DE162194C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

Magnetic ore separation devices are known in which the pole pieces are used to excavate the magnetic particles Magnets that serve the good are not flat 5 or smooth cylindrical, but somehow broken Represent surfaces that terminate in points or sharp edges. The exit of the magnetic lines of force takes place preferentially at these peaks, so that there

ίο the magnetic particles strongest, of the notches located between the tips are only weakly attracted. The magnetic material, over which such pole pieces rotate or which is brought under them, thus becomes open its path is now more, now less strongly influenced, so that it is alternately influenced by that Magnet is attracted and then, following its own weight, falls back again.

As a result, it starts to oscillate, which causes any lumps to be broken up causes and prevents magnetic particles due to adhesion of non-magnetic be held back.

The invention is based on this known basic idea. Apparently the said The greater the difference between the two, the more violent and effective the oscillating motion of the magnetic particles will be the attraction of the stronger and less strong parts of the magnetic fields, and the greatest difference becomes when the attraction ceases completely in places. According to the invention, this is the case with magnetic ore separators, in which the Ore brought under magnets on a vibrating conveyor, and from these the magnetics are applied laterally discharging funds is pulled out, achieved in that the cores of the Magnets consist of individual pieces, between which air spaces are left, and which only have a magnetic connection to one another at one end.

The subject matter of the invention is shown in an exemplary embodiment on the drawings.

Fig. Ι is a longitudinal section of the device,

2 shows a cross section through the first magnet,

3 is a diagram of the horseshoe magnet located at the end of the gutter;

Fig. 4 shows the right end (in the sense of Fig. 1) of the device in section through.die Coil of horseshoe magnet;

Fig. 5 shows schematically the circuit of the magnets;

Fig. 6 shows the attachment of one of the magnets.

A projection 30 is attached to the frame 2, 3 of the machine and has a bolt 32 wearing. The driven shaft 13 is set by means of the crank 42 and the rod 40 (Fig. 4), which is hinged to the lower end of the inclined channel 33 in an eye 41 (FIG. 1) is, the channel 33 in a swinging motion around the bolt 32, transversely to the flow

direction of the goods. The material first passes through the funnel 60 into the box 75, to which a shaking movement is given, so that larger clumps of the material are divided and the material falls in an even, even layer on the channel 33, on which it slips down. The swaying movement of the gutter crushes any clumps of the property even more and also prevents the progress of the latter from stalling. This is how the goods are brought under the magnets. The non-magnetic eventually falls down over the end of the channel 33 into the funnel 28.

The magnets 100, 110 and 120 are located above the channel 33. There are three here as an example Magnets accepted; any number can of course be used where necessary. The former two are suspended from the angle iron frame 92, which is slotted in Approaches 91 of the supports 2 of the frame by means of screws 94 found higher or lower can be.

The magnet 100 (Figs. 1 and 2) extends extends over the entire width of the channel 33. It consists of individual rod-shaped cores 101 made of magnetic material, which together with the also made of magnetic material Brackets 102 are attached. Screws 104 connect the bracket to the frame 92. The cores 101 are surrounded by the coil 103, by which they are aroused. At the lower end the kernels are through a plate 105 made of non-magnetic material.

On one side of the magnet (left after Fig. 2) an extension piece 105 ° (Fig. 6) is off magnetic material arranged, which with a screw made of non-magnetic material on Core is attached and isolated from it.

The magnet 110 is just like the magnet 100 built, just a little stronger. In this magnet, the reference numerals are for the corresponding Divide 10 more numbers than magnet 100.

The last and strongest magnet is the horseshoe magnet 120 (Figs. I, 3 and 4). He consists like the other two magnets, made of rods 121, but which are far stronger than them Bars of magnets 100 and 110. The upper half and the lower half of the magnet, between which the channel 33 is, can be adjusted against each other, namely by means of of a joint 124, which by means of the bolts 124 "and 124 * the two Connecting halves. Stud bolts 122 and 123 hold the upper and lower halves Cores 121 together. The bars of this magnet stand together at their free ends in contact (FIG. 3), while they are otherwise separated by spaces 125 (Fig. 4). Coils 126 are used for excitation.

The ends of the upper rods 121 are closed Teeth formed (Fig. 3), so that also here as with the magnets 100 and 110 a Alternation between zones of high and low potential, but this time in the beginning mentioned known manner is achieved. As in the case of the latter magnets, the plates 105 etc., there is also a shoe here 129 made of non-magnetic material and a lateral magnetic extension piece 130 attached. The lower rods 121 also carry a toothed one by means of the screws 141 magnetic shoe 140.

The upper cores 121 of the magnet are connected by the screw 148 to the holder 147, which is adjustably fastened to the frame part 3 by means of the screw 149. The lower cores can be adjusted by means of the screw 143. Finally, the entire magnet can be adjusted in its height position with the aid of the support 144 and the bolt 124 ^s.

Two shafts 16 and 24 are mounted on the frame of the machine (FIG. 2). The main drive shaft drives the shaft 16 by means of the belt 17 and the pulley 19. Corresponding to the distances between magnets 100 and 110 and the upper end of magnet 110, belt pulleys 20 (only one is visible) are seated on this, opposite which pulleys 20 ″, 21 ″, 22 ″ on shaft 24. The belts run over these disks 20 ^, 2ΐ ^δ , 22 ^δ , in such a way that each band runs straight under the end of a magnet and is pressed down a little in the middle by the non-magnetic shoes 105, 115 and 129.

The device works in the following way:

The material flowing down from the box 75 arrives in a uniform band on the oscillating channel 33. The swaths that are formed by their oscillating movement are replaced by the magnets in front of them arranged distributor 53 (elongated, under cross bars side by side by means of screw bolts the direction of adjustable attached distribution pieces) eliminated, so that the good fed to each magnet as a uniform band covering the entire width of the channel will. Any lumps of the material are thrown up by shaking the gutter, like this that the material fed to the magnet is essentially granular everywhere.

As soon as the material comes into the field of the magnet 100, which, as mentioned, is the weakest In turn, those particles will be those which are most susceptible to magnetic action are susceptible to the belt 20 ″ and thereby to the left with reference to FIG. 2 brought where they are scraped off by the brushes 27 and in a (on the drawing not shown) funnel fall. The mag-

Netic particles pass across the channel 33 while they are being carried away the tape by virtue of the separate arrangement of the core pieces 101 zones of different intensities. This has an oscillation of the particles towards and away from the belt during the. Movement with the tape to As a result, the separation of the magnetic particles from the non-magnetic ones is perfected by adding any remaining particles Lumps are thrown up and opened up for the action of the magnets. By shaking the gutter, at the same time even the beards hanging on the ribbons were shaken, so that some were carried away non-magnetic particles are shaken out of the whiskers. When the good the magnet 100 leaves, it comes under the action of the extension 105 °, which is a sufficient Has the ability to keep the magnetic particles in contact with the conveyor belt until they are over the approach are led out and then fall into a collecting funnel.

The flow of the material now approaches the field of the magnet Ho, which in turn pulls out those magnetic particles which were not sufficiently influenced by the magnet 100. The particles attracted here are ^{discharged through the belt 21 s} into a collecting funnel.

The material then enters the field of magnet 120. This magnet is the strongest the magnet and has relatively great power. As a result of its adjustability with reference on the channel 33 can affect the least sensitive, magnetic Particles or magnetic particles streaked with non-magnetic elements can be regulated as required. The ones raised to band 22 * Particles pass through the successive zones of different intensities. These zones are relative to the zones of the other magnets high potential; this has the consequence that the material is stronger than the other magnets alternately dropped from the conveyor belt and drawn back to it will.

By distributing the work of the magnets one is able to get the full effect of the magnets to be maintained over the entire width of the hollow. If only one magnet were used, so this should be so strong that it contains a comparatively large excess of particles would lift to the associated conveyor belt, especially if it is a very ferrous one Acts well. Such an amount would be lifted onto one of the conveyor belts at once it would only take up a small part of the width in the form of a beard. This beard would seriously impair the action of the magnet on the unsupported particles adhering diamagnetic particles can be entrained.

The non-magnetic passes over the lower end of the channel 33 into a channel 2o, ^a , from which it falls into the funnel 28.

Claims (1)

Patent claim: Magnetic ore separator, consisting of a vibrating conveyor with one above it Magnets and conveyors moving between magnets and vibrating conveyor, characterized in that the cores of the magnets from individual, except for one Magnetic connection exist at one end of the lamellae arranged separately from one another. 1 sheet of drawings.