RU2435558C1 - Absorbing product of particular shape with marginal elastic elements - Google Patents

Abstract

FIELD: medicine. ^ SUBSTANCE: invention relates to disposable absorbing product, such as diapers, sanitary napkins and protective devices used in case of incontinence. Absorbing product contains liquid-permeable upper sheet, liquid-impermeable posterior sheet and absorbing core, located between them. Permeable for flowing media upper sheet and impermeable for flowing media posterior sheet extend beyond absorbing core, at least, in direction of width (X) and are connected with each other in zone outside absorbing core for formation of marginal suture. Absorbing product contains two absorbing elements, each elastic element passing along one longitudinal edge of absorbing core in such a way that along larger part of extension of elastic elements in direction of length (Y) elastic elements cover both part of absorbing core and part of marginal suture in direction of width (X). ^ EFFECT: construction ensures improved formation of three dimensional shape of product, which provides possibility of fast and efficient reception, distribution and holding of large amount of organism secretions. ^ 16 cl, 10 dwg

Description

FIELD OF TECHNOLOGY

The present invention relates to an absorbent article that is configured to take a predetermined three-dimensional shape when subjected to pressure in the width direction.

BACKGROUND OF THE INVENTION

Disposable absorbent articles such as diapers, sanitary napkins, incontinence protectors and panty liners for everyday use are used to absorb and treat body exudates such as urine, menstrual flow or feces. They can be made to take on a specific shape when used. Such products of a certain shape can provide improved protection against leaks, since their shape is consistent with the shape of the body of the carrier during use.

For example, documents WO 9717920 and GB 2289419 describe disposable liquid absorbing products in which prestressed curved elastic elements are laid across the absorbent body. Elastic elements deform the product when used to form a cup shape.

British Patent 2,289,417 describes an absorbent article having elastic means extending along the entire length of the article, which form a curved "path" with a bulge outward on both sides of the longitudinal axis, so that the article assumes a cup shape when used. GB 2095561 describes a disposable diaper having elastic strips 34, 36. A portion of each elastic strip overlaps the gasket and is adhered to the gasket.

WO 9717920 describes an absorbent article (for example, an incontinence guard) that has two or more curved elastic elements arranged so as to shape the article in a cup shape. Swedish Patent 520411 shows an absorbent article (for example, an incontinence guard) having elastic threads over the core and elastic threads in the seams. US 5,295,988 illustrates an absorbent article that has an elastic material located both under the core and under the seams.

US Pat. No. 4,988,344 discloses a multilayer absorbent article in which the top layer has a reception area having a lower density and designed to quickly receive the recovered liquids.

Absorbent articles that take on a particular shape in use can provide improved fit, but they can also be problematic when handling large amounts of body excretions or with rapid outpouring of body excretions. There remains a need for improved absorbent products that are designed to take a specific shape when used, while this shape provides the ability to quickly and efficiently receive, distribute and retain large amounts of body excretion. It is also preferable that such absorbent articles can be manufactured in a simple, adaptable, economical manner.

Elastic elements in prior art products are typically located only within the edge seam of an absorbent product (for example, in US Pat. No. 4,988,344, discussed above). Since the edge seam is usually made of thin sheet material and, therefore, is very flexible, there is often a situation in which only the edge seam rises with stretching by means of elastic elements. Thus, the edge seam moves independently of the absorbent core. Therefore, a situation often arises in which the absorbent core remains relatively flat, and the cup-shaped shape of the product is provided only by the edge seams. If elastic elements are only present on the absorbent core of the absorbent article, the edge seam will tend to hang freely. Preferably, if the shape of the absorbent article can be attached to a large part of the absorbent article and to as many components as possible.

SUMMARY OF THE INVENTION

In accordance with the present invention, an absorbent article is provided comprising a liquid-permeable topsheet, a liquid-impervious backsheet and an absorbent core disposed therebetween. The absorbent article extends in the directions of length (Y), width (X), and thickness (Z), with the fluid permeable top sheet and the fluid impermeable back sheet extending beyond the absorbent core at least in the width direction (X) . The top sheet and the back sheet are connected to each other in the area outside the absorbent core to form an edge seam. The absorbent article further comprises two elastic elements, wherein each elastic element has a greater length in the length direction (Y) of the product and a smaller length in the width direction (X) of the product.

Each elastic element extends along one longitudinal edge of the absorbent core so that along most of the length of the elastic elements in the length direction (Y), the elastic elements overlap both a part of the absorbent core and a portion of the edge seam in the width direction (X).

Thus, the absorbent core and the edge seam interact so that the deformation of the product can be controlled throughout the product, which improves the fit and ability of the absorbent product to process liquids. The performance of the bend indicators is also improved.

The elastic elements can overlap both a part of the absorbent core and a part of the edge seam in the width direction (X) along essentially the entire length of the elastic elements in the length direction (Y). Accordingly, the elastic elements are located on the side of the absorbent core facing the wearer. Preferably, the elastic elements overlap both a portion of the absorbent core and a portion of the edge seam to a substantially equal extent in the width direction (X).

In one embodiment, the absorbent core extends in the directions of length (Y), width (X), and thickness (Z) and comprises an upper absorbent core and a lower absorbent core. The upper core has a length in the X direction, which is greater than the length of the lower absorbent core in the X direction, at least in its certain area. The receiving layer is located between the specified upper and the specified lower absorbent cores in the direction of thickness (Z), at least in the specified area. The receiving layer has a length in the X direction, which is less than the length of the upper core in the X direction, at least in the specified area. The upper absorbent core comprises an opening located at least in said zone, such that the opening in the upper absorbent core is both above the receiving layer and above the lower absorbent core.

The upper core may comprise bend indicators that have their greatest extent substantially in the length direction (Y) and which are located between the hole and the edges of the upper core in the width direction (X) of the core. The hole in the upper core is preferably located in the center of the upper core in the width direction (X).

The absorbent core may further comprise an elastic forming element that overlaps at least a hole in the upper absorbent core. The forming element is positioned appropriately between the receiving layer and the lower absorbent core.

At least in the aforementioned zone, the forming element may have a length in the width direction (X) that is less than the length of the upper absorbent core in the width direction (X) and the length of the lower absorbent core in the width direction (X). The compression of the product in accordance with this embodiment in the width direction (X) forces it to take the form of a double bowl, namely the first bowl (A), which is determined by the curvature of the upper core, and the second smaller bowl (B) contained within the first bowl (A ), which is limited by a hole in the upper core.

DEFINITIONS

The term “upper” when used in relation to the component of the present invention is used to describe components that are closer to the body of the carrier in use. Similarly, the term "lower" when used with reference to the component of the present invention is used to describe components that are located further from the body of the carrier in use.

In the context of the present invention, the term “disposable, disposable” is used to describe a product that is not intended to be cleaned or reused, but rather discarded after use.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described in more detail with reference to the attached drawings, in which:

figure 1 is a plan view of an absorbent article of the invention,

figure 2 is a section along the line II-II in figure 1, when the product is not compressed,

figure 3 is a section along the line II-II in figure 1, when the product is compressed in the direction X of the width,

4 is a plan view of an absorbent article containing a composite absorbent core in accordance with the invention,

5 is a section along the line V-V in figure 4, when the product is not compressed,

6 is a section along the line V-V in figure 4, when the product is compressed in the direction X of the width,

7 is a perspective view of an absorbent article comprising a composite absorbent core in accordance with the invention,

Fig. 8 shows an embodiment of an absorbent article,

Fig.9 shows a device for measuring the stiffness of an absorbent product,

10 is a graph showing stiffness measurement data for various absorbent articles,

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The invention also relates to an absorbent article 100, which extends in the directions of length (Y), width (X) and thickness (Z). The absorbent product is disposable due to the fact that it is not intended for reuse, but, on the contrary, for discarding it after soiling. FIG. 1 illustrates a mild incontinence guard, although the invention is equally applicable to other absorbent articles, such as diapers, sanitary napkins, and panty liners for everyday use. The absorbent article 100 has a front portion 110, which, when used, is intended to close the user's pubic mound and to face the user's stomach, a rear part 120, which, when used, is designed to close the user's buttocks and to face its back and a crotch portion 130 located between said front and rear parts 110, 120 in the direction (Y) of the length of the article 100.

The absorbent article 100 comprises a liquid-permeable topsheet 101, a liquid-impervious backsheet 102, and an absorbent core 10 located between them.

The top sheet 101 of the product 100 is a layer that is in contact with the body of the carrier when using the product. Essentially, it should be soft, non-irritating to the skin and comfortable for the skin, and should allow for the unhindered passage of the fluid released by the body through it. The top sheet 101 may consist of a non-woven material, for example a non-woven material of a spunbond production method, a non-woven material obtained by the aerodynamic method from a melt, a non-woven material obtained by carding, hydro-entangling, a hydraulic method of forming a canvas, etc. Suitable non-woven materials may consist of natural fibers, such as wood pulp or cotton fibers, artificial fibers such as polyester, polyethylene, polypropylene, rayon, etc., or a mixture of natural and artificial fibers. In addition, the top sheet 101 may consist of fiber bundles that can be bonded to each other to form some kind of connection configuration, such as, for example, disclosed in EP-A-1035818. Additional examples of materials suitable for top sheets are porous plastics, plastic films with holes, etc. The top sheet 101 may be different in different parts of the absorbent article 100.

The back sheet 102 of the article 100 is the layer that is farthest from the body of the carrier when using the product. To protect the wearer's clothing from getting dirty, it must be impervious to liquids, but preferably gas-permeable to allow air and steam to pass into and out of the product in order to “weaken” the state of heating and humidity that may occur in the diaper. Typically, the backsheet 102 is made of a liquid impervious material, such as a thin plastic film, such as a polyethylene or polypropylene film, a non-woven material coated with a liquid-impervious material, a hydrophobic non-woven material that prevents the penetration of liquids, or a laminate containing plastic films and nonwoven materials. Examples of breathable backsheet materials are porous polymer films, non-woven laminates from layers obtained by a spinneret production method and an aerodynamic method from a melt, laminates from porous polymer films and non-woven materials. The backsheet 102 may be different in different parts of the absorbent article 100. An improved appearance of the absorbent article can be achieved by using a back sheet of textile material.

The absorbent core 10 is a component of the absorbent article 100, which receives and contains most of the fluid and other exudates secreted by the body, and can be any conventional type of absorbent core. Essentially, it typically contains absorbent material. Examples of frequently occurring absorbent materials are fluff pulverized pulp, thin paper layers, high absorbency polymers (so-called ultra-high absorbency polymers, SAP), absorbent foam materials, absorbent nonwoven materials, or the like. It is well known to “combine” fluff pulverized pulp with superabsorbents in an absorbent body. It is also well known to have absorbent cores containing layers of different materials with different properties from the point of view of the ability to receive liquids, the ability to distribute liquids and retention capacity. Thin absorbent cores, which are widely used, for example, in diapers for children and in protective devices used for incontinence, often contain a compressed mixed or layered structure of fluffy powdered cellulose and superabsorbent. The size and absorbency of the absorbent core 10 may vary to suit various applications, such as for babies or adult incontinence people.

The top sheet 101 and the back sheet 102, as a rule, have a similar length in the plane of the product, while the absorbent core 10 has a length that is slightly less. Typically, the absorbent core 10 has a total length, measured in a flat stretched state, of 120 to 800 mm, a total width of 40 to 150 mm, and a total thickness of 3 to 25 mm. The top sheet 101 and the back sheet 102 are connected to each other around the periphery of the absorbent core 10, so that the core 10 will be enclosed in a shell formed by the top sheet 101 and the back sheet 102. A fluid permeable top sheet 101 and a fluid impervious back sheet 102 extend beyond the absorbent core 10 at least in the width direction (X) and are connected to each other in the area outside the absorbent core 10 to form an edge seam 104. FIG. 1 shows that the top sheet 101 and the back sheet 102 can extend beyond sensing core 10 in all directions (X and Y). The top sheet 101 and the back sheet 102 can be connected to each other and to the core 10 by any means common in the art, for example by ultrasonic welding, heat sealing or gluing.

The absorbent article 100, in accordance with the invention, contains two elastic elements 103 (figure 1). The elastic elements may comprise elastic foam, elastic film or elastic non-woven material.

Each elastic element 103 has a greater length in the length direction (Y) of the product 100 and a smaller length in the width direction (X) of the product 100. Each elastic element 103 extends along one longitudinal edge 12 of the absorbent core 10 so that along most of the length of the elastic elements 103 in the length direction (Y), the elastic elements 103 overlap both part of the absorbent core 10 and part of the edge seam 104 in the width direction (X). By “predominantly” it is meant that the elastic elements 103 overlap both the absorbent core 10 and the edge seam 104 in the width direction (X) at least half their length in the length direction (Y), for example, preferably at least 70% or at least 80% of their length in the length direction (Y). The elastic elements 103 may even overlap both a part of the absorbent core 10 and a part of the edge seam 104 in the width direction (X) along essentially their entire length in the length direction (Y). The elastic members 103, measured in a flat stretched state, typically have a length in the direction of length (Y) of 1 to 30 cm, preferably 5 to 20 cm, more preferably 8 to 18 cm, most preferably 10 up to 15 cm. Accordingly, the elastic elements 103 are located next to the hole 21 in the width direction (X) and have a length in the length direction (Y) of the product, which is at least equal to the length of the hole 21 in the length direction (Y). In order for the elastic elements 103 to overlap both part of the absorbent core 10 and part of the edge seam 104, they must also have a certain width when measuring them in a flat unstretched state, for example, from 5 mm to 50 mm, preferably from 8 mm to 25 mm. The elastic elements are integral, at least in the direction of width (X) and preferably in all directions (X, Y, Z), that is, they should not contain many elastic elements, some of which could be located above the absorbent core 10, and some of which could be located above the marginal suture 104.

In the present invention, the elastic elements 103 overlap both a part of the absorbent core and a part of the edge seam (and attached to both the part of the absorbent core and the part of the edge seam), which means that the elastic elements act on both of these components. Therefore, the absorbent core 10 also assumes a preferred bowl shape, resulting in improved properties of the absorbent article 100 with respect to liquid handling (see FIG. 3).

To obtain the best shaping effect, the elastic elements 103 are located on the side of the absorbent core 10 facing the wearer. The elastic elements 103 can overlap both a part of the absorbent core 10 and a part of the edge seam 104 in substantially the same degree in the width direction (X) ( there is an overlap of 50/50), although the overlap can be 60:40 or even 70:30 in one direction or in the other. Preferably, the elastic members 103 overlap the absorbent core 10 at a greater distance in the width direction (X) than that at which they overlap the edge seam. However, the elastic members 103 may even cover the entire edge seam 104 at each side edge of the article.

In order to facilitate the formation of a cup-shaped shape, the absorbent core 10 may include bend indicators 22 that have their greatest extent, essentially in the direction of length (Y). These bend indicators 22 provide additional flexibility to the absorbent core 10 (see FIGS. 2, 3, and 5).

The bend indicators 22 essentially have a greater length in the length direction (Y) of the absorbent core 10. The absorbent core 10 preferably comprises at least two bend indicators 22, one on each of the two sides of the core 10 in the width direction (X) although a larger number of bend indicators 22 may be included to provide even more flexibility. The bend indicators 22 were illustrated in FIGS. 2 and 3 in the form of cutouts that extend all the way through the entire thickness of the absorbent core 10, however, compression lines, weakening lines or cutouts that do not extend all the way through the entire core 10 can also be used as indicators 22 folds. In addition, absorbent cores that contain compressed material obtained by the aerodynamic method of forming the canvas, can have a lower density of the material obtained by the aerodynamic method of forming the canvas in the areas of these bend indicators 22, which becomes almost invisible when compressed. The bend indicators 22 can extend to the edges of the absorbent core 10 in more than two places, so that the absorbent core 10 becomes divided into two or more separate parts that can move relative to each other. As shown in FIG. 1, the bend indicators 22 may be substantially curved and located closer to the axis of symmetry of the core 10 in the region 50 in the direction of the length (Y) of the absorbent core.

Figure 4 shows an embodiment of the invention in which the absorbent core is a composite core. The absorbent core 10 shown in FIG. 4 extends in the directions of length (Y), width (X), and thickness (Z). The absorbent core 10 of this embodiment has a layered structure comprising two cores — an upper absorbent core 20 located on the side of the absorbent core 10 facing the wearer and a lower absorbent core 30 located on the garment side of the absorbent core 10. Upper and lower the absorbent cores 20, 30 are separate objects, that is, they are manufactured separately and subsequently placed one on top of the other. The invention does not include solid absorbent cores 10 in which certain zones or areas can be considered as “upper” or “lower”. The upper and lower cores 20, 30 can independently of any other have any shape in the X-Y plane, such as an oval, rectangular or hourglass shape. Each core preferably has a thickness in the Z direction, which decreases from the middle of the core toward the edges. The thickness in the Z direction of each of the upper core 20 and the lower core 30, respectively, is from 2 to 20 mm. The upper and lower cores 20, 30 typically contain absorbing materials described above, which may be the same or different in the upper and lower cores. However, the lower core 30 typically has a higher absorption capacity than the upper core 20, which can be achieved, for example, by using a larger polymer with ultra-high absorption capacity or more fluff pulverized pulp.

At least in the region 50 of the length of the core 10, the upper core 20 has a length in the X direction that is greater than the length of the lower absorbent core 30 in the X direction. Accordingly, the width of the upper absorbent core 20 is 1.2-3 times the width of the lower absorbent core 30, preferably 1.2-2.5 times and most preferably 1.2-2.0 times the width of the lower absorbent core 30 at any given point in the Y direction. Figure 4 shows the upper core 20 with a length in the X direction, which exceeds extended the fact that the lower core 30 in the X direction along the entire length of the core 10 is a preferred embodiment. Indeed, the upper core 20 may even have a length in both X and Y directions that is greater than the length of the lower core 30 in both X and Y directions (also shown in FIG. 4). However, in order to obtain the desired shape, it is important that, at least in the region 50 of the length of the core 10, the upper core 20 has a length in the X direction that is greater than the length of the lower absorbent core 30 in the X direction.

As can be seen in FIGS. 5, 6 and 8, it is preferable that the lower absorbent core 30 has a length in the width direction (X) that is similar to the distance between the bend indicators 22 in the width direction (X) or the same as the distance between the bend indicators 22 in the direction of the width (X). In addition, it is preferable if the bend indicators 22 are located above the lateral edges of the lower absorbent core 30 along the length of the bend indicators (when viewed from the side of the article facing the carrier). In both of these cases, the bend indicators 22 and the lower absorbent core 30 can interact to provide the best shaping effect.

Zone 50 forms a portion extending mainly in the direction of length (Y) in which the desired double-cup shape is created by applying pressure to the longitudinal edges of the upper absorbent core 20. Zone 50 may extend along the entire length of the core 10 in the Y direction. less, zone 50 may extend only over a portion of the length of the core 10 in the length direction (Y), for example, from 10% to 80%, preferably from 15% to 70%, more preferably from 20% to 50% of the length of the core 10 Y direction. Preferably, an area of 50 scenes ingly about a line extending in the width direction (X), which is located at a distance from the front edge of the core 10 is one-third the length of the core 10.

The receiving layer 40 may be located between the specified upper 20 and the specified lower 30 absorbent cores in the direction of thickness (Z) (Fig.5-6). The receiving layer 40 serves to quickly receive the liquid, to temporarily hold it and to distribute it evenly over the upper and lower absorbent cores 20, 30. As a rule, it generally does not contain any materials with an ultrahigh absorption capacity, similar to those described above, but respectively contains fibrous materials, for example, such as synthetic fibers.

The receiving layer 40 is located at least in said zone 50 and can be located along the entire length of the core 10. At least in the zone 50, the receiving layer 40 has a length in the X direction that is less than the length of the upper core 20 in the X direction. How 4, the receiving layer 40 may have a length in the X direction that is less than the length of the upper core 20 in the X direction over the entire length of the receiving layer 40. The receiving layer 40 may have any shape in the XY plane, such as an oval, rectangular or hourglass shape. Preferably, it has a thickness in the Z direction, which is the same throughout the layer. The thickness of the receiving layer 40 in the Z direction is preferably from 0.5 to 7 mm.

The upper absorbent core 20 comprises an opening 21, as shown in FIGS. 4-7. The hole 21 passes through the entire thickness of the upper absorbent core 20 from one surface to another (see FIGS. 5-7). The operation of forming the hole 21 can be included as part of the manufacturing process of the upper core 20, that is, the hole 21 can be formed by stamping or extruding in the upper core 20 or formed in the mold in an operation that is part of the process of aerodynamic formation of the canvas (pneumatic laying). The hole 21 is located at least in the region 50 so that the hole 21 in the upper absorbent core 20 at least “overlaps” both the receiving layer 40 and the lower absorbent core 30. The hole 21 should have a surface area in the XY plane which is less than the surface area of the lower absorbent core 30, and preferably has lengths in each of the X and Y directions, which are less than the lengths of the lower absorbent core 30 in the X and Y directions.

Thus, when compressed in the direction of width (X), the structure of the absorbent core 10, similar to that described, provides the formation of a certain shape in the form of a double bowl, especially in zone 50. The first bowl (A) is formed due to the curvature of the upper core 20, and the boundaries the second smaller bowl (B) contained within the first bowl (A) is defined by an opening 21 in the upper core 20 (see FIG. 6). This form in the form of a double bowl is especially effective for the rapid and effective reception, distribution and retention of large amounts of body excretion. The location and overlap of the components of the absorbent core 10 provide the ability to precisely control the location, depth and shape of the configuration in the form of a double bowl and ensure that it will be formed in a predetermined manner.

The area 50 of the core 10 can be considered as that portion of the core 10 in which at least:

- the upper core 20 has a length in the width direction (X), which is greater than the length of the lower absorbent core 30 in the direction (X);

- the receiving layer 40 is located between the upper 20 and lower 30 absorbing cores;

- the receiving layer 40 has a length in the width direction (X), which is less than the length of the upper core 20 in the width direction (X), and

- the hole 21 is located at least partially.

The fulfillment of these requirements ensures the adoption by the core 10 of the desired shape in the form of a double bowl in the zone 50.

In order to facilitate the formation of the first bowl (A), the upper core 20 may include bend indicators 22 that have their greatest extent mainly in the length direction (Y) and which are located between the hole 21 and the edges of the upper core 20 in the width direction (X) cores 10. These bend indicators 22 provide additional flexibility in the upper core 20 (see FIG. 6).

The bend indicators 22 essentially have a greater length in the length direction (Y) of the absorbent core 10. The upper core 20 preferably contains at least two bend indicators 22, one on each of the two sides of the opening 21, although a larger number bend indicators 22 may be included for even more flexibility. The bend indicators 22 were illustrated in FIG. 4 in the form of cutouts that extend all the way through the entire thickness of the upper core 20, however, compression lines or cuts that do not extend all the way through the entire upper core 20 can also be used as bend indicators 22. The bend indicators 22 can extend to the edges of the upper absorbent core 20 in more than two places, so that the upper absorbent core 20 becomes divided into two or more separate parts that can move relative to each other. As shown in FIG. 4, the bend indicators 22 may be substantially curved and may be located closer to the axis of symmetry of the core 10 in the region 50 of the absorbent core 10.

Since the human body is symmetrical, the absorbent core is accordingly symmetric in the direction of width (X), that is, it has an axis of symmetry passing through its center parallel to the direction of length (Y). The absorbent cores 20, 30, the receiving layer 40, the bend indicators 22 and the hole 21 are located symmetrically with respect to this axis of symmetry.

In order to help prevent flattening of the three-dimensional structure of the absorbent core 10 under pressure in the width direction, the absorbent core 10 according to the invention may further comprise an elastic forming element 60 that overlaps at least a hole 21 in the upper absorbent core 20 (FIG. .4-8). This is especially important for thin absorbent products (defined here as products with a thickness of ≤ 15 mm). The forming element 60 is preferably located between the receiving layer 40 and the lower absorbent core 30 - thus, it will be less noticeable to the carrier and provide a better forming effect than if it were located elsewhere. To maintain the desired shape of the core 10, the forming element 60, respectively, has a width of 13 to 20 mm, preferably 14 to 19 mm, most preferably 15.5 to 18 mm with a transverse compressive force of 25 N when measured in accordance with the method described below. The forming element 60 having high rigidity will be perceived as uncomfortable for the user. The rigid forming element 60 will also give the absorbent article 100 a relatively flat surface on which urine enters.

In a particular embodiment, the forming member 60 has a particular shape similar to that shown in FIG. It has four branches 61: two front branches 61a extending forward in the length direction (Y), and two rear branches 61b extending back in the length direction (Y). It has a tapered portion 62 and a hole 63 in the middle. The narrowest part 62 should be located between the tendons in the crotch area, where the distance between the legs of the wearer is the smallest. The front branches 61a serve to maintain the shape of the absorbent core 10 at the front of the core 10, while the rear branches 61b have the same function at the rear of the core 10. The branches 61a, 61b also serve to maintain the optimal position of the core 10 relative to the carrier body even then when the media moves. In particular, the front branches 61a help prevent the product 100 from moving backward between the legs of the wearer. The hole 63 should overlap the hole 21 in the upper core 20 to allow liquid to pass through into the lower core 30. The hole 63 also provides some lateral flexibility that can be adjusted by changing the size and shape of the hole 63.

In the aforementioned region 50, the forming member 60 preferably has a length in the width direction (X) that is less than the length of the upper absorbent core 20 in the width direction (X) and the length of the lower absorbent core 30 in the width direction (X) (see FIGS. 5-7 ) Since the forming element 60 is generally liquid impermeable, such a design causes the liquid to flow around the edges of the forming element 60 in the width direction (X), which ensures the best use of the upper and lower absorbent cores 20 and 30 due to the distribution of the liquid, at least , in the direction of width (X). In addition, the forming element 60 may have a length in the direction of length (Y), which is less than the lengths of the upper and lower absorbent cores 20, 30 in this direction. Thus, the fluid flow is accelerated towards the ends of the core 10. The length of the forming element 60 in the direction of width (X) in the specified zone 50, as a rule, should be not more than 40 mm, preferably not more than 36 mm and most preferably not more than 32 mm at its narrowest point.

The forming element 60 is accordingly made of non-absorbent material, so that the liquid does not substantially affect its physical and mechanical properties. As mentioned above, it must also have the required stiffness. Therefore, suitable materials for the forming member 60 are plastic films, perforated plastic films, and reinforced fabric or reinforced non-woven materials. Combinations of similar materials in the form of a laminate are also possible.

The absorbent core 10 is located in the absorbent article 100 so that the cups A and B are formed in the proper place - at a distance from the front edge of the core 10 (i.e., from the edge that is closest to the wearer's stomach in use), which is approximately one third of the length the specified core 10.

All layers of the absorbent article 100 (top sheet 101, back sheet 102, core 10 including an upper core 20, a receiving layer 40, a lower core 30 and a possible forming element 60) are respectively in contact over substantially their entire overlapping area . They are preferably connected to each other in their overlapping zone by any suitable means known in the art, for example by gluing, heat sealing or ultrasonic welding. The adhesive joint may be, for example, a patterned joint or a spiral joint. Therefore, when compressing the article 100 in the width direction (X), all components are bent or bent together as one element.

RIGIDITY METHOD

"Rigidity" in the present invention is defined as the width of the product with a transverse compressive force of 25 N. The LRX device from Lloyd Instruments (generally indicated by 200 in FIG. 9) is connected to a computer 210 that uses Nexygen Ondio software for data collection.

Absorbent articles 100 are held at a temperature of 20-23 ° C. and a relative humidity of approximately 50% for 24 hours. The longitudinal center line of the article is marked on the top sheet 101 of the absorbent article 100 with a soft marking pen (pen), being careful not to damage the absorbent article. Make a mark along this longitudinal center line at a distance from the front edge of the core, which is one third of the length of the core 10.

The device consists of a clamp 201 configured to hold the absorbent article of the invention in a vertical plane so that one long edge (side edge) of the article 100 is facing up. The clamping jaws are TG26 of the product and have a length of 10 cm in the longitudinal direction (length direction) of the product.

The article 100 is clamped in the clamp 201, as shown in FIG. 9, so that the edges of the jaws of the clamp are located along the longitudinal center line of the product, and so that the mark located at a distance from the edge of the core, 1/3 of the length of the core, is centrally located in the clamp (i.e., so that the jaws extend 5 cm in either of two directions along the longitudinal center line relative to the mark). The jaws are clamped relative to the product under a pressure of 1 kN.

The foot 202 is located in a vertical direction above the clamp. The foot 202 is a rectangular piece of metal located in a horizontal plane that has a length of 3.5 cm (in the same direction in which the length of the jaws is determined) and a width of 4.8 cm. The centers of the foot 202 and the clamp 201 are aligned vertically one above the other and are at a sufficient distance from each other, so that there is no contact between the foot 202 and the absorbent product 100. The device is designed so that the foot 202 moves vertically downward with a pre-programmed speed (in this case, a speed of 100 mm per minute is used).

The computer 210 is configured to collect data related to the downward pressure of the tab 202 and the distance between the tab 202 and the clamp 201. For the present invention, the distance between the tab 202 and the jaws of the clamp 201 (i.e., axial longitudinal) is important. product line 100) at a pressure of 25 N. Distances are measured from the lower surface of the foot 202 to the upper surface of the clamp 201.

Figure 10 is a graph of the dependence of the load (N) on the value (Width of the crotch part) / 2 during loading (in mm) for a number of absorbent articles AE. Products A, D and E have a thickness that exceeds 15 mm, while products B (w), B (wo), C and F have a thickness of up to 15 mm. Product B is tested with (- w) and without (- wo) forming element.

When compressing the product in the transverse (lateral) direction with a force of approximately 10 N, products with a forming element have greater compression resistance and retain their width of the crotch part better than products without a forming element. With a force exceeding 15 N, there is a noticeable difference between products having forming elements and not having forming elements, in terms of maintaining the width of the crotch part and, therefore, providing a wider and flatter surface on which the liquid falls when it reaches the product .

10, it can also be seen that thin articles (B (wo), C, and F) have a smaller residual width of the crotch portion than corresponding thick articles (A, D, E) at a pressure of over 17 N.

When measuring the thickness of an absorbent product, a thickness gauge is used that has a rectangular foot with dimensions of 40 × 100 mm. The foot acts on the product with a pressure of 0.1 kPa.

The thickness of two absorbent articles is measured, and the average value represents the thickness of the absorbent article. Products must be kept at a temperature of 20-23 ° C and a relative humidity of approximately 50% for 24 hours before measurement. It is important that each product is aligned before measuring its thickness, which can be done by stretching the product to the stop.

The center of the rectangular tab of the thickness gauge is located above the longitudinal axial line at a distance that is one third of the length of the core from the front edge of the core (that is, in the same position on the product in the longitudinal direction in which the jaw centers are located when measuring the stiffness of the product). The longer sides (100 mm) of the foot are parallel to the longitudinal center lines of the product to be measured. The foot is carefully lowered onto the absorbent article, and the thickness is read on the thickness gauge after 5 seconds at a pressure of 0.1 kPa.

The present invention has been described with reference to a number of embodiments in the description and in the drawings. However, the invention should not be construed as limited only by these embodiments, but, on the contrary, features from different embodiments may be combined as desired. The scope of the invention should be considered as defined in the attached claims.

Claims (16)

1. An absorbent article (100) comprising a liquid-permeable topsheet (101), a liquid-impermeable backsheet (102) and an absorbent core (10) disposed therebetween, said absorbent article (100) extending in length directions (Y), width (X) and thickness (Z), the fluid permeable top sheet (101) and the fluid impermeable back sheet (102) extend beyond the absorbent core (10) in at least the direction width (X) and connected to each other in the area outside the absorbent core (10) to form boundary seam (104), said absorbent article (100) containing two elastic elements (103), each elastic element (103) having a greater length in the length direction (Y) of the product (100) and a smaller length in the width direction (X ) products (100), characterized in that each elastic element (103) extends along one longitudinal edge (12) of the absorbent core (10) so that along most of the length of the elastic elements (103) in the direction of length (Y), each of these elastic elements (103) overlaps as part of the absorb core (10), and part of the edge seam (104) in the direction of width (X). 2. An absorbent article (100) according to claim 1, in which the elastic elements (103) overlap both a part of the absorbent core (10) and a part of the edge seam (104) in the width direction (X) along essentially the entire length of the elastic elements (103) in the length direction (Y). 3. An absorbent article (100) according to any one of claims 1 and 2, in which the elastic elements (103) are located on the side of the absorbent core facing the carrier (10). 4. An absorbent article (100) according to claim 1, wherein the elastic elements (103) overlap both a part of the absorbent core (10) and a part of the edge seam (104) to a substantially equal extent in the width direction (X). 5. The absorbent article (100) according to claim 1, in which the elastic elements (103) overlap the entire edge seam (104) in the width direction (X) of the article (100). 6. The absorbent article (100) according to claim 1, wherein the absorbent core (10) comprises bend indicators (22) that have their greatest extent, essentially, in the length direction (Y) of the article (100). 7. An absorbent article (100) according to claim 6, containing two bend indicators (22) that have their greatest extent, essentially, in the direction of the length (Y) of the article (100). 8. The absorbent article (100) according to claim 1, wherein the absorbent core (10) extends in the directions of length (Y), width (X) and thickness (Z), wherein said absorbent core (10) comprises an upper absorbent core ( 20) and a lower absorbent core (30), wherein said upper core (20) has a length in the X direction that is greater than the length of the lower absorbent core (30) in the X direction, at least in its certain zone (50), while the receiving layer (40) is located between the specified upper (20) and the specified lower (30) absorbing and cores in the thickness direction (Z), at least in the specified zone (50), and the specified receiving layer (40) has a length in the X direction, which is less than the length of the upper core (20) in the X direction, at least in said zone (50), while the upper absorbent core (20) comprises an opening (21) located at least in said zone (50) so that the hole (21) in the upper absorbent core (20) is located both above the receiving layer (40) and above the lower absorbent core (30). 9. The absorbent article (100) according to claim 8, in which the elastic elements (103) are located next to the hole (21) in the width direction (X) and have a length in the length direction (Y) of the product, which is at least equal to the length of the hole (21) in the direction of the length (Y) of the product. 10. An absorbent article (100) according to any one of claims 8 and 9, in which the upper core (20) contains bend indicators (22) that have their greatest extent, essentially in the length direction (Y), and which are located between the hole (21) and the edges of the upper core (20) in the direction (X) of the width of the core (10). 11. The absorbent article (100) according to claim 10, in which the bend indicators (22) are essentially curved and are located closer to the axis of symmetry of the core (10) in the specified zone (50) in the direction of the length (Y) of the absorbent core (10). 12. The absorbent article (100) according to claim 9, in which the hole (21) in the upper core (20) is located in the center of the upper core (20) in the width direction (X). 13. An absorbent article (100) according to claim 8, in which the absorbent core (10) further comprises an elastic forming element (60) that overlaps at least a hole (21) in the upper absorbent core (20). 14. An absorbent article (100) according to claim 12, in which the forming element (60) is located between the receiving layer (40) and the lower absorbent core (30). 15. An absorbent article (100) according to any one of claims 11 to 13, wherein at least in said zone (50) the forming element (60) has a length in the width direction (X) that is less than the length of the upper absorbent core ( 20) in the direction of width (X) and the length of the lower absorbent core (30) in the direction of width (X). 16. The absorbent article (100) of claim 8, wherein compressing the article (100) in the width direction (X) forces it to take the form of a double bowl, namely the first bowl (A), which is determined by the curvature of the upper core (20), and a second smaller bowl (B) contained within the first bowl (A), which is bounded by an opening (21) in the upper core (20).

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