JP6260952B2 - Solid polymer electrolysis method and system. - Google Patents

Description

  The present invention relates to a solid polymer electrolysis method and system in which carbon dioxide is supplied to the cathode side of a membrane electrode assembly provided with a catalyst layer and water or water vapor is supplied to the anode side to generate a hydrocarbon compound.

In recent years, carbon dioxide emissions into the atmosphere derived from the combustion of fossil fuels can have a significant impact on ecosystems and the global environment, and therefore, suppression of carbon dioxide emissions has been demanded worldwide.
For this reason, technology that does not emit carbon dioxide or that reduces carbon dioxide emissions has been developed, and as part of this, technology that fixes carbon dioxide or converts it to other substances has also been developed. Yes.
Also, in a completely enclosed environment such as a space station or rocket, replenishment of materials is not easy, and it is necessary to keep the replenishment and discharge to the minimum necessary at the elemental level.
For this reason, it is required to increase substances that can be recovered by converting the generated carbon dioxide into other substances, and to reduce substances that are replenished and discharged as much as possible at the elemental level.

As a method for reducing the amount of carbon dioxide in the atmosphere, a method of collecting carbon dioxide and filling it in the ground is being advanced.
In addition, there is an attempt to react carbon dioxide with hydrogen at a high temperature near 300 ° C. by a Sabatier catalyst reaction to generate methane, and recover the methane and use it as energy that can be easily transferred.
However, all these methods are methods that require a large amount of energy for burying or that require energy to maintain a high temperature.

  As carbon dioxide is immobilized by suppressing energy input, carbon dioxide is supplied to the cathode side of the electrolysis unit having a membrane electrode assembly provided with a catalyst layer, water is supplied to the anode side, and the cathode and anode Solid polymer electrolysis method and system that can recycle carbon resources by applying a voltage between them to reduce water and carbon dioxide to produce other usable compounds such as carbon monoxide Has been proposed (see, for example, Patent Document 1).

International Patent Publication No. 2012/118065

However, in the technique known in Patent Document 1 described above, carbon monoxide is mainly generated, and other compounds such as hydrocarbon compounds are also generated. The control of the production ratio of a plurality of hydrocarbon compounds, etc.) was not considered at all.
Therefore, complicated equipment is required to separate and recover various products.
In addition, since the utility value and use differ depending on the compound produced, it is necessary to prepare multiple collection and utilization routes, and many facilities are required for collection and use. There was a problem that utilization efficiency fell.
Therefore, as a result of intensive studies by the present inventors, carbon dioxide is supplied to the cathode side of the electrolysis part having the membrane electrode assembly provided with the catalyst layer, and water or water vapor is supplied to the anode side to electrolyze the water. When reducing carbon dioxide, it was found that the production amount and the ratio by type of multiple hydrocarbon compounds produced per unit time can be controlled according to the applied voltage of electrolysis, temperature conditions, humidification conditions, etc. .
In addition, a potential of the same polarity as the voltage applied to electrolysis is generated by the reduction reaction of carbon dioxide, and electrolysis and reduction are performed simultaneously in the electrolysis part (that is, the electrolysis part also functions as a fuel cell). Less.

  The present invention solves the problems of known solid polymer electrolysis methods and systems based on the above-mentioned knowledge, and requires less energy, does not require high temperature maintenance, and carbon dioxide is beneficially carbonized. It can be converted as a hydrogen compound, and the production amount of hydrocarbon compounds, etc., and the ratio of each type can be controlled, and it becomes possible to produce a large amount of compounds according to the intended use. An object of the present invention is to provide a solid polymer electrolysis method and system capable of improving the utilization efficiency and simplifying the equipment for separation and recovery.

According to the first aspect of the present invention, carbon dioxide is supplied to the cathode side of an electrolysis part having a membrane electrode assembly provided with a catalyst layer, and water or water vapor is supplied to the anode side to produce a hydrocarbon compound. A molecular electrolysis method, wherein the applied voltage between the cathode and anode of the electrolysis unit and the temperature of the electrolysis unit are controlled, and the amount and type ratio of the hydrocarbon compound produced per unit time are changed. The above-mentioned problem is solved.

In addition to the configuration of the polymer electrolyte electrolysis method according to claim 1 , the invention according to claim 2 humidifies the supplied carbon dioxide with water, controls the degree of humidification, and generates per unit time. The problem is solved by changing the amount of the hydrocarbon compound to be produced and the ratio by type.
The invention according to claim 3 solves the above problem by continuously supplying the carbon dioxide and water or water vapor in addition to the configuration of the solid polymer electrolysis method according to claim 1 or claim 2. Is.
In addition to the configuration of the solid polymer electrolysis method according to any one of claims 1 to 3 , the invention according to claim 4 is such that the temperature of the electrolysis unit is 200 ° C. or lower, and methane, methanol, ethanol, propanol The above-mentioned problems are solved by generating at least one component of formaldehyde and acetaldehyde.

The invention according to claim 5 includes an electrolysis unit having a membrane electrode assembly provided with a catalyst layer, carbon dioxide supply means for supplying carbon dioxide to the cathode side of the electrolysis unit, and water on the cathode side of the electrolysis unit. Or a solid polymer electrolysis system comprising a water supply means for supplying water vapor and a gas-liquid separation means for separating and recovering the product, and controls the applied voltage between the cathode and anode of the electrolysis unit. A voltage control means, and a temperature control means for controlling the temperature of the electrolysis unit, by changing the amount and type ratio of the hydrocarbon compound produced per unit time by the voltage control means and the temperature control means. The above-mentioned problem is solved.

In the invention according to claim 6 , in addition to the configuration of the solid polymer electrolyte system according to claim 5 , the humidification means for supplying water for humidification is connected to the carbon dioxide supply means. The problem is solved.
According to the seventh aspect of the invention, in addition to the configuration of the solid polymer electrolysis system according to the fifth or sixth aspect, the gas-liquid separation unit circulates unreacted gas through the carbon dioxide supply unit again. By having a route, the above-mentioned problem is solved.
In addition to the configuration of the solid polymer electrolysis system according to any one of claims 5 to 7 , the invention according to claim 8 is a temperature control unit in which the electrolysis unit, the gas-liquid separation unit, and the humidification unit are independent of each other. Central control means for controlling the plurality of the voltage control means, the humidification control means, and each temperature control means according to the type and amount of the product to be recovered. By providing the above, the above-mentioned problem is solved.
According to the ninth aspect of the present invention, in addition to the configuration of the solid polymer electrolysis system according to any one of the fifth to eighth aspects, the voltage control means extracts a power by a reverse reaction as a direct methanol fuel cell. By being configured to operate, the above-described problems are solved.
A regenerative fuel cell system according to claim 10 is a combination of the solid polymer electrolysis system according to any one of claims 5 to 8 , a water electrolysis device, and a device for reacting carbon dioxide with hydrogen. By being configured, the above-described problems are solved.

According to the solid polymer electrolysis method according to claim 1 and the solid polymer electrolysis system according to claim 5 , carbon dioxide is reduced by a fuel cell reaction using hydrogen generated by water electrolysis, Since the hydrocarbon compound can be obtained as a direct product from the fuel cell reaction, less energy is required, high temperature environment maintenance is not necessary, and carbon dioxide can be converted as a beneficial hydrocarbon compound. .
In addition, by controlling the applied voltage between the cathode and anode of the electrolysis unit and the temperature of the electrolysis unit, it is possible to control the amount of hydrocarbon compound etc. produced and the ratio by type, and a large amount of compounds depending on the intended use It becomes possible to produce | generate, the utilization efficiency of a product improves, and it also becomes possible to simplify the installation for isolation | separation collection | recovery.
In addition, since less energy is required, there is no need to maintain a high-temperature environment, and the equipment can be simplified, it is included in the exhalation of people when performing manned activities in a completely enclosed environment such as outer space. It is also very useful as a technology for removing carbon dioxide and recovering carbon resources.

According to the configuration of the second and sixth aspects of the present invention, by controlling the degree of humidification, the production amount of hydrocarbon compounds and the ratios by type can be controlled more finely.
According to the configuration described in claim 3 , continuous supply of carbon dioxide and water enables continuous and stable electrolysis and generation of hydrocarbon compounds and the like.
According to the configuration described in claim 4 , it is not necessary to maintain a high temperature environment like the Sabatier reaction, and the facility can be further simplified.
In particular, it can be carried out in a low-temperature environment of 100 ° C. or lower, which cannot be realized by using a Sabatier reaction or a known solid polymer electrolysis method and system.
According to the configuration of the present invention , the gas-liquid separation means can operate efficiently even in a closed system by having a circulation path for circulating the unreacted gas to the carbon dioxide supply means again. It becomes.
According to the configuration of the eighth aspect of the present invention, since the central control unit that performs overall control of the voltage control unit, the humidification control unit, and each of the temperature control units is provided, the hydrocarbon can be accurately and accurately electrolyzed. It is possible to control the amount of compound etc. produced and the ratio by type.
According to the configuration of the ninth aspect of the present invention , by selectively generating methanol by electrolysis and taking out electric power by a reverse reaction, a charge / discharge cycle is assembled in a state where the raw materials and products are closed in the system. By using methanol or water as a component during storage, it can be used as an extremely safe and useful regenerative fuel cell.
According to regenerative fuel cell system according to the claim 10, methanol selectively can generate solid polymer electrolyte systems and water electrolysis device, combining the device and reacting the carbon dioxide gas and hydrogen, 3 steps path Can be assembled with the raw materials and products closed in the system, and methanol and water can be used as storage components, so that they can be used as extremely safe and useful regenerative fuel cells. It becomes possible.

BRIEF DESCRIPTION OF THE DRAWINGS Explanatory drawing of the solid polymer electrolyte system which concerns on 1st Embodiment of this invention. FIG. 2 is an exploded explanatory view of the electrolysis unit of FIG. Explanatory drawing of the solid polymer electrolyte system which concerns on 2nd Embodiment of this invention. The graph which shows the relationship between the applied voltage and the production | generation compound by the solid polymer electrolyte system which concerns on one Embodiment of this invention. The graph which shows the relationship between the applied voltage and production | generation compound of the solid polymer electrolyte system (adopting another catalyst) which concerns on other embodiment. The graph which shows the relationship between the temperature of the electrolysis part (cell) by the solid polymer electrolyte system which concerns on other embodiment, and a production | generation compound. The graph which shows the production | generation of formaldehyde by the solid polymer electrolyte system which concerns on this invention. The graph which shows the production | generation of acetone and 2-propanol by the solid polymer electrolyte system which concerns on this invention. Explanatory drawing of reaction at the time of utilizing the solid polymer electrolyte system which concerns on this invention as a regeneration type fuel cell. The reference figure of the carbon circulation system which applied the solid polymer electrolysis system concerning the present invention.

In the polymer electrolyte electrolysis method of the present invention, carbon dioxide is supplied to the cathode side of an electrolysis part having a membrane electrode assembly provided with a catalyst layer, and water or water vapor is supplied to the anode side to produce a hydrocarbon compound. Solid polymer electrolysis method, which controls the applied voltage between the cathode and anode of the electrolysis unit and the temperature of the electrolysis unit, and changes the amount and type ratio of hydrocarbon compounds produced per unit time It is.
The solid polymer electrolysis system of the present invention includes an electrolysis unit having a membrane electrode assembly provided with a catalyst layer, a carbon dioxide supply means for supplying carbon dioxide to the cathode side of the electrolysis unit, and a cathode side of the electrolysis unit Is a solid polymer electrolysis system comprising a water supply means for supplying water or water vapor to the gas and a gas-liquid separation means for separating and recovering the product, and controls the applied voltage between the cathode and anode of the electrolysis section And a temperature control means for controlling the temperature of the electrolysis section, and the amount and type ratio of the hydrocarbon compound produced per unit time by the voltage control means and the temperature control means are changed .
In any case, less energy is required, high temperature does not need to be maintained, carbon dioxide can be converted as a useful hydrocarbon compound, and the amount of hydrocarbon compound etc. produced and the ratio of each type is controlled. It is possible to produce a large amount of a compound according to the intended use, improve the utilization efficiency of the product, and simplify the equipment for separation and recovery. Any specific embodiment may be used.

The temperature of the electrolysis part having the membrane electrode assembly (MEA) is preferably 100 ° C. or lower, and it is desirable to maintain the reaction field by continuously supplying gas and circulating as necessary.
Further, the electrode catalyst for supplying carbon dioxide is not particularly limited, but a platinum ruthenium alloy, or one that is not poisoned by methanol generated during the reaction of ruthenium, rhodium or the like is preferable.
It is desirable to supply the carbon dioxide with humidification, which makes it possible to maintain stable electrolysis.

An embodiment of a solid polymer electrolysis system according to the present invention will be described with reference to the drawings.
As shown in FIGS. 1 and 2, the polymer electrolyte system 100 according to the first embodiment of the present invention includes an electrolysis unit 110 having a membrane electrode assembly 113 provided with a catalyst layer 114, and an electrolysis unit 110. A carbon dioxide supply means 120 for supplying carbon dioxide to the cathode 111 side, a water supply means 130 for supplying water or water vapor to the anode 112 side of the electrolysis unit 110, and a gas for separating and recovering a product, a carrier gas described later, and the like. Liquid separation means 140 and 150 are provided.
In addition, for the sake of explanation, the electrolysis unit 110 is illustrated by simplifying the one constituted by only one cell, but the actual shape is not limited to this, and the electrolysis unit 110 as a whole includes a plurality of cells. Are preferably arranged in series in a stack.

A humidifying means 121 for supplying water for humidification is connected to the path from the carbon dioxide supply means 120 to the electrolysis unit 110.
The water supply means 130 is configured to supply water or water vapor to the electrolysis unit 110 by humidifying the carrier gas supplied from the carrier gas supply means 132 by the humidification means 131.
The gas-liquid separation unit 140 has a circulation path 141 that circulates unreacted gas through a path from the carbon dioxide supply unit 120 to the electrolysis unit 110 again. The circulation path 141 is provided with a circulation pump 142. ing.
The gas-liquid separation means 150 has a circulation path 151 that circulates the carrier gas and unreacted water vapor again through the path from the water supply means 130 to the electrolysis unit 110, and a circulation pump 152 is provided in the circulation path 151. Is provided.
The power supplied to the electrolysis unit 110 is supplied by a power supply unit (not shown), but the applied voltage between the cathode 111 and the anode 112 of the electrolysis unit 110 is configured to be controllable by the voltage control means 161.
The temperature of the electrolysis unit 110 is configured to be controllable by the electrolysis unit temperature control means 162.

The temperatures of the gas-liquid separation means 140 and 150 can be controlled independently by the gas-liquid separation means temperature control means 163 and 166, respectively.
Further, the temperature and the humidification amount of the humidifying means 121 and 131 are configured to be independently controllable by the humidifying means temperature control means 164 and 167 and the humidification control means 165 and 168, respectively.
Further, the voltage control means 161, the electrolysis section temperature control means 162, the gas-liquid separation means temperature control means 163 and 166, the humidification means temperature control means 164 and 167, and the humidification control means 165 and 168 should be collected by the central control means 160. It is configured so that it can be controlled comprehensively according to the type and amount of products.
The carrier gas may be any gas, such as nitrogen, argon, helium, etc., as long as it is a gas that is stable to the reaction and product in the electrolysis section.
Furthermore, the carrier gas may contain hydrogen. In this case, hydrogen can be supplied without electrolysis in the electrolysis section, so less energy is required and energy can be recovered depending on the amount of hydrogen supplied. It becomes.

The effects of the solid polymer electrolysis method and system of the present invention configured as described above will be described below.
For the catalyst layer 114 of the membrane electrode assembly 113, two different types of PtRu alloy-based catalysts that have been proven in direct methanol fuel cells (DMFC) are used, respectively, between the cathode 111 and the anode 112 of the electrolysis unit 110. FIG. 4 and FIG. 5 show the compound synthesis ratio when the applied voltage (potential) is changed.
The graph shown in FIG. 4 shows the experimental results when 1 mg / cm ² of PtRu (trade name: TEC66E50) was used as the catalyst. The graph shown in FIG. 5 shows 3 mg / cm ² of PtRu (trade name: TEC61E54) as the catalyst. the experimental results when used in cm ^2.
In any experiment, the applied voltage (potential) was determined by the counter electrode (hydrogen).

From these experimental results, it was confirmed that the synthesis ratio of the compound changed depending on the applied voltage (potential), the higher the synthesis ratio of methane, the lower the alcohol production ratio (the lower the potential, the more reduction). It can be confirmed that the hydrocarbon compound can be selectively produced.
Although not shown in the conditions of FIG. 5, the formation of formaldehyde was confirmed in the region where the potential was 80 mV or more.

FIG. 6 shows the compound synthesis ratio when PtRu (trade name: TEC61E54) was used at 3 mg / cm ² for the catalyst layer 114 of the membrane electrode assembly 113 when the temperature of the electrolysis part (cell) was changed. .
The carrier gas was supplied at a rate of 50 ml / min in a humidified state of 100%, and the measured values were plotted for each temperature between the applied voltage (potential) of 40 mV to 60 mV.
A vertical range display is a range of measured values of 40 mV to 60 mV of methane, methanol, and ethanol at each temperature, and a curve graph is a curve of a tendency depending on temperature.
The composition ratio of the hydrocarbon compound changes depending on the temperature of the electrolysis part (cell), and a contradictory increase / decrease tendency between methane and other alcohols can be confirmed.

Another embodiment of the solid polymer electrolytic system according to the present invention will be described with reference to the drawings.
The polymer electrolyte system 100a according to the second embodiment of the present invention is configured without using a carrier gas. As shown in FIG. 3, the electrolysis unit 110, the carbon dioxide supply means 120, the gas-liquid The separation means 140 is the same as that of the solid polymer electrolysis system 100 according to the first embodiment.
The water supply unit 130 is configured to adjust the temperature of the water supplied from the water storage unit 133 by the heating unit 134 or supply the water to the electrolysis unit 110 as water vapor.
The product separation means 170 has a circulation path 151 that circulates unreacted water or steam again to the path from the water supply means 130 to the electrolysis unit 110, and a circulation pump 152 is provided in the circulation path 151. It has been.

The power supplied to the electrolysis unit 110 is supplied by a power supply unit (not shown), but the applied voltage between the cathode 111 and the anode 112 of the electrolysis unit 110 is configured to be controllable by the voltage control means 161.
The temperature of the electrolysis unit 110 is configured to be controllable by the electrolysis unit temperature control means 162.
The temperature of the gas-liquid separation unit 140 is configured to be independently controllable by the gas-liquid separation unit temperature control unit 163.
The temperature and the humidification amount of the humidifying means 121 are configured to be independently controllable by the humidifying means temperature control means 164 and the humidification control means 165.
The temperature of the heating means 134 is configured to be independently controllable by the heating means temperature control means 169.
The temperature of the product separation means 170 is configured to be independently controllable by the product separation means temperature control means 171.
Further, the voltage control means 161, the electrolysis section temperature control means 162, the gas-liquid separation means temperature control means 163, the humidification means temperature control means 164, the humidification control means 165, the heating means temperature control means 169, and the product separation means temperature control means 171. The central control means 160 is configured to be able to perform overall control according to the type and amount of the product to be collected.

Moreover, according to the solid polymer electrolysis method and system of the present invention, it is possible to control the production of other hydrocarbon compounds by appropriately setting conditions such as voltage and temperature of the electrolysis section.
For example, from the chromatographic analysis of the product when the voltage was 60 mV and the temperature was 80 ° C., the formation of formaldehyde was confirmed as shown in FIG.
Moreover, from the chromatographic analysis of the product at a voltage of 60 mV and a temperature of 95 ° C., it was confirmed that acetaldehyde and 2-propanol were produced as shown in FIG.

According to the solid polymer electrolysis method and system of the present invention, less energy is required, high temperature does not need to be maintained, carbon dioxide can be converted as a useful hydrocarbon compound, and hydrocarbons are used. It is possible to control the amount of compound and the like and the ratio by type.
As a result, it is possible to produce a large amount of a compound corresponding to the intended use, improving the utilization efficiency of the product and simplifying the equipment for separation and recovery.
Taking advantage of these characteristics, for example, by producing specialized ethanol that is extremely useful as a raw material or energy source in various industries, it is possible to fix carbon dioxide and produce useful ethanol with less energy It becomes possible to solve environmental problems, energy problems, and resource problems together.

In addition, when produced specifically for methanol, as shown in FIG. 9, since solid polymer electrolysis and power generation with methanol are reversible reactions by charging and discharging, it is combined with a separate direct methanol fuel cell. Alternatively, by controlling the voltage control means 161 of the solid polymer electrolysis system 100 of the present invention to operate as a direct methanol fuel cell, it is possible to form a cycle with the raw materials and products closed in the system. By using methanol or water as a component during storage, it can be used as an extremely safe and useful regenerative fuel cell.
Further, by combining the polymer electrolyte electrolysis system 100 with a water electrolysis apparatus, an apparatus for reacting carbon dioxide gas with hydrogen, etc., for example, as shown in FIG. 10, a regenerative fuel cell system that takes a three-step path And can be used as an extremely safe and useful regenerative fuel cell.
Furthermore, it can be effectively used from the viewpoints of carbon dioxide removal, element-level circulation, energy generation, etc. as a control technology for a completely enclosed environment such as a space station or rocket.

DESCRIPTION OF SYMBOLS 100 ... Solid polymer electrolysis system 110 ... Electrolysis part 111 ... Cathode 112 ... Anode 113 ... Membrane electrode assembly 114 ... Catalyst layer 120 ... Carbon dioxide supply means 121 ..Humidification means (carbon dioxide side)
130: Water supply means 131: Humidification means (water side)
132 ... Carrier gas supply means 133 ... Water storage part 134 ... Heating means 140 ... Gas-liquid separation means (carbon dioxide side)
141 ・ ・ ・ Circulation route (carbon dioxide side)
142 ... Circulation pump (carbon dioxide side)
150 ... Gas-liquid separation means (water side)
151 ・ ・ ・ Circulation route (water side)
152 ... Circulation pump (water side)
160 ... central control means 161 ... voltage control means 162 ... electrolysis part temperature control means 163 ... gas-liquid separation means temperature control means (carbon dioxide side)
164 ... Humidification means temperature control means (carbon dioxide side)
165 ... Humidification control means (carbon dioxide side)
166 ... Gas-liquid separation means temperature control means (water side)
167 ... Humidification means temperature control means (water side)
168 ... Humidification control means (water side)
169 ... heating means temperature control means 170 ... product separation means 171 ... product separation means temperature control means

Claims (10)

A solid polymer electrolysis method for producing a hydrocarbon compound by supplying carbon dioxide to the cathode side of an electrolysis part having a membrane electrode assembly provided with a catalyst layer and supplying water or water vapor to the anode side,
Controlling the applied voltage between the cathode and anode of the electrolysis unit and the temperature of the electrolysis unit ,
A solid polymer electrolysis method characterized by changing the amount and type ratio of hydrocarbon compounds produced per unit time. Humidifying the supplied carbon dioxide with water;
2. The solid polymer electrolysis method according to claim 1, wherein the degree of humidification is controlled to change the amount and type ratio of the hydrocarbon compound produced per unit time. The solid polymer electrolysis method according to claim 1 or 2, wherein the carbon dioxide and water or water vapor are continuously supplied. The temperature of the electrolysis part is 200 ° C. or less,
The solid polymer electrolysis method according to any one of claims 1 to 3 , wherein at least one component of methane, methanol, ethanol, propanol, formaldehyde, and acetaldehyde is produced. An electrolysis part having a membrane electrode assembly provided with a catalyst layer; a carbon dioxide supply means for supplying carbon dioxide to the cathode side of the electrolysis part; and a water supply means for supplying water or steam to the anode side of the electrolysis part; A polymer electrolyte system comprising a gas-liquid separation means for separating and recovering the product,
Voltage control means for controlling the applied voltage between the cathode and anode of the electrolysis unit ;
Temperature control means for controlling the temperature of the electrolysis unit,
A solid polymer electrolysis system characterized in that the amount and type ratio of hydrocarbon compounds produced per unit time by the voltage control means and the temperature control means are changed . 6. The solid polymer electrolysis system according to claim 5, wherein humidification means for supplying water for humidification is connected to the carbon dioxide supply means. The solid polymer electrolysis system according to claim 5 or 6, wherein the gas-liquid separation means has a circulation path for circulating unreacted gas to the carbon dioxide supply means again. The electrolysis unit, the gas-liquid separation unit and the humidification unit each have independent temperature control means,
The humidifying means has a humidifying control means;
Depending on the type and amount of to be recovered product, said voltage control means, claims 5 to 7, characterized in that a central control unit for a plurality of integrated control of the humidification control unit and the temperature control means The solid polymer electrolyte system according to any one of the above. The solid polymer electrolysis system according to any one of claims 5 to 8 , wherein the voltage control means is configured to take out electric power by a reverse reaction and operate as a direct methanol fuel cell. A regenerative fuel cell system comprising a combination of the solid polymer electrolysis system according to any one of claims 5 to 8 , a water electrolysis device, and a device for reacting carbon dioxide with hydrogen.

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