KR100449376B1 - Sticking method for pneumatic tire - Google Patents

Abstract

The present invention is an adhesive method for coating two organic functional silane-based coupling agent having an amine functional group and a sulfan functional group in order to impart an adhesive force to a steel cord cutting surface which does not form a bond with rubber because there is no brass layer. In this regard, the characteristics of the silane coupling agent reacting with the rubber phase and the silane and the metal oxide layer make it possible to adhere 100% to the steel cord cutting surface and rubber from which the brass layer has been removed, and thus to remove the cracks. It is possible to suppress the occurrence, to prevent separation between the belt stacks, and consequently to improve the durability of the tire.

Description

Bonding method of steel cord cutting surface of pneumatic tire {Sticking method for pneumatic tire}

The present invention relates to a method for bonding the steel cord cutting surface of the pneumatic tire, and more particularly, the adhesive force is applied to the steel cord cutting surface of the pneumatic tire which does not have a brass layer and thus does not form an adhesion with the rubber, causing initial cracking of the belt portion. It is about how to give.

Pneumatic tires are subjected to high loads and deformations of the vehicle while driving. In particular, since the belt portion of the tire supports most of such vehicle loads, it must withstand severe deformation of the tire compared to other parts of the tire. At this time, the stress of the belt part to be deformed is particularly concentrated at the end portion, and the concentration of this stress causes cracking from the belt end portion, and gradually causes growth, ultimately leading to separation between the stacked belts.

In general, the adhesion of steel belts refers to the adhesion of brass plated steel to rubber. In other words, by inducing Cu _x S bond between the sulfur present in the rubber compound and the copper in the brass layer, it is strongly bonded. However, the end portion of the belt portion is cut to a certain width and angle, and consequently, The cutting surface will be a bare steel surface without a brass coating. Therefore, as described above, the belt edge portion, which is particularly stress-intensive, is such that no adhesion occurs between rubber and steel. This problem causes crack initiation.

At present, there is no technique used to induce the adhesion between rubber and steel in consideration of the adhesion problem to the belt edge portion in the world, and to suppress the detachment of the belt portion based on such an effect.

Therefore, the inventors of the present invention, while trying to develop a method that can be attached to both edge portions of the tire steel cord, as a result of treating the silane coupling agent to both edge portions of the steel cord from which the brass layer is removed, It has been found that the adhesion between rubber and steel can be imparted to complete the present invention.

Accordingly, an object of the present invention is to treat the silane coupling agent on both edge portions of the steel cord from which the brass layer has been removed to impart adhesion between the rubber and the steel, thereby suppressing the occurrence of initial cracks that cause the belt to detach. The present invention provides a method for bonding the steel cord cutting surface of a pneumatic tire that can prevent separation between the laminated portions and, as a result, improve durability.

The method of bonding the steel cord cutting surface of the pneumatic tire of the present invention for achieving the above object is to form a silane adhesive layer having an alkoxy silyl end group between the bare steel surface and rubber of the steel cord cutting surface of the pneumatic tire. It has its features.

1 is a photograph of the adhesion amount measurement of the adhesion between the brass cord surface and the rubber according to Comparative Example 1,

Figure 2 is a photograph of the adhesion amount measurement at the time of adhesion between the bare cord surface and the rubber according to Comparative Example 2,

3 is a photograph of measuring the adhesion amount when the silane A is applied to the soaked cord surface according to Comparative Example 3 and bonded with rubber,

4 is a photograph of measuring the adhesion amount when the silane B is applied to the soaked cord surface according to Comparative Example 4 and bonded with rubber,

5 is a photograph of measuring the adhesion amount during adhesion with rubber by applying silane A and silane B by mixing 1: 1 weight ratio on the soaked cord surface according to Example 1 of the present invention.

Fig. 6 is a photograph of the rubber adhesion amount of the actual cord edge part without the silane coupling agent treated;

7 is a photograph of the rubber adhesion amount of the actual cord edge portion treated with only silane A,

8 is a photograph of the rubber adhesion amount of the actual cord edge portion treated with only silane B.

Fig. 9 is a photograph of the actual rubber adhesion amount of the cord edges treated by mixing silane A and silane B in a 1: 1 weight ratio.

The present invention will be described in more detail as follows.

In the present invention, the adhesive layer is formed on the cutting surfaces corresponding to both ends of the steel cord of the tire so as to be able to adhere to the rubber, and a specific coupling agent is introduced between the bare steel surface and the rubber soaked steel. It is made to bond between the rubber and.

The coupling agent used in the present invention is a silane coupling agent, which is applied to the edge portion of the steel cord exposed in the cutting process.

Specifically, the silane coupling agent has an alkoxy silyl end group, and more specifically, one having an amine functional group and one having a sulfan functional group is used in combination. More specifically, bis- (γ-trimethoxysilylpropyl) amine (hereinafter referred to as silane A) and bis- (3- [triethoxysilyl] -propyl) -tetrasulfane (hereinafter referred to as silane B) It is a combination of two silane compounds of.

These two organofunctional silanes each have a property of reacting with a rubbery phase, a silane, and a metal oxide layer. In the present invention, the two compounds are applied by applying such properties. In other words, the silane group of the silane coupling agent having an amine functional group reacts first with the silane group of the silane coupling agent having a sulfan functional group to form a spider web, and then the silane coupling agent having an amine functional group The silane reacts with the metal, and the sulfur component of the silane coupling agent having a sulfen-based functional group combines with the rubber to form a complex adhesive layer.

Applying such an organofunctional silane compound to a steel cord surface without a brass coating can impart an adhesive force between the steel cord surface and rubber, and the strength of the adhesive force is 83% or more than that of the brass layer. In particular, as a result of evaluating the cross section to be bonded to the rubber with a very small area such as the edge part, the rubber adhesion amount was 0%, whereas the adhesion was 100%.

The mixing ratio of the two organic functional silane compounds suitable for exhibiting such an effect is when silane B is a weight ratio of 1: 1 to 5 with respect to silane A.

In applying such a silane coupling agent to the bare steel surface from which the brass layer was removed, it is preferable to apply the quantity to thickness of about several micrometers.

As described above, when a separate adhesive layer is formed between both edge portions of the steel cord from which the non-bonding brass layer is removed and the rubber layer, it is possible to suppress the occurrence of an initial crack that causes the belt to detach. By suppressing crack generation, it is possible to prevent separation between the belt stacks and ultimately improve the durability of the tire.

Hereinafter, the present invention will be described in detail with reference to the following Examples, but the present invention is not limited by the Examples. In the following examples, Examples 1 to 3 illustrate the result of applying the adhesive force by coating the silane coupling agent on the surface of the steel cord from which the brass layer was removed, and in the case of Example 4, substantially the edge portion of the belt portion. The effect of Esau is tested.

Examples 1-3 and Comparative Examples 1-4

The brass layer was used after removing the brass layer from the 3 + 9 + 15 (0.22) 1 W cord used in the tire to test the adhesion using the steel cord without the brass layer. A peeling solution was prepared and used to remove the brass layer. The peeling solution was prepared by mixing 300 ml of NH ₄ OH and 25 g of CCl ₃ COOH in 500 ml of distilled water.

The bare steel, from which the brass layer was removed, was immersed and washed in hexane and methanol, and then washed with acetone and dried with hot air.

General rubber cord adhesive rubber was used as the rubber.

Meanwhile, as an adhesive, silane A, silane B, and 1: 1 mixtures of silane A and silane B were prepared in vials, respectively, and then the previously prepared soak cord was used by dip coating.

Coated steel cords were immediately fabricated and vulcanized into rubber pull-out samples and edge-adhesion specimens with rubber stock without special drying.

Basically, adhesion between brass flatted steel and rubber (Comparative Example 1), untreated sample for bare steel (Comparative Example 2), and each silane coupling agent applied (Comparative Examples 3 to 4 and Examples 1 to 1). 3) was tested according to ASTM D2229-80 method.

The treatment methods of Examples 1 to 3 and Comparative Examples 1 to 4 are shown in Table 1 below, and the results of measuring the adhesive strength are shown in Table 2, and the rubber adhesion amount photographs after the adhesion test were observed by Video MicroScope (VMS). The results are shown in FIGS. 1 to 5.

1 is a photograph of the adhesion amount measurement of the adhesion of the brass cord surface and the rubber according to Comparative Example 1, Figure 2 is a photograph of the adhesion amount measurement of the adhesion of the bare cord surface and the rubber according to Comparative Example 2, Figure 3 is Comparative Example 3 According to Comparative Example 4 is a photograph of measuring the adhesion amount when the silane A is coated with rubber by applying silane A on the surface, and FIG. According to the invention example 1, the silane A and the silane B are mixed in a 1: 1 weight ratio and applied to the bare cord surface, and the adhesion amount at the time of adhesion with rubber is a photograph.

Example Comparative Example One 2 3 One 2 3 4 Silane coupling agent (mixing ratio) Silane A One One One - - One - Silane B One 2 3 - - - One Code surface condition Soaked (without brass) Brass layer Soaked (without brass)

Example Comparative Example One 2 3 One 2 3 4 Adhesive force (kgf / in) 77 90 100 121 32 17 55 Adhesion amount (%) 80 85 90 100 0 0 10

From the results of Table 2 and Figs. 1 to 5, in the state where the brass layer was not removed as in Comparative Example 1, as shown in Fig. 1, the adhesive force with the rubber was 121 kgf / in and the adhesion amount was 100%, In bare steel, the adhesion was 32 kgf / in and the adhesion amount was 0%. That is, it can be seen that the adhesion is not made between the steel cord from which the brass layer is removed and rubber.

In Comparative Example 3, only silane A was soaked in the cord, and no coating rubber was observed as in Comparative Example 2 (FIG. 3), and the adhesive strength was lower than that without the coupling agent treatment. Showed. This is because the curing process proceeded immediately after immersion without any drying process, so that the silane A did not meet the atmosphere to form a film to some extent.

As in Comparative Example 4, when silane B was treated with a soaked cord, the adhesion amount was increased by 10% with a slight increase in adhesion.

From the results of Comparative Examples 3 and 4, it can be seen that silane A and silane B each do not achieve sufficient adhesion.

This can be more clearly confirmed from Examples 1 to 3, as shown in FIG. 5, when silane A and silane B were mixed 1: 1 (Example 1), the adhesive force was 77 kgf / in, and the adhesion amount was 80%. Reached. In other words, unlike the original reactions to the respective silane functional groups, the reaction in the mixed state showed up to 64% adhesion compared to the state in which the brass layer was not removed through the effective mechanism of adhesion.

Examples 4-6 and Comparative Examples 5-7

Each silane coupling agent mixture as in Examples 1 to 3 was tested by coating the end cross section of the steel cord substantially free of the brass layer. Since the cross-sectional area of the edge part is relatively small, in order to quantitatively evaluate the actual adhesive strength in this part, the adhesion of the rubber to the edge part (as cut edge, in the bare steel state) and when the silane coupling agent is treated The amount was taken by VMS image and compared.

In particular, for the edge portion, the cord was placed up to the middle portion of the rubber specimen, followed by vulcanization and drawing, and the images were taken and compared.

The treatment of the silane coupling agent was carried out as shown in Table 3 below, and the amount of cross section was measured and the results are shown in Table 3 and FIGS. 6 to 9.

6 is a rubber adhesion amount photograph of the cord edge portion untreated with a silane coupling agent, FIG. 7 is a rubber adhesion amount photograph of the cord edge portion treated with only silane A, and FIG. 8 is a rubber adhesion amount photograph of the cord edge portion treated with only silane B, Fig. 9 is a photograph of the rubber adhesion amount of the cord edge portion treated by mixing silane A and silane B in a 1: 1 weight ratio.

Example Comparative Example 4 5 6 5 6 7 Silane coupling agent treatment (mixing ratio) Silane A One One One - One - Silane B One 2 3 - - One Cross section adhesion amount (%) 100 100 100 0 0 15

From the results in Table 3 above, when the two silane coupling agents were mixed and applied to the soaked cord surface according to the present invention, the adhesive amount was 100%. When not used, the adhesion amount was 0%, and when only silane B was used, the adhesion amount was about 15%.

As described in detail above, according to the present invention, two organic functional silane coupling agents having an amine functional group and a sulfan functional group are applied to the steel cord cutting surface from which the brass layer is removed and adhered to the steel cord rubber. In one case, since there is no brass layer, adhesion with rubber is not formed, but 100% adhesion is possible due to the action of the silane coupling agent, thereby preventing the occurrence of initial cracks causing the separation of the belt. The separation of the liver can be prevented, resulting in improved tire durability.

Claims (4)

(Correction) A composite of a silane coupling agent having a amine functional group and a silane coupling agent having a sulfan functional group is coated between a bare steel surface and rubber having a brass coating of the steel cord cutting surface of a pneumatic tire. A method for bonding the steel cord cutting surface of a pneumatic tire, characterized by forming a silane adhesive layer. (delete) (Two-time crystal) The silane coupling agent according to claim 1, wherein the silane coupling agent having an amine functional group is bis- (γ-trimethoxysilylpropyl) amine, and the silane coupling agent having a sulfane functional group is bis- (3- [Triethoxysilyl] -propyl) -tetrasulfane . (Correction) The air pressure according to claim 1 or 3, wherein a silane coupling agent having an amine functional group and a silane coupling agent having a sulfane functional group are mixed and used in a weight ratio of 1: 1 to 1: 5. Bonding the steel cord cutting surface of a tire.