DE102006017694A1 - Resonator for absorption of noises in e.g. hydraulic clutch systems, has disk-like chamber, which defines resonance area, formed rotationally symmetric with respect to fluid flow direction - Google Patents

Abstract

A resonator (2), installed in a fluid line (15), includes a chamber rotationally symmetric with respect to the fluid flow direction and defining a resonance area. The chamber is of a flat disk-shape with a higher modulus of elasticity in the radial direction compared to the axial direction. A pair of disks and an intermediate ring surround both sides and circumference of the chamber. An independent claim is also included for a hydraulic system.

Description

The The present invention relates to a resonator for hydraulic lines and a hydraulic system with such a resonator.

From the DE 1475701 a resonator known there as a pressure wave interference silencer is known, which comprises a branch line parallel to a main line, wherein the wall of the branch line for reducing the speed of propagation of the pressure wave and thus the length of the second sliding has a large elasticity, which is a function of the elastic modulus of Wall material, the wall thickness and the inner diameter of the branch line is.

Although the construction proposed in the prior art serves to reduce the resulting installation space, the installation space there still remains rather large. The in the DE 1475701 proposed calculation method for determining the length of the branch line shows that at resonant frequencies of about 100 Hz lengths of the order of a meter are necessary.

Of the Present invention is based on the object for a Resonator needed To reduce installation space.

This Problem is solved through a resonator for Hydraulic lines, the one to the flow direction substantially Includes rotationally symmetric chamber as a resonance chamber. With essentially is meant that the resonator is not over its full extent Be rotational body must, but e.g. only over a circle cutout. He can also flattened areas, notches or the like, e.g. the adaptation to space requirements serve, have.

In a preferred embodiment the chamber is disk-shaped and has axially to the flow direction the hydraulic line has a lower modulus of elasticity than radially to the flow direction the hydraulic line. Under disc-shaped chamber here is a sliced substantially radially to the flow direction extending chamber understood. This does not have a circular cross-section but may be e.g. also be executed oval or even rectangular. The axial length the chamber is much smaller than the radial extent, therefore the term "disk-shaped" the disk-shaped Chamber substantially radially to the flow direction of the hydraulic line extend. This can be achieved by the disc-shaped chamber of two radially to the flow direction of the hydraulic line extending slices is formed, between which at least an intermediate ring is arranged. The at least one intermediate ring consists preferably of a material with a larger modulus of elasticity as that of the discs.

Of Furthermore, it can be provided that a plurality of intermediate rings different Inner diameter and / or different moduli of elasticity and / or different axial lengths between the discs are arranged. As a result, several modules are parallel in one module switched resonators of different resonant frequency formed.

Preferably the at least one intermediate ring are at least partially made Metal and the discs at least partially made of plastic, for example made of rubber. Already by this choice of materials are the aforementioned different elasticity modules reached in different directions. Both the or the intermediate rings as well as the discs can made of composite materials, e.g. plastic or steel provided with steel reinforcements like that, exist.

In an alternative embodiment it is provided that the chamber is hollow cylindrical and substantially axially to the flow direction the hydraulic line extends and in the flow direction the hydraulic line a higher modulus of elasticity as radial to the flow direction having the hydraulic line. One receives one in the radial direction smaller size at Essentially the same effect. The chamber is preferably of two substantially axially to the flow direction of the hydraulic line extending tubes formed between which a lens is arranged, wherein the annular Chamber over one at least over parts the circumference extending annular gap connected to the hydraulic line is. Here can be provided in particular that the lens in the axial direction (this corresponds to the flow direction the hydraulic line) a higher modulus of elasticity has as the tubes in the radial direction.

The problem mentioned at the outset is also solved by a hydraulic system, in particular for motor vehicles, comprising a master cylinder with a housing, a piston arranged axially displaceably therein, which delimits a pressure space filled with a hydraulic fluid, and axially upon actuation of the master cylinder by means of a piston rod acting on the piston is shifted and thereby the hydraulic fluid with Pressure is further applied comprising a slave cylinder and a pressure medium line connecting them, wherein the hydraulic system comprises a resonator according to one of the preceding claims, which is arranged in the pressure medium line between the master cylinder and slave cylinder.

In a development of the hydraulic system is provided that the resonator in the master cylinder, the slave cylinder, a connection coupling or a Kribbelfilter is integrated, whereby no additional Assemblies must be provided in the hydraulic system.

in the Below are embodiments of the Invention explained with reference to the accompanying drawings. there demonstrate:

1 a schematic representation of a hydraulic system based on an embodiment of a clutch release device;

2 a sketch of a first type of resonator;

3 a sketch of a second type of resonator;

4 a cross section through the resonator according to 2 ,

5 a further development of a resonator according to 4 ,

1 shows a schematic representation of a possible embodiment of a hydraulic system ( 1 ) Based on a clutch release device 3 with a master cylinder 4 and a slave cylinder 5 , A resonator 2 is in the embodiment shown in a connecting these pressure medium line 15 installed and separates them into a first line strand 11 and a second wiring harness 12 from each other. It is understood that in other embodiments, the resonator 2 on the master cylinder 4 or the slave cylinder 5 can be arranged. The resonator can be used, for example, in a plug connection, which the line parts 11 and 12 connecting, being integrated.

The clutch release system 3 operates the clutch 7 hydraulically by acting on the master cylinder 4 by means of an actuator 14 which may be a foot pedal, an actuator, such as an electric actuator, or the like. As a result, by means of a mechanical transmission 13 Pressure in the master cylinder 4 built, the on the pressure medium line 15 or the second wiring harness 12 , the resonator 2 and the first wiring harness 11 a pressure in the slave cylinder 5 builds. The slave cylinder 5 can - as in the example shown - concentric to the transmission input shaft 10 be arranged and axially supported on a - not shown - gear housing and the necessary disengaging force via a release bearing on the clutch 7 , or on the release elements such as disc spring, apply. Further embodiments may be a slave cylinder 5 that has a release mechanism 6 a releaser is actuated and arranged outside the clutch bell, provide, this by means of a hydraulically connected to the master cylinder housed in the slave cylinder housing piston the release mechanism 6 acted upon axially. To apply the disengagement of the slave cylinder is fixed to the housing respectively on the gear housing, which is not shown here, or attached to another housing-fixed component. The transmission input shaft 10 transmits when the clutch is closed 7 the torque of the internal combustion engine 8th to a not-shown gear and then to the drive wheels of a motor vehicle.

By the combustion processes in the internal combustion engine 8th experiences the crankshaft 9 depending on the configuration of the internal combustion engine 8th , For example, depending on the number of cylinders, non-uniform loads that express themselves in axial and / or tumbling oscillations of these and the release mechanism 6 on the slave cylinder 5 , the pressure medium line 15 on the master cylinder 4 and from there via the mechanical transmission 13 on the actuator 14 be transmitted. In the case of a clutch pedal as an actuator 14 These vibrations are perceived as unpleasant. In the case of an actuator as an actuator 14 For example, a reduced control accuracy or a shortened life can be the result of the vibrations.

2 shows a first embodiment of a resonator according to the invention 2 , the first wiring harness 11 and a second wiring harness 12 connects with each other. 4 shows the resonator according to 2 on average. The first wiring harness 11 is with a first disc 16 connected, accordingly, the second wiring harness 12 with a second disc 17 connected. The connection between the respective wiring harness and the respective disc can be done for example by welding, shrinking, gluing, soldering, flanging or the like or as a screw connection. Between the two discs 16 and 17 is an intermediate ring 18 arranged so that between the two discs 16 . 17 a disk-shaped chamber 19 arises. The two discs 16 . 17 are preferably made of a rubber or general Plastic manufactured, the intermediate ring 18 is preferably made of a metal.

The intermediate ring 18 thus has a higher modulus of elasticity E = σ / ε (Greek small sigma by Greek small epsilon, stress by strain), where ε represents the strain and σ the stress, as the two discs 16 . 17 , For the sake of simplicity, it is assumed that the modulus of elasticity is independent of the stress direction, ie the material is anisotropic.

The cable strands 11 . 12 are by an inner diameter di and the outer diameter because these are usually identical for both strands, and the thickness of the conduit wall t = (da - di) / 2 geometrically designated. The actual resonator 2 forming discs 16 . 17 have an inner diameter di of the strands 11 . 12 and an outer diameter R. The intermediate ring 18 is geometrically described by an inner diameter D and a thickness s.

3 shows an alternative embodiment of the resonator according to the invention 2 , In contrast to the embodiment according to the 2 the chamber extends 19 not substantially in the radial direction here, but essentially in the axial direction to the pressure medium line 15 , The chamber 19 arises here through an inner tube 20 as well as an outer tube 21 coming from a lens 22 are covered, and those with an annular gap 23 with the interior of the pressure medium line 15 are connected. The annular gap 23 can be over the entire circumference of the pressure medium line 15 extend, but can also eg individual webs 24 have, which the line strands 11 . 12 connect with each other.

dabei sind

C_RED

= die reduzierte Fortpflanzungsgeschwindigkeit bei einer elastischen Wand

C_STARR

= die ideale Schallgeschwindigkeit in dem Fluid bei einer absolut starren Leitung

K

= das E-Modul des Fluids

D

= der Innendurchmesser des Resonators 2

E

= das E-Modul der Leitung quer zur Fortpflanzungsrichtung einer Schwingung, dies entspricht hier der Durchflussrichtung der Hydraulikleitung

t

= die Dicke der Leitungswand, dies ist die halbe Differenz aus Außendurchmesser D und Innendurchmesser d

The dimensioning of the resonator 2 essentially results from the already in the DE 1475701 presented calculation. The relative propagation speed compared to an ideal rigid pipe system results

are there

C _RED

= the reduced rate of propagation of an elastic wall

C _STARR

= the ideal speed of sound in the fluid with an absolutely rigid pipe

K

= the modulus of elasticity of the fluid

D

= the inner diameter of the resonator 2

e

= the modulus of elasticity of the line transverse to the direction of propagation of a vibration, this corresponds here to the direction of flow of the hydraulic line

t

= the thickness of the pipe wall, this is half the difference between outer diameter D and inner diameter d

From this relationship results in the length of the resonator 2 to

For a rough estimate of the dimension of the resonator 2 It is assumed that an oil with a C _STARR = 1330 m / s and a K = 1550 kg / cm ² . Furthermore, of one E-module of the two strands 11 . 12 of about E = 2 × 10 ⁶ kg / cm ² (steel) and an E-module of the intermediate ring 18 of K = 56 kg / cm ² , wherein the intermediate ring 18 made of rubber.

For a frequency of 120 Hz, this results in a ratio D of t = 11.5, that is, a thickness of the conduit wall of 11.5 -th of the inner diameter of the resonator 2 , a length l of about 5 cm. At a frequency of 240 Hz results in a length of only 2.5 cm.

In the embodiment according to 3 corresponds to the inner diameter D and thus the resonator length of the resonator 2 according to 4 the axial length A.

The material pairing rubber for reducing the modulus of elasticity in the radial direction with steel with a high modulus of elasticity in the axial direction thus results in a significant reduction in the size of the resonator 2 , Known resonators, for example according to the previously cited DE 1475701 , here require the same numerical values lengths of the order of about 1.6 m at a resonant frequency of 200 Hz.

5 shows a further development of the embodiment according to 4 , Instead of a single intermediate ring 18 here are several intermediate rings 18a . 18b . 18c , here by way of example three, but it can also be any number, each with different inner diameters D ₁ , D ₂ , D ₃ between the discs 17 . 16 arranged. The different diameters result in different resonance frequencies Zen. About the thickness B ₁ , B ₂ , B ₃ , etc. and the inner diameter D ₁ , D ₂ , D ₃ , etc., the attenuation can be made different in individual resonance frequencies. In this way, several resonance frequencies and possibly an entire frequency spectrum can be filtered out of the frequency spectrum transmitted before the hydraulic fluid. These can be the intermediate rings 18a . 18b . 18c for a different inner diameter D ₁ , D ₂ , D ₃ , but also different axial thicknesses I ₁ , I ₂ , I ₃ have. For example, it is also possible to provide an intermediate ring made of externally reinforced with steel rubber to increase the modulus of elasticity.

1

hydraulic system

2

resonator

3

Clutch bearing

4

Master cylinder

5

slave cylinder

6

disengaging mechanism

7

clutch

8th

Internal combustion engine

9

crankshaft

10

Transmission input shaft

11

first wiring harness

12

second wiring harness

13

mechanical transmission

14

actuator

15

Pressure medium line

16

First disc

17

Second disc

18

intermediate ring

18a, 18b, 18c

intermediate rings different inner diameter

19

Disc-shaped or hollow cylindrical chamber

20

Interior pipe

21

Outer tube

22

lens

23

annular gap

24

web

D ₁

Inner diameter

D ₂

Inner diameter

D ₃

Inner diameter

18a, b, c

intermediate rings different inner diameter

di

Inner diameter

there

outer diameter

t

thickness

R

outer diameter

D

Inner diameter

s

thickness

l

overall length

A

Axial length

I ₁

Thickness, axial

I ₂

thickness axial

I ₃

thickness axial

B ₁

Thickness, radial

B ₂

Thickness, radial

B ₃

Thickness, radial

Claims (11)

Resonator ( 2 ) for pressure medium lines ( 15 ), characterized in that this one to the flow direction substantially rotationally symmetrical chamber ( 19 ) as resonance chamber. Resonator ( 2 ) according to claim 1, characterized in that the chamber ( 19 ) is disc-shaped and radially to the flow direction of the pressure medium line ( 15 ) a higher modulus of elasticity than axially to the flow direction of the pressure medium line ( 15 ) having. Resonator ( 2 ) according to one of claims 1 or 2, characterized in that the disc-shaped chamber is substantially radially to the flow direction of the pressure medium line ( 15 ). Resonator ( 2 ) according to one of claims 1 to 3, characterized in that the disc-shaped chamber of two radially to the flow direction of the pressure medium line ( 15 ), or to the first wiring harness ( 11 ) and to the second wiring harness ( 12 ) extending discs ( 16 . 17 ) is formed between which at least one intermediate ring ( 18 ) is arranged. Resonator ( 2 ) according to claim 4, characterized in that the at least one intermediate ring ( 18 ) of a material with a greater modulus of elasticity than those of the discs ( 16 . 17 ) consists. Resonator ( 2 ) according to one of claims 4 or 5, characterized in that a plurality of intermediate rings ( 18a . 18b . 18c ) of different inner diameter (D ₁ , D ₂ , D ₃ ) and / or different axial lengths (I ₁ , I ₂ , I ₃ ) between the discs ( 16 . 17 ) are arranged. Resonator ( 2 ) according to one of claims 4 to 6, characterized in that the at least one intermediate ring ( 18 ) at least partially made of metal and the discs ( 16 . 17 ) at least partially made of rubber. Resonator ( 2 ) according to one of claims 1 or 2, characterized in that the chamber ( 19 ) is hollow cylindrical and substantially axially to the flow direction of the pressure medium line ( 15 ) and in the flow direction of the pressure medium line ( 15 ) a higher modulus of elasticity than radially to the flow direction of the pressure medium line ( 15 ) having. Resonator ( 2 ) according to claim 8, characterized in that the hollow cylindrical chamber ( 19 ) of two substantially axially to the flow direction of the pressure medium line ( 15 ) extending pipes ( 20 . 21 ), between which a lens ( 22 ), wherein the annular chamber ( 19 ) over an at least over parts of the circumference extending annular gap ( 23 ) with the pressure medium line ( 15 ) connected is. Hydraulic system ( 1 ) particularly for motor vehicles comprising a master cylinder ( 4 ) with a housing, a piston arranged in this axially displaceable, which delimits a filled with a hydraulic fluid pressure chamber and upon actuation of the master cylinder ( 4 ) by means of a piston rod acting on the piston ( 13 ) is axially displaced and thereby the hydraulic fluid is pressurized, further comprising a slave cylinder ( 5 ) and a pressure medium line connecting them ( 15 ), characterized in that the hydraulic system ( 1 ) a resonator ( 2 ) according to one of the preceding claims, which in the pressure medium line ( 15 ) between master cylinder ( 4 ) and slave cylinder ( 5 ) is arranged. Hydraulic system ( 1 ) according to claim 9, characterized in that the resonator ( 2 ) in the master cylinder ( 4 ), the slave cylinder ( 5 ), a connection coupling or a Kribbelfilter is integrated.