SU1714425A2 - Method for determining bending rigidity of flexible samples - Google Patents

Abstract

The invention relates to a testing technique and can be used in determining the flexural rigidity of flexible specimens. The purpose of the invention is to increase the reliability of the tests. A twisted flexible specimen is loaded with a tensile force and is placed on a supporting surface of a given curvature, made in the form of biaxisymmetric sections arranged with a gap. The sample is bent at these sites until the arc length of the sample bend in each section is not equal to or equal to an odd number of half the striding step of the sample, and the deflection and radius of curvature in the gap between the sections are determined. Then, in the same way, the sample is loaded until - until the arc length of the sample bend at each site becomes a multiple of an even number of half of the lay of the twist pitch, and the deflection and radius of curvature are determined. From the measured values, the bending stiffness is determined. The implementation of sequential bending with an arc length that is a multiple of an even and odd number of half-steps of the sample lay-up ensures the determination of the minimum and maximum values of flexural rigidity when testing twisted flexible samples, which provides increased reliability. 2 Il.

Description

The invention relates to a testing technique, and specifically to methods for determining the flexural rigidity of flexible specimens, and is an improvement of the invention according to the author. St. N 1196726.

The purpose of the invention is to increase the reliability of tests by determining the limits of bending stiffness of twisted flexible specimens.

FIG. Figure 1 shows the test pattern of the sample at the arc length of the bend of the symmetric sections of the support surface, multiple to an odd number of half-steps of the sample; in fig. 2 - the same, on the length of the arc of bending of the axisymmetric sections of the reference

the surface is a multiple of the even number of half-steps of the pattern.

The method is carried out as follows.

The twisted flexible sample 1 is loaded with a tensile force T, then placed on a supporting surface of a given curvature, made in the form of two axisymmetric sections 2 arranged with a gap, and the sample 1 is bent in these areas until the bending arc length of sample 1 on each Of the sections 2, the deflection YO and the radius / 00 of the curvature of sample 1 in the gap between sections 2, the values of which determine the amount of flexural rigidity, are known. After this, sample 1 is bent until the length of the arc of bending of sample 1 at each study area 2 becomes equal to or a multiple of an even half the stride step of sample 1. In this position, the deflection Yp and the radius of curvature of sample 1 are measured respectively in the gap between sections 2, the values of which also determine the value of the flexural rigidity by known dependencies.

When a twisted sample 1 bends on a supporting surface, its resistance to bending depends on the ratio of the length Lo of the arc of the bend to the pitch H of the twist. If, 5 N, then half of the screw elements, located on the convex side of sample 1, is stretched, and the other half, located on the concave side of sample 1, is compressed. In this case, the stretching of element 3 of sample 1 and the compression of element 4 reach maximum values, which ensures maximum resistance to bending, i.e., maximum rigidity of sample 1. The same happens if any odd number of half-steps of the strand is placed in sections 2 of the bearing surface, t . e., 5Nit.d.

If the length of the arc 1 bend is equal to or the length of the whole stride, i.e., then each of the elements at the half of the stride pitch is in the stretch zone, and in the second half - in the contraction zone, by which compensation of the strains and contractions is achieved. each element 3 and 4. In this case there is no additional resistance to stretching or compressing

when bending sample 1, therefore bending stiffness is minimal with a given tension, the same thing happens with, and so on, i.e. with any other even number of half-steps of the pattern;

Thus, sequential bending of the sample with a bending arc length multiple to odd and even Islam of the half-steps of the sample lay-up provides for determining the maximum and minimum values of flexural rigidity, which allows to increase the reliability of the Flexural rigidity, which allows to increase the accuracy of the Flexural rigidity when testing twisted flexible samples.

Claims (1)

The invention The method for determining the flexural rigidity of flexible samples according to ed. St. N; 1196726, about tl and tea u and so that, in order to increase the reliability of the tests by determining the limits of change in the flexural rigidity of twisted flexible samples, Sample bending on axisymmetric areas of the support surface is performed successively over a bending arc length that is a multiple of an odd, and then an even number of half-steps of the sample. Fig.T fsh.2