The invention relates to a longitudinal plunging unit for the transmission of torque between two parts which are axially displaceable relative to one another and which comprise a profiled journal with first circumferentially distributed, longitudinally extending ball grooves, a profiled sleeve with second circumferentially distributed, longitudinally extending ball grooves, balls which are arranged in groups of pairs of first and second ball grooves and a ball cage which is arranged between the profiled journal and the profiled sleeve and fixes the balls in their positions relative to one another.
Such longitudinal plunging units are used particularly in driveshafts in the driveline of a motor vehicle, as is known from DE 196 09 423 A1 for example. To compensate for tolerances regarding the distance between two attaching parts of the driveshaft during assembly and/or to compensate for changes in the distance between the attaching parts during operation, it must be possible to achieve a low-friction length adjustment under torque load.
The problem under operational conditions is that, under torque-free conditions at the longitudinal plunging unit, the ball cage—as a result of vibrations, axial impacts or weight forces—quickly abuts its axial end stops. In such a case, there is no need for a rolling movement of the balls. If subsequently, the longitudinal plunging unit is again torque-loaded and if, thereafter, there is a need for length adjusting movements, there occur sliding movements at the balls, with the ball cage resting against the end stop. This increases the displacement forces and the degree of wear and can lead to noise, vibration, harshness (NVH) problems which have an adverse effect on the driving comfort.
From U.S. Pat. No. 4,705,491, there is known a longitudinal plunging unit for transmitting torque which comprises a plurality of rows of balls arranged in a ball cage, wherein the balls of a row of balls consist of an elastic material and are radially pretensioned in the associated ball grooves.
U.S. Pat. No. 6,343,993 describes a similar longitudinal plunging unit wherein the balls are radially pretensioned by elastic elements.
DE 18 00 996 U proposes a longitudinal plunging unit for transmitting torque wherein the balls of one row of balls have a greater diameter than those of the other rows of balls.
U.S. Pat. No. 6,902,487 proposes a longitudinal plunging unit wherein the ball cage, in addition to the torque transmitting balls, holds rolling members made of a elastic material between the profiled sleeve and the profiled journal in such a way that they are able to roll. The rolling members are radially pretensioned and, during the transmission of torque, remain largely free from circumferential forces.
It is an object of the present invention to provide a longitudinal plunging unit of the initially mentioned type which has a simple design and wherein the ball cage retains its position when in a torque-free condition.
In accordance with an embodiment of the invention, a longitudinal plunging unit for transmitting torque in a drive assembly is provided, comprising: a profiled sleeve with circumferentially distributed, longitudinally extending first ball grooves; a profiled journal with circumferentially distributed, longitudinally extending second ball grooves; balls which are arranged in groups of pairs of first and second ball grooves; a ball cage which is arranged between the profiled sleeve and the profiled journal and fixes the balls in their positions relative to one another; and a spring mechanism which is supported on at least one axial stop and designed in such a way that, in an unloaded condition, the ball cage is held at a distance from the at least one axial stop.
This assembly is advantageous in that it ensures that the ball cage is always held in its operating position. The use of springs prevents the ball cage—due to vibrations for example—from moving to one of the axial stops. A rolling displacement between the balls and the profiled journal and profiled sleeve respectively is always ensured. The displacement forces are minimized and any noise, vibration, harshness (NVH) problems are avoided.
According to one embodiment, the spring mechanism comprises a first spring which is arranged between the ball cage and the at least one axial stop. Using only one spring is advantageous in those applications where cage wandering occurs in one direction only. In addition, the spring mechanism can also comprise two springs which are supported on a second axial stop, with the first axial stop and the second axial stop being arranged at opposed ends of the ball cage. In this way it is ensured that the ball cage can be axially loaded from both ends and can be held in a central operating position.
According to a further embodiment, both the first and the second axial stop are formed at the profiled journal. Alternatively, the first and the second axial stop can also be formed at the profiled sleeve. According to a further embodiment, the first axial stop is associated with the profiled journal and the second axial stop is associated with the profiled sleeve. The axial stop associated with the profiled journal can be arranged at the end which enters the profiled sleeve. The axial stop associated with the profiled sleeve can be arranged at the end facing the aperture end. This embodiment wherein the axial stop arranged at the shaft end is associated with the profiled journal and wherein the axial stop facing the aperture end is associated with the profiled sleeve is advantageous in that there is formed an extraction stop for the profiled journal relative to the profiled sleeve. The profiled journal, in the extracted position, is supported via the first axial stop, the first spring and the ball cage and the second spring is supported against the second axial stop. The profiled journal is therefore prevented from unintentionally sliding out of the profiled sleeve, for instance during assembly.
According to another embodiment, the at least one axial stop is provided in the form of a securing ring which is axially fixed to the profiled sleeve and profiled hub respectively. This can be achieved, for example, by means of a securing ring which engages a suitably shaped annular groove, and it is advantageous to provide the annular groove in a region outside the ball grooves in order to carry out the turning operation in an uninterrupted cut. Alternatively or in addition to using a securing ring, at least one of the first and second axial stops can be provided in the form of a stop sleeve which is axially supported relative to the profiled sleeve or the profiled journal.
According to a further embodiment, the first and the second spring are pretensioned. In this way, the ball cage is prevented from moving loosely between the springs due to vibrations, On the contrary, the ball cage is held in a defined operating position. The first and the second spring can have different or identical lengths. Identical lengths are advantageous in that the ball cage is held symmetrically between the two axial stops. Different spring lengths are advantageous in certain applications where an asymmetrical position is desirable. The first spring and/or the second spring is preferably provided in the form of a helical spring which can be produced in a simple and cost-effective way.
According to yet another embodiment the first spring and/or the second spring has a greatest outer diameter which is smaller than a smallest inner diameter of the profiled sleeve in the region of the ball grooves. Furthermore, the first spring and/or the second spring has a smallest inner diameter which is greater than the greatest outer diameter of the profiled journal in the region of the ball grooves. As a result of this design, the springs can be freely axially displaced relative to the profiled sleeve and the profiled journal.
The first spring and/or the second spring can be arranged loosely between the ball cage and the axial stops, or, alternatively, it can be firmly connected to the ball cage. A firm connection of the ball cage to the spring on the one hand and of the spring to the axial stop on the other hand is advisable more particularly when using only one spring which can be tension or pressure-loaded without the ball cage moving out of its central position.
To prevent the ball cage from moving in operation, in addition to the spring, one group of balls positioned in a common radial plane comprises a greater diameter than the balls of the remaining groups of balls. In this way, the play between the profiled journal and the profiled sleeve is minimized and there is generated a slight pressure which prevents the ball cage from moving. Alternatively, it is proposed that at least one of the ball grooves of one of the two displaceable parts, i. e. the profiled sleeve or the profiled journal, is arranged outside the region of the regularly distributed remaining ball grooves, wherein the ball grooves of the other one of the two displaceable parts are regularly distributed across the circumference. In this way, too, there is generated a slight pressure which prevents the ball cage from moving when in operation.
Preferred embodiments will be explained below with reference to the drawings wherein
FIGS. 1 to 7 will initially be described jointly below. They each show a longitudinal plunging unit for the transmission of torque in a shaft assembly comprising a profiled journal 11 with first ball grooves 12 and a profiled sleeve 21 with second ball grooves 22. The ball grooves 12, 22 are arranged in corresponding circumferential positions, and the number of first ball grooves 12 can amount to a multiple of the number of second ball grooves 22. The first and second gall grooves 12, 22 arranged opposite one another carry balls 31 which are arranged in groups and which are held by a sleeve-shaped ball cage 41 in a way in which they cannot be lost and in identical axial arrangements.
The profiled journal 11 comprises an attaching end 13 with shaft teeth 14 for transmitting torque to an inner joint part of a constant velocity joint (not illustrated). The inner joint part is axially fixed by a securing ring which engages an annular groove 15 at the attaching end 13. The profiled sleeve 21 comprises an aperture 23 into which the profiled journal 11 is inserted by means of its end 16 which faces the shaft. In the aperture 23, a securing ring 27 is inserted into a matching annular groove, and when the profiled journal 11 is extracted from the profiled sleeve 21, the ball cage 41 is able to indirectly abut said securing ring 27. In this way, the profiled journal 11 is prevented from leaving the profiled sleeve 21, for example when being handled or mounted. However, in principle, it is possible to do without the securing ring 27 which prevents the profile journal from leaving the profiled sleeve. At its end opposite the aperture 23, the profiled sleeve 21 comprises an attaching end 24 with shaft teeth 25 for mounting a constant velocity joint (not shown) in a rotationally fast way. Said constant velocity joint is axially fixed by a securing ring which engages the annular groove 26.
In order to prevent the ball cage 41 from moving against one of the axial stops 42, 43 when in operation, thus preventing a rolling displacement of the torque transmitting balls 31, there is provided a spring mechanism 51 which holds the ball cage 41 in a central position. The spring mechanism 51 according to the embodiments according to FIGS. 1 to 5 comprises a first spring 52 which is arranged in such a way that a movement of the ball cage 41 towards the attaching end 24 of the profiled sleeve 21 is braked, as well as a second spring 53 which is arranged in such a way that a movement of the ball cage 41 towards the attaching end 13 of the profiled journal 11 is braked. The two springs 52, 53 are provided in the form of helical springs, with the radial tolerances being selected to be such that the springs 52, 53 are positioned between the profiled sleeve 21 and the profiled journal 11 with radial play and are thus axially freely movable.
In each of the embodiments, the first spring 52 and/or the second spring 53 can have a greatest outer diameter which is smaller than a smallest inner diameter of the profiled sleeve 21 in the region of the ball groves 22. Furthermore, the first spring 52 and/or the second spring 53 can have a smallest inner diameter which is greater than the greatest outer diameter of the profiled journal 11 in the region of the ball grooves 12. As a result of this design, the springs 52, 53 can be freely axially displaced relative to the profiled sleeve 21 and the profiled journal 11. The first spring 52 and/or the second spring 53 can also be arranged loosely between the ball cage 41 and the axial stops, or, alternatively, it can be firmly connected to the ball cage 41.
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Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP04/12312 | 10/29/2004 | WO | 4/6/2006 |