PNEUMATIC TIRE FOR ROAD VEHICLES

Abstract

A pneumatic tire for road vehicles is provided. The pneumatic tire includes a tread portion. The tread portion includes an outer layer and an inner layer. The outer layer is made with a compound A having a dynamic modulus at 30° C. of between 5 and 15 MPa and a tan δ at 60° C. of between 0.400 and 0.100. The inner layer is made with a compound B having a dynamic modulus at 30° C. that is lower than that of said compound A of a value between 0.5 and 10 MPa and a tan δ at 60° C. that is lower than that of said compound A of a value between 0.01 and 0.20. The outer layer and the inner layer are in contact with one another by means of a connection surface, which has a corrugated conformation that is such to provide an alternated plurality of interpenetrating longitudinal portions. Each of said interpenetrating longitudinal portions extending parallel to an axis of rotation X of the pneumatic tire.

Description

The present disclosure relates to a pneumatic tire for road vehicles.

In particular, the present disclosure relates to a radial pneumatic tire for road vehicles, comprising a tread consisting of an outer portion made with a compound with relatively high hysteresis loss, and an inner portion made with a compound with relatively low hysteresis loss and having a connection interface with the outer portion having a special geometry.

In the field of pneumatic tires for road vehicles, it is known that a low rolling resistance and a good wear resistance on the one hand and good road holding and braking ability in the dry or wet on the other hand are characteristics that are difficult to obtain with the same pneumatic tire. In fact, whilst in order to confer good rolling resistance and good wear resistance to a pneumatic tire, treads made with compounds with low hysteresis loss are used, in order to confer good road holding and braking ability to a pneumatic tire, treads with compounds with relatively higher hysteresis loss become necessary.

Consequently, an optimal tread compound for simultaneously enhancing all of the dynamic responses of the tread of a pneumatic tire should exhibit opposing hysteresis characteristics, at least over certain required performance limits.

In EP-0 864 446 and EP-0 864 447 pneumatic tires of the previously defined type are described that are provided with treads made using two compounds, one with a low hysteresis loss and the other with a high hysteresis loss, in order to form two or more axially adjacent annular tread strips. In each pair of axially contiguous strips, one is made using one of the two compounds and the other is made using the other of the two compounds.

The known multi-compound treads obtained by axially distributing the various strips as a function of the dynamic characteristics to be enhanced, through capable of ensuring the required performance during the first use thereof, are however subject to non-uniform wear with the result that, after a short period of time, the compromise that was so difficult to achieve, is lost.

A further solution that has been adopted concerns the implementation of a tread composed of an outer layer made with a compound with relatively high hysteresis loss, and an inner layer made with a compound with relatively low hysteresis loss. The two layers are radially adjacent to one another and have a substantially planar connection interface surface, i.e., such to avoid any interpenetration of one layer within the other.

Notwithstanding such a solution having provided obvious improvements in terms of rolling resistance, without leading to any deterioration in braking performance, the need was however felt to provide pneumatic tires that also result in obvious improvements in terms of braking. In fact, such a solution makes it possible to improve the balance of the required performance but nonetheless to a limited extent, since the overall performance is a compromise resulting from the contribution of the two components.

The inventors of the present disclosure have found that by implementing a particular connection surface between the two layers with different hysteresis losses, it is possible to obtain surprising advantages in terms of braking, while maintaining unaltered the advantages obtained in terms of rolling resistance.

The object of the present disclosure is a pneumatic tire for road vehicles comprising a tread portion comprising an outer layer made with a compound A having a dynamic modulus at 30 degrees Celsius (° C.) of between 5 and 10 megapascals (MPa) and a tangent delta (tan δ) at ° C. of between 0.400 and 0.100, and an inner layer made with a compound B having a dynamic modulus at 30° C. that is lower than that of said compound A of a value of between 0.5 to 10 MPa and a tan δ at 60° C. that is lower than that of said compound A of value of between 0.01 and 0.20; said outer layer and said inner layer being in contact with each other by means of a connection surface; said pneumatic tire being characterized in that said connection surface has a corrugated conformation that is such to provide an alternated plurality of interpenetrating longitudinal portions; each of said interpenetrating portions extending parallel to an axis of rotation X of the pneumatic tire.

The dynamic properties were measured in accordance with the ISO 4664 standard. As is known to a technician in the field, the values of tan δ at 60° C. are strictly correlated to the rolling resistance: the lower the tan δ value at 60° C., the better the rolling resistance.

Here and hereinafter interpenetrating portion refers to a portion of one of the two (inner or outer) layers of the tread that is found to be axially flanked by two portions of the other (outer or inner) layer of the tread.

Preferably, said connection surface implements a regular continuity of interpenetrating portions, all of equal size and parallel to one another. In this way, said tread portion comprises an outer portion made only from compound A, a central portion made from the alternation of interpenetrating portions, and an inner portion made only from compound B.

Preferably, the ratio between the thickness of said outer portion and the thickness of said inner portion is between 0.1 and 0.9.

Preferably, the ratio between said central portion and the overall thickness of the tread portion is between 0.2 and 0.8.

An example embodiment will now be described with reference to the accompanying FIGURE, which illustrates, by means of a cross-section enlargement, a portion of a preferred embodiment of the pneumatic tire according to the present disclosure.

With reference to FIG. 1, the numeral 1 indicates a radial pneumatic tire comprising an inner radial carcass 2 and an outer tread 3 separated from one another by a tread belt 4 defined by a pack of tread plies 5 overlapping one another.

In the example illustrated, the tread 3 comprises a tread band 6 and a cushion 6a overlapping one another. The tread band 6 comprises an inner layer 7 and an outer layer 8.

The inner layer 7 is made with a compound B with relatively low hysteresis loss, whilst the outer layer 8 is made with a compound A with relatively high hysteresis loss.

The inner layer 7 and the outer layer 8 are in contact to one another by means of a connection surface 9. The connection surface 9 has a corrugated conformation that is such to provide an alternation of interpenetrating longitudinal portions 10 between the two layers 7 and 8. The interpenetrating portions 10 extend parallel to an axis of rotation X of the pneumatic tire.

According to the preferred embodiment shown in the FIGURE, the interpenetrating portions 10 are parallel to one another, all having the same height h.

In this way, the tread band 6 comprises an outer portion of height S made only from compound A, a central portion of height h made from the alternation of interpenetrating portions 10, and an inner portion of height Y made only from compound B.

In order to verify the advantages deriving from the solution of the present disclosure, five specimens were made, all having the same thickness equal to 8 mm. The five specimens, made as described below, were subjected to evaluations in terms of braking and rolling resistance.

A first specimen (I) was made entirely with compound A, a second specimen (II) was made entirely with compound B, a third specimen (III) was made with a 6 mm layer of compound B and a 2 mm layer of compound A and a fourth specimen (IV) was made with a 7 mm layer of compound B and a 1 mm layer of compound A. The fifth specimen (V) comprises two layers made respectively with compounds A and B, which implement a relative plurality of interpenetration portions within the interface. In particular, the connection surface between the layers has a corrugated conformation that is such to implement the longitudinal interpenetration portions. The interpenetration portions have a height equal to 2 mm. In this way the fifth specimen will consist of a 5 mm portion filled with compound B, a 1 mm portion filled with compound A and an intermediate 2 mm portion, wherein the compounds A and B interpenetrate in an alternating manner.

In essence, whilst with the third (III) and fourth (IV) specimens the two layers made with compounds A and B respectively have a planar connection surface, in the fifth specimen (V) the two layers made with compounds A and B respectively have a corrugated connection surface that is such to provide a plurality of alternated interpenetrating longitudinal portions, so that the total volume of the two components is the same in relation to that of specimen III.

Table I shows the compositions of the compounds A and B used in the specimens.

	TABLE I
	COMPOUND A	COMPOUND B
POLYMERIC BASE WITH OIL	E-SBR	72.9	72.9
	S-SBR	56.4	56.4
FILLER	SILICA	70.0	40.0
	CARBON BLACK	10.0	20.0
BINDER AGENT	SILANE	7.0	4.0
	MICROCRYSTALLINE WAX	1.0	1.0
	STEARIC ACID	1.0	1.0
	AROMATIC OIL	9.0	4.0
	ZINC OXIDE	2.0	2.0
	SULFUR	2.0	2.0
VULCANIZING	ACCELERATOR	TBBS	1.0	1.2
AGENTS	ACCELERATOR	MBTS	0.5	0.3
	ACCELERATOR	DPG	1.5	1.1
	ANTIOXIDANT	6PPD	1.5	1.5
	DRY POLYMERIC BASE	100	100

E-SBR is a polymeric base obtained by means of an emulsion polymerization process with an average molecular weight of between 800-1500×10³ and 500-900×10³, respectively, with a styrene content of between 20 and 45% and used with an oil content of between 0 and 30%;

S-SBR is a polymeric base obtained by means of a solution polymerization process with an average molecular weight of between 800-1500×10³ and 500-900×10³, respectively, with a styrene content of between 20 and 45%.

The silica used is marketed under the name ULTRASIL VN3 by the DEGUSSA company.

The carbon black used is marketed under the name Vulcan 7H (N234) by the CABOT company.

The silane used is marketed under the name SI 69 by the DEGUSSA company.

TBBS is the acronym for the compound N-tert-butyl-2-benzotiazilsulfenammide; MBTS is the acronym for the compound mercapto benzothiazole disulfide; DPG is the acronym for the compound diphenyl guanidine; 6PPD is the acronym for N-1,3-dimethylbutyl-N′-phenyl-para-phenylenediamine.

The compounds A and B described above have a dynamic modulus at 30° C. of 10 and 8 MPa, respectively, and a tan δ at 60° C. of 0.200 and 0.170, respectively.

The five specimens above were subjected to testing according to the ISO 4664 standard in order to evaluate the dynamic properties.

The braking performance was evaluated by comparing the coefficient of friction of the compounds, obtained with a linear friction meter at a speed of 500 mm/s, at a temperature of 5° C. under wet conditions. The results were obtained by comparing the respective coefficients of friction: the higher the index, the higher the coefficient of friction and, therefore, the wet grip.

In particular, the performance in terms of rolling resistance was correlated to the values of tan δ at 60° C.

Table II shows the values of braking and rolling resistance indexed to the values of the first specimen (I).

	TABLE II
	Specimens	I	II	III	IX	V
	Braking	100	90	95	90	120
	Rolling resistance	100	110	105	108	105

As is evident from the data of Table III, the conformation of the contact surface of the two layers in specimen V confers a clear improvement in terms of braking compared to specimens III and IV. Specimens III and IV, despite comprising the combination of the two layers with different hysteresis losses, nonetheless fail to achieve the advantages in terms of braking achieved by the solution of the present disclosure specimen V).

In other words, the present disclosure, starting from a known tread conformation comprising an inner layer made with a compound with relatively low hysteresis loss and an outer layer made with a compound with relatively high hysteresis loss, can, by virtue of the presence of the interpenetrating portions of the two layers, greatly boost performance in terms of braking, maintaining, at the same time, the advantages obtained in terms of rolling resistance.

Claims

1. A pneumatic tire for road vehicles, the pneumatic tire comprising a tread portion comprising: an outer layer made with a compound A having a dynamic modulus at 30 degrees Celsius (° C.) of between 5 and 15 megapascals (MPa) and a tangent delta (tan δ) at 60° C. of between 0.400 and 0.100, and an inner layer made with a compound B having a dynamic modulus at 30° C. that is lower than that of said compound A of a value between 0.5 and 10 MPa and a tan δ at 60° C. that is lower than that of said compound A of a value between 0.01 and 0.20;said outer layer and said inner layer being in contact with each other by means of a connection surface, said connection surface having a corrugated conformation that is such to provide an alternated plurality of interpenetrating longitudinal portions, each of said interpenetrating longitudinal portions extending parallel to an axis of rotation X of the pneumatic tire.

2. The pneumatic tire of claim 1, wherein: said connection surface implements a regular continuity of interpenetrating portions all of equal size and parallel to one another; andsaid tread portion comprises an outer portion made only from compound A, a central portion made from the alternation of interpenetrating portions, and an inner portion made only from compound B.

3. The pneumatic tire of claim 2, wherein a ratio between the thickness of said outer portion and the thickness of said inner portion is between 0.1 and 0.9.

4. The pneumatic tire of claim 2, wherein a ratio between the thickness of said central portion and the overall thickness of the tread portion is between 0.2 and 0.8.

5. A pneumatic tire for road vehicles, the pneumatic tire comprising a tread portion comprising: an outer layer made with a first compound, the first compound comprising: a first dynamic modulus at 30 degrees Celsius (° C.) of between 5 and 15 megapascals (MPa), inclusive; anda first tangent delta (tan δ) at 60° C. of between 0.400 and 0.100, inclusive, andan inner layer made with a second compound, the second compound comprising: a second dynamic modulus at 30° C. that is both lower than the first dynamic modulus and between 0.5 and 10 MPa, inclusive; anda second tan δ at 60° C. that is both lower than the first tan δ and between 0.01 and 0.20, inclusive;wherein the outer layer is coupled with the inner layer at a connection surface, the connection surface having a corrugated conformation that comprises an alternated plurality of interpenetrating longitudinal portions, each of the interpenetrating longitudinal portions extending parallel to an axis of rotation X of the pneumatic tire.

6. The pneumatic tire of claim 5, wherein: the connection surface includes a regular continuity of interpenetrating portions all of equal size and parallel to one another; andthe tread portion comprises an outer portion made only from the first compound, a central portion made from the alternated plurality of interpenetrating longitudinal portions, and an inner portion made only from the second compound.

7. The pneumatic tire of claim 6, wherein a ratio between the thickness of the outer portion and the thickness of the inner portion is between 0.1 and 0.9, inclusive.

8. The pneumatic tire of claim 6, wherein a ratio between the thickness of the central portion and the thickness of the tread portion is between 0.2 and 0.8.