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Simulation of Methanol and Urea Production from Catalytic Conversion of Steel Mill Gases

Schlüter, Stefan / Geitner, Christian

The time‐dependent operation of methanol, ammonia, and urea production units embedded in a steel mill environment is analyzed with dynamic simulation models. From different process concepts and gas availability scenarios, a set of simulation cases is defined with blast furnace gas as carbon and coke oven gas as hydrogen source. Dynamic simulations indicate that significant CO₂ reductions require large amounts of additional H₂ from sustainable sources. From the results, global data such as carbon footprint or energy demands and details about process unit operation are obtained and processed.

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Simulation of Methanol and Urea Production from Catalytic Conversion of Steel Mill Gases

Schlüter, Stefan / Geitner, Christian

The time‐dependent operation of methanol, ammonia, and urea production units embedded in a steel mill environment is analyzed with dynamic simulation models. From different process concepts and gas availability scenarios, a set of simulation cases is defined with blast furnace gas as carbon and coke oven gas as hydrogen source. Dynamic simulations indicate that significant CO₂ reductions require large amounts of additional H₂ from sustainable sources. From the results, global data such as carbon footprint or energy demands and details about process unit operation are obtained and processed.

Simulation of Methanol and Urea Production from Catalytic Conversion of Steel Mill Gases

Schlüter, Stefan / Geitner, Christian

The time‐dependent operation of methanol, ammonia, and urea production units embedded in a steel mill environment is analyzed with dynamic simulation models. From different process concepts and gas availability scenarios, a set of simulation cases is defined with blast furnace gas as carbon and coke oven gas as hydrogen source. Dynamic simulations indicate that significant CO₂ reductions require large amounts of additional H₂ from sustainable sources. From the results, global data such as carbon footprint or energy demands and details about process unit operation are obtained and processed.

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Titel:

Simulation of Methanol and Urea Production from Catalytic Conversion of Steel Mill Gases

Beteiligte:

Schlüter, Stefan (Autor:in) / Geitner, Christian (Autor:in)

Erschienen in:

Chemie Ingenieur Technik ; 92 ; 1403-1415

Erscheinungsdatum:

01.10.2020

Format / Umfang:

13 pages

ISSN:

0009-286X , 1522-2640

DOI:

https://doi.org/10.1002/cite.202000068

Medientyp:

Aufsatz (Zeitschrift)

Format:

Elektronische Ressource

Sprache:

Englisch

Schlagwörter:

Carbon2Chem , Urea , Methanol , Simulation , Steel Mill Gases

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