JP7260396B2 - absorbent article - Google Patents

Description

TECHNICAL FIELD The present invention relates to an absorbent article having an absorbent body containing fiber clumps.

Absorbent articles such as disposable diapers and sanitary napkins generally have a topsheet that is relatively close to the wearer's skin and a backsheet that is relatively far from the wearer's skin. , and an absorbent body interposed between the two sheets. Typically, this absorbent is mainly composed of water-absorbing fibers such as wood pulp, and in many cases, it further contains water-absorbing polymer particles.

As a technique for improving the absorbent, for example, Patent Document 1 discloses an absorbent containing thermoplastic resin fibers and cellulose-based water-absorbing fibers, wherein the thermoplastic resin fibers cover the surface of the absorbent on the surface sheet side. and the backsheet-side surface of the absorbent body. According to the absorbent body described in Patent Document 1, the thermoplastic resin fibers function as a skeleton for holding other components of the absorbent body, such as cellulose-based water-absorbent fibers, so it is said to be soft and resistant to twisting. .

Patent Document 2 describes an absorbent body containing a nonwoven fabric piece that includes heat-fusible fibers and is preliminarily bonded to give a three-dimensional structure, and water-absorbing fibers, and the nonwoven fabric piece absorbs Evenly distributed throughout the body. This three-dimensional nonwoven fabric piece is produced by pulverizing the nonwoven fabric into small pieces using a pulverizing means such as a cutter mill method. 3, it has an irregular shape and does not substantially have a portion that can be regarded as a plane. Patent Document 2 describes a preferred form of the absorbent described in the same document, in which pieces of nonwoven fabric are heat-sealed together. According to the absorbent body described in Patent Document 2, since the nonwoven fabric pieces have a three-dimensional structure, voids are formed inside the absorbent body, and the resilience is improved when water is absorbed. As a result, the water absorption performance is improved. It is said that

Patent Document 3 describes a fine web having a relatively dense fine fiber nucleus and fibers or fiber bundles extending outward from the nucleus. can be used as an absorbent body for absorbent articles. This fine web is produced by ripping off or tearing off a raw material sheet such as a nonwoven fabric. substantially do not have

JP 2015-16296 A Japanese Patent Application Laid-Open No. 2002-301105 JP-A-1-156560

In order to enhance the wearing comfort of the absorbent article, it is effective to enhance the cushioning properties of the absorbent core of the absorbent article. It is also believed that the use of absorbents containing fibrous masses, such as the nonwoven pieces and microwebs described in US Pat. However, in the absorbers described in Patent Documents 2 and 3, as described above, the synthetic fiber aggregates contained therein have irregular shapes and are not uniform in shape and size at all. When mixed with water-absorbent fibers such as pulp, it is difficult to obtain a uniform mixture of the two. In addition, since the synthetic fiber aggregates disclosed in these documents are produced by pulverizing nonwoven fabrics mainly composed of synthetic fibers into small pieces, or by tearing off or tearing off, the surfaces are randomly roughened. It is presumed that In an absorbent body containing a large number of such synthetic fiber aggregates with rough surfaces, the synthetic fiber aggregates are entangled with each other with a relatively strong bonding force over the entire surface, resulting in each The degree of freedom of movement of the synthetic fiber assembly is remarkably restricted, the cushioning property and flexibility are insufficient, and gaps through which body fluids pass are difficult to form, resulting in poor liquid absorption.

Accordingly, an object of the present invention is to provide an absorbent article that is excellent in cushioning properties, flexibility and liquid absorbency.

The present invention has a vertical direction corresponding to the front-rear direction of the user and a horizontal direction perpendicular to the vertical direction, and in the vertical direction, a vertical central region including an excretion-section facing portion facing the user's excretion section; An absorbent article comprising an absorbent body divided into a front region arranged on the abdomen side of the user from the central longitudinal region and a rear region arranged on the dorsal side of the user from the central longitudinal region. The absorber contains water-absorbent fibers and fiber clumps containing weakly water-absorbent fibers having lower water absorbency than the water-absorbent fibers, and the fiber clumps or the fiber clumps and the water-absorbent fibers are entangled with each other, and in the absorbent body, the longitudinal central area has a larger basis weight of the water absorbent fibers than the front area and the rear area.

The absorbent article of the present invention is excellent in cushioning properties, flexibility and liquid absorbency.

FIG. 1 is a plan view schematically showing a partly broken surface of a sanitary napkin that is an embodiment of the absorbent article of the present invention, facing the skin (surface sheet side). FIG. 2 is a cross-sectional view schematically showing a section taken along line II of FIG. FIG. 3 is a plan view schematically showing the skin-facing surface side of the absorbent body included in the absorbent article shown in FIG. FIG. 4 is a vertical cross-sectional view schematically showing a II-II cross section of FIG. 3 in one embodiment of the absorbent body according to the present invention. FIG. 5 is a vertical cross-sectional view schematically showing the II-II line cross section of FIG. 3 in another embodiment of the absorbent body according to the present invention. FIG. 6 is a vertical cross-sectional view schematically showing a II-II line cross section of FIG. 3 in still another embodiment of the absorbent body according to the present invention. FIG. 7 is a vertical cross-sectional view schematically showing a II-II line cross section of FIG. 3 in still another embodiment of the absorbent body according to the present invention. FIG. 8 is a vertical cross-sectional view schematically showing a II-II line cross section of FIG. 3 in still another embodiment of the absorbent body according to the present invention. FIG. 9 is a schematic perspective view of one example of a fiber mass according to the present invention. FIG. 10(a) is an electron micrograph (observation magnification of 25 times) of an example of a fiber mass according to the present invention, and FIG. 10(b) is a diagram schematically showing the fiber mass in the electron micrograph.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described based on its preferred embodiments with reference to the drawings. In addition, in the following description of the drawings, the same or similar reference numerals are given to the same or similar parts. The drawings are basically schematic, and the ratio of each dimension may differ from the actual one.

1 and 2 show a sanitary napkin 1 which is one embodiment of the absorbent article of the present invention. The napkin 1 is an article used to absorb bodily fluids such as menstrual blood excreted by its user, that is, the wearer, and comprises an absorbent body 4 having an absorbent core 40 for absorbing and retaining bodily fluids, and the absorbent body 4 . The absorbent body 4 comprises a liquid-permeable topsheet 2 that is arranged on the skin-facing side of the absorbent body 4 and can come into contact with the wearer's skin, and a leak-proof backsheet 3 that is arranged on the non-skin-facing side of the absorbent body 4. do. As shown in FIG. 1, the napkin 1 has a longitudinal direction X corresponding to the wearer's front-back direction and extending from the wearer's abdomen to the dorsal side through the crotch, and a lateral direction Y orthogonal thereto. In addition, in the longitudinal direction X, a longitudinal central region M including an excretory part facing part (excretion point) facing the wearer's excretory part such as the vaginal opening, and the wearer's ventral side (front side) from the longitudinal central region M and a rear area R arranged on the back side (rear side) of the wearer from the longitudinal center area M.

As used herein, the term “skin-facing surface” refers to the surface of the absorbent article or its constituent members (for example, the absorbent body 4) that faces the wearer's skin when the absorbent article is worn, i.e. The "non-skin facing surface", which is the side close to the skin, is the side of the absorbent article or its constituent members opposite to the skin side when the absorbent article is worn, that is, the side relatively far from the wearer's skin. It is an aspect that can be 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 napkin 1, as shown in FIG. It has a pair of extending wing portions 5W, 5W. The absorbent main body 5 is a main part of the napkin 1, comprises the topsheet 2, the backsheet 3 and the absorbent body 4, and has a front region F, a longitudinal central region M and a rear region R in the longitudinal direction X. It is divided into three. The absorbent main body 5 is a portion that overlaps the absorbent body 4 in plan view of the napkin 1 (projection view in the thickness direction).

When the absorbent article has wings such as the napkin 1, the longitudinal central region of the absorbent article of the present invention has wings in the longitudinal direction (longitudinal direction, X direction in the drawing) of the absorbent article. Taking the napkin 1 as an example, it is a region sandwiched between the root of one wing 5W along the longitudinal direction X and the root of the other wing 5W along the longitudinal direction X. In addition, in the napkin 1, the pair of wing portions 5W, 5W are formed symmetrically with respect to the longitudinal center line extending in the longitudinal direction X by dividing the napkin 1 in the lateral direction Y. One wing portion 5W The root on the side closer to the front region F of the wing and that of the other wing portion 5W are located at the same position in the longitudinal direction X. As shown in FIG. In addition, the longitudinal central region of an absorbent article having no wing portions (for example, a disposable diaper) corresponds to a region located in the middle when the absorbent article is vertically divided into three equal parts.

As shown in FIG. 2, the surface sheet 2 covers the entire skin-facing surface of the absorbent body 4 . On the other hand, the back sheet 3 covers the entire non-skin-facing surface of the absorbent body 4, and further extends outward in the lateral direction Y from both side edges along the longitudinal direction X of the absorbent body 4, together with side sheets 6 to be described later. It forms a side flap part. The side flap portion is a portion of the napkin 1 made of a member extending outward in the horizontal direction Y from the absorbent body 4 . The back sheet 3 and the side sheets 6 are joined to each other at the extending portions from both side edges along the longitudinal direction X of the absorbent body 4 by a known joining means such as adhesive, heat sealing, ultrasonic sealing, or the like. Each of the top sheet 2 and the back sheet 3 and the absorbent body 4 may be joined with an adhesive. As the surface sheet 2 and the back sheet 3, various materials conventionally used for absorbent articles such as sanitary napkins can be used without particular limitation. As the surface sheet 2, for example, a liquid-permeable single-layer or multi-layer nonwoven fabric can be used, and examples of the nonwoven fabric include carded nonwoven fabrics, spunbond nonwoven fabrics, meltblown nonwoven fabrics, spunlaced nonwoven fabrics, and needles. A punched nonwoven fabric can be exemplified. The nonwoven fabric forming the surface sheet 2 may be subjected to hydrophilization treatment using a hydrophilizing agent such as a surfactant. The back sheet 3 is a sheet having a leakproof property, that is, a liquid-impermeable (liquid-impermeable property) or a liquid-impermeable (liquid-impermeable property, although not liquid-impermeable). can be used, for example, a moisture-permeable resin film can be used.

As shown in FIG. 1 , the side flap portions protrude greatly outward in the lateral direction Y in the longitudinal central region M, so that a pair of side flap portions are provided on both left and right sides along the longitudinal direction X of the absorbent body 5 . Wing portions 5W, 5W are extended. The wing portion 5W has a substantially trapezoidal shape in which the lower base (longer side than the upper base) is located on the side portion side of the absorbent main body 5 in plan view as shown in FIG. is provided with a wing adhesive portion (not shown) as fixing means for fixing the wing portion 5W to clothes such as shorts. In addition, since the wing portion 5W is folded back to the non-skin facing surface (outer surface) side of the crotch portion of clothing such as shorts, the non-skin facing surface of the wing portion 5W, which is the surface on which the wing adhesive portion is formed, is , when in use, is oriented toward the wearer's skin and forms a skin-facing surface. In addition, on the non-skin facing surface of the absorbent body 5, that is, the non-skin facing surface of the back sheet 3, a body adhesive portion (not shown) is provided as a fixing means for fixing the napkin 1 (absorbent body 5) to clothes such as shorts. ) is provided. The wing adhesive portion and the main body adhesive portion are each covered with a release sheet (not shown) made of film, nonwoven fabric, paper, or the like before use. In addition, on both sides along the longitudinal direction X of the skin-facing surface of the absorbent main body 5, that is, the surface facing the skin of the topsheet 2, a pair of absorbents are provided so as to overlap the left and right sides along the longitudinal direction X of the absorbent body 4 in plan view. are arranged over substantially the entire length of the absorbent main body 5 in the longitudinal direction X. As shown in FIG. The pair of side sheets 6, 6 are joined to other members such as the topsheet 2 by a known joining means such as an adhesive at joining lines (not shown) extending in the longitudinal direction X, respectively.

As shown in FIGS. 1 and 3, the absorbent body 4 extends over substantially the entire length of the napkin 1 (absorbent main body 5) in the longitudinal direction X, and extends from the front region F to the rear region R via the longitudinal central region M. are doing. By being incorporated into an absorbent article such as the napkin 1, the absorbent body 4 is indirectly applied to the human skin, that is, indirectly applied to the skin via members such as the top sheet 2 and the back sheet 3. The skin-facing surface 45 is arranged at a position relatively close to the skin of the user, ie, the wearer of the napkin 1 when in use, and the surface 45 is arranged at a position relatively far from the skin of the wearer. and a non-skin facing surface 46 .

In the napkin 1 , the absorbent body 4 includes a liquid-absorbing absorbent core 40 and a liquid-permeable core wrap sheet 41 covering the surface of the absorbent core 40 . Like the absorbent main body 5 , the absorbent core 40 has a shape elongated in the longitudinal direction X in plan view as shown in FIG. , and the width direction of the absorbent core 40 coincides with the lateral direction Y of the napkin 1 . As shown in FIG. 1, the absorbent body 4 (absorbent core 40) extends over substantially the entire length of the napkin 1 (absorbent main body 5) in the longitudinal direction X, and extends from the front region F to the rear region R via the longitudinal central region M. extends across. The absorbent core 40 and the core wrap sheet 41 may be joined with an adhesive such as a hot-melt adhesive.

The core wrap sheet 41 may be 1) composed of only one sheet, or 2) may be composed of a plurality of sheets. The core wrap sheet 41 of 1) is, for example, one continuous sheet having a width of two to three times the length of the absorbent core 40 in the lateral direction Y, and the absorbent core 40 faces the skin. It covers the entire surface and extends outward in the lateral direction Y from both side edges along the longitudinal direction X of the absorbent core 40, and the extending portion is rolled down below the absorbent core 40 to absorb It covers the entire non-skin facing surface of the core 40 . The core wrap sheet 41 of 2) is, for example, one skin-side core wrap sheet that covers the skin-facing surface of the absorbent core 40, and a skin-side core wrap sheet that is separate from the absorbent core 40. It is composed of two sheets, one of which is a non-skin side core wrap sheet covering the non-skin facing surface.

The absorbent core 40 can be said to be substantially the absorbent body 4 itself, and unless otherwise specified, the following description of the absorbent core 40 is appropriately applied as the description of the absorbent body according to the present invention. The absorbent body according to the present invention includes a form composed only of an absorbent core without a core wrap sheet, and in such a form, the absorbent body and the absorbent core have the same meaning. .

The material (core-forming material) forming the absorbent core 40 includes at least the absorbent fibers 12F and the fiber mass 11 containing the fibers 11F. In the absorbent core 40 of this embodiment, the water absorbent polymer 13 is further included as a core forming material. The constituent fibers 11F of the fiber mass 11 are weakly absorbent fibers having lower water absorption than the absorbent fibers 12F.

As used herein, the term "fiber mass" refers to a fiber aggregate in which a plurality of fibers are bundled together. The fiber mass used in the present invention may be a fiber aggregate of a fixed shape, such as a sheet piece obtained by cutting a synthetic fiber sheet having a certain size with a cutter or the like, regardless of its manufacturing method, or It may also be an amorphous fiber assembly produced by pulverizing, ripping off, or tearing off a nonwoven fabric mainly composed of synthetic fibers, such as the nonwoven fabric pieces disclosed in the above-mentioned patent documents. In the present invention, the absorbent core may i) contain only fixed-shaped fiber aggregates as the fiber mass, ii) may contain only irregular-shaped fiber aggregates as the fiber mass, or iii) may contain only the amorphous fiber mass as the fiber mass. Although a form in which fixed-shaped fiber aggregates and irregular-shaped fiber aggregates are mixed may be used, the above-mentioned form i) is preferably used. In the irregularly shaped fiber assembly, since the constituent fibers are randomly oriented, the surface is rough such that the fibers protrude from here and there on the surface. There is a risk of entanglement, and as a result, the degree of freedom of movement of each fiber assembly is restricted, resulting in reduced flexibility. The fiber clump 11 of this embodiment is a fixed-shaped fiber aggregate as described later.

As described above, the fiber mass 11 is a fiber assembly in which a plurality of fibers 11F are aggregated and integrated, and a plurality of the fiber masses 11 are present in the absorbent core 40 while maintaining their shape. The fiber mass 11 mainly contributes to improvement of the flexibility, cushioning properties, compression recovery properties, and shape retention properties of the absorbent core 40 due to the form of the fiber assembly.

A plurality of water-absorbent fibers 12F are present in the absorbent core 40, and although the plurality of water-absorbent fibers 12F can be entangled with each other, they are not aggregated like the constituent fibers 11F of the fiber mass 11, and are individually independent. preferably present in The water absorbent fibers 12F mainly contribute to improving the liquid absorbency of the absorbent core 40 and also contributes to improving the shape retention of the absorbent core 40 .

As the water-absorbing fibers 12F, water-absorbing fibers conventionally used as a material for forming the absorbent body of this type of absorbent article can be used. Examples of water-absorbent fibers include wood pulp such as softwood pulp and hardwood pulp, natural fibers such as non-wood pulp such as cotton pulp and hemp pulp; modified pulp such as cationized pulp and mercerized pulp. These 1 type can be used individually or in mixture of 2 or more types. Considering that the main role of the absorbent fibers 12F is to improve the liquid absorbency of the absorbent body 4, cellulosic fibers are preferable as the absorbent fibers 12F.

A plurality of water-absorbing polymers 13 are present in the absorbent core 40 as small pieces of water-absorbing polymer, and mainly contribute to the improvement of the liquid absorbency in the absorbent core 40 . The shape of the pieces of the water-absorbent polymer 13 is not particularly limited, and may be, for example, spherical, massive, bale-shaped, fibrous, or irregular. The average particle size of the water absorbing polymer 13 is preferably 10 μm or more, more preferably 100 μm or more, and preferably 1000 μm or less, more preferably 800 μm or less. As the water absorbing polymer 13, generally, a polymer or copolymer of acrylic acid or an alkali metal salt of acrylic acid can be used. Examples thereof include polyacrylic acid and its salts and polymethacrylic acid and its salts. Specifically, acrylic acid polymers such as Aqualic CA and Aqualic CAW (both manufactured by Nippon Shokubai Co., Ltd.) Partial sodium salts are included.

In the absorbent core 40, not only are the plurality of fiber clumps 11 and the water absorbent fibers 12F mixed together, but also the fiber clumps 11 are entangled with each other or the fiber clumps 11 and the water absorbent fibers 12F are entangled. That is, in the absorbent core 40, a plurality of fiber lumps 11 are combined by entanglement with constituent fibers (fibers 11F, 12F) in the absorbent core 40 to form one fiber lump continuum. Further, the plurality of fiber clumps 11 may be entangled with each other, and the fiber clumps 11 and the absorbent fibers 12F may be entangled and bonded. Furthermore, usually, a plurality of water absorbent fibers 12F are also entangled with each other. At least some of the plurality of fiber lumps 11 contained in the absorbent core 40 are entangled with other fiber lumps 11 or water absorbent fibers 12F. In the absorbent core 40, all of the plurality of fiber lumps 11 contained therein may be entangled with each other to form one fiber lump continuum. It is possible that they are mixed in the state of combination.

In the absorbent core 40, in addition to containing the fiber clumps 11 capable of increasing the flexibility of the absorbent core 40, the fiber clumps 11 are entangled with each other or between the fiber clumps 11 and the water absorbent fibers 12F. Since the absorbent core 40 is bonded, the absorbent core 40 is more excellent in responsiveness to external force, and is excellent in flexibility, cushioning property, and compression recovery property. The absorbent core 40 deforms flexibly against external forces received from various directions when the napkin 1 is worn (for example, the body pressure of the wearer of the napkin 1), and the napkin 1 can be brought into close contact with the wearer's body with good fit. . Such excellent deformation-recovery characteristics of the absorbent core 40 can be exhibited not only when the absorbent core 40 is compressed but also when twisted. That is, since the absorbent core 40 incorporated in the napkin 1 is sandwiched between the thighs of the wearer when the napkin 1 is worn, it is Movement of the thighs may cause twisting around a virtual axis of rotation extending in the longitudinal direction X. The napkin 1 can be easily deformed and recovered from an external force that promotes twisting from the body, and therefore, it is difficult to twist, and the napkin 1 can be given a high fit to the wearer's body.

In the absorbent core 40, the fiber lumps 11 or the fiber lumps 11 and the water-absorbing fibers 12F are entangled. be done.
Form A: A form in which the fiber clumps 11 and the like are bonded by entanglement of the constituent fibers 11F of the fiber clumps 11 rather than fusion bonding.
Mode B: In the natural state of the absorbent core 40 (the state in which no external force is applied), the fiber clumps 11 and the like are not bonded together, but in the state in which the absorbent core 40 is subjected to an external force, the fiber clumps 11 and the like are bonded together. A configuration in which the constituent fibers 11F can be bound by entanglement with each other. Here, "a state in which an external force is applied to the absorbent core 40" means, for example, that the absorbent core 40 has It is in a state where deformation force is applied.

As described above, in the absorbent core 40, the fiber clumps 11 are connected to other fiber clumps 11 or the water-absorbing fibers 12F by entanglement, ie, "entangling", as in the form A. Like B, it also exists in a state where it can be entangled with other fiber clumps 11 or water absorbent fibers 12F. Such binding by entangling the fibers is one of the important points for more effectively exhibiting the function and effect of the absorbent core 40 described above. In particular, the absorbent core 40 preferably has form A of "entanglement" in terms of shape retention. Bonding by fiber entanglement does not have an adhesive component or fusion, and is made only by entanglement of fibers. The degree of freedom of movement of the fiber 12F) is high, so that its individual elements can move within a range that maintains their integrity as an assembly composed of them. In this way, the absorbent core 40 is deformed when receiving an external force because the plurality of fiber clumps 11 contained therein or the fiber clumps 11 and the absorbent fibers 12F are relatively loosely connected. It has a gentle shape retention that is possible, and has a high level of shape retention, cushioning property, compression recovery property, and the like. The napkin 1 having such a high-quality absorbent core 40 fits tightly to the wearer's body and is comfortable to wear.

It is not necessary that all of the bindings via the fiber lumps 11 in the absorbent core 40 are "entangled", and a part of the absorbent core 40 includes other bindings other than entangling, such as bonding with an adhesive. may be However, for example, the absorbent core 40 or the absorbent body 4 including the same may be subjected to compression processing such as embossing so that the skin-facing surface 45 and/or the non-skin-facing surface 46 of the absorbent core 40 is provided with leak-proof grooves. (for example, a surface recessed portion 7 to be described later) is formed, the fiber mass 11 or the fiber mass 11 and the water-absorbing fibers 12F are melted in the portion of the absorbent core 40 that overlaps the recessed portion in a plan view. However, at least one of the bonding between the fiber lumps 11 and the bonding between the fiber lumps 11 and the water absorbent fibers 12F in the portions of the absorbent core 40 other than the portion (the portion not subjected to the pressing process) , and preferably both are made only by "entanglement of fibers".

From the viewpoint of more reliably exerting the action and effect of the absorbent core 40 described above, the form A, "the fiber lumps 11 bound by entangling" and the form B, "the fiber lumps 11 in a state where they can be entangled" are used. is preferably half or more, more preferably 70% or more, still more preferably 80% or more of the total number of fiber lumps 11 in the absorbent core 40 .
From a similar point of view, the number of fiber lumps 11 having "entanglement" of form A is 70% or more, particularly 80% or more of the total number of fiber lumps 11 having bonding portions with other fiber lumps 11 or water-absorbent fibers 12F. Preferably.

The absorbent core 40 is characterized in terms of the placement of the core-forming material, including the absorbent fibers 12F. That is, in the absorbent core 40, the longitudinal central region M has a larger basis weight of the water absorbent fibers 12F (mass per unit area of the water absorbent fibers 12F) than the front region F and the rear region R. That is, in the absorbent core 40, regarding the basis weight of the water-absorbing fibers 12F, there is established a size relationship of "longitudinal center region M>front region F, rear region R".

The longitudinal central region M is a region that includes the excretory portion facing portion (excretion point), and body fluids such as menstrual blood excreted from the excretory portion of the wearer of the napkin 1 are disposed earlier than the front region F and the rear region R. Since the absorbent body 4 in the longitudinal central region M is a region that receives body fluids, it is desired that the absorbent core 4 has excellent liquid drawing property and quickly absorbs body fluids into the absorbent core 40 . Among the core-forming materials contained in the absorbent core 40, the water-absorbent fibers 12F are most likely to contribute to the improvement of the liquid drawing property, and the fiber lumps 11 do not contribute much to the improvement of the liquid drawing property. Therefore, in the napkin 1, the above relationship is established with respect to the basis weight of the water absorbent fibers 12F, and the basis weight of the water absorbent fibers 12F in the longitudinal central region M is made larger than that in the front and rear regions F, R. Therefore, the napkin 1 can quickly absorb bodily fluid excreted by the wearer, and has excellent fluid absorbency.

Further, in the absorbent core 40, the basis weight of the water-absorbent fibers 12F is satisfied by the above-described magnitude relationship of "longitudinal center region M>front region F, rear region R". In addition to "improvement of wearing feeling". That is, by establishing the size relationship, the absorbent core 40 in the longitudinal central region M, in which the basis weight of the water absorbent fibers 12F is relatively large, has a relatively large thickness and excellent cushioning properties. The absorbent core 40 in the front region F and the rear region R, in which the basis weight of the water absorbent fibers 12F is relatively small, is relatively thin and highly flexible. Therefore, when the napkin 1 is worn, the bulky and cushioning longitudinal center region M is in close contact with the wearer's excretory part and its surroundings, and the front region F and the rear region R of the thin and flexible napkin 1 are. , Fits in clothes such as shorts, and follows the movement of the wearer's ventral side and back side (buttocks side). is reduced. In addition, as described above, the absorbent core 40 is entangled with each other or between the fiber lumps 11 and the water-absorbing fibers 12F. In addition, in the absorbent core 40 having such excellent physical properties, the feeling of wearing can be further improved by establishing the above-described size relationship with respect to the basis weight of the water-absorbing fibers 12F.

From the viewpoint of ensuring that the effects of the uneven distribution of the water-absorbing fibers 12F described above are exhibited more reliably, the basis weight of the water-absorbing fibers 12F of the absorbent core 40 in the longitudinal central region M, the front region F and the rear region R and the basis weight of the water-absorbing fibers 12F is preferably 1.1 or more, more preferably 1.2 or more as the former/latter, on the premise that the former > the latter.
On the premise that the basis weight of the water-absorbing fibers 12F of the absorbent core 40 in the longitudinal central region M is larger than that of each of the front region F and the rear region R, it is preferably 50 g/m2 or ^more , more preferably 80 g/m2. m ² or more, and preferably 640 g/m ² or less, more preferably 480 g/m ² or less.
On the premise that the basis weight of the water absorbent fibers 12F in each of the front region F and the rear region R is smaller than that of the longitudinal central region M, it is preferably 580 g/m ² or less, more preferably 430 g/m ² or less. , 0 g/m ² .

In the absorbent core 40, on the premise that the basis weight of the water-absorbent fibers 12F satisfies the above-described size relationship of "longitudinal center region M>front region F, rear region R", the core-forming materials (fiber lumps 11, The absorbent fibers 12F and the absorbent polymer 13) may be distributed in any way. For example, the fiber clumps 11 and the absorbent fibers 12F may be uniformly distributed over the entire absorbent core 40, or the fiber clumps 11 may be unevenly distributed in a part of the absorbent core 40. In the latter case, the fiber clumps 11 may be unevenly distributed in a part of the absorbent core 40 in the plane direction (for example, any one or two of the front area F, the longitudinal central area M and the rear area R). , may be unevenly distributed in a part of the thickness direction of the absorbent core 40 (for example, the side of the skin-facing surface 45 or the side of the non-skin-facing surface 46). In addition, the “skin-facing surface 45 side” referred to here means that the absorbent core 40 (absorbent body 4) in the relevant region (for example, the front region F, the longitudinal central region M, or the rear region R) is divided into two equal parts in the thickness direction. The "non-skin facing surface 46 side" is a portion near the non-skin facing surface 46 in such a case.

FIGS. 4 to 8 show absorbent bodies 4A to 4E, which are embodiments of absorbent bodies that can be employed in the present invention. Concerning the absorbers 4A to 4E, the constituent parts different from those of the absorber 4 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 absorbent body 4 is appropriately applied to the components of the absorbent bodies 4A to 4E that are not specifically described. In addition, hereinafter, the absorbent bodies according to the embodiments of the present invention, such as the absorbent bodies 4A to 4E, are collectively referred to as the "absorbent body 4".

In the absorbent body 4A shown in FIG. 4, the core-forming materials (fiber mass 11, water-absorbing fibers 12F, water-absorbing polymer 13) are uniformly distributed over the entire absorbent core 40. As shown in FIG. On the other hand, in each of the absorbers 4B to 4E shown in FIGS. 5 to 8, the fiber clumps 11 or the absorbent fibers 12F are unevenly distributed in a part of the absorbent core 40. FIG. However, the absorbers 4A to 4E are common in that the basis weight of the water-absorbing fibers 12F in the absorbent core 40 satisfies the aforementioned size relationship of "longitudinal center region M>front region F, rear region R".

In the absorbent body 4B shown in FIG. 5, the non-skin facing surface 46 side of the absorbent core 40 is mainly composed of the fiber lumps 11, and the fiber lump occupation ratio described later is preferably 50% by mass or more, more preferably 90% by mass. The above-described portions (hereinafter also referred to as “fiber lump rich portions”) continuously extend over the entire length of the absorbent core 40 in the longitudinal direction X, and the basis weight of the fiber lumps 11 is the front region F, The vertical center region M and the rear region R are substantially the same. In the absorbent body 4B, the absorbent cores 40 in the front region F and the rear region R are respectively the fiber mass rich region as a whole, and the skin facing surface 45 side is mainly composed of the water absorbent fibers 12F, and the fiber mass The portion having a occupancy rate of preferably less than 50% by mass, more preferably 10% by mass or less (hereinafter also referred to as “water-absorbing fiber-rich portion”), and the non-skin facing surface 46 side is the fiber mass-rich portion. In the absorbent body 4B, the absorbent core 40 in the longitudinal central region M has the water-absorbing fiber-rich portion on the skin-facing surface 45 side, and the fiber mass-rich portion on the non-skin facing surface 46 side. In addition, in the absorbent body 4B, the water-absorbing polymer 13 may be unevenly distributed in the water-absorbent fiber-rich region, and may not be contained in the fiber mass-rich region.

An absorbent body 4C shown in FIG. 6 is the same as the absorbent body 4B shown in FIG. 5 except that the absorbent cores 40 in the front region F and the rear region R are the water absorbent fiber rich regions. In the absorbent body 4C, the basis weight of the fiber clumps 11 is the largest on the non-skin facing surface 46 side of the longitudinal central region M, and on the front region F, the rear region R, and the skin facing surface 45 side of the longitudinal central region M , respectively, contain little fiber mass 11 and may have a basis weight of fiber mass 11 of zero. Therefore, in the absorbent body 4C, the fiber clumps 11 are unevenly distributed in the longitudinal central region M in the longitudinal direction X, and in the longitudinal central region M, they are unevenly distributed on the side of the non-skin facing surface 46, and the water-absorbent fibers are centrally located in the longitudinal direction. It is unevenly distributed in area M.

In the absorbent body 4D shown in FIG. 7, the fiber mass-rich portion extends continuously over the entire length of the absorbent core 40 in the longitudinal direction X on the side of the skin-facing surface 45 of the absorbent core 40. The water-absorbent fiber-rich portion extends continuously over the entire length of the absorbent core 40 in the longitudinal direction X on the side of the non-skin facing surface 46 of the core 40 . However, in the absorbent body 4D, the ratio of the thickness of the water-absorbing fiber-rich portion to the thickness of the entire region is different between the front region F or the rear region R and the longitudinal central region M. The ratio is higher in the front area F and the rear area R than in the front area F and the rear area R. In other words, regarding the basis weight of the water-absorbent fibers 12F, there is a size relationship of "longitudinal central area M>front area F, rear area R". Specifically, as shown in FIG. 7 , in the absorbent core 40 in the front region F and the rear region R, a part of the skin-facing surface 45 side, more specifically, a surface layer portion of the skin-facing surface 45 side (skin-facing 45 and the vicinity thereof) is the fiber mass rich region, whereas in the absorbent core 40 in the longitudinal central region M, the whole or most of the skin facing surface 45 side is the fiber mass rich region. . In addition, in the absorbent body 4D, the water-absorbing polymer 13 is unevenly distributed in the water-absorbing fiber-rich region and is not contained in the fiber mass-rich region in the form shown in FIG. 7, but is contained in the fiber mass-rich region. may

Each of the absorbers 4A to 4D described above has a protruding portion 47 in the longitudinal central region M that protrudes toward the wearer's skin side from the peripheral portion. In the raised portions 47 of the absorbent bodies 4A to 4D, the basis weight of the core-forming materials including the fiber clumps 11 and the water-absorbing fibers 12F is larger than that in the peripheral portion, resulting in the difference in basis weight of the absorbent core 40. Therefore, the thickness of the raised portion 47 is thicker than that of the peripheral portion. Then, due to the presence of the raised portion 47 in the longitudinal central region M of the absorbent core 40, the longitudinal central region M of the napkin 1 having any one of the absorbent bodies 4A to 4D as the absorbent body 4 is as shown in FIG. As shown, the skin facing surface has a convex portion that protrudes toward the wearer's skin side. In this way, since the protrusions corresponding to the protrusions 47 of the absorbent core 40 are present on the skin facing surface of the longitudinal central region M of the napkin 1, the protrusions are in close contact with the wearer's excretory part. Wearing comfort and liquid absorbency can be improved.

In addition, in the absorbent core 40 in the longitudinal central region M where the convex portion exists, the fiber clumps 11 are positioned on the non-skin facing surface 46 side, like the absorbent body 4B (see FIG. 5) and the absorbent body 4C (see FIG. 6). Due to the uneven distribution, a high level of cushioning property of the napkin 1 is ensured centering on the longitudinal central region M, and the feeling of wearing the napkin 1 can be further improved in combination with the action and effect of the convex portions. In addition, the raised portion 47 may be formed over the entire length in the lateral direction Y of the longitudinal central region M of the absorbent core 40 . Further, the raised portion 47 may extend from the longitudinal central region M to the front region F and/or the rear region R.

The absorber 4E shown in FIG. 8 has a uniform thickness and does not have the raised portion 47. As shown in FIG. In the absorbent core 40 in the front region F or the rear region R of the absorbent body 4E, the basis weight of the fiber clumps 11 gradually increases from the outer side in the longitudinal direction X toward the inner side (the longitudinal central region M side). While the basis weight of the absorbent fibers 12F decreases (gradual increase in basis weight of the absorbent fibers 12F), the absorbent core 40 in the longitudinal central region M is entirely the absorbent fiber-rich region. In the absorbent body 4E, regarding the basis weight of the fiber clump 11, there is a size relationship of "front area F, rear area R>longitudinal center area M". In addition, in the absorbent body 4E, the water-absorbent polymer 13 is unevenly distributed in the longitudinal central region M (the water-absorbent fiber-rich region).

In the longitudinal central region M, the non-skin-facing surface 46 side of the absorbent core 40 preferably has a larger basis weight (mass per unit area) of the fiber clumps 11 than the skin-facing surface 45 side. Of the absorbent bodies 4A to 4E described above, the absorbent body 4B (see FIG. 5) and the absorbent body 4C (see FIG. 6) have such a configuration. Such a configuration enhances mainly the effects of the fiber mass 11, such as the effects of improving flexibility, cushioning properties, compression recovery properties, and shape retention. In this case, the absorbent core 40 in the longitudinal central region M on the side of the skin-facing surface 45 of the absorbent core 40 may have a larger basis weight of the absorbent fibers 12F than on the non-skin-facing surface 46 side. A relatively large amount of water-absorbing fibers 12F having excellent water-absorbing properties are contained on the side of the skin facing surface 45 of the absorbent core 40 in the longitudinal central region M, which is the part that first receives the bodily fluid excreted by the wearer. As a result, the liquid drawing force (capillary force) of this portion is improved, and the liquid absorbency of the absorbent core 40 is improved. Therefore, in the absorptive core 40 in the longitudinal central region M, the magnitude relationship of "the basis weight of the fiber lumps 11 on the non-skin facing surface 46 side>the basis weight of the fiber lumps 11 on the skin facing surface 45 side" is established. Thus, the possibility that the napkin 1 will be excellent in wearability and liquid absorbency can be further improved.

In addition, not only in the longitudinal central region M, but also in the front region F and the rear region R, as in the longitudinal central region M, in the absorbent core 40, "the basis weight of the fiber mass 11 on the non-skin facing surface 46 side > skin It is preferable that the size relationship of "the basis weight of the fiber mass 11 on the facing surface 45 side" is established. Of the absorbers 4A to 4E described above, the absorber 4B (see FIG. 5) has such a configuration.

The ratio of the basis weight of the fiber clumps 11 on the non-skin-facing surface 46 side of the absorbent core 40 to that on the skin-facing surface 45 side is preferably 1.1 or more, more preferably 10 or more, as the former/latter.
On the premise that the basis weight of the fiber clumps 11 on the non-skin facing surface 46 side of the absorbent core 40 is larger than that on the skin facing surface 45 side, it is preferably 32 g/m ² or more, more preferably 80 g/m ^{2 .} above, and preferably 640 g/m ² or less, more preferably 480 g/m ² or less.
Assuming that the basis weight of the fiber clumps 11 on the skin-facing surface 45 side of the absorbent core 40 is smaller than that on the non-skin-facing surface 46 side, it is preferably 320 g/m ² or less, more preferably 240 g/m ^{2 .} or less, and may be 0 g/m ² .

In addition, in the absorbent core 40, the longitudinal central region M preferably has a larger basis weight of the fiber clumps 11 than the front region F and the rear region R. Of the absorbent bodies 4A to 4E described above, the absorbent body 4C (see FIG. 6) and the absorbent body 4D (see FIG. 7) have such a configuration. Since the absorbent core 40 in the longitudinal central region M is usually sandwiched between the thighs of the wearer when the napkin 1 is worn, the movement of the thighs during the wearer's walking motion causes the vertical direction X It is likely to be twisted around a virtual rotation axis extending in the direction of the arrow, and compared to the front region F and the rear region R, the external force is likely to act strongly, and twisting is likely to occur. Here, in the absorptive core 40, the above-described magnitude relationship "the basis weight of the fiber lumps 11 in the longitudinal central region M>the basis weights of the fiber lumps 11 in the front region F and the rear region R" is established, and relatively twist occurs. In the absorbent core 40 in the longitudinal central region M, which is easy to absorb, the fiber clumps 11 that can contribute to improving cushioning properties, compression recovery, shape retention, etc. are contained more than the front region F and the rear region R. , the inconvenience that the absorbent body 4 is twisted when wearing the napkin 1 can be effectively prevented, and the feeling of wearing can be further improved.

The ratio of the basis weight of the fiber clumps 11 of the absorbent core 40 in the longitudinal central region M to that in each of the front region F and the rear region R is preferably 1.1 or more, more preferably 10 or more as the former/latter. . Since the front region F and the rear region R may not contain the fiber clumps 11, the upper limit of the ratio is not defined.
On the premise that the basis weight of the fiber masses 11 of the absorbent core 40 in the longitudinal central region M is larger than the basis weight of the fiber masses 11 in each of the front region F and the rear region R, it is preferably 32 g/m ² or more, or more. It is preferably 80 g/m ² or more, preferably 640 g/m ² or less, more preferably 480 g/m ² or less.
On the premise that the basis weight of the fiber lumps 11 in each of the front region F and the rear region R is smaller than the basis weight of the fiber lumps 11 in the longitudinal central region M, it is preferably 320 g/ ^m2 or less, more preferably 240 g/m2. ² or less, and may be 0 g/m ² .

The above-mentioned size relationship "the basis weight of the fiber lumps 11 in the longitudinal central region M > the basis weights of the fiber lumps 11 in the front region F and the rear region R" is established, so that the effect can be exhibited more reliably. From the viewpoint, the absorbent core 40 preferably contains 70% by mass or more of all the fiber lumps 11 contained in the absorbent core 40 in the longitudinal central region M, and more preferably 80% by mass or more. Preferably, 100% by mass, that is, all of the fiber lumps 11 contained in the absorbent core 40 may be present in the longitudinal central region M.

The above-described uneven distribution of the fiber lumps 11 in the absorbent core 40 is determined by using the total content mass of the fiber lumps 11 and the water-absorbent fibers 12F used as the core forming material of the absorbent core 40 together with the "fiber lumps 11 and water absorption It can also be defined as the ratio of the mass content of the fiber lumps 11 to the total mass content of the fibrous fibers 12F" (hereinafter also referred to as the "fibrous mass occupancy ratio").

That is, in relation to the magnitude relationship of "the basis weight of the fiber lumps 11 on the non-skin facing surface 46 side>the basis weight of the fiber lumps 11 on the skin facing surface 45 side", "the fiber lumps on the non-skin facing surface 46 side It is preferable that the size relationship of "occupancy rate>fiber mass occupancy rate on the side of the skin-facing surface 45" is established.

Further, in relation to the magnitude relationship of "the basis weight of the fiber lumps 11 in the longitudinal central region M > the basis weights of the fiber lumps 11 in the front region F and the rear region R", the "fiber lump occupancy of the longitudinal central region M It is preferable to establish a magnitude relation of ratio>fibrous clump occupancy ratio of front area F and rear area R". That is, it is preferable that the longitudinal central region M has a larger fiber mass occupation rate than the front region F and the rear region R.

The fiber clump occupancy rate is obtained by measuring the content of each of the fiber clumps 11 and the water-absorbent fibers 12F existing in the predetermined measurement target portion of the absorbent core 40 by mass, and then measuring the fiber clump occupancy rate. 11 is divided by the sum of the masses contained in the water-absorbing fibers 12F and the fiber lumps 11, and expressed as a percentage of 100. That is, fiber lump occupation ratio (% by mass)={mass content of fiber lumps 11/(mass content of water-absorbing fibers 12F+mass content of fiber lumps 11)}×100.

On the premise that the fiber clump occupancy on the non-skin-facing surface 46 side of the absorbent core 40 is higher than that on the skin-facing surface 45 side of the absorbent core 40, it is preferably 50% by mass or more, more preferably 90% by mass. % or more, and 100% by mass, that is, the non-skin facing surface 46 side may not contain the water-absorbing fibers 12F at all instead of containing the fiber lumps 11 .
In addition, in the absorbent core 40, on the premise that the fiber mass occupancy of the longitudinal central region M is higher than the fiber mass occupancy of each of the front region F and the rear region R, it is preferably 20% by mass or more, more preferably 40% by mass or more, preferably 80% by mass or less, more preferably 60% by mass or less.

For example, in the absorbent core 40 in the longitudinal central region M, when the above-described magnitude relationship of "fiber mass occupation rate on the non-skin facing surface 46 side>fiber mass occupation rate on the skin facing surface 45 side" is established, 1) the skin On each of the facing surface 45 side and the non-skin facing surface 46 side, the fiber mass occupancy may be constant without changing in the thickness direction, or 2) the fiber mass may increase from the skin facing surface 45 side toward the non-skin facing surface 46 side. Lump occupancy may increase gradually. In the above-mentioned form 2), in the thickness direction of the absorbent core 40, the fiber lumps 11 do not exist on the skin-facing surface 45 of the absorbent core 40 and its vicinity, or the minimum At the non-skin-facing surface 46 of the absorbent core 40 and its vicinity, the fiber lumps 11 exist at the highest fiber lump occupation rate in the absorbent core 40 in the longitudinal central region M. The front region F and the rear region R of the absorbent core 40 may also have the form of 1) or 2).

As an advantage peculiar to the above-described form 1), it is easy to design independent functions on the skin-facing side and the non-skin-facing side of the absorbent core. In addition, as an advantage peculiar to the above-mentioned form 2), the mixing ratio of the water-absorbing fibers and the fiber clumps gradually changes in the thickness direction of the absorbent body, so that even when an external force is applied to the absorbent core, the fiber clumps intervene. The entangled state is easily maintained over the thickness direction, and good cushioning properties of the absorbent core are easily maintained during use.

In addition, the fiber clump occupancy rate may gradually increase from each of the front region F and the rear region R of the absorbent core 40 toward the longitudinal central region M. For example, in each of the front region F and the rear region R, the fiber mass occupancy gradually increases from the outer side to the inner side in the longitudinal direction X, and the longitudinal central region M is in the form of 1) or 2) above. good too.

As described above, regarding the basis weight of the absorbent fibers 12F in the absorbent core 40, there is a size relationship of "longitudinal central area M>front area F, rear area R". The absorbent body 4 has a change portion (inflection point of the basis weight of the water absorbent fibers 12F) where the thickness or the basis weight of the water absorbent fibers 12F changes in the longitudinal direction X. In addition, the absorbers 4A to 4D (see FIGS. 4 to 7) described above have the raised portion 47 only in the longitudinal central region M. Therefore, the changing portion (absorbent body 4 or the inflection point of the thickness of the absorbent core 40). In this way, if the absorbent body 4 (absorbent core 40) has a changing portion in which the thickness or basis weight of the water-absorbing fibers 12F changes in the longitudinal direction X, twisting, that is, intentional The absorbent body 4 is likely to be deformed if it is not used, which may lead to a decrease in the wearing comfort of the napkin 1 . However, in the napkin 1, since the absorbent core 40 contains the fiber lumps 11 together with the water-absorbent fibers 12F, the fiber lumps 11 and the water-absorbent fibers 12F are entangled in the changing portion and before and after it. This effectively prevents the absorber 4 from twisting.

In the napkin 1, as shown in FIG. A surface concave portion 7 is formed integrally on the side facing the skin (on the side of the back sheet 3). The recessed surface portion 7 does not penetrate the absorbent body 4 (absorbent core 40), has an opening on the skin-facing surface of the topsheet 2, and has a bottom on the opposite side of the opening. The recessed surface 7 formed on the skin-facing surface of the napkin 1 facilitates movement of bodily fluids such as menstrual blood along the recessed surface 7 .

As shown in FIGS. 1 and 3, the surface recesses 7 include a pair of surface vertical recesses 7X, 7X extending in the vertical direction X, and a pair of front and rear horizontal surface recesses 7Y, 7Y extending in the horizontal direction Y. is composed of The pair of surface vertical recesses 7X, 7X are located on both sides of the central portion in the horizontal direction Y of the vertical central region M and are spaced apart in the horizontal direction Y. As shown in FIG.

In the napkin 1, the pair of surface vertical recesses 7X and 7X respectively extend over the entire length of the longitudinal central region M in the longitudinal direction X, further extend to the front region F and the rear region R, and are continuous as a whole. It is linear.
At least a portion of one of the pair of lateral surface recesses 7Y, 7Y is located in the front region F, and at least a portion of the other is located in the rear region R, both of which are vertically oriented in plan view. A U-shaped or arc-shaped continuous line projecting toward the outside of X is formed, and the top of the U-shaped or arc-shaped is located in the center of the napkin 1 in the horizontal direction Y.
The recessed portions 7X and 7Y forming the surface recessed portion 7 are connected to each other at their lengthwise ends, and the surface recessed portion 7 as a whole has a closed annular shape, more specifically a long shape, in plan view. It has an elliptical shape. A region surrounded by the pair of surface vertical recesses 7X, 7X in the longitudinal central region M is located in the central portion of the longitudinal central region M and includes the excretory part facing portion (excretion point).

In addition, as shown in FIG. 2, in the napkin 1, a core wrap sheet 41 (non-skin side core wrap sheet) and an absorbent core 40 are placed at a position overlapping the surface recessed portion 7 of the absorbent main body 5 in plan view. A rear recessed portion 8 integrally recessed on two sides is formed at least in the longitudinal central region M. As shown in FIG. The back concave portion 8 does not penetrate the absorbent body 4 (absorbent core 40), has an opening on the non-skin-facing surface of the absorbent body 4, and has a bottom on the side opposite to the opening. The front surface recessed portion 7 and the rear surface recessed portion 8 share a bottom portion.

In this embodiment, the back surface recessed portion 8 has substantially the same shape and the same dimensions as the front surface recessed portion 7 in plan view, and forms a closed annular shape similar to the front surface recessed portion 7 . That is, the back surface recessed portion 8 extends in the vertical direction X, and extends in the horizontal direction Y along with a pair of left and right back surface vertical recessed portions 8X, 8X that overlap the front surface vertical recess portion 7X in plan view and have the same shape as the front surface vertical recess portion 7X in plan view. , and a pair of front and rear lateral recesses 8Y, 8Y (not shown) overlapping the front lateral recess 7Y in plan view and having the same shape in plan view as the front lateral recess 7Y. They are connected at the ends in the length direction, and form a closed annular shape (oblong elliptical shape) in plan view as a whole of the back recessed portion 8 .

The surface recessed portion 7 is formed by compressing the absorbent body 5 from the napkin 1, specifically from the side of the skin facing surface (the side of the surface sheet 2). ' can be said. In addition, the back concave portion 8 is formed by compressing the absorbent body 4 from the non-skin facing surface side (non-skin side core wrap sheet side), and is also called a "pressing portion". can. Both recessed portions 7 and 8, which are compressed portions, have a higher density than peripheral portions of both recessed portions 7 and 8 in absorbent body 4. As shown in FIG. That is, as shown in FIGS. 1 and 2, the napkin 1 has a high density portion corresponding to the recessed portions 7 and 8 and a low density portion 9 where the recessed portions 7 and 8 are not formed. The absorbent main body 5 has a density difference in the surface direction.

The pressing process for forming both concave portions 7 and 8 melts the core-forming material contained in the absorbent body 4 (absorbent core 40), particularly melts thermoplastic fibers preferably used as constituent fibers of the fiber mass 11. A method involving melting of the core-forming material may be used. Specific examples of the pressing process involving melting of the core-forming material include known embossing processes such as embossing processes involving heat and ultrasonic embossing. At the bottom of the surface recessed portion 7 formed by pressing with melting of the core forming material, that is, at the portion overlapping the surface recessed portion 7 which is a space portion in plan view, the surface sheet 2, the core wrap sheet 41 (skin side core wrap sheet) and the absorbent core 40 may be heat-sealed together. In addition, the core wrap sheet 41 (non-skin side core wrap sheet ) and the absorbent core 40 may be heat-sealed together. As described above, since the bottom portion is shared by the back recessed portion 8 and the front recessed portion 7, the bottom portion common to both the recessed portions 7 and 8 includes the top sheet 2 and the skin side in order from the front recessed portion 7 side. The core wrap sheet, the absorbent core 40 and the non-skin side core wrap sheet may exist in a state of being heat-sealed and integrated with each other.

The width of the surface recessed portion 7 (the length in the direction perpendicular to the length direction of the recessed portion) is not particularly limited, but is preferably 0.1 mm or more, more preferably 0.5 mm or more, and preferably 10 mm or less. It is preferably 5 mm or less. The width of the back recessed portion 8 can also be set within the same range.

As shown in FIGS. 1 to 3, the low-density portion 9 is a portion of the absorbent main body 5 (a region overlapping the absorbent body 4 in a plan view) where neither the front recessed portion 7 nor the back recessed portion 8 is formed. , and the density is lower than that of the concave portions 7 and 8 . As described above, in the napkin 1, the concave portions 7 and 8 have substantially the same shape and the same size in plan view, and form a closed ring (elliptical shape). It exists both inside and outside the closed ring of the parts 7,8. At least the peripheral portion of the absorbent main body 5 and the central portion of the longitudinal central region M (the portion facing the excretory portion and its vicinity) are low-density portions 9 .

Sandwiched between a pair of front surface vertical recesses 7X, 7X (back surface vertical recesses 8X, 8X) extending in the vertical direction X through both sides of the low-density portion 9, particularly in the horizontal direction Y, of the vertical center region M A pressed portion formed by pressing such as embossing may partially exist in the region (the central portion in the horizontal direction Y of the longitudinal central region M). In that case, the area of all the compressed parts present in the low-density portion 9, which occupies the total area of the low-density portion 9 (specifically, for example, the region sandwiched between the pair of surface vertical recesses 7X, 7X) The total ratio is preferably 5% or less, more preferably 3% or less. In the napkin 1 of the present embodiment, there is no compressed portion in the low-density portion 9 sandwiched between the pair of surface vertical recesses 7X, 7X, and the low-density portion sandwiched between the pair of surface vertical recesses 7X, 7X 9 corresponds to a "non-bonded area of fiber lumps" to be described later. Unless otherwise specified, the following description of the low-density portion 9 is a description of a portion of the low-density portion 9 where there is no pressed portion (portion not subjected to pressing).

Since the absorbent core 40 contains the fiber lumps 11, the characteristics such as shape retention and cushioning properties are improved compared to the normal absorbent core 40 that does not contain it. Having the depressed densities 7 compressed and densified further enhances such properties, e.g. the strong compressive force in the lateral direction Y exerted by the thighs of the wearer of the napkin 1. It does not easily lose its shape even when subjected to such an external force, it deforms with good responsiveness to the external force, and can quickly restore itself when the external force is released.

In addition, in the napkin 1, due to the relatively high density recessed portions 7 and 8 and the relatively low density low density portion 9 coexisting in the plane direction, there is a density difference in the plane direction. Due to the difference in density, the body fluid is easily diffused in the plane direction. That is, the napkin 1 can quickly diffuse the bodily fluid excreted by the wearer in the surface direction, and therefore effectively utilizes the absorption performance inherent in the absorbent core 40 to exhibit high liquid leakage prevention. can. Especially in the napkin 1, as shown in FIGS. 1 and 3, the surface recesses 7 are present not only in the longitudinal central region M, but also in the front region F and the rear region R, so that the overall shape retention of the napkin 1 and the liquid diffusibility in the surface direction are enhanced.

In addition, in the low-density portion 9, the plurality of fiber lumps 11 exist in a state in which their original outer shape is substantially maintained. A large number of space portions are present, and the large number of space portions contribute to the expression of the excellent cushioning properties of the low-density portion 9, and can also function as a temporary stock portion for body fluids. Since the napkin 1 has the low-density portion 9 that can function as a temporary storage portion for bodily fluids in the central longitudinal region M where excreted bodily fluids tend to concentrate, the napkin 1 has excellent fluid absorption capacity. and can exhibit high liquid-leakage-proof property, and the high liquid-drawing property can reduce liquid residue on the surface of the topsheet 2 facing the skin, thereby suppressing unpleasant wet feeling and sticky feeling.

In addition, the presence of the low-density portion 9 having excellent cushioning properties and the like in the longitudinal central region M where the excretory part facing portion exists allows the longitudinal central region M to be in a dry state before absorption of body fluids as well as after absorption of body fluids. Even in a wet state, the low-density portion 9 provides flexibility and cushioning properties.

From the viewpoint of ensuring the effects of the concave portions 7 and 8 and the low-density portion 9 described above, it is preferable to set the dimensions of each portion of the napkin 1 as follows.
A separation distance W1 in the lateral direction Y between the side edges along the longitudinal direction X of the absorbent body 4 (absorbent core 40) and the concave portions 7 and 8 (vertical concave portions 7X and 8X) in the longitudinal central region M (see FIG. 1 ) is preferably 5 mm or more, more preferably 10 mm or more, and preferably 25 mm or less, more preferably 20 mm or less. If the length (width) of the absorber 4 in the horizontal direction Y is not constant, the separation distance W1 is the measured value at the widest part of the absorber 4 .
The length in the horizontal direction Y, that is, the width W2 (see FIG. 1) of the low-density portion 9 in the longitudinal central region M is preferably 20 mm or more, more preferably 25 mm or more, and preferably 70 mm or less, more preferably 65 mm or less. be.

The ratio of the total area of the surface recesses 7 to the total area of the skin-facing surface of the absorbent body 4 (absorbent core 40) (recess occupancy) is preferably 0.02% or more, more preferably 0.1%. % or more, preferably 15% or less, more preferably 10% or less. The ratio of the total area of the back recessed portions 8 to the total area of the non-skin facing surface of the absorbent body 4 (absorbent core 40) (recessed portion occupancy) may be the same as that of the front recessed portions 7 described above.
The depth of the surface recessed portions 7 (7X, 7Y) (the depth based on the non-recessed portion of the surface facing the skin of the top sheet 2) is preferably 0.1 mm or more, more preferably 0.2 mm or more, And it is preferably 2.0 mm or less, more preferably 1.0 mm or less.
The depth of the back concave portion 8 (8X, 8Y) (the depth based on the non-concave portion of the non-skin facing surface of the absorbent body 4) is preferably 0.1 mm or more, more preferably 0.2 mm or more. , and preferably 2.0 mm or less, more preferably 1.0 mm or less.

In the napkin 1, the depths of the recesses 7, 8 may be constant over the entire length of the napkin 1, or partially different. Further, the shape, arrangement, etc. of the linear recesses 7 and 8 are not limited to the illustrated form, and can be set in the same manner as what is called a leak-proof groove or the like in this type of absorbent article. The linear recesses 7 and 8 may be configured to include straight lines and/or curved lines in plan view, and each line may be a continuous line or a dashed line (two types of portions with different depths may be a line). alternately arranged in the extending direction of the recesses). In addition, in the absorbent article of the present invention, the pattern (shape and arrangement in a plan view) of the recesses 7 and 8 is not limited to a line-of-sight pattern such as the recesses 7 and 8 shown in FIG. It may be circular, elliptical, rectangular, triangular, star-shaped, heart-shaped, or the like (dot-shaped).

It is preferable that the longitudinal central region M has a non-bonded fiber mass region where the fiber mass 11 and the core wrap sheet 41 are not bonded. As a specific example of bonding between the fiber mass 11 and the core wrap sheet 41, fusion bonding by melting thermoplastic fibers preferably used as constituent fibers of the two can be exemplified. The joining of the fiber mass 11 and the core wrap sheet 41 by fusion bonding can be performed by compression processing accompanied by melting of thermoplastic fibers. embossing. The fiber mass non-bonded region is a region that is not subjected to such "pressing process accompanied by melting of the constituent fibers of the fiber mass 11 and/or the core wrap sheet 41". The longitudinal central region M is a portion sandwiched between the thighs of the wearer when the napkin 1 is worn. If a region exists, the fiber mass 11 is not bonded to the core wrap sheet 41 in the fiber mass non-bonded region and can move relatively freely. shape retention, etc.) are more likely to be expressed.

It is preferable that the fiber mass non-bonded region exists in a region sandwiched between the pair of surface vertical recesses 7X, 7X. Such a region is a region including the excretory portion facing portion (excretion point), and the presence of the fiber lump non-bonded region in such a region improves the adhesion of the napkin 1 to the excretory portion of the wearer. , further improvement in wearability and liquid absorbency can be expected. In the napkin 1, the region sandwiched between the pair of surface vertical recesses 7X, 7X in the longitudinal central region M (the central portion of the longitudinal central region M in the horizontal direction Y) is the fiber mass 11 and / or It is the low-density portion 9 that is not subjected to compression processing accompanied by melting of the constituent fibers of the core wrap sheet 41, and corresponds to the above-described fiber mass non-bonded region.

The back sheet 3 is preferably joined to a portion (non-skin-side core wrap sheet) of the core wrap sheet 41 covering the non-skin facing surface 46 of the absorbent core 40 . With such a configuration, for example, when the wearer of the napkin 1 takes a sitting or lying position, the napkin 1 intervening between the wearer and the seat surface that supports the wearer from below is pressed for a long time. , the cushioning property of the absorber 4 is likely to be maintained, and the wearer can perceive a comfortable wearing feeling. In addition to such a configuration, the size relationship of "the basis weight of the fiber lumps 11 on the non-skin facing surface 46 side>the basis weight of the fiber lumps 11 on the skin facing surface 45 side" is established at least in the longitudinal central region M. Furthermore, it is more effective if it is established in the front area F and the rear area R as well.

In addition, the surface recessed portion 7 (surface vertical recessed portion 7X) that defines the fiber mass non-bonding region in the longitudinal central region M extends in the longitudinal direction X. As shown in FIG. 1, not only when the surface recesses 7 extend in the longitudinal direction X in a continuous line, but also when a plurality of surface recesses 7 are intermittently arranged in the longitudinal direction X, the plurality of surface recesses 7 appears to extend in the longitudinal direction X as a whole. In the latter case, the distance in the longitudinal direction X between the two surface recesses 7 closest to each other in the longitudinal direction X is preferably 30 mm or less, more preferably 20 mm or less. As a specific example of the latter case, a plurality of surface recessed portions 7 having a predetermined shape in plan view are intermittently arranged in the vertical direction X, and the plurality of surface recessed portions 7 extend in the vertical direction X in a dashed line. The same applies to the plurality of rear surface recessed portions 8 intermittently arranged in the longitudinal direction X. As shown in FIG.

In the absorbent core 40, the content mass ratio of the fiber clumps 11 and the water-absorbent fibers 12F is not particularly limited, and may be appropriately adjusted according to the types of the constituent fibers (synthetic fibers) 11F and the water-absorbent fibers 12F of the fiber clumps 11. Just do it. For example, when the constituent fibers 11F of the fiber mass 11 are thermoplastic fibers (non-water-absorbing synthetic fibers) and the water-absorbing fibers 12F are cellulose-based water-absorbing fibers, the predetermined effects of the present invention can be obtained more reliably. From the viewpoint of the above, the content mass ratio of the fiber mass 11 and the water-absorbent fiber 12F is preferably 20/80 to 80/20, more preferably 40, as the former (fiber mass 11) / the latter (water-absorbent fiber 12F). /60 to 60/40.

The content of the fiber lumps 11 in the absorbent core 40 is preferably 20% by mass or more, more preferably 40% by mass or more, and preferably 80% by mass or less with respect to the total mass of the absorbent core 40 in a dry state. , more preferably 60% by mass or less.
The content of the water absorbent fibers 12F in the absorbent core 40 is preferably 20% by mass or more, more preferably 40% by mass or more, and preferably 80% by mass with respect to the total mass of the absorbent core 40 in a dry state. 60% by mass or less, more preferably 60% by mass or less.
The content of the water-absorbent polymer 13 in the absorbent core 40 is preferably 1% by mass or more, more preferably 5% by mass or more, and preferably 80% by mass with respect to the total mass of the absorbent core 40 in a dry state. 50% by mass or less, more preferably 50% by mass or less.
As used herein, the term "dry absorbent core" means an absorbent core before it absorbs bodily fluids.

The absorbent body 4 (absorbent core 40) can be manufactured according to a conventional method using a known fiber stacking device equipped with a rotating drum. As described above, the absorbent body 4 has a configuration in which the core-forming materials (fiber mass 11, water-absorbent fibers 12F, water-absorbent polymer 13) are uniformly distributed throughout the absorbent core 40 (see FIG. 4), and the longitudinal central region M The fiber lumps 11 (water-absorbent fibers 12F) are unevenly distributed on the skin-facing surface 45 side or the non-skin-facing surface 46 side of the absorbent core 40 (see FIGS. 5 to 8). It can be manufactured according to a conventional method using a known fiber stacking device. In particular, the latter form in which the fiber clumps 11 are unevenly distributed in the thickness direction is obtained by changing the stacking order of the fiber clumps 11 and the water-absorbing fibers 12F on a rotating drum in the method of manufacturing an absorbent body using a known fiber stacking device. It can be manufactured by making appropriate adjustments.

A fiber stacking device that can be used to manufacture the absorbent body 4 (absorbent core 40) typically includes a rotating drum having a collecting recess formed on its outer peripheral surface, and a core forming material (fiber mass) placed in the collecting recess. 11, a duct having a flow path for conveying the water-absorbent fiber 12F and the water-absorbent polymer 13) inside the rotating drum while rotating the rotating drum around the rotation axis along the drum circumferential direction The core forming material conveyed by the air flow generated in the flow path by suction from the side is piled up in the accumulating concave portion. The absorbent core 40 is formed in the stacking concave portion by such a stacking process.

As a method of manufacturing an absorbent body in which the fiber lumps 11 are unevenly distributed in the thickness direction, such as the absorbent bodies 4B to 4E, using a known fiber stacking device, there are, for example, the following two methods.
1) A method of using two fiber stacking devices and stacking and integrating a fiber stack manufactured by one of the fiber stacking devices and a fiber stack manufactured by the other fiber stacking device (hereinafter referred to as "first method (Also referred to as “manufacturing method”).
2) A method of using a single fiber stacking device and differentiating the supply timing of the fiber clumps to the accumulating concave portion and that of the water-absorbing fibers (hereinafter also referred to as "second manufacturing method").

In the first manufacturing method, first, the water-absorbing fibers 12F and, if necessary, the water-absorbing polymer 13 are used as the core-forming material, and the core-forming material is accumulated in the accumulation concave portion of the first fiber stacking device. to produce a water-absorbent fiber pile. The water-absorbent fiber stack may correspond to the water-absorbent fiber-rich region of the absorbent core 40 described above. Separately from this, the fiber mass 11 is used as the core forming material, and the core forming material is accumulated in the collecting concave portion of the second fiber stacking device to manufacture a fiber mass piled body. The fiber mass fiber body can correspond to the fiber mass fiber-rich region of the absorbent core 40 described above. Next, the water-absorbing fiber piled body and the fiber piled body are laminated to obtain a laminated body, and the laminated body is integrated by pressing in the thickness direction. As another integration method, suction means such as a known vacuum conveyor is used, the water-absorbing fiber piled body is placed on the suction surface of the suction means, and the suction force of the suction surface acts. In this state, the fiber mass piled body is superimposed on the water-absorbent fiber piled body to be integrated. In any integration method, entanglement occurs between the water-absorbent fibers and the fiber mass at the interface between the water-absorbing fiber pile and the fiber mass. Thus, absorbent bodies such as absorbent bodies 4B to 4E in which the fiber clumps 11 are unevenly distributed in the thickness direction are obtained.

In the second manufacturing method, as the fiber stacking device, a stacking recess having a partially different suction force is used. Specifically, for example, the stacking recess has a low suction recess and a Also, a high-suction concave portion with a high suction force is used. The low suction recesses and the high suction recesses are connected in the rotating direction (circumferential direction) of the rotating drum of the fiber stacking device. Then, the fiber stacking device having such a configuration is operated, and while the rotating drum is rotated in the circumferential direction to convey the stacking concave portion in one direction, the suction from the inside of the rotating drum causes the fiber to be drawn from the outside of the rotating drum. An air flow directed toward the accumulating recess is generated, and the core forming material is supplied to the accumulating recess by the air flow and accumulated (accumulating step). In the accumulating step, first, the fiber mass 11 is supplied to the accumulating concave portion and accumulated. At this time, the fiber lumps 11 are intensively accumulated in the high-suction concave portions, and fiber lump-stacked filaments are formed in the high-suction concave portions. Next, after or during the accumulation of the fiber lumps 11, the water-absorbing fibers 12F and, if necessary, the water-absorbing polymer 13 are supplied to the accumulation concave portion and accumulated. At this time, the water-absorbent fibers 12F (water-absorbent polymer 13) are accumulated in the low-suction recesses in the accumulation recesses, and are also accumulated on the fiber lumps 11 accumulated in the high-suction recesses. A water-absorbing fiber piled body is formed over the entire area. Since the fiber clumps 11 have air permeability, even when the fiber clumps 11 are accumulated in the high suction concave portion, a suction force capable of sucking the water-absorbent fibers 12F acts on the accumulated fiber clumps. The water absorbent fibers 12F (water absorbent polymer 13) can be piled up on the fiber clumps 11 accumulated in the high suction recesses. In this way, a laminate of the fiber mass and the water-absorbent fiber stack is formed in the high suction recess, and the fiber mass 11 and the water-absorbent fiber 12F are entangled at the interface between the two stacks. . Thus, absorbent bodies such as absorbent bodies 4B to 4E in which the fiber clumps 11 are unevenly distributed in the thickness direction are obtained.

The fiber mass 11 will be further described below. Various types can be used as the fiber mass 11 used in the present invention. A fiber mass 11A shown in FIG. 9, which is a preferred form, has a quadrangular prism shape, more specifically, a rectangular parallelepiped shape. The fiber clump 11A has two base planes 111 facing each other and a body plane 112 connecting the two base planes 111 . Both the basic surface 111 and the skeletal surface 112 are portions that are recognized to have substantially no unevenness at the level applied when evaluating the degree of unevenness of the surface of an article mainly composed of this type of fiber.

In the fiber clump 11 , it is preferable that the number of skeletal planes 112 per unit area of fiber ends is larger than that of the basic planes 111 . Such fiber clumps 11 are obtained by cutting a raw fiber sheet (a sheet having the same composition as the fiber clumps 11 and having dimensions larger than those of the fiber clumps 11) with a cutting means such as a cutter. The skeletal surface 112 of the mass 11 is a cut surface formed by cutting the raw material fiber sheet. In other words, the number of fiber ends per unit area is greater than that of the basic surface 111, which is the non-cut surface when the fiber mass 11 is manufactured.

Fiber ends present on each surface (basic surface 111, skeletal surface 112) of the fiber mass 11 are located between the fiber mass 11 and other fiber masses 11 contained in the absorbent core 40 and the absorbent fibers 12F. Useful for forming entanglements. In general, the greater the number of fiber ends per unit area, the better the entanglement, which can lead to the improvement of various properties of the absorbent core 40 such as shape retention. The number of fiber end portions per unit area on each surface of the fiber mass 11 is not uniform, and the number of such fiber end portions per unit area has a size relationship of “skeletal surface 112>basic surface 111”. Therefore, the entanglement with other fibers (other fiber lumps 11, water-absorbing fibers 12F) via the fiber lumps 11 differs depending on the surface of the fiber lumps 11, and the skeletal surface 112 is different from the basic surface 111. Highly confounding. That is, the binding force by entangling with other fibers via the skeletal surface 112 is stronger than that via the basal surface 111, and in one fiber mass 11, the basal surface 111 and the skeletal surface 112 may cause a difference in bonding strength with other fibers. In general, the stronger the binding force, the more restricted the freedom of movement of the bound fibers, and the strength (shape retention) of the absorbent core 40 as a whole improves, but the softness tends to decrease. .

In this way, each of the plurality of fiber clumps 11 contained in the absorbent core 40 exerts two types of bonding strength with respect to other surrounding fibers (other fiber clumps 11, water absorbent fibers 12F). The absorbent core 40 thus has both moderate softness and strength (shape retention). When the absorbent core 40 having such excellent properties is used as an absorbent body of an absorbent article according to a conventional method, it is possible to provide a comfortable wearing feeling to the wearer of the absorbent article. At the same time, the inconvenience of the absorbent core 40 being destroyed by an external force such as body pressure of the wearer when worn is effectively prevented.

A nonwoven fabric piece (fiber mass) manufactured by cutting a raw fiber sheet into an irregular shape with a cutting machine such as a mill cutter is a regular sheet having a "surface" such as a basic surface 111 and a skeleton surface 112. Since the fiber clumps are not flake-like and the external force of the cutting process is applied to the entire fiber clump during its production, the fiber ends of the constituent fibers are randomly formed throughout the fiber clump. Compared to the fiber mass produced in this manner, the fiber mass 11 of the present embodiment described above, for example, the fiber mass 11A shown in FIG.

From the viewpoint of ensuring the effects of the fiber ends described above, the number N1 of fiber ends per unit area on the basic surface 111 (non-cut surface) and the number of fibers on the skeleton surface 112 (cut surface) Assuming that N1<N2, the ratio of N2 to the number of edges per unit area is preferably 0 or more, more preferably 0.05 or more, and more preferably 0.90 or less as N1/N2. is 0.60 or less. More specifically, N1/N2 is preferably 0 or more and 0.90 or less, more preferably 0.05 or more and 0.60 or more.
The number N1 of fiber ends per unit area of the basic surface 111 is preferably 0/mm ² or more, more preferably 3/mm ² or more, and preferably 8/mm ² or less, more preferably 6. pcs/mm ² or less.
The number N2 of fiber ends per unit area of the skeletal surface 112 is preferably 5/mm ² or more, more preferably 8/mm ² or more, and preferably 50/mm ² or less, more preferably 40. pcs/mm ² or less.
The number of fiber ends per unit area of the basic surface 111 and the skeletal surface 112 is measured by the following method.

<Method for measuring the number of fiber ends per unit area on each surface of the fiber mass>
A member (fiber mass) containing fibers to be measured is attached to a sample table using a double-sided paper tape (Nichiban Co., Ltd., Nicetac NW-15). The measuring piece is then platinum coated. An ion sputtering apparatus E-1030 (trade name) manufactured by Hitachi Naka Seiki Co., Ltd. is used for coating, and the sputtering time is 120 seconds. Using a JCM-6000 type electron microscope manufactured by JEOL Co., Ltd., the basal plane and skeletal plane of the cut surface of the measurement piece are observed at a magnification of 100 times. In this observation screen with a magnification of 100 times, a rectangular area of 1.2 mm in length and 0.6 mm in width is set at an arbitrary position on the surface to be measured (basic surface or skeletal surface), and the area of the rectangular area is After adjusting the observation angle and the like so that 90% or more of the area of the observation screen is occupied, the number of fiber ends included in the rectangular area is measured. However, in the observation screen with a magnification of 100 times, when the measurement target surface of the fiber mass is smaller than 1.2 mm × 0.6 mm and the ratio of the area of the rectangular region to the entire observation screen is less than 90% After increasing the observation magnification to 100 times or more, the number of fiber ends included in the rectangular area on the measurement target surface is measured in the same manner as described above. Here, the "fiber ends" to be measured are the ends in the length direction of the constituent fibers of the fiber mass, and the portions other than the ends in the length direction of the constituent fibers from the surface to be measured (middle in the length direction) part) is extended, the intermediate part in the length direction shall not be counted. Then, the number of fiber ends per unit area on the measurement target surface (basic surface or skeletal surface) of the fiber clump is calculated by the following formula. For each of the 10 fiber clumps, according to the above procedure, measure the number of fiber ends per unit area on each of the basic plane and the skeletal plane, and take the average value of these multiple measured values as the fiber end on the measurement target plane. number per unit area.
The number of fiber ends per unit area (number/mm ² ) on the measurement target surface (basic surface or skeletal surface) of the fiber mass = the number of fiber ends included in the rectangular area (1.2 × 0.6 mm)/ Area of said rectangular region (0.72 mm ² )

When the basic surface 111 of the fiber mass 11 has a rectangular shape in plan view like the fiber mass 11A shown in FIG. One side (short side) 111a of the quadrangular shape is preferably equal to or shorter than the thickness of the absorbent body 4 containing the fiber lumps 11 (11A). The ratio of the length of one side (short side) 111a to the thickness of the absorbent body 4 is preferably 0.03 or more, more preferably 0.08 or more, and preferably 1 or less, more preferably 0 as the former/latter. .5 or less.
The thickness of the absorbent body 4 (absorbent core 40) is preferably 1 mm or more, more preferably 2 mm or more, and preferably 30 mm or less, more preferably 20 mm or less.

It is preferable to set the dimensions of each part of the fiber mass 11 (11A) as follows. The dimensions of each part of the fiber mass 11 can be measured based on an electron micrograph or the like during the later-described operation of specifying the outer shape of the fiber mass 11 .
When the basic surface 111 has a rectangular shape in plan view as shown in FIG. 9, the length L1 of one side (short side) 111a is preferably 0.1 mm or more, more preferably 0.3 mm or more, and still more preferably 0.5 mm. and preferably 10 mm or less, more preferably 6 mm or less, and even more preferably 5 mm or less.
When the fiber mass 11 has a rectangular shape in plan view, the length L2 of the other side (long side) 111b of the basic surface 111 is preferably 0.3 mm or more, more preferably 1 mm or more, and still more preferably 2 mm or more. And it is preferably 30 mm or less, more preferably 15 mm or less, still more preferably 10 mm or less.
In addition, as shown in FIG. 9, when the basic surface 111 is the surface having the largest area among the plurality of surfaces of the fiber mass 11, the length L2 of the other side (long side) 111b is equal to that of the fiber mass 11 For example, when the fiber mass 11 is disk-shaped, the maximum span length is, for example, two opposing flat surfaces that are circular in plan view and connect both flat surfaces. When the two flat surfaces are the basic surface 111 and the peripheral surface is the skeletal surface 112, the diameter of the basic surface 111 is circular in plan view.
The ratio of the length L1 of one side (short side) 111a to the length L2 of the other side (long side) 111b is preferably 0.003 or more and 1 or less, more preferably 0.025 or more and 1 as L1/L2. It is below. A particularly preferable fiber mass 11 is one whose aspect ratio of the basic surface 111 is 1 or close to 1, that is, the basic surface 111 having a square shape or a similar shape in plan view. When such a fiber mass 11 is used for the absorbent core 40, the absorbent core 40 tends to be bulky, and the cushioning property and the like can be improved.
The thickness T of the fiber mass 11, that is, the length T between the two opposing basic surfaces 111 is preferably 0.1 mm or more, more preferably 0.3 mm or more, and preferably 10 mm or less, more preferably 6 mm or less. be.
The size of the fiber clump 11 is not particularly limited, and can be appropriately set in consideration of the cushioning properties, liquid permeability, and the like of the absorbent core 40 . The area of the basic plane 111 , which is the plane having the largest area among the plurality of planes of the fiber mass 11 , can serve as an indicator of the size of the fiber mass 11 . The area of the basic surface 111 of the fiber clump 11 is preferably 1 mm ² or more, more preferably 5 mm ² or more, and preferably 100 mm ² or less, more preferably 50 mm ^{2 or} less.

FIG. 10(a) shows an electron micrograph of one embodiment of the fiber clump 11, and FIG. 10(b) shows a diagram schematically showing the fiber clump 11 based on this electron micrograph. there is As shown in FIG. 10, the fiber mass 11 includes a main body portion 110 and fibers 11F extending outward from the main body portion 110, and has a lower fiber density (per unit area) than the main body portion 110. (lower number of fibers per fiber), and those with extended fiber portions 113 may be included. Note that the absorbent core 40 may also include fiber clumps 11 that do not have extended fiber portions 113 , that is, fiber clumps 11 that are composed only of main body portions 110 . The extended fiber portion 113 can include one type of fiber end portion present on each surface (the basic surface 111 and the skeletal surface 112) of the fiber mass 11 described above, and it is one of the fiber ends. Extending outwardly from each face of mass 11 are fiber ends.

The extending fiber portion 113 mainly contributes to improving the entanglement between the plurality of fiber lumps 11 contained in the absorbent core 40 or between the fiber lumps 11 and the water absorbent fibers 12F, thereby improving the shape retention of the absorbent core 40. In addition to being directly related to the improvement of , the uniform dispersibility of the fiber lumps 11 in the absorbent core 40 is also affected, and the effects of the main body 110 can be indirectly reinforced.

As shown in FIG. 10(b), the fiber mass 11 is a type of extended fiber portion 113, and is an extended fiber bundle containing a plurality of fibers 11F extending outward from the main body portion 110, more specifically, from the skeleton surface 112. It has a part 113S. At least one of the extended fiber portions 113 included in the fiber clump 11 may be the extended fiber bundle portion 113S. The extending fiber bundle portion 113S is configured by gathering a plurality of fibers 11F extending from the skeletal surface 112. Compared to the extending fiber portion 113, the extending fiber bundle portion 113S extends from the skeletal surface 112 of the main body portion 110. Characterized by a point of long length. The extending fiber bundle portion 113S may also exist on the basic surface 111, but typically exists on the skeleton surface 112 as shown in FIG. However, the number thereof is smaller than that of the skeletal surface 112 . The reason for this is the same as the reason that the extended fiber portions 113 are mainly present on the skeletal surface 112, which is the cut surface of the raw material fiber sheet, as described above. Since the fiber clump 11 has such extended fiber bundle portions 113S, which can be called long and thick large-sized extended fiber portions 113, the fiber clumps 11 and the absorbent fibers 12F can be separated from each other. The entanglement is further strengthened, and as a result, the predetermined effects of the present invention due to the presence of the fiber clumps 11 are exhibited more stably. In addition, when the extended fiber bundle portion 113S has a heat-sealed portion, the strength of the extended fiber bundle portion 113S itself is improved, and entanglement occurs via the extended fiber bundle portion 113S. This is preferable because the entanglement between the fiber clumps 11 or between the fiber clumps 11 and the absorbent fibers 12F is further strengthened.

The constituent fibers 11F of the fiber mass 11 contain weakly absorbent fibers having lower water absorption than the absorbent fibers 12F. Here, the “weakly absorbent fibers” include “non-absorbent fibers” that do not absorb water, and “weakly absorbent fibers” that have water absorption but lower water absorption than the absorbent fibers 12F. and are included.

The water absorbency of the fiber can be indexed by the moisture content measured by the method described below. The higher the moisture content, the higher the water absorbency. The water content of the absorbent fibers 12F is preferably 6% or more, more preferably 10% or more. On the other hand, the moisture content of the weakly absorbent fibers that can be used as the constituent fibers 11F of the fiber mass 11 is preferably less than 6%, more preferably less than 4%.

<Method for measuring moisture content>
The moisture content was calculated according to the moisture content test method of JIS P8203. That is, after the fiber sample was allowed to stand in a test room at a temperature of 40° C. and a relative humidity of 80% RH for 24 hours, the weight W (g) of the fiber sample before absolutely dry treatment was measured in the room. After that, the fiber sample was completely dried by allowing it to stand for 1 hour in an electric dryer (manufactured by Isuzu Manufacturing Co., Ltd.) at a temperature of 105±2°C. After the absolute dry treatment, in a standard test room at a temperature of 20 ± 2 ° C. and a relative temperature of 65 ± 2%, Si silica gel (for example, (Toyota Kako Co., Ltd.) is placed in a glass desiccator (for example, manufactured by TechJam Co., Ltd.) and allowed to stand until the temperature of the fiber sample reaches 20±2°C. After that, the constant weight W' (g) of the fiber sample is weighed, and the moisture content of the fiber sample is obtained by the following formula. Moisture content (%) = (WW'/W') x 100

The constituent fibers 11F of the fiber mass 11 may contain fibers other than the weakly absorbent fibers, that is, the absorbent fibers 12F, but it is preferable that the fibers are mainly composed of the weakly absorbent fibers. The content of weakly absorbent fibers in the fiber mass 11 is preferably 90% by mass or more with respect to the total mass of the fiber mass 11, and 100% by mass, that is, all of the constituent fibers 11F are weakly absorbent fibers. is most preferred. Since the fiber clump 11 is composed mainly of weakly absorbent fibers, the absorbent core 40 is not only in a dry state but also in a wet state by absorbing water (bodily fluids such as urine and menstrual blood). Even in such a case, the effects (effects of improving flexibility, cushioning properties, compression recovery properties, shape retention properties, etc.) due to the presence of the fiber clumps 11 described above can be stably exhibited.

As the material of the constituent fibers 11F of the fiber clump 11, synthetic resin is preferable, and thermoplastic resin is particularly preferable. That is, the "weakly water-absorbing fiber" is preferably a synthetic fiber mainly composed of a synthetic resin, and particularly preferably a thermoplastic fiber mainly composed of a thermoplastic resin. Examples of thermoplastic resins include polyolefins such as polyethylene and polypropylene; polyesters such as polyethylene terephthalate; polyamides such as nylon 6 and nylon 66; These can be used alone or in combination of two or more. The fiber 11F may be a single fiber made of one type of synthetic resin (thermoplastic 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 (thermoplastic fiber) obtained by combining two or more types of synthetic resins with different components with a spinneret and simultaneously spinning them, and multiple components are continuous in the length direction of the fiber. It is a structure that is bonded to each other within a single fiber. The form of the composite fiber includes core-sheath type, side-by-side type, etc., and is not particularly limited.

Although the present invention has been described based on the embodiments, the present invention is not limited to the above embodiments and can be modified as appropriate.
For example, in the above-described embodiment, the absorber 4 has a higher basis weight of water-absorbent fibers in at least the central portion in the lateral direction Y of the longitudinal central region M than in the other regions F and R. The basis weight of the water-absorbent fibers may be higher than those of the other regions F and R over the entire length in the lateral direction Y of the region.
In addition, in the napkin 1 shown in FIG. 1, the surface vertical recessed portion 7X and the surface horizontal recessed portion 7Y that constitute the surface recessed portion 7 are connected at their longitudinal ends, and the surface recessed portion 7 is closed as a whole. However, the recessed portions forming the surface recessed portion 7 may not be connected to each other, and the surface vertical recessed portion 7X and the surface lateral recessed portion 7Y are arranged close to each other with a gap therebetween. may The same applies to the back recessed portion 8 overlapping the front recessed portion 7 in a plan view.
The absorbent article of the present invention broadly includes articles used for absorbing bodily fluids (urine, loose stool, menstrual blood, sweat, etc.) discharged from the human body. So-called unfolded disposable diapers with tapes, underpants-type disposable diapers, incontinence pads and the like are included.

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.

[Example 1]
A sanitary napkin having the same basic configuration as the napkin 1 shown in FIG. The absorbent body (absorbent core) in the sanitary napkin of Example 1 had the same basic configuration as the absorbent body 4C shown in FIG. .
An air-through nonwoven fabric having a basis weight of 30 g/m ² was used as the top sheet, and a polyethylene resin film (FL-KDJ100nN, manufactured by Taika Kogyo Co., Ltd.) of 37 g/m ² was used as the back sheet. The absorber uses fiber lumps and water-absorbing fibers as the fiber material of the absorbent core, and further uses a separately prepared core wrap sheet made of tissue paper with a basis weight of 16 g / m ² and uses a known fiber stacking device. manufactured. Specifically, a plate having a higher aperture ratio than the positions corresponding to the other regions F and R is arranged at a position corresponding to the longitudinal central region M of the absorbent body 4C in the fiber stacking drum of the fiber stacking device. While sucking from the opposite side of the plate, it was manufactured by first introducing the fiber clumps into the fiber stacking drum, stacking the fiber clumps, and then introducing the water-absorbing fibers. The fiber mass was produced by cutting the raw material fiber sheet into a diced shape. After producing a laminate by superimposing the top sheet and the absorbent body, the laminate is passed between a pair of rolls both having protrusions to form an annular surface closed on the skin facing surface (top sheet side). In addition to forming a concave portion, a similarly closed annular back concave portion was formed on the non-skin facing surface (non-skin side core wrap sheet side). Both concave portions formed in Example 1 were the same as the surface concave portion 7 shown in FIG.
As a raw material fiber sheet for the fiber mass, an air-through nonwoven fabric having a basis weight of 21 g/m ² made of non-absorbent thermoplastic fibers made of polyethylene and polyethylene terephthalate resin (a fiber sheet having a heat-sealed portion between the constituent fibers ) was used. Softwood bleached kraft pulp (NBKP) was used as water-absorbing fibers. The fiber mass (regular synthetic fiber assembly) used for the absorbent body has a rectangular parallelepiped main body as shown in FIG. 9 mm and the thickness T was 0.6 mm. The number of fiber ends per unit area on the basic surface 111 was 3.2/mm ² , and the number of fiber ends per unit area on the skeletal surface 112 was 19.2/mm ² .

[Example 2]
As the absorber, one having the same basic configuration as the absorber 4B shown in FIG. 5 was used. A sanitary napkin was produced in the same manner as in Example 1 except for the above points.

[Reference example]
As the absorber, the core-forming material (fiber mass and water-absorbing fibers) was uniformly distributed over the entire absorbent core. A sanitary napkin was produced in the same manner as in Example 1 except for the above points.

[Comparative example]
As the absorbent, a commercially available absorbent (manufactured by Unicharm Co., Ltd., trade name “Tanom Pew Slim 23 cm”) was used as it was. The absorber used in this comparative example is a mixture of synthetic fibers and cellulosic fibers (water-absorbent fibers) and does not contain fiber clumps. A sanitary napkin was produced in the same manner as in Example 1 except for the above points.

[Performance evaluation]
For the sanitary napkins of each example, reference example and comparative example, the compressive strain rate (ΔT/T ₀ ) of the absorber, the recovery work (WC'), the bending stiffness, and the liquid return amount were measured by the following methods. . The results are shown in Table 1 below.
<Method for measuring compression strain rate (ΔT/T ₀ )>
The compressive strain rate (ΔT/T ₀ ) of the sample can be measured using KES. Specifically, the compression strain rate (ΔT/T ₀ ) was measured using an automated compression tester KES-G5 manufactured by Kato Tech Co., Ltd. The measurement procedure is as follows.
Attach the measurement object (sanitary napkin) to the test table of the compression test device. Next, the object to be measured was compressed between steel plates having a circular plane with an area of 2 cm ² , and the load during compression was gradually increased until the load reached a predetermined maximum value (maximum load). The thickness (compressed thickness) _Tm of the object to be measured at that time is measured. Make sure there are no wrinkles or bends on the object to be measured. The measurement conditions of the compression tester are as follows.
・Compression speed: 0.2mm/sec
・Maximum load: 2450mN/ ^cm2
・SENS: 10
・DEF: 20
The initial thickness (T ₀ ) of the object to be measured was the thickness when the load was 103.9 mN/cm ² . Compressive strain rate (%) is calculated by the following formula. The greater the numerical value of such compression strain rate, the more excellent the flexibility of the measurement object (sanitary napkin), and the higher the evaluation.
Compressive strain rate (%) = {(T ₀ −T _m )/T ₀ )}×100

<Measurement method of compression work and recovery work>
The recovery work load (hereinafter also referred to as "WC'") of the measurement object (sanitary napkin) can generally be expressed as a value measured by KES (Kawabata Evaluation System) manufactured by Kato Tech Co., Ltd. (Reference: Standardization and Analysis of Texture Evaluation (Second Edition), author Toshio Kawabata, published on July 10, 1980). Specifically, WC' can be measured using a compression tester KES-G5 manufactured by Kato Tech Co., Ltd. The measurement procedure is as follows. When measuring WC', it is also possible to measure the work of compression (hereinafter also referred to as "WC").
Prepare an object to be measured (sanitary napkin) and attach it to the test table of the compression test device. Next, the portion of the object to be measured other than the concave portion is compressed between steel plates having a circular flat surface with an area of 2 cm ² . In this compression process, the compression speed is 0.2 cm/sec and the maximum compression load is 2450 mN/cm ² . The recovery process is also measured at the same speed. WC is represented by the following formula (1), and WC' is represented by the following formula (2), and the unit is "mN·cm/cm ² ". In the following formula, T _m indicates the thickness under a load of 2450 mN/cm ² (4.9 kPa), and T _O indicates the thickness under a load of 4.902 mN/cm ² (49 Pa). In addition, P _a in the following formula (1) and P _b in the following formula (2) are the measured load (mN/cm ² ) during the compression process and the measured load (mN/cm ² ) during the recovery process, respectively. indicates

Note that WC' is not displayed on the measurement result screen of KES-G5, and what is displayed on the measurement result screen is WC and the compression recovery rate or compression resilience calculated from WC' (hereinafter referred to as "RC ). In such a case, using the parameters (WC, RC) displayed on the measuring device, WC' is calculated by the following equation. According to the present inventors, the greater the value of WC′, the higher the compression recovery of the object to be measured (sanitary napkin), and the higher the evaluation.

<Measurement method of bending rigidity>
A sanitary napkin was used as a measurement sample and evaluated using a texture tester (handle-o-meter method, model HOM-3) manufactured by Daiei Kagaku Seiki Seisakusho Co., Ltd. First, a sanitary napkin was placed on a sample table having a slit width of 40 mm so that the longitudinal direction (longitudinal direction) of the sanitary napkin was perpendicular to the blade. The measurement sample was placed on the sample stage so that the bending stiffness measurement point of the measurement sample overlapped with the slit position of the sample stage. When measuring the bending stiffness of the front region of the sanitary napkin, the measurement point is a position 35 mm inward in the longitudinal direction from the longitudinal end of the front region (the front end of the napkin), and the rear region of the sanitary napkin. When measuring the bending stiffness, the measurement point is a position 35 mm inward in the longitudinal direction from the longitudinal end of the rear region (the rear end of the napkin), and the bending stiffness of the longitudinal central region of the sanitary napkin is measured. In this case, the center of the longitudinal center region in the longitudinal direction was used as the measurement point. Next, a blade set to be lowered by 10 mm from the surface of the sample stage was lowered to push the measurement sample, and the peak value (mN) at this time was taken as the value of the bending stiffness of the measurement sample. The sanitary napkin is judged to be more comfortable to wear as the flexural rigidity is smaller, and is highly evaluated.

<Method for measuring liquid return amount>
The sanitary napkin to be measured is spread flat and placed horizontally so that the surface facing the skin (surface sheet side) faces upward, and an oval injection port (long diameter 50 mm, short diameter 23 m) is placed on the napkin. ). 3 g of defibrinated horse blood manufactured by Nippon Biotest Laboratory Co., Ltd. and adjusted to have a viscosity of 8 mPa·s is weighed into a 10 cc injection beaker. Such a viscosity is a viscosity measured with a TVB-10M viscometer manufactured by Toki Sangyo Co., Ltd. using a rotor named L/Adp (rotor code 19) at a rotation speed of 12 rpm. After pouring this blood all at once into the inlet, it is left for 3 minutes, then 3 g is poured again, and the napkin is left for 5 minutes. Immediately after that, on the part of the napkin into which the blood was poured, a tissue (Kleenex (registered trademark) manufactured by Nippon Paper Crecia Co., Ltd.) was folded in three, and an absorbent paper and a rectangular parallelepiped weight with a weight of 300 g and a base area of 15 cm ² were placed. After 5 seconds, the weight of the absorbent paper is used to calculate the amount (g) of blood absorbed by the absorbent paper. The measurement is performed three times, and the average value is taken as the liquid return (wet back) amount of the napkin. The smaller the value of the liquid return amount, the more excellent the liquid absorbency of the sanitary napkin, and the higher the evaluation.

As shown in Table 1, in the sanitary napkins of each example, the absorbent body further contained fiber clumps in addition to the water-absorbing fibers, and the basis weight of the water-absorbing fibers in the absorbent body was "longitudinal center region > front region, Since the size relationship of "rear region" is established, compared to the sanitary napkin of the comparative example that does not satisfy this, the numerical value of the compression strain rate is large and the flexibility is excellent, and the numerical value of the recovery work is large and the compression recovery is good. It had excellent liquid absorbency, and the value of the amount of liquid returned was small. In addition, the sanitary napkins of each example had an excellent wearing feeling because the numerical value of the flexural rigidity was sufficiently small. In addition, the sanitary napkin of the reference example differs from the sanitary napkins of the respective examples mainly in that the above-mentioned size relationship is not established. Since the result was inferior in terms of the amount of liquid returned (liquid absorbency), it can be seen that establishing the above-described magnitude relationship is effective in improving the wearing comfort and liquid absorbency.

1 sanitary napkin (absorbent article)
F Front region M Vertical central region R Rear region 2 Top sheet 3 Back sheet 4, 4A, 4B, 4C, 4D, 4E Absorbent body 40 Absorbent core 41 Core wrap sheet 45 Absorbent body or skin facing surface of absorbent core 46 Absorption Non-skin facing surface of the body or absorbent core 47 Raised portion 5 Absorbent main body 6 Side sheet 7, 7X, 7Y Surface recessed portion 8, 8X, 8Y Back recessed portion 9 Low-density portion (fiber mass non-bonded region)
11 Fiber mass 11F Constituent fiber of fiber mass (synthetic fiber)
REFERENCE SIGNS LIST 110 body portion 111 basic surface 112 skeletal surface 113 extended fiber portion 113S extended fiber bundle portion 12F water absorbent fiber 13 water absorbent polymer

Claims (8)

A longitudinal center region having a longitudinal direction corresponding to the front-rear direction of the user and a lateral direction orthogonal thereto, and in the longitudinal direction, a longitudinal central region including an excretory part facing portion facing the excretion part of the user, and from the longitudinal central region An absorbent article that is divided into a front region arranged on the abdomen side of the user and a rear region arranged on the back side of the user from the longitudinal center region, and comprising an absorbent body,
The absorber contains water-absorbent fibers and fiber clumps containing weakly water-absorbent fibers having lower water absorbency than the water-absorbent fibers, and the fiber clumps or the fiber clumps and the water-absorbent fibers are separated from each other. are intertwined,
In the absorbent body, the absorbent article has a larger basis weight of the water-absorbent fibers in the longitudinal central region than in the front region and the rear region. 2. The absorbent article according to claim 1, wherein in the longitudinal central region, the non-skin-facing surface side of the absorbent body has a larger basis weight of the fiber mass than the skin-facing side of the absorbent body. 3. The absorbent according to claim 1 or 2, wherein the longitudinal central region has a larger ratio of the mass content of the fiber mass to the total mass content of the fiber mass and the water-absorbing fibers than the front region and the rear region. sexual goods. The absorbent body has a changing portion in which the thickness or basis weight of the water-absorbing fibers changes in the longitudinal direction, and the water-absorbing fibers and the fiber mass are entangled in the changing portion and before and after the changing portion. Item 4. The absorbent article according to any one of Items 1 to 3. The absorbent body includes an absorbent core containing the water-absorbing fibers and the fiber mass, and a core wrap sheet covering the surface of the absorbent core,
The absorbent article according to any one of claims 1 to 4, wherein the longitudinal central region has a fiber mass non-bonded region where the fiber mass and the core wrap sheet are not bonded. 6. The absorbent body according to claim 5, wherein a back sheet is provided on the non-skin facing side of the absorbent body, and the back sheet is joined to a portion of the core wrap sheet covering the non-skin facing side of the absorbent core. The absorbent article described. A topsheet provided on the skin-facing side of the absorbent body and a backsheet provided on the non-skin-facing side of the absorbent body, wherein the topsheet and the absorbent body are integrally formed on the backsheet side. A recessed surface is formed in the
The surface recesses include a pair of surface vertical recesses extending in the vertical direction, and the pair of surface vertical recesses are located on both sides of the vertical center region with the center portion in the horizontal direction interposed therebetween,
6. The absorbent article according to claim 5, wherein said fiber clump non-bonded region exists in a region sandwiched between said pair of surface vertical depressions. 8. The absorbent article according to claim 7 , wherein the backsheet is joined to a portion of the core wrap sheet covering the non-skin facing surface of the absorbent core.

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