RU2638339C1 - Dynamic vibration damper - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: dynamic vibration damper contains a spherical shell placed in the damping body cavity made in the form of parallelepiped. At least one ball is placed in the spherical shell. Between the walls of the damping body and the spherical shell there are elastic elements installed in the equatorial region of the spherical shell. The elastic elements are made in the form of a spring with an integrated damper. The spring is made as a cylindrical screw and contains two parts with opposite directed 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. The packing seal is mounted at the end of the second spring part to prevent lubricant leakage. The first part of the screw spring is enclosed by the tube of a damping material. The gaps in the first part of the helical spring which is covered by the tube of damping material, are filled with a crumble of friction material.

EFFECT: increased efficiency of vibration damping by reducing side forces on the damping body by increasing damping in the system.

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Description

The invention relates to mechanical engineering and is intended to damp the vibrations of various equipment.

The closest technical solution is a dynamic vibration damper, containing at least one ball placed in the cavity of the damped body, provided with a spherical shell placed in the form of a parallelepiped cavity and elastic elements installed between the walls of the damped body and the spherical shell in the equatorial region of the latter, and the balls are placed inside the spherical shell (USSR AS No. 1467282 - prototype).

A disadvantage of the known device is the relatively low vibration damping.

EFFECT: increased damping of vibrations by reducing lateral forces on a damped body by increasing damping in the system.

This is achieved by the fact that in a dynamic vibration damper containing at least one ball placed in the cavity of the damped body, it is provided with a spherical shell placed in the form of a parallelepiped cavity and elastic elements installed between the walls of the damped body and the spherical shell in the equatorial region of the latter, and the balls are placed inside the spherical shell, the elastic elements installed between the walls of the damped body and the spherical shell in its equatorial region are made in the form of a spring with a built-in 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 is placed in the second cavity, the gaps the segment profile of the contacting parts of the spring is filled with antifriction grease, while at the end of the second part of the spring a sealing sleeve is installed to prevent leakage of lubricant, and the first part of the wines A new 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, are filled with crumbs of friction material, the gaps in the first part of the coil spring, made with coils of rectangular cross section, which covers a tube of damping material, is filled with crumbs of friction material made from a composition comprising the following components in their ratio, by weight. %:

 mixture of resol 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  carbon black friction modifier 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 structural diagram of a dynamic vibration damper, a longitudinal section, in FIG. 2 is an embodiment of elastic elements 5 mounted between the walls of the damped body 4 and the spherical shell 2 in its equatorial region.

The dynamic vibration damper (Fig. 1) contains a spherical shell 2 placed in a cavity 1 made in the form of a parallelepiped and placed at least one ball 3 therein and installed between the walls of the damped body 4 and the spherical shell 2 in the equatorial region of the latter, elastic elements 5. The latter can be installed inside the spherical shell 2 in its equatorial region, and each is made in the form of a profiled plate (not shown) or in the form of a spring with a cam at the end (not shown) to interact with the balls 3.

Dynamic vibration damper operates as follows.

In the presence of an external periodic excitation acting on the damped body 4, the balls 3 begin to run on the inner surface of the spherical shell 2, creating a reaction from the action of centrifugal forces, an antiphase exciting force. Compensation of the exciting force is due to the deformation of the elastic elements 5 and the transition of the vibrational energy of the damped body 4 into the compression-tension energy of the elastic elements 5.

The effectiveness of the dynamic vibration damper can be improved due to the interaction of the balls 3 with profiled plates or spring-loaded cams (not shown).

A possible embodiment of the elastic elements 5 installed between the walls of the damped body 4 and the spherical shell 2 in its equatorial region (Fig. 2).

The elastic element 5 is made in the form of a spring with a built-in damper, which contains a cylindrical helical spring, consisting of two parts 8 and 9 with opposite ends 11 and 10 of the corresponding turns of these springs. On the support coils of the spring support rings 6 and 7 are made for strong and reliable fixation of the ends of the springs during their operation.

The first part of the coil spring 8 is made with coils of rectangular (or square) section with rounded edges, and the second part 9 of the spring is made hollow, for example of circular cross section, while the counter-directed end 11 of the first spring part is placed in the cavity of the counter-directed second spring part with the end 10 while its second end, mounted on the support ring 7, is sealed, for example, using a screw plug (not shown).

In the cavity of the second spring part 9, made of a hollow circular cross section, formed on four sides, relative to the rectangular cross section of the first spring part 8, the gaps 12 of the segment profile in a section perpendicular to the axis of the contacting parts 8 and 9 of the spring.

For better adjustment of the spring stiffness (without scuffing, jamming or jamming), the gaps 12 of the segment profile of the contacting parts 8 and 9 of the spring are filled with antifriction grease, for example, viscous "solid oil" type, and a sealing lip is installed at the end 10 of the second spring part (not shown in the drawing ) 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 12 of the segment profile of the contacting parts 8 and 9 of the spring, which in this case will be analogues of the piston-cylinder system, respectively.

The first part 8 of the coil spring, made with coils of rectangular (or square) section with rounded edges, is covered by a tube 13 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 8 of the coil spring, made with coils of rectangular cross section, which covers the tube 13 of the 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 that includes the following components in their ratio, wt. %:

mixture of resol 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 carbon black friction modifier in the form of a mixture with kaolin and silicon dioxide 7 ÷ 15 barite concentrate 20 ÷ 35 talc 1.5 ÷ 3.0

The elastic element 5 operates as follows.

The spring stiffness is adjusted by shortening or lengthening the spring height. When the support rings 6 and 7 rotate, the coil of the spring moves 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 dynamic vibration damper containing at least one ball placed in the cavity of the damped body is provided with a spherical shell placed in the cavity in the form of a parallelepiped and elastic elements mounted between the walls of the damped body and the spherical shell in the equatorial region of the latter, and the balls are placed inside the spherical shell, characterized in that the elastic elements installed between the walls of the damped body and the spherical shell in its equatorial region are made in de springs with a built-in 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 is placed in the cavity of the second, segmented gaps the profiles 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 to prevent leakage of lubricant, and the first part is screwed springs made with coils of rectangular cross-section with rounded edges are covered by a tube of damping material, for example 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, are filled with crumbs of friction material made of the composition including the following components in their ratio, wt. %: mixture of resol 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 carbon black friction modifier 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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