ° along the diameter of the drum, the magnetic system of the second drum is placed along an arc of 90 ° -180 ° is made stationary from radially of magnetized permanent magnets or a circular magnetic system is rigidly fixed on the drum shaft and rotates with the drum in the direction of movement of the ore, the shell of the second drum is connected to a conveyor belt, due to which the magnetic material is removed into the magnetic product hopper. The magnetic system of the second drum is made with alternation of maximally magnetized permanent magnets, separated by ferromagnetic rings (concentrators) along the axis of the magnetic drum, allows obtaining on the surface of these concentrators the limiting values of the magnetic induction (up to 2 T) (model RU 64947 U1, B03C 1/00, publ. 27.07.2007, bull. No. 21).

The disadvantage of this separator is that it can be used to enrich only the most weakly magnetic ores, the magnetic system of the second drum with a magnetic induction value (up to 2 T) does not allow the separator to be used for enrichment of ores with high magnetic susceptibility.

The technical result of the proposed utility model is to increase the productivity of the device, as well as to increase the efficiency and quality of purification of separated magnetite ores due to the implementation of a circular magnetic system of alternating 18 magnetic poles with the possibility of its rotation from a separate adjustable electric drive from the rotation of the drum shell.

The technical result of the utility model is achieved due to the fact that the magnetic separator, including two non-magnetic drums, in each of which are located magnetic systems made of permanent magnets, receivers of separation separation products, new is that the magnetic system of the lower drum is made in an arc of 360 ° with a greater intensity of the magnetic field forces on its working surface than on the working surface of the upper drum, the shell and the magnetic system of the lower drum are on the same shaft, but they have different electric drives of rotation. In addition, the shell of the lower drum is connected to the conveyor belt, from which the magnetic material is removed, and a tension roller is installed to tension and hold the belt.

The essential features of the utility model are the magnetic system of the lower drum of a circular type on permanent magnets with alternating polarity with rotation towards the supplied ore. The magnetic system of the lower one is made 360 ° circular and rotates from a separate electric drive towards the supplied ore, while the axis of rotation of the magnetic system coincides with the axis of rotation of the drum. The magnetic system of the lower drum is made with a greater intensity of magnetic field forces on its surface than on the working surface of the upper drum. The shell of the lower drum is connected to the conveyor belt; a tension roller is installed to tension and hold the belt. Each magnetic drum has its own electric rotation drive.

The applicant has not identified technical solutions that are identical to the declared utility model, which makes it possible to conclude that it meets the “novelty” criterion.

FIG. 1 is a schematic front view of a magnetic separator (section).

FIG. 2 shows a side view (section).

The magnetic separator consists of two magnetic drums, one above the other. The upper drum 1 is made with a stationary magnetic system 2 with an electric drive of the drum 8. The lower magnetic drum 3 is made with a circular magnetic system 4, which has its own electric drive 10. The shell of the lower drum 3 rotates on the shaft independently of the magnetic system 4 due to its own electric drive 9 and leads to movement of the conveyor belt 5. Under the upper drum 1, a dividing gate 7 is fixed on the frame to separate the fan of the enriched material. In the lower part of the lower drum 3 of the separator, a dividing gate 7 is also installed to separate the separation products into the magnetic product MP. and non-magnetic product Nm.P. The conveyor belt 5 is used to remove the magnetic product from the circular magnetic system. To tension and hold the belt, a belt tensioning roller 6 is installed. Each of the magnetic drums has its own individual electric drive.

The magnetic separator applied for patenting operates as follows (Fig. 1, 2).

The original ore material is fed through the feed hopper from above to the cylindrical surface of the upper magnetic drum 1 located in the separator body.

Under the influence of magnetic forces, the most magnetically susceptible ore particles, overcoming the centrifugal force, are attracted to the surface of the drum 1 and are carried out on this surface as a result of the rotation of the drum from the zone of action of magnetic forces, and then, under the influence of centrifugal and gravitational forces, they are transformed into the receiver of the concentrate M.P. A non-magnetic product under the action of centrifugal and gravitational forces, while still in the zone of action of magnetic forces, is detached from the surface of the drum and is directed by the dividing gate 7 to the lower drum with a running magnetic field, where the final separation into a magnetic MP takes place. and non-magnetic product Nm.p. (tails).

The magnetic product of the upper drum 1 is removed from the separation process and enters the magnetic product hopper M.P. The non-magnetic product (tails) of the upper drum 1 enters the lower magnetic drum 3 with a traveling magnetic field 4. Under the action of a circular magnetic field 4, all magnetic inclusions in the composition of the product to be separated are extracted, attracted and held on the conveyor belt at the time of passing through the magnetic system 4 tape 5. The removal of magnetic material from the conveyor belt 5 occurs when the material is removed from the magnetic system 4.

The magnetic product of the lower drum 3 is combined with the magnetic product of the upper drum 1 in a special collection of magnetic product MP, and the non-magnetic product (tails) enters the collection of non-magnetic product NM.P.

Magnetic particles with a lower magnetic value of susceptibility (middlings) by the dividing gate 7 are directed to the surface of the lower drum 3, which has a magnetic system with a higher intensity than the upper drum 1. The intensity of the magnetic field of the lower drum 3 creates conditions for the process of subsequent enrichment of middlings, which is not happened on top drum 1.

The successful enrichment of magnetic ore on the second magnetic drum is facilitated by a thinner layer of ore on the surface of the conveyor belt 5, from which the magnetic product is removed. As a result, a finished concentrate and a non-magnetic product (tailings) are obtained on the bottom drum as a result of beneficiation.

The implementation of the magnetic system of the lower drum from permanent magnets of high energy niodimum - iron - boron allows in the proposed separator to increase the value of the magnetic induction on the drum surface several times and, accordingly, to significantly increase the magnetic field strength (in comparison with the prototype magnetic separator). The magnetic field strength of 210 MT is sufficient for effective ore dressing.

The magnetic system of the lower drum is made along the entire diameter (circular) and rotates from a separate adjustable electric drive towards the movement of the separated material, while the axis of rotation of the magnetic system coincides with the axis of rotation of the drum.

The material to be separated is in a traveling field, which increases the selectivity of the extraction due to the creation of a "fluidized bed".

Technical characteristics of the separator with a traveling magnetic field

The magnetic separator proposed for patenting was mounted at JSC VGOK and showed its efficiency in the beneficiation of magnetite ores.

On the proposed magnetic separator, the applicant carried out a large series of experiments at various enrichment modes (see table 2). The experiments were carried out at the crushing and processing site of the Yuzhnaya mine, JSC VGOK.

Basic variant

Conducted dry magnetic separation according to schemes and parameters close to the patent, taken as a prototype.

We used dry magnetic separation separators:

first reception - BM-6 (N - 110 MTl., speed 60 rpm);

the second reception - PBS 40/20 (Н - 215 MTL., speed 58 rpm).

A variant with a traveling magnetic field (according to the claimed separator)

First intake - dry magnetic separation separator

BM-6 (N - 100 MTL, speed 60 rpm)

Tailings Cleaning - Traveling Magnetic Field Belt Separator -

(Н -220 MTl., Rotation speed of the magnetic system 140 rpm, belt speed - 1.1 m / s)

From the tables of test results it can be seen that in the CMC version:

When a belt separator with a traveling magnetic field was used, a middling product was obtained with a mass fraction of iron 3.5% higher than the base version.

When enriching the obtained intermediate products by the MMS method:

from middlings with the use of a traveling magnetic field - the through yield of the concentrate increases by 0.3%, through the recovery is higher by 1.6% and the mass fraction of iron in it increases by 0.6%.

On the magnetic separator proposed by the applicant, in comparison with the base version, from a smaller amount of CMC middlings (by 7.6%), an MMC concentrate was obtained by 0.3% more. Thus, the use of this separator makes it possible to reduce the volume of grinding the middlings, which is one of the most costly operations in ore beneficiation.

The magnetic separator improves the separation efficiency of magnetite ores. The separator is easy to manufacture and has a long service life.

Claims (4)

1. Magnetic separator, including a housing, in which, in the direction of movement of the ore to be concentrated, two magnetic drums with magnetic systems inside are installed at different levels and one after another, drum bodies are made of non-magnetic material, the magnetic system is made inside the drums along an arc and is composed of permanent magnets with alternating polarity, characterized in that the magnetic system of the lower drum consists of poles with alternating polarity along the entire diameter of the drum 360 ° with the possibility of its rotation from a separate electric drive, while the axis of rotation of the magnetic system coincides with the axis of rotation of the drum, the magnetic system rotates towards the ore supplied for separation, creating a traveling magnetic field, in addition, the shell of the lower drum is connected to the conveyor belt, due to which the magnetic material is removed into the magnetic product hopper, connecting with the magnetic product of the upper drum. 2. The magnetic separator according to claim 1, characterized in that the circular magnetic system of the lower drum is made with a greater intensity of magnetic field forces on its working surface than on the working surface of the upper drum. 3. A magnetic separator according to claim 1, characterized in that a tension roller is installed to tension and hold the conveyor belt. 4. The magnetic separator according to claim 1, characterized in that, in addition to the drives for rotation of the upper and lower drums, the drive of the magnetic system of the lower drum is additionally equipped.

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