JP7487044B2 - Absorbent articles - Google Patents

Description

The present invention relates to absorbent articles such as disposable diapers.

Wearing absorbent articles such as disposable diapers, sanitary napkins, panty liners (discharge sheets), and incontinence pads can cause skin rashes due to sweating, etc. Therefore, in order to impart a skin care effect and suppress the occurrence of rashes, absorbent articles containing skin care agents as functional agents have been proposed.
For example, Patent Document 1 describes an absorbent article in which a lotion is placed on the top sheet that contacts the wearer's skin to prevent diaper rash. Patent Document 2 describes an absorbent article in which a lotion is placed locally on the top sheet by providing a lotion-placed area and a non-placed area.
Furthermore, Patent Document 3 describes an absorbent article in which a blood modifying agent is disposed as a functional agent.

JP 2002-200112 A JP 2002-172130 A JP 2013-63247 A

In an absorbent article, when a functional agent such as a skin care agent is added to a top sheet, the inherent liquid permeability of the top sheet may be affected. It may be possible to reduce the amount of the functional agent in consideration of the liquid permeability of the top sheet, but such a configuration may make it difficult to obtain the full effect of the functional agent. Thus, there is room for improvement when adding a functional agent to a top sheet of an absorbent article.
For example, in the inventions disclosed in Patent Documents 1 and 2, uneven placement of the lotion agent is likely to occur in the process of applying the lotion agent to the top sheet, making it difficult to achieve both sufficient lotion effect and liquid permeability.
Furthermore, the invention disclosed in Patent Document 3 improves liquid permeability by bringing a blood modifying agent into contact with bodily fluids on the top sheet, but because the functional agent flows out into the absorbent upon contact with bodily fluids, the role of the functional agent is impaired by the passage of fluids.
cough

The present invention relates to an absorbent article having a top sheet that is capable of achieving both good liquid permeability and the expression of functional agent effects.

An absorbent article according to one aspect of the present invention includes an absorbent body and a top sheet.
The top sheet is disposed on the skin-facing side of the absorbent body.
The top sheet includes a fiber layer positioned opposite the wearer's skin and having a mixed fiber region in which first fibers and second fibers are arranged across a plane perpendicular to the thickness direction, and the first fibers and the second fibers are each heat-fusible.
The first fiber includes a hydrophilic treatment agent and a functional agent capable of imparting a predetermined function to the wearer's skin.
The second fibers include a hydrophilic treatment agent.
The second fibers in the mixed fiber region contain a smaller amount of functional agent than the first fibers.
The first fibers and the second fibers are fused together by a heat fusion portion.

An absorbent article according to one embodiment of the present invention comprises an absorbent body and a top sheet.
The top sheet is disposed on the skin-facing side of the absorbent body.
The top sheet includes a fiber layer positioned opposite the wearer's skin and having a mixed fiber region in which first fibers and second fibers are arranged across a plane perpendicular to the thickness direction, and the first fibers and the second fibers are each heat-fusible.
The first fiber includes a hydrophilic treatment agent and a functional agent capable of imparting a predetermined function to the wearer's skin.
The second fibers include a hydrophilic treatment agent.
The second fibers have a smaller contact angle with water than the first fibers.
The first fibers and the second fibers are fused together by a heat fusion portion.

As described above, the absorbent article of the present invention can have a top sheet that can achieve both the effect of the functional agent and good liquid permeability.

FIG. 1 is a diagram showing an example of a disposable diaper as one embodiment of an absorbent article of the present invention, and is a schematic plan view of the skin side (top sheet side) showing the state in which the elastic members of each part are stretched and spread out flat. 2 is a schematic cross-sectional view taken along line II-II in FIG. 1, and corresponds to a cross-sectional view of a disposable diaper provided with a topsheet according to a first embodiment. FIG. 2 is a schematic partially enlarged cross-sectional view of the topsheet according to the first embodiment. FIG. 11 is a schematic perspective view showing an enlarged view of a portion of a top sheet according to a second embodiment. FIG. 11 is a schematic partially enlarged cross-sectional view of the topsheet for explaining the configuration of the convex portions of the topsheet according to the second embodiment.

Hereinafter, the absorbent article of the present invention will be described with reference to the drawings, taking a disposable diaper as an example of one embodiment.
<Overall composition of disposable diapers>
The disposable diaper 1 of this embodiment is a so-called open-type disposable diaper, as shown in FIG. 1. The disposable diaper 1 has a vertical direction X corresponding to the front-rear direction of the wearer, and a horizontal direction Y corresponding to the left-right direction of the wearer and perpendicular to the vertical direction X. Furthermore, the disposable diaper 1 has a thickness direction Z perpendicular to both the vertical direction X and the horizontal direction Y. In this specification, the "skin-facing surface" in each configuration is a surface facing the skin side of the wearer when the disposable diaper is worn, that is, a surface relatively close to the skin of the wearer. The "non-skin-facing surface" in each configuration is a surface facing the opposite side to the skin side of the wearer when the disposable diaper is worn, that is, a surface relatively far from the skin of the wearer. In addition, with regard to the thickness direction Z, the side close to the skin of the wearer when worn may be referred to as the top, and the side close to the clothing may be referred to as the bottom. The disposable diaper 1 will be referred to as diaper 1 hereinafter.

The diaper 1 is divided into a ventral region A located on the ventral side in the longitudinal direction X, a dorsal region B located on the dorsal side in the longitudinal direction X, and a crotch region C located between the ventral region A and the dorsal region B.
The back region B includes side portions protruding outward in the lateral direction Y from the crotch region C. Fastening tapes 6 are provided on the side edges of the side portions in the lateral direction Y. Similarly, the abdominal region A includes side portions protruding outward in the lateral direction Y from the crotch region C. A landing tape (not shown) for adhering the fastening tape 6 is provided on the non-skin-facing surface of the abdominal region A. When worn, the back region B and the abdominal region A are adhered to each other by the fastening tape 6 and are integrally arranged around the hips and waist of the wearer.
The crotch region C has leg openings that are narrower inward in the lateral direction Y than the ventral region A and the dorsal region B, and is positioned around the wearer's crotch area, including the urination area and anus, when worn.
It should be noted that "when worn" here refers to a state in which the normally expected appropriate wearing position is maintained.

As shown in Figures 1 and 2, the diaper 1 has a top sheet 2, a back sheet 3, an absorbent body 4, side sheets 5, a pair of fastening tapes 6, an intermediate sheet 7, and a leak-proof sheet 8. The diaper 1 has a configuration in which the back sheet 3, the leak-proof sheet 8, the absorbent body 4, the intermediate sheet 7, and the top sheet 2 are laminated in the thickness direction Z. These components are joined together by known joining means such as a hot melt adhesive.

The absorbent body 4 extends along the longitudinal direction X, and is disposed between the top sheet 2 and the back sheet 3. The absorbent body 4 absorbs liquid excrement (hereinafter simply referred to as "liquid") such as urine of the wearer from the surface facing the top sheet 2, and retains the liquid by diffusing it internally.
The absorbent body 4 has an absorbent core 40 and a core wrap sheet 41 .
The absorbent core 40 is mainly composed of an absorbent material capable of retaining liquid. Specifically, the absorbent core 40 has a structure in which a hydrophilic fiber stack is supported with an absorbent polymer, or a structure made of only a water-absorbent polymer, or the like.
The core wrap sheet 41 covers the absorbent core 40 and has a function of, for example, maintaining the shape of the absorbent core 40. The core wrap sheet 41 is formed of, for example, a thin, soft paper such as tissue paper or a liquid-permeable nonwoven fabric.
The absorbent body 4 has a skin facing surface 4a and a non-skin facing surface 4b opposite to the skin facing surface 4a.

The top sheet 2 is disposed on the skin-facing surface 4a side (upper in the thickness direction Z) of the absorbent body 4, and constitutes, for example, the central portion in the lateral direction Y of the skin-facing surface of the diaper 1. The top sheet 2 is configured as a liquid-permeable sheet material, and is formed of woven or nonwoven fabric made of synthetic or natural fibers. Details of the top sheet 2 will be described later.

The intermediate sheet 7 is disposed between the top sheet 2 and the absorbent body 4. The intermediate sheet 7 can be made of nonwoven fabric obtained by various manufacturing methods. The intermediate sheet 7 is disposed from the viewpoint of improving the liquid absorption from the top sheet 2 to the absorbent body 4, preventing the liquid absorbed by the absorbent body 4 from returning to the top sheet 2, etc.

The back sheet 3 is disposed on the non-skin facing side 4b of the absorbent body 4 (lower in the thickness direction Z) and, for example, constitutes almost the entire non-skin facing side of the diaper 1, forming the exterior of the diaper 1 when worn. The back sheet 3 is preferably leak-proof, and is formed, for example, from a sheet material that has properties such as low liquid permeability, water vapor permeability, and water repellency.

The pair of side sheets 5 are disposed on the lateral sides of the top sheet 2 in the lateral direction Y, and constitute, for example, the lateral sides of the skin-facing surface of the diaper 1. The side sheets 5 are desirably leak-proof, and are formed, for example, from a sheet material having properties such as poor liquid permeability, water vapor permeability, and water repellency. The pair of side sheets 5 are disposed such that the central sides in the lateral direction Y overlap the top sheet 2, and the lateral sides in the lateral direction Y extend to the outside of the top sheet 2 and are joined to the back sheet 3.
In the diaper 1, the side sheets 5 form a sheet for forming three-dimensional gathers. The side end portions of the side sheets 5 at the center in the lateral direction Y are free ends that are not joined to the top sheet 2 or the like, at least in the crotch region C, and are provided with elastic members 51. The elastic members 51 extend in the longitudinal direction X in the crotch region C, and may extend, for example, to parts of the abdominal region A and the dorsal region B. The provision of the elastic members 51 forms three-dimensional gathers.
Elastic members 52 that stretch in the vertical direction X, for example, are disposed near the side ends of the side sheets 5 on the outer side in the horizontal direction Y, thereby forming leg gathers that fit snugly around the legs of the wearer when worn.
The elastic members 51 and 52 are thread-like or band-like elastic members that are stretchable in the longitudinal direction X.

The pair of fastening tapes 6 have fastening parts 61 made of male members of a mechanical hook-and-loop fastener. A landing tape made of a female member of a mechanical hook-and-loop fastener is provided on the non-skin-facing surface of the abdominal region A of the diaper 1. The fastening parts 61 of the fastening tapes 6 can be removably attached to the landing tape.

The leak-proof sheet 8 is made of a liquid-impermeable or liquid-difficult-to-permeate resin film and covers the skin-facing surface of the back sheet 3.

<Surface sheet>
[Structural description of surface sheet 1]
The topsheet 2 according to the first embodiment and the topsheet 20 according to the second embodiment will be described below.

First Embodiment
The topsheet 2 according to the first embodiment will be described.
As shown in Figs. 2 and 3, the topsheet 2 has a skin-facing surface 2a and a non-skin-facing surface 2b.
As shown in Fig. 3, the topsheet 2 is a fiber layer including first fibers 31 and second fibers 32, and is positioned so as to face the wearer's skin when the diaper 1 is worn. The fibers are partially fused to each other by heat-sealed portions 25. In Fig. 3 and Fig. 5 described later, the first fibers 31 are typically shown by thick lines and the second fibers 32 are typically shown by thin lines, and the thickness of the lines in the figures does not necessarily indicate the thickness of the fibers. In Figs. 3 and 5, circular black dots indicate the heat-sealed portions 25 that have been heat-sealed.

The top sheet 2 is made of a sheet of fibrous material. This sheet is substantially inelastic. As the sheet, various nonwoven fabrics can be used, such as nonwoven fabrics manufactured by the carding method, spunbond nonwoven fabrics, meltblown nonwoven fabrics, spunlace nonwoven fabrics and needlepunch nonwoven fabrics, and meltblown nonwoven fabrics, spunlace nonwoven fabrics and needlepunch nonwoven fabrics.

The first fibers 31 used in the topsheet 2 contain a hydrophilic treatment agent and a functional agent. In detail, the first fibers 31 are coated with a surface treatment agent which is a mixture of a hydrophilic treatment agent and a functional agent.
The first fibers 31 and the second fibers 32 are heat-fusible. Furthermore, the raw first fibers 31 and the second fibers 32, i.e., the fibers 31, 32 not containing a hydrophilic treatment agent and a functional agent, are preferably hydrophobic and non-absorbent. If the raw fibers 31, 32 are hydrophobic and non-absorbent, the topsheet 2 is less likely to retain body fluids, making it easier to suppress liquid residue.
As the first fiber 31, it is preferable to use core-sheath fibers, side-by-side fibers, etc., and core-sheath fibers are particularly preferable. A representative first fiber is one in which the core component is made of PET (polyethylene terephthalate) and the sheath component is made of PE (polyethylene), and the core-sheath ratio is preferably 20/80 to 80/20 by mass. The fineness of the first fiber is preferably 1.5 dtex or more and 5.0 dtex or less. The core-sheath ratio indicates the mass ratio (core/sheath) of the resins constituting the core and the sheath, and is the ratio of core/sheath (former/latter) in one fiber having a core-sheath structure.
The hydrophilic treatment agent adjusts the hydrophilicity in order to control the permeability of the fiber surface to body fluids, and in particular, makes it possible to suppress the liquid repellency of the hydrophobic raw fiber. As the hydrophilic treatment agent, a known agent such as a hydrophilic surfactant can be used. In addition, a fiber being hydrophobic means that the contact angle with ion-exchanged water (hereinafter also simply referred to as "contact angle") is 90° or more, preferably 110° or more. In addition, the hydrophilic treatment agent reduces the hydrophobicity of the hydrophobic fiber, and it is sufficient if it can reduce the contact angle of the hydrophobic fiber, and it is preferable that the contact angle can be adjusted to 85° or less, more preferably 80° or less.
The functional agent contained in the present invention is capable of exerting a predetermined function on the wearer's skin. More specifically, the functional agent may be transferred from the top sheet 2 to the wearer's skin to exert a function, or at least a part of the functional agent may remain on the top sheet 2 or the absorbent article to exert a predetermined function and indirectly affect the wearer's skin. Examples of the former functional agent include skin care agents and cooling agents, and examples of the latter include antibacterial agents, odor absorbing or suppressing agents, fragrances, and combinations thereof. In this embodiment, an example in which a skin care agent is included as a preferred functional agent is given. By using a skin care agent, a skin care effect is exerted on the wearer's skin, and red spots and rashes during long-term use or after urination or defecation can be suppressed. Details of the hydrophilic treatment agent and the functional agent will be described later.

The second fibers 32 include a hydrophilic treatment agent. In detail, the second fibers 32 are coated with the hydrophilic treatment agent.
As the second fiber 32, a core-sheath fiber, a side-by-side fiber, or the like can be preferably used, and a core-sheath fiber is particularly preferable. A representative second fiber has a core component made of PET (polyethylene terephthalate) and a sheath component made of PE (polyethylene), and the core-sheath ratio is preferably 20/80 to 80/20 by mass.

As shown in FIG. 3, the skin-facing surface 2a of the topsheet 2 is configured with only the first fibers 31 arranged. The topsheet 2 is composed of a lower portion 27 including the first fibers 31 and the second fibers 32, and an upper portion 26 in which the ratio of the mass of the first fibers 31 to the total mass of the first fibers 31 and the second fibers 32 is greater than that of the lower portion 27. In the embodiment of FIG. 3, the upper portion 26, which is a first fiber region consisting of only the first fibers 31, and the lower portion 27, which is a mixed fiber region in which the first fibers 31 and the second fibers 32 are mixed and arranged across a plane perpendicular to the thickness direction of the sheet, are laminated.

The amount of functional agent contained in the second fibers 32 per unit area in the mixed fiber region (lower portion 27) is less than that of the first fibers 31. "Low functional agent content" includes cases where the second fibers 32 do not contain any functional agent. In this embodiment, an example is given where the second fibers 32 do not contain any functional agent. In addition, hereinafter, "high (or low) functional agent content per unit area" will simply be referred to as "high (or low) functional agent content."

The topsheet 2 is a nonwoven fabric with a small degree of freedom because the first fibers 31 and the second fibers 32 are fused at a plurality of heat-sealed portions 25 between the fibers, and the first fibers 31 and the second fibers 32 are easily distributed stably in the plane of the topsheet 2 in the lower portion 27. In addition, in the topsheet 2 of this embodiment, the fibers of the first fibers 31 are also fused at a plurality of heat-sealed portions 25 between the fibers of the first fibers 31 in the upper portion 26. As a result, the functional agent contained in the first fibers 31 is stably distributed over the entire surface and thickness direction of the topsheet 2, and a sufficient amount of the functional agent can be contained in the topsheet 2, and the functional agent effect can be well expressed. In addition, in the topsheet 2, the second fibers 32, which contain a relatively smaller amount of functional agent than the first fibers 31, are arranged over the entire surface, so that the effect of the functional agent on the liquid permeability due to the addition of the functional agent is suppressed, and the topsheet 2 can be provided with good liquid permeability that is almost uniformly secured over the surface. Furthermore, the functional agent tends to accumulate in the heat-sealed portions 25, but since the topsheet 2 is configured in the lower portion 27 to include the second fibers 32 that contain less functional agent than the first fibers 31, uneven distribution of the functional agent in the heat-sealed portions 25 is suppressed compared to when the topsheet 2 is configured only with the first fibers 31. In this embodiment, the second fibers 32 do not contain a functional agent, so uneven distribution of the functional agent is further suppressed. This allows the topsheet 2 to have approximately uniform liquid permeability within its plane.
In this way, by having a mixed fiber region in which the first fiber and the second fiber having different functional agent contents are arranged across a plane perpendicular to the thickness direction of the sheet, it is possible to obtain a top sheet 2 that can achieve both good liquid permeability and the expression of the functional agent effect.
In this embodiment, the second fibers do not contain a functional agent, but the second fibers may contain a smaller amount of functional agent than the first fibers, and the same effect can be obtained. From the viewpoint of better liquid permeability, it is more preferable that the second fibers 32 do not contain a functional agent.

When the functional agent of the present invention is one that reduces the hydrophilicity of the first fiber 31 or the second fiber 32 containing the hydrophilic treatment agent, in other words, one that increases the hydrophobicity, the top sheet 2 of this embodiment is preferable in terms of suppressing liquid residue because it contains fibers that maintain hydrophilicity. Note that "increasing hydrophobicity" means that when each fiber 31, 32 contains a hydrophilic treatment agent and the fiber surface has a certain hydrophilicity (for example, a contact angle with ion-exchanged water of 80° or less), the hydrophilicity is reduced by adding the functional agent, and the hydrophobicity is increased. In this case, the fiber in the hydrophobic state does not need to have a contact angle with water of 90° or more. Therefore, it is not necessary for the functional agent to be generally hydrophobic (a contact angle with water of 90° or more), but it is sufficient that the functional agent imparts low hydrophilicity in relation to the hydrophilicity of the fiber to which the functional agent is applied or the fiber containing the fiber treatment agent. Of course, the fiber containing the functional agent may be hydrophobic with a contact angle with water of 90° or more.

In the top sheet 2 of this embodiment, the skin-facing surface 2a is configured with only the first fibers 31 arranged. In other words, the first fiber region (corresponding to the upper portion 26) having the first fibers 31 containing the functional agent is located on the skin-facing side of the top sheet 2 relative to the mixed fiber region (lower portion 27) having the second fibers 32 that do not contain the functional agent. This allows the functional agent to be easily transferred to the wearer, optimizing the effect of the functional agent on the wearer.

In the top sheet 2 of this embodiment, when the sheet is divided in half in the thickness direction, the second fibers 32 are more present on the non-skin facing surface 2b side than on the skin facing surface 2a side. The amount of functional agent contained in the second fibers 32 is less than that contained in the first fibers 31, and the second fibers 32 tend to have higher liquid permeability than the first fibers 31. Therefore, by configuring the top sheet 2 so that there are more second fibers 32 on the non-skin facing surface 2b side, which is located closer to the absorbent body 4, liquid from the wearer is easily drawn from the skin facing surface 21a side to the non-skin facing surface 21b side, and the amount of liquid remaining on the surface of the top sheet 2 can be reduced.

It is preferable that the first fibers 31 and the second fibers 32 have a core-sheath structure, the second fibers 32 have a thinner sheath than the first fibers 31, and have a higher core-sheath ratio.
Since the second fibers 32 have a thinner sheath than the first fibers 31, the number of heat-sealed portions between the fibers is smaller when the nonwoven fabric is formed, and the fusion area can be reduced. That is, by using at least two types of fibers with different core-sheath ratios, the fusion area of the fibers in the topsheet 2 can be reduced compared to the case where only the first fibers with a lower core-sheath ratio are used. Since the functional agent is likely to accumulate in the heat-sealed portions between the fibers, the fusion area is reduced to suppress uneven distribution of the functional agent in the heat-sealed portions. As a result, the prevention of uneven distribution of the functional agent in the heat-sealed portions 25 by forming the topsheet 2 including the second fibers 32 as described above is further suppressed, and the topsheet 2 can have more uniform liquid permeability in the plane.
Furthermore, since the fused area is small, the second fibers 32 are easy to move, and the topsheet 2 has low friction with the skin and is gentle on the skin.
Furthermore, thin-sheath fibers with a higher core-sheath ratio such as the second fibers 32 have greater friction between fibers than fibers with a lower core-sheath ratio such as the first fibers 31, but the functional agent content of the second fibers 32 is less than that of the first fibers 31, so peeling of the functional agent from the surface of the second fibers is suppressed. On the other hand, the first fibers 31, which have lower friction between the fibers, contain a larger amount of functional agent, so the functional agent can be efficiently retained in the first fibers 31. This makes it possible to obtain a topsheet 2 in which the effect of the functional agent can be efficiently expressed.
In this way, by using a first fiber and a second fiber having different core-sheath ratios and different amounts of functional agent, it is possible to achieve both good liquid permeability and good expression of the functional agent effect, and to produce a surface sheet 2 that is pleasant to the touch.

The fineness of the first fibers 31 and the second fibers 32 may be the same or different.
For example, when the fineness of the first fibers 31 is smaller than that of the second fibers 32, that is, when the first fibers 31 are finer than the second fibers 32, the top sheet can be made smoother and more gentle on the skin.
Furthermore, when the fineness of the second fibers 32 is smaller than that of the first fibers 31, i.e., when the second fibers 32 are thinner than the first fibers 31, the gaps between the fibers become narrower, and this narrow gap makes it easier for liquid to be drawn in, thereby reducing the amount of liquid remaining on the top sheet 2.

When the first fiber 31 and the second fiber 32 have different core-sheath ratios or different finenesses, the difference in core-sheath ratio or fineness can be confirmed by observing the fiber cross-sections with an electron microscope (SEM) or optical microscope.

Second Embodiment
The topsheet 20 according to the second embodiment will be described. The same components as those in the first embodiment are designated by the same reference numerals, and the description thereof may be omitted.
As shown in Fig. 4, the top sheet 20 is a sheet having an uneven skin-facing surface and a substantially flat non-skin-facing surface, and is applicable to absorbent articles. The top sheet 20 can be used in place of the top sheet 2 in the above-mentioned diaper 1, which is an example of an absorbent article.

4 and 5 , the topsheet 20 is formed by laminating a first sheet 21 and a second sheet 22. In the diaper 1, the first sheet 21 is located on the skin-facing side of the topsheet 2, and the second sheet 22 is located on the non-skin-facing side of the topsheet 2.
The first sheet 21 is composed of a concave-convex fiber layer having a plurality of convex portions 23, and is positioned so as to face the wearer's skin when the diaper 1 is worn. The concave-convex fiber layer is a nonwoven fabric layer. The convex portions 23 protrude in a dome shape toward the wearer's skin.
The second sheet 22 is made of a nonwoven fabric and has a flat shape.
The first sheet 21 and the second sheet 22 are partially joined and fixed by heat fusion at a number of joints 24. The joints 24 form recesses in the topsheet 2 having projections and recesses. The non-jointed portions of the first sheet 21 other than the joints 24 form projections 23. The interiors of the projections 23 are hollow.
The joints 24 forming the convex portions 23 and the concave portions are arranged alternately in rows in one direction (the vertical direction X in FIG. 3), and such rows are formed in multiple rows in a direction perpendicular to the one direction (the horizontal direction Y in FIG. 3).
The first sheet 21 has a skin-facing surface 21a and a non-skin-facing surface 21b opposite to the skin-facing surface 21a.

The first sheet 21 and the second sheet 22 each consist of a sheet-like material made of a fibrous material. This sheet-like material is substantially non-stretchable. As the sheet-like material, various nonwoven fabrics can be used, such as nonwoven fabrics manufactured by the carding method, spunbond nonwoven fabrics, meltblown nonwoven fabrics, spunlace nonwoven fabrics and needlepunch nonwoven fabrics, and meltblown nonwoven fabrics, spunlace nonwoven fabrics and needlepunch nonwoven fabrics.

5, the first sheet 21 is composed of a fiber layer including first fibers 31 and second fibers 32, similar to the topsheet 2 of the first embodiment, and the fibers are partially fused to each other by a heat-sealing portion 25. The skin-facing surface 21a of the first sheet 21 is also composed of only the first fibers 31. The first sheet 21 has a laminated configuration of an upper portion 26 which is a first fiber region consisting of only the first fibers 31, and a lower portion 27 which is a mixed fiber region in which the first fibers 31 and the second fibers 32 are mixed and arranged over a surface perpendicular to the thickness direction of the sheet.
The first sheet 21 has the same basic structure as the topsheet 2 of the first embodiment, except that the entire sheet is unevenly shaped, and has the same effects. Since the first sheet 21 of the topsheet 20 of this embodiment is unevenly shaped, it can be made into a topsheet 20 that has cushioning properties and a soft feel.

In the topsheet 20 of this embodiment, the second sheet 22 is preferably more hydrophilic than the first sheet 21. This makes it easier for liquid from the wearer that is absorbed by the first sheet 21 to be drawn in by the second sheet 22, and easier for the liquid to be rapidly absorbed into the absorbent body 4.
Therefore, the amount of liquid remaining on the top sheet 20 is reduced, and it is possible to suppress the liquid absorbed in the top sheet 20 returning to the skin due to pressure from the wearer when in a sitting or other position, i.e., so-called liquid backflow. By suppressing liquid backflow, excessive elution of the functional agent into the liquid is suppressed, and the effect of the functional agent can be maintained for a long period of time. Furthermore, by suppressing liquid backflow, hydration of the skin is suppressed, and the occurrence of skin troubles such as redness of the skin inside the diaper 1 is suppressed.
The degree of hydrophilicity of the topsheet 20 can be indicated by a contact angle, similar to the hydrophilicity of the first and second fibers described above, and the contact angle can be measured by a contact angle measuring method described below. For example, it is preferable that the contact angle of the skin-facing surface 21a of the first sheet 21 is about 75° to 90°, the contact angle of the non-skin-facing surface 21b of the first sheet 21 is about 72° to 85°, and the contact angle of the second sheet 22 is about 70° to 83° so as to be smaller than these contact angles.

[Surface treatment agent]
As described above, the first fibers are coated with a surface treatment agent containing a hydrophilic treatment agent and a functional agent. The second fibers 32 are coated with a hydrophilic treatment material. Examples of the hydrophilic treatment agent and the functional agent to be used are shown below.

(Hydrophilic Treatment Agent)
The hydrophilic treatment agent adjusts the hydrophilicity of the fiber surface, and any known agent can be used. For example, a hydrophilic surfactant that makes the fiber surface hydrophilic can be used as the hydrophilic treatment agent.
The hydrophilic treatment agent is preferably a solid lipid-like active agent mass at 36° C., whereas the hydrophobic component skin care agent and polyhydric alcohol, which are functional agents described below, are preferably liquid at 36° C. By including a hydrophilic treatment agent in the hydrophobic raw first and second fibers, a liquid hydrophobic component skin care agent or a hydrophilic component skin care agent (e.g., peach leaf extract) can be stably attached to the fibers. In addition, if a polyhydric alcohol that is liquid at 36° C. is included, the hydrophobic skin care agent and the hydrophilic skin care agent can be easily mixed and can be easily stably attached to the first and second fibers in a mixed state, which is preferable.

(Functional Agent)
Examples of functional agents include skin care agents, cooling agents, antibacterial agents, odor absorbing or suppressing agents, fragrances, etc., or combinations thereof. The functional agent is typically a skin care agent, and the following description will be given taking a skin care agent as an example of the functional agent.
A "skin care agent" is something that gives a skin care effect to the wearer. "Skin care effect" refers to the general efficacy of preventing skin rashes, moisturizing, reducing inflammation, preventing scratches, and providing antibacterial and antibacterial properties to normalize the condition of the skin.
The skin care agent may be a hydrophobic skin care agent as a hydrophobic component, a hydrophilic skin care agent as a hydrophilic component, a skin care agent containing a polyhydric alcohol, etc. One or more kinds of skin care agents may be used.

A hydrophobic skin care agent is a composition or compound that is not water-soluble or water-dispersible or has extremely low solubility, and has efficacy for the wearer's skin, such as protection, healing, etc. For example, when 10 g of a skin care agent is immersed in 100 mL of ion-exchanged water (liquid temperature 25° C.) and left for 24 hours, the skin care agent has a solubility and dispersibility of less than 10% by mass, preferably a solubility and dispersibility of 1% by mass or less, and particularly preferably a skin care agent that is not completely dissolved or dispersed.
Examples of hydrophobic skin care agents include fatty acids with a carbon chain length of 12 to 28 or ester compounds of such fatty acids and glycerin, wax, petrolatum, etc., and in particular, it is preferable to contain unsaturated fatty acids with a carbon chain length of 12 to 28 or glycerin ester compounds of such unsaturated fatty acids. The glycerin ester is a monoester, diester, or triester of glycerin and the above-mentioned unsaturated fatty acid, and in particular, a triester is preferable. As agents containing fatty acids or fatty acid compounds, natural product extracts such as argan oil and shea butter can be preferably used. In particular, argan oil, which is a hydrophobic vegetable oil containing unsaturated fatty acids, maintains the balance between moisture and oil in the skin, prevents dryness, and functions as a skin care agent. In addition, argan oil contains a large amount of unsaturated fatty acids such as oleic acid and linoleic acid, has a strong ability to remove active oxygen, and can reduce skin damage caused by, for example, sunburn.

As the polyhydric alcohol skin care agent, an alcohol having 2 to 4 carbon atoms can be used. A typical example is 1,3-butylene glycol. The use of 1,3-butylene glycol improves moisturizing effect and lubricity. The improved lubricity can reduce friction between the skin and the nonwoven fabric, suppressing damage to the skin. 1,3-butylene glycol is a moisturizing liquid water-soluble base component that has a smooth feel and is less sticky when used, keeps the skin moist, and functions as a skin care agent.
In addition, 1,3-butylene glycol is used as a solvent in addition to being used as a moisturizing agent. For example, 1,3-butylene glycol can be used as an extraction solvent for peach leaf extract, which will be described later. 1,3-butylene glycol promotes compatibility of each component. When both a skin care agent containing hydrophilic components and a skin care agent containing hydrophobic components are used as functional agents, the hydrophilic components and the hydrophobic components of the skin care agents can be uniformly dispersed by using a polyhydric alcohol. In a nonwoven fabric manufactured using fibers coated with such a uniformly dispersed surface treatment agent, the skin care agent containing hydrophobic components, such as argan oil, is prevented from phase separation and peeling off.
Although 1,3-butylene glycol is used as an example here, any polyhydric alcohol having 2 to 4 carbon atoms will have the same effect, and for example, propylene glycol may be used as an extraction solvent for hydrophilic extracts.

On the other hand, a hydrophilic skin care agent is a skin care ingredient that is water-soluble or water-dispersible, and is preferably capable of suppressing the occurrence of rash or inflammation, and, if rash or inflammation occurs, suppressing the progression of the rash or inflammation or alleviating the rash or inflammation. For example, if 10 g of a skin care agent is immersed in 100 mL of ionized water (liquid temperature 25°C) and left for 24 hours, and 10% by mass or more of the skin care agent is dissolved or dispersed, the skin care agent is said to be water-soluble or water-dispersible. The amount of the "dissolved or dispersed" described above is preferably 25% by mass or more, more preferably 50% by mass or more.
As the hydrophilic skin care agent, natural extracts such as peach leaf extract and witch hazel extract, polyhydric alcohols having 2 to 4 carbon atoms, polyethylene glycol, hydrophilic compounds having skin care functions, etc. can be used.
Among these, peach leaf extract (hydrophilic extract), which is a plant extract, is preferred because it has antibacterial and anti-inflammatory effects. The peach leaf extract, which is a hydrophilic component, dissolves in the liquid supplied to the top sheet 2 and transfers to the skin, thereby providing a skin care effect.

It is preferable to use natural product extract components as components contained in the surface treatment agent. For example, the skin of infants who wear the diaper 1 is thinner and has a poorer barrier function than that of adults, so the use of natural product extract components makes it less likely for allergic reactions to occur. In addition, the use of natural product extract components makes it less likely for skin problems such as redness to occur on the skin inside the diaper to occur. The use of natural product extract components also gives consumers a sense of security and a refreshing image.

For example, a mixture of a hydrophilic treatment agent, a hydrophilic skin care agent, a hydrophobic skin care agent, and a polyhydric alcohol can be used as the surface treatment agent applied to the first fiber. The hydrophilic skin care agent, the hydrophobic skin care agent, and the polyhydric alcohol are functional agents. By including a polyhydric alcohol in the surface treatment agent, the compatibility of the skin care agent of the hydrophilic component and the skin care agent of the hydrophobic component is promoted, and the use of the hydrophilic treatment agent makes it easier to attach the skin care agent to the fiber. A nonwoven fabric manufactured using fibers containing such a surface treatment agent has the hydrophilic skin care agent and the hydrophobic skin care agent present in the thickness direction and in the plane perpendicular to the thickness direction.

Specific examples of the functional agent used include peach leaf extract as a hydrophilic skin care agent, argan oil as a hydrophobic skin care agent, and 1,3-butylene glycol as a polyhydric alcohol.
As the fiber treatment composition containing the hydrophilic treatment agent, the following composition may be used.
Alkyl phosphate potassium salt (Kao Corporation's Gripper 4131 neutralized with potassium hydroxide) 30% by mass
Alkyl (stearyl) betaine (Amphitol 86B, manufactured by Kao Corporation) 15% by mass
Polyoxyethylene (number of moles added: 2) stearylamide (Amizol SDE, manufactured by Kawaken Fine Chemicals) 30% by mass
Polyoxyethylene, polyoxypropylene modified silicone (X-22-4515 manufactured by Shin-Etsu Chemical Co., Ltd., Griffin method HLB: 5) 25% by mass

[Amount of hydrophilic treatment agent and functional agent attached]
The amounts of the hydrophilic treatment agent and the functional agent attached to the first fibers 31 are as follows.
From the viewpoint of imparting a desired hydrophilicity to the fibers, the amount of the hydrophilic treatment agent is preferably 0.1% by mass or more and 150% by mass or less based on the fiber mass.
From the viewpoint of further enhancing the effects of the present invention, the functional agent is preferably present in an amount of 1×10 ⁻⁴ mass % or more and 1 mass % or less relative to the mass of the fiber.
When a hydrophilic component, a hydrophobic component, and a polyhydric alcohol are used as functional agents, the hydrophilic component is preferably 0.1% by mass to 150% by mass relative to the fiber mass in order to further enhance the effects of the present invention, and is preferably 0.2% by mass to 50% by mass in order to balance the feeling of use. The hydrophobic component is preferably 1×10 ⁻⁴ % by mass to 0.5% by mass, and more preferably 2×10 ⁻⁴ % by mass to 0.1% by mass relative to the fiber mass, which makes it easier to balance the effects of the present invention and the feeling of use. The polyhydric alcohol is preferably 3×10 ⁻⁴ % by mass or more, and more preferably 8×10 ⁻⁴ % by mass or more relative to the fiber mass in order to achieve a high level of the effects of the present invention, but is preferably 1% by mass or less, and more preferably 0.5% by mass or less, in order to balance the feeling of use.

The amounts of the hydrophilic treatment agent and the functional agent attached to the second fibers 32 are as follows.
From the viewpoint of imparting a desired hydrophilicity to the fibers, the amount of the hydrophilic treatment agent is preferably 0.1% by mass or more and 150% by mass or less based on the fiber mass.
In order to further enhance the effects of the present invention, the amount of functional agent attached to the second fibers 32 is less than the amount of functional agent attached to the first fibers 31, and is preferably 10 mass% or less of the functional agent contained in the first fibers 31, and it is more preferable that the second fibers 32 do not contain any functional agent.

When a hydrophilic component, a hydrophobic component, and a polyhydric alcohol are used as functional agents, the combined mass of the hydrophilic treatment agent and the hydrophilic component is preferably 50% by mass or more and less than 100% by mass, particularly 70% by mass or more and 98% by mass, based on the total mass of the hydrophilic treatment agent, the hydrophilic component, the hydrophobic component, and the polyhydric alcohol, from the viewpoint of liquid spreading. Liquid spreading refers to liquid spreading between the fibers that constitute the nonwoven fabric. The hydrophobic component is preferably 0.05% by mass or more and 20% by mass or less based on the total mass from the viewpoint of liquid permeability and usability, and from the same viewpoint, the upper limit is preferably 5% by mass or less. The polyhydric alcohol is more preferably 0.2% by mass or more and 96% by mass or less based on the total amount, because it is easier to mix the hydrophilic component and the hydrophobic component and the usability is good, and from the viewpoint of making the mixed state more uniform, it is more preferable that the polyhydric alcohol is 0.1% by mass or more and 98% by mass.

[Composition ratio of first fiber and second fiber]
From the viewpoint of achieving good liquid permeability and enabling functional agents (agents having skin care effects) to easily function on the wearer's skin, the weight ratio of the first fibers 31 to the second fibers 32 in the lower portion 27 of each of the above-mentioned surface sheets 2 and 20, in which the first fibers 31 and the second fibers 32 are mixed, is preferably 95:5 or more and 50:50 or less, and more preferably 80:20 or more and 55:45 or less.
From the same viewpoint, the compounding ratio of the first fibers 31 to the second fibers 32 in each of the topsheet 2 and the first sheet 21 is preferably 98:2 or more and 60:40 or less in weight ratio.

[Manufacturing method of top sheet]
An example of a method for manufacturing the topsheet 2 according to the first embodiment will be described.
The upper web is manufactured by forming a nonwoven fabric from a first fiber coated with a surface treatment agent by an air-through process. The lower web is manufactured by mixing the first fiber coated with a surface treatment agent and the second fiber coated with a hydrophilic treatment agent, and forming the nonwoven fabric from the air-through process. The upper web and the lower web are then superimposed to form a laminated web, which is then formed into a nonwoven fabric by air-through process, to manufacture the topsheet 2.

An example of a method for manufacturing the topsheet 20 according to the second embodiment will be described.
The multi-layered topsheet 20 having the irregularities can be manufactured by a conventional method. Typically, the topsheet 20 can be manufactured by forming a first sheet 21 from a laminated web, such as the above-mentioned topsheet 2, by laminating an upper web and a lower web, and forming the laminated web into a nonwoven fabric through air-through, and then laminating and bonding the first sheet 21 having the irregularities and a flat second sheet 22 in accordance with JP-A-2004-174234.

[Supplementary explanation 1]
(Method for measuring the amount of functional agents (skin care agents) in fibers)
When the fibers have different fineness or fiber length, the fibers are separated from the top sheet and collected according to their fineness or fiber length. The fiber length of the collected fibers is measured. Next, the collected fibers (preferably 2 g) are placed in a specified container with a small opening at the bottom. Then, the fibers are held down with a lid, the fibers are pushed into the bottom of the container, and the lid is removed. 10 cc of ether as an extracting solvent for hydrophobic skin care agents, or 10 cc of a mixed solution of ethanol/methanol (volume ratio 1:1) as an extracting solvent mainly for water-soluble skin care agents is added thereto, and the mixture is left to stand for 6 hours. Then, the lid is placed again, and the fibers containing the solution are pressed firmly to squeeze out the ether or ethanol/methanol component, which is the liquid contained in the fibers, and the squeezed liquid is placed in a weighing dish. Then, the weighing dish is heated to remove the solvent, and the weight of this weighing dish is measured, and the amount of the skin care agent is measured from the difference with the weight of the original weighing dish before the liquid was added. The amount of the skin care agent in the three samples is measured, and the average of the amounts is taken as the amount of the attached skin care agent. The skin care amount per unit length is calculated from the obtained skin care amount and the fiber length (total value), and is taken as the mass per fiber. Note that, since hydrophobic skin care agents may be extracted into the ethanol/methanol extraction solvent, if all the skin care agents contained in each fiber are extracted with the ethanol/methanol extraction solvent, extraction with ether is not necessary. Note that, if all the skin care agents can be extracted with the ethanol/methanol mixed solvent, it can be said that the skin care agent has a high affinity with the wearer's skin surface due to its polarity, and it is preferable because good skin care effects can be expected.

(Method for measuring the amount of functional agent (skin care agent) per unit area)
A method for measuring the amount per unit area of the skin care agent as a functional agent contained in the upper portion 26 and the lower portion 27 will be described.
After separating the first sheet and the second sheet from the top sheet 2, the first sheet was further separated into an upper layer and a lower layer, and samples of 50 mm in the vertical direction × 50 mm in the horizontal direction were cut out from each of the upper layer and lower layer, and the area of the samples was calculated. The planar area of the sample cut out from the almost flat lower layer was 2500 ^mm2 . In calculating the planar area of the upper layer having a plurality of convex portions, the cross section is observed at a magnification (for example, 150 to 500 times magnification) using a scanning electron microscope (for example, JCM-5100 (product name) manufactured by JEOL Ltd.), and the unevenness dimensions are measured from the cross-sectional image, and the area of the uneven surface of the upper layer is calculated based on this.
The sample is placed in a container with a small opening at the bottom. Then, the fiber is held down with a lid, the fiber is pushed to the bottom of the container, and the lid is removed. 10 cc of ether or 10 cc of a mixed solution of ethanol/methanol (volume ratio 1:1) is added thereto, and the mixture is left to stand for 10 minutes. Ether is a solvent mainly for the purpose of extracting oily components, and the mixed solvent of ethanol/methanol is a solvent for the purpose of extracting hydrophilic components and polyhydric alcohols. Then, the lid is placed again, and the fiber containing the solution is pressed strongly to squeeze out the liquid (ether or ethanol/methanol components) contained in the fiber, and the squeezed liquid is placed in a weighing dish. Then, the weighing dish is heated to remove the solvent, and the weight of this weighing dish is measured, and the amount of the skin care agent is measured from the difference with the weight of the original weighing dish before the liquid was added. The amount of the skin care agent in the three samples is measured, and the average is taken as the amount of the attached skin care agent.
The amount of the skin care agent per unit area is calculated from the calculated area and the applied amount of the skin care agent.
In addition, since oily components may be extracted into the ethanol/methanol extraction solvent, if all the oily components contained in each fiber are extracted with the ethanol/methanol extraction solvent, extraction with ether is not necessary. If all the skin care agents are extracted with ethanol/methanol, it means that each component has polarity, but if the hydrophilic component and the oily component are skin care agents, it can be said to be advantageous in terms of affinity with the wearer's skin surface, and is preferable.

[Structural description of surface sheet 2]
Third Embodiment
Next, a topsheet used in a disposable diaper according to the third embodiment will be described. For matters not specifically described, the descriptions of the first and second embodiments apply. In this embodiment, the first fiber contains a hydrophilic treatment agent and a functional agent, and the second fiber contains a hydrophilic treatment agent. The first fiber and the second fiber are fused to each other by a heat-sealed portion, which is common to the first and second embodiments, but the second fiber has a smaller water contact angle than the first fiber. That is, the first fiber is hydrophobic to the second fiber, and the second fiber is hydrophilic to the first fiber.

As in the first and second embodiments, the relationship between the water contact angle of the first fiber and the second fiber, combined with the fusion of the first fiber and the second fiber, suppresses the influence on the liquid permeability, and the top sheet 2 and the first sheet 21 can be provided with almost uniform and good liquid permeability throughout the surface. In addition, the presence of the second fiber, which is more hydrophilic than the first fiber, ensures the attraction of body fluids excreted in the top sheet, making it easy to suppress liquid remaining on the top sheet. Furthermore, when the top sheet and the first sheet have a structure having an upper portion 26 and a lower portion 27, the liquid permeability from the upper portion 26 to the lower portion 27 is good, and liquid remaining in the upper portion 26 is suppressed, making it easy to obtain a smooth feel. In particular, in this embodiment, since the second fiber 32 does not contain a functional agent, uneven distribution of the functional agent in the fusion portion is further suppressed, and the top sheet 2 and the first sheet 21 can be provided with almost uniform liquid permeability throughout the surface.
In this way, by having a mixed fiber region in which the first fiber and the second fiber, which have different hydrophilicity, are arranged across a plane perpendicular to the thickness direction of the sheet, it is possible to obtain a top sheet 2 and a first sheet 21 that can achieve both good liquid permeability and the expression of the functional agent effect.

In this way, in order to make the relationship between the contact angles of the first fiber and the second fiber with water like this embodiment, for example, a method of making the content of a highly hydrophobic agent contained in the first fiber and the second fiber less in the second fiber than in the first fiber, or a method of making the amount of hydrophilic components contained in the first fiber less than the amount of hydrophilic components contained in the second fiber, etc. can be mentioned. However, as explained in the first and second embodiments, a method of making the content of the functional agent different between the first fiber and the second fiber can be said to be preferable because it is easier to effectively obtain the action of the functional agent (especially an agent having a skin care effect) on the wearer's skin and it is possible to achieve good liquid permeability at the same time.

Fourth Embodiment
Next, the top sheet used in the disposable diaper of the fourth embodiment will be described. For matters not specifically described, the description of the first and second embodiments applies. In this embodiment, the first fiber contains a hydrophilic treatment agent and a functional agent, and the second fiber contains a hydrophilic treatment agent. The first fiber and the second fiber are fused by a heat-sealing portion, which is common to the first and second embodiments, but the second fiber has a larger water contact angle than the first fiber. That is, the first fiber is hydrophilic to the second fiber, and the second fiber is hydrophobic to the first fiber. By including the second fiber that is more hydrophobic than the first fiber, bodily fluids are less likely to be retained in the first fiber, and the transfer of bodily fluids to the absorbent body can be smooth. This is particularly effective when the amount of the first fiber is greater than the amount of the second fiber.

[Supplementary explanation 2]
The presence of first and second fibers having different water contact angles in the topsheet can be confirmed by the following method. Specifically, multiple fibers are taken from the topsheet to be measured, and the contact angle of each fiber is measured. The contact angle is measured by the following contact angle measurement method.
In addition, when the first fiber and the second fiber have different core-sheath ratios or different finenesses, the difference in core-sheath ratios or finenesses can be confirmed by observing the fiber cross sections with an electron microscope (SEM) or an optical microscope. Therefore, in such cases, by taking out a plurality of fibers having different core-sheath ratios or different finenesses and measuring the contact angles thereof, it can be confirmed that there are first fibers and second fibers having different water contact angles.

(Method of measuring contact angle)
The contact angle is an index showing the degree of hydrophobicity or hydrophilicity of the fibers and the components such as the first and second sheets, and is measured by the measurement method described below. The smaller the contact angle value, the higher the hydrophilicity of the fibers and components can be determined. In general, the contact angle θ of fibers and components classified as hydrophilic is 90° or less (preferably 85° or less; the smaller the contact angle, the higher the hydrophilicity), and the contact angle θ of fibers classified as hydrophobic is more than 90° (preferably more than 90° to 140°).
As a measuring device, an automatic contact angle meter MCA-J manufactured by Kyowa Interface Science Co., Ltd. is used. Distilled water is used for the contact angle measurement. The amount of liquid discharged from the inkjet type water droplet discharge part (CTC-25 pulse injector with a discharge part hole diameter of 25 μm manufactured by Cluster Technology Co., Ltd.) is set to 20 picoliters, and the water droplets are dropped directly above the fiber. The state of the drop is recorded by a high-speed recording device connected to a horizontally installed camera. From the viewpoint of later image analysis, the recording device is preferably a personal computer with a built-in high-speed capture device. In this measurement, an image is recorded every 17 msec. In the recorded video, the first image where the water droplets land on the fiber is subjected to image analysis using the attached software FAMAS (software version 2.62, analysis method is droplet method, analysis method is θ/2 method, image processing algorithm is non-reflective, image processing image mode is frame, threshold level is 200, curvature correction is not performed), and the angle between the surface of the water droplet that touches the air and the fiber is calculated, which is the contact angle. The measurement sample (fibers obtained by removing from the topsheet) is prepared by cutting the fibers located in the measurement area of the topsheet at a fiber length of 1 mm from the outermost layer, placing the fibers on the sample stage of the contact angle meter and maintaining it horizontally, and measuring the contact angle at two different positions for each fiber. At the measurement area, the contact angles of N=5 fibers are measured to one decimal place, and the average value (rounded off to the first decimal place) of the measured values at a total of 10 positions is defined as the contact angle at the measurement area.
In measuring the contact angle of one sheet in a top sheet of a laminated structure having a first sheet and a second sheet, after separating the first sheet from the second sheet, the skin-facing surface and the non-skin-facing surface of the first sheet are taken as the measurement target sites, and the fibers located in the outermost layer are taken out and measured. The measurement results are the contact angles of the skin-facing surface and the non-skin-facing surface of the first sheet. The measurement results indicate the degree of hydrophobicity and hydrophilicity of the first sheet.
On the other hand, in the measurement of the contact angle of the second sheet, the surface of the second sheet facing the skin is used as the measurement target, and the fibers located in the outermost layer are taken out and measured. The measurement result is the contact angle of the second sheet. The measurement result indicates the degree of hydrophobicity and hydrophilicity of the second sheet.

<Other configuration examples>
Although the embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment, and it goes without saying that various modifications can be made without departing from the spirit of the present invention.
For example, in the above embodiment, a disposable diaper is shown as an example of an absorbent article, but the absorbent article is not limited thereto. The absorbent article of the present invention may be a urine pad, a panty liner, a sanitary napkin, etc. Absorbent articles are generally configured to have a liquid-permeable top sheet, a liquid-impermeable back sheet, and a liquid-retentive absorbent interposed between the two sheets.

＜1＞
An absorbent article comprising an absorbent body and a top sheet disposed on a skin-facing side of the absorbent body,
The top sheet includes a fiber layer positioned so as to face the skin of a wearer and having a mixed fiber region in which first fibers and second fibers are arranged across a surface perpendicular to a thickness direction, the first fibers and the second fibers being heat-fusible,
The first fiber contains a hydrophilic treatment agent and a functional agent capable of imparting a predetermined function to the skin of a wearer,
the second fiber contains a hydrophilic treatment agent;
The second fibers in the mixed fiber region contain a smaller amount of functional agent by mass than the first fibers,
An absorbent article, wherein the first fibers and the second fibers are fused together by a heat-sealed portion.
＜2＞
An absorbent article comprising an absorbent body and a top sheet disposed on a skin-facing side of the absorbent body,
The top sheet includes a fiber layer positioned so as to face the skin of a wearer and having a mixed fiber region in which first fibers and second fibers are arranged across a surface perpendicular to a thickness direction, the first fibers and the second fibers being heat-fusible,
The first fiber contains a hydrophilic treatment agent and a functional agent capable of imparting a predetermined function to the skin of a wearer,
the second fiber contains a hydrophilic treatment agent;
The second fibers have a smaller water contact angle than the first fibers,
An absorbent article, wherein the first fibers and the second fibers are fused together by a heat-sealed portion.
＜3＞
An absorbent article comprising an absorbent body and a top sheet disposed on a skin-facing side of the absorbent body,
The top sheet includes a fiber layer positioned so as to face the skin of a wearer and having a mixed fiber region in which first fibers and second fibers are arranged across a surface perpendicular to a thickness direction, the first fibers and the second fibers being heat-fusible,
The first fiber contains a hydrophilic treatment agent and a functional agent capable of imparting a predetermined function to the skin of a wearer,
the second fiber contains a hydrophilic treatment agent;
The second fibers have a larger water contact angle than the first fibers,
An absorbent article, wherein the first fibers and the second fibers are fused together by a heat-sealed portion.
＜4＞
The absorbent article according to any one of <1> to <3>, wherein, when the fiber layer is divided into two equal parts in the thickness direction, the second fibers are present in greater amounts on the non-skin-facing side than on the skin-facing side.
＜5＞
The absorbent article according to any one of <1> to <4>, wherein the skin-facing surface of the fiber layer is composed only of the first fibers.
＜6＞
The absorbent article according to any one of <1> to <5>, wherein the first fibers and the second fibers are core-sheath structure fibers having different core/sheath ratios.
＜７＞
The absorbent article according to <6>, wherein the core/sheath ratio of the second fibers is higher than the core/sheath ratio of the first fibers.
＜8＞
The absorbent article according to any one of <1> to <7>, wherein the fineness of the first fibers is greater than the fineness of the second fibers.
＜9＞
The absorbent article according to any one of <1> to <7>, wherein the fineness of the first fibers is smaller than the fineness of the second fibers.
＜10＞
The absorbent article described in any one of <1> to <9>, wherein the top sheet comprises a first sheet made of the fiber layer, and a second sheet arranged between the first sheet and the absorbent body and having a higher hydrophilicity than the first sheet.
<11>
The absorbent article described in <10>, wherein the contact angle of the skin-facing surface of the first sheet is 75° or more and 90° or less, the contact angle of the non-skin-facing surface of the first sheet is 72° or more and 85° or less, and the contact angle of the second sheet is 70° or more and 83° or less so as to be smaller than these contact angles.
＜12＞
The absorbent article according to any one of <1> to <11>, wherein the functional agent is a skin care agent.
＜13＞
The absorbent article according to <12>, wherein the skin care agent includes a hydrophilic skin care agent and a hydrophobic skin care agent.
＜14＞
The absorbent article according to <13>, wherein the skin care agent further contains a polyhydric alcohol having 2 to 4 carbon atoms.
＜15＞
The absorbent article according to any one of <12> to <14>, wherein the skin care agent includes, as a hydrophobic skin care agent, one or more selected from a fatty acid having a carbon chain length of 12 to 28 or an ester compound of the fatty acid and glycerin, a wax, and petrolatum.
＜16＞
The absorbent article according to <15>, wherein the hydrophobic skin care agent contains an unsaturated fatty acid having a carbon chain length of 12 to 28 or a glycerin ester compound of the unsaturated fatty acid.
＜１７＞
The absorbent article according to <16>, wherein the hydrophobic skin care agent includes argan oil.
＜18＞
The absorbent article according to any one of <12> to <17>, wherein all of the skin care agents are extractable with a mixed solvent of ethanol/methanol (volume ratio 1:1).
＜19＞
The absorbent article according to any one of <1> to <18>, wherein the hydrophilic treatment agent is a hydrophilic surfactant.
＜20＞
The absorbent article according to any one of <1> to <19>, wherein the contact angle of the raw first and second fibers with ion-exchanged water is 90° or more, preferably 110° or more.
＜21＞
The absorbent article according to any one of <1> to <20>, wherein the contact angle of the first and second fibers containing the hydrophilic treatment agent is 85° or less, more preferably 80° or less.
＜22＞
The absorbent article according to any one of <1> to <21>, wherein the blending ratio of the first fibers 31 and the second fibers 32 in the mixed fiber region of the top sheet is preferably 95:5 or more and 50:50 or less, more preferably 80:20 or more and 55:45 or less, by weight.
＜23＞
The absorbent article according to any one of <1> to <22>, wherein a blending ratio of the first fibers 31 to the second fibers 32 in the fiber layer is 98:2 or more and 60:40 or less in weight ratio.

1... Disposable diapers (absorbent articles)
2... Surface sheet (fiber layer)
4: absorbent body 4a: skin-facing surface 20: top sheet 21: first sheet (fiber layer)
25: heat-sealed portion 27: lower portion (mixed fiber region)
31...first fiber 32...second fiber

Claims (7)

An absorbent article comprising an absorbent body and a top sheet disposed on a skin-facing side of the absorbent body,
the top sheet includes a fiber layer having a mixed fiber region in which a first fiber and a second fiber are arranged across a plane perpendicular to a thickness direction, the fiber layer being positioned so as to face the skin of a wearer;
The first fibers and the second fibers are each heat fusible,
The first fiber contains a hydrophilic treatment agent and a functional agent capable of imparting a predetermined function to the skin of a wearer,
the second fiber contains a hydrophilic treatment agent;
The second fibers in the mixed fiber region contain a smaller amount of functional agent than the first fibers,
the first fibers and the second fibers are fused by a heat fusion portion,
The first fiber and the second fiber are core-sheath fibers having different core/sheath ratios,
The core/sheath ratio of the second fibers is higher than the core/sheath ratio of the first fibers.
Absorbent articles. An absorbent article comprising an absorbent body and a top sheet disposed on a skin-facing side of the absorbent body,
the top sheet includes a fiber layer having a mixed fiber region in which a first fiber and a second fiber are arranged across a plane perpendicular to a thickness direction, the fiber layer being positioned so as to face the skin of a wearer;
The first fibers and the second fibers are each heat fusible,
The first fiber contains a hydrophilic treatment agent and a functional agent capable of imparting a predetermined function to the skin of a wearer,
the second fiber contains a hydrophilic treatment agent;
The second fibers have a smaller water contact angle than the first fibers,
the first fibers and the second fibers are fused by a heat fusion portion,
The first fiber and the second fiber are core-sheath fibers having different core/sheath ratios,
The core/sheath ratio of the second fibers is higher than the core/sheath ratio of the first fibers.
Absorbent articles. The absorbent article according to claim 1 or 2, wherein when the fiber layer is divided into two equal parts in a thickness direction, the second fibers are present in a larger amount on the non-skin facing side than on the skin facing side. The absorbent article according to claim 1 , wherein the skin-facing surface of the fiber layer is composed only of the first fibers. The absorbent article according to claim 1 , wherein the fineness of the first fibers is greater than the fineness of the second fibers. The absorbent article according to claim 1 , wherein the fineness of the first fibers is smaller than the fineness of the second fibers. The absorbent article according to any one of claims 1 to 6, wherein the top sheet comprises a first sheet made of the fiber layer, and a second sheet arranged between the first sheet and the absorbent body and having a higher hydrophilicity than the first sheet.

Images