A burning apparatus

By combining the board clamping mechanism, the position locking mechanism, and the locking auxiliary mechanism, the problem of unstable fixation of flexible circuit boards in the programming equipment is solved, achieving high-precision and high-efficiency programming operations and improving the adaptability and production efficiency of the equipment.

CN224473492UActive Publication Date: 2026-07-07JINGMEN HONGYI ELECTRONIC TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JINGMEN HONGYI ELECTRONIC TECH CO LTD
Filing Date
2025-07-09
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing programming equipment has difficulty in stably fixing flexible circuit boards and cannot adapt to flexible circuit boards of different specifications, resulting in low programming accuracy, low yield, and low production efficiency.

Method used

The system employs a plate clamping mechanism, a position locking mechanism, and a locking auxiliary mechanism. A hydraulic cylinder drives the clamping plate to apply uniform pressure. The precise cooperation between the support tube and the locking rod drives the ring and the threaded ring to work together, thereby achieving stable fixation of the flexible circuit board and multi-point position adjustment.

Benefits of technology

It improves programming accuracy and yield, enhances equipment adaptability and flexibility, simplifies operation procedures, and reduces adjustment time and costs.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of burning equipment, including base, board road compression mechanism, position clamping mechanism and clamping auxiliary mechanism, the board road compression mechanism includes mounting bracket and adjusting plate, the position clamping mechanism includes support pipe and clamping rod, the clamping auxiliary mechanism includes driving ring and thread ring, accurate guiding sliding of compression plate in compression groove is driven by compression cylinder, even stable pressure is applied to flexible road board, the cooperation sliding design of guide rod and mounting bracket effectively prevents that compression plate is deflected in movement process, ensure that pressure distribution is even, solved the problem that flexible circuit board is difficult to be fixed stably in traditional equipment, using the precision cooperation of support pipe and clamping rod, by the rotation of clamping pipe make inner sleeve block and wall block form into type connection, two-way spring rod is automatically inserted into embedded groove and form mechanical locking, ensure that clamping is firm and reliable.
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Description

Technical Field

[0001] This utility model relates to the field of programming technology, and more specifically, to a programming device. Background Technology

[0002] In the field of existing programming equipment technology, the fixation and adaptability of flexible circuit boards have always been key bottlenecks restricting production efficiency and quality. Existing programming equipment typically uses simple clamps or suction devices for fixation, which cannot apply uniform and stable pressure to the flexible circuit boards. Because flexible circuit boards have excellent flexibility and ductility, they are prone to deformation and displacement during programming, leading to programming position deviations and severely affecting programming accuracy and yield.

[0003] Existing programming equipment is typically designed for flexible circuit boards of specific sizes and lacks a flexible adjustment mechanism. When it is necessary to replace flexible circuit boards of different specifications, it is often necessary to replace the entire set of fixtures or readjust the fixing device. The adjustment process is cumbersome and time-consuming, which greatly reduces production efficiency and equipment utilization. The adjustment mechanism of traditional equipment has low precision and is difficult to achieve minute and precise position adjustments. It is particularly unsuitable for small flexible circuit boards that require high-precision programming. The lack of reliable positioning references during the adjustment process leads to the need for complex calibration procedures after each adjustment, increasing the workload and production costs. Utility Model Content

[0004] (a) Technical problems to be solved

[0005] In view of the problems existing in the prior art, this utility model provides a programming device to solve the technical problems mentioned in the background art, such as the difficulty in fixing flexible circuit boards and the difficulty in adapting to flexible circuit boards of different sizes.

[0006] (II) Technical Solution

[0007] To achieve the above objectives, this utility model provides the following technical solution: a programming device, comprising a base, a board path clamping mechanism, a position locking mechanism, and a locking auxiliary mechanism. The board path clamping mechanism includes a mounting frame and an adjusting plate. The mounting frame is mounted on the top end of the adjusting plate. A clamping cylinder is mounted on the mounting frame, and a clamping plate is oriented and mounted on one end of the clamping cylinder. A clamping groove is formed on the adjusting plate, and the clamping plate is slidably guided within the clamping groove. A hydraulic cylinder is mounted on the base, and a placement plate is mounted on one end of the hydraulic cylinder. The placement plate has... The device has a placement slot on which a flexible road plate is placed. A clamping plate presses against the flexible road plate through the clamping slot. The position locking mechanism includes a support tube and a locking rod. A locking tube is rotatably mounted on the support tube. A wall-adhering block is mounted on the outer wall of the locking rod. An inner sleeve block is mounted on the inner wall of the locking tube. A bidirectional spring rod is mounted on the wall-adhering block. An insertion groove is opened on the inner sleeve block, and an embedding groove is opened inside the insertion groove. The rotation of the locking tube causes the inner sleeve block to insert the wall-adhering block. The bidirectional spring rod can extend into the embedding groove, so that the locking rod and the locking tube are relatively fixed.

[0008] The present invention is further configured such that the snap-fit ​​auxiliary mechanism includes a driving ring and a threaded ring. The driving ring is installed at the bottom end of the outer wall of the snap-fit ​​tube, and the threaded ring is threadedly connected to the outer wall of the snap-fit ​​tube. A linkage block is installed at the outer end of the threaded ring. A winding rod is fixedly installed on the support tube, and a rotating block is slidably installed on the winding rod. The top end of the rotating block is connected to the bottom end of the driving ring. A return spring is installed on the winding rod, and one end of the return spring is connected to the side of the rotating block. The linkage block can be embedded into the rotating block, so that the rotating block drives the driving ring, so that the snap-fit ​​tube stably drives the inner sleeve block to rotate and fits the wall-attaching block.

[0009] The present invention is further configured such that longitudinal frames are symmetrically installed on the top end of the base, and longitudinal moving components are installed on the longitudinal frames. The longitudinal frames support the longitudinal moving components, thereby constructing a three-dimensional working space frame for the equipment.

[0010] The present invention is further configured such that a longitudinal moving frame is installed on the longitudinal moving component, and a transverse moving component is installed on the longitudinal moving frame. The longitudinal moving component and the longitudinal moving frame enable the programming component to be precisely positioned and moved in the vertical direction.

[0011] The present invention is further configured such that a programming component is installed on the transverse component, one end of which can be adjusted in the space at the top of the placement slot. The programming component performs the core programming function and can be flexibly adjusted in the space at the top of the placement slot to adapt to different programming needs.

[0012] The present invention is further configured such that the placement plate is provided with adjustment holes, and multiple sets of adjustment holes are provided, and the clamping tube is fixedly installed on the adjustment plate.

[0013] The present invention is further configured such that one end of the snap-fit ​​rod can pass through different adjustment holes and extend through the adjustment plate to engage with the support tube, so that the adjustment plate and the placement plate are connected. Multiple sets of adjustment holes are provided to provide flexible snap-fit ​​position selection to adapt to different process requirements and board specifications.

[0014] The present invention is further configured such that a guide rod is installed on one end face of the pressing plate, and the guide rod is slidably disposed relative to the mounting frame. The sliding of the guide rod and the mounting frame prevents the pressing plate from tilting during movement and ensures uniform pressure distribution.

[0015] (III) Beneficial Effects

[0016] Compared with the prior art, the present invention provides a programming device with the following advantages:

[0017] This invention features a board clamping mechanism. A clamping cylinder drives the clamping plate to slide precisely within the clamping groove, applying uniform and stable pressure to the flexible board. The sliding design of the guide rod and the mounting bracket effectively prevents the clamping plate from tilting during movement, ensuring uniform pressure distribution. This solves the problem of unstable fixation of flexible circuit boards in traditional equipment. A hydraulic cylinder controls the height of the placement plate, and combined with the carefully designed placement groove, it provides a stable and flat working platform for the flexible board, significantly improving programming accuracy and product yield.

[0018] This utility model features a position locking mechanism that employs a precise fit between a support tube and a locking rod. The rotation of the locking tube causes the inner sleeve block and the wall-mounted block to form an insert connection. A bidirectional spring rod automatically extends into the embedding groove to form a mechanical lock, ensuring a stable and reliable locking connection. The locking rod can pass through adjustment holes at different positions on the placement plate and engage with the support tube to achieve multi-point position adjustment. This effectively solves the problem of existing technologies being unable to adapt to flexible circuit boards of different sizes, significantly improving the adaptability and flexibility of the equipment.

[0019] This utility model is equipped with a snap-fit ​​auxiliary mechanism. Through the precise cooperation of the drive ring, threaded ring and linkage block, it provides a stable and controllable rotation drive for the snap-fit ​​tube. The rotating block on the winding rod works in coordination with the return spring to ensure the smoothness and accuracy of the snap-fit ​​process. The auxiliary mechanism design significantly improves the convenience and reliability of the snap-fit ​​operation, reduces operational errors, and improves work efficiency. At the same time, it provides technical support for the rapid switching of flexible circuit boards of different specifications. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the overall structure of the device in the unused state of this utility model;

[0021] Figure 2 This is a schematic diagram of the structure of this utility model;

[0022] Figure 3 This is a schematic diagram of the structure of this utility model;

[0023] Figure 4 This is a schematic diagram of the structure of this utility model;

[0024] Figure 5 This is a schematic diagram of the structure of this utility model.

[0025] In the diagram: 1. Base; 2. Mounting bracket; 3. Adjusting plate; 4. Clamping cylinder; 5. Clamping plate; 6. Clamping groove; 7. Hydraulic cylinder; 8. Placement plate; 9. Placement groove; 10. Support tube; 11. Snap-fit ​​rod; 12. Snap-fit ​​tube; 13. Wall-mounting block; 14. Inner sleeve block; 15. Double-acting spring rod; 16. Insertion groove; 17. Embedded groove; 18. Drive ring; 19. Threaded ring; 20. Linkage block; 21. Winding rod; 22. Rotating block; 23. Return spring; 24. Longitudinal frame; 25. Longitudinal movement assembly; 26. Longitudinal movement frame; 27. Transverse movement assembly; 28. Programming assembly; 29. ​​Adjustment hole; 30. Guide rod. Detailed Implementation

[0026] It should be noted that, unless otherwise specified, the embodiments and features described in this application can be combined with each other. The present invention will now be described in detail with reference to the accompanying drawings and embodiments.

[0027] It should be noted that, unless otherwise specified, all technical and scientific terms used in this application have the same meaning as commonly understood by one of ordinary skill in the art to which this application pertains.

[0028] In this utility model, unless otherwise stated, the orientations used, such as "up" and "down", usually refer to the direction shown in the accompanying drawings, or to the vertical, perpendicular, or gravitational direction; similarly, for ease of understanding and description, "left" and "right" usually refer to the left and right shown in the accompanying drawings; "inner" and "outer" refer to the inner and outer contours of each component itself, but the above directional terms are not used to limit this utility model.

[0029] Please see Figures 1-5A programming device includes a base 1, a circuit board clamping mechanism, a position locking mechanism, and a locking auxiliary mechanism. The circuit board clamping mechanism includes a mounting frame 2 and an adjusting plate 3. The mounting frame 2 is mounted on the top end of the adjusting plate 3. A clamping cylinder 4 is mounted on the mounting frame 2, and a clamping plate 5 is oriented and mounted on one end of the clamping cylinder 4. A clamping groove 6 is formed on the adjusting plate 3, and the clamping plate 5 is slidably guided within the clamping groove 6. A hydraulic cylinder 7 is mounted on the base 1, and a placement plate 8 is mounted on one end of the hydraulic cylinder 7. A placement groove 9 is formed on the placement plate 8, and a flexible circuit board is placed on the placement groove 9. The clamping plate 5 is connected to the base 1. The clamping groove 6 presses against the flexible road panel. The position locking mechanism includes a support tube 10 and a locking rod 11. The support tube 10 is rotatably mounted with a locking tube 12. A wall-adhering block 13 is installed on the outer wall of the locking rod 11. An inner sleeve block 14 is installed on the inner wall of the locking tube 12. A bidirectional spring rod 15 is installed on the wall-adhering block 13. A fitting groove 16 is opened on the inner sleeve block 14. An embedding groove 17 is opened in the fitting groove 16. The rotation of the locking tube 12 causes the inner sleeve block 14 to fit the wall-adhering block 13. The bidirectional spring rod 15 can extend into the embedding groove 17, so that the locking rod 11 and the locking tube 12 are relatively fixed.

[0030] In this embodiment, the operator places the flexible circuit board in the placement groove 9 of the placement plate 8. The hydraulic cylinder 7 drives the placement plate 8 to rise to the appropriate position. Then, the clamping cylinder 4 drives the clamping plate 5 to move downward through the clamping groove 6, applying uniform pressure to the flexible circuit board. The guide rod 30 slides in cooperation with the mounting bracket 2 to ensure that the clamping plate 5 is accurately positioned and pressed down smoothly, preventing displacement. The clamping plate 5 firmly fixes the flexible circuit board in the placement groove 9, providing a stable working platform for subsequent burning operations. The adjusting plate 3 needs to be precisely aligned with the placement plate 8. During connection, the operator inserts the locking rod 11 through the adjustment hole 29 on the adjustment plate 3 into the support tube 10, and rotates the locking tube 12 to gradually engage the inner sleeve block 14 with the wall-mounted block 13. As the rotation reaches the desired position, the bidirectional spring rod 15 on the wall-mounted block 13 automatically extends into the embedding groove 17 on the inner sleeve block 14, forming a reliable lock to ensure the precise positioning and stable connection between the adjustment plate 3 and the placement plate 8. When disassembly is required, the locking tube 12 is rotated in the opposite direction to disengage the bidirectional spring rod 15 from the embedding groove 17, thereby quickly releasing the locking state.

[0031] The snap-fit ​​auxiliary mechanism includes a drive ring 18 and a threaded ring 19. The drive ring 18 is installed at the bottom of the outer wall of the snap-fit ​​tube 12, and the threaded ring 19 is threadedly connected to the outer wall of the snap-fit ​​tube 12. A linkage block 20 is installed at the outer end of the threaded ring 19. A winding rod 21 is fixedly installed on the support tube 10, and a rotating block 22 is slidably installed on the winding rod 21. The top end of the rotating block 22 is connected to the bottom end of the drive ring 18. A return spring 23 is installed on the winding rod 21, and one end of the return spring 23 is connected to the side of the rotating block 22. The linkage block 20 can be embedded into the rotating block 22, so that the rotating block 22 drives the drive ring 18, so that the snap-fit ​​tube 12 stably drives the inner sleeve block 14 to rotate, and the wall-mounted block 13 is fitted in.

[0032] In this embodiment, the operator drives the rotating block 22 to rotate via the linkage block 20. The rotating block 22 drives the driving ring 18, which in turn drives the clamping tube 12 to rotate. The threaded connection between the threaded ring 19 and the clamping tube 12 provides precise rotation control. The winding rod 21 and the return spring 23 provide stable sliding guidance and return force for the rotating block 22, ensuring the stability and accuracy of the rotation process of the clamping tube 12, preventing shaking or displacement during the clamping process, and enabling the inner sleeve block 14 to accurately engage with the wall-mounted block 13.

[0033] Please see Figures 1-5 As a supplementary embodiment of the burning device for the plate clamping mechanism, position locking mechanism and locking auxiliary mechanism: a longitudinal frame 24 is symmetrically installed on the top end of the base 1. A longitudinal movement component 25 is installed on the longitudinal frame 24. A longitudinal movement frame 26 is installed on the longitudinal movement component 25. A transverse movement component 27 is installed on the longitudinal movement frame 26. A burning component 28 is installed on the transverse movement component 27. One end of the burning component 28 can be adjusted in the space at the top end of the placement slot 9. An adjustment hole 29 is opened on the placement plate 8. Multiple sets of adjustment holes 29 are provided. The locking tube 12 is fixedly installed on the adjustment plate 3. One end of the locking rod 11 can pass through different adjustment holes 29 and extend through the adjustment plate 3 to cooperate with the support tube 10 for locking, so that the adjustment plate 3 and the placement plate 8 are connected. A guide rod 30 is installed on one end face of the clamping plate 5. The guide rod 30 is relatively slidably set with the mounting frame 2.

[0034] More specifically, the flexible circuit board is placed in the placement slot 9 of the placement plate 8. The hydraulic cylinder 7 adjusts the height of the placement plate 8, and the adjusting plate 3 is precisely connected to the placement plate 8 through the position locking mechanism. Different adjusting holes 29 can be selected for locking as needed to achieve flexible positioning of flexible boards of different sizes. The clamping cylinder 4 drives the clamping plate 5 to press down, and firmly fixes the flexible circuit board in the placement slot 9. The longitudinal moving component 25 and the transverse moving component 27 work together to accurately position the burning component 28. The burning component 28 performs the burning operation of the flexible circuit board in the top space of the placement slot 9. After the burning is completed, the clamping plate 5 rises to release the flexible circuit board. With the assistance of the locking auxiliary mechanism, the locking state is quickly released, which facilitates the removal of the finished product and the next round of operation.

[0035] In summary, during the use or operation of the overall equipment: when the board clamping mechanism is required to operate, the operator places the flexible board in the placement slot 9 of the placement plate 8. The hydraulic cylinder 7 drives the placement plate 8 to rise to the appropriate position. Subsequently, the clamping cylinder 4 drives the clamping plate 5 to move downward through the clamping slot 6, applying uniform pressure to the flexible board. The guide rod 30 slides in cooperation with the mounting bracket 2 to ensure that the clamping plate 5 is accurately positioned and pressed down smoothly, preventing displacement. The clamping plate 5 firmly fixes the flexible board in the placement slot 9, providing a stable working platform for subsequent burning operations.

[0036] When the positioning locking mechanism is in operation, and the adjusting plate 3 needs to be precisely aligned and connected with the placement plate 8, the operator passes the locking rod 11 through the adjusting hole 29 on the adjusting plate 3 and inserts it into the support tube 10. The locking tube 12 is rotated so that the inner sleeve block 14 gradually engages with the wall-mounted block 13. As the rotation reaches the desired position, the bidirectional spring rod 15 on the wall-mounted block 13 automatically extends into the embedding groove 17 on the inner sleeve block 14, forming a reliable lock. This ensures the precise positioning and stable connection between the adjusting plate 3 and the placement plate 8. When disassembly is required, the locking tube 12 is rotated in the opposite direction to disengage the bidirectional spring rod 15 from the embedding groove 17, thus quickly releasing the locking state.

[0037] When the locking auxiliary mechanism is in operation, the operator drives the rotating block 22 to rotate through the linkage block 20. The rotating block 22 drives the driving ring 18, which in turn drives the locking tube 12 to rotate. The threaded connection between the threaded ring 19 and the locking tube 12 provides precise rotation control. The winding rod 21 and the return spring 23 provide stable sliding guidance and return force for the rotating block 22, ensuring the stability and accuracy of the rotation process of the locking tube 12, preventing shaking or deviation during the locking process, and enabling the inner sleeve block 14 to accurately engage with the wall-mounted block 13.

[0038] The flexible circuit board is placed in the placement slot 9 of the placement plate 8. The hydraulic cylinder 7 adjusts the height of the placement plate 8. The adjusting plate 3 is precisely connected to the placement plate 8 through the position locking mechanism. Different adjusting holes 29 can be selected for locking as needed to achieve flexible positioning of flexible boards of different sizes. The clamping cylinder 4 drives the clamping plate 5 to press down and fix the flexible circuit board firmly in the placement slot 9. The longitudinal moving component 25 and the transverse moving component 27 work together to accurately position the burning component 28. The burning component 28 performs the burning operation of the flexible circuit board in the top space of the placement slot 9. After the burning is completed, the clamping plate 5 rises to release the flexible circuit board. With the assistance of the locking auxiliary mechanism, the locking state is quickly released, which facilitates the removal of the finished product and the next round of operation.

[0039] Of all the solutions mentioned above, those involving the connection between two components can be selected according to the actual situation, such as welding, bolt and nut connection, bolt or screw connection, or other known connection methods, which will not be elaborated here. For all the fixed connections mentioned above, welding is preferred. Although embodiments of this utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and variations can be made to these embodiments without departing from the principles and spirit of this utility model. The scope of this utility model is defined by the appended claims and their equivalents.

[0040] In all the solutions mentioned above, those involving the operation of electrical components, unless otherwise explicitly described, are controlled by a controller. Since the devices matched with the controllers are common devices, their control principles and circuit connections are existing, well-known, and mature technologies, and their specific circuit structures will not be elaborated here. In all the solutions mentioned above, those involving motors can be used with a reducer if necessary. The connection structure and working principle between the motor and the reducer are existing, well-known technologies, and will not be elaborated here.

Claims

1. A programming device, comprising a base (1), a circuit board clamping mechanism, a position locking mechanism, and a locking auxiliary mechanism, characterized in that: The board clamping mechanism includes a mounting frame (2) and an adjusting plate (3). The mounting frame (2) is installed on the top end of the adjusting plate (3). A clamping cylinder (4) is installed on the mounting frame (2). A clamping plate (5) is oriented on one end of the clamping cylinder (4). A clamping groove (6) is opened on the adjusting plate (3). The clamping plate (5) is slidably guided in the clamping groove (6). A hydraulic cylinder (7) is installed on the base (1). A placement plate (8) is installed on one end of the hydraulic cylinder (7). A placement groove (9) is opened on the placement plate (8). The flexible board is placed on the placement groove (9). The clamping plate (5) is pressed against the wall through the clamping groove (6). The flexible road plate, the position locking mechanism includes a support tube (10) and a locking rod (11). The support tube (10) is rotatably mounted with a locking tube (12). A wall-adhering block (13) is mounted on the outer wall of the locking rod (11). An inner sleeve block (14) is mounted on the inner wall of the locking tube (12). A bidirectional spring rod (15) is mounted on the wall-adhering block (13). An insertion groove (16) is opened on the inner sleeve block (14). An embedding groove (17) is opened in the insertion groove (16). The rotation of the locking tube (12) causes the inner sleeve block (14) to insert the wall-adhering block (13). The bidirectional spring rod (15) can extend into the embedding groove (17).

2. The programming device according to claim 1, characterized in that: The snap-fit ​​auxiliary mechanism includes a drive ring (18) and a threaded ring (19). The drive ring (18) is installed at the bottom of the outer wall of the snap-fit ​​tube (12). The threaded ring (19) is threadedly connected to the outer wall of the snap-fit ​​tube (12). A linkage block (20) is installed at the outer end of the threaded ring (19). A winding rod (21) is fixedly installed on the support tube (10). A rotating block (22) is slidably installed on the winding rod (21). The top end of the rotating block (22) is connected to the bottom end of the drive ring (18). A return spring (23) is installed on the winding rod (21). One end of the return spring (23) is connected to the side of the rotating block (22). The linkage block (20) can be embedded into the rotating block (22) so that the rotating block (22) drives the drive ring (18).

3. The programming device according to claim 1, characterized in that: The base (1) is symmetrically equipped with a longitudinal frame (24) at its top end, and a longitudinal movement component (25) is installed on the longitudinal frame (24).

4. The programming device according to claim 3, characterized in that: The longitudinal moving component (25) is equipped with a longitudinal moving frame (26), and the longitudinal moving frame (26) is equipped with a transverse moving component (27).

5. The programming device according to claim 4, characterized in that: A programming component (28) is installed on the transverse component (27), and one end of the programming component (28) can be adjusted in the space at the top of the placement slot (9).

6. The programming device according to claim 1, characterized in that: The placement plate (8) is provided with adjustment holes (29), and multiple sets of adjustment holes (29) are provided. The clamping tube (12) is fixedly installed on the adjustment plate (3).

7. The programming device according to claim 6, characterized in that: One end of the snap-fit ​​rod (11) can pass through different adjustment holes (29) and extend through the adjustment plate (3) to engage with the support tube (10), so that the adjustment plate (3) and the placement plate (8) are connected.

8. The programming device according to claim 1, characterized in that: A guide rod (30) is installed on one end face of the clamping plate (5), and the guide rod (30) and the mounting bracket (2) are slidably arranged in cooperation.