WO2023161161A1 - Membrane stack for a humidifer of a fuel cell system - Google Patents

Abstract

The invention relates to a membrane stack (1) for a humidifier module of a fuel cell system. The membrane stack (1) comprises a plurality of moisture-permeable membranes (2a, 2b) that are stacked on top of one another at a distance from one another along a stacking direction (S). An intermediate space (7a, 7b) formed in each case between two membranes (2a, 2b) adjacent in the stacking direction (S) forms a gas path (5a, 5b) through which a gas (G1, FG) can flow, wherein a spacer element (3a, 3b) is located in each intermediate space (7a, 7b) and is supported on these two membranes (2a, 2b). The spacer elements (3a, 3b) each have a corrugated support structure (8a, 8b) which extends perpendicular to the stacking direction (S) along an extension direction (E, E1, E2). The spacer elements (3a, 3b) are fixedly connected on both sides to the membrane (2a, 2b) that is adjacent in the stacking direction (S) by means of an adhesive connection (6a.1, 6a.2, 6b.1, 6b.2).

Description

Membrane stack for a humidifier of a fuel cell system

The invention relates to a membrane stack for a humidifier of a fuel cell system and a humidifier with such a membrane stack. The invention also relates to a method for producing such a membrane stack.

Conventional membrane stacks for humidifiers comprise membranes stacked on top of one another, each with a membrane layer which is impermeable to gas and permeable to moisture or water or water vapor. An intermediate space is formed between the individual membrane layers or membranes, through which the gas can flow, ie forms a gas path. Thus, a membrane of the membrane stack constructed in this way can have a gas to be humidified flow over it on one side and a moist gas flow over it on the other side in the humidifier. The two gases are fluidically separated from one another by the membrane layer of the respective membrane. Consequently, there is no material mixing of the two gases flowing through the humidifier and the membrane stack. However, the humidity of the wetter gas can pass through the membrane layer and be absorbed by the drier gas to humidify it. As a result, the humidity of the two gases equalizes as they flow through the membrane stack.

Such humidifiers are often used in fuel cell systems where dry cathode supply air has to be humidified before it is fed to the fuel cell. The cathode supply air must be humidified in order to prevent or at least delay drying out of the polymer electrolyte membranes typically used in a fuel cell. Such drying out, which by means of the humidifier module is to be avoided, has a particularly negative effect on the durability of the polymer electrolyte membranes and the efficiency of the fuel cell.

However, the production of such a membrane stack from membranes with a respective membrane layer proves to be technically complex, since it must also be ensured under operating conditions that a defined intermediate space for the gas to flow through is maintained between the individual membrane layers. In particular, it must be prevented that adjacent membrane layers can move—for example due to pressure fluctuations in the gas conducted through the gaps or gas paths—or even touch one another as a result of such a movement.

A conventional membrane stack is known, for example, from US 2017/008935 A1. According to this, membranes that are permeable to moisture and impermeable to gas and are flat are arranged at a distance from one another with the aid of spacer elements. Thus, an intermediate space formed between two adjacent membranes can form a gas path for a gas to flow through. To fix the membranes, they are wrapped around the spacer elements and sealed at the edges. However, the production of such a membrane stack proves to be technically relatively complex.

It is therefore an object of the present invention to create an improved embodiment for a membrane stack with a plurality of membranes or membrane layers, which takes account of the problems mentioned above. In addition, such an improved membrane stack should be particularly easy to produce. This object is solved by the subject matter of the independent patent claims. Preferred embodiments are subject matter of the dependent patent claims.

The basic idea of the invention is therefore to stack the membranes of a membrane stack for a humidifier of a fuel cell system on top of one another and to arrange them at a distance from one another by being arranged alternately on a respective spacer element. Said spacer elements are thus arranged between two membranes that are adjacent in the stacking direction. In this case, an intermediate space formed with the aid of a respective spacer element between two adjacent membranes forms a gas path for a gas to flow through, in particular for the gas to be humidified or for the moist gas. According to the invention, said spacer elements are firmly connected on both sides to the two membranes that are adjacent in the stacking direction by means of an adhesive connection. Such a connection can be realized by means of a suitable adhesive layer made of an adhesive or an adhesive tape. This eliminates the folding of the membranes around the spacer element, which is usual in conventional membrane stacks. At the same time, a fluid-tight delimitation of the intermediate space or gas path is realized by means of the spacer element glued to the membranes. The result is a membrane stack that is technically simple in construction and therefore also inexpensive to produce.

Specifically, the membrane stack according to the invention comprises a plurality of, ie at least three, gas-tight and moisture-permeable membranes stacked one on top of the other at a distance along a stacking direction. If a dry gas, in particular air, is guided past a first side of the membrane and a moist gas - in particular air - is guided past a second side opposite the first side, moisture present in the moist gas can be transferred through the membrane to the dry gas become. As used herein, "wet gas" and "dry gas" means that the moisture content of the wet gas is greater than the moisture content of the dry gas, at least before moisture is transferred to the dry gas. The transfer of moisture across the membrane dehumidifies the wet gas and humidifies the dry gas, ie the moisture content of the wet gas decreases and the moisture content of the dry gas increases.

In the present context, "gas-tight membrane" means that the membrane does not permit the passage of a gas through the membrane. In the present context, “moisture-permeable membrane” is to be understood as meaning that the membrane allows moisture to pass through at least in gaseous form, ie in particular in the form of water vapor, or in liquid form. The membrane can preferably be designed to be permeable to moisture both in liquid form and in gaseous form.

A spacer element, which is supported on these two membranes, is arranged between two membranes that are adjacent in the stacking direction. The spacer elements each have a wave-shaped support structure which extends perpendicularly to the stacking direction along a direction of extent and forms a gas path through which a gas can flow along the direction of extent. The gas can in particular be the moist gas or gas to be humidified mentioned above. The spacer elements are firmly bonded on both sides by means of an adhesive bond to the membrane that is adjacent in each case in the stacking direction.

Particularly preferably, the spacer elements can be arranged in intermediate spaces formed between the membranes along the stacking direction, so that the intermediate spaces form a gas path through which a gas can flow. Thus, even in the stacking direction, adjacent gaps or gas paths can each be rotated by 90° with respect to one another and a gas can flow through them. According to a preferred embodiment, the support structure is arranged between two preferably flat edge sections of the respective spacer element, each of which likewise extends along the extension direction. In this embodiment, the two edge sections of a respective spacer element are firmly connected on both sides by means of the adhesive connection to the membrane that is respectively adjacent in the stacking direction. In this embodiment, two spacer elements that are adjacent in the stacking direction are also arranged rotated through 90° with respect to their direction of extension. This means that first spacer elements and second spacer elements alternate along the stacking direction, with the edge sections of the first spacer elements extending along a first direction of extent that runs orthogonally to a second direction of extent, along which the second edge sections of the second spacer elements extend.

According to another preferred embodiment, those intermediate spaces in which a first spacer element is arranged form a first gas path through which flow can take place along the first direction of extent. In this embodiment, those intermediate spaces in which a second spacer element is arranged form a second gas path through which a flow can take place along the second direction of extent.

First and second gas paths preferably alternate along the first stacking direction. If humid gas is conducted through the first gas paths and gas to be humidified is conducted through the second gas paths or vice versa, moisture can be effectively transferred from the humid gas to the gas to be humidified in this way.

Particularly expediently, the adhesive bonds form a fluid-tight lateral delimitation of a respective gas path. In this way, the deployment separate sealing elements for sealing the gas paths or gaps are eliminated.

Particularly expediently, the edge sections can be designed in the form of strips. In this way it is ensured that there is enough space available for the gas path formed in the area of the support structure along the direction of extent.

At least one adhesive connection is particularly expediently realized by means of an adhesive layer of adhesive or of an adhesive tape. This applies particularly preferably to all existing adhesive bonds. In this way, the membrane stack can be assembled in a particularly simple manner while remaining mechanically stable.

According to an advantageous development, the wave-shaped support structure has a, preferably sinusoidal, geometric shape in profile perpendicular to the direction of extension with a number of maxima and minima. In this development, one of the two membranes that are adjacent in the stacking direction is supported on the maxima. The other of the two membranes that are adjacent in the stacking direction is supported accordingly on the minima. In this way, a stable arrangement of adjacent membranes at a distance from one another is ensured.

According to an advantageous development, the membrane stack has the geometry of a square with two opposite first sides and two opposite second sides or the geometry of a rectangle with two opposite narrow sides and two opposite broad sides in a cross section perpendicular to the axial direction. In this development, the edge portions of both the first and end and second spacer elements in each of two adjacent corners of the square or rectangle. A membrane stack with such a geometric shape is mechanically particularly stable, requires only little installation space and still allows moisture to be transferred from the moist gas to the gas to be humidified with a high effective cross section.

The invention also relates to a humidifier for a fuel cell system of a motor vehicle. The humidifier includes a housing surrounding a housing interior. Furthermore, the humidifier comprises a membrane stack according to the invention, which is arranged in the interior of the housing and is presented above.

The advantages of the membrane stack according to the invention explained above are therefore transferred to the humidifier according to the invention.

The invention further relates to a method for producing a membrane stack according to the invention as presented above, according to a first aspect. The advantages of the membrane stack according to the invention explained above are therefore transferred to the method according to the invention, which according to the first aspect comprises measures a) to h) explained below.

According to measure a), a first membrane is provided and an adhesive layer of an adhesive or of an adhesive tape is applied to two membrane edge sections of this membrane that lie opposite one another and each extend along the first direction of extent.

In measure b), a first spacer element is arranged on the first membrane, so that the edge sections of the first spacer element extend along the first direction of extent on the adhesive layers applied in measure a). This spacer element is thus glued with the adhesive or adhesive tape provided in measure a). In measure c), an adhesive layer made of an adhesive or of an adhesive tape is applied to two opposite edge sections of the first spacer element, each extending along the first direction of extent.

In measure d), a further, second membrane is arranged on the first spacer element and this membrane is bonded to the first spacer element by means of the adhesive or adhesive tape provided in measure c).

According to measure e), an adhesive layer consisting of an adhesive or an adhesive tape is applied to two membrane edge sections of the second membrane lying opposite one another and each extending along a second direction of extent, the second direction of extent running perpendicular to the first direction of extent.

In measure f), a second spacer element is arranged on the first membrane, so that the two edge sections of the second spacer element extend along the adhesive layers arranged in measure a) in the second direction of extension. This spacer element is glued to the second membrane using the adhesive layer provided in measure e).

According to measure g), an adhesive layer made of an adhesive or an adhesive tape is applied to two opposite edge sections of the first spacer element, each extending along the second direction of extent. Finally, in measure h), a further, first membrane is arranged on the second spacer element and this first membrane is bonded to the second spacer element by means of the adhesive layer provided in measure g). The invention further relates to a method for producing a membrane stack according to the invention presented above according to a second aspect. The advantages of the membrane stack according to the invention explained above are therefore transferred to the method according to the invention, which according to the first aspect comprises two measures a) and b) explained below.

In measure a), at least two prefabricated humidifier modules are provided. Each humidifier module includes a (second) spacer element, which is arranged in a sandwich-like manner between two membranes and is firmly connected to them by means of a respective adhesive connection.

Furthermore, in measure b), a first spacer element with an adhesive layer of an adhesive or an adhesive tape applied to both edge sections of this spacer element is arranged between the two humidifier modules, so that this adhesive layer, like the edge sections of the first spacer element, extends perpendicularly along a first direction of extension extend to a second direction of extent, along which the two second spacer elements of the at least two humidifier modules extend. In measure c), the first spacer element is bonded to the two humidifier modules, so that after bonding, the first spacer element is sandwiched between the two humidifier modules.

According to an advantageous development of the method according to the invention according to the first aspect, the prefabrication of a respective humidifier module comprises two measures a0) and a1) preceding measure a). According to measure aO), a second spacer element is provided. An adhesive layer made of an adhesive or of an adhesive tape is applied to both sides of the two edge sections of this spacer element, which extend along a second direction of extension. In measure a1), the humidifier module is prefabricated by arranging a respective membrane on both sides Adhesive layer and by gluing the two membranes with the adhesive layer, so that after gluing the second spacer element is sandwiched between the two membranes.

The measures a0), a1), a), b) and c) mentioned can be repeated to form a membrane stack with any desired number of membranes or gas paths.

Further important features and advantages of the invention result from the subclaims, from the drawings and from the associated description of the figures based on the drawings.

It goes without saying that the features mentioned above and those still to be explained below can be used not only in the combination specified in each case, but also in other combinations or on their own, without departing from the scope of the present invention.

Preferred exemplary embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description, with the same reference numbers referring to identical or similar or functionally identical components.

They show, each schematically:

1 shows an example of a membrane stack 1 according to the invention in a perspective representation,

FIG. 2 shows a detailed illustration of FIG. 1, 3 shows a spacer element of the membrane stack in a separate perspective view,

4a shows a side plan view of the membrane stack along a first direction of extension, which runs orthogonally to the stacking direction of the membrane stack,

Fig. 4b shows a detailed representation of Figure 4a,

5a shows a side plan view of the membrane stack along a second direction of extent, which runs orthogonally to the stacking direction and orthogonally to the first direction of extent of the membrane stack,

Fig. 5b shows a detailed representation of Figure 5a,

6a to 6i, various illustrations showing the process of the method according to the invention in the form of snapshots,

7, 8 representations which illustrate the construction of prefabricated humidifier modules for use in a membrane stack according to the invention,

9, 10 two representations which illustrate the installation of the prefabricated humidifier modules in the membrane stack according to the invention.

FIG. 1 illustrates an example of a membrane stack 1 according to the invention in a perspective view. Figure 2 is a detailed representation of the figure 1. The membrane stack 1 comprises a plurality of gas-tight and moisture-permeable membranes 2a, 2b stacked on top of one another at a distance from one another in a stacking direction S (cf. FIG. 2).

According to FIG. 1, the membrane stack 1 has, in a cross section perpendicular to the stacking direction S, the geometry of a square 14 with two opposite first sides 15a, 15b and two opposite second sides 16a, 16b. According to FIG. 2, a first or second intermediate space 7a or 7b formed between two adjacent membranes 2a, 2b in the stacking direction S forms a first gas path 5a through which a first gas G1 can flow or a second gas path through which a second gas G2 can flow 5b.

According to FIGS. 1 and 2, the first and second intermediate spaces 7a, 7b and thus the first and second gas paths 5b alternate along the stacking direction S. The first gas G1 can flow through the first gas paths 5a along a first extension direction E1, E, which runs perpendicular to a second extension direction E2, E, along which the second gas paths 5b can be flowed through by the second gas 5b. This enables the first and second gas G1, G2 to flow through the gas paths 5a, 5b in cross flow.

According to FIG. 2, a first spacer element 3a is arranged in each of the first intermediate spaces 7a and is supported on the two adjacent membranes 2a, 2b. A second spacer element 3b is arranged in each case in the second intermediate spaces 7b, which is also supported on the two adjacent membranes 2a, 2b. The spacer elements 3a, 3b each have a wave-shaped support structure 8a or 8b, which can be seen in FIG. For clarification, one of the first spacer elements 3a is shown separately in FIG. The support structure 8a of the spacer element 3a extends perpendicular to the stacking direction S along the direction of extent E or E1. According to FIG. 3, the first spacer element 3a has two flat edge sections 4a.1, 4a.2, each also extending along the first direction of extent E1, between which the support structure 8a is arranged. The second spacer element 3b (not shown) is designed identically to the first spacer element 3a, but extends according to Figures 1 and 2 along the second direction of extent E2, E, i.e. perpendicular to the first direction of extent E1, E.

As can be seen in FIG. 2, first spacer elements 3a and second spacer elements 3b alternate along the stacking direction S. The first spacer elements 3a are rotated by 90° relative to the second spacer elements 3b. The first direction of extent E1, E of the first spacer elements 3a thus runs orthogonally to the second direction of extent E2, E of the second spacer elements 3b. Correspondingly, the edge sections 4a.1, 4a.2 of the first spacer elements 4a extend along the first direction of extent E, E1. The second edge sections 4b.1, 4b.2 of the second spacer elements 3b accordingly extend along the second direction of extension E, E2. The edge sections 4a.1, 4a.2, 4b.1, 4b.2 are longitudinal or strip-shaped in the example scenario and extend along the first or second direction of extent E1, E2 over the entire extent of the membrane stack 1.

To illustrate the structure of the membrane stack 1 explained above, FIG. 4a shows a plan view of the membrane stack 1 along the first direction of extent E1 and FIG. 5a shows a plan view of the membrane stack 1 along the second direction of extent E2. Figures 4b and 5b are detail views of Figures 4a and 5a. In the example of FIGS. 1 to 5, the two edge sections 4a.1, 4a.2, 4b.1, 4b.2 of a respective spacer element 3a, 3b are bonded on both sides by means of an adhesive connection 6a.1, 6a.2, 6b.1, 6b. 2 (cf. detailed view of FIGS. 4b and 5b) is firmly connected to the diaphragm 2a, 2b that is adjacent in the stacking direction S. The adhesive connections 6a.1, 6a.2, 6b.1, 6b.2 form a fluid-tight delimitation of a respective gas path 5a, 5b. The adhesive connections 6a.1, 6a.2, 6b.1, 6b.2 can be made by means of respective adhesive layers made from an adhesive 9a.1, 9a.2, 9b.1, 9b.2 or from an adhesive tape 10a.1, 10a.2 , 10b.1, 10b.2 can be implemented. The adhesive connections 6a.1, 6a.2, 6b.1, 6b.2 are also designed in the form of strips in the example scenario.

As FIGS. 4b and 5b also illustrate, the wave-shaped support structures 8a, 8b can each have a sinusoidal geometric shape 11 with a plurality of maxima 12 and minima 13 in profile perpendicular to the direction of extent E1 or E2. One of the two membranes 2a, 2b that are adjacent in the stacking direction S is supported on said maxima 12. The other of the two membranes 2b, which are adjacent in the stacking direction S, is supported accordingly on the minima 13.

The method according to the invention for producing the membrane stack 1 according to the invention presented above is explained by way of example below with reference to FIGS. 6a to 6i. The method includes the measures a) to g).

According to measure a), a first membrane 2a shown in FIG. 6a is provided.

As shown in FIG. 6b, in the course of measure a), the two membrane edge sections 18a, 18b of this membrane 2a lying opposite one another and extending in each case along the first direction of extent E, E1 an adhesive layer of an adhesive tape 10a.1, 10a.2 applied. Instead of an adhesive tape 10a.1, 10a.2, an adhesive (not shown) can also be used as the adhesive layer.

In measure b), a first spacer element 3a is arranged on the first membrane 2a, as shown in FIG. Edge sections 18a, 18b are arranged, on which in turn the adhesive tapes 10a.1, 10a.2 were arranged in measure a). In the course of measure b), this first spacer element 3a is bonded to the adhesive tape 10a.1, 10a.2 applied in measure a). The adhesive tapes 10a.1 and 10a.2 thus serve to form a respective adhesive connection 6a.1, 6a.2 of the first membrane 2a with the first spacer element 3a.

In measure c), as shown in FIG. 6d, another adhesive tape 10a.1, 10a.2 is applied to the two opposing edge sections 4a.1, 4a.2 of the first spacer element 3a, each extending along the first direction of extent E, E1.

In measure d), as shown in FIG. 6e, a further, second membrane 2b is arranged on the first spacer element 3a and this membrane 2b is bonded to the first spacer element 3a using the adhesive tape 10a.1, 10a.2 provided in measure c).

In measure e), as shown in FIG. 6f, a further adhesive tape 10b.1, 10b.2 is applied to two opposing membrane edge sections 19a, 19b of the second membrane 2b, each extending along a second direction of extent E, E2. The second direction of extent E, E2 runs perpendicular to the first direction of extent E, E1. In measure f), as shown in Figure 6g, a second spacer element 3b is arranged on the first membrane 2a, so that the two edge sections 4b.1, 4b.2 of the second spacer element 3b extend along the second direction of extent E, E2 and on the membrane -Edge sections 19a, 19b are arranged, on which in turn in measure e) the adhesive tapes 10b.1, 10b.2 were arranged. The second spacer element 3b is thus glued to the second membrane 2b by means of the adhesive tapes 10b.1, 10b.2 provided in measure e). An adhesive bond 6b.1, 6b.2 is thus formed between the second membrane 2b and the second spacer element 3b.

In measure g), as shown in FIG. 6h, another adhesive tape 10b.1, 10b.2 is applied to two opposing edge sections 4a.1, 4a.2 of the second spacer element 3b, each extending along the second direction of extent E2, E.

In measure i), a further first membrane 2a is finally arranged on the second spacer element 3b and this first membrane 2a is bonded to the second spacer element 3b using the adhesive tape 10b.1, 10b.2 provided in measure g). A further adhesive connection 6b.1, 6b.2 is thus formed between the second spacer element 3b and the further first membrane 2a.

By means of the measures a) to i) explained above, a membrane stack 1 with three membranes 2a, 2b, 2a and thus exactly one first gas path 5a - between the membranes 2a, 2b explained above - and with exactly one - between the membranes 2b, 2a - Second gas path 5b made.

A membrane stack 1 with a larger number of first and second gas paths 5a, 5b can be produced by iterating the measures b) to i) explained above. A particularly advantageous variant of the method according to the invention is explained below with reference to FIGS.

In this variant, prefabricated humidifier modules 20 are provided in measure a) of this variant. Such a humidifier module 20 is shown separately in FIG. Each humidifier module 20 accordingly comprises a first spacer element 3a, which is sandwiched between two membranes 2a, 2b and is firmly connected to them by means of a respective adhesive connection 6b.1, 6b.2). The second spacer element 3b extends with its edge sections 4b.1, 4b.2 (only the second edge section 4b.2 and thus the second adhesive connection 6b.2 can be seen in the partial view of Figure 7) along the second direction of extent E2, E. The adhesive connection 6b.1, 6b2 can be realized by means of an adhesive layer made of an adhesive 9b.1, 9b.2 or by means of an adhesive layer made of an adhesive tape 10b.1, 10b.2.

Furthermore, as shown in FIG. 8, in measure b) a first spacer element 3a with adhesive tapes 10a.1, 10a.2 applied to both edge sections 4a.1, 4a.2 of this spacer element 3a is arranged in the stacking direction S between two humidifier modules 20 in each case ( only the first edge section 4a.1 and thus the first adhesive tape 10a.1 can be seen in the partial view of FIG Spacer element 3a along the first direction of extent E1, E perpendicular to the second direction of extent E2, E extend.

In measure c), the first spacer element 3a is bonded to the two humidifier modules 20, 20, so that the first spacer element 3a is arranged in the manner of a sandwich between the two adjacent humidifier modules 20, 20 after bonding. The membrane stack 1 shown in FIGS. 1 and 2 is produced in this way. The manufacture of the humidifier modules 20 explained above is explained below. A respective humidifier module 20 can be produced in two measures a) preceding and following measures a) and a1) explained above.

According to measure aO), the second spacer element 3b is provided as shown in FIG. The adhesive tape 10b.1, 10b.2 is applied to both sides of the two edge sections 4b.1, 4b.2 of this spacer element 3b, which extend along a second direction of extent E2, E (only the second edge section 4b.2 recognizable with the adhesive tapes 10b.2).

In measure a1), as shown in FIG. 10, the humidifier module 20 is then prefabricated by arranging a respective membrane 2a, 2b on both sides on the adhesive tapes 10b.1, 10b.2 and gluing the two membranes 2a, 2b to the adhesive tapes 10a.1, 10a.2, so that after gluing, the first spacer element 3a is arranged in the manner of a sandwich between the two membranes 2a, 2b.

*****

Claims

patent claims

1. membrane stack (1) for a humidifier of a fuel cell system,

- with a plurality of gas-tight and moisture-permeable membranes (2a, 2b) stacked on top of one another at a distance from one another along a stacking direction (S),

- wherein an intermediate space (7a, 7b) formed between two adjacent membranes (2a, 2b) in the stacking direction (S) forms a gas path (5a, 5b) through which a gas (G1, G2) can flow,

- wherein a spacer element (3a, 3b) is arranged in each intermediate space (7a, 7b), which is supported on these two membranes (2a, 2b),

- wherein the spacer elements (3a, 3b) each have a wave-shaped support structure (8a, 8b) which extends perpendicularly to the stacking direction (S) along a direction of extent (E, E1, E2),

- wherein the spacer elements (3a, 3b) are firmly connected on both sides by means of an adhesive connection (6a.1, 6a.2, 6b.1, 6b.2) to the respective membrane (2a, 2b) adjacent in the stacking direction (S).

2. Membrane stack according to claim 1, characterized in that the spacer elements (4a, 4b) are arranged in intermediate spaces (7a, 7b) formed between the membranes (2a, 2b) along the stacking direction (S), so that the intermediate spaces (7a, 7b) each form a gas path (5a, 5b) through which a gas (G1, G2) can flow.

3. membrane stack (1) according to claim 1 or 2, characterized in that - The support structure (8a, 8b) between two preferably flat edge sections (4a.1, 4a.2, 4b.1, 4b.2) of the respective spacer element, each also extending along the extension direction (E, E1, E2). (3a, 3b) is arranged,

- The two edge sections (4a.1, 4a.2, 4b.1, 4b.2) of a respective spacer element (3a, 3b) on both sides by means of the adhesive connection (6a.1, 6a.2, 6b.1, 6b.2) are firmly connected to the membrane (2a, 2b) adjacent in the stacking direction (S),

- in each case two spacer elements (3a, 3b) which are adjacent in the stacking direction (S) are arranged, preferably rotated by 90° with respect to one another.

4. Membrane stack according to one of Claims 1 to 3, characterized in that those intermediate spaces (7a) in which a first spacer element (3a) is arranged have a first gas path (5a) through which a flow can take place along the first direction of extension (E, E1). and those intermediate spaces (7b) in which a second spacer element (3b) is arranged form a second gas path (5b) through which a flow can take place along the second direction of extension (E, E2).

5. Membrane stack according to claim 4, characterized in that along the stacking direction (S) first and second gas paths (5a, 5b) alternate.

6. membrane stack according to one of the preceding claims, characterized in that the adhesive connections (6a.1, 6a.2, 6b.1, 6b.2) form a fluid-tight boundary of a respective gas path (5a, 5b).

7. membrane stack according to any one of the preceding claims, characterized in that the edge sections (4a.1, 4a.2, 4b.1, 4b.2) are strip-shaped (4a.1, 4a.2, 4b.1, 4b.2). Membrane stack according to one of the preceding claims, characterized in that at least one adhesive connection (6a.1, 6a.2, 6b.1, 6b.2), preferably all adhesive connections (6a.1, 6a.2, 6b.1, 6b. 2), by an adhesive layer made of an adhesive (9a.1, 9a.2, 9b.1, 9b.2), or of an adhesive tape (10a.1, 10a.2, 10b.1, 10b.2). is/are. Membrane stack according to one of the preceding claims, characterized in that the corrugated support structure (8a, 8b) in profile perpendicular to the first or second direction of extension (E, E1, E2) has a, preferably sinusoidal, geometric shape (11) with a plurality of maxima ( 12) and minima (13), one of the two membranes (2a, 2b) adjacent in the stacking direction (S) being supported on the maxima (12) and the other of the two membranes (2b) being adjacent in the stacking direction on the minima ( 13) supports. . Membrane stack according to one of the preceding claims, characterized in that in a cross section perpendicular to the stacking direction (S) of the membrane stack (1) the geometry of a square (14) with two opposite first sides (15a, 15b) and with two opposite second sides (16a, 16b) or has the geometry of a rectangle with two opposite narrow sides and two opposite broad sides (19a, 19b), - the edge sections (4a.1, 4a.2, 4b.1, 4b.2) of both the first spacer elements (3a) and the second spacer elements (3b) each in two adjacent corners (17) of the square (14) or rectangle ends.

11. Humidifier for a fuel cell system of a motor vehicle,

- With a housing surrounding a housing interior;

- With a arranged in the housing interior membrane stack (1) according to any one of the preceding claims.

12. The method for producing a membrane stack (1) according to any one of claims 1 to 10, comprising the following measures: a) providing at least two prefabricated humidifier modules (20), each humidifier module (20) comprising a second spacer element (3b) which is sandwiched arranged between two membranes (2a, 2b) and firmly connected to them by means of a respective adhesive connection (6b.1, 6b.2, 6b.1, 6b.2), and b) arranging a first spacer element (3a) with a on both sides on the two edge sections (4a.1, 4a.2) of this spacer element (3a) applied adhesive layer of an adhesive (9a.1, 9a.2) or of an adhesive tape (10a.1, 10a.2) between the two humidifier modules ( 20), so that these adhesive layers, like the edge sections (4b.1, 4b.2) of the first spacer element (3a), extend along a first direction of extent (E, E1) perpendicular to the second direction of extent (E, E2), along which the at least two second spacer elements (3b) of the at least two humidifier modules (20) provided in measure a) extend, c) gluing the first spacer element (3a) to the two humidifier modules (20), so that after gluing the first spacer element (3a) sandwiched between the two humidifier modules (20, 20). 13. The method according to claim 12, characterized in that the prefabrication of a respective humidifier module (20) comprises the following measures aO) and a1) preceding measure a): aO) providing a second spacer element (3b) and applying an adhesive layer on both sides an adhesive (9b.1, 9b.2) or an adhesive tape (10b.1, 10b.2) on the two edge sections (4b.1, 4b.2) of this spacer element, which extend along a second direction of extension (E2, E). (3b), a1) Prefabrication of a humidifier module (20) by arranging a respective membrane (2a, 2b) on both sides on the adhesive (9b.1, 9b.2) or on the adhesive tape (1 Ob.1, 10b.2) and gluing the two membranes (2a, 2b) with the adhesive or with the adhesive tape (10a.1, 10a.2), so that after gluing the second spacer element (3b) is sandwiched between the two membranes (2a, 2b). is.