STEERING SHAFT FOR A MOTOR VEHICLE

Abstract

A steering shaft for a motor vehicle has an inner shaft, arranged in an outer shaft that is displaceable axially in the direction of an axis of rotation. The inner shaft includes axially running radial projections on its outer side. The outer shaft includes axially running grooves on its inner side, into which grooves the projections of the inner shaft engage in a positively locking manner in a direction of rotation and displaceably in an axial direction. With regard to fault-free operation during fluctuating temperatures, on the inner shaft, there is arranged a profiled sleeve with undulating cross-sectional profile, the inner surface of which lies against the flanks of the projections of the inner shaft and the outer surfaces of which lie against the flanks of the grooves of the outer shaft, wherein the profiled sleeve is connected to the inner shaft at one or more fastening points.

Claims

1.-5. (canceled)

6. A steering shaft for a motor vehicle, comprising: an outer shaft; an inner shaft arranged in the outer shaft and configured so as to be displaceable axially along the direction of an axis of rotation; wherein the inner shaft includes axially running radial projections on an outer side thereof; wherein the outer shaft includes axially running grooves on an inner side therof, into which grooves the radial projections of the inner shaft engage in a positively locking manner in a direction of rotation and displaceably in an axial direction; wherein the inner shaft includes a profiled sleeve having an inner circumferential surface that lays against flanks of the radial projections of the inner shaft and the outer circumferential surface of which lies against flanks of the grooves of the outer shaft; and wherein the profiled sleeve is connected to the inner shaft by one or more fastening points distributed over a circumference of the profiled sleeve.

7. The steering shaft of claim 6, wherein the fastening points are formed by means of an ultrasound sonotrode.

8. The steering shaft of claim 6, wherein the projections of the inner shaft are equipped with a knurling on their radial outer side.

9. The steering shaft of claim 8, wherein the knurling is a criss-crossed knurling.

10. The steering shaft of claim 6, wherein the profiled sleeve is composed of plasti

Description

[0014] An exemplary embodiment of the invention will be discussed in more detail below on the basis of the drawings. In the figures, in detail:

[0015] FIG. 1 is a schematic perspective illustration of a steering system for a motor

[0016] FIG. 2 shows a two-part telescopic steering shaft according to the invention in a perspective view;

[0017] FIG. 3 shows a steering shaft according to the invention, composed of an outer shaft and of an inner shaft equipped with a profiled sleeve, in a perspective view;

[0018] FIG. 4 shows the steering shaft as per FIG. 3 before the mounting of the profiled sleeve;

[0019] FIG. 5 shows a cross section through a steering shaft according to the invention;

[0020] FIG. 6 shows a cross section through an inner shaft during the fastening of the profiled sleeve;

[0021] FIG. 7 shows an enlarged detail of an inner shaft with criss-crossed knurling; and

[0022] FIG. 8 shows an enlarged detail of an inner shaft with criss-crossed knurling as per FIG. 7.

[0023] FIG. 1 illustrates a motor vehicle steering system 100, wherein a driver inputs a steering moment as a steering command into a steering shaft 1 using a steering wheel 2. The steering moment is transmitted via the steering shaft 1 to a steering pinion 40, which meshes

[0024] with a toothed rack 5. The toothed rack 5 transmits a displacement of the track rods 6 to the steerable vehicle wheels 7. The steering shaft 1 comprises, at the input side, an input shaft 30 connected to the steering wheel 2 and comprises, at the output side, an output shaft 31 connected to the toothed rack 5 via the steering pinion 40. The input shaft 30 and the output shaft 31 are connected to one another in rotationally elastic fashion by means of a torsion bar which is not illustrated in FIG. 1. A steering moment input into the input shaft 30 by the driver using the steering wheel 2 leads to a relative rotation of the input shaft 30 with respect to the output shaft 31. This relative rotation between input shaft 30 and output shaft 31 can be determined by means of a rotational angle sensor.

[0025] The steering shaft 1 as per FIG. 1 furthermore comprises one or more cardanic joints 32, by means of which the profile of the steering shaft 1 in the motor vehicle can be adapted to the spatial conditions. The steering intermediate shaft of the steering shaft 1, which in the example illustrated is arranged between two cardanic joints 32, and which connects the output shaft 31 to the steering pinion 40 of the steering gear 101, is designed according to the invention as a variable-length steering shaft 2.

[0026] FIG. 2 shows a perspective view of the steering shaft 2 in an assembled state.

[0027] The steering shaft 3 comprises an inner shaft 8, which is arranged in telescopically displaceable fashion in an outer shaft 9. At their joint-side end, the inner shaft 8 and the outer shaft 9 each comprise a joint fork 320. In this way, a longitudinal adjustment of the steering wheel 2 is permitted even during installation and during driving operation.

[0028] As illustrated in FIGS. 3 to 5, the inner shaft 8 is, at its second end, in a defined region 80 on its outer circumferential surface, equipped with axially running radial projections 11 which are formed as an equidistant arcuate profile. The defined region 80 may be formed along the entire length of the inner shaft 8.

[0029] The outer shaft 9 is formed as a hollow shaft and is equipped, on its inner circumferential surface, with axially running grooves 12 into which the projections 11 of the inner shaft 8 engage, wherein the inner shaft 8 is connected in positively locking fashion in a rotational direction to the outer shaft 9 and can transmit the torques predefined by the driver using the steering wheel 2. In the example shown, the outer shaft also comprises, on its outer circumferential surface, axially running grooves 123 which are arranged at regular intervals as an equidistant arcuate profile 90. The arcuate profile 90 of the outer shaft 9 may be formed correspondingly to the arcuate profile of the inner shaft 8 along the entire length of the outer shaft 9, or only in a defined region 80.

[0030] A profiled sleeve 13 is fastened to the inner shaft 8 along the defined region 80. The profiled sleeve 13 may be designed to be shorter than or of equal length to the defined region 80. The profiled sleeve 13 comprises an undulating cross-sectional profile which lies closely against the radial projections 11, such that the inner circumferential surface of the profiled sleeve 13 is connected in positively locking fashion at least to the flanks 201 of the radial projections 11 or to the radial projections 11 of the inner shaft 8. After the connection to the inner shaft 8, the inner circumferential surface of the profiled sleeve 13 is connected fixedly to said inner shaft. The outer profile of the profiled sleeve 13 is designed correspondingly to the grooves 12 on the inner circumferential surface of the outer shaft 9.

[0031] In the assembled state of the steering shaft 3, the outer circumferential surface of the profiled sleeve 13 also lies against the grooves 12 and flanks 202 of the grooves 12 of the outer shaft 9, and thus forms a positively locking connection between inner shaft 11, profiled sleeve 13 and outer shaft 9, whereby a telescopic movement of the inner shaft 8 relative to the outer shaft 9 along an axis of rotation 10 is made possible. In this way, it is furthermore possible for torques to be transmitted between the inner shaft 8 and the outer shaft 9. The profiled sleeve 13, the inner shaft 8 and outer shaft 9 are, in the example, formed as an arcuate profile with an octagonal profile. This may furthermore be formed as a triangular or tetragonal or cloverleaf profile or hexagonal profile. The profiled sleeve 13 is firstly pushed onto the second end and positioned axially in the direction of the joint-side end along the defined region 80 on the walls 201 of the projections 11 or on the projections 11. Here, the sleeve 13 may be arranged centrally on the defined region 80 of the inner shaft 8, such that, on both sides, an equal spacing D1, D2 is provided to the end of the defined region 80. The spacing D1 may be shorter or longer than the spacing D2. Alternatively, the profiled sleeve 13 may comprise a spacing D1 in the direction of the joint-side end or a spacing D2 in the direction of the outer shaft 9. To permit an improved expansion or contraction of the profiled sleeve 13 in t

[0032] he presence of temperature fluctuations, the profiled sleeve 13 is connected to the inner shaft 8 only in punctiform fashion in the defined region 80. The connection may be realized by means of a single fastening point 14. It is however preferable for multiple fastening points 14, 15, 16 to be realized, which are arranged on a circle so as to be distributed over the circumference of the profiled sleeve 13 and of the inner shaft 8. In the specific exemplary embodiment in FIG. 5, three fastening points 14, 15, 16 are provided. By means of the arrangement of the fastening points 14, 15, 16 on a circle, it is ensured that all of the fastening points 14, 15, 16 are situated in the same axial portion of the profiled sleeve 13. It is hereby ensured that the occurrence of bulging or distortion of the profiled sleeve 13 when the latter expands or contracts owing to temperature fluctuations can be counteracted.

[0033] As shown in FIG. 6, the fastening points 14, 15, 16 are produced by means of an ultrasound sonotrode 17, by means of which the plastics material of the profiled sleeve 13 forms, by way of its inner circumferential surface, an intimate connection with the metallic surface of the inner shaft 8. For this purpose, the ultrasound sonotrode 17 is applied from the outside inward in the radial direction 18, and is removed again after the production of the respective fastening point 14, 15, 16.

[0034] It is alternatively possible for a punctiform connection to be provided between the outer circumferential surface of the profiled sleeve 13 and the walls 202 of the grooves 12 on the inner circumference of the outer shaft 9. The profiled sleeve 13 is firstly pushed fully into the outer shaft 9. When the profiled sleeve 13 no longer protrudes out of the outer shaft 9, the outer shaft 9 is connected to the profiled sleeve 13 at one or more fastening points 14, 15, 16.

[0035] In the enlarged illustration of FIG. 7 and FIG. 8, it is illustrated that the radial projections 11 of the inner shaft 8 are equipped with a criss-crossed knurling 20 on their radially outwardly pointing surface 19. As illustrated in FIG. 8, the knurling 20 is formed on the wall 201 of the inner shaft. By means of the criss-crossed knurling 20, the fastening of the profiled sleeve 13 to the inner shaft 8 is additionally improved, such that a reliable fastening remains ensured over the service life of the steering shaft 3.

LIST OF REFERENCE DESIGNATIONS

[0036] 1 Steering column [0037] 2 Steering wheel [0038] 3 Steering shaft [0039] 4 Steering gear [0040] 5 Toothed rack [0041] 6 Track rods [0042] 7 Vehicle wheel [0043] 8 Inner shaft [0044] 9 Outer shaft [0045] 10 Axis of rotation [0046] 11 Radial projections [0047] 12 Grooves [0048] 13 Profiled sleeve [0049] 14 Fastening point [0050] 15 Fastening point [0051] 16 Fastening point [0052] 17 Ultrasound sonotrode [0053] 18 Radial direction [0054] 19 Radially outer surface [0055] 20 Criss-crossed knurling