DE102013203810A1 - Method and apparatus for cutting an electrode tape - Google Patents

Abstract

A method for cutting an electrode strip for an energy storage cell is proposed, wherein in a first method step the electrode strip is transported through a laser cutting device and wherein during the first method step within the laser cutting device a plurality of conductor lugs are cut into the electrode strip by means of a laser beam and furthermore the laser beam is guided exclusively within the electrode band in the first process step.

Description

State of the art

The present invention is based on a method for cutting an electrode band for an energy storage cell.

It is known from the prior art to produce energy storage cells by winding two electrode strips, wherein between the two electrode strips in each case a Separatorband is arranged. The two electrode bands then act as the anode and cathode of the corresponding energy storage cell. To contact the energy storage cell electrically from the outside, the energy storage cell is provided with two Ableiterpolen, wherein one of the Ableiterpole is electrically conductively connected to the anode and the other of the Ableiterpole is electrically conductively connected to the cathode.

In order to form the Ableiterpole it is also known to wrap the electrode bands in such a way that one of the two electrode bands on one end face of the generated electrode coil over the other electrode tape, and then cut into this protruding electrode tape Ableiterfahnen, which are then combined to form a Ableiterpol ,

Disclosure of the invention

It is an object of the present invention to provide a method and an apparatus for cutting an electrode band for an energy storage cell, which allows a faster, cheaper and simpler production of energy storage cells compared to the prior art. In particular, it should also be prevented that a comparatively complicated subsequent processing of completely wound electrode windings or completely stacked electrode stacks is necessary.

This object is achieved with a method for cutting an electrode tape for an energy storage cell, wherein in a first process step, the electrode tape is transported through a laser cutting device, wherein during the first process step within the laser cutting device by means of a laser beam, a plurality of Ableiterfahnen is cut into the electrode tape and wherein the laser beam is guided in the first process step exclusively within the electrode belt.

The method according to the invention has the advantage over the prior art that the conductor tabs are cut into the electrode band before the generation of an electrode coil or an electrode stack. Subsequent processing of the electrode strips after the winding or stacking process is therefore no longer necessary. In this way it is further prevented that the electrode winding or stack is contaminated by chips and waste particles, which are generated in the subsequent processing and can lead to dangerous short circuits between the electrode bands. The cutting of the collector tabs before the further processing of the electrode tape is made possible by the fact that a laser beam cutting device is used in the process of the invention, the laser beam is not led out during the transport of the electrode belt by the laser beam cutting device from the material of the electrode belt, but instead guided exclusively within the electrode belt becomes. As a result, the advantage is achieved that in the edge region of the electrode web, which is provided with the Ableiterfahnen, no generated by constantly repeating renewed application of the laser beam piercing edges. The method according to the invention thus makes it possible, prior to the further processing of the electrode strip, to cut conductor tabs into the electrode strip and at the same time achieve such a good cut edge quality, so that subsequent treatment of the already processed electrode strip, for example the wound or folded electrode strip, can be saved. The saving of the aftertreatment process then ensures a fast and cost-effective production of the energy storage cell. The electrode band preferably comprises a band-like sheet which is made of an electrically conductive material or of a band material coated with electrically conductive material, for example an electrode foil.

Advantageous embodiments and modifications of the invention are the dependent claims, as well as the description with reference to the drawings.

According to a preferred embodiment of the present invention, it is provided that the laser beam is guided in the second method step such that the lengths of the discharge lugs vary and, in particular, increase steadily. If the electrode tape is wound in an eventual later second method step to an electrode winding such that the Ableitfahnen protrude on an end face of the electrode coil from the electrode coil along an axial direction of the electrode coil, take the parallel to the axial direction measured lengths of the Ableitfahnen advantageously in the radial direction from the outside inside, ie in the direction of the central axis of the Electrode winding, from. This has the advantage that all the collector lugs terminate substantially at the same height with respect to the axial direction when the collector lugs are compressed in the radial direction and in the direction of the central axis in any later third method step. The larger lengths of the outer arrester lugs then compensates for the outer conductor lugs to be tilted more strongly than the inner collector lugs.

According to a preferred embodiment of the present invention it is provided that the laser beam is guided in the second method step such that the distances between adjacent Ableiterfahnen vary and in particular steadily increase. Advantageously, it can be achieved by an increasing distance between adjacent arrester tabs that the electrode tape is wound in an eventual later second method step to an electrode winding such that the arrester tabs protrude from an end face of the electrode winding from the electrode winding along an axial direction of the electrode winding projecting Ableitfahnen at least partially overlap along a direction perpendicular to the axial direction transverse direction. Additionally or alternatively, it would also be conceivable that the laser beam is guided in the second method step such that the widths of the discharge lugs vary.

According to a preferred embodiment of the present invention, it is provided that the electrode strip is transported continuously through the laser cutting device in the first method step. Advantageously, the fastest possible and therefore cost-effective production of energy storage cells is thus achieved. In addition, a control of the laser beam as a function of a constant transport speed of the electrode belt by the laser cutting device is comparatively easy to implement, since in particular the laser beam in this case only has to leave a self-contained trajectory with a corresponding speed. Alternatively, of course, it would also be conceivable that the electrode belt is transported stepwise through the laser cutting device.

According to a preferred embodiment of the present invention, it is provided that in a zeroth process step, the electrode belt transported in the first method step by the laser cutting device is unwound from an output roller.

The electrode belt thus preferably comprises a so-called endless belt, which is provided by the starting roller.

According to a preferred embodiment of the present invention, it is provided that in the first method step, the laser beam is guided in such a way that the discharge lugs are provided with rounded edges and / or corners. Advantageously, the mechanical stability of the collector tabs is thus significantly increased. In particular, tearing of the electrode tape material and tearing off of the collector tabs by cracking in the corners are avoided.

According to a preferred embodiment of the present invention, it is provided that in the first method step, the laser beam is moved in the stationary frame of reference of the laser cutting device along a loop-shaped and closed trajectory. The trajectory is selected such that the laser beam is not led out of the electrode belt at any time, while in the first method step the electrode belt is transported through the laser cutting device. The trajectory is thus along a direction perpendicular to the main plane of extension within the electrode band. The cutting process is thus interrupted at any time, whereby a high cut edge quality is achieved. The speed with which the laser beam repeatedly travels the predetermined trajectory is regulated in particular as a function of the transport speed of the electrode belt by the laser cutting device. Advantageously, it is further cut with a constant cutting energy, so that a comparatively clean cut is produced.

According to a preferred embodiment of the present invention, it is provided that the electrode strip cut in the first method step is wound into an electrode winding in a second method step, the electrode strip preferably being wound in such a way that the plurality of collector tabs extend at least along a transverse direction perpendicular to the axial direction of the electrode coil partially cover. Advantageously, the arrester lugs can thus be combined to form a common Ableiterpol, whereby a low-resistance electrical connection between the individual fins of the electrode strip and a current source or current sink is realized.

According to a preferred embodiment of the present invention, it is provided that in the second method step the electrode band is wound together with at least one separator band and preferably a further electrode band. Advantageously, by the winding process thus automatically an electrical insulation and a mechanical spacing between the fins of the electrode belt and Slats of the other electrode band achieved so that one of the two electrode bands can later act as the cathode and the other of the two electrode bands later as the anode. Preferably, in a third method step, the collector lugs aligned with one another are compressed along the transverse direction and preferably in the direction of the axial direction. In this way, the arrester lugs are brought into an electrically conductive contact with each other. It is conceivable that the arrester lugs are pressed together, glued or welded. It is also conceivable that a pole piece is slipped over the compressed Ableiterfahnen, which clamps the Ableiterfahnen in this position.

According to a preferred embodiment of the present invention, it is provided that in the second method step, an electrode winding is produced with a round or rectangular cross-section. The shape of the energy storage cell can thus be flexibly adapted to the corresponding space conditions.

According to a preferred embodiment of the present invention, it is provided that the electrode strip cut in the first method step is folded into an electrode stack in a second method step, wherein the electrode strip is folded in such a way that the collector tabs are at least partially brought into coincidence. It is conceivable for the electrode band to undergo a Z-folding, wherein an electrode sheet arranged between two separator sheets, which was preferably cut out of a further electrode band, is inserted into the individual folds of the Z-folded electrode band. The arrester lugs of the electrode tape protrude from a head side of the electrode stack and overlap with each other. Preferably, in a third process step, the mutually coincident Ableiterfahnen be compressed, in turn, to form the Ableiterpol.

Another object of the present invention is an apparatus for cutting an electrode tape by means of a method according to any one of the preceding claims, wherein the apparatus comprises a laser cutting device and wherein the device comprises transport means for transporting an electrode tape by the laser cutting device, characterized in that the laser cutting device is a laser source for emitting a laser beam intersecting the electrode band, which is configured by means of a control unit such that the laser beam is guided exclusively within the electrode band. The device allows a much simpler, cheaper and faster production of energy storage cells compared to the prior art.

A further subject of the present invention is an energy storage cell having at least one wound or folded electrode strip, the electrode strip having discharge lugs, the discharge lugs being cut into the electrode strip by means of the method according to the invention. Advantageously, the energy storage cell is comparatively inexpensive, quick and easy to manufacture, at the same time the risk of short circuits due to impurities caused by reworking of the energy storage cell is reduced.

The indicated method or apparatus for cutting an electrode tape could also be referred to as a method or apparatus for producing an electrode winding, an electrode stack or an energy storage cell.

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 do not limit the essential inventive idea.

Brief description of the drawings

1 shows a schematic view of an apparatus and a method according to an exemplary first embodiment of the present invention.

2 shows a schematic view of an electrode tape cut by means of the apparatus and the method according to the exemplary first embodiment of the present invention.

3 FIG. 12 is a schematic view of an electrode coil whose electrode tape has been cut by means of the apparatus and method according to the exemplary first embodiment of the present invention. FIG.

4 shows a schematic representation of the trajectory, which is traversed by the laser beam in carrying out the method according to the exemplary first embodiment of the present invention.

5 FIG. 3 shows the shape of drain tabs of an electrode tape which is formed by a method according to an exemplary second embodiment Embodiment of the present invention was cut.

6a to 6c 11 show schematic views of drain tabs of an electrode tape for an electrode winding cut by a method according to an exemplary third embodiment of the present invention.

Embodiments of the invention

In the various figures, the same parts are always provided with the same reference numerals and are therefore usually named or mentioned only once in each case.

In 1 is a schematic view of a device 10 and a method according to an exemplary first embodiment of the present invention. The device 10 and the method serve an electrode band 1 to cut and the electrode tape for producing an energy storage cell 2 to wrap. The electrode band preferably comprises an electrode foil, which comprises a foil made of plastic, which is provided in regions with metal layers. The metal layers later act as electrodes, wherein a part of the electrodes are connected together as an anode and the other part of the electrodes are connected together as a cathode.

The electrode band 1 becomes an endless belt from a starting roll 3 provided by a laser cutter 5 transported and behind the laser cutting device 5 on a take-up roll 6 wound, which is driven by a non-illustrated motor to a rotation and thus acts as a means of transport. In front of and behind the laser cutter 5 are pulleys 7 arranged, which the electrode band 1 align so that the electrode band 1 within the laser cutter 5 by means of a laser beam 8th can be cut. The device 1 also has a donor role 4 on which the transport speed of the electrode band 1 measures and as a parameter to a control unit (not shown) for controlling the laser beam 8th passes. The encoder could, for example, as an incremental encoder on the shaft of the donor role 4 be realized. The rotational speed of the output roller 3 is preferably adjustable. The web tension of the electrode band 1 is preferably realized by the fact that the moment at the take-up roll 6 is electronically controlled by the control unit, wherein the transport speed of the electrode belt 1 as the second controlled variable by the encoder role 4 recorded and a passage to the adjustable rotational speed of the output roller 3 he follows. The rotational speed of the output roller 3 thus becomes dependent on the torque of the take-up roll 6 and the transport speed regulated such that the electrode belt 1 within the laser cutter 5 is curious. Alternatively, of course, would also be conceivable to use spring-biased dancer rollers to the electrode belt 1 to keep tension. Optionally, the device has 1 Furthermore, pressure rollers and / or a web edge correction device for correcting the position of the band edge. The electrode band 1 is preferably at a constant transport speed through the laser cutting device 5 transported.

The laser cutting device 5 has a laser source, which is a laser beam 8th for cutting the electrode band 1 emitted. The electrode band 1 is in a first step by the laser cutting device 5 transported and meanwhile be using the laser beam 8th output lugs 9 into the electrode band 1 cut. The laser beam 8th is repeated along a self-contained and therefore loop-shaped trajectory 16 moved (see, for example 4 ), which along a to the main extension plane of the electrode band 1 vertical direction completely with the electrode band 1 overlaps or within the electrode band 1 lies. This causes the laser beam 8th always within the electrode band 1 is guided and at no time during the first process step from the electrode band 1 is led out. In this way it is prevented that after the lead out of the laser beam 8th from the material of the electrode band 1 again and again a renewed application of the laser beam 8th to the material of the electrode tape 1 would be required, which Einkoppelkanten would arise and thus an undefined cut quality would be brought about.

The laser cutting device 5 includes a window 12 through which the laser beam 8th on the electrode band 1 is directed. The laser beam 8th in particular of the control unit as a function of the transport speed of the electrode belt 1 through the laser cutting device 5 controlled. This is the trajectory 16 preferably traveled at a constant speed. Optionally, the laser cutting device 5 a scanning optics, which show the position of the laser beam 8th on the electrode band 1 monitored in real time. The waste material falls down during the cutting process due to gravity and thus out of the plane of the electrode strip 1 out. Optionally, the laser cutting device 5 In addition, a suction device for sucking off waste material and / or a blower for blowing off waste material, to contamination of the electrode strip 1 to prevent. The window 12 also ensures that no impurities, such as For example, aerosols can get from the laser source into the cutting area.

That by the laser beam 8th caused sectional image in the electrode band 1 is schematic in 2 illustrating which is a plan view along the in 1 shown arrow 11 on the electrode band 1 inside the laser cutting device 5 shows. It can be seen that the cut 13 through the electrode band 1 leads, without the electrode band 1 when cutting out the arrester lugs 9 to leave. The arrester flags 9 have in the present example a rectangular shape with constant lengths 13 perpendicular to the transport direction of the electrode strip 1 but with varying distances 14 among themselves. The distances 14 increase steadily in the example in question. The lower side of the electrode band 1 represents the blend 1' while the upper side of the electrode band 1 to the in 3 wound electrode winding is wound.

In 3 is a schematic view of an energy storage cell designed as an electrode winding 2 shown, which consists of a wound electrode band 1 which is done by means of the device 1 and the method according to the exemplary first embodiment of the present invention. The electrode band 2 became an axis perpendicular to the direction of transport to an electrode winding 2 with a central axis 15 wound. From the front side of the electrode winding 2 stand by the laser cutting device 5 cut out discharge lugs 9 parallel to the central axis 15 out. The arrester flags 9 are each in one piece and electrically conductive with the metal coatings acting as electrodes on the electrode tape 2 connected. The arrester flags 9 An electrode, the later cathode or anode, can thus be combined into a Ableiterpol to allow a low-resistance contact of this electrode.

The 4 shows a schematic representation of the trajectory 16 which is traversed by the laser beam when carrying out the method according to the exemplary first embodiment of the present invention. In the 4 is a top view (corresponds to the view along the arrow 11 in 1 ) of the trajectory 16 displayed. It can be seen that the trajectory 16 is a self-contained loop, which is repeated from the laser beam 8th is traversed while the electrode band 1 along the X direction through the laser cutter 5 emotional. The trajectory 16 has a substantially triangular shape, wherein on the base side 17 the triangle opposite corner a trapezoid 22 is going through. The geometry of the trajectory 16 and the transport speed of the electrode belt 1 are so coordinated that the trajectory 16 at a constant speed from the laser beam 8th is driven to the in 2 shown pattern of arrester flags 9 into the electrode band 1 to cut. It is conceivable that the transport speed increases steadily or gradually to the increasing distances 14 between adjacent arrester vanes 9 to realize.

In 5 is the form of arrester lugs 9 an electrode band 1 which was cut by a method according to an exemplary second embodiment of the present invention. The second embodiment is substantially the same as in FIG 2 and 3 illustrated first embodiment, wherein the cutting operation is performed such that the corners 15 between the arrester lugs 9 and the rest of the electrode band 1 , as well as the outer edges 16 the arrester flags 9 are each rounded off (see left figure). This has the advantage that the from the front side of the electrode coil 2 projecting arrester lugs 9 (see right figure) opposite to the axial direction of the electrode coil 2 vertically acting forces 17 are mechanically stronger. Overall, the service life of the energy storage cell to be produced is thus considerably increased.

In 6a . 6b and 6c are also schematic views of Ableiterfahnen 9 an electrode band 1 for an electrode winding 2 which was cut by a method according to an exemplary third embodiment of the present invention. The third embodiment is substantially the same as in FIG 1 . 2 and 3 illustrated in the first embodiment, wherein in the laser cutting in the first process step, the Ableitfahnen 9 not only with increasing distances between the arrester lugs 9 but also with increasing lengths 13 the arrester flags 9 be cut out (see 6a ). When the electrode track 1 then wrapped in a subsequent second process step, take the lengths 13 the arrester flags 9 in the radial direction outwards (see 6b ). In one to the axial direction 15 vertical transverse direction, the arrester lugs overlap 9 , In a third process step, the arrester vanes which are brought into coincidence with one another become 9 along the transverse direction and in the direction of the axial direction now compressed to a Ableiterpol 18 to create. In the process, the outer conductor lugs become 9 bent inwards. The farther out the arrester lugs 9 are arranged, the stronger they are bent inward. The different angles of inclination of the different arrester lugs 9 are due to the different lengths of the arrester lugs 9 just compensated so that a Ableiterpol 18 with a flat surface perpendicular to the axial direction 15 arises. The arrester flags 9 are in particular glued together, welded, pressed or the like.

LIST OF REFERENCE NUMBERS

1

 electrode strip

2

 Energy storage cell

3

 starting role

4

 feed roller

5

 Laser cutting device

6

 up roll

7

 idler pulley

8th

 laser beam

9

 conductor lug

10

 contraption

11

 arrow

12

 window

13

 length

14

 distance

15

Central axis

16

 trajectory

17

 base side

18

 corners

19

 edge

20

 force

21

Ableiterpol

22

trapeze

Claims (15)

Method for cutting an electrode strip ( 1 ) for an energy storage cell ( 2 ), wherein in a first method step, the electrode band ( 1 ) by a laser cutting device ( 5 ) and during the first method step within the laser cutting device (FIG. 5 ) by means of a laser beam a plurality of Ableiterfahnen ( 9 ) into the electrode band ( 1 ), characterized in that the laser beam ( 8th ) in the first method step exclusively within the electrode band ( 1 ) to be led. Method according to claim 1, wherein the laser beam ( 8th ) is guided in the second method step such that the lengths ( 13 ) of the arrester lugs ( 9 ) and especially steadily increase. Method according to one of the preceding claims, wherein the laser beam ( 8th ) is guided in the second method step such that the distances ( 14 ) between adjacent arrester lugs ( 9 ) and especially steadily increase. Method according to one of the preceding claims, wherein the laser beam ( 8th ) is guided in the second method step such that the widths of the discharge lugs ( 9 ) vary. Method according to one of the preceding claims, wherein the electrode tape ( 1 ) in the first method step continuously by the laser cutting device ( 5 ) is transported. Method according to one of the preceding claims, wherein in a zeroth process step that in the first step by the laser cutting device ( 5 ) transported electrode band ( 1 ) from a starting role ( 3 ). Method according to one of the preceding claims, wherein in the first method step the laser beam ( 8th ) is guided in such a way that the arrester lugs ( 9 ) with rounded edges ( 19 ) and / or corners ( 18 ). Method according to one of the preceding claims, wherein in the first method step the laser beam ( 8th ) in the stationary reference frame of the laser cutting device ( 5 ) along a loop-shaped and self-contained trajectory ( 16 ) is moved. Method according to one of the preceding claims, wherein the electrode strip cut in the first method step ( 1 ) is wound into an electrode winding in a second method step, wherein the electrode strip ( 1 ) is preferably wound in such a way that the plurality of discharge lugs ( 9 ) along one to the axial direction ( 15 ) of the electrode winding perpendicular transverse direction at least partially overlap. Method according to claim 9, wherein in the second method step the electrode band ( 1 ) together with at least one separator belt and preferably a further electrode belt ( 1 ) and / or wherein in the second method step, an electrode winding is produced with a round or rectangular cross-section. Method according to one of claims 9 or 10, wherein in a third method step, the mutually coincident Ableiterfahnen ( 9 ) along the transverse direction and preferably in the direction of the axial direction ( 15 ) are compressed. Method according to one of claims 1 to 8, wherein the electrode strip cut in the first method step ( 1 ) is folded into an electrode stack in a second method step, wherein the electrode strip ( 1 ) is folded such that the arrester lugs ( 9 ) at least partially coincide with each other. The method of claim 12, wherein in a third process step, the mutually in Covered arrester flags ( 9 ) are compressed. Contraption ( 10 ) for cutting an electrode band ( 1 ) by a method according to one of the preceding claims, wherein the device ( 10 ) a laser cutting device ( 5 ) and wherein the device ( 10 ) Transport means for transporting an electrode band ( 1 ) by the laser cutting device ( 5 ), characterized in that the laser cutting device ( 5 ) a laser source for emitting a the electrode tape ( 1 ) cutting laser beam ( 8th ) which is configured such that the laser beam ( 8th ) exclusively within the electrode band ( 1 ) to be led. Energy storage cell ( 2 ) comprising at least one wound or folded electrode strip ( 1 ), wherein the electrode band ( 1 ) a plurality of arrester vanes ( 9 ), wherein the arrester vanes ( 9 ) by means of a method according to one of claims 1 to 11 in the electrode band ( 1 ) are cut.

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