JPS61275005A - Pneumatic radial-ply tire - Google Patents

Abstract

PURPOSE:To improve durability at high speed, by constituting a belt part with a main belt layer to be made up of two metallic cord layers in cross orientation and an auxiliary belt layer constituted of an organic fiber cord paralleled in a tire circumferential direction and strengthening the central zone, in case of a super-flat tire, bearing the above caption, for a passenger car. CONSTITUTION:A belt par 6 is constituted of both main and auxiliary belt layers 10 and 11, and the main belt layer 10, being the same width as tread width W, is crossed at an angle of about 22 deg. with a tire circumferential direction, and constituted of a rubber covering metallic cord layer layer of minimum two layers crossed with each other. And, the auxiliary belt layer 11, being the same width as the main belt layer 10, is constituted of a minimum one layer of the organic fiber cord 12 set up in the tire circumferential direction, and strength of the central zone 11a is set to be larger than that of an outer zone 11b. With this constitution, high-speed durable performance is improved.

Description

Detailed Description of the Invention (Industrial Field of Application) The present invention relates to high-speed durability of pneumatic radial tires, for example, radial tires for passenger cars, particularly ultra-flat pneumatic radial tires with an aspect ratio of 55% to 35%. Concerning performance improvements.

(Prior Art) As a conventional flat pneumatic radial tire, for example, the structure described below is usually used, from a flat tire with a large aspect ratio to a so-called ultra-flat tire with a small aspect ratio. A carcass part is formed between a pair of bead parts of the tire, and the carcass part has an angle of 9 in the circumferential direction of the tire.
It consists of a carcass cord layer consisting of one or two layers of organic fiber cords (for example, nylon cords) arranged at an angle of 0 degrees. A belt portion is formed between the carcass portion and a trend portion forming the tread surface of the tire on the radial outside of the carcass portion, and the belt portion includes a main belt layer and a sub-belt layer disposed on the radial outside of the main belt layer. It consists of The main belt layer consists of two metal cord layers arranged at an angle of 15 to 25 degrees with respect to the circumferential direction of the tire and intersecting each other. The sub-belt layer covers almost the entire width of the metal cord layer and is made of a layer of heat-shrinkable organic fiber cords (for example, nylon cords) arranged approximately parallel to the tire circumferential direction. The organic fiber cord layer suppresses deformation of the tread and metal belt layer due to centrifugal force during tire rotation, thereby maintaining high-speed durability.

Conventionally, the organic fiber cord layer generally strengthens the outer region outside the central region more than the central region of the sub-belt layer near the tire equatorial plane, increasing the stiffness of the belt section in the outer region and creating the so-called tag effect. is increased, and deformation caused by centrifugal force near the shoulder of the outer region is suppressed.

(Problem to be Solved by the Invention) However, in conventional flat pneumatic tires, the central area of the tread near the tire equatorial plane of the tread wears faster than the outer area outside the central area. , there is a problem that so-called uneven wear occurs. In addition, during load transfer, heat generation inside the tread section in the central area is large, causing peeling failures in which the trend rubber decomposes, and failures such as rib chipping or block chipping, resulting in a reduction in high-speed durability performance. .

Therefore, the present invention provides a pneumatic radial tire with excellent high-speed durability performance that does not cause uneven wear in the central area of the tread, and does not cause peeling failures, rib chipping, block chipping, etc. The purpose is to

(Means for solving the problems) The pneumatic radial tire according to the present invention includes a tread portion,
Air having a pair of sidewall parts, a pair of bead parts, a carcass part made of at least one carcass layer arranged between both the bead parts, and a belt part arranged between the carcass part and the tread part. In the radial tire, the belt portion includes a main belt layer and a sub-belt layer disposed radially outward of the main belt layer,
The main belt layer intersects with the circumferential direction of the tire and consists of at least two metal cord layers intersecting each other,
The sub-belt layer has approximately the same width as the main belt layer, and has at least one cord layer made of organic fiber cords arranged approximately in the circumferential direction of the tire, and the sub-belt layer is continuous to the central area and the outside thereof. and an outer area that
It is characterized in that the intensity of the central area is greater than the intensity of the outer areas.

Here, the "central area" refers to the central part of the tire cross-section that includes the tire's rotational axis, and is the central part of the tire cross-section that sandwiches the tire's equatorial plane, and the "outer area" refers to the tire cross-section that includes the tire's rotational axis. In the middle of the day, it refers to the outer part that is continuous to the outside of the central area.

Moreover, "strength" refers to the sum of the breaking strength of the cords in the cord direction per unit width (25 m here, the same applies hereinafter) in the direction perpendicular to the cord direction of the sub-belt layer, and can be expressed by the following formula.

Strength = Breaking strength of one cord (kg) Number of cords per 25mm For the reasons stated.

In conventional ultra-flat, high-performance pneumatic radial tires with an aspect ratio of 55% to 35%, the contact area of the tread portion of the tire, which transfers load at high speed, is determined by the contact length in the circumferential direction of the tire and the cross-sectional direction of the tire. The ground contact width is small, and the ground contact area is small. Also, the ground pressure in the central area is high and the ground pressure in the outer areas is low.

For this reason, the wear in the central area of the contact area is rapid, and the internal heat generation in the central area is large.Due to internal heat generation, the trend rubber decomposes and softens, causing peeling failures, and failures such as rib chipping or block chipping. In addition, vehicles equipped with high-performance pneumatic radial tires are often used in a load range smaller than the JIS standard load, and the contact area of the tread tends to be in the center area.Ultra-flat tires In this case, the central area of the trend part is thicker and has a larger mass than the outer area, especially the shoulder part. Therefore, as shown by arrow A in Fig. Some have larger deformed growth.

Therefore, consideration was given to suppressing deformation growth in the central area of the tread, lowering ground pressure in the central area, and reducing internal heat generation.

Based on the above, as a result of various studies, it has been found that by increasing the strength of the central region of the sub-belt layer, it is possible to suppress deformation growth in the central region (see arrow B in FIG. 2).

(Function) When an ultra-flat, high-performance pneumatic radial tire undergoes load transfer, the central area of the tread portion deforms and grows due to centrifugal force, and tends to protrude. The strength of the central region of the secondary belt layer of the present invention is greater than the strength of the outer regions.

Therefore, there is no deformation growth or protrusion in the central area, and the contact width of the tread portion is increased, resulting in a larger contact area.
Ground pressure decreases. Therefore, the central area wears out quickly (
Moreover, since internal heat generation is small, failures such as rib defects and block defects do not occur.

The strength of the central zone of the secondary belt layer is greater than the strength of the outer zone, preferably 1.2 to 1.6 times. The strength of the sub-belt layer can be increased by increasing the number of cords per unit width by using cords made of the same material in the central region, or by increasing the number of overlapping cord layers. Alternatively, the material of the constituting code layer may be changed.

Further, the width W0 of the central area of the sub-belt layer is preferably 40 to 75%, preferably 50 to 75%, of the width W of the trend portion. If it is less than 40%, there is no effect of suppressing the protrusion of the central area, and if it exceeds 75%, the protrusion of the outer area is suppressed, resulting in a change in ground contact width and a difference in ground pressure between the central area and the outer area. occurs, which is undesirable.

Hereinafter, one embodiment of a pneumatic radial tire according to the present invention will be described based on the drawings.

(Example) FIG. 1 is a diagram showing an example of a pneumatic radial tire according to the present invention, and is a sectional view including the tire rotation axis of the pneumatic radial tire. Tire size is 225150R
16. The air pressure used is 3.1 m/cII+2, the rim used is 8J-16, and the aspect ratio is 50%.

In FIG. 1, l is a pneumatic radial tire,
The pneumatic radial tire 1 includes a tread portion 2, a pair of sidewall portions 3, a pair of bead portions 4, and at least one or more (two layers in this embodiment) carcass layer disposed between the two bead portions 4 (this embodiment). In the example, it has a carcass part 5 made of a polyester cord of 1500 d/2, the cord angle being approximately 90 degrees with respect to the tire circumferential direction, and a belt part 6 disposed between the carcass part 5 and the tread part 2. . Components other than the belt portion 6 are the same as a normal pneumatic radial tire, and detailed description thereof will be omitted.

The belt portion 6 is composed of a main belt layer 10 and a sub belt layer 11 disposed radially outward of the main belt layer 10. The main belt layer 10 has approximately the same width as the trend width W, intersects the circumferential direction of the tire at an angle of 22 degrees, is arranged to intersect with each other, and has at least two layers (in this example, two layers). ) rubber-coated metal cord layer (steel cord IX5 is used in this example). The sub belt layer 11 has approximately the same width as the main belt layer IO, and is made of organic fiber cords 1 arranged approximately in the circumferential direction of the tire (in this example, at an angle of 0 degrees with respect to the circumferential direction).
2 (nylon cord 1260d/2 in this example)
It has at least one code layer (two layers in this embodiment). The sub-belt layer 11 includes a central region 11a with a width V/+t-120wm including the equatorial plane E of the tire, and an outer region 11 with a width wllb continuing from the central region 11a to the outside thereof.
It is composed of b. Central area 1 of sub-belt layer 11
1a strength (709 kg/25fl in this example)
is greater than the strength of the outer region 11b of the secondary belt layer 11 (540 kg/25 tm in this example).

Also, the thickness h2 of the tread portion 2 is 1 at the center of the tread portion.
0 mm, and the thickness h2 gradually decreases from the central region 11a of the sub-belt layer 11 to the outer region llb.

(Effects of the Invention) The following two types of tires were prepared to confirm the effects of the present invention.

The tire side was 225150R16, and a comparative test was conducted on the tire shown in the above example and a comparative example (conventional tire). The sub-belt layer of the conventional tire only used the same strength of 540 kg for the central and outer areas of the sub-belt layer, and the other configurations were the same as in the example, and the same method as in the example was used. manufactured.

Comparative tests were conducted on wear resistance performance, ground contact area during load transfer, and the occurrence of rib chipping and block chipping in the trend section, and the test results are shown in the table below. The test results are shown as an index with the comparative example as 100, and the larger the index, the better the result.

(This page, blank space below) Here, the wear resistance performance of two types of tires is Porsche 911.
Installed on turbo cars (tire pressure is 2.0 to 3.1 k)
The amount of wear on the tread was compared by actually driving on expressways and general roads.The ground contact area was measured at a load of 550 kg and an air pressure of 3°1 kg/cm.
The ground contact area of the tread was measured at 485 kg of load and 3.1 kg/ar of air pressure.
m'', the speed was increased every 10 km/h from a running speed of 250 km/h using a normal drum testing machine,
We conducted a high-speed durability test that lasted until failure occurred, resulting in rib chipping,
The state of occurrence of block chipping or failure and the speed at that time were measured.

As shown in the previous table, in the example of the present invention, the ground contact area of the tread portion during load transfer is almost the same as that of the comparative example (conventional tire), suggesting that the distribution of ground pressure is uniform. , the wear resistance performance has increased significantly. In addition, in the high-speed durability test, there were almost no rib chips or block chips on the tread in the example, which was a significant improvement compared to the comparative example (conventional tire), which had a few chipped ribs and blocks. Conventional tires have a failure time of 300 km
/h occurs at 2Qlua in the example, compared to 2Qlua
/h also has no failures even when running at high speeds, and high-speed performance has been greatly improved.

As explained above, according to the present invention, even when running at high speed under a load, the occurrence of rib chipping and block chipping in the tread portion is significantly reduced, and high-speed durability performance is significantly improved. In addition, the ground contact area during load transfer increases,
Ground pressure is reduced and wear resistance is significantly improved.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing an embodiment of a pneumatic radial tire according to the present invention. FIG. 2 is a diagram for explaining the present invention in detail. 1...Pneumatic radial tire, 2...
・Trend part, 3... Sidewall part, 4... Bead part, 5... Carcass part, 6... Belt part, 10... ...Main belt layer, 11...Sub-belt layer, 11a...Central area of sub-belt layer, 11b...
...outer area, 12...organic fiber cord.

Claims (1)

[Claims] A tread portion, a pair of sidewall portions, a pair of bead portions, a carcass portion comprising at least one carcass layer disposed between the bead portions, and a belt portion disposed between the carcass portion and the tread portion. In a pneumatic radial tire, the belt portion includes a main belt layer and a sub-belt layer disposed radially outward of the main belt layer, the main belt layer intersects with the circumferential direction of the tire, and Consisting of at least two metal cord layers that intersect with each other, the sub belt layer having approximately the same width as the main belt layer, and at least one cord layer consisting of organic fiber cords arranged approximately in the circumferential direction of the tire. and a pneumatic radial tire characterized in that the sub-belt layer comprises a central region and an outer region continuous to the outside thereof, and the strength of the central region is greater than the strength of the outer region.