EA016328B1 - Method for magnetic separation and device therefor - Google Patents

Abstract

The invention relates to material separation by its magnetic properties, in particular, to magnetic concentration of iron-containing ores. A method of magnetic separation comprises preparing dust air mixture, effecting the mixture by magnetic field, collecting magnetic and non-magnetic fractions in receivers. Motion of the dust air mixture is provided in the separation zone by such trajectory where centrifugal force acts upon mixture particles vector of which has a negative projection on the direction of the magnetic force vector. A device for magnetic separation comprises a non-magnetic revolving drum inside which a stationary magnetic system is arranged and receivers for separation products. The device is further provided with a reflector encircling the non-magnetic revolving drum in the separation zone, the inner surface of the reflector is cylindrical with a generatrix parallel to the drum axis, the device is also provided with units for preparing and feeding a dust air mixture into a space between the drum and the reflector. The technical inventive effect is enhanced efficiency of the separation process for fine-grained magnetic particles.

Description

The invention relates to the separation of material by magnetic properties, in particular to the magnetic concentration of iron ores.

Closest to the proposed invention is a method of magnetic separation of bulk mixtures, comprising preparing a dusty air mixture inside a fluidized bed chamber. During boiling, the material in the working chamber is loosened and weighed, magnetic particles from the dust-air mixture are attracted to a non-magnetic drum, inside of which there is a magnetic system. At the entrance to the receiver of the magnetic fraction, the magnetic particles using compressed air supplied through a special nozzle are cleaned of non-magnetic material deposited during boiling on the surface of the drum. The method is implemented in a device for magnetic separation of bulk materials containing a bulk material supply device, a fluidized bed chamber, a non-magnetic drum, a magnetic system installed inside it, a flat air nozzle directing the air flow tangentially to the surface of the drum, receivers of separation products [ed. USSR No. 876169, B 03 C1 / 00, 1981].

The disadvantages of this method are the low efficiency of the separation process for fine particles, low productivity, due to the fact that the particles in the magnetic field go through different trajectories and therefore are in different separation conditions, differing in magnitude and direction of magnetic force, speed and direction of movement of the particles.

The objective of the invention is to increase the efficiency of the separation process for finely divided magnetic particles.

The specified task in the proposed method is achieved by the fact that the pre-finely ground material is loosened and crumbled into individual particles in a device for creating a dust-air mixture, and magnetic separation of particles is carried out from the dust-air mixture, which is supplied at a constant speed to an inhomogeneous magnetic field and moves there along a path defined by a special reflector so that the vector of the resulting centrifugal force has a negative projection on the direction of the magnetic force vector. In this case, the particles are constantly pressed against the internal curved surface of the reflector, as a result of which all particles have the same trajectory in the field of magnetic forces. In this case, particles that have a magnetic susceptibility value above a certain value, depending on the ratio of the values of the centrifugal and magnetic forces opposing each other, are extracted from the total flow into the magnetic product, and the residual dust-air mixture is removed from the separation zone.

In order to more fully separate the magnetic fraction, it is preferable that the shape and location of the reflector in the magnetic field be such that the resulting force acting on the particle moving along the inner surface of the reflector and ensuring the effective extraction of the magnetic fraction from the total flux is the same in size and direction relative to particle velocity.

Most preferably, the resulting force is amplified towards the exit of the separation zone.

It is preferable to remove the dusty air mixture remaining after the separation process from the separation zone, creating a zone of reduced pressure in front of the receiver of the non-magnetic fraction.

The proposed method of magnetic separation can be implemented in a device for magnetic separation of bulk materials (see drawing), containing a drum of non-magnetic material 1, a stationary magnetic system 2 installed inside it, a reflector 3, the inner surface of which is a surface with a generatrix parallel to the axis of the drum , device for preparing a dust-air mixture 4 with a nozzle for supplying a dust-air mixture, receivers of separation products.

Despite the fact that the proposed device uses a cylindrical drum, the drum in the present invention refers to any surface that sequentially passes at a constant speed the separation zone (zone of action of magnetic forces), providing transfer and removal of the magnetic fraction.

The proposed method is carried out in the described device as follows. Pre-crushed by any known method, the bulk material is fed into a device for producing a dust-air mixture. Compressed air enters there. The resulting dusty air mixture is directed into the space between the drum and the reflector. The centrifugal force presses the particles against the inner surface of the reflector facing the drum, the particles move tangentially along it in a magnetic field. Magnetic particles are attracted by a magnetic field to the surface of a rotating drum, moved by a drum into a zone of weakened magnetic field, where they are separated from the surface of the drum, and non-magnetic particles continue tangential movement along the inner surface of the reflector and are then captured by the unloading device. The ore is divided into magnetic and non-magnetic fractions. The drum rotates towards the air flow, is blown by it, which additionally cleans non-magnetic particles from magnetic particles.

Preferably, the dust-air mixture is supplied tangentially to the inner surface of the reflector in the separation zone. Mathematical modeling of the magnetic separation process showed that the conditions for the entry of particles into a magnetic field are the distance from the entry point to the surface of the drum and

- 1 016328 a small variation in the entry angles does not significantly affect the separation process. However, it is desirable that the particles of the dust-air mixture enter the magnetic field tangentially to the inner surface of the reflector.

The greater the speed of the moving dust-air mixture in the space between the drum and the inner surface of the reflector, the greater the centrifugal force that presses the particles against the reflector, and the greater the magnetic force required to detach the magnetic particle from the inner surface of the reflector and its attraction to the drum. Therefore, the lower limit of the magnetic susceptibility of the particles to be separated into the magnetic fraction can be controlled by the air flow rate.

A similar adjustment can be carried out by changing the shape of the reflector and its distance from the magnetic system.

The movement of the dust-air mixture tangential to the inner surface of the reflector can be achieved, for example, by forming a flat flow using a flat output nozzle, whose inner surface is curved so that it mates with the internal surface of the reflector and forms a single smooth surface with it, the formation of which is parallel to the axis of the drum.

In such a nozzle, the dust-air mixture stratifies when moving, particles are pressed by centrifugal force against a wall of a larger radius. In the transition region, they do not violate the nature of their motion and enter the enrichment region tangentially along the internal surface of the reflector. Therefore, a nozzle of this design optimally prepares the dust-air mixture for magnetic separation.

A similar effect can be achieved if the reflector is continued beyond the separation region in the direction of the dust-air mixture supply device. In this case, the dusty-air mixture may approach the angle of the reflector at an angle, which then delaminates it on the way to the separation region. That is, the initial part of the internal surface of the reflector will form and direct the flow.

For effective enrichment, the dust-air mixture should uniformly enter the magnetic separator, therefore, the flat nozzle of the dust-air device should be wide, but not go beyond the side boundaries of the magnetic system. In this case, particles of the dust-air mixture sliding along the inner surface of the reflector should also be in the field of action of magnetic forces and should also not go beyond the lateral boundaries of the zone of effective action of the magnetic system. To this end, it is advisable to provide the reflector from the inside with side guide ribs restricting the width of the dust-air mixture flow in the magnetic separation zone.

As already noted, the heterogeneity of the magnetic field in the separation zone is expressed in that the closer to the drum, the higher the density of magnetic lines of force and magnetic forces increase. Therefore, if the density of the magnetic field lines, and, consequently, the magnetic force is large enough to tear off a magnetic particle pressed by centrifugal force to the inner surface of the reflector, then such a particle will be attracted to the surface of the drum and get into the receiver for the magnetic fraction. If the reflector is made of magnetic material, the number of magnetic lines of force suitable for the surface of the reflector will increase, which will cause an increase in magnetic force at the inner surface of the reflector. In this way, the lower limit of the magnetic susceptibility of particles released during separation into the magnetic fraction can be adjusted.

The reflector can be made combined, consisting of non-magnetic and magnetic parts, which will also provide an additional opportunity to adjust the process of magnetic separation of magnetic particles.

Most simply, such a system can be built by fixing it on the outside of a reflector made of non-magnetic sheet material, for example, a strip of any magnetic material. In particular, iron powder or magnetic concentrate, which is attracted by the force generated by the magnetic system to the outside of the reflector and fixed in this position, creating a magnetic region on the surface of the reflector.

If the inner surface of the reflector is a cylindrical surface, the generatrix of which is parallel to the axis of the drum, and the guide curve is, for example, a circle through the center of which the axis of the drum passes, then the same average magnetic attractive forces act on the particles throughout the movement in the separation zone.

If the center of the guide curve is offset relative to the point of passage of the axis of the drum, for example, towards the particle inlet, then the distance from the inner surface of the reflector to the surface of the drum at the entrance to the separation zone will be greater than at the exit. This means that the average attractive forces from the side of the magnetic system will increase with the movement of particles along the inner surface of the reflector. Therefore, particles with a greater magnetic susceptibility will be effectively separated at the inlet of the mixture, and as particles move in the separation zone, particles whose magnetic susceptibility is less will collect on the drum, which will enhance the separation effect.

A similar effect is achieved by using a magnetic system that creates a magnetic field that increases as one approaches the exit from the separation zone.

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A similar effect is also achieved by using the combined reflector described above. For example, if the reflector consists of two parts: in the initial part of the movement of particles in the separation zone is made of non-magnetic material, and in the final - of magnetic material, then the magnetic force acting on the particles will increase as it moves in the separation zone. If the magnetic part of the reflector will gradually increase along the path of the motion of the stream of partial thickness, then a corresponding smooth increase in the magnetic force can be achieved.

In order to effectively prevent slipping of magnetic particles on the surface of the drum and to effectively remove the magnetic product from the drum, its surface can be provided with ribs, mainly perpendicular to the direction of movement of the drum, which limit the sliding of magnetic particles on the surface of the drum during its rotation from the separation zone to the nonmagnetic zone, where particles are discharged from the surface of the drum into the receiver of magnetic products.

To effectively remove the non-magnetic fraction, it is advisable to place an additional device for collecting the non-magnetic fraction at the outlet of the separation zone in front of the receiver of the non-magnetic fraction, which selects the residual dusty air flow into the rarefaction zone (reduced pressure) created by any known method. As such a device, the use of an air cyclone is effective.

Claims (14)

CLAIM 1. The method of magnetic separation, including the preparation of the dust-air mixture, the effect on the mixture of the magnetic field, the collection of magnetic and non-magnetic fractions in the receivers, characterized in that they ensure the movement of the dust-air mixture in the separation zone along a trajectory where the centrifugal force acts on the particles of the mixture, the vector of which has a negative projection on the direction of the magnetic force vector. 2. The method according to claim 1, characterized in that in the separation zone is affected by magnetic force, mainly having a centripetal direction. 3. The method according to claim 1, characterized in that in the separation zone they are exposed to a magnetic field, mainly amplified towards the exit from the separation zone. 4. The method according to any one of claims 1 to 3, characterized in that they create a zone of reduced pressure in front of the receiver of a non-magnetic fraction. 5. A device for magnetic separation, including a rotating drum of non-magnetic material, inside which a stationary magnetic system is placed, and receivers of separation products, characterized in that the device is additionally equipped with a reflector surrounding the drum of non-magnetic material in the separation zone, the inner surface of the reflector is a cylindrical surface with a generatrix parallel to the axis of the drum, and also equipped with devices for preparing and supplying a dusty air mixture in the space between the drum SG and the reflector, wherein the reflector and the magnets are positioned so that a particle centrifugal force, which has a negative vector component along the direction of the magnetic force. 6. The device for magnetic separation according to claim 5, characterized in that the dust-air mixture supply device is made in the form of a nozzle, wherein the inner cylindrical surface of the nozzle wall tangentially mates with the inner surface of the reflector and forms a single smooth cylindrical surface with it forming parallel to the axis of the drum , and the guide is a smooth convex curve. 7. The device for magnetic separation according to claim 6, characterized in that the nozzle has a rectangular cross section elongated along the generatrix of the inner cylindrical surface of the nozzle wall. 8. The device for magnetic separation according to claim 5, characterized in that the reflector is placed immediately after the device for the preparation and supply of the dusty air mixture. 9. The device for magnetic separation according to any one of paragraphs.5-8, characterized in that the inner surface of the reflector is a cylindrical surface, the generatrix of which is parallel to the axis of the drum, and the guide curve is a circle whose center is eccentric with respect to the axis of the drum. 10. A device for magnetic separation according to any one of claims 5 to 9, characterized in that the reflector is provided on the inside with side ribs protruding towards the drum. 11. A device for magnetic separation according to any one of paragraphs.5-10, characterized in that at least partially the reflector is made using magnetic material. 12. The device for magnetic separation according to any one of paragraphs.5-11, characterized in that on the surface of the rotating drum there are ribs oriented mainly perpendicular to the direction of rotation of the drum. 13. A device for magnetic separation according to any one of paragraphs.5-12, characterized in that it contains an additional device for capturing a non-magnetic fraction, creating a zone of reduced pressure in front of the receiver of the non-magnetic fraction. 14. The device for magnetic separation according to item 13, wherein the device for collecting non-magnetic fraction is an air cyclone.