JP2013208406A - Absorber and absorbent article - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an absorber and absorbent article capable of demonstrating an excellent liquid absorbing property and liquid holding property (liquid holding property when pressurized, in particular).SOLUTION: A sanitary napkin 1 comprises a top sheet 2A, a back sheet 2B, and an absorber 4A provided between the top sheet 2A and a back sheet 3A, in which the absorber 4A contains a crosslinked body of an alkyl cellulose derivative and composite particles including a hydrophilic fiber, and the hydrophilic fiber contains a non-wood pulp having a settling time in water of 2-5 seconds therein.

Description

  The present invention relates to an absorbent body and an absorbent article.

  Conventionally, an absorbent body including an absorbent resin (for example, a sodium polyacrylate-based superabsorbent polymer) and fibers, and an absorbent article including the same are known (for example, Patent Document 1).

JP 2007-319170 A

However, the conventional absorbent articles have been required to be improved from the viewpoint of improving the liquid absorbency and liquid retention (particularly liquid retention during pressurization).
Then, an object of this invention is to provide the absorber and absorbent article which can exhibit the outstanding liquid absorption property and liquid retention property (especially liquid retention property at the time of pressurization).

In order to solve the above-mentioned problems, the present invention is an absorber containing composite particles containing a crosslinked product of an alkyl cellulose derivative and a hydrophilic fiber, wherein the hydrophilic fiber has a settling time in water of 2 to 5 seconds. Absorbers comprising non-wood pulp are provided.
The present invention also relates to an absorbent article comprising a liquid-permeable sheet, a liquid-impermeable sheet, and an absorbent body provided between the liquid-permeable sheet and the liquid-impermeable sheet. Provides an absorbent article which is the absorbent body of the present invention.

The absorbent body and absorbent article of the present invention exhibit the following effects during and after liquid absorption.
[When absorbing]
The voids formed by the entanglement of the hydrophilic fibers and the hydrophilic fibers contained in the composite particles (the hydrophilic fibers contained in the same composite particle and the hydrophilic fibers contained in different composite particles) It functions as a liquid drawing route to the crosslinked product of the alkylcellulose derivative contained. In particular, non-wood pulp with a settling time in water of 2 to 5 seconds contained in hydrophilic fibers has a porous structure (hollow structure), and has a large specific surface area and high porosity, so it has excellent liquid absorbency. High function as a liquid drawing-in route. Therefore, the liquid supplied to the absorber is quickly absorbed by the crosslinked product of the alkyl cellulose derivative contained in the composite particle. Thus, the absorbent body and absorbent article of the present invention exhibit excellent liquid absorbency.

[After absorption]
When the crosslinked product of the alkylcellulose derivative contained in the composite particles absorbs the liquid and swells, gel particles are formed. Since these gel particles maintain a certain gel strength due to the thickening effect, they have excellent liquid retention during pressurization. Non-wood pulp with a sedimentation time in water of 2 to 5 seconds contained in the hydrophilic fiber has a porous structure (hollow structure) and has a large void ratio during pressurization (compression). Excellent liquid retention. Therefore, even if the absorbent body is pressurized (for example, pressurized by the weight of the user), the liquid retained in the absorbent body is prevented from returning and oozing out from the liquid-permeable sheet (rewetting). . Thus, the absorbent body and absorbent article of the present invention exhibit excellent liquid retention (particularly liquid retention during pressurization).

  Moreover, since the space | gap formed by the entanglement of hydrophilic fibers exists between composite particles, coalescence of gel particles is prevented. Accordingly, the gel particles do not serve as a barrier (gel blocking) when the liquid supplied to the liquid permeable sheet penetrates the absorber. Thereby, the phenomenon (overflow phenomenon) that the liquid supplied to the liquid-permeable sheet overflows without penetrating the absorber is prevented.

  Furthermore, the absorbent body and absorbent article of the present invention can maintain strength by entanglement between hydrophilic fibers, and can be reduced in weight by voids formed by entanglement between hydrophilic fibers.

  ADVANTAGE OF THE INVENTION According to this invention, the absorber and absorbent article which can exhibit the outstanding liquid absorptivity and liquid retention (especially liquid retention at the time of pressurization) are provided.

FIG. 1 is a plan view of a sanitary napkin according to a first embodiment of the present invention. FIG. 2 is a cross-sectional view of the sanitary napkin according to the first embodiment of the present invention (A-A cross-sectional view of FIG. 1). FIG. 3 is a perspective view of the disposable diaper according to the second embodiment of the present invention before use (deployed state). 4 is a cross-sectional view of the disposable diaper shown in FIG. FIG. 5 is a perspective view when the disposable diaper shown in FIG. 3 is used. FIG. 6 is a view for explaining a cross-sectional structure of a Manila hemp leaf sheath. FIG. 7 is a view for explaining a nylon mesh bag used for measuring the liquid absorption amount. FIG. 8 is a scanning electron micrograph of the cross-section of the ground pulp fibers. FIG. 9 shows an electron scanning micrograph of composite particles in which a self-crosslinked carboxymethyl cellulose is coated with pulp fibers. FIG. 10 shows an electron scanning micrograph of a self-crosslinked product of carboxymethylcellulose.

Hereinafter, the absorbent body and absorbent article of the present invention will be described.
In a preferred embodiment (embodiment 1) of the absorbent body and absorbent article of the present invention, the crosslinked product of the alkyl cellulose derivative is a dried product of cellulose hydrogel obtained by irradiating a mixture containing the alkyl cellulose derivative and water. . In the aspect 1, the liquid absorptivity and liquid retention (particularly liquid retention during pressurization) of the crosslinked product of the alkyl cellulose derivative are improved.

  In a preferred embodiment (embodiment 2) of the absorbent body and absorbent article of the present invention, in the composite particles, the hydrophilic fiber reaches from the outside to the inside of the crosslinked body of the alkyl cellulose derivative. In the aspect 2, the function of the hydrophilic fiber contained in the composite particle as a liquid drawing route is improved.

  In the preferable aspect (Aspect 3) of the absorbent body and absorbent article of the present invention, the mass ratio of the non-wood pulp and the crosslinked body of the alkyl cellulose derivative is 1: 1 to 3: 1. In the aspect 3, when the liquid to be absorbed is urine, particularly excellent liquid absorption and liquid retention (particularly liquid retention during pressurization) are exhibited.

  In the preferable aspect (Aspect 4) of the absorbent body and absorbent article of the present invention, the mass ratio of the non-wood pulp and the crosslinked body of the alkyl cellulose derivative is 2: 1 to 3: 1. In Aspect 4, when the liquid to be absorbed is blood (for example, menstrual blood), particularly excellent liquid absorption and liquid retention (particularly liquid retention during pressurization) are exhibited.

In a preferred embodiment (embodiment 5) of the absorbent body and absorbent article of the present invention, the apparent bulk density of the non-wood pulp is 0.04 to 0.07 g / cm ³ . Non-wood pulp having an apparent bulk density of 0.04 to 0.07 g / cm ³ has a porous structure (hollow structure), and has a large specific surface area and high porosity, so that it has excellent liquid absorbency and is liquid. High function as a pull-in route. Moreover, since the porosity at the time of pressurization (at the time of compression) is large, it has excellent liquid retention during pressurization.

  In a preferred embodiment (embodiment 6) of the absorbent body and absorbent article of the present invention, the liquid absorption amount of non-wood pulp is 20 times or more of its own weight. Non-wood pulp having a liquid absorption of 20 or more times its own weight is excellent in liquid absorption.

  In the preferable aspect (Aspect 7) of the absorbent body and absorbent article of the present invention, the average fiber diameter of the non-wood pulp is 8 to 25 μm. The non-wood pulp having an average fiber diameter of 8 to 25 μm has a large number of fibers per unit mass (that is, volume), so that the apparent bulk density is reduced, and the specific surface area and porosity are increased. In addition, the interfiber distance is reduced and the capillary force is increased. Therefore, non-wood pulp having an average fiber diameter of 8 to 25 μm is excellent in liquid absorbency and liquid retention during pressurization. Further, since the entanglement between the fibers increases due to the increase in the number of fibers, the strength of the absorber is maintained even if the absorber is reduced in weight and thickness.

  In a preferred embodiment (embodiment 8) of the absorbent body and absorbent article of the present invention, the lignin content of the non-wood pulp is 0.5% by mass or less. Non-wood pulp with a lignin content of 0.5% by mass or less is excellent in liquid absorbency and liquid retention during pressurization because an increase in fiber diameter and a decrease in hydrophilicity due to lignin are prevented. Yes.

  In a preferred embodiment (embodiment 9) of the absorbent body and absorbent article of the present invention, the non-wood pulp is abaca pulp made from Manila hemp leaf sheath or bamboo pulp made from bamboo. By using Manila hemp leaf sheath or bamboo as a raw material, in addition to the property that the sedimentation time in water is 2 to 5 seconds, non-wood pulp having one or more of the properties of aspects 5 to 8 is simple and efficient. Can get well.

  In a preferred embodiment (embodiment 10) of the absorbent body and absorbent article of the present invention, the abaca pulp is an abaca pulp made from raw material in the vicinity of the core of the Manila hemp leaf sheath or in the middle of the core and the outer skin. In addition to the characteristic that the sedimentation time in water is 2 to 5 seconds by using the vicinity of the core of the leaf sheath of Manila hemp or the intermediate part between the core and the outer skin as a raw material, one or two of the characteristics of aspects 5 to 8 The non-wood pulp which has the above can be acquired simply and efficiently.

  In a preferred embodiment (embodiment 11) of the absorbent body and absorbent article of the present invention, the absorption time when 3 mL of artificial menstrual blood is dropped onto the absorbent body 0.1 g at a dropping speed of 1.5 mL / second is 7 seconds or less. .

In a preferred embodiment (embodiment 12) of the absorbent body and absorbent article of the present invention, after 3 mL of artificial menstrual blood is absorbed by 0.1 g of the absorbent body, the rewet amount for 3 minutes measured under a load of 30 g / cm ^2. Is 1.8 g or less.

  In a preferred embodiment (embodiment 13) of the absorbent body and absorbent article of the present invention, the time from the addition of 2 g of the absorbent body to 30 g of 0.9% sodium chloride aqueous solution until the movement of the liquid surface ceases is 11 seconds or less. .

  In a preferred embodiment (embodiment 14) of the absorbent body and absorbent article of the present invention, the water absorption ratio of the absorbent body to a 0.9% sodium chloride aqueous solution is 16 times or more.

  In a preferred embodiment (embodiment 15) of the absorbent body and absorbent article of the present invention, the water retention ratio of the absorbent body to a 0.9% sodium chloride aqueous solution is 10 times or more.

  In the absorbent body and absorbent article of the present invention, two or more aspects among the aspects 1 to 15 can be combined.

The kind and use of the absorber and absorbent article of the present invention are not particularly limited. Examples of the absorbent article include sanitary products and sanitary products such as sanitary napkins, disposable diapers, panty liners, incontinence pads, sweat removing sheets, etc., and these may be used for humans and other than humans such as pets. Animals may be targeted. The liquid to be absorbed by the absorbent body and absorbent article of the present invention is not particularly limited, and examples thereof include liquid excrement and body fluid of the user.
Hereinafter, embodiments of the absorbent body and absorbent article of the present invention will be described by taking sanitary napkins (first embodiment) and disposable diapers (second embodiment) as examples.

[First Embodiment]
As shown in FIGS. 1 and 2, the sanitary napkin 1A according to the first embodiment includes a liquid-permeable top sheet 2A, a liquid-impermeable back sheet 3A, and the top sheet 2A and the back sheet 3A. 4A is disposed.

  The sanitary napkin 1A is worn by the user for the purpose of absorbing the user's liquid excrement. At this time, the user wears the top sheet 2A on the user's skin side and the back sheet 3A on the user's clothes (underwear) side. The liquid excrement of the user penetrates into the absorbent body 4A through the top sheet 2A and is absorbed by the absorbent body 4A. Examples of liquid excreta to be absorbed include menstrual blood, urine, and fallen products, and are mainly menstrual blood. Leakage of liquid excreta absorbed by the absorber 4A is prevented by the back sheet 3A. The tissue 5 covering the absorbent body 4A is provided for the purpose of preventing the absorbent body 4A from collapsing, but may be omitted.

  The top sheet 2A is a sheet through which the user's liquid excrement can permeate, and is provided on a surface that comes into contact with the user's skin for the purpose of improving the touch when the user wears the sanitary napkin 1A. Yes.

  The top sheet 2A is not particularly limited as long as the user's liquid excrement can permeate. Examples of the top sheet 2A include a nonwoven fabric, a woven fabric, a synthetic resin film in which liquid permeation holes are formed, and a net-like sheet having a mesh. Among these, a nonwoven fabric is preferable.

  Nonwoven fabric is produced, for example, by forming a web (fleece) and physically and chemically bonding fibers. In this case, as a method for forming a web, for example, a spunbond method, a dry method (carding) Method, airlaid method), wet method, and the like, and as the bonding method, for example, a thermal bond method, a chemical bond method, a needle punch method, a stitch bond method, a spunlace method, or the like is used.

The material, thickness, basis weight, density, and the like of the top sheet 2A are appropriately adjusted as long as the user's liquid excrement can permeate. When a nonwoven fabric is used as the top sheet 2A, the fibers constituting the nonwoven fabric include, for example, natural fibers (wool, cotton, etc.), recycled fibers (rayon, acetate, etc.), inorganic fibers (glass fibers, carbon fibers, etc.), and synthetic resins. Fiber (polyethylene, polypropylene, polybutylene, ethylene-vinyl acetate copolymer, ethylene-ethyl acrylate copolymer, ethylene-acrylic acid copolymer, polyolefin such as ionomer resin; polyethylene terephthalate, polybutylene terephthalate, polytrimethylene Polyesters such as terephthalate and polylactic acid; polyamides such as nylon) are used. The fiber constituting the nonwoven fabric may be composed of a single component, or may be composed of a composite fiber such as a core / sheath fiber, a side-by-side fiber, or an island / sea fiber. The fineness of the fibers constituting the nonwoven fabric is preferably 1.0 to 20 dtex, more preferably 1.2 to 4.4 dtex, and the fiber length is preferably 5 to 75 mm, more preferably 25 to 51 mm. The basis weight of the nonwoven fabric is preferably 10 to 100 g / m ² , more preferably 20 to 35 g / m ² , and the fiber density is preferably 0.001 to 0.2 g / cm ³ , more preferably 0.015 to 0.08 g / cm ³ . The thickness of the nonwoven fabric under a load of 3 g / cm ² is preferably 0.1 to 3 mm, and more preferably 0.5 to 2 mm.

  The back sheet 3A is a sheet through which the liquid excrement of the user cannot permeate, and on the surface that comes into contact with the user's clothes (underwear) for the purpose of preventing leakage of the liquid excretion absorbed by the absorber 4A. Is provided. The backsheet 3A preferably has moisture permeability in addition to liquid impermeability in order to reduce stuffiness when worn.

  The backsheet 3A is not particularly limited as long as it cannot permeate the user's liquid excrement. Examples of the backsheet 3A include a waterproof nonwoven fabric, a synthetic resin (eg, polyethylene, polypropylene, polyethylene terephthalate, etc.) film, a composite sheet of a nonwoven fabric and a synthetic resin film, and the like.

  The absorber 4A contains composite particles. The composite particles include a crosslinked product of an alkyl cellulose derivative and hydrophilic fibers, and the hydrophilic fibers include non-wood pulp having a settling time in water of 2 to 5 seconds.

  In the absorbent body 4A, voids formed by entanglement of hydrophilic fibers and hydrophilic fibers contained in the composite particles (hydrophilic fibers contained in the same composite particle and hydrophilic fibers contained in different composite particles). Functions as a liquid drawing route to the crosslinked product of the alkylcellulose derivative contained in the composite particles.

  The form of the composite particle is not particularly limited as long as it includes a crosslinked product of alkyl cellulose derivative and hydrophilic fiber. Examples of the form of the composite particle include a form in which a crosslinked body of an alkyl cellulose derivative forms a core part, and a hydrophilic fiber covers the core part to form the surface of the composite particle, and the hydrophilic fiber is an alkyl cellulose derivative. The form which has reached | attained the inside from the exterior of this crosslinked body is mentioned. When the hydrophilic fiber coats the crosslinked body of the alkyl cellulose derivative to form the surface of the composite particle, the density of voids formed by the entanglement of the hydrophilic fibers increases. When the hydrophilic fibers reach from the outside to the inside of the crosslinked body of the alkyl cellulose derivative, the liquid drawing action from the hydrophilic fibers to the crosslinked body of the alkyl cellulose derivative is improved.

  The particle diameter of the composite particles is difficult to specify because the hydrophilic fibers contained in the composite particles are entangled with each other, but the particle diameter of the composite particles is usually 50 to 2000 μm, preferably 100 to 1500 μm, more preferably 200 to 1000 μm. It is. The composite particles having such a particle size are unlikely to become a barrier (gel blocking) when the liquid excretion that has permeated the top sheet 2A penetrates the absorbent body 4A, and is excellent in liquid absorption performance of the liquid excrement.

  The particle size of the composite particles is a particle size measured by a method of passing through a mesh sieve corresponding to a predetermined particle size.

  The amount of the composite particles contained in the absorbent body 4A can be appropriately adjusted according to the characteristics (for example, absorbency, lightness, etc.) that the sanitary napkin 1A should have, but usually 10 to 100% by mass of the absorbent body 4A, Preferably it is 20-100 mass%, More preferably, it is 30-100 mass%.

  In the composite particles, the mass ratio of the non-wood pulp and the crosslinked product of the alkyl cellulose derivative is not particularly limited, but is preferably 2: 1 to 3: 1 and more preferably 2: 1. When the mass ratio between the two is in such a range, the liquid absorption and liquid retention (particularly liquid retention during pressurization) of the sanitary napkin 1A is improved. In addition, when the mass ratio of the crosslinked body of the alkyl cellulose derivative increases, the liquid absorption amount and the liquid retention amount of the absorbent body 4A increase, while the liquid drawing action from the non-wood pulp to the crosslinked body of the alkyl cellulose derivative decreases. Further, when the mass ratio of the non-wood pulp is increased, the liquid drawing action from the non-wood pulp to the crosslinked body of the alkyl cellulose derivative is increased, while the liquid absorption amount and the liquid retention amount of the absorber 4A are decreased. Therefore, the mass ratio between the non-wood pulp and the crosslinked product of the alkyl cellulose derivative is appropriately set in consideration of these.

  The cross-linked product of the alkyl cellulose derivative contained in the composite particle is not particularly limited as long as it can swell by absorbing the liquid excrement of the user. Examples of the crosslinked product of the alkylcellulose derivative include a self-crosslinked product of an alkylcellulose derivative and a crosslinked product of a crosslinking agent. Among these, a self-crosslinked product of an alkylcellulose derivative is preferable.

  Examples of the self-crosslinked product of the alkyl cellulose derivative include, for example, cellulose hydrogel obtained by irradiating a mixture containing the alkyl cellulose derivative and water, or a dried product thereof. Among these, a dried product of cellulose hydrogel is used. preferable. In addition, when an alkyl cellulose derivative such as carboxymethyl cellulose is irradiated with radiation in the presence of water, a hydroxy radical generated from water is generated, and self-crosslinking is considered to proceed through this radical.

  Examples of the alkyl cellulose derivative include those in which hydrogen of a hydroxyl group of cellulose is substituted with an unsubstituted or substituted alkyl group. The number of carbon atoms of the alkyl group is preferably 1 to 3, and the substituted alkyl group is, for example, a carboxyalkyl group or a hydroxyalkyl group.

  Alkyl cellulose derivatives also include salts. Examples of the salt include alkali metal salts (for example, lithium salts, sodium salts, potassium salts, rubidium salts, cesium salts, etc.), ammonium salts, amine salts, etc. Among them, alkali metal salts (particularly sodium salts). ) Is preferred.

  The average degree of polymerization of the alkylcellulose derivative is usually 10 to 7000, preferably 50 to 6000, more preferably 200 to 4000, and the average degree of etherification (replaces hydrogen of the hydroxyl group of cellulose with an unsubstituted or substituted alkyl group). The degree of substitution) is usually 0.5 or more, preferably 0.8 or more, more preferably 1.0 or more, and a maximum of 3. When the average degree of etherification is in such a range, sufficient crosslinking can be formed.

Preferred alkyl cellulose derivatives are alkyl cellulose, carboxyalkyl cellulose, hydroxyalkyl cellulose or salts thereof. Biodegradable alkyl cellulose derivatives such as carboxymethyl cellulose biodegrade quickly when washed with water or disposed in soil. Therefore, there is no need for incineration at the time of disposal, and CO ₂ emissions can be reduced.

  Alkyl cellulose is one in which hydrogen of cellulose hydroxyl group is partially substituted with methyl group, ethyl group, and propyl group. Preferred alkylcellulose is methylcellulose or ethylcellulose. The alkyl etherification degree of the alkyl cellulose is usually 66% or less, preferably 50% or less, and more preferably 33% or less. The proportion of the alkyl cellulose forming hydroxyl group is usually 40% or more, preferably 50% or more. With such a ratio, it is easy to form a uniform mixture or aqueous solution. The upper limit for the ratio of salt formation is 100%.

  Carboxyalkyl cellulose is obtained by replacing the hydrogen of the hydroxyl group of cellulose with a carboxyalkyl group (for example, carboxymethyl group, carboxyethyl group, carboxypropyl group, etc.). Preferred carboxyalkyl cellulose is carboxymethyl cellulose or carboxyethyl cellulose. The ratio of forming an alkali metal salt, ammonium salt or amine salt in the carboxyl group of carboxyalkyl cellulose is preferably 20% or more, more preferably 40% or more. With such a ratio, it is easy to form a uniform mixture or aqueous solution. The upper limit for the ratio of salt formation is 100%.

Hydroxyalkyl cellulose is obtained by adding, for example, alkylene oxide (for example, ethylene oxide, propylene oxide, etc.) to a hydroxyl group of cellulose. Hydrogen of the hydroxyl group of cellulose is, for example, hydroxyethyl (—C ₂ H ₄ OH) group, hydroxyisopropyl group (—C ₃ H ₆ OH) or hydroxy-n-propyl group (—C ₃ H ₆ OH), or an alkylene oxide (for example, ethylene oxide, propylene oxide, etc.) at the hydroxy end thereof ) 1-10 molecules are substituted with a polyoxyalkylene ether group formed by addition. Preferred hydroxyalkylcelluloses are hydroxyethylcellulose, hydroxypropylcellulose, hydroxypropylmethylcellulose or hydroxyethylmethylcellulose. The ratio of the hydroxyl group of the hydroxyalkyl cellulose forming the alkali metal salt is usually 20% or more, preferably 40% or more, more preferably 50% or more. With such a ratio, it is easy to form a uniform mixture or aqueous solution. The upper limit for the ratio of salt formation is 100%.

  A commercial item may be used as an alkylcellulose derivative, and what was manufactured in accordance with the conventional method may be used.

  The alkyl cellulose can be produced, for example, by a reaction between alkali cellulose and alkyl chloride or dialkyl sulfuric acid. For example, methyl cellulose can be produced by a reaction between alkali cellulose and methyl chloride or dimethyl sulfate, and ethyl cellulose can be produced by a reaction between alkali cellulose and ethyl chloride or diethyl sulfate.

  Carboxyalkyl cellulose can be produced according to a conventional method such as a slurry method (high liquid magnification method) or a kneader method (low liquid magnification method). For example, after reacting cellulose and alkali to produce alkali cellulose, it can be reacted with alkali cellulose and monochloroacetic acid to produce carboxymethyl cellulose. After reacting with alkali cellulose and acrylate ester, Carboxyethyl cellulose can be produced by hydrolysis.

  Hydroxyalkyl cellulose can be produced, for example, by reacting a hydroxyl group of cellulose with an alkylene oxide. For example, hydroxyethyl cellulose can be produced by reacting ethylene oxide and hydroxypropyl cellulose by reacting propylene oxide with a hydroxyl group of cellulose, respectively. These may be further reacted with an alkylene oxide. For example, ethyl hydroxyethyl cellulose can be produced by further reacting hydroxyethyl cellulose with ethylene oxide.

  A cellulose hydrogel that is a self-crosslinked product of an alkyl cellulose derivative can be produced, for example, by irradiating a mixture containing the alkyl cellulose derivative and water with radiation.

  Examples of water to be mixed with the alkyl cellulose derivative include city water, industrial water, deaerated water, deionized water, gel filtered water, distilled water, and the like, but water that does not contain oxygen, ions, or the like is preferable.

  The ratio of the alkyl cellulose derivative in the mixture of the alkyl cellulose derivative and water is preferably 10 to 80% by weight. If the proportion of the alkylcellulose derivative is less than 10% by weight, there is a possibility that the crosslinking is not sufficient. If the proportion of the alkylcellulose derivative is more than 80% by weight, the decomposition of the alkylcellulose derivative may be increased.

  The mixed state of the alkyl cellulose derivative and water may be a state in which the alkyl cellulose derivative contains water, a paste-like paste, or an aqueous solution, but is preferably as uniform as possible.

  Examples of the radiation applied to the mixture containing the alkyl cellulose derivative and water include α rays, β rays, γ rays, X rays, electron rays, ultraviolet rays, etc. Among them, γ rays, electron rays or X rays are mentioned. Is preferred. The irradiation dose of radiation is usually 0.1 to 50 kGy, preferably 0.3 to 20 kGy, more preferably 0.5 to 10 kGy in terms of γ-ray. If the dose of radiation is less than 0.1 kGy, there is a possibility that crosslinking is not sufficient, and if it exceeds 50 kGy, crosslinking may proceed too much.

  Irradiation is preferably performed in the absence of oxygen. When irradiation is performed in the absence of oxygen, crosslinking efficiency is improved (that is, crosslinking is possible at a low radiation dose), whereas when performed in the presence of oxygen, the alkylcellulose derivative is oxidatively decomposed. The ratio increases.

  A cellulose hydrogel obtained by irradiating a mixture containing an alkylcellulose derivative and water with radiation is a gel in which water is taken into the self-crosslinked body (three-dimensional network structure) of the alkylcellulose derivative. The gel fraction of cellulose hydrogel is usually 1 to 70%, preferably 3 to 50%, more preferably 5 to 40%. When the gel fraction of the cellulose hydrogel is less than 1%, the crosslinking is insufficient. On the other hand, when it exceeds 70%, the crosslinking proceeds too much, and the liquid absorbency is insufficient.

The gel fraction is a ratio of insoluble matter when the product is immersed in a large amount (for example, 10 to 100 times the product) of distilled water for 48 hours and then filtered through a 20 mesh stainless steel wire mesh. It is calculated by.
Gel fraction (%) = (W ₂ / W ₁ ) × 100 (W ₁ represents the dry weight of the alkyl cellulose derivative used, and W ₂ represents the dry weight of the insoluble matter after filtration of the crosslinked product. Represents.)

  A dried product of cellulose hydrogel can be produced by drying the cellulose hydrogel using an appropriate apparatus such as a dryer (a constant temperature dryer or the like). Drying can be performed in the air, in an oxygen atmosphere, in an inert atmosphere (eg, helium, argon, nitrogen, etc.), and the like. Drying can be performed under atmospheric pressure, reduced pressure, increased pressure, or the like. Drying may be natural drying. A drying temperature is 20-100 degreeC normally, Preferably it is 30-80 degreeC, and drying time can be suitably adjusted according to a drying temperature. When the drying temperature is in such a range, the cellulose hydrogel can be dried without causing deterioration due to thermal decomposition.

  The composite particle containing cellulose hydrogel or dried product thereof and hydrophilic fiber is prepared by, for example, preparing a mixture containing cellulose hydrogel and hydrophilic fiber while or after cutting cellulose hydrogel, and drying the mixture. Can be manufactured.

  When mixing the cellulose hydrogel and the hydrophilic fiber, it is preferable to mix the cellulose hydrogel and the hydrophilic fiber while cutting the cellulose hydrogel. As a result, the hydrophilic fibers reach the inside from the outside of the cellulose hydrogel particles and coat the cellulose hydrogel particles. As an apparatus for performing such mixing, for example, a pulverizer that includes a pulverization cutter and performs pulverization by rotating the pulverization cutter may be used. Examples of such a pulverizer include Wonder crush / mil D3V-10 manufactured by Osaka Chemical Co., Ltd. and Grindmix GM200 manufactured by Lecce Co., Ltd.

  When mixing the cellulose hydrogel and the hydrophilic fiber, the mass ratio of the non-wood pulp and the cellulose hydrogel is preferably 2: 1 to 3: 1 (1 to 1 to 3 in the second embodiment described later). 1), more preferably 2: 1.

  The particle size of the gel particles formed by cutting the cellulose hydrogel is usually 50 to 2000 μm, preferably 100 to 1500 μm, and more preferably 200 to 1000 μm. The composite particles produced using gel particles having such a particle size or a dried product thereof are less likely to be a barrier (gel blocking) when liquid excretion that has permeated through the top sheet 2A penetrates the absorbent body 4A. Excellent liquid absorption performance for liquid excreta.

  The non-wood pulp contained in the composite particles as hydrophilic fibers has a settling time in water of 2 to 5 seconds, preferably 2.5 to 4 seconds. When the non-wood pulp has a porous structure (hollow structure), the water sedimentation time becomes longer due to the air in the porous structure (that is, the water sedimentation speed becomes slower), so the water sedimentation time is 2-5. The non-wood pulp, which is a second, has a porous structure (hollow structure), has a large specific surface area and a high porosity, and a high porosity when pressed (compressed). For this reason, the non-wood pulp whose sedimentation time in water is 2 to 5 seconds is excellent in liquid absorbency, has a high function as a liquid drawing path, and is excellent in liquid retention during pressurization.

  The non-wood pulp settling time in water is the time from when the non-wood pulp comes into contact with the water surface until the non-wood pulp settles below the water surface, and specifically, the time measured as follows. 5.0 g of non-wood pulp is uniformly packed in a cylindrical basket (weight 3 g, diameter 50 mm, depth 80 mm). In addition, the cage | basket is formed with the copper wire (diameter 0.4mm), and a copper wire space | interval is 20 mm. Ion exchange water is put into a 2 L beaker until the water depth reaches 200 mm. Place the basket filled with non-wood pulp on the side and drop it from a height of 10 mm with respect to the water surface of the 2L beaker. Measure the time (seconds) from when the basket touches the water surface until it sinks below the water surface. Time (seconds).

In addition to the property that the sedimentation time in water is 2 to 5 seconds, the non-wood pulp preferably has one or more of the following properties.
-The apparent bulk density of non-wood pulp is 0.04-0.07 g / cm < ³ >.
-The liquid absorption of non-wood pulp is more than 20 times its own weight.
-The average fiber diameter of non-wood pulp is 8-25 micrometers (preferably 10-20 micrometers).
-The lignin content of non-wood pulp is 0.5 mass% or less (preferably 0.3 mass% or less).

Non-wood pulp with an apparent bulk density of 0.04 to 0.07 g / cm ³ has a large specific surface area and porosity, so it has excellent liquid absorbency and has a high function as a liquid drawing route, and is pressurized. Since the porosity at the time (during compression) is large, it has excellent liquid retention during pressurization. When the apparent bulk density of the non-wood pulp is smaller than 0.04 g / cm ³ , the strength and shape retention of the absorbent body 4A may be insufficient, and the apparent bulk density of the non-wood pulp is 0.07 g / cm 2. If it is larger than cm ^3, the liquid absorption amount of the absorber 4A may be insufficient.

The apparent bulk density of non-wood pulp is calculated as follows. 10 g of non-wood pulp is laminated to 100 mm × 100 mm, a 100 mm × 100 mm plate is placed thereon, and a weight of 100 g load is placed on the plate. The apparent bulk density (g / cm ³ ) is calculated by setting the thickness of the laminated pulp 10 seconds after the weight is placed as the apparent bulk (cm ³ ).

  Non-wood pulp having a liquid absorption amount of 20 times or more of its own weight is excellent in liquid absorption and has a high function as a liquid drawing route. If the liquid absorption amount of the non-wood pulp is smaller than 20 times its own weight, the effect of the non-wood pulp becomes small because the liquid absorption of other hydrophilic fibers (for example, wood pulp) is not so different. In measuring the liquid absorption amount, for example, a 0.9% sodium chloride aqueous solution is used as the liquid.

  The non-wood pulp having an average fiber diameter of 8 to 25 μm has a large number of fibers per unit mass (that is, volume), so that the apparent bulk density is reduced, and the specific surface area and porosity are increased. In addition, the interfiber distance is reduced and the capillary force is increased. Therefore, non-wood pulp having an average fiber diameter of 8 to 25 μm is excellent in liquid absorbency, has a high function as a liquid drawing path, and is excellent in liquid retention during pressurization. Further, since the entanglement between the fibers increases due to the increase in the number of fibers, the strength of the absorber 4A is maintained even if the absorber 4A is reduced in weight and thickness.

  Non-wood pulp with a lignin content of 0.5% by mass or less is excellent in liquid absorbency and liquid retention during pressurization because an increase in fiber diameter and a decrease in hydrophilicity due to lignin are prevented. Yes.

  Common raw materials for non-wood pulp include, for example, linter, manila hemp, kenaf, esparto grass, straw, bamboo, banana, etc. In order to easily and efficiently obtain non-wood pulp having the above characteristics It is preferable to use Manila hemp leaf sheath or bamboo. When the leaf sheath of Manila hemp is used as a raw material, it is preferable to use the vicinity of the core of the leaf sheath or an intermediate portion between the core and the outer skin.

  The Manila hemp leaf sheath will be described with reference to FIG. As shown in FIG. 6, the cross-sectional structure of the Manila hemp leaf sheath 40 is classified into a core 41, a first layer 42, a second layer 43, a third layer 44, and an outermost layer 45. The vicinity of the core of the Manila hemp leaf sheath corresponds to a portion (first layer 42 and second layer 43) close to the core of the Manila hemp leaf sheath 40, and the intermediate portion between the core of the Manila hemp sheath and the outer skin is the leaf sheath 40 of Manila hemp. Corresponds to a portion (third layer 44) close to the outermost layer 45.

  Abaca fibers made from Manila hemp are classified into classes such as AD, EF, S2, and S3 based on the parts that make manila hemp. AD is an abaca fiber using the first layer 42 of the Manila hemp 40 as a raw material, and is a glossy pure white fiber. EF is an abaca fiber made from the second layer 43 of the Manila hemp 40 as a raw material, a fiber in the middle part of the soft pure fiber, and has a light ivory color. S2 is an abaca fiber made from the third layer 44 of the Manila hemp 40 as a raw material, and is light ocher or light purple. S3 is an abaca fiber made from the outermost layer 45 of the Manila hemp 40 as a raw material, and is dark red or purple, and is mainly used for ropes.

  Abaca fibers made from Manila hemp are classified into classes such as I, G, and H based on the parts that make Manila hemp. I is an abaca fiber made from the second layer 43 of the Manila hemp 40 as a raw material, and is light yellow. G is an abaca fiber made from the third layer 44 of the Manila hemp 40 as a raw material, is dull dark white, and is likely to be bound. H is an abaca fiber made from the outermost layer 45 of the Manila hemp 40 as a raw material, is brownish brown close to black, and is mainly used for ropes.

  Abaca fibers made from Manila hemp are classified into classes such as JK and M1 based on the parts that make Manila hemp. JK is an abaca fiber made from the third layer 44 of Manila hemp 40, and is light brown or light green and is mainly used as pulp. M1 is an abaca fiber made from the outermost layer 45 of the Manila hemp 40, and is a dark brown to black fiber, and is mainly used for ropes.

  Abaca fiber made from the vicinity of the core of Manila hemp leaf sheath corresponds to the abaca fiber of AD, EF or I, and the abaca fiber made from the middle part of the core and outer skin of Manila hemp sheath is S2, G or Corresponds to JK Abaca Fiber. Moreover, the abaca fiber made from manila hemp skin corresponds to the abaca fiber of S3, H or M1.

  The hydrophilic fibers contained in the composite particles may be composed only of non-wood pulp having a subsidence time in water of 2 to 5 seconds, or may contain other hydrophilic fibers. The content of non-wood pulp having a settling time in water of 2 to 5 seconds with respect to the entire hydrophilic fiber is usually 25 to 100% by mass, preferably 33 to 100% by mass, and more preferably 50 to 100% by mass.

  The hydrophilic fiber is not particularly limited as long as it has a hydrophilic group (for example, hydroxyl group, amino group, carboxyl group, amide group, etc.). Examples of hydrophilic fibers include wood pulp obtained from softwood or hardwood (for example, mechanical pulp such as groundwood pulp, refiner ground pulp, thermomechanical pulp, chemithermomechanical pulp; craft pulp, sulfide pulp, alkaline pulp, etc. Chemical pulp; semi-chemical pulp, etc.]; mercerized pulp or crosslinked pulp obtained by chemically treating wood pulp; regenerated cellulose such as rayon and fibril rayon; semi-synthetic cellulose such as acetate and triacetate; synthetic resin fiber (for example, Acrylic fiber, hydrophilized synthetic resin fiber, etc.).

  The absorber 4A preferably contains another absorbent material in addition to the composite particles. Since the liquid retention of the porous structure of non-wood pulp is weak, the liquid quickly transfers from the non-wood pulp to other absorbent materials. Therefore, the absorber 4A exhibits excellent liquid absorbency even for liquids repeatedly supplied by containing other absorbent materials.

  The mass ratio of the composite particles and the absorbent material contained in the absorber 4A is not particularly limited, but is preferably 4: 1 to 1: 4, more preferably 3: 1 to 1: 3.

  The absorbent material is not particularly limited as long as it can absorb the liquid excrement of the user. Examples of the absorbent material include a water-absorbing fiber and a highly water-absorbing material (for example, a highly water-absorbing resin and a highly water-absorbing fiber).

  Examples of water-absorbing fibers include wood pulp obtained from softwood or hardwood (for example, mechanical pulp such as groundwood pulp, refiner ground pulp, thermomechanical pulp, chemithermomechanical pulp; kraft pulp, sulfide pulp, alkaline pulp, etc. Chemical pulp; semi-chemical pulp, etc.]; mercerized pulp or crosslinked pulp obtained by subjecting wood pulp to chemical treatment; non-wood pulp such as bagasse, kenaf, bamboo, hemp, cotton (for example, cotton linter); rayon, fibril Examples include regenerated cellulose such as rayon; semi-synthetic cellulose such as acetate and triacetate, but pulverized pulp is preferred because it is low in cost and easy to mold.

  Examples of the superabsorbent material include starch-based, cellulose-based, and synthetic polymer-based superabsorbent materials. Examples of starch-based or cellulose-based superabsorbent materials include starch-acrylic acid (salt) graft copolymers, saponified starch-acrylonitrile copolymers, and crosslinked products of sodium carboxymethyl cellulose, and synthetic polymers. Examples of high water-absorbing materials include polyacrylates, polysulfonates, maleic anhydrides, polyacrylamides, polyvinyl alcohols, polyethylene oxides, polyaspartates, polyglutamates , Polyalginate-based, starch-based, and cellulose-based superabsorbent polymers (SAP), and the like. Among these, polyacrylate-based (particularly, sodium polyacrylate-based) superabsorbent Resins are preferred. Examples of the shape of the superabsorbent material include a particulate shape, a fibrous shape, and a scaly shape. In the case of the particulate shape, the particle size is preferably 50 to 1000 μm, more preferably 100 to 600 μm. .

  Absorbency 4A may contain an antiblocking agent, an ultraviolet absorber, a thickening and branching agent, a matting agent, a colorant, and other various improving agents.

The thickness, basis weight, density, and the like of the absorbent body 4A can be appropriately adjusted according to the characteristics (for example, absorbency, lightness, etc.) that the sanitary napkin 1A should have, but the thickness is usually 1 to 10 mm, preferably 2 to 2 mm. 8 mm, more preferably 3 to 7 mm, and the basis weight is usually 20 to 1000 g / m ² , preferably 50 to 800 g / m ² , more preferably 100 to 600 g / m ² , and the density is usually 0.002 ˜1 g / cm ³ , preferably 0.01 to 0.4 g / cm ³ , more preferably 0.02 to 0.2 g / cm ³ .

  The sanitary napkin 1A exhibits the following action during and after absorption of the user's liquid excreta.

[When absorbing]
The liquid excrement that has permeated the top sheet 2A penetrates into the absorber 4A. At this time, the voids formed by the entanglement of the hydrophilic fibers and the hydrophilic fibers contained in the composite particles (the hydrophilic fibers contained in the same composite particle and the hydrophilic fibers contained in different composite particles), It functions as a liquid drawing route to the crosslinked product of the alkyl cellulose derivative contained in the composite particles. In particular, non-wood pulp with a settling time in water of 2 to 5 seconds contained in hydrophilic fibers has a porous structure (hollow structure), and has a large specific surface area and high porosity, so it has excellent liquid absorbency. High function as a liquid drawing-in route. Therefore, the liquid excretion penetrating the absorber 4A is rapidly absorbed by the crosslinked body of the alkyl cellulose derivative contained in the composite particles. In this way, the sanitary napkin 1 exhibits excellent liquid absorbency. For example, the sanitary napkin 1A exhibits a liquid absorption speed that an absorption time is 7 seconds or less when 3 mL of artificial menstrual blood is dropped on a 0.1 g absorber 4A at a dropping speed of 1.5 mL / second. Can do.

[After absorption]
When the crosslinked product of the alkyl cellulose derivative contained in the composite particles absorbs the liquid excreta and swells, gel particles are formed. Since these gel particles maintain a certain gel strength due to the thickening effect, they have excellent liquid retention during pressurization. Non-wood pulp with a sedimentation time in water of 2 to 5 seconds contained in the hydrophilic fiber has a porous structure (hollow structure) and has a large void ratio during pressurization (compression). Excellent liquid retention. Therefore, even when the absorbent body 4A is pressurized (for example, pressurized by the weight of the user), the liquid excrement retained in the absorbent body 4A can be returned and ooze out from the top sheet 2A (rewetting). The surface dryness of the sanitary napkin 1A is prevented. In this way, the sanitary napkin 1A exhibits excellent liquid retention (particularly liquid retention during pressurization). For example, sanitary napkin 1A is said to have a rewetting amount of 1.8 g or less for 3 minutes measured under a load of 30 g / cm ² after 3 mL of artificial menstrual blood is absorbed by 0.1 g of absorber 4A. An anti-wetting action can be exhibited.

  Moreover, since the space | gap formed by the entanglement of hydrophilic fibers exists between composite particles, coalescence of gel particles is prevented. Therefore, the gel particles do not serve as a barrier (gel blocking) when the liquid excrement supplied to the top sheet 2A penetrates the absorbent body 4A. Thereby, the phenomenon (overflow phenomenon) where the liquid excrement supplied to the top sheet 2A overflows without penetrating the absorber 4A is prevented.

  Further, the sanitary napkin 1A can maintain strength by entanglement between hydrophilic fibers, and can be reduced in weight by a gap formed by entanglement between hydrophilic fibers.

Various changes can be added to the sanitary napkin 1A.
For example, in the sanitary napkin 1A, an intermediate layer through which a user's liquid excrement can permeate can be provided between the top sheet 2A and the absorber 4A. Moreover, the intermediate | middle layer which a user's liquid excretion can permeate | transmit or cannot permeate | transmit can be provided between 3 A of back seat | sheets, and absorber 4A.

[Second Embodiment]
As shown in FIGS. 3 and 4, the disposable diaper 1B according to the second embodiment includes a top sheet 2B, a back sheet 3B, and an absorbent body 4B provided between the top sheet 2B and the back sheet 3B. Yes. The diaper 1B includes the auxiliary sheet 7 provided on the upper side of the top sheet 2B, but the auxiliary sheet 7 can be omitted.

  The top sheet 2B, the back sheet 3B, and the auxiliary sheet 7 have an hourglass shape with substantially the same dimensions, and the diaper 1B in the unfolded state (before being worn by the user) has an hourglass shape as shown in FIG.

  The diaper 1B is worn by the user for the purpose of absorbing the user's liquid excrement. At this time, as shown in FIG. 5, the auxiliary sheet 7 is worn by the user so that the auxiliary sheet 7 is located on the inner side (user's skin side) and the back sheet 3B is located on the outer side (user's clothing side). Examples of liquid excreta to be absorbed include urine, menstrual blood, and fallen products, but are usually mainly urine.

  As shown in FIG. 3, the diaper 1 </ b> B includes a front surface portion 11 that is applied to the user's abdomen when worn, an intermediate portion 12 that is applied to the user's crotch portion when worn, a user's buttocks and / or When the diaper 1B is worn by the user, as shown in FIG. 5, both side portions 111a and 111b of the front surface portion 11 and both side portions 131a of the rear surface portion 13 are provided. 131b is joined to each other, and a waist opening is formed by the end portion 112 of the front surface portion 11 and the end portion 132 of the rear surface portion 13, and both side portions 121a and 121b of the intermediate portion 12 are formed on the thigh of the user. The leg opening is formed by the both sides 121a and 121b of the intermediate portion 12. As shown in FIG. 3, elastic members 100a and 100b are provided at the end portion 112 of the front surface portion 11 and the end portion 132 of the rear surface portion 13, and elastic members 100c and 100d are provided at both side portions 121a and 121b of the intermediate portion 12. When the diaper 1 is worn by the user, as shown in FIG. 5, a waist gather is formed in the waist opening by the elastic contraction force of the elastic members 100a and 100b, and the elastic members 100c and 100d. Leg gathers (leg-side cuffs) are formed in the leg openings by the elastic contraction force.

  As shown in FIGS. 3 and 4, an opening 90 is provided in the center of the auxiliary sheet 7, and a part of the top sheet 2 </ b> B (a part covering the absorber 4 </ b> B) is exposed from the opening 90 of the auxiliary sheet 7. ing. The liquid excrement of the user enters from the opening 90 of the auxiliary sheet 7, penetrates the absorbent body 4B through the top sheet 2B, and is absorbed and held by the absorbent body 4B. Leakage of liquid excretion absorbed and held by the absorbent body 4B is prevented by the back sheet 3B.

  As shown in FIGS. 3 and 4, leakage prevention cuffs 6 a and 6 b formed of the back sheet 3 </ b> B are provided on both sides of the opening 90 of the auxiliary sheet 7. As shown in FIG. 4, one end of the leak-proof cuffs 6a and 6b is a fixed end sandwiched between the top sheet 2B and the auxiliary sheet 7, and the other end is the auxiliary sheet. 7 is a free end exposed from the opening 90 of the 7. As shown in FIG. 4, elastic members 61a and 62b are provided at the free ends of the leak-proof cuffs 6a and 6b. When the diaper 1b is worn by the user, as shown in FIG. Leak-proof cuffs 6a and 6b stand up toward the user's thighs.

  The auxiliary sheet 7 may be liquid permeable or liquid impermeable, but is usually liquid impermeable. Examples of the auxiliary sheet 7 include a waterproofed nonwoven fabric (for example, a point bond nonwoven fabric, a spunbond nonwoven fabric, a spunlace nonwoven fabric, etc.), a synthetic resin (for example, polyethylene, polypropylene, polyethylene terephthalate, etc.) film, a nonwoven fabric, and a synthetic resin. Examples include a composite sheet with a film.

  The top sheet 2B, the back sheet 3B, and the absorbent body 4B are obtained by appropriately changing the top sheet 2A, the back sheet 3A, and the absorbent body 4B of the sanitary napkin 1A in consideration of the characteristics that the diaper 1B should have. Can be used. The top sheet 2B, the back sheet 3B, and the absorbent body 4B have the same basic configuration as the top sheet 2A, the back sheet 3A, and the absorbent body 4B of the sanitary napkin 1A. Is omitted.

  The amount of the composite particles contained in the absorber 4B can be appropriately adjusted according to the characteristics (for example, absorbency, light weight, etc.) that the diaper 1B should have, but is usually 10 to 100% by mass of the absorber 4B, preferably It is 20-100 mass%, More preferably, it is 30-100 mass%.

  In the composite particles contained in the absorbent body 4B, the mass ratio between the non-wood pulp and the crosslinked product of the alkyl cellulose derivative is not particularly limited, but is preferably 1: 1 to 3: 1, more preferably 2: 1. When the mass ratio of both is in such a range, the liquid absorption property and liquid retention property (especially liquid retention property at the time of pressurization) of diaper 1B with respect to urine will improve.

  In the composite particles contained in the absorbent body 4B, the content of the non-wood pulp having an underwater sedimentation time of 2 to 5 seconds with respect to the entire hydrophilic fiber is usually 25 to 100% by mass, preferably 33 to 100% by mass, More preferably, it is 50-100 mass%.

  When the absorber 4B contains other absorbent material in addition to the composite particles, the mass ratio of the composite particles and the absorbent material contained in the absorber 4B is not particularly limited, but preferably 4 : 1 to 1: 4, more preferably 3: 1 to 1: 3.

The thickness, basis weight, density, etc. of the absorbent body 4B can be appropriately adjusted according to the properties (for example, absorbency, lightness, etc.) that the diaper 1B should have, but the thickness is usually 1-20 mm, preferably 2-10 mm, More preferably, it is 3 to 8 mm, the basis weight is usually 20 to 1000 g / m ² , preferably 50 to 900 g / m ² , more preferably 100 to 800 g / m ² , and the density is usually 0.001 to 1 g. / Cm ³ , preferably 0.005 to 0.45 g / cm ³ , more preferably 0.013 to 0.267 / cm ³ .

  The diaper 1B exhibits the same action as the sanitary napkin 1A during and after absorption of the user's liquid excreta. For example, the diaper 1B can exhibit a liquid absorption property that the time from when 2 g of the absorber 4B is charged into 30 g of a 0.9% sodium chloride aqueous solution until the liquid surface stops moving is 11 seconds or less. . Moreover, the diaper 1B can exhibit the liquid absorptivity that the water absorption rate with respect to 0.9% sodium chloride aqueous solution of the absorber 4B is 16 times or more. Furthermore, the diaper 1B can exhibit the liquid retention property that the water retention ratio with respect to the 0.9% sodium chloride aqueous solution of the absorber 4B is 10 times or more.

  EXAMPLES Hereinafter, although this invention is demonstrated in detail based on an Example, this invention is not limited by these Examples.

[Test Examples 1 to 14]
(1) Preparation of pulverized pulp 1 (Test Example Product 1) Abaca BKP (manufactured by Toyota Tsusho Co., Ltd., AK104) made from the vicinity of the core of the leaf sheath of Manila hemp (Chrysantaceae) is pulverized into fibers. 1 was prepared. BKP means bleached kraft pulp (the same applies hereinafter).

(2) Preparation of pulverized pulp 2 (Test Example Product 2) Abaca BKP (manufactured by Toyota Tsusho Co., Ltd., AK102) is pulverized into fibers from the middle part of the core of the leaf sheath of manila hemp (Chrysomeaceae) and the outer shell. Thus, pulverized pulp 2 was prepared.

(3) Preparation of pulverized pulp 3 (Test Example Product 3) Abaca BKP (manufactured by Toyota Tsusho Co., Ltd., AK102) made from the vicinity of the outer skin of Manila hemp (Chrysantaceae) is pulverized into fibers to give pulverized pulp 3 Prepared.

(4) Preparation of pulverized pulp 4 (Test Example Product 4) Banana BKP (manufactured by Toyota Tsusho Co., Ltd.) using banana (Chrysantaceae) stems as a raw material was pulverized into fibers to prepare pulverized pulp 4.

(5) Preparation of pulverized pulp 5 (Test Example Product 5) Wood pulp (softwood bleached kraft pulp (NBKP)) made from conifer (Yonematsu) as a raw material was pulverized into fibers to prepare pulverized pulp 5.

(6) Preparation of pulverized pulp 6 (Test Example Product 6) Bagasse BKP (manufactured by Toyota Tsusho Co., Ltd.) using bagasse (Poaceae) as a raw material was pulverized into fibers to prepare pulverized pulp 6.

(7) Preparation of pulverized pulp 7 (Test Example Product 7) Unbleached Bacus NBKP (manufactured by Toyota Tsusho Co., Ltd.) using bagasse (Poaceae) as a raw material was pulverized into fibers to prepare pulverized pulp 7.

(8) Preparation of pulverized pulp 8 (Test Example Product 8) Kenaf BKP (manufactured by Toyota Tsusho Co., Ltd.) using kenaf (Aoiaceae) as a raw material was pulverized into fibers to prepare pulverized pulp 8.

(9) Preparation of pulverized pulp 9 (Test Example Product 9) Esparto glass BKP (produced by Toyota Tsusho Co., Ltd.) using esparto grass (Gramineae) as a raw material was pulverized into fibers to prepare pulverized pulp 9 .

(10) Preparation of pulverized pulp 10 (Test Example Product 10) Sabygrass BKP (manufactured by Toyota Tsusho Co., Ltd.) using sabygrass (Poaceae) as a raw material was pulverized into fibers to prepare pulverized pulp 10.

(11) Preparation of pulverized pulp 11 (Test Example Product 11) Bamboo BKP (manufactured by Toyota Tsusho Co., Ltd.) using bamboo (Gramineae) as a raw material was pulverized into a fiber to prepare pulverized pulp 11.

(12) Preparation of pulverized pulp 12 (Test Example Product 12) Sisal BKP (manufactured by Toyota Tsusho Co., Ltd.) using sisal (Chrysantaceae) as a raw material was pulverized into fibers to prepare pulverized pulp 12.

(13) Preparation of pulverized pulp 13 (Test Example Product 13) Jute BKP (manufactured by Toyota Tsusho Co., Ltd.) using jute (Chrysantaceae) as a raw material was pulverized into fibers to prepare pulverized pulp 13.

(14) Preparation of pulverized pulp 14 (Test Example Product 14) Kapok BKP (manufactured by Toyota Tsusho Co., Ltd.) made from Kapok (Arcoceae) as a raw material was pulverized into a fiber to prepare pulverized pulp 14.

(15) Evaluation test of pulverized pulp 1-14 (Test Examples 1-14) Average fiber diameter (μm), lignin content (% by weight), settling time (seconds), fiber specific gravity (g) of pulverized pulp 1-14 / Cm ³ ), apparent bulk density (g / cm ³ ), water absorption capacity (g / g), water absorption capacity during pressurization (g / g) and water retention capacity (g / g) were measured as follows. .

<Average fiber diameter>
Using a Kajaani fiber length measuring instrument FiberLab 3.8 manufactured by Metssoautomation, the fiber diameter of about 20,000 pulps was measured, and the average fiber diameter (μm) of the pulp was calculated.

<Lignin content>
The lignin content (% by weight) of the pulp was P.P. J. et al. The measurement was performed according to the method of Van Soest et al. (Proc. Nutr. Soc., 32123 (1973)).

<Settling time>
A cylindrical basket (weight 3 g, diameter 50 mm, depth 80 mm) was uniformly packed with 5.0 g of pulp fibers. In addition, the cage | basket is formed with the copper wire (diameter 0.4mm), and a copper wire space | interval is 20 mm. Ion exchange water was put in a 2 L beaker until the water depth reached 200 mm. Place the basket filled with pulp fibers on the side and drop it from a height of 10 mm with respect to the water surface of the 2 L beaker. Measure the time (seconds) from when the basket touches the water surface until it sinks below the water surface. Seconds).

<Fiber specific gravity>
The fiber specific gravity (g / cm ³ ) of the pulp was measured according to JIS M 8717 using a He gas comparative hydrometer (manufactured by Tokyo Science).

<Apparent bulk density>
10 g of pulverized pulp was laminated to 100 mm × 100 mm, a 100 mm × 100 mm plate was placed thereon, and a weight with a load of 100 g was placed on the plate. The apparent bulk density (g / cm ³ ) was calculated by setting the thickness of the laminated pulp 10 seconds after placing the weight as the apparent bulk (cm ³ ).

<Liquid absorption, liquid absorption during pressurization, liquid retention>
(A) 1000 mL of 0.9% physiological saline was placed in a 2 L beaker, and the liquid temperature was measured. 0.9% physiological saline is charged with 27.0 g of sodium chloride (reagent grade 1) in a 3 L beaker and then ion exchanged water in the 3 L beaker until the total amount of ion exchange water and sodium chloride reaches 3000 g. It was prepared by adding
(B) A 250 mesh nylon mesh (NBC Industrial, N-NO. 250HD) was cut into a size of 200 mm × 200 mm (the nylon mesh 21 shown in FIG. 7A) and the weight (x (g)) was measured. After that, as shown in FIG. 7A, the portion of the BB dashed line was folded, and the nylon mesh 21 was folded in half. As shown in FIG. 7 (b), after the folded portion is arranged on the right side, a heat seal 22 is formed at a position 5mm above the lower end, a position 5mm left from the right end, and a position 5mm right from the left end. Thus, a nylon mesh bag 24 having an open upper end 23 was produced. A sample (y (g)) whose weight was measured in advance was placed in the nylon mesh bag 24, a heat seal (not shown) was formed, and the open upper end 23 of the nylon mesh bag 24 was closed.
(C) The bag containing the sample was completely immersed in 0.9% physiological saline and left for 3 minutes.
(D) After leaving, the sample bag was pulled up and drained by standing for 3 minutes.
(E) The weight (z ₁ (g)) of the bag containing the sample was measured.
(F) The water absorption magnification at the normal time (at the time of non-pressurization) was calculated from the following formula.
Water absorption magnification (g / g) = ((z ₁ −x) −y) / y
(G) After (e), an acrylic plate was placed on the sample bag, and a weight of 3.5 kg per 100 mm × 100 mm was further placed on the acrylic plate and left for 3 minutes.
(H) The weight and the acrylic plate were removed, and the weight (z ₂ (g)) of the bag containing the sample was measured.
(I) The water absorption magnification at the time of pressurization was calculated from the following formula.
Water absorption ratio at pressurization (g / g) = ((z ₂ −x) −y) / y
(J) After (h), the bag containing the sample was dehydrated with a centrifuge. At this time, a separator type H130 manufactured by Kokusan Centrifugal Co., Ltd. was used as the centrifuge. The number of rotations of the centrifuge was 850 rpm (150 G).
(K) The weight (z ₃ ) of the sample-containing bag after dehydration was measured.
(L) The liquid retention amount was calculated from the following equation.
Water retention magnification (g / g) = ((z ₃ −x) −y) / y

Average fiber diameter (μm), lignin content (% by weight), settling time (seconds), fiber specific gravity (g / cm ³ ), apparent bulk density (g / cm ³ ), water absorption ratio (g) Table 1 shows the water absorption ratio (g / g) and water retention ratio (g / g).

The pulverized pulps 1, 2, 4 and 11 (Abaca BKP (AK104,102), Banana BKP, Bamboo BKP) satisfied all the following characteristics.
-Settling time in water is 2-5 seconds.
-Apparent bulk density is 0.04-0.07 g / cm < ³ >.
-The liquid absorption is 20 times or more of its own weight.
-Average fiber diameter is 8-25 micrometers.
-Lignin content is 0.5 mass% or less.

  In addition, the liquid absorbability and liquid retention during pressurization of pulverized pulps 1, 2, 4, and 11 (Abaca BKP (AK104,102), Banana BKP, Bamboo BKP) are higher than those of pulverized pulp 5 (wood pulp (NBKP)). Was also excellent.

  Such characteristics of abaca pulp, banana pulp and bamboo pulp are considered to be based on the following reasons. The scanning electron microscope (SEM) photograph of the cross section of each fiber of an abaca pulp, a banana pulp, and a wood pulp is shown in FIG. 8A is an SEM photograph of a cross section of an abaca pulp fiber, FIG. 8B is an SEM photograph of a cross section of a banana pulp fiber, and FIG. 8C is an SEM photograph of a cross section of a wood pulp fiber. It is. As shown in FIG. 8, abaca pulp and banana pulp have a porous structure (hollow structure), whereas wood pulp does not have a porous structure (hollow structure). Abaca pulp and banana pulp are presumed to be excellent in liquid absorbency and liquid retention during pressurization because moisture can be taken into the voids of the porous structure.

[Examples 1-9 and Comparative Examples 1-9]
(1) Production of Example Product 1 Sodium carboxymethylcellulose (manufactured by Daicel Chemical Industries, product number: 1380) and ion-exchanged water were mixed to prepare a paste having a carboxymethylcellulose (CMC) concentration of 20% by weight. The paste was irradiated with γ rays at 10 kGy to prepare carboxymethylcellulose hydrogel (hereinafter referred to as “CMC gel”). 25 g of CMC gel cut into 1 cm square with scissors and 10 g of Abaca pulp fiber (manufactured by Toyota Tsusho Co., Ltd., trade name AK104) were put into a grinder (Grindmix GM200 made by Lecce Co., Ltd.). The weight ratio of the fiber to the crosslinked CMC (dried product of CMC gel was 67:33) was formed into composite particles (pulverized and mixed) for 30 seconds. Subsequently, after drying with warm air of 60 ° C., the mixture was pulverized and passed through a 710 mesh sieve to prepare an absorbent sample (Example product 1).

  An electron scanning microscope (SEM) photograph of Example Product 1 is shown in FIG. As shown in FIG. 9, Example Product 1 includes a large number of composite particles in which a CMC cross-linked product (dried product of CMC gel) by irradiation with radiation is coated with pulp fibers, and the composite particles are shaped like a beard. There were voids formed by intertwining protruding pulp fibers (pulp fibers protruding from the same composite particle or pulp fibers protruding from different composite particles).

  For reference, FIG. 10 shows an electron scanning microscope (SEM) photograph of a material obtained by pulverizing and drying a CMC gel alone without mixing pulp fibers. In the composite particle shown in FIG. 9, the CMC cross-linked body shown in FIG. 10 forms a core portion, and the pulp fiber covers the core portion to form the surface of the composite particle, and the pulp fiber is outside the CMC cross-linked body. It is thought that it has reached the inside from the inside.

(2) Production of Example Product 2 An absorber sample (Example Product 2) was produced in the same manner as in Example 1 except that bamboo pulp fiber was used instead of abaca pulp fiber.

(3) Preparation of Example Product 3 An absorber sample (Example Product 3) was prepared in the same manner as in Example 1 except that the basis weight of the absorber sample was 80% by weight of Example Product 1.

(4) Production of Example Product 4 Absorber sample (implemented in the same manner as in Example 1) except that the ratio of abaca pulp fiber was increased (the weight ratio of abaca pulp fiber to CMC cross-linked product was 75:25). Example product 4) was produced.

(5) Production of Example Product 5 Absorber sample (implemented in the same manner as in Example 1) except that the ratio of abaca pulp fiber was increased (weight ratio of abaca pulp fiber and CMC crosslinked was set to 80:20). Example product 5) was produced.

(6) Production of Example Product 6 Except for the point that the ratio of the CMC crosslinked body was increased (the weight ratio of the abaca pulp fiber to the CMC crosslinked body was 50:50), the absorbent sample ( Example product 6) was prepared.

(7) Production of Example Product 7 Except that the ratio of the CMC crosslinked body was increased (the weight ratio of the abaca pulp fiber to the CMC crosslinked body was set to 33:67), the absorbent sample ( Example product 7) was prepared.

(8) Production of Example Product 8 Except for the point that the ratio of the CMC crosslinked body was increased (the weight ratio of the abaca pulp fiber to the CMC crosslinked body was set to 25:75), the absorbent sample ( Example product 8) was prepared.

(9) superabsorbent polymer prepared basis weight 50 g / cm ² of comparative examples 1 (SAP, AQUA KEEP SA60S, Sumitomo Seika Chemicals Co., Ltd.) and, by mixing and basis weight 50 g / cm ² of wood pulp (NBKP), An absorber sample (Comparative Example Product 1) was prepared.

(10) Production of Comparative Example Product 2 Absorbent sample (Comparative Example Product 2) in the same manner as in Example 1 except that the CMC crosslinked product and Abaca pulp fiber were not combined (pulverized and mixed) and dried. Was made.

(11) Production of Comparative Example Product 3 An absorber sample (Comparative Example Product 3) was produced in the same manner as in Comparative Example 2, except that wood pulp (NBKP) was used instead of abaca pulp fiber.

(12) Preparation of Comparative Example Product 4 An absorber sample (Comparative Example Product 4) was prepared in the same manner as in Example 1 except that wood pulp (NBKP) was used instead of the abaca pulp fiber.

(13) Production of Comparative Example Product 5 Except for the point that the ratio of the CMC crosslinked body was increased (the weight ratio of the CMC crosslinked body and wood pulp (NBKP) was 50:50), the absorbent body was similar to Comparative Example 4. A sample (Comparative Product 5) was prepared.

(14) Production of Comparative Product 6 An absorbent sample (Comparative Product 6) was produced in the same manner as in Comparative Example 3, except that SAP was used instead of the CMC crosslinked product.

(15) Production of Comparative Example Product 7 An absorber sample (Comparative Example Product 7) was produced using only wood pulp (NBKP).

(16) Preparation of Comparative Example Product 8 An absorber sample (Comparative Example Product 8) was prepared using only the CMC crosslinked product (dried product of CMC gel).

(17) Preparation of Comparative Example Product 9 An absorber sample (Comparative Example Product 9) was prepared using only SAP.

(18) Evaluation test of Example products 1 to 8 and Comparative products 1 to 9 Regarding Example products 1 to 8 and Comparative products 1 to 9, blood absorption time (seconds) for artificial menstrual blood, rewetting amount (g) and Blood retention ratio (g / g), water absorption time (seconds), water absorption ratio (g / g) and water retention ratio (g / g) for artificial urine (0.9% sodium chloride aqueous solution) were measured. The artificial menstrual blood was produced as follows.
32. ± 2 g of glycerin (Wako First Grade 072-00621 manufactured by Wako Pure Chemical Industries, Ltd.) 320 ± 2 g is put into a plastic container A, and sodium carboxymethylcellulose (NaCMC) (chemical use 039-01335 manufactured by Wako Pure Chemical Industries, Ltd.) 32. 0 ± 0.3 g was added, and the mixture was stirred for 10 minutes at a rotation speed of about 600 rpm with a stirrer (Model DC-2E, manufactured by HSIANGTAIMACHINERY CO. LTD.) To prepare Solution A. Next, the solution A prepared previously was added little by little while stirring 3 liters of ion-exchanged water in another plastic container B with the above stirrer at a rotation speed of about 1100 rpm. Further, the polycontainer A was added while washing with 1 liter of ion exchange water. Into the solution B thus obtained, 40 g of sodium chloride (NaCl) (reagent special grade 191-01665 manufactured by Wako Pure Chemical Industries, Ltd.) and sodium hydrogen carbonate (NaHCO ₃ ) (Wako Pure Chemical Industries, Ltd. manufactured by Wako) First grade 198-0131) 16g was added little by little with stirring. After the addition was completed, the mixture was stirred for about 3 hours. Next, to the solution C obtained by the above adjustment, food color preparation (manufactured by Koyo Productac Co., Ltd.): 32 g of red No. 102, 8 g of red No. 2 and 8 g of yellow No. 5 were added with stirring, and then The mixture was stirred for about 1 hour to obtain artificial menstrual blood. It was 22-26 mPa * s when the viscosity of the obtained artificial menstrual blood was measured with the viscosity measuring device (Bismetron type | formula VGA-4 by Shibaura system company).

<Blood absorption time>
0.1 g of each sample was placed in an aluminum cup, and 3 mL of artificial menstrual blood was dropped with a pipette at a dropping rate of 1.5 mL / second. After the start of dropping, the time until artificial menstrual blood was absorbed into the sample was measured, and this was defined as blood absorption time (seconds).

<Rewet amount>
Place 0.1 g of each sample in an aluminum cup, drop 3 mL of artificial menstrual blood with a pipette at a dropping rate of 1.5 mL / sec, leave it for 3 minutes, and place a net and filter paper (35 x 50 mm) on the sample in order. A weight was placed on the filter paper so that a load of 30 g / cm ² was applied to the filter paper. Three minutes after the weight was placed, the weight of the filter paper was measured, and the increase relative to the weight of the filter paper before placing on the sample was defined as the rewet amount (g).

<Blood retention ratio>
Based on the following formula, the blood retention rate (g / g) was calculated from the rewetting amount.
{Artificial menstrual blood 3 (mL)-Rewet amount (g)} / Sample 0.1 (g)
For artificial menstrual blood, mL units were converted to g units.

<Water absorption time>
(1) Put the test solution in a 1 liter beaker in advance and place it in a water bath, and adjust the test solution temperature to 25 ° C. ± 1 ° C.
(2) Place the rotor in a 100 mL beaker.
(3) Take 30 g of the test solution (adjusted to a liquid temperature of 25 ° C.) with an electronic balance in a 100 mL beaker. The test solution is a 0.9% sodium chloride aqueous solution (sodium chloride is reagent grade 1) and is prepared as follows. Place a 3 L beaker on the electronic balance (after resetting the weight display to 0 g), add ion-exchanged water to 27.0 g of sodium chloride (reagent grade 1) to make 3000.0 g. Then stir until dissolved.
(4) Place a 100 mL beaker on a magneck stirrer and stir at 600 rpm while watching the attached meter.
(5) The rotational speed is measured with a non-contact tachometer, and the rotational speed is adjusted to 600 ± 30 rpm.
(6) 2.00 g of the absorbent material is precisely weighed.
(7) Start the stopwatch at the same time as putting the weighed absorbent material into the 100 mL beaker.
(8) Stop the stopwatch when the liquid surface becomes flat. The way to view the end point is determined by observing the disappearance of the light reflected on the liquid surface of the vortex, with the inclination of the vortex of the rapidly rotating liquid approaching the plane. The time from when the absorbent material is put into the 100 mL beaker until the liquid surface stops moving is the water absorption time.

<Water absorption magnification>
(1) Place 1000 mL of physiological saline in a 2 L beaker and measure the liquid temperature. For physiological saline, after 27.0 g of sodium chloride (reagent grade 1) is placed in a 3 L beaker, ion exchange water is added to the 3 L beaker until the total amount of ion exchange water and sodium chloride reaches 3000.0 g. It is produced by. The concentration of sodium chloride in physiological saline was 0.9% by weight.
(2) After a 250 mesh nylon mesh (NBC NO.250HD) was cut into a size of 200 mm × 200 mm, the AA chain line portion was folded as shown in FIG. Fold the mesh 21 in half. As shown in FIG. 7B, after placing the folded portion on the right side, a heat seal 22 is formed at a position 5 mm above the lower end, a position 5 mm left from the right end, and a position 5 mm right from the left end. Thus, a nylon mesh bag 24 having an open upper end 23 is produced. 1.000 g of absorbent material is put into the nylon mesh bag 24, a heat seal (not shown) is formed, and the open upper end 23 of the nylon mesh bag 24 is closed.
(3) The bag containing the absorbent material is immersed so as to touch the bottom of the beaker containing physiological saline, and left for 1 hour.
(4) Pull up the bag after standing, pinch the center of the short side of the bag (5 mm from the top, 50 mm from both ends) with a clothespin, and drain the water for 15 minutes.
(5) Measure the weight (W _a ) of the bag containing the absorbent material.
(6) Calculate the water absorption magnification from the following equation.
Water absorption ratio (g / g) = (W _a ) (g) −2.6

<Water retention ratio>
(1) In the above-described water absorption test, the bag containing the absorbent material that has been drained for 15 minutes is dehydrated with a centrifuge. The centrifuge used is a separator type H130 manufactured by Kokusan Centrifugal Co., Ltd. The rotation speed of the centrifuge is 850 rpm (150 G).
(2) The weight (W _b ) of the bag containing the absorbent material after dehydration is measured.
(3) Calculate the water retention magnification from the following equation.
Water retention magnification (g / g) = (W _b ) (g) −2.3

  Table 2 shows the test results of Examples 1 to 8 and Comparative Examples 1 to 9. Note that “ND” indicates that the substance was not absorbed even after 3 minutes.

Hereinafter, the test results shown in Table 2 will be considered.
(1) Absorption and retention of artificial menstrual blood [Discussion 1]
Example product 1 in which CMC crosslinked body and abaca pulp (weight ratio 33:67) are made into composite particles is compared with Comparative product 2 in which CMC crosslinked body and abaca pulp (weight ratio 33:67) are not made into composite particles. Thus, an increase in blood sucking speed (decrease in blood sucking time), a decrease in rewet amount, and an increase in blood retention ratio are shown. In particular, the decrease in the rewetting amount and the increase in the blood retention ratio are remarkable.
Example product 1 in which CMC cross-linked product and abaca pulp (weight ratio 33:67) are made into composite particles is a comparative example product 4 in which CMC cross-linked product and wood pulp (weight ratio 33:67) are made into composite particles. In comparison, an increase in blood absorption rate (decrease in blood absorption time), a decrease in rewet amount, and an increase in blood retention rate are shown. In particular, the increase in blood absorption speed (decrease in blood absorption time) is significant.
Therefore, it is considered that the excellent blood-sucking property and blood-holding property exhibited by Example Product 1 are based on both the fact that it is made into composite particles and that abaca pulp is adopted. In particular, it is considered that the excellent blood retention property exhibited by the example product 1 is based on the composite particles, and the excellent blood-absorbing property exhibited by the example product 1 is based on the use of the abaca pulp.
In addition, the comparative example product 4 in which the CMC crosslinked body and the wood pulp (weight ratio 33:67) are made into composite particles is the comparative example in which the CMC crosslinked body and the wood pulp (weight ratio 33:67) are not made into composite particles. Compared to product 3, it shows a decrease in the rewetting amount and an increase in the blood retention rate, but not an increase in blood absorption rate (decrease in blood absorption time).

[Discussion 2]
Example product 1 in which CMC cross-linked body and abaca pulp (weight ratio 33:67) are formed into composite particles, and Example product 2 in which CMC cross-linked body and bamboo pulp (weight ratio 33:67) are formed into composite particles Is inferior in terms of blood absorption rate (blood absorption time), rewet amount, and blood retention magnification.
Therefore, even when non-wood pulp such as bamboo pulp is employed as the pulp to be complexed with the CMC cross-linked body, it is considered that the same excellent blood absorbability and blood retention as when abaca pulp is employed are exhibited.

[Discussion 3]
Example product 3 shows the same blood absorption rate (blood absorption time), rewetting amount and blood retention magnification as comparative example products 1 to 3, although the amount of the absorbent is smaller than that of comparative product 1 to 3.
Therefore, the amount of the absorbent used can be reduced by making the CMC crosslinked body and non-wood pulp such as abaca pulp and bamboo pulp into composite particles.

[Discussion 4]
Since Examples 1-4 satisfy | fill the preferable conditions that the blood absorption time is 7 seconds or less and the rewetting amount is 1.8 g or less, the weight ratio of non-wood pulp such as CMC crosslinked body and abaca pulp or bamboo pulp is preferably 1: 2. ~ 1: 3.
Since Examples 1 and 2 satisfy the more preferable condition that the blood absorption time is 6 seconds or less and the rewetting amount is 1.5 g or less, the weight ratio of the non-wood pulp such as CMC crosslinked body and abaca pulp or bamboo pulp is more preferably 1. : 2.

(2) Absorption and retention of artificial urine (0.9% sodium chloride aqueous solution) [Discussion 1]
Example product 1 in which CMC crosslinked body and abaca pulp (weight ratio 33:67) are made into composite particles is compared with Comparative product 2 in which CMC crosslinked body and abaca pulp (weight ratio 33:67) are not made into composite particles. Thus, an increase in water absorption rate (decrease in water absorption time) and an increase in water retention ratio are shown. In particular, the increase in water absorption speed (decrease in water absorption time) is remarkable.
Example product 1 in which CMC cross-linked product and abaca pulp (weight ratio 33:67) are made into composite particles is a comparative example product 4 in which CMC cross-linked product and wood pulp (weight ratio 33:67) are made into composite particles. In comparison, an increase in water absorption rate (decrease in water absorption time), an increase in water absorption rate, and an increase in water retention rate are shown. In particular, the increase in water absorption speed (decrease in water absorption time) is remarkable.
Therefore, it is considered that the excellent water absorption and water retention exhibited by Example Product 1 are based on both the formation of composite particles and the use of abaca pulp.

[Discussion 2]
Example product 1 in which CMC cross-linked body and abaca pulp (weight ratio 33:67) are formed into composite particles, and Example product 2 in which CMC cross-linked body and bamboo pulp (weight ratio 33:67) are formed into composite particles Is inferior in terms of water absorption speed (water absorption time), water absorption magnification and water retention magnification.
Therefore, even when non-wood pulp such as bamboo pulp is employed as the pulp to be complexed with the CMC cross-linked body, it is considered that excellent water absorption and water retention similar to the case where abaca pulp is employed are exhibited.

[Discussion 3]
Example product 3 has a water absorption rate (water absorption time), water absorption rate, and water retention rate that are the same as or higher than those of comparative example products 1-3, although the amount of the absorbent is smaller than that of comparative products 1-3. Show.
Therefore, the amount of the absorbent used can be reduced by making the CMC crosslinked body and non-wood pulp such as abaca pulp and bamboo pulp into composite particles.

[Discussion 4]
Since Example goods 1-4 and 6 satisfy | fill the preferable conditions of water absorption time 11 seconds or less, water absorption magnification 16g / g (16 times) or more, and water retention magnification 10g / g (10 times) or more, CMC crosslinked body and abaca pulp The weight ratio of non-wood pulp such as bamboo pulp is preferably 1: 1 to 1: 3.
Since the more preferable condition of the water absorption time of 5 seconds or less is satisfied, the weight ratio of the CMC crosslinked body and the non-wood pulp such as abaca pulp and bamboo pulp is preferably 1: 2.

1A Sanitary napkin (absorbent article)
1B disposable diapers (absorbent articles)
2A, 2B Top sheet (liquid permeable sheet)
3A, 3B Back sheet (liquid impervious sheet)
4A, 4B absorber

Claims (17)

  An absorbent comprising composite particles containing a crosslinked product of an alkyl cellulose derivative and a hydrophilic fiber, wherein the hydrophilic fiber comprises a non-wood pulp having a settling time in water of 2 to 5 seconds.   The absorbent body according to claim 1, wherein the crosslinked product of the alkyl cellulose derivative is a dried product of cellulose hydrogel obtained by irradiating a mixture containing the alkyl cellulose derivative and water.   The absorbent body according to claim 1 or 2, wherein in the composite particle, the hydrophilic fiber reaches the inside from the outside of the crosslinked body of the alkyl cellulose derivative.   The absorber of any one of Claims 1-3 whose mass ratio of the said non-wood pulp and the crosslinked body of the said alkylcellulose derivative is 1: 1-3: 1.   The absorber of any one of Claims 1-3 whose mass ratio of the said non-wood pulp and the crosslinked body of the said alkylcellulose derivative is 2: 1-3: 1. The absorbent body according to any one of claims 1 to 5, wherein the apparent bulk density of the non-wood pulp is 0.04 to 0.07 g / cm ³ .   The absorber according to any one of claims 1 to 6, wherein the liquid absorption amount of the non-wood pulp is 20 times or more of its own weight.   The absorber according to any one of claims 1 to 7, wherein the non-wood pulp has an average fiber diameter of 8 to 25 µm.   The absorber according to any one of claims 1 to 8, wherein the lignin content of the non-wood pulp is 0.5% by mass or less.   The absorber according to any one of claims 1 to 9, wherein the non-wood pulp is an abaca pulp made from Manila hemp leaf sheath or a bamboo pulp made from bamboo.   The absorber according to claim 10, wherein the abaca pulp is an abaca pulp made from a portion near the core of a Manila hemp leaf sheath or an intermediate portion between the core and the outer skin.   The absorber according to any one of claims 1 to 11, wherein an absorption time when 3 mL of artificial menstrual blood is dropped onto 0.1 g of the absorber at a dropping rate of 1.5 mL / sec is 7 seconds or less. The amount of rewet for 3 minutes measured under a load of 30 g / cm ² after absorbing 3 mL of artificial menstrual blood in 0.1 g of the absorber is 1.8 g or less. The absorber as described in.   The absorber according to any one of claims 1 to 13, wherein the time from when 2 g of the absorber is charged into 30 g of a 0.9% sodium chloride aqueous solution until the liquid surface does not move is 11 seconds or less.   The absorber of any one of Claims 1-14 whose water absorption capacity | capacitance with respect to 0.9% sodium chloride aqueous solution of an absorber is 16 times or more.   The absorbent body according to any one of claims 1 to 15, wherein a water retention ratio of the absorbent body to a 0.9% sodium chloride aqueous solution is 10 times or more.   An absorbent article comprising a liquid-permeable sheet, a liquid-impermeable sheet, and an absorbent body provided between the liquid-permeable sheet and the liquid-impermeable sheet, wherein the absorbent body is claimed. The said absorbent article which is an absorber of any one of claim | item 1-116.