RU2462629C1 - Shock absorber - Google Patents

Abstract

FIELD: machine building. ^ SUBSTANCE: shock absorber comprises a shell for fixation to a base and an elastomer elastic element from two parts placed into a shell. The external surface of each part of the elastomer elastic element is formed with a cylindrical surface transferred from one side into a part of a toroid surface, and on the inner side - into a conical surface. Cylindrical grooves are evenly arranged on a conical surface of each part of an elastomer elastic element radially to an axis of a shock absorber. In the centre of each part of the elastomer elastic element at the side of the conical surface there is a bore in the form of a part of the inner toroid surface. In the central hole of the elastomer elastic element there is a bushing. The bushing is arranged with a ledge in the form of an orifice, with a cylindrical bore under an orifice and a vertical journal in the lower end of the bushing. The external and internal surfaces of the toroid part of the elastic element are equipped with circular ledges of a trapezoid profile. On the tops of external toroid surface there are circular planes formed for installation on the upper and lower sides of the orifice. In the lower elastic element at the side of the circular plane there is a hole. The shell is arranged of two parts in the form of sleeves in the form of truncated cones with central holes in each bottom of the sleeve. Parts of the shell are rigidly connected with each other along the end plane. Conical surfaces of elastic elements are inverted into the bottom of sleeves. One end of the bushing is taken out through a hole in the bottom of the first sleeve for connection to the equipment. The lower end of the bushing is inverted in the hole of the second sleeve. Elastic elements are installed between the orifice and the bottom of sleeves due to preliminary pressing. ^ EFFECT: increased permissible level of vibration and impact actions without increased dimensions of a shock absorber, increased reliability of a shock absorber and efficiency of vibration insulation. ^ 8 dwg

Description

The invention relates to mechanical engineering and is intended to protect against vibration and shock of various equipment and objects.

The level of technology.

Known vibration isolator containing an elastomeric elastic element, in the middle part of which is placed a cage, and in the Central hole of the vibration isolator there is a sleeve with clamping washers, see JP 2008255999 (A), F16F 1/36, 15/08.

The indicated vibration isolator has the following disadvantages: using this design of the vibration isolator, it is impossible to carry out vibration protection of products with a small mass and low frequency resonance, since elastic vibrations in the vibration isolator are carried out mainly due to compression and buckling of the elastic element, but its bending deformations are not used either.

Also known is “Shock Absorber”, RF patent No. 2050483, comprising an elastomeric elastic element made of two parts, the outer surface of each of which is formed by a cylindrical surface, passing on the one hand into a part of the torus surface, and on the other hand into a part of a conical surface with a cone apex directed opposite to the part of the torus surface. On the conical surface of each part of the elastomeric elastic element, cylindrical cavities are made uniformly located on the surface of the cone, the axes of which are located radially to the axis of the shock absorber. In the center of each part of the elastomeric elastic element from the side of the conical surface, a bore is made in the form of a part of the inner torus surface, a sleeve is located in them. The shock absorber contains a clip for attaching the shock absorber to the base, and elastomeric elastic elements are placed in the clip equipped with flanges.

However, at elevated levels of vibration and shock, the elastomeric elastic elements of the shock absorber jump out of the cage and “sit” on the edges of the cage flanges, which reduces the reliability of operation. The shock absorber stops functioning.

The technical problem to which the invention is directed is to create a shock absorber design in which, with the same overall dimensions, the permissible levels of vibration and shock effects and the reliability of the shock absorber are significantly increased. In addition, due to the possibility of reducing the resonant frequency of the shock absorber, the effectiveness of vibration isolation increases, including for equipment with a low weight load.

SUMMARY OF THE INVENTION

To achieve this technical result, a shock absorber containing an elastomeric elastic element made of two parts, with the outer surface of each part of the elastomeric elastic element formed by a cylindrical surface, passing from one side to a part of the torus surface, and from the other side to a conical surface, with a vertex of a cone directed opposite the torus part of the surface, with cylindrical cavities uniformly located on the conical surface of each part of the elastomeric of another element, the axes of which are located radially to the axis of the shock absorber, with a bore in the form of a part of the inner torus surface, made in the center of each part of the elastomeric elastic element from the side of the conical surface, a sleeve located in the central hole of the elastomeric elastic element, a clip for attaching the shock absorber to the base and placed in the holder, the elastomeric elastic element of two parts, unlike the known one, is provided with a sleeve made with a protrusion in the form of a washer, with a cylindrical groove under the washer, thickened fifth in the lower end of the sleeve. On both parts of the elastic element of the shock absorber, the outer and inner surfaces of the torus part are provided with annular protrusions of the trapezoidal profile, and on the tops of the outer torus surfaces circular circles are formed for installation on the upper and lower sides of the washer. At the same time, a hole with a diameter equal to the diameter of the cylindrical groove of the sleeve is made in the lower elastic element from the side of the circular plane to a depth equal to the width of the groove. The holder is made of two parts in the form of glasses in the form of truncated straight circular cones with central holes in each bottom of the glass, taken as the top of the truncated cone, and the edges of the glasses - for the base of the cones, rigidly connected to each other along their end plane. The conical surfaces of the parts of the elastomeric elastic element face the bottom of the glasses. One end of the sleeve is brought out through an opening in the bottom of the first glass to attach to the equipment, and the other lower end of the sleeve faces the hole of the second glass. In this case, the elastic elements are installed between the washer and the bottom of the glasses without glue due to preliminary preload. A washer is located in the middle part of the shock absorber, to which parts of an elastomeric elastic element are connected on both sides by their annular projections.

For mounting the shock absorber on the base, the cage is provided with flanges in the middle or lower parts of the shock absorber.

Thus, the salient features of the invention is the new design of the shock absorber, in which the located components of the elastomeric elastic element are placed in a closed space of a closed casing, pressing the parts of the elastic element to the washer, ring protrusions, circular planes and a narrowed hole to the depth part of the lower elastic element, and Also, a cylindrical groove and a thickened heel on the central sleeve ensure the functioning of the shock absorber at elevated levels of vibration and ary effects, enhance its reliability and durability, eliminates "jumping out" of the elastic elements of the cage and "falling off" of a sleeve, preventing pressure sores and damage of elastic elements on the edges of the hole washer and the cage. Due to the possibility of reducing the frequency of resonant oscillations, the efficiency of vibration isolation of equipment increases. The space below the shock absorber required for its operation is reduced by eliminating the course of the elastic element below the cage.

List of figures:

figure 1 presents a longitudinal section of the shock absorber on the axis, made in accordance with the invention, in the installation of the mounting flange in the middle of the shock absorber;

figure 2 presents a top view of the shock absorber of figure 1;

figure 3 is a longitudinal section of the shock absorber on the axis, made in the embodiment with the installation of the mounting flange at the bottom of the shock absorber;

figure 4 presents a top view of the shock absorber of figure 3;

figure 5 shows a longitudinal section of an elastomeric elastic element along the axis, made for installation in shock absorbers on top of the washer shown in figures 1 and 3;

figure 6 is a top view of the elastomeric elastic element;

in Fig.7 shows a longitudinal section of an elastomeric elastic element along the axis, made for installation in shock absorbers from the bottom of the washer shown in Fig.1 and 3;

on Fig is a top view of the elastomeric elastic element.

The implementation of the claimed invention

The shock absorber, see figure 1, 2, contains a cage consisting of two parts made in the form of glasses 1 and 2 in the form of truncated straight circular cones with central holes 12 in the bottom of the glasses and the edges of the glasses rigidly connected to each other along the end plane. A washer 4 is located on the sleeve 7 in the middle part of the shock absorber, on the upper and lower surfaces of which are symmetrically placed by their external torus surfaces through circular planes and pressed to them are parts of the elastomeric elastic element 3 and 11, the conical surfaces 15 of which are facing the bottom of the cups 1 and 2.

Glasses 1 and 2 are given a conical shape to increase the volume in the places of deformation of the bulging surfaces of the elastomeric elastic elements 3 and 11 and increase the space for moving the washer 4 in the horizontal direction.

For mounting the shock absorber to the base on a holder consisting of two glasses 1 and 2, flanges 5 and 6 are formed, see Figs. 1, 2, 3 and 4.

One end of the sleeve 7 in the upper part is brought out through an opening 12 in the bottom of the upper glass for attachment to the equipment, and the other end of the sleeve 7 is made with a cylindrical groove 20 under the washer 4 to a part of the length of the sleeve 7 and a thickened fifth 8 and faces the hole of the second glass 2.

A sleeve 7 with a washer 4, a fifth 8, a cylindrical groove 20, a threaded hole 9, and a flange with flats 10 are made in one piece. Two parts of the elastomeric elastic element 3 and 11 are placed inside the parts of the holder 1 and 2. The cylindrical groove 20 on the sleeve 7 and the narrowed part 21 of the central hole 14 of the elastic element 11 placed therein prevents the elastic element 11 from jumping off the sleeve 7, and the heel 8 on the sleeve 7 limits the movement of the elastic element 11 on the sleeve.

The end face of the sleeve 7 with a threaded hole 9 and a flange with flats 10 for a wrench goes through the hole 12 in the bottom of the glass 1 and serves to mount the equipment on the shock absorber. The hole in the bottom of the other glass 2 eliminates the impact of the heel 8 on the bottom of this glass 2 when moving the sleeve 7 down.

Each part of the elastomeric elastic element 3 and 11 is made with a central hole 14, an end conical surface 15, on which cylindrical cavities 16 are uniformly located, the axes of which are located radially to the axis of the shock absorber, the lateral cylindrical surface 18 turning into a toroidal generatrix 19, while on the end the conical surface 15 is made toroidal bore 17, see figure 5, 6, 7, 8.

In the Central hole 14 of the elastic element 11 from the side of the circular plane 22, the hole 21 is made narrowed to a part of the depth of the hole 14 with a diameter equal to the diameter of the groove on the sleeve 7.

On the inner 17 and outer 18 toroidal surfaces of the elastic element, annular protrusions 23 and 24 of a trapezoidal profile are formed respectively.

Parts of the elastomeric elastic element 3 and 11 with their holes 14 and 21 are placed on the cylindrical part of the sleeve 7 with a slight interference fit, see Figs. 1, 3, 5 and 7. In this case, the torus surfaces 19 are pressed against the circular planes 22 of the elastic elements 3 and 11 the washer 4, and the conical surfaces 15 abut against the bottom of the glasses 1 and 2. Elastic elements 3 and 11 are installed between the washer 4 and the bottom of the glasses 1 and 2 without glue due to preliminary preload.

Figure 3 and 4 shows the inventive shock absorber, but with the location of the mounting flange 6 at the bottom of the shock absorber in the plane of the bottom of the conical cup 2.

The shock absorber also contains two parts of the elastomeric elastic element 3 and 11, a washer 4, a sleeve 7, a clip of two parts 1 and 2 rigidly connected to each other in the middle part of the shock absorber, for example, a bracket 13.

In this case, the parts of the elastomeric elastic element 3 and 11 are in a closed space between the surfaces of the cups 1 and 2 and the washer 4, which eliminates their loss from this space and maintains the damping effect due to the constant contact of the elastic elements on the surface of the cage with increased levels of vibration and shock . The new design of the shock absorber, in which the annular protrusions 23 and 24, the circular planes 22 and the narrowed hole 2 on the depth part of the lower elastic element, as well as the cylindrical groove 20 and the thickened heel 8 on the central sleeve 7 provide the shock absorber to operate at elevated levels of vibration and shock, increase its reliability and durability, eliminate the "popping up" of elastic elements from the cage and "jumping" them from the sleeve, preventing damage and damage to the elastic elements on the edges of the washer and holes in the ymah. Due to the possibility of reducing the frequency of resonant oscillations, the efficiency of vibration isolation of equipment increases. Reduces the space for mounting the shock absorber by eliminating the course of the elastic element down from the cage.

Thus, the essential distinguishing features of the invention and the structural elements of the prototype fully provides a technical solution to which the invention is directed.

Shock absorber

In the resonant frequency range (up to 1.5-2.0 f ₀ , where f ₀ is the resonant frequency of the shock absorber under a weight load), the elastic elements of the shock absorber 3 and 11 experience maximum deformations at which the washer 4 compresses the hemisphere of the parts of the elastic element 3 or 11 and each inner toroidal surface 17 tends to cling to the bottom of the cage of two parts 2 or 1. In this case, the annular protrusions 23, expanding in diameter, lie on the bottom of the parts of the cage, prevent further deformation of the elastic element, damp the pressing of the elastic element to the bottom of the cage and The damage and toroidal surface 19 of the elastic element 3 and 11 are also affected by the edges of the hole 12 in the bottom of the parts of the holder 1 and 2.

A similar effect occurs with the horizontal deformation of the elastic element, where the annular protrusions 24 on the outer toroidal surface 19, in addition, protect against the collision of the washer 4 on the inner surface of the cage 1 and 2.

When squeezing the elastic element 3 and 11 with the washer 4, the circular plane 22 maintains the integrity of the external toroidal surface 19.

The deformation of the elastic element along the axis of the shock absorber is accompanied by the expansion of the central hole 14 from the side of the inner toroidal surface 17 and the compression of the hole 21 from the side of the circular plane 22. Based on this effect, the holding of the elastic element 11 in the cylindrical groove 20 on the sleeve 7 is based.

In the non-resonant frequency range, vibration and shock loads acting on the yoke 1 and 2 are absorbed in the elastic elements 3 and 11. The elastic elements work both in compression and in bending, which allows for large deformations to provide large deformations and increase the efficiency of vibration isolation due to the implementation of shock absorption with resonance at lower frequencies, including for vibration protection of products with a small mass.

The resonant oscillations in the shock absorber are reduced due to internal losses in the elastomer 3 and 11, the friction of the elastic elements against the sleeve 7 and the inner surface of the glasses 1 and 2 and the washer 4. The calculated geometric dimensions of the elastic elements 3 and 11 provide a resonant frequency of the shock absorber in a wide frequency range, in including low-frequency at a given weight load of the equipment, which increases the effectiveness of vibration isolation of the shock absorber.

Claims (1)

A shock absorber containing an elastomeric elastic element made of two parts, with the outer surface of each part of the elastomeric elastic element formed by a cylindrical surface, passing from one side to a part of the torus surface, and from the other inner side to a conical surface, with the top of the cone pointing opposite torus part of the surface, with cylindrical cavities uniformly located on the conical surface of each part of the elastomeric elastic element, the axes of which are located radially Along the axis of the shock absorber, with a bore in the form of a part of the inner torus surface, made in the center of each part of the elastomeric elastic element from the side of the conical surface, a sleeve located in the central hole of the elastomeric elastic element, a clip for attaching the shock absorber to the base and an elastomeric elastic element made of two parts, characterized in that the sleeve is made with a protrusion in the form of a washer, with a cylindrical groove under the washer, with a fifth in the lower end of the sleeve, on both parts of the elastic element and the external and internal surfaces of the torus part are equipped with annular protrusions of the trapezoidal profile of the shock absorber, and circular planes are formed on the tops of the external torus surfaces for installation on the upper and lower sides of the washer, while a hole with a diameter equal to the diameter of the groove is made in the lower elastic element from the side of the circular plane bushings to a depth equal to the width of the groove, the cage is made of two parts in the form of glasses in the form of truncated straight circular cones with central holes in each bottom a channel taken as the top of a truncated cone, and the edges of the glasses — for the bases of the cones rigidly connected to each other along their end plane, the conical surfaces of the elastic elements face the bottom of the glasses, one end of the sleeve is brought out through an opening in the bottom of the first glass to attach to the equipment, and the other lower end of the sleeve faces the hole of the second glass, while the elastic elements are installed between the washer and the bottom of the glasses without glue, due to pre-tightened.

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