See our DI-1000TC thermocouple instrument web page or Download the Data Sheet (pdf) for more information
Download this application note.
Thermocouples are the most widely used devices for temperature measurement. They are:
But these attractive characteristics do not come without a price. Thermocouples also:
The above list of Thermocouple advantages and disadvantages makes them simultaneously easy to use, but difficult to implement from an instrumentation perspective. As a user, or prospective user of thermocouples, you can be assured that any instrument designed for use with these devices has resolved many of these difficulties. Specifically, any such instrument will:
However, you cannot be assured that the instrument has accurately predicted how you will use the thermocouple. And the thermocouple's rugged design allows it to be used in a variety of ways that would destroy other types of temperature sensors. As such an awareness of the three ways thermocouples can be used, and the demands placed on the instrument by each, is crucial for accurate and safe thermocouple measurements. Miscalculate here and your measurements will be noisy in the best case. In the worst case you could incinerate your thermocouple and your measuring instrument, and needlessly expose personnel to injury. The following details the three different ways thermocouples are applied in everyday situations: Isolated; Grounded; and Hot. Each is described in terms of demands placed on the connected instrument's isolation. Note that DATAQ Instruments' model DI-1000TC thermocouple measurement instrument offers two-way isolation (input-to-output and channel-to-channel) that allows it to provide accurate and safe thermocouple measurements in all three application configurations.
Thermocouple is not directly connected to any conductive metal or liquid, and there is no risk of such a connection. It is freestanding in open, non-conductive air. An example is ambient temperature measurements.
Schematic Representation:
| Multi-Channel? | Results with non-isolated instrument | Isolation Requirements | Results with DI-1000TC |
| No | Measurements can be made without incident. | None | Measurements can be made without incident. |
| Yes | Measurements can be made without incident. | None | Measurements can be made without incident. |
Thermocouple is in direct contact with a conductive liquid or metal. As such, a common mode voltage (CMV) exists between the instrument and the thermocouple. Examples include instances where a thermocouple is welded to boiler plating or some other metal structure to increase thermal response.
Schematic Representation:
| Multi-Channel? | Results with non-isolated instrument | Isolation Requirements | Results with DI-1000TC |
| No | Assuming CMV is below the threshold of damage:
|
Input to Output | Measurements can be made without incident. |
| Yes | Assuming CMV is below the threshold of damage:
|
Input to Output Channel-to-Channel |
Measurements can be made without incident. |
Thermocouple is in direct electrical contact with a power source. Examples include instances where a thermocouple is welded to, or comes into accidental contact with an electrical heating element.
Schematic Representation:
| Multi-Channel? | Results with non-isolated instrument | Isolation Requirements | Results with DI-1000TC |
| No | Thermocouple is destroyed, instrument is destroyed, or both. | Input to Output | Measurements can be made without incident. |
| Yes | Thermocouple is destroyed, instrument is destroyed, or both. Damage most likely propagates to adjacent channels causing similar destruction. | Input to Output Channel-to-Channel |
Measurements can be made without incident. |
Go to the DI-1000TC product page for more information or to purchase online.
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