Значение и использование

Fracture toughness, K_Ic, is a measure of the resistance to crack extension in a brittle material. These test methods may be used for material development, material comparison, quality assessment, and characterization.

The pb and the vb fracture toughness values provide information on the fracture resistance of advanced ceramics containing large sharp cracks, while the sc fracture toughness value provides this information for small cracks comparable in size to natural fracture sources. Cracks of different sizes may be used for the sc method. If the fracture toughness values vary as a function of the crack size it can be expected that K_Isc will differ from K_Ipb and K_Ivb.

Область применения

1.1 These test methods cover the fracture toughness, K_Ic, determination of advanced ceramics at ambient temperature. The methods determine K_Ipb (precracked beam test specimen), K_Isc (surface crack in flexure), and K_Ivb (chevron-notched beam test specimen). The fracture toughness values are determined using beam test specimens with a sharp crack. The crack is either a straight-through crack formed via bridge flexure (pb), or a semi-elliptical surface crack formed via Knoop indentation (sc), or it is formed and propagated in a chevron notch (vb), as shown in Fig. 1.

Note 1—The terms bend(ing) and flexure are synonymous in these test methods.

1.2 These test methods are applicable to materials with either flat or with rising R-curves. Differences in test procedure and analysis may cause the values from each test method to be different. For many materials, such as the silicon nitride Standard Reference Material 2100, the three methods give identical results at room temperature in ambient air.

1.3 The fracture toughness values for a material can be functions of environment, test rate and temperature. These test methods give fracture toughness values for specific conditions of environment, test rate and temperature.

1.4 These test methods are intended primarily for use with advanced ceramics which are macroscopically homogeneous. Certain whisker- or particle-reinforced ceramics may also meet the macroscopic behavior assumptions. Single crystals may also be tested.

1.5 This standard begins with a main body that provides information on fracture toughness testing in general. It is followed by annexes and appendices with specific information for the particular test methods.

Main BodySection Scope1 Referenced Documents2 Terminology (including definitions, orientation and symbols)3 Summary of Test Methods4 Significance and Use5 Interferences6 Apparatus7 Test Specimen Configurations, Dimensions and Preparations8 General Procedures9 Report (including reporting tables)11 Precision and Bias12 Keywords13 Summary of Changes Annexes Test Fixture GeometriesA1 Procedures and Special Requirements for Precracked Beam MethodA2 Procedures and Special Requirements for Surface Crack in Flexure MethodA3 Procedures and Special Requirements for Chevron Notch Flexure MethodA4 Appendices Precrack Characterization, Surface Crack in Flexure MethodX1 Complications in Interpreting Surface Crack in Flexure PrecracksX2 Alternative Precracking Procedure, Surface Crack in Flexure MethodX3 Chamfer Correction Factors, Surface Crack in Flexure Method OnlyX4 Crack OrientationX5

1.6 Values expressed in these test methods are in accordance with the International System of Units (SI) and Practice E 380.

1.7 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.

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.

Note—The figures on the right show the test specimen cross sections and crack types. Four-point loading may be used with all three methods. Three-point may be used with the pb and vb specimens.

FIG. 1 The Three Test Methods