Continuous cooling crystallization kinetics of a molten blast furnace slag

“…Kashiwaya et al found that the slags began crystallize less than 10 s from 1 000 to 1 300°C. 17) While merwinite, gehlenite and akermanite were found to be the main phases of the blast furnace slags under both continuous cooing method and quenching method, [18][19][20] which was similar to the results of the present work. Figure 12 shows the SEM pictures of lump ore L-2, sinter S-1 and integrated burden B after continuous cooling.…”

Influence of High Temperature Interaction between Sinter and Lump Ores on the Formation Behavior of Primary-slags in Blast Furnace

“…Kashiwaya et al found that the slags began crystallize less than 10 s from 1 000 to 1 300°C. 17) While merwinite, gehlenite and akermanite were found to be the main phases of the blast furnace slags under both continuous cooing method and quenching method, [18][19][20] which was similar to the results of the present work. Figure 12 shows the SEM pictures of lump ore L-2, sinter S-1 and integrated burden B after continuous cooling.…”

Influence of High Temperature Interaction between Sinter and Lump Ores on the Formation Behavior of Primary-slags in Blast Furnace

“…The expression can be written in the form ln ½À ln ð1 À XÞ ¼ n ln t þ ln K which allows the determination of the constants n and K from a plot of ln [Àln(1 À X)] vs ln t. If the system follows the Avrami equation, it will yield a straight line with gradient n and intercept ln (K). Different values of n represent different crystallization mechanisms, which has been described in previous studies [10].…”

“…But more quantitative methods developed for study of other types of slags with similar composition can also be applied. DTA or DSC is a useful method to study crystallization characteristics and has been widely applied to other kinds of slag under continuous cooling rates [7][8][9][10]. But both DSC and the quenching method are limited in that they do not allow direct observation of the crystallization process.…”

Influence of isothermal temperature and cooling rates on crystallization characteristics of a synthetic coal slag

“…The isothermal kinetics of crystallization are calculated by well-known JMA (Johnson-Mehl-Avrami) equation [29][30][31][32] which can be described as [33] XðtÞ ¼ 1 À expðÀKt n Þ where X is the crystal volume fraction or degree of crystallization; n is Avrami parameter representing mechanisms of crystal growth; t is time and K is a coefficient corresponding to the nucleation and growth mechanism. The expression can be rearranged as ln½À lnð1 À XÞ ¼ n ln t þ ln K Which allows the determination of the constants n and k from a plot of ln[ln(À(1 À X)] vs ln t. If the system follows the Avrami equation, it will yield a straight line with gradient n and intercept ln K. Different mechanisms represented by n are described elsewhere [34].…”

Influence of SiO2/Al2O3 on crystallization characteristics of synthetic coal slags