Thermocouples Part 2: Traps and Hazards

And why we don’t need Types J, K, T, E and S

How do you pick up all of the temperature? Keep in mind that you are processing material so try to get to it rather than a pipe or vessel surface. If it’s a liquid or a gas stream you need an immersion depth at least four times the probe diameter. Heavy metal-sheathed probes can conduct heat outwards cooling the tip and giving a lower than true reading. Thin wall or non-metallic probes mitigate this effect. Plastic processing machinery calls for deep holes drilled in barrels, molds and dies, ending just short of the polymer. You then insert a spring-loaded bayonet-mounted thermocouple that has a grounded hot junction in contact with the blind end of the hole. On a work-piece in an oven or furnace an attached thermocouple is advisable in addition to one in the space. In a vacuum furnace you have to wonder what a thermocouple in the space is representing.

Surface measurements. These may be acceptable but you need a low mass thermocouple in intimate contact with the surface and under a thermally insulating pad. Otherwise the reading will be a compromise between the true surface temperature and the surrounding air temperature.

For a clean or reasonably conducting metal surface you can use a foundry probe. This is a spring-loaded pair of sharp spikes of different thermocouple materials e.g. one of chromel, the other of alumel. These are connected by the appropriate thermocouple extension cable out to your instrument. The metal that you a prodding completes the hot junction but makes no thermoelectric interference with the measurement. This probe is usually used for spot measurements of billets and castings rather than for control.

Don’t ground thermocouple wiring. Many thermocouples are grounded already at the hot end during manufacture for reasons of fast response. Any more grounds, at the protection tube or anywhere at all along the wiring route will more often than not reduce the temperature signal, tell lies to the controller and overheat the process.

Millivolts Vs Degrees curves are different for every type of thermocouple. The top end of the useable range is around 12mV for Type B and some 60mV for type E. Modern dc amplifiers are so stable that the magnitude of the signal is not a big issue when choosing a thermocouple. These curves and tables are widely available from suppliers and on the internet so are not shown here.

The Hazards of Variety. Wider the choice greater the risk. Mismatching controllers and thermocouples during installation and maintenance has long been a threat, not just to product yield and quality but also to people and plant. You cannot depend on round the clock vigilance of operators, installers and maintenance technicians. Do all you can to reduce the variety of thermocouples in your plant Decide whether you want a °F or a °C shop and stick to it. Label your indicators, controllers, thermocouples and zones with the thermocouple type.

The continued use of six different territorial extension cable color codes multiplied by eight different thermocouple types in an importing and exporting industrial market cannot be justified. The color codes have since 1989 been harmonised and standards agreed world wide by representatives of the major industrial countries through the IEC committees. Their adoption in North America has not yet begun at year 2002.

Standards Committee work is needed, aimed at minimising the variety of thermocouple types in process plants. Four of the eight most common, J, K, T and E can be replaced by Type N which has been around and proven for 30 or more years. This would eliminate the short and long-term instability problems associated with these four. Type T is well established for low temperatures in the food industry and has the advantage of about 40% bigger signal than Type N. The useable range of Type N (-250 to 1230 °C) brackets all four. Also there is no need to keep both Type R and Type S. Either one could go and not be missed. For many years controllers, indicators and recording systems, being microprocessor based, have been field configurable to match any of the eight standard thermocouples so changing a thermocouple type does not present a problem. A bigger challenge would be replacement of the thermocouple extension cables in the plant.

Name Confusion. Some common thermocouple alloys are given registered trade names that differ from the commonly used names or defined alloy composition names. Some have caught on and are almost generic and are even used here to avoid being pedantic. . Other trade names may not be recognisable and could add to identification problems.


Adapted from an article originally written by Arthur Holland, Holland Technical Skills, for Eurotherm.
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