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A method of generating a synthesis gas product stream and carbon dioxide in which a fuel is combusted in an oxygen transport membrane combustor to produce a flue gas stream containing the carbon dioxide and water. Reforming duty is divided between a combined reforming process and a gas heated reform

A method of generating a synthesis gas product stream and carbon dioxide in which a fuel is combusted in an oxygen transport membrane combustor to produce a flue gas stream containing the carbon dioxide and water. Reforming duty is divided between a combined reforming process and a gas heated reformer to produce the product stream. The flue gas stream is used to supply heat to a primary, steam methane reforming stage of the combined reforming process. Residual methane, produced in the primary stage, is reacted in a secondary stage having an oxygen transport membrane reactor. Heat produced in the secondary stage is supplied to the gas heated reactor to support its operation. The flue gas stream is cooled and water is separated therefrom to produce the carbon dioxide at a concentration of at least 85 mol percent.

대표청구항 ▼

I claim: 1. A method of generating a synthesis gas product stream and carbon dioxide comprising: combusting a fuel in an oxygen transport membrane combustor to produce a flue gas stream containing the carbon dioxide and water; reacting part of a reactant stream, containing hydrocarbons and steam, i

I claim: 1. A method of generating a synthesis gas product stream and carbon dioxide comprising: combusting a fuel in an oxygen transport membrane combustor to produce a flue gas stream containing the carbon dioxide and water; reacting part of a reactant stream, containing hydrocarbons and steam, in a combined reforming process and a remaining part of said reactant stream in a gas heated reformer to produce the synthesis gas product stream; the combined reforming process including a primary stage having a steam methane reformer to react part of the hydrocarbons and steam and a secondary stage having an oxygen transport membrane reactor configured to react residual methane produced in the primary stage through additional reforming and by catalytic partial oxidation; transferring heat from the flue gas stream to the primary stage and from the secondary stage to the gas heated reformer to support endothermic heat requirements of steam methane reforming reactions occurring within said primary stage and said gas heated reformer; cooling the flue gas stream; and separating water from the flue gas stream after having been cooled to produce the carbon dioxide at a concentration of at least 85 mol percent. 2. The method of claim 1, wherein: the primary stage produces a first synthesis gas stream, the first synthesis gas stream being introduced into the oxygen transport membrane reactor; the secondary stage produces a second synthesis gas stream; and the heat is transferred to the gas heated reformer by indirect heat exchange with the second synthesis gas stream. 3. The method of claim 2, wherein the flue gas stream is sufficiently cooled to condense the water contained therein and the water is separated from the flue gas stream by introducing the flue gas stream into a vessel to collect the water. 4. The method of claim 2 wherein: both the third synthesis gas stream and the first synthesis gas stream are introduced into the catalytic oxygen transport membrane reactor, thereby to react further residual methane present within the third synthesis gas stream along with the residual methane contained in the first synthesis gas stream and to obtain the second synthesis gas stream; and the synthesis gas product stream is formed from the second synthesis gas stream after having indirectly exchanged the heat to the gas heated reformer. 5. The method of claim 2, wherein: the third synthesis gas stream is combined with the second synthesis gas stream prior to the second synthesis gas stream indirectly transferring the heat to the gas heated reformer and a combined synthesis gas stream is thereby obtained from the gas heated reformer; and the synthesis gas product stream is formed from the combined synthesis gas stream. 6. The method of claim 4, wherein the flue gas stream is sufficiently cooled to condense the water contained therein and the water is separated from the flue gas stream by introducing the flue gas stream into a vessel to collect the water. 7. The method of claim 5, wherein the flue gas stream is sufficiently cooled to condense the water contained therein and the water is separated from the flue gas stream by introducing the flue gas stream into a vessel to collect the water.