VACUUM REDUCTION OF SAPROLITE NICKEL ORE USING VARIOUS REDUCING AGENT AND CAO AS ADDITIVE AT 1200 C AND 1400 C
Nickel plays a significant role in world development due to its superior physical and chemical properties. Nickel can be extracted from two types of ores, namely lateritic and sulphide ores. The most widely used method for lateritic nickel ore processing, especially the saprolite type, is the rot...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/73894 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Nickel plays a significant role in world development due to its superior physical
and chemical properties. Nickel can be extracted from two types of ores, namely
lateritic and sulphide ores. The most widely used method for lateritic nickel ore
processing, especially the saprolite type, is the rotary kiln-electric furnace (RKEF)
process. The process produces ferronickel and smelting slag which are still rich in
magnesium. This fact along with the increasing demand for magnesium and nickel
drives research to utilize magnesium contained in ferronickel smelting slag and in
the initial ore as well by simultaneously reduce MgO with reduction of nickel and
iron oxides. This research studied the effects of reduction temperature, types of
reductants, and addition of CaO on the vacuum reduction process of saprolite
nickel ore.
Experimental procedure began with preparation and characterization of the
materials used, such as saprolite nickel ore, ferrosilicon, aluminum powder, coal,
CaO, and CaF2. Saprolite nickel ore and CaO are calcined before being mixed
with CaF2 as catalyst and ferrosilicon, aluminum powder, or coal as reducing
agents and then briquetted. The vacuum reduction process was carried out using a
box type vacuum furnace with a non-isothermal temperature method with an
initial temperature of 25°C, increased gradually to 1200°C and 1400°C and then
held for 4 hours and cooled down gradually to room temperature. The vacuum
reduction process was carried out by varying the types of reducing agents, namely
ferrosilicon, aluminum powder, and coal, as well as the mass ratio of saprolite
nickel ore to CaO of 25%:75%, 50%:50%, 75%:25%, and without CaO.
Experiment result shows that increasing the reduction temperature increases
saprolite nickel ore reduction rate and evaporation of magnesium. Samples
reduced by coal produce the greatest change in weight compared to other
reductants which is most likely due to the evaporation of the volatile matter
content in the coal. Increasing the addition of CaO to the sample with ferrosilicon
and aluminum reducing agents increases the change in sample weight. The
experimental results indicate that the calcium tends to displace magnesium from
its bonds with other elements in a phase, thereby facilitating the reduction and
evaporation processes. This is also supported by the presence of calcium-rich
phases which contain relatively fewer magnesium such as dicalcium ferrite,
dicalcium silicate, monoxide with high calcium content, (Ca,Mg)2(Fe,Al)2O5, and
(CaO,FeO)12( Al2O3)7. Experimental results also indicate that aluminum reducers
tend to produce more reductive conditions than other types of reducing agents
when viewed based on their ability to reduce iron oxide. |
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