CA2867066C - Gas diffusion layer with flowpath - Google Patents
Gas diffusion layer with flowpath Download PDFInfo
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- CA2867066C CA2867066C CA2867066A CA2867066A CA2867066C CA 2867066 C CA2867066 C CA 2867066C CA 2867066 A CA2867066 A CA 2867066A CA 2867066 A CA2867066 A CA 2867066A CA 2867066 C CA2867066 C CA 2867066C
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/86—Inert electrodes with catalytic activity, e.g. for fuel cells
- H01M4/8605—Porous electrodes
- H01M4/8626—Porous electrodes characterised by the form
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/02—Details
- H01M8/0202—Collectors; Separators, e.g. bipolar separators; Interconnectors
- H01M8/023—Porous and characterised by the material
- H01M8/0241—Composites
- H01M8/0245—Composites in the form of layered or coated products
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/02—Details
- H01M8/0202—Collectors; Separators, e.g. bipolar separators; Interconnectors
- H01M8/0247—Collectors; Separators, e.g. bipolar separators; Interconnectors characterised by the form
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/02—Details
- H01M8/0202—Collectors; Separators, e.g. bipolar separators; Interconnectors
- H01M8/0258—Collectors; Separators, e.g. bipolar separators; Interconnectors characterised by the configuration of channels, e.g. by the flow field of the reactant or coolant
- H01M8/026—Collectors; Separators, e.g. bipolar separators; Interconnectors characterised by the configuration of channels, e.g. by the flow field of the reactant or coolant characterised by grooves, e.g. their pitch or depth
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/10—Fuel cells with solid electrolytes
- H01M2008/1095—Fuel cells with polymeric electrolytes
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M2300/00—Electrolytes
- H01M2300/0017—Non-aqueous electrolytes
- H01M2300/0065—Solid electrolytes
- H01M2300/0082—Organic polymers
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/86—Inert electrodes with catalytic activity, e.g. for fuel cells
- H01M4/8605—Porous electrodes
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/04—Auxiliary arrangements, e.g. for control of pressure or for circulation of fluids
- H01M8/04291—Arrangements for managing water in solid electrolyte fuel cell systems
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/30—Hydrogen technology
- Y02E60/50—Fuel cells
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- Chemical Kinetics & Catalysis (AREA)
- Electrochemistry (AREA)
- General Chemical & Material Sciences (AREA)
- Life Sciences & Earth Sciences (AREA)
- Engineering & Computer Science (AREA)
- Manufacturing & Machinery (AREA)
- Sustainable Development (AREA)
- Sustainable Energy (AREA)
- Composite Materials (AREA)
- Fuel Cell (AREA)
- Inert Electrodes (AREA)
Abstract
[Solution] A gas diffusion layer with flowpath in which electroconductive wires A for forming flow channels are disposed upon an electroconductive substrate B, the flow channels formed by the electroconductive wires A having a height of 300 µm or less, and flow channels formed by adjacent electroconductive wires A having an equivalent diameter of 300 µm or less.
Description
Technological Field [0001] The present invention relates to a gas diffusion layer with flowpath. In particular, the present invention relates to a gas diffusion layer with flowpath that exhibits superior power generation capability and comprises a flow channel of low height.
Background Technology
Typically, the separators are manufactured by pressing metal plates or carving plates of graphite.
¨ 1 ¨
Anode reaction: H2 2H+ + 2e- = = = (1) Cathode reaction: 2H + 2e- + (1/2)02 H20 = = = (2)
For example, patent document 1 discloses a fuel cell in which electroconductive members (wires) for forming a specific macro space are disposed between the anode catalyst layer and a fuel supply section or the cathode catalyst layer and an oxidant supply unit so as to contact the catalyst layer and the supply section. That is, patent document 1 discloses forming a flow channel using electroconductive wires and rapidly expelling gas generated at the anode and water generated at the cathode through this macro space to the exterior, enabling electrical resistance to be reduced.
Prior Art Documents Patent Documents
Brief Description of the Drawings
1(a), and a magnified perspective view of the area surrounded by the dotted line.
[FIG. 2] A schematic cross-sectional view of the basic configuration of a fuel cell according to a second embodiment.
¨2¨
[FIG. 3] A schematic cross-sectional view of the basic configuration of a fuel cell according to a third embodiment.
[FIG. 4] A perspective view of a vehicle equipped with a fuel cell stack.
[FIG. 5] A graph showing power generation evaluation results for sub-scale fuel individual cells manufactured according to an example 1 and comparative examples 1 and 2.
[FIG. 61 A schematic perspective view of an electroconductive substrate B
according to another embodiment.
[FIG. 7] A schematic perspective view illustrating the configuration of an electroconductive substrate B.
Preferred Embodiments of the Invention
The individual cells of the fuel cell are generally provided with an electrolyte membrane and pairs of catalyst layers, gas diffusion layers, and gas flow channels formed sequentially on both sides of the membrane. Of these, the catalyst layers and electrolyte membrane have a thickness of 0.01-0.1 mm out of consideration for power-generating ability. The height of the gas flow channels must be 0.5-2 mm, and the thickness of the gas diffusion layers 0.2-0.5 mm. In other words, because the gas flow channels occupy the greater part of the thickness of the individual cells of the fuel cell, it is vital to reduce the height of the gas flow channels in order to reduce the size of the fuel cell. However, the gas flow channel height described above is necessary in conventional arrangements in order to efficiently remove the water produced by power generation and supply the fuel gas and oxidant gas necessary to generate power. For this reason, there is a limit to the extent to which the size of a conventional fuel cell can be reduced.
electroconductive substrate B serve the role of the gas flow channel part of the gas diffusion layer and separator of a conventional individual fuel cell. Because the electroconductive wires A contribute to the formation of the gas flow channel, the height of the gas flow channel can be kept low compared to a conventional separator, in which fine tooling is necessary, thereby allowing the thickness of the individual fuel cells, and thus the size of the fuel cell, to be reduced. In addition, because the diameter of the electroconductive wires A is the height of the gas flow channel, the height of the gas flow channel can be freely selected.
for example, the direction in which the fuel gas or oxidant gas flows can be freely selected, or different electroconductive wires A can be freely selected according to the design (wire diameter, pitch, etc.) of the electroconductive substrate B.
The dimensions and proportions shown in the drawings have been exaggerated for ease of illustration; the actual proportions may differ.
Specific examples include a polymer electrolyte fuel cell (PEFC), an alkaline fuel cell, a direct methanol fuel cell, a micro fuel cell, or a phosphoric acid fuel cell. Of these, a polymer electrolyte fuel cell ¨4¨
is preferable due to its small size and potential for high density and high output. Apart from a power source for a moving object, such as an automobile, in which installation space is limited, the fuel cell is also useful as a stationary power source, but is especially advantageously usable in automotive applications, in which the system is frequently started or stopped and output variations frequently occur.
Ordinarily, the separators are manufactured by pressing metal plates; however, this method leads to problems such as the separators bending during pressing or cracking or strain hardening occurring in the separators during detailed machining. By contrast, smooth separators can be used with the gas diffusion layer with flowpath according to the present invention, obviating such problems. Moreover, in the gas diffusion layer with flowpath according to the present invention, an electroconductive substrate B is disposed between the ¨5¨
catalyst layer and the electroconductive wires A as a gas diffusion layer. As a result, a fuel cell formed using such a gas diffusion layer with flowpath is capable of supplying gas throughout the entirety of the catalyst layer, including in the through-thickness direction, and exhibits superior power generation capability. With respect to the compressive force in the out-of-plane direction generated by the load applied when layering the individual cells of the fuel cell, the electroconductive substrate B minimizes and prevents the electroconductive wires A from sinking into the catalyst layer. This allows for satisfactory gas diffusion and reduces pressure loss.
fuel cell stack is formed by sequentially layering a plurality of MEAs 80 with anode separators 70a and cathode separators 70c interposed therebetween. A state in which the polymer electrolyte membrane 20, anode catalyst layer 30a, and cathode catalyst layer 30c are layered together will be referred to as "CCM". Gas seals may optionally be disposed, for instance, between the separators 70a, 70c and the polymer electrolyte membrane 20 in the fuel cell stack; these are not shown in FIG. 1.
and the separators are in electrical contact, as are the electroconductive substrate B and the electrode layer of the membrane electrode assembly. This allows sufficient electrical conductivity to be ensured between the catalyst layers and the separators by the electroconductive substrate B and the electroconductive wires A, and allows electrical current generated at the cathode catalyst layer to be easily transmitted to the cathode separator. It is thereby possible to reduce the thickness of the fuel cell while ensuring sufficient gas diffusion and electrical conductivity.
¨6¨
An anode separator 120a provided with an anode gas diffusion layer 110a and a flow channel 121a through which fuel gas flows is disposed on the anode side, as in the case of an ordinary fuel cell. Although not shown in the drawings, a configuration that is the reverse of that shown in FIG. 2, as described hereafter, is also within the scope of the invention according to the present application. Specifically, the anode electroconductive substrate B 50a is disposed in proximity to the anode catalyst layer 30a as shown in FIG. 1 only on the anode side, and the anode electroconductive wires A 60a are disposed between the anode electroconductive substrate B 50a and the anode separator 70a. A cathode separator provided with a cathode gas diffusion layer and a flow channel through which oxidant gas flows may also be disposed on the cathode side, as in an ordinary fuel cell.
The various parts may be identically or differently configured between the anode side and the cathode side.
arising from the layers, the electroconductive wires A 60 are preferably disposed at substantially overlapping positions (i.e., substantially identical positions) on the two sides of the MEA.
1(a)) is 300 gm or less. A diameter of 300 gm or less for the electroconductive wires A will allow the thickness of the MEA, and, by extension, the size of the fuel cell, to be reduced. In addition, because the gas supplied through the gas flow channel space can be sufficiently diffused to the area directly beneath the electroconductive wires A within the MEA, the fuel cell has superior power generation capability. Out of considerations for reducing the size of the fuel cell, removing the water formed as the result of power generation, supplying the fuel gas and oxidant gas necessary to generate power, and obtaining high output density, the diameter (D1) of the electroconductive wires A 60 is preferably 10-300 gm, more preferably 50-200 gm, and especially preferably 100-150 gm. If the electroconductive wires A have round cross-sectional shapes, the diameter (D1) of the electroconductive wires A 60 will be the diameter of the electroconductive wires constituting the electroconductive wires A. The electroconductive wires A are not limited to the round cross-sectional shape described above, and may have, for example, ellipsoid, circular, irregular, rectangular, or triangular cross sections. In such cases, the "diameter (D1) of the electroconductive wires A"
is the length that defines the height of the gas flow channel spaces 100, as described above. The electroconductive wires A preferably have round or rectangular cross-sectional shapes.
The pitch (P1) of adjacent electroconductive wires A 60 is preferably 20-600 gm, more preferably 100-400 gm, and especially preferably 200-300 gm. A pitch within this range allows sufficient levels of gas (fuel gas or oxidant gas) to be supplied to the catalyst layer 30 and ensures that a sufficient proportion of the power generation area is occupied by the flow channel, enabling gas transportation resistance to be minimized. As a result, the fuel cell is capable of demonstrating superior power generation capability. In the present description, "the pitch between adjacent electroconductive wires A 60" refers to the distance between the centers of adjacent electroconductive wires A (i.e., the length labeled "Pl"
in FIG. 1 (a)).
The "equivalent diameter of the flow channels formed by adjacent electroconductive wires ¨8¨
IAMENDED
SHEET
A" refers to the distance between adjacent electroconductive wires A that substantially form gas flow channel spaces 100 (i.e., the length labeled "L" in FIG. 1(a)). The "equivalent diameter (L) of the flow channels formed by adjacent electroconductive wires A" is defined as the value (in gm) yielded by subtracting the diameter (D1) of the electroconductive wires A from the pitch (P1) of adjacent electroconductive wires A 60 (L (gm) = P1 (gm) ¨ D1 (j1111))-
50 directly contact the catalyst layer 30, and that the electroconductive wires A 60 directly contact the separator 70. This allows sufficient electrical conductivity to be ensured between the catalyst layer 30 and the separator 70 by the electroconductive substrate B 50 and the electroconductive wires A 60, and allows electrical current generated at the cathode catalyst layer 30c to be easily transmitted to the cathode separator 70c. It is thereby possible to reduce the thickness of the fuel cell while ensuring sufficient gas diffusion and electrical conductivity.
60 be constituted by a non-electroconductive core material and an electroconductive surface ¨9¨
AMENDED' SHEET
layer material coating the non-electroconductive core material, or by an electroconductive metal.
examples include resin materials such as polyalkylene resins, including polyester resins (for example, polyethylene terephthalate), polyethylene resins, and polypropylene resins; epoxy resins; urethane resins; polycarbonate resins; acrylic resins; vinyl chloride resin; polyamide resins; and the like. These may be used singly or in combinations of two or more types.
Specific examples include metals such as gold, platinum, ruthenium, iridium, rhodium, palladium, silver, steel, iron, titanium, aluminum, and alloys of these; electroconductive polymer materials; and electroconductive carbonaceous materials such as diamond-like carbon (DLC).
These may be used singly or in combinations of two or more types.
the metals listed above as examples of electroconductive surface layer materials for covering the core material can similarly be preferably used.
For this reason, it is preferable to form the electroconductive wires A 60 by coating a non-electroconductive core material with a metal (especially gold or palladium) or to form the electroconductive wires A 60 from gold or palladium, as this will make it possible to minimize/prevent corrosion and increase the durability of the cell. Of the options given above, it is preferable that the electroconductive wires A 60 be constituted by a non-electroconductive core material and an electroconductive surface layer material coating the non-electroconductive core material. Manufacturing the centers of the electroconductive wires A using a non-electroconductive core material allows the overall weight of the gas diffusion layer with flowpath to be reduced, as well as costs.
to the electroconductive wires A, to the electroconductive substrate B, or after disposing the electroconductive wires A upon the electroconductive substrate B. For the sake of reducing electrical resistance, it is preferable to apply the anti-corrosion treatment after disposing the electroconductive wires A upon the electroconductive substrate B.
preferably contact and are anchored upon the electroconductive substrate B 50.
Specifically, in the electroconductive substrate B 50, a plurality of electroconductive wires C
51 is disposed in parallel in a single layer, the individual electroconductive wires C 51 are orthogonal to the electroconductive wires A 60 but are not interwoven with them (i.e., the electroconductive wires A 60 are simply laid upon the electroconductive wires C 51).
Meanwhile, "the electroconductive wires C are orthogonal to and are interwoven with the electroconductive wires A" means that the electroconductive wires C (labeled "C" in the ¨ 11 ¨
drawings) both are orthogonal to and are interwoven with the electroconductive wires A, as shown in FIG. 7. The electroconductive substrate B 50 may be formed from a single layer of electroconductive wires C that are orthogonal to but not interwoven with the electroconductive wires A, or from two or more such layers in a layered state.
For the sake of reducing the thickness of the MEA (i.e., the size of the fuel cell), the electroconductive substrate B 50 is preferably formed from a single layer of electroconductive wires C that are orthogonal to but not interwoven with the electroconductive wires A.
for the efficient transmission of electricity generated at the catalyst layer 30 to the separator 70. Meanwhile, because the electroconductive wires A are disposed in parallel at a pitch of a certain size (greater than that of the electroconductive wires C 51), a satisfactory flow of gas from the separator can be ensured. Specifically, the ratio (P2/P1) of the pitch (P2) of adjacent electroconductive wires C 51 to the pitch (P1) of adjacent electroconductive wires A is preferably 0.1-0.8, more preferably 0.2-0.6.
p x rlt (1)
In addition, the electroconductive substrate B is capable of sufficiently minimizing/preventing plastic deformation resulting from out-of-plane compressive force generated by the load arising from the layers.
one layer of electroconductive wires C that are orthogonal to but not interwoven with the electroconductive wires A. Specifically, it is preferable that the electroconductive wires C be constituted by a non-electroconductive core material and an electroconductive surface layer material coating the non-electroconductive core material, or by a metal. There is no particular limitation upon the core material used in the former case; examples include resin materials such as polyalkylene resins, including polyester resins (for example, polyethylene terephthalate), polyethylene resins, and polypropylene resins; epoxy resins;
urethane resins;
polycarbonate resins; acrylic resins; vinyl chloride resin; polyamide resins;
and the like.
These may be used singly or in combinations of two or more types. There is no particular limitation upon the electroconductive surface layer material used to coat the core material as long as it is electrically conductive. Specific examples include metals such as gold, platinum, ruthenium, iridium, rhodium, palladium, silver, steel, iron, titanium, aluminum, and alloys of these; electroconductive polymer materials; and electroconductive carbonaceous materials.
These may be used singly or in combinations of two or more types. There is no particular limit on the metal used in the latter case; the metals listed above as examples of electroconductive surface layer materials for covering the core material can similarly be preferably used. Of the above, it is especially preferable to form the electroconductive substrate B 50 by coating a non-electroconductive core material with a metal (especially gold or palladium) or to form the electroconductive wires from gold or palladium, as this will make it possible to minimize/prevent corrosion and increase the durability of the cell. Of the options given above, it is preferable that the electroconductive wires C be constituted by a non-electroconductive core material and an electroconductive surface layer material coating the non-electroconductive core material. Manufacturing the centers of the electroconductive wires C using non-electroconductive core material allows the overall weight of the gas diffusion layer with flowpath to be reduced, as well as costs.
Applying an electroconductive anti-corrosion treatment minimizes/prevents corrosion of the electroconductive substrate B or electroconductive wires C, allowing the durability of the cell to be increased. A known means, such as plating with a noble metal such as gold or platinum, cladding, sputtering, or coating (via sputtering, chemical vapor deposition (CVD), or physical vapor deposition (PVD)) with an electroconductive carbonaceous material such as diamond-like carbon (DLC), can be advantageously applied as an electroconductive anti-corrosion treatment. The anti-corrosion treatment may be applied to the electroconductive wires A, to ¨ 14 ¨
the electroconductive substrate B, or after disposing the electroconductive wires A upon the electroconductive substrate B. For the sake of reducing electrical resistance, it is preferable to apply the anti-corrosion treatment after disposing the electroconductive wires A upon the electroconductive substrate B.
wires A 60 may be disposed without modification upon the electroconductive substrate B or anchored to the electroconductive substrate B; the latter method is preferable. Such an arrangement allows gas to be supplied uniformly, and makes it possible to minimize/prevent shifting of the electroconductive wires A during assembly, as well as shifting of the electroconductive wires A due to changes in surface pressure or gas pressure during operation.
Anchoring the electroconductive wires A 60 to the electroconductive substrate B 50 allows the bending rigidity of the electroconductive substrate B to be improved.
(electroconductive wires C).
For example, if the electroconductive wires A are formed from a resin or metal, heat bonding or the like can be used. There is no particular method upon the method of heat bonding employed; for example, the contact points between the electroconductive substrate B and the electroconductive wires A can be anchored in place via welding, sintering, deposition, or the like. Using heat bonding ensure electrical conductivity even if there are locations where there is no contact or no surface pressure upon the electroconductive substrate B and the electroconductive wires A. Heat bonding is also advantageous in terms of ease of operation and the like.
electroconductive substrate B 50 allows the bending rigidity of the electroconductive substrate B to be improved. In addition, even if the electroconductive wires A
60 are not straight, anchoring the points of contact with the electroconductive substrate B allows the in-plane bending rigidity of the electroconductive substrate B in both the lateral and longitudinal directions to be improved. There is no particular limitation upon the method used to anchor the wires A' to the substrate B'. If, for example, the wires A' and the substrate B' are made of a resin material such as those listed above, it is possible to arrange the wires A' in parallel rows on the substrate B' in step (a) so as to be orthogonal thereto but not interwoven therewith, followed by bonding the wires by heating to a temperature equal to or greater than the melting point of the resin material. In such cases, because the substrate B' and the wires A' are fused together, the thickness of the gas diffusion layer with flowpath is slightly less than the total of the sizes (or the total of the diameters if the wires A and C are round) of the substrate B' and the wires A'. Similarly, the sizes of the wires A' and the wires C' (or the diameters thereof if the wires A' and C' are round) are slightly less than the sizes of the electroconductive wires A and the electroconductive wires C (or the diameters thereof if the electroconductive wires A and C are round).
Specific examples include bonding together thin films of electroconductive surface layer material or plating (metal plating) using an electroconductive surface layer material.
The substrate B' with wires A' is then plated with a metal (especially gold or palladium). In this method, the centers of the electroconductive wires A and C are manufactured using a non-electroconductive core material, allowing the overall weight of the gas diffusion layer with flowpath to be reduced, as well as costs.
That is, the pitch of adjacent electroconductive wires C 51 (labeled -P2" in FIG. 1(b)) is 480 gm or less, preferably 5-480 gm, more preferably 20-300 gm, and especially preferably 30-150 gm. A pitch in this range allows the thickness of the MEA, and, by extension, the size of the fuel cell, to be reduced. In addition, electricity generated at the catalyst layer 30 can be efficiently transmitted to the separator 70. As a result, the fuel cell is capable of demonstrating superior power generation capability. Moreover, because adjacent electroconductive wires C are densely disposed, plastic deformation resulting from out-of-plane compressive force generated by the load arising from the layers can be sufficiently minimized/prevented. In the present description, "the pitch between adjacent electroconductive wires C 51" refers to the distance between the centers of adjacent electroconductive wires C (labeled "P2" in FIG. 1(b)). In the present description, "Gurley density" is the number of seconds necessary for 100 cc of air to pass through at a pressure of 0.879 g/mm2 in accordance with JIS P 8117 (1998 ed.).
and W as the length in the direction perpendicular to the electroconductive wires A, the gas diffusion layer with flowpath preferably has a rectangular shape such that the ratio L/W is 2 or less. Such a configuration allows gas (fuel gas or oxidant gas) to be efficiently distributed to the separator. The ratio L/W is more preferably 0.05-2, still more preferably 0.1-1.5, and especially preferably 0.2-1.2.
Providing an electroconductive particle layer 40 in this way increases the closeness of the bond between the catalyst layer 30 and the electroconductive substrate B 50, thereby reducing the contact resistance between the MEA 80 and the electroconductive substrate B 50, and ¨ 18 ¨
allowing in-plane electrical conductivity within the MEA 80 to be increased and current collection performance to be improved. As a result, if the electroconductive substrate B 50 is formed from at least one layer of electroconductive wires C that are orthogonal to but not interwoven with the electroconductive wires A 60, a greater pitch can be set between the electroconductive wires C. Water collecting in the electroconductive substrate B 50 can also be more easily expelled. In addition, the electroconductive particle layer 40 functions as a protective layer, allowing direct contact between the electroconductive substrate B 50 and the MEA 80 to be avoided and the corrosion resistance of the electroconductive substrate B 50 to be improved, as well as damage to the catalyst layer 30 due to pressure from the electroconductive substrate B 50 to be avoided. There is no particular limitation upon the method used to form the electroconductive particle layer 40; for example, the electroconductive particle layer 40 can be compression bonded upon the catalyst layer 30.
in the carbon particle layer should be roughly 90:10 to 40:60 by mass. The thickness of the carbon particle layer may be determined as appropriate according to the water repellence of the obtained gas diffusion layer. The carbon particle layer can be manufactured by impregnating porous polytetrafluoroethylene (PTFE) with an aqueous dispersion containing acetylene black, PTFE microparticles, and a thickening agent, then firing.
known material, such as carbon in the form of fine carbon graphite or carbon plates or a metal such as stainless steel, may be used as appropriate as the constituent material of the separator 70. In the present embodiment, the anode separator 70a and the cathode separator 70c are both made of carbon.
The polymer electrolyte membrane 20 also serves as a barrier that prevents the fuel gas supplied to the anode side and the oxidant gas supplied to the cathode side from mixing.
membrane of a polymer electrolyte known in the art in the technical field of fuel cells can be used, as appropriate. Examples include fluorine-based polymer electrolyte membranes constituted by per fluorocarbon sulfonic acid polymers such as Nafion (DuPont), Aciplex (Asahi Kasei), or Flemion (Asahi Glass); Dow Chemical ion exchange resins;
fluoropolymer electrolytes such as ethylene-ethylene tetrafluoride copolymer resin membranes or trifluorostyrene-based resin membranes; sulfonic acid group-comprising hydrocarbon resin membranes; and other commercially available solid polymer electrolyte membranes, membranes of microporous polymer membranes impregnated with liquid electrolytes; and membranes of porous materials filled with polymer electrolytes. The polymer electrolyte used in the polymer electrolyte membrane and the polymer electrolyte used in the catalyst layers may be the same or different, but are preferably the same in order to improve the strength of the bond between the catalyst layers and the polymer electrolyte membrane.
is being operated.
Specifically, a hydrogen oxidation reaction takes place in the anode catalyst layer 30a takes place in the anode catalyst layer 30a, and an oxygen reduction reaction takes place in the cathode catalyst layer 30c. The catalyst layer contains a catalyst component, an electroconductive catalyst carrier for carrying the catalyst component, and a polymer electrolyte.
catalyst component used in the anode catalyst layer 30a as long as it is capable of catalyzing a hydrogen oxidation reaction; a known catalyst can be used in a similar manner.
Specific examples include metals such as platinum, ruthenium, iridium, rhodium, palladium, osmium, tungsten, lead, iron, chromium, cobalt, nickel, manganese, vanadium, molybdenum, gallium, or aluminum, and alloys thereof. Of these, it is preferable that at least platinum is included in order to improve catalytic activity, resistance to catalyst poisoning by carbon monoxide or the like, and heat resistance. The composition of the alloy will vary according to the types of metals being alloyed, but should comprise 30-90% platinum atoms and 10-70%
alloy metal atoms. If an alloy is used as a cathode catalyst, the composition of the alloy will vary according to the types of metal being alloyed and may be selected, as appropriate, by a person skilled in the art, but preferably comprises 30-90% platinum atoms and 10-70%
alloy metal atoms. In the present context, an "alloy" is a general term for mixtures of one or more metallic or nonmetallic elements with a metallic element that exhibit metal-like properties.
Examples of alloy structures include eutectic alloys in which the component elements form separate crystals, solid solutions in which the component elements have completed melted together, and alloys in which the component elements form intermetallic compounds or metal-non-metal compounds; any of these is acceptable. The catalyst component used in the cathode catalyst layer and the catalyst component used in the anode catalyst layer may be selected, as appropriate, from among those listed above. In the following description, unless otherwise noted, the catalyst components for the cathode catalyst layer and the anode catalyst layer are similarly defined, and are referred to collectively as the "catalyst component".
However, the catalyst components for the cathode catalyst layer and the anode catalyst layer need not be identical, and may be selected as appropriate so as to yield the desire effects as described above.
Accordingly, the average particle diameter of the catalyst particles in the catalyst ink is preferably 1-30 nm, more preferably 1.5-20 nm, still more preferably 2-10 nm, and especially preferably 2-5 nm. The diameter is preferably at least 1 nm so that the particles can be more easily carried, and ¨ 22 ¨
preferably no more than 30 nm for the sake of catalyst utilization rate. The "average particle diameter of the catalyst particles" can be measured using the crystallite diameter as calculated using the half-width of the diffraction peak of the catalyst component obtained via X-ray diffraction or the average particle diameter value for the catalyst component as determined from a transmission electron microscope image.
such electrolyte may be used, provided that it at least exhibit high proton conductivity. The types of polymer electrolyte that can be used can be broadly divided into fluorine-based electrolytes comprising fluorine atoms in all or part of the polymer skeletons thereof, and hydrocarbon-based electrolytes that contain no fluorine atoms in the polymer skeletons thereof. Specific preferred examples of fluorine-based electrolytes include per fluorocarbon sulfonic acid polymers such as Nation (DuPont), Aciplex (Asahi Kasei), or FlemionS(Asahi Glass); polytrifluorostyrene sulfonic acid polymers; per fluorocarbon phosphonic acid polymers; trifluorostyrene sulfonic acid polymers; ethylene tetrafluoroethylene-g-styrene sulfonic acid polymers; ethylene-tetrafluoroethylene copolymers; and polyvinylidene fluoride-per fluorocarbon sulfonic acid polymers. Specific preferred examples of hydrocarbon-based electrolytes include polysulfonic acid, polyaryl ether ketone sulfonic acid, polybenzimidazole alkyl sulfonic acid, polybenzimidazole alkyl phosphonic acid, polystyrene sulfonic acid, polyether ether ketone sulfonic acid, and polyphenyl sulfonic acid. The polymer electrolyte preferably contains fluorine atoms, as this will yield superior heat resistance and chemical stability; of these, fluorine-based electrolytes such as Nation (DuPont), Aciplex (Asahi Kasei), and Flemion8(Asahi Glass) are preferable.
Examples include hydrogen, methanol, ethanol, 1-propanol, 2-propanol, 1-butanol, 2-butanol, 3-butanol, dimethyl ether, diethyl ether, ethylene glycol, and diethylene glycol. Of these, hydrogen or methanol is preferable, as these allow for increased output.
the same can be installed, for example, in an automobile as a drive power source. As shown in FIG. 4, to install a fuel cell stack 210 in an automobile such as a fuel cell vehicle 200, the stack may be installed, for example, under the seats in the center of the body of the fuel cell vehicle 200. Disposing the stack underneath the seats allows for more room in the vehicle interior and the trunk. In some instances, the location at which the fuel cell stack 210 is not limited to beneath the seats; for example, it may be installed beneath the rear trunk space, or the engine space at the front of the vehicle. Because the fuel cell 10 and the fuel cell stack 210 described above have superior output properties and durability, it is possible to provide a fuel cell-equipped vehicle of high long-term reliability.
Examples
Wires A' (polyester; 75 denier! 24 filaments; twist rate: 1,000 t/m; diameter:
approx. 150 gm) with surfaces coated with fusable resin and wires C' (polyester: 25 denier monofilament; diameter: 50 gm) were prepared. The wires C' were arranged in a 200 mesh (pitch between wires C': approx. 75 gm) to produce a substrate B'. The wires A' were arranged in a 65 mesh (pitch between wires A': approx. 200 gm) on the substrate B' so as to be orthogonal to but not interwoven with the wires C'. Afterwards, the whole was heated to at least 1,00 C to melt the resin, thereby producing a substrate B' with wires A' in which the wires A' and the wires C' were orthogonal to but not interwoven with each other. Next, the surface of the substrate B' with wires A' was subjected to palladium electroless plating (weight: approx. 1g/m2) and gold electroplating (thickness: approx. 20 nm) to impart electron conductivity, thereby producing a gas diffusion layer with flowpath (flow-channel comprising GDL). In the gas diffusion layer with flowpath, the gaps between adjacent electroconductive wires A function as flow channels for oxygen or hydrogen when power is being generated using the fuel cell, and the electroconductive wires A
arranged in rows preserve the shapes of the flow channels and function as a gas diffusion layer. The gas diffusion layer with flowpath was cut to a rectangular shape of dimensions width 50 mm x length 50 mm, and the perpendicularly cut ends of the wires A were observed.
As a result, the thickness of the gas diffusion layer with flowpath was 130-135 gm, the height of the electroconductive wires A was roughly 100 gm, and the pitch (P1) between adjacent electroconductive wires A 60 was roughly 200 gm, showing that the desired flow channel ¨ 25 ¨
structure had been formed.
The smooth separators were provided with manifolds of dimensions width 50 mm x length 4 mm x depth mm contacting two opposing lengthwise directional ends. In addition, the right ends or left ends of the manifolds were each provided with one gas supply hole (diameter: 3 mm) provided so as to demonstrate point symmetry with respect to the centers of the pool-shaped recessions. A seal groove for receiving a compressive rubber seal was also provided around the periphery of the pool-shaped recessions and pair of manifolds. The width of the seal groove was 2 mm, and the offset distance from the periphery of the rectangle groove and pair of manifolds to the seal groove was 1 mm.
plating (weight: approx. I g/m2), then gold electroplating (thickness: approx.
20 nm) to produce an electroconductive substrate B. Measuring the penetrative resistance and Gurley density of the obtained electroconductive substrate B resulted in 30 m1l/cm2 or less and 300 seconds or less, respectively.
A sub-scale individual fuel cell was produced according to the same method as example 1, except that conventional gas diffusion layers not comprising flow channels were used instead of the gas diffusion layers with flowpath used in example 1 and a plain-weave mesh (thickness: 100 gm) of wires C' was used, and the power generation thereof was evaluated.
The distance between separators (individual fuel cell thickness) was 230 gm.
In lieu of the gas diffusion layers with flowpath used in example 1, pieces of Toray Industries TGP-H-060 carbon paper (thickness: 200 gm) cut to width 50 mm and length 50 mm were used as conventional gas diffusion layers not comprising flow channels.
Also, instead of smooth separators not comprising flow channel grooves, flow channel-comprising separators (graphite) provided with serpentine flow channels having a flow channel height of 1 mm, a rib width of 1 mm, a channel width of 1 mm, a rib pitch 2 mm, a flow channel direction length of 50 mm, and a width direction length of 50 mm were used.
Apart from these points, a sub-scale individual fuel cell was produced according to a method similar to that used in example 1, and the power generation thereof was evaluated. Results are shown in FIG. 5.
¨ 27 ¨
Also, instead of smooth separators not comprising flow channel grooves, flow-channel comprising separators (graphite) provided with straight flow channels having a flow channel height of 100 gm, a rib width of 150 gm, a channel width of 250 gm, a rib pitch of 400 gm, a flow channel direction length of 50 mm, and a width direction length of 50 mm were used.
Apart from these points, a sub-scale individual fuel cell was produced according to a method similar to that used in example 1, and the power generation thereof was evaluated. Results are shown in FIG. 5.
Reference Numerals
Fuel cell Polymer electrolyte membrane 30a Anode catalyst layer 30c Cathode catalyst layer 40a Anode-side electrically conductive particle layer 40c Cathode-side electrically conductive particle layer ¨ 28 ¨
50a Anode electroconductive substrate B
50c Cathode electroconductive substrate B
60a Anode electroconductive wire A
60c Cathode electroconductive wire A
70a Anode separator 70c Cathode separator 80 Membrane electrode assembly (MEA) 100a Anode-side gas flow channel space 100c Cathode-side gas flow channel space 110a Anode gas diffusion layer 120a Separator 121a Groove-shaped electroconductive wires A
200 Fuel cell vehicle 210 Fuel cell stack ¨ 29 ¨
Claims (7)
an electroconductive substrate; and electroconductive wires disposed on the electroconductive substrate, the electroconductive wires forming flow channels, the flow channels formed by the electroconductive wires have a height of 300 µm or less, the flow channels formed by adjacent electroconductive wires of the electroconductive wires have an equivalent diameter of 300 µm or less, and the electroconductive substrate has one layer of electroconductive wires orthogonal to but not interwoven with the electroconductive wires, the electroconductive substrate being in direct contact with the catalyst layer.
[Numerical formula 1] .rho. × r/t <= 5 (1) .rho. being the resistivity (.OMEGA..cndot.cm) of the catalyst layer, r being half the value (cm) of the pitch between the adjacent electroconductive wires, and t being the thickness (cm) of the catalyst layer.
the gas diffusion layer with flowpaths according to any one of claims 1 to 6 is disposed between the separator and the electrode layer of the membrane electrode assembly on the anode side and/or the cathode side of the assembly; and electrical contact is established between the electroconductive wires and the separator, and between the electroconductive substrate and the electrode layer of the membrane electrode assembly.
Applications Claiming Priority (3)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP2012-057407 | 2012-03-14 | ||
| JP2012057407A JP5893970B2 (en) | 2012-03-14 | 2012-03-14 | Gas diffusion layer with flow path |
| PCT/JP2013/056300 WO2013137102A1 (en) | 2012-03-14 | 2013-03-07 | Gas diffusion layer with flowpath |
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| CA2867066A1 CA2867066A1 (en) | 2013-09-19 |
| CA2867066C true CA2867066C (en) | 2020-09-08 |
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| CA2867066A Active CA2867066C (en) | 2012-03-14 | 2013-03-07 | Gas diffusion layer with flowpath |
Country Status (6)
| Country | Link |
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| US (1) | US9531012B2 (en) |
| EP (1) | EP2827417B1 (en) |
| JP (1) | JP5893970B2 (en) |
| CN (1) | CN104170136B (en) |
| CA (1) | CA2867066C (en) |
| WO (1) | WO2013137102A1 (en) |
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| JP5942502B2 (en) * | 2012-03-15 | 2016-06-29 | 日産自動車株式会社 | Fuel cell |
| JP6608649B2 (en) * | 2015-08-26 | 2019-11-20 | 日産自動車株式会社 | Porous sheet manufacturing method and porous sheet manufacturing apparatus |
| US12148965B2 (en) * | 2018-07-05 | 2024-11-19 | Eh Group Engineering Sa | Fuel cells |
| EP4139978B1 (en) | 2020-04-20 | 2024-07-31 | EH Group Engineering AG | Fluid guiding assembly for fuel cell |
| US12126060B2 (en) | 2022-03-11 | 2024-10-22 | Robert Bosch Gmbh | Chemical and electrochemical cell electronics protection system |
| US20230290976A1 (en) * | 2022-03-11 | 2023-09-14 | Robert Bosch Gmbh | Chemical and electrochemical cell electronics protection system |
| US12297550B2 (en) | 2022-03-11 | 2025-05-13 | Robert Bosch Gmbh | Chemical and electrochemical cell electronics protection system |
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JPS61253768A (en) * | 1985-04-30 | 1986-11-11 | Kureha Chem Ind Co Ltd | Electrode substrate for fuel cell and its manufacture |
| US5798187A (en) * | 1996-09-27 | 1998-08-25 | The Regents Of The University Of California | Fuel cell with metal screen flow-field |
| US6613468B2 (en) * | 2000-12-22 | 2003-09-02 | Delphi Technologies, Inc. | Gas diffusion mat for fuel cells |
| US7125625B2 (en) * | 2002-05-31 | 2006-10-24 | Lynnetech, Inc. | Electrochemical cell and bipolar assembly for an electrochemical cell |
| JP2004146226A (en) * | 2002-10-25 | 2004-05-20 | Matsushita Electric Ind Co Ltd | Fuel cell |
| WO2004100295A1 (en) * | 2003-05-12 | 2004-11-18 | Mitsubishi Materials Corporation | Composite porous body, member for gas diffusion layer, cell member, and their manufacturing methods |
| JP4639625B2 (en) * | 2004-04-01 | 2011-02-23 | トヨタ自動車株式会社 | Fuel cell |
| JP2008027672A (en) * | 2006-07-19 | 2008-02-07 | Toyota Motor Corp | Conductive porous body and method for producing the same |
| JP2009043453A (en) * | 2007-08-06 | 2009-02-26 | Toyota Motor Corp | FUEL CELL SEPARATOR, ITS MANUFACTURING METHOD, AND FUEL CELL |
| JP5326330B2 (en) * | 2008-04-04 | 2013-10-30 | 株式会社村田製作所 | Solid electrolyte fuel cell and manufacturing method thereof |
| JP2009272101A (en) | 2008-05-02 | 2009-11-19 | Ricoh Co Ltd | Fuel cell |
| JP5369531B2 (en) * | 2008-07-30 | 2013-12-18 | 日産自動車株式会社 | FUEL CELL, FUEL CELL MANUFACTURING METHOD, AND VEHICLE |
| JP5493544B2 (en) * | 2009-07-28 | 2014-05-14 | 日産自動車株式会社 | GAS DIFFUSION LAYER FOR FUEL CELL, METHOD FOR PRODUCING GAS DIFFUSION LAYER FOR FUEL CELL, FUEL CELL, AND FUEL CELL CAR |
| DE102010042729A1 (en) * | 2010-10-21 | 2012-04-26 | Bayer Materialscience Aktiengesellschaft | Oxygenated cathode and process for its preparation |
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2012
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| Publication number | Publication date |
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| US9531012B2 (en) | 2016-12-27 |
| CN104170136B (en) | 2016-11-16 |
| CN104170136A (en) | 2014-11-26 |
| JP2013191434A (en) | 2013-09-26 |
| US20150118595A1 (en) | 2015-04-30 |
| JP5893970B2 (en) | 2016-03-23 |
| EP2827417A1 (en) | 2015-01-21 |
| CA2867066A1 (en) | 2013-09-19 |
| EP2827417B1 (en) | 2021-01-20 |
| WO2013137102A1 (en) | 2013-09-19 |
| EP2827417A4 (en) | 2015-05-20 |
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