JOINT, LINK FOR A WHEEL SUSPENSION AND METHOD FOR ASSEMBLING A JOINT

Abstract

A joint (10) with first and second joint components (12, 26; 19) are movably connected to one another. The first joint component (12, 26) has a spherical joint body (14, 28) and the second joint component (19) rotatably and pivotably holds the joint body (14, 28). A sensor device, for determining the position of the first and second joint components (12, 26; 19) relative to one another, is arranged on the joint (10). The sensor device has at least one sensor element (21, 31) which can be integrated in a housing (18) that is produced by an assembly overmolding process. The joint housing (18) forms the second joint component (19) in which the joint body (14, 28) is directly supported.

Claims

1-15. (canceled)

16. A joint (10) comprising: first and second joint components (12, 26;19) being movably connected to one another, the first joint component (12, 26) comprising a spherical joint body (14, 28) and the second joint component (19) that rotatably and pivotably holds the joint body (14, 28), a sensor device being arranged on the joint (10) for determining a position of the first and the second joint components (12, 26; 19) relative to one another, the sensor device comprising at least one sensor element (21, 31) being integratable in a joint housing (18) made by an assembly injection-molding process, and the joint housing (18) forming the second joint component (19) which forms a direct bearing for the joint body (14, 2).

17. The joint (10) according to claim 16, wherein the at least one sensor element (21, 31) is overmolded into the joint housing (18).

18. The joint (10) according to claim 16, wherein at least one recess (20) is formed on the joint housing (18) which receives the at least one sensor element (21).

19. The joint (10) according to claim 16, wherein the at least one sensor element (21) is in a form of a magneto-resistive sensor.

20. The joint (10) according to claim 19, wherein a position magnet (17), associated with the sensor element (21), is received into a recess (16) on a surface of the joint body (14).

21. The joint (10) according to claim 20, wherein the sensor element (21) is designed to seal the recess (16) in which the position magnet (17) is arranged.

22. The joint (10) according to claim 16, wherein the sensor element (31) is in a form of an incremental transducer.

23. The joint (10) according to claim 22, wherein the sensor element (31), in the form of the incremental transducer, is designed for one of photoelectric scanning or for magnetic scanning.

24. The joint (10) according to claim 22, wherein a measurement standard (30) that extends in a circumferential direction is provided on a surface of the joint body (28).

25. The joint (10) according to claim 24, wherein the measurement standard (30) is in a form of a magnetic strip or a barcode.

26. The joint (10) according to claim 16, wherein the joint (10) is in a form of a ball joint or a sleeve joint.

27. A control arm (1) with at least one joint (10) for a wheel suspension of a motor vehicle, wherein the at least one joint (10) arranged on the control arm (1) is designed in accordance with claim 16.

28. A method for assembly of a joint (10) on a control arm (1) of a wheel suspension, wherein the joint (10) has first and second joint components (12, 26; 19), the first joint component (12, 26) has a spherically shaped joint body (14, 28), which is connected to the second joint component (19) that rotatably and pivotably holds the joint body (14, 28), a sensor device comprising at least one sensor element (21, 31) is arranged on the joint (10) for determining a position of the first and the second joint components (12, 26; 19) relative to one another, the method comprising: positioning the joint body (14, 28) of the first joint component (12, 26) relative to the control arm (1) in at least one receiving section (3) of the control arm (1); and overmolding at least the joint body (14, 28) of the first joint component (12, 26), wherein by means of the overmolding the joint housing (18) that forms the second joint component (19) is made, such that the at least one sensor element (21, 31) is integrated into the joint housing and the joint housing forms a direct bearing for the spherical joint body (14, 28).

29. The method according to claim 28, further comprising positioning the at least one sensor element (21, 31) relative to the joint body (14, 28) of the first joint component (12, 26) before the overmolding process.

30. The method according to claim 28, wherein the at least one receiving section (3) is formed in wall segments (2) of the control arm (1) that in part extend parallel to one another, the wall segments each has an eyelet (4) and the wall segments are arranged such that the eyelets are substantially coaxial with each other, and the method further comprising: positioning at least the first joint component (14, 28) in the eyelets before the overmolding process.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0024] Advantageous embodiments of the invention, which will be explained below, are illustrated in the drawings, which show:

[0025] FIG. 1: A partial perspective view of a control arm;

[0026] FIG. 2: A partial perspective view according to FIG. 1, with a first joint component of a sleeve joint positioned in the control arm;

[0027] FIG. 3: A partial perspective view according to FIG. 2, with a joint housing formed by overmolding the first joint component;

[0028] FIG. 4: A partial perspective view according to FIG. 3, with a sensor element integrated in the joint housing;

[0029] FIG. 5: A perspective view of the first joint component with a sensor element shown in partial section, according to a second embodiment, before overmolding;

[0030] FIG. 6: A perspective view of a first joint component according to a further embodiment;

[0031] FIG. 7: A perspective view of the first joint component according to FIG. 6, with a measurement standard arranged on it;

[0032] FIG. 8: A perspective view of the first joint component according to FIG. 7, with a sensor element.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0033] FIG. 1 shows a partial perspective view of a control arm 1 for a wheel suspension. The control arm 1 is preferably a metallic stamped and bent component, in particular made of steel. The control arm 1 in the form of a stamped and bent component has a U-shaped cross-section with two wall sections 2 extending parallel to one another. At least at one end of the control arm 1 the wall sections 2 are made as receiving sections 3. The receiving sections 3 are connected to the U-shaped wall sections 2 and are essentially of circular shape. The receiving sections 3 each have an eyelet 4, which is arranged coaxially with an axis of symmetry 5 of the receiving sections 3. On the inner side of the respective receiving section 3, there is in each case a section 6 that extends in the axial direction. The two sections 6 are separated a distance apart from one another by an annular gap 7. Viewed in the circumferential direction, the annular gap 7 is interrupted at one point by a circular cut-out 8.

[0034] The receiving section 3 serves to accommodate a joint 10, whose arrangement in the receiving sections 3 of the control arm 1 will be described below with reference to FIGS. 2 to 4. On the joint 10 is arranged a sensor device for determining the position of two joint components 12, 19 relative to one another. By virtue of the sensor arrangement shown in the example embodiment illustrated, which sensor works in accordance with the magneto-resistive effect, an angular change of the two joint components 12, 19 is detected, by means of which an external height level sensor system which detects a compression travel at a front axle and a rear axle of a vehicle in order to determine the condition or the angular position of chassis components, can be realized.

[0035] FIG. 2 shows a partial perspective view as in FIG. 1, with a first joint component 12 of a joint 10 in the form of a sleeve joint 11. The first joint component 12 has two projections 13 and a spherical joint body 14. The projections 13 and the joint body 14 are provided with a through-going bore 15. On the surface of the joint body 14 is formed a recess 16 which holds a position magnet 17 fixed therein.

[0036] The illustration in FIG. 3 shows a partial perspective view as in FIG. 2, with a joint housing 18 formed by overmolding the joint body 14 of the first joint component 12. For this, the control arm 1 and the first joint body 12 are positioned relative to one another. At least one multi-component die surrounds the joint body 14, while further single- or multi-component dies can be positioned at the sides of the receiving sections 3. This enables the joint body 14 and, in sections, also the receiving sections 3, to be overmolded in order to produce the joint housing 18 that forms the second joint component 19 of the joint 10. The second joint component 19 is made from a plastic. Suitable shaping of the die makes it possible at the same time to form a recess 20 in the joint housing 18, above the position magnet 17. The recess 20 is partially arranged in the cut-out 8, which corresponds to the location of the position magnet 17.

[0037] The recess 20 enables the positioning of a sensor element 21 in the form of a magneto-resistive sensor a small distance away from the position magnet 17. The joint housing 18 produced by the assembly injection-molding process, which housing forms the second joint component 19, forms a direct bearing for the joint body 14 of the first joint component 12. This simplifies the assembly of the joint 10 and its attachment to the control arm 1. The overmolding at least of the joint body 14 positioned in the control arm 1 to form the joint housing 18 eliminates the fitting of the joint housing 18 into the receiving sections 3 and the pressing of the first joint component 12 into the joint housing 18. In order to prevent the imperfection of the surface of the joint body 14 in the area of the recess 16 for the position magnet 17 from being reproduced on the inner surface of the joint housing 18 that is in contact with the joint body 14, a shell-shaped element can enclose the joint body 14 in sections and completely cover the recess 16 and the position magnet 17 arranged therein.

[0038] FIG. 4 shows a partial perspective view as in FIG. 3, with the sensor element 21 integrated in the joint housing 18. The at least one sensor element 21 is inserted into the recess 20 and fixed therein. A signal line 22 connects the sensor element 21 to an external control device for evaluating the sensor signals.

[0039] FIG. 5 shows a perspective view of the first joint component 12 with a sensor element 23 shown in partial section, according to a second embodiment, before overmolding. The at least one sensor element 23 is again in the form of a magneto-resistive sensor. In contrast to the arrangement of the sensor element 21 in the recess 20 formed to hold it on the second joint component 19, in this second embodiment the sensor element 23 is positioned, relative to the joint body 14 and together with the first joint component 12 relative to the control arm 1, before the assembly injection-molding for producing the joint housing 18 or second joint component 19. In this case the sensor element 23 has the additional function of completely sealing or closing off the imperfection in the surface of the joint body 14 in the area of the recess 16 for the position magnet 17 during the overmolding of the joint body 14, so that during the assembly injection-molding no material makes its way into that area. For that purpose, on its side facing toward the position magnet 17 the sensor element 23 has a covering element 24. On its underside 25 that faces toward the joint body 14, the covering element 24 ends essentially flush with the recess 16. In that way the necessary mobility for fulfilling the bearing function of the joint housing 18 can be ensured. Thus, the additional effect is that the assembly of the arrangement with at least one sensor element 23 can be omitted. The recess 16 is sealed when positioning the control arm 1, the first joint component 12 and the sensor element 23, before the overmolding process, in that the sensor element 23 is pressed over the recess 16 and against the joint body 14.

[0040] The illustration in FIG. 6 shows a perspective view of a first joint component 26 according to a third embodiment. The first joint component 26 also has two projections 27 and a spherical joint body 28. The first joint component 26 is made of a metal. In this embodiment at least one sensor element 31 is integrated in the joint housing 18 by overmolding, which sensor is in the form of an incremental transducer. For this, the at least one sensor element 31 in the form of an incremental transducer can be designed for magnetic scanning or for photoelectric scanning. A measurement standard 30 required for that can be in the form of a pole wheel or a magnetic strip, or a barcode. In the example embodiment shown, the measurement standard 30 is arranged in an all-round groove 29 on the surface of the joint body 28. The groove 29 extends coaxially with the longitudinal axis 5 in the area of the maximum outer diameter of the joint body 28. Compared with the recess 16 for the position magnet 17 the depth of the groove 29 is much smaller, so that the joint body 28 is weakened less.

[0041] FIG. 7 shows a perspective view of the first joint component according to FIG. 6 with a measurement standard 30 arranged on it. As can be seen from the figure, the groove 29 can be filled by the measurement standard 30 in such manner that there are virtually no imperfections.

[0042] FIG. 8 shows a perspective view of the first joint component 26 according to FIG. 7 with the at least one sensor element 31 positioned relative to the joint body 28 and the measurement standard 30. The sensor element 31 can be positioned a minimal distance away from the surface of the joint body 28 before at least the joint body 28 of the first joint component 26 together with the sensor element 31 are overmolded, as already described earlier.

[0043] An embodiment of the measurement standard as a barcode can be produced on the surface of the joint body 28 by knurling, engraving or laser etching. Likewise, a barcode can be fixed into the groove. In the simplest case a barcode can be stuck on. With this design of the measurement standard as well, there is only minimal interference with the surface contour of the joint body 28.

INDEXES

[0044] 1 Control arm [0045] 2 Wall section [0046] 3 Receiving section [0047] 4 Eyelet [0048] 5 Axis of symmetry [0049] 6 Section [0050] 7 Gap [0051] 8 Cut-out [0052] 10 Joint [0053] 11 Sleeve joint [0054] 12 First joint component [0055] 13 Projection [0056] 14 Joint body [0057] 15 Bore [0058] 16 Recess [0059] 17 Position magnet [0060] 18 Joint housing [0061] 19 Second joint component [0062] 20 Recess [0063] 21 Sensor element [0064] 22 Signal line [0065] 23 Sensor element [0066] 24 Cover element [0067] 25 Underside [0068] 26 First joint component [0069] 27 Projection [0070] 28 Joint body [0071] 29 Groove [0072] 30 Measurement standard [0073] 31 Sensor element [0074] 32 Longitudinal axis