A material dispensing device for key detection
By designing the misaligned cutting components and clamping mechanism, the problems of tilting and offset in the button material distribution device are solved, realizing efficient and stable separation and conveying of buttons, and improving material distribution efficiency and detection accuracy.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUIZHOU NOAH ELECTRONIC TECHNOLOGY CO LTD
- Filing Date
- 2025-09-18
- Publication Date
- 2026-06-30
AI Technical Summary
Existing button-operated material dispensing devices are prone to tilting or shifting due to uneven force during the separation process, resulting in low dispensing efficiency and affecting detection accuracy and continuity.
The device employs a staggered cutting component and a clamping mechanism. The staggered cutting component drives the cutting component to move along a direction perpendicular to the feeding direction. Combined with anti-tilting grippers and a clamping component, it achieves independent separation and stable clamping of the buttons, preventing them from tilting or shifting.
This improves the efficiency and stability of button feeding, ensuring that buttons can reliably enter the inspection station and improve overall production quality.
Smart Images

Figure CN224429341U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of button product material sorting technology, specifically, it mainly relates to a material sorting device for button detection. Background Technology
[0002] Button sorting is a crucial step connecting button feeding and subsequent testing processes. Buttons must be precisely separated into preset units to ensure they can stably enter the testing station and avoid testing errors or equipment jams due to sorting deviations. Efficient sorting ensures the continuity and accuracy of button testing, thereby improving overall production quality.
[0003] However, the sorting devices commonly used for button detection are mostly single-separation or simple cutting separation. During the separation process, due to the lack of an effective misalignment and clamping structure, the buttons are prone to lifting or shifting due to uneven force, which reduces the efficiency of button sorting. Utility Model Content
[0004] To address the shortcomings of existing technologies, this utility model provides a material sorting device for button detection, which solves the problems of buttons easily lifting or shifting and low material sorting efficiency.
[0005] This utility model discloses a material distribution device for button detection, comprising: a base, a feeding mechanism, a cutting mechanism, and a clamping mechanism; the feeding mechanism is disposed on the base, the cutting mechanism is disposed on the base and located at the end of the feeding mechanism, and the clamping mechanism is disposed on the base and located at the end near the cutting mechanism; the cutting mechanism includes a cutting component and a staggered cutting component, the staggered cutting component is disposed on the base, the cutting component is fixed on the staggered cutting component, the top surface of the cutting component is provided with a material placement groove, the length extension direction of the material placement groove is parallel to the feeding direction of the feeding mechanism, and the staggered cutting component drives the cutting component to move in a direction perpendicular to the feeding mechanism; the clamping mechanism includes a bracket, a driving mechanism, and a clamping component, the bracket is disposed on the base, the driving mechanism is disposed on the bracket, the clamping component is disposed on the driving mechanism, the driving mechanism drives the clamping component to move, and the material placement groove is located on the moving path of the clamping component.
[0006] According to one embodiment of the present invention, the cutting assembly includes a clamping block and an anti-warping assembly. The clamping block is provided with a material placement groove. The anti-warping assembly includes two anti-warping claws and an anti-warping drive assembly. The clamping block is fixed on the anti-warping drive assembly, the anti-warping drive assembly is fixed on the misaligned cutting assembly, the anti-warping drive assembly is connected to one of the two anti-warping claws, and the other anti-warping claw is fixed on the clamping block. The two anti-warping claws are located opposite each other on both sides of the material placement groove.
[0007] According to one embodiment of the present invention, the cutting mechanism further includes a limiting bracket, which is fixed on the cutting assembly and is positioned at the end of the material placement trough away from the feeding mechanism.
[0008] According to one embodiment of the present invention, the anti-tilting drive assembly includes an anti-tilting drive cylinder, a cylinder slider, and a gripper fixing block; the anti-tilting drive cylinder is disposed on the misalignment cutting assembly, and the cylinder slider is disposed on the anti-tilting drive cylinder; the gripper fixing block is disposed on the cylinder slider; one of the two anti-tilting grippers is fixed on the gripper fixing block.
[0009] According to one embodiment of the present invention, the top of the gripper fixing block is provided with a slot that matches the bottom of one of the anti-pry grippers, and the bottom of the anti-pry gripper is engaged in the slot.
[0010] According to one embodiment of the present invention, the misaligned cutting component includes a mounting bracket and a cutting drive component; the mounting bracket is fixed on the base, the cutting drive component is mounted on the mounting bracket, and the cutting drive component is connected to the cutting component in a transmission manner.
[0011] According to one embodiment of the present invention, the cutting drive assembly includes a cutting drive cylinder, a cutting connecting block, a sliding block, and a cutting fixing block. The cutting connecting block is fixedly mounted on a mounting bracket, the cutting drive cylinder is fixedly mounted on the cutting connecting block, a guide strip is provided on the cutting connecting block along the driving direction of the cutting drive cylinder, the sliding block is slidably mounted on the guide strip, the cutting fixing block is mounted on the sliding block and connected to the driving end of the cutting drive cylinder, and the cutting assembly is mounted on the cutting fixing block.
[0012] According to one embodiment of the present invention, the clamping assembly includes a gripper and a clamping drive; the clamping drive is fixed on the drive mechanism, the gripper is fixed on the clamping drive, and the gripper has multiple clamping stations.
[0013] According to one embodiment of the present invention, the clamping assembly further includes an elastic abutment member, which includes an abutment fixing block and a plurality of abutment springs. An abutment spring is provided on one end of the abutment fixing block near the clamping station.
[0014] The beneficial effects of this application are as follows: the feeding mechanism can provide a feeding and conveying channel for the buttons, ensuring that the buttons are conveyed to the cutting mechanism in an orderly manner; the cutting mechanism includes a cutting component and a staggered cutting component, and the top surface of the cutting component is provided with a material placement groove, the length extension direction of the material placement groove is parallel to the feeding direction of the feeding mechanism, so that the material placement groove can receive the buttons conveyed by the feeding mechanism. At the same time, by fixing the cutting component to the staggered cutting component, the staggered cutting component can drive the cutting component to move in a direction perpendicular to the feeding mechanism, thereby realizing the staggered separation of the buttons on the material placement groove from the subsequent buttons, avoiding mutual interference between buttons during traditional simple cutting and separation; the driving mechanism of the clamping mechanism drives the clamping component to move, and the material placement groove is located on the moving path of the clamping component, so that the clamping component can clamp the buttons that have been staggered and separated in the material placement groove. Compared to traditional single-separation or simple cutting separation devices, this structural design achieves independent separation of buttons through staggered cutting. Combined with the clamping component, it realizes the material feeding of buttons. This not only avoids the lifting and displacement caused by subsequent button interference during button separation, but also significantly improves the button feeding efficiency. Attached Figure Description
[0015] The accompanying drawings, which are included to provide a further understanding of this application and form part of this application, illustrate exemplary embodiments and are used to explain this application, but do not constitute an undue limitation of this application. In the drawings:
[0016] Figure 1 This is a three-dimensional structural diagram of the material dispensing device for button detection in the embodiment;
[0017] Figure 2 This is a three-dimensional structural diagram of the cutting mechanism in the embodiment;
[0018] Figure 3 This is a three-dimensional structural diagram of the cutting component in the embodiment;
[0019] Figure 4 This is a three-dimensional structural diagram of the misaligned segmentation component in the embodiment;
[0020] Figure 5 This is a three-dimensional structural diagram of the clamping mechanism in the embodiment;
[0021] Figure 6 This is a three-dimensional structural diagram of the clamping assembly in the embodiment.
[0022] Explanation of reference numerals in the attached figures
[0023] 1. Base;
[0024] 2. Feeding mechanism;
[0025] 3. Cutting mechanism; 31. Cutting assembly; 310. Material trough; 311. Clamping block; 312. Anti-tilting assembly; 3121. Anti-tilting gripper; 3122. Anti-tilting drive assembly; 31220. Slot; 31221. Anti-tilting drive cylinder; 31222. Cylinder slider; 31223. Gripper fixing block; 32. Offset cutting assembly; 321. Mounting bracket; 322. Cutting drive assembly; 3221. Cutting drive cylinder; 32210. Drive end; 3222. Cutting connecting block; 32220. Guide bar; 3223. Sliding block; 3224. Cutting fixing block; 33. Limiting bracket;
[0026] 4. Clamping mechanism; 41. Support; 42. Drive mechanism; 421. Servo motor; 422. PPU robot arm; 4220. Drive shaft; 43. Clamping assembly; 431. Gripper; 4310. Clamping station; 432. Clamping drive component; 433. Elastic abutment component; 4331. Abutment fixing block; 4332. Abutment spring. Detailed Implementation
[0027] The following drawings will disclose several embodiments of this utility model. For clarity, many practical details will be described in the following description. However, it should be understood that these practical details should not be used to limit this utility model. That is, in some embodiments of this utility model, these practical details are not essential. In addition, for the sake of simplicity, some conventional structures and components will be shown in the drawings in a simple schematic manner.
[0028] It should be noted that all directional indicators in this utility model embodiment, such as up, down, left, right, front, back, etc., are only used to explain the relative positional relationship and movement of the components in a specific posture as shown in the attached figure. If the specific posture changes, the directional indicator will also change accordingly.
[0029] Furthermore, in this utility model, the use of terms such as "first" and "second" is for descriptive purposes only and does not specifically refer to any order or sequence, nor is it intended to limit the utility model. They are merely used to distinguish items or operations described with the same technical terminology and should not be construed as indicating or implying relative importance or implicitly specifying the number of indicated technical features. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the technical solutions of various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. If the combination of technical solutions is contradictory or impossible to implement, such a combination should be considered non-existent and not within the scope of protection claimed by this utility model.
[0030] To further understand the utility model's content, features, and effects, the following embodiments are provided, along with detailed descriptions in conjunction with the accompanying drawings:
[0031] like Figure 1 As shown, Figure 1 This is a three-dimensional structural diagram of the button detection dispensing device in this embodiment. This embodiment provides a button detection dispensing device, which includes: a base 1, a feeding mechanism 2, a cutting mechanism 3, and a clamping mechanism 4. The feeding mechanism 2 is mounted on the base 1, the cutting mechanism 3 is mounted on the base 1 and located at the end of the feeding mechanism 2, and the clamping mechanism 4 is mounted on the base 1 and located near the end of the cutting mechanism 3. The feeding mechanism 2 uses a linear vibration device for feeding, which causes the buttons to be fed orderly along a track to the cutting mechanism 3 through linear vibration. The cutting mechanism 3 receives the buttons from the feeding mechanism 2 and cuts them into misaligned sections. Then, in conjunction with the clamping mechanism 4, it achieves efficient and stable button dispensing, thereby improving the button dispensing efficiency.
[0032] Please refer to the following: Figure 2-4 As shown, Figure 2 This is a three-dimensional structural diagram of the cutting mechanism in the embodiment; Figure 3 This is a three-dimensional structural diagram of the cutting component in the embodiment; Figure 4 This is a three-dimensional structural diagram of the misaligned cutting component in the embodiment. The cutting mechanism 3 includes a cutting component 31 and a misaligned cutting component 32. The misaligned cutting component 32 is mounted on the base 1, and the cutting component 31 is fixed to the misaligned cutting component 32. The top surface of the cutting component 31 is provided with a material placement groove 310. The length extension direction of the material placement groove 310 is parallel to the feeding direction of the feeding mechanism 2. The misaligned cutting component 32 drives the cutting component 31 to move in a direction perpendicular to the feeding mechanism 2. Specifically, when receiving the button delivered by the feeding mechanism 2, the misaligned cutting component 32 drives the cutting component 31 to move, so that the material placement groove 310 aligns with the end of the feeding mechanism 2, and the button enters the material placement groove 310. Afterward, the misaligned cutting component 32 drives the cutting component 31 to move, so that the material placement groove 310 is misaligned with the end of the feeding mechanism 2, thereby achieving misaligned separation of the button in the material placement groove 310 from other buttons in the feeding mechanism 2, providing convenience for the subsequent clamping mechanism 4 to clamp the material.
[0033] Furthermore, the cutting mechanism 3 also includes a limiting bracket 33; the limiting bracket 33 is fixed to the cutting assembly 31 and is positioned at the end of the material placement groove 310 away from the feeding mechanism 2. The limiting bracket 33 can limit the end position of the button in the material placement groove 310, preventing the button from sliding out of the end of the material placement groove 310 away from the feeding mechanism 2 during cutting misalignment, thus further improving the stability of the button during the cutting process.
[0034] For further details, please review. Figure 2-3The cutting assembly 31 includes a clamping block 311 and an anti-tilting assembly 312. The clamping block 311 is provided with a material placement groove 310, the shape of which is adapted to the shape of the button to ensure that the button can be placed stably. The anti-tilting assembly 312 includes two anti-tilting claws 3121 and an anti-tilting drive assembly 3122. The clamping block 311 is fixed on the anti-tilting drive assembly 3122, which is fixed on the misaligned cutting assembly 32. The anti-tilting drive assembly 3122 is connected to one of the two anti-tilting claws 3121, while the other anti-tilting claw 3121 is fixed on the clamping block 311. The two anti-tilting claws 3121 are located opposite each other on both sides of the material placement groove 310.
[0035] Among them, the anti-tilting drive component 3122 drives one anti-tilting gripper 3121 to move closer to the other anti-tilting gripper 3121 to clamp the button in the material slot 310, preventing the button from tilting or shifting during the cutting misalignment process, and ensuring the stability of the material distribution.
[0036] Furthermore, the anti-tilting drive assembly 3122 includes an anti-tilting drive cylinder 31221, a cylinder slider 31222, and a gripper fixing block 31223; the anti-tilting drive cylinder 31221 is disposed on the misalignment cutting assembly 32, and the cylinder slider 31222 is disposed on the anti-tilting drive cylinder 31221; the gripper fixing block 31223 is disposed on the cylinder slider 31222; one of the two anti-tilting grippers 3121 is fixed on the gripper fixing block 31223. In this system, the anti-tilting drive cylinder 31221 drives the cylinder slider 31222 to move. The movement of the cylinder slider 31222 causes the gripper fixing block 31223 to move. The movement of the gripper fixing block 31223 causes the anti-tilting gripper 3121 fixed on the gripper fixing block 31223 to move away from or closer to another fixed anti-tilting gripper 3121. When the two anti-tilting grippers 3121 move away from each other, the button delivered by the feeding mechanism 2 can easily enter the material storage groove 310. Then, the anti-tilting drive cylinder 31221 drives the two anti-tilting grippers 3121 to move closer to each other to hold the button in the material storage groove 310, thereby achieving anti-tilting clamping of the button.
[0037] Furthermore, the top of the gripper fixing block 31223 is provided with a slot 31220 that is adapted to the bottom of one of the anti-pry grippers 3121. The bottom of one of the anti-pry grippers 3121 is inserted into the slot 31220. This slot-type connection structure makes the anti-pry gripper 3121 and the gripper fixing block 31223 firmly connected, preventing the anti-pry gripper 3121 from falling off during the clamping process and ensuring the reliable realization of the anti-pry function.
[0038] For further details, please review. Figure 4The misalignment cutting component 32 includes a mounting bracket 321 and a cutting drive component 322. The mounting bracket 321 is fixed on the base 1, and the cutting drive component 322 is mounted on the mounting bracket 321 and is connected to the cutting component 31 in a transmission manner. The cutting drive component 322 can drive the cutting component 31 to move in a direction perpendicular to the feeding mechanism 2, thereby realizing the misalignment of the button cutting.
[0039] Furthermore, the cutting drive assembly 322 includes a cutting drive cylinder 3221, a cutting connecting block 3222, a sliding block 3223, and a cutting fixing block 3224. The cutting connecting block 3222 is fixedly mounted on the mounting bracket 321, and the cutting drive cylinder 3221 is fixedly mounted on the cutting connecting block 3222. A guide strip 32220 is provided on the cutting connecting block 3222 along the driving direction of the cutting drive cylinder 3221. The sliding block 3223 is slidably mounted on the guide strip 32220. The cutting fixing block 3224 is mounted on the sliding block 3223 and connected to the driving end 32210 of the cutting drive cylinder 3221. The cutting assembly 31 is mounted on the cutting fixing block 3224. The cutting drive cylinder 3221 serves as a power source and is fixed on the cutting connecting block 3222, while the cutting connecting block 3222 is mounted on the mounting bracket 321 to form an integral support structure. When the cutting drive cylinder 3221 is activated, its drive end 32210 will extend and retract axially. Since the drive end 32210 is connected to the cutting fixing block 3224, this extension and retraction directly drives the cutting fixing block 3224 to move synchronously. The cutting fixing block 3224 is mounted on the sliding block 3223, thus driving the sliding block 3223 to move as well. At this time, the guide strip 32220 on the cutting connecting block 3222, positioned along the driving direction, acts as a guide, causing the sliding block 3223 to slide linearly along the guide strip 32220, ensuring directional stability throughout the cutting process. Through this series of transmissions, the cutting fixing block 3224 drives the cutting assembly 31 mounted on it to complete the corresponding misaligned cutting action, realizing the misaligned cutting operation of the button within the material placement slot 310.
[0040] Please refer to the following: Figure 5-6 As shown, Figure 5 This is a three-dimensional structural diagram of the clamping mechanism in the embodiment; Figure 6 This is a three-dimensional structural diagram of the clamping assembly in the embodiment. The clamping mechanism 4 includes a bracket 41, a driving mechanism 42, and a clamping assembly 43. The bracket 41 is mounted on the base 1 and provides mounting support for the driving mechanism 42. The driving mechanism 42 is mounted on the bracket 41, and the clamping assembly 43 is mounted on the driving mechanism 42. The driving mechanism 42 drives the clamping assembly 43 to move, and the material placement groove 310 is located on the moving path of the clamping assembly 43.
[0041] The drive mechanism 42 includes a servo motor 421 and a PPU manipulator 422. The PPU manipulator 422 is fixed to the top of the bracket 41. The servo motor 421 is mounted on the drive shaft 4220 of the PPU manipulator 422. The drive shaft 4220 serves as a power input source and is rigidly connected to the output end of the servo motor 421. When the servo motor 421 starts, its output end drives the PPU manipulator 422 to move horizontally by rotating the drive shaft 4220. Simultaneously, the PPU manipulator 422 drives the clamping assembly 43 to move horizontally along the direction close to the material tray 310. While moving horizontally, the PPU manipulator 422 can simultaneously drive the clamping assembly 43 to move vertically, thereby driving the clamping assembly 43 to move horizontally and vertically to the top of the material tray 310, so that the clamping assembly 43 can drive and clamp the buttons in the material tray 310.
[0042] For further details, please review. Figure 5-6 The clamping assembly 43 includes a gripper 431 and a clamping drive 432. The clamping drive 432 is fixed to the drive mechanism 42. The gripper 431 is fixed to the clamping drive 432 and has multiple clamping stations 4310, which can clamp multiple buttons simultaneously, thereby improving material distribution efficiency. Specifically, after the drive mechanism 42 synchronously drives the clamping assembly 43 downwards towards the material placement groove 310 in both horizontal and vertical directions, the clamping drive 432, acting as a power source, has its output end connected to the gripper 431. The clamping drive 432 drives the gripper 431 to open, and the clamping stations 4310 on it grasp the button. Then, the clamping drive 432 drives the gripper 431 to close, and the button is smoothly embedded in the clamping station 4310. After clamping multiple buttons, the drive mechanism 42 synchronously drives the clamping drive 432 to move away from the material placement groove 310 in both horizontal and vertical directions. The clamping drive 432 drives the gripper 431 to move away from the material placement groove 310, thereby moving the clamping station 4310 away to realize the material distribution processing of multiple buttons.
[0043] Furthermore, the clamping assembly 43 also includes an elastic abutment member 433; the elastic abutment member 433 includes an abutment fixing block 4331 and multiple abutment springs 4332, with an abutment spring 4332 provided on one end of the abutment fixing block 4331 near the clamping station 4310. When the gripper 431 clamps the button, the button enters the clamping station 4310, and the abutment spring 4332 abuts against the top of the button, providing elastic cushioning to prevent excessive clamping force from damaging the button, while also enhancing clamping stability and preventing the button from falling off during subsequent handling.
[0044] In summary, traditional button detection and sorting devices lack effective misalignment and clamping structures, leading to buttons easily lifting and shifting, resulting in low sorting efficiency. The button detection and sorting device in this embodiment addresses these issues in two ways: First, the misalignment cutting component 32 of the cutting mechanism 3 achieves button misalignment, while the anti-lifting component 312 clamps and prevents the buttons from lifting or shifting during the cutting process. Second, the clamping component 43 of the clamping mechanism 4 has multiple clamping stations 4310 and elastic abutment members 433, enabling efficient and stable clamping of the buttons, further improving sorting efficiency and stability, and meeting the sorting requirements for button detection.
[0045] The above description is merely an embodiment of this utility model and is 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, improvements, etc., made within the spirit and principle of this utility model should be included within the scope of the claims of this utility model.
Claims
1. A material dispensing device for key detection, characterized in that, include: The system comprises a base (1), a feeding mechanism (2), a cutting mechanism (3), and a clamping mechanism (4); the feeding mechanism (2) is located on the base (1), the cutting mechanism (3) is located on the base (1) and at the end of the feeding mechanism (2), and the clamping mechanism (4) is located on the base (1) and at one end close to the cutting mechanism (3); the cutting mechanism (3) includes a cutting component (31) and a staggered cutting component (32), the staggered cutting component (32) is located on the base (1), the cutting component (31) is fixed to the staggered cutting component (32), and the top surface of the cutting component (31) is provided with a material placement groove (310). The length extension direction of the material trough (310) is parallel to the feeding direction of the feeding mechanism (2). The misaligned cutting component (32) drives the cutting component (31) to move in a direction perpendicular to the feeding mechanism (2). The clamping mechanism (4) includes a bracket (41), a driving mechanism (42), and a clamping component (43). The bracket (41) is mounted on the base (1). The driving mechanism (42) is mounted on the bracket (41). The clamping component (43) is mounted on the driving mechanism (42). The driving mechanism (42) drives the clamping component (43) to move. The material trough (310) is located on the moving path of the clamping component (43).
2. The material dispensing device for button detection according to claim 1, characterized in that, The cutting assembly (31) includes a clamping block (311) and an anti-tilting assembly (312). The clamping block (311) is provided with a material placement groove (310). The anti-tilting assembly (312) includes two anti-tilting grippers (3121) and an anti-tilting drive assembly (3122). The clamping block (311) is fixed on the anti-tilting drive assembly (3122), and the anti-tilting drive assembly (3122) is fixed on the misaligned cutting assembly (32). The anti-tilting drive assembly (3122) is connected to one of the two anti-tilting grippers (3121), and the other anti-tilting gripper (3121) is fixed on the clamping block (311). The two anti-tilting grippers (3121) are located opposite each other on both sides of the material placement groove (310).
3. The material dispensing device for button detection according to claim 1, characterized in that, The cutting mechanism (3) further includes a limiting bracket (33), which is fixed on the cutting assembly (31) and blocks the end of the material placement groove (310) away from the feeding mechanism (2).
4. The material dispensing device for button detection according to claim 2, characterized in that, The anti-tilting drive assembly (3122) includes an anti-tilting drive cylinder (31221), a cylinder slider (31222), and a gripper fixing block (31223); the anti-tilting drive cylinder (31221) is disposed on the misalignment cutting assembly (32), the cylinder slider (31222) is disposed on the anti-tilting drive cylinder (31221); the gripper fixing block (31223) is disposed on the cylinder slider (31222); one of the two anti-tilting grippers (3121) is fixed on the gripper fixing block (31223).
5. The material dispensing device for button detection according to claim 4, characterized in that, The top of the clamp fixing block (31223) is provided with a slot (31220) that is adapted to the bottom of one of the anti-tilting clamps (3121), and the bottom of the anti-tilting clamp (3121) is inserted into the slot (31220).
6. The material dispensing device for button detection according to claim 1, characterized in that, The misaligned cutting component (32) includes a mounting bracket (321) and a cutting drive component (322); the mounting bracket (321) is fixed on the base (1), the cutting drive component (322) is mounted on the mounting bracket (321), and the cutting drive component (322) is connected to the cutting component (31) in a transmission connection.
7. The material dispensing device for button detection according to claim 6, characterized in that, The cutting drive assembly (322) includes a cutting drive cylinder (3221), a cutting connecting block (3222), a sliding block (3223), and a cutting fixing block (3224). The cutting connecting block (3222) is fixedly mounted on the mounting bracket (321). The cutting drive cylinder (3221) is fixedly mounted on the cutting connecting block (3222). The cutting connecting block (3222) has a guide strip (32220) along the driving direction of the cutting drive cylinder (3221). The sliding block (3223) is slidably mounted on the guide strip (32220). The cutting fixing block (3224) is mounted on the sliding block (3223) and connected to the driving end (32210) of the cutting drive cylinder (3221). The cutting assembly (31) is mounted on the cutting fixing block (3224).
8. The material dispensing device for button detection according to claim 1, characterized in that, The clamping assembly (43) includes a gripper (431) and a clamping drive (432); the clamping drive (432) is fixed on the drive mechanism (42), the gripper (431) is fixed on the clamping drive (432), and the gripper (431) has multiple clamping stations (4310).
9. The material dispensing device for button detection according to claim 8, characterized in that, The clamping assembly (43) further includes an elastic abutment (433), which includes an abutment fixing block (4331) and a plurality of abutment springs (4332). An abutment spring (4332) is provided on one end of the abutment fixing block (4331) near the clamping station (4310).