RU2750314C1 - Shock absorber - Google Patents

Abstract

FIELD: vehicles.

SUBSTANCE: invention relates to devices for damping vibrations of vehicle suspensions. The shock absorber contains a cylinder with radial holes and a rod with a piston. The compensation chamber is located in the lower part of the cylinder. In the middle part of the cylinder, a clip is installed. The throttle and the safety valves of the compression and rebound motion are installed in the piston. Two hydraulic channels and two check valves, made coaxially in the tee-fitting, are installed outside the cylinder. The upper and lower bolts are mounted laterally at the upper and lower ends of the cylinder and are connected to the over- and under-piston cavities through the upper and lower radial holes. Inside the clip, a groove is made, communicating with radial holes in the middle part of the cylinder. The groove is also connected to the upper and lower bolts. A sealing ring is installed in the middle part of the piston. The upper and lower edges of the piston are made in the form of truncated cones, forming the upper and lower annular conical slots with the cylinder.

EFFECT: technical result is simplifying the design and reducing the weight of the shock absorber while increasing its damping properties, reliability and smooth motion of vehicles on almost any type of road.

1 cl, 4 dwg

Description

The proposed shock absorber belongs to devices for damping vibrations of vibration-insulated objects and is intended for use in vehicle suspensions together with elastic bearing elements.

Known shock absorber containing a reservoir, a cylinder located in the reservoir, a rod installed in the cylinder with a piston attached to it, holes made in the middle part of the cylinder, alternately blocked by a piston, two valves designed to pass fluid from the overpiston and subpiston cavities of the cylinder into the reservoir, a throttling element , made in the form of an insert with a calibrated hole, two hydraulic channels and a brake device made in the form of a cylindrical capsule with two plungers that divide its cavity into three parts - upper, middle and lower, by a spring installed between the plungers and a stop, the first the hydraulic channel connects the above-piston cavity of the cylinder with the upper cavity of the cylindrical capsule, and the second hydraulic channel connects the sub-piston cavity of the cylinder with the lower cavity of the cylindrical capsule, while the stop is made in the form of a sleeve and is fixed in the middle part of the cylindrical capsule, the plungers are located in different the sides of the stop, the ends of the spring are fixed at the ends of the plungers, the reservoir is connected to the middle cavity of the cylindrical capsule by a tube, and the throttling element is installed in the tube [RF patent 2247881, cl. F 16 F 9/48, Bul. No. 7, 2005].

The disadvantage of this shock absorber is the complexity and large dimensions of its design, which increases the mass of the shock absorber. In addition, to compress or stretch this shock absorber from its extreme positions to the middle position (static equilibrium position), a significant force is required, which leads to blocking of the suspension under small disturbances. Also in this shock absorber there is no limitation of the maximum compression and rebound forces. All this leads to a decrease in the smoothness of the vehicle. The absence of a fluid volume change in the shock absorber due to the influence of temperature and leaks of the working medium reduces the efficiency and reliability of its operation, and also increases the axial dimensions of the shock absorber due to the presence of a piston with a double-sided rod.

The closest to the proposed technical solution is a shock absorber containing a cylinder, a rod with a piston installed in the cylinder, dividing the cylinder into above-piston and sub-piston cavities, made in the middle part of the cylinder in two rows of holes, alternately blocked by a piston, two check valves installed on the upper and lower ends of the cylinder and designed to pass fluid from the above-piston and sub-piston cavities of the cylinder, two hydraulic channels, a throttle and safety valves of the compression and rebound strokes, installed in the piston and communicating the above-piston and sub-piston cavities between themselves, a compensation chamber located in the lower part of the cylinder, the upper and the lower cage mounted on the upper and lower ends of the cylinder opposite the check valves, and the middle cage fixed on the middle part of the cylinder opposite the holes, and a groove is made inside the upper cage, communicated through the check valve with the above-piston cavity, inside the lower cage is made a groove communicated through a check valve with a subpiston cavity, upper and lower grooves are made inside the middle cage, while the upper groove of the middle cage is communicated with the overpiston cavity through the holes in the middle part of the cylinder and is connected to the groove of the lower cage by means of the left hydraulic channel, and the lower groove of the middle cage the cage is communicated with the sub-piston cavity through the holes in the middle part of the cylinder and is connected to the groove of the upper cage by means of the right hydraulic channel. This shock absorber provides a smooth increase and limitation of hydraulic resistance on one half of the compression and rebound strokes (from the moment the direction of deformation of the shock absorber changes to the position of static equilibrium) and its sharp decrease on the other half of the compression and rebound strokes (from the position of static equilibrium to the moment the direction of deformation of the shock absorber changes ) [RF patent 2426921, cl. F 16 F 9/48, Bul. No. 7, 2009].

The disadvantage of this shock absorber is that when the piston passes its middle position when the upper row of holes is opened during the compression stroke and the lower row of holes during the rebound, there is an almost instantaneous weakening of resistance, as a result of which large bursts of acceleration occur, leading to a decrease in the smoothness of the vehicle. In addition, the shock absorber has a relatively high design complexity, which increases its mass and reduces its reliability.

In this regard, the most important task is to create a new, simpler and more reliable design of a self-adjusting shock absorber, which ensures a smooth decrease in resistance during the compression and rebound strokes after the piston has passed its middle position.

The technical result of the claimed invention is to simplify the design and reduce the mass of the shock absorber while increasing its damping properties, reliability and smooth running of vehicles on virtually any type of road.

This technical problem is solved by the fact that in a shock absorber containing a cylinder, a rod installed in the cylinder with a piston dividing the cylinder into above-piston and sub-piston cavities, a compensation chamber located in the lower part of the cylinder, upper and lower radial holes made at the ends of the cylinder, radial holes in the middle part of the cylinder, a cage installed in the middle part of the cylinder, a throttle and safety valves for compression and rebound strokes installed in the piston and communicating the above-piston and sub-piston cavities between themselves, two hydraulic channels and two check valves installed outside the cylinder and designed to pass fluid from the above-piston and sub-piston cavities of the cylinder, the shock absorber is equipped with upper and lower links installed on the side at the upper and lower ends of the cylinder and connected to the above-piston and sub-piston cavities through the upper and lower radial holes in the cylinder, a groove is made inside the cage, communicated with the radial holes cylinder and connected to the upper and lower bonds by means of hydraulic channels through check valves installed coaxially in the tee fitting, one end of which is connected to the cage, a sealing ring is installed on the piston in its middle part, and the upper and lower edges of the piston are made in the form of truncated cones, forming with the cylinder upper and lower annular conical slots, providing a smooth decrease in hydraulic resistance when the radial holes in the middle part of the cylinder are opened during compression and rebound strokes after the piston passes its middle position, with the maximum cross-sectional area of the annular conical slots opposite the upper and lower ends piston is greater than or equal to the area of the throttle.

Due to the fact that the shock absorber is equipped with upper and lower links mounted on the side at the upper and lower ends of the cylinder and connected to the above-piston and sub-piston cavities through the upper and lower radial holes in the cylinder, a groove is made inside the cage, communicated with the above-piston and sub-piston cavities through the radial holes of the cylinder and connected to the upper and lower links by means of hydraulic channels through check valves installed coaxially in the tee fitting, one end of which is connected to the cage, simplifies the design and reduces the mass of the shock absorber, which increases the reliability of its operation.

Due to the fact that an O-ring is installed on the piston in its middle part, the upper and lower edges of the piston are made in the form of truncated cones, forming with the cylinder upper and lower annular conical slots, and the maximum cross-sectional area of the annular conical slots opposite the upper and lower ends of the piston is larger or equal to the throttle area, a smooth and significant (more than 4 times) decrease in hydraulic resistance is provided after the piston passes its middle position at the moments of opening the radial holes in the middle part of the cylinder during compression and rebound strokes, which increases the damping properties of the shock absorber and the smoothness of the vehicle.

FIG. 1 shows a general view of the shock absorber; in fig. 2 is a diagram of a suspension with a shock absorber and an elastic element in a static equilibrium position; in fig. 3 - oscillogram of oscillations of the object and the base with kinematic disturbance, Fig. 4 is a working diagram of a self-adjusting shock absorber suspension.

The shock absorber contains a cylinder 1, a rod 2 installed in it with a piston 3, dividing the cylinder 1 into overpiston 4 and subpiston 5 cavities filled with liquid (Fig. 1). At the ends of the cylinder 1, upper 6 and lower 7 radial holes are made, and against them on the side of the cylinder 1, the upper 8 and lower 9 bonds are welded. In the middle part of the cylinder 1, radial holes 10 are made, which have a small diameter and are closed by the piston 3 in the position of static equilibrium (Figs. 1 and 2).

On the cylinder 1, in its middle part, a cage 11 is welded, having an internal groove 12, communicated with the above-piston 4 and sub-piston 5 cavities through the radial holes 10 when the piston 3 is displaced down or up from the middle position in the cylinder 1. On the side of the cage 11 there is a tee fitting 13 , inside of which are coaxially mounted spring-loaded 14 compression stroke check valve 15 and rebound stroke check valve 16, which are connected by means of hydraulic channels in the form of outer tubes 18 and 17 to the lower 9 and upper 8 bonds.

In the piston 3 there is a throttle 19 and safety valves of the compression stroke 20 and the rebound stroke 21, which communicate the above-piston 4 and sub-piston 5 cavities between themselves. An o-ring 22 is installed on the piston 3 in its middle part, and the upper and lower edges of the piston 3 are made in the form of truncated cones, forming with the cylinder 1 upper 23 and lower 24 annular conical slots, providing a smooth decrease in hydraulic resistance when the radial holes 10 are opened after the passage piston 3 of its middle position. Since the maximum cross-sectional area of the annular conical slots 23 and 24 opposite the upper and lower ends of the piston 3 is greater than or equal to the area of the throttle 19, then when the piston 3 opens the radial holes 10, the total liquid throttling area is increased by more than 2 times, which means a significant (more than 4 times ) decrease in the resistance force of the shock absorber.

In the lower part of the cylinder 1 there is a compensating pneumatic chamber 25, which is separated from the hydraulic sub-piston cavity 5 of the cylinder 1 by a floating piston 26.

The shock absorber is connected to the vibration protection object 27 and the base 28, between which an elastic bearing element 29 is installed (Fig. 2).

In the position of static equilibrium, the piston 3 is in the middle of the cylinder 1, overlapping the radial holes 10 with an O-ring 22 (Fig. 1). The corresponding positions of the object 27 and the base 28 are determined by points a ... g (Fig. 3 and 4).

The shock absorber works as follows.

In the section a ... b, the object 27 and the base 28 come closer to each other (x - y <0), which means the compression of the elastic carrier 29 and the shock absorber (Figs. 2, 3 and 4). In this case, the piston 3 moves from the middle part of the cylinder 1 downward, opening the radial holes 10, and the rod 2 enters the cylinder 1 (Fig. 1). The pressure in the sub-piston cavity 5 increases, and in the above-piston cavity 4 decreases, which leads to the movement of the floating piston 26 downward and an increase in the gas pressure in the compensation chamber 25. Under the action of the pressure difference across the piston 3, the liquid from the sub-piston cavity 5, pressing the check valve of the compression stroke 15 , enters the above-piston cavity 4 through the lower radial opening 7 of the cylinder 1, the lower bonnet 9, the lower bypass tube 18, the tee fitting 13, the groove 12 of the cage 13, the radial holes 10 and the upper annular conical slot 23. When the piston 3 moves down in the area a ... b the cross-section of the upper conical slot 14 opposite the radial holes 10 gradually increases, which provides a smooth and significant (more than 4 times) decrease in the shock absorber drag force until the upper end of the piston 3 is located opposite the radial holes 10 (point b in Fig. 3).

In section b ... c, the object 27 and the base 28 continue to approach each other (x - y <0), which means further compression of the elastic carrier 29 and the shock absorber. Since in this case the bulk of the liquid is freely squeezed out through the compression stroke check valve 15, the throttle 19 is practically turned off and the resistance force of the shock absorber is close to zero.

In the section c ... d there is a process of stretching the elastic carrier 29 and the shock absorber (x - y <0) (Fig. 2, 3 and 4). In this case, the piston 3 moves up to the middle part of the cylinder 1, and the rod 2 comes out of the cylinder 1 (Fig. 1). The pressure in the above-piston cavity 4 increases, and in the sub-piston cavity 5 decreases, which leads to the movement of the floating piston 26 upward and a decrease in the gas pressure in the compensation chamber 25. Since the check valve of the compression stroke 15 is closed, the liquid from the above-piston cavity 4 is squeezed out by the piston 3 into the sub-piston cavity 5 through the throttle 19, providing increased resistance of the shock absorber during rebound, which in the section c ... d smoothly increases from the moment the direction of deformation of the shock absorber changes until the moment the seal 22 passes the middle position in the cylinder 1. With the further course of stretching in the section d… e liquid from the above-piston cavity 4 enters the sub-piston cavity 5 not only through the throttle 19, but also through the upper radial hole 6, the upper link 8, the upper bypass tube 17, the rebound stroke check valve 16, the tee fitting 13, the groove 12 of the cage 11, the lower annular conical slot 24 between cylinder 1 and piston 3, which after passing through the piston 3 of the average static position gradually increases, providing a smooth and significant (more than 4 times) decrease in the resistance force of the shock absorber (point e in Fig. 3).

At high rates of suspension stretching in the section c ... e, the rebound travel safety valve 21 is triggered, through which fluid from the above-piston cavity 4 flows into the sub-piston cavity 5, which limits the shock absorber force during rebound.

In the section e ... f, the object 27 and the base 28 continue to move away from each other (x - y> 0), which means further stretching of the elastic carrier 29 and the shock absorber. Since in this case the main volume of fluid is freely squeezed out through the rebound stroke check valve 16, the throttle 19 is practically turned off and the shock absorber resistance force is close to zero.

In the section f ... g, the object 27 and the base 28 come closer to each other (x - y> 0), which means the compression stroke of the elastic carrier 29 and the shock absorber. In this case, the piston 3 moves down to the middle part of the cylinder 1, and the rod 2 enters the cylinder 1. The pressure in the sub-piston cavity 5 increases, and in the above-piston cavity 4 decreases, which leads to the movement of the floating piston 26 downward and an increase in gas pressure in the compensation chamber 25 Since in this case the rebound stroke check valve 16 is closed, the liquid from the sub-piston cavity 5 is squeezed out into the above-piston cavity 4 through the throttle 19, which provides an increased shock absorber resistance, which smoothly increases from the moment the shock absorber deformation direction changes until the seal 22 passes the radial holes 10 into cylinder 1.

At high speeds of compression of the suspension in the sections f ... g and a ... b, the relief valve of the compression stroke 20 is triggered, through which the liquid from the sub-piston cavity 5 flows into the above-piston cavity 4, which limits the force of the shock absorber during the compression stroke.

With further movement of the object 27 and the base 28, the described sequence of the shock absorber is repeated, which provides self-regulation of inelastic resistance in amplitude, direction and speed of vibration, forming a working diagram of the suspension in the form of a "butterfly" (Fig. 4).

The proposed shock absorber provides a smooth increase in resistance when the direction of deformation of the suspension changes and its smooth decrease almost to zero during compression and rebound strokes after the piston passes its average static position and then moves until the direction of deformation changes. This shock absorber operation algorithm provides a decrease in relative displacements (suspension deformation) and accelerations of the vibration protection object in a wide frequency range.

Thus, the claimed technical result is achieved, which consists in simplifying the design and reducing the mass of the shock absorber while increasing its damping properties, reliability of operation and smooth running of vehicles on almost any type of road.

Claims (1)

A shock absorber containing a cylinder, a rod installed in the cylinder with a piston dividing the cylinder into above-piston and sub-piston cavities, a compensation chamber located in the lower part of the cylinder, upper and lower radial holes made at the ends of the cylinder, radial holes made in the middle part of the cylinder, a cage , installed in the middle part of the cylinder opposite the radial holes, a throttle and safety valves of the compression and rebound strokes installed in the piston and communicating the above-piston and sub-piston cavities between themselves, two hydraulic channels and two check valves installed outside the cylinder and designed to pass fluid from the above-piston and sub-piston cavities of the cylinder, characterized in that the shock absorber is equipped with upper and lower links mounted on the side at the upper and lower ends of the cylinder and connected to the above-piston and sub-piston cavities through the upper and lower radial holes in the cylinder, a groove is made inside the cage, communicated with radial holes in the middle part of the cylinder and connected to the upper and lower bonds by means of hydraulic channels through check valves installed coaxially in the tee fitting, one end of which is connected to the cage, an O-ring is installed on the piston in its middle part, and the upper and lower edges of the piston are made in the form of truncated cones, forming with the cylinder upper and lower annular conical slots, providing a smooth decrease in hydraulic resistance when the radial holes in the middle part of the cylinder are opened during compression and rebound strokes after the piston passes its middle position, with the maximum cross-sectional area of the annular conical slots opposite the upper and lower ends of the piston is greater than or equal to the area of the throttle.

Images