Foil for forming packaging parts and housing parts

EP4761908A1Pending Publication Date: 2026-06-24PROFOL KUNSTE

Patent Information

Authority / Receiving Office
EP · EP
Patent Type
Applications
Current Assignee / Owner
PROFOL KUNSTE
Filing Date
2024-08-16
Publication Date
2026-06-24

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Abstract

A foil for forming packaging units or housing units, comprising: a coupling layer designed to bond to a metal foil; a core layer having a layer thickness that is greater than at least half the foil thickness, and a sealing layer designed to be in permanent contact with an electrolyte.
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Description

[0001] FILM FOR FORMING PACKAGING AND HOUSING ELEMENTS

[0002] Technical area

[0003] The present invention relates to a film for forming packaging and housing elements. In particular, the present invention relates to a film which, together with a diffusion barrier, can form a reliably sealed packaging or housing element for an electrolyte-containing substance or an electrolyte-containing assembly.

[0004] Technological background

[0005] Electrolyte-containing substances and assemblies are used in a wide variety of applications in the electrical, automotive, and chemical industries. Electrolyte-containing substances are packaged for further processing or form corresponding assemblies in the form of electronic components such as batteries. The latter, in particular, are the subject of intensive development in the context of electronic consumer goods, electromobility, and the stationary storage of electrical energy.

[0006] Packaging and housings for such electrolyte-containing substances or assemblies must have certain properties which ensure that the substances and assemblies are securely contained. The function of a diffusion barrier which effectively prevents the escape and loss of electrolytic components plays a particularly important role in this. Metal foils are normally used for this purpose and generally provide a satisfactory diffusion barrier. Metal foils can also be easily formed into packaging or housing parts because they either retain a shape obtained by press forming or can be left flexible and formable anyway. In this way, containers for packaging, such as bottles or bags, or even housings for permanent containment can be reliably provided.

[0007] Although metal foils generally provide a good diffusion barrier and are readily formable, they have certain disadvantages with regard to sealing. It is clear that both the packaging and housings in question must ensure reliable containment of the substances or assemblies. This often presents the challenge of reliably bonding and sealing metal surfaces at the seams to ensure the containment of the electrolyte. Metals can generally be welded or soldered well, but this involves high heat input and energy consumption.

[0008] Therefore, there is a need for a reliable bond of diffusion barriers for producing packaging or housing elements that reliably enclose an electrolyte, an electrolyte-containing substance, or a corresponding assembly. In particular, it is therefore an object of the present invention to provide a film for forming packaging or housing units that ensures reliable enclosing of electrolytes and achieves an overall positive balance of advantages with regard to processing, weight, and energy consumption.

[0009] Summary of the invention

[0010] The above-mentioned and further advantages are provided by the film according to claim 1. Further advantageous embodiments of the present invention are specified in the dependent claims.

[0011] According to one aspect of the present invention, a film is provided for forming packaging or housing units, comprising a coupling layer designed to bond to a metal foil; a core layer having a layer thickness which is at least greater than half the film thickness; and a sealing layer designed to be in permanent contact with an electrolyte.

[0012] Brief summary of the drawings

[0013] Embodiments of the present invention will now be described in more detail with reference to the following figures. The corresponding illustration serves merely to better understand the teaching of the invention and the associated advantages, but should not be construed as limiting in any way. They show:

[0014] Figure 1 schematically shows the basic structure of a film according to an embodiment of the present invention;

[0015] Figure 2 schematically shows the basic structure of a packaging or housing precursor with a film according to an embodiment of the present invention;

[0016] Figures 3A to 3E schematically show possible forms of

[0017] Packaging or housing elements made of a film according to an embodiment of the present invention; and

[0018] Figures 4A & 4B schematically show possible applications of a

[0019] Film according to an embodiment of the present invention. Detailed description

[0020] Figure 1 shows schematically the basic structure of a film according to one embodiment of the present invention. A film 10 is used to form packaging or housing units, in particular for enclosing an electrolyte, a substance containing an electrolyte or an assembly containing an electrolyte. These applications as well as the shapes of the corresponding packaging and housings are described in more detail in connection with further embodiments. The film 10 can preferably be the product of a coextrusion, in which the materials of the individual layers are brought together in a molten state in order to solidify as film 10 at the extrusion nozzle or outlet. In this way, the respective layer properties and layer thicknesses (thickness) can be provided by corresponding precursors and their quantity rates.Overall, the film 10 can be provided as a cast film, in particular a cast polypropylene (CPP) film, insofar as polypropylene or other polyolefin-based plastics are used.

[0021] The film 10 has a coupling layer 101 which is designed to bond to a metal foil. Optionally, an adhesion promoter can be used to bond the coupling layer 101, so that the properties of the coupling layer 101 are tailored either to a direct bond to a metal foil or to a bond to the metal foil via an adhesion promoter. Such an adhesion promoter can be provided by adding an adhesion promoter additive to the coupling layer, e.g. during extrusion. Furthermore, an adhesion promoter can also be provided via a (separate) adhesive system or an adhesive (glue). In the latter case, the adhesion promoter, e.g. in the form of an adhesive system, can at least co-determine the properties of the coupling layer indirectly via the metal foil. This coupling layer 101 can in itself be made of a polyolefin-based plastic, such as e.g. made of or at least contain polypropylene.The coupling layer 101 can be corona pretreated in order to bond well to a metal foil or metal layer in a later manufacturing step, if necessary by means of an adhesion promoter (e.g. adhesive system).

[0022] aluminum) , to bind . (e.g. with a) .

[0023] The coupling layer 101 can preferably have a corona pretreatment. With such a corona pretreatment, the surface tension of the coupling layer can be increased compared to a layer without corresponding pretreatment. For example, the surface tension can be increased to values ​​>30 mN / m (dyn), preferably >38 mN / m (dyn). The surface tension can be measured using a dyn test ink pen or by contact angle measurement, and is therefore a feature of the corresponding embodiments. The corona pretreatment can advantageously improve the bonding of the coupling layer to the metal foil, particularly when using the optional adhesion promoter or adhesive. Otherwise, the coupling layer 101 can bond directly to the metal foil by thermal lamination. The coupling layer 101 can have a layer thickness in a range from 4 μm to 20 μm, or preferably in a range from 5% to 20% of the thickness of the foil 10.

[0024] The film 10 further comprises a core layer 102, which contributes in particular to achieving the desired elasticity, toughness and / or penetration strength of the overall structure of the film 10 and / or the packaging or housing element. For this reason, among others, the core layer 102 has a layer thickness dKE that is at least greater than half the film thickness d, and is preferably even substantially equal to or greater than 70% of the film thickness d. The core layer 102 can have a layer thickness in a range from 20 pm to 200 pm.

[0025] The film 10 further comprises a sealing layer 103 which is designed to be in permanent contact with an electrolyte. The sealing layer can also be easily sealed with another sealing layer, for example with an area of ​​the same sealing layer of the same film at another location, in order to provide a reliable seal. The sealing can be effected by heat-induced thermal welding or ultrasonic welding. The sealing layer is characterised by the formation of a sealing seam with high strength. Furthermore, the sealing layer is characterised in that it has an early sealing point, i.e. it seals even at relatively low temperatures, preferably at temperatures above 100°C.For this purpose, special PP polymer types can be used that have been modified during production to achieve a sealing point lower than that of normal, unmodified PP, thus providing a highly resilient seal seam. The sealing layer can also be characterized by the fact that sealing functions even when the sealing surface is wetted with electrolytes without any significant change in sealing ability.

[0026] Examples of such electrolytes include lithium phosphates, such as lithium hexafluorophosphate, which are dissolved in ethylene carbonate, dimethyl carbonate and / or diethyl carbonate. A property that is advantageous for resistance to permanent contact with an electrolyte can be the chemical resistance and the migration behavior of the electrolyte solution through the film 101. Otherwise, migration of electrolyte solution through the film can attack or decompose the adhesion of the metal foil. This can lead to delamination, which the embodiments of the present invention effectively prevent, however. The desired resistance can be achieved, for example, through the use of cast polypropylene, cast PP. The sealing layer 103 can have a layer thickness in a range from 2 μm to 20 μm, or preferably in a range from 5% to 20% of the thickness of the film 10.

[0027] From the layer thicknesses already mentioned above, a total layer thickness d of the film 10 results depending on the application. For example, for an application in mobile devices, the thickness of the film can be 30 to 50 pm or, for example, 40 pm. For high-voltage batteries in the automotive industry, the film thickness can be in a range from 70 pm to 90 pm, preferably about 80 pm. In the event that aluminum is selected as the metal, the film 10 can then be referred to as aluminum laminating film, ALF for short, which is preferably a three-layer

[0028] Coextrusion film made of CPP is provided for lamination.

[0029] Figure 2 shows schematically the basic structure of a packaging or housing precursor with a film according to one embodiment of the present invention. Shown in particular is a likewise film-like or plate-like semi-finished product 20 which comprises a film 10 for forming packaging or housing units, as described elsewhere in the present disclosure. The semi-finished product further comprises a metal layer 200 in the form of a metal foil, a metal plate or a sheet. Advantageously, the metal layer is an aluminum foil with a material thickness in the range from 10 to 100 pm or 30 to 50 pm.

[0030] The semi-finished product 20 is connected to the film 10 with an adhesive 210, preferably a laminate adhesive, a two-component adhesive, or a polyurethane (PU) adhesive. In an advantageous embodiment, the film 10 is first corona pre-treated, which improves the bond to the metal layer 200 via the adhesive 210. Furthermore, an outer protective layer 300 is arranged on the metal layer 200, which consists, for example, of polyamide (PA) and / or polyethylene terephthalate (PET) or at least contains it. The protective layer 300 can be bonded to the metal layer 200 with a further adhesive 320. The protective layer 300 can have a material thickness in the range of 10 to 30 pm or 15 to 20 pm. A typical layer thickness for the overall composite 20 can then be, for example, approx. 140 pm .In the case of aluminum as a metal layer, this can then be laminated on one side with a co-extrusion film mentioned above and a polyamide film in a composite of at least 3 layers using adhesive systems (e.g. co-extruded PP - aluminum - PA - PET).

[0031] Figures 3A to 3E schematically show possible shapes of packaging or housing elements made from a film according to an embodiment of the present invention. In Fig. 3A, a simple pocket shape 910 is shown, for which a semi-finished product 20 in a rectangular shape was folded over along a fold 911 and welded on the other sides in regions 912. Advantageously, the sealing layers 103 of the semi-finished product 20 meet at each of these points, which provide reliable enclosure of the volume V by welding (here in the inset the sealing layers 103 of the semi-finished products 20A and 20B fuse in a region 103A / B). One or more accesses 914 can be incorporated into the welded regions 912, which provide access to the inner volume V and thus, for example. provide an electrical contact in the case of a battery casing or a closure in the case of packaging.In the right area, a sectional view of the pocket shape 910 with the volume V along the axis 913 is shown.

[0032] In Figures 3B & 3C further pocket shapes are shown, which essentially have a rectangular basic shape as in the case of pocket 920 (Fig. 3B) or else any desired shape as in the case of pocket 920' (Fig. 3C). By means of a film according to the invention and a corresponding semi-finished product, pockets of almost any shape can be obtained by welding the corresponding edge region 922, 932, wherein again the respective sealing layers lie on top of one another and can be welded. In these shapes too, one or more accesses 914 can be provided, the respective position of which can advantageously be set at the most favorable point for the application, since the pocket structure with the film or semi-finished product according to the invention creates great flexibility here. Schematically, in both cases the cross-sectional view 920 / 920' results with the volume V therein.

[0033] Figure 3D shows a cylindrical shape 940 which results from a simple winding of a semi-finished product 20. In this way, pockets in a cylindrical or cup shape can also be produced via at least one welded region 941. Figure 3E shows a pocket 950 in a prismatic shape which results from a combination of one or more folds and one or more welded regions 951 (and optionally 952, 953). Figure 4A schematically shows a possible application of a film according to an embodiment of the present invention. In this application, a battery 980 is provided which is, for example, a rechargeable battery, a lithium-ion battery, a lithium-polymer battery, a solid-state battery or the like. An electrolyte-containing assembly comprises an electrode structure 981 and an electrolyte 983, wherein the inner sealing layer 103 of the semi-finished product 20 is in contact with the electrolyte 983 (see inset).In pouch-type batteries, so-called "pouch cells," several rectangular layers of negative and positive electrodes and conductive foils are typically stacked with corresponding layers of separators, like a sandwich. The electrodes are usually discharged to one side. The outer casing and sealing is made of deep-drawn, welded plastic-aluminum-plastic.

[0034] Multilayer films.

[0035] The housing comprises a pocket made of a film 10 or semi-finished product 20 according to the invention, which is obtained by welding at least one area 987. With regard to the shape of the battery housing, the greatest possible flexibility can be achieved and a corresponding battery, for example a so-called pocket or pouch cell (or "pouch cell"), can be provided in an advantageous manner. In one of the welded areas 987, an access in the form of a contact 984 can be provided, which electrically insulates a battery contact 985 from the inner volume V and from the assembly.

[0036] a pouch battery foil structure "CPP film - aluminum foil - PA foil" can be stamped or press-formed into a (usually) rectangular cavity shape, with two of these shapes sealed together by thermal or ultrasonic welding to form the housing for the battery assembly (coil and electrolyte). After sealing (welding), the sealing layer remains permanently and reliably on the aluminum foil laminated by the adhesive system. Even in the event of damage or at the end of the service life, a residual film should remain on the metal layer, e.g. the aluminum foil, upon delamination or tearing / separation of the seal seam. It should be mentioned at this point that "permanent" in the context of the present disclosure generally refers to at least the duration of a planned service life or usage time of the corresponding product (packaging, housing, battery, etc.) Even in the worst case scenario of delamination, the embodiments of the present invention still offer the significant advantage that a residual layer, e.g. made of PP, remains on the metal foil in the form of a thin protective layer.

[0037] This is achieved in particular by the composite structure of the semi-finished product. Under maximum load, the composite within the film breaks, i.e. the coupling layer detaches from the core layer and / or the core layer detaches from the (welded) sealing layer and the metal foil remains protected from contact with the electrolyte by the film residue. In any case, a residual layer of the film remains on the aluminum, for example, and it can advantageously be avoided that the electrolyte solution comes into contact with the aluminum foil. Delamination can also be demonstrated by the so-called stress whitening indicator, in which, for example, a PP layer remains on the aluminum foil.

[0038] Figure 4B schematically shows a possible application of a film according to an embodiment of the present invention. In this application, a package 990 in the exemplary form of a stand-up pouch is provided. For this purpose, a semi-finished product is produced by means of a combination of one or more folds 991 and one or more welded areas 992. In one of the welded areas, an access in the form of a closure 993 can be provided, which enables filling and / or emptying of the package. By using a film 10 or semi-finished product 20 according to the invention, a reliable product packaging can be obtained which also reliably encloses electrolyte-containing substances.

Claims

Claims:

1. A film for forming packaging or housing units, comprising: a coupling layer configured to bond to a metal foil; a core layer having a layer thickness at least greater than half the film thickness; and a sealing layer configured to be in permanent contact with an electrolyte.

2. The film of claim 1, wherein the coupling layer is designed to bond to a metal foil by having a corona pretreatment which promotes bonding to the metal foil via an adhesion promoter.

3. A film according to claim 2, wherein the adhesion promoter comprises an adhesive or an adhesive system.

4. The film of claim 1, wherein the coupling layer is configured to bond to a metal foil by comprising an adhesion promoter additive that promotes bonding to the metal foil.

5. A film according to claim 4, wherein the coupling layer bonds directly to the metal foil by means of the adhesion promoter additive.

6. Film according to one of claims 1 to 5, wherein the sealing layer forms a welded or sealed connection even when previously wetted by an electrolyte.

7. Film according to one of claims 1 to 6, wherein the coupling layer, core layer and sealing layer are present in a co-extruded structure.

8. Film according to one of claims 1 to 7, wherein the coupling layer, the core layer and / or the sealing layer comprises / comprising a polyolefin-based plastic.

9. A film according to claim 8, wherein the polyolefin-based plastic is a cast polypropylene, cast PP.

10. Semi-finished product for forming packaging or housing units comprising a film according to one of claims 1 to 9 and a metal foil bonded to the coupling layer.

11. Semi-finished product according to claim 10, wherein the metal foil is an aluminum foil.