An optical cored wire includes an optical fiber and a cover laterally surrounding the optical fiber, The cover surrounds the optical fiber in a plurality of layers. One layer is a metal coat, also called a metal jacket or a metal tube. An intermediate layer, also called filler, is arranged beneath the metal tube. The intermediate layer is formed from a thermal insulating material having a melting point in the temperature ulnae of 1000 C. to 1500 C., such that the pieces of the intermediate layer are fluid upon exposure to the molten metal temperatures and a portion of the intermediate layer, the entire intermediate layer and/or the cover laterally surrounding the optical fiber can melt immediately upon immersion into the molten metal or immediate exposure to the molten metal.

A consumable cored wire for measuring a temperature of a molten steel bath includes an optical fiber and a cover laterally surrounding the optical fiber in a plurality of layers. One layer is a metal pipe, also called metal jacket or metal tube. An intermediate layer, also called filler, is arranged beneath the metal tube. The intermediate layer is a rope.

Devices, systems, and methods for calibrating for an electron beam additive manufacturing system. The electron beam manufacturing system includes electron beam guns. A calibration system includes an optical pyrometer. The optical pyrometer captures thermal radiation emitted from raw material. An analysis component is communicatively coupled to the optical pyrometer. The analysis component is programmed to determine calibration parameters from information from the optical pyrometer and a phase transition temperature.

Optical probes and methods for continuously measuring the temperature of molten metals in vessels are described. The optical probe may include a fiber surrounded by a protective structure that is mounted in a wall of a vessel. The protective structure may include a porous body for flowing gas through the optical probe assembly. A portion of the optical probe may be sacrificial and erode or break away during temperature measurements. Calibrations may be used to correct temperature measurements based on an amount of erosion or removal of the optical fiber.

A water-mist-penetrating temperature measurement system and method for steel hot rolling, the system including a water-mist-penetrating temperature measurement device, and the water-mist-penetrating temperature measurement device including a visible light guiding-tracking assembly, an optical focusing assembly, a dual-wavelength beam splitting assembly, a multi-source information processing assembly, and a display assembly; and the method including the steps of obtaining a dual-wavelength radiation signal and a visible light image signal of the object to be measured, processing the obtained dual-wavelength radiation signal and the visible light image signal, and detecting and processing an abnormally fluctuated temperature data.

The invention relates to a device and method for measuring a temperature of a molten metal bath. The device according to the present invention comprises a cored wire and a detector. The cored wire comprises an optical fiber, a first metal tube, a filler layer of an organic material and a second metal tube accommodating the filler layer.

The present invention relates to a method and a system for determining a temperature value of a molten metal bath. The method according to the invention has been proven to be especially suitable for repeated determinations of temperature values; i.e. the method allows for multiple measurements with repeatedly newly generated leading tips of the optical cored wire.

The present invention relates to a method and a system for determining a temperature value of a molten metal bath. The method according to the invention has been proven to be especially suitable for installations of metallurgical vessels which are constantly moved during the metal making process.