JP4435917B2 - Motorcycle tires - Google Patents

Description

【００４４】
【発明の効果】
叙上の如く、本発明の自動二輪車用タイヤは、タイヤ外皮を、軟質の外側ゴムと硬質の内側ゴムとで形成し、しかもこの内側ゴムの基部の厚さをタイヤ赤道からその内端部まで漸増させているため、グリップ性能や乗り心地性を高いレベルで確保しながら、ショルダー剛性およびタイヤ横剛性をバランス良くかつ充分に高めて操縦安定性を向上しうる。
【図面の簡単な説明】
【図１】本発明の一実施例のタイヤの断面を示す図２のＩ−Ｉ線断面図である。
【図２】そのトレッドパターンを示す展開図である。
【図３】図２のII−II線断面図である。
【符号の説明】
２ トレッド部
２Ｓ トレッド面
２Ｇ トレッドゴム
３ サイドウォール部
３Ｓ サイドウォール面
３Ｇ サイドウォールゴム
４ ビード部
５ ビードコア
６ カーカス
１１ 外側ゴム
１２ 内側ゴム
１２Ｅ 内端部
１３ 基部
１４ トレッド陸部
１５ 隆起部
１５Ｓ 隆起部頂面
Ｅ トレッド縁
Ｇｙ 横溝
Ｇ トレッド溝
Ｋ リムフランジ高さ近傍位置
ＹＳ 横溝の溝底[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a structure of a tire skin disposed on the outside of a carcass, and relates to a motorcycle tire having improved grip performance and steering stability.
[0002]
[Background Art and Problems to be Solved by the Invention]
In order to improve grip performance in motorcycle tires, it is preferable to use a soft rubber for the tread rubber. However, this soft rubber has a small amount of deformation in the pattern block of the tread and the tread rigidity is too low. Steering stability is significantly reduced.
[0003]
In order to achieve both the grip performance and the tread rigidity that are in a trade-off relationship, conventionally, a tread rubber is made of a soft rubber that forms the tread surface, and a base rubber made of hard rubber compared to the inside. It is proposed to use a two-layer structure.
[0004]
However, motorcycles are required to have a characteristic of maintaining a stable running by tilting the vehicle body when turning, and maintaining the stable running by counteracting the camber thrust generated at that time. As a result, the tread rubber having the two-layer structure as described above is required. It is difficult to secure a sufficient balance between the tread rigidity on the shoulder side (shoulder rigidity) and the lateral rigidity of the entire tire (tire lateral rigidity).
[0005]
Therefore, in recent years, there is a strong demand for a tire having a structure that can improve steering stability during straight traveling and turning while ensuring grip performance and riding comfort at a high level.
[0006]
In particular, when used under harsh conditions such as motocross tires, the shoulder rigidity and tire lateral rigidity are strongly required, but the shoulder block is placed on the center of the tread to improve off-road traction. It tends to form deeper than that. Therefore, there is a problem that the shoulder rigidity is more insufficient, and the shoulder block is liable to be damaged such as a chipped block.
[0007]
Therefore, the present invention is to form a tire skin straddling between the bead portions with a soft outer rubber and a hard inner rubber, and to gradually increase the thickness of the base portion of the inner rubber from the tire equator to the inner end thereof. Basically, the object is to provide a tire for a motorcycle capable of improving the steering stability by improving the shoulder rigidity and the lateral tire rigidity in a well-balanced and sufficiently balanced manner while ensuring a high level of grip performance and ride comfort.
[0008]
[Means for Solving the Problems]
In order to achieve the object, the invention of claim 1 of the present application
Outside the carcass extending from the tread portion through the sidewall portion to the bead core of the bead portion, an outer rubber composed of a tread rubber forming a tread surface and a sidewall rubber forming a sidewall surface, and the outer rubber and the carcass In addition to providing an inner rubber that is interposed between both ends in the radial direction in the vicinity of the rim flange height,
The rubber hardness Hs1 (durometer A hardness) of the outer rubber is 55 to 75 degrees, the rubber hardness Hs2 (durometer A hardness) of the inner rubber is 60 to 80 degrees, and is larger than the rubber hardness Hs1 of the outer rubber.
Moreover, a tread groove including a lateral groove extending on the tread edge in the direction intersecting with the tire circumferential direction is provided on the tread surface,
And the inner rubber has a base portion whose thickness gradually increases from the tire equator to the inner end portion at the groove bottom position of the lateral groove and the sidewall portion ,
The thickness Tbq of the inner rubber and the thickness Taq of the outer rubber on a line perpendicular to the carcass passing through the bottom of the lateral groove closest to the tire equator or the tire equator are expressed by the following equation (1):
Further, the inner rubber thickness Tbe and the outer rubber thickness Tae at the groove bottom of the lateral groove on a line passing through the tread edge and perpendicular to the carcass satisfy the following expression (2) .
0.1 ≦ Tbq / (Taq + Tbq) ≦ 0.2 −−− (1)
0.3 ≦ Tbe / (Tae + Tbe) ≦ 0.6 −−− (2)
[0009]
The invention of claim 2 is characterized in that the tread rubber and the sidewall rubber are made of rubber having the same composition.
[0011]
In the invention of claim 3, the inner rubber comprises a raised portion that rises in the tread land portion from the base portion in the tread land portion formed by the tread surface between the groove bottom positions of the lateral grooves adjacent in the circumferential direction,
The thickness Tdq of the inner rubber and the thickness Tcq of the outer rubber on a line perpendicular to the carcass passing through the ridge top surface closest to the tire equator or the tire equator are expressed by the following equation (3):
The inner rubber thickness Tde and the outer rubber thickness Tce on the line perpendicular to the carcass passing through the top surface of the tread edge or the ridge portion closest to the tread edge satisfy the following expression (4): Yes.
0.3 ≦ Tdq / (Tcq + Tdq) ≦ 0.6 −−− (3)
0.4 ≦ Tde / (Tce + Tde) ≦ 0.8 −−− (4)
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In FIG. 1, a motorcycle tire 1 includes a tread portion 2, sidewall portions 3 extending inward in the tire radial direction from both ends thereof, and bead portions 4 positioned at inner ends of the sidewall portions 3. Yeah.
[0013]
In this example, the motorcycle tire 1 is illustrated as a motocross tire. In the meridional section, the tread surface 2S is smoothly curved into a convex arc shape, and between the tread edges E and E. width of is formed so that the maximum width tire. Further, the tread portion 2 has a camber value that is a ratio Lc / Le of the radial distance Lc between the equator point on the tread surface 2S and the tread edge E and the tire axial distance Le to ensure high turning performance. .45 to 0.65. In the figure, the case of about 0.58 is illustrated.
[0014]
Further, the motorcycle tire 1 is provided with a carcass 6 having a bias structure, which extends between the bead portions 4 and 4.
[0015]
The carcass 6 includes folded portions 6B that are folded and locked around the bead core 5 on both sides of the main body portion 6A that extends from the tread portion 2 through the sidewall portion 3 to the bead core 5 of the bead portion 4. . Between the main body portion 6A and the folded portion 6B, a bead apex rubber 8 which extends in a tapered shape outward from the bead core 5 in the radial direction of the tire is arranged to increase the rigidity and strength of the bead portion 4.
[0016]
The carcass 6 is composed of a plurality of carcass plies (three in this example) in which carcass cords are inclined and arranged at an angle of 25 to 60 degrees with respect to the tire circumferential direction. The direction of the inclination is different. As the carcass cord, an organic fiber cord such as nylon, polyester, or rayon is preferably employed.
[0017]
If necessary, a breaker may be provided outside the carcass 6 for the purpose of protecting the carcass 6 against an impact from the road surface and preventing trauma received on the tread portion 2 from reaching the carcass 6. You can also. In this example, the case where the breaker is not provided is illustrated. However, when the breaker is provided, the breaker is one or more in which breaker cords made of organic fiber cords similar to the carcass 6 are arranged in an angle range substantially equal to the carcass cords. It is formed by ply.
[0018]
Next, as shown in FIG. 2, the tread surface 2 </ b> S is provided with a tread groove G including a lateral groove Gy extending on the tread edge E in a direction crossing the tire circumferential direction, that is, opening at the tread edge E.
[0019]
Specifically, in this example, the tread groove G includes a transverse groove Gy extending in the tire axial direction between the tread edges E and E, and a circumferential longitudinal groove Gm crossing between the transverse grooves Gy and Gy, thereby blocking A block pattern in which B is spaced apart is formed.
[0020]
The lateral groove Gy is formed by a deep groove whose groove depth Dy (for example, 16.5 mm) from the tread surface 2S is substantially constant. In this example, the contour line of the groove bottom YS in the tire meridional section (shown in FIG. 1). X is substantially concentric with the tread surface 2S, and is connected with the sidewall surface 3S in a substantially arcuate shape.
[0021]
Further, the vertical groove Gm has a groove depth Dm that is equal to or less than the groove depth Dy of the horizontal groove Gy, and the vertical groove Gm1 disposed in the tread central region Cc that contacts the ground during straight traveling is disposed in the outer tread shoulder region Cs. It is formed shallower than the vertical groove Gm2.
[0022]
In the present invention, as shown in FIG. 1, which is a cross-sectional view taken along the line II (passing through the groove bottom YS) in FIG. 2, the tire skin 10 is arranged outside the carcass 6 and straddles between the bead portions 4, 4. Is a two-layer structure of an outer rubber 11 and an inner rubber 12.
[0023]
The outer rubber 11 is made of a relatively soft rubber having a rubber hardness Hs1 (durometer A hardness) of 55 to 75 degrees, and the tread rubber 2G forming the tread surface 2S and the side forming the sidewall surface 3S. It is formed from wall rubber 3G. In this example, the case where the tread rubber 2G and the side wall rubber 3G are made of the rubber having the same composition is illustrated, whereby the side wall surface 3S has the same wear resistance as the tread surface 2S, and Cut resistance can be imparted, and this is a preferred embodiment as a motocross tire.
[0024]
The inner rubber 12 is made of a hard rubber having a rubber hardness Hs2 (durometer A hardness) of 60 to 80 degrees and larger than the rubber hardness Hs1 of the outer rubber 11, and between the outer rubber 11 and the carcass 6. Further, both inner end portions 12E in the radial direction of the inner rubber 12 are interrupted at a position K in the vicinity of the rim flange height. The “rim flange height vicinity position K” means a height region within ± 10 mm in the radial direction centered on the rim flange upper end height HF of a normal rim defined by a standard such as JATMA.
[0025]
The inner rubber 12 includes a base portion 13 whose thickness gradually increases from the tire equator C to the inner end portion 12E at the position of the groove bottom YS of the lateral groove Gy and the sidewall portion 3.
[0026]
In this base portion 13, in this example, the thickness Tbq of the inner rubber 12 and the thickness Taq of the outer rubber 11 on a line passing through the groove bottom YS of the lateral groove Gy on the tire equator C and perpendicular to the carcass 6 Satisfies the following equation (1).
0.1 ≦ Tbq / (Taq + Tbq) ≦ 0.2 −−− (1)
The thickness Tbq of the inner rubber 12 corresponds to the thickness of the base 13 itself. Further, when the lateral groove Gy does not exist on the tire equator C, that is, for example, in the case of a tread pattern in which circumferential ribs continuously pass on the tire equator C, the lateral groove Gy passes through the groove bottom YS of the lateral groove Gy closest to the tire equator C. The thicknesses Taq and Tbq on a line perpendicular to the carcass 6 are employed.
[0027]
Further, in this base portion 13, in this example, the thickness Tbe of the inner rubber 12 and the thickness of the outer rubber 11 at the groove bottom YS of the lateral groove Gy on the line passing through the tread edge E and perpendicular to the carcass 6. Tae satisfies the following formula (2).
0.3 ≦ Tbe / (Tae + Tbe) ≦ 0.6 −−− (2)
Similarly, the thickness Tbe of the inner rubber 12 corresponds to the thickness of the base portion 13 itself.
[0028]
Thus, not only the tread portion 2 but also the entire tire skin 10 including the sidewall portion 3 has a two-layer structure of the soft outer rubber 11 and the hard inner rubber 12, and the thickness of the base portion 13 of the inner rubber 12 is increased. This is gradually increased from the tire equator C to the inner end 12E.
[0029]
Accordingly, the shoulder rigidity and the tire lateral rigidity can be well balanced and sufficiently ensured while improving the grip performance and the ride comfort. In particular, as shown in the above formulas (1) and (2), the ratio of the thickness of the inner rubber 12 occupying the tire outer shell 10 itself is also increased from the tire equator C side to the tread edge E side. It will be possible to exhibit it effectively. It also helps to suppress block chipping on the tread edge E side.
[0030]
If the rubber hardness Hs1 is less than 55 degrees, the wear resistance is lowered. Conversely, if the rubber hardness Hs1 exceeds 75 degrees, the grip property and the ride comfort are deteriorated. If the rubber hardness Hs2 is less than 60 degrees, the shoulder rigidity and the lateral rigidity of the tire are insufficient, leading to a decrease in steering stability and a tendency to block chipping. Deteriorates comfort. The rubber hardness difference (Hs2-Hs1) is preferably in the range of 5 to 15 degrees.
[0031]
Further, when the value Tbq / (Taq + Tbq) and the value Tbe / (Tae + Tbe) are less than 0.1 and less than 0.3, respectively, the rigidity is insufficient and the steering stability is lowered, and conversely, greater than 0.2 and 0, respectively. If it is larger than .6, the rigidity becomes excessive and the ride comfort is lowered.
[0032]
Further, in the inner rubber 12, as shown in FIG. 3 which is a cross-sectional view taken along the line II-II (through the block B) in FIG. 2, the tread land portion formed by the tread surface 2S between the lateral grooves Gy and Gy adjacent in the circumferential direction. 14 (block B in this example) includes a raised portion 15 that rises from the base portion 13 in the tread land portion 14.
[0033]
In this example, the raised portion 15 is formed in a substantially trapezoidal cross section having a contour surface portion 15A having a constant height from the base portion 13.
[0034]
In the raised portion 15, the thickness Tdq of the inner rubber 12 and the thickness Tcq of the outer rubber 11 on the line passing through the top surface 15S of the raised portion 15 on the tire equator C and perpendicular to the carcass 6 are as follows: Expression (3) is satisfied.
0.3 ≦ Tdq / (Tcq + Tdq) ≦ 0.6 −−− (3)
The thickness Tdq of the inner rubber 12 corresponds to the sum of the thicknesses of the base portion 13 and the raised portion 15. Further, when the raised portion 15 does not exist on the tire equator C, that is, for example, in the case of a tread pattern in which the longitudinal groove Gm continuously passes on the tire equator C, the top surface 15S of the raised portion 15 closest to the tire equator C is provided. The thicknesses Tcq and Tdq on a line perpendicular to the carcass 6 are used. The top surface 15S is a surface portion of the outer surface of the raised portion 15 that is farthest from the base portion 13, and corresponds to the contour surface portion 15A in this example.
[0035]
Further, in the raised portion 15, the thickness Tde of the inner rubber 12 and the thickness of the outer rubber 11 on a line passing through the tread edge E or the top surface 15S of the raised portion 15 closest to the tread edge E and perpendicular to the carcass 6. Tce satisfies the following expression (4).
0.4 ≦ Tde / (Tce + Tde) ≦ 0.8 −−− (4)
[0036]
Thus, since the raised portion 15 of the inner rubber 12 is provided in the tread land portion 14, the rigidity and strength of each tread land portion 14 can be sufficiently ensured. Further, as shown in the above formulas (3) and (4), in the tread land portion 14, the ratio of the thickness of the inner rubber 12 occupying the tire outer skin 10 is higher on the tread edge E side than on the tire equator C side. In addition, it can contribute by increasing the shoulder stiffness and the lateral stiffness of the tire, and further helps to suppress the block chipping.
[0037]
When the value Tdq / (Tcq + Tdq) and the value Tde / (Tce + Tde) are less than 0.3 and less than 0.4, respectively, the rigidity is insufficient and the steering stability is lowered. If it is larger than 0.8, the rigidity becomes excessive and the ride comfort is lowered.
[0038]
As described above, the particularly preferred embodiment of the present invention has been described in detail. However, the present invention is not limited to the illustrated embodiment , and a radial structure can be adopted in addition to a bias structure, and an off-road combined tire or As an on-road tire, the tire can be modified in various forms including a tread pattern.
[0039]
Further, as the outer rubber 11, the tread rubber 2G and the side wall rubber 3G can have different rubber compositions, in which case the rubber hardness of both the rubbers 2G and 3G is in the range of 55 to 75 degrees, and The inner rubber is smaller than the rubber hardness Hs2.
[0040]
【Example】
A tire of the size 110 / 100-18 having the structure shown in FIG. 1 is prototyped based on the specifications shown in Table 1, and each sample tire is tested for wear resistance, grip performance, chipped blocks, ride comfort, and handling stability. The results are shown in Table 1.
[0041]
The sample tire has the tread pattern of FIG. 2 and uses three plies made of polyester cord (1670 dtex) as the carcass.
The front wheel tire has a tire size of 80 / 100-21, a tire outer layer having a one-layer structure, the tread pattern shown in FIG. 2, and three plies made of nylon cord (940 dtex) as a carcass.
[0042]
(1) Test method:
A test tire is mounted on the rear wheel of a 250cc motocross motorcycle under the conditions of a rim (2.15 × 18) and internal pressure (80 kpa), and continuously runs on an unpaved dry road for 20 minutes. The wear resistance performance, grip performance, ride comfort, and handling stability were evaluated by a 10-point method based on sensory evaluation of the driver. The higher the number, the better.
In addition, after the running, the presence or absence of block chipping was confirmed visually.
[0043]
[Table 1]

[0044]
【The invention's effect】
As described above, in the motorcycle tire according to the present invention, the tire outer shell is formed of a soft outer rubber and a hard inner rubber, and the thickness of the inner rubber base is made from the tire equator to the inner end thereof. Since it is gradually increased, it is possible to improve the steering stability by sufficiently increasing the shoulder rigidity and the lateral tire rigidity in a well-balanced manner while ensuring a high level of grip performance and ride comfort.
[Brief description of the drawings]
1 is a cross-sectional view taken along the line II of FIG. 2, showing a cross section of a tire according to an embodiment of the present invention.
FIG. 2 is a development view showing the tread pattern.
3 is a cross-sectional view taken along line II-II in FIG.
[Explanation of symbols]
2 tread portion 2S tread surface 2G tread rubber 3 sidewall portion 3S sidewall surface 3G sidewall rubber 4 bead portion 5 bead core 6 carcass 11 outer rubber 12 inner rubber 12E inner end portion 13 base portion 14 tread land portion 15 raised portion 15S raised portion Top surface E Tread edge Gy Lateral groove G Tread groove K Position near the rim flange height YS Horizontal groove bottom

Claims (3)

Outside the carcass extending from the tread portion through the sidewall portion to the bead core of the bead portion, an outer rubber composed of a tread rubber forming a tread surface and a sidewall rubber forming a sidewall surface, and the outer rubber and the carcass In addition to providing an inner rubber that is interposed between both ends in the radial direction in the vicinity of the rim flange height,
The rubber hardness Hs1 (durometer A hardness) of the outer rubber is 55 to 75 degrees, the rubber hardness Hs2 (durometer A hardness) of the inner rubber is 60 to 80 degrees, and is larger than the rubber hardness Hs1 of the outer rubber.
Moreover, a tread groove including a lateral groove extending on the tread edge in the direction intersecting with the tire circumferential direction is provided on the tread surface,
And the inner rubber has a base portion whose thickness gradually increases from the tire equator to the inner end portion at the groove bottom position of the lateral groove and the sidewall portion ,
The thickness Tbq of the inner rubber and the thickness Taq of the outer rubber on a line perpendicular to the carcass passing through the bottom of the lateral groove closest to the tire equator or the tire equator are expressed by the following equation (1):
The inner rubber thickness Tbe and the outer rubber thickness Tae at the bottom of the lateral groove on the line passing through the tread edge and perpendicular to the carcass satisfy the following expression (2) . tire.
0.1 ≦ Tbq / (Taq + Tbq) ≦ 0.2 −−− (1)
0.3 ≦ Tbe / (Tae + Tbe) ≦ 0.6 −−− (2)   The motorcycle tire according to claim 1, wherein the tread rubber and the sidewall rubber are made of rubber having the same composition. The inner rubber comprises a raised portion that rises in the tread land portion from the base portion in the tread land portion formed by the tread surface between the groove bottom positions of the lateral grooves adjacent in the circumferential direction,
The thickness Tdq of the inner rubber and the thickness Tcq of the outer rubber on a line perpendicular to the carcass passing through the ridge top surface closest to the tire equator or the tire equator are expressed by the following equation (3) :
Features and satisfies the following equation (4) is the thickness Tce thickness Tde the outer rubber put that in side rubber a line perpendicular to the tread edges or through the carcass nearest the ridge top surface in the tread edge The motorcycle tire according to any one of claims 1 and 2.
0.3 ≦ Tdq / (Tcq + Tdq) ≦ 0.6 −−− (3)
0.4 ≦ Tde / (Tce + Tde) ≦ 0.8 −−− (4)

Images