EFFECT OF TEMPERATURE PATTERNS ON IRON NUGGET FORMATION OF LATERITE NICKEL ORE LEACHING RESIDUE USING PALM KERNEL SHELL AS REDUCING AGENT
In 2022, global nickel mining production increased by about 20% compared to the previous year. The nickel production through hydrometallurgy process produces leaching residues that are harmful to the environment. On the other hand, leaching residue has an iron content of up to 38.1%. However, the...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/72619 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | In 2022, global nickel mining production increased by about 20% compared to the
previous year. The nickel production through hydrometallurgy process produces
leaching residues that are harmful to the environment. On the other hand, leaching
residue has an iron content of up to 38.1%. However, the high sulfur content in
leaching residue poses a challenge to its use as a raw material for the iron and
steel industry. The palm oil industry in Indonesia has experienced rapid growth
over the last 20 years. The content of fixed carbon in palm kernel shell (PKS) has
potential to be used as a reducing agent in the metal refining process.
A series of experiments were carried out with variations in temperature patterns
and types of briquette used, composite (25% PKS) and non-composite (0% PKS)
briquette. The reduction process was carried out in a muffle furnace with initial
isothermal temperature variations of 1000, 1100, 1200, 1300, and 1450oC. The
temperature was increased to the final isothermal temperature of 1450oC for 60
minutes and held for 30 minutes. The reduction results were analyzed using
ImageJ software to determine the diameter and cross-sectional area of the metal.
Furthermore, the results of the reduction were characterized using a scanning
electron microscope–energy dispersive spectroscopy (SEM-EDS) to determine
chemical composition of the metal and slag.
Based on the experimental results, an increase in the initial isothermal temperature
from 1000 to 1450oC at all temperature patterns affects the increasing average
diameter and average cross-sectional area of the metal from composite and noncomposite
briquette. The increase in initial isothermal temperature also affects the
decrease in iron content and increase in sulfur content in the metal from the
composite and non-composite briquette. Meanwhile, in slag, the higher of the
initial isothermal temperature increases the oxygen content which indicates that
more metal oxides are reduced. In composite briquettes with an initial isothermal
temperature of 1100 to 1450oC, the recovery of iron in the metal decreased. The
highest iron recovery is 98.01% for composite briquettes that were obtained at an
initial isothermal temperature of 1100oC. Furthermore, in non-composite
briquettes with an initial isothermal temperature of 1000 to 1200oC, the recovery
of iron in the metal decreased. While at the initial isothermal temperature of 1200
to 1450oC there is an increase of iron recovery in the metal. The highest iron
recovery is 82.39% for non-composite briquettes that were obtained at an initial
isothermal temperature of 1000oC. |
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