RU2558775C1 - Vibrator isolator for process equipment - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: vibrator isolator consists of a casing and a resilient element interacting with a unit. The casing is made as a base plate where two guiding sleeves with bottoms turned to the base plate are fixed by a layer of cast polyurethane. Resilient elements are set inside the guiding sleeves symmetrically to their axes; the elements are made as two rings placed in vertical planes that are mutually perpendicular to each other. The lower bearing surfaces of springs rest in round disks from antifriction material and the upper ones - in the cap covering the cast polyurethane layer with a gap. By means of a fastening element the cover is connected to a load bearing threaded element, for example, a bolt with its head being covered by the cast polyurethane layer. The sleeves on the side of the open part are fitted by ring flanged edges, coaxial sleeves' axes on which resilient rings are fixed with a gap in respect to the inner cap surface and serve as resilient limiters of moving elements of the vibration absorber. Under disks of the guiding sleeves the resilient damping elements are installed, they are made in form of cone springs filled with polyurethane.

EFFECT: increased efficiency of vibration isolation in resonance mode.

2 dwg

Description

The invention relates to mechanical engineering and can be used for vibration isolation of technological equipment, including looms.

It is known the use of spring elastic elements for vibration isolation of technological equipment in the textile industry [1, 2, 3, 4]. The calculations show the high efficiency of spring elastic elements in vibration isolation systems, while tests in real factory conditions confirm their effectiveness with high reliability and ease of maintenance.

However, a significant height of the springs is required to reduce low-frequency vibrations.

It is known to use spring vibration isolators [5, 6] with a pendulum suspension, which use a suspension type vibration isolation system with a spring elastic element.

The disadvantage of this type of vibration isolators with a pendulum suspension is their large height dimension, since they belong to the category of suspended vibration isolation systems, where the overall dimensions are not limited in height, and relatively small dimensions in height are required for supporting vibration protection systems.

Known spring vibration isolator with dry friction [7], containing a spring, housing and dry friction damper, the housing is made in the form of a hollow vertical strut interacting with a T-shaped platform, elastically connected with the dry friction damper, made in the form of a sleeve, the inner surface of which spring-loaded friction elements interact with the outer surface of the rack, and on its outer surface a spring is fixed, resting on the base of the rack, and between the interacting surfaces of the sleeve and the rack en the buffer restriction member.

The disadvantage of this type of vibration isolators is the relatively low reliability in the resonant mode due to wear of the dry friction damper, which somewhat reduces the efficiency of vibration protection.

It is known the use of spring elements in vibration isolators [8], containing a housing that is made in the form of upper and lower rectangular plates, between which screw elastic elements of different stiffness are placed so that they form a closed loop around the perimeter of the lower plate, and screw elastic elements are made in the form a package consisting of coil springs of different stiffness and height.

The disadvantage of this type of vibration isolators is the ability to block screw elastic elements in packages, which can somewhat change their overall stiffness, and therefore the effectiveness of vibration protection.

It is known the use of spring elements in vibration isolators [9] with a variable damping structure, comprising a housing with a rod and piston placed in it, and a vibration-proof mass held by springs is fixed at the end of the rod, and the dry friction damper is made in the form of a friction sleeve with restrictive stops at the ends, moreover, the force of pressing the friction elements to the sleeve is carried out through the adjusting screws that are connected to the actuating servomotor, and the signal to turn on the servomotor comes from the micro a processor controlling the operation of a dry friction damper according to a given characteristic and associated with a vibration acceleration sensor.

The disadvantage of this type of vibration isolators is the high cost of the vibration protection system, which is not always justified because of their effectiveness of vibration protection.

Known spring vibration isolator with a pendulum suspension [10], containing a coil spring, the lower end of which rests on the upper flange of the housing, and interacting with the pendulum mechanism, which is made in the form of a threaded rod with nuts at the ends and supporting washers, based on rubber elastic elements, acting as an elastic hinge, with the upper rubber elastic element located between the upper spring flange and the support washer, and the lower - between the support washer and the plate on which the vibro is mounted insulated equipment.

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

The closest technical solution to the claimed object is a spring vibration isolator according to.with. USSR No. 717438 [11] (prototype) 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 is located in the gaps between the tubes, for example, polyethylene, which has a high coefficient of thermal expansion compared to 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 ie with the axis of coils housing.

A disadvantage of the known device is the relatively low efficiency at resonance due to insufficient 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 for technological equipment containing a body and an elastic element interacting with the object, the body is made in the form of a base on which at least two guide glasses with bottoms facing the base are fixed by means of a layer of injection molded polyurethane, while the polyurethane injection layer covers the cups along the bottoms and lateral cylindrical surfaces, while the layer thickness is selected depending on the amplitude of the spatial vibrations of the vibration-insulated volume kta (not shown in the drawing). A layer of injection polyurethane can form any shape, for example, rectangular or round in plan (top view), depending on the configuration of the vibration-insulated object and the conditions for placement of vibration isolators on it, and axisymmetrically guiding cups, inside them, there are cylindrical compression coil springs supported by lower supporting surfaces in round discs made of antifriction material, and the upper supporting surfaces in the cover, covering with a gap a layer of injection polyurethane, and the cover is connected by by means of a fastening element with a load-bearing threaded element, for example, a bolt, the head of which is filled with a layer of injection molded polyurethane, and the location of the bolt head is selected depending on the nature of the vibration load and can be either in the middle of the guide glasses, or shifted to the bottom or open part of the glasses, from the side of the open part, annular flanges are made on the cups, coaxial axis of the cups on which elastic rings are fixed with a gap relative to the inner surface of the lid, the functions of the elastic limiters of the moving parts of the vibration isolator, and elasto-damping mesh elements are placed under the guiding cup disks, the mesh density of the elastic mesh elements being in the optimal range of 1.2 g / cm ³ ... 2.0 g / cm ³ and the material of the elastic wire mesh elements - steel grade EI-708, while its diameter is in the optimal range of values of 0.09 mm ... 0.15 mm

Figure 1 presents a frontal section of a vibration isolator for technological equipment, figure 2 is a diagram of an elastic element.

The vibration isolator for technological equipment contains a base 1 on which at least two guide cups 3 and 4 are fixed with a molding polyurethane layer 9 with bottoms facing toward the base 1. A polyurethane molding layer 9 covers the cups 3 and 4 along the bottoms and lateral cylindrical surfaces, wherein the layer thickness is selected depending on the amplitude of the spatial vibrations of the vibroisolated object (not shown in the drawing). The layer of injection polyurethane 9 can form any shape, for example, rectangular or round in plan (top view), depending on the configuration of the vibration insulated object and the conditions for the placement of vibration insulators on it.

Guide glasses 3 and 4 can be made of hard vibration-damping material, such as plastic compound such as "Agate", "Anti-vibration", "Shvim". Axially symmetrically to the guide cups 3 and 4, inside them, there are elastic elements 5 and 6, for example, in the form of cylindrical screw compression springs, supported by lower supporting surfaces in circular disks 15 and 16 of antifriction material, and by upper supporting surfaces - in cover 2, covering with a gap a layer of injection polyurethane 9. The cover 2 is connected by means of a fastening element 11 to a load-bearing threaded element 10, for example a bolt, the head of which is filled with a layer of injection polyurethane 9, and the location of the head of the bolt in Biranne depending on the nature of the load and vibration can be a middle guide cup 3 and 4 (shown in the drawing) and offset towards the bottom, or exposed portion cup.

Each of the elastic elements 5 and 6 is made in the form of two spherical rings 17 and 18 located coaxially and in mutually perpendicular vertical planes and fastened together by fasteners 19 and 20, so that one of the rings, for example, the inner one, enters the other - external, larger diameter by the thickness of the ring.

From the side of the open part on the cups 3 and 4, annular flanges 13 are made, the coaxial axis of the cups 3 and 4, on which elastic rings 14 are fixed with a gap 12 relative to the inner surface of the lid 2, performing the functions of elastic limiters of the moving parts of the vibration isolator.

Under the disks 15 and 16 of the guide cups 3 and 4, elastic-damping mesh elements 7 and 8 are placed, the density of the mesh structure of the elastic mesh elements being in the optimal range of 1.2 g / cm ³ ... 2.0 g / cm ³ and the material of the elastic wire mesh elements - steel grade EI-708, while its diameter is in the optimal range of values of 0.09 mm ... 0.15 mm Elastic mesh elements 7 and 8 can also be made reinforced from a mesh frame, filled with an elastomer, for example polyurethane; combined from a mesh frame and crumbs of solid vibration-damping materials, for example, agate, anti-vibrate, shvim plastic compound with a grain size fraction of 0.5 ... 2.0 mm, filled with an elastomer, such as injection molded polyurethane.

It is possible that under the disks 15 and 16 of the guide cups 3 and 4 elastic-damping elements are placed, made in the form of segments of a sub-standard cable of different diameters mixed with pieces of polyurethane products.

It is possible that under the disks 15 and 16 of the guide cups 3 and 4 are placed elastic-damping elements made in the form of conical springs 21 filled with polyurethane.

Vibration isolator for technological equipment operates as follows.

With vibrations of the vibration-insulated object, the elastic elements 5 and 6 absorb vertical loads, thereby weakening the dynamic effect on the floors of buildings, while the damping in the system is carried out both in the layers of injection polyurethane 9, covering the surfaces of the glasses 3 and 4, and in the elastic-damping mesh elements 7 and 8. Horizontal vibrations are damped in the layers of injection polyurethane 9.

Literature

1. Kochetov O.S., Sazhin B.S. Noise and vibration reduction in production: theory, calculation, technical solutions. M .: MSTU im. A.N. Kosygina, 2001 .-- 319 p.: P. 120, fig. 5.6; p. 287, fig. P.Y.15.

2. Kochetov O.S. Textile vibroacoustics. Textbook for universities. M .: MSTU im. A.N. Kosygina, “Sovezh Bevo” group 2003. - 191 p.: P. 59, fig. 3.1; p. 61, Fig. 3.4a; fig.3.5.

3. Kochetov OS Vibration isolators of type "VSK-1" for looms // Textile industry. - 2000, No. 5. S.19 ... 20.

4. Kochetov O.S. Calculation of the spatial system of vibration protection. The journal "Occupational Safety in Industry", No. 8, 2009, pp. 32-37.

5. Kochetov O.S., Kochetova M.O., Khodakova TD, Shesterninov A.V. Spring vibration isolator with pendulum suspension // Patent for invention No. 2279589. Published on July 10th, 2006. Bulletin of inventions No. 19.

6. Kochetov O.S., Kochetova M.O., Khodakova TD, Shesterninov A.V. Vibration isolating system // Patent for invention No. 2279586. Published on July 10th, 2006. Bulletin of inventions No. 19.

7. Kochetov O.S., Kochetova M.O., Khodakova T.D., Shesterninov A.V., Stareev M.E. Spring vibration isolator with dry friction // Patent for invention No. 2282075. Posted on 08/20/06. Bulletin of inventions No. 23.

8. Kochetov O.S., Kochetova M.O., Khodakova TD, Shesterninov A.V. Vibration-proof pad // Patent for invention No. 2277650. Published on June 10th, 2006. Bulletin of inventions No. 16.

9. Kochetov O.S., Kochetova M.O., Shesterninov A.V., Zubova I.Yu. Vibration isolator with variable damping structure // Patent for invention No. 2303722. Posted on 07/27/07. Bulletin of inventions No. 21.

10. Kochetov O.S., Kochetova M.O., Khodakova T.D. Vibration isolator with pendulum suspension // Patent for invention No. 2269699. Posted on 02/10/06. Bulletin of inventions No. 4.

11. Mironov E.M. Spring shock absorber // USSR copyright certificate for invention No. 717438, class. F16F 9/30. Published 02/25/1980. Bulletin of inventions No. 7.

Claims (1)

A vibration isolator for technological equipment, comprising a housing and an elastic element interacting with the object, characterized in that the housing is made in the form of a base on which at least two guiding cups with bottoms facing the base are fixed by means of a layer of injection polyurethane, the injection layer polyurethane covers glasses on the bottoms and lateral cylindrical surfaces, while the layer thickness is selected depending on the amplitude of the spatial vibrations of the vibration-insulated object, and a layer of injection polyurethane can form any shape, for example, rectangular or round in plan, depending on the configuration of the vibration-insulated object and the conditions for placement of vibration isolators on it, and axisymmetrically guiding glasses, inside them are elastic elements, for example, in the form of two rings arranged in mutually perpendicular to the vertical planes, supported by the lower abutment surfaces in round discs of antifriction material, and the upper abutment surfaces - in a lid covering the gap th layer of injection molded polyurethane, and the lid is connected by means of a fastener to a load-bearing threaded element, for example a bolt, the head of which is filled with a layer of injection molded polyurethane, and the location of the bolt head is selected depending on the nature of the vibration load and can be both in the middle of the guide glasses and with a displacement to the bottom or the open part of the glasses, while from the side of the open part on the glasses are made annular flanges, the coaxial axis of the glasses, on which they are fixed with a gap, include flax inner surface of the cover elastic ring operating functions elastic isolator stops moving parts, and a disk guide cup has elastic-damping elements made in the form of conical springs, filled polyurethane.

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