Recent developments in aqueous ammonia-based post-combustion CO2 capture technologies

doi:10.1016/j.cjche.2018.05.024

Abstract

Abstract: Aqueous ammonia (NH₃) is a promising alternative solvent for the capture of industrial CO₂ emissions, given its high chemical stability and CO₂ removal capacity, and low material costs and regeneration energy. NH₃ also has potential for capturing multiple flue gas components, including NO_x, SO_x and CO₂, and producing value-added chemicals. However, its high volatility and low reactivity towards CO₂ limit its economic viability. Considerable efforts have been made to advance aqueous NH₃-based post-combustion capture technologies in the last few years:in particular, General Electric's chilled NH₃ process, CSIRO's mild-temperature aqueous NH₃ process and SRI International's mixed-salts (NH₃ and potassium carbonate) technology. Here, we review these research activities and other developments in the field, and outline future research needed to further improve aqueous NH₃-based CO₂ capture technologies.

Key words: Aqueous ammonia, NH₃, Post-combustion capture, Ammonia loss, Regeneration energy, Amines

摘要： Aqueous ammonia (NH₃) is a promising alternative solvent for the capture of industrial CO₂ emissions, given its high chemical stability and CO₂ removal capacity, and low material costs and regeneration energy. NH₃ also has potential for capturing multiple flue gas components, including NO_x, SO_x and CO₂, and producing value-added chemicals. However, its high volatility and low reactivity towards CO₂ limit its economic viability. Considerable efforts have been made to advance aqueous NH₃-based post-combustion capture technologies in the last few years:in particular, General Electric's chilled NH₃ process, CSIRO's mild-temperature aqueous NH₃ process and SRI International's mixed-salts (NH₃ and potassium carbonate) technology. Here, we review these research activities and other developments in the field, and outline future research needed to further improve aqueous NH₃-based CO₂ capture technologies.

关键词: Aqueous ammonia, NH₃, Post-combustion capture, Ammonia loss, Regeneration energy, Amines

Hai Yu. Recent developments in aqueous ammonia-based post-combustion CO₂ capture technologies[J]. Chin.J.Chem.Eng., 2018, 26(11): 2255-2265.

Hai Yu. Recent developments in aqueous ammonia-based post-combustion CO₂ capture technologies[J]. Chinese Journal of Chemical Engineering, 2018, 26(11): 2255-2265.

References

[1] International Energy Agency (IEA), Energy Technology Perspectives 2017-Catalysing Energy Technology Transformations, 2017.

[2] Boundary dam carbon capture and storage, https://www.globalccsinstitute.com/projects/boundary-dam-carbon-capture-and-storage-project, Accessed date:12 March 2018.

[3] Global CCS Institute, CO₂ capture technologies:Post combustion capture (PCC), http://hub.globalccsinstitute.com/sites/default/files/publications/29721/co2-capture-technologies-pcc.pdf, Accessed date:12 March 2018.

[4] Petra nova carbon capture, https://www.globalccsinstitute.com/projects/petranova-carbon-capture-project, Accessed date:12 March 2018.

[5] IEA, Integrated carbon capture and storage project at Saskpower's Boundary Dam Power Station, http://www.ieaghg.org/docs/General_Docs/Reports/2015-06.pdf, Accessed date:12 March 2018.

[6] MIT, Boundary dam fact sheet:carbon dioxide capture and storage project, https://sequestration.mit.edu/tools/projects/boundary_dam.html, Accessed date:25 November 2017.

[7] S. Reddy, J.R. Scherffius, J. Yonkoski, P. Radgen, H. Rode, Initial results from Fluor's CO₂ capture demonstration plant using Econamine FG PlusSM technology at E.ON Kraftwerke's Wilhelmshaven Power Plant, Energy Procedia 37(2013) 6216-6225.

[8] B. Baburao, S. Bedell, P. Restrepo, D. Schmidt, C. Schubert, B. Debolt, I. Haji, F. Chopin, Advanced amine process technology operations and results from demonstration facility at EDF Le Havre, Energy Procedia 63(2014) 6173-6187.

[9] J.W. Gayheart, S.A. Moorman, T.R. Parsons, C.W. Poling, Babcock & Wilcox Power Generation Group, Inc.'s, RSAT^TM process and field demonstration of the OptiCap^TM advanced solvent at the US-DOE's National Carbon Capture Center, Energy Procedia 37(2013) 1951-1967.

[10] O. Gorset, J.N. Knudsen, O.M. Bade, I. Askestad, Results from testing of Aker Solutions advanced amine solvents at CO₂ Technology Centre Mongstad, Energy Procedia 63(2014) 6267-6280.

[11] Aker solutions starts pioneering CO₂ capture project in Norway, http://akersolutions.com/news/news-archive/2016/aker-solutions-starts-pioneering-co2-capture-project-in-norway, Accessed date:12 March 2018.

[12] Frequently asked questions for Siemens Postcap^TM CO₂ capture technology, http://www.energy.siemens.com/mx/pool/hq/power-generation/power-plants/carboncapture-solutions/FAQ-summary%202014_07_24-revOR.pdf, Accessed date:12 March 2018.

[13] NETL, Post-combustion solvents, http://www.netl.doe.gov/File%20Library/Research/Coal/carbon%20capture/handbook/CO₂-Capture-Tech-Update-2013-PostCombustion-Solvents.pdf (accessed on March 1220187).

[14] E. Chen, Y. Zhang, D. Sachde, Y.J. Lin, G.T. Rochelle, Pilot plant results for 5 m piperazine with the advanced flash stripper, http://ieaghg.org/docs/General_Docs/PCCC3_PDF/5_PCCC3_6_Chen.pdf, Accessed date:12 March 2018.

[15] J. Tollefson, Low-cost carbon-capture project sparks interest, Nature 469(2011) 276-277.

[16] CO₂CRC Limited, UNO MK3-New generation carbon capture, http://old.co2crc.com.au/research/uno_mk3_process.html, Accessed date:12 March 2018.

[17] S. Badr, J. Frutiger, K. Hungerbuehler, S. Papadokonstantakis, A framework for the environmental, health and safety hazard assessment for amine-based post combustion CO₂ capture, Int. J. Greenhouse Gas Control 56(2017) 202-220.

[18] S.A. Mazari, B. Si Ali, B.M. Jan, I.M. Saeed, S. Nizamuddin, An overview of solvent management and emissions of amine-based CO₂ capture technology, Int. J. Greenhouse Gas Control 34(2015) 129-140.

[19] CO₂CRC Limited, Retrofitting Australian gas power plants with post combustion capture, http://www.co2crc.com.au/wp-content/uploads/2017/05/retrofitGasCaptureReport.pdf, Accessed date:12 March 2018.

[20] N. Yang, H. Yu, L. Li, D. Xu, W. Han, P. Feron, Aqueous ammonia (NH₃) based post combustion CO₂ capture:A review, Oil Gas Sci. Technol. 69(2014) 931-945.

[21] G. Busca, C. Pistarino, Abatement of ammonia and amines from waste gases:A summary, J. Loss Prev. Process 16(2003) 157-163.

[22] Safe Work Australia, Workplace exposure standards for airborne contaminants, https://www.safeworkaustralia.gov.au/system/files/documents/1705/workplaceexposure-standards-airborne-contaminants-v2.pdf 2011, Accessed date:12 March 2018.

[23] F. Kozak, A. Petig, E. Morris, R. Rhudy, D. Thimsen, Chilled ammonia process for CO₂ capture, Energy Procedia 1(2009) 1419-1426.

[24] O. Augustsson, B. Baburao, S. Dube, S. Bedell, P. Strunz, M. Balfe, O. Stallmann, Chilled ammonia process scale-up and lessons learned, Energy Procedia 114(2017) 5593-5615.

[25] G. Lombardo, R. Agarwal, J. Askander, Chilled ammonia process at Technology Center Mongstad-First results, Energy Procedia 51(2014) 31-39.

[26] H. Jilvero, N.-H. Eldrup, F. Normann, K. Andersson, F. Johnsson, R. Skagestad, Technoeconomic evaluation of an ammonia-based post-combustion process integrated with a state-of-the-art coal-fired power plant, Int. J. Greenhouse Gas Control 31(2014) 87-95.

[27] D.P. Hanak, C. Biliyok, V. Manovic, Efficiency improvements for the coal-fired power plant retrofit with CO₂ capture plant using chilled ammonia process, Appl. Energy 151(2015) 258-272.

[28] D.P. Hanak, C. Biliyok, V. Manovic, Rate-based model development, validation and analysis of chilled ammonia process as an alternative CO₂ capture technology for coal-fired power plants, Int. J. Greenhouse Gas Control 34(2015) 52-62.

[29] H. Yu, G. Qi, Q. Xiang, S. Wang, M. Fang, Q. Yang, L. Wardhaugh, P. Feron, Aqueous ammonia based post combustion capture:Results from pilot plant operation, challenges and further opportunities, Energy Procedia 37(2013) 6256-6264.

[30] H. Yu, S. Morgan, A. Allport, A. Cottrell, T. Do, J. Mcgregor, L. Wardhaugh, P. Feron, Results from trialling aqueous NH₃ based post-combustion capture in a pilot plant at Munmorah power station:Absorption, Chem. Eng. Res. Des. 89(2011) 1204-1215.

[31] K. Li, H. Yu, S. Yan, P. Feron, L. Wardhaugh, M. Tade, Technoeconomic assessment of an advanced aqueous ammonia-based post combustion capture process integrated with a 650-MW coal-fired power station, Environ. Sci. Technol. 50(2016) 10746-10755.

[32] K. Li, H. Yu, M. Tade, P. Feron, J. Yu, S. Wang, Process modeling of an advanced NH₃ abatement and recycling technology in the ammonia-based CO₂ capture process, Environ. Sci. Technol. 48(2014) 7179-7186.

[33] K. Li, H. Yu, G. Qi, P. Feron, M. Tade, J. Yu, S. Wang, Rate-based modelling of combined SO₂ removal and NH₃ recycling integrated with an aqueous NH₃-based CO₂ capture process, Appl. Energy 148(2015) 66-77.

[34] A.L. Kohl, R. Nielsen, Gas Purification, 5th ed. Gulf Publishing Company, Houston, Texas, 1997.

[35] K. Li, H. Yu, P. Feron, M. Tade, L. Wardhaugh, Technical and energy performance of an advanced, aqueous ammonia-based CO₂ capture technology for a 500 MW coal-fired power station, Environ. Sci. Technol. 49(2015) 10243-10252.

[36] H. Yu, L. Wardhaugh, P. Feron, Q. Yang, K. Li, M. Tade, L. Li, M. Maeder, Development of an aqueous ammonia-based PCC technology for Australian conditions, Final Report to Australian National Low Emissions Coal Research and Development (ANLEC R&D), 2016.

[37] L. Li, W. Conway, G. Puxty, R. Burns, S. Clifford, M. Maeder, H. Yu, The effect of piperazine (PZ) on CO₂ absorption kinetics into aqueous ammonia solutions at 25.0℃, Int. J. Greenhouse Gas Control 36(2015) 135-143.

[38] Q. Xiang, M. Fang, M. Maeder, H. Yu, Effect of sarcosinate on the absorption kinetics of CO₂ into aqueous ammonia solution, Ind. Eng. Chem. Res. 52(2013) 6382-6389.

[39] I. Jayaweera, P. Jayaweera, R. Elmore, J. Bao, S. Bhamidi, Update on mixed-salt technology development for CO₂ capture from post-combustion power stations, Energy Procedia 63(2014) 640-650.

[40] I. Jayaweera, P. Jayaweera, P. Kundu, A. Anderko, K. Thomsen, G. Valenti, D. Bonalumi, S. Lillia, Results from process modeling of the mixed-salt technology for CO₂ capture from post-combustion-related applications, Energy Procedia 114(2017) 771-780.

[41] I. Jayaweera, P. Jayaweera, Y. Yamasaki, R. Elmore, Mixed salt solutions for CO₂ capture, in:P. Feron (Ed.), Absorption-Based Post-Combustion Capture of Carbon Dioxide, Woodhead Publishing 2016, pp. 167-200.

[42] C. Makhloufi, E. Lasseuguette, J.C. Remigy, B. Belaissaoui, D. Roizard, E. Favre, Ammonia based CO₂ capture process using hollow fiber membrane contactors, J. Membr. Sci. 455(2014) 236-246.

[43] C.T. Molina, C. Bouallou, Assessment of different methods of CO₂ capture in postcombustion using ammonia as solvent, J. Clean. Prod. 103(2015) 463-468.

[44] Z. Cui, D. Demontigny, Experimental study of carbon dioxide absorption into aqueous ammonia with a hollow fiber membrane contactor, J. Membr. Sci. 540(2017) 297-306.

[45] M. Zhang, Y. Guo, A novel process for NH₃-based CO₂ capture by integrating flow-by capacitive ion separation, Int. J. Greenhouse Gas Control 54(2016) 50-58.

[46] A. Ullah, M.W. Saleem, W.-S. Kim, Performance and energy cost evaluation of an integrated NH 3-based CO 2 capture-capacitive deionization process, Int. J. Greenhouse Gas Control 66(2017) 85-96.

[47] D. Sutter, M. Gazzani, M. Mazzotti, A low-energy chilled ammonia process exploiting controlled solid formation for post-combustion CO₂ capture, Faraday Discuss. 192(2016) 59-83.

[48] B. Zhao, Y. Su, G. Cui, Post-combustion CO₂ capture with ammonia by vortex flowbased multistage spraying:Process intensification and performance characteristics, Energy 102(2016) 106-117.

[49] D. Bonalumi, A. Giuffrida, Performance improvement of cooled ammonia-based CO₂ capture in combined cycles with gasification of high-sulfur coal, Energy Procedia 114(2017) 6440-6447.

[50] K. Jiang, K. Li, H. Yu, Z. Chen, L. Wardhaugh, P. Feron, Advancement of ammonia based post-combustion CO₂ capture using the advanced flash stripper process, Appl. Energy 202(2017) 496-506.

[51] N. Kittiampon, A. Kaewchada, A. Jaree, Carbon dioxide absorption using ammonia solution in a microchannel, Int. J. Greenhouse Gas Control 63(2017) 431-441.

[52] L. Li, W. Conway, R. Burns, M. Maeder, G. Puxty, S. Clifford, H. Yu, Investigation of metal ion additives on the suppression of ammonia loss and CO₂ absorption kinetics of aqueous ammonia-based CO₂ capture, Int. J. Greenhouse Gas Control 56(2017) 165-172.

[53] J.-F. Perez-Calvo, D. Sutter, M. Gazzani, M. Mazzotti, Application of a chilled ammonia-based process for CO₂ capture to cement plants, Energy Procedia 114(2017) 6197-6205.

[54] D. Sutter, M. Gazzani, J.-F. Perez-Calvo, C. Leopold, F. Milella, M. Mazzotti, Solid formation in ammonia-based processes for CO₂ capture-Turning a challenge into an opportunity, Energy Procedia 114(2017) 866-872.

[55] M. Fang, Q. Ma, Z. Wang, Q. Xiang, W. Jiang, Z. Xia, A novel method to recover ammonia loss in ammonia-based CO₂ capture system:Ammonia regeneration by vacuum membrane distillation, Greenhouse Gases Sci. Technol. 5(2015) 487-498.

[56] M. Darestani, V. Haigh, S.J. Couperthwaite, G.J. Millar, L.D. Nghiem, Hollow fibre membrane contactors for ammonia recovery:Current status and future developments, J. Environ. Chem. Eng. 5(2017) 1349-1359.

Recent developments in aqueous ammonia-based post-combustion CO₂ capture technologies

Recent developments in aqueous ammonia-based post-combustion CO₂ capture technologies

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