KR200324497Y1 - conveyor's magnetic feeding roller - Google Patents

Abstract

The present invention relates to a magnetic conveying roller for a conveyor which is mounted inside a belt conveyor and drives together with the conveyor and is used for precisely feeding a plate metal material.

The present invention is a rotating shaft 11, a plurality of magnet holders 20 are axially coupled to maintain a predetermined interval on the rotating shaft 11, before and after the front and rear of each of the magnet holder 20 is attached to 1 The magnet 30 is composed of a filler 40 interposed between each of the magnet holder 20.

The present invention is a magnetic force (W) generated in the right angle direction (L) of the shaft by the magnet holder 20 and the magnet 30 is transferred by firmly adhering the material (S) to the surface of the conveyor (belt (B)) Precise surface processing or printing of material is possible.

Description

Magnetic conveyor roller for conveyors {conveyor's magnetic feeding roller}

The present invention relates to a magnetic conveying roller for a conveyor, and more particularly, to a magnetic conveying roller for a conveyor, which is installed inside a belt-type conveyor to drive together with a conveyor and is used for precisely feeding a plate metal material. will be.

In the conveyor for conveying the object, in particular, the belt conveyor is used for the purpose of conveying the metal object by applying a magnet (magnet).

Conventional magnetic conveyors are mainly used for transferring metal debris and the like, and have a configuration in which a magnet is used to arrange a magnet to maintain a predetermined distance to a belt.

The magnetic conveyor described above is not only difficult to manufacture, but also is not suitable for the purpose of precisely accelerating the object because the magnetic force generated in the vertical direction (ultimately upward direction of the conveyor) is not strong.

The present invention relates to a magnetic feed roller that can be installed on a belt conveyor to precisely transfer materials. The present invention provides a combination of a plurality of magnets on a rotating shaft to generate a strong magnetic force in the direction perpendicular to the axis. We want to provide the completed magnetic roller for conveyor.

1 is an exploded perspective view showing a preferred embodiment of the magnetic feed roller proposed in the present invention.

Figure 2 is a partial cross-sectional view showing a combined state of the present invention

Figure 3 is a reference cross-sectional view showing one embodiment of a conveyor to which the present invention is applied.

▣ Explanation of Codes for Major Parts of Drawing

10: Magnetic feed roller 11: rotary shaft

12: fixing clamp 20: magnet holder

21: Boss 22: Axis

30: magnet 31: coupling hole

40: Filler 41:

C: Conveyor D: Belt

P: drive shaft

1 is an exploded perspective view showing a preferred embodiment of the magnetic transport roller 10 for a conveyor presented in the present invention, as shown in the present invention, the rotation axis 11 and a predetermined interval on the rotation axis 11 Interposed between a plurality of magnet holders 20 that are axially coupled to maintain a plurality of magnet holders, a pair of magnets 30 that are attached to the front and rear sides of each of the magnet holders 20, and each of the magnet holders 20. It is composed of a filler 40, each of the magnet holder 20 and the drive assembly (D) made of a combination of the magnet 30 and the filler 40 is fixed on the rotating shaft 11 by a fixed clamp 12 It is rotated together with the rotating shaft (11).

The rotating shaft 11 is made of a non-magnetic material such as pure stainless steel, each magnet holder 20 is axially coupled on the rotating shaft 11 is made of a magnetic material, the respective magnet holder 20 The magnet 30 is attached to the front and rear of the magnet in the form of a disk that generates the N pole and the S pole in the axial direction, the magnet 30 between each of the magnet holder 20 coupled to the front and rear The plurality of cylindrical fillers 40 interposed are made of a nonmagnetic material such as polypropylene or polyethylene resin. At this time, the rotating shaft 11 may also use a nonmagnetic material such as a wear resistant resin. In order to achieve the material of the rotating shaft 11 must be made of a nonmagnetic material.

2 is a cross-sectional view showing a coupling state of the present invention, as shown in the magnet holder 20 is axially coupled to the rotating shaft 11 is provided with a boss 21 that protrudes back and forth inside the boss It is coupled to the rotary shaft 11 by the shaft hole 22 formed in the, and attaches the magnet 30 in the form of a disk, the coupling hole 31 is formed on the boss 21 of the magnet holder 20.

At this time, each magnet 30 attached to the front and rear of each magnet holder 20 is attached so that the N pole and the S pole alternately, each magnet attached to the front and rear with the magnet holder 20 therebetween ( The north pole and the south pole of 30) should be faced to each other because the north pole and the south pole do not face each other with the magnet holder 20 interposed (the north pole and the south pole, or the south pole and the south pole face each other. This is because, even if the magnetism of the magnet 30 is displaced to the magnet holder 20, the magnetic force displaced to the magnet holder 20 does not occur in the right angle direction L of the shaft.

The ultimate goal of the present invention is to allow a strong magnetic force to be exerted in the right-angle direction (L) of the rotary shaft 11, the combination (array) of the magnet holder 20 and the magnet 30 in the present invention Relationships will be very important.

Substantially, in the case where only the magnet 30 is alternately coupled to the north pole and the south pole without interposing a magnetic material (magnet holder 20) between the magnets 30, the combined magnets 30 are axially ( Strong magnetic force is generated only in the N-pole and S-pole directions, and only a very weak magnetic force is generated in the right-angle direction (L) of the axis, which is no difference from a conventional bar magnet composed of N-pole and S-pole. .

3 is a reference cross-sectional view showing an embodiment of the conveyor to which the present invention is applied, and the magnetic feed roller 10 for the conveyor presented in the present invention is installed before and after the belt-type conveyor C as shown. A plurality of drive shafts P are arranged and used. In this case, each of the magnet holder 20 and the drive assembly D formed of a combination of the magnet 30 and the filler 40 has an inner upper surface of the belt B. The magnetic feed roller 10 is to be driven together with the belt (B) by being connected to it.

The present invention has a significant magnetic force (W) is generated in the magnet holder 20 in the perpendicular direction (L) of the shaft by the magnet 30 arranged on the front and rear of the magnet holder 20, which is a magnetic body, the magnetic force generated above ( Since the metal material S loaded on the upper surface of the belt B by W) is tightly and firmly adhered to the belt B, the material S can be precisely conveyed.

On the other hand, in the above embodiment has been described for the configuration using the magnetic feed roller 10 is applied to the conveyor (C), the magnetic feed roller 10 proposed in the present invention is generated in the direction perpendicular to the axis (L) of the shaft Of course, it can also be used as a component of other devices to obtain a strong magnetic force.

Magnetic conveyor roller 10 for the conveyor proposed in the present invention is to be able to exert a strong magnetic force in the direction perpendicular to the axis, conveyed while conveying the plate-like metal material to the belt-type conveyor (C) provided with the magnetic conveyor roller 10 The magnetic force (W) generated in the perpendicular direction (L) of the shaft by the magnet holder 20 and the magnet 30 when the desired material is to be processed, the material (S) firmly on the surface of the conveyor (belt (B)) It is possible to precisely surface process or print the material to be transported by closely contacting it, and since the magnetic force does not occur on the rotating shaft 11 protruding to the outside of the conveyor C, foreign substances such as metal dregs are attached to deteriorate performance or equipment. There is an effect such as to prevent the appearance of the dirty.

Claims (1)

A rotating shaft 11 made of a nonmagnetic material such as pure stainless steel; A plurality of magnet holders 20 formed of a magnetic material and axially coupled to maintain a predetermined distance on the rotating shaft 11; A magnet 30 in the axial direction, the magnet 30 being attached so that the N pole and the S pole are alternately attached to the front and rear sides of the magnet holder 20; It is made of a non-magnetic material such as polypropylene or polyethylene resin, and the magnetic transport roller for a conveyor, characterized in that consisting of a filler 40 interposed between each magnet holder (20).