RU2639356C1 - Vibration isolator combined with built-in rubber-metal elastic element - Google Patents

Abstract

FIELD: machine engineering.SUBSTANCE: vibration isolator contains a stack of alternating elastic and metal plates with holes covered by a combined spring. The stack and the spring are located between the lid and the base of the vibration isolator. Locks enter holes of elastic plates and are fixed in metal plates. The locks of one metal plate are evenly distributed between the facing locks of another metal plate. The locks are in the form of rods with middle part fixed in metal plates. The spring is made helical with built-in damper and consists of two parts with opposite ends. The first spring part has rectangular section turns with rounded edges, and the second part is made hollow. The opposite directed end of the first part is located in the cavity of the second part. The segmental profile gaps of the contacting spring parts are filled with antifriction lubricant. A sealing collar is mounted on the end of the second part of the spring. The first part of the screw spring is enclosed by the tube of a damping material. The gaps between the spring and the tube are filled with crumb of friction material.EFFECT: increased efficiency of vibration isolation in resonant mode by increasing the damping in the system.3 dwg

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 Russian Federation No. 2285842, F16F 15/07 (prototype), containing a package of alternating elastic and metal plates with holes, latches included in the holes of elastic plates and fixed in metal plates, latches of one metal plate evenly distributed between the latches of another metal plate facing them, the latches are made in the form of rods with a length shorter than the sum of the lengths of the corresponding holes in the metal and elastic lastids, the middle part of which is fixed in metal plates.

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

The technical result is an increase in the efficiency of vibration isolation in resonance mode by increasing the damping in the system.

This is achieved by the fact that in a vibration isolator combined with a built-in rubber-metal elastic element containing a packet of alternating elastic and metal plates with holes, the latches included in the holes of the elastic plates and fixed in the metal plates, the latches of one metal plate are evenly distributed between the latches of another metal facing them plates, clamps are made in the form of rods with a length shorter than the sum of the lengths of the corresponding holes in the metal and elastic plates, the middle part fixed in metal plates, a combined spring located between the cover and the base of the vibration isolator and covering a package of alternating elastic and metal plates, is made in the form of a combined spring with a built-in damper and consists of two parts with opposite ends, one part of which has rectangular turns sections, and the other part of the spring is hollow, while the counter-directed end of the first part is placed in the cavity of the second, the gaps of the segment profile of the contact The parts of the spring are filled with antifriction grease, while at the end of the second part of the spring a sealing collar is installed to prevent lubricant leakage, and the first part of the coil spring, made with rectangular turns with rounded edges, is covered by 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 is covered by a tube of damping material, is filled with crumbs of friction material, the gaps in the first the th part of a coil spring made with coils of rectangular cross section, which covers a tube of damping material, is 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 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%

In FIG. 1 shows a vibration isolator combined with a built-in rubber-metal elastic element, a general sectional view; in FIG. 2 - rigid clamps in the form of rods with spherical heads, in FIG. 3 - a combined spring 7, placed between the cover 6 and the base 8 of the vibration isolator and covering a package of alternating elastic and metal plates.

The vibration isolator combined with the integrated rubber-metal elastic element comprises an elastic element 7 made in the form of a combined spring (Fig. 3) placed between the cover 6 and the base 8 of the vibration isolator.

Between the cover 6 and the base 8 of the vibration isolator there is a packet of alternating elastic 1 and metal plates 3 and 5 with holes 2, as well as latches 4 included in the holes 2 of the elastic plates and fixed in metal plates, while the latches of one metal plate are evenly distributed between it with latches of another metal plate, the latches are made in the form of rods with a length shorter than the sum of the lengths of the corresponding holes in the metal and elastic plates, the middle part of which is fixed in a metal x wafers. The base 8 of the vibration isolator is mounted on a vibration damping plate 9.

The latches (Fig. 2) at the ends are equipped with spherical heads 10 and 12, with one head made integral with the rod, and the other put on after pressing the rod into the plate by landing on the conical section of the rod and then expanding it with the formation of the retaining boss 11.

A vibration isolator combined with an integrated rubber-metal elastic element operates as follows.

When a vertical vibration load is applied to the base 8 of the vibration isolator, damping occurs due to free deformation of the elastic elements 1 in the vertical direction, since the length of the clamp rods 4 is much less than the sum of the lengths of the corresponding holes in the metal 3 and elastic 1 plates. When exposed to horizontal vibroloads, damping occurs due to the deformation of the elastic elements 1 in the horizontal direction and internal energy loss due to friction from this deformation. Spherical heads 10 and 12 increase internal energy losses due to their friction on the walls of the holes 2.

It is possible that the combined spring 7 (Fig. 3), placed between the cover 6 and the base 8 of the vibration isolator and covering a package of alternating elastic and metal plates, is made in the form of a combined spring with an integrated damper and contains a coil spring consisting of two parts 15 and 16 with opposite ends 18 and 17 of the corresponding turns of these springs. On the supporting coils of the spring, support rings 13 and 14 are made for strong and reliable fixing of the ends of the springs during their operation.

The first part of the coil spring 15 is made with coils of rectangular (or square) section with rounded edges, and the second part 16 of the spring is hollow, for example of circular cross section, while the counter-directed end 18 of the first part of the spring is placed in the cavity of the counter-directed second part of the spring with the end 17 while its second end, mounted on the support ring 14, is sealed, for example, using a threaded plug (not shown).

In the cavity of the second spring part 16, made of a hollow circular cross section, formed on four sides, relative to the rectangular cross section of the first spring part 15, the gaps 19 of the segment profile in a section perpendicular to the axis of the contacting parts 15 and 16 of the spring.

For better adjustment of the spring stiffness (without scuffing, jamming or jamming), the gaps 19 of the segment profile of the contacting parts 15 and 16 of the spring are filled with antifriction grease, for example, viscous "solid oil" type, and a sealing lip is installed at the end 17 of the second spring part (not shown ) to prevent leakage (loss) of lubricant. This design is a kind of “viscous friction” damper with an extended throttle element in the form of gaps 19 of the segment profile of the contacting parts 15 and 16 of the spring, which in this case will be analogues of the piston-cylinder system, respectively.

The first part 15 of the coil spring, made with coils of rectangular (or square) section with rounded edges, is covered by a tube 20 of damping material, for example polyurethane, which creates friction in the vibration protection system, the value of which increases when the system approaches the resonance mode, which is analogous dry friction damper.

The gaps in the first part 15 of a coil spring made with coils of rectangular cross section, which is covered by a tube 20 of damping material, are filled with crumbs of friction material (not shown in the drawing).

A variant is possible when 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 pitches in the ratio 1: (0.2-1.0) 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) 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%

Combined spring with integrated damper works as follows.

The spring stiffness is adjusted by shortening or lengthening the spring height. When the support rings 13 and 14 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 stiffness of the spring increases, and in the second case (when unscrewing) it decreases, which makes it easier to adjust the stiffness of the spring.

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.

Claims (2)

A vibration isolator combined with an integrated rubber-metal elastic element, containing a packet of alternating elastic and metal plates with holes, clamps included in the holes of the elastic plates and fixed in metal plates, the latches of one metal plate are evenly distributed between the latches of another metal plate facing them, the latches are made in the form rods with a length shorter than the sum of the lengths of the corresponding holes in the metal and elastic plates, the middle part is fixed x in metal plates, characterized in that the combined spring located between the cover and the base of the vibration isolator and covering a package of alternating elastic and metal plates is made in the form of a coil spring with an integrated damper and consists of two parts with opposite ends, one part of which has coils of rectangular cross-section, and the other part of the spring is hollow, while the counter-directed end of the first part is placed in the cavity of the second, the gaps of the segment profile of the contacting parts the springs are filled with antifriction grease, while at the end of the second part of the spring a sealing sleeve is installed to prevent leakage of grease, 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 are screw springs made with coils of rectangular cross section, which covers a tube of damping material, are filled with crumbs of friction material made of 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%

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