SU1477960A1 - Vibration isolator - Google Patents

Abstract

The invention relates to mechanical engineering and can be used for protection against vibrations and impacts of assemblies and blocks of electronic equipment. The purpose of the invention is to increase the efficiency and reliability of vibration isolation by creating a dry friction force of guaranteed initial value, increasing in magnitude with increasing axial displacements, and converting axial displacements to radial displacements with additional damping. Making the casing 3 of the surfaces of the washers 5, 6 and the friction elements 7 as torus parts for their interaction allows one to reduce the transmission coefficient under axial and radial loads. 3 il.

Description

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The invention relates to mechanical engineering and can be used for protection against vibrations and impacts of assemblies and blocks of electronic equipment.

The purpose of the invention is to increase the efficiency and reliability of vibration isolation by creating a dry friction force of a guaranteed value, increasing in magnitude with increasing axial displacements, and converting axial displacements to radial displacements with additional damping.

FIG. 1 shows a vibration isolator, a longitudinal section; in fig. 2 - version of the vibro-insulator sleeve; in fig. 3 - a variant of vibration isolator with the execution of an elastic element in the form of two conical springs.

The vibration isolator contains support bases 1 and 2, body 3, a damping device placed coaxially in it, including sleeve 4, two parallel washers 5 and 6 mounted coaxially on sleeve 4, between them there are friction elements 7 in the form of annular sectors interacting with the surface of the housing 3, spring-loaded in the radial direction, spring 8, installed with an initial tension coaxially on sleeve 4 with the help of a clamp 9 for engaging one end with a washer 6, and the other end with an emphasis 10. Case 3 It executes a part of the torus and is installed in pole bases I and 2 towards each other surfaces of washers 5 and 6 and the corresponding surface of the friction elements 7 formed as part of the torus.

On the sleeve 4 can be installed symmetrically with respect to washers 5 and 6 two conical springs 8.

Vibration isolator works as follows.

Outside the resonance region, where the oscillation amplitudes are reduced, the impact on the housing 3 from the side of the supporting bases 1 and 2 is less than the dry friction force in the contact between the surfaces of the friction elements 7 and the housing 3. Therefore, the friction elements 7 do not move relative to the housing 3. In this area The elastic deformation of the support bases 1 and 2. The elastic characteristic is determined only by the rigidity of the bases 1 and 2. There is no damping in the system, in particular, in the high-frequency region. Due to this, there is no deterioration of the vibration isolation in the high-frequency region. In the resonance region, the oscillation amplitudes increase and the effect from the supporting bases 1 and 2 on the body 3 from a certain moment becomes more dry friction between the friction elements 7 and the body 3. From this moment the friction elements begin to shift relative to the body 3 with friction, and the magnitude of the force dry friction is non-linearly increasing with increasing amplitude of oscillations due to the implementation of the hull as part of a torus. In addition, the friction elements 7 are displaced in the radial direction relative to the washers 5 and 6 with friction, and the amount of dry friction force increases with increasing radial displacements by making the surfaces of the washers facing one another as part of a torus. Thus, a double damping of the oscillations occurs, leading to a decrease in the transmission coefficient in the resonance region.

In addition, when the friction elements 7 are displaced relative to the washers 5 and 6 in the radial direction, the spring 8 is put into operation according to the sequence diagram. As a result, the stiffness of the vibration isolator is abruptly reduced. An abrupt decrease in stiffness when approaching a resonance ensures the exclusion of the operation of the vibration insulator at the resonant frequency, i.e. provides a detuning from the resonance.

The difference in the operation of the vibration isolator of FIG. 3 lies in the fact that under axial action when the damping device breaks down, the rigidity of the vibration insulator increases, which also ensures that the device does not operate at a resonant frequency, i.e. detuning from resonance.

Claims (1)

Invention Formula Vibro-insulator containing support bases, body, coaxially placed in it damping device including sleeve, two parallel spaced washers mounted coaxially on sleeve, placed between