An electrode suitable for use as a cathode for the development of hydrogen in industrial electrolytic processes, equipped with a catalytic coating having an external layer containing ruthenium and selenium; and a method for the production of the same.

An electrode suitable for use as a cathode for the development of hydrogen in industrial electrolytic processes, equipped with a catalytic coating having an external layer containing ruthenium and selenium; and a method for the production of the same.

A system for synthesizing ammonia includes a reactor including an inlet portion, an outlet portion, and an energy source arranged to deliver energy to one or more reactants receivable through the inlet portion of the reactor, and the energy source activatable to reduce nitrogen to ammonia in the presence of hydrogen, at least one hydrogen pump in fluid communication with the outlet portion of the reactor, each hydrogen pump including at least one electrochemical cell, and a recirculation circuit in fluid communication between the at least one hydrogen pump and the inlet portion of the reactor and configured to direct a respective hydrogen stream from each hydrogen pump to the inlet portion of the reactor.

An ozone generator system utilizes an electrochemical cell to produce and control ozone concentrations within an enclosure or to supply ozone to a flow conduit. The enclosure may he coupled with a flow conduit that carries the produced ozone to a desired location. An enclosure may be a sterilization chamber and the concentration of ozone produced by the ozone generating system may be sufficient to sterilize articles within the enclosure. An oxygen control electrolyzer cell and/or humidity control electrolyzer cell may be coupled with the enclosure to further control the environment of the enclosure. A humidity control electrolyzer cell may be fluidly coupled with the ozone generator to supply humidity for reaction on the anode of the ozone generator.

The present invention discloses a modular health gas generator, more particularly, to a modular health gas generator with an automatic circulation and a cooling function. Then, the gas production rate of the hydrogen-oxygen gas can be controlled by a plurality of freely detachable electrolytic tanks. The invention comprises an inner tank and the plurality of detachable electrolytic tanks. In application, a hollow portion of each electrolytic tank can be inputted or supplied the liquid water from the inner tank. The liquid water is electrolyzed in the electrolytic tank to generate the hydrogen-oxygen gas and be output to the inner tank, and then the hydrogen-oxygen gas will be further outputted through a gas outlet of the inner tank.

A distributed hydrogen generating fence is formed from a plurality of electrolysis units and fence posts. Each unit includes one or more PV cells, an associated electrolysis system powered by electricity generated by the one or more PV cells, and a feed header for feeding water and an electrolyte to the electrolysis system. The electrolysis system is inside the feed header, and is operable to produce hydrogen and oxygen. The units are located between and are supported by mutually adjacent fence posts. The feed header extends in an inclined manner between the mutually adjacent fence posts. A gas header conducts at least the hydrogen from each of the plurality of units to a first remote facility. The fence includes openings allowing the passage of animals, people or vehicles. The openings can be controlled by a gate, or a grate laid across a hole in the ground spanning the opening.

A distributed hydrogen generating fence is formed from a plurality of electrolysis units and fence posts. Each unit includes one or more PV cells, an associated electrolysis system powered by electricity generated by the one or more PV cells, and a feed header for feeding water and an electrolyte to the electrolysis system. The electrolysis system is inside the feed header, and is operable to produce hydrogen and oxygen. The units are located between and are supported by mutually adjacent fence posts. The feed header extends in an inclined manner between the mutually adjacent fence posts. A gas header conducts at least the hydrogen from each of the plurality of units to a first remote facility. The fence includes openings allowing the passage of animals, people or vehicles. The openings can be controlled by a gate, or a grate laid across a hole in the ground spanning the opening.

The present invention relates to an energy storage system (10) comprising a plurality of electrical module packs (12) connected in series, each electrical module pack (12) having a positive terminal and a negative terminal, the voltage at the terminals of each electrical module pack (12) being equal to the potential difference between the positive terminal and the negative terminal of the pack (12), the voltage at the terminals of the system (10) being equal to the sum of the voltages of the connected electrical module packs (12), each electrical module pack (12) being supported by a frame (20), each frame (20) being set at a reference potential, characterized in that the reference potential of each frame (20) is broadly between the positive terminal potential and the negative terminal potential of the electrical module pack (12) supported by the frame.

The present invention relates to an energy storage system (10) comprising a plurality of electrical module packs (12) connected in series, each electrical module pack (12) having a positive terminal and a negative terminal, the voltage at the terminals of each electrical module pack (12) being equal to the potential difference between the positive terminal and the negative terminal of the pack (12), the voltage at the terminals of the system (10) being equal to the sum of the voltages of the connected electrical module packs (12), each electrical module pack (12) being supported by a frame (20), each frame (20) being set at a reference potential, characterized in that the reference potential of each frame (20) is broadly between the positive terminal potential and the negative terminal potential of the electrical module pack (12) supported by the frame.

To make it possible to detect whether leakage is external leakage or cross leakage in a water electrolyzer, a valve installed in an oxygen-side path, and a valve installed in a hydrogen-side path are closed; a water electrolysis reaction at a water electrolytic cell is progressed, and leakage in the oxygen-side path and leakage in the hydrogen-side path are determined based on the change in an internal pressure; and a differential pressure is made between the oxygen-side path and the hydrogen-side path, and leakage from a solid polymer electrolyte membrane is determined based on the change in the differential pressure.