RU1768815C - Vibration isolator - Google Patents

Abstract

Usage: mechanical engineering, namely, complex shock-absorbing structures. SUMMARY OF THE INVENTION: A vibration isolator comprises a body filled with viscous liquid, a spring and a support cover. The coils of the spring are covered by a cover of elastic porous material. The cover has fins in length, 3 il.

Description

The invention relates to the field of mechanical engineering, namely to complex shock-absorbing structures.

A spring vibration isolator is known, comprising a coil spring of variable cross-section, the variable cross-section is formed by tubular sections worn on coils of constant diameter.

A hydromechanical vibration isolator is also known, comprising a main hydraulic cylinder, a piston with seals in it, connected to an object, an additional cylinder of a smaller diameter with a piston, piston cavities of which are communicated by a channel, a counterload mounted on the piston of the additional cylinder, and a spring.

A disadvantage of the known vibration isolators is the low de-delphination of oscillations at resonant modes of operation and under pulsed influences.

The aim of the proposed invention is to increase the damping efficiency in resonance modes and under pulsed influences.

The goal is achieved in that the vibration isolator is provided with a cover made of elastic porous material covering the spring coils, having fins along the length, discretely located on the spring coils.

In FIG. 1 shows a vibration isolator; in FIG. 2 - spring with a cover, a longitudinal section; in FIG. 3 is a view along arrow A in FIG. 1, without cover.

The vibration isolator comprises a spring 1, bearing caps 2, a cylinder with a viscous liquid 3, a cover 4, mounted on the spring with fin-like ends of the cover 5.

In statics, the proposed vibration isolator works as follows: when a static load is applied, the spring is compressed to a working state. At the same time, due to the discrete arrangement along the coils of the spring, the fin-shaped ends 5 remain in a free, unloaded state.

Vibroinsulator works as follows:

at resonance modes, including wave resonances, or as a result of

with

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With

ate

pulse action, the coils of the spring oscillate with large amplitudes. In this case, the fin-like ends 5 of the cover 4 due to the oscillations of the spring coils and resistance to the viscous fluid make wave-like movements in the viscous fluid. The increase in vibration damping is determined by the fact that, along with the viscous friction of the spring coils in the fluid and the friction of the cover Spring turns characteristic of known vibration isolators during wave-like motion of fin-shaped ends result in viscous friction in materials of fusilliform ends, and viscous friction in the flow around a porous material and fin-like endings with fluid.

At the same time, an essential feature of the proposed solution is that the transfer of viscous fluid forces in the direction of the spring axis due to the flexibility of the flame-like ends when pulsed and the maximum amplitudes of the resonance modes is much less than, for example,

similar vibrations in the fluid of a porous piston.

Fin-shaped endings can be located one-sidedly, for example, only inside the spring, which will reduce the dimensions of the vibration isolator.

Foamed polystyrene, polyurethane foam, and other materials can be used as a cover material with fin-shaped ends, and at small amplitudes of oscillations in the Zarazonan zone, the delamination increases slightly and will not significantly affect the efficiency of vibration isolation in this zone.

Claims (1)

The claims A vibration isolator comprising a housing filled with a working fluid in the form of a cup, a helical spring placed therein and a support cover resting on it, characterized in that, in order to increase the damping efficiency in resonance modes and during pulsed influences, it is provided with a cover made of spring coils made of elastic porous material with fins in length. / AND I ,,, - „; l U ///// // Х / / 7 // А /// 7 Л .. „,:.„ ... AND  -5 Fia1 1 FIG. I SpeciesA