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

Apparatuses, systems, and methods are disclosed to produce HHO gas in a pressure-resistant container for use in an internal combustion engine to increase fuel efficiency and/or reduce emissions, for example by introducing the HHO gas to one or more air intake ports of the engine.

An oxyhydrogen gas supply equipment includes a gas supply unit, an allocating unit and a mixing unit. The gas supply unit includes an electrolysis device, and an oxygen gas delivery pipeline and a hydrogen gas delivery pipeline that are connected to the electrolysis device. The allocating unit includes a buffer tank connected to the oxygen gas delivery pipeline, and a throttle valve connected to the buffer tank and operable to regulate oxygen gas output therefrom. The mixing unit includes a mixing tank connected to the hydrogen gas delivery pipeline and throttle valve, an output pipeline connected to the mixing tank, and a detector for detecting oxygen gas content inside the mixing tank to regulate the oxygen gas output from the throttle valve.

A GaON/ZnO photoelectrode involving a nanoarchitectured photocatalytic material deposited onto a surface of a conducting substrate, and the nanoarchitectured photocatalytic material containing gallium oxynitride nanoparticles interspersed in zinc oxide nanoparticles, as well as methods of preparing the GaON/ZnO photoelectrode. A method of using the GaON/ZnO photoelectrode for solar water electrolysis is also provided.

Features for an aqueous reactor include a field generator. The field generator includes a series of parallel conductive plates including a series of intermediate neutral plates. The intermediate neutral plates are arranged in interleaved sets between an anode and a cathode. Other features of the aqueous reactor may include a sealed reaction vessel, fluid circulation manifold, electrical power modulator, vacuum port, and barrier membrane. Methods of using the field generator include immersion in an electrolyte solution and application of an external voltage and vacuum to generate hydrogen and oxygen gases. The reactor and related components can be arranged to produce gaseous fuel or liquid fuel. In one use, a mixture of a carbon based material and a liquid hydrocarbon is added. The preferred carbon based material is powdered coal.

The present invention relates to a water splitting cell having at least one electrode comprising a porous membrane, wherein gas produced at the electrode diffuses out of the cell via the porous membrane, separating the gas from the reaction at the electrode without bubble formation.

A hydrogen generator including a series of plates positioned in an electrolysis chamber. The plates are configured to generate hydrogen. The chamber has a water inlet configured to receive water from a water source and a hydrogen outlet configured to allow the hydrogen to exit therefrom. The plates include a positive plate, a negative plate, and a neutral plate. Each of the plates has through-holes configured to allow the water and the hydrogen to flow therethrough. The positive and negative plates are configured to be connected to positive and negative terminals, respectively, of an electrical power source. The water inside the chamber forms an electrical connection between the positive and negative plates that splits the water into the hydrogen and oxygen.

An electrochemical reaction device includes: a first electrolytic solution tank having a first storage part and a second storage part; a second electrolytic solution tank having a third storage part and a fourth storage part; a first reduction electrode layer immersed in a first electrolytic solution; a first oxidation electrode layer immersed in a second electrolytic solution; a first generator electrically connected to the first reduction electrode and the first oxidation electrode layer; a second reduction electrode layer immersed in a third electrolytic solution; a second oxidation electrode layer immersed in a fourth electrolytic solution; a second generator electrically connected to the second reduction electrode and the second oxidation electrode layer; and at least one flow path out of a first flow path connecting the first storage part and the fourth storage part and a second flow path connecting the second storage part and the third storage part.

The present disclosure relates to dehumidifying devices and data storage devices that include a dehumidifying device. A dehumidifying device can include first and second electrical terminals that are located on the same side of the dehumidifying device to easily couple the terminals to electrical connections external to the data storage device such as a printed circuit board assembly.

A vortex reactor (200) for generating hydrogen gas through electrolysis of water, comprising: a reactor body having a first end (204) and a second end (206); one or more inlet ports (202) disposed at or near the first end (204) and configured to direct an electrolytic fluid into the reactor body so that the fluid moves toward the second end (206), the one or more inlet ports (202) being tangentially oriented with respect to an inner surface of the reactor body so that the fluid directed into the reactor body follows a vortical path as the fluid moves toward the second end (206); an anode (242) disposed at the first end (204); and a tubular cathode (244) disposed within the reactor body between the first and second ends, the cathode (244) disposed so that the vortical path of the fluid contacts an inner surface of the cathode (244) as the fluid moves toward the second end (206), wherein power supplied to the anode (242) and cathode (244) cause hydrogen gas to form at the cathode (244) and oxygen gas to form at the anode (242), the vortical path of the moving fluid shearing the forming gases to enable collection of the gases.