CN216084972U - Lamination equipment and battery core - Google Patents

Abstract

The utility model is suitable for the technical field of battery forming, and provides lamination equipment, which comprises a support frame; the bag making device is used for making the upper diaphragm belt, the plurality of first pole pieces and the lower diaphragm belt into a composite belt material, the plurality of first pole pieces are arranged between the upper diaphragm belt and the lower diaphragm belt and are distributed at intervals along the length direction of the composite belt material, and one first pole piece and the upper diaphragm belt and the lower diaphragm belt which cover the two sides of the first pole piece form a diaphragm bag; a lamination device for folding the composite strip material to overlap a plurality of membrane bags; and the clamping device is arranged on the support frame and is adjacent to the lamination device, and the clamping device is used for clamping the second pole piece in the process of folding the composite strip by the lamination device and placing the second pole piece between adjacent diaphragm bags to form the battery cell. The utility model also provides a battery cell. The utility model solves the problems that the diaphragm is easy to tear and the lamination efficiency is not easy to improve in the cell lamination process.

Description

Lamination equipment and battery core

Technical Field

The utility model belongs to the technical field of battery forming, and particularly relates to lamination equipment and a battery core.

Background

In the production process of forming the lithium ion battery cell, single positive and negative plates are loaded by traditional lamination equipment, the positive and negative plates are moved to a lamination table by a manipulator, a diaphragm and a pole piece are pressed by a pressing knife mechanism above the lamination table, and the lamination table and the diaphragm vertically perform relative reciprocating motion to form the cell with a Z-shaped lamination laminated structure.

In the relative motion process that lamination platform and diaphragm unreeled, need set up tension control system after the diaphragm unreels usually to avoid producing sudden change tension to the diaphragm and make the diaphragm tear easily, however, because the diaphragm is thinner, tension control system is difficult to accurate reaction when the lamination accelerates, still can lead to the diaphragm to produce too big pulling force and make the diaphragm tear, has restricted the speed of lamination equipment to promote.

SUMMERY OF THE UTILITY MODEL

The utility model provides lamination equipment and a battery cell, and aims to solve the problems that a diaphragm is easy to tear and the speed of the lamination equipment is difficult to increase in the battery cell forming process.

An embodiment of the first aspect of the utility model proposes a lamination device comprising:

a support frame;

the bag making device is arranged on the support frame and is used for making an upper diaphragm belt, a plurality of first pole pieces and a lower diaphragm belt into a composite belt material, the plurality of first pole pieces are arranged between the upper diaphragm belt and the lower diaphragm belt and are distributed at intervals along the length direction of the composite belt material, and one first pole piece and the upper diaphragm belt and the lower diaphragm belt covering the two sides of the first pole piece form a diaphragm bag;

the laminating device is arranged on the support frame and positioned on one side of the bag making device and is used for folding the composite strip material to enable a plurality of diaphragm bags to be overlapped;

and the clamping device is arranged on the support frame and adjacent to the lamination device, and is used for clamping a second pole piece in the process of folding the composite strip by the lamination device and placing the second pole piece between the adjacent diaphragm bags to form a battery cell.

The lamination equipment comprises a bag making device, a lamination device and a material clamping device, wherein an upper diaphragm belt, a plurality of first pole pieces and a lower diaphragm belt are prepared into a composite belt material through the bag making device, the composite belt material is folded by the lamination device, and meanwhile, a second pole piece is placed between the laminated first pole pieces by the material clamping device, so that a laminated battery cell can be manufactured; because the tensile resistance of the composite strip is strong, the diaphragm is not easy to tear due to fluctuating tensile force in the lamination process, a precondition is provided for the acceleration of the lamination process, and the lamination efficiency of the battery cell is favorably improved.

In one embodiment, a first seal is disposed between adjacent membrane bags; along the width direction of the composite strip material, two sides of each diaphragm bag are provided with second seals, the first seals and the second seals are wound on the peripheral sides of the first pole pieces, and the lamination device folds the composite strip material along the first seals; one side of the first pole piece is provided with a pole lug which is positioned on the outer side of the diaphragm bag.

By adopting the technical scheme, the first pole piece is packaged in the diaphragm bag, the position of the first pole piece is fixed, the first pole piece, the second pole piece and the diaphragm are prevented from being in a loose state to cause pole piece dislocation, and further, the phenomenon of short circuit caused by contact of positive and negative current collectors is avoided, therefore, the short circuit problem after pole piece dislocation is solved by the laminating device, and the safety of the battery cell is improved.

In one embodiment, the lamination device comprises: the guide roller is used for guiding the composite strip; the lamination mechanism is arranged opposite to the guide roller; and the swing arm mechanism is arranged between the guide roller and the lamination mechanism and is used for driving the composite strip to reciprocate along a Z shape so as to stack a plurality of diaphragm bags on the lamination mechanism.

Through adopting above-mentioned technical scheme, swing arm mechanism can realize folding repeatedly to fold the compound area material in lamination mechanism, when folding compound area material, make things convenient for first pole piece and second pole piece to fold the setting.

In an embodiment, the swing arm mechanism includes a swing arm and two pairs of compression rollers connected to two ends of the swing arm, a gap for the composite strip to pass through is provided between each pair of compression rollers, and the swing arm can swing back and forth relative to the lamination mechanism to sequentially stack the plurality of diaphragm bags in the composite strip on the lamination mechanism.

Through adopting above-mentioned technical scheme, swing arm mechanism's simple structure, convenient operation can realize folding repeatedly in succession, and folding efficiency is higher.

In an embodiment, the lamination device further includes two feeding devices respectively disposed at two sides of the lamination mechanism, and the feeding devices are configured to accommodate the second pole pieces and sequentially feed the second pole pieces;

the material clamping device comprises two clamping mechanisms which are respectively arranged on two sides of the lamination mechanism, the two clamping mechanisms alternately grab the corresponding second pole piece on the feeding device and stack the second pole piece on the lamination mechanism, so that the second pole piece and the first pole piece are alternately stacked.

Through adopting above-mentioned technical scheme, two fixture can the centre gripping second pole piece on the corresponding loading attachment to arrange the second pole piece in on the compound area material respectively from the left side or the right side of compound area material, thereby realized continuous lamination processing procedure, promoted lamination efficiency.

In one embodiment, the bag making device comprises a feeding mechanism, a slicing mechanism and a bag making mechanism which are arranged in sequence;

the feeding mechanism comprises an upper diaphragm feeding roller, a pole piece feeding roller and a lower diaphragm feeding roller which are arranged from top to bottom at intervals and are respectively used for winding the upper diaphragm belt, a first pole piece belt comprising a plurality of first pole pieces and the lower diaphragm belt;

the slicing mechanism comprises a cutting traction roller, a cutting knife, a pole piece positioning table, a feeding platform and a feeding transfer part, wherein the cutting traction roller, the cutting knife, the pole piece positioning table and the feeding platform are sequentially arranged, the feeding transfer part is movably arranged above the pole piece positioning table and the feeding platform, the cutting traction roller is used for drawing a first pole piece belt on a pole piece feeding roller to the first pole piece positioning table, the cutting knife is used for cutting a first pole piece from the first pole piece belt, the feeding transfer part is used for transferring the cut first pole piece to the feeding platform and enabling the first pole piece to be attached to a lower diaphragm belt conveyed to the feeding platform;

the bag making mechanism comprises a bag making traction roller and a bag making machine which are arranged adjacently, the bag making traction roller is used for simultaneously drawing the upper diaphragm belt, the first pole piece and the lower diaphragm belt after being attached, and the bag making machine is used for making the upper diaphragm belt, the first pole piece and the lower diaphragm belt into the composite belt material.

By adopting the technical scheme, the bag making device can realize the continuous production of incoming materials and bags, and has higher production efficiency.

In one embodiment, the feeding mechanism further comprises a first guide roller assembly and a second guide roller assembly;

the first guide roller assembly is arranged between the upper membrane feeding roller and the bag-making traction roller along the conveying direction of the upper membrane strip and used for guiding the upper membrane strip to the bag-making traction roller; the second guide roller assembly is arranged between the lower membrane feeding roller and the feeding platform and used for guiding the lower membrane strip to the feeding platform.

By adopting the technical scheme, the first guide roller assembly and the second guide roller assembly can guide and tension the upper diaphragm belt and the lower diaphragm belt, and can also enable the upper diaphragm belt and the lower diaphragm belt to avoid and cut the traction roller, the cutting knife and the pole piece positioning table, so that the lamination efficiency is improved.

In an embodiment, the lamination equipment further includes a blanking device disposed on the support frame, the blanking device is disposed on a side of the lamination device away from the bag making device, and the blanking device is configured to grab the battery cell on the lamination device and drive the battery cell to blank.

Through adopting above-mentioned technical scheme, lamination equipment can be through the unloading of unloader to electric core, and degree of automation and preparation efficiency are higher.

In one embodiment, the first pole piece is a negative pole piece, and the second pole piece is a positive pole piece.

By adopting the technical scheme, the positive plate is convenient to be arranged between the adjacent negative plates.

An embodiment of a second aspect of the present invention provides a battery cell, including:

the composite strip material comprises an upper diaphragm strip, a lower diaphragm strip and a plurality of first pole pieces arranged between the upper diaphragm strip and the lower diaphragm strip, wherein one first pole piece and the upper diaphragm strip and the lower diaphragm strip covering the two sides of the first pole piece form a diaphragm bag, and the diaphragm bags are arranged oppositely and overlapped; and

a plurality of second pole pieces sequentially overlapping the plurality of membrane bags.

Above-mentioned electric core includes composite strip material and a plurality of second pole piece, because composite strip material is by last diaphragm area, lower diaphragm area and locate the diaphragm area and down the compound a plurality of first pole pieces between the diaphragm area form, the stretching resistance of composite strip material is stronger, and the diaphragm is difficult for receiving undulant pulling force and takes place to tear in the lamination in-process, also provides the prerequisite for the speeding up of range upon range of process, is favorable to promoting the lamination efficiency of electric core.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

FIG. 1 is a front view of a lamination apparatus in an embodiment of the present invention;

FIG. 2 is an enlarged view of portion A of the lamination apparatus shown in FIG. 1;

FIG. 3 is an enlarged view of a portion B of the lamination apparatus shown in FIG. 1;

FIG. 4 is a schematic perspective view of the lamination apparatus shown in FIG. 1;

FIG. 5 is an enlarged partial view of portion C of the lamination apparatus shown in FIG. 4;

FIG. 6 is a schematic view of a portion of the lamination assembly of the lamination apparatus shown in FIG. 1;

FIG. 7 is a schematic illustration of the structure of a composite strip in an embodiment of the present invention;

FIG. 8 is an exploded schematic view of the composite strip shown in FIG. 7;

fig. 9 is a schematic diagram of a cell provided by an embodiment of the present invention during a lamination process;

fig. 10 is a schematic flow chart of a method for manufacturing a battery cell according to an embodiment of the present invention.

The designations in the figures mean:

100. a lamination device;

10. a support frame; 11. a support plate; 12. a support table;

20. a bag making device;

21. a feeding mechanism; 211. an upper diaphragm feeding roller; 212. a pole piece feeding roller; 213. a lower diaphragm feed roller; 214. a first guide roller assembly; 215. a second guide roller assembly;

22. a slicing mechanism; 221. cutting a traction roller; 222. cutting knife; 223. a pole piece positioning table; 224. a feeding platform; 225. a feeding and transferring member;

23. a bag making mechanism; 231. a bag making traction roller; 232. a bag making machine;

30. a lamination device; 31. a guide roller; 32. a lamination mechanism; 33. a swing arm mechanism; 331. swinging arms; 332. a compression roller;

40. a material clamping device; 41. a clamping mechanism;

50. a feeding device;

60. a blanking device;

1. an electric core; 2. compounding the belt material; 3. an upper membrane band; 4. a first pole piece; 401. a tab; 5. a lower membrane band; 6. a first seal; 7. a second seal; 8. a second pole piece.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail below with reference to the accompanying drawings, which are examples. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "inner," "outer," and the like, as used herein, refer to an orientation or positional relationship illustrated in the drawings for convenience in describing the present application and to simplify description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be considered limiting of the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

To illustrate the technical solution of the present invention, the following description is made with reference to the specific drawings and examples.

An embodiment of the first aspect of the present invention provides a lamination apparatus for preparing a battery cell. Referring to fig. 1 to 6, the laminating apparatus 100 includes a support frame 10, and a bag-making device 20, a laminating device 30 and a material-clamping device 40 disposed on the support frame 10.

The support frame 10 may include a support plate 11 and a support base 12 connected to one side of the support plate 11, but is not limited thereto, and the present application does not limit the structure of the support frame 10 as long as the bag-making device 20, the laminating device 30 and the clamping device 40 can be installed.

Referring to fig. 1 to 8, the bag making device 20 is used to make the upper diaphragm strip 3, the plurality of first pole pieces 4 and the lower diaphragm strip 5 into the composite strip 2, the plurality of first pole pieces 4 are disposed between the upper diaphragm strip 3 and the lower diaphragm strip 5 and are distributed at intervals along the length direction of the composite strip 2, and one first pole piece 4 and the upper diaphragm strip 3 and the lower diaphragm strip 5 covering both sides thereof form a diaphragm bag. It will be appreciated that the first pole piece 4 is a cut pole piece.

A lamination unit 30 is located on one side of the bag-making unit 20 for folding the composite web 2 so that a plurality of membrane bags are facing and overlapping.

Referring to fig. 1 to 3 and 9, the clamping device 40 is disposed adjacent to the lamination device 30, and the clamping device 40 is configured to clamp the second pole piece 8 during the process of folding the composite tape 2 by the lamination device 30, and place the second pole piece 8 between adjacent membrane bags to form the battery cell 1.

An upper diaphragm strip 3 or a lower diaphragm strip 5 is clamped between the adjacent first pole piece 4 and the second pole piece 8, wherein the first pole piece 4 is one of a positive pole piece and a negative pole piece, and the second pole piece 8 is the other.

When the composite strip material is used, the upper diaphragm strip 3, the plurality of first pole pieces 4 and the lower diaphragm strip 5 are fed to the bag making device 20, and the bag making device 20 makes the upper diaphragm strip 3, the plurality of first pole pieces 4 and the lower diaphragm strip 5 into the composite strip material 2 containing a plurality of diaphragm bags; then, the composite strip 2 is transferred to the lamination device 30, the lamination device 30 folds the composite strip 2 to make a plurality of diaphragm bags face each other and overlap each other, at this time, an upper diaphragm band 3 and a lower diaphragm band 5 are respectively arranged on the upper side and the lower side of each first pole piece 4, when in folding, the material clamping device 40 clamps one second pole piece 8 at a time and superposes the second pole piece 8 and the composite strip 2, so that the second pole piece 8 is arranged between the adjacent diaphragm bags, therefore, the plurality of first pole pieces 4 and the plurality of second pole pieces 8 can be alternatively laminated, and the upper diaphragm band 3 or the lower diaphragm band 5 is clamped between the adjacent first pole pieces 4 and the second pole pieces 8.

In one embodiment, the first pole piece 4 is a negative pole piece, and the second pole piece 8 is a positive pole piece, and the length and the width of the negative pole piece are greater than those of the positive pole piece, so that the positive pole piece is conveniently arranged between the adjacent negative pole pieces; and compared with the positive plate, the negative plate is more prone to powder falling, and the negative plate is packaged between the upper diaphragm band 3 and the lower diaphragm band 5, so that the situation that the powder falling of the negative plate affects the performance of the battery cell can be avoided. It is understood that in other embodiments, the first pole piece 4 can be configured as a positive pole piece, and the second pole piece 8 can be configured as a negative pole piece, and the negative pole piece can still be disposed between the adjacent positive pole pieces because the size of the upper and lower separator strips 3 and 5 is larger than that of the positive pole pieces.

The lamination equipment 100 comprises a bag making device 20, a lamination device 30 and a clamping device 40, wherein an upper diaphragm strip 3, a plurality of first pole pieces 4 and a lower diaphragm strip 5 are prepared into a composite strip material 2 through the bag making device 20, the lamination device 30 is used for folding the composite strip material 2, and meanwhile, a second pole piece 8 is placed between the stacked first pole pieces 4 through the clamping device 40, so that a laminated battery core can be manufactured; because the tensile resistance of the composite strip 2 is strong, the diaphragm is not easy to tear due to fluctuating tensile force in the lamination process, a precondition is provided for the acceleration of the lamination process, and the lamination efficiency of the battery cell is favorably improved. In addition, the first pole piece 4 is packaged in the upper diaphragm belt 3 and the lower diaphragm belt 5 in advance, and the first pole piece 4 and the second pole piece 8 are not easy to misplace, so that short circuit of the battery cell is prevented.

Referring to fig. 7 and 8, in an embodiment, the composite tape 2 is configured as a plurality of membrane bags sequentially arranged, a first seal 6 is disposed between adjacent membrane bags, that is, two adjacent first pole pieces 4 are separated by the first seal 6, and the first seal 6 can be formed by thermally pressing and connecting the upper membrane tape 3 and the lower membrane tape 5 by a bag making device 20.

Along the width direction of the composite strip material 2, two sides of each diaphragm bag are provided with a second seal 7, a first seal 6 and the second seal 7 are wound on the periphery of the first pole piece 4, and the lamination device 30 folds the composite strip material 2 along the first seal 6; one side of the first pole piece 4 is provided with a pole lug 401, and the pole lug 401 is positioned at the outer side of the membrane bag.

Through adopting above-mentioned technical scheme, first pole piece 4 is encapsulated in the diaphragm bag, and the position of first pole piece 4 is fixed, prevents that first pole piece 4, second pole piece 8 and diaphragm from all being in loose state and leading to the pole piece dislocation, and then avoids the contact of positive negative current collector and produce the short circuit phenomenon, consequently, lamination device 30 has solved the short circuit problem after the pole piece dislocation, has promoted the security of electric core. Moreover, the lamination device 30 folds the composite strip 2 along the first seal 6, so that the positions of the folding lines are consistent, a plurality of diaphragm bags are ensured to be arranged just opposite and overlapped, and meanwhile, the pole piece can be prevented from being exposed out of the diaphragm.

It will be appreciated that the second seal 7 may be eliminated and the membrane bag may still locate the first pole piece 4.

Referring to fig. 1 to 6, in an embodiment, the lamination device 30 includes a guide roller 31, a lamination mechanism 32, and a swing arm mechanism 33. The guide roller 31 is used for guiding the composite strip 2; the lamination mechanism 32 is arranged opposite to the guide roller 31, and the swing arm mechanism 33 is arranged between the guide roller 31 and the lamination mechanism 32 and is used for driving the composite strip 2 to reciprocate along the Z shape so as to stack a plurality of membrane bags on the lamination mechanism 32.

Specifically, guide roller 31 may support composite strip 2 and allow composite strip 2 to move thereon, swing arm mechanism 33 is used to pull composite strip 2 and is capable of swinging reciprocally with respect to lamination mechanism 32, and lamination mechanism 32 is capable of supporting the stacked membrane bags; along with the reciprocating swing of the swing arm mechanism 33, the composite strip 2 is folded by taking the first seal 6 as a folding line, so that a plurality of diaphragm bags are sequentially stacked on the lamination mechanism 32; meanwhile, the material clamping mechanism clamps the second pole piece 8 between the adjacent diaphragm bags in sequence, so that the first pole piece 4 and the second pole piece 8 are alternately stacked. Through adopting above-mentioned technical scheme, swing arm mechanism 33 can realize folding repeatedly to fold composite band material 2 on lamination mechanism 32, when folding composite band material 2, make things convenient for first pole piece 4 and the range upon range of setting of second pole piece 8.

In one embodiment, the swing arm mechanism 33 includes a swing arm 331 and two pairs of pressure rollers 332 coupled to both ends of the swing arm 331, the swing arm 331 is rotatably coupled to the support frame 10, and one end of the swing arm 331 is adjacent to the guide roller 31 and the other end is adjacent to the lamination mechanism 32. It is understood that the swing arm mechanism 33 further comprises a swing arm driving member (not shown) connected to the swing arm 331 and for driving the swing arm 331 to swing.

A gap is provided between each pair of press rollers 332 through which composite strip 2 passes, and swing arm 331 is capable of oscillating back and forth relative to lamination mechanism 32 to sequentially stack the plurality of membrane pockets in composite strip 2 on lamination mechanism 32, and thus sequentially stack the plurality of first pole pieces 4 on lamination mechanism 32. Through adopting above-mentioned technical scheme, swing arm mechanism 33's simple structure, convenient operation can realize folding repeatedly in succession, and folding efficiency is higher.

It should be noted that when a plurality of first pole pieces 4 are stacked, an upper separator tape 3 and a lower separator tape 5 are provided on and under each first pole piece 4.

Wherein a pair of press rolls 332 adjacent to the laminating mechanism 32 can act as pulling rolls for the composite strip 2, and can pull the composite strip 2 on the guide rolls 31 toward the laminating mechanism 32.

In an embodiment, the lamination apparatus 100 further includes two feeding devices 50 respectively disposed at two sides of the lamination mechanism 32, and the feeding devices 50 are configured to receive the plurality of second pole pieces 8 and sequentially feed the plurality of second pole pieces 8; the material clamping device 40 comprises two clamping mechanisms 41 respectively arranged at two sides of the lamination mechanism 32, wherein the two clamping mechanisms 41 alternately grab the second pole pieces 8 on the corresponding feeding devices 50, and stack the second pole pieces 8 on the lamination mechanism 32, so that the second pole pieces 8 and the first pole pieces 4 are alternately stacked. The loading device 50 may be a cartridge type loading device 50, but is not limited thereto.

Because two loading attachment 50, two fixture 41 locate the both sides of lamination mechanism 32 respectively, when lamination mechanism 32 folded composite strip 2 along the Z shape, two fixture 41 can the centre gripping second pole piece 8 on corresponding loading attachment 50 to respectively place second pole piece 8 on composite strip 2 from the left side or the right side of composite strip 2, thereby realized continuous lamination process, promoted lamination efficiency. It will be appreciated that in another embodiment, the loading device 50 and the clamping mechanism 41 may be located one on each side, and the clamping mechanism 41 may be moved between the two sides of the lamination mechanism 32 to place the second pole piece 8 on the composite tape 2 from the left or right side of the composite tape 2, respectively.

Optionally, the feeding device 50 is disposed on the supporting platform 12 in a penetrating manner, and the feeding device 50 may include a lifting driving member and a guide rod, where the lifting driving member is configured to drive the second pole piece 8 to ascend along the guide rod relative to the supporting platform 12 to achieve feeding.

Optionally, the clamping mechanism 41 includes a moving driving assembly and a suction cup connected to the moving driving assembly, the suction cup is used for sucking the second pole piece 8, the moving driving assembly can drive the suction cup to move between the feeding device 50 and the lamination mechanism 32, and the moving driving assembly can also drive the suction cup to move up and down along a direction perpendicular to the lamination mechanism 32 so as to place the second pole piece 8 on the lamination mechanism 32 for lamination.

Optionally, lamination mechanism 32 includes a clamping member and a clamping driving member connected to each other, and the clamping driving member can drive the clamping member to clamp composite strip 2 to limit composite strip 2.

It will be appreciated that the lift drive, the travel drive assembly, and the clamp drive described above may include a pneumatic cylinder or other drive, as the present application is not limited in this respect.

In one embodiment, the bag making apparatus 20 includes a feeding mechanism 21, a slicing mechanism 22, and a bag making mechanism 23, which are arranged in this order.

The feeding mechanism 21 includes an upper diaphragm feeding roller 211, a pole piece feeding roller 212, and a lower diaphragm feeding roller 213 spaced from top to bottom, and respectively configured to wind an upper diaphragm band 3, a first pole piece band including a plurality of first pole pieces 4, and a lower diaphragm band 5.

The slicing mechanism 22 is used for cutting the first pole piece 4, and includes a cutting traction roller 221, a cutting knife 222, a pole piece positioning table 223 and a feeding platform 224 which are sequentially arranged, and a feeding transfer part 225 movably arranged above the pole piece positioning table 223 and the feeding platform 224, wherein the cutting traction roller 221 is used for drawing the first pole piece 4 on the pole piece feeding roller 212 to the pole piece positioning table 223, the cutting knife 222 is used for cutting the first pole piece 4 from the first pole piece belt, the feeding transfer part 225 is used for transferring the cut first pole piece 4 to the feeding platform 224, and the first pole piece 4 is attached to the lower diaphragm belt 5 conveyed to the feeding platform.

The bag making mechanism 23 includes a bag making drawing roll 231 and a bag making machine 232 which are adjacently arranged, the bag making drawing roll 231 is used for drawing the upper diaphragm belt 3, the first pole piece 4 and the lower diaphragm belt 5 after being attached, and the bag making machine 232 is used for making the upper diaphragm belt 3, the first pole piece 4 and the lower diaphragm belt 5 into the composite belt material 2. It will be appreciated that the bag making mechanism 23 forms the first seal 6 and the second seal 7 by applying the upper membrane web 3 and the lower membrane web 5 by means of heat pressing.

The feeding mechanism 21 can feed the upper diaphragm strip 3, the first pole piece strip and the lower diaphragm strip 5 at the same time, the slicing mechanism 22 can cut the first pole piece 4, and the bag making mechanism 23 can make bags of the upper diaphragm strip 3, the first pole piece 4 and the lower diaphragm strip 5 to form a plurality of diaphragm bags connected in sequence, so that the first pole piece 4 is packaged. The bag making device 20 can realize continuous production of feeding and bag making, and has high production efficiency.

Optionally, the feeding transfer part 225 comprises a feeding driving assembly and a sucker connected to the feeding driving assembly, the sucker is used for adsorbing the first pole piece 4 after cutting, and the feeding driving assembly is used for driving the sucker to move horizontally and lift. The feeding driving assembly may include a cylinder, but is not limited thereto.

Further, in an embodiment, the loading device 50 further includes a first guide roller assembly 214 and a second guide roller assembly 215. A first guide roller assembly 214 is provided between the upper diaphragm feed roller 211 and the bag-making traction roller 231 along the conveying direction of the upper diaphragm web 3 for guiding the upper diaphragm web 3 onto the bag-making traction roller 231; a second guide roller assembly 215 is provided between the lower membrane feed roller 213 and the loading platform 224 for guiding the lower membrane strip 5 onto the loading platform 224.

It will be appreciated that the first guide roller assembly 214 and the second guide roller assembly 215 may each include a plurality of guide rollers disposed at intervals. By adopting the technical scheme, the first guide roller assembly 214 and the second guide roller assembly 215 can guide and tension the upper diaphragm strip 3 and the lower diaphragm strip 5, and the upper diaphragm strip 3 and the lower diaphragm strip 5 can be avoided from the cutting traction roller 221, the cutting knife 222 and the pole piece positioning table 223, so that the lamination efficiency is improved.

Optionally, in an embodiment, the lamination apparatus 100 further includes a blanking device 60 disposed on the support frame 10, the blanking device 60 is disposed on a side of the lamination device 30 away from the bag-making device 20, and the blanking device 60 is configured to grab the battery cell on the lamination device 30 and drive the battery cell to blank. The blanking device 60 may include a blanking driving assembly and a clamping jaw connected to the blanking driving assembly, the clamping jaw is used to clamp the manufactured battery cell 1, and the blanking driving assembly is used to drive the clamping jaw to translate so as to realize blanking of the battery cell. It can be understood that the blanking device 60 can be adapted to a cutting member, and the cutting member is used to separate the manufactured battery core 1 from the composite strip 2. Through adopting above-mentioned technical scheme, lamination equipment 100 can be through the unloading of unloader to electric core 1, and degree of automation and preparation efficiency are higher.

A second aspect of the utility model provides an electrical core 1 comprising a composite tape 2 and a plurality of second pole pieces 8.

The composite strip material 2 comprises an upper diaphragm strip 3, a lower diaphragm strip 5 and a plurality of first pole pieces 4 arranged between the upper diaphragm strip 3 and the lower diaphragm strip 5, wherein one first pole piece 4 and the upper diaphragm strip 3 and the lower diaphragm strip 5 covering the two sides of the first pole piece 4 form a diaphragm bag, and the plurality of diaphragm bags are arranged just opposite to and overlapped.

The second pole pieces 8 are overlapped with the diaphragm bags in sequence, an upper diaphragm belt 3 or a lower diaphragm belt 5 is clamped between the adjacent first pole piece 4 and the second pole piece 8, wherein the first pole piece 4 is one of a positive pole piece and a negative pole piece, and the second pole piece 8 is the other one.

Above-mentioned electric core 1 includes compound area material 2 and a plurality of second pole piece 8, because compound area material 2 is by last diaphragm area 3, lower diaphragm area 5 and locate the diaphragm area 3 and down the compound a plurality of first pole pieces 4 between the diaphragm area 5 form, compound area material 2's stretching resistance is stronger, the diaphragm is difficult for receiving undulant pulling force and takes place to tear in the lamination in-process, also for the speeding up of range upon range of process provides the prerequisite, be favorable to promoting electric core 1's lamination efficiency.

Optionally, the first pole piece 4 is a negative pole piece, and the second pole piece 8 is a positive pole piece.

Referring to fig. 1 to 10, a method for manufacturing a battery cell includes the following steps.

In step S110, a plurality of first pole pieces 4, an upper membrane band 3 and a lower membrane band 5 are provided.

It can be understood that the first pole piece 4 is a pole piece cut to a predetermined size, and the upper diaphragm strip 3 and the lower diaphragm strip 5 are respectively disposed on two opposite sides of the first pole piece 4 during feeding. This step may be performed by the infeed mechanism 21 of the lamination apparatus 100, and the method of execution may be as described with reference to the first aspect.

Step S120, manufacturing the upper diaphragm strip 3, the plurality of first pole pieces 4 and the lower diaphragm strip 5 into the composite strip 2 through a bag making process, wherein the plurality of first pole pieces 4 are distributed between the upper diaphragm strip 3 and the lower diaphragm strip 5 at intervals along the length direction of the composite strip 2, and a diaphragm bag is formed by one first pole piece 4 and the upper diaphragm strip 3 and the lower diaphragm strip 5 covering the two sides of the first pole piece 4.

This step may be performed by bag-making apparatus 20 of lamination apparatus 100. The composite strip 2 is configured as a plurality of sequentially connected membrane bags, each membrane bag comprising an upper membrane strip 3, a lower membrane strip 5 and a first pole piece 4 disposed between the upper membrane strip 3 and the lower membrane. A first seal 6 is arranged between each diaphragm bag; optionally, each membrane bag also has two second seals 7 along the width of the composite web 2.

Step S130, folding the composite tape 2 to make the plurality of diaphragm bags face each other and overlap each other, and simultaneously overlapping the plurality of second pole pieces 8 and the diaphragm bags in sequence to form a battery cell.

This step may be performed by the lamination device 30 and the clamping device 40 of the lamination apparatus 100. Optionally, the guide roller 31 guides the composite strip 2; the lamination mechanism 32 is arranged opposite to the guide roller 31; the swing arm mechanism 33 is disposed between the guide roller 31 and the lamination mechanism 32, and is used for driving the composite strip 2 to move back and forth along the Z-shape, so as to stack a plurality of membrane bags on the lamination mechanism 32. At the same time, the two clamping mechanisms 41 alternately grab the second pole pieces 8 on the corresponding feeding devices 50 and stack the second pole pieces 8 on the lamination mechanism 32, so that the second pole pieces 8 and the diaphragm bags are alternately stacked, i.e. the second pole pieces 8 and the first pole pieces 4 are alternately stacked.

The first pole piece 4 is one of a positive pole piece and a negative pole piece, and the second pole piece 8 is the other, and in one embodiment, the first pole piece 4 is the negative pole piece, and the second pole piece 8 is the positive pole piece.

According to the preparation method of the battery core, the upper diaphragm strip 3, the plurality of first pole pieces 4 and the lower diaphragm strip 5 are firstly made into the composite strip material 2, then the composite strip material 2 is folded, and meanwhile, the second pole pieces 8 are arranged between adjacent diaphragm bags, so that the laminated battery core 1 can be manufactured. Because the composite strip 2 is formed by compounding the upper diaphragm strip 3, the lower diaphragm strip 5 and the plurality of first pole pieces 4 arranged between the upper diaphragm strip 3 and the lower diaphragm strip 5, during lamination, the tensile resistance of the composite strip 2 is stronger, the diaphragm is not easy to be torn by fluctuating tensile force, a precondition is provided for the speed increase of the lamination process, and the problems that the diaphragm is easy to tear and the speed of lamination equipment is difficult to increase are solved.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the spirit and scope of the embodiments of the present invention, and are intended to be included within the scope of the present invention.

Claims (10)

1. A lamination apparatus, comprising:

a support frame;

the bag making device is arranged on the support frame and is used for making an upper diaphragm belt, a plurality of first pole pieces and a lower diaphragm belt into a composite belt material, the plurality of first pole pieces are arranged between the upper diaphragm belt and the lower diaphragm belt and are distributed at intervals along the length direction of the composite belt material, and one first pole piece and the upper diaphragm belt and the lower diaphragm belt covering the two sides of the first pole piece form a diaphragm bag;

the laminating device is arranged on the support frame and positioned on one side of the bag making device and is used for folding the composite strip material to enable a plurality of diaphragm bags to be overlapped;

and the clamping device is arranged on the support frame and adjacent to the lamination device, and is used for clamping a second pole piece in the process of folding the composite strip by the lamination device and placing the second pole piece between the adjacent diaphragm bags to form a battery cell.

2. The lamination device according to claim 1,

a first seal is arranged between the adjacent diaphragm bags;

along the width direction of the composite strip material, two sides of each diaphragm bag are provided with second seals, the first seals and the second seals are wound on the peripheral sides of the first pole pieces, and the lamination device folds the composite strip material along the first seals;

one side of the first pole piece is provided with a pole lug which is positioned on the outer side of the diaphragm bag.

3. The lamination apparatus according to claim 1, wherein the lamination device comprises:

the guide roller is used for guiding the composite strip;

the lamination mechanism is arranged opposite to the guide roller;

and the swing arm mechanism is arranged between the guide roller and the lamination mechanism and is used for driving the composite strip to reciprocate along a Z shape so as to stack a plurality of diaphragm bags on the lamination mechanism.

4. The lamination apparatus according to claim 3, wherein the swing arm mechanism comprises a swing arm and two pairs of compression rollers connected to opposite ends of the swing arm, a gap is provided between each pair of compression rollers for the composite strip to pass through, and the swing arm is capable of oscillating back and forth relative to the lamination mechanism to sequentially stack a plurality of the membrane bags on the lamination mechanism.

5. The lamination apparatus according to claim 1, further comprising two feeding devices respectively disposed at two sides of the lamination mechanism, wherein the feeding devices are configured to receive the plurality of second pole pieces and sequentially feed the plurality of second pole pieces;

the material clamping device comprises two clamping mechanisms which are respectively arranged on two sides of the lamination mechanism, the two clamping mechanisms alternately grab the corresponding second pole piece on the feeding device and stack the second pole piece on the lamination mechanism, so that the second pole piece and the first pole piece are alternately stacked.

6. The laminating apparatus of claim 1, wherein said bag-making means comprises a feeding mechanism, a slicing mechanism, and a bag-making mechanism arranged in sequence;

the feeding mechanism comprises an upper diaphragm feeding roller, a pole piece feeding roller and a lower diaphragm feeding roller which are arranged from top to bottom at intervals and are respectively used for winding the upper diaphragm belt, a first pole piece belt comprising a plurality of first pole pieces and the lower diaphragm belt;

the slicing mechanism comprises a cutting traction roller, a cutting knife, a pole piece positioning table, a feeding platform and a feeding transfer part, wherein the cutting traction roller, the cutting knife, the pole piece positioning table and the feeding platform are sequentially arranged, the feeding transfer part is movably arranged above the pole piece positioning table and the feeding platform, the cutting traction roller is used for drawing a first pole piece belt on a pole piece feeding roller to the first pole piece positioning table, the cutting knife is used for cutting a first pole piece from the first pole piece belt, the feeding transfer part is used for transferring the cut first pole piece to the feeding platform and enabling the first pole piece to be attached to a lower diaphragm belt conveyed to the feeding platform;

the bag making mechanism comprises a bag making traction roller and a bag making machine which are arranged adjacently, the bag making traction roller is used for simultaneously drawing the upper diaphragm belt, the first pole piece and the lower diaphragm belt after being attached, and the bag making machine is used for making the upper diaphragm belt, the first pole piece and the lower diaphragm belt into the composite belt material.

7. The laminating apparatus of claim 6, wherein the feed mechanism further comprises a first guide roller assembly and a second guide roller assembly;

the first guide roller assembly is arranged between the upper membrane feeding roller and the bag-making traction roller along the conveying direction of the upper membrane strip and used for guiding the upper membrane strip to the bag-making traction roller; the second guide roller assembly is arranged between the lower membrane feeding roller and the feeding platform and used for guiding the lower membrane strip to the feeding platform.

8. The laminating device according to claim 1, further comprising a blanking device disposed on the supporting frame, wherein the blanking device is disposed on a side of the laminating device away from the bag-making device, and the blanking device is configured to grab the battery cell on the laminating device and drive the battery cell to blank.

9. The lamination apparatus according to claim 1, wherein the first pole piece is a negative pole piece and the second pole piece is a positive pole piece.

10. A battery cell, comprising:

the composite strip material comprises an upper diaphragm strip, a lower diaphragm strip and a plurality of first pole pieces arranged between the upper diaphragm strip and the lower diaphragm strip, wherein one first pole piece and the upper diaphragm strip and the lower diaphragm strip covering the two sides of the first pole piece form a diaphragm bag, and the diaphragm bags are arranged oppositely and overlapped; and

a plurality of second pole pieces sequentially overlapping the plurality of membrane bags.

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