Patent Document

BACKGROUND OF THE INVENTION 
     Description 
     The invention relates to a constant velocity universal joint for transmitting torque, having an outer joint part with outer ball tracks, an inner joint part with inner ball tracks, torque transmitting balls guided by pairs of outer and inner ball tracks positioned in corresponding meridian planes, and a ball cage which lodges the balls in circumferentially distributed windows and holds the balls in a common plane and guides the balls on to the angle-bisect-ing plane when the joint is articulated, with the center lines of the outer and inner ball tracks being composed of at least two differently curved portions adjoining one another. 
     Joints of this type are known as Rzeppa fixed joints (RF) or undercut-free fixed joints (UF). The latter are described in DE-PS 22 52 827. For a certain size of such joints, and especially as regards the axial length of such joints, there exists a mutual interdependence between the maximum articulation angle and the thickness of the shaft to be connected to the inner joint part. On the one hand, the articulation angle is limited in that the balls must be prevented from leaving the track ends, or, to be more precise, as far as edge loads at the track ends are concerned, it has to be ensured that there exists a sufficient safety distance between the point of contact of the ball in the track and the track end edge. Furthermore, the articulation angle is limited by the thickness of the connecting shaft which, upon articulation of the inner joint part, abuts against an inner cone of the outer joint part and thus prevents further articulation. It makes sense to adapt the thickness of the connecting shaft and the shape and position of the inner cone to one another in such a way that said abutment of the connecting shaft coincides with the safety distance between the point of contact of the ball and the track end edge. 
     Developments in automotive engineering are such that said constant velocity universal joints are expected to have an ever increasing performance, which means that with a predetermined available space and mass, the service life and functional scope have to be increased, or, vice versa, with a predetermined service and functional scope, space and mass have to be reduced. 
     With prior art joint designs, any improvements on the one side, for example in respect of the articulation angle, can only be achieved by shortening the service life and reducing the breaking strength. 
     SUMMARY OF THE INVENTION 
     It is the object of the present invention to provide a joint of the initially mentioned type whose performance is improved in such a way that space and mass can be reduced without adversely affecting the remaining parameters. 
     In accordance with the invention, the objective is achieved in that the center lines S of the ball tracks of the outer joint part each comprise convexly curved inner portions S 1  and, towards the open end, oppositely curved concave first end portions S 2  and that the center lines of the ball tracks of the inner joint part each comprise curved outer portions and, towards the base end of the outer joint part, oppositely curved, second end portions wherein the inner portions S 1  and the outer portions each extend in a curved way around a center Z 1  inside the outer joint part, and the first end portions S 2  and the second end portions each extend in a curved way around a center Z 2  outside the outer joint part. This means that the inner portions S 1  extend at least partially in a curved way around a joint center C and that the first end portions S 2  positioned towards the open end are curved in the opposite direction, i.e. outwardly. In general, the result is that the distance of the center lines of the ball tracks in the outer joint part from the axis A A  in the first end portions S 2  increases towards the open end of the outer joint part. 
     The shape of the outer joint part is hence characterised in that the ends of the ball tracks widen and radially move away from one another towards the open end of the outer joint part. 
     Preferred embodiments of the invention are described in further sub-claims to which special reference is hereby made. 
     Due to general conditions of symmetry, the ball tracks in the inner joint part widen and move away from one another in an end portion at the axially opposite end, i.e. towards the base of the outer joint part, again with reference to the center lines of the ball tracks whose distance from the axis A I  of the inner joint part is thus greatest at said end. 
     In accordance with certain lines of curvature, said first end portions S 2  can extend as circular arcs for example, but the end portions of the tracks can also extend in straight lines at an angle relative to the longitudinal axis A A . 
     The effect achieved by the track shape in accordance with the invention consists in that—in contrast to joints in accordance with the state of the art wherein the points of contact of the balls in the tracks are positioned approximately in radial planes extending through the respective centers of the balls—there is achieved an axial distance between the points of contact of the balls in the tracks with reference to the radial planes through the joint centers, with the points of contact being offset towards the central joint plane. In this way, it is possible to achieve improvements regarding the relationships of the parameters of joint length/joint mass, maximum articulation angle and thickness of the connecting shaft. As far as further explanations of the inventive measures and effects are concerend, reference has to be made to the following drawings. In the embodiment illustrated, the inventive joint is shown as a UF joint. However, to put the technical teaching in accordance with the invention into effect, it is not necessary for the ball tracks to be undercut-free. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows a longitudinal section of an undercut-free constant velocity universal joint (UF joint) according to the state of the art. 
     FIG. 2 shows a track run-out of the outer joint part of the joint according to FIG.  1 . 
     FIG. 3 shows the outer joint part of the joint according to FIG. 1 with an articulated connecting shaft. 
     FIG. 4 shows a longitudinal section of an inventive constant velocity universal joint with undercut-free tracks (UF joint). 
     FIG. 5 shows a track run-out of the outer joint part of the joint according to FIG.  4 . 
     FIG. 6 shows the outer joint part of the joint according to FIG. 4 with an articulated connecting shaft. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     FIG. 1 shows a prior art constant velocity universal joint which comprises an outer joint part  11 , and inner joint part  12 , torque transmitting balls  13  and a ball cage  14 . AT one end, the outer joint part  11  is closed by a base  15  which is followed by a joint journal  16 . An aperture  17  of the outer joint part  11  is provided axially opposite the base  15 . In the outer joint part  11 , there is shown one of a plurality of circumferentially distributed outer ball tracks  18  which, if viewed from the open end  17 , is undercut-free and has a center line S a . The inner joint part  12  is provided with a central aperture  19  into which there is inserted a connecting shaft  20  which is axially secured by a securing ring  32 . In the inner joint part  12 , there is shown one of a plurality of circumferentially distributed inner ball tracks  22  which is also undercut-free if viewed from the open end  17  and has a center line S i . Outer ball tracks  18  and inner ball tracks  22  are associated with one another in pairs and jointly accommodate in pairs the torque transmitting balls  13 . The balls  13  are jointly held in one plane by the ball cage  14  in that the balls are inserted into the cage windows  23  in the central cage plane which coincides with the central joint plane E. The ball track center lines S i , S a  are parallel to the respective ball track ground lines. Both center lines S i , S a  are symmetrical to one another with respect to plane E. 
     The central joint plane E also contains the joint center C which is defined by the point of intersection of the axes A A , A I  of the outer joint part and inner joint part when the joint is articulated. At the open end  17  of the outer joint part l, there is provided an inner cone  24  which forms a stop for the connecting shaft  20  of the inner joint part  12  when the joint is articulated and thus limits the articulation angle β of the joint, as described below. 
     FIG. 2 shows the outer joint part  11  with an outer ball track  18  in a broken-away manner. Said inner cone  24  which cuts off the outer ball track  18  at the open end  17  is still visible. Furthermore, there is shown a ball  13  in the ball track  18  in a position which is assumed by the ball  13  when the inner joint part is articulated by its maximum amount relative to the outer joint part. In this case, the maximum articulation angle β between the axes, which will again be referred to below, leads to an articulation angle of the cage relative to the outer joint part of β/2 which is shown in the drawing. By correspondingly articulating the central plane of the cage relative to the central joint plane E, the ball  13 , too, is moved out of the central joint plane E by the angle β/2. The center M of the balls follows the dash-dotted central line of the outer ball track  18  which is defined by a circular arc S a  with the radius R 1  whose center Z on the axis A A  is offset by the offset O 1  relative to the central joint plane E, and by a straight lien G following same tangentially and extending parallel to the axis A A . In the ball position as illustrated, the contact point B of the ball in the outer ball track  18  is positioned in a radial plane through the ball center M. Relative to the track end edge defined by the inner cone  24 , the contact point B is at a minimum axial distance L which, in view of possible edge breakages at the track end, must not be allowed to be reduced. The distance between the contact point B and the central joint plane E has been given the reference number N. 
     FIG. 3 shows the above-mentioned joint articulation angle β between the axis A A  of the outer joint part  11  and the axis A I  of the inner joint part  11  in the joint center C. In this case, the connecting shaft  20  replaces the inner joint part; in this position, it comes to rest against the inner cone  24 . By thus limiting the degree of articulation to the angle β, the minimum distance L between the contact point B and the track end edge of the ball track  18  is ensured. 
     FIG. 4 shows an inventive constant velocity universal joint which comprises an outer joint part  31 , an inner joint part  32 , torque transmitting balls  33  and a ball cage  34 . At one end, the outer joint part  31  is closed by a base  35  which is followed by a joint journal  36 . An aperture  37  of the outer joint part  31  is provided axially opposite the base  35 . In the outer joint part  31 , there is shown one of a plurality of circumferentially distributed outer ball tracks  38  which, if viewed from the open end  37 , are undercut-free, without this being absolutely essential. The inner joint part  32  is provided with a central aperture  39  into which there is inserted a connecting shaft  40  which is axially secured by a securing ring  41 . In the inner joint part  32 , there is shown one of a plurality of circumferentially distributed inner ball tracks  42  which, with reference to the central joint plane E, extends symmetrically relative to the outer ball track and—if viewed from the open end  37 —is undercut-free. Outer ball tracks  38  having center lines S a  and inner ball tracks  42  having center lines S i  are associated with one another in pairs and jointly accommodate the torque transmitting balls  33 , wherein each ball is held in the point of intersection of the associated center lines S a , S i . The balls  33  are inserted into cage windows  43  in the central plane of a ball cage  34 , which coincides with the central plane E of the joint, and are jointly held in one plane by the ball cage  34 . The central joint plane E also contains the joint center C which is defined by the point of intersection of the axes A A , A I  of the outer joint part and inner joint part when the joint is articulated. In the outer joint part, on the side of the open end  37 , there is provided an inner cone  44  which can form a stop for the connecting shaft  40  when the joint is articulated. The center lines S a , S i  of the ball tracks  38 ,  42  which extend parallel to the respective track base and which intersect one another in the center of the ball  33  comprise turning points T 1 , T 2 . It is an important aspect that the outer ball tracks  38 , towards the open end  37 , move away from the longitudinal axis A A , for example in that a center of curvature of the end portion of the center line S a  of the outer ball track  38  is positioned outside the outer joint part  31  and said center line S a  respectively. Accordingly, the inner ball tracks  42 , towards the base end  35 , move away from the longitudinal axis A I  in that the center of curvature of the end portion of the center line S i  of the inner ball track  42  is positioned outside the inner joint part  32  and said center line S i  respectively. The center lines S a , S i  are each composed of at least two differently curved portions adjoining one another, to be described more detailed with reference to FIGS. 5 and 6. 
     FIG. 5 shows the outer joint part  31  with the outer ball tracks  38  in a broken away manner. It is possible to see said inner cone  44  which cuts off the outer track base  38  at the open end  38 . Furthermore, the ball  33  of the ball track  38  is shown in the position which it assumes when the inner joint part is articulated relative to the outer joint part by the unchanged joint articulation angle β. The joint articulation angle β between the axes, which will be referred to below, leads to an articulation angle of the cage relative to the outer joint part of β/2 which is shown in the drawing. With the central plane of the cage being articulated accordingly relative to the central joint plane E, the ball  33 , too, is moved out of the central joint plane E by the angle β/2 into the angle bisecting plane W. The center M of the ball follows the dash-dotted central line S a  of the outer ball track  38  which is defined by a first circular arc S 1  with the radius R 1  whose center Z 1  on the axis A A  is offset by the offset O z1  relative tot eh central joint plane E, and by an adjoining second circular arc S 2  with the radius R 2  which is less than the radius R 1  and whose center Z 2  on a straight line extending outside the joint at a distance O Y2  from the longitudinal axis A A  is offset by the offset O Z2  relative to the central joint plane E. The first end portion S 2  of the center line S a  continuously adjoins the inner portion S 1  of the center line S a  in a turning point T 1.2  respectively. Tangents on the center line S a  are axis-parallel in the respective turning points T 1.2 . The inner portion S 1  of the ball tracks  38  in the outer joint part  31  extend by 10° beyond the central joint plane E towards the open end  37  of the outer joint part  31 . 
     With the articulation angle β assumed to be unchanged, the ball center M is slightly displaced towards the central joint plane E. On the other hand, the contact point B of the ball  33  at the outer ball track has moved behind the ball center M back to the central joint plane E and also radially outwards. As a result, the distance N* of the contact point B from the central joint plane becomes smaller as compared to the earlier distance N, as shown in FIG.  6 . This means that by maintaining the minimum axial distance L of the contact point from the track and edge, the position of the inner cone  44  can be displaced towards the base  15 , i.e. the outer joint part has been shortened. 
     FIG. 6 shows the above-mentioned joint articulation angle β between the axis A A  of the outer joint part  31  and the axis A I  of the inner joint part  32 . In FIG. 6, the inner joint part is replaced by the connecting shaft  40  which, in this position, as already mentioned, is positioned at a distance from the inner cone  44  as a result of the displacement of the latter. In consquence, it becomes possible, without changing the articulation angle β, to increase the thickness of the connecting shaft  40  in order to increase the torque transmitting capacity. If, in deviating from the illustration, the position of the inner cone is slightly changed while retaining the thickness of the connecting shaft, and while maintaining an adequate safety distance L of the contact point B from the end of the ball track, the articulation angle β can be increased. 
     Constant Velocity Universal Joint 
     List of Reference Numbers 
       11 ,  31  outer joint part 
       12 ,  32  inner joint part 
       13 ,  33  ball 
       14 ,  34  ball cage 
       15 ,  35  base 
       16 ,  36  joint journal 
       17 ,  37  joint aperture 
       18 ,  38  outer ball track 
       19 ,  39  inner aperture 
       20 ,  40  connecting shaft 
       21 ,  41  securing ring 
       23 ,  43  cage window 
       24 ,  44  inner cone

Technology Category: 4