DE102022000333A1 - Bipolar plate for a fuel cell - Google Patents

Abstract

A bipolar plate (10) for a fuel cell is described, the bipolar plate (10) consisting of a pair of reactant sub-plates, such as a hydrogen sub-plate (12) and an atmospheric oxygen sub-plate (14), which have planar inner surfaces ( 16, 18) are tightly and firmly connected to one another and whose outer surfaces (20, 26) are each formed with longitudinal ribs (22, 28) which are spaced apart from one another by longitudinal grooves (24, 30), the longitudinal ribs (22 ) of the hydrogen partial plate (12) and the longitudinal ribs (28) of the atmospheric oxygen partial plate (14) are opposite, and wherein at least the atmospheric oxygen partial plate (14) is formed on its flat inner surface (18) with longitudinal water channels (32) for the water of reaction which are fluidly connected to at least a number of longitudinal grooves (30) of the atmospheric oxygen partial plate (14).

Description

The invention relates to a bipolar plate for a fuel cell.

The DE 10 2012 210 066 A1 describes a method for producing a graphite bipolar plate for a fuel cell. The bipolar plate has a channel structure with a closed cross section over large areas for guiding a fluid. In this method, graphite powder and a carbonaceous binder are press-molded. The channel structure is represented by a lost mandrel that is thermally removed from the molded bipolar plate.

A similar method for producing a bipolar plate for a fuel cell is from WO 2004/021491 A1 known. The bipolar plate has a flow field for an oxidizing agent on its one outer surface and a flow field for a fuel on its other outer surface facing away from it. In its interior, at a distance from the outer surfaces, the bipolar plate has channels for a cooling medium. The bipolar plate can be made of a graphite material. To produce the channels for the coolant, a volatile material can be embedded in the material of the bipolar plate, which is removed from the bipolar plate by thermal means.

The invention is based on the object of creating a bipolar plate of the type mentioned at the outset, in which case the water of reaction generated during the reaction of hydrogen with atmospheric oxygen in the fuel cell is reliably discharged from the fuel cell, so that the membrane arranged between the pair of bipolar plates of the fuel cell can also a long service life of the fuel cell is not exposed to too much reaction water and remains optimally functional.

This object is achieved according to the invention by the features of claim 1, i.e. that the bipolar plate consists of a pair of reactant sub-plates, such as a hydrogen sub-plate and an atmospheric oxygen sub-plate, which are tightly and firmly connected to one another with their flat inner surfaces and the outer surfaces of which are each formed with longitudinal ribs which are spaced apart from one another by longitudinal grooves, the longitudinal ribs of the hydrogen partial plate and the longitudinal ribs of the atmospheric oxygen partial plate being opposite one another, and that at least the atmospheric oxygen partial plate is formed on its flat inner surface with longitudinal water channels for the water of reaction , which are fluidically connected to at least a number of longitudinal grooves of the atmospheric oxygen partial plate.

A defined drainage of the water of reaction produced during the reaction of the hydrogen with the atmospheric oxygen in the fuel cell from the fuel cell is achieved if the longitudinal water channels are provided congruently with the longitudinal grooves of the atmospheric oxygen partial plate. The longitudinal water channels and the longitudinal grooves of the atmospheric oxygen partial plate are fluidically connected to one another by connecting sections which preferably extend between the bottom of the longitudinal grooves and the longitudinal water channels and which are spaced apart from one another in the longitudinal direction. The connecting sections can be designed as holes or longitudinal slots.

It is particularly advantageous if, in the bipolar plate according to the invention, the hydrogen partial plate is also formed on its flat inner surface with longitudinal water channels which are provided congruently with the longitudinal water channels of the atmospheric oxygen partial plate. This results in longitudinal water channels with a relatively large clear cross section. The longitudinal water channels can be designed with an angular, round or oval clear cross-section.

Optimal water drainage from the bipolar plate according to the invention and consequently from a fuel cell with a pair of bipolar plates according to the invention results when the clear cross section of the longitudinal water channels and the clear cross section of the longitudinal grooves of the partial oxygen plate are at least approximately matched to one another.

Since the operating temperature of a fuel cell can be very high during operation and overheating must be avoided, it has proven to be particularly advantageous if the air-oxygen partial plate and the hydrogen partial plate are formed congruently with cooling water channels on their flat inner surfaces, which are located between the longitudinal water channels , spaced from these, are provided. Through the cooling water channels, a suitable cooling medium such as cooling water or the like. passed through to keep the respective bipolar plate at a suitable operating temperature.

In order to reliably prevent hydrogen from escaping from the fuel cell, it is preferred if a sealing frame runs around the edge of the bipolar plate, which is designed with inlets for the reactants and the cooling medium and with outlets for the reaction and cooling water.

Further details, features and advantages result from the following description in connection with the enclosed drawings.

• 1 in einer Schnittdarstellung einen Abschnitt einer ersten Ausführungsform der Bipolarplatte,
• 2 in einer der 1 ähnlichen Darstellung eine zweite Ausführungsform der Bipolarplatte,
• 3 in einer den 1 und 2 ähnlichen Schnittdarstellung einen Abschnitt einer dritten Ausführungsform der Bipolarplatte,
• 4 noch eine andere Ausführungsform der Bipolarplatte in einer den 1 bis 3 ähnlichen, abschnittweisen Schnittdarstellung, und
• 5 eine abschnittweise Ansicht in Blickrichtung des Pfeiles V in 1 auf eine Bipolarplatte gemäß den 1 bis 4, in welchen neben den jeweiligen Bipolarplatten auch zwei Brennstoffzellenmembranen verdeutlicht sind.

Show it:

• 1 in a sectional view a section of a first embodiment of the bipolar plate,
• 2 in one of the 1 Similar representation a second embodiment of the bipolar plate,
• 3 in a den 1 and 2 similar sectional view of a section of a third embodiment of the bipolar plate,
• 4 yet another embodiment of the bipolar plate in a den 1 until 3 similar, sectional view, and
• 5 a sectional view looking in the direction of arrow V in 1 on a bipolar plate according to the 1 until 4 , in which two fuel cell membranes are illustrated in addition to the respective bipolar plates.

1 12 shows an embodiment of the bipolar plate 10 comprised of a pair of compression molded reactant sub-plates, such as a hydrogen sub-plate 12 and an atmospheric oxygen sub-plate 14. FIG. The hydrogen sub-plate 12 has a planar inner surface 16 and the air-oxygen sub-plate 14 has a planar inner surface 18 . The hydrogen part-plate 12 and the air-oxygen part-plate 14 are tightly and mechanically firmly connected to one another. This is preferably a material-locking connection.

The hydrogen sub-plate 12 has an outer surface 20 formed by longitudinal ribs 22 evenly spaced from one another by longitudinal grooves 24 . The air dividing plate 14 has an outer surface 26 formed by longitudinal ribs 28 which are equally spaced from one another by longitudinal grooves 30 . The longitudinal ribs 22 of the hydrogen part-plate 12 and the longitudinal ribs 28 of the air-oxygen part-plate 14 face one another in the assembled state to form the bipolar plate 10 . The bipolar plate 10 is formed with longitudinal water channels 32 for water of reaction, which are fluidically connected to the longitudinal grooves 30 of the atmospheric oxygen partial plate 14 by connecting sections 34 . The longitudinal water channels 32 are provided congruently with the longitudinal grooves 30 of the atmospheric oxygen partial plate 14, so that the connecting sections 34, which are fluidly connected to the longitudinal grooves 30 of the atmospheric oxygen partial plate 14, can be dimensioned with small length dimensions. For this purpose, it is preferred if the connecting sections 34 are formed between the bottom 36 of the longitudinal channels 30 and the longitudinal water channels 32. are formed between the bottom 36 of the longitudinal grooves 30 and the water longitudinal channels 32.

How out 5 As can be seen, the connecting sections 34 are spaced apart from one another in the longitudinal direction of the bipolar plate 10 . They can, for example, be designed as round holes or expediently as longitudinal slots.

while the 2 and 4 Bipolar plates 10, in which only the partial plate 14 for atmospheric oxygen is formed on its planar inner surface 18 with longitudinal water channels 32 which are fluidically connected to the longitudinal grooves 30 of the partial plate 14 for atmospheric oxygen 1 and 3 Bipolar plates 10, in which not only the atmospheric oxygen partial plate 14 but also the hydrogen partial plate 12 is formed on its flat inner surface 16 with longitudinal water channels 32 which are provided congruently with the longitudinal water channels 32 of the atmospheric oxygen partial plate 14. This ensures that the clear cross section of the longitudinal water channels can be relatively large.

The embodiments of the bipolar plate 10 according to the 1 and 2 differs from the embodiments of the bipolar plate 10 according to FIGS 3 and 4 also in that the bipolar plate 10 is formed not only with longitudinal water channels 32 for water of reaction but also with cooling water channels 38, which are formed between the longitudinal water channels 32 and at a distance from them, in order to avoid overheating during the operation of a fuel cell having bipolar plates 10 according to the invention.

With the reference number 40 are in the 1 until 4 each denotes membranes which are arranged between mutually adjacent bipolar plates 10 .

A sealing frame 42 runs around the edge of the respective bipolar plate 10, by means of which the bipolar plate 10 is reliably sealed against the environment. The sealing frame 42 is formed with inlets (not shown) for the reactants such as hydrogen and atmospheric oxygen and cooling medium such as cooling water, and with outlets (not shown) for reaction water and cooling water.

Identical details are denoted by the same reference numerals in the figures, so that it is not necessary to describe all details in detail in connection with all figures.

Reference List

10

bipolar plate

12

Hydrogen Part Plate (of 10)

14

Air Oxygen Part Plate (of 10)

16

flat inner surface (of 12)

18

flat inner surface (of 14)

20

Exterior (of 12)

22

longitudinal ribs (of 20)

24

Longitudinal gutters (of 20)

26

Exterior (of 14)

28

longitudinal ribs (of 26)

30

Longitudinal gutters (of 26)

32

Longitudinal Water Channels (of 10)

34

Connection sections (for 32)

36

floor (of 30)

38

Cooling water channels (of 10)

40

membrane

42

sealing frame (of 10)

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102012210066 A1 [0002]
• WO 2004/021491 A1 [0003]

Claims (9)

Bipolar plate for a fuel cell, characterized in that the bipolar plate (10) consists of a pair of reactant sub-plates, such as a hydrogen sub-plate (12) and an atmospheric oxygen sub-plate (14), which with their planar inner surfaces (16, 18) are tightly connected to each other tightly and firmly and whose outer surfaces (20, 26) are each formed with longitudinal ribs (22, 28) which are spaced apart from one another by longitudinal grooves (24,30), the longitudinal ribs (22) of the hydrogen Partial plate (12) and the longitudinal ribs (28) of the atmospheric oxygen partial plate (14) are opposite, and that at least the atmospheric oxygen partial plate (14) is formed on its flat inner surface (18) with longitudinal water channels (32) for the water of reaction, which at least a number of longitudinal grooves (30) of the atmospheric oxygen part plate (14) are fluidically connected. bipolar plate after claim 1 , characterized in that the longitudinal water channels (32) are provided congruently with the longitudinal grooves (30) of the atmospheric oxygen partial plate (14). bipolar plate after claim 1 or 2 , characterized in that the longitudinal water channels (32) and the longitudinal channels (30) of the atmospheric oxygen partial plate (14) are fluidically connected to one another by connecting sections (34) which are located between the bottom (36) of the longitudinal channels (30) and the longitudinal water channels ( 34) and which are longitudinally spaced from each other. bipolar plate after claim 3 , characterized in that the connecting sections (34) are designed as holes or longitudinal slots. Bipolar plate according to one of the Claims 1 until 4 , characterized in that the hydrogen part-plate (12) is also formed on its flat inner surface (16) with longitudinal water channels (32) which are provided congruently with the longitudinal water channels (32) of the air-oxygen part-plate (14). Bipolar plate according to one of the Claims 1 until 5 , characterized in that the water longitudinal channels (32) are formed with an angular, round or oval clear cross-section. bipolar plate after claim 6 , characterized in that the clear cross-section of the longitudinal water channels (32) and the clear cross-section of the longitudinal grooves (30) of the atmospheric oxygen partial plate (14) are at least approximately matched to one another. Bipolar plate according to one of the Claims 1 until 7 , characterized in that the air-oxygen partial plate (14) and the hydrogen partial plate (12) are formed on their flat inner surfaces (16, 18) congruently with cooling water channels (38) which are spaced between the longitudinal water channels (32) are trained. Bipolar plate according to one of the preceding claims, characterized in that a sealing frame (42) runs around the edge of the bipolar plate (10), which is designed with inlets for the reactants and with outlets for water produced in the fuel cell.

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