JP7089611B1 - Method for manufacturing an electrolyte membrane for a direct methanol fuel cell and a direct methanol fuel cell - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for manufacturing a direct methanol fuel cell and an electrolyte membrane for a direct methanol fuel cell capable of improving OCV. A DMFC 3 includes a cathode 31, an anode 32 to which a fuel containing methanol is supplied, and an electrolyte membrane 33 including a ceramic material having ionic conductivity and an organic polymer material having insulating properties. Measurement coordinates plotted on the XY coordinate plane with the unit volume surface area of the ceramic material in the disintegration film 33 as the X-axis and the rate of CO2 production at the cathode by methanol penetrating the electrolyte film from the anode to the cathode on the Y-axis. X, Y) is located on the line segment of the first line segment represented by Y = 0.01e1200X or to the right of the first line segment, and is on the line segment of the second line segment represented by Y = 2.5 or the second line segment. It is located below the line segment and is located on the line of the third line segment L3 represented by Y = 0.01 or above the third line segment. [Selection diagram] Fig. 3

Description

The present invention relates to a method for manufacturing a direct methanol fuel cell and an electrolyte membrane for a direct methanol fuel cell.

As a kind of fuel cell, a direct methanol fuel cell (DMFC) using methanol as a fuel is known.

Conventionally, a solid polymer electrolyte composed of Nafion (DuPont, registered trademark), which is a perfluorosulfonic acid-based polymer, has been widely used as an electrolyte for a DMFC. There is a problem that the dimensional change is large in.

Therefore, Patent Document 1 proposes an electrolyte membrane in which a hydrocarbon-based polyelectrolyte and a support made of polytetrafluoroethylene are composited. However, the electrolyte membrane of Patent Document 1 has a problem of low durability because a polymer electrolyte is used.

Therefore, Patent Document 2 proposes an electrolyte membrane in which a ceramic material having ionic conductivity and a support composed of an insulating organic polymer material are composited.

Japanese Unexamined Patent Publication No. 2010-232158 International Publication No. 2019/12431

However, when the electrolyte membrane described in Patent Document 2 is used, there is a problem that the OCV (open circuit voltage) is low. As a result of diligent studies by the present inventors, one reason for the low OCV is that when water (H ₂ O) is adsorbed on the hydrophilic hydroxyl group (-OH) existing on the surface of the ceramic material, the ceramic material and the organic material. It was found that the gap with the polymer material could not be narrowed sufficiently and the fuel methanol permeated through the electrolyte membrane.

The present invention has been made based on the above-mentioned novel findings, and an object of the present invention is to provide a method for manufacturing a direct methanol fuel cell and an electrolyte membrane for a direct methanol fuel cell capable of improving OCV.

The direct methanol fuel cell according to the present invention includes a cathode to which an oxidizing agent is supplied, an anode to which a fuel containing methanol is supplied, a ceramic material having ionic conductivity, and an organic polymer material having insulating properties. , With an electrolyte membrane disposed between the anode and cathode. The unit volume surface area is X on the XY coordinate plane with the unit volume surface area of the ceramic material in the electrolyte film as the X axis and the Y axis as the production rate of CO ₂ generated at the cathode by methanol that permeates the electrolyte film from the anode to the cathode. When plotting measurement coordinates (X, Y) with coordinates and generation speed as Y coordinates, the measurement coordinates (X, Y) are on the first line segment shown by Y = ^0.01e 1200X or the first line segment. Located on the more right side, on the line of the second line segment represented by Y = 2.5 or below the second line segment, on the line of the third line segment L3 represented by Y = 0.01, or at the third line. It is located above the line segment.

According to the present invention, it is possible to provide a method for manufacturing a direct methanol fuel cell and an electrolyte membrane for a direct methanol fuel cell capable of improving OCV.

It is a schematic diagram which shows an example of the structure of the DMFC system which concerns on embodiment. It is a semi-logarithmic graph which shows the relationship between the unit volume surface area of the ceramic material of DMFC which concerns on embodiment, and the CO ₂ generation rate. Sample No. according to the examples. It is a semi-logarithmic graph which shows the relationship between the unit volume surface area of 1 to 42 ceramic materials, and the CO ₂ generation rate.

(Configuration of direct methanol fuel cell system 1)
FIG. 1 is a schematic diagram showing a configuration of a direct methanol fuel cell system (hereinafter, abbreviated as “DMFC system”) 1.

The DMFC system 1 includes a housing 2 and a direct methanol fuel cell (hereinafter, abbreviated as "DMFC") 3.

(Housing 2)
The housing 2 houses the DMFC 3 inside.

The housing 2 has an oxidant supply unit 21 and a fuel supply unit 22 inside. The oxidant supply unit 21 and the fuel supply unit 22 are separated by DMFC3.

The oxidant supply unit 21 supplies an oxidant containing oxygen (O ₂ ) to the cathode 31, which will be described later. As the oxidizing agent, it is preferable to use air, and it is more preferable that the air is humidified. The oxidant supply unit 21 has a supply pipe 21a, a supply space 21b, and a discharge pipe 21c. The oxidant introduced from the supply pipe 21a is supplied to the cathode 31 in the supply space 21b. The oxidant that is not consumed in the cathode 31 is discharged to the outside from the discharge pipe 21c.

The fuel supply unit 22 supplies fuel containing methanol (CH ₃ OH) to the anode 32, which will be described later, during the operation of the DMFC 3. The methanol contained in the fuel may be in a gas phase state, a liquid phase state, or a mixed state of the gas phase and the liquid phase. The fuel supply unit 22 has a supply pipe 22a, a supply space 22b, and a discharge pipe 22c. The fuel introduced from the supply pipe 22a is supplied to the anode 32 in the supply space 22b. The fuel not consumed in the anode 32 and the carbon dioxide (CO ₂ ) and water (H ₂ O) generated in the anode 32 are discharged to the outside from the discharge pipe 22c.

(DMFC3)
The DMFC3 is an example of a direct methanol fuel cell. DMFC3 is a kind of alkaline fuel cell (AFC: Alkaline Fuel Cell) having a hydroxide ion as a carrier. The DMFC 3 includes a cathode 31, an anode 32, and an electrolyte membrane 33.

DMFC3 can generate electricity at a relatively low temperature (for example, 50 ° C. to 250 ° C.) based on the following electrochemical reaction formula.

・ Cathode 31: 3 / 2O ₂ + 3H ₂ O + 6e ^－ → 6OH ^－
・ Anode 32: CH ₃ OH + ^6OH- → ^6e- + CO ₂ + 5H ₂ O
・ Overall: CH ₃ OH + 3 / 2O ₂ → CO ₂ + 2H ₂ O

1. 1. Cathode 31
The cathode 31 is an anode generally called an air electrode. During the power generation of the DMFC 3, an oxidizing agent containing oxygen (O ₂ ) is supplied to the cathode 31 from the oxidizing agent supply unit 21. The cathode 31 is a porous body capable of diffusing an oxidizing agent inside. The porosity of the cathode 31 is not particularly limited. The thickness of the cathode 31 is not particularly limited, but may be, for example, 10 to 200 μm.

The cathode 31 is not particularly limited as long as it contains a known air electrode catalyst used in an alkaline fuel cell. Examples of cathode catalysts include group 8-10 elements (IUPAC format periodic table) such as platinum group elements (Ru, Rh, Pd, Ir, Pt) and iron group elements (Fe, Co, Ni). ~ Group 10 elements), Group 11 elements such as Cu, Ag, Au (elements belonging to Group 11 in the periodic table in the IUPAC format), rhodium phthalocyanine, tetraphenylporphyrin, Co salen, Ni salen (salen = N, N'-bis (salicylidene) ethylenediamine), silver nitrate, and any combination thereof. The amount of the catalyst supported on the cathode 31 is not particularly limited, but is preferably 0.05 to 10 mg / cm ² , more preferably 0.05 to 5 mg / cm ² . The cathode catalyst is preferably supported on carbon. Preferred examples of the cathode 31 are platinum-supported carbon (Pt / C), platinum-cobalt-supported carbon (PtCo / C), palladium-supported carbon (Pd / C), rhodium-supported carbon (Rh / C), and nickel-supported carbon (Ni). / C), copper-supported carbon (Cu / C), and silver-supported carbon (Ag / C).

The method for producing the cathode 31 is not particularly limited, but for example, an air electrode catalyst and, if desired, a carrier are mixed with a binder to prepare a paste-like mixture, and the paste-like mixture is applied to the cathode side surface 33S of the electrolyte membrane 33. Can be formed by.

2. 2. Anode 32
The anode 32 is a cathode generally called a fuel electrode. During the power generation of the DMFC 3, fuel containing methanol is supplied to the anode 32 from the fuel supply unit 22. The anode 32 is a porous body capable of diffusing methanol inside. The porosity of the anode 32 is not particularly limited. The thickness of the anode 32 is not particularly limited, but may be, for example, 10 to 500 μm.

The anode 32 may include a known anode catalyst used in an alkaline fuel cell, and is not particularly limited. Examples of anode catalysts include metal catalysts such as Pt, Ni, Co, Fe, Ru, Sn, and Pd. The metal catalyst is preferably supported on a carrier such as carbon, but may be in the form of an organic metal complex having a metal atom of the metal catalyst as a central metal, or the organic metal complex may be supported as a carrier. Further, a diffusion layer made of a porous material or the like may be arranged on the surface of the anode catalyst. Preferred examples of the anode 32 are nickel, cobalt, silver, platinum-supported carbon (Pt / C), platinum ruthenium-supported carbon (PtRu / C), palladium-supported carbon (Pd / C), and rhodium-supported carbon (Rh / C). , Nickel-supported carbon (Ni / C), copper-supported carbon (Cu / C), and silver-supported carbon (Ag / C).

The method for producing the anode 32 is not particularly limited, but for example, a paste-like mixture is prepared by mixing an anode catalyst and, if desired, a carrier with a binder, and the paste-like mixture is applied to the anode-side surface 33T of the electrolyte membrane 33. Can be formed.

3. 3. Electrolyte membrane 33
The electrolyte membrane 33 is arranged between the cathode 31 and the anode 32. The electrolyte membrane 33 has a cathode side surface 33S in contact with the cathode 31 and an anode side surface 33T in contact with the anode 32.

The electrolyte membrane 33 is formed in the form of a film, a layer, or a sheet. The thickness of the electrolyte membrane 33 is not particularly limited, but can be, for example, 5 to 100 μm.

The thickness of the electrolyte membrane 33 is measured as follows. First, using an FE-SEM (Field Emission Scanning Electron Microscope) using an in-lens secondary electron detector, the cross section of the electrolyte membrane 33 along the thickness direction is enlarged at a magnification of 1000 times. Acquire the SEM image. Next, the thickness of the electrolyte membrane 33 is measured at three points on the SEM image that divide the electrolyte membrane 33 into four equal parts in the plane direction (direction perpendicular to the thickness direction), and the arithmetic average value thereof is taken as the thickness of the electrolyte membrane 33. do.

The electrolyte membrane 33 includes a ceramic material having hydroxide ion conductivity and an organic polymer material having insulating properties.

The ceramic material is dispersed in the organic polymer material. Ceramic materials are supported by organic polymer materials.

The content of the ceramic material in the electrolyte membrane 33 can be 8 to 75 vol%. The average particle size of the ceramic particles constituting the ceramic material can be 0.05 to 5 μm.

The content of the ceramic material is measured as follows. First, by classifying the brightness of the above-mentioned SEM image into 256 gradations, the difference in brightness between the ceramic material, the organic polymer material, and the pores is quantified. For example, the ceramic material can be displayed in light gray, the organic polymer material can be displayed in dark gray, and the pores can be displayed in black. Next, using the image analysis software HALCON manufactured by MVTec (Germany), an analysis image in which the ceramic material is highlighted on the SEM image is acquired. Next, the area occupancy of the ceramic material is calculated by dividing the total area of the ceramic material by the total area of the solid phase (ceramic material and organic polymer material). Further, the above analysis was performed at 5 locations randomly specified from the same cross section of the electrolyte membrane 33, and the arithmetic mean value of the area occupancy of the ceramic material calculated at each of the 5 locations is the value of the ceramic material in the electrolyte membrane 33. The content rate.

The content of the ceramic material is the ratio of the total volume of the ceramic material to the total volume of the solid phase constituting the electrolyte film 33, which is close to the area ratio of the ceramic material per unit area in the cross section of the electrolyte film 33. be able to. In this way, for the method of estimating the three-dimensional structure from the two-dimensional structure, see "Yasuyasu Mizutani, Yoshiharu Ozaki, Toshio Kimura, Takashi Yamaguchi," Ceramic Processing ", Gihodo Publishing Co., Ltd., March 25, 1985. Issued, pp. 190-201 ”.

The average particle size of the ceramic particles is a circle of 20 ceramic particles randomly selected on the TEM image by observing the above-mentioned cross section of the electrolyte film 33 with a TEM (transmission electron microscope) at a magnification of 5000 to 50,000 times. It is obtained by arithmetically averaging the equivalent diameters. The equivalent circle diameter is the diameter of a circle having the same area as each ceramic particle.

As the ceramic material, a well-known ceramic material having hydroxide ion conductivity can be used. Examples of such a ceramic material include layered double hydroxides (LDH) described below.

LDH is M ²⁺ _1-x M ³⁺ _x (OH) ₂ A ^n- x / n · mH ₂ O (in the formula, M ²⁺ is a divalent cation, M ³⁺ is a trivalent cation, and A ^n- is an n-valent anion, n is an integer of 1 or more, x is 0.1 to 0.4, and m is an arbitrary integer meaning the number of moles of water). Have. Examples of M ²⁺ include Mg ²⁺ , Ca ²⁺ , Sr ²⁺ , Ni ²⁺ , Co ²⁺ , Fe ²⁺ , Mn ²⁺ , and Zn ²⁺ , and examples of M ³⁺ include Al ³⁺ , Fe ³⁺ , Ti ³⁺ , Examples include Y ³⁺ , Ce ³⁺ , Mo ³⁺ , and Cr ³⁺ , and examples of An ⁻ include CO ₃ ^2- and OH ⁻ . As M ²⁺ and M ³⁺ , one type may be used alone or two or more types may be used in combination.

LDH is composed of a plurality of hydroxide basic layers and an intermediate layer interposed between the plurality of hydroxide basic layers. The middle layer is composed of anions and _H2O . The hydroxide basic layer contains, for example, Ni, Al, Ti and OH groups when the metal M is Ni, Al, Ti. Hereinafter, the case where the hydroxide basic layer of LDH contains Ni, Al, Ti and OH groups will be described.

Ni in LDH can take the form of nickel ions. Nickel ions in LDH are typically considered to be Ni ²⁺ , but are not particularly limited as other valences such as Ni ³⁺ are possible. Al in LDH can take the form of aluminum ions. Aluminum ions in LDH are typically considered to be Al ³⁺ , but are not particularly limited as other valences are possible. Ti in LDH can take the form of titanium ions. Titanium ions in LDH are typically considered to be Ti ⁴⁺ , but are not particularly limited as other valences such as Ti ³⁺ are possible. The hydroxide basic layer preferably contains Ni, Al, Ti and OH groups as main constituent elements, but may contain other elements or ions, or may contain unavoidable impurities. The unavoidable impurity is an arbitrary element that can be unavoidably mixed in the production method, and can be mixed in LDH, for example, derived from a raw material or a base material.

The middle layer of LDH is composed of anions and _H2O . The anion is a monovalent or higher anion, preferably a monovalent or divalent ion. Preferably, the anions in ^LDH contain OH ^- and / or CO _3-2- .

As mentioned above, since the valences of Ni, Al and Ti are not always fixed, it is impractical or impossible to specify LDH strictly by a general formula. Assuming that the basic hydroxide layer is mainly composed of Ni ²⁺ , Al ³⁺ , Ti ⁴⁺ and OH groups, LDH is expressed by the general formula: Ni ²⁺ _1-xy Al ³⁺ _x Ti ⁴⁺ _y (OH). ) 2A ^n- _{(x + 2y) / n} · mH ₂ O ( _In the formula, Ann- is an n-valent anion, ⁿ is an integer of 1 or more, preferably 1 or 2, and 0 <x <1, preferably. 0.01 ≦ x ≦ 0.5, 0 <y <1, preferably 0.01 ≦ y ≦ 0.5, 0 <x + y <1, m is 0 or more, typically more than 0 or 1 or more It can be expressed by the basic composition (which is a real number of). However, the above general formula should be understood as "basic composition" to the extent that elements such as Ni ²⁺ , Al ³⁺ , and Ti ⁴⁺ do not impair the basic characteristics of LDH, and other elements or ions (of the same element). It should be understood as replaceable with elements or ions of other valences or elements or ions that can be unavoidably mixed in the process.

Organic polymer materials support ceramic materials. The organic polymer material functions as a support that retains the shape of the electrolyte membrane 33.

Organic polymer materials have insulating properties. The fact that the organic polymer material has an insulating property means that the organic polymer material has both electron insulating property and ionic insulating property.

The fact that the organic polymer material has electron insulation means that the electron conductivity of the organic polymer material is 10 ^-4 mS / cm or less. The electron conductivity of an organic polymer material can be measured by attaching terminals with platinum paste to a test piece of the organic polymer material cut into a strip shape by processing it into a sheet shape and measuring the DC resistance.

The fact that the organic polymer material has ionic insulation means that the ionic conductivity of the organic polymer material (in this embodiment, the hydroxide ionic conductivity) is ^10-5 mS / cm or less. The ionic conductivity of the organic polymer material can be measured by measuring the AC resistance of the test piece described above.

As the organic polymer material, a well-known organic polymer material having an insulating property can be used. Examples of such organic polymer materials include polystyrene, polyether sulfone, polypropylene, epoxy resin, polyphenylene sulfide, fluororesin (tetrafluororesin: PTFE, etc.), cellulose, nylon, polyethylene, polyimide, polyvinylidene fluoride. , Polybenzoimidazole, polyamide-imide and any combination thereof.

The content of the organic polymer material in the electrolyte membrane 33 can be 25 to 92 vol%. The content of the organic polymer material is a value obtained by arithmetically averaging the area occupancy of the organic polymer material measured at five points according to the method for measuring the content of the ceramic material described above.

(Manufacturing method of electrolyte membrane 33)
Next, a method for manufacturing the electrolyte membrane 33 will be described.

1. 1. Moisture removal process First, a ceramic material is prepared as one of the raw materials.

The ceramic material is then heat treated to remove moisture from the ceramic material. Specifically, the ceramic material is put into a dryer, heated at 50 to 300 ° C. for 1 to 24 hours in a low humidity environment with a relative humidity of 6% or less using dry air, nitrogen, etc., and then dried as it is. Let the temperature drop inside. As a result, the water adsorbed on the hydroxyl group existing on the surface of the ceramic material is removed, and the water is suppressed from being re-adsorbed when the temperature is lowered.

The value of the water content (water content per unit surface area) obtained by dividing the water content contained in the ceramic material after the heat treatment by the specific surface area of the ceramic material is preferably 1.0 mg / m ² or less, preferably 0.8 mg / m ² or less. Is more preferable. The amount of water contained in the ceramic material is measured at 100 ° C. using a heat-drying type moisture meter (manufactured by A & D Co., Ltd., model MX-50). The specific surface area of the ceramic material is measured using a BET specific surface area measuring device (manufactured by MICROTRRAC, model BELSORP MR1).

2. 2. Film formation step Next, an electrolyte film is formed using a mixture of the heat-treated ceramic material and an organic polymer material having insulating properties.

In the present embodiment, at least a part of the water adsorbed on the hydroxyl group existing on the surface of the ceramic material is removed in the above-mentioned water removal step. Therefore, when the electrolyte film 33 is formed by using a mixture of the ceramic material and the organic polymer material, the ceramic material and the organic polymer are compared with the case where the water adsorbed on the hydroxyl group of the ceramic material is not removed. The gap with the material can be narrowed. As a result, it is possible to prevent water from entering the gap between the ceramic material and the organic polymer material, so that it is possible to prevent water from being adsorbed on the hydroxyl groups existing on the surface of the ceramic material during the operation of DMFC3. As a result, it is possible to prevent the methanol supplied to the anode 32 from being transmitted to the cathode 31 side through the water content in the electrolyte membrane 33, so that the methanol permeability of the electrolyte membrane 33 can be reduced.

The method for forming the electrolyte film is not particularly limited, but for example, the simple dispersion method described below can be used.

First, a varnish is prepared by dissolving an organic polymer in a solvent. The solvent may be any solvent that can dissolve the organic polymer and can be evaporated after the film formation. Examples of the solvent include aprotonic polar solvents such as N, N-dimethylformamide, N, N-dimethylacetamide, N-methyl-2-pyrrolidone and dimethylsulfoxide, or ethylene glycol monomethyl ether, ethylene glycol monoethyl ether and propylene glycol monomethyl. Alkylene glycol monoalkyl ethers such as ether and propylene glycol monoethyl ether, halogen-based solvents such as dichloromethane and trichloroethane, and alcohols such as i-propyl alcohol and t-butyl alcohol can be used.

The mixture is then prepared by mixing the ceramic material with the prepared varnish. As a method for mixing the varnish and the ceramic material, for example, a stirrer method, a ball mill method, a jet mill method, a nanomill method, ultrasonic waves and the like can be used.

Next, the electrolyte film 33 can be produced by forming a film of a mixture of the varnish and the ceramic material on the substrate and then evaporating the solvent. The substrate may be any as long as the electrolyte membrane 33 can be peeled off after film formation, and for example, a glass plate, a polytetrafluoroethylene sheet, a polyimide sheet, or the like can be used. As a method for forming a film of the mixture, for example, a dip coating method, a spray coating method, a roll coating method, a doctor blade method, a gravure coating method, a screen printing method and the like can be used.

It is preferable that the film forming step is carried out promptly in a low humidity environment so that moisture is not adsorbed again on the ceramic material after the heat treatment.

(Characteristics of DMFC3)
FIG. 2 shows the surface area per unit volume of the ceramic material contained in the electrolyte membrane 33 (hereinafter, abbreviated as “unit volume surface area”) and the electrolyte membrane 33 permeated from the anode 32 to the cathode 31 during the operation of the DMFC 3. It is a one-sided logarithm graph which shows the relationship with the production rate of CO ₂ produced from methanol (hereinafter, abbreviated as "CO ₂ production rate").

FIG. 2 shows an XY coordinate plane with the unit volume surface area of the ceramic material as the X-axis, the logarithm of the CO ₂ generation rate as the Y-axis, and the origin (X, Y) as (0,0.01). .. The X-axis is a linear scale and the Y-axis is a logarithmic scale. The value on the X-axis increases toward the right, and the value on the Y-axis increases toward the top.

The unit volume surface area of a ceramic material is measured as follows. First, based on the number of ceramic particles observed on the above-mentioned SEM image, the thickness of the above-mentioned electrolyte membrane 33, and the average particle size of the above-mentioned ceramic particles, the ceramic particles existing in the 1 mm ³ electrolyte membrane 33 Calculate the number. Next, the surface area of one ceramic particle is calculated based on the average particle size of the ceramic particles described above. Next, the total surface area of the ceramic particles existing in the 1 mm ³ electrolyte membrane 33 is calculated by multiplying the number of ceramic particles existing in the 1 mm ³ electrolyte membrane 33 by the surface area of one ceramic particle. The calculated total surface area is the unit volume surface area of the ceramic material according to the present embodiment. Unit The unit of volume surface area is [m ² / mm ³ ].

The CO ₂ generation rate is measured as follows. First, during the operation of DMFC3, the amount of CO ₂ (μmol) generated from methanol at the cathode 31 is measured with a multi-gas analyzer (manufactured by HORIBA, Ltd., model V-5000). Next, when an oxidizing agent containing carbon dioxide is supplied to the cathode 31, the amount of CO ₂ (μmol) contained in the oxidizing agent is subtracted from the measured amount of CO ₂ (μmol). Next, the measured (or calculated) amount of CO ₂ (μmol) is divided by the area (cm ² ) and the measurement time (sec) of the cathode side surface 33S of the electrolyte membrane 33. As a result, the CO ₂ generation rate is calculated. The unit of CO ₂ generation rate is [μmol / scm ² ].

The specific surface area of the ceramic particles constituting the ceramic material contained in the electrolyte membrane 33 tends to increase toward the lower right on the XY coordinate plane of FIG. The filling rate of the ceramic particles constituting the ceramic material contained in the electrolyte membrane 33 tends to increase toward the upper right on the XY coordinate plane of FIG. When moving downward on the XY coordinate plane of FIG. 2, the water adsorbed on the hydroxyl groups present on the surface of the ceramic material contained in the electrolyte membrane 33 tends to decrease.

On the XY coordinate plane of FIG. 2, the first to sixth line segments L1 to L6 represented by the following equations (1) to (6) and the first defined by the first to sixth line segments L1 to L6. To the fourth regions R1 to R4 are illustrated.

Y = ^0.01e 1200X ... Equation (1)
Y = 2.5 ・ ・ ・ Equation (2)
Y = 0.01 ・ ・ ・ Equation (3)
X = 0.0035 ・ ・ ・ Equation (4)
X = 0.25 ・ ・ ・ Equation (5)
Y = 0.01e ^5X ... Equation (6)

The first line segment L1 represented by the formula (1) is a line that defines a range in which the OCV (open circuit voltage) of the DMFC 3 can be improved. In the range on the line of the first line segment L1 and on the right side of the first line segment L1, the particle size of the ceramic particles is small and the filling rate is high. Therefore, a hydroxide ion conduction path can be formed in the electrolyte membrane 33. Therefore, the OCV of DMFC3 can be improved.

The second line segment L2 represented by the formula (2) is a line that defines a range in which the OCV of DMFC3 can be improved. In the range on the line of the second line segment L2 or below the second line segment L2, since the water adsorbed on the hydroxyl group of the ceramic material is small, the gap between the ceramic material and the organic polymer material can be narrowed. .. Therefore, during the operation of DMFC3, it is possible to suppress the adsorption of water on the hydroxyl groups existing on the surface of the ceramic material, so that the methanol permeability of the electrolyte membrane 33 can be reduced. Therefore, the OCV of DMFC3 can be improved.

The third line segment L3 represented by the formula (3) is a line indicating the lower limit of the methanol permeability assumed in the electrolyte membrane 33.

The fourth line segment L4 represented by the formula (4) is a line that defines a range in which the OCV of DMFC3 can be further improved. In the range on the line of the fourth line segment L4 and on the right side of the fourth line segment L4, the particle size of the ceramic particles is smaller and the filling rate is also higher. Therefore, a hydroxide ion conduction path can be sufficiently formed in the electrolyte membrane 33. Therefore, the OCV of DMFC3 can be further improved.

The fifth line segment L5 represented by the formula (5) is a line that defines a range in which the strength of the electrolyte membrane 33 can be improved. In the range on the line segment L5 and on the left side of the fifth line segment L5, it is possible to prevent the particle size of the ceramic particles from becoming too small or the filling rate from becoming too high, so that the surface area becomes too high. It can be suppressed. Therefore, the strength of DMFC3 (specifically, the electrolyte membrane 33) can be improved.

The sixth line segment L6 represented by the formula (6) is a line that defines a range in which the strength of the electrolyte membrane 33 can be further improved. In the range on the line of the sixth line segment L6 and above the sixth line segment L6, it is possible to suppress that the particle size of the ceramic particles becomes too small, so that it is possible to suppress that the surface area becomes too high. Therefore, the strength of DMFC3 (specifically, the electrolyte membrane 33) can be further improved.

Since the XY coordinate plane of FIG. 2 shows the unit volume surface area of the ceramic material on the X-axis with a linear scale and the CO ₂ generation rate on the Y-axis with a logarithmic scale, the first to sixth lines. Each of the minutes L1 to L6 is a straight line. If the unit volume surface area of the ceramic material is shown on the X-axis with a linear scale and the CO ₂ generation rate is shown on the Y-axis with a linear scale, each of the first and sixth line segments L1 and L6 becomes a curve.

The first region R1 is defined by the equations (1), (2), (4) to (6). The first region R1 has a point A (0.0035,0.6), a point B (0.0046,2.5), a point C (0.25,2.5), and a point D (0.25,0). .035), a pentagonal region with a point E (0.0035, 0.01) as the apex. In the first region R1, the first line segment L1, the second line segment L2, the fourth to sixth line segments L4 to L6 are on each line, and the range surrounded by these line segments L1, L2, L4 to L6. And are included.

The second region R2 is defined by the equations (3), (5) and (6). The second region R2 is a triangular region having a point D (0.25, 0.035), a point F (0.0, 0.01), and a point G (0.25, 0.01) as vertices. .. The second region R2 includes on each of the third line segment L3, the fifth line segment L5, and the sixth line segment L6, and the range surrounded by these line segments L3, L5, and L6.

The third region R3 is defined by the equations (2), (3) and (5). The third region R3 is a region extending to the right side toward the infinity direction of the X axis, and only a part thereof is shown in FIG. The third region R3 includes on each of the second line segment L2, the third line segment L3, and the fifth line segment L5, and the range inside these line segments L2, L3, and L5.

The fourth region R4 is defined by the equations (1), (3) and (4). The fourth region R4 is a triangular region having points A (0.0035, 0.6), F (0.0, 0.01), and H (0.0035, 0.01) as vertices. .. The fourth region R4 is surrounded by the lines of the first line segment L1, the fifth line segment L5, and the sixth line segment L6, and by the first line segment L1, the fifth line segment L5, and the sixth line segment L6. The range and is included.

Here, when the unit volume surface area of the ceramic material and the CO ₂ generation rate are measured by the above method for DMFC 3 according to the present embodiment, the measured value of the unit volume surface area of the ceramic material is used as the X coordinate to measure the CO ₂ generation rate. The position of the measured coordinates (X, Y) when the value is the Y coordinate will be described.

In the XY coordinate plane of FIG. 2, the measurement coordinates (X, Y) are located on the line of the first line segment L1 or to the right of the first line segment L1 and on the line of the second line segment L2 or from the second line segment L2. It is located on the lower side and on the line of the third line segment L3 or above the third line segment L3. That is, the measurement coordinates (X, Y) are located in any of the first to fourth regions R1 to R4. As a result, as confirmed experimentally in the examples described later, the OCV of DMFC3 is reduced as compared with the case where the measurement coordinates (X, Y) are located in regions other than the first to fourth regions R1 to R4. Can be improved.

Further, the measurement coordinates (X, Y) are preferably located on the line of the fourth line segment L4 or on the right side of the fourth line segment L4. That is, the measurement coordinates (X, Y) are preferably located in any of the first to third regions R1 to R3. As a result, as confirmed experimentally in the examples described later, the OCV of the DMFC3 can be further improved as compared with the case where the measurement coordinates (X, Y) are located in the fourth region R4.

Further, the measurement coordinates (X, Y) are preferably located on the line of the fifth line segment L5 or on the left side of the fifth line segment L5. That is, the measurement coordinates (X, Y) are preferably located in any of the first region R1, the second region R2, and the fourth region R4. As a result, as confirmed experimentally in the examples described later, the DMFC3 (specifically, the electrolyte membrane 33) is compared with the case where the measurement coordinates (X, Y) are located in the third region R3. The strength can be improved.

Further, the measurement coordinates (X, Y) are preferably located on the line of the sixth line segment L6 or above the sixth line segment L6. That is, the measurement coordinates (X, Y) are preferably located in any of the first region R1 and the fourth region R4. As a result, as confirmed experimentally in the examples described later, the DMFC3 (specifically, the electrolyte membrane 33) has a measurement coordinate (X, Y) as compared with the case where the measurement coordinates (X, Y) are located in the second region R2. The strength can be further improved.

The unit volume surface area of the ceramic material, which is the X coordinate of the measurement coordinates (X, Y), can be adjusted by controlling the content of the ceramic material and the specific surface area of the ceramic particles constituting the ceramic material. The higher the content of the ceramic material, the larger the unit volume surface area of the ceramic material. Further, the larger the specific surface area of the ceramic particles, the larger the unit volume surface area of the ceramic material.

The CO ₂ generation rate, which is the Y coordinate of the measurement coordinates (X, Y), can be adjusted by controlling the amount of water contained in the ceramic material according to the heat treatment conditions applied to the ceramic material in advance. The higher the heat treatment temperature, the lower the CO ₂ generation rate. Further, the longer the heat treatment time, the lower the CO ₂ generation rate.

(Modified example of the embodiment)
The present invention is not limited to the above embodiments, and various modifications or changes can be made without departing from the scope of the present invention.

(Modification 1)
In the above embodiment, as an example of the DMFC, the DMFC3 which is an alkaline fuel cell having a hydroxide ion as a carrier has been described, but the DMFC is not limited to this.

The DMFC may be a fuel cell having a proton as a carrier. In this case, an electrolyte membrane containing a ceramic material having proton conductivity and an organic polymer material having insulating properties may be used.

As the ceramic material having proton conductivity, a metal oxide hydrate having proton conductivity or the like can be used. Examples of such metal oxide hydrates include zirconium oxide hydrate, monohydrated aluminum oxide (bemite), tungsten oxide hydrate, tin oxide hydrate, niobium-doped tungsten oxide, and silicon oxide water. Japanese products, oxidized phosphoric acid hydrate, zirconium-doped silicon oxide hydrate, tongue strinic acid, molybdrine acid and the like can be used.

As organic polymer materials, perfluorocarbon sulfonic acid, polystyrene, polyether ketone, polyether ether ketone, polysulfone, polyether sulfone, and other engineering plastic materials are provided with protons such as sulfonic acid group, phosphonic acid group, and carboxyl group. A body doped or chemically bonded and immobilized can be used.

(Modification 2)
In the above embodiment, the case where the DMFC 3 is used as a single battery has been described, but a stack in which a plurality of DMFC 3s are stacked may be configured.

Examples of the present invention will be described below. However, the present invention is not limited to the examples described below.

(Preparation of DMFC3)
As follows, sample No. DMFC3 according to 1-42 was produced.

First, the ceramic materials shown in Table 1 were prepared.

Next, the ceramic material was put into a dryer and heated at a relative humidity of 6% or less using dry air, nitrogen, or the like to remove water adsorbed on the hydroxyl groups existing on the surface of the ceramic material. At this time, by changing the heat treatment conditions within the range of 50 to 300 ° C. and 1 to 24 hours, Table 1 shows the water content obtained by dividing the water content contained in the ceramic material after the heat treatment by the specific surface area of the ceramic material. Adjusted for each sample as shown.

Next, a varnish was prepared by dissolving the insulating organic polymer shown in Table 1 in N-methyl-2-pyrrolidone.

Next, the varnish and the ceramic material were weighed so that the contents of the ceramic material and the organic polymer became the values shown in Table 1, and the two were mixed by the stirrer method to prepare a mixture.

Next, the prepared mixture was formed into a film on a release film by a doctor blade method, and then subjected to a drying treatment (80 ° C., 1 hour) to evaporate N-methyl-2-pyrrolidone. As a result, the electrolyte membrane 33 was completed.

Next, platinum-supported carbon (hereinafter referred to as "Pt / C") and PVDF powder (hereinafter referred to as "PVDF binder") having a Pt-supported amount of 50 wt% (TEC10E50E manufactured by Tanaka Kikinzoku Kogyo Co., Ltd.) are prepared. did. Then, Pt / C, PVDF binder and water are mixed so that the weight ratio of (Pt / C): (PVDF binder): (water) is 9 wt%: 0.9 wt%: 90 wt%, and the paste for the cathode is used. Was produced.

Next, the cathode 31 was formed by applying a cathode paste to the cathode side surface 33S of the electrolyte membrane 33.

Next, a platinum ruthenium-supported carbon (hereinafter referred to as "Pt-Ru / C") having a Pt-Ru loading amount of 54 wt% (TEC61E54 manufactured by Tanaka Kikinzoku Kogyo Co., Ltd.) and a PVDF binder were prepared. Then, Pt-Ru / C, PVDF binder and water are added so that the weight ratio of (Pt-Ru / C): (PVDF binder): (water) is 9 wt%: 0.9 wt%: 90 wt%. The mixture was mixed to prepare a paste for an anode.

Next, the anode 32 was formed by applying the anode paste to the anode-side surface 33T of the electrolyte membrane 33. As a result, the sample No. DMFC3 according to 1-42 was completed.

(Cross section observation of electrolyte membrane 33)
According to the measurement method described above, the content of the ceramic material, the unit volume surface area of the ceramic material, and the content of the organic polymer material were measured.

(OCV and CO ₂ generation rate)
First, the DMFC 3 was installed in the housing 2 shown in FIG.

Next, the cell temperature was set to 80 ° C., humidified air humidified in dry air having a dew point of 0 ° C. or lower was supplied to the oxidant supply unit 21, and vaporized methanol was supplied to the fuel supply unit 22. The air utilization rate at the cathode 31 was adjusted to 50%, and the fuel utilization rate at the anode 32 was adjusted to 50%.

Next, the cathode 31 and the anode 32 were supplied with air and methanol in an open circuit state for 1 hour without being electrically connected to the external circuit, and then the potential difference (OCV) between the cathode 31 and the anode 32 was measured. The measurement results are as shown in Table 1. In Table 1, the sample No. having the highest OCV value. The OCV value standardized with the OCV value of 5 as 1.00 is shown.

Further, while supplying air and methanol, the amount of CO ₂ (μmol) generated from methanol at the cathode 31 was measured with a multi-gas analyzer (manufactured by Horiba Seisakusho Co., Ltd., model V-5000), and the measured CO was measured. The CO ₂ generation rate was calculated by dividing ₂ quantities (μmol) by the area (cm ² ) and the measurement time (sec) of the cathode side surface 33S of the electrolyte membrane 33. The measurement results are as shown in Table 1.

(Intensity evaluation of DMFC3)
The intensity of DMFC3 was evaluated by the following method. According to the test method of JISZ1707, DMFC3 was sandwiched between a plate having a hole of Φ10 mm, and the maximum breaking load when cracked by piercing the center of the hole with a needle of Φ0.5 mm was measured. In Table 1, a sample having a maximum load of 0.2 N or more is evaluated as “○”, a sample having a maximum load smaller than 0.2 N and 0.15 N or more is evaluated as “Δ”, and a maximum load is evaluated. Samples with a value less than 0.15 N were evaluated as "x".

FIG. 3 shows the sample No. A semi-logarithm in which the measured coordinates (X, Y) in which the measured value of the unit volume surface area of the ceramic material according to 1 to 42 is the X coordinate and the measured value of the CO ₂ generation rate is the Y coordinate are plotted on the XY coordinate plane of FIG. It is a graph.

As shown in Table 1, in the XY coordinate plane of FIG. 3, the measurement coordinates (X, Y) are located on the line of the first line segment L1 or to the right of the first line segment L1 and on the line of the second line segment L2 or. Sample No. 1 located below the second line segment L2 and on the line of the third line segment L3 or above the third line segment L3. In 2 to 12, 14 to 16, 20, 22 to 34, 38 to 41, the OCV of DMFC3 could be improved.

Further, as shown in Table 1, in the XY coordinate plane of FIG. 3, the measurement coordinates (X, Y) are located on the line of the fourth line segment L4 or on the right side of the fourth line segment L4. In 2 to 12, 14 to 15, 17, 20, 22 to 29, 31 to 34, 38 to 41, the OCV of DMFC3 could be further improved.

Further, as shown in Table 1, in the XY coordinate plane of FIG. 3, the sample No. 1 whose measurement coordinates (X, Y) are located on the line of the 5th line segment L5 or on the left side of the 5th line segment L5. In 2 to 6,8 to 12, 14 to 16, 20, 22 to 26, 29 to 34, 38 to 41, the strength of DMFC3 could be improved while improving the OCV of DMFC3.

Further, as shown in Table 1, among the samples for which the intensity of DMFC3 could be improved, the measurement coordinates (X, Y) are on the line of the sixth line segment L6 or on the sixth line in the XY coordinate plane of FIG. Sample No. located on the left side of the minute L6. In 2 to 6, 11 to 12, 14 to 16, 20, 22 to 26, 30 to 34, 38 to 41, the strength of DMFC3 could be further improved while improving the OCV of DMFC3.

1 Direct methanol fuel cell system (DMFC system)
2 Housing 21 Oxidizing agent supply unit 22 Fuel supply unit 3 Direct methanol fuel cell (DMFC)
31 Cathode 32 Anode 33 Electrolyte membrane

Claims (6)

The cathode to which the oxidant is supplied and
With the anode to which fuel containing methanol is supplied,
An electrolyte membrane, which comprises a ceramic material having ionic conductivity and an organic polymer material having insulating properties, and is arranged between the anode and the cathode.
Equipped with
In the XY coordinate plane with the unit volume surface area of the ceramic material in the electrolyte membrane as the X-axis and the production rate of CO ₂ generated at the cathode by the methanol permeating the electrolyte membrane from the anode to the cathode as the Y-axis. When plotting measurement coordinates (X, Y) with the unit volume surface area as the X coordinate and the generation speed as the Y coordinate,
The measured coordinates (X, Y) are
Located on the line segment of the first line segment represented by Y = ^0.01e 1200X or to the right of the first line segment.
It is located on the line segment of the second line segment represented by Y = 2.5 or below the second line segment.
Located on the line of the third line segment L3 represented by Y = 0.01 or above the third line segment.
Direct methanol fuel cell. The measured coordinates (X, Y) are
Located on the line segment of the 4th line segment represented by X = 0.0035 or on the right side of the 4th line segment.
The direct methanol fuel cell according to claim 1. The measured coordinates (X, Y) are
Located on the line segment of the 5th line segment represented by X = 0.25 or on the left side of the 5th line segment.
The direct methanol fuel cell according to claim 1 or 2. The measured coordinates (X, Y) are
Located on the line segment of the 6th line segment represented by Y = 0.01e ^5X or above the 6th line segment.
The direct methanol fuel cell according to claim 3. A water removal step of removing water from the ceramic material by heat-treating the ceramic material having ion conductivity.
A film forming process for forming an electrolyte film using a mixture of the ceramic material from which water has been removed and an organic polymer material having insulating properties, and a film forming process.
A method for manufacturing an electrolyte membrane for a direct methanol fuel cell. In the water removal step, the ceramic material is heat-treated until the water content obtained by dividing the amount of water contained in the ceramic material by the specific surface area of the ceramic material becomes 1.0 mg / m ² or less.
The method for manufacturing an electrolyte membrane for a direct methanol fuel cell according to claim 5.

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