The purpose of the present invention is to provide a method for recovering calcium-containing solid components from steelmaking slag, with which it is possible to easily increase the calcium recovery rate. With the method, steelmaking slag is immersed in an aqueous solution containing carbon dioxide, and calcium in the steelmaking slag is made to leach out into the aqueous solution. Next, the immersed steelmaking slag is removed from the aqueous solution, and, subsequently, the pH of the aqueous solution is increased. When solid components precipitated by doing so are recovered, it is possible to recover solid components containing 20% or more by mass in terms of calcium atoms.

A granular material may include a granular core including quicklime, the granular core having an overall concentration of CaO and MgO equal to or greater than 80% by weight. Optionally, a hydrophobic coating may cover the granular core. The granular core has compressive load until rupture equal to or greater than 50 N/granule, a slaking time t.sub.50 in water not exceeding 10 minutes, when the concentration of MgO is greater than 5% by weight with respect to the weight of the granular core, and a slaking time t.sub.60 in water not exceeding 6 minutes, when the concentration of MgO is less than or equal to 5% by weight with respect to the weight of the granular core. The present disclosure further relates to a process for preparing the granular material and to the use of the granular material in a metallurgical process or in the treatment of agricultural soil.

A granular material may include a granular core including quicklime, the granular core having an overall concentration of CaO and MgO equal to or greater than 80% by weight. Optionally, a hydrophobic coating may cover the granular core. The granular core has compressive load until rupture equal to or greater than 50 N/granule, a slaking time t.sub.50 in water not exceeding 10 minutes, when the concentration of MgO is greater than 5% by weight with respect to the weight of the granular core, and a slaking time t.sub.60 in water not exceeding 6 minutes, when the concentration of MgO is less than or equal to 5% by weight with respect to the weight of the granular core. The present disclosure further relates to a process for preparing the granular material and to the use of the granular material in a metallurgical process or in the treatment of agricultural soil.

A composition of the supplementary cementitious material (SCM) is, on a dry basis, iron silicate having the chemical formula 2FeO.Math.x SiO.sub.2, where x is 1.05-2.1, the iron silicate being the balance of the SCM; 0-4% by weight of aluminum comprised in aluminum-containing compounds, preferably 2-4% by weight, and 0-7% by weight of chain breaking elements, wherein the chain breaking elements are selected from the group consisting of calcium oxide (CaO), magnesium oxide, (MgO), sodium oxide (Na.sub.2O), barium oxide (BaO), strontium oxide (SrO), manganese (II) oxide (MnO), zinc oxide (ZnO), beryllium oxide (BeO), or any combination thereof; 0-4% by weight of trace elements and/or naturally occurring impurities. The SCM has an amorphous content of at least 95% by weight.

A composition of the supplementary cementitious material (SCM) is, on a dry basis, iron silicate having the chemical formula 2FeO.Math.x SiO.sub.2, where x is 1.05-2.1, the iron silicate being the balance of the SCM; 0-4% by weight of aluminum comprised in aluminum-containing compounds, preferably 2-4% by weight, and 0-7% by weight of chain breaking elements, wherein the chain breaking elements are selected from the group consisting of calcium oxide (CaO), magnesium oxide, (MgO), sodium oxide (Na.sub.2O), barium oxide (BaO), strontium oxide (SrO), manganese (II) oxide (MnO), zinc oxide (ZnO), beryllium oxide (BeO), or any combination thereof; 0-4% by weight of trace elements and/or naturally occurring impurities. The SCM has an amorphous content of at least 95% by weight.

The invention relates to a method for processing steel slag to produce a hydraulic mineral binder with a high hardening potential and to recover iron. There is provision for this purpose to provide a feed product comprising steel slag with MnO. This feed product is further processed as a melt by introducing reducing agent into the melt. A lime saturation factor of between 90 and 110 is hereby to be achieved in the mineral melt portion. Subsequently the melt is cooled in a defined manner and elementary iron is mechanically separated from the solidified melt. The solidified melt is then supplied for use as hydraulic mineral binder. Furthermore the invention relates to a hydraulic mineral binder.

The invention relates to a method for processing steel slag to produce a hydraulic mineral binder with a high hardening potential and to recover iron. There is provision for this purpose to provide a feed product comprising steel slag with MnO. This feed product is further processed as a melt by introducing reducing agent into the melt. A lime saturation factor of between 90 and 110 is hereby to be achieved in the mineral melt portion. Subsequently the melt is cooled in a defined manner and elementary iron is mechanically separated from the solidified melt. The solidified melt is then supplied for use as hydraulic mineral binder. Furthermore the invention relates to a hydraulic mineral binder.

A process for preparing solid slag granules from a molten slag composition comprises: (a) providing the molten slag composition; (b) converting the molten slag composition into the solid slag granules in a dispersion apparatus; and (c) sorting the solid slag granules by shape in a separator to produce a plurality of fractions having different sphericities. Granular slag products comprise one or more fractions of solid slag granules produced by the process, and include proppants, roofing granules, catalyst supports, which may be porous or non-porous, and coated or uncoated.

The present disclosure provides a method, a system for dehydrating a gasification fine slag, and a medium thereof. The method is performed by a processor controlling a dehydration device or a detection device, and the detection device is configured to detect at least one of physical properties or chemical properties of a gasification fine slag to be dehydrated. The method includes controlling the detection device to determine characteristic parameters of the gasification fine slag to be dehydrated, and determining a judgmental characteristic index of a dehydration moder of the gasification fine slag to be dehydrated. The method includes determining a target dehydration device and controlling the target dehydration device to dehydrate the gasification fine slag to be dehydrated. The method further includes controlling the detection device to determine a residual moisture content of a dehydrated gasification fine slag, and determining whether to end a dehydration task.

The present disclosure provides a method, a system for dehydrating a gasification fine slag, and a medium thereof. The method is performed by a processor controlling a dehydration device or a detection device, and the detection device is configured to detect at least one of physical properties or chemical properties of a gasification fine slag to be dehydrated. The method includes controlling the detection device to determine characteristic parameters of the gasification fine slag to be dehydrated, and determining a judgmental characteristic index of a dehydration moder of the gasification fine slag to be dehydrated. The method includes determining a target dehydration device and controlling the target dehydration device to dehydrate the gasification fine slag to be dehydrated. The method further includes controlling the detection device to determine a residual moisture content of a dehydrated gasification fine slag, and determining whether to end a dehydration task.