WO2009053131A1

WO2009053131A1 - Pneumatic vehicle tire

Info

Publication number: WO2009053131A1
Application number: PCT/EP2008/060821
Authority: WO
Inventors: Rüdiger MENZ
Original assignee: Continental Aktiengesellschaft
Priority date: 2007-10-18
Filing date: 2008-08-19
Publication date: 2009-04-30
Also published as: DE102007049872A1

Abstract

The invention relates to a pneumatic vehicle tire, comprising a profiled tread (1), a multi-layer belting (2), an air-tight inside layer (4), a carcass (3) guided around high-tensile cores (6) and core profiles (7) placed on the cores in the bead area (5) from axially inside to axially outside as a carcass riser (3a), side walls (8), and at least one thermally conductive insert (10) closed around the circumference of the tire shoulder in the region of the belt edge, dissipating the heat created during operation of the vehicle tire in the region of the belt edge. The insert (10) for thermal conductivity is made of a rubberized metal material, wherein the material has a thermal conductivity that is greater than 40 (W/m x K).

Description

description

Vehicle tires

The invention relates to a pneumatic vehicle tire, comprising a profiled tread, a multi-layer belt, a hermetically executed inner layer, a carcass, which is guided in the bead area from axially inside to axially outside around tensile cores and the core-sitting core profiles as Karkasshochschlag, side walls and at least one in Area of the belt edge ring-shaped over the circumference of the tire shoulder closed thermally conductive insert, which dissipates the heat generated in the operating state of the pneumatic vehicle tire in the belt edge area.

It is known that, especially in the high-speed operation of tires around the 300 km / h in the belt edges heat, hot spots, arise. Rubber is a poor heat conductor, so that the heat generated during driving can only be dissipated insufficiently. The heat effect of a stationary hot

Spots can lead to fatigue of the rubber material heated over a longer period of time, so that the tire can be premature.

In order to be able to dissipate the heat of the hot spots arising in the belt edge region during high-speed operation, a generic pneumatic vehicle tire has become known, for example, from the patent US Pat. No. 4,362,200. The thermally conductive insert is disposed in the shoulder region of the tire between the belt edge and the inner layer and terminates in the region of the upper side wall, in which a further thermally conductive strip is arranged as part of the tire sidewall overlapping with the thermally conductive insert, over which the resulting heat in the operating condition of the tire should be slid off axially beyond the side wall. The thermally conductive deposits exist made of elastomeric material, which is attached to better heat conduction synthetic graphite. Admittedly, the addition of synthetic graphite improves the thermal conductivity of the elastomeric interlayer mixture. However, there remains a need for a tire having a thermally conductive insert with a significantly higher thermal conductivity, in order to be able to derive the heat generated during driving, especially in high-speed operation of the tire quickly and reliably and thus to improve the fatigue life of the tire. Furthermore, the thermally conductive insert should be as thin and lightweight as possible in order to create a tire whose weight and thus its rolling resistance is increased only insignificantly despite the additional heat-conductive insert. In addition, the tire should be easy and inexpensive to manufacture.

It is the object of the present invention to provide a pneumatic vehicle tire which, especially at high speeds, reliably dissipates the heat generated in stationary hot spots to improve the fatigue life of the tire without substantially changing the weight of the tire or its properties and producing it cost-effectively is.

The object is achieved by the insert for heat conduction consists of a rubberized metallic material and that the material has a thermal conductivity greater than 40 (W / m × K).

It is known that metallic materials are good heat conductors. Through the use of metallic materials, which are preferably rubberized, as a heat-conducting insert, at least in the belt edge region of the tire, a dissipation of the heat of the hot spot or a homogenization of the heat balance is achieved by the high thermal conductivity. A premature failure of the tire is avoided due to thermally induced fatigue of the rubber material in the area of the stationary hot spot. Since metallic materials are good conductors of heat, the heat-conductive insert can be made small in size. Therefore, the weight of the tire is insignificant by the

Use of the heat-conducting insert increases, whereby the rolling resistance hardly changed is. Since only at least one further insert is to be introduced into the tire as a thermally conductive insert, the tire structure can be maintained in the usual way. The tire construction is simple and inexpensive despite at least one additional insert.

The insert may also be arranged annularly closed over the entire cross-sectional width of the belt over the circumference thereof or may be arranged beyond its cross-sectional width.

As thermally conductive metallic materials are, for example, aluminum, galvanized copper, brass, zinc, bronze or steel. Especially copper is very suitable due to its excellent thermal conductivity of 401 (W / m x K). Copper is also slightly brittle and therefore particularly suitable for use as a heat conductor in a liner of a pneumatic vehicle tire. The metallic materials can be treated rubber-friendly for better rubber adhesion in the manner known to those skilled in the art.

The insert may be a rubberized layer of parallel arranged material wires or a rubberized fabric of material wires preferably with a mesh size (w) of about 0.50mm and a wire diameter (d) of 0.05mm. Preferably, copper is used as a material. This latter fabric is relatively light in weight, yet still conducts the heat very well. In addition, the fabric is elastic in limits to allow tire movement while driving. The mesh size is chosen so large that during gumming of this fabric the rubber can penetrate the mesh and a firm tissue / rubber bond is achieved. The fabric may be, for example, a square or a diamond mesh fabric. In a fabric, it may be sufficient for the desired heat conduction, if only one of the two yarn directions of the fabric consists of a thermally conductive metallic material.

In another embodiment, a further thermally conductive insert in the region of the apex is arranged on the outside of the carcass. This further thermally conductive Insert is in a preferred embodiment within the cross-sectional height of the bead region on the axially inner side between the carcass and inner layer, starting at the cross-sectional height of the core remote end of the Kernpro fϊls, and extends outside of the carcass around the core around and is in the other Course on the axially outer side on the carcass between carcass and sidewall rubber reaching to a cross-sectional height of the core remote end of Kernprofϊls reaching arranged.

The bead area of the tire, as defined in this application, extends over a cross-sectional height of the tire that extends from the tire foot to the core-remote end of the core profile.

In a particular embodiment, the pneumatic vehicle tire is a pneumatic vehicle tire with emergency running characteristics in case of compressed air loss, the emergency running property is obtained by arranged in each side wall, in cross-section crescent-shaped reinforcing profiles. Such self-supporting in the event of a breakdown, pneumatic vehicle tires are well known in various embodiments. The introduced in the region of the sidewalls of the tire reinforcing profiles are executed with respect to their cross-sectional shape and their elastomeric mixtures such that they are able to self-sustaining the tire at a loss of air pressure in the event of a breakdown, so that a drive over a certain distance is possible. The reinforcing profile is arranged in the side wall between inner layer and carcass. In the case of loss of compressed air, the self-supporting ability of the run-flat tire is achieved by, inter alia, applying compression to the reinforcing profile arranged in the tire sidewall, while the carcass resting against the reinforcing profile is subjected to tensile stress. Through this interaction of the carcass and reinforcement profile, the tire becomes self-supporting and the seat of the bead profile on the rim is maintained. On the other hand, the reinforcing profiles have the function of "springs" that carry the wheel load in the Obar case.Such runflat tires are called SSR tires.SSR stands for "Seif Supporting Runfiat." On high speed SSR tires, hot spots in the belt edge region can also be used in high speed operation The thermal stress resulting from the hot spots is mitigated by the thermally conductive insert. In a special embodiment of the SSR tire, another heat-conductive insert between reinforcing pro fi le and inner layer is arranged at least within the cross-sectional height of the reinforcing profile, so that the heat from the hot spot of the reinforcing profile in the direction of the belt and / or in the emergency run in the Obar case Direction bead is conductive. It has been shown that in emergency operation, a hot spot on the axially inner side of the reinforcing profile in the region of the greatest compression and shear stress, ie in the kink of the Verstärkungsprofϊls developed. In conventional run-flat tires, this heat can not be sufficiently dissipated due to the poor thermal conductivity of rubber of about 0.3 (W / m × K). According to the present embodiment, the further thermally conductive insert is disposed axially inside adjacent to the Verstärkungspro fϊl and axially inside the occurring in Verstärkungsprofϊl in emergency hot spot. As a result, a reliable heat dissipation and homogenization of the heat balance is possible. It is created a run-flat tire, which is simple in construction and can additionally derive the heat generated in emergency operation of the hot spot in the reinforcement profile. The thermal load of the reinforcing profile is reduced in particular in emergency operation and the service life of the reinforcing profile in emergency operation is extended many times over.

In a particular embodiment of the SSR tire, the insert is between

Inner layer and Verstärkungsprofϊl, starting at least at the radial height of the hot spot, out in the direction of bead around the bead around axially outward and ends axially outside within or just above the cross-sectional height of Wulstkernpro fϊls. Thus, the heat from the interior of the tire to the outside can be derived whereby a particularly effective heat dissipation is achieved. In this case, the insert can be guided axially inward between the core and the rim strip. Thus, a safe rim Aufiage the tire is obtained.

In order to achieve a rapid heat dissipation by the shortest route, it would be advantageous if the material wire, preferably the copper wires, are oriented in the insert in the radial direction. To an elasticity of the insert to the direction of movement of To ensure rubber in the tire, it is advantageous if the wires in an angle different from the radial direction angle, preferably at an angle which includes 45 ° with the radial direction, are arranged. The same applies if a rubberized fabric is used as a thermally conductive insert.

In a preferred embodiment, the material wires, as well as the fabric threads of the insert to achieve a feather-like / elastic effect are arranged wavy in the insert.

In another embodiment, the carcass in addition to their

Carcass strength carriers for heat conduction thermally conductive metal wires, which are preferably aligned in the radial direction. The thermally conductive metal wires in the carcass are arranged in addition to the thermally conductive insert disposed axially inward of and adjacent to the reinforcing profile. The homogenization of the heat balance is further improved.

The term "insert" means a thermally conductive insert as a rubber-friendly finished strip or ply. [0005] Run-flat tires having a thickened sidewall cross-section reinforcing profile are referred to as SSR tires and SSR stands for Seif Supporting Runflat.

Further features, advantages and details of the invention will be explained in more detail with reference to the drawings, which illustrate schematic embodiments. It show the:

1 shows a partial cross section through an SSR pneumatic vehicle tire according to the invention with a thermally conductive insert in the belt area, FIG. 2 shows a partial cross section through another SSR tire.

According to the partial cross section shown in Figure 1 by an SSR radial tire for

Passenger cars are the essential components of which the illustrated Radial tire composed of: a profiled tread 1, in the embodiment shown two layers 2a, 2b existing belt 2, a single-layered carcass 3, a largely airtight executed inner layer 4, beads 5 with bead cores 6 and bead core pro fϊlen 7, and side walls 8 and The crescent-shaped Verstärkungspro file 9. The Verstärkungspro fil 9 may consist of a single rubber compound or several rubber compounds. "SSR" stands for "Seif Support Runflat" and refers to pneumatic vehicle tires with runflat properties due to reinforcing profiles 9 reinforced sidewalls 8. The two layers 2a, 2b of the belt 2 consist of embedded in a rubber compound reinforcements made of steel cord, which run parallel to each other within each layer, wherein the steel cords of the one layer 2a are oriented in crossing relationship with the steel cords of the second layer 2b and each enclose an angle between 20 ° and 35 ° with the tire circumferential direction. Also, the carcass 3 may be carried out in a conventional and known manner and thus embedded in a rubber compound, extending in the radial direction reinforcing threads of a textile material. The carcass 3 is guided around the bead cores 6 from the inside to the outside, their elevations 3a run next to the bead core profile 7 in the direction of the belt 2. The reinforcing profile 9 made of elastomeric material, in particular of a rubber mixture, is on the inner layer 4 during the construction of the tire Therefore, the thickness of the reinforcing profile 9 decreases both in the direction of the belt 2 and the direction of the bead 5. Direction belt 2 extends the Verstärkungspro fil 9 to the same under the edge regions. Direction bead 5 ends the reinforcing profile 9 just above the bead core 6. Over the vast majority of the length of the side wall, the reinforcing profile 9 is made almost constant thick, its thickness is 6 to 15mm. The SSR tire is high-speed capable and designed for up to 300 km / h.

In the high-speed operation of the tire is formed in the belt edge 15, a heat, a so-called hot spot 14. By the heat-conductive insert 10, which is disposed below the belt 2, between this and the carcass 3, the heat of the hot spot 14 for heat homogenization direction Tire equator be dissipated. The insert 10 consists of a rubberized copper mesh of a mesh size (w) of about 0.50mm and a wire diameter (d) of 0.05mm. The fabric is oriented such that the fabric threads enclose an angle of 45 ° to the radial direction. The insert 10 has a width which can exceed the width 2 of the belt, so that the hot spot 14 is at least partially covered by the insert 10. In the present embodiment, the insert 10 is arranged below the entire belt 2 between this and the carcass 3 beyond the belt ends reaching out, so that the insert 10 is wider than the belt 2. The heat is distributed and dissipated through the copper cloth of the insert 10 in the direction of the tire equator. The aforementioned embodiment of FIG. 1 is not limited to only one SSR tire, but is also applicable to high speed non-runflat tires.

FIG. 2 shows a partial cross-section through another high-speed SSR tire according to the invention. This tire differs from the tire shown in Figure 1 in that axially inside J_2 of and adjacent to the reinforcing profile 9 between this and the inner layer 3 in addition over the circumference of the side wall 8 annularly closed heat conductive additional insert 16 contour parallel to the reinforcing profile 9. The thermally conductive insert 16 serves to derive the heat occurring in the Obar case of the hot spot (not shown), which develops due to the high shear stresses in emergency operation of the tire axially inside the reinforcing profile 9 and due to which the resulting run-flat can be reduced, deduce and the Heat balance of the tire to homogenize. The hot spot (not shown) forms in the Obar case at the axially inside J_2 located side of the reinforcing profile 9 in the region of the greatest thrust load, ie approximately at the central cross-sectional height of the reinforcing profile 9. The insert 16 extends at least over a cross-sectional height, the Overlapping of the hot spot (not shown), so starting in a cross-sectional height, which lies in the upper half of the reinforcing profile 9 facing the belt 2 and extends between the inner layer 4 and reinforcing profile 9 in the direction of bead 5 and preferably ends axially adjacent within the cross-sectional height of Bead core 6. The insert 16 has rubberized copper material, as parallel aligned wires or as a copper tissue is present. If the insert 16 has mutually parallel copper wires, these are preferably oriented in a direction deviating from the radial direction in order to ensure an elasticity of the insert 16 to the direction of movement of the rubber of the tire. If the insert 16 has a copper mesh, this preferably consists of a mesh width (w) of approximately 0.50 mm and a wire diameter (d) of 0.05 mm. This fabric is comparatively light, yet still conducts the heat very well and the fabric is elastically elastic to allow tire movement while driving.

LIST OF REFERENCE NUMBERS

(Part of the description)

1 tread

2 belts

2a, b belt layer

3 carcass

3a carcass turn-up

4 inner layer

5 bead

6 bead core

7 bead core profile

8 side wall

9 gain profile

10 Thermally conductive insert

12 Axially inside

13 Axially outside

14 hot spot belt edge

16 Thermally conductive insert

Claims

claims

A pneumatic vehicle tire comprising a profiled tread (1), a multi-layered belt bandage (2), an airtight inner layer (4), a carcass (3) formed in the bead area

(5) from axially inward to axially outward around tensile cores (6) and the core-seated core profiles (7) is guided around as Karkasshochschlag (3 a), sidewalls (8) and at least one closed in the belt edge ring over the circumference of the tire shoulder heat-conductive insert (10), which dissipates the heat generated in the operating state of the pneumatic vehicle tire in the belt edge, characterized in that the insert (10) for heat conduction consists of a rubberized metallic material and that the material has a thermal conductivity greater than 40 (W / mx K ) having.

2. pneumatic vehicle tire according to claim 1, characterized in that the metallic material is aluminum, galvanized copper, brass, zinc, bronze, steel or copper.

3. Pneumatic vehicle tire according to one of the preceding claims, characterized in that the insert (10) is a layer of mutually parallel copper wires, which is preferably rubberized.

4. Pneumatic vehicle tire according to one of the preceding claims, characterized in that the insert (10) is a fabric of copper wires preferably with a mesh size (w) of about 0.50 mm and a wire diameter (d) of 0.05 mm as preferably square mesh or diamond mesh pattern which is preferably rubberized.

5. Pneumatic vehicle tire according to one of the preceding claims, characterized in that the insert (10) is arranged on and / or between and / or under the belt package (2) over its entire width.

6. Pneumatic vehicle tire according to one of the preceding claims, characterized in that the insert (10) on and / or between the and under the belt package (2) on the belt edges (15) is arranged reaching out.

7. pneumatic vehicle tire according to one of the preceding claims, characterized in that a further thermally conductive insert in the region of the apex outside of the carcass (3) is arranged resting.

8. Pneumatic vehicle tire according to at least one of the preceding claims, characterized in that the pneumatic vehicle tire runflat properties

Compressed air loss, the emergency running properties by in each side wall (8) arranged in cross-section crescent-shaped reinforcing profiles (9) is obtained.

9. pneumatic vehicle tire according to claim 8, characterized in that a further insert (16) between the reinforcing profile (9) and inner layer (4) at least within the cross-sectional height of the reinforcing profile (9) is arranged so that the heat from the hot spot (11) of the reinforcing profile (9) in the direction of the belt (2) and / or in the direction of the bead (5) can be guided.

10. pneumatic vehicle tire according to one or more of claims 9, characterized in that the further insert (16) around the bead region (5) from axially inside (12) to axially outside (j_3) is guided and axially outside (13) within or just above the cross-sectional height of the bead (5) ends.

11. Pneumatic vehicle tire according to one of the preceding claims, characterized in that the material wires in the insert (10,16) are oriented in the radial direction.

12. Pneumatic vehicle tire according to one of the preceding claims, characterized in that the material wires of the fabric in the insert (10,16) are oriented differently from the radial direction.

13. Pneumatic vehicle tire according to one of the preceding claims, characterized in that the material wires of the insert (10,16) for

Achieve a feather-like / elastic effect within the insert (10,16) are corrugated.

14. Pneumatic vehicle tire according to one of the preceding claims, characterized in that the carcass (3) in addition to their

Reinforcements for heat conduction has thermally conductive metal wires, which are preferably aligned in the radial direction.