Provided herein are membrane electrode assemblies (MEAs) for carbon oxide reduction. According to various embodiments, the MEAs are configured to address challenges particular to CO.sub.x including mitigating the deleterious effects of electrical current fluctuations on the MEA. Bipolar membrane MEAs equipped with an interface composed of nanoparticles are described.

Electrolysis arrangement for producing hydrogen by electrolysis that can include a first input terminal configured to supply electrical energy to the electrolysis arrangement; a second input terminal configured to supply electrical energy to the electrolysis arrangement; a first transformer; a second transformer; a first group of electrolysis stacks, which comprises a first sub-group and a second sub-group; a second group of electrolysis stacks which comprises a first sub-group and a second sub-group, wherein the electrolysis stacks of the first group are spatially separated from the electrolysis stacks of the second group, wherein the electrolysis stacks of the first sub-group of the first group and of the first sub-group of the second group are electrically connected via the first transformer to the first input terminal, and wherein the electrolysis stacks of the second sub-group of the first group (A) and of the second sub-group of the second group are connected electrically via the second transformer to the second input terminal.

Electrolysis arrangement for producing hydrogen by electrolysis that can include a first input terminal configured to supply electrical energy to the electrolysis arrangement; a second input terminal configured to supply electrical energy to the electrolysis arrangement; a first transformer; a second transformer; a first group of electrolysis stacks, which comprises a first sub-group and a second sub-group; a second group of electrolysis stacks which comprises a first sub-group and a second sub-group, wherein the electrolysis stacks of the first group are spatially separated from the electrolysis stacks of the second group, wherein the electrolysis stacks of the first sub-group of the first group and of the first sub-group of the second group are electrically connected via the first transformer to the first input terminal, and wherein the electrolysis stacks of the second sub-group of the first group (A) and of the second sub-group of the second group are connected electrically via the second transformer to the second input terminal.

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

Safe anode for electrochemical cells, of the type of vertical anodes constituted of a hanging structure based on a first horizontal bar, second vertical distribution bars defined by a copper or aluminum core with a titanium exterior layer, and coated or uncoated titanium anode plates attached to the second distribution bars, on both sides, such that the safe anode incorporates an adapter element that comprises, at least, one current limiter assembly, arranged between, at least, one of the second vertical distribution bars, and, at least, one coated or uncoated titanium anode plate, connecting the vertical distribution bar to the coated or uncoated titanium anode plate.

The invention provides a bipolar system comprising two or more electrochemical cells and a bipolar connector operable as a shunt current suppression device positioned in a flow path of an electrolyte solution flowing between the cells.

The invention provides a bipolar system comprising two or more electrochemical cells and a bipolar connector operable as a shunt current suppression device positioned in a flow path of an electrolyte solution flowing between the cells.

The following disclosure relates to methods of identifying defects (e.g., short circuits) in a membrane of an electrolytic cell. The following disclosure further relates to methods of repairing such a defect in the membrane of the electrolytic cell, particularly without having to disassemble the membrane from adjacent components of the electrolytic cell.

The following disclosure relates to methods of identifying defects (e.g., short circuits) in a membrane of an electrolytic cell. The following disclosure further relates to methods of repairing such a defect in the membrane of the electrolytic cell, particularly without having to disassemble the membrane from adjacent components of the electrolytic cell.

Systems and methods are provided for operating an electrolyzer. The systems and methods perform operations comprising extracting, by monitoring circuitry coupled to a plurality of electrolytic cells of an electrolyzer, a set of features comprising at least one of a goodness-of-fit measurement or direct current (DC) measurement of the plurality of electrolytic cells; tracking changes to the set of features over a time period; and generating, based on the changes to the set of features, a model representing operating conditions of the electrolytic cells on an individual electrolytic cell basis.