CN219506901U - Double-station cylindrical battery cell feeding mechanism - Google Patents

Abstract

The utility model discloses a double-station cylindrical battery cell feeding mechanism, which comprises a feeding assembly and a driving assembly, wherein the feeding assembly comprises a feeding mechanism, a feeding mechanism and a feeding mechanism; the feeding assembly comprises a first bracket, a belt line and a driving motor, wherein the driving motor is used for driving the belt line to run; the driving assembly comprises a second bracket, a horizontal pushing cylinder arranged on the second bracket and a pair of pushing blocks arranged on the horizontal pushing cylinder; the horizontal pushing cylinder is used for driving a pair of pushing blocks along the horizontal direction so as to simultaneously push two cylindrical battery cells positioned at preset positions of the belt line into the fixed jig, and the pushing direction of the horizontal pushing cylinder is perpendicular to the running direction of the belt line. According to the double-station cylindrical battery cell feeding mechanism provided by the utility model, the two pushing blocks are simultaneously arranged on the flat pushing cylinder, so that the driving assembly can push the two cylindrical battery cells on the belt line into the fixed jig at one time, the feeding efficiency is improved, and the double-station cylindrical battery cell feeding mechanism is simpler in structure and simpler and more convenient to operate.

Description

Double-station cylindrical battery cell feeding mechanism

[ field of technology ]

The utility model relates to the technical field of battery processing, in particular to a double-station cylindrical battery core feeding mechanism.

[ background Art ]

With the rapid development of new energy industry, batteries serving as cores, such as cylindrical batteries, square batteries, soft-pack batteries and the like, are widely used in electric automobiles, mobile phones and other devices. Therefore, safety as a battery product related to life is an important point of concern. Factors involved in the safety of the battery include the material itself, the assembly process, the test equipment, and the like. Wherein, during the processing procedures such as assembly, test and the like, the battery can be involved in the charging of the battery. However, the existing feeding mechanism can only singly carry the cylindrical battery cell or the cylindrical battery into the jig, so that the battery feeding efficiency is low.

In view of the foregoing, it is desirable to provide a dual-station cylindrical cell feeding mechanism that overcomes the above-mentioned drawbacks.

[ utility model ]

The utility model aims to provide a double-station cylindrical battery cell feeding mechanism, which aims to solve the problem of lower feeding efficiency of the existing feeding mechanism.

In order to achieve the above purpose, the utility model provides a double-station cylindrical battery core feeding mechanism, which is used for feeding a cylindrical battery core into a fixed jig, and comprises a feeding assembly and a driving assembly arranged on one side of the feeding assembly away from the fixed jig; the feeding assembly comprises a first bracket, a belt wire wound on the first bracket and a driving motor arranged on the first bracket, wherein the driving motor is used for driving the belt wire to run; the driving assembly comprises a second bracket, a horizontal pushing cylinder arranged on the second bracket and a pair of pushing blocks arranged on the horizontal pushing cylinder; the horizontal pushing cylinder is used for driving the pair of pushing blocks in the horizontal direction so as to simultaneously push the two cylindrical battery cells positioned at the preset position of the belt line into the fixing jig, and the pushing direction of the horizontal pushing cylinder is perpendicular to the running direction of the belt line.

In a preferred embodiment, the battery cell further comprises a cylindrical bearing seat, wherein the bearing seat is coaxially provided with a containing groove, and the containing groove is used for containing the middle lower part of the cylindrical battery cell.

In a preferred embodiment, the horizontal pushing cylinder comprises a fixed end fixed on the second bracket and a movable end connected to the fixed end; the pushing block is connected to the movable end through a connecting bracket.

In a preferred embodiment, the fixed end is provided with a guide rail parallel to the driving direction of the movable end, and the connecting bracket is provided with a sliding block; a sliding groove is formed in one side, close to the guide rail, of the sliding block, and the sliding groove is matched with the guide rail so that the sliding block can move along the guide rail.

In a preferred embodiment, each push block comprises a support rod connected to the connecting bracket, and a first push block and a second push block arranged on one side of the support rod away from the connecting bracket; the support rods are parallel to the guide rail and are arranged above the sliding blocks at intervals; the first pushing blocks are arranged above the second pushing blocks at intervals; the first pushing block is used for pushing the cylindrical battery cell, and the second pushing block is used for pushing the bearing seat.

In a preferred embodiment, a first arc-shaped groove is formed in one side, far away from the supporting rod, of the first push block, and the shape of the first arc-shaped groove is matched with the surface of the cylindrical battery cell; the second pushing block is far away from one side of the supporting rod, a second arc-shaped groove is formed in the side, away from the supporting rod, of the second pushing block, and the shape of the second arc-shaped groove is matched with the surface of the supporting seat.

In a preferred embodiment, the first bracket is provided with a baffle and a limiting cylinder on the left side and the right side relative to the belt line, the limiting cylinder is provided with a pressing block, and the limiting cylinder is used for driving the pressing block to press and abut the bearing seat positioned at the preset position on the belt line on the baffle; the limit cylinder is arranged at the rear of the push block along the running direction of the belt line.

In a preferred embodiment, a third arc-shaped groove is formed in one side, far away from the limiting cylinder, of the pressing block, and the shape of the third arc-shaped groove is matched with the surface of the bearing seat.

In a preferred embodiment, the first bracket is further provided with a lever; the stop rod is arranged above the belt line and used for stopping the bearing seat from running on the belt line, so that the pushing block can push the bearing seat into the fixing jig.

In a preferred embodiment, the first bracket is further provided with a bearing plate at a side far away from the driving assembly; the bearing plate is arranged between the belt line and the fixed jig and cannot influence the operation of the fixed jig.

According to the double-station cylindrical battery cell feeding mechanism provided by the utility model, the two pushing blocks are simultaneously arranged on the flat pushing cylinder, so that the driving assembly can push the two cylindrical battery cells on the belt line into the fixed jig at one time, the feeding efficiency is improved, and the double-station cylindrical battery cell feeding mechanism is simpler in structure and simpler and more convenient to operate.

[ description of the drawings ]

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present utility model and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a perspective view of a double-station cylindrical battery cell feeding mechanism provided by the utility model;

FIG. 2 is a top view of the dual-station cylindrical cell feeding mechanism shown in FIG. 1;

FIG. 3 is an enlarged view of a portion of the dual-station cylindrical cell feeding mechanism of FIG. 1;

fig. 4 is a perspective view of a drive assembly in the dual-station cylindrical cell feeding mechanism shown in fig. 1.

Reference numerals in the drawings: 100. double-station cylindrical battery cell feeding mechanism; 200. a cylindrical cell; 300. fixing the jig; 301. a turntable; 302. a carrier support; 10. a feeding assembly; 11. a first bracket; 12. a belt line; 13. a driving motor; 14. a baffle; 15. a limit cylinder; 16. briquetting; 161. a third arc-shaped groove; 17. a gear lever; 18. a carrying plate; 20. a drive assembly; 21. a second bracket; 22. a horizontal pushing cylinder; 221. a fixed end; 222. a movable end; 23. a pushing block; 231. a support rod; 232. a first push block; 2321. a first arc-shaped groove; 233. a second push block; 2331. a second arc-shaped groove; 24. a connecting bracket; 25. a guide rail; 26. a slide block; 261. a chute; 30. a support bracket; 31. an accommodating groove.

[ detailed description ] of the utility model

In order to make the objects, technical solutions and advantageous technical effects of the present utility model more apparent, the present utility model will be further described in detail with reference to the accompanying drawings and detailed description. It should be understood that the detailed description is intended to illustrate the utility model, and not to limit the utility model.

It is also to be understood that the terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. As used in this specification and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

It should be further understood that the term "and/or" as used in the present specification and the appended claims refers to any and all possible combinations of one or more of the associated listed items, and includes such combinations.

In the embodiment of the utility model, a dual-station cylindrical battery cell feeding mechanism 100 is provided, which is used for feeding a cylindrical battery cell 200 into a fixed jig 300, so as to realize the feeding operation of the cylindrical battery cell 200, and facilitate corresponding test processing operation of other test processing mechanisms on the cylindrical battery cell 200 in the fixed jig 300.

The fixing jig 300 includes a turntable 301 and a plurality of carrying frames 302 disposed on the turntable 301, so that the stations of the carrying frames 302 can be switched by the rotation of the turntable 301.

As shown in fig. 1-4, the dual-station cylindrical battery cell feeding mechanism 100 includes a feeding assembly 10 and a driving assembly 20 disposed on a side of the feeding assembly 10 away from the fixing jig 300.

The feeding assembly 10 is used for feeding the cylindrical battery cell 200 to be processed, and the driving assembly 20 is used for conveying the cylindrical battery cell 200 in the feeding assembly 10 into the carrying bracket 302 of the fixing jig 300.

Further, the dual-station cylindrical cell feeding mechanism 100 further comprises a cylindrical supporting seat 30. The bearing bracket 30 is coaxially provided with a cylindrical accommodating groove 31, and the accommodating groove 31 is used for accommodating the middle lower part of the cylindrical battery cell 200. In this embodiment, the lower half of the cylindrical battery cell 200 is located in the accommodating groove 31, so as to avoid the toppling of the cylindrical battery cell 200 during movement, and simultaneously facilitate the processing of the upper half of the cylindrical battery cell 200 by the processing mechanism.

Specifically, the feeding assembly 10 includes a first bracket 11, a belt line 12 wound on the first bracket 11, and a driving motor 13 disposed on the first bracket 11. The driving motor 13 is used for driving the belt line 12 to operate, so as to drive the cylindrical battery cell 200 to be processed, which is placed on the belt line 12, to move.

The driving assembly 20 includes a second bracket 21, a horizontal pushing cylinder 22 provided on the second bracket 21, and a pair of pushing blocks 23 provided on the horizontal pushing cylinder 22.

The horizontal pushing cylinder 22 is used for driving a pair of pushing blocks 23 along the horizontal direction so as to push two cylindrical battery cells 200 positioned at preset positions of the belt line 12 into the fixed jig 300 at the same time, thereby improving the feeding efficiency. The pushing direction of the horizontal pushing air cylinder 22 is perpendicular to the running direction of the belt line 12, that is, the horizontal pushing air cylinder 22 transversely pushes the cylindrical battery cell 200 into the fixing jig 300.

Specifically, the horizontal pushing cylinder 22 includes a fixed end 221 fixed on the second bracket 21 and a movable end 222 connected to the fixed end 221. That is, the fixed end 221 is used for implementing the reciprocating motion of the movable end 222, and the specific structure and implementation principle thereof can refer to the existing cylinder, and the present utility model is not described herein. Wherein the push block 23 is connected to the movable end 222 through the connecting bracket 24.

Further, the fixed end 221 is provided with a guide rail 25 parallel to the driving direction of the movable end 222, and the connecting bracket 24 is provided with a slider 26. A sliding groove 261 is formed in one side, close to the guide rail 25, of the sliding block 26, and the sliding groove 261 is matched with the guide rail 25 so that the sliding block 26 can move along the guide rail 25, accuracy of moving directions of the sliding block 26 and the connecting support 24 is improved, and pushing accuracy of the pushing block 23 is improved.

Further, each push block 23 includes a support rod 231 connected to the connecting bracket 24, and a first push block 232 and a second push block 233 disposed on a side of the support rod 231 away from the connecting bracket 24. The struts 231 are arranged parallel to the guide rail 25 and spaced above the slide 26. The first push block 232 is spaced above the second push block 233, so that the first push block 232 is used for pushing the cylindrical battery cell 200, and the second push block 233 is used for pushing the bearing bracket 30.

Wherein, a first arc groove 2321 is provided on a side of the first push block 232 away from the strut 231, and a shape of the first arc groove 2321 is adapted to a surface of the cylindrical battery cell 200, that is, an inner wall of the first arc groove 2321 can be attached to an outer surface of the cylindrical battery cell 200. The second pushing block 233 is provided with a second arc-shaped groove 2331 on one side far away from the supporting rod 231, and the shape of the second arc-shaped groove 2331 is matched with the surface of the supporting seat 30, namely, the inner wall of the second arc-shaped groove 2331 can be attached to the outer surface of the supporting seat 30. It should be noted that, since the radius of the bearing holder 30 is larger than the radius of the cylindrical battery cell 200, the arc radius of the second arc-shaped slot 2331 is larger than the arc radius of the first arc-shaped slot 2321.

In one embodiment, the first bracket 11 is provided with a baffle 14 and a limiting cylinder 15 on the left and right sides relative to the belt line 12. The limiting cylinder 15 is provided with a pressing block 16, and the limiting cylinder 15 is used for driving the pressing block 16 to press and abut the bearing seat 30 positioned at the preset position on the belt line 12 on the baffle 14. That is, the limit cylinder 15 can press the bearing seat 30 onto the baffle 14 through the pressing block 16, so that the bearing seat 30 cannot move along with the running of the belt line 12. Wherein, the limit cylinder 15 is arranged at the rear of the push block 23 along the running direction of the belt line 12. That is, the limit cylinder 15 can stop the bearing seat 30 on the belt line 12, so that the bearing seat 30 cannot move to the position corresponding to the push block 23 along with the belt line 12, so as to avoid affecting the bearing seat 30 in front of the push block 23.

Further, a third arc-shaped groove 161 is formed on one side of the pressing block 16 away from the limiting cylinder 15. The shape of the third arc-shaped groove 161 is matched with the surface of the bearing seat 30, that is, the inner wall of the third arc-shaped groove 161 can be attached to the outer surface of the bearing seat 30.

Further, the first bracket 11 is also provided with a stop lever 17. The stop lever 17 is disposed above the belt line 12, and is used for stopping the movement of the bearing seat 30 on the belt line 12, and performing a positioning function on the bearing seat 30, so that the pushing block 23 located in front of the belt line 12 can push the bearing seat 30 into the fixing jig 300. At the same time, the stop lever 17 can also prevent the bearing bracket 30 from falling down due to the movement of the belt line 12.

Further, the first bracket 11 is further provided with a carrying plate 18 at a side far from the driving assembly 20. The carrier plate 18 is located on a horizontal plane and is flush with the surface of the belt line 12. The carrier plate 18 is disposed between the belt line 12 and the fixing jig 300 and does not affect the operation of the fixing jig 300. In this embodiment, the side of the bearing plate 18 away from the belt line 12 is provided with an arc-shaped groove adapted to the turntable 301 to fill the gap between the belt line 12 and the turntable 301, so that the bearing bracket 30 can cross the gap through the bearing plate 18 to promote smooth running of the bearing bracket 30.

In summary, according to the dual-station cylindrical battery cell feeding mechanism 100 provided by the utility model, the two pushing blocks 23 are simultaneously arranged on the flat pushing cylinder 22, so that the driving assembly 20 can push the two cylindrical battery cells 200 on the belt line 12 into the fixing jig 300 at one time, the feeding efficiency is improved, and the dual-station cylindrical battery cell feeding mechanism has a simpler structure and simpler and more convenient operation.

The present utility model is not limited to the details and embodiments described herein, and thus additional advantages and modifications may readily be made by those skilled in the art, without departing from the spirit and scope of the general concepts defined in the claims and the equivalents thereof, and the utility model is not limited to the specific details, representative apparatus and illustrative examples shown and described herein.

Claims (10)

1. The double-station cylindrical battery cell feeding mechanism is used for feeding a cylindrical battery cell into a fixed jig and is characterized by comprising a feeding assembly and a driving assembly arranged on one side of the feeding assembly away from the fixed jig; the feeding assembly comprises a first bracket, a belt wire wound on the first bracket and a driving motor arranged on the first bracket, wherein the driving motor is used for driving the belt wire to run; the driving assembly comprises a second bracket, a horizontal pushing cylinder arranged on the second bracket and a pair of pushing blocks arranged on the horizontal pushing cylinder; the horizontal pushing cylinder is used for driving the pair of pushing blocks in the horizontal direction so as to simultaneously push the two cylindrical battery cells positioned at the preset position of the belt line into the fixing jig, and the pushing direction of the horizontal pushing cylinder is perpendicular to the running direction of the belt line.

2. The dual-station cylindrical cell feeding mechanism of claim 1, further comprising a cylindrical bearing seat, wherein the bearing seat is coaxially provided with a receiving groove, and the receiving groove is used for receiving the middle lower part of the cylindrical cell.

3. The dual-station cylindrical cell feeding mechanism of claim 2, wherein the horizontal pushing cylinder comprises a fixed end fixed on the second bracket and a movable end connected to the fixed end; the pushing block is connected to the movable end through a connecting bracket.

4. The double-station cylindrical battery cell feeding mechanism according to claim 3, wherein a guide rail parallel to the driving direction of the movable end is arranged on the fixed end, and a sliding block is arranged on the connecting bracket; a sliding groove is formed in one side, close to the guide rail, of the sliding block, and the sliding groove is matched with the guide rail so that the sliding block can move along the guide rail.

5. The dual-station cylindrical battery cell feeding mechanism of claim 4, wherein each push block comprises a support rod connected to the connecting bracket, and a first push block and a second push block arranged on one side of the support rod far away from the connecting bracket; the support rods are parallel to the guide rail and are arranged above the sliding blocks at intervals; the first pushing blocks are arranged above the second pushing blocks at intervals; the first pushing block is used for pushing the cylindrical battery cell, and the second pushing block is used for pushing the bearing seat.

6. The double-station cylindrical battery cell feeding mechanism according to claim 5, wherein a first arc-shaped groove is formed in one side, far away from the supporting rod, of the first push block, and the shape of the first arc-shaped groove is matched with the surface of the cylindrical battery cell; the second pushing block is far away from one side of the supporting rod, a second arc-shaped groove is formed in the side, away from the supporting rod, of the second pushing block, and the shape of the second arc-shaped groove is matched with the surface of the supporting seat.

7. The double-station cylindrical battery cell feeding mechanism according to claim 2, wherein the first bracket is provided with a baffle and a limiting cylinder on the left side and the right side relative to the belt line respectively, the limiting cylinder is provided with a pressing block, and the limiting cylinder is used for driving the pressing block to press and abut the bearing seat positioned at the preset position on the belt line on the baffle; the limit cylinder is arranged at the rear of the push block along the running direction of the belt line.

8. The duplex cylinder cell feeding mechanism of claim 7, wherein a third arc-shaped groove is formed in one side of the pressing block away from the limiting cylinder, and the shape of the third arc-shaped groove is matched with the surface of the bearing seat.

9. The double-station cylindrical battery cell feeding mechanism according to claim 2, wherein the first bracket is further provided with a stop lever; the stop rod is arranged above the belt line and used for stopping the bearing seat from running on the belt line, so that the pushing block can push the bearing seat into the fixing jig.

10. The dual-station cylindrical cell feeding mechanism of claim 1, wherein the first bracket is further provided with a bearing plate at a side far away from the driving assembly; the bearing plate is arranged between the belt line and the fixed jig and cannot influence the operation of the fixed jig.