JP3366179B2 - Composite fiber structure that can be used for clothing for disaster prevention - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to heat resistance, heat insulation,
The present invention relates to a composite fiber structure having water absorption, water retention and waterproof properties. For example, the present invention, in particular, by absorbing water, firefighting clothes excellent in heat resistance and heat insulation, and during a fire,
The present invention relates to a composite fiber structure that can be used as evacuation clothing or disaster prevention clothing that protects the body from flames and heat of fire. The present invention also relates to a composite fiber structure that can be used for disaster prevention clothes and the like that can be used for, for example, cloth stretchers and cooling of burn sites by utilizing the absorbability of water and body fluids such as blood.

[0002]

2. Description of the Related Art Conventionally, in order to protect the body from a flame and heat of a fire in the case of fire, fire fighting clothes made of a chemical fiber such as aromatic polyamide having excellent heat resistance, or a material obtained by mixing wool with it. Has already been devised. In addition, firefighting clothes and the like manufactured using these materials have a multi-layered structure or the like in order to increase the heat resistance and to thicken the clothes and to secure an air layer. However, such thick clothing or multi-layered structure inevitably increases the weight of the fire fighting clothing and the like, which is a burden especially for use by the elderly and people with weak disaster prevention. Moreover, since special chemical fibers are used, these fire fighting clothes and the like are expensive and unsuitable for spreading to the public. On the other hand, the disaster prevention hood is widely used as a disaster prevention article, but protection of only the head cannot sufficiently protect the whole body, and cannot protect the lower part of the chest. By the way, as an evacuation method using water, there is also a method of covering the body with wet sheets and evacuating, but since the amount of water that adheres is small due to thin cloth, long-term heat resistance and heat insulation cannot be expected. In addition, there is a problem that it clings to the feet and interferes with evacuation.

As an evacuation method using this water, one using a fireproof clothing to absorb water has been devised (Japanese Patent Publication No. Sho.
50-34454). The heat-resistant garment disclosed in this publication has a water bladder stored inside, and in the event of a fire or the like, water is leached out by a means such as crushing the water bladder, so that the clothes can be sufficiently infiltrated to have a heat resistance effect. It is intended to improve. However, in this case, since the clothes are filled with water, there is no air layer in the clothes, and the clothes are integrated into the front and back, so that there is a risk that heat is easily transferred to the inside. Further, since the water bladder is usually put in the heat resistant clothes, there is a problem that it is heavy and difficult to use.

[0004]

Therefore, the present invention uses a relatively inexpensive material, is usually lightweight and convenient to carry, and, for example, in the case of a fire or the like, a shower or An object of the present invention is to provide a composite fiber structure capable of producing a fire fighting suit or the like having excellent heat resistance and heat insulating properties by spraying water from a hose or the like over the whole body and absorbing the water throughout. Another object of the present invention is to provide a composite fiber structure capable of producing a disaster-prevention garment that can be used for cooling a cloth stretcher and a burned part by utilizing the water absorbency or liquid absorbency of the material.

[0005]

Means for Solving the Problems As a result of intensive studies to achieve the above object, the present inventor has found that the above object can be achieved by constructing a composite fiber structure as follows. The invention has been reached. That is,
The present invention has the following elements: (1) Outer fabric having a flame-retardant natural cellulose fiber woven fabric and having a limiting oxygen index of 28 to 33, (2) a limiting oxygen index provided adjacent to the outer fabric. A first intermediate layer composed of 28 to 33 non-woven fabric and having a water absorption of 1000 to 3000 g per 100 g / m ² in free water absorption at 20 ° C. for 20 minutes, (3) provided adjacent to the first intermediate layer It is composed of a non-woven fabric having a limiting oxygen index of 28 to 33, and has a free absorption of 100 at 20 ° C. for 20 minutes.
It has a water absorption of 700g or less per g / m ² and a basis weight of 70
-200 g / m ² of the second intermediate layer, and (4) the second intermediate layer, which is provided adjacent to the second intermediate layer and is made of a flameproof fabric having a limiting oxygen index of 28 to 33. And a lining layer having a rubber layer on its side, the invention relates to a composite fiber structure.

[0006]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described in detail below. The surface material used for the composite fiber structure of the present invention forms a surface layer in the composite fiber structure and has flameproof property and, when sprayed with water, allows water to permeate through the water. Has a lower ability to retain water, and therefore has the effect of delivering water to the superabsorbent first intermediate layer, described below. Therefore, the outer material is made of a natural cellulose fiber woven fabric that has been subjected to a flameproof treatment. Examples of the natural cellulose fiber woven fabric subjected to the flameproof treatment include a woven fabric made of cotton, hemp (for example, ramie, linen, etc.). The flameproof treatment has been conventionally known, and various flameproof treatments can be adopted. The flameproof treatment may be performed on the woven fabric after the natural cellulose fibers constituting the woven fabric are woven, or on the woven fabric itself. In the present invention, as the flameproof treatment, it is preferable to perform the flameproof treatment described in JP-B-61-25829. More specifically, this flameproof treatment is performed by using a phosphorus compound having the following formula and a resin having a film-forming ability, and adhering these to natural cellulose fibers.

[0007]

[Chemical 1]

(In the formula, R and R'are the same,
And R ′ may be chlorinated, m is an integer of 1 or 2, and n is 1 to 30; Indicates an integer. ) Examples of the aliphatic hydrocarbon residue as R and R ′ include an ethyl group or a propyl group (including an isopropyl group)
The residue derived from is mentioned. Preferred examples of the phosphorus compound represented by the above formula include the following.

[0009]

[Chemical 2]

[0010]

[Chemical 3]

Further, bis [bis (2-chloroethoxy) phosphinyl] isopropylchloroethyl phosphate represented by the following formula (trade name: NONNEN C-21
0) is displayed as the flameproofing association certified code PC-3, which is a preferable compound that can be used for the flameproofing treatment in the present invention.

[0012]

[Chemical 4]

The phosphorus compound is usually 1 to 40% by weight, preferably 3 to 30% by weight based on the weight of natural cellulose fiber.
Attached in wt%. On the other hand, as the resin having a film-forming ability, for example, trimethylolmelamine, melamine-formaldehyde precondensate, urea-formaldehyde precondensate, phenol-formaldehyde precondensate, urea-melamine-formaldehyde precondensate, acrylic acid. Examples thereof include ester resins, vinyl chloride resins, vinylidene chloride resins, SBR resins, ethylene-vinyl acetate-vinyl chloride copolymer resins, acrylic acid-vinylidene chloride copolymer resins. These resins are usually deposited in an amount of 1 to 30% by weight, preferably 3 to 20% by weight, based on the weight of natural cellulose fibers. The flameproof treatment is carried out by dissolving or emulsifying a phosphorus compound and a resin in water or an organic solvent, or dispersing them, and adding other additives as necessary to prepare a processing liquid, and then preparing natural cellulose fibers or the same. After dipping the woven fabric in the processing liquid, squeezing and drying, or by applying with a spray, brush coating, roller, etc., usually,
0.5 at 120 to 180 ° C, preferably 160 to 170 ° C
By heating for ~ 3 minutes, preferably 0.5-1 minutes,
It can be carried out by a method such as attaching.

The flameproofing treatment can be carried out, for example, by preparing a processing liquid using methyloldimethylphosphonospropionamide (nonnene A) as an aqueous solution, immersing it in cotton cloth or the like, and drying it. As a dress material, the limiting oxygen index (LOI) is 28 to 33, preferably 30 to
What is 33 is used. The flameproof function can be exhibited within the range of the limiting oxygen index. The thickness of the outer material is usually 0.05 to 0.5 mm, preferably 0.1
~ 0.3 mm. Also, the basis weight (weight) of the outer material is usually
80-250 g / m ² , preferably 150-200 g / m ² . The first intermediate layer used in the composite fiber structure of the present invention is a layer having a high ability to absorb and retain water that permeates from the surface material. This first intermediate layer is
When contacting the flame on the surface side, it has a function of preventing the temperature from rising excessively by utilizing the heat of vaporization of water absorbed in this portion. Further, the first intermediate layer itself also needs to have a limiting oxygen index of 28 to 33 and flame resistance.
Therefore, the first intermediate layer has a limiting oxygen index of 28 to 33.
Made of non-flame treated non-woven fabric,
The free water absorption at 0 minutes has high water absorption of 1000 to 3000 g of water per 100 g / m ^{2 of} the first intermediate layer.

As the non-woven fabric in the first intermediate layer, a non-woven fabric containing a fiber made of a super absorbent polymer (hereinafter referred to as super absorbent fiber) or powder is preferably used. That is, the non-woven fabric may be composed of super absorbent fibers and flameproof fibers, or may be one in which powder composed of superabsorbent polymer is fixed in the non-woven fabric formed of flameproof fibers. As the flameproof fiber, for example, a fiber material certified by the flameproof product certification committee can be preferably used. As such a fibrous material, for example, a fibrous material which is indicated as a class A, a class PA, or a class PC with a certification code can be preferably used. Examples of such fibers include phenol-based (trade name: Kynol) (A-8), polyclar (trade name: Cordelan) (PA-1), flame-retardant acrylic (trade name: rufunen).
(PA-2), acrylic (trade name: Kanecaron) (P
A-3), flame-retardant acrylic (brand name: Super Balcer) (PA-4), flame-retardant polynosic (brand name: Toughban) (PA-5), aramid (brand name: Conex)
(PA-6), aramid (trade name: Apierre) (PA
-7), Flame-retardant acrylic (Product name: Cashimiron non-bar)
(PA-8), polyvinyl chloride (trade name: Teviron)
(PA-9), flame-retardant polyester (trade name: Trevira C
S) (PA-10), flame-retardant vinylon (trade name: Vinard) (PA-11), and further flame-proofed fibers include Zapro (T) (PC-4) and the like. Their limiting oxygen index is 28-40. If a fiber material with a limiting oxygen index exceeding 33 is used,
The limiting oxygen index can be adjusted by using together a fiber material having a low limiting oxygen index so that the intermediate layer has a limiting oxygen index in the range of 28 to 33. Of these fibrous materials, the material that drops as a droplet by melting is not preferable. Also, a material that shrinks by heating is not preferable. Preferred fiber materials include, for example, Toughban, Conex, Apierre,
Kynol and the like can be mentioned.

As the superabsorbent fiber, a fiber made of superabsorbent polymer which has been conventionally used in diapers and sanitary products can be preferably used. In particular,
Various polymers have been conventionally devised as superabsorbent polymers. For example, polyvinyl alcohol,
A polymer obtained by cross-linking poly (hydroxyethyl methacrylate), polyethylene glycol or the like has a water absorption capacity 20 to 30 times its own weight. In addition, recently, the water absorption capacity is even greater,
For example, highly water-absorbent polymers that reach 1000 times their own weight are on the market. Examples of such super absorbent polymers include polymers and copolymers containing acrylate as a monomer unit. The water absorption capacity is greatly affected by the amount of hydrophilic groups (carboxyl group and carboxylate group (for example, sodium salt, potassium salt, ammonium salt, etc.)) existing in the molecule, and further by the degree of crosslinking. It is obvious to those skilled in the art how much water absorption is, and it can be easily confirmed experimentally.
The super absorbent polymer used in the first intermediate layer of the present invention is preferably a polyacrylate, for example, a polymer mainly containing sodium acrylate or potassium acrylate. Further, a starch grafted with an acrylate may be used.

As a preferred super absorbent fiber, Bell Oasis (trade name, manufactured by Kanebo Co., Ltd.) absorbs 40 g of water per gram of free water at 20 ° C. for 20 minutes. It is preferable to form the non-woven fabric by combining the highly water-absorbent fiber with various fiber materials certified by the above flameproof product certification committee (which may be flameproofed if necessary).
Usually, the superabsorbent fiber has a limiting oxygen index of 41 or more, so that the limiting oxygen index of the first intermediate layer is 28 to 33.
In order to achieve this, the limiting oxygen index can be easily adjusted by using a fiber material having a limiting oxygen index smaller than 28 in combination. Further, as described above, in the nonwoven fabric made of the fibrous material certified by the flameproof product certification committee, for example, particles made of superabsorbent resin such as bell oasis are used by using simple fiber entanglement such as pre-needle. By fixing, the limiting oxygen index of the first intermediate layer can be adjusted to be in the range of 28 to 33. The amount of super absorbent fibers or powder in the nonwoven fabric is usually 5 to 50% by weight, preferably 7 to 40% by weight, based on the weight of the nonwoven fabric. The thickness of the first intermediate layer is usually 2-1.
It is 5 mm, preferably 3 to 10 mm. A plurality of non-woven fabrics may be laminated and used, and the total thickness may fall within this range. The basis weight of the first intermediate layer is usually 50.
˜150 g / m ² , preferably 80 to 120 g / m ² .

The second intermediate layer in the composite fiber structure of the present invention has a smaller water absorption and water retention than the first intermediate layer, and has a function of providing a heat insulating effect by the air contained therein. Therefore, the second intermediate layer has a water absorption of 700 g or less, preferably 600 g or less per 100 g / m ² in free water absorption at 20 ° C. for 20 minutes, and has a basis weight of 70 to 200 g / m ^2. It is configured. The nonwoven fabric used in the second intermediate layer needs to have flameproofness. For the non-woven fabric forming the second intermediate layer,
No fiber or powder made of super absorbent polymer is used,
The non-woven fabric is composed of fibers having flame resistance so that the limiting oxygen index is 28 to 33. As the flameproof fiber constituting this non-woven fabric, the flameproof fiber described in the first intermediate layer can be preferably used. Preferred flameproof properties include flameproofed natural fibers such as ramie and wool. As the flameproof treatment, the flameproof treatment described above can be preferably adopted. As a preferable flameproof fiber, for example, non-nene C-21
Lamy fibers, Kynol, Zapro, etc., which have been subjected to flameproof treatment using 0 (PC-3). The basis weight of the second intermediate layer is 70 to 200 g / m ² , preferably 90 to 120 g / m ² .
m ² . If the basis weight is set within this range, the second
It is possible to allow sufficient air to be present in the intermediate layer to exert a heat insulating effect.

The thickness of the second intermediate layer is usually 2 to 15 mm,
It is preferably 3 to 10 mm. The backing layer used in the composite fiber structure of the present invention is used to impart flameproofness and waterproofness to the composite fiber structure. Therefore, the lining layer is made of a flameproof fabric, and the rubber layer is provided on the second intermediate layer side. As the woven fabric used for the backing layer, the woven fabric of the flameproof fiber described in relation to the second intermediate layer can be used. As a preferable woven fabric, for example, a woven fabric formed of Conex or the like can be preferably used. As the rubber layer used in the lining layer, those similar to those conventionally used in fire fighting clothing, disaster prevention clothing, etc. can be used without particular limitation. The rubber forming the rubber layer may be synthetic rubber or natural rubber. The rubber layer is bonded to the woven fabric by applying an unvulcanized rubber composition to a flameproofed woven fabric having a limiting oxygen index of 28 to 33 and then curing reaction by heating, and at the same time, is waterproof and heat insulating. Can be given. Alternatively, the woven fabric may be coated by bonding a film-shaped rubber with a heat-resistant adhesive. Further, the rubber layer may be blended with a reflective metal powder such as aluminum powder in order to impart heat radiation properties.

The thickness of the woven fabric is usually 0.05 to 0.3 mm, preferably 0.05 to 0.2 mm. The thickness of the rubber layer is usually 0.05 to 0.3 mm, preferably 0.05 to 0.2 mm. In the case of producing the composite fiber structure of the present invention, in order to enhance waterproofness and heat insulation, first, the outer material, the first intermediate layer and the second intermediate layer are fixed by, for example, a quilting process, and then the back Secure the formation to the laminate. For example, when the composite fiber structure of the present invention is formed into a fire fighting garment, it is appropriate that the lining layer be fixed so that the lining layer is joined by sewing only at the connecting portion of the garment. The composite fiber structure of the present invention thus obtained usually has a thickness of 4.
It is 15 to 31.1 mm, preferably 6.2 to 20.7 mm. The basis weight is usually 340 to 900 g / m ² , preferably 45.
It is 0 to 620 g / m ² . The composite fiber structure of the present invention is excellent in heat resistance, heat insulation, water absorption, water retention and waterproofness. For example, in the case of manufacturing firefighting clothes, disaster prevention clothes, etc. using the composite fiber structure of the present invention, in the event of a fire or the like, by spraying water from the head with a shower or a hose, Can be included in the first intermediate layer, and as a result, the temperature rise is suppressed by the heat of vaporization with respect to high temperature, and the heat insulation is enhanced by the air layer by the second intermediate layer, and further by the lining layer, Improves waterproofness and fireproofness. Also, because the fabric of the lining layer is on the skin side (inside),
It has a good texture on the skin and is easy to use. On the other hand, the composite fiber structure of the present invention is excellent in absorbability of body fluids such as water and blood, so by utilizing this characteristic, for example, as a cloth stretcher for carrying a patient with severe bleeding or an injured person, It can be used for cooling burns by including water.

[0021]

EXAMPLES The present invention will now be described in more detail with reference to examples. Manufacture of Each Element of Composite Fiber Structure (1) Manufacture of Outer Material (Element A) Nonnene C-210 and a melamine-formaldehyde initial condensate were dispersed in water to obtain a working liquid. In this processing liquid,
A cotton cloth for sheets was soaked and then heated at 165 ° C. for 1 minute to produce a surface material (containing 30% by weight of Nonnene C-210). The limit oxygen index of this dress material was 31. (2) Production of First Intermediate Layer (Element B) Three types of first intermediate layers were produced. i) A flame-retardant polyester (PA-10) (limit oxygen index 31) and Bell Oasis (Kanebo Co., Ltd. super absorbent fiber: sodium polyacrylate) were used in a weight ratio of 70:30 to form a nonwoven fabric. Manufactured. The thickness of this nonwoven fabric was 1 mm. The basis weight was 30 g / m ² .
Three sheets of this non-woven fabric were laminated and joined together by being entangled with a pre-needle to produce a first intermediate layer (B1). The thickness and basis weight of the first intermediate layer (B1) were 3 mm and 90 g / m ² , respectively. Further, the limiting oxygen index of the first intermediate layer is 28, which is water absorption by free water absorption at 20 ° C. for 20 minutes (hereinafter, simply referred to as “water absorption”).
Was 2500 g water per 100 g / m ² .

Ii) A flame retardant acrylic (PA-2) (limit oxygen index 32) and Bell Oasis (super absorbent fiber manufactured by Kanebo Co., Ltd.) were used in a weight ratio of 93: 7 to prepare a first intermediate layer. As a non-woven fabric (B2). This first intermediate layer (B
The thickness of 2) was 5 mm and the basis weight was 100 g / m ² . The limiting oxygen index of the first intermediate layer (B2) was 31, and the water absorption was 2000 g of water per 100 g / m ² . iii) Immersing the ramie fiber in an aqueous solution of Nonnen A, and using the flameproof ramie fiber (limit oxygen index 31) and bell oasis in a weight ratio of 90:10, the nonwoven fabric as the first intermediate layer ( B3) was produced. The thickness of the first intermediate layer (B3) was 5 mm, and the basis weight was 100 g / m ² . The limiting oxygen index of the first intermediate layer (B3) was 31, and the water absorption was 2200 g of water per 100 g / m ² . (3) Production of Second Intermediate Layer (Element C) Three types of second intermediate layers were produced. i) Flameproof ramie fiber 100 used in (2) iii) above
A non-woven fabric (C1) was produced as a second intermediate layer from the. The limiting oxygen index of the second intermediate layer (C1) is, the basis weight is 120 g / m ² , and the water absorption is 67 per 100 g / m ^2.
It was 0 g water.

Ii) 7 pieces of the above flameproof ramie fiber and flameproof wool (PC-4) (sabro processed, limiting oxygen index 30)
A non-woven fabric (C2) as a second intermediate layer was produced by using it in a weight ratio of 0:30. The limiting oxygen index of the second intermediate layer (C2) was 31, the basis weight was 120 g / m ² , and the water absorption was 600 g water per 100 g / m ² . iii) The flameproof ramie fiber and Kynol (A-8)
(Limiting oxygen index 33) was used in a weight ratio of 70:30 to produce a nonwoven fabric (C3) as the second intermediate layer. The limiting oxygen index of the second intermediate layer (C3) is 31,
The basis weight was 120 g / m ² and the water absorption was 550 g water per 100 g / m ² . (4) Production of Lining Layer (Element D) A woven fabric was produced from 100% fibers of Conex (aramid fiber, PA-6, limiting oxygen index 29 to 30). The thickness and basis weight of this fabric are 0.11 mm and 90 g / m ² respectively.
Met. Then, this fabric is rubberized with Hypalon containing aluminum powder to give a thickness of 0.1.
A 1 mm rubber layer (145 g / m ² ) was formed. The obtained backing layer is designated as D. Example 1 Outer material (A), first intermediate layer (B) and second intermediate layer (C) cut into a square size of 15 cm in length × 15 cm in width
Are laminated in this order, and a heat-resistant sewing machine (aramid fiber) is used to bond them to each other by quilting, and then
The rubber layer is the second layer of the lining layer (D) cut to the same size.
The layers were laminated so as to face the intermediate layer, and the both ends in the length direction were sewn and fixed by a heat resistant sewing machine. The resulting composite fiber structure had a thickness of 7.0 mm and a basis weight of 525 g / m ² . The obtained composite fiber structure (F) is lightweight,
It was very flexible.

For comparison, the following comparative composite fiber construction was prepared. (1) Comparative composite fiber structure (f-1) (basis weight 485 g /
m ² ) Structure: A / B1 / B1 / D This structure uses the same second intermediate layer as the first intermediate layer. (2) Comparative composite fiber structure (f-2) (basis weight 565 g /
m ² ) Structure: A / C1 / C1 / D This structure uses the same first intermediate layer as the second intermediate layer. (3) Comparative composite fiber structure (f-3) (basis weight 540 g /
m ² ) Structure: A / B1 / C1 / A This structure uses a front material instead of a backing layer. ISO convection heat test The resulting composite fiber structure was subjected to a convection heat test according to ISO 9151. This test tested 8 composite fiber structures.
It is fixed at a distance of 5 cm from a propane gas burner with a heat source of 0 KW / m ² , and the composite fiber structure is exposed to the flame from the heat source. From the start of the experiment, the composite fiber structure is provided on the side opposite to the burner of the composite fiber structure. This is a test for observing the temperature change of a thermometer placed in contact with an object. This test is
It is a test that requires that the time from the start of the test until the temperature of 24 ° C. rises is within 15 seconds, which is a severe test condition.

This test makes it possible to evaluate the heat resistance or heat insulation of the composite fiber structure. Each composite fiber structure does not contain water and contains 10 cc of water uniformly (444 g per 1 m ²
The above-mentioned test was carried out for water), 20 cc of water uniformly contained (889 g water per m ² ), and further, 30 cc of water uniformly contained (1333 g water per m ² ). The results of this experiment are shown in FIGS. Further, FIG. 5 shows the time-dependent change in water absorption after the composite fiber structure was immersed in water for 2 minutes. It can be seen from FIGS. 1 to 4 that the thermal protection improves with the water absorption amount. In particular, regarding the composite fiber structure (F) of the present invention, when the water absorption amount is 20 cc or more, compared with the other composite fiber structures (f-1 to f-3), especially the first 15 to 20 seconds. Excellent thermal protection is obtained. On the other hand, in the comparative composite fiber structure, f-1 can quickly absorb a large amount of water (FIG. 5).
However, because there is no air insulation between the lining layer and
The external high temperature is easily transmitted to the inside. Further, in f-2, on the contrary, since the water absorption capacity is poor, the effect of suppressing the temperature rise due to the heat of vaporization becomes smaller with time after absorbing water. Further, in f-3, since the backing layer is not used, heat is immediately transferred to the inside.

For reference, conventionally used materials for fire protective clothing (almix fire protective clothing) (s-1) or (one aramid fiber woven fabric (s-2) or two layers (s) -3)) was similarly tested. The result is shown in FIG. As can be seen from these results, the conventional material is much inferior to the composite fiber structure of the present invention (see FIG. 1) in the heat protection property in the initial 15 to 20 seconds when the water absorption is 0 cc. I understand. Example 2 (manufacture of fire fighting clothes or disaster prevention clothes) Using the composite fiber structure (F) manufactured in Example 1,
The firefighter's suit shown in FIG. 7 (which can also be used as a disaster suit) was manufactured. In FIG. 8, 1 is a fire fighting suit manufactured from the composite fiber structure (F) 2. Here, 3 indicates a smoke mask. The fire fighting clothing produced from the composite fiber structure (F) of the present invention is usually light and flexible, convenient to carry and excellent in workability. Further, when water was sprayed from the hose and the entire fire fighting suit 1 was made to contain water, the weight increased, but workability and thermal protection were excellent.

The composite fiber structure of the present invention is excellent not only in absorbing water but also in body fluids such as blood. Therefore, the composite fiber structure of the present invention is very useful as a stretcher base cloth for carrying an injured person.

[Brief description of drawings]

FIG. 1 is a diagram showing the results of a thermal protection test with a water absorption of 0 cc.

FIG. 2 is a diagram showing the results of a thermal protection test with a water absorption of 10 cc.

FIG. 3 is a diagram showing the results of a thermal protection test with a water absorption amount of 20 cc.

FIG. 4 is a diagram showing the results of a thermal protection test with a water absorption amount of 30 cc.

FIG. 5 is a diagram showing the results of a water retention test.

FIG. 6 is a view showing a result of a thermal protection test on a conventional protective material.

FIG. 7 is a diagram showing a fire fighting suit manufactured by the composite fiber structure of the present invention.

[Explanation of symbols]

1 Fire suit 2 Composite fiber structure 3 smoke mask

─────────────────────────────────────────────────── ─── Continued front page (72) Inventor Yoshio Otsuka 1-13-20 Hatagaya, Shibuya-ku, Tokyo Inside the Tokyo Fire Department Fire Science Institute (72) Inventor Mikio Kobayashi 1-13-20 Hatagaya, Shibuya-ku, Tokyo No. Tokyo Fire Department Fire Science Research Institute (72) Inventor Shuji Kawasaki 1-13-20 Hatagaya, Shibuya-ku, Tokyo Tokyo Fire Department Fire Science Research Institute (56) Reference JP-A-48-50074 (JP, A) ) JP-A-9-141787 (JP, A) JP-A-4-234640 (JP, A) JP-A-60-127142 (JP, A) Actually open 4-132934 (JP, U) Actually open 5- 95644 (JP, U) (58) Fields surveyed (Int.Cl. ⁷ , DB name) B32B 1/00-35/00 A41D 31/00 A41D 13/00 D06M 15/00-15/715

Claims (2)

(57) [Claims] 1. A composite fiber structure having the following constitution. (1) A dress material having a flame-retardant natural cellulose fiber woven fabric and a limiting oxygen index of 28 to 33, and (2) a nonwoven fabric having a limiting oxygen index of 28 to 33 provided adjacent to the dressing material. And a first intermediate layer having a water absorption of 1000 to 3000 g per 100 g / m ² in free water absorption at 20 ° C. for 20 minutes, (3) a limiting oxygen index of 28 to 33 provided adjacent to the first intermediate layer. 100% in free water absorption at 20 ℃ for 20 minutes.
It has a water absorption of 700g or less per g / m ² and a basis weight of 70
-200 g / m ² of the second intermediate layer, and (4) the second intermediate layer, which is provided adjacent to the second intermediate layer and is made of a flameproof fabric having a limiting oxygen index of 28 to 33. Lining layer with a rubber layer on the side of. 2. A fire fighting suit or disaster prevention suit formed by the composite fiber structure according to claim 1.