Steering triangle

Abstract

A steering triangle (1) is provided for the axle suspension of motor vehicles for the articulated connection of a vehicle axle with a vehicle chassis with two control arms (2, 3). The control arms are connected to each other in a joint housing (6) formed by the control arms (2, 3) together for a rubber-metal bearing (11) for fixing the steering triangle (1) on the vehicle axle. The rubber-metal bearing (11) has a pivot axis (12) provided with a spherical surface and an elastomer body (14), which extends around the pivot axis (12) at least in the area of the spherical surface and which is accommodated in a recess (16) located within the joint housing (6), in which steering triangle two pressing rings (17, 18) are arranged within the recess (16) of the joint housing (6) on the axial outer sides of the elastomer body (14). The pressing rings can be moved toward each other by a tensioning device via the intermediary of stop faces (22) of the joint housing (6). The stop faces are in contact with the outer sides of the pressing rings (17, 18), which outer sides face away from each other. The rubber-metal bearing can be pretensioned both in the axial direction and in the radial direction, so that stronger forces can be absorbed due to the higher rigidity achieved as a result.

Description

FIELD OF THE INVENTION

[0002] The present invention pertains to a steering triangle for the axle suspension of motor vehicles for the articulated connection of a vehicle axle with the vehicle chassis with two control arms, which are connected to each other in a joint housing formed together by the said control arms.

BACKGROUND OF THE INVENTION

[0003] Such steering triangles, which have been known from the state of the art, are used especially in utility vehicles. Thus, for example, a control arm for a motor vehicle wheel suspension has been known, which comprises a two-part arm body, wherein the two arm bodies form at one of their ends a common mount for a rubber-metal bearing, by means of which the control arm can be fixed at a wheel carrier or an axle. The opposite free ends are used for the body-side fixation of the steering triangle.

[0004] Such control arms are usually designed as forged or cast parts, and, when viewed in the top view, a relatively large area is required especially in the case of cast parts within the framework of the preparation of the casting molds, even though the mass of the two control arms proper is relatively small. The division of the steering triangle into two control arms, which may optionally have identical shape, offers a considerable cost advantage in this respect, which can also be felt favorably in the case in which the steering triangle is designed as a forged part, because a considerable reduction of the operations involved in the manufacture can be brought about due to the division into two parts.

[0005] However, the drawback of such control arms is that the rubber-metal bearing arranged within the central joint housing formed by the two control arms together provides for the pretension of the elastomer body responsible for the elastic mounting in the radial direction only due to its design. Since elastomer bodies can absorb, in general, only extremely low tensile stresses, the bearing described within the framework of the invention is hardly suitable for absorbing axial loads.

SUMMARY OF THE INVENTION

[0006] The object of the present invention is therefore to further improve a steering triangle of the type corresponding to this type such that the stresses occurring especially in utility vehicles can be absorbed to an increased extent by the central bearing of the steering triangle for the axle connected thereto.

[0007] This object is accomplished according to the present invention in that two pressing rings, which can be moved toward each other by a tensioning device via the intermediary of stop faces of the joint housing, which stop faces are in contact with the outer sides of the pressing rings, which said outer sides face away from each other, are arranged within the recess of the joint housing on the axial outer sides of the elastomer body. Due to this design according to the present invention, especially the elastomer body, which extends especially around the spherical surface of the pivot axis or pivot part, can be pretensioned not only in the radial direction, but also in the axial direction. This pretension is decisive for the rigidity of the elastomer body in the axial direction, the value of the rigidity being proportional to the capacity for absorbing axial forces that occur.

[0008] Another advantage of the present invention can be seen in the fact that due to the possibility of axial pretensioning, the rubber-metal bearing can be set for different requirements, whereas the rubber blend used for the elastomer body may have to be modified for different rigidities in conventional constructions known from the state of the art.

[0009] The pressing rings are preferably rigidly connected to the elastomer body, and this rigid connection may be embodied, e.g., by vulcanization/molding-on. The pretensioning in the axial direction is performed via the pressing rings.

[0010] Provisions are made according to an expedient variant for the tensioning device to have a plurality of tensioning screw connections, which are arranged in parallel to the pivot axis and are accommodated in through holes of the joint housing. The tensioning screw connections represent an inexpensive possibility of a simple design for pretensioning the pressing rings by screwing together the control arms in the area of the joint housing formed jointly with the necessary forces.

[0011] Sufficient tensioning forces are provided here, e.g., by three or more tensioning screw connections arranged coaxially around the central recess for the rubber-metal bearing.

[0012] To reduce the shearing forces appearing in the area of the central joint housing connection especially in the case of very great torsions of the two control arms in relation to one another and not to overload the tensioning screw connections located there, it proved, moreover, to be advantageous to provide at least one of the tensioning screw connections with a shearing sleeve, which is arranged within the through hole associated with the said tensioning screw connection and extends around the tensioning screw.

[0013] However, it is also possible to provide all tensioning screw connections with shearing sleeves which are arranged within the through holes and extend around the tensioning screws.

[0014] The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and specific objects attained by its uses, reference is made to the accompanying drawings and descriptive matter in which a preferred embodiment of the invention is illustrated.

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] FIG. 1 is a top view of a steering triangle according to an embodiment of the present invention; and

[0016] FIG. 2 is a sectional view of detail B from FIG. 1 in the area of the joint housing formed by the two control arms together.

DESCRIPTION OF THE PREFERRED EMBODIMENT

[0017] Referring to the drawings in particular, the steering triangle is designated in its entirety by 1 and is shown in FIG. 1. The steering triangle 1 has two control arms 2 and 3, which are mirror-symmetrical to each other. The control arm 2 has an end area 5 bent at an angle. The control arm 3 has an end area 4 bent at an angle. The two end areas 4 and 5 together form the joint housing 6. Due to the end areas 4 and 5 being bent at angles and the contact surfaces of the control arms 2 and 3 located in this area, the entire steering triangle 1 has an essentially V-shaped form when viewed in the horizontal projection. The steering triangle 1 has two end areas 7 and 8, which are used for fastening the steering triangle 1 to body-side mounts, which are not specifically shown here. The steering triangle 1 is fastened in an articulated manner by means of rubber-metal bearings 9 and 10. A rubber-metal bearing 11 establishes an articulated connection with a utility vehicle axle, which is fastened to the rubber-metal bearing. The utility vehicle axle is not specifically shown here. The rubber-metal bearing 11 is likewise accommodated in the joint housing 6 formed by the two control arms 2 and 3.

[0018] The special embodiment of the joint housing 6 with the rubber-metal bearing 11 located therein is shown in greater detail in FIG. 2. The rubber-metal bearing 11 contains a pivot part or pivot axis 12 with a spherical segment 13 arranged symmetrically with the ends of the pivot axis. The spherical segment 13 is surrounded by a one-part or multipart elastomer body 14, which is arranged via the intermediary of a sleeve 15 in a recess 16 of the joint housing 6 formed by the end areas of the control arms 2 and 3. Two pressing rings 17 and 18 are molded on the axial outer sides of the elastomer body 14 by vulcanization. The pressing rings 17 and 18 have a flange area 20 arranged essentially in parallel to the central longitudinal axis 19 of the pivot axis 12 as well as a flange area 21 projecting outwardly at right angles thereto. On the outer side of the flange area 21 facing away in the elastomer body 14, a stop face 22 of the joint housing 6 is in contact with the flange area.

[0019] As is additionally apparent from FIG. 2, the two control arms 2 and 3 of the steering triangle 1 are connected to each other via a tensioning device comprising a plurality of tensioning screw connections 23. At least one tensioning screw connection comprises a tensioning screw with a nut screwed on it as well as a shearing sleeve 24 surrounding the tensioning screw. The at least one tensioning screw connection 23 is arranged within a through hole 25 of the joint housing 6 with the shearing sleeve 24 extending around the tensioning screw. The screwing together of the tensioning screw connections 23 causes the rubber-metal bearing 9 inserted loosely into the recess 16 to be fixed both in the radial direction by the sleeve 15 and in the axial direction by the pressing rings 17 and 18, and forces of pressure are applied at the same time on the elastomer body 14. As a result of this a pretensioning of the component is brought about and, as a result of this, the rigidity of the elastomer body 14 is increased, so that forces of pressure applied by a movement of the pivot axis 12 on the elastomer body 14 can be absorbed without problems after the end of the installation.

[0020] It should be observed in this connection that the elastomer body 14 is fixed at the pivot axis 12 and at the pressing rings 17, 18 by means of a vulcanization process. The connection between the elastomer body 14 and the sleeve 15 is due only to corresponding frictional forces.

[0021] While a specific embodiment of the invention has been shown and described in detail to illustrate the application of the principles of the invention, it will be understood that the invention may be embodied otherwise without departing from such principles.

Claims

1. A steering triangle for the axle suspension of a motor vehicle for the articulated connection of a vehicle axle with a vehicle chassis, the steering triangle comprising: two control arms connected to each other to form a joint housing; a rubber-metal bearing for fixing said steering triangle to the vehicle axle, said rubber-metal bearing being connected to said two control arms at said joint housing, said rubber-metal bearing having a pivot axis provided with a spherical surface, and an elastomer body extending around said pivot axis at least in an area of said spherical surface, said elastomer body being accommodated in a recess located within said joint housing; two pressing rings; a tensioning device, said pressing rings being movable toward each other by said tensioning device via the intermediary of stop faces of said joint housing, said stop faces being in contact with outer sides of said pressing rings, said stop faces face away from each other and arranged within said recess of said joint housing on an axial outer sides of said elastomer body.

2. A steering triangle in accordance with claim 1, wherein said tensioning device has a plurality of tensioning screw connections arranged in parallel to said pivot axis and respectively accommodated in through holes of said joint housing.

3. A steering triangle in accordance with claim 2, wherein at least one of said tensioning screw connections is provided with a shearing sleeve arranged within said through hole associated with said one of said tensioning screw connections and extending around the tensioning screw.

4. A motor vehicle axle suspension steering triangle comprising: a first control arm; a second control arm connected to said first control arm, said first control arm and connected second control arm defining a joint housing with a bearing space having stop faces; a pivot part with a spherical surface portion; an elastomer body extending around a portion of said pivot part in an area of said spherical surface, said elastomer body being accommodated in said bearing space; a first pressing ring; a second pressing ring; a tensioning means for moving said pressing rings toward each other by said tensioning device via the intermediary of said stop faces of said joint housing, one of said stop faces being in contact with an outer side of said first pressing ring and another of said stop faces being in contact with an outer side of said second pressing ring.

5. A steering triangle in accordance with claim 4, wherein said tensioning means has a plurality of tensioning screw connections arranged in parallel to said pivot axis and respectively accommodated in through holes of said joint housing.

6. A steering triangle in accordance with claim 5, wherein at least one of said tensioning screw connections is provided with a shearing sleeve arranged within said through hole associated with said one of said tensioning screw connections and extending around the tensioning screw.