An on-demand oxy-hydrogen fuel system for an internal combustion engine includes an oxy-hydrogen generator and a microcontroller which activates the the intake manifold. The addition of the oxy-hydrogen provides a very efficient oxy-hydrogen generator when oxy-hydrogen is needed. The oxy-hydrogen is then mixed with blow-by gases from a PCV valve which are recycled through fuel source which can dramatically increase fuel efficiency and reduce emissions.

An artificial photosynthesis module is used for decomposition of an electrolytic aqueous solution into hydrogen and oxygen by light. The artificial photosynthesis module has an oxygen generation electrode having a first protrusion and a first recess alternately arranged thereon, and a hydrogen generation electrode having a second protrusion and a second recess alternately arranged thereon. The hydrogen generation electrode and the oxygen generation electrode are in contact with the electrolytic aqueous solution, and at least one electrode of the hydrogen generation electrode or the oxygen generation electrode includes a conductive layer and a photocatalyst layer provided on the conductive layer. The hydrogen generation electrode and the oxygen generation electrode are arranged side by side, the second protrusion of the oxygen generation electrode faces the first recess of the hydrogen generation electrode in an arrangement direction, and the first protrusion faces the second recess in the arrangement direction.

This invention relates to electrolysis apparatus 10 adapted to produce oxygenated and hydrogenated fluid, formed during the electrolysis of an electrolytic solution passed into the apparatus 10. The apparatus 10 comprises a first and second outer end members 12 and 14 and first and second permeable electrodes 16 and 18 spaced from one another. Each permeable electrode 16 and 18 are of a foraminous or perforated material. An inlet chamber 20 has two inlets 26 for allowing electrolytic solution to pass into said chamber 20. The apparatus 10 also has an oxygen outlet 28 as well as a hydrogen outlet 30. The flow of electrolytic solution through the permeable electrodes 16 and 18 will carry with it the oxygen and hydrogen gasses generated on the positive and negative (first and second) permeable electrodes respectively.

An ocean-powered hydrogen generator system includes: a transportable ocean-going vessel, the vessel is movable to a location with ocean kinetic energy; a generator for converting ocean kinetic energy into electrical energy, the generator is movable on the vessel between a transport position and a generating position; a dissociator for using the electrical energy to dissociate ocean water into hydrogen and oxygen, the dissociator is located on the vessel and operatively connected to the generator; and a container for storing the generated hydrogen and oxygen on the vessel, the container is in fluid communication with the dissociator.

An electrolyzer or unitized regenerative fuel cell has a flow field with at least one channel, wherein the cross-sectional area of the channel varies along at least a portion of the channel length. In some embodiments the channel width decreases along at least a portion of the length of the channel according to a natural exponential function. The use of this type of improved flow field channel can improve performance and efficiency of operation of the electrolyzer device.

Some embodiments of the present invention provide a balance-of-plant system and apparatus suited for regulating the operation of an electrolyzer cell stack. Specifically, in some embodiments, a balance-of-plant system and apparatus is operable to regulate the respective pressures of at least two reaction products relative to one another. Various examples are provided to demonstrate how the respective pressures of two reaction products can be regulated in relation to one another in a pressure following configuration, thereby regulating the pressure differential across an electrolyte layer according to aspects of different embodiments of the invention. Some of the examples provided also include design simplifications and alternatives that may reduce production costs of electrochemical cells configured according to aspects of different embodiments of the invention.

A hydrogen gas generator comprises: an electrolyzer (2) configured to include a housing (20), a first chamber (21), a second chamber (22), a membrane (25), and a pair of electrode plates (23, 24); a tank (6) configured to store water to be electrolyzed (W); an electric power source (3) configured to apply a DC voltage to the pair of electrode plates; a diluter (4) configured to introduce a diluent gas into the first chamber or the second chamber in which the electrode plate to be a cathode is provided, the diluent gas diluting hydrogen gas generated; an electric quantity detector (51) configured to detect an electric quantity given to the electrode plate to be the cathode; a flow rate detector (52) configured to detect a flow rate of the diluent gas from the diluter; a calculator (5) configured to calculate a concentration of the diluted hydrogen gas on the basis of the electric quantity detected by the electric quantity detector and the flow rate detected by the flow rate detector; and an indicator (54) configured to present the concentration of hydrogen gas calculated by the calculator.

A configuration for an electrolysis stack device with adjustable operating capacity, including a specially shaped polar panel, an electricity connector and a pressing connector. A connection part of the polar panel and a pressing connector ensure that the electrical current can flow smoothly from a power source, via the electricity connector, to the electrolysis stack and back to the power source. In various embodiments, a zigzag track may help an electricity connector move to the correct position to vary the operating capacity of the electrolysis stack device.

An ocean-powered hydrogen generator system includes: a transportable ocean-going vessel, the vessel is movable to a location with ocean kinetic energy; a generator for converting ocean kinetic energy into electrical energy, the generator is movable on the vessel between a transport position and a generating position; a dissociator for using the electrical energy to dissociate ocean water into hydrogen and oxygen, the dissociator is located on the vessel and operatively connected to the generator; and a container for storing the generated hydrogen and oxygen on the vessel, the container is in fluid communication with the dissociator.

Localized excess protons are created with an open-circuit water electrolysis process using a pair of anode and cathode electrodes for a special excess proton production and proton-utilization system to treat a substrate material plate/film by forming and using an excess protons-substrate-hydroxyl anions capacitor-like system. The technology enables protonation and/or proton-driven oxidation of plate/film and/or membrane materials in a pure water environment. The present invention represents a remarkable clean green chemistry technology that does not require the use of any conventional acid chemicals including nitric and sulfuric acids for the said industrial applications. The application of localized excess protons provides a special energy recycling and renewing technology function to extract latent heat including molecular thermal motion energy at ambient temperature for generating local proton motive force (equivalent to Gibbs free energy) to do useful work such as driving ATP synthesis and proton-driven oxidation of certain substrate metal atoms.