DE20019120U1 - Rubber bearing bush - Google Patents

Description

DESCRIPTION

The invention relates to a rubber bearing bush which is intended to be loaded perpendicular to its longitudinal axis. Such rubber bearings are referred to as radial bearings. They are used extensively in motor vehicle construction, and in particular in commercial vehicle construction as chassis bearings, especially for the rear axle.

Bearings of this type typically consist of a cylindrical outer sleeve, a cylindrical inner sleeve and a cylindrical elastomer spring between these two sleeves.

The problem with these bearing bushes, as with most rubber bearings, is the service life of the elastomer spring. If the elastomer spring is set too hard, it can no longer do its job of damping and cushioning vibrations entering the bearing, while if the setting is too soft, it will begin to tear after a relatively short time.

To defuse this conflict of objectives, it is known from the current state of the art to set the rubber spring to be comparatively hard in terms of the mixture in order to extend its service life, but then to incorporate openings and cavities of various configurations into its spring body in order to be able to create a comparatively soft characteristic curve for the spring overall by creating additional deformation cavities inside the spring despite a mechanically strong and spring-stiff matrix. Although such adjustments lead to significantly improved results, they often take away the structural strength of the rubber spring and the bearings constructed with such rubber springs, which then leads to springs and bearings that no longer ensure adequate axle guidance in all three spatial directions when used, particularly in commercial vehicle construction.

· · I

• t ··

A rubber bearing bushing that is configured and coordinated in this way is known, for example, from the international publication WO 97/35123 A1. The bushing, which consists of an outer sleeve, rubber spring and inner sleeve, has a total of four recesses, namely a pair of axially and radially opposing recesses, which open in pairs into the two opposite end faces of the bushing, thus creating two openings in each of the two end faces of the bushing.

In this known bush bearing, which is also used in particular as a chassis bearing, a sufficiently soft characteristic curve is obtained despite the use of a relatively hard material for the rubber spring. By configuring large pocket-like cylindrical recesses that are axially aligned in the radial plane on both sides of the inner sleeve in an axial view, it is achieved that such cavities in the areas in which the load stress peaks occur create the possibility for internal deformation of the elastomer.

The major disadvantage of this well-known rubber bearing bush, however, is that the size and configuration of the required cavities noticeably influences the axial and radial guidance stability of the bearings. This is especially true if the bushes are not to be arbitrarily large, but are to be configured to be particularly small in their dimensions as a target specification.

Based on this state of the art, the present invention is based on the technical problem of stabilizing rubber bearing bushes of the type discussed here both in terms of their axial guidance stability and their radial stability, while maintaining soft characteristics, in such a way that they can also achieve a

still sufficient leadership stability, especially

tracking stability.

To solve this problem, the invention provides a rubber bearing bush which has the features mentioned in claim 1.

The rubber bearing bush according to the invention is therefore characterized primarily by only two axially continuously open recesses in the rubber spring matrix, which, largely enclosing the inner sleeve of the bearing bush, are configured at their tangential ends, also axially continuously, in such a way that they stabilize themselves against torsion in a stop-like manner. At the same time, these recesses, which largely enclose the inner sleeve with complementary surfaces and peripherally, have no axially inner chamber partition walls, which also achieves axial stabilization of the inner sleeve of the rubber bearing bush.

The rubber bearing bush with the features of the invention is therefore also capable of withstanding dynamic mechanical long-term loads through the use of a spring-stiff and mechanically strong spring matrix, shows an easily adjustable soft spring characteristic in the radial direction and is at the same time axially and torsional stiff due to the configuration of the recesses.

The purely configurative features of the rubber bearing bushes, which are the subject of the invention, can therefore achieve a stabilization of the rubber bearing bushes that can only be achieved for the rubber bearing bushes according to the state of the art by a larger dimensioning of the spring matrix. For a given requirement profile, the total construction volume of the rubber bearing bush with the features of the invention can therefore be dimensioned much smaller than for a corresponding rubber bearing bush with the design features according to the state of the art.

Embodiments of the invention are the subject of the dependent claims.

The invention is explained in more detail below using an embodiment in conjunction with the drawings. They show:

Figure 1 shows an embodiment of a rubber bearing bush with the features of the invention in front view; and

Figure 2 shows the bearing shown in Figure 1 in axial section.

In the embodiment shown in the figures, the rubber bearing bush is shown without an outer sleeve, i.e. in the relaxed state of the rubber spring, in order to better illustrate the configuration of the rubber spring. After the rubber bearing bush has been finally assembled, the rubber spring is inserted into the outer sleeve under a massive radial preload and is firmly connected to it.

In detail, the figures show a rubber bearing bush with a cylindrical outer sleeve (not shown here), a cylindrical inner sleeve 2 and a cylindrical elastomer spring 1. The elastomer spring 1 has two recesses 3, 4 that extend over the entire length of the rubber spring 1 and open diametrically opposite each other in the side surfaces of the bearing. The tangential length of the recesses 3, 4 in the radial section or in the opening profile in the end faces of the rubber spring 1 is larger than the outer diameter of the inner sleeve 2.

When viewed in radial section, the contour of the radially curved recesses 3,4 is adapted to the contour of the inner sleeve, which in a sense surrounds the inner sleeve 2 radially on the outside, i.e. peripherally. However, this profile enclosing the inner sleeve 2 is only formed on a central section of the tangential longitudinal extension of the opening profile. At their tangential edges, the two recesses 3,4 are each configured in such a way that they merge smoothly into a

• «

Curvature so that a kidney-shaped contour is formed in the tangential edge areas. Overall, the opening contour of the two recesses 3, 4 in the rubber spring has an approximate and softly curved shape in the form of the letters "M" (bottom) or "W" (top), with "top" and "bottom" each relating to the direction of the load vector 18 intended for the application.

In axial section, the recesses 3,4 have a substantially rectangular configuration (Figure 2). At their tangential edges 6,7, the recesses 3,4 are configured with cylindrical grooves which extend coaxially to the bearing axis 17.

In contrast to the prior art, the bearing of the invention does not have two pairs of recesses lying opposite one another, which are elastically separated from one another in the middle by the matrix material of the rubber spring, but has only two recesses in total, which are continuous from one end face 8 of the rubber spring to the opposite end face 9. However, this "continuity" of the openings should not exclude the possibility that, for manufacturing reasons, for example due to working with pushed cores, thin material flags remain, which may act as membranes to block one or both of the continuous openings from being seen through, but are in any case only so thin that they have no influence whatsoever on the spring characteristic or the stability behavior of the rubber spring.

This design of the rubber spring sleeve can protect the axial guidance of the inner sleeve against tilting, displacement or

Distortion of the axis of the inner spring sleeve compared to the outer spring sleeve can be significantly reduced. At the same time, the radial contour of the two recesses ensures that the inner sleeve has a high degree of torsional strength compared to the outer sleeve, despite the radially soft bearing of the inner sleeve. The effect of a rolling movement of the circumferentially closed inner walls of the recesses when torques are applied between the inner sleeve and the outer sleeve, which tends to occur with enclosing opening contours, is counteracted by the recess edge sections, which are curved in opposite directions in their tangential end areas, in a stop-like braking manner.

By combining both effects, the elimination of the central fixation of the recesses which leads to axle tilting and the torsional stabilization by means of opposing recess contours, the rubber spring sleeve with the features of the invention achieves sufficient radial softness of the spring with high material strength and at the same time high track stabilization both against a destabilization of the axial parallelism between the inner sleeve and the outer sleeve and against a torsion-related floating of the two sleeves against each other.

These two essential effects can be improved by making the rubber spring as thin as possible in its area 19 resting on the outer casing of the inner sleeve 2, viewed radially, so that the spring material required for the spring task in question is formed practically exclusively in the outer ring 20 of the spring 1 surrounding the recesses. This can in particular reduce additional axial floating of the rubber spring sleeve.

As can be clearly seen in Figure 2, stop rings (10, 11) are provided in the central area of the sleeve spring to absorb radial breakdown loads, which practically do not come into contact with one another under the normal operating conditions intended for such a bearing. For this purpose, as shown in Figure 2, the annular bead (10) or the stop (10) provided on the radially inner recess wall (13) is designed in an annular groove-like depression (12) of this inner wall (13).

What is also surprising about the configuration of the rubber bearing bush shown here in Figures 1 and 2 is that the cylindrical configuration of the longitudinal edges 6,7 of the recesses 3,4 prevents the occurrence of stress peaks and thus the tendency for cracks to form in the spring material under dynamic loading, not only in this area but also in the areas 14,15 on both sides of the inner sleeve that are otherwise at risk of cracking, transverse to the intended dynamic loading. Due to the presence of the axial cylindrical inner deformation cavities in the support area and abutment area of the incoming dynamic forces, the deformation stresses that arise under such dynamic loading are already absorbed in the available cavities as internal deformation, and are thus eliminated, without significant peak stresses running into the other compression areas 14,15.

Finally, a further stabilization of the rubber spring sleeve can be achieved by dimensioning the spring contours in the relaxed state in the embodiment shown in the figures in such a way that the axis 16 of the inner sleeve 2 is not coaxial with the axis 17 of the outer sleeve, but in the direction of the

•♦

·

« m * &lgr;

The distance between the two parallel axes 16,17 measured in the direction of the static load vector 18 is configured in such a way that both axes 16,17 fall into each other under the influence of a static load acting as intended, i.e. they are coaxial with each other. If, in the manner also evident from the figures, the lower recess 4 in the central area in the direction of the static load vector is radially higher by as much as the distance between the axes 16,17 measured in the same direction, then in the installed state and under an application-specific statically acting force in the zero position of the dynamic load, a rubber spring radial bearing

or a rubber bearing bush, which ensures the highest possible symmetrical and dissipative distribution of incoming deformation stresses under dynamic load. At the same time, the "saddling" of the inner sleeve on or between the recesses 3,4 that surround it in some areas leads to a pronounced track-stable behavior of the rubber spring sleeve, without this having to be adjusted by additional spring matrix material and thus by over-dimensioning the spring.

Claims (8)

1. Rubber bearing bush, in particular chassis bearing, especially for commercial vehicles, consisting of a cylindrical outer sleeve, a cylindrical inner sleeve and a cylindrical elastomer spring between these two sleeves with diametrically opposed recesses opening into the side surfaces of the cylindrical bearing, the tangential length of which in the radial section is greater than the outer diameter of the inner sleeve, the contour of which in the central region in the radial section is configured to be complementary to the outer contour of the inner sleeve, and which, also in relation to the radial section, are delimited at their tangential edges by axially extending cylindrical grooves, while in the axial section they show a substantially rectangular configuration, characterized by a contour course of the recesses ( 3 , 4 ) on both sides of the central region ( 5 ) in relation to the radial section, which no longer follows the contour of the inner sleeve ( 2 ) in a complementary manner, but turns radially outwards in a substantially kidney-shaped manner, so that the The overall configuration of each of the recesses ( 3 , 4 ) in radial section is shown as edge-free, rounded W-shaped ( 3 ) or M-shaped ( 4 ). 2. Rubber bearing bush according to claim 1, characterized by recesses ( 3 , 4 ) which extend openly on both sides through the elastomer spring ( 1 ). 3. Rubber bearing bush according to one of claims 1 or 2, characterized by an enclosure of the inner sleeve ( 1 ) by the radial central region ( 5 ) of the recesses ( 3 , 4 ) on an arc in the angular range of 50° to 160°. 4. Rubber bearing bush according to one of claims 1 to 3, characterized by a larger radial height of the recess ( 4 ) located at the bottom in the direction of a load vector ( 18 ) acting as intended when the rubber bearing bush is not loaded. 5. Rubber bearing bush according to one of claims 1 to 4, characterized by a wider annular groove-like depression ( 12 ) formed axially centrally in the underlying sole of the lower recess ( 4 ), in which a radially inwardly projecting annular web ( 10 ) is formed, which can cooperate with a correspondingly configured and radially outwardly projecting annular web section ( 11 ) on the upper wall of the recess ( 4 ) as a soft progression stop. 6. Rubber bearing bush according to claim 5, characterized by an annular web ( 10 , 11 ) which runs axially centrally around the entire inner wall of the lower recess and which is configured in the tangentially outer, radially outwardly directed profile sections ( 6 ', 7 ') of at least one of the two recesses ( 4 ) in a membrane-like manner and largely closed in accordance with the tuning requirements in the radial section and which keeps the recess open only in the central region ( 5 ') which is designed to enclose the inner sleeve ( 2 ) in a complementary shape. 7. Rubber bearing bush according to one of claims 1 to 6, characterized by a dimensioning of the radial thickness of the wall sections ( 19 ) of the recesses ( 3 , 4 ) which respectively abut the inner sleeve ( 2 ) is as thin as possible for tuning reasons, but at the same time as strong as necessary in order to withstand the shooting or other subsequent insertion of the inner sleeve into an inner bore of the elastomer spring without damage. 8. Rubber bearing bush according to one of claims 1 to 7, characterized by an eccentric arrangement of the central axis ( 16 ) of the inner sleeve ( 2 ) above the central axis ( 17 ) of the elastomer spring ( 1 ), based on the intended installation position of the bearing and the z-axis of the vehicle.