JP2009123619A - Fuel cell - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fuel cell having an improved output maintenance performance. <P>SOLUTION: The fuel cell is provided with a cathode 6, an anode 5 and an electrolyte membrane 7 arranged between the cathode and the anode 5. The anode 5 is provided with an anode catalyst layer 8 laminated on the electrolyte layer 7, an anode porous layer 9 laminated on the anode catalyst layer 8, and an anode diffusion layer 10 laminated on the anode porous layer 9, and in the anode porous layer 9, a droplet contact angle of a surface facing the anode catalyst layer 8 is 100-140 degrees and the droplet contact angle of a surface facing the anode diffusion layer 10 is 100 degrees or less and is smaller than the droplet contact angle of the surface facing the anode catalyst layer 8. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a fuel cell.

  2. Description of the Related Art In recent years, electronic devices have been reduced in size, performance, and portability due to advances in electronic technology. In portable electronic devices, there is an increasing demand for higher energy density of batteries used. For this reason, a battery having a large capacity while being lightweight and small is required, and a lithium ion battery or the like has been developed.

  However, the operation time of portable electronic devices tends to increase further, and in the lithium ion battery, the improvement in energy density is reaching the limit from the viewpoint of material and structure, and it is becoming impossible to meet further demands.

  In view of the above situation, small fuel cells are attracting attention instead of lithium ion batteries. In particular, a direct methanol fuel cell (DMFC) using methanol as a fuel is difficult to handle hydrogen gas, or an apparatus for reforming organic fuel into hydrogen gas is unnecessary. Compared to a fuel cell using hydrogen gas, it is excellent in miniaturization.

  DMFC oxidizes and decomposes methanol at the anode (fuel electrode) to generate carbon dioxide, protons, and electrons, while the cathode (air electrode) supplies oxygen obtained from the air and the electrolyte membrane from the anode. Water is generated by the protons and electrons supplied from the anode through the external circuit, and power is supplied by the electrons passing through the external circuit.

  Since the DMFC generates power with the above configuration, a pump for supplying methanol and a blower for feeding air are provided as auxiliary devices, and a DMFC having a complicated form as a system has been developed. Therefore, it has been difficult to reduce the size of the fuel cell.

Instead of supplying methanol with a pump, a methanol storage chamber is provided in the vicinity of the power generation element, and methanol is supplied through the gas-liquid separation membrane provided between the methanol storage chamber and the power generation element, thereby reducing the size. It was advanced. For intake of air, a compact DMFC has been proposed by directly installing an air inlet in a power generation element instead of a blower (see Patent Document 1).
JP 2004-164903 A

  The present invention seeks to provide a fuel cell with improved output maintenance performance.

A fuel cell according to the present invention is a fuel cell comprising a cathode, an anode, and an electrolyte membrane interposed between the cathode and the anode,
The anode includes an anode catalyst layer laminated on the electrolyte membrane, an anode porous layer laminated on the anode catalyst layer, and an anode diffusion layer laminated on the anode porous layer,
The anode porous layer has a droplet contact angle of 100 to 140 degrees on the surface facing the anode catalyst layer, a droplet contact angle on the surface facing the anode diffusion layer is 100 degrees or less, and the It is characterized by being smaller than the droplet contact angle of the surface facing the anode catalyst layer.

  According to the present invention, a fuel cell with improved output maintaining performance can be provided.

  An anode of a fuel cell according to the present invention includes an anode catalyst layer laminated on an electrolyte membrane, an anode porous layer laminated on the anode catalyst layer, and an anode diffusion layer laminated on the anode porous layer. In the anode porous layer, the surface (hereinafter referred to as the first surface) facing the anode catalyst layer has a droplet contact angle of 100 to 140 degrees and the surface facing the anode diffusion layer (hereinafter referred to as the second surface). The droplet contact angle of the first surface is 100 degrees or less and smaller than the droplet contact angle of the first surface.

  According to such a configuration, when the generated water generated at the cathode by the power generation reaction diffuses to the anode catalyst layer through the electrolyte membrane, the generated water penetrates to the anode diffusion layer on the first surface of the porous layer. Can be blocked. As a result, (i) the water retention amount of the anode catalyst layer can be increased, (ii) the fluctuation of the water retention amount can be reduced, and (iii) the dilution of fuel with the generated water that has passed through the anode diffusion layer Therefore, high output can be maintained over a long period of time.

  The cathode of the fuel cell preferably includes a cathode catalyst layer laminated on the electrolyte membrane, a cathode porous layer laminated on the cathode catalyst layer, and a cathode diffusion layer laminated on the cathode porous layer. The cathode porous layer has a droplet contact angle of 100 to 140 degrees on the surface facing the cathode catalyst layer (hereinafter referred to as the third surface) and the surface facing the cathode diffusion layer (hereinafter referred to as the first surface). It is desirable that the liquid droplet contact angle (referred to as surface 4) is 100 degrees or less and smaller than the liquid droplet contact angle of the third surface.

  By using such a cathode, water generated at the cathode can be efficiently conveyed to the anode catalyst layer through the electrolyte membrane, so that the output efficiency can be increased. Further, since the generated water can be prevented from staying in the cathode diffusion layer, not only the output efficiency but also the output maintenance rate can be improved. Therefore, by using the cathode, the flow of generated water can be controlled, and a fuel cell excellent in output and maintenance rate can be obtained.

  Here, as shown in FIG. 1, the droplet contact angle θ is a tangent L to the surface curve of the droplet DR at the point P where the droplet DR and the measurement object X (porous layer) are in contact with the measurement object. The angle formed by the surface of X.

  This contact angle θ is measured as follows. First, as shown in FIG. 2, a droplet DR of pure water is formed with the microsyringe M. In the present embodiment, the droplet (water droplet) DR is about 0.5 microliters.

  Next, as shown in FIG. 3, the bottom of the droplet DR is attached to the measurement object X. Then, when the microsyringe M is separated from the measurement object X, the droplet DR adheres to the surface of the measurement object X as shown in FIG. In this state, after 3000 ms, the height h of the droplet DR and the radius r of the droplet DR are measured. Here, the height h of the droplet DR is the distance between the interface of the measurement object X and the apex of the droplet DR.

  Since the contact angle θ is equal to twice the angle θ1 (= arctan (r / h)) shown in FIG. 1, the following equation (A) is used from the height h and the radius r of the measured water droplet DR. The value of the contact angle θ is calculated.

θ = 2 × {arctan (r / h)} Formula (A)
The larger the value of the contact angle θ calculated as described above, the higher the water repellency of the measurement object, and the smaller the value, the lower the water repellency of the measurement object.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS.

  The fuel cell shown in FIG. 5 includes a fuel cell 1 constituting an electromotive unit, a fuel distribution mechanism 2 that supplies fuel to the fuel cell 1, a fuel storage unit 3 that stores liquid fuel, and these fuel distributions. It is mainly composed of a flow path 4 that connects the mechanism 2 and the fuel storage portion 3.

  The fuel cell 1 includes a membrane electrode composed of an anode (fuel electrode) 5, a cathode (air electrode / oxidant electrode) 6, and a proton conductive electrolyte membrane 7 sandwiched between the anode 5 and the cathode 6. It has a joined body (Mebrane Electrode Assembly: MEA).

  For the electrolyte membrane 7, a proton conductive electrolyte membrane can be used. Examples of the proton conductive material constituting the electrolyte membrane include a fluoric resin having a sulfonic acid group (for example, perfluorosulfonic acid polymer), a hydrocarbon resin having a sulfonic acid group, tungstic acid, phosphotungstic acid, and the like. However, it is not limited to these.

  As shown in FIGS. 5 and 7, the anode 5 is laminated on the anode catalyst layer 8 laminated on the electrolyte membrane 7, the anode porous layer 9 laminated on the anode catalyst layer 8, and the anode porous layer 9. And an anode gas diffusion layer 10. The anode porous layer 9 includes a conductive porous substrate 9a made of, for example, carbon paper, and conductive porous layers 9b and 9c formed on both surfaces of the substrate 9a. The droplet contact angle of the surface facing the anode catalyst layer 8 in the conductive porous layer 9b (hereinafter referred to as the first surface) is 100 to 140 degrees. In addition, the droplet contact angle of the surface facing the anode diffusion layer 10 (hereinafter referred to as the second surface) in the conductive porous layer 9c is 100 degrees or less and is smaller than the droplet contact angle of the first surface. Is also small.

  The anode catalyst layer 8 includes an anode catalyst and a binder. Examples of the anode catalyst include platinum group elemental metals (Pt, Ru, Rh, Ir, Os, Pd, etc.), alloys containing platinum group elements, and the like. As the anode catalyst, it is desirable to use Pt-Ru which has strong resistance to methanol and carbon monoxide, but is not limited thereto. Further, a supported catalyst using a conductive support such as a carbon material may be used, or an unsupported catalyst may be used. For the binder, for example, a perfluorosulfonic acid ionomer can be used.

  On the other hand, as shown in FIGS. 5 and 7, the cathode 6 includes a cathode catalyst layer 11 laminated on the electrolyte membrane 7, a cathode porous layer 12 laminated on the cathode catalyst layer 11, and a cathode porous layer 12. The cathode gas diffusion layer 13 is stacked. The cathode porous layer 12 includes a conductive porous substrate 12a made of, for example, carbon paper, and conductive porous layers 12b and 12c formed on both surfaces of the substrate 12a. The droplet contact angle (hereinafter referred to as the third surface) of the surface facing the cathode catalyst layer 11 in the conductive porous layer 12b is preferably 100 to 140 degrees. The droplet contact angle of the surface facing the cathode diffusion layer 13 (hereinafter referred to as the fourth surface) in the conductive porous layer 12c is 100 degrees or less and is smaller than the droplet contact angle of the third surface. Is preferably small.

  The cathode catalyst layer 11 includes a cathode catalyst and a binder. Examples of the cathode catalyst include platinum group elemental metals (Pt, Ru, Rh, Ir, Os, Pd, etc.), alloys containing platinum group elements, and the like. Although it is desirable to use platinum as a cathode catalyst, it is not limited to this. Further, a supported catalyst using a conductive support such as a carbon material may be used, or an unsupported catalyst may be used. For the binder, for example, a perfluorosulfonic acid ionomer can be used.

  The anode gas diffusion layer 10 serves to uniformly supply fuel to the anode catalyst layer 8 and also serves as a current collector for the anode catalyst layer 8. On the other hand, the cathode gas diffusion layer 13 serves to uniformly supply the oxidant to the cathode catalyst layer 11 and also serves as a current collector for the cathode catalyst layer 11. The anode gas diffusion layer 10 and the cathode gas diffusion layer 13 are made of a conductive porous substrate such as carbon paper.

  A conductive layer 14 is laminated on the anode gas diffusion layer 10 and the cathode gas diffusion layer 13 as necessary. Examples of the conductive layer 14 include a porous layer (for example, a mesh) or a foil body made of a metal material such as gold or nickel, or a conductive metal material such as stainless steel (SUS) with a highly conductive metal such as gold. A coated composite material or the like is used. Rubber O-rings 16 are interposed between the electrolyte membrane 7 and the fuel distribution mechanism 2 and the cover plate 15, respectively, thereby preventing fuel leakage and oxidant leakage from the fuel cell (MEA) 1. is doing.

  Although not shown, the cover plate 15 has an opening for taking in air as an oxidant. A moisture retaining layer and a surface layer are disposed between the cover plate 15 and the cathode 6 as necessary. The moisturizing layer is impregnated with a part of the water generated in the cathode catalyst layer 11 to suppress the transpiration of water and promote uniform diffusion of air to the cathode catalyst layer 11. The surface layer adjusts the amount of air taken in, and has a plurality of air inlets whose number, size, etc. are adjusted according to the amount of air taken in.

  Liquid fuel corresponding to the fuel cell 1 is stored in the fuel storage unit 3. Examples of the liquid fuel include methanol fuels such as aqueous methanol solutions of various concentrations and pure methanol. The liquid fuel is not necessarily limited to methanol fuel. The liquid fuel may be, for example, an ethanol fuel such as an ethanol aqueous solution or pure ethanol, a propanol fuel such as a propanol aqueous solution or pure propanol, a glycol fuel such as a glycol aqueous solution or pure glycol, dimethyl ether, formic acid, or other liquid fuel. In any case, liquid fuel corresponding to the fuel cell 1 is stored in the fuel storage portion 3.

  The type and concentration of the liquid fuel are not limited. However, the characteristic of the fuel distribution mechanism 2 having a plurality of fuel discharge ports 22 becomes more apparent when the fuel concentration is high. For this reason, the fuel cell can particularly exhibit its performance and effects when a methanol aqueous solution or pure methanol having a concentration of 80% or more is used as the liquid fuel.

  A fuel distribution mechanism 2 is disposed on the anode (fuel electrode) 5 side of the fuel cell 1. The fuel distribution mechanism 2 is connected to the fuel storage portion 3 through a liquid fuel flow path 4 such as a pipe. Liquid fuel is introduced into the fuel distribution mechanism 2 from the fuel storage portion 3 through the flow path 4. The flow path 4 is not limited to piping independent of the fuel distribution mechanism 2 and the fuel storage unit 3. For example, when the fuel distribution mechanism 2 and the fuel storage unit 3 are stacked and integrated, a liquid fuel flow path connecting them may be used. The fuel distribution mechanism 2 only needs to be connected to the fuel storage unit 3 via the flow path 4.

  The mechanism for feeding the liquid fuel from the fuel storage unit 3 to the fuel distribution mechanism 2 is not particularly limited. For example, when the installation location at the time of use is fixed, liquid fuel can be dropped from the fuel storage unit 3 to the fuel distribution mechanism 2 and fed using gravity. Further, by using the flow path 4 filled with a porous body or the like, the liquid can be fed from the fuel storage portion 3 to the fuel distribution mechanism 2 by a capillary phenomenon. Furthermore, liquid feeding from the fuel storage unit 3 to the fuel distribution mechanism 2 may be performed by a pump 17 as shown in FIG. Alternatively, as long as the fuel is supplied from the fuel distribution mechanism 2 to the fuel cell 1, a fuel cutoff valve may be arranged instead of the pump 17. In this case, the fuel cutoff valve is provided to control the supply of liquid fuel through the flow path.

  As shown in FIG. 6, the fuel distribution mechanism 2 includes at least one fuel inlet 21 through which liquid fuel flows through the flow path 4 and a plurality of fuel outlets 22 through which liquid fuel and vaporized components thereof are discharged. The fuel distribution plate 23 having As shown in FIG. 5, a gap 24 serving as a liquid fuel passage led from the fuel injection port 21 is provided inside the fuel distribution plate 23. The plurality of fuel discharge ports 22 are directly connected to gaps 24 that function as fuel passages.

  The liquid fuel introduced into the fuel distribution mechanism 2 from the fuel inlet 21 enters the gap 24 and is guided to the plurality of fuel discharge ports 22 through the gap 24 functioning as a fuel passage. For example, a gas-liquid separator (not shown) that transmits only the vaporized component of the liquid fuel and does not transmit the liquid component may be disposed in the plurality of fuel discharge ports 22. As a result, the vaporized component of the liquid fuel is supplied to the anode 5 of the fuel cell 1. The gas-liquid separator may be installed as a gas-liquid separation membrane or the like between the fuel distribution mechanism 2 and the anode 5. The vaporized component of the liquid fuel is discharged from a plurality of fuel discharge ports 22 toward a plurality of locations on the anode 5.

A plurality of fuel discharge ports 22 are provided on the surface of the fuel distribution plate 23 facing the anode 5 so that fuel can be supplied to the entire fuel cell 1. The number of the fuel discharge ports 22 may be two or more. However, in order to equalize the fuel supply amount in the surface of the fuel cell 1, the fuel discharge ports 22 of 0.1 to 10 / cm ² exist. It is preferable to form so as to. If the number of the fuel discharge ports 22 is less than 0.1 / cm ² , the amount of fuel supplied to the fuel cells 1 cannot be made sufficiently uniform. Even if the number of the fuel discharge ports 22 exceeds 10 / cm ² , no further effect can be obtained.

  The fuel released from the fuel distribution mechanism 2 is supplied to the anode 5 of the fuel cell 1 as described above. In the fuel cell 1, the fuel diffuses through the anode gas diffusion layer 10 and the anode porous layer 9 and is supplied to the anode catalyst layer 8. When methanol fuel is used as the liquid fuel, an internal reforming reaction of methanol shown in the following formula (1) occurs in the anode catalyst layer 8. When pure methanol is used as the methanol fuel, the water generated in the cathode catalyst layer 11 and the water in the electrolyte membrane 7 are reacted with methanol to cause the internal reforming reaction of the formula (1).

_{CH 3 OH + H 2 O →} CO 2 + 6H + + 6e - (1)
Electrons (e ⁻ ) generated by this reaction are guided to the outside via a current collector, and are operated to a cathode (air electrode) 6 after operating a portable electronic device or the like as so-called electricity. In addition, protons (H ⁺ ) generated by the internal reforming reaction of the formula (1) are guided to the cathode 6 through the electrolyte membrane 7. Air is supplied to the cathode 6 as an oxidant. Electrons (e ⁻ ) and protons (H ⁺ ) that have reached the cathode 6 react with oxygen in the air according to the following equation (2) in the cathode catalyst layer 11, and water is generated along with this reaction.

6e ⁻ + 6H ⁺ + (3/2) O ₂ → 3H ₂ O (2)
In the fuel cell of the present embodiment, the fuel distribution mechanism 2 having the plurality of fuel discharge ports 22 is applied as described above. The liquid fuel introduced into the fuel distribution mechanism 2 is guided to the plurality of fuel discharge ports 22 via the gaps 24. Since the gap 24 of the fuel distribution mechanism 2 functions as a buffer, fuel of a specified concentration is discharged from the plurality of fuel discharge ports 22. Since the plurality of fuel discharge ports 22 are arranged so that fuel is supplied to the entire surface of the fuel cell 1, the amount of fuel supplied to the fuel cell 1 can be made uniform.

  Further, in the fuel cell according to the present embodiment, the droplet contact angle of the first surface of the anode porous layer 9 is 100 to 140 degrees, and the droplet contact angle of the second surface of the anode porous layer 9 is. Is less than 100 degrees and smaller than the droplet contact angle of the first surface. Therefore, when water generated in the cathode catalyst layer 11 by power generation diffuses into the anode catalyst layer 8 through the electrolyte membrane 7, the generated water is diffused into the anode. Infiltration to the layer 8 can be prevented at the first face of the anode porous layer 9. As a result, (i) the water retention amount of the anode catalyst layer 8 can be increased, (ii) the fluctuation of the water retention amount can be reduced, and (iii) the fuel is distributed by the water that has passed through the anode diffusion layer 10. Since the liquid fuel in the mechanism 2 and the fuel storage unit 3 can be prevented from being diluted, a high output can be maintained over a long period of time.

  The reason why the droplet contact angle is limited to the above range will be described. When the droplet contact angle on the first surface is less than 100 degrees, the generated water held in the anode catalyst layer 8 permeates the anode diffusion layer 10 through the anode porous layer 9 and further passes through the anode diffusion layer 10. As a result, the liquid fuel is diluted with the liquid fuel in the fuel distribution mechanism 2 and the fuel storage unit 3, and the output is reduced. On the other hand, if the droplet contact angle of the first surface exceeds 140 degrees, water becomes difficult to penetrate into the anode porous layer 9, excessive water is retained in the anode catalyst layer 8, and the catalytic reaction is inhibited. A decrease in output occurs. A more preferable range of the droplet contact angle on the first surface is 110 to 130 degrees.

  In addition, when the droplet contact angle on the second surface exceeds 100 degrees or becomes larger than the first surface, it becomes difficult for water to penetrate into the anode porous layer 9, and excessive water flows into the anode catalyst layer 8. The output is lowered because the catalytic reaction is inhibited. A more preferable range of the droplet contact angle on the second surface is 70 to 90 degrees.

  In the fuel cell cathode porous layer 12, the droplet contact angle on the third surface is set to 100 to 140 degrees, the droplet contact angle on the fourth surface is 100 degrees or less, and the droplets on the third surface It is preferable to make it smaller than the contact angle. By using such a cathode 6, water generated in the cathode catalyst layer 11 can be efficiently conveyed to the anode catalyst layer 8. Moreover, it is possible to prevent the generated water from staying in the cathode diffusion layer 13. As a result, both output efficiency and output maintenance rate can be improved.

  The reason why the droplet contact angle is limited to the above range will be described. When the droplet contact angle on the third surface is less than 100 degrees, the water retained in the cathode catalyst layer 11 permeates the cathode diffusion layer 13 through the cathode porous layer 12, and therefore the oxidizing agent in the cathode diffusion layer 13. Gas diffusion is hindered and output is reduced. On the other hand, when the droplet contact angle on the third surface exceeds 140 degrees, the amount of water discharged through the cathode porous layer 12 to the outside decreases, and conversely, water accumulates on the surface of the cathode catalyst layer 13 and oxygen Since the supply of is obstructed, the output decreases. A more preferable range of the droplet contact angle on the third surface is 110 to 130 degrees.

  Further, when the droplet contact angle of the fourth surface exceeds 100 degrees or becomes larger than the third surface, water is easily retained in the cathode porous layer 12, and the supply of oxygen is hindered. Output decreases. A more preferable range of the droplet contact angle on the fourth surface is 70 to 90 degrees.

  The anode porous layer 9 and the cathode porous layer 12 are produced, for example, by the method described below. Porous layers 9 and 12 are obtained by applying a slurry containing carbon material particles and polytetrafluoroethylene (PTFE) to carbon paper as a substrate by a spray coating method and drying. The contact angle of the surfaces of the porous layers 9 and 12 can be adjusted by the blending amount of PTFE.

  The fuel cell applicable to the present invention is an active type fuel cell in which liquid fuel and oxidant are supplied by using an auxiliary device such as a pump, and a passive type (internal) that supplies vaporized components of liquid fuel to the anode. (Vaporization type) fuel cell, semi-passive type fuel cell shown in FIGS. The active fuel cell employs a system in which a fuel made of an aqueous methanol solution is supplied to the anode of the MEA while being adjusted by a pump so that the amount thereof is constant, and air is also supplied to the cathode by a pump. In the passive type fuel cell, a system in which vaporized methanol is naturally supplied to the anode of the MEA and natural air is also supplied to the cathode and no extra equipment such as a pump is provided. In the semi-passive type fuel cell, the fuel supplied from the fuel storage part to the membrane electrode assembly is used for the power generation reaction, and is not circulated thereafter and returned to the fuel storage part. The semi-passive type fuel cell is different from the active type because it does not circulate the fuel, and does not impair downsizing of the apparatus. Further, the semi-passive type fuel cell uses a pump for supplying fuel, and is different from a pure passive type such as an internal vaporization type. In this semi-passive type fuel cell, a fuel cutoff valve may be arranged in place of the pump as long as fuel is supplied from the fuel storage portion to the membrane electrode assembly. In this case, the fuel cutoff valve is provided to control the supply of liquid fuel through the flow path.

  As the liquid fuel, a methanol aqueous solution or a direct methanol type using pure methanol is used, but is not limited thereto. For example, ethanol fuel such as an ethanol aqueous solution or pure ethanol, dimethyl ether, formic acid, or other liquid fuel may be used. In any case, liquid fuel corresponding to the fuel cell is accommodated.

[Example]
Embodiments of the present invention will be described below with reference to the drawings.

Example 1
First, carbon paper (TGP-H-030-120 manufactured by Toray Industries, Inc.) was compressed with a flat plate press in the thickness direction until the thickness became 1/2. In addition, the porosity before compression of this carbon paper was 75% when measured using the Archimedes method. Moreover, the porosity after compression of this carbon paper was 40.5% as a result of calculating by external dimension and weight measurement. This carbon paper was used as an anode gas diffusion layer.

  Next, 8.0% by weight of carbon particles (manufactured by vulcan) and PTFE having a blending amount shown in Table 1 below were mixed to prepare a slurry having a solid content ratio of about 13%. The obtained slurry was applied to both surfaces of carbon paper (TGP-H-030-120 manufactured by Toray Industries, Inc.) by a spray coating method to form an anode porous layer. In addition, by changing the amount of PTFE in the slurry applied to one surface of the carbon paper and the amount of PTFE in the slurry applied to the other surface as shown in Table 1 below, the surface facing the catalyst layer ( The droplet contact angle of the first surface) and the droplet contact angle of the surface facing the diffusion layer (second surface) were set as shown in Table 1 below.

  Further, a slurry was prepared by mixing carbon (Ketjen Black) and a nafion (registered trademark) solution (trade name manufactured by DuPont is DE2020, solid content ratio is about 15%). The obtained slurry was applied on a substrate by a bar coating method to form a carbon electrolyte membrane.

  1 part by weight of Nafion (registered trademark) solution (trade name DE2020 manufactured by DuPont) is added to 10 parts by weight of carbon particles carrying platinum ruthenium alloy fine particles, and a solvent is added and mixed with a homogenizer. About 15% of a slurry was prepared as follows, and this was applied onto a carbon electrolyte membrane by a die coater spray coating method and dried to form an anode catalyst layer.

  On the other hand, carbon paper (TGP-H-030-120 manufactured by Toray Industries, Inc.) was compressed with a flat plate press in the thickness direction until the thickness became 1/2. In addition, the porosity before compression of this carbon paper was 75% when measured using the Archimedes method. Moreover, the porosity after compression of this carbon paper was 40.5% as a result of calculating by external dimension and weight measurement. This carbon paper was used as a cathode gas diffusion layer.

  Next, 7.0% by weight of carbon particles (manufactured by vulcan) and PTFE having a blending amount shown in Table 1 below were mixed to prepare a slurry having a solid content ratio of about 13%. The obtained slurry was applied to both surfaces of carbon paper (TGP-H-030-120 manufactured by Toray Industries, Inc.) by a spray coating method to form a cathode porous layer. In addition, by changing the amount of PTFE in the slurry applied to one surface of the carbon paper and the amount of PTFE in the slurry applied to the other surface as shown in Table 1 below, the surface facing the catalyst layer ( The droplet contact angle on the third surface) and the droplet contact angle on the surface facing the diffusion layer (fourth surface) were set as shown in Table 1 below.

  A carbon particle carrying platinum fine particles, a Nafion solution (Du Pont's product name is DE2020) and a solvent are mixed with a homogenizer to prepare a slurry of about 15% solids, and this is coated on a carbon electrolyte membrane by a die coater spray coating method. And dried to form a cathode catalyst layer.

The anode porous layer and the anode diffusion layer were laminated on the anode catalyst layer laminated on the electrolyte membrane, and the cathode porous layer and the cathode diffusion layer were laminated on the cathode catalyst layer laminated on the electrolyte membrane. These were pressed under conditions of a temperature of 150 ° C. and a pressure of 30 kgf / cm ² to produce a membrane electrode assembly (MEA). The electrode area was 12 cm ² for both the cathode and anode.

  Subsequently, the membrane / electrode assembly was sandwiched between gold foils having a plurality of openings for taking in air and vaporized methanol to form an anode conductive layer and a cathode conductive layer.

  The laminate in which the membrane electrode assembly (MEA), the anode conductive layer, and the cathode conductive layer were laminated was sandwiched between two resin frames. A rubber O-ring was sandwiched between the cathode side of the membrane electrode assembly and one frame, and between the anode side of the membrane electrode assembly and the other frame, respectively.

  The anode-side frame was fixed to the liquid fuel storage chamber with screws through a gas-liquid separation membrane. As the gas-liquid separation membrane, a silicone sheet having a thickness of 0.1 mm was used. On the other hand, a porous plate having a porosity of 30% was arranged on the air electrode side frame to form a moisture retaining layer. On this moisturizing layer, a stainless steel plate (SUS304) with a thickness of 2 mm formed with air inlets (4 mm diameter, 64 holes) for air intake is arranged to form a surface cover layer and screwed Fixed by.

  5 ml of pure methanol was injected into the liquid fuel storage chamber of the fuel cell formed as described above, and the initial output and the output after 2000 hours were measured in an environment of a temperature of 25 ° C. and a relative humidity of 50%. The results are shown in Table 1 below.

(Examples 2-4 and Comparative Examples 1-2)
By changing the amount of PTFE blended in the slurry as shown in Table 1 below, the droplet contact angles of the first and second surfaces of the anode porous layer and the third surface of the cathode porous layer A fuel cell having the same configuration as described in Example 1 was manufactured except that the droplet contact angle on the fourth surface was set to the values shown in Table 1 below, and the output performance was measured. .

  As is clear from Table 1, the droplet contact angle on the first surface is 100 to 140 degrees, the droplet contact angle on the second surface is 100 degrees or less, and the droplet contact angle on the first surface In the fuel cells of Examples 1 to 4 having a smaller anode porous layer, the output after 2000 hours has the same droplet contact angle between the first surface and the second surface. The droplet contact angle of the second surface is higher than that of the fuel cell of Comparative Example 2 which is larger than that of the first surface. In particular, the fuel cell of Example 1 in which the droplet contact angle of the first surface of the anode porous layer and the third surface of the cathode porous layer is 110 to 130 degrees is compared with Examples 2 to 4. The output after 2000 hours is high.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined. Also, in the active type fuel cell and the semi-passive type fuel cell, the same effect as described above can be obtained. The liquid fuel vapor supplied to the MEA may be all supplied as a liquid fuel vapor, but the present invention can be applied even when a part of the liquid fuel vapor is supplied in a liquid state.

The schematic diagram for demonstrating the method to measure the contact angle of the surface of the porous layer used for the fuel cell which concerns on this embodiment. The schematic diagram for demonstrating the method to measure the contact angle of the surface of the porous layer used for the fuel cell which concerns on this embodiment. The schematic diagram for demonstrating the method to measure the contact angle of the surface of the porous layer used for the fuel cell which concerns on this embodiment. The schematic diagram for demonstrating the method to measure the contact angle of the surface of the porous layer used for the fuel cell which concerns on this embodiment. 1 is an internal perspective sectional view showing a fuel cell according to an embodiment of the present invention. The perspective view which shows the fuel distribution mechanism of the fuel cell of FIG. The expanded sectional view of the membrane electrode assembly of the fuel cell of FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Fuel cell (MEA), 2 ... Fuel distribution mechanism, 3 ... Fuel accommodating part, 4 ... Flow path, 5 ... Anode, 6 ... Cathode, 7 ... Electrolyte membrane, 8 ... Anode catalyst layer, 9 ... Anode porous Layer, 9a ... porous substrate, 9b, 9c ... conductive porous layer, 10 ... anode gas diffusion layer, 11 ... cathode catalyst layer, 12 ... cathode porous layer, 12a ... porous substrate, 12b, 12c ... Conductive porous layer, 13 ... cathode gas diffusion layer, 14 ... conductive layer, 15 ... cover plate, 16 ... O-ring, 17 ... pump, 21 ... fuel inlet, 22 ... fuel outlet, 23 ... fuel distribution plate, 24: void portion.

Claims (2)

A fuel cell comprising a cathode, an anode, and an electrolyte membrane interposed between the cathode and the anode,
The anode includes an anode catalyst layer laminated on the electrolyte membrane, an anode porous layer laminated on the anode catalyst layer, and an anode diffusion layer laminated on the anode porous layer,
The anode porous layer has a droplet contact angle of 100 to 140 degrees on the surface facing the anode catalyst layer, a droplet contact angle on the surface facing the anode diffusion layer is 100 degrees or less, and the A fuel cell characterized by being smaller than a droplet contact angle on a surface facing an anode catalyst layer. The cathode includes a cathode catalyst layer laminated on the electrolyte membrane, a cathode porous layer laminated on the cathode catalyst layer, and a cathode diffusion layer laminated on the cathode porous layer,
The cathode porous layer has a droplet contact angle of 100 to 140 degrees on the surface facing the cathode catalyst layer, a droplet contact angle on the surface facing the cathode diffusion layer is 100 degrees or less, and the 2. The fuel cell according to claim 1, wherein the fuel cell has a smaller droplet contact angle on the surface facing the cathode catalyst layer.

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