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ASTM E1256-95(2007)

(Test Method)

Standard Test Methods for Radiation Thermometers (Single Waveband Type)

Standard Test Methods for Radiation Thermometers (Single Waveband Type)

SCOPE
1.1 The test methods described in these test methods can be utilized to evaluate the following six basic operational parameters of a radiation thermometer (single waveband type):Calibration AccuracyRepeatabilityTarget SizeResponse TimeWarm-Up TimeLong-Term Drift
1.2 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.

General Information

Status
Historical
Publication Date
31-Oct-2007
ICS
17.200.20 - Temperature-measuring instruments
Technical Committee
E20 - Temperature Measurement
Drafting Committee
E20.02 - Radiation Thermometry
Current Stage
Ref Project

Relations

Replaces
ASTM E1256-95(2001) - Standard Test Methods for Radiation Thermometers (Single Waveband Type)
Effective Date
01-Nov-2007
Replaced By
ASTM E1256-10 - Standard Test Methods for Radiation Thermometers (Single Waveband Type)
Effective Date
01-Dec-2010
Referred By
ASTM E452-02(2023) - Standard Test Method for Calibration of Refractory Metal Thermocouples Using a Radiation Thermometer
Effective Date
01-Nov-2007
Referred By
ASTM E3353-22 - Standard Guide for In-Process Monitoring Using Optical and Thermal Methods for Laser Powder Bed Fusion
Effective Date
01-Nov-2007
Referred By
ASTM E2758-22 - Standard Guide for Selection and Use of Infrared Thermometers
Effective Date
01-Nov-2007
Referred By
ASTM E344-20 - Terminology Relating to Thermometry and Hydrometry
Effective Date
01-Nov-2007
Referred By
ASTM E2847-21 - Standard Test Method for  Calibration and Accuracy Verification of Wideband Infrared Thermometers
Effective Date
01-Nov-2007
Referred By
ASTM C210-95(2019) - Standard Test Method for Reheat Change of Insulating Firebrick
Effective Date
01-Nov-2007

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ASTM E1256-95(2007) - Standard Test Methods for Radiation Thermometers (Single Waveband Type)ASTM E1256-95(2007) - Standard Test Methods for Radiation Thermometers (Single Waveband Type)
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REDLINE ASTM E1256-95(2007) - Standard Test Methods for Radiation Thermometers (Single Waveband Type)
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Standards Content (Sample)


NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
Contact ASTM International (www.astm.org) for the latest information
Designation:E1256–95 (Reapproved 2007)
Standard Test Methods for
Radiation Thermometers (Single Waveband Type)
This standard is issued under the fixed designation E1256; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 2.2 Definitions of Terms Specific to This Standard:
2.2.1 reference temperature source, n—a source of thermal
1.1 The test methods described in these test methods can be
radiant power of known temperature or emissivity, or both,
utilized to evaluate the following six basic operational param-
used in the testing of radiation thermometers.
eters of a radiation thermometer (single waveband type):
2.2.2 target size, n—the diameter of a circle in the target
Section
plane of a radiation thermometer that is centered on its line of
Calibration Accuracy 7
Repeatability 8
sight and contains 99 % of the input radiant power received by
Target Size 9
that instrument.
Response Time 10
2.2.3 temperature resolution, n—the minimum simulated or
Warm-Up Time 11
Long-Term Drift 12
actual change in target temperature that gives a usable change
in output or indication, or both.
1.2 This standard does not purport to address all of the
safety concerns, if any, associated with its use. It is the
3. Significance and Use
responsibility of the user of this standard to establish appro-
3.1 The purpose of these test methods is to establish
priate safety and health practices and determine the applica-
consensus test methods by which both manufacturers and end
bility of regulatory limitations prior to use.
users may make tests to establish the validity of the readings of
2. Terminology
their radiation thermometers. The test results can also serve as
standard performance criteria for instrument evaluation or
2.1 Definitions:
selection, or both.
2.1.1 blackbody, n—the perfect or ideal source of thermal
3.2 The goal is to provide test methods that are reliable and
radiant power having a spectral distribution described by the
can be performed by a sufficiently skilled end user or manu-
Planck equation.
facturer in the hope that it will result in a better understanding
2.1.1.1 Discussion—The term blackbody is often used to
of the operation of radiation thermometers and also promote
describe a furnace or other source of radiant power which
improved communication between the manufacturers and the
approximates the ideal.
end users. A user without sufficient knowledge and experience
2.1.2 center wavelength, n—a wavelength, usually near the
should seek assistance from the equipment makers or other
middle of the band of radiant power over which a radiation
expert sources, such as those found at the National Institute of
thermometer responds, that is used to characterize its perfor-
Standards and Technology in Gaithersburg, Maryland.
mance.
3.3 Use these test methods with the awareness that there are
2.1.2.1 Discussion—The value of the center wavelength is
other parameters, particularly spectral response limits and
usually specified by the manufacturer of the instrument.
temperature resolution, which impact the use and characteriza-
2.1.3 radiation thermometer, n—a radiometer calibrated to
tion of radiation thermometers for which test methods have not
indicate the temperature of a blackbody.
yet been developed.
2.1.4 radiometer, n—a device for measuring radiant power
3.3.1 Temperature resolution is the minimum simulated or
that has an output proportional to the intensity of the input
actual change in target temperature that results in a usable
power.
change in output or indication, or both. It is usually expressed
2.1.5 target plane, n—the plane, perpendicular to the line of
as a temperature differential or a percent of full-scale value, or
sight of a radiation thermometer, that is in focus for that
both, and usually applies to value measured. The magnitude of
instrument.
the temperature resolution depends upon a combination of four
factors: detector noise equivalent power (NEP) or noise
These test methods are under the jurisdiction of ASTM Committee E20 on
equivalent temperature, electronic signal processing, signal-to-
TemperatureMeasurementandarethedirectresponsibilityofSubcommitteeE20.02
noise characteristics (including amplification noise), and
on Radiation Thermometry.
analog-to-digital conversion “granularity.”
Current edition approved Nov. 1, 2007. Published December 2007. Originally
approved in 1988. Last previous edition approved in 2001 as E1256 – 95 (2001).
DOI: 10.1520/E1256-95R07.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.
E1256–95 (2007)
4.1.5 Aperture Set—If an iris diaphragm is not available, an
aperture disc set of appropriate diameters can be used. Each
aperture should be blackened and also mounted and protected
from extraneous sources of radiation as discussed in 4.1.4.1.
4.1.6 Data Acquisition Systems—Of appropriate speed and
storage capacity to measure and record the output signal of the
radiation thermometer in the Response Time Test Method,
Section 9.
4.1.7 Power Supply—Capable of supplying the proper volt-
age and frequency, if necessary, to the radiation thermometer.
5. Calibration Accuracy Test Method
5.1 Summary—This test method outlines the procedure to
be used to evaluate the maximum deviation between the
temperature indicated by the radiation thermometer and the
FIG. 1 Spectral Response Limits
known temperature of a reference temperature source, includ-
ing the uncertainty of the reference temperature source relative
to the current International Temperature Scale.
3.3.2 Spectral response limits are the upper and lower limits
5.2 Test Conditions:
to the wavelength band of radiant energy to which the
5.2.1 Rated supply voltage and frequency.
instrument responds. These limits are generally expressed in
micrometers (µm) and include the effects of all elements in the 5.2.2 Prescribed warm-up period.
measuring optical path. At the spectral response limits, the
5.2.3 After execution of internal standardization check (if
transmission of the measuring optics is 5 % of peak transmis-
available).
sion (see Fig. 1).
5.2.4 Emissivity compensation set to one (1).
5.2.5 Minimumopeningofthereferencetemperaturesource
4. Apparatus
shallnotobstructthefieldofviewoftheradiationthermometer
4.1 The following apparatus, set up as illustrated in Fig. 2,
with the test aperture as specified by the manufacturer.
can be used to perform the standard tests for all six parameters.
5.2.6 Laboratory ambient temperature range (20 to 25 °C).
4.1.1 Reference Temperature Source—A blackbody (or
5.2.7 Manufacturer shall specify any special conditions
other stable isothermal radiant source of high and known
such as atmospheric absorption effects, target distance, etc.
emissivity) with an opening diameter at least as large as that
5.2.8 Manufacturer shall specify the output for determining
specified in these test methods.
the indicated temperature.
NOTE 1—Typical examples include nearly isothermal furnaces with
5.3 Test Method:
internal geometries, such as a sphere with an opening small relative to its
5.3.1 The radiation thermometer is sighted at the reference
radius, or a right circular cylinder with one end closed having a radius
temperature source whose temperature is sequentially stabi-
small relative to its length. Consult footnote for greater detail.
lized at three calibration points distributed uniformly over the
4.1.2 Temperature Indicator—Either contact or radiometric,
measurement range of the instrument.
which accurately displays the temperature of the reference
5.3.2 The temperature of the reference temperature source
temperature source.
and the temperature indicated by the radiation thermometer are
4.1.3 Shutter Mechanism—Of sufficient size so as to com-
recorded, then the difference between the two values is
pletely block the opening of the reference temperature source
calculated and recorded (see Fig. 3).
from the field of view of the test instrument. The shutter
5.3.3 The test sequence is repeated twice for the same three
mechanism shall activate in a time interval that is short when
calibration points, and an average temperature difference is
compared with the response time of the test instrument.
calculated and recorded for each calibration point.
4.1.4 Iris Diaphragm—Of sufficient size so that when fully
5.4 Test Result—The value for the calibration accuracy of
open the iris diameter is greater than the opening of the
the temperature indication of the radiation thermometer is
reference temperature source. It shall be located with its
taken to be the largest of the three average temperature
opening concentric with and perpendicular to the line of sight
differencesdeterminedin5.3.2plusorminustheuncertaintyof
of the radiation thermometer.
the temperature of the reference temperature source relative to
4.1.4.1 The side of the diaphragm facing the radiation
the current International Temperature Scale.
thermometer should be blackened (nearly nonreflective) so as
to minimize the effect of radiation reflected from the surround-
NOTE 2—The calibration accuracy is generally expressed as a tempera-
ture difference or a percent of full-scale value, or both.
ing environment. In addition the iris should be shaded from
sources of intense extraneous radiation. (See Note 9). NOTE 3—The value applies across the entire measurement range.
NOTE 4—If the reference temperature source is measured with other
than a calibrated reference or secondary standard radiation thermometer,
then the emissivity of the source enters into the calibration of the test
DeWitt, D. P., and Nutter, G. D., eds., “Theory and Practice of Radiation
Thermometry,” John Wiley and Sons, New York, NY. radiation thermometer.
E1256–95 (2007)
FIG. 2 Test Method Apparatus
FIG. 3 Worksheet for Calibration Accuracy Test Method
6. Procedure 7.2 Test Conditions:
7.2.1 Rated supply of voltage and frequency.
6.1 Detailed directions for evaluation of each parameter
7.2.2 Prescribed warm-up period.
listed in 1.1 are included in each parameter test method.
7.2.3 After execution of internal standardization check (if
6.2 Each parameter test method is organized by: parameter
available).
term, summary, test conditions, test method, test result, and
7.2.4 Diameter of the reference temperature source opening
applicable notes.
shall be greater than the radiation thermometer target size, as
7. Repeatability Test Method
specified by the manufacturer.
7.2.5 Laboratory ambient temperature range (20 to 25 °C).
7.1 Summary—This test method outlines the procedure to
7.2.6 Emissivity compensation, if any, set to one (1).
be used to evaluate the repeatability of the temperature
indication of a radiation thermometer for a number of consecu- 7.2.7 Manufacturer shall specify any special conditions
tive measurements made under the same conditions over a such as response time, atmospheric absorption effects, target
specified interval of time. distance, etc.
E1256–95 (2007)
FIG. 4 Target Diameter versus Target Distance from Instrument
7.3 Test Method: 8.2.5 Minimumopeningofthereferencetemperaturesource
7.3.1 Once a day for twelve consecutive working days, the shall be large enough so as to not obstruct the optical path of
radiation thermometer is sighted at the reference temperature the radiation thermometer, as specified by the manufacturer,
source whose temperature is stabilized at the approximate whenitissightedthroughanaperturethatistwicethediameter
midpoint of the radiation thermometer calibration range. of the instrument’s target size at the plane of the aperture.
NOTE 5—The selected reference temperature source temperature shall
NOTE 8—Some radiation thermometers have a target size so large that
be reproduced for each of the twelve consecutive tests.
a commercially available reference temperature source cannot be used; a
separate test method is under preparation for use in such cases.
7.3.2 The temperature of the reference temperature source
and the temperature(s) indicated by the radiation thermometer
8.2.6 Manufacturer shall specify any special conditions
during each day’s test are recorded.
such as atmospheric absorption effects, distance, how and
7.3.3 The radiation thermometer shall be switched off after
when to clean the radiation thermometer lens, etc.
each series of measurements.
8.3 Test Method:
7.4 Test Result—The value for the repeatability of the
8.3.1 Thetemperatureofthereferencetemperaturesourceis
readings of the radiation thermometer is taken to be the
stabilized at a value near the top of the calibration range of the
standard deviation of the twelve recorded readings.
radiation thermometer.
N
8.3.2 The iris is positioned in the front of and concentric
X !
~
N N ( i
i 5 1 with the opening of the reference temperature source (as
2 2
¯
~X 2 X! X 2
( (
i i
N
i 5 1 i 5 1 illustrated in Fig. 2). The iris is then adjusted to a diameter
Œ
S.D. 5 5!
N 2 1 N 2 1
slightly smaller (typically 10 %) than the expected target
diameter.
where:
S.D. = standard deviation,
NOTE 9—The iris should be kept cool enough so that its thermal
N = number of measurements,
emissiondoesnotcontributesignificantlytotheoutputsignal.Uncovering
X = value of the ith measurement, and the iris quickly can minimize heating, but this requires care. Evaluation of
i
N
¯
X = the error from this source requires computational procedures beyond the
X
( i scope of this test method; a discussion of such procedures can be found in
i 5 1
footnote 2. In most cases, however, the error is insignificant if the iris is
average of the twelve measurements = .
N
maintained near room temperature (20 °C) and the reference temperature
NOTE 6—The repeatability of the temperature indication is generally
source temperature is at or above 200 °C.
expressed as a temperature difference or a percent of full-scale value, or
8.3.3 The position of the radiation thermometer is then
both.
NOTE 7—Thevaluefortherepeatabilitycanbeappliedacrosstheentire adjusted vertically and horizontally and focused to produce
measurement range, or, the same test can be performed at other selected
maximum output while also maintaining the line of sight
temperatures across the measurement range in order to assess the
perpendicular to the iris.
repeatability of the radiation thermometer at those temperatures.
8.3.4 The iris is then opened to the point where the
temperature indicated by the radiation thermometer stops
8. Target Size
...


This document is not an ASTM standard and is intended only to provide the user of an ASTM standard an indication of what changes have been made to the previous version. Because
it may not be technically possible to adequately depict all changes accurately, ASTM recommends that users consult prior editions as appropriate. In all cases only the current version
of the standard as published by ASTM is to be considered the official document.
Designation:E1256–95 (Reapproved 2001) Designation:E1256–95 (Reapproved 2007)
Standard Test Methods for
Radiation Thermometers (Single Waveband Type)
This standard is issued under the fixed designation E 1256; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (e) indicates an editorial change since the last revision or reapproval.
1. Scope
1.1 The test methods described in these test methods can be utilized to evaluate the following six basic operational parameters
of a radiation thermometer (single waveband type):
Section
Calibration Accuracy 7
Repeatability 8
Target Size 9
Response Time 10
Warm-Up Time 11
Long-Term Drift 12
1.2 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility
of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory
limitations prior to use.
2. Terminology
2.1 Definitions:
2.1.1 blackbody, n—the perfect or ideal source of thermal radiant power having a spectral distribution described by the Planck
equation.
2.1.1.1 Discussion—The term blackbody is often used to describe a furnace or other source of radiant power which
approximates the ideal.
2.1.2 center wavelength, n—a wavelength, usually near the middle of the band of radiant power over which a radiation
thermometer responds, that is used to characterize its performance.
2.1.2.1 Discussion—The value of the center wavelength is usually specified by the manufacturer of the instrument.
2.1.3 radiation thermometer, n—a radiometer calibrated to indicate the temperature of a blackbody.
2.1.4 radiometer, n—a device for measuring radiant power that has an output proportional to the intensity of the input power.
2.1.5 target plane, n—theplane,perpendiculartothelineofsightofaradiationthermometer,thatisinfocusforthatinstrument.
2.2 Definitions of Terms Specific to This Standard:
2.2.1 reference temperature source, n—a source of thermal radiant power of known temperature or emissivity, or both, used in
the testing of radiation thermometers.
2.2.2 target size, n—the diameter of a circle in the target plane of a radiation thermometer that is centered on its line of sight
and contains 99 % of the input radiant power received by that instrument.
2.2.3 temperature resolution, n—the minimum simulated or actual change in target temperature that gives a usable change in
output or indication, or both.
3. Significance and Use
3.1 The purpose of these test methods is to establish consensus test methods by which both manufacturers and end users may
make tests to establish the validity of the readings of their radiation thermometers. The test results can also serve as standard
performance criteria for instrument evaluation or selection, or both.
3.2 The goal is to provide test methods that are reliable and can be performed by a sufficiently skilled end user or manufacturer
in the hope that it will result in a better understanding of the operation of radiation thermometers and also promote improved
communication between the manufacturers and the end users. A user without sufficient knowledge and experience should seek
These test methods are under the jurisdiction of ASTM Committee E20 on Temperature Measurement and are the direct responsibility of Subcommittee E20.02 on
Radiation Thermometry.
Current edition approved Oct. 10, 1995. Published January 1996. Originally published as E1256–88. Last previous edition E1256–88.
Current edition approved Nov. 1, 2007. Published December 2007. Originally approved in 1988. Last previous edition approved in 2001 as E 1256 – 95 (2001).
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.
E1256–95 (2007)
assistance from the equipment makers or other expert sources, such as those found at the National Institute of Standards and
Technology in Gaithersburg, Maryland.
3.3 Use these test methods with the awareness that there are other parameters, particularly spectral response limits and
temperature resolution, which impact the use and characterization of radiation thermometers for which test methods have not yet
been developed.
3.3.1 Temperature resolution is the minimum simulated or actual change in target temperature that results in a usable change
in output or indication, or both. It is usually expressed as a temperature differential or a percent of full-scale value, or both, and
usually applies to value measured. The magnitude of the temperature resolution depends upon a combination of four factors:
detectornoiseequivalentpower(NEP)ornoiseequivalenttemperature,electronicsignalprocessing,signal-to-noisecharacteristics
(including amplification noise), and analog-to-digital conversion “granularity.”
3.3.2 Spectral response limits are the upper and lower limits to the wavelength band of radiant energy to which the instrument
responds.These limits are generally expressed in micrometers (µm) and include the effects of all elements in the measuring optical
path. At the spectral response limits, the transmission of the measuring optics is 5 % of peak transmission (see Fig. 1).
4. Apparatus
4.1 The following apparatus, set up as illustrated in Fig. 2, can be used to perform the standard tests for all six parameters.
4.1.1 Reference Temperature Source—A blackbody (or other stable isothermal radiant source of high and known emissivity)
with an opening diameter at least as large as that specified in these test methods.
NOTE 1—Typical examples include nearly isothermal furnaces with internal geometries, such as a sphere with an opening small relative to its radius,
or a right circular cylinder with one end closed having a radius small relative to its length. Consult footnote for greater detail.
4.1.2 Temperature Indicator—Either contact or radiometric, which accurately displays the temperature of the reference
temperature source.
4.1.3 Shutter Mechanism—Of sufficient size so as to completely block the opening of the reference temperature source from
the field of view of the test instrument. The shutter mechanism shall activate in a time interval that is short when compared with
the response time of the test instrument.
4.1.4 Iris Diaphragm—Of sufficient size so that when fully open the iris diameter is greater than the opening of the reference
temperature source. It shall be located with its opening concentric with and perpendicular to the line of sight of the radiation
thermometer.
4.1.4.1 Thesideofthediaphragmfacingtheradiationthermometershouldbeblackened(nearlynonreflective)soastominimize
the effect of radiation reflected from the surrounding environment. In addition the iris should be shaded from sources of intense
extraneous radiation. (See Note 9).
4.1.5 Aperture Set—If an iris diaphragm is not available, an aperture disc set of appropriate diameters can be used. Each
aperture should be blackened and also mounted and protected from extraneous sources of radiation as discussed in 4.1.4.1.
4.1.6 Data Acquisition Systems—Of appropriate speed and storage capacity to measure and record the output signal of the
radiation thermometer in the Response Time Test Method, Section 9.
4.1.7 Power Supply—Capable of supplying the proper voltage and frequency, if necessary, to the radiation thermometer.
5. Calibration Accuracy Test Method
5.1 Summary—This test method outlines the procedure to be used to evaluate the maximum deviation between the temperature
DeWitt, D. P., and Nutter, G. D., eds., “Theory and Practice of Radiation Thermometry,” John Wiley and Sons, New York, NY.
FIG. 1 Spectral Response Limits
E1256–95 (2007)
FIG. 2 Test Method Apparatus
indicated by the radiation thermometer and the known temperature of a reference temperature source, including the uncertainty of
the reference temperature source relative to the current International Temperature Scale.
5.2 Test Conditions:
5.2.1 Rated supply voltage and frequency.
5.2.2 Prescribed warm-up period.
5.2.3 After execution of internal standardization check (if available).
5.2.4 Emissivity compensation set to one (1).
5.2.5 Minimum opening of the reference temperature source shall not obstruct the field of view of the radiation thermometer
with the test aperture as specified by the manufacturer.
5.2.6 Laboratory ambient temperature range (20 to 25 °C).
5.2.7 Manufacturer shall specify any special conditions such as atmospheric absorption effects, target distance, etc.
5.2.8 Manufacturer shall specify the output for determining the indicated temperature.
5.3 Test Method:
5.3.1 The radiation thermometer is sighted at the reference temperature source whose temperature is sequentially stabilized at
three calibration points distributed uniformly over the measurement range of the instrument.
5.3.2 The temperature of the reference temperature source and the temperature indicated by the radiation thermometer are
recorded, then the difference between the two values is calculated and recorded (see Fig. 3).
5.3.3 The test sequence is repeated twice for the same three calibration points, and an average temperature difference is
calculated and recorded for each calibration point.
5.4 Test Result—The value for the calibration accuracy of the temperature indication of the radiation thermometer is taken to
be the largest of the three average temperature differences determined in 5.3.2 plus or minus the uncertainty of the temperature
of the reference temperature source relative to the current International Temperature Scale.
NOTE 2—The calibration accuracy is generally expressed as a temperature difference or a percent of full-scale value, or both.
NOTE 3—The value applies across the entire measurement range.
NOTE 4—If the reference temperature source is measured with other than a calibrated reference or secondary standard radiation thermometer, then the
emissivity of the source enters into the calibration of the test radiation thermometer.
6. Procedure
6.1 Detailed directions for evaluation of each parameter listed in 1.1 are included in each parameter test method.
6.2 Each parameter test method is organized by: parameter term, summary, test conditions, test method, test result, and
applicable notes.
7. Repeatability Test Method
7.1 Summary—This test method outlines the procedure to be used to evaluate the repeatability of the temperature indication of
a radiation thermometer for a number of consecutive measurements made under the same conditions over a specified interval of
time.
7.2 Test Conditions:
7.2.1 Rated supply of voltage and frequency.
7.2.2 Prescribed warm-up period.
E1256–95 (2007)
FIG. 3 Worksheet for Calibration Accuracy Test Method
7.2.3 After execution of internal standardization check (if available).
7.2.4 Diameter of the reference temperature source opening shall be greater than the radiation thermometer target size, as
specified by the manufacturer.
7.2.5 Laboratory ambient temperature range (20 to 25 °C).
7.2.6 Emissivity compensation, if any, set to one (1).
7.2.7 Manufacturer shall specify any special conditions such as response time, atmospheric absorption effects, target distance,
etc.
7.3 Test Method:
7.3.1 Once a day for twelve consecutive working days, the radiation thermometer is sighted at the reference temperature source
whose temperature is stabilized at the approximate midpoint of the radiation thermometer calibration range.
NOTE 5—The selected reference temperature source temperature shall be reproduced for each of the twelve consecutive tests.
7.3.2 The temperature of the reference temperature source and the temperature(s) indicated by the radiation thermometer during
each day’s test are recorded.
7.3.3 The radiation thermometer shall be switched off after each series of measurements.
7.4 Test Result—Thevaluefortherepeatabilityofthereadingsoftheradiationthermometeristakentobethestandarddeviation
of the twelve recorded readings.
N
~ X !
N N (
i
i 5 1
2 2
¯
~X 2X! X 2
( (
i i
N
i 5 1 i 5 1
Œ
S.D. 5 5!
N 2 1 N 2 1
N
~ X !
(
N N i
i 5 1
2 2
~X 2¯X! X 2
( i ( i
N
i 5 1 i 5 1
Œ
!
S.D. 5 5
N 2 1 N 2 1
where:
S.D. = standard deviation,
N = number of measurements,
X = value of the ith measurement, and
i
E1256–95 (2007)
N
¯
X =
X
(
i
i 5 1
average of the twelve measurements = .
N
NOTE 6—The repeatability of the temperature indication is generally expressed as a temperature difference or a percent of full-scale value, or both.
NOTE 7—The value for the repeatability can be applied across the entire measurement range, or, the same test can be performed at other selected
temperatures across the measurement range in order to assess the repeatability of the radiation thermometer at those temperatures.
8. Target Size Test Method
8.1 Summary—This test method outlines the procedure to be used to evaluate the diameter of the circle located in the target
plane of the reference temperature source, at a known distance along and perpendicular to a radiation thermometer’s line of sight,
and from which 99 % of the radiant power received by the radiation thermometer is collected (see Figs. 3 and 4).
8.2 Test Conditions:
8.2.1 Rated supply voltage and frequency.
8.2.2 Prescribed warm-up period.
8.2.3 After execution of internal standardization check (if applicable).
8.2.4 Laboratory ambient temperature range (20 to 25 °C).
8.2.5 Minimum opening of the reference temperature source shall be large enough so as to not obstruct the optical path of the
radiation thermometer, as specified by the manufacturer, when it is sighted through an aperture that is twice the diameter of the
instrument’s target size at the plane of the aperture.
NOTE 8—Someradiationthermometershaveatargetsizesolargethatacommerciallyavailablereferencetemperaturesourcecannotbeused;aseparate
test method is under preparation for use in such cases.
8.2.6 Manufacturer shall specify any special conditions such as atmospheric absorption effects, distance, how and when to clean
the radiation thermometer lens, etc.
8.3 Test Method:
8.3.1 The temperature of the reference temperature source is stabilized at a value near the top of the calibration range of the
radiation thermometer.
8.3.2 The iris is
...

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ASTM E344-23(Terminology)
Terminology Relating to Thermometry and Hydrometry

SCOPE
1.1 This terminology is a compilation of definitions of terms used by ASTM Committee E20 on Temperature Measurement.  
1.2 Terms with definitions generally applicable to the fields of thermometry and hydrometry are listed in 3.1.  
1.3 Terms with definitions applicable only to the indicated standards in which they appear are listed in 3.2.  
1.4 Information about the International Temperature Scale of 1990 is given in Appendix X1.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E839-23(Test Method)
Standard Test Methods for Sheathed Thermocouples and Sheathed Thermocouple Cable

SIGNIFICANCE AND USE
5.1 This standard provides a description of test methods used in other ASTM specifications to establish certain acceptable methods for characterizing thermocouple assemblies and thermocouple cable. These test methods define how those characteristics shall be determined.  
5.2 The usefulness and purpose of the included tests are given for the category of tests.  
5.3 Warning—Users should be aware that certain characteristics of thermocouples might change with time and use. If a thermocouple’s designed shipping, storage, installation, or operating temperature has been exceeded, that thermocouple’s moisture seal may have been compromised and may no longer adequately prevent the deleterious intrusion of water vapor. Consequently, the thermocouple’s condition established by test at the time of manufacture may not apply later. In addition, inhomogeneities can develop in thermoelements because of exposure to higher temperatures, even in cases where maximum exposure temperatures have been lower than the suggested upper use temperature limits specified in Table 1 of Specification E608/E608M. For this reason, calibration of thermocouples destined for delivery to a customer is not recommended. Because the emf indication of any thermocouple depends upon the condition of the thermoelements along their entire length, as well as the temperature profile pattern in the region of any inhomogeneity, the emf output of a used thermocouple will be unique to its installation. Because temperature profiles in calibration equipment are unlikely to duplicate those of the installation, removal of a used thermocouple to a separate apparatus for calibration is not recommended. Instead, in situ calibration by comparison to a similar thermocouple known to be good is often recommended.
SCOPE
1.1 This document lists methods for testing Mineral-Insulated, Metal-Sheathed (MIMS) thermocouple assemblies and thermocouple cable, but does not require that any of these tests be performed nor does it state criteria for acceptance. The acceptance criteria are given in other ASTM standard specifications that impose this testing for those thermocouples and cable. Examples from ASTM thermocouple specifications for acceptance criteria are given for many of the tests. These tabulated values are not necessarily those that would be required to meet these tests, but are included as examples only.  
1.2 These tests are intended to support quality control and to evaluate the suitability of sheathed thermocouple cable or assemblies for specific applications. Some alternative test methods to obtain the same information are given, since in a given situation, an alternative test method may be more practical. Service conditions are widely variable, so it is unlikely that all the tests described will be appropriate for a given thermocouple application. A brief statement is made following each test description to indicate when it might be used.  
1.3 The tests described herein include test methods to measure the following properties of sheathed thermocouple material and assemblies.  
1.3.1 Insulation Properties:  
1.3.1.1 Compaction—direct method, absorption method, and tension method.
1.3.1.2 Thickness.
1.3.1.3 Resistance—at room temperature and at elevated temperature.  
1.3.2 Sheath Properties:  
1.3.2.1 Integrity—two water test methods and mass spectrometer.
1.3.2.2 Dimensions—length, diameter, and roundness.
1.3.2.3 Wall thickness.
1.3.2.4 Surface—gross visual, finish, defect detection by dye penetrant, and cold-lap detection by tension test.
1.3.2.5 Metallurgical structure.
1.3.2.6 Ductility—bend test and tension test.  
1.3.3 Thermoelement Properties:  
1.3.3.1 Calibration.
1.3.3.2 Homogeneity.
1.3.3.3 Drift.
1.3.3.4 Thermoelement diameter, roundness, and surface appearance.
1.3.3.5 Thermoelement spacing.
1.3.3.6 Thermoelement ductility.
1.3.3.7 Metallurgical structure.  
1.3.4 Thermocouple Assembly Properti...

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ASTM E230/E230M-23a(Specification)
Standard Specification for Temperature-Electromotive Force (emf) Tables for Standardized Thermocouples

ABSTRACT
This specification contains reference tables that give temperature-electromotive force (emf) relationships for types B, E, J, K, N, R, S, T, and C thermocouples. These are the thermocouple types most commonly used in industry. Thermocouples and matched thermocouple wire pairs are normally supplied to the tolerances on initial values of emf versus temperature. Color codes for insulation on thermocouple grade materials, along with corresponding thermocouple and thermoelement letter designations are given. Four types of tables are presented: general tables, EMF versus temperature tables for thermocouples, EMF versus temperature tables for thermoelements, and supplementary tables.
SCOPE
1.1 This specification contains reference tables (Tables 8 to 25) that give temperature-electromotive force (emf) relationships for Types B, C, E, J, K, N, R, S, and T thermocouples.2 These are the thermocouple types most commonly used in industry. The tables contain all of the temperature-emf data currently available for the thermocouple types covered by this standard and may include data outside of the recommended upper temperature limit of an included thermocouple type.  
1.2 In addition, the specification includes standard and special tolerances on initial values of emf versus temperature for thermocouples (Table 1), thermocouple extension wires (Table 2), and compensating extension wires for thermocouples (Table 3). Users should note that the stated tolerances apply only to the temperature ranges specified for the thermocouple types as given in Tables 1, 2, and 3, and do not apply to the temperature ranges covered in Tables 8 to 25.  
1.3 Tables 4 and 5 provide insulation color coding for thermocouple and thermocouple extension wires as customarily used in the United States.  
1.4 Recommendations regarding upper temperature limits for the thermocouple types referred to in 1.1 are provided in Table 6.  
1.5 Tables 26 to 45 give temperature-emf data for single-leg thermoelements referenced to platinum (NIST Pt-67). The tables include values for Types BP, BN, JP, JN, KP (same as EP), KN, NP, NN, TP, and TN (same as EN).  
1.6 Tables for Types RP, RN, SP, and SN thermoelements are not included since, nominally, Tables 18 to 21 represent the thermoelectric properties of Type RP and SP thermoelements referenced to pure platinum. Tables for the individual thermoelements of Type C are not included because materials for Type C thermocouples are normally supplied as matched pairs only.  
1.7 Polynomial coefficients which may be used for computation of thermocouple emf as a function of temperature are given in Table 7. Coefficients for the emf of each thermocouple pair as well as for the emf of most individual thermoelements versus platinum are included. Coefficients for type RP and SP thermoelements are not included since they are nominally the same as for types R and S thermocouples, and coefficients for type RN or SN relative to the nominally similar Pt-67 would be insignificant. Coefficients for the individual thermoelements of Type C thermocouples have not been established.  
1.8 Coefficients for sets of inverse polynomials are given in Table 46. These may be used for computing a close approximation of temperature (°C) as a function of thermocouple emf. Inverse functions are provided only for thermocouple pairs and are valid only over the emf ranges specified.  
1.9 This specification is intended to define the thermoelectric properties of materials that conform to the relationships presented in the tables of this standard and bear the letter designations contained herein. Topics such as ordering information, physical and mechanical properties, workmanship, testing, and marking are not addressed in this specification. The user is referred to specific standards such as Specifications E235, E574, E585/E585M, E608/E608M, E1159, or E2181/E2181M for guidance in these areas.  
1.10 The temperature-emf data in this specifica...

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ASTM E1750-23(Guide)
Standard Guide for Use of Water Triple Point Cells

SIGNIFICANCE AND USE
4.1 This guide describes a procedure for placing a water triple-point cell in service and for using it as a reference temperature in thermometer calibration.  
4.2 The reference temperature attained is that of a fundamental state of pure water, the equilibrium between coexisting solid, liquid, and vapor phases.  
4.3 The cell is subject to qualification but not to calibration. The cell may be qualified as capable of representing the fundamental state (see 4.2) by comparison with a bank of similar qualified cells of known history, and it may be so qualified and the qualification documented by its manufacturer.  
4.4 The temperature to be attributed to a qualified water triple-point cell is exactly 273.16 K on the ITS-90, unless corrected for isotopic composition (refer to Appendix X3).  
4.5 Continued accuracy of a qualified cell depends upon sustained physical integrity. This may be verified by techniques described in Section 6.  
4.6 The commercially available triple point of water cells described in this standard are capable of achieving an expanded uncertainty (k=2) of between ±0.1 mK and ±0.05 mK, depending upon the method of preparation. Specified measurement procedures shall be followed to achieve these levels of uncertainty.  
4.7 Commercially-available triple point of water cells of unknown isotopic composition should be capable of achieving an expanded uncertainty (k=2) of no greater than 0.25 mK, depending upon the actual isotopic composition (3). These types of cells are acceptable for use at this larger value of uncertainty.
SCOPE
1.1 This guide covers the nature of two commercial water triple-point cells (types A and B, see Fig. 1) and provides a method for preparing the cell to realize the water triple-point and calibrate thermometers. The qualifications concerning preparation and the types of glass used for a cell are discussed. Tests for assuring the integrity of a qualified cell and of cells yet to be qualified are given. Precautions for handling the cell to avoid breakage are also described.  
FIG. 1 Configurations of two commonly used triple point of water cells, Type A and Type B, with ice mantle prepared for measurement at the ice/water equilibrium temperature. The cells are used immersed in an ice bath or water bath controlled close to 0.01 °C (see 5.5)  
1.2 The effect of hydrostatic pressure on the temperature of a water triple-point cell is discussed.  
1.3 Procedures for adjusting the observed SPRT resistance readings for the effects of self-heating and hydrostatic pressure are described in Appendix X1 and Appendix X2.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E452-02(2023)(Test Method)
Standard Test Method for Calibration of Refractory Metal Thermocouples Using a Radiation Thermometer

SIGNIFICANCE AND USE
5.1 This test method is intended to be used by wire producers and thermocouple manufacturers for certification of refractory metal thermocouples. It is intended to provide a consistent method for calibration of refractory metal thermocouples referenced to a calibrated radiation thermometer. Uncertainty in calibration and operation of the radiation thermometer, and proper construction and use of the test furnace are of primary importance.  
5.2 Calibration establishes the temperature-emf relationship for a particular thermocouple under a specific temperature and chemical environment. However, during high temperature calibration or application at elevated temperatures in vacuum, oxidizing, reducing or contaminating environments, and depending on temperature distribution, local irreversible changes may occur in the Seebeck Coefficient of one or both thermoelements. If the introduced inhomogeneities are significant, the emf from the thermocouple will depend on the distribution of temperature between the measuring and reference junctions.  
5.3 At high temperatures, the accuracy of refractory metal thermocouples may be limited by electrical shunting errors through the ceramic insulators of the thermocouple assembly. This effect may be reduced by careful choice of the insulator material, but above approximately 2100 °C, the electrical shunting errors may be significant even for the best insulators available.
SCOPE
1.1 This test method covers the calibration of refractory metal thermocouples using a radiation thermometer as the standard instrument. This test method is intended for use with types of thermocouples that cannot be exposed to an oxidizing atmosphere. These procedures are appropriate for thermocouple calibrations at temperatures above 800 °C (1472 °F).  
1.2 The calibration method is applicable to the following thermocouple assemblies:  
1.2.1 Type 1—Bare-wire thermocouple assemblies in which vacuum or an inert or reducing gas is the only electrical insulating medium between the thermoelements.  
1.2.2 Type 2—Assemblies in which loose fitting ceramic insulating pieces, such as single-bore or double-bore tubes, are placed over the thermoelements.  
1.2.3 Type 2A—Assemblies in which loose fitting ceramic insulating pieces, such as single-bore or double-bore tubes, are placed over the thermoelements, permanently enclosed and sealed in a loose fitting metal or ceramic tube.  
1.2.4 Type 3—Swaged assemblies in which a refractory insulating powder is compressed around the thermoelements and encased in a thin-walled tube or sheath made of a high melting point metal or alloy.  
1.2.5 Type 4—Thermocouple assemblies in which one thermoelement is in the shape of a closed-end protection tube and the other thermoelement is a solid wire or rod that is coaxially supported inside the closed-end tube. The space between the two thermoelements can be filled with an inert or reducing gas, or with ceramic insulating materials, or kept under vacuum.  
1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.4 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E1350-18(2023)(Guide)
Standard Guide for Testing Sheathed Thermocouples, Thermocouple Assemblies, and Connecting Wires Prior to, and After Installation or Service

SIGNIFICANCE AND USE
5.1 These test procedures confirm and document that the thermocouple assembly was not damaged prior to or during the installation process and that the extension wires are properly connected.  
5.2 The test procedures should be used when thermocouple assemblies are first installed in their working environment.  
5.3 In the event of subsequent thermocouple failure, these procedures will provide benchmark data to verify failure and may help to identify the cause of failure.  
5.4 The usefulness and purpose of the applicable tests will be found within each category.  
5.5 These tests are not meant to ensure that the thermocouple assembly will measure temperatures accurately. Such assurance is derived from proper thermocouple and instrumentation selection and proper placement in the location at which the temperature is to be measured. For further information, the reader is directed to MNL 12, Manual on the Use of the Thermocouples in Temperature Measurement2 which is an excellent reference document on metal sheathed thermocouple uses.
SCOPE
1.1 This guide covers methods for users to test metal sheathed thermocouple assemblies, including the extension wires just prior to and after installation or some period of service.  
1.2 The tests are intended to ensure that the thermocouple assemblies have not been damaged during storage or installation, to ensure that the extension wires have been attached to connectors and terminals with the correct polarity, and to provide benchmark data for later reference when testing to assess possible damage of the thermocouple assembly after operation. Some of these tests may not be appropriate for thermocouples that have been exposed to temperatures higher than the recommended limits for the particular type.  
1.3 The tests described herein include methods to measure the following characteristics of installed sheathed thermocouple assemblies and to provide benchmark data for determining if the thermocouple assembly has been subsequently damaged in operation:  
1.3.1 Loop Resistance:  
1.3.1.1 Thermoelements,
1.3.1.2 Combined extension wires and thermoelements.  
1.3.2 Insulation Resistance:  
1.3.2.1 Insulation, thermocouple assembly,
1.3.2.2 Insulation, thermocouple assembly and extension wires.  
1.3.3 Seebeck Voltage:  
1.3.3.1 Thermoelements,
1.3.3.2 Combined extension wires and thermocouple assembly.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E2593-17(2023)(Guide)
Standard Guide for Accuracy Verification of Industrial Platinum Resistance Thermometers

SIGNIFICANCE AND USE
5.1 This guide is intended to be used for verifying the resistance-temperature relationship of industrial platinum resistance thermometers that are intended to satisfy the requirements of Specification E1137/E1137M. It is intended to provide a consistent method for calibration and uncertainty evaluation while still allowing the user some flexibility in the choice of apparatus and instrumentation. It is understood that the limits of uncertainty obtained depend in large part upon the apparatus and instrumentation used. Therefore, since this guide is not prescriptive in approach, it provides detailed instruction in uncertainty evaluation to accommodate the variety of apparatus and instrumentation that may be employed.  
5.2 This guide is intended primarily to satisfy applications requiring compliance to Specification E1137/E1137M. However, the techniques described may be appropriate for applications where more accurate calibrations are needed.  
5.3 Many applications require tolerances to be verified using a minimum test uncertainty ratio (TUR). This standard provides guidelines for evaluating uncertainties used to support TUR calculations.
SCOPE
1.1 This guide describes the techniques and apparatus required for the accuracy verification of industrial platinum resistance thermometers constructed in accordance with Specification E1137/E1137M and the evaluation of calibration uncertainties. The procedures described apply over the range of -200 °C to 650 °C.  
1.2 This guide does not intend to describe procedures necessary for the calibration of platinum resistance thermometers used as calibration standards or Standard Platinum Resistance Thermometers. Consequently, calibration of these types of instruments is outside the scope of this guide.  
1.3 Industrial platinum resistance thermometers are available in many styles and configurations. This guide does not purport to determine the suitability of any particular design, style, or configuration for calibration over a desired temperature range.  
1.4 The evaluation of uncertainties is based upon current international practices as described in JCGM 100:2008 “Evaluation of measurement data—Guide to the expression of uncertainty in measurement” and ANSI/NCSL Z540.2-1997 “U.S. Guide to the Expression of Uncertainty in Measurement.”  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E696-23(Specification)
Standard Specification for Tungsten-Rhenium Alloy Thermocouple Wire

ABSTRACT
This specification covers the requirements for bare solid conductors made of tungsten and rhenium alloy thermoelements supplied in matched pairs. These thermoelements shall be suitable for use in either bead-insulated, bare-wire thermocouples, or in compacted metal-sheathed, ceramic insulated thermocouple material or assemblies. Unless otherwise noted, all information in this specification applies to both thermocouple combinations of tungsten-3 % rhenium versus tungsten-25 % rhenium (W3Re/W25Re) and tungsten-5 % rhenium versus tungsten-26 % rhenium (W5Re/W26Re; Type C). Thermoelements should meet specified physical, mechanical, thermoelectric, and compositional requirements.
SCOPE
1.1 This specification covers the requirements for bare, solid conductor, tungsten and rhenium alloy thermoelements having diameters of 0.127 mm (0.005 in.) to 0.508 mm (0.020 in.) supplied in matched pairs. These thermoelements shall be suitable for use either in bead-insulated, bare-wire thermocouples, or in compacted metal-sheathed, ceramic insulated thermocouple material or assemblies.  
1.2 This specification covers the thermocouple combinations of tungsten-3 % rhenium versus tungsten-25 % rhenium (W3Re/W25Re) and tungsten-5 % rhenium versus tungsten-26 % rhenium (W5Re/W26Re; Type C). All information applies to both combinations unless otherwise noted.  
1.3 It is recognized that the alloys described are refractory and are not suitable for use at high temperatures in oxidizing atmospheres. All tests and processes described herein must be performed under conditions that are non-reactive to tungsten-rhenium alloys.  
1.4 The values stated in SI units are to be regarded as the standard. The values given in parentheses are for information only.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E585/E585M-23(Specification)
Standard Specification for Compacted Mineral-Insulated, Metal-Sheathed, Base Metal Thermocouple Cable

ABSTRACT
This specification establishes the required material, processing and testing requirements, and also the optional supplementary testing and quality assurance and verification choices for compacted, mineral-insulated, metal-sheathed, base metal thermocouple cables with at least two thermoelements. The material of construction includes standard base metal thermoelements, austenitic stainless steel or other corrosion resistant sheath material, and either magnesia (MgO) or alumina (Al2O3) insulation. The required tests to which the thermocouple cables shall undergo for quality verification are dimensions, insulation resistance at room temperature, calibration, electrical continuity, insulation density, sheath integrity, and EMF versus temperature values.
SCOPE
1.1 This specification establishes requirements for compacted, mineral-insulated, metal-sheathed (MIMS), base metal thermocouple cable,2 with at least two thermoelements.3  
1.2 This specification describes the required material, processing and testing requirements, optional supplementary testing, quality assurance, and verification choices.  
1.3 The material of construction includes standard base metal thermoelements, austenitic stainless steel or other corrosion resistant sheath material, and either magnesia (MgO) or alumina (Al2O3) insulation.  
1.4 The values stated in either SI units or inch-pound units are to be regarded separately as standard. The values stated in each system may not be exact equivalents; therefore, each system shall be used independently of the other. Combining values from the two systems may result in non-conformance with the standard.  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM E235/E235M-23(Specification)
Standard Specification for Type K and Type N Mineral-Insulated, Metal-Sheathed Thermocouples for Nuclear or for Other High-Reliability Applications

ABSTRACT
This specification covers the requirements for sheathed, Type K and N thermocouples for nuclear service. This specification can be used for sheathed thermocouples which are required for laboratory or general commercial applications where the environmental conditions exceed normal service requirements. The measuring junction styles for thermocouples are as follows: Style G2 (grounded) in which measuring junction is electrically connected to conductive sheaths and Style U2 (ungrounded) in which measuring junctions are electrically isolated from conductive sheaths and from reference ground. Different properties of the sheath such as integrity, cracks, voids, inclusions, surface finish, surface defect, and metallurgical structure shall be determined by performing different tests. Insulation resistance between thermoelements and the sheath shall be measured as well.
SCOPE
1.1 This specification covers the requirements for simplex, compacted mineral-insulated, metal-sheathed (MIMS), Type K and N thermocouples for nuclear or other high reliability service. Depending on size, these thermocouples are normally suitable for operating temperatures to 1652 °F [900 °C]; special conditions of environment and life expectancy may permit their use at temperatures in excess of 2012 °F [1100 °C]. This specification was prepared to detail requirements for this type of MIMS thermocouple for use in nuclear environments, but they can also be used for laboratory or general commercial applications where the environmental conditions exceed normal service requirements. The intended use of a MIMS thermocouple in a specific nuclear application will require evaluation of the compatibility of the thermocouple, including the effect of the temperature, atmosphere, and integrated neutron flux on the materials and accuracy of the thermoelements in the proposed application by the purchaser.  
1.2 This specification does not attempt to include all possible specifications, standards, etc., for materials that may be used as sheathing, insulation, and thermocouple wires for sheathed-type construction. The requirements of this specification include only the austenitic stainless steels and other alloys as allowed by Specification E585/E585M for sheathing, magnesium oxide or aluminum oxide as insulation, and Type K and N thermocouple wires for thermoelements (see Note 1).  
1.3 General Design—Nominal sizes of the finished thermocouples shall be 0.0400 in., 0.0625 in., 0.125 in., 0.1875 in., or 0.250 in. [1.000 mm, 1.500 mm, 3.000 mm, 4.500 mm, or 6.000 mm]. Sheath dimensions and tolerances for each nominal size shall be in accordance with Table 1 and Figs. 1 and 2. The measuring junction styles for thermocouples covered by this specification are as follows:  
FIG. 1 Grounded Measuring Junction, Style G  
FIG. 2 Ungrounded Measuring Junction, Style U  
1.3.1 Style G2  (grounded)—The measuring junction is electrically connected to its conductive sheath, and  
1.3.2 Style U2 (ungrounded)—The measuring junction is electrically isolated from its conductive sheath and from reference ground.  
1.4 The values stated in either SI units or inch-pound units are to be regarded separately as standard. The values stated in each system are not exact equivalents or conversions; therefore, each system shall be used independently of the other. Combining values from the two systems may result in non-conformance with the standard.  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recomm...

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