Integration of CO2 capturing from flue gases using Aqueous Ammonia for Low Emissions Urea Production
El-Maghraby, R., Behairy, M., Fathy, M. (2025). Integration of CO2 capturing from flue gases using Aqueous Ammonia for Low Emissions Urea Production. EKB Journal Management System, 68(2), 361-370. doi: 10.21608/ejchem.2024.291337.9749
Rehab M. El-Maghraby; Mohamed Behairy; Mohammed Fathy. "Integration of CO2 capturing from flue gases using Aqueous Ammonia for Low Emissions Urea Production". EKB Journal Management System, 68, 2, 2025, 361-370. doi: 10.21608/ejchem.2024.291337.9749
El-Maghraby, R., Behairy, M., Fathy, M. (2025). 'Integration of CO2 capturing from flue gases using Aqueous Ammonia for Low Emissions Urea Production', EKB Journal Management System, 68(2), pp. 361-370. doi: 10.21608/ejchem.2024.291337.9749
El-Maghraby, R., Behairy, M., Fathy, M. Integration of CO2 capturing from flue gases using Aqueous Ammonia for Low Emissions Urea Production. EKB Journal Management System, 2025; 68(2): 361-370. doi: 10.21608/ejchem.2024.291337.9749

Integration of CO2 capturing from flue gases using Aqueous Ammonia for Low Emissions Urea Production

Egyptian Journal of Chemistry
Volume 68, Issue 2, February 2025, Page 361-370  XML PDF (438.42 K)
Document Type: Original Article
DOI: 10.21608/ejchem.2024.291337.9749
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Authors
Rehab M. El-Maghraby email 1; Mohamed Behairy2; Mohammed Fathy3
1Petroleum Refinery and Petrochemical Engineering Department, Faculty of Petroleum and Mining Engineering, Suez University
2Misr Fertlizers Production Company (MOPCO), Dameitta, Egypt
3Egyptian Refinery Company (ERC), Cairo, Egypt
Abstract
Carbon Capture and Utilization is one the potential solution to mitigate global warming. In this study, aqueous ammonia is used for capturing CO2 from flue gases, the produced slurry is then utilized for urea production. In this work, modification is conducted to the original solid controlled formation chilled ammonia process. During this, ammonium carbonate slurry is produced, which can play a crucial part as intermediate element in urea synthesis. Process stream integration and waste energy utilization are considered in many points, in addition to, urea revamp to accommodate this modification.



The proposed modification is simulated in Aspen Plus using extended thermodynamics model. Due to this modification and process integration, the regeneration section and effluent treatment section were completely removed which greatly decreased energy consumption. It is found that, energy consumption in the solid controlled formation process decreased by 23.4%. Moreover, through the proposed energy integration with the urea production plant, a zero-energy consumption is reached together with an increase in urea production by 8 t/hr. This also has an environmental impact as the amount of associated CO2 emissions decreased by 6% which affected the carbon footprint of the plant. Our work is in agreement with the United Nation Sustainable Development Goals; goals number 2, 7 and 13. Utilizing carbon dioxide emissions initiated a transformative shift in industrial practices in alignment with sustainability requirements.
Keywords
Carbon Capture and Utilization (CCU); Aqueous Ammonia Process; Post-combustion Capture; Urea Production; Carbon Footprint; Sustainable Urea
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