Significance and Use
5.1 The property KIc determined by this test method characterizes the resistance of a material to fracture in a neutral environment in the presence of a sharp crack under essentially linear-elastic stress and severe tensile constraint, such that (1) the state of stress near the crack front approaches tritensile plane strain, and (2) the crack-tip plastic zone is small compared to the crack size, specimen thickness, and ligament ahead of the crack.
5.1.1 Variation in the value of KIc can be expected within the allowable range of specimen proportions, a/W and W/B. KIc may also be expected to rise with increasing ligament size. Notwithstanding these variations, however, KIc is believed to represent a lower limiting value of fracture toughness (for 2 % apparent crack extension) in the environment and at the speed and temperature of the test.
5.1.2 Lower values of KIc can be obtained for materials that fail by cleavage fracture; for example, ferritic steels in the ductile-to-brittle transition region or below, where the crack front length affects the measurement in a stochastic manner independent of crack front constraint. The present test method does not apply to such materials and the user is referred to Test Method E1921 and E1820. Likewise this test method does not apply to high toughness or high tearing-resistance materials whose failure is accompanied by appreciable amounts of plasticity. Guidance on testing elastic-plastic materials is given in Test Method E1820.
5.1.3 The value of KIc obtained by this test method may be used to estimate the relation between failure stress and crack size for a material in service wherein the conditions of high constraint described above would be expected. Background information concerning the basis for development of this test method in terms of linear elastic fracture mechanics may be found in Refs (1) and (2).
5.1.4 Cyclic forces can cause crack extension at KI values less than KIc. Crack extension under cyclic or sustained forces (as by stress corrosion cracking or creep crack growth) can be influenced by temperature and environment. Therefore, when KIc is applied to the design of service components, differences between laboratory test and field conditions shall be considered.
5.1.5 Plane-strain fracture toughness testing is unusual in that there can be no advance assurance that a valid K Ic will be determined in a particular test. Therefore, compliance with the specified validity criteria of this test method is essential.
5.1.6 Residual stresses can adversely affect the indicated KQ and KIc values. The effect can be especially significant for specimens removed from as-heat treated or otherwise non-stress relieved stock, from weldments, from complex wrought parts, or from parts with intentionally induced residual stresses. Indications of residual stress include distortion during specimen machining, results that are specimen configuration dependent, and irregular fatigue precrack growth (either excessive crack front curvature or out-of-plane growth). Guide B909 provides supplementary guidelines for plane strain fracture toughness testing of aluminum alloy products for which complete stress relief is not practicable. Guide B909 includes additional guidelines for recognizing when residual stresses may be significantly biasing test results, methods for minimizing the effects of residual stress during testing, and guidelines for correction and interpretation of data.
5.2 This test method can serve the following purposes:
5.2.1 In research and development, to establish in quantitative terms significant to service performance, the effects of metallurgical variables such as composition or heat treatment, or of fabricating operations such as welding or forming, on the fracture toughness of new or existing materials.
5.2.2 In service evaluation, to establish the suitability of a material for a specific application for which the stress conditions are prescribed and for which maximum flaw sizes can be established with confidence.
5.2.3 For specifications of acceptance and manufacturing quality control, but only when there is a sound basis for specifying minimum KIc values, and then only if the dimensions of the product are sufficient to provide specimens of the size required for valid KIc determination. The specification of K Ic values in relation to a particular application should signify that a fracture control study has been conducted for the component in relation to the expected loading and environment, and in relation to the sensitivity and reliability of the crack detection procedures that are to be applied prior to service and subsequently during the anticipated life.
Scope
1.1 This test method covers the determination of fracture toughness (KIc) of metallic materials under predominantly linear-elastic, plane-strain conditions using fatigue precracked specimens having a thickness of 1.6 mm (0.063 in.) or greater2 subjected to slowly, or in special (elective) cases rapidly, increasing crack-displacement force. Details of test apparatus, specimen configuration, and experimental procedure are given in the Annexes.
1.2 This test method is divided into two parts. The first part gives general recommendations and requirements for K Ic testing. The second part consists of Annexes that give specific information on displacement gage and loading fixture design, special requirements for individual specimen configurations, and detailed procedures for fatigue precracking. Additional annexes are provided that give specific procedures for beryllium and rapid-force testing.
1.3 General information and requirements common to all specimen configurations:
| Section |
Referenced Documents | 2 |
Terminology | 3 |
Stress-Intensity Factor | 3.1.1 |
Plane-Strain Fracture Toughness | 3.1.2 |
Crack Plane Orientation | 3.1.4 |
Summary of Test Method | 4 |
Significance and Use | 5 |
Significance | 5.1 |
Precautions | 5.1.1 – 5.1.5 |
Practical Applications | 5.2 |
Apparatus (see also 1.4) | 6 |
Tension Machine | 6.1 |
Fatigue Machine | 6.2 |
Loading Fixtures | 6.3 |
Displacement Gage, Measurement | 6.4 |
Specimen Size, Configurations, and Preparation (see also 1.5) | 7 |
Specimen Size Estimates | 7.1 |
Standard and Alternative Specimen Configurations | 7.2 |
Fatigue Crack Starter Notches | 7.3.1 |
Fatigue Precracking (see also 1.6) | 7.3.2 |
Crack Extension Beyond Starter Notch | 7.3.2.2 |
General Procedure | 8 |
Specimen Measurements |
|
Thickness | 8.2.1 |
Width | 8.2.2 |
Crack Size | 8.2.3 |
Crack Plane Angle | 8.2.4 |
Specimen Testing |
|
Loading Rate | 8.3 |
Test Record | 8.4 |
Calculation and Interpretation of Results | 9 |
Test Record Analysis | 9.1 |
Pm ax/PQ Validity Requirement | 9.1.3 |
Specimen Size Validity Requirements | 9.1.4 |
Reporting | 10 |
Precision and Bias | 11 |
1.4 Specific requirements related to test apparatus:
Double-Cantilever Displacement Gage | Annex A1 |
Testing Fixtures | Annex A2 |
Bend Specimen Loading Fixture | Annex A2.1 |
Compact Specimen Loading Clevis | Annex A2.2 |
1.5 Specific requirements related to individual specimen configurations:
Bend Specimen SE(B) | Annex A3 |
Compact Specimen C(T) | Annex A4 |
Disk-Shaped Compact Specimen DC(T) | Annex A5 |
Arc-Shaped Tension Specimen A(T) | Annex A6 |
Arc-Shaped Bend Specimen A(B) | Annex A7 |
1.6 Specific requirements related to special test procedures:
Fatigue Precracking KIc Specimens | Annex A8 |
Hot-Pressed Beryllium Testing | Annex A9 |
Rapid-Force Testing | Annex A10 |
1.7 The values stated in SI units are to be regarded as the standard. The values given in parentheses are for information only.
1.8 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.