UA24449U - Magnetic two-stage drum separator for benefication of dry friable slightly magnetic ores - Google Patents

Abstract

A magnetic two-stage drum separator for benefication of dry friable slightly magnetic ores includes a housing, in which in the direction of displacement of ore, which is subject to benefication, two magnetic drums of different magnetic intensity are mounted at different levels and after each other, the magnetic system of each of which is fixed, and is placed along the arc of 90 DEGREE -180 DEGREE inside thin-walled nonmagnetic cylinder installed with possibility of rotation and consisting of separate permanent magnets of alternate polarity in the direction of rotation of thin-walled cylinder, and a magnetic system of the second magnetic drum is made with greater intensity of magnetic forces of field on its working surface, than on the working surface of the first drum. The magnetic system of each of the magnetic drums is made from permanent magnets of high energy, the width of poles of which decreases in each of the magnetic drums in the direction of their rotation, in this case the width of the first pole of magnetic system of the first magnetic drum is greater than the width of the first pole of magnetic system of the second magnetic drum.

Description

Description of the invention

The useful model refers to the technology of magnetic beneficiation of dry loose weakly magnetic ores and can be used in the mining industry, for example, to beneficiate oxidized iron ores.

The well-known two-stage roll electromagnetic separators are designed for the enrichment of loose weakly magnetic ores 11. The magnetic field in such separators is excited by powerful electromagnets, which provide a magnetic induction value of В-(1.2-1.7) T on the teeth of the rolls. At such values of induction, the magnetic field intensity gradients and, accordingly, the magnitude of the magnetic field forces on the roll teeth allow 70 to carry out enrichment of weakly magnetic ores and separation of other weakly magnetic products on roll separators. Therefore, roll separators |(1| are the main type of magnetic separators in the technology of beneficiation of weakly magnetic ores.

Roller separators (1), which can be considered as functional analogues of the proposed magnetic double-cascade drum separator, have a number of significant disadvantages. 12 Alternating change of the largest magnetic field forces (on the protrusions of the roll teeth) and the smallest magnetic field forces (in the grooves between the roll teeth) does not ensure the creation of a continuous barrier of the largest magnetic forces along the axis of the roll on the path of movement of the ore to be enriched. As a result, in the process of beneficiation of loose ore, some of it moves in the grooves between the teeth of the roll in the area of action of such minimal forces, which are not sufficient for the successful beneficiation of weakly magnetic ore.

The presence of large magnetic forces of mutual attraction between the rolls and the poles of the electromagnets leads to rapid wear and tear of ball bearing supports, which is also a significant structural drawback of roll separators (Fig. 11.

The presence of a relatively small air gap between the rolls and the poles of the electromagnet limits the height of the ore layer to be enriched, thus causing the low specific productivity of the separator. In addition, electromagnetic excitation of the magnetic field requires additional costs of electricity, costs of switching and protection equipment and cable lines.

A two-stage drum magnetic separator |2) is known, which implements a method of two-stage enrichment of strongly magnetic ores. Magnetic separator |2| includes two magnetic drums, which are installed at different levels and one after the other in the direction of movement of crushed loose ore, which is subject to magnetic enrichment. Magnetic drums are mounted in one housing, each of which is equipped with ore feeding devices on their working surface, ore flow distributors in the process of its magnetic enrichment and receivers from separated ore. Each of the drums has its own individual electric drive. Both magnetic drums include thin-walled non-magnetic cylinders, inside which a fixed magnetic system is installed, consisting of individual ferritebarium permanent magnets fixed on a ferromagnetic shunt. Each of the magnets is magnetized 3° radially relative to the working surface of the drum, and the magnets themselves are installed inside the drum in an arc with alternating polarity in the direction of ore movement. The intensity of the magnetic field on the surface of the first magnetic drum (H.--8OkA/m) is less than the corresponding intensity on the second magnetic drum (H2-100kKA/m). The speed of rotation of the first drum is greater than the speed of rotation of the second drum. "

The principle of operation of the two-stage drum magnetic separator |21 is based on the action of the magnetic forces of the Z 40 field on the flow of loose ore moving on the surface of the moving drums. Under the action of magnetic forces, the strongly magnetic ore fraction is attracted to the surface of the drums and, due to the rotation of the drums, is carried out of the zone of action of the magnetic forces, and further, under the action of gravity and external forces, it is detached from the surface of the drums and enters the concentrate receivers. Even in the area of ore movement in the zone of action of the magnetic forces of the field, the non-magnetic (and the least magnetic) fraction of the ore, under the action of internal and gravitational forces, falls into the receivers of the non-magnetic fraction 45 (tails). Part of the ore that moves on the surface of the first drum and is a mixture of non-magnetic fraction and "poor" inclusions (by-product) falls on the lower drum, where it is also separated into concentrate, by-product and tailings.

The disadvantage of the two-stage drum separator |), which is accepted as a prototype, is its unacceptable efficiency for the enrichment of weakly magnetic ores, which is caused, first of all, by the low "" 20 magnetic energy of the ferritebarium permanent magnets, which make up the magnetic system of the separator (21, and as a result of this - obtaining such low values of magnetic field forces in the working volume of the separator, which are not enough for the enrichment of weakly magnetic ores.

The development of high-energy permanent magnets (Ma-BRe-V) allows to create magnetic systems of separators on permanent magnets with the magnitude of magnetic induction and magnetic forces commensurate with the corresponding values obtained on roll electromagnetic separators, which opens the way to the creation of drum magnetic separators for the enrichment of weakly magnetic rood.

The basis of the useful model is the task of improving the two-stage drum magnetic separator for its use in the technological process of beneficiation of dry loose weakly magnetic ores.

The task is solved by the fact that the magnetic two-cascade drum separator for the enrichment of 60 dry loose weakly magnetic ores, which includes a case in which two magnetic drums of different magnetic intensity are installed at different levels and one after the other in the direction of movement of the ore to be enriched, a magnetic system each of which is stationary, placed along the arc 9092-1802 inside a thin-walled non-magnetic cylinder installed with the possibility of rotation and composed of separate permanent magnets of alternating polarity in the direction of rotation of the magnetic drum, and the magnetic system of the second magnetic drum 65 is made with a greater intensity of magnetic field forces on its working surface than on the working surface of the first drum. The magnetic system of each of the magnetic drums is made of high-energy permanent magnets, the width of the poles of which decreases in each of the magnetic drums in the direction of their rotation, while the width of the first pole of the magnetic system of the first magnetic drum is greater than the width of the first pole of the magnetic system of the second magnetic drum.

The problem is solved by the fact that the permanent magnets of the first and second magnetic drums are magnetized radially relative to the thin-walled non-magnetic cylinder.

The problem is solved by the fact that the permanent magnets of the second magnetic drum are magnetized tangentially to the thin-walled non-magnetic cylinder, and the magnets themselves are separated in a circle by 7/0 plate or wedge-shaped ferromagnetic inserts, hubs, to which the magnets are attached by the poles of the same name.

The task is solved by the fact that each of the magnetic drums is set in motion by an individual speed-regulated electric drive.

The problem is solved by the fact that the diameter of the first magnetic drum is larger than the diameter of the second /5 magnetic drum when the speed of rotation of the first drum is lower than the speed of rotation of the second drum.

The implementation of the magnetic systems of both magnetic drums from permanent magnets of high energy (Ma-Re-B) allows in the proposed two-stage separator to increase the value of magnetic induction on the working surface of the drums several times and, accordingly, to increase the magnetic field strength by an order of magnitude (compared to the separator - prototype |2I ). The obtained magnitudes of magnetic field forces (GE m-1013 dg/mU) are sufficient for effective beneficiation of weakly magnetic ores. But in itself, the simple replacement of low-energy permanent magnets with high-energy magnets (Ma-Re-B) in the magnetic systems of the separator |21 is not effective enough, if at the same time as such a replacement of the material of the magnets, the very design of the magnetic systems interconnected in one is not changed technological process of two-stage beneficiation of dry loose weakly magnetic ores. The wide range of magnetic susceptibility values of weakly magnetic ores (for example, crushed oxidized iron ores), which is due to the size of individual ore grains and the heterogeneity of growths (ore and non-ore grains), requires the corresponding heterogeneity of the magnetic field in which the ore moves during its magnetic enrichment.

The conducted experimental studies showed that in order to achieve the most effective enrichment of oxidized iron ores, the magnetic system of each of the drums of the two-stage separator should be performed with a decrease in the width of the poles in the direction of movement of the ore in each of the magnetic drums with a greater width of the first pole of the first magnetic drum compared to the second drum. To do this, the separator is made with a larger diameter of the first magnetic drum than the diameter of the second drum. "AND

The speed of rotation of the second drum is set to a greater value than the first in order to obtain greater force on the second drum. In order to achieve even greater inhomogeneity of the topology of the magnetic M field of two magnetic drums, in a useful model, the magnetic system of the second magnetic drum "I" is proposed to be performed in two variants. According to the first option, the magnetic system is performed traditionally for drum separators with radially magnetized poles installed on a ferromagnetic shunt. According to the second option, in order to achieve the greatest magnetic forces on the surface of the magnetic system, the magnets are magnetized tangentially to the surface of the drum, installed in an arc and separated from each other by plate or wedge-shaped concentrators. It is in the zone of the outer surface of the concentrators that the greatest precipitating magnetic forces are obtained. -- с Such a magnetic system is most effective at enriching a small layer of ore flow, especially ore with the lowest magnetic susceptibility. "» The great heterogeneity of magnetic and other properties (for example, moisture) of the ore to be enriched requires the ability to adjust the beneficiation mode both when the separator is put into operation and when it is readjusted in connection with a change in the composition of the ore already during the operation of the separator For this purpose, in addition to the traditional reconfiguration of the separator with a system of ore flow distributors in the separator, it is proposed to additionally optimize the beneficiation process by independently changing the rotation speed of each of the separator drums, for example, due to the electric drive of each of them from "" speed-regulated asynchronous motors.

Figure 1 shows the structural diagram of the magnetic two-stage drum separator. Fig. 2 shows a cross-section of the magnetic system of the first magnetic drum. (Che) Figure 3 shows a cross-section of the magnetic system of the second magnetic drum with radially magnetized permanent magnets.

Figure 4 shows a cross-section of the magnetic system of the second magnetic drum with tangentially magnetized permanent magnets.

Magnetic double-cascade drum separator for the enrichment of dry loose weakly magnetic ores (Fig. 1) includes a body 1, in which two magnetic drums 2 and 3 are installed one after the other in the direction of movement of the ore to be enriched at different levels. The first magnetic drum 2 includes a thin-walled non-magnetic cylinder 4 is installed with the possibility of rotation, inside which a magnetic system 5 is fixed. The magnetic system bo 5 consists of high-energy permanent magnets (Ma-Re-V), magnetized radially relative to the thin-walled cylinder 4 and installed with alternating polarity in the direction of ore movement .

The second magnetic drum C includes a magnetic system 6 composed of permanent magnets of high energy, placed inside a thin-walled cylinder 7 installed with the possibility of rotation.

The separator is equipped with a system of distributors 8 of the flow of ore in the process of its enrichment and a system 65 of distributors 9 of enriched ore with vibratory feeders 10, 11 of the first and second drums.

The magnetic system of the first magnetic drum 2 (Fig. 2) includes permanent magnets 12 made with different widths of poles (from the largest width thu to the smallest width x3). Permanent magnets 12 are installed on the ferromagnetic shunt 13.

The second magnetic drum C (Fig. 1) can be performed in two versions. According to the first embodiment, the magnetic system 6 (Fig. 1) is structurally similar to the magnetic system of the first drum (Fig. 2), but with a smaller width of the poles of the magnets 14 (Fig. 3) (iii Fig. 2 » x Fig. 3). Magnets 14 are magnetized radially and mounted on a ferromagnetic shunt 15. The diameter O" (Fig. 3) of the second magnetic drum is smaller than the diameter O.4 (Fig. 2) of the first magnetic drum. According to the second version of the magnetic system of the second magnetic drum, the permanent magnets 16 (Fig. 4) are magnetized tangentially to the surface of the thin-walled cylinder 17 (Fig. 4). 70 Wedge-shaped or plate ferromagnetic concentrators 18 are installed in a circle between the poles 16, to which the magnets are attached by the poles of the same name. Permanent magnets 16 and ferromagnetic concentrators 18 are fixed on a stationary non-magnetic hollow cylinder 19.

The proposed magnetic separator works as follows: dry loose weakly magnetic ore is fed by a vibratory feeder 10 (Fig. 1) to the surface of the first magnetic drum 2, which rotates and moves 75 on its surface the flow of ore in the zone of action of magnetic forces.

Under the influence of magnetic forces, the most magneto-susceptible ore particles, overcoming the centrifugal force, are attracted to the surface of the drum and are carried out on this surface due to the rotation of the drum from the zone of action of magnetic forces, and further, under the influence of centrifugal and gravitational forces, they are transported through the ore distributors 8 in the ore concentrate receiver. Under the action of centrifugal and gravitational forces, the non-magnetic product is sent to the receivers of the non-magnetic product (tails) through the system of distributors 8. Magnetic particles of ore with a lower magnetic susceptibility of the body (industrial product) are fed by a system of distributors 8 (Fig. 1) to the surface of the vibratory feeder 11 (Fig. 1), from where they are fed to the surface of the second magnetic drum, which rotates faster than the first magnetic drum (creating larger centrifugal forces) and has a stronger magnetic system. The process of beneficiation of ore (industrial product) on the second magnetic drum is carried out similarly to the process on the first drum, but with the second forces of the magnetic field, centrifugal forces and the layer of ore on the surface of the drum. At the exit of the second drum, three products are received again (concentrate, industrial product and non-tails), the distribution of which is carried out by distributors 9 (Fig. 1).

The proposed two-stage magnetic separator was experimentally studied at the "Prodecologia" scientific research center (Rivne) and showed its efficiency in the process of beneficiation of weakly magnetic iron ores. Gee!

The results of the research are shown in the table:

Chalet Class Exit, Contents Exit, Contents |Removal. Input, Content |Extraction, |Exit, Content |Extraction, « enrichment | G/h of coarseness, 96 Ee, 96 95 Ee, 9696 96 Be, 96195 or Ee, 9696 » VN a sho as s; NI o s V NM 5 (purification of industrial product - from the 1st stage);"

The most promising field of use of the developed two-stage separator is the processing of oxidized iron ore dumps.

GF Source of information: 1. V.A. Gramm, K.V. Nikolaenko, A.G. Fedorov "Machinist of magnetic separators", Moscow, "Nedra", 1990, page 82. drive 2. V.A. Gramm, K.V. Nikolaenko, A.G. Fedorov "Machinist of magnetic separators", Moscow, "Nedra", 1990, p. 44. drive 50

Me)

Claims (5)

The formula of the invention 1. Magnetic double-cascade drum separator for beneficiation of dry loose weakly magnetic ores, which 59 includes a housing in which two magnetic drums of different magnetic intensity are installed one after the other at different levels in the direction of movement of the ore to be beneficiated, the magnetic system of each of which fixed, placed along the arc 9092-1802 inside a thin-walled non-magnetic cylinder installed with the possibility of rotation and composed of separate permanent magnets of alternating polarity in the direction of rotation of the thin-walled cylinder, and the magnetic system of the second magnetic drum is made with a greater intensity of magnetic field forces on its working surface than on the working surface of the first drum, which differs in that the magnetic system of each of the magnetic drums is made of high-energy permanent magnets, the width of the poles of which decreases in each of the magnetic drums in the direction of their rotation, while the width of the first pole of the magnetic system of the first magnetic drum greater than the width of the first pole of the magnetic db of the second magnetic drum system. 2. The magnetic separator according to claim 1, which differs in that the permanent magnets of the first and second magnetic drums are magnetized radially relative to the thin-walled non-magnetic cylinder. Q. The magnetic separator according to claim 1, which differs in that the permanent magnets of the second magnetic drum are magnetized tangentially relative to the thin-walled non-magnetic cylinder, and the magnets themselves are separated in a circle by plate or wedge-shaped ferromagnetic inserts - hubs, to which the magnets are attached by the poles of the same name. 4. The magnetic separator according to claim 1, which differs in that each of the magnetic drums can be driven by an individual speed-regulated electric drive. 5. The magnetic separator according to claim 1, which differs in that the diameter of the first magnetic drum is greater than 7/o the diameter of the second magnetic drum, and the speed of rotation of the first magnetic drum is less than the speed of rotation of the second magnetic drum. with o (o) « « « p - I.Y and? име) ш» ш» ш» 3e) 60 b5