SU1465655A1 - String vibration isolator - Google Patents

Abstract

The invention relates to the construction and engineering industries and can be used to protect the building structures of buildings and structures from vibration, as well as elastic-damping elements in the structures of vibration dampers. The aim of the invention is to increase damping. The cylindrical spring 1 perceives a static effect from the mass of the equipment mounted on the spring vibration isolator, with axial oscillations of which the coil with the damping element 2, having a rectangle shape in cross section, makes torsional vibrations. Due to the large polar moment of inertia of the cross section of the damping coating, due to its high coefficient of inelastic resistance, the vibration insulator is oscillated, i.e. with damping. 1 cl. S (L O) O1 Oud ate

Description

The invention relates to the construction and engineering industries and can be used to protect the building structures of buildings and structures from the effects of vibrations, as well as to the elastic-damping elements in the structures of vibration dampers.

The aim of the invention is to increase the damping of vibrations due to the structural design of the vibration insulator elements.

On,: the drawing schematically shows the proposed device, the cross-section.

The spring-loaded vibration isolator includes a spring 1 and a damping element 2 fixed throughout its entire length in a cross-section in the form of a rectangle, the larger side of which is perpendicular to the axis of the spring.

The height of the section is determined from the condition of obtaining the necessary inelastic resistance coefficient of the vibration isolator and preserving the value of the axial deformability of the spring.

The value of the inelastic resistance coefficient of the composite elastic element is calculated by the formula llG lLiJi24Xi. (one)

Have

G, Y, + YiGi

where G,, Gj. - shear moduli, respectively, of the spring material and damper material; Y /, YJ. - the polar moments of the iner times, respectively, of the section of the spring coil and the section of the dethere. Since the polar moment of inertia does not depend on the orientation of the cross section, to obtain the necessary clearance between the turns and the required coefficient of inelastic resistivity, the section is extended. This follows from formula (1), if it is represented as

,,

TO

 Gj

IG

1 +

- (1 +

r-rf-. (2)

bi) a

five

0

five

0

five

where a is transverse

b - longitudinal dimensions of the cross section.

From formula 2 it follows that increasing the ratio of the longitudinal size of the cross section to the transverse, the coefficient of inelastic resistance of the vibration insulator tends to | A.

Polystyrene textolite is used as a damping material. This material does not corrode, has sound absorbency, adheres well to metals, is stamped and retains its damping properties for a long time.

Spring vibration isolator works as follows.

The static effect of the weight of the equipment mounted on the spring vibration isolator, perceives a cylindrical spring 1, with axial oscillations of which a coil with damping element 2 performs torsional vibrations. Due to the large polar moment of inertia of the damping coating section and its high inelastic resistance coefficient compared to steel, the vibration isolator vibrations are carried out with the absorption of the vibration energy i.e. with damping.

By changing the shape of the damping element 2, the absorption energy of the spring vibration isolator can be changed.

Claims (1)

Invention Formula A spring-loaded vibration isolator containing a spring and a damping element fixed along its entire length, distinguished by the fact that, in order to increase damping, the damping element is suspended in cross-section in the form of a rectangle, the larger side of which is perpendicular to the axis of the spring.