Methane Chemical Looping mixed dry reforming - CLMDR (dry reforming and partial oxidation) is an integrate process that utilizes CO2 directly, in presence of carrier materials, for the production of syngas with tuneable H2/CO molar ratio. Herein Cerium oxide was selected as reference source of oxygen and its use in the CLMDR process was evaluated by means of thermodynamic tools of Aspen Plus process simulator. Crucial features such as reforming and regeneration operative temperature, oxygen to methane molar ratio and CO2 addition were investigated in order to identify the most suitable and effective conditions for process. Simulation results of the proposed metal oxide were compared on the basis of methane conversion and syngas purity. Relevantly, cerium-based oxide was found to be selective in syngas production even when CO2 was added to the reforming reactor. After the required thermodynamic validation, a fixed bed reactor on lab scale was specifically designed and fabricated, and cerium oxide oxygen carrier characterized by Thermogravimetric analysis. Thermodynamic results and experimental tests proved the solid/gas chemical reaction takes place with appreciable conversions, and they also demonstrated the stability of the oxygen carrier redox properties during several cycles, thus confirming the feasibility of this new process.

Storione A., Minelli M., Doghieri F., Landi E., Miccio F. (2021). Thermodynamic study on the feasibility of a new combined chemical looping process for syngas production. CHEMICAL ENGINEERING TRANSACTIONS, 86, 1267-1272 [10.3303/CET2186212].

Thermodynamic study on the feasibility of a new combined chemical looping process for syngas production

Storione A.
;
Minelli M.;Doghieri F.;
2021

Abstract

Methane Chemical Looping mixed dry reforming - CLMDR (dry reforming and partial oxidation) is an integrate process that utilizes CO2 directly, in presence of carrier materials, for the production of syngas with tuneable H2/CO molar ratio. Herein Cerium oxide was selected as reference source of oxygen and its use in the CLMDR process was evaluated by means of thermodynamic tools of Aspen Plus process simulator. Crucial features such as reforming and regeneration operative temperature, oxygen to methane molar ratio and CO2 addition were investigated in order to identify the most suitable and effective conditions for process. Simulation results of the proposed metal oxide were compared on the basis of methane conversion and syngas purity. Relevantly, cerium-based oxide was found to be selective in syngas production even when CO2 was added to the reforming reactor. After the required thermodynamic validation, a fixed bed reactor on lab scale was specifically designed and fabricated, and cerium oxide oxygen carrier characterized by Thermogravimetric analysis. Thermodynamic results and experimental tests proved the solid/gas chemical reaction takes place with appreciable conversions, and they also demonstrated the stability of the oxygen carrier redox properties during several cycles, thus confirming the feasibility of this new process.
2021
Storione A., Minelli M., Doghieri F., Landi E., Miccio F. (2021). Thermodynamic study on the feasibility of a new combined chemical looping process for syngas production. CHEMICAL ENGINEERING TRANSACTIONS, 86, 1267-1272 [10.3303/CET2186212].
Storione A.; Minelli M.; Doghieri F.; Landi E.; Miccio F.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/849982
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