A carbon tape tension testing device
By designing a carbon ribbon tensile testing device, a moving plate and clamping column are used to hold the carbon ribbon cylinder, a rotating plate drives the carbon ribbon to rotate, and a lifting plate stretches the carbon ribbon. This solves the problem of low efficiency in carbon ribbon tensile testing in the existing technology and achieves high-efficiency testing.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- PENGMA NEW MATERIALS (ANHUI) CO LTD
- Filing Date
- 2025-07-29
- Publication Date
- 2026-06-19
AI Technical Summary
The existing carbon ribbon tensile testing device has a cumbersome process for changing the carbon ribbon tube, resulting in low efficiency for large-scale sampling and testing.
A carbon ribbon tensile testing device was designed, including a testing platform, a crossbeam plate, a lifting plate, a rotating plate, a clamping column, a pressure sensor, and other components. The carbon ribbon cylinder is clamped by the moving plate and the clamping column, the rotating plate drives the carbon ribbon to rotate, the lifting plate stretches the carbon ribbon, and the pressure sensor is used to detect the tensile strength performance.
It enables efficient carbon ribbon tensile testing, simplifies the carbon ribbon cartridge replacement process, and improves testing efficiency.
Smart Images

Figure CN224382995U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of carbon ribbon production, and in particular to a carbon ribbon tensile testing device. Background Technology
[0002] During the production of carbon ribbon, carbon ink needs to be sprayed onto a base belt to form a complete carbon ribbon. When in use, the carbon ribbon needs to be wound up and unwound by two rollers. During this process, a certain tension is applied to the carbon ribbon, so the carbon ribbon needs to have a certain tensile strength. This requires testing the tensile strength of the carbon ribbon after production. However, in the existing measurement methods, the carbon ribbon canister is fitted onto the rolling rod. This method makes the process of changing the carbon ribbon canister cumbersome and inefficient for large-scale sampling inspection. Utility Model Content
[0003] The technical problem to be solved by this utility model is to provide a carbon ribbon tensile testing device to solve the problem of low efficiency in carbon ribbon tensile testing in the prior art described in the background art.
[0004] To achieve the above objectives, this utility model provides the following technical solution: a carbon ribbon tensile testing device, comprising...
[0005] Testing station;
[0006] The crossbeam plate is set on the testing platform;
[0007] The lifting platform is U-shaped and can be lifted and lowered on the middle plate of the crossbeam plate;
[0008] A rotating plate is rotatably mounted on one side wall of the lifting plate;
[0009] The first clamping column is frustum-shaped and is mounted on the rotating plate. Several first blades are evenly arranged on the curved surface of the first clamping column.
[0010] The movable plate is movably mounted on the other side wall of the lifting plate;
[0011] The first pressure sensor is mounted on the moving plate;
[0012] A rotating base is positioned on the stress surface of the first pressure sensor;
[0013] The second clamping column is frustum-shaped and rotatably mounted on a rotating seat. Several second blades are evenly arranged on the curved surface of the second clamping column.
[0014] The second pressure sensor is mounted on the testing platform;
[0015] The support plate is U-shaped and is positioned on the stress surface of the second pressure sensor;
[0016] Positioning plates are installed on two opposite side walls of the support plate;
[0017] The clamping plate is movably mounted on the positioning plate and is used to clamp the carbon ribbon in conjunction with the positioning plate.
[0018] Preferably, the clamping plate is provided with a spring piece, and each end of the spring piece is provided with a threaded rod that slides through the spring piece, and the threaded rod is rotatably connected to the positioning plate.
[0019] Preferably, the lifting plate is provided with a movable cylinder, and the output end of the movable cylinder is fixedly connected to the movable plate.
[0020] Preferably, the lifting plate is equipped with a servo motor, and the output end of the servo motor is fixedly connected to the rotating plate.
[0021] Preferably, the crossbeam plate is provided with a lifting cylinder, the output end of which is fixedly connected to the lifting plate, and the lifting plate is provided with a plurality of guide rods that slide through the crossbeam plate.
[0022] The beneficial effects of adopting the above technical solutions are:
[0023] This application uses a movable plate to move the second clamping column, so that the first clamping column and the second clamping column clamp the carbon ribbon cylinder. The rotation of the rotating plate can drive the carbon ribbon cylinder to rotate. The first clamping column rotates on the rotating seat, thereby releasing the carbon ribbon. The clamping plate and the positioning plate can clamp one end of the carbon ribbon, and the lifting plate can stretch the carbon ribbon, thereby testing the tensile strength performance of the carbon ribbon. Attached Figure Description
[0024] Figure 1 This is a front view of a carbon ribbon tensile testing device according to this utility model.
[0025] Figure 2 This is a schematic diagram of some components of this utility model.
[0026] Figure 3 This is a schematic diagram of the second clamping post of this utility model.
[0027] The components include: a testing table 10, a crossbeam plate 20, a lifting plate 30, a lifting cylinder 31, a guide rod 32, a first clamping column 40, a first blade 41, a rotating plate 42, a servo motor 43, a second clamping column 50, a second large plate 51, a rotating seat 52, a first pressure sensor 60, a moving plate 61, a moving cylinder 62, a second pressure sensor 70, a positioning plate 80, a support plate 81, a clamping plate 90, a spring sheet 91, and a threaded rod 92. Detailed Implementation
[0028] The embodiments of this utility model are described in detail below with reference to the accompanying drawings.
[0029] like Figure 1-3In this first embodiment, a carbon ribbon tensile testing device includes...
[0030] Testing station 10;
[0031] A crossbeam plate 20 is installed on the testing table 10;
[0032] The lifting plate 30 is U-shaped and is mounted on the middle plate of the crossbeam plate 20 in a liftable manner.
[0033] The rotating plate 42 is rotatably mounted on one side wall of the lifting plate 30;
[0034] The first clamping post 40 is frustum-shaped and is mounted on the rotating plate 42. Several first blades 41 are evenly arranged on the curved surface of the first clamping post 40.
[0035] The movable plate 61 is movably mounted on the other side wall of the lifting plate 30;
[0036] The first pressure sensor 60 is mounted on the movable plate 61;
[0037] Rotating seat 52 is disposed on the stress surface of the first pressure sensor 60;
[0038] The second clamping column 50 is frustum-shaped and is rotatably mounted on the rotating seat 52. Several second blades 51 are evenly arranged on the curved surface of the second clamping column 50.
[0039] The second pressure sensor 70 is mounted on the detection stage 10;
[0040] The support plate 81 is U-shaped and is located on the stress surface of the second pressure sensor 70;
[0041] Positioning plates 80 are disposed on two opposite side walls of the support plate 81;
[0042] The clamping plate 90 is movably mounted on the positioning plate 80 and is used to clamp the carbon ribbon in conjunction with the positioning plate 80.
[0043] This embodiment is implemented as follows:
[0044] In use, the two ends of the carbon ribbon tube to be tested are first aligned with the first clamping post 40 and the second clamping post 50. Then, the moving plate 61 moves the first pressure sensor 60, which in turn moves the second clamping post 50, causing one end of the second clamping post 50 and the first clamping post 40 to extend into the two ends of the carbon ribbon tube, thus clamping the carbon ribbon tube. At this time, the first blade 41 and the second blade 51 can cut into the plastic carbon ribbon tube, preventing the carbon ribbon tube from slipping relative to the first blade 41 and the second blade 51. When the pressure sensed by the first pressure sensor 60 reaches the set value, the moving plate 61 stops, and then the rotating plate 42 rotates to release a certain length of carbon ribbon, placing the other end of the carbon ribbon between the clamping plate 90 and the positioning plate 80. Then, the clamping plate 90 moves to cooperate with the positioning plate 80 to clamp the carbon ribbon. Finally, the lifting plate 30 moves upward, causing the carbon ribbon to gradually straighten. At this time, the second pressure sensor 70 can sense the tension. When the tension reaches the set range, the lifting plate 30 stops moving, and the change in the carbon ribbon can be observed.
[0045] Please see Figure 1 , 2 A spring plate 91 is provided on the clamping plate 90. Threaded rods 92 that slide through the spring plate 91 are provided at both ends of the spring plate 91. The threaded rods 92 are rotatably connected to the positioning plate 80.
[0046] This application utilizes the rotation of the threaded rod 92 to drive the movement of the spring 91, which in turn drives the clamping plate 90 to move.
[0047] Please see Figure 1 A movable cylinder 62 is provided on the lifting plate 30, and the output end of the movable cylinder 62 is fixedly connected to the movable plate 61.
[0048] The movable cylinder 62 in this application can drive the movable plate 61 to move.
[0049] Please see Figure 1 A servo motor 43 is installed on the lifting plate 30, and the output end of the servo motor 43 is fixedly connected to the rotating plate 42.
[0050] The servo motor 43 configured in this application can drive the rotating plate 42 to rotate.
[0051] Please see Figure 1 A lifting cylinder 31 is provided on the crossbeam plate 20. The output end of the lifting cylinder 31 is fixedly connected to the lifting plate 30. Several guide rods 32 that slide through the crossbeam plate 20 are provided on the lifting plate 30.
[0052] The lifting cylinder 31 provided in this application can drive the lifting plate 30 to move vertically, and the guide rod 32 on the lifting plate 30 can increase the stability of the movement of the lifting plate 30.
[0053] The above are merely preferred embodiments of this utility model. It should be noted that, for those skilled in the art, several modifications and improvements can be made without departing from the inventive concept of this utility model, and these all fall within the protection scope of this utility model.
Claims
1. A carbon tape tension testing device, characterized by, include Testing station; The crossbeam plate is set on the testing platform; The lifting platform is U-shaped and can be lifted and lowered on the middle plate of the crossbeam plate; A rotating plate is rotatably mounted on one side wall of the lifting plate; The first clamping column is frustum-shaped and is mounted on the rotating plate. Several first blades are evenly arranged on the curved surface of the first clamping column. The movable plate is movably mounted on the other side wall of the lifting plate; The first pressure sensor is mounted on the moving plate; A rotating base is positioned on the stress surface of the first pressure sensor; The second clamping column is frustum-shaped and rotatably mounted on a rotating seat. Several second blades are evenly arranged on the curved surface of the second clamping column. The second pressure sensor is mounted on the testing platform; The support plate is U-shaped and is positioned on the stress surface of the second pressure sensor; Positioning plates are installed on two opposite side walls of the support plate; The clamping plate is movably mounted on the positioning plate and is used to clamp the carbon ribbon in conjunction with the positioning plate.
2. A carbon tape tension testing device as defined in claim 1, wherein, The clamp is equipped with a spring piece, and each end of the spring piece is provided with a threaded rod that slides through the spring piece. The threaded rod is rotatably connected to the positioning plate.
3. The carbon tape tension testing device of claim 1, wherein, The lifting plate is equipped with a movable cylinder, and the output end of the movable cylinder is fixedly connected to the movable plate.
4. The carbon tape tension testing device of claim 1, wherein, The lifting plate is equipped with a servo motor, and the output end of the servo motor is fixedly connected to the rotating plate.
5. The carbon tape tension testing device of claim 1, wherein, A lifting cylinder is installed on the crossbeam plate, and the output end of the lifting cylinder is fixedly connected to the lifting plate. Several guide rods that slide through the crossbeam plate are installed on the lifting plate.