DE19932583A1 - Hydraulically damping bearing - Google Patents

Abstract

Hydraulically damping bearing (1) with a first anchoring part (2) and a second anchoring part (3) movable relative to the first anchoring part (2), with a spring element (6) acting between the first and the second anchoring part (2, 3), with a working space (10) filled with damping fluid and a compensation space (11) which is separate from this and is connected to the working space (10) in a liquid-conducting manner via a damping duct (14, 17) delimited by a duct wall, the volume of the working space (10) being at a Relative movement of the first and second support body (2, 3) is changed so that damping fluid is moved in the damping channel (14, 17) between the compensation chamber (11) and the working chamber (10), and with a displacer arranged on the first anchoring part (2) (16) which extends into the working space (10) and which is movable with the first anchoring part (2) relative to the second anchoring part (3), wherein the channel wall of the damping channel (14, 17, 18) is formed at least in sections by the displacer (16).

Description

Technical field

The invention relates to a hydraulically damping bearing with a first Anchoring part and a movable relative to the first anchoring part second anchoring part, with one between the first and the second Anchoring part acting spring element, with a damping fluid filled workspace and one separated from it and over one of a channel wall limited damping channel liquid-conducting with the Work room connected compensation room, the volume of the Working space with a relative movement of the first and second support body is changed so that damping fluid in the damping channel between Compensation room and work space is moved, and with one on the first Anchoring part arranged displacer, which is in the work space extends and that with the first anchoring part relative to the second Anchoring part is movable.

State of the art

Such a hydraulically damping bearing is from DE 196 20 971 A1 known.

Such a bearing can cause low-frequency vibrations due to Resonance reactions of the damping fluid in the damping channel  be reduced. It is desirable that the damping channel is as long as possible around the mass of the fluid moving in the damping channel to enlarge. A long damping channel leads from DE 196 20 971 A1 known solution to a large height of the hydraulic bearing. A However, such is disadvantageous if the installation space, such as in an engine compartment.

Presentation of the invention

The invention has for its object a hydraulically damping bearing to further develop such that a long damping channel at the same time less Height of the warehouse is achieved.

This task is the beginning of a hydraulically damping bearing mentioned type in that the channel wall of the damping channel is formed at least in sections by the displacer.

Due to the design according to the invention, the displacer causes a Extension of the damping channel without thereby reducing the overall height of the Warehouse would be enlarged. The displacer can be designed so that it does not have a channel extension in the extended state and partially sprung or fully sprung condition of the bearing Channel extension causes. There is one in the extended damping channel relatively large amount of damping fluid added, which the Effectiveness of the vibration damping resulting from this increases.

According to an advantageous development of the invention it is provided that the Displacer is designed as a stop, which the movement between first and second anchoring part limited.  

A particularly long damping channel is achieved in that the Channel wall of the damping channel in sections by one on the second anchoring part arranged support body is formed. To this In this way, a long damping channel can be formed Channel wall in a first section through the support body and in one second section by the displacer, possibly together with the Support body is formed.

According to an advantageous embodiment of the invention it is provided that the Displacer in the partially sprung state of the bearing with a first one System section, which forms a first section of the channel wall, on the second support body rests. This ensures that, for. B. at Nominal load on the bearing is an extension of the Damping channel is effected while this is in the unloaded state of the Camp is not the case.

According to a development of this inventive concept, it is provided that when the first anchoring part moves relative to the second Anchoring part of the first contact section abutting the support body is elastically deformed. As a result, a relative movement from the first and second anchoring part not or only insignificantly hampered.

It has proven to be advantageous that the first contact section is in the axial Direction of the bearing extends to the second support body. Consequently the second contact section forms a substantially parallel to the axial Channel wall oriented towards the bearing.

According to an advantageous embodiment of the invention, it is provided that the displacer extends in the radial direction of the bearing has a second contact section, which has a second section of the Forms channel wall and abuts the second anchoring part.  

The second contact section is designed to be flexible, in particular Transverse movements of the first anchoring part to the second To allow anchoring part.

The manufacture of the hydraulic bearing is simplified in that the second Anchoring part in the area of the system of the second system section with a sealing cover layer is coated in particular from elastomer.

A further improvement is achieved in that in the first System section is formed a channel outlet that the damping channel with connects the work space.

The strength of the displacer is improved in that the displacer has a support body embedded in the elastomer.

The manufacturing costs can be reduced in that the displacer is formed in one piece.

This can further improve vibration isolation be that the displacer in the workspace one to the spring body adjacent liquid channel. The one in the liquid channel recorded damping channel forms together with that as an inflation spring acting spring body an oscillatable system. This can be done in the way be tuned that a vibration damping a certain frequency he follows.

According to a development of this inventive concept, it is provided that the liquid channel via an opening formed in the displacer the working chamber is connected to conduct liquid. Such an opening affects the resonant frequency in the liquid channel absorbed damping fluid. The opening can also be opened  the second extending in the radial direction of the bearing Contact section of the displacer can be formed closable. In this Fall would occur when a certain pressure difference between Damping channel and liquid channel the second system section otherwise open closed opening.

It is advantageously provided that a connection between the Liquid space and the work space through a recess, which in the second system section is provided, and through the channel outlet is made, the channel exit and the recess in particular are arranged adjacent to each other.

The vibration isolating properties of the bearing can be further improved that a damping fluid Partition is provided which separates the work space from the compensation space separates. The partition can in particular be designed as a flexible membrane his.

In this case, a long damping channel is achieved in that the Partition from the damping channel radially at least in sections is enclosed.

Brief description of the drawings

The object of the invention will be further explained with the aid of the drawing clarifies.

Fig. 1 shows a cross section through an inventive bearing.

Fig. 2 shows a cross section through an inventive bearing according to another embodiment.

Implementation of the invention

In Fig. 1, a hydraulically damping bearing 1 with a first anchoring part 2 and a relatively movable to the first anchoring part 2 the second anchoring part 3 is shown. About the existing metal first and second anchoring parts 2 , 3 , the bearing z. B. on the one hand to the motor and on the other hand to the chassis (not shown), with attachment via the holes 4 and 5 .

Between the first and second anchoring parts 2 , 3 , a spring element 6 is provided, which is designed as a rubber body. The ring-shaped rubber body has essentially the shape of a truncated cone, the outer end in the radial direction being connected to the second anchoring part 3 and the inner end in the radial direction being connected to the first anchoring part 2 . The spring element 6 can be connected to the first and second anchoring parts 2 , 3 by vulcanization. In the rubber body forming the spring element 6 , a support ring 7 is accommodated, which divides the rubber body into a radially inner and a radially outer section.

The second anchoring part 3 has a housing section 8 which surrounds the bearing axis 9 in a ring shape. The spring element 6 is fixed at the end of the housing section 8 facing the first anchoring part.

A working space 10 and an equalizing space 11 are formed in the space delimited by the housing section 8 . The work space is separated from the compensation space by a partition wall 12 which is mounted on a support body 13 . The working space and the compensation space are filled with damping liquid and connected to one another in a liquid-conducting manner via a damping channel 14 .

The working space 10 is delimited by the first anchoring part 2 , the spring element 6 , the housing section 8 , the partition wall 12 and the support body 13 . The compensation chamber 11 is delimited by the side of the partition wall 12 and the support body 13 facing away from the working chamber 10 and by an elastic membrane 15 designed as a bellows.

A displacer 16 , which extends in the working space 10 , is arranged in the damping liquid on the first anchoring part 2 . The displacer 16 can be moved together with the anchoring part 2 relative to the second anchoring part 3 .

With a relative movement between the first anchoring part 2 and the second anchoring part 3 , the volume of the working space 10 completely filled with damping liquid is changed, so that damping liquid is moved through the damping channel 14 between the working space 10 and the compensating space 11 . The elastic membrane 15 enables a variable volume of the damping liquid to be accommodated in the compensation space 11 . When vibrations are introduced into the bearing 1 , a vibration reduction is achieved in that the damping liquid received in the damping channel 14 is also set in vibration when the natural frequency of the damping liquid is excited in the damping channel 14 . It is advantageous here if the mass of the damping liquid moved in the liquid channel 14 is as large as possible. This can be achieved by a particularly long damping channel 14 .

The damping channel 14 therefore has a first section 17 and a second section 18 which extends the first section 17 .

The first section 17 of the damping channel 14 is formed in the support body 13 and extends in the radial direction outside around the partition wall 12 . The first section of the damping channel is bounded on the one hand by the support body 13 and on the other hand by the housing section 8 of the second anchoring part 3 . The first channel section 17 is opened via a first channel opening 19 to the compensation chamber 11 and via a second channel opening 20 to the working chamber 10 or to the second channel section 18 .

Like the first channel section 17, the second channel section 18 extends in a radial direction along the housing section 8 . It is limited on the one hand by the displacer 16 fixed on the first anchoring part 2 and on the other hand by the support body 13 fixed on the second anchoring part 3 and the housing section 8 . The second channel section 18 is opened via the second channel opening 20 to the first channel section 17 and via the third channel opening 21 to the working space 10 .

In the unloaded, spring-loaded state of the bearing 1 , which is shown in the left half of the figure in FIG. 1, the displacer 16 is not in contact with the support body 13 . In this case, the damping channel 14 consists only of the first channel section 17 .

When the bearing 1 is partially loaded, the displacer 16 rests with a first contact section 22 on the support body 13 and a second contact section 23 on the housing section 8 . First and second contact sections 22 , 23 thus form, together with the support body 13 and the housing section 8, the channel wall of the damping channel 14 in the second channel section 18 .

The first and second contact sections 22 , 23 are designed to be flexible and thereby on the one hand enable a relative movement of first and second anchoring parts 2 , 3 along and transversely to the bearing axis 9 . The first contact section 22 is formed on the body of the displacer 16 and extends in the direction of the bearing axis 9 towards the second support body 3 . The first contact section 22 is arranged such that it comes into contact with the support body 13 in the region of the radially outer end of the partition wall 12 .

The second contact section 23 extends in the radial direction of the bearing, ie transversely to the bearing axis 9 . It has a corrugated cross-section to increase flexibility. At the radially outer end, the second contact section has the shape of a tapered contact lip. The housing section 8 has a cover layer 24 on its inner wall, against which the second contact section 23 lies in a sealing manner.

The displacer 16 consists essentially of elastomer 25 and has a metal support element 26 embedded therein. The first and second contact sections 22 and 23 are formed in one piece with the body of the displacer 16 made of elastomer 25 . The displacer 16 is fastened to the first anchoring part 2 via a pin 27 .

The displacer 16 divides a liquid channel 28 adjacent to the spring element 6 in the working space 10 . The axis of the bearings 9 are formed facing side of the spring member 6 and the spring element 6 facing side of the displacer 16 are substantially parallel. The liquid channel 28 can be connected to the rest of the working space 10 via an opening 29 . In the exemplary embodiment shown, the opening 29 is closed by the second contact section 23 of the displacer 16 . However, since the latter is designed to be flexible, the opening 29 is opened as soon as a considerable pressure difference builds up between the second section 18 of the damping channel 14 and the liquid channel 28 . However, such an opening could also be formed in the body of the displacer 16 (not shown).

The partition 12 separating the working space 10 from the compensation space 11 is designed as an elastic membrane. Damping fluid is applied to both sides. The partition 12 is held in position by holding sections 30 of the support body 13 .

The displacer 16 is also designed as a stop which limits the movement between the first and second anchoring parts 2 , 3 . In its lower position, the displacer bears against the support body 13 , the elastically designed first contact section 22 being bent outward in the radial direction.

The hydraulically damping bearing 1 shown in FIG. 2 largely corresponds to the embodiment shown in FIG. 1. The same reference numbers are therefore used for matching parts. In the hydraulically damping bearing 1 shown in FIG. 2, a recess 31 is provided in the second contact section 23 , which is arranged adjacent to the channel outlet 21 . In this way, a connection is created between the liquid space 28 and the working space 10 .

Claims (17)

1. Hydraulically damping bearing ( 1 ) with a first anchoring part ( 2 ) and a second anchoring part ( 3 ) movable relative to the first anchoring part ( 2 ), with a spring element ( 6 ) acting between the first and the second anchoring part ( 2 , 3 ) ), with a working space ( 10 ) filled with damping liquid and a compensating space ( 11 ) connected to the working space ( 10 ) in a liquid-conducting manner and connected to the working space ( 10 ) via a damping duct ( 14 , 17 ), the volume of the working space ( 10 ) upon a relative movement of the first and second support body ( 2 , 3 ) is changed so that damping fluid is moved in the damping channel ( 14 , 17 ) between the compensation chamber ( 11 ) and the working chamber ( 10 ), and with a on the first anchoring part ( 2 ) arranged displacer ( 16 ) which extends into the working space ( 10 ) and which with the first anchoring part ( 2 ) relative to the two ten anchoring part ( 3 ) is movable, characterized in that the channel wall of the damping channel ( 14 , 17 , 18 ) is formed at least in sections by the displacer ( 16 ). 2. Bearing according to claim 1, characterized in that the displacer ( 16 ) is designed as a stop which limits the movement between the first and second anchoring part ( 2 , 3 ). 3. Bearing according to claim 1 or 2, characterized in that the channel wall of the damping channel ( 14 , 17 , 18 ) is formed in sections by a support body ( 13 ) arranged on the second anchoring part ( 3 ). 4. Bearing according to one of claims 1 to 3, characterized in that the displacer ( 16 ) in the partially compressed state of the bearing ( 1 ) with a first contact section ( 22 ) which forms a first section of the channel wall, on the support body ( 13 ) is present. 5. Bearing according to claim 4, characterized in that in the relative movement of the first anchoring part ( 2 ) to the second anchoring part ( 3 ) of the displacer ( 16 ) on the support body ( 13 ) is elastically deformed. 6. Bearing according to claim 4 or 5, characterized in that the first contact section ( 22 ) extends in the axial direction of the bearing ( 1 ) to the support body ( 13 ). 7. Bearing according to one of claims 1 to 6, characterized in that the displacer ( 16 ) has a in the radial direction of the bearing ( 1 ) extending second contact portion ( 23 ) which forms a second portion of the channel wall and on the second anchoring part ( 3 ) is present. 8. Bearing according to claim 7, characterized in that the second contact section ( 23 ) is flexible. 9. Bearing according to claim 7 or 8, characterized in that the second anchoring part ( 3 ) in the region of the system of the second system section ( 23 ) is coated with a sealing cover layer ( 24 ), in particular made of elastomer. 10. Bearing according to one of claims 4 to 107, characterized in that a channel outlet ( 21 ) is formed in the first contact section ( 22 ), which connects the damping channel ( 14 , 17 , 18 ) with the working space ( 10 ). 11. Bearing according to one of claims 1 to 10, characterized in that the displacer ( 16 ) has a support body ( 26 ) embedded in elastomer. 12. Bearing according to one of claims 1 to 11, characterized in that the displacer ( 16 ) is integrally formed. 13. Bearing according to one of claims 1 to 12, characterized in that the displacer ( 16 ) in the working space ( 10 ) divides a liquid space ( 28 ) adjacent to the spring element ( 6 ). 14. Bearing according to claim 13, characterized in that the liquid space ( 28 ) via an opening in the displacer ( 16 ) formed ( 29 ) with the rest of the working space ( 10 ) is connected in a liquid-conducting manner. 15. Bearing according to one of claims 1 to 13, characterized in that a connection between the liquid space ( 28 ) and the working space ( 10 ) through a recess ( 31 ) which is provided in the second contact section ( 23 ), and through the Channel outlet ( 21 ) is made, the channel outlet ( 21 ) and the recess ( 31 ) being arranged in particular adjacent to one another. 16. Bearing according to one of claims 1 to 15, characterized in that a partition wall ( 12 ) loaded with damping liquid is provided, which separates the working space ( 10 ) from the compensation space ( 11 ). 17. Bearing according to claim 16, characterized in that the partition ( 12 ) from the damping channel ( 14 , 17 , 18 ) is radially enclosed at least in sections.