EP3005448A1 - Method for producing an electrode and device for producing an electrode - Google Patents

Abstract

The invention relates to a method for producing an electrode, wherein in a first method step a coating is applied to an electrode substrate in such a way that at least one coated region and at least one uncoated region are formed, wherein in a second method step at least a part of the coating is removed from the coated region.

Description

 DESCRIPTION

title

 Method for producing an electrode and device for

 Production of an electrode

State of the art

The invention relates to a method for producing an electrode and to an apparatus for producing an electrode.

Electrodes are well known and are an integral part of batteries.

Typically, an electrode intended for a battery consists of an electrode substrate, preferably a metal foil, and a coating. The

Coating, preferably a layer of active material, is usually applied to the

 Electrode substrate applied, wherein the coating does not extend over the entire region of the electrode substrate. Typically, the coating is formed so that the metal foil remains uncoated at its edge regions. These uncoated areas serve as Abieiter for the electrode. Decisive for the quality of the electrode is the uniform or uniform coating. inferior

 Electrodes can adversely affect the performance of the later battery. In general, the quality of the electrode is devalued by the nature of the coating on its edge regions, since the shape of the edges and their positioning

subject to production-related fluctuations. Is the metal foil on two

coated opposite sides, an offset of the two coated areas to each other can cause the two coating layers are not congruent superimposed and thereby the quality of the electrode is reduced so that the electrode is unusable for a battery. Alternatively, the prior art therefore proposes to coat the metal foil completely with an active material and then expose the Abieiter by means of laser ablation. In this case, active material is removed in a disadvantageous manner over a large area, as a result of which a large amount of active material is consumed uselessly. Moreover, if one is interested in coating the electrodes on both sides, there is the problem that a transport means provided for the transport of the electrode substrate has no possibility of gripping the electrode without contacting the coating. By contacting the coating by the Berförderungsmittel there is a risk that To contaminate and / or deform coating layer. As a result, the quality of the coating and thus the electrode is reduced.

Disclosure of the invention

It is an object of the present invention to inexpensively realize electrodes whose coating has homogeneous and uniform edges or edges, wherein

Homogeneity and uniformity affects both the positioning on the electrode substrate and the height profile of the coating. In addition, it would be desirable to realize electrodes coated on both sides whose coatings are substantially congruent to one another.

The object is achieved by a method for producing an electrode, wherein in a first method step, a coating, so applied to an electrode substrate, that at least one coated area and at least one uncoated area are formed, wherein the coated area has a coating and the uncoated area has no coating, and, wherein in a second process step at least a portion of the coating is removed from the coated area.

The inventive method has the advantage over the prior art that less coating must be removed. In addition, the established coating methods can advantageously be used in order to coat the electrode substrate in the first method step. Thus, it is possible in an advantageous manner to resort to existing production facilities or parts of the manufacturing plant, and thus to dispense with a cost associated with additional new acquisition of a manufacturing plant for coating. In addition, in the second process step, less active material is removed if the coated electrode substrate has non-coated areas instead of being completely coated. As a result, active material can be saved in an advantageous manner, which is removed from the electrode substrate.

It is conceivable that the coating is completely removed in one part (ie the electrode substrate is exposed) or is only partially removed in this area, in particular only part of the surface of the coating, in order to realize a level profile of the coating. As a result, the edge of the coating after the first method step is advantageously corrected or reworked such that the coating is configured homogeneously and uniformly with respect to positioning and height profile. Preferably, the electrode substrate is a metal foil and / or the coating is active material. In particular, an electrode is provided for a battery, in particular a lithium-ion battery, supercaps or the like. For example, to form a battery, the electrode may be wound up or stacked together with other electrodes and separators.

Advantageous embodiments and modifications of the invention are the dependent claims, as well as the description with reference to the drawings. In a preferred embodiment of the present invention, it is provided that the part which is removed in the second method step adjoins the non-coated area before the removal. In this way, it is advantageously possible to correct "frayed" parts in the boundary region between the coated and uncoated regions and to realize a smooth or straight edge between the coated and uncoated regions

Boundary can be advantageously ensured that the distance from the electrode edge to the edge of the coated area remains constant, creating a uniform

Positioning on the electrode substrate can be realized. In particular, it is provided that the distance from the electrode edge to the edge of the coated region remains constant for different electrodes of a production series as a result of the second method step. The removal of the coating is not limited to a preferred direction. It is conceivable, for example, for the electrode substrate to be present as a quasi-continuous band which is not continuously coated along a running direction in a first method step, and for the removal in the second method step both along a direction substantially parallel to the running direction and substantially perpendicular to the running direction Direction takes place. In particular, it is provided that the fabricated electrode has a rectangular shaped coated area and the electrode substrate is uncoated at all edges of the electrode.

In a further embodiment, it is provided that the electrode substrate comprises an electrode substrate edge and the non-coated region on

Electrode substrate edge is arranged. In this case, such a non-coated area is particularly suitable for serving as a conductor for the electrode or a battery. It may prove to be an advantage to use the uncoated region as Abieiter if the ablation process used incomplete or only partially removed from the electrode substrate, thereby adversely affecting the electrical properties of the Abieiter, such as its conductivity. It is also conceivable that the ablation process itself will be the properties of the future abieiter negatively influenced. According to the present embodiment, instead, it is possible to use a part of the electrode substrate which is part of the

Production process was advantageously not or only minimally coated. In a further embodiment it is provided that the coated

 Electrode substrate is transported during the removal by means of a conveyor. It is provided that an ablation unit or a removal means, is arranged stationary, while the coated electrode substrate relative to

Abtragungsmittel is transported. As a result, it can be advantageously ensured that the method is integrated as a manufacturing component in the production of batteries, wherein the production also includes, for example, the winding of the electrode or the stacking of a plurality of electrodes and a plurality of separators.

In a further preferred embodiment, it is provided that the

uncoated area is used by the conveyor and / or a guide means for conveying and / or guiding the electrode substrate. It is advantageous that the uncoated area is suitable for transporting a

Make contact point available so that the means of transport can transmit a necessary force for transport to the coated electrode substrate without touching the coating and thus possibly damage this coating. Likewise, it is conceivable that the non-coated area is intended to restrict the freedom of movement of the coated electrode substrate during transport, for example, possible lateral displacements of the coated

To prevent electrode substrate or limit their amplitude to a level that does not adversely affect the production of the electrode or the battery.

In a further preferred embodiment, it is provided that the removal of a portion of the coating, a further non-coated area is formed and / or a portion of the coating is removed between two coated areas. As a result, a multiplicity of electrodes can advantageously be produced in a production process comprising the first and the second method step. For this purpose, it is provided to divide the coated electrode substrate after the second method step in such a way that uncoated and / or further uncoated regions form the edges of the finished electrode. The non-coated region preferably extends parallel and / or perpendicular along the main direction of extension of the electrode substrate or the preferred direction of the coating through the coating. In this way, in particular one after the other or next to each other a plurality of coated Electrode areas are generated, and thus an efficient mass production of electrodes can be achieved.

In a further preferred embodiment, it is provided that the removal takes place with the aid of electromagnetic waves, preferably laser light. When

 Abtragungseinheit is then provided, for example, a laser. The removal by means of electromagnetic waves can ensure that the coating can be removed from the coated electrode substrate as precisely and as quickly as possible in a more advantageous manner. In a further embodiment, it is provided that the electromagnetic waves are focused by means of a focusing device on the ablated part of the coated area. It is conceivable, for example, that the beam cross-section is tapered with the aid of lenses if the removal is to be limited to a smaller partial area of the coated area. As a result, the same ablation effect can be achieved with comparatively less expenditure of energy. In this way, energy costs can be reduced in the manufacture of the electrode, since higher intensities, in particular ablation intensities, can be achieved with a smaller cross section for the same laser power. It is also conceivable that a lens system is provided that adapts the degree of focusing to the required effort required for the removal of the coating.

In a further embodiment, provision is made for a direction along the direction perpendicular to the main extension plane of the electrode substrate

coated areas on opposite sides of the electrode substrate and

uncoated areas are formed. As a result, it is advantageously possible to ensure, in the case of electrode substrates coated on both sides, that the

opposite or underlying coatings are arranged congruent. In particular, such coated on both sides

Electrode substrates that would otherwise have been disposed of because of the insufficient congruence of their coating. This can advantageously on the disposal or complex recycling of a coated on both sides

Electrode substrate be waived if the two opposite

Coatings after the coatings do not have the necessary congruence. In a further embodiment, it is provided that for the second method step, the electrode substrate is positioned, wherein by means of a detection means, the uncoated and / or the coated area and / or the boundary between uncoated and coated area is used for positioning. It is provided that the detection means detects the position of the electrode substrate, for example in which a camera observes at least a part of the electrode substrate. If the determined, ie the actual position deviates from a desired position, it is provided that the position of the electrode substrate is changed until the actual position corresponds to the desired position. By means of this positioning operation, the accuracy with which the edge of the coated area is arranged on the electrode substrate can advantageously be further improved. Another object of the present invention is a device for producing an electrode, in particular according to one of the methods described above, wherein the device comprises a coating unit which is designed such that in a first step on the electrode substrate coated area and

forms uncoated areas, and wherein the apparatus further includes

Abtragungseinheit has, which is designed such that a portion of the coating in the coated area in a second process step is ablatable. With such a device can be realized in an advantageous manner, an electrode whose boundary between the coated and uncoated area forms a straight edge, the coating has a flat height profile and their coatings is congruent, if it is a coated on both sides electrode substrate.

In a further embodiment, it is provided that the device a

Conveying means which is designed such that the electrode substrate is movable relative to the Abtragungseinheit. This can advantageously the

Electrode substrate are moved while the removal of parts of the coating takes place.

In a further embodiment, it is provided that the device a

Having detection means. The detection means supported in advantageous and

in a straightforward way, the exact positioning of the electrode substrate in the device and thereby ensures that the boundary between coated and uncoated area forms a straight edge, the coating has a flat height profile and / or the coatings are congruent, if it is a coated on both sides electrode substrate is. In a further embodiment, it is provided that the removal unit is arranged directly in front of a calendering unit and / or directly after a drying device for drying the coated electrode substrate in a plant for the production of batteries is. Such an arrangement proves to be advantageous in that it can be easily and simply integrated into the manufacturing process of a battery.

Further details, features and advantages of the invention will become apparent from the

Drawings, as well as from the following description of preferred

 Embodiments with reference to the drawings. The drawings illustrate only exemplary embodiments of the invention, which the essential

Do not limit the idea of the invention. Brief description of the figures

FIGS. 1 a to d show the developmental history of a single-sidedly coated electrode according to a method according to the invention in a plan view, starting with an uncoated electrode substrate (FIG. 1 a), after the first method step (FIG. 1 b) and after the second method step (FIG. 1 c) and FIG. 1 d).

2 a to d show the developmental history of a single-sidedly coated electrode according to a method according to the invention as a cross section, beginning with an uncoated electrode substrate (FIG. 2 a), after the first method step (FIG. 2 b) and after the second method step (FIG. 2 c and FIG. ,

FIGS. 3 a to d show the developmental history of a double-coated electrode according to a method according to the invention as a cross section, starting with an uncoated electrode substrate (FIG. 2 a), after the first method step (FIG. 2 b) and after the second method step (FIG. 2 c and FIG. ,

FIGS. 6 a and b show a part of the development history of an electrode according to the method according to the invention in a further embodiment. FIG. 7 shows a device for producing an electrode in accordance with FIG

inventive method.

EMBODIMENTS OF THE INVENTION In the various figures, identical parts are always provided with the same reference numerals and are therefore generally named or mentioned only once in each case. FIGS. 1 a to d follow the production process of a single-sidedly coated electrode 1 from a top view according to a method according to the invention by means of snapshots at the beginning, during and after completion of the method. FIG. 1 a illustrates an uncoated electrode substrate 39 with one

Main extension plane and an electrode substrate edge 41. Typically, the uncoated electrode substrate 39 is a metal foil. However, it is also conceivable that the uncoated electrode substrate 39 is present as a quasi-endless band, which is continuously fed to the manufacturing process of the electrode. When the uncoated electrode substrate 39 is fed to a coating unit as a quasi-endless belt, the direction of travel of the belt through the coating unit generally defines a preferred direction A along which a coating 2 is applied to the uncoated electrode substrate 39. FIG. 1 b shows how a coating 2, according to a first method step of the method according to the invention, is divided along a preferred direction A into a coated electrode substrate 40 in coated regions 3 and non-coated regions 4. In this case, the coated region 3 has two edges 8 which run essentially parallel to one another and substantially parallel to one of the electrode substrate edges 41. It can be seen that after the first

Process step none of the edges of the coated area 8 forms a smooth and sharp edge. Instead, the distance between the electrode substrate edge 41 and the edge of the coated region 8 varies along the preferred direction A. In particular, these variations in distance are subject to fluctuations that are caused by

Coating process, and are stochastically distributed along the preferred direction A. In the state after the first process step, the coated

Electrode substrate 40, in particular the edge of the coated area 8, do not have the quality that would be desirable, for example, for integration as an electrode in a battery. In a second process step of the invention

Method is a part of the coating 2 removed, for example by laser ablation. FIG. 1 c shows the coated electrode substrate after the second method step, with the removed coatings 5 being dotted for better understanding

Areas are part of the figure, but are no longer present at the time of the snapshot. According to the method of the invention, it is possible to realize an electrode 1, as shown in FIG. 1 d, the edge of the coated area 8 forming a straight edge. The distance 15 between the edge of the coated area 8 and the electrode substrate edge 41 remains along the edge or along the edge

Preferred direction A advantageously constant. As a result, an uncoated region 4 is provided to the electrode, which can serve as the Abieiter 6 of the electrode 1. In particular, it is provided that after the second process step Abieiter 6 are arranged on two electrode substrate edges 41. If the coated electrode substrate 40 after the second process step before as a quasi-endless belt, it is particularly intended to divide the quasi-continuous band to electrodes 1 for

To provide, which can be used preferably as a component of a battery use. To form a battery, it is customary to wind up the electrode 1 or to stack it together with other electrodes and separators.

FIGS. 2 a to d follow the production process of a single-sidedly coated electrode 1 according to a method according to the invention on the basis of snapshots at the beginning, during and after completion of the method, wherein the electrode is shown in cross section. After the non-coated electrode substrate 39 from FIG. 2 a has been provided with a coating 2 in a first method step, the electrode substrate 40 coated in FIG. 2 b has coated area 3 and uncoated areas 4. It can be seen that the edge 8 of the coated area does not form a sharp edge that is perpendicular to the main plane of extension. Instead, a coated area 3 is realized by the coating process, the from the

Electrode substrate edge 41 seen gradually increases in height. In particular, hills form, d. H. Areas where the coating 2 is higher than in the other areas of the coating. These elevations or unevenness in the height profile of the coating can have an adverse effect on the stacking of electrodes with separators because they may prevent the entire surface of the

Coating is applied to a separator or to another coated electrode. This disadvantageously leads to possibly stacked layers being able to move relative to one another due to the reduced frictional effect between them. Moreover, if a plurality of electrodes are stacked, it is to be expected that the elevations in the coating lead to unnecessarily increased space requirements for the stacked electrodes. In a second process step, a part of the coating is removed in such a way that both the elevation or the dome and the successive increase in the coating disappear in height. This is shown in FIG. 2 c, in which the removed coating is shown as a dotted area 5. However, it is also conceivable that in an alternative embodiment of the method according to the invention, in particular in the second method step, elevations in the coating are removed, which are not arranged directly on the edge of the coated area 4 but for example in the middle of the coated area. In such situations, it is preferably provided that only a part of the coating is removed. In particular, only so much is removed that the coating 2 in the coated area 3 has a level height profile. The finished electrode 1 after the second process step is shown in Figure 2d. The illustrated unilaterally coated electrode 1 advantageously has a coating 2 with a flat height profile and a rim 8, which forms an edge which is perpendicular to the main extension plane. FIGS. 3 a to d follow the production process of a coating coated on both sides

Electrode 1 according to a method of the invention based on snapshots at the beginning, during and after completion of the method, which is shown as a cross section. After the uncoated electrode substrate from FIG. 3 a has been coated in a first method step, the coated one illustrated in FIG

Electrode substrate on both sides coated areas 3 and uncoated

 Areas 4 on. In this case, the areas coated on the two sides are arranged so that an upper coating 21 and a lower coating 22 substantially follow one another along a direction perpendicular to the main extension plane

opposite, wherein the electrode substrate 40 between upper and lower

Coating 21 and 22 is arranged. However, FIG. 3b also illustrates that after the first method step, the upper coating 21 and the lower coating do not

are arranged congruently, d. H. the edges 8 of the upper coating 22 and the lower coating 21 are not superimposed. In such a condition with congruent coatings is a coated electrode substrate for the

Integration as an electrode in a battery unsuitable. In a second method step, so much coating is removed that the edges 8 of the upper and lower coatings 22 and 21 overlap one another along a direction perpendicular to the main extension plane. Figure 3 c illustrates dotted the ablated areas 5 of

Coating. In an alternative embodiment of the method according to the invention, it is provided that in the first method step the double-sided coating takes place in such a way that, for example, the edges of the lower coating are always arranged below the upper coating, e.g. the upper coating is wider than the lower coating. In this alternative embodiment, it is possible to remove only parts of the coating from the upper coating in a second process step. FIG. 3 d shows the electrode after the second method step, when the upper and lower coatings 21 and 22 advantageously overlap one another congruently and are arranged on both sides of the electrode substrate 40. In this case, the edges 8 of the lower and upper coating are superimposed. FIGS. 4 a to d follow the production process of a one-sided, along one

Preferred direction A non-continuously coated electrode 1 from a plan view according to a method according to the invention by means of snapshots at the beginning, while and after completing the procedure. After the non-coated electrode substrate 39 from FIG. 4 a has been provided with a non-continuous coating 2 running along a preferred direction A in a first method step, the electrode substrate 40 coated in FIG. 4 b comprises coated area 3 and uncoated areas 4. It can be seen that the coated regions 3 are frayed in the border region to the non-coated regions 4, ie, no sharp or straight edges are formed. In a second method step, the coating 2 is removed in such a way that both along the preferred direction A and in a direction perpendicular thereto in each case in the boundary region of the coated and uncoated regions 3 and 4, a sharp or straight edge is formed. FIG. 4c dotted depicts the ablated regions 5. Alternatively, the coating 2 can be removed in such a way that a predetermined and desired edge course is realized by the second method step. FIG. 4 d shows the electrode 1 after the second method step, when the coated regions 3 of the electrode 1 are formed as rectangular surfaces, each with sharp and smooth edge progressions. The rectangular shaped, coated regions 3 are arranged along the preferred direction A at a distance from one another on the coated electrode substrate. In particular, it is intended that

Separate electrode substrate 2 at the non-coated areas 4 between the coated areas 3 to a plurality of flat, rectangular coated

To obtain electrodes, for example, form a part of a battery stacked.

FIGS. 5 a to d follow the production process of an electrode 1, which is not coated on both sides along a preferred direction A, from a plan view according to a method according to the invention by means of snapshots at the beginning, during and after completion of the method. After each side of the uncoated

Electrode substrate 39 of Figure 5a in a first step with a

4b, the coated electrode substrate 40 has coated region 3 and non-coated regions 4. In this case, the regions 3 coated on the two sides are arranged such that an upper coating 21 and a lower coating 22 follow one another along a plane perpendicular to the main extension plane

extending substantially opposite, wherein the electrode substrate 40 between upper and lower coatings 21 and 22 is arranged. However, FIG. 5b also illustrates that after the first method step, the upper coating 21 and the lower coating are not arranged congruently, ie the edges 8 of the upper coating 22 and the lower coating 21 do not overlap one another. this applies both in a direction extending along the preferred direction and in a direction perpendicular thereto. For clarity, the dashed white line is the

Edge profile of the lower coating 22 located. With congruence

Coatings, a coated electrode substrate 40 is unsuitable for integration as an electrode 1 into a battery. In a second method step, the coating 2 is removed in such a way that the remaining upper and lower coatings 21 and 22 overlap one another congruently. In particular, both the edge of the upper coating 21, which extends parallel to the preferred direction A and that which extends perpendicular to the preferred direction A over the corresponding edges of the lower coating 22. The upper and lower coatings 21 and 22 are then superimposed congruent in that the resulting electrode can become part of a battery.

Figures 6 a and b follow the manufacturing process of an electrode 1 according to another embodiment of the method according to the invention in a plan view. FIG. 6 a shows the coated electrode substrate 40 after the first method step, wherein the coated electrode substrate 40 has coated regions 3 which are arranged adjacent to one another along the preferred direction A. In the second method step, a part of the coating 2 is removed such that a further uncoated region 4 'is formed. As a result, the coated areas 3 are after the second

 Process step also arranged adjacent to each other in the direction perpendicular to the preferred direction extending direction. An electrode 1 with the coated regions 3 adjacent to a direction perpendicular to the preferred direction A is shown in FIG. 6b. In an alternative embodiment, the coated electrode substrate 40 has only a single coated area 3 after the first method step, and the second method step generates one or more further non-coated areas 4 'by the removal of the coating. In this embodiment of the method, in a fabrication process of an electrode comprising the first and second process steps, a plurality of electrodes 1 may be generated, for example, when the coated electrode substrate 40 is divided after the second process step, that is at least one coated region 3 remains on the separated portion of the coated electrode substrate.

FIG. 7 shows an ablation unit for an apparatus 100 according to the invention for producing an electrode, comprising an x-directional movable frame 10, on which four laser sources 20 are arranged, which are each provided for emitting laser light 25. In the illustrated ablation unit is a two-sided coated electrode substrate 40 with coated areas 3 and uncoated areas 4 arranged such that laser light 25 falls from the laser sources 20 directly on the or the abzutragenden parts of the coating. Thus the or the parts of the

Coating 2 are removed, which must be removed to realize a high-quality electrode, it is crucial to position the coated electrode foil relative to the ablation unit. To support the positioning, a detection means 30 is arranged on the movable frame 10. The detection means registers

For example, a lateral displacement of the electrode substrate 40 when the position of the electrode substrate rim 41 changes relative to a desired position. With the help of

Detection means 30, the movable frame 10 can be tracked so that the electrode substrate 40 remains substantially always in the desired position .. With the help of such Abtragungseinheit is able to realize, for example, a double-coated electrode, the upper and lower Coating 21 and 22 are congruent. It is also conceivable that during the removal of the electrode substrate 40 is transported by a means of transport.

LIST OF REFERENCE NUMBERS

1 electrode

 2 coating

 3 coated area

 4 uncoated area

 4 'further uncoated area

 5 removed coating

 6 Abieites

 8 edge / edge of the coated area

 10 moving frames

 15 Distance between edge of coated area and electrode substrate edge

20 light source

 21 upper coating

 22 lower coating

 25 laser light

 30 detection means

 39 uncoated electrode substrate

 40 electrode substrate

 41 electrode substrate edge

 100 device

 A preferred direction of the coating

 X Movement direction of the movable frame

Claims

1 . Method for producing an electrode (1), wherein in a first

 Process step, a coating (2) is applied to an electrode substrate (40) such that at least one coated region (3) and at least one uncoated region (4) is formed, characterized in that in a second process step at least a part of the coating (2 ) is removed from the coated area (3).

A method according to claim 1, wherein the part of the coating (2) which is removed in the second method step adjoins the non-coated area (4) before the removal.

Method according to one of the preceding claims, wherein the

 Electrode substrate (40) comprises an electrode substrate edge (41) and wherein the uncoated region (4) is disposed on the electrode substrate edge (41).

Method according to one of the preceding claims, wherein the

 Electrode substrate (40) is transported during the removal by means of a conveyor.

A method according to claim 4, wherein the uncoated region (4) on the

 Electrode substrate edge (41) from the conveyor and / or a

 Guide device is used for the carriage and / or guidance of the electrode substrate.

Method according to one of the preceding claims, wherein the removal of a part of the coating (2) forms a further non-coated area (4 ') and / or a part of the coating is removed between two coated areas (3).

Method according to one of the preceding claims, wherein the coating with the aid of electromagnetic waves, in particular laser light, is removed.

8. The method according to claim 6, wherein the electromagnetic waves by means of a focusing device on the ablated portion of the coated area (3) be focused.

9. The method according to any one of the preceding claims, wherein in the first

 In the method step, the electrode substrate is coated in such a way that coated regions and uncoated regions are formed on opposite sides along a direction perpendicular to the main extension plane of the electrode substrate (40).

10. The method according to any one of the preceding claims, wherein for the second

 Process step, the electrode substrate (40) is positioned, wherein by means of a

Detection means (30) the uncoated and / or the coated area and / or the boundary between uncoated and coated area is used for positioning. 1 1. An apparatus (100) for producing an electrode (1), in particular according to one of the preceding claims, wherein the apparatus (100) has a coating unit which is configured such that a coated area (3) and an uncoated area are present on the electrode substrate (40) Areas (4) is formed, characterized in that the device (100) has an ablation unit which is designed such that a part of the coating (2) in the coated

Area (3) is removed.

12. Device (100) according to claim 1 1, wherein the device (100) a

 Conveying means, which is designed such that the electrode substrate (40) is movable relative to the Abtragungseinheit

13. Device (100) according to claim 1 1 or 12, wherein the device (100) a

 Detection means (30) for positioning the device (100) relative to

 Electrode substrate (40) or for positioning the electrode substrate (40) relative to the device (100).

14. Device (100) according to one of claims 1 1 to 13, wherein the

 Abtragungseinheit is arranged directly in front of a calendering unit and / or directly after a drying device for drying the coated electrode substrate (40) in a plant for the production of batteries.