CN219224608U - Bluetooth battery divides strip machine detection device - Google Patents

Abstract

The utility model discloses a Bluetooth battery slitting machine detection device, which comprises a battery bearing assembly, an acquisition assembly and a movement detection assembly, wherein the battery bearing assembly comprises a bearing seat and a plurality of coaxially distributed rotating shafts arranged on the bearing seat, and battery pieces to be detected are placed between adjacent rotating shafts; the acquisition assembly is positioned above the battery bearing assembly and is used for shooting the surface of a battery piece which is driven to rotate by the rotating shaft on the battery bearing assembly; the collection assembly is installed on the removal detection assembly, the removal detection assembly is used for driving the axis direction removal of collection assembly along the rotation axis. According to the utility model, the battery pieces are rotationally arranged between the adjacent rotating shafts of the battery bearing assemblies, all the battery pieces are driven to rotate by the same motor, and the collection assembly above the battery bearing assemblies is used for batch collection and detection, so that various fine flaws on the surfaces of the battery pieces can be accurately highlighted and collected.

Description

Bluetooth battery divides strip machine detection device

Technical Field

The utility model relates to the technical field of optical detection equipment, in particular to a detection device of a Bluetooth battery slitting machine.

Background

When bluetooth battery production, because battery production board running speed is fast, the battery is little at surface flaw, and the manual work detects not very realistic, and conventional detection mode is difficult to satisfy the production demand again.

In order to improve the accuracy of identifying flaws on the surface of an object and realize the batch detection requirement of Bluetooth batteries, the conventional detection mode is that a lens continuously moves to change positions during detection so as to shoot and collect flaws on the surface of the battery, and the battery is low in efficiency and inconvenient to operate, and is especially not suitable for batteries with columnar specular reflection.

In detection, the imaging effect of flaws is not obvious in many cases because the specular reflection object light source irradiates and then reflects light easily.

Disclosure of Invention

The utility model aims to provide a Bluetooth battery slitter detection device aiming at the defects and shortcomings of the prior art.

In order to achieve the above object, the present utility model provides the following solutions:

the utility model provides a Bluetooth battery slitting machine detection device which comprises a battery bearing assembly, an acquisition assembly and a movement detection assembly, wherein the battery bearing assembly comprises a bearing seat and a plurality of coaxially distributed rotating shafts arranged on the bearing seat, and battery pieces to be detected are placed between adjacent rotating shafts; the acquisition assembly is positioned above the battery bearing assembly and is used for shooting the surface of a battery piece which is driven to rotate by the rotating shaft on the battery bearing assembly; the collection assembly is installed on the removal detection assembly, the removal detection assembly is used for driving the axis direction removal of collection assembly along the rotation axis.

As a further scheme of the utility model, a plurality of rotating shafts which are coaxially distributed are rotatably arranged on the bearing seat, a partition plate is arranged on the bearing seat, the partition plate is used for dividing the same rotating shaft into at least one row of detection areas, and battery pieces are placed between adjacent rotating shafts of each row of detection areas.

As a further scheme of the utility model, the rotating shaft is sleeved with the contact ring, and the contact ring is made of rubber and is used for abutting against the battery piece.

As a further scheme of the utility model, the plurality of coaxially distributed rotating shafts are connected through the synchronous wheels and the belt and are connected with the belt pulley of the motor through the belt, and the plurality of coaxially distributed rotating shafts can be driven to synchronously rotate under the driving of the motor, so that the battery piece rotates.

As a further scheme of the utility model, the magnet is also arranged in the bearing seat below the adjacent rotating shafts and is used for adsorbing the battery pieces arranged between the adjacent rotating shafts, so that the jumping of the battery pieces during rotation is reduced.

As a further scheme of the utility model, the acquisition component comprises a light source, a camera and an induction sensor, wherein the light source is distributed outside a lens of the camera, the induction sensor is further arranged on one side of the lens of the camera, and the acquisition module is composed of the same group of light source, the camera and the induction sensor.

As a further scheme of the utility model, the collecting assembly further comprises a supporting arm, a collecting guide rod, a enclasping block and a guide rod seat, wherein the guide rod seat is rotatably provided with a collecting guide rod, the collecting guide rod is connected with a plurality of supporting arms through the enclasping block, and a group of light sources, cameras and induction sensors are arranged between every two adjacent supporting arms.

As a further scheme of the utility model, the collecting guide rod of the collecting assembly is arranged above the rotating shaft and perpendicular to the rotating shaft, a plurality of supporting arms connected with the collecting guide rod are all arranged right above the rotating shaft, and the collecting module is arranged right above the space between the adjacent rotating shafts.

As a further scheme of the utility model, the number of the supporting arms is equal to that of the rotating shafts, and an acquisition module is arranged above each adjacent rotating shaft.

As a further scheme of the utility model, the movement detection assembly comprises a guide rail, a screw rod and a driver, wherein the guide rail is fixed on one side of the bearing seat and is arranged in parallel with the rotating shaft, the screw rod is arranged in the guide rail, one end of the screw rod is connected with the rotating shaft of the driver, and the guide rod seat is arranged on the guide rail in a sliding manner and is meshed with the screw rod, so that the position of the acquisition assembly is slidably adjusted along the guide rail under the drive of the screw rod.

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

according to the Bluetooth battery slitting machine detection device, the battery pieces are rotatably arranged between the adjacent rotating shafts of the battery bearing assemblies, all the battery pieces are driven to rotate by the same motor, the collection assemblies above the battery bearing assemblies are used for light supplementing and shooting, and the batteries are detected in batches, so that various fine flaws on the surfaces of the battery pieces can be accurately highlighted and collected.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions of the prior art, the drawings that are needed in the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a bluetooth battery slitter detection device when carrying a battery piece.

Fig. 2 is a schematic structural diagram of a battery carrying assembly in a bluetooth battery slitter detection device.

Fig. 3 is a schematic structural diagram of an acquisition assembly in a bluetooth battery slitter detection device.

Fig. 4 is a schematic structural diagram of a mobile detection assembly in a bluetooth battery slitter detection device.

The device comprises a 1-movement detection assembly, a 11-guide rail, a 12-driver, a 13-screw, a 2-battery bearing assembly, a 21-bearing seat, a 22-separation plate, a 23-motor, a 24-synchronous wheel, a 25-rotating shaft, a 26-contact ring, a 27-encoder, a 28-magnet, a 3-acquisition assembly, a 31-guide rod seat, a 32-camera, a 33-enclasping block, a 34-support arm, a 35-acquisition guide rod and a 4-battery piece.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model aims to provide a Bluetooth battery slitter detection device aiming at the defects and shortcomings of the prior art.

In order that the above-recited objects, features and advantages of the present utility model will become more readily apparent, a more particular description of the utility model will be rendered by reference to the appended drawings and appended detailed description.

As shown in fig. 1-4, the utility model provides a detection device of a bluetooth battery slitter, which comprises a battery bearing assembly 2, a collection assembly 3 and a movement detection assembly 1, wherein the battery bearing assembly 2 comprises a bearing seat 21 and a plurality of coaxially distributed rotating shafts 25 arranged on the bearing seat 21, and battery pieces 4 to be detected are placed between adjacent rotating shafts 25; the collecting assembly 3 is positioned above the battery bearing assembly 2 and is used for photographing the surface of the battery piece 4 which is driven to rotate by the rotating shaft 25 on the battery bearing assembly 2; the collection assembly 3 is mounted on the movement detection assembly 1, and the movement detection assembly 1 is used for driving the collection assembly 3 to move along the axis direction of the rotating shaft 25.

According to the Bluetooth battery slitting machine detection device provided by the utility model, the battery parts are rotatably arranged between the adjacent rotating shafts of the battery bearing assemblies, all the battery parts are driven to rotate by the same motor, the collection assemblies above the battery bearing assemblies are used for light supplementing and shooting, the batteries can be detected in batches, and various fine flaws on the surfaces of the battery parts can be accurately highlighted and collected.

In this embodiment, a plurality of rotation shafts 25 coaxially distributed are rotatably disposed on the bearing seat 21, a partition plate 22 is disposed on the bearing seat 21, the partition plate 22 is used for dividing the same rotation shaft 25 into at least one row of detection regions, and a battery piece 4 is placed between adjacent rotation shafts 25 of each row of detection regions.

For example, the same rotation axis 25 may be divided into 3 rows of detection areas, each row of detection areas placing 3 battery pieces 4. The word detects a row of three battery pieces 4.

In order to facilitate stable placement and stability during rotation of the battery piece 4, in this embodiment, the rotating shaft 25 is sleeved with a contact ring 26, and the contact ring 26 is made of rubber and is used for abutting against the battery piece 4.

In order to prevent the battery member 4 from jumping, in the present embodiment, a magnet 28 is further installed in the bearing seat 21 below the adjacent rotating shafts 25, and the magnet 28 is used for adsorbing the battery member 4 placed between the adjacent rotating shafts 25, so as to reduce the jumping of the battery member 4 during rotation.

In the driving mode, preferably, the plurality of coaxially distributed rotating shafts 25 are connected through a synchronizing wheel 24 and a belt, and are connected with a belt pulley of the motor 23 through the belt, and the plurality of coaxially distributed rotating shafts 25 can be driven to synchronously rotate by the motor 23, so that the battery piece 4 rotates.

In this embodiment, the collection assembly 3 includes a light source, a camera 32 and an induction sensor, the light source is distributed on the outer side of the lens of the camera 32, the induction sensor is further disposed on one side of the lens of the camera 32, and the same group of light source, camera 32 and induction sensor form a collection module.

The collecting assembly 3 further comprises a supporting arm 34, a collecting guide rod 35, a holding block 33 and a guide rod seat 31, the collecting guide rod 35 is rotatably arranged on the guide rod seat 31, a plurality of supporting arms 34 are connected to the collecting guide rod 35 through the holding block 33, and a group of light sources, cameras 32 and induction sensors are arranged between every two adjacent supporting arms 34.

The collection guide rod 35 of the collection assembly 3 is located above the rotating shafts 25 and perpendicular to the rotating shafts 25, a plurality of support arms 34 connected with the collection guide rod 35 are located right above the rotating shafts 25, and the collection module is located right above between adjacent rotating shafts 25. The number of the supporting arms 34 is equal to the number of the rotating shafts 25, and an acquisition module is arranged above each adjacent rotating shaft 25.

In this embodiment, one end of the collecting guide rod 35 is connected to a rotating motor, and the rotating motor is mounted on the guide rod seat 31 and is used for driving the collecting guide rod 35 to rotate, so as to adjust the collecting detection angle of the collecting module.

In this embodiment, the movement detection assembly 1 includes a guide rail 11, a screw rod 13, and a driver 12, where the guide rail 11 is fixed on one side of the bearing seat 21 and is parallel to the rotation shaft 25, the screw rod 13 is disposed in the guide rail 11, one end of the screw rod 13 is connected with the rotation shaft of the driver 12, and the guide rod seat 31 is slidably disposed on the guide rail 11 and is engaged with the screw rod 13, and is used to slidably adjust the position of the collection assembly 3 along the guide rail 11 under the driving of the screw rod 13.

When detecting, the driver 12 of the mobile detection assembly 1 starts working, the guide rod seat 31 is driven by the screw rod 13 to brake along the guide rail 11, so that the acquisition module of the acquisition assembly 3 reaches different detection areas above the battery bearing assembly 2, and when detecting, the acquisition module is positioned above the adjacent rotation shafts 25 due to the fact that the battery pieces 4 are arranged between the adjacent rotation shafts 25, therefore, the belt pulley of the motor 23 is connected with the motor 23, a plurality of coaxial rotation shafts 25 distributed can be driven to synchronously rotate under the driving of the motor 23, and when the battery pieces 4 rotate, the acquisition module can detect the battery pieces 4 below in batches, so that the efficiency is high and the detection effect is good.

The principles and embodiments of the present utility model have been described in detail with reference to specific examples, which are provided to facilitate understanding of the method and core ideas of the present utility model; also, it is within the scope of the present utility model to be modified by those of ordinary skill in the art in light of the present teachings. In view of the foregoing, this description should not be construed as limiting the utility model.

Claims (10)

1. The Bluetooth battery slitting machine detection device is characterized by comprising a battery bearing assembly (2), an acquisition assembly (3) and a movement detection assembly (1), wherein the battery bearing assembly (2) comprises a bearing seat (21) and a plurality of rotating shafts (25) which are arranged on the bearing seat (21) and are distributed in the same axial direction, and battery pieces (4) to be detected are placed between the adjacent rotating shafts (25); the acquisition assembly (3) is positioned above the battery bearing assembly (2) and is used for shooting the surface of a battery piece (4) which is driven to rotate by the rotating shaft (25) on the battery bearing assembly (2); the collection assembly (3) is arranged on the movement detection assembly (1), and the movement detection assembly (1) is used for driving the collection assembly (3) to move along the axis direction of the rotating shaft (25).

2. The bluetooth battery slitter detection device according to claim 1, characterized in that a plurality of rotation shafts (25) which are coaxially distributed are rotatably arranged on the bearing seat (21), a separation plate (22) is arranged on the bearing seat (21), the separation plate (22) is used for separating the same rotation shaft (25) into at least one row of detection areas, and battery pieces (4) are placed between adjacent rotation shafts (25) of each row of detection areas.

3. The bluetooth battery slitter detection device according to claim 2, wherein a contact ring (26) is sleeved on the rotating shaft (25), and the contact ring (26) is made of rubber.

4. A bluetooth battery slitter detection device according to claim 3, characterized in that a number of co-axially distributed rotation shafts (25) are connected by means of synchronizing wheels (24) and belts and by means of belts with pulleys of the motor (23).

5. The bluetooth battery slitter detection device according to claim 4, characterized in that a magnet (28) is further mounted in the bearing seat (21) below the adjacent rotating shafts (25), the magnet (28) being used for adsorbing battery pieces (4) placed between the adjacent rotating shafts (25).

6. The bluetooth battery slitter detection device according to claim 1, wherein the collection assembly (3) comprises a light source, a camera (32) and an induction sensor, wherein the light source is distributed on the outer side of a lens of the camera (32), the induction sensor is further arranged on one side of the lens of the camera (32), and the collection module is composed of the same group of light source, the camera (32) and the induction sensor.

7. The bluetooth battery slitter detection device according to claim 6, wherein the collection assembly (3) further comprises a support arm (34), a collection guide rod (35), a clasping block (33) and a guide rod seat (31), the guide rod seat (31) is rotatably provided with the collection guide rod (35), the collection guide rod (35) is connected with a plurality of support arms (34) through the clasping block (33), and a group of light sources, cameras (32) and induction sensors are arranged between every two adjacent support arms (34).

8. The bluetooth battery slitter detection device according to claim 7, wherein a collection guide rod (35) of the collection assembly (3) is located above the rotating shafts (25) and perpendicular to the rotating shafts (25), a plurality of support arms (34) connected with the collection guide rod (35) are located right above the rotating shafts (25), and a collection module is located right above between adjacent rotating shafts (25).

9. The bluetooth battery slitter detection device according to claim 8, wherein the number of the supporting arms (34) is equal to the number of the rotating shafts (25), and an acquisition module is arranged above each adjacent rotating shaft (25).

10. The bluetooth battery slitter detection device according to claim 1, wherein the movement detection assembly (1) comprises a guide rail (11), a screw rod (13) and a driver (12), the guide rail (11) is fixed on one side of a bearing seat (21) and is arranged in parallel with the rotating shaft (25), the screw rod (13) is arranged in the guide rail (11), one end of the screw rod (13) is connected with the rotating shaft of the driver (12), and the guide rod seat (31) is arranged on the guide rail (11) in a sliding manner and is meshed with the screw rod (13).

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