RU226945U1 - HYDRAULIC SHOCK ABSORBER WITH CENTERING RECOVERY INSERT - Google Patents

Abstract

The utility model relates to units and parts of machines that ensure their normal operation, namely to means for damping vibrations in suspension devices of vehicles, in particular to shock absorbers using liquid or gas as an absorbing medium for shock absorption, with a piston moving reciprocatingly in chamber, and regenerative centering structural elements and devices that reduce foaming, as well as with throttle channels, and can be used in transport engineering for elastic suspensions with hydraulic shock absorbers. The technical result of the claimed utility model is the expansion of operational capabilities, consisting in the effective implementation of ensuring increased load-bearing capacity, stability, reliability and service life of shock absorbers by eliminating the possibility of inaccurate centering and coaxial misalignment of the working cylinder of the shock absorber, both relative to its reservoir and its other internal components, during its assembly, as well as reducing foaming of the working shock absorber fluid during shock absorber operation. The specified technical result is achieved due to the fact that a hydraulic shock absorber with a centering recuperative insert contains a reservoir with a working cylinder placed in it, in the upper part of the working cylinder there is a rod guide, in the central axial hole of which a rod equipped with a piston, a rod seal ring with a reservoir nut in the upper part of the reservoir and the bottom of the reservoir with a compression valve in the lower part of the reservoir, while the internal cavity of the working cylinder is divided by a piston into a rod part and a piston part, and the reservoir is made in the form of a cylinder with the formation in its internal part by means of the external part of an internal coaxially located a working cylinder of a cylindrical recuperative cavity, and in the cylindrical recuperative cavity there is a centering recuperative insert coaxially located, made of a cylindrical shape, the inner diameter of which corresponds to the outer diameter of the working cylinder, and its outer diameter corresponds to the inner diameter of the reservoir.

Description

The utility model relates to units and parts of machines that ensure their normal operation, namely to means for damping vibrations in suspension devices of vehicles, in particular to shock absorbers using liquid or gas as an absorbing medium for shock absorption, with a piston moving reciprocatingly in chamber, and regenerative centering structural elements and devices that reduce foaming, as well as with throttle channels, and can be used in transport engineering for elastic suspensions with hydraulic shock absorbers.

From the existing level of technology, a hydraulic shock absorber is known (Patent RU 172294 U1, 07/04/2017, F16F 9/18, F16F 5/00), containing a reservoir, inside of which there is a working cylinder, a rod guide, a rod passing through the through axial hole of the rod guide, a piston with a rebound valve and a bypass valve mounted on a rod, as well as a reservoir nut in the upper part of the reservoir and a compression valve in the lower part of the reservoir, while the internal cavity of the working cylinder is divided by the piston into rod and piston parts, and the lower part of the compression valve body is made in in the form of a spherical belt.

A hydraulic damper with a compression valve with a lock is also known from the prior art (Patent RU 2802987 C1, 05.08.2023, F16F 9/16), containing a reservoir, inside of which there is a working cylinder, a rod guide, a rod movably fixed through the through axial hole of the rod guide , and a piston with a rebound valve and a bypass valve attached to the end of the rod, a reservoir nut with a casing cover in the upper part of the reservoir and a compression valve fixed with the bottom of the reservoir in the lower part of the reservoir, while the internal cavity of the working cylinder is divided by the piston into the rod part and a piston part, wherein said compression valve is made in the form of a cylindrical body with adjusting disks and at least one cylindrical lock in its lower part, offset from the center of the generatrix of the axis of said cylindrical body and configured to prevent rotation of said compression valve through at least one blind hole of the said bottom of the tank, which is made coaxially with the said cylindrical retainer.

The closest technical solution is a hydraulic vibration damper for vehicles (Patent RU 126071 U1, 03/20/2013, F16F 9/16, F16F 9/40), containing a housing and a cylinder coaxially located in the housing with a bottom having a throttle, inlet and discharge valves, in the cylinder there is a rod with a piston installed for movement, having throttles, supra-piston and sub-piston valves and dividing the cylinder into supra-piston and sub-piston cavities, and the outer surface of the cylinder forms a compensation cavity with the inner surface of the body, while the supra-piston and sub-piston cavities of the cylinder are filled with working fluid, compensation the cavity between the cylinder and the body is partially filled with working fluid and contains an anti-foam device, the cylinder is closed from above with a guide bushing, while the rod is passed through the central hole in the guide bushing, the entire cylinder-piston group of parts is fixed in the body with a ring nut and sealed with a rubber boot, and the anti-foam device is made in the form of a fine-mesh three-dimensional mesh, for example, metal.

The main disadvantage of the above-described technical solutions is the inability to ensure low foaming of the working shock absorber fluid during operation of shock absorbers, as well as increased load-bearing capacity, stability, reliability and service life of shock absorbers due to the lack of accuracy of coaxial centering of the shock absorber cylinder relative to its reservoir during its assembly.

The technical result of the claimed utility model is the expansion of operational capabilities, consisting in the effective implementation of ensuring increased load-bearing capacity, stability, reliability and service life of shock absorbers by eliminating the possibility of inaccurate centering and coaxial misalignment of the working cylinder of the shock absorber, both relative to its reservoir and its other internal components, during its assembly, as well as reducing foaming of the working shock absorber fluid during shock absorber operation.

The specified technical result is achieved due to the fact that the hydraulic shock absorber with a centering recuperative insert contains a reservoir with a working cylinder placed in it, in the upper part of the working cylinder there is a guide rod, in the central axial hole of which a rod equipped with a piston is movably installed, a rod gland race with a reservoir nut in the upper part of the reservoir and the bottom of the reservoir with a valve compression in the lower part of the tank, while the internal cavity of the working cylinder is divided by the piston into a rod part and a piston part, and the tank is made in the form of a cylinder with the formation of a cylindrical recuperative cavity in its internal part through the external part of the internal coaxially located working cylinder.

Moreover, in the cylindrical recuperative cavity there is a centering recuperative insert coaxially located, made of a cylindrical shape, the inner diameter of which corresponds to the outer diameter of the working cylinder, and its outer diameter corresponds to the inner diameter of the reservoir.

In particular, the centering recuperative insert can be made in the form of a cylindrical lattice rib structure containing at least three cylindrical horizontal ribs, made in the form of rings, parallel to each other and connected by at least three vertical posts, a perpendicular profile the cross-section of each of them in a plane parallel to the flat side of the rings is made in the form of a ring sector.

In this case, the vertical posts on the side of the lower part of the tank may contain clamps made in the form of internal annular sector protrusions for positioning the working cylinder on the compression valve and fixing it directly inside the centering recuperative insert.

In addition, the rings can be made with technological cutouts and slices located on the outer part of the centering recuperative insert, alternating in a checkerboard pattern.

Moreover, the centering recuperative insert can be made of plastic, or impact-resistant polymer material, or composite material.

In this case, the impact-resistant polymer material can be made in the form of caprolon, or fluoroplastic, or polyacetal, or polyurethane, or textolite, or fiberglass, or polypropylene, or polystyrene, or ABS plastic, or HDPE plastic, or getinax.

The essence of the utility model is illustrated by drawings, which show a special case of the proposed hydraulic shock absorber with a centering regenerative insert: figure 1 shows a general cross-sectional view of a hydraulic shock absorber with a centering regenerative insert; in fig. 2 - local view A in Fig. 1; in fig. 3 - axonometric projection of the centering recuperative insert, where:

1 - reservoir;

2 - working cylinder;

3 - rod guide;

4 - rod;

5 - piston;

6 - rod seal ring;

7 - rod seal;

8 - tank nut;

9 - bottom of the tank;

10 - compression valve;

11 - rod part;

12 - piston part;

13 - cylindrical recuperative cavity;

14 - centering recuperative insert;

15 - rings forming cylindrical horizontal ribs of the centering recuperative insert;

16 - vertical posts connecting the rings;

17 - clamps made in the form of internal annular sector protrusions;

18 - technological cutouts on the rings;

19 - technological cuts on rings;

20 - rebound buffer device.

A special case of implementing a hydraulic shock absorber with a centering regenerative insert can be implemented as follows: hydraulic shock absorber with a centering recuperative insert contains a reservoir 1 with a working cylinder 2 placed in it, in the upper part of the working cylinder 2 there is a guide 3 of the rod 4, in the central axial hole of which a rod 4 is movably installed, equipped with a piston 5, a race 6 of the oil seal 7 of the rod 4 with a nut 8 of the reservoir 1 in the upper part of the reservoir 1 and the bottom 9 of the reservoir 1 with a compression valve 10 in the lower part of the reservoir, while the internal cavity of the working cylinder 2 is divided by the piston 5 into the rod 11 part and the piston 12 part, and the reservoir 1 is made in the form of a cylinder with the formation in its inner part by means of the outer part of the internal coaxially located working cylinder 2 of the cylindrical recuperative cavity 13.

Moreover, in the cylindrical recuperative cavity 13 there is a centering recuperative insert 14 coaxially located, made of a cylindrical shape, the inner diameter of which corresponds to the outer diameter of the working cylinder 2, and its outer diameter - to the inner diameter of the tank 1.

The centering recuperative insert 14 can be made in the form of a cylindrical lattice rib structure containing at least three cylindrical horizontal ribs, made in the form of rings 15, parallel to each other and connected by at least three vertical posts 16, perpendicular profile the cross-section of each of them in a plane parallel to the flat side of the rings 15 is made in the form of an annular sector.

In this case, the vertical posts 16 at the end from the bottom of the tank 1 may contain clamps 17, made in the form of internal annular sector protrusions, for positioning the working cylinder 2 on the compression valve 10 and fixing it directly inside the centering recuperative insert 14.

In addition, rings 15 can be made with technological cutouts 18 and slices 19 located on the outer part of the centering recuperative insert 14, alternating in a checkerboard pattern.

Moreover, the centering recuperative insert 14 can be made of plastic, or an impact-resistant polymer material, or a composite material.

In this case, the impact-resistant polymer material can be made in the form of caprolon, or fluoroplastic, or polyacetal, or polyurethane, or textolite, or fiberglass, or polypropylene, or polystyrene, or ABS plastic, or HDPE plastic, or getinax.

In addition, in the shock absorber on the rod 4 in the rod part 10 of the working cylinder 2 coaxially with the rod 4, a rebound stroke buffer device 20 can be made.

A hydraulic shock absorber with a centering regenerative insert is assembled as follows: first, assemble the rod 4 with the rebound stroke buffer device 20. Then, in the cage 6 of the oil seal 7 of the rod 4, the oil seal 7 of the rod 4 is installed. After this, the working cylinder 2 is assembled with the guide 3 of the rod 4, the rod 4, the piston 5 and the compression valve 10, located at the bottom 9 of the tank 1. At the same time, the working cylinder 2 from below, a centering recuperative insert 5 is mounted, which will subsequently be located in the cylindrical recuperative cavity 13, up to the clamps 17 located in the lower part of the vertical posts 16, for positioning the working cylinder 2 on the compression valve 10 and fixing it directly inside the centering recuperative insert 14 Moreover, the centering recuperative insert 14 can be made in the form of a cylindrical lattice rib structure containing at least three cylindrical horizontal ribs, made in the form of rings 15, parallel to each other and connected by at least three vertical posts 16, the perpendicular profile section of each of them in a plane parallel to the flat side of the rings 15 is made in the form of an annular sector. In addition, rings 15 can be made with technological cutouts 18 and slices 19 located on the outer part of the centering recuperative insert 14, alternating in a checkerboard pattern. After that, the working cylinder 2 assembly is placed in the reservoir 1, so that the internal cavity of the working cylinder 2 is divided by the piston 5 into the rod part 11 and the piston part 12. After this, the position of the working cylinder 2 inside the reservoir 1 is fixed using the rod guide 3 4, and close the upper part of the tank 1 with nut 8.

A hydraulic shock absorber with a centering regenerative insert works as follows: rod 4 together with piston 5, during operation of the hydraulic shock absorber, perform reciprocating movements in the working cylinder 2. When rod 4 moves with piston 5 during the compression stroke, the working shock absorber fluid under the pressure of piston 5 through the bypass holes (not shown in the figures) flows from the piston part 12 into the rod part 11 of the working cylinder 2. Part of the volume in the working cylinder 2 during the compression stroke is occupied by the rod 4, and the excess working shock absorber fluid from the piston part 12 through the channels (not shown in the figures) in the compression valve 10 flows into the cylindrical recuperative cavity 13 between the reservoir 1 and the working cylinder 2, creating a compression force. When the rod 4 with the piston 5 moves during the rebound stroke, pressure is created in the rod part 11, and a vacuum is created in the piston part 12, so that the working shock absorber fluid flows through the holes in the piston 5 from the rod part 11 to the piston part 12 of the working cylinder 2, creating a rebound resistance force. During the rebound stroke, the rod 4 ceases to occupy part of the volume in the working cylinder 2. Compensation for changes in the volume of the working shock-absorbing fluid in the working cylinder 2 occurs due to the flow of the working shock-absorbing fluid through the channels of the compression valve 10 from the cavity between the reservoir 1 and the working cylinder 2 into the piston part 12 of the working cylinder cylinder 2. Moreover, when the rod 4 reaches the stop or the maximum stroke length of the said rod 4 during the rebound stroke, the said buffer device 20 collides with the lower surface of the guide 3 of the rod 4. At the same time, on the centering recuperative insert 5, the rings 15 are made with technological cutouts 18 and cuts 19 along the outer part of the centering recuperative insert 14 with alternation in a checkerboard pattern, which ensures a reduction in foaming and optimal flow of shock absorber fluid into the recuperative cavity 13.

This technical result is achieved due to the fact that the constructive coaxial arrangement of the centering recuperative insert in the cylindrical regenerative cavity of the shock absorber fully ensures the accuracy of centering and eliminates the possibility of coaxial misalignment of the working cylinder of the shock absorber, both relative to its reservoir and its other internal components, during its assemblies. And the design of the centering recuperative insert in the form of a cylindrical lattice rib structure containing rings with technological cutouts and sections located on the outer part of the centering recuperative insert alternating in a checkerboard pattern significantly reduces foaming and ensures optimal flow of shock-absorbing fluid, both inside the recuperative cavity and into the recuperative cavity itself.

No technical solutions coinciding with the set of essential features of the claimed utility model have been identified, which allows us to conclude that the claimed utility model complies with such a patentability condition as “novelty”.

Claims (6)

1. A hydraulic shock absorber with a centering recuperative insert, containing a reservoir with a working cylinder placed in it, in the upper part of the working cylinder there is a rod guide, in the central axial hole of which a rod equipped with a piston is movably installed, a rod seal ring with a reservoir nut in the upper part of the reservoir and the bottom of the tank with a compression valve in the lower part of the tank, while the internal cavity of the working cylinder is divided by a piston into a rod part and a piston part, and the tank is made in the form of a cylinder with the formation in its internal part by means of the external part of the internal coaxially located working cylinder of a cylindrical recuperative cavity, characterized in that in the cylindrical recuperative cavity there is a centering recuperative insert coaxially located, made of a cylindrical shape, the inner diameter of which corresponds to the outer diameter of the working cylinder, and its outer diameter corresponds to the inner diameter of the reservoir. 2. A hydraulic shock absorber with a centering regenerative insert according to claim 1, characterized in that the centering recuperative insert is made in the form of a cylindrical lattice rib structure containing at least three cylindrical horizontal ribs, made in the form of rings, parallel to each other and connected by at least three vertical posts, the perpendicular profile section of each of which in a plane parallel to the flat side of the rings is made in the form of a ring sector. 3. A hydraulic shock absorber with a centering regenerative insert according to claim 2, characterized in that the vertical struts on the side of the lower part of the tank contain clamps made in the form of internal annular sector protrusions for positioning the working cylinder on the compression valve and fixing it directly inside the centering regenerative insert . 4. A hydraulic shock absorber with a centering recuperative insert according to claim 2, characterized in that the rings are made with technological cutouts and sections located on the outer part of the centering recuperative insert alternating in a checkerboard pattern. 5. A hydraulic shock absorber with a centering recuperative insert according to claim 1, characterized in that the centering recuperative insert is made of plastic, or an impact-resistant polymer material, or a composite material. 6. A hydraulic shock absorber with a centering recuperative insert according to claim 5, characterized in that the impact-resistant polymer material is made in the form of caprolon, or fluoroplastic, or polyacetal, or polyurethane, or textolite, or fiberglass, or polypropylene, or polystyrene, or ABS plastic , or HDPE plastic, or getinax.