DE3125830C1 - In a motor vehicle elastically mounted drive unit - Google Patents

Description

The invention relates to a drive unit elastically mounted in a motor vehicle according to the preamble of claim 1.
From DE-OS 27 47 225 a vibration damper for a drive unit of the type mentioned is known, which is held in the support tube via resilient support members, which are designed as rings and have a square cross-sectional shape. Such support members tend to harden when they are subjected to compressive stress, as a result of which sufficient energy is no longer withdrawn from the excitation system. In addition, the damper spring detection is influenced by deformation of the support members as a result of internal diameter deviations of the support tube to the extent that the damper spring detection changes due to post-deformation.

The object of the invention is to provide an improved

To create damper spring for the system mentioned above, in which the dynamic properties of the built-in spring ensures a certain resonance frequency and maximum energy dissipation is possible is.

According to the invention, this object is achieved by the features of claim 1. More beneficial Features include the subclaims.

The main advantages achieved by the invention are that the damper spring by their Training is no longer subject to pressure, but mainly to thrust and they are made of pipe and Mass tolerances is decoupled by the bearing rings provided. When pressing the damper spring into the The pipe and the absorber mass no longer harden and the oscillation process takes place Damper mass is a deformation of the annular part of the damper spring, which is also a very low frequency Elimination vote allowed.

The elastically deformable area of the damper spring is between two relatively stiff bearing rings held with a preferably rib-shaped

Elastomer layer are provided. On the one hand, these ribs are designed in such a way that they have tolerances of the support tube, but on the other hand are made so hard that the dynamic properties of the damper can be determined solely by the damper spring. The stiff design of the two bearing rings causes no change in the distance between these bearing rings, i. H. a squeezing the spring takes place and thus the dynamic properties of the spring despite the deviation of the Inside diameter of the support tube or the mass of the actual size are retained and the desired resonance frequency is achieved.

The damper is pressed into the support tube using a stamp. So that the mass between the The damper springs do not push themselves into the spring and the position of the damper springs is not changed outer bearing ring preferably has a stop on its two end faces.

Embodiments of the invention are shown in the drawing and will be described in more detail below described. It shows

F i g. 1 shows a side view of an internal combustion engine connected via a support tube with a gear unit,

2 shows a longitudinal section through the support tube with an internal vibration damper,

3 shows a front view of the damper spring with an outer and an inner bearing ring,
F i g. 4 shows a section along the line IV-IV of FIG. 3, FIG. 5 shows a side view in section of the damper spring during an oscillation process and

F i g. 6 shows another embodiment of a damper spring.

Like F i g. 1 shows, a support tube 1 provides a rigid connection between a one arranged lying in front Internal combustion engine 2 and a transmission unit 3 arranged at the rear. This unit 3 essentially comprises a change gearbox and an axle drive. Via an inside of the support tube 1 arranged drive shaft 4 is the internal combustion engine 2 with the rear gear unit 3 in one driving connection. This drive unit, known as the “transaxle unit” 5, is on the vehicle body held by appropriately elastically matched bearings, which are not shown in more detail. in the Support tube 1, the drive shaft 4 is arranged between bearings that have a position in the overall system in the Assume that bending resonances of the shaft 4 are avoided.

The support tube 1 can be equipped with one or more vibration absorbers 7, depending on the existing ones vibrating areas of the entire drive unit be provided. In the illustrated embodiment there is only one area rich in vibrations, so that only one area is used to suppress the vibrations Damper 7 is provided.

Like F i g. 2 shows in more detail, the vibration damper 7 comprises a mass 8, which is located via damper springs 9 (FIG. 2) and 10 (FIG. 6) is supported in the support tube 1 in a relatively free-swinging manner relative to the drive shaft 4 and to the support tube 1. the Damper springs 9; 10 are preferably at the same distance a from the center of gravity S of the damper mass 8 arranged. The mass 8 of the absorber 7 has the shape of a sleeve which the drive shaft 4 is free of contact encloses and over the damper springs 9; 10 is supported on the inner wall of the support tube 1. The absorber 7 is self-holding pressed into the support tube.

The damper spring 9 comprises, according to a first embodiment, one between two concentric arranged in the support tube 1 bearing rings 11, 12 held resilient support member 13. After Another embodiment, according to Figure 6, the two bearing rings 14 and 15 in contrast to the Bearing rings 11 and 12 of the first embodiment have the same length, the resilient support member 13 is designed according to the embodiment, according to Fig.2, ίο.

The support member 13 is designed to be resiliently elastic that it is in all radial directions as well as in Longitudinal directions absorbing shear forces and designed to determine the frequency range of the absorber 7 is. For this purpose, it is provided with a kidney-shaped cross section, which has an outer convex area 17 and an inner channel-shaped region 18 comprises. Its circumferential lateral surfaces 19 and 20 or 21, 22 are flattened and vulcanized or by some other joining method to the outer bearing ring 11 or 14 and the inner bearing ring 12 and 15 firmly connected.

In the area of a plane xx, the support member 13 has such a soft ring area that can be deformed in a defined manner in response to thrust forces in accordance with the desired frequency position of the absorber 7.

The spherical region 17 of the support member 13 extends approximately up to one through the two end faces of the bearing rings 11, 12 or 14, 15 formed outer plane 23. The bearing rings 11, 12 or 14, 15 each have an elastomer layer on their outer circumferential surfaces 24 and 32, in the longitudinal direction extending ribs 25, 26 are formed. These ribs can have an angular shape or a have a rounded shape. They are so dynamically stiff that the identifier of the elastic Support members 13 remains unaffected. At the same time, the ribs take on pipe tolerances.

The outer bearing ring 11 or 14 and the inner bearing ring 12 or 15 are deformed so that a predetermined distance b between the bearing rings is maintained despite inaccuracies in the pipe diameter, so that no change in the spring rate and thus the damper effect via the elastic support member 13 of the Damper spring 9; 10 can occur.

According to the first embodiment, according to FIGS. 2

to 5 is the support base 28 formed by the outer bearing ring towards the inner surface 29 of the support tube 1

so made longer than the receiving base 30 of the inner Bearing ring 12 on the damper mass 8, the two bearing rings 11 and 12 with the outer plane 23 to lock. The jacket surface 20 of the elastic support member connected to the inner bearing ring 12 13 is opposite to the connected to the outer bearing ring 12 jacket surface 19 of the support member 13 to Outer plane 23 arranged offset. According to the further embodiment according to FIG. 6, both Bearing rings 14 and 15 of the same length and overlap.

So that the damper spring 9; 10 after it has been pressed into the support tube 1, there is no change in the spring rate Can assume position, the inner end face of the outer bearing ring 11 or 14 is designed above and forms an annular stop 31 for the corresponding to the outer diameter of the bearing ring Damper mass 8. Likewise, the outer end face of the bearing ring can be provided with a stop, which as

Stop for a tool, such as a stamp for Pressing in is used.

In Fig. 5 is the damper spring 9 during the oscillation process shown in the direction of arrow 33 with an oscillation path c. The spherical area 17 of the support member 13 is deformed and the lower crowned area 17 of the support member 13 is stretched. The deformed area folds so that the convex section extends up to or above plane 23. Because of the length and location of the two opposite connecting surfaces of the support member 13 on the inner surfaces of the bearing belts 11, 12 and 14, 15, the spring rate of the support member is also influenced.

For this purpose 3 sheets of drawings

Claims (12)

Patent claims: 1. In a motor vehicle elastically mounted drive unit with an internal combustion engine located in front with a rear gear unit by means of one in the vehicle longitudinal direction aligned support tube., Is rigidly connected, in which a drive shaft runs and to Suppression of vibrations of the entire unit within the support tube in the vibrating area Area a vibration damper is arranged, the damper mass as the drive shaft Contact-free enclosing sleeve is formed and about in end receptacles of the Damper mass supported damper springs on the inner wall of the support tube, the damper together Damper springs in the support tube is pressed self-retaining, characterized in that the Damper spring (9; 10) each one between two concentrically arranged in the support tube (1) bearing rings (11,12; 14,15) held such a resilient support member (13) comprises that it is in all radial Directions as well as in longitudinal directions absorbing shear forces and the frequency range of the absorber (7) is designed to determine. 2. Unit according to claim 1, characterized in that the support member (13) is designed as an elastic ring and has at least one area which is elastically deformable in the case of shear forces in the area of a plane (xx). 3. Unit according to claims 1 or 2, characterized in that the resilient support members (13) from the center of gravity (S) of the damper mass (8) each have the same distance / a ^. 4. Unit according to: claims 1 to 3, characterized in that the support member (13) in cross section Is kidney-shaped, an outer convex area (17), an inner channel-shaped Area (18) and circumferentially flattened jacket surfaces (19, 20), one jacket surface (19) with the outer bearing ring (11) and the further jacket surface (20) with the inner bearing ring (12) is connected. 5. Unit according to claim 4, characterized in that the outer spherical region (17) of the resilient support member (13) approximately up to one through the two end faces of the bearing rings (11,12) formed outer plane (23) extends. 6. Unit according to one or more of the preceding claims, characterized in that that a support base (28) formed by the outer bearing ring (11) for the support tube (1) is longer is designed as a receiving base (30) of the inner bearing ring (12) on the damper mass (8) and both bearing rings (11 and 12) are flush with the outer plane (23). 7. Unit according to one or more of the preceding claims, characterized in, that the outer surface (20) of the elastic one connected to the inner bearing ring (12) Support member (13) opposite to the outer bearing ring (11) connected to the lateral surface (19) of the Support member (13) is arranged offset to the outer plane (23). 8. Unit according to one or more of the preceding claims, characterized in that that the two bearing rings (14,15) have the same length and overlap in the support tube (1) are arranged (Fig. 6). 9. Unit according to one or more of the preceding claims, characterized in that the bearing rings (11, 12 and 14, 15) at their outer circumferential surfaces each have an elastomer layer, extending in the longitudinal direction Ribs (25, 26) are formed in their dynamic stiffness to obtain a defined Spring identification of the resilient support member (13) are designed to absorb tolerances. 10. Unit according to claim 9, characterized in that that to achieve a constant radial distance (meanwhile the bearing rings (11, 12 resp. 14, 15) these are designed to be relatively resistant to deformation. 11. Unit according to one or more of the preceding claims, characterized in that that the damper mass (8) has an outer diameter which corresponds to the outer diameter of the outer bearing ring (11 or 14) corresponds to or is larger than the last mentioned. 12. Unit according to claim 11, characterized in that the outer bearing ring (11 or 14) is designed as a stop (31) at least on its inner end face, that of one end face of the Opposite absorber mass (8).