Russian Internet Journal of Industrial Engineering

Analysis of forming of chromium-bearing ferroalloys production waste in Russian Federation was performed. Chemical, phase, fractional compositions and physico-chemical, technological properties of high-carbon ferrochromium slag were defined. Physico-chemical, thermo-mechanical and thermo-physical properties of fire-resistant materials obtained from ferrochromi-um production slag and dust were researched. It was shown that researched waste may be uti-lized as raw for fire-resistant materials production. Because of their chemical and phase composi-tion researched materials may be utilized for production of forsterite-spinel-based and forsterite-spinel-periclase-based fire-resistant materials. Technological properties of researched materials allow obtaining of dense strength fire-resistant materials. Such fire-resistant materials are promis-ing in the field of ferrous metallurgy (lining of furnaces, ladles and overflow launders in ferroal-loys production).

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