RU2643065C1 - Rubber-metal vibration isolation device - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: invention relates to mechanical engineering. Device comprises of inner and outer tubular profiles joined at the top with a plug made in the form of a bushing. Vibration isolator is made in the form of a coil spring with a flange. Viscoelastic shell is installed in the gap between the tubular profiles and is connected by hot vulcanization with the bushing, spring and flange. Spring is permanently connected to the bushing and flange by means of screw grooves formed on them and fixed in places of connection with them by fixing elements. Between the upper bushing and the lower flange, an additional resilient element is provided, containing the lower and upper support plates. Between the plates coaxially the external with right and internal with left angles of turns rise springs are installed. Bottom support plate is base on which the bottom flanges of springs are rigidly secured. Between the top support plate and top flange of the internal spring the dry friction damper is installed. Damper consists of two contacting cylindrical discs. Bottom disc is rigidly linked with top flange of the internal spring. Top disc is rigidly linked with the top support disk. On facing each other surfaces of discs the concentric diametric grooves and inserted in them shoulders are made.

EFFECT: increased efficiency of vibration isolation in resonance mode is being achieved.

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Description

The invention relates to mechanical engineering, in particular to rubber-metal vibration isolators.

The closest technical solution to the claimed object is a vibration isolator according to the patent of the Russian Federation No. 2324086, F16F 15/07 (prototype), containing inner and outer tubular profiles connected in its upper part with a plug made in the form of a sleeve, a vibration isolator made in the form of a coil spring with a flange, and a viscoelastic shell installed in the gap between the tubular profiles and connected mainly by hot vulcanization with a sleeve, spring and flange.

The disadvantage of the prototype is the relatively low efficiency of vibration isolation in resonance mode at low frequencies due to the cramped location of the spring in the viscoelastic shell.

EFFECT: increased efficiency of vibration isolation in resonance mode by increasing “dry” damping in the system.

This is achieved by the fact that in a rubber-metal vibration-isolating device containing inner and outer tubular profiles connected in its upper part to a plug made in the form of a sleeve, a vibration isolator made in the form of a coil spring with a flange and a viscoelastic shell installed in the gap between the tubular profiles and connected mainly by hot vulcanization with a sleeve, a spring and a flange, the spring is inseparably connected to the sleeve and a flange by means of helical grooves made on them and fixed in m the connection of fixing elements with them, while the latter are mainly connected by means of hot vulcanization with a viscoelastic shell, between the upper sleeve and the lower flange an additional elastic element with a dry friction damper is installed, consisting of a lower and an upper support plate, between which are coaxially and concentrically mounted outer, with a right angle of rise of coils, and internal with a left angle of rise of coils, springs, while the lower base plate is the base on which the lower flanges The springs are fixed rigidly, and between the upper support plate and the upper flange of the internal spring with the left angle of the coil lifting, there is a dry friction damper consisting of two lower and upper cylindrical disks in contact with each other, while the lower disk is rigidly connected to the upper flange of the inner springs, and the upper disk is rigidly connected to the upper support plate, while concentric diametrical grooves are made on one of the disks on the surfaces of the cylindrical disks of the dry friction damper facing each other sills and protrusions on another disk, which enter into each other, and sintered friction material based on copper containing zinc, iron, lead, graphite, vermiculite, copper, chromium can be used as materials for the lower and upper cylindrical disks of the dry friction damper , 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 rubber-metal vibration isolating device, FIG. 2 - an additional elastic element with a dry friction damper located between the upper sleeve 3 and the lower flange 5.

The rubber-vibration isolating device comprises inner and outer 2 rubber conical or cylindrical tubular profiles made of rubber, connected in their upper part to the sleeve 3, respectively to the tubular profiles 1 and 2 of the spring 4 with the flange 5, and a viscoelastic shell 6 installed in the gap between the tubular profiles 1, 2 and connected mainly by hot vulcanization with a sleeve 3, a spring 4 and a flange 5. The upper and lower parts of the spring 4 can be made of cylindrical shape, and its middle (working) part is con personal. The spring 4 is connected to the sleeve 3 and the flange 5 by means of screw grooves 7, 8 made on them and fixed at the points of connection with them by fixing elements 9, 10, made, for example, in the form of ring elements. The locking elements 9, 10 are mainly connected by hot vulcanization with a viscoelastic sheath 6. The fixing element 9 may have slots for holding with a wrench when connecting the vibration isolating device to the equipment.

Rubber vibration isolation device operates as follows.

The load (tension, compression, shear, bending, or a combination thereof) acts through the sleeve 3 and flange 5 on the tubular profiles 1, 2, spring 4 and viscoelastic shell 6, which are interconnected by hot vulcanization and form a rubber-metal shell reinforced with spring 4. Under the action of the load, the device is deformed, the coils of the conical spring 4, due to different diameters, have different stiffnesses, therefore they are deposited in different ways: first, the lower coil is deformed, then the next one in height, etc. Due to the indicated properties of the spring 4, the load characteristic of the device (the dependence of the draft on the force) is nonlinear, which has a positive effect under the action of shock loads, which are effectively suppressed by the device.

Under the action of the load, the coils of the spring 4 are twisted, leading to significant shear deformation of the layers of the rubber shell 6 and profiles 1 and 2, which are cured firmly connected to the coils of the spring 4.

When exposed to vibrations or shock loads, these deformations increase while being cyclic, which significantly enhances the vibration absorption of the device, providing a reduction in the level of vibration in the frequency range up to 100 Hz by an average of 15 dB and in the frequency range from 100 to 10000 Hz from 20 to 40 dB .

The turns of the upper part of the spring 4 are fixed in the screw groove 7 of the sleeve 3 by the locking ring 9, and the turns of the lower part of the spring 4 are fixed in the screw groove 8 of the flange 5 by the locking ring 10. This ensures a reliable connection of the spring 4 with these elements under any type of load.

A variant is possible (Fig. 2), when an additional elastic element with a dry friction damper is installed between the upper sleeve 3 and the lower flange 5, consisting of the lower 11 and upper 12 support plates, between which the outer 15 is coaxially and concentrically mounted, with the right angle of elevation of the turns , and the inner 16 with the left corner of the coil, spring. The lower support plate 11 is the base on which the lower flanges of the springs 15 and 16 are fixed rigidly, and is located between the upper support plate 12, on which the vibration-insulated object is mounted (not shown in the drawing), and the upper flange of the internal spring 16 with the left angle of the coil lifting, dry friction damper, consisting of two cylindrical disks in contact with each other, lower 13 and upper 14. The lower disk 13 is rigidly connected with the upper flange of the inner spring 16, and the upper disk 14 is rigidly connected with the upper support plate 12. The upper 14 cylindrical disk of the dry friction damper is made of steel, and the lower 13 cylindrical disk is made of friction material made of the composition comprising the following components, in their ratio, in wt. %:

- a mixture of rezol and novolac phenol-formaldehyde pitches in the ratio 1: (0.2-1.0) 28 ÷ 34% a fibrous mineral filler containing glass roving or a mixture of glass roving and basalt fiber in a ratio of 1: (0.1-1.0) 12 ÷ 19% - graphite 7 ÷ 18% - friction modifier containing carbon black in the form of a mixture with kaolin and silicon dioxide 7 ÷ 15% - barite concentrate 20 ÷ 35% - talc 1.5 ÷ 3.0%

It is possible that steel, a rigid vibration damping material, for example, Agate type, the above friction material, as well as various combinations of these materials in a dry friction pair of a damper can be used as materials for the lower 13 and upper 14 cylindrical disks of the dry friction damper.

It is possible that in order to increase the damping coefficient of the vibration isolation system, concentric diametrical grooves 17, on one of the disks, and protrusions 18, on the other disk, are made on the surfaces of the cylindrical disks 13 and 14 of the dry friction damper facing each other. These surfaces entering into each other interact with each other without gaps, which leads to an increase in the friction surfaces, and, consequently, to an increase in the damping coefficient of the system.

It is possible that sintered friction material based on copper containing zinc, iron, lead, graphite, vermiculite, copper, chromium, antimony and silicon can be used as materials for the lower and upper cylindrical disks of the dry friction damper, 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.

It is possible that the upper cylindrical disk 14 is made of an elastomer, for example rubber or other elastic material having high damping properties, and the lower cylindrical disk 13 is made of steel.

Spring damper dry friction works as follows.

The outer 15 and the inner 16 of the damper spring absorb significant static and dynamic loads from the machine and transfer to the supporting structure a significantly reduced amount of dynamic load.

Two springs 15 and 16, inserted one into the other, work in compression, while the external spring 15 of the right angle of rotation rotates the upper metal support plate 12 rigidly attached to it, and the internal spring 16 of the left angle of rotation rotates the lower metal rigidly attached to it the cylindrical disk 13 of the dry friction damper is in the other direction. Thus, the effect of mutual rotation in different directions of the end turns of the springs 15 and 16 around the vertical axis is used, due to which dissipative forces arise in the composite reference plane of the dry friction damper, i.e. dry friction appears. The introduction of a dry friction element from a rubber element with an internal friction increased by 10–15 times leads to a decrease in the vibration amplitudes of the machine in start-stop modes by 2–3 times. Under shock, the logarithmic decrement of the attenuation of oscillations decreases.

It is possible that friction material made of a composition comprising the following components, when their ratio, in wt.%, Is used as materials for the lower and upper cylindrical disks of the dry friction damper %: a mixture of rezol and novolac phenol-formaldehyde resins in the ratio 1: (0.2-1.0) - 8 ÷ 34%; fibrous mineral filler containing glass roving or a mixture of glass roving and basalt fiber in a ratio of 1: (0.1-1.0) - 12 ÷ 19%; graphite - 7 ÷ 18%; a friction modifier containing carbon black in the form of a mixture with kaolin and silicon dioxide - 7 ÷ 15%; barite concentrate - 20 ÷ 35%; talc - 1.5 ÷ 3.0%.

Claims (1)

A rubber-metal vibration isolation device containing inner and outer tubular profiles connected in its upper part to a plug made in the form of a sleeve, a vibration isolator made in the form of a coil spring with a flange, and a viscoelastic shell installed in the gap between the tubular profiles and connected mainly by hot vulcanization with a bushing, a spring and a flange, the spring is inseparably connected to the bushing and the flange by means of screw grooves made on them and fixed at the points of connection with them elements, while the latter are mainly connected by a method of hot vulcanization with a viscoelastic shell, characterized in that an additional elastic element with a dry friction damper is installed between the upper sleeve and the lower flange, consisting of the lower and upper support plates, between which the outer the right angle of the lifting of the coils and the inner with the left angle of the lifting of the coils of the spring, while the lower support plate is the base on which the lower flanges of the springs are fixed s is rigid, and between the upper support plate and the upper flange of the internal spring with the left angle of the coil elevation there is a dry friction damper consisting of two lower and upper cylindrical disks in contact with each other, while the lower disk is rigidly connected to the upper flange of the internal spring, and the upper disk rigidly connected to the upper support plate, while on the surfaces of the cylindrical disks of the dry friction damper facing each other, concentric diametrical grooves are made on one of the disks and the protrusions on the other sintered friction material of zinc, iron, lead, graphite, vermiculite, copper, chromium, antimony and silicon can be used as materials of each other, which are included in each other, and as materials for the lower and upper cylindrical disks of the dry friction damper 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, or as the materials of the lower and upper cylindrical disks of the dry friction damper used friction material made of a composition comprising the following components, in their ratio, in wt. %: a mixture of resole and novolac phenol-formaldehyde resins in the ratio 1: (0.2-1.0) -8 ÷ 34%; fibrous mineral filler containing glass roving or a mixture of glass roving and basalt fiber in a ratio of 1: (0.1-1.0) -12 ÷ 19%; graphite - 7 ÷ 18%; a friction modifier containing carbon black in the form of a mixture with kaolin and silicon dioxide - 7 ÷ 15%; barite concentrate - 20 ÷ 35%; talc - 1.5 ÷ 3.0%.

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