JP6990095B2 - Absorber and absorbent article - Google Patents

Description

The present invention relates to an absorber for an absorbent article.

Absorbent articles such as disposable diapers and sanitary napkins generally include a front sheet that is placed relatively close to the wearer's skin and a back sheet that is placed relatively far from the wearer's skin. , Consists of an absorber interposed between the two sheets. This absorber is typically composed mainly of water-absorbent fibers (water-absorbent fibers) such as wood pulp, and further contains water-absorbent polymer particles. For absorbers used in absorbent articles, improving various properties such as flexibility (cushioning property), compression recovery property, and shape retention property is a major issue.

As a technique for improving the absorber, for example, Patent Document 1 describes the synthesis of hydrophobic fibers having a longer fiber length than the pulp fibers, for example, polypropylene which has not been hydrophilized, in the absorber mainly composed of pulp fibers and water-absorbent polymers. It is described that the fibers are dispersed in the pulp fibers. According to Patent Document 1, such an absorber does not have a reversion phenomenon of body fluid due to the presence of hydrophobic fibers, and the strength is increased by entwining hydrophobic fibers having a long fiber length with pulp fibers. It is said that good shape retention can be maintained.

Further, in Patent Document 2, unfused pressed portions are arranged in a repeated pattern on an absorber in which a cellulosic water-absorbent fiber and a thermoplastic resin fiber having a longer fiber length are entangled with each other. As a result, it is described that an absorber having both softness and strength can be obtained.

Further, Patent Document 3 describes an absorber containing heat-sealed fibers, a non-woven fabric piece in which the fibers are bonded in advance to give a three-dimensional structure, and water-absorbent fibers. This non-woven fabric piece having a three-dimensional structure is manufactured by crushing the non-woven fabric into small pieces using a crushing means such as a cutter mill method, and FIGS. 1 and 1 of the same document are produced due to such a manufacturing method. As described in No. 3, it has an indefinite shape and does not substantially have a portion that can be regarded as a flat surface. Patent Document 3 describes a preferred form of the absorber described in the same document in which non-woven fabric pieces are heat-fused together. According to the absorber described in Patent Document 3, since the non-woven fabric piece has a three-dimensional structure, voids are formed inside the absorber, and the resilience when absorbing water is improved, and as a result, the water absorption performance is improved. It is said that.

Further, Patent Document 4 describes a fine web having a relatively dense fine fiber nucleus and a fiber or a fiber bundle extending outward from the nucleus, and the fine web and wood pulp or a water-absorbing polymer. It is described that a non-woven web mixed with particles can be used as an absorber for absorbent articles. This fine web is manufactured by peeling or tearing off a raw material sheet such as a non-woven fabric, and has an irregular shape and can be regarded as a flat surface like the non-woven fabric piece described in Patent Document 3. Substantially does not have.

Japanese Unexamined Patent Publication No. 2004-73698 Japanese Unexamined Patent Publication No. 2016-10594 JP-A-2002-301105 Japanese Unexamined Patent Publication No. 1-156560

In each of the absorbers described in Patent Documents 1 and 2, a plurality of synthetic fibers contained therein are individually present independently and do not form a single cohesive mass, so that various properties thereof are improved. The effect is not sufficient and therefore, when applied to absorbent articles, it may be easily twisted and the fit may be inadequate, especially after absorption of body fluids such as urine and menstrual blood. The outbreak is remarkable.

On the other hand, as described above, the synthetic fiber aggregate contained in the absorbers described in Patent Documents 3 and 4 has an indefinite shape and does not have the same shape and size, and as a result, the synthetic fiber aggregate and the like are combined with pulp fibers and the like. When mixed, it is difficult to obtain a uniform mixture of the two, and there is a possibility that the desired effect cannot be obtained. In addition, these synthetic fiber aggregates disclosed in the literature are manufactured by crushing, stripping, or tearing off a non-woven fabric mainly composed of synthetic fibers into small pieces, so that the surface is randomly roughened. It is presumed that it is. In such an absorber containing a large number of synthetic fiber aggregates having a rough surface as a whole, the plurality of synthetic fiber aggregates are entangled with each other with a relatively strong binding force over the entire surface thereof, and as a result, each of them is entangled with each other. The degree of freedom of movement of the synthetic fiber aggregate is significantly limited, and the softness of the absorber is impaired. Further, as in the preferred form of the absorber described in Patent Document 3, when all the synthetic fiber aggregates contained in the absorber are heat-fused together, the movement of the absorber itself is restricted, and as a result, the absorber itself is restricted. The hardness as a whole may increase, and various properties such as flexibility may decrease.

Therefore, the subject of the present invention is an absorber that has excellent cushioning properties when wet and, when applied to an absorbent article, can improve the wearing feeling at the excretory part even after absorbing the body fluid, and the absorber. Concerning the provision of used absorbent articles.

The present invention is an absorber containing a fiber mass containing synthetic fibers and a water-absorbing fiber, and a plurality of the fiber masses or the fiber mass and the water-absorbing fiber are entangled with each other. Has a main body portion defined by two basic surfaces facing each other and a skeleton surface intersecting both basic surfaces, and a compacted portion in which the absorber is recessed in a compacted state is formed on the surface of the absorber. The partially formed and compacted portion and the non-consolidated portion, which is a portion of the absorber in which the compacted portion is not formed, are alternately arranged in a predetermined direction. It is an absorber in which the fiber lumps are not fused.
Further, the present invention is an absorbent article comprising the above-mentioned absorber of the present invention.

The absorber of the present invention has excellent cushioning properties when wet, and when applied to an absorbent article, can improve the wearing feeling at the excretory part even after absorbing the body fluid.
Further, since the absorbent article of the present invention is provided with such a high-quality absorbent body, it is excellent in wearing feeling and leak-proof property.

FIG. 1 is a plan view schematically showing an example of a sanitary napkin according to an embodiment of the absorbent article of the present invention, with the skin facing surface side (surface sheet side) partially broken. FIG. 2 is a cross-sectional view schematically showing the I-I line cross section of FIG. FIG. 3 is a schematic perspective view of a part (a portion located in the non-consolidated portion) of the absorbent core included in the absorbent article shown in FIG. FIG. 4 is a diagram schematically showing a deformed state of the absorbent core shown in FIG. 3 during compression. 5 (a) and 5 (b) are schematic perspective views of the fiber mass according to the present invention, respectively. FIG. 6 is an explanatory diagram of a method for producing a fiber mass according to the present invention. FIG. 7 (a) is an electron micrograph (observation magnification 25 times) of an example of the fiber mass according to the present invention, and FIG. 7 (b) is the fiber mass contained in the absorbent core shown in FIG. It is a figure which showed schematically the fiber mass of an electron micrograph. FIG. 8 is a plan view schematically showing the skin facing surface side (surface sheet side) of another example of the sanitary napkin according to the embodiment of the absorbent article of the present invention. FIG. 9 is a plan view schematically showing the skin facing surface side (surface sheet side) of another example of the sanitary napkin according to the embodiment of the absorbent article of the present invention. FIG. 10 is a plan view schematically showing the skin facing surface side (surface sheet side) of another example of the sanitary napkin according to the embodiment of the absorbent article of the present invention.

Hereinafter, the absorber of the present invention will be described together with the absorbent article of the present invention comprising the absorber with reference to the drawings based on their preferred embodiments. 1 and 2 show a sanitary napkin 1 (hereinafter, also referred to as napkin 1), which is an embodiment of the absorbent article of the present invention. The napkin 1 has an absorber 4 that absorbs and retains body fluid, a liquid-permeable surface sheet 2 that is arranged on the skin-facing surface side of the absorber 4 and can come into contact with the wearer's skin, and a non-skin-facing surface of the absorber 4. It is provided with a liquid impervious back sheet 3 arranged on the surface side. As shown in FIG. 1, the napkin 1 has a vertical direction X extending from the ventral side of the wearer to the dorsal side via the crotch portion and a lateral direction Y orthogonal to the vertical direction X corresponding to the front-back direction of the wearer. In the vertical direction X, the vertical central region B including the excretion portion facing portion (excretion point) facing the excretion portion such as the wearer's genital region and the wearer's ventral side (anterior side) of the excretion portion facing portion. ), And the posterior region C, which is located on the back side (rear side) of the wearer from the excretory portion facing portion.

In the present specification, the "skin facing surface" is a surface of the absorbent article or its constituent members (for example, the absorbent body 4) that is directed toward the skin side of the wearer when the absorbent article is worn, that is, relatively of the wearer. The side closer to the skin, the "non-skin facing surface" is the side of the absorbent article or its constituents that is opposite to the skin side when the absorbent article is worn, that is, toward the side relatively far from the wearer's skin. It is the surface to be. The term "when worn" as used herein means a state in which a normal proper wearing position, that is, a correct wearing position of the absorbent article is maintained.

As shown in FIG. 1, the napkin 1 has an absorbent main body 5 having a shape long in the vertical direction X and both side portions of the absorbent main body 5 along the vertical direction X in the vertical central region B toward the outside in the horizontal direction Y. It has a pair of extending wing portions 5W and 5W. The absorbent main body 5 is a portion that forms the main body of the napkin 1, includes the front surface sheet 2, the back surface sheet 3, and the absorbent body 4, and has the front region A, the vertical center region B, and the rear region C in the vertical direction X. It is divided into three categories.

The vertical central region of the absorbent article of the present invention is a wing in the vertical direction (longitudinal direction, X direction in the figure) of the absorbent article when the absorbent article has a wing portion as in the napkin 1. It means a region having a portion, and taking the napkin 1 as an example, it is a region sandwiched between a root along the vertical direction X of one wing portion 5W and a root along the vertical direction X of the other wing portion 5W. Further, the vertical central region of the absorbent article having no wing portion means a region located in the center when the absorbent article is divided into three equal parts in the vertical direction.

In the napkin 1, the absorber 4 includes a liquid-absorbable absorbent core 40 and a liquid-permeable core wrap sheet 41 that covers the outer surface of the absorbent core 40. Like the absorbent body 5, the absorbent core 40 has a long shape in the vertical direction X in a plan view as shown in FIG. 1, and the longitudinal direction of the absorbent core 40 is one with respect to the vertical direction X of the napkin 1. However, the width direction of the absorbent core 40 coincides with the lateral direction Y of the napkin 1. The absorbent core 40 and the core wrap sheet 41 may be bonded by an adhesive such as a hot melt type adhesive.
As described above, the absorber 4, which is an embodiment of the absorber of the present invention, is used for an absorbent article such as a napkin 1, and has a vertical direction X corresponding to the front-rear direction of the wearer of the napkin 1 and this. It has a horizontal direction Y orthogonal to the above direction, and is divided into three areas, a front area A, a vertical center area B, and a rear area C in the vertical direction X.

In the napkin 1, the core wrap sheet 41 is one continuous sheet having a width of 2 times or more and 3 times or less the length of the lateral Y of the absorbent core 40, and as shown in FIG. 2, it absorbs. It covers the entire skin-facing surface of the sex core 40 and extends outward in the lateral direction Y from both side edges along the vertical direction X of the absorbent core 40, and the extending portion thereof is below the absorbent core 40. It is rolled down to cover the entire non-skin facing surface of the absorbent core 40. In the present invention, the core wrap sheet does not have to be such a single sheet, for example, one skin-side core wrap sheet that covers the skin-facing surface of the absorbent core 40 and the skin-side. It may be a separate body from the core wrap sheet, and may include two sheets including one non-skin side core wrap sheet that covers the non-skin facing surface of the absorbent core 40.

As shown in FIG. 2, the surface sheet 2 covers the entire surface of the absorber 4 facing the skin. On the other hand, the back surface sheet 3 covers the entire non-skin facing surface of the absorber 4, further extends outward in the lateral direction Y from both side edges along the vertical direction X of the absorber 4, and together with the side sheet 6 described later. It forms a side flap portion. The side flap portion is a portion of the napkin 1 made of a member extending outward in the lateral direction Y from the absorber 4. The back surface sheet 3 and the side sheet 6 are bonded to each other by known bonding means such as an adhesive, a heat seal, and an ultrasonic seal at the extending portions from both side edges of the absorber 4 along the vertical direction X. Each of the front surface sheet 2 and the back surface sheet 3 and the absorber 4 may be bonded by an adhesive. As the front surface sheet 2 and the back surface sheet 3, various types conventionally used for absorbent articles such as sanitary napkins can be used without particular limitation. For example, as the surface sheet 2, a non-woven fabric having a single-layer or multi-layer structure, a perforated film, or the like can be used. As the back sheet 3, a moisture-permeable resin film or the like can be used.

As shown in FIG. 1, the side flap portions greatly project outward in the horizontal direction Y in the vertical central region B, whereby a pair of side flap portions are formed on the left and right sides of the absorbent main body 5 along the vertical direction X. Wings 5W and 5W are extended. The wing portion 5W has a substantially trapezoidal shape in which the lower base (the side longer than the upper base) is located on the side portion side of the absorbent main body 5 in a plan view as shown in FIG. 1, and the non-skin facing surface thereof. Is formed with a wing portion adhesive portion (not shown) for fixing the wing portion 5W to clothing such as shorts. The wing portion 5W is used by being folded back toward the non-skin facing surface (outer surface) side of the crotch portion of clothing such as shorts. Before its use, the adhesive portion of the wing portion is covered with a release sheet (not shown) made of a film, a non-woven fabric, paper or the like. Further, a pair of both side portions of the absorbent body 5 on the skin-facing surface, that is, the skin-facing surface of the surface sheet 2 along the vertical direction X, overlap with the left and right side portions of the absorbent body 4 along the vertical direction X in a plan view. Side sheets 6 and 6 are arranged over substantially the entire length of the absorbent body 5 in the vertical direction X. The pair of side sheets 6 and 6 are joined to another member such as the surface sheet 2 by a known joining means such as an adhesive by a joining line (not shown) extending in the vertical direction X, respectively.

As shown in FIGS. 1 and 2, a plurality of compacted portions 7 in which the absorber 4 is recessed in a compacted state are partially formed on the surface of the absorber 4. More specifically, in the napkin 1, a plurality of compacted portions 7 having a circular shape in a plan view are formed on the skin-facing surface of the absorber 4, that is, the surface facing the surface sheet 2, and the plurality of compacted portions 7 are formed. The portion of the core wrap sheet 41 that covers the skin-facing surface of the absorbent core 40 (skin-side core wrap sheet) and the absorbent core 40 are integrally recessed in the non-skin-facing surface side of the absorber 4, respectively. It is a department. On the skin-facing surface of the absorber 4, a consolidated portion 7 which is a concave portion and a non-consolidated portion 8 which is a portion where the compacted portion 7 is not formed in the absorber 4 are mixed, and corresponds to the consolidated portion 7. An uneven structure including a concave portion and a convex portion corresponding to the non-consolidated portion 8 is formed. On the other hand, the compaction portion 7 is not formed on the non-skin facing surface of the absorber 4, that is, the facing surface with the back surface sheet 3, and the non-skin facing surface of the absorber 4 is flat with substantially no uneven structure. It is a face.

The compaction portion 7 presses the absorber 4, that is, the composite of the absorbent core 40 and the core wrap sheet 41 covering the absorber 4 from the skin facing surface, that is, the skin side core wrap sheet 41 side of the absorber 4. It is formed by applying a squeezing process, and can also be called a "squeezed portion" from the forming method. The compacted portion 7 has a higher density than the non-consolidated portion 8 due to the formation method thereof. That is, the absorber 4 has a high-density portion corresponding to the compacted portion 7 and a low-density portion corresponding to the non-consolidated portion 8.

Further, in the compaction portion 7, the constituent fibers of the absorber 4, specifically, the constituent fibers 11F and the water-absorbing fibers 12F of the fiber mass 11 described later are in a compacted state, but the fiber masses 11 are fused to each other. Not. That is, for example, when the synthetic fiber which is the constituent fiber 11F of the fiber mass 11 is a thermoplastic fiber, the pressing process for forming the compacted portion 7 is performed under the condition that the fiber 11F which is the thermoplastic fiber is melted. In the case where, more specifically, for example, when the compacted portion 7 is formed by embossing with heat, ultrasonic embossing, or the like, at least the fiber lumps 11 are heat-sealed in the compacted portion 7, and a plurality of fiber lumps are fused. 11 can be bonded by heat fusion between the constituent fibers 11F to form one fiber mass continuum, but in the compaction portion 7 of the napkin 1, the constituent fibers 11F are fused between the plurality of fiber masses 11. There is no wearing part.

In the compacted portion 7, the plurality of fiber lumps 11 are not fused to each other, but the constituent fibers 11F may be fused to each other in one fiber lump 11. That is, one of the preferred forms of the fiber mass 11 is one in which a plurality of constituent fibers 11F (thermoplastic fibers) have a three-dimensional structure in which heat-sealed to each other, and in one fiber mass 11, the constituent fibers 11 have a three-dimensional structure. The 11th floors are fused together. Details of this preferred fiber mass 11 will be described later.

Further, in the napkin 1, in addition to the fact that the fiber lumps 11 are not fused to each other in the compacted portion 7, the fiber lumps 11 and the water-absorbent fibers 12F are not fused to each other.

One of the main characteristic portions of the napkin 1 is the absorbent body 4, particularly the absorbent core 40 which is the main body of the absorbent body 4. FIG. 3 shows a part of the absorbent core 40 (a portion located in the non-consolidated portion 8). As shown in FIGS. 2 and 3, the absorber 4, more specifically, the absorbent core 40 includes a fiber mass 11 in which a plurality of fibers (synthetic fibers) 11F are accumulated in a mass, and a water-absorbing fiber 12F. .. The fiber mass 11 is a fiber aggregate in which the fibers 11F are intentionally integrated and integrated, whereas the water-absorbent fiber 12F is absorbed in a state where it can exist independently without being intentionally integrated. It is present in the sex core 40. The fiber mass 11 mainly contributes to the improvement of the flexibility, cushioning property, compression recovery property, shape retention property and the like of the absorbent core 40. On the other hand, the water-absorbent fiber 12F mainly contributes to the improvement of the liquid absorbency and the shape-retaining property of the absorbent core 40. The absorbent core 40 can be said to be substantially the absorber 4 itself, and the following description of the absorbent core 40 is appropriately applied as a description of the absorbent body 4 unless otherwise specified. That is, the present invention includes a case where the absorber is formed only of the absorbent core without containing the core wrap sheet, and in that case, the absorber and the absorbent core have the same meaning.

As used herein, the term "fiber mass" is a fiber aggregate in which a plurality of fibers are grouped together and integrated. Examples of the form of the fiber mass include a sheet piece divided from a synthetic fiber sheet having a certain size. In particular, a non-woven fabric is selected as the synthetic fiber sheet, and a non-woven fabric piece cut out from the non-woven fabric into a predetermined size and shape is preferable as the fiber mass.

As described above, the sheet piece-shaped fiber mass, which is a preferred embodiment of the fiber mass according to the present invention, is not configured to accumulate a plurality of fibers to form the sheet piece, but rather than the sheet piece. It is also manufactured by cutting a fiber sheet (preferably a non-woven fabric) having a large size (see FIG. 6). The plurality of fiber lumps contained in the absorber (absorbent core) of the present invention are a plurality of sheet piece-like fibers having higher stereotypes as compared with those produced by conventional techniques such as Patent Documents 3 and 4. It is a lump.

Further, in the absorbent core 40, a plurality of fiber lumps 11 or the fiber lumps 11 and the water-absorbent fiber 12F are entangled with each other. Typically, the plurality of fiber lumps 11 and the fiber lumps 11 and the water-absorbent fiber 12F are entangled with each other. In the absorbent core 40, not only the non-consolidated portion 8 which has not been squeezed and the original shape of the absorbent core 40 is maintained, but also the squeezed portion is applied, and the constituent fibers 11F and 12F are in a consolidated state. Also in the consolidated portion 7, a plurality of fiber lumps 11 are combined by entanglement between the constituent fibers 11F to form one fiber lump continuum, and the fiber lump continuum absorbs water. The fibers 12F are entwined and bonded. Further, in the absorbent core 40, the plurality of water-absorbent fibers 12F are also entangled with each other. At least a part of the plurality of fiber lumps 11 contained in the absorbent core 40 is entangled with other fiber lumps 11 or the water-absorbent fiber 12F. In the absorbent core 40, all of the plurality of fiber masses 11 contained therein may be entangled with each other to form one fiber mass continuum, and the plurality of fiber mass continuums may be non-existent with each other. It may be mixed in the combined state. The entanglement of the fiber lumps 11, that is, the ease of entanglement with other fiber lumps 11 or the water-absorbent fiber 12F, is the form (number, size, distribution state, etc.) of the extended fiber portion 113 described later in the fiber lumps 11. ), And by appropriately controlling the morphology of the extended fiber portion 113, the entanglement of the fiber mass 11 can be enhanced.

The "entanglement" of the fiber lumps 11 and the like includes the following forms A and B.
Form A: A form in which the fiber lumps 11 and the like are not fused but are bonded by the entanglement of the constituent fibers 11F of the fiber lumps 11.
Form B: In the natural state of the absorbent core 40 (a state in which no external force is applied), the fiber lumps 11 and the like are not bonded to each other, but in a state where the absorbent core 40 is subjected to an external force, the fiber lumps 11 and the like are not bonded to each other. A form that can be bonded by entanglement of constituent fibers 11F. The "state in which an external force is applied to the absorbent core 40" as used herein is, for example, a state in which a deformable force is applied to the absorbent core 40 while the absorbent article to which the absorbent core 40 is applied is being worn. ..

In the absorbent core 40 of the present embodiment, as in the form A, the fiber mass 11 is bonded to the other fiber mass 11 or the water-absorbent fiber 12F by entanglement, that is, "entanglement" between the fibers, and the form B. As described above, it also exists in a state where it can be entangled with another fiber mass 11 or the water-absorbent fiber 12F. The binding of the fibers by entanglement is one of the important points for more effectively expressing the action and effect of the above-mentioned absorbent core 40. However, it is preferable to have the "entanglement" of Form A from the viewpoint of shape retention. The entanglement of the fiber lumps 11 has no adhesive component or fusion, and is performed only by the entanglement of the fibers. The entangled individual elements (fiber mass 11, water-absorbent fiber 12F) have a high degree of freedom of movement, so that the individual elements can move to the extent that they can maintain their integrity as an aggregate. .. As described above, the absorbent core 40 is deformed when it receives an external force because the plurality of fiber lumps 11 contained therein or the fiber lumps 11 and the water-absorbent fiber 12F are relatively loosely bonded to each other. It has a possible and gentle shape retention property, and has both shape retention property, cushioning property, compression recovery property, and the like at a high level.

Since the fiber lump 11 is excellent in flexibility and the like, by including it in the absorber, the absorber is potentially excellent in flexibility and the like. In this respect, as described above, the absorbent core 40 contains a plurality of fiber lumps 11 and the fiber lumps 11 and the water-absorbent fiber 12.
At least one of the fibers with F is entangled with each other, and preferably both of the plurality of fiber lumps 11 and between the fiber lumps 11 and the water-absorbent fiber 12F are entangled with each other. It has excellent shape retention, flexibility, cushioning, compression recovery, etc., and when incorporated into an absorbent article such as the absorbent core 40 in napkin 1, it receives external force from various directions (for example, wearing an absorbent article). It deforms flexibly with respect to the body pressure of the person), and the absorbent article can be brought into close contact with the wearer's body with good fit.

FIG. 4 schematically shows a deformed state when the absorbent core 40 of the non-consolidated portion 8 is compressed by receiving an external force F. In the absorbent core 40 in which the fiber mass 11 which is a fiber aggregate and the water-absorbent fiber 12F which is a non-fiber aggregate coexist, the boundary between the two members 11 and 12F due to the difference in rigidity between the two members 11 and 12F. BL (dotted line in FIG. 4) is particularly easy to bend, and where the boundary BL functions as a bending portion when the absorbent core 40 is deformed, the boundary BL as the bending portion is usually the absorbent core of the non-compacted portion 8. Since it exists over the entire area of 40, the absorbent core 40 flexibly deforms in a responsive manner to various external forces, and when the external force is released, the fiber mass 11 is provided with compression recovery. It can be quickly restored to its original state depending on the sex. Such deformation-recovery properties of the absorbent core 40 can be similarly manifested not only when the absorbent core 40 is compressed, but also when it is twisted. That is, since the absorbent core 40 incorporated in the napkin 1 is arranged in a state of being sandwiched between both thighs of the wearer when the napkin 1 is worn, the absorber 4 is the walking motion of the wearer. Depending on the movement of both thighs at this time, it may be twisted around a virtual axis of rotation extending in the vertical direction X, but even in such a case, at least the absorbent core 40 of the non-compacted portion 8 is highly deformed- Since it has recovery characteristics, it easily deforms and recovers against external forces that promote twisting from both thighs, and therefore is less likely to twist, and can impart a high fit to the wearer's body to the napkin 1.

Further, in the absorbent core 40, as described above, the compacted portion 7 and the non-consolidated portion 7 are partially formed on the surface (the surface facing the skin) of the absorbent core 4 in a compacted state. 8 are alternately arranged in a predetermined direction, whereby the consolidated portion 7 which is a relatively high density portion and the non-consolidated portion 8 which is a relatively low density portion are arranged. It coexists in the plane direction of the absorbent core 40. That is, in the absorbent core 40, a density difference occurs in the surface direction, and the density difference makes it easy for the body fluid to be diffused in the surface direction. Therefore, the napkin 1 provided with the absorbent core 40 can rapidly diffuse the body fluid excreted by the wearer in the plane direction, which is unpleasant due to the residual body fluid remaining in the excretion portion facing portion or the like. It is less likely to cause stickiness or wetness on the skin and is excellent in dry feeling. As a result, the absorbent core 40 is excellent in cushioning property due to the action and effect of the fiber lump 11, and is excellent in wearing feeling. In addition, it is possible to effectively utilize the absorption performance inherent in the absorbent core 40, and it is also excellent in liquid absorption and leakage prevention property of body fluid.

Further, in the absorbent core 40, it is preferable that the fiber mass 11 existing in the compacted portion 7 is entangled with the water-absorbing fiber 12F via the constituent fiber 11F. As a result, body fluid such as menstrual blood that comes into contact with the absorbent core 40 and is drawn into the skin facing surface side is present at the fiber mass 11 via the entanglement site between the fiber mass 11 and the water-absorbing fiber 12F. It becomes easier to be carried to the compacted portion 7, and by extension, the effect of rapid liquid diffusion in the plane direction of the absorbent core 40 becomes easier to be exhibited, and further, the absorbent core 40 cushions even when the liquid is absorbed. Become excellent in sex.

Further, in the compacted portion 7, since there is no bond due to fusion between the plurality of fiber lumps 11, the absorbent core 40 as a whole is soft and high cushioning property can be easily obtained. In particular, in the napkin 1, as described above in the compacted portion 7, the fiber lumps 11 are not fused to each other, and further, the fiber lumps 11 and the water-absorbent fibers 12F are not fused to each other, so that the napkin 1 is absorbent. The core 40 is particularly excellent in flexibility and cushioning property.

The pattern (shape and arrangement in plan view) of the consolidation portion 7 can be arbitrarily designed. Considering that one of the main roles of the consolidation portion 7 is to improve the liquid diffusivity in the plane direction of the absorber 4, the consolidation portion 7 is arranged at a portion of the absorber 4 that frequently contacts the body fluid. It is preferable, and from such a viewpoint, it is preferable that it is partially formed in the vertical central region B including the excretion portion facing portion.

As shown in FIG. 1, the pattern of the consolidated portion 7 of the absorber 4 (absorbable core 40) in the napkin 1 includes a pattern in which the consolidated portions 7 and the non-consolidated portions 8 are alternately arranged in a predetermined direction. It is composed of. More specifically, in the napkin 1, a plurality of consolidated portions 7 having a circular shape in a plan view are arranged in a staggered manner over the entire surface of the absorber 4 facing the skin, and the plurality of compacted portions 7 are arranged in the vertical direction X. It is arranged at equal intervals, and a plurality of compacted portions 7 are arranged at equal intervals in a direction intersecting both the vertical direction X and the horizontal direction Y. The non-consolidated portion 8 is located between the two consolidated portions 7 and 7 adjacent to each other in each direction.

Here, the staggered pattern means that a plurality of rows in which a plurality of consolidated portions 7 are arranged at equal intervals in one direction are arranged in a direction orthogonal to the one direction and adjacent to each other in a direction orthogonal to the one direction. It refers to an arrangement in which a plurality of compacted portions 7 are displaced from each other in two rows. More specifically, when a plurality of rows in which the plurality of compacted portions 7 are arranged at equal intervals in one direction are projected in a direction orthogonal to the one direction, each of the consolidated portions 7 in a specific row is projected. When the projection image of the consolidation portion 7 of another row adjacent to the specific row is arranged between the projection images of (preferably in the middle), the plurality of consolidation portions 7 are arranged in a staggered manner. I can say. The "staggered arrangement" in the present invention includes not only a form in which a plurality of compacted portions 7 are perfectly arranged as described above, but also a slight unintended arrangement such as an unavoidable deviation in manufacturing. The form in which the deviation occurs is also included.

Further, the pattern of the compacted portion 7 of the absorber 4 in the napkin 1 is an isotropic pattern in which the body fluid is isotropically diffused in the plane direction. That is, on the skin-facing surface of the absorber 4,
When a plurality of rows (consolidated portion columns) in which a plurality of consolidated portions 7 are arranged in the vertical direction X are arranged in the horizontal direction Y, three rows adjacent to each other in the horizontal direction Y from the plurality of compacted portion columns (FIG. (Indicated by the symbol 7Lx in 1) is arbitrarily selected, and when attention is paid to any one consolidation portion 7 belonging to the central row of the three rows 7Lx, the one consolidation portion 7 of interest and the three Among the other consolidation portions 7 belonging to the row 7Lx, the pitch 7P1 (see FIG. 1) with the one closest to the one consolidation portion 7 is the same as each other. The term "pitch" as used herein means the length of a straight line connecting the centers of the two consolidated portions 7 and 7 adjacent to each other at predetermined intervals in a plan view. When the compacted portions 7 are arranged in such an isotropic pattern, for example, when the body fluid of the wearer of the napkin 1 is first received at the excretion portion facing portion located in the central portion of the vertical central region B. , The body fluid can diffuse substantially uniformly radially in the plane direction from the excretory portion facing portion.

From the viewpoint of more reliably achieving the effects caused by the presence of the consolidated portion 7 and the non-consolidated portion 8 described above, it is preferable to set the dimensions and the like of each portion of the napkin 1 as follows.
The pitch 7P1 (see FIG. 1), that is, the pitch of the two closest compacted portions 7 and 7, is preferably 2.0 mm or more, more preferably 3.5 mm or more, and preferably 12 mm or less, still more preferably. It is 10 mm or less. In the napkin 1, the pitch 7Px of the consolidation portion 7 in the vertical direction X and the pitch 7Pz of the consolidation portion 7 in the direction intersecting both the directions X and Y are the pitch 7P1 and 7Px = 7Pz.
Further, regarding the pitch of the consolidation portion 7, the napkin 1 has a pitch 7P2 (see FIG. 1) longer than the pitch 7P1 (relatively short pitch), and the pitch 7P2 is relatively long. Is preferably 3.0 mm or more, more preferably 5.0 mm or more, and preferably 15 mm or less, still more preferably 13 mm or less. In the napkin 1, the pitch 7Py of the consolidation portion 7 in the lateral direction Y is the pitch 7P2. That is, in the napkin 1, the pitch 7Px (7P1) of the consolidated portion 7 in the vertical direction X is shorter than the pitch 7Py (7P2) of the consolidated portion 7 in the horizontal direction Y.

The ratio of the total area of the consolidation portion 7 to the total area of the formation surface (skin facing surface in the napkin 1) of the consolidation portion 7 of the absorber 4 (absorbent core 40) (consolidation portion occupancy rate) is preferably 5. % Or more, more preferably 10% or more, and preferably 40% or less, still more preferably 30% or less.
The number of the consolidated portions 7 existing in an arbitrary 10 mm square unit region on the surface of the absorber 4 is preferably 2 or more, more preferably 5 or more, and preferably 10 or less, still more preferably 8. Less than or equal to.

The maximum transfer length 7R (see FIG. 1) in the plan view of the consolidation portion 7 is preferably 0.5 mm or more, more preferably 1 mm or more, and preferably 8 mm or less, still more preferably 6 mm or less. The maximum transfer length 7R is a diameter when the consolidated portion 7 has a circular shape as shown in FIG. 1.
The shape of the compacted portion 7 in a plan view is not particularly limited, and may be an ellipse, a rectangle, a triangle, a star, a heart, or the like, in addition to the circular shape as shown in FIG. Further, as shown in FIG. 1, the shapes and dimensions of the plurality of compacted portions 7 dispersed and arranged in a scattered pattern may not be uniform with each other or may be different from each other.
The depth of the compacted portion 7 (the depth from the non-recessed skin facing surface in the absorber 4) is preferably 0.10 mm or more, more preferably 0.25 mm or more, and preferably 1.50 mm or less, further. It is preferably 1.00 mm or less.

Hereinafter, the absorber 4 will be further described. Unless otherwise specified, the following description of the absorber 4 is the original appearance of the absorber 4 of the non-consolidated portion 8, that is, a state in which the non-consolidated portion 8 is not subjected to squeezing processing and can exhibit the original function. It is about the absorber 4 of. Further, the following description of the absorber 4 is appropriately applied to the absorbent core 40 unless otherwise specified (the word "absorbent 4" can be appropriately replaced with "absorbent core 40").

One of the main features of the absorber 4 is the outer shape of the fiber mass 11. FIG. 5 shows two typical outer shapes of the fiber mass 11. The fiber mass 11A shown in FIG. 5A has a rectangular parallelepiped shape more specifically than the prismatic shape, and the fiber mass 11B shown in FIG. 5B has a disk shape. The fiber lumps 11A and 11B are common in that they include two opposing base planes 111 and a skeleton plane 112 connecting the two base planes 111. Both the basic surface 111 and the skeleton surface 112 are at a level applied when evaluating the degree of surface unevenness in an article mainly composed of this type of fiber, and are portions where it is recognized that there is substantially no unevenness.

The rectangular parallelepiped-shaped fiber mass 11 in FIG. 5A has six flat surfaces, of which two facing surfaces having the maximum area are the basic surfaces 111, and the rest. Each of the four surfaces is a skeletal surface 112. The basic surface 111 and the skeleton surface 112 intersect each other, and more specifically, are orthogonal to each other.
The disk-shaped fiber mass 11B of FIG. 5B has two flat surfaces facing each other in a circular shape in a plan view and a curved peripheral surface connecting the two flat surfaces, where the two flat surfaces are formed. Each surface is a basic surface 111, and the peripheral surface is a skeleton surface 112.
The fiber lumps 11A and 11B are also common in that the skeleton surface 112 has a quadrangular shape, more specifically, a rectangular shape in a plan view.

Each of the plurality of fiber lumps 11 contained in the absorber 4 includes two opposing basic surfaces 111 and a skeleton surface 112 connecting both basic surfaces 111, such as the fiber lumps 11A and 11B shown in FIG. It is different from the non-woven fabric pieces or fine webs described in Patent Documents 3 and 4, which are irregular fiber aggregates, in that they are "standard fiber aggregates". In other words, when any one fiber mass 11 in the absorber 4 is seen through (for example, when observed with an electron microscope), the fluoroscopic shape of the fiber mass 11 differs depending on the observation angle, and one fiber mass. Where there are a large number of perspective shapes per 11, each of the plurality of fiber lumps 11 in the absorber 4 is a skeleton that connects two opposing basic surfaces 111 and both basic surfaces 111 as one of the many perspective shapes. It has a specific perspective shape with a surface 112. The plurality of non-woven fabric pieces or fine webs contained in the absorbers described in Patent Documents 3 and 4 substantially have a "plane" such as a basic surface 111 or a skeleton surface 112, that is, a widened portion. However, the outer shapes are different from each other and they are not "standard".

As described above, Patent Documents 3 and 4 describe that the plurality of fiber lumps 11 contained in the absorber 4 are "standard fiber aggregates" defined by the basic surface 111 and the skeleton surface 112. Since the uniform dispersibility of the fiber mass 11 in the absorber 4 is improved as compared with the case of an amorphous fiber aggregate such as the above, it is expected that the fiber aggregate such as the fiber mass 11 is blended with the absorber 4. The effect (improvement effect such as flexibility, cushioning property, compression recovery property, etc. of the absorber) is stably exhibited. Further, in particular, in the case of the rectangular parallelepiped fiber mass 11 as shown in FIG. 5 (a), the outer surface thereof is composed of six surfaces of two basic surfaces 111 and four skeleton surfaces 112, and thus is shown in FIG. 5 (b). Compared to the disk-shaped fiber mass 11 having three outer surfaces, it is possible to have a relatively large number of contact opportunities with other fiber mass 11 or the water-absorbent fiber 12F, and the entanglement is enhanced and the shape retention property is improved. It can also lead to improvement of such things.

In the fiber mass 11, the total area of the two basic surfaces 111 is preferably larger than the total area of the skeleton surface 112. That is, in the rectangular parallelepiped fiber mass 11A of FIG. 5 (a), the total area of each of the two basic surfaces 111 is larger than the total area of each of the four skeleton surfaces 112, and FIG. 5 (b). In the disk-shaped fiber mass 11B, the total area of each of the two basic surfaces 111 is larger than the area of the skeleton surface 112 forming the peripheral surface of the disk-shaped fiber mass 11B. In any of the fiber lumps 11A and 11B, the basic surface 111 is the surface having the largest area among the plurality of surfaces of the fiber lumps 11A and 11B.

The fiber mass 11 which is a "standard fiber aggregate" defined by the two basic surfaces 111 and the skeleton surface 112 intersecting the two basic surfaces 111 has a different manufacturing method from the prior art. It can be realized by doing so. As shown in FIG. 6, a preferable method for producing the fiber lump 11 is to cut the raw material fiber sheet 10bs (a sheet having the same composition as the fiber lump 11 and having a larger size than the fiber lump 11) as a raw material by using a cutting means such as a cutter. It is used to cut into a fixed form. The plurality of fiber lumps 11 thus produced have a more fixed shape and dimensions as compared with those produced by conventional techniques such as Patent Documents 3 and 4. FIG. 6 is a diagram illustrating a method for manufacturing the rectangular parallelepiped-shaped fiber mass 11A of FIG. 5A, and the dotted line in FIG. 6 indicates a cutting line. The absorbent core 10 contains a plurality of fiber lumps 11 having uniform shapes and dimensions obtained by cutting the fiber sheet into a fixed shape. As described above, a non-woven fabric is preferable as the raw material fiber sheet 10bs.

In the rectangular parallelepiped-shaped fiber mass 11A of FIG. 5A, the raw material fiber sheet 10bs intersects (more specifically, orthogonally) the first direction D1 and the first direction D1 as shown in FIG. Manufactured by cutting into D2 to a predetermined length. Both directions D1 and D2 are each a predetermined direction in the plane direction of the sheet 10bs, and the sheet 10bs is cut along the thickness direction Z orthogonal to the plane direction. As described above, in a plurality of rectangular parallelepiped fiber lumps 11A obtained by cutting the raw material fiber sheet 10bs into a so-called sword pattern, the cut surface, that is, the surface that comes into contact with a cutting means such as a cutter when the sheet 10bs is cut is usually formed. The skeleton surface 112, that is, the non-cut surface, that is, the surface that does not come into contact with the cutting means, is the basic surface 111. The basic surface 111 is a front and back surface (a surface orthogonal to the thickness direction Z) of the sheet 10bs, and as described above, is the surface having the largest area among the plurality of surfaces of the fiber mass 11A.

The above description of the fiber mass 11A basically applies to the disk-shaped fiber mass 11B of FIG. 5 (b). The only substantial difference from the fiber mass 11A is the cutting pattern of the raw material fiber sheet 10bs, and when the sheet 10bs is cut into a fixed shape to obtain the fiber mass 11B, the shape of the fiber mass 11B is matched to the plan view shape. The sheet 10bs may be cut into a circular shape.

Further, the outer shape of the fiber mass 11 is not limited to that shown in FIG. 5, and the basic surface 111 and the skeleton surface 112 are both flat surfaces that are not curved as in the respective surfaces 111 and 112 of FIG. 5 (a). Alternatively, it may be a curved surface such as the skeleton surface 112 (peripheral surface of the disk-shaped fiber mass 11B) in FIG. 5 (b). Further, the basic surface 111 and the skeleton surface 112 may have the same shape and dimensions, and specifically, for example, the outer shape of the fiber mass 11A may be a cubic shape.

As described above, the two types of surfaces (basic surface 111 and skeleton surface 112) of the fiber mass 11 (11A, 11B) are used to cut the raw material fiber sheet 10bs by a cutting means such as a cutter when manufacturing the fiber mass 11. It is classified into a cut surface (skeleton surface 112) formed by the sheet 10bs and a non-cut surface (basic surface 111) that is inherently possessed by the sheet 10bs and does not come into contact with the cutting means. Due to the difference in whether or not the cut surface is used, the cut surface, the skeleton surface 112, is characterized in that the number of fiber ends per unit area is larger than that of the non-cut surface, the basic surface 111. Has. The term "fiber end" as used herein means the end in the length direction of the constituent fibers 11F of the fiber mass 11. Normally, the fiber end is also present on the basic surface 111, which is a non-cut surface, but the skeleton surface 112 is formed by cutting because it is a cut surface formed by cutting the raw material fiber sheet 10bs. A large number of fiber ends consisting of cut ends of the constituent fibers 11F are present in the entire skeleton surface 112, that is, the number of fiber ends per unit area is larger than that of the basic surface 111. ..

At the fiber ends existing on each surface (basic surface 111, skeleton surface 112) of the fiber mass 11, the fiber mass 11 is entangled with other fiber mass 11 and the water-absorbent fiber 12F contained in the absorber 4. Is useful for forming. Further, in general, the larger the number of fiber ends per unit area, the better the entanglement, which may lead to the improvement of various properties such as the shape retention of the absorber 4. As described above, the number of fiber ends per unit area on each surface of the fiber mass 11 is not uniform, and the number of such fiber ends per unit area is "skeleton surface 112> basic surface 111". Since the magnitude relationship is established, the entanglement with other fibers (other fiber mass 11, water-absorbent fiber 12F) via the fiber mass 11 differs depending on the surface of the fiber mass 11, and the skeleton surface 112 is the basic surface 111. Highly entangled compared to. That is, the bond by entanglement with other fibers via the skeleton surface 112 has a stronger bonding force than that through the basic surface 111, and in one fiber mass 11, the basic surface 111 and the skeleton surface There may be a difference in the bonding force with other fibers from 112.

As described above, in the absorber 4, each of the plurality of fiber lumps 11 contained therein has two types of binding forces with respect to other fibers (other fiber lumps 11, water-absorbent fibers 12F) around the absorber 4. The absorber 4 is held and entangled, so that the absorber 4 has appropriate softness and strength (shape retention). When the absorber 4 having such excellent properties is used as an absorber of the absorbent article according to a conventional method, it is possible to provide a comfortable wearing feeling to the wearer of the absorbent article. , The inconvenience that the absorber 4 is destroyed by an external force such as the wearer's body pressure at the time of wearing is effectively prevented.

In particular, in the fiber mass 11 (11A, 11B) shown in FIG. 5, the total area of the two basic surfaces 111 is larger than the total area of the skeleton surface 112, as described above. Therefore, the basic surface 111, which has a relatively small number of fiber ends per unit area and therefore has a relatively low entanglement with other fibers, has a skeleton surface 112 having the opposite property. It means that the total area is larger than that.
Therefore, the fiber lumps 11 (11A, 11B) shown in FIG. 5 have other fibers (other fiber lumps 11, water-absorbent fibers 12F) in the vicinity as compared with the fiber lumps having fiber ends uniformly present on the entire surface. ) Is easily suppressed, and even if it is entangled with other fibers in the vicinity, it is easy to entangle with a relatively weak binding force, and therefore it is difficult to form a large lump, and the absorber 4 has excellent flexibility. Can be granted.

On the other hand, the nonwoven fabric pieces or fine webs described in Patent Documents 3 and 4 are basically manufactured by cutting the raw material fiber sheet into an irregular shape by a cutting machine such as a mill cutter as described above. It is not a fixed-form sheet piece-like fiber mass having a "face" like the surface 111 or the skeleton surface 112, and moreover, the external force of the cutting process is applied to the entire fiber mass at the time of its manufacture, so that the constituent fibers The fiber ends of the above are randomly formed in the entire fiber mass, and it is difficult for the fiber ends to sufficiently exhibit the above-mentioned effects.

From the viewpoint of more reliably exerting the action and effect of the fiber end portion described above, the number N1 per unit area of the fiber end portion of the basic surface 111 (non _- cut surface) and the skeleton surface 112 (cut surface). The ratio of the fiber end to the number N ₂ per unit area is N ₁ / N ₂ , preferably 0 or more, more preferably 0.05 or more, and preferably 0, assuming N ₁ <N ₂ . It is .90 or less, more preferably 0.60 or less. More specifically, N ₁ / N ₂ is preferably 0 or more and 0.90 or less, and more preferably 0.05 or more and 0.60 or more.
The number N ₁ per unit area of the fiber end of the basic surface 111 is preferably 0 pieces / mm ² or more, more preferably 3 pieces / mm ² or more, and preferably 8 pieces / mm ² or less, still more preferably. 6 pieces / mm ² or less.
The number N ₂ per unit area of the fiber end of the skeleton surface 112 is preferably 5 pieces / mm ² or more, more preferably 8 pieces / mm ² or more, and preferably 50 pieces / mm ² or less, still more preferably. 40 pieces / mm ² or less.
The number of fiber ends of the basic surface 111 and the skeleton surface 112 per unit area is measured by the following method.

<Measuring method of the number of fiber ends per unit area on each surface of the fiber mass>
A member (fiber mass) containing a fiber to be measured is attached to a sample table using a paper double-sided tape (Nichiban Co., Ltd. Nystack NW-15). The measurement piece is then platinum coated. For coating, an ion sputtering device E-1030 (trade name) manufactured by Hitachinaka Seiki Co., Ltd. is used, and the sputtering time is 120 seconds. The cut surface of the measurement piece is observed on the basic surface and the skeletal surface at a magnification of 100 times using a JCM-6000 type electron microscope manufactured by JEOL Ltd. 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 measurement target surface (basic surface or skeleton surface), and the area of the rectangular area is the said. After adjusting the observation angle and the like so as to occupy 90% or more of the area of the observation screen, the number of fiber ends contained in the rectangular region 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 more than 100 times, the number of fiber ends contained in the rectangular region on the measurement target surface is measured in the same manner as described above. Here, the "fiber end" to be counted is the end in the length direction of the constituent fibers of the fiber mass, and the portion other than the end in the length direction of the constituent fibers from the measurement target surface (intermediate in the length direction). Even if the part) is extended, the middle part in the length direction is not subject to the number measurement. Then, the number of fiber ends per unit area on the measurement target surface (basic surface or skeleton surface) of the fiber mass is calculated by the following formula. For each of the 10 fiber lumps, the number of fiber ends per unit area on each of the basic surface and the skeleton surface was measured according to the above procedure, and the average value of the plurality of measured values was calculated as the average value of the plurality of measured values. The number per unit area of.
Number of fiber ends per unit area on the measurement target surface (basic surface or skeleton surface) of the fiber mass (number / mm ² ) = number of fiber ends included in the rectangular region (1.2 × 0.6 mm) / Area of the rectangular area (0.72 mm ² )

When the basic surface 111 of the fiber mass 11 has a rectangular shape in a plan view as in the fiber mass 11A shown in FIG. 5A, from the viewpoint of improving the uniform dispersibility of the fiber mass 11 in the absorber 4. The rectangular short side 111a is preferably equal to or shorter than the thickness of the absorber 4 containing the fiber mass 11 (11A). The ratio of the length of the short side 111a to the thickness of the absorber 4 is preferably 0.03 or more, more preferably 0.08 or more, and preferably 1 or less, still more preferably 0.5 or less as the former / the latter. Is.
The thickness of the absorber 4 is preferably 1 mm or more, more preferably 2 mm or more, and preferably 10 mm or less, still more preferably 6 mm or less. The thickness of the absorber 4 is measured by the following method.

<Measuring method of absorber thickness>
The object to be measured (absorbent 4) is placed on a horizontal surface so as not to be wrinkled or bent, and the thickness of the object to be measured is measured under a load of 5 cN / cm ² . Specifically, for measuring the thickness, for example, a thickness meter PEACOCK DIAL UPRIGHT GAUGES R5-C (manufactured by OZAKI MFG.CO.LTD.) Is used. At this time, a plan-viewing circular or square plate (thickness) whose size is adjusted so that the load on the measurement object is 5 cN / cm ² between the tip of the thickness gauge and the cut-out object to be measured. (Acrylic plate of about 5 mm) is placed and the thickness is measured. In the thickness measurement, 10 points are measured, and the average value thereof is calculated to obtain the thickness of the object to be measured.

It is preferable to set the dimensions and the like of each part of the fiber mass 11 (11A, 11B) as follows. The dimensions of each part of the fiber mass 11 can be measured based on an electron micrograph or the like at the time of specifying the outer shape of the fiber mass 11 described later.
When the basic surface 111 has a rectangular shape in a plan view as shown in FIG. 5A, the length L1 of the short side 111a is preferably 0.3 mm or more, more preferably 0.5 mm or more, and preferably 10 mm or less. , More preferably 6 mm or less. The length L2 of the long side 111b of the basic surface 111 having a rectangular shape in a plan view is preferably 0.3 mm or more, more preferably 2 mm or more, and preferably 30 mm or less, still more preferably 15 mm or less.
As shown in FIG. 5, when the basic surface 111 is the surface having the maximum area among the plurality of surfaces of the fiber mass 11, the length L2 of the long side 111b is the maximum transfer length of the fiber mass 11. The maximum transfer length corresponds to the diameter of the basic surface 111 having a circular shape in a plan view in the disk-shaped fiber mass 11B.
The ratio of the length L1 of the short side 111a to the length L2 of the long side 111b is preferably 0.003 or more, more preferably 0.025 or more, and preferably 1 or less, more preferably 1 or less, as L1 / L2. It is 0.5 or less. In the present invention, the plan view shape of the basic surface 111 is not limited to the rectangular shape as shown in FIG. 5A, but may be a square shape, that is, the ratio of the lengths L1 and L2 of the two sides orthogonal to each other is , L1 / L2 may be 1.
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, still more preferably 6 mm or less. be.

Further, it is preferable that the absorber 4 is mechanically isotropic so that the action and effect caused by the presence of the fiber mass 11 can be easily exerted on all aspects of the absorber 4. For that purpose, it is preferable that the fiber lumps 11 are densely and uniformly distributed throughout the absorber 4. From such a viewpoint, it is preferable that the overlapping portion of the plurality of fiber lumps 11 is present in an arbitrary 10 mm square unit region in the projection view of the absorber 4 in two directions orthogonal to each other. Reference numerals 11Z in FIGS. 3 and 4 indicate overlapping portions of the plurality of fiber lumps 11. The term "projective view in two directions orthogonal to each other" as used herein is typically referred to as projection view in the thickness direction of the absorber (that is, when the absorber is observed from its skin-facing surface or non-skin-facing surface). , Projective identification in a direction orthogonal to the thickness direction (that is, when the absorber is observed from its side).

FIG. 7A shows an electron micrograph of an example of the fiber mass according to the present invention, and FIG. 7B shows a diagram schematically showing the fiber mass 11 according to the electron micrograph. Has been done. As shown in FIG. 7, the plurality of fiber lumps 11 included in the absorber 4 are configured to include a main body portion 110 and fibers 11F extending outward from the main body portion 110, and the main body portion 110 includes the main body portion 110. Those having an extended fiber portion 113, which has a relatively low fiber density (the number of fibers per unit area is small), can be included. The absorber 4 may also include a fiber mass 11 having no extended fiber portion 113, that is, a fiber mass 11 composed of only the main body portion 110. The extended fiber portion 113 is a kind of fiber end portion existing on each surface (basic surface 111, skeleton surface 112) of the fiber mass 11 described above, and from each surface of the fiber mass 11 among the fiber end portions. It is a fiber end extending outward.

The main body portion 110 is a portion defined by the above-mentioned two facing basic surfaces 111 and a skeleton surface 112 connecting both basic surfaces 111. The main body 110 is a portion that forms the main body of the fiber mass 11 and forms a fixed outer shape of the fiber mass 11, and various characteristics such as high flexibility, cushioning property, and compression recovery property of the fiber mass 11 are basic. It is largely due to the main body 110. On the other hand, the extended fiber portion 113 mainly contributes to the improvement of the entanglement between the plurality of fiber lumps 11 contained in the absorber 4 or between the fiber lumps 11 and the water-absorbent fiber 12F, and the shape-retaining property of the absorber 4. In addition to being directly related to the improvement of the fiber mass 11, it can also affect the uniform dispersibility of the fiber mass 11 in the absorber 4 and indirectly reinforce the action and effect of the main body 110.

The main body portion 110 has a higher fiber density than the extended fiber portion 113, that is, the number of fibers per unit area is large. Further, usually, the fiber density of the main body 110 itself is uniform. The ratio of the main body 110 to the total mass of the fiber mass 11 is usually at least 40% by mass or more, preferably 50% by mass or more, more preferably 60% by mass or more, and particularly preferably 85% by mass or more. The main body portion 110 and the extended fiber portion 113 can be distinguished by the following work of specifying the outer shape.

The work of specifying the outer shape of the main body 110 of the fiber mass 11 included in the absorber 4 is the work of specifying the height difference of the fiber density in the absorber 4 (the number of fibers per unit area), the type of fiber, and the fiber diameter. This can be done by paying attention to the difference between the two parts and confirming the "boundary" between the main body 110 and the other parts. The main body portion 110 has a higher fiber density than the extended fiber portion 113 existing around the main body portion 110, and the synthetic fiber which is a constituent fiber of the main body portion 110 is usually a water-absorbent fiber 12F (typically a cellulosic fiber). Since they are qualitatively and / or dimensionally different, even in the absorber 4 in which a large number of fiber lumps 11 and water-absorbent fibers 12F are mixed, the boundary can be easily confirmed by paying attention to the above points. The boundary thus confirmed is the peripheral edge (side) of the basic surface 111 or the skeleton surface 112, and the basic surface 111 and the skeleton surface 112 are specified by such boundary confirmation work, and the main body portion 110 is specified. Will be done. Such boundary confirmation work can be carried out by observing the object (absorbent 4) at a plurality of observation angles as needed using an electron microscope. In particular, the fiber mass 11 contained in the absorber 4 is such that the fiber masses 11A and 11B shown in FIG. 5 have "the total area of the two basic surfaces 111 is larger than the total area of the skeleton surface 112". In some cases, in particular, when the basic surface 111 is a surface having the maximum area of the fiber mass 11, the basic surface 111 having a large area can be relatively easily identified, so that the outer shape of the main body 110 can be specified. The shape identification work can be performed smoothly.

As shown in FIG. 7, the extending fiber portion 113 extends outward from at least one of the basic surface 111 and the skeleton surface 112 forming the outer surface of the main body portion 110, and is a constituent fiber of the main body portion 110. It consists of 11F. FIG. 7 is a plan view of the fiber mass 11 from the side of the basic surface 111 (the surface having the maximum area among the plurality of surfaces of the fiber mass 11), and the fibers 11F are formed from the skeleton surface 112 intersecting the basic surface 111. A large number of extended fibers are formed to form the extended fiber portion 113.

The form of the extended fiber portion 113 is not particularly limited. The extended fiber portion 113 may be composed of one fiber 11F, or may be composed of a plurality of fibers 11F as in the extended fiber bundle portion 113S described later. Further, the extended fiber portion 113 includes the end portion in the length direction of the fiber 11F extending from the main body portion 110, but in addition to such the end portion of the fiber, a portion (length) other than both ends in the length direction of the fiber 11F. It may include the middle part in the vertical direction). That is, in the fiber mass 11, both ends of the constituent fibers 11F in the length direction exist in the main body portion 110, and the other portions, that is, the intermediate portions in the length direction extend outward from the main body portion 110 in a loop shape ( Where there is a case of protrusion), the extended fiber portion 113 in that case is configured to include such a loop-shaped protrusion of the fiber 11F.

As described above, one of the main roles of the extended fiber portion 113 is to entangle the plurality of fiber lumps 11 contained in the absorber 4 with each other, or the fiber lumps 11 and the water-absorbent fiber 12F. Generally, the extension length of the extension fiber portion 113 from the main body portion 110 becomes longer, the thickness of the extension fiber portion 113 becomes thicker, or the number of extension fiber portions 113 contained in one fiber mass 11. When the amount of entanglement increases, the connection between the entangled objects via the extended fiber portion 113 becomes stronger and the entanglement becomes difficult to be released, so that the predetermined effect of the present invention can be more stably achieved. Become.

When the fiber mass 11 is obtained by cutting the raw material fiber sheet 10bs into a fixed shape as shown in FIG. 6, the extended fiber portion 113 is present in a relatively large amount on the skeleton surface 112 which is the cut surface thereof. On the other hand, it does not exist at all on the basic surface 111, which is a non-cut surface, or even if it exists, the number is smaller than that of the skeletal surface 112. As described above, the reason why the extended fiber portion 113 is unevenly distributed on the skeleton surface 112 which is the cut surface is that most of the extended fiber portion 113 is "fluff" generated by cutting the raw material fiber sheet. That is, since the skeleton surface 112 formed by cutting the raw material fiber sheet 10bs is entirely rubbed by a cutting means such as a cutter at the time of cutting, fluff made of the constituent fibers 11F of the sheet 10bs is likely to be formed, so-called fluffing. easy. Although it depends on the type of the raw material fiber sheet, if the interval between the cutting lines is shortened or the cutting speed is slowed down, the extended fiber portion 113 is easily formed and its length can be adjusted. On the other hand, since the basic surface 111, which is a non-cut surface, does not have friction with such a cutting means, it is difficult to form fluff, that is, the extended fiber portion 113.

The interval L1a (interval in the first direction, see FIG. 6) and the interval L2a (interval in the second direction, see FIG. 6) at the time of cutting the raw material fiber sheet 10bs are used to promote the formation of the extended fiber portion 113 described above. From the viewpoint of ensuring the dimensions necessary for the fiber lump 11 to exert a predetermined effect, preferably 0.3 mm or more, more preferably 0.5 mm or more, and preferably 30 mm or less, still more preferable. Is 15 mm or less.

As shown in FIG. 7, the fiber mass 11 is a kind of extended fiber portion 113, and is a stretched fiber bundle portion including a plurality of fibers 11F extending outward from the main body portion 110, more specifically, the skeleton surface 112. It has 113S. At least one of the extended fiber portions 113 included in the fiber mass 11 may be the extended fiber bundle portion 113S. The extended fiber bundle portion 113S is formed by gathering a plurality of fibers 11F extending from the skeleton surface 112, and the extending length from the skeleton surface 112 is longer than that of the extended fiber portion 113. Characterized by dots. The extended fiber bundle portion 113S may also be present on the basic surface 111, but typically exists on the skeletal surface 112 as shown in FIG. 7, and does not exist at all on the basic surface 111, or even if it exists. The number is less than the skeletal surface 112. The reason is the same as the reason why the extended fiber portion 113 mainly exists on the skeleton surface 112 which is the cut surface, and is as described above.

Since the fiber mass 11 has such an extended fiber bundle portion 113S which can be said to be a long, thick and large extended fiber portion 113, the fiber masses 11 or the fiber mass 11 and the water-absorbent fiber 12F can be connected to each other. The entanglement becomes stronger, and as a result, the predetermined effect of the present invention due to the presence of the fiber lump 11 becomes more stable. The extended fiber bundle portion 113S is easily formed by performing the above-mentioned cutting of the raw material fiber sheet 10bs under the condition of easy fluffing (see FIG. 6).

The extension length of the extension fiber bundle portion 113S from the main body portion 110, that is, the extension length from the skeleton surface 112 (cut surface) is preferably 0.2 mm or more, more preferably 0.5 mm or more, and It is preferably 7 mm or less, more preferably 4 mm or less. The extension length of the extension fiber bundle portion 113S can be measured in the work of specifying the outer shape of the fiber mass 11 (boundary confirmation work). Specifically, for example, a double-sided tape manufactured by 3M Co., Ltd. was attached to the surface of a transparent sample table made of acrylic with a KEYENCE microscope (50 magnification), and a fiber mass 11 was placed and fixed on the double-sided tape. Above, after specifying the outer shape of the fiber mass 11 according to the above-mentioned work of specifying the outer shape, the length of the extended portion of the fiber 11F extending from the outer shape is measured, and the measured extension is measured. The length of the minute is defined as the extension length of the extension fiber bundle portion 113S.

It is preferable that the plurality of constituent fibers 11F of the extended fiber bundle portion 113S are heat-sealed to each other. The heat-sealed portion of the extended fiber bundle portion 113S is usually in the length direction of the extended fiber bundle portion 113S as compared with other portions (non-heat-fused portions) of the extended fiber bundle portion 113S. The transfer length (diameter when the cross section of the heat-sealed portion is circular) is long in the direction orthogonal to. Since the extended fiber bundle portion 113S has such a heat-sealed portion that can be said to be a large-diameter portion, the strength of the extended fiber bundle portion 113S itself is increased, thereby passing through the extended fiber bundle portion 113S. The entanglement between the entangled fiber lumps 11 or between the fiber lumps 11 and the water-absorbent fiber 12F becomes stronger. Further, when the extended fiber bundle portion 113S has a heat-sealed portion, not only when the extended fiber bundle portion 113S is in a dry state but also when it is in a wet state by absorbing moisture. There is an advantage that the strength and shape retention of the extended fiber bundle portion 113S itself are enhanced. Due to such merits, when the absorber 4 is applied to an absorbent article, it absorbs body fluids such as urine and menstrual blood excreted by the wearer as well as when the absorber 4 is in a dry state. Even in the wet state, the action and effect due to the presence of the above-mentioned fiber mass 11 can be stably exerted. Such an extended fiber bundle portion 113S having a heat-sealed portion is used as the raw material fiber sheet 10bs in the manufacturing process of the fiber mass 11 as shown in FIG. 6, that is, the cutting step of the raw material fiber sheet 10bs of the fiber mass 11. It can be manufactured by using the above-mentioned "fiber sheet having a heat-sealed portion between constituent fibers".

The constituent fibers 11F of the fiber mass 11 include synthetic fibers. The synthetic fiber used as the fiber 11F is preferably a non-water-absorbent synthetic fiber. Since the constituent fibers 11F of the fiber mass 11 are non-water-absorbent fibers, not only when the absorber 4 is in a dry state but also when it is in a wet state by absorbing water (body fluid such as urine or menstrual blood). , The action effect (improvement effect such as shape retention, flexibility, cushioning property, compression recovery property, and resistance to twisting) due to the presence of the fiber mass 11 described above is stably exhibited. The content of the synthetic fiber as the constituent fiber 11F 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, the fiber mass 11 is formed only from the synthetic fiber. Most preferably. In particular, when the synthetic fiber as the constituent fiber 11F is a non-water-absorbent fiber, the action and effect caused by the presence of the fiber mass 11 described above are more stably exhibited.

As used herein, the term "water-absorbent" is easily understood by those of skill in the art, for example, pulp is said to be water-absorbent. Similarly, it can be easily understood that thermoplastic fibers are non-absorbent. On the other hand, the degree of water absorption of the fiber can be compared with the relative difference in water absorption by the value of the water content measured by the following method, and a more preferable range can be defined. The larger the value of the water content, the higher the water absorption of the fiber, and therefore, the water-absorbent fiber has a larger value of the water content than the non-water-absorbent fiber. As the water-absorbent fiber, such a fiber having a water content of 6% or more is preferable, and a fiber having a water content of 10% or more is more preferable. On the other hand, as the non-water-absorbent fiber, such a fiber having a water content of less than 6% is preferable, and a fiber having a water content of less than 4% is more preferable.

<Measurement method of moisture content>
The water content was calculated by applying the water content test method of JIS P8203 mutatis mutandis. That is, after the fiber sample was allowed to stand in a test room having a temperature of 40 ° C. and a relative humidity of 80% RH for 24 hours, the weight W (g) of the fiber sample before the absolute drying treatment was measured in the room. Then, it was allowed to stand for 1 hour in an electric dryer having a temperature of 105 ± 2 ° C. (for example, manufactured by Isuzu Seisakusho Co., Ltd.) to dry out the fiber sample. After the absolute drying treatment, Si silica gel (for example, Si silica gel (for example,) in a state where the fiber sample is covered with Saran Wrap (registered trademark) manufactured by Asahi Kasei Corporation in a test room in a standard state with a temperature of 20 ± 2 ° C. and a relative temperature of 65 ± 2%. Toyoda Kako Co., Ltd. is placed in a glass desigator (for example, manufactured by Tech Jam Co., Ltd.) and allowed to stand until the temperature of the fiber sample reaches 20 ± 2 ° C. Then, the constant amount W'(g) of the fiber sample is weighed, and the water content of the fiber sample is obtained by the following formula. Moisture content (%) = (W-W'/ W') x 100

Similarly, from the viewpoint of enabling the absorber 4 to exhibit excellent effects in shape retention, flexibility, cushioning property, compression recovery property, resistance to twisting, etc. in both a dry state and a wet state. The fiber mass 11 preferably has a three-dimensional structure in which a plurality of thermoplastic fibers are heat-fused together.

Further, in order to obtain such a fiber mass 11 in which a plurality of heat-sealed portions are three-dimensionally dispersed, the synthetic fiber used as the constituent fiber 11F of the fiber mass 11 is preferably a thermoplastic fiber. Further, as described above, it is preferable that the extended fiber bundle portion 113S has a heat-sealed portion. However, since the constituent fiber 11F of the fiber mass 11 is a thermoplastic fiber, such an extended fiber bundle portion It is also possible to obtain a preferable form of 113S.

In order to obtain a fiber mass 11 in which a plurality of heat-sealed portions are three-dimensionally dispersed, the raw material fiber sheets 10bs (see FIG. 6) may be similarly configured, and such a plurality of heat treatments may be obtained. As described above, the raw material fiber sheet 10bs in which the fused portions are three-dimensionally dispersed can be manufactured by subjecting a web or a non-woven fabric mainly composed of thermoplastic fibers to a heat treatment such as hot air treatment.

Examples of the non-water-absorbent synthetic resin (thermoplastic resin) suitable as a material for the constituent fibers 11F of the fiber mass 11 include polyolefins such as polyethylene and polypropylene; polyesters such as polyethylene terephthalate; and polyamides such as nylon 6 and nylon 66; Examples thereof include polyacrylic acid, polymethacrylic acid alkyl ester, polyvinyl chloride, polyvinylidene chloride and the like, and one of these can be used alone or in combination of two or more. The fiber 11F may be a single fiber made of one kind of synthetic resin (thermoplastic resin) or a blend polymer in which two or more kinds of synthetic resins are mixed, or may be a composite fiber. The composite fiber referred to here is a synthetic fiber (thermoplastic fiber) obtained by compounding two or more kinds of synthetic resins having different components with a spinneret and spinning them at the same time, and a plurality of components are continuous in the length direction of the fiber. A structure that is mutually bonded within a single fiber. The form of the composite fiber includes a core sheath type, a side-by-side type, and the like, and is not particularly limited.

Further, it is preferable that the contact angle of the fiber mass 11 with water measured by the following method is less than 90 degrees, particularly 70 degrees or less, from the viewpoint of further improving the drawability of body fluid in the initial excretion. Such fibers can be obtained by treating the above-mentioned non-water-absorbent synthetic fibers with a hydrophilic agent according to a conventional method. As the hydrophilizing agent, an ordinary surfactant can be used.

<Measurement method of contact angle>
The fibers of the fiber mass are taken out from the measurement target (absorbent core), and the contact angle of water with respect to the fibers is measured. As a measuring device, an automatic contact angle meter MCA-J manufactured by Kyowa Interface Science Co., Ltd. is used. Deionized water is used to measure the contact angle. The amount of liquid discharged from the inkjet water droplet discharge unit (Pulse injector CTC-25 manufactured by Cluster Technology Co., Ltd., having a discharge unit hole diameter of 25 μm) is set to 20 picolitres, and the water droplet is dropped directly above the fiber. The state of dripping is recorded on a high-speed recording device connected to a horizontally installed camera. From the viewpoint of image analysis later, the recording device is preferably a personal computer incorporating a high-speed capture device. In this measurement, an image is recorded every 17 msec. In the recorded video, the first image of water droplets on the fibers is the attached software FAMAS (software version is 2.6.2, analysis method is droplet method, analysis method is θ / 2, image processing algorithm. Is non-reflective, the image processing image mode is frame, the threshold level is 200, and the curvature is not corrected.) Make a corner. The fiber taken out from the object to be measured is cut into a fiber length of 1 mm, and the fiber is placed on a sample table of a contact angle meter and maintained horizontally. Measure the contact angles at two different points for each fiber. N = 5 contact angles are measured up to one digit after the decimal point, and the average value of the measured values at 10 points in total (rounded to the second digit after the decimal point) is defined as the contact angle of the fiber with water. The measurement environment is room temperature 22 ± 2 ° C. and humidity 65 ± 2% RH.

As the water-absorbent fiber 12F, water-absorbent fiber conventionally used as a material for forming an absorber of this kind of absorbent article can be used. For example, wood pulp such as coniferous pulp and broadleaf pulp, cotton pulp and hemp. Natural fibers such as non-wood pulp such as pulp; modified pulp such as cationized pulp and marcelified pulp can be mentioned, and one of these can be used alone or in combination of two or more. Among the water-absorbent fibers, cellulosic water-absorbent fibers are particularly preferable.

In the absorber 4, the content mass ratio of the fiber mass 11 and the water-absorbent fiber 12F is not particularly limited, and may be appropriately adjusted according to the types of the constituent fibers (synthetic fiber) 11F and the water-absorbent fiber 12F of the fiber mass 11. good. For example, when the constituent fiber 11F of the fiber mass 11 is a thermoplastic fiber (non-water-absorbent synthetic fiber) and the water-absorbent fiber 12F is a cellulose-based fiber (water-absorbent fiber), the predetermined effect of the present invention can be more reliably achieved. The content mass ratio of the fiber mass 11 and the water-absorbent fiber 12F is preferably 20/80 to 80/20, more preferably 20/80 to 80/20, as the former (fiber mass 11) / the latter (water-absorbent fiber 12F). Is 40/60 to 60/40.

The content of the fiber mass 11 in the absorber 4 is preferably 20% by mass or more, more preferably 40% by mass or more, and preferably 80% by mass or less, more preferably 80% by mass or less, based on the total mass of the dry absorber 4. It is preferably 60% by mass or less.
The content of the water-absorbent fiber 12F in the absorber 4 is preferably 20% by mass or more, more preferably 40% by mass or more, and preferably 80% by mass or less, based on the total mass of the absorbent body 4 in the dry state. More preferably, it is 60% by mass or less.

The basis weight of the fiber mass 11 in the absorber 4 is preferably 32 g / m ² or more, more preferably 80 g / m ² or more, and preferably 640 g / m ² or less, still more preferably 480 g / m ² or less.
The basis weight of the water-absorbent fiber 12F in the absorber 4 is preferably 32 g / m ² or more, more preferably 80 g / m ² or more, and preferably 640 g / m ² or less, still more preferably 480 g / m ² or less. ..

The absorber 4 may contain other components other than the fiber mass 11 and the water-absorbent fiber 12F, and a water-absorbent polymer can be exemplified as the other component. As the water-absorbent polymer, a particulate polymer is generally used, but a fibrous polymer may also be used. When a particulate superabsorbent polymer is used, its shape may be spherical, lumpy, bale-shaped or amorphous. The average particle size of the water-absorbent polymer is preferably 10 μm or more, more preferably 100 μm or more, and preferably 100.
It is 0 μm or less, more preferably 800 μm or less. As the water-absorbent polymer, a polymer or copolymer of acrylic acid or an alkali metal salt of acrylic acid can generally be used. Examples thereof include polyacrylic acid and salts thereof, and polymethacrylic acid and salts thereof.

The content of the water-absorbent polymer in the absorber 4 is preferably 5% by mass or more, more preferably 10% by mass or more, and preferably 60% by mass or less, based on the total mass of the dry absorber 4. It is preferably 40% by mass or less.
The basis weight of the water-absorbent polymer in the absorber 4 is preferably 10 g / m ² or more, more preferably 30 g / m ² or more, and preferably 100 g / m ² or less, still more preferably 70 g / m ² or less.

The absorber 4 can be manufactured in the same manner as the absorber containing this kind of fiber material. As described above, the fiber mass 11 is a raw material fiber sheet (a sheet having the same composition as the fiber mass 11 and having a larger size than the fiber mass 11) as a raw material, using a cutting means such as a cutter. , Can be manufactured by cutting in two directions intersecting (orthogonal) with each other, and the plurality of fiber lumps 11 thus manufactured are "standard fiber aggregates" having uniform shapes and dimensions (for example, a main body portion). 110 is a rectangular parallelepiped shape). The absorber 4 including the fiber lump 11 and the water-absorbent fiber 12F can be manufactured according to a conventional method using, for example, a known fiber stacking device equipped with a rotating drum. Such a fiber stacking device typically conveys a rotary drum having an accumulation recess formed on the outer peripheral surface and raw materials (fiber mass 11, water-absorbent fiber 12F) of the absorbent core 40 to the accumulation recess. It is provided with a duct having a flow path inside, and while rotating the rotating drum around a rotation axis along the circumferential direction of the drum, an air flow (vacuum) generated in the flow path by suction from the inside side of the rotating drum. The raw materials transported on the air) are made to be stacked in the accumulation recesses. The fiber stack formed in the accumulation recess by the fiber stacking process is the absorbent core 40.
The basis weight of the absorber 4 is preferably 100 g / m ² or more, more preferably 200 g / m ² or more, and preferably 800 g / m ² or less, still more preferably 600 g / m ² or less.

Hereinafter, other embodiments of the present invention will be described with reference to FIGS. 8 to 10. Regarding other embodiments described later, components different from the above-mentioned napkin 1 will be mainly described, and similar components will be designated by the same reference numerals and description thereof will be omitted. The description of the napkin 1 is appropriately applied to the components not particularly described.

In the napkin 1A shown in FIG. 8, a leak-proof groove 9 is formed in which the surface sheet 2 and the absorber 4 are integrally recessed on the non-skin facing surface side of the absorbent body 4 on the skin facing surface of the absorbent body 5. Has been done. The leak-proof groove 9 is formed by pressing the napkin 1A (absorbent body 5) from the skin-facing surface, that is, the surface sheet 2 side, and the leak-proof groove 9 is formed due to the forming method. The front surface sheet 2, the core wrap sheet 41, and the absorbent core 40 are integrally recessed toward the non-skin facing surface side (back surface sheet 3 side) of the absorbent core 40. Further, the leakage-proof groove 9 has a higher density than the non-formation portion of the leakage-proof groove 9 in the non-consolidated portion 8 due to such a forming method.

Further, the squeezing process applied to the napkin 1A (absorbent body 5) to form the leak-proof groove 9 usually melts the constituent fibers 11F (synthetic fibers) of the fiber mass 11 contained in the absorber 4. Specific examples thereof include known embossing such as heat-embossing and ultrasonic embossing. Due to the method of forming the leak-proof groove 9, the surface sheet 2 and the core wrap sheet are formed at the bottom of the leak-proof groove 9, that is, the portion overlapping the leak-proof groove 9 which is a space portion in a plan view as shown in FIG. The 41 and the absorbent core 40 are heat-sealed and integrated.

As shown in FIG. 1, the leak-proof groove 9 has a linear shape in a plan view and includes a pair of left and right vertical grooves 9X and 9X extending in the vertical direction X and a pair of front and rear horizontal grooves 9Y and 9Y extending in the horizontal direction Y. The plurality of vertical grooves 9X and the horizontal grooves 9Y are connected to each other at the ends in the length direction thereof, and the leakage-proof groove 9 as a whole forms one closed annular shape. Each of the pair of vertical grooves 9X and 9X has a continuous linear shape extending over the entire length of the vertical direction X in the vertical central region B, respectively. Further, one of the pair of lateral grooves 9Y and 9Y exists in the front region A and the other exists in the rear region C, and each of the lateral grooves 9Y is convex toward the outside in the vertical direction X in a plan view. The U-shaped or arc-shaped continuous linear shape is formed, and the U-shaped or arc-shaped top thereof is located at the center of the napkin 1A in the lateral direction Y. The central portion of the vertical central region B, that is, the portion including the excretion portion facing portion (excretion point) is located in the ring of the leak-proof groove 9 forming a closed annular shape in a plan view.

Examples of the action and effect of the leak-proof groove 9 include improvement of the shape retention property of the absorber 4 and improvement of the liquid diffusivity in the plane direction of the absorber 4, which is similar to the action and effect of the consolidation portion 7 of the absorber 4. ing. Therefore, by further forming the leakage-proof groove 9 in addition to the consolidation portion 7, the shape-retaining property of the absorber 4 and the liquid diffusibility in the plane direction can be further improved.

At least in the vertical central region B of the napkin 1A, the consolidated portion 7 of the absorber 4 exists inside the pair of vertical grooves 9X and 9X in the lateral direction Y. In the form shown in FIG. 8, the consolidated portion 7 exists in the entire area of the ring of the leak-proof groove 9 forming a closed annular shape in a plan view, and not only the vertical central region B but also the front region A and the rear region A and the rear region. In each of C, the consolidation portion 7 exists between the pair of vertical grooves 9X and 9X. With such a configuration, the body fluid absorbed from the surface sheet 2 to the excretion portion facing portion of the absorbent core 40 is rapidly surface-diffused, that is, intersects both the vertical direction X, the horizontal direction Y, and both directions X and Y. By diffusing in each direction, the cushioning property of the area facing the excretory part at the time of wetting is improved.

Further, at least in the vertical central region B of the napkin 1A, the consolidated portion 7 of the absorber 4 is present outside the pair of vertical grooves 9X and 9X in the lateral direction Y. In the form shown in FIG. 8, the consolidated portion 7 exists in the entire area outside the ring of the leak-proof groove 9 forming a closed annular shape in a plan view, and not only the vertical central region B but also the front region A and the rear region A and the rear region. Also in each of C, the consolidation portion 7 exists on the outer side in the lateral direction Y than the pair of vertical grooves 9X and 9X. With such a configuration, when the body fluid reaches the compacted portion 7 existing outside the horizontal direction Y from the pair of vertical grooves 9X, the body fluid is easily diffused in the vertical direction X, and eventually, lateral leakage occurs. Even when it is prevented or wet, the cushioning property of the area facing the excretory part is improved.

Further, in the napkin 1A, the consolidation portion 7 and the leakage-proof groove 9 overlap each other in a plan view as shown in FIG. In the consolidated portion 7 that does not overlap with the leakage-proof groove 9, as described above, the constituent fibers 11F and 12F of the absorber 4 are not fused to each other, and therefore, the bonded body due to the fusion of the plurality of fiber lumps 11 is formed. Although it does not exist, in the consolidated portion 7 that overlaps with the leak-proof groove 9, the leak-proof groove 9 is formed by a pressing process accompanied by melting of the fiber 11F (synthetic fiber), so that the absorber 4 is configured. The fibers 11F and 12F can be fused to each other. The formation of such a fused portion of the fiber may lead to a decrease in the flexibility, cushioning property, etc. of the absorber 4, but since the fused portion is relatively small in the napkin 1A, these characteristics are exhibited. It does not substantially decrease. From the viewpoint of the balance between the action and effect of the leak-proof groove 9 and the inconvenience caused by its formation, the consolidated portion 7 and the leak-proof groove 9 occupy the entire area of one surface of the absorber 4 (the surface facing the skin in the napkin 1A). The ratio of the total area of the overlapping portion is preferably 1% or more, more preferably 3% or more, and preferably 9% or less as the latter (total area of the overlapping portion) / the former (the total area). It is preferably 7% or less.

In the napkin 1B shown in FIG. 9, the consolidated portion 7 is not formed in the absorber 4 located in the excretion portion facing region E having an elliptical shape in a plan view surrounded by a broken line in FIG. 9, and the excretion portion facing region E is not formed. The entire area of the absorber 4 located in is a non-consolidated portion 8 in which the constituent fibers 11F and 12F of the absorber 4 are not consolidated. The excretion portion facing region E is a region of the napkin 1B including the excretion portion facing portion (excretion point), and is usually located at the central portion of the vertical central region B in the lateral direction Y as shown in FIG. The total length in the direction X is 70 to 100 mm, and the length in the lateral direction Y, that is, the width is 30 to 50 mm. As described above, if the consolidation portion 7 is not formed in the absorber 4 located in the excretion portion facing region E, the excretion portion facing region E becomes flexible and rich in cushioning property, so that the napkin 1B feels comfortable to wear and operates. Followability can be further improved.

The napkin 1C shown in FIG. 10 is different from the napkin 1 shown in FIG. 1 in that the pattern of the compacted portion 7 of the absorber 4 is taken. That is, on the skin-facing surface of the absorber 4 in the napkin 1C, rows in which a plurality of compacted portions 7 are arranged at equal intervals in one direction (vertical direction X) are arranged in a direction orthogonal to the one direction (horizontal direction Y). A plurality of compacted portions 7 are formed at the same position in two adjacent rows in a direction orthogonal to the one direction. In the napkin 1C as well, similarly to the napkin 1, a plurality of compacted portions 7 are dispersed and arranged in a scattered pattern over the entire surface of the absorber 4 facing the skin.

Further, the pattern of the compacted portion 7 in the napkin 1C is an anisotropic pattern that diffuses the body fluid anisotropically in the plane direction. That is, in the napkin 1C shown in FIG. 10, the pitch 7Px of the consolidation portion 7 in the vertical direction X is the pitch 7Py of the consolidation portion 7 in the lateral direction Y, and the compaction portion 7 in the direction where both directions X and Y intersect. It is shorter than each of the pitches 7Pz. That is, in the napkin 1C, the pitch 7Px is the pitch 7P1 (relatively short pitch), and the pitches 7Py and 7Pz are the pitch 7P2 (relatively long pitch), respectively. In the absorber 4 of the napkin 1C in which the magnitude relationship of "pitch 7Px <pitch 7Py, 7Pz" is established, the body fluid has priority over the direction X in the horizontal direction and the direction in which both directions X and Y intersect. Therefore, the absorption performance of the absorber 4 can be more effectively utilized. Further, since the diffusivity of the body fluid in the lateral direction Y is relatively low, so-called lateral leakage can be effectively prevented.

When the pattern of the consolidation portion 7 is an anisotropic pattern as shown in FIG. 10, it is preferable to set each pitch of the consolidation portion 7 as follows.
The ratio of the pitch 7Px to the pitch 7Py is preferably 0.20 or more, more preferably 0.38 or more, and preferably 0.90 or less, still more preferably 0.80 or less as the former / the latter.
The ratio of the pitch 7Px to the pitch 7Pz is preferably 0.17 or more, more preferably 0.30 or more, and preferably 0.90 or less, still more preferably 0.80 or less as the former / the latter.
The pitch 7Px of the compacted portion 7 in the vertical direction X is preferably 2.0 mm or more, more preferably 3.0 mm or more, and preferably 7.0 mm or less, still more preferably 5.0 mm or less.
The pitch 7Py of the compacted portion 7 in the lateral direction Y is preferably 3.0 mm or more, more preferably 5.0 mm or more, and preferably 10 mm or less, further preferably 8.0 mm or less.
The pitch 7Pz of the compacted portion 7 in the direction intersecting both the vertical direction X and the horizontal direction Y is preferably 4.0 mm or more, more preferably 5.0 mm or more, and preferably 12 mm or less, further preferably 10 mm or less. be.

Although the present invention has been described above based on the embodiment, the present invention can be appropriately modified without being limited to the embodiment.
For example, in the above-described embodiment, the consolidated portion 7 as a recess is formed on the skin-facing surface of the absorber 4, but the compacted portion 7 is formed on the non-skin-facing surface located on the opposite side of the skin-facing surface. The consolidation portion 7 may be formed on both sides of the absorber 4.
Further, in the above embodiment, the absorber 4 is configured to include the absorbent core 40 and the core wrap sheet 41 covering the absorbent core 40, but the core wrap sheet 41 may be omitted.
Further, in the absorbent core according to the present invention, all of the fiber lumps (synthetic fiber aggregates) contained therein do not have to be a fixed-shaped fiber aggregate such as the fiber lump 11, which deviates from the gist of the present invention. As long as it does not, a very small amount of atypical fiber aggregates may be contained in addition to the fixed-form fiber aggregates.
The absorbent article of the present invention broadly includes articles used for absorbing body fluids (urine, loose stool, menstrual blood, sweat, etc.) discharged from the human body, and in addition to the above-mentioned sanitary napkins, sanitary shorts and fastenings. So-called deployable disposable diapers with tape, pants-type disposable diapers, incontinence pads and the like are included.

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

[Examples 1 to 5]
A sanitary napkin having the same basic configuration as the napkin 1 shown in FIG. 1 was prepared.
As the front sheet, an air-through nonwoven fabric composed of polyethylene having a basis weight of 74 g / m ² and polyethylene terephthalate resin fiber was used, and as the back sheet, a film made of polyethylene resin having a basis weight of 37 g / m ² was used. As the absorber, a fiber mass and a water-absorbent fiber are used as the fiber material of the absorbent core, and a core wrap sheet made of a pulp fiber having a basis weight of 16 g / m ² prepared separately is used, and a known fiber stacking device is used. Manufactured according to the law. The fiber mass was produced by cutting the raw material fiber sheet into a diced pattern according to FIG. The skin-facing surface of the absorbent core and the portion of the core wrap sheet that covers the skin-facing surface (skin-side core wrap sheet) are squeezed under conditions that do not cause fiber fusion, and the compacted portion is described below. It was formed by any of patterns A to C.
An air-through non-woven fabric having a basis weight of 21 g / m ² (a fiber sheet having a heat-sealed portion between constituent fibers) having a non-water-absorbing thermoplastic fiber made of polyethylene and polyethylene terephthalate resin as a constituent fiber as a raw material fiber sheet for the fiber mass. ) Was used. Coniferous bleached kraft pulp (NBKP) was used as the water-absorbent fiber. The fiber mass (standard synthetic fiber aggregate) used for the absorber has a rectangular parallelepiped main body portion as shown in FIG. 5A, and the short side 111a of the basic surface 111 thereof is 0.8 mm and the long side 111b. Was 3.9 mm.

-Pattern A: A compacted portion is formed in a staggered pattern (isotropic pattern) over the entire surface of the absorber facing the skin (see FIG. 1). The pitch Px7.0 mm of the consolidated portion, the pitch Py7.0 mm, the pitch Pz5.0 mm, and the occupancy rate of the consolidated portion 12.8%.
-Pattern B: A consolidated portion is formed in a staggered pattern (isotropic pattern) in the entire area excluding the excretion portion facing region E on the skin facing surface of the absorber (see FIG. 9). The pitch Px7.0 mm, the pitch Py7.0 mm, the pitch Pz5.0 mm of the consolidated portion, and the occupancy rate of the consolidated portion is 9.9%.
-Pattern C: A compacted portion is formed in an anisotropic pattern over the entire surface of the absorber facing the skin (see FIG. 10). The pitch Px3.5 mm, the pitch Py7.0 mm, the pitch Pz10.0 mm of the consolidated portion, and the occupancy rate of the consolidated portion 12.8%.

[Comparative Example 1]
A commercially available sanitary napkin (manufactured by Unicharm Co., Ltd., trade name “Tanom Pew Slim 23 cm”) was used as it was as Comparative Example 1. The absorber in the sanitary napkin of Comparative Example 1 is a mixture of synthetic fibers and cellulosic fibers (water-absorbent fibers) and does not contain fiber lumps.

[Comparative Example 2]
A sanitary napkin was prepared in the same manner as in Example 1 except that the absorber was changed to the following.
It was referred to as Comparative Example 2.
In the absorber used in Comparative Example 2, the absorbent core contains an amorphous piece of non-woven fabric as a fiber mass. Further, the absorbent core used in Comparative Example 2 uses an amorphous non-woven fabric piece as a fiber mass, and the absorbent body is subjected to a hot air step to heat the non-woven fabric pieces contained in the absorbent body to each other. Fused. In the hot air process applied to the absorbent core, a mixed aggregate of non-woven fabric pieces and pulp fibers (length 210 mm × width 66 mm) is placed in an electric dryer (for example, manufactured by Isuzu Seisakusho Co., Ltd.) at a temperature of 140 ° C. The non-woven fabric pieces were allowed to stand for 30 minutes, and the pieces of the non-woven fabric were heat-sealed. The amorphous non-woven fabric piece used is manufactured by tearing the air-through nonwoven fabric used in Examples 1 to 5 in an arbitrary shape and size in the plane or thickness direction of the air-through nonwoven fabric, and the transfer length in the plan view is It was about 25 mm.

[Performance evaluation]
For the sanitary napkins of each Example and Comparative Example, the compression work amount (w-WC) in a wet state was evaluated and measured by the following method. The results are shown in Table 1 below.

<Measurement method of compression work (WC)>
It is generally known that the sample compression work (WC) can be expressed by the measured value by KES (Kawabata Evaluation System) manufactured by Kato Tech Co., Ltd. (Reference: Standardization of texture evaluation and Analysis (2nd edition), author Kiyo Kawabata, published on July 10, 1980). Specifically, the compression work amount and the compression recovery rate can be measured by using the automated compression test apparatus KES-FB3-AUTO-A manufactured by Kato Tech Co., Ltd. The measurement procedure is as follows.
A 195 mm × 68 mm rectangular area in plan view including the excretion part facing portion was cut out from the sanitary napkin and used as a sample, and a cylindrical acrylic plate with an injection port having a diameter of 1 cm at the bottom was attached to the dried sample. The sample is placed so that the center of the sample overlaps with the center of the injection port, and 5.0 g of defibered horse blood (manufactured by Nippon Biotest Laboratory Co., Ltd.) is absorbed to bring the sample into a wet state. This wet sample is attached to the test bench of the compression test device. Next, the wet sample is compressed between steel plates having a circular plane with an area of 2 cm ² . The compression rate is 0.01 cm / sec, and the maximum compression load is 490.2 mN / cm ² . The amount of compression work (unit: mN · cm / cm ² ) is expressed by the following formula. In the following formula, T _m , To and P are 490.2 mN / cm ^{2 (4.9 kPa) thickness under load, 4.902 mN / cm 2} ₍ ⁴⁹ Pa) thickness under load, and the load at measurement (49 Pa), respectively. mN / cm ² ) is shown.
The compression work amount calculated in this way is the compression work amount (w-WC) in the wet state of the sample. The larger the value of w-WC, the higher the cushioning property is judged to be and the higher the evaluation is.

As shown in Table 1, the absorber of each embodiment contains a stereoscopic fiber mass containing synthetic fibers and having a body portion defined by two basic surfaces and a skeletal surface intersecting both basic surfaces. As a result, the amount of compression work in the wet state was larger than in Comparative Examples 1 and 2 which did not contain such a fiber mass. In particular, from the comparison between each example and Comparative Example 2, in order to obtain an absorber having a large compression work amount and excellent cushioning property even in a wet state, it is necessary to form the fiber lumps into a fixed shape and entangle the fiber lumps with each other. It turns out to be valid.

1,1A, 1B, 1C Sanitary napkins (absorbent articles)
A Front area B Vertical center area C Rear area E Excretion part facing area 2 Front sheet 3 Back sheet 4 Absorber 40 Absorbent core 11 Fiber mass 11F Fiber mass constituent fibers (synthetic fiber)
110 Main body 111 Basic surface 112 Skeleton surface 113 Extended fiber part 113S Extended fiber bundle part 12F Water-absorbent fiber 41 Core wrap sheet 5 Absorbent main body 6 Side sheet 7 Consolidation part 8 Non-consolidation part 9 Leakage-proof groove 9X Vertical groove 9Y Horizontal groove 10bs Raw material fiber sheet for fiber mass

Claims (5)

An absorber containing a fiber mass containing synthetic fibers and a water-absorbent fiber, and a plurality of the fiber masses or the fiber mass and the water-absorbent fiber are entangled with each other.
The fiber mass has a main body portion defined by two basic surfaces facing each other and a skeletal surface intersecting both basic surfaces.
The skeleton surface has a rectangular shape in a plan view, and the short side of the rectangular shape is the same as or shorter than the thickness of the absorber.
On the surface of the absorber, a compacted portion in which the absorber is recessed in a compacted state is partially formed, and the compacted portion and a non-consolidated portion which is a portion of the absorber in which the compacted portion is not formed. Are arranged alternately in one predetermined direction,
An absorber in which the fiber lumps are not fused to each other in the consolidated portion. The absorber according to claim 1, wherein a plurality of overlapping portions of the fiber lumps are present in an arbitrary 10 mm square unit region in the projection view in the thickness direction of the absorber. The absorber according to claim 1 or 2, wherein the content mass ratio of the fiber mass to the water-absorbent fiber is 20/80 to 80/20 as the former / the latter. The absorber is used for an absorbent article and has a vertical direction corresponding to the front-back direction of the wearer of the absorbent article and a horizontal direction orthogonal to the vertical direction.
6 . Absorber. An absorbent article comprising the absorber according to any one of claims 1 to 4 .

Images