Upgradation of methane in the biogas by hydrogenation of CO2 in a prototype reactor with double pass operation over optimized Ni-Ce/Al-MCM-41 catalyst

The upgradation of methane in biogas by hydrogenation of CO 2 has been currently recognized as a promising route for efficient full utilization of renewable biogas with potential benefits for storage of renewable hydrogen energy and abatement of greenhouse gas emission. As a main constituent of biog...

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Published in:Scientific reports 2023-06, Vol.13 (1), p.9342-9342, Article 9342
Main Authors: Aieamsam-Aung, Pichawee, Srifa, Atthapon, Koo-Amornpattana, Wanida, Assabumrungrat, Suttichai, Reubroycharoen, Prasert, Suchamalawong, Phorndranrat, Fukuhara, Choji, Ratchahat, Sakhon
Format: Article
Language:English
Subjects:
639/166
639/4077
639/925
704/172
Biogas
Carbon dioxide
Catalysts
Flow rates
Greenhouse gases
Humanities and Social Sciences
Hydrogenation
Methane
multidisciplinary
Physicochemical properties
Prototypes
Reactors
Science
Science (multidisciplinary)
Water vapor
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Summary:The upgradation of methane in biogas by hydrogenation of CO 2 has been currently recognized as a promising route for efficient full utilization of renewable biogas with potential benefits for storage of renewable hydrogen energy and abatement of greenhouse gas emission. As a main constituent of biogas, CO 2 can act as a backbone for the formation of additional CH 4 by hydrogenation, then producing higher amounts of biomethane. In this work, the upgradation process was investigated in a prototype reactor of double pass operation with vertical alignment using an optimized Ni-Ce/Al-MCM-41 catalyst. The experimental results show that the double pass operation that removes water vapor during the run can significantly increase CO 2 conversion, resulting in higher CH 4 production yield. As a result, the purity of biomethane increased by 15% higher than a single pass operation. In addition, search for optimum condition of the process was carried out within an investigated range of conditions including flowrate (77–1108 ml min −1 ), pressure (1 atm–20 bar), and temperature (200–500 °C). The durability test for 458 h was performed using the obtained optimum condition, and it shows that the optimized catalyst can perform excellent stability with negligible influence by the observed change in catalyst properties. The comprehensive characterization on physicochemical properties of fresh and spent catalysts was performed, and the results were discussed.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-023-36425-5