FR2839763A1 - Rubber engine mounting includes hydraulic mounting including two interconnected liquid chambers providing axial damping, and rubber bushing providing radial damping - Google Patents

Abstract

The engine mounting includes an interior casing (9) on which is a hydraulic mounting (2), that provides axial damping and that is constituted by two liquid chambers (4,5) that communicate with one another via a flow channel (6) and that are disposed one behind the other, and a rubber bushing (3) that provides radial damping, are disposed and are surrounded by a common envelope housing (8).

Description

the axle (6) of the vehicle.

PALIERENCAOUTCHOUC

DESCRIPTION

  Technical field For the mounting of motors on a chassis or similar with vibration damping, hydraulic bearings are used which exert a damping effect in the axial direction. The individual hydraulic bearings are also configured so as to be able to exert a damping effect both in the axial direction and in the radial direction. However, such bearings have a very complicated structure and do not

  can therefore be manufactured economically.

  State of the art DE 40 31 495 A1 has disclosed a hydraulic bearing in which two wind liquid chambers connected to each other by flow channels and which acts both in the axial direction and in the radial direction . This level meets a plurality of requirements imposed on such levels. We therefore seek to further simplify the construction of this bearing without thereby removing anything from its efficiency. Presentation of the invention The object of the invention is to create a rubber bearing whose structure is as simple as possible and which thus allows economical manufacture while exerting a damping effect both in the axial direction and in the radial direction. In addition, the bearing should have the smallest

possible dimensions.

  For a rubber bearing according to the invention, this object is achieved with an inner sleeve on which a hydraulic bearing with axial damping, constitutes at least two liquid chambers arranged one behind the other in the axial direction and communicating one with the other by flow channels, and a rubber cushion which exerts a radial damping wind arranged one behind the other in the axial direction and wind surrounded by a common casing sleeve. This combination makes it possible to give the two bearing components an extremely simple structure without limiting

their effectiveness.

  The preferred embodiment of the rubber bearing provides that the inner sleeve has an annular collar which is surrounded by an elastomer ring and which forms the intermediate wall between the liquid chambers. The lateral walls, located axially on the outside, of the liquid liquid chambers produced by two other elastomer rings located at a radial distance from the inner sleeve. The wall, located radially on the outside, of the liquid chambers consists of a closure ring provided with the flow channels. To improve support, the blastomeric radial rings

  wind with reinforcement sole.

  The axially acting rubber pad may consist of an intermediate sleeve wrapped in an elastomeric material. The intermediate bush gives the rubber pad the desired stiffness in the axial direction. The thickness of the elastomer material is selected in

  correspondence to the desired depreciation.

  The casing sleeve has a first rod for receiving the rubber pad and is provided with a cutout which is connected to the latter and which receives the hydraulic bearing. The configuration is advantageous insofar as it is a favorable solution which is suitable for the reception of the forces exerted on the hydraulic bearing. These wind forces taken up by the side walls of the cutout. The side wall of the cutout directed towards the rubber pad is intrinsically very stable thanks to its connection with the first section, con of the casing sleeve. To obtain the same mechanical resistance at the outlet end of the casing sleeve on the hydraulic bearing, this end is provided with a drawdown of the edge obtained by stamping. To obtain a constructed height as small as possible, the liquid chambers are kept small. In the event of a significant impact, this can cause the mutually opposite side walls of the chambers to touch. This may result in the liquid being trapped or unable to flow to the desired extent. To avoid it, on its side wall located in a chamber, at least one of the elastomer rings is provided with hollow channels oriented radially. These hollow channels wind at regular intervals at the periphery of the side wall and thus allow a

liquid evacuation.

  The elastomer rings intended for wind fluid chambers

  vulcanized to the inner sleeve or to the collar of the inner sleeve.

  I It is then very favorable that all the metal parts of the dou he solves it

covered with elastomer.

  The rubber pad can be manufactured separately and then passed over the dou le interieur re already endowed with the hyd ra ulic bearing. In the next manufacturing step, the closing ring is inserted into the hydraulic bearing and the casing sleeve is passed over the rubber pad.

  and the hydraulic bearing, and its wind ends folded down.

  The invention is explained below in more detail using an example

  shown in the drawing.

  In the drawing: FIG. 1 represents the rubber bearing in longitudinal section and FIG. 2 represents a section along the line B-B through the bearing in

rubber of figure 1.

4 2539763

  The rubber bearing 1 shown in longitudinal section in FIG. 1 essentially consists of the hydraulic bearing 2 with axial damping and the rubber bearing 3 with radial damping. The hydraulic bearing 2 has two liquid chambers 4 and 5 which communicate with each other through the flow channels 6. The channels

  flow 6 households in the front side of the closing ring 7.

  The hydraulic bearing 2 and the rubber pad 3 wind made in one piece and wind surrounded and held together by a common casing sleeve 8. The inner sleeve 9 is located inside the hydraulic bearing 2 and the sleeve d envelope 8. The inner sleeve 9 has a

  collar 10 of annular shape on which the elastomer ring 11 is vulcanized.

  The collar 10 and the elastomer ring 11 form the intermediate wall between the two liquid chambers 4 and 5. The lateral walls 12 and 13, located axially outside, of the liquid chambers 4 and 5 are formed by

  the elastomer rings 12, 13 which vulcanize on the inner sleeve 9.

  The reinforcement plates 14 and 15 are connected to the elastomer rings 12 and 13. The closing wall of the liquid chambers 4 and 5 is formed by the closing ring 7 which is made of synthetic material and which is inserted

  on the elastomer rings 12, 13 between the reinforcement plates 14, 15.

  The rubber pad 3 essentially consists of the intermediate sleeve 20 made of sheet metal and the elastomer material 21 applied to its

two sides.

  The casing sleeve 8 has a first section, con 22 of cylindrical shape and a cutout 23 which is connected thereto. While the first section, con 22 re, receives the rubber pad 3, the cutout 23 is configured to receive the hydraulic bearing 2. At the end which comprises the hydraulic bearing

  2, the casing sleeve 8 has a drawdown 24 stamped from its edge.

  This configuration of the casing sleeve 8 is associated with important

technical advantages.

  The elastomer ring 11 connected to the collar 10 is provided with hollow channels 25 on its side walls. Two recessed channels 25 which wind off

  one of the other of 180 wind provided on each side wall.

  The elastomer rings 11 to 13 are connected by vulcanization to the collar 10 or to the inner sleeve 9. The vulcanization is carried out in such a way that all the metal parts are covered by the elastomer, so that the inside of it 9 is completely wrapped, as are the sole

reinforcement 14 and 15.

  Figure 2 shows a cross section along the line BB of Figure 1, in which we can see the relative arrangement of the casing sleeve 8, the elastomer ring 11 and the collar 10. The collar 10 is provided with holes 30 distributed at its periphery, which improves the connection between the elastomer ring 11 and the collar 10. As can also be seen in FIG. 1, the section, con 22 of the casing sleeve 8 is surrounded by a connecting sleeve 26 by which the bearing can be fixed to a corresponding bodywork part. The dou il le interieure 9 is used as other

attachment point.

Claims (12)

  1. Rubber bearing characterized by an inner sleeve (9) on which a hydraulic valve (2) which exerts axial damping and which consists of at least two liquid chambers (4, 5) which communicate with each other by flow channels (6) which are arranged one behind the other, and a rubber cushion (3) which exerts radial damping, wind arranged one beside the other on the other in an axial direction and wind   surrounded by a common casing sleeve (8).   2. Rubber bearing according to claim 1, characterized in that the inner sleeve (9) has a collar (10) of annular shape which is surrounded by an elastomer ring (11) and which forms the intermediate wall between the chambers liquid (4, 5), in that the side walls located axially outside the liquid chambers (4, 5) are formed by two other elastomer rings (12, 13) which project radially from the inner sleeve (9) and in that the wall located on the outside in the radial direction of the liquid chambers (4, 5) consists of a closure ring (7) provided with channels flow (6).   3. Rubber bearing according to one of claims 1 or 2,   characterized in that the radiant elastomer rings (12, 13) have soles reinforcement (14, 15).   4. Rubber bearing according to one of claims 2 to 3, characterized   in that the rubber pad (3) consists of a socket   intermediate (20) wrapped in an elastomeric material (21).   5. Rubber bearing according to one of claims 1 to 4, characterized   in that the casing sleeve (8) has a first section (22) for receiving the rubber pad (3) and is provided with a cutout (23) which   is connected to the rubber pad and which receives the hydraulic bearing (2).   6. Rubber bearing according to claim 5, characterized in that the casing sleeve (8) has at its end which surrounds the bearing   hydraulic (2) a stamped drawdown (24) of its edge.   7. Rubber bearing according to one of claims 1 to 6, characterized   in that on its side wall located in a liquid chamber (4, 5), at least one of the elastomer rings (11, 12, 13) has channels in hollow (25) oriented radially.   8. A rubber bearing according to claim 7, characterized in that the hollow channels (25) are arranged at regular intervals around the periphery of the side wall.   9. Rubber bearing according to one of claims 1 to 8, characterized   in that the elastomer rings (11, 12, 13) are connected to the collar (10)   resp. Ia inner sleeve (9) by vulcanization.   10. Rubber bearing according to one of claims 1 to 9,   characterized in that the rubber pad (3) is passed over the sleeve interior (9).   11. Rubber bearing according to one of claims 1 to 10,   characterized in that the rubber pad (3) and the hydraulic bearing (2) wind made in one piece.   12. Rubber bearing according to one of claims 1 to 11,   characterized in that the flow channels (6) are formed in the