Keithley 5134 Thermocouple secret free download

File name 5134_Thermocouple_secret.pdf

The Secret to Thermocouples - Mind the Metallurgy, and All Else Will Follow by Mike Bayda, Keithley Instruments, Inc. Imagine an electronic sensor technology that's simple, cheap, reliable, and 200 years old. Look no farther than the popular thermocouple. In the early 1800s, Thomas Seebeck discovered that the junction of two metals generates a voltage that depends on temperature. Many lab students have begun their association with thermocouples by exploring this relationship with a set-up similar to that shown in Figure 1. They measure an unknown temperature using a pair of thermocouple junctions, one of which is immersed in an ice water bath. After making voltage measurements, they determine the unknown temperature using a thermocouple look-up table. Today, engineers and scientists use electronic instrumentation that can accept dozens of thermocouple inputs, without requiring an ice bath reference or individual reference junctions. How this has been accomplished remains one of the least understood aspects of thermocouple use. A grasp of the principles involved can go a long way toward helping users avoid set-up and measurement errors with their own thermocouple systems. Thermocouple Construction A thermocouple consists of two wires of dissimilar metals joined at one end. This "hot junction" is used to measure an unknown temperature, while the "reference (cold) junction" and measurement hardware comprise the rest of the system. Although many metal combinations exhibit the Seebeck effect, a limited number have been established as industry standards because of their predictable output characteristics over a wide temperature range. The measured EMF is related to the difference in temperature between the hot and cold junctions (J1 and J4), and the types of metals used to construct the thermocouple. The result can be expressed by the following equation: V = a(TUNKNOWN -T ) REF where a is the Seebeck Coefficient. This coefficient in highly non-linear, and varies for different types of thermocouples. It can be found in thermocouple references (usually in a table of voltage versus temperature), but modern electronic instruments and software generally automate the conversion of voltage to temperature, so the user needn't bother with a. Simplifying the Measurement System Modern thermocouple measurement instruments do not use the ice bath and corresponding reference thermocouple shown in Figure 1. This eliminates the need for a potentially large number of input channels for the references, not to mention the hassle of dealing with ice. Historically, the purpose of the ice bath was to force the reference junction to a known temperature (0