DE102016216072A1 - Commercial vehicle tires - Google Patents

Abstract

The invention relates to a commercial vehicle tire, in particular OTR tires, radial or diagonal design with a multi-layer in the radial direction consisting of rubber tread (1) with a tread base (8) and a tread cap containing the profiling (9), wherein the tread (1). in the Reifenzenit at the equatorial plane has a thickness (d ₁ ) of 12.0 mm to 70.0 mm.
The tread cap (9) has in the radial direction at least two cap layers (9a, 9b), wherein the radially outermost cap layer (9b) in the Reifenzenit at the equatorial plane has a thickness (d ₃ ) of 10% to 70% of the thickness (d ₁ ) of the tread (1) and wherein the rubber material of the radially outermost cap layer (9b) has an elongation at break according to DIN 53504 of 600% to 900%.

Description

The invention relates to a commercial vehicle tire, in particular OTR tire, radial or diagonal design with a radially multi-layer consisting of rubber material tread with a tread base and a tread cap containing the profiling, wherein the tread in Reifenzenit at the equatorial plane has a thickness of 12.0 mm up to 70.0 mm.

So-called OTR tires are intended for special applications, in particular as tires for special vehicles in underground or surface mining. In mines, OTR tires are exposed to extreme debris, mud, water, heat and the like. These stresses can lead to the occurrence of "Chip & Chunk" effects in the known OTR tires in the tread, among which striking damage to the tread, especially deep cuts, but also exfoliations, breakouts and the like are understood. If such tread damage occurs, the tires must be replaced. In particular, in mines known OTR tires can only be traversed to about 50% of their tread depth, since then already present in the tread incisions no longer allow further use of the tire.

Therefore, it is important that treads of commercial vehicle tires provided for the above purposes have a high resistance to chipping & chunking. The usual "chipping & chunking" optimized rubber materials for treads are not suitable for this particular application because of their low rigidity. For a high crack resistance of the rubber materials, it is customary to provide the rubber mixtures underlying these rubber materials with large amounts of fillers. The low rigidity and the large filler quantities lead to an increased specific heat build-up under dynamic load. This occurs in radial tires, in particular in the area of the belt edges and in bias tires, in particular in the area of the breaker, with the increased heat build-up having a particularly disadvantageous effect on the tire durability. In particular, such commercial vehicle tires have a low "TKPH value" (tons per kilometer per hour, "tonne-kilometers per hour). This provides information about the transport capacity of a commercial vehicle tire and serves to determine the optimal performance of a tire. It specifies the operating hours which should be followed to prevent damage to the rubber components due to overheating and is directly proportional to the rated load of the tire and the average speed. In particular, for tires used in mines on special vehicles, a sufficiently high TKPH value is of great importance. Due to the low TKPH value of the known tires, however, it is necessary to limit the operating time depending on the respective tire load.

The invention is therefore based on the object in a commercial vehicle tire of the type mentioned to increase the resistance of its tread to "chipping and chunking" without reducing the TKPH value of the tire.

This object is achieved in that the tread cap in the radial direction has at least two cap layers, wherein the radially outermost cap layer in Reifenzenit at the equatorial plane has a thickness of 10% to 70% of the thickness of the tread and wherein the rubber material of the radially outermost cap layer an elongation at break according to DIN 53504 from 600% to 900%.

A commercial vehicle tire designed according to the invention thus has a tread that is at least three layers in the radial direction. The rubber material of the radially outermost cap layer of the tread is particularly resistant to cracking due to its high elongation at break, so that treads of commercial vehicle tires according to the invention withstand the extreme loads occurring when driving in mines and the like much better than the known treads. Because the radially outermost cap layer gives the tread a very high resistance to "chipping and chunking", it is possible in a commercial vehicle tire according to the invention to design radially further inner layers of the tread with regard to a low heat buildup. Commercial vehicle tires according to the invention can therefore also have a high TKPH value and are therefore particularly suitable for special vehicles used in underground or overground mining.

A particularly high TKPH value while maintaining a high "Chip & Chunk" resistance is given to the tread, when the rubber material of the radially outermost cap layer has an elongation at break of 650% to 750%, preferably of at least 700%.

In a preferred embodiment, the rubber material of the radially outermost cap layer has a tension value at 300% elongation DIN 53504 from 4.0 MPa to 10.0 MPa, preferably at most 6.0 MPa. The test by DIN 53504 Therefore, the stress / strain curve obtained shows a "flat" course. As a result, stresses in the rubber material of the radially outermost cap layer are evenly distributed over a large volume range of this cap layer, as a result of which hardly crack-initiating voltage peaks occur and thus the resistance to "chipping and chunking" is additionally increased.

Further, it is advantageous for a high "chip &chunk" resistance if the rubber material of the radially outermost cap layer is a high-speed breaking elongation according to US Pat DIN EN 10 045 from 18 MJ / m ³ to 25 MJ / m ³ , in particular from 19 MJ / m ³ to 21 MJ / m ³ .

In particular, by adapting the thicknesses of the cap layers, the properties of the tread can be optimally adapted to the respective application. In this context, it is advantageous if the radially outermost cap layer in Reifenzenit along the equatorial plane has a thickness of 20% to 40% of the thickness of the tread.

In a further preferred embodiment, the rubber material of the radially outermost cap layer has a Shore A hardness according to DIN-ISO 7619-1 from 50 Shore A to 80 Shore A, especially from 65 Shore A to 75 Shore A, on.

In a further preferred embodiment variant, the rubber materials of the cap layers correspond to matching Shore A hardnesses DIN-ISO 7619-1 or by at most 4.0 Shore A, in particular by at most 2.0 Shore A, Shore A hardness differing from one another.

According to a further preferred embodiment variant, the rubber material of the radially innermost cap layer directly adjoining the tread base corresponds to a temperature DIN 53533 at a static stress of 0.9 MPa and a dynamic stress of ± 0.8 MPa from 60 ° C to 85 ° C. This is particularly advantageous in view of the conflict of objectives existing between the "chip &chunk" resistance of the rubber material and the extent of heat build-up under dynamic loading, since the innermost cap layer heats only slightly under dynamic load.

In a further preferred embodiment variant, the rubber material of the radially innermost cap layer directly adjoining the tread base has higher rebound resilience at room temperature and at 70 ° C. DIN 53512 as the rubber material of the radially outermost cap layer, the rubber material of the radially innermost cap layer having a rebound resilience at room temperature of 30% to 60%, in particular 40% to 50%, and a rebound resilience at 70 ° C of 45% to 75%, in particular from 55% to 65%. Therefore, the radially innermost cap layer is particularly easy again from the recorded during rolling mechanical energy, without converting them into heat, which contributes to a particularly advantageous solution of the conflict mentioned above.

According to a further preferred embodiment variant, the rubber material of the radially innermost cap layer directly adjoining the tread base has a stress value at 300% elongation of 8.0 MPa to 12.0 MPa, so that the test results by DIN 53504 obtained stress / strain curve shows a "steep" course, which also keeps low the heat buildup in the rubber material under dynamic stress and thus also keeps the rubber-inherent deformability and the resulting heat buildup low.

For the "chip &chunk" resistance of the tread, it is also advantageous if the rubber material of the immediately adjacent to the tread base radially innermost cap layer has an elongation at break according to DIN 53512 from 450% to 700%, especially from 530% to 600%. In this embodiment, therefore, in addition to the outermost cap layer and the innermost cap layer is optimized in terms of their "chip &Chunk" resistance.

Preferably, the rubber material of the radially outermost cap layer is made of a rubber mixture which contains at least one styrene-butadiene rubber (SBR), in particular at least one emulsion-polymerized styrene-butadiene rubber (E-SBR).

Furthermore, it is advantageous if the rubber material of the radially outermost cap layer is made of a rubber mixture which contains at least one resin.

In a preferred embodiment, the rubber material of the radially outermost cap layer is made of a rubber mixture which contains exclusively carbon black as filler, in particular at least one carbon black with an iodine adsorption number of at most 125 g / kg and a DBP number of at most 115 × 10 ^{. 5} m ³ / kg and further at least one resin (a resin).

In a further preferred embodiment variant, the rubber material of the radially innermost cap layer directly adjoining the tread base is made of a rubber mixture which contains 80 phr to 100 phr of natural rubber, up to 20 phr of silica and up to 15 phr of plasticizer.

Further features, advantages and details of the invention will now be described with reference to the single FIGURE. 1 , which schematically shows a cross section through a commercial vehicle tire in the region of the tread and the belt bandage with an embodiment variant of the invention, explained in more detail.

In the following description, as well as in Table 1, the quantities of the components of rubber mixtures in the customary in rubber technology unit phr (Parts per hundred parts rubber). The quantities are based in each case on 100 parts by mass of the base polymer or, in the case of polymer blends, on those of the base polymers.

Commercial vehicle tires designed according to the invention are tires of radial or diagonal design for off-road use (OTR (Off-The-Road) tires), in particular commercial vehicle tires for special vehicles used in underground or overground mining. The invention will be explained below with reference to a radial tire.

In 1 are of the essential components of a commercial vehicle tire in radial design a tread 1 , a multi-layered belt bandage 2 , Sections of a multi-layered carcass ply 3 and an airtight inner layer 4 and the radially outer end portions of side walls 5 shown. The carcass insert 3 , the inner layer 4 and the side walls 5 can be carried out in a conventional manner.

The belt bandage 2 has in the embodiment shown four belt layers 2a . 2 B . 2c . 2d on, each consisting of mutually substantially parallel steel cords, which are embedded in a rubber compound exist. The steel cords run at the usual acute angles to the tire circumferential direction, with the steel cords of adjacent belt plies preferably crossing each other in a known manner.

In each shoulder region of the utility vehicle tire is radially outside the carcass ply 3 a shoulder pad 6 arranged, which in contact with the carcass 3 from the respective side wall 5 under the radially innermost belt layer 2a a piece hineinerstreckt and there runs out in cross section. Radially outside the shoulder pad 6 runs in each case a narrow Gürtelkantenpolster 7 which extends below the respective marginal edge of the second belt layer 2 B hineinerstreckt and at the edge of the radially innermost belt layer 2a ends.

The tread 1 can be structured in a block-like manner by grooves in a conventional manner and has a substantially constant thickness in the radial direction of its profile negatives, such as grooves, cuts and the like, free areas, the profile positive, wherein the tread 1 slightly thicker in the shoulder areas than in the wider middle area. In Reifenzenit points the tread 1 at the equatorial plane, which in 1 indicated by the line l ₁ , a thickness d ₁ of 12.0 mm to 70.0 mm, which in the radial direction between the radially outermost belt ply, in the illustrated embodiment of the fourth belt ply 2d , and one the tread 1 Envelope containing the tread outer surface is determined.

The tread 1 is constructed in three layers in the radial direction and consists of a tread base 8th and a tread cap containing the profiling 9 together, with the tread cap 9 in the radial direction at the equatorial plane has a thickness d ₂ of 60% to 95% of the thickness d _{1 of} the tread 1 having. The tread cap 9 is constructed in two layers in the radial direction and has a radially inner cap layer 9a and a radially outer cap layer contacting the substrate as the tire rolls 9b on. The radially outer cap layer 9b has a thickness d ₃ at the equatorial plane in the radial direction, which is 10% to 70%, in particular 20% to 40%, of the thickness d _{1 of} the tread 1 is.

All layers 8th . 9a . 9b of the tread 1 consist of rubber material and are therefore each made of a rubber compound. The rubber material of the tread base 8th is designed in a conventional manner such that it heats only slightly when rolling the tire, which is responsible for the rolling resistance of the tire and for the durability of the belt 2 is beneficial. In Table 1 are exemplary compositions of the rubber mixture of the radially inner cap layer 9a (M _9a ) and the radially outer cap layer 9b (M _9b ). Table 1 also contains results of tensile tests on the rubber materials made from these rubber compounds DIN 53504 , the Shore A hardnesses according to DIN ISO 7619-1 , the rebound resilience at room temperature (RT, 25 ° C) and at 70 ° C according to DIN 53512 , the high-speed breaking strain, is calculated as the tensile energy per deformed volume at room temperature according to the High Speed Tear Energy Test (HSTE) DIN EN 10 045 , as well as the results of the examination of the heat generation in the fatigue test (flexometer test) according to DIN 53533 , The heat buildup test was performed on 0.7 inch (17.8 mm) diameter cylindrical Goodrich specimens and 1.0 inch (25.4 mm) high at a static stress of 0.9 MPa and dynamic Stress of ± 0.8 MPa. Table 1: Blend Compositions and Test Results component unit M _9a (radially inner cap layer 9a ) M _9b (radially outer cap layer 9b ) natural rubber phr 80-100 0 SBR phr 0-20 100 BR phr 0-20 0 soot phr 30-60 60-100 Silica (& Silane) phr 0-20 0-5 Plasticizer (Oil & Resin) phr 0-15 10-30 accelerator phr 0.9-2 0.9-2 sulfur phr 0.9-2 0.9-3 Anti-aging agents phr 1-10 1-10 zinc oxide phr 1-4 2-5 test results Shore A hardness (RT) Sh 60.1 60.2 Rebound resilience (RT) % 44.0 24.2 Rebound resilience (70 ° C) % 54.0 35.3 M50 MPa 1.1 1.0 M100 MPa 1.9 1.3 M200 MPa 5.0 2.7 M300 MPa 10.0 5.0 tear strength MPa 21.0 16.4 elongation at break % 565 715 HSTE MJ / m ³ 13 20 Temperature after DIN 53533 ° C 76.0 98.3

As will be explained below, the rubber material is the radially outer cap layer 9b particularly resistant to "Chipping &Chunking". The "chip &chunk" properties of a rubber material, which reflect the tendency for tread damage, such as tearing, flaking, or breakout, are closely related to the tearing properties, particularly elongation at break, of the rubber material. The "chip &chunk" resistance of a rubber material is in conflict with the degree of heat build-up under dynamic load, ie the heat build-up when rolling the tire. To counteract this is the rubber material of the radially inner cap layer 9a optimized in particular with regard to its heat build-up, so that it heats only slightly under load.

The rubber material of the radially outer cap layer 9b has an elongation at break according to DIN 53504 from 600% to 900%, in particular from 650% to 750%, preferably of at least 700%. This high elongation at break gives the rubber material of the radially outer cap layer 9b its particularly high resistance to "Chipping &Chunking". The stress value at 300% elongation (M300) of the rubber material is 4.0 MPa to 10.0 MPa, preferably at most 6.0 MPa, so that by the test DIN 53504 obtained stress / strain curve shows a "flat" course. As a result, stresses in the rubber material of the radially outer cap layer 9b over a large volume range of this cap layer 9b evenly distributed, whereby hardly any crack-initiating voltage peaks occur and thus the resistance to "Chipping &Chunking" is further increased. For the "chip &chunk" resistance, it is also advantageous if the rubber material of the radially outer cap layer 9b a high-speed breaking strain (HSTE) after DIN EN 10 045 from 18 MJ / m ³ to 25 MJ / m ³ , in particular from 19 MJ / m ³ to 21 MJ / m ³ . The Shore A hardness according to DIN-ISO 7619-1 the rubber material of the cap layer 9b is 50 Shore A to 80 Shore A, in particular 65 Shore A to 75 Shore A.

That for the radially outer cap layer 9b provided rubber material is in particular made of a rubber mixture which comprises at least one styrene-butadiene rubber (SBR), in particular at least one E-SBR (produced by emulsion polymerization styrene-butadiene rubber), at least one carbon black having an iodine adsorption number of at most 125 g / kg and a DBP number of at most 115 × 10 ^-5 m ³ / kg and further at least one resin (a resin).

The rubber material of the radially inner cap layer 9a indicates a lower heat formation according to DIN 53533 as the rubber material of the radially outer cap layer 9b This heat formation is a measure of the heat buildup of a rubber material under dynamic load and a low temperature value means a low heat build-up. The temperature of the rubber material of the radially inner cap layer 9a according to DIN 53533 (static stress of 0.9 MPa, dynamic stress ± 0.8 MPa) is 60 ° C to 85 ° C. Furthermore, the rubber material has the radially inner cap layer 9a a higher resiliency, both at room temperature and at 70 ° C, than the rubber material of the radially outer cap layer 9b so that the radially inner cap layer 9a The mechanical energy absorbed during unrolling is particularly easy to dispense without converting it into heat. The rebound resilience at room temperature of the rubber material of the radially inner cap layer 9a is 30% to 60%, in particular 40% to 50%, its rebound resilience at a temperature of 70 ° C is 45% to 75%, in particular 55% to 65%.

Furthermore, the rubber material has the radially inner cap layer 9a a stress at 300% elongation of 8.0 MPa to 12.0 MPa, so that by the test DIN 53504 obtained stress / strain curve shows a "steep" course, which also keeps low the heat buildup in the rubber material under dynamic stress and thus the rubber-inherent deformability or the resulting heat build-up. The elongation at break of the rubber material of the radially inner cap layer 9a is 450% to 700%, preferably 530% to 600%, and is therefore slightly smaller than that of the rubber material of the radially outer cap layer 9b However, as a result of this elongation at break, it also has a very high resistance to chipping and chunking. The Shore A hardness according to DIN-ISO 7619-1 the rubber material of the cap layer 9a is 50 Shore A to 80 Shore A, especially 65 Shore A to 75 Shore A, and is preferably consistent with the Shore A hardness of the rubber material of the cap layer 9b match or substantially match. Substantially identical Shore A hardnesses are understood as meaning those which deviate from one another by at most 4.0 Shore A, in particular by at most 2.0 Shore A.

That for the radially inner cap layer 9a The intended rubber material may in particular be produced from a rubber mixture with 80 phr to 100 phr of natural rubber, silica in an amount of up to 20 phr, whereby carbon black is proportionally replaced by silica, and by a plasticizer amount of at most 15 phr.

In particular, by the combination of the two cap layers 9a and 9b On the one hand, it is possible to give the tire a particularly high resistance to "chipping and chunking" and, on the other hand, to limit heat build-up. In particular by adaptation of the thicknesses of the two cap layers 9a and 9b The desired tire properties can be optimally adapted to the respective application.

Notwithstanding the in 1 variant shown, the tread 1 also have more than three layers in the radial direction. In particular, the tread cap 9 have more than two layers in the radial direction.

LIST OF REFERENCE NUMBERS

1

tread

2

belt Association

2a, 2b, 2c, 2d

belt layer

3

carcass

4

inner layer

5

Side wall

6

shoulder pad

7

Belt edge cushion

8th

Tread rubber base

9

tread cap

9a, 9b

Capschicht

d ₁ , d ₂ , d ₃

thickness

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 non-patent literature

• DIN 53504 [0005]
• DIN 53504 [0008]
• DIN 53504 [0008]
• DIN EN 10 045 [0009]
• DIN ISO 7619-1 [0011]
• DIN ISO 7619-1 [0012]
• DIN 53533 [0013]
• DIN 53512 [0014]
• DIN 53504 [0015]
• DIN 53512 [0016]
• DIN 53504 [0029]
• DIN ISO 7619-1 [0029]
• DIN 53512 [0029]
• DIN EN 10 045 [0029]
• DIN 53533 [0029]
• DIN 53533 [0029]
• DIN 53504 [0031]
• DIN 53504 [0031]
• DIN EN 10 045 [0031]
• DIN ISO 7619-1 [0031]
• DIN 53533 [0033]
• DIN 53533 [0033]
• DIN 53504 [0034]
• DIN ISO 7619-1 [0034]

Claims (15)

Commercial vehicle tires, in particular OTR tires, of radial or diagonal type with a radial layer of rubber material consisting of treads (US Pat. 1 ) with a tread base ( 8th ) and a tread cap containing the profiling ( 9 ), whereby the tread ( 1 ) has a thickness (d ₁ ) of 12.0 mm to 70.0 mm at the equatorial plane in the Reifenzenit, characterized in that the tread cap ( 9 ) in the radial direction at least two cap layers ( 9a . 9b ), wherein the radially outermost cap layer ( 9b ) in the Reifenzenit at the equatorial plane has a thickness (d ₃ ) of 10% to 70% of the thickness (d ₁ ) of the tread ( 1 ) and wherein the rubber material of the radially outermost cap layer ( 9b ) has an elongation at break according to DIN 53504 of 600% to 900%. Commercial vehicle tire according to claim 1, characterized in that the rubber material of the radially outermost cap layer ( 9b ) has an elongation at break of 650% to 750%, preferably of at least 700%. Commercial vehicle tire according to claim 1 or 2, characterized in that the rubber material of the radially outermost cap layer ( 9b ) has a stress value at 300% elongation according to DIN 53504 of 4.0 MPa to 10.0 MPa, preferably of at most 6.0 MPa. Commercial vehicle tire according to one of claims 1 to 3, characterized in that the rubber material of the radially outermost cap layer ( 9b ) has a high-speed breaking elongation according to DIN EN 10 045 of 18 MJ / m ³ to 25 MJ / m ³ , in particular from 19 MJ / m ³ to 21 MJ / m ³ . Commercial vehicle tire according to one of claims 1 to 4, characterized in that the radially outermost cap layer ( 9b ) in the Reifenzenit along the equatorial plane has a thickness (d ₃ ) of 20% to 40% of the thickness (d ₁ ) of the tread ( 1 ) having. Commercial vehicle tire according to one of claims 1 to 5, characterized in that the rubber material of the radially outermost cap layer ( 9b ) has a Shore A hardness according to DIN ISO 7619-1 of 50 Shore A to 80 Shore A, in particular from 65 Shore A to 75 Shore A. Commercial vehicle tire according to one of claims 1 to 6, characterized in that the rubber materials of the cap layers ( 9a . 9b ) have matching Shore A hardnesses according to DIN ISO 7619-1 or at most 4.0 Shore A, in particular by at most 2.0 Shore A, Shore A hardness differing from one another. Commercial vehicle tire according to one of claims 1 to 7, characterized in that the rubber material of the tread base ( 8th ) immediately adjacent radially innermost cap layer ( 9a ) has a temperature according to DIN 53533 at a static stress of 0.9 MPa and a dynamic stress of ± 0.8 MPa from 60 ° C to 85 ° C. Commercial vehicle tire according to one of claims 1 to 8, characterized in that the rubber material of the tread base ( 8th ) immediately adjacent radially innermost cap layer ( 9a ) has higher rebound resilience at room temperature and at 70 ° C. according to DIN 53512 than the rubber material of the radially outermost cap layer ( 9b ), wherein the rubber material of the radially innermost cap layer ( 9a ) has a rebound resilience at room temperature of from 30% to 60%, in particular from 40% to 50%, and a rebound resilience at 70 ° C of 45% to 75%, in particular from 55% to 65%. Commercial vehicle tire according to one of claims 1 to 9, characterized in that the rubber material of the tread base ( 8th ) immediately adjacent radially innermost cap layer ( 9a ) has a stress value at 300% elongation of 8.0 MPa to 12.0 MPa. Commercial vehicle tire according to one of claims 1 to 10, characterized in that the rubber material of the tread base ( 8th ) immediately adjacent radially innermost cap layer ( 9a ) has an elongation at break according to DIN 53512 of 450% to 700%, in particular from 530% to 600%. Commercial vehicle tire according to one of claims 1 to 11, characterized in that the rubber material of the radially outermost cap layer ( 9b ) is made of a rubber mixture containing at least one styrene-butadiene rubber (SBR), in particular at least one produced by emulsion polymerization styrene-butadiene rubber (E-SBR). Commercial vehicle tire according to one of claims 1 to 12, characterized in that the rubber material of the radially outermost cap layer ( 9b ) is made of a rubber mixture containing at least one resin. Commercial vehicle tire according to one of claims 1 to 13, characterized in that the rubber material of the radially outermost cap layer ( 9b ) is made of a rubber mixture containing as filler only carbon black, in particular at least one carbon black with an iodine adsorption number of at most 125 g / kg and a DBP number of at most 115 × 10 ^-5 m ³ / kg and further at least one Resin (a resin) contains. Commercial vehicle tire according to one of claims 1 to 14, characterized in that the rubber material of the tread base ( 8th ) immediately adjacent radially innermost cap layer ( 9a ) is made of a rubber compound containing from 80 phr to 100 phr of natural rubber, up to 20 phr of silica and up to 15 phr of plasticizer.

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