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ASTM E2789-10(2021)

(Guide)

Standard Guide for Fretting Fatigue Testing

Standard Guide for Fretting Fatigue Testing

SIGNIFICANCE AND USE
4.1 Fretting fatigue tests are used to determine the effects of several fretting parameters on the fatigue lives of metallic materials. Some of these parameters include differing materials, relative displacement amplitudes, normal force at the fretting contact, alternating tangential force, the contact geometry, surface integrity parameters such as finish, and the environment. Comparative tests are used to determine the effectiveness of palliatives on the fatigue life of specimens with well-controlled boundary conditions so that the mechanics of the fretting fatigue test can be modeled. Generally, it is useful to compare the fretting fatigue response to plain fatigue to obtain knockdown or reduction factors from fretting fatigue. The results may be used as a guide in selecting material combinations, design stress levels, lubricants, and coatings to alleviate or eliminate fretting fatigue concerns in new or existing designs. However, due to the synergisms of fatigue, wear, and corrosion on the fretting fatigue parameters, extreme care should be exercised in the judgment to determine if the test conditions meet the design or system conditions.  
4.2 For data to be comparable, reproducible, and correlated amongst laboratories and relevant to mimic fretting in an application, all parameters critical to the fretting fatigue life of the material in question will need to be replicated. Because alterations in environment, metallurgical properties, fretting loading (controlled forces and displacements), compliance of the test system, etc. can affect the response, no general guidelines exist to quantitatively ascertain what the effect will be on the specimen fretting fatigue life if a single parameter is varied. To assure test results can be correlated and reproduced, all material variables, testing information, physical procedures, and analytical procedures should be reported in a manner that is consistent with good current test practices.  
4.3 Because of the wear phenome...
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1.1 This guide defines terminology and covers general requirements for conducting fretting fatigue tests and reporting the results. It describes the general types of fretting fatigue tests and provides some suggestions on developing and conducting fretting fatigue test programs.  
1.2 Fretting fatigue tests are designed to determine the effects of mechanical and environmental parameters on the fretting fatigue behavior of metallic materials. This guide is not intended to establish preference of one apparatus or specimen design over others, but will establish guidelines for adherence in the design, calibration, and use of fretting fatigue apparatus and recommend the means to collect, record, and reporting of the data.  
1.3 The number of cycles to form a fretting fatigue crack is dependent on both the material of the fatigue specimen and fretting pad, the geometry of contact between the two, and the method by which the loading and displacement are imposed. Similar to wear behavior of materials, it is important to consider fretting fatigue as a system response, instead of a material response. Because of this dependency on the configuration of the system, quantifiable comparisons of various material combinations should be based on tests using similar fretting fatigue configurations and material couples.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

General Information

Status
Published
Publication Date
30-Nov-2021
ICS
77.040.10 - Mechanical testing of metals
Technical Committee
E08 - Fatigue and Fracture
Drafting Committee
E08.05 - Cyclic Deformation and Fatigue Crack Formation
Current Stage
Ref Project

Relations

Refers
ASTM E1823-24a - Standard Terminology Relating to Fatigue and Fracture Testing
Effective Date
15-Feb-2024
Refers
ASTM E1823-24 - Standard Terminology Relating to Fatigue and Fracture Testing
Effective Date
01-Feb-2024
Refers
ASTM E1823-20 - Standard Terminology Relating to Fatigue and Fracture Testing
Effective Date
01-Feb-2020
Refers
ASTM E1942-98(2018)e1 - Standard Guide for Evaluating Data Acquisition Systems Used in Cyclic Fatigue and Fracture Mechanics Testing
Effective Date
01-Jun-2018
Refers
ASTM G40-15 - Standard Terminology Relating to Wear and Erosion
Effective Date
01-Nov-2015
Refers
ASTM E4-14 - Standard Practices for Force Verification of Testing Machines
Effective Date
01-Jun-2014
Refers
ASTM G40-13 - Standard Terminology Relating to Wear and Erosion
Effective Date
01-Jun-2013
Refers
ASTM E1823-12e - Standard Terminology Relating to Fatigue and Fracture Testing
Effective Date
15-Dec-2012
Refers
ASTM E1823-12d - Standard Terminology Relating to Fatigue and Fracture Testing
Effective Date
15-Nov-2012
Refers
ASTM E1823-12c - Standard Terminology Relating to Fatigue and Fracture Testing
Effective Date
01-Sep-2012
Refers
ASTM E1823-12b - Standard Terminology Relating to Fatigue and Fracture Testing
Effective Date
01-Aug-2012
Refers
ASTM E1012-12e1 - Standard Practice for Verification of Testing Frame and Specimen Alignment Under Tensile and Compressive Axial Force Application
Effective Date
01-Jun-2012
Refers
ASTM E1012-12 - Standard Practice for Verification of Testing Frame and Specimen Alignment Under Tensile and Compressive Axial Force Application
Effective Date
01-Jun-2012
Refers
ASTM E1823-12a - Standard Terminology Relating to Fatigue and Fracture Testing
Effective Date
15-May-2012
Refers
ASTM G40-12 - Standard Terminology Relating to Wear and Erosion
Effective Date
01-May-2012

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ASTM E2789-10(2021) - Standard Guide for Fretting Fatigue TestingASTM E2789-10(2021) - Standard Guide for Fretting Fatigue Testing
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ASTM E2789-10(2021) - Standard Guide for Fretting Fatigue Testing
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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: E2789 − 10 (Reapproved 2021)
Standard Guide for
Fretting Fatigue Testing
This standard is issued under the fixed designation E2789; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 2. Referenced Documents
2.1 ASTM Standards:
1.1 This guide defines terminology and covers general
E3 Guide for Preparation of Metallographic Specimens
requirements for conducting fretting fatigue tests and reporting
E4 Practices for Force Calibration and Verification of Test-
the results. It describes the general types of fretting fatigue
ing Machines
tests and provides some suggestions on developing and con-
E466 Practice for Conducting Force Controlled Constant
ducting fretting fatigue test programs.
Amplitude Axial Fatigue Tests of Metallic Materials
1.2 Fretting fatigue tests are designed to determine the
E467 Practice for Verification of Constant Amplitude Dy-
effects of mechanical and environmental parameters on the
namic Forces in an Axial Fatigue Testing System
frettingfatiguebehaviorofmetallicmaterials.Thisguideisnot
E468 Practice for Presentation of Constant Amplitude Fa-
intended to establish preference of one apparatus or specimen
tigue Test Results for Metallic Materials
design over others, but will establish guidelines for adherence
E1012 Practice for Verification of Testing Frame and Speci-
in the design, calibration, and use of fretting fatigue apparatus
men Alignment Under Tensile and Compressive Axial
and recommend the means to collect, record, and reporting of
Force Application
the data.
E1823 TerminologyRelatingtoFatigueandFractureTesting
E1942 Guide for Evaluating DataAcquisition Systems Used
1.3 The number of cycles to form a fretting fatigue crack is
in Cyclic Fatigue and Fracture Mechanics Testing
dependent on both the material of the fatigue specimen and
G15 Terminology Relating to Corrosion and CorrosionTest-
fretting pad, the geometry of contact between the two, and the
ing (Withdrawn 2010)
method by which the loading and displacement are imposed.
G40 Terminology Relating to Wear and Erosion
Similar to wear behavior of materials, it is important to
G190 GuideforDevelopingandSelectingWearTests(With-
consider fretting fatigue as a system response, instead of a
drawn 2021)
material response. Because of this dependency on the configu-
ration of the system, quantifiable comparisons of various
3. Terminology
material combinations should be based on tests using similar
fretting fatigue configurations and material couples. 3.1 Definitions and symbols used in this guide are in
accordance with Terminology E1823. Relevant definitions
1.4 This standard does not purport to address all of the
from Terminology G15 or G40 are provided in 3.2.Additional
safety concerns, if any, associated with its use. It is the
definitions specific to this guide are provided in 3.3.
responsibility of the user of this standard to establish appro-
priate safety, health, and environmental practices and deter- 3.2 Definitions:
3.2.1 Terms from Terminologies G15 and G40.
mine the applicability of regulatory limitations prior to use.
3.2.2 coeffıcient of friction (COF)—The dimensionless ratio
1.5 This international standard was developed in accor-
of the tangential force, Q, between two bodies to the normal
dance with internationally recognized principles on standard-
force,P,pressingthesebodiestogetherwhenthetwobodiesare
ization established in the Decision on Principles for the
slipping with respect to each other, µ=Q/P.
Development of International Standards, Guides and Recom-
3.2.2.1 Discussion—Under partial slip conditions, the ratio
mendations issued by the World Trade Organization Technical
of the tangential force to the normal force is less than the COF.
Barriers to Trade (TBT) Committee.
In addition, when COF is defined as the ratio of Q to P, the
1 2
This guide is under the jurisdiction of ASTM Committee E08 on Fatigue and For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Fracture and is the direct responsibility of Subcommittee E08.05 on Cyclic contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
Deformation and Fatigue Crack Formation. Standards volume information, refer to the standard’s Document Summary page on
Current edition approved Dec. 1, 2021. Published January 2022. Originally the ASTM website.
approved in 2010. Last previous edition approved in 2015 as E2789–10 (2015). The last approved version of this historical standard is referenced on
DOI: 10.1520/E2789–10R21. www.astm.org.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E2789 − 10 (2021)
measured COF is an average along the interface. In reality, the formacrackandtheaccelerationofthecrackgrowthunderthe
COF can vary along the interface. Hence, a local definition is coupling of the fretting and bulk cyclic stresses and strains.
often used, given by µ(x,y)=q(x,y)/p(x,y) where q(x,y) is the
3.3.4 fretting fatigue knockdown factor—The reduction in
shear traction distribution along the interface and p(x,y) is the
fatigue strength due to the presence of fretting, defined as the
normal pressure distribution. The COF is often greater in the
difference in the fatigue limit and fretting fatigue limit divided
slip regions of a partial slip interface compared to the stick
by the fatigue limit.
regions due to the disruptions in the surface caused by fretting.
3.3.4.1 Discussion—This knockdown factor may also be
G40
basedonthefrettingfatiguestrengthdefinedeitherasthestress
3.2.3 fretting—Small amplitude oscillatory motion, usually
level (maximum stress or stress amplitude for a given mean
tangential, between two solid surfaces in contact.
stressorstressratio)forfailureatacertainnumberofcyclesor
3.2.3.1 Discussion—The term fretting refers only to the
the stress level at which a percentage of the population would
nature of the motion without reference to the wear, corrosion,
survive a certain number of cycles.
fatigue, or other damage that may occur. It is discouraged to
3.3.5 fretting fatigue limit—The limiting value of the
use the term fretting to denote fretting corrosion or other forms
of fretting wear due to the ambiguity that may arise. As the median fatigue strength when fretting is present as the fatigue
amplitude of fretting increases, the condition eventually be- life becomes very large.
comes reciprocating sliding and the interaction should no
3.3.5.1 Discussion—The fretting fatigue limit strongly de-
longer be referred to as fretting.
pends on the fretting conditions.
3.2.4 fretting corrosion—The deterioration at the interface
3.3.6 fretting fatigue reduction factor—The reduction in
between contacting surfaces as the result of corrosion and
fatigue strength due to the presence of fretting, defined as the
slight oscillatory slip between the two surfaces. G15
ratio of the fretting fatigue limit and fatigue limit.
3.2.5 fretting wear—Wear that occurs as the result of
3.3.6.1 Discussion—This reduction factor may also be
fretting action. G40
basedonthefrettingfatiguestrengthdefinedeitherasthestress
3.3 Definitions of Terms Specific to This Standard: level (maximum stress or stress amplitude for a given mean
3.3.1 displacement amplitude—The peak-to-peak relative stressorstressratio)forfailureatacertainnumberofcyclesor
displacement divided by two or total cycle displacement the stress level at which a percentage of the population would
divided by four. survive a certain number of cycles.
3.3.1.1 Discussion—The displacement amplitude is typi-
3.3.7 fretting fatigue damage threshold—The combination
cally based on a remote reference location. Note that the
of fretting fatigue loading conditions and number of fretting
definition of displacement amplitude in the context of fretting
cycles that can be sustained before degradation of fatigue life
wear and tribosystems testing sometimes refers to the full
is observed.
peak-to-peak relative displacement, rather than the definition
3.3.7.1 Discussion—The fretting fatigue loading conditions
given here, which is consistent with the use of the term
may include combinations of the normal force, the displace-
amplitude in Terminology E1823. Hence, whenever the term
ment amplitude, the tangential force amplitude, and the bulk
displacement amplitude is used, it should be clearly defined or
fatigue loading. The concept of a fretting fatigue damage
a reference made to this guide.
threshold is related to the development of an initial crack
3.3.2 fretting damage—The pits, scarring, disruptions and
characterizedwithamaximumandrangeinstressintensitythat
material transfer on the surface due to fretting.
exceeds the threshold value for crack growth. Generally, after
3.3.2.1 Discussion—Cracks may be associated with the
the fretting fatigue damage threshold has been reached, remov-
fretting damage, though in many cases they may not be present
ing the source of fretting, while maintaining the fatigue
or be sufficiently small, such that the fatigue life is not
loading, in configurations where they can be separated, has
significantly degraded. Hence, the disturbed appearance and
minimal effect on the remaining life.
level of roughness of the fretting damage cannot be reliably
used to determine whether the fatigue life is reduced. In some 3.3.8 gross slip—The condition for which all points in
cases the directionality of roughness, also called the surface contact experience relative slip over a complete cycle, as
texture, can be determined via profilometry methods. This illustrated in Fig. 1.
texture may be correlated to the directionality of fretting and in
3.3.9 normal force—Force normal to the contact interface.
some cases the characteristics of the texture can provide a
3.3.9.1 Discussion—Due to the accumulation of debris
useful screening metric for fretting damage.
within the contact or wear in the slip regions, this force may
3.3.3 fretting fatigue—The process of crack formation at a
not remain constant but change during the test.
fretting damage site, progressive crack growth, possibly cul-
3.3.10 normal pressure—Resultant of the normal force di-
minating in complete fracture, occurring in a material sub-
vided by the contact area.
jected to concomitantly fretting and fluctuating stresses and
strains. 3.3.10.1 Discussion—Tobeconsideredanaverageonly.The
3.3.3.1 Discussion—Fretting fatigue is generally character- true distribution of pressure within the contact area depends on
the exact profile and roughness of the contacting surfaces.
ized by a sharp decrease in the fatigue life at the same stress
levelofastandardspecimen,attributedtotheshortenedtimeto Analyticalorcomputationalmethodsmaybeusedtodetermine
E2789 − 10 (2021)
FIG. 1 Illustration of the Meanings of Slip and Reciprocating Sliding
this pressure; for example, see Ref. (1) . Wear will cause the materials,relativedisplacementamplitudes,normalforceatthe
profiles of the contacting bodies to change during the test. If fretting contact, alternating tangential force, the contact
wear occurs, the size of the non-conforming contacts (for geometry, surface integrity parameters such as finish, and the
example, flat on cylindrical, cylindrical on cylindrical, sphere environment. Comparative tests are used to determine the
on flat, and so on) will typically increase. effectivenessofpalliativesonthefatiguelifeofspecimenswith
well-controlled boundary conditions so that the mechanics of
3.3.11 partial slip—The condition for which only a portion
the fretting fatigue test can be modeled. Generally, it is useful
oftheinterfaceofthecontactingbodiesexperiencerelativeslip
to compare the fretting fatigue response to plain fatigue to
over a complete cycle, as illustrated in Fig. 1.
obtain knockdown or reduction factors from fretting fatigue.
3.3.12 plain fatigue—Often used to describe fatigue without
The results may be used as a guide in selecting material
presence of fretting.
combinations, design stress levels, lubricants, and coatings to
3.3.13 reciprocating sliding—The condition when the con-
alleviate or eliminate fretting fatigue concerns in new or
tact area at the two extremes of the cycle do not overlap, as
existing designs. However, due to the synergisms of fatigue,
illustrated in Fig. 1.
wear, and corrosion on the fretting fatigue parameters, extreme
3.3.13.1 Discussion—Under fretting conditions, at least a
care should be exercised in the judgment to determine if the
portion of the contact areas always overlap at the extremes of
test conditions meet the design or system conditions.
the cycle.
4.2 For data to be comparable, reproducible, and correlated
3.3.14 relative slip—The amount of tangential displacement
amongst laboratories and relevant to mimic fretting in an
between a point on the interface of one body and a point on the
application, all parameters critical to the fretting fatigue life of
surface of the second body.
the material in question will need to be replicated. Because
3.3.14.1 Discussion—The point on one of the bodies serves
alterations in environment, metallurgical properties, fretting
as a reference, which is often defined as the location when the
loading (controlled forces and displacements), compliance of
two bodies first come into contact under application of the
the test system, etc. can affect the response, no general
normal pressure at the interface. The relative slip may be
guidelines exist to quantitatively ascertain what the effect will
defined as a local or remote reference. Fundamentally, a local
be on the specimen fretting fatigue life if a single parameter is
measureisdesired,however,experimentallyaremotedisplace-
varied. To assure test results can be correlated and reproduced,
ment is measured and in many times controlled.
all material variables, testing information, physical procedures,
3.3.15 slip—Local movement of surfaces in contact. and analytical procedures should be reported in a manner that
is consistent with good current test practices.
3.3.16 tangential force—Force acting parallel to the contact
interface.
4.3 Because of the wear phenomenon involved in fretting,
idealized contact conditions from which the fretting contact
4. Significance and Use
area and pressure may be calculated exist only at the onset of
the test. Although it is still possible to calculate an average
4.1 Fretting
...

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Standard Test Method for Measurement of Fatigue Crack Growth Rates

SIGNIFICANCE AND USE
5.1 Fatigue crack growth rate expressed as a function of crack-tip stress-intensity factor range, da/dN versus ΔK, characterizes a material's resistance to stable crack extension under cyclic loading. Background information on the ration-ale for employing linear elastic fracture mechanics to analyze fatigue crack growth rate data is given in Refs (3) and (4).  
5.1.1 In innocuous (inert) environments fatigue crack growth rates are primarily a function of ΔK and force ratio, R, or Kmax and R (Note 1). Temperature and aggressive environments can significantly affect da/dN versus ΔK, and in many cases accentuate R-effects and introduce effects of other loading variables such as cycle frequency and waveform. Attention needs to be given to the proper selection and control of these variables in research studies and in the generation of design data.
Note 1: ΔK, Kmax, and R are not independent of each other. Specification of any two of these variables is sufficient to define the loading condition. It is customary to specify one of the stress-intensity parameters (ΔK or Kmax) along with the force ratio, R.  
5.1.2 Expressing da/dN as a function of ΔK provides results that are independent of planar geometry, thus enabling exchange and comparison of data obtained from a variety of specimen configurations and loading conditions. Moreover, this feature enables da/dN versus ΔK data to be utilized in the design and evaluation of engineering structures. The concept of similitude is assumed, which implies that cracks of differing lengths subjected to the same nominal ΔK will advance by equal increments of crack extension per cycle.  
5.1.3 Fatigue crack growth rate data are not always geometry-independent in the strict sense since thickness effects sometimes occur. However, data on the influence of thickness on fatigue crack growth rate are mixed. Fatigue crack growth rates over a wide range of ΔK have been reported to either increase, decrease, or remain unaffected as specimen...
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1.1 This test method2 covers the determination of fatigue crack growth rates from near-threshold (see region I in Fig. 1) to Kmax  controlled instability (see region III in Fig. 1.) Results are expressed in terms of the crack-tip stress-intensity factor range (ΔK), defined by the theory of linear elasticity.  
1.9 Special requirements for the various specimen configurations appear in the following order:
The Compact Specimen  
Annex A1  
The Middle Tension Specimen  
Annex A2  
The Eccentrically-Loaded Single Edge Crack Tension Specimen  
Annex A3  
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 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 E1221-23(Test Method)
Standard Test Method for Determining Plane-Strain Crack-Arrest Fracture Toughness, KIa, of Ferritic Steels

SIGNIFICANCE AND USE
5.1 In structures containing gradients in either toughness or stress, a crack may initiate in a region of either low toughness or high stress, or both, and arrest in another region of either higher toughness or lower stress, or both. The value of the stress intensity factor during the short time interval in which a fast-running crack arrests is a measure of the ability of the material to arrest such a crack. Values of the stress intensity factor of this kind, which are determined using dynamic methods of analysis, provide a value for the crack-arrest fracture toughness which will be termed KA  in this discussion. Static methods of analysis, which are much less complex, can often be used to determine K at a short time (1 to 2 ms) after crack arrest. The estimate of the crack-arrest fracture toughness obtained in this fashion is termed K a. When macroscopic dynamic effects are relatively small, the difference between KA  and Ka  is also small (1-4). For cracks propagating under conditions of crack-front plane-strain, in situations where the dynamic effects are also known to be small, KIa  determinations using laboratory-sized specimens have been used successfully to estimate whether, and at what point, a crack will arrest in a structure (5, 6). Depending upon component design, loading compliance, and the crack jump length, a dynamic analysis of a fast-running crack propagation event may be necessary in order to predict whether crack arrest will occur and the arrest position. In such cases, values of K Ia  determined by this test method can be used to identify those values of K below which the crack speed is zero. More details on the use of dynamic analyses can be found in Ref (4).  
5.2 This test method can serve at least the following additional purposes:  
5.2.1 In materials research and development, to establish in quantitative terms significant to service performance, the effects of metallurgical variables (such as composition or heat treatment) or fabrication o...
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1.1 This test method employs a side-grooved, crack-line-wedge-loaded specimen to obtain a rapid run-arrest segment of flat-tensile separation with a nearly straight crack front. This test method provides a static analysis determination of the stress intensity factor at a short time after crack arrest. The estimate is denoted Ka. When certain size requirements are met, the test result provides an estimate, termed KIa, of the plane-strain crack-arrest toughness of the material.  
1.2 The specimen size requirements, discussed later, provide for in-plane dimensions large enough to allow the specimen to be modeled by linear elastic analysis. For conditions of plane-strain, a minimum specimen thickness is also required. Both requirements depend upon the crack arrest toughness and the yield strength of the material. A range of specimen sizes may therefore be needed, as specified in this test method.  
1.3 If the specimen does not exhibit rapid crack propagation and arrest, Ka  cannot be determined.  
1.4 The values stated in SI units are to be regarded as the standards. The values given in parentheses are provided for information only.  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, 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 E468/E468M-23a(Practice)
Standard Practice for Presentation of Constant Amplitude Fatigue Test Results for Metallic Materials

SIGNIFICANCE AND USE
4.1 Fatigue test results may be significantly influenced by the properties and history of the parent material, the operations performed during the preparation of the fatigue specimens, and the testing machine and test procedures used during the generation of the data. The presentation of fatigue test results should include citation of basic information on the material, specimens, and testing to increase the utility of the results and to reduce to a minimum the possibility of misinterpretation or improper application of those results.
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1.1 This practice covers the desirable and minimum information to be communicated between the originator and the user of data derived from constant-force amplitude axial, bending, or torsion fatigue tests of metallic materials tested in air and at room temperature.  
Note 1: Practice E466, although not directly referenced in the text, is considered important enough to be listed in this standard.  
1.2 The values stated in either SI units or inch-pound units are to be regarded separately as standard. The values stated in each system are not necessarily exact equivalents; therefore, to ensure conformance with the standard, each system shall be used independently of the other, and values from the two systems shall not be combined.  
1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.4 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM E1820-23b(Test Method)
Standard Test Method for Measurement of Fracture Toughness

SIGNIFICANCE AND USE
5.1 Assuming the presence of a preexisting, sharp, fatigue crack, the material fracture toughness values identified by this test method characterize its resistance to: (1)  fracture of a stationary crack, (2) fracture after some stable tearing, (3) stable tearing onset, and (4) sustained stable tearing. This test method is particularly useful when the material response cannot be anticipated before the test. Application of procedures in Test Method E1921 is recommended for testing ferritic steels that undergo cleavage fracture in the ductile-to-brittle transition.  
5.1.1 These fracture toughness values may serve as a basis for material comparison, selection, and quality assurance. Fracture toughness can be used to rank materials within a similar yield strength range.  
5.1.2 These fracture toughness values may serve as a basis for structural flaw tolerance assessment. Awareness of differences that may exist between laboratory test and field conditions is required to make proper flaw tolerance assessment.  
5.2 The following cautionary statements are based on some observations.  
5.2.1 Particular care must be exercised in applying to structural flaw tolerance assessment the fracture toughness value associated with fracture after some stable tearing has occurred. This response is characteristic of ferritic steel in the transition regime. This response is especially sensitive to material inhomogeneity and to constraint variations that may be induced by planar geometry, thickness differences, mode of loading, and structural details.  
5.2.2 The J-R curve from bend-type specimens recommended by this test method (SE(B), C(T), and DC(T)) has been observed to be conservative with respect to results from tensile loading configurations.  
5.2.3 The values of δc, δu, Jc, and Ju  may be affected by specimen dimensions.
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1.1 This test method covers procedures and guidelines for the determination of fracture toughness of metallic materials using the following parameters: K, J, and CTOD (δ). Toughness can be measured in the R-curve format or as a point value. The fracture toughness determined in accordance with this test method is for the opening mode (Mode I) of loading.
Note 1: Until this version, KIc could be evaluated using this test method as well as by using Test Method E399. To avoid duplication, the evaluation of KIc has been removed from this test method and the user is referred to Test Method E399.  
1.2 The recommended specimens are single-edge bend, [SE(B)], compact, [C(T)], and disk-shaped compact, [DC(T)]. All specimens contain notches that are sharpened with fatigue cracks.  
1.2.1 Specimen dimensional (size) requirements vary according to the fracture toughness analysis applied. The guidelines are established through consideration of material toughness, material flow strength, and the individual qualification requirements of the toughness value per values sought.  
Note 2: Other standard methods for the determination of fracture toughness using the parameters K, J, and CTOD are contained in Test Methods E399, E1290, and E1921. This test method was developed to provide a common method for determining all applicable toughness parameters from a single test.  
1.3 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.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations iss...

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ASTM
ASTM E399-23(Test Method)
Standard Test Method for Linear-Elastic Plane-Strain Fracture Toughness of Metallic Materials

SIGNIFICANCE AND USE
5.1 The property KIc determined by this test method characterizes the resistance of a material to fracture in a neutral environment in the presence of a sharp crack under essentially linear-elastic stress and severe tensile constraint, such that (1) the state of stress near the crack front approaches tritensile plane strain, and (2) the crack-tip plastic zone is small compared to the crack size, specimen thickness, and ligament ahead of the crack.  
5.1.1 Variation in the value of KIc can be expected within the allowable range of specimen proportions, a/W and  W/B. KIc may also be expected to rise with increasing ligament size. Notwithstanding these variations, however, KIc is believed to represent a lower limiting value of fracture toughness (for 2 % apparent crack extension) in the environment and at the speed and temperature of the test.  
5.1.2 Lower and more highly variable values of fracture toughness can be obtained from specimens that fail by cleavage fracture; for example, specimens of ferritic steels tested at temperatures in the ductile-to-brittle transition region or below. Specimens failing by cleavage are also more likely to exhibit warm prestressing effects, where precracking at a temperature higher than the test temperature can artificially increase the fracture toughness measured (2). The present test method is not intended for cleavage fracture. Instead, the user is referred to Test Method E1921 and E1820 which are applicable to cleavage fracture and contain safeguards against warm prestressing. Likewise this test method should not be used when specimen failure is accompanied by appreciable plastic deformation even after the specimen size has been maximized within product dimensional constraints. Guidance on testing elastic-plastic materials is given in Test Method E1820.  
5.1.3 The value of KIc obtained by this test method may be used to estimate the relation between failure stress and crack size for a material in service wherein the condition...
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1.1 This test method covers the determination of fracture toughness (KIc and optionally KIsi) of metallic materials under predominantly linear-elastic, plane-strain conditions using fatigue precracked specimens having a thickness of 1.6 mm (0.063 in.) or greater2 subjected to slowly, or in special (elective) cases rapidly, increasing crack-displacement force. Details of test apparatus, specimen configuration, and experimental procedure are given in the annexes. Two procedures are outlined for using the experimental data to calculate fracture toughness values:  
1.1.1 The KIc test procedure is described in the main body of this test standard and is a mandatory part of the testing and results reporting procedure for this test method. The KIc test procedure is based on crack growth of up to 2 % percent of the specimen width. This can lead to a specimen size dependent rising fracture toughness resistance curve, with larger specimens producing higher fracture toughness results.  
1.1.2 The KIsi test procedure is described in Appendix X1 and is an optional part of this test method. The KIsi test procedure is based on a fixed amount of crack extension of 0.5 mm, and as a result, KIsi is less sensitive to specimen size than KIc. This less size-sensitive fracture toughness, KIsi, is called size-insensitive throughout this test method. Appendix X1 contains an optional procedure for reinterpreting the force-displacement test record recorded as part of this test method to calculate the additional fracture toughness value, KIsi.
Note 1: Plane-strain fracture toughness tests of materials thinner than 1.6 mm (0.063 in.) that are sufficiently brittle (see 7.1) can be made using other types of specimens (1).3 There is no standard test method for such thin materials.  
1.2 This test method is divided into two parts. The first part gives general recommendations and requirements for testing and includes specific requirements for the KI...

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ASTM
ASTM E561-23(Test Method)
Standard Test Method for KR Curve Determination

SIGNIFICANCE AND USE
5.1 The KR curve characterizes the resistance to fracture of materials during slow, stable crack extension and results from the growth of the plastic zone ahead of the crack as it extends from a fatigue precrack or sharp notch. It provides a record of the toughness development as a crack is driven stably under increasing applied stress intensity factor K. For a given material, KR curves are dependent upon specimen thickness, temperature, and strain rate. The amount of valid KR data generated in the test depends on the specimen type, size, method of loading, and, to a lesser extent, testing machine characteristics.  
5.2 For an untested geometry, the KR curve can be matched with the applied-K curves (crack driving curves) to estimate the degree of stable crack extension and the conditions necessary to cause unstable crack propagation (2). In making this estimate, KR curves are regarded as being independent of initial crack size ao and the specimen configuration in which they are developed. For a given material, material thickness, and test temperature, KR curves appear to be a function of only the effective crack extension Δae (3).  
5.2.1 To predict crack behavior and instability in a component, a family of applied-K curves is generated by calculating  K as a function of crack size for the component using a series of force, displacement, or combined loading conditions. The KR curve may be superimposed on the family of applied-K curves as shown in Fig. 1, with the origin of the KR curve coinciding with the assumed initial crack size ao. The intersection of the applied-K curves with the KR curve shows the expected effective stable crack extension for each loading condition. The applied-K curve that develops tangency with the KR curve defines the critical loading condition that will cause the onset of unstable fracture under the loading conditions used to develop the applied-K curves.
FIG. 1 Schematic Representation of KR curve and Applied K Curves to Predict Insta...
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1.1 This test method covers the determination of the resistance to fracture of metallic materials under Mode I loading at static rates using either of the following notched and precracked specimens: the middle-cracked tension M(T) specimen or the compact tension C(T) specimen. A KR curve is a continuous record of toughness development (resistance to crack extension) in terms of KR plotted against crack extension in the specimen as a crack is driven under an increasing stress intensity factor, K. (1)2  
1.2 Materials that can be tested for KR curve development are not limited by strength, thickness, or toughness, so long as specimens are of sufficient size to remain predominantly elastic to the effective crack extension value of interest.  
1.3 Specimens of standard proportions are required, but size is variable, to be adjusted for yield strength and toughness of the materials.  
1.4 Only two of the many possible specimen types that could be used to develop KR curves are covered in this method.  
1.5 The test is applicable to conditions where a material exhibits slow, stable crack extension under increasing crack driving force, which may exist in relatively tough materials under plane stress crack tip conditions.  
1.6 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.  
1.7 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.  
1.8 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 Reco...

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ASTM
ASTM E466-21(Practice)
Standard Practice for Conducting Force Controlled Constant Amplitude Axial Fatigue Tests of Metallic Materials

SIGNIFICANCE AND USE
4.1 The axial force fatigue test is used to determine the effect of variations in material, geometry, surface condition, stress, and so forth, on the fatigue resistance of metallic materials subjected to direct stress for relatively large numbers of cycles. The results may also be used as a guide for the selection of metallic materials for service under conditions of repeated direct stress.  
4.2 In order to verify that such basic fatigue data generated using this practice is comparable, reproducible, and correlated among laboratories, it may be advantageous to conduct a round-robin-type test program from a statistician's point of view. To do so would require the control or balance of what are often deemed nuisance variables; for example, hardness, cleanliness, grain size, composition, directionality, surface residual stress, surface finish, and so forth. Thus, when embarking on a program of this nature it is essential to define and maintain consistency a priori, as many variables as reasonably possible, with as much economy as prudent. All material variables, testing information, and procedures used should be reported so that correlation and reproducibility of results may be attempted in a fashion that is considered reasonably good current test practice.  
4.3 The results of the axial force fatigue test are suitable for application to design only when the specimen test conditions realistically simulate service conditions or some methodology of accounting for service conditions is available and clearly defined.
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1.1 This practice covers the procedure for the performance of axial force controlled fatigue tests to obtain the fatigue strength of metallic materials in the fatigue regime where the strains are predominately elastic, both upon initial loading and throughout the test. This practice is limited to the fatigue testing of axial unnotched and notched specimens subjected to a constant amplitude, periodic forcing function in air at room temperature.  
1.2 The use of this test method is limited to specimens and does not cover testing of full-scale components, structures, or consumer products.  
1.3 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.  
1.4 The text of this standard references notes and footnotes that provide explanatory material. These notes and footnotes (excluding those in tables and figures) shall not be considered as requirements of the standard.
Note 1: The following documents, although not directly referenced in the text, are considered important enough to be listed in this practice:
E739 Practice for Statistical Analysis of Linear or Linearized Stress-Life (S-N) and Strain-Life (ε-N) Fatigue Data
STP 566 Handbook of Fatigue Testing2
STP 588 Manual on Statistical Planning and Analysis for Fatigue Experiments3
STP 731 Tables for Estimating Median Fatigue Limits4  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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