FR3122607A1 - Method of manufacturing a battery cell - Google Patents

Abstract

A method and system (1000) for manufacturing a battery cell, said method comprising the steps of:- providing a release film (103);- forming sets of electrodes such that each set of electrodes (3) comprises a first electrode (1), a second electrode (2) and a portion of the separator film (103), said portion being interposed between said first (1) and second ( 2) electrodes;- forming, in a stacking station (300), a stack of sets of electrodes (3). Figure 1

Description

Method of manufacturing a battery cell

Technical field of the invention

The invention relates to the technical field of manufacturing a battery cell. In particular, the invention relates to a method for manufacturing a battery cell and a system for manufacturing a battery cell.

State of the art

It is known to manufacture a lithium-ion battery with a battery cell comprising a stack, said stack comprising positive electrodes and negative electrodes and in which the electrodes are separated two by two by a separating film interposed between two electrodes. To obtain such a stack, it is known to treat each layer of the stack one by one, said layer being chosen from: a positive electrode, a negative electrode, a separating film; this is not satisfactory because the manufacture of such a stack takes a long time.

To improve the manufacturing speed, it is known to use a separator film which is integrated into the stack by folding said separator film accordion; thus, the same separating film is arranged to separate each pair of adjacent electrodes in the stack. To this end, at each ply of the separator film added to the stack, an electrode chosen from a positive electrode and a negative electrode is added to a portion of the separator film previously added to the stack. However, in some cases, a problem arises: the folding of the separator can generate creases of said separator and cause mechanical damage to the battery cell. In addition, due to the increasing demand for battery cells, another problem to be solved is that of speeding up the manufacturing process of battery cells.

In an attempt to solve the aforementioned problems, patent application US 2015/0263375 A1 describes a device with which, during the production of a stack of electrodes, a separator film is folded alternately on both sides of a stack of electrodes. electrodes. This device uses supports, which are placed as close as possible to the bend to be formed, immobilize the material to be bent for separation over its entire width, and pocket formation occurs thanks to a flow of gas from a module of overpressure over the entire width of the release film, which allows for damage-free and gentle concertina folding.

However, the solution described in document US 2015/0263375 A1 is based on a guide device for concertina folding of the separator film, as well as on at least one gripper for picking up and removing the electrodes and an overpressure module, this which suggests that the process is expensive to implement and that the movement of the various elements used slows down the manufacturing process of the battery cell.

Object of the invention

The object of the present invention is to provide a battery cell manufactured at a rapid rate.

To this end, the present invention relates to a method for manufacturing a battery cell, said method comprising the following steps:
- provide a separator film;
- forming sets of electrodes such that each set of electrodes comprises a first electrode, a second electrode and a portion of the separator film, said portion of the separator film being interposed between said first electrode and said second electrode;
- forming, in a stacking station, a stack of sets of electrodes, the step of forming the stack comprising multiple folding of the separator film;
each set of electrodes being formed before the introduction of said set of electrodes into the stacking station.

In particular, it can be understood that each set of electrodes comprises its own portion of the separator film, said own portion being different from the portion of the separator film included in each of the other sets of electrodes.

Advantageously, the method described allows high speed stacking and less manipulation of the separator film, which results in faster stacking of the electrode assemblies and therefore in an acceleration of the manufacture of the battery cells.

Advantageously, the method described makes it possible to obtain a satisfactory alignment of the electrodes within the set of electrodes because the set of electrodes is formed before introducing the set of electrodes into the stack of sets of electrodes, which improves the overall alignment of the electrodes within the battery cell.

For each set of electrodes, the first electrode and the second electrode can be chosen from a cathode and an anode. Thus, in this case, each set of electrodes comprises an anode and a cathode. By way of example, the first electrode is an anode for a battery cell and the second electrode is a cathode for the battery cell.

The method may further include one or more of the following features.

According to one characteristic, the method is such that the first electrodes of the battery cell to be manufactured are positioned sequentially on the separator film, each first electrode positioned on the separator film being intended to be associated with one of the second electrodes of the cell battery to be manufactured during the step of forming the sets of electrodes, said method comprises, for each pair of consecutive first electrodes positioned on the separator film, a distance verification step in order to determine whether the distance between the two first electrodes consecutive sequences of said couple has or does not have a predefined value.

According to one characteristic, the method may comprise a step consisting in cutting the separator film after the completion of the stacking of sets of electrodes, in order to make it possible to obtain, from the stacking station, the battery cell comprising the stacked electrode assembly.

Advantageously, the cutting of the separator film after the completion of the stacking of electrode assemblies makes it easier to obtain the battery cell from the stacking station.

According to one characteristic, the step of forming the stack may be such that each pair of sets of adjacent electrodes in the stack of sets of electrodes comprises two sets of electrodes respectively called the first set of electrodes and second set of electrodes, the first set of electrodes and the second set of electrodes being stacked with the interposition of a part of a connecting portion, said connecting portion being formed by a corresponding part of the separator film and connecting the release film portion of said first set of electrodes to release film portion of said second set of electrodes.

Advantageously, the interposition of the part of the connecting portion between the first set of electrodes and the second set of electrodes makes it possible to isolate each adjacent set of electrodes in the stack as well as the first and the second electrode from each set of electrodes using the same separator film.

According to one characteristic, for each set of electrodes introduced into the stacking station after a set of electrodes previously introduced into the stacking station, the step of forming the stack of sets of electrodes can comprise a first folding of the separator film in a first folding direction and a second folding of the separator film in a second folding direction to allow the stacking of said set of electrodes introduced with the corresponding set of electrodes previously introduced, the first and the second bending directions being opposite.

Advantageously, the first and the second folding of the separator film in opposite directions makes it possible to isolate sets of electrodes within the stack and to limit the dimension of a corresponding part of the separator film between two sets of stacked electrodes .

According to one characteristic, for each set of electrodes introduced into the stacking station after a set of electrodes previously introduced into the stacking station, the step of forming the stack of sets of electrodes comprises a displacement said previously introduced set of electrodes to allow the stacking of said introduced set of electrodes with said previously introduced set of electrodes.

Advantageously, the movement of said set of electrodes previously introduced makes it possible to avoid creases in the separating film.

According to one feature, the stacking station includes a stacking platform configured to perform linear movement in a direction substantially parallel to a stacking direction of the sets of electrodes in the assembly station and configured to support the assembly of electrodes, and in which each movement is carried out by the linear movement of the stacking platform, the speed of the linear movement of the stacking platform being adapted to the running speed of the separator film.

Advantageously, such a linear movement of the stacking platform makes it possible to impose the displacement of said previous set of electrodes to allow the stacking of the set of electrodes newly introduced into the stacking station.

According to one characteristic, the step of forming the sets of electrodes includes a step of checking the assembly such that, for each set of electrodes, an alignment between the first electrode and the second electrode of said set of electrodes is checked so as to check whether or not one of said first and second electrodes entirely covers the other of said first and second electrodes.

Advantageously, the assembly control step makes it possible to verify the alignment of the electrodes in order to maximize the capacity of the battery cell.

According to one characteristic, the step of forming the stack of sets of electrodes can comprise a step of controlling the stack such that, for each set of electrodes introduced into the stacking station, the alignment between the first electrode and the second electrode is checked so as to check whether or not one of said first and second electrodes fully covers the other of said first and second electrodes after one of said first or second electrodes has been held and transported by an electrode holder device to the stacking station.

Advantageously, the stack control step makes it possible to determine whether or not the second electrode has slipped from its position and has therefore broken the alignment between the first and the second electrode.

According to one characteristic, the step of forming sets of electrodes can comprise, for each set of electrodes to be formed, a step of laminating the first electrode of said set of electrodes onto the separator film, so that said first electrode is secured to the separator film at the end of said lamination step.

Advantageously, the lamination of the first electrode makes it possible to fix the first electrode on the separator film in order to manufacture the set of electrodes.

According to one feature, after the completion of the stacking of sets of electrodes, the separator film is cut to make it possible to obtain, from the stacking station, the battery cell comprising the set of stacked electrodes .

Advantageously, the cutting of the separator film makes it possible to obtain the battery cell.

The invention also relates to a system for manufacturing a battery cell, said system comprising:
- a separator film supply station;
- an electrode assembly station configured to form sets of electrodes such that each set of electrodes comprises a first electrode, a second electrode and a portion of the separator film, said portion of the separator film being interposed between said first electrode and said second electrode; and
- a stacking station in which a stack of sets of electrodes is intended to be formed by multiple folding of the separator film;
said system being configured to allow the release film to pass from the supply station to the stacking station, the electrode assembly station being arranged so that the release film passes between the release film supply station and the stacking station.

Advantageously, the system improves the efficiency of the battery cell manufacturing process.

The system may further include one or more of the following features.

According to one feature, the system includes:
- an assembly viewing device configured to check, for each set of electrodes, an alignment between the first electrode and the second electrode of said set, so as to check whether or not one of said first and second electrodes entirely covers the other of said first and second electrodes.

Advantageously, the assembly viewing device makes it possible to check the alignment of the first and second electrodes in order to maximize the capacity of the battery cell.

According to one characteristic, the assembly viewing device may comprise an X-ray camera.

According to one feature, the stacking station may include a stacking platform configured to perform linear movement in a direction substantially parallel to a direction of stacking of the sets of electrodes in the stacking station and configured to support the stacked sets of electrodes, the linear movement of the stacking platform being controlled so as to depend on the running speed of the separator film.

Advantageously, the linear movement of the stacking platform makes it possible to avoid creases in the separator film.

According to one characteristic, the electrode assembly station is configured to implement lamination such that, for each set of electrodes to be formed, the portion of the separator film of said set of electrodes is laminated with the first electrode of said set of electrodes. Advantageously, the lamination of the first electrode on the separator film makes it possible to fix the first electrode on the separator film in order to generate the set of electrodes.

According to one characteristic, the rolling station could comprise a heated roll laminator comprising heated rolls.

Advantageously, the heated roller laminator makes it possible to fix the first and the second electrode on the separator film in order to form a set of corresponding electrodes.

Other advantages and features will become apparent from the detailed description which follows.

Brief description of the drawings

The invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

The is a schematic representation of a system for manufacturing a battery cell allowing the implementation according to one embodiment of a method for manufacturing a battery cell.

The is a detailed view of the system stacking station shown in .

In these figures, the same reference numerals are used to designate the same elements.

For reasons of clarity, the figures are not necessarily reproduced to scale.

Claims (14)

A method of manufacturing a battery cell, said method comprising the following steps:
- providing a separator film (103);
- forming sets of electrodes such that each set of electrodes (3) comprises a first electrode (1), a second electrode (2) and a portion (104) of the separator film (103), said portion (104 ) of the separator film (103) being interposed between said first electrode (1) and said second electrode (2);
- forming, in a stacking station (300), a stack (305) of sets of electrodes (3), the step of forming the stack comprising multiple folding of the separator film (103);
each set of electrodes (3) being formed before the introduction of said set of electrodes (3) into the stacking station (300). A method according to claim 1, wherein the step of forming the stack is such that each pair of adjacent sets of electrodes (303, 304) within the stack (305) of sets of electrodes comprises two sets of electrodes respectively called first set of electrodes (303) and second set of electrodes (304), the first set of electrodes (303) and the second set of electrodes (304) being stacked with interposition of a part (306) of a connecting portion (302), said connecting portion (302) being formed by a corresponding part of the release film (103) and connecting the portion (104) of the release film (103) of said first set of electrodes (303) to the portion (104) of the separator film (103) of said second set of electrodes (304). Method according to any one of claims 1 to 2, in which, for each set of electrodes (3) introduced into the stacking station (300) after a set of electrodes previously introduced into the stacking station (300 ), the step of forming the stack of electrode assemblies includes first folding the release film (103) in a first folding direction and second folding the release film (103) in a second folding direction to allowing the said set of electrodes (3) introduced to be stacked with the corresponding set of electrodes previously introduced, the first and the second folding directions being opposite. Method according to any one of claims 1 to 3, in which, for each set of electrodes (3) introduced into the stacking station (300) after a set of electrodes previously introduced into the stacking station (300 ), the step of forming the stack (305) of sets of electrodes comprises moving said set of electrodes previously introduced to allow stacking of said set of electrodes introduced with said set of electrodes previously introduced. A method according to claim 4, wherein the stacking station (300) comprises a stacking platform (301) configured to perform linear movement (F1) in a direction substantially parallel to a stacking direction of the sets of electrodes in the assembly station (300) and configured to support the electrode assembly (3), and in which each movement is effected by the linear movement (F1) of the stacking platform (301) , the speed of the linear movement (F1) of the stacking platform (301) being adapted to the running speed of the separator film (103). A method according to any one of claims 1 to 5, wherein the first electrodes (1) of the battery cell to be manufactured are sequentially positioned on the separator film (103), each first electrode (1) positioned on the separator film ( 103) being intended to be associated with one of the second electrodes (2) of the battery cell to be manufactured during the step of forming the sets of electrodes (3), said method comprises, for each pair of first electrodes ( 1) consecutive positioned on the separator film (103), a distance verification step to determine whether or not the distance between the first two consecutive electrodes of said pair has a predefined value. Method according to any one of Claims 1 to 6, in which the step of forming the sets of electrodes comprises a step of controlling the assembly such that, for each set of electrodes, an alignment between the first electrode ( 1) and the second electrode (2) of said set of electrodes (3) is checked so as to verify whether or not one of said first electrode (1) and second electrode (2) entirely covers the other of said first electrode ( 1) and second electrode (2). Method according to any one of Claims 1 to 7, in which the step of forming the stack of sets of electrodes comprises a step of controlling the stack such that, for each set of electrodes (3) introduced into the stacking station (300), the alignment between the first electrode (1) and the second electrode (2) is checked so as to verify whether one of said first electrode (1) and second electrode (2) whether or not entirely covers the other of said first electrode (1) and second electrode (2) after one of said first or second electrodes (1, 2) has been held and transported by an electrode holder device (602) to the stacking station (300). Method according to any one of claims 1 to 8, in which the step of forming sets of electrodes comprises, for each set of electrodes (3) to be formed, a step of rolling the first electrode (1) said set of electrodes (3) on the separator film (103), so that said first electrode (1) is integral with the separator film (103) at the end of said lamination step. A method according to any one of claims 1 to 9, wherein after completion of the stacking of sets of electrodes, the release film (103) is cut to provide, from the stacking station ( 300), the battery cell comprising the stack (305) of electrode assemblies. A system (1000) for manufacturing a battery cell, said system (1000) comprising:
- a separator film supply station (100);
- an electrode assembly station (200) configured to form sets of electrodes such that each set of electrodes (3) comprises a first electrode (1), a second electrode (2) and a portion of the separator film (103), said portion (104) of the separator film (103) being interposed between said first electrode (1) and said second electrode (2); and
- a stacking station (300) in which a stack of sets of electrodes is intended to be formed by multiple folding of the separator film (103);
said system (1000) being configured to allow the separator film (103) to pass from the supply station (100) to the stacking station (300), the electrode assembly station (200) being arranged so as to be through which the separator film (103) passes between the supply station (100) of the separator film (103) and the stacking station (300). System (1000) according to claim 11, in which it comprises an assembly viewing device (502) configured to check, for each set of electrodes (3), an alignment between the first electrode (1) and the second electrode (2) of said assembly (3), so as to check whether or not one of said first electrode (1) and second electrode (2) completely covers the other of said first electrode (1) and second electrode (2). A system (1000) according to any of claims 11 to 12, wherein the stacking station (300) comprises a stacking platform (301) configured to perform linear motion (F1) in a substantially parallel direction to a direction of stacking the sets of electrodes in the stacking station (300) and configured to support the stacked sets of electrodes, the linear movement (F1) of the stacking platform (301) being controlled so as to depend on the running speed of the separating film (103). A system (1000) according to any one of claims 11 to 13, wherein the electrode assembly station (200) is configured to implement rolling such that, for each set of electrodes (3) to be formed , the separator film portion (103) of said electrode assembly (3) is laminated with the first electrode (1) of said electrode assembly (3).