An integrated processing device for neodymium iron boron magnets

Through innovative design of adjustment and transmission components, the shortcomings of neodymium iron boron magnet processing equipment in adjustment and transmission have been solved, achieving precise adjustment and efficient diversified processing, thereby improving production efficiency and product quality.

CN224424980UActive Publication Date: 2026-06-30DONGGUAN CITY JIADA MAGNETOELECTRICITY PROD CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DONGGUAN CITY JIADA MAGNETOELECTRICITY PROD CO LTD
Filing Date
2025-07-28
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Traditional neodymium iron boron magnet processing equipment suffers from insufficient precision in adjustment and transmission, making it difficult to adapt to the processing needs of products of different specifications, resulting in frequent downtime for debugging and low efficiency.

Method used

By employing the coordination of adjusting rods, adjusting blocks, fixing frames, and limit blocks in the adjustment assembly, combined with the combined design of multiple servo motors, transmission wheels, and transmission belts, precise adjustment and multiple transmission systems are achieved to ensure processing accuracy and efficiency.

Benefits of technology

It achieves precise vertical positioning and diverse adaptability in the processing of neodymium iron boron magnets, improving production efficiency and product quality while reducing processing errors.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses an integrated processing device for neodymium iron boron magnets, including a main body box and an adjustment assembly placed on the upper surface of the main body box. The adjustment assembly includes an adjustment rod, an adjustment block, a fixed frame, and a limiting block. The fixed frame is fixedly connected to the upper surface of the main body box, and the limiting block is fixedly connected to the inner side wall of the fixed frame. The adjustment block is slidably connected to the fixed frame through the limiting block. An adjustment rod is provided through the fixed frame, and the lower end of the adjustment rod is threaded into the adjustment block. The main body box is fixed, and the fixed frame, limiting block, and other components are installed. By rotating the adjustment rod, the adjustment block is driven to slide along the limiting block to adjust the height of the processing part to adapt to workpieces of different specifications. At the same time, a stepper motor drives a first transmission wheel, which drives a first driven wheel via a first transmission belt, causing the rack and pinion conveyor belt to run. The workpiece mounting platform clamps the magnet and smoothly transmits it to the processing area. A second servo motor drives a friction roller via a second transmission belt to perform the processing action.
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Description

Technical Field

[0001] This utility model relates to the field of neodymium iron boron magnet processing technology, specifically an integrated neodymium iron boron magnet processing device. Background Technology

[0002] Current NdFeB magnet processing technology suffers from significant drawbacks. In the adjustment stage, traditional equipment often employs manual or rudimentary adjustment mechanisms, making precise vertical positioning difficult. This hinders the rapid adaptation to the processing requirements of different product specifications, leading to frequent downtime for adjustments, reduced production efficiency, and a high risk of defective products due to adjustment errors. Regarding transmission, existing transmission systems rely on a single power transmission path, often using a single motor, which fails to enable multi-component collaborative operation. This results in low efficiency when facing complex processing steps, making it difficult to meet the demands of mass production. Therefore, those skilled in the art have proposed an integrated NdFeB magnet processing device to address the problems mentioned in the background. Utility Model Content

[0003] The purpose of this invention is to provide an integrated processing device for neodymium iron boron magnets to solve the problems mentioned in the background art.

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

[0005] An integrated processing device for neodymium iron boron magnets includes a main body box and an adjustment assembly placed on the upper surface of the main body box. The adjustment assembly includes an adjustment rod, an adjustment block, a fixing frame, and a limiting block. The fixing frame is fixedly connected to the upper surface of the main body box, and the limiting block is fixedly connected to the inner side wall of the fixing frame. The adjusting block is slidably connected to the fixing frame through the limiting block. An adjustment rod is provided through the fixing frame, and the lower end of the adjustment rod is threaded into the adjusting block.

[0006] Furthermore, the upper surface of the main body box is also provided with a transmission component and a transmission component that work in conjunction with the adjustment component.

[0007] Furthermore, the transmission assembly includes a second servo motor, a second transmission wheel, a second driven wheel, a second transmission belt, and a friction roller. The second servo motor is slidably connected to the upper surface of the main body box via a sliding plate. The output end of the second servo motor is provided with a second transmission wheel. A friction roller is rotatably connected to the adjusting block. One end of the friction roller is fixedly connected to a second driven wheel, and the surfaces of the second driven wheel and the second transmission wheel are provided with a second transmission belt for transmission.

[0008] Furthermore, the transmission assembly also includes a third transmission wheel, a third driven wheel, and a third transmission belt. The third transmission wheel is fixedly connected to the surface of the friction roller and is located on one side of the second driven wheel. Another friction roller is rotatably connected to another adjusting block on the main body box, and one end of this friction roller is fixedly connected to the third driven wheel. The surfaces of the third driven wheel and the third transmission wheel are provided with a third transmission belt for transmission.

[0009] Furthermore, the transmission assembly also includes a first servo motor, which is slidably connected to the upper surface of the main body box via a sliding plate, and the first servo motor is separately connected to a friction roller via a separate transmission belt.

[0010] Furthermore, the transmission component includes a second servo motor, a stepper motor, a first transmission wheel, a first transmission belt, a first driven wheel, and a support block. A stepper motor is fixedly connected to the upper surface of the main body box, and a first transmission wheel is provided at the output end of the stepper motor. A support block is fixedly connected to the upper surface of the main body box, and a first driven wheel is rotatably connected to the surface of the support block. A first transmission belt for transmission is provided on the surfaces of the first driven wheel and the first transmission wheel.

[0011] Furthermore, the transmission assembly also includes a rack and pinion conveyor belt and a workpiece mounting platform. The support block surface is provided with a rack and pinion conveyor belt, which is connected to the first driven wheel. The surface of the rack and pinion conveyor belt is provided with a workpiece mounting platform for fixing the workpiece.

[0012] By adopting the above technical solution

[0013] Compared with the prior art, the beneficial effects of this utility model are:

[0014] 1. The adjustment assembly achieves precise vertical adjustment through the cooperation of the adjustment rod, adjustment block, fixing frame, and limit block. The fixing frame and limit block provide a stable sliding track for the adjustment block, and the threaded connection of the adjustment rod ensures smooth adjustment and accurate positioning. The position of each component of the device can be flexibly adjusted according to the processing requirements of different specifications of neodymium iron boron magnets, effectively ensuring processing accuracy and meeting diverse production requirements.

[0015] 2. The transmission assembly incorporates multiple servo motors, drive wheels, driven wheels, and drive belts, forming multiple transmission systems. A second servo motor drives the friction rollers via a second drive belt to perform specific machining actions on the magnets. A third drive belt further extends the transmission path, enabling multiple friction rollers to work collaboratively and improve machining efficiency. Simultaneously, the first servo motor independently drives the friction rollers, allowing it to perform independent machining tasks. The combination of these multiple transmission methods enhances the device's machining capabilities and efficiency.

[0016] 3. The stepper motor, first drive wheel, first drive belt, and first driven wheel in the transmission assembly constitute a stable transmission system, driving the rack and pinion conveyor belt to operate precisely. The rack and pinion conveyor belt, in conjunction with the workpiece mounting platform, can securely clamp and transmit the neodymium iron boron magnets, ensuring accurate workpiece positioning and smooth transmission during processing, reducing processing errors caused by unstable transmission, and improving product quality and production stability. Attached Figure Description

[0017] Figure 1 This is a front view of an integrated processing device for neodymium iron boron magnets.

[0018] Figure 2 A top view schematic diagram of an integrated processing device for neodymium iron boron magnets;

[0019] Figure 3 This is a side and rear view of an integrated processing device for neodymium iron boron magnets;

[0020] Figure 4 In this utility model Figure 1 A magnified schematic diagram of the structure at point A;

[0021] In the diagram: 1. First servo motor; 2. Second servo motor; 3. Stepper motor; 4. First transmission wheel; 5. First transmission belt; 6. Main body box; 7. First driven wheel; 8. Support block; 9. Rack and pinion conveyor belt; 10. Workpiece mounting platform; 11. Second transmission wheel; 12. Second driven wheel; 13. Third transmission wheel; 14. Third driven wheel; 15. Second transmission belt; 16. Third transmission belt; 17. Friction roller; 18. Adjusting rod; 19. Adjusting block; 20. Fixing frame; 21. Limiting block. Detailed Implementation

[0022] To make the technical means, creative features, achieved objectives and effects of this utility model easier to understand, the present utility model is further described below in conjunction with specific embodiments. In the description of this utility model, it should be noted that the terms "upper," "lower," "inner," "outer," "front end," "rear end," "both ends," "one end," and "the other end," etc., indicating the orientation or positional relationship, are based on the orientation or positional relationship shown in the accompanying drawings and are only for the convenience of describing this utility model and simplifying the description. For those skilled in the art, the specific meaning of the above terms in this utility model can be understood according to the specific circumstances.

[0023] Please see Figures 1-4This utility model provides an embodiment of an integrated processing device for neodymium iron boron magnets, including a main body box 6 and an adjustment assembly placed on the upper surface of the main body box 6. The adjustment assembly includes an adjustment rod 18, an adjustment block 19, a fixing frame 20, and a limiting block 21. The fixing frame 20 is fixedly connected to the upper surface of the main body box 6, and the limiting block 21 is fixedly connected to the inner side wall of the fixing frame 20. The adjusting block 19 is slidably connected to the fixing frame 20 through the limiting block 21. The adjustment rod 18 is provided through the fixing frame 20, and the lower end of the adjustment rod 18 is threadedly connected to the adjusting block 19. The upper surface of the main body box 6 is also provided with a transmission assembly and a transmission component that cooperate with the adjustment assembly. By rotating the adjustment rod 18, the adjusting block 19 can slide up and down along the limiting block 21 on the inner side wall of the fixing frame 20 using the thread transmission principle, thereby adjusting the connected friction roller 17.

[0024] In this embodiment, the transmission assembly includes a second servo motor 2, a second transmission wheel 11, a second driven wheel 12, a second transmission belt 15, and a friction roller 17. The second servo motor 2 is slidably connected to the upper surface of the main body box 6 via a sliding plate. The second transmission wheel 11 is provided at the output end of the second servo motor 2. The friction roller 17 is rotatably connected to the adjusting block 19. The second driven wheel 12 is fixedly connected to one end of the friction roller 17. The second driven wheel 12 and the second transmission wheel 11 are provided with a second transmission belt 15 for transmission. The transmission assembly also includes a third transmission wheel 13, a third driven wheel 14, and a third transmission belt 16. The third transmission wheel 13 is fixedly connected to the surface of the friction roller 17. Located on one side of the second driven wheel 12, another friction roller 17 is rotatably connected to another adjusting block 19 on the main body box 6, and one end of this friction roller 17 is fixedly connected to a third driven wheel 14. The surfaces of the third driven wheel 14 and the third transmission wheel 13 are provided with a third transmission belt 16 for transmission. The transmission assembly also includes a first servo motor 1. The first servo motor 1 is slidably connected to the upper surface of the main body box 6 through a sliding plate, and the first servo motor 1 is separately connected to the friction roller 17 through a separate transmission belt. A sliding plate is installed on the upper surface of the main body box 6, and the second servo motor 2 is fixed to the sliding plate with bolts, so that it can slide on the upper surface of the main body box 6 in a specific direction, which is convenient for adjusting the position according to actual needs. A second transmission wheel 11 is installed at the output end of the second servo motor 2, and a bearing is installed on the adjusting block 19. The friction roller 17 is rotatably connected to the adjusting block 19 through the bearing, and the second driven wheel 12 is fixedly installed at one end of the friction roller 17. A second transmission belt 15 is fitted onto the surfaces of the second transmission wheel 11 and the second driven wheel 12. When the second servo motor 2 is started, its output end drives the second transmission wheel 11 to rotate, and the power is transmitted to the second driven wheel 12 through the second transmission belt 15, thereby driving the friction roller 17 to rotate and perform processing operations on the neodymium iron boron magnet. A third transmission wheel 13 is fixedly installed on the surface of the installed friction roller 17, near the side of the second driven wheel 12. Another friction roller 17 is rotatably connected to another adjusting block 19 on the main body box 6 through a bearing, and a third driven wheel 14 is installed at one end of the friction roller 17. A third transmission belt 16 is fitted onto the surfaces of the third transmission wheel 13 and the third driven wheel 14. In this way, when one friction roller 17 rotates, the third transmission belt 16 can drive another friction roller 17 to rotate synchronously, realizing the coordinated operation of multiple friction rollers 17 and improving processing efficiency. A first servo motor 1 is installed on the sliding plate on the upper surface of the main body box 6, and the first servo motor 1 is connected to a specific friction roller 17 by a separate transmission belt. When an independent processing task needs to be performed, the first servo motor 1 is started, and the friction roller 17 is driven separately through the transmission belt to meet diverse processing needs.

[0025] In this embodiment, the transmission assembly includes a second servo motor 2, a stepper motor 3, a first transmission wheel 4, a first transmission belt 5, a first driven wheel 7, and a support block 8. The stepper motor 3 is fixedly connected to the upper surface of the main body box 6, and the first transmission wheel 4 is provided at the output end of the stepper motor 3. The support block 8 is fixedly connected to the upper surface of the main body box 6, and the first driven wheel 7 is rotatably connected to the surface of the support block 8. The first driven wheel 7 and the first transmission wheel 4 are provided with a first transmission belt 5 for transmission. The transmission assembly also includes a rack and pinion conveyor belt 9 and a workpiece mounting platform 10. The rack and pinion conveyor belt 9 is provided on the surface of the support block 8, and the rack and pinion conveyor belt 9 is interconnected with the first driven wheel 7. The rack and pinion conveyor belt 9 is provided with a workpiece mounting platform 10 for fixing the workpiece. The stepper motor 3 is fixedly installed on the upper surface of the main body box 6 by bolts or welding, and the first transmission wheel 4 is installed at its output end. Simultaneously, a support block 8 is fixedly connected to a suitable position on the upper surface of the main body box 6. A bearing is installed on the surface of the support block 8, and the first driven wheel 7 is rotatably connected to the support block 8 through the bearing. Then, the first transmission belt 5 is sleeved on the surface of the first transmission wheel 4 and the first driven wheel 7. When the stepper motor 3 starts, its output end drives the first transmission wheel 4 to rotate, and transmits power to the first driven wheel 7 through the first transmission belt 5. A rack conveyor belt 9 is installed on the surface of the support block 8, connecting it to the first driven wheel 7 to ensure that the rotation of the first driven wheel 7 can drive the rack conveyor belt 9. A workpiece mounting platform 10 is set on the surface of the rack conveyor belt 9, and neodymium iron boron magnets are fixed on the workpiece mounting platform 10 through fixing structures such as clamps or slots. When the stepper motor 3 drives the rack conveyor belt 9, the workpiece mounting platform 10 moves accordingly, smoothly transferring the neodymium iron boron magnets to the processing position. During the transfer, the workpiece mounting platform 10 can firmly clamp the workpiece, ensuring the stability and accuracy of the transfer.

[0026] The main body box 6 is fixed, and components such as the fixing frame 20 and the limiting block 21 are installed. By rotating the adjusting rod 18, the adjusting block 19 is driven to slide along the limiting block 21 to adjust the height of the processing part to adapt to different specifications of workpieces. At the same time, the stepper motor 3 drives the first transmission wheel 4, which drives the first driven wheel 7 through the first transmission belt 5, so that the rack and pinion conveyor belt 9 runs. The workpiece mounting platform 10 clamps the magnet and smoothly transmits it to the processing area. The second servo motor 2 drives the friction roller 17 through the second transmission belt 15 to perform the processing action. The third transmission belt 16 links multiple friction rollers 17 to work together. The first servo motor 1 can drive a specific friction roller 17 individually to meet diverse processing needs. The transmission, positioning and processing components work together to realize the full automation of the magnet from loading to processing, improving accuracy and efficiency.

[0027] The adjustment assembly achieves precise vertical adjustment through the cooperation of the adjustment rod 18, adjustment block 19, fixing frame 20, and limit block 21. The fixing frame 20 and limit block 21 provide a stable sliding track for the adjustment block 19. The threaded connection of the adjustment rod 18 ensures smooth adjustment and accurate positioning. The position of each component of the device can be flexibly adjusted according to the processing requirements of different specifications of neodymium iron boron magnets, effectively ensuring processing accuracy and meeting diverse production requirements. The transmission assembly combines multiple servo motors, transmission wheels, driven wheels, and transmission belts to form multiple transmission systems. The second servo motor 2 drives the friction roller 17 through the second transmission belt 15 to realize specific processing actions on the magnet. The third transmission belt 16 further expands the transmission path, enabling multiple friction rollers 17 to work together and improve processing efficiency. At the same time, the first servo motor 1 drives the friction roller 17 independently to perform independent processing tasks. The cooperation of multiple transmission methods enhances the processing capacity and efficiency of the device. The stepper motor 3, the first transmission wheel 4, the first transmission belt 5, and the first driven wheel 7 in the transmission assembly constitute a stable transmission system, driving the rack and pinion conveyor belt 9 to run precisely. The rack and pinion conveyor belt 9, in conjunction with the workpiece mounting platform 10, can securely clamp and transport neodymium iron boron magnets, ensuring accurate workpiece positioning and smooth transmission during processing, reducing processing errors caused by unstable transmission, and improving product quality and production stability.

[0028] This specification describes the embodiments, but not every embodiment contains only one independent technical solution. This way of describing the specification is only for clarity. Those skilled in the art should regard the specification as a whole. 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 Nd-Fe-B magnet integrated processing device, comprising a main box (6) and an adjusting assembly arranged on the upper surface of the main box (6), characterized in that, The adjustment assembly includes an adjustment rod (18), an adjustment block (19), a fixing frame (20), and a limiting block (21). The fixing frame (20) is fixedly connected to the upper surface of the main body box (6). The limiting block (21) is fixedly connected to the inner side wall of the fixing frame (20). The adjusting block (19) is slidably connected to the fixing frame (20) through the limiting block (21). The adjustment rod (18) is provided through the fixing frame (20), and the lower end of the adjustment rod (18) is threaded into the adjusting block (19).

2. The Nd-Fe-B magnet integrated processing device according to claim 1, wherein The upper surface of the main body box (6) is also provided with a transmission component and a transmission component that work in conjunction with the adjustment component.

3. The apparatus according to claim 2, wherein the apparatus is characterized by: The transmission assembly includes a second servo motor (2), a second transmission wheel (11), a second driven wheel (12), a second transmission belt (15), and a friction roller (17). The second servo motor (2) is slidably connected to the upper surface of the main body box (6) via a sliding plate. The output end of the second servo motor (2) is provided with a second transmission wheel (11). The friction roller (17) is rotatably connected to the adjusting block (19). One end of the friction roller (17) is fixedly connected to the second driven wheel (12), and the surfaces of the second driven wheel (12) and the second transmission wheel (11) are provided with a second transmission belt (15) for transmission.

4. The apparatus according to claim 3, wherein the apparatus is characterized by: The transmission assembly also includes a third transmission wheel (13), a third driven wheel (14) and a third transmission belt (16). The friction roller (17) is fixedly connected to the surface of the third transmission wheel (13), and the third transmission wheel (13) is located on one side of the second driven wheel (12). Another friction roller (17) is rotatably connected to another adjusting block (19) on the main body box (6), and one end of this friction roller (17) is fixedly connected to the third driven wheel (14). The surfaces of the third driven wheel (14) and the third transmission wheel (13) are provided with a third transmission belt (16) for transmission.

5. The apparatus according to claim 4, wherein the apparatus is characterized by: The transmission assembly also includes a first servo motor (1), which is slidably connected to the upper surface of the main body box (6) via a sliding plate, and the first servo motor (1) is separately connected to a friction roller (17) via a separately provided transmission belt.

6. The apparatus according to claim 2, wherein the apparatus is characterized by: The transmission assembly includes a second servo motor (2), a stepper motor (3), a first transmission wheel (4), a first transmission belt (5), a first driven wheel (7), and a support block (8). The stepper motor (3) is fixedly connected to the upper surface of the main body box (6). The first transmission wheel (4) is provided at the output end of the stepper motor (3). The support block (8) is fixedly connected to the upper surface of the main body box (6). The first driven wheel (7) is rotatably connected to the surface of the support block (8). The first transmission belt (5) for transmission is provided on the surfaces of the first driven wheel (7) and the first transmission wheel (4).

7. The apparatus according to claim 6, wherein the apparatus is characterized by: The transmission assembly also includes a rack conveyor belt (9) and a workpiece mounting platform (10). The support block (8) is provided with a rack conveyor belt (9), and the rack conveyor belt (9) is connected to the first driven wheel (7). The rack conveyor belt (9) is provided with a workpiece mounting platform (10) for fixing the workpiece.