A system and methods for electrolysis of saline solutions are provided. An exemplary system provides a tandem electrolysis cell. The tandem electrolysis cell includes a common enclosure that has two chambers. A first chamber is separated from a second chamber by a cation selective membrane. A common anode and a first cathode (cathode A) are disposed in the first chamber. The first cathode and the common anode are configured to electrolyze a saline solution to hydrogen and oxygen. A second cathode (cathode B) is disposed in the second chamber. The second cathode and the common anode are configured to electrolyze a brine solution in the first chamber to form chlorine and water in the second chamber to form hydrogen and hydroxide ions.

An electrochemical hydrogen pump includes: a cell including a proton conductive electrolyte membrane having a first main surface and a second main surface, a cathode disposed on the first main surface of the proton conductive electrolyte membrane, and an anode disposed on the second main surface of the proton conductive electrolyte membrane; a voltage applier that applies a voltage between the anode and the cathode; a cooler that cools the cell; and a controller that controls the cooler to increase an amount of cooling per unit time of the cell when a pressure of a cathode gas flow path on the cathode increases.

This invention relates to a system comprising one or more electrolysis cell(s) and at least one power electronic unit that supplies the cell(s) with a fluctuating voltage, and to a method for operating one or more electrolysis cell(s), comprising providing one or more voltage fluctuations to the electrolysis cell(s) by at least one power electronic unit, enabling the provision of a low-cost electrolysis system which simultaneously allows for fast-response dynamic operation, improved electrolysis efficiency, increased lifetime and high impurity tolerance.

This invention relates to a system comprising one or more electrolysis cell(s) and at least one power electronic unit that supplies the cell(s) with a fluctuating voltage, and to a method for operating one or more electrolysis cell(s), comprising providing one or more voltage fluctuations to the electrolysis cell(s) by at least one power electronic unit, enabling the provision of a low-cost electrolysis system which simultaneously allows for fast-response dynamic operation, improved electrolysis efficiency, increased lifetime and high impurity tolerance.

A HOCl manufacturing system is disclosed for production of high potency, safe, consistently pure, stable, authentic HOCl in a deployable, portable, high volume, localized manufacturing unit. The electrolysis method uses a deployable, remote-controlled manufacturing system. The method includes: controlling water flow rate into an electrolysis chamber by providing feedback controlled water pressure; applying feedback controlled current to the electrolysis chamber via an adjustable and high-current power supply; adding sodium chloride brine, via a feedback controlled actuator, to an anode chamber inlet and creating an aqueous mixture; adding sodium hydroxide, via a feedback controlled actuator, to the aqueous mixture; and producing aqueous hypochlorous acid free from hypochlorites, phosphates, oxides, and stabilizers.

Provided is a method for producing fluorine gas, capable of suppressing clogging of pipes and valves with mist. Fluorine gas is produced by a method including electrolyzing an electrolyte in an electrolytic cell, measuring the water concentration in a fluid generated in a cathode chamber in the electrolyzing, and sending a fluid generated in the inside of the electrolytic cell in the electrolyzing the electrolyte, from the inside to the outside of the electrolytic cell through a flow path. In the sending, the flow path in which the fluid flows is switched in accordance with the water concentration measured in the measuring the water concentration.

Provided is a method for producing fluorine gas, capable of suppressing clogging of pipes and valves with mist. Fluorine gas is produced by a method including electrolyzing an electrolyte in an electrolytic cell, measuring the water concentration in a fluid generated in a cathode chamber in the electrolyzing, and sending a fluid generated in the inside of the electrolytic cell in the electrolyzing the electrolyte, from the inside to the outside of the electrolytic cell through a flow path. In the sending, the flow path in which the fluid flows is switched in accordance with the water concentration measured in the measuring the water concentration.

A method of recovering performance of a water electrolysis system is a method of recovering performance of a water electrolysis system which includes a water electrolysis stack having a solid polymer membrane, a positive electrode, and a negative electrode, the method including the steps of: bringing an operating state of the water electrolysis system into a state of low-temperature operation in which a temperature of water is lower than a temperature of water during ordinary operation in which water electrolysis is carried out by the water electrolysis stack; and in the state of the low-temperature operation, passing an electric current through each of the positive electrode and the negative electrode.

Topic: The purpose is to provide an oxygen and hydrogen mixed gas generator and a method for producing oxygen and hydrogen mixed gas stably by electrolyzing, and the resulting oxygen and hydrogen mixed gas thereto. Solution: an oxygen hydrogen mixed gas generator (1) is provided with an electrolyze device (10), wherein a first electrode (11) and a second electrode (12) are immersed in water for electrolyzing; and a power supply device (50), supplies the specified current to the first electrode (11) and the second electrode (12), the oxygen hydrogen mixed gas generator (1) mixes the oxygen and hydrogen generated from the electrodes to produce the oxygen hydrogen mixed gas, which is characterized in that the power supply device (50) reverses the polarity of the first electrode (11) and the second electrode (12) alternately.

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.