Application of High Temperature Camera Thermometer in the Steel Industry
Temperature measurement is required in many processing processes in the steel industry. But in most cases, thermocouples are used. However, in some applications, contact measurement is not feasible because there is solid steel in motion or its environment is not suitable for the use of contact probes. These special applications will undoubtedly benefit from the use of high-temperature camera thermometers for image temperature measurement.
Remote photography and non-contact temperature measurement can be well combined and applied in some steel processes, such as heating furnaces and rolling mills. The high-temperature camera thermometer provides an excellent tool for optimizing monitoring and temperature measurement functions due to its flexible combination of unique video imaging and infrared temperature measurement. This combination has opened up new avenues for steel mills that have not yet used cameras, especially making furnace maintenance easier. The following highlights the potential applications of high-temperature camera thermometers in steel plants, and provides relevant introductions to measuring the temperature of solid and liquid steel.
Steel Industry&Temperature Measurement
Generally speaking, it is difficult to measure the temperature of steel using an infrared thermometer due to its low emissivity. Radiation rate is an attribute of matter that indicates how much infrared radiation is emitted from the same black object (which is an object with a radiation rate of 1, representing an excellent radiation source). The higher the radiation value, the higher the energy reaching the detector. Basically, the higher the emissivity, the easier it is to measure the temperature of an object.
For steel products, the emissivity varies with temperature, surface conditions, and the chemical composition of the steel. One variable that has a significant impact on emissivity is surface conditions. For example, the radiation rate of unoxidized stainless steel (such as when treated in the factory) is approximately 0.4. For highly oxidized (more "black") surfaces, this value increases to 0.8. For surfaces that have been polished (very "bright"), the emissivity decreases to 0.2. Since the high-temperature camera thermometer provides a flexible method for changing the emissivity of the cursor selectable area on each terminal screen, as long as we know the parameters and indicators of the processed raw materials, we can obtain reliable temperature measurements.
