Integrating oxy-fuel combustion and power-to-gas in the cement industry: A process modeling and simulation study

Integrating oxy-fuel combustion and power-to-gas in the cement industry: A process modeling and simulation study

•The integration of oxy-fuel combustion and gas energy technology was analyzed using steady-state modeling and simulation of a cement plant.•The simulation results for the studied scenarios indicate that clinker temperature is an important parameter for finding the most appropriate flue gas recircul...

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Bibliographic Details
Published in:International journal of greenhouse gas control Vol. 114; p. 103602
Main Authors: Faria, Débora G., Carvalho, Mariana M.O., Neto, Márcio R.V., de Paula, Eduardo C., Cardoso, Marcelo, Vakkilainen, Esa K.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-02-2022
Subjects:
Carbon dioxide capture
Carbon dioxide emissions
Carbon dioxide utilization
Cement clinkering
Oxy-fuel combustion
Power-to-gas
Carbon dioxide capture
Cement clinkering
Carbon dioxide emissions
Carbon dioxide utilization
Power-to-gas
Oxy-fuel combustion
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Summary:•The integration of oxy-fuel combustion and gas energy technology was analyzed using steady-state modeling and simulation of a cement plant.•The simulation results for the studied scenarios indicate that clinker temperature is an important parameter for finding the most appropriate flue gas recirculation for the oxy-fuel combustion process.•The modeling study showed trat is possible to use power-to-gas for the utilization of CO2 captured in the cement industry via the oxy-fuel process. The cement industry is one of the sectors responsible for the highest carbon dioxide (CO2) emissions of the world. CO2 capture technologies for storage and/or utilization are pointed out as the most relevant alternatives for significant greenhouse gases mitigation. Among CO2 capture technologies, oxy-fuel combustion has stood out due to its greater capture efficiency. For CO2 utilization, one alternative is to apply the power-to-gas technology. This study evaluated the CO2 capture and utilization for a cement industry employing oxy-fuel combustion and power-to-gas technologies. The integration of oxy-fuel combustion and power-to-gas technology was analyzed through the steady-state modeling and simulation of a cement plant using the commercial flowsheet simulation software Aspen Plus®. Results show that despite the high demand for electricity, it is possible to use power-to-gas for the utilization of CO2 captured in the cement industry via the oxy-fuel process. To meet the oxy-fuel O2 requirements, it is necessary that 21.9% of CO2 be utilized. The electric energy consumption by the oxy-fuel and power-to-gas integration could range from 0,7 to 7,0 MWh/tclinker. However, values as high as 304.7 kgSNG/tclinker could be produced, which would adhere to the standards required by Brazilian Law, assuming all captured CO2 was destined for utilization.
ISSN:1750-5836
1878-0148
DOI:10.1016/j.ijggc.2022.103602