Provided is a method of controlling a load of a water electrolysis stack in which a plurality of water electrolysis cells including an anode disposed on one side and a cathode disposed on the other side with a solid polyelectrolyte film interposed are stacked and housed. The method includes determining an appropriate load based on a condition of an inside of the water electrolysis stack obtained from at least one of a temperature of the inside of the water electrolysis stack, an electrical resistance, or a water flow rate, and changing application of the load on the water electrolysis stack such that the load is the appropriate load.

Provided is a method of controlling a load of a water electrolysis stack in which a plurality of water electrolysis cells including an anode disposed on one side and a cathode disposed on the other side with a solid polyelectrolyte film interposed are stacked and housed. The method includes determining an appropriate load based on a condition of an inside of the water electrolysis stack obtained from at least one of a temperature of the inside of the water electrolysis stack, an electrical resistance, or a water flow rate, and changing application of the load on the water electrolysis stack such that the load is the appropriate load.

An electrochemical hydrogen pump according to the present disclosure includes: a cell including an electrolyte membrane, an anode disposed on a first main surface of the electrolyte membrane, and a cathode disposed on a second main surface of the electrolyte membrane; a voltage applicator applying a voltage between the anode and the cathode, the voltage applicator applying the voltage to cause the electrochemical hydrogen pump to transfer hydrogen in hydrogen-containing gas supplied to the anode to the cathode and to pressurize the hydrogen; and a controller, when at least one selected from the group consisting of a dew point of the hydrogen-containing gas supplied to the anode and a temperature of the cell is increased, controlling the voltage applied by the voltage applicator to increase a current flowing between the anode and the cathode.

There are provided system for preparing lithium hydroxide from an aqueous composition comprising a lithium compound and use of the system thereof to prepare lithium hydroxide, the system comprising an electrochemical cell, a pH probe and at least one inlet for receiving acid or base for maintaining pH. For example, the lithium compound can be lithium sulphate and the aqueous composition can be at least substantially maintained at a pH having a value of about 2 to about 4.

The present invention provides a gas generator, comprising a water tank and an electrolysis device. The water tank has a first hollow portion for containing electrolyzed water. The electrolysis device is disposed inside the first hollow portion of the water tank for electrolyzing the electrolyzed water to generate a hydrogen-oxygen mixed gas. When the electrolysis device starts to electrolyze the electrolyzed water, the first hollow portion of the water tank is filled with the electrolyzed water for standing at a full level of water. And after the electrolysis device electrolyzed the electrolyzed water, the level of water for the electrolyzed water filled into the first hollow portion of the water tank is higher than 95% of the full level of water. The gas generator of the present invention provides the design for saving space and nearly a zero gas chamber to reduce the possibility of explosions resulting from hydrogen-oxygen mixed gas.

A modular solid oxide electrolyzer cell (SOEC) system including a stack of electrolyzer cells configured to receive steam in combination with hydrogen, and a steam recycle outlet configured to recycle a portion of the steam.

A modular solid oxide electrolyzer cell (SOEC) system including a stack of electrolyzer cells configured to receive steam in combination with hydrogen, and a steam recycle outlet configured to recycle a portion of the steam.

One variation of an electrolyzer system includes a skid loaded with a set of modules including a feed-supply module, configured to generate a feed mixture of carbon dioxide and water, and, an electrolysis module including: a cell stack arranged within an insulated housing and configured to receive metered volumes of the feed mixture from the feed-supply module to generate a fuel mixture of syngas, water, and carbon dioxide via electrolysis; and a set of heating elements configured to regulate temperature of the cell stack within a target temperature range and regulate temperatures of the feed mixture, the air mixture, and the fuel mixture within the insulated housing. The skid can further include: a processing module configured to extract syngas from the fuel mixture received from the electrolysis module; and a power module configured to drive a voltage across the cell stack to promote electrolysis of the feed mixture.

One variation of an electrolyzer system includes a skid loaded with a set of modules including a feed-supply module, configured to generate a feed mixture of carbon dioxide and water, and, an electrolysis module including: a cell stack arranged within an insulated housing and configured to receive metered volumes of the feed mixture from the feed-supply module to generate a fuel mixture of syngas, water, and carbon dioxide via electrolysis; and a set of heating elements configured to regulate temperature of the cell stack within a target temperature range and regulate temperatures of the feed mixture, the air mixture, and the fuel mixture within the insulated housing. The skid can further include: a processing module configured to extract syngas from the fuel mixture received from the electrolysis module; and a power module configured to drive a voltage across the cell stack to promote electrolysis of the feed mixture.

A system for improving efficiency of an internal combustion engine includes an electronic controller generating an RF signal and an electrolysis reactor electrically connected to the electronic controller. The electrolysis reactor includes a plurality of substantially parallel plates arranged in a stack. The plurality of plates includes a central positive plate, a first positive end plate, and a second positive end plate. The plurality of plates also includes a first negative plate located in the stack equidistantly between the central positive plate and the first positive end plate, and a second negative plate located in the stack equidistantly between the central positive plate and the second positive end plate. The plurality of plates further includes a plurality of neutral plates. The system also includes an aqueous solution flowing through the electrolysis reactor, the solution containing an electrolyte.