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Membrane processes for post-combustion carbon dioxide capture: A parametric study

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  • Bounaceur, Roda
  • Lape, Nancy
  • Roizard, Denis
  • Vallieres, Cécile
  • Favre, Eric

Abstract

Much of the research in the area of carbon dioxide recovery and storage focuses on minimizing the energy required for CO2 capture, as this step corresponds to the major cost contribution of the overall process (capture, transportation, injection). Out of the three traditional methods of CO2 capture (absorption, adsorption and membrane processes), absorption is considered to be the best available technology for post-combustion application. However, amine absorption requires 4–6GJ/tonne of recovered CO2, in a large part due to significant energy consumption associated with the regeneration step.

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  • Bounaceur, Roda & Lape, Nancy & Roizard, Denis & Vallieres, Cécile & Favre, Eric, 2006. "Membrane processes for post-combustion carbon dioxide capture: A parametric study," Energy, Elsevier, vol. 31(14), pages 2556-2570.
  • Handle: RePEc:eee:energy:v:31:y:2006:i:14:p:2556-2570
    DOI: 10.1016/j.energy.2005.10.038
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    1. Corti, Andrea & Fiaschi, Daniele & Lombardi, Lidia, 2004. "Carbon dioxide removal in power generation using membrane technology," Energy, Elsevier, vol. 29(12), pages 2025-2043.
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    2. Wang, Meihong & Joel, Atuman S. & Ramshaw, Colin & Eimer, Dag & Musa, Nuhu M., 2015. "Process intensification for post-combustion CO2 capture with chemical absorption: A critical review," Applied Energy, Elsevier, vol. 158(C), pages 275-291.
    3. Ganapathy, Harish & Steinmayer, Sascha & Shooshtari, Amir & Dessiatoun, Serguei & Ohadi, Michael M. & Alshehhi, Mohamed, 2016. "Process intensification characteristics of a microreactor absorber for enhanced CO2 capture," Applied Energy, Elsevier, vol. 162(C), pages 416-427.
    4. Ganapathy, H. & Shooshtari, A. & Dessiatoun, S. & Alshehhi, M. & Ohadi, M., 2014. "Fluid flow and mass transfer characteristics of enhanced CO2 capture in a minichannel reactor," Applied Energy, Elsevier, vol. 119(C), pages 43-56.
    5. Belaissaoui, Bouchra & Cabot, Gilles & Cabot, Marie-Sophie & Willson, David & Favre, Eric, 2012. "An energetic analysis of CO2 capture on a gas turbine combining flue gas recirculation and membrane separation," Energy, Elsevier, vol. 38(1), pages 167-175.
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    9. Chen, Wei-Hsin & Hou, Yu-Lin & Hung, Chen-I., 2012. "A study of influence of acoustic excitation on carbon dioxide capture by a droplet," Energy, Elsevier, vol. 37(1), pages 311-321.
    10. Rafał Ślefarski, 2019. "Study on the Combustion Process of Premixed Methane Flames with CO 2 Dilution at Elevated Pressures," Energies, MDPI, vol. 12(3), pages 1-17, January.
    11. Kotowicz, Janusz & Chmielniak, Tadeusz & Janusz-Szymańska, Katarzyna, 2010. "The influence of membrane CO2 separation on the efficiency of a coal-fired power plant," Energy, Elsevier, vol. 35(2), pages 841-850.
    12. Kazemi, Abolghasem & Mehrabani-Zeinabad, Arjomand, 2016. "Post combustion carbon capture: Does optimization of the processing system based on energy and utility requirements warrant the lowest possible costs?," Energy, Elsevier, vol. 112(C), pages 353-363.
    13. Akorede, M.F. & Hizam, H. & Ab Kadir, M.Z.A. & Aris, I. & Buba, S.D., 2012. "Mitigating the anthropogenic global warming in the electric power industry," Renewable and Sustainable Energy Reviews, Elsevier, vol. 16(5), pages 2747-2761.
    14. Giordano, Lorena & Roizard, Denis & Bounaceur, Roda & Favre, Eric, 2016. "Interplay of inlet temperature and humidity on energy penalty for CO2 post-combustion capture: Rigorous analysis and simulation of a single stage gas permeation process," Energy, Elsevier, vol. 116(P1), pages 517-525.
    15. Song, Chunfeng & Liu, Qingling & Ji, Na & Deng, Shuai & Zhao, Jun & Li, Yang & Kitamura, Yutaka, 2017. "Reducing the energy consumption of membrane-cryogenic hybrid CO2 capture by process optimization," Energy, Elsevier, vol. 124(C), pages 29-39.
    16. Zhao, Ruikai & Deng, Shuai & Liu, Yinan & Zhao, Qing & He, Junnan & Zhao, Li, 2017. "Carbon pump: Fundamental theory and applications," Energy, Elsevier, vol. 119(C), pages 1131-1143.
    17. Zhang, Yingying & Ji, Xiaoyan & Lu, Xiaohua, 2014. "Energy consumption analysis for CO2 separation from gas mixtures," Applied Energy, Elsevier, vol. 130(C), pages 237-243.
    18. Ryi, Shin-Kun & Lee, Chun-Boo & Lee, Sung-Wook & Park, Jong-Soo, 2013. "Pd-based composite membrane and its high-pressure module for pre-combustion CO2 capture," Energy, Elsevier, vol. 51(C), pages 237-242.
    19. Liu, Yinan & Deng, Shuai & Zhao, Ruikai & He, Junnan & Zhao, Li, 2017. "Energy-saving pathway exploration of CCS integrated with solar energy: A review of innovative concepts," Renewable and Sustainable Energy Reviews, Elsevier, vol. 77(C), pages 652-669.
    20. Nguyen, Ngoc N. & La, Vinh T. & Huynh, Chinh D. & Nguyen, Anh V., 2022. "Technical and economic perspectives of hydrate-based carbon dioxide capture," Applied Energy, Elsevier, vol. 307(C).
    21. Sreedhar, I. & Vaidhiswaran, R. & Kamani, Bansi. M. & Venugopal, A., 2017. "Process and engineering trends in membrane based carbon capture," Renewable and Sustainable Energy Reviews, Elsevier, vol. 68(P1), pages 659-684.
    22. Belaissaoui, Bouchra & Le Moullec, Yann & Favre, Eric, 2016. "Energy efficiency of a hybrid membrane/condensation process for VOC (Volatile Organic Compounds) recovery from air: A generic approach," Energy, Elsevier, vol. 95(C), pages 291-302.
    23. Vahid Mortezaeikia & Omid Tavakoli & Reza Yegani & Mohammadali Faramarzi, 2016. "Cyanobacterial CO 2 biofixation in batch and semi‐continuous cultivation, using hydrophobic and hydrophilic hollow fiber membrane photobioreactors," Greenhouse Gases: Science and Technology, Blackwell Publishing, vol. 6(2), pages 218-231, April.
    24. Li, Sheng & Gao, Lin & Zhang, Xiaosong & Lin, Hu & Jin, Hongguang, 2012. "Evaluation of cost reduction potential for a coal based polygeneration system with CO2 capture," Energy, Elsevier, vol. 45(1), pages 101-106.

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