THERMODYNAMIC SIMULATION AND LABORATORY-SCALE EXPERIMENTS OF TIN SMELTING AT AL2O3 SATURATION
The global demand for tin is projected to continue its upward trajectory, driven by its wide range of applications across various industrial sectors, from minor components to crucial elements that are essential for the advancement of modern technologies. In Indonesia, established tin smelting tec...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/85218 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The global demand for tin is projected to continue its upward trajectory, driven by
its wide range of applications across various industrial sectors, from minor
components to crucial elements that are essential for the advancement of modern
technologies. In Indonesia, established tin smelting technologies currently in use
include the reverberatory furnace and the top submerged lance (TSL) furnace. A
significant issue encountered in tin smelting operations is the corrosion of
refractory materials that comes into direct contact with the molten slag. Magnesiabased
refractories are commonly used. Magnesia-based refractories offer several
advantages, including excellent mechanical properties and durability at high
temperatures, good thermal efficiency, resistance to basic slag attacks, and lower
costs compared to alumina-based refractories. However, these refractories have
limitations in acidic slag environments and exhibit high thermal expansion, which
can lead to the formation of gaps and cracks, thereby degrading the refractory
lining. Otherwise, alumina-based refractories emerge as a promising alternative,
particularly when dealing with the unpredictable slag compositions, owing to
alumina's amphoteric characteristics. Nevertheless, prolonged interaction with
aggressive slag can lead to substantial degradation of the refractory material.
Therefore, this study aims to evaluate the feasibility of employing alumina
refractories in tin smelting processes.
A series of thermodynamic simulations and laboratory-scale experiments were
conducted. The FactSage 8.2 software was employed to simulate the solubility of
Al2O3 in slag and the ratio of %Sn in slag to %Sn in metal (L) during the smelting
and reduction stages in the TSL furnace technology. The parameters examined
included Fe/SiO2 (0.3 – 1.6), CaO/SiO2 (0.3 – 1.6), %Sn in slag (3 – 20%), and
temperature (1100 – 1600°C). Subsequently, laboratory-scale experiments were
carried out to validate the simulation results. The experiments utilized synthetic
slag composed of SnO-FeO-CaO-SiO2-Al2O3, conducted in a vertical tube furnace
at a temperature of 1300°C for 2 hours. The experimental parameters varied
included Fe/SiO2 (0.3 – 1.6), CaO/SiO2 (0.3 – 1.6), and %Sn in slag (3 – 20%). The
resulting smelting samples were analyzed using Scanning Electron Microscope –
Energy Dispersive Spectroscopy (SEM-EDS) to determine the solubility of Al2O3 in
the slag, the ratio of %Sn in slag to %Sn in metal, and the potential phases formed
during high-temperature smelting.
The simulation results revealed that the solubility of Al2O3 during the smelting and
reduction stages is significantly influenced by temperature, Fe/SiO2, and CaO/SiO2,
whereas the ratio of %Sn in slag to %Sn in metal (L) appears to be independent of
these variables, being primarily influenced by the %Sn in the slag. Experimental
results at 1300°C with varying Fe/SiO2 ratios in the range of 0.3 to 1.6, lower
Fe/SiO2 ratio leads to an increase in Al2O3 solubility in the slag, accompanied by
the formation of anorthite (CaAl2Si2O8). In contrast, a higher Fe/SiO2 ratio results
in a decrease in Al2O3 solubility, accompanied by the formation of spinel (FeAl2O4).
A similar trend occurs in experiments varying the CaO/SiO2 ratio within the same
range. Initially, Al2O3 solubility increases, accompanied by the formation of spinel
(FeAl2O4). Subsequently, as the CaO/SiO2 ratio increases, Al2O3 solubility
decreases, and a new solid phase, melilite ((Ca,Na)2(Al,Mg,Fe2+)(Si,Al)2O7),
forms. These solid phases can form within the slag matrix or at the slag-crucible
interface. The formation of solid phases at the slag-crucible interface is effective in
preventing further penetration of molten slag into the crucible lining, as a
protective layer composed of solid phases generated through slag-crucible
interactions during high-temperature smelting processes. Moreover, under
constant CaO/SiO2 and Fe/SiO2 ratios of 0.3, reducing the %Sn within the slag was
found to increase the solubility of Al2O3, due to the creation of a more aggressive
slag towards Al2O3 crucibles. |
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