Electrolyzer devices (e.g., for Brown's gas production, hydrogen production, other electrolysis processes) including a containment vessel configured to be filled with an electrolyte solution, with a plurality of electrically conductive plates positioned therein. Each plate may be oriented vertically, where two or more of the plates are electrode plates. The electrode plates may extend outside of the containment vessel of the electrolyzer so that electrical connections to the electrode plates can be made outside of the containment vessel of the electrolyzer. No electrical connections are made on a sealed interior of the containment vessel. Each plate may include an insular wrap around the edges of each plate. The insular wrap may include grooves formed into the insular wrap into which the plates are received. Such grooves may negate the need for any gaskets. The insular wrap may include holes for passage of the solution into and out of the cells.

An electrolytic ozone generator includes an anode with a longitudinal edge, a cathode with a longitudinal edge spaced apart from the cathode, and an isolator. The isolator electrically separates the cathode from the anode and is semi-impermeable. The anode and cathode are impermeable for generating ozone in a flow area fluidly coupling longitudinal edges of the anode and the cathode. Ozone water apparatus, methods of making electrolytic ozone generators, and methods of generating ozone using electrolytic ozone generators are also described.

A dual-chamber onboard electrolysis system is configured to produce HHO gas for heavy duty trucking applications.

A water reservoir and electrolysis cell combination that has a flow connection between a lower fluid port of the water reservoir and an upper fluid port of the electrolysis cell. The flow connection includes a first conduit with an inner bore which serves as a first flow path for the flow of water by force of gravity from the water reservoir to an outlet for the first conduit positioned within the electrolysis cell. The second conduit is concentric to the first conduit and defines an annular space between the outer surface of the first conduit and the inner surface of the second conduit which serves as a second flow path for an upward flow of gas from the electrolysis cell to the water reservoir.

A dual-chamber electrolysis vessel safely stores HHO gas for use by an internal combustion engine.

The present disclosure concerns a membrane-less electrolyzer comprising a first electrode and a second electrode, a first fluidic channel configured to receive an electrolyte, a second fluidic channel configured to receive the electrolyte from the first fluidic channel, a third fluidic channel configured to receive the electrolyte from the first fluidic channel. The first fluidic channel being in fluidic communication with the second and third fluidic channels. The first fluidic channel is connected to the second and third fluidic channels via a plurality of inclined fluidic canals extending from the first fluidic channel to each of the second and third fluidic channels.

Safety of vehicles employing an electrolysis generator is improved by a rollover abatement system.

Safety of vehicles employing an electrolysis generator is improved by a rollover abatement system.

A process for the microfluidic electrochemical synthesis of geminal dipseudohalide or halide-pseudohalide compounds comprising the steps of pumping a solution comprising a compound of Formula I ##STR00001## into a microfluidic electrochemical reactor in the presence of a base, one of a halide or pseudohalide salt (MY), and a mediator; applying an electrical current through the microfluidic electrochemical reactor; and performing oxidative addition to create a geminal dipseudohalide or halide-pseudohalide compound of the general Formula II ##STR00002##

An HHO gas stream for use in an internal combustion engine is heated by heat exchange from with an exhaust gas stream from the internal combustion engine.