JP4205196B2 - Pneumatic radial tire - Google Patents

Description

【００３１】
表１から明らかなように、本発明タイヤ１〜３は、高速耐久性をベルトカバー層を設けた従来タイヤ２と同等レベルまで高めることができるのが判る。しかも、従来タイヤ２のように重量増加を招くことがない。また、操縦安定性、乗心地性、高周波ロードノイズ、及び生産性においても、優れていることが判る。
実施例２
タイヤサイズを上記と同じにし、上述した本発明タイヤ１において、ベルト総幅に対するセンターベルト層とサイドベルト層の幅の割合を表２のように変えた試験タイヤ１〜５をそれぞれ作製した。
【００３２】
これら各試験タイヤを上述した測定条件により、高速耐久性、重量、操縦安定性、乗心地性、高周波ロードノイズ、及び生産性の評価試験を行ったところ、表２に示す結果を得た。
【００３３】
【表２】

【００３４】
表２から、センターベルト層の幅をベルト総幅の６５〜８５％、サイドベルト層の幅をそれぞれベルト総幅の７．５〜１７．５％（左右合計幅で１５〜３５％）にするのがよいことが判る。
【００３５】
【発明の効果】
上述したように本発明の空気入りラジアルタイヤは、ベルト層をタイヤセンター領域のセンターベルト層と、両サイド領域のサイドベルト層とに３分割し、センターベルト層を補強コードが端部間で折り返されながらタイヤ周方向に連続的に巻き付けられる構成にし、両サイドベルト層を補強コードがタイヤ周方向に対して実質的に０°の角度で連続的に螺旋状で巻き付けられる構造にしたため、ベルト層の端部への層間剪断歪みの集中を回避し、かつ高速走行時のせり上がり現象を抑制し、耐エッジセパレーション性大幅に高めて、高速耐久性を改善することができる。その上、補強コードの連続的巻き付けによってベルト層を形成することによる生産性向上と共に、ベルトカバー層のような補強層を設けることなく、ベルト層の構造を変えるだけでよいので、重量の増加を回避することができる。
【図面の簡単な説明】
【図１】本発明の空気入りラジアルタイヤの一例を示すタイヤ子午線半断面図である。
【図２】図１のベルト層の概略説明図である。
【図３】センターベルト層の作り方の一例を示す斜視図である。
【図４】センターベルト層の作り方の他の例を示す要部斜視図である。
【図５】 （ａ）はセンターベルト層に用いられるベルト材の他の例を示す要部平面図、（ｂ）は（ａ）のＪーＪ矢視断面図である。
【図６】サイドベルト層の補強コードに使用されたタイヤ膨径後の単撚スチールコードの一列を示す拡大断面図である。
【図７】図６の要部正面図である。
【符号の説明】
１ トレッド部 ２ ビード部
３ サイドウォール部 ４ カーカス層
５ ビードコア ６ ビードフィラー
７ ベルト層 ８ センターベルト層
９ サイドベルト層 Ａ，Ａ’ベルト材
ＣＬ タイヤセンターライン Ｍ 単撚スチールコード
Ｑ，Ｓ，Ｓ’ストリップ材 Ｘ タイヤセンター領域
Ｙ サイド領域 Ｚ ベルト総幅
ｆ，ｇ 補強コード[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a pneumatic radial tire, and more particularly to a pneumatic radial tire that improves high-speed durability without increasing weight while improving productivity.
[0002]
[Prior art]
In general, the belt layer of a pneumatic radial tire is obtained by bias-cutting strips that have been calendered so as to impregnate a plurality of aligned steel cords with unvulcanized rubber and joining the strips that have been bias-cut. Winding it as a long belt material, unwinding it at the time of use, cutting it to the length of the belt layer, splicing it so that the ends overlap partly around the outer circumference of the base tire, and winding at least two layers the steel cord is formed by laminating so as to intersect with each other between the layers. However, in the belt layer configured in this way, since the cut ends of the reinforcing cord are formed at both ends of the belt layer, there are portions where the cord and the rubber are not bonded, and the interlaminar shear strain is also large. In addition, when traveling at a high speed, a phenomenon of rising outward due to centrifugal force occurs at both ends of the belt layer, so that there is a problem in that the edge of the belt layer is easily separated and high-speed durability is inferior.
[0003]
Conventionally, as an above measure, by continuously winding an organic fiber cord such as a nylon cord around the outer circumference of the belt layer at an angle of approximately 0 ° in the tire circumferential direction, the belt layer end is prevented from rising, There is a proposal of a technique for improving high-speed durability. However, the provision of a belt cover layer such as a nylon cord has a problem in that the weight increases greatly. In addition, the belt structure that joins the steel cord strips that have been bias-cut has a problem that it takes a lot of time to manufacture, and many processes rely on manual work, so it is difficult to increase productivity.
[0004]
[Problems to be solved by the invention]
An object of the present invention is to provide a pneumatic radial tire capable of improving productivity and improving high-speed durability without increasing weight.
[0005]
[Means for Solving the Problems]
The present invention that achieves the above object is a pneumatic radial tire provided with a belt layer in which reinforcing cords are arranged on the outer periphery side of a carcass layer in a tread portion, a center belt layer in which the belt layer is disposed in a tire center region, and both sides thereof The center belt layer is divided into both side belt layers arranged so that the end in the tire width direction is in contact with or away from the side region adjacent to the tire, and one or more center belt layers are aligned. The reinforcing cords are continuously wound in the tire circumferential direction while being folded between both ends of the center belt layer, and are formed into even layers so that the reinforcing cords intersect each other between the layers. A configuration in which a plurality of reinforced cords are continuously wound in a spiral at an inclination angle of 5 ° or less with respect to the tire circumferential direction. Characterized in that was.
[0006]
In this way, the belt layer is divided into a center belt layer in the tire center region and a side belt layer in both side regions, and the center belt layer is configured to continuously wrap around the tire circumferential direction by folding the reinforcing cord at both ends thereof, Both side belt layers have a continuous spiral winding of 5 ° or less with respect to the tire circumferential direction of the side belt layers, thereby increasing the circumferential effect in the tire circumferential direction, and the cut ends of the reinforcement cords at the belt layer end portions. Therefore, it is possible to reduce the phenomenon of rising of the belt layer end portion and the interlaminar shear strain at the belt layer end portion during high-speed running, and to greatly improve the edge separation resistance of the belt layer.
[0007]
In addition, the belt structure can be improved by simply improving the belt structure without providing any reinforcing layer such as a belt cover layer, and the belt layer is formed by continuously winding the reinforcing cord. Therefore, productivity can be remarkably improved as compared with the case of attaching a bias cut piece.
In addition, the steering stability can be increased by increasing the tire circumferential rigidity of the side belt portion, and the vibration frequency of the tire is moved to the high frequency side, so that high frequency road noise can be improved. Furthermore, since there is no splice portion in the belt layer, riding comfort can be improved.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 shows an example of a pneumatic radial tire according to the present invention with a half section only on one side from the tire center line CL. 1 is a tread portion, 2 is a bead portion, and 3 is a sidewall portion. One carcass layer 4 in which reinforcing cords are arranged in the tire radial direction is disposed inside the tire. The carcass layer 4 is folded back from the inside to the outside of the tire so as to sandwich a bead filler 6 around a bead core 5 having both end portions 4a embedded in the left and right bead portions 2. Two belt layers 7 are embedded on the outer peripheral side of the carcass layer of the tread portion 1.
[0009]
In the pneumatic tire having the above-described configuration, the belt layer 7 is separated from the center belt layer 8 disposed in the tire center region X and the side belt layers 9 disposed in the side region Y adjacent to both sides thereof. It is configured.
As shown in FIG. 3, the center belt layer 8 is made of unstretched strip material S, in which one or a plurality of reinforcement cords (not shown) are aligned in parallel and focused with unvulcanized rubber during green tire molding. It is formed on the carcass layer 4 by continuously winding it in the circumferential direction of the tire through wave-like bending at both ends of the belt width within the width of the tire center region X. As for the winding method of the strip material S, the strip material S may be wound in a wave shape in the circumferential direction of the tire, and may be rotated a plurality of times while being shifted substantially by the strip width of the strip material S, or wound at a pitch several times the strip width. You may make it wind up so that strip material S may adjoin each other finally, turning. The center belt layer 8 having a structure in which the reinforcing cord is folded between both end portions in this way has no center end of the reinforcing cord cut at both end portions, and the center belt layer 8A in which the reinforcing cord intersects between the upper and lower two layers. 8B can be formed.
[0010]
Further, the center belt layer 8 is formed, for example, by forming a tubular body once wound up so that the strip material S is spirally and continuously in contact with the rotating drum, and removing the tubular body from the rotating drum, As shown in FIG. 4, the flat cylindrical belt material A obtained by crushing along the longitudinal direction may be assembled and formed at the time of green tire molding before vulcanization. The center belt layer 8 is folded between both ends of the center belt layer by winding the reinforcing cord f in a flat spiral shape.
[0011]
Furthermore, as shown in FIG. 5, the center belt layer 8 is formed by continuously stripping the strip material S ′ on the uncured carcass layer in a zigzag manner in the tire circumferential direction with folding at the belt width end portion. You may use belt material A 'obtained by winding. In the center belt layer 8, the reinforcing cord f is wound in a zigzag shape so that the center belt layer 8 is folded between both ends of the center belt layer so that the cut ends are not located at both ends. In addition, it is more preferable from the viewpoint of durability that the winding start end portion and the winding end end portion of the strip material S ′ are in the center portion of the center belt layer 8.
[0012]
On the other hand, the side belt layer 9 is continuously formed so that the reinforcing cord g is substantially 0 ° with respect to the tire circumferential direction, specifically, with an inclination angle within 5 ° with respect to the tire circumferential direction. It has a spirally wound structure.
The side belt layer 9 is formed, for example, at the outer peripheral side of the uncured carcass 4 using a strip material Q in which one or a plurality of parallel reinforcing cords g are embedded in unvulcanized rubber when green tires are molded. It can be obtained by continuously winding the side region Y multiple times without gaps.
[0013]
The center belt layer 8 and the side belt layer 9 are formed of independent strip materials Q, S, and S ′, but may be formed of a single continuous strip material. Further, the strip material S, S ′ for forming the center belt layer 8 is not limited to one, and the winding time may be shortened by simultaneously starting winding from a plurality of locations with a plurality of strip materials. .
[0014]
As described above, the present invention divides the belt layer 7 into the center belt layer 8 in the tire center region X and the side belt layers 9 in both side regions Y, and the center belt layer 8 is formed between the both ends of the reinforcing cord f. Since the belt is wound around in the tire circumferential direction and the side belt layers 9 are continuously wound in a spiral shape with the reinforcing cord g being substantially 0 ° with respect to the tire circumferential direction, the center belt layer 8 In addition, since both the side belt layers 9 have no cut ends of the reinforcing cords at both ends thereof, and the rising behavior during high-speed running is suppressed, the edge separation of the belt layer can be greatly suppressed.
[0015]
In addition, the side belt layer 9 has a substantially improved rigidity in the tire circumferential direction because the reinforcing cord g is wound at substantially 0 ° in the tire circumferential direction. Noise can also be improved.
Further, since the belt layer 7 has the above structure, it has a structure without a splice portion, so that riding comfort can be improved.
[0016]
Furthermore, since the reinforcing cords f and g are continuously wound to form the belt layer, productivity can be remarkably improved as compared with the case of pasting a bias cut piece.
In the present invention, as the width of the side belt layer 9, that the total width of 15% to 35% of the belt total width Z, preferably in the case of symmetric structure, the width of the belt total width Z per side It is good to make it 7.5 to 17.5%. The width of the center belt layer 8 is preferably 65 to 85% of the total belt width Z.
[0017]
In the embodiment of FIG. 1, the boundary between the center belt layer 8 and the side belt layer 9 abuts the end in the tire width direction without overlapping the end (end in the tire width direction) with each other. but the center belt layer 8 and the both sides belt layer 9 may be separated through a gap of slightly from. From the tire manufacture, preferably to be slightly overlapped with the center belt layer and the side belt layer, the overlap amount when the lift of the vulcanization molding is corrected to zero in the state of the unvulcanized tire .
[0018]
As the reinforcing cords for the center belt layer 8 and the side belt layers 9, any known high strength and high elastic modulus cords used for conventional belt layers can be used. For example, in addition to steel cords and steel filaments, organic fiber cords having a tensile elastic modulus of 1500 kgf / mm ² or more such as aramid fibers, polyparaphenylene benzbisoxazole (PBO) fibers, polyethylene naphthalate (PEN) fibers, etc. are preferably used. Can do.
[0019]
In the present invention, the strip materials Q, S, S ′ used for forming the center belt layer 8 and the side belt layers 9 are preferably those having a width of 5 mm or more in order to ensure good productivity. . The upper limit of the width is preferably 15 mm or less in the case of the strip material S of the center belt layer 8 accompanied by wave-like bending, and the bending process becomes difficult beyond that. In the strip material S ′ which is folded back in a zigzag shape or wound in a flat spiral shape, it is preferable that the width is 60 mm or less. Above this, the area of the exposed end portion of the reinforcing cord is increased, and the durability is lowered. In the case of the strip material Q, the strip material Q is not particularly limited as long as it does not interfere with productivity, and can be, for example, 10 mm.
[0020]
In particular, as the reinforcing cord used for the side belt layer, it is desirable to use a cord that follows a tire diameter when the tire is lifted during vulcanization of the green tire. For example, as shown in FIGS. 6 and 7, a single-stranded steel cord M in which a plurality of (five in the figure) strands e in a spiral shape have a 1 × n structure can be preferably used.
[0021]
This single twisted steel cord M has a molding rate set in a large range of 140 to 210%, and has extremely high rubber permeability into the cord. However, the mold rate of the single-stranded 1 × n structure is such that when the cord outer diameter is 100 when the n strands are twisted concentrically without gaps, individual strands corresponding to the cord are taken out. It is defined as the spiral outer diameter of the bare wire.
[0022]
Steel cord M the single twisted after tire upset, in a plurality of element wires e tire radial direction cross-section, as shown in FIG. 6, arranged in an arc over the 180 ° with respect to an imaginary circle shown by a dotted line, transverse The surface is a substantially C-shaped array. The number of strands is n, the strand diameter is d, and the distances k1, k2, k3, k4... Kn-1 between the centers of adjacent strands e in the state where they are buried in the tread portion 1 after the tire expansion. The total sum Σk and the outer diameter D of the single-stranded steel cord M that forms a spiral strand arrangement,
Σk <1.16d (n−1) (1)
1.6 <dn / (D−d) <3.0 (2)
It is better to satisfy the following formula. In FIG. 7, R is a rubber filled in the single twist steel cord M.
[0023]
Such a single twisted steel cord M has a relatively small stress generated in the initial strain region, so that it does not hinder the uniform deformation of the inner carcass layer, and the single twisted steel cord M follows the tire expansion diameter during vulcanization. While the steel cord M can be elongated, the elongation of the belt layer can be suppressed after the expansion, so that the belt layer can exert the tagging effect.
When the Σk is in a state separated from 1.16d (n-1) or more, the deformation of the side belt layer to the outside is large, and it is insufficient to increase the tire circumferential rigidity. The lower limit of Σk may be in a state where each strand e is in contact without biting, that is, d (n−1) or more.
[0024]
Even if the dn / (Dd) is 1.6 or less, the tire circumferential rigidity becomes insufficient. Conversely, when the dn / (Dd) is 3.0 or more, the steel cord M bites into the carcass layer at the time of expansion, and durability Is significantly reduced.
The number of strands of the single stranded steel cord M is preferably 3 to 8. If the number is less than 3, it is difficult to process. Conversely, if the number is more than 8, the strands are difficult to be arranged in a circular arc shape, and this is not preferable because nonuniform stress is applied to the strands. Each strand e may have the same diameter or may have different diameters. When the strand diameters are different, the strand diameter d in the above formula is an average of them.
[0025]
The side belt layer 9 may use a so-called high elongation cord having a short pitch double twist structure instead of the above-described single twist steel cord. And may be embedded in an unvulcanized strip material Q.
The angle of the reinforcing cord f of the center belt layer 8 with respect to the tire circumferential direction is preferably in the range of 15 to 45 °.
[0026]
In the above-described embodiment, an example in which the number of belt layers 7 is two has been described, but the present invention is not limited to this. The center belt layer is necessarily an even number, but the side belt layer may be a single layer or a plurality of layers, and may be an odd number or an even number.
[0027]
【Example】
Example 1
The tire of the present invention having the belt structure shown in FIG. 3 and the present invention having the belt structure shown in FIG. 4 in the tire provided with the center belt layer and the side belt layer shown in FIG. The tire 2, the tire 3 of the present invention having the belt structure shown in FIG. 5, the comparative tire 1 having the belt layer formed of the belt layer shown in FIG. 5 over the entire belt width, and the cut end of the reinforcing cord as the center belt layer of the tire 1 of the present invention. Comparative tire 2 constituted by two belt layers having a belt edge portion, conventional tire 1 having a belt layer constituted by two belt layers having a cut end of a reinforcing cord at a belt edge portion, and 2 in this conventional tire 1 The conventional tire 2 in which the belt cover layer of the layer was arranged on the outer periphery of the belt layer was produced.
[0028]
In each test tire, a steel cord is used as the reinforcing cord of the belt layer, and the amount of the cord used is the same. The cord structure and the number of ends are as shown in Table 1. Further, the inclination angle of the reinforcing cord inclined with respect to the tire circumferential direction is 24 °. The width of the center belt layer in the tire of the present invention is 85% of the total width of the belt, and the width of the side belt layers is 7.5% of the total width of the belt. For the belt cover layer in the conventional tire 2, a nylon cord having a structure of 840d / 2 was used.
[0029]
When these test tires were subjected to high-speed durability, weight, handling stability, riding comfort, high-frequency road noise, and productivity evaluation tests under the measurement conditions shown below, the results shown in Table 1 were obtained.
High-speed durability Each test tire is mounted on a rim with a rim size of 14 x 51/2 JJ, the air pressure is 220 kPa, the drum tester is mounted on a rotating drum with a diameter of 1707 mm, and the load is 4.4 kN (450 kg). Then, after running according to the JATMA high-speed durability test, increase the speed by 8 km / hr every 30 minutes, measure the distance until a tire failure occurs, and the result is an index value with the conventional tire 1 as 100 It was evaluated with. The higher this value, the better the high speed durability.
Weight The weight of each test tire was measured, and the result was evaluated by an index value with the conventional tire 1 being 100. A larger value indicates a lighter weight.
Steering stability and riding comfort Each test tire was mounted on a rim with a rim size of 14 x 51/2 JJ, mounted on a 2500cc vehicle with an air pressure of 180 kPa, and a paneling filling test was conducted on the test course. The conventional tire 1 was evaluated with an index value of 100. The larger this value, the better the performance.
High-frequency road noise Each test tire is mounted on a vehicle under the same conditions as described above, and the sound pressure level of high-frequency road noise when traveling straight on a paved road at a speed of 50 km / h is measured. The index value was evaluated. Higher values indicate lower high-frequency road noise.
Productivity Each test tire was evaluated based on the number of tires produced per unit time with an index value where the conventional tire 1 was 100. The larger this value, the higher the productivity.
[0030]
[Table 1]

[0031]
As can be seen from Table 1, the tires 1 to 3 of the present invention can increase the high-speed durability to the same level as the conventional tire 2 provided with the belt cover layer. Moreover, unlike the conventional tire 2, there is no increase in weight. It can also be seen that the steering stability, riding comfort, high-frequency road noise, and productivity are also excellent.
Example 2
Test tires 1 to 5 having the same tire size as described above and having the ratio of the width of the center belt layer and the side belt layer with respect to the total belt width as shown in Table 2 in the tire 1 described above were prepared.
[0032]
When these test tires were subjected to high-speed durability, weight, handling stability, riding comfort, high-frequency road noise, and productivity evaluation tests under the measurement conditions described above, the results shown in Table 2 were obtained.
[0033]
[Table 2]

[0034]
From Table 2, the width of the center belt layer is 65 to 85% of the total belt width, and the width of the side belt layer is 7.5 to 17.5% of the total belt width (15 to 35% in total left and right width), respectively. It turns out that it is good.
[0035]
【The invention's effect】
As described above, in the pneumatic radial tire of the present invention, the belt layer is divided into the center belt layer in the tire center region and the side belt layers in both side regions, and the reinforcing cord is folded between the end portions of the center belt layer. The belt layer is constructed so that the belt is continuously wound in the tire circumferential direction while the both side belt layers are structured so that the reinforcing cord is continuously spirally wound at an angle of substantially 0 ° with respect to the tire circumferential direction. It is possible to avoid the concentration of interlaminar shear strain at the end of the belt, suppress the phenomenon of rising during high speed running, greatly enhance edge separation resistance, and improve high speed durability. In addition, productivity can be improved by forming the belt layer by continuously winding the reinforcing cords, and the weight layer can be increased without changing the structure of the belt layer without providing a reinforcing layer such as a belt cover layer. It can be avoided.
[Brief description of the drawings]
FIG. 1 is a half sectional view of a tire meridian showing an example of a pneumatic radial tire of the present invention.
FIG. 2 is a schematic explanatory diagram of the belt layer in FIG. 1;
FIG. 3 is a perspective view showing an example of how to make a center belt layer.
FIG. 4 is a main part perspective view showing another example of how to make a center belt layer.
5A is a plan view of a principal part showing another example of a belt material used for the center belt layer, and FIG. 5B is a cross-sectional view taken along the line J-J in FIG.
FIG. 6 is an enlarged cross-sectional view showing one row of single-stranded steel cords after tire expansion used for reinforcing cords for side belt layers.
7 is a front view of the main part of FIG. 6. FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Tread part 2 Bead part 3 Side wall part 4 Carcass layer 5 Bead core 6 Bead filler 7 Belt layer 8 Center belt layer 9 Side belt layer A, A 'Belt material CL Tire center line M Single twist steel cord Q, S, S' Strip material X Tire center area Y Side area Z Belt total width f, g Reinforcement cord

Claims (6)

In a pneumatic radial tire provided with a belt layer in which reinforcing cords are arranged on the outer peripheral side of a carcass layer in a tread portion, a center belt layer in which the belt layer is arranged in a tire center region, and the center belt in side regions adjacent to both sides thereof The center belt layer is divided into both side belt layers arranged so that the ends in the tire width direction are in contact with or separated from each other, and the center belt layer is provided with one or a plurality of aligned reinforcing cords at both ends of the center belt layer. The belt is continuously wound in the circumferential direction of the tire while being folded back, and is formed in an even number of layers so that the reinforcing cords intersect each other between the layers, and the side belt layers are provided with one or a plurality of aligned reinforcing cords Is a pneumatic radial tire configured to be continuously spirally wound at an inclination angle of 5 ° or less with respect to the tire circumferential direction.   The pneumatic radial tire according to claim 1, wherein the reinforcing cord is folded back between both end portions of the center belt layer by winding the reinforcing cord in a wave shape, a zigzag shape, or a flat spiral shape.   The pneumatic radial tire according to claim 1 or 2, wherein a total width of the side belt layers is 15 to 35% of a total belt width. The pneumatic radial tire according to claim 1, 2 or 3, wherein the reinforcing cord of the belt layer is selected from a steel filament, a steel cord, and an organic fiber cord having a tensile elastic modulus of 1500 kgf / mm ² or more. The pneumatic steel according to claim 4 , wherein the steel cord is composed of a single twist steel cord having a structure of 1xn having 3 to 8 strands, and the molding rate of the single twist steel cord is 140 to 210%. Radial tire. In the single-stranded steel cord, the strands are arranged in a C shape in a cross section, the outer diameter of the single-stranded steel cord is D, the strand diameter is d, and the total distance between the centers of adjacent strands is Σk. The pneumatic radial tire according to claim 5, wherein the following relationship is satisfied.
Σk <1.16d (n−1)
1.6 <dn / (D−d) <3.0

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