DE102012217040A1 - Air duct arrangement for tire pressure regulation - Google Patents

Abstract

The invention relates to an air guiding arrangement for guiding a tire inflation gas into a system section that runs along on the wheel side. The air guide arrangement according to the invention comprises a sealing ring element, a first sealing lip device formed by the sealing ring element, a second sealing lip device formed by the sealing ring element, an annular space delimited by the sealing ring element, and an annular wall formed by the sealing ring element, which extends into an intermediate area between the two sealing lip devices and comprises an annular space side facing the annular space and an outer side facing away from the annular space. A channel or valve structure is formed in the ring wall which assumes an open position when a structurally defined minimum pressure builds up in the ring chamber.

Description

Field of the invention

The invention relates to an air guide arrangement for a tire pressure regulating device which, as such, makes it possible to form a duct system suitable for supplying compressed air to a system section running on the wheel side in the region of a wheel bearing.

Out DE 10 2006 006 143 A1 an air guide arrangement of the type mentioned is known. This known air duct arrangement comprises a sealing ring designed as a flat ring element of the two sealing lips which, as such, start up permanently dragging on a ring body placed on the sealing ring. The two sealing lips permanently seal off a channel section so that compressed air can be passed through this channel section.

Background of the invention

Tire pressure regulating devices are used in particular to optimize the tire pressure depending on load or terrain. In this case, for example, in loose and muddy ground, the pressure is lowered to achieve a larger Radaufstandsfläche. After crossing such a terrain section, the tire pressure is generally increased again to lower the tire load and the rolling resistance again. There are tire pressure regulating devices with vehicle-side filling system or with wheel-side filling systems such. Radial piston pumps. Tire pressure regulating devices with filling system on the vehicle use rotary unions which are either part of the wheel hub or are additionally mounted on this. These must permanently hold or seal a connection between the tire and the vehicle side.

Wheel-side filling systems require a pump unit in each wheel, which causes correspondingly high costs. In addition, the pump units are in great danger in this exposed position. Permanently sealed and pressurized rotary unions are subject to high wear, which requires a very massive design and regular replacement of wear parts. By control pressure applied seals require in the known variants complex structures with control lines, movement grooves and directional control valves. The execution of all three functions of a tire pressure control system (measuring, filling, draining) via the rotary feedthrough thereby leads to a frequent loading of the sealing system and associated high wear. The above factors all cause high costs, making such tire pressure control systems viable only for special applications (heavy construction and agricultural machinery, military vehicles, etc.).

Object of the invention

The invention has for its object to provide solutions by which it is possible to make a tire pressure regulation in an improved over previous approaches way. In particular, the invention has for its object to provide a rotary feedthrough for a tire pressure control device, which is low maintenance and less expensive than the known variants.

Inventive solution

• – einem Dichtringelement,
• – einer durch das Dichtringelement gebildeten ersten Dichtlippeneinrichtung,
• – einer durch das Dichtringelement gebildeten zweiten Dichtlippeneinrichtung,
• – einem von dem Dichtringelement begrenzten Ringraum, und
• – einer durch das Dichtringelement gebildeten Ringwandung, die sich ein einem zwischen den beiden Dichtlippeneinrichtungen liegenden Zwischenbereich erstreckt und eine dem Ringraum zugewandte Ringraumseite und eine dem Ringraum abgewandte Aussenseite umfasst,
• – wobei in der Ringwandung eine Kanal- oder Ventilstruktur ausgebildet ist, die bei Aufbau eines konstruktiv festgelegten Mindestdruckes in der Ringkammer eine Offenstellung einnimmt.

The above-mentioned object is achieved by an air guide arrangement for guiding a Reifenfüllgases in a wheel-side rotating system section, with:

• A sealing ring element,
• A first sealing lip device formed by the sealing ring element,
• A second sealing lip device formed by the sealing ring element,
• - One of the sealing ring member limited annular space, and
• A ring wall formed by the sealing ring element and extending between an intermediate region lying between the two sealing lip devices and comprising an annular space side facing the annular space and an outer side facing away from the annular space,
• - Wherein a channel or valve structure is formed in the annular wall, which assumes an open position in the construction of a design-defined minimum pressure in the annular chamber.

This advantageously makes it possible to provide an air guide arrangement in which a system pressure can be generated by constructive design of the channel structure formed in the annular wall, which makes it possible to spend the sealing lip device from a wear-resistant passive position in a highly effective sealing state before opening the channel structure , The inventive concept makes it possible to integrate a reliable sealing, durable air guide structure directly into a wheel bearing unit and thus to create a tire pressure regulator which is inexpensive to implement and thus suitable for private off-road, as well as the van sector.

According to a particularly preferred embodiment of the invention, the sealing ring element is designed such that the first sealing lip device and the second sealing lip device according to In accordance with the pressure prevailing in the annular space pressure from a smooth-running position in a sealing position are displaced. In this smooth running position, it may be a position in which at most an extremely low contact pressure between the respective sealing lip device and the tread contacted by this prevails. Preferably, in the smooth running position to a position in which the sealing lip device at most bears against the tread without pressure, preferably stands out from this to form a small running gap. When the respective sealing lip device is moved into that sealing position, the latter contacts the running surface in such a way that essentially no tire filling gas can flow away via the contact zone of the sealing lip device. The sealing ring element is preferably made of an elastomer material, for example NPBR.

At the respective sealing lip device a variety of Filigrangeometrien can be realized. Thus, the respective sealing lip device can form a plurality of circumferential sealing lips, which possibly rest on the respective running surface with different seat forces. Some circumferential sealing lips can act as permanent under low contact pressure on the respective running surface and thereby cause a certain sealing of the lubricant filling an adjacent rolling bearing, further circumferential sealing lips are designed so that they serve for sealing in temporary Druckluftbeaufschlagung, so only be active when in the annulus a corresponding pressure prevails. These circumferential sealing lips are preferably geometrically designed so that they provide a reliable seal and prevention of the passage of air, and are otherwise passive. When adopting the passive position no wear occurs on these special circumferential sealing lips. The function of the air guiding device according to the invention is in this case also guaranteed even if the grease sealing lips provided for the bearing seal are possibly already worn out.

According to a particular aspect of the present invention, the channel structure formed in the annular wall is designed as a slot valve device. This slit valve device can be designed so that it opens upon reaching a predetermined between the annulus side of the annular wall and the outside of the prevailing pressure difference. This pressure difference is for example in the range of 0.2 to 0.4 bar. In the case of the pressure prevailing in the annular chamber, the sealing lip devices of the sealing ring element can be urged highly effectively into an active position.

The inventive concept can be implemented constructively so that the sealing lip devices are displaced radially and / or axially under the effect of the prevailing pressure in the annular chamber. The displacement path is depending on the diameter of the sealing ring element possibly only about 0.1 mm, wherein after contacting the tread under the effect of the chamber pressure of the contact pressure of the respective sealing lip device can be further increased.

The sealing ring element can be used according to a particularly preferred embodiment of the invention in a wheel bearing device. In this case, the sealing ring element is preferably secured to the stationary component of the wheel bearing device. This backup can be done by inserting the sealing ring element under a sufficient interference fit. In an embodiment of a wheel bearing as a multi-row roller bearing, the sealing ring element according to the invention is preferably located in an intermediate region between a first rolling body raceway and a second rolling body raceway.

The air guide arrangement according to the invention can be designed so that it comprises a relatively robust, for example, made of a sheet material or high-strength plastic material support ring comprises on which the sealing ring element is secured. The securing of the sealing ring element can be carried out by the sealing ring element is snapped under temporary elastic deformation on corresponding folding geometries on the support ring. Furthermore, it is also possible to secure the sealing ring element to the support ring by material connection, in particular with this to be glued or to connect it to the support ring by vulcanization.

On the turning side "tire side" a check valve is necessary, which keeps the fed pressure in the tire. Advantageously, this valve is designed so that, starting from a certain, relatively low differential pressure, e.g. in the range of 0.5-0.3 bar (now higher pressure on the rotating side "tire side") opens. From this differential pressure until the tire pressure is reached, air can be removed from the tire back into the feed system. An achieved target pressure is maintained by quickly removing pressure from the supply side so that the differential pressure exceeds 0.5-0.3 bar and then actually close the valve completely.

As an alternative to this special valve design which allows a tire venting practically by setting a temporarily to the tire pressure "approaching from below" filling pressure, a valve provided in the rotating system can also be designed so that this occurs when a certain pressure difference between the tire interior and the Pressure in the stationary filling channel (again higher pressure on the tire side) occupies a blocking position relative to the tire-side channel and at the same time an open position relative to the guided over the wheel bearing channel system. This open position is designed so that it provides only a small, strongly throttling channel. This approach makes it possible to vent the channel system guided via the wheel bearing in such a way that, when the special sealing lips are relieved of pressure, there is no significant residual pressure in the channel section leading to the valve.

The above-described system according to the invention serves primarily to supply and possibly discharge a tire inflation gas, e.g. Air, N2, He, Ne, or CO2. It can also be used to supply other media, in particular fluids / foams, to the interior of a tire, which serve for the interim repair of a puncture, in particular a leak of the tire.

Brief description of the figures

Further details and features of the invention will become apparent from the following description taken in conjunction with the drawings. It shows:

1a a detailed representation of an inventive air duct assembly for a wheel bearing of a vehicle wheel;

1b an axial sectional view of a wheel bearing with an integrated in this invention air duct assembly;

1c a detailed representation of another embodiment of an air guide assembly according to the invention for a wheel bearing of a vehicle wheel;

2a . 2 B in each case a perspective view of a sealing ring element according to the invention with a slit valve;

3 a schematic representation for explaining a variant in which under the pressure prevailing in an annular space pressure initially takes place a radial displacement of the sealing lips;

4a a schematic representation for explaining a variant in which a first under the effect of prevailing in an annular space pressure, an axial displacement of the sealing lips;

4b a schematic representation for explaining a variant in which under the pressure prevailing in an annular space initially an axial displacement of the sealing lips, with a shown, biased check valve;

5 a further schematic representation for explaining various expansion variants of a formed under inclusion of an air guide structure of the invention Raddruckregulierungssystems.

Detailed description of the figures

In 1a is shown in the form of a detailed representation of the structure of an air guide assembly according to the invention. This air guide arrangement serves to guide a Reifenfüllgases from a "stationary" area of a wheel bearing - here specifically a hub carrier 1 - In a wheel side rotating system section - here a hub 2 ,

The air guide arrangement comprises a sealing ring element 3 , This sealing ring element 3 forms a first sealing lip device 3a and a second sealing lip device 3b , The sealing ring element 3 continues to form a ring wall 3c and limited by this one annulus 4 , The ring wall 3c extends in one between the two sealing lip devices 3a . 3b lying intermediate area and forms an annular space 4 facing annular space side 3d and one the annulus 4 opposite outside 3e ,

The sealing ring element shown here 3 is inventively designed such that in the annular wall 3c a channel structure 3f is formed, which only when building a predetermined on the ring wall 3c prevailing minimum pressure difference assumes an open position.

The sealing ring element 3 is inventively further formed such that the first sealing lip device 3a and the second sealing lip device 3b in accordance with the in the annulus 4 prevailing pressure from a smooth running position in a sealing position are displaced. In that smooth running position are the sealing lip devices 3a . 3b not, or under a possibly low contact pressure on the treads 2a . 2 B the wheel hub 2 at.

The channel structure 3f is formed in this embodiment as slit valve means and opens only at the effect of a on the annular wall 3c attacking pressure difference of about 0.3bar. The sealing ring element 3 is here designed such that under the effect of the in the annular chamber 4 prevailing pressure the sealing lip devices 3a . 3b be radially shifted to this on the treads 2a . 2 B sit up sealingly. The Slit valve device 3f ensures a minimum contact pressure.

The sealing ring element shown here 3 is used in a subsequently explained in more detail wheel bearing device and in this case acting on the stationary component hub carrier 1 secured the wheel bearing. The sealing ring element 3 is located in the wheel bearing device in an intermediate region between a first rolling body track B1 and a second rolling body track B2.

The air guide assembly comprises a support ring 5 on which the sealing ring element is secured. The sealing ring element 3 is in this embodiment under temporary elastic deformation of the support ring 5 snapped. It can also be materially connected to this.

The support ring 5 sits under a slight press fit sealingly in an inner bore 1a of the hub carrier 1 , The support ring is made as sheet metal forming part and forms a circumferential groove 5a , This circumferential groove is of a groove bottom 5b limited. In the groove bottom 5b are through holes 5c educated. About these openings 5c he communicates in the hub carrier 1 trained compressed air supply duct 1b with the annulus 4 ,

When loading the compressed air supply duct 1b with compressed air, or another Reifenfüllgas first increases the pressure in the annular chamber 4 ,

The slit valve 3f is still closed. Under the now in the annular chamber 4 prevailing pressure, the two sealing lip devices 3a . 3b against the treads 2a . 2 B crowded and sealed off this. The wheel hub 2 is still under abrasive system of the sealing lip device 3a . 3b opposite the hub carrier 1 rotatable. After further increase of the gas pressure, the ring wall bulges 3c radially inwardly out and the slit valves 3f open up. Now, the compressed gas via the hub-side gas guide channel 2c via other gas guide elements not shown here in the area of the wheel interior drain.

Ideally, an electronically controllable valve device is located in the area of the system section that is running along the wheel side. This preferably includes a check valve and a pressure relief channel via which also the hub-side gas guide channel 2 can be relieved. The gas duct is preferably unwound under the electronic control of corresponding valve members such that at, or slightly before, the interruption of the pressurized gas admission of the gas duct 1b the gas guide channel 2c is relieved. This ensures that any in the gas duct 2c located compressed air with relief of the annular chamber 4 not escaped to the camp.

Furthermore, it is possible in the ring wall 3c trained channel structure 3f That is, to make the slit valves so that they open in the opposite direction under a lower pressure, so that a pressure release in the region of the gas guide channel 2c also about the channel structure 3f can be done.

In 1b illustrates the construction of a wheel bearing, which as such with an air duct arrangement according to the invention 1 Is provided. The air guide arrangement is as stated between the raceways B1, B2 of the rolling elements designed here as balls. The air duct assembly sits in the hub carrier 1 and connects the stationary gas guide channel 1b with the hub-side gas guide channel 2c , The with the sealing lip devices 3a . 3b interacting treads 2a . 2 B are here directly by a correspondingly finely ground surface of the wheel hub 2 educated. It is also possible to form these treads by a ring element on the wheel hub 2 sits and via suitable channel geometries with the gas guide channel 2c communicated. The air guide arrangement according to the invention can then be formed as a cassette element that for the sealing lip devices 3a . 3b provides relevant treads themselves.

The invention provides a sealing system which is integrated into a wheel bearing unit and is applied and pressurized only to fill the tire. The air guiding device according to the invention forms a rotary feedthrough for a wheel bearing unit of the "3" shown here. Generation "in which a part of the Wälzkörperlaufflächen directly through the hub carrier and the hub, as well as through a bearing inner ring 7 provided. The bearing inner ring 7 is on Umformtechnischen ways axially on the wheel hub 2 secured. The seal is only applied to the filling process, which should be kept short by high pressure difference, and applied. In the rest of the operation, the seal is contactless and therefore wear-free.

The functions measuring and discharging are preferably realized by known radio-controlled, wheel-side valve assemblies. Such may be battery operated, or e.g. be powered by an inductor charging device.

The seal is as shown between the rows of balls B1, B2 mounted in the bearing center of gravity (thus resulting in no load by tilting), the fixed mounting on stationary bearing ring or here on the hub carrier 1 takes place in order to realize the desired filling pressure control and to exclude speed-dependent centrifugal force effects. The compressed gas is supplied via the bore 1b in the vehicle-side stationary bearing ring and is distributed over a distributor groove radially on the seal. The seal is designed as a closed cassette with radial or axial sealing surfaces and circumferentially arranged slit valves. The slit valves have a higher opening pressure (eg 0.3 bar) in the filling direction than in the discharge direction (a few mbar). This ensures that when the pressure builds up first, the seal is under internal pressure and the non-contact sealing surfaces in idle 3a . 3b be created. Only after exceeding the opening pressure is a passage of the compressed gas possible. Due to the ratios of inner to outer surfaces of the seal, the force required to apply the sealing surfaces during the filling process remains. The wheel-side fill hole 2c is equipped with a check valve. After the end of the filling process, the vehicle-side pressure line is completely relieved, the check valve closes and the residual pressure in the filling hole escapes back through the slit valve of the seal. Due to the low opening pressure in the discharge direction, the wheel bearing unit is almost completely relieved in the shortest possible time. The provision of the sealing surfaces is done by the elasticity of the sealing material. Any residual pressure in the bearing can escape through the vehicle-side pressure line, since the bearing internal pressure can escape through the slit valves of the seal when not engaged sealing surfaces.

The air guide arrangement according to the invention is particularly suitable for use in conjunction with tire pressure monitoring systems with radio transmission.

In 1c a further embodiment of an air guide arrangement according to the invention for a Fahrzeugradlagerung is shown. The air guide assembly comprises in the same manner as the embodiment of the 1a and 1b a sealing ring element 3 , This sealing ring element 3 forms a first sealing lip device 3a and a second sealing lip device 3b , The sealing ring element 3 continues to form a ring wall 3c and limited by this one annulus 4 , The ring wall 3c extends in one between the two sealing lip devices 3a . 3b lying intermediate area and forms an annular space 4 facing annular space side 3d and one the annulus 4 opposite outside 3e ,

The sealing ring element shown here 3 According to the invention is also designed such that in the annular wall 3c a channel structure 3f is formed, which only when building a predetermined on the ring wall 3c prevailing minimum pressure difference assumes an open position.

The sealing ring element 3 is inventively further formed such that the first sealing lip device 3a and the second sealing lip device 3b in accordance with the in the annulus 4 prevailing pressure from a smooth running position in the sealing position shown here are displaced. In that smooth running position are the sealing lip devices 3a . 3b not, or under a possibly low contact pressure on the treads 2a . 2 B the wheel hub 2 at.

The channel structure 3f is again formed as a slot valve device in this embodiment and opens only at the effect of one on the annular wall 3c attacking pressure difference of about 0.3bar. The sealing ring element 3 is here designed such that under the effect of the in the annular chamber 4 prevailing pressure the sealing lip devices 3a . 3b be radially shifted to this on the treads 2a . 2 B sit up sealingly. The slit valve device 3f ensures a minimum contact pressure. Furthermore, in this embodiment, the support ring 5 designed so that the sealing ring element 3 taken up in this and thus laterally through the support ring 5 is supported. The support ring 5 forms a left and a right ring shoulder 5d . 5e , These ring shoulders 5d . 5e are designed here so that these ring flanks 5f . 5g which as such each provide a cone structure. In each case, a complementarily shaped outer section of the sealing ring element sits in this cone structure 3 , Under the in the annular chamber 4 acting pressure is made of an elastomeric material sealing ring element 3 pushed into the respective cone structure such that the sealing ring element 3 radially narrows and thus with increased contact pressure on the treads 2a . 2 B seated. In the pressure-dependent actuated by this cone mechanism area of the sealing ring element 3 are auxiliary sealing lips 3g . 3h trained this contact the treads 2a . 2 B and provide a certain sealing effect before contacting the treads 2a . 2 B by the likewise pressure-activated sealing lip devices 3a . 3b ready. In addition, these auxiliary sealing lips additionally prevent a passage of compressed air to the web region B1, B2 of the rolling elements and cause a Fettabschottung of the gas guide channel 2c ,

In 2a is the structure of a sealing ring element according to the invention 3 illustrated. In the embodiment shown, the channel structure 3f designed as a cross-slit valve at one of the ring wall 3c attacking pressure difference of about 0.3 bar opens and a gas flow from the annulus 4 in the wheel-side, not shown here channels allows. In Opposite direction open the Phillips valves at a lower pressure difference.

In 2 B is the structure of a slightly modified variant of a sealing ring element according to the invention 3 illustrated. In this second embodiment, the channel structure 3f designed as a straight slot valve which also at one on the ring wall 3c attacking pressure difference of about 0.3 bar opens.

In 3 is in the form of a schematic representation again the basic mechanics of the air duct assembly according to the invention shown. The air guide arrangement serves as an air guide for a tire pressure control and comprises a slot valve-controlled seal F. This consists of a sealing ring element 3 with here radially pressure-controlled displaceable sealing lips 3a . 3b and one between these sealing lips 3a . 3b extending sealing wall 3c , with at least one slit valve 3f ,

The sealing ring element 3 sits in a support ring 5 and is glued in these. The slit valve 3f seals up to the opening pressure (approx. 0.3 bar). This initial pressure pushes the sealing lips 3a . 3b radially against the sealing surfaces 2a . 2 B on the inner ring or on the wheel hub 2 , The air guide arrangement according to the invention allows a secure seal even with slow pressure build-up. The flow only takes place after sealing, so there is no danger of blowing out the bearing grease. The closing force of the respective slit valve 3f can by bringing about a slight angle of attack of the corresponding edges of the annular wall 3c be adjusted for example by slight axial compression of the entire seal. This axial compression can, for example, by axial clamping in the support ring 5 be brought about.

The slot valve structure shown here 3f causes a stronger seal to build up pressure, and a lower opening pressure for emptying the pipe and applying the sealing surfaces by springs during the rotational movement.

4a again shows an air guide assembly for tire pressure control. This air guide arrangement also comprises a slot-valve-controlled seal. In this variant takes place under the effect of in the annular chamber 4 prevailing pressure, an axial displacement of the sealing lip devices 3a . 3b , These are pressure-controlled axially on thrust washers 6a . 6b relocated. This variant requires a relatively small axial space, and allows a relatively simple, robust seal geometry and requires little additional processing on the inner ring IR. The outer ring 1 also forms the stationary component here. At this sits the support ring 5 also the sealing ring element 3 guaranteed. The sealing ring element 3 is in the support ring 5 glued. The slit valve seals up to the opening pressure (approx. 0.3 bar), this initial pressure pushes sealing lips 3a . 3b axially against the sealing surfaces 6c . 6d on the thrust washers 6a . 6b and allows a secure seal even with slow pressure build-up. The flow only takes place after sealing, again there is no danger of blowing out the bearing grease.

The here through the thrust washers 6a . 6b provided sealing surfaces 6c . 6d (axially contacted end surfaces) can also be provided by protrusions formed integrally with the inner ring IR, or by an annular groove.

4b shows the in 4a described air guide assembly, but now with a biased check valve 24 , via which the set pressure is kept in the tire. Since the check valve on the bias voltage upon application of an input pressure already and exceeding a certain differential pressure opens before the tire pressure is reached, can be reduced in the range from opening to reaching the tire pressure, a pressure. If the inlet pressure exceeds the tire pressure, pressure is added to the tire. With abrupt removal of the inlet pressure, the pressure difference rises above the opening differential pressure and the check valve is closed. The set pressure is held.

In 5 are greatly simplified form partially combinable, some alternative details of a formed under inclusion of an air guide structure according to the invention tire pressure regulating illustrated. For purposes of explanation, reference will be made here to an air guide arrangement which essentially follows the air guide arrangement 3 equivalent.

The air guide arrangement shown here is exemplary with discharge channels 8th . 9 Mistake. These relief channels 8th . 9 open into one opposite the sealing edges K1, K2 of the sealing lip devices 3a . 3b axially offset area of the treads 2a . 2 B and allow drainage of any penetrating in this area compressed air. These relief channels 8th . 9 communicate via gas permeable membrane elements 10 . 11 with the environment. Through these relief channels 8th . 9 It is avoided that any compressed air flowing under the sealing edges K1, K2 blows lubricant out of the adjacent bearing.

In the lower half of the drawing, three alternative variants I, II, III of the further design of the wheel bearing provided by the invention to the tire interior, i. Represented as a "running" channel system.

Variant I comprises a check valve 12 which recognizes a blocking position as soon as the pressure P1 in the channel section S1 is smaller than the pressure P2 inside the tire 13 , In this variant, the channel system S1 is filled exclusively by the interior of the tire 13 , The one in the tire 13 Ruling pressure can be due to an electronic circuit 14 detected and by wireless means of a receiving circuit 15 be transmitted. The circuit 14 can be designed so that it can be controlled via this one valve device which possibly a tire venting via the outlet indicated here 16 allows. The system by variant 1 allows a reliable blocking of the channel section S1 against pressure losses and provides over the circuits 14 . 15 the functions "pressure measurement" and "pressure reduction".

Variant II includes a check valve 17 whose switching state is adjustable over the difference of the pressures P1, P2. The check valve 17 can be designed so that this "still" or "already" is open when the pressure in the system section S1 about 0.3 to 0.5 bar below the pressure in the tire 13 lies. This makes it possible to gently reduce the tire pressure P2 by setting in the system section S1 a pressure of about 0.3 to 0.5 bar below the current tire pressure. The check valve 17 takes an open position with this small pressure difference and that in the tire 13 located gas can flow gently through the system section S1. This special function can be realized by various valve mechanisms. By way of example only, an embodiment is shown in which the valve member 18 is designed as a stepped piston. Due to the forces generated by the different piston surfaces forces the valve member 18 even under the pressure P1 are forced into an open position when this up to a certain value under the pressure P2 of the tire 13 lies. If the pressure P1 is within the tire with a predetermined maximum difference under the pressure P2 13 , so via the valve 17 an airflow from the tire 13 , If the pressure P1 is greater than the pressure P2, there is an air flow and thus a filling of the tire. If, for example, the pressure P1 is lowered to ambient pressure, the permissible maximum difference is exceeded and the valve member 18 moves into a blocking position and the tire pressure P2 is maintained.

Variant III illustrates a valve concept in which, similar to variant II, the pressure in the tire is controlled by actuating pressure P1 to a level just below tire pressure P2 13 can be reduced. Deviating from the variant II, however, takes place here, the derivative of the tire air selectively into the environment. The valve shown here 19 is constructed so that this is a valve member 20 includes that can be brought in three switch positions. In the first switching position, the valve is locked. This first switching position takes the valve member 20 when the pressure P1 is substantially equal to or at least very low. If the pressure P1 is increased, the valve member moves 20 against the restoring force of a calibrated spring 21 , The valve member 20 reaches the deflation position shown here as soon as the pressure P1 is about 0.3 to 0.5 bar below the tire pressure P2. In this position, air flows out of the tire 13 from. If the pressure P1 is further increased, the valve member moves 20 in an end position in which the valve channel 22 with the valve channel 23 communicates and the discharge channel is closed. Now, the already at an increased pressure level tire inflation gas in the interior of the tire 13 stream. When the desired tire pressure is reached, the pressurization of the system section S1 is ended and the valve 19 passes through the return flow of the valve member in a safe locking state which allows no airflow.

The valve alternatives described here 12 . 17 . 19 are preferably mounted in or on the pressure hoses, pressure pipes or pressure channels which connect the bearing with the tire.

LIST OF REFERENCE NUMBERS

1

 hub carrier

1b

Compressed air supply duct

2

 wheel hub

2a

 tread

2 B

tread

2c

Gas duct

3

 Seal element

3a

Sealing lip means

3b

 Sealing lip means

3c

annular wall

3d

Annulus side

3e

outside

3f

Channel structure / slit valve

4

 annulus

5

 support ring

5a

circumferential groove

5b

groove bottom

5c

Through openings

6c

sealing surface

6d

sealing surface

6a

thrust washer

6b

thrust washer

7

 Bearing inner ring

B1

 career

B2

 career

IR

 inner ring

8th

 relief channel

9

 relief channel

K1

 sealing edge

K2

 sealing edge

10

 membrane element

11

 membrane element

12

 check valve

13

 tire

14

 circuit

15

 receiving circuit

16

 outlet

17

 check valve

18

 valve member

19

 Valve

20

 valve member

21

 feather

22

valve channel

23

 valve channel

24

 check valve

S1

 channel section

P1

 print

P2

 print

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102006006143 A1 [0002]

Claims (10)

Air guiding arrangement for guiding a tire filling gas over the area of a wheel bearing in a system section co-rotating on the wheel side, comprising: - a sealing ring element ( 3 ), - one through the sealing ring element ( 3 ) formed first sealing lip device ( 3a ), - one through the sealing ring element ( 3 ) formed second sealing lip device ( 3b ), - one of the sealing ring element ( 3 ) limited annulus ( 4 ), and - one through the sealing ring element ( 3 ) formed annular wall ( 3c ) located in one between the two sealing lip devices ( 3a . 3b ) lying intermediate region and a the annular space ( 4 ) facing annular space side ( 3d ) and one of the annulus ( 4 ) facing away from outside ( 3e ), - wherein in the annular wall ( 3c ) a channel structure ( 3f ) is formed, which assumes an open position when building predetermined pressure conditions. Air duct arrangement according to claim 1, characterized in that the sealing ring element ( 3 ) is formed such that the first sealing lip device ( 3a ) and the second sealing lip device ( 3b ) in accordance with the in the annulus ( 4 ) prevailing pressure from a smooth running position in a sealing position are displaced. Air duct arrangement according to claim 1 or 2, characterized in that the channel structure ( 3f ) is designed as a slot valve device. Air duct arrangement according to at least one of claims 1 to 3, characterized in that the sealing ring element ( 3 ) is designed such that under the action of the in the annular chamber ( 4 ) pressure the sealing lip devices ( 3a . 3b ) are displaced radially. Air duct arrangement according to at least one of claims 1 to 4, characterized in that the sealing ring element ( 3 ) is designed such that under the action of the in the annular chamber ( 4 ) pressure the sealing lip devices ( 3a . 3b ) are axially displaced. Air duct arrangement according to at least one of claims 1 to 5, characterized in that the sealing ring element ( 3 ) is inserted into a wheel bearing device, and that the sealing ring element ( 3 ) is secured to the stationary component of the wheel bearing device. Air duct arrangement according to at least one of claims 1 to 6, characterized in that the sealing ring element ( 3 ) is located in the wheel bearing device in an intermediate region between a first rolling body raceway (B1) and a second rolling body raceway (B2), and / or that the air guide arrangement comprises a supporting ring ( 5 ) comprises at which the sealing ring element ( 3 ) is secured or guided. Air duct arrangement according to at least one of claims 1 to 7, characterized in that the sealing ring element ( 3 ) to the support ring ( 5 ), or vulcanized to the support ring, or under temporary elastic deformation of the support ring ( 5 ) is snapped. Air duct arrangement according to at least one of claims 1 to 8, characterized in that it forms part of a tire pressure regulating system, and in that this tire pressure regulating system comprises a valve device ( 12 . 17 . 19 ) which makes it possible to block the return flow of tire inflation gas to the air guide assembly. Air duct arrangement according to claim 9, characterized in that that valve device as a check valve ( 12 ), biased check valve, or as a differential pressure-controlled switching valve ( 17 . 19 ) is executed.

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