RU2462316C2 - Method of magnetic separation of fine submagnetic loose products and magnetic separator to this end - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to dry magnetic separation and may be used in mining, glass-work, chemical industry, etc. Proposed method comprises feeding initial submagnetic loose material along vertical magnetic system inducing magnetic field forces directed along normal to magnet working surface, separating said material into magnetic and nonmagnetic fractions and distributing separated product among appropriate bins. Product is fed in parallel flows along vertical zones of maximum magnetic force effects. Note here that every flow is forced through free fall deceleration device while magnetic fraction deposited on permanent magnet surfaces is forced vertically downward by means of vibrator.

EFFECT: higher efficiency of magnetic separation.

10 cl, 13 dwg

Description

The invention relates to the field of dry magnetic separation of finely dispersed weakly magnetic bulk products and can be used in mining, glass, chemical and other industries.

A known method of dry magnetic separation [1], which includes feeding the separated product from the feeder vertically along a vertically mounted flat magnetic system of the magnetic separator [1], magnetic separation of the product into magnetic and non-magnetic fractions, the distribution of the separated product along the receivers of its magnetic and non-magnetic fractions . The magnetic separator [1], in which the method of dry magnetic separation is implemented, includes a feeder for the product fed to the separation, a vertically mounted magnetic system, distributors and receivers of magnetic and non-magnetic fractions of the product. The magnetic system in the magnetic separator [1] creates a magnetic field whose gradient and magnetic force are directed normal to the working surface of the magnetic system. The method of dry magnetic separation [1], which is implemented in a magnetic separator, and the magnetic separator [1] are accepted as prototypes for the proposed method of magnetic separation of finely dispersed weakly magnetic bulk products and a magnetic separator for its implementation.

The process of magnetic separation in the prototype is as follows. A finely dispersed weakly magnetic bulk product under the action of gravity is fed from the feeder and vertically falls along the magnetic system of the separator. In this case, the trajectory of the non-magnetic fraction of the product is determined only by gravity, and the trajectory of the magnetic fraction is determined by two forces: gravity and the magnetic force directed normal to it, moving the particles of the magnetic fraction horizontally in the direction of the working surface of the magnetic separator system. As a result of this, the motion paths of the particles of magnetic and non-magnetic fractions do not coincide, which ensures magnetic separation of the product into magnetic and non-magnetic fractions: the non-magnetic fraction moving vertically enters the receiver of the non-magnetic fraction, and the magnetic fraction falling vertically and deviating simultaneously to the working surface of the magnetic system, it subsequently enters the receiver of the magnetic fraction of the separated product (if this fraction does not reach the surface of the magnets and settles on this surface under the action of magnetic forces).

When implementing the method of dry magnetic separation in a magnetic separator [1] there are great technical difficulties that are due to the fundamental disadvantages of the magnetic separator prototype. For a clear separation of the magnetic and non-magnetic fractions of the product according to the respective receivers, a significant distance (the width of the "fan") between the magnetic flux and the flux of non-magnetic fractions at the output of these product streams from the zone of action of magnetic forces is necessary. Such a distance (the width of the "fan") should be at least a few centimeters. Since the non-magnetic fraction drops linearly, to obtain the width of the “fan” of the product by several centimeters when it leaves the zone of influence of magnetic forces, it is necessary that the layer of product that moves (falls) along the plane of the working surface of the magnetic system also has several centimeters. But since magnetic forces sharply decrease with distance from the working surface of the magnetic system, deviation of the low-magnetic product stream or its deposition on the working surface from a layer of several centimeters is practically impossible. This is explained by the fact that the product velocity relative to the magnetic system of the separator resulting from free fall is so large, and, accordingly, the allotted time for acceleration of particles of the magnetic fraction along the path toward the working surface is so short that they can overcome alternative magnetic forces on this path forces of inertia, the height of the magnetic system should reach several meters. The indicated technical difficulties in implementing the method of dry magnetic separation of weakly magnetic products [1] in a magnetic separator [1] are fundamental and practically insurmountable: the technological requirements for the thickness of the product layer (at least a few centimeters) contradict the requirements for the magnetic-force characteristics of the separator, which limit this layer of the product to a thickness just within one centimeter (most often within just a few millimeters). The simultaneous requirements for the magnetic separator [1] to the magnitude of the magnetic forces that attract magnetic particles to the working surface of the magnetic system are also contradictory. An increase in these forces improves the separation of the incident product into magnetic and non-magnetic fractions and reduces the necessary height of the magnetic system, but at the same time, the rate of adhesion of these particles to the working surface increases, which can lead to their braking and even complete cessation of downward movement. In order to obtain large magnetic field strengths FM = HgradH, it is necessary not only to create a large magnetic field H, but, equally importantly, to obtain a large gradH, that is, to ensure a rapid increase in H when approaching the deposition surface, which is possible only when thin layer of product.

Thus, in a magnetic separator [1], conflicting requirements come into conflict: on the one hand, the need to provide a layer thickness of the falling product of at least a few centimeters and, on the other hand, the need to have a thickness of this product layer within one centimeter.

It should also be noted that the creation of large magnetic forces on the working surface of the magnetic system can lead to such an intense compression of the particles of the magnetic fraction to the working surface that the movement of these particles under the action of gravity Fg becomes completely impossible and the magnetic separator [1] in this case becomes inoperative . If we use the fundamental possibility of a magnetic separator [1] to obtain the deposition of particles of a magnetic fraction even with insignificant magnetic forces due to an increase in the height of the magnetic system, then the overall dimensions, mass and, as a result, the cost of such a separator will become unacceptable in technical and economic terms. When separating very weakly magnetic products (for example, silica sand, hematite ores) on a magnetic separator [1], all the indicated disadvantages of the magnetic separator [1] are only exacerbated.

Since the separated product falls with acceleration g = 9.8 m / s ² , then, for example, in the first second of its fall the product flies 4.9 meters, which accordingly requires the same height of the magnetic system. This is practically unacceptable.

The fall of the product in a uniform layer over the entire width of the magnetic separator [1] requires the creation of a magnetic field of a correspondingly equal magnetic force over the entire width of the product stream. But, even when using permanent Nd-Fe-B magnets of the highest energy (Wd = 400-500 kJ / m ³ ), it is impossible to achieve the necessary magnetic forces across the entire width of the working surface without concentration of these forces, at least in its individual sections, and therefore realized in magnetic separator [1] the magnetic system is ineffective for the deposition of finely dispersed weakly magnetic products, such as quartz sand, biotites, hematites, ilmenites, etc.

The basis of the invention is the task to increase the efficiency of the method of magnetic separation of finely dispersed weakly magnetic bulk products by reducing the rate of fall of the product, passing the product only along the vertical zones of maximum forces and transporting the magnetic fraction of the product deposited on the working surface of the separator into the receiver of the magnetic fraction.

The problem is solved in a method of magnetic separation of finely dispersed weakly magnetic bulk products, including the supply of a separated product along a vertically mounted magnetic system that creates magnetic field forces directed normal to the working surface of the magnets, magnetic separation of the product into magnetic and non-magnetic fractions, distribution of the separated product to receivers its magnetic and non-magnetic fractions, in which according to the invention the product is fed in parallel flows along vert -local coverage areas of maximum magnetic forces, each stream is fed through the free fall velocity of the product deceleration device, and moving vertically downward magnetic product fraction deposited on the deposition surface along the working surface of the magnetic system formed from permanent magnets is carried out by means of a vibrator.

The problem is solved in a method of magnetic separation of finely dispersed weakly magnetic bulk products, in which the product is dropped along a multi-stage magnetic system, each of the subsequent stages of which are shifted horizontally relative to the previous stage in the direction of product drop.

The problem is solved in a method of magnetic separation of finely dispersed weakly magnetic bulk products, in which the product is dropped relative to the steps of a magnetic system of different heights and different intensities of the magnetic field strengths.

The problem is solved in a magnetic separator, including a separator product feeder, a vertically mounted magnetic system that creates magnetic field forces directed normal to the working surface of the magnets, separators and receivers of magnetic and non-magnetic fractions of the product, in which, according to the invention, the separator is supplemented with a vibrator connected to surface deposition, and devices for slowing down the rate of fall of the product, which are placed in thin-walled non-magnetic guides of the product flow guides x mounted vertically in the zones of maximum magnetic field strength, and the magnetic system is made of permanent magnets of non-uniform horizontal horizontal alternating vertical zones of maximum and minimum magnetic field forces.

The problem is solved in a magnetic separator, in which the device for slowing down the rate of fall of the product is performed in the form of stretched thin non-magnetic strings installed perpendicular to the working surface of the magnets.

The problem is solved in a magnetic separator, in which the device for slowing down the rate of fall of the product is performed in the form of thin non-magnetic plates tilted to the vertical and to each other, mounted stepwise one under the other with the possibility of pouring the product from the plate onto the plate when it falls under gravity.

The problem is solved in a magnetic separator, in which the magnetic system of the separator is performed in the direction of multi-stage product movement with a horizontal offset of each next stage relative to the previous one.

The problem is solved in a magnetic separator, in which each stage of the magnetic system is performed at different heights and with different magnitudes of the magnetic field strengths.

The problem is solved in a magnetic separator, in which the magnetic system of the separator is made of plate permanent magnets placed on a ferromagnetic shunt with alternating horizontal polarity, and the gutters are installed along the separation zone of the polarity of the permanent magnets.

The problem is solved in a magnetic separator, in which the magnetic system of the separator is made of flat plate permanent magnets installed in a row one after another in the horizontal direction and separated by plate ferromagnetic concentrators, to which the permanent magnets are adjacent with their same poles, and the gutters are installed along the ferromagnetic concentrators on two opposite sides of the magnetic system.

The artificial slowdown of the product falling rate along a vertically mounted flat magnetic system in a magnetic separator proposed in the invention allows (in comparison with the prototype) to reduce the height of the magnetic system and the magnitude of the magnetic forces that are needed to extract ferromagnetic particles from the flow of the incident product and to deposit on the working surface of the magnetic system or at least for a sufficient deviation of the trajectory of these particles relative to the trajectory of particles of a non-magnetic fraction of the product. This is because with a decrease in the rate of fall of the product, the time of its movement under the action of magnetic forces in the direction of the working surface of the magnetic system increases accordingly. By increasing the time required for the ferromagnetic particles to overcome the distance to the working surface, it becomes possible to increase the layer of the falling product, and therefore, correspondingly increase the width of the "fan" of the separated product when it leaves the zone of action of magnetic forces. The expansion of the "fan" of the product increases the efficiency of separation of the product into magnetic and non-magnetic fractions.

Reducing the rate of fall of the product also allows you to reduce the height of the magnetic system (with a constant magnitude of magnetic forces) or reduce the magnitude of magnetic forces (with a constant height of the magnetic system).

Since, when approaching the surface of permanent magnets, the magnetic forces that act on ferromagnetic particles increase significantly, some of these particles are deposited on the working surface of the separator, and if the friction forces of particles on this surface are greater than the attractive force, then particles that settled, accumulate on this surface, as a result of which the efficiency of the separation process decreases.

The use of a vibrator proposed in the invention, the forces of which are applied to a freely fixed thin non-magnetic sheet that covers the surface of the permanent magnets, provides for the "sliding" of the ferromagnetic particles deposited on this sheet under the action of vibration and gravity down into the receiver of the magnetic fraction of the separated product. If necessary, vibration forces can be applied to the gutters themselves, if there is a possibility of a product flow jam on the device to slow down the rate of fall of the product.

For the separation of well-flowing (low-viscosity) products that are not prone to clumping, the device for slowing down the fall of the product is proposed to be made in the form of thin non-magnetic plates inclined to the vertical and to each other, installed with the possibility of pouring the product from the plate onto the plate when it falls under the influence of gravity.

When implementing the device for slowing down the rate of fall of the product in the form of thin highly stretched non-magnetic strings placed in the grooves normal to the flow of the falling product, not only is the decrease in the rate of fall of the product but also its loosening, destruction of crumpled fractions and creation of a free-weighted state of the product in the working volume of the separator . In this state, the mutual friction forces between the falling particles of the product disappear and favorable conditions are created for mechanically interdependent motion of non-magnetic particles under the action of gravity — vertically, and magnetic particles under the simultaneous action of magnetic and gravity — at an angle to the working surface of the magnetic system (to deposition surface of the magnetic fraction).

The separation of the least magnetically susceptible products requires the highest magnitude of magnetic forces. The magnitude of these forces limits the maximum permissible layer thickness of the falling product, in which magnetic forces of sufficient magnitude act. In such cases, with a single-stage (vertical) execution of the separator, it is practically impossible to obtain the technologically permissible “fan” width of the separated product. To overcome these difficulties in accordance with the invention, it is proposed to perform the multi-stage separator in the direction of product fall. Each next stage of such a separator is shifted horizontally from the previous one by a small distance, while maintaining the most often vertical position. Since the nonmagnetic fraction falls only vertically, the particles of this fraction will flow (fall) along all stages of the separator in a fine stream without changing their initial trajectory. Particles of the magnetic fraction under the action of magnetic forces at each stage will be displaced horizontally by a distance equal to the displacement of each stage of the separator relative to the next. In this case, the distance of the incident magnetic fraction from the working surface of the magnetic system at each stage can be kept to a given minimum. The more such steps, the greater the width of the “fan” of the product at the exit from the zone of action of magnetic forces.

The magnetic fraction of the product, when it falls freely at each stage and due to its “shaking” from the stage, the vibrator along the deposition surface will be displaced at each stage in the direction of the magnetic system of the separator, moving away from the vertically falling non-magnetic fraction, which ensures the necessary width of the “fan” of the separated product Therefore, the number of vertical stages of the separator is one of the main factors that determine the separation efficiency. With steps of different heights and different intensities of the magnetic field forces, it is possible to flexibly form a topology of magnetic field forces in a wide range in accordance with specific technological requirements.A vertical multi-stage magnetic system with a large number of stages can be considered as a single-stage installed with a slight inclination to the vertical.

An even more important factor in the efficiency of separation, especially the least magnetically sensitive products, is the intensity of the magnetic forces of the field of the permanent magnet system in the working volume of the separator. When separating such products, it is impossible to create sufficient magnetic forces in the entire volume along a flat magnetic system. Therefore, the topology of the magnetic forces should be inhomogeneous with the concentration of the magnetic field in some (working) areas due to the weakening of the magnetic field in other (non-working) areas. Accordingly, the streams of the separated product must be uneven across the width of the magnetic system, which is achieved by passing the product along separate vertical troughs installed precisely in the zones of action of maximum magnetic forces.

According to the invention, the proposed magnetic system complies with the high energy flat permanent magnets (Nd-Fe-B) mounted on a common magnetic shunt - magnetic core with alternating horizontal polarity of the magnets and their vertical unipolarity. The greatest magnetic forces in this magnetic system arise in the vertical zones of change in the polarity of the magnets.

The troughs through which the product stream is fed for separation are installed precisely in these zones, thereby achieving the most efficient extraction of its weakly magnetic fraction from the total product stream.

A magnetic system with a concentration of magnetic field forces in narrow vertical zones can also be made of flat plate permanent magnets mounted vertically one after another in a row and separated by a plate-shaped ferromagnetic concentrator, to which the permanent magnets are adjacent with their same poles. In a magnetic separator with such a magnetic system, vertical zones with a concentration of magnetic forces arise along ferromagnetic concentrators on each of the two opposite symmetrical sides of the magnetic system. This makes it possible to perform the separator symmetrically double-sided, that is, with the product being fed to the separation from two opposite sides, which increases the separator performance and optimizes the use of magnetic energy of permanent magnets in this type of magnetic system.

The essence of the proposed invention is illustrated by the following graphic materials.

Figure 1 shows a longitudinal section of a single-stage separator with one-sided supply of the product.

Figure 2 shows a cross section of a single-stage separator with one-sided supply of the product.

Figure 3 shows a longitudinal section of a device for slowing down the rate of fall of a product made in the form of thin non-magnetic strings.

Figure 4 shows a longitudinal section of a multi-stage separator with one-sided supply of the product.

Figure 5 shows a cross section of one of the stages of a multi-stage separator with one-sided supply of the product.

Figure 6 shows a vertical scan of the magnetic system of a multi-stage separator with one-sided supply of the product.

7 shows a longitudinal section of a single-stage separator with two-sided supply of the product.

On Fig shows a cross section of a single-stage separator with two-sided supply of the product.

Figure 9 shows a longitudinal section of the magnetic system of a single-stage separator with two-sided supply of the product.

Figure 10 shows a longitudinal section of a multi-stage separator with two-sided supply of the product.

Figure 11 shows a cross section of one of the stages of a multi-stage separator with two-sided supply of the product.

On Fig shows a vertical scan of the magnetic system of a multi-stage separator with two-sided supply of the product.

On Fig shows a longitudinal section of a device for slowing down the rate of fall of the product in the form of thin non-magnetic plates tilted to the vertical and to each other.

The proposed magnetic separator in a single-stage execution with one-sided supply of the product (Fig. 1, Fig. 2, Fig. 3) includes a feeder for feeding the product 1 (Fig. 1, Fig. 3), a device for slowing down the fall rate of the product 2 (Fig. 1, Fig. .2, Fig. 3) located inside the product guide of the chute 3. The device for slowing down the rate of fall of the product 2 is made of non-magnetic strings stretched normal to the surface of the permanent magnets. The magnetic system is made of flat permanent magnets 4 mounted vertically on a magnetic shunt 5 with alternating horizontal polarity of the poles. The surface of the permanent magnets (FIG. 1, FIG. 2) is covered by a thin-walled non-magnetic sheet 6, connected to the vibrator 7 with the possibility of vertical displacements of the sheet 6 due to vibration in the guide rollers 8. The separators 9 are installed with the possibility of dividing the product along the receivers of the magnetic fraction 10 and non-magnetic fractions 11.

With the multi-stage execution of the separator (Fig. 4, Fig. 5, Fig. 6), the permanent magnets 12 are mounted with vertical steps, which are fastened to a magnetic shunt 13 common to all stages. The device for slowing down the fall rate of the product 14, as well as the guide chute 15, also perform respectively multi-stage. The surface of the permanent magnets is covered with a thin-walled non-magnetic sheet 16.

A magnetic separator with two-sided supply of the product (Fig. 7, Fig. 8) consists of two identical halves with a vibrator 7 common to both halves and a magnetic system (Fig. 9), which is made of flat permanent magnets 17 separated by a plate-shaped ferromagnetic hubs 18, to which the permanent magnets 17 are adjacent to the same poles. The magnetic system 17, 18 creates identical magnetic fields in each of the halves of the magnetic separator symmetrical with respect to the magnetic system.

The magnetic separator with two-sided supply of the product can also be multi-stage (figure 10, figure 11). The difference between the design of such a separator from a single-stage (Fig. 7, Fig. 8) is reduced to multistage execution of magnetic concentrators 19, permanent magnets 20 and thin-walled non-magnetic sheets 16 connected to a vibrator 7.

The device for slowing down the falling speed of the product shown in FIG. 13 consists of thin-walled non-magnetic plates 21. The plates 21 are mounted in the grooves 3 symmetrically relative to the vertical plane of symmetry of the grooves 3 and at an angle to each other with the possibility of pouring the product from the plates placed on one side of the symmetry plane , on plates placed on the other side of this plane.

The proposed method for magnetic separation of finely dispersed weakly magnetic bulk products is implemented on a magnetic separator, which operates as follows.

The separated product from the feeder 1 (Fig. 1, Fig. 4, Fig. 7, Fig. 10) is fed by gravity under the influence of gravity Fg into the troughs 3, 15 to the device for slowing down the rate of fall of the product 2, 14. If the device for slowing down the rate of fall of the product 2 is made in the form of stretched strings (Fig. 3), then the slowdown of the product fall occurs due to the collision of falling particles of the product with tensioned strings. The decrease in the fall rate of the product is determined by the density and number of strings in the grooves 3, 15. Collision of the product with the strings breaks, loosens and disperses the falling product and puts it into a free-weighed state, in which friction (mechanical interaction) between magnetic and non-magnetic particles of the product practically disappears. Since the grooves 3, 15 are installed vertically along the magnetic system in the zones of the greatest influence of magnetic forces Fm, the magnetically susceptible particles that move in the grooves 3, 15 under the influence of magnetic forces deviate from the vertical path and approach a thin-walled non-magnetic sheet 6, 16. When this part of the magnetically susceptible particles, which did not reach sheet 6, 16 and did not settle on it, then falling down, falls through the product dividers 9 into the receiver of the magnetic fraction 10. The second part of the magnetically susceptible particles, which settled on the surface of the non-magnetic sheet 6, 16, under the action of the vibrator 7 as a result of the vertical vibration of this sheet, freely fixed in the rollers 8, "slides" vertically to the next step and finally through the separator 9 also enters the receiver of the magnetic fraction 10. As for the non-magnetic fraction of the product, then particles of this fraction, which are affected only by gravity Fg, fall vertically and through the separator 9 fall into the receiver of the non-magnetic fraction 11.

When using the separator device for slowing down the rate of fall of the product of FIG. 13, a decrease in the rate of fall of the product occurs as a result of pouring the product from the plates 21 onto the same plates placed on the other side of the plane of symmetry of the grooves 3. A decrease in the rate of fall of the product on the plates 21 can be achieved by changing the angle the inclination of the plates, by changing the vertical distance between adjacent plates and the length of these plates.

In a multi-stage magnetic separator (Fig. 4), the product is fed to the first stage of separation from the feeder 1. Subsequently, the product moves in the working volume of the first stage of the permanent magnet system 12 with the vibrator 7 turned on. In this case, the non-magnetic fraction of the product moves (falls) vertically, and the trajectory of the magnetic fraction deviates from the vertical under the action of the magnetic force Fm in the direction of the magnetic system of the first stage. Reaching the deposition surface (non-magnetic sheet 16), the particles of the magnetic fraction can either settle on the non-magnetic sheet 16, which can be influenced by the vibrational forces of the vibrator 7, or “fly” past the first stage to the next second degree of separation. gets to the second stage of separation. The magnetic fraction "deposited" on the surface of the non-magnetic sheet 16 at the first stage of separation under the influence of vibration forces "slides" down this sheet and, falling away from it, pop At the next stages, the process proceeds similarly. Since the grooves 15 of the magnetic separator (Fig. 4) are also multi-stage with their expansion as they move from one stage to the next, the width of the “fan” of the separated product increases accordingly its exit from the zone of action of magnetic forces, the width of the “fan” being determined by the horizontal shift of the next steps relative to the previous ones and the total number of steps. To optimize the magnetic system under the conditions of a specific product separation process, it is advisable to use each of the steps with different heights and with different topologies of magnetic field strengths.

With a large number of steps of the proposed magnetic separator, it can be considered as single-stage with a slight angle of inclination relative to the vertical.

For all variants of the proposed magnetic separator, its performance is determined both by the rate of fall of the product, and by the number of vertical zones of action of maximum field forces, that is, the width of the magnetic system and the cross-sectional area of the grooves. The lower the magnetic susceptibility of the particles of the separated product, the smaller the indicated area. The cross-sectional shape of the gutters is most often chosen experimentally to separate a particular product.

When using an electric vibrator in the separator, to increase the efficiency of its action, it is advisable to vibrate the forces that act vertically “up”, to form with a smaller amplitude and a larger value, and “down” - on the contrary (with a larger amplitude and a smaller value). Modern electronic controls for electromagnets allow, in principle, to implement any sequence diagram of the operation of electric vibrators.

Implementation of the proposed method and magnetic separator can increase the efficiency of separation of finely dispersed weakly magnetic bulk products while reducing the mass and overall dimensions of the magnetic separator and, as a result, reduce its cost.

The source of information

1. V.G. Derkach, I.S. Datsyuk. “Electromagnetic enrichment processes”, Sverdlovsk, “Metallurgizdat”, 1947, p.66-68.

Claims (10)

1. A method of magnetic separation of finely dispersed weakly magnetic bulk products, comprising supplying a separated product along a vertically mounted magnetic system that generates magnetic field forces directed normal to the working surface of the magnets, magnetic separation of the product into magnetic and non-magnetic fractions, distribution of the separated product along its magnetic receivers and non-magnetic fractions, characterized in that the product is fed in parallel streams along the vertical zones of action of maximum magnesium forces, while each stream is fed through a device for slowing down the free fall of the product, and the vertical movement of the magnetic fraction of the product deposited on the deposition surface along the working surface of the system of permanent magnets is carried out using a vibrator. 2. The method of magnetic separation according to claim 1, characterized in that the product is dropped along a multi-stage magnetic system, each of the subsequent stages of which is shifted horizontally relative to the previous stage in the direction of product fall. 3. The method of magnetic separation according to claim 2, characterized in that the product is dropped relative to the steps of the magnetic system of different heights and different intensities of the magnetic field strengths. 4. A magnetic separator, including a feeder for the separated product, a vertically mounted magnetic system that creates magnetic field forces directed normal to the working surface of the magnets, separators and receivers of magnetic and non-magnetic fractions of the product, characterized in that the separator is supplemented by a vibrator connected to the deposition surface , and devices for slowing down the rate of fall of the product, which are located in thin-walled non-magnetic product flow guides installed vertically in the poppy zones imalnogo action of magnetic field strength and a magnetic system made of permanent magnets with alternating vertical zones of maximum and minimum of the magnetic field strength. 5. The magnetic separator according to claim 4, characterized in that the device for slowing down the rate of fall of the product is made in the form of stretched thin non-magnetic strings installed perpendicular to the working surface of the magnets. 6. The magnetic separator according to claim 4, characterized in that the device for slowing down the rate of fall of the product is made in the form of thin non-magnetic plates inclined to the vertical and to each other, mounted stepwise one under the other with the possibility of pouring the product from the plate onto the plate when it falls under the action gravity. 7. The magnetic separator according to claim 4, characterized in that the magnetic system of the separator is performed in the direction of multi-stage product movement with a horizontal offset of each subsequent stage relative to the previous one. 8. The magnetic separator according to claim 7, characterized in that the steps of the magnetic system are of different heights and with different magnitudes of the magnetic field strengths. 9. The magnetic separator according to claim 4, characterized in that the magnetic system of the separator is made of plate permanent magnets placed on a ferromagnetic shunt with alternating horizontal polarity, and the gutters are installed along the separation zone of the polarity of the permanent magnets. 10. The magnetic separator according to claim 4, characterized in that the magnetic system of the separator is made of flat plate permanent magnets mounted in a row one after another in the horizontal direction and separated by plate ferromagnetic concentrators to which the permanent magnets are adjacent with their same poles, and gutters are installed along ferromagnetic concentrators from two opposite sides of the magnetic system.

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