JPH0478602A - Pneumatic tire - Google Patents

Abstract

PURPOSE:To prevent fatigue failure of a reinforcing element as well as separation of a belt layer at a ply edge by constituting the belt layer out of two kinds of plies with the respective metal reinforcing elements buried inside and specifying the proportion of the overall weight of each of the reinforcing elements buried in each of the plies. CONSTITUTION:A pneumatic tire 1 has a tread part 4 and a carcass layer 8 and simultaneously, it is provided with a belt layer 14 on the outside in the radial direction of the carcass layer 8. In this case, the belt layer 14 is constituted out of laminating two layer plies of a first ply 15 and a single layer second ply 16 to each other. Additionally, a large number of reinforcing elements 20 are crossed at an angle A of fifteen to seventy-five degrees against a tire equatorial surface S in the second ply 16. Then, the overall weight of the reinforcing elements 18 buried in the first ply 15 is set within the range of 0.5 to 1.5 times the overall weight of the reinforcing elements 20 buried in the second ply 16.

Description

DETAILED DESCRIPTION OF THE INVENTION The above invention relates to a pneumatic tire in which the belt layer is constructed by laminating plies.

Conventionally, a pneumatic tire that is lightweight and has good high-speed durability has been known, such as the one described in Japanese Patent Application Laid-open No. 145108/1983.

This belt layer has a first belt layer formed by spirally winding a steel cord approximately parallel to the circumferential direction of the tire, and a belt layer that overlaps the first belt layer and has a cord angle with respect to the circumferential direction of the tire. 10-50
A second belt layer is made of a thin organic fiber cord, and the second belt layer is folded back at both ends in the width direction so as to wrap around the first belt layer.

However, in such pneumatic tires,
Since both ends in the width direction of the second belt layer in which the inclined cord is embedded are folded back, the cord is bent with a small radius of curvature at the folded-back part, and as a result,
It becomes difficult to ensure the adhesive strength between the cord and the rubber at this location. As a result, when the roller is rolling under a lateral load, the input force at the folded end is large, causing a problem in that separation occurs at the folded end.

In order to solve these problems, the present applicant proposed a pneumatic tire as described in Japanese Patent Application Laid-Open No. 2-81705. This comprises a belt layer with a single layer first strip embedded with reinforcing elements aligned in a corrugated or zigzag pattern, oriented along the tire's equator, and at an angle of 15 to 75 degrees to the tire's equatorial plane. and a single-layer second strip in which reinforcing elements are embedded in mutually parallel arrays with an inclination angle of .

However, since the reinforcing elements embedded in such pneumatic tires are wave-shaped or zigzag-shaped as mentioned above, they are repeatedly subjected to tensile and compressive strain as the pneumatic tire runs, causing their surfaces to deteriorate. In particular, a large strain occurs on the surface of the portion with the smallest radius of curvature. This poses a problem in that when the pneumatic tire is run for a long period of time, the reinforcing element breaks down due to fatigue. and,
Such fatigue failure occurs most noticeably at the ends of the belt, where the circumference of the belt during running is greatest.

SUMMARY OF THE INVENTION An object of the present invention is to provide a pneumatic tire that can prevent separation at ply ends and prevent fatigue failure of reinforcing elements.

The purpose of Rudame is to provide a carcass layer consisting of at least one carcass ply in which a large number of cords are embedded substantially perpendicular to the tire equatorial plane, a belt layer disposed radially outward of the carcass layer, A pneumatic tire comprising: a first ply in which a metal reinforcing element extending substantially parallel to the tire equatorial plane is embedded by wrapping the belt layer many times in a spiral shape with a large initial elongation; A single-layer second ply that overlaps the ply and has cut ends at both ends in the width direction, and has a large number of metal reinforcing elements embedded therein that intersect at an angle of 15 degrees to 75 degrees with respect to the tire equatorial plane. , and the total weight of the reinforcing elements embedded in the first ply is within the range of 0.5 to 1.5 times the total weight of the reinforcing elements embedded in the second ply. can do.

Here, it is preferable that the bending stiffness of the reinforcing element embedded in the first ply is equal to or less than the bending stiffness of the reinforcing element embedded in the second ply.

January In the pneumatic tire of the present invention, the second ply in which the inclined reinforcing element is embedded has cut ends at both ends in the width direction, and therefore is not folded back. , there is no risk of separation at the ply ends. In addition, since the reinforcing element embedded in the first ply extends substantially parallel to the tire's equatorial plane, the strain that occurs when the tire runs is small, and it does not cause breakage even after long-term running. This will improve durability. Furthermore, since the reinforcing element within the first ply extends substantially parallel to the tire equatorial plane as described above, the reinforcing element will not be bent even when both widthwise ends of the first ply are folded back. As a result, there is no risk of separation occurring at the ends of the first ply. Here, if the reinforcing element in the first ply is substantially parallel to the tire equatorial plane as described above, vulcanization molding may be difficult, but in this invention, the reinforcing element has a large initial elongation. Since the element is used, vulcanization molding is easily performed.

In addition, since the reinforcing element of the second ply is made of metal rather than organic fiber, there is no reduction in cornering power even when the load exceeds the normal load.

Furthermore, since the total weight of the reinforcing elements in the first ply is within the range of 0.5 to 1.5 times the total weight of the reinforcing elements in the second ply, the cornering power value can be achieved without increasing the weight. can be kept within a certain range.

Moreover, as described in claim 2, it is preferable that the bending stiffness of the reinforcing element embedded in the first ply is equal to or less than the bending stiffness of the reinforcing element embedded in the second ply. The reason for this will be explained below. That is, since there is generally a proportional relationship between the bending stiffness of the reinforcing element and the circumferential bending stiffness of the pneumatic tire, increasing the bending stiffness of the reinforcing element also increases the circumferential bending stiffness of the pneumatic tire. When the circumferential bending rigidity of a pneumatic tire increases, the belt layer becomes difficult to bend when the pneumatic tire is rolled under a load.As a result, buckling occurs and the ground contact of the pneumatic tire deteriorates. However, the steering stability, especially on wet road surfaces, deteriorates. Moreover, it is known that the bending of the ply in the circumferential direction is proportional to cos' Z, where Z is the intersection angle of the reinforcing element with the tire equatorial plane, and from this, when Z is zero, that is, when the reinforcing element is The ply extending substantially parallel to the equatorial plane is the ply with the greatest circumferential bending rigidity. Therefore, if the bending stiffness of the reinforcing elements of the first ply substantially parallel to the tire equatorial plane is greater than the bending stiffness of the reinforcing elements of the second ply,
Since the ground contact of pneumatic tires deteriorates and the steering stability decreases, the bending stiffness of the reinforcing element buried in the first ply and substantially parallel to the tire equatorial plane is reduced by reinforcing elements buried in the second ply that are slanted. It is preferable that the bending stiffness is equal to or less than the bending stiffness of the reinforcing element. Here, the bending stiffness of the reinforcing element is the product of the second moment of area E of the reinforcing element and the Young's modulus E, but since the Young's modulus E is considered to be constant, in other words, the first ply This means that the value of the moment of inertia of the reinforcing element of the second ply is less than the value of the moment of inertia of the reinforcing element of the second ply. The second moment of area (■) is defined by the number of filaments constituting the reinforcing element as n, and the diameter of each filament as d: (i=1 to n
), the distance from the center of gravity of each filament to the centroid of the cross section of the reinforcing element is e: (t・1~n), and the cross-sectional area of each filament is A, (l-1~n), then it is expressed by the following formula: be able to.

I = Qi (πd:'/64+e:2A:) Mu proverb 1 Large JL example Hereinafter, one embodiment of the present invention will be described based on the drawings.

In Figure 1.2, 1 is a pneumatic tire.
This tire 1 has a pair of bead parts 2 and these bead parts 2.
The tread includes a pair of sidewall portions 3 each extending substantially radially outward, and a cylindrical tread portion 4 extending across both sidewall portions 3. The tire 1 also includes a toroidal carcass layer 8 extending from one bead portion 2 to the other bead portion 2.
Both ends of the carcass layer 8 are rolled up around the bead ring 9 from the inside in the axial direction to the outside in the axial direction. This carcass layer 8 is composed of at least one layer of carcass ply, in this embodiment, one layer of carcass ply 11, and a large number of cords 12 that are substantially orthogonal to the tire equatorial plane S are buried in this carcass ply 11. There is.

A belt layer 14 is provided on the outside of the carcass layer 8 in the radial direction, and this belt layer 14 is constructed by overlapping two plies, a first ply 15 and a single-layer second ply 16. . In this embodiment, the first ply 15
is arranged radially outward and the second ply 16 is arranged radially inward, and the width of the first ply 15 is set to the second ply 16.
It is slightly wider than the width of the . Here, the first ply 15
It is also possible to arrange the second ply 16 on the inside in the radial direction and the second ply 16 on the outside in the radial direction, but if this is done, the cornering power will be slightly reduced as will be described later, so it is preferable to use the second ply 16 in this embodiment. Further, the width of the first ply 15 may be made slightly narrower than the width of the second ply 16, but if this is done, the restraint on both widthwise ends of the second ply 16, where the maximum circumferential convergence occurs, will be weakened. Therefore, it is preferable to use the width as in this example. Furthermore, in this embodiment, the second ply 16 has cut ends at both ends in the width direction, and as a result, both ends of the second ply 16 in the width direction are not folded back around the first ply 15. This allows the second
Separation at the ply ends of the ply 16 does not occur. Further, reinforcing elements 18 are embedded inside the first ply 15, and these reinforcing elements 18
As will be described later, by winding the tire many times in a spiral manner, the tire extends substantially parallel to the tire equatorial plane S.

As a result, the strain generated in the reinforcing element 18 when the tire 1 runs becomes smaller than that in the case where the reinforcing element is bent in a wave or zigzag shape.

Therefore, even if the tire 1 is run for a long period of time, the reinforcing element 1
8 does not lead to breakage, and the durability of the tire 1 is improved. Further, both ends of the first ply 15 in the width direction may be folded back to strongly restrain the ends of the ply as in this embodiment, but they may not be folded back like the second ply 16 described above. good. Further, the reinforcing element 18 is made of a cord formed by twisting a plurality of filaments together, and is also made of metal, for example, steel, in order to exhibit the hoop effect. Such a first ply 15 may be formed by, for example, having a small number of reinforcing elements 18 wound in a spiral shape many times (overlapping windings at both ends in the width direction), or formed by a plurality of reinforcing elements The element 18 may be constructed by winding a rubber-coated strip in a spiral shape many times.The reinforcing element 18 may also have a large initial elongation (the load acting on the reinforcing element 18 is 0.25 kgf to 50 kgf). The reinforcing element 18 has an initial elongation of, for example, about 0.4% to 1.5%.As a result, the reinforcing element 18 has a Even if the belt layer 14 extends substantially parallel to the vulcanized segment, the tire 1 can be vulcanized without any problem, that is, without waving the belt layer 14 or the like or biting into the vulcanized segment.Here, Examples of reinforcing elements having a large initial elongation as described above include, for example, strands formed by a plurality of wires twisted together, with the individual strands or cords all wound in the same direction (so-called Highly stretchable cord) or JP-A-60
- Before twisting the filaments constituting the cord into the cord, the element described in Publication No. 116504 is molded into a shape similar to the shape of the filament in the twisted cord by applying stress exceeding the elastic limit. , these filaments are then twisted and formed into cords,
can be mentioned. Here, the amount of molding given to the filament in advance (shape #i) is preferably 98% or more of the maximum diameter of the filament in the corded state.

On the other hand, a large number of reinforcing elements 20 are provided in the second ply 16.
are buried, and these reinforcing elements 20 are at an angle A of 15 to 75 degrees, in this example 25 degrees, with respect to the tire equatorial plane S.
intersect at an angle of degrees. These reinforcing elements 20 are made of, for example, a single filament or a cord made of a plurality of filaments twisted together, and are made of metal, such as steel, instead of organic fiber.

If the reinforcing element 20 is made of metal in this way, it is possible to maintain the cornering power within a practical range when a load exceeding the normal load is applied to the tire 1, as will be described later. In this case, when the load exceeds the normal load, the cornering power decreases significantly and the steering stability deteriorates. The reason is,
This is because organic fibers themselves have almost zero bending rigidity, so if organic fibers are used as reinforcing elements, the reinforcing elements will easily deform when side force is applied to the tire 1. Conversely, reinforcing elements 20 This is believed to be because when the reinforcing element 20 is made of a metal with high bending rigidity, when a side force acts on the tire 1, the reinforcing element 20 suppresses deformation of the tire 1 and prevents a decrease in cornering power. Further, a reinforcing element 18 embedded in the first ply 15
The total weight of the reinforcing element 20 embedded in the second ply 16 must be within a range of 0.5 to 1.5 times. The reason for this is that the value B obtained by dividing the total weight of the reinforcing elements 18 buried in the first ply 16 by the total weight of the reinforcing elements 20 buried in the second ply 16 is If it is less than 0.5, the cornering power will decrease by 10% or more and the steering stability will deteriorate, as will be described later.On the other hand, if it exceeds 1.5, the increase in cornering power will be saturated. This is because, despite this, only the weight increases, and the drawbacks of the increased weight become noticeable. 2
Reference numeral 5 denotes a tread rubber disposed on the outside of the belt layer 14 in the radial direction.

Next, a first test example will be explained. In this test, a conventional tire, a test tire 1.2 in which the present invention was implemented,
Comparative tires 1.2 and 1.2 were prepared.

Here, in conventional tires, the belt layer is composed of four plies, with the outermost ply in the radial direction being the first ply and the innermost ply in the radial direction being the fourth ply. A nylon cord is buried substantially parallel to the tire equatorial plane, and the widths of both the first and second plies are
In addition, a steel cord (cord type 1 x 5 x 0.23) that intersects at an angle of +23 degrees with respect to the tire equatorial plane is buried in the third ply, and its width is 165 mm. Steel cord (
In addition to burying the code type LX 5X0.23),
Its width is 175mm. In addition, the test tire 1 had a steel cord (cord type 3x4
x 0.12) and its width to 180
+nm, and a steel cord (cord type 1x 5xO, 23) that intersects at an angle of 25 degrees with respect to the tire equatorial plane is buried in the second ply placed on the inside in the radial direction, and its width is 170 mm. Further value B
1.0, and the test tire 2 has the arrangement of the first and second plies of the test tire 1 reversed, that is, the first ply is arranged radially inward and the second ply is radially outward. However, the rest of the tire is the same as Test Tire 1. moreover,
Comparative tire 1 had a steel cord (cord type 3
4x 0.12) with a width of 180mm, and an aramid organic fiber cord that intersects at an angle of 25 degrees to the tire equatorial plane in the second ply on the inside in the radial direction. This tire was buried, had a width of 170 mm, and had the above-mentioned value B of 9.3, and was the same as Comparative Tire 2.
The arrangement of the first and second plies of the comparative tire 1 is reversed,
That is, the first ply is arranged on the inside in the radial direction, and the second ply is arranged on the outside in the radial direction, and the rest is the same as the comparative tire 1. Here, the size of each of these tires is 205/80
It was R15. Next, 2. Okg
After filling with an internal pressure of f/cm2, 200 kg gf,
While applying loads of 520 kgf (regular load) and 800 kgf, the test drum was moved at a speed of 50 km/h.
The cornering power was measured at a slip angle of 1 degree. The results are shown in FIG. 3 with the conventional tire as index 100. In Figure 3, the white circle is the test tire l.
, the black circle is the test tire 2, the white triangle is the comparison tire 1, and the black triangle is the comparison tire 2.

As is clear from Fig. 3, the cords that are inclined with respect to the tire equatorial plane are made of organic fibers (here, aranimide fibers).
If the tire is constructed from the above, the cornering power decreases, especially when the load acting on the tire exceeds the normal load, and the cornering power decreases significantly, making it impossible to put it into practical use.

Next, a second test example will be explained. In this test, a comparative tire 3 structurally similar to the test tire 1 was used.
．． 4.5.6 and test tires 3, 4, and 5 were prepared. Here, for these comparisons, the test tires were made with the steel cords of the second ply of the same cord type and the same number of strands, and the steel cords of the first ply of the same cord type with different numbers of strands of the first ply. The value B obtained by dividing the total weight of the cords by the total weight of the cords of the second ply is changed. That is, the value B obtained by dividing the total weight of the cords of the first ply by the total weight of the cords of the second ply is 0.25 for comparative tire 3, 0.5 for test tire 3, and 1.5 for test tire 4. 0, 1.5 for test tire 5, comparative tire 4
2.0 for Comparative Tire 5, 3.0 for Comparative Tire 6, and 4.0 for Comparative Tire 6. Next, as is clear from FIG. 4, which shows the cornering power of each tire as described above, if the value B is less than 0.5, the cornering power is below a practically allowable value (90). On the other hand, if the value B exceeds 1.5, the increase in cornering power will become saturated and only the disadvantage of increased weight will increase, and in reality it can only be used as follows:
The value B is only within the range of 0.5 to 1.5.

Next, a third test example will be explained. For this test,
Comparative Tire 7, Comparative Tire 1, and Test Tire 4 were prepared. Here, the comparative tire 7 has steel cords (cord types 1x 4x
0.23) and a steel cord (cord type LX 5 2. Okgf/c+n
After filling the internal pressure of No. 2, the vehicle was run on the drum at a speed of 50 km/h while applying a regular load (520 kgf), and the cornering power at a slip angle of 1 degree was measured. When the results are shown in index display, for comparison tire 7,
It was 100, but it decreased to 65 for comparison tire 1,
On the other hand, the test tire 4 had improved to 105. next,
A total of 40,000 km at a speed of 60 km/h while applying a regular load to each tire and giving a slip angle of 2 degrees on the drum.
The vehicle was run, and the number of broken cords was counted at the end of the run. The results show that Comparative Tire 7 had 10 broken tires, while both Comparative Tire 1 and Test Tire 4 had 1 broken tire.
The book wasn't even bent.

Next, a fourth test example will be explained. For this test,
Test tire 1 and comparative tire 8 were prepared. here,
Comparison tire 8 has the width of the first and second plies compared to test tire 1.
This tire is the same as , and also uses aramid fiber for the reinforcing element of the second ply. Next, a durable drum condition similar to the third test example was used.
' - In this case, the vehicle was run at a speed of 60 km/h while giving a slip angle of 2 degrees. The results show that test tire 1 had no abnormalities and
Although Comparative Tire 8 completed 32,000 km, it broke down due to separation at the end of the turn.

Next, a fifth test example will be explained. For this test,
Comparative tire 9 and test tire 6.7.8, which are structurally similar to the test tire, were prepared. Here, for these comparisons, the test tires were made by using the same type of steel cord in the second ply and the same number of inserted steel cords, and by making the types of cords in the first ply different from each other. The value C obtained by dividing the moment by the moment of inertia of the reinforcing element of the second ply was made different.

That is, the above value C is 0.38 (LX 5X0.18 code is used for the first ply) for test tire 6, and 0.64 (LX 3X0.30 code is used for the first ply) for test tire 7.
) 2, 1.00 for test tire 8 (Use the same 1x 5x0.23 as the second ply'': I for the first ply)
, 1.40 for comparison tire 9 (LX in the first ply)
5X0.25). Here, the reinforcing element of the second ply is 0th order using 1 x 5 x 0.23, and each tire is filled with the normal internal pressure and loaded with the normal load, giving a slip angle of 8 degrees. The tires were run at a speed of 5 km/h, and the amount of buckling on the inner surface of each tire at this time was measured using an inner surface laser measurement method. The results are shown in FIG. 5, where the test tire 8 whose values of C are i and oo is shown as an index of 100. As is clear from FIG. 5, when the value C exceeds 1.00, the amount of buckling increases, and as a result, the lifting of the tread increases, that is, the ground contact performance deteriorates.

Therefore, the value C that can actually be used is 1.0.
Only when the value is 0 or less.

l1 Yutaka 11 As explained above, according to the present invention, it is possible to prevent separation at the ends of the ply, and it is also possible to prevent fatigue failure of the reinforcing element embedded in the belt layer.

[Brief explanation of drawings]

FIG. 1 is a meridian cross-sectional view showing one embodiment of the present invention, and FIG.
The figure is a partially broken view taken along the line X-X in Figure 1, Figure 3 is a graph showing the relationship between load and cornering power, and Figure 4 is a graph showing the relationship between load and cornering power.
The figure is a graph showing the relationship between value B and cornering power,
FIG. 5 is a graph showing the relationship between the value C and the amount of buckling. l...Pneumatic tire 8...Carcass layer 11.
... Carcass ply 12 ... Cord 14 ... Belt layer 15 ... 11 ply 16 ... Second ply 18 ... Reinforcement element 20 ... Reinforcement element S ... Tire equatorial plane

Claims (2)

[Claims] (1) A pneumatic tire comprising a carcass layer consisting of at least one carcass ply in which a large number of cords are embedded almost perpendicular to the tire equatorial plane, and a belt layer disposed radially outside the carcass layer. The belt layer is wound spirally many times with a large initial elongation to form a first ply in which a metal reinforcing element extending substantially parallel to the tire equatorial plane is buried, and a metal reinforcing element that overlaps the first ply and extends in the width direction. a single-layer second ply having cut ends at both ends and in which a large number of metal reinforcing elements intersecting at an angle of 15 degrees to 75 degrees with respect to the tire equatorial plane are embedded; A pneumatic tire characterized in that the total weight of the reinforcing elements embedded in the first ply is within a range of 0.5 to 1.5 times the total weight of the reinforcing elements embedded in the second ply. (2) The pneumatic tire according to claim 1, wherein the bending stiffness of the reinforcing element embedded in the first ply is less than or equal to the bending stiffness of the reinforcing element embedded in the second ply.