The invention relates to an outer tube of a steering shaft in a motor vehicle.
DE 10 2005 028 054 B3 describes a telescoping steering shaft, which is composed of a telescoping inner steering column part and a telescoping outer steering column part, wherein the inner part and the outer part must be pushed together. The outer part forms an outer tube, the inner part is an inner shaft that is axially displaceably guided in the outer tube. So as to enable the transmission of steering torque, the outer tube and inner shaft are typically positively coupled in the circumferential direction, which is achieved, for example, by mutually engaging ball grooves and elevations on the inside of the outer tube and on the outside of the inner shaft. These ball grooves and elevations extending in the axial direction allow for the outer tube and inner shaft to be both telescopically pushed into, and pulled away from, each other.
In the design of the outer tube, care must be taken to ensure a low weight, yet high torque transmission. In addition, the outer tube should be easy to produce.
It is the object of the invention to provide an outer tube of a steering shaft for a motor vehicle that is easy to produce and characterized by high torque transmission at a comparatively low weight.
The outer tube according to the invention is part of a steering shaft in a motor vehicle, with the steering shaft additionally comprising an inner shaft that is received in the outer tube, wherein the inner shaft and the outer tube can be telescopically displaced in relation to each other. In the direction of rotation, the outer tube and the inner shaft are positively coupled to each other so as to transmit a steering torque or torque. The positive engagement between the outer tube and the inner shaft located inside is achieved by radially mutually engaging ball grooves and elevations, which are configured on the outside of the inner shaft and on the inside of the outer tube. The ball grooves, for receiving balls, and the elevations cause a positive engagement in the circumferential direction, while the telescopic displaceability of the outer tube and inner shaft is not impaired in the axial or longitudinal direction by the form-fitting elements. The smooth translatory displaceability is decisively supported by the design of the ball bearing between the inner shaft and outer tube.
According to the invention, the outer tube has a varying wall thickness in the circumferential direction. Another characteristic of the outer tube is a circular envelope delimiting the outer casing, wherein radially recessed outside wall reduction sections are configured in segments on the outer casing, which have a reduced outside radius, in relation to the circular envelope. As viewed in the circumferential direction, these outside wall reduction sections adjoin circular segment-shaped ball groves on the inside of the outer tube, which represent the form-fitting elements. The outside wall reduction sections correspond to inside wall compensation sections configured at the same angular position, which are located on the inside of the outer tube and, as is analogous to the outside wall reduction sections, are likewise radially recessed.
This embodiment has numerous advantages. In particular, greater uniformity of the wall thickness of the outer tube is achieved, while transmitting maximum torque. In the central region between two ball grooves, distributed in the circumferential direction, the wall thickness of the outer tube is reduced on the inside wall and reinforced in the immediate vicinity of the ball groove. The reduced wall thickness results in significant weight reduction of the outer tube, without substantially lowering the rigidity or maximum torque transmission. Immediately adjacent to the ball grooves, the wall thickness of the outer tube, in contrast, is increased, whereby a comparatively strongly pronounced ball groove is achieved, for secure accommodation of the balls with good support in the circumferential direction. However, delimiting the wall thickness at this site, the outside wall reduction section having the reduced outside radius is provided on the outside, whereby the difference between the reduced wall thickness in the segment located between two ball grooves and in the immediate vicinity of each ball groove can be kept comparatively small. The circular segment shape of the ball grooves allows for planar guidance of the balls in the ball tracks under load.
The outer tube according to the invention takes all manufacturing engineering needs into consideration and constitutes an optimal solution with respect to the geometry. The almost round tube shape enables optimal torque transmission. Given the small differences in the wall thicknesses, the outer tube can be produced in one operation, whereby the high strain hardening required for the desired torque transmission is achieved. At the same time, sufficient core strength is obtained after heat treatment to prevent ball impressions under load. On the outside surface, the outer tube does not comprise any flutes; it rather has an approximately round and undulated shape, which has the advantage that, for welding, the outward heat-treated layer can be turned without the risk of severe weakening and the tube can also be automatically straightened during the manufacturing process.
The approximately round shape of the outer tube also allows for easy assembly by pushing the outer tube, for example, through the cab floor or the firewall of the vehicle using a round cab lead-through. In addition, the outer tube can be rotated directly in the cab lead-through.
The outer tube is optimized in terms of material use, and therefore has a low weight, despite maximum torque transmission. To improve the surface wear, it may be advantageous to heat treat the outer tube whereby, after high strain hardening, sufficient core strength is obtained to prevent ball impressions.
Radius changes both on the outside and on the inside of the outer tube are preferably done smoothly, for example by keeping the change in the outside radius and/or in the inside radius in the circumferential direction constant at least to the first derivative, and more preferably to the second derivative. The smooth radius transitions contribute to the prevention of stress peaks in the material of the outer tube.
The outer casing of the outer tube is advantageously radially recessed only in some segments, and more specifically in regions that immediately adjoin a ball groove on the inside wall of the outer tube in the circumferential direction. So as to prevent large differences in the wall thickness, the radius of the outer casing is reduced, for example, by no more than 10%, and more particularly by no more than 5%, in relation to the envelope in the region of the radially recessed outside wall reduction sections. Between the outside wall reduction sections and the regions between the two ball grooves, the wall thickness differs by no more than 25%, with any value up to 25% being possible. The radius of the inner casing between the inside wall compensation sections and the central regions, between two ball grooves, advantageously differs by no more than 20%, and more particularly by no more than 10%, and in this case any intermediate value up to the maximum limits should again be possible.
Further advantages and advantageous embodiments are disclosed in the remaining claims, the description of the figures, and the drawings.
In the figures, identical components are denoted by identical reference numerals.
As is apparent from the sectional view of the outer tube 2 according to
An outside wall reduction section 9 on the outside 6 corresponds to each inside wall compensation section 10 on the inside 7 of the outer tube 2. Compared in relation to an envelope 11 that is placed around the outer casing 6 (
The outside wall reduction sections 9, together with the corresponding inside wall compensation sections 10, cause the wall thickness to become more uniform. Compared to the standard wall thickness ws, the largest wall thickness wmax is reached in the region of the outside wall reduction section 9 or inside wall compensation section 10, and the smallest wall thickness wmin is reached in the region of the ball grooves 8. The transition between the standard wall thickness ws first to the maximum wall thickness wmax, and then to the minimal wall thickness wmin, in the circumferential direction, both on the outside of the outer tube, and on the inside, is continuous at least to the first derivative, and more preferably to the second derivative, whereby stress peaks in the material of the outer tube are prevented.
The outside wall reduction sections 9 have a radius rR, which is only slightly smaller than the outside radius ra, wherein the deviation preferably does not exceed 5%. In this way, the outer casing 6 substantially coincides with the envelope 11, and the outer casing thus has an approximately circular shape.
As is further apparent from
Given this geometry of the ball groove 8, a ball that is guided in the ball groove, as viewed in the circumferential direction of the ball groove cross- section, has a contact point in the region of each segment 8a and 8b. Under load, the ball surface adapts linearly to the radius of each segment 8a or 8b. However, under load, the lowest point of the ball groove 8, in the region of the intersection point of the two segments, or in the region of the bisector with the segments, remains without contact; at this point, the ball surface has no contact with the ball groove, whereby the rolling of the balls in the ball grooves is improved.
1 Steering shaft
2 Outer tube
3 Inner shaft
4 Joint
5 Joint
6 Outer casing
7 Inside
8 Ball groove
8
a,
8
b Segment
9 Outside wall reduction section
10 Inside wall compensation section
11 Envelope
12 Midline
Number | Date | Country | Kind |
---|---|---|---|
10 2008 041 155.8 | Aug 2008 | DE | national |
This is a Continuation Application of PCT/EP2009/005275 filed Jul. 21, 2009.
Number | Date | Country | |
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Parent | PCT/EP2009/005275 | Jul 2009 | US |
Child | 12931789 | US |