A Study on the Reaction between MgO Based Refractories and Slag-Towards the Development of Carbon-free Lining Material

A Study on the Reaction between MgO Based Refractories and Slag-Towards the Development of Carbon-free Lining Material

In present thesis, the fundamental studies on the reaction between MgO based refractories and slag were undertaken for the development of a carbon-free bonding MgO lining material. Alumina was selected as a potential binder material. Due to MgO-Al 2 O 3 chemical reaction, the developed refractory wa...

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Bibliographische Detailangaben
1. Verfasser: Wang, Huijun
Format: Dissertation
Sprache:eng
Schlagworte:
carbon-free
clean steel
dissolution mechanism
ladle glaze
lining material
Materials Science and Engineering
MgO refractory
slag penetration
Teknisk materialvetenskap
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Zusammenfassung:In present thesis, the fundamental studies on the reaction between MgO based refractories and slag were undertaken for the development of a carbon-free bonding MgO lining material. Alumina was selected as a potential binder material. Due to MgO-Al 2 O 3 chemical reaction, the developed refractory was bonded by MgO·Al 2 O 3 spinel phase. To begin with, an investigation of the dissolution process of dense MgO and MgO·Al 2 O 3 spinel in liquid slag was carried out. To obtain reliable information for dissolution study, a new experimental method was therefore developed. In this method, a cylinder was rotating centrally in a special designed container with a quatrefoil profile. This method also showed a good reliability in revealing the dissolution mechanism by quenching the whole reaction system. The experimental results showed that the dissolution process of MgO and spinel was controlled by both mass transfer and chemical reaction. It was found that the rapid dissolution of spinel was mainly because of its larger driving force. To improve the resistance against slag penetration, two aspects were studied to develop carbon-free MgO refractory. First, colloidal alumina was used and the effect of its addition into MgO matrix was investigated. The use of colloidal alumina was to form bonding products in the grain boundary of MgO. The results showed that the alumina addition greatly improved the resistance of MgO based refractory against slag penetration in comparison with the decarburized MgO-carbon refractory. It was found that the improvement of resistance was mainly related to the spinel-slag reaction products of CaO·Al 2 O 3 and CaO·MgO·Al 2 O 3 solid phases at the grain boundaries. Second, the effect of particle size distribution on the penetration resistance of MgO was investigated. The most profound improvement against the slag penetration was obtained by using a proper particle size distribution. The results highlighted the importance of considering the refractory structure. Experiments were undertaken to investigate the dissolution mechanism of different types of MgO based refractories in liquid slag. It was observed that the dissolution of spinel bonded MgO refractory was much slower than the decarburized MgO-carbon refractory. The primary dissolution in spinel bonded MgO refractory occurred at the slag-penetrated layer, and the removal of this layer by peeling off enhanced the dissolution rate rapidly.