CN217200619U - Transmission device of magnetic shoe - Google Patents

Abstract

The utility model discloses a transmission device of magnetic shoe, include: the feeding end of the first feeding mechanism is connected with the discharge hole of the grinding machine; the feeding end of the second feeding mechanism is connected with the discharge hole of the other grinding machine; and the wire doubling mechanism comprises a carrying assembly, a conveying assembly, a first overturning assembly and a second overturning assembly, wherein the first overturning assembly and the second overturning assembly are arranged on two sides of the conveying assembly, the carrying assembly carries the magnetic shoe from the first feeding mechanism to the first overturning assembly, the carrying assembly carries the magnetic shoe from the second feeding mechanism to the second overturning assembly, the first overturning assembly and the second overturning assembly place the magnetic shoe on the conveying assembly after overturning, and the conveying assembly conveys the magnetic shoe to the same rear-end processing production line. The utility model provides a transmission device of magnetic shoe obviously practices thrift space, optimizes personnel's framework, improves and produces the line productivity and match. Meanwhile, the broken tile deleting and the magnetic tile turning-over are completed in the doubling process, and the operation process on the rear-end processing assembly line can be better executed.

Description

Transmission device of magnetic shoe

Technical Field

The utility model relates to a magnetic shoe production field especially relates to a transmission device of magnetic shoe.

Background

A magnetic shoe is a tile-shaped magnet of permanent magnets mainly used on permanent magnet motors, and below the curie temperature, there are many small regions inside ferromagnetic or ferrimagnetic materials, each having a spontaneous magnetic moment, and the magnetic moments are paired. If they are arranged in a disorientation way and magnetized without a magnetic field, the magnetic moment is zero as a whole, and the small areas are called magnetic tiles.

In the prior art, all links such as feeding, blanking, overturning, detection and the like in the production of the magnetic tiles basically realize automation, but the matching among all links still has the defects of unsmooth connection, unreasonable combination and the like, for example, one magnetic tile grinding machine in one magnetic tile factory is correspondingly connected with one discharge assembly line, then each discharge assembly line is correspondingly connected with one rear end processing assembly line, and each rear end processing assembly line is correspondingly equipped with worker operation. The problems of excessive production equipment, large occupied space, large labor demand and the like in the magnetic shoe factory can be caused, so that the production line in the existing magnetic shoe factory has places needing optimization and improvement, for example, a plurality of discharging lines can be integrated to share one rear end processing line, and thus, the occupied space can be greatly reduced, and the production cost can be reduced.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve the production water line of magnetic shoe among the above-mentioned prior art too much lead to the technical problem of wasting of resources, provide a transmission device of magnetic shoe.

The utility model adopts the technical proposal that:

the utility model provides a transmission device of magnetic shoe, include:

the feeding end of the first feeding mechanism is connected with the discharge hole of the grinding machine;

the feeding end of the second feeding mechanism is connected with the discharge hole of the other grinding machine;

the wire doubling mechanism comprises a carrying assembly, a conveying assembly, a first overturning assembly and a second overturning assembly, wherein the first overturning assembly and the second overturning assembly are arranged on two sides of the conveying assembly, the carrying assembly carries the magnetic shoe from the first feeding mechanism onto the first overturning assembly, the carrying assembly carries the magnetic shoe from the second feeding mechanism onto the second overturning assembly, the first overturning assembly and the second overturning assembly overturn the magnetic shoe and then place the magnetic shoe on the conveying assembly, and the conveying assembly conveys the magnetic shoe onto the same rear end processing assembly line.

In an embodiment, first upset subassembly with second upset subassembly all include with conveying assembly's direction of transfer parallel arrangement's axis of rotation, drive axis of rotation pivoted motor, even interval is provided with a plurality of places in the axis of rotation the piece of placing of magnetic shoe, it is ARC structure to place the piece, place the bellied curved surface directly over the piece and place the magnetic shoe, all place the piece and be located the axis of rotation with conveying assembly one side relative, the axis of rotation drives all place the piece court conveying assembly overturns.

In one embodiment, the carrying assembly comprises a moving plate, a plurality of vacuum chucks for sucking the magnetic shoes are uniformly arranged on the moving plate at intervals, a vertical guide rail connected with one end of the moving plate in a sliding manner, and a horizontal guide rail connected with the vertical guide rail in a sliding manner, and the sucking surface of each vacuum chuck faces to the right lower side.

In an embodiment, the first feeding mechanism includes a first feeding assembly and the carrying assembly, the first feeding assembly includes a first feeding slide way and a first conveyor belt arranged below the first feeding slide way, a feeding end of the first feeding slide way is obliquely arranged, a discharging end of the first feeding slide way is provided with a first valve, a joint of the first conveyor belt and the wire merging mechanism is located below the first overturning assembly, and the carrying assembly carries the magnetic tiles on the first feeding slide way onto the first conveyor belt.

In an embodiment, the second feeding mechanism includes a second feeding assembly and the carrying assembly, the second feeding assembly includes a second feeding chute and a second conveyor belt disposed below the second feeding chute, a feeding end of the second feeding chute is disposed in an inclined manner, a discharging end of the second feeding chute is provided with a second valve, a connection position of the second conveyor belt and the wire merging mechanism is located below the second overturning assembly, and the carrying assembly carries the magnetic tiles on the second feeding chute onto the second conveyor belt.

In an embodiment, the first feeding mechanism and the second feeding mechanism are symmetrically distributed on two sides of the doubling mechanism, and the conveying direction of the first feeding mechanism and the conveying direction of the second feeding mechanism are perpendicular to the conveying direction of the conveying assembly.

In an embodiment, a first notch is arranged on the feeding end of the first feeding slide way and used for screening the cracked magnetic tiles, and collecting boxes for placing the magnetic tiles are arranged below the first notch and below the discharging end of the first feeding slide way.

In an embodiment, a second notch is arranged on the feeding end of the second feeding slide way, the second notch is used for screening the cracked magnetic tiles, and collecting boxes for placing the magnetic tiles are arranged below the second notch and below the discharging end of the second feeding slide way.

Further, a first inductor is arranged at the tail end of the first conveyor belt, and when the first inductor induces that the magnetic shoes conveyed by the first conveyor belt reach a preset position, the first conveyor belt stops moving.

Furthermore, a second sensor is arranged at the tail end of the second conveyor belt, and when the second sensor senses that the magnetic shoes conveyed by the second conveyor belt reach a preset position, the second conveyor belt stops moving.

Compared with the prior art, the utility model provides a doubling mechanism among transmission device of magnetic shoe not only merges into one with two independent magnetic shoe feeding assembly lines, lets a rear end processing assembly line of two independent magnetic shoe feeding assembly lines ability sharing, and this is compared with the design that a magnetic shoe feeding assembly line was furnished with a back end processing assembly line among the prior art, has reduced the quantity on the rear end processing assembly line, has reduced production facility's area, has reduced manufacturing cost. Meanwhile, the doubling mechanism completes the operation of the reverse side of the magnetic tiles through the first overturning assembly and the second overturning assembly while combining the two magnetic tile feeding assembly lines, and reduces the operation links of the rear section processing assembly line.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.

Fig. 1 is a schematic view of an overall structure of a transmission device for magnetic shoes according to an embodiment of the present invention;

fig. 2 is a schematic overall structure diagram of a first feeding mechanism in an embodiment of the present invention;

fig. 3 is a schematic overall structure diagram of a second feeding mechanism in an embodiment of the present invention;

fig. 4 is a schematic view of the overall structure of the wire-doubling mechanism in the embodiment of the present invention;

1. a first feeding mechanism; 11. a first feed chute; 12. a first conveyor belt; 13. a first valve; 14. a first notch; 15. a collection box;

2. a second feeding mechanism; 21. a second feed chute; 22. a second conveyor belt; 23. a second valve; 24. a second notch;

3. a wire doubling mechanism; 31. a first flipping component; 32. a second flipping component; 33. a third conveyor belt; 34. a first sensor; 35. a second sensor; 311. a rotating shaft; 312. placing the blocks; 313. a motor;

4. a handling assembly; 41. moving the plate; 42. a vertical guide rail; 43. a horizontal guide rail; 44. a vacuum chuck;

5. and (4) magnetic tiles.

Detailed Description

In order to make the technical problem, technical solution and advantageous effects to be solved by the present invention more clearly understood, the following description is given in conjunction with the accompanying drawings and embodiments to illustrate the present invention in further detail. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

In the description of the present invention, it is to be understood that the terms "center", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood according to specific situations by those of ordinary skill in the art.

In order to solve among the prior art problem that back end processing water line quantity is too much to cause wasting of resources such as area is big, manufacturing cost height, the utility model provides a transmission device of magnetic shoe, include:

the feeding end of the first feeding mechanism is connected with the discharging hole of the grinding machine, and the magnetic shoe is conveyed to the doubling mechanism;

the feeding end of the second feeding mechanism is connected with the discharge hole of the other grinding machine, and the magnetic shoe is conveyed to the doubling mechanism;

and the wire doubling mechanism comprises a carrying assembly, a conveying assembly, a first overturning assembly and a second overturning assembly, wherein the first overturning assembly and the second overturning assembly are arranged on two sides of the conveying assembly, the carrying assembly carries the magnetic shoe from the first feeding mechanism to the first overturning assembly, the conveying assembly carries the magnetic shoe from the second feeding mechanism to the second overturning assembly, the first overturning assembly and the second overturning assembly place the magnetic shoe on the conveying assembly after overturning, and the conveying assembly carries the magnetic shoe from the first feeding mechanism and the second feeding mechanism to the same rear end processing production line.

To sum up, the utility model provides a doubling mechanism among transmission device of magnetic shoe not only merges into one with two independent magnetic shoe feeding assembly lines, lets a rear end processing assembly line of two independent magnetic shoe feeding assembly lines ability sharing, and this is compared with the design that a magnetic shoe feeding assembly line was furnished with a back end processing assembly line among the prior art, has reduced the quantity on the rear end processing assembly line, has reduced production facility's area, has reduced manufacturing cost. Meanwhile, the doubling mechanism completes the operation of the reverse side of the magnetic tiles through the first overturning assembly and the second overturning assembly while combining the two magnetic tile feeding assembly lines, and reduces the operation links of the rear section processing assembly line.

The principles and structure of the present invention will be described in detail below with reference to the accompanying drawings and examples.

As shown in fig. 1 to 4, in the present embodiment, a first feeding mechanism 1 and a second feeding mechanism 2 are symmetrically provided on both left and right sides of a doubling mechanism 3, the first feeding mechanism and the second feeding mechanism are provided in the X-axis direction, and the conveying direction of the conveying assembly in the doubling mechanism is the Y-axis direction.

Further, as shown in fig. 1 and 2, the first feeding mechanism 1 includes: the first feeding assembly and the carrying assembly are arranged on the operating platform, and the first feeding assembly comprises a first feeding slide way 11 and a first conveyor belt 12 arranged below the first feeding slide way. First feeding slide passes through the support mounting and has a distance on the operation panel and between first feeding slide and the operation panel, and first feeding slide 11 includes the straightway of slope section and slope section end connection, and the slope section is the feed end of first feeding slide, and the discharge gate of grinding machine is connected to the feed end, is equipped with first valve 13 at the end of straightway (being the discharge end of first feeding slide), and the magnetic shoe that produces from the grinding machine gets into first feeding slide and slides to straightway orderly arrangement under the action of gravity from the slope section. In order to screen out broken and cracked magnetic shoes in time, a first notch 14 is arranged on the inclined section, a collecting box 15 is arranged below the first notch, and the broken magnetic shoes can leak out of the first notch to the collecting box after entering the inclined section. Simultaneously, also be equipped with in the below of the terminal (the discharge end of first feeding slide) of straightway and collect box 15, if back end processing equipment breaks down but when the grinding machine can normally produce the magnetic shoe, need in time stop the conveying of magnetic shoe, so can open first valve this moment, let the magnetic shoe temporarily place in collecting the box. The first conveyor belt is arranged on the operating platform, connected with the doubling mechanism and moved to the doubling mechanism. Since the first feeding chute is disposed above the first conveyor belt with a distance therebetween, the carrying assembly is required to carry the magnetic tiles orderly arranged on the straight section of the first feeding chute onto the first conveyor belt. In this embodiment, the carrying assembly 4 includes a moving plate 41 parallel to the straight line segment of the first feeding chute, a vertical guide rail 42 vertically connected to one end of the moving plate, a sliding connection between the moving plate and the vertical guide rail, and a horizontal guide rail 43 sliding connected to the vertical guide rail 42, where the horizontal guide rail is fixed on the operating table, so that the moving plate can move in the Z-axis direction and the vertical guide rail can drive the moving plate to move in the X-axis direction. A plurality of vacuum chucks 44 for sucking magnetic shoes are evenly arranged on the moving plate at intervals, the vacuum chucks 44 are connected with the moving plate through screws which are vertically connected with the moving plate, and the sucking surface of the vacuum chucks 44 faces to the right lower side and faces to the operating table. Therefore, the horizontal guide rail and the vertical guide rail drive the vacuum chuck to move right above a straight line section of the first feeding slide way, the suction surface of the vacuum chuck is just opposite to the magnetic shoe 5 arranged on the first feeding slide way, then the magnetic shoe is sucked to enable the magnetic shoe to be adsorbed on the vacuum chuck, the horizontal guide rail and the vertical guide rail drive the moving plate to move to the upper side of the first conveying belt, the magnetic shoe on the vacuum chuck is placed on the first conveying belt, and the first conveying belt can move the magnetic shoe to the doubling mechanism.

In this embodiment, the first and second feeding mechanisms are identical in composition and design to facilitate the same control and production of the production line. As shown in fig. 1 and 3, the second feed mechanism 2 includes: a second feeding assembly and a handling assembly arranged on the operation table, the second feeding assembly comprising a second feeding chute 21 and a second conveyor belt 22 arranged below the second feeding chute. The second feeding slide way is installed on the operating platform through a support, a distance exists between the second feeding slide way and the operating platform, the second feeding slide way 21 comprises a slope section and a straight line section connected with the tail end of the slope section, the slope section is a feeding end of the second feeding slide way, the feeding end is connected with a discharging port of another grinding machine, a second valve 23 is arranged at the tail end of the straight line section (namely the discharging end of the second feeding slide way), and magnetic tiles produced by the grinding machine enter the second feeding slide way from the slope section and slide to the straight line section under the action of gravity to be orderly arranged. In order to screen out broken and cracked magnetic shoes in time, a second notch 24 is arranged on the inclined section, a collecting box 15 is arranged below the second notch, and the broken magnetic shoes can leak out of the second notch to the collecting box after entering the inclined section. Simultaneously, also be equipped with the collection box in the terminal below of straightway, if back end processing equipment breaks down but the grinding machine can normally produce the magnetic shoe when, need in time stop the conveying of magnetic shoe, so can open the second valve this moment, let the magnetic shoe temporarily place in collecting the box. The second conveyer belt sets up on the operation panel, and the second conveyer belt is connected with doubling mechanism and the second conveyer belt removes to doubling mechanism. Because the second feeding chute is disposed above the second conveyor belt with a distance therebetween, the carrying assembly is required to carry the magnetic tiles orderly arranged on the straight section of the second feeding chute onto the second conveyor belt. In this embodiment, for convenience of unified management and production, the structure of the carrying assembly 4 is the same as that of the carrying assembly in the first feeding mechanism, and details thereof are not repeated herein. Horizontal guide rail and vertical guide rail in transport subassembly 4 drive vacuum chuck and remove to the gliding straightway of second feeding directly over, let vacuum chuck's the face of absorption just to arranging the magnetic shoe on second feeding slide then absorb the magnetic shoe and make the magnetic shoe adsorb on vacuum chuck, let horizontal guide rail and vertical guide rail drive the movable plate again and remove to the top of second conveyer belt, place the magnetic shoe on the vacuum chuck on the second conveyer belt, the second conveyer belt can remove the magnetic shoe to doubling mechanism department.

Further, as shown in fig. 1 and 4, the thread merging mechanism 3 in the present embodiment includes: a conveying assembly 33 arranged on the operation table, a first overturning assembly 31 and a second overturning assembly 32 arranged on two sides of the conveying assembly, and a carrying assembly 4. Specifically, the conveying direction of the conveying assembly 33 is the Y-axis direction, the first flipping assembly 31 and the second flipping assembly 32 are symmetrically disposed at two sides of the conveying assembly 33, and the direction of the first flipping assembly and the second flipping assembly is the X-axis direction. The conveying assembly 33 is a third conveying belt arranged in the center of the operating table and conveying along the Y-axis direction in the embodiment, the first overturning assembly and the second overturning assembly have the same structure and comprise a rotating shaft 311 arranged along the Y-axis direction, a motor 313 driving the rotating shaft to rotate, a plurality of placing blocks 312 arranged on the rotating shaft side by side at uniform intervals, the placing blocks 312 are profiling jigs used for placing magnetic shoes and having a vacuum adsorption function, all the placing blocks 312 are positioned on the same side of the rotating shaft 311, and all the placing blocks 312 and the conveying assembly 33 are positioned on two opposite sides of the rotating shaft 311 when the placing blocks 312 do not adsorb the magnetic shoes. Place piece 312 and be the arcuation structure, place under the initial condition (when not adsorbing the magnetic shoe promptly) and go up the evagination curved surface of piece and be towards directly over, this curved surface is used for adsorbing the magnetic shoe for absorbing the face, all absorb on the face of placing piece 312 and have the magnetic shoe after axis of rotation 311 drive place piece 312 upset 180, place the piece 312 after the upset 180 and overturn towards directly under and just to the third conveyer belt, so place the magnetic shoe on the piece and can place on the third conveyer belt after the upset. The transmission tail end of the third conveyor belt is connected with a rear end processing assembly line, so that the third conveyor belt can transmit the magnetic shoes transmitted by the first feeding mechanism and the second feeding mechanism to the same rear end processing assembly line for processing. Meanwhile, the carrying assembly 4 in the doubling mechanism is the same as the carrying assemblies in the first feeding mechanism and the second feeding mechanism, and the description is omitted again. The transmission tail end of the first conveyor belt is connected with an operation table in the wire doubling mechanism, the first conveyor belt is located under the first turnover mechanism, the tail end of the first conveyor belt 12 is provided with a first sensor 34, and when the first sensor senses that the magnetic shoes on the first conveyor belt are transmitted to a preset position, the first conveyor belt 12 stops moving. And then, the carrying assembly carries the magnetic shoe at the tail end of the first conveyor belt to the first overturning assembly, and the first overturning assembly overturns the magnetic shoe and then places the magnetic shoe on the third conveyor belt. Similarly, the transmission end of the second conveyor belt is connected with the operation table in the doubling structure, the second conveyor belt is positioned under the second turnover mechanism, the second sensor 35 is arranged at the end of the second conveyor belt 22, and when the second sensor senses that the magnetic shoes on the second conveyor belt are transmitted to the preset position, the second conveyor belt stops moving. And then the carrying assembly carries the magnetic tiles at the tail end of the second conveyor belt to the second overturning assembly, and the second overturning assembly overturns the magnetic tiles and then places the magnetic tiles on the third conveyor belt. Because first upset subassembly and second upset subassembly are the symmetry setting, so work between them is in turn gone on, and first upset subassembly upset is placed the magnetic shoe and is overturned back to initial position after, and the second upset subassembly is overturned again and is placed the magnetic shoe and then overturned back to initial position, and first upset subassembly is work again afterwards, and both just so work in turn.

In other embodiments, the first turnover assembly and the second turnover assembly can be arranged on two sides of the conveying assembly in a staggered mode, so that the first turnover assembly and the second turnover assembly can work simultaneously. Meanwhile, in the embodiment, the first feeding mechanism and the second feeding mechanism are arranged in the X-axis direction, but in other embodiments, the first feeding mechanism and the second feeding mechanism may be arranged in the X-axis direction or other directions, and it is only necessary that the directions of the magnetic tiles conveyed by the first feeding mechanism and the second feeding mechanism can be smoothly matched with the doubling mechanism.

To sum up, the utility model provides a transmission device of magnetic shoe obviously practices thrift the space, optimizes personnel's framework, improves and produces the line productivity and match, and further the square propulsion of intelligent manufacturing and lean production. Meanwhile, the influence of the broken tiles on detection equipment in the rear-end processing assembly line is avoided, the magnetic tiles are turned over by 180 degrees, and the operation process on the rear-end processing assembly line can be better executed.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A transmission device for magnetic shoes, comprising:

the feeding end of the first feeding mechanism is connected with the discharge hole of the grinding machine;

the feeding end of the second feeding mechanism is connected with the discharge hole of the other grinding machine;

the wire doubling mechanism comprises a carrying assembly, a conveying assembly, a first overturning assembly and a second overturning assembly, wherein the first overturning assembly and the second overturning assembly are arranged on two sides of the conveying assembly, the carrying assembly carries the magnetic shoe from the first feeding mechanism onto the first overturning assembly, the carrying assembly carries the magnetic shoe from the second feeding mechanism onto the second overturning assembly, the first overturning assembly and the second overturning assembly overturn the magnetic shoe and then place the magnetic shoe on the conveying assembly, and the conveying assembly conveys the magnetic shoe onto the same rear end processing assembly line.

2. The conveying device as claimed in claim 1, wherein the first and second flipping units each include a rotating shaft disposed parallel to the conveying direction of the conveying unit, and a motor for driving the rotating shaft to rotate, the rotating shaft being provided with a plurality of placement blocks for placing the magnetic shoes at regular intervals, the placement blocks having an arc-shaped configuration, the magnetic shoes being placed on a curved surface of the placement blocks protruding upward, all the placement blocks being located on a side of the rotating shaft opposite to the conveying unit, the rotating shaft driving all the placement blocks to flip toward the conveying unit.

3. The conveying device as claimed in claim 1, wherein the carrying assembly comprises a moving plate, a plurality of vacuum chucks arranged on the moving plate at regular intervals for sucking the magnetic shoes, a vertical guide rail connected with one end of the moving plate in a sliding manner, and a horizontal guide rail connected with the vertical guide rail in a sliding manner, and the sucking surface of the vacuum chucks faces to the right lower side.

4. The conveying device according to claim 1, wherein the first feeding mechanism comprises a first feeding assembly and the carrying assembly, the first feeding assembly comprises a first feeding slide way and a first conveying belt arranged below the first feeding slide way, the feeding end of the first feeding slide way is obliquely arranged, the discharging end of the first feeding slide way is provided with a first valve, the joint of the first conveying belt and the wire merging mechanism is arranged below the first overturning assembly, and the carrying assembly carries the magnetic tiles on the first feeding slide way onto the first conveying belt.

5. The conveying device according to claim 1, wherein the second feeding mechanism comprises a second feeding assembly and the carrying assembly, the second feeding assembly comprises a second feeding slide and a second conveyor belt arranged below the second feeding slide, the feeding end of the second feeding slide is obliquely arranged, the discharging end of the second feeding slide is provided with a second valve, the joint of the second conveyor belt and the wire merging mechanism is positioned below the second overturning assembly, and the carrying assembly carries the magnetic tiles on the second feeding slide onto the second conveyor belt.

6. The transfer device of claim 1, wherein the first feeding mechanism and the second feeding mechanism are symmetrically distributed on both sides of the doubling mechanism, and the conveying direction of the first feeding mechanism and the second feeding mechanism is perpendicular to the conveying direction of the conveying assembly.

7. The conveying device as claimed in claim 4, wherein a first notch is arranged on the feeding end of the first feeding slideway, the first notch is used for screening the cracked magnetic tiles, and collecting boxes for placing the magnetic tiles are arranged below the first notch and below the discharging end of the first feeding slideway.

8. The conveying device as claimed in claim 5, wherein a second notch is arranged on the feeding end of the second feeding slideway, the second notch is used for screening the cracked magnetic tiles, and collecting boxes for placing the magnetic tiles are arranged below the second notch and below the discharging end of the second feeding slideway.

9. The transfer device as claimed in claim 4, wherein a first sensor is disposed at an end of the first conveyor belt, and the first sensor senses that the first conveyor belt stops moving when the magnetic shoe conveyed by the first conveyor belt reaches a predetermined position.

10. The transfer apparatus as claimed in claim 5, wherein the second conveyor belt is provided at an end thereof with a second sensor, and the second sensor senses that the magnetic shoes conveyed by the second conveyor belt reach a predetermined position, and stops moving.

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