CN218016120U - Battery monomer cutting machine - Google Patents

Abstract

The utility model relates to a battery monomer cutting machine, it includes workstation, sliding sleeve and cutting knife, the sliding sleeve with workstation sliding connection, the outer wall department of sliding sleeve inwards caves in and forms a storage tank that is used for placing the battery, the length direction of storage tank is the same with the slip direction of sliding sleeve, the outer wall department of sliding sleeve sets up the cutting opening with the storage tank is linked together, the cutting opening forms a cutting route that runs through at least part of the storage tank; the cutting knife is fixedly arranged on the workbench, and the cutting end of the cutting knife is positioned on the cutting path; the problem of current battery cutting machine can only cut along the circumference wall of battery, is not convenient for retrieve its inside material is solved.

Description

Battery monomer cutting machine

Technical Field

The utility model relates to a technical field is retrieved to the battery, especially relates to a battery monomer cutting machine.

Background

In order to meet the concept of green energy, the waste battery can be recycled, and particularly, the shell of the waste battery is crushed to recycle the materials such as graphite in the battery shell and the battery. A cutting machine is required to crush the battery case.

For example, the utility model patent with application number CN201921179113.7 may be adopted to provide an automatic disassembling production line for cylindrical battery and an automatic cutting device thereof, wherein, a conveying mechanism, a rotary driving mechanism and a cutting mechanism are provided on the mounting plate, the conveying mechanism is used for conveying and transferring the battery to be cut to the battery cutting position of the mounting plate, the cutting mechanism includes a cutting member, and when the battery to be cut is located at the battery cutting position, the knife edge of the cutting member abuts against the circumferential wall of the battery to be cut.

However, the conventional battery cutting machine can only cut along the circumferential wall of the battery, and it is inconvenient to recover the substances inside.

SUMMERY OF THE UTILITY MODEL

In view of the above, there is a need for a battery cell cutting machine, which solves the problem that the existing battery cell cutting machine can only cut along the circumferential wall of the battery, and is inconvenient to recycle the internal substances.

The utility model provides a battery monomer cutting machine, including workstation, sliding sleeve and cutting knife, the sliding sleeve with workstation sliding connection, the outer wall department of sliding sleeve inwards caves in and forms a storage tank that is used for placing the battery, the length direction of storage tank is the same with the slip direction of sliding sleeve, the outer wall department of sliding sleeve sets up the cutting opening with the storage tank is linked together, the cutting opening forms a cutting route that runs through at least part of the storage tank; the cutting knife is fixedly arranged on the workbench, and the cutting end of the cutting knife is positioned on the cutting path.

Furthermore, the number of cutting openings is two, and one of them cutting opening, holding tank and another cutting opening follow the slip direction of sliding sleeve sets gradually.

Further, the last fixedly connected with slider of sliding sleeve, the spout has been seted up on the workstation, the slider with spout sliding connection.

The battery pack storage device further comprises a pushing assembly, the pushing assembly is fixedly connected with the workbench, an opening communicated with the storage groove is formed in one side, away from the storage groove, of the sliding sleeve, and a pushing end of the pushing assembly can extend into the opening and is used for pushing the battery out of the storage groove.

Furthermore, the pushing assembly comprises an air cylinder and an ejector rod, the air cylinder is fixedly connected with the workbench, the output end of the air cylinder is connected with the ejector rod, the sliding direction of the ejector rod is perpendicular to the sliding direction of the sliding sleeve, and the ejector rod can slide to penetrate through the opening to the storage groove.

Furthermore, the device also comprises a driving assembly, the driving assembly is fixedly connected with the workbench, and the output end of the driving assembly is connected with the sliding sleeve and used for driving the sliding sleeve to slide.

Further, drive assembly includes motor and screw rod, the motor with workstation fixed connection, the output of motor with the screw rod is connected, the screw rod with the workstation rotates to be connected, the screw rod with the threaded sleeve threaded connection who sets up on the sliding sleeve.

Furthermore, the device also comprises a feeding component, and the feeding end of the feeding component is arranged along a sliding path vertical to the storage groove.

Furthermore, the feeding assembly comprises a push plate and a push rod, the push plate is in sliding connection with a feeding groove formed in the workbench, the push rod is in sliding connection with the workbench, the push rod is fixedly connected with one side, far away from the storage groove, of the push plate, and the sliding direction of the push plate is perpendicular to the sliding direction of the sliding sleeve.

Furthermore, a discharge chute is formed in the workbench, and the discharge chute and the pushing assembly are oppositely arranged on two sides of the cutting path.

Compared with the prior art, the sliding sleeve is connected with the workbench in a sliding mode, the outer wall of the sliding sleeve is inwards sunken to form a storage groove used for containing a battery, the battery can be placed in the storage groove, the battery can slide along with the sliding sleeve, the length direction of the storage groove is the same as the sliding direction of the sliding sleeve, the battery placed in the storage groove can slide along the length direction of the storage groove, a cutting opening communicated with the storage groove is formed in the outer wall of the sliding sleeve, the cutting opening forms a cutting path penetrating through at least part of the storage groove, the cutting knife is fixedly arranged on the workbench, the cutting end of the cutting knife is located on the cutting path, in the process that the battery slides along the length direction of the battery, the cutting knife is in contact with the cutting knife, the cutting knife penetrates through the cutting opening to the storage groove to cut the outer wall of the battery along the length direction of the battery, the battery is cut longer, the exposed outside area inside of the battery is large, and the recycling work of substances inside the battery is facilitated.

Drawings

Fig. 1 is an overall schematic top view of an embodiment of a battery cell cutting machine according to the present invention;

fig. 2 is a schematic front view of a sliding sleeve in an embodiment of the battery cell cutting machine according to the present invention.

Detailed Description

The following detailed description of the preferred embodiments of the invention, which is to be read in connection with the accompanying drawings, forms a part of this application, and together with the embodiments of the invention, serve to explain the principles of the invention and not to limit its scope.

As shown in fig. 1-2, the battery cell cutting machine in this embodiment includes a workbench 100, a sliding sleeve 200 and a cutting knife 300, wherein the sliding sleeve 200 is slidably connected to the workbench 100, an outer wall of the sliding sleeve 200 is recessed inward to form a storage slot 210 for storing a battery, a length direction of the storage slot 210 is the same as a sliding direction of the sliding sleeve 200, an outer wall of the sliding sleeve 200 is provided with a cutting opening 220 communicated with the storage slot 210, and the cutting opening 220 forms a cutting path penetrating at least a part of the storage slot 210; the cutting blade 300 is fixedly disposed on the worktable 100, and the cutting end of the cutting blade 300 is located on the cutting path.

The sliding sleeve 200 is connected with the workbench 100 in a sliding manner, the outer wall of the sliding sleeve 200 is recessed inwards to form a storage groove 210 for placing a battery, the battery can be placed in the storage groove 210 and can slide along with the sliding sleeve 200, the length direction of the storage groove 210 is the same as the sliding direction of the sliding sleeve 200, the battery placed in the storage groove 210 can slide along the length direction of the storage groove, a cutting opening 220 communicated with the storage groove 210 is formed in the outer wall of the sliding sleeve 200, the cutting opening 220 forms a cutting path penetrating through at least part of the storage groove 210, the cutting knife 300 is fixedly arranged on the workbench 100, the cutting end of the cutting knife 300 is located on the cutting path and is in contact with the cutting knife 300 in the process that the battery slides along the length direction, the cutting knife 300 penetrates through the cutting opening 220 to cut the outer wall of the battery in the storage groove 210 along the length direction of the battery, the battery is cut longer, the area exposed outside the battery is large, and the recovery work of substances inside the battery is facilitated.

The worktable 100 of the present embodiment is a structure for supporting the sliding sleeve 200 and the cutting knife 300, so that the sliding sleeve 200 slides in a predetermined direction, and the cutting knife 300 fixed on the worktable 100 can penetrate through the sliding sleeve 200 to cut the battery inside the sliding sleeve 200.

The sliding sleeve 200 in this embodiment is a structure for bearing a battery, and drives the battery to slide relative to the cutting knife 300 fixed on the worktable 100.

In a preferred embodiment, the number of the cuts 220 is two, wherein one cut 220, the storage slot 210, and the other cut 220 are sequentially arranged along the sliding direction of the sliding sleeve 200.

In order to stabilize the sliding process of the sliding sleeve 200 and prevent the cutting knife 300 from affecting the sliding sleeve 200 during the cutting process, in a preferred embodiment, a sliding block 240 is fixedly connected to the sliding sleeve 200, a sliding slot 110 is formed in the worktable 100, and the sliding block 240 is slidably connected to the sliding slot 110.

In order to facilitate ejecting the cut battery out of the storage slot 210 of the sliding sleeve 200, in a preferred embodiment, the battery ejecting device further includes an ejecting assembly 400, the ejecting assembly 400 is fixedly connected to the workbench 100, an opening 230 communicated with the storage slot 210 is formed on one side of the sliding sleeve 200 away from the storage slot 210, and an ejecting end of the ejecting assembly 400 can extend into the opening 230 to eject the battery out of the storage slot 210.

The pushing assembly 400 includes an air cylinder 410 and a push rod 420, the air cylinder 410 is fixedly connected to the working table 100, an output end of the air cylinder 410 is connected to the push rod 420, a sliding direction of the push rod 420 is perpendicular to a sliding direction of the sliding sleeve 200, and the push rod 420 can slide to pass through the opening 230 to the storage tank 210.

In order to facilitate the ejection of the cut battery, in a preferred embodiment, the work table 100 is provided with a discharge chute 130, and the discharge chute 130 and the pushing assembly 400 are disposed at two opposite sides of the cutting path.

In order to facilitate the sliding of the sliding sleeve 200, in a preferred embodiment, the sliding mechanism further comprises a driving assembly 500, the driving assembly 500 is fixedly connected to the worktable 100, and an output end of the driving assembly 500 is connected to the sliding sleeve 200 for driving the sliding sleeve 200 to slide.

The driving assembly 500 includes a motor 510 and a screw 520, the motor 510 is fixedly connected to the worktable 100, an output end of the motor 510 is connected to the screw 520, the screw 520 is rotatably connected to the worktable 100, and the screw 520 is in threaded connection with the threaded sleeve 250 disposed on the sliding sleeve 200.

In order to facilitate the feeding of the batteries to be cut into the storage groove 210, in a preferred embodiment, a feeding assembly 600 is further included, and a feeding end of the feeding assembly 600 is disposed along a sliding path perpendicular to the storage groove 210.

The feeding assembly 600 comprises a push plate 610 and a push rod 620, the push plate 610 is slidably connected with the feeding groove 120 formed in the workbench 100, the push rod 620 is slidably connected with the workbench 100, the push rod 620 is fixedly connected with one side of the push plate 610 far away from the storage groove 210, and the sliding direction of the push plate 610 is arranged along the sliding direction perpendicular to the sliding sleeve 200.

Compared with the prior art: the sliding sleeve 200 is connected with the workbench 100 in a sliding mode, a storage groove 210 used for containing a battery is formed by inwards recessing the outer wall of the sliding sleeve 200, the battery can be placed in the storage groove 210 and can slide along with the sliding sleeve 200, the length direction of the storage groove 210 is the same as the sliding direction of the sliding sleeve 200, the battery placed in the storage groove 210 can slide along the length direction of the battery, a cutting opening 220 communicated with the storage groove 210 is formed in the outer wall of the sliding sleeve 200, the cutting opening 220 forms a cutting path penetrating through at least part of the storage groove 210, the cutting knife 300 is fixedly arranged on the workbench 100, the cutting end of the cutting knife 300 is located on the cutting path and is in contact with the cutting knife 300 in the process that the battery slides along the length direction, the cutting knife 300 penetrates through the cutting opening 220 to the storage groove 210 to cut the outer wall of the battery along the length direction of the battery, the battery is long in cutting, the area of the exposed outside inside of the battery is large, and the recycling work of substances inside the battery is facilitated.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention should be covered by the present invention.

Claims (10)

1. A battery monomer cutting machine is characterized by comprising a workbench, a sliding sleeve and a cutting knife;

the sliding sleeve is connected with the workbench in a sliding mode, the outer wall of the sliding sleeve is inwards recessed to form a storage groove used for containing a battery, the length direction of the storage groove is the same as the sliding direction of the sliding sleeve, a cutting opening communicated with the storage groove is formed in the outer wall of the sliding sleeve, and the cutting opening forms a cutting path penetrating through at least part of the storage groove;

the cutting knife is fixedly arranged on the workbench, and the cutting end of the cutting knife is positioned on the cutting path.

2. The battery cell cutting machine according to claim 1, wherein the number of the cutting openings is two, and one of the cutting openings, the storage groove, and the other cutting opening are sequentially arranged along the sliding direction of the sliding sleeve.

3. The battery cell cutting machine according to claim 1, wherein a slide block is fixedly connected to the slide sleeve, a slide groove is formed in the workbench, and the slide block is slidably connected with the slide groove.

4. The battery cell cutting machine according to claim 1, further comprising a pushing assembly, wherein the pushing assembly is fixedly connected to the workbench, an opening communicated with the storage groove is formed in one side of the sliding sleeve away from the storage groove, and a pushing end of the pushing assembly can extend into the opening to push the battery out of the storage groove.

5. The battery cell cutting machine according to claim 4, wherein the pushing assembly comprises a cylinder and a push rod, the cylinder is fixedly connected with the workbench, an output end of the cylinder is connected with the push rod, a sliding direction of the push rod is perpendicular to a sliding direction of the sliding sleeve, and the push rod can slide to pass through the opening to the storage groove.

6. The battery cell cutting machine according to claim 1, further comprising a driving assembly, wherein the driving assembly is fixedly connected to the worktable, and an output end of the driving assembly is connected to the sliding sleeve to drive the sliding sleeve to slide.

7. The battery cell cutting machine according to claim 6, wherein the driving assembly includes a motor and a screw, the motor is fixedly connected to the table, an output end of the motor is connected to the screw, the screw is rotatably connected to the table, and the screw is in threaded connection with a threaded sleeve provided on the sliding sleeve.

8. The battery cell cutting machine according to claim 1, further comprising a feeding assembly, wherein a feeding end of the feeding assembly is disposed along a sliding path perpendicular to the storage groove.

9. The battery cell cutting machine according to claim 8, wherein the feeding assembly comprises a push plate and a push rod, the push plate is slidably connected with a feeding groove formed in the workbench, the push rod is slidably connected with the workbench, the push rod is fixedly connected with one side, away from the storage groove, of the push plate, and the sliding direction of the push plate is perpendicular to the sliding direction of the sliding sleeve.

10. The battery cell cutting machine according to claim 4, wherein a discharge chute is formed in the workbench, and the discharge chute and the pushing assembly are oppositely arranged on two sides of the cutting path.

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