Conceptual design of syngas production by the integration of gasification and dry-reforming technologies with CO2 capture and utilization

•Series and parallel integrations of gasification and dry reforming are proposed.•The proposed integrated design reduces the energy requirement by 62%.•The proposed integrated design reduced the carbon emissions by 53.5%.•Integrated design offers lower product cost compared to the standalone process...

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Bibliographic Details
Published in:Energy conversion and management 2021-09, Vol.244, p.114485, Article 114485
Main Authors: Alibrahim, Hussain A., Khalafalla, Siddig S., Ahmed, Usama, Park, Seongho, Lee, Chul-Jin, Zahid, Umer
Format: Article
Language:English
Subjects:
Carbon capture and utilization
Carbon dioxide
Carbon dioxide emissions
Carbon sequestration
Clean fuels
Coal gasification
Conceptual design
Design
Dry reforming
Economic analysis
Emissions control
Energy
Fossil fuels
Fuels
Gasification
Integration
Natural gas
Process simulation
Production costs
Reforming
Sustainability
Syngas
Synthesis gas
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Summary:•Series and parallel integrations of gasification and dry reforming are proposed.•The proposed integrated design reduces the energy requirement by 62%.•The proposed integrated design reduced the carbon emissions by 53.5%.•Integrated design offers lower product cost compared to the standalone processes. Syngas is an important intermediate feedstock to produce various downstream chemicals and clean fuels. In this study, two standalone process models are first developed to produce syngas from coal gasification and natural gas dry reforming which provide the results for benchmarking the conceptual design. Two process models are then developed by integrating the gasification and dry-reforming models in the parallel and series configuration to improve the process performance. All the models are developed in Aspen Plus for producing the syngas at the rate of 10,000 kmol/h with H2/CO ratio of 2. The heat integration is also developed in a way to utilize the heat energy from the coal-derived syngas into the dry-reformer without any energy penalties. The performance of the proposed designs is compared to the standalone processes in terms of the energy, emissions and economics. The energy analysis reveals that the integrated design requires 62% less energy input compared to the standalone dry reforming process. The results also show that combining the synergies of the two technologies reduce the CO2 emission by 53.5% compared to the standalone gasification process. In addition to improved process efficiency and reduced emissions, the integrated design offers the lowest syngas production cost of $ 0.99/kmol among all the designs. The proposed integrated designs can enable the utilization of fossil fuels in an environment friendly, technically feasible and an economical way.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2021.114485