DE102014014529A1 - Single cell for an electrochemical energy storage - Google Patents

Abstract

The invention relates to a single cell (1) for an electrochemical energy store, comprising an electrode foil arrangement (2) arranged in a housing (3), which is connected to a number of conductors (4), wherein the arresters (4) are removed from the housing as cell poles (3) are led out. According to the invention, the electrode foil arrangement (2) and / or the arresters (4) are angled at least once in the region of the arresters (4), wherein the angled portion is designed such that the arresters (4) and / or the electrode foil arrangement (2) in FIG Extend substantially perpendicular to the longitudinal extent of the electrode foil assembly (2).

Description

The invention relates to a single cell for an electrochemical energy store, which comprises an electrode foil arrangement arranged in a housing, which is connected to a number of arresters, wherein the arresters are led out of the housing as cell poles. The invention further relates to an electrochemical energy store with a predeterminable number of such electrochemical single cells.

In general, flat and parallelepiped shaped storage elements for electrical energy, such as single cells of a battery and capacitors whose electrochemically active content is surrounded by a foil-like packaging known. Such single cells are called pouch cells or coffeebag cells. The electrochemically active content of the storage element is an electrode foil arrangement, which is designed as a winding or stack and whose layers of anode foils and cathode foils as well as these electrically mutually insulating separator foils is formed. The electrode foils of a respective polarity are uncoated on at least one edge and protrude out of the electrode foil arrangement as flags and are fastened to each other, in particular stapled. The respective flag is connectable to the current input and Stromausleitung with a sheet-shaped arrester. The packaging of the electrode foil arrangement is a composite foil which comprises a diffusion barrier by means of which penetration of water into the storage element and leakage of electrolyte from the individual cell over the lifetime of the storage element is largely precluded.

The invention has for its object to provide a comparison with the prior art improved single cell for placement in an electrochemical energy storage and an improved electrochemical energy storage with a number of such single cells.

The object is achieved with respect to the single cell by the in claim 1 and in terms of the electrochemical energy storage by the features specified in claim 10.

Advantageous embodiments of the invention are the subject of the dependent claims.

A single cell for an electrochemical energy store comprises an electrode foil arrangement arranged in a housing, which is connected to a number of arresters, the arresters being led out of the housing as cell poles. According to the invention, the electrode foil arrangement is at least in the region of the arresters and / or the arresters are angled at least once, wherein the angled portion is designed such that the arresters and / or the electrode foil arrangement extend substantially perpendicular to the longitudinal extent of the electrode foil arrangement.

Because the arresters are angled and / or that the electrode foil arrangement is angled, the cell poles formed by the arresters do not extend in the direction of the longitudinal extent of the individual cell, so that at least one height thereof and thus a required space requirement of the single cell is reduced.

By means of the vertical bending of the arresters and / or the electrode foil arrangement in the region of the arresters, an electrical interconnection of directly adjacent individual cells is simplified, since the arresters forming the cell poles are angled relative to each other and thus an arrangement, in particular of a cell connector, is possible without much effort.

In a further embodiment, the arresters and / or the electrode foil arrangement are angled in the region of the arresters such that a right angle is formed between the respective angled arrester and the electrode foil arrangement and / or between an angled section of the electrode foil arrangement and a further section of the electrode foil arrangement. If a plurality of individual cells are provided for forming a cell block for an electrochemical energy store, the arresters project in the direction of the adjacent individual cell, whereby the electrical interconnection is simplified.

In one embodiment, it is provided that the arresters have an L-shape in cross-section, so that it is not necessary to angle them and a step in the production can be omitted. In addition, a saving of required space, in particular by means of arresters in L-shape is comparatively high.

Another particularly space-saving solution provides that the arresters have a U-shape in cross section.

In a further development, the bending is formed outside a connection region between a respective arrester and the electrode foil arrangement and a sealed seam of the housing. As a result, a force required to produce the angling is comparatively small, since each part, that is to say the electrode foil arrangement and the arresters, can be angled away from one another to reduce the installation space. In addition, will or will the connection area and / or the sealed seam is not loaded when the angled portion is formed.

Furthermore, it is provided that the bend can be formed after a closure of the housing, so that a sealed seam, by means of which the housing is closed, is furthermore arranged in a plane.

In a further embodiment of the single cell, a housing part of the housing is designed such that it has a depth which corresponds to at least one thickness of the electrode foil arrangement. In this case, this housing part forms the receptacle for the electrode foil arrangement. The electrode foil arrangement can only be aligned in relation to the one housing part, so that a cost, for example when closing the single cell, is reduced.

In addition, it can be provided that corner regions of the housing are beveled, so that additional space can be saved on these side edges of the housing. This saved space can be used for the arrangement of components, for example, for fixing the single cell.

Furthermore, the invention relates to an electrochemical energy storage device with a predeterminable number of such individual cells, wherein a required space of the electrochemical energy storage device can also be reduced by the formation of the individual cells.

Embodiments of the invention are explained in more detail below with reference to the drawing.

Showing:

1 1 is a schematic exploded view of a sectional view of a single cell according to the prior art;

2 schematically a sectional view of the single cell according to the prior art in the assembled state,

3 schematically an enlarged detail of the single cell according to the prior art,

4 schematically a sectional view of a single cell in a first embodiment,

5 1 is a schematic sectional view of an exploded view of a single cell in a second embodiment;

6 schematically the single cell according to 5 in the assembled state,

7 schematically the single cell according to 6 with angled cell poles,

8th schematically the single cell according to 7 with fixation of the angled cell poles,

9 1 is a schematic perspective view of an electrode foil arrangement in an alternative embodiment with cell poles spaced therefrom;

10 FIG. 2 schematically a sectional view of an enlarged section of the electrode foil arrangement in the alternative embodiment, FIG.

11 FIG. 2 schematically shows a perspective view of the electrode foil arrangement with fixed cell poles according to the alternative embodiment, FIG.

12 schematically a sectional view of an enlarged section of the electrode foil assembly with attached cell poles according to 11 .

13 FIG. 2 schematically a perspective view of an electrode foil arrangement with angled sections thereof and attached cell poles, FIG.

14 schematically a sectional view of an enlarged section of the electrode foil assembly according to 13 .

15 schematically a perspective view of an exploded view of the electrode foil assembly according to the 13 and 14 and a housing,

16 schematically a perspective view of the partially closed housing,

17 schematically a perspective view of the single cell with closed housing,

18 schematically a plan view of the single cell,

19 schematically a view of the single cell from below,

20 schematically a perspective view of the housing of the single cell in a possible embodiment,

21 schematically a view of the housing of the single cell in the possible embodiment from below,

22 1 is a schematic perspective view of a single cell with housing in another possible embodiment;

23 schematically a plan view of the housing in the further possible embodiment,

24 schematically the single cell in the further embodiment from below,

25 2 is a schematic perspective view of the single cell with the housing in the further embodiment and an additionally angled upper area,

26 schematically a plan view of the single cell according to 25 .

27 schematically a view of the single cell according to the 25 and 26 from underneath,

28 schematically a sectional view of an enlarged section of the single cell according to the 25 to 27 .

29 schematically an enlarged section of a single cell with cut corners, and

30 schematically an enlarged section of a single cell with oblique in the corner oblique seal.

Corresponding parts are provided in all figures with the same reference numerals.

The 1 to 3 each show a sectional view of a single cell 1 According to the state of the art. In 1 is a sectional view of an exploded view of the single cell 1 , in 2 a sectional view of the single cell 1 in the assembled state and in 3 is a sectional view of an enlarged section of the single cell 1 shown.

The single cell 1 is for arrangement in a battery as an electrochemical energy storage, in particular for vehicle applications, provided, wherein the battery is a traction battery of an electric vehicle, a hybrid vehicle or a fuel cell powered vehicle.

Such a trained single cell 1 is also known under the names Coffeebag cell and Pouch cell, with one as electrode foil arrangement 2 trained electrochemical content of the single cell 1 of two film sections 3.1 as a housing 3 is wrapped.

The respective foil section 3.1 is formed from a composite film, which is made of a layer of aluminum foil as a diffusion barrier, which is provided on both sides with plastic, in particular a thermoplastic. By means of aluminum foil as a diffusion barrier is the risk of water entering the single cell 1 and leakage of electrolyte from the single cell 1 at least reduced.

The foil sections 3.1 are to the closure of the single cell 1 welded together at the edge by a hot pressing process, whereby a sealed seam S is formed. Cell poles of the single cell 1 forming arresters 4 are on opposite sides of the means of the film sections 3.1 formed housing 3 led out of this. For receiving the electrode foil arrangement 2 are the two foil sections 3.1 trough-shaped, for example by deep drawing, shaped.

As described above, the electrode foil assembly is 2 inside the single cell 1 arranged and comprises layers of anode foils and cathode foils which are electrically isolated from one another by means of separators.

For example, the electrode foil arrangement 2 as a wrap or a stack.

In the present embodiment according to the prior art according to the present 1 to 3 For example, electrode films of one polarity are uncoated at opposite edges and are flags 2.1 from the electrode foil assembly 2 led out and connected. The respective flag 2.1 is with a trap 4 , which may be formed from a metal sheet, materially connected, whereby a connection region V is formed. In particular, the arresters 4 by means of pressing and / or melting process, for example resistance spot welding, vibration or ultrasonic welding and / or laser welding on the flags 2.1 attached. Alternatively or additionally, the arresters 4 non-positively and / or positively on the flags 2.1 attached.

By means of the arrester 4 as cell poles of the single cell 1 is a current injection in and a current discharge from the single cell 1 realizable.

For improved connection in the area of arresters 4 and the foil sections 3.1 is between each arrester 4 and foil section 3.1 a so-called Vorsiegelband 5 arranged. By means of the presealing tapes 5 is a minimum distance between the voltage-carrying arresters 4 and the aluminum foil of the foil sections 3.1 set for electrical isolation.

The foil cuts 3.1 are attached to one another after filling of an electrolyte at prevailing negative pressure by a peripheral peripheral seal, whereby a circumferential sealing seam S is formed.

According to the state of the art, the arresters protrude 4 according to the longitudinal extent of the single cell 1 from this, creating a space requirement of the single cell 1 is relatively high.

To the space requirement of such a single cell 1 is to be reduced, is provided in a first embodiment of the invention, the opposite arrester 4 the single cell 1 to bend, as in 4 is shown.

Here is the arrester 4 the single cell 1 angled substantially at 90 °, wherein the connection region V between flag 2.1 and arresters 4 parallel to the longitudinal extent of the electrode foil arrangement 2 and the single cell 1 runs. In particular, the arrester 4 perpendicular to a surface of the largest side of the electrode foil assembly 2 that is, parallel to an upper and lower side wall of the electrode foil assembly 2 angled.

The arresters 4 are angled between the sealing seam S and the connection region V, wherein the respective arrester 4 after closing the single cell 1 is angled.

Since the bend between the sealing seam S and the connecting region V is formed, neither the sealing seam S of the two film sections 3.1 nor the connecting region V between flag 2.1 and arresters 4 when bending, so when generating the bend loaded.

In addition, it can be provided that the arrester 4 has an L-shape, so that the step of bending can be omitted.

A second embodiment of the single cell 1 is in a sectional view in 5 shown.

In this second embodiment of the single cell 1 is compared to the case 3 the first embodiment only a film section 3.1 for receiving the electrode foil arrangement 2 formed trough-shaped. A receiving area for the electrode foil arrangement 2 has a depth substantially equal to a thickness of the electrode foil assembly 2 equivalent. Since the one foil section 3.1 such trough-shaped, is the other film section 3.1 largely planar.

According to the second embodiment of the single cell 1 have the arrester forming the cell poles 4 an L-shape, with the flags 2.1 the electrode foil assembly 2 outside the connection region V are angled by 90 °.

In 6 is a sectional view of the single cell 1 in the second embodiment after closing the housing 3 and before bending the arrester 4 to reduce the space requirement of the single cell 1 shown.

In an in 7 shown next production step of the single cell 1 in the second embodiment, the respective arrester 4 Angled at 90 ° so that the arrester 4 has a U-shape. The bending of the arrester 4 is between the weld S and the connection region V between the flag 2.1 and the arrester 4 educated.

In the second embodiment of the single cell 1 are the flags 2.1 angled at 90 °, with the arresters 4 are also angled in the opposite direction by 90 °.

In particular, the arresters are 4 bent so that these do not have an area of the single cell 1 protrude.

To spring back the arrester 4 Being able to essentially exclude after bending is a bent portion of the arresters 4 by means of adhesive 6 cohesively on the single cell 1 fixed, as in 8th is shown in more detail. The cohesive fixation of the respective arrester 4 at the single cell 1 can be additionally or alternatively realized by means of sealing, adhesive tape and / or double-sided adhesive tape.

In 9 is a perspective view of an alternative embodiment of an electrode foil assembly 2 shown, with the flags 2.1 on a side wall of the electrode foil assembly 2 protrude.

The flags 2.1 extend in the direction of the longitudinal extent of the electrode foil arrangement 2 , where the arresters 4 have an L-shape and according to 9 not yet with the flags 2.1 are connected. At the arresters 4 are the presealing tapes 5 attached.

In 10 is a sectional view of an enlarged section of the electrode foil assembly 2 with the deflectors spaced therefrom 4 shown.

The 11 and 12 each show a view of the electrode foil assembly 2 with attached to this L-shaped arresters 4 , where these in particular by means of ultrasound with the flags 2.1 are welded.

In 11 is a perspective view of the electrode foil assembly 2 with attached arresters 4 and in 12 is a sectional view of an enlarged section of the electrode foil assembly 2 with arresters 4 shown.

13 shows a perspective view of the electrode foil assembly 2 in the alternative embodiment, the flags 2.1 are angled at 90 ° and the arresters 4 between the electrode foil assembly 2 and the angled flags 2.1 attached to this.

In 14 is a sectional view of an enlarged section of the electrode foil assembly 2 in the area of attached arresters 4 shown.

15 shows a perspective view of an electrode foil assembly 2 with attached L-shaped arresters 4 and a film section 3.1 for the formation of the housing 3 in an exploded view.

In the present embodiment, the housing 3 by means of only one foil section 3.1 formed, wherein this a trough-shaped so-called Tiefziehkontur for receiving the electrode foil assembly 2 includes.

To form the housing 3 is the electrode foil arrangement 2 can be arranged in the thermoformed receptacle and the planar portion or the deep-drawn portion of the film section 3.1 with the electrode foil arrangement 2 is folded in the direction of the other section, as in 16 is shown in more detail.

17 shows a perspective view of the single cell 1 with closed housing 3 , due to the formation of the housing 3 with only one foil section 3.1 a closing of the single cell 1 is required on only three pages. The sealing seam S at the arresters 4 opposite side of the housing 3 can be omitted, which in turn requires a space requirement of the single cell 1 can be reduced.

In 18 is a plan view of the single cell 1 and in 19 is the single cell 1 shown in a view from below.

The in the area of one side of the arrester 4 trained corner areas 3.2 of the housing 3 are trimmed to additional space of the single cell 1 to reduce. For example, this thus made available space for the arrangement of parts of a cell fixation, z. B. a holding frame, or to form a cell block, z. B. for tie rods 7 to be used, as in 29 is shown in more detail.

The trimming of the corner areas 3.2 Preferably, after the seal, so after the hot pressing process to close the housing 3 to set a defined edge. As described above, the seal is made on three sides of the housing 3 , where the upper corner areas 3.2 be sealed triangular. Alternatively, the seal S, as in 30 is shown in detail, even in strip form obliquely over the respective corner area 3.2 be placed. Subsequently, the trimming takes place, wherein a required width of the sealing seam S in the direction of the single cell 1 preserved.

Alternatively, the corner areas 3.2 also on the foil sections 3.1 be cut as blanks before sealing.

20 shows a perspective view of the single cell 1 with in the two corner areas 3.2 tailored housing 3 , In this case, a plan view corresponds to the single cell 1 with the cut corners 3.2 essentially according to the plan view 18 ,

In 21 is the single cell 1 according to 20 shown in a view from below.

By trimming the corner areas 3.2 the single cell 1 It is to further reduce the space requirement of the single cell 1 additionally possible that side sections and the side on which the arresters 4 out of the case 3 are led out, are foldable, such as in the 22 . 23 and 24 is shown.

In particular, in 23 a bending line B shown in dashed line, at which the bend of the side of the arrester 4 is carried out.

After folding the lateral sections of the housing 3 is the page with the arresters 4 folded upwards, with a bend of this side in the area between the sealing seam S and the connecting region V between the flags 2.1 and the arresters 4 runs.

As an alternative to folding, the lateral sections and the side of the arresters can 4 be rolled up.

25 shows a perspective view of the single cell 1 with folded side sections and folded side of the arrester 4 ,

A top view of the single cell 1 is in 26 and a bottom view is in 27 shown in more detail.

A sectional view of an enlarged section of the single cell 1 with bent side of the arrester 4 is in 28 shown.

The bending line B is shown with a dashed line, which between the sealing seam S and the connection region V between the flags 2.1 and the arresters 4 runs. The bend does not pass through the sealing seam S of the lateral sections of the housing 3 ,

29 shows an enlarged section of the single cell 1 in the field of arresters 4 where the trimmed corner areas 3.2 and in this thus available space arranged tie rods 7 are shown indicated.

In 30 is an enlarged section of the single cell 1 in the field of arresters 4 with in the corner areas 3.2 extending sealing seam S shown, with the non-sealed corner areas 3.2 then be cut.

LIST OF REFERENCE NUMBERS

1

single cell

2

Electrode foil arrangement

2.1

Banner, flag

3

casing

3.1

film section

3.2

corner

4

arrester

5

Vorsiegelband

6

adhesive

7

tie rods

B

elastic line

S

seal

V

connecting area

Claims (8)

Single cell ( 1 ) for an electrochemical energy store, comprising one in a housing ( 3 ) arranged electrode foil arrangement ( 2 ) with a number of arresters ( 4 ), the arresters ( 4 ) as cell poles from the housing ( 3 ), characterized in that the electrode foil arrangement ( 2 ) and / or the arresters ( 4 ) at least in the area of arresters ( 4 ) are angled at least once, wherein the angled portion is formed such that the arrester ( 4 ) and / or the electrode foil arrangement ( 2 ) substantially perpendicular to the longitudinal extent of the electrode foil arrangement ( 2 ). Single cell ( 1 ) according to claim 1, characterized in that the arresters ( 4 ) have an L-shape in cross-section. Single cell ( 1 ) according to claim 1, characterized in that the arresters ( 4 ) have a U-shape in cross-section. Single cell ( 1 ) according to one of the preceding claims, characterized in that the bending outside a connection region (V) between the arresters ( 4 ) and the electrode foil arrangement ( 2 ) and a sealed seam (S) of the housing ( 3 ) is trained. Single cell ( 1 ) according to one of the preceding claims, characterized in that the bend after a closure of the housing ( 3 ) can be formed. Single cell ( 1 ) according to one of the preceding claims, characterized in that a housing part of the housing ( 3 ) is formed such that it has a depth which is at least one thickness of the electrode foil arrangement ( 2 ) corresponds. Single cell ( 1 ) according to one of the preceding claims, characterized in that corner regions ( 3.2 ) of the housing ( 3 ) are formed chamfered to the arrangement of at least one further component. Electrochemical energy store with a predeterminable number of individual cells ( 1 ) according to any one of the preceding claims.

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