RU2645467C1 - Vibroizolator combined with plate net damper - Google Patents

Abstract

FIELD: engineering.

SUBSTANCE: invention relates to mechanical engineering. Vibration isolator contains a combined spring with a built-in dry friction damper. To the combined spring oppositely connected two plates lattice damper. Each damper contains two oppositely arranged and resilient elastic elements of the lattice type, which are relative to their common vibro-damping base. Each of the elastic elements of the lattice type contains a base, an elastic lattice element and plates interacting with the bushings. Main lattice elastic element is supported by the lower part on the base and fixed by the lower plate, and the upper part is fixed by the upper pressure plate. Lower plate is connected to the base, made in the form of a fin with clamping holes. Top pressure plate is connected with central bucket, covered by coaxially aligned allowance of bush ring connected to the base. Between the lower end of the piston and the sleeve bottom there is a flexible element. Elastic element is made of a lattice frame filled with polyurethane, or netted with the parameters of the lattice structure as at the main lattice element.

EFFECT: provided is higher efficiency of vibration isolation in the resonance mode, simplified design and assembling.

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Description

The invention relates to mechanical engineering, instrumentation and can be used for vibration isolation of technological equipment, machine tools, devices.

The closest technical solution to the claimed object is a vibration isolator according to the patent of the Russian Federation No. 2288388 F16F 15/06, containing a base, an elastic mesh element and washers interacting with the bushings.

A disadvantage of the known device is the complexity and lack of efficiency at the resonance due to the lack of vibration damping.

The technical result is an increase in the efficiency of vibration isolation in a resonant mode.

This is achieved by the fact that in the vibration isolator combined with a washer mesh damper 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, while the opposite direction of the first part placed in the cavity of the second, the gaps of the segment profile of the contacting parts of the spring are filled with antifriction grease, while at the end of the second part of the spring a sealing sleeve is installed for prevent leakage of lubricant, and the first part of the coil spring made with coils of rectangular cross-section with rounded edges is covered by a tube of damping material, such as polyurethane, and the gaps in the first part of a coil spring made with coils of rectangular cross-section, which is covered by a tube of damping material, filled with crumb of friction material, the gaps in the first part of the coil spring, made with coils of rectangular cross section, which is covered by a tube of damping material, are filled s grit friction material made of a composition comprising the following components in their ratio in wt. %: a mixture of rezol and novolac phenol-formaldehyde resins in a ratio of 1: (0.2-1.0), in an amount of 28 ÷ 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), in an amount of 12 ÷ 19%: graphite in an amount of 7 ÷ 18%; a friction modifier containing carbon black in the form of a mixture with kaolin and silicon dioxide, in an amount of 7 ÷ 15%; barite concentrate in an amount of 20 ÷ 35%; talc in the amount of 1.5 ÷ 3.0%, or gaps, in the first part of the coil spring, made with coils of rectangular cross section, which is covered by a tube of damping material, filled with crumbs 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, with respect to the combined spring, with its counter-directed parts and the counter-directed ends 6 and 5 of the spring, two opposed, washer mesh dampers are attached to its support rings, each of which contains two opposite and axisymmetrically located relative to a common vibration damping base for them of an elastic element of a mesh type and fixed to a common base by means of plates with fixing holes, each of the elastic elements of a mesh type with holds the base, the elastic mesh element and the washers interacting with the bushings, the base is made in the form of a plate with mounting holes, the main mesh elastic 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 to a centrally located piston, covered with a gap, coaxially located sleeve, rigidly connected to the base, and between the lower end of the piston and the bottom of the sleeve is an elastic The element, the elastic element between the lower end of the piston and the bottom of the liner, is made of a combined mesh frame filled with an elastomer, for example polyurethane, or mesh with parameters of the mesh structure, as in the main elastic mesh element.

In FIG. 1 shows a general view of a vibration isolator combined with a washer mesh damper, FIG. 2 - a variant of a combined spring with an integrated dry friction damper.

The vibration isolator combined with the washer mesh damper contains a combined spring with an integrated dry friction damper and two opposed relative to the combined spring, with its counter-directed parts 3 and 4 and with the opposite ends 6 and 5 of the spring, the washer mesh damper attached to its support rings 1 and 2.

The combined spring with an integrated dry friction damper comprises a coil spring consisting of two parts 3 and 4 with opposite ends 6 and 5 of the corresponding turns of these springs. On the support coils of the spring, support rings 1 and 2 are made for strong and reliable fixation of the ends of the springs during their operation.

The first part of the coil spring 3 is made with coils of rectangular (or square) section with rounded edges, and the second part 4 of the spring is hollow, for example of circular cross section, while the counter-directed end 6 of the first part of the spring is placed in the cavity of the counter-directed second part of the spring with end 5 while its second end, mounted on the support ring 2, is sealed, for example with a screw plug (not shown).

In the cavity of the second spring part 4, made of a hollow circular section, formed on four sides, relative to the rectangular section of the first part 3 of the spring, the gaps 7 of the segment profile in a section perpendicular to the axis of the contacting parts 3 and 4 of the spring.

The first part 3 of the coil spring, made with turns of rectangular (or square) section with rounded edges, covers the tube 8 of a damping material, such as polyurethane. The gaps in the first part 3 of a coil spring made with coils of rectangular cross section, which is covered by a tube 8 of damping material, are filled with crumbs of friction material (not shown in the drawing).

It is possible that the gaps in the first part of a coil spring made with coils of rectangular cross section, which are covered by a tube of damping material, are filled with crumbs of friction material made of a composition comprising the following components in their ratio, in wt. %: a mixture of rezol and novolac phenol-formaldehyde resins in a ratio of 1: (0.2-1.0), in an amount of 28 ÷ 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), in an amount of 12 ÷ 19%: graphite in an amount of 7 ÷ 18%; a friction modifier containing carbon black in the form of a mixture with kaolin and silicon dioxide, in an amount of 7 ÷ 15%; barite concentrate in an amount of 20 ÷ 35%; talc in the amount of 1.5 ÷ 3.0%. It is possible that the gaps are filled with crumbs 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.

Combined spring with integrated damper works as follows.

The spring stiffness is adjusted by shortening or lengthening the spring height. When the support rings 1 and 2 rotate, the spring coils move relative to each other in mutually opposite directions relative to the longitudinal axis of the spring, i.e. screwed in or out. In the first case (when screwing in), the spring stiffness increases, and in the second case (when unscrewing) it decreases, which makes it easier to adjust the spring stiffness.

Thus, due to its selective properties, the spring provides effective spatial vibration isolation of equipment in all six directions of vibration (along three axes X, Y, Z and rotary vibrations around these axes) with vibration damping at resonance, and under various operating conditions.

Each of the washers located opposite to and attached to the support rings 1 and 2 of the spring washer mesh damper contains a base 9 in the form of a plate with mounting holes 10, the main mesh elastic element 15, the lower part resting on the base 9 and fixed by the lower washer 14, rigidly connected to the base 9, and the upper part is fixed by the upper pressure washer 13, rigidly connected to the centrally located piston 12, covered with a gap, coaxially located sleeve 11, rigidly connected to the base 9. Between the lower end 16 EDSS 12 and the bottom 17 of the sleeve 11 is arranged a resilient element 18, for example of polyurethane.

The density of the mesh structure of the elastic mesh element is in the optimal range of values: 1.2 g / cm ³ ... 2.0 g / cm ³ , and the wire material of the elastic mesh elements is steel grade 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 15 can be made combined of a mesh frame, filled with an elastomer, for example polyurethane.

It is possible that the elastic element 18, located between the lower end face 16 of the piston 12 and the bottom 17 of the sleeve 11, is made mesh, with the same parameters of the mesh structure as the main elastic mesh element 15.

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. Between the base 9 in the form of a plate with mounting holes 10 of each washer mesh damper and the support rings 1 and 2 of the spring are vibration damping pads 19 and 20.

The washer mesh damper operates as follows.

When vibrations of a vibroinsulated object (not shown in the drawing) located on the upper pressure plate 13, the elastic mesh element 15 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.

In FIG. 2 shows a variant of a combined spring with an integrated dry friction damper.

The combined spring with an integrated dry friction damper comprises lower 21 and upper 22 support plates, between which the outer 25, with the right angle of the coil, and the inner 26 with the left angle of the coil, are installed coaxially and concentrically. The lower supporting plate 21 is the base on which the lower flanges of the springs 25 and 26 are fixed rigidly, and a damper is located between the upper supporting plate 22, on which the vibration-insulated object is mounted (not shown in the drawing), and the upper flange of the internal spring 26 with a left angle dry friction, consisting of two lower 23 and upper 24 cylindrical disks in contact with each other. The lower disk 23 is rigidly connected with the upper flange of the inner spring 26, and the upper disk 24 is rigidly connected with the upper support plate 22. The upper 24 cylindrical disk of the dry friction damper is made of steel, and the lower 23 cylindrical disk is made of friction material made of the composition including the following components in their ratio, in wt. %:

a mixture of resol 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%.

It is possible that, as the materials of lower 3 and upper 24, cylindrical disks of the dry friction damper, steel, a hard vibration damping material, for example, Agate type, the above friction material, as well as various combinations of these materials in a pair of dry friction damper can be used.

It is possible that in order to increase the damping coefficient of the vibration isolation system, concentric diametrical grooves 27 on one of the disks and protrusions 28 on the other disk are made on the surfaces of the cylindrical disks 23 and 24 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 24 is made of elastomer, for example rubber or other elastic material having high damping properties, and the lower cylindrical disk 23 is made of steel.

Spring damper dry friction works as follows.

The outer 25 and inner 26 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 25 and 26, inserted one into the other, work in compression, while the outer spring 25 of the right angle of rotation rotates the upper metal support plate 22 rigidly attached to it, and the inner spring 26 of the left angle of rotation is rigidly attached to it lower the cylindrical disk 23 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 25 and 26 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. Introduction to the dry friction damper of an element made of rubber with internal friction increased by 10–15 times leads to a decrease in the vibration amplitudes of the machine in pre-stop modes by 2–3 times. Under shock, the logarithmic decrement of the attenuation of oscillations decreases.

Claims (1)

A vibration isolator combined with a washer mesh damper, comprising a combined spring with an integrated dry friction damper, comprising a cylindrical helical spring, consisting of two parts with opposite ends, one part of which has rectangular turns, and the other part of the spring is hollow, with an opposite direction the end of the first part is placed in the cavity of the second, the gaps of the segment profile of the contacting parts of the spring are filled with antifriction grease, while at the end of the second part springs installed sealing cuff to prevent lubricant leakage, and the first part of the coil spring, made with coils of rectangular cross section with rounded edges, covers a tube of damping material, such as polyurethane, and the gaps in the first part of the coil spring, made with coils of rectangular cross section, which covers a tube of damping material filled with crumbs of friction material made of a composition comprising the following components in their ratio, wt. %: a mixture of rezol and novolac phenol-formaldehyde resins in a ratio of 1: (0.2-1.0) in an amount of 28 ÷ 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), in an amount of 12 ÷ 19%; graphite in the amount of 7 ÷ 18%; a friction modifier containing carbon black in the form of a mixture with kaolin and silicon dioxide, in an amount of 7 ÷ 15%; barite concentrate in an amount of 20 ÷ 35%; talc in an amount of 1.5 ÷ 3.0%, or crumbs 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; or a combination spring with an integrated dry friction damper comprises lower and upper support plates, between which the outer with the right angle of the coil and the inner with the left angle of the coil are springed coaxially and concentrically, the lower support plate being the base on which the lower flanges of the springs are fixed rigidly, and between the upper support plate and the upper flange of the internal spring with a left angle of elevation of the coils is a dry friction damper, consisting of two in contact with each other lower and upper cylindrical disks, wherein the lower disk is rigidly connected to the upper flange of the inner spring, and the upper disk is rigidly connected to the upper support plate, and concentric diametrical grooves are made on the surfaces of the cylindrical disks of the dry friction damper facing each other on one of disks and protrusions on another disk that enter into each other, and sintered friction material based on copper containing zinc, iron, lead, graphite, vermiculite, copper, chromium, antimony and silicon in the following ratio, 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 friction material made of a composition comprising the following components in their ratio, in wt. %: 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%, characterized in that two opposed washer mesh dampers are attached relative to the combined spring, each of which contains two opposed and axisymmetrically located relative to the vibration damping base of the elastic element of the mesh type and fixed on a common base by means of plates with fixing holes, wherein each of the elastic elements of the mesh type contains a base, an elastic mesh element and washers interacting with the bushings, the base is made It is in the form of a plate with mounting holes, the main net elastic 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 to the centrally located piston, covered with a clearance by the 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 made of a combined mesh frame, filled with an elastomer, for example polyurethane ohms or gauze with a mesh structure parameters as in the main resilient element mesh.

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