JP5561977B2 - Thermal fiber fabric - Google Patents

Description

  The present invention relates to a heat-retaining fiber fabric including animal hair fibers and having a large absorption in the near infrared region.

  2. Description of the Related Art Conventionally, winter textile products have been strongly demanded to have heat retention properties, and various natural fibers and synthetic fibers have been used to satisfy the demand. In particular, animal hair fiber, which is a natural fiber, has a unique fiber structure crimp (crimp), so it has both heat retention by heat insulation, bulkiness, moisture absorption, and good texture. It is. Accordingly, animal hair fibers are excellent in comfort and are indispensable for winter clothing materials.

  Under such circumstances, many natural fibers and synthetic fibers having a heat retaining property have been studied as a heat retaining fiber instead of animal hair fibers. For example, Patent Document 1 discloses a heat retaining fiber having solar heat selective absorptivity in which transition metal carbide powder is kneaded into a thermoplastic synthetic fiber such as polyamide or polyester. However, the heat-retaining fiber has no hygroscopic property of animal hair fibers and tends to be inferior in comfort.

  Patent Document 2 and Patent Document 3 disclose hygroscopic exothermic fibers that pay attention to the fact that animal hair fibers have excellent hygroscopicity. The moisture-absorbing exothermic fiber has good heat retention in the field of clothing that easily absorbs sweat such as underwear, but in some cases, heat retention is insufficient in the field of outer clothing such as suits and uniforms.

  Furthermore, in Patent Document 4 and Patent Document 5, an animal hair fiber in which a fabric is formed from an animal hair fiber that has been subjected to shrinkage treatment, and the fabric is dyed with an acid mordant dye or a metal-containing dye (a dye having a metal complex compound). A fabric is disclosed. However, these are aimed at improving the dyeability and fastness of animal hair fiber fabrics, and the purpose has been achieved, but there are cases where the effects such as excellent heat retention and moisture absorption are insufficient. It was.

JP-A-1-132816 JP 2003-293235 A JP 2005-256193 A JP-A-3-287874 Japanese Patent Publication No. 1-29917

  The present invention is intended to solve the problems of the prior art as described above, and an object thereof is to provide a heat-retaining fiber fabric having the texture of animal hair fibers, excellent hygroscopicity, bulkiness and heat-retaining properties. To do. By using the heat-retaining fiber fabric, sports clothing, formal clothing, uniform clothing, etc. excellent in comfort can be provided.

  The present inventors examined the cause of difficulty in achieving both hygroscopicity and heat retention even when conventionally known means for improving heat retention is applied to animal hair fiber fabrics. And by this examination, based on the viewpoint that the kind and the amount of the dye used are inappropriate, when a specific dye is used and further an infrared absorber is used, both hygroscopicity and heat retention are achieved at a high level. I found out.

  Furthermore, the present inventors have a large amount of heat energy in the near-infrared region of the wavelength of 700 to 1100 nm of sunlight, and if the infrared rays in this range are absorbed efficiently, the thermal motion of animal hair fiber molecules becomes remarkable. We focused on and examined. And it discovered that the animal hair fiber fabric which absorbs the near infrared ray of the said area | region efficiently by containing a metal-containing dye and an infrared absorber was obtained, and reached | attained this invention.

  That is, as a result of intensive studies in order to solve the above problems, the present inventors have adopted the technical idea of finishing animal hair fibers so as to absorb a lot of near infrared rays. Thus, the inventors have found that a fabric capable of exhibiting excellent heat retaining properties while maintaining high hygroscopicity and bulkiness is obtained, and the present invention has been achieved.

That is, the gist of the present invention is as follows .
(1 ) A fabric composed of a blended spun yarn of animal hair fibers oxidized and dyed with a metal-containing dye and a synthetic fiber containing zirconium carbide, and the reflection of the fabric at a wavelength of 700 nm to less than 900 nm rate is 30% and the reflectance of the cloth in the above wavelength 900 nm 1100 nm or less than 40% and a coercive temperature fiber cloth you wherein the L * value of the fabric is 15 or less.
( 2 ) A fabric including animal hair fibers subjected to oxidation treatment, the fabric is dyed with a metal-containing dye, and zirconium carbide or an anthraquinone-based infrared absorber is attached to the fabric by a binder, and the wavelength is 700 nm or more and less than 900 nm. it is not less than 30% reflectance of the fabric, and the reflectance of the cloth in the above wavelength 900 nm 1100 nm or less than 40% and the fabric of the coercive temperature fiber fabric you, wherein the L * value is 15 or less.

  ADVANTAGE OF THE INVENTION According to this invention, it can provide the heat retention fiber fabric which has the heat retention property with high absorption of near infrared rays, and simultaneously the texture which animal hair fiber has, high moisture absorption, and bulkiness. The heat-retaining fabric is useful for sports clothing, formal clothing, uniform clothing, and the like.

It is a suit back surface temperature measurement result when the suit sewn using the heat retaining fabric obtained in Example 1 and the fabric obtained in Comparative Example 1 is worn outdoors (at an air temperature of 18 ° C.). It is a cutter shirt surface temperature measurement result when the suit sewn using the heat retaining cloth obtained in Example 1 and the cloth obtained in Comparative Example 1 is worn outdoors (at an air temperature of 18 ° C.). It is a suit back surface temperature measurement result when the suit sewn using the heat retaining cloth obtained in Example 2 and the cloth obtained in Comparative Example 1 is worn outdoors (at an air temperature of 18 ° C.). It is a cutter shirt surface temperature measurement result when the suit sewn using the heat retaining cloth obtained in Example 2 and the cloth obtained in Comparative Example 1 is worn outdoors (at an air temperature of 18 ° C.). It is a suit back surface temperature measurement result when the suit sewn using the heat retaining fabric obtained in Example 3 and the fabric obtained in Comparative Example 2 is worn outdoors (at an air temperature of 18 ° C.). It is a cutter shirt surface temperature measurement result when the suit sewn using the heat retaining cloth obtained in Example 3 and the cloth obtained in Comparative Example 2 is worn outdoors (at an air temperature of 18 ° C.).

Hereinafter, the present invention will be described in detail.
The heat-retaining fiber fabric of the present invention contains animal hair fibers that have been oxidized, is dyed with a metal-containing dye, and contains an infrared absorber.

  In the present invention, the oxidized animal hair fiber refers to a scale that is a scale layer existing on the fiber surface from natural keratinous fibers collected from animals such as sheep, camels, goats, llamas, alpaca, and rabbits. It means a fiber from which part or all has been removed.

  Usually, animal hair fibers are hydrophilic because they are composed of polypeptide chain molecules. However, the surface of the animal hair fiber is covered with a hair dermis having a hard scaly structure, and a layer called a hydrophobic epicuticle (upper dermis) is formed as the outermost layer. Since the epicuticle inhibits the dyeability, the surface of the animal hair fiber tends to be poor in wettability. However, it is known that the oxidation treatment improves the wettability and improves the dyeability. However, when the oxidation treatment is performed, if the oxidation proceeds excessively, the strength becomes weak, and further, the dye adsorption rate increases and the leveling property may decrease.

In the present invention, it is important to confirm the oxidation state of animal hair fibers. By applying the oxidation treatment, the animal hair fiber is oxidized and the cystine bond (—S—S— bond) is cleaved to generate a sulfonic acid group (—SO ₃ H group). Become. Therefore, dyeing with a basic dye becomes possible.

  The confirmation of the oxidation state is performed, for example, as follows. First, the oxidized animal fiber was treated with C.I. I. It is immersed in a 1 g / L aqueous solution of a basic dye such as Basic Blue 129 at a bath ratio of 1: 100 and a temperature of 20 ° C. for 5 minutes. With respect to the oxidized animal hair fiber, the L * value is measured by a stimulus value direct reading method based on JIS Z 8722 described later. If this L * value is 18-30, since it is an animal hair fiber with good dyeing | staining of a metal-containing dye and the intensity | strength, elongation, and a favorable texture, it is judged that it is a preferable oxidation state. Here, the basic dye C.I. I. Specific examples of the Basic Blue 129 include a trade name “Aizen Cathilon Blue CD-F2RLH” manufactured by Hodogaya Chemical Co., Ltd.

  Examples of the method for oxidizing animal fiber include a batch type or a continuous type. The form of the animal hair fiber during the oxidation treatment is not particularly limited, and it can be carried out in the form of a top, yarn, woven fabric, knitted fabric or the like. The oxidizing agent used here is not particularly limited, and is a chlorine-based oxidizing agent such as sodium hypochlorite and dichloroisocyanuric acid; ozone, hydrogen peroxide, potassium hydrogen persulfate, potassium persulfate, peracetic acid, performic acid And oxygen-based oxidizing agents such as Of these, a chlorine-based oxidizing agent is preferable from the viewpoint of cost. The oxidation treatment conditions are not particularly limited, and can be performed by a known and usual method.

  The heat-retaining fiber fabric in the present invention refers to a woven fabric or a knitted fabric in which animal hair fibers are used as main constituent fibers. As content of the animal hair fiber in a heat retention fiber cloth, 50 mass% or more is preferable, and 70 mass% or more is more preferable. Here, if the content of animal hair fibers is less than 50% by mass, the bulkiness of the fabric is reduced, and the texture and hygroscopicity are impaired.

  Examples of fibers other than animal hair fibers contained in the heat-retaining fiber fabric of the present invention include polyethylene terephthalate fibers, polylactic acid fibers, acrylic fibers, nylon fibers, polyurethane, and other synthetic fibers; silk, cotton, hemp, bamboo Natural fibers such as viscose rayon, solvent-spun cellulose fiber, and regenerated fibers such as copper ammonia rayon; and semisynthetic fibers such as acetate.

It is essential that the heat-retaining fiber fabric of the present invention is dyed with a metal-containing dye. By using a metal-containing dye, the effect of heat retention by near infrared absorption can be obtained.
The metal-containing dye is complexed with one chromium atom or one cobalt atom per dye molecule having a sulfonic acid group (that is, the metal and dye form a complex salt at a ratio of 1: 1). ) There is a 1: 1 type metal complex hydrochloric acid dye. As the 1: 1 type metal complex hydrochloric acid dye, for example, trade names “NEOLAN Yellow GR 175%” “NEOLAN Yellow RE 250%”, “NEOLAN Red GRE 200%”, “NEOLAN Bordeaux RM 200%” manufactured by Clariant Japan, "NEOLAN Blue 3R 200%", "NEOLAN Blue 2G 250%", "NEOLAN Black WA 200%", DYSTAR JAPAN brand names "PALATIN Yellow GR", "PALATIN Red GRE", "PALATINGlu" Examples include “Navy Blue 2RLB”, “PALATIN Navy Blue RN”, “PALATIN Black WAN 01”, and the like. Of these, black dyes such as “NEOLAN Black WA 200%” and “PALATIN Black WAN 01” are preferable from the viewpoint of heat retention by near infrared absorption.

  In addition, the metal-containing dye is a complex salt with one chromium atom or one cobalt atom for two dye molecules having a sulfonic acid group (that is, the metal and the dye form a complex salt at a ratio of 2: 1). It may be a 1: 2 type metal complex hydrochloric acid dye. Examples of 1: 2 type metal complex hydrochloric acid dyes include, for example, trade names “IRGALAN Yellow GL 220%”, “IRGALAN Yellow GRL 220%”, “IRGALAN Bordeaux EL 200%”, “IRGALAN Blue 3GL 200%” manufactured by Clariant Japan. , “IRGALAN Navy B-01 50%”, “IRGALAN Black BGL 200%”, “IRGALAN Black RBIN”, DYSTAR JAPAN, trade names “Isolan Yellow GRL”, “Isolan Yellow K-PRL 200ol”, “I” R 200% 02 "," Isolan Brown K-3GLS, Isolan Blue 3GL "," Isol n Black 3RL "," Isolan Black S-BGL ", Nippon Kayaku Co., Ltd., trade names" Kayakalan Yellow GL 143 "," Kayakalan Red BL "," Kayakalan Bordeaux BL "," Kayakal GK " "," Kayakalan Black BGL "and the like. Among them, from the viewpoint of heat retention by absorption of near infrared rays, “IRGALAN Black BGL 200%”, “IRGALAN Black RBIN”, “Isolan Black 3RL”, “Isolan Black S-BGL”, “Kayakalan Black 2RL”, “Kakalan Black 2RL”, “K” BGL "black dye is preferred.

Furthermore, the metal-containing dye may be an acid mordant dye. The acid mordant dye is one in which animal hair fibers and a dye are coordinated with a metal using a metal salt such as chromium, cobalt, and aluminum. Acid mordant dyes are, for example, trade names “Chrome Yellow 3R”, “Chrome Red 5G”, “Chrome Bordeaux FB”, “Chrome Navy 3RM”, “Chrome Navi PL conc”, “Cro 5” manufactured by Yamada Chemical Co., Ltd. , “Chrome Black WEF”, “Chrome Black ETS”, Taoka Chemical Industry Co., Ltd., trade name “Sunchrome Yellow MD 120%”, “Sunchrome Red G conc”, “Sunchrome Fast Blue AB”, “S” Black ET (A) conc "," Sunchromine Black P2B ", and the like. Among these, from the viewpoint of heat retention by near infrared absorption, “Black Black 5G”, “Black Black WEF”, “Chrom Black ETS”, “Sunchrome Black PR”, “Sunchrome Black ET (A) conc”, “Bnc”, “B Are preferred.
In addition, said metal-containing dye can be used in combination as appropriate so that L * value may be 15 or less as mentioned later.

  The heat-retaining fiber fabric of the present invention is dyed with a metal-containing dye, and the content of the metal-containing dye is preferably 5.0 to 12.0% by mass with respect to animal hair fibers. If the content of the metal-containing dye is less than 5.0% by mass, the near-infrared reflectance cannot be controlled within a predetermined range, and if it exceeds 12.0% by mass, the color fastness decreases and the cost is further reduced. Is unfavorable because of the high.

  The infrared absorbent used in the present invention absorbs infrared rays having a wavelength of 700 nm or longer in the long wavelength region. In particular, those that absorb near infrared rays of 700 to 2000 nm are preferable. Examples thereof include carbides such as carbon black and zirconium carbide; and organic pigments such as phthalocyanine and anthraquinone. Of these, carbon black and zirconium carbide are preferred from the viewpoint of easy kneading into synthetic fibers.

  The heat-retaining fiber fabric of the present invention is required to have a reflectance of 30% or less at a wavelength of 700 nm or more and less than 900 nm and a reflectance of 40% or less at a wavelength of 900 nm or more and 1100 nm or less. Here, when the reflectance at a wavelength of 700 nm or more and less than 900 nm exceeds 30% and the reflectance at a wavelength of 900 nm or more and 1100 nm or less exceeds 40%, the heat retaining property is inferior. In the present invention, the reflectance refers to a value measured by a spectrocolorimetric method according to JIS Z 8722. The smaller the value, the greater the light absorption.

  It is preferable that the content rate of an infrared absorber is 0.1-0.5 mass% with respect to a heat retention fiber fabric. When the content ratio of the infrared absorber is less than 0.1% by mass, the near infrared reflectance cannot be controlled within a predetermined range, and when it exceeds 0.5% by mass, the fastness to dyeing is lowered and the cost is further reduced. Is unfavorable because of the high.

  The hue of the heat-retaining fiber fabric of the present invention needs to be a dark hue such as black or amber having an L * value of 15 or less. The L * value is an index representing color density, and the smaller the value, the darker the color. When the L * value is 15 or less, the reflectance of the present invention in the near-infrared region can be achieved. If the L * value exceeds 15, the near-infrared reflectance does not fall within a predetermined range, so that the heat retaining effect cannot be achieved.

  In the present invention, the L * value is measured by a stimulus value direct reading method based on JIS Z 8722. That is, using a photoelectric colorimeter, a stimulus value direct-reading type color meter, etc., three sensors having the same sensitivity as the spectral sensitivity corresponding to the human eye, so-called tristimulus values X, Y, Z is measured and converted. Specifically, the tristimulus value can be measured and converted by using a trade name “COLOR-7S” manufactured by Kurashiki Boseki Co., Ltd.

  As the use of the heat insulating fiber fabric of the present invention, sports clothing, formal clothing, and uniform clothing outer clothing are suitable, and the color of the fabric is particularly deep and deep based on black or amber. Formal clothing for winter is preferred. In the present invention, formal clothing refers to items that have been refurbished, and specifically include suits, dresses, mourning dresses, jackets, pants, skirts, dresses, and school uniforms.

Below, the method for obtaining the heat insulation fiber fabric of this invention is demonstrated.
As a first method for obtaining the heat-retaining fiber fabric of the present invention, there is a method in which animal hair fibers dyed with the metal-containing dye and a synthetic fiber containing an infrared absorbent are mixed and spun into a yarn and then woven and knitted. It is done. Further, as a second method for obtaining the heat-retaining fiber fabric of the present invention, there is a method in which after weaving and knitting using animal wool spun yarn, it is dyed with the metal-containing dye, and an infrared absorber is applied. In the present invention, the oxidation treatment is preferably performed before dyeing.

  The first method for obtaining the heat insulating fiber fabric will be described in detail below. First, after washing the animal hair fibers, the washed animal hair fibers are subjected to the steps of opening, carding and combing to create a sliver-like top having a diameter of about 25 mm. Next, the top is subjected to oxidation treatment with a top dyeing machine. Thereafter, in the same top dyeing machine, dyeing is performed by appropriately selecting the dyeing conditions such that the content of the metal-containing dye is 5.0 to 12.0% by mass with respect to the animal hair fibers.

  Next, a dyed animal hair fiber top and a fiber sliver containing an infrared absorber are mixed with a mixing gil (mixing machine), and the content ratio of the infrared absorber is, for example, 0.1 to 0. 0 with respect to the fiber fabric. Mix to 5% by mass. Here, the fiber containing an infrared absorbent refers to a fiber in which an infrared absorbent such as carbon black or zirconium carbide is kneaded into a synthetic fiber such as polyester fiber or nylon fiber.

  Then, the mixture of the animal hair fiber top and the fiber sliver is knitted and knitted from a spun yarn by a known method, and the surface oil agent and the like are removed through a finishing process to obtain the heat retaining fiber fabric of the present invention. Can do.

  The second method is a method of weaving and knitting animal hair spun yarn obtained by a known spinning method and then dyeing it using the metal-containing dye. At this time, the oxidation treatment can be performed in a top dyeing machine in the top state before the spun yarn is formed. Alternatively, the oxidation treatment may be applied to the animal hair fiber after weaving and before dyeing using a known dyeing machine.

  Thereafter, weaving and knitting animal hair fibers to form a fabric, and using a dyeing machine, the fabric is dyed with the metal-containing dye. The dyeing machine is not particularly limited, and examples thereof include a wins dyeing machine, a paddle dyeing machine, a liquid flow dyeing machine, a jigger dyeing machine, and a rotary dyeing machine.

  Next, after the dyed fabric is subjected to a finishing arrangement step, a resin solution in which an infrared absorber and a binder resin are blended is prepared, and the resin solution is applied to the dyed fabric by a padding method. Thereafter, the obtained fabric is dried at a temperature of 80 to 130 ° C., and then heat-treated at a temperature of 110 to 180 ° C. for 0.5 to 5 minutes to obtain the heat-retaining fiber fabric of the present invention.

  The binder resin is a resin that can form a film, such as an acrylic resin, a polyurethane resin, or a polyester resin. The content of the binder resin is preferably in the range of 1 to 5 times the mass of the infrared absorber.

  In the first method and the second method, the dyeing temperature is 80 to 100 ° C., the dyeing time is 60 to 120 minutes, the pH of the dye bath is 4 to 7, and the bath ratio is 1: 5 to 1:50. Is preferred. Depending on the dye used, auxiliary agents such as buffering agents and leveling agents may be used.

  In the present invention, a silicon-based resin, a fluorine-based resin, or the like may be added in order to develop a deeper and deeper color in the heat-retaining fiber fabric. Examples of the silicon resin include dimethylpolysiloxane, amino-modified polysiloxane, and epoxy-modified polysiloxane.

  Commercially available products may be used as the silicon-based resin, and examples thereof include trade name “Funder Oil WW” manufactured by Yamamune Business Co., Ltd. and trade name “Raster CT-125” manufactured by Kotani Chemical Industry Co., Ltd.

  Commercially available products can be used as the fluororesin, for example, trade name “Nichitex F-400” manufactured by Nissei Kasei Co., Ltd., trade name “NK Guard FG-270” manufactured by Nikka Chemical Co., Ltd., product manufactured by Meisei Chemical Co., Ltd. Name "Asahi Guard AG-310" etc. are mentioned. The fluorine-based resin also has an effect of imparting water repellency to the heat-retaining fiber fabric.

  The method for applying the silicon-based resin or the fluorine-based resin is not particularly limited, but it is preferable that the method is applied by a padding method and then subjected to a drying and heat treatment step. In the second method, when a resin liquid containing an infrared absorber and a binder resin is applied to a dyed fabric, a silicone resin or a fluorine resin is mixed with the resin liquid and simultaneously applied. Also good.

Hereinafter, the present invention will be specifically described by way of examples. In addition, evaluation in an Example , a reference example, and a comparative example shall be based on the following method.
1. L * value The product name “COLOR-7S” manufactured by Kurashiki Boseki Co., Ltd. was used, and tristimulus values of X, Y, and Z were measured and converted in accordance with the stimulus value direct reading method according to JIS Z 8722.

2. Reflectance The reflectance was measured according to the spectrocolorimetric method according to JIS Z 8722.
3. Thermal insulation evaluation The measurement environment is the time / meteorological element (hereinafter, terms related to the time / meteorological element conform to the forecast terms as of August 2006 published by the Japan Meteorological Agency), but winter (December to 2 The period until the moon), the test time is around noon (2 hours, including 1 hour before and after noon), the wind is calm (less than 0.3 m / s), the weather is sunny and the illuminance is 100,000 lux The outdoor temperature was 18 ° C.
A suit outerwear was prepared by sewing the fabric obtained in the comparative example on the left half and using the heat-retaining fiber fabric of the present invention and the reference example on the right half. Next, panelists were allowed to wear a cutter shirt, and temperature sensors were attached to the lower left and right shoulder blades on the back of the cutter shirt. Subsequently, after attaching temperature sensors to the lower left and right scapulas on the back of the suit jacket, the panelist was put on the suit jacket, and the paneler sat on the chair for 10 minutes outdoors in the measurement environment conditions. Each temperature was measured in the state. The temperature of the cutter shirt and the temperature of the back side of the suit jacket were measured over time, and the heat retention was evaluated by relative comparison of the temperature of the left half part and the right half part.

( Reference Example 1)
The wool top was obtained by subjecting the wool to an eyelash process. Next, hypochlorous acid was generated by reacting sodium hypochlorite and sulfuric acid so that the effective chlorine content was 2.5% by mass with respect to the mass of wool. Using the hypochlorous acid, the wool top was subjected to an oxidation treatment in a continuous manner. Subsequently, using a top dyeing machine (manufactured by Nisaka Seisakusho Co., Ltd.), in a dyeing bath having the composition shown in Formula 1 described below, the bath ratio is set to 1:15 and dyeing is performed at a temperature of 100 ° C. for 30 minutes. did. Then, the dyeing bath was cooled to 70 ° C., and formic acid (concentration 85%) was added by 3.0% by mass with respect to the mass of the wool top. Furthermore, after cooling the dyeing bath to 90 ° C. and adding 2.0% by mass of potassium dichromate with respect to the top mass, the temperature is raised again at 100 ° C. and dyed for 30 minutes. Wash with water to complete the dyeing.

  Next, the dyed wool top and the polyester fiber sliver (trade name “Unitika Ester” manufactured by Unitika Ltd.) (2% by mass) of carbon black kneaded (2.2 decitex, fiber length: 80 mm) mixing machine mixing gil (Made by OMM) to obtain a blended fiber containing wool mixed with 10% by mass of polyester fiber.

The blended fiber containing wool was subjected to spinning to give a 60th (metric) wool spun yarn, and then woven into a plain structure. Thereafter, the surface was finished and a heat-retaining fiber fabric having a basis weight of 250 g / m ² was obtained.

<Prescription 1>
Chrome dye [made by Taoka Chemical Industry Co., Ltd., trade name “Sunchromine Black P2B”] 6.0% by mass
pH adjuster formic acid (concentration 85%) 1.5% by mass
Leveling agent [manufactured by Huntsman Advanced Materials, trade name “Albegal SET”] 0.8% by mass
In formulation 1, the pH was adjusted to 4.5-5.

(Example 2)
In the same manner as in Reference Example 1, the wool top subjected to the oxidation treatment was set to 60 at 100 ° C. with a bath ratio set to 1:15 in a dye bath having the composition shown in Formula 2 below using a top dyeing machine. Stained for minutes. Next, a dyed wool top and a polyester fiber sliver (product name “Thermotron”, 2.2 decitex, fiber length: 80 mm, manufactured by Unitika Co., Ltd.) kneaded with 2% by mass of zirconium carbide are mixed with a mixing machine mixing gil. A wool fiber mixed with 10% by mass of polyester fiber was mixed, subjected to the spinning process in the same manner as in Reference Example 1, spun, made into a wool spun yarn having a thickness of 60th, and then woven into a plain structure. . Thereafter, the surface was finished and a heat-retaining fiber fabric having a basis weight of 250 g / m ² was obtained.

<Prescription 2>
1: type 2 metal complex hydrochloric acid dye [manufactured by DYATAR Japan, trade name “Isolan Black S-BGL”] 5.0 mass%
pH adjuster anhydrous sodium sulfate 2g / l
Leveling agent [Product name “Avolan UL-75” manufactured by LANXESS] 1.0% by mass
In Formula 2, the pH was adjusted to 4.5-5 using acetic acid.

(Example 3)
A fabric was produced by plain weaving of wool spun yarn having a thickness of 60th (manufactured by Unitika Category, trade name “Unitika wool”). The fabric was oxidized with an oxidizing agent aqueous solution containing 2.0% by mass of dichloroisocyanuric acid at a bath ratio of 1:15 at 20 ° C. for 10 minutes, and then acetic acid (concentration 80%) was applied to the fabric. 2.0% by mass was added, and further oxidized at 20 ° C. for 30 minutes. Further, 1.6% by mass of sulfuric acid (concentration 98%) was added to the fabric, the temperature was raised to 30 ° C., and oxidation treatment was further performed for 10 minutes, followed by washing with water. And after neutralizing with a neutralizer aqueous solution containing 3.0% by mass of sodium sulfite and setting the bath ratio to 1:15 at 20 ° C. for 10 minutes, the temperature is raised to 35 ° C. and further 20 minutes. Neutralization treatment and washing with water completed the oxidation treatment.

  Subsequently, using a liquid dyeing machine (manufactured by Nisaka Seisakusho Co., Ltd., trade name “Circular”), a bath ratio of 1:15 was set at 100 ° C. in a dyeing bath having the composition shown in Formula 3 below. It was dyed for 60 minutes, washed with water and dried to obtain a dyed fabric.

Finally, the dyed fabric was impregnated in a mixed aqueous solution of the following formulation 4 at a drawing ratio of 80%, dried at 110 ° C. for 3 minutes, and heat-treated at 160 ° C. for 1 minute. Thereafter, the surface was finished and a heat-retaining fiber fabric having a basis weight of 250 g / m ² was obtained.

<Prescription 3>
1: type 2 metal complex hydrochloric acid dye [manufactured by Nippon Kayaku Co., Ltd., trade name “Kayakalan Black 2RL”] 5.0 mass%
pH adjuster Ammonium sulfate 5.0% by mass
In Formula 3, the pH was adjusted to 6-7.

<Prescription 4>
Anthraquinone infrared absorber [Nippon Kayaku Co., Ltd., trade name "KP DEEPER NR" 5g / L
Acrylic binder [made by Kitahiro Chemical Co., Ltd., trade name “Light Epoch AX-30”] 20 g / L

(Comparative Example 1)
In Reference Example 1, a fabric dyed by the same method as in Reference Example 1 was obtained except that the wool top was not oxidized.

(Comparative Example 2)
The spun yarn was plain woven to obtain a fabric, and the steps until the fabric was oxidized were performed in the same manner as in Example 3. Thereafter, using a liquid dyeing machine, dyeing was performed at 100 ° C. for 60 minutes in a dyeing bath having the composition shown in Formula 5 below with a bath ratio set to 1:15. And after washing with water, neutralization treatment is performed at 80 ° C. for 20 minutes at a bath ratio of 1:15 using an aqueous ammonia solution adjusted to pH 8.5, followed by washing, removal of ammonia, washing with water, drying, and finishing in this order. And a dyed fabric was obtained.

<Prescription 5>
Acid dye [manufactured by DYSTAR JAPAN, trade name “Telon Black M-VLG”] 6.0% by mass
pH adjuster Ammonium sulfate 4.0% by mass

For the fabrics obtained in the examples , reference examples, and comparative examples, the L * value and the reflectance were measured, respectively. The results are shown in Table 1.

In addition, a combination of Reference Example 1 and Comparative Example 1, Example 2 and Comparative Example 1, Example 3 and Comparative Example 2 was used to sew a suit for thermal insulation evaluation by a wearing test, and the thermal insulation was measured. Are shown in FIGS.

図１〜図６、表１から明らかなように、本発明の保温繊維布帛（実施例２〜３）および参考例１の保温繊維布帛は、酸化処理が施された獣毛繊維を含み、含金属染料で染色され、かつ赤外線吸収剤を含有しており、波長７００ｎｍ以上９００ｎｍ未満における反射率が３０％以下でかつ波長９００ｎｍ以上１１００ｎｍ以下における反射率が４０％以下であり、Ｌ＊値が１５以下であるため、優れた保温性を有するものである。また、本発明および参考例の何れの保温性布帛も羊毛繊維を含むため、ソフトな風合いと嵩高性、吸湿性に優れるものである。

As is clear from FIGS. 1 to 6 and Table 1, the heat insulating fiber fabrics of the present invention (Examples 2 to 3) and the heat insulating fiber fabric of Reference Example 1 contain animal hair fibers that have been subjected to oxidation treatment, and contain It is dyed with a metal dye and contains an infrared absorber. The reflectance at a wavelength of 700 nm to 900 nm is 30% or less, the reflectance at a wavelength of 900 nm to 1100 nm is 40% or less, and the L * value is 15 Since it is the following, it has the outstanding heat retention. In addition, since any of the heat-retaining fabrics of the present invention and the reference example contains wool fibers, they are excellent in soft texture, bulkiness and hygroscopicity.

On the other hand, in Comparative Example 1, since the wool top was not oxidized, the temperature rise was small and the heat retention was inferior.
Since Comparative Example 2 was dyed with a dye that was not a metal-containing dye and did not contain any infrared absorber, the temperature rise was small and the heat retention was poor.

Claims (2)

A fabric composed of a mixed spun yarn of an animal hair fiber that has been oxidized and dyed with a metal-containing dye and a synthetic fiber containing zirconium carbide, and has a reflectance of 30 at a wavelength of 700 nm or more and less than 900 nm. % or less and is the reflectance of the cloth in the above wavelength 900 nm 1100 nm or less than 40%, and the fabric of the coercive temperature fiber fabric you, wherein the L * value is 15 or less. A fabric comprising oxidized animal hair fibers, the fabric being dyed with a metal-containing dye, zirconium carbide or an anthraquinone-based infrared absorber attached to the fabric with a binder, and reflection of the fabric at a wavelength of 700 nm to less than 900 nm rate is 30% and the reflectance of the cloth in the above wavelength 900 nm 1100 nm or less than 40% and a coercive temperature fiber cloth you wherein the L * value of the fabric is 15 or less.

Images