DE10206051C1 - Pneumatic tire reinforcement cords are of twisted filaments/filament bundles, to be impregnated with an adhesive or heat fixed, and then untwisted to increase their bulk before use with the unvulcanized tire rubber - Google Patents

Abstract

The reinforcement cord (1') for a rubber product, and especially a vehicle pneumatic tire, is composed of filaments or filament bundles (2',3') twisted together in one or two stages. They are bonded together by an adhesive impregnation or by heat fixing. Before use with the unvulcanized tire rubber material, the bonded cord is untwisted to reduce the number of twists within a length unit by 1-50% and, at the same time, the cord diameter is increased to give an open cord structure. The reinforcement cord (1') for a rubber product, and especially a vehicle pneumatic tire, is composed of filaments or filament bundles (2',3') twisted together in one or two stages. They are bonded together by an adhesive impregnation or by heat fixing. Before use with the unvulcanized tire rubber material, the bonded cord is untwisted to reduce the number of twists within a length unit by 1-50% and, at the same time, the cord diameter is increased to give an open cord structure. The filaments are of a polymer, carbon, glass or ceramic materials. The adhesive impregnation uses a solution with synthetic lattices with reactive groups, natural rubber lattices together with polymer lattices or a resorcinol formaldehyde solution dip.

Description

The invention relates to a method for producing non-metallic Strengthening cord for the reinforcement of rubber products, the Strengthening cord cords twisted together in one or more stages Have filaments or bundles of filaments and provided with an adhesive impregnation and / or are thermally fixed. The invention further relates to reinforcement cords which are produced by this method, and the use of such Strength cords for the manufacture of pneumatic vehicle tires.

Cord is a thread-like or line-shaped structure produced by twisting or twisting filaments (single fibers) or bundles of filaments (yarn) made of textile or other materials. Strength cords made of textile or other materials are used to reinforce various rubber products, such as. B. vehicle tires, drive belts, air springs, conveyor belts and tubes are used. Due to the cord construction, e.g. B. by the number and direction of rotation, you can influence the cord properties. So z. B. the tensile strength, the elongation at break and the tension value when stretched by the number of twists of the cord per unit length and the pitch angle (angle between the cross-sectional area of the cord and the individual filaments or filament bundles). If you reduce z. B. in the case of a cord, the pitch angle, which corresponds to an increase in the helix angle, leads to a cord with a lower tension value when stretched. Conventional non-metallic reinforcement cords for the reinforcement of rubber products have 100 to 500 turns per meter, depending on the cord diameter.

For some applications of reinforcement cords as reinforcement in rubber products it is desirable and in some cases necessary that the reinforcement cords start at the beginning  allow the cord to stretch when subjected to low tensile forces a certain degree of stretching or stretching a high tensile strength (Tensile strength) and associated with it a high stress value with elongation (Module) have, so it can hardly be stretched. Such reinforcement cords initially show a slight slope of the curve in the tensile force-strain diagram, then the curve bends and an area with a large slope follows the curve. In this last area there is little stretch with a lot of effort connected.

Strength cords, which have such a tensile force-strain diagram are z. B. known from EP 0 461 646 A2 and z. B. as steel cords under the name HE- Corde (high elongation cord) offered by steel cord manufacturers. Such HE- Strength cords, z. B. as a belt material for the production of Pneumatic vehicle tires used. They leave with the bombing of the green tire and with the Vulcanization is sufficient stretching of the belt, which is particularly important in the Manufacture of tires with strongly curved treads, such as B. motorcycle tires from Is needed. The reinforcement cords are subject to one after bombing and vulcanization certain preload and then ensure after completion of the tire in the Driving a high tensile strength of the belt. You get tires that are even at high Speeds of hardly any deformation, essentially caused by Centrifugal forces. Also as material for the belt bandage and as Carcass material can be used with such HE cords.

From EP 1 172 476 A1 it is known to have reinforcements for the reinforcement of tires by twisting strands of twisted filaments apart and thereby the individual filaments spaced apart, the twisted strands in this condition for the most complete coverage with rubber by a Rubber solution and then twisted or twisted the strands again. The Strands only have an open structure for a short time and are inserted into the unvulcanized rubber compound is twisted back into a closed structure or twisted. Such strands should have sufficient strength and good on  the rubber are bound. The problem of reinforcements for rubber products too generate that can be stretched at the beginning with little pulling force and after a certain stretch only further stretched under very great force can be achieved by using these twisted cords do not reach.

The invention is based on the object of a method for the simple production of to provide non-metallic reinforcement cords, which too Strengthening cord cords leads to the reinforcement of rubber products, which is at the beginning Let it stretch under the influence of a small amount of tension and only after a certain stretch can still be stretched under very great force.

According to the invention, this object is achieved by a method in which the Reinforcement cords after being provided with the adhesive impregnation and / or after thermal fixation and before placing in an unvulcanized Rubber mixture can be twisted apart again and thereby the number of Rotations per unit length reduced by 1 to 50% and at the same time the diameter the reinforcement cord is enlarged, creating an open cord structure.

Preferred embodiments of the method according to claim 1 are in claims 2 marked to 5.

In the conventional manufacture of reinforcement cords, which are Impregnation and thermal treatment are twisted or twisted is one Reduction of twists per unit length (twist) with an increase in the Helix angle (reduction of the helix angle) without increasing the diameter of the Cordes connected. This results in a reduced initial elasticity in the acting Tensile forces. The basic idea of the invention can now be seen in the fact that one can Reduction of twists per unit length after the cord has been provided with a Adhesive impregnation and / or after thermal fixation with simultaneous Increase the diameter of the reinforcement cord a permanent open Preserves cord structure. The individual filaments or filament bundles are Impregnation and / or the thermal fixation practically preformed and give one  Turn it back (the cord will go against the original twisting or twisting direction twisted, backtwisting) of the entire cord this form is difficult to open again. Within of the cord, the filaments or filament bundles are therefore spaced apart from one another and have play within the cord. The open structure of the cord now leaves one high initial elasticity in the case of acting forces until the open one Structure has closed again. After that, the cord has a much lower one Elasticity with acting forces. The pitch angle of the cord changes depending on the degree of turning back and the pulling force, which during the Turning back on the cord works. It can grow or shrink.

If one uses such a reinforcement cord with an open cord structure for the Manufacture of rubber products and bring it into an open structure unvulcanized rubber compound, so it can be there under the influence of forces, z. B. in the bombing of a tire, first stretch with little force. is the cord in the rubber product is then stretched so far that the cord structure is closed, it is difficult to stretch the cord and thus the product even further.

In the case of the adhesion impregnation of the solid support cords, it can be all to the expert known impregnation solutions (dip solutions) to improve the adhesion of the Act strength member for embedding rubber. Doing so for different Strengthening materials different impregnation solutions can be used. Frequently z. B. for reinforcement cords made of textile materials with an impregnation solution synthetic latices with reactive groups, natural rubber latices with the addition of Polystyrene vinyl pyridine latices and resorcinol-formaldehyde solution (RFL dip) used. Thermal fixation is used for reinforcement cords, especially for those made of textile material, applied to dimensional stability guarantee.

The reduction in the number of turns per unit length (level of backtwisting) and and the increase in the diameter of the reinforcement cords may vary Desired initial extensibility can be varied in a simple manner. It can  Twisting apart the cords z. B. in such a way that the ends of the with an adhesive Impregnated and / or thermally fixed cordes are clamped and then the pinched ends, if necessary also under a constant tensile force, be rotated against each other in the opposite direction of rotation. In Depends on the rigidity of the cord and on the tensile force during of turning back the total length of the turned back cord can be greater or smaller be than the initial length of the cord before turning back.

According to a preferred development of the invention, the diameter of the Reinforcement cords when twisted apart by 5 to 40%, preferably by 10 to 20%, increased.

As the strength member cords twisted apart again show the tendency to to return the unfixed / unshaken state to its original structure, it has proven to be particularly advantageous if the cords after the Spread apart again with an adhesive impregnating solution and / or thermally be fixed to stabilize the open cord structure. The cords can follow such a treatment without problems in the unclamped state and transported be stored for a long time.

The reinforcement cords according to the invention for the reinforcement of rubber products can be made of different materials, such as. B. rayon or polyester his. However, it is particularly preferred if the filaments of the reinforcement cords made of aramid, poly (p-phenylene-2,6-benzobisisoxazole), carbon, glass and ceramic Materials exist. These materials have a particularly high tensile strength and Tensile strength, are particularly thermally stable and have a low weight. are Cords made of such materials stretched so that the structure of the cords is closed, they can hardly be stretched even with great force.  

The reinforcement cords can be made of filaments from one and the same material be made. But it is also possible that filaments made of different materials for which cords were used, so-called hybrid cords.

The reinforcement cords produced by the method according to the invention with Open cord structure can be used to reinforce various rubber products are used, the strength cords with open cord structure z. B. in Thread form or as cord fabric layers can be used and in one unvulcanized rubber mixture can be introduced. After assembling the unvulcanized product, the product is vulcanized. According to an advantageous Further development of the invention, the strength cords for the production of Pneumatic vehicle tires, especially motorcycle tires, are used. The pneumatic vehicle tires usually have a radial carcass, which is looped around in the bead area tensile bead cores is anchored, a radially outer profile grooves having tread, one between the tread and the carcass belt from at least one belt layer with rubberized Strengthening cord cords and possibly between the tread and belt arranged single or multi-layer belt bandage made of parallel and essentially in Tire circumferential direction reinforcing cord, which at least the Belt edges covering, on. The tire manufacturing process must use the Strength cords according to the invention with open cord structure not changed become. The traditional cords are made easy by the after cords produced according to the inventive method replaced. For example, the Belt bandage, the belt or the carcass by the method according to the invention have produced reinforcement cords.

Since the reinforcement cords produced by the method according to the invention are too Beginning of a force can be easily stretched from a certain stretch but can hardly be stretched any further, it has proven to be particularly advantageous proven when the cords are used for the belt and / or the belt bandage. The cords ensure that the green tire is bombed and vulcanized  sufficient stretching of the belt and / or belt bandage so that the blank can be optimally produced without errors in the profile. The cords should be there in reducing the number of turns per unit length and increasing the diameter des Cordes are set so that after bombing and vulcanization the Cord structure is closed by the stretching during bombing and vulcanization. While then the tire is not subject to driving even at high speeds Deformation, which is particularly evident in conventional tires Increases in diameter of the tire noticeable. The belt and / or the Belt bandages effectively counteract the deformation due to their high tensile strength and thereby prevent z. B. temperature increases in the belt edge area as well Loss of handling and grip that the tire suffers from deformation.

An exemplary embodiment and further advantages of the invention are related to the following figures, showing:

Fig. 1a shows a conventional strength cord made of two filaments twisted together

Fig. 1b the reinforcement cord according to Fig. 1a after unscrewing

Fig. 1c shows the Festigkeitsträgercord FIG. 1b after stretching

Fig. 2 is a tension-strain diagram with the curves of different strength cords determined according to DIN

In Fig. 1a, a conventional reinforcement cord 1 is shown from two twisted filament bundles 2 and 3 . The filament bundles 2 , 3 are helical and twisted in one step and thermally fixed in their shape. The pitch angle α ₀ indicates the angle between the cord cross-sectional area and the individual filament bundle 2 , 3 . D ₀ is the diameter of the reinforcement cord 1 .

After application of the method according to the invention to the reinforcement cord 1 , the reinforcement cord 1 'shown in FIG. 1b is obtained. The cord 1 was clamped at both ends and turned apart against the original direction of rotation, the distance between the clamped ends being reduced. The number of turns per unit length was reduced and the diameter D _{1 of} the cord was increased. There is an open structure of the cord 1 ', the filament bundles 2 ', 3 'having play. Depending on the prevailing conditions (e.g. tensile forces acting on ends), the pitch angle α ₁ can be larger or smaller than α ₀ after the process of turning back.

If a pulling force is now applied to the cord 1 ', the cord assumes the shape of the cord 1 "shown in FIG. 1c. The formerly open structure closes, the diameter decreases to D ₂ and the pitch angle changes to α ₂ , and when the filament bundles 2 ", 3 " touch one another, the cord 1 "can hardly be stretched further due to the high strength of the filaments.

In FIG. 2, a tension-strain diagram is shown in which the tensile force F in Newtons versus elongation ε is plotted in%. It contains the curve A of a conventional cord made of aramide and the curves B and C of two cords made of aramide produced by the method according to the invention. The cord of curve shape A had the following characteristics: 3300 dtex Z 190 T / m × 3 S 190 T / m, cord diameter = 1.3 mm. For the cords that gave the curves B and C, the aforementioned aramid cord was turned back from 190 turns per meter (T / m) 40 (curve B) and 70 (curve C) turns per meter. The result was cords with 150 (curve B) or 120 (curve C) twists per meter and cord diameters of 1.5 or 1.8 mm. It can be seen from the curves that for the stretching of a conventional aramid cord, large tensile forces are required for a further stretching even with slight stretching. The curves B and C of the cords produced according to the invention, on the other hand, can be stretched up to an elongation of approximately 4% or 7% without great effort. Only after overcoming this initial stretch does the curve rise in a strongly linear manner. The strongly rising areas of the curves are present when the cord structure is closed again.

Claims (8)

1. A method for producing non-metallic reinforcement cords ( 1 ') for the reinforcement of rubber products, the reinforcement cords ( 1 ') having filaments or filament bundles ( 2 ', 3 ') twisted together in one or more stages and with an adhesive Impregnation and / or thermally fixed, characterized in that the strength cords ( 1 ') after being provided with the adhesive impregnation and / or after the thermal fixation and before being introduced into an unvulcanized rubber mixture are twisted apart again and thereby the number of the twists per unit length is reduced by 1 to 50% and at the same time the diameter of the reinforcement cords ( 1 ') is increased, an open cord structure being created. 2. The method according to claim 1, characterized in that the number of rotations per Unit of length is reduced by 10 to 30%. 3. The method according to claim 1 or 2, characterized in that the diameter of the reinforcement cords ( 1 ') is increased by 5 to 40%. 4. The method according to any one of claims 1 to 3, characterized in that the reinforcement cords ( 1 ') are stabilized after being twisted apart by a further provision with an adhesive impregnation and / or by thermal fixation. 5. The method according to at least one of claims 1 to 4, characterized in that the filaments or filament bundles ( 2 ', 3 ') of the reinforcement cords ( 1 ') made of aramid, poly (p-phenylene-2,6-benzobisisoxazole), one Liquid crystal polymer, carbon, glass or ceramic materials exist. 6. reinforcement cord ( 1 '), which was produced by a method according to at least one of claims 1 to 5. 7. Use of a reinforcement cord ( 1 ') with an open cord structure according to claim 6 for the manufacture of pneumatic vehicle tires. 8. Use of a reinforcement cord ( 1 ') with an open cord structure according to claim 6 for the production of belts and / or belt bandages of pneumatic vehicle tires.