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New approach for biogas purification using cryogenic separation and distillation process for CO2 capture

Author

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  • Yousef, Ahmed M.
  • El-Maghlany, Wael M.
  • Eldrainy, Yehia A.
  • Attia, Abdelhamid

Abstract

Biogas – a renewable energy source encompassing primarily CO2/CH4 mixture, can fuel vehicles if it is properly purified. Recently, cryogenic biogas upgrading (CO2 Liquefaction) witnesses a significant progress as a promising purification technique; however, the obstacle hinders its implementation is CO2 freeze-out causing crucial issues as blockage pipes. Therefore, in-depth analysis for tackling this barrier is performed in this work through optimizing operating conditions of a typical low-temperature CO2/CH4 distillation process. Optimization is conducted towards avoiding frosting and lowering energy consumption via varying distillation pressure, temperature, reflux ratio and number of trays, biogas feed composition, and CH4 purity generated. We found that, without CO2 freeze-out, obtaining CH4 purity of 97.12% (mol) – besides a valuable by-product (liquid CO2, 99.92% purity) – is achievable using two columns through adjusting some key parameters. The results divulge that raising distillation pressure and reflux ratio significantly mitigates frosting danger. Moreover, for energy-efficient process, using one column is the most efficient way to produce methane purity below 96% whereas two columns for higher purities. Also, feeding cryogenic process with high-concentration CO2 biogas alleviates energy penalty, ameliorating its competitiveness against traditional technologies. With these new findings, cryogenic platforms can be applicable, competitive biogas upgrading approach.

Suggested Citation

  • Yousef, Ahmed M. & El-Maghlany, Wael M. & Eldrainy, Yehia A. & Attia, Abdelhamid, 2018. "New approach for biogas purification using cryogenic separation and distillation process for CO2 capture," Energy, Elsevier, vol. 156(C), pages 328-351.
  • Handle: RePEc:eee:energy:v:156:y:2018:i:c:p:328-351
    DOI: 10.1016/j.energy.2018.05.106
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    Citations

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    Cited by:

    1. Yusuf, Noor & Almomani, Fares, 2023. "Recent advances in biogas purifying technologies: Process design and economic considerations," Energy, Elsevier, vol. 265(C).
    2. Baena-Moreno, Francisco M. & Rodríguez-Galán, Mónica & Vega, Fernando & Reina, T.R. & Vilches, Luis F. & Navarrete, Benito, 2019. "Converting CO2 from biogas and MgCl2 residues into valuable magnesium carbonate: A novel strategy for renewable energy production," Energy, Elsevier, vol. 180(C), pages 457-464.
    3. He, Ting & Si, Bin & Gundersen, Truls & Chen, Liqiong & Lin, Wensheng, 2024. "Integrated ethane recovery and cryogenic carbon capture in a dual mixed refrigerant natural gas liquefaction process," Energy, Elsevier, vol. 290(C).
    4. Chen, Jianan & Li, Anna & Huang, Zhu & Jiang, Wenming & Xi, Guang, 2023. "Non-equilibrium condensation in flue gas and migration trajectory of CO2 droplets in a supersonic separator," Energy, Elsevier, vol. 276(C).
    5. Abdolahi-Mansoorkhani, Hamed & Seddighi, Sadegh, 2019. "H2S and CO2 capture from gaseous fuels using nanoparticle membrane," Energy, Elsevier, vol. 168(C), pages 847-857.
    6. Alexander García-Mariaca & Eva Llera-Sastresa, 2021. "Review on Carbon Capture in ICE Driven Transport," Energies, MDPI, vol. 14(21), pages 1-30, October.
    7. Mohamadi-Baghmolaei, Mohamad & Hajizadeh, Abdollah & Zahedizadeh, Parviz & Azin, Reza & Zendehboudi, Sohrab, 2021. "Evaluation of hybridized performance of amine scrubbing plant based on exergy, energy, environmental, and economic prospects: A gas sweetening plant case study," Energy, Elsevier, vol. 214(C).
    8. Ga, Seongbin & An, Nahyeon & Lee, Gi Yeol & Joo, Chonghyo & Kim, Junghwan, 2024. "Multidisciplinary high-throughput screening of metal–organic framework for ammonia-based green hydrogen production," Renewable and Sustainable Energy Reviews, Elsevier, vol. 192(C).
    9. Kwan, Trevor Hocksun & Liao, Zhixin & Chen, Ziyang, 2024. "Techno-economic analysis of hybrid liquefaction and low-temperature adsorption carbon capture based on waste heat utilization," Energy, Elsevier, vol. 288(C).
    10. Esfandiyar Naeiji & Alireza Noorpoor & Hossein Ghanavati, 2022. "Energy, Exergy, and Economic Analysis of Cryogenic Distillation and Chemical Scrubbing for Biogas Upgrading and Hydrogen Production," Sustainability, MDPI, vol. 14(6), pages 1-23, March.
    11. Alivand, Masood S. & Mazaheri, Omid & Wu, Yue & Stevens, Geoffrey W. & Scholes, Colin A. & Mumford, Kathryn A., 2019. "Development of aqueous-based phase change amino acid solvents for energy-efficient CO2 capture: The role of antisolvent," Applied Energy, Elsevier, vol. 256(C).
    12. Wen, Chuang & Karvounis, Nikolas & Walther, Jens Honore & Yan, Yuying & Feng, Yuqing & Yang, Yan, 2019. "An efficient approach to separate CO2 using supersonic flows for carbon capture and storage," Applied Energy, Elsevier, vol. 238(C), pages 311-319.
    13. Wang, Pengfei & Chen, Yiqi & Teng, Ying & An, Senyou & Li, Yun & Han, Meng & Yuan, Bao & Shen, Suling & Chen, Bin & Han, Songbai & Zhu, Jinlong & Zhu, Jianbo & Zhao, Yusheng & Xie, Heping, 2024. "A comprehensive review of hydrogen purification using a hydrate-based method," Renewable and Sustainable Energy Reviews, Elsevier, vol. 194(C).
    14. Chen, Jianan & Huang, Zhu & Li, Anna & Gao, Ran & Jiang, Wenming, 2022. "Carbon capture in laval nozzles with different bicubic parametric curves and translation of witoszynski curves," Energy, Elsevier, vol. 260(C).
    15. Zang, Xiaoya & Zhou, Xuebing & Wan, Lihua & Wang, Jing & Liang, Deqing, 2020. "Investigation of hydrate formation by synthetic ternary gas mixture with cyclopentane(C5H10)," Energy, Elsevier, vol. 210(C).
    16. Naquash, Ahmad & Qyyum, Muhammad Abdul & Haider, Junaid & Bokhari, Awais & Lim, Hankwon & Lee, Moonyong, 2022. "State-of-the-art assessment of cryogenic technologies for biogas upgrading: Energy, economic, and environmental perspectives," Renewable and Sustainable Energy Reviews, Elsevier, vol. 154(C).
    17. Roberto Paglini & Marta Gandiglio & Andrea Lanzini, 2022. "Technologies for Deep Biogas Purification and Use in Zero-Emission Fuel Cells Systems," Energies, MDPI, vol. 15(10), pages 1-30, May.
    18. R. C. Assunção, Lorena & A. S. Mendes, Pietro & Matos, Stelvia & Borschiver, Suzana, 2021. "Technology roadmap of renewable natural gas: Identifying trends for research and development to improve biogas upgrading technology management," Applied Energy, Elsevier, vol. 292(C).
    19. Chen, Jianan & Huang, Zhu, 2022. "Spontaneous condensation of carbon dioxide in flue gas at supersonic state," Energy, Elsevier, vol. 254(PC).
    20. Yang, Sheng & Zhang, Lu & Song, Dongran, 2022. "Conceptual design, optimization and thermodynamic analysis of a CO2 capture process based on Rectisol," Energy, Elsevier, vol. 244(PA).
    21. Zbigniew Rogala & Michał Stanclik & Dariusz Łuszkiewicz & Ziemowit Malecha, 2023. "Perspectives for the Use of Biogas and Biomethane in the Context of the Green Energy Transformation on the Example of an EU Country," Energies, MDPI, vol. 16(4), pages 1-11, February.
    22. Mahmoodi-Eshkaftaki, Mahmood & Ebrahimi, Rahim, 2021. "Integrated deep learning neural network and desirability analysis in biogas plants: A powerful tool to optimize biogas purification," Energy, Elsevier, vol. 231(C).

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