DE4238728A1 - Vibration damper with speed dependent change of damping force - has two work chambers in piston cylinder connected by openings and additionally using by=pass with valve seat and spring. - Google Patents

Abstract

The fluid-filled cylinder has a piston (12) connected to a piston rod (1) and dividing the inner space into two work chambers (9,10) which can be connected together in the piston by openings (7) and damping valves (8). These work chambers can be further connected together by a bypass (6) in the piston rod parallel to the damper valves (8). A valve (2) in the bypass has on each side of a valve body (4) a valve seat interacting with the valve body. The valve body can be held opposite a support face in the bypass by at least one spring (5). The bypass can have a stepped expansion so that a first step acts as a support face for the spring and a further step acts as the valve seat. USE/ADVANTAGE - A high damping force is produced even at low piston speeds.

Description

The invention relates to a vibration damper speed-dependent change in damping force, be standing from a fluid-filled cylinder, in which a with Piston connected to a piston rod slides and the cylin divides the interior into two work rooms and these work rooms can be connected to each other via damping valves in the piston.

Vibration dampers are already known (e.g. DE-OS 39 23 512, DE-PS 27 21 933), in which damping valves in the piston are provided, the damping force generated by them with increasing flow rate of the damping medium initially increases, but from a predetermined flow rate Damping force increases suddenly or the flow of the damper medium is blocked. Such damping valves produce conditions, however, even at low piston speeds agreed damping forces, which then increase continuously until Blocking.

The object of the invention is to provide a vibration damper speed-dependent change in the damping force create that possible at low piston speeds low, but above a certain piston speed defined high damping force.  

To solve this problem, the invention provides that parallel to the damping valves, the workrooms over one Bypass can be connected in the piston rod, with a valve in the bypass on both sides of a valve body one with the Has valve body cooperating valve seat.

It is advantageous with this training that even at extreme low speeds the valve in the bypass opens so that only a small damping force of the movement of the piston is opposed while from a certain piston speed of the valve body closes the bypass, so that now only the damping valves in the piston are effective, so that a defined damping force can be generated.

According to an essential feature, it is provided that the valve body by at least one spring against one in the bypass orderly support surface is held. When using a Single spring, the valve body rests on a valve seat and can be lifted off its valve seat and be at one agreed piston speed over the opposite Ven Close the bypass by pushing the valve body on Valve seat creates. The advantage here is that the bypass is effective in either the pulling or pushing direction.

Another essential embodiment provides that the Ven tilkörper held in every direction by a spring is. The advantage here is that the bypass in tension and compression direction is effective, so that the valve body depending on Flow direction of the damping medium in the bypass on one or creates another valve seat.  

To achieve a design that is simple to manufacture provided that the bypass has a stepped extension has a first stage as a support surface for the spring serves and a further stage is designed as a valve seat. It is advantageous here that the spring by using a smaller outside diameter than the valve body in this stu fenbohrung so that the valve body on the second stage comes to rest, while the spring in the first Stage of the stepped extension can immerse.

A particularly favorable embodiment provides that the Ven tilkörper is designed as a ball. The valve can body also conical on at least one side or Train according to plan.

As an alternative, the invention provides for the solution of the task hen that parallel to the damping valves the workrooms can be connected via a bypass in the piston rod, wherein a valve body mounted on a coil spring with a Valve seat of the bypass interacts, and that on the opposite opposite side of the valve body the bypass into one that Coil spring supporting support surface within the win the coil spring ends.

This training has the advantage that after opening the Bypasses the windings above a certain pressure Place the coil spring on top of each other and close the bypass the valve body on the coil spring is arranged and on the opposite side of the through Bypass diameter smaller than the diameter of the screws feather is.

Preferred embodiments of the invention are in the Drawings shown schematically.  

It shows:

Fig cut. 1 shows a vibration damper with a check valve in the bypass,

Fig. 2 shows a vibration damper having a rebound and compression direction acting valve in the bypass,

Fig. 3, a valve in the bypass, as a detail,

FIGS. 4 and 5 embodiments of valve bodies in the bypass as a detail.

The vibration damper shown in Fig. 1 consists essentially of the piston rod 1 , the working piston 12 , and the cylinder 13 , which is divided into two working spaces 9 and 10 by the working piston 12 in two Ar. The volume displaced when the piston rod 1 is immersed in the cylinder 13 escapes via the bottom valve 14 into the compensation chamber 15 .

The working piston 2 is provided with constant openings which are closed by damping valves 8 . The openings 7 form a connection of the two working spaces to one another, with an additional connection between the working spaces being created via the bypass 6 and the valve 2 contained in the bypass. The valve 2 consists of the valve seats 3 a and 3 b, the valve body 4 and the spring 5 . The Ausführungsbei game in Fig. 1 provides an opening of the bypass 6 only in the pressure stage, whereby at low speed of the piston 12, the valve body 4 stands out from its valve seat 3 a and is relatively moved against the spring 5 , so that the bypass 6th Damping medium can flow from the work space 9 into the work space 10 . If the speed of the piston exceeds a defined value, the valve body 4 puts on the valve seat 3 b with the aid of the superimposed turns of the spring 5 and closes the bypass 6 , so that now only the damping valves 8 together with the openings 7 in the working piston 12 are effective. The damping valves 8 generate a high damping force, so that at low piston speed via the bypass 6 low damping forces, while 8 damping forces can be generated from a certain piston speed on the damping valves.

In Fig. 2, another embodiment of a vibration damper is shown, in which the bypass 6 is provided with a valve body 4 Ven, which is held between two springs 5 a and 5 b, so that the damping medium from a working space 9 at low piston speeds or 10 to the other Ar beitsraum 10 or 9 can flow through without significant damping forces. Above a certain piston speed, the valve body 4 engages in the pulling direction on the valve seat 3 a or in the pushing direction on the valve seat 3 b, the windings of the springs 5 a and 5 b lying one on top of the other and closing the bypass 6 , so that the damping then occurs valves 8 take effect with their high damping force.

In Fig. 3, a valve body 4 is shown with a flat end face 16 , while the opposite side 17 of the valve body 4 is conical. By using a single spring, this valve in the bypass 6 can only be used in the pulling or pushing direction.

Fig. 4 shows a valve body 4 as a ball, the associated spring 5 being arranged in an extension 11 of the bypass 6 , the first stage 11 a a support surface for the spring 5 and the second stage 11 b a valve seat for Valve body 4 forms. With appropriate pressurization of the valve body 4, the spring 5 immersed in the extension 11 and the valve body 4 forms with its valve seat 11 b proper sealing surface.

In Fig. 5 is again a ball as a valve body 4 is provided, the bypass 6 is reduced in stages towards both sides, so that the springs 5 a and 5 b are each supported in a first stage, while the valve body 4 in the second stage forms a valve seat 3 on both sides in the bypass.

Reference list

1 piston rod
2 valve
3 valve seat
4 valve bodies
5 spring
6 bypass
7 openings in the piston
8 damping valves
9 work space
10 work space
11 extension
12 working pistons
13 cylinders
14 bottom valve
15 compensation room
16 end face
17 end face

Claims (8)

1. Vibration damper with speed-dependent changes tion of the damping force, consisting of a fluid-filled cylinder in which a piston connected to a piston rod is guided and divides the cylinder interior into two working spaces and these working spaces can be connected to one another via damping valves in the piston, characterized in that parallel to the damping valves ( 8 ) the working spaces ( 9 , 10 ) via a bypass ( 6 ) in the piston rod ( 1 ) are ver bindable, with a valve ( 2 ) in the bypass ( 6 ) on both sides of a valve body ( 4 ) each with the Ventilkör by ( 4 ) cooperating valve seat ( 3 ). 2. Vibration damper according to claim 1, characterized in that the valve body ( 4 ) is held by at least one spring ( 5 ) with respect to a support surface arranged in the bypass ( 6 ). 3. Vibration damper according to claim 1, characterized in that the valve body ( 4 ) is held in each direction of movement by a spring ( 5 a, 5 b). 4. Vibration damper according to claim 1, characterized in that the bypass ( 6 ) has a step-shaped extension ( 11 ), wherein a first step ( 11 a) serves as a support surface for the spring ( 5 ) and a further step ( 11 b) as Ven tilsitz ( 3 ) is formed. 5. Vibration damper according to claim 1, characterized in that the valve body ( 4 ) is designed as a ball. 6. Vibration damper according to claim 1, characterized in that at least one side of the valve body ( 4 ) is conical. 7. Vibration damper according to claim 1, characterized in that at least one end face of the valve body ( 4 ) is arranged to run flat. 8. Vibration damper with speed-dependent changes tion of the damping force, consisting of a fluid-filled cylinder in which a piston connected to a piston rod slides and divides the cylinder interior into two working spaces and these working spaces can be connected to one another via damping valves in the piston, characterized in that parallel to the damping valves ( 8 ) the working spaces ( 9 , 10 ) via a bypass ( 6 ) in the piston rod ( 1 ) are ver bindable, a on a coil spring ( 5 ) gela gered valve body ( 4 ) with a valve seat ( 3 ) of the By passes ( 6 ) cooperates, and that on the opposite side of the valve body ( 4 ) the bypass ( 6 ) opens into a support surface supporting the coil spring ( 5 ) within the turns of the coil spring ( 5 ).