A reactor apparatus for dehydrogenating a carrier medium includes a reactor housing, an interior space which is enclosed by the reactor housing and includes a preliminary space, which has an inflow opening for inflow of loaded carrier medium into the preliminary space and at least one first connecting opening for outflow of the carrier medium from the preliminary space, and includes a reaction space connected via the at least one first connecting opening to the preliminary space. The reactor apparatus additionally has a heat transfer space which is arranged between the reactor housing and the reaction space and contains a heat transfer medium for transfer of heat from the heat transfer medium to the carrier medium.

A reactor apparatus for loading a carrier medium with hydrogen and/or unloading it therefrom includes a reactor housing chargeable with carrier medium and having a carrier medium feed orifice, having a carrier medium removal orifice, having a base and having a hydrogen gas orifice. The reactor apparatus further includes at least one heat transfer element for supplying heat into the reactor housing. Catalyst has been provided in the reactor housing.

The present disclosure relates to a reversible hydrogen transfer process and storage system using visible light to photocatalytically generate hydrogen from compounds comprising saturated or partially saturated carbocyclic residue and catalytically hydrogenate compounds comprising at least one carbocyclic aromatic residue.

The invention relates a method for storing a solution of methane and a C2-C30 hydrocarbon, the method comprising: mixing gaseous methane and a C2-C30 hydrocarbon to provide a mixture of methane and C2-C30 hydrocarbon, wherein the mixture comprises greater than or equal to about 50 mole percent of methane; maintaining the mixture of methane and C2-C30 hydrocarbon as a liquid solution at a pressure of 30 to 150 bar within a storage vessel, wherein the storage vessel comprises a porous adsorbent framework. The invention also relates to similar methods for storing hydrogen, nitrogen and carbon dioxide. The invention also relates to the use of a non-polar solvent such as a hydrocarbon for storing a non-polar gas in a porous adsorbent framework.

A heater assembly for use in a hydrogen generator can be retracted to facilitate insertion and removal of a replaceable fuel unit without damaging the heater assembly or the fuel unit and extended to provide good thermal contact with the fuel unit during use of the hydrogen generator. The heater assembly includes a support member, a heater, and an actuator for extending and retracting the heater assembly. When the heater is energized it heats the actuator, thereby extending the heater assembly to contact the adjacent fuel unit, and when the heater is deenergized the actuator cools to retract the heater assembly and provide a gap between the heater assembly and the adjacent fuel unit. The actuator is movably secured to the heater or the support member by a retainer such that an end of the actuator is movable within the retainer as the actuator changes shape during heating and cooling.

The present invention relates to novel branched hydrogen carrier compounds and so to a method for producing hydrogen from said branched hydrogen carrier compounds. The present invention also relates to a process for producing and for regenerating said branched hydrogen carrier compounds.

The subject of the invention is a process for the hydrogenation of hydrogen carbonate in an aqueous reaction system, where the process ensures that the hydrogen carbonate, hydrogen and catalyst come into contact with each other while carbon dioxide is present in the gas space. In this phase of the process, formate is produced. The subject of the invention is also a process for the catalytic decomposition of formate in an aqueous reaction system and the hydrogenation of hydrogen carbonate produced in the same reaction system according to the invention, where the reactants and the reaction products are formed in a reversible reaction cycle using the reaction system according to the invention, and this reaction cycle is repeated in the required number of times. In the mentioned formate mg decomposition process, the formate and the catalyst come into contact, so that hydrogen gas and hydrogen carbonate free of COX by-products are produced as the product of the reaction. Further subject of the invention is a hydrogen storage system based on the method according to the invention, preferably a hydrogen accumulator. Further subject of the invention is a hydrogen storage system according to the invention, preferably the use of a hydrogen accumulator for the storage of hydrogen required for the operation of a fuel cell (or other equipment requiring H2) and, where appropriate, for its release in as needed.

Provided is a hydrogen storage system including a solution including ethylenediamine bisborane (EDAB) and ethylenediamine (ED), in which the hydrogen storage system is capable of performing a reversible dehydrogenation/hydrogenation reaction at a temperature of 20? C. to 200? C. in the presence of a heterogeneous metal catalyst including ruthenium (Ru), rhodium (Rh), palladium (Pd), osmium (Os), iridium (Jr), platinum (Pt), nickel (Ni), iron (Fe), cobalt (Co), or a combination thereof.

The invention relates generally to system for conserving heat during the hydrogenation and dehydrogenation process by using a multi-component system.

A hydrogen storage device comprising (i) hydrogen gas and (ii) a host framework material. A hydrogen discharge device comprising (i) hydrogen gas and (ii) a host framework material. A method of storing hydrogen comprising introducing hydrogen gas to a host framework material comprising a zeolite, carbon, silica, nickel foam, carbon nanosponge (CNS), a graphene aerogel or a combination thereof under conditions suitable for the formation of hydrogen gas hydrates. A battery comprising a host framework material comprising hydrogen gas hydrates wherein the host framework material comprises a zeolite, carbon, silica, nickel foam, carbon nanosponge (CNS), a graphene aerogel or a combination thereof.