DE102021200181A1 - Battery cell and electrically powered motor vehicle - Google Patents

Abstract

The invention relates to a battery cell (8) with an electrode arrangement (20) which is accommodated in a cover (18), the cover (18) being formed using two foils (22) and a wall element (24), and the Wall element (24) is arranged to form a side wall of the envelope (18) between the films (22). The invention also relates to an electrically driven motor vehicle (2) whose traction battery (4) has such a battery cell (8).

Description

The invention relates to a battery cell designed in particular as a lithium-ion battery cell, the casing of which is formed using two foils. Furthermore, the invention relates to an electrically driven motor vehicle whose traction battery has such a battery cell.

An electrically driven motor vehicle typically has a traction battery (high-voltage, HV battery) which supplies an electric motor for driving the motor vehicle with energy. An electrically powered motor vehicle is, in particular, an electric vehicle that only stores the energy required for the drive in the traction battery (BEV, battery electric vehicle), an electric vehicle with a range extender (REEV, range extended electric vehicle), a hybrid vehicle (HEV, hybrid electric vehicle), a plug-in hybrid vehicle (PHEV, plug-in hybrid electric vehicle) and/or a fuel cell vehicle (FCEV, fuel cell electric vehicle), which temporarily stores the electrical energy generated by a fuel cell in the traction battery.

Such a traction battery is designed in particular as a lithium-ion battery. This includes a number of interconnected battery modules, which in turn have a number of lithium-ion battery cells (Li-ion battery cells). Several variants of lithium-ion battery cells are known, namely cylindrical cells (round cells), pouch cells and prismatic cells.

In a conventional pouch cell, an electrode arrangement embodied as an electrode stack or as a flat coil is accommodated in a sleeve, which is formed from two so-called pouch films that are joined together. In particular, plastic-aluminum composite films are used here as pouch films. One of these two pouch films or both pouch films are formed into a trough shape (shell shape) in the course of the production of the battery cell by means of a deep-drawing process, so that a receiving space for the electrode arrangement is formed.

In particular, if the pouch film has to be correspondingly deep-drawn for a comparatively high electrode arrangement, there is a risk due to the deep-drawing that it will thin out or even tear (when the battery cell is in operation), ie become leaky. Furthermore, sealing the battery cell requires an outwardly protruding joint section (flange section), which disadvantageously takes up space and which makes (thermal) contact with a cooling device more difficult.

The invention is based on the object of specifying a particularly suitable battery cell whose casing is formed using a film. In particular, deep drawing of the film to form the shell should be avoided. Furthermore, an electrically driven motor vehicle is to be specified which has a traction battery with such battery cells.

With regard to the battery cell, the object is achieved according to the invention by the features of claim 1. With regard to the electrically driven motor vehicle, the object is achieved by the features of claim 10 according to the invention. Advantageous refinements and developments are the subject of the dependent claims. The statements made in connection with the battery cell also apply to the electrically powered motor vehicle and vice versa.

The battery cell is particularly preferably designed as a lithium-ion battery cell. It comprises an electrode arrangement, which in turn has at least one anode and at least one cathode. The electrode arrangement is designed, for example, as a flat coil, in which the anode and the cathode and a separator arranged between the anode and the cathode are wound around a flat winding mandrel. As an alternative to this, the electrode arrangement is designed as an electrode stack which has a number of anodes and a number of cathodes. In this case, the anodes and the cathodes are stacked alternately on top of one another in a stacking direction, with a separator being arranged in each case between the anodes and the cathodes.

The battery cell is preferably provided and set up for a traction battery of an electrically driven motor vehicle. The battery cell is preferably also provided and set up for a battery module of a traction battery. In principle, it is possible for the battery cell to be a primary battery cell (primary cell), but the battery cell is expediently a secondary battery cell (secondary cell).

The battery cell also has a shell in which the electrode arrangement is accommodated. In other words, the electrode arrangement is enclosed by the sleeve, expediently in a fluid-tight manner. The shell is made of two foils and a wall element. The wall element is arranged between the two films, with the wall element forming a side wall of the envelope. The two films and the wall element thus each form an outer wall of the battery cell. The wall element is in particular arranged at the end, that is to say on a circumference of the respective film.

The two films are thus spaced apart from one another by means of the wall element, in particular at one of its edges.

The two foils are joined to the wall element, expediently in a fluid-tight manner. In particular, the foils are joined to the wall element on two sides which are oriented parallel to one another and face the respective foil element.

A base and the cover of the casing of the battery cell, which is oriented parallel thereto, are particularly preferably formed by means of the two foils. In this case, the base and the cover form, in particular, a large outer surface compared to a front side (narrow side) of the casing of the battery cell. The side wall formed by means of the wall element is therefore preferably an end face (narrow side) of the casing of the battery cell.

The two foils are suitably joined together on the circumference, with the exception of that area in which the foils are joined to the wall element. In particular, the two foils are welded together there and the battery cell is thus sealed.

The two foils are particularly preferably designed as pouch foils, in particular each as a plastic-aluminum composite foil. On the side facing the electrode arrangement, these have an electrically insulating plastic layer, so that a short circuit of the anode(s) and the cathode(s) is avoided due to the aluminum component of the foil.

The wall element has, for example, a thickness, in other words a wall thickness, of between 0.1 mm and 3 mm. The wall element is therefore foil-like according to the selected thickness and is therefore flexible or comparatively rigid. The thickness of the wall element is preferably between 1 mm and 2 mm. In this way, a joining process of the wall element with the foils is comparatively simple and the joining is comparatively reliable.

In the course of the production of the battery cell, the electrode arrangement can first be applied directly to the wall element, so that the electrode arrangement is arranged between the two foils and, in particular, is fixed. The wall element is thus used in an advantageous manner for arranging the electrode arrangement in a defined position with respect to the envelope. The two foils covering the electrode arrangement are then joined to one another on the peripheral side. Further advantageously, at least for the side wall of the casing formed by means of the wall element, deep-drawing of the films is avoided and the risk of the film tearing open is thus reduced.

According to an advantageous development, in a first variant of the battery cell, a second wall element is arranged between the foils and expediently joined to them. The second wall element runs parallel to the (first) wall element. The second wall element forms a second side wall of the shell in a manner analogous to the first wall element.

According to a second variant of the battery cell, the wall element has a U-shape with two side limbs, which run parallel to one another, and a connecting limb connecting the two side limbs at the free end. The two side legs and the connecting leg each form a side wall of the casing.

Advantageously, with these two variants, it is possible to bring the two foils together and to join them together without deep-drawing by bending in the area of their circumference, which is not joined to the wall element or elements.

As an alternative to this, the wall element is designed as a frame which extends along the entire circumference of the battery cell. Thus, all side walls of the casing oriented perpendicularly to the base and to the lid, which are formed using the foils, are formed using the wall element. The two films are joined to the wall element designed as a frame on the upper side of the frame or on the underside of the frame, so that the two films are each flat. Deep drawing of the foils is therefore no longer necessary.

According to a suitable embodiment, the height of the wall element is equal to the height of the electrode arrangement. In other words, the extent of the wall element in the vertical direction of the battery cell is equal to the extent of the electrode arrangement in this direction. If the electrode arrangement is designed as an electrode stack, the vertical direction of the electrode arrangement is in particular the same as a stacking direction in which the anodes and the cathodes are stacked one on top of the other. If the electrode arrangement is designed as a flat coil, the vertical direction of the electrode arrangement is in particular the same as a direction perpendicular to a plane spanned by the winding mandrel, ie in particular the main direction of extension in which the electrode coil has the smallest extent.

It is advantageously made possible in this way that the films are each flat from the wall element extending from above or below the electrode arrangement.

Expediently, the wall element also has an extent in its longitudinal direction, ie perpendicular to the vertical direction and perpendicular to its thickness direction, which is at least equal to the extent of the electrode arrangement in this direction. In other words, the wall element covers the electrode arrangement with respect to a normal of the wall element.

According to an advantageous embodiment, in particular the first and the second variant, the or each wall element tapers continuously at the end. In other words, the height of the respective wall element decreases steadily, ie not abruptly, at the free end. For example, the or each wall element runs conically, triangularly, S-shaped, wavy, parabolic, hyperbolically, or tanh-shaped (hyperbolic tangent-shaped) at the free end.

In this way, the foils have to be kinked or bent to a lesser extent at this free end or at these free ends of the wall element in order to bring them together and join them together.

According to an advantageous embodiment, the wall element has a feed-through opening for a measuring device, in particular for a sensor. A measuring device can thus be introduced from the outside of the battery cell into the cell interior enclosed by the casing. This can expediently be closed in a fluid-tight manner, even if the measuring device protrudes through the through-opening.

The feed-through opening can also advantageously be used as a filling opening for an electrolyte in the course of production.

If a comparatively high pressure builds up inside the battery cell, for example in the event of a malfunction such as a so-called thermal runaway, there is a risk that the battery cell will burst open or even explode. The components of the battery cell, for example the electrolyte, are thus released in an undefined manner into a space accommodating the battery cell. In order to avoid this, according to an advantageous development, a safety valve (pressure relief valve, gas pressure valve) is incorporated into the wall element. The safety valve is set up in particular in such a way that it opens (triggers) when a predetermined pressure threshold value is exceeded. As a result, a gas formed in the battery cell can escape, so that the risk of explosion is reduced.

According to an expedient embodiment, the wall element is made of a plastic. In this way, a short circuit of the anode(s) and the cathode(s) is avoided by means of the wall element.

Preferably, the wall element is additionally provided with a coating of metal, in particular chromium or a chromium compound, or preferably aluminum or an aluminum compound, which acts as a vapor barrier. In other words, the metal coating prevents a fluid from escaping from the battery cell or a fluid from entering the battery cell. For example, the metal coating is applied to the side of the wall element facing away from the electrode arrangement, ie to the outside thereof. Alternatively or additionally, this is applied to the side of the wall element facing the electrode arrangement, ie to the inside thereof. In this case, a separator is expediently arranged between the electrode arrangement and the wall element in order to prevent a short circuit within the electrode arrangement using the metal layer of the wall element.

As an alternative to this, the wall element is made of a metal, in particular aluminum or stainless steel. Because of this, the wall element has a comparatively high thermal conductivity. The battery cell can thus be cooled particularly well by means of the wall element. For this purpose, for example, cooling elements are provided which rest on the outside of the wall element. In addition, a wall element formed from a metal is advantageously particularly fluid-tight, so there is no diffusion or the like from the inside of the cell to the outside of the cell. This metal wall element is suitably provided with a plastic layer. For this purpose, the wall element is painted, for example. In this way, a short circuit within the electrode arrangement is prevented by the metal wall element. In addition or as an alternative to this, the wall element is provided with a coating on its side facing the respective film, which facilitates a joining process with the films and/or which enables a comparatively reliable joint at joints between the respective film and the wall element. For example, this coating has a plastic that melts in the course of joining with the respective film and forms a material connection with the film, in particular with the plastic layer of the pouch film.

For example, a separator is arranged between the electrode arrangement and the wall element, so that a short circuit is prevented. Additionally or alternatively, to the the inside of the wall element facing the electrode arrangement is provided with an insulating layer. The insulation layer is preferably porous. In this way, the electrolyte can enter the pores of the insulating layer. As a result, heat dissipation from the electrolyte to the wall element is advantageously increased.

In an expedient embodiment, the wall element has a recess or a passage for a terminal which is electrically contacted with the anode or with the anodes or with the cathode or with the cathodes of the electrode arrangement. The feed-through opening or the recess through which the terminal protrudes can be closed in a fluid-tight manner. For this purpose, the terminal is, for example, surrounded on the circumference by a preferably electrically insulating joining aid, which in turn is joined to the wall element, for example glued, clamped or welded on.

For example, as an alternative or in addition to this, the wall element is electrically insulating in the area of the terminal, so that a short circuit with another terminal is avoided.

A further aspect of the invention relates to an electrically driven motor vehicle with a traction battery. This has at least one battery cell in one of the variants or designs presented above. In particular, its shell is formed using two foils, between which at least one wall element is arranged, with the respective wall element forming a side wall of the shell.

In summary, the invention advantageously makes it possible to produce a battery cell in which it is not necessary to deep-draw the foils of its casing or in which deep-drawing can at least be reduced. A further advantage is that the height of the electrode arrangement accommodated in the battery cell can be selected more flexibly.

• 1 schematisch ein elektrisch angetriebenes Kraftfahrzeug, dessen Traktionsbatterie eine Anzahl an Batteriemodulen aufweist, wobei die Batteriemodule wiederum eine Anzahl an als Pouchzellen ausgebildeten Lithium-Ionen-Batteriezellen umfassen,
• 2 schematisch in perspektivischer Ansicht eine der Batteriezelle gemäß einer ersten Ausführungsform, wobei deren Hülle aus zwei Folien gebildet ist, zwischen denen ein Wandelement als Seitenwand der Batteriezelle angeordnet ist,
• 3a schematisch in perspektivischer Ansicht eine der Batteriezelle gemäß einer zweiten Ausführungsform, wobei deren Hülle aus zwei Folien gebildet ist, zwischen denen ein erstes Wandelement als erste Seitenwand und ein parallel hierzu orientiertes zweites Wandelement als zweite Seitenwand der Batteriezelle angeordnet ist,
• 3b schematisch in perspektivischer Explosionsdarstellung die Batteriezelle gemäß der 3a,
• 4 schematisch in perspektivischer Explosionsdarstellung eine der Batteriezelle gemäß einer dritten Ausführungsform, wobei deren Hülle aus zwei Folien gebildet ist, zwischen denen ein U-förmiges Wandelement angeordnet ist,
• 5 schematisch in perspektivischer Explosionsdarstellung eine der Batteriezelle gemäß einer vierten Ausführungsform, wobei deren Hülle aus zwei Folien gebildet ist, zwischen denen ein einen Rahmen bildendes Wandelement angeordnet ist, und
• 6a bis 6d in Draufsicht auf das Wandelement, wobei das Terminal zwischen dem Wandelement und einer der Folien aus der Batteriezelle herausgeführt ist, wobei die das Wandelement eine Aussparung auf weist, in der das Terminal eingebracht ist, oder wobei das Wandelement eine Durchführung für das Wandelement aufweist.

Exemplary embodiments of the invention are explained in more detail below with reference to a drawing. Show in it:

• 1 schematically an electrically driven motor vehicle, the traction battery of which has a number of battery modules, the battery modules in turn comprising a number of lithium-ion battery cells designed as pouch cells,
• 2 a schematic perspective view of one of the battery cells according to a first embodiment, the casing of which is formed from two foils between which a wall element is arranged as the side wall of the battery cell,
• 3a a schematic perspective view of one of the battery cells according to a second embodiment, the shell of which is formed from two films, between which a first wall element is arranged as the first side wall and a second wall element oriented parallel thereto as the second side wall of the battery cell,
• 3b schematically in a perspective exploded view the battery cell according to 3a ,
• 4 schematically in a perspective exploded view one of the battery cell according to a third embodiment, wherein its shell is formed from two foils between which a U-shaped wall element is arranged,
• 5 schematically in a perspective exploded view one of the battery cell according to a fourth embodiment, wherein its shell is formed from two foils, between which a frame-forming wall element is arranged, and
• 6a until 6d in plan view of the wall element, wherein the terminal is led out between the wall element and one of the foils of the battery cell, wherein the wall element has a recess in which the terminal is introduced, or wherein the wall element has a passage for the wall element.

Corresponding parts and sizes are always provided with the same reference symbols in all figures.

In 1 a motor vehicle 2 with a traction battery 4 is shown. The traction battery 4 has a number of battery modules 6, also referred to as cell modules, only two of the battery modules 6 being shown for the purpose of better clarity.

Each of the battery modules 6 in turn has a number of battery cells 8 designed as lithium-ion battery cells, of which five are shown for each battery module 6 . The battery cells 8 each provide a voltage at their (cell) terminals 10 . The battery cells 8 of each battery module 6 are connected in series and/or parallel to one another in a manner that is not shown in detail. In addition, the battery modules 6 are connected in series and/or parallel to one another in a manner that is not shown in detail and are electrically connected to battery connections 12 for a consumer.

A consumer is connected to the battery connections 12 of the traction battery 4 and is designed here as an inverter 14 of a drive train of the motor vehicle 2 and an electric motor 16 connected to it. The inverter 14 converts the direct current provided by the traction battery 4 or the direct current provided by it into an alternating current or alternating current that is suitable for operating the electric motor 16 . Alternatively, the electric motor 16 is in the form of a direct current motor, in particular a permanently excited direct current motor, and is connected to the battery connections directly or optionally via a DC/DC converter. In summary, the traction battery provides electrical energy for driving motor vehicle 2 .

In the 2 until 6d different variants of one of the battery cells 8 are shown. What all variants have in common is that the battery cell 8 has a casing 18 in which an electrode arrangement 20 is accommodated and which encloses the electrode arrangement 20 . The casing 18 has two foils 22 designed as pouch foils, that is to say as plastic-aluminum composite foils. The two foils 22 are arranged one above the other in a vertical direction H, with the electrode arrangement 20 being arranged between the foils 22 with respect to the vertical direction H. The two foils 22 thus form a base and a cover of the sleeve 18.

Furthermore, the battery cell 8 (in all variants) includes a wall element 24 which is arranged in the vertical direction H between the two foils 22 . The wall element 24 is arranged on a circumference of the foils 22 and joined to them. The foils 22 are thus spaced apart from one another in the vertical direction H by means of the wall element 24 . So the wall element 24 is on the periphery of the foils 22 perpendicular to these upwards. The wall element 24 spans a plane which runs parallel to the vertical direction H. The wall element 24 runs essentially perpendicularly to the two foils 22.

In summary, the battery cell 8 is designed as a pouch cell, with a wall element 24 being arranged between its pouch films 22 .

Furthermore, all variants of the battery cell 8 have in common that the height hw of the wall element 24 is equal to the height h _E of the electrode arrangement 20 . In other words, the extension of the wall element 24 in the vertical direction H corresponds to the extension of the electrode arrangement 20 in the vertical direction H. This is exemplified in FIG 3b shown.

According to embodiments not shown in detail, the height hw of the wall element 24 is greater or less than the height of the electrode arrangement 20. In this way, for example, the thickness of a separator or the like arranged in the vertical direction H between the foils 22 and the electrode arrangement 20 can be taken into account, or the electrodes of the electrode arrangement 20 are braced against one another.

The wall element 24 is formed from a plastic so that a short circuit of the anode(s) and the cathode(s) of the electrode arrangement 20 through the wall element 24 is avoided. In a manner not shown in more detail, the wall element 24 is provided on the outside, ie on the side facing away from the electrode arrangement 20, with a coating of metal, in particular chrome or preferably aluminum, which forms a water or vapor barrier. Thus, the wall element 24 is particularly fluid-tight. According to configurations of all variants of the battery cell 8 that are not shown in detail, the wall element 24 is additionally or alternatively provided with a metal layer on the inside facing the electrode arrangement 20 , a separator being introduced between the wall element 24 and the electrode arrangement 20 .

According to alternatives of all variants of the battery cell 8 that are not shown in more detail, the wall element 24 is made of a metal, in particular aluminum or stainless steel. Such a wall element 24 has comparatively good heat conduction. In a way that is not shown, the wall element 24 rests against a cooling device, for example a cooling plate, in the assembled state in the traction battery 4 .

The wall element 24 is coated on its inner side facing the electrode arrangement 20 with an (electrical) insulating layer which is porous. Due to the pores, an electrolyte can continue to effectively dissipate heat to the wall element 24 . As an alternative or in addition to this, a separator is arranged between the wall element 24 and the electrode arrangement 20 .

The wall element 24 has a feed-through opening 26 for a measuring device (not shown in any more detail). The feed-through opening 26 is closed in a fluid-tight manner. If the measuring device protrudes through the feed-through opening, a gap between the measuring device and the wall of the wall element 24 delimiting the feed-through opening 26 is sealed in a fluid-tight manner, for example using an adhesive.

Furthermore, the battery cell 8 has a (overpressure valve) safety valve 28 which is introduced into the wall element 24 .

The introduction of the through-opening 26 and/or the safety valve 28 in the wall element 24 is simpler and safer against leakage than their introduction between the two foils.

In the 2 a first variant of the battery cell 8 is shown. The wall element 24 forms a single side wall (front side) of the battery cell 8 or its shell 18 . The other front sides of the battery cell 8 are formed by the two foils 22 . For this purpose, the two foils are joined to one another in a gas-tight manner along their circumference, with the exception of the area, in particular with the exception of that edge on which the wall element 24 is arranged. In particular, the two foils 22 are joined together in a gas-tight manner by impulse or contact sealing, forming a flange section 30, also referred to as a joining section or joining area.

The wall element 24 spans a plane which is parallel to the vertical direction H and to a direction designated as the longitudinal direction X, the vertical direction H and the longitudinal direction X being the main directions in which the wall element 24 extends.

The wall element 24 tapers at the free end, ie at the end with respect to the longitudinal direction. Each of the tapering free ends is provided with the reference number 32 . The taper is constant, in other words the height h _W of the wall element 24 decreases continuously at the free end. In other words, the wall element 24 runs out at the free end.

In order to join the two foils 22 to one another on the end faces adjoining the wall element 24 , the foils 22 are bent or kicked about an axis running perpendicularly to the wall element 24 . The bending or buckling edge 34 extends according to the execution of 2 from the beginning of the tapered portion 32 of the wall element. In order to join the two foils 22 on the end face facing away from the wall element 24, the two foils 22 are either folded in a corner region 36 formed by means of them or (only) deep-drawn there.

In the 3a and 3b a second variant of the battery cell 8 is shown. In this case, the sleeve 18 has a second wall element 38 which is arranged between the two films 22 and joined to them. The second wall element 38 runs parallel to the (first) wall element 24. The second wall element 38 forms an outside (side wall) of the battery cell 8 in a manner analogous to the first wall element 24. The height of the second wall element 38 is equal to the height hw of the (first ) Wall element 24. In addition, its free ends taper continuously in a manner analogous to the free ends of the first wall element 24.

According to this variant of the battery cell, the two foils 22 are merely bent or kinked at the bending or buckling edge 34 in order to bring them together and to join them together to form the respective flange area 30 . It is therefore not necessary to deep-draw the foils 22 .

The two terminals 10 of the battery cell protrude according to the variant 2 until 3b on opposite end faces in the respective flange area 30 out of the battery cell 8 .

The third variant of the battery cell 8 according to the 4 comprises a U-shaped wall element 24. The wall element 24 thus has two side legs 40, which run parallel to one another, and a connecting leg 42 connecting the two side legs 40 at the free end. The two side legs 40 and the connecting leg 42 each form a side wall of the casing 18 or the battery cell 8. In the region of the connecting leg 42, the two foils 22 extend flat in a direction perpendicular to the vertical direction H.

The fourth variant of the battery cell 8 according to the 5 comprises a frame-shaped wall element 24. The wall element 24 thus has two side legs 40, which run parallel to one another, and two connecting legs 42 connecting the two side legs 40 at the free end. The two side legs 40 and the two connecting legs 42 each form a side wall of the casing 18 or of the battery cell 8. In summary, the frame-shaped wall element 24 stands up along the entire circumference of the foils 22, perpendicularly thereto. The two foils 22 each span a plane perpendicular to the vertical direction H, so that deep-drawing of the foils 22 is avoided for the production of the casing 18 .

In summary, the variants of the battery cells according to the 3a until 5 no deep-drawing of the foils 22 necessary. In the variant of 2 the foils 22 are either folded or deep-drawn only on the side facing away from the wall element 24 .

In the 6a until 6d The battery cell 8 is shown in detail in each case, with at least one of the terminals 10 protruding from the battery cell 8 on a side wall of the shell 18 formed using the wall element 24 .

In the design according to 6a the terminal 10 is arranged between the wall element 24 and one of the two films 22. In this case, the pouch film is guided around the terminal 10 .

According to the design of 6b the wall element 24 has a recess 44 which is made on an upper side of the wall element 24 which faces the film 22 . The terminal 10 is seated in the recess 44 . The recess 44 corresponds to the contour of the terminal 10. In particular, the extent of the recess 44 in the vertical direction H corresponds to the extent of the terminal 10, optionally including a joining or sealing element (not shown) that surrounds the terminal on the circumference. Compared to the design of 6a Although the manufacturing cost of the wall element 24 is increased, the pouch cell does not have to be guided around the terminal 10 . In this way, the battery cell has a uniform height. In addition, the joining of the terminal 10 in the recess is comparatively reliable.

Alternatively, the wall element 24 according to the embodiment of 6c a feed-through opening 46 through which the terminal 10 is passed. As a result, the terminal is held in position comparatively securely.

According to the design of 6d the wall element 24 is formed in two parts, the two parts 24a, 24b being arranged one above the other in the vertical direction H. Each of the parts 24a and 24b is joined to one of the two foils 22, the two parts 24a and 24b of the wall element 24 also being joined to one another. The two parts 24a and 24b have a contour on their mutually facing sides such that the passage for the terminal 10 is formed. In this variant, it is possible during assembly that the terminal 10 is inserted into the recess-like contour of the first part 24a before the second part 24b is applied to the first part 24a and joined to it. On the one hand, the two parts 24a and 24b must be joined together in an additional step. On the other hand, introducing the terminal 10 into the implementation is comparatively simple and compared to the variant of 6c the risk of damage in the course of passing the terminals 10 through the bushing 46 is reduced.

The invention is not limited to the embodiment described above. On the contrary, other variants of the invention can also be derived from this by a person skilled in the art without departing from the subject matter of the invention. In particular, all of the individual features described in connection with the exemplary embodiment can also be combined with one another in other ways without departing from the subject matter of the invention.

Reference List

2

electrically powered motor vehicle

4

traction battery

6

battery module

8th

battery cell

10

terminal

12

battery connection

14

inverter

16

electric motor

18

Covering

20

electrode arrangement

22

foil/pouch foil

24

wall element

26

through hole

28

safety valve

30

flange section

32

Free-end side of the wall element

34

bend or crease edge

36

corner area

38

second wall element

40

side leg

42

connecting leg

44

recess

46

execution

hW

height of the wall element

hE

Height of the electrode array

H

vertical direction

X

longitudinal direction

Claims (10)

Having a battery cell (8), in particular designed as a lithium-ion battery cell - Electrode arrangement (20), which is accommodated in a sleeve (18), - the envelope (18) being formed by means of two sheets (22) and a wall element (24), and - wherein the wall element (24) is arranged to form a side wall of the envelope (18) between the films (22). Battery cell (8) after claim 1 , characterized in that the height (h _W ) of change ements (24) is equal to the height (h _E ) of the electrode arrangement (20). Battery cell (8) after claim 1 or 2 , characterized in that the wall element (24) tapers continuously at the free end. Battery cell (8) according to one of Claims 1 until 3 , characterized in that the wall element (24) has a feed-through opening (26) for a measuring device. Battery cell (8) according to one of Claims 1 until 4 , characterized in that a safety valve (28) is introduced into the wall element (24). Battery cell (8) according to one of Claims 1 until 5 , characterized in that - that the wall element (24) is formed from a plastic, - and/or that the wall element (24) is provided with a coating of metal. Battery cell (8) according to one of Claims 1 until 5 , characterized in that - that the wall element (24) is formed from a metal, - and/or that the wall element (24) is provided with an insulating layer on its inner side facing the electrode arrangement (20). Battery cell (8) according to one of Claims 1 until 7 , characterized in that - a second wall element (38) is arranged between the foils (22), the second wall element (38) running parallel to the wall element (24) and forming a second side wall of the casing (18), or - that the Wall element (24) has a U-shape with two side legs (40) and a connecting leg (42), the side legs (40) and the connecting leg (42) each forming a side wall of the casing (18). Battery cell (8) according to one of Claims 1 until 8th , characterized in that the wall element (24) has a recess (44) or a passage (46) for a terminal (10). Electrically driven motor vehicle (2), the traction battery (4) has a battery cell (8) which according to one of Claims 1 until 9 is trained.

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