阅读说明：本技术 用于制造燃料电池堆的方法 (Method for manufacturing fuel cell stack ) 是由 P·多林格尔 T·施梅尔 C·希尔德布朗 L·霍格 M·格雷泽尔 H·赖斯 N·克鲁伊 于 2018-05-29 设计创作，主要内容包括：本发明涉及一种用于制造包括多个层元件(24)的燃料电池堆(22)的方法,其中,层元件(24)彼此上下叠置地布置,每个层元件(24)具有能弹性变形的燃料电池层(26),该燃料电池层被密封条(28)围边,每个层元件(24)的燃料电池层(26)由于重力作用相对于密封条(28)弯曲,其中,最底层的层元件(24)布置在能弯曲的基板(30)上,该基板逆着重力弯曲,由此燃料电池堆(22)的最顶层的层元件(24)的燃料电池层(26)基于由基板(30)产生的力而逆着重力弯曲以及基本上被展平。(The invention relates to a method for producing a fuel cell stack (22) comprising a plurality of layer elements (24), wherein the layer elements (24) are arranged one above the other, each layer element (24) having an elastically deformable fuel cell layer (26) which is bordered by a sealing strip (28), the fuel cell layer (26) of each layer element (24) being bent by gravity relative to the sealing strip (28), wherein the bottommost layer element (24) is arranged on a bendable base plate (30) which is bent against gravity, whereby the fuel cell layer (26) of the topmost layer element (24) of the fuel cell stack (22) is bent against gravity and substantially flattened on the basis of a force generated by the base plate (30).)

1. A method for producing a fuel cell stack (22) comprising a plurality of layer elements (24), wherein the layer elements (24) are arranged one above the other, each layer element (24) having an elastically deformable fuel cell layer (26) which is bordered by a sealing strip (28), the fuel cell layer (26) of each layer element (24) being bent by gravity relative to the sealing strip (28), wherein the bottommost layer element (24) is arranged on a bendable base plate (30) which is bent against gravity, whereby the fuel cell layer (26) of the topmost layer element (24) of the fuel cell stack (22) is bent against gravity and substantially flattened by the force generated by the base plate (30).

2. Method according to claim 1, characterized in that the individual fuel cell layers (26) of all layer elements (24) which have been arranged on the base plate (30) are also bent against the force of gravity as a result of the force generated by the base plate (30), wherein the force of the base plate (30) is transmitted to the fuel cell layers (26) of the topmost layer element (24) by means of the fuel cell layers (26) of all layer elements (24) which are located between the base plate (30) and the topmost layer element (24).

3. Method according to claim 1 or 2, characterized in that a further flat module is arranged between the two layer elements (24), which module is likewise bent against the force of gravity due to the force generated by the substrate (30).

4. Method according to any of the preceding claims, characterized in that the degree of bending of the fuel cell layer (26) of the topmost layer element (24) is determined, wherein the value of the force to be generated by the substrate (30) is set in dependence on the degree of bending.

5. A method according to any one of the preceding claims, characterized by arranging an additional layer element (24) on the already stacked topmost layer element (24), the fuel cell layer (26) of which is substantially flattened out.

6. A system for producing a fuel cell stack (22) comprising a plurality of layer elements (24), comprising a stack module (40) and a bendable base plate (30), wherein the stack module (40) is designed to arrange the layer elements (24) on the topmost layer element (24) of the fuel cell stack (22) to be produced, wherein each layer element (24) has an elastically deformable fuel cell layer (26) which is bordered by a sealing strip (28), wherein the fuel cell layer (26) of each layer element (24) is bent relative to the sealing strip (28) as a result of the effect of gravity, wherein the stack module is further designed to arrange the bottommost layer element (24) on the bendable base plate (30), wherein the elastically deformable base plate (30) is bent against gravity and is designed such that the fuel cell layer (26) of the topmost layer element (24) is bent against the force generated by the base plate (30) The gravity bends and is substantially flattened.

7. System according to claim 6, comprising a bending drive (32) having at least one pin (34) and arranged below the elastically deformable substrate (30), wherein the at least one pin (34) is designed to act on the substrate (30) against gravity and to bend the substrate.

8. The system according to claim 7, characterized in that the at least one pin (34) is designed to act on the base plate (30) in a position below the center of the fuel cell layer (26) of the at least one layer element (24) arranged on the base plate.

9. System according to one of claims 6 to 8, characterized in that the stacking module (40) is designed such that the individual layer elements (24) are arranged one above the other.

Technical Field

The present invention relates to a method for manufacturing a fuel cell stack and a system for manufacturing a fuel cell stack.

Background

When stacking a fuel cell stack or a fuel cell stack, up to several hundreds of fuel cell layers are stacked on top of each other. The fuel cell layers may be comprised of a soft, pliable material. Typically, the fuel cell layers are loosely placed on each other. Once a predetermined number of fuel cell layers are stacked one on top of the other, the fuel cell layers are pressed together. Between each two fuel cell layers, a gap is present, through which the medium flows during operation of the fuel cell stack, so that each fuel cell layer is sealed at its edges. For sealing, a deformable material is used, which, as a result of the action of force, produces a closed contact surface between the two fuel cell layers. Furthermore, each fuel cell layer forms a layer element with the material of the surrounding edge.

It follows that the material used for sealing has a greater height without external pressure than the corresponding fuel cell layer bordered by the material. Due to the material provided for the sealing, a greater layer height results in the edge region of the layer element formed by the sealing material than in the intermediate region formed by a fuel cell layer. Since the fuel cell layers are flexible, they can bend towards their center, thereby changing the geometry of the topmost fuel cell layer, among other things, during stacking.

In order to be able to meet the accuracy requirements of fuel cell layers stacked one on top of the other, for example, a clamping structure can be used which can be deformed dynamically and thus can adjust the curvature of the fuel cell layers. Thereby, however, the costs for stacking the layer elements are increased and the speed of stacking the layer elements one on top of the other is reduced.

A method for producing an electrochemical energy storage cell is known from DE 102010052843 a 1.

A method for producing a membrane electrode assembly for a fuel cell is described in DE 102006059640 a 1.

Disclosure of Invention

Against this background, it is an object of the present invention to ensure that the fuel cell stack does not deform.

This object is achieved by a method and a system having the features of the independent patent claims. Embodiments of the method and system result from the dependent claims and the description.

The method according to the invention provides for producing a fuel cell stack comprising a plurality of layer elements, wherein the layer elements are stacked one above the other and arranged next to the other during the stacking process. Each layer element has a soft, pliable, elastically deformable fuel cell layer which is bordered by a sealing strip/sealing flange. The fuel cell layer of each layer element is thereby bent, for example concavely, in the direction of gravity relative to the sealing strip as a result of the action of gravity. In order to carry out the method, the lowermost/lowermost layer element or the first layer element is arranged on a flexible, elastically deformable base plate/base plate, which is bent upward against the force of gravity, so that the force generated by the base plate causes the uppermost/uppermost layer element or the fuel cell layer of the last layer element already stacked to bend upward and/or lift up against the force of gravity and to be largely flattened or flattened out.

In an embodiment, the fuel cell layers of all layer elements which have been arranged above the substrate are also bent upwards against the force of gravity due to the force generated by the substrate, wherein the force of the substrate is transmitted to the fuel cell layers of the topmost or already stacked last layer element by the fuel cell layers of all layer elements which are located between the substrate and the topmost or already stacked last layer element.

The method can be carried out already at the beginning of the stacking process of the layer elements, it being proposed that at the beginning of the stacking process the bottommost layer element arranged on the substrate is the only layer element first and thus also the last or topmost layer element. The fuel cell layer of the single layer element can be bent upward with the substrate against the force of gravity and thus flattened. If the fuel cell stack already has a plurality of layer elements which are stacked or stacked on top of one another, the force of the base plate and thus the effect of the base plate is indirectly transmitted to the currently topmost layer element, irrespective of the current number of already stacked layer elements which the fuel cell stack currently has during its manufacturing process.

It is also possible to arrange a further flat, usually elastically deformable module between the two layer elements, which module is also bent upwards against the force of gravity due to the force generated by the substrate. In an embodiment, the module is designed as a soft, bendable and thus elastically deformable bipolar plate, which can also be bent due to the forces generated by the substrate and flattened when the method is put into practice.

The degree of concave curvature of the fuel cell layers of the topmost layer element is determined, for example by optical and/or mechanical sensors. The value of the force to be generated by the substrate is set based on the degree of bending. Alternatively or additionally, the value of the force is set as a function of the number of already stacked layer elements, wherein a functional relationship between the number of layer elements and the value of the force is taken into account for this purpose. In this case, in one embodiment, the force value and/or the degree of curvature of the fuel cell layer of the topmost layer element is calculated and/or derived from the number of already stacked layer elements.

During the stacking process, additional layer elements are arranged on the already stacked topmost layer element whose fuel cell layers are currently largely flattened by the substrate.

The system according to the invention, which is designed for manufacturing a fuel cell stack from a plurality of layer elements by performing a stacking process, has a stacking module and an elastically deformable substrate. The stack module is designed to arrange the layer elements one above the other or the last layer element, respectively, of the fuel cell stack to be produced, and thus to stack or arrange the layer elements one above the other. Each layer element has an elastically deformable fuel cell layer which is bordered by sealing strips. In this case, the fuel cell layer of each layer element is concavely curved with respect to the sealing strip due to the effect of gravity. The lowermost or first layer of components is first arranged on a flexible substrate using a stacked module. Furthermore, the base plate is bent upwards against the force of gravity and is designed such that the fuel cell layer of the topmost or already stacked last layer element is bent upwards against the force of gravity and/or lifted and largely flattened or flattened on account of the force generated by the base plate.

The system has a bending actuator having at least one pin and disposed below the substrate. At least one pin is designed to exert a force on the substrate counter to the force of gravity and to bend the substrate upwards.

The at least one pin is also designed to act on the bendable, elastically deformable substrate at a location below the center of the fuel cell layer of the at least one layer element to be arranged above the substrate. For this purpose, at least one pin is arranged in a set position.

The stacking module is also designed for arranging the individual layer elements completely one above the other.

It is also possible for the system to have at least one sensor and a controller as additional components, depending on the definition. The sensor is here designed to detect, generally optically, the degree of bending of the fuel cell layer of the layer element currently located on the topmost layer. The controller is also designed to calculate, taking into account the determined degree of bending, the value of the force with which the base plate should press against the fuel cell layers in order to eliminate the bending of the fuel cell layers of the topmost layer element of the fuel cell stack and thus to flatten them. The controller is further designed for calculating the force to be exerted by at least one pin of the bending actuator on the substrate at the respective set position, taking into account the determined degree of bending.

With this method, it is therefore possible to compensate for the weight-related bending of the fuel cell layers with the elastically deformable substrate during the stacking process and thus to flatten at least the topmost or last layer element of the fuel cell layer to a large extent.

In a possible embodiment of the method, a curvature of the fuel cell layers of the fuel cell stack to be produced is compensated for by an embodiment of the system. The geometry of the fuel cell layer of the topmost or last layer element is thereby kept constant, since the fuel cell layer is now largely flattened or flattened by the system. Here, the stacking process is performed on an elastically deformable or bendable substrate. It is possible here if necessary, starting from the first layer element of the fuel cell stack to be produced, to already bend the base plate upward against the force of gravity. In one embodiment, the center of mass of the fuel cell layers which have been arranged one above the other in the case of a stacking process is arranged above at least one pin of the bending device on the bottom side of the base plate which faces away from the lowermost or first layer element. Furthermore, the at least one pin is moved in particular in the direction of the stacking process and thus against the direction of gravity, thereby acting on the base plate and the fuel cell layers arranged thereon and bending them upwards against the force of gravity.

By a step-by-step movement of the at least one pin against the direction of gravity, a bending of the fuel cell layers of the fuel cell stack to be produced, which is caused by the self-weight of the fuel cell layers, can be compensated. The fuel cell layer of the topmost or last layer element is therefore largely flattened or planar before the application of the further or additional layer element. The lamination process can therefore be carried out identically for each individual fuel cell layer of the individual layer elements arranged as the last layer element on the fuel cell stack produced to date. The fuel cell layer of the layer element currently arranged on the last layer element arranged last on the fuel cell stack is now arranged on the largely flat or flattened fuel cell layer of the previously arranged layer element.

For example, since the fuel cell layers can now be arranged on a flat plane, typically on a previously flat fuel cell layer, it is no longer necessary to use clamps that have to dynamically adjust the current state of the fuel cell stack. In contrast, with this method, identical process conditions can be provided for each layer element and thus for each fuel cell layer, irrespective of the respective current height of the fuel cell stack. Since the grippers can now be omitted, the complexity of the equipment for stacking the fuel cell stack and the work to be performed is also reduced. Furthermore, reliability may also be improved during the execution of the stacking process, thereby also speeding up the stacking process.

In this way, a plurality of flat layer elements, each having a fuel cell layer, can be stacked to form a fuel cell stack. In this case, each layer element comprises, in addition to the fuel cell layer, for example, an elastic sealing strip which surrounds or encloses the fuel cell layer of the layer element. In the context of this method, the respective layer element currently to be arranged on the fuel cell stack stacked up to now is generally grasped in each case by the stacking module and removed, for example, from a storage device provided for this purpose. The individual layer elements are stacked one on top of the other by means of the stack module, wherein a common fuel cell stack is formed from the layer elements. The bending of the fuel cell layer of the respective topmost layer element, which is usually concave due to gravity, is overcome by the force and thus the convex bending of the fuel cell layers of the layer elements arranged below this topmost layer element. The forces generated by the base plate and thus the resulting convex curvature are transmitted via all fuel cell layers already arranged one above the other to the topmost fuel cell layer.

The bendable base plate arranged below the fuel cell stack to be produced is bent convexly upwards against the force of gravity by means of at least one pin of the controllable bending drive. As a result, the fuel cell layers of the respective topmost layer element are at least approximately or largely planar and are therefore planar.

The stack module or the corresponding manipulator is designed to respectively grasp the layer element currently to be placed on the fuel cell stack and to place it on the last layer element arranged so far on the fuel cell stack. During such stacking, the force of the convexly bendable base plate loaded by the bending actuator acts on the fuel cell layer of the layer element stacked immediately before on the fuel cell stack. The controller is designed to actuate the bending actuator and to specify for it the value of the force applied to the substrate, which in turn results in the fuel cell layer of the respective topmost layer element being at least approximately flat. The value of the force is determined, for example, on the basis of the current degree of bending of the fuel cell layer of the last stacked layer element, which bending is detected by the sensor. The at least one pin of the bending actuator is arranged, for example, below the center of the base plate, which in turn is arranged below the center of all fuel cell layers. The at least one pin can be moved in a motorized manner by the bending device against the force of gravity in the direction of the bottom side of the base plate.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the respectively given combination but also in other combinations or alone without departing from the scope of the present invention.

Drawings

The invention is illustrated by way of example in the accompanying drawings and is shown schematically and in detail with reference to the drawings.

Fig. 1 shows an example of a fuel cell stack known from the prior art in a schematic diagram.

Fig. 2 shows an embodiment of the system according to the invention in a schematic diagram.

Detailed Description

The fuel cell stack 2 shown schematically in fig. 1 is known from the prior art and comprises a plurality of layer elements 4 stacked one on top of the other, wherein each such layer element 4 has a flexible and bendable fuel cell layer 6 and a sealing strip 8 which borders the fuel cell layer 6. The fuel cell stack 2 is here shown arranged on a flat base 10. As shown in fig. 1, the fuel cell layer 6 of the layer member 4 is deformed by the action of gravity and its own weight and is concavely curved downward.

The embodiment of the system 20 according to the invention shown schematically in fig. 2 is designed for the production of a fuel cell stack 22. The fuel cell stack 22 in the course of production comprises a plurality of layer elements 24 stacked or stacked one on top of the other, wherein each layer element 24 has a flexible and bendable fuel cell layer 26 and a sealing strip 28 which borders the flexible and bendable fuel cell layer 26 and thus frames the fuel cell layer 26. It is noted here that the sealing strip 28 is thicker than the fuel cell layer 26.

The system 20 according to the invention comprises as components: a flexible substrate 30; a bending device 32, which in turn comprises a movable pin 34; a controller 36 for controlling an embodiment of a method of performing a stacking process for manufacturing the fuel cell stack 22; a sensor 38; and a stacking module 40.

At the beginning of the stacking process, the first layer elements 24 are arranged on the substrate 30 by means of the stacking module 40. A plurality of such layer elements 24 are then stacked one on top of the other in sequence by means of a stacking module 40. In this case, a possible curvature of the fuel cell layer 26 of the first or lowermost layer element 24 can be detected optically as early as from the latter, using a sensor 38, which is designed, for example, as a camera.

The stacking process is carried out in a defined or definable manner, provided that the fuel cell layers 26 of the layer elements 24 which are currently to be arranged on the already formed or hitherto formed fuel cell stack 22 are stacked on the most planar or planar fuel cell layers of the layer elements 24 which were previously stacked on the fuel cell stack 22, so that it is avoided that the fuel cell layers 26 of the topmost layer element 24 do not bend downward, as in the prior art, in a generally concave manner in the direction of gravity.

The sensor module 38 detects the degree of bending of the fuel cell layers 26 of the topmost layer element 24 and forwards it to the controller 36. The controller 36 is designed to calculate, based on the determined or detected degree of bending, a value of the force with which the pins 34 of the bending device 32 are pressed against the bottom side of the bendable substrate 30. This results in all fuel cell layers 26 of all stacked layer elements 24 being bent convexly upward against the force of gravity. The value of the force to be set is determined as a function of the degree of bending, whereby the fuel cell layers 26 of the topmost layer element 24 are flattened or flattened, wherein at least the bending of the fuel cell layers 26 of the topmost layer element 24 is compensated.

By using the system 20 shown for carrying out the stacking process, possible preconditions are created for the continuous execution of the stacking process, since the fuel cell layers 26 of the layer elements 24 to be currently stacked on the fuel cell stack 22 to be produced can be stacked on the planar or flat fuel cell layers 26 of the last stacked layer element 24.

When the method is carried out by the system 20, the pins, which are movable parallel to the direction of gravity, are pressed against the underside of the bendable base plate 30, which is convexly bent upwards. As a result, the individual fuel cell layers 26 arranged on the base plate are deformed and bent upwards by the action of the pins 34 and of the base plate 30 and by the action of the individual fuel cell layers 26 on one another, whereby possible deformations of the fuel cell layers 26 due to their own weight are compensated. In the illustrated embodiment of the system 20, the pin 34 is disposed below the center of mass of the fuel cell stack 22. It is possible here that the force with which the pins press from below via the base plate 30 onto the fuel cell layers 26 of the fuel cell stack 22 corresponds to the weight of the fuel cell stack 22. The force generated by the base plate 30 and/or the pins 34 is oriented opposite to gravity.