A magnetic material separation device

By designing a magnet-feed separation device, the automatic separation of magnets and partitions is achieved using a transverse component, which solves the problem of low efficiency in manual separation in existing technologies and improves production efficiency and automation.

CN224429250UActive Publication Date: 2026-06-30GUANGDONG MAGNETIC STABILITY TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GUANGDONG MAGNETIC STABILITY TECHNOLOGY CO LTD
Filing Date
2025-07-02
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

In existing technologies, magnets need to be manually separated during the production process, which is inefficient and painful for workers, and cannot be automated.

Method used

Design a magnet feeding separation device that uses a transverse component to drive a pusher block to reciprocate in a placement trough, thereby achieving automatic separation of the magnet and the partition, and pushing them to different discharge positions to realize automated operation.

Benefits of technology

It improves the production efficiency of magnet material separation, reduces manual operation, and realizes automated separation and classification of magnets and separators.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a magnet material separation device, including an operating platform. The operating platform has at least one placement slot with openings at both ends for discharging magnets and partitions, respectively. A storage frame is provided above the placement slot, and the bottom of the placement slot has a slot with the same orientation. A transverse moving component is provided below the operating platform, and a pusher is provided on the transverse moving component. The pusher extends into the placement slot from the slot, and the transverse moving component drives the pusher to reciprocate at both ends of the placement slot. One reciprocating motion of the transverse moving component can separate the two incoming material parts, namely the magnet and the partition. The magnet is required for production, while the partition is recyclable. These two parts can be pushed to different places without manual separation, realizing automated operation and improving production efficiency.
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Description

Technical Field

[0001] This utility model belongs to the field of auxiliary production equipment technology, specifically a magnet material separation device. Background Technology

[0002] Magnets, as an important functional material, have wide applications in many fields such as electronics, communications, and machining. The most common application of magnets is in electric motors, and linear motors are the devices that directly convert electrical energy into linear motion kinetic energy. Linear motors require a large number of strong magnetic magnets, which are usually stacked together upon arrival. During production, these magnets need to be manually broken apart, which is not only inefficient but also causes pain to workers' hands after prolonged operation. Utility Model Content

[0003] The purpose of this invention is to provide a magnetic material separation device to solve the problems mentioned in the background art.

[0004] To achieve the above objectives, this utility model provides the following technical solution:

[0005] A magnet feeding separation device includes an operating platform, the operating platform having at least one placement slot with openings at both ends for discharging magnets and a partition, a storage frame above the placement slot, and slots with the same orientation at the bottom of the placement slot;

[0006] A transverse component is located below the operating platform. A push block is provided on the transverse component. The push block extends into the placement slot from the slot and the transverse component drives the push block to reciprocate between the two ends of the placement slot.

[0007] In a further technical solution, the operating platform is provided with two placement slots.

[0008] A further technical solution includes a first discharge position located near one end of the placement trough, a sensor located above the first discharge position, a second discharge position located at the other end of the placement trough, and a sliding plate located at the second discharge position.

[0009] In a further technical solution, the transverse component is a cylinder, a connecting block is installed at the output end of the cylinder, and the push block is installed on the connecting block.

[0010] In a further technical solution, the storage frame package extends upward in the shape of a cuboid, and has guide plates on both sides at its lower end, the guide plates extending into the placement groove.

[0011] The beneficial effects of this utility model are:

[0012] This invention enables the separation of two incoming material parts—a magnet and a partition—through a single reciprocating motion of a transverse component. The magnet is required for production, while the partition is recyclable. These two parts can be pushed to different locations without manual separation, thus achieving automated operation and improving production efficiency.

[0013] Other features and advantages of this invention will be described in detail in the following detailed description section. Attached Figure Description

[0014] Figure 1 The three-dimensional structure of this utility model Figure 1 .

[0015] Figure 2 The three-dimensional structure of this utility model Figure 2 .

[0016] Figure 3 : Cross-sectional structural diagram of this utility model.

[0017] Figure 4 The disassembly structure of this utility model Figure 1 .

[0018] Figure 5 The disassembly structure of this utility model Figure 2 .

[0019] Reference numerals: 1-Operating platform, 11-Placement slot, 12-Strip hole, 13-First discharge position, 14-Sensor, 15-Second discharge position, 16-Slide plate, 2-Storage frame, 21-Guide plate, 3-Transverse component, 31-Cylinder, 32-Connecting block, 4-Push block. Detailed Implementation

[0020] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention.

[0021] Please refer to Figure 1-5 ;

[0022] The magnet material separation device of this utility model aims to automate operation to replace manual labor and improve work efficiency. Specifically, it includes an operating platform 1, which has at least one placement slot 11 with openings at both ends. It should be noted that, in order to facilitate magnet separation, a partition is provided between adjacent magnets, and the two openings of the placement slot 11 are used to output magnets and the partition, respectively. A storage frame 2 is provided above the placement slot 11. Preferably, the storage frame 2 is installed on the operating platform 1 by connection. The bottom of the placement slot 11 has a slot 12 with the same direction as the slot. A transverse moving component 3 is provided below the operating platform 1. A push block 4 is provided on the transverse moving component 3. The push block 4 extends into the placement slot 11 from the slot 12, and the transverse moving component 3 drives the push block 4 to reciprocate between the two ends of the placement slot 11.

[0023] Initially, pusher 4 is located at one end of placement slot 11. Then, stacked magnets are placed into storage frame 2, with the bottom magnet falling into placement slot 11. Next, lateral movement assembly 3 is activated, moving pusher 4 along slot 12 from one end of placement slot 11 to the other. During this movement, pusher 4 contacts the end of the magnet that has fallen into placement slot 11, pushing it to slide along the slot. At this time, the partition is still in storage frame 2, so it does not push the partition. The magnet is then pushed to the opening and detached from placement slot 11, completing the magnet transfer process. Iron separation: When the pusher 4 has completely passed under the storage frame 2, the material magnet falls under the action of gravity, and the partition falls into the placement groove 11. Then, the transverse moving device resets and drives the pusher 4 to move in the opposite direction along the slot 12 back to the end of the placement groove 11. During this movement, the pusher 4 abuts against the end of the partition that has fallen into the placement groove 11 and pushes the partition to slide along the placement groove 11 until it reaches the other end opening and leaves the placement groove 11. When the pusher 4 has completely passed under the storage frame 2, the material magnet falls under the action of gravity, causing another magnet to fall into the placement groove 11 again, and so on.

[0024] This invention enables the separation of two incoming material parts, a magnet and a partition, through a single reciprocating motion of the transverse component 3. The magnet is required for production, while the partition is recyclable. These two parts can be pushed to different locations without manual separation, thus achieving automated operation and improving production efficiency.

[0025] Preferably, the operating platform 1 is provided with two placement slots 11, and a storage frame 2, a transverse moving component 3, and a pusher 4 are respectively provided on the placement slots 11, so as to realize simultaneous operation of two workstations, with smaller additional components and higher efficiency.

[0026] In this embodiment of the utility model, a first discharge position 13 is provided at one end near the placement groove 11, and a sensor 14 is provided above the first discharge position. The sensor 14 can be a Hall sensor or a laser distance sensor 14. A second discharge position 15 is located at the other end of the placement groove 11, and a sliding plate 16 is provided at the second discharge position. First, the transverse component 3 drives the push block 4 to push the magnet from the opening of the placement groove 11 to the first discharge position 13. The sensor 14 senses whether the magnet is located at the first discharge position 13. Then, the magnet at the first discharge position is manually removed for production. Assuming that the magnet at the first discharge position 13 is always present, the transverse component 3 will not drive the push block 4 to reset.

[0027] When the magnet at the first discharge position 13 is removed, the transverse component 3 drives the push block 4 to reset, and at the same time pushes the partition from another opening to the second discharge position. A guide block is provided at the corner of the second discharge position. The guide block has a 45° inclined slope. The next partition pushes the previous partition towards the 45° inclined guide block. When the end of the partition touches the guide block, it will automatically turn towards the slide plate and slide down from the slide plate.

[0028] In this embodiment of the utility model, the transverse component 3 is a cylinder 31, and a connecting block 32 is installed at the output end of the cylinder 31. The push block 4 is installed on the connecting block 32. The cylinder 31 has a fixed stroke for reciprocating movement, which simplifies the control method and makes the overall structure simpler.

[0029] In this embodiment of the utility model, the storage frame 2 extends upward in the shape of a cuboid, and has guide plates 21 on both sides at its lower end. The guide plates 21 extend into the placement groove 11. Of course, there is a certain distance between the bottom of the guide plate 21 and the bottom of the placement groove 11, which can accommodate a magnet or a partition. This design can make the material closer to the placement groove 11 and avoid the material hitting the edge of the operating plate and getting stuck when it falls.

[0030] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

[0031] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style of the specification is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.

Claims

1. A magnet-feed separation device, comprising an operating platform (1), characterized in that: The operating platform (1) is provided with at least one placement slot (11) with openings at both ends, which is used to output magnets and partitions respectively. A storage frame (2) is provided above the placement slot (11), and the bottom of the placement slot (11) is provided with a strip hole (12) with the same setting direction. A transverse component (3) is provided below the operating platform (1). A push block (4) is provided on the transverse component (3). The push block (4) extends into the placement groove (11) from the slot (12), and the transverse component (3) drives the push block (4) to reciprocate between the two ends of the placement groove (11).

2. The magnet feed separation device according to claim 1, characterized in that: The operating platform (1) is provided with two placement slots (11).

3. The magnet feeder separation device according to claim 1, characterized in that: A first discharge position (13) is provided at one end near the placement trough (11), and a sensor (14) is provided above the first discharge position. A second discharge position (15) is located at the other end of the placement trough (11), and a sliding plate (16) is provided at the second discharge position.

4. The magnet feed separation device according to claim 1, characterized in that: The transverse component (3) is a cylinder (31), and a connecting block (32) is installed at the output end of the cylinder (31). The push block (4) is installed on the connecting block (32).

5. The magnet feed separation device according to claim 1, characterized in that: The storage frame (2) is a cuboid extending upwards, with guide plates (21) on both sides at its lower end, and the guide plates (21) extend into the placement groove (11).