CN116081250A - Cell centering and positioning device for new energy battery cell production - Google Patents

Abstract

The utility model provides a cell centering and positioning device for producing a new energy battery cell, which comprises a first conveying belt, a centering and positioning mechanism connected with a discharge end of the first conveying belt, and a second conveying belt connected with the discharge end of the centering and positioning mechanism; the centering and positioning mechanism comprises a positioning box sleeved outside one end of the first conveying belt, a core pushing assembly connected to the bottom end inside the positioning box, and a clamping and positioning assembly connected to the top end inside the positioning box; the clamping and positioning assembly comprises a plurality of sandwich components which are connected with the positioning box and are arranged around the positioning box, unidirectional core bearing components which are arranged at two ends of the inner part of the positioning box, and core lifting components which are arranged at two sides of the unidirectional core bearing components. The utility model can stack and convey the battery cells so as to facilitate the centering and positioning of the battery cells for many times.

Description

Cell centering and positioning device for new energy battery cell production

Technical Field

The utility model mainly relates to the technical field of battery cells, in particular to a cell centering and positioning device for new energy battery cell production.

Background

In the production process of the battery cell of the new energy battery, the new energy battery is often required to be centered and positioned so as to accurately place the battery cell in the tray in the follow-up process.

According to a centering and clamping mechanism for a battery cell provided in patent document with application number of CN201822060050.5, the centering and positioning mechanism comprises a supporting table, a supporting plate arranged in the middle of the top surface of the supporting table, two positioning blocks arranged at intervals, a first clamping device and a second clamping device, wherein the positioning blocks are detachably connected to one side of the supporting table, the second clamping device is arranged on the other side of the supporting table, the first clamping device is used for clamping two sides of the battery cell with the center as a reference, and the second clamping device is used for positioning and clamping the battery cell; according to the utility model, the clamping assemblies are symmetrically arranged on two sides of the supporting plate, and the two clamping assemblies are automatically clamped from two sides of the battery cell under the action of the elastic force of the two tension springs, so that the battery cell is clamped by taking the center as a reference, and then the battery cell is positioned and clamped by matching with the second clamping device, the subsequent processing precision of the battery cell is improved, the error is reduced, the production efficiency is improved, and the automatic production is applicable.

Above-mentioned electric core centering positioning mechanism realizes using the center as the centre to press from both sides tight electric core, and cooperation second clamping device is pressed from both sides tight with electric core location, improves the follow-up machining precision of electric core, but traditional electric core centering positioning mechanism promotes the locating plate through the cylinder and carries out the centering location after, begins the transportation of battery electric core promptly, and this mode can not reserve the time of correcting battery electric core well, influences centering positioning efficiency.

Disclosure of Invention

The utility model mainly provides a cell centering and positioning device for producing a new energy battery cell, which is used for solving the technical problems in the background technology.

The technical scheme adopted for solving the technical problems is as follows:

the battery cell centering and positioning device for the production of the battery cells of the new energy sources comprises a first conveying belt, a centering and positioning mechanism connected with the discharge end of the first conveying belt, and a second conveying belt connected with the discharge end of the centering and positioning mechanism;

the centering and positioning mechanism comprises a positioning box sleeved outside one end of the first conveying belt, a core pushing assembly connected to the bottom end inside the positioning box, and a clamping and positioning assembly connected to the top end inside the positioning box;

the clamping and positioning assembly comprises a plurality of sandwich components which are connected with the positioning box and are arranged around the positioning box, unidirectional core bearing components which are arranged at two ends of the inner part of the positioning box, and core lifting components which are arranged at two sides of the unidirectional core bearing components;

the lifting core part comprises two belt pulleys which are connected with the positioning box in a rotating way through a rotating shaft and are sequentially arranged from top to bottom, a belt connected with the two belt pulleys, and a lifting core plate arranged on the outer surface of the belt.

In the utility model, the piston rod of the oil cylinder drives the core pushing plate to lift, and the core pushing plate pushes the battery cells conveyed by the first conveying belt to lift, so that the battery cells enter the top end of the positioning box to be centered, positioned and tidied by the clamping positioning assembly.

Further, the sandwich component comprises an electric push rod arranged on the outer surface of the positioning box, and a sandwich board is connected with the execution end of the electric push rod.

Further, the unidirectional bearing core part comprises a plurality of rotating shafts which are arranged in the positioning box and are sequentially arranged from top to bottom, a rotating bearing core block which is rotationally connected with two ends of the rotating shafts, and a termination shaft which is abutted against the upper surface of one end of the rotating bearing core block and is arranged in the positioning box.

Further, one end of the rotary bearing core block is inserted with a rotary cylinder, the rotary bearing core block is rotationally connected with the rotary shaft through the rotary cylinder, and when negative pressure is generated in the rotary joint, negative pressure is generated in a first negative pressure pipe connected with the rotary joint, so that the first negative pressure pipe is connected with a negative pressure head, and the battery cell is moved to the top end of the rotary bearing core block.

Further, a negative pressure head is embedded in the shell of the rotary bearing core block, the air inlet end of the negative pressure head is connected with a first negative pressure pipe, and the air inlet end of the first negative pressure pipe is connected with a rotary joint.

Further, the outer surface of the positioning box is connected with a plurality of second negative pressure pipes, the second negative pressure pipes are connected with a plurality of rotary joints at the same end, and in the utility model, the inside of the rotary joints is negative pressure through the second negative pressure pipes connected with the negative pressure fan.

Furthermore, an opening is formed in one side of the positioning box, and the battery cells penetrate through the opening, so that the battery cells subjected to centering positioning can be moved onto a second conveying belt provided with a tray through a mechanical arm.

Further, a manipulator is arranged on the upper surface of the second conveying belt.

Further, an exhaust pipe is installed on the surface of one end of the inside of the positioning box, and a plasma air nozzle is connected to the top end of the exhaust pipe.

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

firstly, the utility model can stack and convey battery cells so as to facilitate the multi-centering positioning of the battery cells, and specifically comprises the following steps: the electric push rod drives the sandwich plate connected with the electric push rod to translate so as to center and position the battery cells through the mutual approaching of the sandwich plates arranged at the opposite ends of the positioning box.

According to the utility model, the piston rod of the oil cylinder drives the core pushing plate to lift, and the core pushing plate pushes the battery cells conveyed by the first conveying belt to lift, so that the battery cells enter the top end of the positioning box to be centered, positioned and tidied through the clamping positioning assembly.

The utility model will be explained in detail below with reference to the drawings and specific embodiments.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a cross-sectional view of the present utility model;

FIG. 3 is an enlarged view of the structure of the area A in FIG. 2;

FIG. 4 is a schematic view of the clamping and positioning assembly of the present utility model;

FIG. 5 is a schematic view of the structure of the positioning box of the present utility model;

FIG. 6 is a cross-sectional view of a rotary bearing core of the present utility model;

FIG. 7 is a schematic view of the centering mechanism and the second conveyor belt of the present utility model;

fig. 8 is a top view of the present utility model.

In the figure: 10. a first conveyor belt; 20. centering and positioning mechanism; 21. a positioning box; 212. an exhaust pipe; 213. a plasma tuyere; 22. a push core assembly; 221. an oil cylinder; 222. pushing the core plate; 23. clamping and positioning components; 231. a sandwich component; 2311. an electric push rod; 2312. a sandwich panel; 232. a unidirectional core bearing component; 2321. a rotation shaft; 2322. rotating the bearing core block; 2323. terminating the shaft; 2324. a rotating cylinder; 2325. a negative pressure head; 2326. a first negative pressure pipe; 2327. a rotary joint; 2328. a second negative pressure pipe; 233. a core lifting component; 2331. a belt pulley; 2332. a belt; 2333. a core lifting plate; 30. a second conveyor belt; 31. and a manipulator.

Detailed Description

In order that the utility model may be more fully understood, a more particular description of the utility model will be rendered by reference to the appended drawings, in which several embodiments of the utility model are illustrated, but which may be embodied in different forms and are not limited to the embodiments described herein, which are, on the contrary, provided to provide a more thorough and complete disclosure of the utility model.

It will be understood that when an element is referred to as being "mounted" on another element, it can be directly on the other element or intervening elements may be present, and when an element is referred to as being "connected" to the other element, it may be directly connected to the other element or intervening elements may also be present, the terms "vertical", "horizontal", "left", "right" and the like are used herein for the purpose of illustration only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs, and the terms used herein in this description of the utility model are for the purpose of describing particular embodiments only and are not intended to be limiting of the utility model, with the term "and/or" as used herein including any and all combinations of one or more of the associated listed items.

Referring to fig. 1-8, a cell centering and positioning device for producing a new energy cell includes a first conveyor belt 10, a centering and positioning mechanism 20 connected to a discharge end of the first conveyor belt 10, and a second conveyor belt 30 connected to a discharge end of the centering and positioning mechanism 20;

the centering and positioning mechanism 20 comprises a positioning box 21 sleeved outside one end of the first conveyor belt 10, a pushing core assembly 22 connected to the bottom end inside the positioning box 21, and a clamping and positioning assembly 23 connected to the top end inside the positioning box 21;

the clamping and positioning assembly 23 comprises a plurality of core-clamping components 231 which are connected with the positioning box 21 and are arranged around the positioning box 21, unidirectional core-supporting components 232 which are arranged at two ends inside the positioning box 21, and core-lifting components 233 which are arranged at two sides of the unidirectional core-supporting components 232;

the core lifting member 233 comprises two belt pulleys 2331 which are rotatably connected with the positioning box 21 through a rotating shaft and are sequentially arranged from top to bottom, a belt 2332 connected with the two belt pulleys 2331, and a core lifting plate 2333 arranged on the outer surface of the belt 2332.

Specifically, referring to fig. 1 and 2, the core pushing assembly 22 includes an oil cylinder 221 installed inside the positioning box 21, and a core pushing plate 222 installed on a piston rod of the oil cylinder 221;

the core member 231 includes an electric push rod 2311 mounted on the outer surface of the positioning box 21, and a sandwich plate 2312 is connected to the actuating end of the electric push rod 2311;

in this embodiment, the piston rod of the oil cylinder 221 drives the push core plate 222 to lift, and the push core plate 222 pushes the battery cells conveyed by the first conveyor belt 10 to lift, so that the battery cells enter the top end of the positioning box 21 and are centered, positioned and arranged by the clamping and positioning assembly 23, and in this way, the battery cells can be conveyed to be positioned under the condition that the first conveyor belt 10 does not stop working, so that the time waiting for centering and positioning due to the stop working of the first conveyor belt 10 is reduced, and the centering and positioning efficiency of the battery cells is improved;

further, the electric push rod 2311 drives the sandwich plate 2312 connected with the electric push rod 2311 to translate, so that the battery cells are centered and positioned through the mutual approaching of the sandwich plates 2312 arranged at the opposite ends of the positioning box 21, and the battery cells ascend step by step along the plurality of rotary bearing blocks 2322, so that the battery cells are positioned for a plurality of times through the sandwich plates 2312.

Specifically, referring to fig. 2 and 3, the unidirectional bearing core 232 includes a plurality of rotating shafts 2321 mounted inside the positioning box 21 and sequentially arranged from top to bottom, a rotating bearing core 2322 rotatably connected to two ends of the rotating shaft 2321, and a terminating shaft 2323 abutting against an upper surface of one end of the rotating bearing core 2322 and mounted inside the positioning box 21;

it should be noted that, in this embodiment, the rotation bearing core 2322 is pushed by the lifted battery cell, so that the rotation bearing core 2322 rotates with the rotation shaft 2321 as the rotation center, until the distance between the two rotation bearing core 2322 at opposite ends is enough for the battery cell to pass through, and when the battery cell descends, the rotation bearing core 2322 is pressed by the battery cell, so that the rotation bearing core 2322 rotates to a state of abutting against the termination shaft 2323, and thus the rotation bearing core 2322 is utilized to bear the battery cells ascending one by one, so as to keep the battery cell from falling;

in the process of the battery cell ascending step by step, the battery cell inserted between the lifting core plate 2333 and the rotating core supporting block 2322 is pushed to keep the process of the battery cell ascending step by step, and the belt 2332 is kept stable in operation through the connection of the motor output shaft and the belt pulley 2331, so that the battery cell clamped between the rotating core supporting block 2322 and the lifting core plate 2333 is kept stable in posture, and the motor is connected with the encoder and the controller, so that the controller connected with the encoder can effectively control the operation of the motor.

Specifically, referring to fig. 4 and 6, a rotating cylinder 2324 is inserted into one end of the rotating bearing core 2322, and the rotating bearing core 2322 is rotationally connected with the rotating shaft 2321 through the rotating cylinder 2324;

a negative pressure head 2325 is embedded in the shell of the rotary bearing core block 2322, an air inlet end of the negative pressure head 2325 is connected with a first negative pressure pipe 2326, and an air inlet end of the first negative pressure pipe 2326 is connected with a rotary joint 2327;

the outer surface of the positioning box 21 is connected with a plurality of second negative pressure pipes 2328, and the second negative pressure pipes 2328 are connected with a plurality of rotary joints 2327 at the same end;

it should be noted that, in the embodiment, when negative pressure is generated inside the rotary joint 2327, negative pressure is generated inside the first negative pressure pipe 2326 connected to the rotary joint 2327, so that the first negative pressure pipe 2326 is connected to the negative pressure head 2325, so that after the battery cell moves to the top end of the rotary core supporting block 2322 and the battery cell is centered and positioned, the battery cell is adsorbed by the negative pressure head 2325, and displacement of the battery cell is reduced;

further, by the arrangement of the rotary joint 2327, when the rotary bearing core block 2322 rotates on the rotary shaft 2321 through the rotary cylinder 2324, the communication between the negative pressure head 2325 and the first negative pressure pipe 2326 in the rotary bearing core block can still be maintained;

further, the inside of the rotary joint 2327 is under negative pressure by a second negative pressure pipe 2328 connected with the negative pressure fan.

Specifically, referring to fig. 1 and 5, an opening 211 is formed on one side of the positioning box 21;

the upper surface of the second conveyor belt 30 is provided with a manipulator 31;

an exhaust pipe 212 is arranged on one surface of the inner end of the positioning box 21, and a plasma tuyere 213 is connected to the top end of the exhaust pipe 212;

in this embodiment, the opening 211 is used to pass through the battery cell, so that the battery cell that is centered and positioned is moved onto the second conveyor belt 30 with the tray by the manipulator 31;

further, the exhaust pipe 212 is supplied with air through the plasma nozzle 213, and the positive and negative charged air mass discharged through the exhaust pipe 212 eliminates static electricity on the surface of the battery cells and removes ash through the air mass, and at the same time, the effect of the blown air mass is enhanced through the gaps of the stacked battery cells.

The specific operation mode of the utility model is as follows:

when the battery cells are placed in the tray, a worker or a manipulator places the battery cells in the first conveying belt 10, the battery cells are conveyed by the first conveying belt 10 and enter the positioning box 21, the piston rod of the oil cylinder 221 drives the push core plate 222 to lift, the battery cells conveyed by the first conveying belt 10 are pushed by the push core plate 222 to lift, so that the battery cells enter the top end of the positioning box 21 to be centered, positioned and tidied by the clamping positioning assembly 23, and the battery cells can be conveyed to be positioned under the condition that the first conveying belt 10 does not stop working, so that the time waiting for centering positioning due to the stop of the first conveying belt 10 is reduced, and the centering positioning efficiency of the battery cells is improved;

the rotary bearing core blocks 2322 are pushed by the lifted battery cells so that the rotary bearing core blocks 2322 rotate by taking the rotary shaft 2321 as a rotary center until the distance between the two rotary bearing core blocks 2322 at opposite ends is enough for the battery cells to pass through, and when the battery cells descend, the rotary bearing core blocks 2322 are pressed by the battery cells so that the rotary bearing core blocks 2322 rotate to a state of being abutted against the stop shaft 2323, and accordingly the rotary bearing core blocks 2322 are utilized to bear the battery cells which ascend one by one, and the battery cells are kept from falling;

the electric push rod 2311 drives the sandwich plate 2312 connected with the electric push rod 2311 to translate so as to center and position the battery cells through mutual approaching of the sandwich plates 2312 arranged at opposite ends of the positioning box 21, and the battery cells ascend step by step along the plurality of rotary bearing core blocks 2322, so that the battery cells are positioned for multiple times through the sandwich plates 2312;

the battery cells pass through the opening 211 so as to be moved onto the second conveyor belt 30 with the trays by the robot 31, wherein the battery cells are centered.

While the utility model has been described above with reference to the accompanying drawings, it will be apparent that the utility model is not limited to the embodiments described above, but is intended to be within the scope of the utility model, as long as such insubstantial modifications are made by the method concepts and technical solutions of the utility model, or the concepts and technical solutions of the utility model are applied directly to other occasions without any modifications.

Claims (10)

1. The cell centering and positioning device for the production of the new energy battery cells is characterized by comprising a first conveying belt (10), a centering and positioning mechanism (20) connected with the discharge end of the first conveying belt (10), and a second conveying belt (30) connected with the discharge end of the centering and positioning mechanism (20);

the centering and positioning mechanism (20) comprises a positioning box (21) sleeved outside one end of the first conveying belt (10), a core pushing assembly (22) connected to the bottom end inside the positioning box (21), and a clamping and positioning assembly (23) connected to the top end inside the positioning box (21);

the clamping and positioning assembly (23) comprises a plurality of sandwich components (231) which are connected with the positioning box (21) and are arranged around the positioning box (21), unidirectional core bearing components (232) which are arranged at two ends inside the positioning box (21), and core lifting components (233) which are arranged at two sides of the unidirectional core bearing components (232);

the core lifting component (233) comprises two belt pulleys (2331) which are connected with the positioning box (21) in a rotating mode through a rotating shaft and are sequentially arranged from top to bottom, a belt (2332) connected with the two belt pulleys (2331), and a core lifting plate (2333) arranged on the outer surface of the belt (2332).

2. The cell centering and positioning device for producing a new energy battery cell according to claim 1, wherein the core pushing assembly (22) comprises an oil cylinder (221) installed inside the positioning box (21), and a core pushing plate (222) installed on a piston rod of the oil cylinder (221).

3. The cell centering and positioning device for producing a new energy battery cell according to claim 1, wherein the core member (231) comprises an electric push rod (2311) mounted on the outer surface of the positioning box (21), and a sandwich board (2312) is connected with an execution end of the electric push rod (2311).

4. The cell centering and positioning device for producing a new energy battery cell according to claim 1, wherein the unidirectional bearing core component (232) comprises a plurality of rotating shafts (2321) which are installed inside the positioning box (21) and are sequentially arranged from top to bottom, rotating bearing core blocks (2322) which are rotationally connected with two ends of the rotating shafts (2321), and a termination shaft (2323) which is abutted with the upper surface of one end of the rotating bearing core blocks (2322) and is installed inside the positioning box (21).

5. The cell centering and positioning device for new energy battery cell production according to claim 4, wherein a rotating cylinder (2324) is inserted into one end of the rotating bearing core block (2322), and the rotating bearing core block (2322) is rotationally connected with the rotating shaft (2321) through the rotating cylinder (2324).

6. The cell centering and positioning device for new energy battery cell production according to claim 5, wherein a negative pressure head (2325) is embedded in a shell of the rotary bearing core block (2322), an air inlet end of the negative pressure head (2325) is connected with a first negative pressure pipe (2326), and an air inlet end of the first negative pressure pipe (2326) is connected with a rotary joint (2327).

7. The cell centering and positioning device for new energy battery cell production according to claim 6, wherein a plurality of second negative pressure pipes (2328) are connected to the outer surface of the positioning box (21), and the second negative pressure pipes (2328) are connected to a plurality of rotary joints (2327) at the same end.

8. The cell centering and positioning device for producing the new energy battery cells according to claim 1, wherein an opening (211) is arranged on one side of the positioning box (21).

9. The cell centering and positioning device for new energy battery cell production according to claim 1, wherein a manipulator (31) is mounted on the upper surface of the second conveyor belt (30).

10. The cell centering and positioning device for new energy battery cell production according to claim 1, wherein an exhaust pipe (212) is installed on one surface of the inner end of the positioning box (21), and a plasma tuyere (213) is connected to the top end of the exhaust pipe (212).

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