CA2979528C - Support carbon material and catalyst for solid polymer type fuel cell use - Google Patents
Support carbon material and catalyst for solid polymer type fuel cell use Download PDFInfo
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- H01M4/00—Electrodes
- H01M4/86—Inert electrodes with catalytic activity, e.g. for fuel cells
- H01M4/90—Selection of catalytic material
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- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
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- H01M8/10—Fuel cells with solid electrolytes
- H01M8/1004—Fuel cells with solid electrolytes characterised by membrane-electrode assemblies [MEA]
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Abstract
Description
Title of Invention: Support Carbon Material and Catalyst For Solid Polymer Type Fuel Cell Use Technical Field [0001] The present invention relates to a support carbon material and catalyst for solid polymer type fuel cell use, more particularly relates to a support carbon material for solid polymer type fuel cell use with little drop in output voltage at the time of power generation by a large current and to a catalyst prepared using this support carbon material.
Background Art
Normally, it is comprised of a plurality of such unit cells connected (stacked) in accordance with the required output.
H2-*2H++2e- (E0=0V)...(reaction 1) 02+4H++4e--->2H20 (E0=1.23V)...(reaction 2) Further, how much voltage is maintained when taking out current to the outside is one indicator of the characteristics of a solid polymer type fuel cell.
Normally, if a higher current is taken out, the voltage tends to drop more.
To impart a solid polymer type fuel cell with high cell characteristics, the above reactions 1 and 2 have to be made to proceed as efficiently as possible. For that reason, it is important to raise the proton conductivity in both the anode and cathode catalyst layers and in the proton conductive electrolyte film. That is, the hydrogen ions generated at the anode side catalyst layer move through the water or ionomer of this catalyst layer from the top of the catalyst metal to the inside of the anode side catalyst layer, through the proton conductive electrolyte film, and, further to the inside of the cathode side catalyst layer of the opposing electrode to the top of the catalyst metal of the cathode side catalyst layer. Raising this proton conductivity is important.
While depending on the flow rate and concentration of the oxygen gas flowing through the cathode, 1.5A/cm2 is also one metric of the limit current density under common sense operating conditions. Further, regarding the sizes of the pores in the support carbon material of the catalyst forming the catalyst layers, the terms "micropores", "mesopores", and "macropores" are used. In accordance with the IUPAC, pore radius 1 nm or less pores are referred to as "micropores", pore radius 1 to 25 nm pores are referred to as "mesopores", and, further, pore radius 25 nm or more pores are referred to as "macropores".
However, such a support carbon material has a specific surface area of 400 m2/g or so. This is too small for achieving the practical support rate of catalyst metal of CA 02979528 201.7.2 40 to 70 mass%. For this reason, the particulates of the catalyst metal easily aggregate and as a result the particle size of the supported catalyst metal becomes coarser and it is difficult to prevent a drop in the power generation performance.
Micropores, which are easily closed by the water of the reaction product, are present in a certain ratio, so it is difficult to completely prevent the occurrence of the flooding phenomenon.
Citation List Patent Literature
PLT 3: W02014/129597A1 PLT 4: Japanese Patent Publication No. 2010-123572A
Summary of Invention Technical Problem
Specifically, the pore size, pore length, hydrophilicity of the pore walls, etc. are controlled. When the pore size becomes a size of an extent of several water molecules, the Van de Waals force (attraction) between the wall surfaces and water molecules causes the pressure causing condensation (liquefaction) (density of water molecules) to fall. As a result, if the current density rises, first, the pores of this size start to be closed.
Further, if the hydrophilicity of the wall surfaces forming the pores is high, the water molecules are adsorbed at the wall surfaces and the substantive pore sizes decrease. Further, since the water molecules form the wall surfaces, the pressure for condensation falls, that is, it becomes easier for water to be condensed by a large current. Further, in the catalyst layer, near the ionomer resin or hydrophilic support carbon material, an environment conducive to condensation of the water molecules is formed, so the flooding phenomenon occurs more easily.
Solution to Problem
(1) A support carbon material for solid polymer type fuel cell use comprised of a porous carbon material which has a pore volume and a pore area found by the Barrett-Joyner Halenda (BJH) analysis method from a nitrogen adsorption isotherm in an adsorption process satisfying the following conditions:a radius 2 nm to 50 nm pore volume VA
of 1 mug to 5 mug and a radius 2 nm to 50 nm pore area S2-50 of 300 m2/g to 1500 m2/g and a ratio (V5_25/VA) of radius 5 nm to 25 nm pore volume V5_25 (ml/g) to the pore volume VA(ml/g) of 0.4 to 0.7 and a ratio (V2_5/VA) of radius 2 nm to 5 nm pore volume V2-5 (ml/g) to the same of 0.2 to 0.5.
(2) The support carbon material for solid polymer type fuel cell use according to (1) wherein the pore volume V5-25 is 0.7 ml/g to 2 ml/g.
(3) The support carbon material for solid polymer type fuel cell use according to (1) or (2) wherein an average particle radius is 0.1 m to 5 m.
(4) A catalyst for solid polymer type fuel cell use comprising a support carbon material for solid polymer type fuel cell use according to any one of (1) to (3) at which catalyst metal particulates comprised of Pt or a Pt alloy having Pt as its main component are supported.
Advantageous Effects of Invention
Brief Description of Drawings
Description of Embodiments
provide a ready setting for condensation of water vapor at low relative pressures and become the cause of the flooding phenomenon. Further, in the micropores, gas diffusion is also slow. It is believed that they do not substantially contribute to large current power generation characteristics. Therefore, smaller volume and area of micropores are preferable, but micropores inherent to the material due to the production process and starting materials are allowed to a certain extent.
The present invention prescribes the volume and area of mesopores so as to lower the relative ratios of the volume and area of micropores.
(3) The area of the radius 2 nm to 50 nm pores provides places for supporting catalyst metal particulates. In the present invention, a lower limit of the value of the area for enabling the practical catalyst metal particulate support rate of 30 mass%, preferably 40 mass% or more, is set. Further, a substantive upper limit is prescribed.
The pores introduced by this method are structured mainly comprised of pores of pore radius 1 nm or less for the purpose of enabling adsorption of substances with relatively small molecular weights. The 5 nm to 25 nm pores which the present invention seeks do not exist much in conventional activated carbon etc. Note that specific numerical values of pore structures of activated carbon are shown in the examples.
specific numerical values of the pore structures of Ketjenblack EC300 are shown in the examples.
1, inside a particle 1 of the support carbon material, there are mesopores comprised of radius 2 nm to 5 nm pores (catalyst support pores) 2 and mesopores comprised of radius 5 nm to 25 nm pores (gas diffusion pores) 3.
Inside the catalyst support pores 2, not shown radius 1 to 3 nm catalyst metal particulates are supported. The water molecules produced on the catalyst metal particulates inside the catalyst support pores 2 immediately diffuse to the inside of the gas diffusion pores 3 connected with the catalyst support pores 2, further diffuse to the outside of the particles 1, and are discharged through the interparticle pores in the catalyst layer to outside the catalyst layer. Therefore, in a catalyst layer formed using the support carbon material of the present invention, space (gas diffusion paths) enabling water vapor and oxygen gas to be sufficiently diffused is secured. Due to this, it is possible to effectively suppress the flooding phenomenon even at the time of large current power generation under high humidity conditions. Further, the supply of oxygen gas required for large current power generation is secured.
resulting in a drop in the surface area effective for the catalyst reaction and a drop in the power generation characteristics, in particular the power generation characteristics at the time of large current power generation. Conversely, if the ratio (V2_5/VA) is larger than 0.5, the radius 5 nm to 25 nm pore volume V.-25 becomes relatively smaller. As a result, it is not possible to supply sufficient oxygen gas to the pore inlets of the radius 2 nm to 5 nm catalyst support pores substantially supporting the catalyst metal or the water molecules produced inside the catalyst support pores can no longer diffuse to outside the particles and the flooding phenomenon is liable to occur at the time of large current power generation. Further, the supply of oxygen gas is restricted in speed so the power generation characteristics at the time of large current power generation are liable to fall.
If this average particle radius is smaller than 0.1 gm, it becomes substantially difficult to form radius 5 nm to 25 nm gas diffusion pores by a ratio (V5_25/VA) of the pore volume V5-25 (ml/g) with respect to the pore volume VA of 0.4 to 0.7, while conversely, if the average particle radius is larger than 5.0 gm, when forming a practical thickness 10 gm catalyst layer, the surface of this catalyst layer is formed with relief shapes of an order of several gm, the flow of reaction gas becomes uneven, CA 02979528 2017.2 and the power generation characteristics are liable to fall.
As the method of activation at this time, for example, the gas activation method or chemical activation method etc. may be mentioned. As the gas activation method, there is the method of making a carbonized material react with water vapor, carbon dioxide, air, combustion gas, etc. at 700 C or more in temperature to make it porous.
Further, as the chemical activation method, the method of using an activation agent comprised of one or more agents selected from the group comprised of phosphoric acid, sulfuric acid, calcium chloride, zinc chloride, potassium sulfide, an alkali metal compound, etc. may be mentioned.
These activation agents sometimes are used as aqueous solutions of activation agents in accordance with need.
Further, as an alkali metal hydroxide used as the activation agent, for example, potassium hydroxide, sodium hydroxide, or other alkali metal hydroxides, potassium carbonate, sodium carbonate, or other alkali metal carbonates, potassium sulfate, sodium sulfate, or other alkali metal sulfonates, etc. may be mentioned.
Furthermore, it is possible to use the thus obtained catalyst for solid polymer type fuel cell use of the present invention by a method similar to the methods known in the past so as to form a catalyst layer for solid polymer type fuel cell use and, further, use the , catalyst layer to produce a solid polymer type fuel cell.
CA 02979528 201.7.2 Examples
for 5 hours or more to dissolve and remove the alumina.
Further, the results were filtered and redispersed in pure water three times repeatedly to wash it. The solids obtained by filtration were dried at 90 C for 4 hours to obtain carbon materials.
CA 02979528 201.7.2
Activation Treatment C
2 to 3 g of each obtained support carbon material was weighed out on an alumina boat. This was set in a horizontal type tubular electric furnace. While circulating nitrogen gas at 100 ml/min, the temperature was raised to 1100 C. After that, carbon dioxide was circulated at a rate of 100 ml/min while treating the material by a treatment time of 1 hour (-Cl) or a treatment time of 3 hours (-C3) for activation treatment to prepare activated support carbon materials. Note that each thus obtained activated support carbon material is indicated with "-Cl" or "-C3" attached to the end of the symbols of the support carbon material in a manner denoting the activated support carbon material obtained by treating the support carbon material A10 for 1 hour (-Cl) as activation treatment as A10-C1 and, further, denoting the activated support carbon material obtained CA 02979528 2017.2 by treating the support carbon material A10 for 3 hours (-C3) as activation treatment as A10-C3.
As the activation treatment, the inventors also studied so-called alkali activation using an alkali as an activation agent. In this alkali activation, about 2 g of each support carbon material obtained above and 5 to 10 g of KOH powder were mixed by a mortar. The obtained mixed powder was packed into a nickel tubular container and treated in an inert gas atmosphere at 450 C for a treatment time of 1 hour (-K1) or a treatment time of 3 hours (-K3) as activation treatment. After that, ethanol was placed inside the nickel tubular container after cooling in a glovebox to dissolve the alkali metal. The result was filtered, and the obtained solids were washed by pure water, then were dried in at 90 C for 4 hours in vacuum to prepare each activated support carbon material.
Each obtained activated support carbon material, in the same way as the case of the activation treatment C, has "-Kl" or "-K3" attached to the end of the symbols of the support carbon material.
was treated by the above activation treatment C or activation treatment K to obtain an activated support carbon material. Each activated support carbon material, in the same way as the case of the above method A, has "-Cl", "-C3", "-Kl", or "-1<3" attached to its end to indicate the support carbon material B-C1, support carbon material B-C3, support carbon material B-K1, or support carbon material B-K3.
aluminum 3%) and sucrose (C12H22011) were mixed. To this, concentrated sulfuric acid was added. The mixture was held at 200 C for 2 hours, then was held at 1200 C for 1 hour to fire it. The obtained silica-carbon complex was washed by hydrogen fluoride to obtain the support carbon material C.
Furthermore, similarly, except for heating in an inert gas atmosphere to 500 C, the above support carbon material C was treated in accordance with the above activation treatment K to obtain an activated support carbon material. The obtained activated support carbon material, in the same way as the case of the above method A, has "-Kl" or "-1<3" attached to its end to indicate the support carbon material C-Kl or support carbon material C-K3.
3D periodic structure regularity. Na-Y type zeolite powder dried in advance at 150 C was placed in a quartz reaction tube. To this, furfuryl alcohol was added to an extent whereby the zeolite was immersed, then the result was stirred while Impregnating it. After that, this was heated to 150 C to make the furfuryl alcohol impregnated in the pores of the zeolite polymerize. Further, this was heat treated at 900 C to make the polymer in the pores carbonize to synthesize a carbon-zeolite composite. Next, the obtained carbon-zeolite composite was treated by hydrofluoric acid and hydrochloric acid to dissolve away the zeolite to obtain a support carbon material D
comprised of a porous carbon material.
Furthermore, except for heating in an inert gas atmosphere to 500 C, the above support carbon material D
was treated in accordance with the above activation treatment K to obtain an activated support carbon material. The obtained activated support carbon material, in the same way as the case of the above method A, has "-Kl" or "-K3" attached to its end to indicate the support carbon material D-Kl or support carbon material D-K3.
CA 02979528 201.7.2
As an example of carbon black, Ketjenblack (EC300 made by Lion) being used as the standard for catalyst supports in current solid polymer type fuel cells was used. This material was designated the support carbon material E. As an example of activated carbon, "YP8OF" made by Kuraray Chemical was used. This was adjusted to an average particle radius 1.2 m using a pulverizer. This material was designated the support carbon material F. As an example of a carbon material not made porous, acetylene black (AB; Denka Black Powder made by Denka) was used.
This material was designated the support carbon material G. Based on the method described in Example 1 of PLT 3, a carbon material (MCND) was produced. This material was designated the support carbon material H.
Further, the ratio (V5_25/VA) and ratio (V2-5/VA) were calculated and the pore structure of each support carbon material was investigated. The results are shown in Table 1 and Table 2.
for 60 minutes to prepare a catalyst layer.
The above prepared catalyst layers were used to prepare MEAs (membrane electrode assemblies) by the following method. A square piece of electrolytic film of 6 cm per side was cut out from a Nafion film (made by Dupont, NR211). Further, the catalyst layers of the anode and cathode coated on Teflon sheets were respectively cut out by a cutter knife to square pieces of 2.5 cm per side. Between the thus cut out catalyst layers of the anode and cathode, this electrolytic film was sandwiched CA 02979528 201.7.2 so that the catalyst layers sandwiched and contacted the center part of the electrolytic film and were not offset from each other, the assembly was pressed at 120 C by 100 kg/cm2 for 10 minutes, then cooled down to room temperature, then only the Teflon sheets were carefully peeled off at both the anode and cathode to prepare a catalyst layer-electrolytic film assembly with the catalyst layers of the anode and cathode fixed to the electrolytic film.
prepared were calculated by finding the mass of the catalyst layers fixed to the Nafion film (electrolytic film) from the difference of the mass of the Teflon sheets with the catalyst layers before pressing and the mass of the Teflon sheets peeled off after pressing and using the mass ratios of the compositions of the catalyst layers. Further, it was made possible to use the carbon material A-60-1400 in common for the anodes and evaluate only the performance of the cathode catalyst layer from the results of evaluation of the power generation characteristics.
and, further, the supplied air and pure hydrogen were moistened by bubbling in distilled water warmed to respectively 85 C and 80 C. Due to this condition, air and hydrogen are supplied to the cell in the state saturated with water vapor. Under the above condition, the fuel cell was evaluated by measuring the cell voltage at 1200 mA/cm2 of the region where the effect of the support carbon material used remarkably appears, that is, the resistance to gas diffusion becomes larger. In Table 1 and Table 2, the cell voltage of the support carbon material evaluated by the above method is shown as the "output voltage (V) at the time of high humidity.
[0 0 65] Table 1 i Aver. t Support A ) iv V 5_25 S z_50 pa r . ,;(.:11-1:P11-e iCnaa trberila (mt /g) v V
-.25f A (m1.1g) 012/g) roAr.d1,-,"s tvi AI0 096 058 024 023 390 I2. 4 042 ____ A20 0.67 0.13 0.82 0.71 220 2.5 0.36 11 2 r i A50 9.57 0.06 0.59 0.34 215 4.5 -- " # 3 A10-C1 2. 30 O. 42 04.3 099 825 2,3 065 Ex=1 A20-CL 2. 20 0. 21 0.6.8 1.50 490 2.4 0.64 2 A50-C1 1. 10 0,13 0.51 = 0.56 320L 4.0 040 C-E:':=4 AR -C3 i 3.00 0. 34 0. 59 1.77 1020 I 1.9 0.72 Ex = 3 A20-C3 2. 50 0. 28 0. 57 1. 43 615 2. 1 0. 66 11 4 A50-C3 1. 54 0. 21 0. 45 0_ 69 480 3. 6 0. 61 #
A21 1. 14 0,51 0.33 0.38 290 2.5 --") C=Ex=S
All i 1.03 0.45 0.61 0.63 260 2.4 0.37 H 6 _Al2 0. 95 0.33 0.77 ' 0.73 245 2.4 0.40 # 7 A21-CI 2. 19 0.44 0.43 0. 94 465 2.3 0.65 Ex 6 Al 1-C1 2. 27 0. 38 0. 49 1. 11 425 2. 2 0.
Al2-C1 2.10 0.33 0.55 1.16 400 2.2 0,66 # 8 A21-C3 2. 98 0. 39 0.47 1.40 535 2.1 0. 65 # 9 Al 1-C3 2. 78 0. 35 O. 51 1. 42 510 2. 0 0. 64 # 10 Al2-C3 2. 66 O. 31 O. 53 1. 41 505 2. 0 0. 65 11 11 A10-K1 2.50 0.44 0.46 I. 15 810 2.3 0. 68 # 12 A20-K1 2.40 0. 24 0. 64 j 1. 54 480 2. 2 0.66 #
A50-1c1 1.30 0. 17 0.49 , 0.64 355 4. 1 0.45 .Ex A10-10 3. 20 0.41 0. 56 : 1.19 990 2.9 0. 67 Ex.14 A20-K3 2. 60 0. 33 0. 51 1. 33 635 1. 9 0. 65 1_5 A50-K3 2.10 0.27- 0.42 1- 0. 88 525 3. 7 0. 66 n A-2-1 -K1 2. 55 0.39 0.43 1. 10 485 2. 2 0. 66 n 17 , All-K1 2. 88 U. 35 0. 49 1. 41 445 2. 1 0.
; Al2-K1 2.59 0.31 0.55 1.42 490 2.2 0.64 AZ I-K3 3.57 0.37 0.50 1.79 605 2. 0 0. 64 # 20 A 11-K3 3. 22 O. 33 O. 48 1. 55 620 1. 9 0, 66 Al2-K3 3.04 0.35 0.48 1. 46 670 1.8 0.65 # 22 I: Not measurable [0 0 6 6] Table 2 Support Aver.V .. Output carbon Võ V õ VS-25 S 2-50 P": voltage material (nlig) 2Y% 5'5 A (IL/g) (m2/g) ""1"s (v) (pro AA11 079 044 044 035 305 2. 0 1042 C=Ex.
AB11 0. 75 1 0.28 059 0.44 270 2. 1 0.43 # .10 AA11-C3 2.85 0.42 0.46 1.31 605 2.2 0.66 Ex=23 AB11-C3 2.61 0.3? 0.46 1.23 __ 585 2. 3 0. 66 n 24 A10S-C3 3.65 0.35 0.51 1.66 1420 0.63 0.71 # 25 AIOSS-03 4. 13 0. 34 0.47 1.94 1440 0.43 0.63 R 26 AI0L-C3 3.5o 0.32 0.52 1.85 965 4.2 0.68 # 27 AlOLL-C3 3.44 0.34 0.53 1.82 920 5.3 0.62 n 28 1.53 0.51 0.2? 0.41 912 2.3 0.43 c=Ex=i' B-Cl 1.98 0.42 0.44 0. 87 877 ______ 2.2 0. 66 B-C3 ___________ 3. 22 0. 37 0. 51 1. 64 765 2. 0 0. 65 n 30 B-K1 1.78 0.40 O. 45 0. 80 856 2.2 0.66 1 # 31 B-K3 4. 02 O. 39 O. 43 1. 73 789 2.0 0.65 n 32 1.67 0.80 0.06 0. 10 896 2.3 039 '=E7--L-7-C-C I
2.05 0. 63 0.24 0.49 823 2.2 0.42 __ n __ 13 I C-C3 2.78 0.48 0.41 I. Li 767 2. 1 0.65 Ex-33 H
C-MI 2. 14 0.01 0.26 0.56 817 2.2 0.41 C.Ex.14 C-K3 3. 15_ O. 45 0.43 1.35 743 2.0 0.65 Ex 34 0. 0 _ 0.01 ___ 0.01 0.00 12 0.6 0.Ex.15 0-C1 0.78 O. 12 O. 17 O. 13 145 ! 0.6 0.41 # 16 1 D 1. 18 1- 0.23 0.41 0.48 313 0.6 (1.64 Ex=35 E(EC300) 065 1 0. 18 0. 33 0. 21 140 0.
2 O. 50 (- EN = 17 F (YP8011) 0.12 0.44 0.41. 0.05 48 ! 1. 9 0. 32 # 18 GCB) 0.09 0.10 0.37 __ 0.03 14 0.2 0.31 # 19 H WNW 0.88 , 0.53 0.23 0.20 435 0. 3 0. 51 # 20 (Note) .-1: Not measurabig, [0067] 5. Results of Evaluation of Fuel Cell (1) Support Carbon Material Prepared by Method A
A10 was too small in pore volume VA and, since using radius 5 nm particles for the template, had a relative large pore volume V2-5. Conversely, the pore volume V5-25 became small, the gas diffusion pores inside the particles became small, and the desired output voltage (0.60V or more) could not be obtained at the time of large current power generation under high humidity conditions. Further, A20 and A50 were too small in pore volume VA and, since using template particles of 5 nm or more in size, had a small pore volume V2-5. The dispersion of the Pt particulates was poor and the diffusion of the reaction gas of oxygen inside the particles was poor, so the desired output voltage could not be achieved.
[0068] Effect of Activation Treatment C
A10-C1 and A20-C1 treated by CO2 for 1 hour as activation treatment increased in pore volume VA due to activation.
The balance of the pore volume V2-5 and the pore volume V5_ 25 became better. Further, the pore area S2-50 also was sufficiently large. Both exhibited good output voltages at the time of large current power generation under high humidity conditions. On the other hand, A50-C1 was increased in pore volume VA, but the increase in pore volume V2_5 was small and the desired output voltage could not be achieved. Further, A10-03, A20-03, and A50-03 treated by CO2 for 3 hours as activation treatment all increased in pore volume VA and became better in balance of pore volume V2-5 and pore volume V5-25 due to the activation treatment. Further, the pore area S2-50 was also sufficiently large. All exhibited good output voltages at the time of large current power generation under high humidity conditions. However, A50-C3 had a somewhat small absolute value of pore volume V5_25 and was slightly inferior to the others in output voltage as a result.
[0069] A21, All, and Al2 all had a pore area S2_50 of less than 300 m2/g and were low in output voltage at the time of large current power generation under high humidity conditions. Among them as well, All and Al2 had good balances of pore volume V2-5 and pore volume V5-25. If treating them to increase the pore area S2-50 by activation treatment, it is expected that good power generation characteristics can be exhibited. Further, A21-C1, All-Cl, Al2-C1, A21-03, All-03, and Al2-03 obtained by treating the above three types of support carbon materials as activation treatment by CO2 for 1 hour or 3 hours all exhibited excellent power generation characteristics at the time of large current power generation under high humidity conditions.
[0070] Further, AAll and AB11 both were good in balance of pore volume V2-5 and pore volume V5_25, but were small in the total volume of the pore volume VA and were low in the output voltage at the time of large current power generation under high humidity conditions. AA11-C3 and AB11-C3 obtained by treating AAll and AB11 by CO2activation treatment were both excellent in output characteristics at the time of large current power generation under high humidity conditions.
[0071] Effect of Activation Treatment K
In the support carbon materials obtained by treating A10, A20, A50, A21, All, and Al2 by activation treatment by KOH for 1 hour or 3 hours, in the case of A50 where the particle size of the particles of the casting mold was 50 nm, with treatment for 1 hour, it was not possible to create a pore volume V2-5 with a small pore size, but with treatment for 3 hours, the balance between the pore volume V2-5 and pore volume V5-25 was good, the desired pore structure with the large pore area S2_50 could be obtained, and, further, in the case of the support carbon materials where the particle size of the casting mold was 10 nm or 20 nm, the desired pore structures were obtained and the materials all exhibited excellent power generation characteristics at the time of large current power generation under high humidity conditions.
[0072] Effect of Average Particle Radius Al0S-C3, AlOSS-C3, Al0L-C3, and AlOLL-C3 were all excellent in pore structure (pore volume VA, ratio V2-5/VA, ratio V5_25/VA, pore volume V5_25, and pore area 52-50) = In particular, A10S-C3 and Al0L-C3 had average particle radii of respectively 0.63 m and 4.2 m and exhibited excellent power generation characteristics at the time of large current power generation under high humidity conditions.
[0073] (2) Support Carbon Material Prepared by Method The support carbon material B prepared by the method B
was excellent in pore volume VA, but the ratio of pore volume V2_5 was high and the ratio of pore volume V5_25 became relatively lower. The output voltage at the time of large current power generation under high humidity conditions was low. On the other hand, the support carbon materials obtained using the support carbon material 13 as a starting material and treating them by the activation treatment C or activation treatment K all were excellent in pore structure (pore volume VA, ratio V2_5/VA, ratio V5_ 25/VA, Pore volume V5-25, and pore area S2-50) and exhibited excellent power generation characteristics at the time of large current power generation under high humidity conditions.
[0074] (3) Support Carbon Material Prepared by Method The support carbon material C prepared by the method C
was excellent in pore volume VA, but the ratio of pore volume V2-5 was high and relatively the ratio of pore volume V5-25 became lower. The output voltage at the time of large current power generation under high humidity conditions was low. On the other hand, the support carbon materials obtained using the support carbon material C as a starting material and treating them by the activation treatment C or activation treatment K all were excellent in pore structure (pore volume VA, ratio V2_5/VA, ratio V5_ 25/VA pore volume V5-25 and pore area S2-50) and exhibited excellent power generation characteristics at the time of large current power generation under high humidity conditions.
[0075] (4) Support Carbon Material Prepared by Method The support carbon material D prepared by the method D
had almost all pores of a radius of 1 nm or less. Radius 2 nm or more pores substantially did not exist. This was inferior in power generation characteristics at the time of large current power generation under high humidity conditions when used as a catalyst support. On the other hand, the support carbon material D-Cl obtained by treating the support carbon material D by the activation treatment C for 1 hour was insufficient in formation of 2 nm or more pores and low in output voltage at the time of large current power generation under high humidity conditions, but the support carbon material D-C3 obtained by treating it by the activation treatment C for 3 hours exhibited excellent power generation characteristics at the time of large current power generation under high humidity conditions.
[0076] (4) Other Carbon Materials .The support carbon material E used as an example of carbon black, the support carbon material F used as an example of activated carbon, the support carbon material G used as an example of a carbon material not treated to make it porous, and the support carbon material H used as an example of MCND all were inferior in pore structures (pore volume VA, ratio V2-5/VA, ratio V5_25/VA, pore volume V5-25, and pore area S2-50 and did not achieve the desired output voltage at the time of large current power generation under high humidity conditions.
Reference Signs List [0077] 1...support carbon material particles 2...radius 2 nm to 5 nm pores (catalyst support pores) 3...radius 5 nm to 25 nm pores (gas diffusion pores)
Claims (4)
a radius 2 nm to 50 nm pore volume V A of 1 ml/g to 5 ml/g and a radius 2 nm to 50 nm pore area S2-50 of 300 m2/g to 1500 m2/g; and a ratio of radius 5 nm to 25 nm pore volume V5-25 to the pore volume V A, V5-25/V A of 0.4 to 0.7, and a ratio of radius 2 nm to 5 nm pore volume V2-5 to the pore volume V A, V2-5/V A of 0 .2 to 0.5, wherein V2-25, V2-5 and V A are expressed in ml/g.
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| PCT/JP2016/056657 WO2016152447A1 (en) | 2015-03-26 | 2016-03-03 | Carrier carbon material for solid polymer fuel cell and catalyst |
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| JP6964448B2 (en) * | 2017-06-29 | 2021-11-10 | 日本製鉄株式会社 | Mold carbon material for fuel cell catalyst carrier, catalyst layer for fuel cell, and fuel cell |
| CN108083255A (en) * | 2017-11-10 | 2018-05-29 | 山东大学 | A kind of preparation method of hollow graphite structure nano cages material |
| KR102613427B1 (en) * | 2018-05-15 | 2023-12-14 | 엔.이. 켐캣 가부시키가이샤 | Catalysts for electrodes, compositions for forming gas diffusion electrodes, gas diffusion electrodes, membrane-electrode assemblies, and fuel cell stacks |
| JP6861370B1 (en) * | 2019-09-27 | 2021-04-21 | パナソニックIpマネジメント株式会社 | Manufacturing method of catalyst, catalyst layer, membrane / electrode assembly, electrochemical device, catalyst |
| JP7484650B2 (en) * | 2020-10-15 | 2024-05-16 | トヨタ自動車株式会社 | Porous carbon, catalyst support, and method for producing porous carbon |
| JP7284776B2 (en) | 2021-03-30 | 2023-05-31 | 株式会社豊田中央研究所 | Mesoporous carbon, electrode catalyst and catalyst layer for fuel cell |
| CN115722271A (en) * | 2021-08-31 | 2023-03-03 | 姚光纯 | Catalyst carrier |
| JP7817525B2 (en) * | 2021-12-07 | 2026-02-19 | 日本製鉄株式会社 | Method for manufacturing template carbon material, method for manufacturing catalyst, method for manufacturing catalyst layer for polymer electrolyte fuel cell, and method for manufacturing fuel cell |
| JP7735208B2 (en) | 2022-03-17 | 2025-09-08 | 株式会社豊田中央研究所 | Mesoporous carbon, and electrode catalyst and catalyst layer for fuel cells |
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| JP4799897B2 (en) * | 2004-04-22 | 2011-10-26 | 新日本製鐵株式会社 | Fuel cell |
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