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Issue
Korean Journal of Chemical Engineering,
Vol.30, No.3, 605-612, 2013
Mineral behavior of low-temperature lignite ashes under gasification atmosphere
Li F, Huang J, Fang Y, Wang Y
To investigate the mineral behavior of lignite ashes under gasification conditions, 450 ℃Xiaolongtan lignite ash samples (XLT-LTA) treated at different temperatures or pressures under reducing atmosphere (H2/CO2=1 : 1, volume ratio) have been examined by means of an SC-444 apparatus, a scanning electron microscope with an energy dispersive X-ray detector (SEM-EDX), and by X-ray diffraction (XRD). The results showed the sulfur content in the XLT-LTA to be much higher than that in ashes prepared at 815 ℃, as a result of the release of sulfur dioxide during the oxidization of pyrite. With increasing temperature, the XLT-LTA particles gradually agglomerate and form partially molten surface entities with obvious apertures, and the content of iron and calcium in the congeries or molten parts increases due to the fusion of fine ash particles with the enrichment of iron and the formation of low-temperature eutectics of calcium and iron. An increase of pressure restrains the decomposition of calcite and muscovite, and promotes the formation of iron minerals (e.g., hercynite, cordierite, and sekaninaite) and orthoclase. The content of amorphous material also increases with increasing pressure.
Keywords: Mineral Behavior; XLT Lignite; Gasification Condition; Temperature; Pressure
[References]
  1. Chadwick BL, Ind. Eng. Chem. Res., 38(3), 1159, 1999
  2. Zhang K, You C, Li Y, Korean J. Chem. Eng., 29(4), 540, 2012
  3. Benson SA, Harb JN, Energy Fuels., 7, 743, 1993
  4. Benson SA, Holm PL, Ind. Eng. Chem. Prod. Res. Dev., 24, 149, 1985
  5. Vassileva CG, Vassilev SV, Fuel Process. Technol., 86(12-13), 1297, 2005
  6. Liu H, Luo CH, Toyota M, Kato S, Uemiya S, Kojima T, Tominaga H, Fuel, 82(5), 523, 2003
  7. Grigore M, Sakurovs R, French D, Sahajwalla V, Int. J. Coal Geol., 75(4), 213, 2008
  8. Bai J, Li W, Li CZ, Bai ZQ, Li BQ, J. Fuel Chem. Technol., 37, 134, 2009
  9. Irfan MF, Usman MR, Kusakabe K, Energy, 36(1), 12, 2011
  10. Skodras G, Sakellaropoulos GP, Fuel Process. Technol., 77-78, 151, 2002
  11. Sun S, Zhang J, Hu X, Qiu P, Qian J, Qin Y, Korean J. Chem.Eng., 28, 554, 2009
  12. Clemens T, Gong D, Pearce S, Int. J. Coal Geol., 65(3-4), 235, 2006
  13. Matsuoka K, Yamashita T, Kuramoto K, Suzuki Y, Takaya A, Tomita A, Fuel, 87(6), 885, 2008
  14. Dahlin RS, Peng WW, Nelson M, Vimalchand P, Liu GH, Energy Fuels, 20(6), 2465, 2006
  15. Dahlin RS, Dorminey JR, Peng WW, Leonard RF, Vimalchand P, Energy Fuels, 23(1), 785, 2009
  16. Skrifvars BJ, Hupa M, Hiltunen M, Ind. Eng. Chem. Res., 31, 1026, 1992
  17. Park HJ, Jung NH, Lee JM, Korean J. Chem. Eng., 28(8), 1791, 2011
  18. Li FH, Huang JJ, Fang YT, Wang Y, Energy Fuels., 25, 273, 2010
  19. Li FH, Huang JJ, Fang YT, Wang Y, Fuel, 90(7), 2377, 2011
  20. Song WJ, Tang LH, Zhu XD, Wu YQ, Rong YQ, Zhu ZB, Koyama S, Fuel, 88(2), 297, 2009
  21. Su S, Pohi JH, Holcombe D, Hart JA, Fuel., 80, 1351, 2001
  22. Li HX, Ninomiya Y, Dong ZB, Zhang MX, Chin. J. Chem. Eng., 14(6), 784, 2006
  23. Bai J, Li W, Li BQ, Fuel, 87(4-5), 583, 2008
  24. Li CY, Zhao JT, Fang YT, Wang Y, Energy Fuels, 23, 5099, 2009
  25. Tomeczek J, Palugniok H, Fuel, 81(10), 1251, 2002
  26. VASSILEV SV, KITANO K, TAKEDA S, TSURUE T, Fuel Process. Technol., 45(1), 27, 1995
  27. Yang JK, Xiao B, Boccaccini AR, Fuel, 88(7), 1275, 2009
  28. Van Dyk JC, Benson SA, Laumb ML, Waanders B, Fuel, 88(6), 1057, 2009
  29. Wu XJ, Zhang ZX, Piao GL, He X, Chen YS, Kobayashi N, Mori S, Itaya Y, Energy Fuels, 23, 2420, 2009
  30. Atakul H, Hilmioglu B, Ekinci E, Fuel Process. Technol., 86(12-13), 1369, 2005
  31. Samaras P, Diamadopoulos E, Sakellaropoulos GP, Fuel., 75, 1108, 1996
  32. Srinivasachar S, Helble JJ, Boni AA, Shah N, Huffman GP, Huggins FE, Prog. Energy Combust. Sci., 16, 293, 1990
  33. Zhou JH, Zhao XH, Yang WJ, Cao XY, Liu JZ, Cen KF, Proc. CSEE., 27, 31, 2007
  34. Wiberg E, Wiberg N, Holleman AF, Inorganic chemistry, Berlin Academic Press Publications, Germany, 2001
  35. Matjie RH, Li ZS, Colin RW, French D, Fuel, 87(6), 857, 2008
  36. Marinov V, Marinov SPL, Lazarov L, Stefanova M, Fuel Process. Technol., 31, 181, 1992
  37. Kondratiev A, Jak E, Fuel., 80, 1989, 2001
  38. Ward CR, French D, Fuel, 85(16), 2268, 2006
[Cited By]
  1. Lee BH, Kim SI, Kim SM, Oh DH, Gupta S, Jeon CH, Korean Journal of Chemical Engineering, 33(1), 147, 2016
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