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Comparative study of chemical absorbents in postcombustion CO2 capture

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  • Pellegrini, G.
  • Strube, R.
  • Manfrida, G.

Abstract

In order to reduce CO2 emissions from a power plant, CO2 can be captured either from the syngas that is to be burned or from the flue gases exiting the energy conversion process. Postcombustion capture has the advantage that it can be applied to retrofit existing power plants. In this paper the authors compare two primary amines (MEA and DGA) to ammonia with respect to their capability to capture CO2 from a flue gas stream. The ammonia process captures CO2 by formation of stable salts, which are separated from the solvent stream by filtration or sedimentation. These salts can be used commercially as fertilizers. Energy requirements are greatly reduced, since no heat is required for solvent regeneration, and no compression of the separated CO2 is necessary. Energy, however, is required for the reduction of ammonia emissions. In order to obtain the solid ammonia salts, their solubility has to be reduced by modification of the solvent and by lowering absorption temperature. With and without separation of the salt products, ammonia proved to be an alternative solvent with high CO2 removal efficiency. Simulation of all processes was carried out with Aspen Plus® and compared to experimental results for CO2 scrubbing with ammonia.

Suggested Citation

  • Pellegrini, G. & Strube, R. & Manfrida, G., 2010. "Comparative study of chemical absorbents in postcombustion CO2 capture," Energy, Elsevier, vol. 35(2), pages 851-857.
  • Handle: RePEc:eee:energy:v:35:y:2010:i:2:p:851-857
    DOI: 10.1016/j.energy.2009.08.011
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    1. Reddick, Christopher & Sorin, Mikhail & Sapoundjiev, Hristo & Aidoun, Zine, 2016. "Carbon capture simulation using ejectors for waste heat upgrading," Energy, Elsevier, vol. 100(C), pages 251-261.
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    3. Zhao, Zhijun & Xing, Xiao & Tang, Zhigang & Zheng, Yong & Fei, Weiyang & Liang, Xiangfeng & Ataeivarjovi, E. & Guo, Dong, 2018. "Experiment and simulation study of CO2 solubility in dimethyl carbonate, 1-octyl-3-methylimidazolium tetrafluoroborate and their mixtures," Energy, Elsevier, vol. 143(C), pages 35-42.
    4. Natalia Czaplicka & Donata Konopacka-Łyskawa, 2020. "Utilization of Gaseous Carbon Dioxide and Industrial Ca-Rich Waste for Calcium Carbonate Precipitation: A Review," Energies, MDPI, vol. 13(23), pages 1-25, November.
    5. Zhang, Minkai & Guo, Yincheng, 2017. "Regeneration energy analysis of NH3-based CO2 capture process integrated with a flow-by capacitive ion separation device," Energy, Elsevier, vol. 125(C), pages 178-185.
    6. Xu, Cheng & Li, Xiaosa & Xin, Tuantuan & Liu, Xin & Xu, Gang & Wang, Min & Yang, Yongping, 2019. "A thermodynamic analysis and economic assessment of a modified de-carbonization coal-fired power plant incorporating a supercritical CO2 power cycle and an absorption heat transformer," Energy, Elsevier, vol. 179(C), pages 30-45.
    7. Zhao, Bingtao & Su, Yaxin & Cui, Guomin, 2016. "Post-combustion CO2 capture with ammonia by vortex flow-based multistage spraying: Process intensification and performance characteristics," Energy, Elsevier, vol. 102(C), pages 106-117.
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    9. Lee, Zhi Hua & Lee, Keat Teong & Bhatia, Subhash & Mohamed, Abdul Rahman, 2012. "Post-combustion carbon dioxide capture: Evolution towards utilization of nanomaterials," Renewable and Sustainable Energy Reviews, Elsevier, vol. 16(5), pages 2599-2609.
    10. Sreenivasulu, B. & Gayatri, D.V. & Sreedhar, I. & Raghavan, K.V., 2015. "A journey into the process and engineering aspects of carbon capture technologies," Renewable and Sustainable Energy Reviews, Elsevier, vol. 41(C), pages 1324-1350.
    11. Wang, Fu & Zhao, Jun & Miao, He & Zhao, Jiapei & Zhang, Houcheng & Yuan, Jinliang & Yan, Jinyue, 2018. "Current status and challenges of the ammonia escape inhibition technologies in ammonia-based CO2 capture process," Applied Energy, Elsevier, vol. 230(C), pages 734-749.
    12. Theunissen, Ton & Golombok, Mike & Brouwers, J.J.H. (Bert) & Bansal, Gagan & van Benthum, Rob, 2011. "Liquid CO2 droplet extraction from gases," Energy, Elsevier, vol. 36(5), pages 2961-2967.
    13. Pettinau, Alberto & Ferrara, Francesca & Amorino, Carlo, 2012. "Techno-economic comparison between different technologies for a CCS power generation plant integrated with a sub-bituminous coal mine in Italy," Applied Energy, Elsevier, vol. 99(C), pages 32-39.
    14. Pettinau, Alberto & Ferrara, Francesca & Amorino, Carlo, 2013. "Combustion vs. gasification for a demonstration CCS (carbon capture and storage) project in Italy: A techno-economic analysis," Energy, Elsevier, vol. 50(C), pages 160-169.
    15. Chang, Yuan & Gao, Siqi & Ma, Qian & Wei, Ying & Li, Guoping, 2024. "Techno-economic analysis of carbon capture and utilization technologies and implications for China," Renewable and Sustainable Energy Reviews, Elsevier, vol. 199(C).
    16. Mores, Patricia & Scenna, Nicolás & Mussati, Sergio, 2012. "CO2 capture using monoethanolamine (MEA) aqueous solution: Modeling and optimization of the solvent regeneration and CO2 desorption process," Energy, Elsevier, vol. 45(1), pages 1042-1058.
    17. Abid Salam Farooqi & Raihan Mahirah Ramli & Serene Sow Mun Lock & Noorhidayah Hussein & Muhammad Zubair Shahid & Ahmad Salam Farooqi, 2022. "Simulation of Natural Gas Treatment for Acid Gas Removal Using the Ternary Blend of MDEA, AEEA, and NMP," Sustainability, MDPI, vol. 14(17), pages 1-16, August.
    18. Harkin, Trent & Hoadley, Andrew & Hooper, Barry, 2012. "Using multi-objective optimisation in the design of CO2 capture systems for retrofit to coal power stations," Energy, Elsevier, vol. 41(1), pages 228-235.
    19. Delgado, Montserrat Rodriguez & Arean, Carlos Otero, 2011. "Carbon monoxide, dinitrogen and carbon dioxide adsorption on zeolite H-Beta: IR spectroscopic and thermodynamic studies," Energy, Elsevier, vol. 36(8), pages 5286-5291.
    20. Chu, Fengming & Liu, Yifang & Yang, Lijun & Du, Xiaoze & Yang, Yongping, 2017. "Ammonia escape mass transfer and heat transfer characteristics of CO2 absorption in packed absorbing column," Applied Energy, Elsevier, vol. 205(C), pages 1596-1604.
    21. Yaser Khojasteh Salkuyeh & Thomas A. Adams II, 2015. "Co-Production of Olefins, Fuels, and Electricity from Conventional Pipeline Gas and Shale Gas with Near-Zero CO 2 Emissions. Part I: Process Development and Technical Performance," Energies, MDPI, vol. 8(5), pages 1-23, April.
    22. Zhang, Yingying & Ji, Xiaoyan & Xie, Yujiao & Lu, Xiaohua, 2016. "Screening of conventional ionic liquids for carbon dioxide capture and separation," Applied Energy, Elsevier, vol. 162(C), pages 1160-1170.
    23. Chmielniak, Tadeusz & Lepszy, Sebastian & Wójcik, Katarzyna, 2012. "Analysis of gas turbine combined heat and power system for carbon capture installation of coal-fired power plant," Energy, Elsevier, vol. 45(1), pages 125-133.
    24. Li, Huiyi & Gao, Jianmin & Du, Qian & Shan, Jingjing & Zhang, Yu & Wu, Shaohua & Wang, Zhijiang, 2021. "Direct CO2electroreduction from NH4HCO3electrolyte to syngas on bromine-modified Ag catalyst," Energy, Elsevier, vol. 216(C).

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