CN210547002U - Mechanism for forming lithium film and device for supplementing lithium to pole piece - Google Patents

Abstract

The utility model provides a device that is used for the mechanism that the lithium membrane takes shape and is used for the lithium to mend by the pole piece. The mechanism for forming the lithium film comprises a first separation film providing mechanism, a second separation film providing mechanism, a lubricating substance applying mechanism, a lithium strip providing mechanism and two rollers, wherein the first separation film providing mechanism is used for providing a first separation film for the two rollers, the second separation film providing mechanism is used for providing a second separation film for the two rollers, the lithium strip providing mechanism can enable the lithium strip to be located between the first separation film and the second separation film and is used for providing the lithium strip for the two rollers, the lubricating substance applying mechanism is used for applying the lubricating substance to the surfaces, facing the lithium strip, of the first separation film and/or the second separation film before entering the two rollers, and the two rollers are used for rolling the first separation film, the lithium strip and the second separation film so as to roll the lithium strip into a lithium foil and enable the lithium foil to be adhered to the second separation film to form the lithium film. By providing the lubricating substance applying mechanism, the rolling force is reduced, and the reuse of the separator is realized.

Description

Mechanism for forming lithium film and device for supplementing lithium to pole piece

Technical Field

The utility model relates to an electrochemistry field, more specifically relate to a device that is used for the mechanism that the lithium membrane takes shape and is used for lithium to mend to the pole piece.

Background

With the popularization of new energy automobiles, the requirements on power batteries of the new energy automobiles are more and more strict; for example, batteries are required to have both high energy density, long cycling and stable performance, as well as the ability to charge quickly.

At present, the cycle performance of the battery can be improved and the energy density can be improved by lithium supplement through the pole piece. In the pole piece lithium supplement technology, two separation films are put into two rollers to roll through a lithium belt, so as to roll the lithium belt into a lithium foil and make the lithium foil adhere to one of the separation films, and then the separation film carrying the lithium foil is rolled with the pole piece, so that the lithium foil is separated from the separation film and adheres to the pole piece, thereby forming a lithium supplement pole piece. In the process of adhering the lithium foil to one of the isolating films, the two rollers and the two isolating films are rolled in a dry friction state, so that the rolling force is high, the two isolating films are greatly damaged when the lithium strip is rolled into the lithium foil, and the consumption of the isolating films is large.

SUMMERY OF THE UTILITY MODEL

In view of the problems existing in the prior art, the present invention aims to provide a mechanism for forming a lithium film and a device for lithium supplement of a pole piece, which can realize the reuse of a separation film and reduce the cost of lithium supplement.

In order to achieve the above object, in a first aspect, the present invention provides a mechanism for lithium film formation, the mechanism for lithium film formation includes a first separator providing mechanism, a second separator providing mechanism, a lubricating substance applying mechanism, a lithium ribbon providing mechanism, and two rolls, the first separator providing mechanism is located upstream of the two rolls, the first separator providing mechanism is used for providing a first separator between the two rolls, the second separator providing mechanism is located upstream of the two rolls, the second separator providing mechanism is used for providing a second separator between the two rolls, the lithium ribbon providing mechanism is located upstream of the two rolls, the lithium ribbon providing mechanism can enable a lithium ribbon to be located between the first separator and the second separator and provide a lithium ribbon between the two rolls, the lubricating substance applying mechanism is located upstream of the two rolls, the lubricating substance applying mechanism is used for applying the first separator and/or the second separator before entering the two rolls And applying a lubricating substance to the surface of the separating film facing the lithium strip, and rolling the first separation film, the lithium strip and the second separation film by two rollers to roll the lithium strip into a lithium foil and adhere the lithium foil to the second separation film to form the lithium film.

In one embodiment, the lubricating substance applying mechanism is a coating mechanism.

In one embodiment, the mechanism for lithium film formation further comprises a first separator take-up mechanism located downstream of the two rolls for taking up the first separator passing between the two rolls.

In an embodiment, the mechanism for lithium film formation further comprises a release agent supply mechanism located between the two rolls and the first separator take-up mechanism for supplying a release agent to a surface of the first separator facing the lithium ribbon.

In one embodiment, the release agent providing mechanism is a coating mechanism.

In order to achieve the above object, in a second aspect, the present invention provides a device for lithium supplement of a pole piece, the pole piece comprises a current collector and an active material layer disposed on the surface of the current collector, the device for lithium supplement of the pole piece comprises a rolling mechanism and a pole piece providing mechanism, the rolling mechanism comprises two rollers; the pole piece provides the upper reaches that the mechanism is located two compression rollers, and the pole piece provides the mechanism and is used for providing the pole piece between two compression rollers for the device of lithium is mended to the pole piece still includes according to the utility model discloses the first aspect a mechanism for lithium membrane takes shape for the mechanism that lithium membrane takes shape is located the upper reaches of two compression rollers, and roll-in mechanism is used for calendering lithium membrane and pole piece to make the lithium foil adhesion in the lithium membrane to the active material layer.

In one embodiment, the device for pole piece lithium supplement further comprises a second isolating film collecting mechanism, the second isolating film collecting mechanism is located at the downstream of the two compression rollers, and the second isolating film collecting mechanism is used for enabling the lithium film to pass between the two compression rollers and collecting the second isolating film in the lithium film passing between the two compression rollers.

In one embodiment, the device for pole piece lithium supplement further comprises a lithium supplement pole piece collecting mechanism, the lithium supplement pole piece collecting mechanism is located at the downstream of the two compression rollers, and the lithium supplement pole piece collecting mechanism is used for collecting the pole piece with the active material layer adhered with the lithium foil.

In one embodiment, the mechanism for lithium film formation and the second separator take-up mechanism are in two sets to provide lithium foil to both surfaces of the pole piece.

In one embodiment, the device for pole piece lithium supplement further comprises a release agent supply mechanism arranged between the two press rollers and the second separation film collecting mechanism and used for supplying release agent to the surface of the second separation film facing the lithium supplement pole piece.

The utility model has the advantages as follows: the lubricating substance applying mechanism is used for applying the lubricating substance to the surfaces, facing the lithium strip, of the first isolating film and/or the second isolating film before entering the two rollers, so that the rolling force between the two rollers can be remarkably reduced, the damage of the rollers to the first isolating film and the second isolating film when the lithium strip is rolled into a lithium foil can be reduced, the first isolating film and the second isolating film are recycled, and the lithium supplement cost is reduced.

Drawings

Fig. 1 is a schematic diagram of a first embodiment of an apparatus for pole piece lithium supplement according to the present invention.

Fig. 2 is a schematic diagram of a second embodiment of the device for pole piece lithium supplement according to the present invention.

Fig. 3 is a schematic diagram of a third embodiment of the device for pole piece lithium supplement according to the present invention.

Fig. 4 is a schematic view of a first embodiment of a coating mechanism of a device for pole piece lithium supplement according to the present invention.

Fig. 5 is a schematic view of a second embodiment of a coating mechanism of a device for pole piece lithium supplement according to the present invention.

Fig. 6 is a schematic view of a third embodiment of a coating mechanism of a device for pole piece lithium supplement according to the present invention.

Wherein the reference numerals are as follows:

1 rolling mechanism P01 current collector

11 active substance layer of pressure roll P02

2 pole piece supply mechanism P1 lithium supplement pole piece

3 mechanism M1 gravure coating mechanism for lithium film forming

31A first separator supply mechanism M11 accommodating groove

31B second separation film supply mechanism M12 gravure roll

32 lubricating substance applying mechanism M121 concave part

33 lithium strip supply mechanism M2 transfer coating mechanism

34 roll M21 scraper

35 first separator take-up mechanism M22 transfer roll

36 release agent supply mechanism M3 extrusion coating mechanism

S1 first separator M31 storage tank

S2 second isolation film M32 screw pump

L0 lithium tape M33 coating head

L1 lithium foil 4 second isolating film collecting mechanism

C lithium membrane 5 mends lithium pole piece receiving mechanism

P0 pole piece

Detailed Description

The accompanying drawings illustrate embodiments of the present invention and it is to be understood that the disclosed embodiments are merely exemplary of the invention, which can be embodied in various forms, and therefore, specific details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present invention.

Further, expressions of directions indicated for explaining operations and configurations of respective members in the embodiment, such as upper, lower, left, right, front, and rear, are not absolute but relative, and although these indications are appropriate when the respective members are in the positions shown in the drawings, when the positions are changed, the directions should be interpreted differently to correspond to the changes.

Fig. 1 is a schematic diagram of a first embodiment of an apparatus for pole piece lithium supplement according to the present invention.

As shown in FIG. 1, the device for lithium supplement of the pole piece comprises a rolling mechanism 1, a pole piece providing mechanism 2 and a mechanism 3 for forming a lithium film. According to the actual situation, the device for supplementing lithium to the pole piece can also comprise a second isolating film collecting mechanism 4. According to the actual conditions, the device for pole piece lithium supplement further comprises a lithium supplement pole piece collecting mechanism 5. The pole piece P0 includes a current collector P01 and an active material layer P02 disposed on the surface of the current collector P01.

The roll pressing mechanism 1 includes two press rolls 11.

The pole piece supply means 2 are located upstream of the two pressure rollers 11. The pole piece providing mechanism 2 is used for providing a pole piece P0 between two pressing rollers 11, as shown in fig. 1, the pole piece providing mechanism 2 can be a roller, so that the pole piece providing mechanism 2 is used for unreeling a pole piece P0 in a roll material form. The active material layer P02 is continuously distributed on the surface of the current collector P01.

The mechanism 3 for lithium film formation is located upstream of the two press rolls 11. The mechanism 3 for lithium film formation includes a first separator supply mechanism 31A, a second separator supply mechanism 31B, a lubricating substance application mechanism 32, a lithium ribbon supply mechanism 33, and two nip rollers 34. The mechanism 3 for lithium film formation may further include a first separator take-up mechanism 35, depending on the actual circumstances. The mechanism 3 for lithium film formation may further include a release agent supply mechanism 36, depending on the actual situation.

The first separator supply mechanism 31A is located upstream of the two rolls 34. The first separator supply mechanism 31A is for supplying a first separator S1 between the two rollers 34. As shown in the drawing, the first separation film supply mechanism 31A is a roller, so that the first separation film supply mechanism 31A is used to unwind the first separation film S1 in the form of a roll.

The second separator supply mechanism 31B is located upstream of the two rolls 34. The second separator supply mechanism 31B is for supplying a second separator S2 between the two rollers 34. As shown in fig. 1, the second separation film supply mechanism 31B may be a roller, so that the second separation film supply mechanism 31B serves to unwind the second separation film S2 in the form of a roll. Wherein the surface roughness of the second isolation film S2 is greater than the surface roughness of the first isolation film S1.

The lubricative substance applying mechanism 32 is located upstream of the two rolls 34. The lubricating substance applying mechanism 32 is used to apply a lubricating substance (not shown) to the surface of the first separator S1 facing the lithium ribbon L0 before entering the two nip rollers 34. The lubricating substance applying mechanism 32 may apply the lubricating substance to the surface of the first separator S1 in a continuous manner.

The lithium strip supply mechanism 33 is located upstream of the two rolls 34. The lithium tape supply mechanism 33 is capable of positioning the lithium tape L0 between the first separator S1 and the second separator S2, and supplying the lithium tape L0 between the two rollers 34. As shown in fig. 1, the lithium ribbon supply mechanism 33 is a roller, so that the lithium ribbon supply mechanism 33 serves to unwind the lithium ribbon L0 in a roll form.

Two rolling rolls 34 are used to roll the first separator S1, the lithium tape L0, and the second separator S2 to roll the lithium tape L0 into lithium foil L1 and adhere the lithium foil L1 to the second separator S2 to form a lithium film C. In fig. 1, two rollers 34 roll a first separation film S1, a lithium tape L0, and a second separation film S2, which enter between the two rollers 34, to change the lithium tape L0 into a lithium foil L1 and continuously adhere the lithium foil L1 to the second separation film S2 to form a lithium film C.

The first separator take-up mechanism 35 is located downstream of the two rolls 34. The first separator take-up mechanism 35 is for taking up the first separator S1 passing between the two rollers 34. As shown in fig. 1, the first separator take-up mechanism 35 is a roller, so that the first separator take-up mechanism 35 serves to take-up the first separator S1.

A release agent supply mechanism 36 is located between the two rolls 34 and the first separator take-up mechanism 35, and the release agent supply mechanism 36 supplies a release agent (not shown) to the surface of the first separator S1 facing the lithium tape L0. The release agent supply mechanism 36 applies the release agent to the surface of the first release film S1 before the first release film take-up mechanism 35 takes up the first release film S1, so that the first release film S1 having the release agent applied to the surface is subsequently reused by the first release film supply mechanism 31A, particularly when the first release film take-up mechanism 35 is in the form of a roll, and after the take-up of the first release film S1 having the release agent applied to the surface is completed, the rolled first release film S1 can be used again by the first release film supply mechanism 31A, thereby reducing the cost.

The rolling mechanism 1 is used for rolling the lithium film C and the pole piece P0 to adhere the lithium foil L1 in the lithium film C to the active material layer P02 to form a lithium supplement pole piece P1.

The second separator take-up mechanism 4 is located downstream of the two press rollers 11. The second separator take-up mechanism 4 serves to pass the lithium film C between the two pressing rollers 11 and take up the second separator S2 in the lithium film C passed between the two pressing rollers 11. In fig. 1, the second separator take-up mechanism 4 is a roller, and the second separator take-up mechanism 4 is used to take up the second separator S2 while the second separator take-up mechanism 4 provides a traction force to the second separator S2 in the lithium film C passing between the two pressing rollers 11. In comparison with the rolling of the first separator S1 by only two rolls 34, the degree of damage of the second separator S2 by the two rolls 34 and the two rolls 11 is increased, but if the performance of the second separator S2 is still good, similarly, a release agent supply mechanism 36 for supplying a release agent to the surface of the second separator S2 facing the lithium supplement electrode sheet P1 may be provided between the two rolls 11 and the second separator receiving mechanism 4. The release agent is applied to the surface of the second separator S2 before the second separator take-up mechanism 4 takes up the second separator S2, so that the second separator S2 having the release agent applied to the surface is subsequently reused by the second separator supply mechanism 31B, particularly when the second separator supply mechanism 31B is in the form of a roll, and after the take-up of the second separator S2 having the release agent applied to the surface is completed, the rolled second separator S2 can be used again by the second separator supply mechanism 31B, thereby reducing the cost.

The lithium supplement electrode sheet take-up mechanism 5 is located downstream of the two press rolls 11. The lithium supplement electrode piece collecting mechanism 5 is used for collecting the electrode piece P0 (i.e., the lithium supplement electrode piece P1) with the lithium foil L1 adhered to the active material layer P02. In fig. 1, the lithium supplement electrode sheet take-up mechanism 5 is a roller, and the lithium supplement electrode sheet take-up mechanism 5 is used for taking up the lithium supplement electrode sheet P1.

In the first embodiment shown in fig. 1, the mechanism 3 for lithium film formation and the second separator take-up mechanism 4 are provided in one or two sets, respectively, depending on the arrangement of the active material layer P02 on one or both surfaces of the current collector P01. In other words, when the active material layer P02 is provided on one surface of the current collector P01, the mechanism 3 for lithium film formation and the second separator take-up mechanism 4 are provided as a set, achieving single-sided lithium replenishment of the pole piece P0; when the active material layer P02 is provided on both surfaces of the current collector P01, the mechanism for lithium film formation 3 and the second separator take-up mechanism 4 are provided in two sets as shown in fig. 1, thereby achieving double-sided lithium replenishment of the pole piece P0.

The first embodiment of the device for pole piece lithium supplement shown in fig. 1 realizes continuous lithium supplement of the pole piece P0.

Fig. 2 is a schematic view of a second embodiment of an apparatus for pole piece lithium replenishment according to the utility model. Note that components having the same structures as those of the first embodiment are denoted by the same reference numerals, and descriptions thereof are omitted. Further, the description of the same actions and actions as those of the first embodiment will be omitted.

In contrast to the first exemplary embodiment of the device for pole piece lithium replenishment of fig. 1: in the second embodiment, the lubricating substance applying mechanism 32 is used to apply a lubricating substance (not shown) to the surface of the second separator S2 facing the lithium ribbon L0 before entering the two nip rollers 34. The lubricating substance applying mechanism 32 is configured to apply the lubricating substance to the surface of the second separator S2 intermittently. The lubricating substance applying mechanism 32 intermittently applies the lubricating substance to the surface of the second separator S2 facing the lithium strip L0, two rolls 34 are used to roll the first separator S1, the lithium strip L0, and the second separator S2 to roll the lithium strip L0 into the lithium foil L1 and intermittently adhere the lithium foil L1 to the second separator S2 to form the lithium film C, and the lithium foil L1 not adhered to the second separator S2 is intermittently adhered to the first separator S1. The active material layers P02 are intermittently distributed on the surface of the current collector P01.

The second embodiment of the device for pole piece lithium replenishment shown in fig. 2 enables intermittent lithium replenishment of the pole piece P0.

Fig. 3 is a schematic view of a third embodiment of an apparatus for pole piece lithium replenishment according to the utility model. Note that components having the same structures as those of the second embodiment are denoted by the same reference numerals, and descriptions thereof are omitted. Further, the explanation of the same action and action as those of the second embodiment will be omitted.

In contrast to the second exemplary embodiment of the device for pole piece lithium replenishment of fig. 2, the following are provided: in the third embodiment, the lubricating substance applying mechanism 32 is used to apply a lubricating substance (not shown) to both the surfaces of the first separator S1 and the second separator S2 facing the lithium ribbon L0 before entering the two rolls 34. The lubricating substance applying mechanism 32 applies the lubricating substance to the surface of the second separator S2 in intermittent fashion. The lubricating substance applying mechanism 32 applies the lubricating substance to the surface of the first separator S1 also in an intermittent manner, but the lubricating substance applied on the surface of the first separator S1 facing the lithium ribbon L0 and the lubricating substance applied on the surface of the second separator S2 facing the lithium ribbon L0 alternately enter between the two nip rollers 34. In fig. 3, there are two lubricating substance applying mechanisms 32, specifically, one of the two lubricating substance applying mechanisms 32 intermittently applies a lubricating substance to the surface of the first separator S1 facing the lithium strip L0, the other of the two lubricating substance applying mechanisms 32 intermittently applies a lubricating substance to the surface of the second separator S2 facing the lithium strip L0, and the lubricating substance applied on the surface of the first separator S1 facing the lithium strip L0 and the lubricating substance applied on the surface of the second separator S2 facing the lithium strip L0 alternately enter between the two rolls 34. Note that the lubricating substance applied to the surface of the first separator S1 facing the lithium zone L0 may be the same as or different from the lubricating substance applied to the surface of the second separator S2 facing the lithium zone L0. In fig. 3, although two lubricating substance applying mechanisms 32 are shown, they may be combined into one and provided with different coating ports and control mechanisms, thereby achieving coating of the lubricating substance with one lubricating substance applying mechanism 32 for the first separator S1 and the second separator S2.

Like the second exemplary embodiment shown in fig. 2, the third exemplary embodiment of the device for pole piece compensation shown in fig. 3 also enables intermittent lithium compensation of pole piece P0.

In the embodiment shown in fig. 1 to 3, the lubricating substance applying mechanism 32 and/or the release agent supplying mechanism 36 are coating mechanisms. The coating mechanism may be a gravure coating mechanism M1, a transfer coating mechanism M2, or an extrusion coating mechanism M3.

Fig. 4 is a schematic view of a first embodiment of a coating mechanism of a device for pole piece lithium supplement according to the present invention.

The coating mechanism of fig. 4 is a gravure coating mechanism M1. The gravure coating mechanism M1 includes a storage tank M11 and a gravure roll M12, the storage tank M11 is used for storing a corresponding lubricating substance or release agent, and the gravure roll M12 is used adjacent to a corresponding separator (i.e., the first separator S1 or the second separator S2); the gravure roll M12 has recesses M121 provided at intervals in the circumferential direction and extending in the circumferential direction, and the gravure roll M12 is used to draw up the corresponding lubricating substance or release agent from the storage tank M11 through the recesses M121 during rotation and coat the corresponding surface of the corresponding separator (i.e., the first separator S1 or the second separator S2). Gravure roll M12 was rotated periodically to achieve intermittent coating. Gravure roll M12 was continuously rotated to achieve continuous coating.

Fig. 5 is a schematic view of a second embodiment of a coating mechanism of a device for pole piece lithium supplement according to the present invention.

The coating mechanism of fig. 5 is a transfer coating mechanism M2. The transfer coating mechanism M2 includes a doctor M21 and a transfer roller M22, the doctor M21 being used to receive a corresponding lubricating substance or release agent and being adjacent to the transfer roller M22, the transfer roller M22 being used to be adjacent to a corresponding separator (i.e., the first separator S1 or the second separator S2); the doctor blade M21 is used to transfer the corresponding lubricating substance or release agent onto the surface of the transfer roller M22, and the corresponding lubricating substance or release agent transferred onto the surface of the transfer roller M22 contacts and is applied to the corresponding surface of the corresponding separator (i.e., the first separator S1 or the second separator S2). The blade M21 was able to spring open periodically to achieve intermittent coating. The blade M21 did not spring open to achieve continuous coating.

Fig. 6 is a schematic view of a third embodiment of a coating mechanism of a device for pole piece lithium supplement according to the present invention.

The coating mechanism of fig. 6 is a press coating mechanism M3. The extrusion coating mechanism M3 includes a housing tank M31, a screw pump M32, and a coating head M33, the housing tank M31 is used for housing a corresponding lubricating substance or release agent, the screw pump M32 is used for delivering the corresponding lubricating substance or release agent to the coating head M33, and the coating head M33 is used for coating the corresponding lubricating substance or release agent to a corresponding separator (i.e., the first separator S1 or the second separator S2). The coating head M33 may be set to timed feed and retract modes to achieve intermittent coating. The coating head M33 set a continuous feed mode to achieve continuous coating.

In summary, in the embodiment of fig. 1 to 3, by using the lubricating substance applying mechanism 32 to apply the lubricating substance to the surface of the first separator S1 and/or the second separator S2 facing the lithium strip L0 before entering the two rollers 34, the rolling force between the two rollers 34 can be reduced, so that the damage of the rollers to the first separator S1 and the second separator S2 when the lithium strip L0 is rolled into the lithium foil L1 can be reduced, and the first separator S1 and the second separator S2 can be recycled.

The above detailed description describes exemplary embodiments, but is not intended to limit the combinations explicitly disclosed herein. Thus, unless otherwise specified, various features disclosed herein can be combined together to form a number of additional combinations that are not shown for the sake of brevity.

Claims (10)

1. A mechanism (3) for lithium film formation, characterized in that,

the mechanism (3) for forming the lithium film comprises a first separation film providing mechanism (31A), a second separation film providing mechanism (31B), a lubricating substance applying mechanism (32), a lithium belt providing mechanism (33) and two rollers (34);

a first separator supply mechanism (31A) located upstream of the two rolls (34), the first separator supply mechanism (31A) for supplying a first separator (S1) between the two rolls (34),

a second separator supply mechanism (31B) located upstream of the two rolls (34), the second separator supply mechanism (31B) for supplying a second separator (S2) between the two rolls (34),

a lithium tape supply mechanism (33) is located upstream of the two rolls (34), the lithium tape supply mechanism (33) being capable of positioning the lithium tape (L0) between the first separator (S1) and the second separator (S2) and for supplying the lithium tape (L0) between the two rolls (34),

a lubricating substance applying mechanism (32) is located upstream of the two rolls (34), the lubricating substance applying mechanism (32) being for applying a lubricating substance to a surface of the first separator (S1) and/or the second separator (S2) facing the lithium ribbon (L0) before entering the two rolls (34);

two rolling rolls (34) are used for rolling the first separation film (S1), the lithium strip (L0) and the second separation film (S2) so as to roll the lithium strip (L0) into a lithium foil (L1) and make the lithium foil (L1) adhere to the second separation film (S2) to form a lithium film (C).

2. The mechanism (3) for lithium film formation according to claim 1, wherein the lubricating substance applying mechanism (32) is a coating mechanism.

3. Mechanism (3) for lithium film forming according to claim 1,

the mechanism (3) for lithium film formation further comprises a first separator take-up mechanism (35),

a first separator take-up mechanism (35) is located downstream of the two rolls (34), the first separator take-up mechanism (35) being for taking up the first separator (S1) passing between the two rolls (34).

4. Mechanism (3) for lithium film forming according to claim 1,

the mechanism (3) for lithium film formation further includes a release agent supply mechanism (36),

a release agent supply mechanism (36) is located between the two rolls (34) and the first separator take-up mechanism (35), the release agent supply mechanism (36) being for supplying a release agent to a surface of the first separator (S1) facing the lithium ribbon (L0).

5. The mechanism (3) for lithium film formation according to claim 4, wherein the release agent supply mechanism (36) is a coating mechanism.

6. A device for pole piece lithium supplement comprises a pole piece (P0) and a pole piece supply mechanism (2), wherein the pole piece (P0) comprises a current collector (P01) and an active material layer (P02) arranged on the surface of the current collector (P01),

the rolling mechanism (1) comprises two pressing rollers (11);

a pole piece supply mechanism (2) is positioned at the upstream of the two compression rollers (11), the pole piece supply mechanism (2) is used for supplying a pole piece (P0) between the two compression rollers (11),

it is characterized in that the preparation method is characterized in that,

the device for pole piece lithium replenishment further comprises a mechanism (3) for lithium film forming according to any one of claims 1 to 5, the mechanism (3) for lithium film forming being located upstream of the two pressure rollers (11);

the rolling mechanism (1) is used for rolling the lithium film (C) and the pole piece (P0) so as to enable the lithium foil (L1) in the lithium film (C) to adhere to the active material layer (P02).

7. The device for lithium supplement of the pole piece according to claim 6,

the device for supplementing lithium to the pole piece also comprises a second isolating film collecting mechanism (4),

the second separator take-up mechanism (4) is located downstream of the two pressing rollers (11), and the second separator take-up mechanism (4) is configured to pass the lithium film (C) between the two pressing rollers (11) and take up the second separator (S2) in the lithium film (C) passed between the two pressing rollers (11).

8. The device for lithium supplement of the pole piece according to claim 6,

the device for supplementing lithium to the pole piece also comprises a lithium supplementing pole piece collecting mechanism (5),

the lithium supplement electrode sheet collecting mechanism (5) is positioned at the downstream of the two compression rollers (11), and the lithium supplement electrode sheet collecting mechanism (5) is used for collecting the electrode sheet (P0) of which the active material layer (P02) is adhered with the lithium foil (L1).

9. The device for pole piece lithium replenishment according to claim 6, characterized in that the means for lithium film formation (3) and the second separator take-up means (4) are in two groups to provide lithium foil (L1) to both surfaces of the pole piece (P0).

10. The device for pole piece lithium replenishment according to claim 7, characterized in that the device for pole piece lithium replenishment further comprises a release agent supply mechanism (36) disposed between the two pressing rollers (11) and the second separator take-up mechanism (4) for supplying a release agent to the surface of the second separator (S2) facing the lithium replenishment pole piece (P1).

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