Abstract: The invention relates to a process for producing olefins from a feed stream containing hydrocarbons by pyrolytic cracking of the hydrocarbons in an autothermal reactor. An oxygen containing stream and a hydrogen and/or methane containing stream are pre-heated outside the autothermal reactor. The pre-heated oxygen containing stream and the pre-heated hydrogen and/or methane containing stream are fed into a burner of the autothermal reactor. Steam is generated in a combustion zone of the autothermal reactor. A feed stream containing hydrocarbons is pre-heated outside the autothermal reactor and then fed into the autothermal reactor. The pre-heated feed stream is mixed with the steam generated in the combustion zone in a mixing and cracking zone of the autothermal reactor. The steam and the pre-heated feed stream containing hydrocarbons are fed into the mixing and cracking zone from substantially opposite directions. The hydrocarbons are pyrolytically cracked the to provide an effluent containing olefins.

Abstract: A method for producing syngas is provided, which comprises providing a feed stream comprising H2 and CO2; heating the feed stream in a first heat exchanger to provide a first heated feed stream, which is introduced into a first RWGS reactor and subjected to a first catalytic RWGS reaction in the presence of a non-methanation promoting catalyst, thereby obtaining a first syngas containing stream, which is cooled in the first heat exchanger against the feed stream, thereby obtaining a first cooled syngas stream, which is separated in a first gas/liquid separator thereby obtaining a first water-enriched stream and a first water-depleted syngas stream; heating the first water-depleted syngas stream in a second heat exchanger thereby obtaining a heated first water-depleted syngas stream, which is introduced into a second RWGS reactor and subjected to a second catalytic RWGS reaction in the presence of a non-methanation promoting catalyst.

Abstract: The present invention relates to a method for producing syngas using a catalytic reverse water gas shift (RWGS) reaction, the method at least comprising the steps of: a) providing a feed stream (10) comprising at least hydrogen (H2) and carbon dioxide (CO2); b) heating the feed stream (10) provided in step a) in a first heat exchanger (3) thereby obtaining a first heated feed stream (20); c) introducing the first heated feed stream (20) into a RWGS reactor (2) and subjecting it to a catalytic RWGS reaction, thereby obtaining a syngas containing stream (30); d) cooling the syngas containing stream (30) obtained in step c) in the first heat exchanger (3) against the feed stream (10) provided in step a), thereby obtaining a first cooled syngas stream (40); c) cooling the first cooled syngas stream (40) obtained in step d) in a second heat exchanger (5) thereby obtaining a second cooled syngas stream (50); f) separating the second cooled syngas stream (50) obtained in step e) in a gas/liquid separator (6) thereby

Abstract: A method for producing syngas that comprises providing a feed stream comprising H2 and CO2; heating the feed stream in a first heat exchanger to obtain a first heated feed stream; introducing the first heated feed stream into a first RWGS reactor to obtain a first syngas containing stream; cooling the first syngas containing stream in the first heat exchanger against the feed stream to obtain a first cooled syngas stream; separating the first cooled syngas stream in a first gas/liquid separator to obtain a water-enriched stream and a water-depleted syngas stream; heating the water-depleted syngas stream in a second heat exchanger to obtain a heated water-depleted syngas stream; introducing the heated water-depleted syngas stream into a second RWGS reactor to obtain a second syngas containing stream; and cooling the second syngas containing stream in the second heat exchanger against the water-depleted syngas to obtain a cooled syngas product stream.

Abstract: The present invention relates to a process for converting feed streams selected from (1) a gas stream comprising carbon dioxide and a hydrogen rich gas stream; (2) a methane rich gas stream; and (3) a combination of feed streams (1) and (2) into a product stream comprising carbon monoxide, water and hydrogen. The process may include introducing feed streams selected from (1), (2) or (3) and oxygen into a reaction vessel and switching modes between performing method I or method II in the reaction vessel wherein no catalyst is present. The reaction vessel may be provided with a burner located at the top of the reaction vessel, the burner may include coaxial channels for the separate introduction of the different gas streams. Method I may be a reverse water gas shift reaction at elevated temperature. Method II may be a partial oxidation reaction at elevated temperature.

Abstract: The present invention relates to a process for converting carbon dioxide and hydrogen by performing a reverse water gas shift reaction at elevated temperature, the process comprising introducing carbon dioxide, hydrogen and oxygen into a reaction vessel having an inlet and an outlet, and, wherein the reverse water gas shift reaction takes place in two different zones of the reaction vessel, being a top zone (z1) adjacent to a bottom zone (z2). The process produces a product stream comprising mainly carbon monoxide, hydrogen and water. The process is useful in reducing the carbon footprint of certain industrial technologies, and in addition, the process is useful in the production of synthesis gas.

Abstract: The present invention pertains to a reactor tube comprising a fixed bed of Fischer-Tropsch catalyst particles, wherein the catalyst particles in 5% to 40% of the fixed bed volume at the upstream end have an average outer surface to volume ratio (S/V) in the range of between 3.0 to 4.5 mm?1, and the catalyst particles in the remaining fixed bed volume have an average outer surface to volume ratio (S/V) in the range of between 4.5 to 8.0 mm?1, and wherein the difference between the average S/V of the particles at the upstream end and the average S/V of the particles in the remaining fixed bed volume is at least 0.5 mm?1.

Abstract: The present invention pertains to a reactor tube comprising a fixed bed of Fischer-Tropsch catalyst particles, wherein the catalyst particles in 5% to 40% of the fixed bed volume at the upstream end have an average outer surface to volume ratio (S/V) in the range of between 3.0 to 4.5 mm?1, and the catalyst particles in the remaining fixed bed volume have an average outer surface to volume ratio (S/V) in the range of between 4.5 to 8.0 mm?1, and wherein the difference between the average S/V of the particles at the upstream end and the average S/V of the particles in the remaining fixed bed volume is at least 0.5 mm?1.