JP4549254B2 - Absorbent articles - Google Patents

Description

  The present invention relates to absorbent articles such as panty liners, side pads, breast milk pads, and light incontinence pads.

  For absorbent articles whose main purpose is to absorb a relatively small amount of bodily fluids such as panty liners (side sheets for urinals) and side pads, in order to obtain a comfortable wearing feeling rather than ensuring a large absorption capacity It is particularly important that the thickness is small.

  Patent Document 1 below describes a panty liner formed by laminating a surface material, an absorbent material, and a back sheet in this order from the skin contact surface side. In the panty liner described in Patent Document 1, a plurality of through-holes are provided in the surface material so as to quickly transfer body fluid from the surface material to the absorbent material.

JP-A-8-24289

  However, if the surface material is simply provided with a through hole, when a large amount of body fluid flows into the surface material, the absorption performance may be insufficient and the body fluid may not be completely absorbed. In addition, in the panty liner described in Patent Document 1, no special contrivance has been made for the return of body fluid once absorbed (so-called wet back).

  Accordingly, the object of the present invention is to provide a temporary stock of bodily fluid when a large amount of bodily fluid flows into the surface layer on the skin contact surface side or when the bodily fluid once absorbed is likely to return (so-called wet back). It is in providing the absorbent article which can be done.

  The present invention is an absorbent article having a laminated structure comprising a surface layer, an absorbent layer, and a leak-proof layer, wherein the leak-proof layer side of the absorbent layer is recessed from the leak-proof layer toward the surface layer. By providing an absorbent article in which a large number of upward recesses are formed, and the openings on the leak-proof layer side of the upward recesses are sealed by the leak-proof layer to form a large number of voids, The above objective has been achieved.

  According to the absorbent article of the present invention, when a large amount of bodily fluid flows into the surface layer on the skin contact surface side, or when the bodily fluid once absorbed is likely to reverse (so-called wet back), Can do stock.

Hereinafter, the absorbent article of the present invention will be described with reference to the drawings based on preferred reference embodiments (hereinafter, also referred to as one embodiment or this embodiment) .
Paragraph [0053] An embodiment of the present invention described later is referred to as an “embodiment of an absorbent article (panty liner) of the present invention”. In the absorbent article (panty liner) of the present invention shown in FIG. 3, the following gap 5 penetrates the following absorption layer 22, and the opening on the following surface layer 21 side of the following gap 5 is also the following surface layer 21. Is substantially the same as the reference embodiment described below, except that
As shown in FIGS. 1 and 2, the panty liner 1 as one embodiment of the absorbent article of the present invention is a back sheet that forms a top sheet 2 having a top layer 21 and an absorbent layer 22 and a leak-proof layer 4. It has a laminated (three-layer) structure consisting of The thickness of the laminated structure is preferably 2 mm or less from the viewpoint that it is difficult to feel uncomfortable at the time of wearing.

  More specifically, the surface layer 21 and the absorption layer 22 in the present embodiment are formed from the surface sheet 2 as shown in FIGS. The surface sheet 2 has a laminated structure in which the surface layer 21 and the absorption layer 22 are partially bonded by the bonding portion 23. The surface layer 21 forms a large number of raised portions 3 that are raised from the absorbing layer 22 toward the surface layer 21 at portions other than the joint portion 23. The details of the top sheet 2 will be described after the entire configuration of the panty liner 1 is described.

  The leak-proof layer 4 in this embodiment is formed from a back sheet. As the back sheet, a liquid-impermeable or water-repellent material is used. For example, a thermoplastic resin film, a water-repellent nonwoven fabric, or a laminate of the film and the nonwoven fabric is used. In the present embodiment, a back sheet made of a thermoplastic resin film having moisture permeability is used.

  The non-skin contact surface side of the top sheet 2 and the skin contact surface side of the back sheet 4 are joined by an adhesive, heat seal or the like. Since a strong bonding force is required at the peripheral edge portion 1A of the panty liner 1, the bonding is performed by continuous (not discontinuous) heat sealing. About the other area | region, it has joined by the adhesion part (not shown) by an adhesive agent. Although the adhesive portion can be provided entirely on the skin contact surface side of the back sheet 4 when viewed macroscopically, the absorbent layer 22 of the top sheet 2 and the back sheet 4 are directly brought into contact with each other so that the moisture-permeable back surface is provided. In order to ensure the air permeability from the sheet 4, it is preferably discontinuous.

  A discontinuous adhesion part can be formed by, for example, applying a hot melt adhesive in a spiral pattern. Examples of the application pattern of the hot melt adhesive include a dot pattern, an Ω-shaped pattern, and a linear pattern in addition to the spiral pattern. These patterns can be formed by spiral spray coating, slot spray coating, control weave coating, gravure coating or the like of a hot melt adhesive. In particular, spiral spray coating and control weave coating are preferably used from the viewpoints of ease of control and small damage to the leak-proof layer.

  On the non-skin contact surface 41 side of the back sheet 4, a fastening adhesive (not shown) for fastening to the underwear can be provided.

Next, the surface sheet 2 in the panty liner 1 of this embodiment will be described in detail. It is preferable that the surface sheet 2 has elasticity in the planar direction. As such a surface sheet 2, in this embodiment, the uneven | corrugated sheet | seat shown in FIG.1 (b) and FIG. 2 is used.
As shown in FIGS. 1B and 2, the surface sheet 2 in the present embodiment is a laminate in which a surface layer 21 and an absorbent layer 22 adjacent to the surface layer 21 are partially bonded by a bonding portion 23 (2 Layer) made of a nonwoven fabric having a structure.

The surface layer 21 is composed of an aggregate of fibers. On the other hand, the absorption layer 22 is composed of an aggregate of fibers of a different type and / or blend from the fibers constituting the surface layer 21. The surface layer 21 and the absorption layer 22 are partially bonded by a large number of bonding portions 23, and therefore the surface layer 21 and the absorption layer 22 are not entirely bonded.
The surface layer 21 of the surface sheet 2 means a layer facing the wearer when the surface sheet 2 is incorporated in the absorbent article, and the absorption layer 22 means an opposite layer.

  The joint portions 23 are small and discretely formed discontinuously, and form a staggered arrangement pattern as a whole. The joint portion 23 is consolidated and has a smaller thickness and a higher density than other portions of the top sheet 2. The surface layer 21 and the absorption layer 22 are integrated in the thickness direction by the joint portion 23. The joint portion 23 in the present embodiment is circular, but the shape may be, for example, an ellipse, a triangle, a rectangle, or a combination thereof. Moreover, the junction part 23 can be made into continuous shapes, for example, linear shapes, such as a straight line and a curve.

  The area ratio of the bonding portion 23 to the area of the surface sheet 2 (area of the bonding portion 23 per unit area of the surface sheet 2) depends on the specific use of the surface sheet 2, but the surface layer 21 and the absorption layer 22 4 to 35%, particularly 5 to 30% is preferable from the standpoint of sufficiently increasing the bonding strength of the sheet and from the viewpoint of sufficiently forming a convex three-dimensional shape to express the bulk of the raised portion 3. . Moreover, when manufacturing the surface sheet 2 according to the manufacturing method mentioned later, it is preferable that the said area rate before shrinkage | contraction is 2 to 15%, especially 5 to 10%.

  As shown in FIG. 1B, a large number of upward recesses 24 that are recessed from the leak-proof layer 4 toward the surface layer 21 are formed on the leak-proof layer (back sheet) 4 side of the absorbent layer 22. The upward concave portion 24 is formed corresponding to the position of the joint portion 23. When the absorbent layer 22 side of the topsheet 2 is joined to the backsheet 4, the upward recess 24 is sealed by the backsheet 4 side (bottom) opening by the backsheet 4, thereby forming the gap 5. The gap 5 is formed when a large amount of body fluid flows into the surface layer 21 side of the surface sheet 2 and cannot be completely absorbed by the surface layer 21, or when the body fluid once absorbed is likely to reverse (so-called wet back). , It serves as a temporary stock area for body fluids.

The number of voids 5 (upward recesses 24) per unit area in the plane direction on the surface sheet 2 is preferably 3 to 20 / cm ² , more preferably 5 to 10 / cm ² . The volume of the gap 5 (upward recess 24) is preferably 0.05 to ³ mm ³ , more preferably 0.1 to ¹ mm ³ . Bottom view area of the opening of the backsheet 4 side upward recesses 24 is preferably 0.5 to 50 mm ^2, more preferably 1 to 20 mm ^2. The ratio (P1 / P0) of the total area P1 of the bottom view area of the opening on the back sheet 4 side of the upward recess 24 to the planar direction area P0 of the top sheet 2 is preferably 0.2 to 1, more preferably 0. .4 to 0.8. The depth of the upward recess 24 is preferably 0.05 to 1 mm, more preferably 0.1 to 0.5 mm.

  In the surface layer 21, the constituent fibers protrude in the thickness direction between the joint portions 23. As a result, the surface layer 21 is formed with a large number of raised portions 3 that are raised from the absorbing layer 22 toward the surface layer 21 at portions other than the joint portion 23. In the present embodiment, the topsheet 2 has a large number of closed regions formed by being surrounded by the joints 23 having a staggered array pattern, and in this closed region, the surface layer 21 is formed. A protruding portion 3 is formed so as to protrude. The interior of the raised portion 3 is filled with the constituent fibers of the surface layer 21. The joint portion 23 is a concave portion relative to the raised portion 3. Therefore, the surface sheet 2 has a bulky structure in which the surface layer 21 has a large number of uneven portions as a whole.

  When the surface connecting the joints 23 is used as a reference surface, the height of the raised portion 3 is higher than the height of the absorbing layer 22. Specifically, the height of the raised portion 3 is preferably 0.3 to 5 mm, and the height of the absorbent layer 22 is preferably 0.1 to 3 mm. When set to such a height, the wearing feeling of the absorbent article provided with the topsheet 2 becomes good. These heights can be measured by observing the longitudinal section of the top sheet 2 with a microscope.

Next, the constituent fibers of the top sheet 2 will be described in detail.
The absorbent layer 22 in the topsheet 2 of the present embodiment includes latent crimpable fibers in which crimps are expressed. The latent crimpable fiber in which crimps are expressed is in a coiled crimped state. The latent crimpable fiber preferably has a fineness of about 1 to 7 dtex. The latent crimpable fiber includes, for example, an eccentric core-sheath type composite fiber or a side-by-side type composite fiber containing two types of thermoplastic polymer materials having different shrinkage rates as components. Examples thereof include those described in JP-A-9-296325 and Japanese Patent No. 2759331. As an example of two types of thermoplastic polymer materials having different shrinkage rates, for example, a combination of an ethylene-propylene random copolymer (EP) and polypropylene (PP) is preferably exemplified. It is preferable from the viewpoint of the formation of the raised portion 3 that the latent crimpable fiber in which crimps are expressed is contained in the absorbent layer 22 by 50 wt% or more, particularly 70 to 90 wt%. The absorbent layer 22 may be made of 100% latent crimpable fiber that has developed crimps.

  In the case where the absorbent layer 22 contains fibers other than the latently crimpable fibers in which crimps have developed, the fibers include heat that does not substantially heat shrink at the crimping start temperature of the latently crimpable fibers. A fused fiber is mentioned. Specifically, a heat-fusible fiber that has heat-shrinkability but does not substantially heat-shrink at the crimp start temperature of the latent crimpable fiber, or a heat-fusible fiber that does not substantially have heat-shrinkability. (Hereinafter, these fibers are collectively referred to as non-heat-shrinkable fused fibers).

  The surface layer 21 includes non-heat-shrinkable fused fibers. Specifically, the surface layer 21 is preferably composed of a core-sheath type or a side-by-side type heat fusion composite fiber. Further, the surface layer 21 may contain latent crimpable fibers contained in the absorbent layer 22. Thereby, the recoverability when the raised portion 3 formed from the surface layer 21 is compressed becomes high. In addition, the recoverability when the surface layer 21 is extended in the plane direction is improved. From these viewpoints, the amount of the latent crimpable fiber contained in the surface layer 21 is preferably 3 to 50% by weight, particularly 10 to 30% by weight.

  In the raised portion 3, it is preferable that the latent crimpable fibers in which crimps are expressed are not heat-sealed. Moreover, it is preferable that the latent crimpable fiber is not heat-sealed with the other fibers contained in the surface layer 21. Thereby, the freedom degree of the fiber in the surface layer 21 increases, and the surface layer 21 further increases the freedom degree with respect to the movement in the plane direction.

  The absorption layer 22 has a liquid permeability of the region R1 on the side of the surface layer 21 of the void portion 5 so that the region R2 on the side portion side of the void portion 5 (region outward in the plane direction from the void portion 5) R2 is. It is lower than that. In order to provide a difference in liquid permeability as described above, for example, [1] provide a difference in hydrophilicity, [2] provide a difference in fiber density.

[1] Hydrophilicity By making the hydrophilicity of the region R1 on the surface layer 21 side of the void 5 lower than the hydrophilicity of the region R2 on the side of the void 5, the absorption layer 22 The liquid permeability of the region R1 on the surface layer 21 side can be made lower than the liquid permeability of the region R2 on the side portion side of the gap 5.
As a method for hydrophilizing the regions R1 and R2, a method commonly used in the technical field can be appropriately used. For example, it is possible to increase the hydrophilicity by mixing hydrophilic fibers such as rayon and pulp fibers at a predetermined ratio, but thermoplastic fibers typically used as constituent fibers are hydrophilized before forming the web. It is more common.

  Specifically, polyethylene, polypropylene, polyester, nylon, or a composite fiber thereof is prepared, and various hydrophilic treatments are applied to the composite fiber at a stage before the staple is cut by cutting to a predetermined length. Work. Hydrophilic treatment agents include various alkyl sulfonates typified by α-olefin sulfonates, acrylates, acrylate / acrylamide copolymers, ester amides, ester amide salts, polyethylene glycol or derivatives thereof, Hydrophilic treatment agents known to those skilled in the art, such as water-soluble polyester resins, various silicone derivatives, various sugar derivatives, or mixtures thereof, can be used.

[2] Fiber density By making the fiber density of the region R1 on the surface layer 21 side of the void 5 closer to the fiber density of the region R2 on the side of the void 5, the void 5 The liquid permeability of the region R1 on the surface layer 21 side can be made lower than the liquid permeability of the region R2 on the side portion side of the gap 5.
In order to form a sparse / dense relationship of fiber density, change the gap between the constituent fibers (if the gap is narrow, the fiber density becomes dense), change the fineness of the fiber assembly (if the fineness is high, the fiber density becomes dense), Use a method such as changing the ratio of heat-fusible fibers (the fiber density becomes dense when the amount of heat-sealing is large), or changing the degree of crimp of the fibers (the fiber density becomes dense when there are many crimps). Can do.

In addition, a fiber density measures the basic weight (mass per m < ² >) and thickness of an applicable area | region, and is calculated by those ratio (basis weight / thickness). At this time, the thickness is based on the concept of fabric compression test (initial thickness) ["Standardization and analysis of texture evaluation (2nd edition)", published by Kyuo Kawabata, Japan Textile Machinery Society, Texture Measurement and Standardization Research Committee (Issued July 10, 1980)] is applied mutatis mutandis, and the thickness under a load of 0.5 g / cm ² is taken as the representative value.

For measurement of thickness, a KES-FB3 compression tester manufactured by Kato Tech is used. This tester applies a compression-recovery load to a cloth or film-like sample by lowering and raising a pressurizing section having a circular compression surface with an area of 2 cm ² , and compressing and compressing one cycle of the compression and recovery process. A hysteresis curve of load-compression deformation amount is obtained, from which sample thickness, compression work amount, recoverability, etc. can be obtained.

The basis weight of the surface layer 21, 10~100g / m ^2, it is particularly preferably 20 to 60 g / m ^2. The basis weight of the absorbent layer 22 is, 10~100g / m ^2, it is particularly preferably 20 to 60 g / m ^2. When manufacturing the surface sheet 2 with the manufacturing method mentioned later, it is preferable that the basic weight of the surface layer 21 before shrinkage is 5-50 g / m < ² >, especially 10-30 g / m < ² >. On the other hand, the basis weight of the absorbent layer 22 is preferably larger than the basis weight of the surface layer 21, specifically 5 to 50 g / m ² , particularly preferably 10 to 30 g / m ² .

Since the topsheet 2 has the raised portions 3 having a relatively low fiber density, the compressive deformability when compressed in the thickness direction is sufficiently large. More specifically, the surface sheet 2 has an apparent density under 0.5 cN / cm ² pressure 0.005~0.05g / cm ^3, to be particularly 0.01 to 0.05 g / cm ^3, the surface It is preferable from the viewpoint of imparting a bulky feeling to the sheet 2 and increasing the compressive deformability and thus the flexibility. Furthermore, the surface sheet 2 has an apparent density of the entire surface sheet 2 under a pressure of 50 cN / cm ² of 0.04 to 0.1 g / cm ³ , particularly 0.05 to 0.08 g / cm ³ . It is preferable from the point that sufficient strength is imparted to the top sheet 2 and the shape retention of the three-dimensional three-dimensional raised portion 3 is enhanced. The pressure of 0.5 cN / cm ² is approximately equal to the pressure during wearing of the absorbent article, and the pressure of 50 cN / cm ² is approximately equal to the pressure when body pressure is applied during wearing of the absorbent article.

The apparent density of the top sheet 2 under a pressure of 0.5 cN / cm ^{2 and a} pressure of 50 cN / cm ² is the basis weight, and the thickness under a pressure of 0.5 cN / cm ² and 50 cN / cm ² , which will be described later, respectively. It is calculated by dividing.

Although the thickness of the surface sheet 2 depends on the specific application, the thickness under a pressure of 0.5 cN / cm ² is preferably 0.5 to 5 mm, particularly preferably 1 to 3 mm, and 50 cN / cm ² pressure. The lower thickness is preferably 0.2 to 3 mm, particularly 0.5 to 2 mm from the viewpoint of bulkiness and compressive deformation.

0.5 cN / cm ² under a pressure and 50 cN / cm ² Thickness under pressure is measured using the KES-FB3 compression tester. The surface sheet is cut into a 2.5 cm × 2.5 cm square, and this is set as a sample in a compression tester. Then, the pressing unit is lowered at a pressing speed of 0.02 mm / second, and the sheet is pressed until pressures of 0.5 cN / cm ² and 50 cN / cm ² are applied. The thickness was measured at that time, the thickness at ² under pressure 0.5 cN / cm ² under a pressure and 50 cN / cm.

The topsheet 2 has a compression rate defined by the following equation (1) of 30 to 85%, particularly 40 with respect to the thickness T1 under the pressure of 0.5 cN / cm ² and the thickness T2 under the pressure of 50 cN / cm ^2. It is preferable that it is -70% from the point that the absorbent article provided with the top sheet can easily follow the body shape and movement of the wearer and the feel of the top sheet 2 is improved.
Compression rate (%) = (T1-T2) / T1 × 100 (1)

From the viewpoint of expressing the surface sheet 2 with sufficient compressive deformability and bulkiness, the basis weight of the surface sheet 2 is preferably ²⁰ to 200 g / m ² , and particularly preferably 40 to 150 g / m ² . The basis weight is obtained by cutting the surface sheet 2 into a size of 50 mm × 50 mm or more, collecting a measurement piece, measuring the weight of the measurement piece using an electronic balance with a minimum display of 1 mg, and converting it to the basis weight. Ask.

  Next, a method for manufacturing the top sheet 2 of the present embodiment will be described. First, the surface layer 21 and the absorption layer 22 are each manufactured. The surface layer 21 is in the form of a web or non-woven fabric containing non-heat-shrinkable fused fibers, for example. Specifically, the surface layer is formed in the form of an air-through nonwoven fabric in which a card web is formed using a non-heat-shrinkable fusion fiber and, if necessary, a latent crimpable fiber as a raw material, and the web is heat-treated as it is or in an air-through manner. 21 is used. On the other hand, as the absorbent layer 22, it is preferable to use a web containing 50% by weight or more of latent crimpable fibers.

  The surface layer 21 and the absorbent layer 22 are laminated and embossed to obtain a nonwoven fabric in which both fiber layers are partially integrated at the joint 23. For embossing, a pair of roll devices or ultrasonic embossing devices heated to a predetermined temperature can be used. Whichever device is used, it is preferable to perform embossing from the side of the absorbent layer 22 containing latent crimpable fibers. “Embossing from the side of the absorbent layer 22” means that when a pair of roll devices is used, the embossing is performed so that the engraving roll comes into contact with the absorbent layer 22 (therefore, the smooth roll is When the ultrasonic embossing device is used, it means that embossing is performed so that the horn contacts the absorbing layer 22.

  By embossing from the side of the absorbent layer 22, the latent crimpable fibers contained in the absorbent layer 22 are preliminarily crimped around the joint portion 23. Gather around. In order to effectively perform preliminary crimping of the latent crimpable fiber, the temperature of the embossing, that is, the temperature of the embossing device in contact with the absorbent layer 22 is sufficiently high. Specifically, embossing is preferably performed at a temperature 5 to 30 ° C, particularly 5 to 20 ° C higher than the crimp start temperature of the latent crimpable fiber. Preliminary crimping is also important from the viewpoint of forming the upward recess 24 by thermal contraction of the absorption layer 22 described later.

  On the other hand, the temperature of the embossing device in contact with the surface layer 21 does not have to be so high, and a temperature that can assist the formation of the joint portion 23 is sufficient. Specifically, the melting point of the non-heat-shrinkable fused fiber contained in the surface layer 21 or a temperature higher by about 10 to 20 ° C. than the melting point may be used.

  Next, the obtained nonwoven fabric is heat-treated at a temperature equal to or higher than the crimp start temperature of the latent crimpable fiber. For the heat treatment, for example, hot air blowing (air-through processing) or infrared irradiation is used. The absorption layer 22 contracts between the joint portions 23 by the heat treatment. However, no or little shrinkage occurs on the surface layer 21. Accordingly, the surface layer 21 protrudes in the thickness direction of the nonwoven fabric as much as the shrinkage of the absorbent layer 22, and a large number of raised portions 3 are formed.

In addition, when the surface layer 21 and the absorbent layer 22 are partially joined by embossing, if the embossing is performed from the side of the absorbent layer 22, what is located around the joint 23 is preliminarily crimped. By gathering around the joint 23, a small upward recess is formed. Under this condition, when the absorbing layer 22 contracts, the thickness of the absorbing layer 22 increases on the side facing the surface layer 21 except for the partially joined portion. Become.
By joining the back sheet forming the leak-proof layer 4 to the absorption layer 22 side of the top sheet 2 in which the upward recess 24 is formed, the opening of the leak-proof layer 4 side of the upward recess 24 is sealed, and the gap Part 5 is formed.

When the absorbent layer 22 contracts, a nonwoven fabric may be attached to a restraining means such as a pin tenter in order to control the degree of contraction and successfully form the upward recess 24. Since the absorbent layer 22 contracts isotropically in the plane thereof, when attaching the nonwoven fabric to the restraining means, it is preferable to attach the entire periphery to the restraining means. The degree of shrinkage of the nonwoven fabric is preferably 30 to 80%, particularly preferably 30 to 60% in terms of area shrinkage. The area shrinkage rate is expressed by the following formula (2), where S0 is a reference area before shrinkage and S1 is an area after shrinkage of the reference area.
Area shrinkage rate (%) = (S0−S1) / S0 × 100 (2)

  In the above description, the method for forming the surface sheet 2 including the raised portions 3 and the upward recessed portions 24 by embossing from the side of the absorption layer 22 has been described in detail. It can also be formed by embossing from the surface layer 21 side.

  According to the panty liner 1 of the present embodiment configured as described above, a large number of upward recesses 24 are formed on the leak-proof layer 4 side of the absorbent layer 22, and the openings on the leak-proof layer 4 side of the upward recesses. Is sealed by the leak-proof layer 4 and a large number of voids 5 are formed. Therefore, when a large amount of body fluid flows into the surface layer 21, the absorption performance is absorbed through the surface layer 21 and absorbed by the absorption layer 22. Even if the body fluid is insufficiently absorbed, the body fluid that has not been completely absorbed travels along the upper surface of the surface layer 21 and flows into the gap 5. And the bodily fluid which flowed into the space | gap part 5 is absorbed by the absorption layer 22 little by little mainly from a plane direction. Thus, it is difficult for the void portion 5 to function as a temporary stock region and for the body fluid that has not been completely absorbed by the absorption layer 22 to remain immediately on the upper surface of the surface layer 21.

  Further, even if a strong pressing force is applied to the absorption layer 22 after the body fluid is absorbed into the absorption layer 22, most of the absorbed body fluid flows into the gap portion 5 from the absorption layer 22, and thus is once absorbed. It is difficult for body fluid to return to the upper surface of the surface layer 21 (so-called wet back).

  Further, the absorption layer 22 has a lower liquid permeability in the region R1 on the surface layer 21 side of the gap 5 than in the region R2 on the side of the gap 5, so that As a result, the fiber density in the region R1 is higher than the fiber density in the region R2, and as a result, resistance to a sudden movement of body fluids and movement of body fluids due to pressure is increased regardless of hydrophilicity / hydrophobicity. Therefore, the body fluid is easier to move in the plane direction than in the thickness direction around the gap 5. Therefore, wetback is less likely to occur from this point.

  Furthermore, if the bonding portion 23 formed on the upper portion of the gap portion 5 is formed into a film so as to have a liquid blocking property, or the fibers of the bonding portion 23 are densely packed, the gap portion 5 Since the liquid does not return directly to the surface side, wet back is less likely to occur. The reason is that when the joint portion 23 is formed into a film, the liquid does not enter the joint portion 23. When the fibers of the joint portion 23 are clogged with high density, This is because the capillary diameter is extremely small, so that it is more likely that the liquid enters the region on the side portion side than the liquid enters between the fibers due to the rapid movement of the liquid. In this case, the bonding portion 23 may be hydrophilic or hydrophobic, but it is preferable that no opening or fiber gap is formed in the bonding portion 23.

  In addition to the various effects described above, the surface sheet 2 of the present embodiment is formed with a large number of raised portions 3, and thus has an extremely bulky structure, and also has an effect of high deformability and recoverability against compression. Play. Moreover, when the absorption layer 22 contains the latent crimpable fiber in which the crimp was expressed, at least the absorption layer 22 has elasticity, so that the absorption layer 22 is free to the wearer's movement. It is possible to expand and contract to follow the movement, and to produce an effect that it is difficult to cause deformation of the surface layer 21. Therefore, the texture of the top sheet 2 is very good, and the panty liner 1 provided with the top sheet 2 exhibits a comfortable wearing feeling.

Next, the implementation form of the absorbent article of the present invention will be described. The longitudinal cross-sectional view of the panty liner 1 of embodiment of this invention absorbent article is shown by FIG. As shown in FIG. 3, a large number of the gaps 5 are formed such that the openings on the leakage prevention layer 4 side of the upward recesses 24 are sealed by the leakage prevention layer 4 and penetrate the surface layer 21 side of the absorption layer 22. The opening on the surface layer 21 side is also sealed with the surface layer 21. Also in the panty liner 1 configured as described above, the same effects as the panty liner 1 of the reference embodiment shown in FIG. 1 are exhibited.

The absorbent article of the present invention is not limited to the above embodiment, and can be variously modified without departing from the spirit of the present invention.
For example, the absorbent article of the present invention can be applied to side pads, breast milk pads, light incontinence pads, and the like.
The surface layer may be a continuous layer in the plane direction.

FIG. 1 is a view showing a panty liner as a reference embodiment (one embodiment) of an absorbent article according to the present invention, wherein (a) is a perspective view and (b) is a partially enlarged longitudinal sectional view. .
FIG. 2 is a perspective view showing a surface sheet in the panty liner shown in FIG.
[Figure 3] Figure 3 is a partially enlarged longitudinal sectional view showing a panty liner as implementation form of the absorbent article of the present invention [FIG. 1 (b) corresponding view].

Explanation of symbols

1 Panty liner (absorbent article)
2 Surface sheet 21 Surface layer 22 Absorbing layer 23 Joint part 24 Upward recessed part 3 Raised part 4 Leak-proof layer (back surface sheet)
5 gap

Claims (3)

A panty liner having a laminated structure consisting of a surface sheet having a surface layer and an absorbent layer and a back sheet forming a leak-proof layer,
Wherein the said backsheet side of the absorbent layer in the surface sheet, the and the backsheet is formed a number of upward concave portions recessed toward the surface layer, the absorbent layer side of the surface sheet is bonded to the back sheet by being, and a number of air gap is formed by sealed by the back sheet side opening said backsheet of said upper-facing recess,
Each said void | hole part has penetrated the said surface layer side of the said absorption layer in the said surface sheet, and the opening part by the side of this surface layer of each said cavity part is also sealed with the said surface layer in this surface sheet. liner. 2. The panty liner according to claim 1, wherein the absorbent layer has a lower liquid permeability in a region on the surface layer side of the gap than in a region on the side of the gap. The panty liner according to claim 1 or 2, wherein the thickness of the laminated structure is 2 mm or less.