Thermocouples operate based on the principle of the Seebeck effect, which is the phenomenon where a temperature difference between two dissimilar metals generates a voltage. This voltage is directly proportional to the temperature difference and is used to measure temperature.
The basic construction of a thermocouple consists of two different metal wires (or occasionally solid rods) joined together at one end to form a junction. This junction is where the temperature being measured is applied. The other ends of the wires are typically connected to a temperature measurement device, such as a meter or controller.
When the junction of the thermocouple is subjected to a temperature gradient (one end is hotter than the other), an electromotive force (EMF) is generated across the wires due to the Seebeck effect. This EMF is proportional to the temperature difference between the hot and cold junctions according to a known relationship specific to the type of thermocouple.
Key points about the operating principle of thermocouples:
Seebeck Effect: The voltage generated by a thermocouple is directly proportional to the temperature difference between the hot and cold junctions, according to the Seebeck effect.
Thermo-electric Circuit: Thermocouples operate as thermo-electric circuits, where the temperature difference between the junctions creates an electric potential that drives a current through the circuit. This current can be measured and used to determine the temperature.
Thermoelectric Properties: The Seebeck effect depends on the thermoelectric properties of the materials used in the thermocouple. Different combinations of metals exhibit different Seebeck coefficients, which determine the sensitivity and temperature range of the thermocouple.
Reference Temperature: In practice, one of the junctions is often maintained at a known reference temperature, usually at ambient temperature, to establish a reference point for temperature measurement. This allows the measurement of the temperature at the other junction relative to the reference temperature.
Compensation: Because the output voltage of a thermocouple depends on the temperature difference between the two junctions, it is important to compensate for changes in the reference junction temperature. This is typically done using a cold junction compensation technique.
Overall, thermocouples are widely used temperature sensors due to their simplicity, ruggedness, wide temperature range, and fast response times, making them suitable for various industrial, commercial, and scientific applications.