PNEUMATIC TIRE

Abstract

A belt layer of a pneumatic tire includes a first main working belt, a second main wording belt having a cord angle different from a cord angle of the first main working belt in a direction with respect to a tire-circumferential direction, reinforcement belt. A cord angle of the reinforcement belt and a representative main groove angle have different directions with respect to the tire-circumferential direction, the representative main groove angle being defined as an angle formed by an element of the main groove with the longest length in the tire-circumferential direction and the tire-circumferential direction.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority of Japanese Patent Application No. 2015-150100 filed on Jul. 29, 2015, the content of which is incorporated herein by reference.

BACKGROUND OF THE INVENTION

Technical Field

The present invention relates to a pneumatic tire.

Related art

In a pneumatic radial tire for a heavy load used for a vehicle such as a truck or a bus, it has been known that a belt layer arranged between a carcass and a tread portion includes a reinforcement belt with cords having a small inclination angle with respect to the tire-circumferential direction (cord angle) of 0 to 5 degrees (see Japanese Patent No. 5182455, for example). The reinforcement belt is intended to suppress a growth of the tire in the radial direction.

SUMMARY

The small cord angle of the reinforcement belt ranging from approximately 0 to 5 degrees increases a force for holding a shape of the tread portion to reduce distortion at an end portion of the belt, and therefore is advantageous in view of belt durability.

However, the small cord angle of the reinforcement belt ranging from approximately 0 to 5 degrees causes an excessively large binding force in a tire-radial direction, thereby promoting an increased tendency in the deformation of a tire in the tire-width direction. The increased deformation in the tire-width direction increases the deformation of the tire at an area ranging from a bead portion to a portion having a largest width in a tire cross section. As a result, distortion in the bead portion is increased, causing lower resistance against a defect such as separation in the bead portion (bead durability).

In forces in the tire-width direction (lateral direction) generated on a tire rotating in a loaded state, a force caused by a tire structure is referred to as a ply steer. For example, in the case where the cord angle of the reinforcement belt is not set to 0 degrees, the ply steer is generated. The ply steer promotes a phenomenon (vehicle drifting) in which a tendency to skew appears in a vehicle traveling straight. In a conventional pneumatic tire having a reinforcement belt including the tire disclosed in Japanese Patent No. 5182455, suppression of the vehicle drifting caused by the cord angle of the reinforcement belt is not particularly discussed.

It is an object of the present invention to enhance bead durability and effectively suppress vehicle drifting in a pneumatic tire while ensuring an effect of suppressing a growth in a tire-radial direction and belt durability

An aspect of the present invention provides a pneumatic tire comprising a belt layer arranged between a carcass and a tread portion, wherein the belt layer comprises a first main working belt, a second main working belt arranged at an outer side of the first main working belt in a tire-radial direction, the second main working belt having a cord angle different from a cord angle of the first main working belt in a direction with respect to a tire-circumferential direction, and a reinforcement belt, an absolute value of a cord angle of the reinforcement belt is not smaller than 6 degrees and not larger than 9 degrees, a tread pattern including a main groove is formed on a tread surface of the tread portion, and the cord angle of the reinforcement belt and a representative main groove angle have different directions with respect to the tire-circumferential direction, the representative main groove angle being defined as an angle formed by an element of the main groove with the longest length in the tire-circumferential direction and the tire-circumferential direction.

in this specification, the term “cord angle” is defined an acute angle which a cord of a belt or a ply forms with respect, to a tire-circumferential direction. When the cord extends in the tire-circumferential direction, the cord angle is 0 degrees. The positive or negative of the “cord angle” id determined as follows. Both of the case where the cord extends rightward and away from a center line in the tire-width direction (right upward direction) viewed from a tread surface and where the cord extends leftward and away from the center line in the tire-width direction (left upward direction) viewed from the tread surface, the cord angle can be defined as the positive. This is also applied to representative main groove angles. In embodiments described later, the left upward direction is defined as the positive.

The cord angle of the reinforcement belt is set to a value not smaller than 6 degrees and not larger than 9 degrees, instead of setting the cord angle to a small angle such as an angle of not smaller than 0 degrees and not larger than 5 degrees (an angle substantially regarded as 0 degrees or an angle close to such angle). Such configuration can obviate a phenomenon where a binding force in a tire-radial direction generated by the reinforcement belt becomes excessively large, and therefore can suppress the excessively large deformation of the tire in the tire-width direction. As a result, the distortion generated in the bead portion can be suppressed, and therefore bead durability can be enhanced.

The cord angle of the reinforcement belt and the representative main groove angle have different directions with respect to the tire-circumferential direction. For this reason, a component force in a lateral direction of a belt tension in the reinforcement belt is offset by a force in the lateral direction which is caused by the tread pattern. As a result, a ply steer component, is decreased so that vehicle drifting can be suppressed effectively.

When the absolute value of the cord angle of the reinforcement belt is set to be not smaller than 6 degrees and not larger than 9 degrees, the effect of suppressing a growth in a tire radial direction is reduced as compared with the case where the absolute value of the cord angle is not smaller than 0 degrees and not larger than 5 degrees. However, the absolute value of the cord angle of the reinforcement belt is 9 degrees at a maximum. Therefore, the binding force in the tire-radial direction is prevented from being reduced excessively. Therefore, it is possible to ensure the effect of suppressing a growth in the tire-radial direction which is required. Moreover, a sufficient shape holding force of the tread portion can be obtained and distortion in a belt end portion can be reduced. Therefore, necessary belt durability can be ensured. Furthermore, the sufficient shape holding force of the tread portion can be obtained and the distortion in the belt end portion can be reduced. Therefore, necessary belt durability can be ensured.

As described above, according to the pneumatic tire of the present invention, it is possible to enhance the bead durability, and furthermore, effectively suppress the vehicle drifting while ensuring the effect of suppressing the growth in the tire-radial direction and the belt durability.

When the tread pattern is a rib pattern the relation “−8<θr+θrmg<8” is satisfied, where θr denotes the cord angle of the reinforcement belt (degrees) and θrmg denotes the representative main groove angle (degrees).

When the tread pattern is a block pattern, “−18<θr+θrmg<8” is satisfied where θr denotes the cord angle of the reinforcement belt (degrees) and θrmg denotes the representative main groove angle (degrees).

Preferably, a width of the reinforcement belt is equal to or wider than 50% of a tire-section width and not wider than a width of a narrower one of the first and second main working belts.

The width of the reinforcement belt is equal to or wider than 50% of a tire-section width. That is, the reinforcement belt has a sufficiently wide width instead of the: narrow width. Also due to this configuration, the tire can ensure a desired effect of suppressing a growth of the tire in the radial direction. Further, the tire can acquire a sufficient force for holding a shape of the tread portion so that distortion at an end portion of the belt can be reduced whereby the tire can ensure required belt durability. The width of the reinforcement belt is not wider than either narrower one of the first and second main working belts. Accordingly, the distortion generated in the reinforcement belt can be reduced.

Preferably, the reinforcement belt is arranged between the first main working belt and the second main working belt.

Arranging the reinforcement belt between the first main working belt and the second main working belt can alleviate breakage of the cord in the vicinity of a road contact surface, and therefore cord breakage can be effectively prevented.

The cord angles of the first and second main working belts can be respectively 20±10 degrees. Further, the cord angles of the first and second main working belts can be respectively 17±5 degrees.

The belt layer can further comprise a protection belt arranged at an outer side of the second main working belt in the tire-radial direction.

The belt layer can further comprise a buffer belt arranged at an inner side of the first main working belt in the tire-radial direction.

The pneumatic tire can have an aspect ratio of not larger than 70% and a nominal section width of not smaller than 365.

According to the pneumatic tire of the present invention, bead durability can be enhanced while ensuring the effect of suppressing the growth of the tire in the radial direction and belt durability.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and the other features of the present invention will become apparent from the following description and drawings of an illustrative embodiment of the invention in which:

FIG. 1 is a meridian sectional view of a Pneumatic tire according to a first embodiment of the present invention;

FIG. 2 is a development view of a tread portion;

FIG. 3 is a schematic partial sectional view of the pneumatic tire when a load is applied;

FIG. 4 is a development view of the tread portion and a belt layer;

FIG. 5 is a development view of a tread portion and a belt layer of a second embodiment of the present invention;

FIG. 6 is a meridian sectional view of a pneumatic tire according to a modification; and

FIG. 7 is a meridian sectional view of a pneumatic tire according to Comparative Example 1.

DETAILED DESCRIPTION OF EMBODIMENTS

First Embodiment

FIG. 1 shows a rubber pneumatic tire (hereinafter referred to as “tire”) 1 according to an embodiment of the present invention. The tire 1 is a pneumatic radial tire for a heavy load used for a vehicle such as a truck or a bus. Further, the tire 1 is a low-profile tire having an aspect ratio of not larger than 70%. An aspect ratio is. defined as a ratio of a maximum tire-section height Ht to a maximum tire-section width Wt. Specifically, a size of the tire 1 in this embodiment is 445/50R22.5 (expressed in accordance with ISO standard).

The tire 1 includes a tread portion 2, a pair of side portions 4, and a pair of bead portions 6. The bead portions 6 are respectively formed on inner edge portions of the side portions 4 in a tire-radial direction (edge portions of the side portions 4 opposite to the tread portion 2). A carcass 8 is arranged between the pair of bead portions 6. An inner liner (not shown in the drawing) is arranged in an innermost peripheral surface of the tire 1. A belt layer 10 is arranged between the carcass 8 and a tread surface of the tread portion 2, in other words, in the tread portion 2, the belt layer 10 is arranged at an outer side of the carcass 8 in the tire-radial direction. As described later in detail, in this embodiment, the belt layer 10 includes five belts 11 to 15.

The bead portion 6 includes a bead core 22, a bead filler 24, and a chafer 26. Around the bead core 22, an end portion of the carcass 8 in a tire-width direction is wound up from an inner side to an outer side in a tire-width direction along the bead filler 24. The chafer 26 is arranged around the bead filler 24 so as to be arranged adjacently to an outer side of the end portion of the carcass 8.

Referring to FIGS. 1 and 2, the carcass 8 in this embodiment is formed of one carcass ply, and is formed of a plurality of carcass cords 8a arranged parallel to each other and coated by a rubber layer. Each carcass cord 8a is arranged so as to extend in the tire-radial direction, and has an angle θ0 with respect to a tire-circumferential direction (cord angle) set to 90 degrees. In FIGS. 1 and 2, symbol Ce indicates a center line in the tire-width direction. The direction along which the center line Ce extends is a tire-radial direction. While the carcass cord 8a in this embodiment is made of steel, the carcass cord 8a can be made of organic fibers.

Referring to FIGS. 1 and 2, the belt layer 10 in this embodiment includes five belts arranged in an overlapping manner. These belts include a buffer belt 11, a first main working belt 12, a reinforcement belt 13, a second main working belt 14, and a protection belt 15.

The buffer belt 11 is arranged adjacently to an outer side of the carcass 8 in the tire-radial direction. The first main working belt 12 is arranged adjacently to an outer side of the buffer belt 11 in the tire-radial direction. The second main working belt 14 is arranged at an outer side of the first main working belt 12 in the tire-radial direction. The reinforcement belt 13 is arranged between the first main working belt 12 and the second main working belt 14. That is, the reinforcement belt 13 is arranged adjacently to the outer side of the first main working belt 12 in the tire-radial direction, and is also arranged adjacently to an inner side of the second main working belt 14 in the tire-radial direction. The protection belt 15 is arranged adjacently to an outer side of the second main working belt 14 in the tire-radial direction.

Main functions of the first and second main working belts 12 and 14 are to apply a binding force in the tire-radial direction to the carcass 8 (with a cord angle θ0 being set to 90 degrees). A main function of the reinforcement belt 13 is to compensate for the shortage in a binding force in the tire-radial direction which is applied to the tire 1 by the first and second main working belts 12 and 14. A main function of the protection belt 15 is to enhance external damage resistance of the tire 1 by protecting the first and second main working belts 12 and 14. A main function of the buffer belt 11 is to enhance impact resistance of the tire 1.

Each of these belts 11 to 15 is formed of a plurality belt cords 11a, 12a, 13a, 14a, and 15a arranged parallel to each other and coated by a rubber layer.

Referring FIG. 2, inclination angles (cord angles) θb, θp1, θr, θp2; and θu of belt cords 11a to 15a of belts 11 to 15 forming the belt layer 10 will be described. In the description hereinafter, regarding the cord angles θb, θp1, θr, θp2, and θu, a direction along which the belt cords 11a to 15a extend rightward and away from the center line Ce in the tire-width direction when an arrow A in FIG. 2 is set as a reference direction can be referred to as “right upward direction”. Similarly, a direction along which the belt cords 11a to 15a extend leftward and away from the center line Ce in the tire-width direction when the arrow A in FIG. 2 is set as the reference direction can be referred to as “left upward direction”.

In this embodiment, the cord angles θb, θp1, θr, θp2, and θu of each of the belts 11 to 15 constituting the belt layer 10 have positive signs when the belt cords 11a to 15a extend in the left upward direction and have negative signs when the belt cords 11a to 15a extend in the right upward direction. This is the same as in the cord angle θ0 of the carcass 8. Alternatively, the cord angles θ0, θb, θp1, θr, θp2, and θu may have positive signs when the belt cords extend in the right upward direction and have negative signs when the belt cords extend in the left upward direction.

The cord angle θp1 of the belt cord 12a of the first main working belt is −17 degrees (right upward direction), in this embodiment. The absolute value of cord angle θp1 can be set to a value which falls within a range of 20±10 degrees, and can preferably be set to a value which falls within a range of 17+5 degrees.

The cord angle θp2 of the belt cord 14a of the second main working belt is −17 degrees (left upward direction), in this embodiment. The absolute value of cord angle θp2 can be set to a value which falls within a range of 20±10 degrees, and can preferably be set to a value which falls within a range of 17±5 degrees.

The cord angles θp1 and θp2 are set so that the belt cords 12a and 14a extend in a different direction with respect to a center line Ce in a tire-width direction. In other words, one of the cord angles θp1 and θp2 is set to the right upward direction, whereas the other of the cord angles θp1 and θp2 is set to the left upward direction.

The cord angle θr of the belt cord 13a of the reinforcement belt 13 is 7 degrees (left upward direction) The absolute value of the cord angle θr can be set to a value which falls within a range of not smaller than 6 degrees and not larger than 9 degrees.

The cord angle θb of the belt cord 11a of the buffer belt 11 is set to −65 degrees (right upward direction), in this embodiment. The cord angle θb can be set to a value which falls within a range of 60±15 degrees.

The cord angle θu of the belt cord 15a of the protection belt 15 is set to −20 degrees in this embodiment. The cord angle θu can be set to a value which falls within a range of 20±10 degrees.

Numerical values (including upper and lower limit values of a numerical value range) of the cord angles θb, θp1, θr, θp2, and θu can include substantially unavoidable errors, and are not necessarily geometrically precise values as long as that functions required for the belts 11 to 15 are satisfied. This is also applied, to the cord angle θ0 of the carcass cords 8a.

The cord angles θb, θp1, θr, θp2, and θu of the belts 11 to 15 can be coordinated as shown in the following Table 1.

TABLE 1
		Settable range of angle
	Embodiment	(Absolute Value)
Buffer belt	−65 degrees	60 ± 15 degrees
	(right upward direction)	(right upward direction)
First main	−17 degrees	20 ± 10 degrees (17 ± 5 degrees)
working belt	(right upward direction)	(right upward direction)
Reinforcement belt	7 degrees	Not smaller than 6 degrees and
	(left upward direction)	not larger than 9 degrees
Second main	17 degrees	20 ± 10 degrees (17 ± 5 degrees)
working belt	(left upward direction)	(right upward direction)
Protection belt	−20 degrees	20 ± 10 degrees
	(right upward direction)	(right upward direction)

Main data except for the cord angles of the belts 11 to 15 in this embodiment are shown in the following Table 2.

TABLE 2
			Thickness
			of cord
			including	Number
		Diameter	cover	of
	Raw	of cord	rubber	ends	Width
	material	(mm)	(mm)	(EPI)	(mm)
Buffer belt	Steel	1.1	1.7	12	W1 = 345
First main	Steel	1.4	2.6	12	W2 = 370
working belt
Reinforcement belt	Steel	1.1	1.7	12	W3 = 290
Second main	Steel	1.4	2.6	12	W4 = 325
working belt
Protection belt	Steel	1.1	1.9	9	W5 = 295

As shown in Table 2, in this embodiment., a width W4 (325 mm) of the second main working belt 14 which is arranged relatively outer side in the tire-radial direction is set narrower than a width W2 (370 mm) of the first main working belt 12 which is arranged relatively inner side in the tire-radial direction.

A width W3 of the reinforcement belt 13 is set to a value equal to or wider than 50% of a maximum tire-section width Wt (W3≧0.5 Wt). In this embodiment, the maximum tire-section width Wt is a value set under conditions where the tire 1 is mounted on a predetermined rim (a rim 31 is schematically shown in FIG. 1), the tire 1 is filled with air until an inner pressure reaches a predetermined internal pressure (830 kPa which is an internal pressure determined by the Tire and Rim Association, Inc (TRA)), and the tire 1 is in an unloaded state. The width W3 of the reinforcement belt 13 is set narrower than a width of either one of the first and second main working belts 12 and 14 having a narrower width than the other (W3<W2, W4) in this embodiment, the width W3 of the reinforcement belt 13 is set to 290 mm. Accordingly, the width W3 of the reinforcement belt 13 is equal to or wider than 50% of a maximum tire-section width Wt (440 mm) under the above-mentioned conditions, and is narrower than the width W4 (325 mm) of the second main working belt 14 having a narrower width.

The absolute value of the cord angle θr of the reinforcement belt 13 is set to an angle of not smaller than 6 degrees and not larger than 9 degrees, instead of a small angle of not smaller than 0 degrees to not more than 5 degrees (an angle which can be substantially regarded as 0 degrees or an angle close to 0 degrees). Such configuration can prevent a binding force in a tire-radial direction generated by a reinforcement belt 13 from becoming excessively large, and therefore the excessively large deformation of the tire in the tire-width direction can be suppressed. Since the excessively large deformation of the tire in the tire-width direction can be suppressed, the distortion generated in the bead portion 6 can be suppressed, and therefore bead durability (resistance against the generation of a defect such as separation in the bead portion) can be enhanced.

As conceptually shown in FIG. 3, in a loaded state (a state where the tire 1 is mounted on a vehicle), belt cords 13a of the reinforcement belt 13 are bent in regions (symbols C) of a tread surface of the tread portion 2 in front of and behind a road contact surface 2a in the rotational direction of the tire indicated by an arrow B. The smaller cord angle θr, the more conspicuous the bending of the belt cords 13a becomes. By setting the cord angle θr to a value not smaller than 6 degrees and not larger than 9 degrees, compared to a case where the cord angle θr is set to a small angle such as an angle not smaller than 0 degrees and not larger than 5 degrees, bending of the belt cord 13a of the reinforcement belt 13 in the vicinity of the road contact surface 2a can be alleviated, and therefore cord breakage can be effectively prevented.

As described above, the width W3 of the reinforcement belt 13 is set narrower than the width W4 of the second main working belt 14 which is narrower one of the first and second main working belts 12, 14. Such configuration can also effectively prevent cord breakage of the belt cord 13a of the reinforcement belt.

As described above, the reinforcement belt 13 is arranged between the first main working belt 12 and the second main working belt 14. Due to such an arrangement, the reinforcement belt 13 is protected by the first and second main working belts 14, and therefore cord breakage of the belt cord 13a of the reinforcement belt 13 caused due to bending of the cord in the vicinity of the road contact surface 2a (symbols C in FIG. 3) can be effectively prevented.

As described above, the width W3 of the reinforcement belt 13 is set to be not wider than the width W4 of the second main working belt 14 which is the narrower one of the first, and second main working belts 12, 14. Also in this respect, it is possible to effectively prevent the cord breakage of the belt cord 13a of the reinforcement belt 13.

From these reasons, the cord breakage of the reinforcement belt 13 can be prevented effectively.

With reference to FIG. 4, a tread pattern is formed on the tread surface of the tread portion 2. The tread pattern according to this embodiment is a rib pattern 50. The rib pattern 50 includes a plurality of main grooves 52 extending in the tire-circumferential direction and a plurality of thin grooves 53 which are sufficiently shallower and thinner than the main groove 52 (having a depth less than 40% of the depth of the main groove 52 and a groove width less than 25% of the groove width of the main groove 52). A rib 54 is defined between two main grooves 52 which are adjacent to each other. A rib pattern provided with only the main grooves 52 and no thin groove 53 is also included in the rib pattern in this specification.

An angle formed by an element with the longest length in the tire-circumferential direction, in the elements constituting the main groove included in the rib pattern, and the tire-circumferential direction is defined as a representative main groove angle θrmg. In this embodiment, the main groove 52 is formed by repetition of two elements 52a and 52b having different tire-circumferential directions from each other. The length of the element 52a in the tire-circumferential direction is greater than the length of the element 52b in the tire-circumferential direction. Therefore, in the rib pattern 50 according to this embodiment, the representative main groove angle θrmg is an angle formed by the element 52a of the main groove 52 and the tire-circumferential direction. As is apparent with reference to FIG. 4, the element 52a of the main groove 52 extends in the right upward direction, and the representative main groove angle θrmg has a negative sign.

A belt tension Fr of the belt cord 13a of the reinforcement belt 13 can be decomposed into a component Frc in the tire-circumferential direction and a component Frw in the tire-width direction (the lateral direction). The component Frw in the tire-width direction (the lateral direction) of the tension Fr of the reinforcement belt 13 having the cord angle θr (the absolute value being not smaller than 6 degrees and not larger than 9 degrees as described above) increases a ply steer component. The ply steer component is one of forces in the tire-width direction (the lateral direction) generated on a tire rotating in a loaded state which is caused by a tire structure.

In this embodiment, the belt cord 13a of the reinforcement belt 13 extends in the left upward direction, and the cord angle θr of the reinforcement belt 13 has a positive sign. On the other hand, the element 52a of the main groove 52 extends in the right upward direction, and the representative main groove angle θrmg has a negative sign. In other words, the cord angle θr of the reinforcement belt 13 and the representative main groove angle θrmg of the rib pattern 50 have different directions with respect to the tire-circumferential direction. For this reason, the component Frw in the tire-width direction (the lateral direction) of the tension Fr of the reinforcement belt 13 having the cord angle θr, and a force Ftw in the tire-width direction which is caused by the shape of the main groove 52 (the element 52a extending in the right upward direction is predominant) have directions opposite to each other. For this reason, the component Frw in the tire-width direction (the lateral direction) of the tension Fr of the reinforcement belt 13 is offset by the force Ftw in the tire-width direction which is caused by the shape of the main groove 52. As a result, the ply steer component is decreased so that the vehicle drifting can be suppressed effectively.

In order to effectively offset the component Frw in the tire-width direction (the lateral direction) of the tension Fr of the reinforcement belt 13 by the force Ftw in the tire-width direction which is caused by the shape of the main groove 52, the cord angle θr and the representative main groove angle θrmg are preferably 0 or around 0, specifically, larger than −8 degrees and smaller than 8 degrees. In other words, in the case of the rib pattern 50, the cord angle θr and the representative main groove angle θrmg preferably satisfy the relationship of the following Expression (1) in order to decrease the ply steer component and effectively suppress the vehicle drifting.

−8<θr+θrmg<8   (1)

By setting the cord angle θr of the reinforcement belt 13 to a value not smaller than 6 degrees and not larger than 9 degrees, an effect of suppressing a growth of the tire 1 in the radial direction is reduced compared to the case where the cord angle θ3 is set to a value not smaller than 0 degrees and not larger than 5 degrees. However, the cord angle θr of the reinforcement belt 13 is 9 degrees at maximum, and therefore there is no possibility that a binding force in the tire-radial direction is excessively reduced. Further, as described above, the width W3 of the reinforcement belt 13 is equal to or wider than 50% of a maximum tire-section width Wt. That is, a width of the reinforcement belt 13 is not narrow but is sufficiently wide. Due to these reasons, the tire 1 can ensure a required effect of suppressing a growth of the tire 1 in the radial direction. Further, the tire can acquire a sufficient force for holding a shape of the tread portion 2 so that distortion at the end portion of the belt can be reduced whereby the tire can ensure required belt durability. The width W3 of the reinforcement belt 13 is narrower than a width of the narrower one of the first and second math working belts 12 and 14 (widths W2, W4). Accordingly, the distortion generated in the reinforcement belt 13 can be reduced.

As described above, the tire 1 according to this embodiment can enhance the belt durability and the bead durability, and furthermore, effectively suppress the vehicle drifting while ensuring the effect of suppressing a growth in a radial direction.

Second Embodiment

FIG. 5 shows a tread pattern formed on a tread surface of a tread portion 2 in a tire 1 according to a second embodiment of the present invention.

The tread pattern according to this embodiment is a block pattern 60. The block pattern 60 includes a plurality of main grooves 62 extending in a tire-circumferential direction, a plurality of lateral grooves 63 extending in a tire-width direction (lateral direction) (having a depth equal to or greater than 40% of the depth of the main groove 62 and a groove width equal to or wider than 25% of the groove width of the main groove 62), and a plurality of thin grooves 64 which are sufficiently shallower and thinner than the main groove 62 (having a depth less than 40% of the depth of the main groove 62 and a groove width not wider than 25% of the groove width of the main groove 62). The block 65 is defined by two main grooves 62 adjacent to each other and two lateral grooves 63 adjacent to each other. A block pattern provided with only the main grooves 62 and the lateral grooves 63 and no thin groove 64 is also included in the block pattern in this specification.

In this embodiment, the main groove 62 is formed by repetition of two elements 62a and 62b having different tire-circumferential directions from each other. The length of the element 62a in the tire-circumferential direction is greater than the length of the element 62b in the tire-circumferential direction. Therefore, in the block pattern 60 according to this embodiment, the representative main groove angle θrmg is an angle formed by the element 62a of the main groove 62 and the tire-circumferential direction. As is apparent with reference to FIG. 5, the element 62a of the main groove 62 extends in the right upward direction, and the representative main groove angle θrmg has a negative sign.

In this embodiment, the belt cord 13a of the reinforcement belt 13 extends in the left upward direction, and the cord angle θr of the reinforcement belt 13 has a positive sign. On the other hand, the element 62a of the main groove 62 extends in the right upward direction, and the representative main groove angle θrmg has a negative sign. In other words, the cord angle θr of the reinforcement belt 13 and the representative main groove angle θrmg of the block pattern 60 have different directions with respect to the tire-circumferential direction. For this reason, a component Frw in the tire-width direction (the lateral direction) of a tension Fr of the reinforcement belt 13 having the cord angle θr, and a force Ftw in the tire-width direction which is caused by the shape of the main groove 62 (the element 62a extending in the right upward direction is predominant) have directions opposite to each other. For this reason, the component Frw in the tire-width direction (the lateral direction) of the tension Fr of the reinforcement belt 13 is offset by the force Ftw in the tire-width direction which is caused by the shape of the main groove 62. As a result, a ply steer component is decreased so that vehicle drifting can be suppressed effectively.

In order to effectively offset the component Frw in the tire-width direction (the lateral direction) of the tension Fr of the reinforcement belt 13 by the force Ftw in the tire-width direction which is caused by the shape of the main groove 62, the cord angle θr and the representative main groove angle θrmg are preferably 0 or around 0, specifically, larger than −18 degrees and smaller than 8 degrees. In other words, in the case of the block pattern 60, the cord angle θr and the representative main groove angle θrmg preferably satisfy the relationship of the following Expression (2) in order to decrease the ply steer component and effectively suppress the vehicle drifting.

−18<θr+θrmg<8   (2)

As is apparent with reference to Expressions (1) and (2), in the case of the block pattern 60 (Expression (2)), a range which can be taken by a sum of the cord angle θr and the representative main groove angle θrmg is wider as compared with case of the rib pattern 50 (Expression (1)). In the case of the block pattern 60, this is influenced by the presence of the lateral groove 63.

The structure of the tire 1 according to this embodiment is the same as that in the first embodiment. Therefore, for the same reason as that in the first embodiment, it is possible to enhance belt durability and bead durability while ensuring an effect of suppressing a growth in a radial direction.

In both of the tires according to the first and second embodiments, the main grooves 52 and 62 are formed by repetition of two elements (the elements 52a and 52b in the first embodiment, and the elements 62a and 62b in the second embodiment). If the main groove is formed of three elements or more, the representative main groove angle θrmg is an angle formed by any of the three or more elements with the longest length in the tire-circumferential direction and the tire-circumferential direction.

FIG. 6 shows a modification of the tire 1 according to the embodiment. In the modification, a belt layer 10 includes four belts, that is, a first main working belt 12, a reinforcement belt 13, a second main working belt 14, and a protection belt 15, but does not include a buffer belt 11. Even if the buffer belt 11 is not provided, it is possible to enhance bead durability, and furthermore, effectively suppress vehicle drifting while ensuring an effect of suppressing a growth in a radial direction of the tire 1 and belt durability in the same manner as in the first and second embodiments.

EXAMPLE

Tires according to Comparative Examples 1 to 6 shown in the following Table 3 and Examples 1 to 6 shown in the following Table 4 were subjected to an evaluation test performed for evaluating belt durability and vehicle drifting. Assume that data which are not described particularly hereinafter are shared in common by the tires according to Comparative Examples 1 to 6 and Examples 1 to 6. Particularly, in all of Comparative Examples 1 to 6 and Examples 1 to 6, a tire size is set to 445/50R22.5. Moreover, in all of Comparative Examples 1 to 6 and Examples 1 to 6, the width W2 of the first main working belt 12 is set to 365 mm and the width W4 of the second main working belt 14 is set to 340 mm. Furthermore, in all of Comparative Examples 1 to 6 and Examples 1 to 6, the width W3 of the reinforcement belt 13 is set to 290 mm.

TABLE 3
	Comparative	Comparative	Comparative
	Example 1	Example 2	Example 3
Note	No	Rib pattern	Rib pattern
	reinforcement	θr and θrmg	θr + θrmg
	belt (FIG. 7)	having	being
		the same	smaller than
		direction	lower
			limit values
Cord angle θr (degrees)	—	9	6
of reinforcement belt
Representative main	7	3	−16
groove angle θrma
θr + θrmg	—	12	−10
Belt durability	100	110	123
Vehicle drifting	100	89	88
	Comparative	Comparative	Comparative
	Example 4	Example 5	Example 6
Note	Rib pattern	Block pattern	Block pattern
	θr + θrmg	θr + θrmg	θr + θrmg
	being	being	being
	larger	smaller	larger
	than upper	than lower	than upper
	limit values	limit values	limit values
Cord angle θr (degrees)	9	6	6
of reinforcement belt
Representative main	1	−26	4
groove angle θrmg
θr + θrmg	10	−20	10
Belt durability	110	123	123
Vehicle drifting	88	85	88

TABLE 4
	Example 1	Example 2	Example 3
Note	Rib pattern	Block pattern	Rib pattern
	θr being around	θr being around	θr + θrmg being
	center value	center value	around lower
			limit values
Cord angle θr (degrees)	7	7	7
of reinforcement belt
Representative main	−8	−17	−12
groove angle θrmg
θr + θrmg	−1	−10	−5
Belt durability	120	120	120
Vehicle drifting	98	97	95
	Example 4	Example 5	Example 6
Note	Rib pattern	Block pattern	Block pattern
	θr + θrmg being	θr + θrmg being	θr + θrmg being
	around upper	around lower	around upper
	limit values	limit values	limit values
Cord angle θr (degrees)	7	7	9
of reinforcement belt
Representative main	−2	−23	−2
groove angle θrmg
θr + θrmg	5	−15	7
Relt durability	120	120	110
Vehicle drifting	95	95	97

The belt layer 10 according to Comparative Example 1 shown in FIG. 7 does not include the reinforcement belt 13, but includes the buffer belt 11, the first main working belt 12, the second main working belt 14, and the protection belt 15.

The tire according to Comparative Example 2 has the rib pattern. In the tire according to Comparative Example 2, both the cord angle θr of the reinforcement belt and the representative main groove angle θrmg have positive signs (both the belt cord 13a of the reinforcement belt 13 and the main groove extend in the left upward direction).

The tire according to Comparative Example 3 has the rib pattern. In the tire according to Comparative Example 3, the sum of the cord angle θr of the reinforcement belt and the representative main groove angle θrmg is −10 degrees, which is smaller than the lower limit value of the range (larger than −8 degrees and smaller than 8 degrees) according to the present invention.

The tire according to Comparative Example 4 has the rib pattern. In the tire according to Comparative Example 4, the sum of the cord angle θr of the reinforcement belt and the representative main groove angle θrmg is 10 degrees, which is larger than the upper limit value of the range (larger than −8 degrees and smaller than 8 degrees) according to the present invention.

The tire according to Comparative Example 5 has the block pattern. In the tire according to Comparative Example 5, the sum of the cord angle θr of the reinforcement belt and the representative main groove angle θrmg is −20 degrees, which is smaller than the lower limit value of the range (larger than −18 degrees and smaller than 8 degrees) according to the present invention.

The tire according to Comparative Example 6 has the block pattern. In the tire according to Comparative Example 6, the sum of the cord angle θr of the reinforcement belt and the representative main groove angle θrmg is 10 degrees, which is larger than the upper limit value of the range (larger than −18 degrees and smaller than 8 degrees) according to the present invention.

The tire according to Example 1 has the rib pattern in the tire according to Example 1, the cord angle θr of the reinforcement belt is set to 7 degrees, which is a value around the center value of the range of the cord angle θr (not smaller than 6 degrees and not larger than 9 degrees) according to the present invention. The sum of the cord angle θr of the reinforcement belt and the representative main groove angle θrmg is −1 degrees, which falls within the range (larger than −8 degrees and smaller than 8 degrees) according to the present invention.

The tire according to Example 2 has the block pattern. In the tire according to Example 2, the cord angle θr of the reinforcement belt is set to 7 degrees, which is a value around the center value of the range of the cord angle θr (not smaller than 6 degrees and not larger than 9 degrees) according to the present invention. The sum of the cord angle θr of the reinforcement belt and the representative main groove angle θrmg is −10 degrees, which falls within the range (larger than −18 degrees and smaller than 8 degrees) according to the present invention.

The tire according to Example 3 has the rib pattern. In the tire according to Example 3, the sum of the cord angle θr of the reinforcement belt and the representative main groove angle θrmg is −5 degrees, which is a value around the lower limit value of the range (larger than −8 degrees and smaller than 8 degrees) according to the present invention.

The tire according to Example 4 has the rib pattern. In the tire according to Example 4, the sum of the cord angle θr of the reinforcement belt and the representative main groove angle θrmg is 5 degrees, which is a value around the upper limit value of the range (larger than −8 degrees and smaller than degrees) according to the present invention.

The tire according to Example 5 has the block pattern. In the tire according to Example 5, the sum of the cord angle θr of the reinforcement belt and the representative main groove angle θrmg is −15 degrees, which is a value around the lower limit value of the range (larger than −18 degrees and smaller than 8 degrees) according to the present invention.

The tire according to Example 6 has the block pattern. In the tire according to Example 6, the sum of the cord angle θr of the reinforcement belt and the representative main groove angle θrmg is 7 degrees, which is a value around the upper limit value of the range (larger than −18 degrees and smaller than 8 degrees) according to the present invention.

In this evaluation test, the belt durability and the vehicle drifting were evaluated.

In the evaluation of the belt durability, a tire having a tire size of 445/50R22.5 was mounted on a wheel having a rim size of 22.5×14.00 (predetermined rim) and the tire was filled with air having a pressure of 930 kPa (a value obtained by adding 100 kPa to 830 kPa which is an internal pressure determined by TRA). A maximum tire-section width Wt when no load is applied was 440 mm. Each tire mounted on the wheel was mounted on a drum tester and a traveling test was performed under conditions where a speed is set to 40 km/h and a load is set to 54.4 kN. As shown in Table 3, a traveling distance of the tire before breakage of the tire is expressed as an index.

In the evaluation of the vehicle drifting, a tire having a tire size of 445/50R22.5 was mounted on a wheel having a rim size of 22.5×14.00 (predetermined rim) and the tire was filled with air having a pressure of 700 kPa. Each tire mounted on the wheel was mounted on a drum tester and a traveling test was performed under conditions where a speed is set to 60 km/h and a load is set to 47.9 kN. As shown in Table 3, a ply steer component, which is obtained by subtracting a lateral force deviation in a reverse rotation from a lateral force deviation in a normal rotation (an average value of a fluctuation of a force in the tire-width direction or the lateral direction) and dividing the obtained value by two, is expressed as an index.

In both the belt durability and the vehicle drifting, assuming the performance of the tire according to Comparative Example 1 as 100, the performances of the tires according to the remaining Comparative Examples 2 to 6 and Examples 1 to 6 were indexed. As to the belt durability, the belt durability is favorable if the index is equal to or greater than 110. As to the vehicle drifting, the vehicle drifting is suppressed effectively if the index is equal to or greater than 90.

In all of Examples 1 to 6, the index of the belt durability is equal to or greater than 110, showing that favorable belt durability is obtained. Moreover, in all of Examples 1 to 6, the index of the vehicle drifting is equal to or greater than 95, showing that the vehicle drifting can be suppressed effectively.

In the tire according to Comparative Example 2, the belt durability is 110, and the cord angle θr of the reinforcement belt 13 and the representative main groove angle θrmg have the same direction. Therefore, the index of the vehicle drifting is lower than 90.

In the tires according to Comparative Examples 3 and 4 (the rib pattern) in which the sum of the cord angle θr of the reinforcement belt 13 and the representative main groove angle θrmg deviates from the range (larger than −8 degrees and smaller than 8 degrees) according to the present invention, although the index of the belt durability is equal to or greater than 110, the index of the vehicle drifting is lower than 90. Therefore, the vehicle drifting cannot be suppressed effectively.

In the tires according to Comparative Examples 5 and 6 (the block pattern) in which the sum of the cord angle θr of the reinforcement belt 13 and the representative main groove angle θrmg deviates from the range (larger than −18 degrees and smaller than 8 degrees) according to the present invention, although the index of the belt durability is 123, the index of the vehicle drifting is lower than 90. Therefore, the vehicle drifting cannot be suppressed effectively.

As described above, by comparing the tires according to Comparative Examples 1 to 6 and the tires according to Examples 1 to 6, it is understood that, according to the pneumatic tire of the present invention, both the belt durability and the suppression of the vehicle drifting can be enhanced.

The tire according to the present invention is favorably applicable to a pneumatic tire (so-called super single tire) having an aspect ratio of not larger than 70% and a nominal section width of not smaller than 365. The tire according to the present invention is also applicable to a pneumatic tire having a small aspect ratio and failing outer side a range of a pneumatic radial tire for heavy load.

Claims

1. A pneumatic tire comprising a belt layer arranged between a carcass and a tread portion, wherein the belt layer comprisesa first main working belt,a second main working belt arranged at an outer side of the first main working belt in a tire-radial direction, the second main working belt having a cord angle different from a cord angle of the first main working belt in a direction with respect to a tire-circumferential direction, anda reinforcement belt,an absolute value of a cord angle of the reinforcement belt is not smaller than 6 degrees and not larger than 9 degrees,a tread pattern including a main groove is formed on a tread surface of the tread portion, andthe cord angle of the reinforcement belt and a representative main groove angle have different directions with respect to the tire-circumferential direction, the representative main groove angle being defined as an angle formed by an element of the main groove with the longest length in the tire-circumferential direction and the tire-circumferential direction.

2. The pneumatic tire according to claim 1, wherein the tread pattern is a rib pattern, andthe following expression is satisfied: −8 <θr+θrmg<8where θr denotes the cord angle of the reinforcement belt (degrees) and θrmg denotes the representative main groove angle (degrees).

3. The pneumatic tire according to claim 1, wherein the tread pattern is a block pattern, andthe following expression is satisfied: −18<θr+θrmg<8where θr denotes the cord angle of the reinforcement belt (degrees) and θrmg denotes the representative main groove angle (degrees).

4. The pneumatic tire according to claim 1, wherein a width of the reinforcement belt is equal to or wider than 50% of a tire-section width and not wider than a width of a narrower one of the first and second main working belts.

5. The pneumatic tire according to claim 1, wherein the reinforcement belt is arranged between the first main working belt and the second main working belt.

6. The pneumatic tire according to claim 1, wherein absolute values of the cord angles of the first and second main working belts are respectively 20±10 degrees.

7. The pneumatic tire according to claim 4, wherein the absolute values of the cord angles of the first and second main working belts are respectively 17±5 degrees.

8. The pneumatic tire according to claim 1, wherein the belt layer further comprises a protection belt arranged at an outer side of the second main working belt in the tire-radial direction.

9. The pneumatic tire according to claim 6, wherein the belt layer further comprises a buffer belt arranged at an inner side of the first main working belt in the tire-radial direction.

10. The pneumatic tire according to claim 1, wherein the pneumatic tire has an aspect ratio of not larger than 70% and a nominal section width of not smaller than 365.