Provided is a method for synthesizing cobalt-incorporated carbon nanotubes (Co/MWCNTs). The method includes a step of mixing cobalt acetate, cobalt nitrate, cobalt chloride, or cobalt sulfate with multi-wall carbon nanotubes in a solvent. A method for generating hydrogen by using the Co/MWCNTs as a catalyst component is also provided herein.

A system for generating hydrogen includes a vessel having a first chamber that is separated from a second chamber by a barrier. A trigger assembly integrated with the barrier allows a liquid to be combined with a reactant and a catalyst in the second chamber to form a chemical reaction to generate hydrogen gas. A pressure relief valve located on the vessel opens to allow the hydrogen gas to exit when a predetermined pressure is reached.

Systems, devices, and methods combine thermally stable reactant materials and aqueous solutions to generate hydrogen and a non-toxic liquid by-product. The reactant materials can sodium silicide or sodium silica gel. The hydrogen generation devices are used in fuels cells and other industrial applications. One system combines cooling, pumping, water storage, and other devices to sense and control reactions between reactant materials and aqueous solutions to generate hydrogen. Springs and other pressurization mechanisms pressurize and deliver an aqueous solution to the reaction. A check valve and other pressure regulation mechanisms regulate the pressure of the aqueous solution delivered to the reactant fuel material in the reactor based upon characteristics of the pressurization mechanisms and can regulate the pressure of the delivered aqueous solution as a steady decay associated with the pressurization force. The pressure regulation mechanism can also prevent hydrogen gas from deflecting the pressure regulation mechanism.

Systems, devices, and methods combine thermally stable reactant materials and aqueous solutions to generate hydrogen and a non-toxic liquid by-product. The reactant materials can sodium silicide or sodium silica gel. The hydrogen generation devices are used in fuels cells and other industrial applications. One system combines cooling, pumping, water storage, and other devices to sense and control reactions between reactant materials and aqueous solutions to generate hydrogen. Springs and other pressurization mechanisms pressurize and deliver an aqueous solution to the reaction. A check valve and other pressure regulation mechanisms regulate the pressure of the aqueous solution delivered to the reactant fuel material in the reactor based upon characteristics of the pressurization mechanisms and can regulate the pressure of the delivered aqueous solution as a steady decay associated with the pressurization force. The pressure regulation mechanism can also prevent hydrogen gas from deflecting the pressure regulation mechanism.

Provided are a CaMg.sub.2-based alloy hydride material for hydrolysis production of hydrogen, a preparation method therefor and a use thereof. The material has a general formula of CaMg.sub.xM.sub.yH.sub.z, wherein M is Ni, Co or Fe, 1.5≦x<2.0, 0<y≦0.5, and 3≦z<6. The preparation method for the material comprises the following steps: (1) stacking three pure metal block materials in a crucible, wherein a metal block material M is placed at the top; (2) installing the crucible in a high-frequency induction melting furnace, evacuating and introducing an argon gas; (3) starting the high-frequency induction melting furnace to heat at a low power first, then increasing the power to uniformly fuse same; and thereafter cooling with the furnace to obtain an alloy ingot, and hammer-milling to obtain a hydrogen storage alloy based on CaMg.sub.2; and (4) hydrogenating the hammer-milled hydrogen storage alloy to obtain the material for hydrolysis production of hydrogen. The preparation method is simple and low in cost. The material can absorb hydrogen at normal temperature with a good hydrogen absorption performance The prepared hydrogen is pure, and can be directly introduced into and used in a hydrogen fuel battery.

A method and process of producing gasoline and diesel from hydrocarbon wastes, by gradually heating the hydrocarbon waste in a reducing atmosphere, up to 550° C. During the heating process and at various temperature points long chains of hydrocarbon are broken down into smaller hydrocarbon chains. During the heating process radical hydrogen gas is introduced to the reactor where the radical hydrogen gas reacts with smaller hydrocarbon chains to produce 45% coke petroleum oil, 45% liquid hydrocarbons composed of gasoline and gasoil and 10% gases including methane, ethane, propane and steam. The radicalized hydrogen atoms are produced at low temperatures and atmospheric pressure. Hydrogen gas is produced by dissolving aluminum scraps are dissolved in a sodium hydroxide solution in a reactor. As hydrogen gas is produced the reactor is heated to 120° C. in the presence of electromagnetic waves causing the breakdown of hydrogen gas into hydrogen gas radicals.

A method and process of producing gasoline and diesel from hydrocarbon wastes, by gradually heating the hydrocarbon waste in a reducing atmosphere, up to 550° C. During the heating process and at various temperature points long chains of hydrocarbon are broken down into smaller hydrocarbon chains. During the heating process radical hydrogen gas is introduced to the reactor where the radical hydrogen gas reacts with smaller hydrocarbon chains to produce 45% coke petroleum oil, 45% liquid hydrocarbons composed of gasoline and gasoil and 10% gases including methane, ethane, propane and steam. The radicalized hydrogen atoms are produced at low temperatures and atmospheric pressure. Hydrogen gas is produced by dissolving aluminum scraps are dissolved in a sodium hydroxide solution in a reactor. As hydrogen gas is produced the reactor is heated to 120° C. in the presence of electromagnetic waves causing the breakdown of hydrogen gas into hydrogen gas radicals.

A dehydrogenation reaction device includes: an acid aqueous solution storage unit including a first aqueous acid solution; a water storage unit including water; and a dehydrogenation reaction unit including a chemical hydride. The dehydrogenation reaction unit receives a second aqueous acid solution in which the first aqueous acid solution and water are mixed, and further reacts the chemical hydride and the second aqueous acid solution to generate hydrogen.

{Problem}

To provide a dissolved hydrogen liquid-discharging pot that makes it easier for a user to use hydrogen water by making the pot capable of discharging or spraying a liquid in which hydrogen is dissolved continuously for a constant period at a prescribed pressure.

{Solution}

The internal pressure of a pressure chamber, the volume of which has been subdivided by an indicator line on a pot body, is maintained with hydrogen, which is generated by a hydrogen-generating agent disposed in a hydrogen-generating section, at a discharge pressure that is sufficient to discharge all of the liquid inside a bottle section while an on-off valve that opens and closes a discharge tube is closed, and when the on-off valve is opened intermittently or continuously, at a pressure sufficient for continuing discharge of the liquid inside the bottle section and performing continuous discharge of dissolved hydrogen liquid until the bottom of the bottle section is reached.

A method of synthesizing fuel from an aqueous solution includes pumping the aqueous solution, containing dissolved inorganic carbon, from a body of water into a carbon extraction unit. The method further includes extracting the dissolved inorganic carbon from the aqueous solution to create CO.sub.2 by changing a pH of the aqueous solution in the carbon extraction unit. The CO.sub.2 derived in the carbon extraction unit is received by a fuel synthesis unit, and the CO.sub.2 is converted into fuel including at least one of a hydrocarbon, an ether, or an alcohol using the fuel synthesis unit.