Response surface methodology for optimization of dry oxidative reforming for hydrogen enrichment of biogas

The exploration of domestically available clean and renewable fuel is essential for the attainment of sustainable development goals. The hydrogen (H 2 )-enriched biogas being renewable and clean can be a highly favorable fuel. In this study, the response surface optimization of dry oxidative reformi...

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Bibliographic Details
Published in:Biomass conversion and biorefinery 2023-02, Vol.13 (4), p.2875-2883
Main Authors: Sharma, Himanshu, Dhir, Amit
Format: Article
Language:English
Subjects:
Bimetals
Biogas
Biotechnology
Carbon dioxide
Catalytic activity
Design factors
Design of experiments
Endothermic reactions
Energy
Enrichment
Experimentation
Fuels
Hydrogen enrichment
Methane
Optimization
Original Article
Reforming
Renewable and Green Energy
Response surface methodology
Statistical models
Sustainable development
Variance analysis
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Summary:The exploration of domestically available clean and renewable fuel is essential for the attainment of sustainable development goals. The hydrogen (H 2 )-enriched biogas being renewable and clean can be a highly favorable fuel. In this study, the response surface optimization of dry oxidative reforming using a three-level, three-factor experimental design for hydrogen enrichment of biogas over the nickel-cobalt bimetallic catalyst was investigated. The Box-Behnken design of experimentation was employed to assess the interaction and discrete effect of reforming temperature and ratios of CH 4 /CO 2 and O 2 /CH 4 . The effects of CH 4 /CO 2 ratio (1–2) and O 2 /CH 4 ratio (0.3–0.5) on catalytic activity were assessed in the temperature range of 700–800 °C. The conversion of both reactants (CH 4 and CO 2 ), yield of products (H 2 and CO), and ratio of products (H 2 /CO ratio) were selected as responses for statistical study. The analysis of variance demonstrated that reforming temperature and O 2 /CH 4 ratio have a statistically considerable impact on the H 2 enrichment of biogas by the virtue of higher endothermic nature of the reaction. Experimentally, the maximum H 2 enrichment of 44.04% was obtained at 800 °C with 1.5 and 0.5 CH 4 /CO 2 and O 2 /CH 4 ratio, respectively. However, from the statistical model, the optimum H 2 enrichment of 36.9% was obtained at 725.68 °C with CH 4 /CO 2 and O 2 /CH 4 ratios of 1.32 and 0.42, respectively. The close agreement between predicted and experimental data shows that the combination of response surface methodology and dry oxidative reforming could be an efficient approach for optimizing the H 2 enrichment of biogas and the generation of environment friendly fuel.
ISSN:2190-6815
2190-6823
DOI:10.1007/s13399-020-01244-5