EP2401779A1

EP2401779A1 - Galvanic cell having a frame and method for the production of said galvanic cell

Info

Publication number: EP2401779A1
Application number: EP10707466A
Authority: EP
Inventors: Jens Meintschel
Original assignee: Li Tec Battery GmbH
Current assignee: Li Tec Battery GmbH
Priority date: 2009-02-27
Filing date: 2010-03-01
Publication date: 2012-01-04
Also published as: DE102009010794A1; CN102334211A; KR20120006984A; BRPI1007834A2; WO2010097242A1; JP2012519349A; US20120135288A1

Abstract

A frame for a galvanic cell made of an electrode stack having a film-like packaging out of which at least two conductors are guided is designed in such a way that the frame can be rigidly connected to the packaging of the cell in the production of the cell. In the production of such a galvanic cell, a frame is rigidly connected to the packaging during the closing of the packaging.

Description

Galvanic cell with frame and method for its production

Description

The present invention relates to a galvanic cell, comprising a frame and a method for its production. Are known flat and rectangular cells (battery cells, capacitors, etc.), whose electrochemically active content of a film-like packaging, such as a thin

Aluminum foil, which is plastic-coated on both sides, through which electrical connections in sheet form (so-called "arrester") are led.In contrast to other cell types, the packaging of such cells is not live because the arresters are led through the package in isolation constructed battery cells are also referred to as pouch or as Coffeebag cells.

In various applications, e.g. in electric or hybrid vehicles, individual galvanic cells are connected in series and / or in parallel and are often in an enclosure with associated electronics. Because of the often not very high mechanical strength of the welded in a foil pouch cells, these can often not be installed directly into the battery case, but must first be mechanically stabilized by suitable support structures.

The object of the present invention is to facilitate the application and treatment of galvanic cells and to alleviate or, if possible, mitigate the problems associated with the sensitivity of their packaging film to solve. This object is achieved by a product or a method according to one of the independent claims.

According to the invention, a frame is provided for a galvanic cell. The cell consists essentially of an electrode stack and a foil-like packaging from the at least two arresters are led out. The frame is designed so that it can be firmly connected to the packaging of the cell in the manufacture of the cell. In the method according to the invention for producing a galvanic cell, a frame is firmly connected to the packaging when the packaging is closed.

In the following, some terms will be explained, which will be used in the further description in the invention.

The term electrode stack is used to designate the electrochemically active contents of a galvanic cell of any type. In contrast, the packaging of a cell is understood as meaning the material which does not participate in the electrochemical reaction and which seals off the electrode stack from the environment.

If in this context of a film-like packaging is mentioned, then it should be understood as all types of packaging or inclusions, which serve the purpose of shielding the electrode stack with a preferably low material use effectively against the environment and complete. The conclusion should act against a transfer of matter and of electrical currents. However, this term does not exclusively include foils in the usual sense, in particular also plastic-coated metal foils.

For the purposes of the present invention, electrical conductors which are routed through the packaging to the outside are referred to as arresters Transport of electrical charge into the cell or from the cell can take place.

A framework within the meaning of the present invention should be understood to mean any constructional device which is suitable for mechanically stabilizing the cell against environmental influences and which can be firmly connected to the packaging of the cell during the production of the cell. As the wording already indicates, a frame is preferably a substantially frame-shaped device, the function of which is essentially to impart mechanical stability to a galvanic cell. Advantageous developments of the invention will become apparent from the dependent claims.

In the following the invention will be described in more detail by means of preferred embodiments and with the help of figures. It shows

1 shows a front view of an embodiment of an integrated frame cell according to the invention;

Figure 2 is a view of the same embodiment from behind.

3 shows an exploded view of this cell from the front and

4 shows an exploded view of this cell from behind;

Figure 5 shows an embodiment of the invention in which the frame is welded to the outwardly extended inside of the packaging film;

6 shows an embodiment of the invention, in which the frame with the

Outside of the packaging film is welded in the region of the seal of the two films; 7 shows the basic structure of a typical packaging film of galvanic cells;

8 shows the structure of a cell block of galvanic cells according to an embodiment of the present invention.

Figure 9 is a view of a galvanic cell according to an embodiment of the present invention with a frame with holes for a tie rod and arresters, which are partially bent around the frame and contacted frictionally;

Fig. 10 is an exploded view of the cell shown in Fig. 9;

Figure 11 is a view of a cell block of individual cells, wherein the tie rod has not been shown;

Fig. 12 is a sectional view of the cell block shown in Fig. 11;

13 shows the view of a cell according to the invention according to another

Embodiment in which the arresters led out parallel to the weld of the film and are contacted non-positively;

Fig. 14 is an exploded view of the cell shown in Fig. 13;

Fig. 15 is a further exploded view of this cell;

16 shows various sectional views through a galvanic cell according to an embodiment of the invention and a Schnittführungsskizze. 17 is a sectional view through a cell according to an embodiment of the invention with an enlargement of the frame area;

FIG. 18 shows a cell block made of cells according to FIG. 13; FIG.

19 is a sectional diagram for explaining the cutting guide in the production of the section shown in FIG. 20 and another

Cutting guide to explain the cutting guide in the production of the cuts shown in Fig. 16.

20 shows a sectional view through the cell block shown in FIG. 18 and FIG

21 shows an enlarged detail of the representation in FIG. 20.

The invention is based on a galvanic cell, which consists essentially of an electrode stack with a foil-like packaging, from which at least two arresters are led out. Such a galvanic cell is stabilized according to the invention by a frame which is designed so that it can be firmly connected to the packaging of the cell in the manufacture of the cell. With an appropriate embodiment of some embodiments of the invention, there is the advantage that the galvanic cells are stabilized not only when installed in a battery by a connection then to be produced with a frame or a frame, but that the cell before installation in a cell block by the frame according to the invention is stabilized. The inventive method, according to which the frame is already connected when closing the package with the cell has the further advantage that the cell already in the further manufacturing process, ie in their filling, in the formation, the aging ("aging") or the so-called "Grading" is already protected against mechanical influences. Depending on the intended use, in particular cohesive processes such as, for example, bonding or similar processes are suitable for producing the frame connection of the cell according to the invention. Preferably, the frame can also be connected by a hot pressing or heat sealing, which is preferably carried out by partial melting of a thermoplastic layer located between the joining partners with subsequent cooling under pressure, with the packaging film, which is often already provided with a corresponding coating suitable for this purpose ,

The term heat sealing is understood to mean a process for joining thermoplastic melt layers of packaging materials (eg.

Composite films), preferably by hot pressing. Heat sealing is an important method of welding films in packaging technology. Essentially one differentiates between the following two variants:

a) sealing with heating rod or heating ruler between sealing jaws, also referred to as contact seals, and

b) impulse sealing.

In the first variant, a preferably movable sealing jaw carries a heated rod. A preferably fixed lower sealing jaw is often equipped with a surface of elastic material to compensate for unevenness in the sealed seam. Sealing elements of this type are used in many commercially available machines for the production and closing of bags and in form, fill and seal machines.

In the case of very long sealing seams, the heating rods often have to be worked extremely accurately and without any deviation in order to ensure uniform pressure over the entire sealing surface. To achieve clean sealing seams, the films are often before using the sealing tool with the help of Stretching devices laid flat. Another possibility is the use of heating rods with saw-like sealing surface, but then there is a risk of hole formation.

For the resilient surface of the fixed, cold sealing jaw, silicone rubber has proven itself. Often you give this back pressure bar a slightly curved shape. During the sealing process, a pressure is initially built up in the middle of the sealing seam, which pressure spreads to the edges when the tool closes. So an optimal sealing seam is to be produced. In addition, small liquid droplets are to be pushed out of the sealing area, which would destroy the seal by the formation of water vapor.

In impulse sealing, the temperature of the sealing bars is maintained for a rather brief moment rather than the entire sealing cycle. The necessary heat is generated by two small resistance elements on both sealing jaws.

Once the sealing tool is closed over the film to be sealed, the welding is performed by a short burst. Compared to the hot-dip sticks, the time of exposure to heat is shorter and the excess heat is dissipated immediately. The sealing surface of the tool may still be covered by a thin, insulating film of heat-resistant material to prevent sticking of the sealed material.

Due to the fact that the packaging film is connected to the frame over a large area, it is possible to largely avoid mechanical stress peaks which otherwise could easily occur when the construction is loaded. The connection to the frame can be made on the inside of the packaging film, which is often coated with polypropylene. Fig. 5 shows such a connection of the frame with the inside of the packaging film. According to another embodiment of the invention, it is also possible to connect the frame to the outside of the packaging, which is often coated with polyamide. Such an embodiment of the invention is shown in FIG.

Furthermore, it is advantageous to control the occlusion of the cell, i. make the connection of the two parts of the packaging film and the connection to the frame in one step.

In order to simplify the construction of a cell block from galvanic cells according to the invention, it is advantageous and therefore preferable to use the frame with corresponding shaping elements, such as e.g. Noses or depressions to be provided which are arranged on, for example, two sides of the frame so that the corresponding mold elements can fit into each other and thus support the assembly of the cell block by promoting the proper alignment of the cells.

The frames of the invention may be provided at suitable locations preferably with holes or other openings, can be introduced through the tie rods that hold the cell block together.

Figures 1 to 4 show a preferred embodiment of the invention, in which the frame is preferably made of plastic and connected to the inside of the packaging film via a hot pressing. The connected to the frame half of the packaging film is in this embodiment over the other half circumferentially over, as shown in Fig. 5.

Fig. 1 shows a three-dimensional view of a cell according to this embodiment with an integrated frame 102, with the

Packaging of the cell 103 is connected. Out of the packaging they protrude Arrester 101 of the cell. Fig. 2 shows the same cell from the other side. Similarly, reference numerals 201, 202 and 203 designate the trap, the frame and the package of the cell. An exploded view of this cell with an integrated frame is shown in FIG. 3. The cell stack 301, to which the cell head is electrically connected with its two electrode bundles 304, 305, and to which the arresters 302, 303 are attached, is entrained by a packaging film from both sides Closed parts 306 and 307, which is mechanically stabilized by a frame 308. A corresponding exploded view from the other side is shown in FIG. 4. Here, too, the electrode stack 401 with the electrode bundles 404, 405 and the arresters 402, 403 attached thereto are enveloped and enclosed by the two parts 406, 407 of the film package and stabilized by the frame 408 ,

The basic structure of a typical packaging film for galvanic cells is shown in FIG. 7. An aluminum foil 702 is coated on one side with a polyamide 701 and on the other side with a polypropylene 703. Other films with other materials, layers or coatings are of course possible.

A preferred embodiment of a cell block of integrated frame galvanic cells according to the present invention is shown in Fig. 8. A complete cell block 801 is constructed by adding a cell block 802 under construction to further cells, e.g. the cell with frame provided with the reference numeral 803 is added. The cell 803 consists of the actual cell 804 with arresters 805, 806 which is frictionally connected to a frame 807. To stabilize the entire cell block, tie rods 808, 809, 810 and 811 are passed through corresponding holes in the frame.

If the frames are designed to be provided with structures such as tabs or grooves that provide centering or alignment of the cells facilitate, then the passage of the tie rods through the holes is greatly facilitated. In this embodiment, the arresters are weight-saving wrapped around the frame or bent around, whereby a solid contact strip is unnecessary.

Fig. 9 shows a detailed illustration of such a cell with arresters wrapped around the frames. The cell 901 has an arrester 904 wrapped around the frame 902. The frame is provided with a hole 903 for the passage of tie rods. Fig. 10 shows the same cell in an exploded view. Unlike shown in the figure, the arrester 1004 is bent around the frame only after attaching the frame 1002. Fig. 11 shows a cell block of galvanic cells of this embodiment.

Fig. 12 is a sectional view of the cell block shown in Fig. 11; Attached to the cell head 1202 of a cell 1201 is an arrestor 1204, which is bent around the frame 1205 and electrically contacted with an arrester of the adjacent cell. The opposite arrester of the cell 1201 is not bent around the frame 1205 and therefore electrically insulated from the adjacent cell arrester 1206, which in turn electrically contacts a surge arrester of the next adjacent cell. In this way, it is possible to achieve a proper electrical shading of the arrester during cell block construction practically without further aids.

Still less space requires an embodiment of the invention shown in FIG. The arresters 1304 of the cell 1301 are led out of the packaging parallel to the weld and contacted non-positively. The frame 1302 has a bore 1303 for the passage of a tie rod. An exploded view of this embodiment is shown in FIG. 14. The packaging of the cell 1401 has at its corners special surfaces 1405 suitable for hot pressing with the frame 1402. The arresters 1404 of the cell are in this case placed so that a proper contacting takes place automatically. The packaging corners of the cell can further with holes 1406 be provided for performing a tie rod, which are placed congruent with corresponding openings 1403 in the frame 1402. An exploded view of this embodiment, Fig. 15. The electrode stack 1501 with deflectors 1502, 1503 is between an upper part 1506 of the package, a frame 1508 and a lower part 1507 of

Packaging included. Upper part and lower part of the packaging are equipped with mold elements shown in Fig. 15, which support an automatic intended contact with the arrester.

FIG. 16 shows three different cutting guides 16a, 16b and 16c through a galvanic cell shown in the lower part of FIG. 16a shows the section along the line 1907, FIG. 16b shows the section along the line 1906, and FIG. 16c shows the section along the line 1905. FIG. 16a shows the cell stack 1601 the cell heads 1602 and 1603, Fig. 16b shows the aperture 1605 through the frame 1604, and Fig. 16c shows the section through the cell perpendicular to Fig. 16a.

Fig. 17 shows an enlarged sectional view of the frame portion of this embodiment of the invention. Shown are the frame 1704 which is connected to both parts of the packaging film 702, 703 of the cell 701. Fig. 18 shows a cell stack of cells according to this embodiment of the invention. Fig. 20 shows a section through the cell block with the cut shown in the upper part of Fig. 19. FIG. 19 shows an enlargement of a section from this sectional view, in which it can be seen more clearly than in FIG. 20 that in this embodiment of the invention the space is used somewhat more efficiently. By recognizable in the upper part of Fig. 21 specific design of the arrester 2107, which electrically contacts the arrester 2108 of the adjacent cell, a nearly column-free structure of the cell block is made possible. Visible are the cell stack 2104, the underside of the package 2105, the top of the package 2106, the frame 2101 and 2103 with the opening 2102.

Claims

Patent claims

1. Frame for a galvanic cell, which consists essentially of an electrode stack with a foil-like packaging, are led out of the at least two arresters, characterized in that the frame is designed so that it with the packaging of the

Cell can be firmly connected in the production of the cell.

2. Frame according to claim 1, which is designed such that it can be materially connected to the packaging of the cell in the manufacture of the cell.

3. Frame according to claim 2, which is designed so that it with the

Packaging of the cell in the production of the cell - without the addition of additional substances - can be materially connected by a heat sealing process.

A frame according to any one of the preceding claims, having structures which assist flush alignment of cells provided with this frame in building a cell block.

5. Frame according to one of the preceding claims with openings for the implementation of tie rods in the construction of a cell block.

6. Galvanische cell with a frame according to one of claims 1 to 5.

7. A method for producing a galvanic cell, wherein a

Electrode stack in a foil-like packaging from which at least two arresters are led out is enclosed, characterized characterized in that when closing the packaging, a frame is firmly connected to the packaging.

8. The method of claim 7, wherein the frame is integrally connected to the packaging.

9. The method of claim 8, wherein the frame with the packaging of the cell in the manufacture of the cell - without the addition of additional substances - is materially connected by a heat sealing process.

10. A method for constructing a block of a plurality of galvanic cells with a frame according to claim 4, wherein the cells are aligned by means of structures of the frame flush.

11. A method for constructing a block of a plurality of galvanic cells with a frame according to claim 5, wherein the block is stabilized by means of tie rods, which are passed through openings in the frame of the cells.

12. A method for constructing a block of a plurality of galvanic cells with the features of claims 10 and 11.