EP0898496A1 - Device and process for separating particles with a rotary magnet system - Google Patents

Abstract

A particle separating device separates material to be sorted (1) into fractions of greater or lesser electrically conductive non-ferromagnetic particles (2, 3). The particles are fed to a conveying device (20), e.g. a conveyor belt (20a). Beneath or above the conveyor belt (20a) there is a rotary magnet system (30). The direction or rotation of the magnet system (30) is selected so that its surface and the conveyor belt (20a) move in different directions (26, 36). The fractions of greater or lesser electrically charged non-ferromagnetic particles (2, 3) are thus distributed over several collecting containers (41, 42).

Description

 Device and method for particle separation with a rotating magnet system

The invention relates to a device and a method for particle separation of sorted material in fractions of more or less highly electrically conductive particles, with a conveyor to which the particles are fed, and a rotating magnet system arranged on the conveyor and a collecting container for the particle fraction sought.

In such a device known from US Pat. No. 3,448,857, a quantity of more or less electrically conductive particles to be sorted is placed on a conveyor belt from above. The conveyor belt runs over a belt drum and guides the particles to be sorted at a speed of 1 m / sec. up to 1.5 m / sec. the belt drum. A magnet system rotates in the belt drum at a speed of approximately 1500 revolutions / min. During operation, a relative movement occurs between the conveyor belt and the drum with the magnet system and this difference in speed causes the magnetic lines of force to move through the cut electrically conductive particles fed to the conveyor belt. This induces currents, the size of which depends on the electrical conductivity of the particles. In each case a higher current is generated in the particles with greater electrical conductivity, which causes these particles to be thrown off the conveyor belt in their direction of movement in a trajectory. The particles with lower electrical conductivity, however, remain in the vicinity of the conveyor belt and fall almost vertically from it. By setting up a collecting container in a suitable manner, it is possible to filter out precisely that fraction which has a desired, specific electrical conductivity.

It should be taken into account that ferromagnetic materials have already been selected from the material to be sorted using well known methods (strong magnets) before such devices are used. The devices are primarily used to separate so-called non-ferrous metals. on the one hand (copper, aluminum, lead, zinc, tin, brass etc.) of residues (paper, plastic, glass, etc.) on the other hand, especially in connection with the waste recycling.

DE 34 16 504 A1 discloses a device for separating mixtures of substances with different electrical conductivities, in which a rotating magnetic device is also provided which rotates rapidly and generates an alternating magnetic field through which the mixture particles are passed. The separating device is surrounded by a jacket that rotates more slowly. The resulting eddy currents have an effect on the particles, which give the electrically conductive particles a further parabola than the electrically non-conductive particles.

WO 89/07981 shows a comparable construction. Here, too, materials made of non-magnetic particles fall from above onto a rotating drum in which there is also a rotating magnet system. The two directions of rotation are opposite, so that non-metallic materials such as glass, plastic and stones fall on one side and non-magnetic metals on the other side of the drum. Constructions according to DE 34 16 504 A1 or WO 89/07981, however, only allow very non-specific separations and the number of incorrectly separated particles is relatively high. Magnetic particles are also a problem, which have not been separated out beforehand and can lead to damage if they enter between the drums and the rotating sleeves.

In order to further improve such devices, EP '0 339 195 B1 proposes to arrange the magnet system eccentrically in the belt drum. This prevents magnetizable, electrically conductive particles from getting stuck between the conveyor belt and belt drum, heating up to glow due to the magnetic field, and causing corresponding damage in the belt drum and conveyor belt. JP 57-119856 A also shows an eccentric arrangement. In order to improve the sorting quality, it has already been proposed in DE 4 323 932 C1 to increase the speed of the magnet system drum and thus to increase the strength of the deflection. However, this requires a correspondingly complex improvement in the properties of the magnet system.

The object of the present invention is to propose a generic device and a corresponding method which improve the sorting quality even without such an increase in speed or improve it even further with such an increase.

This object is achieved in a device in that the direction of rotation of the magnet system is selected so that the directions of movement of the magnet system surface and the conveyor are different.

In one method it is solved by moving the magnetic system surface and the particles to be sorted in different directions.

With such a constellation of the different elements to one another, the sorting quality can be decisively improved. In the known metal separators, the conveyor belt is basically only used to move the particles to be sorted to the actual sorting point, namely the magnet system; This then decides on the basis of the size of the throwing parabola formed whether the particle is to be regarded as more or less good electrical conductor and therefore falls into a certain collecting container or not. Under certain circumstances, this can lead to problems and incorrect assessments if, for example, particles lie on top of one another or obscure one another and thus interfere with one another due to the departure parameters.

According to the invention, however, the electrically highly conductive particles move in a different direction than the less electrically conductive particles (not only to different degrees in the same direction as in the prior art); the limit value can be set very sensitively here by the strength of the magnetic field of the magnet system or the speed of the conveyor belt P97 / 02536

become. The conveyor belt leads to a basic movement of all particles in a certain direction, the magnetic field of the magnet system counteracts this exactly. The magnetic field of the magnet system can easily be set so strongly that it moves the electrically conductive particles against the action of the conveyor belt in the opposite direction; In one embodiment, the approach to the throwing parabola takes place directly above the magnet system, and in some cases the particles will no longer come into contact with the conveyor belt if they are caught or pushed off sufficiently sensitively above the conveyor belt.

In another embodiment, a certain distance of the conveyor belt is considered on purpose. It has also been found here that the strength of the magnetic field is so great that it can convey the particles over the end of the corresponding upper run into a collecting container set up there.

If particles of possibly different specifications are now one above the other or through one another or possibly into one another, the forces going in different directions result in an equalization or swirling back and forth on the conveyor belt, as a result of which these particles separate from one another, which is immediately the case with particles lying on top of one another can be seen.

Instead of simply going through different throwing parabolas in nuances, they now move in diametrically opposite directions and cannot be disturbed.

If, for example, two particles hitting adjacent points move diametrically precisely against each other and hit each other, this does not reduce the sorting quality either: after the impact, they are certainly unchanged in the same place, but with the greatest probability somewhat different arrangement and will then automatically move in the right direction in the second attempt. In particular, a particle is prevented from being conveyed and sorted in the wrong direction.

Not taken into account in the international procedure. In contrast to constructions in which instead of an additional conveying device it is only provided that a jacket rotates around the magnet system, however, the result according to the invention is always that the particles to be separated have a finite dwell time in the magnet area in which they still have the Decisions and influences are accessible. If only a second drum is used instead of the conveying device, it usually remains in the event of incorrect classifications made initially, for example due to mutual interlocking of two elements.

Instead of a conveyor belt, another conveyor device can also be used, for example a conveyor trough, on which the particles are moved forward by vibration or simply by gravity. The effects are similar here.

A feed device is preferably also provided, by means of which the sorted material is fed to the conveyor device. The feed device can in turn be a conveyor belt or a conveyor trough. It is again preferred that at least the area adjacent to the drop point is made of a non-conductive material, for example a plastic.

This ensures that the particles of the material to be sorted are influenced to a certain extent shortly before the drop-off point, and the dwell time in the influence of the magnet system, which is favorable for precise movement and evaluation of the particles, is further increased. As can be seen from observations, the conductive particles thereby orient themselves as they fall onto the drop point and move specifically in the desired direction even before they hit the point.

In a particularly preferred embodiment, the directions of movement which arise in this way are not antiparallel, but are essentially perpendicular to one another. This means that the axis of rotation of the magnet system is parallel to the conveying direction of the conveyor belt or the conveyor trough or at a relatively small angle to it, ie the magnet system is itself rotates under the conveyor and thereby moves the surface of the magnet system substantially perpendicular to the direction of conveyance of the particles to be sorted in the conveyor trough.

This now leads to the fact that the forces acting on the non-ferrous metals lead to a strong movement component of these non-ferrous metals, which drives them away from the conveyor trough or to one side thereof, while the ordinary non-metallic particles remain unaffected.

This effect can be used to drive the non-ferrous metals over the edge of the conveyor trough or from the conveyor belt and collect them there in a collecting container.

Combinations of different ideas with each other are also possible.

All of the above-mentioned devices based on rotating magnet systems were based only on the idea of separating non-ferrous metals in their entirety from other waste such as glass or plastic and thus to enable a justifiable reprocessing. The accuracy of the way of working did not allow any other separations. The throwing parabolas of heavy but well-conducting copper parts and those of light but relatively poorly conductive aluminum parts or also of glass bodies having rolling motion components are similar and also merge into one another, which has previously been a problem.

Separations, for example of metal components in a product to be sorted, are therefore avoided as far as possible or, if absolutely necessary or required, are carried out manually or using very complex methods, for example by means of a floating method in appropriately conditioned liquids with precisely regulated specific densities. However, this is not only complex, but also leads to contaminated liquids which are costly to dispose of and, conversely, to appropriately wetted (and hence again problem components to be cleaned) non-ferrous metals. According to the invention, these non-ferrous metals can even be separated from one another! This is possible in particular in an embodiment in which the conveying device is provided with a conveying direction arranged essentially parallel to the axis of the rotating magnet system, the conveying taking place in a conveying trough above the magnet system. The conveyor trough is preferably not offset in the middle above the magnet system, but slightly offset, albeit overlapping.

The conveyor trough should have a slight incline transversely to the conveying direction, with the lowest point on the side spaced from the magnet system. The side facing the magnet system or the center line in its surface is either open or forms an attachment edge.

With such a shape, the relative differences between, for example, two non-ferrous metals can now be used: copper has a high conductivity, but a relatively high specific weight, aluminum, on the other hand, has a relatively low conductivity, but also a low specific weight. Copper particles are therefore relatively difficult to accelerate despite the great influence of the magnetic field. In fact, it turns out in practice that a corresponding inclination of the conveyor trough and lateral and vertical distance from the central axis make it possible to discharge all aluminum particles laterally from the conveyor trough over the magnet system before copper particles are also discharged.

This is supported by the fact that the particles of the material to be sorted tend to accumulate on the lower edge of the conveyor trough, that is to say small, correspondingly easily accelerated particles tend to run further away from the magnetic field, but larger, but also heavier and less easily accelerated particles protrude further.

This also applies to mixtures with other ingredients. Since aluminum particles do not only occur relatively frequently in standard sorting material, but also the most favorable combination of specific weight (or more precisely expressed from density, of all examined materials) have the ratio of mass to volume) and conductivity, if they are first sorted out of such a non-ferrous metal sorting material, then the parameters are changed until they are sufficient to discharge the next component of interest, and so on.

This can be done not only by repeated passes, but also by arranging different sections of the conveyor trough one behind the other, so that different non-ferrous metals are then sorted out successively in different longitudinal sections of the cylindrical rotating magnet system.

Another possibility arises when the conveyor trough has a cross section transverse to the direction of conveyance, which has a non-flat bottom, in particular a bottom having the highest point in its central region.

In the case of such non-planar cross sections in the conveying direction, there is an additional effect which contributes to the detangling of particles and which also forms a tendency-dependent separation depending on the ratio of density and specific conductivity. With a slight bend, however, slight misorientations that initially occur due to hooking can easily be corrected again, since the particles are in the influence of the various forces for a certain time.

It is particularly preferred if the bottom is adapted to the shape of the drum. If the drum rotates with the magnet system so that its axis is parallel to the conveying direction, it is advisable to arrange the base as a circular section arched upwards at a relatively short distance above the drum. This means in particular that the magnetic field can be used very effectively, that is to say it can be used particularly effectively or can be made relatively smaller in order to achieve the same effect.

A further preferred effect occurs if, in addition, in these or other embodiments, a fluid is applied in the area above the magnet system. Especially with a dosed loading impact, for example from an air nozzle, this enables an even more detailed separation of the different materials, in particular when it is already known from the supplied particles what materials they are made of and a statement can therefore be made, which forces are caused by the magnet system, the conveying effect of the conveyor troughs or the conveyor belt and (due to the specific particle weight and particle shape) by the air nozzle or other fluid loading device.

An improvement of the effect can be achieved by providing a rotating magnet system both above and below the conveyor. The axes of the two rotating magnet systems run parallel, and the direction of rotation is arranged so that the direction of movement is the same in the surface area of both magnet systems facing each other. A particularly stable and unique magnetic field is built up there for the particles passing between them on the conveyor.

In particular, this creates the effect that even particles that already have a certain component of their own motion or that are difficult to control due to irregular jumps, for example, can also be sorted reliably.

One of the basic ideas of the invention is to extend the dwell time of a particle of the material to be considered in the magnetic field used for sorting as far as possible. While in the prior art this dwell time is an extremely short moment in which the particles fall from above onto a conveyor belt, this time is significantly extended according to the invention, and the particles are given a much stronger possibility of being structured under the influence of the ordering Magnetic field in the correct sorting path.

Further advantages arise from features which are further developed in the subclaims. The invention is described in more detail below with reference to several embodiments. Show it:

Figure 1 is a schematic side view of a first embodiment;

Figure 2 is a schematic side view of a second embodiment;

Figure 3 is a schematic side view of a third embodiment;

Figure 4 is a schematic sectional view of a fourth embodiment;

FIG. 5 shows a perspective schematic view of the embodiment from FIG. 4;

FIG. 6 shows a schematic sectional illustration of a fifth embodiment;

FIG. 7 shows a perspective schematic view of the embodiment from FIG. 6;

Figure 8 is a sectional view through an enlarged section of Figure 6;

FIG. 9 shows a plan view of a section from FIG. 6;

Figure 10 is a schematic sectional view of a sixth embodiment;

FIG. 11 shows a perspective schematic view of the embodiment from FIG. 10; FIG. 12 shows a schematic sectional illustration of a seventh embodiment;

Figure 13 is a perspective schematic view of the embodiment of Figure 12; and

Figure 14 is a schematic sectional view of an eighth embodiment.

In all of the illustrated embodiments, the goal of the process can first be clearly recognized: At the beginning, material to be sorted 1, which consists of a mixture of more or less highly electrically conductive particles, is added, the electrically well-conductive particles 2 being shown in this pure scheme ¬ drawings appear as filled triangles, while the electrically poorly conductive particles 3 are represented by open circles. At the end of the process, the highly conductive particles 2 and the poorly conductive particles 3 are separated from one another and can be found at different positions.

First of all, a feed device 11 can be seen at the top left, via which the sorted goods 1 are transferred into a conveyor trough 15. This conveying trough 15, for example a vibrating trough, is intended to separate out the conveying flow from the outset and perhaps to remove undesirable components. Instead of a conveyor trough 15, this can also be a conveyor belt 15b as in the embodiment according to FIG. 4 or FIG. 7.

In this area, for example, the ferrous metals can be sorted out, which could interfere with the subsequent separation of the nonferrous metals from the plastics and other electrically non-conductive or hardly conductive substances. On the one hand, the ferrous metals can be sorted out relatively easily on the basis of their ferromagnetic properties, for which many known devices can be used. On the other hand, this very strong magnetism disrupts any further differentiation. The conveyor trough 15 or the conveyor belt 15b then feeds the sorted goods 1 to a conveyor device 20 in the still unsorted state, which in the embodiments of FIGS. 1 to 3 is a conveyor belt 20a, in the versions according to FIGS. 4 and 5 or 6 to 9 is a conveyor trough 20b. From this position, the embodiments of FIGS. 1 on the one hand and 2 and 3 on the other hand and FIGS. 4 and 5 and 6 to 9 differ to the third and finally of FIGS. 10 to 14.

In Figure 1, this conveyor belt 20a consists of an upper run 21 and a lower run 22 and runs over two drums 23, 24. It is driven and moves counterclockwise in the view shown, the upper run 21 of the conveyor belt 20a to the left in the Direction of movement 26.

The feed point 28, around which the particles of the sorted material 1 from the conveyor trough 15 meet the surface of the conveyor belt 20a, is located in FIG. 1 above the right drum 24.

The magnet system 30 is located inside the drum 24, but eccentrically to its axis and very precisely below the drop point 28. This magnet system 30, which has, for example, a concept according to DE 4 323 932 C1, but also in a different, conventional version can, is cylindrical in the illustration, the axis of rotation is horizontal and the cylindrical drum rotates clockwise in this illustration. The direction of movement 36 of the surface of the magnet system 30 in the area below the drop point 28, ie below the conveyor belt 20a, is thus exactly opposite to the direction of movement 26 of the conveyor belt 20a in this area.

From the point of view of an electrically more or less highly conductive particle falling from the conveyor trough 15 onto the conveyor belt 20a, it sees itself exposed to the influence of two forces above the conveyor belt 20a: on the one hand the currents induced by the magnetic lines, the it in 1 to the right, on the other hand the frictional forces of the conveyor belt 20a which want to move it to the left.

If the particle is a relatively good conductor, the magnetic forces will predominate and the particle will be conveyed to the right in a throwing parabola into a collecting container 41 located there.

If the ratio of electrical conductivity to the density of a particle is very small and therefore the discharge force is low, it is taken along by the conveyor belt and then falls at its corresponding end point in the area of the drum 23 into a second collecting container 42 already held there.

If particles are hooked to one another, lie on top of one another or hinder each other, they can be found over a certain period of time above the still rotating magnet system 30 and at the same time under the influence of the two forces mentioned. In the case of particles lying on top of one another or otherwise obstructing them, these forces naturally act in different directions and thereby lead to equalization and ultimately to the removal of the respective particles in the correct directions. Even if a movement in the wrong direction has already begun, for example by taking a small particle of one type with a larger and thus more influential particle of the other type, it still leads over a corresponding distance and thus time-acting Influence of both forces to the effect that this movement is also reversed and that the corresponding particle can move in the right direction after being released from its partner. Unlike a partition, wrong decisions are still reversible up to a certain point.

If the particle is an iron metal, ie a ferromagnetic material, it is attracted to the magnet system. So it runs with the conveyor belt and thus the less conductive particles and is thus separated from the non-ferrous metals. If desired, it can also be separated from the less highly conductive particles because it is magnetic Attraction tends to remain on the conveyor belt. However, sorting out the ferrous metals is also possible in another way and is preferably carried out in advance.

In FIG. 2, the mode of operation is basically the same as in FIG. 1, but in the illustration there the conveyor belt 20a is guided with its upper run 21 and its lower run 22 around three drums 23, 24 and 25, the conveyor belt 20a being guided by the is stretched between the two outer drums 23 and 24, while, in contrast to the first exemplary embodiment, the magnetic system 30 is again located eccentrically in the middle, largest drum 25.

In contrast to the representation in the first exemplary embodiment, the direction of movement 26 of the conveyor belt of the image representation is to the right, while the direction of movement 36 of the surface of the magnet system 30 leads to the left. So this is also the opposite direction.

The drop point 28 for the particles 2, 3 of the goods 1 to be sorted is located somewhat more centrally on the conveyor belt 20a, but also above the magnet system 30. This results in a somewhat longer influence of the conveyor belt or the forces exerted by it on the conveyor belt 20a Particles 2 with good electrical conductivity, which in the first exemplary embodiment are implemented more or less directly in a throwing parabola.

In the embodiment according to FIG. 3, the mode of operation essentially corresponds to the embodiment from FIG. 2. Here, the magnetic system 30 is constructed such that it largely fills the middle, largest drum 25; Furthermore, the left drum is also additionally adjustable in height, so that the inclination of the upper run 21 of the conveyor belt 20a can also be adjusted, if necessary depending on the type of material mixture to be sorted and fed.

It should also be mentioned that in an embodiment not shown, in addition to a movement in the opposite direction, it is also possible to change the direction of movement. to align lines 26 and 36 of the conveyor belt 20a or the surface of the magnet system 30 at an angle to one another.

Under certain circumstances, this can be interesting in order to also enable the sorting out of a third particle type if a further force component is added.

In the embodiment according to FIGS. 4 and 5, a different relative movement direction 26 and 36 of the conveying device 20 or the surface of the magnet system 30 is also carried out, but not for the sorting out of a third type of particle, but for a particularly expedient sorting out of the non-ferrous metals .

As already explained above, the goods to be sorted 1 are first guided to the drop point 28 via a conveyor belt 15b. At this drop point 28, the unsorted sorting material falls onto a conveyor trough 20b. The conveyor trough 20b can, for example, be made to convey the particles 2, 3 of the items 1 to be sorted on it by means of a vibrator (not shown) or simply by means of a corresponding inclination and inclination.

The magnetic system 30 is in turn arranged below the conveyor trough 20b. Here, however, this magnetic system 30 has an axis of rotation which lies parallel to the direction of conveyance of the particles on the conveying trough 20b. This means that the direction of movement 36 of the magnet system 30 - more precisely from its surface - is perpendicular to the direction of movement 26 of the goods to be sorted on the conveyor device 20.

As a result, the non-ferrous metals are laterally driven down in the same direction of movement 36 by the conveying device 20 or here conveying trough 20b and fall into a collecting container 41 which stands next to the conveying trough 20b.

The remaining components of the sorted goods 1, on the other hand, run to the end of the conveyor trough 20b and only fall there into a collecting container 42. In the schematic sectional or view illustration in FIG. 4, this process can be seen as it would result from the right in FIG. 5.

The conveying device 20 or the conveying trough 20b can, as indicated in the drawing, also be displaced and adjusted both in height and laterally. With this fine adjustment, it is even possible to carry out a separation of different non-ferrous metals from one another on the conveyor device 20, for example a separation of aluminum and tin, which was previously considered impossible in practice. The height adjustability and lateral displaceability of the conveyor trough relative to the magnet system 30 can bring the forces acting on the various elements of the sorted goods 1 into effect so that certain forces are sufficient, a certain type of sorted goods of the type Push down the trough and leave another variety on top.

The embodiment according to FIGS. 6 to 9 is designed similarly to that according to FIGS. 4 and 5. In addition, a second magnetic system 38 is provided in this embodiment, which has a direction of movement 39 of the surface above the conveyor device 20 - here one Conveyor trough 20b. The influence of the two magnet systems 30 and 38 on the particles running between them is thus very evened out, i.a. also by the fact that the second magnetic system 38 above the conveyor trough 20b can now reliably influence rolling or high-jumping particles of the goods to be sorted 1, which, due to their jumping behavior and other irregularities, have so far been unable to access the first magnet system 30 in individual cases, or were difficult to sort.

The increasing influences of the two magnet systems are illustrated in FIG. 9 by increasing angles.

The axes of the two magnet systems 30 and 38 run parallel and moreover parallel to the conveying direction on the conveying trough 20b. Certain win- kel are also conceivable, especially when additional, possibly desired complex influences appear sensible during the sorting process.

It is even possible to carry out a particle separation in which waste stocks with lead content are sorted in such a way that the lead-containing particles are separated from the others.

Under certain circumstances, it would even be possible to extract non-ferrous metals such as gold or silver from sand deposits.

The embodiments according to FIGS. 10 and 11 show, in accordance with that from FIGS. 4 and 5, a conveyor trough 20b with a non-flat bottom 27. However, the non-flat bottom 27 here is not only provided with a slightly raised center, but it is shaped like a circular section arched upwards. As a result, the particles come particularly close to the magnetic field, which is used particularly effectively in this way. The drum rotates, as it were, directly below the particles, transversely to their direction of conveyance, so that one type of particle collects in the relatively acute angle that forms between the base 27 and one side wall and the other type of particle collects exactly on the other side; Of course, it is also possible to omit parts of the side wall in order to remove the particles if this makes sense and because of the materials it is ensured that no particles then tend to stick to the drum surface.

Another embodiment is shown in FIGS. 12 and 13, in which a conveyor belt 20a does not move, but a conveyor belt 20a whose conveying direction 26 likewise runs perpendicular to the direction of movement 36 of the drum surface. With such a conveyor belt construction, similar advantages can be achieved.

In the embodiment according to FIG. 14, an additional application of a fluid from a fluid supply device 50, for example air from a PC17EP97 / 02536

18th

corresponding nozzle, made on the particles 2, 3 above the magnet system. In this way, it is possible to go into the individual specifications of the particles to be sorted in even greater detail. This version can be combined with all other illustrated embodiments.

P 7/02536

19

Reference list

I Sorted goods 2 electrically well conductive particles

3 electrically poorly conductive particles

I I feed device 15 conveyor trough

15b conveyor 20 conveyor

20a conveyor belt

20b conveyor trough

21 upper run

22 lower strand 23 outer drum

24 second outer drum

25 middle drum

26 Direction of movement of the conveyor 20

27 Bottom of the conveying device 28 Drop point of the sorted goods 1

30 magnetic systems

36 Direction of movement of the magnet system 30

38 2. Magnetic systems

39 Direction of movement of the magnet system 38 41 Collection container

42 collection containers

50 fluid supply device

Claims

claims

1. Device for particle separation of sorted material (1) in fractions of more or less good electrically conductive particles (2, 3), with a conveyor (20) onto which the particles (2, 3) are placed and one the conveying device (20) arranged rotating magnetic systems (30) and a collecting container (41) for the desired particle fraction, characterized in that the direction of rotation of the magnet system (30) is selected such that the directions of movement (26, 36) of the magnet system surface and the conveying device (20) are different.

2. Device according to claim 1, characterized in that the directions of movement (26, 36) of the surface of the Magnet¬ system (30) and the conveyor (20) are anti-parallel or at right angles to each other.

3. Apparatus according to claim 1 or 2, characterized in that the conveyor (20) is a conveyor belt (20a).

4. The device according to claim 3, characterized in that the conveyor belt (20a) has an upper run (21) and a lower run (22) and runs over at least two drums (23, 24) which tension the conveyor belt (20a) and that two Collecting containers (41, 42) are provided, each of which is arranged adjacent to the drums (23, 24) below them.

5. Device according to one of the preceding claims, characterized in that the magnetic system (30) is arranged in one of the drums (24, 25).

6. The device according to claim 5, characterized in that the magnetic system (30) is arranged eccentrically in the drum (24, 25).

7. Device according to one of the preceding claims, characterized in that three drums (23, 24, 25) are provided, of which the two outer (23, 24) span the conveyor belt (20a); and that in the third, between the two outer arranged drum (25), the magnetic system (30) is arranged.

8. Device according to one of the preceding claims, characterized in that one of the drums is arranged adjustable in height relative to the other.

9. Device according to one of the preceding claims, characterized in that the drop point (28) on the conveyor (20) is perpendicular to the magnet system (30).

10.Device according to one of the preceding claims, characterized in that a feed device (15) for the sorted material (1) to the conveying device (20) is provided, and that at least the area adjacent to the drop point (28) is made of a non-conductive material , in particular made of plastic.

1 1.Device according to claim 1 or 3, characterized in that the directions of movement (26,36) of the surface of the Magnet¬ system (30) and the conveyor (20) are substantially perpendicular to each other.

12.Device according to claim 1, 2 or 1 1, characterized in that the conveying device (20) is a particularly non-conductive, preferably made of plastic conveying trough (20b), in which the sorting material (1) running therein is preferably is promoted by gravity and / or vibration.

13. The apparatus according to claim 12, characterized in that the conveyor trough (20b) above the magnet system (30) has no side wall on one side and thus enables the non-ferrous metals to be separated out via this side into a collecting container (41), if necessary.

14.The device according to claim 12 or 13, characterized in that the conveying device (20) has a cross section transverse to the conveying direction, which has a non-flat bottom, in particular a bottom (27) having the highest point in its central region.

15. The apparatus according to claim 14, characterized in that the bottom (27) of the conveyor (20) is adapted to the drum shape, that is to say in particular is curved in the form of a circular section upwards in cross section.

16. Device according to one of claims 11 to 15, characterized in that the conveying device (20) with its conveying direction parallel to the axis of the rotating magnet system (30) is arranged closely above and laterally offset but overlapping to the uppermost peripheral portion

17. Device according to one of the preceding claims, characterized in that several sections of the conveyor (20) are provided with different relative arrangements to the magnetic system (30).

18. The apparatus according to claim 16 and 17, characterized in that the conveyor (20) is designed as a conveyor trough (20b) and several successively arranged sections at different heights and / or different lateral assignment to the upper center line of the magnet system and / or different have their own inclinations transverse to the conveying direction.

1 Θ.Device according to one of the preceding claims, characterized in that the conveyor (20) is adjustable laterally and / or in height.

20.Device according to one of the preceding claims, characterized in that a rotating magnet system (30, 38) is provided both below and above the conveying device (20), the directions of rotation of the two magnet systems (30, 38) being selected such that that the magnet system surfaces have the same directions of movement (36, 39) in the region facing each other.

2 I .Device according to one of the preceding claims, characterized in that a fluid supply device (50), in particular an air nozzle, is additionally provided in the area above the rotating magnet system.

22. Process for particle separation of sorted material (1) in fractions of more or less good electrically conductive particles (2, 3), with a conveyor device (20) onto which the particles (2, 3) are placed and one under ¬ half of the conveyor (20) arranged rotating magnet system (30) and a collecting container (41) for the sought particle fraction, characterized in that the direction of rotation of the magnet system (30) is selected so that the magnet system surface and the particles ( 2, 3) move in different directions.

23. The method according to claim 22, characterized in that the magnet system surface and the particles (2, 3) are moved in anti-parallel or mutually perpendicular directions.

24. The method according to claim 22 or 23, characterized in that the particles (2, 3) are acted upon by a fluid, in particular air, above the surface of the magnet system.