CN219737719U - Battery integrated debugging device - Google Patents

Abstract

The utility model relates to the technical field of battery debugging, in particular to a battery integrated debugging device which comprises a frame, a bracket A, a bracket B, a bidirectional module, a bracket C and a hydraulic cylinder. A transmission component is arranged in the frame. The bracket A is arranged on the frame, and the visual camera is arranged at the bottom of the transverse plate of the bracket A. The bracket B is arranged on the frame, the bottom of the transverse end of the bracket B is provided with a movable plate rotationally connected with the bracket B, and the bracket B is provided with a motor B for driving the movable plate to rotate. The bidirectional module is arranged at the bottom of the movable plate and is synchronously connected with the two clamping plates in a driving way. The support C is arranged on the frame, the tester is arranged on the support C, two unidirectional modules are symmetrically arranged at the bottom of the transverse end of the support C, and the two unidirectional modules on the two sides are respectively in driving connection with the corresponding side sliding seat. The pneumatic cylinder sets up in the slide bottom, and the mounting panel is connected in the pneumatic cylinder drive, and the bottom elastic sliding of mounting panel sets up the mount pad, and the bottom of mount pad sets up the probe. The utility model has high debugging efficiency and does not need excessive manual intervention.

Description

Battery integrated debugging device

Technical Field

The utility model relates to the technical field of battery debugging, in particular to a battery integrated debugging device.

Background

Battery tuning can understand the characteristics of the battery: the important parameters of the capacity, the internal resistance, the voltage characteristic, the multiplying power characteristic, the temperature characteristic, the cycle life, the energy density and the like of the battery are known through testing, so that the parameters are needed to demonstrate whether the battery to be tested achieves the original design target or not, and better management and control are needed to be realized in the process of using the battery through the parameters.

The Chinese patent with the publication number of CN218382948U discloses an integrated debugging device for batteries, which relates to the technical field of battery debugging and comprises a test board and a quick clamp assembly, wherein the middle end of the bottom of the test board is fixedly provided with the quick clamp assembly for quick clamping and positioning of the batteries, the quick clamp assembly comprises a mounting plate, bolts, coamings, smooth bottom brackets, locking pins, turning plates, buckles and threaded top brackets, bolts are arranged on two sides of the mounting plate, the mounting plate is fixed with the test board through the bolts, and coamings are fixedly arranged on two sides of the middle of the mounting plate. The utility model provides a battery integrated debugging device, which does not need to rotate a screw rod handle by means of high frequency until a workpiece is clamped as in the prior device, and the battery integrated debugging device only needs to rapidly move the screw rod to press a pressing plate close to a battery body, and then covers a turning plate to rapidly clamp the workpiece under the screw engagement effect of the screw rod and a screw thread jacking, so that the clamping mode is simple, convenient and rapid, and the positioning and clamping of the battery body can be rapidly realized.

However, the device still has the defects that: the device needs to place and take off the battery one by one at in-service use's in-process to the centre gripping location of battery in the debugging in-process needs manual operation, and is very inefficiency to the batch debugging of battery on the production line.

Disclosure of Invention

The utility model aims to solve the problems in the background technology and provides a battery integrated debugging device.

The technical scheme of the utility model is as follows: the battery integrated debugging device comprises a frame, a support A, a support B, a bidirectional module, a support C and a hydraulic cylinder.

An upward opening guide groove is formed in the frame, and a conveying assembly is arranged in the guide groove. The bracket A is arranged on the frame, and the visual camera is arranged at the bottom of the transverse plate of the bracket A. The bracket B is arranged on the frame, the bottom of the transverse end of the bracket B is provided with a movable plate rotationally connected with the bracket B, and the bracket B is provided with a motor B for driving the movable plate to rotate. The bidirectional module is arranged at the bottom of the movable plate and is synchronously connected with the two clamping plates in a driving way.

The support C is arranged on the frame, the support B is arranged between the support A and the support C, the tester is arranged on the support C, two unidirectional modules are symmetrically arranged at the bottom of the transverse end of the support C, two sliding seats are symmetrically and slidingly arranged at the bottom of the transverse end of the support C, and the unidirectional modules at the two sides are respectively in driving connection with the corresponding side sliding seats.

The pneumatic cylinder sets up in the bottom of slide, and the mounting panel is connected in the pneumatic cylinder drive, and the bottom elastic sliding of mounting panel sets up the mount pad, and the bottom of mount pad sets up the probe, both sides probe all with tester electric connection.

Preferably, the conveyor assembly comprises a driving roller, a conveyor belt and a motor a. The driving rollers are symmetrically arranged in the guide groove and are rotationally connected with the frame, the driving rollers at two sides are in transmission connection through the conveying belt, and the motor A is in driving connection with the driving rollers.

Preferably, the guide groove is internally provided with a supporting plate, the supporting plate is positioned between the driving rollers at two sides, and the upper surface of the supporting plate is attached to the lower surface of the upper transverse end of the conveyor belt and is in sliding connection with the lower surface of the upper transverse end of the conveyor belt.

Preferably, two storage grooves are symmetrically formed in the frame and are communicated with the guide groove, the clamping plates on two sides are respectively located in the corresponding storage grooves on the sides and are in sliding connection with the corresponding storage grooves, the shovel plates are arranged on one sides, close to each other, of the clamping plates, and the bottoms of the shovel plates are in sliding connection with the upper surface of the conveying belt.

Preferably, two opposite infrared gratings are symmetrically arranged on the inner wall of the guide groove, and the infrared gratings are positioned below the inner side of the opening of the bracket C.

Preferably, two telescopic rods are symmetrically arranged at the bottom of the sliding seat, and movable sleeves of the telescopic rods at two sides are respectively connected with corresponding ends of the mounting plate.

Preferably, the bottom of frame sets up the supporting legs, and the bottom of supporting legs sets up the universal wheel, sets up auto-lock subassembly on the universal wheel.

Compared with the prior art, the utility model has the following beneficial technical effects:

the position of the positioning battery is automatically detected by the aid of the infrared grating, so that start and stop of the conveying assembly are controlled, and the automation degree of the whole device is improved; by arranging the visual camera, the direction of the battery electrode on the conveyor belt is detected by the visual camera, so that the battery is prevented from entering a debugging point in a state that the electrode direction is opposite, and meanwhile, the device can also automatically reverse the battery which is prevented from reversing; by arranging the elastic sliding mounting seat at the bottom of the mounting plate, the contact between the probe and the battery electrode is flexible contact, and electrode damage caused by rigid contact of the probe with the electrode is avoided.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present utility model;

FIG. 2 is a diagram of the connection of the components of the frame;

FIG. 3 is a diagram showing the connection structure of the components on the bracket B;

fig. 4 is a connection structure diagram of each component on the bracket C.

Reference numerals: 1. a frame; 101. a guide groove; 102. a storage groove; 2. a driving roller; 3. a conveyor belt; 4. a motor A; 5. a support plate; 6. an infrared grating; 7. a bracket A; 8. a vision camera; 9. a bracket B; 10. a movable plate; 11. a motor B; 12. a bidirectional module; 13. a clamping plate; 14. a shovel plate; 15. a bracket C; 16. a tester; 17. a unidirectional module; 18. a slide; 19. a hydraulic cylinder; 20. a mounting plate; 21. a mounting base; 22. a probe.

Detailed Description

Example 1

As shown in fig. 1-4, the utility model provides a battery integrated debugging device, which comprises a frame 1, a bracket A7, a bracket B9, a bidirectional module 12, a bracket C15 and a hydraulic cylinder 19. The bottom of frame 1 sets up the supporting legs, and the bottom of supporting legs sets up the universal wheel, sets up auto-lock subassembly on the universal wheel. A guide groove 101 with an upward opening is arranged in the frame 1, and a conveying assembly is arranged in the guide groove 101. The conveying assembly comprises a driving roller 2, a conveying belt 3 and a motor A4. The driving rollers 2 are symmetrically arranged in the guide groove 101 and are rotationally connected with the frame 1, the driving rollers 2 on two sides are in transmission connection through the conveyor belt 3, and the motor A4 is in driving connection with the driving rollers 2. The guide groove 101 is internally provided with a supporting plate 5, the supporting plate 5 is positioned between the driving rollers 2 at two sides, and the upper surface of the supporting plate 5 is attached to the lower surface of the upper transverse end of the conveyor belt 3 and is in sliding connection. The bracket A7 is arranged on the frame 1, and the visual camera 8 is arranged at the bottom of the transverse plate of the bracket A7. The bracket B9 is arranged on the frame 1, the bottom of the transverse end of the bracket B9 is provided with a movable plate 10 which is rotationally connected with the bracket B9, and the bracket B9 is provided with a motor B11 which drives the movable plate 10 to rotate. The two-way module 12 is arranged at the bottom of the movable plate 10, and the two-way module 12 is synchronously connected with the two clamping plates 13 in a driving way. The support C15 is arranged on the frame 1, the support B9 is positioned between the support A7 and the support C15, the tester 16 is arranged on the support C15, two unidirectional modules 17 are symmetrically arranged at the bottom of the transverse end of the support C15, two sliding seats 18 are symmetrically and slidingly arranged at the bottom of the transverse end of the support C15, and the unidirectional modules 17 at two sides are respectively connected with the corresponding sliding seats 18 in a driving mode. Two opposite infrared gratings 6 are symmetrically arranged on the inner wall of the guide groove 101, and the infrared gratings 6 are positioned below the inner side of the opening of the bracket C15. Two telescopic rods are symmetrically arranged at the bottom of the sliding seat 18, and movable sleeves of the telescopic rods at the two sides are respectively connected with corresponding ends of the mounting plate 20. The pneumatic cylinder 19 sets up in the bottom of slide 18, and pneumatic cylinder 19 drive connection mounting panel 20, the bottom elasticity slip of mounting panel 20 sets up mount pad 21, and the bottom of mount pad 21 sets up probe 22, both sides probe 22 and tester 16 electric connection.

In this embodiment, the two-side unidirectional modules 17 are started to adjust the corresponding side probes 22 to adapt to the positions of the electrodes of the battery to be detected respectively, the batteries are placed on the conveyor belt 3 one by one, when the batteries pass through the conveyor belt 3 and are transmitted to pass through the lower part of the support A7, the vision camera 8 photographs and obtains the current electrode direction of the batteries, if the electrode direction of the batteries is reverse, when the batteries reach the lower part of the support B9, the two-way modules 12 drive the two-side clamping plates 13 to be close to each other, the two-side clamping plates 13 are used for clamping the batteries, then the motor B11 drives the movable plate 10 and the batteries to turn, the electrodes of the batteries correspond to the probes 22, then the clamping plates 13 are reset, after the batteries continue to be transmitted to the debugging points, the hydraulic cylinder 19 presses the mounting plate 20 to the probes 22 to be in electrical contact with the corresponding side electrodes of the batteries, and the test 16 instrument automatically obtains the relevant data of the batteries. The battery is debugged by using the device, the efficiency of battery debugging can be improved, and the device automatically commutates the battery with reverse placement direction, so that electrode contact is prevented from reversing when the battery is debugged.

Example two

As shown in fig. 3, in the integrated battery debugging device according to the present utility model, compared with the first embodiment, two receiving slots 102 are symmetrically disposed on the frame 1, the receiving slots 102 are communicated with the guiding slots 101, two side clamping plates 13 are respectively disposed in the corresponding side receiving slots 102 and slidably connected therewith, and two sides of the clamping plates 13, which are close to each other, are respectively disposed with a shovel plate 14, and the bottom of the shovel plate 14 is slidably connected with the upper surface of the conveyor belt 3.

In this embodiment, the clamping plates 13 are located in the corresponding side receiving slots 102 in the standby state, when the clamping plates 13 clamp and reverse the battery, the clamping plates 13 on both sides are close to each other, and meanwhile the shoveling plates 14 at the bottoms of the clamping plates 13 on both sides shovel the battery to a certain height in the process of approaching, so as to prevent the battery from being scratched due to friction between the bottom of the battery and the conveyor belt 3 in the reversing process.

The embodiments of the present utility model have been described in detail with reference to the drawings, but the present utility model is not limited thereto, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit of the present utility model.

Claims (7)

1. The battery integrated debugging device is characterized by comprising a frame (1), a bracket A (7), a bracket B (9), a bidirectional module (12), a bracket C (15) and a hydraulic cylinder (19);

a guide groove (101) with an upward opening is arranged in the frame (1), and a conveying assembly is arranged in the guide groove (101); the bracket A (7) is arranged on the frame (1), and a visual camera (8) is arranged at the bottom of a transverse plate of the bracket A (7); the bracket B (9) is arranged on the frame (1), the bottom of the transverse end of the bracket B (9) is provided with a movable plate (10) rotationally connected with the bracket B, and the bracket B (9) is provided with a motor B (11) for driving the movable plate (10) to rotate; the bidirectional module (12) is arranged at the bottom of the movable plate (10), and the bidirectional module (12) is synchronously connected with the two clamping plates (13) in a driving way;

the support C (15) is arranged on the frame (1), the support B (9) is positioned between the support A (7) and the support C (15), the tester (16) is arranged on the support C (15), two unidirectional modules (17) are symmetrically arranged at the bottom of the transverse end of the support C (15), two sliding seats (18) are symmetrically and slidingly arranged at the bottom of the transverse end of the support C (15), and the two unidirectional modules (17) at two sides are respectively connected with the corresponding side sliding seats (18) in a driving mode;

the hydraulic cylinder (19) is arranged at the bottom of the sliding seat (18), the hydraulic cylinder (19) is in driving connection with the mounting plate (20), the bottom of the mounting plate (20) is elastically and slidably provided with the mounting seat (21), the bottom of the mounting seat (21) is provided with the probes (22), and the probes (22) at two sides are electrically connected with the tester (16).

2. The battery integrated debugging device according to claim 1, wherein the conveying assembly comprises a driving roller (2), a conveyor belt (3) and a motor a (4); the driving rollers (2) are symmetrically arranged in the guide groove (101) and are rotationally connected with the frame (1), the driving rollers (2) at two sides are in transmission connection through the conveyor belt (3), and the motor A (4) is in driving connection with the driving rollers (2).

3. The battery integrated debugging device according to claim 2, wherein a supporting plate (5) is arranged in the guide groove (101), the supporting plate (5) is positioned between the driving rollers (2) at two sides, and the upper surface of the supporting plate (5) is attached to the lower surface of the upper transverse end of the conveyor belt (3) and is in sliding connection.

4. The battery integrated debugging device according to claim 2, wherein two accommodating grooves (102) are symmetrically formed in the frame (1), the accommodating grooves (102) are communicated with the guide grooves (101), two side clamping plates (13) are respectively located in the corresponding side accommodating grooves (102) and are in sliding connection with the corresponding side accommodating grooves, shovel plates (14) are arranged on the sides, close to each other, of the clamping plates (13), and the bottoms of the shovel plates (14) are in sliding connection with the upper surface of the conveying belt (3).

5. The battery integrated debugging device according to claim 1, wherein two opposite infrared gratings (6) are symmetrically arranged on the inner wall of the guide groove (101), and the infrared gratings (6) are positioned below the inner side of the opening of the bracket C (15).

6. The battery integrated debugging device according to claim 1, wherein two telescopic rods are symmetrically arranged at the bottom of the sliding seat (18), and movable sleeves of the telescopic rods at the two sides are respectively connected with corresponding ends of the mounting plate (20).

7. The battery integrated debugging device according to claim 1, wherein the bottom of the frame (1) is provided with supporting feet, the bottoms of the supporting feet are provided with universal wheels, and the universal wheels are provided with self-locking components.