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Effect of the Basicity on the Crystallization Behavior of Titanium Bearing Blast Furnace Slag
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AbstractBasicity of titanium bearing blast furnace (BF) slag is critical for its crystallization behavior. Thermodynamics calculation indicates that rutile is the main phase after crystallization (or at room temperature). It precipitates during the cooling when the basicity of the slag is lower than 0.7. With increasing basicity, perovskite appears and becomes the main phase instead which contains titanium. Crystallization temperature of perovskite is higher than that of rutile and the other phases. Namely, perovskite crystallizes firstly from the molten slag during decreasing temperature. XRD analysis shows that CaTi21O38 is the main phase with a basicity of 0.6. CaMg0.39Al0.87Ti0.48Si1.26O6, CaTiSiO5 and CaMgSi2O6 are the main crystallization phases with a basicity of 0.8. The difference between experimental and thermodynamics calculation is due to the complicate crystallization behavior of the multiple slag under super cooling rate. When the slag basicity increases to 1.1, the main precipitatied phase is perovskite, which agrees well with theory calculation. In addition, the crystal structure of the synthesized titanium bearing slag is basically similar regardless of the basicity.
Walter de Gruyter GmbH
Title: Effect of the Basicity on the Crystallization Behavior of Titanium Bearing Blast Furnace Slag
Description:
AbstractBasicity of titanium bearing blast furnace (BF) slag is critical for its crystallization behavior.
Thermodynamics calculation indicates that rutile is the main phase after crystallization (or at room temperature).
It precipitates during the cooling when the basicity of the slag is lower than 0.
7.
With increasing basicity, perovskite appears and becomes the main phase instead which contains titanium.
Crystallization temperature of perovskite is higher than that of rutile and the other phases.
Namely, perovskite crystallizes firstly from the molten slag during decreasing temperature.
XRD analysis shows that CaTi21O38 is the main phase with a basicity of 0.
6.
CaMg0.
39Al0.
87Ti0.
48Si1.
26O6, CaTiSiO5 and CaMgSi2O6 are the main crystallization phases with a basicity of 0.
8.
The difference between experimental and thermodynamics calculation is due to the complicate crystallization behavior of the multiple slag under super cooling rate.
When the slag basicity increases to 1.
1, the main precipitatied phase is perovskite, which agrees well with theory calculation.
In addition, the crystal structure of the synthesized titanium bearing slag is basically similar regardless of the basicity.
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