KR100318895B1 - Steel cord for reinforcing rubber with a good rubber penetration properties - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to steel cords embedded in various rubber products including tires and industrial belts of vehicles and used as reinforcing materials.

The present invention is a steel cord consisting of a plurality of strands of twisted pairs of wires, comprising a flat cross-section by the cold rolling of the brass-plated circular steel wires and includes at least one flat spiral steel wire twisted spirally along the longitudinal direction The technical features of the structure, wherein the flat ratio of the flat spiral steel wire is 1.05 to 2.5, the long diameter is 0.2 to 1.0mm, the spiral pitch is 2 to 100 times the long diameter, both outer edges of the upper and lower surfaces consisting of flat surfaces It is desirable to have an additional arcuate curved surface.

The steel cord of the present invention degrades other quality characteristics such as low elongation required for tire reinforcing materials due to the structural characteristics of the steel wire having a flat cross section twisted into other steel wires while being twisted in a constant spiral shape. It provides a gap between adjacent steel wires to improve rubber permeability, fatigue resistance, rubber adhesiveness and handling workability, and ultimately increase tire durability. It is expected.

Description

Steel cord for reinforcing rubber with a good rubber penetration properties

The present invention relates to a structural improvement of a steel cord used as a reinforcement material for various rubber products including tires and industrial belts of a vehicle, and more particularly, has a flat cross section in a spiral shape in a steel cord in which several strands of steel wires are twisted together. The present invention relates to a steel cord for rubber reinforcing materials having excellent rubber penetration property, by which at least one strand of twisted flat spiral steel wire is included, thereby improving adhesion, fatigue resistance and handling workability with rubber.

In general, among the various types of reinforcing materials used to reinforce elastomeric products such as tires or conveyor belts of a vehicle, steel cords have different types of reinforcing materials having different strength, modulus, heat resistance, heat transfer rate, fatigue resistance, and adhesiveness. Compared with the tire reinforcing material to meet the characteristics required, in particular for the reinforcement of the tire has been used a lot, and the amount of use is increasing rapidly.

On the other hand, a radial tire filled with air inside is composed of a radial carcass portion having a radioactive carcass cord and a belt layer arranged radially outward of the carcass to reinforce the tread portion. The belt cord and the carcass layer of such a radial tire are usually buried with steel cords composed of 2 to 40 twisted pairs of ultrafine steel wires having a circular cross section with a diameter of 0.12 to 0.38 mm to reinforce the belt layer and the carcass layer. This is done.

As described above, the stranded cross-section of the steel cord embedded in the rubber product, which serves as a reinforcing material, generally has a circular shape. Several typical structures of the conventional steel cord will be described with reference to FIGS. 1 to 4 as follows. .

First, Figure 1 is a cross-sectional view of a conventional hermetic steel cord structure, as shown in the steel cord 1 of the 1x3 structure in which three strands of steel wire (1a) are twisted and bonded to each other, which is a rubber reinforcement to the rubber to be reinforced When buried and vulcanized, air remains without filling of rubber in the inner central space portion H surrounded by the steel wire 1a.

When the steel cord 1 having such a structure is used as a belt reinforcing material of a tire, deterioration of rubber is promoted by heat generation of the tire while the vehicle is running and air remaining in the center space portion H, thereby adhering the steel cord to the rubber. Separation phenomenon of the interface layer is caused. If the tread part of the tire is damaged by repeated impacts applied during driving of the car or stones or nails on the road surface, water enters the damaged part by the capillary phenomenon and enters the center space part H of the steel cord 1. The water penetrated into the central space portion is diffused in the longitudinal direction of the steel cord along the central space portion serving as a passage to induce rapid rusting of the steel cord.

Furthermore, the moisture penetrated into the center space portion H of the steel cord not only causes the induction of the cord itself, but also seriously destroys the adhesive interfacial layer between the rubber and the cord, resulting in separation between the two members, thereby degrading the durability of the tire.

Further, in the steel cord 1 of the hermetic structure, since the line contact is made between the steel wires 1a that are twisted and coupled with each other, the tire belt 1 which is in contact with the ground plane is repeatedly stretched and compressed every time the tire is rotated. As severe external pressure is transmitted, internal friction progresses gradually in the contact area between the wires, and accordingly, the contact surface of the wires wears out, causing an accident that part of the cord is cut inside the belt due to wear and tear.

In addition, in the hermetic steel cord 1, when the water intrudes as in the case described above into the central space portion H in a state where the brass plating layer on the surface is damaged by the wear as described above, erosion is easily performed and corrosion occurs. The phenomenon of accelerating the progression will occur.

A so-called open steel cord as shown in FIG. 2 is known as JP-A-57-43866 as one of structures developed to solve the problems posed by the hermetic steel cord as described above.

As shown, the open steel cord 2 has a structure in which a certain clearance S is maintained between adjacent steel wires 2a in forming a steel cord by twisting a plurality of steel wires 2a.

In such an open steel cord (2) structure, the rubber penetration through the gap (S) formed between the steel wires (2a) has the advantage that the rubber permeability is improved, but all the steel wire is 100% or more similar high in the longitudinal direction Due to the high rate of elongation between steel wires, it is very unstable in terms of structural stability of stranded wires due to its high elongation at low elongation. There is a problem falling.

In addition, the open steel cord (2) structure in the shape retention (property to maintain the shape), when the external pressure is applied during vulcanization adhesion, the open form is easily closed to the steel cord of the hermetic structure shown in Figure 1 as described above It is pointed out that there is a problem in shape retention as there is a property that is deformed.

In view of the disadvantages pointed out in the conventional open code, Japanese Unexamined Patent Application Publication No. Hei 5-163687 discloses some strands 3a 'in forming a cord by stranding steel strands 3a of several strands as shown in FIG. Disclosed is a single-stranded (or partially open) steel cord 3 in which a mold is given to a bay.

In the single-strand-shaped steel cord 3, the rubber penetration property and the appropriate elongation at low drop were achieved to some extent, but instantaneous severe impact due to external tension and compressive stress was transmitted to the steel cord 3 while driving the vehicle. When a load is applied, tensile and compressive stresses are concentrated intensively on the steel wire with a relatively low mold rate, that is, the element wire supply length per unit length is relatively small. Due to the phenomenon, there is a disadvantage that the structural stability is poor.

The structure of the open-type steel cord 2 of FIG. 2 and the single-strand-shaped steel cord 3 of FIG. 3 is a special tool, specifically, a hard plate type, in order to give the steel wire a certain mold within a predetermined range. Mechanical processing deformation is applied in various ways by using bookkeeping tools such as swelling, rotating molds, toothed gears or polygonal rugs, where the friction between the tool and the steel wires causes chipping or damage of the brass layer on the surface of the steel wire. There is a disadvantage in that the adhesion properties with the deterioration.

In addition, in the steel cords (2) and (3) of these structures, the variation of the mechanical property values in the longitudinal direction of the steel wire increases, particularly in the case of local uneven parts, that is, relatively small curvature radii, in which severe plastic damage is caused by severe plastic working. This is brought about.

Meanwhile, as another conventional steel cord structure for improving rubber penetrability, a deformed steel wire type steel manufactured by a 2-degree twisted strand method using a steel wire 4a having an elliptical cross section as shown in FIG. As the cord 4 is known, the steel cord 4 of the same structure minimizes the central space enclosed by the steel wires 4a while increasing the adhesion area between the steel wire and the rubber, and thus in terms of rubber adhesiveness. Although advantageous, there is a problem that the diameter of the steel cord 4 increases under the same unit weight, thereby counteracting the weight reduction of the tire.

Therefore, in view of the problems of the conventional steel cord, the present invention can bring about excellent rubber permeability and improved fatigue resistance without causing any deterioration of its properties in terms of unit weight and structural stability. The aim of the present invention is to provide a steel cord with a new structure suitable as a reinforcement material for air-injected radial tires by minimizing damage to the brass plating layer.

1 is a cross-sectional view of a conventional hermetic steel cord.

2 is a cross-sectional view of a conventional open steel cord.

Figure 3 is a cross-sectional view of a conventional single strand type steel cord.

Figure 4 is a cross-sectional view of the steel cord is twisted twisted pair with a conventional line having an elliptical cross section.

5 (a) and (b) shows the structure of a steel cord according to the present invention,

(A) is a front view showing the overall structure,

(B) is sectional drawing along the line A-A-D-D of (a).

Figure 6 is a cross-sectional view of a steel cord made of a two-degree twisted twisted steel wire of a flat section without a spiral.

Figure 7 (a) to (c) shows a steel wire manufacturing process of the flat spiral cross section constituting the steel cord of the present invention,

(A) is the cross section of steel wire in the state before rolling

(B) is the cross section of steel wire flattened by rolling process.

(C) is a front view of the finished flat spiral steel wire.

8A to 8D are cross-sectional views of another embodiment steel cord of the present invention including steel wire of flat spiral cross section.

9 is a cross-sectional view of a steel cord of a multi-lead structure as another embodiment of the present invention.

10A and 10B are cross-sectional views of steel cords having a multilayer lead structure as another embodiment of the present invention.

((Description of the code for the main part of the drawing))

10 -14. Steel cord 10a. Round section steel wire

10b. Flat spiral liner H. Center space

S. crevice

The above object of the present invention is achieved by a steel cord for a steel reinforcement having a structure in which at least one or more strands of a flat spiral wire twisted in a spiral shape are included in a steel cord configured by twisting a plurality of strands together. do.

The type of cord including the flat spiral steel wire of the present invention includes at least one stranded spiral steel wire and two to six strands of a conventional circular cross section stranded with a single stranded steel cord, and the stranded strand is stranded. It includes both steel cords of multi-layered structure and multi-lead structure that are used.

The present invention is a geometrical form between the twisted space of the flat spiral steel wire and the adjacent ordinary steel wire by mixing and twisting the steel wire of the conventional circular cross section and the steel wire flattened by cold rolling and twisted spirally by the torsion stress. As a result of the formation of a gap communicating with the central space inside the cord, there is a technical feature in that the rubber easily penetrates the inner space during vulcanization molding through the gap.

The present invention eliminates the risk of plating layer damage by providing a gap between strands of stranded steel wires in the conventional steel cord structure without imparting excessive molds resulting in chipping or damage of the brass plating layer. By filling the rubber up to, even though moisture is penetrated by damage to the tread, the adhesion interface layer with the rubber is protected as the propagation and diffusion channels of the water are blocked.

In addition, in the present invention, the contact between the steel wires is minimized to improve fatigue resistance, and there is no increase in elongation during deterioration, thereby improving the handling workability, while solving the above problems or disadvantages while maintaining the advantages of the conventional steel cord. I'm losing.

Further details of the steel cord for rubber reinforcing material excellent rubber permeability of the present invention will be clearly understood by the description with reference to the following drawings showing a preferred embodiment of the present invention.

First, Figure 5 (a), (b) is showing the structure of an embodiment of the steel cord of the present invention, (a) is a front view showing the overall structure, (b) (a) AA line to DD Line cross section. As shown, the steel cord 10 of the present embodiment has a 1 × 3 structure in which three strands of wire are twisted together, wherein the two steel wires 10a have a conventional circular cross section, and the remaining steel wires are flat spiral steel wires 10b. Consists of

At this time, the flat spiral steel wire (10b) is a self-twist in the spiral along the longitudinal direction of the steel cord 10, the gap (S) is formed between the adjacent common steel wire (10a) is a central space The portion H is in communication with the outside through the gap.

The opening of the steel cord center space H is achieved by the cross-sectional shape and the spiral twist of the flat spiral steel wire 10b. If the flat spiral wire is not spiral, the opening of the center space H is expected. it's difficult.

That is, Fig. 6 is a cross-sectional view of the steel cord 11 manufactured by using a two-degree twisted twisted pair of steel wire of a flat cross section without a spiral, and as shown, in the case of the flat steel wire 11b without twisting, as shown in FIG. 11a) are in line contact with each other to form a central space portion H, which is enclosed by steel wires 11a and 11b, which is sealed inside.

As described above, in the present invention, the flat spiral steel wire 10a constitutes a core technical configuration. The manufacturing method and specific configuration thereof will be described with reference to FIG.

Figure 7 (a), (b) shows a single-wire steel cord manufacturing process of the present invention,

(A) is the cross section of the raw material steel in the state before rolling, (B) is the cross section of the steel wire flattened by cold rolling, and (C) imparts torsional stress to the flattened steel wire to make spiral twist. Front view of a flat spiral steel wire.

First, as shown in Fig. 7 (a), the raw material steel wire W before rolling is made of a circular cross section similar to a conventional steel wire used for steel cords by twisted wire coupling of various conventional steel wires, The brass plated layer BC is plated.

The brass-plated material steel wire W is changed into a flat shape by cold rolling as shown in FIG. At this time, the steel wire (W ') is flattened by cold rolling, the upper surface and the bottom surface is a flat surface and the outer surface of the outer surface is an arc-shaped curved surface.

Subsequently, the steel wire W 'flattened by rolling as described above has a spirally twisted structure as shown in FIG. Is completed.

Looking at the structure of the flat spiral steel wire 10b of the present invention in more detail as follows.

First, in the flat spiral shape, the ratio of the long diameter a that is the largest diameter in the width direction to the short diameter b that is the minimum diameter in the thickness direction, that is, the flat ratio a / b is 1.05 to 2.5, and the long diameter a The size of is 0.2 ~ 1.0mm, the helix flat pitch (P) is 2 to 100 times the long diameter (a), the direction of the direction can be either S or Z, the flat edge portion is composed of an arcuate curved surface It is preferable to be.

In the flat spiral steel wire 10a of the present invention, when the twisted wire is provided by only the flat steel wire without giving a spiral shape, the two-degree twisted twisted wire machine mainly possessed by the steel cord manufacturer has a circular cross section as shown in FIG. Since the twisted pairs are joined at the same pitch as other steel wires, the central space of the steel cord cannot be opened.

For this technical reason, it is advantageous to design the spiral pitch P of the flat spiral steel wire not to be equal to the pitch of the steel cord.

In addition, it is more preferable in terms of rubber permeability that the longitudinal direction of the flat spiral steel wire and the longitudinal direction of the steel cord are different from each other.

The reason for limiting the cross-sectional shape and structure as described above in the flat spiral steel wire of the present invention is as follows.

First, the reason for limiting the long diameter (a), which is the maximum diameter of the flat spiral steel wire, to 0.2 to 1.0 mm is that if the wire diameter becomes less than 0.2 mm, sufficient tensile strength cannot be satisfied as a reinforcing material. If the diameter is too thick, there is a problem that the rubber thickness of the belt layer and the carcass layer of the tire is increased to counteract the weight reduction of the tire and the riding comfort is reduced during driving.

Next, if the flat ratio (a / b) of the flat spiral steel wire is less than 1.05, the steel cord surface area in contact with rubber, which is an effect of flattening, cannot be expected, and if it exceeds 2.5, the rolling work rate is too high, so severe plasticity The deformation causes cracks inside the steel wire. Therefore, the flat ratio of steel wire is restrict | limited to the range of 1.05-2.5.

Further, limiting the helical pitch P to 2 to 100 times the long diameter a is disadvantageous in terms of productivity if it is too small, less than 2 times. On the contrary, if the helical pitch is larger than 100 times, fatigue resistance, which is an effect due to the spiral, is caused. This is because no improvement can be expected.

In general, there are many known ways to improve the fatigue resistance of steel cords. Among them, fatigue resistance depends on the degree of straightness of steel wires. Therefore, increasing the straightness of steel wires increases the fatigue resistance of steel cords. It is important.

In other words, in the case of a steel wire having a poor straightness, that is, a bending wire having bending stress in the steel wire itself, fatigue resistance is sharply lowered even if the material of the steel wire itself is strong.

One aspect of the present invention is to provide a flat steel wire with a torsional stress on the basis of a central axis of the traveling direction to ensure the straightness of the steel wire.

The mechanical properties of the flat spiral steel wire according to the present invention, the tensile strength is 270kgf / mm ² or more, the elongation at break is appropriate in the range of 1.5 to 3.0%, the steel wire that satisfies these conditions is the piano wire SWRS 82A (C of JIS standard) = 0.82%) or repetitive cold drawing and parting heat treatment using a superhard steel piano wire (0.8 <C≤1.1%) as the base wire rod to obtain higher strength. Is obtained.

In general, the thickness of the brass plated layer formed on the surface of the steel wire is preferably 0.05 to 2 μm in order to ensure higher adhesion between the steel cord embedded in the rubber and the rubber, and most preferably 0.07 to 1.5 μm. .

On the other hand, the copper content of the brass plating layer is preferably 55 to 70%, more preferably ternary alloy plating by adding a third element Co, Fe, Ni, etc. in the brass plating in the range of 0.1 to 5.0% By doing so, it will be possible to improve the adhesion between the rubber and the steel wire, as well as the corrosion resistance and aging adhesion.

8 to 10 show various structures of the steel cord according to the present invention, which are stranded using a flat spiral steel wire having the configuration as described above.

8A to 8E are cross-sectional views of the steel cord 12 of the present invention including a steel wire having a flat spiral cross section, in which a sum of a conventional circular cross-section steel wire 10a and a flat spiral steel wire 10b is obtained. In the steel cord of 4 xd (d: wire diameter) structure which shows four strands, the number of strands and arrangement of the flat spiral steel wire 10b were changed. At this time, the arrangement position on the cut surface of the flat spiral steel wire 10b may be arranged regularly or irregularly, a regular arrangement is preferable.

Next, FIG. 9 is a cross-sectional view of a steel cord 13 of a multi-lead structure according to another embodiment of the present invention, in which a strand (St) in which a single strand of helical steel wire 10b and two strands of a conventional steel wire 10a are stranded. It is a 3 x 3 multi-stranded steel cord (13) constructed by closing three pieces.

10 (a) and (b) are cross-sectional views of steel cords 14 and 14 'of a multi-layered lead structure as another embodiment of the present invention. The structure of 1 + 6 + 10 and 1 + 6 + 12 in which the flat spiral steel wire 10b is used in ...) is illustrated.

On the other hand, the steel cord structure of the present invention is not limited to the structure as described above will be applicable to steel cords of various structures within the scope of the technical idea described in the claims that follow.

Embodiments of the present invention are as follows.

In order to evaluate the physical properties between the steel cord and the conventional steel cord using the flat spiral steel wire according to the present invention, using a material wire rod made of high carbon steel of 0.82% carbon (C) weight of 5.5mm in diameter, After the dry drawing, heat treatment, and brass plating processes were sequentially performed, the wire was drawn in the last wet drawing process to obtain a steel wire having a diameter of 0.3 mm, and the test pieces were manufactured under the conditions shown in Table 1 below.

Fatigue resistance, rubber permeability, rubber adhesiveness and elongation at break were measured with respect to the example specimens of the present invention and the conventional specimens obtained through the manufacturing process, and the results are shown in Table 1 below.

division Conventional Example 1 Conventional Example 2 Conventional Example 3 Example 1 Example 2 rescue 1 x 3 1 x 3 1 x 3 1 x 3 1 x 3 Characteristic Hermetic Open (1cr + 2) ** (1fsc + 2) ** (2fsc + 1) ** Cord Pitch (mm) 16 16 16 16 16 Wire diameter (mm) Long view 0.30 0.30 0.30 0.332 0.383 Short diameter 0.30 0.30 0.30 0.239 0.192 Flat rain One One One 1.39 1.99 Flat spiral steel wire 0 0 0 One 2 Spiral Pitch (mm) - - - 5 5 Rubber permeability 0 100 90 95 100 * Fatigue Resistance 100 115 112 128 131 * Aging rubber adhesive 100 116 110 119 123 Surface Fe Elution 0.19 0.58 0.37 0.21 0.24 Elongation at Break (%) 2.4 2.5 2.5 2.4 2.4 Elongation at break (%) 0.156 0.436 0.319 0.158 0.161 * Handling workability ◎ X △ ○ ○

(1cr + 2) **; Strands use curl

(1fsc + 2) **; One strand uses flat screwed steel wire

Fatigue resistance, aging rubber adhesiveness and handling workability indicated by * in Table 1 were evaluated in relative proportions to the prior art example 1.

First, rubber permeability was embedded in a rubber cord and vulcanized, and then compared with a length in terms of whether the rubber was filled in the cord longitudinal direction in the central space portion H of the cord. Therefore, 100% rubber permeability means 100% rubber is filled in the central space of the steel cord.

Fatigue resistance test involves placing steel cord specimens in the center of a small rubber specimen mold having a rectangular cross-section of 5 mm in width and 2.5 mm in length, and applying three bends using rubber compounds with 100% modulus of 35 kgf / cm ² . As the pulley moves from side to side, the number of reciprocating cycles until the steel cord specimen in the rubber is broken by abrasion fatigue or the like was measured and this was evaluated relative to the conventional example 1.

Aging rubber adhesiveness was investigated by American Standard Test Method (ASTM 2229) in relation to rubber adhesion, especially under extreme humidity (95% RH) and under high temperature (82 ° C).

In addition, the measurement of the surface layer iron (Fe) elution amount is a test method for evaluating defect damage of the surface brass layer of the steel cord. [Sample: 0.5N-HNO ₃ solution x 22 ° C (temperature) x 1 minute (hour)] The amount of iron (Fe) eluted per square meter of surface of the specimen was expressed in g / m ² . Therefore, the greater the amount of iron elution per time, the greater the damage to the brass surface layer.

Next, the elongation at break is a percentage of the elongation of the specimen at low loads, typically in the range of 0.25 to 5.1 kgf, and the greater this value, the worse the workability in handling.

The handling workability is the degree of ease in handling the steel cord in the tire forming process. The lower the elongation at break, in particular, due to the structural twist stability of the steel cord, the better the ◎ (excellent), ○ (good) , (Triangled), and X (defective) were shown in order.

As shown in Table 1, it can be seen that the steel cords of Examples 1 and 2 of the present invention exhibit significantly improved fatigue resistance compared to the steel cord of the prior art example 1, which is a twist of the steel cord of the present invention. Due to the helical shape formed by stress, the rubber easily penetrates into the center space between the twisted spaces, and the rubber acts as a buffer between the steel wires, minimizing abrasion caused by the direct contact between adjacent steel wires. It seems to be.

In addition, it can be seen that Examples 1 and 2 steel cords of the present invention are very advantageous in terms of rubber adhesiveness, in particular aging adhesiveness, compared to the conventional Example 1 steel cord, which diffuses the rust due to the opening of the central space of the stranded structure. This is due to the removal of the corrugated passageway and the increased area of contact with the rubber due to the flattening while retaining an undamaged brass layer.

On the other hand, the prior art examples 2 and 3 steel cord is excellent in terms of rubber permeability, but has a double-sided property in that elongation during deterioration is increased, so handling handling is disadvantageous.

According to the iron elution amount evaluation results of Table 1, in the case of the open type steel cords of the prior art examples 2 and 3, damage to the brass plated layer was caused by imparting a mold due to coercive plastic deformation of the steel wire. In Examples 1 and 2 steel cords of the present invention, a good brass plated layer was retained, which also advantageously worked in adhesion with rubber.

The steel cords of the first and second steel cords of the present invention have a steel wire moldability of about 100% in terms of stranded wire stability, as in the conventional steel cord of the prior art. It was found that the elongation during deterioration was relatively low compared to the large conventional steel cords 2 and 3, and the handling workability was excellent in the tire forming process.

As described above, the steel cord of the present invention is due to the structural characteristics of the steel wire having a flat cross-section twisted twisted with other steel wires while being twisted in a constant spiral shape, such as low-elongation elongation required in the tire reinforcement material. Steel for tire reinforcement by providing a gap between adjacent steel wires of stranded structure without significantly degrading the quality characteristics, improving fatigue resistance, rubber adhesiveness and handling workability, and ultimately improving tire durability. It is expected to be a new structure of code.

That is, in the steel cord of the present invention, the central space is opened and sufficient filling of rubber is performed through the open gap, thereby improving rubber permeability, thereby improving corrosion resistance and suppressing adhesion interface with rubber, thereby preventing tires. Contributes to improving durability.

In the fatigue resistance aspect, the gap between the open center space and the adjacent steel wire is filled with rubber, so that friction due to direct contact between steel wires is suppressed. Since wear is minimized, fatigue resistance is increased.

In addition, in the steel cord of the present invention, there is no fear of damaging the brass plating layer caused in the process of inducing the opening of the central space through the provision of the mold by mechanical plastic processing to the conventional steel wire, and due to the flat shape of the steel wire, Sufficient adhesive interface layer can be ensured.

In addition, the steel wire constituting the steel cord of the present invention has a low elongation during deterioration because the moldability is approximately 100%, so that there is no collapse of the stranded wire structure due to external pressure during tire vulcanization, and the handleability in the tire forming operation is good.

Claims (4)

A steel cord for a rubber reinforcing material, in which steel strands of several strands are twisted and bonded to each other, wherein at least one or more flat spiral steel wires are included in the cord. The steel cord for rubber reinforcement having excellent rubber permeability according to claim 1, wherein a flat ratio of the flat spiral steel wire is 1.05 to 2.5, a long diameter is 0.2 to 1.0 mm, and a helical pitch is 2 to 100 times the long diameter. The steel cord for rubber reinforcement having excellent rubber permeability according to claim 1, wherein the flat spiral steel wire is formed of an arcuate curved surface at both outer edges of the upper and lower surfaces of the flat spiral steel wire. 2. The steel cord according to claim 1, wherein the steel cord is a single strand of two to six strands of stranded strands bonded to each other, a multilayer strand or a plurality of strands stranded by using the single strand as a strand or a multilayer strand. Steel cord for rubber reinforcing material having excellent rubber permeability, characterized in that it has a twisted strand structure in which multiple strands are mixed.