CN223073204U - High-speed unloading mechanism for battery cell production - Google Patents

Abstract

The utility model discloses a high-speed blanking mechanism for battery cell production, and belongs to the technical field of battery cell production. The high-speed blanking mechanism comprises a conveying unit, a carrying unit and a blanking unit, wherein the conveying unit is used for conveying an upper layer and a lower layer respectively, a backflow module is arranged at the conveying front section and the tail end respectively, the backflow module is used for conveying a carrier on the upper layer and the lower layer, the carrying unit comprises a carrying robot, the carrying module is arranged at the working end of the carrying robot, and the blanking unit is used for blanking the carrier. The high-speed manufacturing work of the back section of the laminated battery cell is completed by combining all mechanisms together through ingenious layout, the layout can break through the bottleneck that the stations such as rubberizing, thickness measuring and two-dimension code sticking are slow in execution speed, high-speed manufacturing of the blade battery cell is realized, the maximum bottleneck that the existing blade battery is slow in manufacturing speed and high in cost can be broken through, the whole machine cost of the lamination machine is reduced, the occupied area of equipment of the lamination machine is reduced, the production cost of the blade battery is reduced to the greatest extent, and the market competitiveness of the blade battery is enhanced.

Description

High-speed blanking mechanism for battery cell production

Technical Field

The utility model relates to the technical field of blade battery production, in particular to a high-speed blanking mechanism for battery cell production.

Background

Blade batteries are a common battery type in the new energy automotive industry. The production speed of the traditional blade battery is difficult to break through 6PPM, the production speed is limited by the speed of sheet making, the post-stage stations such as rubberizing, weighing and hot pressing are also important bottlenecks, the post-stage manufacturing layout of the traditional blade battery is often unable to finish multi-sheet hot pressing, quick rubberizing, quick thickness measuring and short circuit testing of the blade battery core, and the layout of the traditional blade battery production is often limited by the speed of a streamline, the carrying speed of a manipulator, related layout and the like.

Therefore, the application aims to rapidly complete the rear-stage stations of the blade battery, such as preheating, hot pressing, rubberizing, stacking, thickness measuring, weighing and the like, and realizes the ultra-high-speed manufacturing of the blade battery in a brand-new layout.

Disclosure of utility model

In order to solve the technical problems, the utility model provides a high-speed blanking mechanism for battery cell production.

The technical scheme of the utility model is that the high-speed blanking mechanism for producing the battery cell comprises the following components:

The conveying unit comprises a conveying rack, two groups of conveying modules are arranged on the conveying rack in parallel along the vertical direction and are respectively used for conveying an upper layer and a lower layer, and reflux modules are respectively arranged at the conveying front section and the tail end of each conveying module and are used for conveying a carrier on the upper layer and the lower layer;

The conveying unit comprises a conveying robot, wherein a conveying module is arranged at the working end of the conveying robot and comprises a conveying substrate, at least two groups of conveying assemblies used for conveying blade cells are arranged on the conveying substrate, and

The blanking unit comprises a blanking frame positioned at the tail end of the conveying direction of the conveying unit, a blanking linear module perpendicular to the conveying unit is arranged on the blanking frame, and a blanking clamping module for clamping the battery cell of the blade is arranged on the blanking linear module through a lifting linear module.

Further, the conveying module comprises a conveying frame which is rectangular, conveying belts are respectively arranged on two sides of the conveying frame through conveying wheels, the two groups of conveying belts are synchronously driven through conveying connecting rods, and the conveying connecting rods are connected with a conveying motor. Through the setting of conveying structure, realized conveyer belt's synchronous motion.

Furthermore, generally, the conveying modules can be spliced and used in multiple sections according to actual needs, and the conveying modules are sequentially arranged along the straight line direction.

Further, the electric knife blade comprises a carrier, wherein the carrier comprises a bottom plate, a plurality of supporting blocks are arranged on the bottom plate, and at least one supporting block is respectively arranged on the periphery of the electric knife blade core. The length of the bottom plate is matched with the conveying module.

Further, a supporting inclined plane is arranged on the supporting block, and the supporting inclined plane is matched with the periphery of the blade cell. Realize the steady support to blade electricity core.

Further, the supporting block is connected with the bottom plate through the kidney-shaped hole. Can be adjusted according to actual needs or the size of the blade battery cell.

Further, at least two supporting blocks are arranged in the length direction of the blade battery cell in a matching mode, and at least one supporting block is arranged in the width direction. Further ensuring stable support.

Further, a hollowed-out hole is formed in the bottom plate. The weight of the carrier can be reduced.

The backflow module comprises a backflow support, a group of backflow conveying assemblies are arranged on the backflow support through backflow lifting assemblies which are symmetrically arranged, the backflow conveying assemblies are matched with the conveying module, and the backflow lifting assemblies comprise backflow lifting cylinders which are arranged in the vertical direction and are connected with the backflow conveying assemblies. Namely, the conveying of the upper layer and the lower layer is realized. The basic structure of the reflow conveyor assembly is identical to the conveyor module, but the conveyor length can be used to accommodate one carrier.

Further, a backflow baffle for blocking the carrier is further arranged on the backflow conveying assembly. And a buffer cushion is further arranged on one side of the reflux baffle, which is contacted with the carrier. Meanwhile, the sensor can be matched to sense the position of the carrier, so that the lifting operation is convenient.

Further, the tip of backward flow lift cylinder sets up backward flow lift connecting rod, sets up backward flow synchronizing wheel respectively at the both ends of backward flow lift connecting rod, set up backward flow hold-in range on the backward flow synchronizing wheel, backward flow hold-in range is the strip setting, and one end is connected with backward flow conveying assembly, and the other end is connected with backward flow support. Ensures the stability of lifting.

Furthermore, two ends of the reflux lifting connecting rod are also provided with linear bearings, and a linear guide rod is arranged in the linear bearings along the vertical direction. Further ensuring the stability of lifting.

Further, the handling robot is a multi-axis manipulator, and a six-axis manipulator is used in the application.

Further, the carrying substrate is connected with the carrying robot through the carrying flange seat.

Further, the carrying assembly comprises a carrying seat arranged on the carrying substrate, two carrying air cylinders are arranged on the carrying seat, carrying extension plates are arranged on each carrying air cylinder, and carrying hooks are arranged on the carrying extension plates. The blade battery core is supported by the carrying hooks which are respectively driven.

Further, still set up slide rail and slider between transport extension board and the transport seat, can guarantee stably.

Further, a carrying compression cylinder is further arranged on the carrying extension plate, and the end part of the carrying compression cylinder is provided with a carrying compression plate matched with the carrying hook. The compression of the blade battery core is realized.

Further, the carrying seat is arranged on the carrying substrate through a carrying rotary assembly, the carrying rotary assembly comprises a rotary bearing seat, the rotary bearing seat is fixedly arranged on the carrying substrate, a rotary shaft is arranged in the rotary bearing seat, one end of the rotary shaft is connected with the carrying seat, and the other end of the rotary shaft is connected with a rotary driving source. In general, the slewing drive source is a drive motor, which can rotate 360 degrees, and this configuration is not shown in the drawings of the present application.

Further, a return synchronous wheel is arranged on the rotary rotating shaft, and at least two rotary synchronous wheels are synchronously driven by a rotary synchronous belt. The synchronous rotation is realized, and the electric core is convenient to clamp and take.

Further, the blanking clamping module comprises a blanking clamping seat, wherein a clamping cylinder is arranged at the lower end of the blanking clamping seat, and clamping plates are respectively arranged on two clamping blocks of the clamping cylinder;

the clamping movable plate is arranged on the clamping plate in a matched mode through a vertical guide rail and a vertical guide block which are vertically arranged, an L-shaped hook jaw is arranged at the lower end of the clamping movable plate, a limiting plate is arranged on the clamping movable plate, a limiting block is arranged on the clamping plate, and the limiting plate is always located above the limiting block;

The clamping movable plate is provided with a pressing auxiliary plate matched with the hook claw through a vertical cylinder. The horizontal conveying of the blade battery cell is realized. And the smooth proceeding of the blanking is convenient.

Further, a preheating mechanism is arranged on one side of the conveying unit, a hot pressing mechanism is arranged on the other side of the conveying unit, the conveying unit moves the blade cell between the three,

Meanwhile, a rubberizing mechanism is arranged at a position, close to the tail end, of the conveying unit;

The tail end of the conveying unit is provided with an alternate thickness measuring mechanism and a two-dimension code pasting mechanism. The functional mechanism belongs to the existing equipment and is not described in detail in the present application.

The utility model has the beneficial technical effects that the double-layer up-down backflow belt conveyor line, the double-motor linear motor, the six-axis robot and other instruments are skillfully combined together to finish the ultra-high-speed manufacturing of the rear section of the blade battery, and the manufacturing speed of the battery core is as high as 10PPM. The utility model overcomes the disadvantages of inflexible carrying of the mechanical arm, limited carrying speed of the mechanical arm and the like, realizes flexible and quick carrying of the battery core by adopting a six-axis robot, a linear motor and other mechanisms, can quickly and flexibly carry the battery core to a designated station, enables a functional mechanism to quickly realize rubberizing, thickness measurement and weighing of the battery core, can realize carrying and staying of the battery core by adopting a double-layer belt line carrier for backflow, can realize the stay and positioning of the battery core at any time by adding mechanisms such as blocking positioning or sensor control on the double-layer belt line and the like, and provides convenience for smoothly executing the rubberizing station and carrying of the battery core, and can realize 10PPM of which the hot pressing, rubberizing, thickness measurement and weighing speed of the battery core reach requirements by skillfully combining the mechanisms.

Meanwhile, the invention adopts two six-axis robots, a carrier backflow double-layer belt line, a double-motor linear motor, a double-station thickness measuring mechanism and the like to manufacture an ultra-high speed blade battery manufacturing line, the characteristics of carrying the battery cells rapidly by using the double-layer belt line carrier backflow can be used for receiving the battery cells well manufactured at any time and any place, the procedures of rubberizing and the like can be completed at any time and any place, the battery cells can be grabbed at a wide angle by using the characteristics of high flexibility and the like of the six-axis robots, the battery cells can be carried to a proper position by using the speed advantage of the linear motor, and the alternating double-station thickness measuring mechanism can be used for realizing the rapid thickness measurement and short circuit test of the battery cells.

The invention can break through the biggest bottleneck of low manufacturing speed and high cost of the traditional blade battery, reduce the whole machine cost of the lamination machine, reduce the occupied area of equipment of the lamination machine, thereby reducing the production cost of the blade battery to the maximum extent and enhancing the market competitiveness of the blade battery.

Drawings

Fig. 1 is a schematic overall layout of a high-speed blanking mechanism.

Fig. 2 is a schematic perspective layout of a high-speed blanking mechanism.

Fig. 3 is a schematic diagram of the cooperation of the reflow module and the blanking unit.

Fig. 4 is a schematic diagram of the cooperation of the transport module and the reflow module.

Fig. 5 is a schematic diagram of a transport module.

Fig. 6 is a schematic diagram of a reflow module.

Fig. 7 is a schematic view of a handling unit.

Fig. 8 is a schematic view of a handling assembly and a handling swing assembly.

Fig. 9 is a schematic view of a handling assembly.

Fig. 10 is a schematic view of a carrier.

Fig. 11 is a schematic diagram of a blanking unit.

Fig. 12 is a schematic view of the blanking clamp module.

Fig. 13 is a schematic view of the internal structure of fig. 12.

Wherein:

1. A conveying unit (11), a conveying frame (12), a conveying module (121), a conveying frame (122), a conveying wheel (123), a conveying belt (124), a conveying connecting rod (125), a conveying motor (13), a reflow module (131), a reflow bracket (132), a reflow lifting assembly (133), a reflow conveying assembly,

2. A carrying unit 21, a carrying robot 22, a carrying module 23, a carrying substrate 24, a carrying assembly 241, a carrying seat 242, a carrying cylinder 243, a carrying extension plate 244, a carrying hook 245, a carrying press cylinder 246, a carrying press plate 26, a carrying swivel assembly 261, a swivel bearing seat 262, a swivel synchronizing wheel 263, a swivel synchronizing belt,

3. The blanking unit, 31, blanking frame, 32, blanking linear module, 33, lifting linear module, 34, blanking clamping module, 341, blanking clamping seat, 342, clamping cylinder, 343, clamping plate, 344, clamping movable plate, 345, hook claw, 346, limiting plate, 347, limiting block, 348, vertical cylinder, 349, pressing auxiliary plate,

4. The carrier, 41, the bottom plate, 42 and the supporting block,

5. The device comprises a preheating mechanism, a hot pressing mechanism, a rubberizing mechanism, an alternating thickness measuring mechanism, a two-dimensional code pasting mechanism and a two-dimensional code pasting mechanism.

Detailed Description

In order that the manner in which the above recited features of the present utility model are attained and can be understood in detail, a more particular description of the utility model, briefly summarized below, may be had by reference to the appended drawings and examples, which are illustrated in their embodiments, but are not intended to limit the scope of the utility model.

Referring to fig. 1-13, a high-speed blanking mechanism for producing a battery cell according to this embodiment includes:

The conveying unit 1, the conveying unit 1 comprises a conveying rack 11, two groups of conveying modules 12 are arranged on the conveying rack 11 in parallel along the vertical direction and are respectively used for upper-layer conveying and lower-layer conveying, a backflow module 13 is also respectively arranged at the conveying front section and the tail end of the conveying module 12, and the backflow module 13 is used for conveying the carrier 4 at the upper layer and the lower layer;

A carrying unit 2, the carrying unit 2 comprising a carrying robot 21, a carrying module 22 disposed at a working end of the carrying robot 21, the carrying module 22 comprising a carrying substrate 23, at least two carrying modules 24 disposed on the carrying substrate 23 for carrying the blade cells, and

The blanking unit 3, the blanking unit 3 includes a blanking frame 31 at the end of the conveying direction of the conveying unit 1, a blanking linear module 32 perpendicular to the conveying unit 1 is arranged on the blanking frame 31, and a blanking clamping module 34 for clamping the blade cell is arranged on the blanking linear module 32 through a lifting linear module 33.

Further, the conveying module 12 comprises a conveying frame 121 which is rectangular, conveying belts 123 are respectively arranged on two sides of the conveying frame 121 through conveying wheels 122, the two groups of conveying belts 123 are synchronously driven through conveying connecting rods 124, and the conveying connecting rods 124 are connected with conveying motors 125. By the arrangement of the conveying structure, the synchronous movement of the conveying belt 123 is realized.

Further, generally, the conveying modules 12 may be used in multiple sections according to actual needs, and may be sequentially arranged along a straight line.

Further, the electric knife blade also comprises a carrier 4, wherein the carrier 4 comprises a bottom plate 41, a plurality of supporting blocks 42 are arranged on the bottom plate 41, and at least one supporting block 42 is respectively arranged on the periphery of the electric knife blade core. The length of the base plate 41 is compatible with the conveyor module 12.

Further, a supporting inclined plane is arranged on the supporting block 42, and the supporting inclined plane is matched with the periphery of the blade cell. Realize the steady support to blade electricity core.

Further, the support block 42 is connected to the bottom plate 41 through a kidney-shaped hole. Can be adjusted according to actual needs or the size of the blade battery cell.

Further, at least two support blocks 42 are disposed in the longitudinal direction of the blade cell in a matching manner, and at least one support block 42 is disposed in the width direction. Further ensuring stable support.

Further, a hollowed-out hole is provided in the bottom plate 41. The weight of the carrier 4 can be reduced.

Further, the reflow module 13 comprises a reflow bracket 131, wherein a group of reflow conveying assemblies 133 are arranged on the reflow bracket 131 through reflow lifting assemblies 132 which are symmetrically arranged, the reflow conveying assemblies 133 are matched with the conveying module 12, and the reflow lifting assemblies 132 comprise reflow lifting cylinders which are arranged along the vertical direction and are connected with the reflow conveying assemblies 133. Namely, the conveying of the upper layer and the lower layer is realized. The basic structure of the return transport assembly 133 corresponds to the transport module 12, but its transport length is sufficient to accommodate one carrier 4.

Further, a back flow baffle for blocking the carrier 4 is further provided on the back flow conveying assembly 133. The side of the reflux baffle plate contacted with the carrier 4 is also provided with a buffer cushion. Meanwhile, the sensor can be matched to sense the position of the carrier 4, so that the lifting operation is convenient.

Further, the end of the backflow lifting cylinder is provided with a backflow lifting connecting rod, two ends of the backflow lifting connecting rod are respectively provided with a backflow synchronous wheel, the backflow synchronous wheels are provided with backflow synchronous belts, the backflow synchronous belts are arranged in a strip shape, one end of each backflow synchronous belt is connected with the backflow conveying assembly 133, and the other end of each backflow synchronous belt is connected with the backflow bracket 131. Ensures the stability of lifting.

Furthermore, two ends of the reflux lifting connecting rod are also provided with linear bearings, and a linear guide rod is arranged in the linear bearings along the vertical direction. Further ensuring the stability of lifting.

Further, the transfer robot 21 is a multi-axis robot, and a six-axis robot is used in the present application.

Further, the transfer substrate 23 is connected to the transfer robot 21 via a transfer flange base.

Further, the transfer unit 24 includes a transfer base 241 provided on the transfer substrate 23, two transfer cylinders 242 provided on the transfer base 241, a transfer extension plate 243 provided on each transfer cylinder 242, and a transfer hook 244 provided on the transfer extension plate 243. Namely, the blade cell is supported by the transport hooks 244 which are driven respectively.

Further, a slide rail and a slide block are further disposed between the carrying extension plate 243 and the carrying base 241, so that stability can be ensured.

Further, a conveying and pressing cylinder 245 is further provided on the conveying extension plate 243, and a conveying and pressing plate 246 engaged with the conveying hook 244 is provided at an end of the conveying and pressing cylinder 245. The compression of the blade battery core is realized.

Further, the carrying base 241 is provided on the carrying substrate 23 by a carrying swivel assembly 26, the carrying swivel assembly 26 includes a swivel bearing seat 261, the swivel bearing seat 261 is fixedly provided on the carrying substrate 23, a swivel rotary shaft is provided in the swivel bearing seat 261, one end of the swivel rotary shaft is connected with the carrying base 241, and the other end of the swivel rotary shaft is connected with a swivel drive source. In general, the slewing drive source is a drive motor, which can rotate 360 degrees, and this configuration is not shown in the drawings of the present application.

Further, a return synchronizing wheel is disposed on the rotary shaft, and at least two rotary synchronizing wheels 262 are synchronously driven by a rotary synchronizing belt 263. The synchronous rotation is realized, and the electric core is convenient to clamp and take.

Further, the blanking clamping module 34 comprises a blanking clamping seat 341, a clamping cylinder 342 is arranged at the lower end of the blanking clamping seat 341, and clamping plates 343 are respectively arranged on two clamping blocks of the clamping cylinder 342;

The clamping movable plate 344 is arranged on the clamping plate 343 through the matching of a vertical guide rail and a vertical guide block which are vertically arranged, the L-shaped hook 345 is arranged at the lower end of the clamping movable plate 344, the limiting plate 346 is arranged on the clamping movable plate 344, the limiting block 347 is arranged on the clamping plate 343, and the limiting plate 346 is always positioned above the limiting block 347;

A pressing auxiliary plate 349 engaged with the hooking jaw 345 is provided on the gripping movable plate 344 through a vertical cylinder 348. The horizontal conveying of the blade battery cell is realized. And the smooth proceeding of the blanking is convenient.

Further, a preheating mechanism 5 is arranged on one side of the conveying unit 1, a hot pressing mechanism 6 is arranged on the other side of the conveying unit, the conveying unit 2 moves the blade cell among the three,

Meanwhile, a rubberizing mechanism 7 is arranged at a position of the conveying unit 1 close to the tail end;

An alternate thickness measuring mechanism 8 and a two-dimension code pasting mechanism 9 are arranged at the tail end of the conveying unit 1. The functional mechanism belongs to the existing equipment and is not described in detail in the present application.

The double-layer up-down reflux belt conveying line, the double-motor linear motor, the six-axis robot and other instruments are skillfully combined together to finish the ultra-high-speed manufacturing of the rear section of the blade battery, and the manufacturing speed of the battery core is up to 10PPM. The invention overcomes the disadvantages of inflexible carrying of the mechanical arm, limited carrying speed of the mechanical arm and the like, realizes flexible and quick carrying of the battery core by adopting a six-axis robot, a linear motor and other mechanisms, can quickly and flexibly carry the battery core to a designated station, ensures that a functional mechanism can quickly realize rubberizing, thickness measurement and weighing of the battery core, can realize carrying and staying of the battery core by adopting a double-layer belt line carrier 4 for backflow, can realize the stay and positioning of the battery core at any time by adding mechanisms such as blocking positioning or sensor control on the double-layer belt line and the like, and provides convenience for smoothly executing the rubberizing station and carrying of the battery core, and can realize 10PPM of hot pressing, rubberizing, thickness measurement and weighing speed of the battery core to meet the requirements by skillfully combining the mechanisms.

Meanwhile, the invention adopts two six-axis robots, a carrier 4 to reflow a double-layer belt line, a double-motor linear motor, a double-station thickness measuring mechanism and the like to manufacture an ultra-high speed blade battery manufacturing line, the characteristics of carrying the battery cells quickly by using the double-layer belt line carrier 4 to reflow can receive the battery cells well manufactured at any time and any place, the procedures of rubberizing and the like can be completed at any time and any place, the battery cells can be grabbed at a wide angle by using the characteristics of high flexibility and the like of the six-axis robots, the battery cells can be carried to a proper position by using the speed advantage of the linear motor, and the alternating double-station thickness measuring mechanism can realize quick thickness measuring and short circuit testing of the battery cells. The suspension of the conveying line and the accurate positioning by using the sensor are relatively prior art, so that the description is omitted.

The invention can break through the biggest bottleneck of low manufacturing speed and high cost of the traditional blade battery, reduce the whole machine cost of the lamination machine, reduce the occupied area of equipment of the lamination machine, thereby reducing the production cost of the blade battery to the maximum extent and enhancing the market competitiveness of the blade battery.

The invention adopts a layout as shown in fig. 1-2, the flow direction of a blade cell is from top to bottom in fig. 1, in fig. 2, a six-axis manipulator conveys the cell from a preheating mechanism to a hot pressing mechanism for hot pressing, then the six-axis manipulator conveys the cell from a hot pressing module to a double-layer belt line, two manipulators simultaneously take down the cell on 10 hot presses and put the cell on a double-layer belt reflow line, then the double-layer belt reflow line conveys the cell to a rubberizing position, after rubberizing, the cell is conveyed to a blanking unit by a double-layer belt conveying mechanism, the blanking unit picks up the cell on the double-layer belt line, a linear motor conveys the cell to an alternate thickness measuring mechanism, the thickness measurement of the cell and the blanking action of the cell are completed by the alternate thickness measuring mechanism, after the blanking action of the blanking unit is completed, the cell is conveyed to the initial position by the lower-layer belt line for reflow, the cell is conveyed on the blanking conveying line, the cell is conveyed to the rubberizing position on the blanking conveying line, and the two-dimensional code of the cell is completed.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, and it should be noted that it is possible for those skilled in the art to make several improvements and modifications without departing from the technical principle of the present utility model, and these improvements and modifications should also be regarded as the protection scope of the present utility model.

Claims (10)

1. A high-speed feed mechanism for electricity core production, its characterized in that includes:

The conveying unit (1), the conveying unit (1) comprises a conveying rack (11), two groups of conveying modules (12) are arranged on the conveying rack (11) in parallel along the vertical direction and are respectively used for upper-layer conveying and lower-layer conveying, a backflow module (13) is further arranged at the conveying front section and the tail end of the conveying module (12), and the backflow module (13) is used for conveying the carrier (4) on the upper layer and the lower layer;

A carrying unit (2), wherein the carrying unit (2) comprises a carrying robot (21), a carrying module (22) is arranged at the working end of the carrying robot (21), the carrying module (22) comprises a carrying substrate (23), at least two groups of carrying assemblies (24) for carrying blade cells are arranged on the carrying substrate (23), and

The blanking unit (3), blanking unit (3) is including being located at the terminal unloading frame (31) of conveying unit (1) direction of delivery, set up on unloading frame (31) with conveying unit (1) vertically unloading sharp module (32) blanking sharp module (33) are passed through simultaneously on unloading sharp module (32) set up the unloading of clamping blade electric core and press from both sides and get module (34).

2. The high-speed discharging mechanism for cell production according to claim 1, wherein the conveying module (12) comprises a conveying frame (121) which is rectangular, conveying belts (123) are respectively arranged on two sides of the conveying frame (121) through conveying wheels (122), the two groups of conveying belts (123) are synchronously driven through conveying connecting rods (124), and the conveying connecting rods (124) are connected with a conveying motor (125).

3. The high-speed blanking mechanism for cell production according to claim 1, further comprising a carrier (4), wherein the carrier (4) comprises a bottom plate (41), a plurality of supporting blocks (42) are arranged on the bottom plate (41), and at least one supporting block (42) is respectively arranged on the periphery of the blade cell.

4. The high-speed blanking mechanism for battery cell production according to claim 1, wherein the reflow module (13) comprises a reflow bracket (131), a group of reflow conveying assemblies (133) are arranged on the reflow bracket (131) through reflow lifting assemblies (132) which are symmetrically arranged, the reflow conveying assemblies (133) are matched with the conveying module (12), and the reflow lifting assemblies (132) comprise reflow lifting cylinders which are arranged along the vertical direction and are connected with the reflow conveying assemblies (133).

5. The high-speed discharging mechanism for cell production according to claim 1, wherein the carrying substrate (23) is connected with the carrying robot (21) through a carrying flange seat, the carrying assembly (24) comprises a carrying seat (241) arranged on the carrying substrate (23), two carrying cylinders (242) are arranged on the carrying seat (241), a carrying extension plate (243) is arranged on each carrying cylinder (242), and a carrying hook (244) is arranged on the carrying extension plate (243).

6. The high-speed blanking mechanism for battery cell production according to claim 5, wherein a carrying compression cylinder (245) is further arranged on the carrying extension plate (243), and a carrying compression plate (246) matched with the carrying hook (244) is arranged at the end part of the carrying compression cylinder (245).

7. The high-speed discharging mechanism for cell production according to claim 5, wherein the carrying seat (241) is arranged on the carrying substrate (23) through a carrying rotary assembly (26), the carrying rotary assembly (26) comprises a rotary bearing seat (261), the rotary bearing seat (261) is fixedly arranged on the carrying substrate (23), a rotary rotating shaft is arranged in the rotary bearing seat (261), one end of the rotary rotating shaft is connected with the carrying seat (241), and the other end of the rotary rotating shaft is connected with a rotary driving source.

8. The high-speed discharging mechanism for battery cell production according to claim 7, wherein a return synchronizing wheel is arranged on the rotary shaft, and at least two rotary synchronizing wheels (262) are synchronously driven by a rotary synchronizing belt (263).

9. The high-speed discharging mechanism for producing the battery cells according to claim 1, wherein the discharging clamping module (34) comprises a discharging clamping seat (341), a clamping cylinder (342) is arranged at the lower end of the discharging clamping seat (341), and clamping plates (343) are respectively arranged on two clamping blocks of the clamping cylinder (342);

The clamping plate (343) is provided with a clamping movable plate (344) through a vertical guide rail and a vertical guide block which are vertically arranged in a matching manner, the lower end of the clamping movable plate (344) is provided with an L-shaped hook claw (345), meanwhile, the clamping movable plate (344) is provided with a limiting plate (346), the clamping plate (343) is provided with a limiting block (347), and the limiting plate (346) is always positioned above the limiting block (347);

A pressing auxiliary plate (349) matched with the hook claw (345) is arranged on the clamping movable plate (344) through a vertical air cylinder (348).

10. The high-speed blanking mechanism for battery cell production according to claim 1 is characterized in that a preheating mechanism (5) is arranged on one side of a conveying unit (1), a hot pressing mechanism (6) is arranged on the other side of the conveying unit, a carrying unit (2) moves a blade battery cell among the three, meanwhile, a rubberizing mechanism (7) is arranged on the conveying unit (1) in a matched mode, an alternate thickness measuring mechanism (8) and a two-dimension code pasting mechanism (9) are arranged at the tail end of the conveying unit (1), and the blanking unit (3) performs blanking on the blade battery cell.