A Thermocouple is a temperature sensor, In Most Common form it consist of two wires of different alloys. The two different wires are welded together at 2 different points which have different temperatures.
One of the points is at known temperature . This point is reference junction. The reference junction is also called the “cold” junction. The temperature of the reference junction is held constant , or its variation is electronically compensated for in the associated measuring instrumentation.
The second junction is the measuring junction. The measuring junction is also often, but less preferably, called the “hot” junction. The measuring junction is often at an unknown temperature requiring measurement, or at a temperature at which control is required.
A thermocouple is useful for temperature sensing because a measurable electrical signal is produced. The signal is a function of the difference in temperature between the measuring and reference junctions. Numerous combinations of dissimilar metals are used as thermocouples. Some of these combinations have become relatively standard and widely accepted for a large segment of industrial temperature measurements. A specific combination is generally referred to as a type, or calibration. Most of the common calibrations have American National Standards Institute (ANSI) letter codes. These letter codes were originally established by the Instrument Society of America.
The recommended temperature range for each type is that for which limits of error are established. No guarantee is made, or implied, regarding the successful use of any of the above calibrations in their recommended range. Use of a thermocouple outside its recommended temperature range may adversely affect its reliability over its recommended
Numerous factors combine to determine the successful application of a particular thermocouple. Some of these factors are temperature, cycling, chemical exposure, degree of protection provided, and mechanical abuse given to the thermocouple.
Thermocouple calibrations are maintained by proper manufacturing control of each of the thermoelements. Elemental constituents are controlled to a high degree. Homogeneity must be maintained, and all wire must be properly annealed.
To reduce costs when long thermocouple lengths are required, especially with the noble metal calibrations, extension leadwire extends the reference junction of the thermocouple to the instrument. For the base metal calibrations the extension wire is nominally of the same composition as the thermocouple grade material. Control in manufacturing is not to the same degree as thermocouple grade wire. With lessening rigidity of manufacturing control considerable expense can be saved. There is a limitation on the maximum temperature to which the junction of extension wire and thermocouple wire should be exposed. For the base metal calibration except Type T the maximum temperature is 400°F (204°C). For type T it is 200°F (93°C)
Noble metal types R, S, B, Platinel, the Tungsten-Rhenium calibrations are used with “compensating alternate” extension wire, which means the extension wire is made of material differing in composition from the thermocouple wire, but at temperatures encountered at the thermocouple extension junction, has corresponding temperature-EMF characteristics. The maximum temperature limitations for the thermocouple extension junction for calibration types R, S, B, and Platinel is 400°F (204°C). For Tungsten/Tungsten — 26% Rhenium (W/W — 26% Re), Tungsten — 3% Rhenium/Tungsten — 25% Rhenium (W — 3% Re/W – 25% Re) it is 500°F (260°C). For W- 5% Re/W- 26% Re it is 1600°F (871°C). The reason for the temperature limitation is that the thermocouple and extension wire junction is one of the materials of differing composition, and hence another thermocouple.
Whenever extension wire is used, precautions should be taken to insure a uniform temperature exists across both thermocouple and extension wire junctions. If there is sufficient temperature gradient between the temperature and extension wire junctions and the terminals at the instrument when copper extension wire is used, appreciable error may be produced.
Thermocouple extension wires should be installed in conduit whenever possible, and the conduit should be well grounded. Never run other electrical wires in the same conduit with extension wires. Keep the extension wires at least a foot away from any AC line
Grounded Junction: In grounded junction thermocouple wires and sheath of the mineral insulated cable is welded together to form a junction. Thermocouple wires and sheath becomes an integral part of the junction. Thus, the wire is grounded to the sheath.
· Slower response than Exposed junction, but offers rugged construction.
· Can hold higher pressure than exposed junction and Ungrounded junction.
Ungrounded Junction: Junction is similar to grounded junction except wire are fuse welded, which is then insulated with Mgo powder and formed cap by welding without incorporating thermocouple wires. Thus, the junction is called the ungrounded junction.
Key Benefits :
· Wires are protected from any mechanical damage
· Offers rugged construction, the same as the grounded junction.
· Strain due to differential expansion between wire and sheath is minimized with insulated wires.
Exposed Junction: In expose junction, the sheath is removed, and thermocouple wires fuse-welded to form a junction.
· Fast Response Time
|-200 °C to 0 °C 0 °C to 350 °C
|± 1 °C or 1.5% Whichever is greater ± 1 °C or .75% Whichever is greater
|N/A ± 0.5 °C or 0.4% Whichever is greater
|0 °C to 750 °C
|± 2.2 °C or .75% Whichever is greater
|± 1.1 °C or 0.4% Whichever is greater
|-200 °C to 0 °C 0 °C to 900 °C
|± 1.7 °C or 1.0% Whichever is greater ± 1.7 °C or .5% Whichever is greater
|N/A ± 1 °C or 0.4% Whichever is greater
|K OR N
|-200 °C to 0 °C 0 °C to 1250 °C
|± 2.2 °C or 2.0 % Whichever is greater ± 2.2 °C or .75% Whichever is greater
|N/A ± 1.0 °C or 0.4% Whichever is greater
ANSI ,IEC & JIS Thermocouple wire Insulation Color Coding & Magnet Check