BALL JOINT FOR A CHASSIS OF A VEHCILE, AND METHOD FOR PRODUCING SUCH A BALL JOINT

Abstract

A ball joint (1, 37) for a chassis of a vehicle has an inner joint portion (4) and a one-piece slide bearing (10) made of plastic, A joint ball (35) of the inner joint portion (4) is fitted so that it can swivel in a ball-bearing section (16). The slide bearing (10) has a holding section (12, 38) for the arrangement of a sensor element (13, 39). In order to simplify the structure and/or assembly of the ball joint (1, 37), the outside of the slide bearing (10) has a circular-ring-shaped contact surface (20) which is formed coaxially relative to a central longitudinal axis (19) of the slide bearing (10) and which co-operates with a separate closure ring (9) surrounding the outside of the slide bearing (10) to fix the slide bearing (10) in a joint housing (3).

Claims

1. A ball joint for a chassis of a vehicle, the ball joint comprising: an inner joint portion (4) with a joint ball (35); and a one-piece slide bearing (10) made of plastic, the one-piece slide bearing having a ball-bearing section (16) and a holding section configured to arrange a sensor element (13, 39); a closure ring (9) surrounding an outside of the slide bearing (10); and a joint housing (3); wherein the joint ball (35) of the inner joint portion (4) is fitted so that it can swivel in the ball-bearing section (16), of the slide bearing (10); and wherein an outside of the slide bearing (10) has a circular-ring-shaped contact surface (20) which is formed coaxially relative to a central longitudinal axis (19) of the slide bearing (10) and which, in an axial direction relative to the central longitudinal axis (19), co-operates with the closure ring (9) in the joint housing (3).

2. The ball joint according to claim 1, wherein the circular-ring-shaped contact surface (20) is formed at least in part by an annular projection (21), wherein the annular projection (21) extends radially outward relative to the central longitudinal axis (19) from the outside of the slide bearing (10), and wherein the annular projection (21) engages in a correspondingly shaped rabbet (30) defined by the joint housing (3).

3. The ball joint according to claim 1, wherein the closure ring (9) extends over an outside of the slide bearing (10) radially outward relative to the central longitudinal axis (19), and a radially outer rim of the closure ring (9) is fixed with interlock in a groove (31) shaped to correspond to the said outer rim.

4. The ball joint according to claim 1, wherein the closure ring (9) has a radially inward-directed side in contact with a cylindrical surface (22) of the outside of the slide bearing (10), and wherein the cylindrical surface (22) extends coaxially relative to the central longitudinal axis (19) and/or perpendicularly from and/or perpendicularly to the circular-ring-shaped contact surface (20).

5. The ball joint according to claim 4, wherein the cylindrical surface (22) defines an annular groove (32) immediately adjacent to the contact surface (20) and into which a sealing element (33) is fitted into such that the sealing element (33) co-operates with the radially inward-facing side of the closure ring (9).

6. The ball joint according to claim 1, wherein the holding section (12, 38) of the slide bearing (10) is of ring-like shape and the holding section (12, 38) has at least one web (23, 45) extending outward radially relative to the central longitudinal axis (19), wherein the at least one web co-operates with at least one correspondingly shaped detent hook (15, 41) of the sensor element (13, 39) to form a snap-on and/or detent-type connection for the detachable fixing of the sensor element (13, 39) onto the holding section (12, 38).

7. The ball joint according to claim 1, further comprising a seal positioned coaxially with and in the axial direction relative to the central longitudinal axis (19), between the holding section (12, 38) and the sensor element (13, 39), wherein the seal (46) is surrounded and/or embraced by one or more detent hooks (15, 41) of the sensor element (13, 39).

8. The ball joint according to further comprising the sensor element, wherein at its outer circumference the sensor element (13, 39) has an annular or ring-segment-like securing element (42), the securing element (42) configured to provide a clamping or spring force on the sensor element (13, 39), wherein the spring force is directed radially inward toward the central longitudinal axis (19) to secure a snap-on and/or detent-type connection between the sensor element (13, 39) and the holding section (12, 38).

9. The ball joint according to claim 8, wherein the holding section (12, 38) has at least one aligning section (25, 47) configured to align the sensor element (13, 39) on the holding section (12, 38), such that the at least one aligning section (25, 47) co-operates with a correspondingly shaped fitting section (48) of the sensor element (13, 39), and wherein the aligning section (25, 47) is formed by at least one cut-out (26, 27) in the holding section (12) or by at least one elevation (49) arranged on the outer circumference of the holding section (38).

10. The ball joint according to claim 1, wherein the holding section (12, 38) has an annular shape with a plurality of reinforcing ribs (28) directed radially inward relative to the central longitudinal axis (19), and wherein each of the plurality of reinforcing ribs (28) is ramp-shaped, such that a height of each of the plurality of reinforcing ribs decreases, starting from an inside of the holding section (12, 38), radially in the direction of the central longitudinal axis (19).

11. A method for producing a ball joint (1, 37) according to claim 1, the method comprising: taking into account a predetermined main angular deflection direction of the inner joint portion (4) relative to the joint housing (3); pressing, after alignment, the slide bearing (10) into a housing recess (2) of the joint housing (3); pressing on a separate closure ring (9) on in order to fix the slide bearing (10) axially; folding over a rim (11) of the housing in order to fix the closure ring (9) in an interlocked manner; and fitting the sensor element (13, 39) onto the holding section (12, 38) in an orientation relative to the joint housing (3) which is predetermined by virtue of the holding section (12, 38).

12. The ball joint of claim 8, wherein the securing element comprises one or more detent hooks.

13. The ball joint of claim 12, wherein each of the one or more detent hooks (15, 41) defines a channel (43) in an outside surface, wherein a portion of the securing element (42) is at least partially held in the channel.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0027] In what follows, the invention will be explained in greater detail with reference to the figures, in which the same indexes denote the same, similar or functionally equivalent components. The figures show:

[0028] FIG. 1: Part of a perspective side view of a first ball joint according to the invention,

[0029] FIG. 2: A perspective side view of a slide bearing for the first ball joint according to the invention shown in FIG. 1,

[0030] FIG. 3: A sectioned side view of the first ball joint according to the invention shown in FIG. 1,

[0031] FIG. 4: Part of a perspective side view of a further ball joint according to the invention,

[0032] FIG. 5: A side view of a sensor element for the further ball joint according to the invention shown in FIG. 4,

[0033] FIG. 6: A sectioned side view of the further ball joint according to the invention shown in FIG. 4,

[0034] FIG. 7: Part of the sectioned side view of the further ball joint according to the invention shown in FIG. 6,

[0035] FIG. 8: Part of a further, partially sectioned side view of the further ball joint according to the invention shown in FIG. 4, and

[0036] FIG. 9: Part of a perspective side view of the further ball joint according to the invention, without the sensor element.

DETAILED DESCRIPTION

[0037] FIG. 1 shows part of a perspective side view of a first ball joint 1 according to the invention. In this example embodiment the ball joint 1 is in the form of a ball-and-socket joint. Moreover, the ball joint 1 is arranged in a housing recess 2 of a joint housing 3. In this example embodiment the joint housing 3 is an integral part of a chassis component, the chassis component being in this case for example a control arm.

[0038] The ball joint 1 comprises an inner joint portion 4. In this case the inner joint portion 4 is in the form of a ball stud. Correspondingly, the inner joint portion 4 comprises a joint stud 5 which extends outward from the joint housing 3. To seal the ball joint 1, this has a sealing bellows 6. The sealing bellows 6 extends between the joint stud 5 and the joint housing 3. Here, the sealing bellows 6 is secured on the joint stud side and also on the joint housing side by means of spring rings 7 and 8, respectively onto the joint stud 5 and the joint housing 3.

[0039] On the side remote from the joint stud 5 the joint recess 2 is closed by a closure ring 9 and a slide bearing 10. In this case, the closure ring 9 is fixed into the joint recess 2 by a deformed housing rim 11. Through a central opening of the closure ring 9 a holding section 12 of the slide bearing 10 extends outward.

[0040] A sensor element 13 is arranged and fixed on the holding section 12. In this example embodiment the sensor element 13 is essentially of plug-like form. Starting from the sensor element 13 a conducting lead 14 extends to an evaluation device (not shown). The sensor element 3 is fitted onto and held on the holding section 12 in the axial direction relative to the central longitudinal axis 19, by means of a snap-on and/or detent-type connection. For that purpose, the sensor element 13 has a plurality of detent hooks 15. For greater clarity, not all the detent hooks 15 are provided with an index. The plurality of detent hooks 15 are spaced uniformly apart. Furthermore, in this example embodiment the plurality of detent hooks 15 are arranged in a semicircle relative to one another. Thus, the detent hooks 15 at the same time form part of the outer circumference of the sensor element 13 that faces away from the conducting lead 14.

[0041] FIG. 2 shows a perspective side view of the slide bearing 10 for the first ball joint 1 according to the invention, as shown in FIG. 1. The slide bearing 10 is formed by the holding section 12 and a ball-bearing section 16. On the side facing away from the holding section 12, the ball-bearing section 16 has an opening 17. Through that opening 17 the inner joint portion 4 shown in FIG. 1 extends outward. The ball-bearing section 16 has a plurality of slots 18. The plurality of slots 18 are arranged uniformly spaced in the circumferential direction of the ball-bearing section 16. Furthermore, starting from the opening 17 the slots 18 extend parallel to a central longitudinal axis 19 of the slide bearing 10. The slots 18 extend approximately to an equatorial area of the ball-bearing section 16. In this example embodiment the ball-bearing section 16 has a total of four slots 18.

[0042] On its outside the slide bearing 10 has a circular ring-shaped contact surface 20. The contact surface 20 is coaxial with the central longitudinal axis 19 and extends radially toward the central longitudinal axis 19. Furthermore, the contact surface 20 faces away from the ball-bearing section 16 and toward the holding section 12. The holding section 12 is in the form of a ring, such that the holding section 12 has a smaller outer diameter than the contact surface 20. In this case the holding section 12 is arranged centrally relative to the contact surface 20 and the central longitudinal axis 19.

[0043] The circular ring-shaped contact surface 20 is formed at least partially by an annular projection 21 of the slide bearing 10. The annular projection 21 extends outward, relative to the central longitudinal axis 19, from the outside of the slide bearing. Thus, the projection 21 defines or determines a maximum outer diameter of the slide bearing 10.

[0044] The holding section 12 has a cylindrical surface 22 which extends coaxially relative to the central longitudinal axis 19 and, in this example embodiment, perpendicularly away from the circular ring-shaped contact surface 20.

[0045] To position the sensor element 13 on the holding section 12 as in FIG. 1, the holding section comprises a web 23 projecting outward radially relative to the central longitudinal axis 19. In this example embodiment the holding section 12 has two webs 23. In this example embodiment the two webs 23 are in the form of circular ring segments arranged mirror-symmetrically relative to one another. At the same time the webs 23 form in each case an end face 24 of the holding section 12. The end faces 24 face away from the ball-bearing section 16 in the axial direction relative to the central longitudinal axis 19.

[0046] The holding section 12 has an aligning section 25 for the aligned arrangement of the sensor element 13 on the holding section 12 shown in FIG. 1. The aligning section 25 in this example embodiment is formed by two cut-outs 26, 27 opposite one another. By virtue of the said cut-outs 26, 27 the two webs 23 are separated from one another.

[0047] The holding section 12 is essentially ring-shaped and has a plurality of reinforcing ribs 28 directed radially inward relative to the central longitudinal axis 19. For the sake of greater clarity, not all the reinforcing ribs 28 are indexed. The reinforcing ribs 28 are in each case ramp-like. In this case the height of the ramp-like reinforcing ribs 28 decreases, starting from an inside 29 of the holding section 12, radially in the direction toward the central longitudinal axis 19.

[0048] FIG. 3 shows a sectioned side view of the first ball joint 1 according to FIG. 1. The annular projection 21 of the slide bearing 10 engages in a correspondingly shaped rabbet 30 of the joint housing 3 or the housing recess 2. In this example embodiment the rabbet 30 is of step-like form.

[0049] The closure ring 9 extends over an outside of the slide bearing 10, radially toward the central longitudinal axis 19. In this case a radially outer rim of the closure ring 9 is set with interlock into a groove 31 designed to correspond to the outer rim of the closure ring 9. The groove 31 is annular and is arranged or formed on the inside of the housing recess 2. The shape of the groove 31 is produced after the closure ring 9 has been inserted and the housing rim 11 has been folded over in such manner that the configuration shown is obtained.

[0050] The cylindrical surface 22 of the holding section 12 has an annular groove 32 immediately adjacent to the contact surface 20. Into the said groove 32 is fitted a sealing element 33. In this example embodiment the sealing element 33 is in the form of an O-ring. The sealing element 33 co-operates with the radially inward-directed side of the closure ring 9. By virtue of the sealing element 33, unwanted penetration of dirt and/or moisture into the ball joint 1 is prevented.

[0051] In this example embodiment the sensor element 13 is designed to co-operate with a further sensor element 34. The sensor element 13 and the further sensor element 34 form a sensor device. In this example embodiment the said further sensor element 34 is a magnet and is integrated in a joint ball 35 of the inner joint portion 4. The joint ball 35 is fitted into the ball-bearing section 16 in such manner that it can swivel. The further sensor element 34 is arranged in an area of the joint ball 35 that faces away from the joint stud 5 and toward the holding section 12.

[0052] In this example embodiment the sensor element 13 comprises a Hall sensor 36. Thus, in this example embodiment the sensor device formed by the sensor element 13 and the further sensor element 34 is in the form of an angle sensor device, by means of which the position of the inner joint portion 4 can be determined relative to the joint housing 3 or the slide bearing 10.

[0053] The slide bearing 10, which consists of the holding section 12 and the ball-bearing section 16, is made integrally from a plastic material. The closure ring 9 is metallic. The joint housing 3 and the associated chassis components are also metallic.

[0054] FIG. 4 shows part of a perspective side view of a further ball joint 37 according to the invention. The same features as before are given the same indexes. To that extent reference is also made to the previous description. Like the ball joint 1 according to FIGS. 1 to 3, the ball joint 37 is also in the form of a ball-and-socket joint. Correspondingly, an inner joint portion 4 in the form of a ball stud is arranged in a joint recess 2 of a joint housing 3. In this example embodiment the slide bearing 10 has a holding section 38 onto which a sensor element 39 is attached with a snap-on and/or detent-type connection. The structure of the holding section 38 and the sensor element 39 will be described in greater detail with reference to the figures that follow.

[0055] FIG. 5 shows a side view of the sensor element 39 for the further ball joint 37 according to the invention shown in FIG. 4. Like the sensor element 13 according to FIGS. 1 to 3, the sensor element 39 is designed as a plug-in element. A free end 40 of the sensor element 39 can be connected by a conducting lead (not shown) to an evaluation unit. To position the sensor element 39 on the holding section 38 as in FIG. 4, the sensor element has a plurality of detent hooks 41. For better clarity, not all the detent hooks 41 are indexed. The plurality of detent hooks 41 are uniformly spaced apart and together they form a circular-ring-like or circular-ring-segment-like configuration.

[0056] In addition, in this example embodiment, in the area of the detent hooks 41 the sensor element 39 has at its circumference an annular or circular-ring-segment-like securing element 42. The securing element 42 surrounds or embraces the plurality of detent hooks 41, with the securing element 41 on an outside of the detent hook 41 in each case. In this case the securing element 42 acts upon the sensor element 39 or the detent hooks 41 with a clamping or spring force directed radially toward the central longitudinal axis 19. In that way the snap-on and/or detent-type connection between the sensor element 39 and the holding section 38 according to FIG. 4 is additionally secured.

[0057] On the outside the detent hooks 41 have in each case a channel 43. The securing element 42 is held at least partially in the said channels 43, and thereby correctly positioned on the detent hooks 41.

[0058] FIG. 6 shows a sectioned side view of the further ball joint 37 according to the invention, as shown in FIG. 4. In addition to the holding section 38, the slide bearing 10 comprises the ball-bearing section 16. The ball-bearing section 16, the projection 21, the closure ring 9 and its co-operation with the joint housing 3 and the joint housing recess 2, and also the rim 11 of the housing, correspond to what was said about the ball joint 1 shown in FIG. 1. Accordingly, reference should be made to the previous description.

[0059] In this case too, the sensor element 39 co-operates with a further sensor element 34 in the form of a magnet in the joint ball 35 of the inner joint portion 4. For this, the sensor element 39 again comprises a Hall sensor 36. In this example embodiment, starting from the Hall sensor 36, an electronic assembly 44 is arranged parallel to the central longitudinal axis 19. If it is desired, in an alternative embodiment, to have a flatter sensor element 39 in the axial direction relative to the central longitudinal axis 19, then the electronic assembly 44 can be arranged not parallel to, but at an angle relative to the central longitudinal axis 19. For example, the electronic assembly 44 can be arranged at an angle of 65° or even 90° relative to the central longitudinal axis 19.

[0060] FIG. 7 shows part of the sectioned side view of the further ball joint 37 according to the invention, as shown in FIG. 6. The holding section 38 is essentially annular and has a web 45 projecting outward relative to the central longitudinal axis 19 according to FIG. 6. The web 45 co-operates with the plurality of detent hooks 41 of the sensor element 39 to form the snap-on and/or detent-type connection for the detachable attaching of the sensor element 39 to the holding section 38. For that purpose, the detent hooks 41 are at least partially directed radially inward, in order to co-operate with the radially outward-directed web 45 in an interlocking manner.

[0061] Coaxially, and in the axial direction relative to the central longitudinal axis 19, according to FIG. 6, a seal 46 is arranged between the holding section 38 and the sensor element 39. In this example embodiment, the seal 46 is in the form of an O-ring. Moreover, the seal 46 is surrounded or embraced by the plurality of detent hooks 41. In the area of the seal 46, and in order to hold the seal 46, the holding section 38 has an essentially U-shaped cross-section. In this case the seal 46 is supported on the end face 24 of the web 45. By means of the seal, any penetration of dirt and/or moisture between the sensor element 39 and the slide bearing 10 or the holding section 38 is prevented.

[0062] FIG. 8 shows part of a further, partially sectioned side view of the further ball joint 37 according to the invention shown in FIG. 4. In this case the viewing direction is from the free end 40 of the sensor element 39 toward the snap-on and/or detent-type connection between the sensor element 39 and the holding section 38. In this example it can be seen that the holding section 38 comprises an aligning section 47 for ensuring a correctly aligned arrangement of the sensor element 39 on the holding section 38. The aligning section 47 co-operates with a correspondingly shaped fitting section 48 of the sensor element 39. In this example embodiment the aligning section 47 is formed by a projection-like elevation 49. In this example embodiment the fitting section 48 has a recess 50 shaped to correspond to the elevation 49, in which the elevation 49 engages. By virtue of the co-operation between the aligning section 47 and the fitting section 48, the orientation of the sensor element 39 is predetermined relative to the slide bearing 10 or to the joint housing 3, according to FIG. 6.

[0063] FIG. 9 shows part of a perspective side view of the further ball joint 37 according to the invention, without the sensor element 39. Here, the circular-ring-like web 45 and the aligning section 47 with the projection-like elevation 49 extending radially outward can be seen clearly. As with the holding section 2 according to FIG. 2, the holding section 38 also has a number of reinforcing ribs 28 which are of ramp-like shape and which extend, starting from the inside 29, radially toward the central longitudinal axis 19.

[0064] To produce the ball joint 1 or 37, the slide bearing 10 is pressed into the housing recess 2 of the joint housing 3, with an orientation that takes into account a predetermined main angular deflection direction of the inner joint portion 4 relative to the joint housing 3. In this case the pressing-in of the slide bearing 10 takes place with the opening 17 facing forward in the axial direction of the central longitudinal axis 19. The pressing-in process ends as soon as the projection 21 of the slide bearing 10 encounters the step-like rabbet 30 of the joint housing 3 or the housing recess 2. Then, the separate closure ring 9 is pressed into place in order to fix the slide bearing 10 axially in the housing recess 2. In this case the closure ring 9 is pressed in the axial direction defined by the central longitudinal axis 19 toward the slide bearing 10 until the closure ring 9 encounters the contact surface 20 of the slide bearing 10. At the same time a radially inward-directed side of the closure ring 9 encounters the cylindrical surface 22. Thereafter, the housing rim 11 is folded over in order to fix the closure ring 9 in place in a form-enclosed manner. This creates the groove 31 in which the radially outer rim of the closure ring 9 is fixed with interlock. Finally, the sensor element 13 or 39 is fixed onto the holding section 12 or 38 in the orientation relative to the joint housing 3 determined by means of the holding section 12 or 38. In this case, the predetermined orientation of the sensor element 13 or 39 is defined by the aligning section 25 or 47 of the holding section 12 or 38. In turn, the orientation of the aligning section 25 or 47 is already determined by the orientation of the slide bearing 10 when it is pressed in.

INDEXES

[0065] 1 Ball joint [0066] 2 Housing recess [0067] 3 Joint housing [0068] 4 Inner joint portion [0069] 5 Joint stud [0070] 6 Sealing bellows [0071] 7 Spring ring [0072] 8 Spring ring [0073] 9 Closure ring [0074] 10 Slide bearing [0075] 11 Housing rim [0076] 12 Holding section [0077] 13 Sensor element [0078] 14 Conductor [0079] 15 Detent hook [0080] 16 Ball-bearing section [0081] 17 Opening [0082] 18 Slot [0083] 19 Central longitudinal axis [0084] 20 Contact surface [0085] 21 Projection [0086] 22 Cylindrical surface [0087] 23 Web [0088] 24 End face [0089] 25 Aligning section [0090] 26 Cut-out [0091] 27 Cut-out [0092] 28 Reinforcing rib [0093] 29 Inner side [0094] 30 Rabbet [0095] 31 Groove [0096] 32 Annular groove [0097] 33 Sealing element [0098] 34 Further sensor element (magnet) [0099] 35 Joint ball [0100] 36 Hall sensor [0101] 37 Ball joint [0102] 38 Holding section [0103] 39 Sensor element [0104] 40 Free end [0105] 41 Detent hook [0106] 42 Securing element [0107] 43 Channel [0108] 44 Electronic assembly [0109] 45 Channel [0110] 46 Web [0111] 47 Aligning section [0112] 48 Fitting section [0113] 49 Elevation [0114] 50 Recess