Abstract: In view of the foregoing embodiments of the disclosure provide a high value steel/carbon product from a low value iron-containing waste material and process for producing the steel/carbon product. The high value steel/carbon product is derived from a mixture of metallurgical coal and an oxidized iron waste material under a reducing atmosphere. The steel/carbon product has a porosity of greater than about 60% and a density of greater than about 900 kg/m3 and the steel component of the steel/carbon product has a percent of metalization of greater than about 85 wt. %.

Abstract: Briquette for producing a foamed slag on stainless steel melts in an electric arc furnace, made up of mixtures of individual or multiple substances of following basic components: O2 carrier Dust, sludge or slag with ?10% FeO/Fe2O3, Dust, sludge or slag with ?1% Cr2O3, Dust, sludge or slag with ?1% MnO, Dust, sludge or slag with ?1% NiO, Scale with ?10% FeO/Fe2O3, Gas carrier Dust with ?40% CaCO3, Density adjuster Dust with FeCr, Dust with Fe/low alloy fine scrap, Dust with Cr/ferritic fine scrap, Dust with Ni/austenitic fine scrap, grinding dust, Dust with Mn/ferritic or low alloy fine scrap, Reducing agent Carbon-containing substances ?90% C, Dust or fine granulate of coke, coal or graphite, Binder Molasses, cement, Ca(OH)2, in each case ?5% by weight.

Abstract: It is known that a foamed slag can be produced on stainless steel melts in an electric arc furnace by introducing a mixture of metal oxides, limestone, carbon and a binder in the form of briquettes into the furnace so that the briquettes become arranged there in such a way that the metal oxides are reduced by the carbon and the limestone is thermally dissociated at the metal-slag interface beneath the slag and the resulting gases bring about foaming of the slag by bubble formation. This foaming on steels having a high chromium content, due to the significant uptake of chromium oxide by the slag, leads to problems which result from the physicochemical properties of slags having a high chromium oxide content.

Abstract: Hot briquette iron includes a plurality of reduced iron particles which are bonded to each other by hot forming, wherein the reduced iron particles each have a surface region having an average carbon content of 0.1 to 2.5% by mass and a central region positioned inside the surface region and having an average carbon content higher than that of the surface region.

Abstract: A solidified product (B) is produced by charging a dust (11) generated in a steel making process and containing iron and an oxide thereof as a principal component into a mold (7) and by subjecting it to a pressure molding. A raw material charged to the mold is a mixed granulated product (11p) prepared by mixing the dust and a powder containing carbon as a principal component and by granulating the resultant mixture.

Abstract: Cotton-like aggregates (B) including grinding chips from an iron-based metal and a grinding fluid containing oil and water are compression molded for forming a brittle compact (C) having the fibrous grinding chips roughly sheared and excessive water and oil removed therefrom. The brittle compact (C) is crushed for further finely shearing the grinding chips and the resultant grinding chips are mixed with a solidification assistant (D) for producing an iron-based powder material (E) containing the solidification assistant (D).

Abstract: A method for making surface-coated reduced iron includes the step of coating the surface of reduced iron with a tar emulsion. Preferably, the tar emulsion includes at least one hydrocarbon-based material selected from the group consisting of natural petroleum tar, coal tar, pitch, asphalt, liquefied coal, and residual oil from petroleum refining; a surfactant; and water. More preferably, the tar emulsion contains 60 to 80 percent by mass of the hydrocarbon-based material, 0.1 to 1 percent by mass of the surfactant, and the balance being substantially water.

Abstract: A composite charge for metallurgical processing which reduces the content of non-metallic inclusions in the end product(s) comprises 40-83 wt. % of a metallic agent, 17-50 wt. % of an oxide agent and 0.1-10.0 wt. % of a carbonaceous agent. The carbonaceous agent includes a mixture of metal carbides and free carbon, preferably graphite, having a ratio in the range of 0.1-10.0:1.

Abstract: A method for preparing iron bearing green pellets that can be processed in a rotary hearth furnace without degradation and become self-fluxing sponge iron pellets when charged to a submerged arc furnace operating at a lower temperature than the rotary hearth furnace, to produce hot metal having a carbon content from 1% to about 5%.