SU1320559A1 - Vibration damper - Google Patents

Abstract

This invention relates to the damping of machinery and mechanisms. The aim of the invention is to increase the vibration damping efficiency by automatically changing the gap between the perforated diaphragm and the free surface of the bulk material, regardless of the diaphragm's inductance, as well as the reliability of the absorber due to the absence of movable rubbing surfaces. The vibration absorber contains a hollow body 1, partially filled with bulk material 2, which, with an increase in excitation intensity, is partially throttled through the perforated diaphragm 4 from the working chamber 5 into the auxiliary chamber 6, as a result of which the gap between the upper boundary of the bulk material and the diaphragm 4 automatically changes the parameters that ensure the optimal damping of vibrations at various levels of excitation intensity are maintained most automatically. 1 hp f-ly, 2 ill. S CO oo o ate with Fig.1

Description

FIELD OF THE INVENTION The invention relates to mechanical engineering, namely, to means of damping vibrations of machines and mechanisms.

The aim of the invention is to increase vibration damping by automatically changing the gap between the perforated diaphragm and the free surface of the bulk material, regardless of the inertia of the diaphragm, as well as improving the reliability of the absorber by automatically changing the gap between the perforated diaphragm and the free surface of the bulk material, as well as improving reliability work absorber due to movable sliding surfaces.

FIG. 1 shows a vibration absorber, a longitudinal section; in fig. 2 is a graph showing the dependence of the absorption coefficient f on the excitation intensity level X, where curve 1 is for the described vibration absorber, curve 2 is for the prototype.

The vibration absorber contains a hollow body 1, partially filled with bulk material 2, and a cover 3. Inside the case 1, the perforated diaphragm 4 is mounted for axial movement, the partition of the internal cavity of the body to the working chamber 5 and the secondary chamber 6.

Each of the holes 7 of the diaphragm 4 is made in the form of two symmetrical cones facing each other with smaller bases, connected by a cylinder, the diameter DI of which is equal to 1.2-1.5 of the maximum overall particle size of the bulk material, and the diameter D2 of the larger base of the cone double the value of the same particle size, which orients the particle and ensures its free mono passage without jamming. The vibration absorber is mounted on a vibration-proof object 8.

Vibration absorber works as follows.

Before attaching the vibration absorber to the object 8, the perforated diaphragm 4 is set to the position corresponding to the optimal gap between it and the free surface of the bulk material at excitation intensity levels corresponding to the lower boundary of the specified absorber effective range.

When the object 8 is vibrated, effective damping of the oscillations begins at the excitation level at which the maximum acceleration of the absorber due to vibration

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object, more accelerated free fall.

With increasing excitation intensity, part of the bulk material is throttled through the perforated diaphragm 4 from the working chamber 5 into the auxiliary chamber 6, which is equivalent to changing the gap between the upper boundary of the bulk material 2 in the absence of vibrations and the diaphragm 4 limiting the volume of the working chamber 5 to absorb 0 l of vibrations. This establishes a dynamic equilibrium, which determines the magnitude of the optimal gap between the bulk of the bulk material 2, located in the working chamber 5 and the perforated diaphragm 4, thereby automatically maintaining the parameters that ensure optimal damping of vibrations at different levels of excitation intensity X.

From the graph (Fig. 2) it can be seen that with increasing excitation intensity, the absorption coefficient φ in this absorber increases (curve I), while in the prototype (curve 2) with increasing x, the absorption coefficient φ reaches some maximum value decreases. This shows that with increasing excitation intensity X, the absorption coefficient i |) in the absorber with a perforated diaphragm increases, which characterizes the efficient operation of the absorber in a wide range of excitation intensity levels.

Effective damping of oscillations in a wide range of excitation intensity levels increases the reliability and durability of machines and mechanisms operating under conditions of increased vibration loading.

Claims (2)

1. A vibration absorber comprising a hollow body partially filled with a bulk material and a lid that, in order to increase vibration damping and reliability of the absorber, it is equipped with a perforated diaphragm installed within the body with the possibility of axial mixing. 2. The vibration absorber according to claim I, characterized in that each of the orifices of the diaphragm is made in the form of two facing each other with smaller bases of symmetrical cones connected by a cylinder, The diameter of which is chosen to be 1.2-1.5 of the maximum overall size of the particle of the bulk material, and the diameter of the larger base of the cone is equal to twice the value of the same overall particle size. 0 five 0 five