SU1631255A1 - Method of determining absolute specimen deformation - Google Patents

Abstract

The invention relates to methods for measuring movement with a mechanical recording of a measured parameter and can be used to measure the absolute deformation of specimens at the moment of rupture. The purpose of the invention is to expand the range when determining the absolute deformation at the moment of rupture of a flat sample 3 of an elastic material. This is achieved by combining, before loading, the tape-shaped information carrier 5 and the surface of sample 3, whose length exceeds the length of the sample at the moment of rupture. To do this, before loading, one end of the tape is fixed in the first section of the sample, in the second section of the sample, the tape is passed between the surface of the sample and the spring-loaded guide 8 and pulled, and the writing element 7 is mounted on the sample with the possibility of interaction with the surface of the tape. When the specimen is ruptured, the elastic cord 9 removes the writing element from the spring-loaded guide 8, since the sample 3 does not retain its rectilinear shape anymore caused by its tension. The use of an information carrier in the form of a tape of unlimited length makes it possible to measure any absolute deformations which, for rubber-like materials, can many times exceed the length of the sample between the first and second sections. 4 il. t 1C o soy o er 5-1

Description

The invention relates to methods for measuring movement with a mechanical recording of a measured parameter and can be used to measure the absolute deformation of specimens at the moment of rupture.

The purpose of the invention is to expand the range when determining the absolute deformation at the time of rupture of a flat sample of elastic material.

This goal is achieved by combining the information carrier made in the form of a flexible tape with the sample surface, the length of which exceeds the sample length at the moment of rupture, for which one end of the tape is fixed in the first cross section, and in the second cross section of the sample spring guide and pull it, and the writing element is installed on the sample with the ability to interact with the surface of the tape.

Figure 1 presents a device that implements the method, a general view; figure 2 - the test sample, side view; in FIG. 3, view A in FIG. one; figure 4 - view B in figure 1.

The method is carried out as follows.

In the grippers 1 and 2 of the bursting machine, the ends of the sample 3 of the elastic material under investigation are secured and prestressing of the sample 3 is created. the length of which exceeds the length of the sample 3 at the moment of rupture, and the clamp 6 for fastening the writing element 7. The information carrier 5 is passed in the second section between the surface of the sample 3 and the spring-loaded guide 3 fixed on the grip 2 of the bursting machine, and tighten it to fit snugly to the surface of sample 3. The recording element 7 is placed in such a position that it interacts with the surface of the information carrier tape 5 and is connected with an elastic cord 9 with a bracket 10 fixed on the grip 2 explosive machine.

Before loading the sample 3, the writing element 7 is moved along the surface of the information carrier 5 in the direction perpendicular to the direction of extension of the sample 3, in order to get a reference point.

When loading the sample 3, the gripper 2 moves, causing a slightly smaller movement of the clamp 6 together with the elastic cord 9. At the same time, the cord 9 pulls up, and the sample 3 slightly shifts in the direction of the cord 9, forming a break on the original linear the longitudinal centerline of sample 3. However, this displacement of clamp 6 disrupts the interaction of the writing element 7 with the surface of the information carrier 5, since this element is spring-loaded and can extend out of the slot in clamp 6.

When the sample breaks, the 3 tensioned elastic cord 9 removes the clamp 6 with the writing element 7 fixed in it from

5 of the information carrier 5, since the sample 3 no longer retains its rectilinear form, and the recording of the deformation is stopped. The absolute strains of specimen 3 are determined from the length of the information obtained on the carrier 5 of the line drawn by the writing element 7.

The use of an information carrier in the form of a tape of unlimited length makes it possible to measure any absolute deformations, which for rubber-like materials can be many times greater than the length of the sample between the first and second sections. Therefore, the proposed method, extending the measurement range

0 absolute deformations, makes it possible to more accurately determine the absolute deformation at the moment of fracture of materials with low elastic moduli and large relative elongations

Claims (1)

5 at stretching, and, consequently, increase the reliability of structural elements made of such materials. The invention The method for determining the absolute deformation of a sample, which consists in fixing the sample in the grippers, connects one section of the sample with the information carrier, and the other with the writing element, loads the sample along the length of the sample. 5 lines on the information carrier determine the absolute deformation of the sample, characterized in that, in order to expand the range when determining the magnitude of the absolute deformation at the moment of rupture of the flat sample of elastic material, before loading in the first section, the plane of the sample and one end of the information carrier made in the form of a flexible tape with a length exceeding the length of the sample at the moment of rupture, and in the second section pass the tape between the surface of the sample and the spring-loaded guide and pull it, and writing The element is mounted on the sample with the possibility of interaction with the surface of the tape. / Type A 2 Fig.Z Buff 6 FIG L