Traditional magnesia-based refractories face challenges such as high thermal conductivity and poor slag penetration resistance, which contradict the energy efficiency requirements of modern metallurgy. In this study, microporous magnesia was prepared using low-grade magnesite via the one-step sintering method. The microstructure and properties of microporous magnesia prepared by high-silicon and high-calcium magnesites calcined at various temperatures were compared. The pore structure and phase evolution were analyzed, the effect of which on the properties of lightweight magnesia-based dry vibration mix was discussed. The results indicated that within high-silicon magnesite, SiO2 initially reacted with MgO to form Mg2SiO4, which gradually reacted with CaO impurities as the temperature increased transforming into a MgO-CaO-SiO2 ternary liquid phase and uniformly permeated along the grain boundaries. Due to the bridging effect of strip-like CaO in high-calcium magnesite, the reorganization and sintering of MgO grains at high temperatures were inhibited, resulting in the presence of a significant number of elongated pores within the magnesia after calcination at various temperatures, which was detrimental to the mechanical properties and slag resistance. The microporous MgO prepared by high-silicon magnesite at 1 700 °C exhibited the superior physical properties. The microporous MgO aggregates had a stronger interlocking force with the matrix, resulting in a greater bonding strength. Moreover, the micropores not only effectively reduced the thermal conductivity but also facilitated the supersaturated precipitation of molten slag, hindering further penetration. Compared to the dry vibration mix prepared by fused MgO, the lightweight magnesia-based dry vibration mix prepared with the high-silicon magnesite exhibited higher mechanical strength (~40% increase) and thermal insulation performance (0.870 W · (m · K)-1 at 1 000 °C), and improved slag resistance.
LI Zilong, HUANG Ao, ZOU Yongshun, LIU Yangxi, GU Huazhi, FU Lyuping