SU79971A1 - Dynamometer for testing the strength of textile materials - Google Patents

Description

Existing test machine systems used to test textile materials have significant drawbacks. The main disadvantage of a lab-type testing machine is that the transfer of force to the force measuring machine is performed directly by stretching the test specimen. However, it is known that all tissues at the beginning of the test give significantly greater elongations than at the end, as a result of which the speed and loading throughout the course of the test varies considerably. In addition, the masts of mud pots have a wide variety of sizes of interlacing of the upper vise per unit load. If the first deficiency causes inconsistency of the test conditions for various types of tissue, the second deficiency does not allow one to obtain comparable results from using the same tissue.

The proposed dynamometer for testing the strength of textile materials differs from the known devices in that it employs a loading mechanism, made in the form of a load sliding on the support arm, whereby the value of the load applied to the test sample varies depending on the angle of rotation of the lever and cargo. The movement of the reference shaft according to a given condition or law is carried out by means of a nrofil cam rotated by an electric motor through a gearbox and connected with a reference lever by a chain transmission. Such a construction of the dynamometer makes it possible to maintain a constant loading rate of the test tissue sample, regardless of the material elongation during the test, and to establish uniform p-works of the dynamometers, regardless of their power.

The dynamometer is mounted on the channel meter / (see drawing) and the base 2. The electric motor 3 rotates the profile cam 5 through the gearbox 4, which, when testing the fabric and tearing, winds itself off

 79971-2 -

chain 6; The other end of this chain is fixed on block 7, which rotates freely on axis 8. Block 7 is rigidly coupled with supporting arm bent in one plane 9. Bend of lever ensures exact positioning of npoTiHj of the groove of block W. which, due to the presence of hinge joints, can freely move in both directions of the lever 9. Load // by means of a 12 soy chain; en with double b: 1-kk-10. This block can freely vrang on the axis 8. To the small block 13 by means of a chain / 4 suspend the upper one / 5. The lower clamp 16 is fixed, but due to the screw / 7, it is possible to establish the required distance between the clamps.

When the cam 5 rotates in the clockwise direction, a part of the chain 6 winds up from it, then under the action of its own weight and load // the lever 9 can deflect tps according to a predetermined law, which is set in accordance with the eccentricity of the cam 5. When the lever 9 comes out The horizontal position in the sloped alloy of the weight of the load located on it is decomposed into two components, one of which acts in the direction of the non-ori- radical lever, and the other in the fractional direction of the lever. The first force affects only the force of friction; Between the load and the lever, while the second causes a force that turns the double block 10, 13 and thereby creates tension in the sample under test, clamped in the upper and lower sleeves. At the same time, the force perpendicular to the longitudinal axis of the lever and the influence of the young on the amount of friction decreases as the angle of inclination of the support lever decreases, the income reaches 0 when the lever is in the vertical position, while the component directed along the lever from 0 reaches the maximum value of the weight of the load and. The presence of a large and small dual block allows a small amount of time: load; on the lever, to cause so many times greater forces in the sample, how many times block 10 is greater than block 13. The angle of deflection of the lever, measured on a scale of 18, indicates the load to be received. When the sample is broken, the motor turns off and locks the inclined position of the lever; at the same time, the pawl, located inside the load, snaps onto the ratchet teeth of the lever 9 and thereby stops further movement of the load along the lever. A conventional type of chart device, strengthened on this dynamometer and driven from blocks 7 and 10, makes it possible to take charts (“load-stretch”) at 5 or 10 times the scale, depending on the ratio of the diameters of the double block.

Claims (2)

1. Dynamometer for testing the strength of textile materials using a recording device for recording on an enlarged scale load-stretch diagrams, characterized in that, in order to maintain a constant loading rate of the test fabric, regardless of the material elongation during the test, a loading mechanism is applied, made in the form of a load sliding along the support arm, connected with a movable gripper for a flexible draft sample, and loading the test specimen depending on the angle of inclination on the support arm being moved according to the predetermined condition, determines emomu configuration profile of the cam rotated by motor reducer n associated with the support lever flexible draft type .. Subject invention 2. In the dynamometer according to claim 1, use a stop ycTpoiicTBa that automatically turns off the electric motor when the test specimen breaks and stops the sliding load moving along the support arm. - 3 - № 79971