In situ layer formation on MgO–C refractories with different MgO grade by static and dynamic contact with liquid steel
Florian Kerber,
Tilo Zienert,
Konrad Kerber,
Steffen Dudczig,
Thomas Schemmel,
Helge Jansen,
Christos G. Aneziris
Affiliations
Florian Kerber
Technische Universität Bergakademie Freiberg, Institute of Ceramics, Refractories and Composite Materials, Agricolastraße 17, Freiberg, 09599, Germany; Corresponding author.
Tilo Zienert
Technische Universität Bergakademie Freiberg, Institute of Ceramics, Refractories and Composite Materials, Agricolastraße 17, Freiberg, 09599, Germany
Konrad Kerber
Technische Universität Bergakademie Freiberg, Institute of Materials Engineering, Gustav-Zeuner-Straße 5, Freiberg, 09599, Germany
Steffen Dudczig
Technische Universität Bergakademie Freiberg, Institute of Ceramics, Refractories and Composite Materials, Agricolastraße 17, Freiberg, 09599, Germany
Thomas Schemmel
Refratechnik Steel GmbH, Research and Development, Am Seestern 5, Düsseldorf, 40547, Germany
Helge Jansen
Refratechnik Steel GmbH, Research and Development, Am Seestern 5, Düsseldorf, 40547, Germany
Christos G. Aneziris
Technische Universität Bergakademie Freiberg, Institute of Ceramics, Refractories and Composite Materials, Agricolastraße 17, Freiberg, 09599, Germany
Modern, high-quality steelmaking requires a comprehensive understanding of the behavior of refractories in service. Therefore, MgO–C refractories with different MgO grade were immersed once and twice into a steel melt at 1600 °C and 1680 °C, respectively, in a near-industrial steel casting simulator. The same materials were tested in static crucible melting tests. A coherent MgO layer containing low-melting phases and MgAl2O4 crystal-like structures formed on the specimens’ surface. The morphology and frequency of these structures were strongly related to the MgO grade of the specimens and the immersion procedure. A lower MgO grade caused an increased formation of low-melting phases, which contributed to a denser layer formed on the specimens’ surface, hampering gas diffusion and the formation of MgAl2O4 crystal-like structures. An increased steel melt temperature and the double immersion had a similar effect. Conversely, an excessive formation of MgO and/or MgAl2O4 was observed when the formed layer contained less low-melting phases.
