DE2239618C2 - Vibration damper for hydraulic systems - Google Patents

Description

The invention relates to a vibration damper for hydraulic systems, which according to the preamble of claim I is formed.

From GP-PS 8 35 975 or US-PS 26 09 001 is a vibration damper of the generic type known. With the help of such a vibration damper, the vibrations generated by the fluid attenuated that circulates in the pipe between the connections connected to the system. The fluldum flows through the permeable wall of the pipe to the to dampen vibrations generated by the fluldum. When the Fluldum passes through the permeable The wall of the pipe will transmit the vibrations. so that the vibration frequency and also the

"Fluid velocity in the area of passage through

increase the permeable wall of the pipe. As a result, the vibration-damping tube is heated, including the vibration damping behavior of the Vibration damper suffers.

From US-PS 22 78 688 an accumulator or collector is known in which no fluid circulation in his Tube occurs because only a single liquid connection and an axially oppositely arranged gas valve are provided.

From US-PS 26 25 235 a muffler for a muffler is known, which has a variety of side running slots which are limited by elastic webs.

Furthermore, from DE-PS 6 83 936 a spring-operated pressure collector or one operated with compressed air Known pressure collector, which forms an air chamber. As usual, such a collector has a single system connection and is not flowed through by a fluid as in a vibration damper of the generic type. In such a collector there is also no resilient bubble-shaped separation. The collector Although it has a movable conical nail body, which is only intended to provide the passage cross-section to design variably.

The invention is based on the object of providing a vibration damper for hydraulic systems of the generic type Art dcxart to train that the passed through and fluid to be damped in the region of the permeable pipe in this way through the permeable pipe through and into the area of the flexible partition and out of this again into the area of the permeable Rohres is fed back that the damper is also suitable for high frequency vibrations and when heated and thermal expansion of the pipe is functional and provides good vibration damping.

This object is achieved with the features of the characterizing part of claim 1 in the case of a vibration damper solved the generic type.

In the invention is a deflector or a Closure provided in the longitudinal passage of the permeable tube, so that the fluid around the permeable wall of the pipe flows through twice. In this way, a desired one is obtained with the aid of the deflecting device

* ⁵ Forced guidance of the fluid, which flows through the permeable wall of the pipe at two different points, so that good vibration damping is obtained even with high frequency vibrations. The vibration damper according to the invention is therefore surprisingly effective.

Further developments of the invention are given in the subclaims.

When interpreting the vibration damper according to claim 2, an easy installation and removal of the permeable tube allows, for example, the deflection device or the closure to another To relocate.

When the vibration damper according to claim 5 is a detachable attachment for the deflection device or the Closure indicated. As a result, the deflection device or the closure can be easily and quickly in the The longitudinal passage of the pipe can be offset according to the requirements. By such a transfer the phenomenon of resonance in the vibration damper can be suppressed, so that vibration damping can be achieved achieved even at very high frequencies, for example are on the order of 300 to 400 Hz.

The following is an exemplary embodiment! the invention described with reference to the drawings. Ice shows

Fig. 1 is a longitudinal sectional view of a vibration damper for hydraulic systems and

Fig. 2 is an enlarged view of the vibration damper in partial section to illustrate the formation of the connections in the area of the Connections.

According to FIGS. 1 and 2, a vibration damper for hydraulic systems has a rigid outer shell IO in Shape of an elongated, cylindrical bottle with two hemispherical ends in which two opposite one another Openings Ho and 116 of the same diameter are provided, the axes of which lie on a line. In each opening Πα, 116 is a port 12α and 126 to Connection of the vibration damper with the hydraulic system installed. According to FIGS. 1 and 2 are the Connections 12a, 126 provided with an internal thread 13 to attach the vibration damper to the lines of the to connect hydraulic system (not shown).

Each port 12α or 126 is built into the respective opening Ho or 116 with a rigid ring 14, which diametrically divided and frictional fit? is connected to an undivided elastic ring 15. thanks to the diametrical division of the ring 14, the components 14, 15 can be introduced as a unit in the form that they are in the opening 11a or 116 can be bent into it. The arrangement with the ring 14 is based at 16 on the Inside of the outer sheath 10 around the opening, since it will reset itself after insertion. Of the Connection 12o or 126, which was previously introduced into the interior of the outer shell 10, is then to the outside guided, wherein it is inserted at 17 in the ring 14 so that a neck 18 of the connector 12a, 126 at 19 at the ring 16 rests.

The port 12a or 126 is centered at 17 and pinned at 19, 16 outward. In the interior direction, a nut 20 is provided for fixing, which is screwed onto an external thread 21 of the connection 12a or 126 and a ring 22 against the Outer shell 10 presses. The connection 12α or 126 is firmly connected to the outer shell 10 in all directions.

The port 12a or 126 is inserted into the respective opening 11a or 116 using seals built in, which have two separate toric connection points 23 uiid 24. The Dic.itung 23 is on the one hand inserted radially between the outer shell 10 and the connection 12a or 126 and on the other hand axially between an inclined support 25 of the ring and a disk 26 next to the king 14.

The seal 24 is inserted into a groove 27 of the ring 22 and is axially supported on a flat support 28 around the opening 11a and 116.

A seal in the axial direction is independent of the expansion of the outer shell and the other parts through the seal 23 thanks to the inclined support 25 and in the radial direction through the seal 24 thanks to the flat Edition 28 ensured.

A compliant bubble-shaped partition 30, for example made of a stretchable material, extends inside the rigid outer shell 10 and divides the Inside the outer shell 10 into an inner space 31 and an outer space 32 with variable volumes. A third Connection 33 is provided on the outer shell 10 and is connected to the outer space 32 for vibration damping in connection. In the illustrated embodiment, the third connection 33 is a Cias injection valve 33. das supplies the external space 32 with a pressurized gas and maintains a predetermined gas pressure. Alternatively, the connection 33 can be connected to a liquid space of a pressure accumulator.

The compliant bubble-shaped partition 30 has Mouths 34a and 346 which are opposite each other and whose axes lie on a line. The mouths 34a and 346 are connected to terminals 12a and 126. The partition 30 comprises two parts 30a and 306, which are provided with two mouths 34a and 346 and are connected to one another at 30c When assembling, glue or adhesive is conveniently used and it is an inclined connection line (see Fig. 1) provided.

The mouth 34a includes a rigid ring 35a, which forms a reinforcement and has an L-shaped cross-section and in the same way contains the mouth 346 an annular stiffener 356. The part 30o of the separation 30 is with the stiffening ring 35a and the Part 306 cast with reinforcement ring 356.

The reinforcement ring 35a or £ ftb is centered around a smooth, cylindrical receptacle 3t> a sleeve 37a or 376, which has a thread 38 on the outside of the receptacle 36, which can be screwed into the internal thread 13, and which on the inside outside The receptacle 36 has a flat shoulder 39 and then a fold 40 and a conical support 41.

The reinforcement ring 35a or 256, centered with the aid the receptacle 36 is axially on the sleeve 37a or 376 bearing against the shoulder 39 with a clamp 42 held. The mouth 34a or 346 is between the reinforcement ring 35a or 356 and the fold 40 locked in. When the sleeve 37a or 376 with the thread 38 is screwed into the internal thread 13, the mouth 34a or 346 is also between the reinforcement ring 35a or 356 and the neck 18 of the Terminal 12a, 126 clamped, so that a tight seal is ensured.

An axially extending tube 50 has a longitudinal twisting passage 51 for connection to the connections 12a and 126 and a permeable rare wall 52 which has a plurality of openings 53. The permeable side wall 52 is by means of a stack of disks 54 covered.

The openings 53 and the spaces between the disks 54 form passages in the side wall 52 of the pipe 50, so that the longitudinal passage 51 is connected to the interior space 31.

The tube 50 has a first end 55a with external thread 56, which is in tias internal thread 13 after the threaded piece 38 of the sleeve 37a is screwed. Between the external thread 56 and the disks 54, the Pipe 50 on a smooth support 57, which In the socket 37o is inserted.

The tube 50 has no threaded connection at its second end 556 and only has a smooth support 58, which are freely moveable in the axial direction in the socket 37 is stored.

A deflection device or a closure 60 is arranged in the Lüngsdurchgang 51 of the tube 50 and forms a resistance there, so that dl ?. Connections Ma and 126 are connected via the permeable side wall 52 of the tube 50 and to the interior space 31 of the partition 30.

The deflector or the shutter 60 lsi Im Longitudinal passage 51 axially offset by means of a pin 61

bar, which engages in the openings 53. The deflector 60 is charged arbitrarily in the middle of the pipe 50 or at an eccentric location, in order to generate different pressure drops above and below / u, which causes resonance phenomena of the system suppressed or attenuated. The vibration damper therefore enables the damping of high frequencies Vibrations, for example on the order of 300 to 400 Hertz.

The parts of the vibration damper are put together as follows:

The parts 30a and 306 of the partition 30 are glued together at 30f after being in the vesicular flexible separation 30 sleeves 37 ″ and 376 are used. Each socket 37 ". 376 is then at 36 In the reinforcement ring 35 ". 356 is inserted and rests against 39 and is held in place by the clamp 42.

The assembly with the components 30, 37 ", 376 is inserted into the rigid outer shell 10 via one of the openings 11" or 11 * and the connection 12 "is inserted through the opening 11" of the rigid outer shell 10. The split ring 14 with the elastic ring 15 is inserted through the opening 11 ″ and the connection 12 ″ is pushed into the ring 14. To install the connection 12 ″, the components 26, 23, 24 are attached and the nut 20 is tightened.

The sleeve 37 "is then screwed into the connection 12" at 38 and the bubble-shaped separation 30 is fixed at its first end. Similarly, connector 126 is attached to the opposite cord and sleeve 376 is threaded into connector 126 at 38. The bubble-shaped separation 30 is then firmly connected to the rigid outer shell 10 at both ends.

Finally, the tube 50 with the disks 54 and with the discharge device or the closure 60 is pushed in Fig. 1 from right to left into the rigid outer shell i0. its end 556 being axially displaceably mounted in the sleeve 376. The winding piece 38 is inserted into the Internal thread 13 of connection 12 ″ inserted.

To push the disks 54 onto the tube 50

the rest 57 is at the other end of the tube 50 formed by a separate component 62 that connects to tube 50 in some way. /. U. by means of a Locking screw 63. is connected.

The rigid outer shell 10 is connected to the hydraulic system via the connections 12 ″ and 126 in order to dampen vibrations. Through the connection 38 pressurized (Jas) is introduced into the outer space 32. If a fluid flows like a liquid. In the system, for example, from the connection 12 ″ to the connection 126 , the fluid from the system is in the longitudinal passage 51 to the right of the Deflection device or initiated by the closure 60 and passes through the openings 53 and the spaces between the discs 54 into the interior space 31 and then passes to the left of the deflector 60 via the openings 53 and the spaces 54 in turn into the longitudinal passage 51 to the left of the deflector or the closure 60. The fluid then flows in the direction of the connection 126 and re-enters the hydraulic system.

The vibration damper enables vibrations with a high frequency to be dampened. By changing The position of the deflecting device or the closure 60 in the Lüngsdurchgang 51 allows the damping effect each system optimally and resonance-JO phenomena can be suppressed.

Since the tube 50 is axially displaceable, leave compensate for thermal expansions in a simple way without impairing the attenuation and under Maintaining an effective seal through seals 23 and 24.

The fluid to be damped flows through the vibration damper with extremely low pressure losses.

For this purpose 2 sheets of drawings

Claims (6)

Patent claims: 1. Vibration damper for hydraulic systems with a rigid outer shell, the two opposite Has openings in each of which a connection for connecting the vibration damper with the hydraulic system is built in, a resilient, bubble-shaped separation with two with the Connections connected mouths, which the interior of the outer shell into an interior and a The outside space is divided into a variable volume, a pipe with a longitudinal passage connecting the connections and a permeable side wall that connects the longitudinal passage with the interior, and a third connection for pressurized fluid on the outer shell for supplying the Exterior, characterized in that a deflection device (60) or a closure in the longitudinal passage (51) of the tube (50) is arranged at a fixed point such that the In the Pipe (50) between the ports (12a. 126) forcibly circulates fluid to the deflector (60) or the closure bypasses and via the permeable side wall (52) of the tube (50) to the interior (31) passes. 2. Vibration damper according to claim 1, characterized in that the tube (50) at least in one of the two connections (12a. 126) is mounted freely movable in the axial direction. 3. Vibration damper according to claim 2, characterized in that the tube (50) in the one Connection (126) mounted freely displaceable in the axial direction and fixed with the other connection (12a) is. 4. Vibration damper according to claim 1, characterized in that the deflection device (60) on an axially fixed point in the longitudinal passage (51) of the tube (50) is adjustably arranged. 5. Vibration damper according to claim 4, characterized in that the deflection device (60) or the closure is arranged in the tube (50) by means of a pin (61) which is inserted into openings (53) of the tube (50) intervenes. 6. Vibration damper according to claim 1, wherein the permeable rare wall of the tube is a series of Has slots, characterized in that the slots are formed by a stack of discs (54) which surrounds the tube (50) provided with openings (53).