SU1190111A1 - Vibration isolator - Google Patents

Abstract

VIBROIZOLATOR containing two coaxially installed equal-frequency conical springs, facing large bases to each other, a spacer sleeve and a damping device, including a friction sleeve with a flange and interacting with the flange preloaded elastic elements, characterized in that, in order to improve the quality of vibration isolation, transverse load by detuning from resonance; elastic elements are made in the form of conical springs supported on the flange by smaller bases, the diameter of which is larger than dia tra friction sleeve. (L; o

Description

The invention relates to mechanical engineering and is intended, in particular, to protect the components and blocks of radioelectronic equipment from vibration and shock.

The aim of the invention is to improve the quality of vibration isolation under transverse load by detuning from resonance.

The drawing shows a diagram of the vibration isolator.

The vibration isolator contains coaxially mounted equal-frequency conical springs 1, the bases of which face each other and are enclosed in an annular holder 2 consisting of two fixing flanges 3, a spacer 4 passing through the opening of the holder 2, a damping device located in the opening of the holder 2 comprising a friction sleeve 5 with a support flange 6, pressed against the outer surface of the spacer sleeve 4 by spring rings 7 and formed by at least three sectors with gaps between them, and springs 8 interacting with the flag 6 CEM and pressed bases conical springs supporting schaybe 1 to 9. The springs 8 are made conical, and the diameter of the base mensche Large Live diameter 5 of the friction sleeve.

Vibration isolator works as follows.

When exposed to a load parallel to the axis of the vibration isolator outside the resonance region where the overload is reduced, the parallel connected springs 1 and 8 operate. The friction sleeve 5 does not move. The natural frequency of the device is determined by the total stiffness of the springs 1 and 8. In the region of resonance, the overload increases, starting at some moment the springs 8 begin to move the friction bushing 5, and also slip with friction over the surface of the support flange 6. The natural frequency of the device changes and determines It is only the spring stiffness 1.

Thus, there is a detuning from the resonance without deterioration of the vibration-insulating properties.

Under the action of the load in the transverse direction, when the value does not exceed

the force of friction in the contact between the springs 8 and the flange 6, the natural vibration frequency of the vibration isolator, as in the first case, is determined by the transverse rigidity of the springs I and 8. At the resonant frequency, the loads increase and, starting with some

moment, the ends of the springs 8 begin to slip along the flag 6, and the natural frequency will be determined only by the transverse stiffness of the springs 1, which leads to a detuning from the resonance.

When the load is applied at an angle to the axis of the vibration isolator, the detuning from resonance will occur both due to the movement of the sleeve 5, and due to the slippage of the springs 8 along the flange 6.

Thus, the introduction of conical

the springs 8 allows for a detuning from the resonance under the spatial influence of the load.

Claims (1)

VIBRATOR, comprising two coaxially mounted equal-frequency conical springs facing large bases to each other, a spacer sleeve and a damping device including a friction sleeve with a flange and interacting with the flange pre-pressed elastic elements, characterized in that, in order to improve the quality of vibration isolation under transverse load by detuning from resonance, the elastic elements are made in the form of conical springs resting on the flange with smaller bases whose diameter is larger than the diameter f friction sleeve.