RU176234U1 - Hydraulic shock absorber - Google Patents

Abstract

The utility model relates to the field of transport engineering, namely to the design of hydraulic shock absorbers. The hydraulic shock absorber comprises a reservoir with a working cylinder placed therein, containing a rod guide, a rod movably fixed in the rod guide, a piston with throttling elements, a rebound valve, a rebound valve disk, a rebound valve spring, a rebound valve nut, a compression valve and a tank bottom. the rebound valve nut has a cylindrical shape, contains a through axial hole having an upper and lower part, the diameter of the upper part exceeding the diameter of the lower part, the lower part of the through axial hole with holds the applied thread, a hexagonal flange is located at the bottom of the rebound nut, and the outer surface of the rebound nut has two levels of different diameters and heights. Moreover, the outer surface of the rebound valve nut has an additional level, while the diameter of the first level is equal to the inner diameter of the rebound valve spring, and its height is 85-100% of the cross-sectional diameter of the wire from which the rebound valve spring is made, the diameter of the second level is 70 - 80 % of the inner diameter of the spring of the rebound valve, and its height exceeds the boundary of the upper and lower parts of the through axial hole by 25-35% of the height of the upper part of the through axial hole, and the diameter of the third level is 60-70% of the internal The smaller diameter of the rebound valve spring. The technical result, the achievement of which the claimed utility model is directed, is to increase reliability and increase the service life of the hydraulic damper rebound valve nut. 3 ill.

Description

HYDRAULIC SHOCK ABSORBER

                                                                                                                         IPC: F16F5 / 00

The utility model relates to the field of transport engineering, namely to the design of hydraulic shock absorbers.

A hydraulic shock absorber is known, comprising a reservoir in which a working cylinder is installed, comprising a rod guide, a rod provided with a piston located in a through axial hole of the rod guide, a rebound valve, a rebate valve disc, a rebate valve nut, a compression valve, and a tank bottom. Moreover, the rebound valve nut has a cylindrical shape, a through axial hole containing a protrusion in the lower part, and the outer surface in the lower part contains a hexagonal flange. [Patent No.RU2020310, priority date: 10/31/1991; publication date: 09/30/2004 IPC: F16F5 / 00].

A hydraulic shock absorber is known, comprising a reservoir equipped with a working cylinder comprising a rod guide, a rod equipped with a piston with throttling elements, movably fixed in the rod guide, a rebound valve, a rebound valve disk, a rebound valve spring, a rebound valve nut, a compression valve and a tank bottom. Moreover, the rebound valve nut has a cylindrical shape, a through axial hole and a hexagonal flange in the lower part of the housing. [Patent No.RU118000, priority date: September 29, 2011 publication date: July 10, 2012 IPC: F16F9 / 16, F16F9 / 36].

As a prototype, a hydraulic shock absorber was selected, which contains a reservoir equipped with a working cylinder containing a rod guide, a rod movably fixed in the rod guide, equipped with a piston with throttling elements, a rebound valve, a rebound valve disk, a rebound valve spring, a rebound valve nut, a compression valve and the bottom of the tank. Moreover, the rebound valve nut has a cylindrical shape, contains a through axial hole having an upper and lower part, and the diameter of the upper part exceeds the diameter of the lower part, the lower part of the through axial hole contains a thread, a hexagonal flange is located in the lower part of the rebound nut, and the outer surface of the nut The rebound valve has two levels of different diameters and heights. [Patent No. RU78539, priority date: July 16, 2008, publication date: November 27, 2008 IPC: F16F5 / 00].

The main disadvantage of the prototype is that during operation of the hydraulic shock absorber, contact may occur between the inner surface of the spring of the rebound valve, performing work on twisting and compression, and the outer surface of the nut of the rebound valve, which can lead to wear of parts, ingress of wear products into the working fluid and clogging of the rebound valve, and the small distance between the inner surface of the upper part of the axial hole and the outer surface of the nut of the rebound valve can lead to eniyu top of rebound valve nut rebound valve defect and failure of the hydraulic damper.

The technical task of the claimed utility model is to increase the reliability of the hydraulic shock absorber.

The technical result, which is achieved by the claimed utility model, is to increase reliability and increase the service life of the nut of the rebound valve of the hydraulic shock absorber.

The essence of the claimed utility model is as follows.

The hydraulic shock absorber comprises a reservoir with a working cylinder placed therein containing a rod guide, a rod movably fixed in the rod guide, a piston with throttling elements, a rebound valve, a rebound valve disk, a rebound valve spring, a rebound valve nut, a compression valve and a tank bottom, moreover the rebound valve nut has a cylindrical shape, contains a through axial hole having an upper and lower part, the diameter of the upper part being greater than the diameter of the lower part, the lower part of the through axial hole having holds the applied thread, a hexagonal flange is located at the bottom of the rebound nut, and the outer surface of the rebound nut has two levels of different diameters and heights. Unlike the prototype, the outer surface of the rebound valve nut has an additional level, while the diameter of the first level is equal to the inner diameter of the rebound valve spring, and its height is 85-100% of the cross-sectional diameter of the wire from which the rebound valve spring is made, the diameter of the second level is 70 - 80% of the inner diameter of the rebound valve spring, and its height exceeds the boundary of the upper and lower parts of the through axial hole by 25-35% of the height of the upper part of the through axial hole, and the diameter of the third level ra veins 60-70% of the inner diameter of the rebound valve spring.

The tank has a cylindrical shape and is made of metal, performs structural and protective functions. Inside the tank are the main structural components and elements, as well as the working fluid or gas. For the hydraulic shock absorber to work properly, the reservoir must be tight and free from kinks, and have strength and rigidity.

The working cylinder has a shape determined by the shape of the selected hydraulic shock absorber piston, and can be made of metal. In the working cylinder are sequentially arranged: rod guide, rod, piston, rod nut, compression valve. In the working cylinder, the process of absorbing vibrations created by the piston of the hydraulic shock absorber, the working fluid and converting them into thermal energy occurs. Excess working fluid flows into the tank through a compression valve installed at the bottom of the working cylinder. The working cylinder is located inside the tank, while in the upper part it is fixed by the rod guide.

The rod guide contains a cylindrical body, which can be made of metal, ceramic, or cermet. A through axial hole is made in the center of the housing of the rod guide, equipped with sealing and antifriction elements, into which a rod is installed, the surface of which forms a sliding bearing with the surface of the axial hole, which performs guiding functions and provides rotational and reciprocating rod mobility necessary for the operation of the hydraulic shock absorber. The rod guide is installed in the upper part of the tank, provides immobility of the working cylinder relative to the tank and seals the hydraulic shock absorber.

The rod has a cylindrical shape and is a metal rod coated on the outside with a layer of chromium, which reduces the friction forces arising between the surface of the rod and the surface of the axial through hole of the rod guide. The rod length is due to the design features of the attachment to the unsprung masses of the vehicle, as well as the scope of the hydraulic shock absorber. In the lower part of the rod, a seat for the piston with throttling elements is made, and at the end, a thread is applied to install a rod nut that fixes the piston with throttling elements motionlessly on the seat.

The piston has a predominantly cylindrical shape; its dimensions are determined by the design features and the scope of the hydraulic shock absorber. The piston may be made of metal or composite materials. The piston has a through axial hole in which the stem is inserted, and also contains concentric through holes that play the role of throttling elements. Concentric holes made in the piston have a calibrated size and, together with the disk, spring and nut of the rebound valve, form the rebound valve of the hydraulic shock absorber. The part of the working cylinder located above the piston is supra-piston, and the part of the working cylinder located under the piston is sub-piston. The piston attached to the shock absorber rod makes reciprocating movements in the working cylinder, and the working fluid flowing through the through concentric holes of the throttle piston system absorbs the oscillations created by the piston, thereby doing the work of converting translational movements into thermal energy.

The hydraulic damper rebound valve is formed by a group of concentric through holes made in the piston, having a calibrated size and covered at the bottom of the piston by the rebound valve disc, which in turn is held in place on the stem using the rebound valve spring fixed with a nut rebound valve. The rebound valve is designed to damp vibrations that occur when the rod moves upward by limiting the amount of working fluid flowing through concentric openings from the over-piston to the under-piston part of the working cylinder.

The rebound valve disk can be made of materials resistant to elastic deforming loads, for example, from a sheet of spring steel by stamping. The rebound valve disk contains a through axial hole, which is designed to install the disk on a seat made on the shock absorber rod. The rebound valve disc is designed to overlap concentric through holes and is mounted on the stem after installing the piston. The number of rebound valve discs installed may vary depending on the required damping characteristics. The gap formed between the lower surface of the piston and the upper surface of the rebound valve disc limits the amount of working fluid flowing through concentric through holes when the piston rod moves up.

The spring of the rebound valve is a wire, spirally twisted around the axis, made of metal that can withstand prolonged elastically deforming loads, for example, of various grades of spring steel. The spring has a cylindrical shape, has landing sites on the upper and lower surfaces, which are represented by a coil of spring bent to a horizontal level, and is mounted on the rod so that the platform of the upper surface of the spring presses the release valve disc and the platform of the lower surface of the spring is on the seat made on the upper surface of the hexagonal flange of the rebound valve nut, which creates the downforce of the spring.

The clamping force of the spring may vary depending on how tight the release valve nut is. The spring of the rebound valve, which is elastically deformed by the acting clamping force, acts on the bottom surface of the rebound valve disc, holds it at the seat and ensures that the gap formed between the top surface of the rebound valve disc and the bottom surface of the piston remains constant. Additionally, on the landing site, made on the upper surface of the spring of the rebound valve, a rebound valve plate can be installed to protect the rebound valve disc from frictional effects that occur during operation of the hydraulic shock absorber,

The rebound valve nut has a cylindrical shape and can be machined from metal, for example, structural steel. The rebound valve nut is mounted on the stem and tightened with a certain torque, thus providing the necessary preload of the rebound valve spring. The cylindrical shape of the rebound valve nut is due to the fact that during installation, part of the rebound valve nut is located inside the rebound valve coil spring.

The through axial hole made in the end valve nut contains the upper and lower parts, the diameter of the upper part exceeding the diameter of the lower part, and the lower part of the through axial hole contains applied thread intended for detachable connection when installing the end valve nut on the seat made on the shock absorber stock. The diameter of the upper part of the through axial hole exceeds the diameter of the lower part of the through axial hole in order to enable the installation of the rebound valve nut to overlap the part of the rod that is not threaded and allows the number of rebate valve discs and the preload force of the rebound valve spring to be changed.

The hexagonal flange made in the lower part of the nut provides the possibility of mounting the nut with a tool, and the upper surface of the flange serves as a seat for a platform made in the lower part of the rebound valve spring.

The outer surface of the rebound valve nut contains three levels that allow the rebound valve spring to move freely, preventing contact between the outer surface of the rebound valve nut and the inner surface of the rebound valve spring, while compressing and twisting the spring, while ensuring the strength of the valve nut lights out. The number of levels is due to the fact that the deformation of the spring of the rebound valve occurs in the upper and middle parts with varying degrees, and the lower part of the spring must be fixedly fixed.

The first level is located in the lower part of the rebound valve nut, above the hexagonal flange of the rebound valve nut and is obtained by turning. The diameter of the first level is equal to the inner diameter of the rebound valve spring, which ensures the immobility of the bottom surface of the rebound valve spring relative to the rebound valve nut. In the case when the diameter of the first level is less than the internal diameter of the spring, there is a risk that during operation of the hydraulic shock absorber, the platform made in the lower part of the spring of the rebound valve will have mobility in the horizontal plane relative to the rebound nut. In the case when the diameter of the first level will exceed the inner diameter of the rebound valve spring, the installation of the platform made in the lower part of the rebound valve spring on the seat made on the upper surface of the hex bead will not be possible.

The height of the first level is 85-100% of the cross-sectional diameter of the wire from which the rebound valve spring is made, which reduces the risk of jumping of the bottom surface of the rebound valve spring, represented by a horizontal turn, to the surface of the second level as a result of spring mobility in the vertical plane. In the case when the height of the first level is less than 85% of the cross-sectional diameter of the wire from which the rebound valve spring is made, there is a risk that the pad of the bottom surface of the rebound valve spring will jump to the second level. In the case when the height of the first level exceeds 100% of the cross-sectional diameter of the wire from which the rebound valve spring is made, there is a risk of contact between the surface of the protrusion and the second coil of the rebound valve spring.

The second level is located in the middle of the rebound valve nut and is obtained by turning. The diameter of the second level is 70-80% of the inner diameter of the rebound valve spring, which provides the necessary distance for the free travel of the rebound valve spring during compression and twisting and forms a sufficient wall thickness of the rebound valve nut. In the case where the diameter of the second level is less than 70% of the inner diameter of the rebound valve spring, the risk of destruction of the formed wall of the rebound valve nut increases. In the case where the diameter of the second level exceeds 80% of the inner diameter of the rebound valve spring, the risk of contact between the inner surface of the rebound valve spring and the outer surface of the rebound nut is increased.

The height of the second level exceeds the boundary of the upper and lower parts of the through axial hole by 25-35% of the height of the upper part of the axial hole, which provides sufficient wall thickness formed between the transition to the third level, having a smaller diameter, and the inner surface of the upper part of the through axial hole of the nut rebound valve. In the case where the height of the second level does not exceed 25% the boundary of the upper and lower parts of the through axial hole formed between the transition to the third level having a smaller diameter and the inner surface of the upper part of the through axial hole, the wall has insufficient thickness, which increases the risk of separation the top of the rebound valve nut. In the case where the height of the second level exceeds the boundary of the upper and lower parts of the through axial hole by 35%, contact may occur between the inner surface of the rebound valve spring and the outer surface of the rebound nut.

The third level is located at the top of the rebound valve nut and is obtained by turning. The diameter of the third level is 60-70% of the inner diameter of the rebound valve spring, which provides the distance necessary for the spring to move freely during compression and twisting and forms a wall whose thickness is sufficient to ensure the strength of the rebound valve nut. In the case where the diameter of the third level is less than 60% of the inner diameter of the rebound valve spring, the risk of breaking the wall formed between the outer surface of the rebound nut and the surface of the upper part of the through axial hole increases. In the case where the diameter of the third level exceeds 70% of the inner diameter of the rebound valve spring, the risk of contact between the inner surface of the rebound valve spring and the outer surface of the rebound nut is increased.

The hydraulic shock absorber compression valve comprises a housing whose shape follows the shape of a working cylinder and can be made of metal or composite materials. The housing may contain one or more through holes or channels. The compression valve provides centering of the working cylinder in the reservoir of the hydraulic shock absorber.

The bottom of the tank is made by sheet metal stamping, has a round shape and is attached to the tank in one piece, for example, by welding, or it can be a single element with the tank. The bottom of the tank provides tightness and a fulcrum for the hydraulic shock absorber assemblies located inside the tank. Elements can be attached to the bottom surface of the bottom of the tank in various ways, which secure the hydraulic shock absorber to the unsprung masses of the vehicle, for example, an eye or bracket.

The inventive utility model has new significant distinguishing features:

⎯ the diameter of the first level is equal to the inner diameter of the rebound valve spring, and the height is 85-100% of the cross-sectional diameter of the wire from which the rebound valve spring is made, this provides immobility and prevents the risk of skewing the bottom of the spring relative to the upper surface of the hex flange of the rebound valve nut, thereby reducing the possibility of production and damage to the upper surface of the hex flange of the rebound valve nut.

⎯ the diameter of the second level is 70 - 80% of the inner diameter of the rebound valve spring, which provides the distance necessary for the spring of the rebound valve to move freely during the compression and torsion work by the spring, reducing the risk of contact between the inner surface of the spring and the outer surface of the valve nut rebound, and the height exceeds the boundary of the upper and lower parts of the through axial hole by 25-35% of the height of the upper part of the through axial hole, thereby ensuring the thickness of the valve nut wall a rebound, i.e. the distance from the outer to the inner surface of the rebound valve nut, reducing the risk of cracks and destruction of the nut prevents rebound valve during the operation of the hydraulic damper.

—The third-level diameter is 60-70% of the inner diameter of the rebound valve spring and provides the space necessary for the spring-back of the rebound valve spring during compression and torsion work by the spring, reducing the risk of contact between the inner surface of the spring and the outer surface of the nut.

The distinguishing features that characterize the claimed utility model, at the same time reduce the possibility of formation and damage to the upper surface of the hex flange of the rebound valve nut, reduce the risk of contact between the inner surface of the rebound valve spring and the outer surface of the rebound nut, and reduce the risk of failure of the rebound nut due to which a technical result is achieved, which consists in increasing reliability and increasing the service life of the rebound valve nut, which in turn, improves the reliability of the hydraulic shock absorber.

The presence of new distinctive essential features indicates the compliance of the claimed utility model with the patentability criterion of "novelty."

The inventive utility model can be made of known materials using known means, which indicates the compliance of the claimed utility model with the patentability criterion of "industrial applicability".

The inventive utility model is illustrated by the following drawings:

FIG. 1 - General view of the hydraulic shock absorber.

FIG. 2 - Nut valve rebound.

Figure 3 - Valve rebound hydraulic shock absorber.

A hydraulic shock absorber, consisting of a reservoir 1 containing a working cylinder 2, into which a rod 3 is immersed, movably fixed in a through axial hole of the rod guide 4 and provided with a piston 5 with throttling elements 6, among which there is a rebound valve formed by through concentric holes 7 and discs 8 rebound valve, pressed by the spring 9 of the rebound valve, having platforms 10, made in the upper and lower parts, and resting on the hexagonal flange 11 of the nut 12 of the rebound valve, having on the outer surface three level 13, 14, 15 and containing a through axial hole. In this case, the through axial bore of the rebound valve nut 12 comprises an upper part 16 and a lower part 17, wherein the lower part 17 contains a thread for securing the rebar valve nut 12 on the stem 3. A compression valve 18 is installed in the bottom of the reservoir of the hydraulic shock absorber. In this case, the spring 9 of the rebound valve is equipped with a plate 19 of the rebound valve.

During operation of the hydraulic shock absorber, the rod 3 together with the piston 5 make reciprocating movements in the working cylinder 2. When the rod 3 moves with the piston 5 downward, the working fluid flows under the pressure of the piston 5 through the throttling elements 6 from the under-piston part to the over-piston part of the working cylinder 2. Part the volume of the working fluid during compression flows through the compression valve 18 into the cavity of the tank 1. When the rod 3 moves upward, the working fluid under pressure of the piston 5, through the throttling elements 6, flows from above orshnevoy portion in subpiston and piston underpressure created in the working cylinder 2 through valve 18 draws hydraulic fluid from the compression of the tank 1. Thus, the work performed by the working fluid dampens oscillations arising during operation of the hydraulic damper.

During operation of the hydraulic shock absorber, when the rod 3 moves upward with the piston 5, the working fluid flows through calibrated concentric through holes 7 covered by the rebound valve discs 8 and flows from the over-piston part to the under-piston part of the working cylinder, and its quantity is limited by the rebound valve discs 8 . The working fluid overcomes the resistance of the rebound valve discs 8, which are pressed against the lower surface of the piston 5 by means of the rebound valve spring 9 resting on the upper surface of the hexagonal flange 11 of the rebound valve nut 12. The working fluid interacts with the upper surface of the disc 8 of the rebound valve and acts on the spring 9 of the rebound valve, which begins to curl and contract. Levels 13, 14, 15 performed on the outer surface of the rebound valve nut 12 provide free space for twisting and compression of the rebound valve spring 9 and exclude contact between the inner surface of the rebound valve spring 9 and the outer surface of the rebound nut 12, eliminating the negative frictional effect of a stronger material rebound valve springs 9 to the less durable material of the rebound valve nut 12, thereby increasing the life of the rebound valve nut and increasing the reliability of the hydraulic shock absorber.

Claims (1)

A hydraulic shock absorber comprising a reservoir with a working cylinder containing a rod guide, a rod movably fixed in the rod guide, a piston with throttling elements, a rebound valve, a rebound valve disk, a rebound valve spring, a rebound valve nut, a compression valve, and a tank bottom, moreover, the rebound valve nut has a cylindrical shape, contains a through axial hole having an upper and lower part, and the diameter of the upper part exceeds the diameter of the lower part, the lower part of the through axial hole contains thread, a hexagonal flange is located in the lower part of the rebound nut, and the outer surface of the rebound nut has two levels of different diameters and heights, characterized in that the outer surface of the rebound nut has an additional level, while the diameter of the first level is equal to the inner diameter of the spring rebound valve, and its height is 85-100% of the cross-sectional diameter of the wire from which the rebound valve spring is made, the diameter of the second level is 70 - 80% of the inner diameter of the valve spring ana rebound, and its height exceeds the boundary of the upper and lower parts of the through axial hole by 25-35% of the height of the upper part of the through axial hole, and the diameter of the third level is 60-70% of the inner diameter of the spring of the rebound valve.

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