A mold flux is used in continuous casting of Ti-containing hypo-peritectic steel so as to prevent longitudinal cracks from forming on a surface of a slab. The mold flux contains CaO, SiO.sub.2, an alkali metal oxide and a fluorine compound as major components. f(1), f(2) and f(3), which are calculated from the initial chemical composition, are (1.10.5T) to (1.90.5T), 0.05 to 0.40 and 0 to 0.40, respectively, if the Ti content of the molten steel (mass %) is T. The TiO.sub.2 content in the melting state during the casting is no more than 20 mass % and the ratio of the first peak height of perovskite to the first peak height of cuspidine in the mold flux film is no more than 1.0.

A method of casting a steel semi-product wherein a liquid steel is poured from a ladle to a tundish through a shroud including the steps of determining the light intensity emitted from the surface of the liquid steel in the tundish, detecting, based on said determined intensity, the presence of an open-eye at the surface of the liquid steel and emitting an alert towards an operator when an open-eye is detected.

A method of casting a steel semi-product wherein a liquid steel is poured from a ladle to a tundish through a shroud including the steps of determining the light intensity emitted from the surface of the liquid steel in the tundish, detecting, based on said determined intensity, the presence of an open-eye at the surface of the liquid steel and emitting an alert towards an operator when an open-eye is detected.

A mold flux for continuous casting has a base material composition containing 25 to 60 mass % of CaO, 15 to 45 mass % of SiO.sub.2, 5 to 25 mass % of F, 0.2 to 1.0 mass % of S, and 0 to 20 mass % of a total of Li.sub.2O, Na.sub.2O, and K.sub.2O, and in the base material composition, f(1) is 0.90 to 1.90, f(2) is 0.10 to 0.40, f(3) is 0 to 0.40, and a total of CaO, SiO.sub.2, F, S, Li.sub.2O, Na.sub.2O, and K.sub.2O is 90 to 100 mass %.

Provided are a method and a system for a slag thickness detection and a slag-adding prediction. The method includes: acquiring real-time measurement data and real-time auxiliary data of a slag point on a surface of a protective slag layer of a casting mold; calculating a real-time slag thickness value corresponding to the slag point by using the real-time measurement data and the real-time auxiliary data of the slag point; and predicting a location on the surface of the protective slag layer where a slag-adding is to be performed and a slag-adding time when the slag-adding is to be performed based on a change in the real-time slag thickness value corresponding to the slag point by taking a preset slag thickness value as a reference.

Provided are a method and a system for a slag thickness detection and a slag-adding prediction. The method includes: acquiring real-time measurement data and real-time auxiliary data of a slag point on a surface of a protective slag layer of a casting mold; calculating a real-time slag thickness value corresponding to the slag point by using the real-time measurement data and the real-time auxiliary data of the slag point; and predicting a location on the surface of the protective slag layer where a slag-adding is to be performed and a slag-adding time when the slag-adding is to be performed based on a change in the real-time slag thickness value corresponding to the slag point by taking a preset slag thickness value as a reference.

Compositions, structures and methods are described that improve fire retardant characteristics of various material, and which can be used for protecting structures, devices, or components therein. In one example, a mixture suitable for imparting heat or cold blocking properties to an object is produced. The mixture includes a catalyst comprising particles that are 8 microns or less in diameter, a charring agent comprising particles that are 8 microns or less in diameter, and a blowing agent comprising particles that are 8 microns or less in diameter. The catalyst, the charring agent and the blowing agent are mixed together in equal portions by weight to produce the mixture suitable for imparting heat or cold blocking properties to an object.

Compositions, structures and methods are described that improve fire retardant characteristics of various material, and which can be used for protecting structures, devices, or components therein. In one example, a mixture suitable for imparting heat or cold blocking properties to an object is produced. The mixture includes a catalyst comprising particles that are 8 microns or less in diameter, a charring agent comprising particles that are 8 microns or less in diameter, and a blowing agent comprising particles that are 8 microns or less in diameter. The catalyst, the charring agent and the blowing agent are mixed together in equal portions by weight to produce the mixture suitable for imparting heat or cold blocking properties to an object.

Compositions, structures and methods are described that improve fire retardant characteristics of various material, and which can be used for protecting structures, devices, or components therein. In one example, a mixture suitable for imparting heat or cold blocking properties to an object is produced. The mixture includes a catalyst comprising particles that are 8 microns or less in diameter, a charring agent comprising particles that are 8 microns or less in diameter, and a blowing agent comprising particles that are 8 microns or less in diameter. The catalyst, the charring agent and the blowing agent are mixed together in equal portions by weight to produce the mixture suitable for imparting heat or cold blocking properties to an object.

Compositions, structures and methods are described that improve fire retardant characteristics of various material, and which can be used for protecting structures, devices, or components therein. In one example, a mixture suitable for imparting heat or cold blocking properties to an object is produced. The mixture includes a catalyst comprising particles that are 8 microns or less in diameter, a charring agent comprising particles that are 8 microns or less in diameter, and a blowing agent comprising particles that are 8 microns or less in diameter. The catalyst, the charring agent and the blowing agent are mixed together in equal portions by weight to produce the mixture suitable for imparting heat or cold blocking properties to an object.