The present invention discloses a method for directly synthesizing sodium borohydride by solid-state ball milling at room temperature, which comprises: performing solid-state ball milling on a mixture of a reducing agent and a reduced material by using a ball mill under room temperature, and performing purification to obtain sodium borohydride. The reducing agent comprises one or more of magnesium, magnesium hydride, aluminum, calcium, and magnesium silicide. The reduced material is sodium metaborate containing crystallization water or sodium metaborate, or is a mixture of sodium metaborate containing crystallization water and sodium metaborate. The solid-state milling is performed in a mixed atmosphere of argon and hydrogen, or an argon atmosphere, or a hydrogen atmosphere. The present invention has a simple process, a controllable and adjustable reaction procedure, mild reaction conditions, low energy consumption, low costs, high yield, no pollution, good safety, and easy industrial production.

A recharger includes a manifold having an input to couple to a hydrogen generating module and an output port to couple to at least one rechargeable fuel cell. A vacuum pump is coupled to the manifold to evacuate the manifold. A valve is coupled to the manifold between the vacuum pump and the input of the manifold. A controller is coupled to control the vacuum pump and the valve, as well as an optional fan.

A system for supplying hydrogen gas to a lighter-than-air (LTA) vehicle includes a manifold having multiple vessels. Each vessel has 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 each vessel opens to allow the hydrogen gas to exit when a predetermined pressure is reached, and the hydrogen gas is supplied to the LTA vehicle connected to the manifold.

A fuel tank for storing a hydrogen liquid carrier and a spent hydrogen liquid carrier includes a substantially rigid exterior tank wall including a first chamber and a second chamber. The first chamber is fluidly disconnected from the second chamber, and the second chamber includes a dynamically expandable and contractible enclosure, the enclosure being configured to define a dynamic boundary between the hydrogen liquid carrier and spent hydrogen liquid carrier. The fuel tank also includes a first channel in flow communication with one of the first chamber or the second chamber and a second channel in flow communication with another of the first chamber or the second chamber, wherein the first channel and the second channel are flow connected such that a flow through one of the first or second channels is returned to the another of the first or second channels, and that during the flow, the dynamic boundary changes position causing a change in a volume of the second chamber.

A hydrogen-supplying breathable layer in the present disclosure comprises: a thin layer wrapping a hydrogen-producing formula inside, having an airtight outer side as well as an air-permeable inner side on which a plurality of micro pores are opened and featuring a monolayer or a composite layer; a hydrogen-producing formula wrapped inside the thin layer and not dissipated but absorbing moistures in air or liquid water for generation of hydrogen; hydrogen permeating a plurality of micro pores and released to skin and intra-corporal parts. The hydrogen-producing formula in the hydrogen-supplying breathable layer comprises metal peroxides (metal hydroxides or metal hydrides) and aluminum powders (or silica powders); the breathable layer is applicable to a dressing pack or other sanitary paraphernalia in daily lives for relieving non-bacteria inflammations and promoting health care effects.

A method uses a chemical system to generate hydrogen gas. The chemistry involves a two-step reaction. In the first step, an alkaline hydride reacts with water to produce a hydroxide and hydrogen. In the second step, the hydroxide reacts with aluminum to produce even more hydrogen. The fuel is composed out of a mixture of powders of the alkaline hydride and aluminum. The fuel is encapsulated in a water soluble capsule for easy dispensing and protection against short time exposure to moisture. For large scale systems, the fuel is mixed with a low hydrophilicity ionic liquid to make it into a slurry that can be dispensed into a reaction chamber. The generation system comprises a tank, a pump, a first tube, a second tube, one or more capsules, a tank sensor assembly, and a processing system. The method comprises the steps of dispensing the capsules or the slurry in the tank; supplying water to the tank; and collecting hydrogen gas from the tank. After supplying water to the tank, the two reaction steps, being safe and controllable, facilitating hydrolysis reaction of metal and metal salts, are carried out. The produced hydrogen may be used in a fuel cell or a biomedical application.

Hydrogen being a clean, highly abundant and renewable fuel, is a promising alternative for conventional energy sources. Mostly, this hydrogen is stored in the form of hydrides. The existing methods for identification of material for hydrogen storage as expensive and time consuming. A method and system of identification of materials for hydrogen storage has been provided. The method provides a machine learning technique to predict the hydrogen storage capacity of materials, using only the compositional information of the compound. A random forest model used in the work was able to predict the gravimetric hydrogen storage capacities of intermetallic compounds. The method and system is also configured to predict the thermodynamic stability of the intermetallic compound.

The present invention provides a composition for prevention and/or improvement of encephalitis and/or meningitis. More specifically, the present invention provides a composition for prevention and/or improvement of encephalitis and/or meningitis and a symptom associated with the encephalitis and/or meningitis in a subject, comprising molecular hydrogen as an active ingredient.

A hydrogen storage system includes a pressure-sealed storage unit defining an interior and having an outlet, an upper manifold and a lower manifold separated by a dividing plane having a set of ports, a set of chambers, and a hydrogen storage, wherein at least some hydrogen gas is supplied to the outlet.

A method for obtaining a mixture for producing H.sub.2, the mixture comprising a metal borohydride, Me(BH.sub.4).sub.n, a metal hydroxide, Me(OH).sub.n, and H.sub.2O, in which Me is a metal and n is the valance of the metal ion. The H.sub.2O is provided in ultrapure water, UPW, the UPW having an electrical conductance below 1 μS/cm. The method comprises dissolving the metal borohydride and the metal hydroxide in UPW to obtain the mixture for producing H.sub.2 comprising an amount of borohydride, BH.sub.4, groups of the metal borohydride in the range of 45 to 55% mol of the mixture, an amount of hydroxide, OH, groups of the metal hydroxide in the range of 2 to 5% mol of the mixture, and at least substantially UPW for the remainder of the mixture.