CN112389997A

CN112389997A - Lithium battery processing system

Info

Publication number: CN112389997A
Application number: CN202011314407.3A
Authority: CN
Inventors: 曹鸿雁
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-11-21
Filing date: 2020-11-21
Publication date: 2021-02-23

Abstract

The invention relates to the technical field of battery processing, in particular to a lithium battery processing system which comprises a loading mechanism, a rotating mechanism and a collecting mechanism, wherein the loading mechanism comprises battery placing boxes, a rack, a ratchet gear, a sliding block, a clamping plate and a rotating plate, a plurality of battery placing boxes are all connected in the rack in a sliding mode, the ratchet gear is connected on the rack in a rotating mode, the sliding block is connected on the rack in a sliding mode, a plurality of clamping plates are all connected in the rack in a rotating mode, the other ends of the clamping plates are all connected in the rack through springs, the rotating plate is connected on the rack in a rotating mode, a rack is arranged on each battery placing box, the battery placing boxes are in meshing transmission with the ratchet gear, the ratchet gear and the sliding block are in friction transmission, the sliding block is connected on the rack through springs, the rotating mechanism comprises a material pushing rod and a fixing plate, a plurality of, the collection mechanism includes a collection bin.

Description

Lithium battery processing system

Technical Field

The invention relates to the technical field of battery processing, in particular to a lithium battery processing system.

Background

For example, publication No. CN206550420U includes: the winding assembly is arranged in the middle of the rack and consists of two mounting frames, a winding shaft, a winding wheel, a power shaft and a power motor, wherein the two mounting frames are vertically and fixedly connected to two sides of the rack, two ends of the winding shaft are connected to the two mounting frames through bearing seats, the winding wheel is uniformly connected to the winding shaft, the power shaft is connected to one side of the mounting frames through the bearing seats, the power shaft is connected with the winding shaft through bevel gears, and an output shaft of the power motor is fixedly connected with the power shaft; the invention has the disadvantage that the processed batteries cannot be automatically collected and arranged together.

Disclosure of Invention

The invention aims to provide a lithium battery processing system which can automatically collect and arrange processed batteries together.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a lithium battery processing system, including loading mechanism, slewing mechanism and collection mechanism, loading mechanism includes that the battery places the box, the carrier, the ratchet wheel, the sliding block, pinch-off blades and rotor plate, the equal sliding connection of box is placed to a plurality of batteries in the carrier, the rotation of ratchet wheel connects on the carrier, sliding block sliding connection is on the carrier, a plurality of pinch-off blades all rotate to be connected in the carrier, the other end of a plurality of pinch-off blades all through spring coupling in the carrier, the rotor plate rotates to be connected on the carrier, the battery is placed and is equipped with the rack on the box, box and ratchet wheel meshing transmission are placed to the battery, ratchet wheel and sliding block friction drive, the sliding block passes through spring coupling on the carrier, slewing mechanism includes ejector ram and fixed plate, equal fixedly connected with a plurality of ejector rams on every fixed plate, collection mechanism includes the collecting box.

As a further optimization of the technical solution, in the lithium battery processing system of the present invention, the rotating mechanism further includes a rotating main shaft, a rotating frame and return springs, each fixing plate is connected to the rotating frame through two return springs, the rotating frame is fixedly connected to the main shaft, the fixing plate is slidably connected to the rotating frame, and the plurality of carriers are rotatably connected to the rotating frame.

As a further optimization of the technical scheme, the lithium battery processing system further comprises a support frame, a power motor, a conveyor belt, a sliding pressure plate, a rotating rod, an eccentric wheel and a transmission shaft, wherein the power motor is fixedly connected to the support frame, the conveyor belt is rotatably connected to the support frame, the collecting box and the conveyor belt are in friction transmission, the sliding pressure plate is slidably connected to the support frame, the upper end and the lower end of the rotating rod are respectively rotatably connected to the sliding pressure plate and the eccentric wheel, the eccentric wheel and the transmission shaft are rotatably connected to the support frame, the eccentric wheel and the transmission shaft are in belt transmission, a main shaft is rotatably connected to the support frame, the main shaft is fixedly connected to an output shaft of.

As a further optimization of the technical scheme, the lithium battery processing system further comprises an injection mechanism, wherein the injection mechanism comprises an electrolyte tank, material conveying pipes, injection pipes, a piston frame, a lead screw, threaded sliders and lifting rotating rods, the material conveying pipes are fixedly connected to the electrolyte tank, the injection pipes are fixedly connected to the material conveying pipes respectively, the injection pipes are fixedly connected to the electrolyte tank, the piston frame is connected to the injection pipes in a sliding mode, the lead screw is connected to the lower end of the electrolyte tank in a rotating mode, the threaded sliders are connected to the lower end of the electrolyte tank in a sliding mode, the threaded sliders are in threaded transmission with the lead screw, the lifting rotating rods are connected to the threaded sliders in a rotating mode, the lifting rotating rods are connected to the piston frame in a rotating mode, and the electrolyte tank is fixedly connected to a support frame.

As a further optimization of the technical scheme, the lithium battery processing system further comprises a connecting mechanism, the connecting mechanism comprises a gear shaft, a rack, a rotating rod II, an eccentric wheel II and a motor, the gear shaft and the rack are meshed for transmission, the rotating rod II is rotatably connected to the rack, the rotating rod II is rotatably connected to the eccentric wheel II, the eccentric wheel II is fixedly connected to an output shaft of the motor, the gear shaft is rotatably connected to a support frame, the rack is slidably connected to the support frame, the eccentric wheel II is movably connected to the support frame, the motor is fixedly connected to the support frame, the gear shaft is fixedly connected to a lead screw, and the eccentric wheel II and a transmission shaft are in belt transmission.

As a further optimization of the technical scheme, the lithium battery processing system further comprises a pushing mechanism, wherein the pushing mechanism comprises a cam, a transmission shaft II, a material pushing frame, a material pushing pipe, a material pushing head and sliding rods, the cam is fixedly connected to the transmission shaft II, the transmission shaft II is rotatably connected to the material pushing frame, the material pushing pipe is slidably connected to the material pushing frame, the material pushing head is slidably connected into the material pushing pipe through springs, the two sliding rods are both slidably connected to the material pushing pipe, the material pushing pipe is connected onto the two sliding rods through the two springs, and the material pushing frame is fixedly connected to a support frame.

As a further optimization of the technical scheme, the lithium battery processing system further comprises a conveying mechanism, wherein the conveying mechanism comprises a conveying conveyor belt, a connecting shaft II, bevel gears, a fan-shaped wheel shaft and a connecting wheel, the connecting shaft II is fixedly connected to the conveying conveyor belt and is provided with two bevel gears, one bevel gear is in belt transmission with the connecting shaft II, the other bevel gear is in meshing transmission with the fan-shaped wheel shaft, the fan-shaped wheel shaft is in meshing transmission with the connecting wheel, the two bevel gears are in meshing transmission, the conveying conveyor belt, the two bevel gears, the fan-shaped wheel shaft and the connecting wheel are rotatably connected to a support frame, the connecting wheel is in belt transmission with the driving shaft II, and the fan-shaped wheel shaft is in.

The lithium battery processing system has the beneficial effects that:

according to the lithium battery processing system, after processing is completed, a battery mechanism can be collected and arranged, manual arrangement is not needed in the whole process, the internal collection box can be automatically and orderly, transportation and subsequent processing processes are convenient to carry out, a large amount of manpower and material resources are saved, the working efficiency is improved, the process of filling liquid into a plurality of batteries can be completed at one time in the processing process, the working efficiency is improved while the manpower and material resources are saved, the injection quantity can be fixed every time after adjustment, waste is avoided, or the use of the batteries is not influenced, and the qualification rate is improved.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram of the overall structure of a lithium battery processing system according to the present invention;

FIG. 2 is a schematic view of another aspect of a lithium battery cell processing system of the present invention;

FIG. 3 is a schematic view of the loading mechanism of the present invention;

FIG. 4 is a schematic cross-sectional view of the loading mechanism of the present invention;

FIG. 5 is a schematic view of the ratchet gear configuration of the present invention;

FIG. 6 is a schematic view of the rotating mechanism of the present invention;

FIG. 7 is a schematic view of the collection mechanism of the present invention;

FIG. 8 is a schematic view of the injection mechanism of the present invention;

FIG. 9 is a schematic view of the coupling mechanism of the present invention;

FIG. 10 is a schematic view of the pusher mechanism of the present invention;

fig. 11 is a schematic view of the transport mechanism of the present invention.

In the figure: a loading mechanism 1; a battery housing box 101; a carrier frame 102; a ratchet gear 103; a slider 104; a clamping plate 105; a rotating plate 106; the rotating mechanism 2 is also provided; rotating the main shaft 201; a turret 202; a pusher bar 203; a fixed plate 204; a return spring 205; a collecting mechanism 3; a support frame 301; a power motor 302; a conveyor belt 303; a collection tank 304; a slide platen 305; rotating the rod 306; an eccentric 307; a drive shaft 308; an injection mechanism 4; an electrolyte tank 401; a delivery pipe 402; a syringe 403; a piston frame 404; a lead screw 405; a threaded slider 406; a lifting rotating rod 407; a connecting mechanism 5; a gear shaft 501; a rack 502; rotating the rod II 503; an eccentric wheel II 504; a motor 505; a material pushing mechanism 6; a cam 601; a transmission shaft II 602; a pusher 603; a material pushing pipe 604; a pusher head 605; a slide bar 606; a transport mechanism 7; a transport conveyor 701; a connecting shaft II 702; a bevel gear 703; a sector axle 704; a fifth wheel 705.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

The first embodiment is as follows:

in the following, referring to fig. 1-11 for describing the present embodiment, a lithium battery processing system includes a loading mechanism 1, a rotating mechanism 2 and a collecting mechanism 3, wherein the loading mechanism 1 includes a battery placing box 101, a rack 102, a ratchet gear 103, a sliding block 104, a plurality of clamping plates 105 and a rotating plate 106, the plurality of battery placing boxes 101 are slidably connected in the rack 102, the ratchet gear 103 is rotatably connected to the rack 102, the sliding block 104 is slidably connected to the rack 102, the plurality of clamping plates 105 are rotatably connected in the rack 102, the other ends of the plurality of clamping plates 105 are connected in the rack 102 by springs, the rotating plate 106 is rotatably connected to the rack 102, the battery placing box 101 is provided with a rack, the battery placing box 101 and the ratchet gear 103 are in meshing transmission, the ratchet gear 103 and the sliding block 104 are in friction transmission, the sliding block 104 is connected to the rack 102 by springs, the rotating mechanism 2 includes a material pushing rod 203 and a fixing plate 204, a plurality of material pushing rods 203 are fixedly connected to each fixing plate 204, and the collecting mechanism 3 comprises a collecting box 304;

the battery placing box 101 is provided with a through hole, the battery is blocked by two clamping plates 105 through the through hole and cannot fall off, after the processing is finished, the fixing plate 204 moves downwards to drive the plurality of material pushing rods 203 to move downwards, the material pushing rods 203 move downwards to drive the battery to move downwards, the battery moves downwards to drive the two clamping plates 105 to rotate, the battery moves downwards to orderly fall into the collecting box 304, the whole process does not need manual arrangement, in the built-in collection box 304 that can be automatic orderly, conveniently transport and subsequent course of working, saved a large amount of manpower and materials, improved work efficiency.

The second embodiment is as follows:

referring to fig. 1-11, the present embodiment is further described, and the rotating mechanism 2 further includes a rotating main shaft 201, a rotating frame 202 and return springs 205, each fixing plate 204 is connected to the rotating frame 202 through two return springs 205, the rotating frame 202 is fixedly connected to the main shaft 201, the fixing plate 204 is slidably connected to the rotating frame 202, and the plurality of carrier racks 102 are rotatably connected to the rotating frame 202;

the rotating main shaft 201 rotates to drive the rotating frame 202 to rotate, the rotating frame 202 rotates to drive the carrier frame 102 to rotate, two balancing weights are arranged at the lower end of the carrier frame 102, and the carrier frame 102 is kept stable and placed in the vertical direction through gravity.

The third concrete implementation mode:

this embodiment will be described with reference to fig. 1 to 11, and a second embodiment will be further described with reference to this embodiment, the collecting mechanism 3 further comprises a support frame 301, a power motor 302, a conveyor belt 303, a sliding pressure plate 305, a rotating rod 306, an eccentric wheel 307 and a transmission shaft 308, the power motor 302 is fixedly connected to the support frame 301, the conveyor belt 303 is rotatably connected to the support frame 301, the collecting box 304 and the conveyor belt 303 are in friction transmission, the sliding pressure plate 305 is slidably connected to the support frame 301, the upper end and the lower end of the rotating rod 306 are respectively rotatably connected to the sliding pressure plate 305 and the eccentric wheel 307, the eccentric wheel 307 and the transmission shaft 308 are both rotatably connected to the support frame 301, the eccentric wheel 307 and the transmission shaft 308 are in transmission through a belt, the main shaft 201 is rotatably connected to the support frame 301, the main shaft 201 is fixedly connected;

every time the output shaft of the power motor 302 rotates a quarter of a circle to drive the main shaft 201 to rotate a quarter of a circle, the main shaft 201 rotates to drive the conveyor belt 303 to rotate, the conveyor belt 303 rotates to drive the conveyor belt 303 to rotate and move, the conveyor belt rotation distance is from one row of placing holes of the collecting box 304 to the next row of placing holes, the adjustment can be completed after one collection to prepare for second collection, until the collecting box 304 is full, make the continuity of the whole process better, high efficiency, the transmission shaft 308 rotates to drive the eccentric 307 to rotate, the eccentric 307 rotates to drive the rotating rod 306 to rotate, the rotating rod 306 rotates to drive the sliding pressure plate 305 to move, the sliding pressure plate 305 moves downwards to press the fixed plate 204, drive the fixed plate 204 to move downwards, the fixed plate 204 moves downwards to compress the spring after moving downwards.

The fourth concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 11, and the third embodiment is further described in the present embodiment, the lithium battery processing system further includes an injection mechanism 4, the injection mechanism 4 includes an electrolyte tank 401, material delivery pipes 402, injection pipes 403, a piston frame 404, a screw 405, threaded sliders 406, and lifting/lowering rotating rods 407, the material delivery pipes 402 are all fixedly connected to the electrolyte tank 401, the material delivery pipes 403 are respectively fixedly connected to the material delivery pipes 402, the material injection pipes 403 are all fixedly connected to the electrolyte tank 401, the piston frame 404 is slidably connected to the material injection pipes 403, the screw 405 is rotatably connected to the lower end of the electrolyte tank 401, the two threaded sliders 406 are slidably connected to the lower end of the electrolyte tank 401, the two threaded sliders 406 are in threaded transmission with the screw 405, the two lifting/lowering rotating rods 407 are respectively rotatably connected to the two threaded sliders 406, the two lifting/lowering rotating rods 407 are rotatably connected to the piston frame 404, the electrolyte tank 401 is fixedly connected to the support frame 301;

when the carrier rack 102 rotates to the position right below the plurality of injection tubes 403, the screw rod 405 rotates to drive the two threaded sliders 406 to move towards the middle, the threaded sliders 406 move towards the middle to drive the two lifting rotating rods 407 to rotate, the two lifting rotating rods 407 rotate to drive the piston rack 404 to move downwards, the piston rack 404 moves downwards to extrude the electrolyte in the injection tubes 403 out of the battery, the injection process is completed, the screw rod 405 rotates reversely to drive the two threaded sliders 406 to move towards two sides, the threaded sliders 406 move towards two sides to drive the two lifting rotating rods 407 to rotate, the two lifting rotating rods 407 rotate to drive the piston rack 404 to move upwards, the pressure in the injection tubes 403 is reduced when the piston rack 404 moves upwards, the electrolyte in the electrolyte tank 401 flows into the injection tubes 403 through the feed delivery tubes 402, and the injection tubes 403 are filled with the electrolyte again, the process of injecting liquid of a plurality of batteries can be completed at one time, and the working efficiency is improved while manpower and material resources are saved.

The fifth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 11, which further describes the fourth embodiment, the lithium battery processing system further includes a connecting mechanism 5, the connecting mechanism 5 includes a gear shaft 501, a rack 502, a rotating rod ii 503, an eccentric wheel ii 504 and a motor 505, the gear shaft 501 and the rack 502 are in meshing transmission, the rotating rod ii 503 is rotatably connected to the rack 502, the rotating rod ii 503 is rotatably connected to the eccentric wheel ii, the eccentric wheel ii 504 is fixedly connected to an output shaft of the motor 505, the gear shaft 501 is rotatably connected to the support frame 301, the rack 502 is slidably connected to the support frame 301, the eccentric wheel ii 504 is movably connected to the support frame 301, the motor 505 is fixedly connected to the support frame 301, the gear shaft 501 is fixedly connected to the lead screw 405, and the eccentric wheel ii 504 and the;

an output shaft of the motor 505 rotates to drive the eccentric wheel II 504 to rotate, the eccentric wheel II 504 rotates to drive the rotating rod II 503 to rotate, the rotating rod II 503 rotates to drive the rack 502 to move up and down, the rack 502 moves up and down to drive the gear shaft 501 to rotate forward and backward, the gear shaft 501 rotates forward and backward to drive the screw rod 405 to rotate forward and backward, power is provided for the liquid injection process, and the eccentric wheel II 504 rotates to drive the transmission shaft 308 to rotate.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1 to 11, and the fifth embodiment is further described in the present embodiment, the lithium battery processing system further includes a material pushing mechanism 6, the material pushing mechanism 6 includes a cam 601, a transmission shaft ii 602, a material pushing frame 603, a material pushing pipe 604, a material pushing head 605 and sliding rods 606, the cam 601 is fixedly connected to the transmission shaft ii 602, the transmission shaft ii 602 is rotatably connected to the material pushing frame 603, the material pushing pipe 604 is slidably connected to the material pushing frame 603, the material pushing head 605 is slidably connected to the material pushing pipe 604 through springs, both the sliding rods 606 are slidably connected to the material pushing pipe 604, the material pushing pipe 604 is connected to both the sliding rods 606 through two springs, and the material pushing frame 603 is fixedly connected to the support frame 301.

The seventh embodiment:

the present embodiment is described below with reference to fig. 1 to 11, and the sixth embodiment is further described in the present embodiment, where the lithium battery processing system further includes a transportation mechanism 7, the transportation mechanism 7 includes a transportation conveyor belt 701, a connection shaft ii 702, a bevel gear 703, a sector wheel shaft 704 and a connection wheel 705, the connection shaft ii 702 is fixedly connected to the transportation conveyor belt 701, and is provided with two bevel gears 703, one bevel gear 703 is in belt transmission with the connection shaft ii 702, the other bevel gear 703 is in mesh transmission with the sector wheel shaft 704, the sector wheel shaft 704 is in mesh transmission with the connection wheel 705, the two bevel gears 703 are in mesh transmission, the transportation conveyor belt 701, the two bevel gears 703, the sector wheel shaft 704 and the connection wheel 705 are all rotatably connected to the support frame 301, the connection wheel 705 is in belt transmission with the transmission shaft ii 602, and the sector;

the fan-shaped wheel shaft 704 rotates to drive the two bevel gears 703 at the left end to rotate firstly, the two bevel gears 703 rotate to drive the connecting shaft II 702 to rotate, the connecting shaft II 702 rotates to drive the conveying belt 701 to rotate, the conveying belt 701 rotates to convey the battery placing box 101 to the right, the battery placing box 101 moves to the front of the right material pushing head 605, the fan-shaped wheel shaft 704 is disengaged with the bevel gears 703 at this time, the fan-shaped wheel shaft 704 rotates to drive the connecting wheel 705 to rotate, the connecting wheel 705 rotates to drive the transmission shaft II 602 to rotate, the transmission shaft II 602 rotates to drive the cam 601 to rotate, the cam 601 rotates to push the material pushing pipe 604 to move, the material pushing pipe 604 moves to drive the material pushing head 605 to move, the material pushing head 605 moves to push the battery placing box 101 into the carrier 102, the cycle is repeated until the battery placing box 101 is fully filled in the carrier 102, the material pushing, the material pushing head 605 can slide the compression spring rightwards, so that the battery placing box 101 is prevented from being crushed, unnecessary loss is avoided, the material loading process can be continuously and efficiently completed, manpower and material resources are saved, and the processing speed is increased.

The lithium battery processing system disclosed by the invention has the working principle that:

when the device is used, the output shaft of the motor 505 rotates to drive the eccentric wheel II 504 to rotate, the eccentric wheel II 504 rotates to drive the rotating rod II 503 to rotate, the rotating rod II 503 rotates to drive the rack 502 to move up and down, the rack 502 moves up and down to drive the gear shaft 501 to rotate positively and negatively, the gear shaft 501 rotates positively and negatively to drive the screw rod 405 to rotate positively and negatively to provide power for the liquid injection process, the eccentric wheel II 504 rotates to drive the transmission shaft 308 to rotate, the sector shaft 704 rotates to drive the two bevel gears 703 at the left end to rotate first, the two bevel gears 703 rotate to drive the connecting shaft II 702 to rotate, the connecting shaft II 702 rotates to drive the transportation conveyor belt 701 to rotate, the transportation conveyor belt 701 rotates to transport the battery placing box 101 to the right, the battery placing box 101 moves to the front of the right pushing head 605, the sector shaft 704 is disengaged with the, the transmission shaft II 602 rotates to drive the cam 601 to rotate, the cam 601 rotates to push the material pushing pipe 604 to move, the material pushing pipe 604 moves to drive the material pushing head 605 to move, the material pushing head 605 moves to push the battery placing box 101 into the carrier frame 102, the cycle is repeated until the battery placing box 101 is full in the carrier frame 102, the material pushing head 605 is provided with a spring, when the last battery placing box 101 is pushed, the material pushing head 605 slides rightwards to compress the spring to prevent the battery placing box 101 from being damaged, unnecessary loss is prevented, the feeding process can be continuously and efficiently completed, manpower and material resources are saved, the processing speed is accelerated, when the carrier frame 102 rotates to be right below a plurality of injection pipes 403, the screw rod 405 rotates to drive the two threaded sliders 406 to move towards the middle, the threaded sliders 406 move towards the middle to drive the two lifting rotating rods 407 to rotate, the two lifting rotating rods 407 rotate to drive the piston frame 404 to move downwards, the piston frame 404 moves downwards to extrude the electrolyte in the injection tube 403 to flow into the battery, the injection process is completed, the screw rod 405 rotates reversely to drive the two threaded sliding blocks 406 to move towards two sides, the threaded sliding blocks 406 move towards two sides to drive the two lifting rotating rods 407 to rotate, the two lifting rotating rods 407 rotate to drive the piston frame 404 to move upwards, the piston frame 404 moves upwards to drive the pressure in the injection tube 403 to reduce, the electrolyte in the electrolyte box 401 flows into the injection tube 403 through the material conveying tube 402, the injection tube 403 is filled with the electrolyte again, the process of injecting the electrolyte into a plurality of batteries can be completed at one time, the work efficiency is improved while manpower and material resources are saved, the batteries are placed in the battery placing box 101, the plurality of battery placing boxes 101 are placed in the carrier 102, when the battery placing box 101 slides into the carrier 102, the battery placing box 101 moves to drive the ratchet gear 103 to rotate, the ratchet gear 103 rotates to drive the sliding block 104 to move, the ratchet gear 103 can only rotate rightwards and cannot rotate leftwards, so that the battery placing box 101 can be prevented from falling or sliding, the processing process is prevented from being broken down and causing unnecessary loss and waste, the battery placing box 101 is provided with through holes, batteries are blocked by the two clamping plates 105 through the through holes and cannot fall off, after the processing is finished, the fixed plate 204 moves downwards to drive the plurality of pushing rods 203 to move downwards, the pushing rods 203 move downwards to drive the batteries to move downwards, the batteries move downwards to drive the two clamping plates 105 to rotate, the batteries move downwards to orderly fall into the collecting box 304, the whole process does not need manual arrangement, the internal collecting box 304 can automatically and orderly carry out transportation and subsequent processing processes, a large amount of manpower and material resources are saved, the working efficiency is improved, the rotating main shaft 201 rotates to drive the rotating frame 202 to rotate, the rotating frame 202 rotates to drive the carrier frame 102 to rotate, two balancing weights are arranged at the lower end of the carrier frame 102, the carrier frame 102 is kept stable and placed in the vertical direction through gravity, each time the output shaft of the power motor 302 rotates for a quarter circle to drive the main shaft 201 to rotate for a quarter circle, the main shaft 201 rotates to drive the conveyor belt 303 to rotate, the conveyor belt 303 rotates to drive the conveyor belt 303 to rotate and move, the rotation distance of the conveyor belt is from one row of placing holes of the collection box 304 to the next row of placing holes, the conveyor belt can be adjusted after one-time collection is completed to prepare for second-time collection until the collection box 304 is full, the whole process is better in continuity, and is more efficient, the transmission shaft 308 rotates to drive the eccentric wheel 307 to rotate, the eccentric wheel 307 rotates to drive the rotating rod 306 to rotate, the rotating rod 306 rotates to drive the sliding pressure plate 305 to move, the sliding pressure plate, when the slide platen 305 moves upward, the fixed plate 204 is restored by the spring extension.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a lithium battery processing system, includes loading mechanism (1), slewing mechanism (2) and collects mechanism (3), its characterized in that: the loading mechanism (1) comprises battery placing boxes (101), a carrier rack (102), a ratchet gear (103), a sliding block (104), a clamping plate (105) and a rotating plate (106), wherein a plurality of battery placing boxes (101) are all connected in the carrier rack (102) in a sliding manner, the ratchet gear (103) is connected on the carrier rack (102) in a rotating manner, the sliding block (104) is connected on the carrier rack (102) in a sliding manner, a plurality of clamping plates (105) are all connected in the carrier rack (102) in a rotating manner, the other ends of the clamping plates (105) are all connected in the carrier rack (102) through springs, the rotating plate (106) is connected on the carrier rack (102) in a rotating manner, racks are arranged on the battery placing boxes (101), the battery placing boxes (101) are in meshing transmission with the ratchet gear (103), the ratchet gear (103) is in friction transmission with the sliding block (104), and the sliding block (104) is connected on the carrier rack (, the rotating mechanism (2) comprises a plurality of pushing rods (203) and fixing plates (204), each fixing plate (204) is fixedly connected with the corresponding pushing rod (203), and the collecting mechanism (3) comprises a collecting box (304).

2. The lithium battery processing system of claim 1, wherein: the rotating mechanism (2) further comprises a rotating main shaft (201), a rotating frame (202) and return springs (205), each fixing plate (204) is connected to the rotating frame (202) through the two return springs (205), the rotating frame (202) is fixedly connected to the main shaft (201), the fixing plates (204) are connected to the rotating frame (202) in a sliding mode, and the carrier racks (102) are connected to the rotating frame (202) in a rotating mode.

3. A lithium battery processing system as claimed in claim 2, characterized in that: the collecting mechanism (3) further comprises a support frame (301), a power motor (302), a conveyor belt (303), a sliding pressing plate (305), a rotating rod (306), an eccentric wheel (307) and a transmission shaft (308), the power motor (302) is fixedly connected to the support frame (301), the conveyor belt (303) is rotatably connected to the support frame (301), a collecting box (304) and the conveyor belt (303) are in friction transmission, the sliding pressing plate (305) is slidably connected to the support frame (301), the upper end and the lower end of the rotating rod (306) are respectively rotatably connected to the sliding pressing plate (305) and the eccentric wheel (307), the eccentric wheel (307) and the transmission shaft (308) are both rotatably connected to the support frame (301), the eccentric wheel (307) and the transmission shaft (308) are in belt transmission, a main shaft (201) is rotatably connected to the support frame (301), and the main shaft (201) is fixedly connected, the main shaft (201) and the conveyor belt (303) are driven by a belt.

4. A lithium battery processing system as claimed in claim 3, characterized in that: the lithium battery processing system further comprises an injection mechanism (4), wherein the injection mechanism (4) comprises an electrolyte box (401), material conveying pipes (402), injection pipes (403), a piston frame (404), a screw rod (405), threaded sliding blocks (406) and lifting rotating rods (407), the material conveying pipes (402) are fixedly connected to the electrolyte box (401), the injection pipes (403) are fixedly connected to the material conveying pipes (402) respectively, the injection pipes (403) are fixedly connected to the electrolyte box (401), the piston frame (404) is slidably connected to the injection pipes (403), the screw rod (405) is rotatably connected to the lower end of the electrolyte box (401), the two threaded sliding blocks (406) are slidably connected to the lower end of the electrolyte box (401), the two threaded sliding blocks (406) are in threaded transmission with the screw rod (405), the two lifting rotating rods (407) are rotatably connected to the two threaded sliding blocks (406) respectively, two lifting rotating rods (407) are rotatably connected to the piston frame (404), and the electrolyte tank (401) is fixedly connected to the support frame (301).

5. The lithium battery processing system of claim 4, wherein: the lithium battery processing system further comprises a connecting mechanism (5), the connecting mechanism (5) comprises a gear shaft (501), a rack (502), a rotating rod II (503), an eccentric wheel II (504) and a motor (505), the gear shaft (501) is in meshing transmission with the rack (502), the rotating rod II (503) is rotatably connected onto the eccentric wheel II, the eccentric wheel II (504) is fixedly connected onto an output shaft of the motor (505), the gear shaft (501) is rotatably connected onto the supporting frame (301), the rack (502) is slidably connected onto the supporting frame (301), the eccentric wheel II (504) is movably connected onto the supporting frame (301), the motor (505) is fixedly connected onto the supporting frame (301), the gear shaft (501) is fixedly connected onto the screw rod (405), and the eccentric wheel II (504) and the transmission shaft (308) are in belt transmission.

6. The lithium battery processing system of claim 5, wherein: the lithium battery processing system further comprises a material pushing mechanism (6), wherein the material pushing mechanism (6) comprises a cam (601), a transmission shaft II (602), a material pushing frame (603), a material pushing pipe (604), a material pushing head (605) and sliding rods (606), the cam (601) is fixedly connected to the transmission shaft II (602), the transmission shaft II (602) is rotatably connected to the material pushing frame (603), the material pushing pipe (604) is slidably connected to the material pushing frame (603), the material pushing head (605) is slidably connected to the material pushing pipe (604) through springs, the two sliding rods (606) are slidably connected to the material pushing pipe (604), the material pushing pipe (604) is connected to the two sliding rods (606) through the two springs, and the material pushing frame (603) is fixedly connected to the support frame (301).

7. The lithium battery processing system of claim 6, wherein: the lithium battery processing system further comprises a conveying mechanism (7), wherein the conveying mechanism (7) comprises a conveying conveyor belt (701), a connecting shaft II (702), bevel gears (703), a fan-shaped wheel shaft (704) and a connecting wheel (705), the connecting shaft II (702) is fixedly connected to the conveying conveyor belt (701) and is provided with two bevel gears (703), one bevel gear (703) is in belt transmission with a connecting shaft II (702), the other bevel gear (703) is in meshing transmission with a sector wheel shaft (704), the sector wheel shaft (704) is in meshing transmission with a connecting wheel (705), the two bevel gears (703) are in meshing transmission, a conveying conveyor belt (701), the two bevel gears (703), the sector wheel shaft (704) and the connecting wheel (705) are rotationally connected to a support frame (301), the connecting wheel (705) is in belt transmission with a transmission shaft II (602), and the sector wheel shaft (704) is in meshing transmission with a transmission shaft (308) through the bevel gears.