DE102010053341A1 - Cutting sheet-or plate-shaped object, made of electrodes and/or separators, useful for producing electrochemical energy storage device or parts of electrodes or separators, comprises e.g. introducing the object into a laser cutting device - Google Patents

Abstract

Cutting a sheet-or plate-shaped object (1), preferably made of electrodes and/or separators, for producing an electrochemical energy storage device or parts of such electrodes or separators, comprises (i) introducing the object to be cut, into a laser cutting device (2), (ii) cutting of the objects using the laser cutting device, and (iii) carrying out machining operations at the cutting edges (3), for reducing micro-short circuit. INDEPENDENT CLAIM is also included for a system for cutting sheet-or plate-shaped object, preferably for cutting electrodes and/or separators, comprising (a) a conveying device (5) for conveying the objects to be cut, into a laser cutting device, (b) a laser cutting device, for cutting the objects, and (c) a laser processing device (4) for carrying out machining operations at the cutting edges, for reducing micro-short circuits.

Description

The present invention relates to a method and a system for cutting sheet-like or plate-shaped objects, in particular for cutting electrodes and / or separators for constructing an electrochemical energy store or parts of such electrodes or separators.

As electrochemical energy storage batteries (primary storage) and accumulators (secondary storage) are known, which are composed of one or more memory cells in which upon application of a charging current, electrical energy in an electrochemical charging reaction between a cathode and an anode in or between an electrolyte in chemical Energy is converted and stored and in which when connecting an electrical load chemical energy is converted into electrical energy in an electrochemical discharge reaction. Primary storage is typically charged only once and disposed of after discharge, while secondary storage allows multiple (from a few 100 to over 10,000) cycles of charge and discharge. In this context, it should be noted that, especially in the automotive sector, rechargeable batteries are also referred to as batteries.

In the present case, an "electrochemical energy store" is to be understood as meaning any type of energy store in which electrical energy can be taken, wherein an electrochemical reaction takes place in the interior of the energy store. The term includes energy storage of all kinds, in particular primary batteries and secondary batteries. The electrochemical energy storage device comprises at least one electrochemical cell, preferably a plurality of electrochemical cells. The plurality of electrochemical cells may be connected in parallel to store a larger amount of charge, or may be connected in series to provide a desired operating voltage, or may be a combination of parallel and series connection.

By an "electrochemical cell" is meant a device which serves to deliver electrical energy, the energy being stored in chemical form. In the case of rechargeable secondary batteries, the cell is also designed to receive electrical energy, convert it to chemical energy, and store it. The shape (i.e., size and geometry, in particular) of an electrochemical cell can be chosen depending on the available space. Preferably, the electrochemical cell is formed substantially prismatic or cylindrical. The present invention is particularly useful for electrochemical cells, referred to as pouch cells or coffeebag cells, without the electrochemical cell of the present invention being limited to this application.

Such an electrochemical cell usually has an electrode stack, which is at least partially enclosed by an envelope. In this context, an "electrode stack" is to be understood as meaning an arrangement of at least two electrodes and an electrolyte arranged therebetween. The electrolyte may be partially received by a separator, the separator then separating the electrodes. Preferably, the electrode stack has a plurality of layers of electrodes and separators, wherein the electrodes of the same polarity are each preferably electrically connected to one another, in particular connected in parallel. The electrodes are for example plate-shaped or foil-like and are preferably arranged substantially parallel to one another (prismatic energy storage cells). The electrode stack may also be wound and have a substantially cylindrical shape (cylindrical energy storage cells). The term "electrode stack" is also intended to include such electrode coils. The electrode stack may also comprise lithium or another alkali metal in ionic form.

The electrodes and separators are needed in a very large number, which is why there is a need for high-quality, effective and cost-effective manufacturing processes. When manufacturing the electrodes and separators, it should be noted that these components must be cut to the appropriate dimensions for the assembly of the electrode stacks or cells. For a continuous production line, the electrodes and the separators are cut from electrode strips or separator strips.

It is therefore an object of the present invention to provide an improved method and system for cutting sheet or plate shaped objects.

This object is achieved by a method and a system for cutting sheet or plate-shaped objects according to one of the independent claims. Advantageous embodiments and further developments are the subject of the dependent claims.

In a first aspect, the invention relates to a cutting method. In the method for cutting sheet or plate-shaped objects, in particular of electrodes and / or separators for construction. an electrochemical energy store or parts Such electrodes or separators, this object is achieved in that the cutting method comprises: leading the objects to be cut to a laser cutting device, cutting the objects with the laser cutting device and performing machining operations on the cutting edges to reduce microcircuits. This embodiment has the advantage that the cutting operations can be carried out quickly and the cutting edges have a quality required for further use, since micro-shorts can be avoided or sufficiently reduced with the machining processes at the cutting edges.

It has proven to be advantageous if the step of performing machining operations on the cutting edges to reduce micro-short circuits has a structuring of the cutting edges. Preferably, in this embodiment, the step of patterning the cutting edges is performed with a laser structuring device. An advantage of this embodiment is that microshorting can be avoided particularly quickly and effectively by such structuring.

The step of patterning the cutting edges with the laser structuring device may be performed after the step of cutting the object with the laser cutting device. Alternatively, the step of patterning the cutting edges with the laser structuring apparatus may also be performed prior to the step of cutting the object with the laser cutting apparatus. In these embodiments, for the step of patterning the cutting edges as the laser patterning apparatus, the laser cutting apparatus may be used.

According to another embodiment, the step of patterning the cutting edges with the laser structuring device and the step of cutting the objects with a laser cutting device may be performed substantially simultaneously.

In another embodiment, the step of performing machining operations on the cutting edges to reduce microcircuits may include applying support materials to the cutting edges. An advantage of this embodiment is that the cutting can be assisted with a laser beam.

Preferably, the step of applying support materials to the cutting edges and the step of cutting the objects with the laser cutting device are performed substantially simultaneously. More preferably, the support materials have components with increased absorption coefficients with respect to the wavelengths used by the laser cutting apparatus.

In a second aspect, the invention relates to a cutting system. In the system for cutting sheet or plate-shaped objects, in particular for cutting electrodes and / or separators for the construction of an electrochemical energy storage or parts of such electrodes or separators, this object is achieved in that the cutting system, a transport device, which is used to bring the is designed to cut objects to a laser cutting device, a laser cutting device, which is designed for cutting the objects, and a processing device, which is designed for performing machining operations on the cutting edges to reduce microcircuits.

In the case of the processing device, a laser structuring device which is designed to structure the cutting edges preferably has. Alternatively and / or additionally, the processing device may comprise a material application device, which is designed for the application of support materials to the cutting edges.

In the context of this invention, a "sheet-like or plate-shaped object" is to be understood as meaning a substantially flat article, preferably a thin flat article. A flat article is an article whose dimensions in a direction perpendicular to its surface (also referred to as the thickness direction) are substantially smaller than the dimensions of the largest sections that lie completely within the surface.

With regard to the advantages of this cutting system and the terms used, the statements made above in connection with the cutting method according to the invention apply correspondingly.

The present invention also relates to an electric cell for an electrochemical energy storage device having separators cut by a cutting method as mentioned above and / or produced by means of a cutting system as mentioned above.

Further advantages, features and applications of the present invention will become apparent from the following description taken in conjunction with the drawings. Show it:

1 a schematic representation of a cutting system according to an embodiment of the invention, and

2 a flowchart of a cutting method according to an embodiment of the invention.

The present invention will be described below using the example of cutting separators and electrodes for an electrochemical energy store.

1 shows a schematic representation of a cutting system 10 according to an embodiment of the present invention. The cutting system 10 has a transport device 5 on, leading to the introduction of the separator belt to be cut 1 or the electrode band to be cut 1 to a laser cutting device 1 is designed. The laser cutting device 2 cuts with a laser cutting beam 2a the separator belt 1 or the electrode band at the cutting edge 3 , In the 1 It is shown that the cutting process with a material jet 6a the material application device 6 at the cutting edge 3 can be supported. Furthermore, in the 1 a laser structuring device 4 shown the separator belt 1 or the electrode band at the cutting edge 3 with a laser structuring beam 4a can structure. After the cutting processes are from the Separatorenband 1 cut separators 1' or the electrodes cut from the electrode band with the removal device 7 from the cutting system 10 removed.

2 shows a flow chart for a cutting method according to an embodiment of the present invention. The separator belt to be cut 1 is introduced to the laser cutting device in a step S1. In a step S2, the separators 1' from the separator belt 1 cut, wherein in a step S3 machining operations on the cut edges 3 be performed to reduce micro-short circuits. After in the 2 In the embodiment shown, step S3 is performed after step S2. It is after another in the 2 not shown embodiment but also possible to carry out the steps S2 and S3 simultaneously. After another one in the 2 not shown embodiment, it is also possible to perform the step S3 before step S2. In the 2 It is shown that the step S2 of performing machining operations on the cutting edges 3 a structuring of the cutting edges 3 and / or applying support materials to the cutting edges 3 can have.

LIST OF REFERENCE NUMBERS

1

object to be cut

2

Laser cutter

2a

Laser beam cutting

3

cutting edge

4

Laser scribing device

4a

Laser scribing beam

5

transport device

6

Materialauftragungsvorrichtung

6a

material jet

7

removal device

10

cutting system

S1

Leading the objects to be cut

S2

Cutting the objects

S3

Performing machining operations on the cutting edges

S3a

Structuring the cutting edges

s3b

Applying support materials to the cutting edges

S4

Continue the cut objects

Claims (13)

Method for cutting sheet or plate-shaped objects ( 1 ), in particular of electrodes and / or separators for constructing an electrochemical energy store or of parts of such electrodes or separators, the cutting method comprising the steps: (S1) bringing the objects to be cut ( 1 ) to a laser cutting device ( 2 ), (S2) cutting the objects ( 1 ) with the laser cutting device ( 2 ), and (S3) performing machining operations on the cutting edges (FIG. 3 ) to reduce micro-short circuits. A method according to claim 1, characterized in that the step (S3) of performing machining operations on the cutting edges ( 3 ) for reducing microcircuits: (S3a) structuring the cutting edges ( 3 ). Method according to claim 2, characterized in that the step (S3a) of structuring the cutting edges (S3) 3 ) with a laser structuring device ( 4 ) is carried out. Method according to claim 3, characterized in that the step (S3a) of structuring the cutting edges (S3) 3 ) with the laser structuring device ( 4 ) after the step (S2) of cutting the object ( 1 ) with the laser cutting device ( 2 ) is carried out. Method according to claim 3, characterized in that the step (S3a) of structuring the cutting edges (S3) 3 ) with the laser structuring device ( 4 ) before the step (S2) of cutting the object ( 1 ) with the laser cutting device ( 2 ) is carried out. A method according to claim 4 or 5, characterized in that for the step (S3a) of structuring the cutting edges ( 3 ) as laser structuring device the laser cutting device ( 2 ) of the step (S2) is used. Method according to claim 3, characterized in that the step (S3a) of structuring the cutting edges (S3) 3 ) with the laser structuring device ( 4 ) and the step (S2) of cutting the objects ( 1 ) with a laser cutting device ( 2 ) are carried out substantially simultaneously. Method according to one of claims 1 to 7, characterized in that the step (S3) of performing machining operations on the cutting edges ( 3 ) for reducing microcircuits: (S3b) applying support materials to the cutting edges (S3b) 3 ). Method according to claim 8, characterized in that the step (S3b) of applying supporting materials to the cutting edges (S3) 3 ) and the step (S2) of cutting the objects ( 1 ) with the laser cutting device ( 3 ) are carried out substantially simultaneously. Method according to claim 8 or 9, characterized in that the support materials comprise components with increased absorption coefficients with respect to those of the laser cutting device ( 2 ) have used wavelengths. System ( 10 ) for cutting sheet or plate-shaped objects ( 1 ), in particular for cutting electrodes and / or separators for constructing an electrochemical energy store or parts of such electrodes or separators, wherein the cutting system ( 10 ): - a transport device ( 5 ) used to bring the objects to be cut ( 1 ) to a laser cutting device ( 2 ) is configured - a laser cutting device ( 2 ), which are used to cut objects ( 1 ), and - a processing device ( 4 . 5 ) used to perform machining operations on the cutting edges ( 3 ) is designed to reduce microcircuits. Cutting system ( 10 ) according to claim 11, characterized in that the processing device comprises a laser structuring device ( 4 ), which are used to structure the cutting edges ( 3 ) is configured. Cutting system ( 10 ) according to claim 11 or 12, characterized in that the processing device comprises a material application device ( 6 ) for applying support materials to the cutting edges ( 3 ) is configured.

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