JP7126417B2 - absorbent article - Google Patents

Description

The present invention relates to absorbent articles used for absorbing bodily fluids.

Absorbent articles that are worn in the crotch region of the body are typically composed of a surface sheet arranged so as to be in contact with the wearer's skin, and a surface sheet arranged farther from the wearer's skin than the surface sheet. and an absorbent body interposed between the two sheets, and the absorbent body absorbs and retains body fluids such as urine, feces, and menstrual blood excreted from the crotch. Absorption of bodily fluids excreted from the crotch region is particularly important for this type of absorbent article. In order to reduce discomfort due to stickiness and skin troubles such as eczema, heat rash, and rash caused by sweating while wearing, the ability to absorb sweat and keep the skin dry is also important. Therefore, conventionally, a so-called sweat-absorbing sheet having a sweat-absorbing function is arranged at a portion of an absorbent article that may come into contact with the wearer's skin when worn.

For example, in Patent Document 1, the waist flap, which is the part that contacts the waist of the wearer, has a hydrophobic skin-side sheet relatively close to the wearer's skin and a hydrophilic skin-side sheet relatively far from the wearer's skin. and a non-skin-side sheet having a laminated structure, wherein the skin-side sheet is formed with a plurality of recessed portions recessed toward the non-skin-side sheet side, and each recessed portion contains the constituent fibers of the skin-side sheet is melted to form a fused portion in which the constituent fibers are fused to each other without gaps. The fused portion is formed by subjecting only the hydrophobic skin-side sheet to thermal embossing, and is hydrophobic.

Further, Patent Document 2 describes a method for inexpensively improving the sweat absorption and moisture absorption characteristics of the waist side portion and the side portion of a disposable diaper that do not have absorbent elements. When a second sheet made of hydrophobic or water-repellent fibers is laminated on either the front or back side of the first sheet so as to be in contact with the second sheet, the first sheet coated with a hydrophilizing agent describes a method of forming a laminated portion by laminating a second sheet not coated with a hydrophilizing agent, and then holding the laminated portion in a state of being pressed in the thickness direction. According to Patent Document 2, by such a method, the hydrophilizing agent of the first sheet is transferred to the second sheet to improve the water absorbency of the second sheet, and as a result, the water absorbency of both sheets is improved. It is In the laminated structure obtained by such method, the first sheet and the second sheet are not fused.

JP 2017-113188 A Japanese Patent Application Laid-Open No. 2015-66008

There is room for improvement in the sweat absorption performance of conventional absorbent articles. Accordingly, an object of the present invention is to provide an absorbent article having excellent sweat absorption performance.

The present invention has a longitudinal direction corresponding to the front-rear direction of the wearer and a lateral direction perpendicular to the longitudinal direction. and a crotch portion positioned between the abdominal portion and the dorsal portion, wherein a longitudinally extending absorbent core is disposed in the crotch portion, and the abdominal portion and the dorsal portion An absorbent article having, on at least one side, a waist flap arranged longitudinally outward from the longitudinal end of the absorbent core, wherein at least a part of the waist flap on the side facing the skin is made of a hydrophobic fiber. is formed from a nonwoven fabric having a laminated structure of a hydrophobic fiber layer containing and a hydrophilic fiber layer containing hydrophilic fibers, and the hydrophobic fiber layer is arranged closer to the wearer's skin than the hydrophilic fiber layer At least a partial region of the nonwoven fabric in a plan view is a high-density fiber region having a thickness average fiber-to-fiber distance of 50 μm or less, which is obtained by averaging the fiber-to-fiber distances in the thickness direction of the region, and the hydrophobic fiber layer or a portion of the hydrophobic fiber layer adjacent to the high-density fiber region in the plane direction of the nonwoven fabric has higher hydrophilicity than other portions of the hydrophobic fiber layer. The absorbent article further includes a skin-side hydrophilic region having a lower degree of hydrophilicity than the hydrophilic fiber layer, and the skin-side hydrophilic region intermittently exists in the planar direction of the nonwoven fabric.

ADVANTAGE OF THE INVENTION According to this invention, the absorbent article excellent in sweat absorption performance is provided.

FIG. 1 is a perspective view schematically showing an underpants-type disposable diaper that is one embodiment of the absorbent article of the present invention. FIG. 2 is a developed plan view schematically showing the skin-facing surface side (inner surface side) of the diaper shown in FIG. 1 in an unfolded and stretched state. FIG. 3 is a cross-sectional view schematically showing a section taken along line II in FIG. 2 (a section along the horizontal direction). FIG. 4 is a cross-sectional view schematically showing the II-II line cross section (cross section along the longitudinal direction) of FIG. 2, and one longitudinal end portion of the diaper shown in FIG. ) is an enlarged schematic longitudinal sectional view. 5 is a plan view schematically showing part of the skin-facing surface (skin-facing surface of the hydrophobic fiber layer) of the nonwoven fabric forming the skin-facing surface side of the waist flap of the diaper shown in FIG. 1. FIG. FIG. 6 is a cross-sectional view schematically showing a cross section taken along the line III-III in FIG. 5 (a cross section along the thickness direction of the nonwoven fabric). FIG. 7 is a cross-sectional view schematically showing a cross-section along the thickness direction of another embodiment of the nonwoven fabric forming the skin-facing side of the waist flap in the absorbent article of the present invention. FIG. 8 is a cross-sectional view schematically showing a cross-section along the thickness direction of still another embodiment of the nonwoven fabric forming the skin facing side of the waist flap in the absorbent article of the present invention. FIG. 9 is a cross-sectional view schematically showing a cross section along the thickness direction of still another embodiment of the nonwoven fabric forming the skin facing side of the waist flap in the absorbent article of the present invention. FIG. 10 is a cross-sectional view schematically showing a cross-section along the thickness direction of still another embodiment of the nonwoven fabric forming the skin facing side of the waist flap in the absorbent article of the present invention. FIG. 11 is a cross-sectional view schematically showing a cross section along the thickness direction of still another embodiment of the nonwoven fabric forming the skin facing side of the waist flap in the absorbent article of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the absorbent article of the present invention will be described based on its preferred embodiments with reference to the drawings. 1 to 4 show an underpants-type disposable diaper 1 that is one embodiment of the absorbent article of the present invention. As shown in FIGS. 1 and 2, the diaper 1 has a longitudinal direction X corresponding to the front-rear direction of the wearer, that is, a direction extending from the abdomen to the back through the crotch, and a lateral direction Y orthogonal thereto. , and a ventral portion F and a dorsal portion R disposed on the dorsal side of the wearer when worn, and a crotch portion M located between the ventral portion F and the dorsal portion R and The ventral portion F is positioned forward of the crotch portion M in the longitudinal direction X, and the back portion R is positioned rearward of the crotch portion M in the longitudinal direction X. (around the waist). The crotch portion M includes an excretion spot portion (not shown) that is arranged between the crotch portion of the wearer when the diaper 1 is worn and faces the excretion portion such as the wearer's penis.

The diaper 1 has an absorbent main body 2 including an absorbent body 23 (absorbent core 24) in the central portion in the lateral direction Y, and is worn on the non-skin facing side of the absorbent main body 2, that is, from the absorbent main body 2. The outer body 3 is arranged on the far side from the body of the person, and both side edges along the longitudinal direction X of the outer body 3 in each of the ventral part F and the dorsal part R are bonded with an adhesive, heat-sealed, or ultrasonically. They are joined to each other by known joining means such as seals, and as shown in FIG. A pair of leg openings LH, LH are formed.

As used herein, the term “skin-facing surface” refers to the surface of the absorbent article or its constituent members (for example, the nonwoven fabric 10 described later) that faces the wearer's skin when the absorbent article is worn. The "non-skin facing side" is the side of the absorbent article or its constituent members that faces away from the skin when the absorbent article is worn. on the far side from It should be noted that the term "when worn" as used herein means a state in which the absorbent article is maintained in a normal and appropriate wearing position, that is, in a correct wearing position of the absorbent article.

The absorbent main body 2 has a rectangular shape in plan view in the unfolded and stretched state of the diaper 1 as shown in FIG. is aligned with the longitudinal direction X of the diaper 1 in the unfolded and stretched state, arranged in the center of the outer body 3 in the lateral direction Y, and joined to the outer body 3 with an adhesive. The "unfolded and stretched state" of the diaper 1 means that the diaper 1 is cut off at the side seal portion S to be in the unfolded state, and the elastic members of each part of the diaper 1 in the unfolded state are stretched to the design size (the influence of the elastic member is completely removed). It means the state in which it is expanded until it becomes the same dimension as when it is expanded in a flat state in the excluded state).

As shown in FIG. 3, the absorbent body 2 comprises a liquid-permeable top sheet 21 forming a skin-facing surface and a liquid-impermeable, liquid-impermeable or water-repellent back sheet 22 forming a non-skin facing surface. , and a liquid-retaining absorber 23 interposed between the sheets 21 and 22, which are integrated by a known bonding means such as an adhesive. As the top sheet 21 and the back sheet 22, various types of materials conventionally used for this type of absorbent article can be used without particular limitation. For example, various non-woven fabrics, perforated films, etc. can be used as the top sheet 21, and resin films, laminates of resin films and non-woven fabrics, etc. can be used as the back sheet 22. FIG.

The absorbent body 23 includes a liquid-retaining absorbent core 24 mainly made of an absorbent material, and a core wrap sheet 25 covering the outer surface of the absorbent core 24, that is, the skin-facing surface and the non-skin-facing surface. It is The absorbent core 24 and the core wrap sheet 25 may be joined by a known joining means such as a hot-melt adhesive. The absorbent core 24 has a rectangular shape elongated in the vertical direction X in plan view as shown in FIG. In this embodiment, the absorbent core 24 extends in the longitudinal direction X from the ventral portion F to the dorsal portion R. As shown in FIG. As the absorbent material that forms the main body of the absorbent core 24, any material that is used as an absorbent body material in this type of absorbent article can be used without particular limitation. , water-absorbent polymers, and the like. As a typical form of the absorbent core 24, a fiber aggregate of hydrophilic fibers such as wood pulp, or a fiber aggregate holding particulate water-absorbent polymer can be exemplified. As the core wrap sheet 25, for example, liquid-permeable sheets such as paper, various nonwoven fabrics, and perforated films can be used.

As shown in FIGS. 2 and 3, both sides along the longitudinal direction X of the skin-facing surface of the absorbent body 2 are provided with liquid-resistant or water-repellent and air-permeable leak-proof cuff-forming sheets 27. A pair of leakproof cuffs 26, 26 are also provided. One or more string-like elastic members 28 for forming a leak-preventing cuff are arranged in the longitudinal direction X in a stretched state near the free end of each leak-preventing cuff 26 . The leakage-preventing cuff 26 stands up at least at the crotch portion M by contracting the elastic member 28 arranged in a stretched state when the diaper 1 is put on, thereby preventing excreted fluid such as urine from flowing outward in the lateral direction Y. prevent

The outer body 3 forms the outer shape of the diaper 1 in the unfolded and stretched state as shown in FIG. It forms the outline of each dorsal part R. As shown in FIG. 2, the exterior body 3 has a rectangular shape in which the ventral part F and the dorsal part R are longer in the lateral direction Y than the longitudinal direction X, and the ventral part F and the dorsal part In the crotch portion M located between R, both side edges along the longitudinal direction X of the exterior body 3, that is, a pair of leg edges LS, LS are curved in a convex arc shape toward the center in the lateral direction Y. In a plan view as shown in FIG. 2, the center region in the vertical direction X is constricted inward in the horizontal direction Y to form an hourglass shape.

As shown in FIGS. 3 and 4, the outer body 3 includes an outer layer sheet 31 that forms the outer surface of the diaper 1 in the worn state, that is, the non-skin facing surface, and an inner layer sheet 32 that is arranged to face the skin facing surface of the outer layer sheet 31. It is configured including a laminate of When the diaper 1 is worn, the outer layer sheet 31 is located farther from the wearer's body and forms the non-skin facing surface (outer surface) of the diaper 1, and the inner layer sheet 32 is located closer to the wearer's body. Then, the skin facing surface (inner surface) of the diaper 1 is formed. The outer layer sheet 31 and the inner layer sheet 32 are joined to each other at a predetermined site through a joining means such as an adhesive.

In this embodiment, as shown in FIGS. 2 and 4, the outer layer sheet 31 extends from the longitudinal ends of the inner layer sheet 32 to the ventral side F and the dorsal side R, and the inner layer sheet 32 faces the skin. It has a folded portion 31E that is folded back to the side, and the folded portion 31E covers the end portion of the absorbent body 2 in the longitudinal direction X. As shown in FIG. Although FIG. 4 shows an enlarged longitudinal end of the dorsal portion R and does not show an enlarged view of the ventral portion F, the ventral portion F is configured in the same manner as the dorsal portion R. Unless otherwise specified, the description of the dorsal portion R applies to the ventral portion F as appropriate.

The sheets 31 and 32 forming the exterior body 3 may be sheets of the same type or different types of sheets, and examples of the latter include forms having different stretchability. Specifically, for example, a stretchable sheet having stretchability in the lateral direction Y can be used as the outer layer sheet 31 , and a non-stretchable sheet having no stretchability can be used as the inner layer sheet 32 . Further, for example, the stretchability of the outer layer sheet 31 may be partially different. and the portion of the outer layer sheet 31 located at the crotch portion M is made of a non-stretchable sheet having no stretchability. Examples of the stretchable sheet that can be used as the exterior body 3 include a stretchable sheet in which stretchable fiber layers are integrated on both sides or one side of an elastic fiber layer. Methods of integration include, for example, a method of laminating and hydroentangling the two, a method of entangling fibers by air-through or the like, and a method of bonding by heat embossing, an adhesive, ultrasonic waves, or the like. Non-stretchable sheets that can be used as the exterior body 3 include, for example, nonwoven fabrics produced by various methods, and specific examples include spunbond nonwoven fabrics, air-through nonwoven fabrics, and needle-punched nonwoven fabrics.

As shown in FIGS. 1, 2 and 4, a plurality of thread-like or band-like waist elastic members 33 are arranged in the lateral direction Y in a stretched state in the ventral portion F and the dorsal portion R, respectively. The waist elastic members 33 of the book are intermittently arranged in the vertical direction X at predetermined intervals. Since the waist elastic member 33 is arranged in such a manner that its elastic stretchability is exhibited, the opening edge of the waist opening WH has an annular waist that is substantially continuous over the entire circumference. Gathers are formed. In addition, one or a plurality of thread-like or belt-like leg elastic members 34 for forming leg gathers are arranged in a stretched state at the leg edge LS forming the opening edge of each of the pair of leg openings LH, LH. As a result, substantially continuous annular leg gathers are formed at the opening edges of the pair of leg openings LH, LH. These elastic members 33 and 34 are sandwiched and fixed between the outer layer sheet 31 and the inner layer sheet 32 that constitute the exterior body 3 by a bonding means such as an adhesive.

The diaper 1 has waist flaps WF arranged outward in the longitudinal direction X from the longitudinal ends 24 a of the absorbent core 24 on at least one of the abdominal part F and the back part R. In this embodiment, as shown in FIGS. 1 and 2, waist flaps WF are arranged on both the ventral side F and the dorsal side R. As shown in FIGS. The waist flap WF is a portion of the diaper 1 located outside in the longitudinal direction X of an imaginary straight line VL extending parallel to the lateral direction Y through the longitudinal ends 24a of the absorbent core 24. It is the end portion in the direction X and the portion where the absorbent core 24 (absorbent material) is not arranged. The waist flap WF corresponds to the circumference of the wearer's waist when the diaper 1 is worn.

As shown in FIG. 4, the waist flap WF is mainly composed of the exterior body 3 (the outer layer sheet 31 and the inner layer sheet 32). The waist flap WF has a folded portion 31E of the outer layer sheet 31, and the folded portion 31E is the member closest to the wearer's skin of the diaper 1 in the exterior body 3 of the waist flap WF. As shown in FIG. 2, the folded portion 31E has a shape that is elongated in one direction in a plan view, specifically a rectangular shape, and the longitudinal direction thereof is aligned with the lateral direction Y, and the ventral portion F and the dorsal portion are formed. It is distributed over the full length of each horizontal direction Y of R.

At least one of the waist flap WF of the ventral portion F and the waist flap WF of the back portion R, preferably the latter, and more preferably both, is provided with a sweat absorbing function. More specifically, as shown in FIGS. 1, 2 and 4, at least a portion of the waist flap WF on the side facing the skin is formed of a nonwoven fabric 10 having a sweat absorbing function. The nonwoven fabric 10 is a so-called sweat absorbing sheet. The nonwoven fabric 10 has a shape elongated in one direction, specifically a rectangular shape, in a plan view as shown in FIG. It is In the illustrated example, the nonwoven fabric 10, which is separate from the outer layer sheet 31, is adhered to the skin-facing side of the outer layer sheet 31 in the folded portion 31E, which is the side closest to the wearer's skin. However, the outer layer sheet 31 itself at the folded portion 31E may be made of the nonwoven fabric 10 .

In this embodiment, the nonwoven fabric 10 is joined to the skin-facing surface of the folded portion 31E of the outer layer sheet 31 of the waist flap WF by a known joining means such as adhesive, heat sealing, or ultrasonic sealing. Therefore, the waist flap WF has the nonwoven fabric 10, the folded portion 31E, the inner layer sheet 32, and the outer layer sheet 31 in order from the wearer's skin of the diaper 1. As shown in FIG. In addition, the waist flap WF is stretchable in the lateral direction Y due to having the waist elastic member 33 fixed in the lateral direction Y stretched state between the outer layer sheet 31 and the inner layer sheet 32. have.

FIG. 5 shows the skin-facing surface of the nonwoven fabric 10, that is, the skin-facing surface of the waist flap WF, and FIG. 6 shows a cross section of the nonwoven fabric 10 along the thickness direction. As shown in FIG. 6, the nonwoven fabric 10 has a laminated structure of a hydrophobic fiber layer 11 containing hydrophobic fibers 11F and a hydrophilic fiber layer 12 containing hydrophilic fibers 12F. In this embodiment, the hydrophobic fiber layer 11 and the hydrophilic fiber layer 12 are directly laminated, no other layer is interposed between the layers 11 and 12, and the nonwoven fabric 10 has a two-layer structure. is doing. In addition, the hydrophobic fiber layer 11 is arranged closer to the skin of the wearer of the diaper 1 than the hydrophilic fiber layer 12. More specifically, the hydrophobic fiber layer 11 covers the skin facing surface of the nonwoven fabric 10. ie forming the skin facing surface of the waist flap WF. The hydrophilic fiber layer 12 is interposed between the hydrophobic fiber layer 11 and the folded portion 31E of the outer layer sheet 31 to form the non-skin facing surface of the nonwoven fabric 10 .

The hydrophobic fiber layer 11 is composed mainly of hydrophobic fibers 11F and is hydrophobic. The ratio of the hydrophobic fibers 11F to all constituent fibers of the hydrophobic fiber layer 11 is at least 50% by mass or more, preferably 60% by mass or more, and may be 100% by mass.

The hydrophilic fiber layer 12 is mainly composed of hydrophilic fibers 12F and is hydrophilic. The ratio of the hydrophilic fibers 12F to all constituent fibers of the hydrophilic fiber layer 12 is at least 50% by mass or more, preferably 80% by mass or more, and may be 100% by mass.

In this embodiment, the folded portion 31E of the outer layer sheet 31 to which the nonwoven fabric 10 is fixed has at least a hydrophobic surface (skin facing surface), and is typically made of a nonwoven fabric containing hydrophobic fibers, The entire folded portion 31E is hydrophobic. As the nonwoven fabric constituting the folded portion 31E, nonwoven fabrics produced by various manufacturing methods that can be used as a constituent member of this type of absorbent article can be used without particular limitation, and nonwoven fabrics mainly composed of short fibers (short fiber nonwoven fabrics) may also be used. Alternatively, a nonwoven fabric mainly composed of long fibers (long fiber nonwoven fabric) may be used. The folded portion 31E may be, for example, a short-fiber nonwoven fabric such as an air-through nonwoven fabric, a heat roll nonwoven fabric, a spunlace nonwoven fabric, a needle-punched nonwoven fabric, a chemical-bonded nonwoven fabric, or a long-fiber nonwoven fabric such as a spunbond nonwoven fabric or a meltblown nonwoven fabric.

In the present invention, the hydrophilicity of the fiber is determined based on the contact angle (contact angle with water) measured by the following method. If the contact angle is less than 90 degrees, it is hydrophilic. is hydrophobic. The smaller the contact angle measured by the following method, the higher the hydrophilicity (lower hydrophobicity), and the larger the contact angle, the lower the hydrophilicity (higher hydrophobicity). The hydrophobic fibers 11F, which are the main constituent fibers of the hydrophobic fiber layer 11, have a contact angle of 90 degrees or more as measured by the following method, and the hydrophilic fibers 12F, which are the main constituent fibers of the hydrophilic fiber layer 12, The contact angle is less than 90 degrees.

<Method for measuring contact angle of fiber>
A fiber is taken out from the measurement object (fiber layer), and the contact angle of water with respect to the fiber is measured. As a measuring device, an automatic contact angle meter MCA-J manufactured by Kyowa Interface Science Co., Ltd. is used. Deionized water is used for contact angle measurements. The amount of liquid ejected from an ink-jet type water droplet ejector (Cluster Technology Co., Ltd., Pulse Injector CTC-25 with an ejector hole diameter of 25 μm) is set to 15 picoliters, and water droplets are dropped just above the fibers. The state of dripping is recorded on a high-speed recording device connected to a camera placed horizontally. From the viewpoint of image analysis later, the recorder is preferably a personal computer with a built-in high-speed capture device. In this measurement, an image is recorded every 17 msec. In the recorded image, the first image of water droplets landing on the fiber is captured by the attached software FAMAS (software version is 2.6.2, analysis method is droplet method, analysis method is θ / 2 method, image processing algorithm is non-reflective, the image processing image mode is frame, the threshold level is 200, and no curvature correction is performed. angle. The fiber taken out from the object to be measured is cut into a fiber length of 1 mm, and the fiber is placed on a sample stand of a contact angle meter and maintained horizontally. Two different contact angles are measured for each fiber. N = 5 contact angles are measured to the first decimal place, and the average value of the measured values at a total of 10 points (rounded to the second decimal place) is defined as the contact angle of the fiber with water. The measurement environment is a room temperature of 22±2° C. and a humidity of 65±2% RH.

In the case where the constituent member of the absorbent article (for example, the nonwoven fabric 10 in the diaper 1) contains an object to be measured (for example, fibers), as a method for collecting the object to be measured, the constituent member including the object to be measured is an adhesive. , when it is fixed to another constituent member by fusion or the like, it is necessary to remove the fixation and take out the constituent member including the object to be measured from the absorbent article. If it is not fixed to other constituent members, a method of directly extracting the measurement target from the absorbent article can be adopted. In addition, as a method for releasing the fixation of the constituent members, in the absorbent article, the adhesive or the like used for joining the constituent members including the object to be measured and other constituent members is cooled by a cooling means such as cold spray. A method of carefully peeling off and taking out the component containing the measurement object after weakening is preferred. This extraction method is applied to the measurement of the object to be measured of the present invention, such as the contact angle measurement described above. From the viewpoint of minimizing the effect on the hydrophilizing agent imparted to the constituent members, the method of removing the fixed part should be such as applying a solvent or blowing hot air from a dryer, which may cause deterioration or loss of the oil agent. It is preferable not to employ certain methods.

Hydrophobic synthetic fibers, especially hydrophobic thermoplastic fibers can be used as the hydrophobic fibers 11F. Materials for thermoplastic fibers include, for example, polyolefins such as polyethylene (PE) and polypropylene (PP); polyesters such as polyethylene terephthalate (PET); polyamides such as nylon 6 and nylon 66; polyacrylic acid and polymethacrylic acid alkyl esters. , polyvinyl chloride, polyvinylidene chloride, etc., and these can be used alone or in combination of two or more.

As the hydrophilic fiber 12F, a hydrophilic synthetic fiber, particularly a hydrophilic thermoplastic fiber, can be used. A fiber may be used, or an inherently hydrophobic thermoplastic fiber made of a hydrophobic thermoplastic resin may be subjected to a hydrophilic treatment, and one of these may be used alone or in combination of two or more. can be done. Examples of the latter "hydrophilized thermoplastic fibers" include thermoplastic fibers kneaded with a hydrophilizing agent, thermoplastic fibers having a hydrophilizing agent attached to the surface, and plasma-treated thermoplastic fibers. etc. As the hydrophilizing agent, general hydrophilizing agents (such as various surfactants) used for sanitary products can be used without particular limitation.

Each of the hydrophobic fiber 11F and the hydrophilic fiber 12F may be a single fiber made of one type of synthetic resin or a blend polymer in which two or more types of synthetic resin are mixed, or may be a composite fiber. The composite fiber referred to here is a synthetic fiber obtained by combining two or more types of synthetic resins with different components with a spinneret and spinning them at the same time. It refers to those that are mutually bonded within the fiber. The form of the composite fiber includes core-sheath type, side-by-side type, etc., and is not particularly limited.

The hydrophobic fibers 11F and the hydrophilic fibers 12F may be short fibers (staples) or long fibers (filaments). As used herein, "short fibers" are fibers having a fiber length of less than 80 mm, and "long fibers" are fibers having a fiber length of 80 mm or more.
When the hydrophobic fibers 11F and hydrophilic fibers 12F are short fibers, the fiber length is preferably 30 mm or longer, more preferably 35 mm or longer, and preferably 76 mm or shorter, more preferably 60 mm or shorter.
When the hydrophobic fibers 11F and the hydrophilic fibers 12F are long fibers, the fiber length is preferably 100 mm or more, more preferably 200 mm or more, and preferably 1000 mm or less, more preferably 2000 mm or less.

The nonwoven fabric 10 may be a nonwoven fabric mainly composed of short fibers (short fiber nonwoven fabric) or a nonwoven fabric mainly composed of long fibers (long fiber nonwoven fabric). The ratio of the short fibers or long fibers to the total constituent fibers of the nonwoven fabric 10 is preferably 70% by mass or more, more preferably 100% by mass. Moreover, the manufacturing method of the nonwoven fabric 10 is not particularly limited, and the nonwoven fabric 10 can be manufactured according to a known manufacturing method of nonwoven fabric.

In this embodiment, the hydrophobic fibers 11F and the hydrophilic fibers 12F are short fibers, and the nonwoven fabric 10 (hydrophobic fiber layer 11, hydrophilic fiber layer 12) is a short fiber nonwoven fabric in which all constituent fibers are short fibers. . The nonwoven fabric 10, which is a short fiber nonwoven fabric, is produced by entangling short fibers using a known method such as a carding method or an airlaid method to produce a web, and the constituent fibers (short fibers) of the web are woven together at their intersections. It can be manufactured by heat-sealing. A known method can be used for such a heat-sealing method (non-woven fabric method). For example, as a thermal bonding method, a method of blowing hot air heated to a predetermined temperature onto a web (air-through method), or a method of forming an uneven pattern. There is a method (heat roll method) in which a web is passed between a pair of rolls which are heated to a predetermined temperature and consist of an engraved roll and a smooth roll. The nonwoven fabric 10, which is a staple fiber nonwoven fabric, can be, for example, a thermal bonded nonwoven fabric (air-through nonwoven fabric, heat roll nonwoven fabric, etc.), a spunlace nonwoven fabric, a needle punched nonwoven fabric, or a chemical bonded nonwoven fabric.

In the nonwoven fabric 10, at least a partial area in a plan view as shown in FIG. 5 is a high-density fiber area 13 having a thickness average inter-fiber distance of 50 μm or less, which is obtained by averaging the inter-fiber distances in the thickness direction of the area. The high-density fiber region 13 includes all layers constituting the laminated structure of the nonwoven fabric 10, and in the present embodiment, the portion of the hydrophobic fiber layer 11 located in the high-density fiber region 13 (hereinafter referred to as "fiber height and a portion of the hydrophilic fiber layer 12 located in the high-density fiber region 13 (hereinafter also referred to as a “high-density fiber region-corresponding portion 12a”). The thickness average inter-fiber distance is the inter-fiber distance in the measurement target area when it is assumed that the fibers are uniformly distributed in the thickness direction in a predetermined measurement target area in a plan view of the nonwoven fabric 10, and is measured by the following method. measured.

<Method for measuring thickness average inter-fiber distance>
The thickness average inter-fiber distance is obtained by first measuring the thickness of the nonwoven fabric to be measured, and then applying the measured value of the thickness to the following formula (1).
First, a method for measuring the thickness of the nonwoven fabric to be measured will be described. The nonwoven fabric to be measured is peeled off from the absorbent article such as a diaper using a cold spray or the like, and is removed from the absorbent article. Next, the taken-out nonwoven fabric to be measured is frozen with a cold spray, liquid nitrogen, or the like, and a long side of 25 mm in length parallel to the longitudinal direction of the absorbent article and a long side of the absorbent article parallel to the transverse direction A cut piece of the nonwoven fabric is prepared by cutting into a rectangular shape having a short side of 20 mm in plan view. A plate is placed on the cut piece and a load of 5 g/cm ² is applied, and the thickness of the cut piece is measured. The measurement environment is a temperature of 20±2° C. and a relative humidity of 65±5%, and a microscope (manufactured by Keyence Corporation, VHX-1000) is used as the measuring instrument. Attach the medium-magnification zoom lens tilted at 90°. The cut piece as the measurement sample is set on the measurement stage of the measurement device so that the surface to be measured faces upward and the cut end surface along the vertical direction (longitudinal direction) of the measurement sample can be observed from the horizontal direction. . First, an enlarged photograph of the cut end surface of the cut piece is obtained. In the magnified photograph, an object of known dimensions is photographed at the same time. A scale is adjusted to the enlarged photograph of the cut end surface of the cut piece, and the thickness of the cut piece is measured. The above operation is performed 3 times, and the average value of the 3 times is taken as the thickness [mm] of the cut piece of the nonwoven fabric in a dry state. When the nonwoven fabric to be measured is a laminated product, the thickness is calculated by judging the boundary from the difference in the fiber diameter of the fibers constituting each layer.
Next, using the measured value of the thickness of the nonwoven fabric to be measured, the thickness-average inter-fiber distance of the nonwoven fabric is determined by the formula based on Wrotnowski's assumption. The formula based on Wrotnowski's assumption is generally used when determining the inter-fiber distance of the fibers that make up the non-woven fabric. According to the formula based on Wrotnowski's assumption, the interfiber distance A (μm), the nonwoven fabric thickness h (mm), the basis weight e (g/m ² ), the fiber diameter d (μm) of the fibers constituting the nonwoven fabric, the fiber The density ρ (g/cm ³ ) determines the thickness average inter-fiber distance of the nonwoven fabric by the following formula (1). In the following formula (1), the thickness h (mm) is the measured value of the thickness of the nonwoven fabric to be measured. In addition, the fiber diameter d (μm) is obtained by cutting 10 fibers to be measured in a direction orthogonal to their length direction, and using a scanning electron microscope (DSC6200 manufactured by Seiko Instruments Inc.) for the cut surface of each fiber. The fiber diameter of each fiber is measured by observing the fiber diameter with 1, and the average value of the measured values of the 10 fibers is obtained. In addition, the fiber density ρ (g/cm ³ ) is measured using a density gradient tube according to the density gradient tube method described in JIS L1015 Chemical fiber staple test method (URL is http:// kikakurui.com/l/L1015-2010-01.html, JIS Handbook Textile-2000 for books, (Japanese Standards Association) P.764-765). Further, the basis weight e (g/m ² ) is obtained by cutting a nonwoven fabric to be measured into a predetermined size, for example, a square shape in plan view of 0.12 m × 0.06 m, and measuring the mass of the sample. and calculated by the following formula.
Basis weight e (g/m ² ) = mass of sample / area of sample

In the present embodiment, the high-density fiber region 13 is partially formed in the nonwoven fabric 10 , and the high-density fiber region 13 is a partial region of the nonwoven fabric 10 in plan view. Specifically, as shown in FIG. 5, the high-density fiber regions 13 are intermittently arranged in a pattern in the surface direction of the nonwoven fabric 10 (direction orthogonal to the thickness direction of the nonwoven fabric 10). That is, the high-density fiber regions 13 exist intermittently in the plane direction of the waist flap WF. In the pattern shown in FIG. 5, the high-density fiber regions 13 having a circular shape in a plan view are arranged in a staggered manner in the surface direction of the nonwoven fabric 10, and each of the plurality of high-density fiber regions 13 is the region other than the high-density fiber region 13 (thickness area where the average interfiber distance exceeds 50 μm). The pattern of the high-density fiber regions 13 is not limited to that shown in FIG. It may be curved or the like. Alternatively, for example, a lattice-like pattern in which a plurality of continuous linear high-density fiber regions 13 are arranged to intersect with each other may be used. In addition, since the high-density fiber region 13 is continuous throughout the thickness direction of the nonwoven fabric 10, the surface facing the skin (the surface facing the hydrophobic fiber layer 11) and the non-skin facing surface (the surface facing the hydrophilic fiber layer 12) ), the pattern (planar view shape and arrangement) of the high-density fiber regions 13 is substantially the same.

In a pattern in which the high-density fiber regions 13 exist intermittently in the planar direction of the nonwoven fabric 10, as shown in FIG. area where the distance between them exceeds 50 μm). In general, the shorter the thickness average inter-fiber distance, the smaller the thickness of the region. Therefore, in such a pattern, as shown in FIG. The nonwoven fabric 10 has a thickness difference between the fiber high density region 13 and its peripheral portion. In the embodiment shown in FIG. 6, the portion of the hydrophobic fiber layer 11 located in the high-density fiber region 13 (portion 11a corresponding to the high-density fiber region) corresponds to the hydrophobic fiber in the peripheral portion (region other than the high-density fiber region 13). The portion (portion 12a corresponding to the high-density fiber region) of the hydrophilic fiber layer 12, which is thinner than the layer 11 and located in the high-density fiber region 13, is the peripheral portion (region other than the high-density fiber region 13). ) is thinner than the hydrophilic fiber layer 12 of ).

The high-density fiber region 13 can be formed by compressing, in the thickness direction, a region where the high-density fiber region 13 is to be formed in a nonwoven fabric or its precursor web (a fiber assembly before being made into a nonwoven fabric). can. Compression of such non-woven fabrics or webs is typically performed by pressing accompanied by a melting promoting means (e.g., heat, ultrasonic waves) that promotes melting of the constituent fibers (thermoplastic fibers). It may be carried out by pressing without accompanying. Specific examples of pressing include thermal embossing and ultrasonic embossing. Pressing can be performed, for example, by passing the object to be processed (nonwoven fabric or web) between a pair of processing rolls heated to a predetermined temperature. When smooth rolls with no unevenness on the peripheral surface are used as the pair of processing rolls used in such pressing, it is possible to form a high-density fiber region 13 over the entire processing target, as in the nonwoven fabric 10C shown in FIG. In addition, when one or both of the processing rolls are engraved rolls having an uneven pattern formed on the peripheral surface, the fiber high-density region 13 is formed in a pattern corresponding to the uneven pattern on the processing target. It is possible. When the pressing process is performed on the web, the pressing process may serve both to form the high-fiber region 13 and to convert the web into a non-woven fabric. 13 is formed. The thickness-average inter-fiber distance of the high-density fiber region 13 can be adjusted by appropriately adjusting the pressing conditions, for example, the heating temperature and pressure of the object to be processed during pressing, the conveying speed of the object to be processed, and the like. Depending on the pressing conditions, the form of the high-density fiber region 13 can be a form of a fiber assembly in which the shape of the constituent fibers (hydrophobic fibers 11F, hydrophilic fibers 12F) is maintained, or can be made into a film. It can also be in the form of

In this embodiment, as schematically shown in FIG. 6, the high-density fiber region 13 is made into a film. The term "film formation" as used herein means that the constituent fibers (thermoplastic fibers) of the nonwoven fabric 10 are melted uniformly without any gaps, and the constituent fibers are melted until the fiber shape of the constituent fibers no longer exists, making it difficult for liquid to permeate. It means the state of being. The thickness average inter-fiber distance of the film-formed fiber high-density region 13 is 0 μm. The film-formed high-density fiber region 13 is, for example, a non-woven fabric or a web that is a precursor thereof, and the region where the high-density fiber region 13 is to be formed is the material of the constituent fibers (hydrophobic fibers 11F, hydrophilic fibers 12F). It can be formed by pressing while heating the synthetic resin (thermoplastic resin) at a temperature higher than its melting point.

As shown in FIGS. 5 and 6, the portion of the hydrophobic fiber layer 11 located in the high-density fiber region 13 (portion 11a corresponding to the high-density fiber region), or the fiber height in the plane direction of the nonwoven fabric 10 in the hydrophobic fiber layer 11 The portion adjacent to the high-density region 13 (hereinafter also referred to as “high-density fiber region adjacent portion 11b”) has higher hydrophilicity than other portions of the hydrophobic fiber layer 11 and is more hydrophilic than the hydrophilic fiber layer 12. A skin-side hydrophilic region 14 having a low degree exists. As shown in FIG. 6, the skin-side hydrophilic region 14 in this embodiment exists over both the high-fiber region corresponding portion 11a and the high-fiber region adjacent portion 11b of the hydrophobic fiber layer 11. As shown in FIG. Reference numeral 12b in the drawing denotes a portion of the hydrophilic fiber layer 12 adjacent to the high-density fiber region 13 in the surface direction of the nonwoven fabric 10 (hereinafter also referred to as "high-density fiber region adjacent portion 12b").

The skin-side hydrophilic regions 14 are intermittently present in the planar direction of the nonwoven fabric 10 in the same manner as the high-density fiber regions 13 . That is, a plurality of skin-side hydrophilic regions 14 are discretely present on the skin-facing surface of the hydrophobic fiber layer 11 forming the skin-facing surface of the nonwoven fabric 10 (skin-facing surface of the waist flap WF). In this embodiment, as shown in FIGS. 5 and 6, the high-density fiber regions 13 having a circular shape in a plan view are intermittently present in the surface direction of the nonwoven fabric 10, and the high-density fiber regions 13 of each high-density fiber region A skin-side hydrophilic region 14 having a circular shape in a plan view exists over both the corresponding portion 11a and the fiber-high-density region-adjacent portion 11b. The pattern of the skin-side hydrophilic region 14 is not limited to the illustrated one. For example, the planar shape of the skin-side hydrophilic region 14 is not limited to a circular shape. It may be shaped, linear, curvilinear, or the like.

As described above, the hydrophilicity of the skin-side hydrophilic region 14 is higher than that of other portions of the hydrophobic fiber layer 11 and lower than that of the hydrophilic fiber layer 12 . As will be described later, the hydrophilic fiber layer 12 may have a partially different degree of hydrophilicity. The hydrophilicity of the skin-side hydrophilic region 14 is lower than that of the corresponding portion 12a).

In the present invention, the hydrophilicity of a fiber assembly such as a nonwoven fabric (fiber layer) is determined based on the contact angle (contact angle with water) measured by the following method, and if the contact angle is less than 90 degrees It is hydrophilic, and if it is 90 degrees or more, it is hydrophobic. The smaller the contact angle with water measured by the following method, the higher the hydrophilicity (lower hydrophobicity), and the larger the contact angle, the lower the hydrophilicity (higher hydrophobicity). In the nonwoven fabric 10, as described above, "hydrophilicity of regions other than skin-side hydrophilic region 14 in hydrophobic fiber layer 11<hydrophilicity of skin-side hydrophilic region 14<hydrophilic fiber layer 12 (hydrophilicity of hydrophilic fiber layer 12 If the degrees are partially different, the degree of hydrophilicity of the portion where the degree of hydrophilicity is the lowest)” is established. The contact angle of the region > the contact angle of the skin-side hydrophilic region 14 > the contact angle of the hydrophilic fiber layer 12 (when the hydrophilicity of the hydrophilic fiber layer 12 is partially different, the portion with the lowest hydrophilicity). holds.

<Method for measuring contact angle of fiber assembly>
The fiber layer to be measured (for example, the nonwoven fabric 10) is removed from the absorbent article such as a diaper using a cold spray, etc., and the removed fiber layer is frozen with a cold spray, liquid nitrogen, or the like. In this state, a cutter or the like is used to cut a predetermined shape (for example, a long side of 50 mm in length parallel to the vertical direction of the absorbent article and a short side of 10 mm in length parallel to the horizontal direction of the absorbent article. rectangular shape in plan view) to be used as a measurement sample. In addition, when the measurement object includes a filmed portion (for example, the fiber high-density region 13), if the measurement object is not suitable as a measurement sample for the reason that the filmed portion is too small, it may be filmed. Separately prepare a measurement sample including the portion where the measurement is performed. For example, a hydrophobic fiber layer 11 and a hydrophilic fiber layer 12 having the same configuration as the object to be measured are prepared, and both layers 11 and 12 are heat-fused using a sealer or the like to prepare a measurement sample. The fusion is performed under such conditions that the heat-fused portion forms a film. Then, the contact angle of water with respect to the surface to be measured of the contact angle of the measurement sample (for example, the surface of the hydrophobic fiber layer 11, the hydrophilic fiber layer 12, or the surface of the skin-side hydrophilic region 14) is measured using an automatic contact sensor manufactured by Kyowa Interface Science Co., Ltd. Using a goniometer MCA-J, and using a colored liquid prepared by dissolving 1 mg of Blue No. 1 in 1 L of deionized water as a measurement liquid, measure according to the above <Method for measuring the contact angle of fibers>. do. That is, the colored liquid is dropped on the surface to be measured, the state is recorded on a high-speed recording device, and the recorded image is analyzed to determine the difference between the surface of the droplet of the colored liquid and the surface to be measured. The angle to be formed is calculated and taken as the contact angle. Two different contact angles are measured for each measurement sample. The contact angle of three measurement samples is measured to one decimal place, and the average value of the measured values of a total of six points (rounded to the second decimal place) is defined as the contact angle of the fiber assembly with water. .

The degree of hydrophilicity (contact angle) of each part of the nonwoven fabric 10 can be adjusted by appropriately adjusting the contact angle of the constituent fibers (hydrophobic fibers 11F, hydrophilic fibers 12F) of the part. For example, when the hydrophilic fibers 12F, which are the main constituent fibers of the hydrophilic fiber layer 12, are thermoplastic fibers that have been hydrophilized, the degree of hydrophilization, specifically, for example, the amount of hydrophilizing agent The degree of hydrophilicity (contact angle) of the hydrophilic fiber layer 12 can be adjusted by appropriately adjusting the type and amount used.

As a method for forming the skin-side hydrophilic region 14, for example, i) applying a hydrophilizing agent to the formation planned region (the high-density fiber region corresponding portion 11a and/or the high-density fiber region adjacent portion 11b of the hydrophobic fiber layer 11). and ii) the nonwoven fabric 10 or its precursor web (fiber assembly before being made into a nonwoven fabric) is subjected to a pressing process accompanied by a melting acceleration means such as heat or ultrasonic waves. and a method of melting the fibers (fiber melting method). The skin-side hydrophilic region 14 can also be formed using both i) and ii).

Regarding the above method i), as the hydrophilizing agent, general hydrophilizing agents (such as various surfactants) used for sanitary products can be used without particular limitation. The same kind of hydrophilizing agent as that used in obtaining hydrophilic fibers 12F by hydrophilizing treatment can be used. The method for applying the hydrophilizing agent is not particularly limited, and for example, a known method capable of applying a coating liquid containing the hydrophilizing agent can be used as appropriate. Usable coating methods include, for example, brush coating, gravure coating, flexo coating, and spray coating. The degree of hydrophilicity (contact angle) of the skin-side hydrophilic region 14 can be adjusted by appropriately adjusting the type and amount of the hydrophilizing agent.

The method ii) is the same as the method for forming the high-density fiber region 13 described above. That is, a nonwoven fabric or web containing hydrophobic fibers 11F and a nonwoven fabric or web containing hydrophilic fibers 12F (thermoplastic fibers treated with a hydrophilic agent) are laminated to obtain a laminate, and the laminate is The high-density fiber region 13 is formed by the pressing process, and the portion of the hydrophobic fiber layer 11 located in the high-density fiber region 13 (portion 11 a corresponding to the high-density fiber region) becomes the skin-side hydrophilic region 14 . This is because the hydrophilic fibers 12F in the processed portion are melted by the compression processing of the laminate, and the hydrophilizing agent contained in the hydrophilic fibers 12F diffuses throughout the processed portion. . A portion of the nonwoven fabric or web containing the hydrophobic fiber 11F corresponding to the processed portion is improved in hydrophilicity by the pressing process, and as a result, a skin-side hydrophilic region 14 having a higher degree of hydrophilicity than other portions of the hydrophobic fiber layer 11. (Part 11a corresponding to high-density fiber region).

On the other hand, in the above method ii), the portion corresponding to the processed portion in the nonwoven fabric or web containing the hydrophilic fibers 12F is less hydrophilic than the other portions of the hydrophilic fiber layer 12 as a result of the reduction in hydrophilicity due to the pressing process. May be less hydrophilic. That is, in the nonwoven fabric 10, the hydrophilicity of the hydrophilic fiber layer 12 may be partially different. The degree of hydrophilicity can be lower than that of the other portion (fiber high density region adjacent portion 12b) in the flexible fiber layer 12.

Thus, the method ii) is a method involving the formation of the high-density fiber region 13, and basically, at the same position as the high-density fiber region 13 (portions 11a and 12a corresponding to the high-density fiber region) Since the skin-side hydrophilic region 14 can be formed simultaneously with the formation of the region 13, manufacturing is easy. On the other hand, the method i) is a process separate from the formation of the high-density fiber regions 13 , so that the skin-side hydrophilic regions 14 can be formed at desired positions on the nonwoven fabric 10 . Therefore, according to the method i), that is, the method of applying a hydrophilic agent to the region where the skin-side hydrophilic region 14 is to be formed, the high-density fiber region adjacent portion 11b adjacent to the high-density fiber region 13 in the hydrophobic fiber layer 11 It is easy to form the skin-side hydrophilic region 14 in the . In addition, when the skin-side hydrophilic region 14 is formed by the method i), part of the hydrophilic agent applied to the hydrophobic fiber layer 11 may migrate to the hydrophilic fiber layer 12. A hydrophilizing agent may be present in a portion of the hydrophilic fiber layer 12 corresponding to the skin-side hydrophilic region 14 (a portion overlapping the skin-side hydrophilic region 14 in plan view of the hydrophilic fiber layer 12).

The main features of the nonwoven fabric 10 include the following 1) to 4).
1) It has a hydrophobic fiber layer 11 forming a skin facing surface and a hydrophilic fiber layer 12 laminated so as to be in contact with the non-skin facing surface of the hydrophobic fiber layer 11 .
2) It has a high-density fiber region 13 with a thickness average inter-fiber distance of 50 μm or less.
3) The high-density fiber region corresponding portion 11a and/or the high-density fiber region adjacent portion 11B in the hydrophobic fiber layer 11 has higher hydrophilicity than other portions of the hydrophobic fiber layer 11 and more hydrophilic than the hydrophilic fiber layer 12. A low, skin-side hydrophilic region 14 exists.
4) The skin-side hydrophilic regions 14 exist intermittently in the surface direction of the nonwoven fabric 10 .
Since the nonwoven fabric 10 having the features 1) to 4) forms the side of the waist flap WF facing the skin, the diaper 1 has excellent sweat absorption performance as described below.

That is, in the diaper 1, the skin-facing surface of the waist flap WF, which is in direct contact with the wearer's waist, is formed from the hydrophobic fiber layer 11 of the nonwoven fabric 10, so the skin-facing surface is formed from the hydrophilic fiber layer. Compared to the case where the skin is dry, it is easier to keep the skin dry even after absorbing sweat, so it is possible to reduce discomfort due to stickiness and skin troubles such as eczema, heat rash, and rash.

In addition, the hydrophobic fiber layer 11 of the nonwoven fabric 10 forming the skin-facing surface of the waist flap WF has a low hydrophilicity and is typically hydrophobic, so aqueous liquids such as sweat are less likely to adhere. However, a portion of the hydrophobic fiber layer 11 on the side facing the skin (the high-density fiber region corresponding portion 11a and/or the high-density fiber region adjacent portion 11b) has a higher degree of hydrophilicity than the other portions of the hydrophobic fiber layer 11. There is a skin-side hydrophilic region 14 with a high . That is, on the skin facing surface of the waist flap WF (nonwoven fabric 10), the skin side hydrophilic region 14 with relatively high hydrophilicity (small contact angle) and the skin with relatively low hydrophilicity (large contact angle) The side hydrophilic region 14 is adjacent to the non-arranged region, and a difference in hydrophilicity (contact angle difference) occurs between the two regions. It can preferentially adhere to the skin-side hydrophilic region 14 having a high degree of hydrophilicity and a small contact angle.

As described above, the skin-side hydrophilic region 14 is a portion of the skin-facing surface of the nonwoven fabric 10, that is, the skin-facing surface of the waist flap WF, where sweat can first adhere. As shown in FIG. 5, the skin-side hydrophilic region 14, which is the portion where the Since the degree is low and sweat does not adhere easily, the wearer's skin in contact with the waist flap WF tends to be kept dry.

In general, the capillary pressure of a fiber layer is inversely proportional to the inter-fiber distance of the fiber layer. Capillary pressure is higher than the part. That is, in the hydrophobic fiber layer 11, between the portion located in the high-density fiber region 13 (the high-density fiber region corresponding portion 11a) and the portion adjacent thereto (the high-density fiber region adjacent portion 11b), the former > the latter In the hydrophilic fiber layer 12, the portion located in the high-density fiber region 13 (high-density fiber region corresponding portion 12a) and the portion adjacent thereto (high-density fiber region adjacent portion 12b) There is a capillary pressure difference between the former > the latter. Furthermore, between the hydrophobic fiber layer 11 and the hydrophilic fiber layer 12, due to the difference in hydrophilicity (contact angle), a capillary pressure difference of the former<the latter occurs. The hydrophilic fiber layer 12 has a strong capillary force due to the capillary pressure difference in each part of the nonwoven fabric 10, and the nonwoven fabric 10 moves from the skin facing side (hydrophobic fiber layer 11 side) to the non-skin facing side (hydrophilic The fiber layer 12 side) is excellent in drawing liquid. Therefore, the sweat adhering to the skin-side hydrophilic region 14 on the skin-facing surface of the nonwoven fabric 10 is quickly taken into the interior of the nonwoven fabric 10 by the capillary force of the hydrophilic fiber layer 12, and can be absorbed by the entire hydrophilic fiber layer 12. .

In particular, in the present embodiment, as described above, the high-density fiber regions 13 are filmed, and the thickness average inter-fiber distance of the high-density fiber regions 13 is substantially zero, so the high-density fiber regions 13 are not filmed. The distance between the hydrophilic fiber layer 12 (portion 12a corresponding to the high-density fiber region) and the wearer's skin of the diaper 1, particularly in the high-density fiber region 13, is reduced compared to the case where the constituent fibers maintain their fiber form. The distance is short and the capillary force of the hydrophilic fiber layer 12 is enhanced. Therefore, the diaper 1 of this embodiment is particularly excellent in sweat absorption performance of the waist flap WF.

The magnitude of the "hydrophilicity of the area other than the skin-side hydrophilic area 14 in the hydrophobic fiber layer 11<hydrophilicity of the skin-side hydrophilic area 14<hydrophilicity of the hydrophilic fiber layer 12 (fiber high-density area adjacent portion 12b)" Assuming that the relationship is established, it is preferable to set the contact angle of each portion of the nonwoven fabric 10 as follows.
The contact angle of the hydrophobic fiber layer 11 other than the skin-side hydrophilic region 14 is preferably 80 degrees or more, more preferably 90 degrees or more, and preferably 130 degrees or less, more preferably 120 degrees or less.
The contact angle of the skin-side hydrophilic region 14 is preferably 55 degrees or more, more preferably 60 degrees or more, and preferably 90 degrees or less, more preferably 85 degrees or less.
The contact angle of the hydrophilic fiber layer 12 is preferably 30 degrees or more, more preferably 40 degrees or more, and preferably 70 degrees or less, more preferably 60 degrees or less. As described above, the contact angle (hydrophilicity) of the hydrophilic fiber layer 12 may be partially different. is preferably within the above preferred range. As described above, the portion having the lowest degree of hydrophilicity in the hydrophilic fiber layer 12 tends to become the high-density fiber region corresponding portion 12a.

From the viewpoint of further improving the sweat absorption performance of the nonwoven fabric 10 described above, the thickness average inter-fiber distance of the high-density fiber region 13 is preferably 45 μm or less, more preferably 40 μm or less.
From a similar point of view, the thickness average inter-fiber distance of the high-density fiber region adjacent portion 11b of the hydrophobic fiber layer 11 is longer than that of the high-density fiber region corresponding portion 11a of the hydrophobic fiber layer 11, that is, the "high-density fiber On the premise that the size relationship of thickness average inter-fiber distance of region corresponding portion 11a<thickness average inter-fiber distance of fiber high density region adjacent portion 11b” is established, it is preferably 10 μm or more, more preferably 20 μm or more, and preferably is 60 μm or less, more preferably 50 μm or less. The high-fiber region adjacent portion 11b referred to here is a region within 13 mm in the plane direction of the nonwoven fabric 10 from the high-fiber region corresponding portion 11a (the boundary between the corresponding portion 11a and the adjacent portion 11b).
From a similar point of view, the thickness average inter-fiber distance of the high-density fiber region adjacent portion 12b of the hydrophilic fiber layer 12 is longer than that of the high-density fiber region corresponding portion 12a of the hydrophilic fiber layer 12. On the premise that the size relationship of thickness average inter-fiber distance of region corresponding portion 12a<thickness average inter-fiber distance of fiber high density region adjacent portion 12b” is established, it is preferably 3 μm or more, more preferably 5 μm or more, and preferably is 50 μm or less, more preferably 40 μm or less. The high-fiber region adjacent portion 12b referred to here is a region within 10 mm in the planar direction of the nonwoven fabric 10 from the high-fiber region corresponding portion 12a (the boundary between the corresponding portion 12a and the adjacent portion 12b).

The hydrophilic area 14 on the skin side is preferably within 10 mm, more preferably within 10 mm in the planar direction of the nonwoven fabric 10 from the center of the high-fiber-density area corresponding portion 11a (the portion of the hydrophobic fiber layer 11 located in the high-density fiber area 13) in plan view. is preferably within 4 mm. The reason is as follows.

In the nonwoven fabric 10, as described above, regarding the hydrophilicity, "hydrophilicity of areas other than the skin-side hydrophilic area 14 in the hydrophobic fiber layer 11<hydrophilicity of the skin-side hydrophilic area 14<hydrophilic fiber layer 12 (fiber high-density area A magnitude relationship of "the degree of hydrophilicity of the adjacent portion 12b)" can be established. In the nonwoven fabric 10 provided with such a hydrophilicity gradient, when sweat adheres to the entire skin-side hydrophilic region 14 existing over both the high-fiber region corresponding portion 11a and the high-fiber region adjacent portion 11b, the region The sweat adhering to the portion of the region 14 located at the corresponding portion 11a is absorbed by the adjacent portion 11b and further migrates to the hydrophilic fiber layer 12, whereas the sweat adhered to the portion of the region 14 located at the adjacent portion 11b is absorbed by the adjacent portion 11b. Adhered perspiration is diffused in the surface direction of the nonwoven fabric 10 in the portion of the adjacent portion 11b closer to the corresponding portion 11a and migrates to the hydrophilic fiber layer 12. As shown in FIG. Here, in the distribution of fibers in the high-density-fiber-area-adjacent portion 11b, the number of fibers tends to decrease as the distance from the high-density-area-corresponding portion 12a increases in the planar direction. The fibers become sparse, the distance between the fibers increases, and the capillary force for diffusing the liquid decreases. Therefore, when the area of the skin-side hydrophilic region 14 is relatively large, specifically, for example, when the hydrophilic agent is applied to a relatively wide range of the hydrophobic fiber layer 11 to form the skin-side hydrophilic region 14, In order for the perspiration adhering to the portion of the skin-side hydrophilic region 14 located in the fiber high-density region adjacent portion 11b to migrate quickly to the hydrophilic fiber layer 12, the sweat is diffused in the surface direction in the adjacent portion 11b. Although the adjacent portion 11b has a reduced capillary force, the liquid cannot diffuse to the high density region. Therefore, the liquid is retained on the skin side, and when the retained amount exceeds a certain amount, it cannot be retained and wet back occurs on the skin, making it impossible to keep the skin dry. From the above point of view, considering the diffusion speed, thickness, etc. of a general nonwoven fabric, the skin-side hydrophilic region 14 exists within 10 mm in the plane direction of the nonwoven fabric 10 from the center of the high-fiber-density region-corresponding portion 11a in plan view. is preferred.

In addition, when a child moves a lot, the amount of sweat per minute is about 1.1 mg/min·cm ² , and the specific gravity of sweat is 1 g/cm ³ . If the radius of the region 13 (or the region 13 and its surrounding region) (the distance from the center of the high-fiber-density region corresponding portion 11a in a plan view) is a [cm], when the wearer of the diaper 1 is a child, the region Assuming that the area 14 is not filmed, perspiration produced by the wearer temporarily accumulates in the area 14 . The amount of temporary accumulated sweat is calculated as follows and is 1.1a ² π×10 ⁻³ [cm ³ /min].
a [cm] ² × π × 1.1 [mg/min cm ² ]
= 1.1a ² π [mg/min]
=1.1a ² π×10 ⁻³ [cm ³ /min]
On the other hand, the area per one fiber high-density region 13 is typically 1.5 [mm ² ] or less at maximum. In addition, from the nonwoven fabric 10, a square shape in plan view having a length of 3 cm in the horizontal direction Y and an arbitrary length in the vertical direction X, including the fiber high-density region 13 (skin-side hydrophilic region 14), is cut out and used as a sample. When measuring the Klemm water absorption height of the sample by immersing the part corresponding to the sample and extending 5 mm from the lower end of the sample in deionized water as a test liquid, immediately after immersing the lower end of the sample in deionized water Since the deionized water is sucked up to a minimum height of 10 mm or more, the high-density fiber region 13 has high liquid diffusibility, specifically, it is estimated that the diffusion is possible to double or more. Here, when the thickness of the high-density fiber region 13 is, for example, 0.5 [mm], considering that the region 13 can instantaneously hold liquid twice its volume, the estimated liquid of the region 13 The retention amount is calculated as follows and is 1.5×10 ⁻³ [cm ³ ].
1.5 [mm ² ] × 0.5 [mm] × 2
= 1.5 [mm ³ ]
= 1.5 × 10 ^-3 [cm ³ ]
Then, the entire portion of the nonwoven fabric 10 that overlaps with the skin-side hydrophilic region 14 in plan view (hereinafter also referred to as “skin-side hydrophilic region-existing portion”) is the fiber high density region included in the skin-side hydrophilic region-existing portion. Assuming that the region 13 has the same liquid retention capacity, the radius a [cm] of the region 14 (skin-side hydrophilic region-existing portion) is appropriately changed to calculate the estimated liquid retention amount of the skin-side hydrophilic region-existing portion. Then, it becomes as shown in Table 1 below. As shown in Table 1 below, the amount of sweat accumulated per minute ( A) in Table 1 is 10 times or less the estimated liquid holding amount (B in Table 1) of the region. If the amount of accumulated sweat per minute in the skin-side hydrophilic region-existing portion is within such a range, it is considered that the accumulated sweat can be sufficiently diffused in one minute. More preferably, the skin-side hydrophilic region 14 exists within 4 mm in the planar direction of the nonwoven fabric 10 from the center of the high-fiber-density region corresponding portion 11a in plan view.

The "center of the high-density fiber region corresponding portion 11a" is typically at the same position as the center of the high-density fiber region 13, which is the region including the corresponding portion 11a. The position may differ depending on whether the region 13 is filmed or not.

When the fiber high density region 13 is formed into a film, the region 13 is observed from a plan view using a microscope or the like, and the center of the region 13 is determined. A method for determining the center of the high-density fiber region 13 is not particularly limited, and typically can be appropriately selected according to the planar view shape of the region 13 and the like. For example, if the filmed fiber high-density region 13 whose center should be determined has a circular shape in plan view, the boundary between the region 13 and its peripheral portion (filmed portion and constituent fibers ) and draw a straight line passing through the region 13 with that point as a base point, the longest straight line Let a point be the center of the region 13 . Further, for example, when the filmed fiber high-density region 13 whose center is to be determined has an elliptical shape in plan view, first, draw two parallel lines passing through the ellipse, and then draw the outline of the ellipse from the two parallel lines. A straight line passing through the two centers of each of the portions enclosed by the lines is drawn, and the midpoint of the intersections of the straight line and both parallel lines is taken as the center of the region 13 . Further, for example, when the film-formed fiber high-density region 13 whose center should be determined has a polygonal shape of a triangle or more in a plan view, after drawing the peripheral circle of the polygon, follow the above method of finding the center of the circle. to determine the center of the region 13. Moreover, regardless of the planar view shape of the high-density fiber region 13, the center of the region 13 may be determined using commercially available image analysis software or the like.

When the high-density fiber region 13 is not formed into a film, that is, when the shape of the constituent fibers is maintained, first, the “thinest portion” (thin portion) in the region 13 is determined, and then the thin portion is determined. The center of the portion is determined and the center of the thinned portion is the center of the region 13 . The determination of the center of the thin portion can be performed according to the above-described "Method for determining the center of the high-density fiber region 13". The thin portion can be determined according to the following procedure. First, the nonwoven fabric 10 to be measured is peeled off from the diaper 1 (absorbent article) using a cold spray or the like, and taken out from the diaper 1 . Next, the taken-out nonwoven fabric 10 is frozen with cold spray, liquid nitrogen, or the like, and then stretched along an imaginary straight line extending in the lateral direction Y of the diaper 1 through the high-density fiber region 13 (typically in a plan view). rectangular shape) and cut into predetermined dimensions to produce cut pieces. Then, the cut end face parallel to the lateral direction Y of the cut piece is photographed with an optical microscope or the like, and the thin portion in the high-density fiber region 13 is determined based on the photographed image.

On the other hand, in the hydrophilic fiber layer 12 on the non-skin facing side of the nonwoven fabric 10, the high fiber density region corresponding portion 12a (the portion of the hydrophilic fiber layer 12 located in the high fiber density region 13) corresponds to the corresponding portion 12a ( It is preferably within 10 mm, more preferably within 8 mm in the surface direction of the nonwoven fabric 10 from the center of the high-density fiber region 13). As described above, the high-density fiber region corresponding portion 12a can have a lower hydrophilicity than the other portion (the high-density fiber region adjacent portion 12b) of the hydrophilic fiber layer 12. If the area of the corresponding portion 12a is too large, the liquid diffusion in the hydrophilic fiber layer 12 may be hindered. It is preferable to make it within the above range with reference to (the center of the high-density fiber region 13). The "center of the portion 12a corresponding to the high-density fiber region" can be determined according to the method for determining the "center of the high-density fiber region corresponding portion 11a".

From the viewpoint of further improving the sweat absorption performance of the nonwoven fabric 10 described above, the thickness (substantial thickness) T1 (see FIG. 6) of the high-density fiber region 13 is preferably 0.1 mm or less, more preferably 0.05 mm or less. . Setting the thickness of the high-density fiber region to the upper limit or less is desirable because the inter-fiber distance is reduced and the capillary force for absorbing perspiration is increased. The thickness (substantial thickness) of each part of the nonwoven fabric 10, such as the thickness T1 of the high-density fiber region 13, can be measured according to the method for measuring the thickness of the nonwoven fabric described in <Method for measuring thickness-average distance between fibers>.

As described above, the skin-side hydrophilic regions 14 are intermittently present in the surface direction of the nonwoven fabric 10 as shown in FIG. be able to. From the viewpoint of such balance, the ratio of the total area of the skin-side hydrophilic region 14 to the total area of the skin-facing surface of the nonwoven fabric 10 (skin-facing surface of the hydrophobic fiber layer 11) is preferably 5% or more, more preferably. is 10% or more, and preferably 30% or less, more preferably 25% or less.
The area of one skin-side hydrophilic region 14 is preferably 0.3 mm ² or more, more preferably 0.4 mm ² or more, and preferably 1.5 mm ² or less, more preferably 1.3 mm ² or less.

Further, when the high-density fiber regions 13 exist intermittently in the plane direction of the nonwoven fabric 10 as shown in FIG. is preferably 5% or more, more preferably 12% or more, and preferably 35% or less, more preferably 30% or less.

In addition, when the high-density fiber regions 13 exist intermittently in the surface direction of the nonwoven fabric 10, a square-shaped unit region having a side of 10 mm in plan view is virtually provided at an arbitrary position on the skin-facing surface of the nonwoven fabric 10. In this case, the number of high-density fiber regions 13 included in the unit region is preferably 2 or more, more preferably 4 or more, and preferably 130 or less, more preferably 100 or less. One of the reasons why it is preferable to set the number of the high-density fiber regions 13 per unit region within the above range is based on the perspiration mechanism of children, who are the main wearers of the diaper 1 . That is, since the amount of sweat when a child runs around is about ¹ mg/min·cm In , the sweat accumulated in 1 cm square for 30 seconds becomes a hemispherical droplet with a diameter of about 0.48 mm. This is because dividing the sweat at four points for absorption is effective in preventing the fibers of the hydrophilic fiber layer 12 from becoming hydrophobic due to the absorbed sweat. In addition, when the distribution of Ericsson's sweat glands, which is the starting point of perspiration, is about 130 to 600 per 1 cm ² , the high-density fiber region 13 (region 13 that has lost liquid absorption ability), such as a film, completely covers the sweat glands. From the viewpoint of preventing such an inconvenience, the number of the high-density fiber regions 13 per unit region is set to the above range so that it is equal to or less than the number of sweat glands.

The area of one high-density fiber region 13 is preferably 0.2 mm ² or more, more preferably 0.3 mm ² or more, and preferably 1.5 mm on each of the skin-facing surface and the non-skin-facing surface of the nonwoven fabric 10. ² or less, more preferably 1.3 mm ² or less.
The high-density fiber regions 13 are continuous throughout the thickness direction of the nonwoven fabric 10, and the pattern (shape and arrangement in plan view) of the high-density fiber regions 13 on the skin-facing surface and the non-skin-facing surface are substantially the same. Therefore, the ratio of the area of the high-density fiber regions 13 and the number of unit regions are substantially the same between the skin-facing surface and the non-skin-facing surface.

The apparent thickness T2 (see FIG. 6) of the nonwoven fabric 10 is preferably 5 times or more, particularly 10 times or more, the thickness T1 of the high-density fiber region 13 . The apparent thickness is the thickness of the thickest portion when the nonwoven fabric 10 has an uneven structure and the thickness is partially different when the thickness is measured including the uneven structure. It is different from the actual thickness. That is, the nonwoven fabric 10 preferably has the fiber high density region 13 and a region in which the apparent thickness T2 is five times or more the thickness (substantial thickness) T1 of the fiber high density region 13 in the plane direction. The region having such an apparent thickness T2 is the region other than the high-density fiber region 13 in the nonwoven fabric 10 (the region where the thickness average inter-fiber distance exceeds 50 μm).

In the nonwoven fabric 10, the thickness average fiber-to-fiber distance in the regions other than the fiber high-density region 13 is typically the same as that of the nonwoven fabric used for absorbing body fluids in this type of absorbent article, and the hydrophilic fiber layer 12 A region other than the high-fiber-density region corresponding portion 12a (the portion of the hydrophilic fiber layer 12 located in the high-density fiber region 13) can function as a holding portion for the liquid absorbed by the nonwoven fabric 10. FIG. Therefore, the nonwoven fabric 10 satisfying the size relationship of "apparent thickness T2≧thickness T1×5" has an improved sweat absorption capacity, and such a nonwoven fabric 10 is provided on the side facing the skin of the waist flap WF. According to the diaper 1, even if the wearer sweats a lot in a short time, the sweat can be absorbed and retained in the hydrophilic fiber layer 12, thereby further improving the sweat absorption performance. . Regarding the upper limit of the apparent thickness of the nonwoven fabric 10, the fiber height is set so that the difference between the portion where the nonwoven fabric 10 is placed and the portion where the nonwoven fabric 10 is not placed on the skin-facing surface of the diaper 1 does not lead to chafing or discomfort of the wearer's skin. It is preferably 100 times or less, more preferably 80 times or less, the thickness of the density region 13 . The apparent thickness T2 of the nonwoven fabric 10 can be measured by cutting the nonwoven fabric 10 in its thickness direction and observing the cut surface under magnification with a microscope.

In the present embodiment, as described above, the hydrophobic fibers 11F and the hydrophilic fibers 12F are short fibers, and the nonwoven fabric 10 (hydrophobic fiber layer 11, hydrophilic fiber layer 12) made of these fibers is the short fibers. Since it is a nonwoven fabric, the thickness of the regions other than the high-density fiber regions 13 in the nonwoven fabric 10 (regions where the thickness average inter-fiber distance exceeds 50 μm) compared to the case where the hydrophobic fibers 11F and the hydrophilic fibers 12F are long fibers. tends to grow. In the nonwoven fabric 10, the regions other than the fiber high-density region corresponding portion 12a in the hydrophilic fiber layer 12 function as retention portions for the liquid absorbed by the nonwoven fabric 10, as described above, so the thickness of the region tends to increase. The nonwoven fabric 10, which is a nonwoven fabric, is characterized by having a relatively large liquid absorption capacity. Therefore, even if the wearer of the diaper 1 sweats a lot in a short period of time, the skin-facing side of the waist flap WF of the diaper 1 is made of the nonwoven fabric 10, which is a staple fiber nonwoven fabric. can be absorbed and retained in the nonwoven fabric 10, and the sweat absorption performance can be further improved.

The basis weight (basis weight) of the hydrophobic fiber layer 11 and the hydrophilic fiber layer 12 is preferably 24 g/m ² or more, or more, from the viewpoint of not being bulky while ensuring practically sufficient strength and absorption capacity. It is preferably 28 g/m ² or more, preferably 45 g/m ² or less, more preferably 40 g/m ² or less.

7 to 11 show nonwoven fabrics 10A to 10E, which are other embodiments of the nonwoven fabric forming the skin facing side of the waist flap in the absorbent article of the present invention. In the embodiment to be described later, the constituent parts different from the nonwoven fabric 10 described above will be mainly explained, and the same constituent parts will be denoted by the same reference numerals, and the explanation thereof will be omitted. The description of the nonwoven fabric 10 is appropriately applied to components that are not particularly described.

In the nonwoven fabric 10 described above, the fiber high density region 13 was formed into a film, but in the nonwoven fabric 10A shown in FIG. 12F) is maintained. The high-density fiber region 13 in which the shape of the fiber is maintained is, for example, a non-woven fabric or a web that is a precursor thereof. It can be formed by compressing while heating at a temperature below the melting point of the synthetic resin (thermoplastic resin) that is the material of . Although the nonwoven fabric 10A basically has the same effect as the nonwoven fabric 10, it is preferable that the high-density fiber region 13 is formed into a film from the viewpoint of further improving the sweat absorption performance as described above.

In the non-woven fabric 10B shown in FIG. is not present in the portion adjacent to the high-density fiber region 13 in the plane direction of the nonwoven fabric 10 (high-density fiber region adjacent portion 11b). Such a skin-side hydrophilic region 14 existing only in the high-density fiber region corresponding portion 11a can be formed by the method ii) (method of melting fibers) as described above, and the method i) ( method of applying a hydrophilizing agent). The same effect as the nonwoven fabric 10 is exhibited by the nonwoven fabric 10B.

The nonwoven fabric 10C shown in FIG. 9 has a uniform thickness over its entirety, and both the skin-facing surface and the non-skin-facing surface are flat without irregularities. The term "flat" as used herein means that a cross section along the thickness direction of the nonwoven fabric as shown in FIG. ), draw an imaginary straight line VL1 extending in a direction perpendicular to the thickness direction (surface direction of the nonwoven fabric) through the top of the portion (maximum convex portion) that protrudes most outward in the thickness direction, and draw an imaginary straight line VL1 extending inward in the thickness direction An imaginary straight line VL2 extending in a direction orthogonal to the thickness direction is drawn through the bottom of the most recessed portion (maximum concave portion), and the distance between the two straight lines VL1 and VL2 in the thickness direction is 1 mm or less.

10 C of nonwoven fabrics are the fiber high density area|region 13 as the whole, as shown in FIG. That is, in the nonwoven fabric 10C, all of the hydrophobic fiber layer 11 is the high-fiber region corresponding portion 11a, and all of the hydrophilic fiber layer 12 is the high-fiber region corresponding portion 12a. The skin-side hydrophilic regions 14 exist intermittently in the surface direction of the nonwoven fabric 10C.

The nonwoven fabric 10D shown in FIG. 10 and the nonwoven fabric 10E shown in FIG. They are common in that they have projections and depressions located in regions other than the above (regions where the thickness average inter-fiber distance exceeds 50 μm). That is, both nonwoven fabrics 10D and 10E are common in that the region other than the high-density fiber region 13 is convex on the side opposite to the wearer's skin side (non-skin facing side) of the absorbent article. The high-density fiber region 13 has a relatively small thickness, and the regions other than the high-density fiber region 13 have a relatively large thickness (apparent thickness). Concavities and convexities are formed on the non-skin facing surface of the.

As shown in FIG. 10, the non-woven fabric 10D has unevenness on the non-skin facing surface, whereas the skin facing surface (skin facing surface of the hydrophobic fiber layer 11) does not have unevenness and is flat. is. The meaning of flat here is as described above.

As shown in FIG. 11, the nonwoven fabric 10E has unevenness not only on the non-skin facing surface but also on the skin facing surface. That is, the skin-facing surface of the nonwoven fabric 10E (skin-facing surface of the hydrophobic fiber layer 11) includes recesses located in the high-density fiber regions 13 and regions other than the high-density fiber regions 13 (thickness average fiber-to-fiber distance exceeding 50 μm). region), and has unevenness. That is, in the nonwoven fabric 10E, regions other than the high-density fiber region 13 are convex toward both the skin side and the non-skin side of the absorbent article of the wearer. The concavo-convex pattern (shape and arrangement of concavities and convexities in plan view) on the skin-facing surface of the nonwoven fabric 10E is the same as that on the non-skin-facing surface.

In the non-woven fabrics 10D and 10E, the formation positions of the convex portions on the surface (skin-facing surface, non-skin-facing surface) described above are regions other than the high-density fiber region 13, and the high-fiber region corresponding portion 12a in such a region. As described above, the regions other than (the portion of the hydrophilic fiber layer 12 located in the high-density fiber region 13) function as a holding portion for liquid such as sweat absorbed by the nonwoven fabric 10, and hold the sweat until it evaporates. obtain. The area other than the high-density fiber area 13 of the hydrophilic fiber layer 12 functioning as a retention part for such absorbed sweat is convex toward the non-skin-facing surface side (hydrophilic fiber layer 12 side). Since it is possible to hold it until the sweat evaporates on the side opposite to the skin side, the chances of contact between the wet nonwoven fabric holding the sweat and the skin are reduced, resulting in stickiness caused by sweating while wearing. Discomfort caused by skin irritation and skin troubles such as eczema, heat rash, and rashes can be more effectively reduced.

From the viewpoint of further improving the sweat absorption performance while taking advantage of the effect of the non-skin-facing surface of the non-woven fabric (the non-skin-facing surface of the hydrophilic fiber layer 12) having unevenness, the fiber high-density region In regions other than 13, the thickness of the layer (hydrophilic fiber layer 12) forming the non-skin facing surface is preferably greater than the thickness of the layer (hydrophobic fiber layer 11) forming the skin facing surface. Assuming that the former > the latter, the ratio of the latter to the latter is preferably 1.1 or more, more preferably 1.2 or more, and preferably 5 or less, more preferably 4 or less as the former/latter. The “thickness” referred to here is the thickness of the portion with the largest apparent thickness in the layer (the layer forming the non-skin facing surface or the layer forming the skin facing surface), and usually the top of the convex portion is located. It is the apparent thickness of the part.

In addition to the non-skin facing surface, the non-woven fabric 10E also has unevenness on the skin facing surface. Therefore, in addition to the above-described effects of the unevenness on the non-skin facing surface, other effects can be achieved. That is, the skin-facing surface of the nonwoven fabric 10E can be the skin-facing surface of the waist flap of the absorbent article. The number of contact points with the wearer's skin is reduced, and air permeability between the absorbent article and the wearer's skin is easily ensured, so that the skin is easily kept dry. In addition, since the area of the hydrophilic fiber layer 12 functioning as a perspiration retainer other than the fiber high-density area 13 is convex toward the skin-facing side, sweat absorbed in this area evaporates from the skin-facing side. This also helps keep the skin dry. In addition, since the region of the hydrophilic fiber layer 12 that faces the region other than the high-density skin fiber region 13 in the thickness direction functions as a perspiration retention portion, the hydrophilicity that the liquid is retained by being convex on the skin facing surface side. Since there is a distance between the sexual fiber layer 12 and the skin, the skin is easily kept dry in this respect as well.

In the nonwoven fabric forming the skin-facing side of the waist flap in the absorbent article of the present invention, the region other than the high-density fiber region 13 has a solid structure filled with constituent fibers (see FIGS. 6 to 8). or a hollow structure with a hollow inside. That is, in the nonwoven fabric forming the skin-facing side of the waist flap in the absorbent article of the present invention, the projections forming the irregularities on the surface (skin-facing side, non-skin-facing side) may be solid or hollow.

Embossing, with or without heat, can also be used to create textures on the surface of the nonwoven fabric. Specifically, for example, a nonwoven fabric or a web is passed between a pair of rolls that are heated to a predetermined temperature and consist of an engraved roll on which an uneven pattern is formed and a smooth roll to form unevenness on the surface of the nonwoven fabric. The raised portion of the nonwoven fabric formed by such embossing has a solid structure.
Further, for example, using a first roll having an uneven peripheral surface and a second roll having an uneven peripheral surface that meshes with the uneven shape of the first roll, the meshing portion of both rolls A nonwoven fabric or web is supplied to the surface of the nonwoven fabric to form unevenness. In the nonwoven fabric obtained by such uneven shaping, the portion compressed in the thickness direction by the meshing portion becomes the fiber high density region 13, and the surface of the uncompressed portion is formed with convex portions. A convex portion formed by such uneven shaping has a hollow structure.

Although the present invention has been described above based on its preferred embodiments, the absorbent article of the present invention is not limited to the above embodiments and can be modified as appropriate.
For example, in the diaper 1, the nonwoven fabric 10 is joined to the folded portion 31E of the outer layer sheet 31 as shown in FIG. may be configured.
In addition, in the diaper 1, as shown in FIG. 2, the outer body 3 has a continuous shape extending over the abdominal part F, the crotch part M, and the back side part R, but instead of this, the outer body 3 It may have a split type shape in which the abdominal exterior body, the dorsal exterior body, and the crotch exterior body are separated as separate members.
Configurations different from each other in the plurality of embodiments described above can be changed, replaced, or combined as appropriate.
In addition, the absorbent article of the present invention is not limited to a pants-type disposable diaper such as the diaper 1 described above, but can be applied to general articles used for absorbing bodily fluids. can be applied to

EXAMPLES Hereinafter, the present invention will be described in more detail with reference to Examples, but the present invention is not limited to such Examples.

[Examples 1 to 6 and Comparative Examples 1 to 4]
A hydrophobic fiber layer in which all of the constituent fibers are hydrophobic fibers, and a hydrophilic fiber layer in which all of the constituent fibers are hydrophilic fibers. A layered nonwoven fabric was produced.
In the production of the nonwoven fabric, the nonwoven fabric or its precursor web is subjected to a predetermined pressing process to form a pressed region. When the thickness average inter-fiber distance of the pressed region is 50 μm or less, the pressed region is the high-density fiber region according to the present invention.
In the production of the nonwoven fabric, a portion of the hydrophobic fiber layer, specifically, a portion of the hydrophobic fiber layer located in the region to be pressed (hereinafter also referred to as a “portion corresponding to the region to be pressed”). corresponding to the density region 11a) is hydrophilized, or the portion corresponding to the pressed region and the portion adjacent to the pressed region in the plane direction of the nonwoven fabric in the hydrophobic fiber layer (from the pressed region to the nonwoven fabric A region within 0.2 mm in the surface direction of (hereinafter also referred to as "squeezed region adjacent portion". Corresponding to fiber high density region adjacent portion 11b) was hydrophilized to form a hydrophilized portion. The hydrophilicity (contact angle) of the hydrophilic portion is higher than the other portion of the hydrophobic fiber layer (portion other than the hydrophilic portion) and the hydrophilic fiber layer (the hydrophilicity of the hydrophilic fiber layer is partially different). If the hydrophilicity is lower than the portion where the hydrophilicity is the lowest), the hydrophilic portion is the skin-side hydrophilic region according to the present invention.
The methods for producing the nonwoven fabrics of Examples and Comparative Examples are specifically shown below, and the materials used, production conditions, etc. are shown in Tables 2 and 3 below.

[Method for producing nonwoven fabrics of Examples 1, 2 and 6]
Hydrophobic short fibers are opened by a carding machine and stacked on a conveyer to obtain a web, and hydrophilic short fibers are spread by a carding machine and stacked on the entire surface of the web. After that, embossing was performed under the conditions of a conveying speed of 2 m/min, an oil pressure of 3 MPa, and temperatures of the embossing roll and the smooth roll of 146° C. to form a high-density fiber region and a hydrophilic region on the skin side in a pattern as shown in FIG. A two-layer nonwoven fabric was produced. In such a method for producing a nonwoven fabric, the web is formed into a nonwoven fabric by thermal embossing using a heat roll, and a high fiber density region is formed at the same time as the web is formed into a nonwoven fabric by this thermal embossing.

[Method for producing nonwoven fabrics of Examples 3 to 5]
Hydrophobic short fibers are opened by a carding machine and stacked on a conveyer to obtain a web, and hydrophilic short fibers are spread by a carding machine and stacked on the entire surface of the web. After that, it was formed into a non-woven fabric by a known air-through method to produce an air-through non-woven fabric having a two-layer structure. Then, this air-through nonwoven fabric is subjected to heat embossing, and a coating liquid containing a hydrophilizing agent is applied to one surface (skin-facing surface) of the air-through nonwoven fabric, so that the fiber high-density region and the skin-side hydrophilic region are formed as shown in FIG. A nonwoven fabric having a two-layer structure formed in such a pattern was produced. In the heat embossing, the workpiece (nonwoven fabric) is sandwiched between a pair of aluminum plate-shaped jigs facing each other, and the jig is heated to 120 ° C. while the jig is pressed in a predetermined direction in the thickness direction. This was done by applying pressure for 15 seconds. One of the pair of jigs used had scattered projections on the surface in contact with the workpiece, and the other had scattered recesses corresponding to the projections on the surface in contact with the workpiece. It was formed in the shape of In addition, as the hydrophilizing agent, polyoxyethylene ether potassium phosphate (product name ANHOLEX MP-2K Miyoshi Oil Co., Ltd.) and stearic acid diethanolamide (product name Amisol SDE Kawaken Fine Chemicals Co., Ltd.) are added to the weight ratio of the active ingredient. were mixed at a ratio of 6:4.

[Method for producing nonwoven fabric of Example 7]
Hydrophobic short fibers are opened by a carding machine and stacked on a conveyer to obtain a web, and hydrophilic short fibers are spread by a carding machine and stacked on the entire surface of the web. After that, it was made into a non-woven fabric by an air-through method to produce an air-through non-woven fabric having a two-layer structure. Then, this air-through nonwoven fabric was subjected to ultrasonic embossing to produce a two-layer nonwoven fabric in which the fiber high-density region and the skin-side hydrophilic region were formed in a pattern as shown in FIG. In such a nonwoven fabric manufacturing method, the fiber high density region is formed at the same time as the web is made into a nonwoven fabric by this ultrasonic embossing.

[Method for producing nonwoven fabric of Comparative Example 1]
Hydrophobic short fibers are opened by a carding machine and stacked on a conveyer to obtain a web, and hydrophilic short fibers are spread by a carding machine and stacked on the entire surface of the web. After that, it was formed into a non-woven fabric by a known air-through method to produce an air-through non-woven fabric having a two-layer structure. Then, a coating liquid containing a hydrophilizing agent was applied to one surface (skin-facing surface) of the air-through nonwoven fabric to produce a nonwoven fabric having a two-layer structure in which the skin-side hydrophilic regions were formed in a pattern as shown in FIG. As the hydrophilizing agent, the same hydrophilizing agent used in Examples 3-5 was used.

[Method for producing nonwoven fabrics of Comparative Examples 2 and 4]
Hydrophobic short fibers are opened by a carding machine and stacked on a conveyer to obtain a web, and hydrophilic short fibers are spread by a carding machine and stacked on the entire surface of the web. After that, it was formed into a non-woven fabric by a known air-through method to produce an air-through non-woven fabric having a two-layer structure. Then, this air-through nonwoven fabric is subjected to heat embossing, and a coating liquid containing a hydrophilizing agent is applied to one surface (skin-facing surface) of the air-through nonwoven fabric, so that the fiber high-density region and the skin-side hydrophilic region are formed as shown in FIG. A nonwoven fabric having a two-layer structure formed in such a pattern was produced. The hot embossing is the same as that used in Examples 3-5. Further, as the hydrophilizing agent, the same hydrophilizing agent as used in Examples 3 to 5 was used.

[Method for producing nonwoven fabric of Comparative Example 3]
Hydrophobic short fibers are opened by a carding machine and stacked on a conveyer to obtain a web, and hydrophilic short fibers are spread by a carding machine and stacked on the entire surface of the web. After that, it was formed into a non-woven fabric by a known air-through method to produce an air-through non-woven fabric having a two-layer structure. Then, this air-through nonwoven fabric was subjected to heat embossing to produce a nonwoven fabric having a two-layer structure in which the fiber high-density region and the skin-side hydrophilic region were formed in a pattern as shown in FIG.

A pants-type disposable diaper having the same basic configuration as the diaper 1 described above was produced according to a conventional method. Specifically, the hot melt adhesive bonding each member from a commercially available pants-type disposable diaper (manufactured by Kao Corporation, product name "Mary's Pants Sarasara Air Through M Size", manufactured in 2018) is weakened using a dryer. , a top sheet, a back sheet, and an absorber taken out after disassembly were used, respectively. This absorbent body is obtained by wrapping an absorbent core composed of a mixed pile of fluff pulp and superabsorbent polymer with a core wrap sheet. The non-woven fabric was used to form the skin-facing side of the waist flaps of the abdominal portion and the back portion of the produced underpants-type disposable diapers to obtain diapers of Examples and Comparative Examples.

〔evaluation〕
For the diapers of Examples and Comparative Examples, the sweat absorption performance of the nonwoven fabric on the side facing the skin of the waist flap was measured by the amount of remaining liquid and the amount of retained liquid shown below. The results are shown in Tables 2 and 3 below.

<Method for measuring remaining liquid>
Two acrylic plates each having a square shape in a plan view and having a length of 10 cm, a width of 10 cm, and a weight of 36 g were prepared. One acrylic plate was placed so that one surface was horizontal, and 49 droplets of 1 μL of the test solution were intermittently placed in a 5 cm square area in the center of the one surface with a pipette. Next, the nonwoven fabric to be measured is placed on the acrylic plate so that the surface facing the skin (surface on the side of the hydrophobic fiber layer) faces the acrylic plate so as to cover all the droplets on the acrylic plate, and further the nonwoven fabric. Another acrylic plate was placed on top of this. 60 seconds after placing the acrylic plate on the non-woven fabric, remove the top acrylic plate and the non-woven fabric underneath it, and wipe off the test liquid remaining on the bottom acrylic plate with absorbent paper of a known weight ( Kimwipe (registered trademark)), the weight of the absorbent paper was weighed with an electronic balance, and the weight difference between the measured value and the weight of the absorbent paper before water absorption was calculated, and the amount of liquid remaining in the nonwoven fabric was calculated. . As the amount of remaining liquid is smaller, the nonwoven fabric is evaluated as being superior in water absorption performance, and the diaper is evaluated as being superior in sweat absorption performance of the waist flap.

<Method for measuring liquid retention>
A nonwoven fabric to be measured was cut into a 5 cm x 5 cm square to obtain a sample, and the weight of the sample was measured. A beaker was filled with enough ion-exchanged water to immerse the entire sample, and the entire sample was immersed in the deionized water. After 3 minutes from the start of immersion, remove the sample from the deionized water, weigh the sample with an electronic balance, calculate the weight difference between the measured value and the weight of the sample before immersion, and divide by the area. was taken as the liquid holding amount of the nonwoven fabric. As the liquid retention amount increases, the nonwoven fabric is evaluated as being excellent in water absorption performance, and the diaper is evaluated as being excellent in sweat absorption performance of the waist flap.

As shown in Tables 2 and 3, in each example, the nonwoven fabric forming the skin facing side of the waist flap has a compressed region (fiber high density region) with a thickness average interfiber distance of 50 μm or less. As a result, compared to Comparative Example 1, which does not have the high-density fiber region, and Comparative Example 2, which has a thickness-average fiber-to-fiber distance of the compressed region exceeding 50 μm, the performance was excellent. Further, in each example, the contact angle of the hydrophilized portion of the hydrophobic fiber layer in the nonwoven fabric is smaller than that of the portion other than the hydrophilized portion of the hydrophobic fiber layer and larger than that of the hydrophilic fiber layer. Due to the fact that the size relationship of "hydrophilic fiber layer>hydrophilized portion of hydrophobic fiber layer>portion other than hydrophilic portion of hydrophobic fiber layer" is established, such a size relationship is not established. As compared with Comparative Example 3, the results were excellent in performance. In addition, in each example, the hydrophilized portions of the hydrophobic fiber layer in the nonwoven fabric exist intermittently in the surface direction of the nonwoven fabric. The performance was superior to that of Comparative Example 4 (continuously present in the surface direction).

1 Absorbent article (underpants-type disposable diaper)
F Abdominal part M Crotch part R Back part WF Waist flap 2 Absorbent main body 21 Top sheet 22 Back sheet 23 Absorber 24 Absorbent core 25 Core wrap sheet 3 Exterior body 31 Outer layer sheet 31E Folding part of outer layer sheet 32 Inner layer sheet 10, 10A, 10B, 10C, 10D, 10E nonwoven fabric (sweat absorbing sheet)
11 Hydrophobic fiber layer 11F Hydrophobic fiber 12 Hydrophilic fiber layer 12F Hydrophilic fiber 13 Fiber high density region 14 Skin side hydrophilic region X Vertical direction Y Horizontal direction

Claims (8)

It has a vertical direction corresponding to the front-rear direction of the wearer and a horizontal direction perpendicular to the vertical direction, and has an abdominal portion arranged on the abdomen side of the wearer when worn, and a dorsal portion arranged on the dorsal side of the wearer, and the abdomen. a longitudinally extending absorbent core having a crotch portion positioned between side portions and the dorsal portion, wherein at least one of the ventral portion and the dorsal portion; An absorbent article having waist flaps arranged longitudinally outward from the longitudinal ends of the absorbent core,
At least a portion of the waist flap on the side facing the skin is formed of a nonwoven fabric having a laminated structure of a hydrophobic fiber layer containing hydrophobic fibers and a hydrophilic fiber layer containing hydrophilic fibers, and the hydrophobic fiber layer is It is arranged closer to the wearer's skin than the hydrophilic fiber layer,
At least a partial area of the nonwoven fabric in a plan view is a high-density fiber area having a thickness average inter-fiber distance of 50 μm or less, which is obtained by averaging the inter-fiber distances in the thickness direction of the area,
A high -density fiber region corresponding portion , which is a portion of the hydrophobic fiber layer located in the high-density fiber region, and a fiber height, which is a portion of the hydrophobic fiber layer adjacent to the high-density fiber region in the plane direction of the nonwoven fabric. A skin-side hydrophilic region having a higher hydrophilicity than other portions of the hydrophobic fiber layer and a lower hydrophilicity than the hydrophilic fiber layer is present in the density region adjacent portion ,
The thickness average inter-fiber distance of the fiber high density region adjacent portion is longer than the thickness average inter-fiber distance of the fiber high density region corresponding portion,
The absorbent article, wherein the skin-side hydrophilic regions are intermittently present in the surface direction of the nonwoven fabric. 2. The absorbent article according to claim 1, wherein the apparent thickness of said nonwoven fabric is at least five times the thickness of said high-fiber region. 3. The absorbent article according to claim 1, wherein the thickness of said high fiber density region is 0.1 mm or less. 4. The non-woven fabric according to any one of claims 1 to 3, wherein the non-skin-facing surface of the nonwoven fabric has unevenness comprising concave portions located in the high-fiber region and convex portions located in regions other than the high-fiber region. 1. The absorbent article according to item 1. 5. The absorbent according to claim 4, wherein the skin-facing surface of said non-woven fabric has unevenness comprising recesses located in said high-fiber-density region and protrusions located in regions other than said high-fiber-density region. sexual goods. 6. The absorbent article according to any one of claims 1 to 5, wherein said high fiber density region is formed into a film. The absorbent article according to any one of claims 1 to 6, wherein the hydrophobic fibers and the hydrophilic fibers are staple fibers. A method for manufacturing an absorbent article according to any one of claims 1 to 7,
It has a manufacturing process of the nonwoven fabric, and the manufacturing process of the nonwoven fabric includes:
obtaining a laminate by laminating a first nonwoven fabric or web containing hydrophobic fibers and a second nonwoven fabric or web containing hydrophilic fibers;
forming the high-density fiber region by subjecting the laminate to a pressing process, and applying a hydrophilizing agent to a region of the first nonwoven fabric or web where the hydrophilic region on the skin side is to be formed; A method for manufacturing an absorbent article, comprising:

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