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ASTM E459-05(2011)

(Test Method)

Standard Test Method for Measuring Heat Transfer Rate Using a Thin-Skin Calorimeter

Standard Test Method for Measuring Heat Transfer Rate Using a Thin-Skin Calorimeter

SIGNIFICANCE AND USE
This test method may be used to measure the heat transfer rate to a metallic or coated metallic surface for a variety of applications, including:
Measurements of aerodynamic heating when the calorimeter is placed into a flow environment, such as a wind tunnel or an arc jet; the calorimeters can be designed to have the same size and shape as the actual test specimens to minimize heat transfer corrections;
Heat transfer measurements in fires and fire safety testing;
Laser power and laser absorption measurements; as well as,
X-ray and particle beam (electrons or ions) dosimetry measurements.
The thin-skin calorimeter is one of many concepts used to measure heat transfer rates. It may be used to measure convective, radiative, or combinations of convective and radiative (usually called mixed or total) heat transfer rates. However, when the calorimeter is used to measure radiative or mixed heat transfer rates, the absorptivity and reflectivity of the surface should be measured over the expected radiation wavelength region of the source.
In 4.6 and 4.7, it is demonstrated that lateral heat conduction effects on a local measurement can be minimized by using a calorimeter material with a low thermal conductivity. Alternatively, a distribution of the heat transfer rate may be obtained by placing a number of thermocouples along the back surface of the calorimeter.
In high temperature or high heat transfer rate applications, the principal drawback to the use of thin-skin calorimeters is the short exposure time necessary to ensure survival of the calorimeter such that repeat measurements can be made with the same sensor. When operation to burnout is necessary to obtain the desired heat flux measurements, thin-skin calorimeters are often a good choice because they are relatively inexpensive to fabricate.
FIG. 1 Typical Thin-Skin Calorimeter for Heat Transfer Measurement
SCOPE
1.1 This test method covers the design and use of a thin metallic calorimeter for measuring heat transfer rate (also called heat flux). Thermocouples are attached to the unexposed surface of the calorimeter. A one-dimensional heat flow analysis is used for calculating the heat transfer rate from the temperature measurements. Applications include aerodynamic heating, laser and radiation power measurements, and fire safety testing.
1.2 Advantages:  
1.2.1 Simplicity of Construction—The calorimeter may be constructed from a number of materials. The size and shape can often be made to match the actual application. Thermocouples may be attached to the metal by spot, electron beam, or laser welding.
1.2.2 Heat transfer rate distributions may be obtained if metals with low thermal conductivity, such as some stainless steels, are used.
1.2.3 The calorimeters can be fabricated with smooth surfaces, without insulators or plugs and the attendant temperature discontinuities, to provide more realistic flow conditions for aerodynamic heating measurements.
1.2.4 The calorimeters described in this test method are relatively inexpensive. If necessary, they may be operated to burn-out to obtain heat transfer information.
1.3 Limitations:  
1.3.1 At higher heat flux levels, short test times are necessary to ensure calorimeter survival.
1.3.2 For applications in wind tunnels or arc-jet facilities, the calorimeter must be operated at pressures and temperatures such that the thin-skin does not distort under pressure loads. Distortion of the surface will introduce measurement errors.
1.4 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.
1.4.1 Exception—The values given in parentheses are for information only.
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 and health practices and determine the applicabil...

General Information

Status
Historical
Publication Date
30-Sep-2011
ICS
17.200.10 - Heat. Calorimetry
Technical Committee
E21 - Space Simulation and Applications of Space Technology
Drafting Committee
E21.08 - Thermal Protection
Current Stage
Ref Project

Relations

Replaces
ASTM E459-05 - Standard Test Method for Measuring Heat Transfer Rate Using a Thin-Skin Calorimeter
Effective Date
01-Oct-2011
Referred By
ASTM E458-08(2020) - Standard Test Method for Heat of Ablation
Effective Date
01-Oct-2011
Referred By
ASTM E1529-22 - Standard Test Methods for Determining Effects of Large Hydrocarbon Pool Fires on Structural Members and Assemblies
Effective Date
01-Oct-2011
Referred By
ASTM E637-22 - Standard Test Method for Calculation of Stagnation Enthalpy from Heat Transfer Theory and Experimental Measurements of Stagnation-Point Heat Transfer and Pressure
Effective Date
01-Oct-2011
Referred By
ASTM E3057-19 - Standard Test Method for Measuring Heat Flux Using Directional Flame Thermometers with Advanced Data Analysis Techniques
Effective Date
01-Oct-2011
Referred By
ASTM E457-08(2020) - Standard Test Method for Measuring Heat-Transfer Rate Using a Thermal Capacitance (Slug) Calorimeter
Effective Date
01-Oct-2011
Referred By
ASTM E422-22 - Standard Test Method for Measuring Net Heat Flux Using a Water-Cooled Calorimeter
Effective Date
01-Oct-2011

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ASTM E459-05(2011) - Standard Test Method for Measuring Heat Transfer Rate Using a Thin-Skin CalorimeterASTM E459-05(2011) - Standard Test Method for Measuring Heat Transfer Rate Using a Thin-Skin Calorimeter
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ASTM E459-05(2011) - Standard Test Method for Measuring Heat Transfer Rate Using a Thin-Skin Calorimeter
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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: E459 − 05(Reapproved 2011)
Standard Test Method for
Measuring Heat Transfer Rate Using a Thin-Skin
Calorimeter
This standard is issued under the fixed designation E459; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision.Anumber in parentheses indicates the year of last reapproval.A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 1.4.1 Exception—The values given in parentheses are for
information only.
1.1 This test method covers the design and use of a thin
1.5 This standard does not purport to address all of the
metallic calorimeter for measuring heat transfer rate (also
safety concerns, if any, associated with its use. It is the
calledheatflux).Thermocouplesareattachedtotheunexposed
responsibility of the user of this standard to establish appro-
surface of the calorimeter.Aone-dimensional heat flow analy-
priate safety and health practices and determine the applica-
sis is used for calculating the heat transfer rate from the
bility of regulatory limitations prior to use.
temperature measurements. Applications include aerodynamic
heating, laser and radiation power measurements, and fire
2. Summary of Test Method
safety testing.
2.1 This test method for measuring the heat transfer rate to
1.2 Advantages:
a metal calorimeter of finite thickness is based on the assump-
1.2.1 Simplicity of Construction—The calorimeter may be
tion of one-dimensional heat flow, known metal properties
constructedfromanumberofmaterials.Thesizeandshapecan
(density and specific heat), known metal thickness, and mea-
often be made to match the actual application. Thermocouples
surement of the rate of temperature rise of the back (or
may be attached to the metal by spot, electron beam, or laser
unexposed) surface of the calorimeter.
welding.
1.2.2 Heat transfer rate distributions may be obtained if
2.2 After an initial transient, the response of the calorimeter
metals with low thermal conductivity, such as some stainless
is approximated by a lumped parameter analysis:
steels, are used.
dT
1.2.3 The calorimeters can be fabricated with smooth
q 5 ρC δ (1)
p

surfaces,withoutinsulatorsorplugsandtheattendanttempera-
ture discontinuities, to provide more realistic flow conditions
where:
for aerodynamic heating measurements.
q = heat transfer rate, W/m ,
1.2.4 The calorimeters described in this test method are
ρ = metal density, kg/m ,
relatively inexpensive. If necessary, they may be operated to
δ = metal thickness, m,
burn-out to obtain heat transfer information. C = metal specific heat, J/kg·K, and
p
dT/dτ = back surface temperature rise rate, K/s.
1.3 Limitations:
1.3.1 At higher heat flux levels, short test times are neces-
3. Significance and Use
sary to ensure calorimeter survival.
3.1 This test method may be used to measure the heat
1.3.2 For applications in wind tunnels or arc-jet facilities,
transfer rate to a metallic or coated metallic surface for a
the calorimeter must be operated at pressures and temperatures
variety of applications, including:
such that the thin-skin does not distort under pressure loads.
3.1.1 Measurements of aerodynamic heating when the calo-
Distortion of the surface will introduce measurement errors.
rimeter is placed into a flow environment, such as a wind
1.4 The values stated in SI units are to be regarded as
tunnel or an arc jet; the calorimeters can be designed to have
standard. No other units of measurement are included in this
the same size and shape as the actual test specimens to
standard.
minimize heat transfer corrections;
3.1.2 Heat transfer measurements in fires and fire safety
testing;
This test method is under the jurisdiction of ASTM Committee E21 on Space
Simulation andApplications of SpaceTechnology and is the direct responsibility of
3.1.3 Laser power and laser absorption measurements; as
Subcommittee E21.08 on Thermal Protection.
well as,
Current edition approved Oct. 1, 2011. Published April 2012. Originally
3.1.4 X-ray and particle beam (electrons or ions) dosimetry
approved in 1972. Last previous edition approved in 2005 as E459–05. DOI:
10.1520/E0459-05R11. measurements.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E459 − 05 (2011)
FIG. 1 Typical Thin-Skin Calorimeter for Heat Transfer Measurement
3.2 The thin-skin calorimeter is one of many concepts used niques. This type of thermocouple joint (called an intrinsic
to measure heat transfer rates. It may be used to measure thermocouple) has been found to provide superior transient
convective, radiative, or combinations of convective and ra- response as compared to a peened joint or a beaded thermo-
diative (usually called mixed or total) heat transfer rates. couple that is soldered to the surface (1, 2). The wires should
However, when the calorimeter is used to measure radiative or be positioned approximately 1.6 mm apart along an expected
mixedheattransferrates,theabsorptivityandreflectivityofthe isotherm.Theuseofasmallthermocouplewireminimizesheat
surface should be measured over the expected radiation wave- conduction into the wire but the calorimeter should still be
length region of the source. ruggedenoughforrepeatedmeasurements.However,whenthe
thicknessofthecalorimeterisontheorderofthewirediameter
3.3 In 4.6 and 4.7, it is demonstrated that lateral heat
toobtainthenecessaryresponsecharacteristics,therecommen-
conduction effects on a local measurement can be minimized
dations of Sobolik, et al. [1989], Burnett [1961], and Kidd
by using a calorimeter material with a low thermal conductiv-
[1985] (2-4) should be followed.
ity.Alternatively, a distribution of the heat transfer rate may be
obtainedbyplacinganumberofthermocouplesalongtheback 4.2 Whenheatingstarts,theresponseoftheback(unheated)
surface of the calorimeter. surface of the calorimeter lags behind that of the front (heated)
surface. For a step change in the heat transfer rate, the initial
3.4 In high temperature or high heat transfer rate
response time of the calorimeter is the time required for the
applications, the principal drawback to the use of thin-skin
temperature rise rate of the unheated surface to approach the
calorimeters is the short exposure time necessary to ensure
temperature rise rate of the front surface within 1%. If
survival of the calorimeter such that repeat measurements can
conductionheattransferintothethermocouplewireisignored,
be made with the same sensor. When operation to burnout is
the initial response time is generally defined as:
necessary to obtain the desired heat flux measurements, thin-
ρC δ
skin calorimeters are often a good choice because they are
p
τ 5 0.5 (2)
r
relatively inexpensive to fabricate. k
where:
4. Apparatus
τ = initial response time, s, and
r
4.1 Calorimeter Design—Typicaldetailsofathin-skincalo-
rimeter used for measuring aerodynamic heat transfer rates are
shown in Fig. 1. The thermocouple wires (0.127 mm OD,
0.005 in., 36 gage) are individually welded to the back surface
The boldface numbers in parentheses refer to the list of references at the end of
of the calorimeter using spot, electron beam, or laser tech- this standard.
E459 − 05 (2011)
4.4 Determine the maximum exposure time (6) by setting a
k = thermal conductivity, W/m·K.
maximum allowable temperature for the front surface as
As an example, the 0.76 mm (0.030 in.) thick, 300 series
follows:
stainless steel calorimeter analyzed in Ref (4) has an initial
response time of 72 ms. Eq 2 can be rearranged to show that ρC δ k T 2 T 1
~ !
p max 0
τ 5 * 2 (4)
F G
max
the initial response time also corresponds to a Fourier Number
k qδ 3
(a dimensionless time) of 0.5.
where:
4.3 Conduction heat transfer into the thermocouple wire
τ = maximum exposure time, s,
max
delaysthetimepredictedbyEq2forwhichthemeasuredback
T = initial temperature, K, and
face temperature rise rate accurately follows (that is, within
T = maximum allowable temperature, K.
max
1%) the undisturbed back face temperature rise rate. For a
4.4.1 In order to have time available for the heat transfer
0.127 mm (0.005 in.) OD, Type K intrinsic thermocouple on a
rate measurement, τ must be greater thanτ , which requires
0.76 mm (0.030 in.) thick, 300 series stainless steel
max R
calorimeter, the analysis in Ref (4) indicates the measured that:
temperature rise rate is within 2% of the undisturbed tempera-
k~T 2 T ! 5
max 0
. (5)
ture rise rate in approximately 500 ms. An estimate of the
qδ 6
measured temperature rise rate error (or slope error) can be
obtained from Ref (1) for different material combinations:
4.4.2 Determine an optimum thickness that maximizes
(τ − τ ) (7) as follows:
max R
dT dT αt αt
C TC
2 5 C exp C erfcS C D (3)
S D Œ
1 2 2 2 2
3 k~T 2 T !
dt dt R R
max 0
δ 5 (6)
opt
5 q
where:
4.4.3 Then calculate the maximum exposure time using the
T = calorimeter temperature,
C
T = measured temperature (that is, thermocouple output),
optimum thickness as follows:
TC
C = β/(8/π + β) and C =4⁄(8⁄π + βπ),
1 2
T 2 T
max 0
α = k/ρC (thermaldiffusivityofthecalorimetermaterial),
τ 5 0.48ρC k (7)
p F G
maxopt p
q
β =
=
K/ A ,
4.4.4 When it is desirable for a calorimeter to cover a range
K = k of thermocouple wire/k of calorimeter,
of heat transfer rates without being operated to burn-out,
A = α of thermocouple wire/α of calorimeter,
design the calorimeter around the largest heat-transfer rate.
R = radius of the thermocouple wire, and
This gives the thinnest calorimeter with the shortest initial
t = time.
response time (Eq 2); however, Refs (2, 3, 8, 9) all show the
Using thermal property values given in Ref (4) for the
time to a given error level between the measured and undis-
Alumel (negative) leg of the Type K thermocouple on 300
turbed temperature rise rates (left hand side of Eq 3) increases
Series stainless steel (K=1.73, A=1.56, β=1.39), Eq 3 can
as the thickness of the calorimeter decreases relative to the
be used to show that the measured rate of temperature change
thermocouple wire diameter.
(that is, the slope) is within 5% of the actual rate of
temperaturechangeinapproximately150ms.Forthiscase,the
4.5 In most applications, the value of T should be well
max
time for a 1% error in the measured temperature rise rate is
below the melting temperature to obtain a satisfactory design.
roughly 50 times as long as the initial response time predicted
Limiting the maximum temperature to 700 K will keep
by Eq 2; this ratio depends on the thermophysical properties of
radiation losses below 15 kW/m . For a maximum temperature
the calorimeter and thermocouple materials (see Table 1).
rise (T − T ) of 400 K, Fig. 2 shows the optimum thickness
max 0
4.3.1 When the heat transfer rate varies with time, the
of copper and stainless steel calorimeters as a function of the
thin-skin calorimeter should be designed so the response times
heat-transfer rate.The maximum exposure time of an optimum
defined using Eq 2 and 3 are smaller than the time for
thickness calorimeter for a 400 K temperature rise is shown as
significant variations in the heat transfer rate. If this is not
a function of the heat-transfer rate in Fig. 3.
possible, methods for unfolding the dynamic measurement
errors (1,5) should be used to compensate the temperature
4.6 The one-dimensional heat flow assumption used in 2.2
measurements before calculating the heat flux using Eq 1.
and 4.3–4.4 is valid for a uniform heat-transfer rate; however,
in practice the calorimeter will generally have a heat-transfer
ratedistributionoverthesurface.Refs (9, 10)bothconsiderthe
TABLE 1 Time Required for Different Error Levels in the
effectsoflateralheatconductioninahemisphericalcalorimeter
Unexposed Surface Temperature Rise Rate
on heat transfer measurements in a supersonic stream. For a
Error Level Due to Heat
Conduction into 10% 5%2%1% cosine shaped heat flux distribution at the stagnation-point of
Thermocouple
the hemisphere, Starner gives the lateral conduction error
Negative Leg (Alumel) of 35 ms 150 ms 945 ms 3.8 s
relative to the surface heating as
Type K on 304 Stainless
Negative Leg (Constantan) <1 ms <1 ms 1 ms 4 ms
2αt 8kt
of Type T on Copper
E 5 5 (8)
C 2 2
L
R ρC D
p
E459 − 05 (2011)
FIG. 2 Calorimeter Optimum Material Thickness as a Function of Heat Transfer Rate and Material
where: approach for evaluation of the measured rate of temperature
change. The analysis was developed for laser experiments
E = relative heat-transfer rate ratio,
where only part of the calorimeter surface was exposed to
R = radius of curvature of the body (D/2), and
t = exposure time. heating and the exposure time was long compared to the
thermal penetration time to the edges of the unexposed area
Note the lateral conduction error described in Eq 8 is not a
(penetration time calculation is similar to Eq 2 with L, the
function of the calorimeter skin thickness or the heat-transfer
distance to the edge, substituted for δ, the thickness).
rate; the magnitude of the error is shown in Fig. 4 for copper
and stainless steel. The errors for most other base metal
4.9 A device for recording the thermocouple signals with
calorimeters will fall in between these two lines. While the time is required. The response time of an analog recording
lateral conduction errors can be minimized by using materials system should be an order of magnitude smaller than the
with low thermal diffusivity and short exposure times, these calorimeter response time (see Eq 2). The sampling time of a
mayaggravatesomeoftheotherconstraints,asdescribedinEq digital recording system should be no more than 40% of the
2 and 3. Ref (9) also describes the lateral conduction errors for calorimeter response time; the 3 db frequency of any low-pass
cones and cylinders. filters in the data acquisition system should be greater than
4.7 An approximation of the lateral conduction error can be 1 h
f . 5 (10)
3db
obtainedexperimentallybycontinuingtorecordtheunexposed 2πτ 2πρC δ
p
surface temperature after the heating is removed and calculat-
where:
ing the ratio of the rates of temperature change.
h = estimated heat transfer coefficient for the experiment.
dT
cool down
dt 5. Procedure
?
E; (9)
test
?
dT
5.1 Expose the thin-skin calorimeter to the thermal environ-
dt
ment as rapidly as practical. Operate the recording system for
4.8 When the average heat transfer rate over the exposed several seconds before the exposure to provide data for
area is desired, Wedekind and Beck [1989] (11) give another
evaluating any noise in the calorimeter and data acquisition
------------------
...

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5.1 This test method may be used to measure the net heat transfer rate to a metallic or coated metallic surface for a variety of applications, including:  
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1.2 Units—The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
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 E457-08(2020)(Test Method)
Standard Test Method for Measuring Heat-Transfer Rate Using a Thermal Capacitance (Slug) Calorimeter

SIGNIFICANCE AND USE
4.1 The purpose of this test method is to measure the rate of thermal energy per unit area transferred into a known piece of material (slug) for purposes of calibrating the thermal environment into which test specimens are placed for evaluation. The calorimeter and holder size and shape should be identical to that of the test specimen. In this manner, the measured heat transfer rate to the calorimeter can be related to that experienced by the test specimen.  
4.2 The slug calorimeter is one of many calorimeter concepts used to measure heat transfer rate. This type of calorimeter is simple to fabricate, inexpensive, and readily installed since it is not water-cooled. The primary disadvantages are its short lifetime and relatively long cool-down time after exposure to the thermal environment. In measuring the heat transfer rate to the calorimeter, accurate measurement of the rate of rise in back-face temperature is imperative.  
4.3 In the evaluation of high-temperature materials, slug calorimeters are used to measure the heat transfer rate on various parts of the instrumented models, since heat transfer rate is one of the important parameters in evaluating the performance of ablative materials.  
4.4 Regardless of the source of thermal energy to the calorimeter (radiative, convective, or a combination thereof) the measurement is averaged over the calorimeter surface. If a significant percentage of the total thermal energy is radiative, consideration should be given to the emissivity of the slug surface. If non-uniformities exist in the input energy, the heat transfer rate calorimeter would tend to average these variations; therefore, the size of the sensing element (that is, the slug) should be limited to small diameters in order to measure local heat transfer rate values. Where large ablative samples are to be tested, it is recommended that a number of calorimeters be incorporated in the body of the test specimen such that a heat transfer rate distribution across...
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1.1 This test method describes the measurement of heat transfer rate using a thermal capacitance-type calorimeter which assumes one-dimensional heat conduction into a cylindrical piece of material (slug) with known physical properties.  
1.2 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.
Note 1: For information see Test Methods E285, E422, E458, E459, and E511.  
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 E598-08(2020)(Test Method)
Standard Test Method for Measuring Extreme Heat-Transfer Rates from High-Energy Environments Using a Transient, Null-Point Calorimeter

SIGNIFICANCE AND USE
5.1 The purpose of this test method is to measure extremely high heat-transfer rates to a body immersed in either a static environment or in a high velocity fluid stream. This is usually accomplished while preserving the structural integrity of the measurement device for multiple exposures during the measurement period. Heat-transfer rates ranging up to 2.84 × 102 MW/m2 (2.5 × 104 Btu/ft2-sec) (7) have been measured using null-point calorimeters. Use of copper null-point calorimeters provides a measuring system with good response time and maximum run time to sensor burnout (or ablation). Null-point calorimeters are normally made with sensor body diameters of 2.36 mm (0.093 in.) press-fitted into the nose of an axisymmetric model.  
5.2 Sources of error involving the null-point calorimeter in high heat-flux measurement applications are extensively discussed in Refs (3-7). In particular, it has been shown both analytically and experimentally that the thickness of the copper above the null-point cavity is critical. If the thickness is too great, the time response of the instrument will not be fast enough to pick up important flow characteristics. On the other hand, if the thickness is too small, the null-point calorimeter will indicate significantly larger (and time dependent) values than the input or incident heat flux. Therefore, all null-point calorimeters should be experimentally checked for proper time response and calibration before they are used. Although a calibration apparatus is not very difficult or expensive to fabricate, there is only one known system presently in existence (6 and 7). The design of null-point calorimeters can be accomplished from the data in this documentation. However, fabrication of these sensors is a difficult task. Since there is not presently a significant market for null-point calorimeters, commercial sources of these sensors are few. Fabrication details are generally regarded as proprietary information. Some users have developed me...
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1.1 This test method covers the measurement of the heat-transfer rate or the heat flux to the surface of a solid body (test sample) using the measured transient temperature rise of a thermocouple located at the null point of a calorimeter that is installed in the body and is configured to simulate a semi-infinite solid. By definition the null point is a unique position on the axial centerline of a disturbed body which experiences the same transient temperature history as that on the surface of a solid body in the absence of the physical disturbance (hole) for the same heat-flux input.  
1.2 Null-point calorimeters have been used to measure high convective or radiant heat-transfer rates to bodies immersed in both flowing and static environments of air, nitrogen, carbon dioxide, helium, hydrogen, and mixtures of these and other gases. Flow velocities have ranged from zero (static) through subsonic to hypersonic, total flow enthalpies from 1.16 to greater than 4.65 × 101 MJ/kg (5 × 10 2 to greater than 2 × 104 Btu/lb.), and body pressures from 105 to greater than 1.5 × 107 Pa (atmospheric to greater than 1.5 × 102 atm). Measured heat-transfer rates have ranged from 5.68 to 2.84 × 102 MW/m2 (5 × 102 to 2.5 × 104 Btu/ft2-sec).  
1.3 The most common use of null-point calorimeters is to measure heat-transfer rates at the stagnation point of a solid body that is immersed in a high pressure, high enthalpy flowing gas stream, with the body axis usually oriented parallel to the flow axis (zero angle-of-attack). Use of null-point calorimeters at off-stagnation point locations and for angle-of-attack testing may pose special problems of calorimeter design and data interpretation.  
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 appli...

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ASTM E458-08(2020)(Test Method)
Standard Test Method for Heat of Ablation

SIGNIFICANCE AND USE
4.1 General—The heat of ablation provides a measure of the ability of a material to serve as a heat protection element in a severe thermal environment. The parameter is a function of both the material and the environment to which it is subjected. It is therefore required that laboratory measurements of heat of ablation simulate the service environment as closely as possible. Some of the parameters affecting the heat of ablation are pressure, gas composition, heat transfer rate, mode of heat transfer, and gas enthalpy. As laboratory duplication of all parameters is usually difficult, the user of the data should consider the differences between the service and the test environments. Screening tests of various materials under simulated use conditions may be quite valuable even if all the service environmental parameters are not available. These tests are useful in material selection studies, materials development work, and many other areas.  
4.2 Steady-State Conditions—The nature of the definition of heat of ablation requires steady-state conditions. Variances from steady-state may be required in certain circumstances; however, it must be realized that transient phenomena make the values obtained functions of the test duration and therefore make material comparisons difficult.  
4.2.1 Temperature Requirements—In a steady-state condition, the temperature propagation into the material will move at the same velocity as the gas-ablation surface interface. A constant distance is maintained between the ablation surface and the isotherm representing the temperature front. Under steady-state ablation the mass loss and length change are linearly related.
   where:
  t  =  test time, s,   ρo  =  virgin material density, kg/m3,   δL  =   change in length or ablation depth, m,   ρc  =   char density, kg/m3, and   δc  =   char depth, m.  This relationship may be used to verify the existence of steady-state ablation in the tests of charring ablators.  
4.2.2 Exposure T...
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1.1 This test method covers determination of the heat of ablation of materials subjected to thermal environments requiring the use of ablation as an energy dissipation process. Three concepts of the parameter are described and defined: cold wall, effective, and thermochemical heat of ablation.  
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, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.3 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 E341-08(2020)(Practice)
Standard Practice for Measuring Plasma Arc Gas Enthalpy by Energy Balance

SIGNIFICANCE AND USE
3.1 The purpose of this practice is to measure the total or stagnation gas enthalpy of a plasma-arc gas stream in which nonreactive gases are heated by passage through an electrical discharge device during calibration tests of the system.  
3.2 The plasma arc represents one heat source for determining the performance of high temperature materials under simulated hyperthermal conditions. As such the total or stagnation enthalpy is one of the important parameters for correlating the behavior of ablation materials.  
3.3 The most direct method for obtaining a measure of total enthalpy, and one which can be performed simultaneously with each material test, if desired, is to perform an energy balance on the arc chamber. In addition, in making the energy balance, accurate measurements are needed since the efficiencies of some plasma generators are low (as low as 15 to 20 % or less in which case the enthalpy depends upon the difference of two quantities of nearly equal magnitude). Therefore, the accuracy of the measurements of the primary variables must be high, all energy losses must be correctly taken into account, and steady-state conditions must exist both in plasma performance and fluid flow.  
3.4 In particular it is noted that total enthalpy as determined by the energy balance technique is most useful if the plasma generator design minimizes coring effects. If nonuniformity exists the enthalpy determined by energy balance gives only the average for the entire plasma stream, whereas the local enthalpy experienced by a model in the core of the stream may be much higher. More precise methods are needed to measure local variations in total enthalpy.
SCOPE
1.1 This practice covers the measurement of total gas enthalpy of an electric-arc-heated gas stream by means of an overall system energy balance. This is sometimes referred to as a bulk enthalpy and represents an average energy content of the test stream which may differ from local values in the test stream.  
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, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.3 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 E511-07(2020)(Test Method)
Standard Test Method for Measuring Heat Flux Using a Copper-Constantan Circular Foil, Heat-Flux Transducer

SIGNIFICANCE AND USE
3.1 Fig. 1 is a sectional view of an example circular foil heat-flux transducer. It consists of a circular Constantan foil attached by a metallic bonding process to a heat sink of oxygen-free high conductivity copper (OFHC), with copper leads attached at the center of the circular foil and at any point on the heat-sink body. The transducer impedance is usually less than 1 V. To minimize current flow, the data acquisition system (DAS) should be a potentiometric system or have an input impedance of at least 100 000 Ω.  
3.2 As noted in 2.3, an approximately linear output (versus heat flux) is produced when the body and center wire of the transducer are constructed of copper and the circular foil is constantan. Other metal combinations may be employed for use at higher temperatures, but most (4) are nonlinear.  
3.3 Because the thermocouple junction at the edge of the foil is the reference for the center thermocouple, no cold junction compensation is required with this instrument. The wire leads used to convey the signal from the transducer to the readout device are normally made of stranded, tinned copper, insulated with TFE-fluorocarbon and shielded with a braid over-wrap that is also TFE-fluorocarbon-covered.  
3.4 Transducers with a heat-sink thermocouple can be used to indicate the foil center temperature. Once the edge temperature is known, the temperature difference from the foil edge to its center may be directly read from the copper-constantan (Type T) thermocouple table. This temperature difference then is added to the body temperature, indicating the foil center temperature.  
3.5 Water-Cooled Transducer:  
3.5.1 A water-cooled transducer should be used in any application where the copper heat-sink would rise above 235 °C (450 °F) without cooling. Examples of cooled transducers are shown in Fig. 2. The coolant flow must be sufficient to prevent local boiling of the coolant inside the transducer body, with its characteristic pulsations (“chugging”) of t...
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1.1 This test method describes the measurement of radiative heat flux using a transducer whose sensing element (1, 2)2 is a thin circular metal foil. These sensors are often called Gardon Gauges.  
1.2 The values stated in SI units are to be regarded as the standard. The values stated in parentheses are provided for information only.  
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 E3057-19(Test Method)
Standard Test Method for Measuring Heat Flux Using Directional Flame Thermometers with Advanced Data Analysis Techniques

SIGNIFICANCE AND USE
5.1 Need for Heat Flux Measurements:  
5.1.1 Independent measurements of temperature and heat flux support the development and validation of engineering models of fires and other high environments, such as furnaces. For tests of fire protection materials and structural assemblies, temperature and heat flux are necessary to fully specify the boundary conditions, also known as the thermal exposure. Temperature measurements alone cannot provide a complete set of boundary conditions.  
5.1.2 Temperature is a scalar variable and a primary variable. Heat Flux is a vector quantity, and it is a derived variable. As a result, they should be measured separately just as current and voltage are in electrical systems. For steady-state or quasi-steady state conditions, analysis basically uses a thermal analog of Ohm's Law. The thermal circuit uses the temperature difference instead of voltage drop, the heat flux in place of the current and thermal resistance in place of electrical resistance. As with electrical systems, the thermal performance is not fully specified without knowing at least two of these three parameters (temperature drop, heat flux, or thermal resistance). For dynamic thermal experiments like fires or fire safety tests, the electrical capacitance is replaced by the volumetric heat capacity.  
5.1.3 The net heat flux, which is measured by a DFT, is likely different than the heat flux into the test item of interest because of different surface temperatures. An alternative measurement is the total cold wall heat flux which is measured by water-cooled Gardon or S-B gauges. The incident radiative flux can be estimated from either measurement by use of an energy balance [Keltner, 2007 and 2008 (16, 17)]. The convective flux can be estimated from gas temperatures and the convective heat transfer coefficient, h [Janssens, 2007 (18)]. Assuming the sensor is physically close to the test item of interest; one can use the incident radiative and convective fluxes from the...
SCOPE
1.1 This test method describes the continuous measurement of the hemispherical heat flux to one or both surfaces of an uncooled sensor called a “Directional Flame Thermometer” (DFT).  
1.2 DFTs consist of two heavily oxidized, Inconel 600 plates with mineral insulated, metal-sheathed (MIMS) thermocouples (TCs, type K) attached to the unexposed faces and a layer of ceramic fiber insulation placed between the plates.  
1.3 Post-test calculations of the net heat flux can be made using several methods. The most accurate method uses an inverse heat conduction code. Nonlinear inverse heat conduction analysis uses a thermal model of the DFT with temperature dependent thermal properties along with the two plate temperature measurement histories. The code provides transient heat flux on both exposed faces, temperature histories within the DFT as well as statistical information on the quality of the analysis.  
1.4 A second method uses a transient energy balance on the DFT sensing surface and insulation, which uses the same temperature measurements as in the inverse calculations to estimate the net heat flux.  
1.5 A third method uses Inverse Filter Functions (IFFs) to provide a near real time estimate of the net flux. The heat flux history for the “front face” (either surface exposed to the heat source) of a DFT can be calculated in real-time using a convolution type of digital filter algorithm.  
1.6 Although developed for use in fires and fire safety testing, this measurement method is quite broad in potential fields of application because of the size of the DFTs and their construction. It has been used to measure heat flux levels above 300 kW/m2 in high temperature environments, up to about 1250 °C, which is the generally accepted upper limit of Type K or N thermocouples.  
1.7 The transient response of the DFTs is limited by the response of the MIMS TCs. The larger the thermocouple the slower the transient response. Res...

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ASTM E2684-17(Test Method)
Standard Test Method for Measuring Heat Flux Using Surface-Mounted One-Dimensional Flat Gages

SIGNIFICANCE AND USE
5.1 This test method will provide guidance for the measurement of the net heat flux to or from a surface location. To determine the radiant energy component the emissivity or absorptivity of the gage surface coating is required and should be matched with the surrounding surface. The potential physical and thermal disruptions of the surface due to the presence of the gage should be minimized and characterized. For the case of convection and low source temperature radiation to or from the surface it is important to consider how the presence of the gage alters the surface heat flux. The desired quantity is usually the heat flux at the surface location without the presence of the gage.  
5.1.1 Temperature limitations are determined by the gage material properties and the method of application to the surface. The range of heat flux that can be measured and the time response are limited by the gage design and construction details. Measurements from 10 W/m2 to above 100 kW/m2 are easily obtained with current sensors. Time constants as low as 10 ms are possible, while thicker sensors may have response times greater than 1 s. It is important to choose the sensor style and characteristics to match the range and time response of the required application.  
5.2 The measured heat flux is based on one-dimensional analysis with a uniform heat flux over the surface of the gage surface. Because of the thermal disruption caused by the placement of the gage on the surface, this may not be true. Wesley (3) and Baba et al. (4) have analyzed the effect of the gage on the thermal field and heat transfer within the surface substrate and determined that the one-dimensional assumption is valid when:
   where:
  ks  =   the thermal conductivity of the substrate material,    R   =  the effective radius of the gage,    δ  =  the combined thickness, and     k  =  the effective thermal conductivity of the gage and adhesive layers.    
5.3 Measurements of convective heat flux are part...
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1.1 This test method describes the measurement of the net heat flux normal to a surface using flat gages mounted onto the surface. Conduction heat flux is not the focus of this standard. Conduction applications related to insulation materials are covered by Test Method C518 and Practices C1041 and C1046. The sensors covered by this test method all use a measurement of the temperature difference between two parallel planes normal to the surface to determine the heat that is exchanged to or from the surface in keeping with Fourier’s Law. The gages operate by the same principles for heat transfer in either direction.  
1.2 This test method is quite broad in its field of application, size and construction. Different sensor types are described in detail in later sections as examples of the general method for measuring heat flux from the temperature gradient normal to a surface (1).2 Applications include both radiation and convection heat transfer. The gages have broad application from aerospace to biomedical engineering with measurements ranging form 0.01 to 50 kW/m 2. The gages are usually square or rectangular and vary in size from 1 mm to 10 cm or more on a side. The thicknesses range from 0.05 to 3 mm.  
1.3 The values stated in SI units are to be regarded as the standard. The values stated in parentheses are provided for information only.  
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 and health 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...

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