JP5339690B2 - Absorber - Google Patents

Description

  The present invention has a very thin fabric or paper, is excellent in transparency, liquid absorbency, and flexibility, and is close to the skin color even when worn on wounded skin, and has a resistance to wearing. Less on absorbent material.

  Conventionally, absorbent materials have been provided by various companies in order to keep minor wounds and bleeding sites clean and promote recovery. These are widely used because they are inexpensive and easily available. General wound dressing materials are provided with adhesive films made of urethane film and viscose rayon short fiber nonwoven fabric or absorbent cotton, and also a laminate of hyaluronic acid sponge and hydrophobic nonwoven fabric. Has been. These wound dressings have the effect of promoting the recovery of the affected area by protecting the affected area from the invasion of fungi and preventing the ingress of moisture, but there are some problems in actual use. There is also a point. One of the problems is that due to the high volume of the absorbent material, the adhesive area of the covering material on the absorbent material side part is narrow, and dirt and dirt adhere to it and the cleanliness cannot be maintained. Furthermore, for the same reason, there was a problem that fungi easily invade (see Patent Document 1).

The function of the absorbent is to keep the affected area clean by absorbing blood, body fluids, etc., or to promote recovery by carrying a drug or the like and contacting the affected area. In the case of cotton gauze, which has been often used as an absorbent material from the past, because of its poor liquid absorbency, blood and body fluids cannot be sufficiently absorbed, and drugs etc. cannot be sufficiently loaded, resulting in the absorbent material. There was also a problem that many sheets had to be exchanged (see Patent Document 2).
Furthermore, since the absorbent material is made of cotton gauze, the bulk is high and the transparency is low. Therefore, it is difficult to confirm the state of the affected part, and as a result, it is only necessary to confirm the covering material while exchanging it. In addition, due to the low transparency, the pasted part was conspicuous, and it was difficult to stick to the conspicuous part such as the face.

JP 2001-017527 A JP 2005-192864 A

  The object of the present invention is to use a thin fabric or paper that is excellent in transparency and liquid absorption, and is excellent in liquid absorption and safety. To provide materials.

The present invention improves the above-described prior art, and is excellent in transparency and liquid absorption by using a fabric or paper made of cellulose fibers, and adjusting the transparency when thin and dry and wet to a specific range. The present invention has been completed by discovering that it can be an absorbent material having good performance and wearability.
That is, the present invention is as follows.
(1) An absorbent material composed of a nonwoven fabric using regenerated cellulose long fibers, for absorbing body fluid or blood, wherein the nonwoven fabric has a thickness of 0.01 to 0.13 mm, and the nonwoven fabric has a basis weight of 10 to 10. Absorbent for absorbing body fluid or blood, characterized by 50 g / m ² , transparency of 60% or more when dry and 80% or more when wet.
However, creped absorbent material is excluded.
(2) The absorbent for absorbing body fluid or blood according to (1) above, wherein the nonwoven fabric has a content of regenerated cellulose long fibers of 70 to 100% by weight.
(3) The absorbent for absorbing body fluid or blood according to any one of (1) or (2) above, wherein the nonwoven fabric has a water absorption ratio of 7 to 14 times.
(4) The body fluid according to (3) above, wherein the nonwoven fabric is a hydroentangled nonwoven fabric, the hydroentangled pressure is 0 to 10 kgf / cm ² , and the surface is smooth. Absorbent for absorbing blood.

  The absorbent material of the present invention is composed of cellulose fibers and is excellent in liquid absorbency and safety by using a fabric or paper which is thin, transparent and excellent in liquid absorbency. It is an absorbent material with good transparency at the time, close to skin color due to its transparency, and less resistance to wearing.

The absorbent material of the present invention is a fabric using cellulose fibers, having a thickness of 0.01 to 0.25 mm, transparency of 60% or more when dried, and 75% or more when wet. It is an absorbent material composed of the fabric or paper used.
The fabric made of cellulose fiber in the present invention refers to a nonwoven fabric, a woven fabric, a knitted fabric, a net and the like, and is preferably a nonwoven fabric from the viewpoint of strength, flexibility, and processability.
The type of paper is not particularly limited, but various types of thin paper such as rayon thin paper and oil removing paper can be suitably used. Further, as the cellulose fiber constituting the fabric, fibers such as copper ammonia rayon, viscose rayon, cotton, pulp, polynosic, tencel (lyocell) and the like are used, and preferably regenerated cellulose fibers. The regenerated cellulose fiber may be either a continuous long fiber or a short fiber, but the continuous long fiber is preferable because it has better lint-free properties and better liquid absorption than those of short fibers.

As the fabric of the present invention, a nonwoven fabric composed of regenerated cellulose long fibers is particularly preferable. The nonwoven fabric material suitably used in the present invention is composed of continuous filaments of copper ammonia rayon, and the water flow pressure is 0 (no drilling treatment is applied to a material in which a large number of continuous filaments having a single yarn diameter of around 2.2 dtex are entangled. ) To 10 kgf / cm ² , and column flow treatment. In addition to the high transparency of copper ammonia rayon, an absorbent material with excellent surface smoothness and transparency can be obtained by performing no water flow entanglement treatment or slight treatment.
The cellulose fiber used in the present invention preferably has a single yarn thickness in the range of 1.1 to 3.3 dtex. Moreover, in the cellulose fiber and fabric which provided the binder and surfactant, it is preferable to use the fabric of a no binder, since there exists a concern about the fall of water absorption or an elution of a component.

  The fibers constituting the fabric may contain fibers other than cellulose fibers, for example, synthetic fibers such as polyester fibers, polypropylene fibers, and nylon fibers, as long as the object of the present invention is not impaired. The synthetic fiber may be continuous long fiber or short fiber. The composite form of the synthetic fiber and the cellulose fiber may be laminated in the form of a nonwoven fabric, or may be a sliver composite, or a woven or knitted composite. Moreover, in the case of a short fiber nonwoven fabric, it can also mix at the time of papermaking. A composite of a synthetic fiber and a cellulose fiber is preferable from the viewpoint of improving dimensional stability when wetted with a body fluid or a chemical solution. In the fabric or paper of the present invention, the cellulose fiber content is preferably 70 to 100% by weight, the synthetic fiber mixing ratio is 0 to 30% by weight, preferably 0 to 20% by weight, and more preferably 0 to 0% by weight. It is in the range of 10% by weight. If the content of the synthetic fiber exceeds 30% by weight, the water absorption and transparency are remarkably lowered, which is not preferable for the use of the present invention.

Furthermore, in order to further improve the transparency and water absorption of the fabric or paper made of the cellulose fiber of the present invention, it is also useful to substitute the hydroxyl group of the cellulose fiber with various functional groups for derivatization. The main derivatization is carboxymethylation (CM conversion). For example, CM-modified cellulose fibers can be obtained by the method described in JP-A No. 2001-170104. In order to obtain dimensional stability when wet, a conventionally known crosslinking agent can also be used.
As a useful means for improving the bulk density and transparency of the fabric, for example, in the continuous cellulose long fiber nonwoven fabric described in Japanese Patent Publication No. 52-6181, the hydroentangling pressure is preferably in the range of 0 to 10 kgf / cm ² , It can be achieved by performing no water flow entanglement or by performing a light water treatment of about 10 kgf / cm ² or less.

This is because many continuous filaments having a single yarn fineness of about 2.2 dtex form self-adhesion while coagulating in the spinning bath, so that entanglement by a high-pressure water flow is not required unlike a short fiber nonwoven fabric. Therefore, it has sufficient strength as a non-woven fabric without any hydroentanglement treatment. This makes it possible to obtain a cellulose nonwoven fabric that is extremely excellent in bulk density and transparency without any hydroentanglement treatment. Moreover, in order to improve the softness | flexibility and workability of this cellulose nonwoven fabric, a mild water flow process of about 10 kgf / cm < ² > or less can also be performed, and there is almost no fall of the bulk density and transparency by this.
The relationship between water flow pressure and transparency is illustrated based on examples. As shown in FIG. 1 and FIG. 2, the transparency during drying and wetting increases drastically when the water flow pressure is 10 kg / cm ² or less. I know that

With respect to this phenomenon, the mechanism of the expression of transparency will be described below using a copper ammonia rayon nonwoven fabric (manufactured by Asahi Kasei Fibers Co., Ltd., Benrize (trade name)) as an example.
Non-woven fabrics that are not entangled with water flow entanglement, i.e. columnar flow, sprinkling flow, are often bonded together by self-adhesion of single yarns mainly consisting of hydrogen bonds at the spinning stage. By doing so, an absorber with high bulk density and high transparency can be obtained.
Conventionally, by performing columnar flow and sprinkling flow treatment, this self-adhesion was destroyed and a nonwoven fabric excellent in bulkiness and flexibility was obtained, but air intrusion between fibers and in fibers and increased irregular reflection Therefore, since the transparency is lowered, it cannot be suitably used for the application of the present invention. It is useful to perform the low-pressure columnar flow treatment in order to improve the processability of the nonwoven fabric that is not subjected to the columnar flow treatment, wrinkles due to changes in humidity, and the like. For example, if the basis weight is 28 g / m ² , if the columnar flow treatment is performed at 10 kg / cm ² or less, there is no significant decrease in transparency. This is because the adhesive density of the self-adhered fibers is only slightly loosened, so that changes in bulk density and refractive index are slight. In this case, it is preferable to use as fine a mesh as possible for the lower conveyor net.

The regenerated cellulose continuous long fiber made of copper ammonia rayon has a perfect circular cross section and is not deformed like viscose rayon or pulp. Further, it is hydrophilic, has a fine structure in terms of the fiber structure, is easily penetrated by water, and exhibits a refractive index close to that of water, so that it is very excellent in transparency upon water absorption. Even from the viewpoint of the very large number of hydroxyl groups that exhibit water absorption, it is suitable for the use of the present invention.
In the fabric or paper of the present invention, the transparency needs to be 60% or more when dry, 75% or more when wet, more preferably 62% or more when dry, and 80% or more when wet.
In particular, high transparency when wet is preferable because even when a body fluid or the like is absorbed and impregnated in an absorbent material, the transparency is high and a skin-like state can be obtained even when wet.

The fabric or paper using the cellulose fiber of the present invention needs to have a thickness of 0.01 to 0.25 mm, more preferably 0.01 to 0.21 mm.
The bulk density of the fabric or paper with a cellulose fiber of the present invention, 0.2 g / cm ³ or more, more preferably in the range of 0.2 to 0.3 g / cm ^3.
The fabric weight of the fabric and paper of the present invention is preferably 10 to 100 g / m ² , more preferably 15 to 50 g / m ² .
The water absorption ratio of the fabric and paper of the present invention is preferably 7 to 14 times, and more preferably 10 to 13 times. Further, the water absorption amount per unit volume of the fabric and paper is preferably 2 to ⁵ cc / cm ³ , more preferably 2.2 to 4 cc / cm ³ .

Since a fabric made of a continuous long-fiber non-woven fabric tends to be more transparent, there is an advantage that a fabric having a higher basis weight and transparency can be used as compared with a short-fiber fabric. Among the fabrics, the nonwoven fabric is most preferable from the viewpoint of liquid absorbency, bulk density, impurities, and the cellulose continuous long fiber nonwoven fabric is particularly excellent in liquid absorption speed and magnification, and has few impurities. Most preferred for use. Among cellulose, a cupra material is an old medical device material specified by the Pharmaceutical Affairs Law, and is therefore suitably used for the application of the present invention. In order to improve the transparency and bulk density of these fabrics, it is also effective to perform high-pressure press treatment such as calendering.
In the present invention, the cellulose fiber is used as an absorbent body and used in combination with an adhesive film or a tape substrate. The adhesive film material is a urethane film, and the tape substrate is a short fiber nonwoven fabric including viscose rayon. However, these adhesive substrates and tape substrates are not particularly limited to these.

The present invention will be described in more detail with reference to the following examples, but the present invention is not limited to these examples.
The measurement method in the present invention will be described below.
(1) The bulk density (g / cm ³ ) was calculated from (weight per unit area) / (thickness).
(2) Transparency when wet The sample used for the measurement of the water absorption ratio of (3) below was sandwiched between glass plates and measured according to JIS-P-8149.
(3) Liquid absorption ratio It measured as follows.
That is, a 10 cm × 10 cm sample is cut from a fabric under standard conditions, and the weight is accurately measured. The sample is placed on a mesh (10 mesh, wire diameter 0.5 mm), and this is placed in water or an aqueous solution in a vat and immersed for 30 seconds. Thereafter, the mesh is pulled up and allowed to stand for 10 minutes, and then excess water and an aqueous solution are wiped off with a filter paper or the like, the weight of the sample is measured, and the water absorption (liquid) magnification is calculated by the following formula.
Absorption capacity (times) =
[(Weight of sample after liquid absorption)-(Weight of sample g)] / (Weight of sample g)
The amount of water absorption (liquid) per unit volume is calculated by the following equation.
Liquid absorption per unit volume = (bulk density) x (liquid absorption magnification)

(4) Thickness (mm)
It measured using the peacock thickness measuring device.
(5) Transparency Transparency was measured according to JIS-P-8149 “Opacity Test Method (Paper Backing) —Diffusion Lighting Method” and calculated by the following equation.
O _p = 100 × R ₀ / R∞
O _p : Opacity (%)
R ₀ : single sheet luminous reflectance (%)
R∞: intrinsic luminous reflectance (%)
Transparency (%) = 100-opacity Intrinsic luminous reflectance is a reflectance measured by stacking 10 or more test pieces so that all the tables face upward, and the number is doubled. Also, the number of reflections was not changed.

(6) Appropriate evaluation as an absorbent material About the wound dressing material which cut the sample into 24 mm x 13 mm, and stuck on the polyurethane adhesive sheet 72 mm (long part) x 19 mm,
i) Transparency when worn (easy to see wounds)
ii) Easiness of dirt on the absorbent side (3mm on each side) (barrier property)
iii) Adhesion (fitness)
From the viewpoint, the evaluation was performed, and the results are shown in Table 2.

The evaluation was performed by 10 panelists according to the following criteria, and the average value.
i) Transparency when worn (I can see the wound well)
5: Very transparent, well confirmed wound healing 4: Clearly clear, some wound confirmed 3: Not easy to say 2: Not very transparent, hard to identify wound 1 : There is no transparency at all and the wound cannot be confirmed.
ii) Easiness of dirt on the side of the absorbent material (barrier is good, does both sides get dirty or have gaps)
5: Very good barrier properties, no gaps on both sides and difficult to get dirty 4: Moderately good barrier properties and little stains 3: I don't feel particularly bad or bad 2: Excellent barrier properties There are some gaps and some dirt is easily attached. 1: Barrier property is bad, gaps are generated immediately, and dirt is also easily attached.
iii) Adhesiveness (whether fit is good)
5: Very good adhesion, combined with transparency, no resistance to long-term wearing 4: Adhesiveness is good, relatively long-term wearing is possible 3: Especially good or bad adhesion I don't feel 2: Adhesiveness is not so good and needs to be replaced in a relatively short period of time 1: Adhesiveness is poor and needs to be applied immediately

[Example 1]
As the nonwoven fabric, a nonwoven fabric made of continuous filaments of copper ammonia rayon was used, the single yarn fineness was 2.2 dtex, and a nonwoven fabric was formed by entanglement of many continuous filaments. If high-pressure hydroentanglement is performed, the flexibility and bulkiness are improved, but the transparency is greatly reduced and is not preferable for this application. Therefore, the hydroentanglement is 4 kgf in order to improve the bulk density and transparency. / Cm ² . The basis weight of the cellulose long fiber nonwoven fabric was 13.5 g / m ² and the thickness was 0.06 mm. The water absorption magnification was 12.4 times. The bulk density was 0.23 g / cm ³ . Table 1 shows the characteristics as a nonwoven fabric, and Table 2 shows the evaluation as an absorbent material.

[Example 2]
The condition of Example 1 was the same as that of Example 1 except that hydroentanglement was performed at 6 kgf / cm ² and the basis weight of the nonwoven fabric was 29.0 g / m ² . The thickness was 0.13 mm. The water absorption magnification was 13.2 times. The bulk density was 0.22 g / cm ³ . Table 1 shows the characteristics as a nonwoven fabric, and Table 2 shows the evaluation as an absorbent material.
[Example 3]
In order to produce a cellulose continuous fiber nonwoven fabric of the same production method as in Example 1 with a fabric basis weight of 13.5 g / m ² without any hydroentanglement, and to further improve smoothness and transparency, as a secondary process Calendar processing was performed at a linear pressure of 50 kgf / cm, a line speed of 40 m / min, and a processing temperature of 100 ° C. The thickness was 0.02 mm. The water absorption magnification was 6.0 times. The bulk density was 0.68 g / cm ³ . Table 1 shows the characteristics as a nonwoven fabric, and Table 2 shows the evaluation as an absorbent material.

[Comparative Example 1]
Next, as a known material used for a general wound dressing as a comparison, a short fiber nonwoven fabric of 70% by weight of viscose rayon and 30% by weight of polyester was used. The basis weight of the nonwoven fabric was 29.7 g / m ² , the thickness was 0.26 mm, and the water absorption was 12.1 times. The bulk density was 0.16 g / cm ³ . Table 1 shows the characteristics as a nonwoven fabric, and Table 2 shows the evaluation as an absorbent material.
[Comparative Example 2]
Similarly, as a known material used for a general wound dressing, five nonwoven fabrics of Comparative Example 1 were laminated and a polyethylene film was laminated as a skin contact surface. The basis weight of the laminated material was 138.0 g / m ² , and the water absorption magnification was 12.1 times. The bulk density was also 0.16 g / cm ³ . Table 1 shows the characteristics as a nonwoven fabric, and Table 2 shows the evaluation as an absorbent material.
From Table 1, it can be seen that the nonwoven fabrics or papers of Examples 1, 2, and 3 exhibit superior transparency and water absorption as compared with Comparative Examples 1 and 2.

  Absorbent material with very thin fabric or paper, excellent transparency, liquid absorbency, and flexibility, close to skin color even when worn on wounded skin, and less resistance to wearing provide.

It is a figure which shows the relationship between the water flow pressure at the time of drying, and transparency. It is a figure which shows the relationship between the water flow pressure at the time of moisture, and transparency.

Claims (4)

An absorbent material for absorbing bodily fluids or blood, which is composed of a nonwoven fabric using regenerated cellulose long fibers, wherein the nonwoven fabric has a thickness of 0.01 to 0.13 mm, and the basis weight of the nonwoven fabric is 10 to 50 g / m ² , an absorbent for absorbing body fluid or blood, wherein the transparency is 60% or more when dry and 80% or more when wet.
However, creped absorbent material is excluded.   The absorbent for absorbing body fluid or blood according to claim 1, wherein the nonwoven fabric has a content of regenerated cellulose long fibers of 70 to 100% by weight. The absorbent for absorbing body fluid or blood according to claim 1, wherein the nonwoven fabric has a water absorption ratio of 7 to 14 times. The said nonwoven fabric is a hydroentangled nonwoven fabric, the pressure of this hydroentanglement is 0-10 kgf / cm < ² >, and the surface is smooth, The body fluid or blood of Claim 3 is absorbed. Absorbent material for.

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