RU2550908C1 - Vibration isolation system by kochetov for process equipment with variable mass - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: vibration isolation system comprises a base, a supporting platform and two spring vibration isolators set in-between and fitted by equifrequent springs. The springs are symmetrically set in relation to the supporting platform. The lower spring flange is fixed at the resilient base, and the upper one - on the supporting plate. An object with variable process mass whose vibration shall be isolated is fixed at the supporting platform by fastening elements. The platform is connected to the supporting units by nuts embracing adjusting bolts with the help of vertical and horizontal levers. The supporting units are fixed on the supporting plate of every vibration isolator by adjusting bolts rigidly coupled to the bushes. Every supporting unit comprises vibration damping bushes set coaxially to the adjusting bolts. The resilient base is coupled with the lower platform of the vibration isolator by three poles with screws and elastic bushes coaxially set outside the poles. A cylindrical-conical damper made from elastomer is set under the resilient base of the lower spring flange. The damper is mounted on the lower platform of each vibration isolator by its cylindrical part. The conical part of the damper is connected to the resilient base of the spring.

EFFECT: higher vibration isolation efficiency.

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Description

The invention relates to the field of mechanical engineering, namely to equal-frequency vibration isolators, used to significantly reduce various equipment arising from the operation, mainly with variable mass, dynamic loads.

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, a housing and a dry friction damper.

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.

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 helical 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 that perform functions of the 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 zoliruemoe 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 an equal frequency spring vibration isolator according to.with. USSR No. 299681 [11] (prototype), containing a base, a support plate, an elastic element located between them, made in the form of a cylindrical spring, which has a variable pitch, ensuring the constancy of the natural frequency at any load from a given range.

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 effectiveness of vibration isolation.

This is achieved by the fact that in a vibration-isolating system for technological equipment with variable mass, containing a base, a support platform and an elastic element located between them, made in the form of a cylindrical equal-frequency spring having a variable pitch t, ensuring the constancy of the natural frequency of the system at any loads P from a given range: P ₁ ≤P≤P ₂ , due to its precipitation δ:

$$\delta ={\delta }_{\mathrm{one}}\left(ln\frac{P}{P_{\mathrm{one}}}+\mathrm{one}\right)$$

where P ₁ and P _2, respectively, the minimum and maximum loads under which the conditions of equal frequency are maintained; P is a load satisfying the condition P ₁ ≤P≤P ₂ ;

δ ₁ - a given initial spring draft, corresponding to the minimum load P ₁ , and the condition of equal frequency: the frequency of the natural vibrations of the vibroisolated system is constant when the mass of this system changes within the specified limits, the system contains at least two spring equal-frequency vibration isolators with equal-frequency springs symmetrically mounted relative to the support platforms, while the lower flange of the equal-frequency spring of each vibration isolator is mounted on an elastic base, and the upper one on the base plate, and on the base the platform, by means of fasteners, a vibration-isolating object with a variable technological mass is fixed, and the platform is connected with support nodes mounted on the support plate of each vibration isolator using vertical and horizontal levers with axial-symmetrical adjustment bolts with equal-frequency springs, rigidly connected to bushings covering the adjustment bolts nuts, and each of the support nodes contains vibration damping bushings, coaxially mounted with adjusting bolts, at m the lower flange of the equal-frequency spring of each vibration isolator is mounted on an elastic base, which is connected to the lower platform of the vibration isolator by means of at least three struts with screws and coaxially located outside the struts of the vibration isolator, and a cylinder conical damper is placed under the elastic base of the lower flange of the equal-frequency spring , for example from an elastomer, mounted with its cylindrical part on the lower platform of each vibration isolator, and the conical part is connected with the elastic base the use of an equal-frequency spring.

Figure 1 shows a General vibration-isolating system for technological equipment with variable mass; figure 2 - characteristic of the equal-frequency spring.

Vibration isolation system for technological equipment with variable mass (Fig. 1) contains at least two spring equal frequency vibration isolators with equal frequency springs 3 symmetrically mounted relative to the support platform 20. The lower flange of the equal frequency spring 3 of each vibration isolator is mounted on an elastic base 1, and the upper one on the base plate 2, while the spring 3 has a variable pitch t, ensuring the constancy of the natural frequency at any loads P from a given range:

P ₁ ≤P≤P _2,

where P ₁ and P _2, respectively, the minimum and maximum loads under which the conditions of equal frequency are maintained.

Under the action of the load P, satisfying the condition P ₁ ≤P≤P _2, it will change its draft δ (see figure ₂ ).

$$\delta ={\delta }_{\mathrm{one}}\left(ln\frac{P}{P_{\mathrm{one}}}+\mathrm{one}\right)$$

where δ ₁ is a given initial spring draft corresponding to a minimum load P ₁ . This corresponds to the condition of equal frequency: v = const, i.e. the constancy of the frequency of natural vibrations of the vibration-insulated system when the mass of this system changes within specified limits.

On the supporting platform 20, through the fasteners 19, a vibration-insulated object 12 with a variable technological mass is fixed (for example, removing chips from the workpiece during metalworking, reducing the mass of navoi in weaving equipment, etc.). The platform 20 with the help of vertical 18 and horizontal 11 levers is connected to the support nodes 10, mounted on the support plate 2 of each vibration isolator with the help of axisymmetric adjustment bolts 16 with equal frequency springs 3, rigidly connected to the bushings 14, covering the adjustment bolts 16 with nuts 15 and 17. Each of the supporting nodes 10 contains vibration damping bushings 13, coaxially mounted with adjusting bolts 16.

The lower flange of the equal-frequency spring 3 of each vibration isolator is mounted on an elastic base 1, which is connected to the lower platform 7 of the vibration isolator by means of at least three struts 6 with screws 4 and with elastic coaxially located outside the struts 5.

Under the elastic base 1 of the lower flange of the equal-frequency spring 3, axisymmetrically placed a cylindrical damper 9, for example of elastomer, mounted with its cylindrical part on the lower platform 7 of each vibration isolator, and the conical part 8 is connected with the elastic base 1 of the equal-frequency spring 3.

Vibration isolation system for technological equipment with variable mass works as follows.

When a dynamic load is applied to the spring 3, an equal-frequency vibration isolation of the object is ensured, since the spring has a variable pitch t, which ensures the constancy of the natural frequency at any loads P from a given range:

P ₁ ≤P≤P _2,

where P ₁ and P _2, respectively, the minimum and maximum loads under which the conditions of equal frequency are maintained.

Under the action of the load P, satisfying the condition P ₁ ≤P≤P _2, it will change its draft δ (see figure ₂ )

$$\delta ={\delta }_{\mathrm{one}}\left(ln\frac{P}{P_{\mathrm{one}}}+\mathrm{one}\right)$$

where δ ₁ is a given initial spring draft corresponding to a minimum load P ₁ . This corresponds to the condition of equal frequency: constant frequency of the natural oscillations of the vibration-insulated system when the mass of this system changes within specified limits.

Information sources

1. Kochetov OS, Sazhin B.S. Decrease in noise and vibrations in production: theory, calculation, technical solutions. - M.: MSTU. 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 vibration protection system. 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. Khvoshchevsky I.Ya., Kazakov A.B. Equal-frequency vibration isolator // USSR author's certificate for the invention №299681, class. F16F 1/06. Posted on 05/25/1971. Bulletin of inventions No. 12.

Claims (1)

A vibration-isolating system for technological equipment with variable mass, containing a base, a support platform and an elastic element located between them, made in the form of a cylindrical equal-frequency spring having a variable pitch t, ensuring the constancy of the natural frequency of the system at any loads P from a given range P ₁ ≤P≤ P ₂ due to its precipitation δ:
$$\delta ={\delta }_{\mathrm{one}}\left(ln\frac{P}{P_{\mathrm{one}}}+\mathrm{one}\right)$$

,
where P ₁ and P _2, respectively, the minimum and maximum loads under which the conditions of equal frequency are maintained; P is a load satisfying the condition P ₁ ≤P≤P ₂ ;
δ ₁ - a given initial spring draft, corresponding to the minimum load P ₁ and the condition of equal frequency: constant frequency of natural vibrations of the vibration-insulated system when the mass of this system changes within specified limits, characterized in that the system contains at least two spring-frequency vibration isolators with equal frequency springs, symmetrically mounted relative to the support platform, while the lower flange of the equal-frequency spring of each vibration isolator is mounted on an elastic base, and the upper one on the support plate astin, and on the supporting platform by means of fasteners a vibroisolated object with a variable technological mass is fixed, and the platform is connected with supporting nodes mounted on the supporting plate of each vibration isolator using vertical and horizontal levers with the help of axisymmetric adjustment bolts rigidly connected to the bushings axisymmetric with springs, nuts covering the adjusting bolts, and each of the support nodes contains vibration damping sleeves, coaxially mounted adjustably bolts, while the lower flange of the equal-frequency spring of each vibration isolator is mounted on an elastic base, which is connected to the lower platform of the vibration isolator by at least three struts with screws and elastic coaxially located outside the struts, and axially symmetrically placed under the elastic base of the lower flange of the equal-frequency spring a cylindrical-conical damper, for example from an elastomer, mounted with its cylindrical part on the lower platform of each vibration isolator, and the conical part is connected on with an elastic base of an equal-frequency spring.

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