JP6808771B2 - Connectable disposable wear items - Google Patents

Description

The present invention relates to an articulated disposable wearable article such as a tape-type disposable diaper.

A typical articulated disposable wear article has a crotch portion including the anterior-posterior center, a ventral portion extending anteriorly from the anterior-posterior center, and a dorsal portion extending posteriorly from the anterior-posterior center, at least the dorsal portion. Has wing portions extending from the crotch portion on both the left and right sides in the width direction. Further, the wing portion has a connecting portion that is detachably connected to the outer surface of the ventral portion, and the outer surface of the ventral portion has a target portion to which the connecting portion is connected. At the time of use, the wing portion is turned from both sides of the waist to the outer surface of the ventral portion, and the connecting portion of the wing portion is connected to the target portion. Such an articulated disposable wear article is used not only for infants but also for long-term care (adult use) (see, for example, Patent Document 1).

As the connecting portion of the connecting tape, the one formed of the hook material (male material) of the mechanical fastener (hook-and-loop fastener) is more widely used than the one formed of the adhesive layer. A typical target portion in the former is a component called a target tape made of a plastic film fixed to the outer surface of the ventral portion. On the other hand, a typical target portion in the latter is a base material made of a plastic film sewn with a thread, and a part called a target tape in which a loop is formed on the base material with the thread is fixed to the outer surface of the ventral portion. It is a thing. In this case, the protrusion of the hook material of the connecting tape is entangled with the loop of the target tape, so that the connecting tape is connected to the target portion.

When the connecting portion is a hook material, the outer surface of the product is formed of a non-woven fabric (hereinafter referred to as an exterior non-woven fabric), and a target sheet such as a plastic sheet on which the connecting position is printed is placed adjacent to the inner surface of the exterior non-woven fabric. It is also known that the target portion is formed by this. In this case, the user can perform the connection by entwining the hook material of the connecting portion with the fibers of the exterior non-woven fabric at the position of the target sheet seen through the exterior non-woven fabric.

However, these conventional ones have a problem that the air permeability is lowered by the amount of the target sheet, so that the region having the target sheet tends to get stuffy.

Special Table 2002-253608

Therefore, the main object of the present invention is to reduce stuffiness in the region having the target sheet.

The articulated disposable wear articles that have solved the above problems are as follows.
<First aspect>
It has a crotch part including the center in the anterior-posterior direction, a ventral part extending anteriorly from the center in the anterior-posterior direction, and a dorsal part extending posteriorly from the center in the anterior-posterior direction.
Absorber built in the range including the crotch part,
A liquid-permeable top sheet provided on the front side of the absorber and
A breathable liquid-impermeable sheet provided on the back side of the absorber, and
It has an exterior non-woven fabric that covers the back side of the liquid-impermeable sheet and constitutes the outer surface of the product.
Both sides of the dorsal portion have connecting portions that are detachably connected to the outer surface of the ventral portion.
A target sheet is provided at a connecting position of the connecting portion in the ventral portion.
In articulated disposable wear items
The portion of the ventral portion having the target sheet has a portion to which the fine fibrous cellulose aggregate is attached in a range in the thickness direction from the target sheet to the back surface of the liquid impermeable sheet.
The ventral portion does not have the microfibrous cellulose aggregate other than the portion having the target sheet.
The fine fibrous cellulose aggregate is capable of absorbing moisture located on the front side of the target sheet.
An articulated disposable wear item.

(Action effect)
The fine fibrous cellulose aggregate has high hygroscopicity. Therefore, in this articulated disposable wearable article, stuffiness in the region having the target sheet can be reduced. Further, although the microfibrous cellulose aggregate is hard, in the present connection type disposable wear article, the microfibrous cellulose aggregate is covered with at least a liquid permeable sheet and a top sheet on the front side of the article, and the microfibrous cellulose aggregate thereof The adhesion area is also limited. Therefore, while using the fine fibrous cellulose aggregate as a moisture absorbing material, it is possible to prevent stuffiness while suppressing the hardening of the wearer's touch.

<Second aspect>
The connecting portion is a hook material and
The target sheet is a non-woven fabric attached to the outer surface of the exterior non-woven fabric.
The fine fibrous cellulose aggregate is attached to the non-woven fabric of the target sheet, and the amount of the fine fibrous cellulose aggregate attached to the non-woven fabric of the target sheet decreases from the front side to the back side of the target sheet. ing,
The articulated disposable wear article of the first aspect.

(Action effect)
When the target sheet itself is made of a non-woven fabric and the fine fibrous cellulose aggregate is attached to the non-woven fabric, stuffiness in the region having the target sheet can be reduced without increasing the number of members. Further, since the fine fibrous cellulose aggregate is hard, it affects the touch of the outer surface of the target sheet. Therefore, the amount of the fine fibrous cellulose aggregate adhered is reduced from the front side (the side closer to the wearer's skin when worn) to the back side (the side farther from the wearer's skin when worn). , It is preferable to suppress the hardening of the outer surface of the target sheet to the touch.

<Third aspect>
The connecting portion is a hook material and
The target sheet is a non-woven fabric attached to the outer surface of the exterior non-woven fabric.
The fine fibrous cellulose aggregate is attached to the non-woven fabric of the target sheet, and the attached portion of the fine fibrous cellulose aggregate does not have the fine fibrous cellulose aggregate exposed on the outer surface of the target sheet. ,
The articulated disposable wear article of the first aspect.

(Action effect)
When the target sheet itself is made of a non-woven fabric and the fine fibrous cellulose aggregate is attached to the non-woven fabric, stuffiness in the region having the target sheet can be reduced without increasing the number of members. Further, since the fine fibrous cellulose aggregate is hard, it affects the touch of the outer surface of the target sheet. Therefore, it is preferable not to have the fine fibrous cellulose aggregate exposed on the outer surface of the target sheet because it is possible to suppress the hardening of the outer surface of the target sheet to the touch.

<Fourth aspect>
The connecting portion is a hook material and
The target sheet is a non-woven fabric attached to the outer surface of the exterior non-woven fabric.
In the target sheet, thin-walled portions having dents on at least the inner surface are repeatedly formed at intervals, and the fine fibrous cellulose aggregate is adhered to the thin-walled portions.
A ventilation gap is provided between the thin portion of the target sheet and the sheet adjacent to the inner surface of the target sheet.
A concatenated disposable wear article according to any one of the first to third aspects.
(Action effect)
In this articulated disposable wear item, moisture can escape through at least the inner surface of the target sheet through the ventilation gap. Further, in the process, moisture can be efficiently supplied to the fine fibrous cellulose aggregate which is a hygroscopic material to absorb moisture.

According to the present invention, there are advantages such as prevention of fluffing when peeling is repeated and improvement of the connecting force of the hook material at the same time.

It is a top view in the unfolded state which shows the inner surface of a tape type disposable diaper. It is a top view in the unfolded state which shows the outer surface of a tape type disposable diaper. FIG. 6 is a sectional view taken along line 6-6 of FIG. It is a cross-sectional view of line 7-7 of FIG. (A) is a sectional view taken along line 8-8 of FIG. 1, and (b) is a sectional view taken along line 9-9 of FIG. FIG. 5 is a sectional view taken along line 5-5 of FIG. It is sectional drawing of the attachment part of the fine fibrous cellulose aggregate. It is a top view which shows the main part of the outer surface of a tape type disposable diaper. It is a top view which shows the main part of the outer surface of the tape type disposable diaper including a moisture absorption sheet. It is sectional drawing which shows the main part of the tape type disposable diaper of FIG. It is a top view in the unfolded state which shows the outer surface of a tape type disposable diaper. (A) is an enlarged plan view of the target sheet, and (b) is a cross-sectional view of a portion including the target sheet. It is an enlarged photograph of the attachment part of the fine fibrous cellulose aggregate. It is sectional drawing of the part including a target sheet.

1 to 6 show an example of a tape-type disposable diaper, in which reference numeral W indicates the entire width of the diaper excluding the connecting tape, and reference numeral L indicates the total length of the diaper. The dotted pattern portion shows a hot melt adhesive as a joining means for joining the constituent members located on the front side and the back side thereof. The hot melt adhesive can be coated by a known method such as slot coating, continuous linear or dotted bead coating, spiral or Z-shaped spray coating, or pattern coating (transfer of hot melt adhesive by letterpress method). Can be applied. Alternatively or in conjunction with this, at the fixed portion of the elastic member, a hot melt adhesive can be applied to the outer peripheral surface of the elastic member to fix the elastic member to the adjacent member. Examples of the hot melt adhesive include EVA type, adhesive rubber type (elastomer type), olefin type, polyester / polyamide type and the like, but they can be used without particular limitation. As a joining means for joining each component, a means by material welding such as a heat seal or an ultrasonic seal can also be used.

This tape-type disposable diaper has a crotch portion including the center of the anterior-posterior LD, a ventral portion F extending anteriorly from the center of the anterior-posterior LD, and a dorsal portion B extending posteriorly from the center of the anterior-posterior LD. doing. In addition, this tape-type disposable diaper has an absorber 56 built in a range including the crotch portion, a liquid-permeable top sheet 30 that covers the front side of the absorber 56, and a liquid-impermeable top sheet that covers the back side of the absorber 56. It has a sheet 11 and an exterior non-woven fabric 12 that covers the back side of the liquid-impermeable sheet and constitutes the outer surface of the product.

Hereinafter, the materials and characteristic parts of each part will be described in order.
(Absorber)
The absorber 56 is a portion that absorbs and retains the excrement liquid, and can be formed by an aggregate of fibers. The fiber aggregate is a filament aggregate obtained by stacking short fibers such as cotton-like pulp and synthetic fibers, and opening tow (fiber bundle) of synthetic fibers such as cellulose acetate as necessary. Can also be used. The basis weight of fibers, when fiber stacking flocculent pulp or short fibers, for example, be a 100 to 300 g / m ² approximately, in the case of a filament aggregate, for example, be 30 to 120 g / m ² approximately Can be done. In the case of synthetic fibers, the fineness is, for example, 1 to 16 dtex, preferably 1 to 10 dtex, and more preferably 1 to 5 dtex. In the case of a filament aggregate, the filament may be a non-crimped fiber, but is preferably a crimped fiber. The degree of crimping of the crimped fibers can be, for example, 5 to 75 fibers per 2.54 cm, preferably 10 to 50 fibers, and more preferably about 15 to 50 fibers. In addition, uniformly crimped crimped fibers can be used.

(Highly absorbent polymer particles)
The absorber 56 may contain highly absorbent polymer particles in part or in whole. The highly absorbent polymer particles include "powder" in addition to "particles". As the highly absorbent polymer particles, those used for this kind of absorbent article can be used as they are. The particle size of the highly absorbent polymer particles is not particularly limited, but for example, sieving (shaking for 5 minutes) using a standard sieve (JIS Z8801-1: 2006) of 500 μm, and particles falling under the sieve by this sieving. When sieving (shaking for 5 minutes) using a 180 μm standard sieve (JIS Z8801-1: 2006), the proportion of particles remaining on the 500 μm standard sieve is 30% by weight or less, and the 180 μm standard sieve. It is desirable that the proportion of particles remaining on the top is 60% by weight or more.

The material of the highly absorbent polymer particles can be used without particular limitation, but those having a water absorption of 40 g / g or more are preferable. Highly absorbent polymer particles include starch-based, cellulosic-based and synthetic polymer-based ones, which are starch-acrylic acid (salt) graft copolymers, saponified starch-acrylonitrile copolymers, and crosslinked sodium carboxymethyl cellulose. A substance or an acrylic acid (salt) polymer or the like can be used. As the shape of the highly absorbent polymer particles, a commonly used powder or granular material is preferable, but other shapes can also be used.

As the highly absorbent polymer particles, those having a water absorption rate of 70 seconds or less, particularly 40 seconds or less are preferably used. If the water absorption rate is too slow, so-called reversion, in which the liquid supplied into the absorber 56 returns to the outside of the absorber 56, is likely to occur.

Further, as the highly absorbent polymer particles, those having a gel strength of 1000 Pa or more are preferably used. As a result, even when the bulky absorber 56 is used, the sticky feeling after liquid absorption can be effectively suppressed.

The basis weight of the highly absorbent polymer particles can be appropriately determined according to the amount of absorption required for the application of the absorber 56. Therefore, although it cannot be said unconditionally, it can usually be set to 50 to 350 g / m ² .

(Packaging sheet)
In order to prevent the highly absorbent polymer particles from coming off or to improve the shape retention of the absorber 56, the absorber 56 can be incorporated as an absorbent element 50 wrapped in a packaging sheet 58. As the packaging sheet 58, tissue paper, particularly crepe paper, non-woven fabric, non-woven fabric of polylami, a sheet having small holes, or the like can be used. However, it is desirable that the sheet does not allow the highly absorbent polymer particles to escape. When a non-woven fabric is used instead of the crepe paper, a hydrophilic SMMS (spunbond / meltblown / meltblown / spunbond) non-woven fabric is particularly preferable, and polypropylene, polyethylene / polypropylene or the like can be used as the material. The fiber basis weight is preferably 5 to 40 g / m ² , especially 10 to 30 g / m ² .

As shown in FIG. 3, the packaging sheet 58 has a structure in which one sheet wraps the entire absorber 56, or a plurality of sheets such as two upper and lower sheets may wrap the entire absorber 56 . The packaging sheet 58 may be omitted.

(Top sheet)
The top sheet 30 has liquid permeability, and for example, a perforated or non-perforated non-woven fabric, a porous plastic sheet, or the like can be used.

The top sheet 30 extends from the front end to the rear end of the product in the front-rear direction and extends laterally from the absorber 56 in the width direction WD. For example, the starting point of the rising gather 60 described later is more than the side edge of the absorber 56. If necessary, such as when the top sheet 30 is located on the center side in the width direction, the width of the top sheet 30 can be made shorter than the total width of the absorber 56, and the like can be appropriately deformed.

(Intermediate sheet)
An intermediate sheet (also referred to as a "second sheet") 40 can be provided on the back side of the top sheet 30 in order to prevent the liquid that has permeated the top sheet 30 from returning. The intermediate sheet 40 may be omitted.

As the intermediate sheet 40, various non-woven fabrics can be preferably used, and a particularly bulky air-through non-woven fabric can be preferably used. It is preferable to use a composite fiber having a core-sheath structure for the air-through non-woven fabric. In this case, the resin used for the core may be polypropylene (PP), but polyester (PET) having high rigidity is preferable. Basis weight is preferably ^{17~80g / m 2, 25~60g / m} 2 is more preferable. The thickness of the raw material fiber of the non-woven fabric is preferably 2.0 to 10 dtex. In order to make the non-woven fabric bulky, it is also preferable to use eccentric fibers having no core in the center, hollow fibers, and eccentric and hollow fibers as mixed fibers of all or a part of the raw material fibers.

Although the intermediate sheet 40 of the illustrated example is arranged in the center shorter than the width of the absorber 56, it may be provided over the entire width. Further, the intermediate sheet 40 may be provided over the entire length of the diaper, but may be provided only in the intermediate portion including the excretion position as shown in the illustrated example.

(Liquid impermeable sheet)
Liquid impervious sheet 11, is not particularly limited, and is preferably has a moisture permeability. The liquid-impermeable sheet 11 is microporous obtained by kneading an inorganic filler in an olefin resin such as polyethylene or polypropylene, forming the sheet, and then stretching the sheet in the uniaxial or biaxial direction. The sheet can be preferably used. Further, as the liquid-impermeable sheet 11, a non-woven fabric as a base material with improved waterproofness can also be used.

It is desirable that the liquid-impermeable sheet 11 extends in the same or wider range as the absorber 56 in the front-rear direction LD and the width direction WD, but if necessary, such as when other impermeable means is present, it may be necessary. It is also possible to have a structure that does not cover the end portion of the absorber 56 in the front-rear direction LD and the width direction WD.

(Exterior non-woven fabric)
The exterior non-woven fabric 12 covers the entire back side of the liquid-impermeable sheet 11 and gives the outer surface of the product a cloth-like appearance. The non-woven fabric can be used alone or in layers. In the latter case, it is preferable to bond the non-woven fabrics to each other with a hot melt adhesive or the like. When a non-woven fabric is used, it is preferable that the constituent fibers have a fineness of 1.6 to 2.3 dtex, a basis weight of 15 to 25 g / m ² , and a thickness of 0.3 to 0.8 mm.

(Get up gather)
In order to prevent excrement that travels laterally along the top sheet 30 and prevent so-called lateral leakage, rising gathers 60 that stand up on the skin side of the wearer are provided on both sides of the surface widthwise WD. Is preferable. Of course, the rising gather 60 can be omitted.

When the rising gather 60 is adopted, its structure is not particularly limited, and any known structure can be adopted. The rising gather 60 of the illustrated example is composed of a gather sheet 62 substantially continuous in the width direction WD and an elongated gather elastic member 63 fixed to the gather sheet 62 in an extended state along the front-rear direction LD. ing. A water-repellent non-woven fabric can be used as the gather sheet 62, and a rubber thread or the like can be used as the gather elastic member 63. As shown in FIGS. 1 and 2, a plurality of elastic members may be provided, and one elastic member may be provided.

The inner surface of the gather sheet 62 has a joint start end in the width direction on the side portion of the top sheet 30, and the portion outside the width direction from the joint start end is the inner surface of each side flap portion SF, that is, liquid opaque in the illustrated example. It is bonded to the side portion of the sex sheet 11 and the side portion of the exterior nonwoven fabric 12 located outside in the width direction by a hot melt adhesive or the like.

Around the legs, the inside of the rising gather 60 in the width direction from the joint start end is fixed on the top sheet 30 at both ends in the front-rear direction of the product, but the part between them is a non-fixed free part, and this free part is It rises due to the contraction force of the elastic member 63 and comes into close contact with the body surface.

(End flap part, side flap part)
The tape-type disposable diaper of the illustrated example has a pair of end flap portions EF having no absorber 56 extending to the front side and the rear side of the absorber 56, respectively, and lateral to both side edges of the absorber 56. Each has a pair of side flap portions SF that do not have an absorber 56 and extend. As shown in the illustrated example, the side flap portion SF may be made of a material (exterior nonwoven fabric 12 or the like) continuous from the portion having the absorber 56, or may be formed by attaching another material.

(Plane gather)
A side elastic member 64 made of an elongated elastic member such as rubber thread is fixed to each side flap portion SF in a state of being extended along the front-rear direction LD, whereby the leg circumference portion of each side flap portion SF is fixed. Is configured as a plane gather. As shown in the illustrated example, the leg circumference elastic member 64 is provided between the gather sheet 62 and the liquid-impermeable sheet 11 on the outer side in the width direction near the joint start end in the joint portion of the gather sheet 62, and also has a side flap portion. It can also be provided between the liquid-impermeable sheet 11 and the exterior non-woven fabric 12 in SF. A plurality of elastic members 64 around the legs may be provided on each side as shown in the illustrated example, or only one elastic member 64 may be provided on each side.

The plane gather is a portion on which the contraction force of the side elastic member 64 acts (a portion in which the side elastic member 64 is shown in the drawing). Therefore, in addition to the form in which the side elastic member 64 exists only in the flat gathered portion, the side elastic member 64 exists on the front side, the rear side, or both sides of the flat gathered portion, but the side elastic member 64 exists in other than the flat gathered portion. When the member is finely cut in one place or many places, is not fixed to the sheet sandwiching the side elastic member 64, or both, the contraction force acts on the parts other than the flat gather. It also includes a structure in which the contractile force of the side elastic member 64 acts only on the flat gathered portion (substantially equivalent to not providing the elastic member).

(Wing part)
In this tape-type disposable diaper, the dorsal portion B has a wing portion WP extending outward from the crotch portion M in the width direction WD. Similarly, the ventral portion F also has a wing portion WP extending outward of the WD in the width direction from the crotch portion M. These wing portion WPs can also be formed by a member different from the other portions. However, in the structure having the side flap portion SF as shown in the illustrated example, the concave shape from the side edge of the crotch portion M to the lower edge 71 of the wing portion by cutting the middle of the LD in the front-rear direction on the side portion of the side flap portion SF. It is preferable that the edge 70 is formed and the wing portion WP is formed as a result because it is easy to manufacture.

(Connecting tape)
As shown in FIGS. 1, 2 and 6, the wing portion WP in the dorsal portion B is provided with a connecting tape 80 that is detachably connected to the outer surface of the ventral portion F, respectively. When wearing the diaper 10, the connecting tape 80 is turned from both sides of the waist to the outer surface of the ventral portion F, and the connecting portion 83 of the connecting tape 80 is connected to an appropriate position on the outer surface of the ventral portion F.

As shown in FIG. 6, the connecting tape 80 includes a base end portion 81 fixed to the wing portion WP, a sheet base material 80S forming a main body portion 82 extending from the base end portion 81, and the sheet base material 80S. It has a connecting portion 83 with respect to the ventral portion F provided in the middle portion of the main body portion 82 in the width direction WD. In the main body 82, the base end 81 side of the connecting portion 83 is a non-connecting portion 84 that is not connected to the ventral portion F, and the opposite side is a knob portion 85. The non-connecting portion 84 and the knob portion 85 are composed of only the sheet base material 80S forming the main body portion 82.

The connecting portion 83 is made of a hook material (male material) of a mechanical fastener (hook-and-loop fastener). The hook material has a large number of engaging protrusions on its connecting surface, and the shapes of the engaging protrusions are (A) -shaped, (B) J-shaped, (C) mushroom-shaped, and (D). There are T-shapes, (E) double J-shapes (shapes in which J-shapes are joined back to back), etc., but any shape may be used.

Further, as the sheet base material 80S forming the base end portion 81 to the main body portion 82, a non-woven fabric, a plastic film, a polylace non-woven fabric, paper or a composite material thereof can be used, but the fineness is 1.0 to 3.5 dtex. A spunbonded non-woven fabric, an air-through non-woven fabric, or a spunlaced non-woven fabric having a texture of 60 to 100 g / m ² and a thickness of 1 mm or less is preferable.

Although the connecting portion 83 of the illustrated example is provided on the sheet base material 80S of the connecting tape 80 protruding from the wing portion WP, it may be provided directly on the wing portion WP.

(Target sheet)
A target sheet 20 is provided at a connecting portion of the connecting tape 80 in the ventral portion F.

The material of the target sheet 20 is not particularly limited, but when the connecting portion 83 is a hook material, for example, a long-fiber non-woven fabric in which fibers are partially welded to each other by ultrasonic welding of an intermittent pattern may be used. it can. In this case, the long-fiber non-woven fabric is preferably a non-woven fabric having a fineness of 5 to 10 dtex, a basis weight of 25 to 40 g / m ² , and a thickness of 0.3 to 0.8 mm.

Further, when the connecting portion 83 is a hook material, a target sheet 20 having a large number of loop threads provided on the surface of a base material made of a plastic film or a non-woven fabric in which the engaging protrusions of the hook material are entangled can be used. .. A specific example of this is a composite sheet material in which loop pile fiber threads are sewn on at least the outer surface of the base material. In this sheet material, loop pile fiber threads are projected on the outer surface of the base material, that is, the outer surface side of the disposable diaper at intervals in the weft diameter direction, and the pile fiber threads are projected on the back side (wearer side) of the base material. Are combined with each other to form an intersecting row of pile fiber diameter yarns.

Further, when the connecting portion 83 is a hook material and the connecting portion of the connecting tape 80 on the ventral side portion F is made of the non-woven fabric 21 (for example, when the exterior non-woven fabric 12 is provided as shown in the illustrated example), the inside of the exterior non-woven fabric 12 A target sheet 20 such as a plastic sheet, paper, or a non-woven fabric 21 on which the connection position of the scale 29 or the like is printed can be arranged. In this case, the user can perform the connection by entwining the hook material of the connecting portion 83 with the fibers of the exterior nonwoven fabric 12 at the position of the target sheet 20 which is seen through the exterior nonwoven fabric 12. If the scale 29 is a mark indicating the position of the WD in the width direction, a plurality of linear marks along the LD in the front-rear direction are provided in the WD in the width direction at predetermined intervals, and FIGS. 11 and 12 (a). As shown in, a plurality of Arabic numbers are provided in the width direction WD at a predetermined interval, and a plurality of signs having an appropriate shape such as an arrow or a triangle, which are not shown, are provided in the width direction WD at a predetermined interval. , Or a combination thereof.

On the other hand, when the connecting portion 83 is an adhesive layer, the target sheet 20 can be a plastic film having a smooth surface and having a peeling treatment.

(Adhesion part of microfibrous cellulose aggregate)
Characteristically, the portion of the ventral portion F having the target sheet 20 has the attachment portion 23 of the fine fibrous cellulose aggregate 22 in the range in the thickness direction from the target sheet 20 to the back surface of the liquid impermeable sheet 11. The fine fibrous cellulose aggregate 22 is capable of absorbing moisture located on the front side of the target sheet 20. Further, at least the ventral portion F (more preferably the entire article) does not have the fine fibrous cellulose aggregate 22 other than the portion having the target sheet 20. The fine fibrous cellulose aggregate 22 has high hygroscopicity. Therefore, in this articulated disposable wearable article, stuffiness in the region having the target sheet 20 can be reduced. Further, although the fine fibrous cellulose aggregate 22 is hard, in the present connection type disposable wear article, the fine fibrous cellulose aggregate 22 is covered with at least a liquid permeable sheet 11 and a top sheet 30 on the front side of the article. At the same time, the adhesion area is also limited. Therefore, while using the fine fibrous cellulose aggregate 22 as a moisture absorbing material, it is possible to prevent stuffiness while suppressing the hardening of the wearer's touch. Further, as shown in FIG. 8B, it is preferable not to have the fine fibrous cellulose aggregate 22 other than the portion overlapping with the absorber 56 because the hardness of the wearer's touch can be further suppressed.

The fine fibrous cellulose aggregate 22 is attached to the target sheet 20 itself as shown in the examples shown in FIGS. 2, 7, 8, 11 and 12, and is also attached to the target sheet 20 as shown in FIGS. 9 and 10. It can also be provided on another member at a portion overlapping the sheet 20. As another member in the latter case, when the target sheet 20 is attached to the outer surface of the exterior nonwoven fabric 12, the exterior nonwoven fabric 12 or the liquid-impermeable sheet 11 can be used, and the target sheet 20 is the exterior. When sandwiched between the non-woven fabric 12 and the liquid-impermeable sheet 11, the liquid-impermeable sheet 11 can be used. In addition, as shown in FIGS. 9 and 10, a dedicated moisture absorbing sheet 15 to which the fine fibrous cellulose aggregate 22 is attached may be interposed between the target sheet 20 and the liquid impermeable sheet 11. ..

The attachment portion 23 of the fine fibrous cellulose aggregate 22 is formed by applying a fine fibrous cellulose dispersion liquid dispersed in a dispersion liquid such as water to a member to be adhered such as a non-woven fabric and drying it. Can be manufactured by

When the adhering portion 23 of the fine fibrous cellulose aggregate 22 is formed by applying the fine fibrous cellulose dispersion, the concentration (mass / volume) of the fine fibrous cellulose dispersion may be 0.1 to 10%. It is preferably 1.0 to 5.0%, more preferably 1.5 to 3.0%, and particularly preferably 1.5 to 3.0%.

The B-type viscosity (60 rpm, 20 ° C.) of the fine fibrous cellulose dispersion is, for example, 700 cps or less, preferably 200 cps or less, and more preferably 50 cps or less. By keeping the B-type viscosity of the fine fibrous cellulose dispersion low in this way, the fine fibrous cellulose can be uniformly applied to the non-woven fabric.

In addition to spraying the target surface, a transfer method such as a letterpress method can be used to apply the fine fibrous cellulose dispersion.

Pulp fibers that can be used for producing fine fibrous cellulose include chemical pulps such as broadleaf pulp (LBKP) and coniferous pulp (NBKP), bleached thermomechanical pulp (BTMP), stone ground pulp (SGP), and pressurized stone ground. Pulp (PGW), Refiner Gland Pulp (RGP), ChemiGrand Pulp (CGP), Thermogrand Pulp (TGP), Gland Pulp (GP), Thermomechanical Pulp (TMP), Chemithermo Mechanical Pulp (CTMP), Refiner Mechanical Pulp From machine pulp such as (RMP), brown waste paper, kraft envelope blind paper, magazine waste paper, newspaper waste paper, leaflet waste paper, office waste paper, cardboard waste paper, top white waste paper, Kent waste paper, imitation waste paper, ground ticket waste paper, sashimi waste paper, etc. Examples thereof include used paper pulp produced and deinked pulp (DIP) obtained by deinking waste paper pulp. These may be used alone or in combination of a plurality of types as long as the desired effect is not impaired. Further, the pulp fiber obtained by subjecting the pulp fiber to a chemical treatment such as carboxymethylation may be used.

Examples of the method for producing fine fibrous cellulose include mechanical methods such as a high-pressure homogenizer method, a microfluidizer method, a grinder grinding method, a bead mill freeze pulverization method, and an ultrasonic defibration method, but the method is limited to these methods. It's not a thing. Further, nanofiber formation is promoted by a combination of TEMPO oxidation treatment, phosphoric acid esterification treatment, acid treatment and the like.

The attachment portion 23 of the fine fibrous cellulose aggregate 22 may be provided in any pattern as long as it is a portion having the target sheet 20. For example, the attachment portion 23 of the fine fibrous cellulose aggregate 22 may be provided in a continuous plane shape over the entire or most of the portion having the target sheet 20. However, since the fine fibrous cellulose aggregate 22 is hard, the attachment portion 23 of the fine fibrous cellulose aggregate 22 is spaced apart from each other in the front-rear direction LD, the width direction WD, or the diagonal direction inclined with respect to these. It is preferable that they are arranged in a repeating pattern. For example, as shown in FIG. 8B, the attachment portions 23 of the dot-shaped microfibrous cellulose aggregates 22 having a circular shape or a polygonal shape are arranged in a staggered manner (illustrated example), arranged in a matrix (not shown), or the like. It can also be provided in dots.

As shown in FIGS. 2 and 9, the attachment portion 23 of the fine fibrous cellulose aggregate 22 may be arranged in a horizontal stripe pattern in which a plurality of linear attachment portions 23 along the width direction WD are arranged at intervals in the front-rear direction LD. As shown in FIG. 8A, a plurality of linear attachment portions 23 along the front-rear direction LD may be arranged in a vertical stripe pattern at intervals in the width direction WD. Further, although not shown, the attachment portion 23 of the fine fibrous cellulose aggregate 22 is a linear fine fibrous shape along the attachment portion 23 of the linear fine fibrous cellulose aggregate 22 along the front-rear direction LD and the width direction WD. It may be arranged in a grid pattern composed of the attachment portions 23 of the cellulose aggregate 22 or in an oblique lattice pattern. As described above, when the attachment portion 23 of the fine fibrous cellulose aggregate 22 is continuously connected in a linear shape, it can be continuously continuous in a linear shape or in a curved or wavy shape.

The size of the attachment portion 23 of the fine fibrous cellulose aggregate 22 can be appropriately determined. When the attachment portion 23 of the fine fibrous cellulose aggregate 22 has a dot-like pattern, the diameter 23d (the length of the longest portion) of the attachment portion 23 of the fine fibrous cellulose aggregate 22 is 1.0 to 4.0 mm, particularly. It is preferably 2.0 to 3.0 mm, and the center (or center of gravity) spacing x1 and y1 of the rows adjacent to the WD in the width direction and the LD in the front-rear direction are preferably 5 to 25 mm, particularly preferably 15 to 10 mm. Further, when the arrangement of the attachment portion 23 of the fine fibrous cellulose aggregate 22 is a striped pattern, the line width 23w of the attachment portion 23 of the fine fibrous cellulose aggregate 22 is 1.0 to 4.0 mm, particularly 2. The distance is preferably 0 to 3.0 mm, and the distance x2 and y2 between the adjacent bonding portions 23 is preferably 5 to 30 mm, particularly preferably 10 to 20 mm. Further, when the arrangement of the attachment portion 23 of the fine fibrous cellulose aggregate 22 is a lattice pattern, the line width of the attachment portion 23 of the fine fibrous cellulose aggregate 22 is 1.0 to 4.0 mm, particularly 2.0 to 2.0 to It is preferably 3.0 mm, and the lattice spacing (distance between the attachment portions 23 of the parallel microfibrous cellulose aggregates 22) is 5 to 30 mm, particularly preferably 10 to 20 mm.

The material to which the fine fibrous cellulose aggregate 22 is attached is not particularly limited and may be a resin film or the like, but the non-woven fabric 21 is preferable from the viewpoint of flexibility and breathability.

When the target sheet 20 is a non-woven fabric 21, it is preferable that the fine fibrous cellulose aggregate 22 is attached to the non-woven fabric 21 as shown in FIG. In particular, when the target sheet 20 is attached to the outer surface of the exterior non-woven fabric 12 and the hook material of the connecting portion 83 is entwined with the fibers of the non-woven fabric 21 to be connected, the non-woven fabric is attached to the adhering portion 23 of the fine fibrous cellulose aggregate 22. When the constituent fibers of 21 are bonded to each other via the fine fibrous cellulose aggregate 22, the fibers are less likely to be pulled out even if the hook material is attached or detached many times, and fluffing is less likely to occur, which is preferable. For example, when the adhesion portion 23 of the fine fibrous cellulose aggregate 22 is formed by applying the fine fibrous cellulose dispersion liquid to the non-woven fabric 21, the fine fibrous cellulose dispersion liquid permeates between the fibers of the non-woven fabric 21, and after drying, The fine fibrous cellulose aggregate 22 firmly adheres to the surface of each fiber, and the fibers are firmly bonded to each other via the fine fibrous cellulose aggregate 22 at the intersections and proximity portions of the constituent fibers of the non-woven fabric 21.

In order to firmly bond the constituent fibers of the non-woven fabric 21, the adhesive portion 23 continuous in the direction intersecting the orientation direction of the fibers of the non-woven fabric 21 of the target sheet 20 is targeted in the orientation direction of the fibers of the non-woven fabric 21 of the target sheet 20. A striped pattern that is shorter than the fiber length of the non-woven fabric 21 of the sheet 20 and is arranged at intervals of 5 mm or more is preferable. For example, in the examples shown in FIGS. 2, 11 and 12, the direction of fiber orientation of the non-woven fabric 21 of the target sheet 20 is the anteroposterior direction LD, and the attachment portion 23 of the fine fibrous cellulose aggregate 22 is formed in a horizontal stripe pattern. Then, the distance y2 of the LDs in the front-rear direction of the adjacent adhesive portions 23 can be shorter than the fiber length of the exterior nonwoven fabric 12 and 5 mm or more.

When the object to which the fibrous cellulose aggregate is attached is the non-woven fabric 21, as long as the attached portion 23 of the fine fibrous cellulose aggregate 22 is attached to at least a part of the non-woven fabric 21 in the thickness direction, FIG. 7C shows. As shown, it may be attached to only a part in the thickness direction, it may be attached to all of the thickness direction as shown in FIGS. 7 (a), (b) and (d), or these may be mixed. .. Further, even if the amount of the fine fibrous cellulose aggregate 22 adhered is constant in the thickness direction of the nonwoven fabric 21 as shown in FIG. 7A, as shown in FIGS. 7B, 7C and 7D. It may be changing or a mixture of these.

When the object to which the fibrous cellulose aggregate is attached is the non-woven fabric 21, the fine fibrous cellulose aggregate 22 may be coated on the entire circumferential direction of each fiber, or the fine fibrous cellulose is indicated by a white arrow in FIG. As shown in the aggregate 22, it is not necessary that a large amount of the individual fibers adhere to the coated side F1 and a small amount adheres to the non-coated side F2. Further, as shown in FIG. 13, the fine fibrous cellulose aggregate 22 may be attached substantially continuously along the continuous direction of the fibers, or may be sparsely attached in the continuous direction of the fibers. It is preferable that the number of the fine fibrous cellulose aggregates 22 that do not bond the fibers to each other is small because the non-woven fabric 21 becomes flexible.

As shown in the examples shown in FIGS. 2, 7, 8, 11 and 12, the target sheet 20 itself is a non-woven fabric 21, and when the fine fibrous cellulose aggregate 22 is attached thereto, the number of members is increased. It is possible to reduce stuffiness in the region having the target sheet 20. However, in this case, since the fine fibrous cellulose aggregate 22 is hard, it affects the touch of the outer surface of the target sheet 20. Therefore, it is preferable that the amount of the fine fibrous cellulose aggregate 22 adhered decreases from the front side to the back side as shown in FIGS. 7 (b) and 7 (c). As a result, it is possible to suppress a decrease in the connecting force of the hook material to the adhering portion 23 of the fine fibrous cellulose aggregate 22, and a hardening of the surface feel. It is more preferable that the attachment portion 23 of the fine fibrous cellulose aggregate 22 does not have the fine fibrous cellulose aggregate 22 exposed on the surface of the non-woven fabric 21 of the target sheet 20 as shown in FIG. 7 (c).

The uneven distribution of the fine fibrous cellulose aggregate 22 in the thickness direction and the change in the amount of adhesion are determined by whether the fine fibrous cellulose dispersion is applied from the front or back of the non-woven fabric 21, and the amount of application and the degree of permeability. Can be achieved by selecting. For example, the adhering portion 23 of the fine fibrous cellulose aggregate 22 shown in FIGS. 7 (b) and 7 (c) can be formed by applying an appropriate amount of the fine fibrous cellulose dispersion liquid to the back surface of the nonwoven fabric 21, and FIG. The adhering portion 23 of the fine fibrous cellulose aggregate 22 shown in (d) can be formed by applying an appropriate amount of the fine fibrous cellulose dispersion liquid to the surface of the non-woven fabric 21.

The content of microfibrillated cellulose in the attachment portion 23 of the microfibrous cellulose assembly 22 is preferably to be about 2~7g / m ^2, and more preferably particularly at 2-5 g / m ² approximately.

When the adhering portion 23 of the fine fibrous cellulose aggregate 22 is colored in a color different from that of the member to be adhered and the member located on the outer surface side thereof (for example, the target sheet 20), the range of the target sheet 20 can be easily visually recognized. it can. Further, by forming the colored attachment portion 23 in a scale shape (for example, FIG. 8A), it is possible to use it as a guide for the connection position of the connection portion 83. Such a colored adhesive portion 23 can be formed by adding a coloring agent such as a dye to the dispersion liquid of the fine fibrous cellulose.

The target sheet 20 is a non-woven fabric 21 attached to the outer surface of the exterior non-woven fabric 12, and is a case where the hook material of the connecting portion 83 is entwined with the fibers of the non-woven fabric 21 and connected to the non-woven fabric 21 of the target sheet 20. When the fibrous cellulose aggregate 22 is attached, the structure shown in FIG. 14 is also preferable. That is, in this structure, in the target sheet 20, at least the thin-walled portions 22t having dents on the inner surface are repeatedly formed at intervals, and the fine fibrous cellulose aggregate 22 is attached to the thin-walled portions 22t. A ventilation gap 18 is formed between the thin portion 22t of the sheet 20 and the sheet adjacent to the inner surface of the target sheet 20. This allows moisture to escape through at least the inner surface of the target sheet 20 through the ventilation gap 18. Further, in the process, moisture can be efficiently supplied to the fine fibrous cellulose aggregate 22 which is a hygroscopic material to absorb moisture. The pattern of the thin-walled portion 22t can be, for example, the same as the pattern of the attachment portion 23 of the fine fibrous cellulose aggregate 22 described above. Further, the size of the thin-walled portion 22t can be the same as or less than or larger than the size of the attachment portion 23 of the above-mentioned fine fibrous cellulose aggregate 22. The thin portion 22t may have dents on both the inner and outer sides of the target sheet 20 as shown in the illustrated example, or may have dents only on the inner surface of the target sheet 20.

In the target sheet 20 having such a thin-walled portion 22t, the thin-walled portion 22t is formed on the non-woven fabric 21 to be the target sheet 20 by embossing, or the fine fibrous cellulose aggregate 22 is attached to the thin-walled portion 22t thereafter. Can be manufactured by

Further, such a target sheet 20 can be manufactured by the following method. That is, when the dispersion liquid of the fine fibrous cellulose is applied to the non-woven fabric 21 to be the target sheet 20 in a pattern that repeats at intervals, the dispersion liquid permeates between the fibers of the non-woven fabric 21. Then, when this is dried, a thin-walled portion 22t is formed in the coated portion of the dispersion liquid, and a fine fibrous cellulose aggregate 22 is formed in the thin-walled portion 22t. That is, when the dispersion liquid of the fine fibrous cellulose is applied to the non-woven fabric 21 and then the dispersion liquid of the coated portion is dried, when the fine fibrous cellulose aggregate 22 is formed, the volume of the fine fibrous cellulose aggregate 22 is formed. Gradually decreases. Along with this, the volume of the coated portion of the dispersion liquid of the nonwoven fabric 21 also decreases, and the thin-walled portion 22t is automatically formed. This manufacturing method utilizes this. According to this method, the target sheet 20 can be formed only by applying the dispersion liquid of fine fibrous cellulose to the non-woven fabric 21 to be the target sheet 20 in a desired pattern and drying it.

(Non-woven fabric)
As the non-woven fabric in the above description, a known non-woven fabric can be appropriately used depending on the site and purpose. Examples of the constituent fibers of the non-woven fabric include olefin-based fibers such as polyethylene and polypropylene, polyester-based and polyamide-based synthetic fibers (including single-component fibers and composite fibers such as core sheaths), as well as recycled rayon and cupra. Fibers, natural fibers such as cotton, and the like can be selected without particular limitation, and these can be mixed and used. In order to increase the flexibility of the non-woven fabric, it is preferable that the constituent fibers are crimped fibers. Further, the constituent fibers of the non-woven fabric are hydrophobic fibers or water-repellent fibers (water-repellent fibers made water-repellent by the water-repellent agent) even if they are hydrophilic fibers (including those made hydrophilic by the hydrophilic agent). Includes). In addition, the non-woven fabric generally has a short fiber non-woven fabric, a long fiber non-woven fabric, a spunbond non-woven fabric, a melt blown non-woven fabric, a spunlace non-woven fabric, a thermal bond (air-through) non-woven fabric, and a needle punch depending on the fiber length, the sheet forming method, the fiber bonding method, and the laminated structure. It is classified into non-woven fabrics, point-bonded non-woven fabrics, laminated non-woven fabrics (SMS non-woven fabrics having a melt blown layer sandwiched between spunbond layers, SMMS non-woven fabrics, etc.), and any of these non-woven fabrics can be used.
In particular, it is preferable that the non-woven fabric 21 of the target portion 20 is a non-woven fabric 21 of hydrophilic fibers because the fine fibrous cellulose aggregate 22 adheres to the fibers of the non-woven fabric 21 with less interruption, thinner and more uniformly.

<Explanation of terms in the specification>
The following terms in the specification have the following meanings unless otherwise specified in the specification.

-The "front-back direction" means the direction indicated by the symbol LD in the figure (vertical direction), and the "width direction" means the direction indicated by the WD in the figure (left-right direction), and the front-back direction and the width direction. Are orthogonal.

-The "MD direction" and "CD direction" mean the flow direction (MD direction) in the manufacturing equipment and the lateral direction (CD direction) orthogonal to this, and one of them is the front-rear direction depending on the part of the product. And the other is in the width direction. The MD direction of the non-woven fabric is the direction of fiber orientation of the non-woven fabric. The fiber orientation is the direction along which the fibers of the non-woven fabric follow. For example, the measurement method based on the fiber orientation test method based on the zero-distance tensile strength of the TAPPI standard method T481 or the fiber orientation based on the tensile strength ratio in the front-rear direction and the width direction. It can be discriminated by a simple measuring method for determining the orientation direction.

-The "front side" means the one closer to the wearer's skin when worn, and the "back side" means the one farther from the wearer's skin when worn.

-The "front surface" means the surface of the member that is closer to the wearer's skin when worn, and the "back surface" means the surface of the member that is farther from the wearer's skin when worn. ..

-"Elongation rate" means a value when the natural length is 100%. For example, an elongation rate of 200% is synonymous with an elongation ratio of 2 times.

-"Gel strength" is measured as follows. Artificial urine (urea: 2 wt%, sodium chloride: 0.8 wt%, calcium chloride dihydrate: 0.03 wt%, magnesium sulfate heptahydrate: 0.08 wt%, and ion-exchanged water: 97.09 wt% Add 1.0 g of highly absorbent polymer to 49.0 g (mixed product) and stir with a stirrer. The produced gel is left in a constant temperature and humidity chamber at 40 ° C. × 60% RH for 3 hours, then returned to room temperature, and the gel strength is measured with a card meter (Curdmeter-MAX ME-500 manufactured by I. techno Engineering).

・ "Metsuke" is measured as follows. After pre-drying the sample or test piece, leave it in a test room or device under standard conditions (test location: temperature 23 ± 1 ° C., relative humidity 50 ± 2%) to bring it to a constant weight. Pre-drying refers to making a sample or test piece constant in an environment at a temperature of 100 ° C. It is not necessary to pre-dry the fibers having an official moisture content of 0.0%. A sample having a size of 100 mm × 100 mm is cut out from the test piece in a constant weight state using a sampling template (100 mm × 100 mm). The weight of the sample is measured and multiplied by 100 to calculate the weight per square meter, which is used as the basis weight.

-The "thickness" is automatically measured using an automatic thickness measuring device (KES-G5 handy compression measurement program) under the conditions of a load of 0.098 N / cm ² and a pressurized area of 2 cm ² . The thickness of the perforated non-woven fabric is measured at a portion other than the holes and the protrusions around them.

-The water absorption amount is measured by JIS K7223-1996 "Water absorption amount test method for highly water-absorbent resin".

-The water absorption rate shall be the "time to the end point" when JIS K7224-1996 "Water absorption rate test method for superabsorbent polymer" was performed using 2 g of super absorbent polymer and 50 g of physiological saline. ..

"Microfibrous cellulose" refers to fine cellulose fibers taken out from plants such as pulp or bundles thereof, and generally refers to fibrous cellulose having an average fiber width of nano size (1 to 1000 nm or less), and is an average fiber. Those having a width (median diameter) of 100 nm or less (generally called cellulose nanofibrils (CNF)) are preferable, and those having a width (median diameter) of 10 to 60 nm are particularly preferable.

The "average fiber width" of the fine fibrous cellulose can be measured by the following method. That is, first, 100 ml of an aqueous dispersion of fine fibrous cellulose having a solid content concentration of 0.01 to 0.1% by mass is filtered through a membrane filter made of Teflon (registered trademark), once with 100 ml of ethanol, and with 20 ml of t-butanol. Solvent substitution 3 times. Next, it is freeze-dried and coated with osmium to prepare a sample. This sample is observed by an electron microscope SEM image at a magnification of 5000 times, 10000 times, or 30000 times (in this example, a magnification of 30000 times) depending on the width of the constituent fibers. Specifically, two diagonal lines are drawn on the observation image, and three straight lines passing through the intersections of the diagonal lines are arbitrarily drawn. Further, a total of 100 fiber rods intersecting with these three straight lines are visually measured. Then, the median diameter (median diameter) of the measured value is taken as the average fiber width.

-The direction of fiber orientation of the non-woven fabric is the direction along which the fibers of the non-woven fabric follow. For example, a measurement method based on the fiber orientation test method based on the zero-distance tensile strength of the TAPPI standard method T481, or the front-back direction and the width direction. It can be discriminated by a simple measuring method for determining the fiber orientation direction from the tensile strength ratio.

-"Unfolded state" means a state in which the unfolded state is flat without shrinkage or slack.

-Unless otherwise specified, the dimensions of each part mean the dimensions in the unfolded state, not in the natural length state.

-If there is no description about the environmental conditions in the test or measurement, the test or measurement shall be performed in a test room or equipment under standard conditions (test location: temperature 23 ± 1 ° C, relative humidity 50 ± 2%). To do.

The present invention is applicable to articulated disposable wear items such as the tape-type disposable diapers described above.

11 ... Liquid permeable sheet, 12 ... Exterior non-woven fabric, 80 ... Connecting tape, 83 ... Connecting part, 82 ... Main body part, 81 ... Base end part, 20 ... Target sheet, 21 ... Non-woven fabric, 22 ... Microfibrous cellulose aggregate Body, 23 ... Adhesive part, 29 ... Scale, 30 ... Top sheet, 40 ... Intermediate sheet, 50 ... Absorbent element, 56 ... Absorber, 58 ... Packaging sheet, 60 ... Rise gather, 62 ... Gather sheet, 64 ... Side elasticity Member, 70 ... concave edge, 71 ... lower edge of wing part, B ... dorsal part, F ... ventral part, LD ... front-back direction, M ... crotch part, SF ... side flap part, WD ... width direction, WP ... Wing part, 22t ... thin wall part, 18 ... ventilation gap.

Claims (4)

It has a crotch part including the center in the anterior-posterior direction, a ventral part extending anteriorly from the center in the anterior-posterior direction, and a dorsal part extending posteriorly from the center in the anterior-posterior direction.
Absorber built in the range including the crotch part,
A liquid-permeable top sheet provided on the front side of the absorber and
A breathable liquid-impermeable sheet provided on the back side of the absorber, and
It has an exterior non-woven fabric that covers the back side of the liquid-impermeable sheet and constitutes the outer surface of the product.
Both sides of the dorsal portion have connecting portions that are detachably connected to the outer surface of the ventral portion.
A target sheet is provided at a connecting position of the connecting portion in the ventral portion.
In articulated disposable wear items
The portion of the ventral portion having the target sheet has a portion to which the fine fibrous cellulose aggregate is attached in a range in the thickness direction from the target sheet to the back surface of the liquid impermeable sheet.
The ventral portion does not have the microfibrous cellulose aggregate other than the portion having the target sheet.
The fine fibrous cellulose aggregate is capable of absorbing moisture located on the front side of the target sheet.
An articulated disposable wear item. The connecting portion is a hook material and
The target sheet is a non-woven fabric attached to the outer surface of the exterior non-woven fabric.
The fine fibrous cellulose aggregate is attached to the non-woven fabric of the target sheet, and the amount of the fine fibrous cellulose aggregate attached to the non-woven fabric of the target sheet decreases from the front side to the back side of the target sheet. ing,
The articulated disposable wearable article according to claim 1. The connecting portion is a hook material and
The target sheet is a non-woven fabric attached to the outer surface of the exterior non-woven fabric.
The fine fibrous cellulose aggregate is attached to the non-woven fabric of the target sheet, and the attached portion of the fine fibrous cellulose aggregate does not have the fine fibrous cellulose aggregate exposed on the outer surface of the target sheet. ,
The articulated disposable wearable article according to claim 1. The connecting portion is a hook material and
The target sheet is a non-woven fabric attached to the outer surface of the exterior non-woven fabric.
In the target sheet, thin-walled portions having dents on at least the inner surface are repeatedly formed at intervals, and the fine fibrous cellulose aggregate is adhered to the thin-walled portions.
A ventilation gap is provided between the thin portion of the target sheet and the sheet adjacent to the inner surface of the target sheet.
The articulated disposable wear article according to any one of claims 1 to 3.

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