KR930006013B1 - Fine denier two component corespun yarn for fire resistant safery apparel and manufacturing method thereof - Google Patents

Abstract

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Description

2-corespun yarn for making fireproof safety suit with small denier

1 is an enlarged cross-sectional view of a fragment of the core spun yarn of the present invention and a portion of the coated yarn removed at one end thereof.

2 is a partial schematic perspective view of a portion of a Murata air jet spinning apparatus used to form a two-core spun yarn having a small denier of the present invention.

3 is a partially enlarged perspective view of a fabric (knitted fabric) knitted with the core spun yarn of FIG.

The person who forms the fabric useful for the production of fire resistant safety suit of the present invention relates to a core spun yarn composed of two components having denier (hereinafter referred to as '2-core spun yarn'), in particular a core made of heat resistant fiber. And a core spun yarn composed of a core wrapper made of cold-resistant fibers surrounding and enveloping the screening.

In general, methods for producing heat resistant fabrics composed of various types of yarns have been known. For example, dangerous industrial uniforms, firefighter uniforms, and military protective uniforms have been made from woven fabrics of non-synthetic fibers such as cotton or wool. These fabrics are then treated with refractory based on conventional halogens and phosphorus or one of them. By the way. Uniforms made from this type of fabric are restricted to medical life and are heavier than non-fire resistant fabrics. Chemical treatment typically increases the weight of the fabric by about 15% to 20%. Burning this type of fabric results in brittle charcoal as the fabric moves.

Also formed of non-combustible or heat-resistant fibers or nomex. Fire resistant safety suits of woven fabrics formed from blends of non-combustible fibers such as Kevlar or PBI are also known. These fabrics show thermal stability but are very expensive to produce and lack the comfort, water absorption and dyeing properties of fabrics made from natural fiber yarns.

US Patent No. 4,381,639; 4,500,593; And 4,670,327 show yarns for heat resistant fabrics comprising continuous glass filament coatings coated with a layer of heat resistant aramid fibers. However, the yarns and fabrics shown in these patents are very expensive to produce because the fibers required to make these yarns and fabrics are expensive. In addition, the yarns and fabrics shown in these patents have the appearance characteristics of aramid fibers and therefore do not have the desirable appearance characteristics of the dyeability and comfort of conventional natural fibers such as cotton and wool.

U. S. Patent No. 4,331, 729 shows a heat resistant fiber made of yarn comprising carbon filament screening and aramid coated yarns. The yarns and heat resistant fabrics shown in these patents include disadvantages of the type as indicated in the prior art patents.

Pending U.S. Patent Application No. 288,682, filed December 22, 1988, describes a core spun yarn consisting of three components that form a fabric useful for the production of fire resistant safety clothing (hereinafter referred to as '3-core spun yarn'). Appears. The three-core spun yarn shown in the pending applicant's application consists of a screen consisting of heat resistant fibers, an endothelial radiation consisting of a cold resistant fiber and an outer skin radiation. This three-core spun yarn is spun in a DREF friction spinning device, and the thinnest parameter obtained using this device is the 12/1 cotton yarn variable (equivalent to 380 denier). These three-core spun yarns are desirable to provide fine tissue fabrics with fine parameters, giving excellent fire resistance, dyeability and comfort to fabrics made using them.

The object of the present invention is to have a small denier forming a microstructured fabric useful for the production of fireproof safety suits with the appearance, feel, dyeability and comfort, which is a general characteristic of fabrics composed of conventional natural fibers and having no fireproof properties. -To provide a core spinning yarn.

및 아사히 케미컬 캄파니(Asahi Chemical co.)의 라스탄

과 같은 열안정화되고 산회된 폴리아크릴로니트릴 섬유가 있다. 피복사를 형성하는 내한성 섬유로는 면, 모, 폴리에스테르, 모다크릴과 같은 천연 섬유 도는 합성 섬유나 이들의 혼방인 섬유가 있다. 본 발명의 작은 데니어를 갖는 코어방적사는 22/1(242데니어), 20/1(266데니어), 18/1(295데니어)의 면사 번수로 제조한다.The two-core spun yarn having the small denier of the present invention includes a screening of heat-resistant fibers and an endothelial or outer skin of cold-resistant fibers which are covered and covered. Heat-resistant fibers forming the screen include aramid fibers such as Kevlar or Nomax, polybenzimidazoles such as PBI, or RK Textiles, Ltd.

And rastan from Asahi Chemical Co.

Thermally stabilized and acidic polyacrylonitrile fibers such as; The cold resistant fibers forming the coated yarn include natural fibers such as cotton, wool, polyester, and modacryl, or synthetic fibers or fibers thereof. The core spun yarn having the small denier of the present invention is manufactured with cotton yarn counts of 22/1 (242 denier), 20/1 (266 denier) and 18/1 (295 denier).

The screening of heat resistant fibers constitutes about 20% to 25% of the total weight of the core spun yarn and the coated yarn of cold resistant fibers constitutes about 80% to 75% of the total weight of the core spun yarn. When the screening of heat-resistant fiber accounts for about 20% of the total weight, the coated yarn of cold-resistant fiber preferably accounts for about 80% of the total weight.

The core spun yarn is preferably manufactured by a MURATA air jet spinning device (MJS) which feeds together the screening yarn of the heat resistant fiber and the coated yarn of the cold resistant fiber together through the inlet end of the supply trumpet. The fibers pass through the stretching section and pass through the air jet nozzle in the opposite direction and are then wound in a take-up package. Air jet nozzles allow the coated yarn of cold-resistant fibers to wrap around the screening, and this yarn and its fabric are twisted with very few threads. Since it has rotational and color, the surface property has the property of the cold resistant fiber forming the coated yarn.

Coated yarns made of cold-resistant staple fibers, which are covered with a flame and high temperature when the fabric formed of the two-core spun yarn having the small denier of the present invention is covered by the flame, are burned and burned, but the periphery of the glass fiber yarn to provide a thermal insulation wall Remains on. The screening of the heat-resistant fiber remains undamaged even after a continuous coating of cold-resistant organic fiber, leaving a char for lattice to block the flow of oxygen and other gases, and the residue of the supporting lattice burns the coated yarn It provides a structure that keeps the fabric intact even after it is finished.

The corespun yarn of the present invention can be produced at a much lower cost than refractory fabrics formed of yarns containing a large amount of heat resistant fibers because they comprise a small amount of valuable non-acidic heat resistant fibers, preferably about 20%. For example, the heat resistant fibers to be screened are about $ 9 to $ 10 per pound, while the cotton fibers that make up the coated yarn are about 60 to 80 cents per pound. Therefore, the use of about 80% cotton fibers can significantly reduce the manufacturing cost of the core spun yarn of the present invention.

When the present invention exposes a fabric made from corespun yarn to high temperatures and flames, the coated yarn is burned and left around the screening of heat resistant fibers to make the insulation walls. This creates an insulating air gap between the skin and the fabric. This property is important in fires where firefighters wearing shirts made of this fabric must be thermally protected by an insulating layer of air between his clothing and skin, and the examination will not be compromised if the sheath burns out.

Fabrics knitted with the corespun yarns of the present invention can be treated using conventional refractory agents similar to the fire treatment methods used for dyeing, printing and producing 100% cotton fibers. However, the weight applied to the fabric by the refractory treatment is substantially reduced by about 10% to 12% because the screening, which is a heat resistant fiber, does not absorb the fire resistant agent. Substantially about 10% to 12% decrease because the screening, which is a heat resistant fiber, does not absorb the fire resistant agent. Fabrics made from the corespun yarn of the present invention do not melt, drip, stray or afterglow when burned. The carbonized outer portion of the fabric maintains the flexibility and integrity of the unburned portion of the fabric.

Other objects and advantages will appear from the description of the accompanying drawings.

As broadly shown in FIG. 10, the two-core spun yarn having the small denier of the present invention includes a screen 11 of heat resistant fiber and a cover 12 of cold resistant fiber surrounding and covering the screen 11. Include. As shown in FIG. 1, the screening 11 made of heat resistant fiber extends in the axial direction and the longitudinal direction of the core spun yarn 10, and most of the coated yarns 12 made of cold resistant fiber are spirals around the screening 11 Extend in the direction. A small portion of the coated yarn 12 is separated to form stitched yarns that spirally wrap around the majority of the fibers as shown in FIG. Since the coated yarn 12 made of cold-resistant staple fibers surrounds and covers the periphery of the screening 11, the outer surface of the yarn has the appearance and characteristics of the cold-resistant staple fibers constituting the coated yarn 12.

및 아사히 케미컬 캄파니(Asahi Chemical co.)의 라스탄

과 같은 열안정화 되고 산화된 폴리아크릴로니트릴 섬유 또는 이들 섬유의 혼방으로 구성된 섬유 가운데서 선택한다. 내한성 섬유로된 피복사(12)는 면, 모, 폴리에스테르, 모다크릴, 레이온 또는 이들 섬유의 혼방과 같은 천연 섬유 또는 합성 섬유 가운데서 선택한다.The screening 11 of heat resistant fibers is essentially made from aramid fibers such as Kevlar and Nomex, polybenzimidazole fibers such as PBI, or Panox from RK Textiles, Ltd.

And rastan from Asahi Chemical Co.

It is selected from thermally stabilized and oxidized polyacrylonitrile fibers such as fibers composed of a blend of these fibers. The coated yarn 12 of cold resistant fibers is selected from natural or synthetic fibers such as cotton, wool, polyester, modacryl, rayon or blends of these fibers.

The screening 11 of the heat resistant fiber comprises about 20% to 25% of the total weight of the core spun yarn 10, and the coated yarn 12 of the cold resistant fiber constitutes about 80% to 75% of the total weight of the core spun yarn 10. do. It is preferable that the coated yarn 12 of cold resistant fiber accounts for about 80% of the total weight when the screening 11 of the heat resistant fiber accounts for about 20% of the total weight. The screen 11 may be composed entirely of aramid fibers or may be composed of a mixture of aramid fibers and polybenzimidazole fibers. The coated yarn 12 surrounds and covers the screen 11 so that the fibers constituting the screen 11 are completely hidden from the appearance of the fabric composed of the yarn.

as mentioned above. The core spun yarn 10 of the present invention is preferably made of Murata air jet spinning apparatus of the type schematically shown in FIG. US Patent No. 4,718,225 for Murata Air Jet Spinners; No. 4,551,887; And 4,497,167. As schematically shown in FIG. 2, the air jet spinning apparatus follows the sliver of the coated yarn 12 of cold resistant fiber to form the coated yarn 11 of heat resistant fiber to form a coated yarn that surrounds and coats the coated yarn. And an inlet drum 15 for feeding. The fibers then pass through a draw roll pair 16, a flowable swirling first air jet nozzle 17 and a second jet nozzle 18. This yarn is drawn from the second air jet nozzle 18 by the delivery roll assembly 19 and then wound around a winding bundle (not shown). As schematically shown in FIG. 2, the first and second air jet nozzles 17 and 18 are configured to rotate the fluid in the opposite direction. The first and second air jet nozzles 17 and 18, which operate in the opposite direction, induce a portion of the staple fibers to separate and wind around the unseparated staple fibers, which are in close contact with the screening 11. The state of the coated yarn 12 to be enclosed and covered is maintained.

The following examples are described to illustrate one form of core spun yarn made in accordance with the present invention. The Han Chinese end of the 50-hank roving of the heat resistant Kevlar screening 11, which provides a weight of 20% of the total net weight, is fed to the inlet end of the inlet trompat 15. At the same time, one end of a 100% facet cotton slicer is provided at the distal end of the inlet trumpet 15, providing a weight of up to 80% of the total net weight. The screening is fed to the top of the cotton sliver so that the cotton fibers are wound around the screening. The core spun yarn with the small denier obtained by this air jet spinning process makes the knitted fabric 20 of the flat jersey structure shown in FIG. The core spun yarn 10 forms a continuous looping course in the knitted fabric 20.

This knitted fabric 20 is particularly suitable for the use of a protective cover or a firefighter's underwear and can be dyed, refractory chemically treated, and, if desired, processed in form-fixed resin. This knitted fabric has desirable fire resistance properties that are not present in knitted fabrics consisting solely of cotton fibers, while having a feel and appearance similar to those of 100% cotton fibers.

When treated with the National Fire Prevention Association Test Method (NFPA 701), which includes a 12-second vertical combustion process in a Bunsen combustor flame, the fabric is less than 3.81 cm free of afterglow or afterglow. The length of carbonization is shown. Fabrics exposed twice a second for 12 seconds to hot flowing butane flames according to Federal Test Method 5905 have a vertical combustion of 0 seconds of residual flame and 22% of combustion. Similar weights and similar types of fabrics treated result in 6 seconds of residual flame and 45% combustion. Throughout the entire combustion test, the carbonized part of the remaining fabric is soft, flawless and shows no brittleness, meltability, or fabric shrinkage. While burning the sheath of cotton fibers, the carbonized portion remains in a position surrounding the screening of heat resistant Kevlar fibers to form a thermal barrier and the Kevlar screening provides a matrix or lattice to prevent the fabric from breaking. The insulation wall prevents the flame from passing through the fabric and touching the skin of the person wearing the suit.

In the fabric used to form the fire resistant safety suit, as described herein, the corespun yarn 10 comprises a screen 11 of two components, namely heat resistant fibers extending in the axial or longitudinal direction of the yarn. It includes a coated yarn 12 made of cold-resistant fibers extending in a spiral direction around the screen 11 and covering the screen. The screening 11 of heat resistant fibers is essentially selected from fibers consisting of aramid fibers, polybenzimidazole fibers and heat stabilized and oxidized polyacrylonitrile fibers, and the screening 11 when burned in a hot flame It stays as it is. The coated yarn 12 provides the desired surface properties of the fabric composed of this core spun yarn. When the fabric composed of the core spun yarn is exposed to a high temperature flame, the coated yarn 12 is burned to charcoal but remains around the screening 11 and maintains the same flexibility and original appearance as the unburned fiber.

The most preferred embodiments for carrying out the present invention have been described in the drawings and the specification, and the specific terms used in the present specification are used in a general and technical sense, and are not intended to limit the scope of the present invention. It is intended to limit the scope of the claims.

Claims (6)

Consisting essentially of a screen consisting of a heat resistant fiber selected from fibers consisting of aramid fibers, polybenzimidazole fibers, and heat stabilized and oxidized polyacrylonitrile fibers, and a sheath of cold resistant fibers surrounding the screen. 2-core spun yarn for the manufacture of fire-resistant safety clothing having a small denier. The method of claim 1, wherein the screening of the heat resistant fiber comprises 20% to 25% of the total weight of the core spun yarn, and the coated yarn of the cold resistant fiber comprises 80% to 75% of the total weight of the core spun yarn. 2-core spun yarn for producing fire resistant safety suit with denier. 3. The fire resistant with small denier according to claim 2, wherein the screening of heat resistant fibers constitutes about 20% of the total weight of the core spun yarn, and the coated yarn of cold resistant fibers constitutes about 80% of the total weight of the core spun yarn. 2-core spun yarn for the manufacture of safety clothing. 2. A two-core spun yarn for producing fire resistant safety suit according to claim 1, wherein the screening comprises aramid fibers. 2. A two-core spun yarn for the manufacture of fire resistant safety suit having a small denier according to claim 1, wherein the coated yarn comprises cotton fibers. 5. A two-core spun yarn for producing fire resistant safety suit according to claim 4, wherein the screening comprises Kevlar fibers.

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