SU5688A1 - Magnetic separator for ores - Google Patents

Description

The present invention relates to a magnetic separator consisting of two or more mounted on a common axis, at a certain distance from each other, disk-shaped poles, surrounded by a drum diverting magnetic material. Each two adjacent disk poles form a magnetic field with their edges facing each other, and in the already known separators of this kind, the edges of the poles run parallel to each other, i.e. the distance between the edges of the poles remains the same at all points of the circumference of the pole disks. With these already known separators, the magnetic cores next to each other, parallel to the axis of the separator, sit on the ring-shaped poles, and the device can be able to excite the poles around the circumference of the drum with different strengths, so that different separating or selecting material zones. The use of several magnetic cores, not to mention the considerable energy consumption and the complexity of manufacturing and handling such a magnetic separator, is an inconvenience in that, created by differently excited magnetic cores, the separating zones of different strength go from one to another. , without any or all of them with barely perceptible manifestations of the difference in the strength of these zones; This is due to the fact that the made (each in the form of an iron body, which is a single connected whole), pole disks on which the three magnetic cores sit, act as

core closing the power lines.

According to the present invention, in a magnetic field formed (between facing each other of adjacent pole disks), a different magnetic field in different places is created due to the fact that the distance between the edges of the poles encircled by the poles increases or decreases in the direction of rotation of this drum. If the specified distance in the direction of rotation of the drum increases, then the force of the field between the marked edges decreases. On the contrary, the strength of this field increases if the distance between the edges of the poles in the direction of rotation of the drum decreases. For the purpose of such a change in the distance between the edges of the poles, it is possible, for example, to make the edge of the pole creating a field inclined to a plane perpendicular to the axis of the drum. Due to the possibility of arbitrarily choosing the magnitude of the slope of the pole edge, as well as the length of these pole edges, it is possible to give respectively arbitrary dimensions to the lengths of the sections where the field increases or diminishes, and these sections can be placed anywhere on the floor. Thus, it is possible, under all conditions, to create in the field of increasing or decreasing force all the required greater or lesser changes in the degree of intensity of this force, especially having in mind that with a change in the size of the air gap It is inversely proportional to the square of the distance between the poles.

If, in a similar way, we create, for example, a field of decreasing force and feed the processed material to this field on the upper part of the drum, then at the point of supply, where the field has the greatest force, all magnetic material will be held by the drum, all non-magnetic material will discarded. At the same time, the circumferential speed can be communicated to the drum, comparatively significant, since the most stressed part of the floor can be adjusted in accordance with the composition of the material being processed. The magnetic material adhered to the drum then passes through further weaker parts of the same floor, where various magnetic types of material are shed depending on the strength of the floor, and in these parts too the tension and strength can be adjusted the same way, as in the part of the floor, having the highest power. With such a separation of raw material into different grades within the same sex, diminishing force is obtained, especially when separating fine-grained ores, due to the greater circumference of the drum speed, greater productivity with simultaneous very fine material separation. The latter is explained by the fact that the high circumferential speed of the drum movement favors fineness or sharpness of separation, since, despite its high productivity, the processed material can be fed for the separation operation in the form of a thin layer. As a result, the grains of the non-magnetic material are not covered by the grains of the magnetic material, and are separated without a residue by the action of significant centrifugal force.

By reducing the mutual distance between the two edges of the poles covered by the reels facing each other, an increasing force field is created. As a result, a better separation of the coarse material is facilitated and achieved. When leading to the field of raw material at the top of the drum, in the place where the field has the least strength, the weight of the larger

pieces of material act in the same direction as magnetism, i.e. enhances the effect of this part of the floor. Due to the rotation of the drum, these pieces of material are gradually brought to such a place where the effect of the weight no longer coincides with the magnetic attraction, since this attraction in the named place already acts approximately horizontally, while the force of gravity remains directionally vertical. In order for the force of gravity to not prevail over the force of the magnetic voltage and that the pieces of magnetic material do not begin to separate too early, it is necessary that the strength of the magnetic field in this place (and, in general, in the direction of rotation of the drum) increase. According to the invention, this increase in the strength of the field in the places determined and depending on the type of material being processed, and to the extent required, is achieved by the fact that the distance from each other of the edges of the poles is adjusted accordingly.

FIG. 1 of the drawing shows a side view of a drum separator with fields whose strength, due to a corresponding increase or decrease in the distance between the edges of the poles, decreases or increases, with the drum itself shown in longitudinal section; in fig. 2 is a transverse section of the drum separator along the line AB of FIG. one; in fig. 3- another embodiment of the drum trap in longitudinal section; in fig. 4 is another form of embodiment of the drum separator, partly in a longitudinal section, partly in a side view; in fig. 5 is a cross-sectional view of the drum separator of the C-D of FIG. four; in fig. B-9 illustrate the special possibilities of using a drum separator, in various embodiments shown in the cuts according to the relevant cuts; in fig. 10 and 11 -

two forms of implementation of attracting pole edges.

On the axis a, there are disk poles b, which during operation of the separator remain stationary and between which windings c are located. The interacting edges of the discs are in the form of sharp edges d. The edges d facing each other of each two adjacent disks form a magnetic field, the intensity of which is increasing or decreasing due to a corresponding decrease or increase in the distance of the edges of the poles from each other. All disk poles are surrounded by a common non-magnetic rotating drum for diverting the material to be separated.

The supply of the processed material, with the forms of execution, according to FIG. 1 - 5, occurs at the top of the drum. A decrease or increase in the distance between the edges of the disk can occur gradually or in steps.

Since with different types of ore the danger of premature rejection of the magnetic material may occur earlier, then later, the places of the floor in which its strength increases or decreases can be distributed in different ways. For this purpose, the poles can be made to rotate, individually or in pairs, around their axis a, so that the floor of an increasing or decreasing force can, either individually, be positioned arbitrarily with respect to the location / material being processed.

Rearranging each field separately is particularly convenient when several varieties of material must be processed in parallel by the same magnetic separator, since then, by appropriately rearranging individual fields in the direction of rotation of the drum, it is possible to measure their strength with magnetic properties. appropriate variety

material. Swivel reinforcement of disk poles on its axis can be made in various ways, for example, as shown in FIG. 3, by cutting a screw thread g both on the axis and in the holes of the discs.

According to FIG. 4 and 5, the disks are provided around their circumference with special pole tips h, which, for the purpose of changing the field strength, can be moved in the axial direction. The increase in the tension of the floor occurs in this case in steps, and in each individual step can be adjustable independently of the other.

Such pole tips can also be arranged so that they can move in the radial direction; In this way, it is possible to increase or decrease the distance of the pole pieces from the outer drum, and consequently, weaken or increase the attraction exerted on the magnetic material.

The particular application of the proposed separator is shown in FIG. b-8. In this case, the supply of the processed material occurs under the drum e, so that the magnetic material is removed from the non-magnetic by removing it upwards. In this case, the field force should decrease in the direction of rotation of the drum. Meanwhile, the supply of materials does not occur in the same, but in the opposite direction with respect to the movement of the material already selected. Due to this, in conjunction with an increase in the force of the floor in the direction of material supply, the following is achieved. In the weakest part of the floor, which the material to be processed first comes in contact with, the magnetic material is removed from it and strongly attracted to the drum, in the most powerful part of the k, the floor is then removed and the magnetic material is weakly attracted to the drum. As the drum moves in the direction opposite to the movement of the input material, the weakly attracted later magnetic material falls first on the drum and then a layer of strong magnetic material is deposited on this layer. Thus, the material of two varieties of different magnetic permeability is obtained in the form of two separate layers lying on top of each other, with the strongly magnetic material lying on top holding the weakly magnetic material located beneath it on the drum e.

The removal of the magnetic material from the body or drum that selects it may be either in such a way that the material of either type is attracted simultaneously, as is meant by the device of FIG. 6 and 7, or for each variety separately, as shown in FIG. 8 and 9. For this latter purpose, a magnetic roller / g (or some other magnetic device) can be provided, removing from the drum and discharging a separate layer of highly magnetic material lying on top, while weakly magnetic material is dumped from the same drum myself.

To regulate the magnetic field at the point of removal of a highly magnetic material so that this material can be removed as completely as possible, an adjustable pole tip can be arranged at the appropriate place, as shown in FIG. 9.

The pull edges d, as shown in FIG. 1 and 4 are pointed. In order to achieve greater dispersion of the lines of force, it is possible to arrange one or several pointed edges or the like between the two edges of each pole, according to FIG. 10 and 11.

The subject of the patent.

1. Magnetic separator for ores, consisting of two or HEXOM seated on a common shaft, at some distance from each other, plate-shaped disk electromagnets with edges protruding at one of the ends forming the pole tips, the magnetic field between which varies in the direction of rotation of the drum, covering the above-mentioned disk electromagnets, characterized in that the width of the edges forming the pole tips, measured parallel to the axis of the drum, increases or decreases in the direction of rotation audio the drum (Figs. 1, 2, 3, 4, 5).

2. The form of the magnetic separator indicated in claim 1, wherein the disk-shaped electromagnets, individually or in pairs, are made freely rotating on the axis in order to allow the individual discs to be moved to enhance or weaken the magnetic field (Fig. 1, 2, 3, 4, 5) relative to the place of supply of material.

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