JP3192854U - Far-infrared radioactive clothing - Google Patents

Abstract

[PROBLEMS] To form a garment using a pitch-based carbon fiber non-woven fabric or an acrylic-based carbon fiber precursor fiber non-woven fabric as a part of a fabric composing the garment, thereby reducing the far-infrared radiation function without lowering the texture. Providing clothing that can be fully used.
A synthetic fiber comprising a carbonized fiber nonwoven fabric 1 selected from a pitch-based carbon fiber nonwoven fabric or a carbon fiber precursor fiber nonwoven fabric of acrylic fiber at a site where a far-infrared radiation function is necessary, comprising a natural fiber and a polymer polymer. A far-infrared radiation garment that is used by being overlapped with a fabric 2 containing at least one selected from the group consisting of semi-synthetic fibers and regenerated fibers.
[Selection] Figure 1

Description

  The present invention relates to a far-infrared radiation garment having a function of emitting far-infrared rays by absorbing far-infrared rays emitted by the body.

  Far-infrared radioactive ceramic powder such as far-infrared radioactive alumina, silica, magnesia, zirconia, or far-infrared radioactive material such as germanium powder is mixed in synthetic fiber made of high polymer, regenerated fiber such as rayon or acetate, or semi-synthetic fiber. Far-infrared rays on the surface of clothing made of spinning fibers containing infrared radiation, synthetic fibers made of high molecular polymers, regenerated fibers such as rayon and acetate, semi-synthetic fibers, natural fibers, or fabrics made from these In recent years, development of clothing to which radioactive substance powder or the like is attached has been actively performed (see the following patent document).

  Far-infrared rays have a wavelength of about 3 to 1000 μm, and are absorbed by the body skin and converted into heat, so that a thermal effect is exerted, and has a function of warming and keeping the body, especially a wavelength of about 8 to 14 μm. Far infrared rays are said to be indispensable to the human body. The average human body temperature is 36.5 ° C., which is about 10 μm in terms of far infrared wavelength. Recently, hypothermia has been shown to decrease immunity, and the incidence of cancer is higher in older people than in younger people, while older people gradually become less muscular and therefore generate less heat, resulting in lower body temperature. It is said that one of the factors is that the immunity tends to decrease and the immune ability decreases. Therefore, in the medical field, heat-insulating clothing using the thermal effect of far-infrared rays has come to be emphasized.

Therefore, in a garment composed of fibers containing an infrared radioactive material that has been spun by mixing a powder of a far infrared radioactive material as described above, if a large amount of the far infrared radioactive material is contained, spinning and / or stretching becomes difficult. Or because the fiber strength decreases,
In reality, only a fiber containing a far-infrared radioactive material of about 25% by weight at most is put into practical use. Even in this case, a fiber containing 25% by weight of a far-infrared radioactive material is a far-infrared radioactive material. Since the strength and texture are reduced compared to normal fibers not containing garments, in reality, fabrics of clothing are hardly formed with 100% fibers containing far-infrared radioactive materials. Actually, it is used in an amount of 10% by weight or less by blending with ordinary fibers, blending, union, union, etc. Moreover, since the ceramic powders as described above do not have a far-infrared radiation function so much, it is a reality that the thermal effect of clothing using these fibers cannot be said to be sufficient. In addition, as described above, the far-infrared radioactive material to be applied to the clothing having the far-infrared radioactive material attached to the surface of the fiber or fabric is not so large as described above. When a far-infrared radioactive substance is adhered, there is a problem that the texture of the obtained clothing is lowered. Moreover, there is a problem that it is easy to drop off by washing depending on how it is attached.

Japanese Patent Laid-Open No. 3-51301 JP-A-3-190990 JP 2002-161429 A Japanese Patent Laid-Open No. 2006-219779

  In order to improve the problems of the conventional clothing having far-infrared radiation function and to further enhance the far-infrared radiation function, the present invention is a pitch-based carbon fiber nonwoven fabric or acrylic based on a part of the fabric constituting the clothing. It aims at providing the clothing which can fully exhibit a far-infrared radiation | emission function, without reducing a texture by comprising clothing using the carbon fiber precursor fiber nonwoven fabric of a fiber.

  In order to solve the above problems, the clothing of the present invention is as follows.

  (1) A group in which a pitch-based carbon fiber nonwoven fabric or a carbon fiber precursor fiber nonwoven fabric of acrylic fiber is formed of natural fibers, synthetic fibers made of a polymer, semi-synthetic fibers, and regenerated fibers at a site where the far infrared radiation function is necessary A far-infrared radiation garment characterized by being used in a layered manner with a fabric containing at least one selected from

  (2) In the apparel described in (1), the pitch-based carbon fiber nonwoven fabric or the carbon fiber precursor fiber nonwoven fabric of the acrylic fiber is provided with a plurality of short cuts, whereby the nonwoven fabric is at least 2 The nonwoven fabric is preferably stretchable in the direction.

  (3) In the garment described in (2) above, the short cut is such that another cut adjacent to the lengthwise tip of the one cut interrupts the tip direction of the length of the one cut. It is preferable that it consists of the repeating aspect of the arrangement | positioning aspect of the cut | disposition arrange | positioned in such an aspect.

  (4) In the garment described in any one of the items (2) to (3), the short cut is preferably a straight cut having a length of about 1 to 4 cm.

(5) In the garment described in any one of the above items (1) to (4), the pitch-based carbon fiber nonwoven fabric or the carbon fiber precursor fiber nonwoven fabric of acrylic fiber is a natural fiber, a polymer polymer A mode in which the synthetic fiber, the semi-synthetic fiber, and the fabric containing at least one selected from the group consisting of recycled fibers are used in an overlapping manner,
A fabric containing at least one selected from the group consisting of a carbon fiber precursor fiber nonwoven fabric of pitch-based carbon fiber nonwoven fabric or acrylic fiber, selected from the group consisting of A, natural fibers, synthetic fibers composed of polymer polymers, semi-synthetic fibers, and regenerated fibers Is B,
(A) A mode in which A is laminated to B by point adhesion in terms of the reciprocal number,
(B) A mode in which B is overlapped on both sides of A, and at least one side of A is laminated to B by point bonding in terms of the reciprocal number,
(C) A mode in which B is used on both sides of A, and these three layers are stitched together in a quilting shape (d) A mode in which A is inserted into B in a bag-like shape,
It is preferable that it consists of any one or more aspect chosen from these.

  (6) In the garment described in any one of the above items (1) to (5), a fabric selected from the group consisting of natural fibers, synthetic fibers made of a polymer, semi-synthetic fibers, and regenerated fibers. It is preferably a fabric made of woven fabric or knitted fabric.

  (7) In the clothing according to any one of (1) to (6), the thickness of the fibers constituting the pitch-based carbon fiber nonwoven fabric or the carbon fiber precursor fiber nonwoven fabric of acrylic fiber is small. It is preferable that it is 8-30 micrometers.

  (8) In the garment described in any one of the items (1) to (7), the basis weight of the pitch-based carbon fiber nonwoven fabric or the carbon fiber precursor fiber nonwoven fabric of acrylic fiber is 30 to 120 g / m2 is preferred.

  (9) In the garment described in any one of (1) to (8) above, the garment is a garment selected from underwear, abdomen, supporter, socks, muffler, gloves, hat, and outer garment. Is preferred.

  In the apparel of the present invention, the pitch-based carbon fiber non-woven fabric or the acrylic fiber carbon fiber precursor fiber non-woven fabric is present at the far infrared radiation function required site, so that the acrylic fiber carbon fiber precursor fiber non-woven fabric is high. Infrared radiation function, pitch-based carbon fiber has a very high far-infrared radiation function, and is also a pitch-based carbon fiber or a carbon fiber precursor fiber of acrylic fiber and made into a nonwoven fabric, When far-infrared rays are absorbed by a part of the nonwoven fabric, not only the portion that has absorbed far-infrared rays, but also the pitch-based carbon fiber nonwoven fabric or the carbon fiber precursor fiber nonwoven fabric of acrylic fibers that are continuous from that portion. Non-woven fabric or acrylic fiber made of pitch-based carbon fibers that can easily propagate and diffuse to other parts, and can easily radiate far-infrared rays from other parts. Carbon fiber precursor fiber non-woven fabric can be made into a non-woven fabric with a very soft texture compared to polyacrylonitrile fiber (so-called PAN-based) carbon fiber, so far-infrared radiation function without reducing the texture Can be provided. In addition, pitch-based carbon fiber nonwoven fabrics or acrylic fiber carbon fiber precursor fiber nonwoven fabrics are selected from the group consisting of natural fibers, synthetic fibers composed of polymer polymers, semi-synthetic fibers, and regenerated fibers. In other words, it is selected from the group consisting of natural fibers, synthetic fibers composed of high molecular polymers, semi-synthetic fibers, and regenerated fibers, except for the portions that require the far infrared radiation function. Since the garment is formed of a normal cloth containing at least one selected from the above, the far infrared radiation function-necessary portion is not formed only of the pitch-based carbon fiber nonwoven fabric or the acrylic fiber carbon fiber precursor fiber nonwoven fabric. , Keeps strength as clothing, reduces the occurrence of pilling, etc., or pitch-based carbon fiber nonwoven fabric or acrylic on the clothing surface (Otemen) side. Since it is possible to Le fiber precursor fiber of carbon fiber nonwoven fabric is a structure not exposed, it is possible to also decrease the clothing appearance to prevent possible clothing.

  In addition, by placing discontinuous short cuts in the carbon fiber precursor fiber nonwoven fabric of pitch-based carbon fiber or acrylic fiber, the far-infrared radiation function necessary part of the garment corresponds to the part requiring stretchability. Even in such a case, the clothes can easily follow and elongate, and can be made into a garment having a good wearing feeling without causing a feeling of tension. In the present invention, the term carbonized fiber nonwoven fabric is used generically for pitch-based carbon fiber nonwoven fabric and acrylic fiber carbon fiber precursor fiber nonwoven fabric.

The typical sectional view of the lamination cloth which shows one mode of the lamination state of the cloth which consists of carbonized fiber nonwoven fabric and the usual fiber of clothing of the present invention. The typical sectional view of the lamination cloth which shows another one mode of lamination of the cloth which consists of carbonized fiber nonwoven fabric of clothes of the present invention, and usual textiles. The typical sectional view of the lamination cloth which shows another one mode of the lamination state of the cloth which consists of carbonized fiber nonwoven fabric and the usual fiber of clothing of the present invention. The typical sectional view of the lamination cloth which shows another one mode of the lamination state of the cloth which consists of carbonized fiber nonwoven fabric and the usual fiber of clothing of the present invention. The typical sectional view of the lamination cloth which shows another one mode of the lamination state of the cloth which consists of carbonized fiber nonwoven fabric and the usual fiber of clothing of the present invention. The typical sectional view of the lamination cloth which shows another one mode of the lamination state of the cloth which consists of carbonized fiber nonwoven fabric and the usual fiber of clothing of the present invention. The top view of the one example of the carbonized fiber nonwoven fabric 1 for showing typically the said cut | interruption provided with two or more discontinuous short cuts in the carbonized fiber nonwoven fabric used by this invention. The perspective view seen from the diagonal upside of the cylindrical supporter which is clothing of the present invention. The front view at the time of squashing the cylindrical supporter of FIG. FIG. 9 is an end view of a substantially half-circumferential portion of the supporter in the DD ′ cross section of FIG. 8.

  In the apparel of the present invention, a pitch-based carbon fiber nonwoven fabric or an acrylic fiber carbon fiber precursor fiber nonwoven fabric is formed from natural fibers, synthetic fibers composed of a polymer, semi-synthetic fibers, and recycled fibers at the far infrared radiation function necessary site. It is used overlapping with a fabric containing at least one selected from the group consisting of: Hereinafter, the carbon fiber precursor fiber nonwoven fabric of pitch-based carbon fiber or acrylic fiber may be abbreviated as “carbonized fiber nonwoven fabric” or A as an abbreviation. Similarly, a fabric containing at least one selected from the group consisting of natural fibers, synthetic fibers composed of high molecular polymers, semi-synthetic fibers, and regenerated fibers may be abbreviated as “fabric composed of normal fibers” or B. The expression of synthetic fiber as “synthetic fiber made of a polymer” is to be interpreted that carbon fiber and carbon fiber precursor fiber are also included in the expression of synthetic fiber in some cases, and are difficult to distinguish. Therefore, it is expressed as “synthetic fiber made of a high molecular polymer” and is generally used for clothing such as polyester fiber, polyamide fiber, acrylic fiber, polyolefin fiber, polyurethane fiber, vinylon fiber, and polyvinylidene chloride fiber. It is intended to mean ordinary so-called synthetic fibers, and is not particularly limited to special ones. In the present invention, rubber fibers that are optionally used for supporters and the like are also included in the expression “synthetic fibers made of a polymer”.

  In the apparel of the present invention, as described above, the carbonized fiber non-woven fabric and the fabric B fabric made of ordinary fibers are used in an overlapping manner at the far infrared radiation function-necessary part. When the state is shown by the schematic cross-sectional shape of the laminated fabric, for example, the modes shown in FIGS. 1 to 6 are preferably exemplified.

  The mode shown in FIG. 1 is a mode in which the carbonized fiber nonwoven fabric A (symbol 1) is laminated to the fabric B (symbol 2) made of normal fibers by point bonding with an adhesive 3 or the like. Usually, the far-infrared radiation effect is that the fabric B (reference numeral 2) made of normal fibers is used on the outer side of the garment and the carbonized fiber nonwoven fabric A (reference numeral 1) is on the back side (skin side) of the garment. From the point of a certain thermal effect, the point which keeps the external appearance of clothing favorable, etc. are preferable. Since the carbonized fiber nonwoven fabric A may cause pilling depending on the type, it is preferable to use the above-described aspect in this sense as well in that the appearance of the clothes is kept good. Carbonized fiber nonwoven fabric A can be made into a nonwoven fabric that is extremely soft and comfortable compared to PAN-based carbon fibers used in carbon fiber reinforced plastics, and is softer than ordinary spunbond synthetic fiber nonwoven fabrics. It can be made into a non-woven fabric with a good touch.

  In the embodiment shown in FIG. 2, a fabric B (reference numeral 2) made of normal fibers is used on both sides of a carbonized fiber nonwoven fabric A (reference numeral 1), and one side of A is reconstructed with adhesive 3 or the like on B. It is the aspect laminated | stacked by point adhesion at the point. In this case, the fabric B (reference numeral 2) made of normal fibers on the front and back surfaces may be the same fabric, or may be a different type of fabric depending on the purpose. Although it depends on the type of clothing, a different type of fabric is often used as the fabric B (reference numeral 2) composed of normal fibers on the front and back surfaces. Moreover, in FIG. 2, it is arbitrary whether the upper side of a figure is made into the outer side surface (front side surface) or back side surface (skin side surface) of clothing. Although not shown, the front and back surfaces of A may be laminated to B by point bonding with an adhesive 3 or the like as required, but it is possible to follow the elongation when wearing clothing. From the viewpoint of feeling and the like, a mode in which one side of A is laminated to B by point bonding in terms of the number of reversals with adhesive 3 or the like is preferable. In this case, B, which is not bonded to A, is sewn with three layers B / A / B at the edges of the parts (clothing components) using this when forming clothing. The non-bonded B does not fall off. In this aspect, since the carbonized fiber nonwoven fabric A is not exposed on the front and back surfaces of the garment, the appearance of the garment is kept good and the washing resistance of the garment is improved.

  In the case of laminating by point bonding in the point of reversal with an adhesive as in the embodiment shown in FIG. 1 and FIG. 2, the adhesive is not particularly limited as long as it can be adhered by point adhesion, but it is a hot melt type adhesive. Is easy to use. The hot-melt type adhesive may be appropriately selected from known hot-melt type adhesives as long as it can bond the carbonized fiber nonwoven fabric A and the fabric B made of normal fibers, and is usually made of fibers. For example, polyamide hot-melt adhesive, polyolefin hot-melt adhesive, polyester hot-melt adhesive, thermoplastic polyurethane hot-melt adhesive, depending on the fibers constituting the fabric B And ethylene-vinyl alcohol-based hot-melt adhesives.

  Next, the embodiment shown in FIG. 3 is an embodiment in which a fabric B (reference numeral 2) made of normal fibers is used on both sides of a carbonized fiber nonwoven fabric A (reference numeral 1), and these three layers are stitched together in a quilting shape. Yes, 4 schematically shows a stitching line for quilting. In this case, the fabric B (reference numeral 2) made of normal fibers on the front and back surfaces may be the same fabric, or may be a different type of fabric depending on the purpose. Although it depends on the type of clothing, a different type of fabric is often used as the fabric B (reference numeral 2) composed of normal fibers on the front and back surfaces. Also in this aspect, the carbonized fiber nonwoven fabric A is not exposed on the front and back surfaces of the clothing, so that the appearance of the clothing is kept good and the washing resistance of the clothing is improved.

  In the embodiment shown in FIG. 4, a fabric B (reference numeral 2) made of normal fibers is used on both sides of a carbonized fiber nonwoven fabric A (reference numeral 1), and A is inserted into the bag-shaped B. It is an aspect. Reference numeral 5 denotes a stitching line for forming a fabric B (reference numeral 2) made of normal fibers on the front and back surfaces into a bag shape. Although not shown, the edges located on the front and back sides of the paper shown in FIG. 4 are usually stitched to form the fabric B (reference numeral 2) in a bag shape. Such stitches may be stitched in advance, but may also be stitched when stitching with other parts when forming clothing. In such a case, a water-soluble adhesive (water-soluble hot-melt type) is used between the three layers so that the position of the three layers B / A / B is not shifted during the stitching operation so that the stitching operation becomes difficult. Adhesive is preferable, and it is preferable that the adhesive is preferably point-bonded at the point of reversion as described above), and the water-soluble adhesive is removed with water at an appropriate time such as after the sewing of clothing is completed. May be adopted. In the laminated form shown in FIG. 4 as well, the carbonized fiber nonwoven fabric A is not exposed on the front and back surfaces of the garment, so that the appearance of the garment is kept good and the washing resistance of the garment is improved. Moreover, since A is not bonded to B, it is a very preferable embodiment from the viewpoints of stretch following ability and feeling of tension when wearing clothing. When using a water-soluble hot melt type adhesive, it is not particularly limited. For example, a polyvinyl alcohol-based water soluble hot melt type adhesive described in JP-A-5-65465, manufactured by Nippon Synthetic Chemical Industry Co., Ltd. For example, “Ecomati”.

  Next, the embodiment shown in FIG. 5 is basically the same as the embodiment in which A is inserted into the bag-shaped B described in FIG. Rather than sewing and closing the periphery, a part of the edge of B is opened without opening, and the carbonized fiber nonwoven fabric A (reference numeral 1) is made of normal fibers as necessary. This is an aspect in which the cloth B (reference numeral 2) can be taken in and out of the bag-like space. For example, when this aspect is adopted for a breast cup part of a female apparel having a brassiere, body suit or other breast cup, a plurality of types of carbonized fiber nonwoven fabrics A having different thicknesses are prepared and replaced according to preference. There is an advantage such as easy replacement when the carbonized fiber nonwoven fabric A is used or deteriorated after multiple washings. This is not limited to women's clothing having any breast cups, and can be applied to supporters, stomachbands, shorts, girdles, various underwear, outer garments, trousers and almost all other clothing.

  In the embodiment shown in FIG. 6, a fabric B (reference numeral 2) made of normal fibers is used on both sides of the carbonized fiber nonwoven fabric A (reference numeral 1), and A is inserted into a large number of bag-shaped forms B. It is the aspect which is. That is, it can be said that the aspect shown in FIG. Reference numeral 5 denotes a stitching line for forming a fabric B (reference numeral 2) made of normal fibers on the front and back surfaces into a bag shape. The carbonized fiber nonwoven fabric 1 is inserted in each bag-like space of the fabric B (reference numeral 2). The carbonized fiber nonwoven fabric 1 is usually not bonded to the fabric B (reference numeral 2) made of ordinary fibers. However, if necessary, for example, only a part of the carbonized fiber nonwoven fabric 1 is spot-bonded with the hot-melt adhesive described above. Good. In this aspect, for example, in the case of forming an apparel that needs to be stretched considerably when worn, such as a supporter, the fabric B (reference 2) is made of a stretchable fabric, so that the fabric B (reference 2) and the carbonized fiber are formed. When the nonwoven fabrics 1 are not substantially bonded to each other or only a part is bonded to the fabric B (reference numeral 2), the carbonized fiber nonwoven fabric 1 does not expand and contract even if the fabric B (reference numeral 2) expands or contracts. This is a preferred embodiment because it does not interfere.

  In addition, when bonding with the adhesive shown in FIGS. 1 and 2, an aluminum film is point-bonded with a hot-melt adhesive on the back side (skin side) of the fabric B instead of the fabric B (reference numeral 2) made of ordinary fibers. A fabric / aluminum film laminated fabric, for example, manufactured by Hoonaga Co., Ltd., which is provided with a hot-melt adhesive so that it can be further point-bonded with the hot-melt adhesive on the surface of the aluminum film opposite to the fabric B. A “thermoface” or the like can also be used. When this is used, it is presumed that fine holes will open in the aluminum film, and it can prevent the passage of wind, etc., but it does not interfere with the evaporation of moisture generated from the body, so it prevents steaming and makes it a wind-insulated type You can also. However, when a fabric / aluminum film laminated fabric is used instead of the fabric B, it is preferable from the viewpoint of the thermal effect that the fabric / aluminum film laminated fabric is used so as to be outside the clothing from the carbonized fiber nonwoven fabric A.

  FIG. 7 shows a plan view of one embodiment of the carbonized fiber nonwoven fabric 1 for schematically showing the cuts provided with a plurality of short cuts in the carbonized fiber nonwoven fabric used in the present invention.

  The cut shown in FIG. 7 is an example in which a plurality of short straight cuts 8, 8 'are provided. The cuts 8 and 8 ′ penetrate through the carbonized fiber nonwoven fabric 1 in the thickness direction. In the case where a plurality of such short straight cuts are provided, for example, when the vertical direction of the garment when used for the garment of the carbonized fiber nonwoven fabric 1 is the CC ′ direction, the length of the cuts 8 and 8 ′ The vertical direction is an oblique direction with respect to the up-and-down direction of the clothing, the cut 8 is a right-downward inclination, and the cut 8 ′ is a left-down inclination. Particularly preferably, both of the inclinations are substantially the same with respect to the CC ′ direction. It is preferable to be provided in the direction of 45 degrees. In this embodiment, the short cuts 8, 8 ′ are alternated in such a manner that the other cut 8 ′ adjacent to the lengthwise tip of the one cut 8 blocks the lengthwise tip direction of the one cut 8. It is preferable that it consists of the repeating aspect of the arrangement | positioning aspect of the cut | disconnected arrange | positioned in. Since the carbonized fiber nonwoven fabric 1 can be stretched in any direction by making the cuts in this way, when used in a stretchable part of the garment, the carbonized fiber nonwoven fabric 1 stretches following, has no feeling of tension, and has a feeling of wearing. Good clothing can be obtained. The length of the cut is not particularly limited, but is preferably about 1 to 4 cm. Further, the distances AA ′ and BB ′ from the tip of one cut 8 to the cut 8 ′ arranged in such a manner as to block the tip direction of the cut 8 are not particularly limited. Is preferably about 2 to 6 mm. The length of the cuts and the intervals A-A ′ and B-B ′ are not limited to the above, and it is arbitrary within the range where the function of the present invention is not hindered depending on the purpose of the clothing. In addition, as it is called a short cut, each cut is not a continuous cut in principle. This is because the strength of the nonwoven fabric may be significantly reduced when the cuts are long and continuous.

  In FIG. 7, the length direction of the cuts 8 and 8 ′ is an oblique direction with respect to the up-and-down direction CC ′ of the clothing, the cut 8 is inclined to the right downward direction, and the cut 8 ′ is inclined to the left downward direction. If necessary, you can change the direction of the cut. For example, the length direction of the cut 8 is perpendicular to the vertical direction CC ′ of the garment, and the length direction of the cut 8 ′ is parallel to the vertical direction CC ′ of the garment, or the vertical direction C- The angle in the longitudinal direction of the cuts 8 and 8 'with respect to C' is made smaller than 45 degrees, or larger than 45 degrees, making it easier to stretch in the longitudinal direction of clothing than in the lateral direction, and vice versa. It can also be changed according to the required characteristics of clothing, such as making it easier to stretch in the vertical direction. Therefore, depending on the required characteristics of the clothing, it is possible to make it easy to extend only in the lateral direction of the clothing by making only a cut parallel to the upward and downward direction CC ′ of the clothing, and vice versa. It is good also as an aspect which makes it easy to extend only to the clothing longitudinal direction only by a slit.

  In addition, although not shown, if a plurality of discontinuous short cuts are provided, the cuts are not straight, but are bent, for example, “S” shape, left-right symmetric shape, “<” As long as the object of the present invention can be achieved, such as a letter shape, a “>” letter shape, a “Z” letter shape, a symmetrical shape thereof, and a combination thereof, the shape of the cut is arbitrary.

  It is preferable to provide a cut when a carbonized fiber nonwoven fabric is used in a relatively large and wide range, so that the cut can be accommodated to cope with the expansion and contraction of clothing. For example, in a small clothing such as a supporter, for example, it will be described later. Since it can also be made to respond | correspond to elasticity with another device as shown in an Example, it can also respond to the elasticity of clothing without providing a cut.

  The basis weight of the carbonized fiber nonwoven fabric and the thickness of the fibers constituting it may be selected according to the purpose, but are not particularly limited, but the basis weight is preferably 30 to 120 g / m2. As for the thickness of the fiber which comprises a carbonization fiber nonwoven fabric, about 8-30 micrometers is preferable, More preferably, it is 10-20 micrometers, Especially preferably, it is 13-15 micrometers.

  If the fabric weight is too large, the amount of far-infrared radiation increases, but the feeling of wear tends to decrease.If the fabric weight is too small, the feel of wear improves, but the tensile strength of the nonwoven fabric tends to decrease. Therefore, the far-infrared radiation amount tends to decrease. If the thickness of the constituent fibers is too large, the feeling of wear tends to be reduced. When the thickness of the constituent fiber is too thin, the feeling of wearing is improved, but the tensile strength of the nonwoven fabric tends to be lowered. In addition, for example, the apparent density of the carbonized fiber nonwoven fabric can be easily set to about 1.4 and is also available as a commercial product, so instead of the feathers that are the batting of a quilted jacket such as a down jacket Even if it uses, it can also be set as the cold clothing which feels lighter than the case where a feather is used, and has a good feeling of wear.

  Since pitch-based carbon fiber nonwoven fabrics are commercially available, they can be used. Therefore, the production method of the pitch-based carbon fiber nonwoven fabric is not particularly limited, but in brief, it is the same as the production method of cotton candy (cotton candy), and the raw material to be input is not sugar, Pitch refined from coal tar obtained by dry distillation of coal is used. In other words, there are many small holes for discharging fibers on the side of the rotating pan, or fibers are discharged near the edge of the pot lid with a ring-shaped pot lid with a hole for feeding raw material in the center on the rotating pan. Using a rotating pan (also called a rotary pot) having a large number of small holes for melting, the pitch raw material put into the heated rotating pan is melted, and the molten pitch is linearly discharged from the small holes by centrifugal force, and the surrounding air or Pitch fibers are cooled by blowing air, and it is preferable to apply curl to the fibers by applying an air flow so that the fibers are twisted, because the fibers are particularly easy to entangle. Stabilized in 300 ° C. air (to make thermoplastics heat infusible), the obtained fiber is usually referred to as infusible fiber, etc. Baked and carbonized for about 5-24 hours A carbon fiber Te. A thin non-woven fabric can be made into a pitch-based carbon fiber non-woven fabric by spinning the fibers in the same manner as papermaking. At this time, the binder for bonding the fibers to each other is not particularly limited. For example, an epoxy resin binder, a polyester resin binder, a polyvinyl alcohol resin binder, or the like is used. Two or more binders may be used in combination as required. Since the non-woven fabric is formed by the same method as papermaking, the fibers are uniformly dispersed and substantially uniformly in the surface direction, that is, randomly dispersed, so that the non-woven fabric is substantially isotropic in the non-woven fabric surface direction. Will have sex. The reason why the fibers are isotropically dispersed in this surface direction and isotropic in the nonwoven fabric surface direction is not clear, but to exert the far infrared radiation function of the pitch-based carbon fiber nonwoven fabric strongly. preferable. In addition, when carbon fiber is produced by the above method, curling can be imparted. Therefore, in the case of a thick non-woven fabric, the curling can be used to entangle the fibers without using a binder or the like. It can also be made into a non-woven fabric, and it can be made into a non-woven fabric that is thick and soft.

  The pitch-based carbon fiber nonwoven fabric thus obtained may be used as it is, or may be further used if necessary by further baking at 1800 to 2400 ° C. for about 4 to 24 hours in an oxygen-free oven to improve the carbonization rate. preferable.

  As pitch-based carbon fiber nonwoven fabrics, there are commercially available products such as “DonaCarbo” (“Donacarbo felt”, “Donacarbo paper” carbonization rate of about 97%) from Osaka Gas Chemical Co., Ltd., which are also used as they are. Alternatively, if necessary, it is also preferable to use it after baking in an oxygen-free furnace at 1800 to 2400 ° C. for about 4 to 24 hours to improve the carbonization rate.

  The pitch raw material includes an optical isotropic pitch and an optical anisotropic pitch (mesophase pitch), and any of them can be used. Carbon fiber nonwoven fabrics that use optically anisotropic pitch as a raw material can absorb heat more quickly, but in clothing that is worn for a long time, carbon fiber nonwoven fabrics that use optically isotropic pitches that are easy to diffuse heat are better. It is preferable because the far infrared radiation range is likely to be widened. The carbonization rate of the pitch-based carbon fiber nonwoven fabric is preferably 90% or more.

  Pitch-based carbon fiber has high thermal conductivity, about 2 times that of copper and about 3.7 times that of aluminum. For example, one edge of a pitch-based carbon fiber nonwoven fabric is irradiated with far-infrared rays to generate energy. The present inventor has found that, when the water is absorbed, it diffuses to the other edge side of the nonwoven fabric in a relatively short time and emits far infrared rays from the entire surface of the nonwoven fabric. However, in the case of a woven fabric made of PAN-based carbon fibers (a normal woven fabric made of warp and weft), even if one edge side of the fabric is irradiated with far infrared rays to absorb energy, It was confirmed that there was no property of emitting far infrared rays from the entire surface of the fabric without diffusing to the other edge side. Although the reason is not clarified, it has been confirmed that at least the pitch-based carbon fiber nonwoven fabric has an excellent function in terms of thermal diffusivity as described above. It is presumed that the carbon fiber and the non-woven fabric bring about the above-mentioned good results.

  In the present invention, an acrylic fiber carbon fiber precursor fiber nonwoven fabric, a so-called PAN carbon fiber precursor fiber nonwoven fabric can be used as the carbonized fiber nonwoven fabric.

  The precursor fiber of the PAN-based carbon fiber is treated with a high-temperature furnace in an air atmosphere in which an acrylic fiber such as polyacrylonitrile is wound around a bobbin and maintained at 200 to 300 ° C. when the PAN-based carbon fiber is produced. It is made into a flame-resistant fiber, and then it is not carbonized at a high rate at all, but it is a fiber that is baked in an oxygen-free furnace at 800 to 1000 ° C. for about 4 to 5 hours and the carbonization rate is kept at 40 to 90%. is there. Since this fiber is relatively flexible, it can be made into a non-woven fabric by a method of making a normal synthetic fiber into a non-woven fabric, such as a needle punch method. Of course, a non-woven fabric using a binder resin or the like for binding the intersections of the fibers constituting the non-woven fabric is also included as required.

  In the precursor fiber nonwoven fabric of the PAN-based carbon fiber, it is estimated that if the carbonization rate is increased, the far-infrared emission function is also increased. However, if the carbonization rate is increased to the same level as that of the PAN-based carbon fiber, the texture decreases. It is difficult to use. Therefore, the precursor fiber nonwoven fabric of the PAN-based carbon fiber described above is preferably used.

  Such a precursor fiber nonwoven fabric of PAN-based carbon fiber is a commercially available product such as “Panox nonwoven fabric” (carbonization rate of about 60%) manufactured by Asahi Kasei Co., Ltd. Specifically, as the product number, “AF- "50" (50 g / m2), "AF-70" (70 g / m2), "AF-200" (200 g / m2), "AF-400" (400 g / m2), "AF-200AP" (Weight per unit area 230 g / m @ 2) and the like, and "AF-50" and "AF-70" are particularly preferable from the viewpoint of texture.

  As a fabric B constituting the garment of the present invention, containing at least one selected from the group consisting of natural fibers, synthetic fibers composed of polymer polymers, semi-synthetic fibers, and regenerated fibers other than carbonized fiber nonwoven fabrics, Usually, fabrics using fibers used in clothing, that is, woven fabrics, knitted fabrics, nonwoven fabrics, etc. using these fibers are used and are appropriately selected according to the type and part of clothing. Or a knitted fabric is preferably used.

  Although not particularly limited, natural fibers include, for example, synthetic fibers made of a high molecular polymer such as cotton, hemp, silk, wool, and other animal hairs. For example, polyester fibers, Semi-synthetic fibers such as polyamide fibers, acrylic fibers, polyolefin fibers, polyurethane fibers, vinylon fibers, polyvinylidene chloride fibers, rubber fibers, etc. are not particularly limited, but for example, recycled fibers such as acetate and promix Is not particularly limited, and examples thereof include viscose rayon and cupra.

  In the present invention, the clothing is particularly preferable from the viewpoint of the thermal effect of absorbing far-infrared rays having a wavelength of around 10 μm generated from the skin, which are worn in contact with the skin, and emitting the far-infrared rays to the skin side. It is not limited to clothing worn in contact with the skin, but the outerwear is also warmed at body temperature in the outer clothing worn outside these clothing, and as a result, absorbs far-infrared rays generated from the underwear, and the underwear side By radiating the far-infrared rays, the thermal effect is exerted, even in the outermost garment such as a quilting jacket, the far-infrared rays that are generated by being warmed by sunlight etc. are absorbed and radiated, as described above, The underwear is warmed by body temperature, and as a result, the far infrared rays generated from the underwear side are absorbed and radiated, so that the underwear is not limited to clothing worn in contact with the skin. Specifically, various underwear shirts, bras, corsets, briefs, pants, shorts, girdle, spats, tights, trousers, body suits, shimmies, petticoats, stomachbands, socks, gloves, supporters, quilted jackets, mufflers, leg warmers, There is no particular limitation such as various sportswear.

  The carbonized fiber nonwoven fabric A used in the present invention may be applied to the entire composition range of the clothing together with the fabric B made of normal fibers. However, from the viewpoint of cost, the pitch-based carbon fiber nonwoven fabric A is used only at the site where the far infrared radiation function is required. May be used together with the fabric B made of normal fibers, and only the fabric B made of normal fibers may be used for other portions.

  Hereinafter, one of the embodiments in which the carbonized fiber nonwoven fabric A is used for the site where the far infrared radiation function is necessary will be described with reference to a representative example. However, the embodiment is limited to this example. It is not a thing.

  As clothing, cylindrical elbow supporters and knee supporters were manufactured.

  FIG. 8 is a perspective view of the cylindrical supporter, which is the clothing of the present invention, viewed obliquely from above, and FIG. 9 is a front view when the cylindrical supporter of FIG. 8 is crushed and flattened (drawing quoted for explaining dimensions). 10 is an end view of the DD ′ cross section of FIG. 8 of a substantially half-circumferential portion of the supporter. Although the elbow supporter and the knee supporter are similar in size, the elbow supporter and the knee supporter will be described with reference to FIGS.

  The elbow supporter has a length of 11 cm in FIG. 9, a length of b of 24 cm, and a length of c of 10 cm, and the knee supporter has a length of 15 cm in a and a length of b in FIG. The length was 12 cm. Both the outer and inner knitted fabrics 11 and 12 (see FIGS. 8 and 10) of each supporter were formed of 50% polyester fiber, 40% cotton, and 5% polyurethane fiber. A pitch-based carbon fiber nonwoven fabric 15 is inserted between the two outer and inner knitted fabrics 11, 12, and the outer and inner knitted fabrics are surrounded by the outer edges of the pitch-based carbon fiber nonwoven fabric 15. 11 and 12 are stitched. The suture lines in the longitudinal direction are indicated by 13 and 14, and the suture lines near the upper and lower edges are indicated by 17 and 18, respectively.

  The pitch-based carbon fiber non-woven fabric used was “Donna Carbo Paper” product number S-253 (weight per unit: 30 g / m 2, binder PVA) of Osaka Gas Chemical Co., Ltd. A total of 4 carbon fiber non-woven fabrics are used for knee supporters, with a rectangular carbon fiber non-woven fabric having a width of 5 cm and a length of 23 cm so as to surround each supporter outside and inside knitted fabrics 11 and 12 with a partial space between them. Used. And in order to ensure the expansion | extension to the circumference direction of a supporter, both width f between the adjacent stitching lines 13 and 14 shall be 5 mm, and there is no carbon fiber nonwoven fabric here, and the knitted fabrics 11 and 12 on the outside and inside It was designed not to hinder the elongation alone. Both supporters are about 4 mm thick.

  In order to measure the performance of this supporter, each left elbow and left knee of a 56 year old female monitor was worn, and the temperature change with the passage of wearing time was measured. In the case of a supporter having a difference in the diameter of the supporter, that is, a supporter having a small length c in FIGS. 9A and 9C, the test was carried out with the c side facing the tip direction of the arm or leg.

The temperature is measured by using an infrared radiation thermometer (model: SK-8700II) manufactured by Sato Keiki Seisakusho Co., Ltd., 30 cm away from the surface of the temperature measurement object, and irradiating the surface of the temperature measurement object with laser light to obtain the surface temperature. Was measured.

  The measurement starts from the temperature of the skin of the left elbow and the left knee of the female monitor, and every 10 minutes after wearing each supporter for 60 minutes from the top of the supporter at the elapsed time indicated in the elapsed time column of Table 1, respectively. Measure the surface temperature, and after measuring the surface temperature after 60 minutes, immediately remove the supporter (removal was expressed as “desorption” in Table 1) and measure the temperature of the bare skin where the supporter was removed. Then, the temperature of the bare skin where the supporter was removed was measured after 10 minutes, 15 minutes, and 20 minutes. The results are shown in Table 1.

  In addition, for reference of performance comparison, we measured the temperature change with the passage of wearing time in the same way as for the supporter for knee and the supporter for knee containing commercially available Kishu Bincho charcoal (powder) It is shown in Table 1.

  A commercially available elbow supporter will be described with reference to FIG. 9. The length of a is 8 cm, the length of b is 24 cm, the length of c is 8 cm, the thickness is about 3 mm, and the knee supporter is a length of 11 cm, b The length is 27 cm, the length is 10 cm, the thickness is about 3 mm, and is a trade name seamless supporter manufactured by Miyajima Bussan Co., Ltd., which is composed of a knitted fabric made of cotton, polyester fiber, rayon fiber, and polyurethane fiber. The reason why the length of a and c in FIG. 9, that is, the supporter diameter is smaller in the commercially available product is that the carbon fiber non-woven fabric is not used, so that it grows well.

  As is clear from the results in Table 1, the effect of far-infrared radiation by using a carbon fiber nonwoven fabric was observed. Moreover, a thermal effect is maintained that maintains a high skin temperature even after the supporter is removed (removed).

  In the above embodiments, pitch-based carbon fiber nonwoven fabric is used as the carbonized fiber nonwoven fabric, but acrylic fiber carbon fiber precursor fiber nonwoven fabric may be used.

  The far-infrared radiation clothing of the present invention can provide clothing that can sufficiently exhibit the far-infrared radiation function without reducing the texture, and can be effectively used as a clothing for normal clothing fields or hypothermia patients.

DESCRIPTION OF SYMBOLS 1 Carbonized fiber nonwoven fabric 2 Fabric which consists of normal fiber 3 Adhesive 4 Sewing line 5 Sewing line 6 Opening 8, 8 'Straight short cut 11 Knitted fabric outside supporter 12 Knitted fabric inside supporter 13 Longitudinal direction Stitching line 14 Longitudinal stitching line 15 Pitch-based carbon fiber nonwoven fabric 17 Sewing line near the upper edge 18 Sewing line near the lower edge

Claims (8)

Pitch-based carbon fiber nonwoven fabric or acrylic fiber carbon fiber precursor fiber nonwoven fabric is selected from the group consisting of natural fibers, synthetic fibers composed of polymer polymers, semi-synthetic fibers, and regenerated fibers. Used with a fabric containing at least one kind,
The pitch-based carbon fiber nonwoven fabric or the acrylic fiber-based carbon fiber precursor fiber nonwoven fabric is a nonwoven fabric in which a plurality of short cuts are provided, whereby the nonwoven fabric is stretchable in at least two directions. Far-infrared radioactive clothing. In the far-infrared radioactive clothing according to claim 1,
The short cut is a repetitive form of the cut arrangement in which the other cut adjacent to the lengthwise tip of the one cut is arranged in such a manner as to block the tip direction of the length of the one cut. Far-infrared radioactive clothing characterized by comprising. In the far-infrared radioactive clothing according to claim 1 or 2,
A far-infrared radioactive garment characterized in that the short cut is a straight cut having a length of about 1 to 4 cm. In the far-infrared radioactive clothing according to any one of claims 1 to 3,
The pitch-based carbon fiber non-woven fabric or the acrylic fiber carbon fiber precursor fiber non-woven fabric contains at least one selected from the group consisting of natural fibers, synthetic fibers composed of polymer polymers, semi-synthetic fibers, and regenerated fibers. The aspect used overlapping with the fabric is
The pitch-based carbon fiber nonwoven fabric or the acrylic fiber-based carbon fiber precursor fiber nonwoven fabric contains at least one selected from the group consisting of A, natural fibers, synthetic fibers composed of polymer polymers, semi-synthetic fibers, and regenerated fibers. When the fabric is B,
(A) A mode in which A is laminated to B by point adhesion in terms of the reciprocal number,
(B) A mode in which B is overlapped on both sides of A, and at least one side of A is laminated to B by point bonding in terms of the reciprocal number,
(C) A mode in which B is used on both sides of A, and these three layers are stitched together in a quilting shape (d) A mode in which A is inserted into B in a bag-like shape,
A far-infrared radioactive garment comprising any one or more aspects selected from the above. In the far-infrared radioactive clothing according to any one of claims 1 to 4,
A far-infrared radiation garment characterized in that the fabric selected from the group consisting of natural fibers, synthetic fibers composed of high-molecular polymers, semi-synthetic fibers, and regenerated fibers is a fabric composed of woven fabric or knitted fabric. In the far-infrared radioactive clothing according to any one of claims 1 to 5,
A far-infrared radioactive garment characterized in that the fiber constituting the carbon fiber precursor fiber nonwoven fabric of pitch-based carbon fiber or acrylic fiber is 8-30 μm. In the far-infrared radioactive clothing according to any one of claims 1 to 6,
A far-infrared radioactive garment characterized in that the basis weight of a pitch-based carbon fiber nonwoven fabric or a carbon fiber precursor fiber nonwoven fabric of acrylic fibers is 30 to 120 g / m2. In the far-infrared radioactive clothing according to any one of claims 1 to 7,
Far-infrared radioactive clothing, characterized in that the clothing is clothing selected from underwear, stomachbands, supporters, socks, mufflers, gloves, hats, and outer clothing.

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