阅读说明：本技术 不平整地面行驶用的轮胎 (Tire for running on rough terrain ) 是由 疋田真浩 于 2019-07-19 设计创作，主要内容包括：本发明提高松软路、硬质路上的操纵稳定性能,并且抑制花纹块的缺失。本发明为不平整地面行驶用的轮胎(1)。在胎面部(2)的胎冠区域(Cr)、中间区域(Mi)以及胎肩区域(Sh),分别配置有多个胎冠花纹块(11)、多个中间花纹块(12)以及多个胎肩花纹块(13)。各中间花纹块(12)通过胎冠拉筋(14)而与任一个胎冠花纹块(11)连结,并且通过胎肩拉筋(15)而与任一个胎肩花纹块(13)连结。胎肩区域(Sh)的陆地比Ls为胎冠区域(Cr)的陆地比Lc的90％～115％。(The invention improves the operation stability on soft roads and hard roads and inhibits the deletion of pattern blocks. The invention relates to a tire (1) for running on rough terrain. A plurality of crown blocks (11), a plurality of intermediate blocks (12), and a plurality of shoulder blocks (13) are arranged in a crown region (Cr), an intermediate region (Mi), and a shoulder region (Sh) of a tread portion (2), respectively. Each of the intermediate blocks (12) is connected to any one of the crown blocks (11) by a crown tie (14) and to any one of the shoulder blocks (13) by a shoulder tie (15). The land ratio Ls of the tire shoulder area (Sh) is 90-115% of the land ratio Lc of the tire crown area (Cr).)

1. A tire for running on uneven ground, having a tread portion, wherein,

the tread portion includes: a crown region having a center at the tire equator and having a developed width of 1/3 of the developed width of the tread; a middle region, located on both outer sides of the crown region, and having a developed width of 1/6 of the tread developed width; and shoulder regions located on both outer sides of the intermediate region and having a developed width of 1/6 which is the developed width of the tread,

a plurality of crown blocks, a plurality of intermediate blocks, and a plurality of shoulder blocks are arranged in the crown region, the intermediate region, and the shoulder region, respectively,

each of the intermediate blocks is connected to any one of the crown blocks by a crown tie and to any one of the shoulder blocks by a shoulder tie,

the land ratio of the tire shoulder area is 90-115% of the land ratio of the tire crown area.

2. The run flat tire according to claim 1,

the shoulder lacing includes a 1 st shoulder lacing extending from one of the plurality of shoulder lugs to two different ones of the plurality of intermediate lugs, respectively.

3. The tire for running on uneven ground according to claim 1 or 2, wherein,

the shoulder lacing includes a 2 nd shoulder lacing extending from one of the plurality of middle lugs to two different ones of the plurality of shoulder lugs, respectively.

4. The run flat tire according to claim 2,

the shoulder tendon includes a 2 nd shoulder tendon extending from one of the plurality of middle lugs respectively to two different ones of the plurality of shoulder lugs,

the 1 st shoulder rib and the 2 nd shoulder rib are alternately arranged along the tire circumferential direction.

5. The tire for running on uneven ground according to any one of claims 1 to 4,

the height of the tire shoulder lacing wire and the height of the tire crown lacing wire are 10% -40% of the maximum pattern block height in the tire crown pattern block, the middle pattern block and the tire shoulder pattern block.

6. The tire for running on uneven ground according to any one of claims 1 to 5,

the width of the tire shoulder tie bar, which is orthogonal to the length direction, includes a portion of the tire shoulder pattern block, the portion being 50% or more of the axial length of the tire.

7. The tire for running on uneven ground according to any one of claims 1 to 6,

at least one of the middle pattern block and the shoulder pattern block comprises a step-shaped tread, and the step-shaped tread comprises a 1 st top surface and a 2 nd top surface, wherein the height of the pattern block is smaller than that of the 1 st top surface.

8. The run flat tire according to claim 7,

a groove is arranged between the 1 st top surface and the 2 nd top surface,

the groove includes a pair of axial portions extending in the tire axial direction.

9. The run flat tire according to claim 8,

the pair of axial portions respectively include: the tire has a 1 st inclined portion inclined to one side with respect to the tire axial direction, and a 2 nd inclined portion inclined in a direction opposite to the 1 st inclined portion.

Technical Field

The present invention relates to a tire for running on rough terrain.

Background

Patent document 1 listed below describes a pneumatic tire for running on rough terrain, in which a plurality of blocks are provided in a tread portion. In such a pneumatic tire, a plurality of blocks bite into a loose road such as a sandy ground or a muddy ground, and traction and cornering forces are obtained by the edges of the blocks, thereby improving steering stability.

Patent document 1: japanese patent No. 5615924

In recent years, improvement in steering stability performance has been desired for the pneumatic tire as described above not only on a soft road but also on a hard road such as an asphalt road. In addition, in such a pneumatic tire, it is desirable to suppress the missing of the blocks.

Disclosure of Invention

The present invention has been made in view of the above circumstances, and a main object thereof is to provide a tire for running on rough terrain which improves steering stability on soft roads and hard roads and suppresses the loss of blocks.

The present invention relates to a tire for running on rough terrain, comprising a tread portion, the tread portion comprising: a crown region having a center at the tire equator and having a developed width of 1/3 of the developed width of the tread; a middle region located on both outer sides of said crown region and having a developed width of 1/6 of said tread developed width; and a shoulder region located on both outer sides of the intermediate region and having a developed width of 1/6 of the tread developed width, wherein a plurality of crown blocks, a plurality of intermediate blocks, and a plurality of shoulder blocks are arranged in the crown region, the intermediate region, and the shoulder region, respectively, each of the intermediate blocks is connected to any one of the crown blocks by a crown tie and connected to any one of the shoulder blocks by a shoulder tie, and a land ratio in the shoulder region is 90% to 115% of a land ratio in the crown region.

In the tire for rough terrain traveling according to the present invention, the shoulder rib preferably includes a 1 st shoulder rib extending from one of the plurality of shoulder blocks to two different ones of the plurality of intermediate blocks, respectively.

In the tire for rough terrain traveling according to the present invention, the shoulder rib preferably includes a 2 nd shoulder rib extending from one of the plurality of intermediate blocks to two different ones of the plurality of shoulder blocks, respectively.

In the tire for rough terrain traveling according to the present invention, it is preferable that the shoulder rib includes a 2 nd shoulder rib extending from one of the plurality of intermediate blocks to two different ones of the plurality of shoulder blocks, and the 1 st shoulder rib and the 2 nd shoulder rib are alternately arranged in the tire circumferential direction.

In the tire for running on rough terrain according to the present invention, the height of the shoulder rib and the height of the crown rib are preferably 10% to 40% of the maximum block height among the crown block, the middle block, and the shoulder block.

In the tire for rough terrain traveling according to the present invention, it is preferable that the width of the shoulder rib orthogonal to the longitudinal direction includes a portion of 50% or more of the axial length of the shoulder block.

In the tire for running on rough terrain according to the present invention, it is preferable that at least one of the intermediate block and the shoulder block includes a step-like tread surface including a 1 st top surface and a 2 nd top surface having a block height smaller than the 1 st top surface.

In the tire for rough terrain traveling according to the present invention, it is preferable that a groove including a pair of axial portions extending in the tire axial direction is provided between the 1 st summit and the 2 nd summit.

In the tire for running on rough terrain according to the present invention, preferably, the pair of axial portions includes: a 1 st inclined portion inclined toward one side with respect to the tire axial direction; and a 2 nd inclined part inclined in a direction opposite to the 1 st inclined part.

In the tire for running on rough terrain according to the present invention, the intermediate block is connected to any one of the crown blocks by the crown tie and is connected to any one of the shoulder blocks by the shoulder tie. This improves the rigidity of each block, and suppresses deformation of each block during traveling, thereby suppressing missing of the block. In addition, since such a tire for running on rough terrain has an increased shearing force on soft roads, it exhibits excellent steering stability performance on soft roads. Further, each block having increased rigidity can increase the ground contact pressure with the hard road, thereby improving the steering stability performance on the hard road.

The land ratio of the tire shoulder area is 90-115% of that of the tire crown area. In such a tire for running on rough terrain, the difference in rigidity between the crown block on which a large ground contact pressure acts and the shoulder block on which a large lateral force acts is reduced. Therefore, during straight running and during cornering, stable running can be performed, and therefore, steering stability performance on soft roads and hard roads is improved.

Therefore, the tire for running on rough terrain of the present invention can suppress the missing of the blocks while exhibiting excellent steering stability performance on soft roads and hard roads.

Drawings

Fig. 1 is a cross-sectional view showing an embodiment of a tire for running on rough terrain according to the present invention.

Fig. 2 is a developed view showing a tread pattern of the tread portion of fig. 1.

Fig. 3 is an enlarged view of the middle region and shoulder regions of fig. 2.

FIG. 4 (a) is a perspective view of the middle block, and (B) is a sectional view taken along line B-B of (a).

Fig. 5 is an enlarged view of the crown area of fig. 2.

Description of reference numerals

1 … tire; 2 … tread portion; 11 … crown blocks; 12 … middle blocks; 13 … shoulder blocks; 14 … crown lacing; 15 … tire shoulder tie bars; cr … crown area; mi … middle region; sh … shoulder regions; land ratio of the crown area of Lc …; ls … shoulder area land ratio.

Detailed Description

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

Fig. 1 is a cross-sectional view showing a normal state of a tire for rough terrain traveling (hereinafter, may be simply referred to as "tire") 1 according to an embodiment of the present invention. In the present embodiment, a tire for a motorcycle is shown as a preferable tire 1. The present invention is not limited to motorcycles, and is also applicable to tires 1 for cars, heavy loads, and other types, for example. Fig. 2 is a developed view showing a tread pattern of the tread portion 2 of the tire 1. Fig. 1 is a sectional view taken along line a-a of fig. 2.

The "normal state" is a state of no load in which the tire 1 is assembled to a normal rim (not shown) and is filled with normal internal pressure. In the present specification, the dimensions of each portion of the tire 1 are values measured in a normal state, unless otherwise specified.

The "regular Rim" is a Rim for each tire specified in a specification system including the specification under which the tire is based, and is, for example, "standard Rim" in case of JATMA, "Design Rim" in case of TRA, or "Measuring Rim" in case of ETRTO.

The "normal internal pressure" is an air pressure determined for each TIRE in a specification system including a specification according to the TIRE, and is "maximum air pressure" in case of JATMA, a maximum value described in a table "TIRE LOAD conditions associated with TIREs INFLATION pressure" in case of TRA, and "INFLATION pressure" in case of ETRTO.

As shown in fig. 1, in the tread portion 2 of the tire 1 of the present embodiment, in the cross section, the outer surface is curved in a convex arc shape toward the outer side in the tire radial direction.

The tire 1 of the present embodiment is provided with a carcass 6, a belt layer 7, and the like. They suitably adopt a known structure.

As shown in fig. 2, the tread portion 2 is divided to include a crown region Cr, a middle region Mi, and a shoulder region Sh. The crown region Cr has a center at the tire equator C and has a developed width of 1/3 of the tread developed width TWe. The intermediate region Mi is located on both outer sides of the crown region Cr and has a development width of 1/6 of the tread development width TWe. The shoulder regions Sh are located on both outer sides of the intermediate region Mi, and have a developed width of 1/6 of the tread developed width TWe.

The tread spread width TWe is a distance in the tire axial direction between the tread ends Te, Te when the tread portion 2 is spread in a flat surface. The tread end Te is a ground contact position on the outermost side of the tread portion 2 in the tire axial direction.

In the crown region Cr, the intermediate region Mi, and the shoulder region Sh, a plurality of crown blocks 11, intermediate blocks 12, and shoulder blocks 13 are arranged, respectively. For the crown block 11, the centroid of the tread lies within the crown region Cr. For the middle block 12, the centroid of the tread lies within the middle zone Mi. For the shoulder blocks 13, the centroid of the tread is located within the shoulder region Sh. In the case where a recessed portion such as a groove is provided on the tread surface of each block, the centroid of a virtual tread surface obtained by filling the recessed portion is used.

As shown in FIG. 1, each of the blocks 11 to 13 is divided by a tread groove 10. In the tread groove 10, the groove bottom 10b is formed by a smooth surface along the carcass 6 in the present embodiment.

Although not particularly limited, the block heights H1 to H3 of the crown block 11, the middle block 12, and the shoulder block 13 are preferably 6 to 20mm, respectively. The block heights H1 to H3 are heights in the tire radial direction from the groove bottom 10b of the tread groove 10 to the tread closest to the outer side in the tire radial direction.

As shown in fig. 2, in the present embodiment, each of the intermediate blocks 12 is coupled to any one of the crown blocks 11 by a crown tie 14. In the present embodiment, each of the intermediate blocks 12 is connected to any one of the shoulder blocks 13 by the shoulder rib 15. This improves the rigidity of the crown block 11, the middle block 12, and the shoulder block 13, and suppresses deformation of each of the blocks 11 to 13 during running, thereby suppressing missing of the blocks. In addition, since the tire 1 increases the shearing force with respect to a soft road, it exhibits excellent steering stability performance on a soft road. Further, the respective blocks 11 to 13 having increased rigidity can increase the ground contact pressure with the hard road, and therefore, the steering stability on the hard road can be improved.

In the present embodiment, the crown bead 14 and the shoulder bead 15 are formed as a raised portion in which a part of the groove bottom 10b of the tread groove 10 is raised.

The land ratio Ls of the shoulder region Sh is 90-115% of the land ratio Lc of the crown region Cr. In such a tire 1, the difference in rigidity between the crown block 11 on which a large ground contact pressure acts and the shoulder block 13 on which a large lateral force acts is reduced. Therefore, during straight running and during cornering, stable running can be performed, and therefore, steering stability performance on soft roads and hard roads is improved.

In order to effectively exhibit the above-described effects, the land ratio Lm of the middle region Mi is preferably set to 95% to 105% of the land ratio Lc of the crown region Cr. Accordingly, since the difference in rigidity from the crown blocks 11 to the shoulder blocks 13 is small, the behavior change of the downward projection during the period from the straight running to the cornering running in which the camber angle becomes large is suppressed, thereby further improving the steering stability performance. In the present specification, each land ratio is Sb/Sa of a total area Sb of tread surfaces of the blocks 11 to 13 of each region Cr, Mi, Sh to an area Sa of a virtual ground contact surface of each region Cr, Mi, Sh obtained by filling the tread groove 10.

The shoulder anchor 15 of the present embodiment includes a 1 st shoulder anchor 16 and a 2 nd shoulder anchor 17. The 1 st shoulder rib 16 of the present embodiment extends from one of the shoulder blocks 13 to two different ones of the intermediate blocks 12, respectively. The 2 nd shoulder rib 17 of the present embodiment extends from one of the intermediate blocks 12 to two different ones of the shoulder blocks 13, respectively.

In the present embodiment, the 1 st shoulder rib 16 is connected to the shoulder block 13 and the intermediate blocks 12, 12 adjacent to the shoulder block 13 on both sides in the tire circumferential direction. In the present embodiment, the 2 nd shoulder rib 17 is connected to the intermediate block 12 and the shoulder blocks 13 and 13 adjacent to each other on both sides of the intermediate block 12 in the tire circumferential direction. Thus, the 1 st shoulder bead 16 is formed in a substantially V shape projecting outward in the tire axial direction. Further, the 2 nd shoulder bead 17 is formed in a substantially V shape protruding inward in the tire axial direction. Such a 1 st shoulder rib 16 and a 2 nd shoulder rib 17 restrain the movement of the intermediate block 12 and the shoulder block 13 in the tire axial direction and the tire circumferential direction, thereby improving the effect of suppressing the block from being missing.

The 1 st shoulder bead 16 and the 2 nd shoulder bead 17 are alternately arranged in the tire circumferential direction. That is, in the present embodiment, the 1 st block group 18 connected to the 1 st shoulder rib 16 and the 2 nd block group 19 connected to the 2 nd shoulder rib 17 are alternately arranged in the tire circumferential direction. The 1 st block group 18 is formed of one shoulder block 13 and two intermediate blocks 12, 12 connected to the 1 st shoulder rib 16. The 2 nd block group 19 is formed of one intermediate block 12 and two shoulder blocks 13, 13 connected to the 2 nd shoulder rib 17. This can reduce the difference in rigidity between the shoulder region Sh and the intermediate region Mi, thereby improving stability during cornering on soft roads and hard roads.

The 1 st shoulder rib 16 is formed of a 1 st portion 16A connected to one of the intermediate blocks 12 and a 2 nd portion 16B connected to the other intermediate block 12. The 1 st portion 16A and the 2 nd portion 16B are separately connected without crossing at the shoulder blocks 13. The 2 nd shoulder rib 17 is also formed of a 1 st portion 17A connected to one of the shoulder blocks 13 and a 2 nd portion 17B connected to the other shoulder block 13, and they are also connected separately in the intermediate block 12 without crossing. Thus, the load from each of the 1 st portions 16A, 17A and the 2 nd portions 16B, 17B is dispersedly applied to the middle block 12 or the shoulder block 13, and hence the block loss is suppressed.

The angle θ 1 of the shoulder rib 15 with respect to the tire axial direction is preferably 30 to 60 degrees. This suppresses deformation of the middle blocks 12 and the shoulder blocks 13, which mainly contact the ground during cornering, due to running, thereby improving the grip during cornering on a hard road. The angle θ 1 of the shoulder rib 15 is more preferably 40 to 50 degrees. The angle θ 1 is determined by the width center line of the shoulder rib 15 between one intermediate block 12 and one shoulder block 13 in the plan view of the tread portion 2.

The crown lacing 14 of this embodiment extends from one of the crown blocks 11 to two different ones of the intermediate blocks 12, respectively. The crown bead 14 connects the crown block 11 and two intermediate blocks 12, 12 adjacent to each other on both sides of the crown block 11 in the tire circumferential direction. Thereby, the crown bead 14 is formed in a substantially V-shape projecting inward in the tire axial direction.

The crown lacing 14 comprises a 1 st crown lacing 21 and a 2 nd crown lacing 22. The 1 st crown bead 21 extends to the intermediate block 12 connected to the 1 st shoulder bead 16 and the intermediate block 12 connected to the 2 nd shoulder bead 17 adjacent to the 1 st shoulder bead 16 in the tire circumferential direction, respectively. The 2 nd crown tie 22 extends toward the two intermediate blocks 12 connected to the 1 st shoulder tie 16, respectively. In the present embodiment, the 2 nd crown bead 22 is disposed on both sides in the tire circumferential direction of two 1 st crown beads 21 arranged in the tire circumferential direction. The arrangement of the 1 st crown bead 21 and the 2 nd crown bead 22 is not limited to this manner.

In the present embodiment, the crown tie 14 includes the 1 st crown portion 14A coupled to one of the intermediate blocks 12 and the 2 nd crown portion 14B coupled to the other intermediate block 12. In the present embodiment, the 1 st crown portion 14A and the 2 nd crown portion 14B are separately joined at the crown block 11 without crossing. The crown reinforcement 14 is not limited to this form, and may be formed of only the 1 st crown portion 14A that connects one crown block 11 and one intermediate block 12, for example.

The angle θ 2 of the crown bead 14 with respect to the tire axial direction is preferably larger than the above-described angle θ 1 of the shoulder bead 15. Thus, the crown bead 14 has a large tire circumferential component, and effectively suppresses the movement of the crown block 11, to which a large ground contact pressure is applied, in the tire circumferential direction, thereby improving the grip on a hard road. From such a viewpoint, the angle θ 2 of the crown bead 14 is preferably 35 to 65 degrees, for example.

In the present embodiment, all the crown blocks 11 and all the intermediate blocks 12 are connected by the crown tie 14, and all the intermediate blocks 12 and all the shoulder blocks 13 are connected by the shoulder tie 15. However, the present invention is not limited to such an embodiment.

The width w1 of the shoulder rib 15 perpendicular to the longitudinal direction includes a portion of 50% or more of the tire axial direction length Ws of the shoulder block 13. Such a shoulder rib 15 increases the rigidity of the shoulder blocks 13 and the intermediate blocks 12, which are applied with a relatively large lateral force during cornering. When the width w1 of the shoulder tie 15 is too large, the groove volume of the tread groove 10 becomes small, and the traction on the muddy ground may be reduced. Therefore, the width w1 of the shoulder rib 15 preferably does not include a portion of 90% or more of the length Ws of the shoulder block 13.

In the present embodiment, the width w1 of the shoulder rib 15 gradually increases toward the tire axial direction outer side. In the present embodiment, the width w2 of the crown bead 14 orthogonal to the longitudinal direction thereof gradually increases toward the tire equator C side. The shoulder anchor 15 increases the rigidity of the shoulder block 13 to which a large lateral force acts. The crown bead 14 increases the rigidity of the crown block 11 to which a large ground pressure is applied. The crown bead 14 and the shoulder beads 15 extend, for example, in a straight line.

As shown in fig. 1, in the present embodiment, the height h1 of the crown rib 14 and the height h1 of the shoulder rib 15 are preferably 10% to 40% of the maximum block height Hm of the crown block 11, the middle block 12, and the shoulder block 13. This increases the rigidity of each of the blocks 11 to 13, ensures the groove volume of the tread groove 10, and improves the grip performance on hard roads and the traction performance on muddy lands.

Fig. 3 is an enlarged view of the middle region Mi and the shoulder region Sh. As shown in fig. 3, the treads 12a and 13a of the middle block 12 and the shoulder block 13 are formed in a rectangular shape including, for example, a pair of axial edges 23 and a pair of circumferential edges 24 and 24 connecting both ends of the pair of axial edges 23 and 23. The axial edges 23 are disposed on both sides of each block 12, 13 in the tire circumferential direction and extend in the tire axial direction. The circumferential edges 24 are disposed on both sides of each of the blocks 12 and 13 in the tire axial direction and extend in the tire circumferential direction. Such axial edges 23 and circumferential edges 24 improve the scraping force against the road surface during cornering, thereby improving the steering stability. However, the tread surfaces 12a and 13a of the intermediate block 12 and the shoulder block 13 are not limited to this configuration.

At least one of the intermediate block 12 and the shoulder block 13 includes a stepped tread 28, and the stepped tread 28 includes a 1 st top surface 25 and a 2 nd top surface 26 having a block height smaller than the 1 st top surface 25. In the present embodiment, the stepped tread surface 28 is formed on all the intermediate blocks 12 and all the shoulder blocks 13.

In the present embodiment, the stepped tread surface 28 is provided with a groove 29 between the 1 st top surface 25 and the 2 nd top surface 26. Such grooves 29 increase the edge components of the center blocks 12 and the shoulder blocks 13, and maintain high frictional force against the road surface.

The groove 29 of the present embodiment includes: a pair of axial portions 30 extending in the tire axial direction; and a circumferential portion 31 connecting between the axial portions 30, 30 and extending in the tire circumferential direction. In the present embodiment, the axial portions 30 are separated in the tire circumferential direction.

In the present embodiment, each of the pair of axial portions 30 includes a 1 st inclined portion 33 inclined toward one side with respect to the tire axial direction, and a 2 nd inclined portion 34 inclined in a direction opposite to the 1 st inclined portion 33. In the present embodiment, the axial portion 30 is bent so as to protrude outward of each block 12, 13 by the 1 st inclined portion 33 and the 2 nd inclined portion 34.

The axial portion 30 extends from one circumferential edge 24 toward the other circumferential edge 24, and has a terminal end 30e in the tread surface without reaching the other circumferential edge 24. In the present embodiment, the circumferential portion 31 connects the both terminals 30e, 30 e.

The 1 st top surface 25 of the present embodiment is formed in a hexagonal shape surrounded by a pair of axial portions 30 and a circumferential portion 31. The 2 nd top surface 26 of the present embodiment is formed in a substantially U shape so as to surround the 1 st top surface 25 and the groove 29 in a plan view. Such 1 st top surface 25 is prevented from excessive movement and deformation in the tire axial direction by bending of the axial portion 30, and hence the block is prevented from being missing.

More specifically, the axial portion 30 of the shoulder block 13 extends from the circumferential edge 24a disposed on the tire equator C side toward the tread end Te side. The axial portion 30 of the intermediate block 12 extends from the circumferential edge 24b disposed on the tread end Te side toward the tire equator C side.

The groove 29 preferably has a groove width w3 of, for example, about 0.5 to 3 mm. The depth h3 (shown in FIG. 1) of the groove 29 is preferably 0.5 to 5 mm.

Fig. 4 (a) is a perspective view of the intermediate block 12. FIG. 4 (B) is a sectional view taken along line B-B of (a). As shown in fig. 4, the 1 st block wall 25a extending inward in the tire radial direction from the 1 st top surface 25 protrudes outward from each of the blocks 12 and 13 more than the 2 nd block wall 26a extending inward in the tire radial direction from the 2 nd top surface 26. Such a 1 st block wall 25a and a 2 nd block wall 26a improve shear force against mud. Further, the 1 st block wall 25a and the 2 nd block wall 26a may be formed on the shoulder block 13.

As shown in fig. 3, in the present embodiment, the intermediate blocks 12 include a 1 st intermediate block 12A disposed on the tire equator C side and a 2 nd intermediate block 12B disposed on the tread end Te side of the 1 st intermediate block 12A. The intermediate region Mi of the present embodiment is provided such that the 1 st intermediate block 12A and the 2 nd intermediate block 12B overlap in the tire circumferential direction. This stabilizes the behavior of the vehicle body due to a change in the inclination of the vehicle body during cornering.

Fig. 5 is an enlarged view of the crown region Cr. As shown in fig. 5, in the present embodiment, the crown blocks 11 include the 1 st crown block 11A, the 2 nd crown block 11B, and the 3 rd crown block 11C. The 1 st crown block 11A is disposed in the crown region Cr. The 2 nd crown block 11B is disposed so as to span the crown region Cr and an intermediate region Mi (right side in the drawing) on one side in the tire axial direction. The 3 rd crown block 11C is disposed so as to span the crown region Cr and the intermediate region Mi (left side in the drawing) on the other side in the tire axial direction. Thus, in the crown region Cr of the present embodiment, since any one of the crown blocks 11A to 11C is arranged on the tire circumferential line over the entire tire axial direction range, the behavior of the vehicle body in the inclination change from the straight running to the initial stage of turning is stabilized, and the steering stability performance is improved.

In the present embodiment, in the crown region Cr and the intermediate region Mi, any one of the crown blocks 11A to 11C or the intermediate blocks 12A and 12B is arranged on the tire circumferential line over the entire tire axial direction range. This stabilizes the behavior of the vehicle body in the middle period of tilting from straight traveling to turning, and improves the steering stability performance.

In the present embodiment, one crown block group 11G is formed by the 1 st, 2 nd, and 3 rd crown blocks 11A, 11B, and 11C, and the crown block group 11G is arranged in the tire circumferential direction. This effectively exerts the above-described effects.

The crown block 11 is divided into two block pieces 37, 37 by being provided with a shallow undercut 35 extending in the tire circumferential direction at the center portion in the tire axial direction. Such shallow furrows 35 increase the edge component of the crown block 11 in the tire circumferential direction. For example, the width W4 of the shallow trench 35 is preferably 5% to 25% of the width W of the crown block 11, and the depth H4 (as shown in fig. 1) is preferably 5% to 50% of the block height H1 of the crown block 11.

The 1 st crown block 11A is shaped as a non-offset block in which the two block pieces 37, 37 are not displaced in the tire circumferential direction. The 2 nd crown block 11B and the 3 rd crown block 11C are formed as offset blocks in which two block pieces 37, 37 are offset in the tire circumferential direction.

While the embodiments of the present invention have been described in detail, the present invention is not limited to the illustrated embodiments, and can be modified into various embodiments.