Advance in post-combustion CO2 capture with alkaline solution: A brief review

Energy Procedia

Volumn 14, Issue , 2012, Pages 1515-1522

  Peng, Yuanchang ^a   Zhao, Bingtao ^a   Li, Leilei ^a  

^a UNIVERSITY OF SHANGHAI FOR SCIENCE AND TECHNOLOGY   (China)

Author keywords

Absorbent type; Absorption efficiency; CO2; Operating conditions; Reactors structure

Indexed keywords

ALKALINITY; CARBON DIOXIDE; CHEMICAL ANALYSIS; COMBUSTION; FLUE GASES; FLUES; GLOBAL WARMING;

ABSORBENT TYPE; ABSORPTION EFFICIENCY; ALKALINE SOLUTIONS; CHEMICAL METHOD; COMBUSTION FLUE GAS; OPERATING CONDITION; REACTORS STRUCTURE; RESEARCH AND DEVELOPMENT;

GAS ABSORPTION;

EID: 84863340997     PISSN: 18766102     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1016/j.egypro.2011.12.1086     Document Type: Conference Paper

References (59)

1. 2 emission. World Environ. 1996;4: 38-41.
2. Yan J. Status and trends of carbon dioxide in the atmosphere. World Environ. 1995;4:34-39.
3. Xia MZ, Yan LH, Lei W, Wang FY, Zhu B, Zhao XL. Carbon dioxide separation and recovery technology and utilization. Mod. Chem. 1999; 19: 46-48.
4. Mohamed H, Marzouqi A, Muftah H, Naas E, Sayed A.M, Marzouk, Mohamed A, Zarooni A, Abdullatif N, Faiz R. Modeling of CO2 absorption in membrane contactors. Sep. Purif. Technol. 2008; 59: 286-293.
5. 2. Fuel 2001;80: 1953-1962.
6. Chris A, Hendriks KB. Underground storage of carbon dioxide. Energy Converse. Management 1995; 36: 539-542.
7. 2. Nat. 2002; 417: 279-282.
8. 2 research. Biol. Eng. 2005;21:177-181.
9. 2 and alkalinoamines both in aqueous and non-aqueous solutions, An overview. Chem. En.g Commun. 1996.
10. Cao ZW, Li ZX, Yuan HX. Cyclone used in gas absorption research. Environ. Eng. 2007;1:102-104.
11. Hong CX, Yuan HX. Hydrocyclone technology applied to strengthening the multi-phase flow response. Chem.l Eng. Prog. 2008;27:1328-1331.
12. Design Institute of Chemical Industry IV. Cryogenic Manual (second volume).Beijing: Chemical Industry Press; 1979, p.385-388.
13. 2 in conversion gas experiments study and application prospects. Gas Chem. 2010;35:23-25.
14. 2 in the flue gas. Coal Soc. 2007;32:748-752.
15. Li ZX, Yuan HX, Cao ZW. The absorption process of static-gravity device(cyclone). Colliery Machinery 2006;27:24-27.
16. Silva AJ, Varesche MB, Foresti E. Sulphate removal from industrial wastewater using a packed-bed anaerobic reactor. Process Biochem. 2002;37:927-935.
17. Soon HY, Lee KS, Sea BK. Application of pilot-scale membrane contactorhybrid system removal of carbon dioxide from flue gases. J Membrane Sci. 2005;257:156-160.
18. Tang LX, Ding ZP, Ji JL, Jiang LF, Zhou LD. Cross-flow packed column hydrodynamics and mass transfer performance experimental study. Refining Technol. Eng. 2008;38:29-33.
19. 2 in the air in packed tower. Chem.l Ind. Times 2004;18:35-40.
20. Vidwans AD, Sharma MM. Gasside Mass Transfer coefficient in Packed Columns. Chem. Eng. Sci. 1967;22:673-684.
21. 2 in packed column simulation study. Chem. Eng. 2004;32:74-77.
22. Tang LZ, Liu CJ, Chen JB, Wang GQ, Yuan XG, Yu GC. Evaluate the performance of packed tower from concentration distribution. Fine spray ammonia absorbed CO2 total volume mass transfer coefficient. China Electrical Eng. 2011;31:45-50.
23. Li YT, Li AP, Wang S, Yu T, Huang Z. FGD spray tower gas swirl experimental study. Experimental studies on removal of carbon dioxide by aqueous ammonia fine spray. Sci. China 2010;53:117-122.
24. Franz K, Thomas B. Ger. Chem. Eng. 1984;7:365-370.
25. Burgess JM, Calderbank PH. The measurement of bubble parameters in two-phase dispersions. Chem. Eng. Sci. 1975;30:734-739.
26. Serizaw A, Nicholas WG, Richard GR. Circulat ion andscale-up in bubble columns. AIChE 1992;38:76-82.
27. 2O system in vibration sieve plate bubble column. Process Eng. 2010;10:696-700.
28. Chen JM, Tian TE, Shi XN. Model of swirl board tower efficiency. Chem. Technol. 2003;54:1755-1760.
29. Sun WS, Wu ZB, Li Y, Tian TE. Sodium to strengthen the limestone wet FGD in swirl board tower. Environ. Sci. 2002;23:105-108.
30. Gu YX, Tian TE. Wirl board tower mass transfer coefficient. Chem. Technol. 1990;4:263-271.
31. Lin CC, Chen BC. Carbon Dioxide Absorption into NaOH solution in a cross-flow rotating packed bed. Chem. Eng. Sci. 2007;13:1083-1090.
32. Yang NS, Shen ZQ. Hydrodynamics performance of bubble plate tower. Dalian University Technol. 1989;29:139-144.
33. Yang NS, Shen ZQ. Compare tower wet desulfurization process. Power Environ. Prot. 2006;22:26-28.
34. 2 absorb study. Hangzhou: Zhejiang University;2007.
35. 2 capture by MEA. Energy Procedia 2009;1:205- 209.
36. Niu ZQ, Guo YC, Lin WY. MEA spray absorb CO2 in the flue gas experiment study. China Electrical Eng. 2010;30:41-45.
37. 2 green house gas by ammonia scrubbing. Ind. Eng. Chem. Res. 1997;36:2490-93.
38. Li XN, Hagaman E, Tsouris C. Removal of carbon dioxide from flue gas by ammonia carbonation in the gas phase. Energy Fuels 2003; 17:69-74.
39. 2 performance. Tsinghua University 2010;50:1130-34.
40. 2 green house gas by ammonia scrubbing. Energy Convers. Manage. 2004;45:2283-96.
41. Lee JW, Hagaman E. Removal of carbon dioxide from flue gas by ammonia carbonation in the gas phase. Energy Fuel 2003;17:69-74.
42. Liu F, Wang SJ, Chen CH, Xu XC. Ammonia decarbonization in flue gas in power plant research. Chem. Technol. 2009;60:269-278.
43. 2 greenhouse gas emissions. Sci. Total Environ. 1999;28:121-133..
44. Pinsent BRW, Pearson L, Roughton FJW. The kinetics of combination of carbon dioxide with ammonia. Trans. Faraday Soc 1956;52:1594-98.
45. 2 into low degree carbonated ammonia-water solutions. J East China Ins. Chem. Technol. 1984;2:137-146.
46. 2 in flue gas study. Taiwan: National Cheng Kung University;2003.
47. 2 absorption into partially carbonated ammonia liquor. Chem. Eng. Sci. 1954;3:279-286.
48. Astarita G. Mass transfer with chemical reactions. Amsterdam: Elsevier;1967.
49. Danckwerts PV. Gas-liquid reactions. New York: McGraw-Hill;1970.
50. 2 absorbers packed with structured packings. Chem. Eng. Sci. 2003;58:4037-53.
51. Stolaroff JK, Keith DW, Lowry GV. Carbon dioxide capture f rom atmospheric air using sodium hydroxide spray. Environ. Sci. Technol. 2008;42:2728-35.
52. 2 capture performance of a high-intensity vortex spray scrubber. Chem. Eng. J 2010;162:448-456.
53. Haghnegahdar MR, Hatamipour MS, Rahimi A. Removal of carbon dioxide in an experimental powder-particle spoutedbed reactor. Carbon dioxide removal by alkanolamines in aqueous organic solvents. A method for enhancing the desorption process. Sci. Direct 2011;4:187-194.
54. Guo YC, Niu ZQ, Lin WY. Comparison of removal efficiencies of carbon dioxide between aqueous ammonia and NaOH solution in a fine spray column. Energy Procedia 2011;4:512-518.
55. 2 from combustion flue gas with the ammonia solution as the absorbent. Power Eng. 2007;27:438-450.
56. 2 from coal-fired flue gas by using ammonia, J Eng. Therm. Energy Power (In Chinese) 2008;23: 191-194.
57. 2 using ammonia scrubbing. Proceedings of the 6th International Symposium on Coal Combustion, 2007, p.767-771.
58. Liu F, Wang S, Chen C, Xu X, Experimental research of CO2 removal by ammonia solutions from flue gas of coal-fired power plant. Proceedings of the 6th International Symposium on Coal Combustion; 2007: 727-731.
59. Zeng Q, Guo YC, Niu ZQ. Experimental studies on removal capacity of carbon dioxide by a packed reactor and a spray column using aqueous ammonia. Energy Procedia 2011;4:519-524.