SU1002890A1 - Method of determination of stress intensity critical coefficient in longitudinal shear - Google Patents

Description

(5) METHOD FOR DETERMINING CRITICAL

STRESS INTENSITY COEFFICIENT UNDER LONG SHIFT

. one

The invention relates to the study of the strength properties of the material, and in particular to methods for determining the critical stress intensity factor in the longitudinal shift

There is a method for determining the critical stress intensity factor under shear e by loading, the qi of an individual specimen with a notch Г М

The disadvantage of this method is the impossibility of determining the material properties of prismatic blanks.

The closest to the invention to the technical essence and the achieved result is a method for determining the critical stress intensity factor in the longitudinal shift by loading a prismatic specimen with a notch and a fatigue crack induced from its top.

sample with two cantilever "1 working parts 12J,

The disadvantage of this method is the low accuracy of determining the intensity coefficient of stresses associated with the deplanation of the sample, especially when testing thin-sheet composite and bimetallic materials.

The aim of the invention is to improve the accuracy of determining the critical stress intensity factor,

Claims (2)

This target is achieved in that, according to the method for determining the circular stress intensity factor under longitudinal shear by loading a prismatic specimen with a notch and a fatigue crack induced from its top, a specimen with two parallel identical central projections located symmetrically relative to the axes of symmetry of the sample and dividing the sample into two side and central working parts, install the sample with the side parts on cylindrical supports that are ayut another along its axis of symmetry, and the sample was loaded in the center of the working section perpendicular to its surface. FIG. 1 The test specimen was taken. FIG. 2 is a section A-A in FIG. one; in fig. 3 sample mounted on cylindrical supports; in fig. k - sample under loading, side view. The method is carried out as follows. Sample 1 is used with two parallel, identical central slits 2 and 3 arranged symmetrically with respect to the axis C of symmetry of sample 1 and the sample is divided into two lateral chats 5, 6 and the central working part 7 Chevron cuts 8-11 are made at the tops of the slits 2 and 3, and the guide grooves Y-17 are applied to the side surfaces 12 and 13. To secure the sample in the grips of the loading device to induce fatigue cracks (not shown; from the tops of the notches 8-11, holes 18-20 are made in the sample. Without holes 18 and 20 in the grips of the loading device and growing fatigue cracks from the tops of the notches 8 to 11. If the cracks are not of sufficient length, the sample is then fixed through holes 18 and 19 or 19 and 20 and the fatigue cracks are increased. lateral parts 5 and 6 on cylindrical supports 21 and 22, which are placed along the symmetry axis of the sample and load the sample in the center of the working section 7 by force 8904 Р through a punch 23 perpendicular to the side surface 13. In the process of loading, gram load-displacement force application point P. The loading is performed prior to the propagation of cracks in the sample and the test results determined stress intensity factor in shear. The invention makes it possible to increase the accuracy of determining the stress intensity factor during shear by eliminating the deplanation of thin-sheet specimens from homogeneous, composite and bimetallic materials. The invention of the method for determining the critical stress intensity factor for longitudinal shear by loading a prismatic sample with a notch and a fatigue crack induced from its top, characterized in that, in order to improve the determination accuracy, it is used; The sample with two parallel-shaped identical central slits located symmetrically with respect to the axis of symmetry of the sample and dividing the sample into two side and central working parts, installs the sample with lateral parts on cylindrical supports, which are placed along its other axis of symmetry, and load the sample into the center of the working part perpendicular to its surface. Sources of information taken into account in the examination 1. USSR author's certificate for the application Vf 2886713, class, 601 N 3/00, 1980. 2. Heckel K. Technical application of fracture mechanics, M., Metallurgists, 197, p. 2C (prototype). Ifffff. f fff, Y ///////////// //////// FIG. J