DE4041829A1 - Hydraulic shock absorber with piston and piston rod - has two damping fluid compartments with compensating compartment between and includes damping valve - Google Patents

Abstract

The hydraulic, adjustable shock absorber has a piston (2) fixed to a piston-rod (3) and which divides the operating cylinder (1) filled with damping fluid into two compartments (4,5). A damping-valve (7) cooperates with a gas-filled compensating compartment and is positioned to one side of the operating cylinder (1) and has at least one duct (10). The part of the damping valve (7) housing (8) facing the shock absorber is connected to the shock absorber by a hollow piece (9) in the form of a screw (9a) going through the housing (8). At least one collar-type fitment (11) screws the shock absorber pipes (1) telescopically together. ADVANTAGE - The damping valve is fitted and the separate parts of the shock absorber are assembled without soldering or welding.

Description

The invention relates to a hydraulic, adjustable vibration damper with one on a piston rod attached piston, which with the damping fluid filled working cylinder in two working rooms divided, one working with one of the work rooms and compensation room filled with gas and a laterally arranged on the working cylinder controllable at least one channel Damping valve.

Such vibration dampers are already known (DE-PS 34 34 877, Fig. 8 and Fig. 10), in which the Working cylinder has a compensation room and at a controllable damping valve on the side of the working cylinder is provided. The inflow of the damping valve takes place via nested Steel pipes through which the damping fluid is used several times must be deflected and being a housing of the damping valve welded to the outer tube and subsequently machined.

The object of the invention is a vibration damper so that the installation of a damping valve not only cheaper through constructive measures, but by appropriate design of the  Individual parts can be designed to be easy to assemble, so that z. B. no welding or soldering operations necessary are.

To achieve this object, the invention provides that at least the one facing the vibration damper Part of the housing of the damping valve over a the hollow element penetrating the housing with the Vibration damper is connected sealed, the Hollow element the flow connection from the channel to Damping valve manufactures.

The advantage of this construction is that it is the simplest Way an inflow or outflow channel is created and the high damping pressure does not connect the damping valve, but only loaded the housing. Are there for the tear-off force of the damping valve only the holes of the hollow element as pressurized Decisive areas.

In an embodiment of the invention is a as a hollow element Banjo bolt provided. The advantage here is that the housing of the damping valve directly over this Banjo bolt on the outside of the vibration damper appropriate place can be screwed.

According to another cheap embodiment when using thin-walled vibration damper tubes two banjo bolts, each with a collar-shaped shoulder screwed into each other telescopically.

According to another particularly favorable feature, that on the hollow element axially one behind the other Valve disks, valve bodies, valve disks and at least one spacer ring is threaded and this Unit with a recess in the bottom of the housing is connected to the vibration damper. Here is from Advantage that the entire pressure-controlled valve unit together with the hollow element via a through hole  not just the housing, but this unit at the same time fixed.

In an advantageous embodiment, a collar is Approach of the hollow element as a valve seat for the valve body of the damping valve.

Another essential feature provides that as Channel one over at least part of the length of the Vibration damper tubular component is provided on which the housing is attached. Here can advantageously the working cylinder and the tubular Form the component in one piece. The production such a unit could, for example, in the extrusion process done as steel or aluminum tube.

In an embodiment of the invention, the tubular component by inserting a clamping piece in a feed and Process divided. With this training can be about the channel is sealed at its end faces and be closed.

According to another essential feature, that the housing in at least one direction is connected to the vibration damper.

In an embodiment of the invention, the channel is by deep hole drilling produced.

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

It shows:

Fig. 1 shows a single-tube vibration damper with a damping valve attached to the side in section

Fig. 2 shows a further embodiment of a vibration damper shown in Fig. 1

Fig. 3 shows a vibration damper with a damping valve for the separate control of the rebound or compression stage

Fig. 4 shows another embodiment of a damping valve with a corresponding screw

Fig. 5, the end portions of the working cylinder of a vibration damper according to FIG. 1

Fig. 6 shows a section through a working cylinder and a channel of a vibration damper according to FIG. 1

Fig. 7 is a cylinder in which the channel is made in deep hole drilling.

The vibration damper shown in Fig. 1 consists essentially of the working cylinder 1 , the piston 2 and the piston rod 3rd The piston 2 divides the working cylinder into an upper working space 4 and a lower working space 5 , an equalizing space 6 being attached via a connecting line. The damping valve 7 is acted upon via a channel 10 , the damping means displaced by the piston rod 3 passing the damping valve and into the compensation chamber 6 . The housing 8 of the damping valve 7 is connected to the outer wall of the vibration damper via the hollow screw 9 a. The collar-shaped extension 11 and the seal 19 serve to securely connect the damping valve 7 to the vibration damper. During the operation of the vibration damper, the damping means passes from the lower working chamber 5 via the recess 20 past the damping valve 7 into the compensation chamber 6 . The channel 10 is divided into an inlet and outlet by a clamping piece 18 .

In FIG. 2, a further embodiment is shown a vibration damper, wherein the working cylinder 1 is in turn divided into the upper working space 4 and the lower working chamber 5. In this embodiment, the recess 20 is located in the area of the upper working space 4 , so that the damping fluid can only pass from the upper working space 4 of the recess 20 via the channel 10 past the damping valve 7 into the compensation space 6 . The connection for the compensation chamber 6 can thus be placed below the damping valve 7 . Otherwise, this embodiment corresponds to the vibration damper already shown in FIG. 1.

In Fig. 3, a vibration damper is shown, in which the upper working space 4 and the lower working space 5 each have a recess 20 , so that due to the closed piston 2, the piston ring volume always passes alternately via the upper and lower channel 10 to the damping valve 7 . The damping means displaced by the piston rod 3 thus reaches the compensation chamber 6 without damping via the recess 20 in the upper working chamber 4 .

In FIG. 4 is a working cylinder 1 is proposed, wherein the channel 10 is formed by an additional pipe 21 and the hollow screws 9 a with the valve discs 12, the valve body 13 and a spacer ring are fitted fourteenth This complete assembly is screwed directly to the working cylinder 1 via the recess 15 in the housing 8 . At the same time, the collar-shaped extension 11 of the hollow screw 9 a serves as the valve seat of the valve body 16 .

In FIG. 5, a working cylinder 1 is shown, as found for example in the vibration dampers of FIGS. 1 to 3 is applied, wherein the channel is arranged in a tubular component 17 10. The tubular component 17 is formed in one piece together with the working cylinder 1 and can be produced, for example, as an extruded part.

In FIG. 6, a working cylinder 1 as well as a tubular member 17 is shown as a unit, can be applied with positive locking by the groove 22, not only brake hose holder 23, but also the damping valve 7.

In FIG. 7, a work cylinder 1 is again shown with a tubular member 17, wherein the working cylinder 1 is formed together with the tubular member 17 as the extrusion and as a single unit, while the channel 10 can be manufactured by deep-hole drilling.

Reference symbol list

1 working cylinder
2 pistons
3 piston rod
4 upper work area
5 lower work area
6 compensation room
7 damping valve
8 housing
9 hollow element
9 a banjo bolt
10 channel
11 collar-shaped approach
12 valve disks
13 valve body
14 spacer ring
15 recess
16 valve body
17 tubular component
18 clamping piece
19 seal
20 recess
21 pipe
22 groove
23 brake hose holder

Claims (11)

1.Hydraulic, controllable vibration damper with a piston attached to a piston rod, which divides the working cylinder filled with damping fluid into two working spaces, a compensation chamber working with one of the working spaces and filled with gas, and a controllable damping valve arranged on the side of the working cylinder and capable of being flowed through at least one channel , characterized in that at least the part of the housing ( 8 ) of the damping valve ( 7 ) facing the vibration damper is connected to the vibration damper in a sealed manner via a hollow element ( 9 ) passing through the housing ( 8 ), the hollow element ( 9 ) connecting the flow from the channel ( 10 ) to the damping valve ( 7 ). 2. Vibration damper according to claim 1, characterized in that a hollow screw ( 9 a) is provided as the hollow element ( 9 ). 3. Vibration damper according to claim 1, characterized in that when using thin-walled vibration damper tubes ( 1 ) two banjo bolts ( 9 a), each with a collar-shaped projection ( 11 ) are screwed together telescopically. 4. Vibration damper according to claim 1, characterized in that on the hollow element ( 9 ) axially one behind the other valve disks ( 12 ), valve body ( 13 ), valve disks ( 12 ) and at least one spacer ring ( 14 ) are threaded and this unit via a recess ( 15 ) is connected to the vibration damper in the bottom of the housing ( 8 ). 5. Vibration damper according to claim 1, characterized in that a collar-shaped extension ( 11 ) of the hollow element ( 9 ) is designed as a valve seat for the valve body ( 16 ) of the damping valve ( 7 ). 6. Vibration damper according to claim 1, characterized in that as a channel ( 10 ) extending over at least part of the length of the vibration damper tubular component ( 17 ) is provided to which the housing ( 8 ) is attached. 7. Vibration damper according to claim 6, characterized in that the working cylinder ( 1 ) and the tubular component ( 17 ) are integrally formed. 8. Vibration damper according to claim 6, characterized in that the tubular component ( 17 ) is divided into an inlet and outlet by inserting a clamping piece ( 18 ). 9. Vibration damper according to claim 1, characterized in that the channel ( 10 ) is sealed and closed at its end faces. 10. Vibration damper according to claim 1, characterized in that the housing ( 8 ) is positively connected to the vibration damper in at least one direction. 11. Vibration damper according to claim 1, characterized in that the channel ( 10 ) is made by deep hole drilling.