DE10134122B4 - Vibration damper with guided flow - Google Patents

Abstract

Vibration damper with guided flow, which is arranged in particular in vehicles between a vehicle body and a wheel carrier and has a piston rod connected to a piston, at least two working spaces and a compensation space being provided, these spaces being filled with damping fluid and flow openings between the spaces , wherein between the compensation space (9) and the working space (7) having throughflow openings (15, 17) are arranged, which serve to generate and / or utilize a rotational movement of the damping liquid. characterized in that the outlet cross-sections (19) in the direction of the compensation chamber (9) are designed in the shape of a nozzle and are arranged to run obliquely in the circumferential and axial directions.

Description

The invention relates to a vibration damper with guided flow according to the preamble of patent claim 1.

In the known vibration dampers provided with a damping device is provided between a working space and a compensation chamber or between the working spaces, which are in hydraulic communication with each other by damping valves. To dampen the vibrations between the vehicle body and the chassis, the damping fluid volume corresponding to the retracting and extending piston rod volume is forced through the damping devices, whereby the vibration energy absorbed by the vibration damper is converted into heat. As damping devices are for example by the DE 1 251 116 B , the DE 2 221 944 A , the DE 32 02 721 A1 and the DE 27 31 015 C2 Bottom valve arrangements with radially extending channels are known, which have a corresponding outflow, ie when the damping fluid flows into the compensation chamber, the liquid jets strike the inner wall of the outer container almost perpendicularly so that an undefined turbulence of the liquid filling in the compensation chamber takes place. Especially at higher damping performance, the Dämpfflüssigkeit mixed intensively with the gas and there is a strong foaming, which is entrained when flowing out of the damping fluid from the expansion chamber gas and thus not only performance dips occur but also increases the noise and the heat dissipation is deteriorated.

The DE 30 07 410 A1 describes a vibration damper with a bottom valve, which generates a swirl in the damping medium in the flow. For this purpose, the bottom valve has inclined channels whose inlet and outlet cross-section is at least approximately the same size.

The object of the present invention is to provide a significant improvement in the function of vibration dampers with simple and inexpensive to produce means.

This object is achieved according to the invention with the characterizing features of claim 1. Further advantageous embodiments are the subject of the dependent claims.

Due to the rotational movement of the damping fluid, the foaming is prevented even at high damping power, because the twist ensures by compressing the liquid for freedom from gas bubbles. In addition, the heat transfer to the container wall and thus the heat dissipation is significantly improved by the rotation of the damping fluid. Furthermore, by exploiting the rotational energy, pressure support for the outflow of the damping fluid from the compensation chamber is achieved.

The device used to generate the rotational movement is created in a simple manner in that the flow-through openings are provided with outlet cross-sections which have components running in the circumferential direction of the expansion chamber or the working space, whereby the rotational movement is generated with only little effort. The thus guided liquid jets prevent the foaming and cause an intense heat exchange between the Dämpfflüssigkeit and the container, whereby an overheating of the vibration damper and the rubber-elastic sealing parts is counteracted.

In order to exploit the rotational energy for the outflow of the damping fluid from the space, the corresponding flow openings are provided with inlet cross sections, which are arranged opposite to the rotational movement of the damping fluid. As a result, the dynamic pressure generated by the rotational movement is utilized, thereby avoiding the suction of gas or the escape of gas from the damping fluid as a result of a vacuum which normally arises during suction.

The arrangement according to the invention of the throughflow openings in the valve body is particularly suitable for the bottom valves provided in twin-tube vibration dampers, which are installed between the lower working space and the compensation space. With such a construction, the outlet cross sections in the valve body can be produced in a simple and cost-effective manner. The same applies to the arrangement of the inlet cross sections in the valve body.

In particular, in the case of flow-through openings which are arranged in the piston, it is advantageous if the outlet cross-sections used to generate the rotational movement are arranged in a component connected to the piston. The throughflow openings in the piston are as previously stated and only the inlet cross sections and / or the outlet cross sections are provided in separate and preferably made of sheet metal components, so that a cost-effective overall structure is created.

Based on the embodiments shown in the drawings for the guided flow of the invention will be explained in more detail below. It shows:

1 a section of a twin-tube vibration damper in the region of the bottom valve in longitudinal section;

2 a cross section through the in 1 shown bottom valve according to the section line AB;

3 a cross section through the in 1 shown bottom valve according to the section line CD;

4 an embodiment of a bottom valve in the view from below;

5 another bottom valve design seen from below;

6 an embodiment of a bottom valve with an easily manufacturable valve body.

7 u. 8th perspective view of a valve body for a bottom valve

In 1 the lower end of a twin-tube vibration damper is shown in longitudinal section. A cylinder 1 is through a valve body 5 in a container 3 clamped when closing the vibration damper. The valve body 5 has a check valve 11 and a damping valve 13 on, with the check valve 11 flow openings 17 are assigned and the damping valve 13 with flow openings 15 interacts. One in the cylinder 1 existing and filled with Dämpfllüssigkeit workspace 7 gets through in the valve body 5 existing flow openings 15 and 17 hydraulically with a between the outer wall of the cylinder 1 and the inner wall of the container 3 arranged equalization space 9 connected. During the relative movement of the vehicle body to the wheel carrier, the piston rod, not shown, moves into the cylinder 1 on and off, whereby the retracting the corresponding piston rod volume from the working space 7 via the damping valve 13 and the flow openings 15 in the compensation room 9 is displaced. When extending the piston rod out of the cylinder 1 is the Dämpfflüssigkeitsmenge corresponding to the extending piston rod volume from the compensation chamber 9 over the flow openings 17 and the check valve 11 in the workroom 7 promoted. The compensation room 9 this has in most cases except the Dämpfflüssigkeitsfüllung a gas cushion.

So when retracting the piston rod into the cylinder 1 in the workroom 7 in the compensation room 9 displaced damping fluid causes no foaming by turbulence of the damping fluid with the gas, a device is provided, the damping fluid in the compensation chamber 9 granted a rotational movement. This device has flow openings 15 on, by appropriate shaping in the circumferential direction of the compensation chamber 9 have running component.

In 2 is the cut AB after 1 shown, wherein an embodiment of this with the outlet cross sections 19 provided through-flow openings 15 is shown, each exerting a circumferentially extending force component on the damping fluid and thus cause their rotation in the expansion chamber. The thus from the outlet cross sections 19 Exiting liquid jets not only prevent the foaming, but also cause better cooling of the vibration by an intense heat exchange between the Dämpfflüssigkeit and the container 3 , At the same time, this twist ensures a compression of the damping fluid and thus its freedom from gas bubbles.

The device for utilizing the rotational energy is in 3 that cut the CD in 1 corresponds, clearly shown. The cooperating with the check valve flow openings 17 are with inlet cross sections 21 provided, the rotational movement of the damping fluid in the expansion chamber 9 arranged in opposite directions. As a result of the rotational movement and the employment of the inlet cross-sections 21 creates a pressure that promotes the return flow and avoids the escape of gas from the gas-saturated damping fluid.

A further advantageous embodiment of the device for generating the rotational movement of the damping fluid in the expansion chamber is in 4 shown. The flow openings 15 are again designed as downwardly open channels in the valve body, extending to the outlet cross sections 19 narrowing and the outlet cross sections 19 are designed as substantially circumferentially acting nozzles. With such an embodiment, a fast rotational movement can be realized.

Very simple and therefore inexpensive to produce facilities for generating and exploiting the rotational movement of the Dämpfflüssigkeit are in the 5 and 6 shown. In 5 are in the valve body 5 with the outlet cross sections 19 provided through-flow openings 15 and those with the inlet cross sections 21 trained flow openings 17 designed as separate and downwardly open channels, which are covered when installed in the container from the bottom of the container. In the embodiment according to 6 open the flow openings 15 with the outlet cross sections 19 in arcuate limited flow openings 17 ,

The 7 and 8th show a bottom valve body in perspective view. The with the damping valve 13 cooperating flow openings 15 are made by circumferentially extending webs 23 formed on which the bottom valve body is also sealingly supported on the bottom of the vibration damper. In an inflow section 15a the through-flow opening performs a radial offset, so that a flow of the damping fluid extending to the webs in the circumferential direction is established. In the last section of the flow path deflects an arcuate wall part 25 the exiting damping fluid radially into the expansion chamber 9 (S. 1 ). The arcuate wall part has a baffle surface 27 which slows down the speed of the damping fluid entering the bottom valve body. It builds up a back pressure, which is the check valve 11 (S. 1 ) opens. The flow paths of the damping fluid overlap because the flow-through opening 17 with its inlet cross-section 21 a part of the flow opening 15 represents.

From the top view 8th it can be seen that the flow opening 17 in the direction of the check valve 11 has a nozzle-shaped cross-sectional enlargement, of a one-sided molded bevel 29 is formed. This slope 29 is adjacent to the baffle in the flow direction 27 executed. Thus, an easier drainage of the damping fluid is achieved in the check valve. It is essential in the subject invention that the swirl generated in the valve body is continued into the working space or in the compensation chamber

The embodiments described above show that the guided flows for the damping fluid in the rooms can be made in a great variety of ways. It is not necessary that the flow openings must cooperate with damping valves, because they can also be used with other throttle devices, eg. As holes or nozzles, combined. Likewise, such a guided flow is not limited only to vibration damper, because other hydraulic devices in which liquid is moved between spaces can be improved by such a flow guide in the function.

Claims (8)

Vibration damper with guided flow, which is arranged in particular in vehicles between a vehicle body and a wheel carrier and having a piston connected to a piston rod, wherein at least two working spaces and a compensation chamber are provided, these spaces have a filling with Dämpfflüssigkeit and between the spaces flow openings are present , where between the compensation room ( 9 ) and the workspace ( 7 ) Flow openings ( 15 . 17 ), which are used for generating and / or exploiting a rotational movement of the Dämpfflüssigkeit arranged. characterized in that the outlet cross sections ( 19 ) in the direction of the equalization chamber ( 9 ) nozzle-shaped and are arranged obliquely extending in the circumferential and axial direction. Vibration damper according to claim 1, characterized in that the means for generating the rotational movement serving outlet cross-sections ( 19 ), which in the circumferential direction of the compensation space ( 9 ) or the working space extending components. Vibration damper according to Claims 1 and 2, characterized in that the device serving for the utilization of the rotational movement has inlet cross-sections ( 21 ), which are arranged opposite to the rotational movement of the damping fluid. Vibration damper according to one or more of claims 1 to 3, characterized in that the flow openings ( 15 . 17 ) in the valve body ( 5 ) are arranged. Vibration damper according to one or more of claims 1 to 4, characterized in that the outlet cross sections ( 19 ) in the valve body ( 5 ) are arranged. Vibration damper according to one or more of claims 1 to 5, characterized in that the inlet cross sections ( 21 ) in the valve body ( 5 ) are arranged. Vibration damper according to one or more of claims 1 to 4, characterized in that the outlet cross sections ( 19 ) in one with the valve body ( 5 ) are arranged connected component. Vibration damper according to one or more of claims 1 to 4, characterized in that the inlet cross sections ( 21 ) in one with the valve body ( 5 ) are arranged connected component.

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