DE19853411A1 - Divided stabiliser especially for motor vehicles has external shape at one end of one part with outwardly inclined non-circular cone face axially tensioned into inner shape of second part - Google Patents

Abstract

The external shape (7) of one end of one stabiliser part (1) is formed by a non-circular conical face with a wedge surface (13) running inclined outwards relative to the swivel axis (4) of the stabiliser part. The two stabiliser parts are connected by a tension device such as a threaded bolt (9) which tensions the wedge face axially into the inner shape (8) on a further second stabiliser part. The conical face has two radially opposite wedge faces which are inclined axially outwards relative to each other.

Description

The invention relates to a divided stabilizer, with the in the preamble of the patent Claim 1 specified features.

Such a stabilizer in DE 43 37 771 A1 has two stabilizer parts, the can be pivoted in opposite directions by a hydraulic swivel motor or with opposite torques are resilient. For the rotationally fixed coupling of a Stabilizer part with a coupling element of the swivel motor is in the coupling element provided a fork-shaped receptacle into which a flattened end of the Stabilizer part insertable and via screw connections on the coupling ment can be clamped. When the stabilizer part is clamped, the coupling becomes mentally elastically deformed in some areas, whereby the stabilizer part is one of the predefined installation position can take a different position. With this attachment The forces causing a torque are transmitted near the axis of rotation gene, whereby the coupling element and the stabilizer part significantly stressed become. The connection of the stabilizer part with the coupling element is therefore for a high load on the stabilizer is not suitable.

The invention has for its object a split stabilizer with the Merk paint specify in the preamble of claim 1, in which two Stabilisa Gate parts are connected so that the stabilizer can also transmit high torques can and for the connection of the two stabilizer parts only a small construction space is required.

This object is achieved by the features specified in claim 1. Advantageous embodiments of the invention can be found in the subclaims.

Six exemplary embodiments of the invention are illustrated by a drawing explained. Show it

Fig. 1 shows a first embodiment with a conical surface, which is formed by two opposed wedge surfaces,

Fig. 2 shows a second embodiment with a wedge surface,

Fig. 3 is a cross section through the wedge surfaces in Fig. 1,

Fig. 4 shows a third embodiment having six wedge-shaped surfaces,

Fig. 5 shows a fourth embodiment in which forms the conical surface of a truncated cone-shaped polygonal surface,

Fig. 6 shows a fifth embodiment with a bevel gear and

Fig. 7 shows a sixth embodiment in which the conical surface has a Torx profile known from screw heads in cross section.

The stabilizer shown in simplified form in FIG. 1 according to a first exemplary embodiment has two separate stabilizer parts 1 , 2 which are supported on an axle of a motor vehicle and which do not form or carry stabilizer legs, not shown, either directly or via pendulum supports on an associated wheel carrier or are articulated on a wheel guide element. The two stabilizer parts 1 , 2 can be rotated in opposite directions by means of a swivel motor 3, which is shown in simplified form, and can optionally be activated in such a way that the two stabilizer parts 1 , 2 are completely or largely decoupled from one another. The two stabilizer parts can have a round or any un round circumference and can be rotated electrically, hydraulically or pneumatically by the swivel motor 3 around the swivel axis 4 . For the rotationally fixed connec tion of a stabilizer part 1 with a rotatable by the swivel motor 3 coupling element 5 , the swivel motor 3 facing end 6 of the stabilizer part 1 is made with an outer shape 7 which has an axially tapering to the swivel motor 3 conical surface. The coupling element 5 has an inner shape 8 adapted to the outer shape 7 of the stabilizer part 1 . From the tapered end face of the stabilizer part 1 , a threaded bolt 9 protrudes axially, which penetrates a passage opening 10 in the coupling element 5 after the outer mold 7 has been inserted into the inner mold 8 . In this position, the end 11 of the thread pin 9 protrudes inward in a free space from the passage opening 10 . A threaded nut 12 is screwed onto the end 11 , which brings about an axial force on the stabilizer part 1 which loads the outer shape 7 into the inner shape.

The other embodiments only have a different outer shape of the stabilizer part and an adapted other inner shape of the coupling element, so that to avoid a repeated description in the exemplary embodiments, identical or comparable parts with the same reference number and possibly for better differentiation with a superscript character are seen. In Figs. 2 to 7, only the cross-sectional shapes of the conical surface respectively used in the further embodiments are illustrated.

In the second embodiment shown in FIG. 2, the conical surface of the stabilizer part 1 ^I a wedge surface 13 which is preferably formed flat, may be curved but also any concave or convex.

In Fig. 3 is a cross section through the cone surface of the stabilizer part 1 used in Fig. 1, the symmetrically opposite formed two wedge surfaces 13, 13 has ^I.

In the third embodiment according to FIG. 4, the conical surface of the stabilizer gate part 1 ^{II is formed} by six cone surfaces 13 ^II , 13 ^III , 13 ^IV , 13 ^V , 13 ^VI , 13 ^VII evenly distributed over the circumference, so that the cross section of the stabilizer part 1 ^II forms a regular hexagon in the area of the cone surface.

A fourth, in Fig. 5 shown embodiment, to the stabilizer 1 ^III in a cone surface which is formed by a frustoconical surface 14 polygon having rounded corners in the present embodiment three. The polygon surface could also have a different, predeterminable number of rounded or pointed corners.

In FIG. 6, a fifth embodiment is shown in which the stabilizer part is formed a spur bevel gear 15 1 ^IV at the periphery of the conical surface. The bevel gear could also be designed with helical teeth.

A sixth exemplary embodiment according to FIG. 7 has a cross section in the region of the conical surface of the stabilizer part 1 ^V , which forms a known Torx profile 16 on the outer circumference, for example of screw heads.

In the exemplary embodiments, it was assumed that the stabilizer parts are made of a rod material that has a cylindrical outer surface points. Likewise, the stabilizer parts or some of them can have a non-circular exterior Have shape and for example not be made from a rod material. An the outer shape of the stabilizer part in question in the inner shape of the coupling Axial clamping force loading element can also in other ways, for example as a radially protruding collar on the stabilizer part in question take place, which has openings for a passage of fasteners, which cause an axial clamping force. The stabilizers or stabilizer halves are resilient with high torques and can be made from a hardened or hard material, for example made of spring steel. The assembly of the Stabilizer can be done with low forces and is the required space low. Incorrect assembly is prevented by the non-round conical surface. The cone surface can be forged, sintered, cold formed or with the help of machining machine be manufactured. The stabilizer part is play in all versions freely and non-rotatably connected to the other stabilizer part, which any Stabilizer part can be. Those taken separately in the exemplary embodiments Measures can also be overlaid.

Claims (10)

1. Split stabilizer, which has an outer shape at one end of a stabilizer part, which can be inserted into an adapted inner shape on a further stabilizer part in an assembly position in which a tensioning device connects the two stabilizer parts, characterized in that the outer shape ( 7 ) by an out-of-round cone surface with a wedge surface ( 13 , 13 ^I , 13 ^II , 13 ^III , 13 ^IV) that extends obliquely to the pivot axis ( 4 ) of the stabilizer part ( 1 , 1 ^I , 1 ^II , 1 ^III , 1 ^IV , 1 ^V ), 13 ^V , 13 ^VI , 13 ^VII , polygonal surface 14 , bevel gearing 15 , Torx profile 16 ) is formed and the clamping device (threaded bolt 9 , threaded nut 12 ) the wedge surface ( 13 , 13 ^I , 13 ^II , 13 ^III , 13 ^IV , 13 ^V , 13 ^VI , 13 ^VII , polygonal surface 14 , bevel gear 15 , Torx profile 16 ) axially into the inner shape ( 8 ). 2. Split stabilizer according to claim 1, characterized in that the conical surface has two radially opposite wedge surfaces ( 13 , 13 ^I ) which are inclined axially outwards to one another. 3. Split stabilizer according to claim 1 or 2, characterized in that the conical surface has a plurality of wedge surfaces ( 13 ^II , 13 ^III , 13 ^IV , 13 ^V , 13 ^VI , 13 ^VII ) which are arranged regularly or irregularly. 4. Split stabilizer according to claim 1, characterized in that the conical surface is formed by a frustoconical polygon surface ( 14 ). 5. Split stabilizer according to claim 4, characterized in that the polygon surface ( 14 ) has a predetermined number of corners which are pointed or rounded. 6. Split stabilizer according to one of claims 1 to 5, characterized in that the conical surface has a spur or helical bevel ( 15 ) with radially projecting teeth. 7. Split stabilizer according to one of claims 1 to 6, characterized in that the conical surface has a circumference with a known Torx profile ( 16 ), for example, from force application surfaces on screw heads. 8. Split stabilizer according to one of claims 1 to 7, characterized in that the further stabilizer part is a motor-rotatable coupling element ( 5 ) of a swivel motor ( 3 ), the two stabilizer parts connected with stabilizer arms ( 1 , 2 ) rotate in opposite directions or with one opposite torque load. 9. Split stabilizer according to one of claims 1 to 8, characterized in that the tensioning device axially projecting from the end of the outer shape ( 7 ) having the stabilizer part ( 1 , 1 ^I , 1 ^II , 1 ^III , 1 ^IV , 1 ^V ) Ge threaded bolt ( 9 ) which passes through a passage opening ( 10 ) in the coupling part ( 5 ) of the swivel motor ( 3 ) and has an end ( 11 ) projecting from the passage opening ( 10 ) onto which a threaded nut ( 12 ) can be screwed, which causes an axial force on the stabilizer part ( 1 , 1 ^I , 1 ^II , 1 ^III , 1 ^IV , 1 ^V ) loading the outer shape ( 7 ) into the inner shape ( 8 ). 10. Split stabilizer according to one of claims 1 to 9, characterized records that the clamping device has a radially projecting collar or Has flange on a stabilizer part, the fastener with a mating surface of the further stabilizer part is to be connected, the one cause axial loading of the outer shape into the inner shape.