CN219716926U - Battery core automatic feeding, tab cutting, shaping, detecting and blanking equipment - Google Patents

Abstract

The utility model discloses automatic battery core feeding, tab cutting, shaping, detecting and blanking equipment, which comprises a workbench, wherein a feeding mechanism, a first conveying mechanism, a battery core position correcting mechanism, a second conveying mechanism, an index plate, an electrode shaping device, a battery core electrode cutting mechanism, battery core detecting equipment, battery core visual detecting equipment and a blanking mechanism are sequentially arranged on the top surface of the workbench according to a working flow, the index plate rotates in the horizontal direction under the action of a servo motor, and the second conveying mechanism, the electrode shaping device, the battery core electrode cutting mechanism, the battery core detecting equipment, the battery core visual detecting equipment and the blanking mechanism are sequentially arranged around the index plate.

Description

Battery core automatic feeding, tab cutting, shaping, detecting and blanking equipment

Technical Field

The utility model belongs to the technical field of automatic equipment for auxiliary teaching, and particularly relates to automatic battery core feeding, tab cutting, shaping, detecting and blanking equipment.

Background

The battery core is an electrochemical battery core containing an anode and a cathode, and is not directly used generally, the lithium ion secondary rechargeable battery generally consists of the battery core and a protection circuit board, and the battery core is the battery core after the protection circuit board is removed, and is an electric storage part in the rechargeable battery. The battery cell needs to be subjected to multiple processes such as cutting, shaping, detecting and the like before leaving the factory so as to meet the use requirements.

Because the inside mechanism that constitutes of equipment is more, the structure is complicated, if the certain mechanism of equipment goes wrong, will cause the influence to leaving the factory of electric core, operating personnel is unclear the work flow and the principle of equipment, just can't fix a position and handle the reason (mechanism) of problem that goes wrong, let the unable quick restart of equipment, consequently, need the simple transparent automatic feeding of a dedicated battery core of work flow, utmost point ear cuts, plastic, detects, unloading equipment be used for the teaching to students, staff such as universities, enterprise department, etc. to make things convenient for them to understand battery core automatic feeding, utmost point ear cuts, plastic, detects, unloading equipment's theory of operation and operation flow.

Disclosure of Invention

The utility model aims to provide automatic battery core feeding, tab cutting, shaping, detecting and blanking equipment, so that the automatic battery core feeding, tab cutting, shaping, detecting and blanking equipment can be conveniently understood by the user, the working principle and the operation flow of the battery core automatic feeding, tab cutting, shaping, detecting and blanking equipment can be positioned and processed in time when the related equipment is in a problem, and production cannot be influenced.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the battery core automatic feeding, tab cutting, shaping, detecting and blanking equipment comprises a workbench, wherein a feeding mechanism, a first material conveying mechanism, a battery core position correcting mechanism, a second material conveying mechanism, an index plate, an electrode shaping device, a battery core electrode cutting mechanism, a battery core detecting device, a battery core visual detecting device and a blanking mechanism are sequentially arranged on the top surface of the workbench according to a working flow;

a tray filled with batch of battery cells is arranged on the feeding mechanism; the first material conveying mechanism is used for conveying the battery cells on the tray to the battery cell position correcting mechanism; the battery cell position correction mechanism is used for conveying the battery cell to the upper material level and correcting the upper material level; the top surface of the dividing disc is provided with a plurality of material fixing stations; the second material conveying mechanism is used for conveying the battery cells on the feeding level to a material fixing station on the dividing plate; the electrode shaping device is used for leveling the battery core body and the electrode; the cell electrode cutting mechanism is used for cutting the electrode; the battery cell detection equipment is used for testing whether the function of the battery cell is normal or not; the battery cell visual detection equipment is used for detecting whether the appearance of the battery cell is qualified or not; the top surface of the workbench is provided with a storage table, and the blanking mechanism is used for transferring qualified materials to the storage table;

the index plate rotates in the horizontal direction under the action of the servo motor, and the second material conveying mechanism, the electrode shaping device, the battery cell electrode cutting mechanism, the battery cell detection equipment, the battery cell visual detection equipment and the blanking mechanism are sequentially arranged around the index plate.

Preferably, the fixed station of material is including placing the platform, place the bench and be provided with the fixed subassembly of material, the fixed subassembly of material includes a pair of fastening stopper and the Y epaxial direction that set up of placing bench top surface X axle direction on one fastening stopper, two grooves of sliding that set up in the X axle direction and one groove of sliding that sets up in the Y axle direction are seted up to the top surface of placing the platform, three fastening stopper sliding connection respectively in one groove of sliding, the fixed station of material still includes the elastic component, the elastic component is used for making three fastening stopper draw close each other along the groove of sliding, be provided with on the workstation and be used for making three fastening stopper follow the subassembly that opens and shuts that slides the groove and keep away from each other, works as when the second fortune material mechanism places the material on the bench, the subassembly that opens and shuts is kept away from each other so that the electric core can put in the space that three fastening stopper encloses.

Preferably, the feeding mechanism comprises a mounting plate which is arranged on the workbench and horizontally, a tray supporting plate used for stacking trays is arranged on the top surface of the mounting plate, a plurality of connecting columns which are vertically arranged downwards and penetrate the mounting plate are fixedly connected to the ground of the tray supporting plate, a plurality of fixing plates are fixedly connected to the bottom ends of the connecting columns together, the feeding mechanism further comprises a first screw rod which is vertically arranged and is rotatable, the first screw rod is in threaded connection with the first screw rod, and the first screw rod is controlled to move through a driving motor.

Preferably, the first material transporting mechanism comprises a material transporting frame fixed on the top surface of the workbench and a guide groove fixed on the material transporting frame and horizontally arranged, a negative pressure sucker component moving along the arrangement direction of the guide groove is arranged on the guide groove, and the negative pressure sucker component is used for sucking the battery cell for transportation.

Preferably, the mounting plate is provided with an empty disc storage area, the empty disc storage area is positioned on the travelling route of the negative pressure sucker assembly, and the negative pressure sucker assembly can absorb empty discs.

Preferably, the electric core position correction mechanism comprises a conveyor belt horizontally arranged on the top surface of the workbench and a stop plate arranged at the end part of the travelling direction of the conveyor belt, one side of the conveyor belt is provided with a stop bar, a straightening cylinder is fixed on the stop plate, a shifting plate is fixed on a piston rod of the straightening cylinder, the straightening cylinder is used for enabling the shifting plate to shift the electric core to be attached to the stop bar, and the stop plate and the stop bar enclose a feeding position on the top surface of the conveyor belt.

Preferably, the electrode shaping device comprises a shaping frame fixed on the top surface of the workbench and a shaping cylinder I fixed on the shaping frame and arranged vertically downwards, a pressing block I for flattening the electrode is fixed on a piston rod of the shaping cylinder I, the electrode shaping device further comprises a shaping cylinder II fixed on the shaping frame and arranged vertically downwards, and a pressing block II for flattening the battery cell body is fixed on a piston rod of the shaping cylinder II.

Preferably, the structures of the second material conveying mechanism and the blanking mechanism are identical to those of the first material conveying mechanism.

Compared with the prior art, the utility model provides automatic battery core feeding, tab cutting, shaping, detecting and blanking equipment, which has the following beneficial effects:

according to the utility model, the feeding mechanism, the first material conveying mechanism, the battery core position correcting mechanism, the second material conveying mechanism, the dividing plate, the electrode shaping device, the battery core electrode cutting mechanism, the battery core detecting equipment, the battery core visual detecting equipment and the discharging mechanism are arranged on the workbench according to the working flow, the whole process of the whole battery core processing and detecting is covered by the battery core detecting equipment, the operation flow is transparent, meanwhile, the structure of each mechanism is simple, the working principle is easy to understand, students and staff of universities, enterprise departments and the like can conveniently learn the operation flow of the automatic detecting machine, so that the mechanism with the problem can be positioned in time if the equipment has the problem in the actual use, the maintenance process of the equipment is quickened, and the influence on production is reduced.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate and together with the embodiments of the utility model and do not constitute a limitation to the utility model, and in which:

fig. 1 is a schematic overall outline view of an automatic battery cell feeding, tab cutting, shaping, detecting and blanking device provided by the utility model;

fig. 2 is a schematic diagram of the positions of the mechanisms in the automatic feeding, tab cutting, shaping, detecting and blanking device on the workbench;

fig. 3 is a schematic structural diagram of a feeding mechanism in an automatic feeding, tab cutting, shaping, detecting and blanking device for battery cells according to the present utility model;

fig. 4 is a schematic diagram of a bottom structure of a feeding mechanism in an automatic feeding, tab cutting, shaping, detecting and blanking device for battery cells according to the present utility model;

fig. 5 is a schematic structural diagram of a first material conveying mechanism in an automatic battery core feeding, tab cutting, shaping, detecting and blanking device according to the present utility model;

fig. 6 is a schematic structural diagram of a cell position correction mechanism in an automatic cell feeding, tab cutting, shaping, detecting and blanking device according to the present utility model;

fig. 7 is a schematic structural diagram of an electrode shaping device in an automatic battery cell feeding, tab cutting, shaping, detecting and blanking device according to the present utility model;

fig. 8 is a schematic structural diagram of a cutting mechanism for a battery cell electrode in an automatic battery cell feeding, tab cutting, shaping, detecting and blanking device according to the present utility model;

fig. 9 is a schematic structural diagram of a battery cell detection device in an automatic battery cell feeding, tab cutting, shaping, detecting and blanking device according to the present utility model;

fig. 10 is a schematic structural diagram of a visual detection device for a battery cell in an automatic battery cell feeding, tab cutting, shaping, detecting and blanking device according to the present utility model;

fig. 11 is a schematic structural diagram of an index plate in an automatic battery core feeding, tab cutting, shaping, detecting and blanking device according to the present utility model;

fig. 12 is a schematic diagram of a structure of an opening and closing component in automatic battery core feeding, tab cutting, shaping, detecting and blanking equipment and a position relationship between the opening and closing component and an index plate;

in the figure: 1. a work table; 2. a protective cover; 3. a feeding mechanism; 31. a mounting plate; 32. a tray; 33. a tray pallet; 34. a connecting column; 35. a fixing plate; 36. a first screw rod; 37. a driving motor; 38. a connecting bottom plate; 4. a first material conveying mechanism; 41. a material conveying frame; 42. a guide groove; 43. controlling a motor; 44. a fixed base; 45. a negative pressure suction cup assembly; 46. a lifting cylinder; 5. a cell position correction mechanism; 51. a correction mechanism mounting frame; 52. a conveyor belt; 53. a stop plate; 54. a straightening cylinder; 55. a poking plate; 56. a barrier strip; 6. a second material conveying mechanism; 7. an index plate; 71. a placement table; 72. a slip groove; 73. fastening a limiting block; 74. a fixed slide bar; 75. a connecting block; 76. a fixed block; 77. fixing a limit bolt; 78. an elastic member; 79. a toggle member; 710. an opening and closing cylinder; 711. a poking wheel; 8. electrode shaping means; 81. shaping frame; 82. shaping a first cylinder; 83. a first pressing block; 84. shaping cylinder II; 85. pressing a second block; 9. a cell electrode cutting mechanism; 10. the battery cell detection equipment; 11. the battery cell visual detection equipment; 12. a blanking mechanism; 13. a storage table; 14. empty disc storage area.

Description of the embodiments

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1 and 2, the present utility model provides a technical solution: the utility model provides a battery core automatic feeding, utmost point ear cuts, plastic, detection, unloading equipment, including workstation 1, have set gradually feed mechanism 3 according to work flow at workstation 1 top surface, first fortune material mechanism 4, electric core position correction mechanism 5, second fortune material mechanism 6, index plate 7, electrode shaping device 8, electric core electrode cuts mechanism 9, electric core check out test set 10, electric core vision check out test set 11 and unloading mechanism 12, be provided with at workstation 1 top surface and deposit bench 13, unloading mechanism 12 is used for transporting qualified electric core to deposit bench 13, cover is equipped with safety cover 2 on workstation 1 and wraps all mechanisms in it in order to increase the security of this equipment.

Referring to fig. 3 and 4, the feeding mechanism 3 includes a mounting plate 31 mounted on the workbench 1 and horizontally disposed, a tray supporting plate 33 for stacking the tray 32 is disposed on the top surface of the mounting plate 31, a plurality of connecting columns 34 vertically disposed downward and penetrating the mounting plate 31 are fixedly connected to the bottom surface of the tray supporting plate 33, a fixing plate 35 is fixedly connected to the bottom ends of the plurality of connecting columns 34, four connecting limiting columns vertically disposed downward are fixedly connected to the bottom surface of the mounting plate 31, the bottom ends of the four connecting limiting columns are fixedly connected to a connecting bottom plate 38, the connecting columns 34 penetrate the connecting bottom plate 38 and can slide along the connecting limiting columns in the vertical direction, the feeding mechanism 3 further includes a first rotatable screw rod 36 vertically disposed, one end of the first screw rod 36 is disposed on the bottom surface of the mounting plate 31, the other end of the first screw rod penetrates the connecting bottom plate 38, the fixing plate 35 is in threaded connection with the first screw rod 36, a driving motor 37 is fixedly connected to the bottom end of the first screw rod 36, a belt pulley is fixedly connected to the bottom end of the first screw rod 36, and the driving motor 37 drives the first screw rod 36 to rotate through a belt.

Referring to fig. 5, the first material transporting mechanism 4 includes a material transporting frame 41 fixed on the top surface of the working table 1 and a guiding groove 42 fixed on the material transporting frame 41 and horizontally arranged, a rotatable screw rod II is arranged in the guiding groove 42 along the length direction thereof, a control motor 43 for controlling the rotation of the screw rod II is fixed on the guiding groove 42, a sliding block is connected on the screw rod II in a threaded manner, the sliding block can move on the sliding block along the length direction of the screw rod II under the rotation of the screw rod II, a fixed base 44 is fixedly connected on the top surface of the sliding block, the fixed base 44 is attached to the side wall of the guiding groove 42 and bent downwards, a lifting cylinder 46 which is vertically arranged is fixedly connected on the vertical surface of the fixed base 44, a group of negative pressure sucker assemblies 45 for sucking the electrical core for transportation is fixedly connected on the bottom end of a piston rod of the lifting cylinder 46, an empty disc storage area 14 (see fig. 3) is arranged on a mounting plate 31 of the material transporting mechanism 3, the empty disc storage area 14 is positioned on a travelling route of the negative pressure sucker assemblies 45, and the negative pressure sucker assemblies 45 can transport the electrical core transporting the electrical core 32 to the empty disc storage area 14 under the operation of the control motor 43.

Referring to fig. 6, the cell position correction mechanism 5 includes a correction mechanism mounting frame 51 horizontally disposed on the top surface of the workbench 1 and a conveyor belt 52 horizontally disposed on the correction mechanism mounting frame 51, a stop plate 53 is fixedly connected to the correction mechanism mounting frame 51, the stop plate 53 is located at an end of the travel direction of the conveyor belt 52 and is used for blocking the movement of a cell on the conveyor belt 52, a correction cylinder 54 is fixed to the stop plate 53, a shift plate 55 is fixed to a piston rod of the correction cylinder 54, a stop bar 56 is disposed on one side of the conveyor belt 52 close to the dividing plate 7, and the correction cylinder 54 is used for enabling the shift plate 55 to shift the cell to be attached to the stop bar 56, and the stop plate 53 and the stop bar 56 enclose a feeding position on the top surface of the conveyor belt 52.

Referring to fig. 11 and 12, the dividing plate 7 is a horizontally placed disc, a rotating motor is arranged on the top surface of the worktable 1 to control the dividing plate 7 to rotate in the horizontal direction, a plurality of material fixing stations are distributed on the circumference of the top surface of the dividing plate 7 in an array manner, each material fixing station comprises a placing table 71 horizontally fixed on the dividing plate 7 and a material fixing component arranged on the placing table 71, the material fixing component comprises a pair of fastening limiting blocks 73 arranged on the top surface of the placing table 71 in the X-axis direction and one fastening limiting block 73 arranged on the Y-axis direction, two sliding grooves 72 arranged on the top surface of the placing table 71 in the X-axis direction and one sliding groove 72 arranged on the Y-axis direction, a fixing sliding bar 74 sliding along the sliding groove 72, each fastening limiting block 73 is fixed on one fixing sliding bar 74, one fastening limiting block 73 is fixed on the placing table 71 through bolts and the like, one end of the fixing sliding block is provided with a 75, one end of the sliding block is abutted against the other end of the sliding block 77, a connecting block 76 is arranged on the other end of the sliding block 77 and is fixed on the other end of the sliding block 77, a connecting block 76 is abutted to one end of the sliding block is fixed on the sliding block 77, a connecting block 76 is fixed on the other end of the sliding block 76 is fixed on the sliding block 76, and the sliding block is abutted to the sliding block is fixed on the sliding block 76, and the other end is abutted against the sliding block is fixed on the sliding block 76, and the sliding block is fixed on the sliding block 76, the connecting block 75 is attached to the fixing block 76 under the action of the elastic piece 78, and one action of the fixing block 76 is to limit the nearest position which can be reached when the fastening limiting blocks 73 are mutually closed, so that the fastening limiting blocks 73 are prevented from applying excessive pressure to the battery cell to cause damage.

Referring to fig. 12, an opening and closing component for enabling three fastening limiting blocks 73 to be far away from each other along a sliding groove 72 is arranged on a workbench 1, when a second material conveying mechanism 6 places materials on a placing table 71, the opening and closing component controls the three fastening limiting blocks 73 to be far away from each other so that a battery cell can be placed in a space surrounded by the three fastening limiting blocks 73, the opening and closing component comprises an opening and closing cylinder 710 fixed on the top surface of the workbench 1 and a stirring wheel 711 fixed on a piston rod of the opening and closing cylinder 710, an L-shaped stirring member 79 which is rotatably connected with the fixing block 76 is arranged on the fixing block 76, and when the stirring wheel 711 collides with the stirring member 79, the stirring member 79 rotates and collides with a connecting block 75 so that the connecting block 75 is far away from the fixing block 76, wherein the opening and closing component is fixed on the top surface of the workbench 1 through which a second material conveying component runs and the top surface of the workbench 1 through which a material discharging mechanism 12 runs.

The second material conveying mechanism 6 has the same structure as the first material conveying mechanism 4 and is used for conveying the battery cells on the feeding level of the battery cell position correcting mechanism 5 to a fixed station on the index plate 7.

Referring to fig. 7, the electrode shaping device 8 includes a shaping frame 81 fixed on the top surface of the workbench 1, a shaping cylinder one 82 fixed on the shaping frame 81 and arranged vertically downwards, a pressing block one 83 for flattening the electrode is fixed on a piston rod of the shaping cylinder one 82, the electrode shaping device 8 further includes a shaping cylinder two 84 fixed on the shaping frame 81 and arranged vertically downwards, and a pressing block two 85 for flattening the cell body is fixed on a piston rod of the shaping cylinder two 84.

Referring to fig. 8, 9 and 10, the cutting mechanism 9 for cutting the electrode is used for cutting the electrode; the cell detection device 10 is used for testing whether the cell functions normally; the electric core visual detection equipment 11 is used for detecting whether the appearance of the electric core is qualified, and the electric core electrode cutting mechanism 9, the electric core detection equipment 10 and the electric core visual detection equipment 11 are all existing special equipment and are annularly distributed on the periphery of the index plate 7 according to the process flow.

Referring to fig. 2, the structure of the blanking mechanism 12 is consistent with that of the first material conveying mechanism 4, the storage table 13 comprises a storage rack fixed on the top surface of the workbench 1 and a conveying belt arranged on the storage rack, the blanking mechanism 12 is used for transferring qualified electric cores onto the conveying belt of the storage table 13, a disqualified product placement area is arranged on the workbench 1, and the disqualified product placement area is located on the running path of the blanking mechanism 12.

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

when the device works, the first material moving mechanism 4 controls the operation of the motor 43 to enable the negative pressure sucker assembly 45 to move on the guide groove 42 along the second screw rod, so that the negative pressure sucker assembly 45 reaches the upper part of the tray supporting plate 33 and controls the negative pressure sucker assembly 45 to move downwards under the action of the lifting air cylinder 46 to suck the battery cells on the tray 32, then the lifting air cylinder 46 controls the negative pressure sucker assembly 45 to ascend and enables the negative pressure sucker assembly 45 to transfer the battery cells to the conveyor belt 52 on the battery cell position correcting mechanism 5 under the operation of the control motor 43, the conveyor belt 52 drives the battery cells to move and stop advancing under the blocking of the blocking plate 53 when reaching the feeding position, meanwhile, the piston rod of the swinging air cylinder 54 on the blocking plate 53 is contracted to enable the shifting plate 55 to shift the battery cells to be abutted to the blocking strip 56, at the moment, the conveyor belt 52 is operated to enable the two sides of the battery cells to be abutted to one side of the blocking plate 53 and one side of the blocking strip 56 respectively, then, the second material conveying mechanism 6 controls the negative pressure sucker assembly 45 on the second material conveying mechanism to convey the battery core on the conveyor belt 52 to the material fixing station on the dividing plate 7, before that, the dividing plate 7 rotates one material fixing station on the dividing plate 7 to a corresponding position under the control of the rotating motor, meanwhile, the opening and closing cylinder 710 on the moving path of the second material conveying mechanism 6 on the workbench 1 controls the shifting wheel 711 to move upwards, the shifting wheel 711 collides with the shifting piece 79 to enable the shifting piece 79 to rotate and drive the three fastening limiting blocks 73 to be far away, so that the battery core conveyed by the second material conveying mechanism 6 can be placed on the placing table 71, after the battery core can be placed on the placing table 71, the piston rod of the opening and closing cylinder 710 is contracted, so that the fastening limiting blocks 73 are mutually close under the action of the elastic piece 78 and the battery core is fixed at the fixed position on the placing table 71, then, the dividing disc 7 rotates to transfer the battery core on the material fixing station to the electrode shaping device 8, the first pressing block 83 and the second pressing block 85 on the electrode shaping device 8 respectively flatten the electrode and the battery core body under the action of the first shaping cylinder 82 and the second shaping cylinder 84, then, the dividing disc 7 rotates and sequentially passes through the battery core electrode cutting mechanism 9, the battery core detecting equipment 10 and the battery core visual detecting equipment 11 to cut and detect, when the material fixing station carrying the battery core reaches the position of the opening and closing component on the running path of the blanking mechanism 12, the opening and closing component controls the fastening limiting block 73 on the material fixing station to be mutually far away, so that the blanking mechanism 12 can take the battery core out and place the qualified battery core on the storage table 13, place the unqualified battery core on the unqualified product placing area, in addition, after the electric cores on the single tray 32 on the feeding mechanism 3 are all transferred, the first material conveying mechanism 4 controls the negative pressure sucker assembly 45 to transfer the empty tray to the empty tray placing area, meanwhile, the driving motor 37 drives the screw rod one 36 to rotate and enables the tray 32 stacked on the tray supporting plate 33 to ascend by one unit so that the tray 32 at the topmost layer ascends to the height of the original empty tray, each mechanism of the device is simple in structure, the whole operation flow of the device is simple and transparent, students and staff in colleges and universities, enterprise departments and the like can conveniently learn the working principle of the master die surface measuring machine, so that the students, the staff and the like can quickly put into production when encountering the master die surface measuring machine with the related principle during working, and can timely position and process when encountering the problem of the related device, the production is not affected.

Although embodiments of the present utility model 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 principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. Automatic battery core feeding, tab cutting, shaping, detecting and blanking equipment is characterized in that: the automatic feeding device comprises a workbench (1), wherein a feeding mechanism (3), a first material conveying mechanism (4), a battery cell position correcting mechanism (5), a second material conveying mechanism (6), an index plate (7), an electrode shaping device (8), a battery cell electrode cutting mechanism (9), a battery cell detecting device (10), a battery cell visual detecting device (11) and a discharging mechanism (12) are sequentially arranged on the top surface of the workbench (1) according to a working flow;

a tray (32) with batch of battery cores is arranged on the feeding mechanism (3); the first material conveying mechanism (4) is used for conveying the battery cells on the tray (32) to the battery cell position correcting mechanism (5); the battery cell position correction mechanism (5) is provided with a feeding level, and the battery cell position correction mechanism (5) is used for conveying the battery cell to the feeding level and correcting the feeding level; the top surface of the dividing disc (7) is provided with a plurality of material fixing stations; the second material conveying mechanism (6) is used for conveying the battery cells on the feeding level to a material fixing station on the dividing disc (7); the electrode shaping device (8) is used for leveling the battery core body and the electrode; the cell electrode cutting mechanism (9) is used for cutting the electrode; the battery cell detection equipment (10) is used for testing whether the function of the battery cell is normal or not; the battery cell visual detection equipment (11) is used for detecting whether the appearance of the battery cell is qualified or not; the top surface of the workbench (1) is provided with a storage table (13), and the blanking mechanism (12) is used for transferring qualified battery cells to the storage table (13);

the index plate (7) rotates in the horizontal direction under the action of a servo motor, and the second material conveying mechanism (6), the electrode shaping device (8), the battery cell electrode cutting mechanism (9), the battery cell detection equipment (10), the battery cell visual detection equipment (11) and the blanking mechanism (12) are sequentially arranged around the index plate (7).

2. The automatic battery cell feeding, tab cutting, shaping, detecting and blanking device according to claim 1, wherein: the utility model provides a fixed station of material is including placing platform (71), be provided with the fixed subassembly of material on placing platform (71), the fixed subassembly of material includes a pair of fastening stopper (73) that place platform (71) top surface X axis direction set up and one fastening stopper (73) in the Y axis direction, two sliding groove (72) that set up in the X axis direction and one sliding groove (72) that set up in the Y axis direction are seted up to the top surface of placing platform (71), three fastening stopper (73) sliding connection respectively in one sliding groove (72), the fixed station of material still includes elastic component (78), elastic component (78) are used for making three fastening stopper (73) draw close each other along sliding groove (72), be provided with on workstation (1) and be used for making three fastening stopper (73) keep away from each other along the opening and shutting subassembly of sliding groove (72), when second fortune material mechanism (6) place the material on placing platform (71), it can make three fastening stopper (73) keep away from each other so that three electricity core can become in the space of fastening stopper (73).

3. The automatic battery cell feeding, tab cutting, shaping, detecting and blanking device according to claim 2, wherein: feed mechanism (3) are including installing mounting panel (31) on workstation (1) and the level setting, mounting panel (31) top surface is provided with tray layer board (33) that are used for stacking tray (32), tray layer board (33) bottom surface fixedly connected with many vertical downwardly disposed and with spliced pole (34) that mounting panel (31) penetrated, many spliced pole (34) the bottom is fixed connection jointly on a fixed plate (35), feed mechanism (3) still include rotatable lead screw one (36) of a vertical setting, fixed plate (35) threaded connection is on lead screw one (36), lead screw one (36) make fixed plate (35) can be along lead screw one (36) in vertical direction motion through driving motor (37) control its motion.

4. The automatic battery cell feeding, tab cutting, shaping, detecting and blanking device according to claim 3, wherein: the first material conveying mechanism (4) comprises a material conveying frame (41) fixed on the top surface of the workbench (1) and a guide groove (42) horizontally arranged on the material conveying frame (41), a negative pressure sucker assembly (45) moving along the direction of the guide groove (42) is arranged on the guide groove (42), and the negative pressure sucker assembly (45) is used for sucking the battery cell for transferring.

5. The automatic battery cell feeding, tab cutting, shaping, detecting and blanking device according to claim 4, wherein: the mounting plate (31) is provided with an empty disc storage area (14), the empty disc storage area (14) is positioned on the advancing route of the negative pressure sucker assembly (45), and the negative pressure sucker assembly (45) can suck empty discs.

6. The automatic battery cell feeding, tab cutting, shaping, detecting and blanking device according to claim 2, wherein: the battery cell position correction mechanism (5) comprises a conveyor belt (52) horizontally arranged on the top surface of the workbench (1) and a stop plate (53) arranged at the end part of the travelling direction of the conveyor belt (52), one side of the conveyor belt (52) is provided with a stop bar (56), a straightening cylinder (54) is fixed on the stop plate (53), a shifting plate (55) is fixed on a piston rod of the straightening cylinder (54), the straightening cylinder (54) is used for enabling the shifting plate (55) to shift a battery cell to enable the battery cell to be attached to the stop bar (56), and the stop plate (53) and the stop bar (56) enclose a charging position on the top surface of the conveyor belt (52).

7. The automatic battery cell feeding, tab cutting, shaping, detecting and blanking device according to claim 2, wherein: electrode shaping device (8) are including fixing plastic frame (81) of workstation (1) top surface and fixing plastic cylinder one (82) of vertical decurrent setting on plastic frame (81), be fixed with briquetting one (83) that are used for flattening the electrode on the piston rod of plastic cylinder one (82), electrode shaping device (8) still include one vertical decurrent setting's that fixes plastic cylinder two (84) on plastic frame (81), be fixed with briquetting two (85) that are used for flattening the electric core body on the piston rod of plastic cylinder two (84).

8. The automatic battery cell feeding, tab cutting, shaping, detecting and blanking device according to claim 4, wherein: the structures of the second material conveying mechanism (6) and the blanking mechanism (12) are identical to those of the first material conveying mechanism (4).