DE3248193C2 - - Google Patents

Description

The invention relates to a roller magnetic conveyor for Chips and other parts made of magnetic material, consisting of at least one rotating driven hollow conveyor roller made of non-magnetic material and arranged in this firmly on an axial support Permanent magnets.

Such a roller magnetic conveyor is from DE-OS 26 21 120 became known. On an axially inside The tube arranged on the conveyor roller are perpendicular in the plane to the axis direction several permanent magnets, their surface have the same radial distance from the axis, known become. Only the last magnet is flattened so that the chips do not suddenly move out of the magnetic field into one only get into space filled with gravity because otherwise the chips against gravity and against Friction of the rotating conveyor roller in the area of end of the last permanent magnet would accumulate here to form a larger agglomerate would. Coarser chips and other larger parts This magnetic roller conveyor is made of magnetic material but only with difficulty. These parts remain usually at the beginning of the conveyor track on the circumference of the conveyor roller hang under the influence of magnetic forces  and can only be by protrusions on the surface of the Conveyor rollers that take these parts out of the magnetic Lift out the force field, be promoted.

However, this roller magnetic conveyor promotes after DE-OS 26 21 120 chips better than those equipped with conveyor belts Conveyors such as B. from US-PS 38 58 710 are known.

The invention overcomes the disadvantages of the prior art Technology. It is the object of the invention to make one safe all chips collecting and removing roller magnetic conveyors to create one with enough Magnetic power reserve is equipped.

The invention is that between the axially magnetized permanent magnet pole pieces on the common axial supports are mounted that the polarity the permanent magnet is such that the on the pole piece repel the end faces of the permanent magnets and the abutting end faces of the permanent magnets get dressed and that the outer surface of the pole pieces is spirally formed.

This roller magnetic conveyor promotes through its sufficient Magnetic power reserve and by design the outer surface of the pole pieces small and large Chips and other parts made of magnetic material, even of complicated form, certainly without this Parts get caught somewhere in the magnetic field. This will gripping the chips even with a larger flow the coolant ensured. Here is the Funding impact even in poor conditions perfect. The sponsor works just as well  magnetic filter. That in the direction of funding continuously decreasing magnetic field supports thereby the flow of the magnetic material.  

Another advantage lies in the possibility of essentially arbitrary dimensioning of the conveyor rollers accordingly the wishes of the various customer requirements.

The essence of the invention is based on one in the Drawing schematically illustrated embodiment explained. It shows

Fig. 1 shows a longitudinal section through the magnetic conveyor and the promotion roller,

Fig. 2 shows a cross section through the promotion roller,

Fig. 3 shows the direction of funding.

The magnetic conveyor consists of a drive shaft 1 which is mounted by means of the bearings 2 in a flange 3 which is fixedly connected to the supporting structure 4 of the magnetic conveyor. A cover 6 is firmly connected to the drive shaft 1 by means of the wedge 5 . On this cover 6 , a conveyor roller 7 is fixed, which is firmly connected on the second side to the rear cover 8 , which is rotatably mounted on the rear flange 12 . The drive shaft 1 is further z. B. slidably mounted by means of the bushing 9 in the shaft 10 of the conveyor, the other end of the shaft 10 of the conveyor being fixedly connected to the supporting structure 4 by a second wedge 11 by means of the rear flange 12 . The permanent magnets 13 are attached to the shaft 10 of the conveyor. The magnetization of the permanent magnets 13 (toroids) is in the axial direction 16 and the magnetic polarity is carried out alternately according to FIG. 1. Pole shoes 14 , the spiral shape of which is shown in FIG. 2, are inserted between the magnet pairs. The permanent magnets 13 and the pole shoes 14 are secured on the shaft 10 of the conveyor against displacement by a nut 15 . The position of the pole shoes 14 on the shaft 10 of the conveyor is still z. B. by a wedge u. secured.

The magnetic conveyor for chips described works as follows:

The drive shaft 1 rotates the conveyor roller 7 , which is made of a non-magnetizable rustproof steel, alternatively made of rubber, plastic and the like. Ä. Is made, while the shaft 10 of the conveyor made of the non-magnetizable material with the permanent magnets 13 and the pole pieces 14 is stationary. The pole shoes 14 are made of a soft steel (sheet metal) so that their thickness is equal to 0.15 to 0.2 of the magnet thickness used. This arrangement creates a strong magnetic field, which ensures the operation of the conveyor. The individual conveyor rollers are arranged one behind the other, such as. B. in a mechanical roller conveyor. This arrangement allows the production of different forms of conveyor, z. B. of straight, broken, multiple broken conveyors, without any intervention in the conveyor roller construction - only the pole shoes are rotated in a position corresponding to the direction of conveyance (horizontal, oblique, vertical direction; the conveyance on the top or bottom of the roller - see examples in Fig. 3).

The pole piece 14 has a spiral shape which changes the magnetic field strength such that minimal forces occur at the locations where the magnetic field of one roller or roller is minimal (represented by the distance "A" in FIG. 2) with the following Roller or roller but the maximum force is present (represented by the distance "B"). In this way, the conveyed chips (of material) slide away from one roller or roller onto the other. Here, the conveyed material is transferred by the rotation of the conveying roller 7 to the point of further sliding away and the whole cycle is repeated on the entire chip conveying path (material conveying path). This ensures smooth chip transport regardless of the direction of conveyance and regardless of whether the chips are conveyed on the top or bottom of the roller. For a different conveying direction or for conveying on the underside of the roll, the pole shoes 14 are to be rotated. In Fig. 3, the Polschuheinstellung is shown for promoting direction 17 on the roller top.

Another advantage of the specified construction is in that there are no magnetic shorts that occur in a A number of well-known promoters to transport longer Make chips or longer components impossible. A yet another advantage lies in the reduction in together with the chips discharged coolant about ¹ / ₃ in Comparison with the known magnetic conveyors.

In comparison with the known conveyors for chips, the Delivery rate for the same masses at least twice as high with about half the power requirement of the electric motor. In the manufacture of this conveyor, the sink Handicraft requirements.  

List of the reference symbols used

1 - drive shaft
2 - bearings
3 - flange
4 - supporting structure
5 - wedge
6 - lid
7 - (rotatable) feed roller
8 - back cover
9 - socket
10 - (common) shaft of the conveyor
11 - second wedge
12 - rear flange
13 - permanent magnet
14 - pole piece
15 - mother
16 - axial direction
17 - Direction of funding

Claims (1)

Roller magnetic conveyor for chips and other parts made of magnetic material, consisting of at least one rotating hollow conveyor roller made of non-magnetic material and permanent magnet arranged in it on an axial support, characterized in that
that pole shoes ( 14 ) are mounted on the common axial carrier ( 10 ) between the permanent magnets ( 13 ) magnetized in the axial direction ( 16 ),
that the polarity of the permanent magnets ( 13 ) is such
that the end faces of the permanent magnets ( 13 ) abutting the pole piece ( 14 ) repel each other and the abutting end faces of the permanent magnets ( 13 ) attract each other,
and that the outer surface of the pole shoes ( 14 ) is spiral.