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ASTM C1239-00(2005)

(Practice)

Standard Practice for Reporting Uniaxial Strength Data and Estimating Weibull Distribution Parameters for Advanced Ceramics

Standard Practice for Reporting Uniaxial Strength Data and Estimating Weibull Distribution Parameters for Advanced Ceramics

SCOPE
1.1 This practice covers the evaluation and subsequent reporting of uniaxial strength data and the estimation of probability distribution parameters for advanced ceramics that fail in a brittle fashion. The failure strength of advanced ceramics is treated as a continuous random variable. Typically, a number of test specimens with well-defined geometry are failed under well-defined isothermal loading conditions. The load at which each specimen fails is recorded. The resulting failure stresses are used to obtain parameter estimates associated with the underlying population distribution. This practice is restricted to the assumption that the distribution underlying the failure strengths is the two-parameter Weibull distribution with size scaling. Furthermore, this practice is restricted to test specimens (tensile, flexural, pressurized ring, etc.) that are primarily subjected to uniaxial stress states. Section 8 outlines methods to correct for bias errors in the estimated Weibull parameters and to calculate confidence bounds on those estimates from data sets where all failures originate from a single flaw population (that is, a single failure mode). In samples where failures originate from multiple independent flaw populations (for example, competing failure modes), the methods outlined in Section 8 for bias correction and confidence bounds are not applicable.
1.2 Measurements of the strength at failure are taken for one of two reasons: either for a comparison of the relative quality of two materials, or the prediction of the probability of failure (or, alternatively, the fracture strength) for a structure of interest. This practice will permit estimates of the distribution parameters that are needed for either. In addition, this practice encourages the integration of mechanical property data and fractographic analysis.
1.3 This practice includes the following:Section Scope 1 Referenced Documents 2 Terminology 3 Summary of Practice 4 Significance and Use 5 Outlying Observations 6 Maximum Likelihood Parameter Estimators for Competing Flaw Distributions7 Unbiasing Factors and Confidence Bounds  8 Fractography 9 Examples 10 Keywords 11 Computer Algorithm MAXL X1 Test Specimens with Unidentified Fracture Origins X2
1.4 The values stated in SI units are to be regarded as the standard.

General Information

Status
Historical
Publication Date
31-May-2005
ICS
81.060.99 - Other standards related to ceramics
Technical Committee
C28 - Advanced Ceramics
Drafting Committee
C28.01 - Mechanical Properties and Performance
Current Stage
Ref Project

Relations

Replaces
ASTM C1239-00 - Standard Practice for Reporting Uniaxial Strength Data and Estimating Weibull Distribution Parameters for Advanced Ceramics
Effective Date
01-Jun-2005
Replaced By
ASTM C1239-06 - Standard Practice for Reporting Uniaxial Strength Data and Estimating Weibull Distribution Parameters for Advanced Ceramics
Effective Date
01-Jan-2006
Referred By
ASTM C1161-18(2023) - Standard Test Method for Flexural Strength of Advanced Ceramics at Ambient Temperature
Effective Date
01-Jun-2005
Referred By
ASTM C1322-15(2019) - Standard Practice for Fractography and Characterization of Fracture Origins in Advanced Ceramics
Effective Date
01-Jun-2005
Referred By
ASTM C1863-18 - Standard Test Method for Hoop Tensile Strength of Continuous Fiber-Reinforced Advanced Ceramic Composite Tubular Test Specimens at Ambient Temperature Using Direct Pressurization
Effective Date
01-Jun-2005
Referred By
ASTM C1557-20 - Standard Test Method for Tensile Strength and Young's Modulus of Fibers
Effective Date
01-Jun-2005
Referred By
ASTM C1834-16 - Standard Test Method for Determination of Slow Crack Growth Parameters of Advanced Ceramics by Constant Stress Flexural Testing (Stress Rupture) at Elevated Temperatures
Effective Date
01-Jun-2005
Referred By
ASTM C1683-10(2019) - Standard Practice for Size Scaling of Tensile Strengths Using Weibull Statistics for Advanced Ceramics
Effective Date
01-Jun-2005
Referred By
ASTM C1323-22 - Standard Test Method for Ultimate Strength of Advanced Ceramics with Diametrally Compressed C-Ring Specimens at Ambient Temperature
Effective Date
01-Jun-2005
Referred By
ASTM C1368-18 - Standard Test Method for Determination of Slow Crack Growth Parameters of Advanced Ceramics by Constant Stress Rate Strength Testing at Ambient Temperature
Effective Date
01-Jun-2005
Referred By
ASTM C1275-18 - Standard Test Method for Monotonic Tensile Behavior of Continuous Fiber-Reinforced Advanced Ceramics with Solid Rectangular Cross-Section Test Specimens at Ambient Temperature
Effective Date
01-Jun-2005
Referred By
ASTM F2393-12(2020) - Standard Specification for High-Purity Dense Magnesia Partially Stabilized Zirconia (Mg-PSZ) for Surgical Implant Applications
Effective Date
01-Jun-2005
Referred By
ASTM C1674-23 - Standard Test Method for Flexural Strength of Advanced Ceramics with Engineered Porosity (Honeycomb Cellular Channels) at Ambient Temperatures
Effective Date
01-Jun-2005
Referred By
ASTM C1899-21 - Standard Test Method for Flexural Strength of Continuous Fiber-Reinforced Advanced Ceramic Tubular Test Specimens at Ambient Temperature
Effective Date
01-Jun-2005
Referred By
ASTM C1525-18 - Standard Test Method for Determination of Thermal Shock Resistance for Advanced Ceramics by Water Quenching
Effective Date
01-Jun-2005

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ASTM C1239-00(2005) - Standard Practice for Reporting Uniaxial Strength Data and Estimating Weibull Distribution Parameters for Advanced CeramicsASTM C1239-00(2005) - Standard Practice for Reporting Uniaxial Strength Data and Estimating Weibull Distribution Parameters for Advanced Ceramics
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ASTM C1239-00(2005) - Standard Practice for Reporting Uniaxial Strength Data and Estimating Weibull Distribution Parameters for Advanced Ceramics
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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: C 1239 – 00 (Reapproved 2005)
Standard Practice for
Reporting Uniaxial Strength Data and Estimating Weibull
Distribution Parameters for Advanced Ceramics
This standard is issued under the fixed designation C1239; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision.Anumber in parentheses indicates the year of last reapproval.A
superscript epsilon (e) indicates an editorial change since the last revision or reapproval.
1. Scope
Outlying Observations 6
Maximum Likelihood Parameter Estimators for Competing 7
1.1 This practice covers the evaluation and subsequent
Flaw Distributions
reporting of uniaxial strength data and the estimation of
Unbiasing Factors and Confidence Bounds 8
Fractography 9
probability distribution parameters for advanced ceramics that
Examples 10
fail in a brittle fashion. The failure strength of advanced
Keywords 11
ceramics is treated as a continuous random variable.Typically,
ComputerAlgorithm MAXL X1
Test Specimens with Unidentified Fracture Origins X2
a number of test specimens with well-defined geometry are
failed under well-defined isothermal loading conditions. The
1.4 The values stated in SI units are to be regarded as the
load at which each specimen fails is recorded. The resulting
standard.
failure stresses are used to obtain parameter estimates associ-
2. Referenced Documents
ated with the underlying population distribution. This practice
is restricted to the assumption that the distribution underlying
2.1 ASTM Standards:
the failure strengths is the two-parameter Weibull distribution
C1145 Terminology of Advanced Ceramics
with size scaling. Furthermore, this practice is restricted to test
C1322 Practice for Fractography and Characterization of
specimens (tensile, flexural, pressurized ring, etc.) that are
Fracture Origins in Advanced Ceramics
primarily subjected to uniaxial stress states. Section 8 outlines
D4392 Terminology for Statistically Related Terms
methods to correct for bias errors in the estimated Weibull
E6 Terminology Relating to Methods of Mechanical Test-
parameters and to calculate confidence bounds on those esti-
ing
mates from data sets where all failures originate from a single
E178 Practice for Dealing With Outlying Observations
flaw population (that is, a single failure mode). In samples
E456 Terminology for Relating to Quality and Statistics
where failures originate from multiple independent flaw popu-
2.2 Military Handbook:
lations (for example, competing failure modes), the methods
MIL-HDBK-790 Fractography and Characterization of
outlinedinSection8forbiascorrectionandconfidencebounds
Fracture Origins in Advanced Structural Ceramics
are not applicable.
3. Terminology
1.2 Measurementsofthestrengthatfailurearetakenforone
of two reasons: either for a comparison of the relative quality
3.1 Proper use of the following terms and equations will
of two materials, or the prediction of the probability of failure
alleviate misunderstanding in the presentation of data and in
(or, alternatively, the fracture strength) for a structure of
the calculation of strength distribution parameters.
interest. This practice will permit estimates of the distribution
3.1.1 censored strength data—strength measurements (that
parameters that are needed for either. In addition, this practice
is, a sample) containing suspended observations such as that
encourages the integration of mechanical property data and
produced by multiple competing or concurrent flaw popula-
fractographic analysis.
tions.
1.3 This practice includes the following:
3.1.1.1 Considerasamplewherefractographyclearlyestab-
lished the existence of three concurrent flaw distributions
Section
Scope 1
(although this discussion is applicable to a sample with any
Referenced Documents 2
Terminology 3
Summary of Practice 4
Significance and Use 5
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
Standards volume information, refer to the standard’s Document Summary page on
This practice is under the jurisdiction ofASTM Committee C28 onAdvanced the ASTM website.
Ceramics and is the direct responsibility of Subcommittee C28.02 on Reliability. Withdrawn.
Current edition approved June 1, 2005. Published June 2005. Originally AvailablefromStandardizationDocumentsOrderDesk,Bldg.4SectionD,700
approved in 1993. Last previous edition approved in 2000 as C1239–00. Robbins Ave., Philadelphia, PA 19111-5094, Attn: NPODS.
Copyright ©ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA19428-2959, United States.
C 1239 – 00 (2005)
number of concurrent flaw distributions).The three concurrent the total data set reflects more than one type of strength-
flaw distributions are referred to here as distributions A, B, and controlling flaw. This term is synonymous with “mixtures of
C. Based on fractographic analyses, each specimen strength is flaw distributions.”
assigned to a flaw distribution that initiated failure. In estimat- 3.2.7 extraneous flaws—strength-controlling flaws ob-
ing parameters that characterize the strength distribution asso- servedinsomefractionoftestspecimensthatcannotbepresent
ciated with flaw distribution A, all specimens (and not just in the component being designed. An example is machining
those that failed from Type A flaws) must be incorporated in flaws in ground bend specimens that will not be present in
the analysis to ensure efficiency and accuracy of the resulting as-sintered components of the same material.
parameter estimates. The strength of a specimen that failed by 3.2.8 fractography—analysis and characterization of pat-
a Type B (or Type C) flaw is treated as a right censored terns generated on the fracture surface of a test specimen.
observation relative to the A flaw distribution. Failure due to a Fractography can be used to determine the nature and location
Type B (or Type C) flaw restricts, or censors, the information of the critical fracture origin causing catastrophic failure in an
concerning TypeAflaws in a specimen by suspending the test advanced ceramic test specimen or component.
before failure occurred by a Type A flaw (1). The strength 3.2.9 multiple flaw distributions—strengthcontrollingflaws
from the most severe Type A flaw in those specimens that observed by fractography where distinguishably different flaw
failed from Type B (or Type C) flaws is higher than (and thus types are identified as the failure initiation site within different
tothe rightof)theobservedstrength.However,noinformation specimens of the data set and where the flaw types are known
is provided regarding the magnitude of that difference. Cen- or expected to originate from independent causes.
sored data analysis techniques incorporated in this practice 3.2.9.1 Discussion—An example of multiple flaw distribu-
utilize this incomplete information to provide efficient and tions would be carbon inclusions and large voids which may
relatively unbiased estimates of the distribution parameters. both have been observed as strength controlling flaws within a
data set and where there is no reason to believe that the
3.2 Definitions:
frequency or distribution of carbon inclusions created during
3.2.1 competing failure modes—distinguishably different
fabrication was in any way dependent on the frequency or
types of fracture initiation events that result from concurrent
distribution of voids (or vice-versa).
(competing) flaw distributions.
3.2.10 population—totality of potential observations about
3.2.2 compound flaw distributions—any form of multiple
which inferences are made.
flaw distribution that is neither pure concurrent nor pure
3.2.11 population mean—average of all potential measure-
exclusive.Asimpleexampleiswhereeveryspecimencontains
mentsinagivenpopulationweightedbytheirrelativefrequen-
the flaw distribution A, while some fraction of the specimens
cies in the population.
also contains a second independent flaw distribution B.
3.2.12 probability density function—function f (x)isa
3.2.3 concurrent flaw distributions—type of multiple flaw
probabilitydensityfunctionforthecontinuousrandomvariable
distribution in a homogeneous material where every specimen
X if:
of that material contains representative flaws from each inde-
pendent flaw population. Within a given specimen, all flaw
f ~x!$0
populations are then present concurrently and are competing (1)
with each other to causefailure.Thistermissynonymouswith
and
“competing flaw distributions.”
`
3.2.4 effective gage section—that portion of the test speci- f ~ x! dx 51 (2)
*
2`
men geometry that has been included within the limits of
integration (volume, area, or edge length) of the Weibull
The probability that the random variable X assumes a value
distribution function. In tensile specimens, the integration may
between a and b is given by the following equation:
be restricted to the uniformly stressed central gage section, or
b
it may be extended to include transition and shank regions.
Pr~a , X , b! 5 f~x! dx
*
a
3.2.5 estimator—well-defined function that is dependent on
(3)
the observations in a sample. The resulting value for a given
sample may be an estimate of a distribution parameter (a point
3.2.13 sample—collectionofmeasurementsorobservations
estimate) associated with the underlying population.The arith-
taken from a specified population.
metic average of a sample is, for example, an estimator of the
3.2.14 skewness—term relating to the asymmetry of a
distribution mean.
probability density function. The distribution of failure
3.2.6 exclusive flaw distributions—type of multiple flaw
strength for advanced ceramics is not symmetric with respect
distribution created by mixing and randomizing specimens
to the maximum value of the distribution function but has one
from two or more versions of a material where each version
tail longer than the other.
contains a different single flaw population. Thus, each speci-
3.2.15 statistical bias—inherent to most estimates, this is a
men contains flaws exclusively from a single distribution, but
typeofconsistentnumericaloffsetinanestimaterelativetothe
trueunderlyingvalue.Themagnitudeofthebiaserrortypically
decreases as the sample size increases.
3.2.16 unbiased estimator—estimator that has been cor-
Theboldfacenumbersinparenthesesrefertothelistofreferencesattheendof
this practice. rected for statistical bias error.
C 1239 – 00 (2005)
3.2.17 Weibull distribution—continuous random variable X material scale parameter can be described as the Weibull
has a two-parameter Weibull distribution if the probability characteristic strength of a specimen with unit volume or area
density function is given by the following equations: loaded in uniform uniaxial tension. The Weibull material scale
1/m
parameter has units of stress·(volume) and should be re-
m21 m
m x x
3/m 3/m
f~x!5 exp — x.0 (4)
S DS D F S D G
ported using units of MPa·(m) or GPa·(m) if the
b b b
strength-controlling flaws are distributed through the volume
of the material. If the strength-controlling flaws are restricted
f~x!50 x#0 (5)
to the surface of the specimens in a sample, then the Weibull
and the cumulative distribution function is given by the
material scale parameter should be reported using units of
2/m
following equations: 2/m
MPa·(m) orGPa·(m) .Foragivenspecimengeometry,Eq
m
x
8 and Eq 10 can be equated, which yields an expression
F~x!51 2 exp 2 x .0 (6)
F S D G
b
relating s and s . Further discussion related to this issue can
0 u
be found in 7.6.
or
3.3 Fordefinitionsofotherstatisticalterms,termsrelatedto
F~x!50 x#0 (7)
mechanical testing, and terms related to advanced ceramics
used in this practice, refer to Terminologies D4392, E456,
where
m = Weibull modulus (or the shape parameter) (>0), and
C1145,andE6ortoappropriatetextbooksonstatistics(2345)
b = scale parameter (>0).
.
3.2.18 The random variable representing uniaxial tensile
3.4 Symbols:
strength of an advanced ceramic will assume only positive
values, and the distribution is asymmetrical about the mean.
A = specimen area (or area of effective gage section, if
Thesecharacteristicsruleouttheuseofthenormaldistribution
used).
(as well as others) and point to the use of the Weibull and
b = gage section dimension, base of bend test specimen.
similar skewed distributions. If the random variable represent-
d = gage section dimension, depth of bend test speci-
ing uniaxial tensile strength of an advanced ceramic is char-
men.
acterized by Eq 4-7, then the probability that this advanced
F(x) = cumulative distribution function.
ceramic will fail under an applied uniaxial tensile stress s is
f(x) = probability density function.
given by the cumulative distribution function as follows:
L = length of the inner load span for a bend test
i
s
specimen.
m
P 51– exp — s.0 (8)
F S D G
f
s
u L = length of the outer load span for a bend test
o
specimen.
P 50 s#0 (9) + = likelihood function.
f
m = Weibull modulus.
where:
mˆ = estimate of the Weibull modulus.
P = probability of failure, and
f mˆ = unbiased estimate of the Weibull modulus.
U
s = Weibull characteristic strength.
u N = number of specimens in a sample.
Note that theWeibull characteristic strength is dependent on
P = probability of failure.
f
theuniaxialtestspecimen(tensile,flexural,orpressurizedring) r = number of specimens that failed from the flaw
and will change with specimen size and geometry. In addition, population for which the Weibull estimators are
the Weibull characteristic strength has units of stress and being calculated.
t = intermediate quantity defined by Eq 27, used in
should be reported using units of megapascals or gigapascals.
3.2.19 An alternative expression for the probability of calculation of confidence bounds.
V = specimen volume (or volume of effective gage
failure is given by the following equation:
section, if used).
s
m
X = random variable.
P 51– exp — dV s.0 (10)
f F *S D G
s
v
x = realization of a random variable X.
b = Weibull scale parameter.
P 50 s#0(11)
f
e = stopping tolerance in the computer algorithm
The integration in the exponential is performed over all MAXL.
tensile regions of the specimen volume if the strength- µˆ = estimate of mean strength.
s = uniaxial tensile stress.
controlling flaws are randomly distributed through the volume
s = maximum stress in the ith test specimen at failure.
of the material, or over all tensile regions of the specimen area
i
s = maximum stress in the jth test specimen at failure.
j
if flaws are restricted to the specimen surface. The integration
s = Weibull material scale parameter (strength relative
O
is sometimes carried out over an effective gage section i
...

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5.2 This test method determines the specific surface area of advanced ceramic powders and porous bodies. Both suppliers and users of advanced ceramics can use knowledge of the surface area of these ceramics for material development and comparison, product characterization, design data, quality control, and engineering/ production specifications.
SCOPE
1.1 This test method covers the determination of the surface area of advanced ceramic materials (in a solid form) based on multilayer physisorption of gas in accordance with the method of Brunauer, Emmett, and Teller (BET) (1)2 and based on IUPAC Recommendations (1984 and 1994) (2, 3). This test method specifies general procedures that are applicable to many commercial physical adsorption instruments. This test method provides specific sample outgassing procedures for selected common ceramic materials, including: amorphous and crystalline silicas, TiO2, kaolin, silicon nitride, silicon carbide, zirconium oxide, etc. The multipoint BET (1) equation along with the single-point approximation of the BET equation are the basis for all calculations. This test method is appropriate for measuring surface areas of advanced ceramic powders down to at least 0.05 m2 (if in addition to nitrogen, krypton at 77.35 K is utilized as an adsorptive).  
1.2 This test method does not include all existing procedures appropriate for outgassing of advanced ceramic materials. However, it provides a comprehensive summary of procedures recommended in the literature for selected types of ceramic materials. The investigator shall determine the appropriateness of listed procedures.  
1.3 The values stated in SI units are to be regarded as standard. State all numerical values in terms of SI units unless specific instrumentation software reports surface area using alternate units. In this case, provide both reported and equivalent SI units in the final written report. It is commonly accepted and customary (in physical adsorption and related fields) to report the (specific) surface area of solids as m2/g and, as a convention, many instruments (as well as certificates of reference materials) report surface area as m2 g–1, instead of using SI units (m2 kg–1).  
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 C1273-18(Test Method)
Standard Test Method for Tensile Strength of Monolithic Advanced Ceramics at Ambient Temperatures

SIGNIFICANCE AND USE
4.1 This test method may be used for material development, material comparison, quality assurance, characterization, and design data generation.  
4.2 High-strength, monolithic advanced ceramic materials generally characterized by small grain sizes (  
4.3 Although the volume or surface area of material subjected to a uniform tensile stress for a single uniaxially loaded tensile test may be several times that of a single flexure test specimen, the need to test a statistically significant number of tensile test specimens is not obviated. Therefore, 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. Note that size-scaling effects as discussed in Practice C1239 will affect the strength values. Therefore, strengths obtained using different recommended tensile test specimens with different volumes or surface areas of material in the gage sections will be different due to these size differences. Resulting strength values can be scaled to an effective volume or surface area of unity as discussed in Practice C1239.  
4.4 Tensile tests provide information on the strength and deformation of materials under uniaxial tensile stresses. Uniform stress states are required to effectively evaluate any nonlinear stress-strain behavior which may develop as the result of testing mode, testing rate, processing or alloying effects, or environmental influences. These effects may be consequences of stress corrosion or subcritical (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 test specimens fabricated to standardized dimensions from a particular material or selected portions, or both, of a part may not totally represent the strength and deforma...
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1.1 This test method covers the determination of tensile strength under uniaxial loading of monolithic advanced ceramics at ambient temperatures. This test method addresses, but is not restricted to, various suggested test specimen geometries as listed in the appendixes. 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. Note that 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 that 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 practice to these materials is not recommended.  
1.3 Values expressed in this test method are in accordance with the International System of Units (SI) and 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 precautionary statements are given in Section 7.  
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, Guid...

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ASTM C1239-13(2018)(Practice)
Standard Practice for Reporting Uniaxial Strength Data and Estimating Weibull Distribution Parameters for Advanced Ceramics

SIGNIFICANCE AND USE
5.1 Advanced ceramics usually display a linear stress-strain behavior to failure. Lack of ductility combined with flaws that have various sizes and orientations leads to scatter in failure strength. Strength is not a deterministic property, but instead reflects an intrinsic fracture toughness and a distribution (size and orientation) of flaws present in the material. This practice is applicable to brittle monolithic ceramics that fail as a result of catastrophic propagation of flaws present in the material. This practice is also applicable to composite ceramics that do not exhibit any appreciable bilinear or nonlinear deformation behavior. In addition, the composite must contain a sufficient quantity of uniformly distributed reinforcements such that the material is effectively homogeneous. Whisker-toughened ceramic composites may be representative of this type of material.  
5.2 Two- and three-parameter formulations exist for the Weibull distribution. This practice is restricted to the two-parameter formulation. An objective of this practice is to obtain point estimates of the unknown parameters by using well-defined functions that incorporate the failure data. These functions are referred to as “estimators.” It is desirable that an estimator be consistent and efficient. In addition, the estimator should produce unique, unbiased estimates of the distribution parameters (6). Different types of estimators exist, including moment estimators, least-squares estimators, and maximum likelihood estimators. This practice details the use of maximum likelihood estimators due to the efficiency and the ease of application when censored failure populations are encountered.  
5.3 Tensile and flexural test specimens are the most commonly used test configurations for advanced ceramics. The observed strength values are dependent on test specimen size and geometry. Parameter estimates can be computed for a given test specimen geometry ( m^, ^σθ), but it is suggested that the paramet...
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1.1 This practice covers the evaluation and reporting of uniaxial strength data and the estimation of Weibull probability distribution parameters for advanced ceramics that fail in a brittle fashion (see Fig. 1). The estimated Weibull distribution parameters are used for statistical comparison of the relative quality of two or more test data sets and for the prediction of the probability of failure (or, alternatively, the fracture strength) for a structure of interest. In addition, this practice encourages the integration of mechanical property data and fractographic analysis.  
1.6 The values stated in SI units are to be regarded as the standard per IEEE/ASTM SI 10.  
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 C1291-18(Test Method)
Standard Test Method for Elevated Temperature Tensile Creep Strain, Creep Strain Rate, and Creep Time to Failure for Monolithic Advanced Ceramics

SIGNIFICANCE AND USE
4.1 Creep tests measure the time-dependent deformation under force at a given temperature, and, by implication, the force-carrying capability of the material for limited deformations. Creep rupture tests, properly interpreted, provide a measure of the force-carrying capability of the material as a function of time and temperature. The two tests complement each other in defining the force-carrying capability of a material for a given period of time. In selecting materials and designing parts for service at elevated temperatures, the type of test data used will depend on the criteria for force-carrying capability that best defines the service usefulness of the material.  
4.2 This test method may be used for material development, quality assurance, characterization, and design data generation.  
4.3 High-strength, monolithic ceramic materials, generally characterized by small grain sizes (  
4.4 Data obtained for design and predictive purposes shall be obtained using any appropriate combination of test methods that provide the most relevant information for the applications being considered. It is noted here that ceramic materials tend to creep more rapidly in tension than in compression (1-3).4 This difference results in time-dependent changes in the stress distribution and the position of the neutral axis when tests are conducted in flexure. As a consequence, deconvolution of flexural creep data to obtain the constitutive equations needed for design cannot be achieved without some degree of uncertainty concerning the form of the creep equations, and the magnitude of the creep rate in tension vis-a-vis the creep rate in compression. Therefore, creep data for design and life prediction shall be obtained in both tension and compression, as well as the expected service stress state.
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1.1 This test method covers the determination of tensile creep strain, creep strain rate, and creep time to failure for advanced monolithic ceramics at elevated temperatures, typically between 1073 and 2073 K. A variety of test specimen geometries are included. The creep strain at a fixed temperature is evaluated from direct measurements of the gage length extension over the time of the test. The minimum creep strain rate, which may be invariant with time, is evaluated as a function of temperature and applied stress. Creep time to failure is also included in this test method.  
1.2 This test method is for use with advanced ceramics that behave as macroscopically isotropic, homogeneous, continuous materials. While this test method is intended for use on monolithic ceramics, whisker- or particle-reinforced composite ceramics as well as low-volume-fraction discontinuous fiber-reinforced composite ceramics may also meet these macroscopic behavior assumptions. Continuous fiber-reinforced ceramic composites (CFCCs) do not behave as macroscopically isotropic, homogeneous, continuous materials, and application of this test method to these materials is not recommended.  
1.3 The values in SI units are to be regarded as the standard (see IEEE/ASTM SI 10). The values given in parentheses are mathematical conversions to inch-pound units that 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 issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM C1275-18(Test Method)
Standard Test Method for Monotonic Tensile Behavior of Continuous Fiber-Reinforced Advanced Ceramics with Solid Rectangular Cross-Section Test Specimens at Ambient Temperature

SIGNIFICANCE AND USE
4.1 This test method may be used for material development, material comparison, quality assurance, characterization, and design data generation.  
4.2 Continuous fiber-reinforced ceramic matrix composites generally characterized by fine grain-sized (  
4.3 Unlike monolithic advanced ceramics which fracture catastrophically from a single dominant flaw, CFCCs generally experience “graceful” fracture from a cumulative damage process. Therefore, the volume of material subjected to a uniform tensile stress for a single uniaxially loaded tensile test may not be as significant a factor in determining the ultimate strengths of CFCCs. However, the need to test a statistically significant number of tensile test specimens is not obviated. Therefore, because of the probabilistic nature of the strength distributions of the brittle matrices of CFCCs, a sufficient number of test specimens at each testing condition is required for statistical analysis and design. Studies to determine the exact influence of test specimen volume on strength distributions for CFCCs have not been completed. It should be noted that tensile strengths obtained using different recommended tensile specimens with different volumes of material in the gage sections may be different due to these volume differences.  
4.4 Tensile tests provide information on the strength and deformation of materials under uniaxial tensile stresses. Uniform stress states are required to effectively evaluate any nonlinear stress-strain behavior which may develop as the result of cumulative damage processes (for example, matrix cracking, matrix/fiber debonding, fiber fracture, delamination, etc.) which may be influenced by testing mode, testing rate, processing or alloying effects, or environmental influences. Some of these effects may be consequences of stress corrosion or subcritical (slow) crack growth that can be minimized by testing at sufficiently rapid rates as outlined in this test method.  
4.5 The results of tensile t...
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1.1 This test method covers the determination of tensile behavior including tensile strength and stress-strain response under monotonic uniaxial loading of continuous fiber-reinforced advanced ceramics at ambient temperature. 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. Note that tensile strength as used in this test method refers to the tensile strength obtained under monotonic uniaxial loading where monotonic refers to a continuous nonstop test rate with no reversals from test initiation to final fracture.  
1.2 This test method applies primarily to all advanced ceramic matrix composites with continuous fiber reinforcement: unidirectional (1D), bidirectional (2D), and tridirectional (3D). In addition, this test method may also be used with glass (amorphous) matrix composites with 1D, 2D, and 3D continuous fiber reinforcement. This test method does not directly address discontinuous fiber-reinforced, whisker-reinforced, or particulate-reinforced ceramics, although the test methods detailed here may be equally applicable to these composites.  
1.3 Values expressed in this test method are in accordance with the International System of Units (SI) and 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 Section 7 and 8.2.5.2.  
1.5 This international standard was developed in accordance...

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ASTM
ASTM C1337-17(Test Method)
Standard Test Method for Creep and Creep Rupture of Continuous Fiber-Reinforced Advanced Ceramics Under Tensile Loading at Elevated Temperatures

SIGNIFICANCE AND USE
4.1 This test method may be used for material development, material comparison, quality assurance, characterization, and design data generation.  
4.2 Continuous fiber-reinforced ceramic matrix composites are candidate materials for structural applications requiring high degrees of wear and corrosion resistance and toughness at high temperatures.  
4.3 Creep tests measure the time-dependent deformation of a material under constant load at a given temperature. Creep rupture tests provide a measure of the life of the material when subjected to constant mechanical loading at elevated temperatures. In selecting materials and designing parts for service at elevated temperatures, the type of test data used will depend on the criteria for load-carrying capability which best defines the service usefulness of the material.  
4.4 Creep and creep rupture tests provide information on the time-dependent deformation and on the time-of-failure of materials subjected to uniaxial tensile stresses at elevated temperatures. Uniform stress states are required to effectively evaluate any nonlinear stress-strain behavior which may develop as the result of cumulative damage processes (for example, matrix cracking, matrix/fiber debonding, fiber fracture, delamination, etc.) which may be influenced by test mode, test rate, processing or alloying effects, environmental influences, or elevated temperatures. Some of these effects may be consequences of stress corrosion or subcritical (slow) crack growth. It is noted that ceramic materials typically creep more rapidly in tension than in compression. Therefore, creep data for design and life prediction should be obtained in both tension and compression.  
4.5 The results of tensile creep and tensile creep rupture tests of specimens fabricated to standardized dimensions from a particular material or selected portions of a part, or both, may not totally represent the creep deformation and creep rupture properties of the entire, full-size end p...
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1.1 This test method covers the determination of the time-dependent deformation and time-to-rupture of continuous fiber-reinforced ceramic composites under constant tensile loading at elevated temperatures. This test method addresses, but is not restricted to, various suggested test specimen geometries. In addition, test specimen fabrication methods, allowable bending, temperature measurements, temperature control, data collection, and reporting procedures are addressed.  
1.2 This test method is intended primarily for use with all advanced ceramic matrix composites with continuous fiber reinforcement: unidirectional (1-D), bidirectional (2-D), and tridirectional (3-D). In addition, this test method may also be used with glass matrix composites with 1-D, 2-D, and 3-D continuous fiber reinforcement. This test method does not address directly discontinuous fiber-reinforced, whisker-reinforced, or particulate-reinforced ceramics, although the test methods detailed here may be equally applicable to these composites.  
1.3 Values expressed in this test method are in accordance with the International System of Units (SI) and 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 and health practices and determine the applicability of regulatory limitations prior to use. Hazard statements are noted in 7.1 and 7.2.

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ASTM
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...
SCOPE
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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