Patent Description:
For example, <CIT> discloses a motorcycle tire that includes central blocks, first lateral blocks, and second lateral blocks, and that is suitable for both running on rough terrain and running on paved road surfaces. In the motorcycle tire, a ratio between a length in the tire circumferential direction and a length in the tire axial direction for each of the central block, the first lateral block, and the second lateral block, a ratio between a sea area and a land area, and the like are specified. Such a motorcycle tire is considered to enhance traction performance without increasing a noise level.

A motorcycle tire in accordance with the preamble of claim <NUM> is known from <CIT>. Related tires are described in <CIT>, <CIT>, <CIT> and <CIT>.

In recent years, since quietness has been improved in a vehicle power unit, noise (tire noise) generated in the tire while the vehicle is running has also been required to be further reduced.

The present invention has been made in view of the aforementioned circumstances, and a main object of the present invention is to provide a motorcycle tire that allows tire noise to be further reduced.

The object is solved by a motorcycle tire having the features of claim <NUM>. Subclaims are directed to preferable embodiments of the invention.

The present invention is directed to a motorcycle tire including a tread portion. The tread portion has, on a tire equator, a crown block array in which a plurality of crown blocks are aligned in a tire circumferential direction. Distances in the tire circumferential direction over which the crown blocks adjacent to each other in the tire circumferential direction are distant from each other include a first distance and a second distance different from the first distance. A centroid of a tread surface of each of the plurality of crown blocks is positioned so as to be distant from the tire equator over a certain distance in a tire axial direction.

The motorcycle tire of the present invention has the above-described configuration, and, therefore, can further reduce tire noise.

According to an embodiment of the invention, the distance between the tire equator and the centroid of each crown block is <NUM> to <NUM>.

According to an embodiment of the invention, the tread portion includes a first tread end and a second tread end, and the crown blocks include a plurality of first crown blocks each having the centroid disposed on the first tread end side relative to the tire equator, and a plurality of second crown blocks each having the centroid disposed on the second tread end side relative to the tire equator.

According to an embodiment of the invention, the first crown blocks and the second crown blocks alternate in the tire circumferential direction.

According to an embodiment of the invention, the tread portion includes a pair of middle block arrays each of which is disposed outward of the crown blocks in the tire axial direction and has a plurality of middle blocks aligned in the tire circumferential direction, and includes a pair of shoulder block arrays each of which is disposed outward of the middle blocks in the tire axial direction and has a plurality of shoulder blocks aligned in the tire circumferential direction, and a centroid of a tread surface of each of the plurality of middle blocks and a centroid of a tread surface of each of the plurality of shoulder blocks are each distanced from the centroid of the tread surface of a corresponding one of the plurality of crown blocks by a distance in the tire circumferential direction.

According to an embodiment of the invention, the distance in the tire circumferential direction between the centroid of the tread surface of each of the plurality of middle blocks and the centroid of the tread surface of a corresponding one of the plurality of crown blocks is <NUM> to <NUM>.

According to an embodiment of the invention, the distance in the tire circumferential direction between the centroid of the tread surface of each of the plurality of shoulder blocks and the centroid of the tread surface of a corresponding one of the plurality of crown blocks is <NUM> to <NUM>.

According to an embodiment of the invention, the tread portion has a designated tire rotation direction, the plurality of crown blocks each include a crown toe-side edge disposed on a toe side in the tire rotation direction, and the crown toe-side edge is inclined relative to the tire axial direction.

According to an embodiment of the invention, an angle of the crown toe-side edge relative to the tire axial direction is <NUM> to <NUM>°.

According to an embodiment of the invention, the crown toe-side edge extends from a first outer end to a second outer end in the tire axial direction so as to be V-shaped, the crown toe-side edge includes a first edge portion that linearly extends from the first outer end toward the tire equator, and a second edge portion that linearly extends from the second outer end toward the tire equator, and the first edge portion and the second edge portion connect to each other at a position distant from the tire equator by a distance in the tire axial direction.

According to an embodiment of the invention, the tread portion includes a pair of middle block arrays each of which is disposed outward of the crown blocks in the tire axial direction and has a plurality of middle blocks aligned in the tire circumferential direction, and includes a pair of shoulder block arrays each of which is disposed outward of the middle blocks in the tire axial direction and has a plurality of shoulder blocks aligned in the tire circumferential direction, each of the plurality of middle blocks and each of the plurality of shoulder blocks include a middle toe-side edge and a shoulder toe-side edge, respectively, disposed on a toe side in the tire rotation direction, the first edge portion or the second edge portion, and the shoulder toe-side edge are positioned on a first imaginary straight line, and the middle toe-side edge is disposed closer to a heel side in tire rotation direction than the first imaginary straight line is.

According to an embodiment of the invention, the plurality of crown blocks each have a crown sipe extending in the tire axial direction, and a depth of the crown sipe is <NUM>% to <NUM>% of a block height of each crown block.

According to an embodiment of the invention, a length of the crown sipe in the tire axial direction is <NUM>% to <NUM>% of a maximum length of each crown block in the tire axial direction.

One embodiment of the present invention will be described below with reference to the drawings.

<FIG> is a development of a tread portion <NUM> of a motorcycle tire <NUM> (hereinafter, may be simply referred to as a "tire") according to one embodiment of the present invention. The tire <NUM> of the present embodiment of the invention is suitable for, for example, running on a course in which an on-road course and an off-road course are mixed. The tire <NUM> of the present embodiment of the invention is preferably used for, for example, both a front wheel and a rear wheel of a motorcycle.

In the present embodiment of the invention, the tread portion <NUM> has, on a tire equator C, a crown block array 3R in which a plurality of crown blocks <NUM> are aligned in the tire circumferential direction. Distances over which the crown blocks <NUM> and <NUM> adjacent to each other in the tire circumferential direction are distant from each other in the tire circumferential direction include a first distance La1 and a second distance La2 different from the first distance La1. Thus, a time interval of air compression/release generated between the crown blocks <NUM> and <NUM> when the tire rolls, varies, and concentration of noise in a specific frequency range is inhibited. Therefore, a tire noise level during running is reduced. In the present embodiment of the invention, the above-described distances include three kinds of distances that are the first distance La1, the second distance La2, and a third distance La3 different from each of the first and the second distances La1 and La2. Thus, the above-described effect is more effectively exhibited. In the present invention, the tire <NUM> may include four kinds of distances that are the first distance La1, the second distance La2, the third distance La3, and a fourth distance (not shown) different from each of the first, the second, and the third distances La1, La2, and La3.

A centroid 3c of a tread surface 3a of each of the plurality of crown blocks <NUM> is positioned so as to be distant from the tire equator C over a distance Lb in the tire axial direction. Thus, noise generated when air is compressed/released between the crown blocks <NUM> and <NUM> is different between both sides of the tire equator C in the crown block <NUM>. By combining this difference with variation of the time interval, concentration of noise in a specific frequency range is further inhibited. As described above, the tire <NUM> of the present embodiment of the invention allows tire noise to be further reduced.

If the distance Lb is excessively great, running balance during straight running is degraded, and rough terrain running-through performance may be degraded. Therefore, the distance Lb is preferably not less than <NUM> and more preferably not less than <NUM>, and preferably not greater than <NUM> and more preferably not greater than <NUM>.

The tread portion <NUM> has, for example, a directional pattern in which the tire rotation direction R is designated. However, the tire <NUM> of the present invention is not limited to a tire having a designated tire rotation direction.

In the present embodiment of the invention, the tread portion <NUM> includes a pair of middle block arrays 4R and a pair of shoulder block arrays 5R. The pair of middle block arrays 4R are disposed on both outer sides of the crown block <NUM> in the tire axial direction. Each middle block array 4R has a plurality of middle blocks <NUM> aligned in the tire circumferential direction. The pair of shoulder block arrays 5R are disposed outward of the middle blocks <NUM> in the tire axial direction. Each shoulder block array 5R has a plurality of shoulder blocks <NUM> aligned in the tire circumferential direction.

The tread portion <NUM> includes a first tread end T1 (left side in the drawings) and a second tread end T2. The crown blocks <NUM> include a plurality of first crown blocks 3A each having the centroid 3c disposed on the first tread end T1 side relative to the tire equator C, and a plurality of second crown blocks 3B each having the centroid 3c disposed on the second tread end T2 side relative to the tire equator C.

The first crown blocks 3A and the second crown blocks 3B alternate in the tire circumferential direction. Thus, noise generated when air is compressed/released between the crown blocks <NUM> and <NUM> repeatedly flows alternately toward the first tread end T1 and the second tread end T2, and is reduced, so that concentration of noise in a specific frequency range is further inhibited.

The first tread end T1 and the second tread end T2 correspond to both ends in the tire axial direction in the normal state of the tire <NUM>. The "normal state" represents a state in which the tire <NUM> is mounted on a normal rim (not shown) and is inflated to a normal internal pressure, and no load is applied. In the description herein, unless otherwise specified, dimensions of components of the tire <NUM> are represented as values measured in the normal state.

The "normal rim" represents a rim that is defined in a standard system including a standard on which the tire is based, by the standard, for each tire, and is, for example, the "standard rim" in the JATMA standard, the "Design Rim" in the TRA standard, or the "Measuring Rim" in the ETRTO standard.

The "normal internal pressure" represents an air pressure that is defined in a standard system including a standard on which the tire is based, by the standard, for each tire, and is the "maximum air pressure" in the JATMA standard, the maximum value recited in the table "TIRE LOAD LIMITS AT VARIOUS COLD INFLATION PRESSURES" in the TRA standard, or the "INFLATION PRESSURE" in the ETRTO standard.

<FIG> is an enlarged view of <FIG>. As shown in <FIG>, the plurality of the crown blocks <NUM> each include, for example, a crown toe-side edge 10A disposed on a toe side in the tire rotation direction R. In the present embodiment of the invention, each of the crown blocks <NUM> includes a crown heel-side edge 11A disposed on a heel side in the tire rotation direction R, and a pair of crown lateral edges 12A connecting between both ends of the crown toe-side edge 10A and both ends of the crown heel-side edge 11A.

The crown toe-side edge 10A is, for example, inclined relative to the tire axial direction. Thus, the entirety of the crown toe-side edge 10A is inhibited from simultaneously coming into contact with a road surface when the crown block <NUM> comes into contact with the ground, so that impact sound becomes low to further reduce tire noise.

If an angle θ1 of the crown toe-side edge 10A relative to the tire axial direction is excessively great, traction by the crown toe-side edge 10A may be reduced. Therefore, the angle θ1 of the crown toe-side edge 10A is preferably not less than <NUM>° and more preferably not less than <NUM>°, and preferably not greater than <NUM>° and more preferably not greater than <NUM>°.

The crown toe-side edge 10A extends from a first outer end 15a (left side in the drawings) to a second outer end 15b (right side in the drawings) in the tire axial direction so as to be V-shaped. The crown toe-side edge 10A includes a first edge portion 16a that linearly extends from the first outer end 15a toward the tire equator C, and a second edge portion 16b that linearly extends from the second outer end 15b toward the tire equator C. The term "linearly" implies a straight line, and a curved line formed of a single arc in which a curvature radius is not less than <NUM>.

The first edge portion 16a and the second edge portion 16b connect to each other at a position (first connection position) X1 distant from the tire equator C over a distance Lc in the tire axial direction. Thus, concentration of noise in a specific frequency range can be further inhibited. In order to exhibit such an effect, the distance Lc in the tire axial direction between the first connection position X1 and the tire equator C is preferably not less than <NUM>% of a maximum width Wc of the crown block <NUM> in the tire axial direction and more preferably not less than <NUM>% thereof, and preferably not greater than <NUM>% thereof and more preferably not greater than <NUM>% thereof.

The crown heel-side edge 11A extends from a third outer end 15c (left side in the drawings) to a fourth outer end 15d in the tire axial direction so as to be V-shaped. The crown heel-side edge 11A includes a third edge portion 16c that linearly extends from the third outer end 15c toward the tire equator C, and a fourth edge portion 16d that linearly extends from the fourth outer end 15d toward the tire equator C. In the present embodiment of the invention, the third edge portion 16c and the fourth edge portion 16d are inclined relative to the tire axial direction.

For example, the third edge portion 16c and the fourth edge portion 16d connect to each other at a position (second connection position) X2 distant from the tire equator C over a distance Ld in the tire axial direction. The second connection position X2 is positioned on the same side as the first connection position X1 relative to the tire equator C in the tire axial direction. The distance Ld is preferably equal to the distance Lc.

In the present embodiment of the invention, each crown lateral edge 12A linearly extends. For example, each crown lateral edge 12A extends outward in the tire axial direction toward the heel side in the tire rotation direction R.

The plurality of the crown blocks <NUM> each have a crown sipe <NUM> extending in the tire axial direction. The crown sipe <NUM> contributes to proper reduction of stiffness of the crown block <NUM>, and reduction of impact sound during contact with a road surface. In the description herein, sipes including a middle sipe <NUM> and a shoulder sipe <NUM> described below each represent a cut recess having a width of not greater than <NUM>, and are clearly distinguished from a groove in which a width for demarcating each block is not less than <NUM>.

The crown sipe <NUM> is formed as a semi-open sipe that extends from the crown lateral edge 12A and terminates in the tread surface 3a of the crown block <NUM> without reaching the tire equator C. Therefore, reduction of stiffness of the crown block <NUM> is inhibited, and running performance (rough terrain running-through performance) is thus stabilized in rough terrain. In the present embodiment of the invention, the crown sipe <NUM> linearly extends. The crown sipe <NUM> may extend, for example, in a wavy or zigzag manner.

An angle θ2 of the crown sipe <NUM> relative to the tire axial direction is preferably equal to the angle θ1 of the crown toe-side edge 10A. Thus, an edge effect is enhanced, and rough terrain running-through performance becomes excellent. The term "equal" means that an absolute value |θ2-θ1| of a difference between the angle θ2 of the crown sipe <NUM> and the angle θ1 of the crown toe-side edge 10A is <NUM>°, and also means the absolute value is not greater than <NUM>°.

In order to effectively exhibit the above-described effect, a length L1 of the crown sipe <NUM> in the tire axial direction is preferably not less than <NUM>% of the maximum width Wc of the crown block <NUM> in the tire axial direction and more preferably not less than <NUM>% thereof, and preferably not greater than <NUM>% thereof and more preferably not greater than <NUM>% thereof.

<FIG> is a cross-sectional view taken along a line A-A in <FIG>. As shown in <FIG>, a depth d of the crown sipe <NUM> is preferably not less than <NUM>% of a block height H1 of the crown block <NUM> and more preferably not less than <NUM>% thereof, and preferably not greater than <NUM>% thereof and more preferably not greater than <NUM>% thereof.

<FIG> is an enlarged view of <FIG>. <FIG> shows the crown blocks <NUM>, and the middle blocks <NUM> and the shoulder blocks <NUM> on the first tread end T1 side. As shown in <FIG>, a centroid 4c of a tread surface 4a of each of the plurality of middle blocks <NUM> and a centroid 5c of a tread surface 5a of each of the plurality of shoulder blocks <NUM> are each distanced from the centroid 3c of a corresponding one of the plurality of the crown blocks <NUM> over a certain distance in the tire circumferential direction. Thus, a portion at which impact sound between the crown block <NUM> and a road surface is high, and a portion at which impact sound between the middle block <NUM> and the shoulder block <NUM>, and the road surface is high, are shifted in the tire circumferential direction, thereby further reducing tire noise.

A distance Le in the tire circumferential direction between the centroid 4c of the middle block <NUM> and the centroid 3c of the crown block <NUM> is, but is not particularly limited to, preferably not less than <NUM> and more preferably not less than <NUM>, and preferably not greater than <NUM> and more preferably not greater than <NUM>. From the same viewpoint, a distance Lf in the tire circumferential direction between the centroid 5c of the shoulder block <NUM> and the centroid 3c of the crown block <NUM> is preferably not less than <NUM> and more preferably not less than <NUM>, and preferably not greater than <NUM> and more preferably not greater than <NUM>.

In the present embodiment of the invention, the centroid 5c of the shoulder block <NUM> is distanced from the centroid 4c of the middle block <NUM> over a certain distance in the tire circumferential direction. For example, the centroid 5c of the shoulder block <NUM> is disposed closer to the heel side in the tire rotation direction R than the centroid 4c of the middle block <NUM> is. A distance Lg in the tire circumferential direction between the centroid 4c of the middle block <NUM> and the centroid 5c of the shoulder block <NUM> is, but is not particularly limited to, preferably not less than <NUM> and more preferably not less than <NUM>, and preferably not greater than <NUM> and more preferably not greater than <NUM>.

In the present embodiment of the invention, each of the plurality of the middle blocks <NUM> and each of the plurality of the shoulder blocks <NUM> include a middle toe-side edge 10B and a shoulder toe-side edge 10C, respectively, disposed on the toe side in the tire rotation direction R. Each of the middle blocks <NUM> includes, for example, a middle heel-side edge 11B disposed on the heel side in the tire rotation direction R, and a pair of middle lateral edges 12B connecting between both ends of the middle toe-side edge 10B and both ends of the middle heel-side edge 11B. Furthermore, each of the shoulder blocks <NUM> includes, for example, a shoulder heel-side edge 11C disposed on the heel side in the tire rotation direction R, and a shoulder lateral edge 12C connecting between an inner end of the shoulder toe-side edge 10C and an inner end of the shoulder heel-side edge 11C.

The shoulder toe-side edge 10C, and the first edge portion 16a or the second edge portion 16b are positioned on a first imaginary straight line m1. <FIG> shows the shoulder toe-side edge 10C and the first edge portion 16a that are positioned on the first imaginary straight line m1. <FIG> shows the shoulder toe-side edge 10C and the second edge portion 16b that are positioned on the first imaginary straight line m1. The first imaginary straight line m1 is a straight line that passes through the first connection position X1 and the first outer end 15a or passes through the first connection position X1 and the second outer end 15b. The phrase "positioned on the first imaginary straight line m1" means that the first imaginary straight line m1 and the shoulder toe-side edge 10C overlap each other. Furthermore, the phrase "positioned on the first imaginary straight line m1" also implies a state where a maximum distance Lm over which the first imaginary straight line m1 and the shoulder toe-side edge 10C are distant from each other in the tire circumferential direction is not greater than <NUM>. In the present embodiment of the invention, the shoulder toe-side edge 10C overlaps the first imaginary straight line m1.

In the present embodiment of the invention, the middle toe-side edge 10B is disposed closer to the heel side in the tire rotation direction R than the first imaginary straight line m1 is. Thus, air resonance sound between the middle blocks <NUM> is reduced at the middle toe-side edge 10B, thereby reducing tire noise. The middle toe-side edge 10B is, for example, disposed so as not to come into contact with or intersect the first imaginary straight line m1. Thus, the above-described effect is more effectively exhibited. A minimum distance Ln over which the middle toe-side edge 10B and the first imaginary straight line m1 are distant from each other in the tire circumferential direction is, but is not particularly limited to, preferably not less than <NUM> and more preferably not less than <NUM>, and preferably not greater than <NUM> and more preferably not greater than <NUM>.

The shoulder heel-side edge 11C, and the third edge portion 16c or the fourth edge portion 16d are positioned on a second imaginary straight line m2. <FIG> shows the shoulder heel-side edge 11C and the third edge portion 16c that are positioned on the second imaginary straight line m2. <FIG> shows the shoulder heel-side edge 11C and the fourth edge portion 16d that are positioned on the second imaginary straight line m2. The second imaginary straight line m2 is a straight line that passes through the second connection position X2 and the third outer end 15c or passes through the second connection position X2 and the fourth outer end 15d. The "positioned on the second imaginary straight line m2" is defined similarly to the "positioned on the first imaginary straight line m1".

In the present embodiment of the invention, the middle heel-side edge 11B is disposed closer to the heel side in the tire rotation direction R than the second imaginary straight line m2 is. Thus, air resonance sound between the middle blocks <NUM> is reduced at the middle heel-side edge 11B, thereby further reducing tire noise.

In the present embodiment of the invention, the middle toe-side edge 10B, the shoulder toe-side edge 10C, the middle heel-side edge 11B, and the shoulder heel-side edge 11C linearly extend outwardly in the tire axial direction toward the heel side in the tire rotation direction R. For example, the middle lateral edge 12B and the shoulder lateral edge 12C linearly extend outwardly in the tire axial direction toward the heel side in the tire rotation direction R.

<FIG> is an enlarged view of <FIG>. As shown in <FIG>, the plurality of the middle blocks <NUM> each have a middle sipe <NUM> extending in the tire axial direction.

The middle sipe <NUM> is formed as a semi-open sipe that extends from the middle lateral edge 12B to the inner side of the middle block <NUM>, and terminates in the middle block <NUM> without extending across the middle block <NUM>. In the present embodiment of the invention, the middle sipe <NUM> linearly extends. The middle sipe <NUM> may extend, for example, in a wavy or zigzag manner. The middle sipe <NUM> is disposed in each of the pair of middle lateral edges 12B.

An angle θ3 of the middle sipe <NUM> relative to the tire axial direction is preferably equal to an angle θ4 of the middle toe-side edge 10B relative to the tire axial direction. Thus, rough terrain running-through performance can be further enhanced. The term "equal" means that an absolute value |θ3-θ4| of a difference between the angle θ3 of the middle sipe <NUM> and the angle θ4 of the middle toe-side edge 10B is not greater than <NUM>°.

A distance Lh in the tire axial direction between the middle sipes <NUM> distanced from each other in the tire axial direction is, for example, preferably not less than <NUM>% of a maximum width Wm of the middle block <NUM> in the tire axial direction and more preferably not less than <NUM>% thereof, and preferably not greater than <NUM>% thereof and more preferably not greater than <NUM>% thereof.

In the present embodiment of the invention, the plurality of the shoulder blocks <NUM> each have a shoulder sipe <NUM> extending in the tire axial direction.

The shoulder sipe <NUM> is formed as a semi-open sipe that extends from the shoulder lateral edge 12C, the first tread end T1, or the second tread end T2 to the inner side of the shoulder block <NUM>, and terminates in the shoulder block <NUM>. In the present embodiment of the invention, the shoulder sipe <NUM> linearly extends. The shoulder sipe <NUM> may extend, for example, in a wavy or zigzag manner.

An angle θ5 of the shoulder sipe <NUM> relative to the tire axial direction is preferably equal to an angle θ6 of the shoulder toe-side edge 10C relative to the tire axial direction. Thus, rough terrain running-through performance is enhanced. The term "equal" means that an absolute value |θ5-θ6| of a difference between the angle θ5 of the shoulder sipe <NUM> and the angle θ6 of the shoulder toe-side edge 10C is not greater than <NUM>°.

A distance Li in the tire axial direction between the shoulder sipes <NUM> distanced from each other in the tire axial direction is, for example, preferably not less than <NUM>% of a maximum width Ws of the shoulder block <NUM> and more preferably not less than <NUM>% thereof, and preferably not greater than <NUM>% thereof and more preferably not greater than <NUM>% thereof.

Although the particularly preferred embodiment of the present invention has been described above in detail, the present invention is not limited to the above-described embodiment, and various modifications can be made to implement the invention within the scope of the appended claims.

A motorcycle rear wheel tire and a motorcycle front wheel tire each having the tread pattern shown in <FIG> were produced as test tires according to the specifications in Table <NUM>. Each test tire was tested for noise performance and rough terrain running-through performance. Specifications common to the test tires were as follows.

The test was performed in accordance with an actual vehicle coasting test specified in ASO/C/<NUM>. Pass-by noise (maximum level dB(a)) was measured by a stationary microphone when the test vehicle was coasted under the following conditions. The results are each indicated as an index with the index of comparative example <NUM> being <NUM>. The less the value is, the less tire noise is and the better the noise performance is.

A test rider drove the test vehicle on rough terrain. At this time, the test rider made a sensory evaluation for stability. The results are each indicated as a score with the score of comparative example <NUM> being <NUM>. The greater the value is, the more excellent rough terrain running-through performance is.

In Table <NUM>, "A" indicates that the centroid of the crown block was distant from the tire equator, and.

"B" indicates that the centroid of the crown block was on the tire equator.

In Table <NUM>, "C" indicates that the centroid of the middle block and the centroid of the shoulder block, and the centroid of the crown block were shifted from each other in the tire circumferential direction, and "D" indicates that the centroid of the middle block and the centroid of the shoulder block, and the centroid of the crown block were not shifted from each other in the tire circumferential direction.

Claim 1:
A motorcycle tire (<NUM>) comprising
a tread portion (<NUM>), wherein
the tread portion (<NUM>) has, on a tire equator (C), a crown block array (3R) in which a plurality of crown blocks (<NUM>) are aligned in a tire circumferential direction,
distances in the tire circumferential direction over which the crown blocks (<NUM>) adjacent to each other in the tire circumferential direction are distant from each other include a first distance (La1), and
a centroid (3c) of a tread surface (3a) of each of the plurality of crown blocks (<NUM>) is positioned so as to be distant from the tire equator (C) by a distance (Lb) in a tire axial direction,
characterized in that
distances in the tire circumferential direction over which the crown blocks (<NUM>) adjacent to each other in the tire circumferential direction are distant from each other include a second distance (La2) different from the first distance (La1).