Advantages of Infrared Thermometer Temperature Measurement
Non-contact temperature measurement by receiving infrared rays radiated from the object to be measured has many advantages. In this way, difficult-to-reach or moving objects can be measured without problems, such as materials with poor heat transfer properties or low heat capacity. The very short response time of the infrared thermometer enables fast and efficient regulation of the loop. Thermometers have no wearing parts, so there are no ongoing costs as there are with thermometers. Especially for small objects to be measured, such as contact measurement, there will be a large measurement error due to the thermal conductivity of the object. Here the thermometer can be used without any problems, and for aggressive chemicals or sensitive surfaces, such as on painted, paper and plastic rails. Through the long-distance remote control measurement, it can stay away from the dangerous area, so that the operator will not be in danger.
The principle structure of infrared thermometer
The infrared rays received from the measured object are focused on the detector through the lens through the filter. The detector generates a current or voltage signal proportional to the temperature through the integration of the radiation density of the measured object. In the electrical components connected thereafter, the temperature signal is linearized, the emissivity area is corrected, and converted into a standard output signal.
In principle, there are two types of portable thermometers and fixed thermometers. Therefore, when choosing a suitable infrared thermometer for different measurement points, the following characteristics will be the main ones:
1. Aimer
The collimator has this effect, and the measuring block or measuring point pointed by the thermometer can be seen, and the collimator can often be used for large-area measured objects. For small objects and long measuring distances, sights with instrument panel scales or laser pointing points in the form of light-transmitting lenses are recommended.
2. Lens
The lens determines the measured point of the pyrometer. For large-area objects, a pyrometer with a fixed focal length is generally sufficient. But when the measurement distance is far from the focus point, the image at the edge of the measurement point will be unclear. For this reason, it is better to use a zoom lens. Within the given zoom range, the thermometer can adjust the measurement distance. The latest thermometer has a zoomable replaceable lens. The near lens and the far lens can be rechecked without calibration. replace.
3. Sensors, i.e. spectral receivers
Temperature is inversely proportional to wavelength. At low object temperatures, sensors sensitive to the long-wave spectral region (hot-film sensors or pyroelectric sensors) are suitable, at high temperatures, short-wave sensitive sensors composed of germanium, silicon, indium-gallium, etc. will be used Photoelectric Sensors.
When selecting the spectral sensitivity, also consider the absorption bands for hydrogen and carbon dioxide. In a certain wavelength range, the so-called "atmospheric window", H2 and CO2 are almost transparent to infrared rays, so the light sensitivity of the thermometer must be within this range in order to exclude the influence of atmospheric concentration changes , when measuring thin films or glasses, it must also be considered that these materials are not easily penetrated within a certain wavelength. In order to avoid the measurement error caused by the background light, use a suitable sensor that only receives the surface temperature. Metals have this physical property, and the emissivity increases with the decrease of the wavelength. From experience, to measure the temperature of metals, generally choose * Short measurement wavelength.
