A device for producing fuel gas from materials of organic and/or inorganic origin, comprising filling chamber connected to at least one supply auger conveyor for supplying material from the filling chamber into a reactor comprising at least two heated gasification augers. The invention consists in the fact that each horizontal row of gasification augers is formed by a gasification body, the casing of which has a closed oval cross-section formed by an upper base, a lower base, and convex side walls each with circular arc profiles, wherein each gasifying body contains at least two gasification augers arranged side by side and mutually partially separated by longitudinal partitions that form half-grooves for gasifying augers. The device is provided with at least one electrical heater. The filling chamber is hermetically sealed.

A direct carbonaceous material to power generation system integrates one or more solid oxide fuel cells (SOFC) into a fluidized bed gasifier. The fuel cell anode is in direct contact with bed material so that the H.sub.2 and CO generated in the bed are oxidized to H.sub.2O and CO.sub.2 to create a push-pull or source-sink reaction environment. The SOFC is exothermic and supplies heat within a reaction chamber of the gasifier where the fluidized bed conducts an endothermic reaction. The products from the anode are the reactants for the reformer and vice versa. A lower bed in the reaction chamber may comprise engineered multi-function material which may incorporate one or more catalysts and reactant adsorbent sites to facilitate excellent heat and mass transfer and fluidization dynamics in fluidized beds. The catalyst is capable of cracking tars and reforming hydrocarbons.

A device for producing fuel gas from materials of organic and/or inorganic origin, comprising filling chamber connected to at least one supply auger conveyor for supplying material from the filling chamber into a reactor comprising at least two heated gasification augers. The invention consists in the fact that each horizontal row of gasification augers is formed by a gasification body, the casing of which has a closed oval cross-section formed by an upper base, a lower base, and convex side walls each with circular arc profiles, wherein each gasifying body contains at least two gasification augers arranged side by side and mutually partially separated by longitudinal partitions that form half-grooves for gasifying augers. The device is provided with at least one electrical heater. The filling chamber is hermetically sealed.

A device for reacting an organic starting material to yield a gas that includes hydrogen has a feed device, a tubular furnace with an entry zone, an interior space, an axis of rotation and an exit side, and a water feed arranged by the feed device or entry zone and controllable as a function of the content of hydrogen in the gas mixture. The feed device feeds the starting material in the region of the entry zone into the interior space of the tubular furnace, from which a solid material and a gas mixture is discharged. The tubular furnace has a compensator for different thermal expansions of a first zone and a second zone. A gas-conducting system includes a gas monitor for the content of hydrogen in the gas mixture.

A method of separating solid particles from gaseous matter comprises rotating a spinner about a spinner axis in a rotational direction. The spinner has fluid passageways that operatively connect a gaseous inlet environment to a gaseous outlet environment. The fluid passageways circumferentially extending in a direction opposite the rotational direction as the fluid passageways extend radially inward. The method further comprises forcing gaseous matter radially inward through the rotating spinner by creating pressure differential that is such that the pressure of the gaseous inlet environment exceeds the pressure of the gaseous fluid outlet. An assembly comprises a spinner configured to rotate in a rotational direction. The spinner has fluid passageways that operatively connect a gaseous inlet environment to a gaseous outlet environment. A heating element is positioned adjacent to the spinner in a manner such that particles flung from the spinner can strike the heating element.

The process includes activating a char in an oven by heating the char with steam to generate activated carbon and syngas. The process also includes monitoring parameters of the syngas produced and controlling the oven in response to the parameter. The process converts a feedstock, typically organic waste, into useable products.

Methods and apparatuses for producing fuel and power from the reformation of organic waste include the use of steam to produce syngas in a Fischer-Tropsch reaction, followed by conversion of that syngas product to hydrogen. Some embodiments include the use of a heated auger both to heat the organic waste and further cool the syngas.