阅读说明：本技术 轮胎 (Tyre for vehicle wheels ) 是由 仓科大辅 于 2018-12-12 设计创作，主要内容包括：轮胎的胎面的特征在于,包括该轮胎的赤道面的中央区域的平均模量值大于与胎面的端部相邻的胎肩区域的平均模量值,并且在胎肩区域中,胎面的表面层的模量值比除了该表面层之外的部分的模量值高。(The tread of the tire is characterized in that the average modulus value of a central region including the equatorial plane of the tire is larger than the average modulus value of a shoulder region adjacent to an end of the tread, and in the shoulder region, the modulus value of a surface layer of the tread is higher than the modulus value of a portion other than the surface layer.)

1. A tire, comprising a tread,

wherein, in the tread, an average modulus value in a central region including an equatorial plane of the tire is higher than an average modulus value in a shoulder region adjacent to an edge of the tread; and is

In the shoulder region, the modulus value in the surface layer of the tread is higher than the modulus value in the portion other than the surface layer.

2. The tire according to claim 1, wherein the modulus value of the surface layer of the tread in the shoulder region is the same as the modulus value of the surface layer of the tread in the central region.

3. The tire according to claim 1 or 2, wherein the ratio of the average modulus value in the shoulder region to the average modulus value in the central region is 80% or more and less than 100%.

4. A tire according to any one of claims 1 to 3, wherein in the central region, the modulus value in a surface layer of the tread is lower than the modulus value in a portion other than the surface layer.

5. The tire according to any one of claims 1 to 4, wherein the modulus value of the surface layer of the tread in the central region is 2MPa or more and 4MPa or less.

6. The tire according to any one of claims 1 to 5, wherein the tread is formed of a cap rubber layer on a surface side of the tread and a base rubber layer on a tire radial direction inner side of the cap rubber layer.

7. The tire of claim 6 wherein said crown rubber layer in said shoulder region comprises a plurality of layers stacked in the tire radial direction and differing in modulus value between said plurality of layers.

8. The tire according to claim 6 or 7, wherein in the cap rubber layer in the shoulder region, the modulus decreases from the surface of the tread radially inward of the tire.

9. The tire according to any one of claims 6 to 8, wherein said crown rubber layer in said central region comprises a plurality of layers stacked in the tire radial direction, and modulus values differ between said plurality of layers.

10. The tire according to any one of claims 6 to 9, wherein in the cap rubber layer in the central region, the modulus increases from the surface of the tread radially inward of the tire.

Technical Field

The present disclosure relates to a tire, and particularly to a tire capable of improving a cornering force while suppressing rolling resistance.

Background

In order to suppress the rolling resistance of a tire, the following methods are known: the rubber forming the tread of the tire is divided into a plurality of regions in the tire width direction and the physical properties of the rubber between the regions are changed.

For example, patent document 1 discloses dividing the tread of a tire into three regions: a central region at a central portion in the width direction and shoulder regions on both sides in the width direction of the central region. Further, the value of the loss tangent tan of the rubber is made larger in the central region than in the shoulder region of the tire, and the value of the elastic modulus of the rubber forming each region is also made larger in the central region than in the shoulder region, so that rolling resistance, braking performance on a wet road surface, and the like are compatible.

Disclosure of Invention

Technical problem to be solved by the invention

In patent document 1, the modulus of elasticity of the tread is varied between the center region and the shoulder regions to allow reduction of rolling resistance. On the other hand, forming the shoulder region with rubber having a lower modulus of elasticity than the center region results in insufficient rigidity in the shoulder region on the vehicle outer side, particularly during cornering. As a result, the cornering power of the tire is reduced. Furthermore, the reduction of the cornering power adversely affects the abrasion resistance.

Therefore, an object of the present disclosure is to suppress a decrease in the cornering force while maintaining the effect of suppressing the rolling resistance.

Means for solving the problems

As a result of earnest studies on how to solve the above-described problems, the inventors found that by dividing the tread of the tire into a plurality of regions in the tire width direction, specifying the physical properties of the rubber forming each region, and changing the physical properties of the rubber at the tread surface side and the tire radial direction inner side of the tire of the rubber for forming the shoulder region, the cornering power can be improved without impairing the effect of suppressing the rolling resistance, and completed the present disclosure.

The main features of the present disclosure are as follows.

The tire of the present disclosure includes a tread, wherein, in the tread, an average modulus value in a central region including an equatorial plane of the tire is higher than an average modulus value in a shoulder region adjacent to an edge of the tread; and in the shoulder region, the modulus value in the surface layer of the tread is higher than the modulus value in a portion other than the surface layer.

In the present disclosure, "center region" means a region that is centered on the tire equatorial plane C L and extends from the tire equatorial plane C L to both sides of the tread width of the tire to a point at a distance of 25% of the tire tread width.

"tread edge" means the outermost ground contact portion in the tire width direction when the tire is mounted on an applicable rim, filled to a prescribed internal pressure, and a prescribed load is applied. "applicable rim" means a rim prescribed by an industrial standard effective in an area where a tire is manufactured and used, such as JATMA (japan automobile tire manufacturer association) yearbook in japan, ETRTO (european tire and rim technical organization) standards manual in europe, and TRA (tire and rim association) yearbook in the united states. The "predetermined internal pressure" refers to an air pressure corresponding to the maximum load (maximum load capacity) of an individual wheel at the applicable size described in the above-mentioned industrial standard. "specified load" means the maximum load (maximum load capacity) of a single wheel at the applicable size specified by the above-mentioned industry standard. Further, "tread width of a tire" means a tire width direction distance between two tread edges of the tire.

"modulus" means a tensile stress at 100% elongation measured by a tensile test conducted under conditions of a temperature of 30 ℃ and a speed of 500. + -. 25mm/min in accordance with JIS K6251 by preparing a JIS dumbbell shape No. 3 sample.

In addition, the "surface layer of the tread" in the present disclosure means a layer 2mm thick from the tread surface to the tire radial direction inner side.

ADVANTAGEOUS EFFECTS OF INVENTION

The present disclosure can provide a tire that suppresses a reduction in cornering power while maintaining a suppression effect on rolling resistance.

Drawings

Fig. 1 is a cross-sectional view of a tire according to an embodiment of the present disclosure.

Fig. 2 is an enlarged sectional view showing a portion of the tire in fig. 1.

Fig. 3 is an enlarged sectional view illustrating a portion of a tire according to another embodiment of the present disclosure.

Detailed Description

[ first embodiment ]

The tire according to the present disclosure is explained in detail below with reference to the drawings.

FIG. 1 is a widthwise sectional view of a tire according to the present disclosure A tire 1 of the present disclosure includes a carcass 3 as a frame extending annularly between a pair of bead cores 2, a belt 4 formed of two inclined belt layers 4a, 4b on the outer side of the carcass 3 in the tire radial direction, and a tread rubber 5. the inclined belt layers 4a, 4b are inclined with respect to the tire equatorial plane C L and are formed of a plurality of cords extending across each other between the layers and covered with rubber.the bead cores 2, the carcass 3, and the belt 4 are not limited to the illustrated example.for example, the carcass 3 may also be composed of two carcass plies, and the belt 4 may be provided with a circumferential belt layer.the tread surface may have any tread pattern.in FIG. 1, four land portions are defined by circumferential grooves 10a, 10b, 10C.

The tread rubber 5 is shown to have a two-layer structure in the tire radial direction, which is formed of a cap rubber layer 6 on the tread surface side and a base rubber layer 7 disposed on the tire radial direction inner side of the cap rubber layer 6, but the tread rubber 5 does not necessarily have two layers.

In the illustrated example, the thickness of the cap rubber layer 6 is larger than that of the base rubber layer 7. The thickness of the cap rubber layer 6 and the base rubber layer 7 means an average value of the thickness in the tire radial direction. These thicknesses are not limited to the illustrated examples and may be appropriately set to obtain the basic performance of the tire.

Specifically, a region that is centered on the tire equatorial plane C L and extends from the tire equatorial plane C L to points P1 and P2 at a distance of 25% of the tire tread width TW to both sides of the tire tread width TW is the central region Tcent a region from points P1 and P2, which are tire width direction edges of the central region Tcent, to the tread edge TE is the shoulder region Tsho when the average modulus value M1 of the central rubber 5C forming the central region Tcent must be made larger than the average modulus value M2 of the shoulder rubber 5S forming the shoulder region Tsho, here, the average modulus value means an average of the modulus values in the tire radial direction.

The above-described configuration in which the average modulus values of the center rubber 5C and the shoulder rubbers 5S satisfy the relationship M1> M2 allows the rolling resistance of the tire to be suppressed. In other words, the rolling resistance of the tire can be reduced by reducing the energy consumed by repeated deformation accompanying the rolling of the tire. That is, the center rubber 5C serves as a core for supporting the load of the tire in the center region Tcent of the tire. Therefore, setting the average modulus value M1 relatively high can reduce distortion with respect to the load. On the other hand, when in contact with the road surface, the tread tends to deform in the shoulder region Tsho of the tire. Therefore, setting the average modulus value M2 of the shoulder rubber 5C to be relatively low enables stress on the rubber to be reduced and energy consumption to be reduced.

The ratio M2/M1 of the average modulus value M2 of the shoulder rubbers 5S to the average modulus value M1 of the center rubber 5C is preferably 80% or more and less than 100%. Setting the ratio to 80% or more can prevent the difference in physical properties between the center rubber 5C and the shoulder rubber 5S from becoming excessively large, and setting the ratio to less than 100% can maintain the function of the central region Tcent as a load supporting core.

Further, it is important that, in the shoulder rubber 5S, the modulus value in the surface layer 5So of the tread is larger than that in the portion other than the surface layer 5 So. In other words, the surface layer 5So of the tread in the shoulder rubber 5S is provided with the following rubber characteristics in addition to the average modulus value M1 of the center rubber 5C being larger than the average modulus value M2 of the shoulder rubber 5S: its modulus value M3 is higher than that of the portions other than the surface layer 5So as to reduce the modulus difference between the tread surface of the central region Tcent and the tread surface of the shoulder region Tsho and suppress the rigidity difference between the central region Tcent and the shoulder region Tsho in the ground contact region when the tire rolls under a load. This is effective for maintaining a high cornering force. Furthermore, abrasion resistance is also obtained by maintaining the cornering force.

Assuming that the ratio M2/M1 is 80% or more and less than 100% as described above, for example, the average modulus value M1 of the center rubber 5C may be set to 2MPa or more and 4MPa or less, and the average modulus value M2 of the shoulder rubber 5S may be set to 1.6MPa or more and 4MPa or less. Further, the modulus value M3 in the surface layer 5So of the shoulder rubber 5S can be set to 1.9MPa or more and 4MPa or less. In other words, by setting the average modulus value M1 to 2MPa or more, the distortion with respect to the load can be reduced, and by setting the average modulus value M1 to 4MPa or less, the wear resistance can also be obtained. By setting the average modulus value M2 to 1.6MPa or more, the difference from the average modulus value M1 can be prevented from becoming excessively large, and by setting the average modulus value M2 to 4MPa or less, the effect of reducing the stress of the rubber can be sufficiently obtained, and the rolling resistance can be suppressed. Further, by setting the modulus value M3 in the surface layer 5So of the shoulder rubber 5S to be 1.9MPa or more and 4MPa or less, it is possible to suppress the difference in rigidity between the center region Tcent and the shoulder region Tsho, and to sufficiently maintain the cornering power.

Here, the modulus value M3 of the surface layer 5So of the shoulder rubber 5S is preferably the same as the modulus value M4 of the surface layer 5Co of the center rubber 5C.

Here, "the same" is not limited to the case where the modulus values are the same, but includes the case where the difference between the modulus value M3 of the surface layer of the shoulder rubber 5S and the modulus value M4 of the surface layer of the center rubber 5C is-5% or more and 0% or less of the modulus value M4 of the surface layer of the center rubber 5C. In other words, the above configuration is effective for maintaining a high cornering force while suppressing a difference in rigidity between the center region Tcent and the shoulder region Tsho of the tread surface. Furthermore, wear resistance is also obtained by maintaining the cornering power. In addition, uneven wear due to differences in the level of rigidity can also be prevented.

Assuming that the aforementioned ratio is-5% or more and 0% or less, the modulus value M4 in the surface layer 5Co of the center rubber 5C may be set to 2MPa or more and 4MPa or less, and the modulus value M3 in the surface layer 5So of the shoulder rubber 5S may be set to 1.9MPa or more and 4MPa or less.

In the illustrated example tire, i.e., a tire having a crown base structure, the rubber characteristics of the crown rubber layer 6 in the central region Tcent and the shoulder regions Tsho are mainly changed, which is advantageous for adapting to the implementation of the structure thus described.

In other words, the crown rubber layer 6 in the illustrated example is formed of a center crown rubber layer 6C constituting the center region Tcent of the tread and a shoulder crown rubber layer 6S constituting the shoulder region Tsho of the tread. In the illustrated example, the circumferential grooves 10a and 10c are located at the boundary between the center region Tcent and the shoulder region Tsho, but the grooves may be at any position or may be omitted. Further, in the illustrated example, the base rubber layer 7 is formed uniformly in the tire width direction, but may be divided in the tire width direction.

Referring to fig. 2, the structure of a tire according to the present disclosure is explained in more detail. Fig. 2 is an enlarged sectional view of a portion of the tire 1 in fig. 1.

The shoulder crown rubber layer 6S preferably includes a plurality of layers stacked in the tire radial direction, and includes three layers 60S, 61S, and 62S in the example of fig. 2. This structure with multiple layers allows for the easy formation of rubber with different multiple physical properties in the crown rubber layer. Although three layers are included in the illustrated example, the number of layers may be two layers, or may be four or more layers.

The three layers 60s, 61s, and 62s can be formed of rubbers having different physical properties, respectively. For example, the modulus values of the respective layers preferably satisfy the relationship of layer 60s > layer 61s > layer 62 s. This structure can improve the cornering power and reduce uneven wear while enjoying the effect of suppressing rolling resistance. Further, since the modulus value is changed stepwise, it is possible to suppress rubber peeling or the like due to a change in physical properties in the tire radial direction.

For example, the modulus value of the layer 60s may be set to 3.3MPa or more and 3.5MPa or less, the modulus value of the layer 61s may be set to 2.8MPa or more and 3MPa or less, and the modulus value of the layer 62s may be set to 2.6MPa or more and 3MPa or less.

The three layers 60s, 61s and 62s may have any thickness. In the illustrated example, the thicknesses of the three layers 60s, 61s, and 62s are substantially uniform. The thicknesses of the three layers 60s, 61s, and 62s refer to an average value of the thicknesses in the tire radial direction.

Further, the shoulder cap rubber layer 6S may be configured such that the modulus value decreases from the tread surface inward in the tire radial direction. At this time, a plurality of layers may be provided in the tire radial direction, or the physical properties may be individually changed within one layer. In this structure, the physical property variation in the tire radial direction is smooth, thereby allowing prevention of rubber peeling or the like.

[ second embodiment ]

Referring to fig. 1 and 3, a second embodiment of a tire according to the present disclosure is explained below. FIG. 3 is an enlarged cross-sectional view of a portion of a tire according to another embodiment of the present disclosure. This tyre 1 has the same internal reinforcing structure as the tyre 1 of figures 1 and 2. The tire in the second embodiment has the same structure as the tire according to the first embodiment except for the form of the center rubber 5C.

In the tire according to the present embodiment, the center rubber 5C preferably has a modulus value M4, and the modulus value M4 is lower in the surface layer 5Co of the tread than in the portion other than the surface layer 5 Co. In other words, the central rubber 5C may be configured such that the modulus value is uniform from the tread surface inward in the tread radial direction or is large on the inner side, thereby achieving the function of a core that supports the load when the tire rolls. However, in order to ensure safety as a load supporting core, it is more preferable to increase the modulus value radially inward of the tread. Further, reducing the modulus value in the vicinity of the tread surface of the center region Tcent makes it easier to reduce the difference in rigidity from the tread surface layer 5So in the shoulder rubber 5S, further contributing to preventing a decrease in cornering power. It is possible to reduce the occurrence of uneven wear due to the difference in the level of rigidity.

In more detail, the modulus value of the surface layer 5Co of the center rubber 5C can be set to 3.3MPa or more and 3.5MPa or less, for example. Setting the modulus value to 3.3MPa or more allows reduction of distortion with respect to the load, and setting the modulus value to 3.5MPa or less is advantageous for reducing the difference in rigidity with the shoulder crown rubber layer 6S and for preventing reduction of the cornering power. It is also possible to reduce the occurrence of uneven wear due to a difference in the level of rigidity.

In fig. 3, the central crown rubber layer 6C includes a plurality of layers 60C, 61C, and 62C stacked in the tire radial direction. Although three layers are included in the illustrated example, one layer, two layers, or more than four layers may be included. The multiple layers can be formed of rubbers having different physical properties.

Here, the modulus values of the respective layers preferably satisfy the relationship of layer 60c ≦ layer 61c ≦ layer 62 c. This structure can improve the cornering power and reduce uneven wear while enjoying the effect of suppressing rolling resistance. Further, since the modulus value is changed stepwise, when the modulus values are different between layers, it is possible to suppress rubber peeling or the like due to a change in physical properties in the tire radial direction.

The three layers 60c, 61c and 62c may have any thickness. In the illustrated example, the thicknesses of the three layers 60c, 61c, and 62c are substantially uniform. The thicknesses of the three layers 60c, 61c, and 62c refer to an average value of the thicknesses in the tire radial direction.

Further, the central cap rubber layer 6C may be configured such that the modulus value increases from the tread surface inward in the tire radial direction. At this time, a plurality of layers may be provided in the tire radial direction, or the physical properties may be individually changed within one layer. In this structure, the physical property variation in the tire radial direction is smooth, thereby allowing prevention of rubber peeling or the like.

Description of the reference numerals

1 tire

2 bead core

3 tyre body

4a, 4b inclined belt layers

4 belted

5 Tread rubber

5C Central rubber

5S tire shoulder rubber

Tread surface layer in 5Co center rubber

Tread surface layer in 5So shoulder rubber

6 crown rubber layer

6C center crown rubber layer

6S tire shoulder crown rubber layer

60s, 61s, 62s, 60c, 61c, 62c layers

7 base rubber layer

10a, 10b, 10c circumferential grooves