JP5680988B2 - Pneumatic radial tire - Google Patents

Description

  The present invention relates to a belt reinforcing layer formed of one or more types of reinforcing elements extending along the tire equator line on the outer side in the tire radial direction of a carcass extending in a toroidal shape between a pair of bead portions, and each belt layer A heavy load suitable for use in pneumatic radial tires, in particular construction vehicles, etc., in which two or more crossing belt layers formed by extending cords in a direction crossing each other are sequentially arranged from the inner peripheral side. In particular, the present invention proposes a technique for effectively suppressing the separation of the belt reinforcing layer from the cross belt layer and greatly improving the durability performance of the belt reinforcing layer itself.

  In this type of pneumatic radial tire, in which a belt reinforcing layer composed of reinforcing elements extending along the tire equator line is arranged outside the carcass tire radially inside the crossing belt layer inside the tire radial direction, Due to the difference in the amount of elongation in the tire circumferential direction between the belt reinforcing layer and the crossing belt layer adjacent to the outer peripheral side when the internal pressure increases due to the rolling load of the tire when filling the air pressure, the belt reinforcing layer It has been confirmed that separation from the crossing belt layer occurs at the side edge portion of the belt.

  In other words, in the crossing belt layer, each belt cord extends while being inclined with respect to the tire equator line, and under the action of the circumferential tensile force, it is easy to stretch and deform in the circumferential direction. Since the reinforcing element of the belt reinforcing layer extends parallel to the tire equator line, it is difficult to stretch and deform even when the tire air pressure increases. This is due to the fact that it is greatly stretched in the tire circumferential direction as compared with the belt reinforcing layer adjacent to the circumferential side.

  By the way, the difference in the circumferential extension amount becomes more conspicuous toward the outer side in the tire width direction, and at the side edge position of the belt reinforcing layer, the interlayer rubber between the crossing belt layer and the belt reinforcing layer has a circumferential direction. Since a large circumferential shear strain is generated due to the difference in the amount of elongation, inter-layer separation tends to occur particularly at the side edge position of the belt reinforcing layer.

  Here, in recent years, pneumatic tires tend to increase flatness under the demand for higher speeds and lower floors of vehicles, and in the case of pneumatic tires with increased flatness, the diameter growth when the tires are filled with air pressure As the amount increases, the amount of expansion of the belt reinforcing layer increases, so that the allowable expansion amount in the circumferential direction of the reinforcing element of the belt reinforcing layer extending parallel to the tire equator line when the tire rolls is increased. As a result, there is a greater difference in the amount of elongation between the belt reinforcing layer and the crossing belt layer on the outer circumference side of the tire when rolling the tire. Since the circumferential shear strain generated in the interlayer rubber further increases, the separation between the belt reinforcing layer and the crossing belt layer becomes a more serious problem.

In this regard, in recent years, a required rubber thickness is secured between the belt reinforcing layer at the belt side edge position and the crossing belt layer adjacent to the outer peripheral side of the belt reinforcing layer, and a circumferential shear force is provided by the interlayer rubber. For the purpose of reducing and preventing the occurrence of interlayer separation, for example, in Patent Document 1, “the belt cord crossing zone width of two or more belt layers is in the range of 65 to 90% of the tire width, belt reinforcing layer The maximum width of the tire is in a range of 60 to 85% of the tire width, and the belt has a radius (R ₀ ) from the tire axis on the tire equator line and the belt side when the tire is filled with normal internal pressure. the difference between the radius (R ₁₎ at the edges the position of the (R 0 _{-R 1),} the belt radius ratio pneumatic radial tire "comprising as 0.06 or less have been proposed for the belt half width, the pneumatic radial tire Then While ensuring good wear resistance of the tread surface, it has to be able to effectively improve the belt durability. "

International Publication No. 2008/102667 Pamphlet

  By the way, in a pneumatic radial tire having a belt reinforcing layer, in addition to the above-described problem of interlayer separation, the reinforcing element of the belt reinforcing layer causes an amount of expansion deformation in the tire circumferential direction in comparison with the load rolling of the tire. The reinforcing element of the belt reinforcing layer is dragged by the crossing belt layer positioned adjacent to the outer peripheral side of the belt, particularly when receiving a large tensile force in the tread circumferential direction at the side edge position of the belt reinforcing layer. Has also been confirmed to break.

  Regarding the delamination and breakage of the reinforcing element, the thickness of the interlayer rubber between the belt reinforcing layer and the crossing belt layer of the conventional pneumatic radial tire described above sufficiently absorbs the circumferential deformation of the crossing belt layer. Therefore, it was difficult to more effectively prevent peeling of the belt reinforcing layer and breakage of the reinforcing element.

  On the other hand, when the thickness of the rubber is made thicker than that of the prior art while being interposed between the belt reinforcing layer and the crossing belt layer adjacent to the outer peripheral side at the side edge portion of the belt reinforcing layer Although it is possible to prevent the reinforcing elements of the belt reinforcing layer from being dragged and deformed by the cross belt layer and receiving a large tensile force, the rubber volume between these two layers increases. As a result, the amount of heat generated in the belt installation area increases due to expansion / contraction deformation of the crossing belt layer and the belt reinforcing layer caused by the load applied to the tire, and the thermal deterioration is forced to progress. Therefore, further improvement in the durability performance of the belt cannot be expected.

  In addition, belt failures such as separation of the belt reinforcement layer from the cross belt layer and breakage of the reinforcement element of the belt reinforcement layer, which are particularly serious at the side edge position of the belt reinforcement layer, are all caused when the tire is filled with internal pressure. If the carcass line of the side part of the tire is different, it is confirmed that the reinforcing element located on the side edge of the belt reinforcing layer is filled with the internal pressure. However, in the conventional pneumatic radial tire, the durability of the belt may not be sufficiently improved depending on the selection of the carcass line.

  An object of the present invention is to solve such problems of the prior art, and the object of the invention is to provide a belt reinforcing layer regardless of the selection of the carcass line of the side portion of the tire. A pneumatic radial tire that effectively suppresses the occurrence of interlayer separation at the side edge position of the belt and sufficiently prevents the breakage of the reinforcing element located at the side edge of the belt reinforcing layer, thereby greatly improving the durability of the belt. Is to provide.

  The inventor pays attention to the fact that the tensile elastic modulus of the reinforcing element located at the side edge of the belt reinforcing layer increases by filling the tire with air pressure. The cause of any failure of the breakage of the reinforcing element is that the reinforcing element of the belt reinforcing layer is twisted with a plurality of steel filaments having a characteristic showing the relationship of the tensile elastic modulus to the elongation strain in FIG. This reinforcing element located on the side edge of the belt reinforcing layer is greatly stretched by the tire diameter growth when the tire is filled with air pressure. As a result, the tensile elastic modulus of the reinforcing element is considerably increased. The knowledge that it is in the point is obtained.

  From this, the inventor aims to suppress an increase in the amount of expansion of the reinforcing element at the side edge portion of the belt reinforcing layer, which is the location where the failure occurs, when the tire diameter grows due to air pressure filling. The reinforcing element at the side edge portion of the belt reinforcing layer is a twisted cord of steel filament, and the reinforcing element at the side edge portion of the belt reinforcing layer is shown in FIG. It has been found that any of the above failures can be prevented by disposing up to a position outside the width direction in which the diameter growth rate during filling is small.

Based on the above knowledge, the pneumatic radial tire according to the present application has one or more types of reinforcement extending along the tire equator line on the outer side in the tire radial direction of the carcass extending in a toroidal shape between the pair of bead portions. A pneumatic radial tire in which a belt reinforcing layer composed of elements and two or more crossing belt layers formed by extending respective belt layer cords in a direction crossing each other are sequentially disposed from the inner peripheral side. In the above, at least one type of reinforcing element of the belt reinforcing layer is a high elongation cord or WAVY cord having a large initial elongation formed by twisting a plurality of steel filaments, and the reinforcing element has a tensile elastic modulus of 10 at break. %, When the tensile modulus of elasticity of the reinforcing element is%, the elongation percentage of the reinforcing element is A%. From a position where the tire size growth rate due to the filling of the pressure is A%, it is made by arranging the extent of widthwise outer.

  Here, “regular internal pressure” is the air pressure defined by each standard for each tire size. If it is JATMA, it is the maximum air pressure. If the value is ETRTO, it shall be "INFLATION PRESSURE".

  According to the pneumatic radial tire of the present invention, the reinforcing element of the belt reinforcing layer is formed by twisting a plurality of steel filaments, and the reinforcing element has a tensile modulus that is sufficiently smaller than the tensile modulus at break. That is, when the tensile modulus of elasticity is 10% of the tensile modulus of elasticity at break, the elongation rate of the reinforcing element is A%, and the reinforcing element is cross-sectioned in the tire width direction and is filled with normal internal pressure. Since it is arranged from the position where the diameter growth rate is A% to the outer side in the width direction, depending on the diameter growth of the tire during the air pressure filling, the side edge position of the belt reinforcing layer that may cause breakage failure or the like The expansion rate of the reinforcing element at 10% of the tensile elastic modulus at break does not exceed the elongation rate A%, and the tension of the reinforcing element at the side edge position after filling with air pressure Low elastic modulus It will be maintained.

Thus, even if the cross belt layer adjacent to the outer peripheral side of the belt reinforcing layer is greatly stretched and deformed in the circumferential direction due to an increase in internal pressure accompanying the load rolling of the tire, a belt having a low tensile elastic modulus in the circumferential direction. Since the side edge portion of the reinforcing layer can be extended and deformed following the deformation of the cross belt layer, the circumferential shear strain generated between these layers is reduced, and the side edge of the belt reinforcing layer is reduced. Interlayer separation of positions can be effectively suppressed.
Moreover, since the permissible extension amount in the circumferential direction still remains after the air pressure is filled in the reinforcing element of the belt reinforcing layer, it is possible to effectively prevent the reinforcing element at the side edge portion from being broken. it can.

  By the way, depending on the selection of the carcass line on the side portion of the tire, the amount of expansion of the reinforcing element located on the side edge of the belt reinforcing layer when the tire is filled with air pressure varies. The tire specifies the side edge position of the belt reinforcing layer based on the tire diameter growth rate by filling with the normal internal pressure, so that any of the belt reinforcing layer is used regardless of the carcass line on the side of the tire. Can also be prevented.

It is a graph which shows the relationship of the tensile elasticity modulus with respect to the elongation strain of the reinforcement element of a belt reinforcement layer. It is a figure which shows the relationship between the width direction cross section of a tire half part, the extension aspect of each code | cord | chord, and the diameter growth rate at the time of the air pressure filling to a tire. It is a partial section perspective view showing an embodiment of this invention. It is a figure which shows the relationship of the radial direction growth rate at the time of the pneumatic direction filling to the tire of the pneumatic radial tire of FIG. It is a graph which shows the relationship of the tensile elasticity modulus with respect to the elongation strain of the reinforcement element of a belt reinforcement layer. It is a figure which shows the relationship between the width direction cross section of the pneumatic radial tire of other embodiment, the extension aspect of each code | cord | chord, and the diameter growth rate at the time of the air pressure filling to a tire. It is a width direction cross-sectional half view which shows the carcass line of the side part of the tire used in the Example.

Embodiments of a pneumatic radial tire according to the present invention will be described below with reference to the drawings.
FIG. 3 is a cross-sectional perspective view showing a half portion of the pneumatic radial tire 1 with a part thereof removed by breaking.

  The illustrated pneumatic radial tire 1 is a belt reinforcement composed of a carcass 3 extending in a toroidal shape between a pair of bead portions 2 and one or more kinds of reinforcing elements 4 disposed on the outer side in the tire radial direction of the carcass 3. It comprises a layer 5 and two or more cross belt layers 6, 7 in the figure.

  Here, the carcass 3 can be composed of, for example, one or more carcass plies obtained by extending steel cords, organic fiber cords, and the like in the radial direction. The radial carcass 3 is configured such that each side portion is folded around the pair of bead cores 8 outward in the tire width direction and extends from the bead portion 2 to the tread portion 10 through the sidewall portion 9.

As shown in FIGS. 3 and 4, the belt reinforcing layer 5 has a reinforcing element 4 as shown in FIGS. It extends along the tire equator line C.
This reinforcing element 4 is formed by twisting together a plurality of steel filaments. For example, a high elongation cord or a twist cord having a large initial elongation is subjected to brazing processing such as a zigzag shape or a wave shape. A so-called WAVY code can be formed.
More specifically, the twisted structure of the reinforcing element 4 can be 3 + 9 + 15 × 0.23, for example.

Also, here, the two intersecting belt layers 6 and 7 on the outer side in the tire radial direction of the belt reinforcing layer 5 respectively extend in directions opposite to each other with respect to the tire equatorial plane and cross each other. Each of the belt layer cords 11 and 12 extends.
In this embodiment, the belt has a two-layer structure of crossing belt layers 6 and 7, but may have a laminated structure including three or more belt layers.

  As described above, in the pneumatic radial tire 1 in which the belt reinforcing layer 5 is disposed between the carcass 3 and the crossing belt layer 6, when the tire is filled with air pressure or when the internal pressure increases due to tire rolling, Due to the difference in the amount of elongation in the circumferential direction between the belt reinforcing layer 5 and the crossing belt layer 6 adjacent to the outer peripheral side thereof, the crossing belt of the belt reinforcing layer 5 particularly at the side edge portion of the belt reinforcing layer 5 Failures such as separation from the layer 6 and breakage of the reinforcing element 4 of the belt reinforcing layer 5 may occur.

Therefore, in the pneumatic radial tire 1 of the present invention, at least one type of reinforcing element 4 of the belt reinforcing layer 5 is formed by twisting a plurality of steel filaments, and as shown in FIG. The elongation percentage of the reinforcing element 4 when the tensile elastic modulus E2 is 10% of the tensile elastic modulus E1 at the time of fracture is A%, and FIG. 4 shows the belt reinforcing layer reinforcing element at the position in the tire width direction. As shown by the relationship of the diameter growth rate when the tire is filled with air pressure, the reinforcing element 4 is arranged in the width direction outer side from the position where the diameter growth rate of the tire 1 by filling with the normal internal pressure becomes A% in the cross section in the tire width direction. It arrange | positions to the range of.
Preferably, the arrangement width of the belt reinforcing layer 5 is 75% or more with respect to the maximum tire width.

  3 and 4, the belt reinforcing layer 5 is composed of one type of reinforcing element. However, the belt reinforcing layer 5 may be composed of two or more types of reinforcing elements 4. 6, the reinforcing element 4a of the outer portion in the tire width direction of the belt reinforcing layer 5 including a range on the outer side in the width direction from the position where the diameter growth rate of the tire 1 due to filling of the normal internal pressure becomes A%, The other methods of twisting the steel filament can be made different from those of the reinforcing element 4b at the inner portion in the width direction.

Next, a pneumatic radial tire according to the present invention was prototyped and its performance was evaluated, which will be described below.
The size of the test tire was 435 / 45R22.5 for both the example tire and the conventional tire.

Each of the example tires 1 to 4 has the structure shown in FIGS. 3 and 4. The width of the belt reinforcing layer 5 is set to 370 mm with respect to the tire width of 435 mm, and the reinforcing element 4 of the belt reinforcing layer 5 is used. As, a cord having a tensile elastic modulus at break of 140 GPa was used.
And in order to verify the difference in the durability performance of the belt reinforcement layer 5 by selection of the carcass line of the side part 9 of a tire, Example tires 1-4 are either one of the carcass lines A or B shown in FIG. Further, the thickness of the interlayer rubber between the belt reinforcing layer 5 and the crossing belt layer 6 is different from each other.
Table 1 shows these configurations of Example Tires 1 to 4.

The conventional tires 1 to 4 have the same structure as that of the tires 1 to 4 except that the width of the belt reinforcing layer 5 is 300 mm. In addition, the thickness of the interlayer rubber between the belt reinforcing layer 5 and the crossing belt layer 6 is different from each other.
These configurations of the conventional tires 1 to 4 are also shown in Table 1.

(Evaluation method)
Each of these test tires was assembled on a 14.00 × 22.5 rim and tested under the action of an internal pressure of 900 kPa. The results are shown in Table 2.

Here, the diameter growth rate due to internal pressure filling was calculated from the difference between the tire radius when filling the air pressure and the tire radius when removing the internal pressure at the side edge position of the belt reinforcement layer. It is.
Interlaminar shear strain is a static load applied to each test tire at a load of 50 kN. At that time, the circumferential shear strain generated between the belt reinforcing layer and the crossing belt layer adjacent to the outer periphery thereof is measured. Then, evaluation was made with an index value using the conventional tire 1 as a control. In addition, this interlaminar shear strain represents that durability performance is so high that a numerical value is small.

  Further, the internal temperature means that the tires run on a drum at a speed of 60 km / h with a load of 50 kN applied to each test tire, and the tires measured at the position where the belt reinforcing layer was disposed at that time. The internal temperature was evaluated by an index value using the conventional tire 1 as a control. The lower the numerical value, the lower the internal temperature, and the higher the heat generation durability performance.

  Furthermore, the interlayer separation durability performance is determined by making each of the test tires run at a speed of 65 km / h on the drum under the action of a load of 50 kN, and the distance traveled until the failure of the tire occurs. The index value was evaluated as a control. The larger the value, the more difficult the interlayer separation occurs, and the higher the durability against interlayer separation.

The maximum tensile force is an index based on the conventional tire 1 with the maximum value of the tensile force acting on the reinforcing element located on the side edge of the belt reinforcing layer when a load of 50 kN is applied to each test tire. The value is evaluated, and the smaller the numerical value, the smaller the maximum tensile force that acts.
In addition, here, the durability against breakage refers to a belt reinforcement that breaks after running 10,000 km by running the tire on a drum at a speed of 65 km / h with a load of 65 kN applied to each test tire. The number of reinforcing elements in the layer is evaluated by an index value based on the conventional tire 1. In addition, it represents that the durability performance with respect to the fracture | rupture of the reinforcement element of a belt reinforcement layer is so high that a numerical value is large.

  As is apparent from the results of Table 2, according to the pneumatic radial tire of the present invention, the separation of the belt reinforcing layer from the cross belt layer adjacent to the outer peripheral side of the belt reinforcing layer and the belt, regardless of the selection of the carcass line. It has been found that the durability performance against any failure of the reinforcing element in the reinforcing layer can be greatly improved.

DESCRIPTION OF SYMBOLS 1 Pneumatic radial tire 2 Bead part 3 Carcass 4 Reinforcement element 5 Belt reinforcement layer 6, 7 Crossing belt layer 8 Bead core 9 Side wall part 10 Tread part C Tire equator line E1 Tensile elastic modulus at break of reinforcement element E2 Tensile at break Tensile modulus of elasticity 10%

Claims (1)

A belt reinforcing layer made of one or more kinds of reinforcing elements extending along the tire equator line on the outer side in the tire radial direction of the carcass extending in a toroidal shape between a pair of bead portions, and each belt layer cord are mutually connected In a pneumatic radial tire in which each of two or more crossing belt layers extending in an intersecting direction is sequentially arranged from the inner peripheral side,
At least one type of reinforcing element of the belt reinforcing layer is a high elongation cord or WAVY cord having a large initial elongation formed by twisting a plurality of steel filaments ,
When the reinforcing element has a tensile elastic modulus of 10% of the tensile elastic modulus at break, the elongation percentage of the reinforcing element is A%,
A pneumatic radial tire in which the reinforcing element is arranged in a cross section in the tire width direction, at least from a position where the tire diameter growth rate by filling with the normal internal pressure is A% to a range outside in the width direction.

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