KR101031326B1 - Pattern Structure of Snow Tire upgraded Hydroplaning Performance - Google Patents

Abstract

The present invention relates to a pattern structure of a snow tire with improved drainage performance, and has a groove formed in a predetermined shift symmetry with respect to a center line (CL) on a tread external to the ground, and is divided by a plurality of blocks. In the tread patten structure of the tire having a, the block is located on the center line (CL) of the tread and the center block formed continuously in the driving direction; Side blocks formed at both ends of the tread in a predetermined shift symmetry with respect to the center line CL; And an auxiliary block formed between the center block and the side block, the auxiliary block being formed to have a predetermined shift symmetry based on the center line CL, wherein the groove includes a main slave groove partitioning between the center block and the auxiliary block; A first major horizontal groove communicating with one end of the main slave groove in a side direction of the tread; A second circumferential groove communicating with a point where the dominant groove and the first circumferential groove meet and the other end of the dominant groove; And an auxiliary longitudinal groove partitioning between the auxiliary block and the side block, thereby improving drainage performance on a slush road surface in winter to maintain or improve braking and traction. By arranging a plurality of blocks in a predetermined shift symmetry, it is possible not to have the entire periodicity of the tire, thereby reducing the noise generated when the vehicle runs.

Drainage, noise reduction, braking ability, traction, snow tires

Description

Pattern Structure of Snow Tire upgraded Hydroplaning Performance

The present invention relates to a tread pattern structure of a snow tire mainly used for snow roads or ice roads among pneumatic tires for vehicles, and more particularly, to improve braking and traction during snow and ice road driving in winter, and to slush. The present invention relates to a tread pattern structure of a pneumatic tire for a vehicle that maintains braking and traction by improving drainage performance on a road surface and improves noise performance.

Generally, a pneumatic snow tire has a block type tread pattern structure in which a tread contacting the ground or snow road when driving a vehicle is used. That is, as shown in FIG. Ground blocks 114 and 115 are formed with the central main groove 110 and the zigzag groove 112 interposed between the blocks 111, and a plurality of cuffs 120 and Kerf are formed in the blocks 114 and 115. The stiffness of these blocks is reduced, and the soft compound material is used to increase the traction performance on snow and ice.

However, the conventional block pattern structure of the snow tire is noisy when driving on a general dry road, and the cuffs formed on the blocks are crushed finely, which not only weakens the rigidity of the blocks but also causes abnormal wear between the blocks due to the soft material. The structure is easy to make.

In addition, the block pattern structure of such a snow tire in the prior art exhibits good performance when going straight on the snow road and the ice road, but when turning is also reduced in traction by the cuffs, the performance was somewhat reduced, there was also a disadvantage in noise.

Particularly, on the road where the snow road or the ice road is slightly melted and the water is thin, the drainage performance is weak and the braking and towing performance is lost by the water.

An object of the present invention for solving the above problems, to improve the snow tire pattern structure to improve the drainage performance, to improve the braking performance and traction, and to provide a pattern of snow tires to reduce the noise during driving. .

The pattern structure of the snow tire with improved drainage performance of the present invention for achieving the above object, has a groove formed on the tread external to the ground with a predetermined shift symmetrical with respect to the center line (CL), by the groove A tread patine structure of a tire having a plurality of blocks partitioned, the block comprising: a center block located on a center line of the tread (CL) and continuously formed in a driving direction; Side blocks formed at both ends of the tread in a predetermined shift symmetry with respect to the center line CL; And an auxiliary block formed between the center block and the side block, the auxiliary block being formed to have a predetermined shift symmetry based on the center line CL, wherein the groove includes a main slave groove partitioning between the center block and the auxiliary block; A first major horizontal groove communicating with one end of the main slave groove in a side direction of the tread; A second circumferential groove communicating with a point where the dominant groove and the first circumferential groove meet and the other end of the dominant groove; And an auxiliary vertical groove partitioning between the auxiliary block and the side block.

Here, the main slave groove may be formed to be inclined in the side direction of the tread along the driving direction, the main slave groove and the first main horizontal groove may be connected roundly.

In addition, the side block may further include a side horizontal groove partitioning the first side block and the second side block.

On the other hand, the auxiliary block may further include at least one auxiliary horizontal groove for improving the drainage performance.

The plurality of blocks may further include a plurality of semi grooves for improving braking performance.

In addition, the width A of the dominant groove, the first circumferential groove, and the second circumferential groove may be 4.3% to 4.6% of the total width of the tread.

In addition, the width B of the side groove may be 4.0% to 4.2% of the total width of the tread.

On the other hand, the width (C) of the secondary seed groove may be formed to 2.9% to 3.3% of the total width of the tread (TAW).

In addition, the width D of the auxiliary horizontal groove may be formed to be 4.3% to 4.6% of the total width of the tread (TAW).

In addition, the angle formed by the auxiliary longitudinal groove with respect to the center line CL may be 13 degrees to 14, and the angle made by the auxiliary horizontal groove with respect to the center line CL may include 56 degrees to 57 degrees.

In addition, the length of the auxiliary transverse groove may be formed in the range of 5.5% to 7.5% of the total width of the tread (TAW).

According to the pattern structure of the snow tire with improved drainage performance of the present invention, it is possible to maintain or improve the braking and traction by improving the drainage performance in the winter slush (slush) road surface.

In addition, by arranging a plurality of blocks in a predetermined shift symmetry, there is an effect of reducing noise generated when the vehicle is driven by not having the entire periodicity of the tire.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

Figure 2 is a partial plan view showing the snow tire tread pattern structure with improved drainage performance according to the present invention.

Referring to FIG. 2, the pattern structure of the snow tire having improved drainage performance of the present invention includes a groove formed on the tread external to the ground by a predetermined shift symmetry with respect to the center line CL. It has a number of blocks partitioned by.

In FIG. 2, the upper side is a driving direction of the vehicle.

The pattern structure of the snow tire with improved drainage performance of the present invention is formed with a constant pitch as shown in FIG.

The material of the tread is generally a material of a snow tire tread.

In this case, the block includes a center block 11, a side block and an auxiliary block 12.

The center block 11 is located on the center line CL of the tread and is continuously formed in the driving direction.

In addition, the shape is formed in a predetermined shift symmetry based on the center line CL of the center block 11.

The side blocks are formed at both ends of the tread in a predetermined shift symmetry with respect to the center line CL.

That is, the side blocks are located at both ends of the tread, and the shoulder part 2 and one surface thereof are connected to each other.

In addition, the side block may be divided into a first side block 13 and a second side block 14.

That is, the side lateral grooves 41 divide between the first side block 13 and the second side block 14.

Therefore, the side lateral grooves 41 serve to improve drainage performance.

In addition, the auxiliary block 12 is formed between the center block 11 and the side block and is formed to have a predetermined shift symmetry based on the center line CL.

Therefore, as described above, the center block 11, the auxiliary block 12, and the side block are formed to have a predetermined shift symmetry based on the center line CL, thereby reducing noise generated when driving.

That is, by arranging the tire so as not to have the entire periodicity, the noise reduction effect is achieved.

In addition, a plurality of semi grooves S1 may be further formed in the plurality of blocks.

The plurality of semi grooves S1 may be formed to be perpendicular to the traveling direction, or may be formed to be close to the vertical.

Therefore, the plurality of semi grooves S1 improves braking force and traction force of the tire.

Here, the main slave groove 21, the first circumferential groove 31, the second circumferential groove 32 and the secondary longitudinal groove 22 is formed.

The main slave groove 21 partitions between the center block 11 and the sub block 12 and is formed in a driving direction.

The first circumferential groove 31 communicates with one end of the dominant groove 21 and is formed in the side direction of the tread, and is formed up to the shoulder 2.

The master groove 21 may be formed to be inclined in the side direction of the tread along the driving direction.

In addition, the main groove 21, the second circumferential groove 32 may be connected round.

Therefore, the water on the road surface is drained along the main groove 21 and the first lateral groove 31.

The second major horizontal groove 32 communicates the point where the main slave groove 21 and the first main horizontal groove 31 meet with the other end of the main slave groove 21.

The secondary seed groove 22 partitions between the secondary block 12 and the side block.

That is, the auxiliary longitudinal groove 22 communicates the first lateral groove 31 and the first lateral groove 31, and the side lateral groove 41 communicates with the central portion thereof.

Therefore, when the vehicle travels, mutual complementary action is performed on the drainage performance between the first circumferential groove 31 and the side lateral groove 41.

In addition, at least one auxiliary horizontal groove 33 may be further formed in the auxiliary block 12 to improve drainage performance.

As shown in Fig. 2, two auxiliary transverse grooves 33 are formed in this embodiment.

Although the number of the auxiliary side grooves 33 is not limited, two are preferable in consideration of the braking performance, drainage performance and rigidity of the tire.

In addition, the width D of the auxiliary horizontal groove 33 is preferably formed to be 4.3% to 4.6% of the total width of the tread (TAW).

In addition, the angle formed by the auxiliary horizontal groove 33 with respect to the center line CL is preferably 56 degrees to 57 degrees.

In addition, the length of the auxiliary horizontal groove 33 is preferably formed in the range of 5.5% to 7.5% of the total width of the tread (TAW).

As described above, the width, length, and angle of the auxiliary transverse groove 33 improve drainage performance, braking performance, and traction.

The width A of the main groove 21, the first main horizontal groove 31, and the second main horizontal groove 32 is preferably formed to be 4.3% to 4.6% of the total width of the tread. This takes into account the tread stiffness, braking performance and drainage performance.

The width B of the side grooves 41 is preferably formed to 4.0% to 4.2% of the total width of the tread (TAW).

In addition, the width C of the auxiliary seed groove 22 is preferably formed to be 2.9% to 3.3% of the total width of the tread (TAW).

In addition, it is preferable that the angle formed by the auxiliary longitudinal groove 22 with respect to the center line CL is 13 degrees to 14 degrees.

Therefore, according to the present invention, it is possible to maintain braking and traction by improving drainage performance on a slush road in winter, and to improve noise performance.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but many variations and modifications may be made without departing from the spirit and scope of the invention. And it goes without saying that they belong to the scope of the present invention.

1 is a partial plan view showing the tread pattern of a snow tire according to the prior art.

Figure 2 is a partial plan view showing the snow tire tread pattern structure with improved drainage performance according to the present invention.

<Description of Main Reference Signs>

2: shoulder section 11: center block

12: auxiliary block 13: first side block

14: 2nd side block 21: master groove

22: subsidiary groove 31: first circumferential groove

32: 2nd lateral groove 33: Auxiliary lateral groove

41: side groove S1: semi groove

Claims (11)

In the tread patten structure of a tire having a groove formed on the tread circumscribed to the ground in a predetermined shift symmetry with respect to the center line CL, and having a plurality of blocks partitioned by the groove, The block is, A center block positioned on the center line CL of the tread and continuously formed in the driving direction; Side blocks formed at both ends of the tread in a predetermined shift symmetry with respect to the center line CL; And It is formed between the center block and the side block, and comprises a secondary block formed in a predetermined shift symmetry based on the center line (CL), The groove is Main slave groove partitioning between the center block and the auxiliary block; A first major horizontal groove communicating with one end of the main slave groove in a side direction of the tread; A second circumferential groove communicating with a point where the dominant groove and the first circumferential groove meet and the other end of the dominant groove; And Pattern structure of a snow tire with improved drainage performance comprising a secondary longitudinal groove for partitioning between the secondary block and the side block. The method of claim 1, The main slave groove is formed to be inclined in the side direction of the tread along the running direction, The main grove and the first circumferential groove is a pattern structure of the snow tire with improved drainage, characterized in that the rounded connection. The method of claim 2, The pattern structure of a snow tire, characterized in that it further comprises a side horizontal groove partitioning the side block into a first side block and a second side block. The method of claim 3, wherein The auxiliary block pattern structure of the snow tire with improved drainage performance, characterized in that it further comprises at least one auxiliary horizontal groove for improving the drainage performance. The method of claim 4, wherein The plurality of blocks is a pattern structure of the snow tire with improved drainage performance, characterized in that it further comprises a plurality of semi grooves for improving the braking performance. The method of claim 3, wherein The width (A) of the dominant groove, the first circumferential groove and the second circumferential groove is formed to be 4.3% to 4.6% of the total width of the tread (TAW) pattern structure of the snow tire with improved drainage performance. The method of claim 3, wherein The width (B) of the side groove pattern structure of the snow tire with improved drainage performance, characterized in that formed in 4.0% to 4.2% of the total width of the tread (TAW). The method of claim 3, wherein The width (C) of the secondary longitudinal groove is a pattern structure of the snow tire with improved drainage performance, characterized in that formed in 2.9% to 3.3% of the total width of the tread (TAW). The method of claim 4, wherein The width (D) of the auxiliary lateral groove is a pattern structure of the snow tire with improved drainage performance, characterized in that formed in 4.3% to 4.6% of the total width of the tread (TAW). The method of claim 4, wherein The auxiliary species grooves are formed at an angle of 13 degrees to 14 with respect to the center line CL, The angle of the auxiliary horizontal groove with respect to the center line (CL) is a pattern structure of the snow tire with improved drainage performance, characterized in that 56 to 57 degrees. The method of claim 4, wherein The length of the auxiliary transverse groove pattern structure of the snow tire with improved drainage performance, characterized in that formed in the range of 5.5% to 7.5% of the total width of the tread (TAW).

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