(19)
(11)EP 3 208 874 B1

(12)EUROPEAN PATENT SPECIFICATION

(45)Mention of the grant of the patent:
18.03.2020 Bulletin 2020/12

(21)Application number: 15851244.2

(22)Date of filing:  07.10.2015
(51)International Patent Classification (IPC): 
H01M 8/0234(2016.01)
H01M 8/0241(2016.01)
H01M 8/0239(2016.01)
H01M 8/0245(2016.01)
(86)International application number:
PCT/JP2015/078492
(87)International publication number:
WO 2016/060043 (21.04.2016 Gazette  2016/16)

(54)

CARBON SHEET, GAS DIFFUSION ELECTRODE BASE MATERIAL, AND FUEL CELL

CARBONFOLIE, BASISMATERIAL FÜR GASDIFFUSIONSELEKTRODE UND BRENNSTOFFZELLE

FEUILLE DE CARBONE, MATÉRIAU DE BASE D'ÉLECTRODE DE DIFFUSION DE GAZ, ET PILE À COMBUSTIBLE


(84)Designated Contracting States:
AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR

(30)Priority: 17.10.2014 JP 2014212518
17.10.2014 JP 2014212519
17.10.2014 JP 2014212424

(43)Date of publication of application:
23.08.2017 Bulletin 2017/34

(73)Proprietor: Toray Industries, Inc.
Tokyo 103-8666 (JP)

(72)Inventors:
  • TANIMURA, Yasuaki
    Otsu-shi Shiga 520-8558 (JP)
  • CHIDA, Takashi
    Otsu-shi Shiga 520-8558 (JP)
  • SUGAHARA, Toru
    Otsu-shi Shiga 520-2141 (JP)
  • UTSUNOMIYA, Masamichi
    Otsu-shi Shiga 520-8558 (JP)
  • KAMAE, Toshiya
    Otsu-shi Shiga 520-8558 (JP)
  • SODE, Katsuya
    Otsu-shi Shiga 520-2141 (JP)
  • ANDO, Takashi
    Otsu-shi Shiga 520-2141 (JP)

(74)Representative: Kador & Partner PartG mbB 
Corneliusstraße 15
80469 München
80469 München (DE)


(56)References cited: : 
EP-A1- 1 612 313
WO-A1-2014/126002
JP-A- S63 254 669
US-A1- 2006 046 926
WO-A1-2007/037084
WO-A1-2014/181771
JP-A- 2003 109 604
  
      
    Note: Within nine months from the publication of the mention of the grant of the European patent, any person may give notice to the European Patent Office of opposition to the European patent granted. Notice of opposition shall be filed in a written reasoned statement. It shall not be deemed to have been filed until the opposition fee has been paid. (Art. 99(1) European Patent Convention).


    Description

    TECHNICAL FIELD



    [0001] The present invention relates to a carbon sheet which is suitably used in a fuel cell, particularly in a polymer electrolyte fuel cell; a gas diffusion electrode substrate; and a fuel cell including the gas diffusion electrode substrate.

    BACKGROUND ART



    [0002] A polymer electrolyte fuel cell in which a hydrogen-containing fuel gas and oxygen-containing oxidizing gas are supplied to an anode and cathode, respectively, and an electromotive force is generated by an electrochemical reaction occurring at both poles is generally constituted by laminating a bipolar plate, a gas diffusion electrode substrate, a catalyst layer, an electrolyte membrane, a catalyst layer, a gas diffusion electrode substrate and a bipolar plate in this order. The gas diffusion electrode substrate is required to have high gas diffusivity for allowing a gas supplied from the bipolar plate to be diffused into the catalyst layer and high water removal performance for discharging water generated by the electrochemical reaction to the bipolar plate, as well as high electrical conductivity for extracting generated electric current, and thus gas diffusive electrode substrates with a microporous layer formed on a surface of a carbon sheet as a substrate, which is composed of a carbon fiber and so on, are widely used.

    [0003] However, as a problem with the gas diffusion electrode substrate, the following problem is known: when the polymer electrolyte fuel cell is operated at a relatively low temperature of below 70°C in a high current density region, as a result of blockage of the gas diffusion electrode substrate by liquid water generated in a large amount and shortage in the gas supply, the fuel cell performance is impaired (this problem may be hereinafter described as "flooding"). Thus, the gas diffusion electrode substrate is required to have higher water removal performance. In order to solve this problem, various efforts have been made.

    [0004] For example, there have been proposed fuel cell gas diffusion electrode substrates having the following configurations for improving gas diffusivity and water removal performance: a plurality of layers including electrically conductive particles having different average particle sizes are laminated to control the porosity on both sides (see Patent Document 1) ; and carbon fibers having different fiber lengths are mixed to control the pore diameter on both sides (see Patent Document 2).

    [0005] There has been proposed a method for preparing a gas diffusion electrode substrate in which the loading amount of a binding material is continuously decreased in a through-plane direction (see Patent Document 3).

    [0006] Patent Document 4 discloses porous material such as a carbon fiber paper dipped into a suspension of hydrophobic polymer and drying the paper so as to obtain a desired pattern of hydrophobic polymer on the substrate. Then a paste of fluorocarbon polymer and carbon particles is applied to a desired side of the substrate.

    [0007] A porous carbon base material is disclosed in Patent Document 5. The porous carbon base material contains carbon short fibers dispersed randomly and a carbonized resin.

    PRIOR ART DOCUMENTS


    PATENT DOCUMENTS



    [0008] 

    Patent Document 1: Japanese Patent Laid-open Publication No. 2004-233537

    Patent Document 2: Japanese Patent Laid-open Publication No. 2010-102879

    Patent Document 3: Japanese Patent Laid-open Publication No. 2013-145640

    Patent Document 4: US Patent Application US 200610046926 A1

    Patent Document 5: European Patent Application EP 1 612 313 A1


    SUMMARY OF THE INVENTION


    PROBLEMS TO BE SOLVED BY THE INVENTION



    [0009] However, in the inventions described in Patent Documents 1 and 2, the total thickness of a carbon sheet increases because a plurality of layers each having a controlled porosity and pore diameter are prepared, and laminated. As a result, gas diffusivity and water removal performance are insufficient, so that flooding cannot be sufficiently suppressed, and therefore fuel cell performance is still insufficient.

    [0010] In the invention described in Patent Document 3, a resin composition serving as a binding material is applied to one surface, and therefore deviation of the binding material increases, so that the amount of the binding material becomes excessively large for maintaining binding as a whole. As a result, gas diffusivity is rather deteriorated, so that flooding cannot be sufficiently suppressed, and therefore fuel cell performance is still insufficient.

    [0011] In view of the background of the conventional art, an object of the present invention is to provide a carbon sheet that is suitably used in a gas diffusion electrode substrate which has considerably improved gas diffusivity and water removal performance, and thus has an excellent anti-flooding characteristic, and capable of exhibiting high fuel cell performance even in operation at a relatively low temperature in a high current density region, and which has excellent mechanical properties, electrical conductivity and thermal conductivity.

    [0012]  Another object of the present invention is to stably produce a thin carbon sheet which has sufficient gas diffusivity and water removal performance and which has been difficult to prepare using a conventional method, and a gas diffusion electrode substrate.

    [0013] Still another object of the present invention is to provide a gas diffusion electrode substrate obtained using the carbon sheet as a substrate, and a fuel cell including the gas diffusion electrode substrate.

    SOLUTIONS TO THE PROBLEMS



    [0014] For solving the above-mentioned problems, the present invention has the following configurations.

    [0015] A first embodiment of a carbon sheet of the present invention is a porous carbon sheet including a carbon fiber and a binding material, wherein when in a measured surface depth distribution, the ratio of the area of a portion having a depth of 20 µm or less in the measured area of one surface is a surface layer area ratio X, and the ratio of the area of a portion having a depth of 20 µm or less in the measured area of the other surface is a surface layer area ratio Y, the surface layer area ratio X is larger than the surface layer area ratio Y, and a difference between the surface layer area ratios is 3% or more and 12% or less.

    [0016] According to a preferred aspect of the first embodiment of the carbon sheet of the present invention, the surface layer area ratio X is 13% or more and 17% or less, and the surface layer area ratio Y is 9% or more and 13% or less.

    [0017] According to a preferred aspect of the first embodiment of the carbon sheet of the present invention, where a surface having the surface layer area ratio X is a surface X1, and a surface having the surface layer area ratio Y is a surface Y1, the surface roughness of the surface X1 is smaller than the surface roughness of the surface Y1, and a difference between the surface roughnesses of the surfaces X1 and Y1 is 1 µm or more and 4 µm or less.

    [0018] According to a preferred aspect of the first embodiment of the carbon sheet of the present invention, where a surface having the surface layer area ratio X is a surface X1, the surface roughness of the surface X1 is 16 µm or less.

    [0019] A second embodiment of the carbon sheet of the present invention is a porous carbon sheet including a carbon fiber and a binding material, wherein when a surface having a larger covering rate on the surface by the carbon fiber and the binding material is a surface X2, and a surface having a smaller covering rate on the surface by the carbon fiber and the binding material is a surface Y2, a difference in the covering rate between the surface X2 and the surface Y2 is 5% or more and 20% or less.

    [0020] According to a preferred aspect of the second embodiment of the carbon sheet of the present invention, the covering rate on the surface X2 is 70% or more and 90% or less, and the covering rate on the surface Y2 is 50% or more and 75% or less.

    [0021] According to a preferred aspect of the first embodiment or the second embodiment of the carbon sheet of the present invention, the carbon sheet includes a hydrophobic material, and where among layers obtained by dividing the carbon sheet in a through-plane direction thereof into three equal parts within a section extending from a surface having a 50% average fluorine intensity, which is closest to one surface, to a surface having a 50% average fluorine intensity, which is closest to the other surface, one of a layer close to one surface and a layer close to the other layer, which has a larger average fluorine intensity, is a layer A, the other one of a layer close to one surface and a layer close to the other layer, which has a smaller average fluorine intensity, is a layer B, and a layer between the layer A and the layer B is a layer C, the average fluorine intensity of the layer decreases in the order of the layer A, the layer B and the layer C.

    [0022] According to a preferred aspect of the first embodiment or the second embodiment of the carbon sheet of the present invention, the melting point of the hydrophobic material is 200°C or more and 320°C or less.

    [0023] According to a preferred aspect of the first embodiment or the second embodiment of the carbon sheet of the present invention, the sliding angle of water at the surface Y1 or the surface Y2 is 40 degrees or less.

    [0024] According to a preferred aspect of the first embodiment or the second embodiment of the carbon sheet of the present invention, where the sum of volumes of pores having a diameter in the range of 1 to 100 µm is 100%, the sum of volumes of pores having a diameter in the range of 50 to 100 µm is 17 to 50%, and the porosity ((ρtb)/ρt) calculated from the bulk density (ρb) and the true density (ρt) is 75 to 87%.

    [0025] According to a preferred aspect of the first embodiment or the second embodiment of the carbon sheet of the present invention, the diameter of a pore having the largest volume (peak diameter) in the diameter range of 1 to 100 µm is within the range of 30 to 50 µm.

    [0026] A third embodiment of the carbon sheet of the present invention is a carbon sheet, wherein when the sum of volumes of pores having a pore diameter in the range of 1 to 100 µm is 100%, the sum of volumes of pores having a pore diameter in the range of 50 to 100 µm is 17 to 50%, and the porosity ((ρtb)/ρt) calculated from the bulk density (ρb) and the true density (ρt) is 75 to 87%.

    [0027] According to a preferred aspect of the third embodiment of the carbon sheet of the present invention, the diameter of a pore having the largest volume (peak diameter) in the diameter range of 1 to 100 µm is within the range of 30 to 50 µm.

    EFFECTS OF THE INVENTION



    [0028] According to the present invention, a relatively thin carbon sheet having an excellent anti-flooding characteristic, which has been heretofore difficult to prepare, can be obtained. The carbon sheet of the present invention is capable of improving fuel cell performance particularly at a low temperature, and is suitably used in a gas diffusion electrode substrate.

    BRIEF DESCRIPTION OF THE DRAWINGS



    [0029] 

    Fig. 1 is a schematic view of a profile of a depth versus a ratio of an area of a portion having the depth in measurement of a depth distribution.

    Fig. 2 is a schematic sectional view for explaining a configuration of a carbon sheet of the present invention.

    Fig. 3 is a schematic view showing how to determine the fluorine intensity of the carbon sheet of the present invention.


    MODE FOR CARRYING OUT THE INVENTION



    [0030] A first embodiment of a carbon sheet of the present invention is a porous carbon sheet according to claim 1 including a carbon fiber and a binding material, wherein when in a measured surface depth distribution, the ratio of the area of a portion having a depth of 20 µm or less in the measured area of one surface is a surface layer area ratio X, and the ratio of the area of a portion having a depth of 20 µm or less in the measured area of the other surface is a surface layer area ratio Y, the surface layer area ratio X is larger than the surface layer area ratio Y, and a difference between the surface layer area ratios is 3% to 12%.

    [0031] In the present invention, the "area of a portion having a depth of 20 µm or less in the measured area of a surface" is obtained in the following manner: a surface depth distribution is measured, the areas of portions having a depth from the outermost surface to a part close to the outermost surface side (shallow portions close to the outermost surface side) are cumulatively added, a depth at which the ratio of the cumulative area in the whole measured range reaches 2% is determined, and with the depth as a reference, a sum of the areas of portions in a range from the reference to a depth of 20 µm is determined. The area thus determined is defined as the "area of a portion having a depth of 20 µm or less in the measured area of a surface". The ratio of the "area of a portion having a depth of 20 µm or less" in the measured area is defined as a surface layer area ratio.

    [0032] Accordingly, the surface layer area ratio is an area ratio obtained in the following manner: a surface depth distribution is measured, the area ratios of portions having a depth from the outermost surface to a part close to the outermost surface side (shallow portions close to the outermost surface side) are cumulatively added, a depth at which the ratio of the cumulative area in the whole measured range reaches 2% is determined, and with the depth as a reference, the area ratios of portions in a range from the reference to a depth of 20 µm are cumulatively added. In the present invention, the surface layer area ratio on one surface is different from the surface layer area ratio on the other surface.

    [0033] Fig. 1 is a schematic view of a profile of a depth versus a ratio of an area (area ratio) of a portion having the depth in measurement of a depth distribution. A depth-versus-area ratio profile (1) represents a ratio of an area (area ratio) of a portion having the depth in the whole measured range, and a total measured area ratio (4) represents a total of area ratios in all depth regions in the measured range, and is equal to 100%. Area ratios of shallow portions close to the outermost surface are cumulatively added, and the area ratio of a portion at which the cumulative area ratio reaches 2% is defined as an excluded area ratio (2). The rightmost point (depth) included in the excluded area ratio (2) is defined as a depth (5) at which the cumulative area ratio reaches 2%, and with this point as a reference (0 µm) of the depth, the area ratios of portions situated in a range from the reference (0 µm) to a depth of 20 µm in a through-plane direction. The cumulative area ratio thus obtained is defined as a surface layer area ratio (3).

    [0034] A second embodiment of the carbon sheet of the present invention is a porous carbon sheet according to claim 5 including a carbon fiber and a binding material, wherein when a surface having a larger covering rate on the surface by the carbon fiber and the binding material is a surface X2, and a surface having a smaller covering rate on the surface by the carbon fiber and the binding material is a surface Y2, a difference in the covering rate between the surface X2 and the surface Y2 is 5% or more and 20% or less.

    [0035] In a preferred aspect of the carbon sheet of the present invention, the carbon sheet includes a hydrophobic material, and where among layers obtained by dividing the carbon sheet in a through-plane direction thereof into three equal parts within a section extending from a surface having a 50% average fluorine intensity, which is closest to one surface, to a surface having a 50% average fluorine intensity, which is closest to the other surface, one of a layer close to one surface and a layer close to the other layer, which has a larger average fluorine intensity, is a layer A, the other one of a layer close to one surface and a layer close to the other layer, which has a smaller average fluorine intensity, is a layer B, and a layer between the layer A and the layer B is a layer C, the average fluorine intensity of the layer decreases in the order of the layer A, the layer B and the layer C.

    [0036] Here, the 50% average fluorine intensity is a value of 50% of the average of fluorine intensities measured along a straight line extending in a through-plane direction of the carbon sheet from one surface to the other surface of the carbon sheet. The "surface having a 50% average fluorine intensity, which is closest to one surface" represents a virtual surface that is substantially parallel to a surface of the carbon sheet and that includes a set of points showing a 50% average fluorine intensity, which are closest to one surface on a straight line in a through-plane direction of the carbon sheet in the measurement. The "surface having a 50% average fluorine intensity, which is closest to one surface" is not required to be actually a continuous surface in the carbon sheet. The phrase "the average fluorine intensity of the layer decreases in the order of the layer A, the layer B and the layer C" means that the layers satisfy the relationship of layer A > layer B > layer C in terms of the average fluorine intensity.

    [0037] Hereinafter, the configurations of the carbon sheet and the gas diffusion electrode substrate in the present invention will be described with reference to the drawings. Fig. 2 is a schematic sectional view for explaining the first embodiment and the second embodiment of the carbon sheet of the present invention, and a preferred aspect of the carbon sheet of the present invention.

    [0038] In Fig. 2, a depth (reference depth) (9) in a through-plane direction from one surface (surface X1 or surface X2 (7)), at which the cumulative area ratio reaches 2%, is determined by measurement of a surface depth distribution. Using as a reference the depth (reference depth) (9) at which the cumulative area ratio reaches 2%, a depth (10) of a part deeper than the reference depth by 20 µm can be determined. For the opposite surface, a depth (reference depth) (9) at which the cumulative area ratio reaches 2% can be determined, followed by determining a depth (10) of a part deeper than the reference depth by 20 µm.

    [0039] Next, in a preferred aspect of the present invention, where among layers obtained by dividing the carbon sheet in a through-plane direction thereof into three equal parts within a section (17) extending from a surface (surface AA(12)) having a 50% average fluorine intensity, which is closest to one surface (surface X1 or surface X2(7)), to a surface (surface BB(13)) having a 50% average fluorine intensity, which is closest to the other surface (surface Y1 or surface Y2 (8)), one of a layer close to one surface (surface X1 or surface X2(7)) and a layer to the other surface (surface Y1 or surface Y2 (8)), which has the largest average fluorine intensity, is a layer A(14), and the other one of a layer close to one surface (surface X1 or surface X2(7)) and a layer to the other surface (surface Y1 or surface Y2(8)), which is close to the other surface (surface Y1 or surface Y2(8)) and has an average fluorine intensity smaller than that of the layer A(14), is a layer B(16), and a layer between the layer A(14) and the layer B(16) is a layer C(15), it is preferred that the average fluorine intensity of the layer decrease in the order of the layer A (14), the layer B(16) and the layer C(15).

    [0040] Thus, the preferred aspect of the carbon sheet (6) of the present invention includes the layer A(14), the layer B(16), the layer C(15), and the layer (10) having an average fluorine intensity less than the 50% average fluorine intensity. In the present invention, a gas diffusion electrode substrate can be obtained by providing a microporous layer on the surface X1 or the surface X2(7).

    [Carbon Sheet]



    [0041] The carbon sheet of the present invention can be prepared through the steps of preparation of a porous material including a carbon fiber as described below, impregnation of a resin composition, lamination and annealing performed as necessary, carbonation, and hydrophobic treatment performed as necessary. The carbon sheet of the present invention is a porous carbon sheet including a carbon fiber and a binding material, and can be subjected to a hydrophobic treatment as necessary.

    [0042] In the present invention, the binding material represents components other than the carbon fiber in the carbon sheet. Thus, the binding material includes a carbonized material of a resin composition that is a material serving to bind carbon fibers. When a hydrophobic material is used in the carbon sheet of the present invention, the hydrophobic material is included in the binding material.

    [0043] It is important that the carbon sheet of the present invention is porous. When the carbon sheet is porous, both excellent gas diffusivity and excellent water removal performance can be achieved. For making the carbon sheet porous, a porous material is preferably used as a material to be used for producing the carbon sheet.

    <Preparation of Porous Material Including Carbon Fiber>



    [0044] A porous material to be used for producing a porous carbon sheet will be described. Preferably, the porous carbon sheet of the present invention has high gas diffusivity for allowing a gas supplied from a bipolar plate to be diffused into a catalyst and high water removal performance for discharging water generated by an electrochemical reaction to the bipolar plate, as well as high electrical conductivity for extracting generated electric current. Thus, for obtaining a porous carbon sheet, a porous material having electrical conductivity is preferably used. More specifically, as the porous material to be used for obtaining a porous carbon sheet, for example, a porous material including a carbon fiber, such as a carbon fiber papermaking substrate, a carbon fiber woven material or a felt-type carbon fiber nonwoven fabric, is preferably used. Among them, a carbon fiber papermaking substrate is preferably used as a porous material because it has excellent property of absorbing a change in dimension of an electrolyte membrane in a through-plane direction when the porous substrate is formed into a porous carbon sheet. Hereinafter, preparation of the porous material will be described with a carbon fiber papermaking substrate as a typical example.

    [0045] In the present invention, as described below, a substrate on which a carbon fiber papermaking substrate is bonded with a binding material can also be obtained by impregnating a carbon fiber papermaking substrate with a resin and then carbonizing the resultant.

    [0046]  Examples of the carbon fiber in the carbon sheet of the present invention and the porous material to be used for obtaining the carbon sheet include polyacrylonitrile (PAN) -based, pitch-based and rayon-based carbon fibers. Among them, a PAN-based carbon fiber or a pitch-based carbon fiber is preferably used because of its excellent mechanical strength.

    [0047] In the carbon fiber in the carbon sheet of the present invention and the porous material to be used for obtaining the carbon sheet, the mean diameter of monofilaments is preferably within the range of 3 to 20 µm, more preferably within the range of 5 to 10 µm. When the mean diameter of monofilaments is 3 µm or more, the pore diameter becomes large, and the water removal performance is improved, so that flooding can be suppressed. Meanwhile, when the mean diameter of monofilaments is 20 µm or less, diffusion of water vapor is reduced. Resultantly, when the fuel cell is operated at a relatively high temperature of 80°C or more, the electrolyte membrane is dried, so that proton conductivity is reduced, and resultantly, the problem of deterioration of fuel cell performance (hereinafter, described as "dry-out") can be suppressed.

    [0048] Here, the mean diameter of monofilaments in the carbon fiber is an average value determined by taking a photograph of the carbon fiber at a magnification of 1000 times, under a microscope such as a scanning electron microscope, randomly selecting 30 different monofilaments, and measuring their diameters. As the scanning electron microscope, S-4800 manufactured by Hitachi, Ltd. or its equivalent product can be used.

    [0049] In the carbon fiber to be used in the present invention, the mean length of monofilaments is preferably within the range of 3 to 20 mm, more preferably within the range of 5 to 15 mm. When the mean length is 3 mm or more, the carbon sheet attains excellent mechanical strength, electrical conductivity and thermal conductivity. Meanwhile, when the mean length of monofilaments is 20 mm or less, dispersibility of the carbon fiber in papermaking is improved, so that a uniform carbon sheet can be obtained. A carbon fiber having the above-mentioned mean length of monofilaments can be obtained by a method of cutting a continuous carbon fiber into a desired length, or the like.

    [0050] Here, the mean length of monofilaments in the carbon fiber is an average value determined by taking a photograph of the carbon fiber at a magnification of 50 times, under a microscope such as a scanning electron microscope, randomly selecting 30 different monofilaments, and measuring their length. As the scanning electron microscope, S-4800 manufactured by Hitachi, Ltd. or its equivalent product can be used.

    [0051] The mean diameter and mean length of monofilaments in the carbon fiber are usually measured by directly observing the carbon fiber for a carbon fiber to be a raw material, and can be measured by observing the carbon sheet.

    [0052] The carbon fiber papermaking substrate formed by papermaking as one aspect of the porous material to be used for obtaining the carbon sheet is preferably in the form of a sheet in which a carbon fiber is randomly dispersed in a two-dimensional plane, in order to maintain the in-plane electrical conductivity and thermal conductivity to be isotropic when the papermaking substrate is formed into the carbon sheet. Papermaking of the carbon fiber in preparation of the carbon fiber papermaking substrate can be performed once, or performed multiple times in a laminated form. In the present invention, it is desirable to perform papermaking once for not only improving productivity but also stably preparing a thin carbon sheet having a thickness that allows high fuel cell performance to be easily achieved.

    [0053] For the mean diameter of monofilaments in the carbon fiber, the ratio of the mean diameter of monofilaments in the carbon fiber which is determined from one surface of the carbon sheet and the mean diameter of monofilaments in the carbon fiber which is determined from the other surface of the carbon sheet is 0.5 or more and 1 or less. When both the mean diameters are equal to each other, the ratio is 1, and when both the mean diameters are different from each other, the ratio is a value of "smaller mean diameter/larger mean diameter". A difference between the mean length of monofilaments in the carbon fiber which is determined from one surface of the carbon sheet and the mean length of monofilaments in the carbon fiber which is determined from the other surface of the carbon sheet is preferably 0 mm or more and 10 mm or less. Accordingly, uniform dispersion can be performed in dispersion of the fiber, and variations in density and thickness can be reduced at the time of performing papermaking. Thus, in a fuel cell obtained using a gas diffusion electrode substrate including the carbon sheet of the present invention, adhesion between a catalyst layer and the gas diffusion electrode substrate is improved, so that the fuel cell has good fuel cell performance. In the present invention, a fiber composed of monofilaments having a mean diameter of less than 1 µm is considered as a binding material.

    [0054] In the present invention, the carbon fiber areal weight in the carbon fiber papermaking substrate is preferably within the range of 10 to 50 g/m2, more preferably within the range of 15 to 35 g/m2, further preferably within the range of 20 to 30 g/m2. When the carbon fiber areal weight in the carbon fiber papermaking substrate is 10 g/m2 or more, the carbon sheet obtained from the carbon fiber papermaking substrate has excellent mechanical strength. When the carbon fiber areal weight in the carbon fiber papermaking substrate is 50 g/m2 or less, the carbon sheet obtained from the carbon fiber papermaking substrate has excellent gas diffusivity and water removal performance in an in-plane direction. In cases where a plurality of papermaking substrates are laminated to obtain a carbon fiber papermaking substrate, it is preferred that the carbon fiber areal weight in the carbon fiber papermaking substrate after the lamination be in the above-described range.

    [0055] Here, the carbon fiber areal weight in the carbon sheet can be determined by retaining a carbon fiber papermaking substrate cut into a 10-cm square under a nitrogen atmosphere in an electric furnace at a temperature of 450°C for 15 minutes and then dividing the mass of the residue obtained by removal of organic matters by the area of the carbon fiber papermaking substrate (0.01 m2).

    <Impregnation of Resin Composition>



    [0056] In preparation of the carbon sheet of the present invention, a porous material containing a carbon fiber, such as a carbon fiber papermaking substrate, is impregnated with a resin composition that serves as a binding material.

    [0057] In the present invention, the binding material in the carbon sheet represents components other than the carbon fiber in the carbon sheet, and mainly serves to bind carbon fibers. Examples of the material that serves to bind carbon fibers include resin compositions to be impregnated into the porous material, and carbides thereof. Hereinbelow, a carbon fiber-containing porous material impregnated with a resin composition that serves as a binding material may be described as a "prepreg".

    [0058] As a method for impregnating a carbon fiber-containing porous material with a resin composition that serves as a binding material, a method of dipping a porous material into a resin composition containing a solvent, a method of coating a porous material with a resin composition containing a solvent, a method of forming on a release film a layer composed of a resin composition, and transferring to a porous material the layer composed of a resin composition, or the like is preferably employed. Among them, a method of dipping a porous material into a resin composition containing solvent is preferably employed because of its excellent productivity. By adhering the resin composition to the whole of a prepreg, the binding material can be adhered to the whole of the resulting carbon sheet, and therefore the strength of the carbon sheet can be further improved.

    [0059] In the first embodiment or the second embodiment of the carbon sheet of the present invention, the surface layer area ratio or the covering rate for one surface of the carbon sheet is different from the surface layer area ratio or the covering rate for the other surface of the carbon sheet (details thereof will be described below) . This can be achieved by distributing a larger loading amount of the resin composition to one surface at the time of impregnating the porous material with the resin composition that serves as a binding material in the carbon sheet. In other words, this can be achieved by distributing a larger amount of the binding material to one surface in the carbon sheet. More specifically, by uniformly impregnating the whole of a porous material such as a carbon fiber-containing papermaking substrate with a resin composition by dipping or the like, and then removing an excess amount of the adhered resin composition from one surface before drying, one surface and the other surface of the resulting carbon sheet can be controlled to have different surface layer area ratios or covering rates.

    [0060] As one example, by dipping a carbon fiber papermaking substrate into a resin composition-containing solution to obtain a prepreg, and then suctioning the resin composition-containing solution from one surface or pressing a squeeze roll against only one surface of the carbon fiber papermaking substrate before drying the prepreg, the loading amount of the resin composition in the vicinity of one surface of the carbon fiber papermaking substrate (a surface corresponding to the below-described surface Y1 or Y2 in a carbon sheet formed from the carbon fiber papermaking substrate) can be made smaller than the loading amount of the resin composition in the vicinity of the other surface of the carbon fiber papermaking substrate (a surface corresponding to the below-described surface X1 or X2 in a carbon sheet formed from the carbon fiber papermaking substrate). According to this method, the resin composition can be adhered to the whole of the carbon fiber papermaking substrate, and therefore the binding material exists on the whole of the resulting carbon sheet, so mechanical strength can be retained.

    [0061] As another example, by dipping a carbon fiber papermaking substrate into a resin composition-containing solution to obtain a prepreg, and then additionally coating only one surface of the carbon fiber papermaking substrate with the resin composition by a spray or a gravure roll, one surface and the other surface of the carbon sheet can be controlled to have different surface layer area ratios or covering rates. Further, by adhering a larger amount of the resin composition to one surface by means of gravity applied to the resin composition or by hot-air drying from the surface during drying after dipping the carbon fiber papermaking substrate into the resin composition-containing solution, one surface and the other surface of the carbon sheet can be controlled to have different surface layer area ratios or covering rates.

    [0062] By dipping two carbon fiber papermaking substrates with the carbon fiber papermaking substrates superimposed on each other in such a manner that their surfaces corresponding to the surface Y1 or the surface Y2 are mated with each other, drying the two carbon fiber papermaking substrates with the carbon fiber papermaking substrates superimposed on each other, and drying and then separating the carbon fiber papermaking substrates, the amount of the binding material adhered to the surface Y1 or the surface Y2 can be made smaller than the amount of the binding material adhered to the surface X1 or the surface X2.

    [0063] Similarly to the carbon sheets of the first embodiment and the second embodiment, a carbon sheet of a third embodiment of the present invention can be prepared by a method of additionally coating only one surface of a carbon fiber papermaking substrate with a resin composition. By impregnating at least one surface of a carbon fiber papermaking substrate with a resin composition containing particles which are eliminated at a high temperature of 400°C or more, and eliminating the particles in a carbonization step as described below, the sizes of pores formed in the carbon sheet can be controlled. Here, only one surface may be impregnated with particles that are eliminated, or the particles can be applied in the form of a pattern to unevenly form portions having large pores.

    [0064] In the present invention, the resin composition to be used in preparation of a prepreg is a resin component to which a solvent or the like is added as required. Here, the term "resin component" refers to a component which contains a resin such as a thermosetting resin or a thermoplastic resin and, as required, an additive(s) such as a carbon-based powder and a surfactant.

    [0065] The carbonization yield of the resin component contained in the resin composition is preferably 40% by mass or more. When the carbonization yield is 40% by mass or more, the carbon sheet easily attains excellent mechanical properties, electrical conductivity and thermal conductivity. The carbonization yield of the resin component contained in the resin composition is not particularly limited, and is normally about 60% by mass.

    [0066] The resin constituting the resin component in the resin composition includes thermosetting resins such as phenolic resins, epoxy resins, melamine resins and furan resins, and the like. Among them, a phenolic resin is preferably used because of its high carbonization yield.

    [0067] Further, as an additive to be added as a resin component in the resin composition as required, a carbon powder can be used for the purpose of improving the mechanical properties, electrical conductivity and thermal conductivity of the carbon sheet. Here, for the carbon powder, a carbon black such as furnace black, acetylene black, lamp black or thermal black, a graphite such as scaly graphite, scale-like graphite, earthy graphite, artificial graphite, expanded graphite or flaky graphite, a carbon nanotube, a carbon nanofiber, a milled fiber of carbon fiber or the like can be used.

    [0068] As the resin composition, the resin component can be used as it is, or the resin component may contain various kinds of solvents as required for the purpose of improving impregnation property into a porous material such as a carbon fiber papermaking substrate. Here, as the solvent, methanol, ethanol, isopropyl alcohol or the like can be used.

    [0069]  It is preferred that the resin composition be in a liquid form under a condition of 25°C and 0.1 MPa. When the resin composition is in a liquid form, it has excellent impregnation property into a porous material such as a papermaking substrate, so that the resulting carbon sheet attains excellent mechanical properties, electrical conductivity and thermal conductivity.

    [0070] In impregnation of the resin composition, the porous material is impregnated with the resin composition in such a manner that the amount of the resin component is preferably 30 to 400 parts by mass, more preferably 50 to 300 parts by mass based on 100 parts by mass of the carbon fiber in the prepreg. When the amount of the impregnated resin composition based on 100 parts by mass of the carbon fiber in the prepreg is 30 parts by mass or more, more preferably 50 parts by mass or more, the carbon sheet has excellent mechanical properties, electrical conductivity and thermal conductivity. Meanwhile, when the amount of the impregnated resin composition based on 100 parts by mass of the carbon fiber in the prepreg is 400 parts by mass or less, more preferably 300 parts by mass or less, the carbon sheet has excellent gas diffusivity in an in-plane direction and excellent gas diffusivity in a through-plane direction.

    <Lamination and Annealing>



    [0071] In the present invention, after a prepreg in which a porous material such as a carbon fiber papermaking substrate is impregnated with a resin composition is formed, the prepreg can be laminated and/or annealed prior to carbonization.

    [0072] In the present invention, a plurality of prepregs can be laminated in order to allow the carbon sheet to have a prescribed thickness. In this case, a plurality of prepregs having the same properties can be laminated, or a plurality of prepregs having different properties can be laminated. Specifically, it is possible to laminate a plurality of prepregs that are different in terms of the carbon fiber diameter or carbon fiber length, the areal weight of the carbon fiber in a porous material such as a carbon fiber papermaking substrate to be used in preparation of the prepreg, the amount of the impregnated resin component, and the like.

    [0073] Meanwhile, lamination of a plurality of prepregs causes formation of a discontinuous surface in a through-plane direction, so that internal separation may occur, and therefore in the present invention, it is desirable that rather than laminating a plurality of porous materials such as carbon fiber papermaking substrates, only one porous material be subjected to annealing.

    [0074] In order to increase viscosity of the resin composition in the prepreg or partially cross-link the resin composition, the prepreg can be subjected to annealing. As an annealing method, a method of blowing hot air against the prepreg, a method of heating the prepreg by sandwiching it between hot platens of a press apparatus, a method of heating the prepreg by sandwiching it between continuous belts or the like can be employed.

    <Carbonization>



    [0075] In the present invention, a porous material such as a carbon fiber paper making substrate is impregnated with a resin composition to obtain a prepreg, and the prepreg is then baked in an inert atmosphere for carbonizing the resin component. For this baking, a batch-type heating furnace or a continuous heating furnace can be used. Further, the inert atmosphere can be obtained by allowing an inert gas such as nitrogen gas or argon gas to flow in the furnace.

    [0076] In the present invention, the highest temperature in the baking is preferably within the range of 1300 to 3000°C, more preferably within the range of 1700 to 3000°C, and further preferably within the range of 1900 to 3000°C. When the highest temperature is 1300°C or more, carbonization of the resin component in the prepreg is facilitated, so that the carbon sheet attains excellent electrical conductivity and thermal conductivity. Meanwhile, when the highest temperature is 3000°C or less, the operating cost of the heating furnace is reduced.

    [0077] In the present invention, a porous material such as a carbon fiber papermaking substrate which is impregnated with a resin composition and then carbonized may be referred to as "baked carbon fiber". The carbon sheet means a baked carbon fiber, and both the baked carbon fiber before being subjected to a hydrophobic treatment and the baked carbon fiber after being subjected to a hydrophobic treatment correspond to the carbon sheet.

    <Hydrophobic Treatment>



    [0078] In the present invention, it is preferred that the baked carbon fiber be subjected to a hydrophobic treatment for the purpose of improving water removal performance. In other words, it is preferred that the carbon sheet contain a hydrophobic material. The hydrophobic treatment can be performed by coating the baked carbon fiber with a hydrophobic material and subsequently annealing the coated baked carbon fiber. When the hydrophobic treatment is performed using a hydrophobic material, the carbon sheet contains the hydrophobic material as a binding material.

    [0079] As the hydrophobic material, a fluorine-based polymer is preferably used because of its excellent corrosion resistance. The fluorine-based polymer includes polytetrafluoroethylene (PTFE), tetrafluoroethylene-hexa fluoro propylene copolymers (FEP), tetrafluoroethylene-perfluoroalkylvinyl ether copolymers (PFA), and the like.

    [0080] In the first embodiment or the second embodiment of the carbon sheet of the present invention, the sliding angle of water at the surface Y1 or the surface Y2 is preferably 40 degrees or less. A gas diffusion electrode substrate of the present invention can be obtained by forming a microporous layer on the surface X1 or the surface X2 of the carbon sheet of the present invention. When the gas diffusion electrode substrate is used as a fuel cell, the surface Y1 or the surface Y2 is on the bipolar plate side, and good water removal performance from the carbon sheet to the bipolar plate can be obtained by setting the sliding angle of water at the surface Y1 or the surface Y2 to 40 degrees or less. Here, the sliding angle of water at the surface Y1 or the surface Y2 means a sliding angle determined by making a measurement from the surface Y1 or surface Y2 side of the carbon sheet. The sliding angle at the surface Y1 or the surface Y2 is preferably as small as possible, and the best water removal performance can be achieved at a sliding angle of 1 degree.

    [0081] As a method for performing control so that the sliding angle of water at the surface Y1 or the surface Y2 is 40 degrees or less, mention may be made of a method of performing a hydrophobic treatment. In annealing in the hydrophobic treatment step, the hydrophobic material is melted, and thus has a low viscosity, so that the hydrophobic material can be uniformly adhered to the surface of the carbon fiber in the carbon sheet, and the sliding angle of water can be kept at 40 degrees or less to improve the hydrophobicity of the carbon sheet.

    [0082] In the third embodiment of the carbon sheet of the present invention, similarly the sliding angle of water at one surface of the carbon sheet is preferably 40 degrees or less, and this surface is preferably a surface on a side opposite to a surface which is provided with a microporous layer.

    [0083] Meanwhile, by thinly adhering the hydrophobic material to a surface of the baked carbon sheet, electrical conductivity with the bipolar plate can be improved. It is preferred that the melting point of the hydrophobic material to be used in the hydrophobic treatment be 200°C or more and 320°C or less for thinly adhering the hydrophobic material. As a type of the hydrophobic material that satisfies the above-mentioned requirement, mention is made of FEP or PFA. When the melting point of the hydrophobic material is 320°C or less, the hydrophobic material is easily melted to uniformly spread the hydrophobic over the carbon fiber surface in the carbon sheet in annealing in the hydrophobic treatment, so that a carbon sheet having high hydrophobicity can be obtained, and the anti-flooding characteristic can be improved. When the melting point of the hydrophobic material is 200°C or more, the hydrophobic material is hardly thermally decomposed in annealing in the hydrophobic treatment, so that a carbon sheet having high hydrophobicity can be obtained. By using the above-mentioned material, the water removal performance of the carbon sheet having a structure according to the present invention can be considerably enhanced, so that accumulation of water in the carbon sheet subjected to the hydrophobic treatment can be reduced, and therefore gas diffusivity can be considerably improved.

    [0084] The loading amount of the hydrophobic material is preferably 1 to 50 parts by mass, more preferably 2 to 40 parts by mass based on 100 parts by mass of the baked carbon fiber. When the loading amount of the hydrophobic material is 1 part by mass or more, the carbon sheet has excellent water removal performance. Meanwhile, when the loading amount of the hydrophobic material is 50 parts by mass or less, the carbon sheet has excellent electrical conductivity.

    [0085] In the present invention, the baked carbon fiber corresponds to the "carbon sheet". As described above, the baked carbon fiber is subjected to a hydrophobic treatment as necessary, and in the present invention, the baked carbon fiber subjected to a hydrophobic treatment also corresponds to the "carbon sheet". Of course, the baked carbon fiber that is not subjected to a hydrophobic treatment corresponds to the "carbon sheet".

    [Feature of Carbon Sheet]



    [0086] The feature of the carbon sheet of the present invention which is obtained through steps as described above will be now be described.

    [0087] In the present invention, the density of the carbon sheet is preferably within the range of 0.20 to 0.40 g/m3, more preferably within the range of 0.22 to 0.35 g/m3, further preferably within the range of 0.24 to 0.30 g/m3. When the density is 0.20 g/cm3 or more, water vapor diffusivity is small, so that dry-out can be suppressed. The mechanical strength of the carbon sheet is improved, so that the electrolyte membrane and the catalyst layer can be sufficiently supported. In addition, high electrical conductivity is attained, and the fuel cell performance is thus improved. Meanwhile, when the density is 0.40 g/cm3 or less, water removal performance is improved, and flooding can thus be suppressed.

    [0088]  A carbon sheet having a density as described above can be obtained by controlling the areal weight of the carbon fiber, the addition amount of the resin component based on the amount of the carbon fiber, and the thickness of the carbon sheet as described below in a method for producing a carbon sheet. Here, the density of the carbon sheet can be determined by dividing the areal weight (mass per unit area), which is measured using an electronic balance, by the thickness of the carbon sheet in a state of being compressed at a pressure of 0.15 MPa.

    [0089] In the present invention, it is not necessarily required to laminate a plurality of prepregs as in the conventional art. Thus, in the present invention, it is easy to reduce the thickness of the carbon sheet.

    [0090] Also, the thickness of the carbon sheet of the present invention is preferably 50 to 230 µm, more preferably 70 to 180 µm, further preferably 90 to 130 µm. When the thickness of the carbon sheet is 230 µm or less, more preferably 180 µm or less, further preferably 130 µm or less, gas diffusivity is easily enhanced, and generated water is easily discharged. Further, the size of a fuel cell as a whole is easily reduced. Meanwhile, when the thickness of the carbon sheet is 50 µm or more, more preferably 70 µm or more, further preferably 90 µm or more, gas diffusion in a plane direction in the carbon sheet is efficiently performed, and fuel cell performance is easily improved.

    [0091] The thickness of the carbon sheet of the present invention is determined by the following method. Specifically, a carbon sheet and a gas diffusion electrode substrate are placed on a smooth surface plate, and a difference in height between the case of presence of a measurement object and the case of absence of the measurement object is measured in a state in which a pressure of 0.15 MPa is applied. Samples are taken at 10 different parts, measured values of the difference in height are averaged, and the average thus obtained is defined as a thickness.

    [0092] As described above, it is preferred that the surface layer area ratio for one surface be different from the surface layer area ratio for the other surface in the first embodiment of the carbon sheet of the present invention.

    [0093] The surface layer area ratio is determined by measuring a surface depth distribution of the carbon sheet using a shape analysis laser microscope. First, the range of 5 mm square of each of randomly selected carbon sheets is fixed on a surface plate in such a manner that lifting does not occur, and the surface depth distributions of randomly selected portions are measured using the laser microscope.

    [0094] The obtained data is subjected to automatic plane tilt correction, and a surface depth distribution is then calculated. A profile of a depth versus a ratio of an area (area ratio) of a portion having the depth in measurement of a depth distribution as shown in Fig. 1 is prepared. Area ratios of shallow portions close to the outermost surface are cumulatively added, and the area ratio of a portion at which the cumulative area ratio reaches 2% is defined as an excluded area ratio. Further, using as a reference the depth at which the cumulative area ratio reaches 2%, a cumulative area ratio from the depth as a reference to the depth of a part deeper than the reference by 20 µm is determined. The cumulative area ratio obtained in this manner is a surface layer area ratio. An average of values determined in this manner for 10 points is employed as the surface layer area ratio.

    [0095] From a physical point of view, the surface layer area ratio represents an area ratio of a substance existing at the surface layer. When a large amount of the carbon fiber or binding material exists at a relatively shallow portion of the surface, the surface layer area ratio is large. The surface layer area ratio can be controlled by adhering a large amount of the binding material in the vicinity of a surface of the carbon sheet by adhering a large amount of the resin composition in the vicinity of a surface of a prepreg in preparation of the prepreg.

    [0096] For the measurement, a laser microscope (VK-X100 manufactured by KEYENCE CORPORATION) is used, and an objective lens with a magnification of 10 is used. Measurements are made for five lines in a longitudinal direction and for four rows in a lateral direction, and the images of results are linked, whereby surface depth distribution data in the range of 5 mm square can be obtained.

    [0097] When a fuel cell is operated at a relatively low temperature of below 70°C in a high-current-density region, as a result of blockage of the gas diffusion electrode substrate by liquid water generated in a large amount and shortage in the gas supply, the fuel cell performance is impaired. This problem is so called flooding, which should be suppressed.

    [0098] In the first embodiment of the carbon sheet of the present invention, the surface layer area ratio Y is made smaller than the surface layer area ratio X, so that liquid water in the carbon sheet moves from the surface X1 having a large surface layer area ratio to the surface Y1 having a large opening and having a small surface layer area ratio Y, and thus liquid water can be efficiently discharged from the carbon sheet to the bipolar plate. Accordingly, not only water removal performance is improved, but also the inside of the carbon sheet is no longer blocked by water, so that gas diffusivity is improved. Thus, flooding can be suppressed even in the case of electrical power generation in a high-current-density region where a large amount of liquid water is generated.

    [0099] It is desirable that there be a certain difference in surface layer area ratio between both the surfaces of the carbon sheet as described above, and the difference in surface layer area ratio between the surface X1 and the surface Y1 is preferably 3% or more. Meanwhile, when the difference in surface layer area ratio is excessively large, deviation of the binding material distribution excessively increases, so that mechanical strength is apt to be insufficient. Thus, the difference in surface layer area ratio is preferably 12% or less. Further, in view of a balance between efficient water removal performance and gas diffusivity, the difference in surface later area ratio is preferably 4.0% or more and 9.6% or less, more preferably 4.7% or more and 7.0% or less.

    [0100] For the surface X1, the surface layer area ratio X is preferably 13% or more for controlling diffusion of water vapor by the surface layer area ratio, and preferably 17% or less for securing diffusion of a fuel gas and an oxidizing gas. Further, in view of a balance with mechanical strength, the surface layer area ratio X is preferably 14.8% or more and 16.0% or less.

    [0101] For the surface Y1, the surface layer area ratio Y is preferably 9% or more for retaining mechanical strength, while the surface layer area ratio is preferably 13% or less for effectively discharging liquid water. In view of a balance with mechanical strength, the surface layer area ratio Y is more preferably 9.1% or more and 10.3% or less.

    [0102] Where a surface having the surface layer area ratio X is the surface X1, and a surface having the surface layer area ratio Y is the surface Y1, the surface roughness of the surface X1 is preferably smaller than the surface roughness of the surface Y1. When the surface roughness of the surface X1 is smaller than the surface roughness of the surface Y1, penetration of a filler-containing coating solution into the carbon sheet is reduced, so that the gas diffusivity of the gas diffusion electrode substrate can be improved. It is desirable that there be a certain difference in surface roughness between the surface X1 and the surface Y1, and the difference in surface roughness is preferably 1 µm or more and 4 µm or less. The surface roughness of the surface X1 means a surface roughness measured from the surface X1 side of the carbon sheet, and the surface roughness of the surface Y1 means a surface roughness measured from the surface Y1 side of the carbon sheet. In the second embodiment or the third embodiment of the carbon sheet of the present invention, similarly it is desirable that there be a certain difference in surface roughness between one surface and the other surface, and the difference in surface roughness is preferably 1 µm or more and 4 µm or less.

    [0103] Here, the surface roughness of the surface X1 is preferably 16 µm or less, more preferably 11 µm or more and 16 µm or less, further preferably 13 µ or more and 15 µm or less. Meanwhile, the surface roughness of the surface Y1 is preferably 12 µm or more and 20 µm or less, further preferably 14 µ or more and 19 µm or less. When the surface roughness of the surface X1 of the carbon sheet is 16 µm or less, and the surface roughness of the surface Y1 is 12 µm or more and 20 µm or less, penetration of a filler-containing coating solution into the carbon sheet is reduced, so that the gas diffusivity of the gas diffusion electrode substrate can be improved. Further, a microporous layer having a small surface roughness can be obtained. In the second embodiment or the third embodiment of the carbon sheet of the present invention, similarly the surface roughness of a surface having a smaller surface roughness is preferably 16 µm or less, more preferably 11 µm or more and 16 µm or less, further preferably 13 µ or more and 15 µm or less. Meanwhile, the surface roughness of a surface having a larger surface roughness is preferably 12 µm or more and 20 µm or less, further preferably 14 µ or more and 19 µm or less.

    [0104] In the second embodiment of the carbon sheet of the present invention, it is important that the covering rate on the surface by the carbon fiber and the binding material for one surface of the surface X2 and the surface Y2 is different from the covering rate on the surface by the carbon fiber and the binding material for the other surface.

    [0105] The covering rate is represented by a ratio of a portion where the surface is covered with the carbon fiber and the binding material in the whole surface (the whole of a void portion and a portion where the carbon fiber and the binding material exist). The covering rate can be determined by performing a numerical treatment of an image of a surface of the carbon sheet which is observed with a scanning electron microscope. Specifically, the void portion on the surface is separated from the portion where the carbon fiber and the binding material exist on the surface, and the covering rate can be determined from the area ratio of these portions.

    [0106] First, using a scanning electron microscope (S4800 manufactured by Hitachi, Ltd.), a surface of the carbon sheet is magnified 50 times, a contrast between lightness and darkness is added by an attached automatic adjustment function, and an image of the surface of the carbon sheet is taken. Next, using "J-trim" that is an image processing program, the obtained image is divided in 256 stages between the maximum and the minimum of lightness in terms of a luminance, a portion at the 70th stage from the minimum is defined as a threshold, and binarization is performed. The ratio of the area of a lighter binarized part in the total area is defined as a covering rate [%]. In the second embodiment of the carbon sheet of the present invention, a surface having a larger covering rate is a surface X2, and a surface having a smaller covering rate is a surface Y2.

    [0107] In the second embodiment of the carbon sheet of the present invention, the covering rate on the surface Y2 is made smaller than the covering rate on the surface X2, so that liquid water in the carbon sheet moves from the surface X having a large covering rate to the surface Y2 having a large opening and having a small covering rate, and thus liquid water can be efficiently discharged from the carbon sheet to the bipolar plate. Accordingly, not only water removal performance is improved, but also the inside of the carbon sheet is no longer blocked by water, so that gas diffusivity is improved. Thus, flooding can be suppressed even in the case of electrical power generation in a high-current-density region where a large amount of liquid water is generated. For positively making use of a covering rate structure, it is desirable that there be a certain difference in covering rate between both the surfaces of the carbon sheet as described above, and it is important that the difference in covering rate between the surface X2 and the surface Y2 is 5% or more. Meanwhile, when the difference in covering rate is excessively large, deviation of the binding material distribution in the layer excessively increases, so that mechanical strength is apt to be insufficient. Thus, it is important that the difference in surface layer area ratio is 20% or less. Further, in view of a balance between efficient water removal performance and gas diffusivity, the difference in surface later area ratio is preferably 6.5% or more and 15.0% or less, more preferably 7.5% or more and 12.0% or less.

    [0108] For the surface X2, the covering rate on the surface X2 is preferably 70% or more for controlling diffusion of water vapor by the covering rate, and preferably 90% or less for securing diffusion of a fuel gas and an oxygen gas. Further, in view of a balance between efficient water removal performance and gas diffusivity, the covering rate on the surface X2 is preferably 75.0% or more and 81.4% or less.

    [0109] For the surface Y2, the covering rate on the surface Y2 is preferably 50% or more for retaining strength by binding, while the covering rate on the surface Y2 is preferably 75% or less for effectively discharging liquid water. Further, in view of a balance between efficient water removal performance and gas diffusivity, the covering rate on the surface X2 is preferably 68.0% or more and 75.0% or less.

    [0110] Preferably, the carbon sheet of the present invention contains a hydrophobic material, and for the layers A, B and C, the average fluorine intensity of the layer decreases in the order of the layer A, the layer B and the layer C.

    [0111] Since the average fluorine intensity of the layer C is smaller than the average fluorine intensity of the layer A, generated water produced due to electrical power generation quickly moves from the layer A to the layer C. Since the average fluorine intensity of the layer B is larger than that of the layer C, generated water is hardly accumulated in a portion that is in contact with a bipolar plate rib portion of the layer B, so that flooding is suppressed. Generated water flowing through a bipolar plate channel is hardly returned to the carbon sheet. When the layers are arranged in terms of the average fluorine intensity in such a manner that the average fluorine intensity decreases in the order of the layer A, the layer B and the layer C, the anti-flooding characteristic can be improved as compared to a case where the average fluorine intensity decreases in the order of the layer A, the layer C and the layer B.

    [0112] The average fluorine intensity of the layer for improving the anti-flooding characteristic is preferably such that where the average fluorine intensity of the layer B is 1, the average fluorine intensity of the layer A is within the range of 1.30 to 9.00, and the average fluorine intensity of the layer C is within the range of 0.10 to 0.90.

    [0113] Where the average fluorine intensity of the layer B is 1, the average fluorine intensity of the layer C is more preferably 0.30 to 0.80, further preferably 0.50 to 0.70. When where the average fluorine intensity of the layer B is 1, the average fluorine intensity of the layer C is 0.90 or less, more preferably 0.80 or less, further preferably 0.70 or less, generated water removal performance is easily remarkably improved, and fuel cell performance is easily improved. When the ratio of the average fluorine intensity of the layer C to the average fluorine intensity of the layer B is 0.10 or more, more preferably 0.30 or more, further preferably 0.50 or more, the layer C has hydrophobicity above a certain level, so that generated water is hardly accumulated in the layer C, leading to suppression of flooding.

    [0114] Where the average fluorine intensity of the layer A is 1, the average fluorine intensity of the layer B is more preferably 1.40 to 8.00, further preferably 1.50 to 7.00. When the ratio of the average fluorine intensity of the layer B to the average fluorine intensity of the layer A is 1.30 or more, more preferably 1.40 or more, further preferably 1.50 or more, generated water is easily discharged from the layer A to the layer B. When where the average fluorine intensity of the layer B is 1, the average fluorine intensity of the layer A is 9.00 or less, more preferably 8.00 or less, further preferably 7.00 or less, the layer B has hydrophobicity above a certain level, so that generated water is hardly accumulated in a portion that is in contact with a bipolar plate rib portion of the layer B, leading to suppression of flooding.

    [0115] The carbon sheet of the present invention in which the average fluorine intensity of the layer decreases in the order of the layer A, the layer B and the layer C is obtained by controlling in a through-plane direction the fiber diameter of the carbon fiber constituting the carbon sheet, the density and the distribution of the binding material, but it is more preferred to control the distribution of the binding material.

    [0116] The fluorine intensity of the carbon sheet can be measured using a scanning electron microscope (SEM)-energy dispersive X-ray analyzer (EDX). If a carbon sheet subjected to a hydrophobic treatment is not available, the fluorine intensity can be determined using a sample for observation of a thickness-direction cross-section of a carbon sheet in a gas diffusion electrode substrate or a carbon sheet in a membrane electrode assembly.

    [0117] When a fuel cell is operated at a relatively low temperature of below 70°C in a high-current-density region, as a result of blockage of the gas diffusion electrode substrate by liquid water generated in a large amount and shortage in the gas supply, the fuel cell performance is impaired. This problem is so called flooding, which should be suppressed.

    [0118] In the first embodiment or the second embodiment of the carbon sheet of the present invention, it is preferred that where the sum of volumes of pores having a diameter in the range of 1 to 100 µm is 100%, the sum of volumes of pores having a diameter in the range of 50 to 100 µm be 17 to 50%, and the porosity ((ρt-ρb)/ρt) calculated from the bulk density (ρb) and the true density (ρt) be 75 to 87%. In the first embodiment or the second embodiment of the carbon sheet of the present invention, the diameter of a pore having the largest volume (peak diameter) in the pore diameter range of 1 to 100 µm is more preferably within the range of 30 to 50 µm. The sum of volumes of pores having a diameter in the range of 50 to 100 µm where the sum of volumes of pores having a diameter in the range of 1 to 100 µm is 100% may be hereinafter described as a volume ratio of pores with a diameter of 50 to 100 µm. The preferred range of the volume ratio of pores with a diameter of 50 to 100 µm, the porosity and the peak diameter in the first embodiment and the second embodiment of the carbon sheet of the present invention are the same as the preferred ranges described below in the third embodiment.

    [0119] A third embodiment of the carbon sheet of the present invention is a porous carbon sheet including a carbon fiber and a binding material, wherein when the sum of volumes of pores having a pore diameter in the range of 1 to 100 µm is 100%, the sum of volumes of pores having a pore diameter in the range of 50 to 100 µm is 17 to 50%, and the porosity ((ρt-ρb)/ρt) calculated from the bulk density (ρb) and the true density (ρt) is 75 to 87%. The volume ratio of pores with a diameter of 50 to 100 µm is preferably 25 to 35%. The porosity ((ρtb)/ρt) is preferably 77 to 85%.

    [0120] Pores having a diameter in the range of 50 to 100 µm has an important role in control of water and water vapor during electrical power generation. The volume ratio of pores with a diameter of 50 to 100 µm is also associated with uniformity of the carbon sheet with respect to formation unevenness or the like. When the volume ratio of pores with a diameter of 50 to 100 µm in the carbon sheet is 17% or more, water removal performance is improved, so that flooding can be suppressed. When the volume ratio of pores with a diameter of 50 to 100 µm in the carbon sheet is 50% or less, water vapor diffusivity is small, so that dry-out can be suppressed, and a carbon sheet formed by papermaking or the like can be made free from formation unevenness or the like, and uniformly prepared, so that mechanical properties such as tensile property can be improved.

    [0121] Further, when the porosity of the carbon sheet is 75% or more, water removal performance is improved, so that flooding can be suppressed. In addition, the carbon sheet can be made flexible, and is therefore easily processed without causing such a failure that the carbon sheet is broken or creased during process passage. A process using a roll having a small diameter can be employed, and space saving and cost reduction of a processing machine are also facilitated. When the porosity of the carbon sheet is 87% or less, dry-out can be suppressed. In addition, since a carbon sheet formed by papermaking or the like can be made free from formation unevenness or the like, and uniformly prepared, mechanical strength such as tensile strength can be improved. Accordingly, sheet breakage does not occur during process passage, and thus stable processing is facilitated.

    [0122]  When the volume ratio of pores with a diameter of 50 to 100 µm in the carbon sheet is 17 to 50%, and the porosity of the carbon sheet is 75 to 87%, flooding and dry-out can be suppressed to improve fuel cell performance at a low temperature and a high temperature, and in addition, stable process passage property can be achieved.

    [0123] In the third embodiment of the carbon sheet of the present invention, the diameter of a pore having the largest volume (peak diameter) in the pore diameter range of 1 to 100 µm is preferably within the range of 30 to 50 µm, more preferably within 35 to 45 µm. When the peak diameter of the carbon sheet is in the range of 30 to 50 µm, flooding and dry-out can be more effectively suppressed.

    [0124] A carbon sheet having a peak diameter in the range of 30 to 50 µm can be obtained by controlling the areal weight and thickness of the carbon sheet, the loading amount of the binding material based on the amount of the carbon fiber, and the covering rate on each of both surfaces of the carbon sheet.

    [0125] Here, the pore diameter distribution (distribution showing diameters of pores versus volumes of pores) of the carbon sheet is obtained using a mercury penetration method. Three specimens of about 12 mm × 20 mm square are cut out from the carbon sheet, precisely weighed, and then put in a measuring cell so as not to overlap one another, and mercury is injected into the cell under reduced pressure. A measurement is made under the conditions shown below.
    • Measurement pressure range: 6 kPa (pressure at the start of measurement) (pore diameter: 400 µm) to 414 MPa (pressure at the end of measurement) (pore diameter: 30 nm)
    • Measurement cell mode: pressure raising process in the above pressure range
    • Cell volume: 5 cm3
    • Surface tension of mercury: 485 dyn/cm
    • Contact angle of mercury: 130°


    [0126] As the measurement apparatus, AutoPore 9520 manufactured by Shimadzu Corporation or its equivalent product can be used. The sum of volumes of pores having a diameter in the range of 1 to 100 µm and the sum of volumes of pores having a diameter in the range of 50 to 100 µm is determined, and the volume ratio of pores with a diameter of 50 to 100 µm is calculated.

    [0127] The diameter of a pore having the largest volume (peak diameter) in the pore diameter range of 1 to 100 µm is also determined from the pore diameter distribution.

    [0128] The porosity is calculated from a bulk density ρb (g/cm3) and a true density ρt (g/cm3) which are measured by the following methods, respectively. The bulk density ρb is calculated in accordance with the following equation from a thickness tb (cm) of a carbon sheet which is determined using a micrometer in a state of being compressed at a pressure of 0.15 MPa, and a mass Mb (g/100 cm2) which is measured with the carbon sheet cut to a square of 10 cm × 10 cm.



    [0129] Next, the true density ρt is calculated in accordance with the following equation from a true volume Vt (cm3) measured by a pycnometer method, and a mass Mt (g) of the sample used in the measurement.



    [0130] As an apparatus for measurement of the true volume Vt (cm3), a pycnometer: MicroUltrapyc 1200e manufactured by Quantachrome Company, or its equivalent product can be used. In the measurement, the sample is filled into a cell in such a manner that the ratio of the true volume Vt to the cell volume is 10% or more.

    [0131] The bulk density ρb of the carbon sheet is preferably within the range of 0.2 to 0.4 g/m3, more preferably within the range of 0.22 to 0.35 g/m3. When the bulk density ρb is 0.2 g/cm3 or more, water vapor diffusivity decreases, so that dry-out can be suppressed. The mechanical properties of the carbon sheet are improved, so that the electrolyte membrane and the catalyst layer can be sufficiently supported. In addition, high electrical conductivity is attained, and fuel cell performance is thus improved at both high and low temperatures. Meanwhile, when the bulk density ρb is 0.4 g/cm3 or less, water removal performance is improved, so that flooding can be suppressed.

    [0132] It is also possible to separate the carbon sheet from the gas diffusion electrode substrate, and measure the surface layer area ratio, the covering rate, the volume ratio of pores with a diameter of 50 to 100 µm, the porosity and the peak diameter for the carbon sheet. For example, a gas diffusion electrode substrate is heated in the atmosphere at 600°C for 30 minutes, a resin composition contained in the microporous layer in the gas diffusion electrode substrate is oxidatively decomposed, then ultrasonic treatment is carried out in a solvent such as ethanol, whereby it is possible to remove the residue of the microporous layer and take out the carbon sheet.

    [Gas Diffusion Electrode Substrate]



    [0133] The gas diffusion electrode substrate of the present invention will now be described.

    [0134]  The gas diffusion electrode substrate of the present invention can be prepared by forming the below-described microporous layer on the carbon sheet.

    <Formation of Microporous Layer>



    [0135] A microporous layer as one of the constituent elements in the present invention will now be described.

    [0136] The carbon sheet of the present invention can be used as a gas diffusion electrode substrate by forming the microporous layer on one surface of the carbon sheet. When the first embodiment or the second embodiment of the carbon sheet is used, the gas diffusion electrode substrate of the present invention has the microporous layer on the surface X1 or the surface X2 of the carbon sheet. When the third embodiment of the carbon sheet is used, the microporous layer may be formed on either surface of the carbon sheet, but in the case of using a carbon sheet prepared by a method in which one surface is made to have pores smaller than the pores of the other surface, it is desirable to form the microporous layer on a surface having smaller pores.

    [0137] The microporous layer can be formed by performing coating once, but the microporous layer can also be formed by performing coating multiple times. Accordingly, defects on the surface can be considerably reduced, so that durability can be improved.

    [0138] The areal weight of the microporous layer is preferably within the range of 10 to 35 g/m2, more preferably 30 g/m2 or less, further preferably 25 g/m2 or less. The areal weight of the microporous layer is preferably 14 g/m2 or more, more preferably 16 g/m2 or more.

    [0139] When the areal weight of the microporous layer is 10 g/m2 or more, one surface of the carbon sheet can be covered with the microporous layer, and back-diffusion of generated water is further promoted, so that dry-out of the electrolyte membrane can be further suppressed. When the areal weight of the microporous layer is 35 g/m2 or less, water removal performance is further improved, so that flooding can be further suppressed.

    [0140] In the present invention, it is preferred that the microporous layer contain a filler. As the filler, a carbon powder is preferred. Examples of the carbon powder include carbon blacks such as furnace black, acetylene black, lamp black and thermal black, graphites such as scaly graphite, scale-like graphite, earthy graphite, artificial graphite, expanded graphite and flaky graphite, carbon nanotubes, carbon nanofibers and milled fibers of carbon fiber. Among them, for the carbon powder, a carbon black is more preferably used, and acetylene black is most preferably used because the content of impurities is low.

    [0141] In the present invention, a porous material containing linear carbon and a hydrophobic material can also be used in the microporous layer from the viewpoint of improving electrical conductivity and water removal performance.

    [0142] In the present invention, the microporous layer contains a carbon powder, the carbon powder is that of linear carbon, and the aspect ratio of the linear carbon is 30 to 5000, whereby penetration of a filler-containing coating solution as a precursor of the microporous layer into the carbon sheet can be properly suppressed to improve gas diffusivity and water removal performance in an in-plane direction, so that flooding can be suppressed, and further, a microporous layer having a sufficient thickness is formed on a surface of the carbon sheet to back-diffusion of generated water is promoted, so that dry-out can be suppressed.

    [0143] In the present invention, it is preferred that the microporous layer contain water removal material from the viewpoint of promoting removal of water. In particular, a fluorine-based polymer is preferably used as the hydrophobic material because of its excellent corrosion resistance. The fluorine-based polymer includes polytetrafluoroethylene (PTFE), tetrafluoroethylene-hexa fluoro propylene copolymers (FEP), tetrafluoroethylene-perfluoroalkylvinyl ether copolymers (PFA), and the like.

    [0144] The filler-containing coating solution may contain a dispersion medium such as water or an organic solvent, and may contain a dispersant such as a surfactant. The dispersion medium is preferably water, and a nonionic surfactant is preferably used as the dispersant. The filler-containing coating solution may contain a filler such as a variety of carbon powders and a hydrophobic material as described above.

    [0145] The microporous layer can be formed by coating one surface of the carbon sheet with the filler-containing coating solution containing the filler.

    [0146] Coating of the carbon sheet with the filler-containing coating solution can be performed using a variety of commercially available coating apparatuses. As a coating system, a coating system such as screen printing, rotary screen printing, spraying, intaglio printing, gravure printing, die coating, bar coating or blade coating can be employed. The coating methods exemplified above are presented for the illustration purpose only, and the coating method is not necessarily restricted thereto.

    [0147] It is preferred to dry the coating solution at a temperature of 80 to 180°C after coating the carbon sheet with the filler-containing coating solution. That is, the coated matter is placed in a dryer whose temperature is set at 80 to 180°C and dried in the range of 5 to 30 minutes. The drying air volume may be appropriately decided, but rapid drying may induce micro cracks in the surface. It is preferred that after the coated matter is dried, the coated matter be placed in a muffle furnace, a baking furnace or a high-temperature drying furnace, and heated at preferably at a temperature of 300 to 380°C for 5 to 20 minutes to melt the hydrophobic material, so that fillers such as carbon powders are bonded together into a binder to form the microporous layer.

    [Membrane Electrode Assembly]



    [0148] In the present invention, a membrane electrode assembly can be formed by binding the above-described gas diffusion electrode substrate on at least one surface of a solid polymer electrolyte membrane having a catalyst layer on both surfaces. At this time, when the microporous layer of the gas diffusion electrode substrate is arranged on the catalyst layer side, back-diffusion of the generated water is more likely to occur, and also the contact area between the catalyst layer and the gas diffusion electrode substrate is increased, so that the contact electrical resistance can be reduced.

    [Fuel Cell]



    [0149] The fuel cell of the present invention is a fuel cell including the gas diffusion electrode substrate of the present invention, i.e. a fuel cell having bipolar plates on both sides of the membrane electrode assembly described above. That is, the fuel cell is constituted by arranging bipolar plates on both sides of the membrane electrode assembly described above. Usually, a polymer electrolyte fuel cell is constituted by laminating a plurality of such membrane electrode assemblies that are sandwiched by bipolar plates from both sides via a gasket. The catalyst layer is composed of a layer containing a solid polymer electrolyte and a carbon material of carbon-supported catalyst. As the catalyst, platinum is usually used. In a fuel cell in which a carbon monoxide-containing reformed gas is supplied to the anode side, it is preferred to use platinum and ruthenium as catalysts of the anode side. As the solid polymer electrolyte, it is preferred to use a perfluorosulfonic acid-based polymer material having high protonic conductivity, oxidation resistance, and heat resistance. The constitutions themselves of the above-mentioned fuel cell unit and fuel cell are well known.

    EXAMPLES



    [0150] The carbon sheet and the gas diffusion electrode substrate of the present invention will now be described in detail by ways of examples. The materials, and the methods for producing a carbon sheet and a gas diffusion electrode substrate, and the battery performance evaluation method of fuel cell that are used in the examples are described below.

    <Preparation of Carbon Sheet>


    • Preparation of 220 µm-thick carbon sheet



    [0151] Polyacrylonitrile-based carbon fiber "TORAYCA" (registered trademark) T300 (average carbon fiber diameter: 7 µm) manufactured by Toray Industries, Inc. was cut at a mean length of 12 mm and dispersed in water to continuously make a paper by a wet papermaking method. Further, a 10% by mass aqueous solution of polyvinyl alcohol as a binder was coated on the paper and then dried to prepare a papermaking substrate having a carbon fiber areal weight of 44.0 g/m2. The loading amount of the polyvinyl alcohol was 22 parts by mass with respect to 100 parts by mass of the carbon fiber papermaking substrate.

    [0152] Next, using a resin composition obtained by mixing a resol type phenolic resin and a novolak type phenolic resin at a 1 : 1 mass ratio as a thermosetting resin, scaly graphite (mean particle size 5 µm) as a carbon powder and methanol as a solvent, the materials were mixed at a ratio of thermosetting resin/carbon powder/solvent = 10 parts by mass/5 parts by mass/85 parts by mass, and the resulting mixture was stirred for 1 minute using an ultrasonic dispersion apparatus to obtain a uniformly dispersed resin composition impregnation liquid.

    [0153] Next, the papermaking substrate was cut into a size of 15 cm × 12.5 cm and dipped into the resin composition filled in an aluminum tray, and was then sandwiched between two horizontally arranged rolls, and squeezed. Here, the loading amount of the resin composition based on the amount of the carbon fiber papermaking substrate was adjusted by changing the clearance between the two horizontally arranged rolls. One of the two rolls was a smooth metallic roll having a structure allowing an excess resin to be removed by a doctor blade, and as the other roll, a roll provided with irregularities and called a gravure roll in terms of a configuration was used. The carbon fiber papermaking substrate was sandwiched by the metallic roll on the one surface side and the gravure roll on the other surface side, and the resin composition impregnation liquid was squeezed to provide a difference in loading amount of the resin component between the one surface side and the other surface side of the carbon fiber papermaking substrate. The carbon fiber papermaking substrate was impregnated with the resin composition, and then heated and dried at a temperature of 100°C for 5 minutes to prepare a prepreg. Next, the prepreg was annealed at a temperature of 180°C for 5 minutes while being pressed by a pressing machine with flat plates. In pressing of the prepreg, the space between the upper and lower press plates was adjusted by arranging a spacer in the pressing machine with flat plates.

    [0154] A substrate obtained by annealing the prepreg was introduced into a heating furnace having the highest temperature of 2400°C, in which a nitrogen gas atmosphere was maintained, to obtain a 220 µm-thick carbon sheet composed of a baked carbon fiber.

    • Preparation of 150 µm-thick carbon sheet



    [0155] A 150 µm-thick carbon sheet was prepared in accordance with the method described in the above-mentioned method for preparation of the 220 µm-thick carbon sheet, except that the areal weight of the carbon fiber was 30.0 g/m2, and the space between the upper and lower press plates was adjusted in annealing by the pressing machine with flat plates.

    • Preparation of 100 µm-thick carbon sheet



    [0156] A 100 µm-thick carbon sheet was prepared in accordance with the method described in the above-mentioned method for preparation of the 220 µm-thick carbon sheet, except that the areal weight of the carbon fiber was 22.0 g/m2, and the space between the upper and lower press plates was adjusted in annealing by the pressing machine with flat plates.

    <Hydrophobic Treatment>



    [0157] The carbon sheet prepared as described above was dipped into a water dispersion liquid of PTFE resin ("POLYFLON" (registered trademark) PTFE Dispersion D-1E (manufactured by DAIKIN INDUSTRIES, Ltd.)) or a water dispersion liquid of FEP resin ("NEOFLON" (registered trademark) FEP Dispersion ND-110 (manufactured by DAIKIN INDUSTRIES, Ltd.)) as a hydrophobic material to impregnate the baked carbon fiber with the hydrophobic material. Thereafter, the carbon sheet was heated and dried in a drying furnace at a temperature of 100°C for 5 minutes to prepare a carbon sheet subjected to a hydrophobic treatment. In the drying, the carbon sheet was vertically arranged, and the vertical direction was changed every 1 minute. The water dispersion liquid of the hydrophobic material was diluted to an appropriate concentration so as to add 5 parts by mass of the hydrophobic material to the 95 parts by mass of the carbon sheet in terms of an amount after drying.

    <Preparation of Gas Diffusion Electrode Substrate>


    [Materials]



    [0158] 
    • Carbon powder A: acetylene black "DENKA BLACK" (registered trademark) manufactured by Denka Company Limited)
    • Carbon powder B: linear carbon: vapor phase growth carbon fiber "VGCF" (registered trademark) (manufactured by SHOWA DENKO K.K.), aspect ratio: 70
    • Material C: hydrophobic material: PTFE resin ("POLYFLON" (registered trademark) PTFE Dispersion D-1E (manufactured by DAIKIN INDUSTRIES, Ltd.)) that is a water dispersion liquid containing 60 parts by mass of PTFE resin
    • Material D: surfactant "TRITON" (registered trademark) X-100 (manufactured by Nacalai Tesque)


    [0159] A filler-containing coating solution was prepared by mixing the above-mentioned materials using a disperser. One surface of the carbon sheet subjected to a hydrophobic treatment was coated with the filler-containing coating solution in a planar form using a slit die coater, and heating was then performed at a temperature of 120°C for 10 minutes, and then at a temperature of 380°C for 10 minutes. In this way, a microporous layer was formed on the carbon sheet subjected to a hydrophobic treatment, so that a gas diffusion electrode substrate was prepared. The filler-containing coating solutions used here are filler-containing coating solutions prepared using a carbon powder, a hydrophobic material, a surfactant and purified water and adjusted so as to have compositions of the filler-containing coating solutions with the addition amounts described in terms of parts by mass as shown in the tables. The addition amounts of the material C (PTFE resin) shown in the tables represent the addition amount of PTFE resin itself rather than the addition amounts of the water dispersion liquid of PTFE resin.

    <Evaluation of Fuel Cell Performance of Polymer Electrolyte Fuel Cell>



    [0160] A catalyst paste was prepared by sequentially adding 1.00 g of a carbon material of carbon-supported platinum catalyst (manufactured by Tanaka Kikinzoku Kogyo K.K., platinum supporting amount: 50% by mass), 1.00 g of purified water, 8.00 g of "Nafion" (registered trademark) solution (manufactured by Aldrich, "Nafion" (registered trademark), 5.0% by mass) and 18.00 g of isopropyl alcohol (manufactured by Nacalai Tesque) .

    [0161] Then, a "NAFLON" (registered trademark) PTFE tape "TOMBO" (registered trademark) No. 9001 (manufactured by NICHIAS Corporation) which was cut into a size of 5 cm × 5 cm was coated with the obtained catalyst paste using a spray and dried at ordinary temperature to prepare a PTFE sheet equipped with a catalyst layer having a platinum amount of 0.3 mg/cm2. Subsequently, a solid polymer electrolyte membrane, "Nafion" (registered trademark) NRE-211CS (manufactured by DuPont) which was cut into a size of 8 cm × 8 cm was sandwiched with two catalyst layer-equipped PTFE sheets. The resultant was pressed at a temperature of 130°C for 5 minutes while pressurizing at 5 MPa using a pressing machine with flat plates, thereby transferring the respective catalyst layers onto the solid polymer electrolyte membrane. After pressing, the PTFE sheets were removed to prepare a catalyst layer-equipped solid polymer electrolyte membrane.

    [0162] Next, the obtained catalyst layer-equipped solid polymer electrolyte membrane was sandwiched with two gas diffusion electrode substrates cut into a size of 5 cm × 5 cm, and the resultant was pressed at a temperature of 130°C for 5 minutes while pressurizing at 3 MPa using a pressing machine with flat plates, thereby preparing a membrane electrode assembly. It is noted here that the gas diffusion electrode substrate was arranged such that the surface having the microporous layer was in contact with the catalyst layer.

    [0163] The obtained membrane electrode assembly was incorporated into a fuel cell evaluation unit cell to measure the voltage when the current density was changed. Here, as a bipolar plate, a serpentine-type bipolar plate having one flow channel of 1.0 mm in each of channel width, channel depth and rib width was used. Further, the evaluation was carried out with non-pressurized hydrogen and non-pressurized air being supplied to the anode side and the cathode side, respectively.

    [0164] For examining the anti-flooding characteristic, hydrogen and air were humidified using a humidification pot whose temperature was set at 40°C. The humidity at this time was 100%. The utilization ratios of hydrogen and atmospheric oxygen were set at 70 mol% and 40 mol%, respectively. The output voltage at a current density of 1.5 A/cm2 was measured, and used as an index of the anti-flooding characteristic. Next, for examining the anti-dry-out characteristic, hydrogen and air were humidified using a humidification pot whose temperature was set at 80°C. The humidity at this time was 42%. The utilization ratios of hydrogen and atmospheric oxygen were set at 80 mol% and 67 mol%, respectively, and the output voltage at a current density of 1.5 A/cm2 was measured, and used as an index of the anti-dry-out characteristic.

    <Measurement of Areal Weight>



    [0165] The areal weights of the carbon sheet and the gas diffusion electrode substrate were determined by the mass of a sample cut into a 10 cm-square by the area (0.01 m2) of the sample.

    <Measurement of Thickness>



    [0166] A carbon sheet and a gas diffusion electrode substrate were placed on a smooth surface plate, and a difference in height between the case of presence of a measurement object and the case of absence of the measurement object was measured in a state in which a pressure of 0.15 MPa was applied. Samples were taken at 10 different parts, measured values of the difference in height were averaged, and the average thus obtained was defined as a thickness.

    <Measurement of Mean Diameter in Monofilaments in Carbon Fiber>



    [0167] The mean diameter (carbon fiber diameter) of monofilaments in the carbon fiber is an average value determined by taking a photograph of the carbon fiber on one surface of the carbon sheet at a magnification of 1000 times, under a microscope such as a scanning electron microscope, randomly selecting 30 different monofilaments, and measuring their diameters. The mean diameter of monofilaments in the carbon fiber on the other surface of the carbon sheet is determined in the same manner as described above. As the scanning electron microscope, S-4800 manufactured by Hitachi, Ltd. or its equivalent product can be used. The mean diameters determined from the surface X1 or the surface X2 and the surface Y1 or the surface Y2 are shown in the tables.

    [0168] Here, the "carbon fiber diameter (surface X1/surface Y1) " in the tables show the mean diameter of monofilaments in the carbon fiber which is determined from the surface X1 side and the mean diameter of monofilaments in the carbon fiber which is determined from the surface Y1 side.

    <Measurement of Melting Point of Hydrophobic Material>



    [0169] In the present invention, the melting point of the hydrophobic material was measured by differential scanning calorimetry. Using DSC6220 manufactured by Seiko Instruments Inc. (SII) as the apparatus, the temperature was changed from 30°C to 400°C at a heating rate of 2°C/min in nitrogen. The endothermic and exothermic peaks at that time were observed, and the endothermic peak at a temperature of 150°C or more was defined as the melting point of the hydrophobic material.

    <Measurement of Surface Roughness>



    [0170] The surface roughness of the carbon sheet was measured using a laser microscope. The measurement was performed by scanning a 5 mm square range with an objective lens with a magnification of 10, using VK-X100 (manufactured by KEYENCE CORPORATION) as a measuring apparatus, and the arithmetic average roughness (Ra) in the 5 mm square was obtained. 10 measurement points were selected, and the average of arithmetic average roughnesses was defined as a surface roughness. Here, the result obtained by making a measurement from the surface X1 side of the carbon sheet was defined as a surface roughness of the surface X1, and the result obtained by making a measurement from the surface Y1 side of the carbon sheet was defined as a surface roughness of the surface Y1.

    <Measurement of Sliding Angle>



    [0171] The sliding angle of the carbon sheet was determined by a sliding method using an automated contact angle meter. As the apparatus, an automated contact angle meter DM-501 manufactured by Kyowa Interface Science Co., Ltd. was used. The carbon sheet subjected to a hydrophobic treatment was fixed on an apparatus stage with the surface Y set on the upper side (measurement side), 10 µL of a droplet of ion-exchanged water was added to the carbon sheet, the carbon sheet subjected to a hydrophobic treatment was left standing for 1 second, and then inclined together with the apparatus stage, and the inclination angle at the time when the droplet started to slide down along the surface of the carbon sheet subjected to a hydrophobic treatment.

    <Measurement of Fluorine Intensity>



    [0172] The fluorine intensity of the carbon sheet was determined in the following manner. This will be described below with reference to Fig. 3. First, one surface and the other surface of a carbon sheet (6) were provisionally defined as a surface X1 or surface X2(7) and a surface Y1 or surface Y2(8), respectively, and randomly 50 samples for observation of a through-plane-direction cross-section of the carbon sheet (6) were then prepared using a sharp-edged tool. Using a scanning electron microscope (SEM)-energy dispersive X-ray analyzer (EDX), the cross sections of the 50 samples of the carbon sheet (6) were line-scanned in the through-plane direction of the carbon sheet (6) to determine a distribution (18) of the fluorine intensity (signal intensity of fluorine). The fluorine intensity was measured under the conditions of an acceleration voltage of 7 kV, a magnification of 300 times and a line width of 20 µm. A value (20) of 50% of an average value (19) of fluorine intensities measured along a line in the through-plane direction of the carbon sheet (6), which extended from one surface to the other surface of the carbon sheet (6), was determined, and among layers obtained by dividing the carbon sheet (6) in the through-plane direction into three equal parts within a section (17) extending from a surface (surface AA(12)) having a 50% average fluorine intensity, which was closest to the provisionally defined surface X1 or surface X2(7), to a surface (surface BB(13)) having a 50% average fluorine intensity, which was closest to the provisionally defined surface Y1 or surface Y2(8), a layer including the surface AA(12) was provisionally defined as a layer A(14), a layer including the surface BB(13) was provisionally defined as a layer B(16), and a middle layer sandwiched between the layer A(14) and the layer B(16) was defined as a layer C(15).

    [0173] The average value of the fluorine intensity in the layer A of each of the 50 carbon sheets was calculated to obtain an "average value of fluorine intensity in layer A" for 50 carbon sheets. The average value of the obtained "average value of fluorine intensity in layer A" for 50 carbon sheets was defined as an average fluorine intensity of the layer A. For the layers B and C, the average fluorine intensity was calculated by the same method as described above. A layer having a larger average fluorine intensity and a layer having a smaller average fluorine intensity were defined as the layer A and the layer B, respectively, of the provisionally defined layers A and B, and a surface on the layer A side of the carbon sheet and a surface on the layer B side of the carbon sheet were defined as the surface X1 or surface X2 and the surface Y1 or surface Y2, respectively.

    [0174] If the fluorine intensity in the carbon sheet cannot be determined because a single carbon sheet is not available, the fluorine intensity can be determined by the above-mentioned method using a sample for observation of a thickness-direction cross-section of a carbon sheet in a gas diffusion electrode substrate or a carbon sheet in a membrane electrode assembly.

    [0175] Even when the hydrophobic treatment is performed in a discontinuous planar form, for example in the form of inside portions of a grid or in a dot form, the fluorine intensity can be determined by the above-mentioned method because in this method, the average is taken for randomly prepared 50 samples, and therefore the fluorine intensity is averaged including that of a discontinuous portion.

    [0176] As the scanning electron microscope, S-3500N manufactured by Hitachi, Ltd. was used, and as the energy dispersive X-ray analyzer, EX-370 manufactured by HORIBA, Ltd. was used.

    (Example 1)



    [0177] In accordance with the methods described in <Preparation of Carbon Sheet>, <Hydrophobic Treatment> and <Preparation of Gas Diffusion Electrode Substrate>, a gas diffusion electrode substrate including a 220 µm-thickness porous carbon sheet having different surface layer area ratios on both sides was obtained. As a result of evaluating the fuel cell performance of this gas diffusion electrode substrate, the output voltage was 0.4 V or more for the anti-flooding characteristic and 0.35 V or more for the anti-dry-out characteristic, and thus both the anti-flooding characteristic and the anti-dry-out characteristic were very good. The results are shown in Table 1.

    (Example 2)



    [0178] In accordance with the methods described in <Preparation of Carbon Sheet>, <Hydrophobic Treatment> and <Preparation of Gas Diffusion Electrode Substrate>, a gas diffusion electrode substrate including a 150 µm-thickness porous carbon sheet having different surface layer area ratios on both sides was obtained. As a result of evaluating the fuel cell performance of this gas diffusion electrode substrate, the output voltage was 0.4 V or more for the anti-flooding characteristic and 0.35 V or more for the anti-dry-out characteristic, and thus both the anti-flooding characteristic and the anti-dry-out characteristic were very good. The results are shown in Table 1.

    (Example 3)



    [0179] In accordance with the methods described in <Preparation of Carbon Sheet>, <Hydrophobic Treatment> and <Preparation of Gas Diffusion Electrode Substrate>, a gas diffusion electrode substrate including a 100 µm-thickness porous carbon sheet having different surface layer area ratios on both sides was obtained. As a result of evaluating the fuel cell performance of this gas diffusion electrode substrate, the output voltage was 0.4 V or more for the anti-flooding characteristic, and thus the anti-flooding characteristic was very good. For the anti-dry-out characteristic, the output voltage was less than 0.35 V, but a good result was shown with the output voltage being 0.3 V or more. The results are shown in Table 1.

    (Example 4)



    [0180] In accordance with the methods described in <Preparation of Carbon Sheet>, <Hydrophobic Treatment> and <Preparation of Gas Diffusion Electrode Substrate>, a gas diffusion electrode substrate including a 150 µm-thickness porous carbon sheet having different surface layer area ratios on both sides was obtained. Here, a doctor blade was attached to a roll which was in contact with the surface Y1 or surface Y2, so that a resin composition adhered to the surface Y1 or surface Y2 was reduced to remove a large amount of a binding material on the surface Y1 or surface Y2, whereby a difference in amount of bonded resin between the surface X1 or surface X2 and surface Y1 or surface Y2 was considerably changed as compared to Example 2. As a result of evaluating the fuel cell performance of this gas diffusion electrode substrate, the output voltage was 0.45 V or more for the anti-flooding characteristic and 0.35 V or more for the anti-dry-out characteristic, and thus both the anti-flooding characteristic and the anti-dry-out characteristic were very good. As described above, the anti-flooding characteristic and the anti-dry-out characteristic were considerably improved, and this may be because there was a large difference in surface layer area ratio, leading to improvement of water removal performance. The results are shown in Table 1.

    (Example 5)



    [0181] In accordance with the methods described in <Preparation of Carbon Sheet>, <Hydrophobic Treatment> and <Preparation of Gas Diffusion Electrode Substrate>, a gas diffusion electrode substrate including a 150 µm-thickness porous carbon sheet having different surface layer area ratios on both sides as shown in Table 1 was obtained. Here, the clearance between two rolls for sandwiching the carbon sheet was made larger as compared to Example 2, so that the amount of the binding material was larger on both the surface X and the surface Y as compared to Example 2. The output voltage was 0.4 V or more for the anti-flooding characteristic and 0.35 V or more for the anti-dry-out characteristic, and thus both the anti-flooding characteristic and the anti-dry-out characteristic were very good. The results are shown in Table 1.

    (Example 6)



    [0182] In accordance with the methods described in <Preparation of Carbon Sheet>, <Hydrophobic Treatment> and <Preparation of Gas Diffusion Electrode Substrate>, a gas diffusion electrode substrate was prepared in the same manner as in Example 4 except that the amount of the resin composition was made larger as compared to Example 4. A 150 µm-thickness porous carbon sheet having different surface layer area ratios on both sides was obtained, and further a gas diffusion electrode substrate was obtained. The anti-flooding characteristic was good with the output voltage being 0.35 V or more. The anti-dry-out characteristic was very good with the output voltage being 0.35 V or more. The results are shown in Table 1.

    (Example 7)



    [0183] In accordance with the methods described in <Preparation of Carbon Sheet>, <Hydrophobic Treatment> and <Preparation of Gas Diffusion Electrode Substrate>, a gas diffusion electrode substrate was prepared in the same manner as in Example 2 except that the hydrophobic material used for the hydrophobic treatment of the carbon sheet was changed to a tetrafluoroethylene-hexafluoropropylene copolymer (FEP). As a result, a 150 µm-thickness porous carbon sheet having different surface layer area ratios on both sides was obtained, and further a gas diffusion electrode substrate was obtained. The output voltage was 0.45 V or more for the anti-flooding characteristic and 0.35 V or more for the anti-dry-out characteristic, and thus both the anti-flooding characteristic and the anti-dry-out characteristic were very good. The carbon sheet was made uniformly hydrophobic by a hydrophobic treatment using FEP having a low melting point, and the sliding angle was 25 degrees, a value much smaller than 40 degrees. Thus, it was confirmed that hydrophobicity was considerably improved. Therefore, it was confirmed that the anti-flooding characteristic was considerably improved owing to a synergistic effect in improvement of water removal performance due to a difference in surface layer area ratio between both sides and improvement of hydrophobicity in the present invention. The results are shown in Table 1.

    (Example 8)



    [0184] A carbon sheet and a gas diffusion electrode substrate were obtained in the same manner as in Example 2 except that in the configuration shown in Table 2, the composition of a filler-containing coating solution for forming a microporous layer was different from that in Example 2. As a result of evaluating the fuel cell performance of this gas diffusion electrode substrate, the output voltage was much larger than 0.4 V or more for the anti-flooding characteristic and 0.35 V or more for the anti-dry-out characteristic, and thus both the anti-flooding characteristic and the anti-dry-out characteristic were very good. This may be because due to use of a filler having a high aspect ratio in the microporous layer, the microporous layer has a high porosity, leading to gas diffusivity. Therefore, it was confirmed that the anti-flooding characteristic was considerably improved owing to a synergistic effect of improvement of gas diffusivity due to enhancement of the porosity of the microporous layer and improvement of water removal performance in the present invention. The results are shown in Table 2.

    (Example 9)



    [0185] A long fiber of polyacrylonitrile was subjected to a flameproofing treatment at a temperature of 200°C for 10 minutes, a nonwoven fabric was prepared by a water flow entanglement treatment, and roll pressing was performed. The long fiber was introduced into a heating furnace at a temperature of 2000°C to obtain a carbon sheet composed of a baked carbon fiber of a 150 µm-thick nonwoven fabric. As a binding material also serving as a hydrophobic material, an impregnation liquid was prepared by dispersing the carbon powder A as a solid and the material C, i.e. PTFE resin, in water together with a dispersant in such a manner that the solid mass ratio of the carbon powder A and the material C was 1 : 1. The nonwoven fabric subjected to a flameproofing treatment was dipped into the impregnation liquid, and then sandwiched between two horizontally arranged rolls (one of the two rolls is a smooth metallic roll having a doctor blade, and the other roll is a gravure roll provided with irregularities) with a certain clearance provided therebetween, and was squeezed to impregnate the nonwoven fabric with the impregnation liquid, so that loading amounts on both sides were adjusted. Thereafter, heating was performed in a heating furnace at 380°C for 10 minutes. As a result, a hydrophobic-treated carbon sheet bonded by 5% by mass, in terms of a solid amount, of a binding material also serving as a hydrophobic material was obtained. In accordance with the method described in <Preparation of Gas Diffusion Electrode Substrate>, a gas diffusion electrode substrate was prepared in the same manner as in Example 2. A gas diffusion electrode substrate including a 150 µm-thickness porous carbon sheet having different surface layer area ratios on both sides as shown in Table 2 was obtained. The output voltage was 0.4 V or more for the anti-flooding characteristic and 0.35 V or more for the anti-dry-out characteristic, and thus both the anti-flooding characteristic and the anti-dry-out characteristic were very good. The results are shown in Table 2.

    (Comparative Example 1)



    [0186] In the methods described in <Preparation of Carbon Sheet>, <Hydrophobic Treatment> and <Preparation of Gas Diffusion Electrode Substrate>, a carbon fiber papermaking substrate impregnated with a resin composition was sandwiched between two rolls of the same shape from both surfaces to squeeze a liquid, so that a binding material was adhered to the carbon fiber papermaking substrate to perform a hydrophobic treatment. Otherwise in the same manner as in Example 2, a gas diffusion electrode substrate was prepared. As a result, the amounts of the binding material adhered to both surfaces were similar to each other, and therefore the difference in surface layer area ratio between both surfaces was 5% or less as shown in Table 2. A gas diffusion electrode substrate including a 150 µm-thickness porous carbon sheet. The output voltage was smaller than 0.35 V for the anti-flooding characteristic and much smaller than 0.3 V for the anti-dry-out characteristic, and thus both the anti-flooding characteristic and the anti-dry-out characteristic were insufficient. The results are shown in Table 2.

    (Comparative Example 2)



    [0187] In the methods described in <Preparation of Carbon Sheet>, <Hydrophobic Treatment> and <Preparation of Gas Diffusion Electrode Substrate>, a gas diffusion electrode substrate was prepared in the same manner as in Example 2 except that a resin composition was adhered to one surface by gravure coating in impregnation of the carbon fiber papermaking substrate with the resin composition. As a result, the difference in surface layer area ratio between both surfaces was 13% or more as shown in Table 2. A gas diffusion electrode substrate including a 150 µm-thickness porous carbon sheet. The output voltage was smaller than 0.35 V for the anti-flooding characteristic and much smaller than 0.3 V for the anti-dry-out characteristic, and thus both the anti-flooding characteristic and the anti-dry-out characteristic were insufficient. The results are shown in Table 2.

    (Comparative Example 3)



    [0188] In <Preparation of Carbon Sheet>, the same carbon fiber papermaking substrate as in Example 3 was impregnated with a resin composition by the same method as in Comparative Example 1 to prepare a prepreg. Meanwhile, a carbon fiber papermaking substrate was obtained by the same method as in Example 3 except that a carbon fiber having a mean diameter of 3 µm and a mean length of 2 mm was used, and the carbon fiber papermaking substrate was impregnated with a resin composition by the same method as in Comparative Example 1 to prepare a prepreg. These two prepregs were superimposed on each other, and heated and pressed to be laminated. Otherwise by the same method as in Example 3, a 250 µm-thickness porous carbon sheet was obtained, and further a gas diffusion electrode substrate was obtained. As a result of evaluating the fuel cell performance of this gas diffusion electrode substrate, the output voltage was much smaller than 0.35 V for the anti-flooding characteristic and much smaller than 0.3 V for the anti-dry-out characteristic, and thus both the anti-flooding characteristic and the anti-dry-out characteristic were insufficient. This is because a lamination system was employed, and therefore the carbon sheet was thickened, leading to insufficient gas diffusivity and water removal performance. The results are shown in Table 2.

    [0189] An attempt was made to prepare a gas diffusion electrode substrate using a thinner carbon sheet, but it was unable to stably prepare a gas diffusion electrode substrate due to insufficient strength of the carbon sheet.

    [Table 1]



    [0190] 
    [Table 1]
      Example 1Example 2Example 3Example 4Example 5Example 6Example 7
      Thickness [µm] 220 150 100 150 150 150 150
      Areal weight [g/m2] 69 45 35 46 48 51 46
      Mean diameter of carbon fiber (surface X1 side) [µm] 7.1 7.1 7.1 7.1 7.2 7.1 7.1
      Mean diameter of carbon fiber (surface Y1 side) [µm] 7.0 7.2 7.1 7.0 7.0 7.3 7.3
      Resin used for hydrophobic treatment PTFE PTFE PTFE PTFE PTFE PTFE FEP
      Surface layer area ratio X [%] 16.9 15.0 14.9 15.2 19.8 22.7 14.9
      Surface layer area ratio Y [%] 8.9 10.4 10.4 9.2 16.0 10.9 9.8
      Difference in surface layer area ratio (surface X1 - surface Y1) [%] 8.0 4.6 4.5 6.0 3.8 11.8 5.1
      Surface roughness (surface X1) [µm] 14.0 15.1 14.2 14.8 13.8 12.8 14.9
      Surface roughness (surface Y1) [µm] 16.3 17.8 17.6 18.6 14.0 17.4 17.9
    Carbon sheet Difference in surface roughness (surface Y1 - surface X1) [µm] 4.3 2.7 3.4 3.8 0.2 4.6 3.0
      Covering rate on surface X2 side [%] 81.2 78.2 78.0 78.5 85.9 90.5 78.0
      Covering rate on surface Y2 side [%] 66.5 70.9 70.9 68.9 79.8 71.6 69.9
      Difference in covering rate (surface X2 - surface Y2) [%] 12.8 7.3 7.2 9.6 6.1 18.9 8.1
      Volume ratio of pores with dimeter of 50 to 100 µm [%] 38 34 31 37 27 25 34
      Porosity [%] 81 80 76 79 81 81 82
      Peak diameter [µm] 43 41 39 43 39 36 40
      Ratio of fluorine intensity (layer A/layer B) 1.45 1.45 1.45 2.03 7.50 8.50 1.45
      Ratio of fluorine intensity (layer C/layer B) 0.40 0.40 0.40 0.60 0.75 0.85 0.40
      Sliding angle (surface Y1 or surface Y2) [degree] 65 64 67 63 64 65 25
      Melting point of hydrophobic material (DSC method) [degree] 331 329 330 331 330 329 309
    Composition of filler-containing coating solution for microporous layer Carbon powder A [parts by mass] 7.0 7.0 7.0 7.0 7.0 7.0 7.0
    Carbon powder B [parts by mass] - - - - - - -
    Material C [parts by mass] 2.5 2.5 2.5 2.5 2.5 2.5 2.5
    Material D [parts by mass] 14 14 14 14 14 14 14
    Purified water [parts by mass] 74.8 74.8 74.8 74.8 74.8 74.8 74.8
    Gas diffusion electrode substrate Areal weight [g/m2] 83 59 49 60 63 65 60
    Thickness [µm] 240 171 121 169 170 169 170
    Anti-flooding characteristic Output voltage [V] 0.40 0.43 0.44 0.45 0.41 0.35 0.46
    Anti-dry-out characteristic Output voltage [V] 0.36 0.35 0.34 0.35 0.36 0.36 0.35

    [Table 2]



    [0191] 
    [Table 2]
     Example 8Example 9Comparative Example 1Comparative Example 2Comparative Example 3
      Thickness [µm] 150 150 150 150 250
      Areal weight [g/m2] 46 46 47 47 80
      Mean diameter of carbon fiber (surface X1 side) [µm] 7.2 7.2 7.1 7.0 3.1
      Mean diameter of carbon fiber (surface Y1 side) [µm] 7.1 7.1 7.1 7.2 7.2
      Resin used for hydrophobic treatment PTFE PTFE PTFE PTFE PTFE
      Surface layer area ratio X [%] 15.0 15.0 12.6 21.8 31.0
      Surface layer area ratio Y [%] 10.2 10.4 12.4 8.1 9.7
      Difference in surface layer area ratio (surface X1 - surface Y1) [%] 4.8 4.6 0.2 13.7 21.3
      Surface roughness (surface X1) [µm] 14.8 15.2 16.2 12.8 11.0
      Surface roughness (surface Y1) [µm] 17.1 17.7 16.3 19.2 17.8
    Carbon sheet Difference in surface roughness (surface Y1 - surface X1) [µm] 2.3 2.5 0.1 6.4 6.8
      Covering rate on surface X2 side [%] 78.2 78.2 74.4 89.1 92.0
      Covering rate on surface Y2 side [%] 70.5 70.9 74.0 67.2 69.7
      Difference in covering rate (surface X2 - surface Y2) [%] 7.7 7.3 0.3 21.9 22.3
      Volume ratio of pores with diameter of 50 to 100 µm [%] 34 27 15 52 25
      Porosity [%] 80 81 81 80 73
      Peak diameter [µm] 41 34 40 47 38
      Ratio of fluorine intensity (layer A/layer B) 1.45 1.45 1.00 2.60 9.50
      Ratio of fluorine intensity (layer C/layer B) 0.40 0.85 0.66 1.40 0.39
      Sliding angle (surface Y1 or surface Y2) [degree] 64 65 63 68 66
      Melting point of hydrophobic material (DSC method) [degree] 329 331 328 330 328
    Composition of filler-containing coating solution for microporous layer Carbon powder A [parts by mass] 3.5 7.0 7.0 7.0 7.0
    Carbon powder B [parts by mass] 3.5 - - - -
    Material C [parts by mass] 2.5 2.5 2.5 2.5 2.5
    Material D [parts by mass] 14 14 14 14 14
    Purified water [parts by mass] 74.8 74.8 74.8 74.8 74.8
    Gas diffusion electrode substrate Areal weight [g/m2] 60 60 61 61 85
    Thickness [µm] 172 170 171 169 270
    Anti-flooding characteristic Output voltage [V] 0.46 0.42 0.31 0.33 0.25
    Anti-dry-out characteristic Output voltage [V] 0.37 0.35 0.23 0.22 0.27

    DESCRIPTION OF REFERENCE SIGNS



    [0192] 

    1: Depth-versus-area ratio profile

    2: Excluded area ratio

    3: Surface layer area ratio

    4: Total measured area ratio

    5: Depth at which cumulative area ratio reaches 2%

    6: Carbon sheet

    7: Surface X1 or surface X2

    8: Surface Y1 or surface Y2

    9: Depth at which cumulative area ratio reaches 2% (reference depth)

    10: Depth of part deeper than reference depth by 20 µm

    11: Layer having average fluorine intensity less than 50% average fluorine intensity

    12: Surface AA

    13: Surface BB

    14: Layer A

    15: Layer C

    16: Layer B

    17: Section

    18: Distribution of fluorine intensity

    19: Average value of fluorine intensity

    20: Value of 50% of average value of fluorine intensity




    Claims

    1. A porous carbon sheet comprising a carbon fiber and a binding material, wherein when in a measured surface depth distribution, the ratio of the area of a portion having a depth of 20 µm or less in the measured area of one surface is a surface layer area ratio X, and the ratio of the area of a portion having a depth of 20 µm or less in the measured area of the opposite surface is a surface layer area ratio Y, the surface layer area ratio X is larger than the surface layer area ratio Y, and a difference between the surface layer area ratios is 3% or more and 12% or less, wherein the porous carbon sheet is carbonized, wherein the binding material includes a carbonized material of a resin composition, and wherein the surface layer area ratio is measured as described in the description.
     
    2. The carbon sheet according to claim 1, wherein the surface layer area ratio X is 13% or more and 17% or less, and the surface layer area ratio Y is 9% or more and 13% or less.
     
    3. The carbon sheet according to claim 1 or 2, wherein when a surface having the surface layer area ratio X is a surface X1, and a surface having the surface layer area ratio Y is a surface Y1, the surface roughness of the surface X1 is smaller than the surface roughness of the surface Y1, and a difference between the surface roughnesses of the surfaces X1 and Y1 is 1 µm or more and 4 µm or less, the surface roughness of the carbon sheet is the arithmetic average surface roughness Ra which is measured according to the description using a laser microscope.
     
    4. The carbon sheet according to any one of claims 1 to 3, wherein when a surface having the surface layer area ratio X is a surface X1, the surface roughness of the surface X1 is 16 µm or less.
     
    5. A porous carbon sheet comprising a carbon fiber and a binding material, wherein the porous carbon sheet is carbonized and has two opposing surfaces, wherein when a surface having a larger covering rate on the surface by the carbon fiber and the binding material is a surface X2, and a surface having a smaller covering rate on the surface by the carbon fiber and the binding material is a surface Y2, a difference in the covering rate between the surface X2 and the surface Y2 is 5% or more and 20% or less, wherein the covering rate is determined as specified in the description by performing a numerical treatment of an image of a surface of the carbon sheet which is observed with a scanning electron microscope, and wherein the binding material is a carbonized material of a resin composition.
     
    6. The carbon sheet according to claim 5, wherein the covering rate on the surface X2 is 70% or more and 90% or less,
    and the covering rate on the surface Y2 is 50% or more and 75% or less.
     
    7. The carbon sheet according to any one of claims 1 to 6, wherein the carbon sheet includes a hydrophobic material, and where among layers obtained by dividing the carbon sheet in a through-plane direction thereof into three equal parts within a section (17) extending from a surface (12) having a 50% average fluorine intensity, which is closest to one surface (7), to a surface (13) having a 50% average fluorine intensity, which is closest to the other surface (8), one of a layer close to one surface (7) and a layer close to the other surface (8), which has a larger average fluorine intensity, is a layer A (14), the other one of a layer close to one surface (7) and a layer close to the other surface (8), which has a smaller average fluorine intensity, is a layer B (16), and a layer between the layer A (14) and the layer B (16) is a layer C (15), the average fluorine intensity of the layer decreases in the order of the layer A (14), the layer B (16) and the layer C (15), wherein the fluorine intensity is measured using a scanning electron microscope (SEM)-energy dispersive X-ray Analyzer (EDX).
     
    8. The carbon sheet according to claim 7, wherein the melting point of the hydrophobic material is 200°C or more and 320°C or less.
     
    9. The carbon sheet according to any one of claims 3 to 8, wherein the sliding angle of water at the surface Y1 or the surface Y2 is 40 degrees or less, the sliding angle being determined by a sliding method using an automated contact angle meter.
     
    10. The carbon sheet according to any one of claims 1 to 9, wherein when the sum of volumes of pores having a pore diameter in the range of 1 to 100 µm is 100%, the sum of volumes of pores having a pore diameter in the range of 50 to 100 µm is 17 to 50%, wherein the pore diameter and the volumes of pores are determined using a mercury penetration method, and
    the porosity ((ρt-ρb)/ρt) calculated from the bulk density (ρb) and the true density (ρt) is 75 to 87%.
     
    11. The carbon sheet according to claim 10, wherein the diameter of a pore having the largest volume (peak diameter) in the diameter range of 1 to 100 µm is within the range of 30 to 50 µm.
     
    12. A gas diffusion electrode substrate comprising the carbon sheet according to any one of claims 1 to 11 and a microporous layer, wherein when a surface having a surface layer area ratio X is a surface X1, the gas diffusion electrode substrate has a microporous layer on the surface X1 or surface X2 side of the carbon sheet according to any one of claims 1 to 11.
     
    13. A fuel cell comprising the gas diffusion electrode substrate according to claim 12.
     


    Ansprüche

    1. Poröse Kohlenstoffplatte, umfassend eine Kohlenstofffaser und ein Bindematerial, wobei, wenn in einer gemessenen Oberflächentiefenverteilung das Verhältnis der Fläche eines Teils mit einer Tiefe von 20 µm oder weniger in der gemessenen Fläche einer Oberfläche ein Oberflächenschichtflächenverhältnis X ist und das Verhältnis der Fläche eines Teils mit einer Tiefe von 20 µm oder weniger in der gemessenen Fläche der gegenüberliegenden Oberfläche ein Oberflächenschichtflächenverhältnis Y ist, das Oberflächenschichtflächenverhältnis X größer als das Oberflächenschichtflächenverhältnis Y ist und eine Differenz zwischen den Oberflächenschichtflächenverhältnissen 3 % oder mehr und 12 % oder weniger beträgt, wobei die poröse Kohlenstoffplatte karbonisiert ist, wobei das Bindematerial ein karbonisiertes Material einer Harzzusammensetzung umfasst und wobei das Oberflächenschichtflächenverhältnis wie in der Beschreibung beschrieben gemessen wird.
     
    2. Kohlenstoffplatte nach Anspruch 1, wobei das Oberflächenschichtflächenverhältnis X 13 % oder mehr und 17 % oder weniger beträgt, und wobei das Oberflächenschichtflächenverhältnis Y 9 % oder mehr und 13 % oder weniger beträgt.
     
    3. Kohlenstoffplatte nach Anspruch 1 oder 2, wobei, wenn eine Oberfläche mit dem Oberflächenschichtflächenverhältnis X eine Oberfläche X1 und eine Oberfläche mit dem Oberflächenschichtflächenverhältnis Y eine Oberfläche Y1 ist, die Oberflächenrauhigkeit der Oberfläche X1 kleiner als die Oberflächenrauhigkeit der Oberfläche Y1 ist, und eine Differenz zwischen den Oberflächenrauhigkeiten der Oberfläche X1 und Y1 1 µm oder mehr und 4 µm oder weniger beträgt, wobei die Oberflächenrauhigkeit der Kohlenstoffplatte das arithmetische Mittel der Oberflächenrauhigkeit Ra ist, die entsprechend der Beschreibung unter Verwendung eines Lasermikroskops gemessen wird.
     
    4. Kohlenstoffplatte nach einem der Ansprüche 1 bis 3, wobei, wenn eine Oberfläche mit dem Oberflächenschichtflächenverhältnis X eine Oberfläche X1 ist, die Oberflächenrauhigkeit der Oberfläche X1 16 µm oder weniger beträgt.
     
    5. Poröses Kohlenstoffplatte, umfassend eine Kohlenstofffaser und ein Bindematerial, wobei die poröse Kohlenstoffplatte karbonisiert ist und zwei gegenüberliegende Oberflächen aufweist, wobei, wenn eine Oberfläche mit einer größeren Bedeckungsrate auf der Oberfläche durch die Kohlenstofffaser und das Bindematerial eine Oberfläche X2 ist und eine Oberfläche mit einer kleineren Bedeckungsrate auf der Oberfläche durch die Kohlenstofffaser und das Bindematerial eine Oberfläche Y2 ist, eine Differenz in der Bedeckungsrate zwischen der Oberfläche X2 und der Oberfläche Y2 5 % oder mehr und 20 % oder weniger beträgt, wobei die Bedeckungsrate wie in der Beschreibung angegeben bestimmt wird, indem eine numerische Behandlung von einem Bild einer Oberfläche der Kohlenstoffplatte durchgeführt wird, die mit einem Rasterelektronenmikroskop betrachtet wird, und wobei das Bindematerial ein karbonisiertes Material einer Harzzusammensetzung ist.
     
    6. Kohlenstoffplatte nach Anspruch 5, wobei die Bedeckungsrate auf der Oberfläche X2 70 % oder mehr und 90 % oder weniger beträgt und die Bedeckungsrate auf der Oberfläche Y2 50 % oder mehr und 75 % oder weniger beträgt.
     
    7. Kohlenstoffplatte nach einem der Ansprüche 1 bis 6, wobei die Kohlenstoffplatte ein hydrophobes Material umfasst und wobei unter den Schichten, die durch Teilen der Kohlenstoffplatte in einer Durchgangsebenenrichtung in drei gleiche Teile innerhalb eines Abschnitts (17) erhalten werden, der sich von einer Oberfläche (12) mit einer 50-%igen durchschnittlichen Fluorintensität, die am nächsten zu einer Oberfläche (7) liegt, zu einer Oberfläche (13) mit einer 50-%igen durchschnittlichen Fluorintensität, die am nächsten zu einer anderen Oberfläche (8) liegt, eine von einer Schicht nahe zu einer Oberfläche (7) und einer Schicht nahe zu der anderen Oberfläche (8), die eine größere durchschnittliche Fluorintensität aufweist, eine Schicht A (14) ist, die andere eine von einer Schicht nahe zu einer Oberfläche (7) und einer Schicht nahe zu der anderen Oberfläche (8), die eine kleinere durchschnittlichen Fluorintensität aufweist, eine Schicht B (16) ist, und eine Schicht zwischen der Schicht A (14) und der Schicht B (16) eine Schicht C (15) ist, wobei die durchschnittliche Fluorintensität der Schicht in der Reihenfolge der Schicht A (14), der Schicht B(16) und der Schicht C (15) abnimmt, wobei die Fluorintensität unter Verwendung eines Rasterelektronenmikroskops (SEM; für Englisch: Scanning Electron Microscope) mit einem energiedispensiven Röntgenfluoreszenz-Analysegerät (EDX) gemessen wird.
     
    8. Kohlenstoffplatte nach Anspruch 7, wobei der Schmelzpunkt des hydrophoben Materials 200 °C oder mehr und 320 °C oder weniger beträgt.
     
    9. Kohlenstoffplatte nach einem der Ansprüche 3 bis 8, wobei der Gleitwinkel des Wassers an der Oberfläche Y1 oder der Oberfläche Y2 40 Grad oder weniger beträgt, wobei der Gleitwinkel durch ein Gleitverfahren unter Verwendung eines automatischen Kontaktwinkelmessers bestimmt wird.
     
    10. Kohlenstoffplatte nach einem der Ansprüche 1 bis 9, wobei, wenn die Summe der Volumina der Poren mit einem Porendurchmesser in dem Bereich von 1 bis 100 µm 100 % beträgt, die Summe der Volumina der Poren mit einem Porendurchmesser in dem Bereich von 50 bis 100 µm 17 bis 50 % beträgt, wobei der Porendurchmesser und die Volumina der Poren unter Verwendung einer Quecksilberpenetrationsmethode bestimmt werden und die Porosität ((ρt-ρb)/ ρt), die aus der Rohdichte (pb) und der Reindichte (pt) berechnet wird, 75 bis 87 % beträgt.
     
    11. Kohlenstoffplatte nach Anspruch 10, wobei der Durchmesser einer Pore mit dem größten Volumen (Peakdurchmesser) in dem Durchmesserbereich von 1 bis 100 µm in dem Bereich von 30 bis 50 µm liegt.
     
    12. Gasdiffusionselektrodensubstrat, umfassend die Kohlenstoffplatte nach einem der Ansprüche 1 bis 11 und eine mikroporöse Schicht, wobei, wenn eine Oberfläche mit einem Oberflächenschichtflächenverhältnis X eine Oberfläche X1 ist, das Gasdiffusionselektrodensubstrat eine mikroporöse Schicht auf der Seite der Oberfläche X1 oder der Oberfläche X2 der Kohlenstoffplatte nach einem der Ansprüche 1 bis 11 aufweist.
     
    13. Brennstoffzelle, die das Gasdiffusionselektrodensubstrat nach Anspruch 12 umfasst.
     


    Revendications

    1. Feuille de carbone poreuse qui comprend une fibre de carbone et un matériau de liaison, dans laquelle, lorsqu'elle se trouve dans une répartition en profondeur de surface mesurée, le rapport entre la superficie d'une partie qui possède une profondeur de 20 µm ou moins dans la zone mesurée d'une surface est un rapport de superficie de couche de surface X, et le rapport entre la superficie d'une partie qui possède une profondeur de 20 µm ou moins dans la zone mesurée de la surface opposée est un rapport de superficie de couche de surface Y, le rapport de superficie de couche de surface X est supérieur au rapport de superficie zone de couche de surface Y, et une différence entre les rapports de superficie de couche de surface est de 3% ou plus et de 12% ou moins, dans laquelle la feuille de carbone poreuse est carbonisée, dans laquelle le matériau de liaison comprend un matériau carbonisé composé d'une résine, et dans laquelle le rapport de superficie de couche de surface est mesuré comme cela est décrit dans la description.
     
    2. Feuille de carbone selon la revendication 1, dans laquelle le rapport de superficie de couche de surface X est de 13% ou plus et de 17% ou moins, et le rapport de superficie zone de couche de surface Y est de 9% ou plus et de 13% ou moins.
     
    3. Feuille de carbone selon la revendication 1 ou 2, dans laquelle, lorsqu'une surface qui présente le rapport de superficie zone de couche de surface X est une surface X1, et une surface qui présente le rapport de superficie de couche de surface Y est une surface Y1, la rugosité de surface de la surface X1 est inférieure à la rugosité de surface de la surface Y1, et une différence entre les rugosités de surfaces de la surface X1 et Y1 est supérieure de 1 µm ou plus et de 4 µm ou moins, la rugosité de surface de la feuille de carbone est la rugosité de surface moyenne arithmétique Ra qui est mesurée selon la description en utilisant un microscope laser.
     
    4. Feuille de carbone selon l'une quelconque des revendications 1 à 3, dans laquelle, lorsqu'une surface qui présente le rapport de superficie de couche de surface X est une surface X1, la rugosité de surface de la surface X1 est de 16 µm ou moins.
     
    5. Feuille de carbone poreuse qui comprend une fibre de carbone et un matériau de liaison, dans laquelle la feuille de carbone poreuse est carbonisée et possède deux surfaces opposées, dans laquelle, lorsqu'une surface qui présente un taux de recouvrement plus élevé sur la surface par la fibre de carbone et le matériau de liaison est une surface X2, et une surface qui présente un taux de recouvrement plus faible sur la surface par la fibre de carbone et le matériau de liaison est une surface Y2, une différence de taux de recouvrement entre la surface X2 et la surface Y2 est de 5% ou plus et de 20% ou moins, dans laquelle le taux de recouvrement est déterminé comme cela est spécifié dans la description en réalisant un traitement numérique d'une image d'une surface de la feuille de carbone qui est observée avec un microscope à balayage électronique, et dans laquelle le matériau de liaison est un matériau carbonisé composé d'une résine.
     
    6. Feuille de carbone selon la revendication 5, dans laquelle le taux de recouvrement sur la surface X2 est de 70% ou plus et de 90% ou moins, et le taux de recouvrement sur la surface Y2 est de 50% ou plus et de 75% ou moins.
     
    7. Feuille de carbone selon l'une quelconque des revendications 1 à 6, dans laquelle la feuille de carbone comprend un matériau hydrophobe, et dans laquelle, parmi les couches obtenues en divisant la feuille de carbone dans une direction traversante de celle-ci en trois parties égales à l'intérieur d'une section (17) qui s'étend entre une surface (12) qui présente une intensité moyenne de fluor de 50% , qui est la plus proche d'une surface (7), et une surface (13) qui présente une intensité moyenne de fluor de 50% , qui est la plus proche de l'autre surface (8), l'une d'une couche proche d'une surface (7) et d'une couche proche de l'autre surface (8), qui présente une intensité moyenne de fluor plus élevée, est une couche A (14), l'autre d'une couche proche d'une surface (7) et d'une couche proche de l'autre surface (8), qui présente une intensité moyenne de fluor moins élevée, est une couche B (16), et une couche entre la couche A (14) et la couche B (16) est une couche C (15), l'intensité moyenne de fluor de la couche diminue dans l'ordre de la couche A (14), la couche B (16) et la couche C (15), dans laquelle l'intensité de fluor est mesurée en utilisant un analyseur à rayons X dispersifs (EDX) à énergie de microscope à balayage électronique (SEM).
     
    8. Feuille de carbone selon la revendication 7, dans laquelle le point de fusion du matériau hydrophobe est de 200°C ou plus et de 320°C ou moins.
     
    9. Feuille de carbone selon l'une quelconque des revendications 3 à 8, dans laquelle l'angle de glissement de l'eau au niveau de la surface Y1 ou de la surface Y2 est de 40 degrés ou moins, l'angle de glissement étant déterminé par un procédé de glissement en utilisant un dispositif de mesure d'angle de contact automatisé.
     
    10. Feuille de carbone selon l'une quelconque des revendications 1 à 9, dans laquelle, lorsque la somme des volumes des pores qui présentent un diamètre de pores compris entre 1 et 100 µm est de 100%, la somme des volumes des pores qui présentent un diamètre de pores compris entre 50 et 100 µm est de 17% à 50%, dans laquelle le diamètre de pores et les volumes des pores sont déterminés en utilisant un procédé de pénétration de mercure, et
    la porosité ((pt-pb)/pt) calculée à partir de la masse volumique (pb) et de la densité réelle (pt) est comprise entre 75% et 87%.
     
    11. Feuille de carbone selon la revendication 10, dans laquelle le diamètre d'un pore qui présente le plus gros volume (diamètre maximal) sur la plage de diamètres comprise entre 1 et 100 µm est compris entre 30 µm et 50 µm.
     
    12. Substrat d'électrode à diffusion de gaz qui comprend la feuille de carbone selon l'une quelconque des revendications 1 à 11 et une couche microporeuse, dans lequel, lorsqu'une surface qui présente un rapport de superficie de couche de surface X est une surface X1, le substrat d'électrode à diffusion de gaz possède une couche microporeuse sur le côté de surface X1 ou le côté de surface X2 de la feuille de carbone selon l'une quelconque des revendications 1 à 11.
     
    13. Pile à combustible qui comprend le substrat d'électrode à diffusion de gaz selon la revendication 12.
     




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    Cited references

    REFERENCES CITED IN THE DESCRIPTION



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    Patent documents cited in the description