Impact of steel ladle preheating on the decarburization of a MgO-C refractory lining
Research output: Thesis › Doctoral Thesis
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2015.
Research output: Thesis › Doctoral Thesis
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TY - BOOK
T1 - Impact of steel ladle preheating on the decarburization of a MgO-C refractory lining
AU - Drozd-Rys, Magdalena
N1 - no embargo
PY - 2015
Y1 - 2015
N2 - Steel ladles are lined with a variety of refractories including shaped and unshaped, basic and non-basic materials. In many cases magnesia carbon bricks are applied to the slag area as they show an excellent corrosion resistance. The disadvantage of magnesia carbon refractories is their limited oxidation resistance. Steel ladles need to be preheated to avoid thermal shock damage to the refractory lining. During preheating up to the temperature of 1000 °C a considerable oxygen content in the exhaust gas favors carbon burnout in MgO-C refractories at elevated temperatures and thereby, negatively influences their initial corrosion and erosion resistance. The aim of this thesis was to analyze the impact of steel ladle preheating on possible decarburization of MgO-C refractories. This was done by establishing a kinetic model for carbon burnout in MgO-C refractories and experimentally evaluating it at laboratory scale. Further, a computational fluid dynamics (CFD) simulation of ladle preheating was executed to obtain the necessary process data. With the help of the proposed kinetic model and applying simulated process data the decarburization depth in MgO-C refractory during ladle preheating was calculated for various material types.
AB - Steel ladles are lined with a variety of refractories including shaped and unshaped, basic and non-basic materials. In many cases magnesia carbon bricks are applied to the slag area as they show an excellent corrosion resistance. The disadvantage of magnesia carbon refractories is their limited oxidation resistance. Steel ladles need to be preheated to avoid thermal shock damage to the refractory lining. During preheating up to the temperature of 1000 °C a considerable oxygen content in the exhaust gas favors carbon burnout in MgO-C refractories at elevated temperatures and thereby, negatively influences their initial corrosion and erosion resistance. The aim of this thesis was to analyze the impact of steel ladle preheating on possible decarburization of MgO-C refractories. This was done by establishing a kinetic model for carbon burnout in MgO-C refractories and experimentally evaluating it at laboratory scale. Further, a computational fluid dynamics (CFD) simulation of ladle preheating was executed to obtain the necessary process data. With the help of the proposed kinetic model and applying simulated process data the decarburization depth in MgO-C refractory during ladle preheating was calculated for various material types.
KW - Magnesia-carbon bricks
KW - refractories
KW - CFD
KW - carbon burnout
KW - Magnesiacarbonstein
KW - CFD Simulation
KW - Feuerfestmaterial
KW - Kohlenstoffausbrand
M3 - Doctoral Thesis
ER -