RU2141065C1 - Group protective device - Google Patents

Abstract

FIELD: mechanical engineering; protection of articles against vibrations and impacts. SUBSTANCE: device is provided with base made in form of two parallel flanges with vibration isolators mounted in them and bearing member also made in form of two parallel fastening flanges. Each vibration isolator consists of fastening bush in which flexible members are inserted, dampening bush and flanged bush received by hole in bearing member at radial interference. Radial interference in one flange is 0<0 0<Δ₁≤Δ(RV) and Δ₂≤Δ(RI) in other fastening member. EFFECT: reduction of vibratory impact loads on object being protected due to reduction of torsional vibrations. 4 dwg

Description

 The invention relates to mechanical engineering and can be used to protect the product from vibration and shock.

 Known group protective device (GZU) containing a base, a support element with holes in which vibration isolators are mounted, mounted on the base / 1 /.

 However, this device does not protect the object from shock loads of large amplitude due to low energy consumption.

 The closest device to the claimed invention in terms of features and the achieved result is a group protective device consisting of a base, a support element with holes in which vibration isolators are installed, each of which consists of a mounting sleeve on which elastic elements are located, a damping sleeve, a sleeve with flanges installed in the hole of the support element with a radial interference and with an axial interference between its flanges and elastic elements, and a damping sleeve is placed in the hole bushings with flanges between elastic elements with axial interference, with each vibration isolator fixed to the base by a fastening element passing through the hole of the mounting sleeve. This device is taken as a prototype / 2 /.

 In this design, shock absorption is suppressed due to the high energy intensity of the connection of the sleeve with the support element (the sleeve is installed with interference) and a damping sleeve.

 However, such a group protective device does not provide effective damping of vibration and shock loads due to the occurrence of torsional vibrations when the center of mass of the object is displaced relative to the support element.

 To exclude torsional vibrations of the protected object, the optimal solution would be to supply the protected object with two parallel mounting flanges between which the center of mass of the object is located.

 However, due to tolerances on the distance between the mounting surfaces of the vibration isolators located in different flanges of the support element, and on the distance between the base flanges to which the vibration isolators are attached, a significant deformation of elastic elements inevitably occurs when the group protective device (GDU) is fixed, leading to an increase in vibration shock loads on the protected object (in extreme cases, the clamping of elastic elements can lead to a violation of their strength).

 In the implementation of this invention, the technical result is expressed in the reduction of vibrational loads on the protected object by reducing torsional vibrations.

The specified technical result, in the implementation of the present invention, is achieved by the fact that in a group protective device containing a base, a support element with holes in which vibration isolators are installed, each of which consists of a mounting sleeve on which elastic elements are placed, a damping sleeve and a sleeve with flanges installed in the hole of the support element with a radial interference and with an axial interference between the flanges of the mounting sleeve and the elastic elements, and the damping sleeve is installed in the hole of the sleeve with fl in between elastic elements with axial interference, each vibration isolator being fixed on the base with a fastening element passing through the hole of the fastening sleeve, in accordance with the invention, the base is equipped with two parallel flanges, and the supporting element is made in the form of two parallel mounting flanges, and the values of radial tightness bushings with flanges installed in each of the mounting flanges are selected from the inequalities:
0 <Δ ₁ ≤ Δ (Pw),
Δ ₂ ≤ Δ (Py),
where Δ ₁ is the value of the radial interference of bushings with flanges installed in the hole of one of the mounting flanges;
Δ ₂ - the value of the radial interference of bushings with flanges installed in the hole of another mounting flange;
Δ (Pv) - radial interference, providing axial displacement of the bushings with flanges in one of the mounting flanges, with a force equal to the permissible amplitude Pv of the vibration load of the support element;
Δ (Py) is the radial interference that provides axial displacement of the bushings with flanges in another mounting flange with a force equal to the permissible amplitude Pу of the shock load of the support element.

The radial interference values Δ ₁ and Δ ₂ for given values (for example, in the technical specifications) of Pv and Py are found either theoretically, for example, by the Lyame formulas [3], or experimentally.

 When exposed to transverse vibratory shock loads, torsional vibrations on the protected object with two mounting flanges are reduced. In the case when the center of mass of the protected object is located at a point relative to which the moment from the reactions of the sum of the forces of the vibration isolators is 0, torsional vibrations disappear completely.

The installation in one of the mounting flanges of the supporting element of the sleeve with flanges with a radial tightness Δ ₁ selected from the condition of their axial movement at a given value of the permissible vibration load Pv, makes it possible, due to the axial displacement of the sleeve with flanges in this mounting flange of the supporting element, to secure group protective device with significant tolerances for the distance between the mounting surfaces of the vibration isolators in different mounting flanges of the support element and between the base flanges. In this case, a load exceeding the axial displacement of the bushings with flanges is not transferred to the elastic elements, which excludes the clamping of the elastic elements.

The structural strength under axial inertial forces and the axial shock absorption are ensured by bushings with flanges installed in another mounting flange with a radial tightness Δ ₂ selected from the condition of their axial movement at a given value of permissible shock load Pu.

 In the study of the distinguishing features of the claims of the described GZU, no similar known solutions were found regarding the reduction of vibrational loads due to the reduction, and in some cases the elimination of torsional vibrations on the protected object, the center of mass of which is offset relative to the supporting element.

In FIG. 1 shows a group protective device (GZU), a top view;
in FIG. 2 - the same front view;
in FIG. 3 is a structural diagram of the GZU, section AA in FIG. 1;
in FIG. 4 is a structural diagram of the GZU, section BB in FIG. 1.

GZU contains a base in the form of parallel flanges 1 and 2, a support element in the form of two parallel mounting flanges 3 and 4, in the openings of which vibration isolators are installed. Each vibration isolator consists of a mounting sleeve 5, a damping sleeve 6 and bushings with flanges 7 and 8, which are installed in the holes of the mounting flanges 3 and 4, respectively, with radial tightnesses Δ ₁ and Δ ₂ , where
Δ ₁ is the value of the radial interference of the sleeve with the flanges 7 installed in the hole of the mounting flange 3;
Δ ₂ - the value of the radial interference of the sleeve with the flanges 8 installed in the hole of the mounting flange 4.

 Between the flanges of the bushings 7 and 8 and the flanges of the mounting sleeves 5 installed elastic elements 9. The fastening elements, made in the form of threaded rods 10 installed in the flanges 1 and 2 of the base, pass through the holes of the mounting sleeves 5 and are tightened with nuts 11.

 A is the distance between the flanges of the base.

 B - the distance between the mounting surfaces of the vibration isolators.

 δ = A-B - the difference in size A and B.

 GZU works as follows.

 When tightening the nuts 11 of all vibration isolators installed in the mounting flange 3, the sleeves move with the flanges 7. Due to this, when tightening the nuts 11 of all vibration isolators installed in the mounting flange 4, gaps δ are formed due to the difference in sizes A and B. A further tightening of the nuts 11 of the vibration isolators installed in the flanges 3 and 4 ensures the fixing of the fixing sleeves 5 in the directions perpendicular to the axes of the studs 10.

 When vibration and shock in the directions perpendicular to the axes of the studs 10, protection is provided due to the deformation of the damping bushings 6 and the elastic elements 9 of all vibration isolators.

 The mounting flanges 3 and 4 of the support element are installed in such a way that under the action of vibrational loads in the transverse direction, the moment in the center of mass of the protected object from the reaction of the sum of the forces of the vibration isolators is 0 and there are no torsional vibrations of the protected object.

 Under the action of vibrations in the axial direction, vibration isolation is carried out due to the elastic elements 9 of all vibration isolators.

 When the inertial force reaches a value exceeding the shear force of the bushings with flanges 7 in the holes of the flange 3, each sleeve with flanges 7 moves with dry friction, dissipating the vibration energy.

 Under the action of the shock load in the axial direction, the impact energy is absorbed due to the deformation of the elastic elements 9 and the movement of the sleeves with flanges 8 in the holes of the flange 4.

At the institute, on this proposal, the design of a group protective device, a device with two parallel base flanges and with two mounting flanges, has been developed, which has the following parameters:
A = 89.5 ± 0.05 mm - the distance between the flanges of the base;
B = 89.5 ± 0.7 mm - the distance between the mounting surfaces of the vibration isolators;
δ = A _max - B _min = 89.55 - 88.8 = 0.75 mm.

Number of vibration isolators (bushings with flanges):
- in a fixing flange 3 - 2 vibration isolators;
- in a fixing flange 4 - 4 vibration isolators;
m = 3.1 kg is the mass of the device;
jв = 180 m / s ² - permissible amplitude of vibrational acceleration of the mounting flange 3;
jу = 10000 m / s ² - permissible amplitude of shock acceleration of the mounting flange 4.

The design of a group protective device was carried out in the following sequence:
- values were determined
Pv = jv • m = 180 • 3.1 = 560 H;
Pу = jу • m = 10000 • 3.1 = 31000 H;
Pv - allowable amplitude of the vibration load of the support element 3;
Pу - allowable amplitude of the shock load of the support element 4.

Based on the experimental data, radial interference fit of bushings with flanges were selected:
- in the mounting flange 3 - Δ ₁ = 0.1 mm (the sleeve 7 is cut along the generatrix of the cylinder to ensure a stable sufficiently small force for the press connection);
- in the mounting flange 4 - Δ ₂ = 0.068 mm (sleeve without a cut).

These interference fit the sleeve shear forces:
180 H <Pv ≅ 560 H - in the mounting flange 3;
9600 H <Pу = 31000 H - in the mounting flange 4;
which corresponds to the amplitudes of acceleration:
60 m / s ² <jв = 180 m / s ² ;
3300 m / s ² <jу = 10000 m / s ² .

Tests have shown that GZU, despite significant tolerances on dimensions A and B, is easy to assemble, bushings with flanges 7 of the mounting flange 3 provide damping (due to displacement with friction of the sleeve with flanges 7 in the holes of the mounting flange) with vibration with an amplitude of more than 60 m / s ² , and the bushings with flanges 8 of the mounting flange 4 provide effective protection against shock loads.

 Thus, the implementation of the base in the form of two parallel flanges, the support element in the form of two parallel flanges, as well as the installation of bushings with flanges in the hole of one of the flanges with radial interference, providing their axial displacement, with a force less than the permissible amplitude Pv of the vibration load, and in the hole of another flange with a radial interference, ensuring their axial displacement, with a force less than the permissible amplitude Pу of the shock load, it reduces vibration shock loads on the protected object by reducing scrap oscillations.

 Sources of information.

 1. V. S. Ilyinsky "Protection of apparatus from dynamic influences" - M .: Energy, 1970, p. 131-132.

 2. Report "Statistical processing of the pressing force of protective devices", number GOSchetut G77381, 1985

 3. Strength calculations in mechanical engineering, vol. II, M .: Mashgiz, 1985, p. 321-379.

Claims (1)

A group protective device containing a base, a support element with holes in which vibration isolators are installed, each of which consists of a mounting sleeve on which elastic elements are placed, a damping sleeve and a sleeve with flanges installed in the hole of the support element with radial interference and with axial interference between the flanges of the mounting sleeve and the elastic elements, and the damping sleeve is installed in the hole of the sleeve with flanges between the elastic elements with axial interference, with each vibration isolator mounted on based on the fastening element passing through the hole of the mounting sleeve, characterized in that the base is provided with two parallel flanges, and the supporting element is made in the form of two parallel mounting flanges, and the values Δ ₁ and Δ _{2 of the} radial interference of the sleeves with flanges installed in each of the mounting flanges are selected from the inequalities:
0 <Δ ₁ ≤ Δ (Pw),
Δ ₂ ≤ Δ (Py),
where Δ ₁ is the value of the radial interference of bushings with flanges installed in the hole of one of the mounting flanges;
Δ ₂ - the value of the radial interference of bushings with flanges installed in the hole of another mounting flange;
Δ (Pv) - radial interference, providing axial displacement of the bushings with flanges in one of the mounting flanges with a force equal to the permissible amplitude Pv of the vibration load of the support element;
Δ (Py) is the radial interference that provides axial displacement of the bushings with flanges in another mounting flange with a force equal to the permissible amplitude Py of the shock load of the support element.

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