DE10300967A1 - Resilient, damping, anti-vibration engine mounting, includes elastic spring sections providing location and stops for liquid-filled damping chamber - Google Patents

Abstract

The upper connecting section (3) has a shaft (5) coaxial with the central axis (A) passing through the center of the spring (2), in the direction of loading (B). The shaft passes through a sealed chamber (7) filled with viscous fluid (6). A rigid plate (9) fixed permanently to the shaft extends radially within the chamber leaving an opening (8) (a narrow gap). Axial movement of the chamber is limited by stops (10, 11) and positioning spring sections (12, 13). These hold the chamber in a central axial location between themselves.

Description

The invention relates to an elastic Bearings for elastic support of machines producing vibrations, in particular motors in motor vehicles, with an elastic spring element that between an upper and a lower connecting part is arranged.

Such bearings serve the Body of a motor vehicle against the engine vibrations isolate.

Elastic bearings, in particular for elastic support used by motors, limit the occurrence Vibration amplitudes stops on. There is a significant lack of such known attacks in that they're always just for a very specific basic static load on the bearing and the the resulting static deflection can be optimally set can, that - starting from their given basic or middle position - which is resulting free paths until the attacks take effect in both Deflection directions have exactly the required dimensions.

A change in the available free routes occurs but not only when increasing or reducing the base load of the camp, but also if the elastic properties of the bearing change due to material aging change over time.

Readjustment or automatic tracking for Maintaining the clearances is in the known principle of operation of the attacks problematic and only possible with considerable design effort.

From the DE-OS 36 41 006 an elastic hydraulic bearing is known which always guarantees the same constant free travel for deflections both with different basic loads and with deflection changed due to aging. The elastic hydraulic bearing for supporting a vibrating body, in particular a motor vehicle engine, has an upper and a lower connecting part, these connecting parts being supported against one another by an elastic spring element. The elastic bearing also has a hydraulic chamber which is filled with a hydraulic fluid and is divided by a partition into a first and a second partial space, the wall of the first partial space being formed by the elastic spring element and the wall of the second partial space being elastically deformable. The partition provided comprises a closure part which can be deflected in the direction of the bearing axis and a frame part which surrounds the closure part and which has two stop elements which limit the deflections of the closure part to a free path. Between the closure part and the stop elements, an overflow path connecting the subspaces is provided, which is closed when the closure part rests against one of the stop elements. With such an elastic hydraulic bearing, the design freedom in the design, in particular of the stops and existing spring elements, is severely restricted.

The invention is based on the object alternative elastic bearing of the type mentioned with To create a vibration path limitation that is independent of a changing base load and / or a deflection due to aging changes and the more freedom in the constructive design of the elastic Camp enables.

This task is done with an elastic bearing of the type mentioned at the beginning with the characteristics of the characteristic Part of claim 1 solved.

According to the invention, the elastic bearing comprises an annular elastic spring element that attaches to a lower connector is, and an upper connector that is coaxial with the bearing center axis extending centrally through the spring element in the direction of loading Shaft. The shaft extends through a sealed axially displaceable chamber filled with a viscous liquid and is within the chamber with a cross section up to on at least one flow opening, rigid plate extending transversely to the shaft. The chamber can be moved axially in the direction of tension and compression by attached to the lower connector and opposite each other Train and pressure stops limited. Moreover positioning springs are provided that keep the chamber in keep a middle axial position between the pull and push stops.

By such a trained elastic bearing is achieved that the distance between the chamber the train and push stops even with a changing Basic load and / or an age-related change Deflection of the annular spring element designed as a suspension spring remains constant. The vibration path running through the deflection is accepted by the Chamber. The chamber itself is about that Positioning springs dynamically coupled with the pull and push stops. The dynamic coupling according to the invention the chamber with the pull and push stops allows more freedom in the constructive design of the train and pressure stops as well of the positioning springs. In particular, very hard stops and vibration travel limits be created, using progressive stop characteristics possible is.

Through the at least one flow opening the dynamic displacement caused by vibrations the viscous liquid from the chamber in below the rigid plate the chamber space located above the rigid plate and vice versa. The throughflow opening is preferably through formed a narrow circumferential gap.

But it is also possible that through the flow opening at least one bore disposed within the rigid plate and / or by at least one arranged within the rigid plate damping valve is formed, between the circumference of the rigid plate and the circumferential Inside the wall of the chamber, a seal can be provided an axial displacement of the chamber relative to the rigid plate allowed and impermeable for the viscous liquid is. When using a damping valve opens the passage opening always only when a certain pressure in the below the rigid plate located chamber or in the above the rigid plate Chamber space is reached.

Another useful embodiment of the The invention provides that the flow opening through at least one Channel in the form of a tubular body or the like is formed, the channel on the one hand to the above the rigid plate chamber and on the other hand to chamber space below the rigid plate is open, being between the circumference of the rigid plate and the circumferential inner side wall the chamber can be provided with a seal that is axially displaceable the chamber allowed relative to the rigid plate and impermeable to the viscous liquid is. length and diameter of the channel, which can be designed, for example, as a hose can be selected depending on the requirements.

Further training and advantageous Refinements of the invention result from the subclaims and from the exemplary embodiment of the invention described below, which is shown in the drawing. In this shows:

1 a schematic representation of the elastic bearing according to the invention in longitudinal section.

This in 1 illustrated elastic bearings 1 comprises an annular elastomeric spring element 2 , preferably a vulcanized elastomer that is between a lower connector 4 and an upper connector 3 is arranged. The lower connector 4 consists of a pot-shaped housing 16 with a mounting flange 17 over which the elastic bearing 1 is attached to a chassis, foundation, chassis or the like, not shown here. The top connector 3 is connected to a motor vehicle engine or the like, not shown here. The ring-shaped elastomeric spring element 2 closes the lower connector 4 such that inside the pot-shaped housing 16 a cavity 19 remains.

The top connector 3 has a coaxial to the central bearing axis A in the direction of loading B centered by the annular elastomeric spring element 2 extending shaft 5 on. This shaft 5 extends sealed by a viscous damper fluid 6 filled annular damper chamber 7 , As a damper fluid 6 a highly viscous silicone oil is preferably used. The damper chamber 7 is axially on the shaft 5 can be moved up and down, being between the shaft 5 and damper chamber 7 sliding seals 18 are arranged for sealing.

The shaft 5 is also inside the damper chamber 7 with a chamber cross section except for a narrow circumferential annular gap 8th overlapping, horizontally extending rigid disc 9 firmly connected.

The disc 9 is between the top and bottom of the damper chamber 7 Movable up and down by a free path D. The ring gap 8th is chosen so narrow that at high speeds the axial free path D of the disk, which is usually provided for decoupling acoustic vibrations 7 is blocked. The ring gap 8th represents a throttle gap, which forms a flow connection between an upper and a lower sub-chamber within the damper chamber.

The damper chamber 7 is in the cavity 19 of the housing 16 between ring-shaped elastic rubber springs 12 . 13 positioned with the rubber springs 12 . 13 in an upper spring gap 14 and a lower spring gap 15 can swing. To limit the lower spring gap 15 is on the bottom of the case 16 a lower elastomeric pressure stop 11 arranged, which is annular. To limit the upper spring gap 14 is in the upper area of the housing 16 an upper elastomeric stop 10 arranged, which is also annular. The pull and push stops are preferred 10 . 11 with the corresponding rubber springs 12 . 13 integrally formed. The upper elastomeric pull stop is particularly preferred 10 also one-story with the annular spring element 2 educated.

Due to the provided train and pressure stops 10 . 11 is the axial displacement of the damper chamber 7 limited in tension and compression direction C. The provided rubber springs 12 . 13 enable the dynamic coupling of the train and pressure stops 10 . 11 with the damper chamber provided for damping 7 ,

1

elastic camp

2

annular spring element

3

upper connector

4

lower connector

5

shaft

6

viscose liquid

7

chamber

8th

gap

9

plate

10

cable stop

11

jounce

12

upper positioning spring

13

lower positioning spring

14

upper spring gap

15

lower spring gap

16

casing

17

mounting flange

18

sliding seals

19

Hohhaum

A

Bearing center axis

B

load direction

C

Train- and printing direction

D

Freiweg in the chamber

Claims (9)

Elastic bearing ( 1 ) for the elastic support of machines producing vibrations, in particular engines in motor vehicles, with an elastic spring element ( 2 ) between an upper and a lower connector ( 3 . 4 ) is arranged, characterized in that the upper connecting part ( 3 ) centered coaxially to the central axis of the bearing (A) in the direction of loading (B) through the spring element ( 2 ) extending shaft ( 5 ) which is sealed by an axially displaceable, viscous liquid ( 6 ) filled chamber ( 7 ) which extends within the chamber ( 7 ) with a rigid plate that extends across the chamber cross section to at least one flow opening and extends transversely to it ( 9 ) is firmly connected, the axial displacement of the chamber ( 7 ) in the pulling and pushing direction through on the lower connecting part ( 4 ) attached and opposing tension and pressure stops ( 10 . 11 ) is limited and positioning springs ( 12 . 13 ) are provided, which the chamber ( 7 ) constantly in a central axial position between the pull and push stops ( 10 . 11 ) hold. Elastic bearing ( 1 ) according to claim 1, characterized in that the flow opening through a narrow circumferential gap ( 8th ) is formed. Elastic bearing ( 1 ) according to claim 1 or 2, characterized in that the flow opening through at least one inside the rigid plate ( 9 ) arranged bore and / or through at least one inside the rigid plate ( 9 ) arranged damping valve is formed, wherein between the circumference of the rigid plate ( 9 ) and circumferential inside wall of the chamber ( 7 ) a seal can be provided which allows the chamber to be axially displaceable ( 7 ) relative to the rigid plate ( 9 ) allowed and impermeable to the viscous liquid ( 6 ) is. Elastic bearing ( 1 ) according to one of claims 1 to 3, characterized in that the throughflow opening is formed by at least one channel in the form of a tubular body or the like, the channel on the one hand to above the rigid plate ( 9 ) located chamber and on the other hand to below the rigid plate ( 9 ) located chamber space is open, between the circumference of the rigid plate ( 9 ) and circumferential inside wall of the chamber ( 7 ) a seal can be provided which allows the chamber to be axially displaceable ( 7 ) relative to the rigid plate ( 9 ) allowed and impermeable to the viscous liquid ( 6 ) is. Elastic bearing ( 1 ) according to one of claims 1 to 4, characterized in that the positioning springs provided ( 12 . 13 ) in one piece with the associated pull and push stops ( 10 . 11 ) are trained. Elastic bearing ( 1 ) according to one of claims 1 to 5, characterized in that the positioning springs ( 12 . 13 ) are designed as rubber springs, each rubber spring having a spring gap ( 14 . 15 ) which is caused by the pull or push stop ( 10 . 11 ) is limited. Elastic bearing ( 1 ) according to one of claims 1 to 6, characterized in that the lower connecting part ( 4 ) a pot-shaped housing ( 16 ) with a mounting flange ( 17 ) over which the elastic bearing ( 1 ) can be attached to a chassis or the like. Elastic bearing ( 1 ) according to one of claims 1 to 7, characterized in that the chamber ( 7 ) is provided with a control device for changing or switching off the damping. Elastic bearing ( 1 ) according to one of claims 1 to 8, characterized in that the viscous liquid ( 6 ) is a silicone oil.