RU187553U1 - SEPARATOR FOR SEPARATION OF BULK MATERIALS BY FRICTIONAL MAGNETIC CHARACTERISTICS - Google Patents

Abstract

The separator for separating bulk materials by frictional magnetic characteristics relates to the field of separation of weakly magnetic bulk ore and nonmetallic materials with different frictional and magnetic characteristics and can be used to separate asbestos ores. The device is a stratification unit in the form of an inclined plane, rotary ribs, articulated on an inclined plane at an appropriate angle (not more than 90 °), open towards the movement of the material, a curved springboard equipped with by staggered ball segments, which provides the best conditions for double impact interaction of rock particles with the surface of the elements and improves the performance and quality of separation of components with different friction and recovery coefficients. Also, to increase the separation efficiency, a drum with magnetic circuit, offset relative to the center of the friction separation drum, equipped with a sector magnetic system, located coupled with alternating poles along the axis and along the arc of the drum sector of bipolar radial neodymium magnets with residual magnetic induction B = 1.17-14.8 T, a gate with an adjustable tilt to separate the magnetic fraction and an air flow forming unit made in the form of radial curved blades mounted on the end surfaces of the drum, the length of the blades being greater than the radius of the drum.

Description

The separator for the separation of bulk materials by frictional magnetic characteristics relates to the field of separation of weakly magnetic bulk ore and non-metallic materials with various frictional and magnetic characteristics and can be used to separate asbestos ores.

A device for implementing this method is known comprising a conveyor for transporting material, a matrix drum located under the working branch of the conveyor [Device for magnetization: RF Patent No. 460891, M.KL. B03C 1/00 / A.A. Bikbov, S.V. Ryzhkov - No.145770 / 22-3; application from 02.25.1970; publication date 02/25/1975. Bull. No. 33.]

The disadvantage of this device is the low energy efficiency of the process of magnetization of the material due to the chaotic location on the conveyor belt of ore particles of various shapes and insufficient exposure to a magnetic field, which affects the efficiency of the separation process

Also known is a device for separating bulk materials by frictional characteristics, including a feeder, a system of inclined planes and receivers of products [Practice of beneficiation of asbestos ores / Ed. F.P. Safronova - M .: Nedra, 1975. 224 p.].

A disadvantage of the known device for its implementation is the low productivity and separation efficiency of asbestos-containing materials due to the high sensitivity of the process to factors such as load, change in the fractional composition of the aggregate state of asbestos, surface properties of the particles, moisture of the material and, as a result, fluctuations in the width of the fan on the plane . The need for a narrow ore classification, low specific productivity of plants predetermines the need for the construction of bulky buildings and structures.

The closest to the proposed technical essence and the achieved result is the device [Method for the separation of solid materials by size: RF Patent No.1313530, B07B 13/00 / Matrosov A.A., Panfilov F.V., Sysoev AM, Nikolsky V.V. ; Applicant and patent holder State All-Union Road Research Institute - No. 3398005 / 29-03, application dated 02/18/1982; publication date 05/30/1987. Bull. No. 20] including a feeder, an inclined vibratory tray, an air flow forming unit, a rotating separation drum with a drive, receivers of separated products. The device operates as follows. The source material with the help of an inclined vibratory tray exfoliates by size (by density, when it is necessary to separate a mixture of various materials) and is fed by a freely falling stream to the side surface of a rotating drum. Under the influence of the air flow directed towards the rotation direction of the drum, the layered material forms a fan of particles. Particles fall on the surface of the drum along different paths. Particles with a large coefficient of friction and with a lower coefficient of recovery are held on the surface of the drum and carried away by it in the direction of rotation. Particles (usually large) with a high recovery coefficient bounce off the surface of the drum in the direction opposite to its rotation.

The disadvantage of this device is the low separation efficiency with respect to asbestos products, due to the fact that particles with different physical properties fall from the vibrator tray at the same speed and a fan of material particles, over the rotating surface of the drum is formed only due to the air flow directed onto the falling material. Under these conditions, it is difficult to achieve a stable distribution of particles according to their physical properties along the width of the fan. Another disadvantage is the increased energy intensity of the process associated with the cost of creating an air stream.

The technical result achieved by the implementation of the claimed invention is to increase the efficiency of separation of bulk materials due to the fact that the inclined tray is made in the form of a plane with a curved springboard with a varying radius, in the lower part of which rotary ribs are fixed across the material flow, capable of changing the angle of inclination towards the movement of the material no more than 90 °, and the curvilinear springboard is equipped with deflectors made in the form of spherical segments, installed in a checkerboard pattern e and separating drum for a drum mounted with the magnetic system and a sector gate with adjustable angle for separating the magnetic fraction. A sector magnetic system located with alternating poles along the axis and along the arc of the drum sector of heteropolar radial neodymium magnets has a residual magnetic induction B _r = 1.17-14.8 T.

In addition, to achieve a technical result, the airflow forming unit is made in the form of radial curved blades mounted on the end surfaces of the drum, the blades being longer than the radius of the drum.

The invention is illustrated by drawings:

FIG. 1 - general view of the separator;

FIG. 2 - curved springboard equipped with baffles;

FIG. 3 - is an enlarged remote view B, a drum with a magnetic circuit, shown in figure 1;

FIG. 4. - is a cross-section of a drum with a magnetic circuit along line AA shown in FIG. one;

The separator (Fig. 1) includes:

1 - feeder; 2 - inclined tray; 3 - curved springboard; 4 - rotary ribs; 5 - a drum with a magnetic circuit; 6 - sector magnetic system; 7 - friction separation drum; 8 - bunkers for unloading waste rock; 9 - a hopper for unloading the magnetic fraction; 10 - hopper for unloading the concentrate; 11 - gate with adjustable slope to separate the ferromagnetic material; 12 - gates; 13 - radially concave blades; 14 - deflectors

The operation of the proposed device is as follows.

The effect of the stratification of the material into two products (asbestos - rock) on the inclined plane 2 will be the greater, the greater the difference in the friction coefficients of the separated particles. In the table. 1 shows the friction coefficients of products on surfaces with different coatings. The maximum difference in the coefficients of friction of the separated particles corresponds to the coating of an asbestos inclined plane.

Friction coefficient determination results

^* The coefficient of friction is different when using asbestos of different lengths as a type of surface coating.

Thus, the use of asbestos as a coating on plane 2 for stratification of the material into two products (a product with a higher coefficient of friction) will increase the separation efficiency.

To create asbestos coating on an inclined plane 2, for stratification of the material into two products, rotary ribs 4 are fixed on the plane across the material flow, capable of changing the angle of inclination towards the movement of the material by no more than 90 °. The use of such a technical solution as rotary ribs allows a fraction of free asbestos to be isolated from a mixture of products during the movement of the material along the plane.

This is as follows. Particles having a low coefficient of friction and a relatively large recovery coefficient move with greater speed and, hitting the surface of the rotary ribs 4, slip through without filling the intercostal space. Asbestos and dust inclusions having a high coefficient of friction and a low coefficient of recovery sliding on the surface 2 are held by turning ribs 4 and fill the intercostal space, thus creating a special uniform coating, which subsequently participates in the separation of the material into two products, due to retention their asbestos surface from the selected material. In the process of moving the material along an inclined plane 2, free "asbestos fiber" emitted from the stream is transported to the edge of the plane. The formation of a special coating is carried out at angles of inclination of the ribs equal to 70-90 °, then the ribs help to keep part of the free asbestos fiber on the plane. At these angles, the efficiency of the process and the yield of the tails remain virtually unchanged. When the angle of inclination of the rotary ribs is greater than 90 °, for example, 100, 110 °, free asbestos begins to roll through the rotary ribs and a uniform coating of the inclined plane is not created. With a further increase in the angle of inclination, the rotary ribs do not delay asbestos on an inclined plane and the effect of using a product with a higher coefficient of friction (asbestos) as a coating completely disappears.

A curved springboard 3 with a varying radius (Fig. 2) is an element that provides the second stage of preparation of particles with different coefficients of friction for separation. The friction force in this section varies, since at different points of the curved path the normal pressure of the particle on the surface is different. Therefore, if at the first stage the motion is uniformly accelerated, then at the second it is slowed down with acceleration, which varies according to a nonlinear law. At the exit from the curved springboard, deflectors 14 are installed, which are located along the width of the curved springboard. The movement of particles slows down when raised to the deflector 14 and at the exit from it. Behind the springboard 3, the asbestos fibers fall vertically downward, while the rock particles rise to the deflector 14 or, having hit the deflector, skip further. As a result, when the particles exit to the free flight area, they have significantly different speeds, and the particles escape along the flat paths. Changing the radius of the curved springboard allows you to create a separation fan, taking into account the various frictional characteristics of the shared materials. Thus, a fan of material separation is formed, due to which it is possible to form products with different contents of the useful component.

As a result of the study, it was found that magnetite, which is part of asbestos-containing minerals, is formed at the interface between the asbestos and the rock, which allows this effect to be used to derive intergrowths from the total volume of the rock mass using a magnetic system, with radial neodymium magnets, which are powerful rare-earth magnets and having a high "separation force" B = 263-406 kJ / m ³ , with residual magnetic induction B _r = 11.7-14.8 T. It was established that a change in the residual magnetic induction within these limits allows all particles of weakly magnetic asbestos-containing ore to be retained on the drum surface, which also improves the quality of separation of these products (table 3).

Table 2 shows the specific magnetic susceptibility of the host rocks characterizing the chemical composition of chrysotile.

Studies on the separation of asbestos ores have shown good ability to separate magnetic fractions using magnets with a "separation force" of B = 334 kJ / m ³ and with residual magnetic induction within B _r = 13.25 T. The results of the study are presented in table 3.

The process of passing pieces in a magnetic field is as follows: when the material leaves the curved springboard, 3 pieces with a high recovery coefficient, hitting the surface of the rotating friction separation drum 7, are released from the rock accumulation and fly along the flat paths in the direction opposite to the rotation of the drum, pieces of ore containing magnetite are easily magnetized and oriented axially relative to the poles of the magnetic system 6. Next, the magnetized pieces are captured by a drum the yoke 5 and are discharged into the hopper for the magnetic fraction 9. An enlarged view of B (FIG. 3) and a section along the line A-A (Fig. 4) should provide more information concerning the structure of the drum with the yoke 5 and the magnetic system 6.

Thus, the material is divided into magnetic and rock fractions. At the same time, pieces having a low recovery coefficient and a high coefficient of friction when leaving the springboard 3, hitting the surface of the friction separation drum 7, are carried away in the direction of its rotation and are unloaded into the hopper for unloading the concentrate 10.

In order to increase the separation efficiency of the material, an air stream is used, formed using radially curved blades 13 with a length greater than the radius of the drum, mounted on the end surfaces of the drum 7. Radial curved blades 13 are made longer than the radius of the drum and are fixed to the end surfaces so that the formed air flow is directed toward the middle of the side surface of the drum and the maximum flow force acted on the products to be separated, which will allow to reject asbestos particles, possessing those with higher windage. This solution provides the efficiency of separation of asbestos and rock, and also reduces the energy intensity of the process, in contrast to the known drum-type devices for the separation of bulk materials, where an air nozzle is used to direct the air in the direction of rotation of the drum.

In the known technical solutions, no signs are found that are similar to those distinguishing the claimed solution from the prototype, on the basis of which we can conclude that the proposed solution meets the criterion of "novelty."

An experimental verification of the device was carried out in an asbestos experimental factory on an experimental model of a friction-magnetic separator on various asbestos-containing products. The mode of experiments and the results of the separation are shown in table 3.

According to the results of the experiments, it was found that using the FMS magnetic system, up to 12.4% of the magnetic fractions of undisclosed asbestos in the form of strings can be returned to the enrichment cycle, which allows to reduce the emission of overgrown asbestos with enrichment tailings, thus ensuring the environmental safety of the removed tailings from the enrichment plant .

In turn, the use of an inclined plane equipped with rotary ribs, allowing to form a surface of asbestos, which creates conditions for holding particles with a high coefficient of friction and particles containing asbestos. It was found that the separation efficiency and tail yield are higher than with an inclined plane of steel and rubber: 42.9 and 66.7 versus 30.9 and 48.3 (steel) and 33.1 and 52.1 (rubber) (table 3, experiments No. 1, 2, 4).

With an increase in the angle of inclination of the ribs above 90 °, the separation efficiency and the yield of the tails decrease:

38.1 and 58.8 (α = 100 °);

36.8 and 48.7 (α = 110 °) versus 42.9 and 66.7 (α = 80 °);

42.5 and 65.6 (α = 90 °)

The method of forming the air flow practically does not affect the separation efficiency and the tail yield: 42.9 and 66.7 - (experiment No. 3, table 3) versus 42.3 and 64.8 (experiment No. 7, table 3), respectively, although during the formation of the air flow from the ends of the drum and the direction of the flow to the center of the side surface of the drum, these indicators are slightly higher (experiment No. 3).

In turn, the use of a curved springboard with a varying radius, simultaneously equipped with staggered deflectors and made in the form of spherical segments allows increasing the yield of the magnetic fraction to 15.6% and improving the quality of separation of friction products to 78.5% (experiment No. 1 table 3)

The proposed method and device for its implementation will improve the efficiency of processing of asbestos and mica-containing by-products, and when used in existing technological schemes, reduce the processing staging, therefore, reduce the number of energy-intensive devices. In addition, when using the proposed method and device, the texture will be preserved to a greater extent.

Claims (3)

1. The separator for separating bulk materials according to frictional magnetic characteristics, including a feeder, an inclined tray, an air flow forming unit, a rotating separation friction drum with a drive and receivers for separation products, characterized in that the inclined tray is made in the form of a plane with a curved springboard with a changing radius, in the lower part of which transverse ribs are fixed across the material flow, capable of changing the angle of inclination towards the movement of the material by no more than 90 °, a curved ramp provided made in the form of spherical segments deflectors mounted in a staggered manner, and for separating drum mounted drum with a sector of the magnetic system and the damper with adjustable angle for separating the magnetic fraction. 2. The separator according to claim 1, characterized in that the sector magnetic system located with alternating poles along the axis and along the arc of the drum sector of different-polar radial neodymium magnets has a residual magnetic induction B _r = 1.17-14.8 T. 3. The separator according to claim 1, characterized in that the air flow forming unit is made in the form of radial curved blades mounted on the end surfaces of the separation friction drum, while the length of the blades is greater than the radius of the drum.

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