|
Thermocouples with magnesium oxide insulation
are recommended where the thermocouple is immersed in liquids,
high moisture, corrosive gases, or high pressures. The thermocouple
can be formed to reach otherwise inaccessible areas. The magnesium
oxide has a high dielectric strength, responds quickly to temperature
changes, and is very durable.
T/C MgO insulated thermocouple wire is manufactured
from premium quality wire encased in pure magnesium oxide, and
processed into a chemically clean outer metal sheath. The wires
are individually selected and matched, and are of uniform cross
section with smooth surfaces. Finished stock is warranted to meet
ANSI standard limits of error set forth in MC96.1. The unique
preparation of MgO insulated thermocouple wire produces a uniform
thickness of insulation with high density. The result is a product
that is mechanically strong and resistant to penetration of corrosive
gases and moisture. The diameters of 0.040” and 1/16”
are useful for applications requiring fast response.
Junction Construction: Ungrounded (insulated):
Thermocouple insulated from sheath with MgO. Stray EMF is prevented
from affecting the reading. Response from rapid or frequent temperature
cycling is slower than for grounded style.
|
|
Exposed: Thermocouple junction is not protected
by welded cap. Used for quick response, but is susceptible to
corrosive failure.
Time Constants: The time constant is the amount
of time required for a thermocouple to indicated 63.2% of step
change in temperature of a surrounding media. Some of the factors
influencing the measured time constant are sheath wall thickness,
degree of insulation compaction, and distance of junction from
the welded cap on an ungrounded thermocouple. In addition, the
velocity of a gas past the thermocouple probe greatly influences
the time constant measurement.
In general, time constants for measurement of
gas can be estimated to be ten times as long as those for measurement
of liquid. The time constant also varies inversely proportional
to the square root of the velocity of the media.
In general, time constants for measurement of
gas can be estimated to be ten times as long as those for measurement
of liquid. The time constant also varies inversely proportional
to the square root of the velocity of the media.
Approximate time constants for different sheath
diameters in water are shown below for a step change from 0 to
100°C:
|
