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ASTM C1155-95(2021)

(Practice)

Standard Practice for Determining Thermal Resistance of Building Envelope Components from the In-Situ Data

Standard Practice for Determining Thermal Resistance of Building Envelope Components from the In-Situ Data

SIGNIFICANCE AND USE
5.1 Significance of Thermal Resistance Measurements—Knowledge of the thermal resistance of new buildings is important to determine whether the quality of construction satisfies criteria set by the designer, by the owner, or by a regulatory agency. Differences in quality of materials or workmanship may cause building components not to achieve design performance.  
5.1.1 For Existing Buildings—Knowledge of thermal resistance is important to the owners of older buildings to determine whether the buildings should receive insulation or other energy-conserving improvements. Inadequate knowledge of the thermal properties of materials or heat flow paths within the construction or degradation of materials may cause inaccurate assumptions in calculations that use published data.  
5.2 Advantage of In-Situ Data—This practice provides information about thermal performance that is based on measured data. This may determine the quality of new construction for acceptance by the owner or occupant or it may provide justification for an energy conservation investment that could not be made based on calculations using published design data.  
5.3 Heat Flow Paths—This practice assumes that net heat flow is perpendicular to the surface of the building envelope component within a given subsection. Knowledge of surface temperature in the area subject to measurement is required for placing sensors appropriately. Appropriate use of infrared thermography is often used to obtain such information. Thermography reveals nonuniform surface temperatures caused by structural members, convection currents, air leakage, and moisture in insulation. Practices C1060 and C1153 detail the appropriate use of infrared thermography. Note that thermography as a basis for extrapolating the results obtained at a measurement site to other similar parts of the same building is beyond the scope of this practice.  
5.4 User Knowledge Required—This practice requires that the user have knowledge that the data empl...
SCOPE
1.1 This practice covers how to obtain and use data from in-situ measurement of temperatures and heat fluxes on building envelopes to compute thermal resistance. Thermal resistance is defined in Terminology C168 in terms of steady-state conditions only. This practice provides an estimate of that value for the range of temperatures encountered during the measurement of temperatures and heat flux.  
1.2 This practice presents two specific techniques, the summation technique and the sum of least squares technique, and permits the use of other techniques that have been properly validated. This practice provides a means for estimating the mean temperature of the building component for estimating the dependence of measured R-value on temperature for the summation technique. The sum of least squares technique produces a calculation of thermal resistance which is a function of mean temperature.  
1.3 Each thermal resistance calculation applies to a subsection of the building envelope component that was instrumented. Each calculation applies to temperature conditions similar to those of the measurement. The calculation of thermal resistance from in-situ data represents in-service conditions. However, field measurements of temperature and heat flux may not achieve the accuracy obtainable in laboratory apparatuses.  
1.4 This practice permits calculation of thermal resistance on portions of a building envelope that have been properly instrumented with temperature and heat flux sensing instruments. The size of sensors and construction of the building component determine how many sensors shall be used and where they should be placed. Because of the variety of possible construction types, sensor placement and subsequent data analysis require the demonstrated good judgement of the user.  
1.5 Each calculation pertains only to a defined subsection of the building envelope. Combining results from different subsections to characterize...

General Information

Status
Published
Publication Date
30-Sep-2021
ICS
91.120.10 - Thermal insulation of buildings
Technical Committee
C16 - Thermal Insulation
Drafting Committee
C16.30 - Thermal Measurement
Current Stage
Ref Project

Relations

Refers
ASTM C168-24 - Standard Terminology Relating to Thermal Insulation
Effective Date
15-Apr-2024
Refers
ASTM C1130-24 - Standard Practice for Calibration of Thin Heat Flux Transducers
Effective Date
15-Mar-2024
Refers
ASTM C1153-23 - Standard Practice for Location of Wet Insulation in Roofing Systems Using Infrared Imaging
Effective Date
01-Sep-2023
Refers
ASTM C168-18 - Standard Terminology Relating to Thermal Insulation
Effective Date
15-Apr-2018
Refers
ASTM C168-17 - Standard Terminology Relating to Thermal Insulation
Effective Date
01-Jun-2017
Refers
ASTM C168-15a - Standard Terminology Relating to Thermal Insulation
Effective Date
15-Oct-2015
Refers
ASTM C1153-10(2015) - Standard Practice for Location of Wet Insulation in Roofing Systems Using Infrared Imaging
Effective Date
01-Sep-2015
Refers
ASTM C168-15 - Standard Terminology Relating to Thermal Insulation
Effective Date
01-Jun-2015
Refers
ASTM C168-13 - Standard Terminology Relating to Thermal Insulation
Effective Date
01-Apr-2013
Refers
ASTM C1130-07(2012) - Standard Practice for Calibrating Thin Heat Flux Transducers
Effective Date
01-Sep-2012
Refers
ASTM C1060-11a - Standard Practice for Thermographic Inspection of Insulation Installations in Envelope Cavities of Frame Buildings
Effective Date
15-Mar-2011
Refers
ASTM C1060-11 - Standard Practice for Thermographic Inspection of Insulation Installations in Envelope Cavities of Frame Buildings
Effective Date
01-Mar-2011
Refers
ASTM C1153-10 - Standard Practice for Location of Wet Insulation in Roofing Systems Using Infrared Imaging
Effective Date
01-Sep-2010
Refers
ASTM C168-10 - Standard Terminology Relating to Thermal Insulation
Effective Date
01-Jan-2010
Refers
ASTM C168-08b - Standard Terminology Relating to Thermal Insulation
Effective Date
15-Dec-2008

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ASTM C1155-95(2021) - Standard Practice for Determining Thermal Resistance of Building Envelope Components from the In-Situ DataASTM C1155-95(2021) - Standard Practice for Determining Thermal Resistance of Building Envelope Components from the In-Situ Data
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ASTM C1155-95(2021) - Standard Practice for Determining Thermal Resistance of Building Envelope Components from the In-Situ Data
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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.
Designation: C1155 − 95 (Reapproved 2021)
Standard Practice for
Determining Thermal Resistance of Building Envelope
Components from the In-Situ Data
This standard is issued under the fixed designation C1155; 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 sectionstocharacterizeoverallthermalresistanceisbeyondthe
scope of this practice.
1.1 This practice covers how to obtain and use data from
in-situ measurement of temperatures and heat fluxes on build- 1.6 This practice sets criteria for the data-collection tech-
ing envelopes to compute thermal resistance. Thermal resis- niques necessary for the calculation of thermal properties (see
tance is defined in Terminology C168 in terms of steady-state Note 1). Any valid technique may provide the data for this
conditions only. This practice provides an estimate of that practice, but the results of this practice shall not be considered
value for the range of temperatures encountered during the to be from an ASTM standard, unless the instrumentation
measurement of temperatures and heat flux. technique itself is an ASTM standard.
1.2 This practice presents two specific techniques, the
NOTE 1—Currently only Practice C1046 can provide the data for this
practice. It also offers guidance on how to place sensors in a manner
summation technique and the sum of least squares technique,
representative of more than just the instrumented portions of the building
andpermitstheuseofothertechniquesthathavebeenproperly
components.
validated. This practice provides a means for estimating the
1.7 This practice pertains to light-through medium-weight
meantemperatureofthebuildingcomponentforestimatingthe
construction as defined by example in 5.8. The calculations
dependence of measured R-value on temperature for the
apply to the range of indoor and outdoor temperatures ob-
summation technique. The sum of least squares technique
served.
producesacalculationofthermalresistancewhichisafunction
of mean temperature.
1.8 The values stated in SI units are to be regarded as
standard. No other units of measurement are included in this
1.3 Each thermal resistance calculation applies to a subsec-
standard.
tion of the building envelope component that was instru-
mented. Each calculation applies to temperature conditions
1.9 This standard does not purport to address all of the
similartothoseofthemeasurement.Thecalculationofthermal
safety concerns, if any, associated with its use. It is the
resistance from in-situ data represents in-service conditions.
responsibility of the user of this standard to establish appro-
However,fieldmeasurementsoftemperatureandheatfluxmay
priate safety, health, and environmental practices and deter-
not achieve the accuracy obtainable in laboratory apparatuses.
mine the applicability of regulatory limitations prior to use.
1.10 This international standard was developed in accor-
1.4 This practice permits calculation of thermal resistance
dance with internationally recognized principles on standard-
on portions of a building envelope that have been properly
ization established in the Decision on Principles for the
instrumented with temperature and heat flux sensing instru-
Development of International Standards, Guides and Recom-
ments. The size of sensors and construction of the building
mendations issued by the World Trade Organization Technical
component determine how many sensors shall be used and
Barriers to Trade (TBT) Committee.
wheretheyshouldbeplaced.Becauseofthevarietyofpossible
construction types, sensor placement and subsequent data
2. Referenced Documents
analysis require the demonstrated good judgement of the user.
2.1 ASTM Standards:
1.5 Eachcalculationpertainsonlytoadefinedsubsectionof
C168Terminology Relating to Thermal Insulation
the building envelope. Combining results from different sub-
C1046Practice for In-Situ Measurement of Heat Flux and
Temperature on Building Envelope Components
This practice is under the jurisdiction of ASTM Committee C16 on Thermal
Insulation and is the direct responsibility of Subcommittee C16.30 on Thermal
Measurement. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Current edition approved Oct. 1, 2021. Published October 2021. Originally contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
approved in 1990. Last previous edition approved in 2013 as C1155–95 (2013). Standards volume information, refer to the standard’s Document Summary page on
DOI: 10.1520/C1155-95R21. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
C1155 − 95 (2021)
C1060Practice for Thermographic Inspection of Insulation ρ=material density, kg/m .
Installations in Envelope Cavities of Frame Buildings 3.3.2 Subscripts for the Summation Technique: a =air,
C1130Practice for Calibration of Thin Heat Flux Transduc- e=estimate,
ers I=indoor,
C1153Practice for Location of Wet Insulation in Roofing j=counter for summation of sensor sites,
Systems Using Infrared Imaging k=counter for summation of time-series data,
m=area coverage,
3. Terminology
n=test for convergence value.
o=outdoor, and
3.1 Definitions—For definitions of terms relating to thermal
s=surface,
insulating materials, see Terminology C168.
3.3.3 Variables for the Sum of Least Squares Technique:
3.2 Definitions of Terms Specific to This Standard:
C =material specific heat, J/kg·K (Btu/lb·°F),
3.2.1 building envelope component—the portion of the ρ
Y =measured temperature at indoor node m for time IK,
building envelope, such as a wall, roof, floor, window, or door, mi
F =measured heat flux at interior node n for time i W/m ,
that has consistent construction. — For example, an exterior ni
λ=apparent thermal conductivity, W/m·K,
stud wall would be a building envelope component, whereas a
T =calculated temperature at indoor node m for time I K,
layer thereof would not be. mi
q =calculated heat flux at interior node n for time i W/m ,
ni
3.2.2 convergence factor for thermal resistance, CR —the
n
W =weighting factor to normalize temperature contribu-
Tm
differencebetweenR attime,t,andR attime,t−n,dividedby
e e
tion to Γ,
R at time, t, where n is a time interval chosen by the user
e
W =weightingfactortonormalizeheatfluxcontributionto
qn
making the calculation of thermal resistance.
Γ, and
3.2.3 corresponding mean temperature—arithmetic average
Γ=weighted sum of squares function.
of the two boundary temperatures on a building envelope
3.3.4 Subscripts for the Sum of Least Squares Technique:
component,weightedtoaccountfornon-steady-stateheatflux.
s=specific heat of value, “s,” J/kg·K
3.2.4 estimate of thermal resistance, R —the working cal-
e
4. Summary of Practice
culation of thermal resistance from in-situ data at any one
sensor site. This does not contribute to the thermal resistance
4.1 This practice presents two mathematical procedures for
calculated in this practice until criteria for sufficient data and
calculating the thermal resistance of a building envelope
for variance of R are met.
e subsection from measured in-situ temperature and heat flux
3.2.5 heat flow sensor—any device that produces a continu- data.The procedures are the summation technique (1) and the
ous output which is a function of heat flux or heat flow, for sumofleastsquarestechnique (2, 3).Propervalidationofother
example, heat flux transducer (HFT) or portable calorimeter. techniques is required.
3.2.6 temperature sensor—any device that produces a con-
4.2 The results of each calculation pertain only to a particu-
tinuousoutputwhichisafunctionoftemperature,forexample,
larsubsectionthatwasinstrumentedappropriately.Appropriate
thermocouple, thermistor, or resistance device.
instrumentation implies that heat flow can be substantially
accounted for by the placement of sensors within the defined
3.3 Definitions:SymbolsAppliedtotheTermsUsedinThis
subsection. Since data obtained from in-situ measurements are
Standard:
unlikely to represent steady-state conditions, a calculation of
3.3.1 Variables for the Summation Technique: A =area
thermal resistance is possible only when certain criteria are
associated with a single set of temperature and heat flux
met. The data also provide an estimate of whether the collec-
sensors,
tion process has run long enough to satisfy an accuracy
C=thermal conductance, W/m ·K,
criterion for the calculation of thermal resistance.An estimate
CR=convergence factor (dimensionless),
of error is also possible.
e=error of measurement of heat flux, W/m ,
M=number of values of ∆T and q in the source data,
4.3 This practice provides a means for estimating the mean
N=number of sensor sites,
temperature of the building component (see 6.5.1.4) for esti-
n=test for convergence interval, h,
matingthedependenceofmeasuredR-valueontemperaturefor
q=heat flux, W/m ,
the summation technique by weighting the recorded tempera-
R=thermal resistance, m ·K/W,
turessuchthattheycorrespondtotheobservedheatfluxes.The
s(x)=standard deviation of x, based on N−1 degrees of
sum of least squares technique has its own means for estimat-
freedom,
ing thermal resistance as a function of temperature.
T=temperature, K,
t=time, h, 5. Significance and Use
V(x)=coefficient of variation of x,
5.1 Significance of Thermal Resistance Measurements—
∆T = difference in temperature between indoors and
Knowledge of the thermal resistance of new buildings is
outdoors, K,
λ=apparent thermal conductivity, W/m·K, and
x=position coordinate (from 0 to distance L in increments
Theboldfacenumbersinparenthesesrefertothelistofreferencesattheendof
of ∆x), this practice.
C1155 − 95 (2021)
important to determine whether the quality of construction 5.6.1 Gather the data over an adequate range of thermal
satisfies criteria set by the designer, by the owner, or by a conditions to represent the thermal resistance under the condi-
regulatory agency. Differences in quality of materials or tions to be characterized.
workmanship may cause building components not to achieve
NOTE 2—The construction of some building components includes
design performance.
materialswhosethermalperformanceisdependentonthedirectionofheat
5.1.1 For Existing Buildings—Knowledge of thermal resis-
flow, for example, switching modes between convection and stable
stratification in horizontal air spaces.
tanceisimportanttotheownersofolderbuildingstodetermine
whether the buildings should receive insulation or other
5.7 Lateral Heat Flow—Avoid areas with significant lateral
energy-conserving improvements. Inadequate knowledge of
heat flow. Report the location of each source of temperature
thethermalpropertiesofmaterialsorheatflowpathswithinthe
andheatfluxdata.Identifypossiblesourcesoflateralheatflow,
construction or degradation of materials may cause inaccurate
includingahighlyconductivesurface,thermalbridgesbeneath
assumptions in calculations that use published data.
thesurface,convectioncells,etc.,thatmayviolatetheassump-
tion of heat flow perpendicular to the building envelope
5.2 Advantage of In-Situ Data—This practice provides in-
component.
formation about thermal performance that is based on mea-
sureddata.Thismaydeterminethequalityofnewconstruction
NOTE 3—Appropriate choice of heat flow sensors and placement of
for acceptance by the owner or occupant or it may provide thosesensorscansometimesprovidemeaningfulresultsinthepresenceof
lateral heat flow in building components. Metal surfaces and certain
justification for an energy conservation investment that could
concrete or masonry components may create severe difficulties for
notbemadebasedoncalculationsusingpublisheddesigndata.
measurement due to lateral heat flow.
5.3 Heat Flow Paths—This practice assumes that net heat
5.8 Light-toMedium-WeightConstruction—Thispracticeis
flow is perpendicular to the surface of the building envelope
limited to light- to medium-weight construction that has an
component within a given subsection. Knowledge of surface
indoor temperature that varies by less than 3 K. The heaviest
temperature in the area subject to measurement is required for
construction to which this practice applies would weigh 440
placing sensors appropriately. Appropriate use of infrared
kg/m , assuming that the massive elements in building con-
thermography is often used to obtain such information. Ther-
struction all have a specific heat of about 0.9 kJ/kg K.
mography reveals nonuniform surface temperatures caused by
Examplesoftheheaviestconstructioninclude:(1)a390-kg/m
structural members, convection currents, air leakage, and
wall with a brick veneer, a layer of insulation, and concrete
moisture in insulation. Practices C1060 and C1153 detail the
blocks on the inside layer or (2) a 76-mm concrete slab with
appropriate use of infrared thermography. Note that thermog- 2
insulatedbuilt-uproofingof240kg/m .Insufficientknowledge
raphy as a basis for extrapolating the results obtained at a
and experience exists to extend the practice to heavier con-
measurement site to other similar parts of the same building is
struction.
beyond the scope of this practice.
5.9 Heat Flow Modes—The mode of heat flow is a signifi-
5.4 User Knowledge Required—This practice requires that
cant factor determining R-value in construction that contains
the user have knowledge that the data employed represent an
air spaces. In horizontal construction, air stratifies or convects,
adequate sample of locations to describe the thermal perfor-
depending on whether heat flow is downwards or upwards. In
mance of the construction. Sources for this knowledge include
vertical construction, such as walls with cavities, convection
the referenced literature in Practice C1046 and related works
cells affect determination of R-value significantly. In these
listed in Appendix X2. The accuracy of the calculation is
configurations, apparent R-value is a function of mean
strongly dependent on the history of the temperature differ-
temperature, temperature difference, and location along the
ences across the envelope component. The sensing and data
height of the convection cell. Measurements on a construction
collection apparatuses shall have been used properly. Factors
whose performance is changing with conditions is beyond the
suchasconvectionandmoisturemigrationaffectinterpretation
scope of this practice.
of the field data.
...

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4.3 In normal use, the thickness of these products range from less than 100 mm (4 in.) to greater than 150 mm (6 in.). Installed densities depend upon the product type, the installed thickness, the installation equipment used, the installation techniques, and the geometry of the insulated space.  
4.4 Loose-fill insulations provide coverage information using densities selected by manufacturers to represent the product installed densities. Generally, it is necessary to know the product thermal performance at a representative density.  
4.5 When applicable specifications or codes do not specify the nominal thermal resistance level to be used for comparison purposes, a recommended practice is to use the Rsi (metric) = 2.65 m F/Btu]) label density and thickness for that measurement.  
4.6 If the density for test purposes is not available from the coverage chart, a test density shall be established by use of applicable specifications and codes or, if none apply, agreement between the requesting body and the testing organization.  
4.7 Generally, thin sections of these materials are not uniform. Thus, the test thickness must be greater than or equal to the product’s representative thickness if the results are to be consistent and typical of use.
Note 1: The representative thickness is specific for each product and is determined by running a series of tests in which the density is held constant but the thickness is increased. The representative thickness is defined here as that thickness above which there is no more than a 2 % change in the resistivity of the product. The representative thickness is a function of product blown density. In gene...
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1.1 This practice presents a laboratory guide to determine the thermal resistance of pneumatically installed loose-fill building insulations for enclosed applications of the building thermal envelope behind netting at mean temperatures between –10 and 35°C (14 to 95°F).  
1.2 This practice applies to a wide variety of loose-fill thermal insulation products including but not limited to fibrous glass, rock/slag wool, or cellulosic fiber materials and any other insulation material that can be installed pneumatically. It does not apply to products that change their character after installation either by chemical reaction or the application of binders, adhesives or other materials that are not used in the sample preparation described in this practice, nor does it consider the effects of structures, containments, facings, or air films.  
1.3 Since this practice is designed for reproducible product comparison, it measures the thermal resistance of an insulation material which has been preconditioned to a relatively dry state. Consideration of changes of thermal performance of a hygroscopic insulation by sorption of water is beyond the scope of this practice.  
1.4 The sample preparation techniques outlined in this practice do not cover the characterization of loose-fill materials intended for open applications and not intended for spray-applied applications.  
1.5 The values stated in SI units are to be regarded as the standard. The values given in parentheses are for information only.  
1.6 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.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in t...

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ASTM
ASTM C1594-23(Specification)
Standard Specification for Polyimide Rigid Cellular Thermal Insulation

ABSTRACT
This specification establishes the composition and physical properties of rigid polyimide cellular foams intended for use as thermal and sound-isolating insulation in commercial and industrial environments. The polyimide insulations covered are classified into three types (Types I, II, and III) according to closed cell content, and into four grades (Grades 1, 2, 3, and 4) according to density. Type II insulation is further divided into two classes (Classes 1 and 2) according to upper temperature limits. Materials shall be manufactured from the appropriate monomers and necessary ingredients. Specimens shall be sampled, tested, and conform accordingly to the following physical property requirements: apparent thermal conductivity; water and gas permeability; density; percent closed cell; upper temperature limit; high temperature stability; compressive strength; compressive force deflection; water vapor transmission; steam aging characteristics (tensile strength, dimensional and weight changes), corrosiveness; chemical resistance; vertical burn characteristics (flame application and time, burn length, and dripping); specific optical smoke density for both flaming and non-flaming exposures; toxic smoke generation; surface burning characteristics (flame spread and smoke developed indices); combustion by-products (carbon monoxide, hydrogen fluoride, hydrogen chloride, nitrogen oxides, sulfur dioxide, and hydrogen cyanide); oxygen index, and 14 scale room burn.
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1.1 This specification covers the composition and physical properties of polyimide foam insulation with nominal densities from 1.0 lb/ft3 to 8.0 lb/ft3 (16 kg/m3 to 128 kg/m3) and intended for use as thermal and sound-isolating insulation for temperatures from −423°F to +600°F (−253°C to +316°C) in commercial and industrial environments.  
1.1.1 The annex shall apply to this specification for marine applications.  
1.1.2 This standard is designed as a material specification and not a design document.  
1.1.3 The values stated in Table 1 and Table 2 are not to be used as design values. It is the buyer’s responsibility to specify design requirements and obtain supporting documentation from the material supplier.  
* = Not available consult manufacturer for additional information.
NA = Not Applicable
NB = A manufacturer can only claim conformance to this standard to the values reported in this table. The * notes are confidential data to the manufacturers and as such are not considered part of any qualifying requirements for the standard and only tell the user to inquire about that data.  
* = Not available consult manufacturer for additional information.
NA = Not Applicable
NB = A manufacturer can only claim conformance to this standard to the values reported in this table. The * notes are confidential data to the manufacturers and as such are not considered part of any qualifying requirements for the standard and only tell the user to inquire about that data.
Note 1: The subject matter of this material specification is not covered by any other ASTM specification. There is no known ISO standard covering the subject of this standard.  
1.2 The values stated in inch-pound units are to be regarded as standard. The values given in parentheses are mathematical conversions to SI units that are provided for information only and are not considered 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 B...

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ASTM
ASTM C1149-23(Specification)
Standard Specification for Self-Supported Spray Applied Cellulosic Thermal Insulation

ABSTRACT
This specification covers self-supported spray applied cellulosic thermal insulation for use as thermal insulation or acoustical absorbent material, or both. The chemically-treated cellulosic materials that are also covered in this specification are used for pneumatic applications operating within a specific temperature range. The materials are classified into two types based on the type of adhesive used and exposure of the application. Specimens for testing should be prepared and tested using the prescribed methods and should conform to the specified values of density, thermal resistance, surface bonding characteristics, adhesive strength, cohesive strength, smoldering combustion, fungi resistance, corrosion, moisture vapor absorption, odor, flame resistance permanency, substrate deflection, and air erosion.
SCOPE
1.1 The specification covers the physical properties of self-supported spray applied cellulosic fibers intended for use as thermal insulation or an acoustical absorbent material, or both.  
1.2 This specification covers chemically treated cellulosic materials intended for pneumatic applications where temperatures do not exceed 82.2°C and where temperatures will routinely remain below 65.6°C.  
1.2.1 Type I—Material applied with liquid adhesive and suitable for either exposed or enclosed applications.  
1.2.2 Type II—Materials containing a dry adhesive that is activated by water during installation and intended only for enclosed or covered applications.  
1.3 This is a material specification only and is not intended to deal with methods of application that are supplied by the manufacturer.  
1.4 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.5 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
ASTM C1058/C1058M-10(2023)(Practice)
Standard Practice for Selecting Temperatures for Evaluating and Reporting Thermal Properties of Thermal Insulation

SIGNIFICANCE AND USE
4.1 The various methods for measuring and calculating thermal properties provide data and information for manufacturer's published information, for comparison of related products, and for designers and users to evaluate insulation products for particular applications. For these purposes it is advisable to provide basic data and information produced under standard temperature conditions.  
4.2 It is possible that thermal properties of a specimen will change with mean temperature, with temperature difference across the specimens, and with high temperature exposure. Data and information at standard temperatures are necessary for valid comparison of thermal properties.  
4.3 The mean test temperatures to measure thermal properties shall be selected from those listed in Table 1. It is recommended that thermal properties of insulation materials be evaluated over a mean temperature range that represents the intended end use. For this situation, the lowest and greatest mean temperatures need to be within 10°C of the maximum and minimum mean temperature of interest. The temperature differences for any chosen mean temperature will depend upon both the thermal insulation application (see appropriate materials specification), the method of evaluation, and the limitations of the apparatus. Temperature differences or relevant temperature conditions required by ASTM material specifications shall take precedence over those recommended in this practice. (A) The values in degrees Fahrenheit given in this table are not intended to be exact conversions of those values in degrees Celsius.  
4.3.1 Standard conditions are presented where both surfaces are exposed to fixed ambient temperatures that are typical for testing building constructions, both insulated and uninsulated (Table 2). (A) Thermal transmission properties of panels of various building constructions are thermal transmittance (U), and thermal conductance (C).(B) Celsius temperatures are standard. The values in degrees Fa...
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1.1 This practice covers standard mean temperatures for reporting thermal properties of thermal insulations, products, and materials, and of related systems and components, both insulated and uninsulated.  
1.2 Thermal properties shall be determined as a function of temperature by standard test methods. (Test Methods C177, C201, C335/C335M, C518, C745, C1114, C1363, Guide C653, and Practice C687, all in combination with Practice C1045.)  
Note 1: Standard referenced materials are needed to span the temperature range of the tests.  
1.3 This practice recommends standard conditions for use in testing and evaluating thermal properties as a function of temperature by standard test methods.  
1.4 General applications of thermal insulations include:  
1.4.1 Building envelopes,  
1.4.2 Mechanical systems or processes, and  
1.4.3 Building and industrial insulations.  
1.5 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.  
1.6 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.  
1.7 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
ASTM C1374-18(2023)(Test Method)
Standard Test Method for Determination of Installed Thickness of Pneumatically Applied Loose-Fill Building Insulation

SIGNIFICANCE AND USE
5.1 This test method was designed to give the manufacturer of loose-fill insulation products a way of determining what the initial installed thickness should be in a horizontal open attic for pneumatic applications.  
5.2 The installed thickness value developed by this test method is intended to provide guidance to the installer in order to achieve a minimum mass/unit area for a given R-value.  
5.3 For the purpose of product design, testing should be done at a variety of R-values. At least three R-values should be used: the lowest R-value on the product label, the highest R-value on the product label, and an R-value near the midpoint of the R-value range.
Note 1: For quality control purposes, testing may be done at one R-value of R-19 (h×ft 2×°F/Btu) or higher.  
5.4 Specimens are blown in a manner consistent with the intended installation procedure. Blowing machine settings should be representative of those typically used for field application with that machine.  
5.5 The material blown for a given R-value as part of the installed thickness test equals the installed mass/unit area times the test chamber area. This mass can be calculated from information provided on the package label at the R-value prescribed.
SCOPE
1.1 This test method covers determination of the installed thickness of pneumatically applied loose-fill building insulations prior to settling by simulating an open attic with horizontal blown applications.  
1.2 This test method is a laboratory procedure for use by manufacturers of loose-fill insulation for product design, label development, and quality control testing. The apparatus used produces installed thickness results at a given mass/unit area.  
1.3 This test method is not the same as the design density procedures described in Test Methods C520 or Specifications C739 or C764.  
1.4 The values stated in inch-pound units are to be regarded as standard. The values given in parentheses are mathematical conversions to SI units that are provided for information only and are not considered 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 C1919-22(Practice)
Standard Practice for Measurement of the Steady-State Thermal Transmission Properties of Small Specimens Using the Heat Flow Meter Apparatus

SIGNIFICANCE AND USE
5.1 Thermal conductivity measurements on small insulation specimens are important during new product development processes or when larger specimens cannot be collected during forensic investigation (that is, failure analysis) (1, 2).  
5.2 Numerous research projects have recently been initiated to develop insulation materials that have very high thermal resistivities (greater than 83 (m K)/W). Projects ranging from coatings to improve the thermal performance of single pane/layer glazing systems to the development of novel insulation products for building envelopes are being undertaken (1-4). All these projects have struggled in the development of new material technologies due to the difficulty associated with the measurement of thermal conductivity of small sections (approximately 0.025 m by 0.025 m) of high thermal resistance materials. As new materials are being developed, the size of each test specimen impacts the cost of development. Most of the existing test equipment and the methods do not align with the researcher’s need; the equipment requires a large specimen size is time consuming, and expensive to produce.  
5.3 This practice provides a standardized procedure to enable the thermal characterization of small specimens of insulation materials. Accurate, and reliable thermal metrology to assess thermal properties of new insulation materials, such as novel very low thermal conductivity (  
5.4 The ratio of the area of the specimen and the heat flux transducer has a significant impact on the uncertainty of the results obtained from this practice. As the specimen area decreases this ratio decreases, a smaller percentage of the total heat flow is associated with the unknown specimen. Information from the literature (4) shows that some heat-flow-meter apparatus, generally not available commercially and used by the research laboratories only, can be modified to change out the heat flux transducer so that transducers of varying sizes can be deployed. The observat...
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1.1 This practice covers the measurement of steady state thermal transmission properties of the small flat slab thermal insulation specimen using a heat-flow-meter apparatus.  
1.2 This practice provides a supplemental procedure for use in conjunction with Test Method C518 for testing a small specimen. This practice is limited to only small specimens and, in all other particulars, the requirements of Test Method C518 apply.  
1.3 This practice characterizes small specimens having lateral dimensions less than the lateral dimensions of the heat flux transducer used to measure the heat flow. The procedure in Test Method C518 shall be used for specimens having lateral dimensions equal to or larger than the lateral dimensions of the heat flux transducer.
Note 1: The lower limit for specimen size is typically determined by the user for their particular material. As an example, Ref. (1)2 established a lower limit for specimen dimensions of 0.1 m by 0.1 m for several different thermal insulation materials for a 0.3 m by 0.3 m heat-flow-meter apparatus having a heat flux transducer 0.15 m by 0.15 m.  
1.4 This practice is intended only for research purposes, in particular, when larger specimens are unavailable. This practice shall not be used in conjunction with Test Method C518 for certification testing of products; compliance with ASTM Specifications; or compliance with regulatory or building code requirements.  
1.5 The values stated in SI units are to be regarded as the standard. No other units of measurement are included in this practice.  
1.6 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.  
1.7 This international standard was developed in accordance with internationall...

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ASTM C1199-22(Test Method)
Standard Test Method for Measuring the Steady-State Thermal Transmittance of Fenestration Systems Using Hot Box Methods

SIGNIFICANCE AND USE
4.1 This test method details the calibration and testing procedures and necessary additional temperature instrumentation required in applying Test Method C1363 to measure the thermal transmittance of fenestration systems mounted vertically in the thermal chamber.  
4.2 The thermal transmittance of a test specimen is affected by its size and three-dimensional geometry. Care must be exercised when extrapolating to product sizes smaller or larger than the test specimen. Therefore, it is recommended that fenestration systems be tested at the recommended sizes specified in Practice E1423 or NFRC 100.  
4.3 Since both temperature and surface heat transfer coefficient conditions affect results, use of recommended conditions will assist in reducing confusion caused by comparing results of tests performed under dissimilar conditions. Standardized test conditions for determining the thermal transmittance of fenestration systems are specified in Practice E1423 and Section 6.2. The performance of a test specimen measured at standardized test conditions is potentially different than the performance of the same fenestration product when installed in the wall of a building located outdoors. Standardized test conditions often represent extreme summer or winter design conditions, which are potentially different than the average conditions typically experienced by a fenestration product installed in an exterior wall. For the purpose of comparison, it is essential to calibrate with surface heat transfer coefficients on the Calibration Transfer Standard (CTS) which are as close as possible to the conventionally accepted values for building design; however, this procedure can be used at other conditions for research purposes or product development.  
4.4 Similarly, it would be desirable to have a surround panel that closely duplicates the actual wall where the fenestration system would be installed. Since there are such a wide variety of fenestration system openings in North American...
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1.1 This test method covers requirements and guidelines and specifies calibration procedures required for the measurement of the steady-state thermal transmittance of fenestration systems installed vertically in the test chamber. This test method specifies the necessary measurements to be made using measurement systems conforming to Test Method C1363 for determination of fenestration system thermal transmittance.  
Note 1: This test method allows the testing of projecting fenestration products (that is, garden windows, skylights, and roof windows) installed vertically in a surround panel. Current research on skylights, roof windows, and projecting products hopefully will provide additional information that can be added to the next version of this test method so that skylight and roof windows can be tested horizontally or at some angle typical of a sloping roof.  
1.2 This test method refers to the thermal transmittance, U of a fenestration system installed vertically in the absence of solar radiation and air leakage effects.
Note 2: The methods described in this document may also be adapted for use in determining the thermal transmittance of sections of building wall, and roof and floor assemblies containing thermal anomalies, which are smaller than the hot box metering area.  
1.3 This test method describes how to determine the thermal transmittance, US of a fenestration product (also called test specimen) at well-defined environmental conditions. The thermal transmittance is also a reported test result from Test Method C1363. If only the thermal transmittance is reported using this test method, the test report must also include a detailed description of the environmental conditions in the thermal chamber during the test as outlined in 10.1.14.  
1.4 For rating purposes, this test method also describes how to calculate a standardized thermal transmittance,  UST, which can be used to compare test results from labor...

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