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ASTM G77-17(2022)

(Test Method)

Standard Test Method for Ranking Resistance of Materials to Sliding Wear Using Block-on-Ring Wear Test

Standard Test Method for Ranking Resistance of Materials to Sliding Wear Using Block-on-Ring Wear Test

SIGNIFICANCE AND USE
5.1 The significance of this test method in any overall measurement program directed toward a service application will depend on the relative match of test conditions to the conditions of the service application.  
5.2 This test method seeks only to prescribe the general test procedure and method of calculating and reporting data. The choice of test operating parameters is left to the user. A fixed amount of sliding distance must be used because wear is usually non-linear with distance in this test.
SCOPE
1.1 This test method covers laboratory procedures for determining the resistance of materials to sliding wear. The test utilizes a block-on-ring friction and wear testing machine to rank pairs of materials according to their sliding wear characteristics under various conditions.  
1.2 An important attribute of this test is that it is very flexible. Any material that can be fabricated into, or applied to, blocks and rings can be tested. Thus, the potential materials combinations are endless. However, the interlaboratory testing has been limited to metals. In addition, the test can be run with various lubricants, liquids, or gaseous atmospheres, as desired, to simulate service conditions. Rotational speed and load can also be varied to better correspond to service requirements.  
1.3 The values stated in SI units are to be regarded as standard. The values given in parentheses are for information only. Wear test results are reported as the volume loss in cubic millimetres for both the block and ring. Materials of higher wear resistance will have lower volume loss.  
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
31-Oct-2022
ICS
77.040.10 - Mechanical testing of metals
Technical Committee
G02 - Wear and Erosion
Drafting Committee
G02.40 - Non-Abrasive Wear
Current Stage
Ref Project

Relations

Refers
ASTM D2714-94(2019) - Standard Test Method for Calibration and Operation of the Falex Block-on-Ring Friction and Wear Testing Machine
Effective Date
01-May-2019
Refers
ASTM G40-15 - Standard Terminology Relating to Wear and Erosion
Effective Date
01-Nov-2015
Refers
ASTM E177-14 - Standard Practice for Use of the Terms Precision and Bias in ASTM Test Methods
Effective Date
01-May-2014
Refers
ASTM D2714-94(2014) - Standard Test Method for Calibration and Operation of the Falex Block-on-Ring Friction and Wear Testing Machine
Effective Date
01-May-2014
Refers
ASTM G40-13 - Standard Terminology Relating to Wear and Erosion
Effective Date
01-Jun-2013
Refers
ASTM E177-13 - Standard Practice for Use of the Terms Precision and Bias in ASTM Test Methods
Effective Date
01-May-2013
Refers
ASTM E691-13 - Standard Practice for Conducting an Interlaboratory Study to Determine the Precision of a Test Method
Effective Date
01-May-2013
Refers
ASTM G40-12 - Standard Terminology Relating to Wear and Erosion
Effective Date
01-May-2012
Refers
ASTM E691-11 - Standard Practice for Conducting an Interlaboratory Study to Determine the Precision of a Test Method
Effective Date
01-Nov-2011
Refers
ASTM E122-09e1 - Standard Practice for Calculating Sample Size to Estimate, With Specified Precision, the Average for a Characteristic of a Lot or Process
Effective Date
01-Aug-2011
Refers
ASTM G40-10b - Standard Terminology Relating to Wear and Erosion
Effective Date
01-Dec-2010
Refers
ASTM E177-10 - Standard Practice for Use of the Terms Precision and Bias in ASTM Test Methods
Effective Date
01-Oct-2010
Refers
ASTM G40-10a - Standard Terminology Relating to Wear and Erosion
Effective Date
01-Jul-2010
Refers
ASTM G40-10 - Standard Terminology Relating to Wear and Erosion
Effective Date
01-Jan-2010
Refers
ASTM G40-09 - Standard Terminology Relating to Wear and Erosion
Effective Date
15-Nov-2009

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ASTM G77-17(2022) - Standard Test Method for Ranking Resistance of Materials to Sliding Wear Using Block-on-Ring Wear TestASTM G77-17(2022) - Standard Test Method for Ranking Resistance of Materials to Sliding Wear Using Block-on-Ring Wear Test
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ASTM G77-17(2022) - Standard Test Method for Ranking Resistance of Materials to Sliding Wear Using Block-on-Ring Wear Test
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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: G77 − 17 (Reapproved 2022)
Standard Test Method for
Ranking Resistance of Materials to Sliding Wear Using
Block-on-Ring Wear Test
ThisstandardisissuedunderthefixeddesignationG77;thenumberimmediatelyfollowingthedesignationindicatestheyearoforiginal
adoptionor,inthecaseofrevision,theyearoflastrevision.Anumberinparenthesesindicatestheyearoflastreapproval.Asuperscript
epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 2. Referenced Documents
2.1 ASTM Standards:
1.1 This test method covers laboratory procedures for de-
D2714Test Method for Calibration and Operation of the
termining the resistance of materials to sliding wear. The test
Falex Block-on-Ring Friction and Wear Testing Machine
utilizes a block-on-ring friction and wear testing machine to
E122PracticeforCalculatingSampleSizetoEstimate,With
rank pairs of materials according to their sliding wear charac-
Specified Precision, the Average for a Characteristic of a
teristics under various conditions.
Lot or Process
1.2 An important attribute of this test is that it is very E177Practice for Use of the Terms Precision and Bias in
flexible.Anymaterialthatcanbefabricatedinto,orappliedto, ASTM Test Methods
E691Practice for Conducting an Interlaboratory Study to
blocks and rings can be tested. Thus, the potential materials
Determine the Precision of a Test Method
combinations are endless. However, the interlaboratory testing
G40Terminology Relating to Wear and Erosion
hasbeenlimitedtometals.Inaddition,thetestcanberunwith
various lubricants, liquids, or gaseous atmospheres, as desired,
3. Terminology
to simulate service conditions. Rotational speed and load can
3.1 Definitions:
also be varied to better correspond to service requirements.
3.1.1 sliding wear, n—wearduetotherelativemotioninthe
1.3 The values stated in SI units are to be regarded as
tangential plane of contact between two solid bodies.
standard. The values given in parentheses are for information
3.1.2 wear—damage to a solid surface, generally involving
only.Wear test results are reported as the volume loss in cubic
progressive loss of material, due to relative motion between
millimetres for both the block and ring. Materials of higher
that surface and a contacting substance or substances.
wear resistance will have lower volume loss.
3.1.3 Foradditionaldefinitionspertinenttothistestmethod,
1.4 This standard does not purport to address all of the
see Terminology G40.
safety concerns, if any, associated with its use. It is the
responsibility of the user of this standard to establish appro-
4. Summary of Test Method
priate safety, health, and environmental practices and deter-
4.1 Atest block is loaded against a test ring that rotates at a
mine the applicability of regulatory limitations prior to use.
given speed for a given number of revolutions. Block scar
1.5 This international standard was developed in accor-
volume is calculated from the block scar width, and ring scar
dance with internationally recognized principles on standard-
volume is calculated from ring weight loss. The friction force
ization established in the Decision on Principles for the
required to keep the block in place is continuously measured
Development of International Standards, Guides and Recom-
during the test with a load cell. These data, combined with
mendations issued by the World Trade Organization Technical
normal force data, are converted to coefficient of friction
Barriers to Trade (TBT) Committee.
values and reported.
5. Significance and Use
5.1 The significance of this test method in any overall
measurement program directed toward a service application
This test method is under the jurisdiction of ASTM Committee G02 on Wear
and Erosion and is the direct responsibility of G02.40 on Non-Abrasive Wear. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Current edition approved Nov. 1, 2022. Published November 2022. Originally contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
approved in 1983. Last previous edition approved in 2017 as G77–17. DOI: Standards volume information, refer to the standard’s Document Summary page on
10.1520/G0077-17R22. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
G77 − 17 (2022)
0.203µm (4µin. to 8 µin.) CLA in the direction of motion is
recommended. However, other surface conditions may be
evaluated as desired.
6.4 Analytical Balance, capable of measuring to the nearest
0.1 mg.
6.5 Optical Device (or equivalent), with metric or inch-
pound unit calibration, is also necessary so that scar width can
be measured with a precision of 0.005 mm (0.0002 in.) or
equivalent.
7. Reagents
7.1 Methanol.
8. Preparation and Calibration of Apparatus
8.1 Run the calibration procedure that is in Test Method
D2714 to ensure good mechanical operation of the test
equipment.
9. Procedure
9.1 Clean the block and ring using a procedure that will
remove any scale, oil film, or residue without damaging the
surface.
FIG. 1 Test Schematic
9.1.1 For metals, the following procedure is recommended:
clean the block and ring in a non-chlorine containing solvent,
will depend on the relative match of test conditions to the
ultrasonically, if possible; a methanol rinse may be used to
conditions of the service application.
remove any traces of solvent residue. Allow the blocks and
5.2 This test method seeks only to prescribe the general test
rings to dry completely. Handle the block and ring with clean,
procedure and method of calculating and reporting data. The
lint-free cotton gloves from this point on.
choice of test operating parameters is left to the user. A fixed
9.2 Make surface texture and surface roughness measure-
amount of sliding distance must be used because wear is
ments across the width of the block and the ring, as necessary.
usually non-linear with distance in this test.
Note that a surface profile does not completely describe a
surface topology. Scanning electron micrographs may be used,
6. Apparatus and Materials
as desired, to augment the description of the wear surfaces.
6.1 Test Schematic—Aschematic of one possible block-on-
Clean the block and the ring if necessary as in 9.1.
ring wear test geometry is shown in Fig. 1.
9.3 Demagnetizethemetalspecimensandferrousassembly.
6.2 Test Ring—AtypicaltestringisshowninFig.2.Thetest
Weigh the block and ring to the nearest 0.1 mg.
ring must have an outer diameter of 34.99mm 6 0.025 mm
9.4 Measure the block width and ring diameter to the
(1.377in. 6 0.001 in.) with an eccentricity between the inner
nearest 0.025 mm (0.001 in.).
and outer surface of no greater than 0.00125 mm (0.0005 in.).
For couples where surface condition is not under study, it is
9.5 Clean the self-aligning block holder, ring shaft, and
recommended that the outer diameter be a ground surface with
lubricant reservoir with solvent.
a roughness of 0.152µm to 0.305 µm (6µin. to 12 µin.) rms or
9.6 Put the self-aligning block holder on the block.
center line average (CLA), in the direction of motion.
9.7 Place the block in position on the machine and, while
However, alternate surface conditions may be evaluated in the
holding the block in position, place the ring on the shaft and
test,asdesired.Itshouldbekeptinmindthatsurfacecondition
lock the ring in place, using a test method in accordance with
can have an effect on sliding wear results.
the requirements of the specific machine design.
6.3 Test Block—AtestblockisshowninFig.3.Blockwidth
9.8 Center the block on the ring while placing a light
is 6.35+0.000,−0.025 mm (0.250+0.000,−0.001 in.). For
manual pressure on the lever arm to bring the block and ring
coupleswheresurfaceconditionisnotaparameterunderstudy,
into contact. Be sure the edge of the block is parallel to the
a ground surface with the grinding marks running parallel to
edge of the ring and that the mating surfaces are perfectly
the long axis of the block and a roughness of 0.102µm to
aligned. This is accomplished by making sure the specimen
holder is free during mounting so that the self-aligning block
Several machines have been found satisfactory for the purposes of this test.
holder can properly seat itself. Release the pressure on the
These models may differ in lever arm ratio, load range, speed control (variable or
fixed), speed range, and type of friction measuring device. lever arm.
G77 − 17 (2022)
NOTE 1—The outer diameter and concentricity with the inner diameter are the only critical parameters. The inner diameter is optional depending on
machine design. The inside diameter taper shown fits a number of standard machines.
FIG. 2 Test Ring
FIG. 3 Test Block
9.9 One may choose either a preloading or a step-loading 9.13 Gentlylowertheweights,applyingtherequiredload,if
procedure. Generally, preloading is chosen for variable speed using the preloading procedure.
machines, while step-loading is chosen for fixed speed ma-
9.14 If using a variable speed machine, turn on the machine
chines in order to avoid an initial high wear transient. The
and slowly increase the power to the drive motor until the ring
differences in the two procedures are indicated in 9.10 – 9.22.
startstorotate,recordingthe“static”frictionforce.Continueto
9.10 Place the required weights on the load bale and adjust increase the rate of rotation to the desired rate. If using a fixed
the lever arm in accordance with the requirements of the speed machine, simply turn on the machine.
specific machine design. Then remove the load by raising the
9.15 If using step-loading, start the machine with no
weights, if using the preloading procedure, or by removing the
weights, then gently add a 133N (30lbf) load every 200 rev
weights if using the step-loading procedure.
until the required test load is reached. Adjust the rate of
9.11 If running a lubricated test, clean all components that rotationasneeded.Iftherequiredloadislessthan133N,apply
will come in contact with lubricant; fill the lubricant reservoir the load in one step.
with lubricant to 6.4 mm (0.25 in.) above the lower surface of
9.16 During the test, record the friction force, lubricant or
the ring; rotate the ring several times.
block temperature, as required, and, if desired, the vertical
9.12 Set the revolution counter to zero. displacement of the block.
G77 − 17 (2022)
A. A good rectangular scar with straight edges.
B. The center of the scar is curved because the block was crowned. Also, debris covers the center left edge of the scar. Ordinarily, the debris should be visually
ignored, but in this case scar curvature makes this too difficult. The test should be rerun.
C. Severe galling resulted in jagged scar edges and a lip of plastically deformed material along the right side of the scar. The raised lip of material is excluded from
the scar measurement. The cross hair should be run to a visual average of the jagged edge, not to the point of a zigzag.
D. Tapered scar with jagged edges. This scar is too tapered (coefficient of variation >10 %); therefore, the test should be rerun.
FIG. 4 Block Scars
9.17 Stop the test manually or automatically after the Atracealongthelongaxisoftheblock,throughthewearscar,
4 5
desired number of revolutions. is also useful to verify the scar depth and shape.
9.18 Afinal “static” friction force may be measured with a 9.21 Measure the scar width on the test block in the center
variablespeedmachine.Leavingonthefullload,wait3min 6 and ;1 mm (0.04 in.) away from each edge. These measure-
10 s, then turn on the machine and slowly increase the power ments shall be to the nearest 0.025 mm (0.001 in.). Record the
to the drive motor until the ring starts to rotate, recording the average of the three readings. Sometimes oxidation debris or a
“static” final friction force. Then turn off the motor. lip of plastically deformed material will extend over the edge
of the wear scar (Fig. 4). When measuring scar width, try to
9.19 Remove the block and ring, clean, and reweigh to the
visually ignore this material or measure the scar width in an
nearest 0.1 mg.
area where this is not a problem.
9.20 Make surface roughness measurements and profilome-
ter traces across the width of the block and the ring as desired.
On some of the old test machines, it is possible for the block to move back and
forth slightly, increasing the apparent size of the wear scar. If this problem is
5400 and 10 800 revolutions have been used for metals in interlaboratory test suspected, a profilometer trace through the wear scar will verify whether or not the
programs. scar shape corresponds to the curvature of the ring.
G77 − 17 (2022)
θ
t = block width, mm Scar Width
= b5D sin
D t
r = radius of ring, mm Scar volume
5 sθ 2 sin θd
D =2r = diameter of ring, mm
b
b = average scar width, mm where θ
= 2sin.
D
θ = sector angle in radians
D t b b
d = scar depth, mm [ Scar Volume
21 21
5 2sin 2sin 2sin
F S DG
8 D D
FIG. 5 Block Scar Volume Based on the Width of the Scar
9.22 Tapered scars indicate improper block alignment dur-
F = measured friction force, N (lbf), and
ing testing. If the three width measurements on a given scar
W = normal force, N (lbf).
have a coefficient of variation of greater than 10%, the test
10.3 Calculate ring volume loss as follows:
shall be declared invalid.
ringmassloss
volumeloss 5 (2)
10. Calculation
ringdensity
NOTE 1—If the ring gains mass during the test, the volume loss is
10.1 Calculation of Block Scar Volume:
reported as zero with a notation that weight gain occurred. Mass loss is
10.1.1 Block scar volume may be derived from block scar
effected by material transfer from one component to another, by genera-
width by using Table 1 (applicable only when ring diameter is
tion of oxide films, or by infiltration into porous material by the lubricant,
34.99mm 6 0.025 mm (1.377in. 6 0.001 in.) and scar length
or combinations thereof. If material transfer to the ring is obvious, then a
ring scar volume should not be calculated from the weight loss
(block width) is 6.35 + 0.000, −0.025 mm (0.250 + 0.000,
measurement, but a notation should be made that material transfer
−0.001 in.)).
occurred.
10.1.2 The preferred method of calculating block scar
volume is by using the formula shown in Fig. 5. This formula
11. Report
may be programmed on a calculator or computer.
11.1 Report any unusual event or an overload shutoff of the
10.1.3 Block scar vo
...

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Annex A10  
1.4 The values stated in inch-pound units are to be regarded as standard. The values given in parentheses are mathematical conversions to SI units that are provided for information only and are not considered standard.  
1.5 When these test methods are referenced in a metric product specification, the yield and tensile values may be determined in inch-pound (ksi) units then converted into SI (MPa) units. The elongation determined in inch-pound gauge lengths of 2 in. or 8 in. may be report...

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ASTM
ASTM E345-24(Test Method)
Standard Test Methods of Tension Testing of Metallic Foil

SIGNIFICANCE AND USE
4.1 Tension tests provide information on the strength and ductility of materials under uniaxial tensile stresses. This information may be useful in comparisons of materials, alloy development, quality control, and design.  
4.2 The results of tension tests from selected portions of a part or material may not totally represent the strength and ductility of the entire end product of its in-service behavior in different environments.  
4.3 These test methods are considered satisfactory for acceptance testing of commercial shipments, since the methods have been used extensively for these purposes.  
4.4 Tension tests provide a means to determine the ductility of materials through the measurement of elongation or reduction of area. However, as specimen thickness is reduced, tension tests may become less useful for determining ductility. For these purposes Test Method E796 is an alternative procedure for measuring ductility.  
4.5 Different industries differentiate between foil and sheet at different thicknesses.  
Note 1: In 2013, to harmonize with international standards, the Aluminum Association revised its definition of foil to include thicknesses less than or equal to 0.2 mm (0.008 in.).  
4.6 This standard differs from Test Methods E8/E8M in that it permits determining the specimen thickness by weighing (7.3) and determining the elongation from crosshead displacement for some specimens (7.8).  
4.7 It is impossible for this standard to define the thickness range for every possible alloy where this standard should be used instead of Test Methods E8/E8M or other tensile test standards. Superior results for a specific alloy and thickness could be obtained by measuring the specimen thickness by weighing (7.3) to avoid damaging the material and to obtain sufficient accuracy. In addition, it may be acceptable for a given alloy and thickness to determine the elongation from crosshead displacement in cases where conventional extensometers that contact the specimen or...
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1.1 These test methods cover the tension testing of metallic foil at room temperature. Exception to these methods may be necessary in individual specifications or test methods for a particular material.  
1.2 Units—The values stated in SI units are to be regarded as standard. The values given in parentheses are mathematical conversions to inch-pound units that are provided for information only and are not considered standard.  
1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.4 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM E8/E8M-24(Test Method)
Standard Test Methods for Tension Testing of Metallic Materials

SIGNIFICANCE AND USE
4.1 Tension tests provide information on the strength and ductility of materials under uniaxial tensile stresses. This information may be useful in comparisons of materials, alloy development, quality control, and design under certain circumstances.  
4.2 The results of tension tests of specimens machined to standardized dimensions from selected portions of a part or material may not totally represent the strength and ductility properties of the entire end product or its in-service behavior in different environments.  
4.3 These test methods are considered satisfactory for acceptance testing of commercial shipments. The test methods have been used extensively in the trade for this purpose.
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1.1 These test methods cover the tension testing of metallic materials in any form at room temperature, specifically, the methods of determination of yield strength, yield point elongation, tensile strength, elongation, and reduction of area.  
1.2 The gauge lengths for most round specimens are required to be 4D for E8 and 5D for E8M. The gauge length is the most significant difference between E8 and E8M test specimens. Test specimens made from powder metallurgy (P/M) materials are exempt from this requirement by industry-wide agreement to keep the pressing of the material to a specific projected area and density.  
1.3 Exceptions to the provisions of these test methods may need to be made in individual specifications or test methods for a particular material. For examples, see Test Methods and Definitions A370 and Test Methods B557, and B557M.  
1.4 Room temperature shall be considered to be 10 °C to 38 °C [50 °F to 100°F] unless otherwise specified.  
1.5 The values stated in SI units are to be regarded as separate from inch/pound units. The values stated in each system are not exact equivalents; therefore each system must be used independently of the other. Combining values from the two systems may result in non-conformance with the standard.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM E1921-23b(Test Method)
Standard Test Method for Determination of Reference Temperature, T0, for Ferritic Steels in the Transition Range

SIGNIFICANCE AND USE
5.1 Fracture toughness is expressed in terms of an elastic-plastic stress-intensity factor, KJc, that is derived from the J-integral calculated at fracture.  
5.2 Ferritic steels are microscopically inhomogeneous with respect to the orientation of individual grains. Also, grain boundaries have properties distinct from those of the grains. Both contain carbides or nonmetallic inclusions that can act as nucleation sites for cleavage microcracks. The random location of such nucleation sites with respect to the position of the crack front manifests itself as variability of the associated fracture toughness (13). This results in a distribution of fracture toughness values that is amenable to characterization using the statistical methods in this test method.  
5.3 The statistical methods in this test method assume that the data set represents a macroscopically homogeneous material, such that the test material has both the uniform tensile and toughness properties. The fracture toughness evaluation of nonuniform materials is not amenable to the statistical analysis procedures employed in this test method. For example, multi-pass weldments can create heat-affected and brittle zones with localized properties that are quite different from either the bulk or weld materials. Thick-section steels also often exhibit some variation in properties near the surfaces. Metallographic analysis can be used to identify possible nonuniform regions in a material. These regions can then be evaluated through mechanical testing such as hardness, microhardness, and tensile testing for comparison with the bulk material. It is also advisable to measure the toughness properties of these nonuniform regions distinctly from the bulk material. Section 10.6 provides a screening criterion to assess whether the data set may not be representative of a macroscopically homogeneous material, and therefore, may not be amenable to the statistical analysis procedures employed in this test method. If the data ...
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1.1 This test method covers the determination of a reference temperature, T0, which characterizes the fracture toughness of ferritic steels that experience onset of cleavage cracking at elastic, or elastic-plastic KJc instabilities, or both. The specific types of ferritic steels (3.2.2) covered are those with yield strengths ranging from 275 MPa to 825 MPa (40 ksi to 120 ksi) and weld metals, after stress-relief annealing, that have 10 % or less strength mismatch relative to that of the base metal.  
1.2 The specimens covered are fatigue precracked single-edge notched bend bars, SE(B), and standard or disk-shaped compact tension specimens, C(T) or DC(T). A range of specimen sizes with proportional dimensions is recommended. The dimension on which the proportionality is based is specimen thickness.  
1.3 Median KJc values tend to vary with the specimen type at a given test temperature, presumably due to constraint differences among the allowable test specimens in 1.2. The degree of KJc variability among specimen types is analytically predicted to be a function of the material flow properties (1)2 and decreases with increasing strain hardening capacity for a given yield strength material. This KJc dependency ultimately leads to discrepancies in calculated T0 values as a function of specimen type for the same material. T0 values obtained from C(T) specimens are expected to be higher than T0 values obtained from SE(B) specimens. Best estimate comparisons of several materials indicate that the average difference between C(T) and SE(B)-derived T0 values is approximately 10°C (2). C(T) and SE(B) T0 differences up to 15 °C have also been recorded (3). However, comparisons of individual, small datasets may not necessarily reveal this average trend. Datasets which contain both C(T) and SE(B) specimens may generate T0 results which fall between the T0 values calculated using solely C(T) or SE(B) specimens. It is therefore strongl...

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ASTM
ASTM E647-23b(Test Method)
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 E740/E740M-23(Practice)
Standard Practice for Fracture Testing with Surface-Crack Tension Specimens

SIGNIFICANCE AND USE
4.1 The surface-crack tension (SCT) test is used to estimate the load-carrying capacity of simple sheet- or plate-like structural components having a type of flaw likely to occur in service. The test is also used for research purposes to investigate failure mechanisms of cracks under service conditions.  
4.2 The residual strength of an SCT specimen is a function of the crack depth and length and the specimen thickness as well as the characteristics of the material. This relationship is extremely complex and cannot be completely described or characterized at present.  
4.2.1 The results of the SCT test are suitable for direct application to design only when the service conditions exactly parallel the test conditions. Some methods for further analysis are suggested in Appendix X1.  
4.3 In order that SCT test data can be comparable and reproducible and can be correlated among laboratories, it is essential that uniform SCT testing practices be established.  
4.4 The specimen configuration, preparation, and instrumentation described in this practice are generally suitable for cyclic- or sustained-force testing as well. However, certain constraints are peculiar to each of these tests. These are beyond the scope of this practice but are discussed in Ref. (1).
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1.1 This practice covers the design, preparation, and testing of surface-crack tension (SCT) specimens. It relates specifically to testing under continuously increasing force and excludes cyclic and sustained loadings. The quantity determined is the residual strength of a specimen having a semielliptical or circular-segment fatigue crack in one surface. This value depends on the crack dimensions and the specimen thickness as well as the characteristics of the material.  
1.2 Metallic materials that can be tested are not limited by strength, thickness, or toughness. However, tests of thick specimens of tough materials may require a tension test machine of extremely high capacity. The applicability of this practice to nonmetallic materials has not been determined.  
1.3 This practice is limited to specimens having a uniform rectangular cross section in the test section. The test section width and length must be large with respect to the crack length. Crack depth and length should be chosen to suit the ultimate purpose of the test.  
1.4 Residual strength may depend strongly upon temperature within a certain range depending upon the characteristics of the material. This practice is suitable for tests at any appropriate temperature.  
1.5 Residual strength is believed to be relatively insensitive to loading rate within the range normally used in conventional tension tests. When very low or very high rates of loading are expected in service, the effect of loading rate should be investigated using special procedures that are beyond the scope of this practice.  
Note 1: Further information on background and need for this type of test is given in the report of ASTM Task Group E24.01.05 on Part-Through-Crack Testing (1).2  
1.6 The values stated in either SI units or inch-pound units are to be regarded separately as standard. The values stated in each system may not be exact equivalents; therefore, each system shall be used independently of the other. Combining values from the two systems may result in non-conformance with the standard.  
1.7 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 Recommendations issued by the World Trade Organization Technical Barriers to T...

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ASTM
ASTM E1457-23e1(Test Method)
Standard Test Method for Measurement of Creep Crack Growth Times in Metals

SIGNIFICANCE AND USE
6.1 Creep crack growth rate expressed as a function of the steady state C* or K characterizes the resistance of a material to crack growth under conditions of extensive creep deformation or under brittle creep conditions. Background information on the rationale for employing the fracture mechanics approach in the analyses of creep crack growth data is given in (11, 13, 30-35).  
6.2 Aggressive environments at high temperatures can significantly affect the creep crack growth behavior. Attention must be given to the proper selection and control of temperature and environment in research studies and in generation of design data.  
6.2.1 Expressing CCI time, t0.2 and CCG rate, da/dt as a function of an appropriate fracture mechanics related parameter generally provides results that are independent of specimen size and planar geometry for the same stress state at the crack tip for the range of geometries and sizes presented in this document (see Annex A1). Thus, the appropriate correlation will enable exchange and comparison of data obtained from a variety of specimen configurations and loading conditions. Moreover, this feature enables creep crack growth data to be utilized in the design and evaluation of engineering structures operated at elevated temperatures where creep deformation is a concern. The concept of similitude is assumed, implying that cracks of differing sizes subjected to the same nominal C*(t), Ct, or K will advance by equal increments of crack extension per unit time, provided the conditions for the validity for the specific crack growth rate relating parameter are met. See 11.7 for details.  
6.2.2 The effects of crack tip constraint arising from variations in specimen size, geometry and material ductility can influence t0.2 and da/dt. For example, crack growth rates at the same value of C*(t), Ct in creep-ductile materials generally increases with increasing thickness. It is therefore necessary to keep the component dimensions in mind when selecti...
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1.1 This test method covers the determination of creep crack initiation (CCI) and creep crack growth (CCG) in metals at elevated temperatures using pre-cracked specimens subjected to static or quasi-static loading conditions. The solutions presented in this test method are validated for base material (that is, homogenous properties) and mixed base/weld material with inhomogeneous microstructures and creep properties. The CCI time, t0.2, which is the time required to reach an initial crack extension of δai = 0.2 mm to occur from the onset of first applied force, and CCG rate, a˙  or da/dt are expressed in terms of the magnitude of creep crack growth correlated by fracture mechanics parameters, C* or K, with C* defined as the steady state determination of the crack tip stresses derived in principal from C*(t) and Ct   (1-17).2 The crack growth derived in this manner is identified as a material property which can be used in modeling and life assessment methods (17-28).  
1.1.1 The choice of the crack growth correlating parameter C*, C*(t), Ct, or K depends on the material creep properties, geometry and size of the specimen. Two types of material behavior are generally observed during creep crack growth tests; creep-ductile (1-17) and creep-brittle (29-44). In creep ductile materials, where creep strains dominate and creep crack growth is accompanied by substantial time-dependent creep strains at the crack tip, the crack growth rate is correlated by the steady state definitions of Ct or C*(t) , defined as C* (see 1.1.4). In creep-brittle materials, creep crack growth occurs at low creep ductility. Consequently, the time-dependent creep strains are comparable to or dominated by accompanying elastic strains local to the crack tip. Under such steady state creep-brittle conditions, Ct or K could be chosen as the correlating parameter (8-14).  
1.1.2 In any one test, two regions of crack growth behavior may be present (12, 13)....

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