DE3622544A1 - Matrix ring magnetic separator - Google Patents

Abstract

The invention relates to a matrix ring magnetic separator whose induction bodies are formed by wire gauzes which are arranged vertically and stacked one behind the other in the direction of the magnetic field in such a manner that the intersection points of the wires of one wire gauze meet the free area of the adjacent wire gauze and, as a result, packs of wire gauzes, which give in the direction of the magnetic field, are formed. A magnetic separator of this type is characterised in that it can be dedusted well even in the case of very high field strength gradients and can additionally be produced cost-effectively.

Description

The invention relates to a matrix ring magnetic separator according to the preamble of claim 1.

A matrix ring magnetic separator of this type is through DE-A-34 04 216 known. The induction bodies are here by radial and spaced apart arranged rods formed in several rows arranged one below the other are that provided in adjacent rows Bars are staggered against each other. With such a magnetic separator can also Sorting of weakly magnetic substances carried out are achieved, with high throughput rates and easy cleaning of the induction body is possible.

The invention has for its object a Matrix ring magnetic separator which is the generic term of the type of claim 1 that while maintaining the above Advantages even when the goods are dry and application of very high field strength gradients reliable cleaning of the induction bodies is achieved.

This object is achieved by the characterizing Feature of claim 1 solved.  

According to the induction body through Screen fabric formed, arranged vertically and stacked one behind the other in the direction of the magnetic field are that the crossing points the wires of the one mesh to the free one Hit the field of the neighboring mesh and hereby in the direction of the magnetic field itself resilient packets of screen fabrics are formed.

In such an embodiment, the screen mesh can relax in the area outside the magnetic field, with the spaces between enlarge the wires of adjacent sieve fabrics. In this way, large grains and Foreign objects that clog the matrix could lead by means of a wet or dry Detergent reliably from the enlarged Remove gaps between the sieve mesh matrix.

The screen fabric induction body according to the invention can be used in dry and wet operation deploy. There are special advantages in Dry operation as there is a risk of clogging the matrix through grains and foreign bodies by relaxing the sieve fabric packages outside of the magnetic field and this made it possible easy cleaning practically impossible is.

According to an expedient embodiment of the invention can the cleaning of the matrix  further improve and at the same time the throughput significantly increase that at least in the area of Magnetic field, but also expedient outside of the magnetic field in the zone to detach the magnetic components of the good, above the Matrix ring air nozzles are arranged through which Blown compressed air jets into the matrix ring from above will. These compressed air jets are special when processing dry feed materials an effective transport aid that the Movement of the limited flowable feed material supported and accelerated by the screen mesh matrix, so that the throughput rate increases significantly and a desired cleaning of the adherent magnetic particle occurs. In the area outside of the magnetic field ensure the Compressed air jets in the springy relaxed Sieve mesh matrix with the enlarged hereby Interspaces a quick and reliable detachment of the magnetic particles from the screen mesh.

Appropriate configurations of the invention are Subject of the subclaims and are in connection with the description of an embodiment explained in more detail.  

Show in the drawing

Fig. 1 is a vertical section through a portion of the erfingsgemäßen Matrixring- magnetic separator,

Fig. 2 is a cross section along the line II-II of Fig. 1,

Figure (as seen in enlarged scale, in the direction of the magnetic field) is a view of a partial area of the screen mesh. 3,

Fig. 4 is a vertical section through a variant of the matrix ring (in the cut according to FIG. 1, but on an enlarged scale).

The matrix ring magnetic cutter shown contains a matrix ring 1 which can be rotated about a vertical axis and which is mounted in a housing 2 and is open at its top 1 a and bottom 1 b .

A solenoid coil 3 generates in a partial area of the matrix ring 1 an essentially circumferential magnetic field (its direction is schematically indicated in the matrix ring 1 by the arrow 4 ).

The feed of the dry goods is carried out via a chute 5 onto the top 1 a of the matrix ring 1 . The discharge of the non-magnetic material (arrow 6 ) emerging from the matrix ring 1 downward in the area of the solenoid coil 3 takes place via an air conveyor trough 8 or a slide with the required inclination.

In the area of the solenoid coil 3 , a number of air nozzles 9 are arranged above the matrix ring 1 , to which compressed air is supplied via an air line 10 . The sharp air jets generated by the air nozzles 9 penetrate the matrix ring 1 from top to bottom and form an effective transport aid for the dry material which can be poured to a limited extent.

Outside the area of the magnetic field generated by the solenoid coil 3 , in the zone serving to detach the magnetic components of the material (arrow 11 ), air nozzles 12 are likewise arranged, to which compressed air is supplied via a line 13 .

To extract the air emerging from the underside 1 b of the matrix ring 1 , at least one fan is provided, which is connected, for example, to the collecting funnel 14 used to discharge the magnetic product (arrow 11 ).

To reduce the intake of false air, a cover 15 or 15 a is arranged at a short distance above and below the matrix ring. Sealing elements 16 , such as brushes or rubber seals, are provided between these stationary covers 15, 15 a and the rotatable matrix ring 1 . In this way, in particular the zone containing the air nozzles 9 is sealed in the direction of the magnetic field and transversely to the direction of the magnetic field by sealing elements 16 against air leakage or air entry. The negative pressure occurring in the area of these sealing elements 16 is very low.

Intermediate walls 17 , which divide the matrix ring into individual chambers in the circumferential direction, also contribute to reducing the amount of false air sucked in. These intermediate walls 17 also form an effective guide for the compressed air jets supplied through the air nozzles 9 and 12 and prevent a lateral deflection of the flow.

The air nozzles 9 provided in the area of the magnetic field are distributed over a zone whose length (in the direction of the magnetic field) and whose width (transverse to the direction of the magnetic field) corresponds to the length and width of the chambers of the matrix ring 1 formed by the partition walls 17 .

The distance between the sealing elements 16 in the direction of the magnetic field is equal to the distance between successive partition walls 17 .

By contrast, the air nozzles 12 provided outside the area of the magnetic field are distributed over a zone whose length (in the circumferential direction of the matrix ring) is greater than the length of the individual chambers of the matrix ring formed by the partition walls 17 (the width of the zone over which the air nozzles 12 distributed, corresponds to the width of the individual chambers of the matrix ring).

The matrix ring 1 contains soft magnetic material in the partition walls, between which there are essentially vertical channels for the material to be subjected to the magnetic separation.

According to the invention, the induction bodies are formed by screen mesh 18 , which are arranged vertically and stacked one behind the other in the direction of the magnetic field (arrow 4 ) such that the crossing points of the wires of one screen mesh (e.g. 18 according to FIG. 3) onto the free field of the adjacent one Sieve cloth 18 ' meet. This results, so to speak, in a "bar-on-gap" arrangement (cf. FIG. 3). The individual sieve fabrics fit together well due to their weave and together form a sieve fabric package that springs in the direction of the magnetic field. Under the effect of the magnetic field, these sieve mesh packets are compressed while they expand again outside the magnetic field. The resulting enlargement of the spaces in the screen mesh package, together with the effect of the compressed air jets, favors the cleaning of the matrix in the area outside the magnetic field and thus results in an effective removal of the magnetic product (arrow 11 ).

Such a screen fabric matrix is also characterized by a very dense packing and high field strength gradients with at the same time inexpensive production. If, during the movement of the matrix ring, a certain chamber of the matrix ring leaves the area of the magnetic field of the solenoid coil 3 , the sieve fabric package expands like an accordion, the gaps between the wires of adjacent sieve fabrics being able to double, for example, when they spring apart.

From a design point of view, care must be taken to ensure that the sieve fabric packs can contract and relax within the chambers of the matrix ring 1 formed by the partition walls 17 in the direction of the magnetic field, without any free spaces occurring during the contraction. This can be achieved, for example, by means of movable partition walls or elastic intermediate layers. The sealing elements 16 also prevent the feed material from penetrating into the spaces created when the screen mesh package is contracted.

The length of the sieve fabric packages 18 in the direction of the magnetic field is expediently 80 to 120 mm.

When operating the magnetic separator shown the speed of the top of the matrix ring injected compressed air jets between 5 and 20 m / s lie.  

It is possible within the scope of the invention to reduce the air consumption to apply air to the air nozzles 9 periodically when a chamber of the matrix ring 1 formed by two successive partition walls 17 is located in the zone of the air nozzles. The next air is applied to the air nozzles 9 only when the matrix ring has moved on by the length of a chamber.

In the variant illustrated in FIG. 4, sieve cloth 18 a is provided in the upper region of the matrix ring 1 , the wires of which have a greater distance from one another in the direction of the magnetic field (arrow 4 ) than the wires of the sieve cloth 18 b arranged in the lower region of the matrix ring. The magnetic separation begins here in the upper area of the matrix ring with a low field strength, so that the stronger magnetic particles are deposited in the sieve fabrics 18 a . In the lower area of the matrix, where the field strength is higher, the pre-separation of the more magnetic particles has already taken place. In this way, a multistage magnetic separation without bridging is achieved for a feed with a wide range of susceptibility.

In order to prevent magnetic short circuits, the vertical wires of the screen cloth 18 are expediently made of non-magnetic material, while the horizontal wires are made of soft magnetic material. For cost reasons, however, the vertical wires can also be made of soft magnetic material. The packs of screen fabrics 18 can also be designed to be self-supporting and therefore do not require a separate housing, which considerably simplifies manufacture and maintenance.

Claims (19)

1. Matrix ring magnetic separator, containing
a) a matrix ring ( 1 ) which can be rotated about a vertical axis and which is open at the top and bottom and contains a large number of induction bodies made of soft magnetic material, between which there are essentially vertical channels for the material to be subjected to magnetic separation,
b) at least one solenoid coil ( 3 ) which generates a magnetic field running essentially in the circumferential direction in a partial area of the matrix ring ( 1 ),
c) a device for feeding the material in the area of the magnetic field onto the top of the matrix ring ( 1 ),
d) a zone for the downward removal of the non-magnetic components of the material in the area of the magnetic field,
e) a zone arranged outside the magnetic field for detaching the magnetic components of the material from the induction bodies and for removing these components downwards, characterized by the following feature:
g) the induction bodies are formed by screen fabrics ( 18 ) which are arranged vertically and stacked one behind the other in the direction of the magnetic field in such a way that the crossing points of the wires of the one screen fabric (e.g. 18 ) point to the free field of the adjacent screen fabric (e.g. . 18 ' ) meet and are thereby formed in the direction of the magnetic field in resilient packages of screen fabrics. 2. Magnetic separator according to claim 1, characterized in that the vertical wires of the screen fabric ( 18 ) consist of non-magnetic material. 3. Magnetic separator according to claim 1, characterized in that the packages of screen fabrics ( 18 ) are self-supporting. 4. Magnetic separator according to claim 1, characterized by such an arrangement of the screen fabric ( 18 ) that the packets of screen fabrics ( 18 ) compressed in the area of the magnetic field can relax resiliently outside the area of the magnetic field. 5. Magnetic separator according to claim 1, characterized in that in the upper region of the matrix ring ( 1 ) screen fabric ( 18 a ) are provided, the wires of which are at a greater distance from one another in the direction of the magnetic field than the wires of the screen fabric arranged in the lower area of the matrix ring ( 18 b ). 6. Magnetic separator according to claim 1, characterized by relinquishing the goods in a dry state. 7. Magnetic separator according to claim 1, characterized by relinquishing the goods in the wet state. 8. Magnetic separator according to claim 6, characterized in that at least in the area of the magnetic field, but preferably also outside the area of the magnetic field in the zone for detaching the magnetic components of the material, above the matrix ring ( 1 ) air nozzles ( 9, 12 ) are arranged through which compressed air jets are blown into the matrix ring ( 1 ) from above. 9. Magnetic separator according to claim 1, characterized in that the matrix ring ( 1 ) is divided in the circumferential direction by partition walls ( 17 ) into individual chambers, each of which receive a screen fabric package ( 18 ). 10. A magnetic separator according to claim 9, characterized in that the air nozzles ( 9 ) provided in the region of the magnetic field are distributed over a zone, the length (in the direction of the magnetic field) and the width (transverse to the direction of the magnetic field) of the length and width of the corresponds to individual chambers of the matrix ring ( 1 ). 11. Magnetic separator according to claim 10, characterized in that the zone containing the air nozzles ( 9 ) in the direction of the magnetic field and transverse to the direction of the magnetic field is sealed by sealing elements ( 16 ) against air leakage. 12. Magnetic separator according to claim 11, characterized in that the distance between the sealing elements ( 16 ) in the direction of the magnetic field corresponds to the distance between successive partition walls ( 17 ). 13. Magnetic separator according to claim 8, characterized in that at least one fan is provided, through which the compressed air jets acting on the matrix ring ( 1 ) in the vertical direction are blown from above into the matrix ring ( 1 ) and suctioned down. 14. Magnetic separator according to claim 1, characterized in that the length of the sieve fabric packages ( 18 ) in the direction of the magnetic field is 80 to 120 mm. 15. Magnetic separator according to claim 9, characterized in that the air nozzles ( 12 ) provided outside the region of the magnetic field are distributed over a zone whose width corresponds to the width of the individual chambers of the matrix ring ( 1 ) and whose length is greater than the length of the individual Chambers of the matrix ring is. 16. Method of operating a magnetic separator according to claims 8 and 10, characterized in that the speed of the top compressed air jets blown into the matrix ring is between 5 and 20 m / s. 17. The method according to claim 16, characterized in that the air is applied to the air nozzles ( 9 ) periodically when a chamber of the matrix ring ( 1 ) is in the zone of the air nozzles. 18. Magnetic separator according to claim 1, characterized in that the screen fabrics stacked in the field direction ( 18, 18 ' ) have different mesh sizes and / or different wire diameters, the coarse fabric serving as a spacer for increasing the vertical gaps, while the fine fabric the field gradients generated.