CN112896812A - Inner core stacking method convenient to take for battery production line - Google Patents

Abstract

The invention provides a conveniently-taken inner core stacking method for a battery production line, which relates to the technical field of battery production and processing, and specifically comprises the following steps: s1, picking up inner cores: picking up a plurality of battery inner cores at one time by a manipulator from the battery inner cores flowing on a battery production line, and lifting up the picked up inner cores for transferring; s2, stacking inner cores: orderly placing a plurality of battery cores picked up by the manipulator in the step S1 in the core stacking device according to rows and columns, wherein the manipulator is used in the process of placing the plurality of battery cores in the core stacking device; according to the invention, the concave storage partition plate groove is formed in the front side of the inner wall of the inner core stacking groove, and a plurality of partition plates can be stored in the storage partition plate groove, so that the storage partition plate groove can be rapidly collected, the continuous supply of battery cores is realized, the conveying efficiency of the battery cores is improved, and the timely supply of the battery cores in the material outlet is ensured.

Description

Inner core stacking method convenient to take for battery production line

Technical Field

The invention relates to the technical field of battery production and processing, in particular to a method for stacking inner cores, which is convenient to take, for a battery production line.

Background

The battery inner core is the lithium battery board of a square form essentially, often installs in the treasured that charges, and is current, and a treasured that charges is inside to establish ties by polylith lithium cell more, therefore on battery production lines such as rechargeable battery, need arrange in order polylith battery inner core in order to be convenient for count and conveniently take fast, improve the production efficiency on the production line.

Currently, patent No. CN201811595974.3 discloses a cylindrical battery core ejection device, which includes a first support, a feeding mechanism, a four-station turntable mechanism, a battery top cover separating mechanism, and a battery core ejection mechanism, which are disposed on the first support. The first support is provided with four stations which are respectively a feeding station, a battery top cover separating station, a battery inner core ejecting station and a discharging station, and the four stations are distributed around the rotary table; wherein, the battery top cover separation, the battery inner core ejection and the blanking station are all provided with a collection bin fixed on the first bracket. After the cylindrical battery is cut, the full-automatic operation is carried out to separate the positive and negative top covers of the battery, push out the inner core of the battery, collect the metal shell of the battery and collect unqualified products. Through hydraulic pressure, pneumatic, electric actuator, thereby it replaces artifically to realize automaticly through PLC control, saves the labour, reduces the cost of labor, and efficient.

The patent discloses that battery inner core ejecting device still has some shortcomings in the in-service use, and concrete shortcoming lies in:

firstly, current, battery production line is at the during operation, and the battery inner core volume that needs is big, and the staff is after taking the battery in succession, and when stopping suddenly and taking the battery inner core and lead to forgetting the count, be difficult to return the inquiry or recount again, lead to delaying the normal work of production line.

Disclosure of Invention

Aiming at the problems in the prior art, the invention aims to provide a method for stacking inner cores convenient to take for a battery production line, and the method is used for solving the technical problems that when the battery production line works, the number of the required battery inner cores is large, and workers stop taking the battery inner cores suddenly after continuously taking the batteries, so that the counting is forgotten, the heads are difficult to return for inquiring or the counting is difficult, and the normal work of the production line is delayed.

The technical problem to be solved by the invention is realized by adopting the following technical scheme: the utility model provides a battery production line is with inner core stacking method convenient to take, is applied to on the battery production line, shifts the transport to the inner core on the battery production line, and this battery production line is with inner core stacking method convenient to take specifically includes several following steps:

s1, picking up inner cores: picking up a plurality of battery inner cores at one time by a manipulator from the battery inner cores flowing on a battery production line, and lifting up the picked up inner cores for transferring;

s2, stacking inner cores: orderly stacking the plurality of battery cores picked up by the manipulator in the step S1 in the core stacking device according to rows and columns, and placing a layer of partition plate between two adjacent columns of battery cores in the core stacking device through manual cooperation of the manipulator in the process that the manipulator places the plurality of battery cores in the core stacking device;

s3, taking inner cores: taking the battery cores placed in the core stacking device in the step S2, and arranging and discharging the batteries inside through the core stacking device to enable one of the batteries to extend out of the core stacking device, so that the batteries can be conveniently taken in the production process;

the inner core stacking device in the steps S1-S3 includes an inner core stacking box, the inner core stacking box is set to be a square box structure, an inner core stacking groove with a square groove structure is formed in the middle of the top end of the inner core stacking box, a material spitting table is fixedly mounted on the left side of the inner core stacking box and close to the front end of the inner core stacking box, a material spitting port is formed in the middle of the top end of the material spitting table, and the bottom end of the material spitting port is communicated with the inner core stacking groove;

a first motor is fixedly installed at the bottom end of the inner core stacking box, a shaft outlet shaft extends forwards from the first motor, a first crank is fixedly installed at the top end of an output shaft of the first motor, a through square hole is formed in the bottom end of the material discharging opening and is located at the bottom surface of the inner core stacking groove, a second material pushing block is connected in the square hole in the bottom surface of the inner core stacking groove in a sliding mode, a first transverse frame is fixedly installed at the bottom end of the second material pushing block, and the middle of the bottom end of the first transverse frame is connected with the first crank in a sliding mode;

a abdicating groove is arranged on the bottom surface of the inner core stacking box and close to the front side of the inner core stacking box, the abdicating groove is positioned on the right side of the material discharging port on the bottom surface of the inner core stacking groove, the inside of the abdicating groove is provided with a circularly rotating conveying belt which is a flat belt, the top surface of the conveying belt is slightly lower than the bottom surface of the inner core stacking groove, two ends of the inner ring of the conveying belt are symmetrically provided with conveying belt rollers, two ends of the conveying belt roller on each side are rotatably connected with two sides of the inner wall of the abdicating groove through bearings, a second motor groove is arranged on one side of the inner wall of the abdicating groove, a second motor is fixedly arranged in the second motor groove, wherein the conveyer belt roller on one side is fixedly connected with an output shaft of the second motor, a support plate is arranged in the middle of the inner ring of the conveyer belt, the top surface of backup pad is the plane, the both ends of backup pad are fixed in the left and right sides in groove 3 of stepping down.

As a preferred technical scheme of the invention, the left side and the right side of the inner wall of the inner core stacking groove are symmetrically provided with a sunken sliding groove in the middle of the inner wall positioned at the left side and the right side, the sliding grooves at the two sides of the inner core stacking groove are embedded with partition plates at equal intervals in a sliding fit manner, and a plurality of battery inner cores are orderly arranged between two adjacent partition plates;

the left end and the right end of one partition plate positioned at the rear side of the inner core stacking groove are symmetrically provided with convex lug plates, the upper end of the sliding groove and the lower end of the sliding groove at each side are symmetrically provided with a pull rope groove, the lug plates at the two sides of the partition plate extend into the pull rope groove in a sliding fit mode, and the top end of the lug plate extending into the pull rope groove is fixedly provided with a pull rope buckle;

the inner core stacking box is characterized in that rope winding grooves are symmetrically formed in the inner core stacking box and located in the front side of the inner core stacking groove, a rope winding frame is rotatably connected to the inner portion of each rope winding groove, a torsion spring is fixedly arranged at one end of each rope winding frame, the torsion spring at one end of each rope winding frame is fixed to one end of each rope winding groove, a pull rope is wound on each rope winding frame, and the other end of each pull rope penetrates through the pull rope groove and is fixedly connected with a pull rope buckle on the lug plate.

As a preferable technical scheme of the invention, a concave storage clapboard groove is formed in the front side of the inner wall of the inner core stacking groove, and a plurality of clapboards can be stored in the storage clapboard groove.

As a preferred technical scheme of the invention, one side of the inner wall of the material discharge port is hinged with a pressing plate, the bottom end of the pressing plate is hinged with one side of the inner wall of the material discharge port, and the middle part of the pressing plate is connected with a lifting shaft rod in a sliding manner;

a second pressing hole is formed in the material spitting platform and close to the material spitting opening, a second motor starting button is fixedly mounted on one side of the inner wall of the second pressing hole, the second motor starting button is of a circular ring structure with a circular hole in the middle, and the second motor starting button is electrically connected with the second motor through a cable;

the left end of the lifting shaft rod stretches into the material spitting opening in a sliding fit mode, stretches into the material spitting opening, the left end of the lifting shaft rod penetrates through a round hole of a second motor starting button, and stretches into the material spitting opening, and a second pressing block of a circular ring structure is fixedly arranged at the left end of the lifting shaft rod.

Compared with the prior art, the invention has the beneficial effects that:

according to the battery inner core stacking box, the inner core stacking groove with the square groove structure is formed in the top end of the inner core stacking box, the battery inner cores can be placed in order conveniently, the placing operation simplicity is improved, the inner core stacking groove is used for isolating two adjacent rows of battery inner cores in each row through the partition plates so as to be beneficial to counting the battery inner cores, the battery inner cores can be counted timely and rapidly according to production requirements, the batteries in each row are pushed forwards through the partition plates between the two adjacent rows of battery inner cores, the battery inner cores in the inner core stacking groove can be pushed in order, and the effects of facilitating counting and conveying the battery inner cores in order are achieved.

Secondly, each row of orderly stacked battery cores in the inner core stacking groove is isolated by each partition plate, so that a plurality of battery cores in each row form an integral unit when moving in the inner core stacking groove, the battery cores in each row are pushed forwards by a partition plate at the last side, the battery cores in each row move forwards, and when the battery cores in the row close to the material discharge port are completely taken, the battery cores in the next row can move forwards. Thereby facilitating the work of the staff.

Thirdly, the battery inner core which is arranged on the bottom surface of the inner core stacking groove and is positioned on the right side of the material spitting opening is dragged to move towards the material spitting opening by the circularly rotating conveying belt, so that the continuous material feeding to the material spitting opening is realized, a pressing plate is hinged on one side of the inner wall of the material spitting opening, the battery inner core in the material spitting opening is pressed and clamped on the material spitting opening by the pressing plate, at the moment, the top end of the battery inner core extends out by more than a half, the battery inner core is very convenient to be manually taken in time, so that the operation simplicity in taking is improved,

fourthly, when the battery inner core is propped by the propping plate in the material spitting port, at the moment, a second motor starting button in the propping plate is in a closed state, when the battery inner core is taken out from the material spitting port, the pressure is lost through the propping plate, at the moment, the second motor starting button is pressed by the second pressing block all the time, the second motor and the first motor are started to work, the battery inner core is conveyed into the material spitting port, when the battery inner core is conveyed into the material spitting port to press the propping plate, at the moment, the second motor and the first motor are powered off, and the battery inner core can be clamped in the material spitting port for a long time, so that a worker can take the battery inner core quickly in time when needing, wherein, after the battery inner core is taken out from the material spitting port, the second pressing block can press the second motor starting button all the time, which is favorable for completely conveying the battery inner core in the battery inner core groove, the technical defect that the battery inner core needs to be manually taken out when the battery inner core is still reserved in the battery inner core groove in the using process in the prior art is overcome.

The concave storage partition plate groove is formed in the front side of the inner wall of the inner core stacking groove, and a plurality of partition plates can be stored in the storage partition plate groove, so that the storage partition plate groove can be collected quickly, continuous supply of battery cores is realized, the conveying efficiency of the battery inner cores is improved, and timely supply of the battery inner cores in the material discharging port is guaranteed.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a process flow diagram of a core stacking method for a battery production line with easy access in accordance with the present invention;

FIG. 2 is a front cross-sectional structural view of the inner core stacking box of the present invention;

FIG. 3 is a schematic top cross-sectional view of an inner core stacking box of the present invention;

FIG. 4 is a schematic top view of the inner core stacking box of the present invention;

FIG. 5 is a schematic left side view of the inner core stacking box of the present invention;

FIG. 6 is an enlarged view of a portion of FIG. 2;

fig. 7 is a schematic structural view of a battery core according to the present invention;

in the figure: 2. an inner core stacking groove; 3. a yielding groove; 4. a support plate; 5. a first cross frame; 6. a first crank; 7. a first motor; 8. a second topping block; 9. an inner core stacking box; 10. a rope pulling groove; 11. pulling a rope; 12. a second motor; 13. a conveyor belt drum; 14. a material spitting platform; 15. a rope winding frame; 16. rope winding grooves; 17. a torsion spring; 18. a second crank; 19. a second motor slot; 20. a partition plate; 21. a storage partition plate groove; 22. a chute; 23. a material discharging port; 24. pressing the plate; 25. a pressure spring; 26. a second motor start button; 27. a second pressing block; 28. a second pressing hole; 29. an ear plate; 30. a lifting shaft lever; 31. and (5) conveying the belt.

Detailed Description

In order to make the technical means, the creation features, the achievement purposes and the effects of the invention easy to understand, the invention is further described below by combining with the specific drawings, and it is to be noted that the embodiments and the features in the embodiments can be combined with each other in the application without conflict.

Referring to fig. 1-7, a core stacking method for a battery production line is provided,

1. the utility model provides a battery production line is with inner core stacking method convenient to take, is applied to on the battery production line, shifts the transport to the inner core on the battery production line, and this battery production line is with inner core stacking method convenient to take specifically includes several following steps:

s1, picking up inner cores: picking up a plurality of battery inner cores at one time by a manipulator from the battery inner cores flowing on a battery production line, and lifting up the picked up inner cores for transferring;

s2, stacking inner cores: orderly stacking the plurality of battery cores picked up by the manipulator in the step S1 in the core stacking device according to rows and columns, and placing a layer of partition plate between two adjacent columns of battery cores in the core stacking device through manual cooperation of the manipulator in the process that the manipulator places the plurality of battery cores in the core stacking device;

s3, taking inner cores: taking the battery cores placed in the core stacking device in the step S2, and arranging and discharging the batteries inside through the core stacking device to enable one of the batteries to extend out of the core stacking device, so that the batteries can be conveniently taken in the production process;

the inner core stacking device described in the above steps S1-S3 includes an inner core stacking box 9, the inner core stacking box 9 is set to be a square box structure, an inner core stacking groove 2 with a square groove structure is provided in the middle of the top end of the inner core stacking box 9, a material spitting table 14 is fixedly installed on the left side of the inner core stacking box 9 and close to the front end of the inner core stacking box 9, a material spitting port 23 is provided in the middle of the top end of the material spitting table 14, and the bottom end of the material spitting port 23 is communicated with the inner core stacking groove 2;

a first motor 7 is fixedly installed at the bottom end of the inner core stacking box 9, a shaft output shaft extends forwards from the first motor 7, a first crank 6 is fixedly installed at the top end of an output shaft of the first motor 7, a through square hole is formed in the bottom end of the material discharge port 23 and is positioned on the bottom surface of the inner core stacking groove 2, a second material pushing block 8 is connected in the square hole in the bottom surface of the inner core stacking groove 2 in a sliding mode, a first transverse frame 5 is fixedly installed at the bottom end of the second material pushing block 8, and the middle of the bottom end of the first transverse frame 5 is connected with the first crank 6 in a sliding mode;

the bottom surface of the inner core stacking box 9 and the front side close to the inner core stacking box 9 are provided with a abdicating groove 3, the abdicating groove 3 is positioned at the right side position of the material discharging port 23 at the bottom surface of the inner core stacking groove 2, a circularly rotating conveyer belt 31 is arranged in the abdicating groove 3, the conveyer belt 31 is a flat belt, the top surface of the conveyer belt 31 is slightly lower than the bottom surface of the inner core stacking groove 2, so that the battery cores can be conveniently transferred to the conveyer belt 31, meanwhile, the battery cores are prevented from being extruded and inclined by a clapboard, the two ends of the inner ring of the conveyer belt 31 are symmetrically provided with conveyer belt rollers 13, the two ends of the conveyer belt roller 13 at each side are rotatably connected with the two sides of the inner wall of the abdicating groove 3 through bearings, one side of the inner wall of the abdicating groove 3 is provided with a second motor groove 19, a second motor 12 is fixedly arranged in the second motor groove 19, the top surface of the supporting plate 4 is a plane, and the two ends of the supporting plate 4 are fixed at the left side and the right side of the abdicating groove 3.

Specifically, the inner core stacking groove 2 with the square groove structure is formed in the top end of the inner core stacking box 9, the inner core stacking groove 2 with the square groove structure is convenient for orderly arranging the battery inner cores, the arrangement operation simplicity is improved, the inner core stacking groove 2 is used for isolating two adjacent rows of battery inner cores in each row through the partition plate 20 so as to be beneficial to counting the battery inner cores, the battery inner cores can be timely and quickly counted according to production requirements, the batteries in each row are pushed forwards through the partition plate 20 between the two adjacent rows of battery inner cores, so that the battery inner cores in the inner core stacking groove 2 are sequentially pushed, the counting is convenient, and the effect of orderly conveying the battery inner cores is achieved.

Specifically, each row of orderly stacked battery cores in the core stacking groove 2 is isolated by each partition plate 20, so that a plurality of battery cores in each row form an integral unit when moving in the core stacking groove 2, the plurality of battery cores in each row are pushed forwards by a last partition plate 20, and the plurality of battery cores in each row move forwards, and when the plurality of battery cores in the row close to the material discharge opening 23 are completely taken out, the plurality of battery cores in the next row can move forwards, the baffle plates in each row are isolated by the partition plates 20, so that the partition plates 20 can move forwards only after the battery cores in the previous row are completely taken out, the taken battery cores are counted conveniently, and the problem that a worker suddenly stops taking the battery cores after continuously taking the battery cores on a production line to cause the counting interruption of the worker is solved, the device is convenient for returning to inquire and recounting, and further is convenient for helping workers to work.

Specifically, the battery inner cores which are arranged on the bottom surface of the inner core stacking groove 2 and are positioned at the right side of the material discharge port 23 are dragged by the circularly rotating conveying belt 31 to move towards the material discharge port 23, so that continuous material supply to the material discharge port 23 is realized.

The left side and the right side of the inner wall of the inner core stacking groove 2 are symmetrically provided with a sunken sliding groove 22 in the middle of the inner wall positioned on the left side and the right side, the sliding grooves 22 on the two sides of the inner core stacking groove 2 are embedded with partition plates 20 at equal intervals in a sliding fit mode, and a plurality of battery inner cores are arranged between every two adjacent partition plates 20 in order;

the left end and the right end of a partition plate 20 positioned at the rear side of the inner core stacking groove 2 are symmetrically provided with convex lug plates 29, the upper end of a sliding groove 22 and the lower end of the sliding groove 22 at each side are symmetrically provided with a rope pulling groove 10, the lug plates 29 at two sides of the partition plate 20 extend into the rope pulling groove 10 in a sliding fit mode, and the top end of the lug plate 29 extending into the rope pulling groove 10 is fixedly provided with a rope pulling buckle;

the inner core pile box 9 is internally provided with rope winding grooves 16 symmetrically arranged on the front side of the inner core stacking groove 2, the rope winding groove 16 on each side is internally rotatably connected with a rope winding frame 15, one end of the rope winding frame 15 is fixedly provided with a torsion spring 17, the torsion spring 17 on one end of the rope winding frame 15 is fixed on one end of the rope winding groove 16, the rope winding frame 15 is wound with a pull rope 11, and the other end of the pull rope 11 on each side penetrates through the pull rope groove 10 and is fixedly connected with a pull rope buckle on the lug plate 29.

The battery inner core is more orderly and uniformly moved in the inner core stacking groove 2 through the isolation of the partition board 20.

The inner wall front side of inner core pile groove 2 is opened and is equipped with sunken storage baffle groove 21, stores up inside the storing up baffle groove 21 and can store many baffles 20.

Specifically, the concave storage partition plate groove 20 is formed in the front side of the inner wall of the inner core stacking groove 2, and a plurality of partition plates 20 can be stored in the storage partition plate groove 20, so that the storage partition plate groove 20 can be rapidly collected, the continuous supply of the battery inner cores is realized, the conveying efficiency of the battery inner cores is improved, and the timely supply of the battery inner cores in the material discharge opening 23 is guaranteed.

One side of the inner wall of the material discharging port 23 is hinged with a pressing plate 24, the bottom end of the pressing plate 24 is hinged with one side of the inner wall of the material discharging port 23, and the middle part of the pressing plate 24 is connected with a lifting shaft rod 30 in a sliding manner;

a second pressing hole 28 is formed in the material discharging platform 14 and close to the material discharging port 23, a second motor starting button 26 is fixedly mounted on one side of the inner wall of the second pressing hole 28, the second motor starting button 26 is a circular ring structure with a circular hole in the middle, and the second motor starting button 26 is electrically connected with the second motor 12 through a cable;

the left end of the lifting shaft rod 30 extends into the material discharging port 23 in a sliding fit mode, the left end of the lifting shaft rod 30 extending into the material discharging port 23 penetrates through a round hole of the second motor starting button 26, and the left end of the lifting shaft rod 30 extending into the material discharging port 23 is fixedly provided with a second pressing block 27 of a circular ring structure.

Specifically, when the battery core is pushed by the pushing plate 24 in the material discharge port 23, at this time, the second motor start button 26 in the pushing plate 24 is in a closed state, when the battery core is taken out from the material discharge port 23, the pushing plate 24 loses pressure, at this time, the second pushing block 27 always pushes the second motor start button 26, the second motor 12 and the first motor 7 are started to work, the battery core is conveyed into the material discharge port 23, when the pushing plate 24 is pushed in the material discharge port 23, at this time, the second motor 12 and the first motor 7 are powered off, and further the battery core can be clamped in the material discharge port 23 for a long time, so that a worker can timely and quickly take the battery core when needing, wherein, after the battery core is taken out from the material discharge port 23, the second pushing block 27 always pushes the second motor start button 26, the battery inner core conveying device is beneficial to conveying all the battery inner cores in the battery inner core groove, and the technical defect that the battery inner cores need to be manually taken out and are still reserved in the battery inner core groove in the using process in the prior art is overcome.

The working principle is as follows: when the inner core stacking device is used, firstly, the battery inner cores are orderly stacked in the inner core stacking groove 2 formed in the top end of the inner core stacking box 9, the inner core stacking groove 2 isolates two adjacent rows of the battery inner cores in each row through the partition plates 20 to facilitate counting of the battery inner cores, the battery inner cores are conveniently and rapidly counted in time according to production requirements, the batteries in each row are pushed forwards through the partition plates 20 between the two adjacent rows of the battery inner cores, the battery inner cores in the inner core stacking groove 2 are conveniently and orderly pushed, and the effects of facilitating counting and orderly conveying the battery inner cores are achieved.

The invention separates each row of orderly stacked battery cores in the inner core stacking groove 2 through each clapboard 20, so that a plurality of battery cores in each row form an integral unit when moving in the inner core stacking groove 2, the plurality of battery cores in each row move forwards by pushing a clapboard 20 at the last side, and when the plurality of battery cores in the row close to the material discharge opening 23 are completely taken, the plurality of battery cores in the next row can move forwards, the invention separates each row through the clapboard 20, so that the clapboard 20 can move forwards only after the battery cores in the previous row are completely taken, thereby being convenient for counting the taken battery cores, avoiding the phenomenon that a worker suddenly stops taking the battery cores after the battery cores are continuously taken on a production line, causing the counting interruption of the worker, and being convenient for back query and recounting, thereby facilitating the work of the staff.

The battery inner core which is arranged on the bottom surface of the inner core stacking groove 2 and is positioned at the right side position of the material discharge port 23 is dragged by the conveying belt 31 which rotates circularly to move towards the material discharge port 23, so that continuous feeding to the material discharge port 23 is realized.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are given by way of illustration of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (4)

1. The utility model provides a battery production line is with inner core stacking method convenient to take, is applied to on the battery production line, shifts the transport to the inner core on the battery production line, its characterized in that, this battery production line is with inner core stacking method convenient to take, specifically includes several following steps:

s1, picking up inner cores: picking up a plurality of battery inner cores at one time by a manipulator from the battery inner cores flowing on a battery production line, and lifting up the picked up inner cores for transferring;

s2, stacking inner cores: orderly stacking the plurality of battery cores picked up by the manipulator in the step S1 in the core stacking device according to rows and columns, and placing a layer of partition plate between two adjacent columns of battery cores in the core stacking device through manual cooperation of the manipulator in the process that the manipulator places the plurality of battery cores in the core stacking device;

s3, taking inner cores: taking the battery cores placed in the core stacking device in the step S2, and arranging and discharging the batteries inside through the core stacking device to enable one of the batteries to extend out of the core stacking device, so that the batteries can be conveniently taken in the production process;

the inner core stacking device in the steps S1-S3 includes an inner core stacking box, the inner core stacking box is set to be a square box structure, an inner core stacking groove with a square groove structure is formed in the middle of the top end of the inner core stacking box, a material spitting table is fixedly mounted on the left side of the inner core stacking box and close to the front end of the inner core stacking box, a material spitting port is formed in the middle of the top end of the material spitting table, and the bottom end of the material spitting port is communicated with the inner core stacking groove;

a first motor is fixedly installed at the bottom end of the inner core stacking box, a shaft outlet shaft extends forwards from the first motor, a first crank is fixedly installed at the top end of an output shaft of the first motor, a through square hole is formed in the bottom end of the material discharging opening and is located at the bottom surface of the inner core stacking groove, a second material pushing block is connected in the square hole in the bottom surface of the inner core stacking groove in a sliding mode, a first transverse frame is fixedly installed at the bottom end of the second material pushing block, and the middle of the bottom end of the first transverse frame is connected with the first crank in a sliding mode;

a abdicating groove is arranged on the bottom surface of the inner core stacking box and close to the front side of the inner core stacking box, the abdicating groove is positioned on the right side of the material discharging port on the bottom surface of the inner core stacking groove, the inside of the abdicating groove is provided with a circularly rotating conveying belt which is a flat belt, the top surface of the conveying belt is slightly lower than the bottom surface of the inner core stacking groove, two ends of the inner ring of the conveying belt are symmetrically provided with conveying belt rollers, two ends of the conveying belt roller on each side are rotatably connected with two sides of the inner wall of the abdicating groove through bearings, a second motor groove is arranged on one side of the inner wall of the abdicating groove, a second motor is fixedly arranged in the second motor groove, wherein the conveyer belt roller on one side is fixedly connected with an output shaft of the second motor, a support plate is arranged in the middle of the inner ring of the conveyer belt, the top surface of backup pad is the plane, the both ends of backup pad are fixed in the left and right sides in groove 3 of stepping down.

2. The method for stacking inner cores for a battery production line, which is convenient to take, according to claim 1, wherein the method comprises the following steps: the inner core stacking groove is characterized in that the left side and the right side of the inner wall of the inner core stacking groove are symmetrically provided with sunken sliding grooves in the middle of the inner walls at the left side and the right side, partition plates are embedded into the sliding grooves at the two sides of the inner core stacking groove at equal intervals in a sliding fit mode, and a plurality of battery inner cores are arranged between every two adjacent partition plates in order;

the left end and the right end of one partition plate positioned at the rear side of the inner core stacking groove are symmetrically provided with convex lug plates, the upper end of the sliding groove and the lower end of the sliding groove at each side are symmetrically provided with a pull rope groove, the lug plates at the two sides of the partition plate extend into the pull rope groove in a sliding fit mode, and the top end of the lug plate extending into the pull rope groove is fixedly provided with a pull rope buckle;

the inner core stacking box is characterized in that rope winding grooves are symmetrically formed in the inner core stacking box and located in the front side of the inner core stacking groove, a rope winding frame is rotatably connected to the inner portion of each rope winding groove, a torsion spring is fixedly arranged at one end of each rope winding frame, the torsion spring at one end of each rope winding frame is fixed to one end of each rope winding groove, a pull rope is wound on each rope winding frame, and the other end of each pull rope penetrates through the pull rope groove and is fixedly connected with a pull rope buckle on the lug plate.

3. The method for stacking cores for a battery production line, which is convenient to take, according to claim 2, wherein the method comprises the following steps: the inner wall front side in inner core pile-up groove is opened and is equipped with sunken storage baffle groove, store up baffle inslot portion and store many baffles.

4. The method for stacking inner cores for a battery production line, which is convenient to take, according to claim 1, wherein the method comprises the following steps: one side of the inner wall of the material discharging port is hinged with a pressing plate, the bottom end of the pressing plate is hinged to one side of the inner wall of the material discharging port, and the middle part of the pressing plate is connected with a lifting shaft rod in a sliding manner;

a second pressing hole is formed in the material spitting platform and close to the material spitting opening, a second motor starting button is fixedly mounted on one side of the inner wall of the second pressing hole, the second motor starting button is of a circular ring structure with a circular hole in the middle, and the second motor starting button is electrically connected with the second motor through a cable;

the left end of the lifting shaft rod stretches into the material spitting opening in a sliding fit mode, stretches into the material spitting opening, the left end of the lifting shaft rod penetrates through a round hole of a second motor starting button, and stretches into the material spitting opening, and a second pressing block of a circular ring structure is fixedly arranged at the left end of the lifting shaft rod.

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