DE202011100931U1 - Apparatus for cleaning a mixture of metal scrap from non-magnetic components - Google Patents

Abstract

Device according to protection claim 1, characterized in that a conveyor belt (1) is a, in a shredding machine, e.g. B. a shredder, processed batch (5) of scrap metal in the magnetic field of a first magnetic block (3) of an overband magnet device, and from this magnetic field to a, under the magnet block (3) continuously running amagnetic conveyor belt (2) is pulled and this conveyor belt (2) The metal scrap is transported further to magnet blocks (14) following in series with the material flow.

Description

Mixtures of magnetic scrap are mostly supplied by industry as a by-product of manufacturing processes and consist of magnetic and non-magnetic metal parts. As for further processing only pure metals of a kind, eg. B. magnetic components such as iron or non-magnetic materials such as copper come into question, waste disposal companies have the task such mixtures again in the individual components, according to their nature to separate. This results in a considerable difficulty, since the individual components of the metal species contained in the mixture can be so strongly connected to each other by adhesive forces and / or loose connections that z. B. the use of a conventional magnetic separator is not able to separate magnetic components from non-magnetic clean. Finest non-magnetic particles usually adhere to magnetic parts and / or are interwoven with them by loose connections and thus arrive together with the magnetizable parts for further smelting. However, a steel obtained from this mix no longer meets today's high demands on the desired purity of a steel, as the steel quality suffers. In order to achieve the quality of steel demanded today, it is indispensable that the scrap released for smelting consists of pure iron and does not contain any non-magnetisable constituents, such as, for example, B. copper as an admixture, also in the form of copper dust, not even in low admixture contains.

Such a clean separation of magnetizable and non-magnetizable material is the object of the invention.

So far it is common to use so-called magnetic separator for this purpose. These are magnetic paths that are located above a metal scrap conveyor belt fed from a mixture of different metals. The magnets attract the magnetizable material and allow large parts of the non-magnetizable portion to fall back onto the conveyor belt and continue to run. However, this type of separation of magnetizable components in the metal mixture is insufficient because non-magnetizable particles adhere to the magnetizable parts and / or may still be loosely connected to them.

For this reason, the invention proposes a device in which measures are taken both to keep the metallic bulk material on the conveyor belt, as well as attracted by a magnet magnetizable material in motion, so quasi shaken by these movement forces adhering non-magnetizable material of the magnetizable material or disconnected from it, separates from it. For this it is necessary to repeat and eliminate the influence of magnetic forces several times. The necessary technical measures foresee that a first conveyor belt, a by means of a crusher z. B. shredder crushed metal mixture to transport into the sphere of action of a first magnetic block of an overband magnet. This first magnet block absorbs magnetizable components from the delivered metal mixture. The non-magnetizable portion falls in part, as far as it is not attached to magnetizable materials or loosely connected to this, in a collection container or on a transport device, which leads to such. A Überbandmagneteinrichtung is a non-magnetizable conveyor belt, which consists of an elastic band that runs at both ends via pulleys and so a top and bottom band (top and bottom strand) results. This creates a gap between the upper and lower strand. In the space between the two strip parts individual magnetic blocks (at least two) are arranged in series one behind the other. The number of magnetic blocks and the length of the non-magnetic strip of such an overband magnetic device depend on the need of the end product to be achieved, in this case a clean separation between magnetizable and non-magnetic metal parts. The band of the overband magnet is provided on the surface facing the applied metal compound with a kind of nubs or bumps designed to attract the cargo to be transported by the magnetic field generated by the magnetic blocks against the surface of the belt facing the magnetic blocks , constantly in motion, with changing direction, is held. Therefore, the knobs are made variable in shape and arrangement and distributed over the entire length and width of the band. It is only important that the bulk material is constantly kept in motion so that non-magnetisable particles can detach from the magnetizable material. Since the material attracted by the first magnetic block contains, in addition to magnetizable constituents, non-magnetizable particles which adhere to and / or are loosely connected to the magnetizable material parts, the material attracted by the first magnet is pulled away from the area of action of the first magnet block by means of the band provided with projections spent in the sphere of action of the subsequent magnet block. This further transport causes the effective magnetic forces of the first magnetic block to be reduced for a short time or completely switched off, the adhesion forces in the initially drawn batch of compounds to fade and, during the transition from one to the next following magnetic block, the metal mixture to float freely in the space for a short time, so that non-magnetizable Release materials and can fall away down. This process is repeated until most of non-magnetizable shares iron is obtained. In the magnetic blocks both permanent and electromagnets can be used.

Electro-magnetic blocks in series one behind the other have the advantage over permanent magnets that they are electrically switchable via a control device such that a magnetic block arranged upstream in the material flow shuts off, ie. H. can be made magnetically inactive, if downstream of this a magnetic block is switched to magnetically active and vice versa. Here, the transition from one magnet block to the other, by eliminating the adhesion forces, facilitates the detachment of non-magnetic material from magnetizable material. Non-magnetic particles can then more easily fall off the magnetizable material, and the downstream magnetic block takes up magnetizable material of higher purity, which has already been subjected to a first separation process of non-magnetic substances. This game can be repeated as many times as most of the cleaned, d. H. obtained from non-magnetizable substances pure iron is obtained.

Another development proposes to equip the magnetic blocks with vibration devices so that the material attracted by a magnetic block is also kept moving on the magnetic block itself and will shake off particles that are not held by magnetic forces.

Likewise, the pulleys at the ends of the belt can be equipped with vibrators and thus hold the entire belt in a shaking motion, so that all metal parts that are not magnetic are shaken off.

Another development provides for the magnetic blocks to be arranged horizontally and / or vertically displaceable. Such an arrangement aims, if the horizontal and / or vertical movement z. B. is carried out in a rhythmic sequence that further movement is introduced into the material to be separated, so that a detachment of the non-magnetic components in the scrap mixture to be separated is in turn favorably influenced by the magnetizable portions. Loosely bonded non-magnetic material parts are thus more easily separated from magnetizable material components.

All of these additionally indicated measures may be used separately or together to provide optimum conditions for the separation of magnetizable material from non-magnetic material.

Brief Description:

About the conveyor belt ( 1 ) is a mixture of metal scrap, which has been comminuted by means of a shredder or a hammer mill into the magnetic field of a first magnetic block I ( 14 to n) spent a Umlaufbandmagneteinrichtung. The magnetic field of the first magnet block I ( 3 ) pulls the metal scrap mixture ( 5 ) to the below the magnetic blocks ( 14 to n) running non-magnetic conveyor belt ( 2 ). Easy release, non-magnetizable material ( 6 ) falls down into a collecting container ( 8th ). The non-magnetic conveyor belt ( 2 ) indicates at its the metal scrap mixture ( 5 ) facing surface knobs or bumps ( 11 ), or may have only a roughened surface to the metal scrap ( 5 ) better and be able to transport to the next magnet block II. During this transport from one preceding magnetic block to the next following magnetic block, the metal mixture floats in the short term, so that non-magnetizable material can detach from the magnetizable metal and fall into the collecting container. This process is repeated until the magnetizable metal is freed from non-magnetisable fractions. The number (n) of the successive magnetic blocks (m) depends exclusively on the desired degree of purity of the magnetizable material. The non-magnetic conveyor belt ( 2 ) runs at the end and at the beginning of the magnetic path via pulleys ( 12 ) of which at least one is connected to an electromotive, controllable in its speed electric drive and the non-magnetic conveyor belt ( 2 ) drives. The non-magnetic conveyor belt ( 2 ) Is endless. About at least one pulley, the driving forces resulting from an electric drive, on the non-magnetic conveyor belt ( 2 ) transfer. In order to further improve the possibility of separating non-magnetic scrap elements from the magnetic scrap fraction, the magnetic blocks (m) are equipped with vibrators ( 9 ) and / or with facilities ( 15 and 16 ) to raise and lower the magnetic blocks during operation and / or to move horizontally.

LIST OF REFERENCE NUMBERS

1

conveyor belt

2

conveyor belt

3

Magnetic block I

4

Magnetic block II

5

Metal scrap batch

6

Amagnetic material

7

Iron scrap (cleaned)

8th

Clippings

9

vibrator

10

Fe-collecting

11

Pimples and / or humps

12

Pulleys (with electric drive)

13

Number of magnetic blocks

14

Magnetic blocks (m to n)

15

Device for lifting and lowering the magnetic blocks

16

Device for moving the magnetic blocks horizontally

Claims (6)

Device according to protection claim 1, characterized in that a conveyor belt ( 1 ), in a crusher, z. B. a shredder, processed mixture ( 5 ) of metal scrap in the magnetic field of a first magnetic block ( 3 ) of an overband magnetic device, and from this magnetic field to, under the magnetic block ( 3 ) continuously running non-magnetic conveyor belt ( 2 ) and this conveyor belt ( 2 ) the metal scrap to magnetic blocks following in the flow of material ( 14 ) transported on. Device according to protection claim 1, characterized in that the non-magnetic conveyor belt ( 2 ) on the metal scrap ( 5 ) side pimples or humps ( 11 ) or other protrusions or an increased degree of surface roughness. Device according to one of the protection claims 1 and / or 2, characterized in that the magnetic blocks ( 14 ) and / or the pulleys ( 12 ), of which at least one is the drive of the non-magnetic conveyor belt ( 2 ), at the end of the non-magnetic conveyor belt ( 2 ) with vibration devices ( 9 ) are equipped. Device according to one of the claims 1 to 3, characterized in that each magnet block ( 1 to n) heights and / or horizontally displaceable over at least one position direction ( 15 or 16 ) is mounted, so that a movement in the attracted metal mixture ( 5 ) is generated by changing the effective magnetic forces. Device according to one of the protection claims 2 to 4, characterized in that when using electromagnets in the magnetic blocks ( 14 to n) these cooperate with an electrical control device, each of which switches a subsequent magnetic block to magnetic and at the same time magnetically ineffective the preceding magnetic block. Device according to one of the preceding claims 2 to 5, characterized in that the non-magnetic conveyor belt ( 2 ) of the overband magnet device at its two-sided deflection over at least two rollers ( 12 ) is guided, of which at least one of them, the driving forces of a controllable speed controllable electromotive drive device on the non-magnetic conveyor belt ( 2 ) and also with vibration devices ( 9 ), so that a vibration on the entire non-magnetic conveyor belt ( 2 ) is effective.

Images