HEAT TRANSFER ANALYSIS ON ELECTRIC ARC FURNACE REFRACTORY LINING USING COMPUTATIONAL FLUID DYNAMICS
The processing of nickel ore and iron ore in Indonesia mostly used pyrometallurgical process to produce nickel and steel. Production of nickel and steel use electric arc furnaces requires a large amount of energy. The smelting process in an electric arc furnace occur at high temperature so it req...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/69397 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The processing of nickel ore and iron ore in Indonesia mostly used
pyrometallurgical process to produce nickel and steel. Production of nickel and
steel use electric arc furnaces requires a large amount of energy. The smelting
process in an electric arc furnace occur at high temperature so it requires refractory
materials. Refractory materials have good refractoriness and resist from chemical
reactions at high temperature. Refractory material contacts with slag and occur
degradation. In this study, heat transfer simulation uses computational fluid
cdynamics to determine refractory material and degradation of refractory lining, so
heat transfer process would not damage steel layer. Heat transfer simulation was
carried out by an electric arc furnace to obtain temperature profile and temperature
distribution on refractory lining.
Simulation use ANSYS Fluent. The geometry used an electric furnace with 7 m
high, inner, and outer diameters are 17.66 m and 18 m, respectively. Refractory
material use magnesia, chrome alumina, high alumina, and fireclay. The boundary
conditions are fixed temperature on inner wall surface, convection, and radiation at
outer wall temperature reach 30°C. Simulations were carried out on magnesia,
alumina chrome, and highalumina materials at slag refractory interface. Simulation
with variation refractory degradation are 46 mm, 68 mm, and 100 mm degradation
at refractory slag interface. The results of this simulation will obtain temperature
profile and temperature distribution on refractory lining and determine maximum
limit of refractory degradation.
Heat transfer on variation material, magnesia material can reduce temperature
refractory lining higher than other material. Magnesia material conduct heat at
distance 9.605 m to temperature 317.1 K, while alumina chrome material reach
temperature of 420.2 K, and highalumina material reach temperature of 477.4 K.
Simulation of degradation refractory, temperature at position x=9.5 m is 529 K on
100 mm refractory degradation. The maximum temperature for operation on steel
layer is around 250 °C (523 K). Based on the simulation results, the refractory
magnesia material has high performance and the maximum limit for degradation
refractory lining is 100 mm. |
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