1 Jak, E., Hayes, P.C., “Thermodynamic modelling of the coal ash systems in black coal utilization”, In: Proceed-ings of 18th Pittsburgh Coal Conference 2001, Newcastle, Australia ( 2001). 2 Ninomiya, Y., Sato, A., “Ash melting behavior under coal gasification conditions”, Energy Convers. Magmt, 38, 1405—1412(1997). 3 Yamashita, T., Tominaga, H., Asahiro, N., “Modeling of ash formation behavior during pulverized coal combus-tion”, IFRF Combust. J., 8, 1—17(2000). 4 Patterson, J.H., Hurst, H.J., “Ash and slag qualities of Australian bituminous coals for use in slagging gasifiers”, Fuel, 79, 1671—1678( 2000). 5 Skrifvars, B.J., Laurén, T., Hupa, M., Korbee, R., Ljung, P., “Ash behaviour in a pulverized wood fired boiler—A case study ”, Fuel, 83, 1371—1379(2004). 6 Gray, V.R., “Prediction of ash fusion temperature from ash composition for some New Zealand coals”, Fuel, 66, 1230—1239(1987). 7 Kucukbayrak, S., Ersoy, M.A., Haykiri, A.H., Guner, H., Urkan, K., “Investigation of the relation between chemi-cal composition and ash fusion temperatures for some Turkish lignites”, Fuel Sci. Technol. Internat., 11, 1231—1249(1993). 8 Llyod, W.G., Riley, J.T., Zhon, S., Risen, M.A., “Ash fu-sion temperatures under oxidizing conditions”, Energy and Fuels, 7, 490—494(1995). 9 Seggiani, M., “Empirical correlations of the ash fusion temperatures and temperature of critical viscosity for coal and biomass ashes”, Fuel, 78, 1121—1125(1999). 10 Yin, C., Luo, Z., Ni, M., Cen, K., “Predicting coal ash fusion temperature with a back-propagation neural net-work model”, Fuel, 77, 1777—1782(1998). 11 Huggins, F.E., Kosmack, D.A.,Huffman, G.P., “Correla-tion between ash-fusion temperatures and ternary equi-librium phase diagrams”, Fuel, 60, 577—584(1981). 12 Huffman, G.P., Huggins, F.E., Dunmyre, G.R., “Investi-gation of the high temperature behavior of coal ash in reducing and oxidizing atmospheres”, Fuel, 60, 585—597(1981). 13 Goni, C., Helle, S., Garcia, X., Gordon, A., Parra, R., Kelm, U., Jimenez, R., Alfaro, G., “ Coal blend combus-tion: Fusibility ranking from mineral matter composi-tion”, Fuel, 82, 2087—2095(2003). 14 Yan, L., Gupta, R.P., Wall, T.F., “The implication of min-eral coalescence behavior on ash formation and ash deposition during pulverized coal combustion”, Fuel, 80, 1333—1340(2001). 15 Yin, C.G., Luo, Z.Y., Ni, M.J., Cen, K.F., “Predicting coal ash fusion temperature with a back propagation neu-ral network model”, Fuel, 77, 1777—1782(1998). 16 Rhinehart, R.R., Attar, A.A., “Ash fusion temperature: A thermodynamically-based model”, Am. Soc. Mech. Eng., Petroleum Division, 8, 97—101(1987). 17 Kondratiev, A., Jak, E., “Predicting coal ash slag flow characteristics”, Fuel, 80, 1989—2000(2001). 18 Qiu, J.R., Li, F., Zheng, C.G., “Mineral transformation during combustion of coal blends”, Int. J. Energy Res., 23, 453—463(1999). 19 Jak, E., Degterov, S., Zhao, B., Pelton, A. Hayes, P., “Cou-pled experimental and thermodynamic modelling studies for metallurgical smelting and coal combustion systems”, Metal. Trans., 31B, 621—630(2000). 20 Bale, C.W., Chartrand, P., Degterov, S.A., “FactSage thermochemical software and databases”, Calphad, 26, 189—228(2002).
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