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ASTM A912/A912M-11(2019)

(Test Method)

Standard Test Method for Alternating-Current Magnetic Properties of Amorphous Materials at Power Frequencies Using Wattmeter-Ammeter-Voltmeter Method with Toroidal Specimens

Standard Test Method for Alternating-Current Magnetic Properties of Amorphous Materials at Power Frequencies Using Wattmeter-Ammeter-Voltmeter Method with Toroidal Specimens

SIGNIFICANCE AND USE
3.1 This test method provides a satisfactory means of determining various ac magnetic properties of amorphous magnetic materials.  
3.2 The procedures described herein are suitable for use by producers and users of magnetic materials for materials specification acceptance and manufacturing control.  
3.3 The procedures described herein may be adapted for use with specimens of other alloys and other toroidal forms.
SCOPE
1.1 This test method covers tests for various magnetic properties of amorphous materials at power frequencies [25 to 400 Hz] using a toroidal test transformer. The term “toroidal test transformer” is used to describe the test device, reserving the term “specimen” to refer to the material used in the test. The test specimen consists of toroidally wound flat strip.  
1.2 This test method covers the determination of core loss, exciting power, rms and peak exciting current, several types of ac permeability, and related properties under ac magnetization at moderate and high inductions at power frequencies [25 to 70 Hz].  
1.3 With proper instrumentation and specimen preparation, this test method is acceptable for measurements at frequencies from 5 Hz to 100 kHz. Proper instrumentation implies that all test instruments have the required frequency bandwidth. Also see Annex A2.  
1.4 This test method also provides procedures for calculating impedance permeability from measured values of rms exciting current and for calculating ac peak permeability from measured peak values of total exciting current at magnetic field strengths up to about 10 Oe [796 A/m].  
1.5 Explanations of symbols and brief definitions appear in the text of this test method. The official symbols and definitions are listed in Terminology A340.  
1.6 This test method shall be used in conjunction with Practice A34/A34M.  
1.7 The values and equations stated in customary (cgs-emu and inch-pound) units or SI units are to be regarded separately as standard. Within this standard, SI units are shown in brackets. 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 nonconformance with this standard.  
1.8 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.  
1.9 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.

General Information

Status
Published
Publication Date
31-Mar-2019
ICS
77.040.99 - Other methods of testing of metals
Technical Committee
A06 - Magnetic Properties
Drafting Committee
A06.01 - Test Methods
Current Stage
Ref Project

Relations

Replaces
ASTM A912/A912M-11 - Standard Test Method for Alternating-Current Magnetic Properties of Amorphous Materials at Power Frequencies Using Wattmeter-Ammeter-Voltmeter Method with Toroidal Specimens
Effective Date
01-Apr-2019
Refers
ASTM A340-23a - Standard Terminology of Symbols and Definitions Relating to Magnetic Testing
Effective Date
01-Dec-2023
Refers
ASTM A340-19b - Standard Terminology of Symbols and Definitions Relating to Magnetic Testing
Effective Date
15-Oct-2019
Refers
ASTM C693-93(2019) - Standard Test Method for Density of Glass by Buoyancy
Effective Date
01-Aug-2019
Refers
ASTM A340-19a - Standard Terminology of Symbols and Definitions Relating to Magnetic Testing
Effective Date
15-Jun-2019
Refers
ASTM A343/A343M-14(2019) - Standard Test Method for Alternating-Current Magnetic Properties of Materials at Power Frequencies Using Wattmeter-Ammeter-Voltmeter Method and 25-cm Epstein Test Frame
Effective Date
01-Apr-2019
Refers
ASTM A340-19 - Standard Terminology of Symbols and Definitions Relating to Magnetic Testing
Effective Date
15-Feb-2019
Refers
ASTM A340-18 - Standard Terminology of Symbols and Definitions Relating to Magnetic Testing
Effective Date
01-Jun-2018
Refers
ASTM A340-17a - Standard Terminology of Symbols and Definitions Relating to Magnetic Testing
Effective Date
15-Oct-2017
Refers
ASTM A340-17 - Standard Terminology of Symbols and Definitions Relating to Magnetic Testing
Effective Date
01-Jul-2017
Refers
ASTM A340-16 - Standard Terminology of Symbols and Definitions Relating to Magnetic Testing
Effective Date
01-May-2016
Refers
ASTM A340-16e1 - Standard Terminology of Symbols and Definitions Relating to Magnetic Testing
Effective Date
01-May-2016
Refers
ASTM A340-15 - Standard Terminology of Symbols and Definitions Relating to Magnetic Testing
Effective Date
01-Oct-2015
Refers
ASTM A340-14 - Standard Terminology of Symbols and Definitions Relating to Magnetic Testing
Effective Date
01-Oct-2014
Refers
ASTM A343/A343M-14 - Standard Test Method for Alternating-Current Magnetic Properties of Materials at Power Frequencies Using Wattmeter-Ammeter-Voltmeter Method and 25-cm Epstein Test Frame
Effective Date
01-May-2014

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ASTM A912/A912M-11(2019) - Standard Test Method for Alternating-Current Magnetic Properties of Amorphous Materials at Power Frequencies Using Wattmeter-Ammeter-Voltmeter Method with Toroidal SpecimensASTM A912/A912M-11(2019) - Standard Test Method for Alternating-Current Magnetic Properties of Amorphous Materials at Power Frequencies Using Wattmeter-Ammeter-Voltmeter Method with Toroidal Specimens
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ASTM A912/A912M-11(2019) - Standard Test Method for Alternating-Current Magnetic Properties of Amorphous Materials at Power Frequencies Using Wattmeter-Ammeter-Voltmeter Method with Toroidal Specimens
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Standards Content (Sample)


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: A912/A912M − 11 (Reapproved 2019)
Standard Test Method for
Alternating-Current Magnetic Properties of Amorphous
Materials at Power Frequencies Using Wattmeter-Ammeter-
Voltmeter Method with Toroidal Specimens
This standard is issued under the fixed designationA912/A912M; 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 of the other. Combining values from the two systems may
result in nonconformance with this standard.
1.1 This test method covers tests for various magnetic
1.8 This standard does not purport to address all of the
properties of amorphous materials at power frequencies [25 to
safety concerns, if any, associated with its use. It is the
400 Hz] using a toroidal test transformer. The term “toroidal
responsibility of the user of this standard to establish appro-
test transformer” is used to describe the test device, reserving
priate safety, health, and environmental practices and deter-
the term “specimen” to refer to the material used in the test.
mine the applicability of regulatory limitations prior to use.
The test specimen consists of toroidally wound flat strip.
1.9 This international standard was developed in accor-
1.2 This test method covers the determination of core loss,
dance with internationally recognized principles on standard-
exciting power, rms and peak exciting current, several types of
ization established in the Decision on Principles for the
ac permeability, and related properties under ac magnetization
Development of International Standards, Guides and Recom-
atmoderateandhighinductionsatpowerfrequencies[25to70
mendations issued by the World Trade Organization Technical
Hz].
Barriers to Trade (TBT) Committee.
1.3 With proper instrumentation and specimen preparation,
this test method is acceptable for measurements at frequencies
2. Referenced Documents
from 5 Hz to 100 kHz. Proper instrumentation implies that all
2.1 ASTM Standards:
test instruments have the required frequency bandwidth. Also
A34/A34MPractice for Sampling and Procurement Testing
see Annex A2.
of Magnetic Materials
1.4 This test method also provides procedures for calculat-
A340Terminology of Symbols and Definitions Relating to
ing impedance permeability from measured values of rms
Magnetic Testing
exciting current and for calculating ac peak permeability from
A343/A343MTest Method for Alternating-Current Mag-
measuredpeakvaluesoftotalexcitingcurrentatmagneticfield
netic Properties of Materials at Power Frequencies Using
strengths up to about 10 Oe [796 A/m].
Wattmeter-Ammeter-Voltmeter Method and 25-cm Ep-
stein Test Frame
1.5 Explanations of symbols and brief definitions appear in
A901Specification for Amorphous Magnetic Core Alloys,
thetextofthistestmethod.Theofficialsymbolsanddefinitions
Semi-Processed Types
are listed in Terminology A340.
C693Test Method for Density of Glass by Buoyancy
1.6 This test method shall be used in conjunction with
Practice A34/A34M.
3. Significance and Use
1.7 The values and equations stated in customary (cgs-emu
3.1 This test method provides a satisfactory means of
and inch-pound) units or SI units are to be regarded separately
determining various ac magnetic properties of amorphous
as standard. Within this standard, SI units are shown in
magnetic materials.
brackets. The values stated in each system may not be exact
3.2 The procedures described herein are suitable for use by
equivalents;therefore,eachsystemshallbeusedindependently
producers and users of magnetic materials for materials speci-
fication acceptance and manufacturing control.
This test method is under the jurisdiction of ASTM Committee A06 on
MagneticPropertiesandisthedirectresponsibilityofSubcommitteeA06.01onTest
Methods. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Current edition approved April 1, 2019. Published April 2019. Originally contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
approved in 1992. Last previous edition approved in 2011 as A912/A912M–11. Standards volume information, refer to the standard’s Document Summary page on
DOI: 10.1520/A0912_A0912M-11R19. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
A912/A912M − 11 (2019)
3.3 Theproceduresdescribedhereinmaybeadaptedforuse 5.3 Instruments:
with specimens of other alloys and other toroidal forms.
5.3.1 Electronic digital instruments are preferred for use in
this test method. The use of analog instruments is permitted
4. Interferences
provided the requirements given in 5.3.2 – 5.5.2 as well as the
4.1 Test methods using toroidal test transformers are espe- requirements given in Test Method A343/A343M are met.
cially useful for evaluating the magnetic properties of a
5.3.1.1 Theelectricalimpedanceandaccuracyrequirements
material. There are, however, several important requirements
are given in 5.3.2 – 5.5.2. The operating principles for the
to be met when determining the material characteristics.
various instruments are not specified.
4.1.1 Theratioofinsidetooutsidediametermustbe0.82or
5.3.1.2 Combination instruments (volt-watt-ammeters) may
greater, or the magnetic field strength will be excessively
beusedprovidedtherequirementsgivenin5.3.2–5.5.2forthe
nonuniform throughout the test specimen and the measured
individual instruments are met.
parameters will not represent the basic material properties.
5.3.1.3 Automatic or data logging equipment may be used.
4.1.2 To best represent the average material properties, the
Itispreferablefortheoperatortohavearecordavailableofthe
cross-sectional area of the toroid should be uniform and the
specimen identification and measured values of the tests being
winding should be designed to avoid nonuniform induction.
performed.
4.1.3 Preparation of test specimens, especially of stress
5.3.1.4 Although electronic digital equipment usually fails
sensitivealloys,iscritical.Stressesthatareintroducedintoflat
catastrophically and errors are easily detected, it is incumbent
strip material when it is wound into a toroid depend on the
upon the user of this test method to ensure that the instruments
diameteroftheresultingtoroid,thethicknessanduniformityof
continue to meet the performance requirements.
the material, and the winding tension. These stresses shall be
5.3.2 Flux Voltmeter—A full-wave, true-average voltmeter,
removed or reduced by annealing. The annealing conditions
=2π
(time, temperature, and atmosphere) are a function of the
with scale reading in average volts times so that its
material chosen. The details of sample preparation must be
indications will be identical with those of a true rms voltmeter
agreed upon between the producer and user. Suggested condi-
on a pure sinusoidal voltage, shall be provided for evaluating
tions for preparation of amorphous specimens are contained in
the peak value of the test induction. To produce the estimated
Annex A2, Annex A3, Annex A4, and Annex A5.
precision of test under this test method, the full-scale meter
errorsshallnotexceed 60.25%(Note1).Metersof 60.5%or
5. Apparatus
more error may be used at reduced accuracy.
5.1 Theapparatusshallconsistofasmanyofthecomponent
5.3.3 RMS Voltmeter—Atrue rms-indicating voltmeter shall
parts shown in the basic block circuit diagram (Fig. 1)asare
be provided for evaluating the form factor of the voltage
required to perform the desired measurement functions.
induced in the secondary winding of the test fixture and for
5.2 Toroidal Test Transformer—The test transformer shall
evaluating the instrument losses. The accuracy of the rms
consist of a toroidal specimen, prepared as directed in Annex
voltmeter shall be the same as specified for the flux voltmeter.
A2, enclosed by primary and secondary windings. When the
5.3.3.1 The normally high input impedance of digital flux
test specimen is small or especially stressed, the use of a
and rms voltmeters will minimize loading effects and reduce
protective case, bobbin, spool, or core form is necessary, see
the magnitude of instrument losses to an insignificant value.
Annex A3.
5.3.3.2 Anelectronicscalingamplifiermaybeusedtocause
5.2.1 The primary and secondary windings may be any
the flux voltmeter and the rms voltmeter to indicate directly in
number of turns suited to the instrumentation, mass of
units of induction. The input impedance of the scaling ampli-
specimen, and test frequency. A 1:1 turns ratio is recom-
fier must be high enough to minimize loading effects and
mended.Anair-fluxcompensatoristobeusedwhenevertheair
instrumentlosses.Thecombinationofabasicinstrumentanda
flux is a measurable fraction of the total flux.
scalingdevicemustconformtothespecificationsstatedabove.
NOTE 1—Inaccuracies in setting the flux voltage produce errors
approximately two times as large in the specific core loss.
5.4 Wattmeter—The full-scale accuracy of the wattmeter
must not be poorer than 0.25% at the frequency of test and at
unity power factor. The power factor encountered by a watt-
meter during a core-loss test on a specimen is always less than
unityand,atinductionsfarabovethekneeofthemagnetization
curve,approacheszero.Thewattmetermustmaintainadequate
accuracy (1% of reading) even at the most severe (lowest)
power factor that is presented to it. Variable scaling devices
maybeusedtocausethewattmetertoindicatedirectlyinunits
ofspecificcorelossifthecombinationofbasicinstrumentand
scaling devices conforms to the specifications stated here.
5.4.1 Electronic Digital Wattmeter—An electronic digital
FIG. 1 Basic Circuit Diagram for Wattmeter Method wattmeter is preferred in this test method because of its high
A912/A912M − 11 (2019)
sensitivity, digital readout, and its capability for direct inter- a nominal full-scale accuracy of at least 3% at the test
facing with electronic data acquisition systems. frequency and be able to accommodate a voltage with a crest
factor of 5 or more.
5.4.1.1 The voltage input circuitry of the electronic digital
wattmeter must have an input impedance high enough that
5.6 Series Resistor—The standard series resistor (usually in
connection of the circuitry, during testing, to the secondary
the range 0.1 to 1.0 Ω) that carries the exciting current must
windingofthetestfixturedoesnotchangetheterminalvoltage
have adequate current-carrying capacity and be accurate to at
of the secondary by more than 0.05%.Also, the voltage input least 60.1%. It must have negligible temperature and fre-
circuitry must be capable of accepting the maximum peak quency variation with the conditions applicable to this test
voltage, which is induced in the secondary winding during method. If desired, the value of the resistor may be such that
testing. the peak-reading voltmeter indicates directly in terms of peak
magnetic field strength provided that the resistor conforms to
5.4.1.2 The current input circuitry of the electronic digital
the limitations stated herein.
wattmeter should have as low an input impedance as possible,
preferably no more than 0.1 Ω, otherwise the flux waveform 5.7 Power Supply—Asourceofsinusoidaltestpoweroflow
distortion can be corrected for as described in 9.3. The current internal impedance and excellent voltage and frequency stabil-
input circuitry must be capable of accepting the maximum rms ity is required for this test. The voltage for the test circuit may
be adjustable by use of a tapped transformer between the
current and the maximum peak current drawn by the primary
source and the test circuit or by generator field control. The
winding of the test transformer when core-loss tests are being
harmonic content of the voltage output from the source under
performed. In particular, since the primary current will be very
the heaviest test load should not exceed 1%. For testing at
nonsinusoidal (peaked) if core-loss tests are performed on a
commercial power frequencies, the volt-ampere rating of the
specimen at inductions above the knee of the magnetizing
source and its associated voltage control equipment should be
curve, the crest factor capability of the current input circuitry
adequate to supply the requirements of the test specimen
should be 4 or more.
without an excessive increase in the distortion of the voltage
5.4.2 Waveform Calculator—A waveform calculator, in
waveform. Voltage stability within 60.1% is necessary for
combination with a digitizing oscilloscope, may be used in
precise work. For testing at commercial frequencies, low-
place of the wattmeter for core-loss measurements, provided
distortion line voltage regulating equipment is available. The
that it meets the accuracy requirements given in 5.4. This
frequency of the source should be accurately controlled within
equipment is able to measure, compute, and display the rms,
60.1% of the nominal value.
average, and peak values for current and flux voltage, as well
5.7.1 An electronic power source consisting of a low-
as measure the core loss and excitation power demand. It is
distortion oscillator (Note 2) and a linear amplifier makes an
convenient for making a large number of repetitive measure-
acceptable source of test power. The form factor of the test
ments. See Appendix X2 for details regarding these instru-
=

ments.
voltage should be as close to as practicable and must be
5.4.2.1 The current and flux sensing leads must be con-
within 61% of this value. The line power for the electronic
nected in the proper phase relationship.
oscillator and amplifier should come from a voltage-regulated
5.4.2.2 The normally high input impedance of these instru-
source to ensure voltage stability within 0.1%, and the output
ments(approximately1MΩ)reducespossibleerrorsasaresult ofthesystemshouldbemonitoredwithanaccuratefrequency-
of instrument loading to negligible levels.
indicating device to see that control of the frequency is
maintained to within 60.1% or better. It is permissible to use
5.5 Ammeters—Two types of current measurements are
an amplifier with negative feedback to reduce the waveform
used in conjunction with this test method: rms current values
distortion.
are used for calculating exciting power and impedance perme-
NOTE 2—It is advisable when testing at power line frequency to have
ability while peak current values are used for calculating peak
the oscillator synchronized with the power line.
permeability. The prefe
...

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4.4 The microscopic test methods are employed to characterize inclusions that form as a result of deoxidation or due to limited solubility in solid steel (indigenous inclusions). As stated in 1.1, these microscopic test methods rate inclusion severities and types based on morphological type, that is, by size, shape, concentration, and distribution, but not specifically by composition. These inclusions are characterized by morphological type, that is, by size, shape, concentration, and distribution, but not specifically by composition. The microscopic methods are not intended for assessing the content of exogenous inclusions (those from entrapped slag or refractories). In case of a dispute whether an inclusion is indigenous or exogenous, microanalytical techniques such as energy dispersive X-ray spectroscopy (EDS) may be used to aid in determining the nature of the inclusion. However, experience and knowledge of the casting proce...
SCOPE
1.1 These test methods cover a number of recognized procedures for determining the nonmetallic inclusion content of wrought steel. Macroscopic methods include macroetch, fracture, step-down, and magnetic particle tests. Microscopic methods include five generally accepted systems of examination. In these microscopic methods, inclusions are assigned to a category based on similarities in morphology, and not necessarily on their chemical identity. Metallographic techniques that allow simple differentiation between morphologically similar inclusions are briefly discussed. While the methods are primarily intended for rating inclusions, constituents such as carbides, nitrides, carbonitrides, borides, and intermetallic phases may be rated using some of the microscopic methods. In some cases, alloys other than steels may be rated using one or more of these methods; the methods will be described in terms of their use on steels.  
1.2 These test methods cover procedures to perform JK-type inclusion ratings using automatic image analysis in accordance with microscopic methods A and D.  
1.3 Depending on the type of steel and the properties required, either a macroscopic or a microscopic method for determining the inclusion content, or combinations of the two methods, may be found most satisfactory.  
1.4 These test methods deal only with recommended test methods and nothing in them should be construed as defining or establishing limits of acceptability for any grade of steel.  
1.5 The values stated in SI units are to be regarded as standard. The values given in parentheses after SI units are provided for information only and are not considered 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...

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ASTM E407-23(Practice)
Standard Practice for Microetching Metals and Alloys

SIGNIFICANCE AND USE
5.1 This practice lists recommended methods and solutions for the etching of specimens for metallographic examination. Solutions are listed that highlight the phases and constituents present in most major alloy systems.
SCOPE
1.1 This practice covers chemical solutions and procedures to be used in etching metals and alloys for microscopic examination. Safety precautions and miscellaneous information are also included.  
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. For specific cautionary statements, see 6.1 and Table 2.  
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 A1033-18(2023)(Practice)
Standard Practice for Quantitative Measurement and Reporting of Hypoeutectoid Carbon and Low-Alloy Steel Phase Transformations

SIGNIFICANCE AND USE
5.1 This practice is used to provide steel phase transformation data required for use in numerical models for the prediction of microstructures, properties, and distortion during steel manufacturing, forging, casting, heat treatment, and welding. Alternatively, the practice provides end users of steel and fabricated steel products the phase transformation data required for selecting steel grades for a given application by determining the microstructure resulting from a prescribed thermal cycle.  
5.1.1 There are available several computer models designed to predict the microstructures, mechanical properties, and distortion of steels as a function of thermal processing cycle. Their use is predicated on the availability of accurate and consistent thermal and transformation strain data. Strain, both thermal and transformation, developed during thermal cycling is the parameter used in predicting both microstructure and properties, and for estimating distortion. It should be noted that these models are undergoing continued development. This process is aimed, among other things, at establishing a direct link between discrete values of strain and specific microstructure constituents in steels. This practice describes a standardized method for measuring strain during a defined thermal cycle.  
5.1.2 This practice is suitable for providing data for computer models used in the control of steel manufacturing, forging, casting, heat-treating, and welding processes. It is also useful in providing data for the prediction of microstructures and properties to assist in steel alloy selection for end-use applications.  
5.1.3 This practice is suitable for providing the data needed for the construction of transformation diagrams that depict the microstructures developed during the thermal processing of steels as functions of time and temperature. Such diagrams provide a qualitative assessment of the effects of changes in thermal cycle on steel microstructure. Appendix X2 describes ...
SCOPE
1.1 This practice covers the determination of hypoeutectoid steel phase transformation behavior by using high-speed dilatometry techniques for measuring linear dimensional change as a function of time and temperature, and reporting the results as linear strain in either a numerical or graphical format.  
1.2 The practice is applicable to high-speed dilatometry equipment capable of programmable thermal profiles and with digital data storage and output capability.  
1.3 This practice is applicable to the determination of steel phase transformation behavior under both isothermal and continuous cooling conditions.  
1.4 This practice includes requirements for obtaining metallographic information to be used as a supplement to the dilatometry measurements.  
1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this 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 E942-23(Guide)
Standard Guide for Investigating the Effects of Helium in Irradiated Metals

ABSTRACT
This guide presents the simulation procedure which would provide advice for conducting experiments to investigate the effects of helium on the properties of irradiated metals where the technique for introducing the helium differs in someway from the actual mechanism of introduction of helium in service. Simulation techniques considered for introducing helium shall include charged particle implantation, exposure to α-emitting radioisotopes, and tritium decay techniques. Procedures for the analysis of helium content and helium distribution within the specimen are also recommended. The two other methods for introducing helium into irradiated materials namely, the enhancement of helium production in nickel-bearing alloys by spectral tailoring in mixed-spectrum fission reactors, and the isotopic tailoring in both fast and mixed-spectrum fission reactors, are not covered in this guide. Dual ion beam techniques for simultaneously implanting helium and generating displacement damage are also not included here.
SIGNIFICANCE AND USE
4.1 Helium is introduced into metals as a consequence of nuclear reactions, such as (n, α), or by the injection of helium into metals from the plasma in fusion reactors. The characterization of the effect of helium on the properties of metals using direct irradiation methods may be impractical because of the time required to perform the irradiation or the lack of a radiation facility, as in the case of the fusion reactor. Simulation techniques can accelerate the research by identifying and isolating major effects caused by the presence of helium. The word ‘simulation’ is used here in a broad sense to imply an approximation of the relevant irradiation environment. There are many complex interactions between the helium produced during irradiation and other irradiation effects, so care must be exercised to ensure that the effects being studied are a suitable approximation of the real effect. By way of illustration, details of helium introduction, especially the implantation temperature, may determine the subsequent distribution of the helium (that is, dispersed atomistically, in small clusters in bubbles, etc.).
SCOPE
1.1 This guide provides advice for conducting experiments to investigate the effects of helium on the properties of metals where the technique for introducing the helium differs in some way from the actual mechanism of introduction of helium in service. Techniques considered for introducing helium may include charged particle implantation, exposure to α-emitting radioisotopes, and tritium decay techniques. Procedures for the analysis of helium content and helium distribution within the specimen are also recommended.  
1.2 Three other methods for introducing helium into irradiated materials are not covered in this guide. They are: (1) the enhancement of helium production in nickel-bearing alloys by spectral tailoring in mixed-spectrum fission reactors, (2) a related technique that uses a thin layer of NiAl on the specimen surface to inject helium, and (3) isotopic tailoring in both fast and mixed-spectrum fission reactors. These techniques are described in Refs (1-6).2 Dual ion beam techniques (7) for simultaneously implanting helium and generating displacement damage are also not included here. This latter method is discussed in Practice E521.  
1.3 In addition to helium, hydrogen is also produced in many materials by nuclear transmutation. In some cases it appears to act synergistically with helium (8-10). The specific impact of hydrogen is not addressed in this guide.  
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 regulat...

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ASTM
ASTM A923-23(Test Method)
Standard Test Methods for Detecting Detrimental Intermetallic Phase in Duplex Austenitic/Ferritic Stainless Steels

ABSTRACT
These test methods cover the detection of detrimental intermetallic phase in duplex austenitic/ferritic stainless steel to the extent that toughness and corrosion resistance is affected significantly. These test methods will not necessarily detect losses of toughness or corrosion resistance attributable to other causes. Test method A-sodium hydroxide etch test, test method B-Charpy impact test, and test method C-ferric chloride corrosion test shall be made for classification of structures of duplex stainless steels.
SCOPE
1.1 The purpose of these test methods is to allow detection of the presence of intermetallic phases in certain duplex stainless steels as listed in Table 1, Table 2, and Table 3 to the extent that toughness or corrosion resistance is affected significantly. These test methods will not necessarily detect losses of toughness or corrosion resistance attributable to other causes. Similar test methods for other duplex stainless steels are described in Test Method A1084, but the procedures described in this standard differ significantly from Test Methods A, B, and C in A1084.  
1.2 Duplex (austenitic-ferritic) stainless steels are susceptible to the formation of intermetallic compounds during exposures in the temperature range from approximately 600 to 1750 °F (320 to 955 °C). The speed of these precipitation reactions is a function of composition and thermal or thermomechanical history of each individual piece. The presence of these phases is detrimental to toughness and corrosion resistance.  
1.3 Correct heat treatment of duplex stainless steels can eliminate these detrimental phases. Rapid cooling of the product provides the maximum resistance to formation of detrimental phases by subsequent thermal exposures.  
1.4 Compliance with the chemical and mechanical requirements for the applicable product specification does not necessarily indicate the absence of detrimental phases in the product.  
1.5 These test methods include the following:  
1.5.1 Test Method A—Sodium Hydroxide Etch Test for Classification of Etch Structures of Duplex Stainless Steels (Sections 3 – 7).  
1.5.2 Test Method B—Charpy Impact Test for Classification of Structures of Duplex Stainless Steels (Sections 8 – 13).  
1.5.3 Test Method C—Ferric Chloride Corrosion Test for Classification of Structures of Duplex Stainless Steels (Sections 14 – 20).  
1.6 The presence of detrimental intermetallic phases is readily detected in all three tests, provided that a sample of appropriate location and orientation is selected. Because the occurrence of intermetallic phases is a function of temperature and cooling rate, it is essential that the tests be applied to the region of the material experiencing the conditions most likely to promote the formation of an intermetallic phase. In the case of common heat treatment, this region will be that which cooled most slowly. Except for rapidly cooled material, it may be necessary to sample from a location determined to be the most slowly cooled for the material piece to be characterized.  
1.7 The tests do not determine the precise nature of the detrimental phase but rather the presence or absence of an intermetallic phase to the extent that it is detrimental to the toughness and corrosion resistance of the material.  
1.8 Examples of the correlation of thermal exposures, the occurrence of intermetallic phases, and the degradation of toughness and corrosion resistance are given in Appendix X1 and Appendix X2.  
1.9 The values stated in either inch-pound or SI units are to be regarded as the standard. The values given in parentheses are for information only.  
1.10 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.  
1.11 This internat...

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ASTM
ASTM E1181-02(2023)(Test Method)
Standard Test Methods for Characterizing Duplex Grain Sizes

SIGNIFICANCE AND USE
5.1 Duplex grain size may occur in some metals and alloys as a result of their thermomechanical processing history. For comparison of mechanical properties with metallurgical features, or for specification purposes, it may be important to be able to characterize grain size in such materials. Assigning an average grain size value to a duplex grain size specimen does not adequately characterize the appearance of that specimen, and may even misrepresent its appearance. For example, averaging two distinctly different grain sizes may result in reporting a size that does not actually exist anywhere in the specimen.  
5.2 These test methods may be applied to specimens or products containing randomly intermingled grains of two or more significantly different sizes (henceforth referred to as random duplex grain size). Examples of random duplex grain sizes include: isolated coarse grains in a matrix of much finer grains, extremely wide distributions of grain sizes, and bimodal distributions of grain size.  
5.3 These test methods may also be applied to specimens or products containing grains of two or more significantly different sizes, but distributed in topologically varying patterns (henceforth referred to as topological duplex grain sizes). Examples of topological duplex grain sizes include: systematic variation of grain size across the section of a product, necklace structures, banded structures, and germinative grain growth in selected areas of critical strain.  
5.4 These test methods may be applied to specimens or products regardless of their state of recrystallization.  
5.5 Because these test methods describe deviations from a single, log-normal distribution of grain sizes, and characterize patterns of variation in grain size, the total specimen cross-section must be evaluated.  
5.6 These test methods are limited to duplex grain sizes as identifiable within a single polished and etched metallurgical specimen. If duplex grain size is suspected in a product too ...
SCOPE
1.1 These test methods provide simple guidelines for deciding whether a duplex grain size exists. The test methods separate duplex grain sizes into one of two distinct classes, then into specific types within those classes, and provide systems for grain size characterization of each type.  
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 may involve hazardous materials, operations, and equipment. 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 E1245-03(2023)(Practice)
Standard Practice for Determining the Inclusion or Second-Phase Constituent Content of Metals by Automatic Image Analysis

SIGNIFICANCE AND USE
5.1 This practice is used to assess the indigenous inclusions or second-phase constituents of metals using basic stereological procedures performed by automatic image analyzers.  
5.2 This practice is not suitable for assessing the exogenous inclusions in steels and other metals. Because of the sporadic, unpredictable nature of the distribution of exogenous inclusions, other methods involving complete inspection, for example, ultrasonics, must be used to locate their presence. The exact nature of the exogenous material can then be determined by sectioning into the suspect region followed by serial, step-wise grinding to expose the exogenous matter for identification and individual measurement. Direct size measurement rather than application of stereological methods is employed.  
5.3 Because the characteristics of the indigenous inclusion population vary within a given lot of material due to the influence of compositional fluctuations, solidification conditions and processing, the lot must be sampled statistically to assess its inclusion content. The largest lot sampled is the heat lot but smaller lots, for example, the product of an ingot, within the heat may be sampled as a separate lot. The sampling of a given lot must be adequate for the lot size and characteristics.  
5.4 The practice is suitable for assessment of the indigenous inclusions in any steel (or other metal) product regardless of its size or shape as long as enough different fields can be measured to obtain reasonable statistical confidence in the data. Because the specifics of the manufacture of the product do influence the morphological characteristics of the inclusions, the report should state the relevant manufacturing details, that is, data regarding the deformation history of the product.  
5.5 To compare the inclusion measurement results from different lots of the same or similar types of steels, or other metals, a standard sampling scheme should be adopted such as described in Test Method...
SCOPE
1.1 This practice describes a procedure for obtaining stereological measurements that describe basic characteristics of the morphology of indigenous inclusions in steels and other metals using automatic image analysis. The practice can be applied to provide such data for any discrete second phase.  
Note 1: Stereological measurement methods are used in this practice to assess the average characteristics of inclusions or other second-phase particles on a longitudinal plane-of-polish. This information, by itself, does not produce a three-dimensional description of these constituents in space as deformation processes cause rotation and alignment of these constituents in a preferred manner. Development of such information requires measurements on three orthogonal planes and is beyond the scope of this practice.  
1.2 This practice specifically addresses the problem of producing stereological data when the features of the constituents to be measured make attainment of statistically reliable data difficult.  
1.3 This practice deals only with the recommended test methods and nothing in it should be construed as defining or establishing limits of acceptability.  
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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