Flexible copper clad plate processing conveying device
By using the linkage structure of components such as the adjustment table, electric telescopic rod, and drive shaft of the flexible copper clad laminate processing conveyor, the problem that existing devices cannot adapt to different specifications and processes is solved, and stable conveying and efficient production of the boards are achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- LINZHOU CHENGYU ELECTRONIC MATERIALS CO LTD
- Filing Date
- 2025-09-15
- Publication Date
- 2026-07-14
AI Technical Summary
Existing flexible copper clad laminate (FCCL) processing and conveying devices have shortcomings in structural design and functional implementation. They cannot easily adapt to FCCLs of different specifications and processing techniques, which makes the boards prone to deviation and jamming during the conveying process, affecting processing accuracy and production efficiency.
It adopts a linkage structure of components such as adjustment platform, electric telescopic rod, drive shaft, electric top rod and pulley to realize flexible adjustment of conveyor frame, and combined with controller to precisely control the operation of each component to adapt to different specifications and height requirements.
It effectively avoids the offset and jamming of the plates during the conveying process, improves processing accuracy and production efficiency, and enhances the adaptability of the equipment to diverse production environments.
Smart Images

Figure CN224492465U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of copper clad laminate processing and conveying technology, and in particular to a flexible copper clad laminate processing and conveying device. Background Technology
[0002] In the processing and production of flexible copper-clad laminates (FCLs), conveying devices are key equipment to ensure the continuity and efficiency of the production process. However, existing FCL processing conveying devices have many shortcomings in terms of structural design and functional implementation.
[0003] From a structural design perspective, traditional conveying devices often employ fixed frame structures with a relatively simple internal conveying component layout. The connection between the conveyor frame and the adjustment table lacks flexibility, making it difficult to adapt to different specifications and processing techniques of flexible copper-clad laminates. In actual production, different batches of flexible copper-clad laminates may vary in size and thickness. Existing conveying devices cannot easily change the position and angle of the conveyor frame, leading to problems such as board misalignment and jamming during conveying, affecting processing accuracy and production efficiency. Furthermore, traditional flexible copper-clad laminate processing conveying devices typically use a fixed conveying height, which cannot adapt to changes in height requirements under different production scenarios.
[0004] Therefore, it is necessary to provide a flexible copper-clad laminate processing and conveying device to solve the above-mentioned technical problems. Utility Model Content
[0005] This invention provides a flexible copper-clad laminate processing and conveying device, which solves the problems in the background art.
[0006] To address the aforementioned technical problems, this utility model provides a flexible copper-clad laminate processing and conveying device, comprising a device body. An adjustment platform is installed inside the device body, and the two are vertically connected by multiple sets of equidistantly distributed electric telescopic rods. These electric telescopic rods not only support the adjustment platform but also precisely control its height through telescopic movement to adapt to the height requirements of different production scenarios. A vertical plate is installed at the edge of the top surface of the adjustment platform. The surface of the vertical plate is movably connected to a drive shaft via a bearing seat. A conveying frame is fixed between the two drive shafts, allowing the conveying frame to adjust its position and angle in conjunction with the vertical plate and drive shafts to accommodate different specifications of laminates. A mounting frame is installed on the bottom surface of the adjustment platform. Two sets of symmetrically distributed electric push rods are vertically mounted on the mounting frame. Rollers are movably installed inside the mounting seats fixed at the output ends of the electric push rods. The rollers contact the bottom surface of the adjustment platform, and the electric push rods push the mounting seats and rollers, achieving fine-tuning of the position and angle of the adjustment platform and conveying frame through rolling. A conveying mechanism is installed inside the conveying frame. An electric push rod is vertically mounted on a mounting bracket on the bottom surface of the adjusting platform. A mounting base is fixed to the output end of the electric push rod, and rollers movably mounted inside the mounting base contact the bottom surface of the adjusting platform, assisting in the flexible adjustment of the conveying frame. Multiple pulleys are evenly distributed at the four corners of the bottom surface of the device body to facilitate movement and ensure stability. A controller is installed on the outer surface of the device body to control the operation of each component.
[0007] Preferably, multiple sets of equally spaced electric telescopic rods are vertically installed at the bottom of the device body. These electric telescopic rods are located between the device body and the adjustment platform, and the height of the adjustment platform can be precisely controlled by telescopic extension.
[0008] Preferably, the conveying mechanism includes a conveyor roller and a conveyor belt. The conveyor roller is driven by a drive motor, which drives the conveyor roller to rotate, thereby driving the conveyor belt to operate and complete the conveying of the flexible copper-clad laminate.
[0009] Preferably, the end face of the adjustment platform is provided with a clearance cavity to provide space for the movement and adjustment of each component during the operation of the device, avoid interference between components, and ensure smooth operation of the device.
[0010] Preferably, two sets of electric push rods are installed symmetrically on the mounting frame. The symmetrical distribution design ensures balance and stability when pushing the adjustment table and conveyor frame to adjust their position and angle.
[0011] Preferably, the device body has multiple pulleys installed on its bottom surface. These pulleys are evenly distributed at the four corners of the bottom of the device body, which facilitates the flexible movement of the device in the production workshop and ensures the stability of the movement process.
[0012] Preferably, a controller is installed on the outer surface of the device body, serving as the control core of the entire device. The controller is used to precisely control the operation of components such as the electric jack, electric telescopic rod, and drive motor, thereby realizing the various functions of the device.
[0013] Compared with related technologies, the flexible copper-clad laminate processing and conveying device provided by this utility model has the following beneficial effects:
[0014] Compared to existing technologies, the adjustable platform installed inside the device body achieves the movable connection of the conveyor frame through vertical plates, bearing seats, and drive shafts. Simultaneously, the mounting frame, electric push rods, mounting base, and rollers at the bottom of the adjustable platform form a linked adjustment structure. This design allows the conveyor frame to easily change position and angle according to flexible copper-clad laminates of different specifications and processing techniques, effectively avoiding offset and jamming problems during conveying, significantly improving processing accuracy and production efficiency. Multiple sets of equidistantly installed electric telescopic rods at the bottom of the device body can precisely control the height of the adjustable platform. This allows the conveying device to be flexibly adjusted according to changes in height requirements in different production scenarios, greatly enhancing the device's adaptability to diverse production environments.
[0015] The parts of the device not covered herein are the same as or can be implemented using existing technologies. Attached Figure Description
[0016] Figure 1 A schematic diagram of the structure of a flexible copper-clad laminate processing and conveying device provided by this utility model;
[0017] Figure 2 A schematic diagram of the conveyor frame structure of a flexible copper-clad laminate processing and conveying device provided by this utility model;
[0018] Figure 3 A schematic diagram of the clearance cavity structure of a flexible copper-clad laminate processing and conveying device provided by this utility model;
[0019] Figure 4 A schematic diagram of the mounting base structure of a flexible copper-clad laminate processing and conveying device provided by this utility model.
[0020] Numbering on the map:
[0021] 1. Device body; 2. Electric telescopic rod; 3. Adjusting platform; 4. Vertical plate; 5. Drive motor; 6. Conveying frame; 7. Conveying mechanism; 8. Controller; 9. Pulley; 10. Electric push rod; 11. Mounting frame; 12. Relief cavity; 13. Mounting base; 14. Roller. Detailed Implementation
[0022] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0023] Example 1
[0024] Please refer to the following: Figures 1-4 A flexible copper-clad laminate processing and conveying device includes a device body 1, which serves as the basic frame of the entire conveying device and provides a mounting carrier for other components. An adjusting platform 3 is installed inside the device body 1, and the two are vertically connected by multiple sets of equally spaced electric telescopic rods 2. During installation, the electric telescopic rods 2 are first fixed to the bottom of the device body 1, and their top ends are securely connected to the bottom surface of the adjusting platform 3 using bolts or other methods. The electric telescopic rods 2 not only support the adjusting platform 3 but also achieve telescopic movement through a built-in motor-driven screw and nut mechanism, thereby precisely controlling the height of the adjusting platform 3 to adapt to the height requirements of different production scenarios. For example, when the height of subsequent process equipment changes, the height of the adjusting platform 3 can be adjusted via the electric telescopic rods 2, ensuring smooth conveying.
[0025] A vertical plate 4 is installed at the edge of the top surface of the adjusting platform 3 by welding or bolting. The surface of the vertical plate 4 is movably connected to the drive shaft via a bearing seat. During installation, the bearing seat is first fixed in the preset position of the vertical plate 4, and then the drive shaft is passed through the inner ring of the bearing seat to ensure that the drive shaft can rotate flexibly. A conveyor frame 6 is fixed between the two drive shafts by welding or keying. This connection allows the conveyor frame 6 to adjust its position and angle around the drive shaft with the cooperation of the vertical plate 4 and the drive shaft. When it is necessary to adapt to flexible copper-clad laminates of different specifications and thicknesses, the posture of the conveyor frame 6 can be finely adjusted by external force or subsequent control structure to ensure that the board remains stable during the conveying process and will not shift or jam due to differences in specifications.
[0026] The bottom surface of the adjusting platform 3 is fitted with a mounting frame 11 by welding or bolting. Two sets of symmetrically distributed electric push rods 10 are vertically mounted on the mounting frame 11. The bottom of the electric push rod 10 is fixed to the mounting frame 11 by a flange, and the output end is connected to the mounting base 13 by a pin or bolt. The mounting base 13 is internally connected to a roller 14 via a bearing, and the roller 14 contacts the bottom surface of the adjusting platform 3. In actual operation, after the electric push rod 10 is started, its internal hydraulic or electric push rod mechanism pushes the mounting base 13, causing the roller 14 to roll on the bottom surface of the adjusting platform 3. This, in turn, drives the adjusting platform 3 and the conveying frame 6 to make fine adjustments to their position and angle, further enhancing the device's adaptability to changes in plate specifications and achieving precise adjustment of the posture of the conveying frame 6.
[0027] The conveying frame 6 houses a conveying mechanism 7 via bearing seats and a rotating shaft. The conveying mechanism 7 includes a conveyor roller and a conveyor belt driven by a drive motor 5. During installation, the conveyor roller is first installed in a suitable position within the conveying frame 6 via the bearing seats, then the conveyor belt is fitted onto it, and finally, the drive motor 5 is connected to the conveyor roller via a coupling. When the drive motor 5 is powered on, it drives the conveyor roller to rotate. The friction between the conveyor belt and the conveyor roller drives the conveyor belt to operate, thereby completing the conveying of the flexible copper-clad laminate.
[0028] Multiple pulleys 9 are bolted and evenly distributed at the four corners of the bottom surface of the device body 1. The pulleys 9 facilitate the movement of the device within the production workshop, and their distribution ensures stability during movement. A controller 8 is fixed to the outer surface of the device body 1 with screws. The controller 8 serves as the control core of the entire device and is connected to components such as the electric push rod 10, the electric telescopic rod 2, and the drive motor 5 via wires. It controls the operation of each component, receives operator commands, converts them into electrical signals, drives the corresponding components, and achieves precise control of the various functions of the device.
[0029] Example 2
[0030] Please refer to the following: Figures 1-4 Multiple sets of equidistantly distributed electric telescopic rods 2 are vertically installed at the bottom of the device body 1, located between the device body 1 and the adjusting platform 3. During installation, installation points are marked inside the device body 1 according to the designed spacing, and the electric telescopic rods 2 are fixed sequentially to ensure vertical installation and the smooth lifting and lowering of the adjusting platform 3. Through the built-in control system, the electric telescopic rods 2 can extend and retract in unison, achieving precise control of the height of the adjusting platform 3. When production requires a change in conveying height, the controller 8 sends a signal to the electric telescopic rods 2, and each electric telescopic rod 2 extends and retracts synchronously, adjusting the adjusting platform 3 to a suitable height to meet the docking requirements of different production equipment.
[0031] Example 3
[0032] Please refer to the following: Figures 1-4 The conveying mechanism 7 includes a conveyor roller and a conveyor belt. The conveyor roller is driven by a drive motor 5. The two ends of the conveyor roller are mounted on the conveyor frame 6 via bearings, and the conveyor belt is fitted over the outer surface of the conveyor roller. The drive motor 5 is fixed to the outside of the conveyor frame 6 by a mounting bracket, and its output shaft is connected to the conveyor roller via a coupling. When the drive motor 5 is powered on, the rotational motion of the motor shaft is transmitted to the conveyor roller through the coupling. The rotation of the conveyor roller drives the conveyor belt, and the friction between the conveyor belt and the flexible copper-clad laminate ensures smooth conveying of the laminate. Simultaneously, the tension of the conveyor belt can be adjusted by adjusting the spacing of the conveyor rollers or by setting a tensioning wheel to ensure the stability of the conveying process.
[0033] Example 4
[0034] Please refer to the following: Figures 1-4 The adjusting table 3 has a clearance cavity 12 on its end face. During the manufacturing of the adjusting table 3, the clearance cavity 12 is created through milling or cutting processes, and its position and size are designed according to the range of motion of the internal components of the device. During device operation, when the adjusting table 3 and the conveying frame 6 are adjusted in position and angle, or when the electric push rod 10 and the electric telescopic rod 2 extend or retract, the clearance cavity 12 provides space for the movement and adjustment of each component, avoiding interference between components, ensuring smooth operation of the device, and ensuring that each component has sufficient room for movement during its motion.
[0035] Example 5
[0036] Please refer to the following: Figures 1-4 Two sets of electric push rods 10 are installed symmetrically on the mounting frame 11. During installation, symmetrical installation points are first marked on the mounting frame 11 to ensure that the installation positions of the two sets of electric push rods 10 are precisely symmetrical. Through the symmetrical distribution design, when the electric push rods 10 push the adjusting platform 3 and the conveying frame 6 to adjust their position and angle, they can provide a balanced pushing force, preventing the adjusting platform 3 from tilting or shifting, and ensuring the balance and stability of the adjustment process. The two sets of electric push rods 10 work together to achieve multi-angle and multi-directional fine adjustments to the adjusting platform 3 and the conveying frame 6, improving the adaptability of the device to different specifications of plates.
[0037] Example 6
[0038] Please refer to the following: Figures 1-4 The device body 1 has multiple pulleys 9 mounted on its bottom surface, which are evenly distributed at the four corners of the bottom. After the device body 1 is manufactured, mounting holes are pre-drilled at the four corners. The pulley 9 mounting bases 13 are then fixed to the device body 1 with bolts, and the pulleys 9 are installed on the mounting bases 13. This installation method facilitates flexible movement of the device within the production workshop. When the device position needs to be adjusted, the operator can easily push the device, and the distribution of the pulleys 9 at the four corners ensures stability during movement, preventing the device from tilting or tipping over. This facilitates the transfer and layout adjustment of the device between different production areas.
[0039] Example 7
[0040] Please refer to the following: Figures 1-4A controller 8 is mounted on the outer surface of the device body 1. The controller 8 is fixed to a pre-installed mounting plate on the outer side of the device body 1 with screws. During installation, ensure that the electrical connection lines between the controller 8 and the device body 1 are neatly arranged and properly protected. As the control core of the entire device, the controller 8 integrates control circuits and related programs, and is connected to the control terminals of components such as the electric jack 10, the electric telescopic rod 2, and the drive motor 5 via wires. Operators input commands through the controller 8's operating interface. After parsing and processing the commands, the controller 8 sends control signals to the corresponding components, precisely controlling the operation of components such as the electric jack 10, the electric telescopic rod 2, and the drive motor 5, achieving automated control of various functions of the device, such as conveying speed adjustment, conveying height adjustment, and conveying frame 6 angle adjustment, ensuring stable operation of the device according to production requirements.
[0041] It should be noted that the control circuit of controller 8 can be implemented by simple programming by those skilled in the art, and is common knowledge in the field. It is only used and not modified, so the control method and circuit connection will not be described in detail.
[0042] The working principle of the flexible copper-clad laminate processing and conveying device provided by this utility model is as follows:
[0043] When using this flexible copper clad laminate processing conveyor, first, move the device to a suitable production position. Multiple pulleys 9 installed on the bottom surface of the device body 1 can easily push the device to move within the production workshop. Furthermore, the pulleys 9 are distributed at the four corners of the bottom of the device body 1, ensuring stability during the movement.
[0044] When flexible copper-clad laminates need to be transported, the conveyor mechanism 7 is activated. The conveyor rollers inside the conveyor mechanism 7 are driven by the drive motor 5, which drives the conveyor belt to rotate, thereby realizing the transport of the flexible copper-clad laminates.
[0045] If the flexible copper-clad laminates to be processed differ in size and thickness, and the position and angle of the conveyor frame 6 need to be adjusted, the electric push rod 10 on the mounting frame 11 can be activated by the controller 8 mounted on the outer surface of the control device body 1. The output end of the electric push rod 10 pushes the mounting base 13, causing the roller 14 to roll on the bottom surface of the adjusting table 3, thereby driving the adjusting table 3 and the conveyor frame 6 to adjust their position and angle to accommodate flexible copper-clad laminates of different specifications, ensuring that the board remains stable during the conveying process and does not shift or jam.
[0046] If different production scenarios have different requirements for conveying height, the electric telescopic rod 2 at the bottom of the device body 1 is activated via the controller 8. Multiple sets of electric telescopic rods 2 work together to precisely control the lifting and lowering of the adjusting platform 3 according to the set height requirements, enabling the conveying device to meet diverse production needs. Throughout the conveying process, the clearance cavity 12 opened on the end face of the adjusting platform 3 provides space for the movement and adjustment of related components, ensuring the smooth operation of the device.
[0047] It should be noted that all components used in this application are standard parts that can be purchased from the market. The specific connection methods of each part adopt conventional methods such as bolts, rivets and welding that are mature in the prior art. The mechanical parts and electrical equipment adopt conventional models in the prior art. The circuit connection adopts conventional connection methods in the prior art. The electrical equipment is connected to an external safe power source. These will not be described in detail here.
[0048] The above description is merely an embodiment of this utility model and does not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the content of this utility model specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this utility model.
Claims
1. A flexible copper-clad laminate processing and conveying device, comprising a device body (1), characterized in that, An adjustment platform (3) is installed inside the main body (1) of the device. A vertical plate (4) is installed at the edge of the top surface of the adjustment platform (3). A transmission shaft is movably connected to the surface of the vertical plate (4) through a bearing seat. A conveying frame (6) is fixed between the two transmission shafts. A conveying mechanism (7) is installed inside the conveying frame (6). A mounting bracket (11) is installed on the bottom surface of the adjustment platform (3). An electric push rod (10) is vertically installed on the mounting bracket (11). A mounting seat (13) is fixed at the output end of the electric push rod (10). A roller (14) is movably installed inside the mounting seat (13). The roller (14) is in contact with the bottom surface of the adjustment platform (3).
2. The flexible copper-clad laminate processing and conveying device according to claim 1, characterized in that, An electric telescopic rod (2) is vertically installed at the bottom of the device body (1). Multiple sets of electric telescopic rods (2) are installed, and the multiple sets of electric telescopic rods (2) are installed at equal distances between the device body (1) and the adjustment table (3).
3. The flexible copper-clad laminate processing and conveying device according to claim 1, characterized in that, The conveying mechanism (7) includes a conveyor roller and a conveyor belt, and the conveyor roller is driven by a drive motor (5).
4. The flexible copper-clad laminate processing and conveying device according to claim 1, characterized in that, The adjustment platform (3) has a relief cavity (12) on its end face.
5. The flexible copper-clad laminate processing and conveying device according to claim 1, characterized in that, Two sets of electric jacks (10) are installed, and the two sets of electric jacks (10) are symmetrically installed on the mounting frame (11).
6. The flexible copper-clad laminate processing and conveying device according to claim 1, characterized in that, The device body (1) is equipped with pulleys (9) on its bottom surface, and multiple pulleys (9) are installed, and the multiple pulleys (9) are evenly distributed at the four corners of the bottom of the device body (1).
7. The flexible copper-clad laminate processing and conveying device according to claim 1, characterized in that, A controller (8) is mounted on the outer surface of the device body (1).