A composite control panel production and processing device

By designing a composite control panel production and processing device, using a laser cutter and servo motor drive, combined with multiple drive components and clamping devices, precise cutting and automatic material collection of substrates are achieved, solving the problem of the single function of existing cutting devices and improving work efficiency.

CN224475727UActive Publication Date: 2026-07-10ZHEJIANG DAAN ELECTRONIC TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHEJIANG DAAN ELECTRONIC TECH CO LTD
Filing Date
2025-08-04
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Existing cutting devices for cutting substrates have limited functionality and require manual assistance, resulting in low work efficiency.

Method used

A composite control panel manufacturing and processing device was designed, which uses a laser cutter and servo motor drive, and combines multiple drive components to achieve precise cutting and automatic material collection of the substrate. The device includes the integration of clamping components, multiple drive components and controller to achieve automated cutting and material collection.

Benefits of technology

It enables precise cutting and automatic material collection of substrates, improves cutting efficiency, reduces the need for manual assistance, and enhances production efficiency.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224475727U_ABST
    Figure CN224475727U_ABST
Patent Text Reader

Abstract

The utility model relates to control panel production and processing field discloses a kind of composite control panel production and processing device, and the workbench is equipped with processing assembly, and the processing assembly includes cutter, and the first drive component for driving cutter up and down movement is connected with cutter, and the second drive component for driving first drive component left and right movement is connected with first drive component, and the third drive component for driving second drive component forward and backward movement is connected with second drive component, and the table plate located above workbench, clamping assembly being equipped on table plate, telescopic cylinder A located right side of workbench, the bottom end of telescopic cylinder A is rotatably connected with workbench, and the piston rod top end of telescopic cylinder A is rotatably connected with push bar.The utility model has the beneficial effects of accurate cutting and direction material receiving, solves the problem that the cutting device for cutting substrate in the prior art has relatively single function, only has cutting function, and needs manual assistance, resulting in low work efficiency.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of control panel manufacturing and processing technology, specifically to a composite control panel manufacturing and processing device. Background Technology

[0002] In industrial production, control panels serve as crucial operating and display components for various devices and systems, making the quality and efficiency of their manufacturing paramount. With continuous technological advancements, higher demands are being placed on the manufacturing of control panels, requiring not only guaranteed processing precision but also increased production efficiency to meet the needs of large-scale production.

[0003] The substrate inside the control panel is its core component. When manufactured, the substrate is typically in large sheet form and needs to be cut into smaller pieces using a cutting device. Existing cutting devices for substrates have relatively limited functionality; for example, disc cutters only have cutting capabilities and require manual assistance, leading to low work efficiency. Utility Model Content

[0004] The purpose of this invention is to provide a composite control panel manufacturing and processing device to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a composite control panel production and processing device, including a workbench, a processing component on the workbench, the processing component including a cutter, a first driving component connected to the cutter for driving the cutter to move up and down, a second driving component connected to the first driving component for driving the first driving component to move left and right, a third driving component connected to the second driving component for driving the second driving component to move back and forth, a table plate located above the workbench, a clamping component disposed on the table plate, and a telescopic cylinder A located on the right side of the workbench, the third driving component being disposed above the workbench, the cutter being located above the table plate, the front end of the table plate being rotatably connected to the workbench via a rotating shaft, a push bar being fixedly disposed on the right side of the table plate, the bottom end of the telescopic cylinder A being rotatably connected to the workbench, and the top end of the piston rod of the telescopic cylinder A being rotatably connected to the push bar.

[0006] Preferably, the clamping assembly includes an L-shaped strip fixedly disposed above the platform, a plurality of threaded sleeves fixedly disposed inside the L-shaped strip, and a plurality of screws. The threaded sleeves are located above the platform, and the screws are screwed into the threaded sleeves and threadedly connected to the threaded sleeves. A pressure pad is fixedly disposed below the screws.

[0007] Preferably, the first drive assembly includes a bracket A, a telescopic cylinder B fixedly disposed above the bracket A, and a top plate fixedly disposed above the cutter and slidably connected to the bracket A. The piston rod of the telescopic cylinder B is fixedly connected to the top plate, and the bracket A is connected to the second drive assembly.

[0008] Preferably, the second drive assembly includes a bracket B, a slide A slidably disposed above the bracket B, a screw A rotatably disposed on the bracket B, and a motor A fixedly disposed on the left side of the bracket B. The output shaft of the motor A is fixedly connected to the screw A. The slide A has a screw hole A. The screw A is located in the screw hole A and threadedly connected to the slide A. The bracket A is fixedly disposed on the front side of the slide A. The bracket B is connected to the third drive assembly.

[0009] Preferably, the third drive assembly includes a bracket C fixedly mounted above the worktable, a slide B slidably mounted above the bracket C, a screw B rotatably mounted on the bracket C, and a motor B fixedly mounted on the rear side of the bracket C. The output shaft of the motor B is fixedly connected to the screw B. The slide B has a screw hole B, and the screw B is located in the screw hole B and threadedly connected to the slide B. The bracket B is fixedly mounted above the slide B.

[0010] Preferably, the processing assembly further includes a controller fixedly mounted above the worktable, and the cutter, motor A and motor B, telescopic cylinder A and telescopic cylinder B are all connected to the controller via wires.

[0011] Preferably, the cutter is a laser cutter, motor A and motor B are both servo motors, and telescopic cylinder A and telescopic cylinder B are both electric cylinders.

[0012] The beneficial effects of this utility model are as follows: When using this utility model, a large substrate to be cut is placed on the table, and the upper left corner of the substrate is aligned with the L-shaped strip, which serves to position the substrate. Rotating the screw moves it downwards, fixing the pressure pad above the substrate and pressing the substrate firmly against the table. Starting motors A and B drives screws A and B to rotate, moving the cutter to the starting cutting position. Activating the telescopic cylinder B pushes out its piston rod, moving the cutter downwards, bringing it closer to the substrate, and starting the cutter to cut the substrate. The position of the cutter is controlled by setting the operating rhythm of motors A and B, allowing the cutter to cut the large substrate into several smaller substrate pieces. The cutter is a laser cutter. The cutter, motors A and B are both servo motors, which play a role in precise cutting. After the substrate is cut, the cutter is turned off, and motors A and B are started to move the cutter to the back of the table. The telescopic cylinder A is activated to push its piston rod out, pushing the push bar and the table upward, making the table tilted. The receiving box is placed in front of the worktable, and the waste material frame after cutting is removed by loosening the screws. At this time, the cut small substrate pieces will slide from the table into the receiving box, which facilitates material collection. In summary, this utility model has the beneficial effects of precise cutting and directional material collection, and solves the problem that the existing cutting devices for cutting substrates have relatively simple functions, only have cutting functions, and require manual assistance, resulting in low work efficiency. Attached Figure Description

[0013] Appendix Figure 1 This is a schematic diagram of the structure of this utility model;

[0014] Appendix Figure 2 This is a schematic diagram of the processing component structure of this utility model;

[0015] Appendix Figure 3 This is a schematic diagram of the first drive component structure of this utility model.

[0016] In the diagram: 1. Workbench; 2. Cutter; 3. Tabletop; 4. Telescopic cylinder A; 5. Push bar; 6. L-shaped bar; 7. Screw sleeve; 8. Screw; 9. Pressure pad; 10. Bracket A; 11. Telescopic cylinder B; 12. Top plate; 13. Bracket B; 14. Slide table A; 15. Screw A; 16. Motor A; 17. Screw hole A; 18. Bracket C; 19. Slide table B; 20. Screw B; 21. Motor B; 22. Screw hole B; 23. Controller. Detailed Implementation

[0017] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention.

[0018] like Figure 1-3As shown, this utility model discloses a composite control panel production and processing device, including a workbench 1. The workbench 1 is provided with a processing component, which includes a cutter 2, a first driving component connected to the cutter 2 for driving the cutter 2 to move up and down, a second driving component connected to the first driving component for driving the first driving component to move left and right, a third driving component connected to the second driving component for driving the second driving component to move back and forth, a table plate 3 located above the workbench 1, a clamping component provided on the table plate 3, and a telescopic cylinder A4 located on the right side of the workbench 1. The third driving component is located above the workbench 1, and the cutter 2 is located above the table plate 3. The front end of the table plate 3 is rotatably connected to the workbench 1 through a rotating shaft. A push bar 5 is fixedly provided on the right side of the table plate 3. The bottom end of the telescopic cylinder A4 is rotatably connected to the workbench 1, and the top end of the piston rod of the telescopic cylinder A4 is rotatably connected to the push bar 5. In use, the large substrate to be cut is placed on the platform 3, and the upper left corner of the substrate is aligned with the L-shaped strip 6 to position the substrate. The screw 8 is rotated downwards to fix the pressure pad 9 above the substrate, pressing the substrate firmly against the platform 3. Motors A16 and B21 are started to rotate screws A15 and B20, moving the cutter 2 to the starting cutting position. The telescopic cylinder B11 is activated to extend its piston rod, moving the cutter 2 downwards closer to the substrate. The cutter 2 then cuts the substrate. The position of the cutter 2 is controlled by setting the operating rhythm of motors A16 and B21, allowing the cutter 2 to cut the large substrate into several smaller substrate pieces. The cutter 2 is a laser cutter. Both motors A16 and B21 are servo motors, which play a role in precise cutting. After the substrate is cut, the cutter 2 is turned off, and motors A16 and B21 are started to move the cutter 2 to the rear of the table 3. The telescopic cylinder A4 is activated to push its piston rod out, pushing the push bar 5 and the table 3 upward, so that the table 3 is tilted. The receiving box is placed in front of the worktable 1, and the waste frame after cutting is removed by loosening the screw 8. At this time, the cut small substrate pieces will slide from the table 3 into the receiving box, which facilitates material collection. In summary, this utility model has the beneficial effects of precise cutting and directional material collection, and solves the problem that the existing cutting devices for cutting substrates have relatively simple functions, only have cutting functions, and require manual assistance, resulting in low work efficiency.

[0019] Preferably, the clamping assembly includes an L-shaped strip 6 fixedly disposed above the platform 3, a plurality of threaded sleeves 7 fixedly disposed inside the L-shaped strip 6, and a plurality of screws 8. The threaded sleeves 7 are located above the platform 3, and the screws 8 are screwed into the threaded sleeves 7 and threadedly connected to them. A pressure washer 9 is fixedly disposed below the screws 8. Because the screws 8 are screwed into the threaded sleeves 7 and threadedly connected to them, it facilitates the clamping of the substrate; because the pressure washer 9 is fixedly disposed below the screws 8, it increases the clamping area.

[0020] Preferably, the first drive assembly includes a bracket A10, a telescopic cylinder B11 fixedly mounted above the bracket A10, and a top plate 12 fixedly mounted above the cutter 2 and slidably connected to the bracket A10. The piston rod of the telescopic cylinder B11 is fixedly connected to the top plate 12, and the bracket A10 is connected to the second drive assembly. Because the piston rod of the telescopic cylinder B11 is fixedly connected to the top plate 12, it facilitates the up-and-down movement of the cutter 2.

[0021] Preferably, the second drive assembly includes a bracket B13, a slide A14 slidably disposed above the bracket B13, a screw A15 rotatably disposed on the bracket B13, and a motor A16 fixedly disposed on the left side of the bracket B13. The output shaft of the motor A16 is fixedly connected to the screw A15. The slide A14 has a screw hole A17, and the screw A15 is located in the screw hole A17 and threadedly connected to the slide A14. The bracket A10 is fixedly disposed on the front side of the slide A14, and the bracket B13 is connected to the third drive assembly. Since the bracket A10 is fixedly disposed on the front side of the slide A14, it facilitates the left and right movement of the cutter 2.

[0022] Preferably, the third drive assembly includes a bracket C18 fixedly mounted above the worktable 1, a slide B19 slidably mounted above the bracket C18, a screw B20 rotatably mounted on the bracket C18, and a motor B21 fixedly mounted on the rear side of the bracket C18. The output shaft of the motor B21 is fixedly connected to the screw B20. The slide B19 has a screw hole B22, and the screw B20 is located in the screw hole B22 and threadedly connected to the slide B19. The bracket B13 is fixedly mounted above the slide B19. Because the bracket B13 is fixedly mounted above the slide B19, it facilitates the forward and backward movement of the cutter 2.

[0023] Preferably, the processing assembly further includes a controller 23 fixedly mounted above the workbench 1. The cutter 2, motors A16 and B21, and telescopic cylinders A4 and B11 are all connected to the controller 23 via wires. Since the cutter 2, motors A16 and B21, and telescopic cylinders A4 and B11 are all connected to the controller 23 via wires, it facilitates the control of the operation of each component.

[0024] Preferably, the cutter 2 is a laser cutter 2, the motors A16 and B21 are both servo motors, and the telescopic cylinders A4 and B11 are both electric cylinders. Because the cutter 2 is a laser cutter 2 and the motors A16 and B21 are both servo motors, it achieves precise cutting.

[0025] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. 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 composite control panel manufacturing and processing device, comprising a workbench (1), wherein processing components are provided on the workbench (1), characterized in that: The processing assembly includes a cutter (2), a first drive assembly connected to the cutter (2) for driving the cutter (2) to move up and down, a second drive assembly connected to the first drive assembly for driving the first drive assembly to move left and right, a third drive assembly connected to the second drive assembly for driving the second drive assembly to move back and forth, a table plate (3) located above the worktable (1), a clamping assembly provided on the table plate (3), and a telescopic cylinder A (4) located on the right side of the worktable (1). The third drive assembly is located above the worktable (1), the cutter (2) is located above the table plate (3), the front end of the table plate (3) is rotatably connected to the worktable (1) through a rotating shaft, a push bar (5) is fixedly provided on the right side of the table plate (3), the bottom end of the telescopic cylinder A (4) is rotatably connected to the worktable (1), and the top end of the piston rod of the telescopic cylinder A (4) is rotatably connected to the push bar (5).

2. The composite control panel manufacturing and processing device according to claim 1, characterized in that: The clamping assembly includes an L-shaped strip (6) fixedly disposed above the platform (3), several threaded sleeves (7) fixedly disposed inside the L-shaped strip (6), and several screws (8). The threaded sleeves (7) are located above the platform (3), and the screws (8) are screwed into the threaded sleeves (7) and threadedly connected to the threaded sleeves (7). A pressure pad (9) is fixedly disposed below the screws (8).

3. The composite control panel manufacturing and processing device according to claim 1, characterized in that: The first drive assembly includes a bracket A (10), a telescopic cylinder B (11) fixedly disposed above the bracket A (10), and a top plate (12) fixedly disposed above the cutter (2) and slidably connected to the bracket A (10). The piston rod of the telescopic cylinder B (11) is fixedly connected to the top plate (12), and the bracket A (10) is connected to the second drive assembly.

4. The composite control panel manufacturing and processing device according to claim 3, characterized in that: The second drive assembly includes a bracket B (13), a slide A (14) slidably disposed above the bracket B (13), a screw A (15) rotatably disposed on the bracket B (13), and a motor A (16) fixedly disposed on the left side of the bracket B (13). The output shaft of the motor A (16) is fixedly connected to the screw A (15). The slide A (14) has a screw hole A (17). The screw A (15) is located in the screw hole A (17) and threadedly connected to the slide A (14). The bracket A (10) is fixedly disposed on the front side of the slide A (14). The bracket B (13) is connected to the third drive assembly.

5. The composite control panel manufacturing and processing device according to claim 4, characterized in that: The third drive assembly includes a bracket C (18) fixedly mounted above the workbench (1), a slide B (19) slidably mounted above the bracket C (18), a screw B (20) rotatably mounted on the bracket C (18), and a motor B (21) fixedly mounted on the rear side of the bracket C (18). The output shaft of the motor B (21) is fixedly connected to the screw B (20). The slide B (19) has a screw hole B (22). The screw B (20) is located in the screw hole B (22) and threadedly connected to the slide B (19). The bracket B (13) is fixedly mounted above the slide B (19).

6. The composite control panel manufacturing and processing apparatus according to claim 5, characterized in that: The processing assembly also includes a controller (23) fixedly mounted above the workbench (1). The cutter (2), motor A (16) and motor B (21), telescopic cylinder A (4) and telescopic cylinder B (11) are all connected to the controller (23) via wires.

7. The composite control panel manufacturing and processing apparatus according to claim 6, characterized in that: The cutter (2) is a laser cutter (2), the motor A (16) and the motor B (21) are both servo motors, and the telescopic cylinder A (4) and the telescopic cylinder B (11) are both electric cylinders.