DE1002168B - Rubber-to-metal component with relief notches in the rubber - Google Patents

Description

Rubber-to-metal component with relief notches in rubber The invention relates on a rubber-metal component with relief notches in the rubber.

In a known rotationally symmetrical rubber buffer, the rubber and metal are not firmly bonded to each other, the rubber buffer has a outwardly concave peripheral surface. This is intended to make movements of the contact surfaces opposite the metal parts when the rubber buffer is deformed under the influence of compressive loads be prevented. In the case of a cylindrical design, the rubber buffer would be underneath deform barrel-shaped under a compressive load, and the contact surfaces with the metal parts would strive to expand outward as well. This endeavor to movements in relation to the metal parts, which the friction prevailing there more or less opposed, leads to destruction of the rubber body fairly quickly. The outwardly concave peripheral surface is intended to counteract or reduce the relative movement prevent such as much as possible.

It was also used for similarly designed rubber-to-metal components Relief notches in the rubber suggested, special shrinking rubber compounds to use or the rubber body provided for the construction of the rubber-metal component Vulcanize beforehand so that the rubber body is in the unloaded state in each case is under tension, which is only under the influence of the load must be lifted again.

At z. B. normal wedge bearings resulted in endurance tests with 5 mm preload and + 4 mm path change at 300 strokes / min. a breaking load cycle number of 150,000. But even wedge bearings, the strength-wise through the use of relief notches were made cheaper in the rubber near the adhesive surface, are sufficient under the The described conditions do not meet the requirements in practical operation, although with the same test conditions, they showed a breaking load cycle number of 1,250,000. The reason for the experiments were wedge bearings, which in rear-mounted engines were quickly destroyed exhibited. In addition to stresses from the engine load and torque also occurred additional stresses due to longitudinal thrusts from the cardan shaft and on the other hand, there are also loads resulting from drops in speed up to resonance on.

In complicated bearing bodies, as they are, for. B. represent wedge bearings, it has been shown that there is a rubber volume in the edge zones of the rubber body is that the free deformation of the rubber body under load as it were in the way is. This rubber volume has to be pushed away, so to speak, when the rubber body is deformed , whereby it is practically uninvolved in absorbing the load. this has the consequence that for this rubber volume an increase in the flexing work to be performed enters and on the other hand a rubber body provided with relief notches of the usual type tends to wrinkle at the bottom of the relief notches, which leads to cracking and then leads to breakage in a short time.

The invention is based on a rubber body with relief notches, which has no pre-tension in the unloaded state, and wants to be eliminated of the rubber volume, which is dead in a certain sense, the breaking strength of the rubber-metal component increase significantly or increase it many times over. This is according to the invention achieved in that the relief notches by removing the in the loaded state of the rubber occurring swellings are generated.

You can accomplish this removal in a simple manner by from the edge zone surface of the rubber, which is flat in the unloaded state, between the adjacent metal part edges swelling when exposed to stress, so in particular @ dlere which everted out almost parallel to the adhesive surface on the particularly stressed parts and places that almost form a sharp edge, in the loaded state of the Component can be ground down to a flat surface along the metal part. After releasing the load, notches with unexpected characteristics then result Design with a deep countersink near the points where the breakage was previously made occurred, d. H. at the places subject to unfavorable stress, especially in the edge zones of the rubber body.

A wedge bearing made in this way, in which the under the influence of the normal deformation in the rubber body due to swelling in the unloaded In the condition of the rubber body, indentations that emerge are pre-compensated according to position and depth are, did not show any at the previously critical points of the camp Tendency to break more. Those determined under the same test conditions given above The number of cycles to failure of the bearing according to the invention was 2,500,000.

In the drawing is an embodiment of a rubber-metal component illustrated in the form of a bearing body designed as a wedge bearing according to the invention in comparison with a known bearing body. 1 to 3 show a bearing body known training in front view, top view and side view, Fig. 4 a Bearing body with a rubber-metal component according to the invention in section along the line IV-IV of Fig. 5, Fig. 5 is a sectional view along line V-V of Fig. 4, Fig. 6 shows a partial section along the line VI-VI in FIG. 4.

In the figures, parts that correspond to one another are given the same reference numerals Mistake.

1 and 2 are the metal parts of the bearing body, 3 is the attached one Rubber body of the wedge bearing, which has a cavity at 4. In the left half 1 are the lines of the presumed voltage curve in the rubber body 3 indicated. As can be seen, they accumulate near point 5 where at Loads fractures occurred in the adhesive surface. The places 5 are therefore the places the greatest stresses, which then occur on the side longitudinal edges when stressed almost parallel to the adhesive surface z. B. turn sharp edges out of the rubber, such as one by the dashed line 6 in the right half of FIG. 3 is indicated. The components are shown in Fig. 1 to 5 in the unloaded state.

As can be clearly seen in FIGS. 5 and 6, are distinguished in the Edge zones after the swelling has been removed under load and removal of the same in the rubber 3 characteristic, especially at the points 5 (Fig. 1) not foreseeable Depressions 6 'from. These depressions 6 'begin immediately at 7 (FIG. 5) the edges of the metal bodies 1, 2.

Instead of removing the duels z. B. by way of the entrance Abrasion mentioned for example with the help of a profiled grinding wheel can Relief notches in the rubber are also formed by elevations in the forming tool will. The shape and location of the relief notches can therefore, for. B. by the Arrangement of oppositely shaped elevations on the forming tool in advance which practically correspond to the notches produced by grinding. When molding the rubber body, form it in a suitably prepared shape Then the depressions or relief notches according to the invention, which loaded the im Compensate for any duels that occur in the situation according to position and depth. The one made in this way Rubber-to-metal component has the additional advantage that the rubber skin is nowhere the outer surface of the rubber body needs to be attacked. Usually done then also the shaping of the rubber body in one operation with the production an adhesive connection with the associated metal parts.

Claims (2)

PATENT CLAIMS: 1. Rubber-to-metal component with relief notches in the rubber, characterized in that the relief notches (6 @ by removing the loaded State of the rubber occurring swellings (6) are generated. 2. Rubber-to-metal component with relief notches in the rubber, which are formed by bumps in the forming tool are, characterized in that the surveys are practically the one produced according to claim 1 Notches correspond. Publications considered: German patent specification No. 668987; French patents nos. 568 280, 762 631.