Die cutting waste removal device
By coordinating the die-cutting machine body and the fixture, the material and waste are separated synchronously, solving the problem of waste falling and affecting production efficiency, and improving the production efficiency of the die-cutting waste removal device and the convenience of adjusting the support position.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHUNG TING ALFA ELECTRONIC TECH SHENZHEN CO LTD
- Filing Date
- 2025-06-19
- Publication Date
- 2026-06-05
AI Technical Summary
When using existing die-cutting waste removal devices, waste material easily falls onto the surface of the device, affecting production efficiency.
A die-cutting waste removal device was designed. By cooperating with the die-cutting machine body and the fixture, the material and waste are separated synchronously. The hydraulic system drives the die-cutting blade and the fixing block, and the collection mechanism adsorbs and collects the waste, simplifying the separation process.
It improved the production efficiency of the die-cutting waste removal device, reduced the sorting steps for subsequent workers, and simplified the adjustment process of the support position.
Smart Images

Figure CN224323238U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of die-cutting waste removal technology, and in particular relates to a die-cutting waste removal device. Background Technology
[0002] With the continuous development of modern industry, die-cutting technology, as an important processing technology, is widely used in packaging, electronics, printing and other fields. As an indispensable part of this process, the die-cutting waste removal device is responsible for separating and processing the waste material after die-cutting.
[0003] However, existing die-cutting waste removal devices typically use mechanical lifting or air blowing to eject waste from the mold and collect it to ensure product integrity and production efficiency. While this method simplifies the waste separation process, the lifted or blown waste sometimes falls onto the surface of the die-cutting waste removal device, affecting its normal operation and reducing its production efficiency.
[0004] In other words, traditional die-cutting waste removal devices often result in waste material falling onto their surface during use, thus reducing their production efficiency. Utility Model Content
[0005] This utility model addresses the problem in existing die-cutting waste removal devices where waste material falls onto the surface of the device during use, thus reducing its production efficiency. The following technical solution is proposed:
[0006] A die-cutting waste removal device, comprising:
[0007] Die cutting machine body;
[0008] The separation component includes a fixed block, an optical axis, a first movable block, a bracket, a second movable block, and a fixture. The fixture moves horizontally on the surface of the bracket via the second movable block. The bracket moves horizontally on the surface of the optical axis via the first movable block. A fixed block is provided on the optical axis. The fixed block is connected to the die-cutting machine body, so that the die-cutting machine body drives the separation component to operate synchronously.
[0009] As a preferred embodiment of the above technical solution, the bracket is provided with an active component, the active component is provided with a connecting rod and a handle, the connecting rod is located between the active component and the handle, the moving block two is provided with a driven component, the moving block two is provided with a linkage component and a linkage bar, the linkage component is connected to the driven component, and through the cooperation between the linkage component and the linkage bar, the linkage component drives the moving block two to move horizontally on the surface of the linkage bar.
[0010] As a preferred embodiment of the above technical solution, there are two optical axes, and the two optical axes are respectively located at the edge of the die-cutting machine body.
[0011] As a preferred embodiment of the above technical solution, the optical axis surface is in contact with the inner wall of the moving block to limit the moving direction of the moving block.
[0012] As a preferred embodiment of the above technical solution, the handle is provided with multiple grooves and the grooves are distributed in a circumferential array around the surface of the handle.
[0013] As a preferred embodiment of the above technical solution, the linkage bar is connected to one side of each of the two moving blocks, and the two moving blocks are horizontally aligned under the constraint of the linkage bar.
[0014] The beneficial effects of this utility model are as follows:
[0015] (1) By cooperating with the die-cutting machine body and the fixture, the die-cutting material and waste are separated, so that the die-cutting and separation steps can be carried out simultaneously, thereby reducing the subsequent sorting steps required by the staff and improving the production efficiency of the device.
[0016] (2) By rotating the handle to adjust the position of the moving block 2 on the support surface, the steps of adjusting the support position are simplified, so that the staff can complete the adjustment of the support position more quickly, thereby improving the process of adjusting the fixture. Attached Figure Description
[0017] Figure 1 The diagram shown is a structural schematic of a die-cutting waste removal device in Embodiment 1;
[0018] Figure 2 The diagram shown is a structural schematic of the fixing block in Embodiment 1;
[0019] Figure 3 The diagram shown is a schematic diagram of the back structure of the fixing block in Embodiment 1;
[0020] Figure 4 The diagram shown is a structural schematic of the handle in Embodiment 1.
[0021] In the diagram: 1. Die-cutting machine body; 2. Fixed block; 3. Optical axis; 4. Moving block one; 5. Support; 6. Moving block two; 7. Fixture; 8. Connecting rod; 9. Handle; 10. Driven component; 11. Linking component; 12. Linking bar; 13. Driving component. Detailed Implementation
[0022] To make the objectives, technical solutions, and advantages of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below in conjunction with the embodiments.
[0023] Example 1
[0024] This utility model provides a die-cutting waste removal device, such as... Figures 1 to 4 As shown, the assembly includes: a die-cutting machine body 1 and a separation component. The separation component includes a fixed block 2, an optical axis 3, a first movable block 4, a support 5, a second movable block 6, and a fixture 7. The fixture 7 has a rubber pad at its bottom end. The fixture 7 moves horizontally on the surface of the support 5 via the second movable block 6. The support 5 moves horizontally on the surface of the optical axis 3 via the first movable block 4. The top and bottom ends of the first movable block 4 are provided with threaded grooves, and screws are threaded into the threaded grooves to lock the first movable block 4 onto the surface of the optical axis 3. The optical axis 3 is provided with a fixed block 2. There are two fixed blocks 2 on the surface of a single optical axis 3, and the two fixed blocks 2 are connected by the same bolt via threads. The fixed blocks 2 are connected to the die-cutting machine body 1, so that the die-cutting machine body 1 drives the separation component to run synchronously. There are two optical axes 3, and the two fixed blocks 2 are located at the edges of the die-cutting machine body 1. The surface of the optical axis 3 is in contact with the inner wall of the first movable block 4 to limit the movement direction of the first movable block 4.
[0025] By cooperating with the die-cutting machine body 1 and the fixture 7, the die-cut material and waste are separated, so that the die-cutting and separation steps can be carried out simultaneously, thereby reducing the subsequent sorting steps required by the staff and improving the production efficiency of the device.
[0026] In operation, one end of the material is first wrapped around the surface of the collecting roller, which then moves the material. The operator then activates the hydraulic system inside the die-cutting machine body 1. The hydraulic system moves the die-cutting blade and the fixing block 2 downwards synchronously, and the die-cutting blade cuts the material inside the die-cutting machine body 1. Meanwhile, the collecting roller moves the die-cut material. When the die-cut material reaches the position below the fixture 7, the fixing block 2 moves the optical axis 3 downwards, which in turn moves the sliding block 4 downwards. The sliding block 4 moves the support 5 downwards, which in turn moves the sliding block 6 downwards. The sliding block 6 then moves the fixture 7 downwards. During the downward movement of the fixture 7, the die-cut material is squeezed, separating it from the waste. The waste is then collected by the collecting mechanism, completing the die-cutting process. Through the cooperation between the die-cutting machine body 1 and the fixture 7, the die-cut material and waste are separated, allowing the die-cutting and separation steps to be performed simultaneously. This reduces the need for subsequent sorting by operators, thereby improving the production efficiency of the device.
[0027] Specifically, a fixing block 2 is installed on one side of the die-cutting machine body 1 by screws. A light axis 3 is snapped into the inside of the fixing block 2. A sliding rod is connected to a moving block 4 on the surface of the light axis 3. A bracket 5 is snapped into the bottom of the moving block 4. A moving block 6 is slidably connected to the surface of the bracket 5. A fixture 7 is snapped into the edge of the moving block 6. The bottom of the fixture 7 is in contact with the surface of the die-cutting machine body 1.
[0028] In the above example, the die-cutting machine body 1 also includes a collecting roller, a hydraulic system, a die-cutting blade, and a collecting structure. During use, the hydraulic system drives the die-cutting blade to cut the material. Then, the fixture 7 separates the die-cut material from the waste. Finally, the collecting structure adsorbs and collects the waste, while the die-cut material is collected by the collecting roller, thus completing the separation of material and waste. The above are all prior art in this technical field and will not be elaborated here.
[0029] To facilitate the movement of the fixture 7 on the surface of the support 5 by the movable block 6 in the above example, the following solution is proposed: Figure 3 and Figure 4 As shown, the bracket 5 has an active component 13, and the active component 13 has a connecting rod 8 and a handle 9. The connecting rod 8 is located between the active component 13 and the handle 9. The moving block 2 6 has a driven component 10. The active component 13 is a worm gear, and the driven component 10 is a turbine. The active component 13 and the driven component 10 are meshed together. The moving block 2 6 has a linkage component 11 and a linkage bar 12. The linkage component 11 is connected to the driven component 10. The linkage component 11 is a gear, and the linkage bar 12 is a rack. The linkage component 11 is rotatably connected to the inside of the moving block 2 6, and the linkage bar 12 is slidably connected to the inside of the moving block 2 6. Through the cooperation between the linkage component 11 and the linkage bar 12, the linkage component 11 drives the moving block 2 6 to move horizontally on the surface of the linkage bar 12. The handle 9 has multiple grooves, and the grooves are arranged in a circumferential array around the surface of the handle 9. The linkage bar 12 is connected to one side of the two moving blocks 1 4 respectively, and the two moving blocks 1 4 are aligned horizontally by the constraint of the linkage bar 12.
[0030] By rotating the handle 9 to adjust the position of the moving block 2 6 on the surface of the bracket 5, the steps for adjusting the position of the bracket 5 are simplified, allowing the staff to complete the adjustment of the position of the bracket 5 more quickly, thereby improving the process of adjusting the fixture 7.
[0031] In use, the operator rotates handle 9, which drives connecting rod 8 and driving member 13 to rotate synchronously. Driving member 13 drives driven member 10 to rotate, and driven member 10 drives linkage member 11 to rotate. When linkage member 11 rotates, it is restricted by linkage bar 12, causing linkage member 11 to drive driven member 10 to move on the surface of linkage bar 12. At this time, driven member 10 moves synchronously with linkage member 11 along driving member 13. Driven by driven member 10, moving block 6 slides on the surface of bracket 5 and linkage bar 12. The restriction of moving block 6 by bracket 5 and linkage bar 12 makes the sliding process of moving block 6 more stable. The movement of moving block 6 drives fixture 7 to move. When fixture 7 moves to the desired position, it stops moving. The position of moving block 6 on the surface of bracket 5 is adjusted by rotating handle 9, which simplifies the steps of adjusting the position of bracket 5, allowing the operator to complete the adjustment of bracket 5 position more quickly, thereby improving the process of adjusting fixture 7.
[0032] Specifically, one end of the driving member 13 is fixedly connected to a connecting rod 8. Both the connecting rod 8 and the driving member 13 are rotatably connected inside the bracket 5. One end of the connecting rod 8 is fixedly connected to a handle 9. The surface of the driving member 13 is engaged with a driven member 10. The interior of the driven member 10 is fixedly connected with a linkage member 11. Both the driven member 10 and the linkage member 11 are rotatably connected inside the second moving block 6. The surface of the linkage member 11 is engaged with a linkage bar 12. Both ends of the linkage bar 12 are fixedly connected to the surface of the first moving block 4. The second moving block 6 is slidably connected to the surface of the linkage bar 12.
[0033] Working Principle: When using this device, one end of the material is first wrapped around the surface of the collecting roller, which then moves the material. The operator then activates the hydraulic system inside the die-cutting machine body 1. The hydraulic system drives the die-cutting blade and the fixing block 2 to move downwards synchronously, and the die-cutting blade cuts the material inside the die-cutting machine body 1. Meanwhile, the collecting roller moves the die-cut material. When the die-cut material moves to a position below the fixture 7, the fixing block 2 moves the optical axis 3 downwards, which in turn moves the first moving block 4 downwards. The first moving block 4 moves the support 5 downwards, which in turn moves the second moving block 6 downwards. The second moving block 6 then moves the fixture 7 downwards. During the downward movement of the fixture 7, the die-cut material is squeezed, separating the material from the waste. The waste is then collected by the collecting mechanism, completing the die-cutting process. Through the cooperation between the die-cutting machine body 1 and the fixture 7, the die-cut material and waste are separated, allowing the die-cutting and separation steps to be performed simultaneously. This reduces the need for subsequent sorting by operators, thereby improving the production efficiency of the device.
[0034] When the operator adjusts the position of fixture 7, they first turn handle 9. Handle 9 drives connecting rod 8 and driving member 13 to rotate synchronously. Driving member 13 drives driven member 10 to rotate, and driven member 10 drives linkage member 11 to rotate. When linkage member 11 rotates, it is restricted by linkage bar 12, causing linkage member 11 to drive driven member 10 to move on the surface of linkage bar 12. At this time, driven member 10 moves synchronously with linkage member 11 along driving member 13. Driven member 10 drives moving block 6 to slide on the surface of bracket 5 and linkage bar 12. The restriction of moving block 6 by bracket 5 and linkage bar 12 makes the sliding process of moving block 6 more stable. The movement of moving block 6 drives fixture 7 to move. When fixture 7 moves to the desired position, it stops moving. The position of moving block 6 on the surface of bracket 5 is adjusted by turning handle 9, which simplifies the steps of adjusting the position of bracket 5, allowing the operator to complete the adjustment of bracket 5 position more quickly, thereby improving the process of adjusting fixture 7.
[0035] The above embodiments are only used to illustrate the technical solution of this utility model, and are not intended to limit it.
Claims
1. A die-cutting waste discharge device, characterized in that, include: Die cutting machine body (1); The separation component includes a fixed block (2), an optical axis (3), a first movable block (4), a bracket (5), a second movable block (6), and a fixture (7). The fixture (7) moves horizontally on the surface of the bracket (5) via the second movable block (6). The bracket (5) moves horizontally on the surface of the optical axis (3) via the first movable block (4). The optical axis (3) is provided with a fixed block (2). The fixed block (2) is connected to the die-cutting machine body (1), so that the die-cutting machine body (1) drives the separation component to run synchronously.
2. The die-cutting waste removal device according to claim 1, characterized in that, The bracket (5) is provided with an active member (13), and the active member (13) is provided with a connecting rod (8) and a handle (9). The connecting rod (8) is located between the active member (13) and the handle (9). The second moving block (6) is provided with a driven member (10), and the second moving block (6) is provided with a linkage member (11) and a linkage bar (12). The linkage member (11) is connected to the driven member (10). Through the cooperation between the linkage member (11) and the linkage bar (12), the linkage member (11) drives the second moving block (6) to move horizontally on the surface of the linkage bar (12).
3. The die-cutting waste removal device according to claim 1, characterized in that, The optical axis (3) is set to two, and the two optical axes (3) are respectively located at the edge of the die-cutting machine body (1).
4. The die-cutting waste removal device according to claim 1, characterized in that, The surface of the optical axis (3) is in contact with the inner wall of the moving block (4) to restrict the moving direction of the moving block (4).
5. The die-cutting waste removal device according to claim 2, characterized in that, The handle (9) has multiple grooves that are arranged in a circular array around the surface of the handle (9).
6. The die-cutting waste removal device according to claim 2, characterized in that, The linkage bar (12) is connected to one side of the two moving blocks (4) respectively, and the two moving blocks (4) are aligned horizontally under the restriction of the linkage bar (12).