RU170717U1 - VIBRATION ISOLATING DEVICE - Google Patents

Abstract

The utility model relates to vibration isolation means and can be used in mechanical engineering, shipbuilding and other areas of technology to reduce the effect of equipment vibration activity on the object on which it is installed and on the environment. The technical result is the provision of effective vibration isolation of forced vibrations of equipment at medium and high frequencies with relatively smaller dimensions and a simplified design of the device, while protecting the elastic-dissipative elements from critical stresses The technical result is achieved by the fact that the vibration isolating device comprises rubber bushings, a rigid rod, a body made of metal or hard polymer with an internal cavity of a barrel-shaped or cone-shaped, collapsible along the transverse plane of symmetry, dividing the internal cavity of the case into two symmetrical cavities in which there are two elastic-dissipative elements made of rubber compound or thermoplastic elastomer, made in the form of asymmetrically truncated barrel-shaped or onus-shaped bushings with central holes close to each other by end surfaces with a larger area and mechanically connected to each other through a gasket of an elastomer that is more rigid than bushings made in the form of a ring with a central hole, while a rigid rod passes through the holes in the gasket and bushings preferably made of metal, on which restrictive washers of metal or hard polymer with thickenings directed inside the bushings and nuts that are used to tighten the elastic ipativnyh elements of the device to the nominal value of the static deformation and for mounting hardware to the antivibration device.

Description

The utility model relates to means of vibration isolation and can be used in mechanical engineering, shipbuilding and other areas of technology to reduce the effect of vibration activity of equipment on the object on which it is installed and on the environment.

It is known vibration-isolating device containing an elastic-dissipative element of a rubber-like material with a cavity, a rigid rod, coaxial with the cavity, two mushroom-shaped reinforcing elements, mechanically connected by a rod with an elastic-dissipative element, while the reinforcing elements are made of rigid polymeric material (RF patent for the invention No. 2151929, IPC ⁷ , F16F 1/36, Holland V.N., Gorbach V.D., Rozov N.A., Shlyapnikov S.A., Chizhov V.Yu., published on June 27, 2000).

A disadvantage of the known vibration-isolating device is the limitation in use under dynamic influences due to the lack of protection of the elastic-dissipative element from shock loads in the device.

Rubber-metal shock absorbers are also known (closest in technical essence to the proposed device), containing a rigid metal case with a cavity in the form of a cylinder, in which there are two persistent rubber bushings with fluoroplastic gaskets, to which two are pressed through metal plates on both sides with a metal rod supporting rubber bushings, (RF patent for the invention No. 2306462, IPC ⁷ , F16F 7/12, Tselishchev GP, Tsekhmestryuk GS, published September 20, 2007).

The use of well-known rubber-metal shock absorbers does not give advantages in vibration isolation of forced vibrations of equipment at medium and high frequencies due to their relative bulkiness and complexity.

The objective of the proposed vibration-isolating device is to ensure effective vibration isolation of forced vibrations of equipment at medium and high frequencies with relatively smaller dimensions and a simplified device design, ensuring the protection of elastic-dissipative elements from critical stresses and fractures under shock loads. Such a need arises in practice when equipment installed on standard shock absorbers of the AKCC type gives an excess in vibration velocity in individual sections of medium and high frequencies and requires additional damping.

In the proposed utility model, the indicated technical result is achieved in that the vibration isolating device comprises rubber bushings, a rigid rod, a body made of metal or hard polymer, with an internal cavity of a barrel-shaped or cone-shaped, collapsible along the transverse plane of symmetry, dividing the internal cavity of the housing into two symmetrical cavities, in which there are two elastic-dissipative elements made of rubber compound or thermoplastic elastomer, made in the form of asymmetrically truncated barrel-shaped whether there are cone-shaped bushings with central holes close to each other by end surfaces with a larger area and mechanically connected to each other through a gasket made of an elastomer that is more rigid than bushings made in the form of a ring with a central hole, while rigid passes through the holes in the gasket and bushings a rod, preferably made of metal, on which restrictive washers of metal or hard polymer with thickenings directed inside the bushings and nuts are used on both sides, which serve to tighten the elastic dissipative elements of the device and for fastening equipment to a vibration isolating device.

The proposed vibration-isolating device allows for effective damping of forced vibrations of equipment at medium and high frequencies, ceiling or deck mounting, providing insurance against equipment breakdown and protection of elastic-dissipative elements of the device from critical loads during impacts.

The essence of the proposed utility model is illustrated by the structural diagram of the vibration isolation device shown in FIG.

The vibration isolating device comprises a housing 1 of metal or a rigid polymer with an internal cavity 2 of a barrel-shaped or conical shape. The housing 1 is made collapsible along the transverse plane of symmetry, dividing the inner cavity 2 into two symmetrical cavities, in which there are two elasto-dissipative elements 3,4 of the rubber compound or thermoplastic elastomer, made in the form of asymmetrically truncated barrel-shaped or cone-shaped bushings with central holes close to each other each other end surfaces with a larger area and mechanically connected to each other through a strip 5 of elastomer more rigid than the sleeve 3, 4, made in the form of a ring with a central hole. A rigid rod 6 passes through the openings of the bushings 3, 4 and gasket 5, preferably of metal, on which restrictive washers 7, 8 of metal or hard polymer with thickenings directed inside the bushings 3, 4 and nuts 9, 10 are dressed on both sides for screed elastic-dissipative elements 3, 4, 5 of the device and for fastening equipment.

The vibration isolating device is attached to the object using the holes 11 in the housing 1.

The gasket 5, located between the bushings 3, 4, is made with a gap 12 between its lateral surface and the inner surface of the cavity 2 of the housing 1 with the unloaded condition of the vibration isolation device.

In the transverse plane of symmetry of the device, when it is unloaded, two annular cavities 13, 14 are coaxially formed, symmetrically separated by a gasket 5.

The proposed vibration-isolating device allows for effective damping of forced vibrations of the equipment along all axes, its ceiling and deck mounts with insurance against breakdown of the equipment under shock loads.

Indeed, when attaching the housing 1 of the vibration isolating device to the object using the holes 11 and attaching the equipment to the vibration isolating device using a rigid rod 6 and nut 9 (or an additional nut), a mechanical connection is formed between the equipment and the object through elastic-dissipative elements 3, 4, 5, in which the energy dissipation of the forced vibrations of the equipment occurs due to hysteresis losses inside the elastic-dissipative elements. The composition of the rubber mixture of elements 3,4, the choice of a particular rubber composition affects mechanical losses (tan δ is the tangent of the angle of mechanical losses) and is determined by the specific task of damping vibration of the equipment.

In practice, when using equipment with executive motors with a shaft rotation speed of 3000 rpm, there is a need for vibration damping at frequencies of 50 Hz and higher. The efficiency of damping the vibration velocity of the equipment when it is installed on vibration-isolating devices with rubber elastic-dissipative elements is characterized by the ratio:

where L _ν is the required decrease in the amplitude of the vibration in dB;

- частота вибрационных колебаний в Гц;

- frequency of vibrational vibrations in Hz;

- собственная резонансная частота оборудования на виброизоляторах в Гц.

- natural resonant frequency of the equipment on vibration isolators in Hz.

эффективность демпфирования будет в оптимальной зоне по коэффициенту передачи и эксплуатационным характеристикам виброизолирующего устройства. Поэтому, для демпфирования вибрации с частотой 50 Гц и выше необходимо определять размеры виброизолирующего устройства, их количество, состав резиновой смеси упругодиссипативных элементов, ориентируясь на собственную частоту свободных колебаний оборудования на виброизоляторах в пределах 10-15 Гц:With the ratio

the damping efficiency will be in the optimal zone in terms of transmission coefficient and operational characteristics of the vibration isolating device. Therefore, to damp vibration with a frequency of 50 Hz and above, it is necessary to determine the dimensions of the vibration isolating device, their quantity, the composition of the rubber mixture of elastically dissipative elements, focusing on the natural frequency of free vibrations of the equipment on vibration isolators within 10-15 Hz:

where K is the total stiffness of the vibration isolators in N / m;

m is the mass of equipment in kg,

wherein

where Δ is the total static deformation (draft) of vibration isolators in the metro (V.T. Lyapunov, E.E. Lavendel, S.A. Shlyapochnikov. Rubber vibration isolators. Shipbuilding, L., 1988).

≤15 Гц практически не вызывает трудности в его реализации при использовании известных резиновых смесей, например, марки ИРП-1347.Based on the foregoing, for effective vibration damping of equipment at medium and high frequencies, a vibration isolating device with a nominal static load, for example 400 kG, with a static deformation of 1.5-2 mm with a device's overall dimensions of 60 * 60 * 40 mm (Fig.) And a resonant frequency

≤15 Hz practically does not cause difficulties in its implementation when using well-known rubber compounds, for example, grade IRP-1347.

The use of a gasket 5 from a more rigid elastomer allows nonlinearity of the elastic characteristics of the vibration isolating device under dynamic stresses, for example, during transients, when the gap 12 is selected (the free run of the gasket 5 is completed in radial or axial directions) and the gasket 5 works for bending and compression. The gasket 5 protects the rubber bushings 3, 4 from additional stresses during transients and allows you to reduce the free movement of the rod 6.

To reduce stresses inside the elastic-dissipative elements 3, 4 during dynamic and shock impacts, the device has two annular cavities 13, 14 symmetrically separated by a gasket 5, which allows parts of the rubber mixture of the bushings to flow into them, removing internal critical stress.

When impacted to protect the elastic-dissipative elements 3, 4, 5 from destruction and insurance of the equipment from disruption, the rigid rod 6, through the thrust washers 7, 8, rests against the housing 1 after completing the free run and ensures reliable fastening of the equipment.

The collapsible housing 1 of the vibration-isolating device makes it relatively easy to change the elastic-dissipative elements 3, 4, 5 during operation upon completion of their resource.

Using the proposed vibration isolating device allows to obtain a technical and economic effect by simplifying the technology of its manufacture and operation with effective damping of equipment vibration at medium and high frequencies.

Claims (3)

1. A vibration-isolating device comprising a rigid body with a cavity, rubber bushings, a rigid shaft, characterized in that the body is made of metal with a barrel-shaped internal cavity, collapsible along the transverse plane of symmetry, dividing the internal cavity of the body into two symmetrical cavities, in which two elastic-dissipative elements made of rubber compound, made in the form of asymmetrically truncated barrel-shaped bushings with central holes, close to each other by end surfaces with a larger plane sparingly and mechanically connected to each other through a gasket made of an elastomer which is more rigid than a sleeve, made in the form of a ring with a central hole, and through the holes in the gasket and the bushings there passes a rigid rod, preferably made of metal, on which restrictive washers from both sides are worn metal with thickenings directed inside the bushings, and nuts, used to tighten the elastic-dissipative elements of the device and for fastening the equipment to a vibration-isolating device. 2. Vibration isolating device according to claim 1, characterized in that the gasket located between the bushings is made with a gap between the outer side surface of the gasket and the inner surface of the cavity of the housing when the device is not loaded. 3. The vibration isolating device according to claim 1, characterized in that in the transverse plane of symmetry of the device, when it is unloaded, two annular cavities are coaxially formed, one of which is located between the outer surfaces of the bushings and the inner surface of the cavity of the housing, and the other between the inner surfaces bushings and the rod, while the cavity is symmetrically separated by a gasket located between the bushings.

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