JP2000226782A - Steel cord - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a steel cord excellent in fatigue resistance and suitable for reinforcing an elastomer material by twisting a second steel filament around plural first steel filaments meandering in a prescribed amplitude at a prescribed helically twisting angle. SOLUTION: This steel cord 1 having 2+1 structure, is obtained by forming 2 pieces of a first steel filament 2 having their axis centers parallel each other and having diameter(d) as wavily meandering in an amplitude(a) and also helically twisting one piece of a second steel filament 3 around the above first steel filaments 2 at 5-10 deg. twisting angle in a helical state having a pitch T.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a steel cord used to reinforce an elastomer material, and is used for automobile tires, high-pressure hoses, conveyor belts, force transmission belts, and the like.

[0002]

2. Description of the Related Art As a steel cord used for reinforcing an elastomer material, a steel cord having a 1 × 4 structure and a 1 × 5 structure has been widely used until now.
There is also a steel cord with a structure. However, in a steel cord having a 1 × n structure, there is also a problem that rust progresses in the longitudinal direction of the cord when moisture penetrates into the cord due to external factors due to poor permeability of the elastomer material into the steel cord. Was.

[0003] Therefore, as a steel cord that can be expected to greatly reduce the cord weight without deteriorating the permeability and fatigue resistance of the elastomer material, a steel cord whose axes are parallel to each other is used.
Japanese Patent Application Laid-Open No. 5-23 discloses a structure in which one second steel filament is helically twisted at a predetermined twist pitch around a first steel filament to form a 2 + 1 structure.
No. 9781.

[0004]

In the above publication, the first steel filament meanders at a certain amplitude, but no consideration is given to the range of the meandering amplitude. Met. When the amplitude of the first steel filament exceeds a certain range or falls below a certain range, it has been found that a problem arises that fatigue resistance deteriorates. In the above,
No consideration is given to the twist angle of the second steel filament with respect to the first steel filament, and there is a problem that fatigue resistance may be deteriorated depending on the twist angle of the second steel filament.

Therefore, an object of the present invention is to provide a steel cord having a good fatigue resistance in a steel cord having a 2 + 1 structure.

[0006]

In order to achieve the above-mentioned object, the present invention takes the following technical measures. In other words, the present invention according to claim 1 has a structure in which the axes are parallel to each other and the two first steel filaments having a diameter d are provided around:
In a steel cord in which one second steel filament is helically twisted at a predetermined twist pitch to form a 2 + 1 structure, the first steel filament meanders in an amplitude range of 0.8d to 1.2d. It is characterized by having.

Further, according to the present invention, the first steel filaments whose axes are parallel to each other are provided around two first steel filaments.
In a steel cord in which one second steel filament is helically twisted at a predetermined twist pitch to form a 2 + 1 structure, the second steel filament has a twist angle of 5 ° to 10 ° with respect to the first steel filament.
Characterized by being twisted in the range of

[0008]

Embodiments of the present invention will be described below with reference to the drawings. Steel cord 1 according to the present invention
Is used to reinforce elastomeric materials such as rubber, and is used, for example, in automotive tire breaker layers, high pressure hoses, conveyor belts, and the like. Fig. 1 shows the steel cord
1 shows a cross section at a part of the side surface and at a quarter of the pitch P distance. This steel cord 1 is formed around two first steel filaments 2 whose axes are parallel to each other.
One second steel filament 3 is spirally twisted at a predetermined twist pitch P to form a 2 + 1 structure.

The two first steel filaments 2 may be twisted at a larger twist pitch and in the same torsion direction than the surrounding one second steel filament 3, and the two first steel filaments 2 2 is molded at the same period as one second steel filament 3 around it. Further, the first and second steel filaments 2 and 3 are made of a high-strength wire having a carbon content of 0.75 to 0.95%, and are configured so as to be able to improve fatigue resistance due to tensile stress while being lightweight. ing.

In FIG. 1, when two first steel filaments 2 are arranged substantially vertically (in the vertical direction), one second steel filament 3 surrounding the first steel filaments 2 has a 1/4 pitch and a 3/4 pitch. Two first steel filaments at the position
2 at a pitch of 1/2 and in contact with two first steel filaments 2 in a substantially horizontal state, where two first steel filaments 2 and one second steel filament 2 3 will be greatly open to the outside space, ensuring that elastomeric material, such as rubber, will well penetrate the gap.

As shown in FIG. 1, the steel cord 1 has two first steel filaments 2 having a predetermined amplitude a.
And a second steel filament 3 is helically twisted around the first steel filament 2 at a predetermined twist angle θ with respect to the first steel filament 2. It is formed with. In addition, amplitude a is one first steel filament.
2 is shown. The twist angle θ is, as shown in FIG. 1 and FIG. 2, the axial center of the second steel filament 3 with respect to the first steel filament 2 as viewed from a direction orthogonal to the longitudinal direction (axial direction) of the steel cord 1. b)
The second steel filament 3 is twisted with respect to the first steel filament 2 at a twist angle θ5 ° to 10 °.

In FIG. 1, the twist angle θ is an axis c parallel to the center line of the amplitude a of the first steel filament 2 (or the axis of the steel cord 1) and an axis c of the second steel filament 3. In FIG. 2, a line segment parallel to the axis of the first steel filament 2 and the second steel filament before the first steel filament 2 is formed in a meandering shape are shown in FIG. 3 with the axis b. If the twist angle θ is less than 5 °, the fatigue resistance due to the compressive stress becomes poor, and the twist angle θ
If it exceeds 10 °, the twist pitch is substantially shortened and productivity is deteriorated, and the level of cord strength is also reduced,
Fatigue resistance due to tensile stress deteriorates.

The steel cord 1 is configured such that, when the diameter of the first steel filament 2 is d, the amplitude a of the first steel filament 2 is in the range of 0.8d to 1.2d. If the amplitude a is less than 0.8d, the fatigue resistance due to the compressive stress becomes poor, and if the amplitude a exceeds 1.2d, the level of the cord strength becomes low and the fatigue resistance due to the tensile stress becomes poor. Because it becomes. Next, Table 1 shows Examples 1 and 2 according to the present invention and Comparative Example 1
4 shows the test results.

In this test, as shown in FIGS. 3 and 4, the width w is 1 inch, the thickness t is 10 mm, and the circumference is 80 m.
A rubber composite in which 20 steel cords K having the structure of any of Example 1 or 2 or Comparative Examples 1 to 4 are embedded in an endless belt body B made of rubber of m in two layers in the thickness direction. A body sample S is formed, the sample S is mounted over a pair of rolls R having a diameter of 20 mm, and the rolls R are driven to rotate.
By rotating in the circumferential direction. The steel cord K is embedded in the circumferential direction E of the endless belt body B. As described above, the steel cord K has a 2 + 1 structure in which one steel filament is helically twisted at a predetermined twist pitch P around two steel filaments whose axes are parallel to each other. The steel filament constituting each steel cord K has a diameter d of 0.25 mm.

[0015]

[Table 1]

A compressive stress is applied to the steel cord K of the inner layer of the sample S, and a tensile stress is applied to the steel cord K of the outer layer. In Table 1, the “compression fatigue resistance” is evaluated by expressing the total number of broken steel filaments of the steel cord K of the inner layer after the sample S was rotated 5,000 by an index, and the numerical value is large. The more the number of broken steel filaments, the better. Also, “tensile fatigue”
After the sample S was rotated 5000 times, the sample S
The strength of the steel cord K of the outer layer taken out from the steel cord K is measured, and the strength of the cord is evaluated by the strength retention rate represented by an index. is there.

[0017]

According to the present invention, one second steel filament is helically twisted at a predetermined twist pitch around two first steel filaments whose axes are parallel to each other and whose diameter is d. In the steel cord having the 2 + 1 structure, the first steel filament is meandering in the amplitude range of 0.8d to 1.2d. Can provide code. That is, when the amplitude is less than 0.8d, the fatigue resistance due to the compressive stress becomes poor, and when the amplitude exceeds 1.2d, the level of the cord strength becomes low, and the fatigue resistance due to the tensile stress becomes poor. When the amplitude is in the range of 0.8d to 1.2d, the fatigue resistance of the steel cord is improved.

Further, one second steel filament is helically twisted at a predetermined twist pitch around two first steel filaments whose axes are parallel to each other, and 2+
In a steel cord having a single structure, the second
Since the steel filament is twisted at a twist angle of 5 ° to 10 ° with respect to the first steel filament, a steel cord having a 2 + 1 structure and excellent fatigue resistance can be provided. That is, when the twist angle is less than 5 °, fatigue resistance due to compressive stress is deteriorated, and when the twist angle is more than 10 °, the twist pitch is substantially shortened and productivity is deteriorated, and the cord strength level is also reduced. Therefore, the fatigue resistance due to tensile stress is deteriorated. Therefore, when the twist angle is in the range of 5 ° to 10 °, the fatigue resistance of the steel cord is improved.

[Brief description of the drawings]

FIG. 1 is a side view and a sectional view of a steel cord according to the present invention.

FIG. 2 is a side view showing a twist angle of a second steel filament with respect to a first steel filament before being formed into a meandering shape.

FIG. 3 is a perspective view of a portion of a sample for testing a steel cord.

FIG. 4 is a schematic diagram of an apparatus for testing a steel cord.

[Explanation of symbols]

 Reference Signs List 1 steel cord 2 first steel filament 3 second steel filament a amplitude θ twist angle

Claims (2)

[Claims] 1. A 2 + 1 structure in which one second steel filament is helically twisted at a predetermined twist pitch around two first steel filaments whose axes are parallel to each other and whose diameter is d. In the steel cord, the first steel filament has an amplitude of 0.8d to 1.d.
A steel cord characterized by meandering in a range of 2d. 2. A steel cord in which one second steel filament is helically twisted at a predetermined twist pitch around two first steel filaments whose axes are parallel to each other to form a 2 + 1 structure. A steel cord, wherein the second steel filament is twisted at a twist angle of 5 ° to 10 ° with respect to the first steel filament.