JP7508214B2 - Absorbent articles - Google Patents

Description

The present invention relates to absorbent articles such as sanitary napkins.

From the viewpoint of improving the fit to the wearer, there is known an absorbent article having an absorbent core in which the portion located in the region facing the excretory part is narrowed. For example, Patent Document 1 describes an absorbent article having a front end region, a rear end region, and a central region disposed between them, in which the absorbent core has a narrowed shape in the central region.

JP 2008-541943 A

However, such absorbent articles may sometimes be worn shifted backward from the correct wearing position. In this case, the wearer's thighs come into strong contact with the wide part of the absorbent core at the front of the absorbent article, which can easily cause undesirable deformation of the absorbent article and an associated decrease in fit. In addition, this part can easily rub against the skin of the wearer's groin, which can cause skin problems.

The objective of the present invention is to provide an absorbent article that fits well and is less likely to cause chafing in the groin area, even when worn shifted backwards.

An absorbent article according to one embodiment of the present invention comprises a main body including a liquid-permeable top sheet, a back sheet, and an absorbent body having an absorbent core and arranged between the top sheet and the back sheet, and a pair of wing portions protruding from the main body, and has a vertical direction corresponding to the front-to-back direction of the wearer and a horizontal direction perpendicular to the vertical direction.
The body includes:
a middle region in which the pair of wing portions are arranged on the outer sides in the lateral direction, a front region located in front of the middle region in the longitudinal direction, and a rear region located behind the middle region in the longitudinal direction;
A pair of left and right longitudinal compressed grooves extending in the longitudinal direction in the front region;
The tire further includes a lateral compressed groove located laterally inward of the pair of longitudinal compressed grooves in the front region and extending in the lateral direction.
The absorbent core has a narrow portion at least a portion of which is located in the intermediate region, and a wide portion which is located longitudinally forward of the narrow portion and is wider in the lateral direction than the narrow portion.
The pair of longitudinal compressed grooves have a constricted portion that is constricted inward in the laterally direction and is positioned so as to overlap the wide portion in a plan view in the front region.
At least a portion of the lateral compressed groove is located on an imaginary line that passes through the narrowed portion and extends in the lateral direction.

The absorbent article of the present invention provides a good fit and reduces chafing in the groin area.

1 is a plan view showing an absorbent article according to one embodiment of the present invention. 2 is a cross-sectional view taken along line II-II in FIG. 1. FIG. 2 is a plan view showing an absorbent core of the absorbent article. FIG. 2 is an enlarged view of a main portion of FIG. 1, showing a front region of a main body of the absorbent article. 1A and 1B are diagrams showing a measuring device used to measure a lateral compressive load in an embodiment of the present invention, in which FIG. 1A is a plan view and FIG.

The following describes an embodiment of the present invention with reference to the drawings.

[Overall structure of the napkin]
The absorbent article 1 shown in Fig. 1 includes a main body M, a pair of wing portions W, and a pair of rear flap portions F. The absorbent article 1 is configured as a sanitary napkin, and will be referred to as a napkin 1 hereinafter.
The napkin 1 has a vertical direction X corresponding to the front-to-back direction of the wearer, and a horizontal direction Y corresponding to the left-to-right direction of the wearer and perpendicular to the vertical direction X. Furthermore, the napkin 1 has a thickness direction Z perpendicular to both the vertical direction X and the horizontal direction Y. In this specification, the "front of the vertical direction X" is also simply referred to as the "front," and the "rear of the vertical direction X" is also simply referred to as the "rear." In this specification, the side closer to the wearer's skin when worn may be referred to as the upper or skin side, and the side closer to the clothing may be referred to as the lower or non-skin side. The napkin 1 is preferably used while sleeping, and may have a length of, for example, 30 cm or more along the vertical direction X.

The main body M extends along the longitudinal direction X and is fixed to the inner surface of the wearer's clothing when worn. The main body M has an absorbent body 4, which will be described later, and has the function of absorbing liquids (hereinafter also referred to as "liquid") such as menstrual blood of the wearer.

The main body M is divided along the longitudinal direction X into a front region M1, a middle region M2, and a rear region M3.
The intermediate region M2 is a region that faces the excretory part of the wearer when the diaper is normally worn. The intermediate region M2 is a region between the front and rear base ends of the wing portions W, which are disposed on the outer side in the lateral direction Y.
The front region M1 is a region located in front of the middle region M2 (toward the ventral side of the wearer).
The rear region M3 is a region located rearward of the middle region M2 (toward the back of the wearer).
The "normal wearing position" here means the normally assumed wearing position of the napkin 1, specifically, the wearing position where the excretory opening faces the center of the middle region M2 in the vertical direction X. As will be described later, the napkin 1 of this embodiment has a good fit even when worn backward from the normal wearing position, and can prevent chafing against the wearer's groin.

The wing portion W protrudes outward in the lateral direction Y from the main body M.
The rear flap portion F bulges outward in the lateral direction Y in a rear region M3 of the main body M.
In addition, the napkin 1 does not necessarily have to have at least one of the wing portion W and the rear flap portion F.

As shown in FIG. 2, the napkin 1 comprises an absorbent body 4, a top sheet 2, a back sheet 3, and a pair of side sheets 5. In the main body M, the napkin 1 has a configuration in which the back sheet 3, the absorbent body 4, and the top sheet 2 are laminated in the thickness direction Z. These components are appropriately joined and integrated, for example, by bonding with adhesive or heat sealing, or by embossing with compressed grooves, which will be described later.

The absorbent body 4 extends along the longitudinal direction X, and is disposed between the topsheet 2 and the backsheet 3. The absorbent body 4 absorbs liquid from the surface facing the topsheet 2, and retains the liquid by diffusing it internally.
The absorbent body 4 has an absorbent core 7 and a core wrap sheet 8 .
The absorbent core 7 may be formed of, for example, a fiber assembly made of hydrophilic fibers such as pulp fibers, or may have a configuration in which a water-absorbent polymer is held in the fiber assembly.
The core wrap sheet 8 covers the absorbent core 7 and has a function of, for example, maintaining the shape of the absorbent core 7. The core wrap sheet 8 is formed of, for example, a thin, soft paper such as tissue paper or a liquid-permeable nonwoven fabric.

The top sheet 2 is constructed as a liquid-permeable sheet material and is arranged above the absorbent body 4 in the thickness direction Z. A second sheet (sublayer sheet) may be arranged between the top sheet 2 and the absorbent body 4 to improve the liquid permeability from the top sheet 2 to the absorbent body 4 and to prevent the liquid absorbed by the absorbent body 4 from returning to the top sheet 2.

The back sheet 3 is disposed below the absorbent body 4 in the thickness direction Z. The back sheet 3 is joined, for example, at its periphery to the top sheet 2 and the side sheets 5 by heat sealing without the absorbent body 4. The back sheet 3 may be joined to the absorbent body 4 by an adhesive or the like.
The back sheet 3 is formed of, for example, a sheet material having functions such as poor liquid permeability, water vapor permeability, water repellency, etc. As the sheet material, for example, a thermoplastic resin film or a laminate of the film and a nonwoven fabric can be used.
Although not shown, the back sheet 3 is provided with an adhesive portion for fixing the main body M and the wing portions W to clothing.

The pair of side sheets 5 are arranged on the outer side of the top sheet 2 in the lateral direction Y. The material of the side sheets 5 is preferably a sheet material that is less hydrophilic than the top sheet 2, and specific examples include nonwoven fabrics, film materials, and sheets with a laminate structure of nonwoven fabrics and film materials that are less hydrophilic than the top sheet 2. The side sheets 5 are joined to the top sheet 2 by, for example, adhesive E.

[Configuration of absorbent core]
3, the absorbent core 7 has a front wide portion (wide portion) 9, a narrow portion 10, and a rear wide portion 11. The front wide portion 9, the narrow portion 10, and the rear wide portion 11 are aligned along the vertical direction X. That is, the front wide portion 9 is located in front of the narrow portion 10, and the rear wide portion 11 is located behind the narrow portion 10. The absorbent core 7 has a planar shape that is symmetrical in the horizontal direction Y.

At least a portion of the narrow portion 10 is located in the intermediate region M2, and in the example shown in Fig. 3, it extends from the intermediate region M2 to portions of the front region M1 and the rear region M3. The narrow portion 10 is configured to be narrower than the front wide portion 9 and the rear wide portion 11, and has a width D2 which is narrower than the width D1 of the front wide portion 9 and the width D3 of the rear wide portion 11. The width D2 of the narrow portion 10 refers to the minimum width dimension in the horizontal direction Y. In the example shown in Fig. 3, the narrow portion 10 is configured to have a constant width D2 along the vertical direction X.
In addition, "constant width" in a certain region means that when the minimum width of the region in the horizontal direction Y is taken as 100%, the variation in the width dimension within the region is within 20% or less, and the variation is preferably 15% or less, and more preferably 10% or less.

The front wide portion 9 is located in the front region M1, and is configured to be wider in the lateral direction Y than the narrow portion 10. Similarly, the rear wide portion 11 is located in the rear region M3, and is configured to be wider in the lateral direction Y than the narrow portion 10.
The front wide portion 9 includes a front tapered portion 9t that gradually becomes wider from the narrow portion 10 toward the front, and further includes a region having a constant width D1 in front of the front tapered portion 9t. Similarly, the rear wide portion 11 includes a rear tapered portion 11t that gradually becomes wider from the wide portion 9 toward the rear, and further includes a region having a constant width D3 behind the rear tapered portion 11t.
The width D1 of the front wide portion 9 and the width D3 of the rear wide portion 11 may be the same or different, and in the example shown in Fig. 3, they have approximately the same dimensions. The width D1 of the front wide portion 9 and the width D3 of the rear wide portion 11 refer to the maximum width dimensions in the horizontal direction Y. Furthermore, the lengths of the front wide portion 9 and the rear wide portion 11 in the vertical direction X may be the same or different, and for example, the rear wide portion 11 is configured to be longer.

The absorbent core 7 has the narrow width portion 10, so that when the wearer's legs are closed and the crotch width becomes narrow, the external force applied to the narrow width portion 10 from the lateral direction Y can be reduced. This makes it possible to suppress undesirable deformation of the middle region M2 such as compression in the lateral direction Y, and improve the fit of the middle region M2.
On the other hand, when the napkin 1 is worn shifted backward from the normal wearing position, external forces from the wearer's legs are likely to be applied to the front region M1 as well as the middle region M2. In this case, the wearer's legs are likely to come into contact with the front wide portion 9, but the napkin 1 has the following configuration, which makes it possible to suppress a decrease in fit and friction with the groin area.

[Configuration of vertical and horizontal compressed grooves]
As shown in FIG. 1 , the main body M further has a pair of vertical compressed grooves 12 on the left and right sides and a horizontal compressed groove 13 .
The longitudinal compressed grooves 12 and the transverse compressed grooves 13 are linear grooves provided on the surface sheet 2 side of the main body M. The "linear" compressed grooves are not limited to grooves that are linear in plan view, but also include curved grooves and grooves that are a combination of linear and curved grooves. The "linear" compressed grooves also include grooves that are linear overall, with the high-pressure compressed portions aligned slightly apart in the extension direction.

The longitudinal compressed grooves 12 and the transverse compressed grooves 13 are formed by compressing the main body M from the top sheet 2 side in the thickness direction Z.
The longitudinal compressed grooves 12 and the transverse compressed grooves 13 have a configuration in which the topsheet 2 and the absorbent body 4 are integrally recessed toward the backsheet 3 (see FIG. 2). The longitudinal compressed grooves 12 and the transverse compressed grooves 13 can be formed in accordance with a conventional method by compression processing such as heat embossing or ultrasonic sealing. In the longitudinal compressed grooves 12 and the transverse compressed grooves 13, the topsheet 2 and the absorbent body 4 are integrated together by heat fusion or the like.

The vertical compression grooves 12 and the horizontal compression grooves 13 are more compacted than other regions. As a result, when the napkin 1 is subjected to a force, the vertical compression grooves 12 and the horizontal compression grooves 13 elastically deform in response to the force and can function as a starting point for deformation that promotes deformation of the surrounding regions.

1 and 4, the longitudinal compressed grooves 12 extend in the longitudinal direction X in the front region M1. At least a portion of the longitudinal compressed grooves 12 needs to be located in the front region M1, and in the example shown in FIG. 1, the longitudinal compressed grooves 12 extend in the longitudinal direction X over the entire body M.
The term "extending in the vertical direction X" in the vertical compressed grooves 12 is not limited to the vertical compressed grooves 12 extending parallel to the vertical direction X, but may mean that the vertical compressed grooves 12 as a whole extend in a direction that includes a vector component parallel to the vertical direction X.

1 and 4, the vertical compressed grooves 12 have a constricted portion 14 that is constricted inward in the horizontal direction Y. The constricted portion 14 is a portion where a pair of vertical compressed grooves 12 are close to each other inward in the horizontal direction Y, and is configured as a minimum point that is convex inward in the horizontal direction Y. In other words, the vertical compressed grooves 12 are configured so that both the front and rear portions across the constricted portion 14 extend in a direction that includes a vector component that faces inward in the horizontal direction Y toward the constricted portion 14.
The constricted portion 14 is positioned in the front region M1 so as to overlap with the front wide portion 9 in a plan view. The phrase "overlapping with the front wide portion 9 in a plan view" means that the constricted portion 14 overlaps with at least a part of the front wide portion 9 in a plan view seen from the thickness direction Z. In the example shown in Fig. 4, the constricted portion 14 is positioned so as to overlap with the front tapered portion 9t of the front wide portion 9.

As shown in Fig. 1 and Fig. 4, the horizontal compressed groove 13 is located on the inside of the pair of vertical compressed grooves 12 in the horizontal direction Y, and extends in the horizontal direction Y in the front region M1. The horizontal compressed groove 13 is located rearward of the frontmost portion (front end portion 12a) of the pair of vertical compressed grooves 12. In the example shown in Fig. 4, the entire horizontal compressed groove 13 is located in the front region M1. The "extending in the horizontal direction Y" of the horizontal compressed groove 13 is not limited to the aspect in which the horizontal compressed groove 13 extends parallel to the horizontal direction Y, but may be any direction including a vector component parallel to the horizontal direction Y as a whole. In other words, the horizontal compressed groove 13 may be configured as a curve, as will be described in detail later.
4, at least a portion of the lateral compressed groove 13 is located on an imaginary line L that passes through the constricted portion 14 and extends in the lateral direction Y. When the lateral compressed groove 13 is configured in a curved shape, a portion of the groove is disposed on the imaginary line L, and when the lateral compressed groove 13 is configured in a straight line extending in the lateral direction Y, the entire groove is disposed on the imaginary line L.

When the napkin 1 is worn shifted backward from the normal wearing position, the wearer's legs (thighs) are likely to come into contact with the front region M1 where the wide portion 9 of the absorbent core 7 is located. When an external force is applied to this front region M1 from the wearer's legs in the lateral direction Y, in the napkin 1, the longitudinal compressed grooves 12 including the constricted portions 14 receive this external force, inducing deformation of the constricted portions 14 so that they approach each other in the lateral direction Y. Furthermore, since the longitudinal compressed grooves 13 are present at positions overlapping the constricted portions 14 in the longitudinal direction X, the longitudinal compressed grooves 13 also receive this external force and elastically deform along with the constricted portions 14. Specifically, the external force brings the left and right end points of the longitudinal compressed grooves 13 closer to each other, and the central portion of the longitudinal compressed grooves 13 in the lateral direction Y is deformed so as to rise toward the skin. In this way, the constricted portion 14 and the lateral compressed grooves 13 elastically deform in response to an external force from the lateral direction Y, which encourages the front region M1 including the wide portion 9 to deform so as to raise its central portion in the lateral direction Y toward the skin. Therefore, even when an external force is applied by the legs, the front region M1 can easily deform flexibly to fit the wearer's body shape, improving the fit to the wearer.
Furthermore, when an external force is applied to the front region M1 from the lateral direction Y, the energy of the external force is efficiently consumed by the above-mentioned preferable deformation, thereby reducing the contact pressure (resistance) from the napkin 1 to the wearer's groin. This makes it possible to suppress chafing of the wearer's groin and prevent the occurrence of skin troubles.
In addition, the napkin 1 includes an absorbent core 7 having a narrow width portion 10. This makes it difficult for external force to be applied to the middle region M2 from the lateral direction Y, improving the fit in the middle region M2 as described above. Also, the contact pressure from the napkin 1 to the wearer in the middle region M2 is reduced, suppressing chafing in the groin area.
As described above, the napkin 1 exhibits good fitting properties over a wide range from the front region M1 to the middle region M2, and can effectively suppress chafing in the wearer's groin area.

[Detailed configuration of the vertical compression groove]
As shown in FIG. 1, the pair of longitudinal compressed grooves 12 preferably extend from the front region M1 to the rear region M3, and are connected to each other at the front end 12a and the rear end 12b, and have a closed shape. The "closed shape" means a continuous annular shape, but also includes an embodiment having a slight discontinuity of approximately 4 mm or less. The front end 12a is the most forward part of the longitudinal compressed groove 12 and is located in the front region M1. The rear end 12b is the most rearward part of the longitudinal compressed groove 12 and is located in the rear region M3. The front end 12a and the rear end 12b are preferably located on the longitudinal center line CL that divides the main body M into two equal parts in the lateral direction Y.

With this configuration, in the front region M1 where the front end 12a is located, the pair of left and right vertical compression grooves 12 are more likely to act in conjunction with each other. As a result, when the napkin 1 is worn shifted backward from the normal wearing position and an external force is applied to the front region M1 from the lateral direction Y, the pair of vertical compression grooves 12 in the front region M1 are more likely to elastically deform and approach each other, flexibly deforming the area between them. Therefore, the front region M1 is more likely to deform to fit the wearer's body shape, improving the fit to the wearer. In addition, the flexibly deforming front region M1 further reduces the contact pressure from the napkin 1 to the groin area, effectively suppressing chafing in the wearer's groin area.

[Detailed configuration of horizontal compression grooves]
As shown in Figures 1 and 4, the horizontal compressed groove 13 preferably has a shape that is convex forward. In other words, the horizontal compressed groove 13 has a shape that protrudes forward at the center in the horizontal direction Y. As shown in Figure 4, the portion located most forward of the horizontal compressed groove 13 is the front end portion 13a. The portions from the front end portion 13a toward the left and right end points are the left portion 13b and the right portion 13c, respectively. In the horizontal compressed groove 13, the left portion 13b and the right portion 13c extend in a direction that includes a vector component of the vertical direction X. The front end portion 13a is preferably located on the vertical center line CL of the main body M.

When an external force is applied from the lateral direction Y in the lateral compression groove 13 configured as above, the left portion 13b and the right portion 13c are more likely to receive the external force, and the lateral compression groove 13 itself is more likely to flexibly and elastically deform so as to rise toward the skin. This also makes it easier to promote favorable deformation of the entire front region M1 including the constricted portion 14, such that the central portion in the lateral direction Y is raised toward the skin. Therefore, this configuration further improves the fit in the front region M1 and more effectively suppresses chafing in the wearer's groin.

More preferably, the lateral compressed groove 13 is configured with a curved line. That is, in this case, the lateral compressed groove 13 has a shape that is curved convexly forward.
In this configuration, the left portion 13b and the right portion 13c each have a curved shape, so that the length of these portions can be sufficiently ensured and the external force from the lateral direction Y can be sufficiently received. This allows the energy of the external force to be consumed more efficiently and the contact pressure on the wearer's groin to be further reduced.
Furthermore, by having the left portion 13b and the right portion 13c having a curved shape, the central portion of the front region M1 in the lateral direction Y can be curved in a gentle convex shape, thereby further improving the fit in the front region M1.

[Configuration of the central compression groove]
As shown in Fig. 1, the main body M may further have at least one central compressed groove 15 located in the center of the intermediate region M2 in the horizontal direction Y and extending in the vertical direction X. The center of the intermediate region M2 in the horizontal direction Y is the central region when the intermediate region M2 is divided into thirds in the horizontal direction Y. "Extending in the vertical direction X" for the central compressed groove 15 is not limited to the central compressed groove 15 extending parallel to the vertical direction X, but may be any central compressed groove 15 extending in a direction including a vector component parallel to the vertical direction X as a whole.

The central compressed groove 15 is a linear groove provided on the topsheet 2 side of the main body M, and is formed by compression processing from the topsheet 2 side of the main body M in the thickness direction Z. As shown in Figure 2, the central compressed groove 15 has a configuration in which the topsheet 2 and the absorbent body 4 are integrally recessed toward the backsheet 3 side. The central compressed groove 15 can be formed in accordance with a conventional method by compression processing such as heat embossing or ultrasonic sealing. In the central compressed groove 15, the topsheet 2 and the absorbent body 4 are integrated together by heat fusion or the like.
In this way, the central compressed groove 15 is more compacted than the surrounding areas and functions as a deformation starting point that promotes deformation of the surrounding areas when subjected to force.

In the intermediate region M2, the narrow portion 10 acts to reduce the effect of force from the wearer's legs, but even if the force is large, the central compression groove 15 can utilize the force to promote favorable deformation of the intermediate region M2.
Specifically, the central compressed groove 15 can provide a starting point for deformation in the center of the middle region M2 in the lateral direction Y, and the regions on both sides of the central compressed groove 15 in the lateral direction Y can be flexibly deformed by a force from the lateral direction Y. This makes it easier for the middle region M2 to deform so as to rise toward the skin, making it easier to fit along the shape of the body.
Furthermore, in the napkin 1, the force energy is efficiently consumed by the preferable deformation of the middle region M2, so that the contact pressure from the middle region M2 to the groin area of the wearer is reduced.
Therefore, with this configuration, the fit is further improved in the middle region M2 as well as the front region M1, and chafing in the groin area is effectively suppressed over a wide range of the front region M1 and the middle region M2.

The central compression groove 15 is configured in a fragmentary shape extending in the vertical direction X, and is configured to be short relative to the length of the intermediate region M2 in the vertical direction X. From the viewpoint of flexibly deforming the intermediate region M2, the length of the central compression groove 15 in the vertical direction X is preferably 5 mm or more, more preferably 7 mm or more, and is preferably 30 mm or less, more preferably 25 mm or less.

As shown in FIG. 1, the main body M preferably has multiple central compression grooves 15. This allows multiple deformation starting points to be provided in the center of the middle region M2 in the lateral direction Y, allowing the middle region M2 to deform more flexibly.

The main body M may have, for example, four central compressed grooves 15. In the example shown in Fig. 1, two central compressed grooves 15 are arranged in the center of the intermediate region M2 in the vertical direction X, and one central compressed groove 15 is arranged in front of and one central compressed groove 15 is arranged in the rear of the two central compressed grooves 15. The two central compressed grooves 15 in the center of the vertical direction X are arranged, for example, in the left and right parts of the main body M with respect to the vertical center line CL, and the front and rear central compressed grooves 15 are arranged, for example, on the vertical center line CL.
As a result, the central compressed groove 15 is disposed so as to surround the central portion of the intermediate region M2, and the central portion of the intermediate region M2 can be deformed so as to rise up in response to a force from the lateral direction Y. Therefore, with this configuration, the intermediate region M2 can be more easily deformed to conform to the shape of the body, and the fit of the intermediate region M2 is further improved.

[Configuration of low basis weight grooves in absorbent core]
As shown in Fig. 3, the absorbent core 7 further has low basis weight vertical grooves 16 extending in the longitudinal direction X, and low basis weight horizontal grooves 17 extending in the transverse direction Y. In the example shown in Fig. 3, the absorbent core 7 has a plurality of vertical grooves 16 and a plurality of horizontal grooves 17, which divide the absorbent core 7 into blocks. "Extending in the longitudinal direction X" or "extending in the transverse direction Y" for these grooves means that they extend in the longitudinal direction X or transverse direction Y as a whole, and also includes a configuration in which at least a portion of them is curved or meandering.
2, these grooves include grooves formed downward from the upper surface in the thickness direction Z of the absorbent core 7. These grooves are configured to have a lower basis weight than the surrounding areas.
The "low basis weight" of the grooves includes not only the case where the material of the absorbent core 7 is present, but also the case where the material of the absorbent core 7 is not present. The case where the material of the absorbent core 7 is present in each of the longitudinal grooves 16 and the transverse grooves 17 is more preferable because the block-shaped portions of the absorbent core 7 located on both sides are connected via each groove, thereby making it possible to impart flexibility to the absorbent core 7 while suppressing deformation and destruction, etc.

The vertical grooves 16 and horizontal grooves 17 are thinner than the surrounding block-shaped parts, and therefore tend to be the starting point of deformation. In other words, the absorbent core 7 has vertical grooves 16 and horizontal grooves 17, which makes it easier for the main body M to flexibly deform. This allows the deformation action of each compressed groove in response to the above-mentioned forces to be exerted more effectively, improving fit. In addition, the increased flexibility of the absorbent core 7 reduces the contact pressure on the wearer's groin, and chafing in the groin can be prevented even more effectively.

[Additional Description of the Present Embodiment]
The following provides a supplementary explanation of this embodiment.

(Additional explanation of absorbent core)
2 and 3, the absorbent core 7 is located at least in the center of the intermediate region M2 in the lateral direction Y, and has a high basis weight section 18 having a basis weight higher than that of the surrounding area. In Fig. 3, the high basis weight section 18 is shown by a dot pattern. The high basis weight section 18 protrudes upward in the thickness direction Z, for example. The high basis weight section 18 enhances the absorbency of the absorbent core 7 in the intermediate region M2, and can further enhance the fit in the intermediate region M2.

As shown in FIG. 3, the high basis weight portion 18 may extend from the middle region M2 to the front region M1 and rear region M3, for example, over the entire length of the narrow portion 10 of the absorbent core 7 in the longitudinal direction X. This enhances the absorbency of the narrow portion 10 and ensures a sufficient fit.

Also, as shown in FIG. 2, the central compressed groove 15 may be formed on the high basis weight portion 18. This can promote flexible deformation of the high basis weight portion 18, which has a large basis weight, and can further improve the fit in the middle region M2.

(Width of each part of the absorbent core)
The widths D1, D3 of the front wide portion 9 and the rear wide portion 11 are preferably 60 mm or more and 100 mm or less, and more preferably 70 mm or more and 90 mm or less.
The width D2 of the narrow portion 10 is preferably 40 mm or more and 75 mm or less, and more preferably 50 mm or more and 70 mm or less, from the viewpoint of obtaining the above-mentioned force buffering effect while ensuring sufficient absorbency.

(Additional explanation of the vertical and horizontal grooves)
3, five vertical grooves 16 are arranged at intervals in the lateral direction Y in the front wide portion 9 and the rear wide portion 11. The arrangement of these vertical grooves 16 is not limited, but for example, one vertical groove 16 is arranged on the vertical center line CL, and two pairs of vertical grooves 16 are arranged on both sides of the vertical center line CL in the lateral direction Y.
In the narrow width portion 10, one vertical groove portion 16 is disposed on the vertical centerline CL, and a pair of vertical groove portions 16 are disposed on both sides of the vertical centerline CL in the horizontal direction Y. The two vertical groove portions 16 on both sides of the narrow width portion 10 may extend so as to surround the outer periphery of the high basis weight portion 18. This makes it possible to prevent the high basis weight portion 18 from breaking and to maintain its shape well, and also to promote flexible deformation of the narrow width portion 10.
As shown in FIG. 3, these vertical grooves 16 may extend over the entire length of the front wide portion 9, the narrow portion 10 and the rear wide portion 11 in the vertical direction X, or may extend over a portion of each of these portions.

In the example shown in FIG. 3, the lateral grooves 17 are arranged across the entire absorbent core 7 at intervals in the longitudinal direction X. The lateral grooves 17 may extend across the entire width of the absorbent core 7 in the lateral direction Y as shown in FIG. 3, or may extend across only a portion of it.

The width of the vertical grooves 16 and the horizontal grooves 17 in a direction perpendicular to the extension direction is preferably 0.5 mm or more, more preferably 1 mm or more, and is preferably 10 mm or less, more preferably 5 mm or less. The depth of the vertical grooves 16 and the horizontal grooves 17 is preferably 0.5 mm or more, and preferably 10 mm or less.

(Other compression groove configurations)
As shown in Fig. 1, the main body M may further have one or more lateral compressed grooves extending in the lateral direction Y in the rear region M3. Hereinafter, the lateral compressed groove 13 in the front region M1 will be referred to as the first lateral compressed groove 13. The lateral compressed groove located inside the longitudinal compressed groove 12 in the longitudinal direction X and lateral direction Y in the rear region M3 will be referred to as the second lateral compressed groove 19. The lateral compressed groove located rearward (outside) of the longitudinal compressed groove 12 in the rear region M3 will be referred to as the third lateral compressed groove 20.
In addition, the main body M may have other compressed grooves (not shown), for example, one or more pairs of auxiliary compressed grooves extending in the longitudinal direction X in the intermediate region M2.

The second horizontal compressed groove 19 has, for example, a shape that convexly extends rearward and is configured in a curved shape. The second horizontal compressed groove 19 is located inside the area surrounded by the annular structure of the vertical compressed groove 12, and for example, two second horizontal compressed grooves 19 are provided spaced apart in the vertical direction X. The rear end portion located at the rearmost position of each second horizontal compressed groove 19 is positioned, for example, on the vertical center line CL. Such second horizontal compressed grooves 19 promote deformation of the central portion of the rear region M3 in the horizontal direction Y toward the skin, improving the fit of the rear region M3 to the wearer's buttocks.

The third horizontal compressed groove 20 has, for example, a shape that convexly extends rearward and is configured in a curved shape. The third horizontal compressed groove 20 is located outside the annular structure of the vertical compressed groove 12. The rear end portion of the third horizontal compressed groove 20 located at the rearmost position is disposed, for example, at a position spaced apart in the horizontal direction Y from the vertical center line CL. In addition, one of the left and right end points of the third horizontal compressed groove 20 may be configured in a spiral shape. Such a third horizontal compressed groove 20 can suppress the area near the rear end portion of the rear region M3 from rising toward the skin side, thereby improving the fit behind the wearer's approximately flat buttocks.

The above describes an embodiment of the present invention, but the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

In the above embodiment, a sanitary napkin is shown as an example of an absorbent article, but the absorbent article is not limited to this. The absorbent article of the present invention may be, for example, a urine pad, a panty liner, a disposable diaper, etc.

The present invention will be explained in more detail below with reference to examples, but the present invention is not limited thereto.

[Preparation of absorbent articles for evaluation]
(Example)
As the absorbent article of Example 1, a sanitary napkin (napkin) having the configuration shown in Figs. 1 to 4 was produced.
First, an absorbent body was prepared by wrapping an absorbent core with a core wrap sheet. As shown in Fig. 3, the absorbent core had a narrow portion and wide portions located at both front and rear end sides thereof, and had a block structure formed by vertical grooves and horizontal grooves.
This absorbent body was placed between a liquid-permeable top sheet and a back sheet made of a polyethylene resin film to produce a laminate. The top sheet was fixed onto the absorbent body by applying an adhesive in a spiral pattern onto the absorbent body.
Further, the laminate was compressed from the top sheet side. The compression process was carried out, for example, by heating and pressing the laminate between an embossing roll having a convex portion on its outer circumferential surface and a flat roll having a flat outer circumferential surface. As a result, compressed grooves having a pattern corresponding to the planar shape of the convex portion were formed, and the napkin according to the embodiment was produced.
The napkin of this Example 1 had a total length of 400 mm, the longitudinal and lateral lengths of the narrow portion of the absorbent core were 130 mm and 65 mm, respectively, the maximum lateral width of the wide portion was 80 mm, and the longitudinal length of the tapered portion was 11 mm.

As shown in Table 1, the napkin according to the embodiment had a vertical compressed groove having a narrowed portion located so as to overlap the wide portion in a plan view in the front region, and a horizontal compressed groove, at least a portion of which was located on an imaginary line extending horizontally through the narrowed portion.

(Comparative Example 1)
As Comparative Example 1, a napkin was produced having the same configuration as the Examples, except that it did not have longitudinal compressed grooves having a constricted portion in the front region and transverse compressed grooves at least a portion of which was located on an imaginary line extending laterally through the constricted portion, as shown in Table 1. As shown in Table 1, the napkin according to Comparative Example 1 had an absorbent core having a narrow portion, like the napkins according to the Examples.

(Comparative Example 2)
As Comparative Example 2, a napkin was prepared with the same structure as in the Examples, except that it had an absorbent core that did not have a narrow portion and had a constant width over the entire length in the longitudinal direction X, as shown in Table 1. As shown in Table 1, the napkin in Comparative Example 2 had longitudinal compressed grooves with a constricted portion in the front region, and lateral compressed grooves at least a portion of which was located on an imaginary line that passed through the constricted portion and extended laterally.

(Comparative Example 3)
As Comparative Example 3, a napkin was prepared with the same structure as in the Examples, except that it had no narrow portion, was provided with an absorbent core whose width was constant over the entire length in the longitudinal direction X, and did not have lateral compressed grooves, at least a part of which was located on an imaginary line extending laterally through a constricted portion, as shown in Table 1. As shown in Table 1, the napkin in Comparative Example 3 had longitudinal compressed grooves with a constricted portion in the front region.

(Comparative Example 4)
As Comparative Example 4, as shown in Table 1, a napkin was prepared having the same configuration as the Examples, except that it had no narrow portion, had an absorbent core with a constant width over the entire length in the longitudinal direction X, and did not have a longitudinal compressed groove with a constricted portion in the front region, and at least a portion of a lateral compressed groove located on an imaginary line extending laterally through the constricted portion.

[Measurement of lateral compression load]
The lateral (width) compressive load was measured by the following method for the napkins of Examples and Comparative Examples 1 to 4. The lateral compressive load was used to evaluate the flexibility of the absorbent article and the magnitude of the contact load applied to the skin against lateral compression from the thighs of the wearer.

As the measuring equipment, a TENSILON RTC-1210S (measuring device T) manufactured by Orientec Co., Ltd. and a jig J were used, as shown in Fig. 5. The jig J has a pair of arcs J11 and J12 for applying a width compression load to the sample S, and a pulley J2 for pulling a string J3 attached to the arc J11.
Sample S was placed between arcs J11 and J12 with tissue paper attached to the entire adhesive portion of the back sheet of the napkin body and the wings and rear flap folded back toward the back sheet side. The width of sample S was adjusted to be the same as the width of the core wrap sheet.
As shown in Fig. 5A, the sample S was placed under the fixed string J4 so that the measurement position was in the same horizontal position as the vertices of the pair of arcs J11 and J12 of the jig J and in contact with the arc J12 on the pulley J2 side. At this time, the distance between the left and right arcs J11 and J12 was set to 100 mm.
The measurement positions of the sample S were two positions: a position that vertically bisects the middle region (the region facing the excretory part) and a position shifted 42 mm backward from this position. Hereinafter, the former measurement position is referred to as the "normal measurement position" and the latter measurement position is referred to as the "measurement position when shifted backward."
During the measurement, as shown in Fig. 5B, the string J3 attached to the arc J11 was pulled by the measuring device T and pulley J2 to compress the sample S to a width of 30 mm, and the load at the point where the sample S was compressed to a width of 50 mm was measured as the width compression load. The measurement conditions were a pulling speed of 50 mm/min, and the height of the fixed string J4 from the sample S mounting surface was 22 mm.
Table 1 shows the measurement results.

From the results of Example and Comparative Examples 1 and 2, it was confirmed that the compressive load at the normal measurement position can be reduced by providing an absorbent core with a narrow width portion.
On the other hand, the results of Example and Comparative Example 1 confirmed that the compressive load at the measurement position during rearward shifting can also be reduced by providing a longitudinal compressed groove having a constricted portion in the front region and a transverse compressed groove at least a part of which is located on a virtual line extending laterally through the constricted portion. Also, the results of Example 1 and Comparative Example 2 confirmed that the compressive load during rearward shifting can be further reduced by providing the absorbent core with a narrow portion in addition to these compressed grooves.
From the results of the Example and Comparative Examples 2 and 3, it was confirmed that the compressive load at all measurement positions can be reduced by the lateral compression grooves located on the imaginary lines extending laterally through the constricted portion.
From the results of the embodiment and comparative examples 3 and 4, it was confirmed that by providing a longitudinal compression groove having a narrowed portion in the front region, the compression load at the measurement position when shifted backward can be significantly reduced.
From the above, it has been confirmed that an absorbent article having an absorbent core with a narrow width portion, longitudinal compressed grooves with a constricted portion in the front region, and transverse compressed grooves at least a part of which is located on a virtual line extending transversely through the constricted portion can reduce the transverse compressive load not only in the normal wearing position but also in the wearing position shifted backward. Therefore, such an absorbent article can improve the fit of the wearer and reduce the contact pressure on the groin area to suppress chafing.

1... Napkin (absorbent article)
2: Top sheet 3: Back sheet 4: Absorbent body 9: Front wide portion (wide portion)
10: Narrow width portion 12: Longitudinal compressed groove 13: Horizontal compressed groove 14: Narrowed portion M: Main body M1: Front region M2: Middle region M3: Rear region W: Wing portion

Claims (5)

An absorbent article comprising a main body including a liquid-permeable top sheet, a back sheet, and an absorbent body having an absorbent core and disposed between the top sheet and the back sheet, and a pair of wing portions protruding from the main body, the absorbent article having a vertical direction corresponding to the front-to-rear direction of a wearer and a horizontal direction perpendicular to the vertical direction,
The body includes:
a middle region in which the pair of wing portions are arranged on the outer sides in the lateral direction, a front region located in front of the middle region in the longitudinal direction, and a rear region located behind the middle region in the longitudinal direction;
A pair of left and right longitudinal compressed grooves extending in the longitudinal direction in the front region;
A lateral compressed groove is located laterally inside the pair of longitudinal compressed grooves in the front region and extends in the lateral direction,
The absorbent core has a narrow portion at least a portion of which is located in the intermediate region, and a wide portion which is located in front of the narrow portion in the longitudinal direction and is wider in the lateral direction than the narrow portion,
The narrow portion has a constant width along the longitudinal direction and extends from the intermediate region to a portion of the front region and a portion of the rear region.
The wide portion includes a forward tapered portion that gradually becomes wider from the narrow portion toward the front in the longitudinal direction, and a region having a constant width in the longitudinal direction forward of the forward tapered portion,
The pair of longitudinal compressed grooves have a constricted portion constricted inwardly in the laterally direction and positioned so as to overlap the wide portion in a plan view in the front region,
At least a portion of the lateral compressed groove is located on a virtual line passing through the constricted portion and extending in the lateral direction,
The lateral compression grooves are
a front end portion located furthest forward in the longitudinal direction;
a pair of end points located on both sides in the lateral direction from the front end portion, and having a forwardly convex shape;
The body includes:
An absorbent article, wherein there is no compressed groove extending in the longitudinal direction across the entire longitudinal direction of the narrow width portion on the laterally inner side of the longitudinal compressed groove. The absorbent article according to claim 1 , wherein the pair of longitudinal compressed grooves extend from the front region to the rear region, are connected to each other at the front end and the rear end, and have a closed shape. The absorbent article according to claim 2 , wherein the lateral compression grooves are configured with curved lines. The body further includes at least one central squeeze groove located in the laterally central portion of the intermediate region and extending in the longitudinal direction;
The absorbent article according to claim 1 , wherein the central compressed groove is configured in a segment shape having a length in the longitudinal direction shorter than that of the narrow width portion. The absorbent core comprises:
a longitudinally extending low basis weight flute;
The absorbent article according to claim 1 , further comprising a transverse groove portion of low basis weight extending in the transverse direction.

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