About The Journal
  Aims and Scope
  Editorial Board
  Submit a Manuscript 
  Subscription Information
  Guidelines for Publication
  Ethics
Articles & Issues
  Search
  Issue
  Online First
  KJChE on
For Authors
  Instructions to Authors
  Ethical Responsibilities of
  Authors in KJChE
  Ethics in Publishing
  Peer Review Process
  Author's Checklist
  Copyright Transfer Form
Contact us
 
 
 
Issue
Korean Journal of Chemical Engineering,
Vol.29, No.4, 478-482, 2012
Influence of operating temperature on CO2-NH3 reaction in an aqueous solution
Choi BG, Kim GH, Yi KB, Kim JN, Hong WH
Although aqueous ammonia solution has been focused on the removal of CO2 from flue gas, there have been very few reports regarding the underlying analysis of the reaction between CO2 and NH3. In this work, we explored the reaction of CO2-NH3-H2O system at various operating temperatures: 40℃ , 20℃ , and 5℃ . The CO2 removal efficiency and the loss of ammonia were influenced by the operating temperatures. Also, infrared spectroscopy measurement was used in order to understand the formation mechanism of ion species in absorbent, such as NH2COO6(-), HCO3^(-), CO32^(-), and NH4+, during CO2, NH3, and H2O reaction. The reactions of CO2-NH3-H2O system at 20 ℃ and 40 ℃ have similar reaction routes. However, a different reaction route was observed at 5 ℃ compared to the other operating temperatures, showing the solid products of ammonium bicarbonates, relatively. The CO2 removal efficiency and the formation of carbamate and bicarbonate were strongly influenced by the operating temperatures. In particular, the analysis of the formation carbamate and bicarbonate by infrared spectroscopy measurement provides useful information on the reaction mechanism of CO2 in an aqueous ammonia solution.
Keywords: Ammonia Solution; CO2 Capture; Operating Temperature; Ammonia Loss; FT-IR
[References]
  1. Yeh AC, Bai H, Sci. Total Environ., 228, 121, 1999
  2. Bonenfant D, Mimeault M, Hausler R, Ind. Eng. Chem. Res., 42(14), 3179, 2003
  3. Bai HL, Yeh AC, Ind. Eng. Chem. Res., 36(6), 2490, 1997
  4. Huang HP, Chang SG, Dorchak T, Energy Fuels, 16(4), 904, 2002
  5. Lee BD, Kim DM, Cho J, Park SW, Korean J. Chem. Eng., 22, 818, 2009
  6. Seo Y, Jo SH, Ryu HJ, Bae DH, Ryu CK, Yi CK, Korean J. Chem. Eng., 24(3), 457, 2007
  7. Lee DH, Choi WJ, Moon SJ, Ha SH, Kim IG, Oh KJ, Korean J. Chem. Eng., 25(2), 279, 2008
  8. Kim YJ, You JK, Hong WH, Yi KB, Ko CH, Kim JN, Sep. Sci. Technol., 43(4), 766, 2008
  9. Yeh JT, Resnik KP, Rygle K, Pennline HW, Fuel Process. Technol., 86(14-15), 1533, 2005
  10. Kozak F, Petig A, Morris E, Rhudy R, Thimsen D, Energy Procedia., 1, 1419, 2009
  11. Pilot scale of CO2 capture, www.powerspan.com.
  12. Park H, Jung YM, You JK, Hong WH, Kim JN, J. Phys. Chem. A, 112(29), 6558, 2008
  13. You JK, Park H, Yang SH, Hong WH, Shin W, Kang JK, Yi KB, Kim JN, J. Phys. Chem. B, 112(14), 4323, 2008
  14. Park SY, Yi KB, Ko CH, Park JH, Kim JN, Hong WH, Energy Fuels., 24, 3704, 2010
  15. Li XN, Hagaman E, Tsouris C, Lee JW, Energy Fuels, 17(1), 69, 2003
  16. Meng L, Burris S, Bui H, Pan WP, Anal. Chem., 77, 5947, 2005
  17. Mani F, Peruzzini M, Stoppioni P, Green Chem., 8, 995, 2006
  18. Guennoun Z, Pietri N, Couturier-Tamburelli I, Aycard JP, J. Phys. Chem. A, 110(24), 7738, 2006
  19. Khanna RK, Moore MH, Spectrochim. Acta A., 55, 961, 1999
  20. Wen NP, Brooker MH, J. Phys. Chem., 99(1), 359, 1995
  21. Hisatsune IC, Can. J. Chem., 62, 945, 1984
[Cited By]
  1. Kang MK, Jeon SB, Lee MH, Oh KJ, Korean Journal of Chemical Engineering, 30(6), 1171, 2013
  2. Zhang M, Guo Y, Korean Journal of Chemical Engineering, 32(8), 1477, 2015
참고문헌정보(참고문헌, 인용문헌)는 화학공학소재연구정보센터에 의해 제공되고 있습니다.