RU2002243C1 - Device for measuring transverse deformation of high-elastic materials - Google Patents

Abstract

The invention relates to testing highly elastic materials, in particular to devices for testing materials under uniaxial tension. The purpose of the invention is to increase the objectivity and accuracy of the lateral reduction of samples of highly elastic materials due to the non-contact measurement method and its continuous registration during stretching, to prevent twisting of the samples and to ensure the measurement of lateral reduction strictly in the center of the sample. The material sample is fixed to the clamps of the tensile testing machine so he went along the guides 5. Then the device is lifted until the needle tip coincides with the center of the working part of the sample, and this ii REMCO movable portion is closed and is secured to a fixed part by means of latch 12. When the needle passes through the material and enters the window opening 7 of the pressing b, thereby securing the device on the sample after this voltage is supplied to light bulb 2 and the recording device is turned on. Then a tensile testing machine is turned on and the sample is stretched. A transverse reduction of the material occurs, which increases the luminous flux passing through the slot 8 to the photosensor 9. This leads to an increase in the current from the photosensor which is recorded by the recording device. When the specimen is elongated, the device moves upward along with the central part of the specimen thanks to the needle and articulated guides 13. t silt.

Description

v "

I AM

The invention relates to uniaxial tensile testing of AISJ resilient materials and can be used in light, textile and technical cutting industries.

A known method for determining the lateral reduction coefficient of rubber and polyethylene samples 1, in which the lateral reduction of the samples was measured using a thickness gauge with a division value of 0.01.

This method also does not allow continuous recording of transverse deformation of the sample. In addition, measuring the transverse dimensions of a sample with a thickness gauge requires frequent stopping of tensile testing machines, and this is undesirable since shoe materials are elastoplastic and subject to relaxation, which affects the amount of transverse deformation.

A method is also known for determining the transverse deformation of samples of leather materials 2 using mercury sensors that are directly glued to a sample of material. This method allows continuous recording of deformation of the middle part of the sample during its stretching.

However, the use of an adhesive to adhere the sensor is undesirable since it renders the olivan work on the structure of the material and, therefore, on its ability to deform. In addition, stretching most synthetic leathers, film materials, knitwear, etc. coupling is caused by significant folding of the samples (the so-called marginal effect) due to the different ability to contract individual layers, and this in turn leads to a strong distortion of the obtained measurement results.

The purpose of the invention. - improving the accuracy and objectivity of the measurement result.

This is achieved by the fact that the device for measuring the transverse deformation of highly elastic materials, comprising a measurement sensor and a recording unit, is equipped with an optical system and a subject frame made of two parts, one of which is fixedly connected to the optical system, and the other is mounted with the possibility of rotation relative to the first, it has slots for the passage of radiation and in its central part there is a needle designed to fix the device on the material being studied, and the measurement sensor full in the form of a photosensor mounted on a rotary MSS | And a subject frame.

The drawing shows the proposed device.

Device for measuring lateral deformation of highly elastic materials

contains an optical system 1 consisting of a projection lamp 2 and a lens 3. The optical system is connected to an object frame 4, the casing of which consists of two parts, one of which is fixedly connected to the optical system 1, has two guide rollers 5 and pressure glass 6, through which light from the optical system enters the central zone of the test sample. A hole 7 is made in the center of the pressure glass.

The second part of the subject frame 4 is mounted rotatably relative to the first and has slots 8 located in the center through which the radiation

0 hits the photosensor 9, mounted on a subject frame. The photosensor is connected to a recording unit (not shown in the drawing). In the center of the rotatable part of the subject frame is attached a needle 10, which

5 passes into the hole 7 of the pressure glass.

Parts of subject frame 4 are connected

between themselves by a loop 11 and are fastened between

latch 12. The device is fixed

using articulated guides

0 struts 13 on a bar 14, which is attached to the stationary clamp of the tensile testing machine with a pair of screws through holes 15.

The device operates as follows. A sample of material (for example, leather, synthetic leather, fabric, etc.) is fixed in the clamps of the tensile testing machine so that it passes along the guides 5. Then the device rises to

0 so that the needle tip coincides with the center of the working part of the sample, and in this position the pivoting part of the frame is closed and fastened to the fixed part by means of the latch 12. In this case, the needle passes through the material and enters the hole 7 of the pressure glass b, secured device on the sample.

After that, the voltage is applied to the light bulb 2 and the recording device is turned on (DZU-021 coordinate recorder). Then a tensile testing machine is turned on and the sample is stretched. In this case, a transverse reduction of the material occurs, which increases the luminous flux,

5 passing through the slots 8 to the photosensor 9, which ultimately leads to an increase in the current from the photosensor, which is recorded by a recording device.

When the sample is elongated, the device moves upward along with the central part 520022436

Thanks to the needle and articulated design, the device is reliable, easy to use with the support racks 13. This allows and provides high accuracy, to ensure that the narrowing of the sample is strictly centered and repeatable.

the real part of the working area, i.e. where (56) 1. Lebedeva E.K. On the coefficient of popeono the greatest. If on another coordinate-5 river deformation of rubbers and metals. To give a signal to Kaut of the recorder, I register-chuk and rubber, 1981, No. 10, p. ,

longitudinal deformation of the sample, then 2. Shaganova IM, Zybina Yu.P., A kozfpribor will write down a graph of the dependence of the transverse reduction coefficient in the material deformation of a specimen ex, on its material for leather products, Scientific works

longitudinal deformation, as his f (ei) .10 MTILPa, vol. 38, 1972, p. 235-241.

Claims (1)

The claims nzv, to b, with nr, a psystem, and the other is installed with the DEVICE FOR MEASUREMENT The pivoting ability of the rotation relative to the first, in TRANSVERSE DEFORMATION HIGH- 15 it has slots for passing OF ELASTIC MATERIALS, containing radiation and in its central part an aid to a measurement sensor and a recording needle, designed to fix blocks, characterized in that it is provided with material, and the measurement sensor The optical system and the object frame are made in the form of a photosensor installed in two parts, one of which on the rotary part of the object frame is fixedly connected to the optics.