RU194245U1 - INSTALLATION FOR MEASURING AREA OF CROSS-SECTION OF NON-CONDUCTING HARNESS FIBER BUNDLES MICROPLASTIC POLYMERIC MATERIALS - Google Patents

Abstract

A device for measuring the cross-sectional area of non-conductive fiber bundles of microplastic polymer materials. The objective of the utility model is to increase the accuracy of determining the onset of resonance by automatically changing the length of the test sample when measuring the cross-sectional area of non-conductive fiber bundles of microplastic polymer materials. the metal support mounted on the table of the vibrator of the vibrating stand is fixed on the base, while the metal support is installed with the possibility of connecting to one end of the test sample, the other end of which is thrown through the block and connected to the load, also on the basis of the test sample perpendicular to the test sample, and a vibrostand control stand connected to the frequency meter input, while the support , to which the block is attached, is fixed on the base with the possibility of its reciprocating movement, a reverse electric motor is also introduced, mounted on the base and connected to sometimes. 1 ill.

Description

The utility model relates to the fields of production and application of fiber bundles of microplastic polymer materials and can be used to measure and control the cross-sectional area of the bundles.

A known installation that implements a method of measuring the cross-sectional area of a microwire, containing a massive cast base of a microscope, to which a bracket is mounted rigidly, bearing plates made of PCB, holes are drilled in the plates in which a composite brass pin is fixed, another composite brass pin is fixed by means of a clamp made of vinyl plastic on a microscope stage, a test wire-string sample, rigidly fixed with a screw in a hairpin, and the other end of the string thrown over cutting a microblock at the end of the stud and connected by a screw to a load that creates the necessary string tension (RU No. 2293947, 02/20/2007).

The closest solution in technical essence is the installation that implements a method of non-contact measurement of the cross-sectional area of non-conductive fiber bundles of microplastic polymer materials, containing the test sample, one end of which is thrown through the unit and connected to the load, the other is attached to a metal support mounted on the table of the vibrator stand vibrator, fixed on the base, also on which perpendicular to the test specimen, a stroboscope and a control stand of the vibration bench are mounted, constant prices to the input of the frequency counter (RU №2672190, 12.11.2018).

The disadvantage is the difficulty in changing the length of the test sample when measuring the cross-sectional area of the fiber bundles.

The objective of the utility model is to increase the accuracy of determining the onset of resonance by automatically changing the length of the test sample when measuring the cross-sectional area of fiber bundles.

The technical result is to increase the accuracy of determining the cross-sectional area of the fiber bundles due to the improved determination of the onset of resonance with automatic change in the length of the test sample.

The essence of the utility model lies in the fact that in the installation for measuring the cross-sectional area of non-conductive fiber bundles of microplastic polymer materials containing a test sample, one end of which is thrown through the block and connected to the load, the other is attached to a metal support mounted on the table of the vibrator stand mounted on the base, also on which a stroboscope and a control stand of a vibrostand connected to the input of the frequency meter, a support to which the unit is attached, fixed on the base with the possibility of its reciprocating movement, also introduced a reverse motor mounted on the base and connected to the support.

The novelty lies in the fact that the support to which the unit is attached is fixed on the base with the possibility of its reciprocating movement, also introduced a reverse motor mounted on the base and connected to the support.

The analysis of known technical solutions (analogues) in the studied area and related areas allows us to conclude that they lack features similar to the significant distinguishing features in the claimed device.

The drawing shows the installation.

The test sample 1 is attached on one side to a metal support 2, which is mounted on the base 3, and the other end is thrown over the block 4 and connected to the load 5. The metal support 2 is mounted on the table of the vibrator 6 of the vibrostand, on the common base 3, on which it is perpendicular to the test person sample 1 is equipped with a stroboscope 7, and the control stand 8 of the vibrostand is connected to the input of the frequency meter 9. The support 10, to which the unit 4 is attached, is fixed on the base 3 with the possibility of its reciprocating movement, due to the reverse electric motor latch 11 installed on the basis of 3.

The device operates as follows.

The test sample 1 is clamped in a metal support 2, twist it and the other end, setting the length of the sample, tossed through the block 4 and connected to the load 5, the mass of which can vary. The metal support 2 is installed on the table of the vibrator 6 of the vibrostand, on a common base 3, on which a strobe 7 is installed perpendicular to the test sample 1. The control stand 8 of the vibrostand is connected to the input of the frequency counter 9.

Turn on the vibration stand. Oscillations of the test sample 1 on the table of the vibrator 6 of the vibration bench can be achieved by smoothly changing the frequencies on the control stand 8 of the vibration bench. They feed power to the reverse motor 11, changing the location of the support 10, and hence the length of the tow 1. When the frequency of the driving force approaches the frequency of natural vibrations, the amplitude of the twisted tow of sample 1 increases, the onset of resonance is determined by a strobe 7.

The magnitude of the frequency is determined by the frequency meter 9. Having established the frequency of the resonant vibrations of the twisted bundle of the sample, determine the mode of vibration corresponding to this mode.

The application of the proposed installation improves the accuracy of determining the cross-sectional area of fiber bundles due to the improved determination of the onset of resonance with automatic change in the length of the test sample.

Claims (1)

A device for measuring the cross-sectional area of non-conductive fiber bundles of microplastic polymer materials containing a metal support mounted on a vibrator table vibrator stand mounted on the base, the metal support being installed with the possibility of connecting to one end of the test sample, the other end of which is thrown through the block and connected to the load, also on the basis perpendicular to the test sample, a stroboscope and a control stand of the vibrostand connected to the frequency input are installed ra, characterized in that the support to which the unit is attached is fixed on the base with the possibility of its reciprocating movement, also introduced a reverse motor mounted on the base and connected to the support.

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