WO2010054744A1 - Bipolar plate for a fuel cell arrangement, particularly for disposing between two adjacent membrane electrode arrangements in a fuel cell stack - Google Patents

Abstract

The invention relates to a bipolar plate (B) for a fuel cell having at least two plates (A, K) arranged plane-parallel to each other, of which one is designed as an anode plate (A) and the other as a cathode plate (K), a flow field being formed on the outer side of each by flow field channels (SK) introduced in the plates (A, K), each being permeable by a reaction material, wherein at least one refrigerant channel (KK) being formed between the anode plate (A) and the cathode plate (K) on the inner side thereof by negative structures of the flow field channels (SK). According to the invention, only flow structures for the inflowing or outflowing reaction material and the refrigerant, or only flow structure for the two reaction materials, are formed in reaction material inflow areas (RE) and/or reaction material outflow areas, respectively, of the bipolar plate (B).

Description

 Daimler AG

Bipolar plate for a fuel cell assembly, in particular for the arrangement between two adjacent membrane-electrode assemblies in a fuel cell stack

The invention relates to a bipolar plate for a fuel cell assembly, in particular for the arrangement between two adjacent membrane electrode assemblies in a fuel cell stack according to the features of the preamble of claim 1 and a fuel cell assembly according to the features of the preamble of claim 20.

A fuel cell arrangement or a fuel cell stack (also referred to as a stack for short) consists of a plurality of fuel cells, which are electrically connected in series and are arranged plane-parallel one above the other. Each fuel cell has, as electrodes in the form of gas diffusion electrodes, an anode, a cathode and an electrolyte arranged therebetween, for example in the form of a polymer electrolyte membrane (referred to as PEM for short), which together form a membrane electrode arrangement (MEA for short) ,

A bipolar plate (also called a bipolar separator plate unit) is arranged in each case between the membrane-electrode assemblies adjacent to the fuel cell stack. The bipolar plate serves the spacing of adjacent membrane-electrode assemblies, the distribution of fuel cell reactants, such as fuel and oxidant, the adjacent membrane electrode assemblies and the removal of the reactants in each provided to the membrane electrode Arrangements for open channels, the removal of the heat of reaction via a guided in separate coolant channels coolant and the establishment of an electrical connection between the anode and the cathode of adjacent membrane-electrode assemblies. The reactants used are a fuel and an oxidizing agent. Most gaseous reactants (in short: reaction gases) are used, for. For example, hydrogen or a hydrogen-containing gas (eg reformate gas) as fuel and oxygen or an oxygen-containing gas (eg air) as oxidant. Reactants are all substances involved in the electrochemical reaction understood, including the reaction products such. As water or residual fuel gas.

The respective bipolar plate consists of two plane-parallel interconnected moldings, in particular plates - an anode plate for connection to the anode of a membrane electrode assembly and a cathode plate for connection to the cathode of the other membrane-electrode assembly - or a plate with upper - and bottom introduced channel structures. At the one of the membrane electrode assembly facing surface of the anode plate while anode channels for distributing a fuel along a membrane-electrode assembly are arranged, wherein at the other membrane electrode assembly facing surface of the cathode plate cathode channels for distribution of the oxidant over the other membrane electrode assembly are arranged. The cathode channels and the anode channels are not connected to each other.

In this case, the cathode and anode channels are formed by depressions (referred to below as channels) which are separated from one another by elevations (referred to below as webs) on the surfaces of the anode and cathode plates which respectively face the membrane electrode assemblies. The cathode and anode plate are preferably shaped, in particular hollow embossed. The ridges and channels are produced, for example, discontinuously by forming, deep drawing, extrusion or the like, or continuously by rolling or drawing.

In order to achieve sufficient cost-effectiveness and low costs when using a fuel cell arrangement for a vehicle during operation, for example, the power per square meter cell area and thus the efficiency of the fuel cell is to be increased.

DE 103 92 682 T5 describes a fuel cell which is formed by alternately stacking an electrolyte-electrode arrangement and a pair of separators. The electrolyte-electrode assembly includes a pair of electrodes and an electrolyte interposed between the respective electrodes. A reactant gas supply passage and a reactant gas discharge passage extend the respective separators in a stacking direction. Thereby, at least one oxygen-containing gas or a fuel gas as a reactant gas to a reactant gas flow field, which is formed in a Separatorfläche, which faces said membrane electrode assembly, can be fed and discharged from this reactant gas flow field again. At least the respective reactant gas supply passage or said reactant gas discharge passage includes first and second straight portions elongated along two sides from a corner of the respective separator.

From US 2007/0154758 A1 a fuel cell stack is known, which comprises a coolant supply passage and a coolant discharge passage. These extend in a stacking direction and are connected to a coolant flow field. The coolant supply passage and the coolant discharge passage are disposed on horizontally opposite sides of a reactant gas flow field. The fuel cell stack further includes a venting opening extending in the stacking direction, which is disposed on the coolant flow field such that it is higher than the highest part of the coolant flow field. A drainage opening extending in the stacking direction is arranged on the coolant flow field in such a way that it lies lower than the lowest part of the coolant flow field.

US 2004/0106028 A1 describes a fuel cell in which a coolant supply passage, a coolant discharge passage and a vent opening in the stacking direction extend through a bipolar plate. The coolant supply passage and the coolant discharge passage are arranged centrally at horizontally opposite ends of the bipolar plate. In between, a coolant flow field is arranged. The vent opening for bleeding the coolant flow field is disposed above the coolant discharge passage. At least part of the vent opening is arranged above the highest part of the coolant flow field.

The invention has for its object to provide a bipolar plate for a fuel cell, which is improved over the known from the prior art bipolar plates. In addition, an improved fuel cell assembly is to be specified. The object is achieved in terms of the bipolar plate according to the invention by the features specified in claim 1. With regard to the fuel cell assembly, the object is achieved by the features specified in claim 20.

Preferred embodiments and further developments of the invention are specified in the dependent claims.

A bipolar plate for a fuel cell, in particular for the arrangement between two adjacent membrane electrode assemblies in a fuel cell stack, conventionally comprises two plates arranged plane-parallel to each other, one of which is formed as an anode plate and the other as a cathode plate, on the outer sides of each one Flow field is formed by introduced into the plates flow field channels, which are each traversed by a reactant, wherein between the anode plate and the cathode plate on the inner sides by negative structures of the flow field channels at least one coolant channel is formed.

According to the invention, only flow structures for the respective inflowing or outflowing reactant and the coolant or only flow structures for the two reactants are respectively formed in the reactant inflow regions and / or the reactant outflow regions of the bipolar plate.

By reducing the number of flow structures, the bipolar plate is flatter, with deeper flow structures in the reactant inflow regions. A fuel cell stack is therefore more compact executable. This is particularly important in applications in which only a limited space is available, for example in fuel cell vehicles, of great importance. Due to the lower flow structures, a better distribution of the reactants to flow field channels of the flow field can be achieved and a compressor power required for this lower, whereby an improved efficiency can be achieved by an increased power density of the fuel cell.

As a result of the solution according to the invention, it is achieved that the coolant and the reactants, in particular a cathode gas, flow largely parallel, so that a favorable temperature gradient, ie a temperature progression rising from a start to one end of a cathode gas duct, can be achieved. In this way is a little humidified or not moistened cathode gas can be introduced without the drying of a polymer electrolyte membrane in the region of the beginning of the cathode gas channel is to be feared. As the temperature in the flow direction gradually increases, the ability of the cathode gas to absorb water arising during the electrochemical reaction increases. As a result, no liquid water can form, which could clog the channels.

In order to achieve an optimal distribution of the channels on the bipolar plate, whereby an available space on the bipolar plate can be used efficiently, reactant entrances, a Kuhlmitteleingang, reactant exits and a coolant outlet are preferably arranged in respectively different, separate regions of the bipolar plate. As a result, an optimal supply and removal of the reactants and the coolant and the smallest possible dimensions of the fuel cell can be achieved.

In a preferred embodiment, inflow channels are arranged in the reactant inflow regions and outflow channels in reactant outflow regions, whereby the reactants can be distributed optimally and uniformly to the channels of the respective flow field.

In this embodiment, the coolant inlet preferably opens into the reactant inflow region of the bipolar plate and / or the coolant outlet leads away from the reactant outflow region of the bipolar plate. Since inflow channels or outflow channels are arranged in each of these areas, which occupy approximately half the thickness of the bipolar plate on only one plate, the other half of the thickness of the bipolar plate can be used for the coolant. As a result, both an optimal cooling of the reactants from the beginning and optimum delivery of both the reactants and the coolant to the flow field can be achieved.

Since inflow channels of a flow field inflow region and / or outflow channels of a flow field outflow region are preferably arranged on the anode plate in the flow direction perpendicular to the inflow channels of the flow field inflow region and / or outflow channels of the flow field outflow region on the cathode plate, unimpeded inflow of the coolant is also provided formed gaps between the intersecting inflow channels of Anode plate and cathode plate through in the flow field area and similarly ensured an unhindered outflow of the coolant.

In a further preferred embodiment, the coolant inlet opens directly into the flow field region of the bipolar plate and / or the coolant outlet leads directly from the flow field region of the bipolar plate. In this embodiment, the reactant inflow region can be used for optimum inflow and distribution of the reactants, since the entire thickness of the bipolar plate can be used in half to form flow structures for the reactants on the anode plate or on the cathode plate.

Conveniently, the flow field channels of the flow field are arranged to run straight in the flow direction, whereby an optimal flow of the reactants and optimal utilization of the available space on the bipolar plate for the flow field and thus optimizing the power density of the fuel cell is reached.

Preferably, a number of flow field channels twice the number of inflow channels are arranged in the flow field, wherein in each case one inflow channel of the flow field inflow region opens into two flow field channels of the flow field and two flow field channels of the flow field each open into an outflow channel of the flow field outflow region. As a result, relatively small dimensions of reagent entrances or reactant exits can be achieved, so that they can be arranged in different regions of the bipolar plate. At the same time, however, this arrangement ensures that the entire flow field can be optimally supplied with the reactants, i. an entire width of the bipolar plate can be used for the flow field. Since in this way a longitudinal extent of the flow field inflow region or of the flow field outflow region is relatively small, the available installation space of the bipolar plate in the longitudinal direction can be used optimally for the flow field or a longitudinal extent of the bipolar plate and thus a size of the fuel cell can be reduced.

In a further embodiment, the number of flow field channels in the flow field and / or the number of inflow channels in the flow field inflow region and / or the number of outflow channels in the flow field outflow region are identical. This is achievable by stretching reaction material entrances or reaction substance outlets in the longitudinal direction of the bipolar plate. In this way, the entire flow field is optimally supplied with the reactants, but this is associated with a slightly larger longitudinal extent of the flow field inflow region or the flow field-outflow region.

In a further embodiment, the flow field channels of the flow field in the flow direction are wavy or serpentine. In this way, also relatively small dimensions of reactant entrances or Reaktionsstoffausgängen be achieved, while still ensuring that the entire flow field is optimally supplied with the reactants, i. an entire width of the bipolar plate can be used for the flow field by the channels covering the area of the flow field in a wave-like or serpentine manner. In this way, again a longitudinal extent of the flow field inflow region or the flow field outflow region is relatively small, so that the available space of the bipolar plate in the longitudinal direction can be used optimally for the flow field or a longitudinal extent of the bipolar plate and thus a size of the fuel cell can be reduced. Of course, regardless of the particular embodiment, this also contributes to the parallel arrangement of the flow field channels of the flow field. By means of these various embodiments, in each case an optimal design of a channel structure can be used, depending on the respective intended use as well as other factors, such as, for example, production possibilities, expenditure and costs for the bipolar plate.

In all these embodiments, the flow field channels of the flow field and the inflow and outflow preferably have an identical depth, so that an optimal flow and flow through the flow field is secured with reactants and therefore a required compressor power compared to the prior art can be reduced and thus an optimal Power density of the fuel cell can be achieved.

Preferably, in addition to the flow field region of the bipolar plate, the flow field inflow region and the flow field outflow region can be used as active regions of the fuel cell for generating electrical energy, whereby a power density of the fuel cell is significantly optimized. This represents over the prior art, a much more efficient space utilization, so that by the inventive solution with the same space much more efficient fuel cells can be produced or at a constant power a considerable space reduction can be achieved.

Preferably, corresponding channels of the anode plate and the cathode plate have an identical flow area, i. The thickness of the bipolar plate can be used in each case half of channels of the anode plate and the cathode plate, this being true for the entire channel structure of the bipolar plate by the solution according to the invention, so that an optimal supply of the fuel cell with reaction gases ensures an optimal sequence of the electrochemical reaction for energy generation is.

Preferably, in a region of the bipolar plate in which the flow fields of the anode plate and the cathode plate are arranged, the flow directions of the reactants and the coolant are equal to or opposite to each other, i. either in the same direction or parallel in the opposite direction. As a result, both an optimal cooling of the reactants and an optimal sequence of the electrochemical reaction for energy production by a uniform supply of the reactants and their optimal cooling is ensured.

For a simple and inexpensive to produce bipolar plate with a homogenous as possible reagent supply is provided that all inflow passages of the respective plate depart from a common reagent inlet. In this case, the reactant inlet depending on the associated electrode as the reactant, a gaseous reaction or fuel, eg. As hydrogen or a hydrogen-containing gas, or an oxidizing agent, for. As oxygen or an oxygen-containing gas, for. As air, fed. Analogously, all discharge channels of the respective plate expire expediently into a common reagent outlet, via which water or steam and / or a residual combustion gas can be discharged as reaction products.

Expediently, all the coolant channels of the bipolar plate likewise depart from a common coolant inlet or open into a common coolant outlet in order to ensure the most effective possible cooling of the fuel cell. For a robust construction and easy insertion of the entire channel structure, the two plates are made of metal. In this case, the channel structure in the respective plate by forming stretching, deep drawing, extrusion or the like, or continuously by rolling or drawing can be introduced.

With regard to the fuel cell arrangement with a plurality of stacked fuel cells, which are designed as a membrane-electrode arrangement with an electrolyte membrane arranged between two gas diffusion electrodes, it is provided that in each case a bipolar plate according to the invention is arranged between two adjacent fuel cells.

The bipolar plate according to the invention is preferably used in a fuel cell arrangement. In this case, the fuel cell arrangement may be a number of stacked polymer electrolyte membrane fuel cells, between each of which a bipolar plate is arranged.

Embodiments of the invention will be explained in more detail with reference to drawings.

Showing:

1 is a schematic representation of a bipolar plate,

2 shows a representation of a cross section in a flow field region,

3 is a schematic representation of a bipolar plate with undulating channels,

4 is a schematic representation of a bipolar plate with serpentine channels,

Fig. 5 is a schematic representation of a bipolar plate with the same number

Flow field channels in a flow field region and inflow channels in a flow field inflow region, and

Fig. 6 shows another embodiment of the solution according to the invention. Corresponding parts are provided in all figures with the same reference numerals.

Figure 1 shows a schematic representation of a bipolar plate B. The illustrated bipolar plate B comprises two plane-parallel plates A, K, of which one is formed as the anode plate A and the other as the cathode plate K. On outer sides of the plates A ₁ K, a respective flow field S is formed by flow field channels SK introduced into the plates A ₁ K. These flow fields S are each traversed by a reactant, which in this way a gas diffusion layer, not shown, for example, a membrane-electrode assembly, a fuel cell for power generation can be fed. Between the anode plate A and the cathode plate K, coolant channels KK are formed on their insides by negative structures of the flow field channels SK. A depth of the flow field channels SK in each outer side of the plate A, K corresponds approximately to half the thickness of the bipolar plate B. The flow field channels SK of the two plates A, K are arranged exactly above one another so that bottom regions of the flow field channels SK touch the plates A ₁ K. , As a result, on the one hand, an effective and cost-effective support structure of the bipolar plate B is formed, on the other between the two plates A, K between the contacting with the bottom region flow field channels SK gaps are formed, which are used as coolant channels KK.

2 shows a cross section through a flow field region of the bipolar plate B, which illustrates the structure of an entire channel structure of the bipolar plate B in this area. Here clearly visible are the two plates A, K of the bipolar plate B with the respective flow field channels SK, which rest on one another, and the coolant channels KK formed thereby between the two plates A, K. The flow field channels SK on the outer sides of the plates A, K use in each case half the thickness of the bipolar plate B, between the full thickness of the bipolar plate B is available for the coolant.

In the region of transverse sides of the bipolar plate B reaction material inputs RA, RK or reaction material outputs and a coolant inlet KE or a coolant outlet are arranged. Only one transverse side of the bipolar plate B is shown in FIG. 1, ie two reagent inputs RA ₁ RK and one coolant input KE, since the corresponding outputs are arranged analogously thereto. Reactant inputs RA, RK include a reagent inlet RA on the cathode plate K of the bipolar plate B and a reagent inlet RK on the anode side A of the bipolar plate B. The coolant inlet KE is provided for introducing a coolant between the plates A, K of the bipolar plate B.

In the solution according to the invention, the reagent inputs RA, RK and outputs and the coolant inlet KE and output on the bipolar plate B are all spatially separated from each other. Immediately before each reactant inlet RA ₁ RK is a reactant inlet area RE arranged, analogous to, not shown here, immediately before the respective Reaktionsstoffausgang a reactant outflow area. In the illustrated embodiment, inflow channels EK for inflowing the respective reactant or outflow channels for outflow of the respective reaction substance are arranged in each of these reactant inflow regions RE and reactant outflow regions in each case only on one plate A, K. The respective full channel depth is half the thickness the bipolar plate B corresponds, have. Thereby, a space between the plates A, K, in which the respective other channels would extend, is completely available for distributing the coolant in these reactant inflow regions RE or reactant outflow regions. This is made possible by the already mentioned spatial separation of the reagent entrances RA, RK or outputs on the bipolar plate B. This achieves an immediate effective cooling of each inflowing reactant and an optimal inflow and distribution of the reactants and the coolant.

In this way, over the prior art, a thinner design of the bipolar plate B with a constant distribution of the reactants and the coolant or a constant thickness of the bipolar plate B allows a much improved distribution. According to the state of the art, channel structures are arranged on both plates A, K in these areas. However, since these channel structures do not run parallel in these areas but cross each other, they can only be implemented with reduced depth in bipolar plates B according to the prior art in order to be able to conduct both the reactants and the coolant through this area. This results in increased pressure losses, whereby a higher compressor power is required and an efficiency of the fuel cell is reduced. Furthermore, due to the smaller depth of the channel structures, an optimal distribution of the reactants and of the coolant to the respective channels SK, KK in the flow field S is made more difficult. Between the reactant inflow regions RE or the reactant outflow regions and the flow field S, a flow field inflow region SZ or an unillustrated flow field outflow region is arranged. In this flow field inflow area SZ or flow field discharge area, inflow passages EK or outflow passages of both plates A, K of the bipolar plate B, but are still formed with full channel depth, as the coolant through spaces between the crossing inflow channels EK and outflow to the flow field S feasible or can be discharged from this. Since both reactants are guided through the inflow channels EK or outflow channels in this flow field inflow region SZ or flow field outflow region, the flow field inflow region SZ or the flow field outflow region can be used in addition to the flow field S as active regions of the fuel cell for energy generation optimal use of a space of the fuel cell is reached. A performance of such a fuel cell is therefore significantly increased with the same space requirements or a space requirement of the fuel cell can be significantly reduced at the same power. This is particularly important when using fuel cells, for example for power generation in vehicles of great importance, since only a very limited space is available.

By means of the solution according to the invention, it is achieved that the coolant and the reactants, in particular a cathode gas, flow largely parallel over large parts of the bipolar plate B, thereby producing a favorable temperature gradient, ie. a temperature profile increasing from a beginning to an end of the channel structure can be achieved. In this way, a little moistened or not humidified cathode gas can be introduced without the drying out of a polymer electrolyte membrane in the region of the beginning of a cathode gas channel is to be feared. As the temperature in the flow direction gradually increases, the ability of the cathode gas to absorb water arising during the electrochemical reaction increases. As a result, no liquid water can form, which could clog the entire channel structure.

In the exemplary embodiment illustrated here, dimensions of the reactant entrances RA, RK and / or outlets are kept as small as possible in order to allow the largest possible active area of the fuel cell in this way. However, this means that only a limited number of inflow channels EK for inflow and distribution of the reactants or outflow for the derivation of Reactants can be arranged, which are to be distributed to the flow field S with much more flow field channels SK, in the illustrated embodiment, the double number flow field channels SK ₁ . In order to make this possible, in each case an inflow channel EK of the flow field inflow region SZ or an outflow channel of the flow field outflow region is connected to two flow field channels SK of the flow field S so that the reactants can be distributed uniformly to the respective flow field S or can be diverted therefrom ,

FIG. 3 shows a further possibility, on the one hand, of making the reactant entrances RA, RK or outputs as small as possible, but nevertheless to use a full width of the bipolar plate B for the flow field S. In the exemplary embodiment shown here, in which, for the sake of clarity, only the cathode plate K of the bipolar plate B is shown, this is realized by wave-shaped flow field channels SK of the flow field S. In this way, an area available for the flow field S on the bipolar plate B can also be used optimally in order to achieve an optimum power density of the fuel cell. By changing the amplitude of these wave-shaped flow field channels SK of the flow field S, a design of the bipolar plate B is variable, d. H. the bipolar plate B, for example, longer or shorter executable in the longitudinal direction and optimally adaptable to the fuel cell or the fuel cell to be manufactured optimally adapted to the respective requirements, for example to an available space in a vehicle. The flow field channels SK of the flow field S on the anode plate A of the bipolar plate B are arranged analogously thereto. The reactant inflow region RE, the reactant outflow region as well as the flow field inflow region SZ and the flow field outflow region of the illustrated embodiment are analogous to the embodiment already illustrated and explained in FIG.

FIG. 4 shows a further embodiment. Here is a course of the flow field channels SK of the flow field S for optimum utilization of the surface on the bipolar plate B, which is available for the flow field S, serpentine-shaped. In this case, a width of the flow field S in the exemplary embodiment illustrated here is subdivided into three regions B1, B2, BM. A first outer region B1 extends along a first longitudinal side of the flow field S and has approximately one third of the width of the flow field S, a second outer region B2 extends along a second longitudinal side of the flow field S and likewise has approximately one third of the width of the Flow field S on. A middle one Region BM of the flow field S extends between the first outer region B1 and the second outer region B2 of the flow field S in a middle third of the width of the flow field S.

The flow field channels SK extend from the flow field inflow region SZ in the flow direction through the first outer region B1 of the flow field S to a transverse side of the flow field S opposite the flow field inflow region SZ, where they are in a 180 ° curve in the middle region BM of the flow field S open. In this middle region BM of the flow field S, the flow field channels SK run parallel and counter to the flow direction to a transverse side of the flow field S opposite the flow field discharge region, at which they open, describing a 180 ° curve, into the second outer region B2 of the flow field S. and in this second outer region B2 of the flow field S run parallel and in the flow direction to the flow field discharge region. In this way, the flow field channels SK of the illustrated embodiment form three serpentines, which run through these three regions B1, B2, BM of the flow field S. The illustrated embodiment thus offers a further possibility of making the reagent entrances RA, RK or outputs as small as possible, but nevertheless to utilize a full width of the bipolar plate B for the flow field S. Of course, a larger number of serpentines are possible in other embodiments.

The reactant inflow region RE, the reactant outflow region as well as the flow field inflow region SZ and the flow field outflow region of the illustrated embodiment are similar to the embodiment already illustrated and explained in FIG. In particular, according to the solution according to the invention in the reactant inflow region RE or the reactant outflow region, inflow channels EK are formed only on one plate A, K.

FIG. 5 shows a further exemplary embodiment. For the sake of clarity, in turn only one side of the bipolar plate B is shown. In this embodiment, the flow field channels SK of the flow field S, analogous to Figure 1, run straight again. In this exemplary embodiment, however, an identical number of inflow channels EK are arranged both in the flow field S and in the flow field inflow regions SZ or flow field outflow regions. To achieve this, the Reagent inputs RA, RK and outputs increased. Since, however, it must furthermore be ensured that a channel structure is formed in each of the respective reactant inflow regions RE or reactant outflow regions only on one plate A, K, these are

Reactant inputs RA, RK and exits in the longitudinal direction of the bipolar plate B increases. In this way, an identical number of inflow passages EK can be led out of the reactant material inlets RA, RK, or an identical number of outflow passages can be introduced into the reactant outlets, as are arranged in the flow field S.

FIG. 6 shows a further embodiment of the solution according to the invention, which, however, deviates in its mode of operation from the previously illustrated embodiments. In this embodiment, between the reagent entrances RA, RK and -ausgängen and the flow field S, only the reactant inlet area RE or reactant outflow area of the bipolar plate B is arranged, in which no inflow channels EK or outflow as flow structures, but only Leit- and Support elements L are arranged. These have both a guiding function for the inflowing reactants in order to distribute them optimally to the flow field channels SK of the flow field S, as well as analogous to channel walls of the flow field channels SK, a support function for the voltage applied to these, not shown gas diffusion layer of the fuel cell.

Contrary to the other illustrated embodiments of the solution according to the invention, in each of which flow structures for a reactant and the coolant are arranged in these areas, flow structures for both reactants are arranged in this embodiment. Thus, the thickness of the bipolar plate B can be used in half for the flow structures of the reactants, whereby an optimal inflow of the reactants and an optimal distribution to the flow field channels SK of the flow field S is ensured, with the already described advantages of the inventive solution over the prior art ,

The coolant inputs KE and outputs are arranged in this embodiment, the side of the flow field S, respectively in the region of an input or output of the flow field S. However, the flow field channels SK of the flow field S for the reactants in these areas partially not with the full Can be executed channel depth, ie in some places, the channel bottoms must not touch, so that passages for a cross-connection between the coolant inputs KE and -ausgängen and the cooling channels KK of the flow field region of the bipolar plate B are formed to flow through the coolant.

This, as well as the not yet optimally parallel to the reactants in this area flowing coolant, although a disadvantage compared to the other illustrated embodiments of the inventive solution, but in the vast majority of the flow field S this optimally parallel flow of the coolant and the reactants ensured , Compared to the prior art, this embodiment of the solution according to the invention is also associated with considerable advantages due to a higher power density, an optimum inflow and distribution of the reactants and a lower required compressor output.

By a large number of possible embodiments of bipolar plates B according to the solution according to the invention, an optimal embodiment can be used for the respective field of application and in this way a fuel cell or a fuel cell stack can be optimized and produced, for example, depending on the required power and the available installation space, wherein by means of the invention Solution over the prior art more efficient or smaller fuel cells can be produced.

Daimler AG

LIST OF REFERENCE NUMBERS

B bipolar plate

A anode plate

K cathode plate

L Guide and support elements

KE coolant inlet RA, RK reactant inlet

S flow field

RE reactant inflow area

SZ flow field inflow area

EK inflow channels

SK flow field channels

KK coolant channels

B1 first outer area

B2 second outer area

BM middle range

Claims

Daimler AG patent claims 1. bipolar plate (B) for a fuel cell with at least two plane-parallel plates (A, K), one of which is formed as an anode plate (A) and the other as the cathode plate (K), on the outer sides of each of which a flow field (S ) is formed by introduced into the plates (A, K) flow field channels (SK), which are each traversed by a reactant, wherein between the anode plate (A) and the cathode plate (K) on their insides by negative structures of the flow field channels (SK) at least a coolant channel (KK) is formed, characterized in that in the reactant inflow regions (RE) and / or reactant outflow regions of the bipolar plate (B) only flow structures for each inflowing or outflowing reactant and the coolant or only flow structures for the two reactants are formed. 2. bipolar plate (B) according to claim 1, characterized in that Reactant entrances (RA, RK), a coolant inlet (KE), reactant exits and a coolant outlet are arranged in different, separate areas of the bipolar plate (B). 3. bipolar plate (B) according to claim 1 or 2, characterized in that in the reactant inflow regions (RE) inflow channels (EK) and in the reactant outflow areas Ausströmkanäle are arranged. 4. bipolar plate (B) according to claim 2 or 3, characterized in that the coolant inlet (KE) in the reactant inflow region (RE) of the bipolar plate (B) opens and / or the coolant outlet of the reactant outflow region of the bipolar plate (B) dissipates. 5. bipolar plate (B) according to claim 3 or 4, characterized in that Einströmkanäle (EK) of a flow field inflow area (SZ) and / or outflow of a flow field discharge area on the anode plate (A) in the flow direction perpendicular to inflow channels (EK) of the Flow field inflow area (SZ) and / or outflow of the flow field-discharge area on the cathode plate (K) are arranged. 6. bipolar plate (B) according to any one of the preceding claims, characterized in that the coolant inlet (KE) opens directly into a flow field region of the bipolar plate (B) and / or discharges the coolant outlet directly from the flow field region of the bipolar plate (B). 7. bipolar plate (B) according to any one of the preceding claims, characterized in that the flow field channels (SK) of the flow field (S) are arranged to extend straight in the flow direction. 8. bipolar plate (B) according to any one of the preceding claims, characterized in that in the flow field (S) to the number of inflow channels (EK) double the number of flow field channels (SK) are arranged, wherein in each case an inflow channel (EK) of the flow field inflow area (SZ) opens into two flow field channels (SK) of the flow field (S) and in each case two flow field channels (SK) of the flow field (S) open into an outflow channel of the flow field discharge region. 9. bipolar plate (B) according to any one of the preceding claims, characterized in that the number of flow field channels (SK) in the flow field (S) and / or the number of inflow channels (EK) in the flow field Inflow area (SZ) and / or the number of outflow channels in the flow field discharge area is identical. 10. bipolar plate (B) according to any one of the preceding claims, characterized in that the flow field channels (SK) of the flow field (S) in the flow direction wave-shaped. 11. Bipolar plate (B) according to one of the preceding claims, characterized in that the flow field channels (SK) of the flow field (S) run serpentine in the flow direction. 12. bipolar plate (B) according to any one of the preceding claims, characterized in that the flow field channels (SK) of the flow field (S) parallel to each other. 13. bipolar plate (B) according to any one of the preceding claims, characterized in that the flow field channels (SK) _1, the inflow channels (EK) and the outflow channels have an identical depth. 14. Bipolar plate (B) according to one of the preceding claims, characterized in that the flow field inflow region (SZ) and the flow field discharge region can be used as active regions of the fuel cell for generating electrical energy. 15. Bipolar plate (B) according to one of the preceding claims, characterized in that corresponding channels (EK, SK) of the anode plate (A) and the cathode plate (K) have an identical flow cross-section. 16. Bipolar plate (B) according to one of the preceding claims, characterized in that in a region of the bipolar plate (B), in which the flow fields (S) of the anode plate (A) and the cathode plate (K) are arranged, the flow directions of the reactants and the coolant in the same direction or in opposite directions to each other. 17. Bipolar plate (B) according to one of the preceding claims, characterized in that all inflow channels (EK) of the respective plate (A, K) depart from a common reagent inlet (RA, RK) and / or all outflow channels of the respective plate (A, K) open into a common reagent outlet. 18. Bipolar plate (B) according to any one of the preceding claims, characterized in that all the coolant channels (KK) of the bipolar plate (B) depart from a common coolant inlet (KE) and open into a common coolant outlet. 19. bipolar plate (B) according to any one of the preceding claims, characterized in that the plates (A, K) are made of metal. 20 fuel cell assembly having a plurality of stacked fuel cells, which are formed as a membrane-electrode assembly with an arranged between two gas diffusion electrodes electrolyte membrane, wherein between at least two fuel cells each have a bipolar plate (B) is arranged according to one of claims 1 to 19. 21. Use of a bipolar plate (B) according to one of claims 1 to 19 in a fuel cell assembly of a number of stacked polymer electrolyte membrane fuel cells, between which the bipolar plates (B) are arranged.