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Możliwości zastosowania popiołów lotnych ze spalania węgla kamiennego w kotłach wodnych do sekwestracji CO2 na drodze mineralnej karbonatyzacji

Treść / Zawartość
Identyfikatory
Warianty tytułu
EN
Application of fly ash from hard coal combustion in water boilers for CO2 sequestration via mineral carbonation
Języki publikacji
PL
Abstrakty
EN
CO2 sequestration via mineral carbonation is one of the reduction methods of anthropogenic emission of CO2. It is based on permanent, and at the same time, ecologically safe CO2 bonding through mineral resources or waste. For CO2 bonding there may be used the alkaline mineral waste, f.ex: fly ash, originating from professional power industry plants - the greatest source of anthropogenic emission of CO2 in Poland. In the article there have been presented the results of examination of carbonation extent for ash aqueous suspension, prepared on the basis of fly ash from hard coal combustion. The findings on carbon dioxide absorption through fresh ash aqueous suspension have been shown, as well as the extent of its bonding in the hardened suspensions. On the basis of thermogravimetric analyses supplemented with phase composition examinations with the use of roentgenographic method and microstructure examinations with the use of a scanning microscope. There has been carried out an analysis of the impact of carbon dioxide insertion on the leachability of the ions: Cl-, SO4, As, total Cr, Cd, Cu, Pb, Hg, S (sulphide), on the basis of results of leachability examinations from ash suspension with water before and after CO2 insertion, as well as the influence of carbon dioxide insertion on pH of leachates and the chemical oxygen demand (COD). It was affirmed as the result of thermogravimetric investigations of ash-water suspension without introduction of CO2, content of CaCO3 was 0.75 %, and in suspensions with introduced CO2, content of CaCO3 was 2.27% [24], which confirms that processes of mineral carbonation takes place. Investigations of leachability showed increased concentration of Zn and the content of chlorides and sulfates in suspensions with introduced CO2. Concentration of determined elements in extracts of ash-water suspensions "clean" and with the addition of CO2 fulfilled standards of PN-G-11011. Sequestration of CO2 via mineral carbonation is an interesting option of limitation of anthropogenic emission of CO2. Use of wastes for bonding CO2 seems particularly interesting. In case of Poland, where production of electric and thermal energy in plants of professional energetics is based on coal incineration, the waste which used for bonding CO2 is produced in large quantities fly ash.
Rocznik
Tom
Strony
567--574
Opis fizyczny
Bibliogr. 25 poz.
Twórcy
  • Instytut Gospodarki Surowcami Mineralnymi i Energią PAN, Kraków
Bibliografia
  • 1. Baciocchi R., Polettini A., Pomi R., Prigiobbe V., Zedwitz-Nikulshyna, Steinfeld A.: Performance and kinetics of CO2 sequestration by direct gas-solid carbonation of APC residues. Proceedings Materials of 8th International Conference on Greenhouse Gas Control Technologies. Trondheim, Norway, 2006.
  • 2. Back M., Vosbeck K., Kühn M., Stanjek H., Clauser Ch., Peiffer S.: Pretreament of CO2 with fly ashes to generate alkalinity for subsurface sequestration. Proceedings Materials of 8th International Conference on Greenhouse Gas Control Technologies. Trondheim, Norway, 2006a.
  • 3. Back M., Vosbeck K., Kühn M., Stanjek H., Clauser Ch., Peiffer S.: Storage of CO2 and generation of alkalinity from reaction of alkaline fly ashes with flue gas. Proceedings Materials of 8th International Conference on Greenhouse Gas Control Technologies. Trondheim, Norway, 2006b.
  • 4. Costa G., Baciocchi R., Polettini A., Pomi R., Hills C.D., Carey P.J.: Current status and perspectives of accelerated carbonation processes on municipal waste combustion residues. Environm. Monit. Assess., 135, p. 55-75, 2007.
  • 5. Fauth J.D., Soong Y., White C.M.: Carbon sequestration utilizing industrial solid residues. Preprints Symposium, American Chemical Society, Division Fuel Chemistry, p. 37-28, 2002.
  • 6. Huijgen W.J.J., Comans R.N.J.: Carbon dioxide sequestration by mineral carboantion. ECN. ECN-C-03-016, www.ecn.nl, 2002.
  • 7. Huijgen W.J.J., Comans R.N.J.: Mineral CO2 sequestration by carboantion of industrial residues. ECN. ECN-C-05-074, www.ecn.nl, 2005.
  • 8. IPCC Special Report on Carbon Dioxide Capture and Storage, part 7. Mineral Carbonation and Industrial uses of Carbon Dioxide. Coordinating Lead Author: Marco Mazzotti, 2005.
  • 9. Johnson D.C.: Accelerated carbonation of waste calcium silicate materials. SCI Lecture Papers Series, Society of Chemical Industry, ISSN 1353-114X, 2000.
  • 10. Lackner K.S., Wendt C.H., Butt D.P., Joyce L.E., Sharp D.H.: Carbon dioxide disposal in carbonate minerals. Energy, Vol. 20, No 11, p. 1153-1170, 1995.
  • 11. Mazurkiewicz M., Piotrowski M., Pomykała R.: The proposition of CO2 gas disposal. Twenty-First Annual International Pittsburgh Coal Conference. Osaka, 2004.
  • 12. Meima J.A., Comans R.N.J.: Geochemical modeling of weathering reactions in municipal solid waste incinerator bottom ash. Environment Science and Technology 31, p. 1269-1276, 1997.
  • 13. Meima J.A., van der Weijden R., Eighmy T.T., Comans R.N.J.: Carbonation in municipal solid waste incinerator bottom ash and their effect on leaching of copper and molybdenum. Applied Geochemistry 17, p. 1503-1513, 2002.
  • 14. Reddy K.J., Drever J.I., Hasfurther V.R.: Reaction of CO2 with alkaline solid wastes to reduce contaminant mobility. Water Research 28/6, p. 1377-1382, 1994.
  • 15. Rendek E., Ducom G., Germain P.: Carbon dioxide sequestration in municipal solid waste incinerator (MSWI) bottom ash. Journal of Hazardous Materials B128, p. 73-79, 2006.
  • 16. Seifritz W.: CO2 disposal by means of silicates. Nature 345, 486, 1990.
  • 17. Soong Y., Fauth D.L., Howard B.H., Jones J.R., Harrison D.K., Goodman A.I., Gray M.L., Fromell E.A.: CO2 sequestration with brine solution and fly ashes. Energy Conversion and Management 47, p. 1676-1685, 2006.
  • 18. Todorovic J., Ecke H.: Demobilisation of critical contaminants in four typical waste-to-energy ashes by carbonation. Waste Management 26, p. 430-441, 2006.
  • 19. Uliasz-Bocheńczyk A., Mokrzycki E.: Fly Ashes from Polish Power Plants and Combined Heat and Power Plants and Conditions of their Application for Carbon Dioxide Utilization. Chemical Engineering Research and Design, 84(A9, 837-842), 2006.
  • 20. Uliasz-Bocheńczyk A., Mokrzycki E., Mazurkiewicz M., Piotrowski Z.: Utylizacja dwutlenku węgla poprzez mineralną karbonatyzację. Polityka Energetyczna t.7, zeszyt specjalny, s. 541-554, 2004.
  • 21. Uliasz-Bocheńczyk A., Mokrzycki E., Mazurkiewicz M., Piotrowski Z.: Utilization of carbon dioxide in fly ash and water mixtures. Chemical Engineering Research and Design 84(A9, p. 843-846), 2006.
  • 22. Uliasz-Bocheńczyk A., Mokrzycki E., Piotrowski Z., Pomykała R.: Składowanie CO2 z zawiesinami popiołowo-wodnymi pod ziemią. Wyd. IGSMiE PAN, Kraków, 2007.
  • 23. Uliasz-Bocheńczyk A.: Waste used for CO2 bonding via mineral carbonation. Gospodarka Surowcami Mineralnymi, vol. 23(4), s. 121-129, 2007.
  • 24. Wacławska I.: Badania ilości związanego CO2 w zawiesinach popiołowowodnych. Arch. IGSMiE PAN, Kraków, 2007.
  • 25. www.netl.doe.gov
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BPW8-0009-0040
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