WO2014056492A1 - Wheel bearing cover - Google Patents

Description

 Name of the invention

Wheel bearing cover Description

Field of the invention

The invention relates to a wheel bearing cover for a wheel bearing and a wheel bearing equipped therewith.

Background of the invention

There are various ways known to provide a wheel bearing with a speed and / or rotation angle detection function.

One possibility is to provide the wheel bearing with an encoder ring, which is read by means of a sensor attached to the wheel. For this, however, the wheel carrier must have a corresponding bracket. Another possibility is to position a sensor in a continuous opening in a wheel bearing cover. However, gaps may arise between the section of the wheel bearing cover surrounding the continuous opening and the sensor, for example in the case of temperature fluctuations and / or mechanical loads, through which water can penetrate into the wheel bearing. Summary of the invention

Object of the present invention is to provide a way to provide by means of which a wheel bearing in a simple and cost-effective manner with a speed and / or rotational angle detection function, provided and a reliable seal the wheel bearing can be realized.

This object is achieved by a wheel bearing cover for a wheel bearing, which comprises a, in particular completely closed lid body made of a magnetically permeable metallic material and a sensor carrier for a magnetic field sensor, wherein the, in particular made of plastic, sensor carrier on the outer side in the mounting position of the lid body fastened or fastened, in particular injected, is.

Under a wheel bearing can be understood in particular an arrangement comprising a wheel bearing. In addition to the actual wheel bearing and its components, a wheel bearing other components, such as a lid, a bearing seat, et cetera include.

The fact that the wheel bearing cover has a closed lid main body, advantageously otherwise possible leaks or leaks, for example, through openings and / or by, for example, temperature fluctuations and / or mechanical stresses resulting, gaps between individual components or materials can be removed or avoided. Thus, advantageously, penetration of water into the storage can be avoided. By the lid body can thus advantageously an improved seal, especially in a fit fit, and thus a reliable sealing of the wheel bearing can be achieved. Thus, in turn, advantageously corrosion damage to the wheel bearing can be reduced or avoided. A magnetically permeable material may, in particular, be understood as meaning a material which has a sufficiently high permeability in order to measure and / or induce a magnetic field through the material. For example, the magnetically permeable material may be a non-ferromagnetic and / or non-ferrimagnetic and / or non-magnetic material. In particular, the magnetically permeable material may be a non-ferromagnetic material, for example an austenitic alloy.

Due to the fact that the cover base body is formed from a magnetically permeable, for example non-ferromagnetic material, the magnetic field measurement and possibly also magnetic field induction can be effected by the magnetic field sensor through the cover main body or a magnetic field which is variable in time, for example Lid body are transmitted through, which in turn makes it possible to attach a magnetic field sensor on the outer side in the mounting position of the lid main body and to design the lid body closed. Thus, both a reliable sealing of the wheel bearing and the wheel bearing in a simple manner, in particular by means of a simple assembly and handling of the wheel bearing cover and in particular without additional modification of the wheel carrier, with a speed and / or Drehwinkelermittlungsfunkti- on, for example, to control a ABS system, be provided.

The fact that the cover body is formed of a metallic material, advantageously a high mechanical stability of the lid body can be achieved. This also has an advantageous effect on the reliability of the Radlagerabdichtung through the wheel bearing cover. For example, a metallic lid body can ensure a reliable seal even in the case of a pressure difference between the bearing interior and the environment. An embodiment of the sensor carrier made of a plastic and, for example, spraying of the sensor carrier on the lid base body have the advantage that the wheel bearing cover can be produced in a particularly simple and cost-effective manner.

The sensor carrier may for example be in the form of a dome or possibly also in the form of a ring, for example a sprayed retaining ring. In particular, the magnetic field sensor in the sensor carrier can be aligned such that the magnetic field measurement is performed by the lid base body.

The magnetic field sensor can be designed in particular for measuring time-variable magnetic fields. In particular, the magnetic field sensor may be a sensor of a rotational speed and / or rotational angle determination system, which comprises an encoder (rotary encoder), for example in the form of a so-called encoder ring. In this case, the encoder can in particular be mounted or mounted on a rotatable component of the wheel bearing. In this case, the magnetic field sensor can be stationary with respect to the encoder and in particular represent the actively measuring unit of the rotational speed and / or rotational angle determination system. The rotational speed and / or the angle of rotation of the rotatable wheel bearing component and thus of the wheel can be detected or ascertainable by the magnetic field sensor on the basis of a magnetic field change based on a rotation of the encoder. The encoder can be, for example, a permanent magnetic encoder, for example a so-called multipole encoder, or a passive encoder, for example in the form of a perforated plate made of a magnetizable and / or magnetically conductive material. The sensor may be, for example, a Hall sensor or another magnetic field sensor. The speed and / or rotation angle detection system can be used, for example, for an ABS system. In this case, the magnetic field sensor can be referred to as ABS sensor. In the context of one embodiment, the lid base body is in the form of a sheet, for example a sheet metal cap. Thus, the lid base body advantageously particularly simple, for example by deep drawing and / or embossing, are produced. In addition, a sheet-like lid basic body can advantageously be realized with a low weight.

In the context of a further embodiment, the lid body is made of an austenitic alloy, for example an austenitic (noble) steel, for example V2A steel. Austenitic alloys have proved to be particularly advantageous as magnetically permeable and, in particular, non-ferromagnetic materials for forming the cover body. Optionally, the lid body may be formed of aluminum or an aluminum alloy.

The magnetic field sensor can be fastened or fastened on the sensor carrier both detachably and non-detachably.

In the context of a further embodiment, the magnetic field sensor can be fastened or fastened to the sensor carrier by means of a screw connection or click connection (latching connection / snap connection). In particular, the magnetic field sensor can be fastened or fastened to the sensor carrier by means of a detachable click connection. By a screw connection or a detachable click connection, the sensor can be advantageously mounted and dismantled in a simple manner and optionally also replaced, in particular without having to replace the cover body and sensor carrier. By a non-detachable click connection advantageously at least the mounting of the sensor can be simplified.

In a further embodiment, the magnetic field sensor is encapsulated with the plastic of the sensor carrier. For example, in this case the magnetic field sensor can be positively locked to the sensor carrier, in particular in a non-detachable manner. to be bound. Thus, advantageously, the production can be simplified. An exchange of the sensor then usually requires a removal and replacement of the wheel bearing cover. In the context of a further embodiment, the lid base body has at least one undercut section, in which the plastic of the sensor carrier is injected and / or which is encapsulated with the plastic of the sensor carrier. Thus, advantageously, a form-fitting and mechanically stable connection between the lid base body and the sensor carrier can be realized.

The undercut or sections may be formed in the lid body, for example, by depressions, for example, grooves, and / or protrusions. In the case of a sheet-metal lid main body, intersected sections can be formed, for example, by puncturing of the sheet-metal lid main body, in particular non-continuous.

In principle, many different embodiments of undercut sections are possible. However, the cover base body preferably has at least one undercut section that does not run around or extends radially undercut. Thus, advantageously, the undercut section can serve for positioning the sensor in the direction of rotation and for preventing rotation of the sensor carrier and thus also of the sensor.

Within the scope of a further embodiment, therefore, the lid base body has at least one undercut section with a radial extension and / or with a circumferentially limited extension, in which the plastic of the sensor carrier is injected and / or which is encapsulated with the plastic of the sensor carrier.

The terms radial and axial refer in the context of the invention to the axis of rotation of the wheel bearing. The attachment of the wheel bearing cover to the wheel bearing can be done in particular by means of a radially outer edge portion of the lid body.

In the context of a further embodiment, the cover base body has a, in particular radially outer, fastening section for fastening the wheel bearing cover to the wheel bearing. The attachment can be done for example by means of a press fit. The attachment portion may be designed in particular to form a radially resilient interference fit with the wheel bearing. The operation of the attachment portion may be similar to the operation of a cover of a paint tin. For example, the mounting portion for a press fit may be designed in an inner diameter of the wheel bearing and / or on an outer diameter of the wheel bearing. For example, the mounting portion for a press fit in and / or on an outer ring of the wheel bearing or in and / or on an associated component, such as an outer ßenringflansch or a bearing seat, designed.

In the context of one embodiment, the attachment portion has a radially resilient portion. By this section, for example, the radially resilient interference fit - for example, similar to a lid of a tinplate - can be formed. The radially resilient portion may in particular have an axial extent.

Optionally, a suspension cavity may be provided to provide space for radial spring movement of the radially resilient portion or a tolerance range for the radially resilient portion. For example, a mechanical load on the plastic of the sensor carrier can be avoided. In the context of a further embodiment, the attachment portion has an axial stop. The axial stop may in particular have a radial extent. In the context of another embodiment, the attachment portion is partially encapsulated with the plastic of the sensor carrier. Thus, advantageously, an additional sealing effect or a sealing seat can be achieved by the plastic material. In particular, the axial stop can be encapsulated with the plastic of the sensor carrier. Optionally, in addition, the radially resilient portion may be partially encapsulated with the plastic of the sensor carrier.

The wheel bearing cover may in particular be a cover for a wheel bearing for a motor vehicle, for example a passenger car or a truck.

The wheel bearing cover can be used both for wheel bearings with speed and / or rotational angle detection function, for example ABS function, as well as for wheel bearings without speed and / or rotation angle detection function, such as ABS function.

The wheel bearing can be both a non-driven and a driven wheel bearing. In particular, the wheel bearing can be a non-driven wheel bearing, in particular with rotational speed and / or rotational angle detection function, for example ABS function.

Another object is a wheel bearing, in particular for a motor vehicle, which comprises a wheel bearing cover according to the invention.

The wheel bearing may in particular comprise a rolling bearing with an outer ring and an inner ring. In this case, the inner ring, for example, rotatable and the outer ring with respect to the inner ring be formed standing. The inner ring can be connectable or connected to the vehicle wheel and the outer ring with the vehicle. In principle, however, a reverse arrangement is possible.

The motor vehicle may be, for example, a passenger car or a truck.

The wheel bearing cover can in particular be fastened or fastened to the wheel bearing by means of the fastening section of the cover body. The attachment can be done in particular by means of a press fit. The attachment portion may form a radially resilient interference fit, in particular with the wheel bearing - similar to the operation of a cover of a paint tin can - form. The interference fit can take place in an inner diameter of the wheel bearing and / or on an outer diameter of the wheel bearing.

For example, the wheel bearing cover can be fastened or fastened by means of a press fit on the outer ring or a component assigned to the outer ring, for example outer ring flange or bearing seat. The outer ring associated with the component may be connected to the outer ring, with the outer ring in one piece or loosely arranged with respect to the outer ring. For example, the attachment portion of the lid main body may form a press fit in and / or on the outer ring of the wheel bearing or in and / or on a component associated with the outer ring, for example an outer ring flange or a bearing seat. The wheel bearing may further comprise an encoder, in particular encoder ring. The encoder can be arranged in particular within the wheel bearing and, for example, adjacent to the wheel bearing cover. The encoder can also by means of a press fit on a component of the be mounted or fastened mounting. For example, the encoder can be fastened or fastened by means of a press fit on the inner ring or a component assigned to the inner ring, for example inner ring flange. The component associated with the inner ring can in this case be connected to the inner ring or arranged in one piece with the inner ring or loose relative to the inner ring.

For example, the encoder may have an attachment portion, for example annular, which forms a press fit in and / or on the inner ring of the wheel bearing or in and / or on a component associated with the inner ring, for example an inner ring flange. The attachment portion of the encoder may have a substantially axial extent. In order to simplify the assembly of the encoder, the encoder may additionally have a, for example, likewise annular, auxiliary assembly section, for example auxiliary installation end section, with a substantially radial extension. During assembly of the encoder, an axial force can be exerted thereon in order to push the fastening section of the encoder to form the interference fit in an axial direction over or into the corresponding component of the wheel bearing.

To encode a signal, the encoder has in particular a coding section. With respect to the axis of rotation of the wheel bearing, the coding portion may have an axial, radial or oblique extent. The magnetic field sensor of the wheel bearing cover can, for example, be arranged or arranged axially or radially adjacent to the coding section. The wheel bearing can be both a non-driven and a driven wheel bearing. In particular, the wheel bearing can be a non-driven wheel bearing, for example with rotational speed and / or rotational angle determination function, for example ABS function. BRIEF DESCRIPTION OF THE DRAWING The invention is explained below by way of example with reference to the appended drawings with reference to preferred exemplary embodiments, wherein the features illustrated below may represent an aspect of the invention both individually and in combination. 1 shows a schematic cross section through a wheel bearing with an embodiment of a wheel bearing cover according to the invention with an inner circumferential interference fit an unimpacted axial stop and a screwed sensor,

2 shows a schematic cross section through a wheel bearing with a further embodiment of a wheel bearing cover according to the invention with an inner circumferential interference fit, an unimpacted axial stop and a screwed sensor.

3 shows schematic cross sections through wheel bearings with a further embodiment of a wheel bearing cover according to the invention with an inner circumferential press fit with a spring cavity, an unimpacted axial stop and a screwed sensor;

 4 shows a schematic cross section through a wheel bearing with a further embodiment of a wheel bearing cover according to the invention with an outer circumferential interference fit, an unimpacted axial stop and a screwed sensor;

 5 shows a schematic cross section through a wheel bearing with a further embodiment of a wheel bearing cover according to the invention with an inner circumferential press fit, an overmolded axial stop and a bolted sensor;

6 shows a schematic cross section through a wheel bearing with a further embodiment of a wheel bearing cover according to the invention with an inner circumferential press fit with a partial overmolded radially resilient portion, an overmolded axial stop and a bolted sensor;

7 shows a schematic cross section through a wheel bearing with a further embodiment of a wheel bearing cover according to the invention with an inner circumferential press fit, an unimpacted axial stop and a sensor fastened by means of a detachable click connection;

 8 shows a schematic cross section through a wheel bearing with a further embodiment of a wheel bearing cover according to the invention with an inner circumferential press fit, an unimpacted axial stop and an overmolded sensor;

9 shows a schematic cross-section through a wheel bearing with a further embodiment of a wheel bearing cover according to the invention with an outer circumferential interference fit, an unimpreciated axial stop and an overmolded sensor;

 10 shows a schematic cross section through a wheel bearing with a further embodiment of a wheel bearing cover according to the invention with an inner circumferential interference fit, an unimpacted axial stop and an overmolded sensor; and

Fig. 1 1 is a highly schematic view in the direction of the axis of rotation to illustrate different embodiments of wheel bearing covers according to the invention.

Detailed description of the drawing

Figures 1 to 1 1 show different embodiments of wheel bearing units 20, which are sealed by different embodiments of inventive wheel bearing cover 10.

The embodiments shown in Figures 1 to 1 1 comprise a rolling bearing with an outer ring 21, an inner ring 22 and arranged therebetween rolling elements 23. The dashed line indicate that for the inner ring 22 - as well as for the outer ring 21 (not specifically indicated by dashed line) -various embodiments are possible, in the context of which the inner ring 22 (or the outer ring 21) on the one hand both one-piece and multi-part and on the other partially or completely with another Component 22a, for example, flange, connected or in one piece or possibly also in this regard 22a may be arranged loosely. In the context of the embodiments shown in Figures 1 to 1 1, the inner ring 22 is rotatable and the outer ring 21 with respect to the inner ring 22 is arranged standing. The vehicle wheel (not shown) can be connected, for example, to inner ring 21 or its flange 21 a, wherein the wheel bearing 20 via the outer ring 21 or via an outer ring 21 associated component, such as a Außenringflansch (not shown) to the vehicle (not shown) can be connected.

FIGS. 1 to 1 1 show that the wheel bearing has an encoder 24 with a coding section 24 a, a fastening section 24 b and an auxiliary mounting section 24 c, which is fastened by means of a press fit to the outer circumference of the inner ring 21. The mounting portion 24b of the encoder is annular and has an axial Erstre- ckung. The mounting auxiliary portion 24c is also annular, but formed with a radial extent at one end portion of the encoder 24 and serves to simplify the assembly of the encoder 24, in which during assembly of the encoder 24, an axial force can be exerted on the auxiliary mounting portion 24c to To push the mounting portion 24b of the encoder 24 in an axial direction over the inner ring 22 of the wheel bearing 20 to form the press fit.

The encoders 24 shown in FIGS. 1 to 11 differ from one another in the extent of their coding section 24a. In the context of the embodiments shown in FIGS. 1, 3, 5, 6 and 8, the coding sections 24a have an oblique extension with respect to the axis of rotation R of the wheel bearings 20, whereas the coding sections 24a in FIG Frame of the embodiments shown in Figures 2, 4, 7 and 9 have a radial extent with respect to the axis of rotation R of the wheel bearings 20 and the coding portion 24a in the embodiment shown in Figure 10 with respect to the axis of rotation R of the wheel bearing 20 has an axial extent.

In the embodiments shown in FIGS. 1 to 10, the wheel bearing covers 10 each have a magnetic field sensor 13, which is arranged axially adjacent to the coding section 24a of the respective encoder 24. In the embodiment shown in FIG. 10, in which the coding section 24a has an axial extent, the magnetic field sensor 13 is arranged radially adjacent to the coding section 24a. In this case, the magnetic field is measured through the magnetically permeable metallic material of a arranged between the encoder 24 and the sensor 13 closed lid main body 1 1 therethrough. With regard to the coding section 24a of the respective encoder 24, the reading position of the sensor 13 in the context of the embodiments shown in FIGS. 1, 3, 5, 6 and 8 can be inclined, in the context of the embodiments shown in FIGS. 2, 4, 7 and 9 be referred to as axial and in the context of the embodiment shown in Figure 10 as radial.

FIGS. 1 to 1 1 show that the different embodiments of wheel bearing lids 10 according to the invention shown therein each have a closed lid base 1 1 made of a magnetically permeable, for example non-ferromagnetic, metallic material, for example V2A steel. The magnetic field sensor 13 is attached to a sensor carrier 12 made of plastic, which is sprayed onto the outer side in the assembled position of the lid body 1 1. In the context of the embodiment shown in FIGS. 1 to 6, the magnetic field sensor 13 is fastened to the sensor carrier 12 by means of a detachable screw connection 14. In the context of the embodiment shown in FIG. 7, the magnetic field sensor 13 is connected by means of a detachable click connection attached to the sensor carrier 12, the click mechanism - similar to a network connector or detachable cable ties - can be solved by pressing one or more levers. In the context of the embodiments shown in FIGS. 8 to 10, the magnetic field sensor 13 is encapsulated with the plastic of the sensor carrier 12 and is connected to the sensor carrier 12 in a form-fitting and inseparable manner.

Figures 1 to 1 1 show that the lid base body 1 1 is formed in each case in the form of a sheet. In this case, the lid body 1 1 each at least one undercut portion 1 1 a, in which the plastic of the sensor carrier 12 is injected. Thus, a positive and mechanically stable connection between the lid body 1 1 and the plastic of the sensor carrier 12 can be effected. Figure 1 1 illustrates that the undercut portion 1 1 a preferably has a radial extent and / or a circumferentially limited extent. Thus, the undercut portion 1 1 a advantageously used in addition to the sensor orientation and as anti-rotation.

Figures 1 to 10 further show that the lid body 1 1 each having a radially outer mounting portion 1 1 b, 1 1 c, via which the wheel bearing cover 10 is fixed to the wheel bearing 20 by means of a press fit. To form the interference fit, the attachment portion 1 1 b, 1 1 c of the cover base body 1 1 while a radially resilient portion 1 1 b on. In addition, the attachment portion 1 1 b, 1 1 c of the cover body 1 1 an axial stop 1 1 c. FIG. 3 shows that optionally a spring cavity 1 1 d can be provided in order to provide space for a radial spring movement of the radially resilient portion 11 b or a tolerance range for the radially resilient portion 11b, for example a mechanical load on the spring Plastic to avoid the sensor carrier 12.

In the context of the embodiments shown in FIGS. 1 to 3, 5 to 8 and 10, the attachment section 1 1 b of the cover base body 1 1 forms ins ins i i in particular its radially resilient portion 1 1 b, a press fit in the inner circumference of the outer ring 21, so that the wheel bearing cover 10 seals the inner diameter of the outer ring 21. In the context of the embodiments shown in Figures 4 and 9 of the mounting portion 1 1 b of the lid body 1 1, in particular its radially resilient portion 1 1 b, a press fit on the outer circumference of the outer ring 21, so that the wheel bearing cover 10, the outer diameter of the outer ring 21st seals. In the context of the embodiments shown in Figures 1 to 4 and 7 to 10 of the radially resilient portion 1 1 b and the axial stop 1 1 c of the lid body 1 1 lie directly on the outer ring 21 at. In the context of the embodiments shown in Figures 5 and 6, however, the axial stop 1 1 c is overmolded with the plastic of the sensor carrier 12, so that between the axial stop 1 1 c of the lid body 1 1 and the outer ring 21, in particular the axial side of the Outer ring 21, plastic material is arranged, which forms an axial sealing seat. In the context of the embodiment shown in FIG. 6, the radially resilient section 11b is additionally partially encapsulated with the plastic of the sensor carrier 12, so that additionally a radial sealing seat is formed. In this way, advantageously, the sealing effect of the wheel bearing cover 10 can be improved.

FIG. 11 is a highly schematized view in the direction of the axis of rotation R and illustrates different embodiments of wheel bearing lids 10 according to the invention. The dashed lines illustrate that the sensor carrier 12 can be designed in the form of a dome of different shape. Optionally, the sensor carrier 12 may also be configured in the form of a ring (not shown). The finely dotted lines illustrate by way of example positions in which undercut sections 11a with a radial extent and a circumferentially limited extent can be formed. The dot-dash line exemplifies a possible position for the sensor 13. The rough dotted line exemplifies a possible position for a screw 14. Reference number list Wheel bearing cover

 Lid body

a undercut portion of the lid body b radially resilient portion of the lid body c axial stop of the lid body d suspension cavity

 sensor support

 magnetic field sensor

 screw

 click connection

 Rotary axle wheel bearing

 outer ring

 inner ring

a flange of the inner ring

 rolling elements

 encoder

a Encoding section of the encoder

b Mounting section of the encoder

c Mounting aid section of the encoder

Claims

Patent claims 1 . Wheel bearing cover (10) for a wheel bearing (20), in particular for a motor vehicle, comprising a closed cover base body (1 1) made of a magnetically permeable metallic material and a sensor carrier (12) for a magnetic field sensor (13), the sensor carrier (12) being made of Plastic is formed and is sprayed onto the outer side of the lid base body (1 1) in the assembly position. 2. Wheel bearing cover (10) according to claim 1, wherein the cover base body (1 1) is designed in the form of a sheet metal. 3. Wheel bearing cover (10) according to claim 1 or 2, wherein the cover base body (1 1) is made of an austenitic alloy, in particular V2A steel. 4. Wheel bearing cover (10) according to one of claims 1 to 3, wherein the magnetic field sensor (13) can be attached or attached to the sensor carrier (12) by means of a screw connection (14) or click connection (15), or wherein the magnetic field sensor (13) is encapsulated with the plastic of the sensor carrier (12). 5. Wheel bearing cover (10) according to one of claims 1 to 4, wherein the cover base body (1 1) has at least one undercut section (1 1 a), into which the plastic of the sensor carrier (12) is injected and / or which is encapsulated with the plastic of the sensor carrier (12). Wheel bearing cover (10) according to one of claims 1 to 5, wherein the cover base body (1 1) has at least one undercut section (1 1 a) with a radial extent and / or with a circumferentially limited extent, in which the plastic of the sensor carrier (12 ) is injected and/or which is encapsulated with the plastic of the sensor carrier (12). Wheel bearing cover (10) according to one of claims 1 to 6, wherein the cover base body (1 1) has a fastening section (1 1 b, 1 1 c) for fastening the wheel bearing cover (10) to the wheel bearing (20) by means of a press fit, in particular wherein the fastening section (1 1 b, 1 1 c) is designed for a press fit in an inner diameter of the wheel bearing (20) and / or on an outer diameter of the wheel bearing (20). 8. Wheel bearing cover (10) according to one of claims 1 to 7, wherein the fastening section (1 1 b, 1 1 c) has a radially resilient section (1 1 b) and / or an axial stop (1 1 c). 9. Wheel bearing cover (10) according to one of claims 1 to 8, wherein the fastening section (1 1 b, 1 1 c), in particular its axial stop (1 1 c) and / or its radially resilient section (1 1 b), partially is encapsulated with the plastic of the sensor carrier (12). 10. Wheel bearing (20) for a motor vehicle, comprising a wheel bearing cover (10) according to one of claims 1 to 9.