JP6744627B2 - String for gut - Google Patents

Description

The present invention relates to a gut string for a racket such as a tennis racket.

As a form of the racket gut, there is one formed of a multifilament core material. Such multifilaments are generally subjected to processing such as impregnation of a resin as an adhesive between the filaments in order to improve durability such as wear resistance of the gut.

However, when processing with resin, it is necessary to select the resin that matches the material of the core material, select the processing temperature, and prepare the equipment for processing with the resin. Is complicated and may lead to higher costs. Further, it may lead to variations in gut performance due to resin adhesion unevenness. Furthermore, when an organic solvent is used in the resin processing, there are problems of toxicity and exhaust of the organic solvent, treatment of residual liquid, and the like.

In view of such a situation, two types of fibers, a high-melting point fiber and a low-melting point fiber, are used as the core material, and the core material is formed by melting and solidifying the low-melting point fiber only by heat treatment without undergoing a resin processing step. It has also been proposed that the gut surface be evenly covered with resin. Thereby, a string for gut having excellent durability is obtained (Patent Document 1).

Japanese Examined Patent Publication No. 5-060954

However, in the invention described in Patent Document 1, since two kinds of fibers are used for the core material, it is necessary to control both fibers in the production process, and the compounding ratio of both fibers is strictly controlled. Must. Furthermore, since the periphery of the core material is covered with another resin, it is necessary to manage that resin, and in the end, the same selection of resin and processing temperature as the old core material is made. However, the problem that the equipment for processing with resin is required and the previous process is complicated is still unsolved.

The present invention is intended to provide a string for gut in which the above problems are solved. That is, it is an object of the present invention to provide a string for a gut which has easy production control and does not have the above-mentioned special problems related to the working environment and hygiene in the manufacturing process.

The present inventors have not required to prepare two kinds of fibers by using the composite heat-fusible fiber as the material for the string for gut, and the composite heat fusion can be performed only by the heat treatment without the resin processing step. It has been found that the heat-fusible component of the adhesive fiber can be melted and solidified, whereby the multifilaments forming the gut can be adhered to each other, and the gut surface can be uniformly covered with the resin.

The gist of the present invention is as follows.

(1) Multi-filament including a composite-type heat-fusible fiber in which a low-melting point thermoplastic polymer and a high-melting point thermoplastic polymer having a higher melting point than the low-melting point thermoplastic polymer are composited and melt-solidified. The string for gut, wherein the filaments in the multifilament are adhered to each other by the low melting point thermoplastic polymer, and the surface of the multifilament is covered with the low melting point thermoplastic polymer.

(2) A core material composed of multifilaments or monofilaments, and a side thread composed of multifilaments, at least the multifilaments of the side threads containing composite heat-fusible fibers, The string for gut according to (1), characterized in that the core material and the side yarns or the side yarns are fixed by the melted and solidified low melting point thermoplastic polymer in the fusible fiber.

(3) The string for gut according to (1), which has a core material composed of multifilaments of the composite heat-fusible fiber and has no side yarn.

(4) The composite type heat-fusible fiber is a core-sheath type heat-fusible fiber in which a low-melting point thermoplastic polymer is arranged in the sheath part and a high-melting point thermoplastic polymer is arranged in the core part. The string for gut which is one of the features (1) to (3).

(5) The string for gut according to any one of (1) to (4), wherein the composite heat-fusible fiber is composed of a nylon resin or a polyester resin.

(6) A multi-filament is formed by a composite-type heat-fusible fiber obtained by compounding a low-melting point thermoplastic polymer and a high-melting point thermoplastic polymer having a higher melting point than the low-melting point thermoplastic polymer. A method for producing a string for gut characterized by melting and solidifying a low melting point thermoplastic polymer in a fusible fiber to bond filaments in a multifilament to each other and covering the surface of the multifilament with the low melting point thermoplastic polymer. ..

Since the string for gut of the present invention is composed of the multi-filament containing the composite heat-fusible fiber, the composite heat-fusible fiber itself has a high melting point component and a low melting point component, and thus one type You only need to use the fiber. For this reason, the production process is simplified as compared with the case of using two types of fibers, a high melting point fiber and a low melting point fiber. Further, since it is not necessary to use a resin for heat fusion, it is possible to solve all the problems when using this resin.

It is a figure which shows the string for gut of embodiment of this invention. It is a cross-sectional view of the string for gut of FIG. It is a cross-sectional view of an example of the composite heat-fusible fiber which constitutes the string for the gut. It is a cross-sectional view showing a state in which a large number of composite heat-fusible fibers are aggregated. FIG. 5 is a cross-sectional view showing a state in which the sheath portion of the fiber of FIG. 4 is melted and solidified. It is a cross-sectional view of the string for gut of other embodiment of the present invention. It is a cross-sectional view of the string for gut of another embodiment of the present invention.

(First embodiment)
As shown in FIGS. 1 and 2, the string for gut according to the first embodiment of the present invention has a core material 11 at the center and side threads 12 wound around the core material 11. Both the core material 11 and the side threads 12 are composed of multifilaments. Then, at least the multifilament of the side yarn 12 includes the composite heat-fusible fiber. That is, the multifilament of the side thread 12 contains the composite heat-fusible fiber and the multifilament of the core material 11 does not contain the composite heat-fusible fiber, or the multifilament of the side thread 12 and the core material 11 Both of the multifilaments of the present invention include composite heat fusible fibers. The string for gut of the first embodiment causes the core material 11 and the side threads 12 or the side threads 12 to adhere to each other by melting and solidifying only the heat-sealing component of the composite heat-fusible fiber, and the string. The surface can be evenly covered with resin.

The composite-type heat-fusible fiber is a fiber in which a low melting point thermoplastic polymer and a high melting point thermoplastic polymer having a higher melting point than the low melting point thermoplastic polymer are compounded. Examples of the composite form include a core-sheath type heat-fusible fiber in which a low-melting thermoplastic polymer is arranged in the sheath 13 and a high-melting thermoplastic polymer is arranged in the core 14, as shown in FIG. To be In addition, side-by-side type heat-fusible fibers in which a low-melting thermoplastic polymer and a high-melting thermoplastic polymer are arranged in half and the like. Considering that the low melting point thermoplastic polymer is melted and uniformly adhered and coated without impairing the original performance of the string for gut, the core-sheath type heat fusible fiber shown in FIG. 3 is preferable.

The low-melting point thermoplastic polymer and the high-melting point thermoplastic polymer in the composite heat-fusible fiber are preferably the same type of polymer in consideration of the compatibility of the both.

Further, considering the adhesiveness between the core material 11 and the side threads 12 shown in FIGS. 1 and 2, the polymer of the core-sheath type heat-fusible fiber of the core material 11 and the side threads 12 is finally heated by heat treatment. Since the fusion component is melted and solidified and the core material 11 and the side threads 12 or the side threads 12 are adhered to each other, it is preferable that the materials have good compatibility. From the viewpoint of adhesion durability, it is preferable that they are polymers of the same kind, and it is more preferable that they are the same material. For example, if the core material 11 is a polyester-based multifilament, the side thread 12 can also be a polyester-based multifilament. If the core material 11 is a nylon multifilament, the side thread 12 can also be a nylon multifilament.

The mass ratio of the low melting point thermoplastic polymer to the high melting point thermoplastic polymer in the composite type heat fusible fiber such as the core-sheath type heat fusible fiber shown in FIG. From the viewpoint of uniform resin coating, for example, the ratio of high melting point thermoplastic polymer/low melting point thermoplastic polymer is preferably 1/1 to 5/1, and particularly preferably 1.5/1 to 3.5/1.

The fineness, strength and elongation of the composite heat-fusible fiber are not particularly limited as long as the object of the present invention is achieved.

The cross-sectional shape of the composite heat-fusible fiber may be any of a round cross section, a modified cross section, a hollow cross section, etc., as long as the performance of the string is not impaired. Further, the fiber may be subjected to processing such as false twisting and Taslan processing.

The low-melting point thermoplastic polymer and the high-melting point thermoplastic polymer in the composite heat-fusible fiber are, independently of each other, a heat stabilizer, a crystal nucleating agent, a matting agent, and a pigment to the extent that the performance of the string is not impaired. Even if it contains additives such as, light resistance agent, weather resistance agent, lubricant, antioxidant, antibacterial agent, fragrance, plasticizer, dye, surfactant, flame retardant, surface modifier, various inorganic and organic electrolytes, etc. Good.

The core-sheath type heat-fusible fiber is commercially available. For example, "MELSET (registered trademark)" manufactured by Unitika Ltd. can be used.

As the composite heat-fusible fiber, two or more kinds of composite heat-fusible fibers having different melting points of low melting point thermoplastic polymer and high melting point thermoplastic polymer, mass ratio of both, fineness, strength and elongation, etc. Fibers may be used.

The low-melting point thermoplastic polymer may be any one having spinnability by melt spinning, and examples thereof include polyester-based polymers, polyamide-based polymers (nylon), polyolefin-based polymers, polybutyral-based polymers, polyacrylic-based polymers. Examples thereof include polymers, polyethylene-vinyl acetate copolymers and polyurethane polymers.

The melting point of the low melting point thermoplastic polymer is preferably 20° C. or more lower than the melting point of the high melting point thermoplastic polymer as the fiber forming component. With such a temperature, there is an advantage that the physical properties of the high melting point thermoplastic polymer are not affected even when subjected to heat treatment and the string form can be favorably maintained. The melting point of the low melting point thermoplastic polymer is preferably in the range of 80 to 160° C. in consideration of processability and various physical properties. When the low melting thermoplastic polymer does not have a definite melting point, the softening point of the low melting thermoplastic polymer is considered as the melting point.

A preferable combination of the low melting point thermoplastic polymer and the high melting point thermoplastic polymer is a low melting point polyester and a high melting point polyester, a low melting point polypropylene and a high melting point polypropylene, a polyethylene and a polypropylene, a low melting point polyester in consideration of compatibility and thermal adhesiveness of the both. Examples include melting point nylon and high melting point nylon.

As the core-sheath type heat-fusible fiber, specifically, a high melting point polyester having a melting point of 240° C. or higher is arranged in the core part, and a low melting point copolymerized polyester having a melting point of 110 to 200° C. is arranged in the sheath part. A core-sheath type polyester fiber having a melting point of 180° C. or higher and a high-melting point polyamide having a melting point of 180° C. or higher and a low-melting point polyamide having a melting point of 80 to 150° C. in a sheath part are preferably used. ..

In the string for gut of the first embodiment, as shown in FIG. 5, for example, by melting and solidifying only the sheath portion 13 as the heat-sealing component in the core-sheath heat-fusible fiber shown in FIG. The core material 11 and the side threads 12 or side threads 12 shown in FIGS. 1 and 2 are adhered to each other by the component 15 melted and solidified leaving the core portion 14, and the string surface is made uniform as understood from FIG. It can be covered with resin.

As a method of melting the low melting point thermoplastic polymer which is a heat fusion component, heat treatment can be mentioned. The heat treatment is a treatment for holding the string for gut at an ambient temperature higher than the melting point of the low melting point thermoplastic polymer. As a result, in the composite heat-fusible fiber, the core material 11 and the side threads 12 or the side threads 12 shown in FIGS. 1 and 2 are bonded to each other by melting and solidifying the low-melting point thermoplastic polymer that is the heat-sealing component. Can be made When all the single filaments of the multifilament of the side yarn 12 are all uniform core-sheath type heat-fusible fibers, the heat-fusible component is uniformly melted and solidified, so that the gut surface is uniformly resin. Can be covered with.

When using two or more kinds of composite thermofusible fibers each containing a different low melting point thermoplastic polymer, the melting point of the low melting point thermoplastic polymer having the highest melting point is used as a reference, The heat treatment may be performed at an ambient temperature higher than the melting point of the plastic polymer. The atmosphere temperature during the heat treatment is preferably higher than the melting point of the low melting point thermoplastic polymer and lower than the melting point of the high melting point thermoplastic polymer. If the ambient temperature is too high, not only is it disadvantageous in terms of cost, but also the high melting point thermoplastic polymer is damaged by heat, and the strength of the string decreases. The ambient temperature is preferably Mp _L +5° C. or higher and less than Mp _L +20° C. when the melting point of the low melting point thermoplastic polymer is expressed as Mp _L.

The heat treatment may be carried out for a time such that the low melting point thermoplastic polymer is sufficiently melted. However, if the heat treatment time is too long, not only is it disadvantageous in terms of cost, but also the high melting point thermoplastic polymer is damaged by heat, and the strength of the entire string decreases. Therefore, the heat treatment time is preferably 30 seconds to 5 minutes, more preferably 1 minute to 3 minutes. The heating method for applying the heat treatment is not particularly limited, and well-known means such as an iron, a hot air welding machine, a hot air dryer, and a tenter machine can be used.

(Second embodiment)
The gut string according to the second embodiment of the present invention is different from the gut string according to the first embodiment in that the core material 11 is composed of a monofilament, as shown in FIG. As in the case of the first embodiment, the monofilament constituting the core material 11 is either composed of the composite heat-fusible fiber or is not composed of the composite heat-fusible fiber. is there. Other than that, it is the same as the first embodiment.

(Third Embodiment)
As shown in FIG. 7, the string for gut according to the third embodiment of the present invention has a core material 11 made of multifilament and no side thread. Other than that, it is the same as the first embodiment.

Next, the present invention will be specifically described with reference to examples. The strings were evaluated in the following examples and comparative examples by the following method.

1. Adhesiveness between core material and side thread According to JIS L-1013, a tensile test of a string is performed at a sample length of 250 mm and a pulling speed of 300 mm/min, and when the string is broken, the core material and the side thread are simultaneously formed. Whether it breaks or separates was observed and evaluated according to the following criteria.
(Adhesiveness)
◯: Core material and side thread are broken at the same time X: Core material and side thread are separated and broken

2. Abrasion resistance of core material A load of 0.25g per decitex is applied to a string, and it is used in conformity with JIS D4604 for OCHI FILE WORK's company's round file (300m/m, (12″) round medium grain). The test pieces were brought into contact with each other at an angle of 90 degrees, and the stroke width was 330±30 mm, and the stroke speed was 30±1 times/min.
In addition, the following judgment was made by visually observing the state of the surface of the string when reciprocally rubbed.
(Surface condition)
○: The surface of the string is not fluffed ×: The surface of the string is fluffed

(Manufacture of nylon-based core-sheath heat-fusible fiber)
Melt spinning was performed using separate extruder type spinning machines so that the core was made of nylon 6 resin (Unitika, BRF) and the sheath was made of copolymer nylon (Arkema, PLATAMID M1425F, melting point 155°C). Stretching and relaxation heat treatment were performed (core:sheath mass ratio of 2.7:1) to obtain 1400 dtex 192 filaments and 235 dtex 48 filaments of nylon core-sheath type heat-fusible fibers.

(Example 1)
Six 1400 dtex 192 filaments of nylon core-sheath type heat-fusible fibers were aligned to form a core material. Around this core material, ten nylon-sheath type heat-fusible fibers of 235 dtex 48 filaments were spirally wound. Next, this was passed through a hot air drier set at 170° C. for 2 minutes to be heat treated to obtain a string for gut.

As a result of evaluating the obtained string, the adhesiveness was ◯, and the core material and the side threads were adhered to each other without peeling.

(Example 2)
Six single-phase nylon multifilaments of 1,400 dtex192 filaments were aligned and used as a core material. Around this core material, ten nylon-sheath type heat-fusible fibers of 235 dtex 48 filaments were spirally wound. Next, this was passed through a hot air drier set at 170° C. for 2 minutes to be heat treated to obtain a string for gut.

As a result of evaluating the obtained string, the adhesiveness was ◯, and the core material and the side threads were adhered to each other without peeling.

(Example 3)
Six 1670 dtex192 filament polyester core-sheath type heat-fusible fibers (MELSET (registered trademark) manufactured by Unitika Ltd.) were aligned to form a core material. Around the core material, ten 280T48 filament polyester core-sheath type heat-fusible fibers (MELSET (registered trademark) manufactured by Unitika Ltd.) were spirally wound. Next, this was passed through a hot air drier set at 170° C. for 2 minutes to be heat treated to obtain a string for gut.

As a result of evaluating the obtained string, the adhesiveness was ◯, and the core material and the side threads were adhered to each other without peeling.

(Example 4)
Six 1670 dtex 192 filament single-phase polyester multifilaments were aligned to form a core material. Around the core material, ten 280T48 filament polyester core-sheath type heat-fusible fibers (MELSET (registered trademark) manufactured by Unitika Ltd.) were spirally wound. Next, this was passed through a hot air drier set at 170° C. for 2 minutes to be heat treated to obtain a string for gut.

As a result of evaluating the obtained string, the adhesiveness was ◯, and the core material and the side threads were adhered to each other without peeling.

(Example 5)
A nylon 6 monofilament having a diameter of 0.93 mm was used as a core material, and four nylon-sheath type heat-sealing fibers of 235 dtex 48 filament were wound around the core material. Then, 16 nylon core-sheath type heat-fusible fibers of 235 dtex 48 filaments were braided around the outer circumference. This was passed through a hot air dryer set at 170° C. for 2 minutes for heat treatment to obtain a string for gut.

As a result of evaluating the adhesiveness of the obtained string, the adhesiveness was ◯, and the core material and the side threads were adhered without peeling.

(Example 6)
Using a polyester monofilament having a diameter of 0.93 mm as a core material, four polyester-sheath-type heat-fusible fibers (MELSET (registered trademark) manufactured by Unitika Ltd.) of 280T48 filaments were wound around the core material. Next, 16 pieces of 280T48 filament polyester core-sheath type heat-fusible fibers (MELSET (registered trademark) manufactured by Unitika Ltd.) were further braided on the outer circumference. This was passed through a hot air dryer set at 170° C. for 2 minutes for heat treatment to obtain a string for gut.

As a result of evaluating the adhesiveness of the obtained string, the adhesiveness was ◯, and the core material and the side threads were adhered without peeling.

(Comparative Example 1)
A nylon 6 monofilament having a diameter of 0.93 mm was used as a core material, and four 235 dtex nylon monofilaments were wound around the core material. Next, 16 235 dtex nylon 6 monofilaments were further braided around the outer circumference. This was passed through a hot air dryer set at 170° C. for 2 minutes for heat treatment to obtain a string for gut.

As a result of evaluating the adhesiveness of the obtained string, the adhesiveness was x, and the core material and the side threads were separated.

(Comparative example 2)
A nylon 6 monofilament having a diameter of 0.93 mm was used as a core material, and four 280 dtex polyester monofilaments were wound around the core material. Next, 16 pieces of 280 dtex nylon 6 monofilament were further braided on the outer circumference. This was passed through a hot air dryer set at 170° C. for 2 minutes for heat treatment to obtain a string for gut.

As a result of evaluating the adhesiveness of the obtained string, the adhesiveness was x, and the core material and the side threads were separated.

(Example 7)
Eight 1400 dtex192 filaments of nylon core-sheath type heat-fusible fiber were aligned and used as a core material, and the core material was twisted at 200 T/m. Next, this was passed through a hot air dryer set at 170° C. for 2 minutes to be heat-treated, and a string for gut having only a core material and no side thread was obtained.

Table 1 shows the results of evaluating the abrasion resistance of the obtained strings. As shown in Table 1, the abrasion resistance was good, and the strings were not easily fluffed even when worn.

(Example 8)
Eight pieces of 1670 dtex192 filament polyester core-sheath type heat-fusible fibers (MELSET (registered trademark) manufactured by Unitika Ltd.) were aligned to form a core material, and the core material was twisted at 200 T/m. Then, this was passed through a hot air dryer set at 170° C. for 2 minutes to be heat-treated, and a string for gut having only a core material and no side thread was obtained.

Table 1 shows the results of evaluating the abrasion resistance of the obtained strings. As shown in Table 1, the abrasion resistance was good, and the strings were not easily fluffed even when worn.

(Comparative example 3)
Eight single-phase nylon multifilaments of 1,400 dtex 192 filaments were aligned and made into a core material, and the core material was twisted at 200 T/m. Then, nylon 6 resin was extrusion-coated on the surface of the twisted yarn, and a squeeze coating layer was formed using a 1.3 mm nozzle to obtain a string for gut having only the core material and no side yarn.

Table 1 shows the results of evaluating the abrasion resistance of the obtained strings. As shown in Table 1, the wear resistance of the obtained strings was poor as compared with Examples 5 and 6. In particular, the surface condition of the string was x. That is, the resin on the string surface was peeled off and the filament of the core material was fluffed.

11 core material 12 side thread

Claims (6)

A low melting point thermoplastic polymer and a multi-filament including a composite type heat fusible fiber in which a high melting point high melting point thermoplastic polymer having a higher melting point than the low melting point thermoplastic polymer is compounded, and melted and solidified. A string for a gut characterized in that the filaments in the multifilament are adhered to each other by the melting point thermoplastic polymer, and the surface of the multifilament is covered with the low melting point thermoplastic polymer. It has a core material composed of multifilaments or monofilaments, and side yarns composed of multifilaments, and at least the multifilaments of the side yarns include composite heat-fusible fibers The string for gut according to claim 1, wherein the core material and the side threads or the side threads are fixed to each other by the melt-solidified low melting point thermoplastic polymer in the fiber. The string for gut according to claim 1, which has a core material composed of multifilaments of the composite heat-fusible fiber and has no side yarn. The composite heat-fusible fiber is characterized in that it is a core-sheath heat-fusible fiber in which a low-melting point thermoplastic polymer is arranged in the sheath part and a high-melting point thermoplastic polymer is arranged in the core part. The string for gut according to any one of claims 1 to 3. The gut string according to any one of claims 1 to 4, wherein the composite heat-fusible fiber is made of a nylon resin or a polyester resin. A multi-filament is formed by a composite-type heat-fusible fiber in which a low-melting point thermoplastic polymer and a high-melting point thermoplastic polymer having a higher melting point than this low-melting point thermoplastic polymer are combined to form a multi-filament. A method for producing a string for gut, which comprises melting and solidifying a low-melting point thermoplastic polymer in a fiber to bond the filaments in the multifilament to each other and covering the surface of the multifilament with the low-melting point thermoplastic polymer.