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ASTM C1366-04(2013)

(Test Method)

Standard Test Method for Tensile Strength of Monolithic Advanced Ceramics at Elevated Temperatures

Standard Test Method for Tensile Strength of Monolithic Advanced Ceramics at Elevated Temperatures

SIGNIFICANCE AND USE
4.1 This test method may be used for material development, material comparison, quality assurance, characterization, reliability assessment, and design data generation.  
4.2 High strength, monolithic advanced ceramic materials are generally characterized by small grain sizes (  
4.3 Because of the probabilistic strength distributions of brittle materials such as advanced ceramics, a sufficient number of test specimens at each testing condition is required for statistical analysis and eventual design with guidelines for sufficient numbers provided in this test method. Size-scaling effects as discussed in practice C1239 will affect the strength values. Therefore, strengths obtained using different recommended tensile test specimen geometries with different volumes or surface areas of material in the gage sections will be different due to these size differences. Resulting strength values can, in principle, be scaled to an effective volume or effective surface area of unity as discussed in Practice C1239.  
4.4 Tensile tests provide information on the strength and deformation of materials under uniaxial stresses. Uniform stress states are required to effectively evaluate any non-linear stress-strain behavior which may develop as the result of testing mode, testing rate, processing or alloying effects, environmental influences, or elevated temperatures. These effects may be consequences of stress corrosion or sub critical (slow) crack growth which can be minimized by testing at appropriately rapid rates as outlined in this test method.  
4.5 The results of tensile tests of specimens fabricated to standardized dimensions from a particular material or selected portions of a part, or both, may not totally represent the strength and deformation properties of the entire, full-size end product or its in-service behavior in different environments.  
4.6 For quality control purposes, results derived from standardized tensile test specimens can be considered to be indicativ...
SCOPE
1.1 This test method covers the determination of tensile strength under uniaxial loading of monolithic advanced ceramics at elevated temperatures. This test method addresses, but is not restricted to, various suggested test specimen geometries as listed in the appendix. In addition, test specimen fabrication methods, testing modes (force, displacement, or strain control), testing rates (force rate, stress rate, displacement rate, or strain rate), allowable bending, and data collection and reporting procedures are addressed. Tensile strength as used in this test method refers to the tensile strength obtained under uniaxial loading.  
1.2 This test method applies primarily to advanced ceramics which macroscopically exhibit isotropic, homogeneous, continuous behavior. While this test method applies primarily to monolithic advanced ceramics, certain whisker, or particle-reinforced composite ceramics as well as certain discontinuous fiber-reinforced composite ceramics may also meet these macroscopic behavior assumptions. Generally, continuous fiber ceramic composites (CFCCs) do not macroscopically exhibit isotropic, homogeneous, continuous behavior and application of this test method to these materials is not recommended.  
1.3 The values stated in SI units are to be regarded as the standard and are in accordance with Practice E380.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use. Refer to Section 7 for specific precautions.

General Information

Status
Historical
Publication Date
31-Jul-2013
ICS
81.060.30 - Advanced ceramics
Technical Committee
C28 - Advanced Ceramics
Drafting Committee
C28.01 - Mechanical Properties and Performance
Current Stage
Ref Project

Relations

Replaces
ASTM C1366-04(2009) - Standard Test Method for Tensile Strength of Monolithic Advanced Ceramics at Elevated Temperatures
Effective Date
01-Aug-2013
Replaced By
ASTM C1366-19 - Standard Test Method for Tensile Strength of Monolithic Advanced Ceramics at Elevated Temperatures
Effective Date
01-Aug-2019
Referred By
ASTM C1683-10(2019) - Standard Practice for Size Scaling of Tensile Strengths Using Weibull Statistics for Advanced Ceramics
Effective Date
01-Aug-2013

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ASTM C1366-04(2013) - Standard Test Method for Tensile Strength of Monolithic Advanced Ceramics at Elevated TemperaturesASTM C1366-04(2013) - Standard Test Method for Tensile Strength of Monolithic Advanced Ceramics at Elevated Temperatures
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ASTM C1366-04(2013) - Standard Test Method for Tensile Strength of Monolithic Advanced Ceramics at Elevated Temperatures
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NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
Contact ASTM International (www.astm.org) for the latest information
Designation: C1366 − 04 (Reapproved 2013)
Standard Test Method for
Tensile Strength of Monolithic Advanced Ceramics at
Elevated Temperatures
This standard is issued under the fixed designation C1366; 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
1.1 This test method covers the determination of tensile 2.1 ASTM Standards:
strength under uniaxial loading of monolithic advanced ceram- C1145 Terminology of Advanced Ceramics
ics at elevated temperatures. This test method addresses, but is C1161 Test Method for Flexural Strength of Advanced
not restricted to, various suggested test specimen geometries as Ceramics at Ambient Temperature
listed in the appendix. In addition, test specimen fabrication C1239 Practice for Reporting Uniaxial Strength Data and
methods,testingmodes(force,displacement,orstraincontrol), Estimating Weibull Distribution Parameters forAdvanced
testing rates (force rate, stress rate, displacement rate, or strain Ceramics
rate), allowable bending, and data collection and reporting C1322 Practice for Fractography and Characterization of
procedures are addressed. Tensile strength as used in this test Fracture Origins in Advanced Ceramics
method refers to the tensile strength obtained under uniaxial D3379 Test Method forTensile Strength andYoung’s Modu-
loading. lus for High-Modulus Single-Filament Materials
E4 Practices for Force Verification of Testing Machines
1.2 This test method applies primarily to advanced ceramics
E6 Terminology Relating to Methods of Mechanical Testing
which macroscopically exhibit isotropic, homogeneous, con-
E21 TestMethodsforElevatedTemperatureTensionTestsof
tinuous behavior. While this test method applies primarily to
Metallic Materials
monolithic advanced ceramics, certain whisker, or particle-
E83 Practice for Verification and Classification of Exten-
reinforced composite ceramics as well as certain discontinuous
someter Systems
fiber-reinforced composite ceramics may also meet these
E220 Test Method for Calibration of Thermocouples By
macroscopicbehaviorassumptions.Generally,continuousfiber
Comparison Techniques
ceramic composites (CFCCs) do not macroscopically exhibit
E337 Test Method for Measuring Humidity with a Psy-
isotropic, homogeneous, continuous behavior and application
chrometer (the Measurement of Wet- and Dry-Bulb Tem-
of this test method to these materials is not recommended.
peratures)
1.3 The values stated in SI units are to be regarded as the
E380 Practice for Use of the International System of Units
standard and are in accordance with IEEE/ASTM SI 10.
(SI) (the Modernized Metric System) (Withdrawn 1997)
1.4 This standard does not purport to address all of the
E1012 Practice for Verification of Testing Frame and Speci-
safety concerns, if any, associated with its use. It is the men Alignment Under Tensile and Compressive Axial
responsibility of the user of this standard to establish appro-
Force Application
priate safety and health practices and determine the applica- IEEE/ASTM SI 10 Standard for Use of the International
bility of regulatory limitations prior to use. Refer to Section 7
System of Units (SI) (The Modern Metric System)
for specific precautions.
1 2
This test method is under the jurisdiction of ASTM Committee C28 on For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Advanced Ceramics and is the direct responsibility of Subcommittee C28.01 on contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
Mechanical Properties and Performance. Standards volume information, refer to the standard’s Document Summary page on
Current edition approved Aug. 1, 2013. Published September 2013. Originally the ASTM website.
approved in 1997. Last previous edition approved in 2009 as C1366 – 04 (2009). The last approved version of this historical standard is referenced on
DOI: 10.1520/C1366-04R13. www.astm.org.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
C1366 − 04 (2013)
3. Terminology mation on strength-limiting flaws from a greater volume of
uniformly stressed material.
3.1 Definitions:
4.3 Because of the probabilistic strength distributions of
3.1.1 Definitions of terms relating to tensile testing and
advanced ceramics as they appear in Terminology E6 and brittle materials such as advanced ceramics, a sufficient num-
ber of test specimens at each testing condition is required for
Terminology C1145, respectively, apply to the terms used in
this test method. Pertinent definitions are shown in the follow- statistical analysis and eventual design with guidelines for
sufficient numbers provided in this test method. Size-scaling
ingwiththeappropriatesourcegiveninparenthesis.Additional
terms used in conjunction with this test method are defined in effects as discussed in practice C1239 will affect the strength
values. Therefore, strengths obtained using different recom-
the following.
mended tensile test specimen geometries with different vol-
3.1.2 advanced ceramic, n—a highly engineered, high per-
umes or surface areas of material in the gage sections will be
formance predominately non-metallic, inorganic, ceramic ma-
different due to these size differences. Resulting strength
terial having specific functional attributes. (See Terminology
values can, in principle, be scaled to an effective volume or
C1145.)
–1 effective surface area of unity as discussed in Practice C1239.
3.1.3 axial strain [LL ], n—theaveragelongitudinalstrains
4.4 Tensile tests provide information on the strength and
measured at the surface on opposite sides of the longitudinal
deformation of materials under uniaxial stresses. Uniform
axis of symmetry of the specimen by two strain-sensing
stress states are required to effectively evaluate any non-linear
devices located at the mid length of the reduced section. (See
stress-strain behavior which may develop as the result of
Practice E1012.)
–1 testing mode, testing rate, processing or alloying effects,
3.1.4 bending strain [LL ], n—the difference between the
environmental influences, or elevated temperatures. These
strain at the surface and the axial strain. In general, the bending
effects may be consequences of stress corrosion or sub critical
strain varies from point to point around and along the reduced
(slow) crack growth which can be minimized by testing at
section of the specimen. (See Practice E1012.)
appropriately rapid rates as outlined in this test method.
3.1.5 breaking load [F], n—the load at which fracture
4.5 The results of tensile tests of specimens fabricated to
occurs. (See Terminology E6.)
standardized dimensions from a particular material or selected
3.1.6 fractography, n—the means and methods for charac-
portions of a part, or both, may not totally represent the
terizing a fractured specimen or component. (See Terminology
strength and deformation properties of the entire, full-size end
C1145.)
product or its in-service behavior in different environments.
3.1.7 fracture origin, n—the source from which brittle
4.6 For quality control purposes, results derived from stan-
fracture commences. (See Terminology C1145).
dardized tensile test specimens can be considered to be
3.1.8 percent binding, n—the bending strain times 100
indicativeoftheresponseofthematerialfromwhichtheywere
divided by the axial strain. (See Practice E1012.)
taken for particular primary processing conditions and post-
processing heat treatments.
3.1.9 slow crack growth, n—sub critical crack growth (ex-
tension) that may result from, but is not restricted to, such
4.7 The tensile strength of a ceramic material is dependent
mechanisms as environmentally-assisted stress corrosion or on both its inherent resistance to fracture and the presence of
diffusive crack growth.
flaws. Analysis of fracture surfaces and fractography as de-
scribed in Practice C1322 and MIL-HDBK-790, though be-
3.1.10 tensile strength, S [FL ], n—the maximum tensile
u
yond the scope of this test method, are recommended for all
stress which a material is capable of sustaining. Tensile
purposes, especially for design data.
strength is calculated from the maximum load during a tension
test carried to rupture and the original cross-sectional area of
5. Interferences
the specimen. (See Terminology E6.)
5.1 Test environment (vacuum, inert gas, ambient air, etc.)
including moisture content for example relative humidity) may
4. Significance and Use
have an influence on the measured tensile strength. In
4.1 This test method may be used for material development,
particular, the behavior of materials susceptible to slow crack
material comparison, quality assurance, characterization, reli-
growth fracture will be strongly influenced by test
ability assessment, and design data generation.
environment,testingrate,andelevatedtemperatures.Testingto
4.2 High strength, monolithic advanced ceramic materials evaluate the maximum strength potential of a material should
are generally characterized by small grain sizes (< 50 µm) and be conducted in inert environments or at sufficiently rapid
bulk densities near the theoretical density. These materials are testing rates, or both, to minimize slow crack growth effects.
candidates for load-bearing structural applications requiring Conversely, testing can be conducted in environments and
high degrees of wear and corrosion resistance and elevated- testing modes and rates representative of service conditions to
temperature strength. Although flexural test methods are com- evaluate material performance under use conditions. When
monly used to evaluate strength of advanced ceramics, the non testing is conducted in uncontrolled ambient air with the intent
uniform stress distribution of the flexure specimen limits the of evaluating maximum strength potential, monitor and report
volume of material subjected to the maximum applied stress at relative humidity and ambient temperature.Testing at humidity
fracture. Uniaxially-loaded tensile strength tests provide infor- levels >65 % relative humidity (RH) is not recommended.
C1366 − 04 (2013)
5.2 Surface preparation of test specimens can introduce
fabrication flaws that may have pronounced effects on tensile
strength. Machining damage introduced during test specimen
preparation can be either a random interfering factor in the
determination of ultimate strength of pristine material (that is
increase frequency of surface initiated fractures compared to
volume initiated fractures), or an inherent part of the strength
characteristics. Surface preparation can also lead to the intro-
duction of residual stresses. Universal or standardized test
methods of surface preparation do not exist. Final machining
steps may, or may not negate machining damage introduced
during the early coarse or intermediate machining.Thus, report
testspecimenfabricationhistorysinceitmayplayanimportant
role in the measured strength distributions.
5.3 Bending in uniaxial tensile tests can cause or promote
non uniform stress distributions with maximum stresses occur-
ring at the test specimen surface leading to non representative
fracturesoriginatingatsurfacesorneargeometricaltransitions.
Bending may be introduced from several sources including
misaligned load trains, eccentric or mis-shaped test specimens,
and non-uniformly heated test specimens or grips. In addition,
if strains or deformations are measured at surfaces where
maximum or minimum stresses occur, bending may introduce
over or under measurement of strains. Similarly, fracture from
FIG. 1 Schematic Diagram of One Possible Apparatus for Con-
surface flaws may be accentuated or muted by the presence of
ducting a Uniaxially-Loaded Tensile Test
the non uniform stresses caused by bending.
6. Apparatus
elevated-temperature oxidizing environment. Cooled grips lo-
cated outside the heated zone are termed“ cold grips” and
6.1 Testing Machines—Machines used for tensile testing
generally induce a steep thermal gradient in the test specimen
shall conform to the requirements of Practice E4. The forces
at a greater relative expense because of grip cooling equipment
used in determining tensile strength shall be accurate within
and allowances, although with the advantage of consistent
61%atanyforcewithintheselectedforcerangeofthetesting
alignment and little degradation from exposure to elevated
machine as defined in Practice E4. A schematic showing
temperatures.
pertinent features of a possible tensile testing apparatus is
shown in Fig. 1.
NOTE 1—The expense of the cooling system for cold grips is balanced
against maintaining alignment which remains consistent from test to test
6.2 Gripping Devices:
(stable grip temperature) and decreased degradation of the grips due to
6.2.1 General—Various types of gripping devices may be
exposure to the elevated-temperature oxidizing environment. When grip
used to transmit the measured load applied by the testing
cooling is employed, means should be provided to control the cooling
machine to the test specimen. The brittle nature of advanced
medium to maximum fluctuations of 5 K (less than 1 K preferred) about
a setpoint temperature (1) over the course of the test to minimize
ceramics requires a uniform interface between the grip com-
thermally-induced strain changes in the test specimen. In addition,
ponents and the gripped section of the test specimen. Line or
opposing grip temperatures should be maintained at uniform and consis-
point contacts and non uniform pressure can produce Hertzian-
tent temperatures within 65 K (less than 61 K preferred) (1) so as to
type stress leading to crack initiation and fracture of the test
avoid introducing unequal thermal gradients and subsequent non uniaxial
specimen in the gripped section. Gripping devices can be
stresses in the test specimen. Generally, the need for control of grip
temperature fluctuations or differences may be indicated if test specimen
classed generally as those employing active and those employ-
gage-section temperatures cannot be maintained within the limits required
ing passive grip interfaces as discussed in the following
in 9.3.2.
sections. Uncooled grips located inside the heated zone are
6.2.1.1 Active Grip Interfaces—Active grip interfaces re-
termed “hot grips” and generally produce almost no thermal
quire a continuous application of a mechanical, hydraulic, or
gradient in the test specimen but at the relative expense of grip
pneumatic force to transmit the l
...

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4.4 The flexural strength of a ceramic material is dependent on both its inherent resistance to fracture and the size and severity of flaws in the material. Flaws in rods may be intrinsically volume-distributed throughout the bulk. Some of these flaws by chance may be located at or near the outer surface. Flaws may alternatively be intrinsically surface-distrib...
SCOPE
1.1 This test method is for the determination of flexural strength of rod-shaped specimens of advanced ceramic materials at ambient temperature. In many instances it is preferable to test round specimens rather than rectangular bend specimens, especially if the material is fabricated in rod form. This method permits testing of machined, drawn, or as-fired rod-shaped specimens. It allows some latitude in the rod sizes and cross section shape uniformity. Rod diameters between 1.5 and 8 mm and lengths from 25 to 85 mm are recommended, but other sizes are permitted. Four-point-1/4-point as shown in Fig. 1 is the preferred testing configuration. Three-point loading is permitted. This method describes the apparatus, specimen requirements, test procedure, calculations, and reporting requirements. The method is applicable to monolithic or particulate- or whisker-reinforced ceramics. It may also be used for glasses. It is not applicable to continuous fiber-reinforced ceramic composites.
FIG. 1 Four-Point-1/4-Point Flexure Loading Configuration  
1.2 The values stated in SI units are to be regarded as the standard. The values given in parentheses are for information only.  
1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.4 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM C1326-13(2023)(Test Method)
Standard Test Method for Knoop Indentation Hardness of Advanced Ceramics

SIGNIFICANCE AND USE
5.1 For advanced ceramics, Knoop indenters are used to create indentations. The surface projection of the long diagonal is measured with optical microscopes.  
5.2 The Knoop indentation hardness is one of many properties that is used to characterize advanced ceramics. Attempts have been made to relate Knoop indentation hardness to other hardness scales, but no generally accepted methods are available. Such conversions are limited in scope and should be used with caution, except for special cases where a reliable basis for the conversion has been obtained by comparison tests.  
5.3 For advanced ceramics, the Knoop indentation is often preferred to the Vickers indentation since the Knoop long diagonal length is 2.8 times longer than the Vickers diagonal for the same force, and cracking is much less of a problem (1).5 On the other hand, the long slender tip of the Knoop indentation is more difficult to precisely discern, especially in materials with low contrast. The indentation forces chosen in this test method are designed to produce indentations as large as may be possible with conventional microhardness equipment, yet not so large as to cause cracking.  
5.4 The Knoop indentation is shallower than Vickers indentations made at the same force. Knoop indents may be useful in evaluating coating hardnesses.  
5.5 Knoop hardness is calculated from the ratio of the applied force divided by the projected indentation area on the specimen surface. It is assumed that the elastic springback of the narrow diagonal is negligible. (Vickers indenters are also used to measure hardness, but Vickers hardness is calculated from the ratio of applied force to the area of contact of the four faces of the undeformed indenter.)  
5.6 A full hardness characterization includes measurements over a broad range of indentation forces. Knoop hardness of ceramics usually decreases with increasing indentation size or indentation force such as that shown in Fig. 1.6 The trend is known as the in...
SCOPE
1.1 This test method covers the determination of the Knoop indentation hardness of advanced ceramics. In this test, a pointed, rhombic-based, pyramidal diamond indenter of prescribed shape is pressed into the surface of a ceramic with a predetermined force to produce a relatively small, permanent indentation. The surface projection of the long diagonal of the permanent indentation is measured using a light microscope. The length of the long diagonal and the applied force are used to calculate the Knoop hardness which represents the material’s resistance to penetration by the Knoop indenter.  
1.2 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.3 Units—When Knoop and Vickers hardness tests were developed, the force levels were specified in units of grams-force (gf) and kilograms-force (kgf). This standard specifies the units of force and length in the International System of Units (SI); that is, force in newtons (N) and length in mm or μm. However, because of the historical precedent and continued common usage, force values in gf and kgf units are occasionally provided for information. This test method specifies that Knoop hardness be reported either in units of GPa or as a dimensionless Knoop hardness number.  
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.

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ASTM C1495-16(2023)(Test Method)
Standard Test Method for Effect of Surface Grinding on Flexure Strength of Advanced Ceramics

SIGNIFICANCE AND USE
5.1 Surface grinding can cause a significant decrease4 in the flexure strength of advanced ceramic materials. The magnitude of the loss in strength is determined by the grinding conditions and the response of the material. This test method can be used to obtain a detailed characterization of the relationship between grinding conditions and flexure strength for an advanced ceramic material. The effect on flexure strength of varying a single grinding parameter or several grinding parameters can be measured. The method may also be used to compare and rank different materials according to their response to one or more different grinding conditions. Results obtained by this method can be used to develop an optimum grinding process with respect to maximizing material removal rate for a specified flexure strength requirement. The test method can assist in the development of improved grinding-damage-tolerant ceramic materials. It may also be used for quality control purposes to monitor and assure the consistency of a grinding process in the fabrication of parts from advanced ceramic materials. The test method is applicable to grinding methods that generate a planar surface and is not directly applicable to grinding methods that produce non-planar surfaces such as cylindrical and centerless grinding.
SCOPE
1.1 This test method covers the determination of the effect of surface grinding on the flexure strength of advanced ceramics. Surface grinding of an advanced ceramic material can introduce microcracks and other changes in the near surface layer, generally referred to as damage (see Fig. 1 and Ref. (1)).2 Such damage can result in a change—most often a decrease—in flexure strength of the material. The degree of change in flexure strength is determined by both the grinding process and the response characteristics of the specific ceramic material. This method compares the flexure strength of an advanced ceramic material after application of a user-specified surface grinding process with the baseline flexure strength of the same material. The baseline flexure strength is obtained after application of a surface grinding process specified in this standard. The baseline flexure strength is expected to approximate closely the inherent strength of the material. The flexure strength is measured by means of ASTM flexure test methods.
FIG. 1 Microcracks Associated with Grinding (Ref. (1))2  
1.2 Flexure test methods used to determine the effect of surface grinding are C1161 Test Method for Flexure Strength of Advanced Ceramics at Ambient Temperatures and C1211 Test Method for Flexure Strength of Advanced Ceramics at Elevated Temperatures.  
1.3 Materials covered in this standard are those advanced ceramics that meet criteria specified in flexure testing standards C1161 and C1211.  
1.4 The flexure test methods supporting this standard (C1161 and C1211) require test specimens that have a rectangular cross section, flat surfaces, and that are fabricated with specific dimensions and tolerances. Only grinding processes that are capable of generating the specified flat surfaces, that is, planar grinding modes, are suitable for evaluation by this method. Among the applicable machine types are horizontal and vertical spindle reciprocating surface grinders, horizontal and vertical spindle rotary surface grinders, double disk grinders, and tool-and-cutter grinders. Incremental cross-feed, plunge, and creep-feed grinding methods may be used.  
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 develop...

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ASTM C1211-18(2023)(Test Method)
Standard Test Method for Flexural Strength of Advanced Ceramics at Elevated Temperatures

SIGNIFICANCE AND USE
4.1 This test method may be used for material development, quality control, characterization, and design data generation purposes. This test method is intended to be used with ceramics whose flexural strength is ∼50 MPa (∼7 ksi) or greater.  
4.2 The flexure stress is computed based on simple beam theory, with assumptions that the material is isotropic and homogeneous, the moduli of elasticity in tension and compression are identical, and the material is linearly elastic. The average grain size should be no greater than 1/50 of the beam thickness. The homogeneity and isotropy assumptions in the test method rule out the use of it for continuous fiber-reinforced composites for which Test Method C1341 is more appropriate.  
4.3 The flexural strength of a group of test specimens is influenced by several parameters associated with the test procedure. Such factors include the testing rate, test environment, specimen size, specimen preparation, and test fixtures. Specimen and fixture sizes were chosen to provide a balance between the practical configurations and resulting errors as discussed in Test Method C1161, and Refs (1-3).4 Specific fixture and specimen configurations were designated in order to permit the ready comparison of data without the need for Weibull size scaling.  
4.4 The flexural strength of a ceramic material is dependent on both its inherent resistance to fracture and the size and severity of flaws. Variations in these cause a natural scatter in test results for a sample of test specimens. Fractographic analysis of fracture surfaces, although beyond the scope of this test method, is highly recommended for all purposes, especially if the data will be used for design as discussed in Ref (4) and Practices C1322 and C1239.  
4.5 This method determines the flexural strength at elevated temperature and ambient environmental conditions at a nominal, moderately fast testing rate. The flexural strength under these conditions may or may not necessarily be the...
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1.1 This test method covers determination of the flexural strength of advanced ceramics at elevated temperatures.2 Four-point-1/4-point and three-point loadings with prescribed spans are the standard as shown in Fig. 1. Rectangular specimens of prescribed cross-section are used with specified features in prescribed specimen-fixture combinations. Test specimens may be 3 by 4 by 45 to 50 mm in size that are tested on 40-mm outer span four-point or three-point fixtures. Alternatively, test specimens and fixture spans half or twice these sizes may be used. The test method permits testing of machined or as-fired test specimens. Several options for machining preparation are included: application matched machining, customary procedures, or a specified standard procedure. This test method describes the apparatus, specimen requirements, test procedure, calculations, and reporting requirements. The test method is applicable to monolithic or particulate- or whisker-reinforced ceramics. It may also be used for glasses. It is not applicable to continuous fiber-reinforced ceramic composites.  
1.2 The values stated in SI units are to be regarded as the standard. The values given in parentheses are for information only.  
1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.4 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM C1323-22(Test Method)
Standard Test Method for Ultimate Strength of Advanced Ceramics with Diametrally Compressed C-Ring Specimens at Ambient Temperature

SIGNIFICANCE AND USE
4.1 This test method may be used for material development, material comparison, quality assurance, and characterization. Extreme care should be exercised when generating design data.  
4.2 For a C-ring under diametral compression, the maximum tensile stress occurs at the outer surface. Hence, the C-ring specimen loaded in compression will predominately evaluate the strength distribution and flaw population(s) on the external surface of a tubular component in the hoop direction. Accordingly, the condition of the inner surface may be of lesser consequence in specimen preparation and testing.
Note 1: A C-ring in tension or an O-ring in compression may be used to evaluate the internal surface.  
4.2.1 The flexure stress is computed based on simple curved beam theory (1-5).3 It is assumed that the material is isotropic and homogeneous, the moduli of elasticity are identical in compression or tension, and the material is linearly elastic. These homogeneity and isotropy assumptions preclude the use of this standard for continuous fiber reinforced composites. Average grain size(s) should be no greater than one fiftieth (1/50 ) of the C-ring thickness. The curved beam stress solution from engineering mechanics is in good agreement (within 2 %) with an elasticity solution as discussed in (6) for the test specimen geometries recommended for this standard. The curved beam stress equations are simple and straightforward, and therefore it is relatively easy to integrate the equations for calculations for effective area or effective volume for Weibull analyses as discussed in Appendix X1.  
4.2.2 The simple curved beam and theory of elasticity stress solutions both are two-dimensional plane stress solutions. They do not account for stresses in the axial (parallel to b) direction, or variations in the circumferential (hoop, σθ) stresses through the width (b) of the test piece. The variations in the circumferential stresses increase with increases in width (b) and ring thicknes...
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1.1 This test method covers the determination of ultimate strength under monotonic loading of advanced ceramics in tubular form at ambient temperatures. The ultimate strength as used in this test method refers to the strength obtained under monotonic compressive loading of C-ring specimens such as shown in Fig. 1, where monotonic refers to a continuous nonstop test rate with no reversals from test initiation to final fracture. This method permits a range of sizes and shapes since test specimens may be prepared from a variety of tubular structures. The method may be used with microminiature test specimens.
FIG. 1 C-Ring Test Geometry with Defining Geometry and Reference Angle (θ) for the Point of Fracture Initiation on the Circumference  
1.2 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.2.1 Values expressed in this test method are in accordance with the International System of Units (SI) and IEEE/ASTM SI 10.  
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 C1730-17(2022)(Test Method)
Standard Test Method for Particle Size Distribution of Advanced Ceramics by X-Ray Monitoring of Gravity Sedimentation

SIGNIFICANCE AND USE
5.1 This test method is useful to both suppliers and users of powders, as outlined in 1.1 and 1.2, in determining particle size distribution for product specifications, manufacturing control, development, and research.  
5.2 Users should be aware that sample concentrations used in this test method may not be what is considered ideal by some authorities, and that the range of this test method extends into the region where Brownian movement could be a factor in conventional sedimentation. Within the range of this test method, neither the sample concentration nor Brownian movement is believed to be significant. Standard reference materials traceable to national standards, of chemical composition specifically covered by this test method, are available from NIST,3 and perhaps other suppliers.  
5.3 Reported particle size measurement is a function of the actual particle dimension and shape factor as well as the particular physical or chemical properties being measured. Caution is required when comparing data from instruments operating on different physical or chemical parameters or with different particle size measurement ranges. Sample acquisition, handling, and preparation can also affect reported particle size results.  
5.4 Suppliers and users of data obtained using this test method need to agree upon the suitability of these data to provide specification for and allow performance prediction of the materials analyzed.
SCOPE
1.1 This test method covers the determination of particle size distribution of advanced ceramic powders. Experience has shown that this test method is satisfactory for the analysis of silicon carbide, silicon nitride, and zirconium oxide in the size range of 0.1 up to 50 µm.  
1.1.1 However, the relationship between size and sedimentation velocity used in this test method assumes that particles sediment within the laminar flow regime. It is generally accepted that particles sedimenting with a Reynolds number of 0.3 or less will do so under conditions of laminar flow with negligible error. Particle size distribution analysis for particles settling with a larger Reynolds number may be incorrect due to turbulent flow. Some materials covered by this test method may settle in water with a Reynolds number greater than 0.3 if large particles are present. The user of this test method should calculate the Reynolds number of the largest particle expected to be present in order to judge the quality of obtained results. Reynolds number (Re) can be calculated using the following equation:
   where:  
  D  =  the diameter of the largest particle expected to be present, in cm,   ρ  =  the particle density, in g/cm3,   ρ0  =  the suspending liquid density, in g/cm3,   g  =  the acceleration due to gravity, 981 cm/sec2, and   η  =  the suspending liquid viscosity, in poise.    
1.1.2 A table of the largest particles that can be analyzed with a suggested maximum Reynolds number of 0.3 or less in water at 35 °C is given for a number of materials in Table 1. A column of the Reynolds number calculated for a 50-µm particle sedimenting in the same liquid system is also given for each material. Larger particles can be analyzed in dispersing media with viscosities greater than that for water. Aqueous solutions of glycerine or sucrose have such higher viscosities.  
1.2 The procedure described in this test method may be applied successfully to other ceramic powders in this general size range, provided that appropriate dispersion procedures are developed. It is the responsibility of the user to determine the applicability of this test method to other materials. Note however that some ceramics, such as boron carbide and boron nitride, may not absorb X-rays sufficiently to be characterized by this analysis method.  
1.3 The values stated in cgs units are to be regarded as the standard, which is the long-standing industry practice. The values given in parentheses are for information onl...

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ASTM C1292-22(Test Method)
Standard Test Method for Shear Strength of Continuous Fiber-Reinforced Advanced Ceramics at Ambient Temperatures

SIGNIFICANCE AND USE
5.1 Continuous fiber-reinforced ceramic composites can be candidate materials for structural applications requiring high degrees of wear and corrosion resistance, and damage tolerance at high temperatures.  
5.2 Shear tests provide information on the strength and deformation of materials under shear stresses.  
5.3 This test method may be used for material development, material comparison, quality assurance, characterization, and design data generation.  
5.4 For quality control purposes, results derived from standardized shear test specimens may be considered indicative of the response of the material from which they were taken for given primary processing conditions and post-processing heat treatments.
SCOPE
1.1 This test method covers the determination of shear strength of continuous fiber-reinforced ceramic composites (CFCCs) at ambient temperature. The test methods addressed are (1) the compression of a double-notched test specimen to determine interlaminar shear strength, and (2) the Iosipescu test method to determine the shear strength in any one of the material planes of laminated composites. Test specimen fabrication methods, testing modes (load or displacement control), testing rates (load rate or displacement rate), data collection, and reporting procedures are addressed.  
1.2 This test method is used for testing advanced ceramic or glass matrix composites with continuous fiber reinforcement having unidirectional (1D) or bidirectional (2D) fiber architecture. This test method does not address composites with 3D fiber architecture or discontinuous fiber-reinforced, whisker-reinforced, or particulate-reinforced ceramics.  
1.3 The values stated in SI units are to be regarded as the standard and are in accordance with IEEE/ASTM SI 10.  
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. Specific hazard statements are given in 8.1 and 8.2.  
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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