RU2662357C1 - Vibration isolator with mesh damper - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to the machine building. Vibration isolator contains a frame made in the form of two supporting horizontal plates, resting against the left and right elastic elements upper covers, respectively. Horizontal plates are rigidly connected to the vertical plates, which in the frame lower part are connected together by the base plate. Platform for the vibration-insulated object is installed onto the base plate through the vibration damping gasket and vertical post. Left elastic element is made in the form of washer mesh damper. By the lower part the damper main mesh elastic element rests on the base and is fixed by the bottom washer, and by the upper part is fixed by the upper pressure washer. Lower plate is connected to the base, made in the form of plate with mounting holes. Upper pressure plate is connected to the centrally located piston, covered with a gap by the connected to the base coaxially located sleeve. Between the piston lower end and the sleeve bottom the elastic element is located. Right elastic element is made in the form of vibration damping spring comprising body made of helical hollow elastic steel tube. Inside the body the additional elastic steel tube is located with the gap. In the gaps between the tubes the polyethylene friction element is located. Coaxial to the body the helical solid elastic rod is arranged.

EFFECT: enabling increase in the vibration isolation efficiency at resonance.

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Description

The invention relates to mechanical engineering, namely to spring vibration isolators used to reduce vibration.

The closest technical solution to the claimed object is a shock absorber according to the USSR copyright certificate for invention No. 916805, class. F16F 1/06, published 04/05/1982 (prototype), containing a cylindrical helical spring, consisting of two parts with opposite ends, one part of which has turns of rectangular cross section, and the other part of the spring is hollow, with the opposite direction of the end of the first part placed in the cavity of the second.

A disadvantage of the known device is the relatively low efficiency at resonance due to the absence of vibration damping.

The technical result is an increase in the efficiency of vibration isolation at resonance.

This is achieved by the fact that in a vibration isolator with a mesh damper containing a frame connecting in parallel two elastic elements of different designs but of the same stiffness, designed for highly loaded vibration isolation systems, the frame is made in the form of two horizontal support plates resting on the upper covers, respectively, of the left and the right elastic elements, the horizontal plates of the frame are rigidly connected to the vertical plates, which in the lower part of the frame are interconnected between the base plates d, on which a platform for a vibroinsulated object is installed through a vibration damping pad and a vertical strut, while the left elastic element is made in the form of a washer mesh elastic element that contains a base, an elastic mesh element and washers interacting with the bushings, the base is made in the form of a plate with fixing holes, the main mesh elastic element, the lower part rests on the base and is fixed with the lower washer, rigidly connected to the base, and the upper part is fixed with the upper with a washer rigidly connected to a centrally located piston, covered with a gap, coaxially located by a sleeve rigidly connected to the base, and between the lower end of the piston and the bottom of the sleeve there is an elastic element, the elastic element between the lower end of the piston and the bottom of the sleeve is made of a combined mesh frame, filled with an elastomer, for example polyurethane, or mesh, with the parameters of the mesh structure as the main elastic mesh element, and the right elastic element is made in the form of a vibration damping spring, comprising a housing made of a helical, hollow, and elastic steel tube, inside of which at least one additional elastic steel tube is coaxially and axisymmetrically installed with a gap, and at least one friction element having a high coefficient of thermal expansion is located in the gaps between the tubes compared with steel, while the surfaces of the housing and the additional elastic steel tube are in contact with the surfaces of the friction elements, and their axes coincide with the axis of the turns of the housing, at centrally, coaxially and axisymmetrically to the housing, there is a solid elastic screw rod, the friction element is made in the form of a granular bed of sintered friction material based on copper, which contains zinc, iron, lead, graphite, vermiculite, copper, chromium, antimony and silicon in the following ratio of components, wt.%: zinc 6.0 ÷ 8.0; iron 0.1 ÷ 0.2; lead 2.0 ÷ 4.0; graphite 3.0 ÷ 7.0; vermiculite 8.0 ÷ 12.0; chrome 4.0 ÷ 6.0; antimony 0.05 ÷ 0.1; silicon 2.0 ÷ 3.0; copper is the rest.

In FIG. 1 shows a general view of a vibration isolator with a mesh damper; FIG. 2 shows an embodiment of a vibration damping pad 8, a frontal section of an arched type rubber vibration isolator, FIG. 3 - view from above.

The vibration isolator with a mesh damper contains a frame connecting two parallel elastic elements of different design but of the same stiffness in parallel, designed for highly loaded vibration isolation systems. The frame is made in the form of two horizontal supporting plates 3 and 6, based on the left 1 and right 2 (in the plane of the drawing) elastic elements, respectively. The horizontal plates 3 and 6 of the frame are rigidly connected to the vertical plates 4 and 5, which are connected to each other in the lower part of the frame by a base plate 7, on which a platform 10 for a vibroinsulated object (not shown) is installed through a vibration damping pad 8 and a vertical rack 9.

The left elastic element 1 (see the plane of the drawing on the left) is made in the form of a washer mesh elastic element, which contains a base 11 in the form of a plate with mounting holes 12, a main mesh elastic element 17, the lower part resting on the base 11, and fixed by the lower washer 16 rigidly connected to the base 11, and the upper part is fixed by the upper pressure washer 15, rigidly connected to the centrally located piston 14, covered with a gap, coaxially located sleeve 13, rigidly connected to the base 11. Between the lower the end face 18 of the piston 14 and the bottom 19 of the sleeve 13 is an elastic element 20, for example of polyurethane.

The density of the mesh structure of the elastic mesh element is in the optimal range of values: 1.2 ... 2.0 g / cm ³ , and the material of the wire of the elastic mesh elements is steel EI-708, and its diameter is in the optimal range of 0.09 mm. ..0.15 mm. The density of the mesh structure of the outer layers of the elastic mesh element is 1.5 times higher than the density of the mesh structure of the inner layers of the elastic mesh element. The main elastic mesh element 17 can be made combined of a mesh frame, filled with an elastomer, for example polyurethane.

It is possible that the elastic element 20, located between the lower end face 18 of the piston 14 and the bottom 19 of the sleeve 13 is made mesh, with the same parameters of the mesh structure as the main elastic mesh element 17.

It is possible that the elastic element located between the lower end of the piston and the bottom of the sleeve is made mesh, and the density of the mesh structure is 1.5 times higher than the density of the mesh structure of the main elastic mesh element.

It is possible that the elastic element located between the lower end of the piston and the bottom of the sleeve is made combined of a mesh frame filled with an elastomer, for example polyurethane.

The washer mesh elastic element operates as follows.

When vibrations of a vibroinsulated object (not shown in the drawing) located on the upper pressure plate 15, the elastic mesh element 17 perceives both vertical and horizontal loads, thereby weakening the dynamic effect on the vibroisolated object, i.e. spatial vibration protection and shock protection are provided.

The left elastic element 1 and the right elastic element 2 are mounted respectively on the vibration damping plates 21 and 22. The right elastic element 2 (see the plane of the drawing to the right) is made in the form of a vibration damping spring containing a housing 23 made of a helical, hollow, and elastic steel tube, inside of which at least one additional elastic steel tube 25 is coaxially and axisymmetrically installed with a gap, and at least one friction element 24, for example, made of polyethylene, is located in the gaps between the tubes present a high coefficient of thermal expansion compared to steel. The surfaces of the housing 23, the additional elastic steel tube 25 are in contact with the surfaces of the friction elements 24 and 26, and their axis coincides with the axis of the turns of the housing. Centrally, coaxially and axisymmetrically to the housing 23, is located a screw elastic rod 27, which can also be made as a housing and additional elastic steel tubes hollow, as shown in the drawing, or solid (not shown). Friction elements 24 and 26 can be made tubular as shown in the drawing, while having either a continuous structure, for example of polyethylene, as element 26, or combined, as element 24, for example, of polyethylene interspersed with granules of vibration-damping material. A variant is possible when the friction element is made in the form of a granular backfill from vibration damping material (not shown in the drawing).

A variant is possible when the screw elastic rod 27 is made in the form of a helical spring with a step less by 5 ÷ 10% of the step of the helical line of the housing 23 to create an interference fit that provides the functional purpose of the friction elements 24 and 26.

It is possible that the friction element is made in the form of a granular bed of sintered friction material based on copper, which contains zinc, iron, lead, graphite, vermiculite, copper, chromium, antimony and silicon, in the following ratio of components, wt. %: zinc 6.0 ÷ 8.0; iron 0.1 ÷ 0.2; lead 2.0 ÷ 4.0; graphite 3.0 ÷ 7.0; vermiculite 8.0 ÷ 12.0; chrome 4.0 ÷ 6.0; antimony 0.05 ÷ 0.1; silicon 2.0 ÷ 3.0; copper is the rest.

A vibration isolator with a mesh damper operates as follows.

At low vibration amplitudes, when large attenuation is undesirable, the dissipated energy due to dry friction between the steel tube and the friction element will be small. At large amplitudes of vibrations, especially at resonances, damping increases due to the relative movement of steel tubes and a friction element, which ensures effective spatial vibration isolation of equipment in all six directions of vibrations (along three axes X. U, Z and rotational vibrations around these axes) with damping oscillations at resonance.

It is possible that the vibration damping pad 8, located between the base plate 7 of the frame and the vertical strut 9 connected to the platform 10 for installing a vibration-insulated object (not shown in the drawing), is made in the form of a rubber vibration insulator of the arch type (Fig. 2, 3)

An arch-type rubber vibration isolator comprises a body made in the form of an upper plate 28 with mounting 34 and fixing 35 holes, supported by the upper end of the elastic element 30. The lower plate 29 is made of a trough-like shape, with side plates 33 and holes for attachment to the base. The profile of the lateral surfaces of the elastic element 30 is made hyperbolic in the form of a bar of equal resistance, having constant stiffness in the axial and transverse directions and includes a conical surface 31 along the entire length and hemispherical 32. The ratio of the width of the vibration isolator A to its height B is in the optimal ratio of values : A / B = 1.4 ... 1.5, and the ratio of the length of the bottom plate D to the length of the top plate C is in the optimal ratio of values: D / C = 1.4 ... 1.7.

Rubber vibration insulator arch type works as follows.

With vibrations of the vibration-insulated object, the elastic rubber element 30 perceives vertical loads, thereby weakening the dynamic effect on the floors of buildings or on board an aircraft or a mobile vehicle. Horizontal vibrations are damped due to the unrestricted location of the elastic element, which gives it a certain degree of freedom of vibrations in the horizontal plane. The profile of the lateral surfaces of the elastic element is hyperbolic in the form of a bar of equal resistance, having constant stiffness in the axial and transverse directions, allows for equal strength and economy of rubber (elastomer).

Claims (2)

1. Vibration isolator with a mesh damper, comprising a frame connecting in parallel two elastic elements of different designs but of the same stiffness, designed for highly loaded vibration isolation systems, the frame is made in the form of two horizontal supporting plates resting on the upper covers of the left and right elastic elements , the horizontal plates of the frame are rigidly connected to the vertical plates, which in the lower part of the frame are interconnected by a base plate, onto which through a platform for a vibroinsulated object is installed for the damping pad and the vertical strut, while the left elastic element is made in the form of a washer net elastic element that contains a base, an elastic net element and washers interacting with the bushings, the base is made in the form of a plate with fixing holes, the main net elastic the element is supported by the lower part on the base and fixed by the lower washer, rigidly connected to the base, and the upper part is fixed by the upper pressure washer, rigidly connected with a centrally located piston, covered with a gap by a coaxially located sleeve rigidly connected to the base, and between the lower end of the piston and the bottom of the sleeve there is an elastic element, the elastic element between the lower end of the piston and the bottom of the sleeve is made of a combined mesh frame filled with an elastomer, for example polyurethane , or mesh with the parameters of the mesh structure, as in the main elastic mesh element, and the right elastic element is made in the form of a vibration-damping spring containing a housing, made of a screw hollow and elastic steel tube, inside of which at least one additional elastic steel tube is coaxially and axisymmetrically installed with a gap, and at least one friction element is located in the gaps between the tubes, which has a high coefficient of thermal expansion compared to steel, at the surfaces of the housing and the additional elastic steel tube are in contact with the surfaces of the friction elements, and their axes coincide with the axis of the turns of the housing, while being centrally coaxial and axisymmetrically located to the body is a screw elastic rod made in a continuous manner, the friction element is made in the form of a granular bed of sintered friction material based on copper, which contains zinc, iron, lead, graphite, vermiculite, copper, chromium, antimony and silicon in the following ratio of components, wt .%: zinc 6.0 ÷ 8.0; iron 0.1 ÷ 0.2; lead 2.0 ÷ 4.0; graphite 3.0 ÷ 7.0; vermiculite 8.0 ÷ 12.0; chrome 4.0 ÷ 6.0; antimony 0.05 ÷ 0.1; silicon 2.0 ÷ 3.0; copper the rest. 2. A vibration isolator with a mesh damper according to claim 1, characterized in that the vibration damping gasket located between the base plate of the frame and the vertical strut connected to the platform for installing the vibration-insulated object is made in the form of an arch-type rubber vibration isolator containing a body and an elastic element made of elastomer interacting with the object, while the housing is made in the form of an upper plate with mounting and mounting holes, supported by the upper end of the elastic element, and the lower plate, made trough shaped with holes for attaching to the base, and the profile of the side surfaces of the elastic element is made hyperbolic in the form of a bar of equal resistance having constant stiffness in the axial and transverse directions, and the ratio of the width of the vibration isolator A to its height B is in the optimal ratio of values: A / B = 1.4 ... 1.5, and the ratio of the length of the lower plate D to the length of the upper plate C is in the optimal ratio of values: D / C = 1.4 ... 1.7.

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