RU2673426C1 - Sleeve extension shock-absorber - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: invention relates to machine building. Sleeve extension shock-absorber contains a rubber-cord shell made in the form of a cylinder with an angle of reinforcing threads from 0 to 54°. Casing at each end is clamped with flanges and fastening discs, filled with compressed gas and connected to the gas supply system. Flexible rubber diaphragm is placed in the inner cavity of the rubber cord casing in the form of a closed cylinder. Diaphragm is sealed to one of the mounting discs, connected to a separate power system and filled with liquid.EFFECT: improved operational properties of the sleeve extension shock absorber are achieved with the simplicity of its design.1 cl, 1 dwg

Description

The invention relates to mechanical engineering, in particular to means for damping the vibration of units and assemblies.

Known adaptive hydropneumatic support (patent RU 2290548 C1, F16F 13/00, F16F 9/06, B60K 5/12, publ. 12/27/2006, bull. No. 36), containing a hollow body consisting of a base and interconnected by an elastomeric element side part and stem with a flange, an elastic membrane and a partition dividing the internal cavity of the support into several chambers connected by throttling holes to valve devices.

A disadvantage of the known adaptive hydropneumatic support is its structural complexity due to the presence of a large number of components, as well as complex elements such as throttling holes, the implementation of which requires great accuracy.

The closest in technical essence and the achieved technical result to the claimed sleeve tensile shock absorber is a pneumatic tensile shock absorber (copyright certificate SU 1100441 A, F16F 9/04) containing a rubber-cord shell made in the form of a cylinder with an angle of reinforcing threads from 0 to 54 degrees and filled compressed gas, and flange and support connected to the ends of the shell.

A disadvantage of the known pneumatic tensile shock absorber is the deterioration of its operational properties when operating in various modes, due to the low adaptability of the shock absorber. The operational properties of the known pneumatic tensile shock absorber are regulated only by changing the angle of the reinforcing threads (laborious replacement of rubber-cord shell), or by changing the pressure of the compressed gas in the rubber-cord shell.

The technical result of the claimed invention is to improve the operational properties of a sleeve tensile shock absorber with the simplicity of its design.

The technical result is achieved due to the fact that the sleeve tensile shock absorber has a cylindrical diaphragm in the internal cavity connected to a separate power system and filled with liquid.

The essence of the claimed technical solution is illustrated by the following drawing:

FIG. 1 - General view of the sleeve tensile shock absorber:

A - in the starting position,

B - when applying the working pressure.

The claimed sleeve tensile shock absorber (Fig. 1) contains a rubber-cord casing 1 made in the form of a cylinder with an angle of reinforcing threads 2 from 0 to 54 degrees, at each end compressed by flanges 3 and mounting discs 4, filled with compressed gas and connected to a gas supply system, in the inner cavity of which is placed a flexible rubber diaphragm 5 in the form of a closed cylinder, hermetically attached to one of the mounting discs 4, connected to a separate power system and filled with liquid.

The claimed sleeve tensile shock absorber works as follows.

When applying the working pressure to the inner cavity of the rubber-cord shell 1 through the gas supply system, the reinforcing threads 2, superimposed at an angle of 0 to 54 degrees (angle α, Fig. 1A), under the action of the working pressure, tend to increase their angle to an equilibrium angle of 54, 4 degrees, thereby creating an elastic force F supporting the shock-absorbing object (Fig. 1, B). The force F and potential energy (expansion delay or compression resistance) of the gas in the inner cavity of the rubber-cord shell 1 compensate for vibrations and periodic movements of the shock-absorbing object.

In the claimed invention, a change in the fluid pressure in the internal cavity of the flexible rubber diaphragm 5 allows you to adapt the stiffness and load characteristics of the sleeve tensile shock absorber when changing the load on the sleeve tensile shock absorber, as well as the vibration frequency or the amount of movement of the shock-absorbing object.

Increasing the fluid pressure in the inner cavity of the flexible rubber diaphragm 5 located in the inner cavity of the rubber cord casing 1 increases the volume of the flexible rubber diaphragm 5, displacing part of the gas from the inner cavity of the rubber cord casing 1 through the gas supply system. A decrease in the volume of gas in the inner cavity of the rubber-cord casing 1 reduces its potential energy, thereby adapting the rubber-cord tensile shock absorber to increased loads.

Reducing the pressure of the liquid in the inner cavity of the flexible rubber diaphragm 5 located in the inner cavity of the rubber cord casing 1 reduces the volume of the flexible rubber diaphragm 5, freeing up additional volume in the inner cavity of the rubber cord diaphragm 1 for supplying gas through the gas supply system. An increase in the volume of gas in the inner cavity of the rubber-cord casing 1 increases its potential energy, thereby adapting the rubber-cord tensile shock absorber to reduced loads.

Thus, with the simplicity of the design of the inventive rubber-cord tensile shock absorber, the possibility of changing the fluid pressure in the inner cavity of the flexible rubber diaphragm 5 provides improved operational properties of the rubber-cord tensile shock absorber when operating in various modes by increasing its adaptability.

Claims (1)

A sleeve tensile damper containing a rubber-cord shell made in the form of a cylinder with an angle of reinforcing threads from 0 to 54 °, at each end compressed by flanges and mounting discs, filled with compressed gas and connected to a gas supply system, characterized in that in the inner cavity of the rubber-cord shell a flexible rubber diaphragm in the form of a closed cylinder is placed, hermetically attached to one of the mounting discs, connected to a separate power system and filled with liquid.

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