KR20060105808A - Fabric for sport garment and method for producing the same - Google Patents

Abstract

The present invention relates to a fabric for sports clothing, wherein the body of the polyurethane fabric, the adhesive coating layer and the far-infrared radiation coating layer is composed of an integral laminate of firmly bonded to each other, the far-infrared radiation coating layer is 50 to 80% by weight of polyurethane And 5 to 13% by weight of clam flour, 7 to 25% by weight of ceramic powder and 8 to 12% by weight of volatile solvent.

Sports clothing fabric according to the present invention of the structure as described above has a minimum of air resistance and excellent elasticity and at the same time radiate far infrared rays and negative ions to facilitate blood circulation during the exercise and promote metabolism to activate cell tissue and muscle By properly holding the muscles to prevent relaxation or stiffening of the muscles and cleansing and detoxification gives the body a comfortable, so that the athlete can maintain the best physical condition when worn.

far-infrared ray, negative ions, dissipation, air resistance, synergism

Description

Fabric for sport garments and its manufacturing method {fabric for sport garment and method for producing the same}

1 is an enlarged perspective view showing the overall structure of a fabric for sports clothing according to the present invention,

Figure 2 is a graph showing the far-infrared emissivity of the fabric for sports clothing according to the present invention,

3 is a graph showing the far-infrared radiation energy of the fabric for sports clothing according to the present invention,

Figure 4a is a thermal image photograph visually image the far-infrared emission on the body when wearing a garment made of a fabric for sports clothing according to the present invention,

Figure 4b is unlike the Figure 4a, the thermal image of the body before wearing the fabric for sports clothing according to the present invention,

Figure 5a is a micrograph showing the movement of red blood cells when 15 minutes after wearing the clothing made of fabric for sports clothing according to the present invention,

Figure 5b is a micrograph of the normal red blood cells of the tester in Figure 5a,

Figure 6 is an application example of the fabric for sports clothing according to the present invention, a front view showing the ice skating athlete is exercising after wearing the sportswear partially applied fabric of the present invention.

※ Explanation of symbols for main parts of drawing

A: Fabric 1 according to the present invention: Body

2: adhesive coating layer 3: far-infrared radiation coating layer

The present invention relates to a fabric for sports clothing and a method for manufacturing the same, more specifically, to a cloth for sports clothing and a method for manufacturing the same, which can lead to an optimal exercise state by reducing the air resistance and activating the body when wearing clothing It is about.

As is well known, the slightest reduction in air resistance in athletic competition is the key to winning. Therefore, athletes can reduce air resistance during exercise, such as wearing special sportswear to reduce air resistance, or even getting a little less air resistance and getting favorable results by moving closely behind other athletes in the course of the exercise. I am trying my best to find out how.

In particular, ice skates and swimmers wear sportswear made of polyurethane knitted fabric which is close to the body and has no air-containing layer to minimize air resistance and has excellent elasticity. These tracksuits, which are currently worn, are multifunctional specialty garments manufactured under highly developed textile technology, but athletes are still looking for tracksuits that can help the game to achieve even better results or results.

In addition, even when exercising with these high-performance sportswear on the market, the muscles of the legs were often stiffened or relaxed, which interfered with the exercise.

As an ice skating enthusiast, the inventors can press the body appropriately so that the sportswear not only minimizes air resistance but also goes further and prevents the leg muscles of the athletes from firming or relaxing. If he could activate the blood circulation smoothly, he would focus on developing new materials by encouraging him to be able to get a much better performance while helping exercise.

As a result, sports clothes with special functions that can minimize the air resistance as sportswear and at the same time light weight and emit far-infrared rays to facilitate the functioning of the body and hold the muscles properly to prevent muscle relaxation or stiffening. I developed a fabric.

The fabric for sports clothing according to the present invention is a laminate in which a main body, an adhesive coating layer and a far-infrared radiation coating layer of a polyurethane fabric are firmly bonded to each other;

The far-infrared radiation coating layer is composed of 50 to 80% by weight of polyurethane, 5 to 13% by weight of clam flour, 7 to 25% by weight of ceramic powder and 8 to 12% by weight of volatile solvent. It is characterized by consisting of a composition.

The main body of the polyurethane fabric is mainly an ultra-light, thin, highly stretchable fabric, and in some cases, the thickness thereof can be adjusted appropriately. In addition, as usual, a woven fabric or knitted fabric made of polyurethane fibers is applied, and since the knitted fabric has a higher elasticity in structure, it may be more preferably applied to various sports clothes.

Among the compositions constituting the far-infrared radiation coating layer in the fabric for sports clothing according to the present invention as the ceramic powder is well known barley, jadeite, nephrite, ocher, macsumite, hornblende, alumina, silica, quartz, quartzite, etc. A single or a mixture of two or more thereof is also applicable. In addition, these ceramic powders are applied in an amount of 7 to 25% based on the weight of the total composition, and when the lower limit of 7% by weight or less is added, the far infrared radiation is insignificant. As it increases, it should be adjusted within the above range, and the coating thickness is also appropriately selected according to the use and the season.

In addition, the ceramic powder is in a state that can emit more far infrared rays by the aid of shell powder added together, when the amount of shell powder is less than 5% by weight relative to the total composition interacts with the ceramic powder Since this becomes poor, it is inadequate, and when it exceeds 13 weight%, it is inadequate in the ratio adjustment with another component, and it must mix within the said range. The type of shellfish that can be applied is not particularly limited, and various shellfish powders such as abalone, clam shellfish, pearl clam, clam shell, mica clam, white sea clam, scallop clam, and white clam can be applied.

The volatile solvent facilitates the mixing of the components and improves the coating property with the main body as the volatiles fly away, and both known organic and inorganic solvents are applicable, and the amount thereof is less than the lower limit. It is important to add in the said range because coating property is poor, it does not mix well, and even if it exceeds the upper limit, the density | concentration of a composition is inadequate.

As shown in FIG. 1, the fabric A for sports clothing according to the present invention, as the adhesive is sprayed onto the back surface of the main body 1 of the polyurethane fabric, an adhesive coating layer 2 is formed thereon and far-infrared radiation thereon. Layer 3 is a laminate which is laminated and compacted and then dried under high temperature to bond integrally and firmly.

That is, in the present invention, the fabric for sports clothes A is coated with the adhesive on the conveyor into which the main body 1 of the polyurethane fabric is introduced, as in a conventional laminate forming process, to form an adhesive layer 2. After forming the far-infrared radiation coating layer (3) by applying a solution of far-infrared radiation material on the formed laminate, the fabric for sports clothes comprising a pressing step and a drying step passing through the pressure roller and then winding In the method of manufacturing (A),

50 to 80% by weight of polyurethane, 5 to 13% by weight of clam flour, 7-13% by weight of the mixed solution constituting the far-infrared radiation layer 3 applied on the main body 1 and the adhesive layer 2 of the polyurethane fabric. A composition composed of -25% by weight of ceramic powder and 8-12% by weight of volatile solvent, the composition being applied to a predetermined thickness to form the far-infrared radiation coating layer;

Thereafter, in the drying step before the winding-up step of the laminate, the volatile solvent is dried at a high temperature of 110 to 145 ° C with volatilization;

After the winding step, the laminate is also characterized in that it is produced through a aging step for 18 to 27 hours at 60 to 85 ℃.

Fabrics for sports clothing of the present invention manufactured through such a process is completely bound together through the special conditions of the bonding process and sufficient aging process to be integrated in the same form as a single fabric, so even during post-treatment process such as cutting or sewing process There is nothing to be done.

In order to understand more clearly the characteristics of the fabric for sports clothing according to the present invention will be described with reference to the following examples. However, it will be apparent to those skilled in the art that the present invention is not limited to this embodiment, but may be modified and modified within the spirit and scope of the claims. Percentages are given by weight).

(Example 1)

The main body 1 of the polyurethane fabric knitted with the polyurethane fiber was prepared previously.

The main body of the prepared polyurethane fabric is positioned with its back side facing up, and the polyurethane resin is applied onto the conveyor while the adhesive layer is formed thereon to form an adhesive layer, and 56% of polyurethane resin, 12% of shell powder, 24% of the ceramic powder and 8% of the volatile solvent were added and uniformly mixed to apply a thinly prepared composition to form a far-infrared radiation coating layer.

Then, the formed laminate was passed between press rollers to squeeze each layer to form an integral laminate, and then further dried under a high temperature of 125 ° C to volatilize the volatile solvent in the laminate.

Thereafter, after winding, the winding roll of the fabric was aged at 76 ° C. for 23 hours to finally complete the fabric for sports clothing.

The finished fabrics were commissioned by Korea Institute of Far-Infrared Application Evaluation and tested for their function. As a result, when the far-infrared emissivity (5-20 micrometers) and the radiation energy (W / m <2> micrometer, 37 degreeC) were measured using the FT-IR spectrometer, the high numerical value of 0.885 and 3.41x10 <^2> was shown, respectively. (See FIGS. 2 and 3).

In addition, the anion generation rate was commissioned by the Korea Far Infrared Application Evaluation Institute, using 100 × 150 mm of the fabric according to the present invention as a test piece. The temperature was 20 ° C. and 40% humidity using a charge particle measurement device under the KFIA-FI-1042 test method. When the anion release amount was measured under the condition of anion number 102 / cc in the air, the anion released from the specimen was 254 (ion number per unit volume: ION / cc), 2.5 times higher than in the air.

(Example 2)

 The fabric prepared in Example 1 was cut into a sleeved top, wherein the fabrics were completely integrally bound to each other and did not peel off.

In addition, when the fabric is sewn into the top of the cut fabric so that the main body is the surface and the far-infrared radiation layer is the back side, contrast with the thermal image of Figs. 4a, 4b to visually image the degree of far-infrared emission on the body. As shown, there is a marked difference in the temperature of the body.

In addition, as shown in the micrograph enlarged at 2000 magnification of FIGS. 5A and 5B, there was a significant difference in the movement of red blood cells. That is, when red blood cells are clustered as shown in FIG. 5B, oxygen supply is not smooth, but as shown in FIG. 5A, red blood cells are actively moved, and thus, the oxygen supply to the body is smoothly performed and blood circulation is actively performed.

(Example 3)

As shown in FIG. 6, the fabric finished in Example 1 was partially applied to the ice, skates, and shoulders, and was worn on ice skaters. As a result, the basic conditions as sportswear were satisfied. However, the elasticity is better and the body is free to move, and the blood circulation is good, there is no muscle paralysis or relaxation state. Fatigue was also less.

Fabric for sports clothing according to the present invention of the laminated structure as described above is a laminate of the main body of the polyurethane fabric, the adhesive coating layer and the far-infrared radiation layer, it is formed by being firmly bonded to each other integrally as a single fabric, cutting for sewing It does not peel off even at the time.

In addition, the fabric for sports apparel according to the present invention is excellent in minimizing air resistance and elasticity and at the same time smoothing the blood circulation of athletes to promote metabolism, reduce fatigue, activate cellular tissues and hold muscles appropriately to relax muscles It does not harden or harden, and furthermore, it anionizes the body and enhances the purification and detoxification action so that the athlete can maintain the best exercise state to obtain good results.

Fabric for sports clothing according to the present invention is somewhat expensive, but mainly applied to sportswear, but not necessarily limited to high-quality wallpaper or bedding, such as cushions, pillows, bed covers, etc. In this case, as in the above-mentioned clothing The effect can be obtained.

Claims (2)

In the sports garment fabric (A) which can minimize air resistance, The fabric (A) is a laminate in which the main body (1) of the polyurethane fabric, the adhesive coating layer (2) and the far-infrared radiation coating layer (3) are firmly bonded to each other; The far-infrared radiation coating layer 3 is composed of 50 to 80% by weight of polyurethane, 5 to 13% by weight of clam powder, 7 to 25% by weight of ceramic powder and 8 to 12% by weight of volatile solvent. . A step of forming an adhesive coating layer (2) by applying an adhesive to the back of the body (1) of the polyurethane fabric on a conveyor in which the body (1) of the polyurethane fabric is introduced, the far-infrared radiation coating layer on the adhesive coating layer (2) (3) A method of manufacturing a fabric for sporting clothing comprising a step of coating a mixed solution of a composition to form a step, a step of pressurizing the formed laminate through a pressure roller, and a step of drying and winding up; The far-infrared radiation coating layer (3) is formed by coating with a composition consisting of 50 to 80% by weight polyurethane, 5 to 13% by weight shell powder, 7 to 25% by weight ceramic powder and 8 to 12% by weight volatile solvent; In the drying step, the formed laminate is dried under a high temperature of 110 to 145 ° C and treated to volatilize the volatile solvent in the laminate; After the winding step, the winding roll of the laminate is subjected to a aging step for 18 to 27 hours at 60 to 85 ℃, the manufacturing method of the fabric for sports clothes.

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