Formation of metallic phase on reducing-gas injection in multicomponent oxide melt. Part 2. Density and surface properties

Abstract

The density and surface tension of melts of ferronickel (0–100% Ni) and oxidized nickel ore are measured by the sessile-drop method, as well as the interface tension at their boundary in the temperature range 1550–1750°C. The composition of the nickel ore is as follows: 14.8 wt % Fetot, 7.1 wt % FeO, 13.2 wt % Fe2O3, 1.4 wt % CaO, 16.2 wt % MgO, 54.5 wt % SiO2, 4.8 wt % Al2O3, 1.5 wt % NiO, and 1.2 wt % Cr2O3. In the given temperature range, the density of the alloys varies from 7700 to 6900 kg/m3; the surface tension from 1770 to 1570 mJ/m2; the interface tension from 1650 to 1450 mJ/m2, the density of the oxide melt from 2250 to 1750 kg/m3; and its surface tension from 310 to 290 mJ/m2. The results are in good agreement with literature data. Functional relationships of the density, surface tension, and interphase tension with the melt temperature and composition are derived. The dependence of the alloy density on the temperature and nickel content corresponds to a first-order equation. The temperature dependence of the surface tension and interphase tension is similar, whereas the dependence on the nickel content corresponds to a second-order equation. The density and surface tension of the oxide melt depend linearly on the temperature. The results may be used to describe the formation of metallic phase when carbon monoxide is bubbled into oxide melt.