DE2321281A1 - PROCESS FOR SEPARATING MAGNETIZABLE PARTICLES FROM A FINE-GRAIN SOLID AND DEVICE FOR CARRYING OUT THE PROCESS - Google Patents

Description

Annex to the patent application from H 73/1 h

Klöckner-Humboldt-Deutz Lg / -

Corporation

dated April 18, 1973

Process for separating magnetizable particles from a fine-grained solid and device for carrying out the method

The invention relates to a method for separating magnetizable Particles from a material flow, in particular from a fine-grained solid, carried by a carrier in a channel by a magnetic field with a high field strength of at least 15-000 G is performed.

From the German Offenlegungsschrift 2.159.525 is a Method and apparatus for separating magnetizable particles from a fine-grained solid with Described using a magnetic field generated by superconducting coils. In the known method, however the fine-grained solid to be processed is initially suspended in a carrier and then over the entire Cross-section of the carrier means channel distributed through the magnetic field. This method has the disadvantage that For example, when separating magnetizable ores from their gangue, gangue near the wall

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particles not of the magnetizable ones adhering there Let particles separate and that on the other hand, located approximately in the middle of the flow channel magnetizable Particles have to move across the full width of the channel through the entire suspension flow. This is in the known Process affects the selectivity and the output to a considerable extent. Since there is also the discharge of the separated magnetizable particles are to take place solely through a partial flow of the carrier medium, cannot be prevented be that magnetizable particles attach themselves to the duct wall in the area of the separation zone of the magnetic field and adhere there, so that in the course of time the free flow cross-section of the canal overgrows.

The object of the invention is to avoid the disadvantages of the known method, a method for separating magnetizable particles from a material flow, in particular to create from a fine-grained solid, which by using high field strengths of, for example, 15,000 G, especially as they can be generated by using superconducting coils, a perfect separation the magnetizable particles from the rest of the material flow, caused in particular by the other solids and the carrier. This is done according to the invention in that the feed material is in the form of a beam and with Distance from which lie in the area of the highest field strength -

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the canal wall is introduced into the canal and that the this canal edge in the area of the - seen in the direction of flow - adhering to the separation zone located behind the feed point magnetizable particles are mechanically withdrawn from the channel. This procedure achieves that the magnetizable particles in the feed material are under the influence of the magnetic field from the feed beam can be pulled out laterally and only from the carrier means without being hindered by the other accompanying solids filled areas of the channel have to traverse, while the non-magnetizable material flow together flows off with the carrier medium without, however, noticeably mixing with it and, above all, without the whole Fill in the duct cross-section.

In an embodiment of the invention it is provided that the feed material with one of the field strength and / or the magnetizability the inlet speed depending on the particles to be separated be introduced into the magnetic field.

This can be particularly useful when using

the
superconducting coils, ^v generate a magnetic field running essentially in the direction of the carrier medium flow, which practically only has a gradient in the area of the coil ends, achieve perfect separation by using the speed at which the particles to be separated through the inhomogeneous area of the

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Magnetic field, even with weakly magnetizable! Particle a sufficiently large magnetic force acts on the particle.

In an embodiment of the invention it is also provided that the feed material in the carrier means in the form of a thin, preferably band-shaped jet above the separation zone is introduced in an area with a lower field strength. It is particularly advantageous if the shape of the Beam is designed so that its outer, the precipitation wall facing side parallel to the precipitation wall runs so that the magnetizable particles to be separated from the feed beam over the entire beam width have to cover the same distance to the precipitation wall. For this reason it is also advantageous if the feed jet with respect to the direction of movement of the magnetizable particles is very thin, so that accompanying by the rest Solid matter does not hinder the movement of the magnetizable particles towards the precipitation wall.

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In a further advantageous embodiment of the method according to the invention it is provided that the feed jet obliquely to the direction of flow of the carrier medium in Introduced in the direction of increasing strength of the magnetic field will. This measure ensures that the magnetizable particles to be deposited are ready

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homogeneous field in the area of the feed zone as a result of the deflection of the feed beam from the original direction a magnetic force becomes effective by the carrier medium current, so that the separation result is further improved.

In an embodiment of the method according to the invention it is further provided that the magnetizable particles displaced material flow passes through at least two magnetic fields one after the other, the strength of each subsequent Field is larger than that of the previous field. By this measure it is possible either one after the other to separate particles of different magnetizability from the input material or with one input material Particles of defined magnetizability to increase the output, since in this way even the finest particles from can be separated from the feed material.

The invention also relates to an apparatus for performing the method according to the invention, which has a preferably vertically extending channel at least partially enclosed by at least one magnetic coil. The device according to the invention is characterized by a duct wall at a distance from the magnet coil, preferably opening into the channel in the homogeneous area of the magnetic field generated by the magnetic coil Feeding device, one in the separation zone - in flow

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seen direction - arranged below the feeder wall of precipitation as well as one with the wall of precipitation related discharge device for the magnetizable particles. This arrangement is with Advantage ensures that the magnetizable particles to be deposited move undisturbed in the direction of the precipitation wall can move.

In an advantageous embodiment of the invention it is also provided that the precipitation wall as a conveyor belt is trained. This measure makes it possible in a simple manner to remove those adhering to the wall of precipitation pull magnetizable particles out of the channel.

In another embodiment of the invention it is provided that the precipitation wall with an intermittent operated scraper is provided. Such a design is particularly advantageous when · for example when cleaning liquids or solids, which are only mixed with small proportions of magnetizable particles, a continuously discharging device would be too expensive because of the small proportion of magnetizable particles.

In an embodiment of the invention it is also provided that

the feed device is designed as an ejector nozzle. This configuration has the advantage that

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the feed material is sucked in by the carrier means flowing through the channel, so that an expansion of the feed material jet is avoided within the channel. Here it is in the case of the separation of magnetizable particles from solids advantageous if the feed material is already suspended in the carrier medium in the carrier medium flow is introduced.

To simplify the feeding of the feed material into the flow channel it is advantageous if, according to a further embodiment of the invention, an additional magnetic coil in the material feed area is arranged, by the field of which the main magnetic field is influenced so that it is in the area of the mouth the feed device has practically no gradient.

The method according to the invention is carried out on the basis of schematically illustrated exemplary embodiments of devices according to the invention explained in more detail.

Show it

1 shows a device in vertical section,

Fig. 2 is a horizontal section along the line II-II in Fig. 1,

3 shows a further exemplary embodiment with a conveyor belt as the precipitation wall,

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4 shows a schematic representation of a multi-stage Contraption.

As FIG. 1 and FIG. 2 show, the device is at this embodiment from a preferably vertically arranged rectangular carrier center channel 1, on the a duct wall a magnet coil 2 of a superconducting magnet is arranged, with which a magnetic field of, for example 100,000 G is generated. A carrier medium, for example air, is passed through the channel from top to bottom or water, led.

On the side of the wall opposite the solenoid Channel opens in the area of the upper end of the magnetic field for example in the form of a nozzle 3 a material feed device into the channel, with a sufficient one between the wall adjacent to the magnet coil and the nozzle mouth Distance remains. As can be seen from FIG. 2, the nozzle is advantageously designed as a slot nozzle, which extends parallel to the magnet coil over the entire width of the channel, so that the feed material is in the form of a thin film or thin veil in the carrier medium flow enters the canal. For this purpose it is advantageous if for example when processing a fine-grain mineral mixture this suspended in a medium corresponding to the carrier means before introduction into the channel

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and is then preferably introduced into the channel in such a way that the static pressure within the material jet is the same or less than the static pressure of the carrier medium in the channel. In this way it is prevented that the The jet expands when it enters the carrier channel and particles of the gait get close to the wall of precipitation. Instead of a slot nozzle, a large number of juxtaposed nozzles of round or angular cross-section can be used.

The fine-grained feed material occurs approximately in the homogeneous area of the magnetic field running in the same direction as the medium current of the carrier and arrives at a speed that corresponds approximately to the flow velocity of the carrier medium flow Velocity in the inhomogeneous area of the magnetic field at the lower end, i.e. in the part in which the magnetic field has a gradient, so that on the magnetizable particles within the fine-grained solid magnetic forces become effective, under the influence of which they are drawn to the precipitation wall 4.

at.

The magnetizable particles that are emaciated on the precipitation wall are removed with the aid of an intermittently or circularly moving scraper 5 and, if necessary, withdrawn from the device together with a small partial flow of the carrier medium. The main mass, i.e. the non-magnetic

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sable part of the fine-grained solid, here follows approximately the path of the strongly drawn out arrow 7 »during the magnetizable particles reach the precipitation wall following approximately the course of the thin solid arrows 8. As is readily apparent from the arrangement, this procedure avoids that magnetizable Particles are hindered on their way to the precipitation wall by the remaining solid particles. Advantageous it is when the feed nozzle is at least slightly inclined and inserted into the channel in the direction of the carrier medium flow is, so that in connection with the inlet speed, the solid particles in the direction of an increase in the Magnetic field cut the field lines, but at the same time describe a curved path as a result of the deflection by the carrier medium flow, so that already in this reference on the flow direction of the carrier medium inherently homogeneous ί & εχϊχΑκ partial magnetic field on magnetic forces the magnetizable particles become effective.

In the embodiment according to FIG. 3, the lower area is the canal wall lying in the separation zone 9, which acts as a precipitation wall serves, designed in the form of a conveyor belt 10, which extends over the entire width of the wall. That on the inside of the duct from top to bottom, "i.e. in

Conveyor belt running in the direction of flow on which the magnetizable particles precipitate, promotes

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this from a discharge opening 11, whereby by a stripping device 12 on the back of the conveyor belt all particles are removed. Here, too, the withdrawal is expediently carried out with a small partial flow of the carrier medium .

It is independent of the type of discharge device Depending on the type of material to be processed, it is expedient if in the lower area of the carrier center channel, i.e. below the separation zone, the channel is divided by a partition 13, so that magnetizable particles, especially the finest Particles that have not reached the precipitation wall, but have accumulated in the flow zone adjacent to the precipitation wall, separated from the rest with the The main amount of the carrier medium flow provided with gangue can be deducted. The separation of those contained in the substream 14 magnetisable particles can then either via a new magnetic separation or a mechanical, chemical or thermal separation from the carrier.

About the inhomogeneity influencing the feed jet To prevent the upper end of the magnetic field, it is also useful when switched by a corresponding Additional coil 16, the inhomogeneity of the upper end of the field is suppressed. In this way it is avoided that it is already magnetizable to a separation

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Particles inside the feeder that come for example, leads to "caking" on the wall of the feed nozzle and thus to malfunctions.

In Fig. 4, a further embodiment is shown. In this embodiment are a continuous tubular channel a plurality of magnet coils 17, 18 and 19 arranged one behind the other, with each subsequent Coil creates a stronger magnetic field than the previous coil. Below each coil is a

schematically indicated discharge device 10 from the separated magnetizable material in the respective separation zone removed from the carrier medium flow, while the main flow is introduced into the next magnetic field. The feeding device Expediently opens coaxially into the channel, a deflector 20 advantageously below the opening is arranged. Depending on the size of the channel cross-section, it may be useful to use a deflector instead of a deflector displacement body extending along the channel axis

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to be provided so that the channel has an approximately circular cross-section receives.

The above-described method and devices for Implementation of the procedure can be used in particular for the following applications:

1. When processing magnetizable ores, especially

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especially of weakly magnetizable ores to separate the ore from the gangue mineral;

2. For the removal of iron-containing magnetizable accompanying minerals from an ore concentrate of a non-ferrous ore;

3 · For removing iron-containing magnetizable minerals for example from kaolin.

In cases 2 and 3, the magnetizable components represent the impurity, while the main amount of the solid represents the product of value to be obtained.

4. Removal of magnetizable contaminants from liquids, due to the high level of application Coming field strengths also particles in the colloidal range can be removed from the liquid.

Claims

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Claims (11)

Claims 1. A method for separating magnetizable particles from a material flow, in particular from a fine-grained solid, which is guided by a carrier in a channel through a partially in the direction of the material flow high field strength of at least 15,000 Gauss, characterized in that the feed material in the form a beam and is introduced at a distance from the lying in the region of the highest field strength channel wall into the channel, and that on the channel wall in the region of - are withdrawn adhering behind the feed point lying separation zone magnetizable particles mechanically from the channel - seen in the flow direction. 2. The method according to claim 1, characterized in that the feed material with one of the field strength and / or the Magnetizability of the particle-dependent inlet speed are introduced into the magnetic field. 3. The method according to claim 1 or 2, characterized in that that the feed material in the carrier in the form of a thin, preferably band-shaped jet above the separation zone is introduced into an area with a lower field strength. - 2 409846/0131 4. The method according to any one of claims 1 to 3 »thereby characterized in that the feed jet obliquely to the flow direction of the carrier means in the direction of increasing strength of the magnetic field is introduced. 5. The method according to any one of claims 1 to 4, characterized in that that the material flow mixed with magnetizable particles has at least two magnetic fields in succession runs through, the strength of the subsequent magnetic field being greater than that of the preceding magnetic field. 6. Apparatus for performing the method according to any one of claims 1 to 5, which has a preferably vertically extending, at least partially encompassed by at least one magnetic coil channel, characterized by a channel wall at a distance from the surrounded by the magnetic coil, preferably in the homogeneous region of the through Magnetic coil {2) generated magnetic field into the channel (1) opening feed device (3) »a precipitation wall in the separation zone - seen in the direction of flow - below the feed device (3) and a discharge device connected to the precipitation wall {5},, 10) for the magnetizable particles. 7. Apparatus according to claim 6, characterized in that the precipitation wall is designed as a conveyor belt (lo). - 3 - 409846/0131 8. Apparatus according to claim 6, characterized in that that the precipitation wall is provided with an intermittently operated scraper (5). 9. Apparatus according to claim 6, 7 or 8, characterized in that the feed device (3) is designed as an ejector nozzle is. 10. Device according to one of claims 6 to 9> characterized in that the feed device, which is preferably designed as a nozzle (3 / inclined in the direction of the precipitation wall (4i of the channel (1) is directed, the feeding device at a distance from the wall of precipitation in the channel (1) opens. 11. Device according to one of claims 6 to 10, characterized in that an additional magnetic coil in the material feed area (16) is arranged, through whose field the main magnetic field is influenced so that it has practically no gradient in the area of the mouth of the feed device ^ 3>. 409846/0131