A review of chemical absorption of carbon dioxide for biogas upgrading
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摘要
Significant attention has been given to biogas production, purification and upgrading as a renewable and clean fuel supplement. Biogas is a product of an anaerobic digestion process comprising methane, carbon dioxide,and trace amounts of other gases. Biogas purification removes trace gases in biogas for safe utilisation. Biogas upgrading produces methane-rich biogas by removing bulk carbon dioxide from the gas mixture. Several carbon dioxide removal techniques can be applied for biogas upgrading. However, chemical absorption of carbon dioxide for biogas upgrading is of special significance due to its operation at ambient or near ambient temperature and pressure, thus reducing energy consumption. This paper reviews the chemical absorption of carbon dioxide using amine scrubbing, caustic solvent scrubbing, and amino acid salt solution scrubbing. Each of these techniques for biogas upgrading is discussed. The paper concludes that an optimised implementation of the chemical absorption techniques for biogas upgrading requires further research.
Significant attention has been given to biogas production, purification and upgrading as a renewable and clean fuel supplement. Biogas is a product of an anaerobic digestion process comprising methane, carbon dioxide,and trace amounts of other gases. Biogas purification removes trace gases in biogas for safe utilisation. Biogas upgrading produces methane-rich biogas by removing bulk carbon dioxide from the gas mixture. Several carbon dioxide removal techniques can be applied for biogas upgrading. However, chemical absorption of carbon dioxide for biogas upgrading is of special significance due to its operation at ambient or near ambient temperature and pressure, thus reducing energy consumption. This paper reviews the chemical absorption of carbon dioxide using amine scrubbing, caustic solvent scrubbing, and amino acid salt solution scrubbing. Each of these techniques for biogas upgrading is discussed. The paper concludes that an optimised implementation of the chemical absorption techniques for biogas upgrading requires further research.
Significant attention has been given to biogas production, purification and upgrading as a renewable and clean fuel supplement. Biogas is a product of an anaerobic digestion process comprising methane, carbon dioxide,and trace amounts of other gases. Biogas purification removes trace gases in biogas for safe utilisation. Biogas upgrading produces methane-rich biogas by removing bulk carbon dioxide from the gas mixture. Several carbon dioxide removal techniques can be applied for biogas upgrading. However, chemical absorption of carbon dioxide for biogas upgrading is of special significance due to its operation at ambient or near ambient temperature and pressure, thus reducing energy consumption. This paper reviews the chemical absorption of carbon dioxide using amine scrubbing, caustic solvent scrubbing, and amino acid salt solution scrubbing. Each of these techniques for biogas upgrading is discussed. The paper concludes that an optimised implementation of the chemical absorption techniques for biogas upgrading requires further research.
引文
[1]H.Oechsner,S.K.Khanal,M.Taherzadeh,Advances in biogas research and application,Bioresour.Technol.178(2015)177.
[2]D.Divya,L.R.Gopinath,P.Merlin Christy,A review on current aspects and diverse prospects for enhancing biogas production in sustainable means,Renew.Sust.Energ.Rev.42(2015)690–699.
[3]N.Korres,P.O'Kiely,J.A.H.Benzie,J.S.West,Bioenergy production by anaerobic digestion:using agricultural biomass and organic wastes,Routledge,2013.
[4]M.Persson,O.J?nsson,A.Wellinger,Biogas upgrading to vehicle fuel standards and grid injection,IEA bioenergy task,2006(http://www.businessregiongoteborg.com/download/18.37dc8386114072e4a2d80003405/1389235333763/upgrading_report_final.pdf(accessed March 5,2014)).
[5]F.Osorio,J.C.Torres,Biogas purification from anaerobic digestion in a wastewater treatment plant for biofuel production,Renew.Energy 34(2009)2164–2171.
[6]N.Abatzoglou,S.Boivin,A review of biogas purification processes,Biofuels Bioprod.Biorefin.3(2009)42–71.
[7]M.S.Horikawa,F.Rossi,M.L.Gimenes,C.M.M.Costa,M.da Silva,Chemical absorption of H2S for biogas purification,Braz.J.Chem.Eng.21(2004)415–422.
[8]W.-C.Lin,Y.-P.Chen,C.-P.Tseng,Pilot-scale chemical–biological system for efficient H2S removal from biogas,Bioresour.Technol.135(2013)283–291.
[9]D.Ramírez-Sáenz,P.B.Zarate-Segura,C.Guerrero-Barajas,E.I.García-Pe?a,H2S and volatile fatty acids elimination by biofiltration:Clean-up process for biogas potential use,J.Hazard.Mater.163(2009)1272–1281.
[10]D.Dieter,S.Angelika,Biogas from waste and renewable resources:An introduction,Wiley-VCH,Weiheim,Germany,2008.
[11]S.Rasi,J.L?ntel?,J.Rintala,Trace compounds affecting biogas energy utilisation—A review,Energy Convers.Manag.52(2011)3369–3375.
[12]L.Yang,X.Ge,C.Wan,F.Yu,Y.Li,Progress and perspectives in converting biogas to transportation fuels,Renew.Sust.Energ.Rev.40(2014)1133–1152.
[13]P.Weiland,Biogas production:Current state and perspectives,Appl.Microbiol.Biotechnol.85(2010)849–860.
[14]Y.Xu,Y.Huang,B.Wu,X.Zhang,S.Zhang,Biogas upgrading technologies:Energetic analysis and environmental impact assessment,Chin.J.Chem.Eng.23(1)(2015)247–254.
[15]J.Arroyo,F.Moreno,M.Mu?oz,C.Monné,N.Bernal,Combustion behavior of a spark ignition engine fueled with synthetic gases derived from biogas,Fuel 117,Part A(2014)50–58.
[16]E.Privalova,S.Rasi,P.M?ki-Arvela,et al.,CO2capture from biogas:Absorbent selection,RSC Adv.3(2013)2979–2994.
[17]A.L.Kohl,R.Nielsen,Gas purification,Gulf Professional Publishing,1997.
[18]F.Bauer,C.Hulteberg,T.Persson,D.Tamm,Biogas upgrading—Review of commercial technologies,SGC Rapp.,2013(http://lup.lub.lu.se/record/3512502(accessed October 16,2014)).
[19]R.H.Perry,D.W.Green,Perry's chemical engineers'handbook,Mc Graw-Hill,New York,2008.
[20]D.S.Clark,H.W.Blanch,Biochemical engineering,2 ed.CRC Press,New York,1997.
[21]J.Reynolds,J.S.Jeris,L.Theodore(Eds.),Handbook of chemical and environmental engineering calculations,1 ed.Wiley-Interscience,Hoboken,N.J.,2007.
[22]Y.Xiao,H.Yuan,Y.Pang,et al.,CO2removal from biogas by water washing system,Chin.J.Chem.Eng.22(2014)950–953.
[23]N.A.Al-Baghli,S.A.Pruess,V.F.Yesavage,M.S.Selim,A rate-based model for the design of gas absorbers for the removal of CO2and H2S using aqueous solutions of MEA and DEA,Fluid Phase Equilib.185(2001)31–43.
[24]N.Razi,H.F.Svendsen,O.Bolland,Validation of mass transfer correlations for CO2absorption with MEA using pilot data,Int.J.Greenhouse Gas Control 19(2013)478–491.
[25]J.T.Yeh,H.W.Pennline,K.P.Resnik,Study of CO2absorption and desorption in a packed column,Energy Fuel 15(2001)274–278.
[26]L.A.Pellegrini,S.Moioli,S.Gamba,Energy saving in a CO2capture plant by MEA scrubbing,Chem.Eng.Res.Des.89(2011)1676–1683.
[27]A.Aroonwilas,Mass-transfer with chemical reaction in structured packing for carbon dioxide absorption process(Ph.D.)The University of Regina,Canada,2001.
[28]R.B.Robert,Process for separating acidic gases,US1783901 A,1930.
[29]L.B.Gregory,W.G.Scharmann,Carbon dioxide scrubbing by amine solutions,Ind.Eng.Chem.29(1937)514–519.
[30]H.W.Wainwright,G.C.Egleson,C.M.Brock,J.Fisher,A.E.Sands,Removal of hydrogen sulfide and carbon dioxide from synthesis gas,using di-and tri-ethanolamine,US Department of the Interior,Bureau of Mines,1952.
[31]A.L.Shrier,P.V.Danckwerts,Carbon dioxide absorption into amine-promoted potash solutions,Ind.Eng.Chem.Fundam.8(1969)415–423.
[32]E.Bartholome,H.W.Schmidt,J.Friebe,Process for removing carbon dioxide from gas mixtures,3622267,1971.
[33]G.Sartori,F.Leder,Process and amine-solvent absorbent for removing acidic gases from gaseous mixtures,US4112051 A,1978.
[34]P.J.Birbara,T.P.Filburn,T.A.Nalette,Carbon dioxide,water,US5876488 A,1999.
[35]R.J.Hook,An investigation of some sterically hindered amines as potential carbon dioxide scrubbing compounds,Ind.Eng.Chem.Res.36(1997)1779–1790.
[36]M.T.Melchior,G.E.Milliman,G.Sartori,Method of removing carbon dioxide from gases utilizing an alkaline absorption solution containing a cyclic urea antifoaming agent,US4183903 A,1980.
[37]G.Sartori,D.W.Savage,Sterically hindered amines for carbon dioxide removal from gases,Ind.Eng.Chem.Fundam.22(1983)239–249.
[38]M.Appl,U.Wagner,H.J.Henrici,K.Kuessner,K.Volkamer,E.Fuerst,Removal of CO2and/or H2S and/or COS from gases containing these constituents,4336233,1982.
[39]S.Bishnoi,G.T.Rochelle,Absorption of carbon dioxide in aqueous piperazine/methyldiethanolamine,AICh E J.48(2002)2788–2799.
[40]R.Litonjua,I.Cvetkovski,Biogas:Production,consumption and applications,Nova Science Pub Inc.,Hauppauge,N.Y.,2012
[41]R.W.Millar,R.L.Maycock,Purification and separation of gaseous mixtures,2164194,1939.
[42]E.W.Zublin,Purification and separation of gaseous mixtures,2157879,1939.
[43]G.T.Rochelle,et al.,Amine scrubbing for CO2capture,Science 325(2009)1652–1654.
[44]P.Zhang,Y.Shi,J.Wei,W.Zhao,Q.Ye,Regeneration of 2-amino-2-methyl-1-propanol used for carbon dioxide absorption,J.Environ.Sci.20(2008)39–44.
[45]B.A.Oyenekan,Modeling of strippers for carbon dioxide capture by aqueous amines,Pro Quest,2007.
[46]B.A.Oyenekan,G.T.Rochelle,Energy performance of stripper configurations for CO2capture by aqueous amines,Ind.Eng.Chem.Res.45(2006)2457–2464.
[47]R.A.Frimpong,J.E.Remias,J.K.Neathery,K.Liu,Solvent regeneration with a high volatility liquid as stripping carrier,Int.J.Greenhouse Gas Control 9(2012)124–129.
[48]M.Rashidian,Thermal degradation study by continuous thermal stability rig,http://www.diva-portal.org/smash/record.jsf?pid=diva2:6550632013(accessed November 8,2014).
[49]B.R.Strazisar,R.R.Anderson,C.M.White,Degradation pathways for monoethanolamine in a CO2capture facility,Energy Fuel 17(2003)1034–1039.
[50]J.Davis,G.Rochelle,Thermal degradation of monoethanolamine at stripper conditions,Energy Procedia 1(2009)327–333.
[51]I.Eide-Haugmo,O.G.Brakstad,K.A.Hoff,K.R.S?rheim,E.F.da Silva,H.F.Svendsen,Environmental impact of amines,Energy Procedia 1(2009)1297–1304.
[52]S.A.Freeman,J.Davis,G.T.Rochelle,Degradation of aqueous piperazine in carbon dioxide capture,Int.J.Greenhouse Gas Control 4(2010)756–761.
[53]V.P.Talzi,S.V.Ignashin,NMR study of decomposition of monoethanolamine under conditions of industrial gas treatment,Russ.J.Appl.Chem.75(2002)80–85.
[54]J.Reza,A.Trejo,Degradation of aqueous solutions of alkanolamine blends at high temperature,under the presence of CO2and H2S,Chem.Eng.Commun.193(2006)129–138.
[55]S.A.Bedell,Oxidative degradation mechanisms for amines in flue gas capture,Energy Procedia 1(2009)771–778.
[56]H.Lepaumier,E.F.da Silva,A.Einbu,et al.,Comparison of MEA degradation in pilotscale with lab-scale experiments,Energy Procedia 4(2011)1652–1659.
[57]A.K.Voice,G.T.Rochelle,Inhibitors of monoethanolamine oxidation in CO2capture processes,Ind.Eng.Chem.Res.53(2014)16222–16228.
[58]J.Kittel,R.Idem,D.Gelowitz,P.Tontiwachwuthikul,G.Parrain,A.Bonneau,Corrosion in MEA units for CO2capture:Pilot plant studies,Energy Procedia 1(2009)791–797.
[59]I.R.Soosaiprakasam,A.Veawab,Corrosion and polarization behavior of carbon steel in MEA-based CO2capture process,Int.J.Greenhouse Gas Control 2(2008)553–562.
[60]S.Saito,M.Udatsu,H.Kitamura,et al.,Development and evaluation of a new amine solvent at the Mikawa CO2capture pilot plant,Energy Procedia 51(2014)176–183.
[61]E.Sanchez Fernandez,E.L.V.Goetheer,G.Manzolini,E.Macchi,S.Rezvani,T.J.H.Vlugt,Thermodynamic assessment of amine based CO2capture technologies in power plants based on European benchmarking task force methodology,Fuel129(2014)318–329.
[62]S.Yan,Q.He,P.Ai,Y.Wang,Y.Zhang,Regeneration performance of concentrated CO2-rich alkanolamine solvents:The first step study of a novel concept for reducing regeneration heat consumption by using concentration swing absorption technology,Chem.Eng.Process.Process Intensif.70(2013)86–94.
[63]B.Morero,E.A.Campanella,Simulación del Proceso de Absorción Química con Soluciones de Aminas Para la Purificación Biogás,Inf.Tecnol.24(2013)25–32.
[64]S.Gamba,L.A.Pellegrini,Biogas upgrading:Analysis and comparison between water and chemical scrubbings,Chem.Eng.32(2013)1273–1278.
[65]S.Gamba,L.A.Pellegrini,S.Langè,Energy analysis of different municipal sewage sludge-derived biogas upgrading techniques,Chem.Eng.37(2014)829–834.
[66]L.Günther,Method and device for separating methane and carbon dioxide from biogas,US20100024647 A1,2010.
[67]N.G.Peralta,Mass transfer in chemical engeering processes-Chapter 7-Removal of H2S and CO2from biogas by amine absorption,Ingeniería e Investigación 33(2013)75–76.
[68]A.Gaur,J.-W.Park,S.Maken,H.-J.Song,J.-J.Park,Landfill gas(LFG)processing via adsorption and alkanolamine absorption,Fuel Process.Technol.91(2010)635–640.
[69]N.Tippayawong,P.Thanompongchart,Biogas quality upgrade by simultaneous removal of CO2and H2S in a packed column reactor,Energy 35(2010)4531–4535.
[70]Q.Zhao,E.Leonhardt,C.Mac Connell,C.Frear,S.Chen,Purification technologies for biogas generated by anaerobic digestion,Clim.Friendly Farming,http://csanr.wsu.edu/wp-content/uploads/2013/02/CSANR2010-001.Ch09.pdf 2010(accessed January 3,2015).
[71]L.Günther,Method and device for separating methane and carbon dioxide from biogas,US8231706 B2,2012.
[72]P.V.Danckwerts,A.M.Kennedy,The kinetics of absorption of carbon dioxide into neutral and alkaline solutions,Chem.Eng.Sci.8(1958)201–215.
[73]V.A.Juvekar,M.M.Sharma,Absorption of CO2in a suspension of lime,Chem.Eng.Sci.28(1973)825–837.
[74]D.Roberts,P.V.Danckwerts,Kinetics of CO2absorption in alkaline solutions—I transient absorption rates and catalysis by arsenite,Chem.Eng.Sci.17(1962)961–969.
[75]H.Hikita,S.Asai,T.Takatsuka,Absorption of carbon dioxide into aqueous sodium hydroxide and sodium carbonate–bicarbonate solutions,Chem.Eng.J.11(1976)131–141.
[76]J.B.Tepe,B.F.Dodge,Absorption of carbon dioxide by sodium hydroxide solutions in a packed column,Trans.Am.Inst.Chem.Eng.39(1943)255–276.
[77]L.B.Hitchcock,Mechanism of gas–liquid reaction batch absorption of carbon dioxide by stirred alkaline solutions,Ind.Eng.Chem.29(1937)302–308.
[78]F.Yoshida,Y.Miura,Effective interfacial area in packed columns for absorption with chemical reaction,AICh E J.9(1963)331–337.
[79]M.Yoo,S.-J.Han,J.-H.Wee,Carbon dioxide capture capacity of sodium hydroxide aqueous solution,J.Environ.Manag.114(2013)512–519.
[80]S.Gondal,N.Asif,H.F.Svendsen,H.Knuutila,Kinetics of the absorption of carbon dioxide into aqueous hydroxides of lithium,sodium and potassium and blends of hydroxides and carbonates,Chem.Eng.Sci.123(2015)487–499.
[81]M.Mahmoudkhani,D.W.Keith,Low-energy sodium hydroxide recovery for CO2capture from atmospheric air—thermodynamic analysis,Int.J.Greenhouse Gas Control 3(2009)376–384.
[82]A.Aroonwilas,P.Tontiwachwuthikul,A.Chakma,Effects of operating and design parameters on CO2absorption in columns with structured packings,Sep.Purif.Technol.24(2001)403–411.
[83]M.Mahmoudkhani,K.R.Heidel,J.C.Ferreira,D.W.Keith,R.S.Cherry,Low energy packed tower and caustic recovery for direct capture of CO2from air,Energy Procedia 1(2009)1535–1542.
[84]J.K.Stolaroff,D.W.Keith,G.V.Lowry,Carbon dioxide capture from atmospheric air using sodium hydroxide spray,Environ.Sci.Technol.42(2008)2728–2735.
[85]L.Lombardia,A.Corti,E.Carnevale,R.Baciocchi,D.Zingaretti,Carbon dioxide removal and capture for landfill gas up-grading,Energy Procedia 4(2011)465–472.
[86]J.Blamey,N.P.M.Paterson,D.R.Dugwell,P.Stevenson,P.S.Fennell,Reactivation of a Ca O-based sorbent for CO2capture from stationary sources,Proc.Combust.Inst.33(2011)2673–2681.
[87]D.-R.Han,H.Namkung,H.-M.Lee,D.-G.Huh,H.-T.Kim,CO2sequestration by aqueous mineral carbonation of limestone in a supercritical reactor,J.Ind.Eng.Chem.21(2015)792–796.
[88]L.Reich,L.Yue,R.Bader,W.Lipiński,Towards solar thermochemical carbon dioxide capture via calcium oxide looping:a review,Aerosol Air Qual.Res.14(2014)500–514.
[89]R.M.Santos,W.Verbeeck,P.Knops,K.Rijnsburger,Y.Pontikes,T.Van Gerven,Integrated mineral carbonation reactor technology for sustainable carbon dioxide sequestration:“CO2energy reactor”,Energy Procedia 37(2013)5884–5891.
[90]J.-H.Wee,A review on carbon dioxide capture and storage technology using coal fly ash,Appl.Energy 106(2013)143–151.
[91]W.J.Huijgen,G.-J.Witkamp,R.N.Comans,Mineral CO2sequestration by steel slag carbonation,Environ.Sci.Technol.39(2005)9676–9682.
[92]S.Eloneva,S.Teir,J.Salminen,C.-J.Fogelholm,R.Zevenhoven,Fixation of CO2by carbonating calcium derived from blast furnace slag,Energy 33(2008)1461–1467.
[93]M.F.Bertos,S.J.R.Simons,C.D.Hills,P.J.Carey,A review of accelerated carbonation technology in the treatment of cement-based materials and sequestration of CO2,J.Hazard.Mater.B 112(2004)193–205.
[94]D.N.Huntzinger,J.S.Gierke,S.K.Kawatra,T.C.Eisele,L.L.Sutter,Carbon dioxide sequestration in cement kiln dust through mineral carbonation,Environ.Sci.Technol.43(2009)1986–1992.
[95]G.Costa,R.Baciocchi,A.Polettini,R.Pomi,C.D.Hills,P.J.Carey,Current status and perspectives of accelerated carbonation processes on municipal waste combustion residues,Environ.Monit.Assess.135(2007)55–75.
[96]E.Rendek,G.Ducom,P.Germain,Carbon dioxide sequestration in municipal solid waste incinerator(MSWI)bottom ash,J.Hazard.Mater.128(2006)73–79.
[97]R.Pérez-López,G.Montes-Hernandez,J.M.Nieto,F.Renard,L.Charlet,Carbonation of alkaline paper mill waste to reduce CO2greenhouse gas emissions into the atmosphere,Appl.Geochem.23(2008)2292–2300.
[98]E.R.Bobicki,Q.Liu,Z.Xu,H.Zeng,Carbon capture and storage using alkaline industrial wastes,Prog.Energy Combust.Sci.38(2012)302–320.
[99]J.Sipil?,S.Teir,R.Zevenhoven,Carbon dioxide sequestration by mineral carbonation literature review update 2005–2007,Rep.VT 1(2008)2008.
[100]A.Kothandaraman,Carbon dioxide capture by chemical absorption:A solvent comparison study,Massachusetts Institute of Technology,2010.
[101]H.E.Benson,J.H.Field,R.M.Jimeson,CO2absorption:employing hot potassium carbonate solutions,Chem Eng Prog U.S.50(1954)7.
[102]H.A.Blum,L.F.Stutzman,W.S.Dodds,Gas absorption—Absorption of carbon dioxide from air by sodium and potassium hydroxides,Ind.Eng.Chem.44(1952)2969–2974.
[103]C.S.Comstock,B.F.Dodge,Rate of carbon dioxide absorption by carbonate solutions in a packed tower,Ind.Eng.Chem.29(1937)520–529.
[104]C.R.Harte,E.M.Baker,H.H.Purcell,Absorption of carbon dioxide in sodium carbonate–bicarbonate solutions,Ind.Eng.Chem.25(1933)528–531.
[105]D.W.Savage,G.Astarita,S.Joshi,Chemical absorption and desorption of carbon dioxide from hot carbonate solutions,Chem.Eng.Sci.35(1980)1513–1522.
[106]M.R.Bohloul,S.M.Peyghambarzadeh,A.Lee,A.Vatani,Experimental and analytical study of solubility of carbon dioxide in aqueous solutions of potassium carbonate,Int.J.Greenhouse Gas Control 29(2014)169–175.
[107]T.N.G.Borhani,A.Azarpour,V.Akbari,S.R.Wan Alwi,Z.A.Manan,CO2capture with potassium carbonate solutions:A state-of-the-art review,Int.J.Greenhouse Gas Control 41(2015)142–162.
[108]S.Li,H.Jin,L.Gao,K.A.Mumford,K.Smith,G.Stevens,Energy and exergy analyses of an integrated gasification combined cycle power plant with CO2capture using hot potassium carbonate solvent,Environ.Sci.Technol.48(2014)14814–14821.
[109]Z.Tang,W.Fei,Y.Oli,CO2capture by improved hot potash process,Energy Procedia4(2011)307–317.
[110]B.P.Spigarelli,S.K.Kawatra,Opportunities and challenges in carbon dioxide capture,J.CO2Util.1(2013)69–87.
[111]Y.E.Kim,J.H.Choi,S.C.Nam,Y.I.Yoon,CO2absorption capacity using aqueous potassium carbonate with 2-methylpiperazine and piperazine,J.Ind.Eng.Chem.18(2012)105–110.
[112]H.Thee,Y.A.Suryaputradinata,K.A.Mumford,K.H.Smith,G.da Silva,S.E.Kentish,et al.,A kinetic and process modeling study of CO2capture with MEA-promoted potassium carbonate solutions,Chem.Eng.J.210(2012)271–279.
[113]K.H.Smith,C.J.Anderson,W.Tao,et al.,Pre-combustion capture of CO2—Results from solvent absorption pilot plant trials using 30 wt%potassium carbonate and boric acid promoted potassium carbonate solvent,Int.J.Greenhouse Gas Control10(2012)64–73.
[114]H.Thee,N.J.Nicholas,K.H.Smith,G.da Silva,S.E.Kentish,G.W.Stevens,A kinetic study of CO2capture with potassium carbonate solutions promoted with various amino acids:Glycine,sarcosine and proline,Int.J.Greenhouse Gas Control 20(2014)212–222.
[115]R.Baciocchi,A.Corti,G.Costa,L.Lombardi,D.Zingaretti,Storage of carbon dioxide captured in a pilot-scale biogas upgrading plant by accelerated carbonation of industrial residues,Energy Procedia 4(2011)4985–4992.
[116]P.Mostbauer,L.Lombardi,T.Olivieri,S.Lenz,Pilot scale evaluation of the BABIU process—Upgrading of landfill gas or biogas with the use of MSWI bottom ash,Waste Manag.34(2014)125–133.
[117]R.Baciocchi,E.Carnevale,A.Corti,G.Costa,L.Lombardi,T.Olivieri,et al.,Innovative process for biogas upgrading with CO2storage:Results from pilot plant operation,Biomass Bioenergy 53(2013)128–137.
[118]R.Baciocchi,G.Costa,R.Gavasci,L.Lombardi,D.Zingaretti,Regeneration of a spent alkaline solution from a biogas upgrading unit by carbonation of APC residues,Chem.Eng.J.179(2012)63–71.
[119]R.Baciocchi,E.Carnevale,G.Costa,et al.,Performance of a biogas upgrading process based on alkali absorption with regeneration using air pollution control residues,Waste Manag.33(2013)2694–2705.
[120]P.Mostbauer,S.Lenz,Upgrading of lean landfill gas using MSWI bottom ash,Proc.Sard,2007.
[121]K.Starr,X.Gabarrell,G.Villalba,L.Talens,L.Lombardi,Life cycle assessment of biogas upgrading technologies,Waste Manag.32(2012)991–999.
[122]K.Starr,X.Gabarrell,G.Villalba,L.Talens Peiro,L.Lombardi,Potential CO2savings through biomethane generation from municipal waste biogas,Biomass Bioenergy62(2014)8–16.
[123]K.Starr,L.Talens Peiro,L.Lombardi,X.Gabarrell,G.Villalba,Optimization of environmental benefits of carbon mineralization technologies for biogas upgrading,J.Clean.Prod.76(2014)32–41.
[124]J.van Holst,G.F.Versteeg,D.W.F.Brilman,J.A.Hogendoorn,Kinetic study of CO2with various amino acid salts in aqueous solution,Chem.Eng.Sci.64(2009)59–68.
[125]P.S.Kumar,J.A.Hogendoorn,G.F.Versteeg,P.H.M.Feron,Kinetics of the reaction of CO2with aqueous potassium salt of taurine and glycine,AICh E J.49(2003)203–213.
[126]U.E.Aronu,H.F.Svendsen,K.A.Hoff,Investigation of amine amino acid salts for carbon dioxide absorption,Int.J.Greenhouse Gas Control 4(2010)771–775.
[127]S.Yan,Q.He,S.Zhao,H.Zhai,M.Cao,P.Ai,CO2removal from biogas by using green amino acid salts:Performance evaluation,Fuel Process.Technol.129(2015)203–212.
[128]J.P.Brouwer,P.H.M.Feron,N.A.M.Ten Asbroek,Amino-acid salts for CO2capture from flue gases,Proc.4th Annu.Conf.Carbon capture sequestration Alex.Va.USA,2005.
[129]A.Jensen,J.B.Jensen,C.Faurholt,Studies on carbamates.6.The carbamate of glycine,Acta Chem.Scand.6(1952)395–397.
[130]A.Jensen,C.Faurholt,Studies on carbamates.5.The carbamates of alpha-alanine and beta-alanine,Acta Chem.Scand.6(1952)385–394.
[131]D.E.Penny,T.J.Ritter,Kinetic study of the reaction between carbon dioxide and primary amines,J.Chem.Soc.Faraday Trans.1 Phys.Chem.Condens.Phases 79(1983)2103–2109.
[132]U.E.Aronu,E.T.Hessen,T.Haug-Warberg,K.A.Hoff,H.F.Svendsen,Equilibrium absorption of carbon dioxide by amino acid salt and amine amino acid salt solutions,Energy Procedia 4(2011)109–116.
[133]H.-J.Song,S.Park,H.Kim,A.Gaur,J.-W.Park,S.-J.Lee,Carbon dioxide absorption characteristics of aqueous amino acid salt solutions,Int.J.Greenhouse Gas Control11(2012)64–72.
[134]P.D.Vaidya,P.Konduru,M.Vaidyanathan,E.Y.Kenig,Kinetics of carbon dioxide removal by aqueous alkaline amino acid salts,Ind.Eng.Chem.Res.49(2010)11067–11072.
[135]U.E.Aronu,A.Hartono,K.A.Hoff,H.F.Svendsen,Kinetics of carbon dioxide absorption into aqueous amino acid salt:Potassium salt of sarcosine solution,Ind.Eng.Chem.Res.50(2011)10465–10475.
[136]H.Knuutila,U.E.Aronu,H.M.Kvamsdal,A.Chikukwa,Post combustion CO2capture with an amino acid salt,Energy Procedia 4(2011)1550–1557.
[137]S.Park,H.-J.Song,J.Park,Selection of suitable aqueous potassium amino acid salts:CH4recovery in coal bed methane via CO2removal,Fuel Process.Technol.120(2014)48–53.
[138]A.Hartono,U.E.Aronu,H.F.Svendsen,Liquid speciation study in amine amino acid salts for CO2absorbent with13C-NMR,Energy Procedia 4(2011)209–215.
[139]K.Simons,K.Nijmeijer,H.Mengers,W.Brilman,M.Wessling,Highly selective amino acid salt solutions as absorption liquid for CO2capture in gas–liquid membrane contactors,Chem.Sus.Chem.3(2010)939–947.
[140]S.Yan,Q.He,S.Zhao,Y.Wang,P.Ai,Biogas upgrading by CO2removal with a highly selective natural amino acid salt in gas–liquid membrane contactor,Chem.Eng.Process.Process Intensif.85(2014)125–135.
[141]Y.Shui Ping,Q.Y.He,C.Kai,A.Ping,Y.Y.Wang,Z.Yan Lin,Performance of CO2removal from biogas by using amine-based amino acid salts,Nongye Jixie Xuebao Trans.Chin.Soc.Agric.Mach.45(2014)199–205.
[2]D.Divya,L.R.Gopinath,P.Merlin Christy,A review on current aspects and diverse prospects for enhancing biogas production in sustainable means,Renew.Sust.Energ.Rev.42(2015)690–699.
[3]N.Korres,P.O'Kiely,J.A.H.Benzie,J.S.West,Bioenergy production by anaerobic digestion:using agricultural biomass and organic wastes,Routledge,2013.
[4]M.Persson,O.J?nsson,A.Wellinger,Biogas upgrading to vehicle fuel standards and grid injection,IEA bioenergy task,2006(http://www.businessregiongoteborg.com/download/18.37dc8386114072e4a2d80003405/1389235333763/upgrading_report_final.pdf(accessed March 5,2014)).
[5]F.Osorio,J.C.Torres,Biogas purification from anaerobic digestion in a wastewater treatment plant for biofuel production,Renew.Energy 34(2009)2164–2171.
[6]N.Abatzoglou,S.Boivin,A review of biogas purification processes,Biofuels Bioprod.Biorefin.3(2009)42–71.
[7]M.S.Horikawa,F.Rossi,M.L.Gimenes,C.M.M.Costa,M.da Silva,Chemical absorption of H2S for biogas purification,Braz.J.Chem.Eng.21(2004)415–422.
[8]W.-C.Lin,Y.-P.Chen,C.-P.Tseng,Pilot-scale chemical–biological system for efficient H2S removal from biogas,Bioresour.Technol.135(2013)283–291.
[9]D.Ramírez-Sáenz,P.B.Zarate-Segura,C.Guerrero-Barajas,E.I.García-Pe?a,H2S and volatile fatty acids elimination by biofiltration:Clean-up process for biogas potential use,J.Hazard.Mater.163(2009)1272–1281.
[10]D.Dieter,S.Angelika,Biogas from waste and renewable resources:An introduction,Wiley-VCH,Weiheim,Germany,2008.
[11]S.Rasi,J.L?ntel?,J.Rintala,Trace compounds affecting biogas energy utilisation—A review,Energy Convers.Manag.52(2011)3369–3375.
[12]L.Yang,X.Ge,C.Wan,F.Yu,Y.Li,Progress and perspectives in converting biogas to transportation fuels,Renew.Sust.Energ.Rev.40(2014)1133–1152.
[13]P.Weiland,Biogas production:Current state and perspectives,Appl.Microbiol.Biotechnol.85(2010)849–860.
[14]Y.Xu,Y.Huang,B.Wu,X.Zhang,S.Zhang,Biogas upgrading technologies:Energetic analysis and environmental impact assessment,Chin.J.Chem.Eng.23(1)(2015)247–254.
[15]J.Arroyo,F.Moreno,M.Mu?oz,C.Monné,N.Bernal,Combustion behavior of a spark ignition engine fueled with synthetic gases derived from biogas,Fuel 117,Part A(2014)50–58.
[16]E.Privalova,S.Rasi,P.M?ki-Arvela,et al.,CO2capture from biogas:Absorbent selection,RSC Adv.3(2013)2979–2994.
[17]A.L.Kohl,R.Nielsen,Gas purification,Gulf Professional Publishing,1997.
[18]F.Bauer,C.Hulteberg,T.Persson,D.Tamm,Biogas upgrading—Review of commercial technologies,SGC Rapp.,2013(http://lup.lub.lu.se/record/3512502(accessed October 16,2014)).
[19]R.H.Perry,D.W.Green,Perry's chemical engineers'handbook,Mc Graw-Hill,New York,2008.
[20]D.S.Clark,H.W.Blanch,Biochemical engineering,2 ed.CRC Press,New York,1997.
[21]J.Reynolds,J.S.Jeris,L.Theodore(Eds.),Handbook of chemical and environmental engineering calculations,1 ed.Wiley-Interscience,Hoboken,N.J.,2007.
[22]Y.Xiao,H.Yuan,Y.Pang,et al.,CO2removal from biogas by water washing system,Chin.J.Chem.Eng.22(2014)950–953.
[23]N.A.Al-Baghli,S.A.Pruess,V.F.Yesavage,M.S.Selim,A rate-based model for the design of gas absorbers for the removal of CO2and H2S using aqueous solutions of MEA and DEA,Fluid Phase Equilib.185(2001)31–43.
[24]N.Razi,H.F.Svendsen,O.Bolland,Validation of mass transfer correlations for CO2absorption with MEA using pilot data,Int.J.Greenhouse Gas Control 19(2013)478–491.
[25]J.T.Yeh,H.W.Pennline,K.P.Resnik,Study of CO2absorption and desorption in a packed column,Energy Fuel 15(2001)274–278.
[26]L.A.Pellegrini,S.Moioli,S.Gamba,Energy saving in a CO2capture plant by MEA scrubbing,Chem.Eng.Res.Des.89(2011)1676–1683.
[27]A.Aroonwilas,Mass-transfer with chemical reaction in structured packing for carbon dioxide absorption process(Ph.D.)The University of Regina,Canada,2001.
[28]R.B.Robert,Process for separating acidic gases,US1783901 A,1930.
[29]L.B.Gregory,W.G.Scharmann,Carbon dioxide scrubbing by amine solutions,Ind.Eng.Chem.29(1937)514–519.
[30]H.W.Wainwright,G.C.Egleson,C.M.Brock,J.Fisher,A.E.Sands,Removal of hydrogen sulfide and carbon dioxide from synthesis gas,using di-and tri-ethanolamine,US Department of the Interior,Bureau of Mines,1952.
[31]A.L.Shrier,P.V.Danckwerts,Carbon dioxide absorption into amine-promoted potash solutions,Ind.Eng.Chem.Fundam.8(1969)415–423.
[32]E.Bartholome,H.W.Schmidt,J.Friebe,Process for removing carbon dioxide from gas mixtures,3622267,1971.
[33]G.Sartori,F.Leder,Process and amine-solvent absorbent for removing acidic gases from gaseous mixtures,US4112051 A,1978.
[34]P.J.Birbara,T.P.Filburn,T.A.Nalette,Carbon dioxide,water,US5876488 A,1999.
[35]R.J.Hook,An investigation of some sterically hindered amines as potential carbon dioxide scrubbing compounds,Ind.Eng.Chem.Res.36(1997)1779–1790.
[36]M.T.Melchior,G.E.Milliman,G.Sartori,Method of removing carbon dioxide from gases utilizing an alkaline absorption solution containing a cyclic urea antifoaming agent,US4183903 A,1980.
[37]G.Sartori,D.W.Savage,Sterically hindered amines for carbon dioxide removal from gases,Ind.Eng.Chem.Fundam.22(1983)239–249.
[38]M.Appl,U.Wagner,H.J.Henrici,K.Kuessner,K.Volkamer,E.Fuerst,Removal of CO2and/or H2S and/or COS from gases containing these constituents,4336233,1982.
[39]S.Bishnoi,G.T.Rochelle,Absorption of carbon dioxide in aqueous piperazine/methyldiethanolamine,AICh E J.48(2002)2788–2799.
[40]R.Litonjua,I.Cvetkovski,Biogas:Production,consumption and applications,Nova Science Pub Inc.,Hauppauge,N.Y.,2012
[41]R.W.Millar,R.L.Maycock,Purification and separation of gaseous mixtures,2164194,1939.
[42]E.W.Zublin,Purification and separation of gaseous mixtures,2157879,1939.
[43]G.T.Rochelle,et al.,Amine scrubbing for CO2capture,Science 325(2009)1652–1654.
[44]P.Zhang,Y.Shi,J.Wei,W.Zhao,Q.Ye,Regeneration of 2-amino-2-methyl-1-propanol used for carbon dioxide absorption,J.Environ.Sci.20(2008)39–44.
[45]B.A.Oyenekan,Modeling of strippers for carbon dioxide capture by aqueous amines,Pro Quest,2007.
[46]B.A.Oyenekan,G.T.Rochelle,Energy performance of stripper configurations for CO2capture by aqueous amines,Ind.Eng.Chem.Res.45(2006)2457–2464.
[47]R.A.Frimpong,J.E.Remias,J.K.Neathery,K.Liu,Solvent regeneration with a high volatility liquid as stripping carrier,Int.J.Greenhouse Gas Control 9(2012)124–129.
[48]M.Rashidian,Thermal degradation study by continuous thermal stability rig,http://www.diva-portal.org/smash/record.jsf?pid=diva2:6550632013(accessed November 8,2014).
[49]B.R.Strazisar,R.R.Anderson,C.M.White,Degradation pathways for monoethanolamine in a CO2capture facility,Energy Fuel 17(2003)1034–1039.
[50]J.Davis,G.Rochelle,Thermal degradation of monoethanolamine at stripper conditions,Energy Procedia 1(2009)327–333.
[51]I.Eide-Haugmo,O.G.Brakstad,K.A.Hoff,K.R.S?rheim,E.F.da Silva,H.F.Svendsen,Environmental impact of amines,Energy Procedia 1(2009)1297–1304.
[52]S.A.Freeman,J.Davis,G.T.Rochelle,Degradation of aqueous piperazine in carbon dioxide capture,Int.J.Greenhouse Gas Control 4(2010)756–761.
[53]V.P.Talzi,S.V.Ignashin,NMR study of decomposition of monoethanolamine under conditions of industrial gas treatment,Russ.J.Appl.Chem.75(2002)80–85.
[54]J.Reza,A.Trejo,Degradation of aqueous solutions of alkanolamine blends at high temperature,under the presence of CO2and H2S,Chem.Eng.Commun.193(2006)129–138.
[55]S.A.Bedell,Oxidative degradation mechanisms for amines in flue gas capture,Energy Procedia 1(2009)771–778.
[56]H.Lepaumier,E.F.da Silva,A.Einbu,et al.,Comparison of MEA degradation in pilotscale with lab-scale experiments,Energy Procedia 4(2011)1652–1659.
[57]A.K.Voice,G.T.Rochelle,Inhibitors of monoethanolamine oxidation in CO2capture processes,Ind.Eng.Chem.Res.53(2014)16222–16228.
[58]J.Kittel,R.Idem,D.Gelowitz,P.Tontiwachwuthikul,G.Parrain,A.Bonneau,Corrosion in MEA units for CO2capture:Pilot plant studies,Energy Procedia 1(2009)791–797.
[59]I.R.Soosaiprakasam,A.Veawab,Corrosion and polarization behavior of carbon steel in MEA-based CO2capture process,Int.J.Greenhouse Gas Control 2(2008)553–562.
[60]S.Saito,M.Udatsu,H.Kitamura,et al.,Development and evaluation of a new amine solvent at the Mikawa CO2capture pilot plant,Energy Procedia 51(2014)176–183.
[61]E.Sanchez Fernandez,E.L.V.Goetheer,G.Manzolini,E.Macchi,S.Rezvani,T.J.H.Vlugt,Thermodynamic assessment of amine based CO2capture technologies in power plants based on European benchmarking task force methodology,Fuel129(2014)318–329.
[62]S.Yan,Q.He,P.Ai,Y.Wang,Y.Zhang,Regeneration performance of concentrated CO2-rich alkanolamine solvents:The first step study of a novel concept for reducing regeneration heat consumption by using concentration swing absorption technology,Chem.Eng.Process.Process Intensif.70(2013)86–94.
[63]B.Morero,E.A.Campanella,Simulación del Proceso de Absorción Química con Soluciones de Aminas Para la Purificación Biogás,Inf.Tecnol.24(2013)25–32.
[64]S.Gamba,L.A.Pellegrini,Biogas upgrading:Analysis and comparison between water and chemical scrubbings,Chem.Eng.32(2013)1273–1278.
[65]S.Gamba,L.A.Pellegrini,S.Langè,Energy analysis of different municipal sewage sludge-derived biogas upgrading techniques,Chem.Eng.37(2014)829–834.
[66]L.Günther,Method and device for separating methane and carbon dioxide from biogas,US20100024647 A1,2010.
[67]N.G.Peralta,Mass transfer in chemical engeering processes-Chapter 7-Removal of H2S and CO2from biogas by amine absorption,Ingeniería e Investigación 33(2013)75–76.
[68]A.Gaur,J.-W.Park,S.Maken,H.-J.Song,J.-J.Park,Landfill gas(LFG)processing via adsorption and alkanolamine absorption,Fuel Process.Technol.91(2010)635–640.
[69]N.Tippayawong,P.Thanompongchart,Biogas quality upgrade by simultaneous removal of CO2and H2S in a packed column reactor,Energy 35(2010)4531–4535.
[70]Q.Zhao,E.Leonhardt,C.Mac Connell,C.Frear,S.Chen,Purification technologies for biogas generated by anaerobic digestion,Clim.Friendly Farming,http://csanr.wsu.edu/wp-content/uploads/2013/02/CSANR2010-001.Ch09.pdf 2010(accessed January 3,2015).
[71]L.Günther,Method and device for separating methane and carbon dioxide from biogas,US8231706 B2,2012.
[72]P.V.Danckwerts,A.M.Kennedy,The kinetics of absorption of carbon dioxide into neutral and alkaline solutions,Chem.Eng.Sci.8(1958)201–215.
[73]V.A.Juvekar,M.M.Sharma,Absorption of CO2in a suspension of lime,Chem.Eng.Sci.28(1973)825–837.
[74]D.Roberts,P.V.Danckwerts,Kinetics of CO2absorption in alkaline solutions—I transient absorption rates and catalysis by arsenite,Chem.Eng.Sci.17(1962)961–969.
[75]H.Hikita,S.Asai,T.Takatsuka,Absorption of carbon dioxide into aqueous sodium hydroxide and sodium carbonate–bicarbonate solutions,Chem.Eng.J.11(1976)131–141.
[76]J.B.Tepe,B.F.Dodge,Absorption of carbon dioxide by sodium hydroxide solutions in a packed column,Trans.Am.Inst.Chem.Eng.39(1943)255–276.
[77]L.B.Hitchcock,Mechanism of gas–liquid reaction batch absorption of carbon dioxide by stirred alkaline solutions,Ind.Eng.Chem.29(1937)302–308.
[78]F.Yoshida,Y.Miura,Effective interfacial area in packed columns for absorption with chemical reaction,AICh E J.9(1963)331–337.
[79]M.Yoo,S.-J.Han,J.-H.Wee,Carbon dioxide capture capacity of sodium hydroxide aqueous solution,J.Environ.Manag.114(2013)512–519.
[80]S.Gondal,N.Asif,H.F.Svendsen,H.Knuutila,Kinetics of the absorption of carbon dioxide into aqueous hydroxides of lithium,sodium and potassium and blends of hydroxides and carbonates,Chem.Eng.Sci.123(2015)487–499.
[81]M.Mahmoudkhani,D.W.Keith,Low-energy sodium hydroxide recovery for CO2capture from atmospheric air—thermodynamic analysis,Int.J.Greenhouse Gas Control 3(2009)376–384.
[82]A.Aroonwilas,P.Tontiwachwuthikul,A.Chakma,Effects of operating and design parameters on CO2absorption in columns with structured packings,Sep.Purif.Technol.24(2001)403–411.
[83]M.Mahmoudkhani,K.R.Heidel,J.C.Ferreira,D.W.Keith,R.S.Cherry,Low energy packed tower and caustic recovery for direct capture of CO2from air,Energy Procedia 1(2009)1535–1542.
[84]J.K.Stolaroff,D.W.Keith,G.V.Lowry,Carbon dioxide capture from atmospheric air using sodium hydroxide spray,Environ.Sci.Technol.42(2008)2728–2735.
[85]L.Lombardia,A.Corti,E.Carnevale,R.Baciocchi,D.Zingaretti,Carbon dioxide removal and capture for landfill gas up-grading,Energy Procedia 4(2011)465–472.
[86]J.Blamey,N.P.M.Paterson,D.R.Dugwell,P.Stevenson,P.S.Fennell,Reactivation of a Ca O-based sorbent for CO2capture from stationary sources,Proc.Combust.Inst.33(2011)2673–2681.
[87]D.-R.Han,H.Namkung,H.-M.Lee,D.-G.Huh,H.-T.Kim,CO2sequestration by aqueous mineral carbonation of limestone in a supercritical reactor,J.Ind.Eng.Chem.21(2015)792–796.
[88]L.Reich,L.Yue,R.Bader,W.Lipiński,Towards solar thermochemical carbon dioxide capture via calcium oxide looping:a review,Aerosol Air Qual.Res.14(2014)500–514.
[89]R.M.Santos,W.Verbeeck,P.Knops,K.Rijnsburger,Y.Pontikes,T.Van Gerven,Integrated mineral carbonation reactor technology for sustainable carbon dioxide sequestration:“CO2energy reactor”,Energy Procedia 37(2013)5884–5891.
[90]J.-H.Wee,A review on carbon dioxide capture and storage technology using coal fly ash,Appl.Energy 106(2013)143–151.
[91]W.J.Huijgen,G.-J.Witkamp,R.N.Comans,Mineral CO2sequestration by steel slag carbonation,Environ.Sci.Technol.39(2005)9676–9682.
[92]S.Eloneva,S.Teir,J.Salminen,C.-J.Fogelholm,R.Zevenhoven,Fixation of CO2by carbonating calcium derived from blast furnace slag,Energy 33(2008)1461–1467.
[93]M.F.Bertos,S.J.R.Simons,C.D.Hills,P.J.Carey,A review of accelerated carbonation technology in the treatment of cement-based materials and sequestration of CO2,J.Hazard.Mater.B 112(2004)193–205.
[94]D.N.Huntzinger,J.S.Gierke,S.K.Kawatra,T.C.Eisele,L.L.Sutter,Carbon dioxide sequestration in cement kiln dust through mineral carbonation,Environ.Sci.Technol.43(2009)1986–1992.
[95]G.Costa,R.Baciocchi,A.Polettini,R.Pomi,C.D.Hills,P.J.Carey,Current status and perspectives of accelerated carbonation processes on municipal waste combustion residues,Environ.Monit.Assess.135(2007)55–75.
[96]E.Rendek,G.Ducom,P.Germain,Carbon dioxide sequestration in municipal solid waste incinerator(MSWI)bottom ash,J.Hazard.Mater.128(2006)73–79.
[97]R.Pérez-López,G.Montes-Hernandez,J.M.Nieto,F.Renard,L.Charlet,Carbonation of alkaline paper mill waste to reduce CO2greenhouse gas emissions into the atmosphere,Appl.Geochem.23(2008)2292–2300.
[98]E.R.Bobicki,Q.Liu,Z.Xu,H.Zeng,Carbon capture and storage using alkaline industrial wastes,Prog.Energy Combust.Sci.38(2012)302–320.
[99]J.Sipil?,S.Teir,R.Zevenhoven,Carbon dioxide sequestration by mineral carbonation literature review update 2005–2007,Rep.VT 1(2008)2008.
[100]A.Kothandaraman,Carbon dioxide capture by chemical absorption:A solvent comparison study,Massachusetts Institute of Technology,2010.
[101]H.E.Benson,J.H.Field,R.M.Jimeson,CO2absorption:employing hot potassium carbonate solutions,Chem Eng Prog U.S.50(1954)7.
[102]H.A.Blum,L.F.Stutzman,W.S.Dodds,Gas absorption—Absorption of carbon dioxide from air by sodium and potassium hydroxides,Ind.Eng.Chem.44(1952)2969–2974.
[103]C.S.Comstock,B.F.Dodge,Rate of carbon dioxide absorption by carbonate solutions in a packed tower,Ind.Eng.Chem.29(1937)520–529.
[104]C.R.Harte,E.M.Baker,H.H.Purcell,Absorption of carbon dioxide in sodium carbonate–bicarbonate solutions,Ind.Eng.Chem.25(1933)528–531.
[105]D.W.Savage,G.Astarita,S.Joshi,Chemical absorption and desorption of carbon dioxide from hot carbonate solutions,Chem.Eng.Sci.35(1980)1513–1522.
[106]M.R.Bohloul,S.M.Peyghambarzadeh,A.Lee,A.Vatani,Experimental and analytical study of solubility of carbon dioxide in aqueous solutions of potassium carbonate,Int.J.Greenhouse Gas Control 29(2014)169–175.
[107]T.N.G.Borhani,A.Azarpour,V.Akbari,S.R.Wan Alwi,Z.A.Manan,CO2capture with potassium carbonate solutions:A state-of-the-art review,Int.J.Greenhouse Gas Control 41(2015)142–162.
[108]S.Li,H.Jin,L.Gao,K.A.Mumford,K.Smith,G.Stevens,Energy and exergy analyses of an integrated gasification combined cycle power plant with CO2capture using hot potassium carbonate solvent,Environ.Sci.Technol.48(2014)14814–14821.
[109]Z.Tang,W.Fei,Y.Oli,CO2capture by improved hot potash process,Energy Procedia4(2011)307–317.
[110]B.P.Spigarelli,S.K.Kawatra,Opportunities and challenges in carbon dioxide capture,J.CO2Util.1(2013)69–87.
[111]Y.E.Kim,J.H.Choi,S.C.Nam,Y.I.Yoon,CO2absorption capacity using aqueous potassium carbonate with 2-methylpiperazine and piperazine,J.Ind.Eng.Chem.18(2012)105–110.
[112]H.Thee,Y.A.Suryaputradinata,K.A.Mumford,K.H.Smith,G.da Silva,S.E.Kentish,et al.,A kinetic and process modeling study of CO2capture with MEA-promoted potassium carbonate solutions,Chem.Eng.J.210(2012)271–279.
[113]K.H.Smith,C.J.Anderson,W.Tao,et al.,Pre-combustion capture of CO2—Results from solvent absorption pilot plant trials using 30 wt%potassium carbonate and boric acid promoted potassium carbonate solvent,Int.J.Greenhouse Gas Control10(2012)64–73.
[114]H.Thee,N.J.Nicholas,K.H.Smith,G.da Silva,S.E.Kentish,G.W.Stevens,A kinetic study of CO2capture with potassium carbonate solutions promoted with various amino acids:Glycine,sarcosine and proline,Int.J.Greenhouse Gas Control 20(2014)212–222.
[115]R.Baciocchi,A.Corti,G.Costa,L.Lombardi,D.Zingaretti,Storage of carbon dioxide captured in a pilot-scale biogas upgrading plant by accelerated carbonation of industrial residues,Energy Procedia 4(2011)4985–4992.
[116]P.Mostbauer,L.Lombardi,T.Olivieri,S.Lenz,Pilot scale evaluation of the BABIU process—Upgrading of landfill gas or biogas with the use of MSWI bottom ash,Waste Manag.34(2014)125–133.
[117]R.Baciocchi,E.Carnevale,A.Corti,G.Costa,L.Lombardi,T.Olivieri,et al.,Innovative process for biogas upgrading with CO2storage:Results from pilot plant operation,Biomass Bioenergy 53(2013)128–137.
[118]R.Baciocchi,G.Costa,R.Gavasci,L.Lombardi,D.Zingaretti,Regeneration of a spent alkaline solution from a biogas upgrading unit by carbonation of APC residues,Chem.Eng.J.179(2012)63–71.
[119]R.Baciocchi,E.Carnevale,G.Costa,et al.,Performance of a biogas upgrading process based on alkali absorption with regeneration using air pollution control residues,Waste Manag.33(2013)2694–2705.
[120]P.Mostbauer,S.Lenz,Upgrading of lean landfill gas using MSWI bottom ash,Proc.Sard,2007.
[121]K.Starr,X.Gabarrell,G.Villalba,L.Talens,L.Lombardi,Life cycle assessment of biogas upgrading technologies,Waste Manag.32(2012)991–999.
[122]K.Starr,X.Gabarrell,G.Villalba,L.Talens Peiro,L.Lombardi,Potential CO2savings through biomethane generation from municipal waste biogas,Biomass Bioenergy62(2014)8–16.
[123]K.Starr,L.Talens Peiro,L.Lombardi,X.Gabarrell,G.Villalba,Optimization of environmental benefits of carbon mineralization technologies for biogas upgrading,J.Clean.Prod.76(2014)32–41.
[124]J.van Holst,G.F.Versteeg,D.W.F.Brilman,J.A.Hogendoorn,Kinetic study of CO2with various amino acid salts in aqueous solution,Chem.Eng.Sci.64(2009)59–68.
[125]P.S.Kumar,J.A.Hogendoorn,G.F.Versteeg,P.H.M.Feron,Kinetics of the reaction of CO2with aqueous potassium salt of taurine and glycine,AICh E J.49(2003)203–213.
[126]U.E.Aronu,H.F.Svendsen,K.A.Hoff,Investigation of amine amino acid salts for carbon dioxide absorption,Int.J.Greenhouse Gas Control 4(2010)771–775.
[127]S.Yan,Q.He,S.Zhao,H.Zhai,M.Cao,P.Ai,CO2removal from biogas by using green amino acid salts:Performance evaluation,Fuel Process.Technol.129(2015)203–212.
[128]J.P.Brouwer,P.H.M.Feron,N.A.M.Ten Asbroek,Amino-acid salts for CO2capture from flue gases,Proc.4th Annu.Conf.Carbon capture sequestration Alex.Va.USA,2005.
[129]A.Jensen,J.B.Jensen,C.Faurholt,Studies on carbamates.6.The carbamate of glycine,Acta Chem.Scand.6(1952)395–397.
[130]A.Jensen,C.Faurholt,Studies on carbamates.5.The carbamates of alpha-alanine and beta-alanine,Acta Chem.Scand.6(1952)385–394.
[131]D.E.Penny,T.J.Ritter,Kinetic study of the reaction between carbon dioxide and primary amines,J.Chem.Soc.Faraday Trans.1 Phys.Chem.Condens.Phases 79(1983)2103–2109.
[132]U.E.Aronu,E.T.Hessen,T.Haug-Warberg,K.A.Hoff,H.F.Svendsen,Equilibrium absorption of carbon dioxide by amino acid salt and amine amino acid salt solutions,Energy Procedia 4(2011)109–116.
[133]H.-J.Song,S.Park,H.Kim,A.Gaur,J.-W.Park,S.-J.Lee,Carbon dioxide absorption characteristics of aqueous amino acid salt solutions,Int.J.Greenhouse Gas Control11(2012)64–72.
[134]P.D.Vaidya,P.Konduru,M.Vaidyanathan,E.Y.Kenig,Kinetics of carbon dioxide removal by aqueous alkaline amino acid salts,Ind.Eng.Chem.Res.49(2010)11067–11072.
[135]U.E.Aronu,A.Hartono,K.A.Hoff,H.F.Svendsen,Kinetics of carbon dioxide absorption into aqueous amino acid salt:Potassium salt of sarcosine solution,Ind.Eng.Chem.Res.50(2011)10465–10475.
[136]H.Knuutila,U.E.Aronu,H.M.Kvamsdal,A.Chikukwa,Post combustion CO2capture with an amino acid salt,Energy Procedia 4(2011)1550–1557.
[137]S.Park,H.-J.Song,J.Park,Selection of suitable aqueous potassium amino acid salts:CH4recovery in coal bed methane via CO2removal,Fuel Process.Technol.120(2014)48–53.
[138]A.Hartono,U.E.Aronu,H.F.Svendsen,Liquid speciation study in amine amino acid salts for CO2absorbent with13C-NMR,Energy Procedia 4(2011)209–215.
[139]K.Simons,K.Nijmeijer,H.Mengers,W.Brilman,M.Wessling,Highly selective amino acid salt solutions as absorption liquid for CO2capture in gas–liquid membrane contactors,Chem.Sus.Chem.3(2010)939–947.
[140]S.Yan,Q.He,S.Zhao,Y.Wang,P.Ai,Biogas upgrading by CO2removal with a highly selective natural amino acid salt in gas–liquid membrane contactor,Chem.Eng.Process.Process Intensif.85(2014)125–135.
[141]Y.Shui Ping,Q.Y.He,C.Kai,A.Ping,Y.Y.Wang,Z.Yan Lin,Performance of CO2removal from biogas by using amine-based amino acid salts,Nongye Jixie Xuebao Trans.Chin.Soc.Agric.Mach.45(2014)199–205.