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The environmental impact of post-combustion CO2 capture with MEA, with aqueous ammonia, and with an aqueous ammonia-ethanol mixture for a coal-fired power plant

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

Abstract

In this paper the authors compare monoethanolamine (MEA) to aqueous ammonia (AA) and a solvent mixture of aqueous ammonia and ethanol (EAA) with respect to their post-combustion CO2 capture performance and their environmental impact. Simulation of all processes was carried out with Aspen Plus® and compared to experimental results for CO2 scrubbing with ammonia. Of special interest was the formation of stable salts, which could be observed in the experimental CO2 capture with both ammonia solvents. If CO2 can be captured in the form of ammonium salts, energy requirements are greatly reduced, since no energy is required for solvent regeneration and CO2 compression. The environmental impact of CO2 capture was investigated for a 500 MW pulverised coal power plant employing Life Cycle Assessment (LCA) using the software SimaPro®. For a comprehensive evaluation of this impact, influencing factors such as solvent production and solvent emissions were included. With kinetics taken into account, no salt formation could be observed in CO2 removal with aqueous ammonia. The necessary reduction of ammonia emissions leads to further energy requirements, and solvent production as well as the remaining ammonia losses to the environment have a more significant environmental impact than CO2 removal with MEA.

Suggested Citation

  • Strube, R. & Pellegrini, G. & Manfrida, G., 2011. "The environmental impact of post-combustion CO2 capture with MEA, with aqueous ammonia, and with an aqueous ammonia-ethanol mixture for a coal-fired power plant," Energy, Elsevier, vol. 36(6), pages 3763-3770.
    • Handle: RePEc:eee:energy:v:36:y:2011:i:6:p:3763-3770
    DOI: 10.1016/j.energy.2010.12.060
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    Cited by:

    1. 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.
    2. Don Rukmal Liyanage & Kasun Hewage & Hirushie Karunathilake & Gyan Chhipi-Shrestha & Rehan Sadiq, 2021. "Carbon Capture Systems for Building-Level Heating Systems—A Socio-Economic and Environmental Evaluation," Sustainability, MDPI, vol. 13(19), pages 1-30, September.
    3. N.Borhani, Tohid & Wang, Meihong, 2019. "Role of solvents in CO2 capture processes: The review of selection and design methods," Renewable and Sustainable Energy Reviews, Elsevier, vol. 114(C), pages 1-1.
    4. Iribarren, Diego & Petrakopoulou, Fontina & Dufour, Javier, 2013. "Environmental and thermodynamic evaluation of CO2 capture, transport and storage with and without enhanced resource recovery," Energy, Elsevier, vol. 50(C), pages 477-485.
    5. Shakerian, Farid & Kim, Ki-Hyun & Szulejko, Jan E. & Park, Jae-Woo, 2015. "A comparative review between amines and ammonia as sorptive media for post-combustion CO2 capture," Applied Energy, Elsevier, vol. 148(C), pages 10-22.
    6. Bartela, Łukasz & Skorek-Osikowska, Anna & Kotowicz, Janusz, 2014. "Economic analysis of a supercritical coal-fired CHP plant integrated with an absorption carbon capture installation," Energy, Elsevier, vol. 64(C), pages 513-523.
    7. Skorek-Osikowska, Anna & Janusz-Szymańska, Katarzyna & Kotowicz, Janusz, 2012. "Modeling and analysis of selected carbon dioxide capture methods in IGCC systems," Energy, Elsevier, vol. 45(1), pages 92-100.
    8. Cormos, Calin-Cristian & Vatopoulos, Konstantinos & Tzimas, Evangelos, 2013. "Assessment of the consumption of water and construction materials in state-of-the-art fossil fuel power generation technologies involving CO2 capture," Energy, Elsevier, vol. 51(C), pages 37-49.
    9. Michaelides, Efstathios E., 2021. "Thermodynamic analysis and power requirements of CO2 capture, transportation, and storage in the ocean," Energy, Elsevier, vol. 230(C).
    10. Rasul, M.G. & Moazzem, S. & Khan, M.M.K., 2014. "Performance assessment of carbonation process integrated with coal fired power plant to reduce CO2 (carbon dioxide) emissions," Energy, Elsevier, vol. 64(C), pages 330-341.
    11. Li, Kangkang & Yu, Hai & Qi, Guojie & Feron, Paul & Tade, Moses & Yu, Jingwen & Wang, Shujuan, 2015. "Rate-based modelling of combined SO2 removal and NH3 recycling integrated with an aqueous NH3-based CO2 capture process," Applied Energy, Elsevier, vol. 148(C), pages 66-77.
    12. Perevertaylenko, Olexander Yu. & Gariev, Andriy O. & Damartzis, Theodoros & Tovazhnyanskyy, Leonid L. & Kapustenko, Petro O. & Arsenyeva, Olga P., 2015. "Searches of cost effective ways for amine absorption unit design in CO2 post-combustion capture process," Energy, Elsevier, vol. 90(P1), pages 105-112.
    13. Janusz-Szymańska, Katarzyna & Dryjańska, Aleksandra, 2015. "Possibilities for improving the thermodynamic and economic characteristics of an oxy-type power plant with a cryogenic air separation unit," Energy, Elsevier, vol. 85(C), pages 45-61.
    14. Zhang, Yongliang & Jin, Bo & Zou, Xixian & Zhao, Haibo, 2016. "A clean coal utilization technology based on coal pyrolysis and chemical looping with oxygen uncoupling: Principle and experimental validation," Energy, Elsevier, vol. 98(C), pages 181-189.
    15. Hosseini, Tahereh & Haque, Nawshad & Selomulya, Cordelia & Zhang, Lian, 2016. "Mineral carbonation of Victorian brown coal fly ash using regenerative ammonium chloride – Process simulation and techno-economic analysis," Applied Energy, Elsevier, vol. 175(C), pages 54-68.

    More about this item

    Keywords

    LCA; Ammonia; Post-combustion; CO2; Capture; Aspen plus;
    All these keywords.

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