SU1087718A1 - Vibration insulating support - Google Patents

Abstract

I. VIBRATION ISOLATING SUPPORT, containing an intermediate mass between the first vibratory element and the first vibratory object and the second elastic element, one end of which is designed to secure the insulated object, characterized in that, in order to increase efficiency1 | vibroisolation, it is provided with an elastic-inertial vibration compensator, which includes additional mass, d.v are additional elastic elements, one of which is designed to be placed between the vibroactive and insulated objects, and the other between the additional mass and the insulated object, and the movement conversion mechanism in the form of connected to the second the end of the second elastic element of the two shoulders arm, the ends of the short and long arms of which are fixed respectively on the intermediate and additional masses. 2. Anti-vibration bearing support according to claim 1, characterized in that the mechanism for converting the movement is made in the form of two fluid-filled and connected between SU (s) hydraulically bellows. 00 | 00

Description

The invention relates to the protection against the vibrations of various objects.

A device for vibration isolation is known, which contains a shock absorber, elastic elements and weights 1 fixed to them.

The drawback of the device is the strong dependence of its efficiency on frequency tuning and the need to use large masses.

Closest to the invention in its technical essence and the achieved result is a vibration-insulating support containing an intermediate mass, which is installed between it and the vibration-active object, the first elastic element and the second elastic element, one end of which is intended to be fixed to the insulated object 2.

A disadvantage of the known vibration isolating support is that, in order to provide vibration isolation at low frequencies, it is necessary to use significant intermediate masses.

The aim of the invention is to increase the efficiency of vibration isolation.

This goal is achieved by the fact that a vibration isolating support, containing an intermediate mass, between the first elastic element and the second elastic element, which is installed between it and the vibrating object, is designed to be fixed to an insulated object at one end, including an additional mass, two additional elastic elements. an element, one of which is intended to be placed between the vibroactive and insulated objects, and the other between the additional mass and the insulated object , and a motion conversion mechanism in the form of a two-arm lever connected to the second end of the second elastic element, the ends of whose short and long arms are fixed respectively on the intermediate and additional masses.

In addition, the motion conversion mechanism can be made in the form of two fluid-filled and interconnected hydraulically bellows.

FIG. 1 shows a diagram of the vibration isolating support; in fig. 2 - constructive version of the support, longitudinal section; in fig. 3 - dependence of the vibration isolation efficiency on the dimensionless frequency.

The anti-vibration support contains intermediate mass 1, installed between it and the vibrating object 2, the first elastic element 3, the second elastic element 4, one end of which is intended to be fixed on the insulated object 5, an elastic-inertial vibration compensator including additional mass 6, two additional elastic elements 7 and 8 one of which is intended for placement between vibroactive 2 and isolable 5

objects, and the other between the additional mass 6 and the insulated object 5, and the motion conversion mechanism in the form of a two-arm 9 connected to the second end of the second elastic element 4, the ends of the short and long arms of which are fixed to the intermediate 1 and additional 6 masses.

The motion conversion mechanism can be made in the form of two filled

fluid and interconnected hydraulically bellows 10 and 11.

Anti-vibration support works as follows.

The effectiveness of vibration isolation is achieved by the fact that in a given frequency range (usually in the range of the most intense vibration components), the forces transmitted to the insulated object 5 by elastic elements 3 and 4 with intermediate mass 1 are compensated by the forces generated by the elastic-inertial vibration compensator.

FIG. 3 for comparison, the efficiency (reciprocal of the transfer coefficient of the force in dB) of the simplest single-stage (curve 1) and two-stage sound (curve 2) vibration-proof supports versus the dimensionless frequency Si Wtv / (K / t) is the natural frequency of the single-stage support; K is the stiffness of its elastic element. Here (curve 3) a similar relationship is given for the vibration-insulating support with the following parameters of the elements included in it: intermediate 1 and additional 6 masses are 0.064 and 0.004w respectively (t is the mass of the object to be mounted on the support); the stiffness of the elastic elements 3 and 4 of the support and the additional elastic elements 7 and 8 are respectively 2.07, 2, 17, 0.21 and 0.054 of the rigidity K of the single-stage support. At the same time, for correct comparison, the sum of intermediate 1 and additional 6 is a mass of the proposed vibration isolating support equal to

0 intermediate mass two-stage support. From the comparison of the efficiency curves, it can be seen that, compared with the single-stage support (curve 1), the proposed support (curve 3) provides an increased vibration-isolating effect in the J2tt 5 range, which in this example is ± 10% of the tuning frequency TH of the elastic-inertial vibration compensator.

The negative efficiency in the range of Zone 3 is explained by the presence of additional natural frequencies in the vibration isolation system. The structure of the support and the parameters of its elements should be chosen so that this section of the performance characteristic is located in the frequency range 5 free from intense disturbances.

From the comparison: curves 2 and 3 (Fig. 3) it can be seen that in a fairly wide range of 4acTOT5 ni.-B -5 5imax the proposed support

Claims (2)

1. VIBRATION ISOLATING SUPPORT, containing an intermediate mass, a first elastic element and a second elastic element installed between it and a vibroactive object, one end of which is designed to be mounted on an insulated object, characterized in that, in order to increase the effectiveness of vibration isolation, it is equipped with an inertial inertial vibration compensator, including an additional mass, two additional elastic elements, one of which is designed to be placed between vibroactive and insulated objects, and the other between the additional mass and isol uemym object, and motion converting mechanism coupled to a second end of the second resilient element a two-armed lever, the ends of the short and long arms of which are fixed respectively on the intermediate and additional masses. 2. Vibration isolating support along π. 1, characterized in that the motion conversion mechanism is made in the form of two fluid-filled and interconnected hydraulically bellows. Figure 1