Termopāra temperatūras mērīšanas klasifikācija

Termopāra sensori (Bruņota termiskā pretestība, Ugunsdroša platīna izturība, Augstas temperatūras dārgmetāls (platīna rodijs) termopārs, Pretkorozijas termiskā pretestība, End face thermal resistance, Power station thermocouple sensors, Hot runner thermocouple) is a kind of temperature sensing element. thermocouple directly measures temperature. Two different components of a conductor material composed of a closed loop. Due to different materials, different electron densities produce electron diffusion, and an electric potential is generated after stable equilibrium. When there is a gradient temperature at both ends, a current will be generated in the loop, generating thermoelectromotive force. The greater the temperature difference, the greater the current. The temperature value can be known after measuring the thermoelectromotive force. A thermocouple sensors is actually an energy converter that converts heat energy into electrical energy.

The technical advantages of thermocouples sensors: the thermocouple has a wide temperature measurement range, and its performance is relatively stable. The measurement accuracy is high, the thermocouple is in direct contact with the measured object, and is not affected by the intermediate medium. The thermal response time is fast, and the thermocouple responds flexibly to temperature changes. The measuring range is large, and the thermocouple can measure the temperature continuously from -40~+1600℃. The thermocouple has reliable performance and good mechanical strength. Long service life and convenient installation.

The galvanic couple must be composed of two conductor (or semiconductor) materials with different properties but meet certain requirements to form a loop. There must be a temperature difference between the measuring terminal and the reference terminal of the thermocouple.

The conductors or semiconductors A and B of two different materials are welded together to form a closed loop. Ja starp diviem stiprinājuma punktiem ir temperatūras starpība 1 un 2 of the conductors A and B, starp abiem tiek radīts elektromotora spēks, so a current of a magnitude is formed in the loop. Šo parādību sauc par termoelektrisko efektu. Thermocouple is the application of this effect to work.

The thermocouple is actually a kind of energy converter. It converts thermal energy into electrical energy, and uses the generated thermoelectric potential to measure temperature. For the thermoelectric potential of a thermocouple, the following issues should be paid attention to :
1. The thermoelectric potential of a thermocouple is the difference between the temperature functions of the two ends of the thermocouple, not the temperature difference between the cold and working ends of the thermocouple.
2. The size of the thermoelectric potential generated by the thermocouple. When the material of the thermocouple is uniform, it has nothing to do with the length and diameter of the thermocouple, bet tikai ar termopāra materiāla sastāvu un temperatūras starpību starp abiem galiem.
3. After the material composition of the two thermocouple wires of the thermocouple is determined, the thermoelectric potential of the thermocouple is only related to the temperature difference of the thermocouple. If the temperature of the cold junction of the thermocouple remains constant, the thermoelectric potential of the thermocouple is only a single value function of the temperature of the working junction. Solder two conductors or semiconductors A and B of different materials to form a closed loop, kā parādīts attēlā. Ja starp diviem stiprinājuma punktiem ir temperatūras starpība 1 un 2 of the conductors A and B, starp abiem tiek radīts elektromotora spēks, thus forming an order of magnitude current in the loop. Thermocouples use this effect to work.