A bio-multi-reactor hydrogen generation method using a bio-multi-reactor hydrogen generation system including a plurality of carbonization-water gasification furnaces and a plurality of heating furnaces arranged alternately side by side includes: arranging solid combustibles in each carbonization-water gasification furnace; dry distilling the solid combustibles by heating from each heating furnace adjacent to each carbonization-water gasification furnace; gasifying carbide obtained by dry distillation within each carbonization-water gasification furnace by supplying steam to the carbide to cause a water gasification reaction to take place; and maintaining each heating furnace at a temperature for dry distilling the solid combustibles in each carbonization-water gasification furnace by collecting a combustible gas generated in dry distillation of the solid combustibles in each carbonization-water gasification furnace in a tank and supplying the combustible gas to each heating furnace for combustion.

A system including a mixing apparatus configured to produce a reformer feedstock and comprising one or more cylindrical vessel having a conical bottom section, an inlet for superheated steam within the conical bottom section and an inlet for at least one carbonaceous material at or near the top of the cylindrical vessel, wherein the one or more cylindrical vessel is a pressure vessel configured for operation at a pressure in the range of from about 5 psig (34.5 kPa) to about 50 psig (344.7 kPa); a reformer configured to produce, from the reformer feedstock, a reformer product comprising synthesis gas, and also producing a hot flue gas; a synthesis gas conversion apparatus configured to catalytically convert at least a portion of the synthesis gas in the reformer product into synthesis gas conversion product, and to separate, from the synthesis gas conversion product, a spent catalyst stream and a tailgas.

The invention relates to a catalyst regeneration process for a tar reforming catalyst within a catalyst bed in a tar reformer. The process comprises the steps of:Admitting a main gas stream with controlled temperature and oxygen content to an inlet into the tar reformer;Passing the main gas stream through the catalyst bed to form an oxygen depleted gas stream;Exiting the oxygen depleted gas stream from the tar reformer; andRecycling at least a part of the oxygen depleted gas stream exiting from the tar reformer back into said main gas stream upstream said tar reformer. The temperature of said main gas stream at the inlet is controlled to be within the range from about 500 C. to about 1000 C.

A combined hydrothermal liquefaction (HTL) and catalytic hydrothermal gasification (CHG) system and process are described that convert various biomass-containing sources into separable bio-oils and aqueous effluents that contain residual organics. Bio-oils may be converted to useful bio-based fuels and other chemical feedstocks. Residual organics in HTL aqueous effluents may be gasified and converted into medium-BTU product gases and directly used for process heating or to provide energy.

An apparatus includes a reactor vessel containing a carbonaceous bed and having means for establishing an elevated temperature within the carbonaceous bed; and the reactor vessel also having one or more feed material inlets above the carbonaceous bed for depositing process material from outside the vessel onto the carbonaceous bed, one or more gas exhaust ports above the bed for exit of gaseous products from the vessel, and one or more slag ports at the bottom of the carbonaceous bed for exit of molten and vitreous material from the vessel; wherein the carbonaceous bed comprises bricks that contain carbon and are of varied size and shape of which at least 25% of the total carbon content of the bed comprises spent pot liner material from aluminum processing, and wherein the bricks further comprise at least one of: Portland cement, potassium silicate cement, or aluminum silicate cement.

A bottom fraction of a product of a hydrocatalytic reaction is gasified to generate hydrogen for use in further hydrocatalytic reactions. In one embodiment, one or more volatile organic compounds is also vaporized using heat generated in the gasification process. In one embodiment, an overhead fraction of the hydrocatalytic reaction is further processed to generate higher molecular weight compounds. In another embodiment, a product of the further processing is separated into a bottom fraction and an overhead fraction, where the bottom fraction is also gasified to generate hydrogen for use in further hydrocatalytic reactions.

A process for processing carbonaceous material includes delivering a carbonaceous material to a reactor; delivering a catalyst to the reactor; processing the carbonaceous material at a relatively low temperature within the reactor to decompose the carbonaceous material to base compounds.

This disclosure describes systems and methods for processing raw syngas with in-situ catalyst regeneration.

The present invention relates to the processing of carbonaceous materials for, inter alia, hydrogen production. In particular, the invention relates to the production of hydrogen, for example, as input for industrial manufacturing applications or as a fuel source for the associated generation of electric power. In one form, the invention provides a method of producing hydrogen comprising the step of reacting a combination of solid carbonaceous material and a catalyst comprising alpha phase iron-based material adapted to produce an exothermic reaction with the solid carbonaceous material.

Combining multiple subsystems involving biomass processing, biomass gasification of the processed biomass where a synthesis gas is produced then converted to hydrogen fuels or other transportation fuels for use in coupled transportation systems sized to consume all the transportation fuel produced. Carbon in the biomass is converted to CO.sub.2 in the conversion process and a portion of that CO.sub.2 is captured and sequestrated for long term storage.