Abstract: An electrochemical reaction device in an embodiment includes: an electrochemical reaction cell including a first accommodation part for accommodating carbon dioxide, a second accommodation part for accommodating an electrolytic solution containing water, or water vapor, a diaphragm provided between the first accommodation part and the second accommodation part, a reduction electrode arranged in the first accommodation part, and an oxidation electrode arranged in the second accommodation part, a detection unit detecting a reaction amount in the electrochemical reaction cell; a regulation unit regulating an amount of the carbon dioxide to be supplied to the first accommodation part, and a control unit controlling the regulation unit based on a detection signal of the detection unit.

Abstract: An electrolytic device includes: an electrolysis cell including: an anode; a cathode; a first flow path plate facing on the anode, the first flow path plate having a first recess defining an anode flow path through which a first liquid flows; a second flow path plate facing on the cathode, the second flow path plate having a second recess defining a cathode flow path through which a first gas flows; and a separator provided between the anode and the cathode. The second flow path plate has an uneven surface on an inner surface of the second recess. An arithmetic mean roughness of the uneven surface is 0.03 ?m or more and 50 ?m or less.

Abstract: An electrolytic device includes: a humidifier to humidify a cathode gas; a cathode discharge flow path through which a cathode fluid flows; an anode collector to separate an anode fluid into an anode discharge liquid and an anode exhaust gas; a first cooler to cool the anode exhaust gas to condense water vapor in the anode exhaust gas to produce a anode condensed water; a first flow path connecting the anode collector and an anode supply flow path, the first flow path through which the anode solution flows from the anode collector to the anode supply flow path; a second flow path through which the anode condensed water flows from the condensed water collector to the humidifier; and a first heat exchange structure to exchange heat between the anode solution through the first flow path and the anode condensed water through the second flow path.

Abstract: An electrochemical reaction device in an embodiment includes: a reaction unit including a first accommodation part to accommodate carbon dioxide and a second accommodation part to accommodate an electrolytic solution containing water; a reduction electrode to reduce the carbon dioxide; an oxidation electrode to oxidize the water; a power supply to pass current between the reduction electrode and the oxidation electrode; a pressure regulator to regulate a pressure in the first accommodation part; a reaction product detector to detect at least one of an amount and a kind of a substance produced at the reduction electrode; and a controller to control the pressure regulator based on a detection signal of the reaction product detector.

Abstract: An electrolysis device includes: an electrolysis cell having a cathode flow path, an anode flow path, a cathode, an anode, and a diaphragm; an anode supply flow path; an anode discharge flow path; a cathode supply flow path; a cathode discharge flow path through which a cathode fluid flows; first to third pressure detectors; first and second pressure controllers that control pressures of the cathode and anode flow paths; a first gas/liquid separator that separates a reduction product from the cathode fluid; a gas detector that measures a concentration of the separated reduction product; and an arithmetic device that calculates pressure values of the anode and cathode flow paths based on the measured concentration and pressures, and controls the pressure controllers to adjust the pressures of the anode and cathode flow paths to the calculated pressure values.

Abstract: A sequestration system includes: an electrolysis part having an electrolysis cell having an anode, a cathode, an anode flow path facing on the anode, and a cathode flow path facing on the cathode; and a reaction part configured to switch a first operation and a second operation, the first operation including producing solid carbon using a catalyst from a first raw material containing a first fluid to be introduced from the cathode flow path, and the second operation including performing a reaction of a second raw material containing a second fluid to be introduced from the anode flow path and solid carbon to be deposited on the catalyst to remove at least a part of the deposited solid carbon from the catalyst.

Abstract: An electrolysis device of an embodiment includes: an electrolysis cell including a cathode part in which a reduction electrode is disposed, an anode part in which an oxidation electrode is disposed, and a diaphragm provided between the cathode part and the anode part; a supply power property obtaining unit that obtains a property of power that is to be supplied to the electrolysis cell; an input gas property obtaining unit that obtains a property of a gas that is to be input to the electrolysis cell; an electric property obtaining unit that obtains an electric property of the electrolysis cell; an output gas property obtaining unit that obtains a property of an output gas of the electrolysis cell; a temperature obtaining unit that obtains a temperature of the electrolysis cell; a data storage unit that stores data from the obtaining units; and a data processing unit to which the data is sent from the data storage unit and that processes the data to determine a state of the electrolysis cell.

Abstract: An electrochemical reaction device includes: a first reactor including a first room and a second room, the first room being configured to store a gas containing carbon dioxide or a first electrolytic solution containing carbon dioxide, and the second room being configured to store a second electrolytic solution containing water; a cathode disposed in the first room, the cathode being configured to reduce the carbon dioxide and thus produce a reduction product; an anode disposed in the second room, the anode being configured to oxidize the water and thus produce an oxidation product; a first pressure adjuster configured to adjust pressure in the first room; a temperature detector configured to detect a temperature in the first reactor to form a detection signal; and a controller configured to control the pressure adjuster in accordance with the detection signal from the temperature detector.

Abstract: A carbon dioxide electrolytic device according to an embodiment includes: an electrolysis cell including a reduction electrode, an oxidation electrode, a gas flow path supplying gas containing CO2 to the reduction electrode, a liquid flow path supplying an electrolytic solution containing water to the oxidation electrode, and a diaphragm separating the reduction electrode from the oxidation electrode; a first supply path connected to the gas flow path; a first discharge path connected to the gas flow path; a first moisture content detecting unit installed in the first discharge path to detect a moisture content in the gas flowing in the first discharge path; a moisture content adjusting unit configured to adjust a moisture content supplied to the reduction electrode; and a control unit configured to control the moisture content adjusting unit based on a detection signal of the first moisture content detecting unit.

Abstract: A carbon compound manufacturing system includes: a recovery unit; a conversion unit; a synthesis unit; a first flow path to supply the supply gas to the recovery unit; a second flow path connecting the recovery and the conversion units; a third flow path connecting the conversion and the synthesis units; at least one of first to third detectors to respectively measure a flow rate of the supply gas flowing through the first flow path to generate a first data signal, a flow rate of the carbon dioxide flowing through the second flow path to generate a second data signal, and a value of voltage or current to the conversion unit to generate a third data signal; and an integration controller to collate at least one data of the first to third data signals with a corresponding plan data to generate at least one of first to third control signals.

Abstract: An electrochemical reaction device includes: a first reactor including a first room and a second room, the first room being configured to store a gas containing carbon dioxide or a first electrolytic solution containing carbon dioxide, and the second room being configured to store a second electrolytic solution containing water; a cathode disposed in the first room, the cathode being configured to reduce the carbon dioxide and thus produce a reduction product; an anode disposed in the second room, the anode being configured to oxidize the water and thus produce an oxidation product; a first pressure adjuster configured to adjust pressure in the first room; a temperature detector configured to detect a temperature in the first reactor to form a detection signal; and a controller configured to control the pressure adjuster in accordance with the detection signal from the temperature detector.

Abstract: An electrode catalyst layer for electrolytic cell 3 of an embodiment includes: a carbon material; a metal catalyst supported on the carbon material; and a water-repellent organic substance. In the electrode catalyst layer for electrolytic cell of the embodiment, the water-repellent organic substance includes an organic substance containing sulfur. A metal-sulfur bond is formed between the organic substance containing sulfur and the metal catalyst. A mass ratio (S/M) of a sulfur element (S) to a metal element (M) in the metal catalyst in the catalyst layer is not less than 0.03 nor more than 0.1.

Abstract: A carbon dioxide electrolytic device, includes: an electrolysis cell including an anode to oxidize water and thus form oxygen, an anode flow path facing the anode, a cathode to reduce carbon dioxide and thus form a carbon compound, a cathode flow path facing the cathode, and a separator between the anode and the cathode; a cooling flow path provided opposite to the anode flow path or the cathode flow path and connected in parallel to the anode flow path; an anode inflow path connecting an inlet of the anode flow path, an inlet of the cooling flow path, and an outlet of a liquid tank to store a liquid containing water; an anode outflow path connecting an outlet of the anode flow path, an outlet of the cooling flow path, and an inlet of the liquid tank; and a cooler to cool the anode outflow path.

Abstract: An electrolytic device, includes: an electrolysis cell including: a cathode; an anode; a cathode flow path facing the cathode; and an anode flow path facing the anode; a tank including: a first room; a second room; and an opening connecting the first and second rooms, the first and second rooms store a liquid containing at least one ion, the tank forms a level difference so that the first liquid level of the liquid in the first room is higher to the bottom of the second room than the second liquid level of the liquid in the second room, and thus cause an ion in the liquid to move from the first to the second room through the opening; a first flow path connecting an outlet of the cathode flow path and the first room; and a second flow path connecting the second room and an outlet of the anode flow path.

Abstract: A carbon dioxide electrolytic device includes: a carbon dioxide electrolysis cell having a cathode and an anode flow path, a cathode, an anode, and a first diaphragm; a first current regulator to supply a first current; a first gas/liquid separator to separate a first fluid from the anode flow path into a first liquid and gas; an electrodialysis cell having, first and second electrodes, first to fourth rooms, and second to fourth diaphragms; a second current regulator to supply a second current; at least one detector out of a first detector to detect a flow rate of the first gas or a concentration of carbon dioxide in the first gas, and a second detector to detect a pH or a concentration of at least one ion in the first fluid; and a first controller to regulate a second current, in accordance with at least one detection signal.

Abstract: A carbon dioxide electrolytic device in an embodiment includes: an electrochemical reaction cell including: a first accommodation part that accommodates gas or a first electrolytic solution containing CO2; a second accommodation part that accommodates a second electrolytic solution containing H2O; a diaphragm provided between the first and second accommodation parts; a cathode that is in contact with the gas or the first electrolytic solution; and an anode that is in contact with the second electrolytic solution; a first supply part that supplies the gas or the first electrolytic solution to the first accommodation part; a second supply part that supplies the second electrolytic solution to the second accommodation part; and a carbon dioxide separation part that is connected to a discharge portion of a discharge containing O2 and CO2 from the second accommodation part and includes a cryogenic separation device to separate CO2 from a gas component in the discharge.

Abstract: CO2 reaction methods may include: supplying CO2-containing gas to a first accommodation part (AP) of an electrochemical reaction cell (ERC) from a first supply unit, the ERC including the first AP, a second AP, a cathode in the first AP, and an anode in the second AP; supplying an electrolytic solution containing H2O to the second AP; controlling ERC temperature to 60 to 150° C. so discharged gas and discharged solution discharged from the first and second APs are 60 to 100° C.; supplying current to the electrodes, reducing the CO2 at the reduction electrode and discharge gas from the first AP, and oxidizing H2O and discharge the solution containing O2 and CO2 from the second AP; separating O2 and CO2 gas from the discharged solution; combusting the O2 to produce CO2, and discharging mixed-CO2 gas containing combustion CO2 and CO2; and supplying the mixed-CO2 gas to the first AP.

Abstract: A CO2 electrolyzing method may include: supplying gas containing CO2 and/or a first electrolytic solution (ES) containing CO2 to a first accommodation part (AP) of an electrolysis cell so the gas or first ES contacts a reduction electrode in the first AP, the electrolysis cell including the reduction electrode, an oxidation electrode, the first AP, and a second AP; supplying a second ES containing water and CO2, HCO3-, and/or CO32- to the second AP so the second ES contacts the oxidation electrode in the second AP, the oxidation electrode including a conductive metal substrate and oxidation catalyst layer thereon, of a 20 to 70 mass% Fe, balance Ni, a nickel and iron bonding state in the composite body including Ni(OH)2, NiOOH, and FeOOH; supplying an electric current to the reduction and oxidation electrode, to reduce the CO2 in the reduction electrode and produce a carbon compound.

Abstract: A carbon compound manufacturing system includes: a recovery unit; a conversion unit; a synthesis unit; a first flow path to supply the supply gas to the recovery unit; a second flow path connecting the recovery and the conversion units; a third flow path connecting the conversion and the synthesis units; at least one of first to third detectors to respectively measure a flow rate of the supply gas flowing through the first flow path to generate a first data signal, a flow rate of the carbon dioxide flowing through the second flow path to generate a second data signal, and a value of voltage or current to the conversion unit to generate a third data signal; and an integration controller to collate at least one data of the first to third data signals with a corresponding plan data to generate at least one of first to third control signals.

Abstract: A carbon dioxide electrolytic device of an embodiment includes: an electrolysis cell including a first accommodation part for accommodating carbon dioxide, a second accommodation part for accommodating an electrolytic solution containing water, or water vapor, a diaphragm provided between the first accommodation part and the second accommodation part, a reduction electrode arranged in the first accommodation part, and an oxidation electrode arranged in the second accommodation part; a first power supply control unit capable of being connected to a first power supply which supplies power to the electrolysis cell; a second power supply control unit capable of being connected to a second power supply which supplies power to the electrolysis cell; and an integration control unit controlling the first power supply control unit and the second power supply control unit, and switching the supply of power from the first power supply or the second power supply to the electrolysis cell.