JP2009289681A - Method of cleaning fuel cell - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method of cleaning a fuel cell, by which platinum precipitated in the electrolyte membrane can be cleaned and removed, and which can improve durability of the fuel cell. <P>SOLUTION: This invention relates to the cleaning method of a fuel cell equipped with a membrane-electrode assembly having an electrolyte membrane, an anode electrode which is installed on one surface of the electrolyte membrane and contains at least platinum particles and a cathode electrode which is installed on the other surface of the electrolyte membrane and contains at least platinum particles. While applying on the platinum in the electrolyte membrane a high potential higher than a melting potential of platinum and a lower potential lower than the melting potential of platinum alternately, cleaning water is made to flow from the anode electrode side to the cathode electrode side or from the cathode electrode side to the anode electrode side in lamination direction of the membrane-electrode assembly. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a fuel cell cleaning method for removing platinum deposited in an electrolyte membrane.

  A fuel cell directly converts chemical energy into electrical energy by supplying fuel and an oxidant to two electrically connected electrodes and causing the fuel to be oxidized electrochemically. Unlike thermal power generation, fuel cells are not subject to the Carnot cycle, and thus exhibit high energy conversion efficiency. A fuel cell is usually formed by laminating a plurality of single cells having a basic structure of a membrane / electrode assembly in which an electrolyte membrane is sandwiched between a pair of electrodes. Among them, a solid polymer electrolyte fuel cell using a solid polymer electrolyte membrane as an electrolyte membrane has advantages such as easy miniaturization and operation at a low temperature. It is attracting attention as a power source for the body.

In the solid polymer electrolyte fuel cell, the reaction of the following formula (1) proceeds at the fuel electrode (anode).
H ₂ → 2H ⁺ + 2e ⁻ (1)
The electrons generated by the equation (1) reach the oxidant electrode (cathode) after working with an external load via an external circuit. Then, the proton generated in the formula (1) moves in the solid polymer electrolyte membrane from the fuel electrode side to the oxidant electrode side by electroosmosis while being hydrated with water.
On the other hand, the reaction of the following formula (2) proceeds at the oxidant electrode.
4H ⁺ + O ₂ + 4e ⁻ → 2H ₂ O (2)

The cathode potential may rise temporarily under the operating environment of the fuel cell, such as when the fuel gas is insufficient or when the fuel cell is idle. Due to such a change in cathode potential, platinum contained as an electrode catalyst in the catalyst layer of the oxidizer electrode is dissolved (Pt ²⁺ ). The generated platinum ions diffuse in the electrolyte membrane having proton conductivity and are reduced by the hydrogen gas diffused from the fuel electrode to become platinum atoms (Pt ²⁺ + H ₂ → Pt + 2H ⁺ ) It is known to precipitate in the film. The platinum atoms thus deposited serve as nuclei for platinum particle growth, and platinum particles are formed or aggregated in the film, and it is considered that platinum particles grow using the aggregates as nuclei.

In recent years, it has been found that the coexistence state of electrolyte, oxygen, hydrogen and platinum is a cause of deterioration of the fuel cell. That is, as described above, precipitation of platinum particles in the electrolyte membrane is one of the major factors that cause deterioration of the electrolyte membrane and other components of the fuel cell. It is considered that hydrogen gas is generated by the catalytic action of platinum when hydrogen gas diffuses from the fuel electrode side and oxygen gas diffuses from the oxidant electrode side while platinum is deposited in the electrolyte membrane. . Hydrogen peroxide has a strong oxidizing power and is a source of radicals such as a hydroxy radical having a strong oxidizing power, and is one of the causative substances that cause deterioration of fuel cell constituent materials such as electrolytes.
It has been reported that the coexistence state of electrolyte, oxygen, hydrogen, and platinum particles is formed in several tens of hours after the start of operation of the fuel cell depending on the type of the electrolyte membrane. Therefore, avoiding this coexistence has become a major issue.

  In Patent Document 1, by changing the position of a so-called platinum band formed by aggregation of platinum particles precipitated in an electrolyte membrane, local degradation of the electrolyte membrane is prevented, and the electrolyte membrane and the fuel cell stack A fuel cell cleaning method for improving the durability of the battery is described. Specifically, by changing the partial pressure ratio between the hydrogen gas and the oxygen gas, changing the differential pressure between the fuel electrode and the oxidant electrode, or changing the humidity of the oxygen gas and the hydrogen gas at a specified timing, A cleaning method for changing the position of a platinum band formed by aggregation of platinum particles in a solid polymer electrolyte membrane is described.

  On the other hand, a fuel cell system that cleans impurities contained in the reaction gas, ion components derived therefrom, and dirt that adversely affects the operation of the fuel cell has also been proposed. For example, Patent Document 2 discloses a fuel cell configured by stacking a plurality of single cells (single cells), humidifying means capable of humidifying the inside of the fuel cell for each of a plurality of regions, and a part of the plurality of regions. Describes a fuel cell system comprising a humidification control means for controlling the humidification means so as to temporarily reach an excessive humidity state. The technique described in Patent Document 2 generates condensed water by setting a part of the plurality of regions in the fuel cell to an excessively humidified state, that is, a state exceeding the saturation relative humidity. Is used to clean impurities in the fuel cell.

JP 2006-302578 A JP 2003-163023 A

However, in the method of Patent Document 1, it is possible to change the position where platinum particles are formed from platinum atoms, but it is not possible to change the position where platinum ions are reduced by hydrogen gas and platinum atoms are deposited. . Further, according to the knowledge of the present inventor, the effect of suppressing the deterioration of the electrolyte membrane by changing the position where the platinum particles grow is low. Furthermore, in the method of Patent Document 1, it is impossible to remove the coexistence state of the electrolyte, oxygen, hydrogen, and platinum particles in the electrolyte membrane because platinum cannot be removed from the electrolyte membrane.
In addition, the cleaning method using condensed water, a chelating agent, electroosmosis and the like represented by Patent Document 2 can remove ions and water-soluble low molecules from the fuel cell. The Pt atoms and particles deposited inside cannot be washed away.

  The present invention has been accomplished in view of the above circumstances, and an object of the present invention is to provide a fuel cell cleaning method capable of cleaning and removing platinum deposited in an electrolyte membrane and improving the durability of the fuel cell.

  The method for cleaning a fuel cell according to the present invention includes an electrolyte membrane, an anode electrode provided on one surface of the electrolyte membrane, and provided on the other surface of the electrolyte membrane, and at least platinum particles. A cleaning method for a fuel cell comprising a membrane / electrode assembly comprising a cathode electrode containing a high potential higher than a dissolution potential of platinum and lower than a dissolution potential of platinum in platinum in the electrolyte membrane. Washing water is allowed to flow from the anode electrode side to the cathode electrode side or from the cathode electrode side to the anode electrode side in the stacking direction of the membrane-electrode assembly while alternately applying a low potential. .

  According to the present invention, platinum deposited in the electrolyte membrane is provided by applying a potential cycle (hereinafter simply referred to as potential cycle) in which the high potential and the low potential are alternately applied to platinum deposited in the electrolyte membrane. Can be dissolved and ionized. Moreover, the produced | generated platinum ion can be removed from an electrolyte membrane by distribution | circulation of washing water.

  From the viewpoint of efficient platinum dissolution in the electrolyte membrane, the high potential is 0.75 V to 1.2 V (vs. SHE), and the low potential is 0 V to 0.60 V (vs. SHE). It is preferable. In particular, from the viewpoint of suppressing dissolution of platinum in the electrode, the high potential is preferably 0.9 V or less (vs. SHE).

As a specific aspect of the cleaning method according to the present invention, for example, an oxidizing gas is supplied to the anode electrode, and an oxidizing gas or an inert gas is supplied to the cathode electrode. Applying a high potential to platinum, supplying an inert gas or reducing gas to the anode electrode, and supplying a reducing gas to the cathode electrode, applying a low potential to platinum in the electrolyte membrane, There is a method of flowing cleaning water from the anode electrode side toward the cathode electrode side in the stacking direction of the membrane / electrode assembly (hereinafter, also referred to as method (A)). In this method (A), platinum ions can be moved to the cathode electrode by flowing cleaning water from the anode electrode side to the cathode electrode side. Part of the platinum ions that have moved to the cathode electrode side is reduced at the cathode electrode by applying a low potential in the above-described potential cycle, is precipitated as platinum, and can be restored as a cathode electrode catalyst again.
In the method (A), after supplying an inert gas to the anode electrode and the cathode electrode, a high potential is applied to platinum in the electrolyte membrane by replacing the anode electrode with an oxidizing gas, After supplying an inert gas to the anode electrode and the cathode electrode, the cathode electrode is replaced with a reducing gas, so that a high potential is applied to platinum in the electrolyte membrane. ) And oxygen (oxidizing gas) can be prevented from being directly mixed.

  As another specific aspect of the cleaning method according to the present invention, for example, a current is supplied from the membrane-electrode assembly while closing a gas flow path of the anode electrode and supplying an oxidizing gas to the cathode electrode. By pulling the reducing gas present in the anode electrode, a high potential is applied to platinum in the electrolyte membrane, the reducing gas is supplied to the anode electrode, and the gas flow path of the cathode electrode is closed. However, by drawing a current from the membrane-electrode assembly and consuming the oxidizing gas present in the cathode electrode, a low potential is applied to platinum in the electrolyte membrane, and the lamination of the membrane-electrode assembly is performed. There is a method of flowing cleaning water from the cathode electrode side to the anode electrode side in the direction (hereinafter also referred to as method (B)).

  According to the present invention, it is possible to remove platinum deposited on the electrolyte membrane, so that the generation of hydrogen peroxide in the electrolyte membrane can be suppressed. Therefore, according to the present invention, it is possible to prevent the deterioration of the constituent members of the membrane-electrode assembly, particularly the electrolyte membrane, caused by the hydrogen peroxide generated in the electrolyte membrane, and the durability of the fuel cell can be improved. It is. Furthermore, in the present invention, platinum deposited on the electrolyte membrane can be used again as an electrode catalyst by depositing it on the cathode electrode or the anode electrode. It is possible to improve the stability.

  The method for cleaning a fuel cell according to the present invention includes an electrolyte membrane, an anode electrode provided on one surface of the electrolyte membrane, and provided on the other surface of the electrolyte membrane, and at least platinum particles. A cleaning method for a fuel cell comprising a membrane / electrode assembly comprising a cathode electrode containing a high potential higher than a dissolution potential of platinum and lower than a dissolution potential of platinum in platinum in the electrolyte membrane. Washing water is allowed to flow from the anode electrode side to the cathode electrode side or from the cathode electrode side to the anode electrode side in the stacking direction of the membrane-electrode assembly while alternately applying a low potential. .

When the cathode potential rises due to fuel deficiency or the like and the cathode potential fluctuates, the platinum particles contained as the electrode catalyst in the cathode dissolve, and the generated platinum ions (Pt ²⁺ ) ^{enter the} electrolyte membrane due to the concentration gradient. Come on. The platinum ions in the electrolyte membrane are reduced by the hydrogen gas that has been supplied to the anode and diffused in the electrolyte membrane, and precipitate as platinum atoms. Each of the platinum atoms generated in the electrolyte membrane aggregates to form a stable nucleus, and the reduction of platinum ions proceeds on the surface of the nucleus, or the reduction of platinum ions proceeds on the surface of the platinum atoms. Platinum particles grow. Since the stability of the platinum particles increases as the grains grow, the larger the platinum particles are, the more difficult it is to dissolve. In the present invention, the platinum deposited in the electrolyte membrane is dissolved and ionized while the particle size is small, unstable and easily dissolved, thereby enabling washing and removal from the electrolyte membrane.

In the present invention, in order to dissolve (ionize) platinum deposited in the electrolyte membrane, a high potential higher than the dissolution potential of platinum and a lower potential lower than the dissolution potential of platinum are alternately applied to the platinum in the electrolyte membrane. Apply. By applying to the platinum in the electrolyte membrane such a high potential and low potential cycle that sandwiches such a dissolution potential of platinum, the platinum deposited in the electrolyte membrane can be efficiently dissolved.
Since the dissolution potential of platinum deposited on the electrolyte membrane differs depending on the environment of the electrolyte membrane, the radius of the platinum, etc., it is difficult to specify in general, but usually it is 0.75 V or higher as a higher potential than the dissolution potential of platinum. An electrolyte membrane is applied by applying a potential of 1.2 V or less (vs. SHE; hereinafter, the same is omitted) and applying a potential of 0 V or more and 0.60 V or less as a low potential lower than the dissolution potential of platinum. This makes it possible to efficiently dissolve platinum. Particularly preferably, the high potential is set to 0.75 V to 1.1 V, and more preferably, the high potential is set to 0.75 V to 1.0 V.

  The potential of platinum contained in the anode electrode and the cathode electrode also varies in accordance with the potential of platinum in the electrolyte membrane. Therefore, it is preferable to prevent dissolution of platinum contained in the anode electrode and the cathode electrode, particularly dissolution of platinum contained in the cathode electrode, when applying the potential cycle. The catalyst particles contained in the electrode usually have a particle size of about 3 to 30 nm. It is known that dissolution of platinum particles having such a particle size proceeds at 0.95 V or more. That is, by setting it to less than 0.95 V, dissolution of platinum particles contained in the electrode can be suppressed. From such a viewpoint, the high potential in the potential cycle is particularly preferably 0.9 V or less.

  The number of cycles of the potential cycle (one cycle for one high potential application and one cycle for low potential application) and the execution time of the potential cycle are appropriately determined depending on the amount of platinum deposited in the electrolyte membrane, the applied potential, the application time, etc. You only have to set it. The amount of platinum deposited in the electrolyte membrane varies depending on the operating conditions of the fuel cell, the amount of platinum supported on the catalyst layer, the electrolyte film thickness, and the like.

For example, the execution time of the potential cycle can be calculated as follows.
When the amount of platinum supported (weight per unit area) in the catalyst layer of the cathode electrode is 0.4 mg / cm ² and 10% of the platinum is deposited in the electrolyte membrane in 10 years, it is deposited in the electrolyte membrane in 10 years. platinum amount is ^{0.04mg / cm 2 = 4 × 10} -5 g / cm 2. At this time, the amount of platinum to be dissolved from the electrolyte membrane per day is [4 × 10 ⁻⁵ (g / cm ² )] / (365 × 10) = 1 × 10 ⁻⁸ g / cm ² .
On the other hand, the dissolution rate of platinum is 1.7 × 10 ⁻¹⁴ g / cm ² · s per platinum surface area when an electric potential is maintained at 0.9 V (Electrochem, and Solid-state Let., 9 (5 ) A225 (2006)). Further, the surface area of the average platinum particles used as the electrode catalyst is 70 m ² / g = 7 × 10 ⁵ cm ² / g, and assuming that the radius of the platinum particles deposited in the film is about this level, the electrode 1 cm ² The surface area of platinum deposited in the film is 7 × 10 ⁵ (cm ² / g) × 4 × 10 ⁻⁵ (g / cm ² ) = 28 (cm ² / cm ² ). Therefore, assuming that the platinum deposited in the film has the same radius as the average platinum particles used as the electrocatalyst, the time required for dissolution of platinum in the film is [(1 × 10 ⁻⁸ ) × 28] / [1.7 × 10 ⁻¹⁴ ] = 21000 s≈6 hours.
At this time, it is known that by applying a potential cycle, dissolution of platinum is promoted, and the time required for dissolution of platinum is about one order of magnitude (for example, J. ElectroChem. Soc., 152 (1) A242 (2005)). Moreover, as described above, platinum deposited in the film is extremely small compared to the platinum particles of the electrode catalyst. Therefore, it can be seen that the upper limit of the total time of the potential cycle performed on one day may be about 1 to 2 hours, and it is not an unrealistic value such as a few dozen hours. When a high potential is applied or a low potential is applied, a time required for dissolution of platinum (minimum of 1 minute) is usually required in addition to the time required for each gas to reach each electrode.

  In the present invention, the platinum ions generated by the potential cycle are washed away from the electrolyte membrane by flowing washing water through the membrane-electrode assembly. Specifically, at the same time as the potential cycle, flush water is allowed to flow from the anode electrode side to the cathode electrode side or from the cathode electrode side to the anode electrode side in the stacking direction of the membrane / electrode assembly. Thus, platinum ions generated in the electrolyte membrane can be sequentially washed away from the electrolyte membrane and removed.

When reducing gas is allowed to flow through the cathode electrode in the potential cycle (for example, the method (A) described later), platinum ions generated in the potential cycle are caused by flowing the cleaning water from the anode electrode side to the cathode electrode side. Are sequentially removed from the electrolyte membrane and move to the cathode electrode side. At this time, some of the platinum ions that have moved to the cathode electrode side are discharged together with the cleaning water to the outside of the membrane / electrode assembly through the gas flow path of the cathode electrode, while the other part is the cathode electrode. In the above-mentioned potential cycle, it is reduced and deposited by contact with a reducing gas (application of a low potential) in the potential cycle. That is, it can be used again as an electrode catalyst in the cathode electrode.
Similarly, when reducing gas is circulated through the anode electrode in the potential cycle (for example, method (B) described later), the cleaning water is generated in the potential cycle by flowing the cleaning water from the cathode electrode side to the anode electrode side. The platinum ions thus removed are sequentially removed from the electrolyte membrane and moved to the anode electrode side, and a part of the platinum ions is reduced by the contact with the reducing gas in the potential cycle (application of a low potential) and deposited at the anode electrode. To do. That is, it can be utilized again as an electrode catalyst in the anode electrode.
Since platinum deposited on the electrolyte membrane is considered to be derived from the cathode electrode, as described above, reducing gas is circulated to the cathode electrode in the potential cycle, and cleaning water is supplied from the anode electrode side to the cathode electrode side. It is considered that by flowing washing water into the cathode, platinum can be returned to the cathode electrode, and the power generation performance of the cathode electrode can be maintained.

Here, the stacking direction of the membrane / electrode assembly is the direction in which the anode electrode, electrolyte membrane, and cathode electrode constituting the membrane / electrode assembly are stacked, that is, the thickness direction of each electrode and membrane.
The method of flowing the cleaning water from the anode electrode toward the cathode electrode is not particularly limited. For example, the cleaning water is introduced into the anode electrode from one of the gas supply port and the gas discharge port of the anode electrode, and the supply port and the discharge port are supplied. By closing the other of these, the washing water introduced into the anode electrode flows to the cathode electrode side through the electrolyte membrane, and can be discharged out of the cell from the gas supply port or gas discharge port of the cathode electrode. Similarly, the method of flowing cleaning water from the cathode electrode toward the anode electrode is not particularly limited. For example, the cleaning water is introduced into the cathode electrode from either the gas supply port or the gas discharge port of the cathode electrode, and the supply port By closing the other of the discharge ports, the cleaning water introduced into the cathode electrode flows to the anode electrode side through the electrolyte membrane, and can be discharged out of the cell from the gas supply port or gas discharge port of the anode electrode. it can. Note that the cleaning water inlet and outlet may be provided separately without using the gas supply port and gas outlet.
Examples of the washing water include ion exchange water, sulfuric acid, nitric acid, and the like, and ion exchange water is preferable from the viewpoint of reducing residual ions after washing. The cleaning water may be supplied as a humidified gas to the membrane / electrode assembly and distributed in the stacking direction of the membrane / electrode assembly.

The flow rate of the washing water may be appropriately determined according to the applied potential and application time in the potential cycle, the amount of platinum deposited in the film, and the like.
For example, the flow rate of cleaning water can be calculated as follows.
It is known that the equilibrium concentration of platinum ions dissolved in 0.5 M H ₂ SO ₄ at 1.1 V is 3 × 10 ⁻⁶ mol / L (for example, J. ElectroChem. Soc., 152 ( 11) A2256 (2005)). In addition, the amount of platinum supported (weight per unit area) in the catalyst layer of the cathode electrode was 0.4 mg / cm ² = 2.05 × 10 ⁻⁶ mol / cm ² , and 10% of this was deposited in the electrolyte membrane in 10 years. In the case of operating conditions, the amount of platinum deposited in the electrolyte membrane in 10 years is 2 × 10 ⁻⁷ mol / cm ² . Assuming a fuel cell stack in which one cell has an electrode area of 333 cm ² and 400 cells are stacked, the amount of platinum deposited per day in the fuel cell stack is (2 × 10 ⁻⁷ mol / cm ² ) / (365 × 10) × (333 cm ² ) × (400 sheets) = 7.3 × 10 ⁻⁶ mol, and the environment inside the electrolyte membrane is strongly acidic. Therefore, the minimum amount of water necessary to dissolve this platinum is It can be calculated as (7.3 × 10 ⁻⁶ mol) / (3 × 10 ⁻⁶ mol / L) = 2.4 L.

As described above, according to the present invention, platinum deposited on the electrolyte membrane can be dissolved and washed away from the electrolyte membrane. Furthermore, platinum ions eluted from the electrolyte membrane can be deposited on the cathode electrode or the anode electrode and used again as an electrode catalyst.
Therefore, according to the present invention, the production of hydrogen peroxide due to the coexistence of platinum, oxygen and hydrogen in the electrolyte membrane can be suppressed. Therefore, according to the present invention, it is possible to prevent the deterioration of the constituent members of the membrane-electrode assembly, particularly the electrolyte membrane, caused by the hydrogen peroxide generated in the electrolyte membrane, and the durability of the fuel cell can be improved. It is. Furthermore, in the present invention, platinum deposited on the electrolyte membrane can be used again as an electrode catalyst by being deposited on the cathode electrode or the anode electrode, particularly the cathode electrode. The stability of power generation performance can be improved.

Here, first, a membrane / electrode assembly for a fuel cell to which the cleaning method of the present invention can be applied will be described with reference to the drawings.
FIG. 1 is a schematic cross-sectional view showing an embodiment of a single cell including a membrane / electrode assembly.
In FIG. 1, a single cell 100 has a membrane / electrode assembly 6 in which an anode electrode 2 and a cathode electrode 3 are provided on one surface side of a polymer electrolyte membrane (hereinafter sometimes referred to simply as an electrolyte membrane) 1. ing. The anode electrode 2 has a structure in which an anode side catalyst layer 4a and an anode side gas diffusion layer 5a are laminated in order from the electrolyte membrane 1 side. Similarly, the cathode electrode 3 has a structure in which a cathode side catalyst layer 4b and a cathode electrode side gas diffusion layer 5b are laminated in order from the electrolyte membrane 1 side.

  The membrane / electrode assembly 6 is sandwiched between two separators 7 a and 7 b to constitute a single cell 100. Each separator 7a, 7b is formed with a groove that forms a flow path for each reaction gas (fuel gas, oxidant gas), and a flow for supplying and discharging the reaction gas and the outermost surface of each electrode 2, 3. Paths 8a and 8b are defined. The flow path 8a on the fuel electrode side is a flow path for supplying fuel gas (a gas containing hydrogen or generating hydrogen) to the fuel electrode 2 and discharging unreacted fuel gas, and on the oxidant electrode side. The flow path 8b is a flow path for supplying an oxidant gas (a gas containing oxygen or generating oxygen) to the oxidant electrode 3 and discharging an unreacted portion of the oxidant gas.

In FIG. 1, each electrode has a structure in which a catalyst layer and a gas diffusion layer are laminated. In addition to the single layer structure consisting of only the catalyst layer, in addition to the catalyst layer and the gas diffusion layer, A structure provided with a functional layer may also be used.
Examples of the electrolyte membrane include fluorine-based electrolyte membranes such as perfluorocarbon sulfonic acid resin membranes typified by Nafion, hydrocarbon polymers such as polyether ketone, polyether ether ketone, and polyether sulfone, sulfonic acid groups, and phosphoric acid. Hydrocarbon electrolyte membranes or the like into which proton conductive groups such as groups and hydroxyl groups are introduced are used. However, hydrocarbon electrolyte membranes have lower gas permeability than fluorine electrolyte membranes, and hydrogen from the anode side. Since the gas permeability is low, the progress of platinum deposition in the electrolyte membrane is relatively slow. Therefore, it is preferable to use a hydrocarbon-based electrolyte membrane from the viewpoint of reducing the number of times of application of washing and removing platinum and improving the convenience of the fuel cell.

  The catalyst layer can be formed using a catalyst ink in which at least platinum particles as an electrode catalyst are dissolved and dispersed in a solvent. As the electrode catalyst, those commonly used in fuel cells can be used, and they have catalytic activity for hydrogen oxidation reaction at the fuel electrode and oxygen reduction reaction at the oxidant electrode. In addition to platinum particles, other than platinum particles may be used in combination.

The electrode catalyst is usually blended in the catalyst ink in a state where it is previously supported on conductive particles. This is because the dispersibility of the electrode catalyst can be ensured by including it in the catalyst ink in a state of being supported on conductive particles. There is also an advantage that the electron transfer property of the electrode catalyst is improved.
The electroconductive particle which carries an electrode catalyst will not be specifically limited if it has electroconductivity, Carbon particles, such as carbon black, etc. are mentioned. Since it has a surface area capable of supporting many electrode catalysts, carbon particles are preferably used, and carbon black is particularly preferable. Examples of carbon black include ketjen black, furnace black, channel black, lamp black, thermal black, and acetylene black.

  The catalyst ink can contain a polymer electrolyte for the purpose of imparting proton conductivity to the catalyst layer, fixing the electrode catalyst, and the like. As a polymer electrolyte, what is generally used as what comprises the electrolyte membrane of a fuel cell can be used without being restrict | limited especially, For example, what was illustrated as said electrolyte membrane is mentioned.

  Any catalyst ink may be used as long as it can prepare a catalyst ink in which an electrode catalyst is dispersed, in particular, a catalyst ink in which an electrode catalyst and a polymer electrolyte are dispersed. What is necessary is just to select suitably by etc. For example, alcohols such as methanol, ethanol, propanol, propylene glycol, N, N-dimethylformamide, N, N-diethylformamide, N, N-dimethylacetamide, N, N-diethylacetamide, or a mixture thereof A mixture with water can be used, but is not limited thereto.

  A catalyst layer can be formed on the electrolyte membrane or the gas diffusion layer by applying the catalyst ink to the surface of the electrolyte membrane or the gas diffusion layer sheet constituting the gas diffusion layer and drying. Alternatively, a catalyst layer transfer sheet is prepared by applying and drying catalyst ink on the surface of the transfer substrate, and the catalyst layer is transferred to the electrolyte membrane surface or the gas diffusion layer sheet surface using the catalyst layer transfer sheet. it can. The method for applying the catalyst ink is not particularly limited, and general methods such as an inkjet method, a spray method, a doctor blade method, a gravure printing method, and a die coating method can be used. The drying method of the catalyst ink is not particularly limited, and examples thereof include vacuum drying, heat drying, combined use of vacuum drying and heat drying.

  The gas diffusion layer sheet has gas diffusibility, conductivity, and a strength required as a material constituting the gas diffusion layer, for example, carbon paper, carbon cloth, which can efficiently supply gas to the catalyst layer. Carbonaceous porous bodies such as carbon felt, titanium, aluminum, copper, nickel, nickel-chromium alloy, copper and its alloys, silver, aluminum alloy, zinc alloy, lead alloy, titanium, niobium, tantalum, iron, stainless steel A conductive porous body such as a metal mesh or a metal porous body made of metal such as gold or platinum can be used. The gas diffusion layer sheet may be composed of a single layer of the conductive porous body as described above, but a water repellent layer may be provided on the side facing the catalyst layer. The water-repellent layer usually has a porous structure containing conductive particles such as carbon particles and carbon fibers, water-repellent resin such as polytetrafluoroethylene (PTFE), and the like. In addition, the conductive porous body is formed by impregnating and applying a water-repellent resin such as polytetrafluoroethylene to the side facing the catalyst layer with a bar coater or the like, so that the moisture in the catalyst layer is efficiently removed from the gas diffusion layer. It may be processed so as to be discharged well.

  The obtained electrolyte membrane-catalyst layer assembly is joined to the gas diffusion layer sheet, or the obtained gas diffusion layer-catalyst layer assembly is joined to the electrolyte membrane to produce a membrane / electrode assembly. can do.

Hereinafter, the procedure of the cleaning method of the present invention will be described in detail.
The specific method for giving the potential cycle to platinum deposited in the electrolyte membrane is not particularly limited, and examples thereof include the following two methods (A) and (B). Here, the methods (A) and (B) will be specifically described.
(A): An oxidizing gas is supplied to the anode electrode, and an oxidizing gas or an inert gas is supplied to the cathode electrode, whereby a high potential is applied to platinum in the electrolyte membrane, and the inert gas is supplied to the anode electrode. Alternatively, by supplying a reducing gas and supplying a reducing gas to the cathode electrode, a low potential is applied to platinum in the electrolyte membrane, and the cathode from the anode electrode side in the stacking direction of the membrane-electrode assembly A method of flowing cleaning water toward the electrode side.
(B): While closing the gas flow path of the anode electrode and supplying the oxidizing gas to the cathode electrode, the current is drawn from the membrane / electrode assembly, and the reducing gas present in the anode electrode is consumed, thereby providing an electrolyte. Applying a high potential to platinum in the membrane, supplying reducing gas to the anode electrode, and closing the gas flow path of the cathode electrode, drawing current from the membrane-electrode assembly, and oxidizing gas present in the cathode electrode A method in which a low potential is applied to platinum in the electrolyte membrane by consuming water, and washing water is caused to flow from the cathode electrode side to the anode electrode side in the stacking direction of the membrane-electrode assembly.

In the method (A), one of the anode electrode and the cathode electrode causes an oxidation gas reduction reaction, and the other electrode causes an oxidation gas reduction reaction, or an inert gas is supplied to oxidize the gas. It is utilized that the potential of platinum in the electrolyte membrane adjacent to the electrode is higher than the dissolution potential of platinum due to the potential of the electrode where the reduction reaction of the reactive gas occurs. Examples of the oxidizing gas include those containing at least one selected from oxygen, N ₂ O _{5 and the} like, and may be a mixed gas thereof, or a mixed gas with an inert gas such as nitrogen, argon or helium. But you can. From the viewpoint of simplification of the fuel cell system, air can be preferably used. Moreover, as an inert gas, what consists of at least 1 sort (s) chosen from nitrogen, argon, helium etc. is mentioned, It does not contain oxidizing gas and reducing gas.

  In the electrode supplied with the oxidizing gas, the reducing reaction of the oxidizing gas proceeds, and the potential becomes a high potential of 0.75V to 1.2V. When an oxygen-containing mixed gas such as air is supplied as the oxidizing gas, the oxidizing gas supply electrode has a high potential of about 1.2V. At this time, when the oxidizing gas is supplied also to the counter electrode opposite to the oxidizing gas supply electrode with the electrolyte membrane interposed therebetween, the potential of the counter electrode becomes high, so that the entire membrane / electrode assembly is in a high potential state, and the electrolyte A high potential can be applied to platinum in the film. In addition, when an inert gas is supplied to the counter electrode, no reaction occurs at the counter electrode, so that the potential of the electrolyte membrane is maintained at a high potential, and a high potential can be applied to platinum in the electrolyte membrane.

  In the method (A), one of the anode electrode and the cathode electrode causes an oxidation reaction of the reducing gas, and the other electrode also causes an oxidation reaction of the reducing gas, or by supplying an inert gas. Utilizing the fact that the potential of platinum in the electrolyte membrane adjacent to the electrode is lower than the dissolution potential of platinum due to the potential of the electrode where the oxidation reaction of the reducing gas occurs. An example of the reducing gas is hydrogen. In the electrode to which the reducing gas is supplied, the oxidation reaction of the reducing gas proceeds and becomes a low potential of 0.6 V or less. When hydrogen gas is supplied as the reducing gas, the reducing gas supply electrode has a low potential of about 0V. At this time, when reducing gas is supplied also to the counter electrode facing the reducing gas supply electrode across the electrolyte membrane, the potential of the counter electrode is also low, so the entire membrane / electrode assembly is in a low potential state, and the electrolyte A low potential can be applied to platinum in the film. In addition, when an inert gas is supplied to the counter electrode, no reaction occurs at the counter electrode, so that the potential of the electrolyte membrane can be maintained at a low potential, and a low potential can be applied to platinum in the electrolyte membrane. .

In the method (A), in order to prevent dissolution of platinum particles at the cathode electrode in the potential cycle, an oxidation gas is reduced only at the anode electrode, and an inert gas is supplied to the cathode electrode, whereby an electrolyte membrane is obtained. It is preferable to apply a high potential to the inner platinum.
In order to return platinum deposited in the electrolyte membrane to the cathode electrode, it is preferable to apply a low potential to the platinum deposited in the electrolyte membrane by causing an oxidation reaction of the reducing gas at least at the cathode electrode. That is, by setting the potential of the cathode electrode to a low potential, it is possible to promote the deposition of platinum on the cathode electrode.

  The combination of the oxidizing gas, reducing gas, and inert gas in (A) is not particularly limited. From the viewpoint of using the system during fuel cell operation, it is preferable to use hydrogen gas as the reducing gas and air as the oxidizing gas. Specifically, when a high potential is applied, both the cathode electrode and the anode electrode are opened to the atmosphere, and when a low potential is applied, a method of supplying hydrogen gas to the cathode electrode and the anode electrode can be mentioned.

  When applying a high potential, it is preferable to introduce the oxidizing gas into the anode electrode by adjusting the amount of the oxidizing gas introduced using the hydrogen circulation system of the fuel cell so as to moderate the rise in potential. By adjusting the supply amount of the hydrogen gas and the supply amount of the oxidizing gas by the hydrogen circulation system and gradually increasing the supply amount of the oxidizing gas, it is possible to prevent a rapid increase in potential. As a result, platinum that is easily dissolved such as platinum atoms and platinum fine particles in the electrolyte membrane can be selectively dissolved, and dissolution of platinum particles in the electrode can be suppressed.

  Further, as described above, the high potential applied to platinum in the electrolyte membrane is preferably controlled to 0.9 V or less. However, in (A), in order to control to 0.9 V or less, for example, an oxidizing gas is used. Examples thereof include a method in which a reducing gas such as hydrogen is mixed or a current is swept.

On the other hand, in the anode electrode, the fuel gas (hydrogen gas, etc.) supplied during fuel cell operation and the oxidizing gas when high potential is applied are mixed directly, or when oxidizing gas and low potential are applied when applying high potential. From the viewpoint of preventing direct mixing with a reducing gas, and the cathode electrode from the viewpoint of preventing direct mixing of an oxidizing gas when a high potential is applied and a reducing gas when a low potential is applied. It is preferable to supply gas to each electrode in such a procedure.
That is, supplying an inert gas to the anode electrode and the cathode electrode, filling each electrode with an inert gas, supplying an oxidizing gas to the anode electrode, and replacing the anode electrode with an oxidizing gas, A high potential is applied to platinum of the electrolyte membrane. Then, after supplying an inert gas to the anode electrode and the cathode electrode, filling each electrode with an inert gas, supplying a reducing gas to the cathode electrode, and replacing the cathode electrode with the reducing gas, It is preferable to apply a high potential to platinum of the electrolyte membrane.
As described above, by filling each electrode with an inert gas between application of a low potential and application of a high potential, oxidation of the carbonaceous material constituting each electrode can be prevented.

In the method (A), along with the supply of the gas, washing water is circulated from the anode electrode side to the cathode electrode side. The washing water dissolves the platinum ions generated in the electrolyte membrane and flushes it to the cathode electrode side. The platinum ions that have reached the cathode electrode together with the cleaning water are partly discharged together with the cleaning water from the gas supply port and gas discharge port of the cathode electrode to the outside of the cell, and the other part is reduced by applying a low potential. Precipitate. That is, platinum deposited on the electrolyte membrane can be used again as an electrode catalyst for the cathode electrode.
In (A), it is also possible to remove platinum ions generated in the electrolyte membrane from the membrane by flowing cleaning water from the cathode electrode side to the anode electrode side. However, in order to precipitate the washed-out platinum ions again with the electrode, it is effective to distribute the washing water from the anode electrode side to the cathode electrode side.

  In the method (A), as the method of flowing the washing water from the anode electrode side to the cathode electrode side, for example, the gas supplied to the anode electrode is supplied in a humidified state so as to be higher than the saturated vapor pressure at the cell temperature, and And a method in which the gas pressure on the anode electrode side is higher than the gas pressure on the cathode electrode side. According to this method, by raising the temperature of the humidifier that humidifies the gas supplied to the anode electrode to a dew point higher than the saturated vapor pressure at the cell temperature, water (washing water) supplied from the humidifier as water vapor is obtained. It can be condensed and liquefied in the cell. The liquefied water flows from the anode electrode side to the cathode electrode side using the difference in gas pressure between the anode electrode and the cathode electrode as a driving force.

Next, the method (B) will be described. In (B), since the same gas as (A) can be used for reducing gas, oxidizing gas, and inert gas, it is omitted here.
In the method (B), first, the gas flow of the anode electrode is closed and the oxidizing gas is supplied to the cathode electrode, and the current is drawn from the membrane / electrode assembly, so that the reducing gas is oxidized at the anode electrode. The reaction occurs and the reducing gas remaining on the anode electrode is consumed. The reducing gas consumed at this time is typically the residual amount of hydrogen gas derived from the fuel gas supplied during fuel cell operation or the reducing gas supplied when a low potential is applied. Since the gas flow path of the anode electrode is closed and no gas is supplied, the oxidizing gas supplied to the cathode electrode permeates toward the anode electrode as the remaining reducing gas is consumed.

  At this time, the reduction reaction of the oxidizing gas proceeds at the cathode electrode, and the potential becomes a high potential of 0.75 V to 1.2 V. When an oxygen-containing mixed gas such as air is supplied as the oxidizing gas, the oxidizing gas supply electrode has a high potential of about 1.2V. On the other hand, since the oxidizing gas permeates through the anode electrode, the reduction reaction of the oxidizing gas proceeds even at the anode electrode, and the whole membrane / electrode assembly becomes in a high potential state, and a high potential is applied to platinum in the electrolyte membrane. Can be applied. When the oxidizing gas supplied to the cathode electrode is a mixed gas containing an inert gas such as air, the inert gas that is not consumed by the cathode electrode permeates the anode electrode, and the anode electrode may not react. However, since the potential of the electrolyte membrane is kept at a high potential, a high potential can be applied to platinum in the electrolyte membrane.

  From the viewpoint of preventing oxidation of the carbonaceous material constituting each electrode, the anode electrode is preferably filled with an inert gas. Therefore, the oxidizing gas supplied to the cathode electrode is preferably an inert gas mixed gas such as air. From the same viewpoint, an inert gas may be supplied and the anode electrode may be filled with the inert gas without closing the gas flow path of the anode electrode.

  In addition, when the current is drawn from the membrane / electrode assembly while the gas flow path of the anode electrode is closed and the oxidizing gas is supplied to the cathode electrode, the hydrogen circulation of the fuel cell is stopped while the supply of hydrogen gas is stopped. By operating the system, the reducing gas concentration in the cell can be reduced uniformly. By making the concentration of hydrogen, which is a typical example of the reducing gas, uniform in the cell, oxidation of the carbonaceous material constituting the electrode can be suppressed.

  The application time of the high potential is performed until all the reducing gas sealed in the anode electrode is consumed, and the time can be obtained from the integrated current amount.

  In the method (B), the reducing gas is supplied to the anode electrode, and the gas is drawn from the membrane / electrode assembly while closing the gas flow path of the cathode electrode. The oxidizing gas remaining in the cathode electrode is consumed. The oxidizing gas consumed at this time is typically a residue of oxygen derived from an oxidant gas supplied during fuel cell operation or an oxidizing gas supplied when a high potential is applied. As the cathode electrode has a closed gas flow path and no gas is supplied, is the reducing gas supplied to the anode electrode permeated to the cathode electrode side as the oxidizing gas residue is consumed? Alternatively, the inert gas such as nitrogen remaining in the cathode electrode together with the oxidizing gas remains as it is.

At this time, the oxidation reaction of the reducing gas proceeds at the anode electrode, and the potential becomes a low potential of 0.6 V or less. When hydrogen gas is supplied as the reducing gas, the anode electrode has a low potential of about 0V. On the other hand, when the reducing gas permeates through the cathode electrode, the oxidizing reaction of the reducing gas proceeds even at the cathode electrode, and the entire membrane / electrode assembly becomes a low potential state, and the platinum in the electrolyte membrane has a low potential. Can be applied. When the reducing gas supplied to the anode electrode is a mixed gas containing an inert gas such as air, the inert gas that is not consumed by the cathode electrode remains, and the anode electrode may not react. Since the potential of the electrolyte membrane is kept at a low potential, a low potential can be applied to platinum in the electrolyte membrane.
From the viewpoint of preventing oxidation of the carbonaceous material constituting each electrode, the cathode electrode is preferably filled with an inert gas. Therefore, an inert gas mixed gas such as air is preferable as the oxidizing gas supplied to the cathode electrode when a high potential is applied. From the same point of view, the cathode electrode may be filled with an inert gas without closing the gas flow path of the cathode electrode.
The low potential application time is performed until all the oxidizing gas sealed in the cathode electrode is consumed, and the time can be obtained from the integrated current amount.

The combination of the oxidizing gas, reducing gas, and inert gas in (B) is not particularly limited. From the viewpoint of using the system during fuel cell operation, it is preferable to use hydrogen gas as the reducing gas and air as the oxidizing gas.
Specifically, when a high potential is applied, the cathode electrode is opened to the atmosphere, and when a low potential is applied, hydrogen gas is supplied to the anode electrode. In this case, when a high potential is applied, the anode electrode is filled with nitrogen permeated from the cathode electrode, and when a low potential is applied, the cathode electrode consumes oxygen from the air that was supplied when the high potential was applied or during fuel cell operation. To fill with nitrogen.

  As described above, the high potential applied to platinum in the electrolyte membrane is preferably controlled to 0.9 V or less. However, in (B), in order to control to 0.9 V or less, for example, in an oxidizing gas A method of mixing a reducing gas such as hydrogen or sweeping an electric current can be used.

In the method (B), along with the supply of the gas, washing water is circulated from the cathode electrode side to the anode electrode side. The washing water dissolves the platinum ions generated in the electrolyte membrane and rinses away to the anode electrode side. The platinum ions that have reached the anode electrode together with the cleaning water are partly discharged together with the cleaning water from the gas supply port and gas discharge port of the anode electrode, and the other part is reduced by applying a low potential. Precipitate. That is, platinum deposited on the electrolyte membrane can be used again as an electrode catalyst for the anode electrode.
In (B), it is also possible to remove platinum ions generated in the electrolyte membrane from the membrane by flowing cleaning water from the anode electrode side to the cathode electrode side. However, in order to precipitate the washed-out platinum ions again with the electrode, it is effective to circulate the washing water from the cathode electrode side to the anode electrode side.

  In the method (B), as a method of flowing cleaning water from the cathode electrode side to the anode electrode side, for example, the gas supplied to the cathode electrode is supplied in a humidified state so as to be higher than the saturated vapor pressure at the cell temperature, and And a method in which the gas pressure on the cathode electrode side is higher than the gas pressure on the anode electrode side. According to this method, by raising the temperature of the humidifier that humidifies the gas supplied to the cathode electrode to a dew point higher than the saturated vapor pressure at the cell temperature, water (washing water) supplied from the humidifier as water vapor is obtained. Then, it can be condensed and liquefied in the cell, and this liquefied water can be flowed from the cathode electrode side to the anode electrode side using the difference in gas pressure between the cathode electrode and the anode electrode as a driving force.

  The cleaning of the fuel cell according to the present invention is preferably performed periodically every time the continuous operation is performed for a certain time. Specifically, in the operating history of the fuel cell, predicting the degree of platinum deposition on the electrolyte membrane from the open circuit voltage or the integrated operating time at the highest potential taken by the fuel cell (the integrated operating time at the high potential) Can do. It can be determined that platinum is deposited when the accumulated operation time at a high potential from the initial processing or the previous processing exceeds a certain time.

It is a cross-sectional schematic diagram which shows one example of a single cell for fuel cells.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Electrolyte membrane 2 ... Fuel electrode (anode)
3 ... Oxidant electrode (cathode)
4a ... Fuel electrode side catalyst layer 4b ... Oxidant electrode side catalyst layer 5a ... Fuel electrode side gas diffusion layer 5b ... Oxidant electrode side gas diffusion layer 6 ... Membrane / electrode assembly 7a ... Fuel electrode side separator 7b ... Oxidant electrode Side separator 8a ... Fuel electrode side gas flow path 8b ... Oxidant electrode side gas flow path 100 ... Single cell

Claims (6)

A membrane comprising: an electrolyte membrane; an anode electrode provided on one surface of the electrolyte membrane and containing at least platinum particles; and a cathode electrode provided on the other surface of the electrolyte membrane and containing at least platinum particles. A method for cleaning a fuel cell comprising an electrode assembly,
While alternately applying a high potential higher than the dissolution potential of platinum and a lower potential lower than the dissolution potential of platinum to platinum in the electrolyte membrane, the cathode from the anode electrode side in the stacking direction of the membrane-electrode assembly A cleaning method characterized by flowing cleaning water toward an electrode side or from a cathode electrode side toward an anode electrode side.   The cleaning method according to claim 1, wherein the high potential is 0.75 V or more and 1.2 V or less (vs. SHE), and the low potential is 0 V or more and 0.60 V or less (vs. SHE).   The cleaning method according to claim 1, wherein the high potential is 0.9 V or less (vs. SHE). Supplying an oxidizing gas to the anode electrode, and supplying an oxidizing gas or an inert gas to the cathode electrode, applying a high potential to platinum in the electrolyte membrane;
Supplying an inert gas or a reducing gas to the anode electrode, and supplying a reducing gas to the cathode electrode, applying a low potential to platinum in the electrolyte membrane;
The cleaning method according to claim 1, wherein cleaning water is allowed to flow from the anode electrode side toward the cathode electrode side in the stacking direction of the membrane / electrode assembly. After supplying an inert gas to the anode electrode and the cathode electrode, a high potential is applied to platinum in the electrolyte membrane by replacing the anode electrode with an oxidizing gas,
The cleaning method according to claim 4, wherein after supplying an inert gas to the anode electrode and the cathode electrode, a high potential is applied to platinum in the electrolyte membrane by replacing the cathode electrode with a reducing gas. . While closing the gas flow path of the anode electrode and supplying an oxidizing gas to the cathode electrode, by drawing a current from the membrane-electrode assembly and consuming the reducing gas present in the anode electrode, Apply a high potential to platinum in the electrolyte membrane,
While supplying a reducing gas to the anode electrode and closing a gas flow path of the cathode electrode, current is drawn from the membrane-electrode assembly, and the oxidizing gas present in the cathode electrode is consumed, Apply a low potential to platinum in the electrolyte membrane,
The cleaning method according to claim 1, wherein cleaning water is flowed from the cathode electrode side toward the anode electrode side in the stacking direction of the membrane-electrode assembly.

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