EP0223301A1 - Method for producing a weft thread from pOY polyester - Google Patents

Abstract

A process is disclosed for production of a heat-treated, coarse fiber of polyester-POY, whereby the fiber is first twisted and then continuously relaxed and tempered at a temperature from 130 DEG to 250 DEG C. to an extent from 20 to 55%. The slide-resistant fiber produced in this manner, displaying an elongation at break from 150 to 350%, a thermal shrink from +6 to -6% can be employed without further pre-treatment as weft yarn for tire cord webs.

Description

The invention relates to a method for producing a heat-treated, rough thread made of polyester POY, preferably as a weft thread for a tire cord fabric, and a polyester thread produced by the method.

A polyester POY, based on at least 90% polyethylene terephthalate, is used as the starting material for the process according to the invention. with a titer of 50-300 dtex and 20-50 fibrils.

Vehicle tires of known design consist in the essential parts of a reinforcement in the form of threads made of synthetic fibers, which are embedded in rubber in the form of a cord fabric. The outer appearance and especially the tread are determined by the rubber.

In order for such tires with a cord fabric made of synthetic fibers to have good running properties and a long service life, two important conditions must be met, among other things: the shape of the tire must be very uniform and it must retain its dimensional stability as much as possible, even at high speeds . This presupposes that the carcass cord threads are spread and distributed as evenly as possible during tire manufacture. In particular, the weft threads must not provide any disruptive resistance.

In order to achieve this, methods are known in which the carcass cord threads are calendered directly into the rubber in an organized family of threads or the fabric weft is cut between the cord warp threads prior to calendering. Both methods are not easy to control in terms of reliability.

Other methods are that the tire cord fabrics are made with a slightly stretchable weft.

Such weft yarns consist of either polyester or nylon POY filament yarns, which achieve very high elongation values through extensive shrinking. With additional cotton staple twisting, the initial strength required for processing as well as sufficient sliding resistance and heat resistance can be achieved. A decisive disadvantage of these yarns, however, is that they have fluctuating initial strengths due to the never quite similar BW twisting along their thread, which later have a negative effect on a uniform carcass cord spread in the tire.

Other tire cord fabrics are known, in which the weft threads are made of POY polyester filaments, which are subjected to additional heat treatment under certain tension on appropriate thread straps to fix or reduce the shrinkage and pretreated with a rubber latex to prevent slipping or sliding between the warp threads are twisted with cotton threads (DE-A-27 48 747). The relaxation corresponds only to the portion possible due to the wrapping. In the known weft yarn, the frictional stability is brought about by a latex jacket. The elongation at break is given as 80 to 250%.

The known method has several disadvantages. In order to avoid excessive shrinkage, the heat treatment takes place under a certain thread tension. The resulting forces put different stresses on the thread within the winding in its most sensitive state, which can lead to shrinkage and tension differences.

With high temperature impregnated fabrics ("240 ° C) with the known weft filaments of less than 100% residual elongation at break, the weft threads often tear when the green tire is brought into its required shape by expansion.

Another disadvantage is the use of a rubber latex to prevent the weft threads from sliding along the long sides of the warp threads, which requires an additional process step which adversely affects the economics of the process.

Another significant disadvantage of using latices is the abrasion that occurs during weaving. The abrasion consists of electrically charged rubber particles, which are difficult and expensive to remove and can lead to weaving problems.

The object of the invention is to provide a method for producing a polyester thread which has a rough, non-slip surface, a secant modulus of 0 to 50%, an initial modulus> 4 cN / tex. high tensile elongation, poor shrinkage and good adhesion without the use of adhesive rubber latices. Such a weft thread should in particular meet the high thermal and mechanical loads during impregnation, calendering and later processing into vehicle tires.

This object is achieved according to the invention in that the weft thread is twisted at 40 to 200 U / m in a first process step and in a second process step the twisted thread is continuous for 0.1 to 60 s and at a temperature of 130 to 250 ° C. 22 to 55% is relaxed and tempered.

A thread twisted at 40 to 200 revolutions per meter has the advantageous property of roughness, which until now could only be achieved with a latex treatment. The thread twisted in this way is practically only with a process-related pretensioning force for 0.1 to 60 s, in particular for 0.1 to 30 s, preferably for about 0.2 s in a vertical or horizontal heating shaft at more than t30 ° C. in particular at 130 to 250 ° C., preferably at about 230 ° C. The short tempering time has the advantage that optimal properties of the weft threads are obtained without the known disadvantages at relatively high temperatures.

It is advisable to use POY yarn as the weft. A shock-like temperature treatment is particularly advantageous, since this results in minimal damage to the fibers and the best thread closure and a sliding-resistant surface are achieved. If necessary, a rubber-friendly treatment, for example based on epoxy or isocyanate, can also be carried out.

A targeted relaxation is achieved through a tension-free thermal treatment or with a controlled advance, which gives the thread a textured structure.

It is expedient to carry out the thermal treatment by means of a convection or contact heater. It is also possible to increase the degree of fixation by means of additional thermal after-treatments.

The elongation at break of the weft thread is between 150 and 350%. In general, particularly good results are obtained with an elongation at break of about 300%. This area has proven to be expedient for extreme loads, such as hot stretching at temperatures above 240 ° C.

In connection with the elongation at break, a thermal shrinkage of +6 to -6, at 160 ° C and 0.025 cN / tex thread tension, in particular a secant modulus of 0 to 50%, a reversibility limit of 0.2 to 0.6 cN / dtex and a Starting module from 4 to 10 cN / dtex is most appropriate.

A thread measurement variable that is independent of the titer is referred to as a secant module. The secant modulus is defined by the gradient of a distance within the force-elongation curve in the flow area of a thread limited between 10 + 30% elongation. Extending the distance up to 100% theoretical expansion and parallel displacement of the resulting straight line through the zero point of the coordinate system leads to a theoretical force at 100% theoretical expansion. The secant module defines this point as a percentage of the effective tensile strength (WO 84/02357).

The reversibility limit denotes the transition from the reversible to the irreversible stretching range.

The tensile strength of the thread is in the range of 0.6 to 2 cN / dtex and satisfies the stresses of the carcass fabric processed under normal tire production conditions.

The fibrils with irregular curvature cause a slight crimp, which contributes to the latex-free warp thread fixation in the carcass fabric.

A twist-free weft thread has the advantage that there are no running difficulties when canetting and weaving. It is advantageous to swirl the material in addition to the given rotations or to swirl exclusively. The intermingling points or the number of knots per meter should be limited to 10 to 120 in order to obtain the correct, compact thread closure that keeps the dip absorption during impregnation within the correct limits.

The invention will be explained in more detail using an example.

example

A POY polyester dtex 190 f 36 produces at a spinning speed of> 3000 m / min is twisted to 100 t / m and then passed through a convection dryer heated to 230 ° C with 100% lead over the winding. Instead of a convection dryer, a contact dryer is also suitable.

The resulting yarn has a titer of -385 dtex. Its initial modulus is 6.25 cN / tex, its reversibility limit is 0.4 cN / tex and its elongation at break is 285%.

The results of the thread produced according to the invention are summarized in the table below.

Claims (9)

I. Process for producing a heat-treated, rough thread made of polyester POY, preferably as a weft thread for a tire cord fabric, characterized in that the thread is twisted at 40 to 200 U / m in a first process step and the twisted thread continuously in a second process step during 0.1 to 60 s at a temperature of 10 to 250 ° C 20 to 55% is relaxed and annealed. 2. The method according to claims I and 2, characterized gekennzeihnet that the thermal treatment - is carried out in a shock. 3. The method according to claims I and 2, characterized in that the thermal treatment is carried out without tension or with controlled advance. 4. The method according to claims I to 3, characterized in that the thermal treatment is carried out by means of a convection or contact heater. 5. Thread produced by the process according to claims I to 4, characterized in that the thread simultaneously satisfies the following conditions: that the surface of the wire is rough and resistant to sliding, an elongation at break of 150 to 350%, a thermal shrinkage of +6 up to -6%, a secant modulus of 0 to 50%, a reversibility limit of 0.2 to 0.6 cN / dtex and an initial modulus of 4 to 10 cN / dex. 6. Thread according to claim 5, characterized by a tear strength of 0.6 to 3 cN / dtex. 7. Thread according to claims 5 and 6, characterized by fibrils with irregular curvatures. 8. Thread according to claims 5 to 7, characterized in that the thread is free from twisting. 9. Thread according to claims 6 to 8, characterized by a compact thread closure with 100 to 500 U / m and / or a swirl intensity of 10 to 100 swirl points per meter.