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Novel Adsorption–Reaction Process for Biomethane Purification/Production and Renewable Energy Storage

[Image: see text] This work proposes an innovative method for the simultaneous upgrading of biogas streams and valorization of the separated CO(2), through its conversion to renewable methane. To this end, two sorptive reactors were filled with a layered bed containing a CO(2) sorbent (K-promoted hy...

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Autores principales: Martins, Joana A., Miguel, Carlos V., Rodrigues, Alírio E., Madeira, Luis M.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: American Chemical Society 2022
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9793493/
https://www.ncbi.nlm.nih.gov/pubmed/36590651
http://dx.doi.org/10.1021/acssuschemeng.1c06844
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author Martins, Joana A.
Miguel, Carlos V.
Rodrigues, Alírio E.
Madeira, Luis M.
author_facet Martins, Joana A.
Miguel, Carlos V.
Rodrigues, Alírio E.
Madeira, Luis M.
author_sort Martins, Joana A.
collection PubMed
description [Image: see text] This work proposes an innovative method for the simultaneous upgrading of biogas streams and valorization of the separated CO(2), through its conversion to renewable methane. To this end, two sorptive reactors were filled with a layered bed containing a CO(2) sorbent (K-promoted hydrotalcite) and a methanation catalyst (Ru/Al(2)O(3)). The continuous cyclic operation of the parallel sorptive reactors was carried out by alternately feeding a biogas stream (CO(2)/CH(4) mixture) or H(2). The CO(2)/CH(4) mixture is fed to the sorptive reactor during the sorption stage, with CO(2) being captured by the sorbent and CH(4) exiting as a purified stream (i.e., as biomethane). During the reactive regeneration stage, the inlet stream is switched to pure H(2), which reacts with the previously captured CO(2) at the methanation catalyst active sites thus producing additional methane. For continuous operation, the two sorptive reactors were operated 180° out of phase and cyclic steady-state could be reached after ca. five cycles. The performance of the cyclic sorptive-reactive unit was assessed through a parametric study to evaluate the influence of different operating conditions, namely, the inlet flow rate and CO(2) content during the sorption stage, the hydrogen inlet flow rate during the reactive regeneration stage, the stage duration, and temperature. The inclusion of an inert purge after the reactive regeneration stage was also tested. The performance of the unit was compared to the case of direct hydrogenation of biogas, and conclusions were drawn regarding future optimization, with special attention being given to CH(4) productivity and purity. During the parametric study, a compromise between these process indicators, i.e., a productivity of 1.63 mol(CH4) kg(cat)(–1) h(–1) with 70.3% of CH(4) purity, was obtained at 350 °C. However, biomethane purities above 80% were easily achieved, though at the expense of methane productivities.
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spelling pubmed-97934932022-12-28 Novel Adsorption–Reaction Process for Biomethane Purification/Production and Renewable Energy Storage Martins, Joana A. Miguel, Carlos V. Rodrigues, Alírio E. Madeira, Luis M. ACS Sustain Chem Eng [Image: see text] This work proposes an innovative method for the simultaneous upgrading of biogas streams and valorization of the separated CO(2), through its conversion to renewable methane. To this end, two sorptive reactors were filled with a layered bed containing a CO(2) sorbent (K-promoted hydrotalcite) and a methanation catalyst (Ru/Al(2)O(3)). The continuous cyclic operation of the parallel sorptive reactors was carried out by alternately feeding a biogas stream (CO(2)/CH(4) mixture) or H(2). The CO(2)/CH(4) mixture is fed to the sorptive reactor during the sorption stage, with CO(2) being captured by the sorbent and CH(4) exiting as a purified stream (i.e., as biomethane). During the reactive regeneration stage, the inlet stream is switched to pure H(2), which reacts with the previously captured CO(2) at the methanation catalyst active sites thus producing additional methane. For continuous operation, the two sorptive reactors were operated 180° out of phase and cyclic steady-state could be reached after ca. five cycles. The performance of the cyclic sorptive-reactive unit was assessed through a parametric study to evaluate the influence of different operating conditions, namely, the inlet flow rate and CO(2) content during the sorption stage, the hydrogen inlet flow rate during the reactive regeneration stage, the stage duration, and temperature. The inclusion of an inert purge after the reactive regeneration stage was also tested. The performance of the unit was compared to the case of direct hydrogenation of biogas, and conclusions were drawn regarding future optimization, with special attention being given to CH(4) productivity and purity. During the parametric study, a compromise between these process indicators, i.e., a productivity of 1.63 mol(CH4) kg(cat)(–1) h(–1) with 70.3% of CH(4) purity, was obtained at 350 °C. However, biomethane purities above 80% were easily achieved, though at the expense of methane productivities. American Chemical Society 2022-06-07 2022-06-20 /pmc/articles/PMC9793493/ /pubmed/36590651 http://dx.doi.org/10.1021/acssuschemeng.1c06844 Text en © 2022 American Chemical Society https://creativecommons.org/licenses/by/4.0/Permits the broadest form of re-use including for commercial purposes, provided that author attribution and integrity are maintained (https://creativecommons.org/licenses/by/4.0/).
spellingShingle Martins, Joana A.
Miguel, Carlos V.
Rodrigues, Alírio E.
Madeira, Luis M.
Novel Adsorption–Reaction Process for Biomethane Purification/Production and Renewable Energy Storage
title Novel Adsorption–Reaction Process for Biomethane Purification/Production and Renewable Energy Storage
title_full Novel Adsorption–Reaction Process for Biomethane Purification/Production and Renewable Energy Storage
title_fullStr Novel Adsorption–Reaction Process for Biomethane Purification/Production and Renewable Energy Storage
title_full_unstemmed Novel Adsorption–Reaction Process for Biomethane Purification/Production and Renewable Energy Storage
title_short Novel Adsorption–Reaction Process for Biomethane Purification/Production and Renewable Energy Storage
title_sort novel adsorption–reaction process for biomethane purification/production and renewable energy storage
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9793493/
https://www.ncbi.nlm.nih.gov/pubmed/36590651
http://dx.doi.org/10.1021/acssuschemeng.1c06844
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