Dossier: Post Combustion CO2 Capture
Open Access
Issue
Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles
Volume 69, Number 5, September-October 2014
Dossier: Post Combustion CO2 Capture
Page(s) 915 - 929
DOI https://doi.org/10.2516/ogst/2013161
Published online 27 November 2013
  • Kohl A.L., Nielsen R.B. (1997) Gas Purification, fifth edition, Gulf Publishing Company, Houston, Texas. [Google Scholar]
  • Bouillon P.A., Carrette P.L., Faraj A., Lemaire E., Raynal L. (2011) IFPEN solutions for lowering the cost of post-combustion CO2 capture, ICCDU International Conference on Carbon Dioxide Utilization, 27-30 June, Dijon, France. [Google Scholar]
  • Tems R., Al-Zahrani A. (2006) Cost of corrosion in gas sweetening and fractionation plants, Corrosion/2006, Paper No. 444, NACE International. [Google Scholar]
  • Dingman J.C., Allen D.L., Moore T.F. (1966) Minimize corrosion in MEA units, Hydrocarbon Processing 45, (9), 570–575. [Google Scholar]
  • Lang F.S., Mason J.F. (1958) Corrosion in amine gas treating solutions, Corrosion 14, (2), 65–68. [Google Scholar]
  • Montrone E.D., Long W.P. (1971) Choosing materials for CO2 absorption systems, Chemical Engineering, Jan. 25. [Google Scholar]
  • Polderman L.D., Dillon C.P., Steele A.B. (1955) Degradation of monoethanolamine in natural gas treating service, Oil Gas Journal 16, (5), 180–183. [Google Scholar]
  • Riesenfeld F.C., Blohm C.L. (1950) Corrosion problems in gas purification units employing MEA solutions, Petroleum Refiner 20, (4), 141–150. [Google Scholar]
  • Riesenfeld F.C., Hugues C.L. (1951) Corrosion in amine gas treating plants, Petroleum Refiner 30, (2), 97–106. [Google Scholar]
  • Riesenfeld F.C., Blohm C.L. (1951) Corrosion resistance of alloys in amine gas treating systems, Petroleum Refiner 30, (10), 107–115. [Google Scholar]
  • Williams E., Leckie H.P. (1968) Corrosion and its prevention in a monoethanolamine gas treating plant, Materials Protection 7, (7), 321–326. [Google Scholar]
  • McHenry H.I., Read D.T., Shives T.R. (1987) Failure analysis of an amine-absorber pressure vessel, Materials Performance 26, (8), 18–24. [Google Scholar]
  • Richert J.P., Bagdasarian A.J., Shargay C.A. (1987) Stress corrosion cracking of carbon steel in amine systems, Corrosion/87, Paper No. 187, NACE International. [Google Scholar]
  • Richert J.P., Bagdasarian A.J., Shargay C.A. (1989) Extent of stress corrosion cracking in amine plants revealed by survey, Oil Gas Journal 5, 45–52. [Google Scholar]
  • Nielsen R.B., Lewis K.R., McCullough J.G., Hansen D.A. (1995) Controlling corrosion in amine treating plants, Proceedings of the Laurance Reid Gas Conditioning Conference, Norman, Oklahoma. [Google Scholar]
  • Nielsen R.B., Lewis K.R., McCullough J.G., Hansen D.A. (1995) Corrosion in refinery amine systems, Corrosion/95, Paper No. 571, NACE International. [Google Scholar]
  • EFC (2003) Publication No. 46, Avoiding environmental cracking in amine units, The European Federation of Corrosion, Woodhead Publishing Ltd, Cambridge, England. [Google Scholar]
  • Dupart M.S., Bacon T.R., Edwards D.J. (1993) Understanding corrosion in alkanolamine gas treating plants. 1. proper mechanism diagnosis optimizes amine operations, Hydrocarbon Processing 72, 75–79. [Google Scholar]
  • Dupart M.S., Bacon T.R., Edwards D.J. (1993) Understanding corrosion in alkanolamine gas treating plants. 2. Case histories show actual plant problems and their solutions, Hydrocarbon Processing 72, 89–94. [Google Scholar]
  • Kosseim A.J., McCullough J.G., Butwell K.F. (1984) Corrosion-Inhibited Amine Guard St Process, Chemical Engineering Progress 80, 64–71. [Google Scholar]
  • Soosaiprakasam I.R., Veawab A. (2008) Corrosion and polarization behavior of carbon steel in MEA-based CO2 capture process, International Journal of Greenhouse Gas Control 2, (4), 553–562. [CrossRef] [Google Scholar]
  • Tomoe Y., Shimizu M., Kaneta H. (1996) Active dissolution and natural passivation of carbon steel in carbon dioxide loaded alkanolamine solutions, Corrosion/96, Paper No. 395, NACE International. [Google Scholar]
  • Veawab A., Aroonwilas A. (2002) Identification of oxidizing agents in aqueous amine-CO2 systems using a mechanistic corrosion model, Corrosion Science 44, (5), 967–987. [CrossRef] [Google Scholar]
  • Bich N.N., Vacha F., Schubert R. (1996) Corrosion in MDEA sour gas treating plants: correlation between laboratory testing and field experience, Corrosion/96, Paper No. 392, NACE International. [Google Scholar]
  • Veawab A., Tontiwachwuthikul P., Chakma A. (1999) Corrosion behavior of carbon steel in the CO2 absorption process using aqueous amine solutions, Industrial Engineering Chemistry Research 38, (10), 3917–3924. [CrossRef] [Google Scholar]
  • Bonis M.R., Ballaguet J.P., Rigaill C. (2004) A critical look at amines: a practical review of corrosion experience over four decades, 83rd annual GPA convention, 14-17 March, New-Orleans, LO. [Google Scholar]
  • Blanc C., Grall M., Demarais G. (1982) The part played by degradation products in the corrosion of gas sweetening plants using DEA and MDEA, Proceedings of the Laurance Reid Gas Conditioning Conference, 8-10 March, Norman, OK. [Google Scholar]
  • DuPart M.S., Rooney P.C., Bacon T.R. (1999) Comparing laboratory and plant data for MDEA/DEA blends, Hydrocarbon Processing 78, (4), 81–86. [Google Scholar]
  • DuPart M.S., Rooney P.C., Bacon T.R. (1999) Comparison of laboratory and operating plant data of MDEA/DEA blends, Proceedings of the 49th Laurance Reid Gas Conditioning Conference, 21-24 Feb., Norman, OK. [Google Scholar]
  • Veldman R.R. (2000) Alkalonamine solution corrosion mechanisms and inhibition from heat stable salts and CO2, Corrosion/2000, Paper No. 496, NACE International. [Google Scholar]
  • Guo X.P., Tomoe Y. (1999) The effect of corrosion product layers on the anodic and cathodic reactions of carbon steel in CO2-saturated MDEA solutions at 100 C, Corrosion Science 41, (7), 1391–1402. [CrossRef] [Google Scholar]
  • Vazquez R.C., Rios G., Trejo A., Rincon R.E., Uruchurtu J., Malo J.M. (2000) The effect of diethanolamine solution concentration in the corrosion of steel, Corrosion/2000, Paper No. 696, NACE International. [Google Scholar]
  • Rooney P.C., Bacon T.R., DuPart M.S. (1996) Effect of heat stable salts on MDEA solution corrosivity, Hydrocarbon Processing 75, (3), 95–103. [Google Scholar]
  • Rooney P.C., DuPart M.S., Bacon T.R. (1997) Effect of heat stable salts on MDEA solution corrosivity .2, Hydrocarbon Processing 76, (4), 65–71. [Google Scholar]
  • Tanthapanichakoon W., Veawab A., McGarvey B. (2006) Electrochemical investigation on the effect of heat-stable salts on corrosion in CO2 capture plants using aqueous solution of MEA, Industrial Engineering Chemistry Research 45, (8), 2586–2593. [CrossRef] [Google Scholar]
  • Al-Zahrani A., Al-Luqmaun S.I. (2006) Methodology of mitigating corrosion mechanisms in amine gas treating units, Corrosion/2006, Paper No. 441, NACE International. [Google Scholar]
  • Raut N., Chaudhari R.M., Naik V.S. (2009) Failure of amine regenerating column of amine treatment unit, Corrosion/2009, Paper No. 334, NACE International. [Google Scholar]
  • Xie J., Simanzhenkov V., Santos B., Ikeda K., Davies L. (2010) Corrosion of UNS S30403 stainless steel trays in an amine unit, Corrosion/2010, Paper No. 187, NACE International. [Google Scholar]
  • Moore M.A., Qarni M.M., Lobley G.R. (2008) Corrosion problems in gas treating systems, Corrosion/2008, Paper No. 08419, NACE International. [Google Scholar]
  • Safruddin S., Safruddin R. (2000) Twenty years experience in controlling corrosion in amine unit, Badak LNG plant, Corrosion/2000, Paper No. 497, NACE International. [Google Scholar]
  • Howard M., Sargent A. (2001) Operating experiences at Duke energy field services Wilcox plant with oxygen contamination and amine degradation, Proceedings of the 51st Laurance Reid Gas Conditioning Conference, 25-28 Feb., Norman, OK. [Google Scholar]
  • Kane R.D., Wilhelm S.M., Oldfield J.W. (1989) Review of hydrogen induced cracking of steels in wet H2S refinery service, Materials Property Council, 28 March, Paris, France. [Google Scholar]
  • Teevens P.J. (1990) Toward a better understanding of of the cracking behavior of carbon steel in alkanolamine sour gas sweetening units: its detection, monitoring and how to avoid it, Corrosion/90, Paper No. 198, NACE International. [Google Scholar]
  • DeHart T.R., Hansen D.A., Mariz C.L., McCullough J.G. (1999) Solving corrosion problems at the NEA Bellingham Massachusetts carbon dioxide recovery plant, Corrosion/99, Paper No. 264, NACE International. [Google Scholar]
  • Dupart M.S., Bacon T.R., Edwards D.J. (1991) Understanding and preventing corrosion in alkanolamine gas treating plants, Proceedings of the 41st Laurance Reid Gas Conditioning Conference, 4-6 March, Norman, OK. [Google Scholar]
  • Kittel J., Bonis M.R., Perdu G. (2008) Corrosion control on amine plants: new compact unit design for high acid gas loadings, Sour Oil & Gas Advanced Technology Conference, 27 April-1 May, Abu Dhabi, UAE. [Google Scholar]
  • Pearson H., Shao J., Norton D., Dandekar S. (2005) Case study of effects of bicine in CO2 only amine treater service, Proceedings of the 55th Laurance Reid Gas Conditioning Conference, Norman, OK. [Google Scholar]
  • Fan D., Kolp L.E., Huett D.S., Sargent M.A. (2000) Role of impurities and H2S in refinery lean DEA system corrosion, Corrosion/2000, Paper No. 495, NACE International. [Google Scholar]
  • Tomoe Y., Miyata K., Ihara M., Masuda K., Efird K.D. (2002) Evaluation of corrosion resistance of metallic materials for DGA regenerators in dynamic conditions, Corrosion/2002, Paper No. 350, NACE International. [Google Scholar]
  • Jordan T.J., Nozal P.J., Azodi A. (2006) Handling trace oxygen at the saunders gas processing facility, Proceedings of the 56th Laurance Reid Gas Conditioning Conference, Norman, OK. [Google Scholar]
  • Fleury E., Kittel J., Vuillemin B., Oltra R., Ropital F. (2008) Corrosion in amine solvents used for the removal of acid gases, Eurocorr 2008, The European Federation of Corrosion, Edinburgh, UK, 7–11 Sept. [Google Scholar]
  • Kittel J., Fleury E., Vuillemin B., Gonzalez S., Ropital F., Oltra R. (2012) Corrosion in alkanolamine used for acid gas removal: From natural gas processing to CO2 capture, Materials and Corrosion 63, (3), 223–230. [CrossRef] [Google Scholar]
  • Wagner R., Judd B. (2006) Fundamentals - Gas sweetening, Proceedings of the 56th Laurance Reid Gas Conditioning Conference, Norman, OK. [Google Scholar]
  • Lawal A.O., Idem R.O. (2006) Kinetics of the oxidative degradation of CO2 loaded and concentrated aqueous MEA-MDEA blends during CO2 absorption from flue gas streams, Industrial Engineering Chemistry Research 45, (8), 2601–2607. [CrossRef] [Google Scholar]
  • Duan D., Choi Y.S., Nesic S., Vitse F., Bedell S.A., Worley C. (2010) Effect of oxygen and heat stable salts on the corrosion of carbon steel in MDEA-based CO2 capture process, Corrosion/2010, Paper No. 191, NACE International. [Google Scholar]
  • Kladkaew N., Idem R., Tontiwachwuthikul P., Saiwan C. (2009) Corrosion Behavior of Carbon Steel in the Monoethanolamine-H2O-CO2-O2-SO2 System: Products, Reaction Pathways, and Kinetics, Industrial Engineering Chemistry Research 48, (23), 10169–10179. [CrossRef] [Google Scholar]
  • Kladkaew N., Idem R., Tontiwachwuthikul P., Saiwan C. (2009) Corrosion Behavior of Carbon Steel in the Monoethanolamine-H2O-CO2-O2-SO2 System, Industrial & Engineering Chemistry Research 48, (19), 8913–8919. [CrossRef] [Google Scholar]
  • Kittel J., Idem R., Gelowitz D., Tontiwachwuthikul P., Parrain G., Bonneau A. (2009) Corrosion in MEA units for CO2 capture: Pilot plant studies, Energy Procedia 1, (1), 791–797. [CrossRef] [Google Scholar]
  • Pearce B., DuPart M.S. (1987) Corrosion in gas conditionning plants - An overview, Corrosion/87, Paper No. 39, NACE International. [Google Scholar]
  • Bello A., Idem R.O. (2006) Comprehensive study of the kinetics of the oxidative degradation of CO2 loaded and concentrated aqueous monoethanolamine (MEA) with and without sodium metavanadate during CO2 absorption from flue gases, Industrial Engineering Chemistry Research 45, (8), 2569–2579. [CrossRef] [Google Scholar]
  • Goff G.S., Rochelle G.T. (2006) Oxidation inhibitors for copper and iron catalyzed degradation of monoethanolamine in CO2 capture processes, Industrial Engineering Chemistry Research 45, (8), 2513–2521. [CrossRef] [Google Scholar]
  • Soosaiprakasam I.R., Veawab A. (2009) Corrosion inhibition performance of copper carbonate in MEA- CO2 capture unit, Energy Procedia 1, (1), 225–229. [CrossRef] [Google Scholar]
  • Soosaiprakasam I.R., Veawab A. (2007) Inhibition performance of copper carbonate in CO2 absorption process using aqueous MEA, Corrosion/2007, Paper No. 396, NACE International. [Google Scholar]
  • Tanthapanichakoon W., Veawab A. (2005) Polarization behavior and performance of inorganic corrosion inhibitors in monoethanolamine solution containing carbon dioxide and heat-stable salts, Corrosion 61, (4), 371–380. [CrossRef] [Google Scholar]
  • Veawab A., Tontiwachwuthikul P. (2001) Investigation of low-toxic organic corrosion inhibitors for CO2 separation process using aqueous MEA solvent, Industrial Engineering Chemistry Research 40, (22), 4771–4777. [CrossRef] [Google Scholar]
  • Reddy S., Johnson D., Gilmartin J. (2008) Fluor’s econamine FG plus technology for CO2 capture at coal-fired power plants, Power Plant Air Pollutant Control Mega Symposium, Baltimore, MD, 25-28 Aug. [Google Scholar]
  • Rennie S. (2006) Corrosion and materials selection for amine service, Materials and Testing Conference, Fremantle, Australia, 30 Oct.-2 Nov. [Google Scholar]
  • Rooney P.C., DuPart M.S. (2000) Corrosion in alkanolamine plants: causes and minimization, Corrosion/2000, Paper No. 494, NACE International. [Google Scholar]
  • Titz J.T., Asprion N., Katz T., Wagner R. (2003) Corrosion in amine solutions used for acid gas removal, Proceedings of the 53rd Laurance Reid Gas Conditioning Conference, Norman, OK. [Google Scholar]
  • Martin S., Lepaumier H., Picq D., Kittel J., de Bruin T., Faraj A., Carrette P.L. (2012) New amines for CO2 capture. IV. Degradation, corrosion, and quantitative structure property relationship model, Industrial Engineering Chemistry Research 51, (18), 6283–6289. [CrossRef] [Google Scholar]
  • Nainar M., Veawab A. (2009) Corrosion in CO2 capture process using blended monoethanolamine and piperazine, Industrial Engineering Chemistry Research 48, (20), 9299–9306. [CrossRef] [Google Scholar]
  • Ali B.S., Aroua M.K. (2004) Effect of piperazine on CO2 loading in aqueous solutions of MDEA at low pressure, International Journal Thermophysics 25, (6), 1863–1870. [CrossRef] [Google Scholar]
  • Bishnoi S., Rochelle G.T. (2002) Absorption of carbon dioxide in aqueous piperazine/methyldiethanolamine, AIChE Journal 48, (12), 2788–2799. [CrossRef] [Google Scholar]
  • Derks P.W.J., Hogendoorn J.A., Versteeg G.F. (2006) Absorption of carbon dioxide into aqueous solutions of MDEA and piperazine, CHISA 2006 – 17th International Congress of Chemical and Process Engineering, Prague, Czech Republic, 27-31 August. [Google Scholar]
  • Zhao B., Sun Y., Yuan Y., Gao J., Wang S., Zhuo Y., Chen C. (2011) Study on corrosion in CO2 chemical absorption process using amine solution, Energy Procedia 4, 93–100. [CrossRef] [Google Scholar]
  • Kittel J., Gonzalez S., Lemaire E., Raynal L. (2012) Corrosion in post-combustion CO2 capture plants - comparisons between MEA 30% and new processes, Eurocorr 2012, The European Federation of Corrosion, Istanbul. [Google Scholar]
  • Knudsen J.N., Jensen J.R.N., Vilhelmsen P.J., Biede O. (2009) Experience with CO2 capture from coal flue gas in pilot-scale: Testing of different amine solvents, Energy Procedia 1, (1), 783–790. [CrossRef] [Google Scholar]
  • Moser P., Schmidt S., Sieder G., Garcia H., Stoffregen T. (2011) Performance of MEA in a long-term test at the post-combustion capture pilot plant in Niederaussem, International Journal of Greenhouse Gas Control 5, (4), 620–627. [CrossRef] [Google Scholar]
  • Moser P., Schmidt S., Uerlings R., Sieder G., Titz J.T., Hahn A., Stoffregen T. (2011) Material testing for future commercial post-combustion capture plants. Results of the testing programme conducted at the Niederaussem pilot plant, Energy Procedia 4, 1317–1322. [CrossRef] [Google Scholar]
  • Pearson P., Cousins A., Cottrell A.J., Duncombe B., Feron P.H.M., Hollenkamp T.F., Huang S., Meuleman E. (2013) Corrosion in amine post combustion capture plants, Eurocorr 2012, The European Federation of Corrosion, Istanbul. [Google Scholar]
  • Lemaire E., Bouillon P.A., Mangiaracina A., Normand L., Laborie G. (2012) Results of the 2.25 t/h post-combustion CO2 capture pilot plant of ENEL at the Brindisi coal power plant and last R&D developments for Hicapt+ process, SOGAT - CO2 forum, Abu-Dhabi, UAE, 29 March. [Google Scholar]
  • Gao J., Wang S., Sun C., Zhao B., Chen C. (2012) Corrosion behavior of carbon steel at typical positions of an amine-based CO2 capture pilot plant, Industrial Engineering Chemistry Research 51, (19), 6714–6721. [CrossRef] [Google Scholar]
  • Gao J., Wang S., Zhou S., Zhao B., Chen C. (2011) Corrosion and degradation performance of novel absorbent for CO2 capture in pilot-scale, Energy Procedia 4, 1534–1541. [CrossRef] [Google Scholar]
  • Zhang X., Zevenbergen J., Spruijt M.P.N., Benedictus T. (2012) Corrosion of steels in CO2 transport and storage environments, Eurocorr 2012, The European Federation of Corrosion, Istanbul. [Google Scholar]
  • Xiang Y., Wang Z., Yang X., Li Z., Ni W. (2012) The upper limit of moisture content for supercritical CO2 pipeline transport, Journal Supercritical Fluids 67, (7), 14–21. [CrossRef] [Google Scholar]
  • Xiang Y., Wang Z., Xu C., Zhou C., Li Z., Ni W. (2011) Impact of SO2 concentration on the corrosion rate of X70 steel and iron in water-saturated supercritical CO2 mixed with SO2, Journal Supercritical Fluids 58, (2), 286–294. [CrossRef] [Google Scholar]
  • Xiang Y., Wang Z., Yang X., Ni W., Li Z. (2011) Corrosion behavior of X70 steel in the supercritical CO2 mixed with SO2 and saturated water, Proceedings of the Twenty-first International Offshore and Polar Engineering Conference, Maui, Hawaii, USA, 19-24 June. [Google Scholar]
  • Ruhl A.S., Kranzmann A. (2012) Corrosion behavior of various steels in a continuous flow of carbon dioxide containing impurities, International Journal Greenhouse Gas Control 9, (7), 85–90. [CrossRef] [Google Scholar]
  • Lucci A., Demofonti G., Spinelli C.M. (2011) CO2 anthropogenic pipeline transportation, Proceedings of the Twenty-first International Offshore and Polar Engineering Conference, Maui, Hawaii, USA, 19-24 June. [Google Scholar]
  • Farelas F., Choi Y.S., Nesic S. (2012) Effects of CO2 phase change, SO2 content and flow on the corrosion of CO2 transmission pipeline steel, Corrosion/2012, NACE International, C2012-0001322. [Google Scholar]
  • Dugstad A., Halseid M., Morland B., Siversten A.O. (2012) Corrosion in dense phase CO2 with small amounts of SO2, NO2 and water, Eurocorr 2012, The European Federation of Corrosion, Istanbul. [Google Scholar]
  • Dugstad A., Halseid M. (2012) Internal corrosion in dense phase CO2 transport pipelines - State of the art and the need for further R&D, Corrosion/2012, Paper No. 1452, NACE International, Corrosion 2012, Salt Lake City, Utah, 11-15 March. [Google Scholar]
  • Dugstad A., Morland B., Clausen S. (2011) Corrosion of transport pipelines for CO2 - Effect of water ingress, Energy Procedia 4, 3063–3070. [CrossRef] [Google Scholar]
  • Dugstad A., Clausen S., Morland B. (2011) Transport of dense phase CO2 in C-steel pipelines- When is corrosion an issue? Corrosion/2011, Paper No. 70, NACE International. [Google Scholar]
  • Dugstad A., Halseid M., Morland B. (2011) Corrosion in dense phase CO2 pipelines - State of the art, Eurocorr 2011, The European Federation of Corrosion, Stockholm. [Google Scholar]
  • Choi Y.S., Nesic S. (2011) Effect of water content on the corrosion behavior of carbon steel in supercritical CO2 phase with impurities, Corrosion/2011, Paper No. 377, NACE International. [Google Scholar]
  • Chambers B., Kane R., Yunovich M. (2010) Corrosion and selection of alloys for carbon capture and storage (CCS) systems: Current challenges, SPE International Conference on CO2 capture, storage and utilization, The New-Orleans, LO, 10-12 Nov. [Google Scholar]
  • de Visser E., Hendriks C., Barrio M., Mølnvik M.J., de Koeijer G., Liljemark S., Le Gallo Y. (2008) Dynamis CO2 quality recommendations, International Journal Greenhouse Gas Control 2, (4), 478–484. [CrossRef] [Google Scholar]
  • de Visser E., Hendriks C., de Koeijer G., Liljemark S., Barrio M., Austegard A., Brown A. (2007) Dynamis CO2 recommendations, FP6 European Project No. 019672 report No. D3.1.3. [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.