SU1446512A1 - Method of investigating a vibration insulator - Google Patents

Abstract

The invention relates to the study of the dynamic characteristics of rubber vibration isolators. The aim of the invention is to determine the upper limit of the range of operating stresses for the compression of a rubber vibration isolator. For this, the dynamic characteristic of the loaded vibration isolator is recorded as the dependence of the natural frequency on the value of the static load. Static loading is carried out in steps due to a change in the value of the added mass at each stage of loading. As the upper limit of the range of operating compression voltages, they take voltages corresponding to the minimum of the natural frequency. The natural frequency is recorded with free damped oscillations of a loaded vibration vibration torus. The oscillations are excited by pre-deforming the loaded vibration isolator with a subsequent discharge of the load. The amplitude of the pre-deformation is set constant at all loading stages. 1 hp ff, 2 ill. g (L

Description

one

The invention relates to the study of the dynamic characteristics of new vibration isolators.

The aim of the invention is to determine the upper limit of the range of working stresses of compression of a rubber vibration isolator.

FIG. 1 given the dynamic characteristics of vibration isolators, isolated from various rubber grades; in fig. 2 - experimental setup for determining the dynamic characteristics of the vibration isolator.

The method is as follows.

Step vibration loading of the vibration isolator 1 under investigation is carried out using an attached mass of various sizes, excite- ing and oscillating at each load step, and recording the dynamic characteristic as a dependence of the natural frequency Cx of the loaded vibration isolator 1 against the static load p, loading leads to a minimum of its own Frequencies. The compression pressures corresponding to the minimum frequency are taken over the upper limit of the working range of the rubber vibration isolator to be investigated. The natural frequency ω is recorded during free oscillations of a loaded vibration e torus 1, which is excited by the preliminary deformation of a loaded vibration isolator with a subsequent load shedding. The value of the pre-deformation is set constant at all loading steps.

When determining the dynamic characteristics of the vibration isolator 1, it is installed on the movable table 2, using the lead screw 3, the stamp 4 is mounted on the vibration isolator

The driver 1, to the lever 5. The lever 5 at the same time establish in horizontal position. The required voltage (5 squeezing is set by setting the appropriate torque value on the lever 5 by adjusting the masses of the weights 6 and 7. Using the mechanism 8, the lever 5 is moved, deforming the elastic element of the vibration isolator 1 by a specified amount. Then, using the mechanism 8, the load is removed Lever 5 with weights 6 and 7 performs free damped oscillations with a frequency of co. Repeat these operations for different masses of loads 6 and 7, obtaining.

KIT is a variety of values of C1 1bstt frequency from a loaded insulator at different voltages, which are used to construct the dynamic characteristic of the vibration insulator under study.

The dynamic characteristics of CO (G), tj) j (G),) are obtained for elastic elements of vibration insulators of 66–4 cm in size, made of rubber of different grades: 7889, 1365, and 1347, at a voltage of x.G compression, reaching 3.5 MPa.

From the dynamic characteristic to, (5) it can be seen that the upper limit of the working range of compressive stresses for rubber grade 7889 with the dimensions of the elastic element 664 cm is the compressive stress 6 1.3 MPa, corresponding to the minimum of its own

W frequency

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Compression of elastic elements

Commodity of rubber vibration isolators leads to a change in their shape, which affects the natural frequency of the vibration isolator loaded with various static loads.

Studies have shown that this method allows you to extend the range

operating compressive stresses of the elastic elements of the vibration isolator and determine the upper limit of this range at which the loaded vibration isolator has a minimum, natural frequency and the greatest dynamic efficiency.

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Formula 1

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The method of studying the vibration isolator, according to which step static loading of the vibration isolator under investigation is carried out by a compressive load using an attached mass of various sizes, oscillates are excited at each loading step and the dynamic characteristic is recorded as a function of static load, which is determined - its limits of the range of operating voltages Compress a rubber vibration isolator, as a dynamic characteristic register the natural frequency of the loaded About vibration isolator, loading. Before the detection of the minimum of the natural frequency and the compression voltage corresponding to the minimum frequency, they are taken as the upper limit of the working range.

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2. The method of paragraphs 1 and 2 of t and h. Of preliminary pre-shaping and with the fact that one’s own loaded one with an insulator with a post-frequency is recorded with the HafpysKH free by the reset, the vibro-insulated vibration which is set constant on all x: tutors that excite by. pen x loading.

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FIG. 2

Claims (2)

Claim 1. A method for studying a vibration isolator, according to which stepwise static loading of the investigated vibration isolator with a compressive load using a connected mass of various sizes is performed, vibrations are excited at each loading stage and the dynamic characteristic is recorded as a function of the static load, o Compared with the fact that, in order to determine the top · * the boundaries of the range of operating compressive stresses of the rubber vibration isolator, as a dynamic characteristic register the natural frequency of the loaded broizolyatora, loading is carried out to identify the minimum natural frequency of the compression and tension corresponding to the frequency minimum is taken as the upper limit of the operating range. 2. The method according to p. ^ Characterized in that, the natural frequency is recorded during free vibrations of the loaded vibration isolator, which is excited by preliminary deformation of the loaded vibration isolator with subsequent discharge of the load, the value of which is set constant at all degrees of loading. figure 1! 44651 2