Precise bending equipment for battery tab processing

By setting up conveying, positioning, bending, and stopping mechanisms, the problems of positional deviation and inconvenient material handling in the processing of battery connecting pieces are solved, achieving precise processing and efficient production.

CN224406115UActive Publication Date: 2026-06-26SHENZHEN CITY FUJIADA HARDWARE PLASTIC PROD CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN CITY FUJIADA HARDWARE PLASTIC PROD CO LTD
Filing Date
2025-07-31
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing battery connector bending equipment lacks a precise conveying and positioning mechanism, which makes it easy for the bending position to deviate. In addition, the lack of a stop mechanism makes it inconvenient to pick up materials, affecting processing accuracy and efficiency.

Method used

A precision bending device for processing battery connectors was designed, comprising a conveying mechanism, a positioning mechanism, a bending mechanism, and a stopping mechanism. These mechanisms enable precise conveying, positioning, bending, and stopping of battery connectors, thereby improving processing accuracy and production efficiency.

Benefits of technology

It enables precise delivery, positioning, bending, and stable dwell of battery connectors, improving processing accuracy and production efficiency, ensuring stable delivery and accurate positioning of battery connectors, and adapting to the needs of different production rhythms.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224406115U_ABST
    Figure CN224406115U_ABST
Patent Text Reader

Abstract

The utility model discloses a kind of precision bending equipment for battery connecting piece processing, it relates to the technical field of battery processing equipment, and the precision bending equipment for battery connecting piece processing includes workbench, conveying mechanism for conveying battery connecting piece, positioning mechanism for the connecting piece positioning on conveying mechanism, bending mechanism for the bending of battery connecting piece and the stop mechanism for the stop of battery connecting piece after bending, the positioning mechanism and bending mechanism are all set in conveying mechanism side, and the stop mechanism is located at the end of conveying mechanism;The conveying mechanism has material discharging support plate for placing battery connecting piece, and the bending mechanism has bending plate, and the bending plate is movably contacted with battery connecting piece on material discharging support plate;By setting conveying mechanism, positioning mechanism, bending mechanism and stop mechanism, accurate transmission, positioning, bending and stop to battery connecting piece are realized, and processing precision and production efficiency are improved.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the technical field of equipment for processing battery connectors, and in particular to a precision bending device for processing battery connectors. Background Technology

[0002] Bending is a crucial step in the processing of battery connectors. Existing battery connector bending equipment has several shortcomings. For example, the lack of a precise conveying and positioning mechanism during connector transport leads to positional deviations during bending, affecting bending accuracy. Furthermore, the absence of a stopping mechanism after bending hinders the unloading of the connectors. Therefore, there is an urgent need to develop a precision bending machine for battery connector processing to meet practical application requirements. Utility Model Content

[0003] In view of this, the present invention addresses the deficiencies of the existing technology, and its main objective is to provide a precision bending device for processing battery connectors. This device, by setting up a conveying mechanism, a positioning mechanism, a bending mechanism, and a stopping mechanism, achieves precise conveying, positioning, bending, and stopping of battery connectors, thereby improving processing accuracy and production efficiency.

[0004] To achieve the above objectives, the present invention adopts the following technical solution:

[0005] A precision bending device for processing battery connectors includes a worktable, a conveying mechanism for conveying battery connectors, a positioning mechanism for positioning connectors on the conveying mechanism, a bending mechanism for bending the battery connectors, and a stopping mechanism for stopping the bent battery connectors. The conveying mechanism is disposed on the worktable, the positioning mechanism and the bending mechanism are disposed beside the conveying mechanism, and the stopping mechanism is located at the end of the conveying mechanism. The conveying mechanism has a feeding tray for placing battery connectors, and the bending mechanism has a bending plate that is movably abutting against the battery connectors on the feeding tray.

[0006] As a preferred embodiment, the bending mechanism further includes a longitudinal drive assembly and a rotary drive assembly. The longitudinal drive assembly is mounted on the worktable, the rotary drive assembly is mounted at the output end of the longitudinal drive assembly, and the bending plate is mounted at the output end of the rotary drive assembly.

[0007] As a preferred embodiment: the rotary drive assembly includes a rotary drive motor, a belt drive device, and a rotary shaft. The rotary drive motor is mounted at the output end of the longitudinal drive assembly, and the rotary shaft is mounted at the output end of the rotary drive motor via the belt drive device. One end of the bending plate is fastened to the rotary shaft.

[0008] As a preferred embodiment: the belt drive device includes a driving pulley, a driven pulley, a transmission belt, and an adjusting pulley. The driving pulley is installed at the output end of the rotary drive motor, the transmission belt is sleeved on the driving pulley and the driven pulley, and the adjusting pulley is rotatably abutted against the transmission belt.

[0009] As a preferred embodiment: the longitudinal drive assembly includes a longitudinal drive motor, a longitudinal lead screw, and a longitudinal slide. The longitudinal drive motor is mounted on the worktable, the longitudinal lead screw is mounted on the output end of the longitudinal drive motor, the longitudinal slide is rotatably engaged with the longitudinal lead screw, and the rotary drive assembly is mounted on the longitudinal slide.

[0010] As a preferred embodiment: the positioning mechanism includes a positioning drive cylinder and a positioning block. The positioning drive cylinder is longitudinally mounted on the conveying mechanism, and the positioning block is mounted on the output end of the positioning drive cylinder. The positioning block is movable and abuts against the feeding tray.

[0011] As a preferred embodiment: the stop mechanism includes a support, a stop driving cylinder and a stop block. The stop driving cylinder is vertically mounted on the support, and the stop block is mounted on the output end of the stop driving cylinder. When the stop block descends, it stops at the front end of the material feeding tray.

[0012] As a preferred embodiment: the conveying mechanism includes a conveying drive motor and a conveyor belt, the conveyor belt being installed at the output end of the conveying drive motor, the feeding tray being movably sleeved on the conveyor belt, and the feeding tray being provided with a receiving groove for accommodating battery connecting pieces.

[0013] Compared with the prior art, this utility model has obvious advantages and beneficial effects. Specifically, as can be seen from the above technical solution, by setting a conveying mechanism, a positioning mechanism, a bending mechanism, and a stopping mechanism, the precise conveying, positioning, bending, and stopping of the battery connecting piece are achieved, thereby improving processing accuracy and production efficiency. The conveying mechanism ensures the stable conveying of the battery connecting piece, the positioning mechanism ensures the accurate position of the battery connecting piece, the bending mechanism flexibly bends the battery connecting piece, and the stopping mechanism ensures that the bent battery connecting piece remains stably in place.

[0014] To more clearly illustrate the structural features and effects of this utility model, the following detailed description is provided in conjunction with the accompanying drawings and specific embodiments. Attached Figure Description

[0015] Figure 1 This is a three-dimensional structural diagram of a precision bending device for processing battery connectors according to this utility model;

[0016] Figure 2 This is a three-dimensional structural diagram of the material feeding tray of this utility model;

[0017] Figure 3This is a three-dimensional structural diagram of the positioning mechanism of this utility model;

[0018] Figure 4 This is a three-dimensional structural diagram of the bending mechanism of this utility model;

[0019] Figure 5 This is a three-dimensional structural diagram of the stopping mechanism of this utility model.

[0020] Explanation of reference numerals in the attached diagram:

[0021] In the diagram: 10. Workbench; 20. Conveying mechanism; 21. Conveying drive motor; 22. Conveyor belt; 23. Feeding tray; 231. Receiving trough; 30. Positioning mechanism; 31. Positioning drive cylinder; 32. Positioning block; 40. Bending mechanism; 41. Bending plate; 42. Longitudinal drive assembly; 421. Longitudinal drive motor; 422. Longitudinal lead screw; 423. Longitudinal slide; 43. Rotary drive assembly; 431. Rotary drive motor; 4321. Driving wheel; 4322. Driven wheel; 4323. Transmission belt; 4324. Adjusting wheel; 433. Rotating shaft; 50. Stopping mechanism; 51. Support; 52. Stopping drive cylinder; 53. Stopping block. Detailed Implementation

[0022] This utility model is as follows Figures 1 to 5 As shown, a precision bending device for processing battery connectors includes a worktable 10, a conveying mechanism 20 for conveying battery connectors, a positioning mechanism 30 for positioning the connectors on the conveying mechanism 20, a bending mechanism 40 for bending the battery connectors, and a stopping mechanism 50 for stopping the bent battery connectors.

[0023] The conveying mechanism 20 is disposed on the workbench 10. The positioning mechanism 30 and the bending mechanism 40 are both disposed on the side of the conveying mechanism 20. The stopping mechanism 50 is located at the end of the conveying mechanism 20. The conveying mechanism 20 has a feeding tray 23 for placing battery connecting pieces. The bending mechanism 40 has a bending plate 41, which is movable and abuts against the battery connecting pieces on the feeding tray 23.

[0024] The battery connector is placed in the feeding tray 23, with the part of the battery connector to be bent extending to the outside of the feeding tray 23. The feeding tray 23 of the conveying mechanism 20 moves. When the feeding tray 23 moves to the designated position, the positioning mechanism 30 positions the feeding tray 23. The bending plate 41 on the bending mechanism 40 moves to the position of the feeding tray 23 and rotates to bend the battery connector. After bending, the conveying mechanism 20 continues to drive the feeding tray 23 to move. When the feeding tray 23 moves to the end of the conveying mechanism 20, the stopping mechanism 50 stops the feeding tray 23.

[0025] By setting up a conveying mechanism 20, a positioning mechanism 30, a bending mechanism 40, and a stopping mechanism 50, the battery connecting piece is accurately conveyed, positioned, bent, and stopped, thereby improving processing accuracy and production efficiency. The conveying mechanism 20 ensures the stable conveying of the battery connecting piece, the positioning mechanism 30 ensures the accurate position of the battery connecting piece, the bending mechanism 40 flexibly bends the battery connecting piece, and the stopping mechanism 50 ensures that the bent battery connecting piece remains stably in place.

[0026] The conveying mechanism 20 includes a conveying drive motor 21 and a conveyor belt 22. The conveyor belt 22 is installed at the output end of the conveying drive motor 21. The feeding tray 23 is movably sleeved on the conveyor belt 22. The feeding tray 23 is provided with a receiving groove 231 for accommodating battery connecting pieces.

[0027] The drive motor 21 provides power to the conveyor belt 22, which can continuously and stably drive the feeding tray 23 to move, realize the automated conveying of battery connecting pieces, and improve production efficiency. The receiving slot 231 on the feeding tray 23 can accurately place the battery connecting pieces, prevent them from shifting or shaking during the conveying process, and ensure the accuracy of subsequent positioning and bending processes.

[0028] The positioning mechanism 30 includes a positioning drive cylinder 31 and a positioning block 32. The positioning drive cylinder 31 is longitudinally mounted on the conveying mechanism 20, and the positioning block 32 is mounted on the output end of the positioning drive cylinder 31. The positioning block 32 is movable and abuts against the feeding tray 23. The positioning drive cylinder 31 drives the positioning block 32 to abut against the feeding tray 23, which can accurately position the feeding tray 23 in a designated position, ensuring that the battery connecting piece is in an accurate processing position and improving bending accuracy. By controlling the extension and retraction of the positioning drive cylinder 31, the movement of the positioning block 32 can be easily realized, and the positioning and depositioning operations can be completed quickly to adapt to different production rhythms.

[0029] The bending mechanism 40 also includes a longitudinal drive assembly 42 and a rotary drive assembly 43. The longitudinal drive assembly 42 is mounted on the worktable 10, and the rotary drive assembly 43 is mounted at the output end of the longitudinal drive assembly 42. The bending plate 41 is mounted at the output end of the rotary drive assembly 43. The longitudinal drive assembly 42 can move the rotary drive assembly 43 and the bending plate 41 in the longitudinal direction to adjust the relative position of the bending plate 41 and the battery connecting piece. The rotary drive assembly 43 can drive the bending plate 41 to rotate, thereby bending the battery connecting piece. By controlling the movement of the longitudinal drive assembly 42 and the rotary drive assembly 43 respectively, the position and angle of the bending plate 41 can be precisely controlled to achieve precise bending of the battery connecting piece.

[0030] The rotary drive assembly 43 includes a rotary drive motor 431, a belt drive device, and a rotary shaft 433. The rotary drive motor 431 is mounted at the output end of the longitudinal drive assembly 42, and the rotary shaft 433 is mounted at the output end of the rotary drive motor 431 via the belt drive device. One end of the bending plate 41 is fastened to the rotary shaft 433. The belt drive device has the functions of buffering and shock absorption, and can smoothly transmit the power of the rotary drive motor 431 to the rotary shaft 433, ensuring the stable rotational movement of the bending plate 41 and reducing the impact of vibration on bending accuracy. The belt drive device has a relatively simple structure and occupies little space, making the overall structure of the rotary drive assembly 43 more compact, which is beneficial to the layout and installation of the equipment.

[0031] The belt drive device includes a drive pulley 4321, a driven pulley 4322, a drive belt 4323, and an adjusting pulley 4324. The drive pulley 4321 is mounted on the output end of the rotary drive motor 431. The drive belt 4323 is sleeved on the drive pulley 4321 and the driven pulley 4322. The adjusting pulley 4324 is rotatably in contact with the drive belt 4323. The adjusting pulley 4324 can adjust the tension of the drive belt 4323 to ensure that the drive belt 4323 maintains a suitable tension during long-term use, prevents slippage, and ensures the stability and reliability of power transmission.

[0032] The longitudinal drive assembly 42 includes a longitudinal drive motor 421, a longitudinal lead screw 422, and a longitudinal slide 423. The longitudinal drive motor 421 is mounted on the worktable 10, the longitudinal lead screw 422 is mounted on the output end of the longitudinal drive motor 421, and the longitudinal slide 423 is rotatably engaged with the longitudinal lead screw 422. The rotary drive assembly 43 is mounted on the longitudinal slide 423. The longitudinal drive motor 421 drives the longitudinal lead screw 422 to rotate, converting the rotational motion into linear motion of the longitudinal slide 423. This allows for precise control of the displacement of the longitudinal slide 423, thereby achieving accurate positioning of the bending plate 41 in the longitudinal direction. The engagement of the longitudinal lead screw 422 and the longitudinal slide 423 can withstand a large load, ensuring the stability and reliability of the rotary drive assembly 43 and the bending plate 41 during longitudinal movement.

[0033] The stop mechanism 50 includes a support 51, a stop drive cylinder 52, and a stop block 53. The stop drive cylinder 52 is vertically mounted on the support 51, and the stop block 53 is mounted on the output end of the stop drive cylinder 52. When the stop block 53 descends, it blocks the front end of the discharge tray 23. The stop drive cylinder 52 drives the stop block 53 to descend, which can timely and accurately block the discharge tray 23, so that the bent battery connecting piece stops in the designated position, which is convenient for subsequent collection or further processing. The stop mechanism 50 can cooperate with the control system of the whole equipment to realize automated stop operation, improve production efficiency and production continuity.

[0034] The conveying mechanism 20 drives the feeding tray 23 to move via the conveying drive motor 21 and the conveyor belt 22, achieving precise conveying of the battery connecting pieces. The positioning mechanism 30 drives the positioning block 32 to abut against the feeding tray 23 via the positioning drive cylinder 31, accurately positioning the battery connecting pieces and improving processing accuracy. The longitudinal drive component 42 and the rotary drive component 43 of the bending mechanism 40 enable the bending plate 41 to move longitudinally and rotate, allowing for flexible bending of the battery connecting pieces. The stop mechanism 50 drives the stop block 53 to descend via the stop drive cylinder 52, stopping the feeding tray 23 and ensuring that the bent battery connecting pieces remain stably in place, facilitating subsequent operations.

[0035] The operating method and principle of this precision bending equipment for processing battery connectors are as follows:

[0036] The battery connector is placed in the feeding tray, with the part of the battery connector to be bent extending to the outside of the feeding tray. The feeding tray of the conveying mechanism moves. When the feeding tray moves to the designated position, the positioning mechanism positions the feeding tray. The bending plate on the bending mechanism moves to the position of the feeding tray and rotates to bend the battery connector. After bending, the conveying mechanism continues to drive the feeding tray to move. When the feeding tray moves to the end of the conveying mechanism, the stopping mechanism stops the feeding tray.

[0037] The key design feature of this invention is that by setting up a conveying mechanism, a positioning mechanism, a bending mechanism, and a stopping mechanism, it achieves precise conveying, positioning, bending, and stopping of the battery connecting piece, thereby improving processing accuracy and production efficiency. The conveying mechanism ensures stable conveying of the battery connecting piece, the positioning mechanism ensures the accurate position of the battery connecting piece, the bending mechanism flexibly bends the battery connecting piece, and the stopping mechanism ensures that the bent battery connecting piece remains stably in place.

[0038] The above description is merely a preferred embodiment of the present utility model and does not constitute any limitation on the technical scope of the present utility model. Therefore, any minor modifications, equivalent changes, and alterations made to the above embodiments based on the technical essence of the present utility model shall still fall within the scope of the technical solution of the present utility model.

Claims

1. A precision bending apparatus for battery tab processing, characterized by: The device includes a workbench, a conveying mechanism for conveying battery connector pieces, a positioning mechanism for positioning the connector pieces on the conveying mechanism, a bending mechanism for bending the battery connector pieces, and a stopping mechanism for stopping the bent battery connector pieces. The conveying mechanism is disposed on the workbench, the positioning mechanism and the bending mechanism are disposed on the side of the conveying mechanism, and the stopping mechanism is located at the end of the conveying mechanism. The conveying mechanism has a feeding tray for placing battery connector pieces, and the bending mechanism has a bending plate that is movably abuts against the battery connector pieces on the feeding tray.

2. The precision bending equipment for processing battery connectors according to claim 1, characterized in that: The bending mechanism further includes a longitudinal drive assembly and a rotary drive assembly. The longitudinal drive assembly is mounted on the worktable, the rotary drive assembly is mounted at the output end of the longitudinal drive assembly, and the bending plate is mounted at the output end of the rotary drive assembly.

3. The precision bending equipment for processing battery connectors according to claim 2, characterized in that: The rotary drive assembly includes a rotary drive motor, a belt drive device, and a rotary shaft. The rotary drive motor is mounted at the output end of the longitudinal drive assembly, and the rotary shaft is mounted at the output end of the rotary drive motor via the belt drive device. One end of the bending plate is fastened to the rotary shaft.

4. The precision bending equipment for processing battery connectors according to claim 3, characterized in that: The belt drive device includes a driving pulley, a driven pulley, a transmission belt, and an adjusting pulley. The driving pulley is installed at the output end of the rotary drive motor, the transmission belt is sleeved on the driving pulley and the driven pulley, and the adjusting pulley is rotatably abutted against the transmission belt.

5. The precision bending equipment for processing battery connectors according to claim 2, characterized in that: The longitudinal drive assembly includes a longitudinal drive motor, a longitudinal lead screw, and a longitudinal slide. The longitudinal drive motor is mounted on the worktable, the longitudinal lead screw is mounted on the output end of the longitudinal drive motor, the longitudinal slide is rotatably engaged with the longitudinal lead screw, and the rotary drive assembly is mounted on the longitudinal slide.

6. The precision bending equipment for processing battery connectors according to claim 1, characterized in that: The positioning mechanism includes a positioning drive cylinder and a positioning block. The positioning drive cylinder is longitudinally mounted on the conveying mechanism, and the positioning block is mounted on the output end of the positioning drive cylinder. The positioning block is movable and abuts against the feeding tray.

7. The precision bending equipment for processing battery connectors according to claim 1, characterized in that: The stopping mechanism includes a support, a stopping drive cylinder, and a stopping block. The stopping drive cylinder is vertically mounted on the support, and the stopping block is mounted on the output end of the stopping drive cylinder. When the stopping block descends, it stops at the front end of the material feeding tray.

8. The precision bending equipment for processing battery connectors according to claim 1, characterized in that: The conveying mechanism includes a conveyor drive motor and a conveyor belt. The conveyor belt is installed at the output end of the conveyor drive motor. The feeding tray is movably sleeved on the conveyor belt. The feeding tray is provided with a receiving groove for accommodating battery connecting pieces.