Hidrógeno electrolítico

極性を反転可能な電極およびその使用

Resumen de: WO2021164702A1

The application discloses an electrode having polarity capable of being reversed and use thereof. The electrode includes a substrate comprising a metal or an alloy thereof; an intermediate layer arranged on the substrate and comprising a platinum group metal and a platinum group metal oxide; and a catalytic layer arranged on the intermediate layer and comprising a mixed metal oxide. The electrode may be used as an electrode for electrolysis, electrodialysis or electroplating. The electrode can simultaneously meet the working environment requirements of the cathode and the anode, which improves the environmental tolerance and realizes the protection of the substrate; and can carry out polarity reversal to clean deposits on the surface of the electrode quickly and efficiently.

電気化学セルプラント

Resumen de: GB2613128A

A system comprising an electrolyser stack connected to a water/gas separation vessel, via an inlet and an outlet pipe. The separation vessel is adapted to passively separate the water and gas and the separation vessel contains a heat exchanger. The separation vessel is constructed from polymeric material and the vessel also has at least two nozzles which are adapted to be in communication with the inlet pipe. At least two nozzles are also adapted to be in communication with the outlet pipe where the nozzles are integral to the separation vessel and constructed from the same polymeric material. The nozzles are located so that, in use, they create a cyclonic effect.

用作水电解电极的复杂针织结构

Resumen de: WO2022101865A1

"Smart bracelet device containing glucose and/or glucagon" Ergonomic, wearable smart device, containing predetermined quantities of glucose and/or glucagon adapted to restore the concentration of glucose in the blood comprising: - a body of the device (1) with tubular shape containing predetermined quantities of glucose and/or glucagon; - a reload valve (4) housing at least a lip (6.1) of a reload cartridge (6), adapted to restore the reserves of glucose and/or glucagon; - a straw (3), a nasal spray (11) or both adapted for the consumption of a predetermined quantity of glucose and/or glucagon; - a smart valve (2) adapted to receive information regarding the exact quantity to be administered; - a magnetic closure (5); - a reload cartridge (6) comprising a tank (6.2) and a lip (6.1); - a display (7); - a glycemia detector (8) adapted to check the quantity of glucose in the blood, adapted to interact with said display (7) with latest-generation cellular device, CGM, insulin pumps.

電気化学システム、光電極および光電極の製造方法

Resumen de: JP2026510958A

【課題】水分解および他の反応中、ならびに他のタイプのデバイス動作中のデバイス表面の安定化および活性化に資する電気化学システムを提供する。【解決手段】電気化学システムは、カウンター電極と、カウンター電極から離間した作用電極とを含む。作用電極は、基板と、基板によって支持され、基板から外向きに延在する導電性突起のアレイとを含む。導電性突起のアレイの各導電性突起は、半導体組成を有し、窒素を含む表面と、表面上に配置された酸窒化物層とを含む。カウンター電極および作用電極は、２電極構成で配置される。【選択図】図６

エネルギー生成、及び硝酸の生成などのグリーン産業用途のための統合エネルギーシステム

Resumen de: US2024308850A1

Described herein are techniques that may be performed in an Integrated Energy System (IES) to produce Nitric Acid (HNO3) while minimizing a carbon footprint. Such techniques, as performed by a resource production plant, may comprise receiving electricity and steam from a power plant to produce Hydrogen (H2) gas from the steam at a Hydrogen (H2) production sub-plant, receiving electricity from the power plant and air from the environment to produce Nitrogen (N2) gas at a Nitrogen (N2) production sub-plant, producing Ammonia (NH3) from the Hydrogen (H2) gas and the Nitrogen (N2) gas at a nitrogen production sub-plant, and producing Nitric Acid (HNO3) from the Ammonia (NH3) at a Nitric Acid (HNO3) production sub-plant.

水電解システム

Resumen de: EP4403671A1

Provided is a water electrolysis system (10) that obtains hydrogen by water electrolysis with a water electrolysis cell (13), the water electrolysis system (10) including a water electrolysis stack (12) having a plurality of the water electrolysis cells (13), a water supply side passage (30) that supplies water to the water electrolysis stack (12), a hydrogen side passage (40) that discharges the hydrogen obtained in the water electrolysis stack (12) from the water electrolysis stack (12), a plurality of voltage sensors (22a) that measures voltages for the respective water electrolysis cells (13) or for each group of the water electrolysis cells (13), and a control device (23) configured to acquire a voltage from each of the voltage sensors (22a), determine whether the voltage is lower than a predetermined value and notify the water electrolysis cell (13) has a failure when it is determined that the voltage is lower than a predetermined value .

膜電極アセンブリ、その製造方法、燃料電池、および電解セル

Resumen de: WO2024200435A2

The invention relates to a membrane electrode assembly (1) having an anode (2), a cathode (3) and a hydrocarbon membrane (4) between the anode (2) and the cathode (3). The membrane electrode assembly (1) further comprises a protective layer (5) which is arranged between the anode (2) and the hydrocarbon membrane (4) and/or between the cathode (3) and the hydrocarbon membrane (4), wherein the protective layer (5) comprises at least one ceramic material (6) and a fluorine-containing ionomer (7), wherein the ceramic material (6) is dispersed in the fluorine-containing ionomer (7).

MODULAR ELECTROLYSIS SYSTEM

Resumen de: AU2024351803A1

The invention relates to a modular electrolysis system comprising multiple modules, wherein each of the multiple modules comprises a support frame and at least one interface accessible from outside the support frame and configured to connect the module with at least one of the remaining modules, the multiple modules comprising a water-gas coarse separation module downstream an anode outlet of the electrolysis cell module, and a water-gas fine separation module downstream a liquid outlet of the water-gas coarse separation module.

GRID FORMING CONTROL IN A POWER SYSTEM COMPRISING A HYDROGEN ELECTROLYZER STACK

Resumen de: AU2024350634A1

According to the invention it is provided a method for controlling a grid connected power converter having a DC side with a DC link and an AC grid side, and being configured to control power supply to a hydrogen electrolyzer stack. The power supply to the hydrogen electrolyzer stack is controlled by controlling the DC link to thereby control hydrogen production. The method comprises: determining a grid voltage reference; providing a grid forming control for controlling at least the phase angle of the voltage of the power converter using a grid forming controller, operating according to a grid forming algorithm, the grid forming controller being configured to emulate inertia through control of the voltage of the power converter towards the grid voltage reference; the grid forming controller emulating inertia by charging and discharging an inherent capacitance of the electrolyzer stack; monitoring at least one operating parameter of the hydrogen electrolyzer stack; and limiting a change in charging level of the inherent capacitance based on the monitored operating parameter of the electrolyzer stack.

REFORMER-ELECTROLYZER-PURIFIER (REP) ASSEMBLY FOR HYDROGEN PRODUCTION, SYSTEMS INCORPORATING SAME AND METHOD OF PRODUCING HYDROGEN

Resumen de: US20260100390A1

A high temperature electrolyzer assembly comprising at least one electrolyzer fuel cell including an anode and a cathode separated by an electrolyte matrix, and a power supply for applying a reverse voltage to the at least one electrolyzer fuel cell, wherein a gas feed comprising steam and one or more of CO2 and hydrocarbon fuel is fed to the anode of the at least one electrolyzer fuel cell, and wherein, when the power supply applies the reverse voltage to the at least one electrolyzer fuel cell, hydrogen-containing gas is generated by an electrolysis reaction in the anode of the at least one electrolyzer fuel cell and carbon dioxide is separated from the hydrogen-containing gas so that the at least one electrolyzer fuel cell outputs the hydrogen-containing gas and separately outputs an oxidant gas comprising carbon dioxide and oxygen.

Syntheseverfahren zur Wasserstoffgas-getriebenen Abscheidung von Iridium auf Platinoberflächen, Iridium-beschichtete Platinnanopartikel, und deren Verwendung in elektrochemischen Vorrichtungen

Resumen de: DE102024128720A1

Die Anmeldung betrifft Iridium-beschichtete Platinnanopartikel mit einem Iridiumgehalt der Iridium-beschichteten Platinnanopartikel von 1 bis 40 Gewichts-% bezogen auf das Gesamtgewicht der Iridium-beschichteten Platinnanopartikel, sowie ein Verfahren zur Wasserstoff-getriebenen Abscheidung von Iridium auf Platinoberflächen, insbesondere von Platinnanopartikeln, dadurch gekennzeichnet, dass die Oberfläche von Platinnanopartikeln in einem sauren flüssigen Reaktionsmedium in Anwesenheit von H2-Gas mit Ir-Kationen in Kontakt gebracht wird. Außerdem betrifft die Anmeldung die Anwendung von Irbeschichteten Pt-Nanopartikeln und nicht aus Platin bestehenden Trägermaterialien mit Iridium-beschichteten Pt-Oberflächen in elektrochemischen Vorrichtungen.

ELECTROCHEMICAL PROCESSES FOR PRODUCING DIFFERENT RATIOS OF H2 TO CO2 GASES

Resumen de: US20260098349A1

0000 Aspects and embodiments disclosed herein include an apparatus for generation of carbon dioxide and hydrogen from a saline water source. The apparatus comprises an electrolytic-cation exchange module (E-CEM) cell unit and at least one electrolyzer, each of the E-CEM cell unit and the at least one electrolyzer disposed between a set of endplates and endblocks.

PROCESS AND SYSTEM FOR PRODUCING HYDROGEN AND/OR SYNGAS

Resumen de: WO2026074433A1

A process for producing hydrogen and/or syngas comprises a first operation mode, wherein an active metal is reduced electrolytically to at least one first electrode (E1) immersed in an electrolytic solution, generating a solution enriched with negative ions, and the solution enriched with negative ions is used on a second electrode (E2 ) to produce oxygen gas; and a second operation mode, wherein the reduced metal of the first electrode (E1) is thermochemically oxidised in an oxidation reaction with oxidation reagents producing hydrogen or synthesis gas.

APPARATUS FOR GENERATING HYDROGEN AND OXYGEN FROM A WATER-CONTAINING LIQUID, USE AND ELECTROCHEMICAL CELL ARRANGEMENT

Resumen de: WO2026073297A1

The invention relates in particular to an apparatus (1), to a use and to an electrochemical cell arrangement (32) for generating hydrogen and oxygen, wherein the apparatus (1) comprises an anodic half-cell (6), a cathodic half-cell (7) and an ion exchange apparatus (10), wherein the apparatus (1) comprises a frame apparatus (11), wherein the frame apparatus (11) has a frame apparatus recess (12), wherein the apparatus (1) comprises current-conducting apparatuses (13, 36, 37), wherein the anodic half-cell (6), the cathodic half-cell (7) and the ion exchange apparatus (10) are arranged within the frame apparatus recess (12), wherein the frame apparatus has at least one feed apparatus (18), at least one drain apparatus (19) and at least one hydrogen removal apparatus (20), wherein the at least one feed apparatus (18) feeds a water-containing liquid to the anodic half-cell (6), wherein the at least one drain apparatus (19) drains a further water-containing liquid from the anodic half-cell (6), wherein the at least one hydrogen removal apparatus (20) removes hydrogen from the cathodic half-cell (7), and wherein the frame apparatus (11) is a non-conductor.

METHODS AND SYSTEMS FOR RENEWABLE ENERGY CONVERSION AND STORAGE

Resumen de: US20260098001A1

Disclosed herein are systems and methods for converting and storing renewable energy. An example system includes a source of electrical energy, an electrolyzer unit, a source of carbon dioxide, and a reactor unit that can produce synthetic methane in a Sabatier reaction. An example method includes using electrical energy to electrolyze water to produce hydrogen and oxygen, and reacting the hydrogen with carbon dioxide to produce synthetic methane in a Sabatier reaction.

HYDROCARBON PRODUCTION SYSTEM AND HYDROCARBON PRODUCTION METHOD

Resumen de: WO2026075057A1

A hydrocarbon production system (1) comprises: a carbon dioxide recovery device (10) that recovers carbon dioxide and water from air in the atmosphere; a hydrogen production device (30) that produces hydrogen from the water recovered by the carbon dioxide recovery device (10); and a hydrocarbon production device (40) that produces a reaction product containing hydrocarbons from a starting material containing the carbon dioxide recovered by the carbon dioxide recovery device (10) and the hydrogen produced by the hydrogen production device (30).

REGOLITH HEATING AND HYDROLOX FUEL PRODUCTION VIA ENERGY FROM A NUCLEAR POWERED BRAYTON CYCLE

Resumen de: US20260098488A1

0000 A system powered by a nuclear reactor to heat regolith, extract water from the regolith, perform electrolysis on the water to produce hydrogen and oxygen, and liquify the hydrogen and oxygen to produce fuel is presented. For example, among other possible celestial bodies, the regolith may be lunar regolith and the system may operate on the Moon to perform these activities on the Moon. The system may operate in a permanent shadow region of the Moon, such as at the bottom of a crater, where water-ice is present. In such regions, solar energy may not be available and thus a nuclear reactor provides a benefit in that it operates independently of solar illumination. Another benefit is that the primary loop of a nuclear reactor carries heat that may be used to heat regolith.

ELECTROLYZER SYSTEM REPAIR AND REVIVE TECHNIQUES

Resumen de: WO2026076343A1

A method for repairing, rejuvenating or reviving at least one aging, or degraded, or underperforming electrolyzer cell, including an oxygen electrode and a hydrogen electrode in to improve, or to enhance electrolysis efficiency and/or to extend the service lifetime of the electrolyzer cell. The method includes providing one or more activation solutions to the electrolyzer cell. The method also includes providing one or more deposition solutions including one or more metal ions to deposit the one or more metals onto at least one of the oxygen electrode and hydrogen electrode after providing the one or more activation solutions. Further, the method includes forming an oxygen evolution reaction (OER) electrocatalyst onto the oxygen electrode using an OER precursor solution, a hydrogen evolution reaction (HER) electrocatalyst onto the hydrogen electrode using a HER precursor solution, or both, after providing the one or more deposition solutions.

DIRECT AIR CAPTURE-BASED RESOURCE RECOVERY SYSTEM

Resumen de: WO2026075463A1

A direct air capture resource recovery apparatus, according to one embodiment of the present invention, comprises: a carbon dioxide capture device (100) which directly captures carbon dioxide in the atmosphere; a carbon dioxide desorption device (200) which uses a calcination furnace and desorbs carbon dioxide from carbonates generated in the carbon dioxide capture device; a carbon dioxide purification device (300) which uses a purification column and separates and purifies carbon dioxide desorbed in the carbon dioxide desorption device into liquefied carbonic acid and carbon dioxide; a hydrogen production device (600) which produces hydrogen by using a water electrolysis device; a sustainable aviation fuel (SAF) production device (400) which produces SAF by mixing liquefied carbonic acid obtained from the carbon dioxide purification device and hydrogen obtained from the hydrogen production device; an artificial gravel production device (500) which produces artificial gravel by using at least one of carbon dioxide captured in the carbon dioxide capture device, carbon dioxide obtained from the carbon dioxide purification device, or carbon dioxide unreacted and discharged from the SAF production device; and a calcium carbonate production device (700) which produces calcium carbonate by using at least one of carbon dioxide captured in the carbon dioxide capture device, carbon dioxide obtained from the carbon dioxide purification device, or carbon dioxide unreacted and discharged

POWER CONTROL DEVICE, POWER CONTROL METHOD, AND POWER CONTROL PROGRAM

Resumen de: WO2026074941A1

A power control device according to one aspect disclosed herein controls SOEC power supply using power based on renewable energy. This power control device comprises: a power separation unit that separates power based on renewable energy into a first power component and a second power component; a heat generation device that generates thermal energy using the first power component; a heat storage device that stores the thermal energy and outputs steam; and a cell stack that generates hydrogen using the second power component and the steam. The first power component includes a fluctuation component of the power based on renewable energy.

TWIN-STACK ELECTROLYSIS SYSTEM AND A METHOD OF OPERATING IT

Resumen de: WO2026073537A1

Twin-stack electrolysis system and a method of operating it An electrolysis system (1) comprising a first electrolyzer stack (2A) and a second elec trolyzer stack (2B) for producing hydrogen gas. Liquid-electrolyte is pumped by a pump (4) from the liquid-electrolyte supply (3) through a common conduit (5) to a split point (6) at which the electrolyte from the common conduit (5) is split into a first portion fed into the first stack (2A) through a first feedline (7A) and a second portion that is fed into the second stack (2B) through a second feedline (7B). The second feedline (7B) but not the first feedline (7A) comprises an adjustable throttle (8) that is configured for variably decreasing the second flow rate through the throttle (8). The first feedline (7A) is configured to have a first flow rate that is smaller than a second flow rate flow through the second feedline (7B) when the throttle (8) of the second feedline is fully open, and the throttle (8) is configured for variably decreasing the second flow rate through the throttle (8) and the second feedline (7B) to second flow rates lower than the first flow rate through the first feedline (7A).

METHOD FOR IMPROVING EFFICIENCY OF WATER ELECTROLYSIS SYSTEM, APPARATUS AND SYSTEM THEREFOR

Resumen de: US20260098347A1

0000 A method for improving the efficiency of a water electrolysis system and a system therefor are disclosed. The system includes a stack, a power source configured to supply a voltage to an anode and a cathode of the stack, and a contact electrification pipe connected to the anode such that a fluid circulates within the pipe. The fluid includes at least water. Electric power generated in the contact electrification pipe is supplied to the power source to improve power efficiency.

AMMONIA DECOMPOSITION FACILITY

Resumen de: WO2026074759A1

This ammonia decomposition facility comprises: a light collection device; an ammonia decomposition device; a detection device; and a control device. The light collection device collects sunlight. An ammonia decomposition unit decomposes ammonia using, as a heat source, the sunlight collected by the light collection device to generate hydrogen. The detection device detects at least one physical quantity selected from the group consisting of the irradiation quantity of sunlight and the temperature of the ammonia decomposition device. The control device controls the quantity of ammonia supplied to the ammonia decomposition device according to the physical quantity detected by the detection device.

OXYGEN EVOLUTION CATALYST COMPOSITIONS, FORMS, AND MANUFACTURING OF THE SAME

Resumen de: US20260098351A1

A catalyst for an electrode of an electrolytic cell, comprising a metal-containing substance having at least two of the three elements Nickel (Ni), Iron (Fe), and Chromium (Cr).

ELECTROLYSIS SYSTEM, AND METHOD FOR OPERATING AN ELECTROLYSIS SYSTEM

Nº publicación: AU2024352615A1 09/04/2026

Solicitante:

SIEMENS ENERGY GLOBAL GMBH & CO KG

Resumen de: AU2024352615A1

The invention relates to an electrolysis system (100) comprising: a wind turbine (1); an electrolysis plant (5) which is connected to the wind turbine (1) in order to supply electrolysis current, wherein an island network is implemented without connection to a power supply network; and a heat supply device (7) which is coupled to the electrolysis plant (5) and can be operated with a working medium (23), and which has an evaporator (13) and a condenser (11), and which is designed in such a way that, during a standstill mode, condensation heat of the working medium (23) can be transferred to the electrolysis plant (5) by means of the condenser (11) so as to maintain the temperature above a minimum temperature. During a standstill mode, the heat supply device (7) evaporates a working medium and condenses the evaporated working medium (23), condensation heat being generated and transferred to the electrolysis plant (5) so as to maintain the temperature above a minimum temperature and prevent freezing of water-carrying components of the electrolysis plant (5).