DE102018220654B4 - Damping valve arrangement, in particular for a vibration damper - Google Patents

Abstract

Damping valve arrangement (1), in particular for a vibration damper, comprising a damping valve body (2) through which a damping fluid flows, this having a first damping valve (3) with a first outlet opening (5) for the damping fluid and at least one to the first damping valve (3) ) comprises a second damping valve (4) that is functionally parallel and has a second outlet opening (6) for the damping fluid, each outlet opening (5; 6) being at least partially covered with at least one valve disc (7; 8) and wherein the damping valve body (2) furthermore has at least one damping valve body opening (9) axially protruding through the damping valve body (2) with an inlet opening (10) for the damping fluid, characterized in that the damping valve body opening (9) is designed in such a way that it extends through the damping valve body in the course of its axial extension (2), within the damping valve body (2), so that the damping valve Valve body opening (9) whose one, identical inlet opening (10) simultaneously with the first outlet opening (5) of the first damping valve (3) and with the second outlet opening (6) of the second damping valve, which is arranged radially offset from the first outlet opening (5) at a defined angle (4) connects.

Description

The invention relates to a damping valve arrangement, in particular for a vibration damper, in particular for a motor vehicle vibration damper, according to the preamble of patent claim 1.

Generic damping valve arrangements are well known.

The DE 10 2014 205 855 A1 discloses, for example, a damping valve arrangement which comprises a damping valve body, the damping valve body having at least one damping valve body opening axially projecting through the damping valve body with an inlet opening for the damping fluid. A damping fluid flows through the damping valve body in the operating state. In order to generate the damping effect, the damping valve body of the damping valve arrangement comprises a first damping valve with a first outlet opening for the damping fluid and at least one second damping valve that is functionally parallel to the first damping valve and has a second outlet opening for the damping fluid. Each outlet opening is at least partially covered with at least one valve disk, the valve disk of one damping valve being designed to be significantly weaker than the valve disks of the other damping valve. This is intended to achieve a comfort-emphasizing damping on small bumps in the road and a safety-supporting damping in the case of strong rolling movements of the motor vehicle. The ones in the DE 10 2014 205 855 A1 The damping valve arrangement disclosed provides that at least one damping fluid path, which leads to one of the two damping valves, is designed as a flattening of the central carrier, designed as a piston rod pin, or as a groove or bore made in the carrier, whereby the implementation of the construction is sufficient strong dimensioning of the carrier is bound. In addition, the damping valve arrangement requires a comparably large axial length, which has a negative effect on the available stroke. For the purposes of the invention, the stroke is intended to be the difference between the axial extent of a vibration damper compressed up to the stop and the axial extent of the same vibration damper in its maximally expanded state.

The DE 103 12 225 A1 discloses a damping valve arrangement for a vibration damper, comprising a damping valve body through which a damping fluid flows, this having a first damping valve with a first outlet opening for the damping fluid and at least one second damping valve, which is functionally parallel to the first damping valve and having a second outlet opening for the Comprises damping fluid, each outlet opening is covered with at least one valve disk. In addition, the DE 103 12 225 A1 two piston openings of which one is designed as a groove designed close to the piston rod and the other as a channel extending parallel to the groove. Both the groove and the channel each have an inlet opening and an outlet opening, the two inlet openings being located within an annular trench which is formed by a control edge covered with a valve disk.

On the basis of the problems explained above, the object of the present invention is to provide an alternative damping valve arrangement which has a short axial extent and can also be used with small-sized carriers. The carrier in the sense of the invention is understood to be the piston rod in a piston valve or the connecting component, which is usually arranged in the center, in a bottom valve.

This object is achieved by a damping valve arrangement designed in accordance with claim 1.

If the damper valve body opening is designed in such a way that it connects its inlet opening with the first outlet opening of the first damping valve and with the second outlet opening of the second damping valve, the damping fluid flow to the two damping valves is simultaneously guided through the damping valve body, whereby the required functionality regardless of the dimensioning of the Can be provided carrier. In addition, the entire damping valve arrangement can thereby be made significantly shorter, which brings about a gain in lift.

Advantageous design variants are specified in the dependent claims, as well as in the figures and their description.

According to a first advantageous embodiment variant, the damping valve body opening comprises at least one throttle section, the cross section of which is smaller than the cross section of the damping valve body opening. This prevents the valve disc from opening suddenly and minimizes the associated generation of so-called rumbling noises, which are perceived as unpleasant.

According to a further advantageous embodiment variant, this effect can be reinforced by the throttle section opening into an annular channel, the annular channel being arranged between the valve disc and the outlet opening. As a result, the damping fluid collects in the ring channel, before it lifts the valve disc. This ensures a uniform effect on the valve disc, which has a positive effect on the service life of the valve disc. The annular channel can advantageously be designed as an annular bore.

In order to counteract the noise generation of the damping valve even further, it can advantageously be provided that a calming chamber is arranged between the throttle section and the valve disc, which has a larger cross section than the cross section of the throttle section.

For reasons of noise reduction or to increase the service life of the valve disk, it can be advantageous to influence the lifting behavior of the valve disk in a targeted manner. For this reason, a further advantageous embodiment variant provides that the annular channel designed as an annular bore has at least one axial opening which opens into a control edge, the control edge serving as a contact for the valve disc. This opening can be positioned in a targeted manner relative to the valve disk in order to achieve a desired effect, such as, for example, a one-sided or one-sided increased lifting movement of the valve disk.

According to a further advantageous embodiment variant, it is provided that the axial opening comprises a wall which is axially raised and extends axially from the base body of the damping valve to the support structure over a defined extent. The valve disc rests against the control edge with a defined closing force. The level of this closing force can be adjusted by choosing the appropriate extension.

Since the closing force which a valve disk or a valve disk package exerts on the control edge is usually very large, it is quite advantageous if the damping valve body comprises at least one support structure which is designed in such a way that it extends from the control edge to the damping valve base body the thickness increases and the wall of the axial opening is reinforced.

Due to the funnel-shaped design of the inlet opening, the damping fluid can advantageously be guided in a defined manner into the damping valve body opening.

The damping valve arrangement can be produced by any suitable method known to the person skilled in the art, such as, for example, sintering or turning. According to a further advantageous embodiment variant, the damping valve body can be produced by an additive manufacturing process, in particular by a 3D printing process, in particular by selective laser melting (SLM), since this method offers a high degree of flexibility in the design of the damping valve body and the individual components of the damping valve arrangement enable.

• 1: eine erste Ausführungsvariante einer Dämpfventilanordnung gemäß Patentanspruch 1 in einer Axialschnittdarstellung;
• 2: eine zweite Ausführungsvariante einer Dämpfventilanordnung gemäß Patentanspruch 1 in einer Axialschnittdarstellung;
• 3: eine dritte Ausführungsvariante einer Dämpfventilanordnung gemäß Patentanspruch 1 in einer Axialschnittdarstellung;
• 4: eine vierte Ausführungsvariante einer Dämpfventilanordnung gemäß Patentanspruch 1 in einer Axialschnittdarstellung;
• 5: eine weitere Ausführungsvariante einer Dämpfventilanordnung gemäß Patentanspruch 1 in einer Axialschnittdarstellung;
• 6: eine Draufsichtdarstellung eines Dämpfventilkörper gemäß 5;
• 7: eine perspektivische Darstellung eines Dämpfventilkörpers gemäß 5;
• 8: eine weitere perspektivische Darstellung eines Dämpfventilkörpers gemäß 5.

The invention will now be explained in more detail according to the following figures. Show it:

• 1 : a first embodiment variant of a damping valve arrangement according to claim 1 in an axial sectional view;
• 2 : a second embodiment variant of a damping valve arrangement according to claim 1 in an axial sectional view;
• 3 : a third embodiment variant of a damping valve arrangement according to claim 1 in an axial sectional view;
• 4th : a fourth variant embodiment of a damping valve arrangement according to claim 1 in an axial sectional view;
• 5 : Another embodiment variant of a damping valve arrangement according to claim 1 in an axial section;
• 6th : a plan view of a damping valve body according to FIG 5 ;
• 7th : a perspective view of a damping valve body according to 5 ;
• 8th : Another perspective view of a damping valve body according to 5 .

The 1 shows an example of a first variant embodiment of a damping valve arrangement 1 according to claim 1. This comprises a damping valve body 2 , which is usually arranged in a damper cylinder, not shown here, at least partially filled with a damping fluid. In the operating state, the damping valve body 2 flows through the damping fluid, which flows through a the damping valve body 2 axially protruding damper valve body opening 9 flows. The in 1 to 5 each shown damping valve body 2 each includes a first damping valve 3 with a first outlet opening 5 for the damping fluid and at least one second damping valve 4th with a second outlet opening 6th for the damping fluid, the two damping valves 3 ; 4th are executed functionally parallel to each other. The outlet openings 5 ; 6th are each at least partially with at least one valve disc 7th ; 8th covered. One, the damper valve body 2 axially protruding damper valve body opening 9 has an inlet opening 10 for the damping fluid and is designed in such a way that it has its inlet opening 10 at the same time as the first outlet opening 5 of the first damping valve 3 and with the second outlet opening 6th of the second damping valve 4th connects. This can be achieved, for example, by two bores which have the same inlet opening 10 have their outlet openings 5 ; 6th are offset radially from one another at a defined angle. The ones in the 3 , 4th and 5 The illustrated embodiment variants each show a damping valve arrangement produced by an additive manufacturing process 1 , whose damping valve body openings 9 Have curvatures, which for an optimal low-noise flow through the damping valve body opening 9 are formed by the damping fluid. Like it in the 6th , 7th and 8th is shown, the inlet opening 10 be funnel-shaped.

The 2 , 3 , 4th and 5 each show an embodiment variant which has an opening in the damping valve body 9 arranged throttle section 11 ; 12 includes. The cross section of each throttle section 11 ; 12 is smaller than the cross section of the inlet opening 10 . This can be done directly on the valve disc 7th ; 8th end, or in one, between the valve disc 7th ; 8th and the outlet opening 5 ; 6th arranged ring channel 13 , or alternatively in one between the throttle section 11 ; 12 and the valve disc 7th ; 8th positioned calming chamber 14th ; 15th flow out. In the latter case is the calming chamber 14th ; 15th perform in such a way that it has a larger cross section than the cross section of the adjacent throttle section 11 ; 12 .

The 5 shows an embodiment, according to which the ring channel 13 is designed as an annular bore. This configuration can be used with a two-part damping valve body 2 can be achieved by sintering or turning. In the 5 However, the embodiment variant shown provides the damping valve body 2 in one piece, using an additive manufacturing process, in particular using a 3D printing process, in particular using selective laser melting (SLM).

The 5 , 6th and 8th show an embodiment, according to which the annular channel designed as an annular bore 13 at least one axial opening 16 having. This is in the circumferential direction of a wall 18th enclosed and extends axially over a defined extent 19th , starting from the main body of the damping valve body 2 until he's in a control edge 17th opens, which as an attachment for the valve disc 7th ; 8th serves. The wall 18th of the breakthrough 16 is axially raised, essentially tubular and has an oval, in particular kidney-shaped cross-section.

In addition, the wall 18th through a support structure 20th reinforced, which is designed in such a way that this from the control edge 17th off to the main body of the damping valve body 2 increases in thickness and the wall 18th of the axial breakthrough 16 gives additional stability.

List of reference symbols

1

Damping valve assembly

2

Damper valve body

3

first damping valve

4th

second damping valve

5

first outlet

6th

second outlet opening

7th

Valve disc

8th

Valve disc

9

Damper valve body breakthrough

10

Inlet opening

11

Throttle section

12

Throttle section

13

Ring channel

14th

Calming chamber

15th

Calming chamber

16

axial breakthrough

17th

Control edge

18th

Wall

19th

Extent

20th

Support structure

21st

carrier

22nd

exemption

Claims (10)

Damping valve arrangement (1), in particular for a vibration damper, comprising a damping valve body (2) through which a damping fluid flows, this having a first damping valve (3) with a first outlet opening (5) for the damping fluid and at least one to the first damping valve (3) ) comprises a second damping valve (4) that is functionally parallel and has a second outlet opening (6) for the damping fluid, each outlet opening (5; 6) being at least partially covered with at least one valve disc (7; 8) and wherein the damping valve body (2) furthermore has at least one damping valve body opening (9) axially projecting through the damping valve body (2) with an inlet opening (10) for the damping fluid, characterized in that the damping valve body opening (9) is designed in such a way that it extends in the course of its axial extension through the The damping valve body (2) divides within the damping valve body (2) so that the damping valve body opening (9) has one, identical inlet opening (10) at the same time as the first outlet opening (5) of the first damping valve (3) and with the one leading to the first outlet opening (5) at a defined angle radially offset second outlet opening (6) of the second damping valve (4) connects. Damping valve assembly (1) according to Claim 1 , characterized in that the damping valve body opening (9) comprises at least one throttle section (11; 12), the cross section of which is smaller than the cross section of the inlet opening (10). Damping valve assembly (1) according to Claim 2 , characterized in that the throttle section (11; 12) opens into an annular channel (13), the annular channel (13) being arranged between the valve disc (7; 8) and the outlet opening (5; 6). Damping valve arrangement (1) according to at least one of the preceding claims, characterized in that a calming chamber (14; 15) is arranged between the throttle section (11; 12) and the valve disc (7; 8), which has a larger cross section than the cross section of the adjacent throttle section (11; 12). Damping valve assembly (1) according to Claim 3 , characterized in that the annular channel (13) is designed as an annular bore. Damping valve assembly (1) according to Claim 5 , characterized in that the annular channel (13) designed as an annular bore has at least one axial opening (16) which opens into a control edge (17), the control edge (17) serving as a contact for the valve disc (7; 8). Damping valve assembly (1) according to Claim 6 , characterized in that the axial opening (16) comprises a wall (18) which is axially raised and extends axially from the base body of the damping valve body (2) to the control edge (17) over a defined extent (19). Damping valve assembly (1) according to Claim 7 , characterized in that the damping valve body (2) comprises at least one support structure (20) which is designed such that it increases in thickness from the control edge (17) to the base body of the damping valve body (2) and the wall (18 ) of the axial opening (16) reinforced. Damping valve arrangement (1) according to at least one of the preceding claims, characterized in that the inlet opening (10) is funnel-shaped. Damping valve arrangement (1) according to at least one of the preceding claims, characterized in that the damping valve body (2) is produced by an additive manufacturing process.

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