The invention relates to a process for utilizing a hydrocarbon-comprising and/or carbon dioxide-comprising coproduct gas, accompanying gas and/or biogas, wherein hydrocarbon-comprising and/or carbon dioxide-comprising coproduct gas, accompanying gas and/or biogas is introduced into a reaction space and the multicomponent mixture comprised in the coproduct gas, accompanying gas and/or biogas is converted in a high-temperature zone at temperatures of more than 1000? C. and in the presence of a carrier into a product gas mixture which comprises more than 95% by volume of CO, CO.sub.2, H.sub.2, H.sub.2O, CH.sub.4 and N.sub.2 and optionally into a carbon-comprising solid which is deposited to an extent of at least 75% by weight, based on the total mass of the carbon-comprising solid, on the carrier where the flow velocity of the gas mixture of coproduct gas, accompanying gas and/or biogas in the reaction zone is less than 20 m/s.

It is provided a process for increasing production of carbon monoxide (CO) and recycling carbon dioxide when treating synthesis gas using a carbon dioxide-to-carbon monoxide conversion unit, such as a Reverse Water Gas Shift (RWGS) reactor, converting excess CO.sub.2 from the produced syngas to additional CO, using an external source of green, renewable or low carbon intensity hydrogen.

The present disclosure is directed to methods using durable functional materials for processes that include an oxidation step. The durable functional materials are redox active oxygen carrier materials that include a zirconia or yttria-stabilized-zirconia (YSZ) matrix containing a redox-active metal ion(s), such as, but not limited to Fe, Mn, Cu, Co and Cr. In an embodiment, these materials are used in chemical looping processes.

An apparatus for producing synthesis gas at high capacity is described, wherein particularly fast conversion and operation for a long time without interruption is obtained. The apparatus comprises a reactor (1) having a reactor chamber (2) which comprises at least one first inlet (5) connected to a source of hydrocarbon fluid and at least one outlet (15); further a plasma burner (7) having a burner part (11) which is adapted to produce a plasma; and at least one second inlet (6) connected to a source of CO.sub.2 or H.sub.2O. The reactor chamber (2) defines a flow path from the first inlet (5) to the outlet (15), wherein the burner part is located, with respect to the flow path, between the first inlet (5) for hydrocarbon fluid and the second inlet (6) for CO.sub.2 or H.sub.2O; and wherein the second inlet (6) is located with respect to the flow path such that the second inlet (6) is at a location where between 90% and 95% of the hydrocarbon fluid is thermally decomposed. Further a method for operating an apparatus for producing synthesis gas is described.

Operation of a thermochemical regenerator combustion system in which fuel is fed with furnace flue gas into the regenerators to reduce the oxygen content and optionally to establish a reducing atmosphere in both cycles in which the regenerators operate.

The invention relates to a process for producing synthesis gas (5) in which hydrocarbon (2) is decomposed thermally in a first reaction zone (11) to hydrogen and carbon, and hydrogen formed is passed from the first reaction zone (Z1) into a second action zone (Z2) in order to be reacted therein with carbon dioxide (4) to give water and carbon monoxide. The characteristic feature here is that energy required for the thermal decomposition of the hydrocarbon is supplied to the first reaction zone (Z1) from the second reaction zone (Z2).

According to the present invention, organic material is converted to biogas through anaerobic digestion and the biogas is purified to yield a combustible fluid feedstock comprising methane. A fuel production facility utilizes or arranges to utilize combustible fluid feedstock to generate renewable hydrogen that is used to hydrogenate crude oil derived hydrocarbons in a process to make transportation or heating fuel. The renewable hydrogen is combined with crude oil derived hydrocarbons that have been desulfurized under conditions to hydrogenate the liquid hydrocarbon with the renewable hydrogen or alternatively, the renewable hydrogen can be added to a reactor operated so as to simultaneously desulfurize and hydrogenate the hydrocarbons. The present invention enables a party to receive a renewable fuel credit for the transportation or heating fuel.

This disclosure describes systems and methods for using pyrolysis tail gas as the source for additional hydrogen to be used in the pyrolysis reaction. Tail gas is separated from the pyrolysis products and a portion of the tail gas is converted into formic acid (HCOOH). The formic acid is then injected into the pyrolysis reactor where it becomes the donor of two monohydrogen atoms and is ultimately converted into CO.sub.2 under reaction conditions. In this fashion, a closed loop pyrolysis hydrogen donor system may be created utilizing a generally non-toxic intermediary derived from the pyrolysis reaction products. This disclosure also describes using a ruthenium catalyst supported on particles of activated carbon to improve the yield of pyrolysis reactions.

A process for producing syngas that uses the syngas product from a partial oxidation reactor to provide all necessary heating duties, which eliminates the need for a fired heater. Soot is removed from the syngas using a dry filter to avoid a wet scrubber quenching the syngas stream and wasting the high-quality heat. Without the flue gas stream leaving a fired heater, all of the carbon dioxide produced by the reforming process is concentrated in the high-pressure syngas stream, allowing essentially complete carbon dioxide capture.

A feedstock gas reactor includes a reaction chamber and a first regenerative heat exchanger. A feedstock gas is flowed into the reaction chamber via the first regenerative heat exchanger. The feedstock gas is decomposed in the reaction chamber so as to produce reaction products. The reaction products are flowed out of the reaction chamber. The feedstock gas reactor may also include a second regenerative heat exchanger, and the reaction products may be flowed out of the reaction chamber via the second regenerative heat exchanger. Heat from the reaction products may stored in the second regenerative heat exchanger as the reaction products flow through the second regenerative heat exchanger, for later transfer to a feedstock gas flowing into the reaction chamber via the second regenerative heat exchanger.