WO2016193447A1 - Method for flanging of an at least two-layer material - Google Patents

Abstract

The present invention relates to a method for flanging of an at least two-layer material (1, 2; 301, 302, 306, 307) with at least one metal film layer and an additional layer, comprising the steps of: defining an inner peripheral edge portion (8) of the at least two-layer material (1, 2; 301, 302, 306, 307), which is spaced apart from a circumferential limiting edge of the at least two-layer material (1, 2; 301, 302, 306, 307) via an outer peripheral edge portion (9); displacing the fixed inner peripheral edge portion (8) and an folding element (14) relative to each other in order to angle the outer peripheral edge portion (9) against the inner peripheral edge portion (8) such that the inner peripheral edge portion (8) and the outer peripheral edge portion (9) form an angle of about 90° or less between them; and folding over the outer peripheral edge portion (9) against the inner peripheral edge portion (8) by means of a flanging element (17, 18, 21), so that the two portions (8, 9) bear substantially at least in sections against one another. According to the inventive method, a simplified method for flanging of an at least two-layer material is specified. According to further secondary aspects of the invention, a method for producing a pocket for a pouch battery and a method for producing a temperature control unit are specified. Furthermore, a pouch battery comprising a bag made of an at least two-layer material as well as a temperature control unit made of an at least two-layer material (1, 2; 301, 302, 306, 307) with at least one metal film layer and an additional layer are specified.

Description

 Method for beading at least two-day material

The present invention relates to a method for flanging an at least two-ply material with at least one metal foil layer and an additional layer. In particular, a cell pocket of a pouch cell or a temperature control unit is produced with this method.

From EP 2 492 989 B1 a pouch cell with a cell bag is known. The cell bag of the known Pouch cell is made of two plastic film sections, which are folded over at their overlapping peripheral edge portions and applied against the bag body. For sealing, the bent-over peripheral edge portions of the two plastic film sections are sealed by means of adhesive tapes. The process for producing the pouch cell known from EP 2 492 989 B1 is complicated and complicated.

Starting from the problem described above, it is an object of the present invention to provide a simplified method for beading an at least two-ply material.

The problem described above is solved in the present invention by a method according to claim 1.

An at least two-layered material with at least one metal foil layer, in particular aluminum foil layer and a further layer is crimped with the method described below, so that at least the two layers are at least partially crimped together. Individual steps when folding or folding sections can also be called folding.

Overall, the at least two-ply material is crimped, so that at least one layer, in particular the metal foil layer, is folded over in such a way that it mechanically surrounds the other layer at least partially. Basically, it may be sufficient for flanging that only one of the layers is crimped with its outer peripheral edge portion toward its inner peripheral edge portion, wherein the other layer itself is not folded, but extends virtually only over the inner peripheral edge portion of a layer so that you frontal end without Umfalzen edged and crimped. This ultimately depends on from ab whether the peripheral edge portions of both layers before forming have the same length when they lie on each other. The arrangement of the two layers in the region of the peripheral edge sections to each other, this ultimately leads to effective flanging.

The method according to the invention contains at least the three method steps described below.

In a first method step, an inner peripheral edge portion of the at least two-ply material is determined. This inner peripheral edge portion is spaced from an outer circumferential edge portion of the at least two-ply material from a peripheral boundary edge of the at least two-ply material.

In a further method step following this first method step, the outer peripheral edge section is folded over relative to the fixed inner peripheral edge section, so that a crease line is formed between the inner peripheral edge section and the outer peripheral edge section. For this buckling of the outer peripheral edge portion of the at least two-ply material, the fixed, inner peripheral edge portion and a Umknickelement be moved relative to each other. At this time, the buckling element preferably slides past the outer peripheral edge portion so as to be folded over from the inner peripheral edge portion such that an angle of about 90 ° or less is included between the inner peripheral edge portion and the outer peripheral edge portion.

Preferably, the outer peripheral edge portion forms a kind of folded tab, opposite the inner peripheral edge portion, which projects from the inner peripheral edge portion substantially obliquely or perpendicularly, so that an angle of about 90 ° or less is formed between the tab and the inner peripheral edge portion.

Following the above-described folding step, in a further flanging step carried out separately from the folding step, the outer peripheral edge section is folded over against the inner peripheral edge section, so that the two sections abut against each other substantially at least in sections.

For crimping a crimping element is used, which is provided in addition to the Umknickelement on the corresponding device for performing this method. However, this embodiment does not exclude that these two elements could be combined in a single flanging unit. According to an advantageous development according to claim 2, the crimping element has at least one Umlegeoberflächenbereich which is at least partially aligned obliquely with respect to the fixed inner peripheral edge portion. This at least partially oblique orientation of the Umlegeoberflächenbereiches allowed following the buckling step a simple flanging. Namely, when the outer peripheral edge portion is oriented approximately perpendicular to the inner peripheral edge portion or the two portions enclose an angle of less than 90 ° therebetween, this inclined surface allows the turnup surface area of the flanging member to be perpendicular to the fixed inner peripheral edge portion of the at least two-ply material is supplied at the crimping on the at least two-layer material, that the one end of the outer peripheral edge portion is supplied with the peripheral boundary edge on the inner peripheral edge portion. Thus, the two sections, which are separated from each other by the seaming edge, are laid substantially flat against each other.

According to an advantageous development of the invention according to claim 3, the method includes at least one sealing step for at least partially sealing together at least one of the peripheral edge portions. Such a sealing of the at least two-ply material in the circumferential boundary edge region can be achieved in particular by means of a known welding process, by means of high frequency, ultrasound, laser or by means of a hot stamp. Other sealing methods such as heating by infrared radiation are also conceivable. By means of the sealing step, at least the peripheral boundary edge of the multilayer material is sealed in such a way that, in particular, no liquid can escape at the edge or sufficient closure is achieved. As a variant, it may be advantageous if a gas-tight seal is made.

According to an advantageous embodiment according to claim 4, the sealing step is performed before the buckling step, in particular after setting the inner peripheral portion. Alternatively or additionally, the sealing step can be carried out only after the crimping step. When sealing before the buckling step, on the one hand only the inner peripheral edge portion or the outer peripheral edge portion can be sealed, or on the other hand, the entire edge region of inner and outer peripheral edge portion are sealed. Insofar as the sealing step is carried out during or after the flanging step, sealing of the entire folding area, in particular also a sealing of the abutting surfaces of the inner circumferential edge section and of the outer peripheral edge section, is advantageous. According to an advantageous embodiment of the invention according to claim 5, the additional layer may be a metal foil or a plastic film. The use of an at least two-ply material made of metal and plastic film improves the barrier properties.

As far as the additional layer is formed from a plastic film, this can be laminated with the metal foil of the first layer or even loosely rest on this. As the plastic film, any plastic can be used, in particular PE (polyethylene), LDPE (low density polyethylene), HDPE (high density polyethylene), EVOH (ethylene-vinyl alcohol).

The plastic film used can also be constructed in multiple layers with film composites. An example of this would be: one layer of LDPE (Low Density Polyethylene) or HDPE (High Density Polyethylene), another layer of EVOH (Ethylene Vinyl Alcohol) and / or another layer of LDPE (Low Density Polyethylene) or HDPE (High Density Polyethylene). Between the individual layers may be a bonding agent.

Alternatively, in the simplest case, the at least two-ply material can be produced from a single sheet of metal foil, which is subdivided into two metal foil sections via a further fold line, which metal foil sections lie against one another at least in sections.

According to an advantageous development of the invention according to claim 6, the at least two-ply material may include at least two metal foil layers and at least two plastic film layers, wherein the two plastic film layers face each other and have between them a receiving space and / or a flow. The two metal foil layers take up the two plastic film layers between them. At least the two metal foil layers are crimped together. This can be done with the interposition of the plastic film. Alternatively, the metal foil layers can be crimped without interposition of the plastic film. The plastic film is used as an additional layer to prevent, for example, the contact of a Temperiersubstrates or a liquid with the metal foil.

The at least two-layered material may, however, contain one or more further layers of metal foil, in particular aluminum foil and / or plastic foil and / or fiber composite material. Insofar as a fiber composite material is used, it may contain glass fibers and / or carbon fibers and / or aramid fibers and / or basalt fibers. Other, commonly used fiber materials may be provided in the fiber composite material. For example, hemp is conceivable as natural fibers. Usually these fiber materials embedded in a matrix. The matrix can advantageously be PEEK (polyetheretherketone), PP (polypropylene), PA 6 (polyamide 6), PA 6.6 (polyamide 6.6), ABS (acrylonitrile-butadiene-styrene), PVC (polyvinyl chloride), PC (polycarbonate) or a Be mixture of these substances.

There may also be provided further amplifiers, e.g. GF glass fiber, GK, glass balls.

According to a side-by-side aspect, according to claim 7, the invention proposes a method for producing a bag, a so-called pouch cell. A pouch cell or battery is also called a coffee bag battery or cell. The terms battery and cell are used synonymously. The housing of the pouch cell is not necessarily rigid, but it may be a bag made of a sheet material, in which the actual cell is laminated. Often, the cell bag is completely sealed, so that only supply leads to the anode or cathode of sealed in the pocket battery.

In the inventive method according to claim 7, a cell bag is formed from the at least two-ply material. The cell pocket has opposing pocket walls which are interconnected by opposing flanges. The two flanges of the respective opposing cell pockets form the peripheral edge portion of the at least two-ply material. Thus, the cell bag can be seen as at least two-ply material with a receiving space for the cell. The opposing flanges are crimped by the previously described method.

The battery / cell inserted in such a cell bag may be a lithium ion battery made of a stack of different layers. Alternatively, besides such accumulators, i. rechargeable cells, even cells conceivable, which are not rechargeable.

According to a further independent aspect of the invention according to claim 8, a temperature control unit is produced by the method according to the invention. Such a temperature control unit may be a cooling unit and / or a heating unit. Accordingly, either heat is released to the temperature control medium, or absorbed by this.

Such a tempering unit contains the at least two-ply material with at least one metal foil layer and an additional layer. In the at least two-layered material, a tempering flow is formed, through which temperature control medium can flow from an inlet opening to an outlet opening through the tempering unit. Of the Temperiermediumsdurchfluss thus connects a provided on the temperature control unit inlet and outlet. The peripheral edge sections of the temperature control unit are crimped by means of the method according to the invention described above. In particular, the sealing of the tempering medium flow or the sealing of the entire tempering unit can be improved. The Temperiermediumsdurchfluss which is formed between at least two layers may have different geometries. It is also possible to form a plurality of such tempering flows in the tempering unit. In order to give the Temperierdurchfluss a corresponding geometry or a flow pattern, the opposing material layers of the at least two-ply material are at least sealed together so that a pattern is formed with the corresponding Temperiermediumsdurchflussgeometrie.

According to a device-related aspect of the invention according to claim 9, a pouch cell is proposed with a cell pocket made of the at least two-layered material described above. The at least two layers preferably form the respective pocket walls. The cell pocket has a receiving space for a cell, wherein opposing edge portions of the pocket walls abut each other and form a flange. This flange is at least partially, but advantageously fully flanged. The curling can be carried out in particular with the method according to the invention described above.

According to a preferred embodiment according to claim 10, the respective outer side of the opposite pocket walls can be formed by a metal foil layer or by a fiber composite material layer. As far as the respective outer side of the opposite pocket walls is formed from a fiber composite material layer, this layer can also be crimped by means of the aforementioned method.

According to a preferred embodiment of claim 1 1, the respective inner side of the opposite pocket walls can be formed in each case by a plastic film. The plastic film protects the metal foil from, for example, electrolyte fluid contained in the bag.

According to a preferred embodiment according to claim 12, the pocket walls may also be formed by a double layer of metal foil and plastic film.

In particular, each of the two pocket walls may have a multi-layered structure, wherein a Temperiermediumsdurchfluss may be provided for each within this multilayer structure, similar to the temperature control unit described below. Consequently, the individual pocket walls or the entire cell pocket can also comprise the features of the temperature control unit described below.

According to a further sibling device-related aspect of the invention according to claim 13, this also relates to a tempering of an at least two-ply material with at least one metal foil layer and an additional layer. For the choice of the additional situation reference is made to the previously described. It can e.g. also be provided a composite film layer.

Between two layers of the at least two-layer material, a tempering flow is formed, which connects an inlet and an outlet of the temperature control unit with each other. The tempering unit itself is optionally beaded in such a sealing manner at its peripheral edges, by means of the method according to the invention described above, that in particular only at least one inlet or one outlet is provided in the tempering unit.

According to an advantageous embodiment of the invention according to claim 14, the temperature control unit should be dimensionally stable.

Such a dimensional stability is achieved in particular by the choice of a corresponding thickness of the metal foil layer. Advantageously, the thickness of the film between 10 and 200 μηη particular 50 to 150 μηη, most preferably 80 to 120 μηη. The aforementioned limits can also be combined with one another differently than in the previously described manner. For a dimensionally stable temperature control unit, the mold remains e.g. obtained independently after deformation. A flexible, deformable tempering unit, which is automatically deformed back into its original shape after deformation, is not dimensionally stable.

To ensure dimensional stability, alternatively or additionally, a corresponding structure such as e.g. Stiffening ribs and / or a corresponding dimensionally stable material can be used.

According to an advantageous embodiment of the invention according to claim 15, the temperature control unit is designed as a surface element, which has at least one indentation. The indentation is designed for partially receiving a heat-generating and / or heat-absorbing element. Thus, the temperature control unit can be slipped over a heat-generating and / or heat-absorbing element in some way and the heat generated in the heat-generating element or the heat absorbed by the heat-absorbing element via the inner walls of the indentation to a tempering medium flowing through the Temperiermediumsdurchfluss delivered or added. Such an indentation is a receptacle for at least a part of the heat-generating or heat-absorbing element.

Hereinafter, for the sake of simplicity, only the configuration as a cooling unit will be described, and accordingly the conceptually speed heat generating element is used.

According to a preferred embodiment according to claim 16, the interior geometry of the indentation should be substantially adapted to the surface geometry of the heat-generating element. In particular, the surface of the corresponding heat-generating element conforms close to the inner surface of the indentation of the temperature control unit (cooling unit). Optionally, a full-surface system can be made possible, so that the best possible heat transfer takes place. Depending on the design, such a direct installation can also take place only partially, that is to say be formed virtually contoured on the inner surface of the indentation of the temperature control unit, in particular with directly adjacent areas as well as slightly spaced areas.

According to a preferred embodiment of the invention according to claim 17, the Temperiermediumsdurchfluss in the region of the indentation adapted to their shape and forms there a kind of tempering. It essentially corresponds to the size of the indentation. The tempering element is connected to the inlet and the outlet of the tempering unit via a temperature-control channel provided with a substantially thinner cross-section in relation to its surface area. Each tempering can also with multiple Zuleitungsbzw. Dissipation cooling ducts may be connected to different or the same inlet or outlet. It is also possible for a plurality of tempering elements to be connected to different tempering circuits via corresponding line guides of the tempering line to one another.

According to an advantageous embodiment of claim 18 go from the at least one inlet or the at least one outlet tempering channels branched off. Thus, the inlet or the outlet is connected to a plurality of tempering channels, wherein the different tempering channels, for example, lead to different tempering elements and / or assume a different geometric course. Thus, a different tempering pattern can be generated in the multilayer material of the tempering unit by the tempering channels or tempering elements.

For example, the temperature control channels may be formed meander-shaped. An increased density of Temperierkanälen leads to increased heat removal and a reduced density leads to a reduced heat dissipation. Due to the density of the temperature control channels in the temperature control unit and / or the size of the temperature control elements, the heat dissipation can be precisely controlled. According to an advantageous embodiment according to claim 19, the temperature control unit is designed as a plate element, protruding from which at least one heat transfer projection. Accordingly, a kind of projection is formed on at least one side of the plate element. This projection is preferably integrally connected to the plate element.

According to a preferred embodiment according to claim 20, it is advantageous if the Temperiermediumsdurchfluss is at least partially guided within the projection. In particular, it is advantageous if the projection accordingly forms a cavity corresponding to its geometry, through which the temperature control medium can flow.

According to an advantageous development according to claim 21 mutually heat transfer projections should be provided on the plate member. These heat transfer projections can be brought into abutment with corresponding heat-generating elements and thus provide an increased surface for dissipating heat from the heat-generating elements. The heat transfer protrusions may be seen as an alternative or addition to the indentations.

According to an advantageous embodiment according to claim 22, the heat projections in cross section through the at least two-ply material, seen transversely to the layers, a triangular cross-section. Also conceivable are other polygonal cross sections. In principle, such heat projections can also be made modular and variable, whereby they can adapt to the particular application.

According to a further advantageous development according to claim 23, two heat transfer projections are each to be designed in such a way that a corresponding cell and / or an electronic component can be inserted between them, so that their areas of the outer walls can be brought into contact with two heat transfer projections.

According to a further advantageous embodiment of the invention according to claim 24, the temperature control unit may also be formed as a frame within which a semiconductor plate may be inserted, and which framing this semiconductor plate. Advantageously, the tempering medium flow is formed in the frame such that it passes completely through the frame, i. the inlet and the outlet are provided on the same frame spar, in particular directly adjacent to each other.

Further advantages and developments of the invention will become apparent from the following explained embodiments, in conjunction with the drawings. In this show

1 a to 1 e is a schematic representation of the various method steps of the method according to the invention,

2 is a schematic view of a so-called pouch battery, in which the opposing flanges are not yet folded with the method according to the invention,

3a to 3d a temperature control,

4a to 4d a temperature control unit with various indentations, which to the

 Geometry of different heat generating elements of a populated semiconductor plate are adapted

Fig. 5 is formed as a frame tempering unit, in which a semiconductor plate can be used and

Fig. 6a and 6b a temperature control with mutually provided

 Temperiervorsprüngen, between which batteries are fitted.

Fig. 1 a to 1 e schematically illustrates a method for beading two layers. In the present example, the two layers are formed by two abutting layers of an upper flange section 5 of an upper enveloping element 1 and a lower flange section 6 of a lower enveloping element 2, which flange sections 5, 6 form a peripheral edge section.

In the present case, the two enveloping elements 1, 2 and therefore also the two layers are each made of a single metal foil material. In particular, each of these layers can be produced as a double layer of a metal foil layer and a plastic layer by itself, or even both layers. In particular, the plastic film layers include a receiving space 10 formed by the upper enveloping element 1 and the lower enveloping element 2. The plastic film may be laminated to the inner wall of the corresponding Hüllelementes, or even loosely abut this. As far as the plastic film is laminated to the metal foil, the flange area can also be formed without interposition of the plastic film. The receiving space 10 may be a pocket of a pouch cell described later, or a tempering medium flow in a tempering unit described later. Vorzugseise contains the at least two-ply material a layer of a metal foil and a layer, which is not a metal layer. Such a layer may be a plastic layer or a fiber composite material layer.

In Fig. 1 a, the upper shell element 1 and the lower shell element 2 is inserted into a provided in a lower mold half 4 lower mold cavity 3. The lower mold half 4 has a support region 7, on which an inner peripheral edge portion 8, the two layers 1, 2 rests planar. An outer peripheral edge portion 9 protrudes beyond the support area 7 of the lower mold half 4 and is laterally from the lower mold half 4 from.

In the course of the method of FIG. 1 a according to FIG. 1 b, an upper mold half 1 1, which contains an upper mold cavity 12, placed over the housing formed from the two Hüllelementen 1, 2, so that the upper Hüllelement 1 in the upper mold cavity 12 comes to rest (see Figure 1 b). The upper mold half 1 1 has a fixing surface 13, which determines the inner peripheral edge portion 8 in cooperation with the support area 7 of the lower mold half 4. The inner peripheral edge portion is thus set between the fixing surface 13 and the support portion 7.

For this purpose, the upper mold half 12 is pressed down against the lower mold half 4, wherein the lower mold half 4 is mounted so resilient or otherwise mechanically or kraftbeaufschlagt that this, in the pressure exerted by the upper mold half 12 to this pressure, as in Fig. 1 b shown slightly pushed back. Here, the complete housing from the two enveloping elements 1, 2 together with the peripheral edge portion, shown in the figures, pressed down vertical direction and displaced against a fixed Umknickelement 14, so that the outer peripheral edge portion 9 against the inner peripheral portion 8 substantially in kinked at a 90 ° angle. Ultimately, however, the upper and lower mold halves 4, 12 may be designed to be fixed and the Umknickelement 14 may be designed as a height-displaceable element. Finally, a displacement of the Umknickelementes 14 should be ensured in relation to the specified peripheral edge portion.

In order to ensure a simpler bending, the Umknickelement 14 at one, the later formed between the inner peripheral edge portion 8 and the outer peripheral edge portion 9 formed bending line a rounded surface 16.

Preferably, at least one of the two surfaces, the fixing surface 13 or the support region 7 or both of these surfaces is heated during the kinking, and / or additional areas of the surface of the Umknickelementes 14, in particular areas of the rounded surface 16, so that the two layers in the flange due the heat effect can be easily deformed and folded over. As far as at least one layer contains a plastic film, for example made of PE, heating to 130 to 140 ° C is advantageous because the melting point of PE is in this temperature range. Thus, a seal can take place during the kinking at the same time. As far as other plastic materials are used, the temperature should be adjusted accordingly to the melting point of this material and lie in Beriech +/- 20 ° C, in particular +/- 10 ° C to the melting point.

As thermal heating or in addition, an ultrasonic heating, high frequency heating, laser heating and / or infrared heating can be used. These heaters can also serve for welding.

In the simple case, the Abknickelement is formed as a solid, at least one of the mold halves, in particular the lower mold half 4, associated block, which has a side surface which is in contact with a side surface of the mold halves and slidably formed along this.

After the outer peripheral edge portion 9 is bent over in the process step shown in Figure 1 b at an angle of about 90 °, takes place in the steps shown in Fig. 1 c to 1 e, the final folding or flanging instead.

Unlike in the embodiment shown, it is sufficient that the at least two-ply material is crimped so that at least one layer, in particular the metal foil layer, is folded over in such a way that it mechanically at least partially encloses the other layer. Basically, it may be sufficient for flanging that only one of the layers is crimped with its outer peripheral edge portion toward its inner peripheral edge portion, wherein the other layer itself is not folded, but extends virtually only over the inner peripheral edge portion of a layer so that you frontal end without crimping is captured and crimped. In the present case, however, both layers are crimped or crimped together.

Instead of the upper mold half 1 1 used in the process steps illustrated in FIGS. 1 a and b, a multipart second upper mold half 17 is used in the steps illustrated in FIGS. 1 c to 1 e, with the kinematics of the vertical outer peripheral edge section ultimately being folded over is, so that it comes to rest against the inner peripheral portion 8 and, as shown in Fig. 1 d, is folded back.

After the upper mold half 1 1 has been raised again in the vertical direction in the case of the folding shown in FIG. 1 b, the lower mold half 4 is returned to the position shown in FIG. 1 a. shifted starting position shifted. Preferably, this occurs instantaneously due to the resilient mounting of the lower mold half when the upper mold half 1 1 is withdrawn.

The Umknickelement 14 is positioned in this initial state or relaxed state of the lower mold half 4 so below the support area 7 of the lower mold half 4.

In this initial position, preferably, the lower mold half 4 is also set during the subsequent process steps, so that it is not displaced in the vertical direction when the multi-part second upper mold half 17 is lowered in the vertical direction on the housing of the two Hüllelementen 1, 2.

The multi-part second upper mold half 17 has seen in the radial direction of the housing or the peripheral edge portion, at its outer region a spring-mounted in the longitudinal direction movable forming die 18 (see Figure 1 c). This has an oblique Umschlagoberflächenbereich 19, which is positioned with respect to the kinked outer peripheral edge portion 9 that the Umschlagoberflächenbereich 19, as far as the movable forming punch 18 is pressed in a horizontal direction down against the established outer peripheral edge portion, the kinked outer Peripheral edge portion 9 at least slightly obliquely inwardly from the 90 ° angle kinks out (see Figure 1 c, d).

As a result, an edge-side end of the outer circumferential edge portion 9 of the peripheral boundary edge of two-ply material enters an area of a pusher surface 20 of the multi-part second upper mold half 17.

Although the forming die 18 is formed in the embodiment as part of the upper mold half 17 and suspended by a spring. However, other embodiments that allow the described kinematics are also possible.

The radial orientation of the pressing surface 20 seen in the cross-sectional direction in FIG. 1 c is preferably smaller than the radial extent of the bearing area 7 of the lower mold half 4. The radial length expansions of the pressing surface 20 together with the inclined rear surface area 19 are slightly larger than the extent of the bearing area 7 the lower mold half 4 or substantially corresponds to the radial extent of the support area. 7

In the step shown in Fig. 1d, the outer peripheral edge portion 9 is slightly bent inwardly by means of the movable forming punch 18 to be subsequently engaged with the pressing surface 20 of the molded body 21 of the upper multipart second Form half 17 ultimately created or folded. While the upper multi-part second mold half 17 is moved down, a counterforce is exerted on the spring-free on the spring forming die 18, against the weight of the forming punch 18, so that relative to the molded body 21 of the upper multi-part second mold half 17 moves relatively. Such a relative displacement can also be achieved instead of the spring arrangement by a motor position or other kinematics.

In order to achieve a corresponding counterforce during folding, the lower mold half 4 is fixed during the process steps c, d and e (FIG. 1). This does not exclude a slightly resilient design.

The multi-part second upper mold half 17 may also be formed of separate non-interconnected parts, so that, for example, not as shown in the figures, a forming die 18 is used, which acts only via a spring and the corresponding gravity such that this first impinges on the folded outer peripheral edge portion. Alternatively, the forming die 18 may also be active, e.g. be operated by a motor. The Umlegeoberfläche 19 of the forming die 18 and the Festdrückoberfläche 20 could also be made via a control ultimately motor instead of mechanical.

In the embodiment shown here, the forming dies 17/18 and the pressing surface 20 are quasi a crimping element, with which the two sections 8 and 9 are crimped together, that they form a mechanically stable closure.

Also, not only, as shown in Fig. 1, housing can be formed with a receiving space, but also flat elements of at least two layers, which for example have no receiving space between them.

By means of this method illustrated in FIGS. 1 a to 1 e, the housings or the devices illustrated in FIGS. 2 to 6 are preferably produced.

FIG. 2 shows a so-called pouch cell 200. Within a at least two-layer material 101, which in the present case is made up of two metal / plastic foil double-layer sections 201, a cell pocket 202 is provided into which a cell stack 203 is inserted. The cell stack 203 has the following material layers: first separator 204, anode 205, second separator 206, cathode 207, third separator 208. The anode or cathode 205, 207 are each designed as discharge lugs 209 and form connecting poles. The aforementioned separators 204, 206, 208 are not to be equated with the later-described plastic film layers, which are not shown in the example in FIG. These plastic film layers can also be referred to as Separatorfolien depending on their application for separation.

At least one or more or all of the aforementioned separators 204, 206, 208 can also be crimped with the described method and form at least one layer of the at least two-ply material per se.

The cell stack 203 is inserted in a pocket which is constructed of two metal / plastic foil double-layer sections. The bag is filled with an electrolyte, not shown in FIG. The pocket has circumferentially a kind of flange, which is formed from opposite edge portions 210, 21 1 of an upper pocket wall 212 and a lower pocket wall 213, wherein the corresponding pocket walls 212, 213 correspond to the double-layer sections. The two bag walls have on the inside of the previously described plastic film to protect the outer wall surfaces of the bag walls forming metal foils from the electrolyte in the bag. Alternatively, the bag walls can each also be formed from a single metal foil, so that the inner walls are formed by the same. Then the battery stack should be put into a plastic bag before it is put in the bag and only then be transferred into the bag. The pocket formed pocket can also be plugged into a housing made of a fiber composite material.

In Fig. 3 is not shown how the flange is bent by means of the method described above and subsequently folded or crimped. In the finished pouch cell, therefore, an exchange is planned. Preferably, the flanging should be full and tight against leakage, so that only the Abieiter 209 and / or a temperature control inflow and / or outflow is provided.

In each of the pocket walls 212, 213 by itself or in the entire pocket, one or more Temperiermediumsdurchflüsse may be provided, as described later for the temperature control unit.

FIGS. 3a to 3d show different views of a temperature control unit. In the schematic exploded view of the temperature control unit in FIGS. 3c and 3d, the position provided with reference numbers 301 and 302 is a layer of a plastic film.

Between the upper plastic film layer 301 and the lower plastic film layer 302, a tempering labyrinth 303, shown only schematically, is provided. This is generated a corresponding seal pattern between the two layers is provided. By means of a schematically illustrated inlet 304, temperature control liquid or a temperature control medium is introduced into the temperature control labyrinth 303 between the layers 301, 302 and is led out of the outlet 305 again. The density of the temperature control channels between the two double layers can be varied as already described and can thus be adapted to the corresponding temperature control requirements in the corresponding regions. At locations where much heat must be dissipated, a higher density of tempering channels and / or larger and / or more Temperierpads ie Temperierdurchflussregionen with wider cross-section.

The two plastic film layers 301, 302 are smaller in their areal extent than the upper metal foil layer 306 or lower metal foil layer 307 enclosing them. The metal foil layers 306, 307 each have a peripheral edge region against which they abut each other directly, so that a type of circumferential flange is formed ,

This flange is, which is not shown in the figures 3a to d, crimped by the method described above, so that a flanged flange, which is also advantageously still sealed, is formed. Alternatively, the two plastic film layers can also be formed so large in the surface extension that they are crimped with. In particular, the plastic layers are advantageously substantially the same size as the metal foil layers.

Also, to generate the tempering labyrinth between the plastic layers 301, 302, a seal is necessary. Accordingly, a sealing labyrinth is usually provided between the plastic layers 301, 302. Such a seal may be performed simultaneously with the sealing step in which the flange is sealed, or before or after, that is, in a separate step.

Although the temperature control unit shown in Figures a to d is designed as a rigid plate member 300, Alternatively, however, such a planar temperature control unit may also be formed as a flexible element.

Such tempering units designed as a plate element or as a flexible element can have any desired size.

In particular, such tempering plate elements can also be provided between different heating layers of auxiliary heaters in motor vehicles. Such a heater is provided preferably formed from an alternating layer of heating layers and Temperierplattenelementen.

FIGS. 4a to 4c show a further embodiment of a tempering unit.

The construction tempering unit is similar to the structure of the temperature control unit shown in Figures 3a to d. As can be seen in FIG. 4 b, the tempering element illustrated in FIG. 4 a also has an inlet 304 and an outlet 305. This tempering is designed as a dimensionally stable plate member, said tempering different differently shaped recesses 309, 310, 31 1 for at least partially receiving a heat-generating element. For this purpose, it is necessary for at least one of the metal foil layers to have a corresponding thickness or thickness, so that the dimensional stability described can be achieved.

In the examples shown in FIGS. 4 a, 4 c, 4 d, three rectangular recesses 309, three substantially square recesses 310 and three circular segment-shaped recesses 31 1 are provided in each case. The square or rectangular recesses 309, 310 are, as shown in Fig. 4a, 4b, contour close to the surface geometry of a single on a semiconductor plate 12 arranged heat-generating element 313 adapted. Such heat-generating elements 313 may be any semiconductor components, in particular, these are to be understood as power transistors. Under the circular segment-shaped recesses 31 1, a single heat-generating element or two heat-generating elements is housed together.

In principle, the shapes of the recesses 31 1 can be different and also vary. You can also be at least partially designed variable so that it adapts in the particular use of a shape of an element to be cooled.

The size of the receiving space of the corresponding circular segment-shaped recesses 31 1 is slightly larger than the outer geometry of the corresponding heat-generating elements 313, which are accommodated within these recesses. These elements 313 may also be general electronic components.

Starting from the single inlet 304 or ending in the single outlet 305, temperature control channels not shown in FIGS. 5a to d are provided. These tempering channels each lead to the respective tempering elements, not shown, which are formed between two layers of material within the multilayer material in the region of the respective indentation. The size of the respective tempering element formed essentially corresponds to the size of the respective indentation 309.

On the respectively opposite side of the indentation 309 projects from the plate member according to a respective bulge 314 from.

Before the corresponding indentations 313 are formed, the corresponding tempering channel geometries and the corresponding tempering element are advantageously formed between the corresponding layers of at least two-ply material and only subsequently generated in the same forming process, in which the crimp takes place, under the corresponding bulges. Alternatively, this forming process can also take place before or after the beading in separate steps.

FIG. 5 shows an example of a tempering unit, which is designed as a frame 400. In a receiving opening 401 of the frame 400, a printed circuit board with semiconductor devices 313 can be used. Also, the frame 400 has at least one fold, not shown, in which at least two layers are crimped together according to the previously described method.

The frame is provided with an inlet 304 and outlet 305, each connected to a tempering channel formed circumferentially around the frame 400 therein. Accordingly, temperature control medium flows into the temperature control channel via the inlet 304 and the heated temperature control medium out of the outlet 305 again.

FIGS. 6a and 6b show a further embodiment of a temperature control unit. The temperature control unit is formed from a plate element 300 from which, as shown schematically in FIG. 6 b, heat transfer projections 500 protrude. Unlike in FIG. 6, the heat transfer projections are integrally formed in the temperature control unit. The temperature control unit forms an elongated plate strip on whose opposite longitudinal sides an inlet 304 or an outlet 305 is provided.

Between the inlet 304 and the outlet 305, a tempering channel is provided in a meandering and labyrinth-like manner in the longitudinal direction.

In the embodiment shown in FIGS. 6a and 6b, the corresponding tempering channel is substantially planar and not within the region of the respective heat transfer projection 500. The heat transfer projections 500 of the embodiment serve only for heat transfer to those shown in FIGS. 6a and 6b, respectively Protrusions formed interstices, inserted cell 501. The respective heat transfer projections 500 have a triangular geometry in cross-section and are each elongated in their longitudinal direction transversely to the longitudinal direction of the plate element 300. Other geometries of the heat transfer projections are additionally or alternatively conceivable.

Another geometry of the heat transfer projections is also conceivable. Essentially, however, their respective outer sides abut on outer peripheral walls of the respective cell 501 of the cell pack of seven batteries 501 shown in FIGS. 6a and b by the heat transfer protrusion geometry.

The term cell covers the local use in this respect with the term battery. As a cooling element, a battery or an electronic component can be understood instead of the cell.

Claims

claims

1 . A method for flanging an at least two-ply material (1, 2; 301, 302, 306, 307) with at least one metal foil ply and an additional ply comprising the steps of: a) defining an inner peripheral edge portion (8) of the at least two-ply material (1, 2; 301, 302, 306, 307) spaced over an outer peripheral edge portion (9) from a peripheral boundary edge of said at least two-ply material (1, 2; 301, 302, 306, 307); b) shifting said fixed inner peripheral edge portion (8) and an inverting member (14) relative to each other for angling the outer peripheral edge portion (9) against the inner peripheral edge portion (8) so that the inner peripheral edge portion (8) and the outer peripheral edge portion (9) enclose an angle of about 90 ° or less therebetween , and c) turning the outer peripheral edge portion (9) against the inner peripheral edge portion (8) by means of a Bördelementes (17, 18, 21), so that the be The sections (8, 9) essentially abut one another at least in sections.

2. The method according to claim 1, characterized in that the folding in step c) by means of an at least partially obliquely to the fixed inner peripheral edge portion (8) aligned Umlegoberflächenbereich (19) of the crimping element (17, 18, 21) is performed.

3. The method according to any one of the preceding claims, characterized by a sealing step for at least partially sealing together at least one of the peripheral edge portions.

4. The method according to any one of the preceding claims, characterized in that the sealing step before step b) and / or after and / or during step c) is performed.

5. The method according to any one of the preceding claims, characterized in that the additional layer is a metal foil or a plastic film.

6. The method according to any one of the preceding claims, characterized in that the at least two-layered material (1, 2; 301, 302, 306, 307) contains at least two metal foil layers and at least two plastic film layers, wherein the two plastic film layers face each other and between them a receiving space and / or have a flow, the two metal foil layers accommodate the two plastic film layers between them and that at least the two metal foil layers are crimped.

A method of making a bag for a pouch cell (200) wherein an at least two-ply material (1, 2; 301, 302, 306, 307) having at least one metal foil ply and an additional ply is formed into a cell bag having two opposing pocket walls (212, 213), which in the at least two-ply material (1, 2;

301, 302, 306, 307) form a receiving space for a cell, wherein opposing edge portions of the pocket walls (212, 213) abut each other and a peripheral edge portion of the at least two-ply material (1, 2;

302, 306, 307) which is crimped using the method of any one of claims 1 to 6.

8. A method for producing a tempering unit from an at least two-layered material (1, 2, 301, 302, 306, 307) having at least one metal foil layer and an additional layer, wherein at least between two layers of the at least two-layered material (301, 302, 306, 307) is formed, which connects at least one inlet (304) and outlet (305) provided in the at least two-layered material (301, 302, 306, 307), wherein the peripheral edge sections of the at least two-layered material (301, 302, 306, 307) are folded at least in sections using the method according to one of claims 1 to 6.

9. Pouch cell (200) having a cell pocket of at least two-ply material, with two opposing pocket walls (212, 213) forming a receiving space for a cell, wherein opposing edge portions of the pocket walls (212, 213) abut each other, wherein opposite edge portions form a flange-shaped peripheral edge portion of the at least two-ply material which is sealingly folded at least at one portion, wherein the at least two-ply material (1, 2; 301, 302, 306, 307) includes at least one metal foil ply and an additional ply.

10. pouch cell (200) according to claim 9, characterized in that the respective outer side of the opposing pocket walls (212, 213) is formed by a metal foil layer or by a fiber composite material layer.

1 1. Pouch cell (200) according to any one of claims 9 or 10, characterized in that the respective inner side of the opposite pocket walls (212, 213) is formed in each case by a plastic film.

12. pouch cell (200) according to claims 9, characterized in that the opposite pocket walls (212, 213) is formed in each case by a double layer of metal foil and plastic film.

13. tempering unit (301, 302, 306, 307) of an at least two-ply material (301, 302, 306, 307) with at least one metal foil layer and an additional layer, wherein at least between two layers of at least two-ply material (301, 302, 306, 307) at least one Temperiermediumsdurchfluss (303) is formed, which connects at least one inlet (304) and outlet (305) of the temperature control unit with each other, wherein the temperature control unit is crimped at least at a peripheral edge portion, in particular sealingly beaded.

14. tempering unit according to claim 13, characterized in that it is dimensionally stable.

15. tempering unit according to claim 13, characterized in that it comprises a surface element with at least one indentation (309) for at least partially receiving a heat-generating and / or heat-absorbing element (313).

16. tempering unit according to one of claims 15, characterized in that an inner space geometry of the indentation (309) is substantially adapted to the surface geometry of the heat-generating or heat-absorbing element (313).

17. tempering unit according to one of claims 15 or 16, characterized in that the Temperiermediumsdurchfluss (303) in the region of the indentation (309) whose shape is adapted to form there a tempering, and at least one temperature control each with the inlet (304 ) and outlet (305) of the temperature control unit is connected to each other.

18. tempering unit according to one of claims 14 to 17, characterized in that depart from the inlet (304) and / or the outlet (305) tempering channels ramified.

19. Tempering unit according to one of claims 14 to 18, characterized in that the temperature control unit is designed as a plate element (300), protrudes from which at least one heat transfer projection (500).

20. Temperature control unit according to one of claims 14 to 19, characterized in that at least a portion of the Temperiermediumsdurchflusses (303) extends within the heat transfer projection (500).

21. tempering unit according to one of claims 14 to 20, characterized in that mutually protrude from the plate member (300) and offset from one another heat transfer projections (500).

22 tempering unit according to one of claims 14 to 21, characterized in that

Heat transfer projections (500) have a triangular cross-section.

23. Tempering unit according to one of claims 14 to 22, characterized in that between two heat transfer projections (500), a cell (501) and / or an electronic component is used, so that the outer wall with the two heat transfer projections (500) is brought into abutment.

24. tempering unit according to one of claims 14 to 23, characterized in that the temperature control unit is designed as a frame (400) in which a semiconductor device plate is used.

25. Tempering unit according to one of claims 14 to 24, characterized in that the Temperiermediumsdurchfluss (203) in the frame (400) is formed circumferentially.