Hidrógeno electrolítico

WATER ELECTROLYSIS SYSTEM

Resumen de: EP4421210A1

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

PROTON-EXCHANGE MEMBRANES FOR ELECTROCHEMICAL REACTIONS

Resumen de: CN118119649A

A proton conducting polymer has a plurality of repeating units of formula (I) for use in electrochemical reactions. The polymers can be synthesized from superacid-catalyzed polyhydroxyalkylation reactions of monomers Ar1 ', Ar2' and X1 ', followed by nucleophilic substitution or grafting reactions, and optionally acidification reactions, Proton exchange membranes and membrane electrode assemblies made from the polymers are also described. # imgabs0 #

METHOD AND REACTOR SYSTEM FOR SPLITTING WATER AND/OR CARBON DIOXIDE

Resumen de: AU2022368740A1

Methods and systems for splitting one or more of water and carbon dioxide are disclosed. Exemplary methods can operate under substantially isothermal conditions. The methods can include use of a material including two or more spinel phases in a solid solution. The solid solution can include oxygen, aluminum, and one or more transition metals.

OFFSHORE WIND TURBINE AND METHOD FOR OPERATING AN OFFSHORE WIND TURBINE

Resumen de: EP4421314A1

An offshore wind turbine (1), comprising:a generator (5) for generating electrical power from wind power,a hydrogen production apparatus (10) for converting water (W) into hydrogen (H) by means of the generated electrical power, anda water-intake apparatus (15) for taking in water (W) from the sea (16) and/or an open water reservoir and supplying the water (W) to the hydrogen production apparatus (10),wherein the water-intake apparatus (15) comprises at least one UV-irradiation unit (22) for irradiating the water (W) .By use of the at least one UV-irradiation unit, the water supplied from the water-intake apparatus to the hydrogen production apparatus can be treated with UV-light for providing an antifouling treatment.

OFFSHORE WIND TURBINE AND METHOD FOR OPERATING AN OFFSHORE WIND TURBINE

Resumen de: EP4421315A1

An offshore wind turbine (1), comprising:a hydrogen production apparatus (10) for converting water (W) into hydrogen (H),a water-intake apparatus (15) comprising a first and second pump (24, 25) for pumping water (W) from the sea (16) to the hydrogen production apparatus with a predetermined desired total pumping capacity (P_d), the first and second pumps having first and second current pumping capacities (P_c1, P_c2), respectively, anda control device (26) for controlling the first and second pumps such that:both the first and second current pumping capacities are non-zero and their sum is equal to or larger than the desired total pumping capacity, and/orthe first and second pumps alternatingly deliver the predetermined desired total pumping capacity.By having the two pumps and avoiding long idle times of the pumps, the availability of the water-intake apparatus is increased.

SYSTEM FOR INTEGRATED NITRIC ACID AND AMMONIA PRODUCTION AND METHOD OF PRODUCTION THEREOF

Resumen de: EP4421040A1

The present disclosure relates to the field of integrated nitric acid and ammonia production. The nitric acid tail gas is, following depletion in NOx to 100 ppm or less, combined with hydrogen at least partly produced from a water electrolyzer. The tail gas being combined with hydrogen or the combined tail gas and hydrogen gas is further treated for removal of NO_x, CO, CO₂ and O₂ and compressed for synthesizing ammonia. At least part of the compression is performed prior to the further treatment of the nitric acid tail gas being combined with hydrogen, or prior to the treatment of the combined tail gas and hydrogen gas.

An air additive system

Resumen de: GB2627423A

A stand-alone, electronically controlled system of producing real-time responsive, controlled hydrogen as an air additive for an internal combustion engine 2 or oil-fired heating system described. A plurality of hydrogen electrolyser cells 4, with membranes, are in communication with a power supply and the produced oxygen is vented to the atmosphere and the hydrogen outlet configured for use with an air inlet 7 of an internal combustion engine 2 (ICE) or an oil-fired heating system. An electronic hydrogen monitoring device (HECU) 3 controls the operation of the cells 4 via an engine sensor and thus varies the amount of power supplied to the cells 4 dependent on the interpolation of signals from the engine sensor.

ELECTROLYSIS UNIT FOR OBTAINING GASEOUS PRODUCTS

Resumen de: AU2022394749A1

The intervention relates to an electrolysis unit A fluid manifold system is feeding electrolytic solution into the electrolytic cells and discharging the electrolytic solution out of the electrolytic cells. The cavity of an expandable closing means is pressurized so that its shell expands and the volume of the cavity increases. The expandable closing means is arranged within the fluid manifold system, so that the fluid manifold system is open for the passage of electrolytic solution if the expandable closing means is in a depressurized state and the fluid manifold system is closed for the passage of electrolytic solution if the expandable closing means is in a pressurized state.

METHOD FOR THE PRODUCTION OF HYDROGEN

Resumen de: CA3235030A1

The present invention relates to a method for electrolysis of water (1 ) by means of a device (7) comprising a reversible cell for the production of hydrogen and oxygen. A solution of potassium hydroxide (KOH) is fed into the cell at a concentration of between 35% and 55% w/v, at a temperature of between 150°C and 374°C, and in a condition of minimum pressure of between 2.2 bar and 129.1 bar. The method provides for I) preparing in the mixer the aqueous alkaline solution of KOH having a concentration of potassium hydroxide (KOH) of between 35% and 55% w/v; II) heating said aqueous alkaline solution to a temperature of between 150°C and 374°C; III) increasing the pressure to maintain the aqueous alkaline solution in the liquid phase at a minimum pressure condition of between 2.2 bar and 129.1 bar; IV) passing the water through the hydrophobic layer (3) of each electrode and reaching the respective catalyst layer (5) to catalyse a reduction phase of said hydrogen or an oxidation phase of said oxygen and the porous electrode layer (4) to carry out said reduction and said oxidation respectively; V) collecting gaseous hydrogen and oxygen released from phase IV).

PRESSURISED ELECTROLYSER

Resumen de: CN118140012A

The invention relates to an electrolytic cell (100) for generating hydrogen, comprising: a housing (102) comprising an electrolyte chamber (104); two electrodes (108, 112) for decomposing the electrolyte water, at least one of the two electrodes being permeable to gases produced by the decomposition of the electrolyte water, where the at least one permeable electrode (108) has a first surface (114) facing the electrolyte chamber and a second surface (116) facing the first gas collection chamber (106); an electrolyte supply circuit (130) for supplying electrolyte water to the electrolyte chamber; and a control unit (160) and/or a mechanical control for controlling a pressure drop across the at least one permeable electrode between the electrolyte chamber and the first gas collection chamber.

AN OXYGEN EVOLUTION REACTION ELECTRODE CATALYST ASSEMBLY COMPRISING DENDRITIC NICKEL FOAM, ITS USE AND A METHOD TO PRODUCE SAID ASSEMBLY

Resumen de: CA3234979A1

The present disclosure relates to a method to produce an oxygen evolution reaction electrode catalyst assembly comprising a dendritic nickel foam. The method is remarkable in that it comprises the steps of (a) providing a dendritic nickel foam material; (b) etching the dendritic nickel foam material by placing it in a etch solution being an acidic aqueous solution or an aqueous solution of metal chloride and recovering an etched dendritic nickel foam with nickel dendrites showing a chimney-like structure.

HYDROGEN GENERATION DEVICE

Resumen de: EP4421024A1

A device for generating hydrogen (100) from water in a liquid state comprising a hydrolysis chamber (101) which is configured to contain a variable volume of water in a liquid state at ambient temperature and atmospheric pressure, this volume of water being the element processed to obtain hydrogen and other gases by the implosion of a plurality of bubbles generated inside the hydrolysis chamber (101) due to a change in pressure conditions; and a second gas chamber (110) separated from the first hydrolysis chamber (101) by means of gas separation means (106,107); and wherein said second gas chamber (110), in its upper part, comprises a gas outlet (103) configured to facilitate the exit of the gases resulting from the process.

WATER ELECTROLYSIS ELECTRODE STRUCTURE, WATER ELECTROLYSIS MEMBRANE ELECTRODE ASSEMBLY, AND WATER ELECTROLYSIS DEVICE

Resumen de: EP4421211A1

An object of the present invention is to provide an electrode assembly for water electrolysis, in which an electrolyte membrane is kept from being deteriorated. The present invention provides an electrode structure for water electrolysis, including an anode electrode and a cathode electrode disposed to face each other, characterized in that at least one of the anode electrode and the cathode electrode includes a porous component and a reticular component in order from the facing surface side, and the standard deviation of a pressure distribution at the surface of contact between the anode electrode and the cathode electrode, determined by the following measurement method, is 2.7 MPa or less.<Measurement Method>After a test piece that has a pressure measurement film sandwiched between the anode electrode and the cathode electrode is pressurized at 4 MPa for 2 minutes, the pressure distribution obtained by a pressure analysis from a color image of the pressure measurement film, obtained from a pressure image analysis system, is defined as a pressure distribution at the surface of contact between the anode electrode and the cathode electrode, and the standard deviation of the pressure distribution is determined.

具有制氢系统的风力涡轮机

Resumen de: AU2022435941A1

A wind turbine is provided that comprises a nacelle (10) configured to be arranged on a wind turbine tower (103), a nacelle housing (11) of the nacelle (10), wherein the nacelle housing (11) is configured to house at least part of an electrical power generation system (20) of the wind turbine (100), and a hydrogen production system (30). The hydrogen production system (30) comprises an electrolyzer (31) configured to receive electrical power from the electrical power generation system (20), wherein the electrolyzer (31) is arranged inside said nacelle housing (11) of the nacelle (20) in which at least said part of the electrical power generation system (20) is arranged. One or more other components (32, 33, 34, 35, 36, 37, 38) of the hydrogen production system (30) are arranged at a base (105) of the wind turbine tower (103) and/or within the wind turbine tower (103).

具有氢气泄漏自检功能的氢气产生器

Resumen de: US2023272544A1

A hydrogen generator with hydrogen leakage self-aware function comprises an electrolytic module, an integrated passageway device, a condensate filter, a humidification cup, a housing, an internal hydrogen sensing component, and a monitoring device. The electrolytic module is configured to electrolyze an electrolyzed water to generate a gas comprising hydrogen. The integrated passageway device comprises gas inlet passageway and a gas outlet passageway. The condensate filter is configured for filtering the gas comprising hydrogen. The humidification cup is configured for humidifying the gas comprising hydrogen. The gas comprising hydrogen flows through the condensate filter and the humidification cup by the way of the integrated passageway device. The internal hydrogen sensing component is configured in the housing for sensing the hydrogen concentration in the housing to generate an internal sensing result. The monitoring device is coupled to the internal hydrogen sensing component. The monitoring device controls the operation of the hydrogen generator according to the internal sensing result to avoid the hydrogen generator from the problem caused by hydrogen.

碱性高压电解槽

Resumen de: WO2023118492A2

It is described a high-pressure alkaline electrolyzer for splitting water into hydrogen and oxygen, said electrolyzer comprising a stack of electrolysis cells (1), with channels supplying lye to the cathodes and anodes and channels conducting hydrogen from the cathodes and oxygen from the anodes. The electrolyzer includes first and second lye inlet channels (4a, 4b), a multitude of first intermediate lye channels (5a) conducting lye from the first lye inlet channel (4a) to each cathode (3a) in the stack, a multitude of second intermediate lye channels (5b) conducting lye from the second lye inlet channel (4b) to each anode (3b) in the stack, wherein the hydrogen conducting channels include a common hydrogen outlet channel (7a) and a multitude of intermediate hydrogen channels (8a) conducting hydrogen from each cathode (3a) to the common hydrogen outlet channel (7a), and the oxygen conducting channels include a common oxygen outlet channel (7b) and a multitude of intermediate oxygen channels (8b) conducting oxygen from each anode (3b) to the common oxygen outlet channel (7b).

水素発生材料及び水素発生材料の製造方法

Resumen de: JP2024114480A

【課題】原材料の比率が一定に保たれる水素発生材料を提供する。【解決手段】水素化ホウ素ナトリウムの粉末と、酸の粉末とを含む。【選択図】なし

熱インバータボックス

Resumen de: US2024238746A1

The invention relates to a thermal converter (1, 2) for generating from a parent compound a first fluid of first molecules (H2) with a first molecular weight and a second fluid of second molecules (O2) with a second molecular weight, whereby the first molecular weight of the first molecules (H2) is less than the second molecular weight of the second molecules (O2).In order to improve the efficiency of the thermal converter, the thermal converter comprises a spray device (18) for generating from the parent compound in fluid form a spray, which is supplied to a reaction device (1) for splitting the parent compound into a mixture compound of the first molecules (H2) and the second molecules (O2).

電解電力変換のための装置及び方法

Resumen de: CN117616156A

The object of the invention is a system for electrolytic power conversion, the system comprises electrolytic cell cells arranged as a battery pack (103) controllably connected in series, means (142) for electrolytic operation at a first voltage in the range of 1.0 V to 2.5 V per cell, and means (144) for at least intermittently withdrawing current from the battery pack at a second voltage in the range of 0.4 V to 1.0 V per cell. The system comprises at least one capacitor bank (146) held at a first voltage and at least one capacitor bank (148) held at a second voltage, the capacitor banks (146, 148) and the battery pack (103) having a common pole for connecting at least one bidirectional non-isolated DC/DC converter (150) of the first and second voltage capacitor banks. The system further comprises means (152) for controlling the first and second voltage levels and, for each controllable battery pack (103), at least one half-bridge switch pair (154) for individually alternating between the first and second voltage levels applied to the battery pack (103) to prevent imbalance aggravation and battery degradation.

电解槽

Resumen de: WO2023099877A2

An electrolyser (200) comprising: a cathode structure comprising a first PCB plate (202) and an electrically conductive substrate (220); an anode structure comprising a second PCB plate (204) and an electrically conductive substrate (220); an anion exchange membrane (218) located between the cathode structure (202) and the anode structure (204); two transport layers, (214, 216), one transport layer (216) disposed between the anode structure (204) and the anion exchange membrane (218) and one transport layer (214) disposed between the cathode structure (202) and the anion exchange membrane (218); and at least one fluid path to supply an electrolyte to the electrolyser (200).

以MOx共催化剂改质的单晶TA3N5纳米粒子、催化剂、使用所述催化剂进行水分解的方法和制造所述催化剂的方法

Resumen de: AU2023220958A1

Tantalum nitride and specifically a novel Ta

用于调节电解系统的方法

Resumen de: AU2023218352A1

A start-up process for conditioning an electrolysis system containing ionically conductive membrane, such as a poly electrolyte multilayer coated proton exchange membranes, to reduce the break-in period is described. The conditioning involves heating the electrolysis feed, the electrolysis system, or both at a temperature above the desired operating temperature to achieve faster startup. In some cases, the voltage is controlled to avoid damage to the sample.

Electrolyser unit comprising a plurality of individual electrolyser stacks and method for connecting electrolyser units

Resumen de: DK202300143A1

The invention comprises a method for connecting a pair of electrolyser stacks with electrolyte, electric current and gas drain piping. Accordingly, each pair of stacks of the electrolyser: a. through interconnection endplates are supplied with alkaline electrolyte at elevated pressure by common electrolyte supply pipes and further, b. through the interconnection endplate drain off oxygen gas containing electrolyte, and hydrogen gas containing electrolyte, to common gas separation vessels for oxygen and hydrogen respectively, c. pull first electrically interconnected current injection electrodes adjacent to interconnection endplates to zero electrical potential through a zero potential conductor, and d. supply second current injection electrodes placed adjacent to distal endplates with electric current at potentials equally higher and lower respectively than the zero potential at the first electrodes.

ELECTROLYTIC GENERATOR, WATER TREATMENT ASSEMBLY, WATER HEATER ASSEMBLY, AND WATER HEATING SYSTEM

Resumen de: WO2024169471A1

An electrolytic generator (100), a water treatment assembly (1000), a water heater assembly, and a water heating system. The electrolytic generator (100) comprises a housing (10), an anode (20), and a cathode (30). An electrolysis chamber (10a) is formed in the housing (10), the housing (10) is provided with a first water inlet (111) and a first water outlet (112) which are in communication with the electrolysis chamber (10a), and the first water inlet (111) is used for being communicated with a drainage hole of a water heater; the anode (20) is provided with an anode plate (21), and the anode plate (21) is provided in the electrolysis chamber (10a); the cathode (30) is provided with a cathode plate (31), and the cathode plate (31) is provided in the electrolysis chamber (10a) and is spaced apart from the anode plate (21).

METHOD OF PRODUCING GREEN HYDROGEN FROM PYRITE RECOVERED FROM MINE WASTE

Nº publicación: WO2024170774A1 22/08/2024

Solicitante:

H2 SPHERE GMBH [DE]
H2-SPHERE GMBH

Resumen de: WO2024170774A1

The present invention relates to a method of producing green hydrogen and associated products from pyrite separated from mine waste (e.g., disposed tailings or active tailings streams) in an energetically self-sustained process. This is achieved by a method according to the present invention comprising the following steps: (a) separation and enrichment of a mine waste material comprising pyrite to obtain a pyrite concentrate, (b) oxidation of the pyrite concentrate to obtain SO2 gas; (c) separation of the SO2 gas; (d) utilization of SO2 gas from step (c) to generate H2 gas and H2SO4 via a SO2-depolarized electrolyzer (SDE) process or a sulfur-iodine-cycle (S-I-cycle) process.