RU2505795C1 - Specimen impact test bench - Google Patents

Abstract

FIELD: test equipment.

SUBSTANCE: test bench includes a base, a guide tube fixed on the base and having two parallel vertical sections connected in lower part to each other by means of an elbow, a ball striker arranged in the first tube section, grips for arrangement of a specimen on ends, which are located in the second tube section. In addition, the test bench is equipped with an inertia weight and a movement sensor of the inertia weight along the guide tube; grips are made in the form of two membranes fixed on the tube. One of the membranes is designed for interaction with the striker, and the second membrane is designed for interaction with the inertia weight.

EFFECT: enlarging the scope of information at investigation of material properties.

1 dwg

Description

The invention relates to testing equipment, to strength tests.

A known bench for impact testing of samples (RF patent No. 1355884 class G01M 7/08, 1987), containing a base, a guide tube fixed to the base, made with two parallel vertical sections connected at the bottom by a knee, a ball impactor in the first pipe section, grippers for placement at the ends of the sample, placed in the second pipe section.

The disadvantage of the stand is that it is not feasible to study the absorption of energy of inelastic deformation by the material of the sample.

A known bench for impact testing of samples (RF patent No. 1647327, class G01M 7/08, 1991), containing a base, a guide tube fixed to the base, made with two parallel vertical sections connected at the bottom by a knee, a ball impactor in the first pipe section, grippers for placement at the ends of the sample, placed in the second pipe section.

The disadvantage of the stand also lies in the fact that it is not feasible to study the absorption of energy of inelastic deformation by the material of the sample.

A known stand for impact testing of samples (RF patent No. 2379652, class G01N 3/34, 2010), containing a base, a guide tube fixed to the base, made with two parallel vertical sections connected at the bottom by a knee, a ball impactor in the first pipe section, grippers for placement at the ends of the sample, placed in the second pipe section.

The disadvantage of the stand also lies in the fact that it is not feasible to study the absorption of energy of inelastic deformation by the material of the sample. This limits the amount of information when studying the properties of materials.

The technical result of the invention is to expand the amount of information in the study of the properties of materials.

The technical result is achieved by the fact that the stand for impact testing of samples, containing a base, a guide tube fixed to the base, made with two parallel vertical sections connected at the bottom by a knee, a ball hammer located in the first pipe section, grips for placement at the ends the sample placed in the second pipe section, according to the invention, it is equipped with an inertial load and an inertial load displacement sensor along the guide pipe, the grippers are made in the form of two embran mounted on the pipe, with one of the membranes is intended to interact with the striker, and the second membrane is designed to interact with the inertial load.

Figure 1 shows the proposed stand.

The stand for impact testing of samples contains a base 1, a guide tube fixed to the base, made with two parallel vertical sections 2, 3, connected at the bottom by a knee 4, a ball impactor 5, located in the first pipe section 2, grippers 6.7 for placement at the ends of the sample 8, placed in the second section 3 of the pipe.

The stand is equipped with an inertial load 9 and a sensor 10 for moving the inertial load along the guide pipe. Grips 6,7 are made in the form of two membranes mounted on the pipe 3. One of the membranes 6 is designed to interact with the hammer 5, and the second membrane 7 is designed to interact with the inertial load 9.

The latch 11 is designed to hold the striker 5 in its original position. The sensor 10 has a typical design.

The stand works as follows.

The striker 5 is released by the latch 11. When the striker 5 is dropped, it strikes the membrane 6, sample 8, membrane 7 and inertial load 9. The load 9 moves along the pipe 3, which is fixed by the sensor 10. The energy of the dumped load is spent on elastic deformation of the membranes 6 and 7 , elastic and inelastic deformation of the sample 8 and the movement of the load 9. The costs of deformation of the membranes and the movement of the load are determined by calibration or calculation. The difference between the supplied energy and the cost of the deformation of the membranes with the movement of the load is spent on inelastic deformation of the sample. All things being equal, the lower the load 9 rises, the greater the energy absorbed by the sample for inelastic deformation.

The proposed stand allows for new studies to determine the energy absorption of inelastic deformation by the material of the sample. This expands the amount of information in the study of the properties of materials.

Claims (1)

Stand for impact testing of samples, containing a base, a guide tube fixed to the base, made with two parallel vertical sections connected by a knee in the lower part, a ball striker placed in the first pipe section, grippers for placement on the ends of the sample, placed in the second section pipe, characterized in that it is equipped with an inertial load and a sensor for moving the inertial load along the guide pipe, the grippers are made in the form of two membranes mounted on the pipe, while one of the membranes is designed to interact with the hammer, and the second membrane is designed to interact with the inertial load.