A continuous flow guiding and feeding device for neodymium iron boron magnetizing process

Abstract

The utility model discloses a kind of neodymium iron boron magnetizing processing continuous flow guide material conveying devices, and it relates to neodymium iron boron processing technical field.The neodymium iron boron magnetizing processing continuous flow guide material conveying device, including conveying device, the top fixedly connected with flow guide plate in the rear side of conveying device, the left and right sides of the front side of flow guide plate are all fixedly connected with inclined plate, the outer surface of the top of inclined plate is equipped with height plate, the front side of the top of conveying device is equipped with visual detection device, the outer surface of the left and right sides of conveying device is equipped with rectification component.This technical scheme can effectively automatically rectify the neodymium iron boron in inclined conveying state by setting rectification component, ensure that every piece of neodymium iron boron can enter subsequent flow guide process with correct posture, not only substantially reduce the jam problem caused by improper material arrangement, improve the overall smoothness and efficiency of production line, while also reduce the demand of manual intervention, save time and human resources.

Description

Technical Field

[0001] This utility model relates to the field of neodymium iron boron processing technology, and in particular to a continuous flow conveying device for neodymium iron boron magnetization processing. Background Technology

[0002] The continuous feeding and conveying device for NdFeB magnetization is a specialized processing equipment for NdFeB materials, primarily used to automate the feeding and transport of NdFeB magnetic materials during production. NdFeB is one of the strongest permanent magnet materials currently available, widely used in electronics, power machinery, medical devices, toys, packaging, hardware machinery, and many other fields. This device is designed to improve the efficiency and quality of NdFeB magnet production by achieving continuous material transport through automation, reducing manual intervention, thereby increasing production efficiency and ensuring consistent product quality.

[0003] While current NdFeB (neodymium iron boron) feeding devices possess a degree of automation in practical applications, the problem of NdFeB material tilting during transport still frequently arises. This tilting not only affects the overall efficiency of the production line but also makes the NdFeB material prone to blockage during the flow guiding stage. Whenever this occurs, manual intervention is required to clear the blockage, which consumes significant time and manpower, reduces production continuity and stability, increases operational complexity, and makes the device inconvenient to use. Utility Model Content

[0004] The purpose of this invention is to provide a continuous flow conveying device for NdFeB magnetization processing, which can avoid the problem that current NdFeB conveying devices, although they have certain automation functions, often have material tilting problems during the conveying process, which leads to blockages during flow guidance, requiring frequent manual unblocking, wasting time and manpower, reducing production efficiency and continuity, increasing operational complexity, and making them inconvenient to use.

[0005] This utility model provides a continuous guiding and conveying device for NdFeB magnetization processing, including a conveying device. A guide plate is fixedly connected to the top of the rear side of the conveying device. Inclined plates are fixedly connected to the left and right sides of the front side of the guide plate. A height limiting plate is installed on the outer surface of the top of the inclined plate. A visual inspection device is installed on the front side of the top of the conveying device. Correction components are provided on the outer surfaces of the left and right sides of the conveying device, and the correction components are used in conjunction with the visual inspection device.

[0006] In one specific implementation, the correction assembly includes two cylinders, the output end of which is fixedly connected to a movable box, and motors are installed on both the left and right sides of the inner cavity of the movable box.

[0007] In one specific implementation, threaded rods are rotatably connected to both the left and right sides of the inner cavity of the movable box, and threaded blocks are threadedly connected to the outer surface of the threaded rods, with the bottom of the threaded blocks slidably connected to the bottom of the inner cavity of the movable box.

[0008] In one specific implementation, the left and right sides of the front of the movable box and the front of the threaded block are rotatably connected to a first rotating rod, and the outer surface of the first rotating rod is fixedly connected to two symmetrically arranged first push plates.

[0009] In one specific implementation, a plurality of second push plates are rotatably connected to the side of the first push plate away from the first rotating rod, and the plurality of second push plates are connected to each other by a second rotating rod.

[0010] In one specific implementation, a placement plate is connected to the outer surface of the first and second rotating rods, and the rear side of the placement plate is fixedly connected to the front side of the threaded block.

[0011] In one specific implementation, clamping plates are fixedly connected to both the left and right sides of the placement plate, and the clamping plates are used in conjunction with the guide plate.

[0012] In one specific implementation, a slider is fixedly connected to the outer surface of the rear side of the placement plate, and the slider is slidably connected to the rear side of the movable box.

[0013] In one specific implementation, an electric telescopic rod is fixedly connected to the rear side of the mobile box, and a stop plate is fixedly connected to the output end of the electric telescopic rod.

[0014] The beneficial effects of this application are as follows: By setting up a correction component, the NdFeB magnets in an inclined conveying state can be automatically corrected, ensuring that each NdFeB magnet enters the subsequent guiding process in the correct posture. This not only significantly reduces blockage problems caused by improper material arrangement, improving the overall smoothness and efficiency of the production line, but also reduces the need for manual intervention, saving time and human resources. The application of the correction component makes the NdFeB magnets more stable and reliable during conveying and guiding, further ensuring the continuity of production and the consistency of product quality, improving the ease of use and maintenance of the equipment, providing strong support for achieving efficient and stable production, and facilitating its use. Attached Figure Description

[0015] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the embodiments will be briefly introduced below. It should be understood that the following drawings only show some embodiments of this utility model and should not be regarded as a limitation of the scope. For those skilled in the art, other related drawings can be obtained from these drawings without creative effort.

[0016] Figure 1 This is a three-dimensional schematic diagram of the overall structure of an embodiment of the present utility model;

[0017] Figure 2 This is an embodiment of the present utility model. Figure 1 Enlarged structural diagram at point A in the middle;

[0018] Figure 3 This is a rear-view perspective view of the overall structure of an embodiment of the present utility model;

[0019] Figure 4 This is a three-dimensional schematic diagram of the overall structure of the correction component according to an embodiment of the present utility model;

[0020] Figure 5 This is a three-dimensional schematic diagram of the clamping plate structure according to an embodiment of the present utility model;

[0021] Figure 6 This is a three-dimensional schematic diagram of the first push plate structure according to an embodiment of the present utility model;

[0022] Figure 7 This is a three-dimensional schematic diagram of the mobile box structure according to an embodiment of the present utility model.

[0023] Icons: 1. Conveying device; 2. Guide plate; 3. Inclined plate; 4. Height limit plate; 5. Vision inspection device; 6. Correction assembly; 61. Cylinder; 62. Moving box; 63. Motor; 64. Threaded rod; 65. Threaded block; 66. First rotating rod; 67. First push plate; 68. Second push plate; 69. Second rotating rod; 610. Placement plate; 611. Clamping plate; 612. Slider; 613. Electric telescopic rod; 614. Stop plate. Detailed Implementation

[0024] While current NdFeB (neodymium iron boron) feeding devices possess some automation capabilities, material tilting frequently occurs during the conveying process, leading to blockages during flow guidance. This necessitates frequent manual unblocking, wasting time and manpower, reducing production efficiency and continuity, increasing operational complexity, and causing inconvenience. Therefore, the inventors have developed a continuous flow guiding and feeding device for NdFeB magnetization processing. By incorporating a correction component, the tilted NdFeB material can be effectively adjusted, ensuring it enters the flow guidance process in the correct posture, reducing blockages and improving production line efficiency, while simultaneously minimizing the need for manual intervention, thus resolving the aforementioned shortcomings.

[0025] The following detailed description, in conjunction with the accompanying drawings, outlines some embodiments of the present invention. Unless otherwise specified, the following embodiments and features can be combined with each other.

[0026] Please refer to Figures 1 to 7This utility model provides a continuous conveying device for magnetizing neodymium iron boron (NdFeB) magnetization, including a conveying device 1. The rear side of the conveying device 1 is connected to the next magnetizing device to facilitate NdFeB magnetization. A guide plate 2 is fixedly connected to the top of the rear side of the conveying device 1. The guide plate 2 is L-shaped, and its bottom is in contact with the belt on the conveying device 1. Inclined plates 3 are fixedly connected to the left and right sides of the front side of the guide plate 2. A height limiting plate 4 is installed on the outer surface of the top of the inclined plate 3. A vision inspection device 5 is installed on the front side of the top of the conveying device 1 to determine whether the NdFeB magnet is tilted during the conveying process. Correction components 6 are provided on the outer surfaces of the left and right sides of the conveying device 1 and are used in conjunction with the vision inspection device 5. The correction components 6 include two cylinders 61, and the outer surfaces of the cylinders 61 are fixedly connected to the left and right sides of the conveying device 1. A movable box 62 is fixedly connected to the output end of the cylinders 61. Motors 63 are installed on both the left and right sides of the inner cavity of the movable box 62. Threaded rods 64 are rotatably connected to both the left and right sides of the inner cavity of the movable box 62. The outer surfaces of the two threaded rods 64 are provided with opposite external threads. Threaded blocks 65 are threadedly connected to the outer surfaces of the threaded rods 64. The contact area between the threaded blocks 65 and the threaded rods 64 is provided with matching internal threads. The bottom of the threaded blocks 65 is slidably connected to the bottom of the inner cavity of the movable box 62. First rotating rods 66 are rotatably connected to the left and right sides of the front of the movable box 62 and the front of the threaded blocks 65. There are a total of four first rotating rods 66. Two first rotating rods 66 are rotatably connected to the movable box 62, and the remaining two are connected to the threaded blocks 65. Two symmetrically arranged first push plates 67 are fixedly connected to the outer surfaces of the first rotating rods 66. Several second push plates 68 are rotatably connected to the side of the first push plates 67 away from the first rotating rods 66, and the several second push plates 68 are connected to each other by a second rotating rod 69.

[0027] Please refer to Figures 2 to 7 The outer surfaces of the first rotating rod 66 and the second rotating rod 69 are connected to a placement plate 610. The rear side of the placement plate 610 is fixedly connected to the front side of the threaded block 65. The front side of the movable box 62 has a through cavity to facilitate the movement of the threaded block 65. One of the placement plates 610 away from the first rotating rod 66 is fixedly connected to the threaded block 65. Clamping plates 611 are fixedly connected to both the left and right sides of the placement plate 610. The clamping plates 611 are used in conjunction with the guide plate 2. A slider 612 is fixedly connected to the outer surface of the rear side of the placement plate 610. The slider 612 is slidably connected to the rear side of the movable box 62. The slider 612 is L-shaped. An electric telescopic rod 613 is fixedly connected to the rear side of the movable box 62. A stop plate 614 is fixedly connected to the output end of the electric telescopic rod 613.

[0028] Specifically, when NdFeB is conveyed to the conveying device 1, the visual inspection device 5 first checks whether the NdFeB is tilted. Once confirmed, the motor 63 is started, which drives the threaded rod 64 to rotate. Using the thread transmission principle, the threaded block 65 is pushed to move back and forth. The movement of the threaded block 65 causes one of the placement plates 610 to move synchronously. This placement plate 610 then pushes the first rotating rod 66 connected to the moving box 62, so that the placement plate 610 pulls multiple second push plates 68 to unfold or close around the first rotating rod 66. During this process, the first rotating rod 66 and the second rotating rod 69 work together to drive multiple placement plates 610 and clamping plates 611 to adjust synchronously, ensuring that NdFeB of different widths and tilted states can be clamped and corrected. To prevent the NdFeB from being missed during the correction process, the electric telescopic rod 613 pushes the stop plate 614 downward and blocks the NdFeB transport, ensuring that the NdFeB is transported in a straight line to the guide plate 2. This effectively avoids the blockage problem that may occur during the guide process and improves the convenience and efficiency of the overall operation.

[0029] In summary, the working principle of the continuous guiding and conveying device for NdFeB magnetization processing according to this utility model embodiment is as follows: First, when the NdFeB is conveyed to the conveying device 1, the cylinder 61 is activated. The cylinder 61 pushes the moving box 62, the clamping plate 611, and the placement plate 610 to adjust their height positions appropriately to accommodate NdFeB at different heights. Before correcting the NdFeB, the visual detection device 5 identifies whether the NdFeB is tilted. Then, the correction component 6 is activated to correct the tilted NdFeB. After correction, the NdFeB is conveyed to the guide plate 2 through the conveying device 1. The guide plate 2 then conveys the NdFeB in batches to the magnetization device for easy use.

[0030] The above are merely preferred embodiments of this utility model and are not intended to limit the scope of this utility model. Various modifications and variations can be made to this utility model by those skilled in the art. Any modifications, equivalent substitutions, or improvements made within the spirit and principles of this utility model should be included within the protection scope of this utility model.

Claims

1. A continuous flow conveying device for neodymium iron boron magnetization processing, characterized in that, The device includes a conveying device (1), a guide plate (2) is fixedly connected to the top of the rear side of the conveying device (1), and inclined plates (3) are fixedly connected to the left and right sides of the front side of the guide plate (2). A height limit plate (4) is installed on the outer surface of the top of the inclined plate (3). A visual inspection device (5) is installed on the front side of the top of the conveying device (1). A correction component (6) is provided on the outer surface of the left and right sides of the conveying device (1), and the correction component (6) is used in conjunction with the visual inspection device (5).

2. The continuous flow conveying device for NdFeB magnetization processing according to claim 1, characterized in that, The correction assembly (6) includes two cylinders (61), the output end of which is fixedly connected to a movable box (62), and motors (63) are installed on both the left and right sides of the inner cavity of the movable box (62).

3. The continuous flow conveying device for NdFeB magnetization processing according to claim 2, characterized in that, The movable box (62) has threaded rods (64) rotatably connected to both sides of its inner cavity. The outer surface of the threaded rods (64) is threaded with threaded blocks (65), and the bottom of the threaded blocks (65) is slidably connected to the bottom of the inner cavity of the movable box (62).

4. The continuous flow conveying device for NdFeB magnetization processing according to claim 3, characterized in that, The left and right sides of the front of the movable box (62) and the front of the threaded block (65) are rotatably connected to a first rotating rod (66), and two first push plates (67) arranged symmetrically are fixedly connected to the outer surface of the first rotating rod (66).

5. The continuous flow conveying device for NdFeB magnetization processing according to claim 4, characterized in that, The first push plate (67) is rotatably connected to a plurality of second push plates (68) on the side away from the first rotating rod (66), and the plurality of second push plates (68) are connected to each other by a second rotating rod (69).

6. The continuous flow conveying device for NdFeB magnetization processing according to claim 5, characterized in that, The outer surfaces of the first rotating rod (66) and the second rotating rod (69) are connected to a placement plate (610), and the rear side of the placement plate (610) is fixedly connected to the front side of the threaded block (65).

7. A continuous flow conveying device for neodymium iron boron magnetization processing according to claim 6, characterized in that, The placement plate (610) is fixedly connected to clamping plates (611) on both the left and right sides, and the clamping plates (611) are used in conjunction with the guide plate (2).

8. The continuous flow conveying device for NdFeB magnetization processing according to claim 7, characterized in that, A slider (612) is fixedly connected to the outer surface of the rear side of the placement plate (610), and the slider (612) is slidably connected to the rear side of the movable box (62).

9. A continuous flow conveying device for NdFeB magnetization processing according to claim 8, characterized in that, An electric telescopic rod (613) is fixedly connected to the rear side of the mobile box (62), and a stop plate (614) is fixedly connected to the output end of the electric telescopic rod (613).

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