Discrete device frame gradient coating positioning and clamping mechanism
By combining the design of positioning pins and limiting grooves with the structure of springs and sliding blocks, the discrete component frame clamping plate can be conveniently adjusted and stably fixed, solving the problem of cumbersome operation of traditional clamping mechanisms and improving coating efficiency and production efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- TAIXING YONGZHI ELECTRONIC DEVICE CO LTD
- Filing Date
- 2025-06-19
- Publication Date
- 2026-06-09
AI Technical Summary
The traditional discrete device frame gradient coating positioning clamping mechanism has a cumbersome clamping plate adjustment, resulting in low production efficiency, especially when changing frames of different specifications, which takes a long time.
The design employs a positioning pin and a limiting groove, combined with a reset spring, a spring spring, and an energy storage spring, to achieve convenient adjustment and fixation of the clamping plate. The wedge-shaped slide groove and the slider work together to achieve gradient position adjustment. The surface of the clamping plate is equipped with a rubber contact plate to increase friction.
It significantly reduces the complexity of clamping plate operation, improves coating efficiency and fixation stability, and enhances production efficiency and the practicality of the equipment.
Smart Images

Figure CN224337702U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of discrete device frame processing technology, and in particular to a gradient coating positioning and clamping mechanism for discrete device frames. Background Technology
[0002] Discrete component frame processing refers to a series of manufacturing and processing steps for the frame used to support discrete components. Discrete component frame processing requires high precision to ensure that the discrete components can be accurately installed on the frame. In the coating process, the coating positioning and clamping mechanism can accurately position and clamp the processed discrete component frame, ensuring accurate coating position, thereby transferring the precision of frame processing to the coating process and ensuring the performance and quality of the final product.
[0003] Some traditional discrete device frame gradient coating positioning clamping mechanisms generally use threaded adjustment or other relatively cumbersome methods to adjust the position of the clamping plate. This method requires multiple rotations or operations to achieve a certain displacement. Especially when it is necessary to frequently change discrete device frames of different specifications, a lot of time will be spent on adjustment, which reduces production efficiency. Utility Model Content
[0004] The technical problem to be solved by this utility model is that the adjustment of the clamping plate in the existing clamping mechanism is cumbersome, resulting in low production efficiency. To address this, we propose a discrete device frame gradient coating positioning clamping mechanism.
[0005] To achieve the above objectives, this application adopts the following technical solution: a discrete device frame gradient coating positioning and clamping mechanism, including a worktable, four adjustment slots at the top of the worktable, a fixed rod fixedly connected inside the adjustment slot, adjustment blocks slidably connected inside the adjustment slot and on the surface of the fixed rod, a gradient fixing cavity fixedly connected at the top of the adjustment block, a first connecting plate fixedly connected at one end of the gradient fixing cavity, a positioning pin slidably connected inside the first connecting plate, a push-pull plate fixedly connected at the top of the positioning pin, a clamping plate slidably connected inside the gradient fixing cavity, and four sets of limiting slots at the top of the worktable, the inside of the limiting slots slidably connected to the positioning pin.
[0006] Preferably, a return spring is slidably connected to the surface of the fixed rod. The end of the return spring near the adjusting block is fixedly connected to the adjusting block, and the end of the return spring away from the adjusting block is fixedly connected to the inside of the adjusting groove.
[0007] Preferably, limit grooves are provided on both sides of the inside of the adjustment groove, and limit sliders are fixedly connected to both sides of the adjustment block. The inside of the limit groove is slidably connected to the limit slider.
[0008] Preferably, a spring is slidably connected to the surface of the positioning pin, the top end of the spring is fixedly connected to the bottom end of the push-pull plate, and the bottom end of the positioning pin is fixedly connected to the top end of the first connecting plate.
[0009] Preferably, the size of the locating pin is designed to match the inner diameter of the limiting groove.
[0010] Preferably, the gradient fixing cavity is internally fixedly connected with four energy storage springs. Wedge-shaped grooves are provided on both sides of the gradient fixing cavity. Wedge-shaped sliders are fixedly connected to both sides of the clamping plate. The inside of the wedge-shaped grooves is slidably connected to the wedge-shaped sliders. A limit sleeve is installed at the top of the clamping plate. A second connecting plate is installed at the top of the gradient fixing cavity. A threaded rod is threadedly connected to the inside of the second connecting plate.
[0011] Preferably, a contact plate is mounted on the surface of the clamping plate, and the contact plate is made of rubber.
[0012] The technical effects and advantages of this utility model are as follows:
[0013] In this invention, when the operator needs to adjust the clamping position of the clamping plate, the push-pull plate is pulled upward to pull the positioning pin out of the limiting groove, so that the position of the adjusting block and the gradient fixing cavity are simultaneously released. At this time, the gradient fixing cavity is moved to make the clamping plate fit tightly against the discrete component frame. Then, the push-pull plate is moved downward to make the positioning pin re-insert into the limiting groove, thus achieving convenient adjustment of the clamping position of the clamping plate. By using the positioning pin and the limiting groove to fix the clamping plate, the operator can significantly reduce the cumbersomeness of the operation when clamping different discrete component frames, and effectively improve the coating efficiency of the discrete component frame during coating.
[0014] In this invention, when the operator needs to adjust the gradient position of the clamping plate, the threaded rod is rotated downwards to move the clamping plate downwards synchronously. The wedge-shaped groove and wedge-shaped slider ensure that the movement of the clamping plate will not deviate. After the movement is completed, the threaded rod is released to achieve the downward adjustment of the clamping plate. When upward adjustment is required, the threaded rod is rotated upwards. At this time, the elastic force of the energy storage spring will drive the clamping plate upwards synchronously to achieve the upward adjustment of the clamping plate. By setting the clamping plate to adjust the gradient position, the force pressure at different positions of the discrete device frame can be flexibly changed according to the coating requirements, effectively improving the practicality and performance of the device. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the main body of the positioning and clamping mechanism of this utility model;
[0016] Figure 2 This is a schematic diagram of the main structure of the workbench of this utility model;
[0017] Figure 3 This is a rear view schematic diagram of the gradient fixing cavity structure of this utility model;
[0018] Figure 4 This is a schematic diagram of the internal structure of the gradient fixing cavity of this utility model;
[0019] Figure 5 This is a schematic diagram of the clamping plate structure of this utility model.
[0020] Legend: 1. Worktable surface; 2. Adjustment groove; 3. Fixing rod; 4. Adjustment block; 5. Gradient fixing cavity; 6. First connecting plate; 7. Positioning pin; 8. Push-pull plate; 9. Clamping plate; 10. Limiting groove; 11. Return spring; 12. Limiting slide groove; 13. Limiting slider; 14. Elastic spring; 15. Energy storage spring; 16. Wedge-shaped slide groove; 17. Wedge-shaped slider; 18. Limiting sleeve; 19. Second connecting plate; 20. Threaded rod; 21. Contact plate. Detailed Implementation
[0021] The present invention will now be described in further detail with reference to the accompanying drawings and preferred embodiments. These drawings are simplified schematic diagrams, which only illustrate the basic structure of the present invention in a schematic manner, and therefore only show the components related to the present invention.
[0022] Reference Figures 1-5 As shown, this utility model provides a technical solution: a discrete device frame gradient coating positioning and clamping mechanism, including a worktable 1, four adjustment grooves 2 are formed at the top of the worktable 1, a fixing rod 3 is fixedly connected inside the adjustment groove 2, and an adjustment block 4 is slidably connected to both the inside of the adjustment groove 2 and the surface of the fixing rod 3. A gradient fixing cavity 5 is fixedly connected to the top of the adjustment block 4, a first connecting plate 6 is fixedly connected to one end of the gradient fixing cavity 5, a positioning pin 7 is slidably connected inside the first connecting plate 6, a push-pull plate 8 is fixedly connected to the top of the positioning pin 7, a clamping plate 9 is slidably connected inside the gradient fixing cavity 5, and four sets of limiting grooves 10 are formed at the top of the worktable 1, the inside of the limiting grooves 10 being slidably connected to the positioning pin 7. Next, when the operator needs to adjust the clamping position of the clamping plate 9, the push-pull plate 8 is pulled upward to pull the positioning pin 7 out of the limiting groove 10, so that the position of the adjusting block 4 and the gradient fixing cavity 5 are simultaneously released. At this time, the gradient fixing cavity 5 is moved to make the clamping plate 9 fit tightly against the discrete component frame. Then, the push-pull plate 8 is moved downward to make the positioning pin 7 re-insert into the limiting groove 10, thus achieving convenient adjustment of the clamping position of the clamping plate 9. By using the positioning pin 7 and the limiting groove 10 to fix the clamping plate 9, the operator can significantly reduce the cumbersomeness of the operation when clamping different discrete component frames, and effectively improve the coating efficiency of the discrete component frame during coating.
[0023] Reference Figure 2 and Figure 3 As shown in this embodiment: a return spring 11 is slidably connected to the surface of the fixing rod 3. The end of the return spring 11 near the adjusting block 4 is fixedly connected to the adjusting block 4, and the end of the return spring 11 away from the adjusting block 4 is fixedly connected to the inside of the adjusting groove 2. By setting the return spring 11, when it is necessary to remove the discrete device frame, the position of the gradient fixing cavity 5 is released. At this time, the stored tension of the return spring 11 will drive the clamping plate 9 to quickly pull back to the initial position, thereby releasing the discrete device frame from the clamping state, making it easy for the staff to remove it.
[0024] Reference Figure 2 As shown in this embodiment: both sides of the adjustment groove 2 are provided with limiting slide grooves 12, and both sides of the adjustment block 4 are fixedly connected with limiting sliders 13. The interior of the limiting slide groove 12 is slidably connected with the limiting sliders 13. Through the setting of the limiting slide groove 12 and the limiting sliders 13, the adjustment block 4 can form a stable guiding effect when sliding inside the adjustment groove 2, so that the adjustment block 4 will not deviate during the movement, effectively ensuring the accuracy of the position movement of the clamping plate 9.
[0025] Reference Figure 3 As shown in this embodiment: a spring spring 14 is slidably connected to the surface of the positioning pin 7. The top end of the spring spring 14 is fixedly connected to the bottom end of the push-pull plate 8, and the bottom end of the positioning pin 7 is fixedly connected to the top end of the first connecting plate 6. With the setting of the spring spring 14, when the operator adjusts the position of the clamping plate 9 and aligns the push-pull plate 8 with the limiting groove 10, the elastic force of the spring spring 14 is released, which will drive the positioning pin 7 to quickly insert into the limiting groove 10, thereby achieving quick fixation after the position of the clamping plate 9 is adjusted, and further improving the convenience of operation.
[0026] Reference Figure 2 and Figure 3 As shown in this embodiment, the size of the positioning pin 7 is designed to match the inner diameter of the limiting groove 10. By setting the special size, the position of the clamping plate 9 can be more stable after adjustment, and it is not easy to shake or shift, which effectively improves the fixing effect of the clamping plate 9, thereby significantly improving the fixing stability of the discrete device frame.
[0027] Reference Figure 4 and Figure 5As shown in this embodiment: four energy storage springs 15 are fixedly connected inside the gradient fixing cavity 5. Wedge-shaped grooves 16 are provided on both sides of the gradient fixing cavity 5. Wedge-shaped sliders 17 are fixedly connected to both sides of the clamping plate 9. The inside of the wedge-shaped grooves 16 is slidably connected to the wedge-shaped sliders 17. A limit sleeve 18 is installed at the top of the clamping plate 9. A second connecting plate 19 is installed at the top of the gradient fixing cavity 5. A threaded rod 20 is threadedly connected inside the second connecting plate 19. When the operator needs to adjust the gradient position of the clamping plate 9, the threaded rod 20 is rotated downwards to drive the clamping plate 9. The clamping plate 9 moves downward synchronously, and the wedge-shaped groove 16 and wedge-shaped slider 17 ensure that the movement of the clamping plate 9 will not deviate. After the movement is completed, the threaded rod 20 is released, which can achieve the downward adjustment of the clamping plate 9. When it is necessary to adjust upward, the threaded rod 20 is rotated upward. At this time, the elastic force of the energy storage spring 15 will drive the clamping plate 9 to move upward synchronously, thereby adjusting the upward position of the clamping plate 9. By setting the clamping plate 9 to perform gradient position adjustment, the force pressure at different positions of the discrete device frame can be flexibly changed according to the coating requirements, effectively improving the practicality and use effect of the device.
[0028] Reference Figure 5 As shown in this embodiment: a contact plate 21 is installed on the surface of the clamping plate 9. The contact plate 21 is made of rubber. By setting the contact plate 21, the clamping plate 9 can have greater friction when clamping the discrete device frame, thereby effectively improving the clamping effect of the clamping plate 9 and making it less prone to shaking and displacement.
[0029] Working principle: When the operator needs to adjust the clamping position of the clamping plate 9, the push-pull plate 8 is pulled upwards, causing the positioning pin 7 to be pulled out from the inside of the limiting groove 10. This releases the position of the adjusting block 4 from the gradient fixing cavity 5. At this time, the gradient fixing cavity 5 is moved, causing the clamping plate 9 to be pressed against the discrete component frame. Then, the push-pull plate 8 is moved downwards, causing the positioning pin 7 to be inserted back into the limiting groove 10. This allows for convenient adjustment of the clamping position of the clamping plate 9. By using the positioning pin 7 and the limiting groove 10 to fix the clamping plate 9, the operator can significantly reduce the complexity of the operation when clamping different discrete component frames, effectively improving the performance of discrete component clamping. The coating efficiency during device frame coating is improved by the reset spring 11. When the discrete device frame needs to be removed, the position of the gradient fixing cavity 5 is released. At this time, the stored tension of the reset spring 11 will drive the clamping plate 9 to quickly return to the initial position, thereby releasing the discrete device frame from the clamping state and making it easier for the operator to remove it. The limiting slide groove 12 and the limiting slider 13 can provide a stable guiding effect when the adjusting block 4 slides inside the adjusting groove 2, so that the adjusting block 4 will not deviate during the movement, effectively ensuring the accuracy of the clamping plate 9's position movement. The elastic spring 14, after the operator adjusts the position of the clamping plate 9, ensures that the clamping plate 9 is in a stable position. Align the push-pull plate 8 with the limiting groove 10. The release of the spring force of the elastic spring 14 will cause the positioning pin 7 to quickly insert into the limiting groove 10, achieving rapid fixation of the clamping plate 9 after position adjustment. This further enhances the convenience of operation. The special dimensional settings ensure greater stability after position adjustment of the clamping plate 9, preventing wobbling and displacement, effectively improving the fixing effect of the clamping plate 9 and significantly enhancing the stability of the discrete component frame. When the operator needs to adjust the gradient position of the clamping plate 9, rotating the threaded rod 20 downwards will cause the clamping plate 9 to move downwards synchronously. Furthermore, the wedge-shaped groove 16 and wedge-shaped slider 17 prevent the movement of the clamping plate 9 from causing... After the offset is completed, the threaded rod 20 is released, which allows the clamping plate 9 to be adjusted downwards. When upward adjustment is required, the threaded rod 20 is rotated upwards. At this time, the elastic force of the energy storage spring 15 will drive the clamping plate 9 to move upwards synchronously, thereby adjusting the upward position of the clamping plate 9. By setting the clamping plate 9 to adjust the gradient position, the force pressure on different positions of the discrete device frame can be flexibly changed according to the coating requirements, effectively improving the practicality and performance of the device. Through the setting of the contact plate 21, the clamping plate 9 can have greater friction when clamping the discrete device frame, thereby effectively improving the clamping effect of the clamping plate 9 and making it less prone to shaking and displacement.
[0030] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.
Claims
1. A discrete device frame gradient coating positioning and clamping mechanism, including a worktable, characterized in that: The top of the worktable has four adjustment slots. A fixing rod is fixedly connected inside each adjustment slot. Adjustment blocks are slidably connected to both the inside of the adjustment slot and the surface of the fixing rod. A gradient fixing cavity is fixedly connected to the top of each adjustment block. A first connecting plate is fixedly connected to one end of the gradient fixing cavity. A positioning pin is slidably connected inside the first connecting plate. A push-pull plate is fixedly connected to the top of the positioning pin. A clamping plate is slidably connected inside the gradient fixing cavity. The top of the worktable has four sets of limiting slots. The inside of each limiting slot is slidably connected to the positioning pin.
2. The discrete device frame gradient coating positioning and clamping mechanism according to claim 1, characterized in that: A return spring is slidably connected to the surface of the fixed rod. The end of the return spring near the adjusting block is fixedly connected to the adjusting block, and the end of the return spring away from the adjusting block is fixedly connected to the inside of the adjusting groove.
3. The discrete device frame gradient coating positioning and clamping mechanism according to claim 1, characterized in that: Limiting grooves are provided on both sides of the inside of the adjusting groove, and limiting sliders are fixedly connected to both sides of the adjusting block. The inside of the limiting groove is slidably connected to the limiting slider.
4. The discrete device frame gradient coating positioning and clamping mechanism according to claim 1, characterized in that: A spring is slidably connected to the surface of the positioning pin. The top end of the spring is fixedly connected to the bottom end of the push-pull plate, and the bottom end of the positioning pin is fixedly connected to the top end of the first connecting plate.
5. The discrete device frame gradient coating positioning and clamping mechanism according to claim 1, characterized in that: The dimensions of the positioning pin are designed to be compatible with the inner diameter of the limiting groove.
6. The discrete device frame gradient coating positioning and clamping mechanism according to claim 1, characterized in that: The gradient fixing cavity is internally fixedly connected with four energy storage springs. Wedge-shaped grooves are provided on both sides of the gradient fixing cavity. Wedge-shaped sliders are fixedly connected to both sides of the clamping plate. The inside of the wedge-shaped groove is slidably connected to the wedge-shaped slider. A limit sleeve is installed at the top of the clamping plate. A second connecting plate is installed at the top of the gradient fixing cavity. A threaded rod is threadedly connected to the inside of the second connecting plate.
7. The discrete device frame gradient coating positioning and clamping mechanism according to claim 1, characterized in that: The surface of the clamping plate is equipped with a contact plate, which is made of rubber.