WO2001003844A1 - Separating facility and method for separating a fraction containing nonferrous metals from an electronic scrap preparation - Google Patents

Abstract

The invention relates to a separating facility for a fraction containing nonferrous metals, especially from an electronic scrap preparation, comprising a grinder and a magnetic separator connected downstream thereof. The invention aims at enabling the production of high-quality nonferrous metal fractions using simple means and in a cost-effective manner. This is achieved in that a belt conveyor having an eddy current separator disposed on the head side and a feeder disposed on the head side and discharging into the area of the eddy current separator are connected downstream of the magnetic separator and in that the rotation of the eddy current and the direction of conveyance of the belt conveyor are directed toward the end of the belt conveyor. The invention also relates to a method for separating a fraction of an electronic scrap preparation containing nonferrous metals, whereby said fraction is ground to a grain size of less than 30-40 mm in a grinder and the Fe constituents are removed from the ground fraction by means of magnetic separation. Said method makes it possible to produce high-quality nonferrous metal fractions of nonferrous metals using simple means and in a cost-effective manner.

Description

Separation plant and method for separating a fraction containing non-ferrous metals from an electronic scrap processing plant

Technical field

The present invention relates to a separation plant and a method for separating a fraction containing non-ferrous metals, in particular from electronic scrap processing according to the preamble of claim 1 and claim 12.

State of the art

When processing electronic waste, individual metal fractions are generally recovered. This is usually crushed in stages, and fractions of ferrous and non-ferrous metals are obtained by magnetic and non-ferrous separation.

From DE-Al-41 00 346 it is known to pre-shred the electronic scrap to a grain size of less than 20 to 40 mm in a first shredding stage and the fraction remaining after sieving and a non-ferrous and Fe separation to a shredding in a second shredding step Resize grain size below 10 mm. After the shredding, an additional Fe separation and then a multi-stage screening using air stoves and an intermediate screening are provided as further processing steps. To prepare the coarse material from the second sieving, grinding to a grain size of less than 100 μm and subsequent separation in a wet separation process are proposed.

This known separation system or this known separation process requires a relatively high investment volume and thus causes relatively high operating costs. Presentation of the invention

The object of the present invention is to provide a separation plant and a method according to the preamble of claim 1 and claim 12, respectively, in order to produce high-quality recyclable fractions of non-ferrous metals with simple means in a cost-effective manner.

This object is achieved by a separation system according to the features of claims 1 to 1 1 and by a method according to the features of claims 12 to 17.

In this way, a copper-rich and an aluminum-rich material fraction can be produced inexpensively and with simple means.

Due to the - contrary to the usual design and driving style - intended head-side task on the conveyor belt with the eddy-current separator arranged on the head side, sorting of the crushed and largely Fe-free fraction takes place directly after the shaping of the particles and thus indirectly increases the copper concentration in the flat part fraction and an increase in the aluminum concentration in the spherical part fraction, in which case at least one high-quality material fraction can be separated from both the flat part and the spherical part fraction in a simple manner.

After the screening of the flat part fraction, a fraction of valuable material containing predominantly copper and a predominantly piece of board is obtained. After sighting the spherical fraction, a fraction of recyclable material is obtained which contains over 90% aluminum and contains over 85% heavy metals (eg Cu, Pb, Ms, Zn; density greater than 4 kg / dm ³ ).

REPLACEMENT BLADE (RULE 26) The feed, the conveyor belt, the arrangement and mode of operation of the eddy current separator work together in such a way that the flat and spherical particles initially fall into the magnetic force field of the rotating magnet system of the eddy current separator and are excited by the acting forces to rotate around their respective center of gravity Ω * 6 * _* / take 1, the flat particles are transported on a stable equilibrium position on the conveyor belt after a short flight phase until they are ejected

Q _" mg & qei-i f for spherical particles / are set in rotation such that their peripheral speed is higher than the transport speed and vice versa and is therefore discharged - after contact with the conveyor belt - at the head end.

With the present separation system or the present method, the effort for an otherwise complex dedusting is also significantly reduced, since there is no need for very fine comminution and the number of sightings that require dedusting can be significantly reduced. The amount of air to be extracted and dedusted can be reduced by about half.

If a non-ferrous metal separator is connected upstream of the feed, the quality of the recyclable material fractions can be improved by separating off disturbing residues and largely trouble-free operation of the downstream stages. e.g. by separating any vaults formed by residues. If the non-ferrous metal separator is designed as a very fine pole separator, a fraction that is particularly highly concentrated in non-ferrous metals can be fed in via the feed.

In a particularly inexpensive and robust embodiment, the eddy current separator is designed as a rough pole separator.

If a sieve is connected between the magnetic separator and the feed, a partial fraction can be split off, from which a further fraction of valuable material can already be split off in a simple manner by means of a sighting or a non-ferrous metal separation.

REPLACEMENT BLADE (RULE 26) If the sieve is designed as a vibrating or drum sieve, largely trouble-free operation and, at the same time, reliable separation into a fine and a coarse fraction is guaranteed.

By means of the sieving, relatively small particles, which could interfere with the subsequent processing steps and cannot be completely separated by a non-ferrous metal separator, can be reliably separated onto the conveyor belt before processing and processed further separately.

With a screen hole diameter in the range of approximately 1 to 6 mm, preferably approximately 2 to 5 mm for fine screening, a particularly high yield and quality of valuable materials is achieved.

By means of the sieving, even relatively large particles, which may not be able to be set sufficiently in rotation and would therefore impair the sorting into a spherical fraction and a flat fraction, can be reliably separated and further processed separately.

With a screen hole diameter in the range of approximately 12 to 30 mm, preferably approximately 15 to 25 mm for coarse screening, a particularly high quality of valuable materials is achieved.

If the feed opens near the vertex of the eddy current separator, flat and spherical particles can be separated from one another particularly reliably.

If a baffle plate is provided adjacent to the feeder and at a distance from the conveyor belt, it can largely be prevented that spherical particles which unfavorably spring back after an impact on the conveyor belt get into the flat part fraction.

Seating tables or air stoves are particularly suitable for classifying the flat part and ball part fractions. Training the shredder as a mill supports the formation of flat and spherical particles.

Further refinements of the invention can be found in the subclaims and the following description of an exemplary embodiment.

The invention is explained in more detail below using an exemplary embodiment of a separation system.

Brief description of the drawings

Show in the accompanying drawings

Fig. 1 is a schematic representation of a separation system and

2 shows a schematic section of the separation system according to FIG.

Best way to carry out the invention

The separating system shown in FIG. 1 comprises a shredder designed as a hammer mill 1, which is followed by a magnetic separator designed as a magnetic roller 2 and a sieve designed as a vibrating sieve 3.

An NE separator designed as a very fine pole separator 4 is arranged downstream of the sieve 3.

The NE separator 4 is followed by a sorting device 5, which comprises a conveyor belt 6, an eddy current separator 7 and a feed 8.

REPLACEMENT BLADE (RULE 26) On the output side, a first setting table 10 and a second setting table 9 are arranged downstream of the sorting device 5.

A third setting table 11 is connected downstream of the screen 3.

As shown in Fig. 2 in more detail, the feed 8 is arranged above the conveyor belt 6 at the head end (right).

The conveyor belt 6 is received by two deflection rollers 12, 13, one of which is provided with a rotary drive. In the deflection roller 13 provided at the head end of the conveyor belt 6, the eddy current separator 7 is arranged eccentrically with respect to the axis of the deflection roller 13 in the transport direction of the conveyor belt 6.

Above the conveyor belt 6 a baffle plate 14 adjacent to the end of the feed 8 is arranged in such a way that spherical (approximate) particles which spring back from the conveyor belt 6 - in the direction of transport of the conveyor belt - bounce off there and are thrown back to the head end.

In order to separate a fraction of an electronic scrap preparation containing non-ferrous metals, the fraction in the present exemplary embodiment is ground in the hammer mill 1 with grinding action to a grain size of less than 30 mm, so that the grain spectrum is in the range from approximately 0 to approximately 30 mm. The comminuted fraction is fed to the magnetic separator 2, with which Fe-containing particles are separated off. The remaining fraction is then sieved in the vibrating sieve 3 with a sieve hole diameter of approximately 4 mm. The fine fraction obtained thereafter is fed to the setting table 11 for screening and into a valuable fraction containing predominantly copper in the form of spherical wires, and into a predominantly contaminant such as pieces of board, wood splinters, plastics, etc. containing residual fraction split.

REPLACEMENT BLADE (RULE 26) The coarse fraction from the vibrating sieve 3 is fed to the non-ferrous separator 4 and freed of larger residues and concentrated with regard to the content of non-ferrous metals.

The concentrated coarse fraction is fed to the sorting device 5 and sorted into a flat part fraction comprising essentially flat, plate-like parts and a ball part fraction comprising essentially spherical, rather body-shaped particles.

Here, the particles fall from the feed 8, for example a feed trough, onto the end of the conveyor belt 6 provided with the eddy current separator 7.

While the flat particles land on the conveyor belt 6 after a short flight phase and are discharged in the direction of the deflection roller 12, the spherical particles experience such a rotation about their center of gravity as a result of the magnetic forces that after contact with the conveyor belt 6 they move against the conveying direction of the conveyor belt 6 move and be discharged in the direction of the guide roller 13.

Finally, after the sorting, the flat part fraction is fed to the setting table 9 for screening and separated there into two recyclable material fractions, one essentially containing copper and the other predominantly coated pieces of board.

The spherical part fraction is sifted by means of a setting table 10, whereby a recyclable material fraction containing over 90% aluminum and a recyclable material fraction containing over 85% heavy metals is generated.

Through the interaction of the sorting provided in the sorting device 5 and the screening by means of the setting tables 9, 10, an effective separation can be achieved in a simple manner. Difficulties that have previously arisen in sighting different particle shapes, which can lead to the fact that lighter particles due to their shape end up in a heavy fraction, are thus avoided from the outset.

REPLACEMENT BLADE (RULE 26) In a modification of the exemplary embodiment described above, in a second exemplary embodiment of the separating system, the sieve 3 is designed with a sieve hole diameter of approximately 20 mm and an NE separator 11 is provided instead of the third setting table 11 from the first exemplary embodiment. This design of the separation system is particularly suitable for fractions containing non-ferrous metals, such as z. B. from shredded car and / or electric motor scrap. The material in the area of the upper grain spectrum can be split off from such a fraction in a simple manner by sieving and further separated into valuable material fractions by means of the NE separator 11. The fine fraction remaining after the screening is then, if necessary after NE enrichment (or depletion of impurities), fed to the sorting device 5 by means of an NE separator 4 and processed as in the first exemplary embodiment.

In a modification of the two exemplary embodiments described above, the sieve 3 is omitted in a third exemplary embodiment of the separation system and the comminuted and largely Fe-free non-ferrous fraction is fed directly to the sorting device 5, if appropriate after an non-enrichment. This design of the separation system is particularly suitable for non-ferrous fractions, the components of which have a grain diameter of approximately less than 20 mm.

Industrial applicability

The separation system and the process ensure the more cost-effective production of high-quality fractions of non-ferrous metals with simple means.

REPLACEMENT BLADE (RULE 26) LIST OF REFERENCE NUMBERS

^~ Hammer mill / shredder

= Magnetic roller / magnetic separator

= Vibrating sieve / sieve

= Fine pole separator / NE separator

= Sorting device

= Conveyor belt

= Eddy current separator

= Feed

= second seating table

= first seating table

= third nesting table / NE separator

= Pulley

= Pulley

= Baffle plate

REPLACEMENT BLADE (RULE 26)

Claims

claims

1. Separation system for a fraction containing non-ferrous metals, in particular from an electronic scrap processing unit, with a shredder (1), which is followed by a magnetic separator (2), characterized in that the magnetic separator (2) has a conveyor belt (6) with a head end Eddy current separator (7) and a feeder (8) giving up in the area of the eddy current separator (7) is arranged downstream and the rotation of the eddy current separator (7) and the conveying direction of the conveyor belt (6) are directed towards the end of the conveyor belt (6).

2. Separating system according to claim 1, characterized in that the conveyor belt (6) is followed by a first setting table (10) on the head side and a second setting table (9) at the end.

3. Separation plant according to claim 1 or 2, characterized in that the feed (8) is preceded by a non-ferrous separator (4).

4. Separation system according to claim 3, characterized in that the non-ferrous separator (4) is designed as a fine pole separator.

5. Separation system according to one of claims 1 to 4, characterized in that the eddy current separator (7) is designed as a coarse pole and / or fine pole separator.

6. Separation plant according to one of claims 1 to 5, characterized in that the

Magnetic separator (2) is followed by a sieve (3).

7. Separation plant according to claim 6, characterized in that the sieve (3) is designed as a vibration or as a drum sieve.

REPLACEMENT BLADE (RULE 26)

8. Separation plant according to claim 6 or 7, characterized in that the sieve (3) has a sieve hole diameter in the range of about 1 to 6 mm, preferably from about 2 to 5 mm.

9. Separating plant according to claim 6 or 7, characterized in that the sieve (3) has a sieve hole diameter in the range of about 12 to 30 mm, preferably from about 15 to 25 mm.

10. Separation system according to claim 1 to 9, characterized in that the end of the feed (8) above the conveyor belt (6) is arranged near the vertex of the eddy current separator (7).

1 1. Separation system according to one of claims 1 to 10, characterized in that a baffle plate (14) is provided adjacent to the end of the feeder (8) and spaced from the conveyor belt (6).

12. A method for separating a fraction containing non-ferrous metals, in particular from electronic scrap processing, in which the fraction is reduced in a shredder to a grain size of less than 30-40 mm and the shredded fraction is freed from Fe components by means of a magnetic separation, characterized in that that the comminuted and largely Fe-free fraction is split at least partially by means of an eddy current separation into a flat part fraction comprising essentially flat parts and a spherical part fraction comprising essentially spherical parts, with at least part of the fraction on the head side and on the head side using an eddy current separator (7) provided conveyor belt (6), the flat part fraction is conveyed in the conveying direction of the conveyor belt (6) and the eddy current separator (7) rotates in the conveying direction of the conveyor belt (6).

13. The method according to claim 12, characterized in that at least one valuable material fraction is split off from the flat part fraction and from the spherical part fraction by means of sighting.

REPLACEMENT BLADE (RULE 26)

14. The method according to claim 12 or 13, characterized in that the crushed and largely Fe-free fraction is split after the magnetic separation by means of sieving into a coarse fraction and a fine fraction.

15. The method according to claim 14, characterized in that sieved with a sieve hole diameter of about 1 to 6 mm, preferably from about 2 to 5 mm and the coarse fraction is placed on the conveyor belt (6).

16. The method according to claim 14, characterized in that sieved with a sieve hole diameter of about 12 to 30 mm, preferably from about 15 to 25 mm and the fine fraction is placed on the conveyor belt (6).

17. The method according to any one of claims 12 to 16, characterized in that the fraction on task on the conveyor belt (6) is freed of non-metallic components by means of a non-ferrous deposition and enriched in non-ferrous metals.

REPLACEMENT BLADE (RULE 26)