CN116031425A - Automatic production line of button lithium-manganese battery - Google Patents

Abstract

The invention relates to the technical field of automation, in particular to an automatic production line of a button lithium-manganese battery, which comprises a working cabinet, a feeding mechanism, a polishing processing assembly and a button piece tool mechanism, wherein a delivery guide rail and an output conveyor belt are fixedly arranged in the working cabinet, the output conveyor belt and the feeding mechanism are symmetrically distributed on two sides of the polishing processing assembly and are arranged in the vertical direction of the delivery guide rail, the feeding mechanism, the polishing processing assembly and the button piece tool mechanism are fixedly arranged in the working cabinet, and the output end of the delivery guide rail is fixedly connected with a finger cylinder which is vertically and downwards arranged. Through adopting many automation mechanized operation structures to carry out integral type worker assembly and close, utilize feed mechanism, delivery guide rail, throw and grind processing subassembly, cramp frock mechanism and output conveyer belt to carry out the material loading pay-off of battery negative pole cramp bottom respectively, frock throws and grinds and output, accomplishes whole battery cramp material loading and throws and grinds and output work, and retrograde automation pipelined production, need not personnel on duty and improves work efficiency.

Description

Automatic production line of button lithium-manganese battery

Technical Field

The invention relates to the technical field of automation, in particular to an automatic production line of a button lithium-manganese battery.

Background

The lithium-manganese button cell is a type of cell with lithium as the negative electrode and manganese dioxide as the positive electrode. The manganese dioxide battery has the advantages of good low-rate and medium-rate discharge performance, low price, good safety performance, competitive power compared with the conventional battery, very large use amount and reliable performance, is popular with consumers, is widely applied to various electronic products, and adopts an automatic production line in the processing process of the lithium-manganese button battery for realizing automation.

The existing button lithium-manganese battery automatic production line mainly comprises the steps of manually placing button sheets on the surface of a tray one by one in the fine polishing work of the button sheets of the battery anode, driving a large number of button sheets to be polished to uniform thickness and surface smoothness by the tray under the work of a polishing machine head, placing the button sheets one by one in a tray clamping groove and fixing the button sheets through a clamping assembly in the swinging plate work, and the operation is complicated, wherein the general maximum yield of the existing manual production mode is about ten thousand, and the processing of a large number of lithium-manganese batteries cannot be met.

In view of the above, the present invention provides an automated production line for lithium-manganese button cells, which solves the problem of complicated operation and limited yield, and aims to solve the problem and improve the practical value.

Disclosure of Invention

The present invention aims to solve one of the technical problems existing in the prior art or related technologies.

The technical scheme adopted by the invention is as follows: an automated production line for button lithium-manganese batteries, comprising: the polishing and grinding machine comprises a working cabinet, a feeding mechanism, a polishing and grinding assembly and a cramp tool mechanism, wherein a material conveying guide rail and an output conveyor belt are fixedly arranged in the working cabinet, the output conveyor belt and the feeding mechanism are symmetrically distributed on two sides of the polishing and grinding assembly and are arranged in the vertical direction of the material conveying guide rail, the feeding mechanism, the polishing and grinding assembly and the cramp tool mechanism are fixedly arranged in the working cabinet, and the output end of the material conveying guide rail is fixedly connected with a finger cylinder which is vertically downwards arranged;

the feeding mechanism comprises a fixed seat, a material tray, a feeding ladder, a feeding motor and a linear oscillator fixedly arranged on the bottom surface of the feeding ladder, wherein the material tray is fixedly arranged on one side of the fixed seat and is positioned in the same vertical plane with the finger cylinder and the buckle piece tool mechanism, an elastic supporting plate fixedly connected with the surface of the fixed seat is fixedly arranged on the bottom surface of the feeding ladder, the feeding motor is fixedly arranged on one side of the fixed seat and the output end of the feeding motor is fixedly provided with a collecting plate, a hopper sleeved on the surface of the fixed seat is fixedly arranged on the inner side of the working cabinet, a magnetic induction guide cylinder is movably arranged in the linear oscillator, one end of the magnetic induction guide cylinder is fixedly connected with a damper fixed on the bottom surface of the feeding ladder, a moving magnetic block is slidably arranged on the inner side of the magnetic induction guide cylinder, and a plurality of exciting coils are fixedly sleeved on the surface of the magnetic induction guide cylinder;

the cramp frock mechanism includes rail platform and frock positioning seat, rail platform's output fixed mounting has slidable mounting in the motion seat of rail platform top surface, the inboard fixed mounting of motion seat has rotatory steering wheel, the output of rotatory steering wheel and the top surface fixed connection of frock positioning seat, the surface mounting of frock positioning seat has the driving disc and slidable mounting has the chuck, the transmission groove has been seted up on the output of driving disc and the surface of disc, the one end fixed mounting of chuck cup joints in the inboard pin of transmission groove.

The present invention may be further configured in a preferred example to: the material conveying guide rail is one of an electromagnetic guide rail and a screw rod guide rail, the number of the finger air cylinders is two, and the output ends of the finger air cylinders are fixedly provided with material sucking heads.

The present invention may be further configured in a preferred example to: the end part of the exciting coil is electrically connected with a current generator, the moving magnet is positioned at the inner side of the exciting coil, the damper is a damping telescopic rod, and the surface of the damper is fixedly sleeved with a spring.

The present invention may be further configured in a preferred example to: the surface of charging tray is equipped with material sensor, material sensor's output and the input electric connection of controller, the output and feed mechanism, delivery guide rail, cramp frock mechanism's of controller input electric connection.

The present invention may be further configured in a preferred example to: the elastic supporting plate is of an elastic metal plate structure, a plurality of grid holes are formed in the surface of the elastic supporting plate, the feeding ladder is obliquely arranged, and a plurality of guiding steps are arranged on the surface of the feeding ladder.

The present invention may be further configured in a preferred example to: the polishing and grinding processing assembly comprises a first driving table, a second driving table and a polishing machine, wherein the surface of the second driving table is rotatably provided with a deflection table, the polishing machine is fixedly arranged on the bottom surface of the deflection table, the surface of the first driving table is provided with a driving assembly for driving the deflection table to deflect, and the second driving table is slidably arranged on the surface of the first driving table.

The present invention may be further configured in a preferred example to: the polishing machine is of an abrasive belt polishing machine structure.

The present invention may be further configured in a preferred example to: the surface of frock positioning seat is equipped with the frock trench, the quantity of chuck is a plurality of and is the circumferencial direction and arrange in the periphery of frock trench, the transmission groove is arc structure and both ends are different from driving disk centre of a circle distance.

The beneficial effects obtained by the invention are as follows:

1. according to the invention, by adopting a multi-automation operation structure to carry out integral type work assembly and closing, the feeding mechanism, the material conveying guide rail, the polishing and grinding processing assembly, the buckle piece tooling mechanism and the output conveyor belt are utilized to respectively carry out feeding, tooling polishing and outputting of the battery negative buckle piece bottom cover, so that the whole battery buckle piece feeding polishing and outputting work and retrograde automation assembly line type production are completed, and the working efficiency is improved without personnel on duty.

2. According to the invention, by arranging the novel automatic feeding component structure, the alternating magnetic field is generated by electrifying the exciting coil in the linear oscillator to drive the moving magnetic block to reciprocate in the magnetic induction guide cylinder to generate impact kinetic energy, so that the linear vibration of the whole linear oscillator and the feeding ladder is realized, the bottom covers are conveyed one by one, and the feeding guide rail and the finger cylinder are used for feeding one by one, so that the automatic feeding is realized.

3. According to the invention, by arranging the novel tool positioning structure, after the feeding mechanism and the feeding guide rail feed materials one by one, the end part of the chuck is tightly abutted and fixed on the edge of the buckle piece bottom cover under the rotary drive of the driving disc, so that the automatic tool clamping is realized, the tool positioning efficiency of the bottom cover is quickened, and the yield is improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present invention;

FIG. 2 is a schematic view of the internal structure of a working cabinet according to an embodiment of the invention;

FIG. 3 is a schematic view of a polishing assembly and cleat tooling mechanism according to one embodiment of the present invention;

FIG. 4 is a schematic view of a surface structure of a fixture positioning seat according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a feeding mechanism according to an embodiment of the present invention;

FIG. 6 is a schematic diagram of a loading ladder mounting structure according to an embodiment of the invention;

FIG. 7 is a schematic cross-sectional view of a linear oscillator according to an embodiment of the present invention;

fig. 8 is an exploded view of a linear oscillator according to an embodiment of the present invention.

Reference numerals:

100. a working cabinet; 110. a delivery guide rail; 120. an output conveyor belt; 111. a finger cylinder; 112. a suction head;

200. a feeding mechanism; 210. a fixing seat; 220. a material tray; 230. a feeding ladder; 240. a feeding motor; 250. a linear oscillator; 231. an elastic support plate; 232. a material guiding step; 241. a collecting plate; 251. a magnetically permeable cartridge; 252. a damper; 253. an exciting coil; 254. a moving magnetic block;

300. polishing and grinding the processing assembly; 310. a first drive stage; 320. a second drive stage; 330. polishing machine; 321. a deflection table;

400. a cramp tooling mechanism; 410. a transverse rail table; 420. a tool positioning seat; 411. a motion seat; 412. rotating a steering engine; 421. a chuck; 422. a drive plate; 423. a transmission groove.

Detailed Description

The objects, technical solutions and advantages of the present invention will become more apparent by the following detailed description of the present invention with reference to the accompanying drawings. It should be noted that, without conflict, the embodiments of the present invention and features in the embodiments may be combined with each other.

An automated lithium manganese button battery production line according to some embodiments of the present invention is described below with reference to the accompanying drawings.

Referring to fig. 1 to 8, the automatic production line of button lithium-manganese battery provided by the invention comprises: the polishing machine comprises a working machine cabinet 100, a feeding mechanism 200, a polishing processing assembly 300 and a cramp tooling mechanism 400, wherein a material delivery guide rail 110 and an output conveyor belt 120 are fixedly arranged in the working machine cabinet 100, the output conveyor belt 120 and the feeding mechanism 200 are symmetrically distributed on two sides of the polishing processing assembly 300 and are arranged in the vertical direction of the material delivery guide rail 110, the feeding mechanism 200, the polishing processing assembly 300 and the cramp tooling mechanism 400 are fixedly arranged in the working machine cabinet 100, and the output end of the material delivery guide rail 110 is fixedly connected with a finger cylinder 111 which is vertically and downwards arranged;

the feeding mechanism 200 comprises a fixed seat 210, a tray 220, a feeding ladder 230, a feeding motor 240 and a linear oscillator 250 fixedly arranged on the bottom surface of the feeding ladder 230, wherein the tray 220 is fixedly arranged on one side of the fixed seat 210 and is positioned in the same vertical plane with the finger cylinder 111 and the buckle piece tool mechanism 400, an elastic supporting plate 231 fixedly connected with the surface of the fixed seat 210 is fixedly arranged on the bottom surface of the feeding ladder 230, the feeding motor 240 is fixedly arranged on one side of the fixed seat 210 and is fixedly provided with a collecting plate 241 at the output end, a hopper sleeved on the surface of the fixed seat 210 is fixedly arranged on the inner side of the working cabinet 100, a magnetic induction guide cylinder 251 is movably arranged in the linear oscillator 250, a damper 252 fixedly connected with the bottom surface of the feeding ladder 230 is fixedly connected to one end of the magnetic induction guide cylinder 251, a moving magnet 251 is slidably arranged on the inner side of the magnetic induction guide cylinder 251, and a plurality of exciting coils 253 are fixedly sleeved on the surface of the magnetic induction guide cylinder; the cramp frock mechanism 400 includes rail platform 410 and frock positioning seat 420, rail platform 410's output fixed mounting has slidable mounting in rail platform 410 top surface's motion seat 411, the inboard fixed mounting of motion seat 411 has rotatory steering wheel 412, rotatory steering wheel 412's output and frock positioning seat 420's top surface fixed connection, frock positioning seat 420's surface mounting has driving disk 422 and slidable mounting to have chuck 421, driving disk 422's output is equipped with the disc and the transmission groove 423 has been seted up on the surface of disc, chuck 421's one end fixed mounting cup joints in transmission groove 423 inboard pin.

In this embodiment, the feeding guide rail 110 is one of an electromagnetic guide rail or a screw guide rail, the number of the finger cylinders 111 is two, and the suction head 112 is fixedly mounted at the output end of the finger cylinders 111.

Specifically, the finger cylinder 111 is moved to the upper side of the tray 220 under the driving of the delivery guide rail 110, and the bottom cover is sucked and grabbed under the action of the finger cylinder 111 and the suction head 112, and the materials are transferred to the surface of the tooling positioning seat 420 by the delivery guide rail 110 for delivery one by one.

In this embodiment, the end of the exciting coil 253 is electrically connected with a current generator, the moving magnet 254 is located at the inner side of the exciting coil 253, the damper 252 is a damping telescopic rod, and the surface of the damper 252 is fixedly sleeved with a spring.

Specifically, the exciting coil 253 in the linear oscillator 250 is electrified to generate an alternating magnetic field to drive the moving magnet 254 to reciprocate in the magnetic induction cylinder 251 to generate impact kinetic energy, so that the linear vibration of the whole linear oscillator 250 and the feeding ladder 230 is realized, and the bottom covers are conveyed one by one.

In this embodiment, a material sensor is disposed on the surface of the tray 220, and an output end of the material sensor is electrically connected to an input end of the controller, and an output end of the controller is electrically connected to input ends of the feeding mechanism 200, the delivery guide rail 110, and the buckle piece tooling mechanism 400.

Specifically, after the surface sensor of the tray 220 detects that the bottom cover on the surface of the feeding ladder 230 falls to the surface of the tray 220, the linear oscillator 250 is automatically controlled to stop, and the delivery guide rail 110 is started to control the finger cylinder 111 to grasp and transfer the bottom cover, so that all the structures are mutually matched and driven.

In this embodiment, the elastic supporting plate 231 is a flexible metal plate structure, the surface of the elastic supporting plate 231 is provided with a plurality of grid holes, the feeding ladder 230 is arranged in an inclined manner, and the surface of the feeding ladder is provided with a plurality of guiding steps 232.

Specifically, the feeding ladder 230 is driven by the linear vibrator 250 to perform oblique movement and vibration under the elastic support of the elastic supporting plate 231, so that the materials gradually move upward from the bottom end of the feeding ladder 230, and the materials drop to the surface of the tray 220 one by one.

In this embodiment, the polishing processing assembly 300 includes a first driving stage 310, a second driving stage 320, and a polishing machine 330, wherein a deflection stage 321 is rotatably mounted on a surface of the second driving stage 320, the polishing machine 330 is fixedly mounted on a bottom surface of the deflection stage 321, a driving assembly for driving the deflection stage 321 to deflect is disposed on a surface of the first driving stage 310, and the second driving stage 320 is slidably mounted on a surface of the first driving stage 310.

Further, the first driving table 310 and the transverse rail table 410 are both screw driving guide rail structures, the arrangement directions of the first driving table 310 and the transverse rail table 410 are mutually perpendicular, the arrangement directions of the transverse rail table 410 and the delivery guide rail 110 are the same, and the polishing machine 330 is an abrasive belt polishing machine structure.

Specifically, the first driving table 310 is used for driving the surface second driving table 320 and the polishing machine 330 to move relative to the surface of the tool positioning seat 420, so that the polishing machine 330 contacts with the battery workpiece clamped on the surface of the tool positioning seat 420, the second driving table 320 is used for driving the deflection table 321 and the polishing machine 330 to deflect and adjust the fitting angle of the polishing machine 330 and the surface of the bottom cover, and the series of movements are automatically operated under the control of the control end to uniformly polish the surface of the buckle piece.

In this embodiment, the surface of the tool positioning seat 420 is provided with a plurality of tool slots, the number of the chucks 421 is several, and the chucks are circumferentially arranged on the periphery of the tool slots, and the driving slots 423 are in arc structures, and the distances between the two ends of the driving slots and the center of the driving disk 422 are different.

Specifically, the rotation of the driving disc 422 drives the disc surface driving groove 423 to rotate, so that the pin on the bottom surface of the chuck 421 slides inside the driving groove 423, and the chuck 421 is pulled or pushed to move, so that the chuck 421 slides to abut against the peripheral side of the bottom cover, and the bottom cover of the battery is clamped.

The working principle and the using flow of the invention are as follows:

when the button lithium manganese battery automatic production line is used, firstly, a button sheet bottom cover to be processed is poured into a hopper at the end part of the feeding mechanism 200, a collecting plate 241 is driven by a feeding motor 240 to rotate so as to enable the bottom cover to move to the surface of a feeding tray 230, a current input of an exciting coil 253 is automatically controlled by a control end to control reciprocating impact vibration of a moving magnetic block 254 in the magnetic induction cylinder 251, the impact kinetic energy drives the feeding tray 230 to shake obliquely up and down on the surface of a fixed seat 210 under the conduction of a damper 252, so that the bottom cover is gradually moved up after receiving vibration on the surface of the feeding tray 230, and the bottom cover is enabled to drop above the tray 220 one by one;

then, the finger cylinder 111 is driven by the delivery guide rail 110 to move above the material tray 220, the bottom cover is sucked and grabbed under the action of the finger cylinder 111 and the suction head 112, the material is transferred to the surface of the tool positioning seat 420 through the delivery guide rail 110, and the chuck 421 is driven by the deflection of the driving disk 422 to enable the chuck 421 to abut against the edge of the bottom cover under the deflection traction of the bottom surface pin and the transmission groove 423, so that the tool clamping and positioning are realized; in polishing, the horizontal movement of the bottom cover relative to the polishing machine 330 is realized by driving the movement seat 411 and the tool positioning seat 420 to move horizontally through the horizontal rail table 410, the tool positioning seat 420 and the bottom cover are driven to rotate relative to the polishing machine 330 by the rotary steering engine 412, the second driving table 320 and the polishing machine 330 are driven to move vertically along the horizontal rail table 410 through the first driving table 310, the polishing machine 330 moves horizontally relative to the bottom cover, the deflection table 321 and the polishing machine 330 are driven by the second driving table 320 to deflect and adjust the joint angle of the polishing machine 330 and the surface of the bottom cover, and the series of movements are automatically operated under the control of the control end to uniformly polish the surface of the buckle slice, so that the automatic processing of the buckle slice is realized.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents.

Claims (8)

1. An automatic production line of button lithium-manganese battery, which is characterized by comprising: the polishing machine comprises a working machine cabinet (100), a feeding mechanism (200), a polishing processing assembly (300) and a cramp tooling mechanism (400), wherein a delivery guide rail (110) and an output conveyor belt (120) are fixedly arranged in the working machine cabinet (100), the output conveyor belt (120) and the feeding mechanism (200) are symmetrically distributed on two sides of the polishing processing assembly (300) and are arranged in the vertical direction with the delivery guide rail (110), the feeding mechanism (200), the polishing processing assembly (300) and the cramp tooling mechanism (400) are fixedly arranged in the working machine cabinet (100), and the output end of the delivery guide rail (110) is fixedly connected with a finger cylinder (111) which is vertically and downwards arranged;

the feeding mechanism (200) comprises a fixed seat (210), a material tray (220), a feeding ladder (230) and a feeding motor (240) and a linear oscillator (250) fixedly arranged on the bottom surface of the feeding ladder (230), the material tray (220) is fixedly arranged on one side of the fixed seat (210) and is positioned in the same vertical plane with a finger cylinder (111) and a buckle piece tool mechanism (400), an elastic supporting plate (231) fixedly connected with the surface of the fixed seat (210) is fixedly arranged on the bottom surface of the feeding ladder (230), the feeding motor (240) is fixedly arranged on one side of the fixed seat (210) and the output end of the feeding motor is fixedly provided with a collecting plate (241), a hopper sleeved on the surface of the fixed seat (210) is fixedly arranged on the inner side of the working machine cabinet (100), a magnetic induction guide cylinder (251) is movably arranged in the linear oscillator (250), one end of the magnetic induction guide cylinder (251) is fixedly connected with a damper (252) fixed on the bottom surface of the feeding ladder (230), a plurality of magnetic induction guide cylinders (251) are fixedly sleeved on the inner moving blocks (254) of the magnetic induction guide cylinder (251), and a plurality of magnetic induction coils (253) are fixedly sleeved on the surface of the magnetic induction cylinders (253).

The cramp frock mechanism (400) comprises a transverse rail platform (410) and a frock positioning seat (420), wherein the output end of the transverse rail platform (410) is fixedly provided with a moving seat (411) which is slidably arranged on the top surface of the transverse rail platform (410), the inner side of the moving seat (411) is fixedly provided with a rotary steering engine (412), the output end of the rotary steering engine (412) is fixedly connected with the top surface of the frock positioning seat (420), the surface of the frock positioning seat (420) is embedded with a driving disc (422) and is slidably provided with a clamping head (421), the output end of the driving disc (422) is provided with a disc, the surface of the disc is provided with a transmission groove (423), and one end of the clamping head (421) is fixedly provided with a pin sleeved on the inner side of the transmission groove (423).

2. The automatic lithium manganese button cell production line according to claim 1, wherein the delivery guide rail (110) is one of an electromagnetic guide rail and a screw guide rail, the number of the finger air cylinders (111) is two, and a suction head (112) is fixedly arranged at the output end of the finger air cylinders (111).

3. The automatic lithium manganese button battery production line according to claim 1, wherein an end portion of the excitation coil (253) is electrically connected with a current generator, the moving magnet (254) is located on the inner side of the excitation coil (253), the damper (252) is a damping telescopic rod, and a spring is fixedly sleeved on the surface of the damper (252).

4. The automatic lithium-manganese button cell production line according to claim 1, wherein a material sensor is arranged on the surface of the material tray (220), an output end of the material sensor is electrically connected with an input end of a controller, and an output end of the controller is electrically connected with an input end of a feeding mechanism (200), a material delivering guide rail (110) and a buckle piece tool mechanism (400).

5. The automatic production line of button lithium-manganese battery according to claim 1, wherein the elastic supporting plate (231) is an elastic metal plate structure, a plurality of grid holes are formed in the surface of the elastic supporting plate (231), the feeding ladder (230) is obliquely arranged, and a plurality of guiding steps (232) are formed in the surface of the feeding ladder.

6. The automatic lithium manganese button cell production line according to claim 1, wherein the polishing processing assembly (300) comprises a first driving table (310), a second driving table (320) and a polishing machine (330), a deflection table (321) is rotatably installed on the surface of the second driving table (320), the polishing machine (330) is fixedly installed on the bottom surface of the deflection table (321), a driving assembly for driving the deflection table (321) to deflect is arranged on the surface of the first driving table (310), and the second driving table (320) is slidably installed on the surface of the first driving table (310).

7. The automatic lithium manganese button cell production line according to claim 6, wherein the first driving table (310) and the transverse rail table (410) are of screw driving guide rail structures, the arrangement directions of the first driving table (310) and the transverse rail table (410) are perpendicular to each other, the arrangement directions of the transverse rail table (410) and the delivery guide rail (110) are the same, and the polishing machine (330) is of an abrasive belt polishing machine structure.

8. The automatic production line of button lithium-manganese batteries according to claim 1, wherein tool slots are formed in the surface of the tool positioning seat (420), the number of the chucks (421) is several, the chucks are circumferentially arranged on the periphery of the tool slots, and the transmission slots (423) are of arc structures, and the distances between the two ends of the transmission slots and the center of the driving disk (422) are unequal.

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