CN220182050U

CN220182050U - Synchronous transfer device for cylindrical battery cells

Info

Publication number: CN220182050U
Application number: CN202321447787.7U
Authority: CN
Inventors: 姜志军; 肖振中; 李建民; 杨涛锋; 祥积业; 宋善鹏; 陈云
Original assignee: Suzhou Hanhe Intelligent Equipment Co ltd
Current assignee: Suzhou Hanhe Intelligent Equipment Co ltd
Priority date: 2023-06-08
Filing date: 2023-06-08
Publication date: 2023-12-15
Anticipated expiration: 2033-06-08

Abstract

The utility model relates to a synchronous transfer device for cylindrical battery cells, which relates to the technical field of conveying devices and comprises a conveying line, wherein a plurality of pushing seats are arranged below the conveying line and are uniformly distributed along the length direction of the conveying line at intervals; a base is arranged at one end of the pushing seat, which is far away from the material conveying line, and is provided with a track groove which is annular; one end of each pushing seat, which is far away from the material conveying line, is commonly connected with a transmission block, and the transmission blocks are arranged on the base in a sliding manner; the base is provided with a driving component for driving the transmission block to move along the track groove. The utility model has the advantages of high transfer speed and stable rhythm.

Description

Synchronous transfer device for cylindrical battery cells

Technical Field

The utility model relates to the technical field of conveying devices, in particular to a synchronous transfer device for cylindrical battery cells.

Background

In the assembly stage of the battery cell, in order to ensure that no error occurs in the assembly process, the battery cell moves by a fixed distance every time, and a stepping motor is generally used for driving a transportation line to move at present, but the moving mode causes the wire to move and drive at a lower speed, so that the overall working efficiency is influenced.

Disclosure of Invention

Aiming at the defects existing in the prior art, the utility model aims to provide a synchronous cylindrical battery cell transferring device which has the advantages of high transferring speed and stable rhythm.

The above object of the present utility model is achieved by the following technical solutions:

the synchronous transfer device for the cylindrical battery cells comprises a conveying line, wherein a plurality of pushing seats are arranged below the conveying line and are uniformly distributed at intervals along the length direction of the conveying line;

a base is arranged at one end of the pushing seat, which is far away from the material conveying line, and is provided with a track groove which is annular;

one end of each pushing seat, which is far away from the material conveying line, is commonly connected with a transmission block, and the transmission blocks are arranged on the base in a sliding manner;

the base is provided with a driving component for driving the transmission block to move along the track groove.

The utility model is further provided with: the pushing seat comprises two pushing plates, a connecting plate and a push rod, wherein the two pushing plates are respectively arranged on two sides of the material conveying line, the connecting plate is used for connecting the two pushing plates, the push rod is arranged on one side surface of the connecting plate, which is away from the pushing plates, the connecting plate is positioned on one side surface of the pushing plates, which is towards the base, the push rod is arranged in the vertical direction, each pushing plate is provided with a material supporting groove, and the material supporting grooves on the pushing plates are different and symmetrically arranged about the material conveying line.

The utility model is further provided with: and a synchronizing rod is arranged between any two adjacent push rods, and is arranged along the length direction of the conveying line, and a plurality of synchronizing rods are all positioned on the same straight line.

The utility model is further provided with: the driving assembly comprises a driving motor fixedly connected to the base and a swing rod fixedly connected to the driving shaft of the driving motor, a waist-shaped hole is formed in one end, far away from the driving shaft of the driving motor, of the swing rod, a sliding rod is inserted into the transmission block, and one end of the sliding rod penetrates through the waist-shaped hole and is inserted into the track groove.

The utility model is further provided with: the horizontal guide rail is characterized in that a plurality of sliding rails are arranged on the base along the length direction of the conveying line, the number of the sliding rails is consistent with that of the synchronizing rods, the length direction of the sliding rails is arranged along the vertical direction, each sliding rail is provided with a vertical sliding block in a sliding manner, one side of each vertical sliding block, which is away from the base, is provided with a horizontal sliding block, each synchronizing rod is provided with a horizontal guide rail towards one side of each horizontal sliding block, the horizontal guide rails are arranged along the length direction of the synchronizing rods, and the horizontal sliding blocks are embedded on the horizontal guide rails and slide along the horizontal guide rails.

The utility model is further provided with: limiting baffles are arranged at two ends of the sliding rail.

The utility model is further provided with: the vertical sliding block is provided with a stabilizing spring, and the stabilizing spring is connected with the base.

In summary, the beneficial technical effects of the utility model are as follows:

1. the transfer speed is increased, and the overall working efficiency is improved;

2. the transferring rhythm is kept stable, and the stability of the whole operation of the device is improved.

Drawings

Fig. 1 is a schematic structural view of a synchronous transfer device;

FIG. 2 is an enlarged view of portion A of FIG. 1;

fig. 3 is a plan view of the synchronous transfer device.

In the figure, 1, a conveying line; 2. a pushing seat; 21. a pushing plate; 211. a material supporting groove; 22. a connecting plate; 23. a push rod; 24. a synchronizing lever; 241. a horizontal guide rail; 3. a base; 31. a slide rail; 32. a vertical slider; 321. a stabilizing spring; 33. a limit baffle; 4. a track groove; 5. a transmission block; 51. a slide bar; 6. a drive assembly; 61. a driving motor; 62. swing rod; 621. a waist-shaped hole; 7. a horizontal sliding block.

Detailed Description

The present utility model will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1 and 3, the cylindrical battery cell synchronous transfer device disclosed by the utility model comprises a conveying line 1, wherein the conveying line 1 is arranged along the horizontal direction. Both sides of the length direction of the material conveying line 1 are provided with material pushing plates 21, the two material pushing plates 21 are symmetrically arranged relative to the material conveying line 1, and the length direction of the material pushing plates 21 is consistent with the length direction of the material conveying line 1. The lower end surfaces of the two pushing plates 21 are fixedly connected with a connecting plate 22, the connecting plate 22 is arranged along the width direction of the material conveying line 1, and the connecting plate 22 is parallel to the material conveying line 1. A push rod 23 is fixedly connected to one side surface of the connecting plate 22, which faces away from the pushing plate 21, and the push rod 23 is arranged in the vertical direction. The pushing plate 21, the connecting plate 22 and the pushing rod 23 together form a pushing seat 2, in this embodiment, the number of the pushing seats 2 is set to three, the three pushing seats 2 are uniformly distributed along the length direction of the material conveying line 1 at intervals, and the distances between any two adjacent pushing seats 2 in the length direction of the material conveying line 1 are equal.

Referring to fig. 1, a plurality of holding tanks 211 are provided on the upper end surface of each pushing plate 21, the number of holding tanks 211 on the same pushing plate 21 is plural, the plurality of holding tanks 211 are arranged at intervals along the length direction of the pushing plate 21, and the number of holding tanks 211 on different pushing plates 21 of the same pushing seat 2 is equal and symmetrically arranged about the conveying line 1. In this embodiment, two supporting slots 211 are formed on each pushing plate 21, and the cross section of each supporting slot 211 is trapezoidal.

Referring to fig. 1, a synchronizing rod 24 is connected between two adjacent pushing seats 2, the synchronizing rod 24 is located at one end of the push rod 23 far away from the pushing plate 21, the length direction of the synchronizing rod 24 is consistent with the length direction of the conveying line 1, and all the synchronizing rods 24 are located on the same straight line. The synchronizing rod 24 enables all pushing seats 2 to move synchronously, and only one pushing seat 2 needs to be pushed, and all pushing seats 2 move together.

Referring to fig. 1 and 3, a base 3 is disposed below the material transporting line 1, the base 3 is rectangular overall, a driving motor 61 is fixedly connected to one side surface of the base 3, in this embodiment, the driving motor 61 is a servo motor, and a driving shaft of the driving motor 61 penetrates through the base 3 and extends out from the other side surface of the base 3. By adopting the servo motor, the transfer device can adjust different speeds in different process sections, and the applicability is improved.

Referring to fig. 1 and 2, a swing link 62 is fixedly connected to a driving shaft of the driving motor 61, and a connection position is located at one end of the swing link 62, and a waist-shaped hole 621 is formed at the other end of the swing link 62 away from the driving shaft of the driving motor 61. The bottom of the pushing seat 2 in the middle is fixedly connected with a transmission block 5, a sliding rod 51 is inserted on the transmission block 5, and the sliding rod 51 is arranged towards the base 3. The side surface of the base 3 where the swing rod 62 is located is provided with a track groove 4, the track groove 4 is elliptical, and one end of the sliding rod 51, which is far away from the transmission block 5, penetrates through the waist-shaped hole 621 to be inserted into the track groove 4 and slides in the track groove 4.

Referring to fig. 1, two ends of the base 3 are provided with slide rails 31, two slide rails 31 are provided corresponding to two synchronizing bars 24, the slide rails 31 are provided along a vertical direction, and a vertical sliding block 32 is slidably provided on each slide rail 31. A horizontal sliding block 7 is fixedly connected to one side surface of the vertical sliding block 32, which faces away from the base 3, and the horizontal sliding block 7 is positioned at the upper end part of the vertical sliding block 32. A horizontal guide rail 241 is provided on one side of the synchronizing bar 24 facing the horizontal slider 7, the horizontal guide rail 241 is provided along the length direction of the synchronizing bar 24, and the horizontal slider 7 is embedded on the horizontal guide rail 241 and slides along the horizontal guide rail 241. The driving motor 61 and the swing rod 62 together form a driving assembly 6, the pushing seat 2 moves along the track groove 4 under the driving of the driving assembly 6, and the pushing frame does not deflect laterally under the constraint of the sliding rail 31 and the horizontal guide rail 241.

Referring to fig. 1, limit baffles 33 are respectively mounted at two ends of the sliding rail 31, and the limit baffles 33 are fixedly connected to the base 3. When the vertical sliding block 32 moves to the end of the sliding rail 31, the vertical sliding block 32 is blocked by the limiting baffle 33, so that the vertical sliding block 32 cannot slide out of the sliding rail 31 to influence normal operation. The vertical sliding block 32 is provided with a stabilizing spring 321 on a side surface deviating from the base 3, two stabilizing springs 321 are arranged on the same vertical sliding block 32, the two stabilizing springs 321 are parallel to each other, and one end of the stabilizing spring 321, which is far away from the vertical sliding block 32, is connected with the limit baffle 33.

3. The implementation principle of the embodiment is as follows: when the product to be transferred is placed on the material conveying line 1, the driving component 6 drives the material pushing seat 2 to move leftwards and upwards so that the product is separated from the material conveying line 1 and falls into the material pushing groove of the material pushing plate 21, then the driving component 6 drives the material pushing seat 2 to move leftwards so that the product moves along the length direction of the material conveying line 1, and finally the driving component 6 drives the material pushing seat 2 to move leftwards and downwards so that the product falls into the material conveying line 1 again and is transferred by the next material conveying seat. The utility model can increase the transfer speed, improve the overall working efficiency, keep the transfer rhythm stable and improve the stability of the device during the overall operation.

The embodiments of the present utility model are all preferred embodiments of the present utility model, and are not intended to limit the scope of the present utility model in this way, therefore: all equivalent changes in structure, shape and principle of the utility model should be covered in the scope of protection of the utility model.

Claims

1. The utility model provides a synchronous transfer device of cylinder electricity core, includes fortune stockline (1), its characterized in that: a plurality of pushing seats (2) are arranged below the conveying line (1), and the pushing seats (2) are uniformly distributed at intervals along the length direction of the conveying line (1);

a base (3) is arranged at one end, far away from the material conveying line (1), of the material pushing seat (2), a track groove (4) is formed in the base (3), and the track groove (4) is annular;

one end, far away from the material conveying line (1), of the plurality of material pushing seats (2) is commonly connected with a transmission block (5), and the transmission block (5) is arranged on the base (3) in a sliding manner;

the base (3) is provided with a driving component (6) for driving the transmission block (5) to move along the track groove (4).

2. The synchronous transfer device for cylindrical battery cells according to claim 1, wherein: the material pushing seat (2) comprises two material pushing plates (21) which are respectively arranged on two sides of the material conveying line (1), a connecting plate (22) used for connecting the two material pushing plates (21), and a push rod (23) arranged on one side surface of the connecting plate (22) deviating from the material pushing plates (21), wherein the connecting plate (22) is positioned on one side surface of the material pushing plates (21) facing the base (3), the push rods (23) are arranged in the vertical direction, each material pushing plate (21) is provided with a material supporting groove (211), and the material supporting grooves (211) on the different material pushing plates (21) are symmetrically arranged with respect to the material conveying line (1).

3. The synchronous transfer device for cylindrical battery cells according to claim 2, wherein: a synchronizing rod (24) is arranged between any two adjacent push rods (23), the synchronizing rods (24) are arranged along the length direction of the conveying line (1), and a plurality of synchronizing rods (24) are all positioned on the same straight line.

4. A synchronous transfer device for cylindrical cells according to claim 3, wherein: the driving assembly (6) comprises a driving motor (61) fixedly connected to the base (3), and a swing rod (62) fixedly connected to the driving shaft of the driving motor (61), a waist-shaped hole (621) is formed in one end, far away from the driving shaft of the driving motor (61), of the swing rod (62), a sliding rod (51) is inserted into the transmission block (5), and one end of the sliding rod (51) penetrates through the waist-shaped hole (621) and is inserted into the track groove (4).

5. The synchronous transfer device for cylindrical cells according to claim 4, wherein: be provided with a plurality of slide rails (31) along fortune stockline (1) length direction on base (3), slide rail (31) quantity is unanimous with synchronizing lever (24) quantity, slide rail (31) length direction sets up along vertical direction, each all slide on slide rail (31) and be provided with vertical slider (32), be provided with horizontal slider (7) on the side that vertical slider (32) deviate from base (3), each synchronizing lever (24) all are provided with horizontal guide (241) towards one side of horizontal slider (7), horizontal guide (241) set up along synchronizing lever (24) length direction, horizontal slider (7) inlay and establish on horizontal guide (241) and follow horizontal guide (241) and slide.

6. The synchronous transfer device for cylindrical cells according to claim 5, wherein: limiting baffles (33) are arranged at two ends of the sliding rail (31).

7. The synchronous transfer device for cylindrical cells according to claim 5, wherein: the vertical sliding block (32) is provided with a stabilizing spring (321), and the stabilizing spring (321) is connected with the base (3).