DE102021127860A1 - Method for manufacturing a battery cell and battery cell - Google Patents

Abstract

The present invention relates to a method for producing a battery cell (1) for a battery, in particular for a traction battery in a motor vehicle. The present invention also relates to a battery cell, in particular a prismatic battery cell (1). The battery cell (1) has a cell housing (10), an electrode coil (2) or electrode stack being arranged in the cell housing (10), with interconnected anode conductors of the electrode coil (2) or electrode stack being connected to a first current conductor (7). and interconnected cathode collectors (4) of the electrode coil (2) or electrode stack are connected to a second current collector (8), the cell housing (10) having openings (14) on the front, the respective current collector (7, 8) having one of the openings on the front (14) closes.

Description

The present invention relates to a method for producing a battery cell for a battery, in particular for a traction battery of a motor vehicle. Furthermore, the present invention relates to a battery cell, in particular a prismatic battery cell. The battery cell according to the invention is preferably produced using the method according to the invention.

Motor vehicle batteries, which are used as traction batteries in electrically or partially electrically driven vehicles, usually have several battery cells. Each battery cell may include one or more anodes, one or more cathodes, and separators that form a cell stack or cell coil. One type of such battery cells is, for example, the so-called pouch cell, in which the cell stacks are arranged in flexible packaging, also referred to as softback. An advantage of such pouch cells is their simple structure, the good interconnection through external tabs and the high energy density. Disadvantages are the relatively high internal resistance and the not particularly good fast charging capability due to the length of the pouch cells. Another disadvantage of pouch cells is that they do not have particularly high mechanical stability.

From the DE 10 2019 211 253 A1 a battery cell is known which comprises one or more cell coils, the battery cell also comprising a cell housing which serves as a receiving space for accommodating the one or more cell coils. The one or more cell coils are accommodated in the accommodation space of the cell housing, with the cell housing comprising or forming one or more spacer elements.

There is a need to simplify the production of a battery cell and, in particular, to improve it with regard to mechanical stability while using as little material as possible.

These objects are achieved by a method having the features of patent claim 1 and by a battery cell having the features of patent claim 11 .

1. a) Herstellen eines Elektrodenwickels oder Elektrodenstapels mit endseitig freiliegenden Anodenableitern und Kathodenableitern,
2. b) Elektrisches Verbinden der Anodenableiter miteinander,
3. c) Elektrisches Verbinden der Kathodenableiter miteinander,
4. d) Anbringen eines ersten Stromableiters an die miteinander verbundenen Anodenableiter,
5. e) Anbringen eines zweiten Stromableiters an die miteinander verbundenen Kathodenableitern,
6. f) Einbringen des Elektrodenwickels oder Elektrodenstapels mit daran befestigten Stromableitern in ein Zellgehäuse mit stirnseitigen Öffnungen, derart, dass der jeweilige Stromableiter eine der stirnseitigen Öffnungen verschließt.

The method according to the invention is used to produce a battery cell for a battery, in particular for a traction battery of a motor vehicle. The battery cell produced by the method is in particular a prismatic battery cell. The method has at least the following method steps:

1. a) Production of an electrode coil or electrode stack with anode collectors and cathode collectors exposed at the ends,
2. b) Electrically connecting the anode conductors to each other,
3. c) Electrically connecting the cathode conductors to one another,
4. d) attaching a first current collector to the interconnected anode collectors,
5. e) attaching a second current conductor to the interconnected cathode conductors,
6. f) Introduction of the electrode coil or electrode stack with current collectors attached thereto in a cell housing with end openings such that the respective current collector closes one of the end openings.

In the method according to the invention for manufacturing a battery cell, it is provided that the current collector assumes a dual function, namely enabling contacting of the anode(s) or cathode(s) on the one hand and forming a component of the cell housing on the other. As a result, material can be saved and the production of the battery cell is simplified. In this respect, the current conductor also assumes the function of a structural component for stabilizing the cell housing, so that further structural components for the purpose of stiffening the cell housing can be dispensed with, since the current conductor assumes this function. In addition, it is not necessary to provide additional sealing plates or covers, since the current arrester is used to close the front openings and is therefore itself a component of a sealing system. This simplifies the production of the battery cell, reduces the material requirement and yet ensures high stability and good electrical contact with low energy losses. In addition, the respective current arrester can have additional connection structures that enable direct contacting of several cells designed in this way with one another without additional connection elements such as busbars.

The anode conductors or cathode conductors that are exposed at the end are often also referred to as electrode lugs.

It is considered to be particularly advantageous if the exposed anode conductors and the exposed cathode conductors are designed to protrude at opposite ends of the electrode coil or electrode stack.

The exposed anode conductors and cathode conductors are preferably overlapping arranged and connected to each other over a large area in the overlapping area.

Preferably, the exposed portions of the anode conductors and cathode conductors respectively have a length, a width and a thickness, the thickness being less than the width and the thickness being less than the length, with the anode conductors and the cathode conductors respectively covering the entire width electrically connected to one another, in particular welded.

Furthermore, it is considered particularly advantageous if the openings in the cell housing are formed on opposite end faces of the cell housing.

In the aforementioned configurations, the anode collectors or cathode collectors can have a particularly large extent, since they protrude on different sides in relation to the cell coil or cell stack. In particular in this context, it is considered to be particularly advantageous if the width of the anode conductor is identical to the width of a non-exposed area of the respective anode and/or the width of the cathode conductor is identical to the width of a non-exposed area of the respective cathode. As a result, ohmic losses can be reduced or kept particularly low.

It is considered particularly advantageous if the current conductors are fixed mechanically in the cell housing, for example by means of crimping or welding. Furthermore, it is considered particularly advantageous if the current collectors are connected to the cell housing in such a way that the current collectors seal the openings of the cell housing. This can be done, for example, by sealing welding.

It is considered particularly advantageous if the current conductors are permanently connected to the cell housing.

It is quite conceivable that the current collectors, preferably on their side facing away from the electrode coil or electrode stack, have a connection structure that makes it possible to connect the respective current collector directly to a current collector of another battery cell. In this context, directly is understood to mean that no further components, such as busbars, are required to establish the electrical connection.

It is entirely conceivable that the current conductor and/or the cell housing has venting openings and/or openings for electrolyte filling.

It is considered to be particularly advantageous if the current conductors are connected to the cell housing in a materially bonded manner, for example by being welded and/or glued to it.

The current collectors are preferably connected to the cell housing in a materially bonded manner. The materially bonded connection can be a circumferential weld seam, for example.

The anode conductors and/or the cathode conductors are preferably connected to one another by means of welding, in particular by means of ultrasonic welding.

The anode conductor and/or cathode conductor can be connected to the respective current conductor, for example, by means of a cohesive pressing or melting process, such as resistance spot welding, vibration or ultrasonic welding or laser welding.

In a preferred embodiment, it is provided that the electrode coil or the electrode stack with the current conductors attached to it is pushed into the cell housing at the front.

The cell housing preferably encloses the electrode coil or the electrode stack.

The cell housing is preferably dimensionally stable.

The cell housing is preferably a cuboid or prism-shaped cell housing.

The cell housing is designed in particular as a monoframe.

The cell housing is preferably an extruded or extruded profile.

The material thickness of the cell housing is preferably 100 μm to 3 mm.

The cell housing is preferably made of a metal or a metal alloy. The cell housing preferably has aluminum and/or magnesium.

It is considered particularly advantageous if the cell housing is designed in one piece.

The anode conductors and/or cathode conductors preferably have a thickness of 1 μm to 40 μm. The length of the exposed sections of the anode conductors and/or cathode conductors is preferably several millimeters. The width of the exposed sections of the anode conductors and/or cathode conductors is preferably several millimeters.

It is considered to be particularly advantageous if the current collector is designed in one piece. The current collector on the anode side preferably has copper. The current collector on the cathode side preferably has aluminum. Other materials or material combinations are conceivable.

The anode and the cathode are, in particular, an anode foil and a cathode foil, respectively. The cathode or cathodes are preferably coated aluminum carrier foils and the anodes are coated copper carrier foils.

Preferably, the cathodes and the anodes are separated by a separator.

It is considered to be particularly advantageous if the anodes and cathodes are uncoated in the edge region and protrude at the ends, as a result of which the anode conductors and cathode conductors are formed.

It is considered particularly advantageous if the first and/or the second current conductor has a cover section for closing the front opening and a connection section that protrudes inwards relative to the cover section, with the anode conductors or the cathode conductors being connected to the current conductor in the region of the connection section . The cover section and/or the connection section is preferably designed in the form of a plate. The sections are preferably at an angle of 90° to one another.

In connection with an embodiment with a cover section, it is considered particularly advantageous if the first and/or the second current collector is connected to the cell housing in the area of the cover section.

It is considered particularly advantageous if the first and/or the second current conductor has a T-shaped cross section. As a result, the opening can be closed particularly effectively and the anode collectors or cathode collectors can be connected to the respective current collector in a particularly simple manner. Any other shape of a cross section, which deviates from a T-shape and which allows an electrode foil to be attached, is conceivable.

The current arrester preferably has a metal or a metal alloy as the conductive material.

The first and/or the second current collector preferably has a cross section that is smaller than a cross section of the opening. This makes it easier to insert and connect the current conductors into or with the cell housing.

The thickness of the current conductor is preferably in the range of the thickness of the cell housing, preferably in the range from 100 μm to 5 mm.

It is also considered to be particularly advantageous if the first and/or the second current arrester is/are connected to a terminal or has a terminal for establishing an electrical connection to a further battery cell. The first current arrester preferably has a terminal and the second current arrester has a terminal that corresponds to the first terminal. In particular, it is provided that the terminal of the first current arrester can be mechanically and electrically directly connected to a terminal of a second current arrester of a further battery cell.

The battery cell according to the invention is a battery cell for a traction battery of a motor vehicle. The battery cell according to the invention is designed in particular as a prismatic battery cell. The battery cell has a cell housing, an electrode coil or electrode stack being arranged in the cell housing, with interconnected anode conductors of the electrode coil or electrode stack being connected to a first current conductor and interconnected cathode conductors of the electrode coil or electrode stack being connected to a second current conductor. The cell housing has openings on the face side, preferably opposite openings, with the respective current collector closing one of the openings on the face side.

The battery cell according to the invention is preferably produced using the method according to the invention or one of its advantageous embodiments.

The statements regarding the method according to the invention apply correspondingly to the battery cell according to the invention and vice versa.

• 1 ein Elektrodenwickel in einer schematischen Darstellung in einer perspektivischen Ansicht,
• 2 das Elektrodenwickel gemäß 1 beim Vorgang eines Verbindens von endseitig freiliegenden Anodenableitern,
• 3 das Elektrodenwickel gemäß 2 nach dem Verbinden der endseitig freiliegenden Anodenableiter und Kathodenableiter,
• 4 das Elektrodenwickel gemäß 3 beim Vorgang des Verbindens von Stromableitern mit den Anodenableitern und Kathodenableitern,
• 5 das Elektrodenwickel gemäß 4 beim Vorgang des Einschiebens des Elektrodenwickels in ein Zellgehäuse,
• 6 die Anordnung gemäß 5 nach dem Einschieben des Elektrodenwickels in das Zellgehäuse und Verschweißen der Stromableiter mit dem Zellgehäuse unter Bildung einer Batteriezelle,
• 7 ein Stromableiter in einer perspektivischen Darstellung,
• 8 ein Elektrodenstapel in einer perspektivischen Darstellung.

The invention is explained in more detail in the following figures using exemplary embodiments explained without being limited to these. Show it:

• 1 an electrode coil in a schematic representation in a perspective view,
• 2 the electrode coil according to 1 in the process of connecting end-exposed anode conductors,
• 3 the electrode coil according to 2 after connecting the exposed anode conductors and cathode conductors,
• 4 the electrode coil according to 3 in the process of connecting current collectors to the anode collectors and cathode collectors,
• 5 the electrode coil according to 4 during the process of inserting the electrode coil into a cell housing,
• 6 the arrangement according to 5 After the electrode coil has been pushed into the cell housing and the current collector is welded to the cell housing to form a battery cell,
• 7 a current conductor in a perspective view,
• 8th an electrode stack in a perspective representation.

The 1 until 6 show an embodiment of the inventive method for manufacturing a battery cell 1, wherein the 1 until 6 show different process steps in chronological order. In the present case, the battery cell 1 produced by means of the method is a prismatic battery cell 1.

First, in a first step in the 1 is shown, an electrode coil 2 is produced or provided with anode conductors 3 and cathode conductors 4 exposed at the ends. The anode conductors 3 and cathode conductors 4 are then connected to one another, namely over their entire width, by being welded to one another over the entire width of the exposed sections. This process is in the 2 shown. in the 2 This is done by means of ultrasonic welding, with an ultrasonic welding device having two plate-shaped sections 5 being used for this purpose, which are placed one on top of the other. Joining methods similar to ultrasonic welding are conceivable.

The 3 shows the state of the electrode coil 2 after the electrical connection of the anode conductor 3 and the cathode conductor 4. As in particular 3 can be seen, by connecting the anode conductors 3 and the cathode conductors 4, a plate-shaped connecting section 6 is formed in the region of the anode conductors 3 and the cathode conductors 4. A first current conductor 7 is then welded to the anode conductors 3 connected to one another in the area of this plate-shaped connecting section 6 . Furthermore, a second current conductor 8 is welded to the cathode conductors 4 connected to one another in the region of the plate-shaped connecting section 6 . In the present case, the welding is carried out by means of laser welding using a laser 9.

Thereafter, the electrode coil 2 with the welded-on first current collector 7 and the welded-on second current collector 8 is introduced into a cell housing 10, the cell housing 10 having openings 14 lying opposite one another at the end.

In the present case, the electrode coil 2 is pushed along the arrow 11 through one of the openings 14 into the cell housing 10 . The openings 14 or the respective current conductor 7, 8 are designed in such a way that a cover section 15 of the respective current conductor 7, 8 corresponds to the respective opening 14, such that the cover section 15 covers or closes the opening 14. After the insertion, the cover sections 15 of the current conductors 7, 8 are positioned in the area of the respective opening 14 and welded to the cell housing 10 all around, such that a circumferential weld seam 12 is formed between the cover section 15 and the cell housing 10, whereby the opening 14 is closed in a fluid-tight manner by the cover section 15 and the cell housing is mechanically connected to the cover section 15 . Crimping instead of welding is definitely conceivable.

Like the one in particular 6 and 7 As can be seen, the respective current arrester 7, 8 is designed in such a way that a connection section 16 projects inwards relative to the cover section 15, with the anode arresters 3 and the cathode arresters 4 being connected to the respective current conductor 7 and 8 in the region of the connection section 15 . Like that one in particular 7 can be seen, the current collector 7, 8 has a T-shaped cross section.

The cell housing 10 is preferably an extruded profile or extruded profile. Such a profile is particularly easy to produce. The opposite end openings 14 associated with such a profile can be closed particularly easily and efficiently by means of the current conductors 7, 8 and the profile can be reinforced by the current conductors 7, 8, so that high mechanical stability can be achieved without additional structural elements ment. In this respect, the respective current arrester 7, 8 serves as an integrated assembly for a cell connector for establishing an electrical connection between battery cells 1 and also as a cell cover for the respective battery cell 1. The material and manufacturing costs can be reduced as a result.

As an alternative to an electrode coil 2, the battery cell 1 can also have an electrode stack 13, as shown in FIG 8th is shown schematically.

reference list

1

battery cell

2

electrode coil

3

anode conductor

4

cathode conductor

5

Section

6

connection section

7

first current collector

8th

second current conductor

9

Laser

10

cell case

11

Arrow

12

Weld

13

electrode stack

14

opening

15

cover section

16

connection section

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102019211253 A1 [0003]

Claims (11)

Method for producing a battery cell (1) for a battery, in particular for a traction battery of a motor vehicle, in particular a prismatic battery cell, the method having the following method steps: a) Production of an electrode coil (2) or electrode stack (13) with exposed anode conductors (3) and cathode conductors (4) at the ends, b) Electrically connecting the anode conductors (3) to one another, c) Electrically connecting the cathode conductors (4) to one another, d) attaching a first current arrester (7) to the interconnected anode arresters (3), e) attaching a second current conductor (8) to the interconnected cathode conductors (4), f) Insertion of the electrode coil (2) or electrode stack (13) with current collectors (7, 8) attached to it in a cell housing (10) with openings (14) on the front, such that the respective current collector (7, 8) has one of the openings on the front (14) closes. procedure after claim 1 wherein the exposed anode conductors (3) and the exposed cathode conductors (4) are protrudingly formed at opposite ends of the electrode coil (2) or electrode stack (13). procedure after claim 1 or 2 , wherein the openings (14) are formed on opposite end faces of the cell housing (10). procedure after claim 1 or 3 , wherein the current conductors (7, 8) are mechanically fixed in the cell housing (10). Procedure according to one of Claims 1 until 4 , wherein the current conductors (7, 8) are materially connected to the cell housing (10). Procedure according to one of Claims 1 until 5 wherein the width of the anode conductors (3) is identical to the width of a non-exposed area of the respective anode and/or the width of the cathode conductors (4) is identical to the width of a non-exposed area of the respective cathode. Procedure according to one of Claims 1 until 6 , wherein the electrode coil (2) or the electrode stack (13) with the current collectors (7, 8) attached thereto is pushed into the cell housing (10) at the front. Procedure according to one of Claims 1 until 7 , wherein the cell housing (10) is an extruded or extruded profile. Procedure according to one of Claims 1 until 8th , wherein the first and/or the second current arrester (7, 8) has a cover section (15) for closing the front opening (14) and a connection section (16) protruding inwards relative to the cover section (15), the anode conductors (3 ) or the cathode arresters (4) are connected to the current arrester (7, 8) in the region of the connection section (15). Procedure according to one of Claims 1 until 9 , wherein the first and/or the second current collector (7, 8) has a T-shaped cross section. Battery cell for a traction battery of a motor vehicle, in particular a prismatic battery cell, the battery cell (1) having a cell housing (10), an electrode coil (2) or electrode stack (13) being arranged in the cell housing (10), with interconnected anode conductors (3 ) of the electrode coil (2) or electrode stack (13) are connected to a first current conductor (7) and interconnected cathode conductors (4) of the electrode coil (2) or electrode stack (13) are connected to a second current conductor (8), the cell housing (10) has openings (14) on the face side, with the respective current conductor (7, 8) closing one of the openings (14) on the face side.

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