SU1538093A2 - Arrangement for testing specimen of sheet material in two-axial loading - Google Patents

Abstract

This invention relates to a testing technique. The aim of the invention is to improve the accuracy of testing by eliminating the bending of the specimen and expanding the functionality of the device by providing both stepwise and smooth control of the ratio of forces and strain rates of the specimen. The device contains active grippers 1 for fastening the sample 2, the rods 3 rigidly connected to them, pivotally connected by means of the lever 8 with the rods 6. The pipes 6 are made in the form of beams of equal resistance to bending, which by means of the longitudinal groove 7, covering the finger 5 , are connected to the corresponding passive gripper 4 of sample 2. The load is transferred to the sample through rods 3 in one direction and through levers 8, rods 6 and seizures 4 in the other. The ratio of the forces and strain rates of the sample is determined by the value of the angles α, α ¹ and the length of the levers 8. The hinged connection of t g 6 with the passive grippers 4 with a finger 5 and a longitudinal groove 7 with a length L greater than half the distance between the fixing points levers 8 on the tail portions x and r 6 excludes bending of sample 2 at angles α ≠ α ¹ . 1 il.

Description

is to improve the accuracy of testing by eliminating the bending of the sample and increasing the functionality of the device by providing both stepwise and smooth control of the ratio of forces and strain rates of the sample. The device contains active grippers 1 for fastening the sample 2, the rods 3 rigidly connected with them, pivotally connected by means of the lever 8 with ti gt 6. The legs 6 are made in the form of beams of equal resistance to bending, which with the aid of the longitudinal groove 7, covering finger 5, are connected with sootnosti15380934

by the inert passive gripping of the sample 2. The load is transferred to the sample through the gi 3 in one direction and through the levers 8, the gi 6 and the grips k in the other. The ratio of the forces and strain rates of the sample is determined by the values of the angles L, and the length of the levers 8. The hinged connection of the t 6 with the passive grippers k with the finger 5 and the longitudinal groove 7 with the length L greater than half the distance between the fixing points arms C at the tail end

ten

J5 t g 6, eliminates the bending of sample 2 at

corner t ui. 1 il.

J5 t g 6, eliminates the bending of sample 2 at

corner t ui. 1 il.

The invention relates to a testing technique, namely to testing samples of sheet materials under biaxial loading by stretching, compressing or stretching-compressing, and is an improvement of the known device according to the author. V 1 69298. The aim of the invention is to increase the accuracy of testing by eliminating the bending of the sample and expanding the functional capabilities due to the liver providing both stepwise and smooth control of the ratio of forces and rates of deformation of the sample in mutually perpendicular directions. x

The drawing shows a diagram of the device.

The device contains active grippers 1 for fastening sample 2, rigidly connected with them rod 3, driving them to move (not shown), passive grippers k connected with a finger 5 to the corresponding rod 6, having the form of a beam of equal bending resistance. in the central part of which a longitudinal groove 7 is made, and four levers 8 connecting the plugs 3 to the tail parts of the nuts 6 with the help of hinges mounted into the corresponding openings of 9 tons of g and the levers.

The length L of the longitudinal groove 7 is selected from a ratio of 1, a / 2, where a is the distance between adjacent holes 9 in the tail portions of t g 6, which allows smooth adjustment of the ratio of forces and deformation rates of sample 2 within

5 about 5

0 5

0

five

stepwise variation of the indicated ratios with discrete changes in the length of the levers 8 and the angles oi - Y. A hinged joint tg 6 with passive grippers k eliminates bending of the sample 2 at angles of about.

The device works as follows.

Sample 2 is fixed in grippers 1 and k. The levers 8 are hinged securely in the corresponding holes 9 t g 3 and and 6 at an acute angle ei when tested under conditions of tension (compression) along the same axis of the sample and compression (tension) along the other or obtuse angle, when loading the sample biaxial stretching or compression.

The drive load is transmitted to sample 2 through the gi gi 3 in one direction and through the levers 8, the gi 6 and grips k in the other, the magnitude and direction of movement of the gg 6, and hence the ratio of the forces and rates of deformation of the sample in mutually perpendicular The directions are determined by the value of the uglast, the length of the levers, the magnitude and the speed of movement, and r 3.

To smoothly adjust the ratios of applied forces within a step change in angle Ј when both pairs of levers are fixed in the corresponding holes of the tail parts, tg 6, the length of one of the pairs of levers 8 and the angle about (figure 1) between their axes and the axis of the ty 3 are set not equal to the lengths of the other pair of levers and the angle about. At the same time, the compound t g b with passive grippers k with the help of

one

the finger and the longitudinal groove do not create a bend in the specimen, transmitting only longitudinal force.

The forces and deformations of the sample are recorded by known methods.

Claims (1)

Invention Formula A device for testing a sample of sheet material under biaxial loading according to the ed. St. (J1 Y69298, characterized in that, in order to increase the test accuracy by eliminating the bending of the sample and 38093. 6 expanding the functionality of the device by providing both stepwise and smooth adjustment of the ratio of forces and strain rates, each passive grip is connected to a corresponding beam of equal bending resistance by means of a finger fixed on .Q placed in the longitudinal groove in the beam, the length of which is L selected from the relation, where a is the distance between the points of fastening the lever on the tail part of the beam.