화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Korean Chemical Engineering Research, Vol.48, No.2, 140-146, April, 2010
Export Citation
건식흡수제 이용 연소배가스 이산화탄소 포집기술
Advances of Post-combustion Carbon Capture Technology by Dry Sorbent
이창근
  • 한국에너지기술연구원 기후변화기술연구본부, 305-343 대전시 유성구 장동 71-2
Chang-Keun Yi
  • Climate Change Technology Research Division, Korea Institute of Energy Research, 71-2 Jangdong, Yuseong-gu, Daejeon 305-343, Korea
E-mail:
초록
이산화탄소 포집기술 중 건식흡수제를 이용한 연소 후 이산화탄소 포집기술에 대하여 최신기술개발 현황에 대하여 자세히 기술하였다. CO2 포집에 있어서 건식흡수제 이용 기술의 장점으로는 조업온도의 폭이 크고, 에너지손실이 적으며, 폐수발생이 없고, 부식성이 적으며, 고체폐기물의 상대적인 천연성을 들 수 있다. 현재 한국과 미국에서는 건식 흡수제의 성능 개선과 더불어 실제 연소배가스로부터 CO2 포집을 위한 공정 개발을 통해 포집비용을 줄이려는 연구가 지속적으로 이루어지고 있다. 건식흡수제는 가격이 싼 알칼리금속 계열의 화학흡수제, 아민을 실리카 지지체에 고정시킨 흡수제, 아민을 실리카 지지체에 공유결합시킨 흡수제, 기공성의 탄소에 아민의 기능성을 첨가시킨 흡수제, 아민고정 고분자지지체 흡수제, 금속유기구조체등의 연구가 이루어지고 있다. 포집비용을 대폭 줄이기 위하여 소재에 있어서도 혁신적인 성능 개선이 필요한 시점이다.
This paper addresses recent status and trends of carbon dioxide capture technologies using dry sorbents in the flue gas. The advantages of dry sorbent CO2 capture technology are broader operating temperature range, less energy loss, less waste water, less corrosion problem, and natural properties of solid wastes. Recently, U.S.A. and Korea have been developing processes capturing CO2 from real coal flue gas as well as sorbents improving sorption capacity to decrease total CO2 capture cost.. New class of dry sorbents have been developed such as chemisorbents with alkali metals of which material cost is low, amines physically adsorbed on silica supports, amines covalently tethered to the silica support, carbon-supported amines, polymer-supported amines, amine-containing solid organic resins and metal-organic framework. The breakthrough is needed in the materials on dry sorbents to decrease capture cost.
Keywords:Dry Sorbent;CO2 Capture;Post-Combustion;Carbon Capture & Storage;CCS
  1. Intergovernmental Panel on Climate Change “Special Report on Carbon Dioxide Capture and Storage : Summary for Policy Makers", www.ipcc.ca (2005)
  2. White C, Strazisar BR, Granite EV, Koffman JS, Pennline HW, J. Air Waste Manage. Assoc., 53, 645 (2003)
  3. Harrison DP, “The Role of Solids in CO2 Capture: a Mini Review,” Proceedings of the 7th International Conference on Greenhouse Gas Control Technologies Vancouver, Canada 1101-1106 (2004)
  4. Nelson T, Coleman L, Green D, Gupta R, “The Dry Carbonate Process: Carbon dioxide recovery from power plant flue gas,” 9th Int. Conf. on Greenhouse Gas Control Technology, http://mit.edu/ghgt9/ (2008)
  5. Nelson T, Coleman L, Green D, Gupta R, “The Dry Carbonate Process: Carbon Dioxide Recovery from Power Plant Flue Gas,” 7th Annual Conference on Carbon Capture & Sequestration, May, Pittsburgh, USA (2008)
  6. Yi CK, Jo SH, Seo YW, Moon KH, Yoo JS, Stud. Surf. Sci. Catal., 159, 501 (2006)
  7. Yi CK, Jo SH, Seo Y, J. Chem. Eng. Jpn., 41(7), 691 (2008)
  8. Seo YW, Jo SH, Ryu CK, Yi CK, Chemosphere, 69, 712 (2007)
  9. Seo YW, Jo SH, Ryu CK, Yi CK, J. Environ. Eng., 135, 473 (2009)
  10. Park YC, Jo SH, Park KW, Park YS, Yi CK, Korean J. Chem. Eng., 26(3), 874 (2009)
  11. Park KW, Park YS, Park YC, Jo SH, Yi CK, Korean Chem. Eng. Res., 47(3), 349 (2009)
  12. Yi CK, Jo SH, Seo YW, Lee JB, Ryu CK, Int. J. Greenhouse. Gas. Control., 1, 31 (2007)
  13. Ryu CK, Lee J, Eom TH, Baek JI, Eom HM, Yi CK, “CO2 Capture from Flue Gas using Dry Regenerable Sorbents," 8th International Conference on Green House Gas Control Technology Trondheim, Norway, CD-Rom (2006)
  14. Lee JB, Ryu CK, Baek JI, Lee JH, Eom TH, Kim SH, Ind. Eng. Chem. Res., 47(13), 4465 (2008)
  15. Lee SC, Kim JC, Catalysis Surveys from Asia, 11, 171 (2007)
  16. Lee SC, Chae HJ, Lee SJ, Park YH, Ryu CK, Yi CK, Kim JC, J. Mol. Catal. B-Enzym., 56, 179 (2009)
  17. Lee SC, Choi BY, Lee TJ, Ryu CK, Soo YS, Kim JC, Catal. Today, 111(3-4), 385 (2006)
  18. Lee SC, Chae HJ, Lee SJ, Choi BY, Yi CK, Lee JB, Ryu CK, Kim JC, Environ. Sci. Technol., 42, 2736 (2008)
  19. http://www.netl.doe.gov/technologies/carbon_seq/refshelf/project%20portfolio/2007/2007Roadmap.pdf.
  20. http://www.fe.doe.gov.
  21. Figueroa J, Fout T, Plasynski S, McIlvried H, Srivastava R, Int. J. Greenhouse. Gas. Control., 2, 9 (2008)
  22. Choi S, Drese JH, Jones CW, Chem Sus Chem, 2, 796 (2009)
  23. Przepiorski J, Skrodzewicz M, Morawski AW, Appl. Surf. Sci., 225(1-4), 235 (2004)
  24. Pevida C, Plaza MG, Arias B, Fermoso J, Rubiera F, Pis JJ, “Nitrogen Enriched Solid Sorbents for CO2 Capture,” 2007 International Conference on Coal Science and Technology, paper 7C4, 6 Aug. London (2007)
  25. Veawab A, Tontiwachwuthikul P, Chakma A, Ind. Eng. Chem. Res., 38(10), 3917 (1999)
  26. Satyapal S, Filburn T, Trela J, Strange J, Energy Fuels, 15(2), 250 (2001)
  27. Birbara PJ, Filburn TP, Nalette TA, US Patent No. 5,876,488 (1999)
  28. Birbara PJ, Nalette TA, US Patent 5,492,683 (1996)
  29. Xu XC, Song CS, Andresen JM, Miller BG, Scaroni AW, Energy Fuels, 16(6), 1463 (2002)
  30. Ma X, Wang X, Song C, “The Second Generation of Nano-Porous “Molecular-Basket” Sorbents for CO2 Capture from Flue Gas,” The 25th Annual International Pittsburgh Coal Conference, Pittsburgh, PA (2008)
  31. Son WJ, Choi JS, Ahn HS, Microporous Mesoporous Mater., 113, 31 (2008)
  32. Plaza MG, Pevida C, Arenillas A, Rubiera F, Pis JJ, Fuel, 86, 22042212 (2007)
  33. Gray ML, Soong Y, Champagne KJ, Baltrus J, Stevens RW, Toochinda P, Chuang SSC, Sep. Purif. Technol., 35(1), 31 (2004)
  34. Maroto-Valer MM, Tang Z, Zhang YZ, Fuel Process. Technol., 86(14-15), 1487 (2005)
  35. Maroto-Valer MM, Lu Z, Tang Z, Zhang Y, Waste Management, 28, 2320 (2008)
  36. Dillon EP, Crouse CA, Barron AR, ACS Nano, 2, 156 (2008)
  37. Siriwardane R, Robinson C, Stevens R Jr., “Solid Sorbents for CO2 Capture from Post-Combustion and Pre-Combustion Gas Streams,” 2007 International Conf. on Coal Science and Technology, 8C4, 7 CD-Rom, Aug., London (2007)
  38. Gray ML, Champagne KJ, Fauth D, Baltrus JP, Pennline H, Int. J. Greenhouse Gas Control, 2, 3 (2008)
  39. Drage TC, Arenillas A, Smith KM, Pevida C, Piippo S, Snape CE, Fuel, 86, 22 (2007)
  40. Arenillas A, Drage TC, Smith K, Snape CE, J. Anal. Appl. Pyrolysis., 74, 298 (2005)
  41. Li H, Eddaoudi M, O’keeffe M, Yaghi OM, Nature, 402, 276 (1999)
  42. Eddaoudi M, Kim J, Rosi N, Vodak D, Wachter J, O’keeffe M, Yaghi OM, Science, 295, 469 (2002)
  43. Millward AR, Yaghi OM, J. Am. Chem. Soc., 127(51), 17998 (2005)
  44. Arstad B, Fjellvag H, Kongshaug KO, Swang O, Blom R, Adsorption, 14, 755 (2008)
  45. Abanades JC, Rubin ES, Anthony EJ, Ind. Eng. Chem. Res., 43(13), 3462 (2004)
  46. Abanades JC, Grasa G, Alonso M, Rodriguez N, Anthony EJ, Romeo LM, Environ. Sci. Technol., 41, 5523 (2007)
  47. Chang ACC, Chuang SSC, Gray M, Soong Y, Energy Fuels, 17(2), 468 (2003)
  48. Leal O, Bolivar C, Ovalles C, Garcia J, Espidel Y, Inorg. Chimica. Acta, 240, 183 (1995)
  49. Siriwardane RV, Shen MS, Fisher EP, Poston JA, Energy Fuels, 15(2), 279 (2001)
  50. Siriwardane RV, Shen MS, Fisher EP, Energy Fuels, 17(3), 571 (2003)
  51. Siriwardane RV, Shen MS, Fisher EP, Energy Fuels, 19(3), 1153 (2005)
  52. Siriwardane RV, Robinson C, Shen M, Simonyi T, Energy Fuels, 21(4), 2088 (2007)
  53. Birbara PJ, Filburn TP, Harvey MH, Nalette TA, 2006. US Patent 6,364,938.
  54. Liang Y, Harrison DP, Gupta RP, Green DA, McMichael WJ, Energy Fuels, 18(2), 569 (2004)