EP1023192A2

EP1023192A2 - Vehicle wheel with an emergency running support body

Info

Publication number: EP1023192A2
Application number: EP98963404A
Authority: EP
Inventors: Michael Glinz; Hans Bernd Hellweg
Original assignee: Continental AG
Current assignee: Continental AG
Priority date: 1997-10-15
Filing date: 1998-10-15
Publication date: 2000-08-02
Also published as: CZ292889B6; HU220811B1; CZ20001359A3; KR20010031129A; DE19745409C2; WO1999019158A3; US6463976B1; JP2001519279A; PL340387A1; HUP0004278A3; DE19745409A1; WO1999019158A2; HUP0004278A2

Abstract

The invention relates to a vehicle wheel with an emergency running support body for a pneumatic tire mounted on a wheel rim. Said tire essentially comprises a running strip, two sidewalls, a carcass, reinforcing elements, and two tire beads provided with bead cores. According to the invention, the emergency running support body (2) is configured as a shell-shaped ring body (3) inside the pneumatic tire. The ring body has an emergency running surface which supports the tire when damaged and supports itself with both axially outward facing wall areas (6, 7) thereof by means of ring-shaped supporting elements on the wheel rim. At least three parts consist of shell-shaped ring bodies (3) and two ring-shaped supporting elements, whereby at least one of the parts, said parts constructing the emergency running support body (2), is constructed as a separate component which is first complementary to the emergency running support body when the tire is being mounted on the rim.

Description

description

Vehicle wheel with an emergency running support body

The invention relates to a vehicle wheel with a run-flat support body for a pneumatic tire fastened to a wheel rim, which essentially has a tread, two side walls, a carcass, reinforcing elements and two tire beads provided with bead cores, in which the run-flat support body is designed as a bowl-shaped ring body within the pneumatic tire which has an emergency running surface supporting the tire in the event of damage and is supported on the wheel rim with its two axially outer wall regions via annular support elements.

A wheel provided with an emergency running support body is disclosed in DE-OS 35 07 046, the emergency running body shown there consisting of an outer metallic stiffening ring and a cushion ring arranged between the stiffening ring and the rim. With such a wheel, it is necessary that the emergency running support body and the wheel are applied to the rim in a comprehensive assembly, the emergency running body and the stiffening ring in particular having to be carefully fixed in the deep rim bed. Disadvantageously, an assembly which can be carried out in a reasonable time and without great effort is not possible with this system.

US Pat. No. 3,610,308 shows a runflat tire in which the tire beads extend toward the inside of the tire and are designed as runflat bodies against which the underside of the tire tread can rest. Such a design of an emergency running body, however, due to the relatively narrow contact surface that is available in emergency running for the installation of the tread, a heavy load and premature wear of the rubbing or sliding rubber parts. In addition, the tire beads, which are designed as emergency run support bodies, can also move into the deep rim and thus promote peeling of the tire. The disadvantage of such peeling in emergency running is somewhat reduced by a solution, such as is disclosed in DE-AS 10 22 483, in which projections are arranged below the tread on the surface facing the tire cavity, which provide an effective connection between transverse forces the tread and the emergency rings on the tire beads. The manufacture of such a tire provided with protrusions is relatively complex and, in addition, the manufacture of tires with run-flat support bodies must be specifically adapted and planned in deviation from the normal production process.

The invention was therefore based on the object of providing a vehicle wheel for pneumatic tires with an emergency running support body, which can be easily and without special effort also mounted on conventional drop center rims, which maintains safe driving behavior and a sufficiently elastic rolling in emergency running, which transmit cornering forces without excessive weight increase can and safely counteracts peeling of the tire, and which flexibly allows the - also subsequent - combination with already existing tire types and assemblies, so that separate production and logistics do not necessarily have to be maintained.

This task is solved by the features of the main claim. Further advantageous developments are characterized in the subclaims.

Here, at least one of the at least three parts, which form the emergency running support body, and is composed of a shell-shaped ring body and at least two annular supporting elements, is designed as a separate component that only completes the emergency running support body when the tire is mounted on the rim.

The formation of the parts forming the emergency run support body in a manner that enables completion only during assembly allows, in addition to a hitherto unequaled variable design of the emergency run support body, also a pre-production or partial production level of an emergency run support body which can be adapted to any rim and tire shape, and which corresponds to the respective allows optimal consideration of geometric conditions.

At least one of the axially outer wall areas of the bowl-shaped ring body is advantageously detachably connected to the associated first annular support element and at least the second ring-shaped support element belonging to the other of the axially outer wall areas of the bowl-shaped ring body is in the axial direction Direction elastically deformable and / or pivotable.

The detachable connection allows an extremely simple assembly of the tire on the rim, in which the cup-shaped ring body - possibly in conjunction with other parts - is initially placed loosely within the tire cavity and in the usual way first a tire bead and optionally as part of the run-flat support body first support element over the drop center onto which a rim shoulder is fitted. Then the releasable connection between the cup-shaped ring body located in the tire cavity and the first support element can be closed after the ring body has been positioned accordingly.

Due to the design of the second ring-shaped support element as being elastically deformable and / or pivotable in the axial direction, the second support body is elastically molded towards the center of the tire during assembly for mounting the second tire bead, so that the second tire bead can slide into the drop center. The tire bead is then lifted onto the rim shoulder, the second support element elastically following the tire bead and springing back next to and adjacent to it into the original position, so that radial loads can be absorbed.

The elasticity of the second support element is dimensioned in such a way that there is sufficient restoring force to overcome the rim hump, which fixes both the support element and the tire bead lying above it in its position on the inside.

In the same way, if a tire change becomes necessary due to the corresponding mileage, the cup-shaped ring body already in the tire cavity can be released in its connection with the associated support element, after which the tire can be pulled off the rim and replaced without further problems, while the others Elements, but at least the cup-shaped ring body, can continue to be used with a new tire.

Advantageously, the supports of at least the first support element on the rim and / or the associated releasable connection are designed as latching or snap connections.

This makes installation easier and at the same time appropriate elastic design of the locking or snap mechanisms allows easy and accurate positioning of the ring body. When replacing the tire, such a snap-in or snap-in connection is just as easy to loosen and to be precisely positioned again.

In an advantageous further development, the releasable connection between the one axially outer wall region of the shell-shaped ring body and the associated first ring-shaped support element and its support on the rim is designed as a fixed bearing for the ring body, which acts in the axial and radial direction after wheel mounting.

The support element designed as a fixed bearing has an annular collar for receiving the radially outer wall regions of the bowl-shaped ring body, which axially and radially fixes the bowl-shaped ring body. With the help of such a collar, both a fixation of the ring body to the support element and a releasable connection can be implemented equally simply and in both cases leads to a secure support and mounting and to the construction of a highly resilient emergency running support body.

Such a design also provides a secure fixation of the cup-shaped ring body or the entire emergency running support body already during assembly, which means a clear relief for the mounting of the second tire bead. On the other hand, it is also possible in this way to check the correct fit and the positioning of the cup-shaped ring body before mounting the second tire bead and thus to guarantee an extraordinarily safe emergency operation function without great installation effort.

Corresponding to such a construction, the other of the axially outer wall regions of the cup-shaped ring body is then firmly and positively connected to the associated second ring-shaped support element, the support of the second ring-shaped support element on the rim being designed as a floating bearing in the axial direction .

In particular, in conjunction with a first connection designed as a snap or snap-in connection between the outer wall areas and the first support body, this configuration can provide partial preassembly, namely the shell-shaped ring body and the second support element, which do the assembly and mounting of the tire on the rim further relieved. In addition, the design as a floating bearing in connection with the fixed bearing arranged on the other side results in a desired tolerance for manufacturing and assembly inaccuracies during assembly with simultaneous high-precision positioning of the shell-shaped ring body due to the fixed bearing.

This advantage is retained even when operating under unfavorable loads, since with such a design neither dynamic loads nor temperature influences can adversely affect the correct fit of the cup-shaped ring body relative to the tire, which is defined by the fixed bearing.

The interaction of the previously mentioned features results in a further great advantage of the design according to the invention in that the cross-section of the support element extending inwards into the tire cavity can be adapted to the requirements during assembly and to the operating behavior in emergency operation. As a rule, this leads to the fact that the support elements for the outer wall areas of the bowl-shaped ring body are designed asymmetrically in such a way that the first ring-shaped support element installed first, for example, already has an axial stop for the ring body and a support or contact surface designed for holding during the assembly having.

The advantage of the above-mentioned training is further that the vehicle wheel according to the invention provided with such an emergency running body is not dependent on or adapted to a special rim shape or rim construction and is adapted to each rim, e.g. B. every car drop center rim is to be applied, which can also be used for conventional tire types without runflat support systems or bodies.

Such an adjustment of the cross-section can also be achieved by a different size with the same cross-sectional shape of the support elements.

In addition, with the design of the vehicle wheel according to the invention, it is possible to use conventional tire types only by completing and combining them with other adapted components for providing an emergency running property.

Ultimately, the construction of the emergency running property or the emergency running support body can be carried out at any time during the construction of the vehicle wheel according to the invention or carried out after tire assembly, whereas previously it had always been necessary to decide within production planning when and which quantities of tire types with run-flat properties were to be produced.

Advantageously, at least one of the support elements is designed as a rubber-elastic component of the tire which is connected to the tire beads and extends essentially inward within the tire cavity.

Depending on the material selected for the support elements, their connection to the tire beads can now take place at different times, for example by vulcanizing directly during the vulcanization of the finished tire or by cold vulcanization or gluing in a special "finishing shop" or also directly at the tire supplier or in the company that pulls the tire onto the rim.

A further advantageous embodiment consists in that at least one of the support elements is attached to the tire beads by foaming an elastic liquid foam that is curable in a mold before the tire is mounted on the rim. Spraying a foam into a position that can be positioned in relation to the tire beads results in a very good adaptation of the support elements to the surface of the tire beads and, after the foam has cured, a very durable connection.

Advantageously, the second annular support element beneath the positive and / or non-positive fixed connection to the outer wall areas of the cup-shaped ring body has an incision which runs over the circumference and extends transversely to the circumferential direction from the tire side to the center of the tire over a partial width of the support element.

In this way, it is achieved that in the cross-section of the support element a narrow zone is formed which is flexible with regard to the bending stiffness and which permits particularly simple deformation or an articulation-like folding of the support element and thus a further simplified assembly.

While avoiding axial forces is so much easier, the absorption of radial forces is not restricted, so that after the spring-back into the support position, the annular support element is fully operational. With the appropriate training, the mounting of the second tire bead on the rim shoulder is here temporary storage in the rim well just as easily as would be the case without a support element and ring body.

As already mentioned above, the division of functions into floating bearings and fixed bearings and the other features mentioned above result in the advantage that the cross section, in particular of the connecting area designed as a floating bearing, can be arbitrarily adapted in its shape to the best possible compromise between ease of installation and excellent product properties in operation can be.

For this purpose, the minimum inner diameter of the tread area of the tire in the compressed state advantageously exceeds the maximum outer diameter of the cup-shaped ring body by at least 35 mm. The inner diameter of the tread area in the sprung-in state is to be understood as the diameter which is calculated from the "static radius", which is reduced by the total thickness of the tread and then doubled, the static radius being the radius, which is the plumb line from the wheel axle to the outside of the Tire contact area is felled when the vehicle is stationary.

In addition to the reduction of the mass of the support element as such, the moving masses are also centered and connected to the rims, which results in a high tolerance to imbalance influences in the operating state. The weight of the wheel is only increased slightly. In addition, an excellent emergency running behavior and the possibility of being able to provide such an emergency running system for almost every height-width ratio of a tire are achieved by the arrangement of the cup-shaped ring body close to the rim.

The shell-shaped ring body is advantageously designed as a non-closed slot ring. This results in a further possibility of downsizing the support elements and arranging all emergency running components close to the rim. Due to the slot-shaped design, the shell-shaped ring body or its outer wall areas can be produced in diameters that do not or only slightly exceed the diameter of the rim flange or rim. During assembly, such a design provides the possibility of inserting the slotted ring into the tire cavity by helical rebounding after a tire bead has already been fixed on the rim shoulder. After insertion, the bowl-shaped ring body then takes its original shape with less Diameters.

An advantageous further development of this design consists in that at least one expansion element, which acts during assembly and increases the diameter of the annular body, is arranged in the slot region of the annular body and produces a slightly enlarged assembly diameter, so that the insert into the tire cavity can be carried out without problems. If the ring body then lies in the tire cavity, the slot can be closed by snapping it in, for example by pressing in a spreading spring, so that the ring body is returned to its reduced operating diameter. When changing the tire, the spreading spring can then snap back into its holding position by spreading the tire body with a tool, after which the ring body can be removed and, if necessary, inserted within a new tire.

In particular when used in connection with a slotted ring, a further advantageous embodiment results from the fact that at least one of the axially outer wall regions of the bowl-shaped ring body has a clamping profile at its end region, the associated supporting element being complementary to this and having a negative shape corresponding to the clamping profile .

The support element can then be easily pushed in the circumferential direction onto an axially outer wall area of the expanded ring body, as a result of which a secure connection is established which, depending on the elasticity of the support element, is almost undetachable in the radial direction.

On the other hand, with such a design, with a correspondingly high elasticity of the support element and with an adaptation of the clamping profile, there is a further possibility of forming a snap or snap connection.

In a further advantageous embodiment, one or more spring-elastic elements are arranged between the ring-shaped support elements and distributed over the rim circumference and axially spreading the support elements. In particular when the shell-shaped ring body is designed as a slotted ring with a clamping profile and complementary support elements, this can compensate for an approximately reduced pretension of the support elements in the axial direction and a lack of contact with the tire beads. Furthermore, a vehicle wheel is disclosed with a run-flat support body for a pneumatic tire fastened to a wheel rim, which essentially has a tread, two side walls, a carcass, reinforcement elements and two tire beads provided with bead cores, in which the run-flat support body is designed as a cup-shaped ring body within the pneumatic tire , which has an emergency running surface supporting the tire in the event of damage and is supported with its two axially outer wall regions via annular support elements on the wheel rim, in which the cup-shaped annular body has rubber-elastic pads on its emergency running surface. Such a training significantly increases the driving comfort available in emergency running.

The cross-section of the ring-shaped support elements can of course also be made variable over the circumference, for example for reasons of weight reduction. Forms are conceivable here in which the support on the rim is only in regions at a distance of 60 ° in each case over the circumference, so that the support elements rest against the rim shoulder only via the regionally arranged “support feet” and the intermediate regions are bridged by reduced cross sections . Likewise, only the width of the support elements can be reduced in regions over the circumference.

The invention is to be illustrated in more detail using an exemplary embodiment.

Show it

1 shows a vehicle wheel according to the invention with emergency running support body in cross section, FIG. 2 shows an intermediate step in the assembly of the one shown in FIG

3 another vehicle wheel according to the invention with emergency running body in

Cross section Fig. 4 shows a vehicle wheel according to the invention with a support element and an incision extending over a partial width of the support element.

FIG. 1 shows a vehicle wheel 1 which is provided with an emergency running support body 2, which essentially consists of the shell-shaped ring body 3 within the pneumatic tire and the support elements 4 and 5 for the two axially outer wall regions 6 and 7 of the ring body 3. Also can be seen a commercially available drop center rim 8 with the rim flange diameter 9. One axially outer wall region 7 of the shell-shaped ring body 3 is detachably connected to the associated first ring-shaped support element 4 via a snap connection 10.

The latching function can in principle be implemented either in the ring-shaped support element or in the bowl-shaped ring body or, as shown here, in both. The bowl-shaped ring body also has a certain elasticity in its outer wall areas. The support element 4 also consists of an elastic, namely a rubber-elastic material, and can elastically deflect when the support body is pushed into the locking groove on the mounting flank 11.

In the exemplary embodiment shown here, the assembly includes, in order, the pulling of the tire bead 12 through the drop center 13 into its position on the rim shoulder 14, after which the support element 4 as a ring is also supported by the drop center and ultimately by the rim hump 15 Position is introduced. During assembly, the shell-shaped annular body 3, the other of the axially outer wall regions 6 of which is already firmly connected to the second annular support element 5 in a positive and / or non-positive manner, is inserted into the tire cavity.

The next step then consists in that the shell-shaped ring body 3 is pressed into the latching connection 10 and is already completely axially and radially fixed there in the form of a fixed bearing.

The connection of the other of the axially outer wall regions 6 of the shell-shaped ring body 3 to the second ring-shaped support element can be carried out by vulcanization or also by connecting elements.

The support element 5 is designed in such a way that, despite the basic fixation by the hump 16, there is a floating bearing function and sufficient elasticity that it can be easily folded in or elastically bent toward the inside, as a result of which the second tire bead 17 can slide into the deep bed 13 , so that tire mounting is possible without any problems. FIG. 2 shows the corresponding intermediate step in the assembly, in which the support element 5 has already been folded over and the tire bead 17 has entered the drop center. After the tire bead 17 is also fixed on the second rim shoulder, the support element 5 springs back into its original position and thus back into the operating position. If the elasticity for the springback is not sufficient, one or more spring-elastic elements can be arranged between the ring-shaped support elements and axially spreading the support elements, which compensate for a lack of contact with the tire beads.

With such a design, the emergency running support body is fixed as a fixed bearing Losiagersystem within the tire cavity, can absorb all forces occurring in emergency running and can be easily replaced when changing the tire by performing the steps already described in reverse order.

It is also clearly visible in this embodiment that the inner diameter of the axially outer wall regions 7 corresponds approximately to the outer rim flange diameter 9.

3 shows another vehicle wheel 18 according to the invention with a slotted emergency running support body 19 in cross section, in which the axially outer wall regions 20 and 21 of the cup-shaped ring body 22 have clamping profiles 25 and 26 at their end regions 23 and 24, the associated supporting elements 27 and

28 are complementary to this and one of the bracketing profile

29 have a corresponding negative form.

FIG. 4 shows a vehicle wheel 30 according to the invention with a support element 31 and an incision 32 which extends over a partial width of the support element 31 and which permits particularly simple deformation or an articulation-like folding down of the support element and thus a further simplified assembly.

Reference list

1 vehicle wheel

2 emergency support bodies

3 bowl-shaped ring body 4, 5 support element

6, 7 axially outer wall area

8 drop center rim

9 rim flange diameter

10 locking connection

11 mounting flank

12 tire bead

13 low bed

14 rim shoulder 15, 16 rim hump

17 tire bead

18 vehicle wheel

19 run-flat support body

20, 21 axially outer wall area 22 shell-shaped ring body 23, 24 clamping profile 25, 26 support element

27 vehicle wheel

28 support element

29 section

30 circumferential incision

Claims

Vehicle wheel with an emergency running support body

1. Vehicle wheel with a run-flat support body for a pneumatic tire fastened to a wheel rim, which essentially has a tread, two side walls, a carcass, reinforcing elements and two tire beads provided with bead cores, in which the run-flat support body is designed as a cup-shaped ring body within the pneumatic tire, which has an emergency running surface supporting the tire in the event of damage and is supported with its two axially outer wall areas via ring-shaped support elements on the wheel rim, characterized in that at least one of the at least three parts which form the run-flat support body and consist of a shell-shaped ring body and two ring-shaped support elements as a separate and first part when the tire is mounted on the rim, the component that completes the run-flat support body is formed.

2. Vehicle wheel according to claim 1, characterized in that at least one of the axially outer wall regions of the cup-shaped ring body is releasably connected to the associated first annular support element and at least the other of the axially outer wall regions of the cup-shaped ring body associated second annular support element is elastically deformable in the axial direction and / or is designed to be pivotable.

3. Vehicle wheel according to claim 1 or 2, characterized in that the support of at least the first support element on the rim and / or the associated releasable connection are designed as a latching or snap connection.

4. Vehicle wheel according to claim 1 to 3, characterized in that at least one of the support elements as a connected to the tire beads and extending within the tire cavity substantially inwardly extending rubber elastic Part of the tire is formed.

5. Vehicle wheel according to claim 1 to 4, characterized in that at least one of the support elements consists of elastic curable liquid foam and is connected to the tire rim by foaming with a tire bead before the vulcanized and assembled pneumatic tire is mounted.

6. Vehicle wheel according to claim 1 to 5, characterized in that the releasable connection between the one axially outer wall region of the cup-shaped annular body and the associated first annular support element and its support on the rim as a fixed bearing for the wheel assembly in the axial and radial direction the ring body are formed.

7. Vehicle wheel according to claim 1 to 6, characterized in that the second annular support element below the positive and / or non-positive fixed connection with the outer wall regions of the cup-shaped ring body a circumferential and transverse to the circumferential direction from the tire side to the center of the tire has an incision extending over a partial width of the support element.

8. Vehicle wheel according to one or more of the preceding claims, characterized in that the minimum inner diameter of the tread of the tire in the compressed state exceeds the maximum outer diameter of the cup-shaped ring body by at least 35 mm.

9. Vehicle wheel according to claim 8, characterized in that the cup-shaped ring body is designed as a non-closed slot ring.

10. Vehicle wheel according to claim 9, characterized in that at least one of the axially outer wall regions of the cup-shaped ring body has a Verklammerunng profile at its end region, the associated support element being complementary thereto and having a negative shape corresponding to the Verklammerunng profile.

1 1. Vehicle wheel according to claim 9 or 10, characterized in that in the slot area of the ring body at least one acting during assembly and the diameter of the 'ring body expanding element is arranged.

12. Vehicle wheel according to one or more of the preceding claims, characterized in that between the annular support elements one or more distributed over the rim circumference and the support elements axially spreading spring-elastic elements are arranged.

13. Vehicle wheel with a run-flat support body for a pneumatic tire fastened to a wheel rim, which essentially has a tread, two side walls, a carcass, reinforcing elements and two tire beads provided with bead cores, in which the run-flat support body is designed as a cup-shaped ring body within the pneumatic tire, which has an emergency running surface supporting the tire in the event of damage and is supported with its two axially outer wall regions via annular support elements on the wheel rim, characterized in that the cup-shaped annular body has rubber-elastic pads on its emergency running surface.