The present disclosure relates to a device comprising at least one wheel hub and a constant velocity rotary joint that are coupled together. Such a device may be used in a drive train of a motor vehicle.
Examples of known wheel hub/rotary joint devices are revealed, for example, in WO 2007/054189 A1 and WO 2007/054190 A1. These references in particular describe a wheel hub/rotary joint arrangement for connecting a wheel-side rotary joint of a side shaft of a motor vehicle to a wheel hub held by a vehicle-side wheel carrier. In this case, the wheel hub comprises a sleeve section for receiving a wheel mounting, which, for its part, is held in the wheel carrier of the motor vehicle body, and a flange section for the bolting-on of a wheel, i.e. in particular, of the central wheel disk.
In the case of devices of this type, the joint outer part and the wheel hub are generally connected to each other, in particular clamped to each other. For this purpose, the joint outer part can be designed, for example, with a bore which has an internal toothing and into which a corresponding bolt is screwed through the wheel hub. The wheel hub and the joint outer part are therefore clamped axially. It is thus ensured that the spur toothing of the wheel hub engages securely and permanently in the joint outer part via the spur toothing and consequently a reliable transmission of torque is ensured. With regard to the configuration of the wheel hub, the constant-velocity joint and/or the spur toothing, recourse can be made in particular to the disclosure content of the two above-mentioned international patent publications, the subject matter of which to this extent is fully incorporated here with the subject matter of the present application.
Even though the above-described construction has already proven suitable for daily use, particularly adverse circumstances which put the satisfactory operation of a device of this type at risk may occur. In particular, severe weather effects and the tendency of the components used to corrode should be taken into consideration in this case. Due to their proximity to the roadway, the above mentioned components are exposed to a particularly great extent to the external weather conditions, with the materials, which are predominantly metallic here, also sometimes being exposed to corrosion. In addition, it should be taken into consideration that a magnetic transmitter ring for an antilock system (ABS) may also be arranged in the region of the wheel hub or of the constant-velocity rotary joint, and therefore, due to said magnetic effect, an increased accumulation of rust particles could be a cause for concern here. There is therefore the risk of such rust particles accumulating right in the region of the device, even if it has been assumed to date that such an “encapsulated system” is already sufficiently protected.
A device is disclosed herein which, even in the event of an increased tendency of the components of the device to corrode, a reliable transmission of torque is ensured. More specifically, a device is disclosed that provides protection for the spur toothing, with which protection the requirements with regard to cost-effective use, simple installation or a long service life of the said protection are equally achieved. In one exemplary configuration, this device is used in arrangements wherein a magnetic transmitter ring of the antilock system (ABS) is located on the wheel-bearing inner ring of a wheel-bearing.
The device disclosed herein comprises at least one wheel hub with a flange section and a sleeve section, and a constant-velocity rotary joint having at least one joint outer part, a joint inner part and torque-transmitting elements, wherein the wheel hub and the constant-velocity rotary joint are coupled to each other via a spur toothing, and the spur toothing is surrounded radially on the outside by a flexible seal.
The device disclosed herein may be used in this respect in particular in the arrangements described in the background section above, and therefore, in order to explain the individual components and the action thereof with regard to the transmission of torque, additional information, if appropriate, may also be obtained from the two international patent publications of the applicant (WO 2007/054189 A1 and WO 2007/054190 A1), the contents of which are incorporated herein by reference in their entireties.
In principle, use may be made here of any known type of constant-velocity rotary joint, with it being possible, in particular, also for the type and/or number of torque-transmitting elements (balls or the like) and, if appropriate, also the type and/or design of the guide tracks for said torque-transmitting elements to be adapted in a manner corresponding to the requirements. In one exemplary configuration, the constant-velocity rotary joint is designed as a fixed joint (such as, for example, the Rzeppa type; if appropriate, a fixed joint with ball tracks opening in opposite directions in an alternating manner), though, in principle, sliding joints (which permit axial displacement of joint inner part and joint outer part during operation) can equally be used. The design of the joint outer part is of major significance for the connection to the wheel hub because the toothing for the spur toothing is formed here in a plane that is generally perpendicular to the axis of the constant-velocity rotary joint. If appropriate, the joint outer part can be designed with at least one receptacle (bore, thread, etc.) in which a clamping mechanism (journal, bolt, etc.) for pressing the wheel hub onto the joint outer part can engage.
In order to directly protect said spur toothing against corrosion, it is proposed herein to provide, radially on the outside, a flexible seal which completely surrounds the spur toothing. That is also to say, in other words, that, if appropriate, an encircling space is created between the spur toothing and the flexible seal and is bounded (partially) by the spur toothing and the flexible seal. Said space may advantageously kept relatively small in order to be able to design the flexible seal to likewise be small. An exemplary effect achieved by this design, in particular, is that the spur toothing is sealed in the direct vicinity, i.e. contact with other regions of the device (with the exception of the directly adjacent regions) is consequently reliably avoided. Furthermore, in one exemplary arrangement, an encircling space is equally formed on the outside around said seal, which space can serve, if appropriate, as a collecting reservoir for rust particles or the like. Protection for the spur toothing can thus be provided particularly effectively and cost-effectively.
According to a further refinement, it is proposed that the flexible seal may extend from a wheel-bearing inner ring of a wheel-bearing, which inner ring is positioned on the sleeve section of the wheel hub, as far as the joint outer part. Such a wheel-bearing is positioned in particular radially on the outside of the sleeve section of the wheel hub, with, in particular, double-row ball bearings being used here. A first row of balls is guided on the inside, for example directly on the sleeve section, while a second row of balls, which is positioned closer to the constant-velocity joint, is guided on a separate wheel-bearing inner ring which is positioned and fixed radially on the outside of the sleeve section. In this case, said wheel-bearing inner ring extends into the vicinity of that end side of the sleeve section on which the spur toothing is formed. In one exemplary arrangement, the distance between the spur toothing of the sleeve section and the closest end surface of the wheel-bearing inner ring is less than 8 mm.
With said compact design, it is therefore now proposed that the flexible seal makes contact on one side with the joint outer part and on the other side (only) with the wheel-bearing inner ring of the wheel-bearing. Although it is possible, in principle, to provide stops for said flexible seal on both components in the direction of the axis of the joint or of the device, these may be omitted here. The flexible seal therefore forms a contact region with the two components mentioned here, for example in the form of an encircling contact wherein the contact region is formed as a line-type contact and/or as an area-type contact. The required retaining force for permanently fixing the flexible seal in place is may be realized here via said contact region. Though the focus in this exemplary configuration is on the specific case of making contact with the wheel-bearing inner ring, it is nevertheless equally also possible to realize a contact connection with the sleeve section itself and/or with a different subregion of the wheel-bearing.
According to one exemplary development, it is also proposed that the flexible seal is designed at least on one side with a sealing lip. That is to say, in other words, that the flexible seal can form a sealing lip toward the sleeve section and/or the wheel-bearing inner ring, on the one hand, or the joint outer part, on the other hand The variant in which a sealing lip is realized only toward the joint outer part is one exemplary arrangement. In one exemplary configuration, the sealing lip may be designed in the form of a membrane being arranged substantially oblique or perpendicular with regard to the adjacent sealing surface. Such a sealing lip is formed, for example, by a flexible ring which has an outside diameter which is larger than the seat of the flexible seal on the joint outer part and the inside diameter of which is smaller than said diameter of the seat. Therefore, said sealing lip has an important sealing function. Said sealing lip is now pulled over the joint outer part such that the sealing lip is at least partially deformed and/or even only partially (elastically) deformed and is therefore fixed in a cylindrical manner (circumferential strip-like area) on the seat of the joint outer part with a sufficient degree of prestressing. This ensures a stable fixation of the flexible seal on the outer part even in case of an uneven surface of the outer part and/or a displacement of the bearing and the outer part. In one exemplary configuration, the sealing lip forms a contacting surface on the seat of the joint outer part of 2 to 4 mm. In addition, the sealing lip can have, radially on the outside, a receptacle for, for example, a sealing body which covers the adjacently arranged spur toothing and makes contact with the opposite components of the device. In this case it may be advantageous that a stiffer sealing body (in particular made from sheet metal) keeps the sealing lip preferably at a distance of at least 2 mm away from the surface or the seat of the joint outer part. Such a sealing lip may be designed similar to a ring-type washer that can be elastically deformed so that an inner collar-like section is provided.
Furthermore, an exemplary arrangement is is also proposed in which the flexible seal forms at least on one side, a form-fitting contacting surface with the wheel-bearing inner ring or the joint outer part. In principle, an arrangement is also possible, in which form-fitting contacting surfaces are formed on both sides on the wheel-bearing inner ring and the joint outer ring. However, a variant is also possible, in which a form-fitting contacting surface is formed only with the wheel-bearing inner ring. Such wheel-bearing inner rings are generally already available with a relatively high degree of precision as a standard part, but may equally have positional and/or circularity tolerances because of being supported on the sleeve section in the fitted situation. In order now to obtain a sufficient sealing action here, a form-fitting supporting surface is proposed here, wherein an additional sealing compound can optionally positioned there. In one exemplary arrangement, the supporting surface preferably has a width parallel to the axis, which width lies in the range of generally 1 to 5 mm.
In another exemplary embodiment, the wheel-bearing inner ring or the joint outer part may have a textured-surface seat for the contacting surface of the flexible seal. For example, surfaces on the wheel-bearing inner ring and/or the joint outer part that are roughened, micro-textured, embossed, forged or the like, are suitable for this. In one exemplary configuration, a relatively rough surface roughness is to be provided here, for example a roughness parameter Ra at the outer part being in the range of approximately 5 to 8 μm (micrometers), in one particular configuration, circa 6.3 μm, and a roughness parameter Ra at the bearing ring being in the range of about 1 to 2 μm, in particular circa 1.6 μm.
Furthermore, in yet another alternative arrangement, the flexible seal may be designed to compensate for a radial offset up to approximately 2 mm. A radial offset can be established in the fitted state of the flexible seal and relates in particular to an encircling widened portion, for example of a sealing body of sleeve-like design (elastic formation). The region indicated here firstly ensures secure fixing of the flexible seal and secondly takes into consideration the load-bearing capacity of the materials of the flexible seal for permanent use. On the other hand, it is also possible that a displacement and/or different diameters of the contacting surfaces is compensated by the flexible seal, and in particular only by the deformation of the sealing lip.
According to one development of the disclosure, it is also proposed that the flexible seal may be designed as an annular collar. The flexible seal or the collar may be partly formed from rubber or a comparable elastic material and also from a stiffer material, for example sheet-metal. The term “collar” is intended in particular to express the fact that a more complex construction of the flexible seal is also possible here, for example with structures running in the circumferential direction, a multi-part construction, double-wall constructions, etc. “Annular” is intended in particular to mean here that the collar is of encircling (in particular uninterrupted) design, if appropriate in the manner of a sleeve.
The present disclosure may be used in one example, in a motor vehicle having at least one side shaft toward a wheel, wherein the side shaft and the wheel are connected to each other via a device described according to the disclosure. In one exemplary arrangement, all of the side shafts may be connected to all of the wheels of the motor vehicle via a device of this type. Furthermore, the device itself may be designed with a fixed joint, while a sliding joint is provided on the opposite side of the side shaft.
The disclosure and the technical environment are now illustrated in further detail with reference to the figures. The figures show exemplary embodiments of the disclosure but the disclosure is not restricted to the particular embodiments described herein. Identical parts in the different figures are provided with the same reference numbers. The figures show schematically:
The constant-velocity rotary joint 5 is now attached further to the right in
The transmission of torque from the joint outer part 6 to the wheel hub 2 takes place here via a spur toothing 9 which is formed on the contacting end surfaces of joint outer part 6 and sleeve section 4 of the wheel hub 2. Said spur toothing 9 is now protected, for example, against rust particles and other dirt by a flexible seal 10 which, in one exemplary configuration, is of sleeve-shaped configuration, and completely surrounds the spur toothing 9 radially on the outside being provided. For more detailed illustration of said seal 10, a detail is marked in
For this purpose, the flexible seal 10 is fixed firstly on the joint outer part 6 by means of an elastic sealing lip 13. In this case, the elastic sealing lip 13 is arranged in a frictional manner on a corresponding seat 15 of the joint outer part 6 and holds a sealing body 22 which is of a sleeve-like design. A two-part construction of the flexible seal 10 is therefore provided here. The sealing body 22 extends through the space 37 from the sealing lip 13 to a seat 15 radially on the outside of the wheel-bearing inner ring 11 of the wheel-bearing 12. In this case, the sealing body 22 fits firmly on said seat 15 and forms an encircling contacting surface 14. The contacting surface 14 and the seat 15 of the wheel-bearing inner ring 11 are likewise only connected frictionally to each other. For this purpose, the seat 15 of the wheel-bearing inner ring 11 can be designed, for example, with a particularly rough surface. In the case of the installation situation illustrated here, the sealing body 22 may be designed to undergo deformation in the fitted state, with, in particular, secure fixing of the sealing body 22 on the seat 15 of the wheel-bearing inner ring 11 being ensured. The sealing body 22 is may be widened for this purpose.
The sealing lip 13 therefore tightly butts against the outer part of the joint outer part 6 due to the elastic deformation of the (originally) disk-like shape resulting in a cylindrical contact area after the assembling.
Whereas
In one exemplary arrangement, the sealing body 22 and the flexible seal 10 here have an extent 25 of, for example, at least 10 to 25 mm.
In one exemplary arrangement, the contact region or the contacting surface 14 of the flexible seal 10 on the wheel-bearing inner ring 11 has a width 23 of, for example, 1 to 5 mm. As illustrated here, the sealing body 22 engages around the wheel-bearing inner ring 11 in such a manner that a radial offset 24 is formed. The radial offset 24 is generally about 1 to 2 mm. The sealing body 22 and the sealing lip 13 may, in principle, be manufactured from different materials, with rubber-like materials nevertheless being preferred, but not required.
This application is a National Phase of International Application No. PCT/EP2008/056131, filed on May 19, 2008, which application is hereby incorporated by reference in its entirety.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2008/056131 | 5/19/2008 | WO | 00 | 8/29/2011 |